The Next Scripting Language (NX) is a highly flexible object oriented scripting language based on Tcl [Ousterhout 1990]. NX is a successor of XOTcl 1 [Neumann and Zdun 2000a] and was developed based on 10 years of experience with XOTcl in projects containing several hundred thousand lines of code. While XOTcl was the first language designed to provide language support for design patterns, the focus of the Next Scripting Framework and NX is on combining this with Language Oriented Programming. In many respects, NX was designed to ease the learning of the language for novices (by using a more mainstream terminology, higher orthogonality of the methods, less predefined methods), to improve maintainability (remove sources of common errors) and to encourage developers to write better structured programs (to provide interfaces) especially for large projects, where many developers are involved.
The Next Scripting Language is based on the Next Scripting Framework (NSF) which was developed based on the notion of language oriented programming. The Next Scripting Frameworks provides C-level support for defining and hosting multiple object systems in a single Tcl interpreter. The name of the Next Scripting Framework is derived from the universal method combinator "next", which was introduced in XOTcl. The combinator "next" serves as a single instrument for method combination with filters, per-object and transitive per-class mixin classes, object methods and multiple inheritance.
The definition of NX is fully scripted (e.g. defined in
nx.tcl
). The Next Scripting Framework is shipped with three language
definitions, containing NX and XOTcl 2. Most of the existing XOTcl 1
programs can be used without modification in the Next Scripting
Framework by using XOTcl 2. The Next Scripting Framework requires Tcl
8.5 or newer.
1. NX and its Roots
Object oriented extensions of Tcl have quite a long history. Two of the most prominent early Tcl based OO languages were incr Tcl (abbreviated as itcl) and Object Tcl (OTcl [Wetherall and Lindblad 1995]). While itcl provides a traditional C++/Java-like object system, OTcl was following the CLOS approach and supports a dynamic object system, allowing incremental class and object extensions and re-classing of objects.
Extended Object Tcl (abbreviated as XOTcl [Neumann and Zdun 2000a]) is a successor of OTcl and was the first language providing language support for design patterns. XOTcl extends OTcl by providing namespace support, adding assertions, dynamic object aggregations, slots and by introducing per-object and per-class filters and per-object and per-class mixins.
XOTcl was so far released in more than 30 versions. It is described in its detail in more than 20 papers and serves as a basis for other object systems like TclOO [Donal ???]. The scripting language NX and the Next Scripting Framework [Neumann and Sobernig 2009] extend the basic ideas of XOTcl by providing support for language-oriented programming. The the Next Scripting Framework supports multiple object systems concurrently. Effectively, every object system has different base classes for creating objects and classes. Therefore, these object systems can have different interfaces and can follow different naming conventions for built-in methods. Currently, the Next Scripting Framework is packaged with three object systems: NX, XOTcl 2.0, and TclCool (the language introduced by TIP#279).
The primary purpose of this document is to introduce NX to beginners. We expect some prior knowledge of programming languages, and some knowledge about Tcl. In the following sections we introduce NX by examples. In later sections we introduce the more advanced concepts of the language. Conceptually, most of the addressed concepts are very similar to XOTcl. Concerning the differences between NX and XOTcl, please refer to the "Migration Guide for the Next Scripting Language".
2. Introductory Overview Example: Stack
A classical programming example is the implementation of a stack, which
is most likely familiar to many readers from many introductory
programming courses. A stack is a last-in first-out data structure
which is manipulated via operations like push
(add something to the
stack) and pop
remove an entry from the stack. These operations are
called methods in the context of object oriented programming
systems. Primary goals of object orientation are encapsulation and
abstraction. Therefore, we define a common unit (a class) that defines
and encapsulates the behavior of a stack and provides methods to a user
of the data structure that abstract from the actual implementation.
2.1. Define a Class "Stack"
In our first example, we define a class named Stack
with the methods
push
and pop
. When an instance of the stack is created (e.g. a
concrete stack s1
) the stack will contain an instance variable named
things
, initialized with the an empty list.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 | nx::Class create Stack { # # Stack of Things # :variable things {} :public method push {thing} { set :things [linsert ${:things} 0 $thing] return $thing } :public method pop {} { set top [lindex ${:things} 0] set :things [lrange ${:things} 1 end] return $top } } |
Typically, classes are defined in NX via nx::Class create
, followed
by the name of the new class (here: Stack
). The definition of the
stack placed between curly braces and contains here just the method
definitions. Methods of the class are defined via :method
followed
by the name of the method, an argument list and the body of the
method, consisting of Tcl and NX statements.
When an instance of Stack
is created, it will contain an instance
variable named things
. If several Stack
instances are created,
each of the instances will have their own (same-named but different)
instance variable. The instance variable things
is used in our
example as a list for the internal representation of the stack. We
define in a next step the methods to access and modify this list
structure. A user of the stack using the provided methods does not
have to have any knowledge about the name or the structure of the
internal representation (the instance variable things
).
The method push
receives an argument thing
which should be placed
on the stack. Note that we do not have to specify the type of the
element on the stack, so we can push strings as well as numbers or
other kind of things. When an element is pushed, we add this element
as the first element to the list things
. We insert the element using
the Tcl command linsert
which receives the list as first element,
the position where the element should be added as second and the new
element as third argument. To access the value of the instance
variable we use Tcl’s dollar operator followed by the name. The
names of instance variables are preceded with a colon :
. Since the
name contains a non-plain character, Tcl requires us to put braces
around the name. The command linsert
and its arguments are placed
between square brackets. This means that the function linsert
is called and
a new list is returned, where the new element is inserted at the first
position (index 0) in the list things
. The result of the linsert
function is assigned again to the instance variable things
, which is
updated this way. Finally the method push
returns the pushed thing
using the return
statement.
The method pop
returns the most recently stacked element and removes
it from the stack. Therefore, it takes the first element from the list
(using the Tcl command lindex
), assigns it to the method-scoped
variable top
, removes the element from the instance variable
things
(by using the Tcl command lrange
) and returns the value
popped element top
.
This finishes our first implementation of the stack, more enhanced
versions will follow. Note that the methods push
and pop
are
defined as public
; this means that these methods can be
used from all other objects in the system. Therefore, these methods
provide an interface to the stack implementation.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 | #!/usr/bin/env tclsh package require nx nx::Class create Stack { # # Stack of Things # .... } Stack create s1 s1 push a s1 push b s1 push c puts [s1 pop] puts [s1 pop] s1 destroy |
Now we want to use the stack. The code snippet in Listing 3 shows how to use the class Stack in a script.
Since NX is based on Tcl, the script will be called with the Tcl shell
tclsh
. In the Tcl shell we have to require package nx
to use the
Next Scripting Framework and NX. The next lines contain the definition
of the stack as presented before. Of course, it is as well possible to
make the definition of the stack an own package, such we could simple
say package require stack
, or to save the definition of a stack
simply in a file and load it via source
.
