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'''Lisp''', created by [[John McCarthy]] in 1958, is the second-oldest high-level [[computer]] [[programming language]].  Only [[FORTRAN]] is older.  Lisp takes its name from "List Processing", since one of its prominently featured [[data structure|data structures]] is the [[linked list]].
{{subpages}}


Lisp derives some of its ideas from [[Alonzo Church]]'s [[lambda calculus]], although the language is ''not'' a literal implementation of that formalism.  Features in the spirit of the [[lambda calculus]] are probably easiest to see in [[Scheme]].
''This article is about the programming language.  For the speech disorder, see [[Lisp (impediment)]].''
 
'''Lisp''', created by [[John McCarthy]] in 1958, is one of the oldest extant, high-level [[computer]] [[programming language|programming languages]], dating from the same era as [[Fortran]] and [[COBOL]].  Lisp takes its name from "List Processing", since one of its prominently featured [[data structure|data structures]] is the [[linked list]].  Lisp is still used, and sometimes taught, in universities, and has had enormous influence on the field of computer programming.  Lisp derives some of its ideas from [[Alonzo Church]]'s [[lambda calculus]], although the language is ''not'' a literal implementation of that formalism.  Features in the spirit of the [[lambda calculus]] are probably easiest to see in [[Scheme]].


At [[John McCarthy|McCarthy]]'s request, the word Lisp now designates the family of languages that has resulted from his original design, and no longer any specific language, dialect, or implementation.  For this reason, the [[American National Standards Institute]] (ANSI) relating to Lisp, X3.226/1994, is a standard for the language [[Common Lisp]], in order that other members of the Lisp language family not be affected.  Likewise, the [[International Organization for Standardization|ISO]] standard, ISO/IEC 13816:1997(E), defines a language named [[ISLISP]].
At [[John McCarthy|McCarthy]]'s request, the word Lisp now designates the family of languages that has resulted from his original design, and no longer any specific language, dialect, or implementation.  For this reason, the [[American National Standards Institute]] (ANSI) relating to Lisp, X3.226/1994, is a standard for the language [[Common Lisp]], in order that other members of the Lisp language family not be affected.  Likewise, the [[International Organization for Standardization|ISO]] standard, ISO/IEC 13816:1997(E), defines a language named [[ISLISP]].


== Hello World ==
== Language properties ==


;;; This is an example of a Common Lisp program
The following list represents a series of powerful software language concepts in which Lisp was really the pioneer.
;;; This defines a function, but does not call it.
 
  ;;; The call from another Lisp program would be: (hello-world)
* [[Garbage collection]]/[[automatic storage management]]
* [[Dynamic typing]]
* [[Object Oriented Programming]] ([[Common Lisp Object System]])
* [[Meta Object Protocol]]
* [[Self-contained compiler]]
* [[Source code as a data structure]]
* [[Closure]]s
 
Others
 
* [[Marco system]]
 
== A Brief Look at Lisp: ''Hello World'' ==
 
:''This section describes the most popular Lisp dialect: Common Lisp. It should be notes that there are other dialects which may invalidate these examples.
 
The [[Hello World]] program is traditionally the first program an aspiring programmer writes when learning a new language. Its function is to write some short text to some output device (often a computer screen). It turns out that Hello World is a rather bad way to introduce someone to the Lisp programming language, since it shows very few of its important features. Computer custom dictates that we write it down, however:
 
  ; This is one of the simplest possible Lisp programs.
; It prints the words "Hello, World!" to standard output.
   
   
  (in-package "CL-USER")
  (print "Hello, World!")
<br />
 
'''Analysis.''' The defining data type of Lisp is the ''linked list''. A list is written between parentheses, with spaces to separate elements. Lisp programs are themselves lists, and this program consists of one list with two elements. The first is the symbol <tt>print</tt> and the second is the text string "Hello World!". Lists which are part of a program commonly start with a function name:
 
(function arg1 arg2 arg3 ...)
 
Note also the difference between a ''symbol'' and a ''string''. Symbols are the labels used internally by Lisp for variables. They are case-insensitive, and may not contain spaces. Strings may contain any character supported by the environment, and are case-sensitive.
 
As you may have guessed, everything from a semicolon to the end of the line is a ''comment''. Comments are ignored by Lisp. Their purpose is to explain to human programmers the function of the code.
 
