process camil's notes

[msc-thesis1617.git] / methods.top.tex

\section{iTasks}
\gls{TOP} is a modern recent programming paradigm implemented as
\gls{iTasks}\cite{achten_introduction_2015} in the pure lazy functional
language \gls{Clean}\cite{brus_cleanlanguage_1987}. \gls{iTasks} is a
\gls{EDSL} to model workflow tasks in the broadest sense. A \gls{Task} is just
a function that --- given some state --- returns the observable \CI{TaskValue}. The
\CI{TaskValue} of a \CI{Task} can have different states. Not all state
transitions are possible as shown in Figure~\ref{fig:taskvalue}. Once a value
is stable it can never become unstable again. Stability is often reached
by pressing a confirmation button. \glspl{Task} yielding a constant value are
immediately stable.

A simple \gls{iTasks} example illustrating the route to stability of a
\gls{Task} in which the user has to enter a full name is shown in
Listing~\ref{lst:taskex}. The code is accompanied by screenshots showing the
user interface in Figure~\ref{fig:taskex1},~\ref{fig:taskex2}
and~\ref{fig:taskex3}. The \CI{TaskValue} of the \gls{Task} is in the first
image in the \CI{NoValue} state, the second image does not have all the fields
filled in and therefore the \CI{TaskValue} remains \CI{Unstable}. In the third
image all fields are entered and the \CI{TaskValue} transitions to the
\CI{Unstable} state. When the user presses \emph{Continue} the value becomes
\CI{Stable} and cannot be changed any further.

\begin{figure}[H]
        \centering
        \includegraphics[width=.5\linewidth]{fig-taskvalue}
        \caption{The states of a \CI{TaskValue}}\label{fig:taskvalue}
\end{figure}

\begin{lstlisting}[language=Clean,label={lst:taskex},%
        caption={An example \gls{Task} for entering a name}]
:: Name = { firstname :: String
          , lastname  :: String
          }

derive class iTask Name

enterInformation :: String [EnterOption m] -> (Task m) | iTask m

enterName :: Task Name
enterName = enterInformation "Enter your name" []
\end{lstlisting}

\begin{figure}[H]
        \centering
        \begin{subfigure}{.25\textwidth}
                \centering
                \includegraphics[width=.9\linewidth]{taskex1}
                \caption{Initial interface}\label{fig:taskex1}
        \end{subfigure}
        \begin{subfigure}{.25\textwidth}
                \centering
                \includegraphics[width=.9\linewidth]{taskex2}
                \caption{Incomplete entrance}\label{fig:taskex2}
        \end{subfigure}
        \begin{subfigure}{.25\textwidth}
                \centering
                \includegraphics[width=.9\linewidth]{taskex3}
                \caption{Complete entry}\label{fig:taskex3}
        \end{subfigure}
        \caption{Example of a generated user interface}
\end{figure}

For a type to be suitable, it must have instances for a collection of generic
functions that is captured in the class \CI{iTask}. Basic types have
specialization instances for these functions and show an according interface.
Generated interfaces can be modified with decoration operators.

\section{Combinators}
\Glspl{Task} can be combined using so called \gls{Task}-combinators.
Combinators describe relations between \glspl{Task}. \Glspl{Task} can be
combined in parallel, sequenced and their result values can be converted to
\glspl{SDS}. Moreover, a very important combinator is the step combinator which
starts a new task according to specified predicates on the \CI{TaskValue}.
Type signatures of the basic combinators are shown in
Listing~\ref{lst:combinators}.

\begin{itemize}
        \item Step:

                The step combinator is used to start \glspl{Task} when a predicate on
                the \CI{TaskValue} holds or an action has taken place. The bind
                operator can be written as a step combinator.
                \begin{lstlisting}[language=Clean]
(>>=) infixl 1 :: (Task a) (a -> (Task b)) -> (Task b) | iTask a & iTask b
(>>=) ta f = ta >>* [OnAction "Continue" onValue, OnValue onStable]
    where
        onValue (Value a _)     = Just (f a)
        onValue _               = Nothing

        onStable (Value a True) = Just (f a)
        onStable _              = Nothing
                \end{lstlisting}
        \item Parallel:

                The parallel combinator allows for concurrent \glspl{Task}. The
                \glspl{Task} combined with these operators will appear at the same time
                in the web browser of the user and the results are combined as the type
                dictates.
\end{itemize}

\begin{lstlisting}[language=Clean,%
        caption={\Gls{Task}-combinators},label={lst:combinators}]
//Step combinator
(>>*)  infixl 1 :: (Task a) [TaskCont a (Task b)] -> Task b     | iTask a & iTask b
(>>=)  infixl 1 :: (Task a) (a -> Task b)         -> Task b   | iTask a & iTask b
:: TaskCont a b
        =     OnValue             ((TaskValue a)  -> Maybe b)
        |     OnAction    Action  ((TaskValue a)  -> Maybe b)
        | E.e: OnException         (e              -> b)       & iTask e
        |     OnAllExceptions     (String         -> b)
:: Action = Action String

//Parallel combinators
(-||-) infixr 3 :: (Task a) (Task a)              -> Task a     | iTask a
(||-)  infixr 3 :: (Task a) (Task b)              -> Task b     | iTask a & iTask b
(-||)  infixl 3 :: (Task a) (Task b)              -> Task a     | iTask a & iTask b
(-&&-) infixr 4 :: (Task a) (Task b)              -> Task (a,b) | iTask a & iTask b
\end{lstlisting}

\section{\acrlongpl{SDS}}
\Glspl{SDS} are an abstraction over resources that are available in the world
or in the \gls{iTasks} system. The shared data can be a file on disk, it can be
the time, a random integer or just some data stored in memory. The actual
\gls{SDS} is just a record containing functions on how to read and write the
source. In these functions the \CI{*World} is available and therefore it can
interact with the outside world. The \CI{*IWorld} is also available and
therefore the functions can also access other shares, possibly combining them.

The basic operations for \glspl{SDS} are get, set and update. The signatures
for these functions are shown in Listing~\ref{lst:shares}. All of the
operations are atomic in the sense that during reading no other tasks are
executed.

\begin{lstlisting}[%
        language=Clean,label={lst:shares},caption={\Gls{SDS} functions}]
get ::          (ReadWriteShared r w)           -> Task r | iTask r
set :: w        (ReadWriteShared r w)           -> Task w | iTask w
upd :: (r -> w) (ReadWriteShared r w)           -> Task w | iTask r & iTask w

\end{lstlisting}