Magik is an object-oriented programming language that supports multiple inheritance and polymorphism, and it is dynamically typed. It was designed and implemented in 1989 by Arthur Chance of Smallworld Systems Ltd. as part of Smallworld Geographical Information System (GIS). Following Smallworld's acquisition in 2000, Magik is now provided by GE Energy, still as part of its Smallworld technology platform.
Magik (Inspirational Magik) was originally introduced in 1990 and has been improved and updated over the years. Its current version is 5.2.
In July 2012, Magik developers announced that they were in the process of porting Magik language on the Java virtual machine. The successful porting was confirmed by Oracle Corporation in November of the same year.[1]
Magik itself shares some similarities with Smalltalk in terms of its language features and its architecture: the Magik language is compiled into byte codes interpreted by the Magik virtual machine. The Magik virtual machine is available on several platforms including Microsoft Windows, various flavours of Unix and Linux.
Magik is console based and code can be modified on the fly even when an application is running. The console can also be used to execute Magik code and to see the results.
Compiled code is stored in a single file called an image file. Each image file holds the compiled byte-codes and the state of the session (for example variable values) when the image was last saved.
Magik uses the #
token to mark sections of code as comments:
# This is a comment.
Magik uses the <<
operator to make assignments:
a << 1.234 b << b + a c << "foo" + "bar" # Concat strings
For clarity, this notation is read as "a becomes 1.234" or "b becomes b plus a". This terminology separates assignment from comparison.
Magik also supports a compressed variation of this operator that works in a similar way to those found in C:
b +<< a # Equivalent to b << b + a
To print a variable you can use the following command
a << "hello" write(a)
As well as conventional data types such as integers, floats and strings Magik also implements symbols. Symbols are a special token data type that are used extensively throughout Magik to uniquely identify objects. They are represented by a colon followed by a string of characters. Symbols can be escaped using the vertical bar character. For example:
a << :hello # whenever :hello is encountered, it is the same instance b << :|hello world|
Magik variables are not typed as they are in say C# and can reference different objects at runtime. Everything in Magik is an object (there is no distinction between objects and primitive types such as integers):
a << 1.2 # a floating point number is assigned to variable 'a' a << "1.2" # later, a string is assigned to variable 'a'
Objects are implemented in Magik using exemplars. Exemplars have similarities to classes in other programming languages such as Java, but with important differences. Magik supports multiple inheritance, and mixins (which implement functionality with no data). New instances are made by cloning an existing instance (which will typically be the exemplar but does not have to be).
New exemplars are created using the statement def_slotted_exemplar()
, for example:
def_slotted_exemplar(:my_object, { {:slot_a, 34}, {:slot_b, "hello"} }, {:parent_object_a, :parent_object_b})
This code fragment will define a new exemplar called my_object
that has two slots (or fields) called slot_a
(pre-initialised to 34) and slot_b
(pre-initialised to "hello") that inherits from two existing exemplars called parent_object_a
and parent_object_b
.
Magik implements all usual logical operators (=
, <
, <=
, >
, >=
, ~=/<>
) for comparison, as well as a few unusual ones. The _is
and _isnt
operators are used for comparing specific instances of objects, or object references rather than values.
For example:
a << "hello" b << "hello" a = b # returns True (_true) because the values of a and b are equal a _is b # returns False (_false) because a is not the same instance as b a << "hello" b << a a = b # returns True (_true) because the values of a and b are equal a _is b # returns True (_true) because b was assigned the specific instance of the same object as a, rather than the value of a.
Methods are defined on exemplars using the statements _method
and _endmethod
:
_method my_object.my_method(a, b) _return a + b _endmethod
It is convention to supply two methods new()
(to create a new instance) and init()
(to initialise an instance).
# New method _method person.new(name, age) _return _clone.init(name, age) _endmethod # Initialise method. _private _method person.init(name, age) # Call the parent implementation. _super.init(name, age) # Initialise the slots. .name << name .age << age _return _self _endmethod
The _clone
creates a physical copy of the person
object. The _super
statement allows objects to invoke an implementation of a method on the parent exemplar. Objects can reference themselves using the _self
statement. An object's slots are accessed and assigned using a dot notation.
Methods that are not part of the public interface of the object can be marked private using the _private
statement. Private methods can only be called by _self
, _super
and _clone
.
Optional arguments can be declared using the _optional
statement. Optional arguments that are not passed are assigned by Magik to the special object _unset
(the equivalent of null). The _gather
statement can be used to declare a list of optional arguments.
_method my_object.my_method(_gather values) _endmethod
In Magik the _while
, _for
, _over
, _loop
and _endloop
statements allow iteration.
_block _local s << 0 _local i << 0 _while i <= 100 _loop s +<< i i +<< 1 _endloop >> s _endblock
Here, the _while is combined with _loop and _endloop.
_method my_object.my_method(_gather values) total << 0.0 _for a _over values.elements() _loop total +<< a _endloop _return total _endmethod m << my_object.new() x << m.my_method(1.0, 2, 3.0, 4) # x = 10.0
Here values.elements() is an iterator which helps to iterate the values.
In Magik generator methods are called iterator methods. New iterator methods can be defined using the _iter
and _loopbody
statements:
_iter _method my_object.even_elements() _for a _over _self.elements() _loop _if a.even? _is _true _then _loopbody(a) _endif _endloop _endmethod
Magik also supports functions called procedures. Procedures are also objects and are declared using the _proc
and _endproc
statements. Procedures are assigned to variables which may then be invoked:
my_procedure << _proc @my_procedure(a, b, c) _return a + b + c _endproc x << my_procedure(1, 2, 3) # x = 6
Magik supports // regular expression syntax:
_if /Hello\,\s(\w)+!/.matches?("Hello, Magik!") _then write("Got a match!") _endif
and to capture groups in Regex:
/sw([0-9]+)-([0-9]+).*/.replace_all("sw65456-324sss", "$1") # "65456" /sw([0-9]+)-([0-9]+).*/.replace_all("sw65456-324sss", "$2") # "324"
Magik supports making HTTP or HTTPS requests via http library, see below examples:
magikhttp << http.new() magikhttp.url("https://www.google.com").get() magikhttp.url("https://www.google.com").post({"User-agent", "Bot"}, "some data")
Because Magik was originally developed in England, methods in the core smallworld libraries are spelled using British English. For example:
Use "initialise", not "initialize".
Like other programming language Magik too has collections. They include the following:
The following is an example of the Hello world program written in Magik:
write("Hello World!")
Original source: https://en.wikipedia.org/wiki/Magik (programming language).
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Categories: [Class-based programming languages] [Dynamically typed programming languages]