In line 12 we create an instance of the stack, namely the stack object
s1
. The object s1
is an instance of Stack
and has therefore
access to its methods. The methods like push
or pop
can be invoked
via a command starting with the object name followed by the
method name. In lines 13-15 we push on the stack the values a
, then
b
, and c
. In line 16 we output the result of the pop
method
using the Tcl command puts
. We will see on standard output the
value+c+ (the last stacked item). The output of the line 17 is the
value b
(the previously stacked item). Finally, in line 18 we
destroy the object. This is not necessary here, but shows the life
cycle of an object. In some respects, destroy
is the counterpart of
create
from line 12.
Figure 4 shows the actual class and
object structure of the first Stack
example. Note that the common
root class is nx::Object
that contains methods for all objects.
Since classes are as well objects in NX, nx::Class
is a
specialization of nx::Object
. nx::Class
provides methods for
creating objects, such as the method create
which is used to create
objects (and classes as well).
2.2. Define an Object Named "stack"
The definition of the stack in Listing 2 follows the traditional object oriented approach, found in practically every object oriented programming language: Define a class with some methods, create instances from this class, and use the methods defined in the class in the instances of the class.
In our next example, we introduce generic objects and object
specific methods. With NX, we can define generic objects, which are
instances of the most generic class nx::Object
(sometimes called
"common root class"). nx::Object
is predefined and contains a
minimal set of methods applicable to all NX objects. In this example,
we define a generic object named stack
and provide methods for this
object. The methods defined above were methods provided by a class for
objects. Now we define object specific methods, which are methods
applicable only to the object for which they are defined.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 | nx::Object create stack { :object variable things {} :public object method push {thing} { set :things [linsert ${:things} 0 $thing] return $thing } :public object method pop {} { set top [lindex ${:things} 0] set :things [lrange ${:things} 1 end] return $top } } |
The example in Listing 5 defines the
object stack
in a very similar way as the class Stack
. But the
following points are different.
-
First, we use
nx::Object
instead ofnx::Class
to denote that we want to create a generic object, not a class. -
We use
:object variable
to define the variablethings
just for this single instance (the objectstack
). -
The definition for the methods
push
andpop
are the same as before, but here we defined these withobject method
. Therefore, these two methodspush
andpop
are object-specific.
In order to use
the stack, we can use directly the object stack
in the same way as
we have used the object s1
in Listing 3
the class diagram for this the object stack
.
A reader might wonder when to use a class Stack
or rather an object
stack
. A big difference is certainly that one can define easily
multiple instances of a class, while the object is actually a
single, tailored entity. The concept of the object stack
is similar to a module,
providing a certain functionality via a common interface, without
providing the functionality to create multiple instances. The reuse of
methods provided by the class to objects is as well a difference. If
the methods of the class are updated, all instances of the class will
immediately get the modified behavior. However, this does not mean that
the reuse for the methods of stack
is not possible. NX allows for
example to copy objects (similar to prototype based languages) or to
reuse methods via e.g. aliases (more about this later).
Note that we use capitalized names for classes and lowercase names for instances. This is not required and a pure convention making it easier to understand scripts without much analysis.
2.3. Implementing Features using Mixin Classes
So far, the definition of the stack methods was pretty minimal.
Suppose, we want to define "safe stacks" that protect e.g. against
stack under-runs (a stack under-run happens, when more pop
than
push
operations are issued on a stack). Safety checking can be
implemented mostly independent from the implementation details of the
stack (usage of internal data structures). There are as well different
ways of checking the safety. Therefore we say that safety checking is
orthogonal to the stack core implementation.
With NX we can define stack-safety as a separate class using methods
with the same names as the implementations before, and "mix" this
behavior into classes or objects. The implementation of Safety
in
stack under-runs and to issue error messages, when this happens.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 | nx::Class create Safety { # # Implement stack safety by defining an additional # instance variable named "count" that keeps track of # the number of stacked elements. The methods of # this class have the same names and argument lists # as the methods of Stack; these methods "shadow" # the methods of class Stack. # :variable count 0 :public method push {thing} { incr :count next } :public method pop {} { if {${:count} == 0} then { error "Stack empty!" } incr :count -1 next } } |
Note that all the methods of the class Safety
end with next
.
This command is a primitive command of NX, which calls the
same-named method with the same argument list as the current
invocation.
Assume we save the definition of the class Stack
in a file named
Stack.tcl
and the definition of the class Safety
in a file named
Safety.tcl
in the current directory. When we load the classes
Stack
and Safety
into the same script (see the terminal dialog in
e.g. a certain stack s2
as a safe stack, while all other stacks
(such as s1
) might be still "unsafe". This can be achieved via the
option -mixin
at the object creation time (see line 9 in
option -mixin
mixes the class Safety
into the new instance s2
.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 | % package require nx 2.0 % source Stack.tcl ::Stack % source Safety.tcl ::Safety % Stack create s1 ::s1 % Stack create s2 -object-mixin Safety ::s2 % s2 push a a % s2 pop a % s2 pop Stack empty! % s1 info precedence ::Stack ::nx::Object % s2 info precedence ::Safety ::Stack ::nx::Object |
When the method push
of s2
is called, first the method of the
mixin class Safety
will be invoked that increments the counter and
continues with next
to call the shadowed method, here the method
push
of the Stack
implementation that actually pushes the item.
The same happens, when s2 pop
is invoked, first the method of
Safety
is called, then the method of the Stack
. When the stack is
empty (the value of count
reaches 0), and pop
is invoked, the
mixin class Safety
generates an error message (raises an exception),
and does not invoke the method of the Stack
.
The last two commands in
Listing 8
use introspection to query for the objects
s1
and s2
in which order the involved classes are processed. This
order is called the precedence order
and is obtained via info
precedence
. We see that the mixin class Safety
is only in use for
s2
, and takes there precedence over Stack
. The common root class
nx::Object
is for both s1
and s2
the base class.
Note that in Listing 8,
the class Safety
is only mixed into a single object (here
s2
), therefore we refer to this case as a per-object mixin.
Figure 9 shows the class
diagram, where the class Safety
is used as a per-object mixin for
s2
.
The mixin class Safety
can be used as well in other ways, such as e.g. for
defining classes of safe stacks:
1 2 3 4 5 6 7 | # # Create a safe stack class by using Stack and mixin # Safety # nx::Class create SafeStack -superclass Stack -mixin Safety SafeStack create s3 |
The difference of a per-class mixin and an per-object mixin is that
the per-class mixin is applicable to all instances of the
class. Therefore, we call these mixins also sometimes instance mixins.
In our example in Listing 10,
Safety
is mixed into the definition of
SafeStack
. Therefore, all instances of the class SafeStack
(here
the instance s3
) will be using the safety definitions.
Figure 11 shows the class diagram
for this definition.
Note that we could use Safety
as well as a per-class mixin on
Stack
. In this case, all stacks would be safe stacks and we could
not provide a selective feature selection (which might be perfectly
fine).
2.4. Define Different Kinds of Stacks
The definition of Stack
is generic and allows all kind of elements
to be stacked. Suppose, we want to use the generic stack definition,
but a certain stack (say, stack s4
) should be a stack for integers
only. This behavior can be achieved by the same means as introduced
already in Listing 5, namely
object-specific methods.
