Classes

Classes are data structures with associated state and functions. A variable of class type either refers to a class instance, or contains a special nil value. Note that object is another name for a class instance. Storage for a class instance is not necessarily tied to the scope of the variable(s) referring to that class instance. It is possible for multiple variables to refer to the same class instance.

The new-expression can be used to create an instance of a class (Class New). Depending on the memory management strategy, a class instance is either deleted automatically or can be deleted using the delete-statement (Deleting Unmanaged Class Instances).

A class declaration (Class Declarations) generates a class type (Class Types). A variable of a class type can refer to an instance of that class or any of its derived classes.

A class is generic if it has generic fields. A class can also be generic if it inherits from a generic class. Generic classes and fields are discussed in Generic Types.

Class Declarations

A class is defined with the following syntax:

class-declaration-statement:
  'class' identifier class-inherit[OPT] { class-statement-list[OPT] }

class-inherit:
  : basic-class-type

class-statement-list:
  class-statement
  class-statement class-statement-list

class-statement:
  variable-declaration-statement
  method-declaration-statement
  type-declaration-statement
  empty-statement

A class-declaration-statement defines a new class type symbol specified by the identifier. It inherits from the class specified in the class-inherit clause, when provided (Inheritance).

The body of a class declaration consists of a sequence of statements where each of the statements either defines a variable (called a field), a procedure or iterator (called a method), or a type alias. In addition, empty statements are allowed in class declarations, and they have no effect.

If a class declaration contains a type alias or a parameter field, or it contains a variable or constant without a specified type and without an initialization expression, then it declares a generic class type. Generic classes are described in Generic Types.

Note

Future:.

Privacy controls for classes and records are currently not specified, as discussion is needed regarding its impact on inheritance, for instance.

Class Lifetime and Borrows

The lifetime of a class instance is the time between its creation and its deletion. It is legal to access the class fields or methods only during its lifetime.

Each allocation of a class instance specifies a memory management strategy. Four memory management strategies are available: owned, shared, borrowed, and unmanaged.

owned and shared class instances always have their lifetime managed by the compiler. In other words, the compiler automatically calls delete on these instances to reclaim their memory. For these instances, = and copy initialization can result in the transfer or sharing of ownership. See the module documentation for owned and shared. When borrowed is used as a memory management strategy in a new-expression, it also creates an instance that has its lifetime managed by the compiler (Class New).

Class instances that are unmanaged have their lifetime managed explicitly and delete must be used to reclaim their memory.

No matter the memory management strategy used, class types support borrowing. A borrowed class instance refers to the same class instance as another variable but has no impact on the lifetime of that instance. The process of getting such a reference to an instance is called borrowing.

There are several ways to borrow an instance. To borrow explicitly the instance managed by another variable, call the .borrow() method. Additionally, coercions are available that are equivalent to calling the .borrow() method. For example:

Example (borrowing.chpl).

class C { }
proc test() {
  var own = new owned C();   // 'own' manages the memory of the instance
  var b = own.borrow();      // 'b' refers to the same instance but has no
                             // impact on the lifetime.

  var bc: borrowed C = own;  // 'bc' stores the result of own.borrow()
                             // due to coercion from owned C to
                             // borrowed C

                             // Note that these coercions can also apply
                             // in the context of procedure calls.

                             // the instance referred to by 'own' is
                             // deleted here, at the end of the containing
                             // block.
}

The .borrow() method is available on all class types (including unmanaged and borrowed) in order to support generic programming. For nilable class types, it returns the borrowed nilable class type.

Errors due to accessing an instance after the end of its lifetime are particularly difficult to debug. For this reason, the compiler includes a component called the lifetime checker. It identifies some cases where a borrowing variable can be accessed beyond the lifetime of an instance it refers to.

Note

Future:

The details of lifetime checking are not yet finalized or specified. Additional syntax to specify the lifetimes of function returns will probably be needed.

Class Types

A class type is formed by the combination of a basic class type and a memory management strategy.

class-type:
  basic-class-type
  'owned' basic-class-type
  'shared' basic-class-type
  'borrowed' basic-class-type
  'unmanaged' basic-class-type

A basic class type is given simply by the class name for non-generic classes. Generic classes must be instantiated to serve as a fully-specified type, for example to declare a variable. This is done with type constructors, which are defined in Section The Type Constructor.

basic-class-type:
  identifier
  identifier ( named-expression-list )

A basic class type, including a generic class type that is not fully specified, may appear in the inheritance lists of other class declarations.

If no memory management strategy is indicated, the class will be considered to have generic management.

Variables of class type cannot store nil unless the class type is nilable (Nilable Class Types).

The memory management strategies have the following meaning:

  • owned the instance will be deleted automatically when the owned variable goes out of scope, but only one owned variable can refer to the instance at a time. See the module documentation for owned.

