--- a/doc-src/IsarAdvanced/Codegen/Thy/document/Adaption.tex Mon Mar 02 16:58:39 2009 +0100
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-\begin{isabellebody}%
-\def\isabellecontext{Adaption}%
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-\ Adaption\isanewline
-\isakeyword{imports}\ Setup\isanewline
-\isakeyword{begin}%
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-\ {\isacharverbatimopen}\ Code{\isacharunderscore}Target{\isachardot}extend{\isacharunderscore}target\ {\isacharparenleft}{\isachardoublequote}{\isasymSML}{\isachardoublequote}{\isacharcomma}\ {\isacharparenleft}{\isachardoublequote}SML{\isachardoublequote}{\isacharcomma}\ K\ I{\isacharparenright}{\isacharparenright}\ {\isacharverbatimclose}%
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-\isamarkupsection{Adaption to target languages \label{sec:adaption}%
-}
-\isamarkuptrue%
-%
-\isamarkupsubsection{Adapting code generation%
-}
-\isamarkuptrue%
-%
-\begin{isamarkuptext}%
-The aspects of code generation introduced so far have two aspects
- in common:
-
- \begin{itemize}
- \item They act uniformly, without reference to a specific
- target language.
- \item They are \emph{safe} in the sense that as long as you trust
- the code generator meta theory and implementation, you cannot
- produce programs that yield results which are not derivable
- in the logic.
- \end{itemize}
-
- \noindent In this section we will introduce means to \emph{adapt} the serialiser
- to a specific target language, i.e.~to print program fragments
- in a way which accommodates \qt{already existing} ingredients of
- a target language environment, for three reasons:
-
- \begin{itemize}
- \item improving readability and aesthetics of generated code
- \item gaining efficiency
- \item interface with language parts which have no direct counterpart
- in \isa{HOL} (say, imperative data structures)
- \end{itemize}
-
- \noindent Generally, you should avoid using those features yourself
- \emph{at any cost}:
-
- \begin{itemize}
- \item The safe configuration methods act uniformly on every target language,
- whereas for adaption you have to treat each target language separate.
- \item Application is extremely tedious since there is no abstraction
- which would allow for a static check, making it easy to produce garbage.
- \item More or less subtle errors can be introduced unconsciously.
- \end{itemize}
-
- \noindent However, even if you ought refrain from setting up adaption
- yourself, already the \isa{HOL} comes with some reasonable default
- adaptions (say, using target language list syntax). There also some
- common adaption cases which you can setup by importing particular
- library theories. In order to understand these, we provide some clues here;
- these however are not supposed to replace a careful study of the sources.%
-\end{isamarkuptext}%
-\isamarkuptrue%
-%
-\isamarkupsubsection{The adaption principle%
-}
-\isamarkuptrue%
-%
-\begin{isamarkuptext}%
-The following figure illustrates what \qt{adaption} is conceptually
- supposed to be:
-
- \begin{figure}[here]
- \begin{tikzpicture}[scale = 0.5]
- \tikzstyle water=[color = blue, thick]
- \tikzstyle ice=[color = black, very thick, cap = round, join = round, fill = white]
- \tikzstyle process=[color = green, semithick, ->]
- \tikzstyle adaption=[color = red, semithick, ->]
- \tikzstyle target=[color = black]
- \foreach \x in {0, ..., 24}
- \draw[style=water] (\x, 0.25) sin + (0.25, 0.25) cos + (0.25, -0.25) sin
- + (0.25, -0.25) cos + (0.25, 0.25);
- \draw[style=ice] (1, 0) --
- (3, 6) node[above, fill=white] {logic} -- (5, 0) -- cycle;
- \draw[style=ice] (9, 0) --
- (11, 6) node[above, fill=white] {intermediate language} -- (13, 0) -- cycle;
