Fixup some missing files

This commit is contained in:
Frederik Hanghøj Iversen 2018-05-31 01:07:05 +02:00
parent 08046d05dc
commit 27ae920634
10 changed files with 41 additions and 27 deletions

3
doc/.gitignore vendored
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@ -4,6 +4,7 @@
*.log
*.out
*.pdf
!assets/**
*.bbl
*.blg
*.toc
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*.ilg
*.ind
*.nav
*.snm
*.snm

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Presentation
====
Find one clear goal.
Remember crowd-control.
Leave out:
lemPropF
Talk about structure of library:
===

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\chapter*{Abstract}
The usual notion of propositional equality in intensional type-theory
is restrictive. For instance it does not admit functional
extensionality nor univalence. This poses a severe limitation on both
what is \emph{provable} and the \emph{re-usability} of proofs. Recent
is restrictive. For instance it does not admit functional
extensionality nor univalence. This poses a severe limitation on both
what is \emph{provable} and the \emph{re-usability} of proofs. Recent
developments have however resulted in cubical type theory which
permits a constructive proof of these two important notions. The
permits a constructive proof of these two important notions. The
programming language Agda has been extended with capabilities for
working in such a cubical setting. This thesis will explore the
working in such a cubical setting. This thesis will explore the
usefulness of this extension in the context of category theory.
The thesis will motivate the need for univalence and explain why
propositional equality in cubical Agda is more expressive than in
standard Agda. Alternative approaches to Cubical Agda will be
presented and their pros and cons will be explained. As an example of
standard Agda. Alternative approaches to Cubical Agda will be
presented and their pros and cons will be explained. As an example of
the application of univalence two formulations of monads will be
presented: Namely monads in the monoidal form and monads in the
Kleisli form and under the univalent interpretation it will be shown
@ -20,5 +20,5 @@ how these are equal.
Finally the thesis will explain the challenges that a developer will
face when working with cubical Agda and give some techniques to
overcome these difficulties. It will also try to suggest how further
overcome these difficulties. It will also try to suggest how further
work can help alleviate some of these challenges.

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\chapter*{Acknowledgements}

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@ -7,7 +7,7 @@ can conjure up various proofs. I also want to recognize the support
of Knud Højgaards Fond who graciously sponsored me with a 20.000 DKK
scholarship which helped toward sponsoring the two years I have spent
studying abroad. I would also like to give a warm thanks to my fellow
students Pierre Kraft and Nachiappan Villiappan who have made the time
students Pierre~Kraft and Nachiappan~Valliappan who have made the time
spent working on the thesis way more enjoyable. Lastly I would like to
give a special thanks to Valentina Méndez who have been a great moral
give a special thanks to Valentina~Méndez who have been a great moral
support throughout the whole process.

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doc/assets/logo_eng.pdf Normal file

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@ -80,7 +80,7 @@ Master's thesis in Computer Science
\vfill
\centering
\includegraphics[width=0.2\pdfpagewidth]{logo_eng.pdf}
\includegraphics[width=0.2\pdfpagewidth]{assets/logo_eng.pdf}
\vspace{5mm}
\textsc{Department of Computer Science and Engineering}\\

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@ -75,8 +75,8 @@ some limitations inherent in ITT and -- by extension -- Agda.
Consider the functions:
%
\begin{align*}%
\var{zeroLeft} & \defeq \lambda\; (n \tp \bN) \to (0 + n \tp \bN) \\
\var{zeroRight} & \defeq \lambda\; (n \tp \bN) \to (n + 0 \tp \bN)
\var{zeroLeft} & \defeq λ\; (n \tp \bN) \to (0 + n \tp \bN) \\
\var{zeroRight} & \defeq λ\; (n \tp \bN) \to (n + 0 \tp \bN)
\end{align*}%
%
The term $n + 0$ is \nomenindex{definitionally} equal to $n$, which we

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@ -4,8 +4,12 @@
%% \usecolortheme[named=seagull]{structure}
\input{packages.tex}
\input{macros.tex}
\title[Univalent Categories]{Univalent Categories\\ \footnotesize A formalization of category theory in Cubical Agda}
\title{Univalent Categories}
\subtitle{A formalization of category theory in Cubical Agda}
\newcommand{\myname}{Frederik Hangh{\o}j Iversen}
\author[\myname]{
\myname\\
@ -74,14 +78,14 @@
\framesubtitle{Definition}
Heterogeneous paths
\begin{equation*}
\Path \tp (P \tp I → \MCU) → P\ 0 → P\ 1 → \MCU
\Path \tp (P \tp \I\MCU) → P\ 0 → P\ 1 → \MCU
\end{equation*}
\pause
For $P \tp I → \MCU$, $A \tp \MCU$ and $a_0, a_1 \tp A$
For $P \tp \I\MCU$, $A \tp \MCU$ and $a_0, a_1 \tp A$
inhabitants of $\Path\ P\ a_0\ a_1$ are like functions
%
$$
p \tp_{i \tp I} P\ i
p \tp_{i \tp \I} P\ i
$$
%
Which satisfy $p\ 0 & = a_0$ and $p\ 1 & = a_1$
@ -255,13 +259,13 @@
\end{align*}
where
$$
\phi\ f ≜ \identity
( \lll f ≡ f )
\phi\ f ≜
( \identity \lll f ≡ f )
×
( f \lll \identity ≡ f)
$$
\pause
Let $\approxeq$ denote ismorphism of objects. We can then construct
Let $\approxeq$ denote isomorphism of objects. We can then construct
the identity isomorphism in any category:
$$
\identity , \identity , \var{isIdentity} \tp A \approxeq A
@ -326,7 +330,7 @@
Use $\lemPropF$ for the latter.
\pause
%
Univalence is indexed by an identity proof. So $A ≜
Univalence is indexed by an identity proof. So $A ≜
IsIdentity\ identity$ and $B ≜ \var{Univalent}$.
\pause
%
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\end{align*}
\pause
%
Induction will be based at $A$. Let $\widetilde{B}$ and $\widetilde{p}
Induction will be based at $A$. Let $\widetilde{B}$ and $\widetilde{p}
\tp A ≡ \widetilde{B}$ be given.
%
\pause
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\end{align*}
\pause
%
Let $\fmap$ be the map on arrows of $\EndoR$. Likewise
Let $\fmap$ be the map on arrows of $\EndoR$. Likewise
$\pure$ and $\join$ are the maps of the natural transformations
$\pureNT$ and $\joinNT$ respectively.
%
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\join\bind\ \identity
$$
\pause
The laws are logically equivalent. So we get:
The laws are logically equivalent. So we get:
%
$$
\var{Monoidal}\var{Kleisli}

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@ -37,7 +37,7 @@ Master's thesis in Computer Science
\vfill
\centering
\includegraphics[width=0.2\pdfpagewidth]{logo_eng.pdf}
\includegraphics[width=0.2\pdfpagewidth]{assets/logo_eng.pdf}
\vspace{5mm}
\textsc{Department of Computer Science and Engineering}\\