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-%\documentstyle[11pt,../tools/coq-tex/coq]{article}
-%\input{title}
- 
-%\include{macros}
-%\begin{document}
-
-%\coverpage{Co-inductive types in Coq}{Eduardo Gim\'enez}
-\chapter[Co-inductive types in Coq]{Co-inductive types in Coq\label{Coinductives}}
-
-%\begin{abstract}
-{\it Co-inductive} types are types whose elements may not be well-founded.
-A formal study of the Calculus of Constructions extended by 
-co-inductive types has been presented
-in \cite{Gim94}. It is based on the notion of
-{\it guarded definitions} introduced by Th. Coquand
-in \cite{Coquand93}. The implementation is by E. Gim\'enez.
-%\end{abstract}
-
-\section{A short introduction to co-inductive types}
-
-We assume that the reader is rather familiar with inductive types.
-These types are characterized by their {\it constructors}, which can be 
-regarded as the basic methods from which the elements 
-of the type can be built up. It is implicit in the definition 
-of an inductive type that 
-its elements are the result of a {\it finite} number of 
-applications of its constructors. Co-inductive types arise from 
-relaxing this implicit condition and admitting that an element of
-the type can also be introduced by a non-ending (but effective) process 
-of construction defined in terms of the basic methods which characterize the
-type. So we could think in the wider notion of types defined by
-constructors (let us call them {\it recursive types}) and classify
-them into inductive and co-inductive ones, depending on whether or not
-we consider non-ending methods as admissible for constructing elements
-of the type. Note that in both cases we obtain a ``closed type'', all whose 
-elements are pre-determined in advance (by the constructors). When we
-know that $a$ is an element of a recursive type (no matter if it is 
-inductive or co-inductive) what we know is that it is the result of applying
-one of the basic forms of construction allowed for the type.
-So the more primitive way of eliminating an element of a recursive type is 
-by case analysis, i.e. by considering through which constructor it could have
-been introduced. In the case of inductive sets, the additional knowledge that
-constructors can be applied only a finite number of times provide
-us with a more powerful way of eliminating their elements, say,  
-the principle of
-induction. This principle is obviously not valid for co-inductive types,
-since it is just the expression of this extra knowledge attached to inductive 
-types.
-
-
-An example of a co-inductive type is the type of infinite sequences formed with
-elements of type $A$, or streams for shorter. In Coq, 
-it can be introduced using the \verb!CoInductive! command~:
-\begin{coq_example}
-CoInductive Stream (A:Set) : Set :=
-    cons : A -> Stream A -> Stream A.
-\end{coq_example}
-
-The syntax of this command is the same as the 
-command \verb!Inductive! (cf. section
-\ref{gal_Inductive_Definitions}).
-Definition of mutually coinductive types are possible.
-
-As was already said, there are not principles of 
-induction for co-inductive sets, the only way of eliminating these
-elements is by case analysis. 
-In the example of streams, this elimination principle can be
-used for instance to define the well known 
-destructors on streams $\hd : (\Str\;A)\rightarrow A$ 
-and $\tl: (\Str\;A)\rightarrow (\Str\;A)$  :
-\begin{coq_example}
-Section Destructors.
-Variable A : Set.
-Definition hd (x:Stream A) := match x with
-                              | cons a s => a
-                              end.
-Definition tl (x:Stream A) := match x with
-                              | cons a s => s
-                              end.
-\end{coq_example}
-\begin{coq_example*}
-End Destructors.
-\end{coq_example*}
-
-\subsection{Non-ending methods of construction}
-
-At this point the reader should have realized that we have left unexplained
-what is a ``non-ending but effective process of
-construction'' of a stream. In the widest sense, a 
-method is a non-ending process of construction if we can eliminate the
-stream that it introduces, in other words, if we can reduce
-any case analysis on it. In this sense, the following ways of 
-introducing a stream are not acceptable. 
