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Daniel Hillerström
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8
macros.tex
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@@ -351,8 +351,14 @@
\newcommand{\fail}{\dec{fail}} \newcommand{\fail}{\dec{fail}}
\newcommand{\optionalise}{\dec{optionalise}} \newcommand{\optionalise}{\dec{optionalise}}
\newcommand{\bind}{\ensuremath{\gg\!=}} \newcommand{\bind}{\ensuremath{\gg\!=}}
\newcommand{\return}{\dec{return}} \newcommand{\return}{\dec{Return}}
\newcommand{\faild}{\dec{withDefault}} \newcommand{\faild}{\dec{withDefault}}
\newcommand{\Free}{\dec{Free}}
\newcommand{\OpF}{\dec{Op}}
\newcommand{\DoF}{\dec{do}}
\newcommand{\getF}{\dec{get}}
\newcommand{\putF}{\dec{put}}
\newcommand{\fmap}{\dec{fmap}}
% Abstract machine % Abstract machine
\newcommand{\cek}[1]{\ensuremath{\langle #1 \rangle}} \newcommand{\cek}[1]{\ensuremath{\langle #1 \rangle}}

10
thesis.bib
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@@ -768,6 +768,16 @@
year = {1992} year = {1992}
} }
@article{Wadler92b,
author = {Philip Wadler},
title = {Comprehending Monads},
journal = {Math. Struct. Comput. Sci.},
volume = {2},
number = {4},
pages = {461--493},
year = {1992}
}
@inproceedings{JonesW93, @inproceedings{JonesW93,
author = {Simon L. Peyton Jones and author = {Simon L. Peyton Jones and
Philip Wadler}, Philip Wadler},

75
thesis.tex
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@@ -512,6 +512,79 @@ monadic operation on the continuation monad~\cite{Wadler92}.
\el \el
\] \]
\subsection{Free monad}
Just like other monads the free monad satisfies the monad laws,
however, unlike other monads the free monad does not perform any
computation \emph{per se}. Instead the free monad builds an abstract
representation of the computation in form of a computation tree, whose
interior nodes correspond to an invocation of some operation on the
monad, where each outgoing edge correspond to a possible continuation
of the operation; the leaves correspond to return values. The meaning
of a free monadic computation is ascribed by a separate function, or
interpreter, that traverses the computation tree.
The shape of computation trees is captured by the following generic
type definition.
%
\[
\Free~F~A \defas [\return:A|\OpF:F\,(\Free~F~A)]
\]
%
The type constructor $\Free$ takes two type arguments. The first
parameter $F$ is itself a type constructor of kind
$\TypeCat \to \TypeCat$. The second parameter is the usual type of
values computed by the monad. The $\Return$ tag creates a leaf of the
computation tree, whilst the $\OpF$ tag creates an interior node. In
the type signature for $\OpF$ the type variable $F$ is applied to the
$\Free$ type. The idea is that $F~K$ computes an enumeration of the
signatures of the possible operations on the monad, where $K$ is the
type of continuation for each operation. Thus the continuation of an
operation is another computation tree node.
%
\begin{definition} The free monad is a triple
$(F^{\TypeCat \to \TypeCat}, \Return, \bind)$ which forms a monad
with respect to $F$. In addition an adequate instance of $F$ must
supply a map, $\dec{fmap} : (A \to B) \to F~A \to F~B$, over its
structure.
%
\[
\bl
T~A \defas \Free~F~A \smallskip\\
\Return : A \to T~A\\
\Return \defas \lambda x.\return~x\\
\bind ~: T~A \to (A \to T~B) \to T~B\\
\bind ~\defas \lambda m.\lambda k.\Case\;m\;\{\return~x \mapsto k~x;\OpF~y \mapsto \OpF\,(\fmap\,(\lambda m'. m' \bind k)\,y)\}
\el
\]
%
We define an auxiliary function to alleviate some of the
boilerplate involved with performing operations on the monad.
%
\[
\bl
\DoF : F~A \to \Free~F~A\\
\DoF \defas \lambda op.\OpF\,(\fmap\,(\lambda x.\return~x)\,op)
\el
\]
%
\end{definition}
\[
\bl
\dec{FreeState}~S~R \defas [\Get:S \to R|\Put:\Record{S;R}|\Done] \smallskip\\
\fmap~f~x \defas \Case\;x\;\{
\bl
\Get~k \mapsto \Get\,(\lambda st.f\,(k~st));\\
\Put~st'~k \mapsto \Put\,\Record{st';f~k};\\
\Done \mapsto \Done\}
\el \smallskip\\
\getF : \UnitType \to T~S\\
\getF~\Unit \defas \DoF~(\Get\,(\lambda x.x)))\\
\putF : S \to T~\UnitType\\
\putF~st \defas \DoF~(\Put\,\Record{st;\Unit})
\el
\]
\subsection{Direct-style revolution} \subsection{Direct-style revolution}
@@ -8175,7 +8248,7 @@ $\Co$-operations have been handled.
% %
In the definition the scheduler state is bound by the name $st$. In the definition the scheduler state is bound by the name $st$.
The $\return$ case is invoked when a process completes. The return The $\Return$ case is invoked when a process completes. The return
value $x$ is paired with the identifier of the currently executing value $x$ is paired with the identifier of the currently executing
process and consed onto the list $done$. Subsequently, the function process and consed onto the list $done$. Subsequently, the function
$\runNext$ is invoked in order to the next ready process. $\runNext$ is invoked in order to the next ready process.