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Fleshed out intro
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.gitignore
vendored
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*.out
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*.pdf
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*.toc
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*.bbl
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*.blg
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*.ilg
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*.ind
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5
Makefile
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Makefile
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frap.pdf: frap.tex
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frap.pdf: frap.tex Makefile
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pdflatex frap
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pdflatex frap
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makeindex frap
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pdflatex frap
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pdflatex frap
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57
frap.tex
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frap.tex
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@ -85,12 +85,65 @@ Eventually, there will no doubt be some sort of historical overview here, as par
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There will also be plenty of scholarly citations (here and throughout the book).
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In this early version, you get to take the author's word for it that we are about to learn a promising approach!
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However, one overarching element of our strategy is important enough to deserve to be called out here.
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We will study a variety of different approaches for formalizing what a program should do and for proving that a program does what it should.
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At every step, we will pay close attention to the \emph{common foundation} that underlies everything.
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For one thing, we will be proving all of our theorems with the Coq proof assistant, a powerful framework for writing and machine-checking proofs.
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Coq itself is based on a relatively small set of core features, much like a well-designed programming language, and in both we build up increasingly sophisticated abstractions as libraries.
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Those features can be thought of as the core of all mathematical reasoning.
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We will also apply a recipe specific to program proof.
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When we encounter a new challenge, to prove a new kind of property about a new kind of program, we will generally be considering four broad elements that appear in nearly all techniques.
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\begin{itemize}
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\item \index{encoding}\textbf{Encoding.}
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Every programming language has both \index{syntax}\emph{syntax}, which defines what programs look like, and \index{semantics}\emph{semantics}, which defines how programs behave when run.
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Even when these elements seem obvious intuitively, we often find that there are surprisingly subtle choices to be made in defining syntax and semantics at the highest level of rigor.
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Seemingly minor decisions can have big impacts on how smoothly our proofs go.
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\item \textbf{Invariants.}
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Nearly every theorem about a program is stated in terms of a \index{transition system}\emph{transition system}, with some set of states and a relation for stepping from one state to the next, moving forward in time.
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Nearly every program proof also works by finding an \index{invariant}\emph{invariant} of a transition system, or a property that always holds of every state reachable from some starting state.
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The concept of invariant is very close to being a direct reinterpretation of mathematical induction, that glue of every serious mathematical development, known and loved by all.
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\item \index{abstraction}\textbf{Abstraction.}
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Often a transition system is too complex to analyze directly.
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Instead, we \emph{abstract} it with another transition system that is somehow more tractable, proving that the new system preserves all relevant properties of the original.
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\item \index{modularity}\textbf{Modularity.}
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Similarly, when a transition system is too complex, we often break it into separate \emph{modules} and use some well-behaved composition operators to reassemble them into the whole.
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Often abstraction and modularity go together, as we decompose a system both \index{horizontal decomposition}\emph{horizontally} (i.e., with modularity), splitting it into more manageable parts, and \index{vertical decomposition}\emph{vertically} (i.e., with abstraction), simplifying parts in ways that preserve key properties.
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We can even alternate between strategies, breaking a system into parts, abstracting one as a simpler part, further decomposing that part into pieces, and so on.
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\end{itemize}
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In the course of the book, we will never quite define any of these meta-techniques in complete formality.
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Instead, we'll meet many examples of each, called out by eye-catching margin notes.
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Generalizing from the examples should help the reader start developing an intuition for when to use each element and for the common design patterns that apply.
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The core subject matter of the book is often grouped under traditional disciplinary headers like \index{semantics}\emph{semantics}, \index{programming-languages theory}\emph{programming-languages theory}, \index{formal methods}\emph{formal methods}, and \index{verification}\emph{verification}.
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Often these different traditions have their own competing terminology for shared concepts.
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We'll follow one particular set of unified terminology and notation, cherry-picked from the conventions of different communities.
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There really is a huge amount of commonality across everything that we'll study, so we don't want to distract by constantly translating between notations.
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It is quite important to be literate in the standard notational conventions, which are almost always implemented with \index{\LaTeX{}}\LaTeX{}, and we stick entirely to that kind of notation in this book.
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However, we follow another, much less usual convention: while we give theorem and lemma statements, we rarely give their proofs.
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The reason is that the author and many other researchers today feel that proofs on paper have outlived their usefulness.
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Instead, the proofs are all found in the parallel world of the accompanying Coq source code.
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That is, each chapter of this book has a corresponding Coq source file, distributed with the general book source code.
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The Coq sources are heavily commented and may even, in many cases, be feasible to read without also reading the book chapters.
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More importantly, the Coq sources aren't just meant to be \emph{read}.
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They are meant to be \emph{executed}.
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We suggest stepping through them interactively, seeing intermediate states of proofs as appropriate.
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The book proper can be read without the Coq sources, to learn the standard background material of program proof; and the Coq sources can be read without the book proper, to learn a particular concrete realization of those ideas.
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However, they go better together.
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\appendix
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\backmatter
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% Bibliography styles amsplain or harvard are also acceptable.
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\bibliographystyle{amsalpha}
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\bibliography{}
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%% \bibliographystyle{amsalpha}
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%% \bibliography{}
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% See note above about multiple indexes.
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\printindex
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