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author Adam Chlipala <adam@chlipala.net>
date Thu, 25 Aug 2011 11:46:56 -0400
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(* Copyright (c) 2008-2011, Adam Chlipala
 * 
 * This work is licensed under a
 * Creative Commons Attribution-Noncommercial-No Derivative Works 3.0
 * Unported License.
 * The license text is available at:
 *   http://creativecommons.org/licenses/by-nc-nd/3.0/
 *)

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\title{Certified Programming with Dependent Types}
\author{Adam Chlipala}

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(**

Copyright Adam Chlipala 2008-2011.

This work is licensed under a
Creative Commons Attribution-Noncommercial-No Derivative Works 3.0
Unported License.
The license text is available at:
%\begin{center} \url{http://creativecommons.org/licenses/by-nc-nd/3.0/} \end{center}%
#<a href="http://creativecommons.org/licenses/by-nc-nd/3.0/">http://creativecommons.org/licenses/by-nc-nd/3.0/</a>#

*)

(** %\vfill\mbox{}
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\chapter{Introduction}% *)




(** * Whence This Book? *)

(**

We would all like to have programs check that our programs are correct.  Due in no small part to some bold but unfulfilled promises in the history of computer science, today most people who write software, practitioners and academics alike, assume that the costs of formal program verification outweigh the benefits.  The purpose of this book is to convince you that the technology of program verification is mature enough today that it makes sense to use it in a support role in many kinds of research projects in computer science.  Beyond the convincing, I also want to provide a handbook on practical engineering of certified programs with the Coq proof assistant.  Almost every subject covered is also relevant to interactive computer theorem-proving in general, such as for traditional mathematical theorems.  In fact, I hope to demonstrate how verified programs are useful as building blocks in all sorts of formalizations.

Research into mechanized theorem-proving began around the 1970's, and some of the earliest practical work involved Nqthm%~\cite{Nqthm}\index{Nqthm}%, the %``%#"#Boyer-Moore Theorem Prover,#"#%''% which was used to prove such theorems as correctness of a complete hardware and software stack%~\cite{Piton}%.  ACL2%~\cite{CAR}\index{ACL2}%, Nqthm's successor, has seen significant industry adoption, for instance, by AMD to verify correctness of floating-point division units%~\cite{AMD}%.

Around the beginning of the 21st century, the pace of progress in practical applications of interactive theorem-proving accelerated significantly.  Several well-known formal developments have been carried out in Coq, the system that this book deals with.  In the realm of pure mathematics, Georges Gonthier built a machine-checked proof of the four color theorem%~\cite{4C}%, a mathematical problem first posed more than a hundred years before, where the only previous proofs had required trusting ad-hoc software to do brute-force checking of key facts.  In the realm of program verification, Xavier Leroy led the CompCert project to produce a verified C compiler back-end%~\cite{CompCert}% robust enough to use with real embedded software.

Many other recent projects have attracted attention by proving important theorems using computer proof assistant software.  For instance, the L4.verified project%~\cite{seL4}% has given a mechanized proof of correctness for a realistic microkernel, using the Isabelle/HOL proof assistant%~\cite{Isabelle/HOL}\index{Isabelle/HOL}%.  The amount of ongoing work in the area is so large that I cannot hope to list all the recent successes, so from this point I will assume that the reader is convinced both that we ought to want machine-checked proofs and that they seem to be feasible to produce.  (To readers not yet convinced, I suggest a Web search for %``%#"#machine-checked proof#"#%''%!)

There are a good number of (though definitely not %``%#"#many#"#%''%) tools that are in wide use today for building machine-checked mathematical proofs and machine-certified programs.  The following is my attempt at an exhaustive list of interactive %``%#"#proof assistants#"#%''% satisfying a few criteria.  First, the authors of each tool must intend for it to be put to use for software-related applications.  Second, there must have been enough engineering effort put into the tool that someone not doing research on the tool itself would feel his time was well spent using it.  A third criterion is more of an empirical validation of the second: the tool must have a significant user community outside of its own development team.

