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Eiffel
Paradigmobject-oriented
Designed byBertrand Meyer
DeveloperBertrand Meyer & Eiffel Software
First appeared1986
Stable release
4.2 / Feb 6, 1998
Typing disciplinestatic typing, strong typing
Major implementations
EiffelStudio, SmartEiffel, Visual Eiffel
Influenced by
Ada, Simula, Z
Influenced
Sather, Ruby, Java, C#

Eiffel is an ISO-standardized object-oriented programming language, based on a conscious design methodology, intended for the production of quality software with a particular emphasis on extendibility, reusability, reliability and programmer productivity.

With roots going back to 1985, Eiffel is a mature language with development environments available from multiple suppliers. Although less well known than some other object-oriented approaches, Eiffel is used by large projects in various industries (finance, aerospace, health care, games and others) as well as for teaching programming in academia.

The language design is closely connected with the method, based on a set of principles: Design by contract, Command-query separation, Uniform access principle, Single choice principle, Open-closed principle, Option-Operand separation and others.

Many concepts initially introduced by Eiffel have later found their way into other languages such as Java and C#, and Eiffel continues to try language design ideas, particularly through the ECMA/ISO standardization process.

Overview

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Key characteristics of the language, explained in more detail below, include:

  • Mechanisms supporting Design by contract (routine pre- and postconditions, class invariants), tightly integrated with the inheritance mechanism and other language constructs.
  • Object-oriented program structure; classes are the basic decomposition unit.
  • Static typing.
  • Support for automatic memory management, typically implemented by garbage collection).
  • Central role of inheritance including multiple inheritance and mechanisms to make it safe (renaming, redefinition, "select", non-conforming inheritance).
  • A uniform type system handling both value and reference semantics, where all types including basic types such as INTEGER are based on classes.
  • Genericity, constrained and unconstrained.
  • "Agents" (objects wrapping computations, closely connected with closures and lambda calculus.
  • "Once" routines (evaluated only the first time around), for object sharing and decentralized initialization.
  • Keyword-based syntax ALGOL/Pascal tradition but separator-free (semicolon is optional); operator syntax available for routines.

Design goals

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The Eiffel language aims to promote clear and elegant programming. Eiffel emphasizes declarative statements over procedural code, and eliminates the need for bookkeeping instructions.

Eiffel shuns coding tricks or coding techniques intended as optimization hints to the compiler. The aim is not only to make the code more readable, but also to allow programmers to concentrate on the important aspects of a program without getting bogged down in implementation details. Eiffel's simplicity is intended to promote simple, extendible, reusable and reliable answers to computing problems. Compilers provide extensive optimization techniques such as automatic inlining which remove part of the burden of optimization from the programmer, with the aim of producing extremely efficient code comparable to e.g. C++.

Design by Contract in Eiffel

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(With this section some code examples start appearing. The use of fonts and color are part of the Eiffel standard style. See "Style rules" below.)

The concepts of Design by Contract are central to Eiffel. The mechanisms are tightly integrated with the language. The basic constructs are:

  • Routine precondition
  • Routine postcondition
  • Class invariant

In addition, the language supports a "Check instruction" (a kind of "assert") and, in the syntax for loops, clauses for a loop invariant and a loop variant.

As defined in the Design by Contract methodology, contracts guide redefinition of features in inheritance. Specifically, in a redefinition:

  • The precondition can only be weakened, to ensure that any call that met the requirements of the original version still meets those of the redefined one. The keyword in that case is no longer require but require else.
  • The postcondition can only be strengthened, to ensure that any result guaranteed by the original version is still provided by the redefined one. The keyword in that case is no longer ensure but ensure then.

Other language mechanisms

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Overall structure

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An Eiffel "system" (or "program") is a collection of classes. The class is the major unit of decomposition.

At the level above classes: there is a notion of "cluster". A cluster is essentially a group of classes, and possibly subclusters since clusters can be nested. But there is no language construct for "cluster"; this is an organizational tool left to the environment. Typically (but again this is not prescribed):

  • Each class will be in a separate file (standard convention: x.e for the file name if the class is called X).
  • Each cluster will be in a directory (folder) containing such class files; subclusters are in subdirectories.

At the level below classes: a class contains features (roughly corresponding to "members" in e.g. C++), a class invariant, and some other properties such as a "notes" section for documentation.