  • shared will be deleted when all of the shared variables referring to the instance go out of scope. See the module documentation for shared.

  • borrowed refers to a class instance that has a lifetime managed by another variable.

  • unmanaged the instance must have delete called on it explicitly to reclaim its memory.

It is an error to apply more than one memory management strategy to a class type. However, in some cases, generic code needs to compute a variant of the class type using a different memory management strategy. Casts from the class type to a different memory management strategy are available for this purpose (see Explicit Class Conversions).

Example (duplicate-management.chpl).

class C { }
var x: borrowed unmanaged C;

Example (changing-management.chpl).

class C { }
type borrowedC = borrowed C;
type ownedC = (borrowedC:owned);

Nilable Class Types

Variables of a class type cannot store nil and do not have a default value unless the class type is nilable. To create a nilable class type, use the postfix ? operator. For example, if C is a class, then C? indicates the nilable class type with generic memory management strategy. The ? operator can be combined with memory management specifiers as well. For example, borrowed C? indicates a nilable class using the borrowed memory management strategy. Note that the ? operator applies only to types.

A nilable type can also be created with a cast to class?. For example, if T is a class type, then T: class? indicates its nilable counterpart, or T itself if it is already nilable. T: borrowed class? produces the nilable borrowed variant of T.

To create a non-nilable class type from a nilable class type, apply a cast to class or to a more specific type. For example, if T is a class type, then T: class indicates its non-nilable counterpart, or T itself if it is already non-nilable. T: borrowed class produces the non-nilable borrowed variant of T.

The postfix ! operator converts a class value to a non-nilable type. If the value is not nil, it returns a copy of that value if it is borrowed or unmanaged, or a borrow from it if it is owned or shared. If the value is in fact nil, it halts.

An alternative to ! is to use a cast to a non-nilable type. Such a cast will throw NilClassError if the value was in fact nil. See Explicit Class Conversions.

Non-nilable class types are implicitly convertible to nilable class types. See Implicit Class Conversions.

Class methods generally expect a receiver of type borrowed C (see Class Methods). Since such a class method call might involve dynamic dispatch, it is a program error to call a class method on a class receiver storing nil. The compiler will not resolve calls to class methods if the receiver has nilable type. If the programmer knows that the receiver cannot store nil at that moment, they can use ! to assert that the receiver is not nil and to convert it to the non-nilable borrowed type. For example:

Example (nilable-classes-bang.chpl).

class C {
  proc method() { }
}
var c: owned C? = new C();

// Invoke c.method() only when c is non-nil.
if c != nil {
  c!.method(); // c! converts from 'owned C?' to 'borrowed C'
}

The borrow() method is an exception. Suppose it is invoked on an expression of a class type C. It will return borrowed C for any non-nilable C type (e.g. owned C). It will return borrowed C? for any nilable C type (e.g. C?).

Class Values

A class value is either a reference to an instance of a class or nil (The nil Value). Class instances can be created using a new expression (Class New).

For a given class type, a legal value of that type is a reference to an instance of either that class or a class inheriting, directly or indirectly, from that class. nil is a legal value of any non-nilable class type.

The default value of a concrete nilable class type is nil. Generic class types and non-nilable class types do not have a default value. For this reason, rectangular arrays of non-nilable classes cannot be resized, since the new array values don’t have a logical default value. For similar reasons, associative and sparse arrays of non-nilable classes are not currently supported.

Example (declaration.chpl).

class C { }
var c : owned C?;    // c has class type owned C?, meaning
                     // the instance can be nil and is deleted automatically
                     // when it is not.
c = new C();         // Now c refers to an initialized instance of type C.
var c2 = c.borrow(); // The type of c2 is borrowed C?.
                     // c2 refers to the same object as c.
class D : C {}    // Class D is derived from C.
c = new D();      // Now c refers to an object of type D.
                  // Since c is owned, the previous is deleted.
// the C and D instances allocated above will be reclaimed
// at the end of this block.

When the variable c is declared, it initially has the value of nil. The next statement assigned to it an instance of the class C. The declaration of variable c2 shows that these steps can be combined. The type of c2 is also borrowed C?, determined implicitly from the the initialization expression. Finally, an object of type owned D is created and assigned to c.

The nil Value

Chapel provides nil to indicate the absence of a reference to any object. Invoking a class method or accessing a field of the nil value results in a run-time or compile-time error.

nil can be assigned to a variable of any nilable class type. There is a restriction for using nil as the default value or the actual argument of a function formal, or as the initializer for a variable or a field. Such a use is disallowed when the declared type of the formal/variable/field is non-nilable or generic, including generic memory management.

Class Fields

A variable declaration within a class declaration defines a field within that class. Each class instance consists of one variable per each var or const field in the class.

Example (defineActor.chpl).

