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] for a computer program in ]. The gray lines are ] that explain the program to humans. When ] and ], it will give the output "]".]] | ] for a computer program in ]. The gray lines are ] that explain the program to humans. When ] and ], it will give the output "]".]] | ||
A '''programming language''' is a system of notation for writing ]s.<ref name="Aaby 2004">{{cite book |last=Aaby |first=Anthony |url=http://www.emu.edu.tr/aelci/Courses/D-318/D-318-Files/plbook/intro.htm |title=Introduction to Programming Languages |year=2004 |access-date=29 September 2012 |archive-url=https://web.archive.org/web/20121108043216/http://www.emu.edu.tr/aelci/Courses/D-318/D-318-Files/plbook/intro.htm |archive-date=8 November 2012 |url-status=dead}}</ref> | A '''programming language''' is a system of notation for writing ]s.<ref name="Aaby 2004">{{cite book |last=Aaby |first=Anthony |url=http://www.emu.edu.tr/aelci/Courses/D-318/D-318-Files/plbook/intro.htm |title=Introduction to Programming Languages |year=2004 |access-date=29 September 2012 |archive-url=https://web.archive.org/web/20121108043216/http://www.emu.edu.tr/aelci/Courses/D-318/D-318-Files/plbook/intro.htm |archive-date=8 November 2012 |url-status=dead}}</ref> | ||
Programming languages are described in terms of their ] (form) and ] (meaning), usually defined by a ]. Languages usually provide features such as a ], ], and mechanisms for ]. An ] of a programming language is required in order to ] programs, namely an ] or a ]. An interpreter directly executes the source code, while a ] produces an ] program. | Programming languages are described in terms of their ] (form) and ] (meaning), usually defined by a ]. Languages usually provide features such as a ], ], and mechanisms for ]. An ] of a programming language is required in order to ] programs, namely an ] or a ]. An interpreter directly executes the source code, while a ] produces an ] program. | ||
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==Definitions== | ==Definitions== | ||
Programming languages differ from ]s in that natural languages are used for interaction between people, while programming languages are designed to allow humans to communicate instructions to machines.{{Citation needed|date=October 2024}} | |||
There are a variety of criteria that may be considered when defining what constitutes a programming language. | |||
The term '']'' is sometimes used interchangeably with "programming language".<ref>Robert A. Edmunds, The Prentice-Hall standard glossary of computer terminology, Prentice-Hall, 1985, p. 91</ref> However, usage of these terms varies among authors. | |||
===Computer languages vs programming languages=== | |||
The term '']'' is sometimes used interchangeably with programming language.<ref>Robert A. Edmunds, The Prentice-Hall standard glossary of computer terminology, Prentice-Hall, 1985, p. 91</ref> However, the usage of both terms varies among authors, including the exact scope of each. One usage describes programming languages as a subset of computer languages.<ref>Pascal Lando, Anne Lapujade, Gilles Kassel, and Frédéric Fürst, '''' {{webarchive|url=https://web.archive.org/web/20150707093557/http://home.mis.u-picardie.fr/~site-ic/site/IMG/pdf/ICSOFT2007_final.pdf|date=7 July 2015}}, {{webarchive|url=https://web.archive.org/web/20100427063709/http://dblp.uni-trier.de/db/conf/icsoft/icsoft2007-1.html|date=27 April 2010}}, pp. 163–170</ref> Similarly, languages used in computing that have a different goal than expressing computer programs are generically designated computer languages. For instance, markup languages are sometimes referred to as computer languages to emphasize that they are not meant to be used for programming.<ref>S.K. Bajpai, ''Introduction To Computers And C Programming'', New Age International, 2007, {{ISBN|81-224-1379-X}}, p. 346</ref> | |||
In one usage, programming languages are described as a subset of computer languages.<ref>Pascal Lando, Anne Lapujade, Gilles Kassel, and Frédéric Fürst, '''' {{webarchive|url=https://web.archive.org/web/20150707093557/http://home.mis.u-picardie.fr/~site-ic/site/IMG/pdf/ICSOFT2007_final.pdf|date=7 July 2015}}, {{webarchive|url=https://web.archive.org/web/20100427063709/http://dblp.uni-trier.de/db/conf/icsoft/icsoft2007-1.html|date=27 April 2010}}, pp. 163–170</ref> Similarly, the term "computer language" may be used in contrast to the term "programming language" to describe languages used in computing but not considered programming languages{{Citation needed|date=October 2024}} – for example, ].<ref> {{webarchive|url=https://web.archive.org/web/20090906083110/http://www.w3.org/XML/1999/XML-in-10-points.html|date=6 September 2009}} ], 1999, "XML is not a programming language."</ref><ref>{{cite book |last=Powell |first=Thomas |title=HTML & XHTML: the complete reference |publisher=McGraw-Hill |year=2003 |isbn=978-0-07-222942-4 |page=25 |quote=HTML is not a programming language.}}</ref><ref>{{cite book |last1=Dykes |first1=Lucinda |url=https://archive.org/details/html4fordummies00titt_2 |title=XML For Dummies |last2=Tittel |first2=Ed |publisher=Wiley |year=2005 |isbn=978-0-7645-8845-7 |edition=4th |page= |quote=...it's a markup language, not a programming language. |url-access=registration}}</ref> Some authors restrict the term "programming language" to ] languages.<ref name="Aaby 2004" /><ref name=":3">In mathematical terms, this means the programming language is ] {{cite book |last=MacLennan |first=Bruce J. |title=Principles of Programming Languages |publisher=Oxford University Press |year=1987 |isbn=978-0-19-511306-8 |page=1}}</ref> Most practical programming languages are Turing complete,<ref name=":0">{{Cite web |title=Turing Completeness |url=https://www.cs.odu.edu/~zeil/cs390/latest/Public/turing-complete/index.html |url-status=live |archive-url=https://web.archive.org/web/20220816145137/https://cs.odu.edu/~zeil/cs390/latest/Public/turing-complete/index.html |archive-date=16 August 2022 |access-date=2022-10-05 |website=www.cs.odu.edu}}</ref> and as such are equivalent in what programs they can compute. | |||
Another usage regards programming languages as theoretical constructs for programming ]s and computer languages as the subset thereof that runs on physical computers, which have finite hardware resources.<ref>R. Narasimhan, Programming Languages and Computers: A Unified Metatheory, pp. 189—247 in Franz Alt, Morris Rubinoff (eds.) Advances in computers, Volume 8, Academic Press, 1994, {{ISBN|0-12-012108-5}}, p.215: " the model for computer languages differs from that for programming languages in only two respects. In a computer language, there are only finitely many names—or registers—which can assume only finitely many values—or states—and these states are not further distinguished in terms of any other attributes. This may sound like a truism but its implications are far-reaching. For example, it would imply that any model for programming languages, by fixing certain of its parameters or features, should be reducible in a natural way to a model for computer languages."</ref> ] emphasizes that ] languages are just as much programming languages as are the languages intended for execution. He also argues that textual and even graphical input formats that affect the behavior of a computer are programming languages, despite the fact they are commonly not Turing-complete, and remarks that ignorance of programming language concepts is the reason for many flaws in input formats.<ref>John C. Reynolds, "Some thoughts on teaching programming and programming languages", ''] Notices'', Volume 43, Issue 11, November 2008, p.109</ref> | Another usage regards programming languages as theoretical constructs for programming ]s and computer languages as the subset thereof that runs on physical computers, which have finite hardware resources.<ref>R. Narasimhan, Programming Languages and Computers: A Unified Metatheory, pp. 189—247 in Franz Alt, Morris Rubinoff (eds.) Advances in computers, Volume 8, Academic Press, 1994, {{ISBN|0-12-012108-5}}, p.215: " the model for computer languages differs from that for programming languages in only two respects. In a computer language, there are only finitely many names—or registers—which can assume only finitely many values—or states—and these states are not further distinguished in terms of any other attributes. This may sound like a truism but its implications are far-reaching. For example, it would imply that any model for programming languages, by fixing certain of its parameters or features, should be reducible in a natural way to a model for computer languages."</ref> ] emphasizes that ] languages are just as much programming languages as are the languages intended for execution. He also argues that textual and even graphical input formats that affect the behavior of a computer are programming languages, despite the fact they are commonly not Turing-complete, and remarks that ignorance of programming language concepts is the reason for many flaws in input formats.<ref>John C. Reynolds, "Some thoughts on teaching programming and programming languages", ''] Notices'', Volume 43, Issue 11, November 2008, p.109</ref> | ||
===Domain and target=== | |||
In most practical contexts, a programming language involves a computer; consequently, programming languages are usually defined and studied this way.<ref>{{cite book |last=Ben Ari |first=Mordechai |title=Understanding Programming Languages |publisher=John Wiley and Sons |year=1996 |quote=Programs and languages can be defined as purely formal mathematical objects. However, more people are interested in programs than in other mathematical objects such as groups, precisely because it is possible to use the program—the sequence of symbols—to control the execution of a computer. While we highly recommend the study of the theory of programming, this text will generally limit itself to the study of programs as they are executed on a computer.}}</ref> Programming languages differ from ]s in that natural languages are only used for interaction between people, while programming languages also allow humans to communicate instructions to machines. | |||
