nLab modal type theory

Redirected from "multimodal type theory".

Contents

Context

Type theory

natural deduction metalanguage, practical foundations

judgement
hypothetical judgement, sequent
- antecedents $\vdash$ consequent, succedents

type theory (dependent, intensional, observational type theory, homotopy type theory)

calculus of constructions

syntax object language

theory, axiom
proposition/type (propositions as types)
definition/proof/program (proofs as programs)
theorem

computational trinitarianism =
propositions as types +programs as proofs +relation type theory/category theory

logic	set theory (internal logic of)	category theory	type theory
proposition	set	object	type
predicate	family of sets	display morphism	dependent type
proof	element	generalized element	term/program
cut rule		composition of classifying morphisms / pullback of display maps	substitution
introduction rule for implication		counit for hom-tensor adjunction	lambda
elimination rule for implication		unit for hom-tensor adjunction	application
cut elimination for implication		one of the zigzag identities for hom-tensor adjunction	beta reduction
identity elimination for implication		the other zigzag identity for hom-tensor adjunction	eta conversion
true	singleton	terminal object/(-2)-truncated object	h-level 0-type/unit type
false	empty set	initial object	empty type
proposition, truth value	subsingleton	subterminal object/(-1)-truncated object	h-proposition, mere proposition
logical conjunction	cartesian product	product	product type
disjunction	disjoint union (support of)	coproduct ((-1)-truncation of)	sum type (bracket type of)
implication	function set (into subsingleton)	internal hom (into subterminal object)	function type (into h-proposition)
negation	function set into empty set	internal hom into initial object	function type into empty type
universal quantification	indexed cartesian product (of family of subsingletons)	dependent product (of family of subterminal objects)	dependent product type (of family of h-propositions)
existential quantification	indexed disjoint union (support of)	dependent sum ((-1)-truncation of)	dependent sum type (bracket type of)
logical equivalence	bijection set	object of isomorphisms	equivalence type
	support set	support object/(-1)-truncation	propositional truncation/bracket type
		n-image of morphism into terminal object/n-truncation	n-truncation modality
equality	diagonal function/diagonal subset/diagonal relation	path space object	identity type/path type
completely presented set	set	discrete object/0-truncated object	h-level 2-type/set/h-set
set	set with equivalence relation	internal 0-groupoid	Bishop set/setoid with its pseudo-equivalence relation an actual equivalence relation
	equivalence class/quotient set	quotient	quotient type
induction		colimit	inductive type, W-type, M-type
higher induction		higher colimit	higher inductive type
-		0-truncated higher colimit	quotient inductive type
coinduction		limit	coinductive type
	preset		type without identity types
	set of truth values	subobject classifier	type of propositions
domain of discourse	universe	object classifier	type universe
modality		closure operator, (idempotent) monad	modal type theory, monad (in computer science)
linear logic		(symmetric, closed) monoidal category	linear type theory/quantum computation
proof net		string diagram	quantum circuit
(absence of) contraction rule		(absence of) diagonal	no-cloning theorem
		synthetic mathematics	domain specific embedded programming language

homotopy levels

semantics

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Relation to monads
Relation to endo-adjunctions

Examples

Geometric modality – Grothendieck topology
Closure modality
Necessity and possibility
Cohesive and differential modality

Related concepts
References

Idea

Modal type theory is a flavor of type theory with type formation rules for modalities, hence type theory which on propositions reduces to modal logic.

Following (Moggi91, Benton, Bierman & de Paiva 19198; Bierman & de Paiva 1996, 2000; Kobayashi 1997) modal type theory is specifically understood as being a type theory equipped with (co-)monads on its type system, representing the intended modal operators. Since monads in computer science embody a notion of computation, some authors also speak of computational type theory here (Benton, Bierman & de Paiva 1998, Fairtlough-Mendler 02).