The code

class Actor {
  var name: string;
  var age: uint;
}

defines a new class type called Actor that has two fields: the string field name and the unsigned integer field age.

Field access is described in Field Accesses.

Note

Future:

ref fields, which are fields corresponding to variable declarations with ref or const ref keywords, are an area of future work.

Class Methods

Methods on classes are referred to as class methods. See Methods for more information about methods.

Within a class method, the type of this is generally the non-nilable borrowed variant of the class type. It is different for type methods (see below) and it might be a different type if the class method is declared as a secondary method with a type expression.

For example:

Example (class-method-this-type.chpl).

class C {
  proc primaryMethod() {
    assert(this.type == borrowed C);
  }
}
proc C.secondaryMethod() {
  assert(this.type == borrowed C);
}
proc (owned C?).secondaryMethodWithTypeExpression() {
  assert(this.type == owned C?);
}

var x:owned C? = new owned C();
x!.primaryMethod();   // within the method, this: borrowed C
x!.secondaryMethod(); // within the method, this: borrowed C
x.secondaryMethodWithTypeExpression(); // within the method, this: owned C?

For type methods on a class, this will accept any management or nilability variant of the class type and it will refer to that type in the body of the method. For example:

Example (class-type-method-this.chpl).

class C {
  proc type typeMethod() {
    writeln(this:string); // print out the type of 'this'
  }
}
(C).typeMethod(); // prints 'C'
(owned C).typeMethod(); // prints 'owned C'
(borrowed C?).typeMethod(); // prints 'borrowed C?'

When a type method is defined only in a parent class, the type will be the corresponding variant of the parent class. For example:

Example (class-type-method-inherit.chpl).

class Parent { }
class Child : Parent { }
proc type Parent.typeMethod() {
  writeln(this:string); // print out the type 'this'
}

Child.typeMethod(); // prints 'Parent'
(borrowed Child?).typeMethod(); // prints 'borrowed Parent?'

Nested Classes

A class defined within another class or record is a nested class. A nested class can be referenced only within its immediately enclosing class or record.

Inheritance

A class inherits, or derives, from the class specified in the class declaration’s class-inherit clause when such clause is present. Otherwise the class inherits from the predefined object class (The object Class). In either case, there is exactly one parent class. There can be many classes that inherit from a particular parent class.

It is possible for a class to inherit from a generic class. Suppose for example that a class C inherits from class ParentC. In this situation, C will have type constructor arguments based upon generic fields in the ParentC as described in The Type Constructor. Furthermore, a fully specified C will be a subclass of a corresponding fully specified ParentC.

The object Class

All classes are derived from the object class, either directly or indirectly. If no class name appears in class-inherit clause, the class derives implicitly from object. Otherwise, a class derives from object indirectly through the class it inherits. A variable of type object can hold a reference to an object of any class type.

Accessing Base Class Fields

A derived class contains data associated with the fields in its base classes. The fields can be accessed in the same way that they are accessed in their base class unless a getter method is overridden in the derived class, as discussed in Overriding Base Class Methods.

Shadowing Base Class Fields

A field in the derived class can be declared with the same name as a field in the base class. Such a field shadows the field in the base class in that it is always referenced when it is accessed in the context of the derived class.

Open issue.

There is an expectation that there will be a way to reference the field in the base class but this is not defined at this time.

Overriding Base Class Methods

If a method in a derived class is declared with a signature identical to that of a method in a base class, then it is said to override the base class’s method. Such methods may be considered for dynamic dispatch if certain criteria are met. In particular, dynamic dispatch will be used when the method receiver has a static type of the base class but refers to an instance of a derived class type. Additionally, a method eligible for dynamic dispatch must not be a class method (see Class Methods), must not return type, and must not return param.

Rationale.

Class methods, methods that return type, and methods that return param are not considered as candidates for dynamic dispatch because they are resolved at compile-time based on the static type of the method receiver.

In order to have identical signatures, two methods must have the same names, and their formal arguments must have the same names, intents, types, and order.

The return type of the overriding method must either be the same as the return type of the base class’s method or be a subclass of the base class method’s return type.

Methods that override a base class method must be marked with the override keyword in the procedure-kind. Additionally, methods marked with override but for which there is no parent class method with an identical signature will result in a compiler error.

Rationale.

This feature is designed to help avoid cases where class authors accidentally override a method without knowing it; or fail to override a method that they intended to due to not meeting the identical signature condition.

Methods without parentheses are not candidates for dynamic dispatch.

Rationale.

Methods without parentheses are primarily used for field accessors. A default is created if none is specified. The field accessor should not dispatch dynamically since that would make it impossible to access a base field within a base method should that field be shadowed by a subclass.