- \draw[style=ice] (15, -6) --
- (19, 6) node[above, fill=white] {target language} -- (23, -6) -- cycle;
- \draw[style=process]
- (3.5, 3) .. controls (7, 5) .. node[fill=white] {translation} (10.5, 3);
- \draw[style=process]
- (11.5, 3) .. controls (15, 5) .. node[fill=white] (serialisation) {serialisation} (18.5, 3);
- \node (adaption) at (11, -2) [style=adaption] {adaption};
- \node at (19, 3) [rotate=90] {generated};
- \node at (19.5, -5) {language};
- \node at (19.5, -3) {library};
- \node (includes) at (19.5, -1) {includes};
- \node (reserved) at (16.5, -3) [rotate=72] {reserved}; % proper 71.57
- \draw[style=process]
- (includes) -- (serialisation);
- \draw[style=process]
- (reserved) -- (serialisation);
- \draw[style=adaption]
- (adaption) -- (serialisation);
- \draw[style=adaption]
- (adaption) -- (includes);
- \draw[style=adaption]
- (adaption) -- (reserved);
- \end{tikzpicture}
- \caption{The adaption principle}
- \label{fig:adaption}
- \end{figure}
-
- \noindent In the tame view, code generation acts as broker between
- \isa{logic}, \isa{intermediate\ language} and
- \isa{target\ language} by means of \isa{translation} and
- \isa{serialisation}; for the latter, the serialiser has to observe
- the structure of the \isa{language} itself plus some \isa{reserved}
- keywords which have to be avoided for generated code.
- However, if you consider \isa{adaption} mechanisms, the code generated
- by the serializer is just the tip of the iceberg:
-
- \begin{itemize}
- \item \isa{serialisation} can be \emph{parametrised} such that
- logical entities are mapped to target-specific ones
- (e.g. target-specific list syntax,
- see also \secref{sec:adaption_mechanisms})
- \item Such parametrisations can involve references to a
- target-specific standard \isa{library} (e.g. using
- the \isa{Haskell} \verb|Maybe| type instead
- of the \isa{HOL} \isa{option} type);
- if such are used, the corresponding identifiers
- (in our example, \verb|Maybe|, \verb|Nothing|
- and \verb|Just|) also have to be considered \isa{reserved}.
- \item Even more, the user can enrich the library of the
- target-language by providing code snippets
- (\qt{\isa{includes}}) which are prepended to
- any generated code (see \secref{sec:include}); this typically
- also involves further \isa{reserved} identifiers.
- \end{itemize}
-
- \noindent As figure \ref{fig:adaption} illustrates, all these adaption mechanisms
- have to act consistently; it is at the discretion of the user
- to take care for this.%
-\end{isamarkuptext}%
-\isamarkuptrue%
-%
-\isamarkupsubsection{Common adaption patterns%
-}
-\isamarkuptrue%
-%
-\begin{isamarkuptext}%
-The \hyperlink{theory.HOL}{\mbox{\isa{HOL}}} \hyperlink{theory.Main}{\mbox{\isa{Main}}} theory already provides a code
- generator setup
- which should be suitable for most applications. Common extensions
- and modifications are available by certain theories of the \isa{HOL}
- library; beside being useful in applications, they may serve
- as a tutorial for customising the code generator setup (see below
- \secref{sec:adaption_mechanisms}).
-
- \begin{description}
-
- \item[\hyperlink{theory.Code-Integer}{\mbox{\isa{Code{\isacharunderscore}Integer}}}] represents \isa{HOL} integers by big
- integer literals in target languages.
- \item[\hyperlink{theory.Code-Char}{\mbox{\isa{Code{\isacharunderscore}Char}}}] represents \isa{HOL} characters by
- character literals in target languages.
- \item[\hyperlink{theory.Code-Char-chr}{\mbox{\isa{Code{\isacharunderscore}Char{\isacharunderscore}chr}}}] like \isa{Code{\isacharunderscore}Char},
- but also offers treatment of character codes; includes
- \hyperlink{theory.Code-Char}{\mbox{\isa{Code{\isacharunderscore}Char}}}.