1 2 3 4 5 6 7 8 9 10 11 | Stack create s4 { # # Create a stack with a object-specific method # to check the type of entries # :public object method push {thing:integer} { next } } |
The program snippet in Listing 12 defines an instance s4
of the class
Stack
and provides an object specific method for push
to implement
an integer stack. The method pull
is the same for the integer stack
as for all other stacks, so it will be reused as usual from the class
Stack
. The object-specific method push
of s4
has a value
constraint in its argument list (thing:integer
) that makes sure,
that only integers can be stacked. In case the argument is not an
integer, an exception will be raised. Of course, one could perform the
value constraint checking as well in the body of the method proc
by
accepting an generic argument and by performing the test for the value
in the body of the method. In the case, the passed value is an
integer, the push
method of Listing 12 calls next
, and therefore calls the
shadowed generic definition of push
as provided by Stack
.
1 2 3 4 5 6 7 8 9 10 | nx::Class create IntegerStack -superclass Stack { # # Create a Stack accepting only integers # :public method push {thing:integer} { next } } |
An alternative approach is shown in
Listing 13, where the class
IntegerStack
is defined, using the same method definition
as s4
, this time on the class level.
2.5. Define Object Specific Methods on Classes
In our previous examples we defined methods provided by classes (applicable for their instances) and object-specific methods (methods defined on objects, which are only applicable for these objects). In this section, we introduce methods that are defined on the class objects. Such methods are sometimes called class methods or static methods.
In NX classes are objects, they are specialized objects with
additional methods. Methods for classes are often used for managing
the life-cycles of the instances of the classes (we will come to this
point in later sections in more detail). Since classes are objects, we
can use exactly the same notation as above to define class methods by
using object method
. The methods defined on the class object are
in all respects idential with object specific methods shown in the
examples above.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 | nx::Class create Stack2 { :public object method available_stacks {} { return [llength [:info instances]] } :variable things {} :public method push {thing} { set :things [linsert ${:things} 0 $thing] return $thing } :public method pop {} { set top [lindex ${:things} 0] set :things [lrange ${:things} 1 end] return $top } } Stack2 create s1 Stack2 create s2 puts [Stack2 available_stacks] |
The class Stack2
in Listing 14 consists of the
earlier definition of the class Stack
and is extended by the
class-specific method available_stacks
, which returns the
current number of instances of the stack. The final command puts
(line 26) prints 2 to the console.
The class diagram in Figure 15 shows the
diagrammatic representation of the class object-specific method
available_stacks
. Since every class is a specialization of the
common root class nx::Object
, the common root class is often omitted
from the class diagrams, so it was omitted here as well in the diagram.
3. Basic Language Features of NX
3.1. Variables and Properties
In general, NX does not need variable declarations. It allows to
create or modify variables on the fly by using for example the Tcl
commands set
and unset
. Depending on the variable name (or more
precisely, depending on the variable name’s prefix consisting of
colons :
) a variable is either local to a method, or it is an
instance variable, or a global variable. The rules are:
-
A variable without any colon prefix refers typically to a method scoped variable. Such a variable is created during the invocation of the method, and it is deleted, when the method ends. In the example below, the variable
a
is method scoped. -
A variable with a single colon prefix refers to an instance variable. An instance variable is part of the object; when the object is destroyed, its instance variables are deleted as well. In the example below, the variable
b
is an instance variable. -
A variable with two leading colons refers to a global variable. The lifespan of a globale variable ends when the variable is explicitly unset or the script terminates. Variables, which are placed in Tcl namespaces, are also global variables. In the example below, the variable
c
is a global variable.
1 2 3 4 5 6 7 8 9 10 11 | nx::Class create Foo { :method foo args {...} # "a" is a method scoped variable set a 1 # "b" is an Instance variable set :b 2 # "c" is a global variable/namespaced variable set ::c 3 } } |
Listing 16 shows a method foo
of some class Foo
referring to differently scoped variables.
3.1.1. Properties: Instance Variables with Accessors
Generally, there is no need to define or declare instance variables in NX. In some cases, however, a definition of instance variables is useful. NX allows us to define instances variables as properties on classes, which are inherited to subclasses. Furthermore, the definition of properties can be used the check permissible values for instance variables or to initialize instance variables from default values during object initialization.
A property is a definition of an attribute (an instance variable) with accessor methods. A property definition might carry value-constraints and a default value.
The class diagram above defines the classes Person
and
Student
. For both classes, accessor methods are specified with the
same names as the attributes. (Note that we show the accessor methods
only in this example, we omit it in later ones). By defining
properties we can use the name of the attribute as method name to
access the attributes. The listing below shows an implementation of this
conceptual model in NX.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 | # # Define a class Person with properties "name" # and "birthday" # nx::Class create Person { :property name:required :property birthday } # # Define a class Student as specialization of Person # with additional properties # nx::Class create Student -superclass Person { :property matnr:required :property {oncampus:boolean true} } # # Create instances using object parameters # for the initialization # Person create p1 -name Bob Student create s1 -name Susan -matnr 4711 # Access property value via accessor method puts "The name of s1 is [s1 name]" |
By defining name
and birthday
as properties of Person
, NX
provides automatically accessor methods with the same name. The
accessors methods (or shortly called "accessors") provide read and
write access to the underlying instance variables. In our example, the
class Person
has two methods implied by the property
definition:
the method name
and the method birthday
.
The class Student
is defined as a specialization of Person
with
two additional properties: matnr
and oncampus
. The property
matnr
is required (it has to be provided, when an instance of this
class is created), and the property oncampus
is boolean, and is per
default set to true
. Note that the class Student
inherits the
properties of Person
. So, Student
has four properties in total.
The property definitions are also used to providing object
parameters
. These are typically non-positional parameters, which are
used during object creation to supply values to the instance
variables. In our listing, we create an instance of Person
using the
object parameter name
and provide the value of Bob
to the instance
variable name
. Similarly, we create an instance of Student
using
the two object parameters name
and matnr
. Finally, we use the
accessor method name
to obtain the value of the instance variable
name
of object s1
.
3.1.2. Instance Variables without Accessors
To define instances variables with default values without accessors
the predefined method variable
can be used. Such instance variables
are often used for e.g. keeping the internal state of an object. The
usage of variable
is in many respects similar to property
. One
difference is, that property
uses the same syntax as for method
parameters, whereas variable
receives the default value as a separate
argument (similar to the variable
command in Tcl). The introductory
Stack example in Listing 2 uses already
the method variable
.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 | nx::Class create Base { :variable x 1 # ... } nx::Class create Derived -superclass Base { :variable y 2 # ... } # Create instance of the class Derived Derived create d1 # Object d1 has instance variables # x == 1 and y == 2 |
Note that the variable definitions are inherited in the same way as
properties. The example in Listing 19 shows a
class Derived
that inherits from Base
. When an instance d1
is
created, it will contain the two instance variables x
and y
.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 | nx::Class create Base2 { # ... :method init {} { set :x 1 # .... } } nx::Class create Derived2 -superclass Base2 { # ... :method init {} { set :y 2 next # .... } } # Create instance of the class Derived2 Derived2 create d2 |
In many other object oriented languages, the instance variables are
initialized solely by the constructor (similar to class Derived2
in
Listing 20). This approach is certainly
also possible in NX. Note that the approach using constructors
requires an explicit method chaining between the constructors and is
less declarative than the approach in NX using property
and variable
.