Class New

To create an instance of a class, use a new expression. For example:

Example (class-new.chpl).

class C {
  var x: int;
}
var instance = new C(1);

The new expression can be defined by the following syntax:

new-expression:
  'new' type-expression ( argument-list )

An initializer for a given class is called by placing the new operator in front of a type expression. Any initializer arguments follow the class name in a parenthesized list.

Syntactically, the type-expression includes owned, shared, borrowed, and unmanaged. However these have important consequences for class new expressions. In particular, suppose C is a type-expression that results in a class type. Then:

  • new C() is the same as new owned C()

  • new owned C() allocates and initializes an instance that will be deleted at the end of the current block unless it is transferred to another owned variable. It results in something of type owned C.

  • new shared C() allocates and initializes the instance that will be deleted when the last shared variable referring to it goes out of scope. Results in something of type shared C.

  • new borrowed C() allocates and initializes an instance that will be automatically deleted at the end of the current block. This process is managed by an owned temporary. Unlike new owned C(), this results in a value of type borrowed C and ownership of the instance cannot be transferred out of the block. In other words, new borrowed C() is equivalent to

    (new owned C()).borrow()
    
  • new unmanaged C() allocates and initializes an instance that must have delete called on it explicitly to avoid a memory leak. It results in something of type unmanaged C.

See also Class Lifetime and Borrows and Class Types.

Class Initializers

A new expression allocates memory for the desired class and invokes an initializer method on the uninitialized memory, passing any arguments following the class name. An initializer is implemented by a method named init and is responsible for initializing the fields of the class.

Any initializers declared in a program are user-defined initializers. If the program declares no initializers for a class, the compiler must generate an initializer for that class based on the types and initialization expressions of fields defined by that class.

User-Defined Initializers

A user-defined initializer is an initializer method explicitly declared in the program. An initializer declaration has the same syntax as a method declaration, with the restrictions that the name of the method must be init and there must not be a return type specifier. When an initializer is called, the usual function resolution mechanism (Function Resolution) is applied with the exception that an initializer may not be virtually dispatched.

A user-defined initializer is responsible for initializing all fields. An initializer may omit initialization of fields, but all fields that are initialized must be initialized in declaration order.

Initializers for generic classes (Generic Types) handle generic fields without default values differently and may need to satisfy additional requirements. See Section User-Defined Initializers for details.

Example (simpleInitializers.chpl).

The following example shows a class with two initializers:

class MessagePoint {
  var x, y: real;
  var message: string;

  proc init(x: real, y: real) {
    this.x = x;
    this.y = y;
    this.message = "a point";
  }

  proc init(message: string) {
    this.x = 0;
    this.y = 0;
    this.message = message;
  }
}  // class MessagePoint

// create two objects
var mp1 = new MessagePoint(1.0, 2.0);
var mp2 = new MessagePoint("point mp2");

The first initializer lets the user specify the initial coordinates and the second initializer lets the user specify the initial message when creating a MessagePoint.

Field Initialization Versus Assignment

Within the body of an initializer, the first use of a field as the left-hand side of an assignment statement will be considered initialization. Subsequent uses of the assignment operator on the field will invoke regular assignment as defined by the language.

Example (fieldInitAssignment.chpl).

The following example documents the difference between field initialization and field assignment.

class PointDoubleX {
  var x, y : real;

  proc init(x: real, y: real) {
    this.x = x;              // initialization
    writeln("x = ", this.x); // use of initialized field
    this.x = this.x * 2;     // assignment, use of initialized field

    this.y = y;              // initialization
  }
}

var p = new PointDoubleX(1.0, 2.0);

The first statement in the initializer initializes field x to the value of the formal x. The second statement simply reads the value of the initialized field. The third statement reads the value of the field, doubles it, and assigns the result to the field x.

If a field is used before it is initialized, an compile-time error will be issued.

Example (usedBeforeInitialized.chpl).

In the following code:

class Point {
  var x, y : real;

  proc init(x: real, y: real) {
    writeln(this.x); // Error: use of uninitialized field!
    this.x = x;
    this.y = y;
    writeln(this.y);
  }
}
var p = new Point(1.0, 2.0);

The first statement in the initializer reads the value of uninitialized field x, so the compiler will issue an error:

usedBeforeInitialized.chpl:4: In initializer:
usedBeforeInitialized.chpl:5: error: field "x" used before it is initialized

Omitting Field Initializations

In order to support productive and elegant initializers, the language allows field initializations to be omitted if the field has a type or if the field has an initialization expression. The compiler will insert initialization statements for such fields based on their types and default values.

Example (fieldInitOmitted.chpl).