Any system must have a class designated as "root", and one of its creation procedures designated as "root procedure". Executing the system consists of creating an instance of the root class and executing its root procedure. (Of course this generally creates new objects, calls new features etc.)

Features, commands, queries

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The primary characteristic of a class is that it contains a set of features. As a class represents a set of run-time objects (its instances), a feature is an operation on these objects. Operations are of two kinds:

  • Queries, which give information about an instance.
  • Commands, which modify an instance.

This distinction is important to the Eiffel method. In particular:

  • Uniform Access Principle: from the outside, whether a query is an attribute (field in each object) or a function (algorithm) should not make any difference. For example a_vehicle.speed could be an attribute, accessed from the object's representation; or it could be computed by a function that divides distance by time. The notation is the same in both cases, so that it's easy to change representation without affecting the rest of the software.
  • Command-Query Separation Principle: Queries must not modify the instance. This is not a language rule but a methodological principle. So in good Eiffel style one does not find "get" function that change something and return a result; instead there are commands (procedures) to change objects, and queries to obtain information about the object, resulting from preceding changes.

Feature names and no-overloading

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An important property of Eiffel is that a class is fundamentally a mapping from feature names to features. More plainly said this means that one name, within one class, means one thing. This keeps things simple and in particular is what makes the multiple inheritance mechanism possible (see below).

Names can, of course, be reused in different classes, but in a given class if you need another feature you'll have to invent another name. This is really no limitation since the conventional kinds of overloading are, in an object-oriented perspective, applied to different classes. For example if you want to have several versions of "+":

a + b  for a, b: INTEGER
a + b  for a, b: REAL
a + b  for a, b: VECTOR [INTEGER]

then in Eiffel it simply means that the three classes involved each have a feature

plus alias "+" (other: XXX): XXX

where XXX is the given class (INTEGER, REAL, VECTOR [G]). (See "Operator and bracket syntax, assigner commands" below.) All the usual forms of operator overloading are thus supported; in fact the mechanism (unlike in most languages) leaves considerable freedom in making up new operators, as may be needed in scientific and engineering applications. What is not possible is the kind of argument overloading where a given class has both a feature f (x: X) and another f (y: Y) with the same names. Meyer has argued [1] that such overloading is useless, damages readability, and complicates the language mechanism needlessly.

Genericity

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Classes can be generic, to express that they are parameterized by types. Generic parameters appear in square brackets:

class LIST [G] ...

G is known as a "formal generic parameter". (Eiffel reserves "argument" for routines, and uses "parameter" only for generic classes.) With such a declaration G represents within the class an arbitrary type; so a function can return a value of type G, and a routine can take an argument of that type:

item: G do ... end
put (x: G) do ... end

The LIST [INTEGER] and LIST [WORD] are "generic derivations" of this class. Permitted combinations(with n: INTEGER, w: WORD, il: LIST [INTEGER], wl: LIST [WORD]) are

n := il.item
wl.put (w)

INTEGER resp. WORD are the "actual generic parameters" in these generic derivations.

It is also possible to have 'constrained' formal parameters, for which the actual parameter must inherit from a given class, the "constraint". For example in

class HASH_TABLE  [G, KEY -> HASHABLE]

a derivation HASH_TABLE [INTEGER, STRING] is valid only if STRING inherits from HASHABLE (as it it indeed does in typical Eiffel libraries). Within the class, having KEY constrained by HASHABLE means that for x: KEY it is possible to apply to x all the features of HASHABLE, as in x.hash_code.

Inheritance basics

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To inherit from one or more others, a class will include a inherit clause at the beginning:

class C inherit
    A
    B
    ... Rest of class declaration ...

The class may redefine (override) some or all of the inherited features. This must be explicitly announced at the beginning of the class through a redefine subclause of the inheritance clause, as in

class C inherit
   A
   redefine f, g, h end
   B
   redefine u, v end

Multiple and repeated inheritance

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Renaming

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A class that inherits from one or more others gets all its features, by default under their original names. It may, however, change their names through a rename clauses. This is required in the case of multiple inheritance if there are name clashes between inherited features; without renaming, the resulting class would violate the no-overloading principle noted above and hence would be invalid.

