\begin{document}
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-\chapter{\texorpdfstring{\glsentrytext{CLEAN}}{Clean} for \texorpdfstring{\glsentrytext{HASKELL}}{Haskell} programmers}%
+\chapter{Clean for Haskell programmers}%
\label{chp:clean_for_haskell_programmers}
This appendix is meant give people who are familiar with the \gls{FP} language \gls{HASKELL} a consise overview of the programming language \gls{CLEAN} and how it differs from \gls{HASKELL}.
Metadata about the types is available using the \cleaninline{of} syntax that gives the function access to metadata records, as can be seen in \cref{lst:generic_print} showing a generic print function. This abundance of metadata allows for very complex generic functions that near the expression level of template metaprogramming (see \cref{chp:first-class_datatypes,sec:ccodegen}).
\cleaninputlisting[language=Clean,firstline=4,label={lst:generic_print},caption={Generic print function}]{lst/generic_print.icl}
-\subsection{\texorpdfstring{\glsentrytext{GADT}}{GADT}s}
+\subsection{GADTs}
\Glspl{GADT} are enriched data types that allow the type instantiation of the constructor to be explicitly defined \citep{cheney_first-class_2003,hinze_fun_2003}.
While \glspl{GADT} are not natively supported in \gls{CLEAN}, they can be simulated using embedding-projection pairs or equivalence types \citep[\citesection{2.2}]{cheney_lightweight_2002}.
To illustrate this, \cref{lst:gadt_haskell} shows a \gls{GADT} in \gls{HASKELL}\requiresGHCmod{GADTs} that can be implemented as in \cref{lst:gadt_clean}.
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