In the following code:

class LabeledPoint {
  var x : real;
  var y : real;
  var msg : string = 'Unlabeled';

  proc init(x: real, y: real) {
    this.x = x;
    this.y = y;
    // compiler inserts "this.msg = 'Unlabeled'";
  }

  proc init(msg : string) {
    // compiler inserts "this.x = 0.0;"
    // compiler inserts "this.y = 0.0;"
    this.msg = msg;
  }
}

var A = new LabeledPoint(2.0, 3.0);
var B = new LabeledPoint("Origin");

The first initializer initializes the values of fields x and y, and the compiler inserts initialization for the msg field by using its default value. The second initializer initializes the msg field, and the compiler inserts initialization for fields x and y based on the type of those fields (Default Initialization).

In order to reduce ambiguity and to ensure a well-defined order for side-effects, the language requires that all fields be initialized in field declaration order. This applies regardless of whether field initializations are omitted from the initializer body. If fields are initialized out of order, a compile-time error will be issued.

Example (fieldsOutOfOrder.chpl).

In the following code:

class Point3D {
  var x = 1.0;
  var y = 1.0;
  var z = 1.0;

  proc init(x: real) {
    this.x = x;
    // compiler inserts "this.y = 1.0;"
    this.z = y * 2.0;
  }

  proc init(x: real, y: real, z: real) {
    this.x = x;
    this.z = z;
    this.y = y; // Error!
  }
}

var A = new Point3D(1.0);
var B = new Point3D(1.0, 2.0, 3.0);

The first initializer leverages the well-defined order of omitted field initialization to use the default value of field y in order to explicitly initialize field z.

The second initializer initializes field z before field y, causing a compile-time error to be issued.

Rationale.

Without this rule the compiler could insert default initialization for field y before z is explicitly initialized. The following statement would then be assignment to field y, despite appearing to be initialization. This subtle difference may be confusing and surprising, and is avoided by requiring fields to be initialized in field declaration order.

Limitations on Instance Usage in Initializers

As the initializer makes progress, the class instance is incrementally initialized. In order to prevent usage of uninitialized memory, there are restrictions on usage of the class instance before it is fully initialized:

  • Methods may not be invoked on partially-initialized instances

  • this may not be passed to functions while partially-initialized

These rules allow all methods and functions to assume that class instances have been initialized, provided their value is not nil.

Rationale.

The compiler could conceivably attempt to analyze methods and functions to determine which fields are used, and selectively allow method calls on partially-initialized class instances. Instead, it is simpler for the language to forbid method calls on partially-initialized instances.

Methods may be called and this may be passed to functions only after the built-in complete method is invoked. This method may not be overridden. If any fields have not been initialized by the time the complete method is invoked, they will be considered omitted and the compiler will insert initialization statements as described earlier. If the user does not invoke the complete method explicitly, the compiler will insert a call to complete at the end of the initializer.

Rationale.

Due to support for omitted field initialization, there is potential for confusion regarding the overall status of initialization. This confusion is addressed in the design by requiring complete to explicitly mark the transition between partially and fully initialized instances.

Implementors’ note.

Even if the user explicitly initializes every field, the complete method is still required to invoke other methods.

Example (thisDotComplete.chpl).

In the following code:

class LabeledPoint {
  var x, y : real;
  var max = 10.0;
  var msg : string = 'Unlabeled';

  proc init(x: real, y: real) {
    this.x = x;
    this.y = y;
    // compiler inserts initialization for 'max' and 'msg'

    this.complete(); // 'this' is now considered to be fully initialized

    this.verify();
    writeln(this);
  }

  proc init(msg : string) {
    // compiler inserts initialization for fields 'x', 'y', and 'max'
    this.msg = msg;

    // Illegal: this.verify();
    // Implicit 'this.complete();'
  }

  proc verify() {
    if x > max || y > max then
      halt("LabeledPoint out of bounds!");
  }
}

var A = new LabeledPoint(1.0, 2.0);
var B = new LabeledPoint("Origin");

The first initializer leverages the complete method to initialize the remaining fields and to allow for the usage of the verify method. Calling the verify method or passing this to writeln before the complete method is called would result in a compile-time error.

The second initializer exists to emphasize the rule that even though all fields are initialized after the initialization of the msg field, the compiler does not consider the type initialized until the complete method is called. If the second initializer tried to invoke the verify method, a compile-time error would be issued.

Invoking Other Initializers

In order to allow for code-reuse, an initializer may invoke another initializer implemented for the same type. Because the invoked initializer must operate on completely uninitialized memory, a compile-time error will be issued for field initialization before a call to init. Because each initializer either explicitly or implicitly invokes the complete method, all fields and methods may be used after such a call to init.

Example (thisDotInit.chpl).

In the following code:

class Point3D {
  var x, y, z : real;

  proc init(x: real, y: real, z: real) {
    this.x = x;
    this.y = y;
    this.z = z;
    // implicit 'this.complete();'
  }

  proc init(u: real) {
    this.init(u, u, u);
    writeln(this);
  }
}

var A = new Point3D(1.0);

The second initializer leverages the first initializer to initialize all fields with the same value. After the init call the type is fully initialized, the complete method has been invoked, and so this can be passed to the writeln function.