-\begin{center}
-$\zeros = (\cons\;\nat\;\nO\;(\tl\;\zeros))\;\;:\;\;(\Str\;\nat)$\\[12pt]
-$\filter\;(\cons\;A\;a\;s) = \si\;\;(P\;a)\;\;\alors\;\;(\cons\;A\;a\;(\filter\;s))\;\;\sinon\;\;(\filter\;s) )\;\;:\;\;(\Str\;A)$
-\end{center}
-\noindent The former it is not valid since the stream can not be eliminated 
-to obtain its tail. In the latter, a stream is naively defined as
-the result of erasing from another (arbitrary) stream 
-all the elements which does not verify a certain property $P$. This
-does not always makes sense, for example it does not when all the elements
-of the stream verify $P$, in which case we can not eliminate it to
-obtain its head\footnote{Note that there is no notion of ``the empty
-stream'', a stream is always infinite and build by a \texttt{cons}.}. 
-On the contrary, the following definitions are acceptable methods for
-constructing a stream~:
-\begin{center}
-$\zeros = (\cons\;\nat\;\nO\;\zeros)\;\;:\;\;(\Str\;\nat)\;\;\;(*)$\\[12pt]
-$(\from\;n) = (\cons\;\nat\;n\;(\from\;(\nS\;n)))\;:\;(\Str\;\nat)$\\[12pt]
-$\alter  = (\cons\;\bool\;\true\;(\cons\;\bool\;\false\;\alter))\;:\;(\Str\;\bool)$.
-\end{center}
-\noindent The first one introduces a stream containing all the natural numbers
-greater than a given one, and the second the stream which infinitely
-alternates the booleans true and false.
-
-In general it is not evident to realise when a definition can 
-be accepted or not. However, there is a class of definitions that
-can be easily recognised as being valid :  those 
-where (1) all the recursive calls of the method  are done 
-after having explicitly mentioned  which is (at least) the first constructor 
-to start building the element, and (2) no other 
-functions apart from constructors are applied to recursive calls. 
-This class of definitions is usually
-referred as {\it guarded-by-constructors} 
-definitions \cite{Coquand93,Gim94}. 
-The methods $\from$ 
-and $\alter$ are examples of definitions which are guarded by constructors.
-The definition of function $\filter$ is not, because there is no 
-constructor to guard 
-the recursive call in the {\it else} branch. Neither is the one of
-$\zeros$, since there is function applied to the recursive call
-which is not a constructor. However, there is a difference between 
-the definition of $\zeros$ and $\filter$. The former may be seen as a
-wrong way of characterising an object which makes sense, and it can
-be reformulated in an admissible way using the equation (*). On the contrary, 
-the definition of
-$\filter$ can not be patched, since is the idea itself 
-of traversing an infinite
-construction searching for an element whose existence is not ensured
-which does not make sense.
-
-
-
-Guarded definitions are exactly the kind of non-ending process of 
-construction which are allowed in Coq. The way of introducing 
-a guarded definition in Coq is using the special command 
-{\tt CoFixpoint}.  This command verifies that the definition introduces an
-element of a co-inductive type, and checks if it is guarded by constructors. 
-If we try to 
-introduce the definitions above, $\from$ and $\alter$ will be accepted,
-while $\zeros$ and $\filter$ will be rejected giving some explanation 
-about why.
-\begin{coq_example}
-CoFixpoint zeros  : Stream nat := cons nat 0%N (tl nat zeros).
-CoFixpoint zeros  : Stream nat := cons nat 0%N zeros.
-CoFixpoint from (n:nat) : Stream nat := cons nat n (from (S n)).
-\end{coq_example}
-
-As in the \verb!Fixpoint! command (see Section~\ref{Fixpoint}), it is possible 
-to introduce a block of mutually dependent methods. The general syntax
-for this case is :
-
-{\tt CoFixpoint {\ident$_1$}  :{\term$_1$} := {\term$_1'$}\\
-     with\\
-        \mbox{}\hspace{0.1cm} $\ldots$  \\
-        with {\ident$_m$}   : {\term$_m$} := {\term$_m'$}}
-
-
-\subsection{Non-ending methods and reduction}
-
-The elimination of a stream introduced by a \verb!CoFixpoint! definition 
-is done lazily, i.e. its definition can be expanded only when it occurs 
-at the head of an application which is the argument of a case expression. 
-Isolately it is considered as a canonical expression which 
-is completely evaluated. We can test this using the command \verb!compute! 
-to calculate the normal forms of some terms~:
-\begin{coq_example}
-Eval compute in (from 0).
-Eval compute in (hd nat (from 0)).