=== Sidetrack: Evaluation ===
 
If you entered the above program into a Lisp interpreter (go ahead and try!
<ref>There are several Common Lisps available, such as [http://clisp.sourceforge.net/ GNU CLISP].</ref>
) you will probably see two Hello Worlds printed. This is because every Lisp object evaluates to a value! In this case, the print function evaluates to its argument, and the interpreter has been configured to always print the resulting value. Evaluation is recursive, starting at the outermost level and going inwardswards. It works such that:
 
* ''Literals'' such as 1, 7/4, "ape" evaluate to themselves, and
* ''Functions'' provide rules for evaluating their arguments recursively.
 
For instance, the <tt>+</tt> function evaluates to the sum of its arguments. Its arguments are either numbers, in which case we are done since numbers always evaluate to themselves. More commonly, the arguments are other functions which then have to be evaluated and so on. We shall see that this ''recursion'' is one of the most important properties of Lisp.
 
=== A Better Hello World for Lisp ===
 
We proposed earlier that Hello World was not the best way to showcase Lisp to first-time users. We shall now provide a slightly better example, which shows some of the language's distinctive features:
 
; Factorial: calculates the factorial of its argument.
; Recall the definition of the factorial.
; If n is a natural number, we define the factorial of n as:
;
;    n! = n * (n - 1) * (n - 2) * ... * 2 * 1.
;
; And additionally: 0! = 1.
   
   
  (defun hello-world ()
  (defun fact (n)  
   (write-line "Hello, world!"))
   (if (= n 0)
    1
    (* n (fact (- n 1)))))
<br />
 
'''Analysis.''' First, we notice that lists can contain other lists; this program has five levels. We'll go through the lines one at a time.
 
<tt>defun</tt> is a ''macro'' which defines new functions for our use. One of the key ideas in Lisp (as in most programming languages) is to divide your program into several functions. Each function should take arguments and produce a single return value. In Lisp the return value is the last value which was evaluated. This line asks Lisp to associate the symbol <tt>fact</tt> with the function which takes one argument (a number) and evaluates to the factorial of that argument.
 
<tt>if</tt> is a macro which evaluates its first argument and checks if it is true. If it is, <tt>if</tt> evaluates to its second argument. If not, to the third. You can think of it as "if (...) then (...) else (...)". In this case, it checks whether n is equal to 0. Notice that <tt>=</tt> is also a function, namely the function that takes two numbers and checks for ''numerical'' equality.
 
Boolean truth/falsity in Lisp is handled such that the empty list <tt>NIL</tt> is false, and everything else is true. There is also a dedicated <tt>T</tt> value to indicate truth.
 
Now what this function essentially says is "if n = 0, the factorial is 1. Otherwise, the factorial is n times the factorial of (n - 1)". This is the beauty of recursion. If you do not see it yet, imagine what will happen when n gets smaller and smaller. One strength of programs constructed in this fashion is that we need not prove their correctness for every input value. We need only prove that:
 
* It works for the number 0, or for the list of length zero (NIL) and,
* Given that it works for the number k, it will work for the number k + 1. (or lists of those lengths)
 
Naturally, such theoretical proofs do not protect from the possibility that the user will ask for the factorial of a decimal number, or even a text string!


== Popular Myths About Lisp ==
== Popular Myths About Lisp ==


Lisp is sometimes mischaracterized as an "interpreted" language.  In fact, it has been true for several decades that all major Lisps have had compilers.  Some very important and influential research in compiler design has been done in Lisp.  For example, the notion of [[continuation-passing style]] was invented for [[Scheme]].
Lisp is sometimes mischaracterized as an "interpreted" language.  In fact, Lisp compilers have been available for decades.  Some very important and influential research in compiler design has been done in Lisp.  For example, the notion of [[continuation-passing style]] was invented for [[Scheme]].


Lisp is sometimes mischaracterized as a language that only has lists for container types.  In fact, it has been true for several decades that all major Lisps have had arrays, strings, and user-defined structures or classes.
Lisp is sometimes mischaracterized as a language that only has lists for container types.  In fact, for several decades, all major Lisps have had a rich variety of container types, such as [[array]]s, [[string (computer programming)|strings]], [[hash table]]s, and user-defined [[class instance]]s.