Initializing Fields in Conditional Statements

Fields may be initialized inside of conditional statements, with the restriction that the same set of fields must be initialized in every branch. If the user omits any field initializations, the compiler will insert field initializations up to and including the field furthest in field declaration order between the conditional branches. If the else branch of a conditional statement is omitted, the compiler will generate an empty else branch and insert field initialization statements as needed.

Example (initFieldConditional.chpl).

In the following code:

class Point {
  var x, y : real;
  var r, theta : real;

  proc init(polar : bool, val : real) {
    if polar {
      // compiler inserts initialization for fields 'x' and 'y'
      this.r = val;
    } else {
      this.x = val;
      this.y = val;
      // compiler inserts initialization for field 'r'
    }
    // compiler inserts initialization for field 'theta'
  }
}

var A = new Point(true, 5.0);
var B = new Point(false, 1.0);

The compiler identifies field r as the latest field in both branches, and inserts omitted field initialization statements as needed to ensure that fields x, y, and r are all initialized by the end of the conditional.

Conditionals may also contain calls to parent initializers (Initializing Inherited Classes) and other initializers defined for the current type, provided that the initialization state is the same at the end of the conditional statement.

Example (thisDotInitConditional.chpl).

In the following code:

class Parent {
  var x, y : real;
}

class Child : Parent {
  var z : real;

  proc init(cond : bool, val : real) {
    if cond {
      super.init(val, val);
      this.z = val;
      this.complete();
    } else {
      this.init(val, val, val);
    }
  }

  proc init(x: real, y: real, z: real) {
    super.init(x, y);
    this.z = z;
  }
}

var c = new Child(true, 5.0);

The first initializer must invoke the complete method at the end of the if-branch in order to match the state at the end of the else-branch.

Miscellaneous Field Initialization Rules

Fields may not be initialized within loop statements or parallel statements.

The Compiler-Generated Initializer

A compiler-generated initializer for a class is created automatically if there are no initializers for that class in the program. The compiler-generated initializer has one argument for every field in the class, each of which has a default value equal to the field’s default value (if present) or the default value of the field’s type (if not). The order and names of arguments matches the order and names of field declarations within the class.

Generic fields are discussed in Section The Compiler-Generated Generic Initializer.

The compiler-generated initializer will initialize each field to the value of the corresponding actual argument.

Example (defaultInitializer.chpl).

Given the class

class C {
  var x: int;
  var y: real = 3.14;
  var z: string = "Hello, World!";
}

there are no user-defined initializers for C, so new expressions will invoke C’s compiler-generated initializer. The x argument of the compiler-generated initializer has the default value 0. The y and z arguments have the default values 3.14 and "Hello, World!”, respectively.

C instances can be created by calling the compiler-generated initializer as follows:

  • The call new C() is equivalent to new C(0,3.14,"Hello, World!").

  • The call new C(2) is equivalent to new C(2,3.14,"Hello, World!").

  • The call new C(z="") is equivalent to new C(0,3.14,"").

  • The call new C(2, z="") is equivalent to new C(2,3.14,"").

  • The call new C(0,0.0,"") specifies the initial values for all fields explicitly.

The postinit Method

The compiler-generated initializer is powerful and flexible, but cannot satisfy all initialization patterns desired by users. One way for users to leverage the compiler-generated initializer while adding their own functionality is to implement a method named postinit. The postinit method may also be implemented for types with user-defined initializers.

The compiler will insert a call to the postinit method after the initializer invoked by the new expression finishes, if the method exists. The postinit method accepts zero arguments and may not return anything. Otherwise, this method behaves like any other method.

Example (postinit.chpl).

In the following code:

class Point3D {
  var x, y : real;
  var max = 10.0;

  proc postinit() {
    verify();
  }

  proc verify() {
    writeln("(", x, ", ", y, ")");
    if x > max || y > max then
      writeln("  Point out of bounds!");
  }
}

var A = new Point3D();
var B = new Point3D(1.0, 2.0);
var C = new Point3D(y=5.0);
var D = new Point3D(50.0, 50.0);

Each of the new expressions invokes the compiler-generated initializer, then invokes the verify method via the postinit method:

(0.0, 0.0)
(1.0, 2.0)
(0.0, 5.0)
(50.0, 50.0)
  Point out of bounds!

For classes that inherit, the user may invoke the parent’s postinit method or let the compiler insert a call automatically (The postinit Method for Inheriting Classes).

Initializing Inherited Classes

User-defined initializers also allow for control over initialization of parent classes. All the fields of the parent type must be initialized before any fields of the child type, otherwise a compile-time error is issued. This allows for parent fields to be used in the definition of child fields. An initializer may invoke a parent’s initializer using the super keyword.