The domain of the language is also worth consideration. ] like ], ], or ], which define ], are not usually considered programming languages.<ref> {{webarchive|url=https://web.archive.org/web/20090906083110/http://www.w3.org/XML/1999/XML-in-10-points.html|date=6 September 2009}} ], 1999, "XML is not a programming language."</ref><ref>{{cite book |last=Powell |first=Thomas |title=HTML & XHTML: the complete reference |publisher=McGraw-Hill |year=2003 |isbn=978-0-07-222942-4 |page=25 |quote=HTML is not a programming language.}}</ref><ref>{{cite book |last1=Dykes |first1=Lucinda |url=https://archive.org/details/html4fordummies00titt_2 |title=XML For Dummies |last2=Tittel |first2=Ed |publisher=Wiley |year=2005 |isbn=978-0-7645-8845-7 |edition=4th |page= |quote=...it's a markup language, not a programming language. |url-access=registration}}</ref> Programming languages may, however, share the syntax with markup languages if a computational semantics is defined. ], for example, is a Turing complete language entirely using XML syntax.<ref>{{cite web |date=2005-04-20 |title=What kind of language is XSLT? |url=http://www.ibm.com/developerworks/library/x-xslt/ |url-status=live |archive-url=https://web.archive.org/web/20110511192712/http://www.ibm.com/developerworks/library/x-xslt/ |archive-date=11 May 2011 |publisher=IBM.com}}</ref><ref>{{cite web |title=XSLT is a Programming Language |url=http://msdn.microsoft.com/en-us/library/ms767587(VS.85).aspx |url-status=live |archive-url=https://web.archive.org/web/20110203015119/http://msdn.microsoft.com/en-us/library/ms767587(VS.85).aspx |archive-date=3 February 2011 |access-date=3 December 2010 |publisher=Msdn.microsoft.com}}</ref><ref>{{cite book |last=Scott |first=Michael |url=https://archive.org/details/programminglangu00scot_912 |title=Programming Language Pragmatics |publisher=] |year=2006 |isbn=978-0-12-633951-2 |page= |quote=XSLT, though highly specialized to the transformation of XML, is a Turing-complete programming language. |url-access=limited}}</ref> Moreover, ], which is mostly used for structuring documents, also contains a Turing complete subset.<ref name="Oetiker et Al., 2017">{{cite web |last1=Oetiker |first1=Tobias |last2=Partl |first2=Hubert |last3=Hyna |first3=Irene |last4=Schlegl |first4=Elisabeth |date=20 June 2016 |title=The Not So Short Introduction to LATEX 2ε |url=https://tobi.oetiker.ch/lshort/lshort.pdf |url-status=live |archive-url=https://web.archive.org/web/20170314015536/https://tobi.oetiker.ch/lshort/lshort.pdf |archive-date=14 March 2017 |website=tobi.oetiker.ch |pages=1–157 |format=Version 5.06}}</ref><ref>{{cite book |last=Syropoulos |first=Apostolos |url=https://archive.org/details/digitaltypograph00syro_587 |title=Digital typography using LaTeX |author2=Antonis Tsolomitis |author3=Nick Sofroniou |publisher=Springer-Verlag |year=2003 |isbn=978-0-387-95217-8 |page= |quote=TeX is not only an excellent typesetting engine but also a real programming language. |url-access=limited}}</ref> | |||
===Abstractions=== | |||
Programming languages usually contain ] for defining and manipulating ]s or controlling the ]. The practical necessity that a programming language supports adequate abstractions is expressed by the ].<ref>David A. Schmidt, ''The structure of typed programming languages'', MIT Press, 1994, {{ISBN|0-262-19349-3}}, p. 32</ref> This principle is sometimes formulated as a recommendation to the programmer to make proper use of such abstractions.<ref>{{cite book|last=Pierce|first=Benjamin|title=Types and Programming Languages|url=https://archive.org/details/typesprogramming00pier_207|url-access=limited|publisher=MIT Press|year=2002|isbn=978-0-262-16209-8|page=}}</ref> | |||
==History== | ==History== | ||
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Around 1960, the first ]—general purpose computers—were developed, although they could only be operated by professionals and the cost was extreme. The data and instructions were input by ], meaning that no input could be added while the program was running. The languages developed at this time therefore are designed for minimal interaction.{{sfn|Gabbrielli|Martini|2023|pp=523–524}} After the invention of the ], computers in the 1970s became dramatically cheaper.{{sfn|Gabbrielli|Martini|2023|p=527}} New computers also allowed more user interaction, which was supported by newer programming languages.{{sfn|Gabbrielli|Martini|2023|p=528}} | Around 1960, the first ]—general purpose computers—were developed, although they could only be operated by professionals and the cost was extreme. The data and instructions were input by ], meaning that no input could be added while the program was running. The languages developed at this time therefore are designed for minimal interaction.{{sfn|Gabbrielli|Martini|2023|pp=523–524}} After the invention of the ], computers in the 1970s became dramatically cheaper.{{sfn|Gabbrielli|Martini|2023|p=527}} New computers also allowed more user interaction, which was supported by newer programming languages.{{sfn|Gabbrielli|Martini|2023|p=528}} | ||
], implemented in 1958, was the first ] language.<ref>{{Cite web|url=https://twobithistory.org/2018/10/14/lisp.html|title=How Lisp Became God's Own Programming Language|website=twobithistory.org|access-date=10 April 2024|archive-date=10 April 2024|archive-url=https://web.archive.org/web/20240410060444/https://twobithistory.org/2018/10/14/lisp.html|url-status=live}}</ref> Unlike Fortran, it |
], implemented in 1958, was the first ] language.<ref>{{Cite web|url=https://twobithistory.org/2018/10/14/lisp.html|title=How Lisp Became God's Own Programming Language|website=twobithistory.org|access-date=10 April 2024|archive-date=10 April 2024|archive-url=https://web.archive.org/web/20240410060444/https://twobithistory.org/2018/10/14/lisp.html|url-status=live}}</ref> Unlike Fortran, it supported ] and ]s,{{sfn|Sebesta|2012|pp=47–48}} and it also introduced ] on a ] and automatic ].{{sfn|Gabbrielli|Martini|2023|p=526}} For the next decades, Lisp dominated ] applications.{{sfn|Sebesta|2012|p=50}} In 1978, another functional language, ], introduced ] and polymorphic ]s.{{sfn|Gabbrielli|Martini|2023|p=528}}{{sfn|Sebesta|2012|pp=701–703}} | ||
After ] (ALGOrithmic Language) was released in 1958 and 1960,{{sfn|Gabbrielli|Martini|2023|pp=524–525}} it became the standard in computing literature for describing ]s. Although its commercial success was limited, most popular imperative languages—including ], ], ], ], ], and ]—are directly or indirectly descended from ALGOL 60.{{sfn|Sebesta|2012|pp=56–57}}{{sfn|Gabbrielli|Martini|2023|p=524}} Among its innovations adopted by later programming languages included greater portability and the first use of ], ] grammar.{{sfn|Gabbrielli|Martini|2023|p=525}} ], the first language to support ] (including ], ], and ]), also descends from ALGOL and achieved commercial success.{{sfn|Gabbrielli|Martini|2023|pp=526–527}} C, another ALGOL descendant, has sustained popularity into the twenty-first century. C allows access to lower-level machine operations more than other contemporary languages. Its power and efficiency, generated in part with flexible ] operations, comes at the cost of making it more difficult to write correct code.{{sfn|Gabbrielli|Martini|2023|p=528}} | After ] (ALGOrithmic Language) was released in 1958 and 1960,{{sfn|Gabbrielli|Martini|2023|pp=524–525}} it became the standard in computing literature for describing ]s. Although its commercial success was limited, most popular imperative languages—including ], ], ], ], ], and ]—are directly or indirectly descended from ALGOL 60.{{sfn|Sebesta|2012|pp=56–57}}{{sfn|Gabbrielli|Martini|2023|p=524}} Among its innovations adopted by later programming languages included greater portability and the first use of ], ] grammar.{{sfn|Gabbrielli|Martini|2023|p=525}} ], the first language to support ] (including ], ], and ]), also descends from ALGOL and achieved commercial success.{{sfn|Gabbrielli|Martini|2023|pp=526–527}} C, another ALGOL descendant, has sustained popularity into the twenty-first century. C allows access to lower-level machine operations more than other contemporary languages. Its power and efficiency, generated in part with flexible ] operations, comes at the cost of making it more difficult to write correct code.{{sfn|Gabbrielli|Martini|2023|p=528}} | ||
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* an ''atom'' is either a ''number'' or a ''symbol''; | * an ''atom'' is either a ''number'' or a ''symbol''; | ||
* a ''number'' is an unbroken sequence of one or more decimal digits, optionally preceded by a plus or minus sign; | * a ''number'' is an unbroken sequence of one or more decimal digits, optionally preceded by a plus or minus sign; | ||
* a ''symbol'' is a letter followed by zero or more of any characters (excluding whitespace); and | * a ''symbol'' is a letter followed by zero or more of any alphabetical characters (excluding whitespace); and | ||
* a ''list'' is a matched pair of parentheses, with zero or more ''expressions'' inside it. | * a ''list'' is a matched pair of parentheses, with zero or more ''expressions'' inside it. | ||
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====Static semantics==== | ====Static semantics==== | ||
Static semantics defines restrictions on the structure of valid texts that are hard or impossible to express in standard syntactic formalisms.<ref name="Aaby 2004"/>{{Failed verification|date=January 2023|reason=This site says nothing about "static semantics" or any connection between semantics and "structure" or "restrictions".}} For compiled languages, static semantics essentially include those semantic rules that can be checked at compile time. Examples include checking that every ] is declared before it is used (in languages that require such declarations) or that the labels on the arms of a ] are distinct.<ref>Michael Lee Scott, ''Programming language pragmatics'', Edition 2, Morgan Kaufmann, 2006, {{ISBN|0-12-633951-1}}, p. 18–19</ref> Many important restrictions of this type, like checking that identifiers are used in the appropriate context (e.g. not adding an integer to a function name), or that ] calls have the appropriate number and type of arguments, can be enforced by defining them as rules in a ] called a ]. Other forms of ] like ] may also be part of static semantics. Programming languages such as ] and ] have ], a form of data flow analysis, as part of their respective static semantics. | Static semantics defines restrictions on the structure of valid texts that are hard or impossible to express in standard syntactic formalisms.<ref name="Aaby 2004"/>{{Failed verification|date=January 2023|reason=This site says nothing about "static semantics" or any connection between semantics and "structure" or "restrictions".}} For compiled languages, static semantics essentially include those semantic rules that can be checked at compile time. Examples include checking that every ] is declared before it is used (in languages that require such declarations) or that the labels on the arms of a ] are distinct.<ref>Michael Lee Scott, ''Programming language pragmatics'', Edition 2, Morgan Kaufmann, 2006, {{ISBN|0-12-633951-1}}, p. 18–19</ref> Many important restrictions of this type, like checking that identifiers are used in the appropriate context (e.g. not adding an integer to a function name), or that ] calls have the appropriate number and type of arguments, can be enforced by defining them as rules in a ] called a ]. Other forms of ] like ] may also be part of static semantics. Programming languages such as ] and ] have ], a form of data flow analysis, as part of their respective static semantics.<ref name=":1">{{Cite book |last=Winskel |first=Glynn |url=https://books.google.com/books?id=JzUNn6uUxm0C |title=The Formal Semantics of Programming Languages: An Introduction |date=5 February 1993 |publisher=MIT Press |isbn=978-0-262-73103-4 |language=en}}</ref> | ||