%
\medskip

\begin{tabular}{rl}
\textbf{ACL2} & \url{http://www.cs.utexas.edu/users/moore/acl2/} \\
\textbf{Coq} & \url{http://coq.inria.fr/} \\
\textbf{Isabelle/HOL} & \url{http://isabelle.in.tum.de/} \\
\textbf{PVS} & \url{http://pvs.csl.sri.com/} \\
\textbf{Twelf} & \url{http://www.twelf.org/} \\
\end{tabular}

\medskip
%
#
<table align="center">
<tr><td align="right"><b>ACL2</b></td> <td><a href="http://www.cs.utexas.edu/users/moore/acl2/">http://www.cs.utexas.edu/users/moore/acl2/</a></td></tr>
<tr><td align="right"><b>Coq</b></td> <td><a href="http://coq.inria.fr/">http://coq.inria.fr/</a></td></tr>
<tr><td align="right"><b>Isabelle/HOL</b></td> <td><a href="http://isabelle.in.tum.de/">http://isabelle.in.tum.de/</a></td></tr>
<tr><td align="right"><b>PVS</b></td> <td><a href="http://pvs.csl.sri.com/">http://pvs.csl.sri.com/</a></td></tr>
<tr><td align="right"><b>Twelf</b></td> <td><a href="http://www.twelf.org/">http://www.twelf.org/</a></td></tr>
</table>
#

Isabelle/HOL, implemented with the %``%#"#proof assistant development framework#"#%''% Isabelle%~\cite{Isabelle}%, is the most popular proof assistant for the HOL logic.  The other implementations of HOL can be considered equivalent for purposes of the discussion here.

*)


(** * Why Coq? *)

(**
This book is going to be about certified programming using Coq, and I am convinced that it is the best tool for the job.  Coq has a number of very attractive properties, which I will summarize here, mentioning which of the other candidate tools lack each property.
*)


(** ** Based on a Higher-Order Functional Programming Language *)

(**
There is no reason to give up the familiar comforts of functional programming when you start writing certified programs.  All of the tools I listed are based on functional programming languages, which means you can use them without their proof-related aspects to write and run regular programs.

ACL2 is notable in this field for having only a %\textit{%#<i>#first-order#</i>#%}% language at its foundation.  That is, you cannot work with functions over functions and all those other treats of functional programming.  By giving up this facility, ACL2 can make broader assumptions about how well its proof automation will work, but we can generally recover the same advantages in other proof assistants when we happen to be programming in first-order fragments.
*)


(** ** Dependent Types *)

(**
A language of %\textit{%#<i>#dependent types#</i>#%}% may include references to programs inside of types.  For instance, the type of an array might include a program expression giving the size of the array, making it possible to verify absence of out-of-bounds accesses statically.  Dependent types can go even further than this, effectively capturing any correctness property in a type.  For instance, later in this book, we will see how to give a Mini-ML compiler a type that guarantees that it maps well-typed source programs to well-typed target programs.

ACL2 and HOL lack dependent types outright.  PVS and Twelf each supports a different strict subset of Coq's dependent type language.  Twelf's type language is restricted to a bare-bones, monomorphic lambda calculus, which places serious restrictions on how complicated %\textit{%#<i>#computations inside types#</i>#%}% can be.  This restriction is important for the soundness argument behind Twelf's approach to representing and checking proofs.

In contrast, PVS's dependent types are much more general, but they are squeezed inside the single mechanism of %\textit{%#<i>#subset types#</i>#%}%, where a normal type is refined by attaching a predicate over its elements.  Each member of the subset type is an element of the base type that satisfies the predicate.  Chapter 6 of this book introduces that style of programming in Coq, while the remaining chapters of Part II deal with features of dependent typing in Coq that go beyond what PVS supports.

Dependent types are not just useful because they help you express correctness properties in types.  Dependent types also often let you write certified programs %\textit{%#<i>#without writing anything that looks like a proof#</i>#%}%.  Even with subset types, which for many contexts can be used to express any relevant property with enough acrobatics, the human driving the proof assistant usually has to build some proofs explicitly.  Writing formal proofs is hard, so we want to avoid it as far as possible, so dependent types are invaluable.

*)

(** ** An Easy-to-Check Kernel Proof Language *)

(**
Scores of automated decision procedures are useful in practical theorem proving, but it is unfortunate to have to trust in the correct implementation of each procedure.  Proof assistants satisfy the %``%#"#de Bruijn criterion#"#%''% when they produce %\textit{%#<i>#proof terms#</i>#%}% in small kernel languages, even when they use complicated and extensible procedures to seek out proofs in the first place.  These core languages have feature complexity on par with what you find in proposals for formal foundations for mathematics.  To believe a proof, we can ignore the possibility of bugs during %\textit{%#<i>#search#</i>#%}% and just rely on a (relatively small) proof-checking kernel that we apply to the %\textit{%#<i>#result#</i>#%}% of the search.