According to (Benton, Bierman & de Paiva 1998, p. 1-2) this matches well with the default interpretation of (S4) modal logic as being about the modality $T$ of “possibility”:

The starting point for Moggi’s work is an explicit semantic distinction between computations and values. If $A$ is an object which interprets the values of a particular type, then $T(A)$ is the object which models computation of that type $A$ . $[...]$ For a wide variety of notions of computation, the unary operator $T(-)$ turns out to have the categorical structure of a strong monad on an underlying cartesian closed category of values. $[...]$ On a purely intuitive level and particularly if one thinks about non-termination, there is certainly something appealing about the idea that a computation of type $A$ represents the possibility of a value of type $A$ .

When the underlying type theory is homotopy type theory these modalities are a “higher” generalization of traditional modalities, with “higher” in the sense of higher category theory: they have categorical semantics in (∞,1)-categories given by (∞,1)-monads. See (Shulman 12, Rijke, Shulman, Spitters ) for definition of such higher modalities, and see at reflective subuniverse.

Properties

Relation to monads

At least in many cases, modalities in type theory are identified with monads or comonads on the underlying type universe, or on the subuniverse of propositions.

See for instance (Benton, Bierman & de Paiva 1998, section 3.2), (Kobayashi), (Gabbay-Nanevski, section 8), (Gaubault-Larrecq, Goubault, section 5.1), (Park-Harper, section 2.6), (Shulman) as examples of the first, and (Moggi, def. 4.7), (Awodey-Birkedal, section 4.2) as examples of the second.

Relation to endo-adjunctions

An endo-adjunction on a lex category gives rise to a modal type theory satisfying the modal axiom K; see dependent right adjoint. This also gives rise to a sound sound and complete interpretation of Fitch-style modal $\lambda$ -calculus.

Examples

Geometric modality – Grothendieck topology

As a special case of the modalities-are-monads relation, a Grothendieck topology on the site underlying a presheaf topos is equivalently encoded in the sheafification monad $PSh(C) \to Sh(C) \hookrightarrow PSh(C)$ induced by the sheaf topos geometric embedding. More generally, any geometric subtopos is equivalently represented by a left-exact idempotent monad.

When restricted to act on (-1)-truncated objects (i.e. subterminal objects or more generally monomorphisms), this becomes a universal closure operator. When internalized as an operation on the subobject classifier, this becomes the corresponding Lawvere-Tierney operator. This modal perspective on sheafification was maybe first made explicit by Bill Lawvere:

A Grothendieck ‘topology’ appears most naturally as a modal operator of the nature ‘it is locally the case that’ (Lawvere).

Here, “It is locally the case that [X is /Euclidean/etc],” corresponds to, “X is locally metrizable/Euclidean/etc,” in the usual parlance.

More discussion is in (Goldblatt), where this kind of modality is called a geometric modality.

For higher toposes, it is no longer true in general that a subtopos is determined by its behavior on the $(-1)$ -truncated objects, but we can still regard the entire sheafification monad as a higher modality in the internal homotopy type theory.

Closure modality

The canonical monad on a local topos gives rise to a closure modality on propositions in its internal language, as described in (Awodey-Birkedal).

Necessity and possibility

See at necessity and possibility the section Possible worlds via dependent type theory

Cohesive and differential modality

By adding to homotopy type theory three (higher) modalities that encode discrete types and codiscrete types and hence implicitly a non-(co)-discrete notion of cohesion one obtained cohesive homotopy type theory. Adding furthermore modalities for infinitesimal (co)discreteness yields differential homotopy type theory.

Related concepts

References

The clear identification of modal operators on types with monads (see at monad (in computer science)) is due to

Eugenio Moggi, Notions of computation and monads. Information and Computation, 93(1), 1991. (pdf)

This was observed (independently) to systematically yield constructive modal logic in (see also at computational type theory)

Nick Benton, Gavin Bierman, Valeria de Paiva, Computational Types from a Logical Perspective, Journal of Functional Programming 8 2 (1998) 177-193 [doi:10.1017/S0956796898002998, web]
Gavin M. Bierman, Valeria de Paiva, Intuitionistic necessity revisited, School of Computer Science research reports-University of Birmingham CSR (1996) [researchgate, pdf]
Gavin M. Bierman, Valeria de Paiva, On an Intuitionistic Modal Logic, Studia Logica 65 (2000) 383–416 [doi:10.1023/A:1005291931660, pdf]
Satoshi Kobayashi, Monad as modality, Theoretical Computer Science 175 1 (1997) 29-74 [doi:10.1016/S0304-3975(96)00169-7]
M. Fairlough, Michael Mendler, Propositional lax logic, Information and computation 137(1):1-33 (1997) [pdf]
Steve Awodey, p. 279 in: Category theory, Oxford University Press (2006, 2010) [doi:10.1093/acprof:oso/9780198568612.001.0001, ISBN:9780199237180, pdf]