====Dynamic semantics==== | ====Dynamic semantics==== | ||
{{Main|Semantics of programming languages}} | {{Main|Semantics of programming languages}} | ||
{{unreferenced|section|date=April 2024}} | {{unreferenced|section|date=April 2024}} | ||
Once data has been specified, the machine must be instructed to perform operations on the data. For example, the semantics may define the ] by which expressions are evaluated to values, or the manner in which ] conditionally execute ]. The ''dynamic semantics'' (also known as ''execution semantics'') of a language defines how and when the various constructs of a language should produce a program behavior. There are many ways of defining execution semantics. Natural language is often used to specify the execution semantics of languages commonly used in practice. A significant amount of academic research goes into ], which allows execution semantics to be specified in a formal manner. Results from this field of research have seen limited application to programming language design and implementation outside academia. | Once data has been specified, the machine must be instructed to perform operations on the data. For example, the semantics may define the ] by which expressions are evaluated to values, or the manner in which ] conditionally execute ]. The ''dynamic semantics'' (also known as ''execution semantics'') of a language defines how and when the various constructs of a language should produce a program behavior. There are many ways of defining execution semantics. Natural language is often used to specify the execution semantics of languages commonly used in practice. A significant amount of academic research goes into ], which allows execution semantics to be specified in a formal manner. Results from this field of research have seen limited application to programming language design and implementation outside academia.<ref name=":1" /> | ||
===Type system=== | ===Type system=== | ||
{{Main|Data type|Type system|Type safety}} | {{Main|Data type|Type system|Type safety}} | ||
A ] is a set of allowable values and operations that can be performed on these values.{{sfn|Sebesta|2012|p=244}} Each programming language's ] defines which data types exist, the type of an ], and how ] and ] function in the language.{{sfn|Sebesta|2012|p=245}} | |||
A type system defines how a programming language classifies values and expressions into ''types'', how it can manipulate those types and how they interact. The goal of a type system is to verify and usually enforce a certain level of correctness in programs written in that language by detecting certain incorrect operations. Any ] type system involves a trade-off: while it rejects many incorrect programs, it can also prohibit some correct, albeit unusual programs. In order to bypass this downside, a number of languages have ''type loopholes'', usually unchecked ] that may be used by the programmer to explicitly allow a normally disallowed operation between different types. In most typed languages, the type system is used only to ] programs, but a number of languages, usually functional ones, ], relieving the programmer from the need to write type annotations. The formal design and study of type systems is known as '']''. | |||
⚫ | According to ], a language is fully typed if the specification of every operation defines types of data to which the operation is applicable.<ref name="typing">{{cite web|url=http://www.acooke.org/comp-lang.html|author=Andrew Cooke|title=Introduction To Computer Languages|access-date=13 July 2012|url-status=live|archive-url=https://web.archive.org/web/20120815140215/http://www.acooke.org/comp-lang.html|archive-date=15 August 2012}}</ref> In contrast, an untyped language, such as most ]s, allows any operation to be performed on any data, generally sequences of bits of various lengths.<ref name="typing"/> In practice, while few languages are fully typed, most offer a degree of typing.<ref name="typing"/> | ||
====Typed versus untyped languages==== | |||
⚫ | |||
Because different types (such as ]s and ]) represent values differently, unexpected results will occur if one type is used when another is expected. ] will flag this error, usually at ] (runtime type checking is more costly).{{sfn|Sebesta|2012|pp=15, 408–409}} With ], ]s can always be detected unless variables are explicitly ] to a different type. ] occurs when languages allow implicit casting—for example, to enable operations between variables of different types without the programmer making an explicit type conversion. The more cases in which this ] is allowed, the fewer type errors can be detected.{{sfn|Sebesta|2012|pp=303–304}} | |||
A special case of typed languages is the ''single-typed'' languages. These are often scripting or markup languages, such as ] or ], and have only one data type{{dubious|date=March 2018}}–—most commonly character strings which are used for both symbolic and numeric data. | |||
====Commonly supported types==== | |||
{{See also|Primitive data type}} | |||
Early programming languages often supported only built-in, numeric types such as the ] (signed and unsigned) and ] (to support operations on ]s that are not integers). Most programming languages support multiple sizes of floats (often called ] and ]) and integers depending on the size and precision required by the programmer. Storing an integer in a type that is too small to represent it leads to ]. The most common way of representing negative numbers with signed types is ], although ] is also used.{{sfn|Sebesta|2012|pp=246–247}} Other common types include ]—which is either true or false—and ]—traditionally one ], sufficient to represent all ] characters.{{sfn|Sebesta|2012|p=249}} | |||
] are a data type whose elements, in many languages, must consist of a single type of fixed length. Other languages define arrays as references to data stored elsewhere and support elements of varying types.{{sfn|Sebesta|2012|p=260}} Depending on the programming language, sequences of multiple characters, called ], may be supported as arrays of characters or their own ].{{sfn|Sebesta|2012|p=250}} Strings may be of fixed or variable length, which enables greater flexibility at the cost of increased storage space and more complexity.{{sfn|Sebesta|2012|p=254}} Other data types that may be supported include ],{{sfn|Sebesta|2012|pp=281–282}} ] accessed via keys,{{sfn|Sebesta|2012|pp=272–273}} ]s in which data is mapped to names in an ordered structure,{{sfn|Sebesta|2012|pp=276–277}} and ]s—similar to records but without names for data fields.{{sfn|Sebesta|2012|p=280}} ]s store memory addresses, typically referencing locations on the ] where other data is stored.{{sfn|Sebesta|2012|pp=289–290}} | |||
In contrast, an ''untyped language'', such as most ]s, allows any operation to be performed on any data, generally sequences of bits of various lengths.<ref name="typing"/> High-level untyped languages include ], ], and some varieties of ]. | |||
The simplest ] is an ] whose values can be mapped onto the set of positive integers.{{sfn|Sebesta|2012|p=255}} Since the mid-1980s, most programming languages also support ], in which the representation of the data and operations are ], who can only access an ].{{sfn|Sebesta|2012|pp=244–245}} The benefits of ] can include increased reliability, reduced complexity, less potential for ], and allowing the underlying ] to be changed without the client needing to alter its code.{{sfn|Sebesta|2012|p=477}} | |||
In practice, while few languages are considered typed from the ] (verifying or rejecting all operations), most modern languages offer a degree of typing.<ref name="typing"/> Many production languages provide means to bypass or subvert the type system, trading type safety for finer control over the program's execution (see ]). | |||
====Static |
====Static and dynamic typing==== | ||
In ], all expressions have their types determined before a program executes, typically at compile-time.<ref name="typing"/> Most widely used, statically typed programming languages require the types of variables to be specified explicitly. In some languages, types are implicit; one form of this is when the compiler can ] types based on context. The downside of ] is the potential for errors to go undetected.{{sfn|Sebesta|2012|p=211}} Complete type inference has traditionally been associated with functional languages such as ] and ].<ref>{{Cite conference |last=Leivant |first=Daniel |date=1983 |title=Polymorphic type inference |conference=ACM SIGACT-SIGPLAN symposium on Principles of programming languages |language=en |location=Austin, Texas |publisher=ACM Press |pages=88–98 |doi=10.1145/567067.567077 |isbn=978-0-89791-090-3|doi-access=free }}</ref> | |||
In '']'', all expressions have their types determined before a program executes, typically at compile-time. For example, 1 and (2+2) are integer expressions; they cannot be passed to a function that expects a string or stored in a variable that is defined to hold dates.<ref name="typing"/> | |||
With dynamic typing, the type is not attached to the variable but only the value encoded in it. A single variable can be reused for a value of a different type. Although this provides more flexibility to the programmer, it is at the cost of lower reliability and less ability for the programming language to check for errors.{{sfn|Sebesta|2012|pp=212–213}} Some languages allow variables of a ] to which any type of value can be assigned, in an exception to their usual static typing rules.{{sfn|Sebesta|2012|pp=284–285}} | |||
