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[[Image:Lambda_cube.png|frame|The lambda cube. Direction of each arrow is direction of inclusion. ]]
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In [[mathematical logic]] and [[type theory]], the '''λ-cube''' is a framework for exploring the axes of refinement in [[Thierry Coquand|Coquand]]'s [[calculus of constructions]], starting from the [[simply typed lambda calculus]] (written as <math>\lambda\rightarrow</math> in the cube diagram to the right) as the vertex of a cube placed at the origin, and the calculus of constructions (higher order dependently-typed polymorphic lambda calculus; written as λPω in the diagram) as its diametrically opposite vertex.  Each axis of the cube represents a new form of abstraction:
* Terms depending on types, or [[Polymorphism (computer science)|polymorphism]]. [[System F]], aka second order lambda calculus (written as λ2 in the diagram), is obtained by imposing only this property.
* Types depending on types, or [[type operator]]s. [[Simply typed lambda-calculus with type operators]], λ<sub>ω</sub> (the diagram underlines the ω), is obtained by imposing only this property. Combined with [[System F]] it yields [[System F#System Fω|System F<sub>ω</sub>]] (written as λω without the underline in the diagram).
* Types depending on terms, or [[Dependent type theory|dependent types]]. Imposing only this property yields λΠ (written as λP in the diagram), a type system closely related to [[LF (logical framework)|LF]].


All eight calculi include the most basic form of abstraction, terms depending on terms, ordinary functions as in the simply-typed lambda calculus. The richest calculus in the cube, with all three abstractions, is the [[calculus of constructions]]. All eight calculi are [[Normalization property (lambda-calculus) |strongly normalizing]].


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[[Subtyping]] however is not represented in the cube, even though systems like <math>F^\omega_{<:}</math>, known as [[higher-order bounded quantification]], which combines subtyping and polymorphism are of practical interest, and can be further generalized to [[bounded type operator]]s. Further extensions to <math>F^\omega_{<:}</math> allow the definition of [[purely functional objects]]; these systems were generally developed after the lambda cube paper was published.<ref>Pierce, 2002, chapters 31 and 32</ref>
 
The idea of the cube is due to the mathematician [[Henk Barendregt]] (1991). The framework of [[pure type system]]s generalizes the lambda cube in the sense that all corners of the cube, as well as many other systems can be represented as instances of this general framework.<ref>Pierce, 2002, p. 466</ref> This framework predates lambda cube a couple of years. In his 1991 paper, Barendregt also defines the corners of the cube in this framework.
 
==See also==
 
* Some of the systems included in the cube were first defined in [[Automath]].
 
== Notes ==
{{reflist}}
 
==References==
{{refbegin}}
* Morten Heine Sørensen, Paweł Urzyczyn, ''Lectures on the Curry-Howard isomorphism'', Elsevier, 2006, ISBN 0-444-52077-5, chapter 14, "Pure type systems and the lambda cube"<!-- this covers pretty much everything in this article, except the subtyping stuff, which is only discussed by Pierce -->
* [[H.P. Barendregt]], [http://dare.ubn.kun.nl/bitstream/2066/17240/1/13256.pdf Introduction to generalized type systems], ''Journal of Functional Programming'', 1(2):125-154, April 1991.
* {{cite book|last=Pierce|first=Benjamin|title=Types and Programming Languages|publisher=MIT Press|date=2002|id=ISBN 0-262-16209-1}}
{{refend}}
 
==Further reading==
* Simon Peyton Jones and Erik Meijer, 1997. [http://citeseer.ist.psu.edu/peytonjones97henk.html ''Henk: A Typed Intermediate Language'']<!-- Not clear why this is given as ref since it's never mentioned in the article, but the article could mention it-->
 
== External links ==
* [http://www.rbjones.com/rbjpub/logic/cl/tlc001.htm Barendregt's Lambda Cube] in the context of [[pure type systems]] by Roger Bishop Jones
 
[[Category:Lambda calculus]]
[[Category:Type theory]]

Revision as of 22:36, 7 January 2014

The lambda cube. Direction of each arrow is direction of inclusion.

In mathematical logic and type theory, the λ-cube is a framework for exploring the axes of refinement in Coquand's calculus of constructions, starting from the simply typed lambda calculus (written as λ in the cube diagram to the right) as the vertex of a cube placed at the origin, and the calculus of constructions (higher order dependently-typed polymorphic lambda calculus; written as λPω in the diagram) as its diametrically opposite vertex. Each axis of the cube represents a new form of abstraction:

  • Terms depending on types, or polymorphism. System F, aka second order lambda calculus (written as λ2 in the diagram), is obtained by imposing only this property.
  • Types depending on types, or type operators. Simply typed lambda-calculus with type operators, λω (the diagram underlines the ω), is obtained by imposing only this property. Combined with System F it yields System Fω (written as λω without the underline in the diagram).
  • Types depending on terms, or dependent types. Imposing only this property yields λΠ (written as λP in the diagram), a type system closely related to LF.

All eight calculi include the most basic form of abstraction, terms depending on terms, ordinary functions as in the simply-typed lambda calculus. The richest calculus in the cube, with all three abstractions, is the calculus of constructions. All eight calculi are strongly normalizing.

Subtyping however is not represented in the cube, even though systems like F<:ω, known as higher-order bounded quantification, which combines subtyping and polymorphism are of practical interest, and can be further generalized to bounded type operators. Further extensions to F<:ω allow the definition of purely functional objects; these systems were generally developed after the lambda cube paper was published.[1]

The idea of the cube is due to the mathematician Henk Barendregt (1991). The framework of pure type systems generalizes the lambda cube in the sense that all corners of the cube, as well as many other systems can be represented as instances of this general framework.[2] This framework predates lambda cube a couple of years. In his 1991 paper, Barendregt also defines the corners of the cube in this framework.

See also

  • Some of the systems included in the cube were first defined in Automath.

Notes

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References

Template:Refbegin

  • Morten Heine Sørensen, Paweł Urzyczyn, Lectures on the Curry-Howard isomorphism, Elsevier, 2006, ISBN 0-444-52077-5, chapter 14, "Pure type systems and the lambda cube"
  • H.P. Barendregt, Introduction to generalized type systems, Journal of Functional Programming, 1(2):125-154, April 1991.
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Template:Refend

Further reading

External links

  1. Pierce, 2002, chapters 31 and 32
  2. Pierce, 2002, p. 466