- \item[\hyperlink{theory.Efficient-Nat}{\mbox{\isa{Efficient{\isacharunderscore}Nat}}}] \label{eff_nat} implements natural numbers by integers,
- which in general will result in higher efficiency; pattern
- matching with \isa{{\isadigit{0}}} / \isa{Suc}
- is eliminated; includes \hyperlink{theory.Code-Integer}{\mbox{\isa{Code{\isacharunderscore}Integer}}}
- and \hyperlink{theory.Code-Index}{\mbox{\isa{Code{\isacharunderscore}Index}}}.
- \item[\hyperlink{theory.Code-Index}{\mbox{\isa{Code{\isacharunderscore}Index}}}] provides an additional datatype
- \isa{index} which is mapped to target-language built-in integers.
- Useful for code setups which involve e.g. indexing of
- target-language arrays.
- \item[\hyperlink{theory.Code-Message}{\mbox{\isa{Code{\isacharunderscore}Message}}}] provides an additional datatype
- \isa{message{\isacharunderscore}string} which is isomorphic to strings;
- \isa{message{\isacharunderscore}string}s are mapped to target-language strings.
- Useful for code setups which involve e.g. printing (error) messages.
-
- \end{description}
-
- \begin{warn}
- When importing any of these theories, they should form the last
- items in an import list. Since these theories adapt the
- code generator setup in a non-conservative fashion,
- strange effects may occur otherwise.
- \end{warn}%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isamarkupsubsection{Parametrising serialisation \label{sec:adaption_mechanisms}%
-}
-\isamarkuptrue%
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-\begin{isamarkuptext}%
-Consider the following function and its corresponding
- SML code:%
-\end{isamarkuptext}%
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-\ in{\isacharunderscore}interval\ {\isacharcolon}{\isacharcolon}\ {\isachardoublequoteopen}nat\ {\isasymtimes}\ nat\ {\isasymRightarrow}\ nat\ {\isasymRightarrow}\ bool{\isachardoublequoteclose}\ \isakeyword{where}\isanewline
-\ \ {\isachardoublequoteopen}in{\isacharunderscore}interval\ {\isacharparenleft}k{\isacharcomma}\ l{\isacharparenright}\ n\ {\isasymlongleftrightarrow}\ k\ {\isasymle}\ n\ {\isasymand}\ n\ {\isasymle}\ l{\isachardoublequoteclose}%
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-\begin{isamarkuptext}%
-\isatypewriter%
-\noindent%
-\hspace*{0pt}structure Example = \\
-\hspace*{0pt}struct\\
-\hspace*{0pt}\\
-\hspace*{0pt}datatype nat = Zero{\char95}nat | Suc of nat;\\
-\hspace*{0pt}\\
-\hspace*{0pt}datatype boola = True | False;\\
-\hspace*{0pt}\\
-\hspace*{0pt}fun anda x True = x\\
-\hspace*{0pt} ~| anda x False = False\\
-\hspace*{0pt} ~| anda True x = x\\
-\hspace*{0pt} ~| anda False x = False;\\
-\hspace*{0pt}\\
-\hspace*{0pt}fun less{\char95}nat m (Suc n) = less{\char95}eq{\char95}nat m n\\
-\hspace*{0pt} ~| less{\char95}nat n Zero{\char95}nat = False\\
-\hspace*{0pt}and less{\char95}eq{\char95}nat (Suc m) n = less{\char95}nat m n\\
-\hspace*{0pt} ~| less{\char95}eq{\char95}nat Zero{\char95}nat n = True;\\
-\hspace*{0pt}\\
-\hspace*{0pt}fun in{\char95}interval (k,~l) n = anda (less{\char95}eq{\char95}nat k n) (less{\char95}eq{\char95}nat n l);\\
-\hspace*{0pt}\\