Tuples

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Tuples types may be viewed as a simple form of class, providing only attributes and the corresponding "setter" procedure. A typical tuple type reads

TUPLE [name: STRING; weight: REAL; date: DATE]

and could be use to describe a simple notion of birth record if a class is not needed. An instance of such a tuple is simply a sequence of values with the given types, given in brackets, such as

["Brigitte", 3.5, Last_night]

Components of such a tuple can be accessed as if the tuple tags were attributes of a class, for example if t] has been assigned the above tuple then t.weight] has value 3.5.

Thanks to the notion of assigner command (see below), dot notation can also be used to assign components of such a tuple, as in

t.weight := t.weight + 0.5

The tuple tags are optional, so that it is also possible to write a tuple type as TUPLE [STRING, REAL, DATE]. (In some compilers this is the only form of tuple, as tags were introduced with the ECMA standard.)

The precise specification of e.g. TUPLE [A, B, C] is that it describes sequences of at least three elements, the first three being of types A, B, C respectively. As a result TUPLE [A, B, C] conforms to (may be assigned to) TUPLE [A, B], to TUPLE [A] and to TUPLE (without parameters), the topmost tuple type to which all tuple types conform.

Agents

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Eiffel provides an "agent" mechanism to wrap operations into objects. This is useful for iteration, event-driven programming, and other applications for which it is useful to pass operations around the program structure. Agents correspond lambda expressions and to closures; they make it possible to combine the object-oriented paradigm with a significant set of mechanisms available in functional programming languages.

For example, to iterate a certain action over a list, it suffices to write

my_list.do_all (agent my_action)

or, if the action is to be executed only on elements satisfying a certain condition:

my_list.do_all (agent my_action, agent my_condition)

In these examples, my_action and my_condition are routines. Prefixing them with agent yields an object that represents the corresponding routine with all its properties, in particular the ability to be called with the appropriate arguments. So if a represents that object (for example because a is the argument to do_all), the instruction

a.call ([x])

will call the original routine with the argument x, as if we had directly called the original routine: my_action (x). Arguments to call are passed as a tuple, here [x].

It is possible to keep some arguments to an agent open and make others closed. The open arguments are passed as arguments to call: they are provided at the time of agent use. The closed arguments are provided at the time of agent definition. For example, if action2 has two arguments, the iteration

my_list.do_all (agent action2 (?, y))

iterates action2 (x, y) for successive values of x, where the second arguments remained set to y. The question mark ? indicates an open argument; y is a closed argument of the agent. Note that the basic syntax agent f is a short hand for agent f (?, ?, ...) with all arguments open. It is also possible to make the target of an agent open through the notation {T}? where T is the type of the target.

The distinction between open and closed operands (operands = arguments + target) corresponds to the distinction between bound and free variables in lambda calculus. An agent expression such as action2 (?, y) with some operands closed and some open corresponds to a version of the original operation curried on the closed operands.

The agent mechanism has been recently generalized to allow defining an agent without reference to an existing routine (such as my_action, my_condition, action2), through inline agents as in

my_list.do_all
   (agent (x: INTEGER)
      require
         positive: x > 0
      do
         x := x – 1
      ensure
         x = old x – 1
      end
   )

The inline agent passed here can have all the trappings of a normal routine, including precondition, postcondition, rescue clause (not used here), and a full signature. This avoids defining routines when all that's needed is a computation to be wrapped in an agent. This is useful in particular for contracts, as in an invariant clause that expresses that all elements of a list are positive:

my_list.for_all (agent (x: INTEGER): BOOLEAN do Result := (x > 0) end)

The current agent mechanism leaves a possibility of run-time type error (if a routine with n arguments is passed to an agent expecting m arguments with m < n). This can be avoided by a run-time check through the precondition valid_arguments of call. Several proposals for a purely static correction of this problem are available, including a language change proposal by Ribet et al. [2].

Once routines

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A routine can be declared "once" (with the keyword once replacing the more common do) to indicate that it will only be executed on the first call. Subsequent calls have no further effect; in the case of a function, they return the same value as the first, for example a reference to the same object.

"Once" functions serve in particular to provide shared objects; the first call will create the object, subsequent ones will return the reference to that object. The typical scheme is

shared_object: SOME_TYPE
   do
      create Result.make (args) -- This creates the object and returns a reference to it through 'Result'
   end

While the reference remains the same, later calls of the form shared_object.do_something can change the content of the object.

