292 lines
11 KiB
TeX
292 lines
11 KiB
TeX
\section{Implementation}
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This implementation formalizes the following concepts:
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\begin{itemize}
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\item Core categorical concepts
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\subitem Categories
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\subitem Functors
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\subitem Products
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\subitem Exponentials
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\subitem Cartesian closed categories
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\subitem Natural transformations
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\subitem Yoneda embedding
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\subitem Monads
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\subsubitem Monoidal monads
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\subsubitem Kleisli monads
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\subsubitem Voevodsky's construction
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\item Category of \ldots
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\subitem Homotopy sets
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\subitem Categories
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\subitem Relations
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\subitem Functors
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\subitem Free category
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\end{itemize}
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Since it is useful to distinguish between types with more or less (homotopical)
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structure I have followed the following design-principle: I have split concepts
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up into things that represent ``data'' and ``laws'' about this data. The idea is
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that we can provide a proof that the laws are mere propositions. As an example a
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category is defined to have two members: `raw` which is a collection of the data
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and `isCategory` which asserts some laws about that data.
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This allows me to reason about things in a more mathematical way, where one can
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reason about two categories by simply focusing on the data. This is acheived by
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creating a function embodying the ``equality principle'' for a given type.
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\subsubsection{Categories}
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The data for a category consist of objects, morphisms (or arrows as I will refer
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to them henceforth), the identity arrow and composition of arrows.
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Another record encapsulates some laws about this data: associativity of
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composition, identity law for the identity morphism. These are standard
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requirements for being a category as can be found in standard mathematical
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expositions on the topic. We, however, impose one further requirement on what it
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means to be a category, namely that the type of arrows form a set. We could
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relax this requirement, this would give us the notion of higher categorier
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(\cite[p. 307]{hott-2013}). For the purpose of this project, however, this
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report will restrict itself to 1-categories.
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Raw categories satisfying these properties are called a pre-categories.
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As a further requirement to be a proper category we require it to be univalent.
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This requirement is quite similiar to univalence for types, but we let
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isomorphism of objects play the role of equivalence of types. The univalence
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criterion is:
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$$
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\isEquiv\ (A \cong B)\ (A \equiv B)\ \idToIso_{A\ B}
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$$
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Note that this is a stronger requirement than:
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$$
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(A \cong B) \simeq (A \equiv B)
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$$
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Which is permissable simply by ``forgetting'' that $\idToIso_{A\ B}$ plays the
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role of the equivalence.
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With all this in place it is now possible to prove that all the laws are indeed
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mere propositions. Most of the proofs simply use the fact that the type of
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arrows are sets. This is because most of the laws are a collection of equations
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between arrows in the category. And since such a proof does not have any
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content, two witnesses must be the same. All the proofs are really quite
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mechanical. Lets have a look at one of them: The identity law states that:
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$$
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\prod_{A\ B \tp \Object} \prod_{f \tp A \to B} \id \comp f \equiv f \x f \id \equiv f
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$$
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There are multiple ways to prove this. Perhaps one of the more intuitive proofs
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is by way of the following `combinators':
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$$
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\mathit{propPi} \tp \left(\prod_{a \tp A} \isProp\ (P\ a)\right) \to \isProp\ \left(\prod_{a \tp A} P\ a\right)
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$$
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I.e.; pi-types preserve propositionality when the co-domain is always a
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proposition.
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$$
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\mathit{propSig} \tp \isProp\ A \to \left(\prod_{a : A} \isProp\ (P\ a)\right) \to \isProp\ \left(\sum_{a \tp A} P\ a\right)
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$$
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I.e.; sigma-types preserve propositionality whenever it's first component is a
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proposition, and it's second component is always a proposition for all points of
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in the left type.
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Defines the basic notion of a category. This definition
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closely follows that of [HoTT]: That is, the standard definition of a category
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(data; objects, arrows, composition and identity, laws; preservation of identity
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and composition) plus the extra condition that it is univalent - namely that you
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can get an equality of two objects from an isomorphism.
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\subsubsection{Functors}
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Defines the notion of a functor - also split up into data and laws.
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Propositionality for being a functor.
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Composition of functors and the identity functor.
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\subsubsection{Products}
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Definition of what it means for an object to be a product in a given category.
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Definition of what it means for a category to have all products.
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\WIP{} Prove propositionality for being a product and having products.
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\subsubsection{Exponentials}
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Definition of what it means to be an exponential object.
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Definition of what it means for a category to have all exponential objects.
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\subsubsection{Cartesian closed categories}
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Definition of what it means for a category to be cartesian closed; namely that
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it has all products and all exponentials.
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\subsubsection{Natural transformations}
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Definition of transformations\footnote{Maybe this is a name I made up for a
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family of morphisms} and the naturality condition for these.
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Proof that naturality is a mere proposition and the accompanying equality
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principle. Proof that natural transformations are homotopic sets.
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The identity natural transformation.
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\subsubsection{Yoneda embedding}
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The yoneda embedding is typically presented in terms of the category of
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categories (cf. Awodey) \emph however this is not stricly needed - all we need
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is what would be the exponential object in that category - this happens to be
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functors and so this is how we define the yoneda embedding.