-\hspace*{0pt}end;~(*struct Example*)%
-\end{isamarkuptext}%
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-\begin{isamarkuptext}%
-\noindent Though this is correct code, it is a little bit unsatisfactory:
- boolean values and operators are materialised as distinguished
- entities with have nothing to do with the SML-built-in notion
- of \qt{bool}. This results in less readable code;
- additionally, eager evaluation may cause programs to
- loop or break which would perfectly terminate when
- the existing SML \verb|bool| would be used. To map
- the HOL \isa{bool} on SML \verb|bool|, we may use
- \qn{custom serialisations}:%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isacommand{code{\isacharunderscore}type}\isamarkupfalse%
-\ bool\isanewline
-\ \ {\isacharparenleft}SML\ {\isachardoublequoteopen}bool{\isachardoublequoteclose}{\isacharparenright}\isanewline
-\isacommand{code{\isacharunderscore}const}\isamarkupfalse%
-\ True\ \isakeyword{and}\ False\ \isakeyword{and}\ {\isachardoublequoteopen}op\ {\isasymand}{\isachardoublequoteclose}\isanewline
-\ \ {\isacharparenleft}SML\ {\isachardoublequoteopen}true{\isachardoublequoteclose}\ \isakeyword{and}\ {\isachardoublequoteopen}false{\isachardoublequoteclose}\ \isakeyword{and}\ {\isachardoublequoteopen}{\isacharunderscore}\ andalso\ {\isacharunderscore}{\isachardoublequoteclose}{\isacharparenright}%
-\endisatagquotett
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-\begin{isamarkuptext}%
-\noindent The \hyperlink{command.code-type}{\mbox{\isa{\isacommand{code{\isacharunderscore}type}}}} command takes a type constructor
- as arguments together with a list of custom serialisations.
- Each custom serialisation starts with a target language
- identifier followed by an expression, which during
- code serialisation is inserted whenever the type constructor
- would occur. For constants, \hyperlink{command.code-const}{\mbox{\isa{\isacommand{code{\isacharunderscore}const}}}} implements
- the corresponding mechanism. Each ``\verb|_|'' in
- a serialisation expression is treated as a placeholder
- for the type constructor's (the constant's) arguments.%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\begin{isamarkuptext}%
-\isatypewriter%
-\noindent%
-\hspace*{0pt}structure Example = \\
-\hspace*{0pt}struct\\
-\hspace*{0pt}\\
-\hspace*{0pt}datatype nat = Zero{\char95}nat | Suc of nat;\\
-\hspace*{0pt}\\
-\hspace*{0pt}fun less{\char95}nat m (Suc n) = less{\char95}eq{\char95}nat m n\\
-\hspace*{0pt} ~| less{\char95}nat n Zero{\char95}nat = false\\
-\hspace*{0pt}and less{\char95}eq{\char95}nat (Suc m) n = less{\char95}nat m n\\
-\hspace*{0pt} ~| less{\char95}eq{\char95}nat Zero{\char95}nat n = true;\\
-\hspace*{0pt}\\
-\hspace*{0pt}fun in{\char95}interval (k,~l) n = (less{\char95}eq{\char95}nat k n) andalso (less{\char95}eq{\char95}nat n l);\\
-\hspace*{0pt}\\
-\hspace*{0pt}end;~(*struct Example*)%
-\end{isamarkuptext}%
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-\begin{isamarkuptext}%
-\noindent This still is not perfect: the parentheses
- around the \qt{andalso} expression are superfluous.