== Members of the Lisp Language Family ==
== Members of the Lisp Language Family ==
Line 26: Line 97:
There have been many members of the Lisp language family.  Some of the more prominent Lisps are:
There have been many members of the Lisp language family.  Some of the more prominent Lisps are:
* [[BBN Lisp]]
* [[BBN Lisp]]
* [[Dylan]]
 
* [[Eulisp]]
* [[Eulisp]]
* [[Lisp 1.5]]
* [[Lisp 1.5]]
Line 39: Line 110:
* [[Emacs Lisp]]
* [[Emacs Lisp]]
* [[ISLISP]]
* [[ISLISP]]
Languages which were inspired by Lisp:
* [[Scheme]]
* [[Scheme]]
* [[Dylan]]
* [[Haskell]]


== Significant Applications ==
== Significant Applications ==
* The [[Emacs]] text editor includes a dialect of Lisp as an extension language. Emacs Lisp, as it is called, is very widely used to write extensions or "macros" for this very popular editor.
* The [[Maxima]] computer algebra system is implemented in Common Lisp.


Some of the many historically important applications that have been created in Lisp:
Some of the many historically important applications that have been created in Lisp:
* [[ELIZA]] (emulator/parody of human therapist)
* [[ELIZA]] (emulator/parody of human therapist)
* [[MACSYMA]] (symbolic algebra)
* [[MACSYMA]] (symbolic algebra, a predecessor of Maxima.)
* [[SHRDLU]] (natural language understanding)
* [[SHRDLU]] (natural language understanding)
* [[Lisp Machine]] (Lisp-based hardware and operating systems)
* [[Lisp Machine]] (Lisp-based hardware and operating systems)
Line 53: Line 133:
* [http://www.lispworks.com/documentation/HyperSpec/Front/index.htm Common Lisp HyperSpec]
* [http://www.lispworks.com/documentation/HyperSpec/Front/index.htm Common Lisp HyperSpec]
* [http://www.gnu.org/software/emacs/emacs-lisp-intro/ Programming in Emacs Lisp]
* [http://www.gnu.org/software/emacs/emacs-lisp-intro/ Programming in Emacs Lisp]
* [http://www.islisp.info/ ISLISP Programming Language]
* [http://www.islisp.info/ ISLisp Programming Language]
* [http://www-swiss.ai.mit.edu/projects/scheme/ Scheme Programming Language]
* [http://www-swiss.ai.mit.edu/projects/scheme/ Scheme Programming Language]


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* [[John McCarthy]] [http://www-formal.stanford.edu/jmc/history/lisp/lisp.html ''History of Lisp'']
* [[John McCarthy]] [http://www-formal.stanford.edu/jmc/history/lisp/lisp.html ''History of Lisp'']


[[Category:Computers Workgroup]]
<references />[[Category:Suggestion Bot Tag]]

Latest revision as of 11:01, 12 September 2024

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This editable Main Article is under development and subject to a disclaimer.

This article is about the programming language. For the speech disorder, see Lisp (impediment).

Lisp, created by John McCarthy in 1958, is one of the oldest extant, high-level computer programming languages, dating from the same era as Fortran and COBOL. Lisp takes its name from "List Processing", since one of its prominently featured data structures is the linked list. Lisp is still used, and sometimes taught, in universities, and has had enormous influence on the field of computer programming. Lisp derives some of its ideas from Alonzo Church's lambda calculus, although the language is not a literal implementation of that formalism. Features in the spirit of the lambda calculus are probably easiest to see in Scheme.

At McCarthy's request, the word Lisp now designates the family of languages that has resulted from his original design, and no longer any specific language, dialect, or implementation. For this reason, the American National Standards Institute (ANSI) relating to Lisp, X3.226/1994, is a standard for the language Common Lisp, in order that other members of the Lisp language family not be affected. Likewise, the ISO standard, ISO/IEC 13816:1997(E), defines a language named ISLISP.

Language properties

The following list represents a series of powerful software language concepts in which Lisp was really the pioneer.

Others

A Brief Look at Lisp: Hello World

This section describes the most popular Lisp dialect: Common Lisp. It should be notes that there are other dialects which may invalidate these examples.

The Hello World program is traditionally the first program an aspiring programmer writes when learning a new language. Its function is to write some short text to some output device (often a computer screen). It turns out that Hello World is a rather bad way to introduce someone to the Lisp programming language, since it shows very few of its important features. Computer custom dictates that we write it down, however:

; This is one of the simplest possible Lisp programs. 
; It prints the words "Hello, World!" to standard output.

(print "Hello, World!")


Analysis. The defining data type of Lisp is the linked list. A list is written between parentheses, with spaces to separate elements. Lisp programs are themselves lists, and this program consists of one list with two elements. The first is the symbol print and the second is the text string "Hello World!". Lists which are part of a program commonly start with a function name:

(function arg1 arg2 arg3 ...)