Coq meets the de Bruijn criterion, while ACL2 and PVS do not, as they employ fancy decision procedures that produce no %``%#"#evidence trails#"#%''% justifying their results.
*)

(** ** Convenient Programmable Proof Automation *)

(**
A commitment to a kernel proof language opens up wide possibilities for user extension of proof automation systems, without allowing user mistakes to trick the overall system into accepting invalid proofs.  Almost any interesting verification problem is undecidable, so it is important to help users build their own procedures for solving the restricted problems that they encounter in particular implementations.

Twelf features no proof automation marked as a bonafide part of the latest release; there is some automation code included for testing purposes.  The Twelf style is based on writing out all proofs in full detail.  Because Twelf is specialized to the domain of syntactic metatheory proofs about programming languages and logics, it is feasible to use it to write those kinds of proofs manually.  Outside that domain, the lack of automation can be a serious obstacle to productivity.  Most kinds of program verification fall outside Twelf's forte.

Of the remaining tools, all can support user extension with new decision procedures by hacking directly in the tool's implementation language (such as OCaml for Coq).  Since ACL2 and PVS do not satisfy the de Bruijn criterion, overall correctness is at the mercy of the authors of new procedures.

Isabelle/HOL and Coq both support coding new proof manipulations in ML in ways that cannot lead to the acceptance of invalid proofs.  Additionally, Coq includes a domain-specific language for coding decision procedures in normal Coq source code, with no need to break out into ML.  This language is called Ltac, and I think of it as the unsung hero of the proof assistant world.  Not only does Ltac prevent you from making fatal mistakes, it also includes a number of novel programming constructs which combine to make a %``%#"#proof by decision procedure#"#%''% style very pleasant.  We will meet these features in the chapters to come.
*)

(** ** Proof by Reflection *)

(**
A surprising wealth of benefits follow from choosing a proof language that integrates a rich notion of computation.  Coq includes programs and proof terms in the same syntactic class.  This makes it easy to write programs that compute proofs.  With rich enough dependent types, such programs are %\textit{%#<i>#certified decision procedures#</i>#%}%.  In such cases, these certified procedures can be put to good use %\textit{%#<i>#without ever running them#</i>#%}%!  Their types guarantee that, if we did bother to run them, we would receive proper %``%#"#ground#"#%''% proofs.

The critical ingredient for this technique, many of whose instances are referred to as %\textit{%#<i>#proof by reflection#</i>#%}%, is a way of inducing non-trivial computation inside of logical propositions during proof checking.  Further, most of these instances require dependent types to make it possible to state the appropriate theorems.  Of the proof assistants I listed, only Coq really provides this support.
*)


(** * Why Not a Different Dependently Typed Language? *)

(**
The logic and programming language behind Coq belongs to a type-theory ecosystem with a good number of other thriving members.  %Agda\footnote{\url{http://appserv.cs.chalmers.se/users/ulfn/wiki/agda.php}}%#<a href="http://appserv.cs.chalmers.se/users/ulfn/wiki/agda.php">Agda</a># and %Epigram\footnote{\url{http://www.e-pig.org/}}%#<a href="http://www.e-pig.org/">Epigram</a># are the most developed tools among the alternatives to Coq, and there are others that are earlier in their lifecycles.  All of the languages in this family feel sort of like different historical offshoots of Latin.  The hardest conceptual epiphanies are, for the most part, portable among all the languages.  Given this, why choose Coq for certified programming?

I think the answer is simple.  None of the competition has well-developed systems for tactic-based theorem proving.  Agda and Epigram are designed and marketed more as programming languages than proof assistants.  Dependent types are great, because they often help you prove deep theorems without doing anything that feels like proving.  Nonetheless, almost any interesting certified programming project will benefit from some activity that deserves to be called proving, and many interesting projects absolutely require semi-automated proving, to protect the sanity of the programmer.  Informally, proving is unavoidable when any correctness proof for a program has a structure that does not mirror the structure of the program itself.  An example is a compiler correctness proof, which probably proceeds by induction on program execution traces, which have no simple relationship with the structure of the compiler or the structure of the programs it compiles.  In building such proofs, a mature system for scripted proof automation is invaluable.