Statically-typed languages can be either '']'' or '']''. In the first case, the programmer must explicitly write types at certain textual positions (for example, at variable ]). In the second case, the compiler ''infers'' the types of expressions and declarations based on context. Most mainstream statically-typed languages, such as ], ], and ], are manifestly typed. Complete type inference has traditionally been associated with functional languages such as ] and ].<ref>{{Cite conference |last=Leivant |first=Daniel |date=1983 |title=Polymorphic type inference |conference=ACM SIGACT-SIGPLAN symposium on Principles of programming languages |language=en |location=Austin, Texas |publisher=ACM Press |pages=88–98 |doi=10.1145/567067.567077 |isbn=978-0-89791-090-3|doi-access=free }}</ref> However, many manifestly-typed languages support partial type inference; for example, ], ], and ] all infer types in certain limited cases.<ref>Specifically, instantiations of ] types are inferred for certain expression forms. Type inference in Generic Java—the research language that provided the basis for Java 1.5's bounded ] extensions—is discussed in two informal manuscripts from the Types mailing list: {{webarchive|url=https://web.archive.org/web/20070129073839/http://www.seas.upenn.edu/~sweirich/types/archive/1999-2003/msg00849.html |date=29 January 2007 }} (], 17 December 2001) and {{webarchive|url=https://web.archive.org/web/20070129073849/http://www.seas.upenn.edu/~sweirich/types/archive/1999-2003/msg00921.html |date=29 January 2007 }} (], 15 January 2002). C#'s type system is similar to Java's and uses a similar partial type inference scheme.</ref> Additionally, some programming languages allow for some types to be automatically converted to other types; for example, an int can be used where the program expects a float. | |||
'']'', also called ''latent typing'', determines the type-safety of operations at run time; in other words, types are associated with ''run-time values'' rather than ''textual expressions''.<ref name="typing"/> As with type-inferred languages, dynamically-typed languages do not require the programmer to write explicit type annotations on expressions. Among other things, this may permit a single variable to refer to values of different types at different points in the program execution. However, type ] cannot be automatically detected until a piece of code is actually executed, potentially making ] more difficult. ], ], ], ], ], ], ] and ] are all examples of dynamically-typed languages. | |||
====Weak and strong typing==== | |||
'']'' allows a value of one type to be treated as another, for example treating a ] as a number.<ref name="typing"/> This can occasionally be useful, but it can also allow some kinds of program faults to go undetected at ] and even at ]. | |||
'']'' prevents these program faults. An attempt to perform an operation on the wrong type of value raises an error.<ref name="typing"/> Strongly-typed languages are often termed ''type-safe'' or '']''. | |||
An alternative definition for "weakly typed" refers to languages, such as ], ] and ], which permit a large number of implicit type conversions. In JavaScript, for example, the expression <code>2 * x</code> implicitly converts <code>x</code> to a number, and this conversion succeeds even if <code>x</code> is <code>null</code>, <code>undefined</code>, an <code>Array</code>, or a string of letters. Such implicit conversions are often useful, but they can mask programming errors. ''Strong'' and ''static'' are now generally considered orthogonal concepts, but usage in the literature differs. Some use the term ''strongly typed'' to mean ''strongly, statically typed'', or, even more confusingly, to mean simply ''statically typed''. Thus ] has been called both strongly typed and weakly, statically typed.<ref>{{cite web|url=http://www.schemers.org/Documents/Standards/R5RS/HTML/r5rs-Z-H-4.html|title=Revised Report on the Algorithmic Language Scheme|date=20 February 1998|url-status=live|archive-url=https://web.archive.org/web/20060714212928/http://www.schemers.org/Documents/Standards/R5RS/HTML/r5rs-Z-H-4.html|archive-date=14 July 2006}}</ref><ref>{{cite web|url=http://citeseer.ist.psu.edu/cardelli85understanding.html|title=On Understanding Types, Data Abstraction, and Polymorphism|author=] and ]|work=Manuscript (1985)|url-status=live|archive-url=https://web.archive.org/web/20060619072646/http://citeseer.ist.psu.edu/cardelli85understanding.html|archive-date=19 June 2006}}</ref><ref>Ayouni, M., 2020. Beginning Ring programming (Vol. 978, No. 1, pp. 4842-5832). Apress.</ref> | |||
It may seem odd to some professional programmers that C could be "weakly, statically typed". However, the use of the generic pointer, the '''void*''' pointer, does allow casting pointers to other pointers without needing to do an explicit cast. This is extremely similar to somehow casting an array of bytes to any kind of datatype in C without using an explicit cast, such as <code>(int)</code> or <code>(char)</code>. | |||
===Standard library and run-time system=== | |||
{{Main|Standard library}} | |||
Most programming languages have an associated core ] (sometimes known as the "standard library", especially if it is included as part of the published language standard), which is conventionally made available by all implementations of the language. Core libraries typically include definitions for commonly used algorithms, data structures, and mechanisms for input and output. | |||
The line between a language and its core library differs from language to language. In some cases, the language designers may treat the library as a separate entity from the language. However, a language's core library is often treated as part of the language by its users, and some language specifications even require that this library be made available in all implementations. Indeed, some languages are designed so that the meanings of certain syntactic constructs cannot even be described without referring to the core library. For example, in ], a string literal is defined as an instance of the <code>java.lang.String</code> class; similarly, in ], an ] expression (a "block") constructs an instance of the library's <code>BlockContext</code> class. Conversely, ] contains multiple coherent subsets that suffice to construct the rest of the language as library macros, and so the language designers do not even bother to say which portions of the language must be implemented as language constructs, and which must be implemented as parts of a library. | |||
===Concurrency=== | ===Concurrency=== | ||
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==Design and implementation== | ==Design and implementation== | ||
{{Main|Programming language design and implementation}} | {{Main|Programming language design and implementation}} | ||
One of the most important influences on programming language design has been ]. ], the most commonly used type, were designed to perform well on ], the most common computer architecture.{{sfn|Sebesta|2012|p=18}} In von Neumann architecture, the ] stores both data and instructions, while the ] that performs instructions on data is separate, and data must be piped back and forth to the CPU. The central elements in these languages are variables, ], and ], which is more efficient than ] on these machines.{{sfn|Sebesta|2012|p=19}} | |||
Programming languages share properties with natural languages related to their purpose as vehicles for communication, having a syntactic form separate from its semantics, and showing ''language families'' of related languages branching one from another.<ref name="Fischer">Steven R. Fischer, ''A history of language'', Reaktion Books, 2003, {{ISBN|1-86189-080-X}}, p. 205</ref><ref name="levenez">{{cite web|author=Éric Lévénez|title=Computer Languages History|year=2011|url=http://www.levenez.com/lang/|url-status=live|archive-url=https://web.archive.org/web/20060107162045/http://www.levenez.com/lang/|archive-date=7 January 2006}}</ref> But as artificial constructs, they also differ in fundamental ways from languages that have evolved through usage. A significant difference is that a programming language can be fully described and studied in its entirety since it has a precise and finite definition.<ref>{{cite web|url=http://www.cs.cornell.edu/info/Projects/Nuprl/cs611/fall94notes/cn2/subsection3_1_3.html|author=Jing Huang|title=Artificial Language vs. Natural Language|url-status=live|archive-url=https://web.archive.org/web/20090903084542/http://www.cs.cornell.edu/info/Projects/Nuprl/cs611/fall94notes/cn2/subsection3_1_3.html|archive-date=3 September 2009}}</ref> By contrast, ]s have changing meanings given by their users in different communities. While ] are also artificial languages designed from the ground up with a specific purpose, they lack the precise and complete semantic definition that a programming language has. | |||
Many programming languages have been designed from scratch, altered to meet new needs, and combined with other languages. Many have eventually fallen into disuse. |
Many programming languages have been designed from scratch, altered to meet new needs, and combined with other languages. Many have eventually fallen into disuse.{{cn|date=August 2024}} The birth of programming languages in the 1950s was stimulated by the desire to make a universal programming language suitable for all machines and uses, avoiding the need to write code for different computers.{{sfn|Nofre|Priestley|Alberts|2014|p=55}} By the early 1960s, the idea of a universal language was rejected due to the differing requirements of the variety of purposes for which code was written.{{sfn|Nofre|Priestley|Alberts|2014|p=60}} | ||
* Programs range from tiny scripts written by individual hobbyists to huge systems written by hundreds of ]s. | |||
* Programmers range in expertise from novices who need simplicity above all else to experts who may be comfortable with considerable complexity. | |||
* Programs must balance speed, size, and simplicity on systems ranging from ]s to ]s. | |||
* Programs may be written once and not change for generations, or they may undergo continual modification. | |||
* Programmers may simply differ in their tastes: they may be accustomed to discussing problems and expressing them in a particular language. | |||
===Tradeoffs=== | |||
One common trend in the development of programming languages has been to add more ability to solve problems using a higher level of ]. The earliest programming languages were tied very closely to the underlying hardware of the computer. As new programming languages have developed, features have been added that let programmers express ideas that are more remote from simple translation into underlying hardware instructions. Because programmers are less tied to the complexity of the computer, their programs can do more computing with less effort from the programmer. This lets them write more functionality per time unit.<ref>Frederick P. Brooks, Jr.: ''The Mythical Man-Month'', Addison-Wesley, 1982, pp. 93–94</ref> | |||
Desirable qualities of programming languages include readability, writability, and reliability.{{sfn|Sebesta|2012|p=8}} These features can reduce the cost of training programmers in a language, the amount of time needed to write and maintain programs in the language, the cost of compiling the code, and increase runtime performance.{{sfn|Sebesta|2012|pp=16–17}} | |||
