--- a/CookBook/Package/Ind_Intro.thy	Fri Feb 13 01:05:09 2009 +0000
+++ b/CookBook/Package/Ind_Intro.thy	Fri Feb 13 01:05:31 2009 +0000
@@ -15,89 +15,31 @@
   \end{flushright}
 
   \medskip
-  HOL is based on just a few primitive constants, like equality, implication,
-  and the description operator, whose properties are described as axioms. All
-  other concepts, such as inductive predicates, datatypes, or recursive
-  functions are defined in terms of those constants, and the desired
-  properties, for example induction theorems, or recursion equations are
-  derived from the definitions by a formal proof. Since it would be very
-  tedious for a user to define complex inductive predicates or datatypes ``by
-  hand'' just using the primitive operators of higher order logic,
-  Isabelle/HOL already contains a number of packages automating such
-  work. Thanks to those packages, the user can give a high-level
-  specification, like a list of introduction rules or constructors, and the
-  package then does all the low-level definitions and proofs behind the
-  scenes. In this chapter we explain how such a package can be implemented.
-
-
-  %The packages are written in Standard ML, the implementation
-  %language of Isabelle, and can be invoked by the user from within theory documents
-  %written in the Isabelle/Isar language via specific commands. Most of the time,
-  %when using Isabelle for applications, users do not have to worry about the inner
-  %workings of packages, since they can just use the packages that are already part
-  %of the Isabelle distribution. However, when developing a general theory that is
-  %intended to be applied by other users, one may need to write a new package from
-  %scratch. Recent examples of such packages include the verification environment
-  %for sequential imperative programs by Schirmer \cite{Schirmer-LPAR04}, the
-  %package for defining general recursive functions by Krauss \cite{Krauss-IJCAR06},
-  %as well as the nominal datatype package by Berghofer and Urban \cite{Urban-Berghofer06}.
+  HOL is based on just a few primitive constants, like equality and
+  implication, whose properties are described by a few axioms. All other
+  concepts, such as inductive predicates, datatypes, or recursive functions
+  are defined in terms of those constants, and the desired properties, for
+  example induction theorems, or recursion equations are derived from the
+  definitions by a formal proof. Since it would be very tedious for a user to
+  define complex inductive predicates or datatypes ``by hand'' just using the
+  primitive operators of higher order logic, packages have been implemented
+  automating such work. Thanks to those packages, the user can give a
+  high-level specification, like a list of introduction rules or constructors,
+  and the package then does all the low-level definitions and proofs behind
+  the scenes. In this chapter we explain how such a package can be
+  implemented.
 
-  %The scientific value of implementing a package should not be underestimated:
-  %it is often more than just the automation of long-established scientific
-  %results. Of course, a carefully-developed theory on paper is indispensable
-  %as a basis. However, without an implementation, such a theory will only be of
-  %very limited practical use, since only an implementation enables other users
-  %to apply the theory on a larger scale without too much effort. Moreover,
-  %implementing a package is a bit like formalizing a paper proof in a theorem
-  %prover. In the literature, there are many examples of paper proofs that
-  %turned out to be incomplete or even faulty, and doing a formalization is
-  %a good way of uncovering such errors and ensuring that a proof is really
-  %correct. The same applies to the theory underlying definitional packages.
-  %For example, the general form of some complicated induction rules for nominal
-  %datatypes turned out to be quite hard to get right on the first try, so
-  %an implementation is an excellent way to find out whether the rules really
-  %work in practice.
-
-  Writing a package is a particularly difficult task for users that are new
-  to Isabelle, since its programming interface consists of thousands of functions.
-  Rather than just listing all those functions, we give a step-by-step tutorial
-  for writing a package, using an example that is still simple enough to be
-  easily understandable, but at the same time sufficiently complex to demonstrate
-  enough of Isabelle's interesting features. As a running example, we have
-  chosen a rather simple package for defining inductive predicates. To keep
-  things simple, we will not use the general Knaster-Tarski fixpoint
-  theorem on complete lattices, which forms the basis of Isabelle's standard
-  inductive definition package originally due to Paulson \cite{Paulson-ind-defs}.
-  Instead, we will use a simpler \emph{impredicative} (i.e.\ involving
-  quantification on predicate variables) encoding of inductive predicates
-  suggested by Melham \cite{Melham:1992:PIR}. Due to its simplicity, this
-  package will necessarily have a reduced functionality. It does neither
-  support introduction rules involving arbitrary monotone operators, nor does
-  it prove case analysis (or inversion) rules. Moreover, it only proves a weaker
-  form of the rule induction theorem.
-
-  %Reading this article does not require any prior knowledge of Isabelle's programming
-  %interface. However, we assume the reader to already be familiar with writing
-  %proofs in Isabelle/HOL using the Isar language. For further information on
-  %this topic, consult the book by Nipkow, Paulson, and Wenzel
-  %\cite{isa-tutorial}. Moreover, in order to understand the pieces of
-  %code given in this tutorial, some familiarity with the basic concepts of the Standard
-  %ML programming language, as described for example in the textbook by Paulson
-  %\cite{paulson-ml2}, is required as well.
-
-  %The rest of this chapter is structured as follows. In \S\ref{sec:ind-examples},
-  %we will illustrate the ``manual'' definition of inductive predicates using
-  %some examples. Starting from these examples, we will describe in
-  %\S\ref{sec:ind-general-method} how the construction works in general.
-  %The following sections are then dedicated to the implementation of a
-  %package that carries out the construction of such inductive predicates.
-  %First of all, a parser for a high-level notation for specifying inductive
-  %predicates via a list of introduction rules is developed in \S\ref{sec:ind-interface}.
-  %Having parsed the specification, a suitable primitive definition must be
-  %added to the theory, which will be explained in \S\ref{sec:ind-definition}.
-  %Finally, \S\ref{sec:ind-proofs} will focus on methods for proving introduction
-  %and induction rules from the definitions introduced in \S\ref{sec:ind-definition}.
-
+  As a running example, we have chosen a rather simple package for defining
+  inductive predicates. To keep things simple, we will not use the general
+  Knaster-Tarski fixpoint theorem on complete lattices, which forms the basis
+  of Isabelle's standard inductive definition package.  Instead, we will use a
+  simpler \emph{impredicative} (i.e.\ involving quantification on predicate
+  variables) encoding of inductive predicates suggested by Melham
+  \cite{Melham:1992:PIR}. Due to its simplicity, this package will necessarily
+  have a reduced functionality. It does neither support introduction rules
+  involving arbitrary monotone operators, nor does it prove case analysis (or
+  inversion) rules. Moreover, it only proves a weaker form of the rule
+  induction theorem.
 *}
 
 end