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Call-by-push-value

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In programming language theory, call-by-push-value (CBPV) is an intermediate language that embeds the call-by-value (CBV) and call-by-name (CBN) evaluation strategies. CBPV is structured as a polarized λ-calculus with two main types, "values" (+) and "computations" (-).[1] Restrictions on interactions between the two types enforce a controlled order of evaluation, similar to monads or CPS. The calculus can embed computational effects, such as nontermination, mutable state, or nondeterminism. There are natural semantics-preserving translations from CBV and CBN into CBPV. This means that giving a CBPV semantics and proving its properties implicitly establishes CBV and CBN semantics and properties as well. Paul Blain Levy formulated and developed CBPV in several papers and his doctoral thesis.[2][3][4]

Definition

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The CBPV paradigm is based on the slogan "a value is, a computation does". One complication in the presentation is distinguishing type variables ranging over value types from those ranging over computation types. This article follows Levy in using underlines to denote computations, so is an (arbitrary) value type but is a computation type.[4] Some authors use other conventions, such as distinct sets of letters.[5]

The exact set of constructs varies by author and desired use for the calculus, but the following constructs are typical:[2][4]

  • Lambdas λx.M are computations of type , where and . A lambda application F V or V'F is a computation of type , where and . The let-binding construct let { x_1 = V_1; ... }. M binds values x_1 to values V_1, of matching types , inside a computation M : .
  • A thunk thunk M is a value of type constructed from a computation M of type . Forcing a thunk is a computation, force X : for a thunk X : .
  • It is also possible to wrap a value V of type as a computation return V : . Such a computation can be used inside another computation as M to x. N : , where M : , and N : is a computation.
  • Values can also include algebraic data types constructed from a tag and zero or more sub-values, while computations include a deconstructing pattern-match match V as { (1,...) in M_1, ... }. Depending on presentation, ADTs may be limited to binary sums and products, Booleans only, or be omitted altogether.

A program is a closed computation of type , where is a ground ADT type.[4]

Complex values

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Expressions such as not true : bool make sense denotationally. But, following the rules above, not can only be encoded using pattern-matching, which would make it a computation, and therefore the overall expression must also be a computation, giving not true : F bool. Similarly, there is no way to obtain 1 from (1,2) without constructing a computation. When modelling CBPV in the equational or category theory, such constructs are indispensable. Levy therefore defines an extended IR, "CBPV with complex values". This IR extends let-binding to bind values within a value expression, and also to pattern-match a value with each clause returning a value expression.[3] Besides modelling, such constructs also make writing programs in CBPV more natural.[2]

Complex values complicate the operational semantics, in particular requiring an arbitrary decision of when to evaluate the complex value. Such a decision has no semantic significance because evaluating complex values has no side effects. Also, it is possible to syntactically convert any computation or closed expression to one of the same type and denotation without complex values.[3] Therefore, many presentations omit complex values.[4]

Translation

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The CBV translation produces CBPV values for each expression. A CBV function λx.M : is translated to thunk λx.Mv : . A CBV application M N : is translated to a computation Mv to f in Nv to x in x'(force f) of type , making the order of evaluation explicit. A pattern match match V as { (1,...) in M_1, ... } is translated as Vv to z in match z as { (1,...) in M_1v, ... }. Values are wrapped with return when necessary, but otherwise remain unmodified.[2] In some translations, sequencing may be required, such as translating inl M to M to x. return inl x.[4]

The CBN translation produces CBPV computations for each expression. A CBN function λx.M : translates unaltered, λx.MN : . A CBN application M N : is translated to a computation Mv (thunk Nv) of type . A pattern match match V as { (1,...) in M_1, ... } is translated similarly to CBN as Vn to z in match z as { (1,...) in M_1n, ... }. ADT values are wrapped with return, but force and thunk are also necessary on internal structure. Levy's translation assumes that M = force (thunk M), which does indeed hold.[2]