-Eval compute in (tl nat (from 0)).
-\end{coq_example}
-\noindent Thus, the equality 
-$(\from\;n)\equiv(\cons\;\nat\;n\;(\from \; (\S\;n)))$
-does not hold as definitional one. Nevertheless, it can be proved 
-as a propositional  equality, in the sense of Leibniz's equality. 
-The version {\it à la Leibniz} of the equality above follows from 
-a general lemma stating that eliminating and then re-introducing a stream
-yields the same stream.
-\begin{coq_example}
-Lemma unfold_Stream :
-   forall x:Stream nat, x = match x with
-                            | cons a s => cons nat a s
-                            end.
-\end{coq_example}
- 
-\noindent The proof is immediate from the analysis of 
-the possible cases for $x$, which transforms 
-the equality in a trivial one.
-
-\begin{coq_example}
-olddestruct x.
-trivial.
-\end{coq_example}
-\begin{coq_eval}
-Qed.
-\end{coq_eval}
-The application of this lemma to  $(\from\;n)$ puts this
-constant at the head of an application which is an  argument 
-of a case analysis, forcing its expansion. 
-We can test the type of this application using Coq's command \verb!Check!,
-which infers the type of a given term. 
-\begin{coq_example}
-Check (fun n:nat => unfold_Stream (from n)).
-\end{coq_example}
- \noindent  Actually, The elimination of $(\from\;n)$ has actually 
-no effect, because it is followed by a re-introduction, 
-so the type of this application is in fact 
-definitionally equal to the
-desired proposition. We can test this computing
-the normal form of the application above to see its type.  
-\begin{coq_example}
-Transparent unfold_Stream.
-Eval compute in (fun n:nat => unfold_Stream (from n)).
-\end{coq_example}
-
-
-\section{Reasoning about infinite objects}
-
-At a first sight, it might seem that 
-case analysis does not provide a very powerful way
-of reasoning about infinite objects. In fact, what we can prove about 
-an infinite object using
-only case analysis is just what we can prove unfolding its method
-of construction a finite number of times, which is not always
-enough. Consider for example the following method for appending 
-two streams~:
-\begin{coq_example}
-Variable A : Set.
-CoFixpoint conc (s1 s2:Stream A) : Stream A :=
-  cons A (hd A s1) (conc (tl A s1) s2).
-\end{coq_example}
-
-Informally speaking, we expect that for all pair of streams $s_1$ and $s_2$, 
-$(\conc\;s_1\;s_2)$ 
-defines the ``the same'' stream as $s_1$, 
-in the sense that if we would be able to unfold the definition 
-``up to the infinite'', we would obtain definitionally equal normal forms.
-However, no finite unfolding of the definitions gives definitionally 
-equal terms. Their equality can not be proved just using case analysis.
-
-
-The weakness of the elimination principle proposed for infinite objects
-contrast with the power provided by the inductive 
-elimination principles, but it is not actually surprising. It just means
-that we can not expect to prove very interesting things about infinite
-objects doing finite proofs. To take advantage of infinite objects we
-have to consider infinite proofs as well. For example,
-if we want to catch up the equality between $(\conc\;s_1\;s_2)$ and 
-$s_1$ we have to introduce first the type of the infinite proofs 
-of equality between streams. This is a 
-co-inductive type, whose elements are build up from a 
-unique constructor, requiring a proof of the equality of the
-heads of the streams, and an (infinite) proof of the equality 
-of their tails. 
-
-\begin{coq_example}
-CoInductive EqSt : Stream A -> Stream A -> Prop :=
-    eqst :
-      forall s1 s2:Stream A,
-        hd A s1 = hd A s2 -> EqSt (tl A s1) (tl A s2) -> EqSt s1 s2.
-\end{coq_example}
-\noindent Now the equality of both streams can be proved introducing
-an infinite object of type 
-
-\noindent $(\EqSt\;s_1\;(\conc\;s_1\;s_2))$ by a \verb!CoFixpoint!
-definition.
-\begin{coq_example}
-CoFixpoint eqproof (s1 s2:Stream A) : EqSt s1 (conc s1 s2) :=
-  eqst s1 (conc s1 s2) (refl_equal (hd A (conc s1 s2)))
-    (eqproof (tl A s1) s2).