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\subsubsection{Monads}
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Defines an equivalence between these two formulations of a monad:
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\subsubsubsection{Monoidal monads}
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Defines the standard monoidal representation of a monad:
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An endofunctor with two natural transformations (called ``pure'' and ``join'')
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and some laws about these natural transformations.
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Propositionality proofs and equality principle is provided.
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\subsubsubsection{Kleisli monads}
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A presentation of monads perhaps more familiar to a functional programer:
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A map on objects and two maps on morphisms (called ``pure'' and ``bind'') and
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some laws about these maps.
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Propositionality proofs and equality principle is provided.
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\subsubsubsection{Voevodsky's construction}
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Provides construction 2.3 as presented in an unpublished paper by Vladimir
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Voevodsky. This construction is similiar to the equivalence provided for the two
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preceding formulations
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\footnote{ TODO: I would like to include in the thesis some motivation for why
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this construction is particularly interesting.}
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\subsubsection{Homotopy sets}
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The typical category of sets where the objects are modelled by an Agda set
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(henceforth ``$\Type$'') at a given level is not a valid category in this cubical
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settings, we need to restrict the types to be those that are homotopy sets. Thus
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the objects of this category are:
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$$\hSet_\ell \defeq \sum_{A \tp \MCU_\ell} \isSet\ A$$
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The definition of univalence for categories I have defined is:
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$$\isEquiv\ (\hA \equiv \hB)\ (\hA \cong \hB)\ \idToIso$$
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Where $\hA and \hB$ denote objects in the category. Note that this is stronger
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than
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$$(\hA \equiv \hB) \simeq (\hA \cong \hB)$$
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Because we require that the equivalence is constructed from the witness to:
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$$\id \comp f \equiv f \x f \comp \id \equiv f$$
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And indeed univalence does not follow immediately from univalence for types:
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$$(A \equiv B) \simeq (A \simeq B)$$
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Because $A\ B \tp \Type$ whereas $\hA\ \hB \tp \hSet$.
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For this reason I have shown that this category satisfies the following
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equivalent formulation of being univalent:
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$$\prod_{A \tp hSet} \isContr \left( \sum_{X \tp hSet} A \cong X \right)$$
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But I have not shown that it is indeed equivalent to my former definition.
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\subsubsection{Categories}
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Note that this category does in fact not exist. In stead I provide the
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definition of the ``raw'' category as well as some of the laws.
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Furthermore I provide some helpful lemmas about this raw category. For instance
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I have shown what would be the exponential object in such a category.
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These lemmas can be used to provide the actual exponential object in a context
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where we have a witness to this being a category. This is useful if this library
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is later extended to talk about higher categories.
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\subsubsection{Functors}
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The category of functors and natural transformations. An immediate corrolary is
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the set of presheaf categories.
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\WIP{} I have not shown that the category of functors is univalent.
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\subsubsection{Relations}
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The category of relations. \WIP{} I have not shown that this category is
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univalent. Not sure I intend to do so either.
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\subsubsection{Free category}
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The free category of a category. \WIP{} I have not shown that this category is
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univalent.
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\subsection{Current Challenges}
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Besides the items marked \WIP{} above I still feel a bit unsure about what to
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include in my report. Most of my work so far has been specifically about
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developing this library. Some ideas:
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\begin{itemize}
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\item
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Modularity properties
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\item
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Compare with setoid-approach to solve similiar problems.
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\item
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How to structure an implementation to best deal with types that have no
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structure (propositions) and those that do (sets and everything above)
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\end{itemize}
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\subsection{Ideas for future developments}
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\subsubsection{Higher categories}
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I only have a notion of (1-)categories. Perhaps it would be nice to also
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formalize higher categories.
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\subsubsection{Hierarchy of concepts related to monads}
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In Haskell the type-class Monad sits in a hierarchy atop the notion of a functor
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and applicative functors. There's probably a similiar notion in the
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category-theoretic approach to developing this.
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As I have already defined monads from these two perspectives, it would be
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interesting to take this idea even further and actually show how monads are
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related to applicative functors and functors. I'm not entirely sure how this
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would look in Agda though.
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\subsubsection{Use formulation on the standard library}
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I also thought it would be interesting to use this library to show certain
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properties about functors, applicative functors and monads used in the Agda
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Standard library. So I went ahead and tried to show that agda's standard
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library's notion of a functor (along with suitable laws) is equivalent to my
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formulation (in the category of homotopic sets). I ran into two problems here,
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however; the first one is that the standard library's notion of a functor is
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indexed by the object map:
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$$
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\Functor \tp (\Type \to \Type) \to \Type
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$$
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Where $\Functor\ F$ has the member:
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$$
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\fmap \tp (A \to B) \to F A \to F B
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$$
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Whereas the object map in my definition is existentially quantified:
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$$
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\Functor \tp \Type
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$$
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And $\Functor$ has these members:
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\begin{align*}
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F & \tp \Type \to \Type \\
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\fmap & \tp (A \to B) \to F A \to F B\}
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\end{align*}
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