If the user does not explicitly call the parent’s initializer, the compiler will insert a call to the parent initializer with zero arguments at the start of the initializer.

Example (simpleSuperInit.chpl).

In the following code:

class A {
  var a, b : real;

  proc init() {
    this.init(1.0);
  }

  proc init(val : real) {
    this.a = val;
    this.b = val * 2;
  }
}

class B : A {
  var x, y : real;

  proc init(val: real, x: real, y: real) {
    super.init(val);
    this.x = x;
    this.y = y;
  }

  proc init() {
    // implicit super.init();
    this.x = a*2;
    this.y = b*2;
  }
}

var b1 = new B(4.0, 1.0, 2.0);
var b2 = new B();

The first initializer explicitly calls an initializer for class A. Once the parent’s initializer is complete, fields of class B may be initialized.

The second initializer implicitly invokes the parent’s initializer with zero arguments, and then uses the parent’s fields to initialize its own fields.

As stated earlier, the compiler will insert a zero-argument call to the parent’s initializer if the user has not explicitly written one themselves. The exception to this rule is if the initializer body invokes another initializer on the current type (Invoking Other Initializers). This other initializer will either contain an implicit or explicit call to the parent initializer, and so the calling initializer should not attempt to initialize the parent itself. This also means that parent fields may not be accessed before explicit calls to init.

Example (superInitThisInit.chpl).

In the following code:

class Parent {
  var x, y: real;
}

class Child : Parent {
  var z : real;

  proc init(x: real, y: real, z: real) {
    super.init(x, y);
    this.z = z;
  }

  proc init(z: real) {
    this.init(0.0, 0.0, z);
  }
}

var c = new Child(5.0);

The second initializer does not contain an implicit call to the parent’s initializer because it explicitly invokes another initializer.

Calling Methods on Parent Classes

Once super.init() returns, the dynamic type of this is the parent’s type until the complete method (Limitations on Instance Usage in Initializers) is invoked (except when the child’s fields are initialized and used). As a result, the parent’s methods may be called and this may be passed to functions as though it were of the parent type.

Rationale.

After super.init() returns the instance is in some partially-initialized, but valid, state. Allowing this to be treated as the parent allows for additional functionality and flexibility for users.

Example (dynamicThisInit.chpl).

In the following code:

class Parent {
  var x, y : real;

  proc foo() {
    writeln("Parent.foo");
  }
}

class Child : Parent {
  var z : real;

  proc init(x: real, y: real, z: real) {
    super.init(x, y); // parent's compiler-generated initializer
    foo(); // Parent.foo()
    this.z = z;
    this.complete();
    foo(); // Child.foo()
  }

  override proc foo() {
    writeln("Child.foo");
  }
}

var c = new Child(1.0, 2.0, 3.0);

Once the parent’s initializer is finished, the parent method foo may be called. After the complete method is invoked, a call to foo resolves to the child’s overridden (Overriding Base Class Methods) implementation:

Parent.foo
Child.foo
{x = 1.0, y = 2.0, z = 3.0}

The Compiler Generated Initializer for Inheriting Classes

The compiler-generated initializer for inheriting classes will have arguments with default values and names based on the field declarations in the parent class. Formals for the parent type will be listed before formals for the child type.

Example (compilerGeneratedInheritanceInit.chpl).

In the following code:

class Parent {
  var x, y: real;
}

class Child : Parent {
  var z : real;
}

var A = new Child();
var B = new Child(1.0, 2.0, 3.0); // x=1.0, y=2.0, z=3.0
var C = new Child(y=10.0);

Any new expressions using the Child type can invoke an initializer with three formals named x, y, and z that all have default values based on their types.

The postinit Method for Inheriting Classes

The postinit method on inheriting classes allows users to invoke the parent’s postinit method using the super keyword. If the user does not explicitly invoke the parent’s postinit, the compiler will insert the call at the top of the user’s postinit method. If the parent type has a postinit method but the inheriting class does not, the compiler will generate a postinit method that simply invokes the parent’s postinit method.

Example (inheritancePostinit.chpl).

In the following code:

class Parent {
  var a, b : real;
  proc postinit() {
    writeln("Parent.postinit: ", a, ", ", b);
  }
}

class Child : Parent {
  var x, y : real;
  proc postinit() {
    // compiler inserts "super.postinit();"
    writeln("Child.postinit: ", x, ", ", y);
  }
}

var c = new Child(1.0, 2.0, 3.0, 4.0);

The compiler inserts a call to the parent’s postinit method in the child’s postinit method, and invokes the child’s postinit method after the compiler-generated initializer finishes:

Parent.postinit: 1.0, 2.0
Child.postinit: 3.0, 4.0

Field Accesses

The field in a class is accessed via a field access expression.

field-access-expression:
  receiver-clause[OPT] identifier

receiver-clause:
  expression .