-\end{coq_example}
-\begin{coq_eval}
-Reset eqproof.
-\end{coq_eval}
-\noindent Instead of giving an explicit definition, 
-we can use the proof editor of Coq to help us in 
-the construction of the proof.
-A tactic \verb!Cofix! allows to place a \verb!CoFixpoint! definition
-inside a proof. 
-This tactic introduces a variable in the context which has
-the same type as the current goal, and its application stands
-for a recursive call in the construction of the proof. If no name is
-specified for this variable, the name of the lemma  is chosen by
-default.
-%\pagebreak 
-
-\begin{coq_example}
-Lemma eqproof : forall s1 s2:Stream A, EqSt s1 (conc s1 s2).
-cofix.
-\end{coq_example}
-
-\noindent An easy (and wrong!) way of finishing the proof is just to apply the
-variable \verb!eqproof!, which has the same type as the goal. 
-
-\begin{coq_example}
-intros.
-apply eqproof.
-\end{coq_example}
-
-\noindent The ``proof'' constructed in this way 
-would correspond to the \verb!CoFixpoint! definition
-\begin{coq_example*}
-CoFixpoint eqproof  : forall s1 s2:Stream A, EqSt s1 (conc s1 s2) :=
-  eqproof.
-\end{coq_example*}
-
-\noindent which is obviously non-guarded. This means that 
-we can use the proof editor to
-define a method of construction which does not make sense. However,
-the system will never accept to include it as part of the theory,
-because the guard condition is always verified before saving the proof.
-
-\begin{coq_example}
-Qed.
-\end{coq_example}
-
-\noindent Thus, the user must be careful in the 
-construction of infinite proofs 
-with the tactic \verb!Cofix!. Remark that once it has been used 
-the application of tactics performing automatic proof search in 
-the environment (like for example \verb!Auto!)
-could introduce unguarded recursive calls in the proof.
-The command \verb!Guarded! allows to verify 
-if the guarded condition has been violated 
-during the construction of the proof. This command can be
-applied even if the proof term is not complete.
-
-
-
-\begin{coq_example}
-Restart.
-cofix.
-auto.
-Guarded.
-Undo.
-Guarded.
-\end{coq_example}
-
-\noindent To finish with this example, let us restart from the
-beginning and show how to construct an admissible proof~:
-
-\begin{coq_example} 
-Restart.
- cofix.
-\end{coq_example}
-
-%\pagebreak
-
-\begin{coq_example}
-intros.
-apply eqst.
-trivial.
-simpl.
-apply eqproof.
-Qed.
-\end{coq_example}
-
-
-\section{Experiments with co-inductive types}
-
-Some examples involving co-inductive types are available with
-the distributed system, in the theories library and in the contributions
-of the Lyon site. Here we present a short description of their contents~:
-\begin{itemize}
-\item Directory \verb!theories/LISTS! : 
-        \begin{itemize}
-                \item File \verb!Streams.v! : The type of streams and the 
-extensional equality between streams. 
-        \end{itemize}
-
-\item Directory \verb!contrib/Lyon/COINDUCTIVES! : 
-      \begin{itemize}
-                \item Directory \verb!ARITH! : An arithmetic where $\infty$
-is an explicit constant of the language instead of a metatheoretical notion.
-                \item Directory \verb!STREAM! :
-      \begin{itemize}
-                \item File \verb!Examples! :
-Several examples of guarded definitions, as well as 
-of frequent errors in the introduction of a stream. A different 
-way of defining the extensional equality of two streams,
-and the proofs showing that it is equivalent to the one in \verb!theories!.
-                \item File \verb!Alter.v! : An example showing how 
-an infinite proof introduced by a guarded definition can be also described
-using an operator of co-recursion \cite{Gimenez95b}.
-                 \end{itemize}
-\item Directory \verb!PROCESSES! : A proof of the alternating 
-bit protocol based on Pra\-sad's Calculus of Broadcasting Systems \cite{Prasad93},
-and the verification of an interpreter for this calculus. 
-See \cite{Gimenez95b} for a complete description about this development.
-        \end{itemize}
-\end{itemize}
-
-%\end{document}
-
-% $Id: RefMan-coi.tex 10421 2008-01-05 14:06:51Z herbelin $