3.2. Method Definitions
The basic building blocks of an object oriented program are object and classes, which contain named pieces of code, the methods.
Methods are subroutines (pieces of code) associated with objects and/or classes. A method has a name, receives optionally arguments during invocation and returns a value.
Plain Tcl provides subroutines, which are not associated with objects or classes. Tcl distinguishes between +proc+s (scripted subroutines) and commands (system-languages implemented subroutines).
Methods might have different scopes, defining, on which kind of objects these methods are applicable to. These are described in more detail later on. For the time being, we deal here with methods defined on classes, which are applicable for the instance of these classes.
3.2.1. Scripted Methods
Since NX is a scripting language, most methods are most likely scripted methods, in which the method body contains Tcl code.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 | # Define a class nx::Class create Dog { # Define a scripted method for the class :public method bark {} { puts "[self] Bark, bark, bark." } } # Create an instance of the class Dog create fido # The following line prints "::fido Bark, bark, bark." fido bark |
In the example above we create a class Dog
with a scripted method
named bark
. The method body defines the code, which is executed when
the method is invoked. In this example, the method bar
prints out a
line on the terminal starting with the object name (this is determined
by the built in command self
) followed by "Bark, bark, bark.". This
method is defined on a class and applicable to instances of the class
(here the instance fido
).
3.2.2. C-implemented Methods
Not all of the methods usable in NX are scripted methods; many
predefined methods are defined in the underlying system language,
which is typically C. For example, in Listing 21 we
used the method create
to create the class Dog
and to create the
dog instance fido
. These methods are implemented in C in the next
scripting framework.
C-implemented methods are not only provided by the underlying framework but might be as well defined by application developers. This is an advanced topic, not covered here. However, application developer might reuse some generic C code to define their own C-implemented methods. Such methods are for example accessors, forwarders and aliases.
An accessor method is in most cases a C-implemented method that accesses instance variables of an object. A call to an accessor without arguments uses the accessor as a getter, obtaining the actual value of the associated variable. A call to an accessor with an argument uses it as a setter, setting the value of the associated variable.
Accessors have already been discussed in the section about properties, in which the accessors were created automatically.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 | nx::Class create Dog { :public method bark {} { puts "[self] Bark, bark, bark." } :method init {} { Tail create [self]::tail} } nx::Class create Tail { :property {length:double 5} :public method wag {} {return Joy} } # Create an instance of the class Dog create fido # Use the accessor "length" as a getter, to obtain the value # of a property. The following call returns the length of the # tail of fido fido::tail length # Use the accessor "length" as a setter, to alter the value # of a property. The following call changes the length of # the tail of fido fido::tail length 10 # Proving an invalid values will raise an error fido::tail length "Hello" |
Listing 22 shows an extended example, where every dog
has a tail. The object tail
is created as a subobject of the dog in
the constructor init
. The subobject can be accessed by providing the
full name of the subobject fido::tail
. The method length
is an
C-implemented accessor, that enforces the value constraint (here a
floating point number, since length uses the value constraint
double
).
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 | nx::Class create Dog { :public method bark {} { puts "[self] Bark, bark, bark." } :method init {} { Tail create [self]::tail :public object forward wag [self]::tail wag } } nx::Class create Tail { :property {length 5} :public method wag {} {return Joy} } # Create an instance of the class Dog create fido # The invocation of "fido wag" is delegated to "fido::tail wag". # Therefore, the following method returns "Joy". fido wag |
Listing 23 again extends the example by adding a
forwarder named wag
to the object (e.g. fido
). The forwarder
redirects all calls of the form fido wag
with arbitrary arguments to
the subobject fido::tail
.
A forwarder method is a C-implemented method that redirects an invocation for a certain method to either a method of another object or to some other method of the same object. Forwarding an invocation of a method to some other object is a means of delegation.
The functionality of the forwarder can just as well be implemented as
a scripted method, but for the most common cases, the forward
implementation is more efficient, and the forward
method expresses
the intention of the developer.
The method forwarder
has several options to change e.g. the order of
the arguments, or to substitute certain patterns in the argument list
etc. This will be described in later sections.
3.2.3. Method-Aliases
An alias method is a means to register either an existing method, or a Tcl proc, or a Tcl command as a method with the provided name on a class or object.
In some way, the method alias is a restricted form of a forwarder, though it does not support delegation to different objects or argument reordering. The advantage of the method alias compared to a forwarder is that it has close to zero overhead, especially for aliasing c-implemented methods.
1 2 3 4 5 6 7 8 9 10 11 12 13 | nx::Class create Dog { :public method bark {} { puts "[self] Bark, bark, bark." } # Define a public alias for the method "bark" :public alias warn [:info method handle bark] # ... } # Create an instance of the class Dog create fido # The following line prints "::fido Bark, bark, bark." fido warn |
Listing 24 extends the last example by defining an alias for the method "bark". The example only shows the bare mechanism. In general, method aliases are very powerful means for reusing pre-existing functionality. The full object system of NX and XOTcl2 is built from aliases, reusing functionality provided by the next scripting framework under different names. Method aliases are as well a means for implementing traits in NX.
3.3. Method Protection
All kinds of methods might have different kind of protections in NX. The call-protection defines from which calling context methods might be called. The Next Scripting Framework supports as well redefinition protection for methods.
NX distinguishes between public
, protected
and private
methods,
where the default call-protection is protected
.
A public method can be called from every context. A protected
method can only be invoked from the same object. A private method
can only be invoked from methods defined on the same entity
(defined on the same class or on the same object) via the invocation
with the local flag (i.e. ": -local foo
").
All kind of method protections are applicable for all kind of methods, either scripted or C-implemented.
The distinction between public and protected leads to interfaces for classes and objects. Public methods are intended for consumers of these entities. Public methods define the intended ways of providing methods for external usages (usages, from other objects or classes). Protected methods are intended for the implementor of the class or subclasses and not for public usage. The distinction between protected and public reduces the coupling between consumers and the implementation, and offers more flexibility to the developer.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 | nx::Class create Foo { # Define a public method :public method foo {} { # .... return [:helper] } # Define a protected method :method helper {} { return 1 } } # Create an instance of the class: Foo create f1 # The invocation of the public method "foo" returns 1 f1 foo # The invocation of the protected method "helper" raises an error: f1 helper |
The example above uses :protected method helper …
. We could have
used here as well :method helper …
, since the default method
call-protection is already protected.