On the other hand, Agda, Epigram, and similar tools have less implementation baggage associated with them, and so they tend to be the default first homes of innovations in practical type theory.  Some significant kinds of dependently typed programs are much easier to write in Agda and Epigram than in Coq.  The former tools may very well be superior choices for projects that do not involve any %``%#"#proving.#"#%''%  Anecdotally, I have gotten the impression that manual proving is orders of magnitudes more costly than manual coping with Coq's lack of programming bells and whistles.  In this book, I will devote significant time to patterns for programming with dependent types in Coq as it is today.  We can hope that the type theory community is tending towards convergence on the right set of features for practical programming with dependent types, and that we will eventually have a single tool embodying those features.
*)


(** * Engineering with a Proof Assistant *)

(**
In comparisons with its competitors, Coq is often derided for promoting unreadable proofs.  It is very easy to write proof scripts that manipulate proof goals imperatively, with no structure to aid readers.  Such developments are nightmares to maintain, and they certainly do not manage to convey %``%#"#why the theorem is true#"#%''% to anyone but the original author.  One additional (and not insignificant) purpose of this book is to show why it is unfair and unproductive to dismiss Coq based on the existence of such developments.

I will go out on a limb and guess that the reader is a dedicated fan of some functional programming language or another, and that he may even have been involved in teaching that language to undergraduates.  I want to propose an analogy between two attitudes: coming to a negative conclusion about Coq after reading common Coq developments in the wild, and coming to a negative conclusion about Your Favorite Language after looking at the programs undergraduates write in it in the first week of class.  The pragmatics of mechanized proving and program verification have been under serious study for much less time than the pragmatics of programming have been.  The computer theorem proving community is still developing the key insights that correspond to those that functional programming texts and instructors impart to their students, to help those students get over that critical hump where using the language stops being more trouble than it is worth.  Most of the insights for Coq are barely even disseminated among the experts, let alone set down in a tutorial form.  I hope to use this book to go a long way towards remedying that.

If I do that job well, then this book should be of interest even to people who have participated in classes or tutorials specifically about Coq.  The book should even be useful to people who have been using Coq for years but who are mystified when their Coq developments prove impenetrable by colleagues.  The crucial angle in this book is that there are %``%#"#design patterns#"#%''% for reliably avoiding the really grungy parts of theorem proving, and consistent use of these patterns can get you over the hump to the point where it is worth your while to use Coq to prove your theorems and certify your programs, even if formal verification is not your main concern in a project.  We will follow this theme by pursuing two main methods for replacing manual proofs with more understandable artifacts: dependently typed functions and custom Ltac decision procedures.
*)


(** * Prerequisites *)

(**
I try to keep the required background knowledge to a minimum in this book.  I will assume familiarity with the material from usual discrete math and logic courses taken by all undergraduate computer science majors, and I will assume that readers have significant experience programming in one of the ML dialects, in Haskell, or in some other, closely related language.  Experience with only dynamically typed functional languages might lead to befuddlement in some places, but a reader who has come to understand Scheme deeply will probably be fine.

Part IV of this manuscript is about formalizing programming languages and compilers.  That part certainly depends on basic knowledge of formal type systems, operational semantics, and the theorems usually proved about such systems.  As a reference on these topics, I recommend %\emph{%#<i>#Types and Programming Languages#</i>#%}~\cite{TAPL}%, by Benjamin C. Pierce.  However, my current plan is to break Part IV into a separate, online-only document, since I expect the formalization interests of many readers of the book to lie outside of programming languages.  I do often use examples from programming languages in the earlier parts of the book, but I have tried to design them to be comprehensible on the basis of ML or Haskell experience alone.
*)


(** * Using This Book *)