- Though the serialiser
- by no means attempts to imitate the rich Isabelle syntax
- framework, it provides some common idioms, notably
- associative infixes with precedences which may be used here:%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isacommand{code{\isacharunderscore}const}\isamarkupfalse%
-\ {\isachardoublequoteopen}op\ {\isasymand}{\isachardoublequoteclose}\isanewline
-\ \ {\isacharparenleft}SML\ \isakeyword{infixl}\ {\isadigit{1}}\ {\isachardoublequoteopen}andalso{\isachardoublequoteclose}{\isacharparenright}%
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-\begin{isamarkuptext}%
-\isatypewriter%
-\noindent%
-\hspace*{0pt}structure Example = \\
-\hspace*{0pt}struct\\
-\hspace*{0pt}\\
-\hspace*{0pt}datatype nat = Zero{\char95}nat | Suc of nat;\\
-\hspace*{0pt}\\
-\hspace*{0pt}fun less{\char95}nat m (Suc n) = less{\char95}eq{\char95}nat m n\\
-\hspace*{0pt} ~| less{\char95}nat n Zero{\char95}nat = false\\
-\hspace*{0pt}and less{\char95}eq{\char95}nat (Suc m) n = less{\char95}nat m n\\
-\hspace*{0pt} ~| less{\char95}eq{\char95}nat Zero{\char95}nat n = true;\\
-\hspace*{0pt}\\
-\hspace*{0pt}fun in{\char95}interval (k,~l) n = less{\char95}eq{\char95}nat k n andalso less{\char95}eq{\char95}nat n l;\\
-\hspace*{0pt}\\
-\hspace*{0pt}end;~(*struct Example*)%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\begin{isamarkuptext}%
-\noindent The attentive reader may ask how we assert that no generated
- code will accidentally overwrite. For this reason the serialiser has
- an internal table of identifiers which have to be avoided to be used
- for new declarations. Initially, this table typically contains the
- keywords of the target language. It can be extended manually, thus avoiding
- accidental overwrites, using the \hyperlink{command.code-reserved}{\mbox{\isa{\isacommand{code{\isacharunderscore}reserved}}}} command:%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isacommand{code{\isacharunderscore}reserved}\isamarkupfalse%
-\ {\isachardoublequoteopen}{\isasymSML}{\isachardoublequoteclose}\ bool\ true\ false\ andalso%
-\endisatagquote
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-\begin{isamarkuptext}%
-\noindent Next, we try to map HOL pairs to SML pairs, using the
- infix ``\verb|*|'' type constructor and parentheses:%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isacommand{code{\isacharunderscore}type}\isamarkupfalse%
-\ {\isacharasterisk}\isanewline
-\ \ {\isacharparenleft}SML\ \isakeyword{infix}\ {\isadigit{2}}\ {\isachardoublequoteopen}{\isacharasterisk}{\isachardoublequoteclose}{\isacharparenright}\isanewline
-\isacommand{code{\isacharunderscore}const}\isamarkupfalse%
-\ Pair\isanewline
-\ \ {\isacharparenleft}SML\ {\isachardoublequoteopen}{\isacharbang}{\isacharparenleft}{\isacharparenleft}{\isacharunderscore}{\isacharparenright}{\isacharcomma}{\isacharslash}\ {\isacharparenleft}{\isacharunderscore}{\isacharparenright}{\isacharparenright}{\isachardoublequoteclose}{\isacharparenright}%
-\endisatagquotett
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-\begin{isamarkuptext}%
-\noindent The initial bang ``\verb|!|'' tells the serialiser
- never to put
- parentheses around the whole expression (they are already present),
- while the parentheses around argument place holders
- tell not to put parentheses around the arguments.
- The slash ``\verb|/|'' (followed by arbitrary white space)
- inserts a space which may be used as a break if necessary
- during pretty printing.
-
- These examples give a glimpse what mechanisms
- custom serialisations provide; however their usage
- requires careful thinking in order not to introduce
- inconsistencies -- or, in other words:
- custom serialisations are completely axiomatic.