"Once" procedures can take care of initialization: several clients of a certain libraries can include a call to the initialization procedure, but only the first such call to happen will actually have an effect. The goal is to achieve decentralized initialization, avoiding the need for an initialization module (which could damage the modular structure of the program).

The ECMA specification allows variants of "once" (qualified by a keyword in parentheses, e.g. once (THREAD): once per process, once per thread, once per object. This is not, however, fully implemented yet by current compilers (typically, only PROCESS and THREAD).

Conversions

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Eiffel provides a mechanism to allow conversions between various types. The mechanisms coexists with inheritance and complements it. To avoid any confusion between the two mechanisms, the design enforces the following principle:

(Conversion principle) A type may not both conform and convert to another

For example NEWSPAPER may conform to to PUBLICATION, but INTEGER converts to REAL (and does not inherit from it).

The conversion mechanism simply generalizes the ad hoc conversion rules (such as indeed between INTEGERand REAL) that exist in most programming languages, making them applicable to any type as long as the above principle is observed. For example a REAL class may be declared to convert to REAL; this makes it possible to create a string from a date simply through

my_string := my_date

as a shortcut for using an explicit object creation with a conversion procedure:

create my_string.make_from_date (my_date)

To make the first form possible as a synonym for the first, it suffices to list the creation procedure (constructor) make_from_date in a convert clause at the beginning of the class.

As another example, if there is such a conversion procedure listed from TUPLE [day: INTEGER; month: STRING; year: INTEGER]], then one can directly assign a tuple to a date, causing the appropriate conversion, as in

Bastille_day := [14, "July", 1789]

Exception handling

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Exception handling in Eiffel is done at the routine level. If any operation fails in a routine the entire routine is considered as not having satisfied its "contract" and an error is produced. If the routine is not set up to handle the error the failure is propagated up to the routine that called it and the process repeats.

If Eiffel one defines an exception using the rescue keyword which defines a block of text to be executed upon failure. Using the retry keyword in the rescue section (the only section it is allowed to be used in) causes the routine to be executed again after making the changes specified. This allows the programmer to correct mistakes in the input data or to keep track of the number of attempts at executing the routine.

-- Connect to a server or give up after 10 attempts
connect_to_server (server : SOCKET) is
    require
      server . address /= Void
    local
      attempts : INTEGER
    do
      server . connect
    rescue
      if attempts < 10 then
          attempts := attempts + 1
          retry
      end
    end

Operator and bracket syntax, assigner commands

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Eiffel's view of computation is completely object-oriented in the sense that every operation is relative to an object, the "target". So for example an addition

a + b

is conceptually understood as if it were a function call

a.plus (b)

with target a, feature plus and argument b.

Of course [2] is the conventional syntax and usually preferred. Operator syntax makes it possible to use either form by declaring the feature (for example in INTEGER, but this applies to other basic classes and can be used in any other for which such an operator appropriate):

plus alias "+" (other: INTEGER): INTEGER
   ... Normal function declaration...
   end

The range of operators that can be used as "alias" is quite broad; they include predefined operators such as "+" but also "free operators" made of non-alphanumeric symbols. This makes it possible to design special infix and prefix notations, for example in mathematics and physics applications.

Every class may in addition have one function aliased to "[]", the "bracket" operator, allowing the notation a [i, ...] as a synonym for a.f (i, ...) where f is the chosen function. This is particularly useful for container structures such as arrays, hash tables, lists etc. For example access to an element of a hash table with string keys can be written

number := phone_book ["JILL SMITH"]

"Assigner commands" are a companion mechanism designed in the same spirit of allowing well-established, convenient notation reinterpreted in the framework of object-oriented programming. Assigner commands allow assignment-like syntax to call "setter" procedures. An assignment proper can never be of the form a.x := v] as this violates information hiding; you have to go for a setter command (procedure). For example the hash table class can have the function and the procedure

item alias "[]" (key: STRING): ELEMENT
   -- The element of key key
   -- ("Getter" query)
   do
      ...
   end
put(e: ELEMENT; key: STRING): ELEMENT
   -- Insert the element e, associating it with the key key.
   -- ("Setter" command)
   do
      ...
   end