(**
This book is generated automatically from Coq source files using the wonderful coqdoc program.  The latest PDF version, with hyperlinks from identifier uses to the corresponding definitions, is available at:
%\begin{center}\url{http://adam.chlipala.net/cpdt/cpdt.pdf}\end{center}%#<blockquote><tt><a href="http://adam.chlipala.net/cpdt/cpdt.pdf">http://adam.chlipala.net/cpdt/cpdt.pdf</a></tt></blockquote>#
There is also an online HTML version available, which of course also provides hyperlinks:
%\begin{center}\url{http://adam.chlipala.net/cpdt/html/toc.html}\end{center}%#<blockquote><tt><a href="http://adam.chlipala.net/cpdt/html/toc.html">http://adam.chlipala.net/cpdt/html/toc.html</a></tt></blockquote>#
The source code to the book is also freely available at:
%\begin{center}\url{http://adam.chlipala.net/cpdt/cpdt.tgz}\end{center}%#<blockquote><tt><a href="http://adam.chlipala.net/cpdt/cpdt.tgz">http://adam.chlipala.net/cpdt/cpdt.tgz</a></tt></blockquote>#

There, you can find all of the code appearing in this book, with prose interspersed in comments, in exactly the order that you find in this document.  You can step through the code interactively with your chosen graphical Coq interface.  The code also has special comments indicating which parts of the chapters make suitable starting points for interactive class sessions, where the class works together to construct the programs and proofs.  The included Makefile has a target %\texttt{%#<tt>#templates#</tt>#%}% for building a fresh set of class template files automatically from the book source.

A traditional printed version of the book is slated to appear from MIT Press in the future.  The online versions will remain available at no cost even after the printed book is released, and I intend to keep the source code up-to-date with bug fixes and compatibility changes to track new Coq releases.

I believe that a good graphical interface to Coq is crucial for using it productively.  I use the %Proof General\footnote{\url{http://proofgeneral.inf.ed.ac.uk/}}%#<a href="http://proofgeneral.inf.ed.ac.uk/">Proof General</a># mode for Emacs, which supports a number of other proof assistants besides Coq.  There is also the standalone CoqIDE program developed by the Coq team.  I like being able to combine certified programming and proving with other kinds of work inside the same full-featured editor, and CoqIDE has had a good number of crashes and other annoying bugs in recent history, though I hear that it is improving.  In the initial part of this book, I will reference Proof General procedures explicitly, in introducing how to use Coq, but most of the book will be interface-agnostic, so feel free to use CoqIDE if you prefer it.  The one issue with CoqIDE, regarding running through the book source, is that I will sometimes begin a proof attempt but cancel it with the Coq [Abort] or #<span class="inlinecode"><span class="id" type="keyword">#%\coqdockw{%Restart%}%#</span></span># commands, which CoqIDE does not support.  It would be bad form to leave such commands lying around in a real, finished development, but I find these commands helpful in writing single source files that trace a user's thought process in designing a proof.

The next chapter will introduce Coq with some simple examples, and the chapter starts with step-by-step instructions on getting set up to run the book chapters interactively, assuming that you have Coq and Proof General installed.
*)


(** %\section{Chapter Source Files}

\begin{center} \begin{tabular}{|r|l|}
\hline
\textbf{Chapter} & \textbf{Source} \\
\hline
Some Quick Examples & \texttt{StackMachine.v} \\
\hline
Introducing Inductive Types & \texttt{InductiveTypes.v} \\
\hline
Inductive Predicates & \texttt{Predicates.v} \\
\hline
Infinite Data and Proofs & \texttt{Coinductive.v} \\
\hline
Subset Types and Variations & \texttt{Subset.v} \\
\hline
More Dependent Types & \texttt{MoreDep.v} \\
\hline
Dependent Data Structures & \texttt{DataStruct.v} \\
\hline
Reasoning About Equality Proofs & \texttt{Equality.v} \\
\hline
Generic Programming & \texttt{Generic.v} \\
\hline
Universes and Axioms & \texttt{Universes.v} \\
\hline
Proof Search in Ltac & \texttt{Match.v} \\
\hline
Proof by Reflection & \texttt{Reflection.v} \\
\hline
Proving in the Large & \texttt{Large.v} \\
\hline
First-Order Abstract Syntax & \texttt{Firstorder.v} \\
\hline
Dependent De Bruijn Indices & \texttt{DeBruijn.v} \\
\hline
Higher-Order Abstract Syntax & \texttt{Hoas.v} \\
\hline
Type-Theoretic Interpreters & \texttt{Interps.v} \\
\hline
Extensional Transformations & \texttt{Extensional.v} \\
\hline
Intensional Transformations & \texttt{Intensional.v} \\
\hline
Higher-Order Operational Semantics & \texttt{OpSem.v} \\
\hline
\end{tabular} \end{center}

% *)