-
- A further noteworthy details is that any special
- character in a custom serialisation may be quoted
- using ``\verb|'|''; thus, in
- ``\verb|fn '_ => _|'' the first
- ``\verb|_|'' is a proper underscore while the
- second ``\verb|_|'' is a placeholder.%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isamarkupsubsection{\isa{Haskell} serialisation%
-}
-\isamarkuptrue%
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-\begin{isamarkuptext}%
-For convenience, the default
- \isa{HOL} setup for \isa{Haskell} maps the \isa{eq} class to
- its counterpart in \isa{Haskell}, giving custom serialisations
- for the class \isa{eq} (by command \hyperlink{command.code-class}{\mbox{\isa{\isacommand{code{\isacharunderscore}class}}}}) and its operation
- \isa{eq{\isacharunderscore}class{\isachardot}eq}%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isadelimquotett
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-\isacommand{code{\isacharunderscore}class}\isamarkupfalse%
-\ eq\isanewline
-\ \ {\isacharparenleft}Haskell\ {\isachardoublequoteopen}Eq{\isachardoublequoteclose}{\isacharparenright}\isanewline
-\isanewline
-\isacommand{code{\isacharunderscore}const}\isamarkupfalse%
-\ {\isachardoublequoteopen}op\ {\isacharequal}{\isachardoublequoteclose}\isanewline
-\ \ {\isacharparenleft}Haskell\ \isakeyword{infixl}\ {\isadigit{4}}\ {\isachardoublequoteopen}{\isacharequal}{\isacharequal}{\isachardoublequoteclose}{\isacharparenright}%
-\endisatagquotett
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-\begin{isamarkuptext}%
-\noindent A problem now occurs whenever a type which
- is an instance of \isa{eq} in \isa{HOL} is mapped
- on a \isa{Haskell}-built-in type which is also an instance
- of \isa{Haskell} \isa{Eq}:%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isadelimquote
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-\isatagquote
-\isacommand{typedecl}\isamarkupfalse%
-\ bar\isanewline
-\isanewline
-\isacommand{instantiation}\isamarkupfalse%
-\ bar\ {\isacharcolon}{\isacharcolon}\ eq\isanewline
-\isakeyword{begin}\isanewline
-\isanewline
-\isacommand{definition}\isamarkupfalse%
-\ {\isachardoublequoteopen}eq{\isacharunderscore}class{\isachardot}eq\ {\isacharparenleft}x{\isasymColon}bar{\isacharparenright}\ y\ {\isasymlongleftrightarrow}\ x\ {\isacharequal}\ y{\isachardoublequoteclose}\isanewline
-\isanewline
-\isacommand{instance}\isamarkupfalse%
-\ \isacommand{by}\isamarkupfalse%
-\ default\ {\isacharparenleft}simp\ add{\isacharcolon}\ eq{\isacharunderscore}bar{\isacharunderscore}def{\isacharparenright}\isanewline
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-\isacommand{code{\isacharunderscore}type}\isamarkupfalse%
-\ bar\isanewline
-\ \ {\isacharparenleft}Haskell\ {\isachardoublequoteopen}Integer{\isachardoublequoteclose}{\isacharparenright}%
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-\begin{isamarkuptext}%
-\noindent The code generator would produce
- an additional instance, which of course is rejected by the \isa{Haskell}
- compiler.
- To suppress this additional instance, use
- \isa{code{\isacharunderscore}instance}:%
-\end{isamarkuptext}%
-\isamarkuptrue%
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-\isacommand{code{\isacharunderscore}instance}\isamarkupfalse%
-\ bar\ {\isacharcolon}{\isacharcolon}\ eq\isanewline
-\ \ {\isacharparenleft}Haskell\ {\isacharminus}{\isacharparenright}%
-\endisatagquotett
-{\isafoldquotett}%
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-\isamarkupsubsection{Enhancing the target language context \label{sec:include}%
-}
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-\begin{isamarkuptext}%
-In rare cases it is necessary to \emph{enrich} the context of a
- target language; this is accomplished using the \hyperlink{command.code-include}{\mbox{\isa{\isacommand{code{\isacharunderscore}include}}}}
- command:%
-\end{isamarkuptext}%
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-\isacommand{code{\isacharunderscore}include}\isamarkupfalse%
-\ Haskell\ {\isachardoublequoteopen}Errno{\isachardoublequoteclose}\isanewline
-{\isacharverbatimopen}errno\ i\ {\isacharequal}\ error\ {\isacharparenleft}{\isachardoublequote}Error\ number{\isacharcolon}\ {\isachardoublequote}\ {\isacharplus}{\isacharplus}\ show\ i{\isacharparenright}{\isacharverbatimclose}\isanewline
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-\ Haskell\ Errno%
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-\begin{isamarkuptext}%
-\noindent Such named \isa{include}s are then prepended to every generated code.
- Inspect such code in order to find out how \hyperlink{command.code-include}{\mbox{\isa{\isacommand{code{\isacharunderscore}include}}}} behaves
- with respect to a particular target language.%
-\end{isamarkuptext}%
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