*Although early programming languages often prioritized efficiency over readability, the latter has grown in importance since the 1970s. Having multiple operations to achieve the same result can be detrimental to readability, as is ], so that the same operator can have multiple meanings.{{sfn|Sebesta|2012|pp=8–9}} Another feature important to readability is ], limiting the number of constructs that a programmer has to learn.{{sfn|Sebesta|2012|pp=9–10}} A syntax structure that is easily understood and ]s that are immediately obvious also supports readability.{{sfn|Sebesta|2012|pp=12–13}} | |||
*Writability is the ease of use for writing code to solve the desired problem. Along with the same features essential for readability,{{sfn|Sebesta|2012|p=13}} ]—interfaces that enable hiding details from the client—and ]—enabling more concise programs—additionally help the programmer write code.{{sfn|Sebesta|2012|pp=14–15}} The earliest programming languages were tied very closely to the underlying hardware of the computer, but over time support for abstraction has increased, allowing programmers express ideas that are more remote from simple translation into underlying hardware instructions. Because programmers are less tied to the complexity of the computer, their programs can do more computing with less effort from the programmer.<ref>Frederick P. Brooks, Jr.: ''The Mythical Man-Month'', Addison-Wesley, 1982, pp. 93–94</ref> Most programming languages come with a ] of commonly used functions.<ref>{{cite journal |last1=Busbee |first1=Kenneth Leroy |last2=Braunschweig |first2=Dave |title=Standard Libraries |url=https://press.rebus.community/programmingfundamentals/chapter/standard-libraries/ |website=Programming Fundamentals – A Modular Structured Approach |access-date=27 January 2024 |language=en |date=15 December 2018}}</ref> | |||
*Reliability means that a program performs as specified in a wide range of circumstances.{{sfn|Sebesta|2012|p=15}} ], ], and restricted ] (multiple variable names accessing the same region of memory) all can improve a program's reliability.{{sfn|Sebesta|2012|pp=8, 16}} | |||
Programming language design often involves tradeoffs.{{sfn|Sebesta|2012|pp=18, 23}} For example, features to improve reliability typically come at the cost of performance.{{sfn|Sebesta|2012|p=23}} Increased expressivity due to a large number of operators makes writing code easier but comes at the cost of readability.{{sfn|Sebesta|2012|p=23}} | |||
{{anchor|English-like programming languages}} | {{anchor|English-like programming languages}} | ||
] has been proposed as a way to eliminate the need for a specialized language for programming. However, this goal remains distant and its benefits are open to debate. ] took the position that the use of a formal language is essential to prevent the introduction of meaningless constructs |
] has been proposed as a way to eliminate the need for a specialized language for programming. However, this goal remains distant and its benefits are open to debate. ] took the position that the use of a formal language is essential to prevent the introduction of meaningless constructs.<ref>Dijkstra, Edsger W. {{webarchive|url=https://web.archive.org/web/20080120201526/http://www.cs.utexas.edu/users/EWD/transcriptions/EWD06xx/EWD667.html |date=20 January 2008 }} EWD667.</ref> ] was similarly dismissive of the idea.<ref>{{cite web|last=Perlis|first=Alan|url=http://www-pu.informatik.uni-tuebingen.de/users/klaeren/epigrams.html|title=Epigrams on Programming|work=SIGPLAN Notices Vol. 17, No. 9|date=September 1982|pages=7–13|url-status=live|archive-url=https://web.archive.org/web/19990117034445/http://www-pu.informatik.uni-tuebingen.de/users/klaeren/epigrams.html|archive-date=17 January 1999}}</ref> | ||
A language's designers and users must construct a number of artifacts that govern and enable the practice of programming. The most important of these artifacts are the language ''specification'' and ''implementation''. | |||
===Specification=== | ===Specification=== | ||
{{Main|Programming language specification}} | {{Main|Programming language specification}} | ||
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A programming language specification can take several forms, including the following: | A programming language specification can take several forms, including the following: | ||
* An explicit definition of the syntax, static semantics, and execution semantics of the language. While syntax is commonly specified using a |
* An explicit definition of the syntax, static semantics, and execution semantics of the language. While syntax is commonly specified using a formal grammar, semantic definitions may be written in ] (e.g., as in the ]), or a ] (e.g., as in ]<ref>{{cite book|last=Milner|first=R.|author-link=Robin Milner |author2=] |author3=] |author4=D. MacQueen |title=The Definition of Standard ML (Revised)|publisher=MIT Press|year=1997|isbn=978-0-262-63181-5}}</ref> and ]<ref>{{cite web|first=Richard|last=Kelsey|author2=William Clinger|author3=Jonathan Rees|title=Section 7.2 Formal semantics|work=Revised<sup>5</sup> Report on the Algorithmic Language Scheme|url=http://www.schemers.org/Documents/Standards/R5RS/HTML/r5rs-Z-H-10.html#%_sec_7.2|date=February 1998|url-status=live|archive-url=https://web.archive.org/web/20060706081110/http://www.schemers.org/Documents/Standards/R5RS/HTML/r5rs-Z-H-10.html#%_sec_7.2|archive-date=6 July 2006}}</ref> specifications). | ||
* A description of the behavior of a ] for the language (e.g., the ] and ] specifications). The syntax and semantics of the language have to be inferred from this description, which may be written in natural or formal language. | * A description of the behavior of a ] for the language (e.g., the ] and ] specifications). The syntax and semantics of the language have to be inferred from this description, which may be written in natural or formal language. | ||
* A ], sometimes ] (e.g., ] or ]<ref>] – Programming Language Rexx, X3-274.1996</ref>). The syntax and semantics of the language are explicit in the behavior of the reference implementation. | * A ], sometimes ] (e.g., ] or ]<ref>] – Programming Language Rexx, X3-274.1996</ref>). The syntax and semantics of the language are explicit in the behavior of the reference implementation. | ||
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An implementation of a programming language is the conversion of a program into ] that can be executed by the hardware. The machine code then can be executed with the help of the ].{{sfn|Sebesta|2012|pp=23–24}} The most common form of interpretation in ] is by a ], which translates the source code via an intermediate-level language into machine code, known as an ]. Once the program is compiled, it will run more quickly than with other implementation methods.{{sfn|Sebesta|2012|pp=25–27}} Some compilers are able to provide further ] to reduce memory or computation usage when the executable runs, but increasing compilation time.{{sfn|Sebesta|2012|p=27}} | An implementation of a programming language is the conversion of a program into ] that can be executed by the hardware. The machine code then can be executed with the help of the ].{{sfn|Sebesta|2012|pp=23–24}} The most common form of interpretation in ] is by a ], which translates the source code via an intermediate-level language into machine code, known as an ]. Once the program is compiled, it will run more quickly than with other implementation methods.{{sfn|Sebesta|2012|pp=25–27}} Some compilers are able to provide further ] to reduce memory or computation usage when the executable runs, but increasing compilation time.{{sfn|Sebesta|2012|p=27}} | ||
Another implementation method is to run the program with an ], which translates each line of software into machine code just before it executes. Although it can make debugging easier, the downside of interpretation is that it runs 10 to 100 times slower than a compiled executable.{{sfn|Sebesta|2012|p=28}} Hybrid interpretation methods provide some of the benefits of compilation and some of the benefits of interpretation via partial compilation. One form this takes is ], in which the software is compiled ahead of time into an intermediate language, and then into machine code immediately before execution.{{sfn|Sebesta|2012|pp=29–30}} | Another implementation method is to run the program with an ], which translates each line of software into machine code just before it executes. Although it can make debugging easier, the downside of interpretation is that it runs 10 to 100 times slower than a compiled executable.{{sfn|Sebesta|2012|p=28}} Hybrid interpretation methods provide some of the benefits of compilation and some of the benefits of interpretation via partial compilation. One form this takes is ], in which the software is compiled ahead of time into an intermediate language, and then into machine code immediately before execution.{{sfn|Sebesta|2012|pp=29–30}} | ||
==Proprietary languages== | ==Proprietary languages== | ||
Line 325: | Line 297: | ||
* ]: ''Principles of Programming Languages: Design, Evaluation, and Implementation'', ] 1999. | * ]: ''Principles of Programming Languages: Design, Evaluation, and Implementation'', ] 1999. | ||
* ]: ''Concepts in Programming Languages'', ] 2002. | * ]: ''Concepts in Programming Languages'', ] 2002. | ||
*{{cite journal |last1=Nofre |first1=David |last2=Priestley |first2=Mark |last3=Alberts |first3=Gerard |title=When Technology Became Language: The Origins of the Linguistic Conception of Computer Programming, 1950–1960 |journal=Technology and Culture |date=2014 |volume=55 |issue=1 |pages=40–75 |doi=10.1353/tech.2014.0031 |jstor=24468397 |pmid=24988794 |url=https://www.jstor.org/stable/24468397 |issn=0040-165X}} | |||
* ]: '']'', The MIT Press 2002. | * ]: '']'', The MIT Press 2002. | ||
* ] and ]: ''Programming Languages: Design and Implementation'' (4th ed.), Prentice Hall 2000. | * ] and ]: ''Programming Languages: Design and Implementation'' (4th ed.), Prentice Hall 2000. |
Latest revision as of 22:05, 20 December 2024
Language for communicating instructions to a machine
A programming language is a system of notation for writing computer programs. Programming languages are described in terms of their syntax (form) and semantics (meaning), usually defined by a formal language. Languages usually provide features such as a type system, variables, and mechanisms for error handling. An implementation of a programming language is required in order to execute programs, namely an interpreter or a compiler. An interpreter directly executes the source code, while a compiler produces an executable program.
