--- a/doc-src/ZF/FOL.tex Wed Aug 20 11:12:48 2003 +0200
+++ b/doc-src/ZF/FOL.tex Wed Aug 20 13:05:22 2003 +0200
@@ -259,8 +259,9 @@
IntPr.fast_tac : int -> tactic
IntPr.best_tac : int -> tactic
\end{ttbox}
-Most of these belong to the structure \ML{} \texttt{IntPr} and resemble the
-tactics of Isabelle's classical reasoner. Note that you can use the
+Most of these belong to the structure \ML{} structure \texttt{IntPr} and resemble the
+tactics of Isabelle's classical reasoner. There are no corresponding
+Isar methods, but you can use the
\isa{tactic} method to call \ML{} tactics in an Isar script:
\begin{isabelle}
\isacommand{apply}\ (tactic\ {* IntPr.fast\_tac 1*})
@@ -350,12 +351,14 @@
\section{An intuitionistic example}
-Here is a session similar to one in {\em Logic and Computation}
-\cite[pages~222--3]{paulson87}. Isabelle treats quantifiers differently
-from {\sc lcf}-based theorem provers such as {\sc hol}.
+Here is a session similar to one in the book {\em Logic and Computation}
+\cite[pages~222--3]{paulson87}. It illustrates the treatment of
+quantifier reasoning, which is different in Isabelle than it is in
+{\sc lcf}-based theorem provers such as {\sc hol}.
-The theory header must specify that we are working in intuitionistic
-logic:
+The theory header specifies that we are working in intuitionistic
+logic by designating \isa{IFOL} rather than \isa{FOL} as the parent
+theory:
\begin{isabelle}
\isacommand{theory}\ IFOL\_examples\ =\ IFOL:
\end{isabelle}
@@ -524,7 +527,7 @@
$\ex{y}\all{x}P(y)\imp P(x)$. Informally, the theorem can be proved as
follows. Choose~$y$ such that~$\neg P(y)$, if such exists; otherwise
$\all{x}P(x)$ is true. Either way the theorem holds. First, we must
-work in a theory based on classical logic:
+work in a theory based on classical logic, the theory \isa{FOL}:
\begin{isabelle}
\isacommand{theory}\ FOL\_examples\ =\ FOL:
\end{isabelle}