The receiver-clause specifies the receiver, which is the class instance whose field is being accessed. The receiver clause can be omitted when the field access is within a method. In this case the receiver is the method’s receiver. The receiver clause can also be omitted when the field access is within a class declaration. In this case the receiver is the instance being implicitly defined or referenced.

The identifier in the field access expression indicates which field is accessed.

A field can be modified via an assignment statement where the left-hand side of the assignment is a field access expression.

Accessing a parameter or type field returns a parameter or type, respectively. In addition to being available for access with a class instance receiver, parameter and type fields can be accessed from the instantiated class type itself.

Example (useActor1.chpl).

Given a variable anActor of type Actor as defined above, the code

var s: string = anActor.name;
anActor.age = 27;

reads the field name and assigns the value to the variable s, and assigns the field age in the object anActor the value 27.

Variable Getter Methods

All field accesses are performed via getters. A getter is a method without parentheses with the same name as the field. It is defined in the field’s class and has a ref return intent (The Ref Return Intent). If the program does not define it, the default getter, which simply returns the field, is provided.

Example (getterSetter.chpl).

In the code

class C {
  var setCount: int;
  var x: int;
  proc x ref {
    setCount += 1;
    return x;
  }
  proc x {
    return x;
  }

}

an explicit variable getter method is defined for field x. It returns the field x and increments another field that records the number of times x was assigned a value.

Class Method Calls

Class method calls are similar to other method calls which are described in Method Calls. However, class method calls are subject to dynamic dispatch.

The receiver-clause (or its absence) specifies the method’s receiver in the same way it does for field accesses Field Accesses.

See (The Method Receiver and the this Argument) for more details of about method receivers.

Common Operations

Class Assignment

Classes are assigned by reference. After an assignment from one variable of a class type to another, both variables reference the same class instance. Assignments from an owned variable to another owned or shared variable are an exception. They transfer ownership, leaving the source variable empty i.e. storing nil.

Example (owned-assignment.chpl).

// assume that C is a class
var a:owned C? = new owned C();
var b:owned C?; // default initialized to store `nil`
b = a; // transfers ownership from a to b
writeln(a); // a is left storing `nil`

In contrast, assignment for shared variables allows both variables to refer to the same class instance.

The following assignments between variables or expressions with different memory management strategies are disallowed:

  • to owned from shared or borrowed, as it would not ensure unique ownership of the instance

  • to shared from borrowed, as the original owner would be unaware of the shared ownership

  • to owned, shared, or borrowed from unmanaged, as both the source and the destination would appear responsible for deleting the instance

Deleting Unmanaged Class Instances

Memory associated with unmanaged class instances can be reclaimed with the delete statement:

delete-statement:
  'delete' expression-list ;

where the expression-list specifies the class objects whose memory will be reclaimed. Prior to releasing their memory, the deinitialization routines for these objects will be executed (Class Deinitializer). The expression-list can contain array expressions, in which case each element of that array will be deleted in parallel using a forall loop over the array. It is legal to delete a class variable whose value is nil, though this has no effect. If a class instance is referenced after it has been deleted, the behavior is undefined.

Example (delete.chpl).

The following example allocates a new object c of class type C and then deletes it.

var c : unmanaged C? = nil;
delete c;              // Does nothing: c is nil.

c = new unmanaged C(); // Creates a new object.
delete c;              // Deletes that object.

// The following statements reference an object after it has been deleted, so
// the behavior of each is "undefined":
// writeln(c.i); // May read from freed memory.
// c.i = 3;      // May overwrite freed memory.
// delete c;     // May confuse some allocators.

Class Deinitializer

A class author may create a deinitializer to specify additional actions to be performed when a class instance is deleted. A class deinitializer is a method named deinit(). It must take no arguments (aside from the implicit this argument). If defined, the deinitializer is called each time a delete statement is invoked with a valid instance of that class type. The deinitializer is not called if the argument of delete evaluates to nil. Note that when an owned or shared reaches its deinit point (see Deinit Points), it may call delete on a class instance which in turn will run the deinitializer and then reclaim the memory.

Example (classDeinitializer.chpl).

class C {
  var i: int;
  proc deinit() { writeln("Bye, bye ", i); }
}

var c : unmanaged C? = nil;
delete c;              // Does nothing: c is nil.

c = new unmanaged C(1); // Creates a new instance.
delete c;               // Deletes that instance: Writes out "Bye, bye 1"
                        // and reclaims the memory that was held by c.
{
  var own = new owned C(2); // Creates a new owned instance
                            // The instance is automatically deleted at
                            // the end of this block, so "Bye, bye 2" is
                            // output and then the memory is reclaimed.
}