See also the type-theoretic generalization of adjoint logic, as discussed in

Dan Licata, Mike Shulman, Adjoint logic with a 2-category of modes, in Logical Foundations of Computer Science 2016 (pdf, slides)

The modal systems “CL” and “PLL” in (Benton, Bierman & de Paiva 1998) and (Fairlough-Mendler), respectively, turn out to be equivalent to the geometric modality of Goldblatt. The system CS4 in (Kobayashi 1997) yields a constructive version of S4 modal logic.

Explicit mentioning of type theory equipped with such a monad as modal type theory or computational type theory is in

Matt Fairtlough, Michael Mendler, On the Logical Content of Computational Type Theory: A Solution to Curry’s Problem, Types for Proofs and Programs Lecture Notes in Computer Science Volume 2277, 2002, pp 63-78

Discussion of modal operators explicitly in dependent type theory (and with a brief mentioning of the relation to monads) is in

Aleksandar Nanevski, Frank Pfenning, Brigitte Pientka, Contextual Modal Type Theory (2005) [web, slides]
Valeria de Paiva, Eike Ritter, Fibrational Modal Type Theory, Electronic Notes in Theoretical Computer Science Volume 323, 11 July 2016, Proceedings of the Tenth Workshop on Logical and Semantic Frameworks, with Applications (LSFA 2015), pp. 143–161 (doi:10.1016/j.entcs.2016.06.010)
Daniel Gratzer, Jonathan Sterling, Lars Birkedal, Implementing Modal Dependent Type Theory, (pdf, GitHub)
Daniel Gratzer, Implementing Modal Dependent Type Theory, talk at ICFP 19 (slides pdf)
Daniel Gratzer, G. Alex Kavvos, Andreas Nuyts, Lars Birkedal: Multimodal Dependent Type Theory, Logical Methods in Computer Science 17 3 (2021) lmcs:7713 [arXiv:2011.15021, doi:10.46298/lmcs-17(3:11)2021]
Mike Shulman, Semantics of multimodal adjoint type theory (arXiv:2303.02572)
Daniel Gratzer, Syntax and semantics of modal type theory, PhD Aarhus (2023) [pdf]

A survey of the field of modal type theory is in the collections

M. Fairtlough, M. Mendler, Eugenio Moggi (eds.), Modalities in Type Theory, Mathematical Structures in Computer Science, Vol. 11, No. 4, (2001)
Valeria de Paiva, Rajeev Goré, Michael Mendler, Modalities in constructive logics and type theories, Special issue of the Journal of Logic and Computation, editorial pp. 439-446, Vol. 14, No. 4, Oxford University Press, (2004) (pdf)
Valeria de Paiva, Brigitte Pientka (eds.) Intuitionistic Modal Logic and Applications (IMLA 2008), . Inf. Comput. 209(12): 1435-1436 (2011) (web)

The historically first modal type theory, the interpretation of sheafification as a modality in the internal language of a Grothendieck topos goes back to the notion of Lawvere-Tierney operator

Bill Lawvere, Quantifiers and sheaves, Actes, Congrès intern, math., 1970. Tome 1, p. 329 à 334 (pdf)

reviewed in

Robert Goldblatt, Grothendieck topology as geometric modality, Mathematical Logic Quarterly, Volume 27, Issue 31-35, pages 495–529, (1981)

Modal type theory with an eye towards homotopy type theory is discussed in

UF-IAS-2012, Modal type theory

Formalization of modalities in homotopy type theory (modal homotopy type theory) is discussed in

