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theory pairs = Main:;
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text{*
HOL also has pairs: \isa{($a@1$,$a@2$)} is of type $\tau@1$
\indexboldpos{\isasymtimes}{$IsaFun} $\tau@2$ provided each $a@i$ is of type
$\tau@i$. The components of a pair are extracted by @{term"fst"} and
@{term"snd"}: \isa{fst($x$,$y$) = $x$} and \isa{snd($x$,$y$) = $y$}. Tuples
are simulated by pairs nested to the right: \isa{($a@1$,$a@2$,$a@3$)} stands
for \isa{($a@1$,($a@2$,$a@3$))} and $\tau@1 \times \tau@2 \times \tau@3$ for
$\tau@1 \times (\tau@2 \times \tau@3)$. Therefore we have
\isa{fst(snd($a@1$,$a@2$,$a@3$)) = $a@2$}.
It is possible to use (nested) tuples as patterns in abstractions, for
example \isa{\isasymlambda(x,y,z).x+y+z} and
\isa{\isasymlambda((x,y),z).x+y+z}.
In addition to explicit $\lambda$-abstractions, tuple patterns can be used in
most variable binding constructs. Typical examples are
\begin{quote}
@{term"let (x,y) = f z in (y,x)"}\\
@{term"case xs of [] => 0 | (x,y)#zs => x+y"}
\end{quote}
Further important examples are quantifiers and sets (see~\S\ref{quant-pats}).
*}
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end
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