1 Similar research has been conducted on the subject.
2 For example, microcontrollers such as the
\gls{Arduino
} can be remotely
3 controlled by the
\gls{Firmata
}-protocol
\footnote{``firmata/protocol:
4 Documentation of the Firmata protocol.''
5 (
\url{https://github.com/firmata/protocol
}).
[Accessed:
23-May-
2017].
}. This
6 protocol is designed to expose the peripherals such as sensors to the server.
7 This allows very fine grained control but with the cost of excessive
8 communication overhead since no code is executed on the device, only the
9 peripherals are queried. A
\gls{Haskell
} implementation of the protocol is
10 also available
\footnote{``hArduino by LeventErkok.'' (
\url{%
11 https://leventerkok.github.io/hArduino
}).
[Accessed:
23-May-
2017].
}.
13 \Gls{Clean
} has a history of interpretation and there is a lot of research
14 happening on the intermediate language
\gls{SAPL
}.
\Gls{SAPL
} is a purely
15 functional intermediate language that has interpreters written in
16 \gls{C++
}~
\cite{jansen_efficient_2007
},
\gls{Javascript
}%
17 ~
\cite{domoszlai_implementing_2011
} and
\gls{Clean
} and
\gls{Haskell
} compiler
18 backends~
\cite{domoszlai_compiling_2012
}. However, interpreting the resulting
19 code is still heap-heavy and therefore not directly suitable for devices with
20 as little as $
2K$ of RAM such as the
\gls{Arduino
} \emph{Uno
}. It might be
21 possible to compile the
\gls{SAPL
} code into efficient machine language or
22 \gls{C
} but then the system would lose its dynamic properties since the
23 microcontroller then would have to be reprogrammed every time a new
\gls{Task
}
24 is sent to the device.
26 \Glspl{EDSL
} have often been used to generate
\gls{C
} code for microcontroller
27 environments. This work uses parts of the existing
\gls{mTask
}-
\gls{EDSL
} which
28 generates
\gls{C
} code to run a
\gls{TOP
}-like system on microcontrollers
%
29 ~
\cite{plasmeijer_shallow_2016
}~
\cite{koopman_type-safe_nodate
}. Again, this
30 requires a reprogramming cycle every time the
\gls{Task
}-specification is
33 Another
\gls{EDSL
} designed to generate low-level high-assurance programs is
34 called
\gls{Ivory
} and uses
\gls{Haskell
} as a host language
%
35 ~
\cite{elliott_guilt_2015
}. The language uses the
\gls{Haskell
} type-system to
36 make unsafe languages type safe. For example,
\gls{Ivory
} has been used in the
37 automotive industry to program parts of an autopilot
%
38 ~
\cite{pike_programming_2014
}~
\cite{hickey_building_2014
}.
\Gls{Ivory
}'s syntax
39 is deeply embedded but the type system is shallowly embedded. This requires
40 several
\gls{Haskell
} extensions that offer dependent type constructions. The
41 process of compiling an
\gls{Ivory
} program happens in stages. The embedded
42 code is transformed into an
\gls{AST
} that is sent to a backend. In the new
43 system, the
\gls{mTask
}-
\gls{EDSL
} transforms the embedded code during
44 compile-time directly into the backend which is often a state transformer that
45 will execute on runtime.