Then to insert an element you have to use an explicit call to the setter command:

phone_book.put (New_person, "JILL SMITH")

It is possible to write this equivalently as

phone_book  ["JILL SMITH"] := New_person

(in the same way that phone_book ["JILL SMITH"] is a synonym for number := phone_book.item ("JILL SMITH")), provided the declaration of item now starts (replacement for [3]) with

item alias "[]" (key: STRING): ELEMENT assign put

This declares put as the assigner command associated with item and, combined with the bracket alias, makes [5] legal and equivalent to [4]. (It could also be written, without taking advantage of the bracket, as phone_book.item ("JILL SMITH") := New_person.

Lexical and syntax properties

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Eiffel is not case-sensitive. The tokens make, maKe and MAKE all denote the same identifier. See, however, the "style rules" below.

Comments are introduced by -- (two consecutive dashes) and extend to the end of the line.

The semicolon, as instruction separator, is optional. Most of the time the semicolon is just omitted, except to separate multiple instructions on a line. This results in less clutter on the program page.

There is no nesting of feature and class declarations. As a result the structure of an Eiffel class is simple: some class-level clauses (inheritance, invariant) and a succession of feature declarations, all at the same level.

It is customary to group features into separate "feature clauses" for more readability, with a standard set of basic feature tags appearing in a standard order, for example:

class HASH_TABLE [ELEMENT, KEY -> HASHABLE] inherit
      TABLE [ELEMENT]
   feature -- Initialization
      ... Declarations of initialization commands (creation procedures/constructors) ...
   feature -- Access
      ... Declarations of non-boolean queries on the object state, e.g. item ...
   feature -- Status report
      ... Declarations of boolean queries on the object state, e.g. is_empty ...
   feature -- Element change
      ... Declarations of commands that change the structure, e.g. put ...
   etc.
end

In contrast to most curly bracket programming languages, Eiffel makes a clear distinction between expressions and instructions. This is in line with the Command-Query Separation principle of the Eiffel method.

Style rules

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Eiffel is distinguished by strong style rules, designed to enforce a consistent look-and-feel.

While the language is case-insensitive, the style standards prescribe the use of all-capitals for class names (LIST), all-lower-case for feature names (make), and initial capitals for constants (Avogadro).

The recommended style also suggests underscore to separate components of a multi-word identifier, as in average_temperature.

The specification of Eiffel includes guidelines for displaying software texts in typeset formats: keywords in bold, user-defined identifiers and constants are shown in italics, comments, operators, and punctuation marks in roman, with program text in blue as in the present article to distinguish it from explanatory text.

Basic instructions

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Eiffel has only six basic executable instructions:

  • assignment
  • object creation
  • routine call
  • conditional
  • iteration
  • choice (case)

Unlike many object-oriented languages, but like Smalltalk, Eiffel does not permit an assignment into fields of other objects, as this violates the principles of information hiding and data abstraction. The assignment instruction can only change the value of a field of the current object, or a local variable of the current routine. All changes to other objects must be accomplished by calls to features of that object.

The loop instruction includes a from clause that takes care of loop initialization. The programmer must express the stepping as part of the loop. For example:

from i := 0 until i >= 10 loop
   my_array.put (0, i)
   i := i + 1
end

The example above also illustrates that Eiffel treats arrays simply as instances of the class ARRAY, providing access in the form of routine calls, in line with object-oriented ideas. Eiffel compilers optimize this access.

Eiffel's control structures closely follow the principles of structured programming; every block is one-entry-one exit.

Interfaces to other tools and languages

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Eiffel is a purely object-oriented language but provides an open architecture for interfacing with "external" software in any other programming language.

It is possible for example to program machine- and operating-system level operations in C. Eiffel provides a straightforward interface to C routines, including support for "inline C" (writing the body of an Eiffel routine in C, typically for short machine-level operations).

Although there is no direct connection between Eiffel and C, all of the current Eiffel compilers except one (Visual Eiffel) output C source code as an intermediate language, to submit to a C compiler, for optimizing and portability. On .NET, the EiffelStudio compiler directly generates CIL (Common Intermediate Language) code for the .NET virtual machine. The SmartEiffel compiler can also output Java bytecode.