The method call-protection of private
goes one step further and
helps to hide implementation details also for implementors of
subclasses. Private methods are a means for avoiding unanticipated name
clashes. Consider the following example:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 | nx::Class create Base { :private method helper {a b} {expr {$a + $b}} :public method foo {a b} {: -local helper $a $b} } nx::Class create Sub -superclass Base { :public method bar {a b} {: -local helper $a $b} :private method helper {a b} {expr {$a * $b}} :create s1 } s1 foo 3 4 ;# returns 7 s1 bar 3 4 ;# returns 12 s1 helper 3 4 ;# raises error: unable to dispatch method helper |
The base class implements a public method foo
using the helper
method named helper
. The derived class implements a as well a public
method bar
, which is also using a helper method named helper
. When
an instance s1
is created from the derived class, the method foo
is invoked which uses in turn the private method of the base
class. Therefore, the invocation s1 foo 3 4
returns its sum. If
the local
flag had not beed used in helper, s1
would
have tried to call the helper of Sub
, which would be incorrect. For
all other purposes, the private methods are "invisible" in all
situations, e.g., when mixins are used, or within the next
-path, etc.
By using the -local
flag at the call site it is possible to invoce
only the local definition of the method. If we would call the method
without this flag, the resolution order would be the standard
resolution order, starting with filters, mixins, object methods
and the full intrinsic class hierarchy.
NX supports the modifier private
for methods and properties. In all
cases private
is an instrument to avoid unanticipated interactions
and means actually "accessible for methods defined on the same entity
(object or class)". The main usage for private
is to improve
locality of the code e.g. for compositional operations.
In order to improve locality for properties, a private property
defines therfore internally a variable with a different name to avoid
unintended interactions. The variable should be accessed via the
private accessor, which can be invoved with the -local
flag. In the
following example class D
introduces a private property with the
same name as a property in the superclass.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 | # # Define a class C with a (public) property "x" # nx::Class create C { :property {x c} } # # Define a subclass D with a private property "x" # and a method bar, which is capable of accessing # the private property. # nx::Class create D -superclass C { :private property {x d} :public method bar {p} {return [: -local $p]} } # # The private and public (or protected) properties # define internally separate variable that do not # conflict. # D create d1 puts [d1 x] ;# prints "c" puts [d1 bar x] ;# prints "d" |
Without the private
definition of the property, the definition of
property x
in class D
would shadow the
definition of the property in the superclass C
for its instances
(d1 x
or set :x
would return d
instead of c
).
3.4. Applicability of Methods
As defined above, a method is a subroutine defined on an object or class. This object (or class) contains the method. If the object (or class) is deleted, the contained methods will be deleted as well.
3.4.1. Instance Methods
Typically, methods are defined on a class, and the methods defined on the class are applicable to the instances (direct or indirect) of this class. These methods are called instance methods.
In the following example method, foo
is an instance method defined
on class C
.
1 2 3 4 5 6 7 8 | nx::Class create C { :public method foo {} {return 1} :create c1 } # Method "foo" is defined on class "C" # and applicable to the instances of "C" c1 foo |
There are many programming languages that only allow these types of methods. However, NX also allows methods to be defined on objects.
3.4.2. Object Methods
Methods defined on objects are object methods. Object methods are only applicable on the object, on which they are defined. Object methods cannot be inherited from other objects.
The following example defines an object method bar
on the
instance c1
of class C
, and as well as the object specific method
baz
defined on the object o1
. An object method is defined
via object method
.
Note that we can define a object method that shadows (redefines) for this object methods provided from classes.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 | nx::Class create C { :public method foo {} {return 1} :create c1 { :public object method foo {} {return 2} :public object method bar {} {return 3} } } # Method "bar" is an object specific method of "c1" c1 bar # object-specific method "foo" returns 2 c1 foo # Method "baz" is an object specific method of "o1" nx::Object create o1 { :public object method baz {} {return 4} } o1 baz |
3.4.3. Class Methods
A class method is a method defined on a class, which is only applicable to the class object itself. The class method is actually an object method of the class object.
In NX, all classes are objects. Classes are in NX special kind of objects that have e.g. the ability to create instances and to provide methods for the instances. Classes manage their instances. The general method set for classes is defined on the meta-classes (more about this later).
The following example defines a public class method bar
on class
C
. The class method is specified by using the modifier object
in
front of method
in the method definition command.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 | nx::Class create C { # # Define a class method "bar" and an instance # method "foo" # :public object method bar {} {return 2} :public method foo {} {return 1} # # Create an instance of the current class # :create c1 } # Method "bar" is a class method of class "C" # therefore applicable on the class object "C" C bar # Method "foo" is an instance method of "C" # therefore applicable on instance "c1" c1 foo # When trying to invoke the class method on the # instance, an error will be raised. c1 bar |
In some other object oriented programming languages, class methods are called "static methods".
3.5. Ensemble Methods
NX provides "ensemble methods" as a means to structure the method name space and to group related methods. Ensemble methods are similar in concept to Tcl’s ensemble commands.
An ensemble method is a form of a hierarchical method consisting of a container method and sub-methods. The first argument of the container method is interpreted as a selector (the sub-method). Every sub-method can be an container method as well.
Ensemble methods provide a means to group related commands together, and they are extensible in various ways. It is possible to add sub-methods at any time to existing ensembles. Furthermore, it is possible to extend ensemble methods via mixin classes.
The following example defines an ensemble method for string
. An
ensemble method is defined when the provide method name contains a
space.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 | nx::Class create C { # Define an ensemble method "string" with sub-methods # "length", "tolower" and "info" :public method "string length" {x} {....} :public method "string tolower" {x} {...} :public method "string info" {x} {...} ... :create c1 } # Invoke the ensemble method c1 string length "hello world" |
3.6. Method Resolution
When a method is invoked, the applicable method is searched in the following order:
In the case, no mixins are involved, first the object is searched for an object method with the given name, and then the class hierarchy of the object. The method can be defined multiple times on the search path, so some of these method definitions might be shadowed by the more specific definitions.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 | nx::Class create C { :public method foo {} { return "C foo: [next]"} } nx::Class create D -superclass C { :public method foo {} { return "D foo: [next]"} :create d1 { :public object method foo {} { return "d1 foo: [next]"} } } # Invoke the method foo d1 foo # result: "d1 foo: D foo: C foo: " # Query the precedence order from NX via introspection d1 info precedence # result: "::D ::C ::nx::Object" |
Consider the example in
foo
is invoked on object d1
, the object method has the highest
precedence and is therefore invoked. The object methods shadows
the same-named methods in the class hierarchy, namely the method foo
of class D
and the method foo
of class C
. The shadowed methods
can be still invoked, either via the primitive next
or via method
handles (we used already method handles in the section about method
aliases). In the example above, next
calls the shadowed method and
add their results to the results of every method. So, the final result
contains parts from d1
, D
and C
. Note, that the topmost next
in method foo
of class C
shadows no method foo
and simply
returns empty (and not an error message).