It is also possible to extend CBPV to model call-by-need, by introducing a M need x. N construct that allows visible sharing. This construct has semantics similar to M name x. N = (λy.N[x ↦ (force y)])(thunk M), except that with the need construct, the thunk of M is evaluated at most once.[6]

Modifications

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Some authors have noted that CBPV can be simplified, by removing either the U type constructor (thunks)[7] or the F type constructor (computations returning values).[8] Egger and Mogelberg justify omitting U on the grounds of streamlined syntax and avoiding the clutter of inferable conversions from computations to values. This choice makes computation types a subset of value types, and it is then natural to expand function types to a full function space between values. They term their calculus the "Enriched Effects Calculus". This modified calculus is equivalent to a superset of CBPV via a bidirectional semantics-preserving translation.[7] Ehrhard in contrast omits the F type constructor, making values a subset of computations. Ehrhard renames computations to "general types" to better reflect their semantics. This modified calculus, the "half-polarized lambda calculus", has close connections to linear logic.[8][9] It can be translated bidirectionally to a subset of a fully-polarized variant of CBPV.[10]

See also

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References

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  1. ^ Kavvos, G. A.; Morehouse, Edward; Licata, Daniel R.; Danner, Norman (January 2020). "Recurrence extraction for functional programs through call-by-push-value". Proceedings of the ACM on Programming Languages. 4 (POPL): 1–31. arXiv:1911.04588. doi:10.1145/3371083. ISSN 2475-1421.
  2. ^ a b c d e Blain Levy, Paul (April 1999). Call-by-Push-Value: A Subsuming Paradigm (PDF). Typed Lambda Calculi and Applications, 4th International Conference, TLCA'99, L'Aquila, Italy. Lecture Notes in Computer Science. Vol. 1581. pp. 228–242.
  3. ^ a b c Levy, Paul Blain (2003). Call-by-push-value: a functional/imperative synthesis (PDF). Dordrecht ; Boston: Kluwer Academic Publishers. ISBN 978-1-4020-1730-8.
  4. ^ a b c d e f Levy, Paul Blain (April 2022). "Call-by-push-value". ACM SIGLOG News. 9 (2): 7–29. doi:10.1145/3537668.3537670.
  5. ^ Pédrot, Pierre-Marie; Tabareau, Nicolas (January 2020). "The fire triangle: how to mix substitution, dependent elimination, and effects". Proceedings of the ACM on Programming Languages. 4 (POPL): 1–28. doi:10.1145/3371126.
  6. ^ McDermott, Dylan; Mycroft, Alan (2019). "Extended Call-by-Push-Value: Reasoning About Effectful Programs and Evaluation Order". Programming Languages and Systems. Springer International Publishing. pp. 235–262. doi:10.1007/978-3-030-17184-1_9. ISBN 978-3-030-17184-1.
  7. ^ a b Egger, J.; Mogelberg, R. E.; Simpson, A. (1 June 2014). "The enriched effect calculus: syntax and semantics" (PDF). Journal of Logic and Computation. 24 (3): 615–654. doi:10.1093/logcom/exs025.
  8. ^ a b Ehrhard, Thomas (2016). "Call-By-Push-Value from a Linear Logic Point of View". Programming Languages and Systems. Lecture Notes in Computer Science. Vol. 9632. pp. 202–228. doi:10.1007/978-3-662-49498-1_9. ISBN 978-3-662-49497-4.
  9. ^ Chouquet, Jules; Tasson, Christine (2020). Taylor expansion for Call-By-Push-Value. Leibniz International Proceedings in Informatics. Vol. 152. Schloss Dagstuhl – Leibniz-Zentrum für Informatik. pp. 16:1–16:16. doi:10.4230/LIPIcs.CSL.2020.16.
  10. ^ Ehrhard, Thomas (July 2015), A Call-By-Push-Value FPC and its interpretation in Linear Logic