Note also the difference between a symbol and a string. Symbols are the labels used internally by Lisp for variables. They are case-insensitive, and may not contain spaces. Strings may contain any character supported by the environment, and are case-sensitive.

As you may have guessed, everything from a semicolon to the end of the line is a comment. Comments are ignored by Lisp. Their purpose is to explain to human programmers the function of the code.

Sidetrack: Evaluation

If you entered the above program into a Lisp interpreter (go ahead and try! [1] ) you will probably see two Hello Worlds printed. This is because every Lisp object evaluates to a value! In this case, the print function evaluates to its argument, and the interpreter has been configured to always print the resulting value. Evaluation is recursive, starting at the outermost level and going inwardswards. It works such that:

  • Literals such as 1, 7/4, "ape" evaluate to themselves, and
  • Functions provide rules for evaluating their arguments recursively.

For instance, the + function evaluates to the sum of its arguments. Its arguments are either numbers, in which case we are done since numbers always evaluate to themselves. More commonly, the arguments are other functions which then have to be evaluated and so on. We shall see that this recursion is one of the most important properties of Lisp.

A Better Hello World for Lisp

We proposed earlier that Hello World was not the best way to showcase Lisp to first-time users. We shall now provide a slightly better example, which shows some of the language's distinctive features:

; Factorial: calculates the factorial of its argument. 
; Recall the definition of the factorial.
; If n is a natural number, we define the factorial of n as:
;
;     n! = n * (n - 1) * (n - 2) * ... * 2 * 1.
;
; And additionally: 0! = 1.

(defun fact (n) 
  (if (= n 0)
    1
    (* n (fact (- n 1)))))


Analysis. First, we notice that lists can contain other lists; this program has five levels. We'll go through the lines one at a time.

defun is a macro which defines new functions for our use. One of the key ideas in Lisp (as in most programming languages) is to divide your program into several functions. Each function should take arguments and produce a single return value. In Lisp the return value is the last value which was evaluated. This line asks Lisp to associate the symbol fact with the function which takes one argument (a number) and evaluates to the factorial of that argument.

if is a macro which evaluates its first argument and checks if it is true. If it is, if evaluates to its second argument. If not, to the third. You can think of it as "if (...) then (...) else (...)". In this case, it checks whether n is equal to 0. Notice that = is also a function, namely the function that takes two numbers and checks for numerical equality.

Boolean truth/falsity in Lisp is handled such that the empty list NIL is false, and everything else is true. There is also a dedicated T value to indicate truth.

Now what this function essentially says is "if n = 0, the factorial is 1. Otherwise, the factorial is n times the factorial of (n - 1)". This is the beauty of recursion. If you do not see it yet, imagine what will happen when n gets smaller and smaller. One strength of programs constructed in this fashion is that we need not prove their correctness for every input value. We need only prove that:

  • It works for the number 0, or for the list of length zero (NIL) and,
  • Given that it works for the number k, it will work for the number k + 1. (or lists of those lengths)

Naturally, such theoretical proofs do not protect from the possibility that the user will ask for the factorial of a decimal number, or even a text string!

Popular Myths About Lisp

Lisp is sometimes mischaracterized as an "interpreted" language. In fact, Lisp compilers have been available for decades. Some very important and influential research in compiler design has been done in Lisp. For example, the notion of continuation-passing style was invented for Scheme.

Lisp is sometimes mischaracterized as a language that only has lists for container types. In fact, for several decades, all major Lisps have had a rich variety of container types, such as arrays, strings, hash tables, and user-defined class instances.

Members of the Lisp Language Family

There have been many members of the Lisp language family. Some of the more prominent Lisps are:

Lisps in more recent use are:


Languages which were inspired by Lisp:

Significant Applications

  • The Emacs text editor includes a dialect of Lisp as an extension language. Emacs Lisp, as it is called, is very widely used to write extensions or "macros" for this very popular editor.
  • The Maxima computer algebra system is implemented in Common Lisp.

Some of the many historically important applications that have been created in Lisp:

  • ELIZA (emulator/parody of human therapist)
  • MACSYMA (symbolic algebra, a predecessor of Maxima.)
  • SHRDLU (natural language understanding)
  • Lisp Machine (Lisp-based hardware and operating systems)

External Links

References

  1. There are several Common Lisps available, such as GNU CLISP.