Background

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Eiffel was originally developed by Eiffel Software, a company founded by Bertrand Meyer (originally called Interactive Software Engineering Inc. or ISE). Eiffel closely follows Dr. Meyer's work in Object Oriented Software Construction, Second Edition. Eiffel differs from most popular languages in several ways.

The goal of the language, libraries, and programing methods is to create reliable, reusable software modules. It supports multiple inheritance, genericity, polymorphism, encapsulation, type-safe conversions, and parameter covariance. Its most important contribution to software engineering is Design by contract (DbC), in which assertions, preconditions, postconditions, and class invariants are used to assist in assuring program correctness without sacrificing efficiency.

Eiffel also offers multiple class inheritance. Many people (such as the designers of Java) have objections to multiple inheritance. The Eiffel implementation of multiple inheritance, in the opinion of its supporters, successfully meets these objections.

Eiffel's design is closely based on Object-Oriented Programming (OOP) theory, with less influence from other paradigms or support for legacy code. The language has formal support for abstract data types. In accordance with Self Documentation, a software text should be able to reproduce its design documentation from the text itself. Eiffel accomplishes this by using a formalized implementation of the Abstract Data Type.

EiffelStudio, an integrated development environment for Eiffel available under both an open source and a commercial licenses, offers an object-oriented environment for software engineering, using some innovative user-interface techniques such as Pick-And-Drop. There are two alternative, also open source implementations, SmartEiffel - the GNU implementation, based on an older version of the language, and Visual Eiffel, which provides a more "traditional" interface. So does EiffelEnvision, a plugin for Microsoft Visual Studio which allows users to edit, compile, and debug Eiffel apps from within the Microsoft Visual Studio IDE. EiffelStudio and EiffelEnvision are only free for non-commercial use, though.

Originally, the language Sather was based on Eiffel, but it has diverged, and now includes several functional programming features.

Specifications and standards

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The Eiffel language definition is an international standard of ISO, the International Standards Organization. The standard was developed by ECMA International and its first version approved by ECMA on 21 June 2005 as ECMA standard 367, Eiffel: Analysis, Design and Implementation Language. The second edition was adopted by ECMA in June 2006 and in the same month by ISO. Its text can be found, and used free of charge, on the ECMA site[3]. The ISO version, standard ISO/IEC DIS 25436, has different formating but its text is identical.

Eiffel Software and Gobo have committed to implementing the standard; Eiffel Software's EiffelStudio 5.7 implements some of the major new mechanisms, in particular inline agents, assigner commands, bracket notation. The SmartEiffel team has turned away from this standard to create its own version of the language, which they believe to be closer to the original style of Eiffel. Object Tools has not to date expressed a position.

The standard cites the following as earlier Eiffel Language specifications:

  • Bertrand Meyer: Eiffel: The Language, Prentice Hall, second printing, 1992 (first printing: 1991)
  • Bertrand Meyer: Standard Eiffel (revision of preceding entry), ongoing, 1997-present, at Bertrand Meyer's ETL3 page, and
  • Bertrand Meyer: Object-Oriented Software Construction, Prentice Hall: first edition, 1988; second edition, 1997.

The ETL3 page requires a password for access which can be found at Bertrand Meyer's Home Page under Work in progress

Differences between SmartEiffel and other implementations

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  • SmartEiffel is currently unable to compile the open-source EiffelBase library from Eiffel Software.
  • SmartEiffel is case-sensitive.

A "Hello World" class

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class
   HELLO_WORLD
create
   make
feature
   make is
      do
         io.put_string ("Hello, world!")
         io.put_new_line
      end
end

References

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  1. ^ Bertrand Meyer: Overloading vs Object Technology, in Journal of Object-Oriented Programming (JOOP), vol. 14, no. 4, October-November 2001, available online
  2. ^ Philippe Ribet, Cyril Adrian, Olivier Zendra, Dominique Colnet: Conformance of agents in the Eiffel language, in Journal of Object Technology, vol. 3, no. 4, April 2004, Special issue: TOOLS USA 2003, pp. 125-143. Available on line from the JOT article page
  3. ^ ECMA International: Standard ECMA-367 —Eiffel: Analysis, Design and Programming Language 2nd edition (June 2006); available online at www.ecma-international.org/publications/standards/Ecma-367.htm

See also

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