The introspection method info precedence
provides information about
the order, in which classes processed during method resolution.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 | nx::Class create M1 { :public method foo {} { return "M1 foo: [next]"} } nx::Class create M2 { :public method foo {} { return "M2 foo: [next]"} } # # "d1" is created based on the definitions of the last example # # Add the methods from "M1" as per-object mixin to "d1" d1 object mixin M1 # # Add the methods from "M2" as per-class mixin to class "C" C mixin M2 # Invoke the method foo d1 foo # result: "M1 foo: M2 foo: d1 foo: D foo: C foo: " # Query the precedence order from NX via introspection d1 info precedence # result: "::M1 ::M2 ::D ::C ::nx::Object" |
an extension of the previous example. We define here two additional
classes M1
and M2
which are used as per-object and per-class
mixins. Both classes define the method foo
, these methods shadow
the definitions of the intrinsic class hierarchy. Therefore an
invocation of foo
on object d1
causes first an invocation of
method in the per-object mixin.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 | # # "d1" is created based on the definitions of the last two examples, # the mixins "M1" and "M2" are registered. # # Define a public object method "bar", which calls the method # "foo" which various invocation options: # d1 public object method bar {} { puts [:foo] puts [: -local foo] puts [: -intrinsic foo] puts [: -system foo] } # Invoke the method "bar" d1 bar |
In the first line of the body of method bar
, the method foo
is
called as usual with an implicit receiver, which defaults to the
current object (therefore, the call is equivalent to d1 foo
). The
next three calls show how to provide flags that influence the method
resolution. The flags can be provided between the colon and the method
name. These flags are used rather seldomly but can be helpful in some
situations.
The invocation flag -local
means that the method has to be resolved
from the same place, where the current method is defined. Since the
current method is defined as a object method, foo
is resolved as
a object method. The effect is that the mixin definitions are
ignored. The invocation flag -local
was already introduced int the
section about method protection, where it was used to call private
methods.
The invocation flag -intrinsic
means that the method has to be resolved
from the intrinsic definitions, meaning simply without mixins. The
effect is here the same as with the invocation flag -local
.
The invocation flag -system
means that the method has to be resolved
from basic - typically predefined - classes of the object system. This
can be useful, when script overloads system methods, but still want to
call the shadowed methods from the base classes. In our case, we have
no definitions of foo
on the base clases, therefore an error message
is returned.
M1 foo: M2 foo: d1 foo: D foo: C foo:
d1 foo: D foo: C foo:
d1 foo: D foo: C foo:
::d1: unable to dispatch method 'foo'
3.7. Parameters
NX provides a generalized mechanism for passing values to either methods (we refer to these as method parameters) or to objects (these are called object parameters). Both kind of parameters might have different features, such as:
-
Positional and non-positional parameters
-
Required and non-required parameters
-
Default values for parameters
-
Value-checking for parameters
-
Multiplicity of parameters
TODO: complete list above and provide a short summary of the section
Before we discuss method and object parameters in more detail, we describe the parameter features in the subsequent sections based on method parameters.
3.7.1. Positional and Non-Positional Parameters
If the position of a parameter in the list of formal arguments (e.g. passed to a function) is significant for its meaning, this is a positional parameter. If the meaning of the parameter is independent of its position, this is a non-positional parameter. When we call a method with positional parameters, the meaning of the parameters (the association with the argument in the argument list of the method) is determined by its position. When we call a method with non-positional parameters, their meaning is determined via a name passed with the argument during invocation.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 | nx::Object create o1 { # # Method foo has positional parameters: # :public method foo {x y} { puts "x=$x y=$y" } # # Method bar has non-positional parameters: # :public method bar {-x -y} { puts "x=$x y=$y" } # # Method baz has non-positional and # positional parameters: # :public method baz {-x -y a} { puts "x? [info exists x] y? [info exists y] a=$a" } } # invoke foo (positional parameters) o1 foo 1 2 # invoke bar (non-positional parameters) o1 bar -y 3 -x 1 o1 bar -x 1 -y 3 # invoke baz (positional and non-positional parameters) o1 baz -x 1 100 o1 baz 200 o1 baz -- -y |
Consider the example in Listing 35. The method
foo
has the argument list x y
. This means that the first argument
is passed in an invocation like o1 foo 1 2
to x
(here, the value
1
), and the second argument is passed to y
(here the value 2
).
Method bar
has in contrary just with non-positional arguments. Here
we pass the names of the parameter together with the values. In the
invocation o1 bar -y 3 -x 1
the names of the parameters are prefixed
with a dash ("-"). No matter whether in which order we write the
non-positional parameters in the invocation (see line 30 and 31 in
Listing 35) in both cases the variables x
and y
in the body of the method bar
get the same values assigned
(x
becomes 1
, y
becomes 3
).
It is certainly possible to combine positional and non-positional
arguments. Method baz
provides two non-positional parameter (-y
and -y
) and one positional parameter (namely a
). The invocation in
line 34 passes the value of 1
to x
and the value of 100
to a
.
There is no value passed to y
, therefore value of y
will be
undefined in the body of baz
, info exists y
checks for the
existence of the variable y
and returns 0
.
The invocation in line 35 passes only a value to the positional
parameter. A more tricky case is in line 36, where we want to pass
-y
as a value to the positional parameter a
. The case is more
tricky since syntactically the argument parser might consider -y
as
the name of one of the non-positional parameter. Therefore we use --
(double dash) to indicate the end of the block of the non-positional
parameters and therefore the value of -y
is passed to a
.
3.7.2. Optional and Required Parameters
Per default positional parameters are required, and non-positional parameters are optional (they can be left out). By using parameter options, we can as well define positional parameters, which are optional, and non-positional parameters, which are required.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 | nx::Object create o2 { # # Method foo has one required and one optional # positional parameter: # :public method foo {x:required y:optional} { puts "x=$x y? [info exists y]" } # # Method bar has one required and one optional # non-positional parameter: # :public method bar {-x:required -y:optional} { puts "x=$x y? [info exists y]" } } # invoke foo (one optional positional parameter is missing) o2 foo 1 |
The example in Listing 36 defined method foo
with one required and one optional positional parameter. For this
purpose we use the parameter options required
and optional
. The
parameter options are separated from the parameter name by a colon. If
there are multiple parameter options, these are separated by commas
(we show this in later examples).
The parameter definition x:required
for method foo
is equivalent
to x
without any parameter options (see e.g. previous example),
since positional parameters are per default required. The invocation
in line 21 of Listing 36 will lead to an
undefined variable y
in method foo
, because no value us passed to
the optional parameter. Note that only trailing positional parameters might be
optional. If we would call method foo
of Listing 35 with only one argument, the system would raise an
exception.
Similarly, we define method bar
in Listing 36 with one required and one optional non-positional
parameter. The parameter definition -y:optional
is equivalent to
-y
, since non-positional parameter are per default optional.
However, the non-positional parameter -x:required
is required. If we
invoke bar
without it, the system will raise an exception.
3.7.3. Default Values for Parameters
Optional parameters might have a default value, which will be used, when not value is provided for this parameter. Default values can be specified for positional and non-positional parameters.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 | nx::Object create o3 { # # Positional parameter with default value: # :public method foo {x:required {y 101}} { puts "x=$x y? [info exists y]" } # # Non-positional parameter with default value: # :public method bar {{-x 10} {-y 20}} { puts "x=$x y? [info exists y]" } } # use default values o3 foo o3 bar |
In order to define a default value, the parameter specification must be of the form of a 2 element list, where the second argument is the default value. See for an example in Listing 37.