Mike Shulman, Higher modalities, talk at UF-IAS-2012, October 2012 (pdf)
Egbert Rijke, Mike Shulman, Bas Spitters, Modalities in homotopy type theory, Logical Methods in Computer Science, 16 1 (2020) [arXiv:1706.07526, episciences:6015, doi:10.23638/LMCS-16(1:2)2020]
Mike Shulman, http://homotopytypetheory.org/2015/07/05/modules-for-modalities/ (2015)
Egbert Rijke, Bas Spitters, around def. 1.11 of Sets in homotopy type theory (arXiv:1305.3835)
Kevin Quirin and Nicolas Tabareau, Lawvere-Tierney Sheafification in Homotopy Type Theory, Workshop talk 2015 (pdf), Kevin Quirin thesis

and specifically in cohesive homotopy type theory in

Urs Schreiber, Michael Shulman, Quantum gauge field theory in Cohesive homotopy type theory, in Ross Duncan, Prakash Panangaden (eds.) Proceedings 9th Workshop on Quantum Physics and Logic, Brussels, Belgium, 10-12 October 2012 (arXiv:1408.0054)
Mike Shulman, Brouwer’s fixed-point theorem in real-cohesive homotopy type theory, Mathematical Structures in Computer Science Vol 28 (6) (2018): 856-941 (arXiv:1509.07584, doi:10.1017/S0960129517000147)
Felix Wellen, Cartan Geometry in Modal Homotopy Type Theory (arXiv:1806.05966, thesis pdf)
David Jaz Myers, Good Fibrations through the Modal Prism (arXiv:1908.08034v2)

A monograph aimed at philosophers is in

David Corfield, Modal homotopy type theory, Oxford University Press 2020 (ISBN: 9780198853404)

following

David Corfield, Modal homotopy type theory, 2017 (PhilSci archive:15260)

Monadic modal type theory with idempotent monads/monadic reflection is discussed in

Andrzej Filinski, Representing Layered Monads, POPL 1999. (pdf)
Andrzej Filinski, On the Relations between Monadic Semantics, TCS 375:1-3, 2007. (pdf)
Andrzej Filinski, Monads in Action, POPL 2010. (pdf)
Oleg Kiselyov and Chung-chieh Shan, Embedded Probabilistic Programming. Working conference on domain-specific languages, (2009) (pdf)

A general framework is discussed in

Dan Licata, Mike Shulman, Adjoint logic with a 2-category of modes, in Logical Foundations of Computer Science 2016 (pdf, slides)

(for modal unary type theory?)
Daniel Licata, Mike Shulman, and Mitchell Riley, A Fibrational Framework for Substructural and Modal Logics (extended version), in Proceedings of 2nd International Conference on Formal Structures for Computation and Deduction (FSCD 2017) (doi: 10.4230/LIPIcs.FSCD.2017.25, pdf)

(for modal simple type theory)

Review includes

Dan Licata, Felix Wellen, Synthetic Mathematics in Modal Dependent Type Theories, tutorial at Types, Homotopy Theory and Verification, 2018

Tutorial 1, Dan Licata: A Fibrational Framework for Modal Simple Type Theories (recording)

Tutorial 2, Felix Wellen: The Shape Modality in Real cohesive HoTT and Covering Spaces (recording)

Tutorial 3, Dan Licata: Discrete and Codiscrete Modalities in Cohesive HoTT (recording)

Tutorial 4, Felix Wellen, Discrete and Codiscrete Modalities in Cohesive HoTT, II (recording)

Tutorial 5, Dan Licata: A Fibrational Framework for Modal Dependent Type Theories (recording)

Tutorial 6, Felix Wellen: Differential Cohesive HoTT, (recording)
Dan Licata, Synthetic Mathematics in Modal Dependent Type Theories, notes for tutorial at Types, Homotopy Theory and Verification, 2018 (pdf)
Michael Shulman, Semantics of higher modalities, talk at Geometry in Modal HoTT (2019) (pdf slides, video recording)
Felix Cherubini, Geometry in Modal HoTT, talk at Geometry in Modal HoTT (2019) (video recording)
Egbert Rijke, Reflective subuniverses and modalities, talk at Geometry in Modal HoTT (2019) (video recording)
Egbert Rijke, Modal descent, talk at Geometry in Modal HoTT (2019) (video recording)