Computer architecture has strongly influenced the design of programming languages, with the most common type (imperative languages—which implement operations in a specified order) developed to perform well on the popular von Neumann architecture. While early programming languages were closely tied to the hardware, over time they have developed more abstraction to hide implementation details for greater simplicity.
Thousands of programming languages—often classified as imperative, functional, logic, or object-oriented—have been developed for a wide variety of uses. Many aspects of programming language design involve tradeoffs—for example, exception handling simplifies error handling, but at a performance cost. Programming language theory is the subfield of computer science that studies the design, implementation, analysis, characterization, and classification of programming languages.
Definitions
Programming languages differ from natural languages in that natural languages are used for interaction between people, while programming languages are designed to allow humans to communicate instructions to machines.
The term computer language is sometimes used interchangeably with "programming language". However, usage of these terms varies among authors.
In one usage, programming languages are described as a subset of computer languages. Similarly, the term "computer language" may be used in contrast to the term "programming language" to describe languages used in computing but not considered programming languages – for example, markup languages. Some authors restrict the term "programming language" to Turing complete languages. Most practical programming languages are Turing complete, and as such are equivalent in what programs they can compute.
Another usage regards programming languages as theoretical constructs for programming abstract machines and computer languages as the subset thereof that runs on physical computers, which have finite hardware resources. John C. Reynolds emphasizes that formal specification languages are just as much programming languages as are the languages intended for execution. He also argues that textual and even graphical input formats that affect the behavior of a computer are programming languages, despite the fact they are commonly not Turing-complete, and remarks that ignorance of programming language concepts is the reason for many flaws in input formats.
History
Early developments
The first programmable computers were invented at the end of the 1940s, and with them, the first programming languages. The earliest computers were programmed in first-generation programming languages (1GLs), machine language (simple instructions that could be directly executed by the processor). This code was very difficult to debug and was not portable between different computer systems. In order to improve the ease of programming, assembly languages (or second-generation programming languages—2GLs) were invented, diverging from the machine language to make programs easier to understand for humans, although they did not increase portability.
Initially, hardware resources were scarce and expensive, while human resources were cheaper. Therefore, cumbersome languages that were time-consuming to use, but were closer to the hardware for higher efficiency were favored. The introduction of high-level programming languages (third-generation programming languages—3GLs)—revolutionized programming. These languages abstracted away the details of the hardware, instead being designed to express algorithms that could be understood more easily by humans. For example, arithmetic expressions could now be written in symbolic notation and later translated into machine code that the hardware could execute. In 1957, Fortran (FORmula TRANslation) was invented. Often considered the first compiled high-level programming language, Fortran has remained in use into the twenty-first century.
1960s and 1970s
Around 1960, the first mainframes—general purpose computers—were developed, although they could only be operated by professionals and the cost was extreme. The data and instructions were input by punch cards, meaning that no input could be added while the program was running. The languages developed at this time therefore are designed for minimal interaction. After the invention of the microprocessor, computers in the 1970s became dramatically cheaper. New computers also allowed more user interaction, which was supported by newer programming languages.
Lisp, implemented in 1958, was the first functional programming language. Unlike Fortran, it supported recursion and conditional expressions, and it also introduced dynamic memory management on a heap and automatic garbage collection. For the next decades, Lisp dominated artificial intelligence applications. In 1978, another functional language, ML, introduced inferred types and polymorphic parameters.
After ALGOL (ALGOrithmic Language) was released in 1958 and 1960, it became the standard in computing literature for describing algorithms. Although its commercial success was limited, most popular imperative languages—including C, Pascal, Ada, C++, Java, and C#—are directly or indirectly descended from ALGOL 60. Among its innovations adopted by later programming languages included greater portability and the first use of context-free, BNF grammar. Simula, the first language to support object-oriented programming (including subtypes, dynamic dispatch, and inheritance), also descends from ALGOL and achieved commercial success. C, another ALGOL descendant, has sustained popularity into the twenty-first century. C allows access to lower-level machine operations more than other contemporary languages. Its power and efficiency, generated in part with flexible pointer operations, comes at the cost of making it more difficult to write correct code.
Prolog, designed in 1972, was the first logic programming language, communicating with a computer using formal logic notation. With logic programming, the programmer specifies a desired result and allows the interpreter to decide how to achieve it.
1980s to 2000s
During the 1980s, the invention of the personal computer transformed the roles for which programming languages were used. New languages introduced in the 1980s included C++, a superset of C that can compile C programs but also supports classes and inheritance. Ada and other new languages introduced support for concurrency. The Japanese government invested heavily into the so-called fifth-generation languages that added support for concurrency to logic programming constructs, but these languages were outperformed by other concurrency-supporting languages.
Due to the rapid growth of the Internet and the World Wide Web in the 1990s, new programming languages were introduced to support Web pages and networking. Java, based on C++ and designed for increased portability across systems and security, enjoyed large-scale success because these features are essential for many Internet applications. Another development was that of dynamically typed scripting languages—Python, JavaScript, PHP, and Ruby—designed to quickly produce small programs that coordinate existing applications. Due to their integration with HTML, they have also been used for building web pages hosted on servers.
2000s to present
During the 2000s, there was a slowdown in the development of new programming languages that achieved widespread popularity. One innovation was service-oriented programming, designed to exploit distributed systems whose components are connected by a network. Services are similar to objects in object-oriented programming, but run on a separate process. C# and F# cross-pollinated ideas between imperative and functional programming. After 2010, several new languages—Rust, Go, Swift, Zig and Carbon —competed for the performance-critical software for which C had historically been used. Most of the new programming languages uses static typing while a few numbers of new languages use dynamic typing like Ring and Julia.
Some of the new programming languages are classified as visual programming languages like Scratch, LabVIEW and PWCT. Also, some of these languages mix between textual and visual programming usage like Ballerina. Also, this trend lead to developing projects that help in developing new VPLs like Blockly by Google. Many game engines like Unreal and Unity added support for visual scripting too.
Elements
Every programming language includes fundamental elements for describing data and the operations or transformations applied to them, such as adding two numbers or selecting an item from a collection. These elements are governed by syntactic and semantic rules that define their structure and meaning, respectively.
Syntax
Main article: Syntax (programming languages)A programming language's surface form is known as its syntax. Most programming languages are purely textual; they use sequences of text including words, numbers, and punctuation, much like written natural languages. On the other hand, some programming languages are graphical, using visual relationships between symbols to specify a program.
The syntax of a language describes the possible combinations of symbols that form a syntactically correct program. The meaning given to a combination of symbols is handled by semantics (either formal or hard-coded in a reference implementation). Since most languages are textual, this article discusses textual syntax.
The programming language syntax is usually defined using a combination of regular expressions (for lexical structure) and Backus–Naur form (for grammatical structure). Below is a simple grammar, based on Lisp:
expression ::= atom | list atom ::= number | symbol number ::= ?+ symbol ::= .* list ::= '(' expression* ')'
This grammar specifies the following:
- an expression is either an atom or a list;
- an atom is either a number or a symbol;
- a number is an unbroken sequence of one or more decimal digits, optionally preceded by a plus or minus sign;
- a symbol is a letter followed by zero or more of any alphabetical characters (excluding whitespace); and
- a list is a matched pair of parentheses, with zero or more expressions inside it.
The following are examples of well-formed token sequences in this grammar: 12345
, ()
and (a b c232 (1))
.
Not all syntactically correct programs are semantically correct. Many syntactically correct programs are nonetheless ill-formed, per the language's rules; and may (depending on the language specification and the soundness of the implementation) result in an error on translation or execution. In some cases, such programs may exhibit undefined behavior. Even when a program is well-defined within a language, it may still have a meaning that is not intended by the person who wrote it.
Using natural language as an example, it may not be possible to assign a meaning to a grammatically correct sentence or the sentence may be false:
- "Colorless green ideas sleep furiously." is grammatically well-formed but has no generally accepted meaning.
- "John is a married bachelor." is grammatically well-formed but expresses a meaning that cannot be true.
The following C language fragment is syntactically correct, but performs operations that are not semantically defined (the operation *p >> 4
has no meaning for a value having a complex type and p->im
is not defined because the value of p
is the null pointer):
complex *p = NULL; complex abs_p = sqrt(*p >> 4 + p->im);
If the type declaration on the first line were omitted, the program would trigger an error on the undefined variable p
during compilation. However, the program would still be syntactically correct since type declarations provide only semantic information.
The grammar needed to specify a programming language can be classified by its position in the Chomsky hierarchy. The syntax of most programming languages can be specified using a Type-2 grammar, i.e., they are context-free grammars. Some languages, including Perl and Lisp, contain constructs that allow execution during the parsing phase. Languages that have constructs that allow the programmer to alter the behavior of the parser make syntax analysis an undecidable problem, and generally blur the distinction between parsing and execution. In contrast to Lisp's macro system and Perl's BEGIN
blocks, which may contain general computations, C macros are merely string replacements and do not require code execution.
Semantics
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The term semantics refers to the meaning of languages, as opposed to their form (syntax).
Static semantics
Static semantics defines restrictions on the structure of valid texts that are hard or impossible to express in standard syntactic formalisms. For compiled languages, static semantics essentially include those semantic rules that can be checked at compile time. Examples include checking that every identifier is declared before it is used (in languages that require such declarations) or that the labels on the arms of a case statement are distinct. Many important restrictions of this type, like checking that identifiers are used in the appropriate context (e.g. not adding an integer to a function name), or that subroutine calls have the appropriate number and type of arguments, can be enforced by defining them as rules in a logic called a type system. Other forms of static analyses like data flow analysis may also be part of static semantics. Programming languages such as Java and C# have definite assignment analysis, a form of data flow analysis, as part of their respective static semantics.