3.7.4. Value Constraints
NX provides value constraints for all kind of parameters. By specifying value constraints a developer can restrict the permissible values for a parameter and document the expected values in the source code. Value checking in NX is conditional, it can be turned on or off in general or on a per-usage level (more about this later). The same mechanisms can be used not only for input value checking, but as well for return value checking (we will address this point as well later).
Built-in Value Constraints
NX comes with a set of built-in value constraints, which can be
extended on the scripting level. The built-in checkers are either the
native checkers provided directly by the Next Scripting Framework (the
most efficient checkers) or the value checkers provided by Tcl through
string is …
. The built-in checkers have as well the advantage that
they can be used also at any time during bootstrap of an object
system, at a time, when e.g. no objects or methods are defined. The
same checkers are used as well for all C-implemented primitives of NX
and the Next Scripting Framework.
Figure 38 shows the built-in general applicable value checkers available in NX, which can be used for all method and object parameters. In the next step, we show how to use these value-checkers for checking permissible values for method parameters. Then we will show, how to provide more detailed value constraints.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 | nx::Object create o4 { # # Positional parameter with value constraints: # :public method foo {x:integer o:object,optional} { puts "x=$x o? [info exists o]" } # # Non-positional parameter with value constraints: # :public method bar {{-x:integer 10} {-verbose:boolean false}} { puts "x=$x y=$y" } } # The following invocation raises an exception o4 foo a |
Value contraints are specified as parameter options in the parameter
specifications. The parameter specification x:integer
defines x
as
a required positional parmeter which value is constraint to an
integer. The parameter specification o:object,optional
shows how to
combine multiple parameter options. The parameter o
is an optional
positional parameter, its value must be an object (see
Listing 39). Value constraints are
specified exactly the same way for non-positional parameters (see
method bar
in Listing 39).
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 | # # Create classes for Person and Project # nx::Class create Person nx::Class create Project nx::Object create o5 { # # Parameterized value constraints # :public method work { -person:object,type=Person -project:object,type=Project } { # ... } } # # Create a Person and a Project instance # Person create gustaf Project create nx # # Use method with value constraints # o5 work -person gustaf -project nx |
The native checkers object
, class
, metaclass
and baseclass
can
be further specialized with the parameter option type
to restrict
the permissible values to instances of certain classes. We can use for
example the native value constraint object
either for testing
whether an argument is some object (without further constraints, as in
Listing 37, method foo
), or we can
constrain the value further to some type (direct or indirect instance
of a class). This is shown by method work
in
Listing 40 which requires
the parameter -person
to be an instance of class Person
and the
parameter -project
to be an instance of class Project
.
Scripted Value Constraints
The set of predefined value checkers can be extended by application
programs via defining methods following certain conventions. The user
defined value checkers are defined as methods of the class nx::Slot
or of one of its subclasses or instances. We will address such cases
in the next sections. In the following example we define two new
value checkers on class nx::Slot
. The first value checker is called
groupsize
, the second one is called choice
.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 | # # Value checker named "groupsize" # ::nx::Slot method type=groupsize {name value} { if {$value < 1 || $value > 6} { error "Value '$value' of parameter $name is not between 1 and 6" } } # # Value checker named "choice" with extra argument # ::nx::Slot method type=choice {name value arg} { if {$value ni [split $arg |]} { error "Value '$value' of parameter $name not in permissible values $arg" } } # # Create an application class D # using the new value checkers # nx::Class create D { :public method foo {a:groupsize} { # ... } :public method bar {a:choice,arg=red|yellow|green b:choice,arg=good|bad} { # ... } } D create d1 # testing "groupsize" d1 foo 2 d1 foo 10 # testing "choice" d1 bar green good d1 bar pink bad |
In order to define a checker groupsize
a method of the name
type=groupsize
is defined. This method receives two arguments,
name
and value
. The first argument is the name of the parameter
(mostly used for the error message) and the second parameter is
provided value. The value checker simply tests whether the provided
value is between 1 and 3 and raises an exception if this is not the
case (invocation in line 36 in Listing 41).
The checker groupsize
has the permissible values defined in its
method’s body. It is as well possible to define more generic checkers
that can be parameterized. For this parameterization, one can pass an
argument to the checker method (last argument). The checker choice
can be used for restricting the values to a set of predefined
constants. This set is defined in the parameter specification. The
parameter a
of method bar
in Listing 41
is restricted to the values red
, yellow
or green
, and the
parameter b
is restricted to good
or bad
. Note that the syntax
of the permissible values is solely defined by the definition of the
value checker in lines 13 to 17. The invocation in line 39 will be ok,
the invocation in line 40 will raise an exception, since pink
is not
allowed.
If the same checks are used in many places in the program, defining names for the value checker will be the better choice since it improves maintainability. For seldomly used kind of checks, the parameterized value checkers might be more convenient.
3.7.5. Multiplicity
A multiplicity specification has a lower and an upper bound. A lower
bound of 0
means that the value might be empty. A lower bound of 1
means that the parameter needs at least one value. The upper bound
might be 1
or n
(or synonymously *
). While the upper bound of
1
states that at most one value has to be passed, the upper bound of
n
says that multiple values are permitted. Other kinds of
multiplicity are currently not allowed.
The multiplicity is written as parameter option in the parameter
specification in the form lower-bound..upper-bound. If no
multiplicity is defined the default multiplicity is 1..1
, which
means: provide exactly one (atomic) value (this was the case in the
previous examples).
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 | nx::Object create o6 { # # Positional parameter with an possibly empty # single value # :public method foo {x:integer,0..1} { puts "x=$x" } # # Positional parameter with an possibly empty # list of values value # :public method bar {x:integer,0..n} { puts "x=$x" } # # Positional parameter with a non-empty # list of values # :public method baz {x:integer,1..n} { puts "x=$x" } } |
Listing 42 contains three examples for
positional parameters with different multiplicities. Multiplicity is
often combined with value constraints. A parameter specification of
the form x:integer,0..n
means that the parameter x
receives a list
of integers, which might be empty. Note that the value constraints are
applied to every single element of the list.
The parameter specification x:integer,0..1
means that x
might be
an integer or it might be empty. This is one style of specifying that
no explicit value is passed for a certain parameter. Another style is
to use required or optional parameters. NX does not enforce any
particular style for handling unspecified values.
All the examples in Listing 42 are for single positional parameters. Certainly, multiplicity is fully orthogonal with the other parameter features and can be used as well for multiple parameters, non-positional parameter, default values, etc.
4. Advanced Language Features
…
4.1. Objects, Classes and Meta-Classes
…
4.2. Resolution Order and Next-Path
…
4.3. Details on Method and Object Parameters
The parameter specifications are used in NX for the following purposes. They are used for
-
the specification of input arguments of methods and commands, for
-
the specification of return values of methods and commands, and for
-
the specification for the initialization of objects.
We refer to the first two as method parameters and the last one as object parameters. The examples in the previous sections all parameter specification were specifications of method parameters.
