Modelling Recursion and Probabilistic Choice in Guarded Type Theory

Philipp Stassen; Rasmus Ejlers Møgelberg; Maaike Annebet Zwart; Alejandro Aguirre; Lars Birkedal

doi:10.1145/370488

Modelling Recursion and Probabilistic Choice in Guarded Type Theory

Philipp Stassen, Rasmus Ejlers Møgelberg, Maaike Annebet Zwart, Alejandro Aguirre, Lars Birkedal

Aarhus University

Research output: Journal Article or Conference Article in Journal › Conference article › Research › peer-review

Abstract

Constructive type theory combines logic and programming in one language. This is useful both for reasoning about programs written in type theory, as well as for reasoning about other programming languages inside type theory. It is well-known that it is challenging to extend these applications to languages with recursion and computational effects such as probabilistic choice, because these features are not easily represented in constructive type theory. We show how to define and reason about a programming language with probabilistic choice and recursive types, in guarded type theory. We use higher inductive types to represent finite distributions and guarded recursion to model recursion. We define both operational and denotational semantics, as well as a relation between the two. The relation can be used to prove adequacy, but we also show how to use it to reason about programs up to contextual equivalence.

Original language	English
Journal	Proceedings of the ACM on Programming Languages
Volume	9
Issue number	POPL
DOIs	https://doi.org/10.1145/370488
Publication status	Published - 2025

Keywords

Probabilistic Programming Languages
Type Theory
Guarded Recursion
Recursive Types

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10.1145/370488Licence: CC BY

popl2025-preprintProof, 863 KBLicence: CC BY

https://arxiv.org/abs/2408.04455Licence: CC BY

Alegro: Algebraic Effects and Guarded Recursion
Møgelberg, R. E. (PI) & Zwart, M. A. (CoI)
Independent Research Fund Denmark
01/07/2022 → 30/06/2026
Project: Research

Cite this

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title = "Modelling Recursion and Probabilistic Choice in Guarded Type Theory",

abstract = "Constructive type theory combines logic and programming in one language. This is useful both for reasoning about programs written in type theory, as well as for reasoning about other programming languages inside type theory. It is well-known that it is challenging to extend these applications to languages with recursion and computational effects such as probabilistic choice, because these features are not easily represented in constructive type theory. We show how to define and reason about a programming language with probabilistic choice and recursive types, in guarded type theory. We use higher inductive types to represent finite distributions and guarded recursion to model recursion. We define both operational and denotational semantics, as well as a relation between the two. The relation can be used to prove adequacy, but we also show how to use it to reason about programs up to contextual equivalence.",

keywords = "Probabilistic Programming Languages, Type Theory, Guarded Recursion, Recursive Types",

author = "Philipp Stassen and M{\o}gelberg, {Rasmus Ejlers} and Zwart, {Maaike Annebet} and Alejandro Aguirre and Lars Birkedal",

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doi = "10.1145/370488",

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AU - Møgelberg, Rasmus Ejlers

AU - Zwart, Maaike Annebet

AU - Aguirre, Alejandro

AU - Birkedal, Lars

PY - 2025

Y1 - 2025

N2 - Constructive type theory combines logic and programming in one language. This is useful both for reasoning about programs written in type theory, as well as for reasoning about other programming languages inside type theory. It is well-known that it is challenging to extend these applications to languages with recursion and computational effects such as probabilistic choice, because these features are not easily represented in constructive type theory. We show how to define and reason about a programming language with probabilistic choice and recursive types, in guarded type theory. We use higher inductive types to represent finite distributions and guarded recursion to model recursion. We define both operational and denotational semantics, as well as a relation between the two. The relation can be used to prove adequacy, but we also show how to use it to reason about programs up to contextual equivalence.

AB - Constructive type theory combines logic and programming in one language. This is useful both for reasoning about programs written in type theory, as well as for reasoning about other programming languages inside type theory. It is well-known that it is challenging to extend these applications to languages with recursion and computational effects such as probabilistic choice, because these features are not easily represented in constructive type theory. We show how to define and reason about a programming language with probabilistic choice and recursive types, in guarded type theory. We use higher inductive types to represent finite distributions and guarded recursion to model recursion. We define both operational and denotational semantics, as well as a relation between the two. The relation can be used to prove adequacy, but we also show how to use it to reason about programs up to contextual equivalence.

KW - Probabilistic Programming Languages

KW - Type Theory

KW - Guarded Recursion

KW - Recursive Types

U2 - 10.1145/370488

DO - 10.1145/370488

M3 - Conference article

SN - 2475-1421

VL - 9

JO - Proceedings of the ACM on Programming Languages

JF - Proceedings of the ACM on Programming Languages

IS - POPL

ER -

Modelling Recursion and Probabilistic Choice in Guarded Type Theory

Abstract

Keywords

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Alegro: Algebraic Effects and Guarded Recursion

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