Dynamic semantics
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Once data has been specified, the machine must be instructed to perform operations on the data. For example, the semantics may define the strategy by which expressions are evaluated to values, or the manner in which control structures conditionally execute statements. The dynamic semantics (also known as execution semantics) of a language defines how and when the various constructs of a language should produce a program behavior. There are many ways of defining execution semantics. Natural language is often used to specify the execution semantics of languages commonly used in practice. A significant amount of academic research goes into formal semantics of programming languages, which allows execution semantics to be specified in a formal manner. Results from this field of research have seen limited application to programming language design and implementation outside academia.
Type system
Main articles: Data type, Type system, and Type safetyA data type is a set of allowable values and operations that can be performed on these values. Each programming language's type system defines which data types exist, the type of an expression, and how type equivalence and type compatibility function in the language.
According to type theory, a language is fully typed if the specification of every operation defines types of data to which the operation is applicable. In contrast, an untyped language, such as most assembly languages, allows any operation to be performed on any data, generally sequences of bits of various lengths. In practice, while few languages are fully typed, most offer a degree of typing.
Because different types (such as integers and floats) represent values differently, unexpected results will occur if one type is used when another is expected. Type checking will flag this error, usually at compile time (runtime type checking is more costly). With strong typing, type errors can always be detected unless variables are explicitly cast to a different type. Weak typing occurs when languages allow implicit casting—for example, to enable operations between variables of different types without the programmer making an explicit type conversion. The more cases in which this type coercion is allowed, the fewer type errors can be detected.
Commonly supported types
See also: Primitive data typeEarly programming languages often supported only built-in, numeric types such as the integer (signed and unsigned) and floating point (to support operations on real numbers that are not integers). Most programming languages support multiple sizes of floats (often called float and double) and integers depending on the size and precision required by the programmer. Storing an integer in a type that is too small to represent it leads to integer overflow. The most common way of representing negative numbers with signed types is twos complement, although ones complement is also used. Other common types include Boolean—which is either true or false—and character—traditionally one byte, sufficient to represent all ASCII characters.
Arrays are a data type whose elements, in many languages, must consist of a single type of fixed length. Other languages define arrays as references to data stored elsewhere and support elements of varying types. Depending on the programming language, sequences of multiple characters, called strings, may be supported as arrays of characters or their own primitive type. Strings may be of fixed or variable length, which enables greater flexibility at the cost of increased storage space and more complexity. Other data types that may be supported include lists, associative (unordered) arrays accessed via keys, records in which data is mapped to names in an ordered structure, and tuples—similar to records but without names for data fields. Pointers store memory addresses, typically referencing locations on the heap where other data is stored.
The simplest user-defined type is an ordinal type whose values can be mapped onto the set of positive integers. Since the mid-1980s, most programming languages also support abstract data types, in which the representation of the data and operations are hidden from the user, who can only access an interface. The benefits of data abstraction can include increased reliability, reduced complexity, less potential for name collision, and allowing the underlying data structure to be changed without the client needing to alter its code.
Static and dynamic typing
In static typing, all expressions have their types determined before a program executes, typically at compile-time. Most widely used, statically typed programming languages require the types of variables to be specified explicitly. In some languages, types are implicit; one form of this is when the compiler can infer types based on context. The downside of implicit typing is the potential for errors to go undetected. Complete type inference has traditionally been associated with functional languages such as Haskell and ML.
With dynamic typing, the type is not attached to the variable but only the value encoded in it. A single variable can be reused for a value of a different type. Although this provides more flexibility to the programmer, it is at the cost of lower reliability and less ability for the programming language to check for errors. Some languages allow variables of a union type to which any type of value can be assigned, in an exception to their usual static typing rules.
Concurrency
See also: Concurrent computingIn computing, multiple instructions can be executed simultaneously. Many programming languages support instruction-level and subprogram-level concurrency. By the twenty-first century, additional processing power on computers was increasingly coming from the use of additional processors, which requires programmers to design software that makes use of multiple processors simultaneously to achieve improved performance. Interpreted languages such as Python and Ruby do not support the concurrent use of multiple processors. Other programming languages do support managing data shared between different threads by controlling the order of execution of key instructions via the use of semaphores, controlling access to shared data via monitor, or enabling message passing between threads.
Exception handling
Main article: Exception handlingMany programming languages include exception handlers, a section of code triggered by runtime errors that can deal with them in two main ways:
- Termination: shutting down and handing over control to the operating system. This option is considered the simplest.
- Resumption: resuming the program near where the exception occurred. This can trigger a repeat of the exception, unless the exception handler is able to modify values to prevent the exception from reoccurring.
Some programming languages support dedicating a block of code to run regardless of whether an exception occurs before the code is reached; this is called finalization.
There is a tradeoff between increased ability to handle exceptions and reduced performance. For example, even though array index errors are common C does not check them for performance reasons. Although programmers can write code to catch user-defined exceptions, this can clutter a program. Standard libraries in some languages, such as C, use their return values to indicate an exception. Some languages and their compilers have the option of turning on and off error handling capability, either temporarily or permanently.
Design and implementation
Main article: Programming language design and implementationOne of the most important influences on programming language design has been computer architecture. Imperative languages, the most commonly used type, were designed to perform well on von Neumann architecture, the most common computer architecture. In von Neumann architecture, the memory stores both data and instructions, while the CPU that performs instructions on data is separate, and data must be piped back and forth to the CPU. The central elements in these languages are variables, assignment, and iteration, which is more efficient than recursion on these machines.
Many programming languages have been designed from scratch, altered to meet new needs, and combined with other languages. Many have eventually fallen into disuse. The birth of programming languages in the 1950s was stimulated by the desire to make a universal programming language suitable for all machines and uses, avoiding the need to write code for different computers. By the early 1960s, the idea of a universal language was rejected due to the differing requirements of the variety of purposes for which code was written.
Tradeoffs
Desirable qualities of programming languages include readability, writability, and reliability. These features can reduce the cost of training programmers in a language, the amount of time needed to write and maintain programs in the language, the cost of compiling the code, and increase runtime performance.
- Although early programming languages often prioritized efficiency over readability, the latter has grown in importance since the 1970s. Having multiple operations to achieve the same result can be detrimental to readability, as is overloading operators, so that the same operator can have multiple meanings. Another feature important to readability is orthogonality, limiting the number of constructs that a programmer has to learn. A syntax structure that is easily understood and special words that are immediately obvious also supports readability.
- Writability is the ease of use for writing code to solve the desired problem. Along with the same features essential for readability, abstraction—interfaces that enable hiding details from the client—and expressivity—enabling more concise programs—additionally help the programmer write code. The earliest programming languages were tied very closely to the underlying hardware of the computer, but over time support for abstraction has increased, allowing programmers express ideas that are more remote from simple translation into underlying hardware instructions. Because programmers are less tied to the complexity of the computer, their programs can do more computing with less effort from the programmer. Most programming languages come with a standard library of commonly used functions.
- Reliability means that a program performs as specified in a wide range of circumstances. Type checking, exception handling, and restricted aliasing (multiple variable names accessing the same region of memory) all can improve a program's reliability.
Programming language design often involves tradeoffs. For example, features to improve reliability typically come at the cost of performance. Increased expressivity due to a large number of operators makes writing code easier but comes at the cost of readability.
Natural-language programming has been proposed as a way to eliminate the need for a specialized language for programming. However, this goal remains distant and its benefits are open to debate. Edsger W. Dijkstra took the position that the use of a formal language is essential to prevent the introduction of meaningless constructs. Alan Perlis was similarly dismissive of the idea.
Specification
Main article: Programming language specificationThe specification of a programming language is an artifact that the language users and the implementors can use to agree upon whether a piece of source code is a valid program in that language, and if so what its behavior shall be.
A programming language specification can take several forms, including the following:
- An explicit definition of the syntax, static semantics, and execution semantics of the language. While syntax is commonly specified using a formal grammar, semantic definitions may be written in natural language (e.g., as in the C language), or a formal semantics (e.g., as in Standard ML and Scheme specifications).
- A description of the behavior of a translator for the language (e.g., the C++ and Fortran specifications). The syntax and semantics of the language have to be inferred from this description, which may be written in natural or formal language.
- A reference or model implementation, sometimes written in the language being specified (e.g., Prolog or ANSI REXX). The syntax and semantics of the language are explicit in the behavior of the reference implementation.
Implementation
Main article: Programming language implementationAn implementation of a programming language is the conversion of a program into machine code that can be executed by the hardware. The machine code then can be executed with the help of the operating system. The most common form of interpretation in production code is by a compiler, which translates the source code via an intermediate-level language into machine code, known as an executable. Once the program is compiled, it will run more quickly than with other implementation methods. Some compilers are able to provide further optimization to reduce memory or computation usage when the executable runs, but increasing compilation time.
Another implementation method is to run the program with an interpreter, which translates each line of software into machine code just before it executes. Although it can make debugging easier, the downside of interpretation is that it runs 10 to 100 times slower than a compiled executable. Hybrid interpretation methods provide some of the benefits of compilation and some of the benefits of interpretation via partial compilation. One form this takes is just-in-time compilation, in which the software is compiled ahead of time into an intermediate language, and then into machine code immediately before execution.
Proprietary languages
Although most of the most commonly used programming languages have fully open specifications and implementations, many programming languages exist only as proprietary programming languages with the implementation available only from a single vendor, which may claim that such a proprietary language is their intellectual property. Proprietary programming languages are commonly domain-specific languages or internal scripting languages for a single product; some proprietary languages are used only internally within a vendor, while others are available to external users.