The method parameter specify how methods are invoked, how the actual arguments are passed to local variables of the invoked method and what kind of checks should be performed on these.
Syntactically, object parameters and method parameters are the same,
although there are certain differences (e.g. some parameter options
are only applicable for objects parameters, the list of object
parameters is computed dynamically from the class structures, object
parameters are often used in combination with special setter methods,
etc.). Consider the following example, where we define the two
application classes Person
and Student
with a few properties.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 | # # Define a class Person with properties "name" # and "birthday" # nx::Class create Person { :property name:required :property birthday } # # Define a class Student as specialization of Person # with and additional property # nx::Class create Student -superclass Person { :property matnr:required :property {oncampus:boolean true} } # # Create instances using object parameters # for the initialization # Person create p1 -name Bob Student create s1 -name Susan -matnr 4711 # Access property value via accessor method puts "The name of s1 is [s1 name]" |
The class Person
has two properties name
and birthday
, where the
property name
is required, the property birthday
is not. The
class Student
is a subclass of Person
with the additional required
property matnr
and an optional property oncampus
with the
default value true
(see Listing 43). The class diagram below visualizes these
definitions.
In NX, these definitions imply that instances of the class of Person
have the properties name
and birthday
as non-positional object
parameters. Furthermore it implies that instances of Student
will
have the object parameters of Person
augmented with the object
parameters from Student
(namely matnr
and oncampus
). Based on
these object parameters, we can create a Person
named Bob
and a
Student
named Susan
with the matriculation number 4711
(see line
23 and 24 in Listing 43). After the object s1
is created it has the
instance variables name
, matnr
and oncampus
(the latter is
initialized with the default value).
4.3.1. Object Parameters for all NX Objects
The object parameters are not limited to the application defined
properties, also NX provides some predefined definitions. Since
Person
is a subclass of nx::Object
also the object parameters of
nx::Object
are inherited. In the introductory stack example, we used
-mixin
applied to an object to denote per-object mixins (see
Listing 8). Since mixin
is defined as a parameter on nx::Object
it can be used as an object
parameter -mixin
for all objects in NX. To put it in other words,
every object can be configured to have per-object mixins. If we would
remove this definition, this feature would be removed as well.
As shown in the introductory examples, every object can be configured
via a scripted initialization block (the optional scripted block
specified at object creation as last argument; see
Listing 5 or
Listing 12). The
scripted block and its meaning are as well defined by the means of
object parameters. However, this object parameter is positional (last
argument) and optional (it can be omitted). The following listing shows
(simplified) the object parameters of Person p1
and Student s1
.
1 2 3 4 5 6 7 8 | Object parameter for Person p1: -name:required -birthday ... -mixin:mixinreg,alias,1..n -filter:filterreg,alias,1..n _:initcmd,optional Object parameter for Student s1: -matnr:required {-oncampus:boolean true} -name:required -birthday ... -mixin:mixinreg,alias,1..n -filter:filterreg,alias,1..n _:initcmd,optional |
The actual values can be obtained via introspection via Person info
parameter definition
. The object parameter types mixinreg
and
filterreg
are for converting definitions of filters and mixins. The
object parameter type initcmd
says that the content of this variable
will be executed in the context of the object being created (before
the constructor init
is called). More about the object parameter
types later.
4.3.2. Object Parameters for all NX Classes
Since classes are certain kind of objects, classes are parameterized
in the same way as objects. A typical parameter for a class definition
is the relation of the class to its superclass.In our example, we have
specified, that Student
has Person
as superclass via the
non-positional object parameter -superclass
. If no superclass is
specified for a class, the default superclass is
nx::Object
. Therefore nx::Object
is the default value for the
parameter superclass
.
Another frequently used parameter for classes is -mixin
to denote
per-class mixins (see e.g. the introductory Stack example in
Listing 10), which is defined in
the same way.
Since Student
is an instance of the meta-class nx::Class
it
inherits the object parameters from nx::Class
(see class diagram
Figure 44). Therefore, one can
use e.g. -superclass
in the definition of classes.
Since nx::Class
is a subclass of nx::Object
, the meta-class
nx::Class
inherits the parameter definitions from the most general
class nx::Object
. Therefore, every class might as well be configured
with a scripted initialization block the same way as objects can be
configured. We used actually this scripted initialization block in
most examples for defining the methods of the class. The following
listing shows (simplified) the parameters applicable for Class
Student
.
1 2 3 | Object parameter for Class Student: -mixin:mixinreg,alias,1..n -filter:filterreg,alias,1..n ... {-superclass:class,alias,1..n ::nx::Object} ... |
The actual values can be obtained via introspection via nx::Class info
parameter definition
.
4.3.3. User defined Parameter Types
More detailed definition of the object parameter types comes here.
4.3.4. Slot Classes and Slot Objects
In one of the previous sections, we defined scripted (application
defined) checker methods on a class named nx::Slot
. In general NX
offers the possibility to define value checkers not only for all
usages of parameters but as well differently for method parameters or
object parameters
4.3.5. Attribute Slots
Still Missing
-
return value checking
-
switch
-
initcmd …
-
subst rules
-
converter
-
incremental slots
5. Miscellaneous
5.1. Profiling
5.2. Unknown Handlers
NX provides two kinds of unknown handlers:
-
Unknown handlers for methods
-
Unknown handlers for objects and classes
5.2.1. Unknown Handlers for Methods
Object and classes might be equipped
with a method unknown
which is called in cases, where an unknown
method is called. The method unknown receives as first argument the
called method followed by the provided arguments
1 2 3 4 5 6 7 8 9 10 | ::nx::Object create o { :method unknown {called_method args} { puts "Unknown method '$called_method' called" } } # Invoke an unknown method for object o: o foo 1 2 3 # Output will be: "Unknown method 'foo' called" |
Without any provision of an unknown method handler, an error will be raised, when an unknown method is called.
5.2.2. Unknown Handlers for Objects and Classes
The next scripting framework provides in addition to unknown method handlers also a means to dynamically create objects and classes, when these are referenced. This happens e.g. when superclasses, mixins, or parent objects are referenced. This mechanism can be used to implement e.g. lazy loading of these classes. Nsf allows to register multiple unknown handlers, each identified by a key (a unique name, different from the keys of other unknown handlers).
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 | ::nx::Class public object method __unknown {name} { # A very simple unknown handler, showing just how # the mechanism works. puts "***** __unknown called with <$name>" ::nx::Class create $name } # Register an unknown handler as a method of ::nx::Class ::nsf::object::unknown::add nx {::nx::Class __unknown} ::nx::Object create o { # The class M is unknown at this point :mixin add M # The line above has triggered the unknown class handler, # class M is now defined puts [:info mixin classes] # The output will be: # ***** __unknown called with <::M> # ::M } |
The Next Scripting Framework allows to add, query, delete and list unknown handlers.
1 2 3 4 5 | # Interface for unknown handlers: # nsf::object::unknown::add /key/ /handler/ # nsf::object::unknown::get /key/ # nsf::object::unknown::delete /key/ # nsf::object::unknown::keys |
-
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