%% THIS FILE IS COMMON TO ALL LOGIC MANUALS

 \chapter{Syntax definitions}

 The syntax of each logic is presented using a context-free grammar.

 These grammars obey the following conventions:

 \begin{itemize}

 \item identifiers denote nonterminal symbols

 \item \texttt{typewriter} font denotes terminal symbols

 \item parentheses $(\ldots)$ express grouping

 \item constructs followed by a Kleene star, such as $id^*$ and $(\ldots)^*$

 can be repeated~0 or more times 

 \item alternatives are separated by a vertical bar,~$|$

 \item the symbol for alphanumeric identifiers is~{\it id\/} 

 \item the symbol for scheme variables is~{\it var}

 \end{itemize}

 To reduce the number of nonterminals and grammar rules required, Isabelle's

 syntax module employs {\bf priorities},\index{priorities} or precedences.

 Each grammar rule is given by a mixfix declaration, which has a priority,

 and each argument place has a priority.  This general approach handles

 infix operators that associate either to the left or to the right, as well

 as prefix and binding operators.

 In a syntactically valid expression, an operator's arguments never involve

 an operator of lower priority unless brackets are used.  Consider

 first-order logic, where $\exists$ has lower priority than $\disj$,

 which has lower priority than $\conj$.  There, $P\conj Q \disj R$

 abbreviates $(P\conj Q) \disj R$ rather than $P\conj (Q\disj R)$.  Also,

 $\exists x.P\disj Q$ abbreviates $\exists x.(P\disj Q)$ rather than

 $(\exists x.P)\disj Q$.  Note especially that $P\disj(\exists x.Q)$

 becomes syntactically invalid if the brackets are removed.

 A {\bf binder} is a symbol associated with a constant of type

 $(\sigma\To\tau)\To\tau'$.  For instance, we may declare~$\forall$ as a binder

 for the constant~$All$, which has type $(\alpha\To o)\To o$.  This defines the

 syntax $\forall x.t$ to mean $All(\lambda x.t)$.  We can also write $\forall

 x@1\ldots x@m.t$ to abbreviate $\forall x@1.  \ldots \forall x@m.t$; this is

 possible for any constant provided that $\tau$ and $\tau'$ are the same type.

 The Hilbert description operator $\varepsilon x.P\,x$ has type $(\alpha\To

 bool)\To\alpha$ and normally binds only one variable.  

 ZF's bounded quantifier $\forall x\in A.P(x)$ cannot be declared as a

 binder because it has type $[i, i\To o]\To o$.  The syntax for binders allows

 type constraints on bound variables, as in

 \[ \forall (x{::}\alpha) \; (y{::}\beta) \; z{::}\gamma. Q(x,y,z) \]

 To avoid excess detail, the logic descriptions adopt a semi-formal style.

 Infix operators and binding operators are listed in separate tables, which

 include their priorities.  Grammar descriptions do not include numeric

 priorities; instead, the rules appear in order of decreasing priority.

 This should suffice for most purposes; for full details, please consult the

 actual syntax definitions in the {\tt.thy} files.

 Each nonterminal symbol is associated with some Isabelle type.  For

 example, the formulae of first-order logic have type~$o$.  Every

 Isabelle expression of type~$o$ is therefore a formula.  These include

 atomic formulae such as $P$, where $P$ is a variable of type~$o$, and more

 generally expressions such as $P(t,u)$, where $P$, $t$ and~$u$ have

 suitable types.  Therefore, `expression of type~$o$' is listed as a

 separate possibility in the grammar for formulae.