Some programming languages exist on the border between proprietary and open; for example, Oracle Corporation asserts proprietary rights to some aspects of the Java programming language, and Microsoft's C# programming language, which has open implementations of most parts of the system, also has Common Language Runtime (CLR) as a closed environment.
Many proprietary languages are widely used, in spite of their proprietary nature; examples include MATLAB, VBScript, and Wolfram Language. Some languages may make the transition from closed to open; for example, Erlang was originally Ericsson's internal programming language.
Open source programming languages are particularly helpful for open science applications, enhancing the capacity for replication and code sharing.
Use
Thousands of different programming languages have been created, mainly in the computing field. Individual software projects commonly use five programming languages or more.
Programming languages differ from most other forms of human expression in that they require a greater degree of precision and completeness. When using a natural language to communicate with other people, human authors and speakers can be ambiguous and make small errors, and still expect their intent to be understood. However, figuratively speaking, computers "do exactly what they are told to do", and cannot "understand" what code the programmer intended to write. The combination of the language definition, a program, and the program's inputs must fully specify the external behavior that occurs when the program is executed, within the domain of control of that program. On the other hand, ideas about an algorithm can be communicated to humans without the precision required for execution by using pseudocode, which interleaves natural language with code written in a programming language.
A programming language provides a structured mechanism for defining pieces of data, and the operations or transformations that may be carried out automatically on that data. A programmer uses the abstractions present in the language to represent the concepts involved in a computation. These concepts are represented as a collection of the simplest elements available (called primitives). Programming is the process by which programmers combine these primitives to compose new programs, or adapt existing ones to new uses or a changing environment.
Programs for a computer might be executed in a batch process without human interaction, or a user might type commands in an interactive session of an interpreter. In this case the "commands" are simply programs, whose execution is chained together. When a language can run its commands through an interpreter (such as a Unix shell or other command-line interface), without compiling, it is called a scripting language.
Measuring language usage
Determining which is the most widely used programming language is difficult since the definition of usage varies by context. One language may occupy the greater number of programmer hours, a different one has more lines of code, and a third may consume the most CPU time. Some languages are very popular for particular kinds of applications. For example, COBOL is still strong in the corporate data center, often on large mainframes; Fortran in scientific and engineering applications; Ada in aerospace, transportation, military, real-time, and embedded applications; and C in embedded applications and operating systems. Other languages are regularly used to write many different kinds of applications.
Various methods of measuring language popularity, each subject to a different bias over what is measured, have been proposed:
- counting the number of job advertisements that mention the language
- the number of books sold that teach or describe the language
- estimates of the number of existing lines of code written in the language – which may underestimate languages not often found in public searches
- counts of language references (i.e., to the name of the language) found using a web search engine.
Combining and averaging information from various internet sites, stackify.com reported the ten most popular programming languages (in descending order by overall popularity): Java, C, C++, Python, C#, JavaScript, VB .NET, R, PHP, and MATLAB.
As of June 2024, the top five programming languages as measured by TIOBE index are Python, C++, C, Java and C#. TIOBE provide a list of top 100 programming languages according to popularity and update this list every month.
Dialects, flavors and implementations
A dialect of a programming language or a data exchange language is a (relatively small) variation or extension of the language that does not change its intrinsic nature. With languages such as Scheme and Forth, standards may be considered insufficient, inadequate, or illegitimate by implementors, so often they will deviate from the standard, making a new dialect. In other cases, a dialect is created for use in a domain-specific language, often a subset. In the Lisp world, most languages that use basic S-expression syntax and Lisp-like semantics are considered Lisp dialects, although they vary wildly as do, say, Racket and Clojure. As it is common for one language to have several dialects, it can become quite difficult for an inexperienced programmer to find the right documentation. The BASIC language has many dialects.
Classifications
Further information: Categorical list of programming languagesProgramming languages are often placed into four main categories: imperative, functional, logic, and object oriented.
- Imperative languages are designed to implement an algorithm in a specified order; they include visual programming languages such as .NET for generating graphical user interfaces. Scripting languages, which are partly or fully interpreted rather than compiled, are sometimes considered a separate category but meet the definition of imperative languages.
- Functional programming languages work by successively applying functions to the given parameters. Although appreciated by many researchers for their simplicity and elegance, problems with efficiency have prevented them from being widely adopted.
- Logic languages are designed so that the software, rather than the programmer, decides what order in which the instructions are executed.
- Object-oriented programming—whose characteristic features are data abstraction, inheritance, and dynamic dispatch—is supported by most popular imperative languages and some functional languages.
Although markup languages are not programming languages, some have extensions that support limited programming. Additionally, there are special-purpose languages that are not easily compared to other programming languages.
See also
- Comparison of programming languages (basic instructions)
- Comparison of programming languages
- Computer programming
- Computer science and Outline of computer science
- Domain-specific language
- Domain-specific modeling
- Educational programming language
- Esoteric programming language
- Extensible programming
- Category:Extensible syntax programming languages
- Invariant-based programming
- List of BASIC dialects
- Lists of programming languages
- List of programming language researchers
- Programming languages used in most popular websites
- Language-oriented programming
- Logic programming
- Literate programming
- Metaprogramming
- Modeling language
- Programming language theory
- Pseudocode
- Rebol § Dialects
- Reflective programming
- Scientific programming language
- Scripting language
- Software engineering and List of software engineering topics
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- Mayer, Philip; Bauer, Alexander (2015). "An empirical analysis of the utilization of multiple programming languages in open source projects". Proceedings of the 19th International Conference on Evaluation and Assessment in Software Engineering. Proceedings of the 19th International Conference on Evaluation and Assessment in Software Engineering – EASE '15. New York, NY, US: ACM. pp. 4:1–4:10. doi:10.1145/2745802.2745805. ISBN 978-1-4503-3350-4.
Results: We found (a) a mean number of 5 languages per project with a clearly dominant main general-purpose language and 5 often-used DSL types, (b) a significant influence of the size, number of commits, and the main language on the number of languages as well as no significant influence of age and number of contributors, and (c) three language ecosystems grouped around XML, Shell/Make, and HTML/CSS. Conclusions: Multi-language programming seems to be common in open-source projects and is a factor that must be dealt with in tooling and when assessing the development and maintenance of such software systems.
- Abelson, Sussman, and Sussman. "Structure and Interpretation of Computer Programs". Archived from the original on 26 February 2009. Retrieved 3 March 2009.
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- Sebesta 2012, p. 21.
- ^ Sebesta 2012, pp. 21–22.
- Sebesta 2012, p. 12.
- Sebesta 2012, p. 22.
- Sebesta 2012, pp. 22–23.
Further reading
See also: History of programming languages § Further reading- Abelson, Harold; Sussman, Gerald Jay (1996). Structure and Interpretation of Computer Programs (2nd ed.). MIT Press. Archived from the original on 9 March 2018.
- Raphael Finkel: Advanced Programming Language Design, Addison Wesley 1995.
- Daniel P. Friedman, Mitchell Wand, Christopher T. Haynes: Essentials of Programming Languages, The MIT Press 2001.
- David Gelernter, Suresh Jagannathan: Programming Linguistics, The MIT Press 1990.
- Ellis Horowitz (ed.): Programming Languages, a Grand Tour (3rd ed.), 1987.
- Ellis Horowitz: Fundamentals of Programming Languages, 1989.
- Shriram Krishnamurthi: Programming Languages: Application and Interpretation, online publication Archived 30 April 2021 at the Wayback Machine.
- Gabbrielli, Maurizio; Martini, Simone (2023). Programming Languages: Principles and Paradigms (2nd ed.). Springer. ISBN 978-3-031-34144-1.
- Bruce J. MacLennan: Principles of Programming Languages: Design, Evaluation, and Implementation, Oxford University Press 1999.
- John C. Mitchell: Concepts in Programming Languages, Cambridge University Press 2002.
- Nofre, David; Priestley, Mark; Alberts, Gerard (2014). "When Technology Became Language: The Origins of the Linguistic Conception of Computer Programming, 1950–1960". Technology and Culture. 55 (1): 40–75. doi:10.1353/tech.2014.0031. ISSN 0040-165X. JSTOR 24468397. PMID 24988794.
- Benjamin C. Pierce: Types and Programming Languages, The MIT Press 2002.
- Terrence W. Pratt and Marvin Victor Zelkowitz: Programming Languages: Design and Implementation (4th ed.), Prentice Hall 2000.
- Peter H. Salus. Handbook of Programming Languages (4 vols.). Macmillan 1998.
- Ravi Sethi: Programming Languages: Concepts and Constructs, 2nd ed., Addison-Wesley 1996.
- Michael L. Scott: Programming Language Pragmatics, Morgan Kaufmann Publishers 2005.
- Sebesta, Robert W. (2012). Concepts of Programming Languages (10 ed.). Addison-Wesley. ISBN 978-0-13-139531-2.
- Franklyn Turbak and David Gifford with Mark Sheldon: Design Concepts in Programming Languages, The MIT Press 2009.
- Peter Van Roy and Seif Haridi. Concepts, Techniques, and Models of Computer Programming, The MIT Press 2004.
- David A. Watt. Programming Language Concepts and Paradigms. Prentice Hall 1990.
- David A. Watt and Muffy Thomas. Programming Language Syntax and Semantics. Prentice Hall 1991.
- David A. Watt. Programming Language Processors. Prentice Hall 1993.
- David A. Watt. Programming Language Design Concepts. John Wiley & Sons 2004.
- Wilson, Leslie B. (2001). Comparative Programming Languages, Third Edition. Addison-Wesley. ISBN 0-201-71012-9.
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