(*<*)theory Paperimports "../Nominal/Nominal2" "LaTeXsugar"beginconsts fv :: "'a \<Rightarrow> 'b" abs_set :: "'a \<Rightarrow> 'b \<Rightarrow> 'c" alpha_bn :: "'a \<Rightarrow> 'a \<Rightarrow> bool" abs_set2 :: "'a \<Rightarrow> perm \<Rightarrow> 'b \<Rightarrow> 'c" Abs_dist :: "'a \<Rightarrow> 'b \<Rightarrow> 'c" Abs_print :: "'a \<Rightarrow> 'b \<Rightarrow> 'c" definition "equal \<equiv> (op =)" notation (latex output) swap ("'(_ _')" [1000, 1000] 1000) and fresh ("_ # _" [51, 51] 50) and fresh_star ("_ #\<^sup>* _" [51, 51] 50) and supp ("supp _" [78] 73) and uminus ("-_" [78] 73) and If ("if _ then _ else _" 10) and alpha_set ("_ \<approx>\<^raw:\,\raisebox{-1pt}{\makebox[0mm][l]{$_{\textit{set}}$}}>\<^bsup>_, _, _\<^esup> _") and alpha_lst ("_ \<approx>\<^raw:\,\raisebox{-1pt}{\makebox[0mm][l]{$_{\textit{list}}$}}>\<^bsup>_, _, _\<^esup> _") and alpha_res ("_ \<approx>\<^raw:\,\raisebox{-1pt}{\makebox[0mm][l]{$_{\textit{res}}$}}>\<^bsup>_, _, _\<^esup> _") and abs_set ("_ \<approx>\<^raw:{$\,_{\textit{abs\_set}}$}> _") and abs_set2 ("_ \<approx>\<^raw:\raisebox{-1pt}{\makebox[0mm][l]{$\,_{\textit{list}}$}}>\<^bsup>_\<^esup> _") and fv ("fa'(_')" [100] 100) and equal ("=") and alpha_abs_set ("_ \<approx>\<^raw:{$\,_{\textit{abs\_set}}$}> _") and Abs_set ("[_]\<^bsub>set\<^esub>._" [20, 101] 999) and Abs_lst ("[_]\<^bsub>list\<^esub>._") and Abs_dist ("[_]\<^bsub>#list\<^esub>._") and Abs_res ("[_]\<^bsub>res\<^esub>._") and Abs_print ("_\<^bsub>set\<^esub>._") and Cons ("_::_" [78,77] 73) and supp_set ("aux _" [1000] 10) and alpha_bn ("_ \<approx>bn _")consts alpha_trm ::'aconsts fa_trm :: 'aconsts alpha_trm2 ::'aconsts fa_trm2 :: 'aconsts ast :: 'aconsts ast' :: 'anotation (latex output) alpha_trm ("\<approx>\<^bsub>trm\<^esub>") and fa_trm ("fa\<^bsub>trm\<^esub>") and alpha_trm2 ("'(\<approx>\<^bsub>assn\<^esub>, \<approx>\<^bsub>trm\<^esub>')") and fa_trm2 ("'(fa\<^bsub>assn\<^esub>, fa\<^bsub>trm\<^esub>')") and ast ("'(as, t')") and ast' ("'(as', t\<PRIME> ')")(*>*)section {* Introduction *}text {* So far, Nominal Isabelle provided a mechanism for constructing $\alpha$-equated terms, for example lambda-terms, @{text "t ::= x | t t | \<lambda>x. t"}, where free and bound variables have names. For such $\alpha$-equated terms, Nominal Isabelle derives automatically a reasoning infrastructure that has been used successfully in formalisations of an equivalence checking algorithm for LF \cite{UrbanCheneyBerghofer08}, Typed Scheme~\cite{TobinHochstadtFelleisen08}, several calculi for concurrency \cite{BengtsonParow09} and a strong normalisation result for cut-elimination in classical logic \cite{UrbanZhu08}. It has also been used by Pollack for formalisations in the locally-nameless approach to binding \cite{SatoPollack10}. However, Nominal Isabelle has fared less well in a formalisation of the algorithm W \cite{UrbanNipkow09}, where types and type-schemes are, respectively, of the form % \begin{equation}\label{tysch} \begin{array}{l} @{text "T ::= x | T \<rightarrow> T"}\hspace{9mm} @{text "S ::= \<forall>{x\<^isub>1,\<dots>, x\<^isub>n}. T"} \end{array} \end{equation} % \noindent and the @{text "\<forall>"}-quantification binds a finite (possibly empty) set of type-variables. While it is possible to implement this kind of more general binders by iterating single binders, this leads to a rather clumsy formalisation of W. %The need of iterating single binders is also one reason %why Nominal Isabelle % and similar theorem provers that only provide %mechanisms for binding single variables %has not fared extremely well with the %more advanced tasks in the POPLmark challenge \cite{challenge05}, because %also there one would like to bind multiple variables at once. Binding multiple variables has interesting properties that cannot be captured easily by iterating single binders. For example in the case of type-schemes we do not want to make a distinction about the order of the bound variables. Therefore we would like to regard the following two type-schemes as $\alpha$-equivalent % \begin{equation}\label{ex1} @{text "\<forall>{x, y}. x \<rightarrow> y \<approx>\<^isub>\<alpha> \<forall>{y, x}. x \<rightarrow> y"} \end{equation} % \noindent but assuming that @{text x}, @{text y} and @{text z} are distinct variables, the following two should \emph{not} be $\alpha$-equivalent % \begin{equation}\label{ex2} @{text "\<forall>{x, y}. x \<rightarrow> y \<notapprox>\<^isub>\<alpha> \<forall>{z}. z \<rightarrow> z"} \end{equation} % \noindent Moreover, we like to regard type-schemes as $\alpha$-equivalent, if they differ only on \emph{vacuous} binders, such as % \begin{equation}\label{ex3} @{text "\<forall>{x}. x \<rightarrow> y \<approx>\<^isub>\<alpha> \<forall>{x, z}. x \<rightarrow> y"} \end{equation} % \noindent where @{text z} does not occur freely in the type. In this paper we will give a general binding mechanism and associated notion of $\alpha$-equivalence that can be used to faithfully represent this kind of binding in Nominal Isabelle. %The difficulty of finding the right notion for $\alpha$-equivalence %can be appreciated in this case by considering that the definition given by %Leroy in \cite{Leroy92} is incorrect (it omits a side-condition). However, the notion of $\alpha$-equivalence that is preserved by vacuous binders is not always wanted. For example in terms like % \begin{equation}\label{one} @{text "\<LET> x = 3 \<AND> y = 2 \<IN> x - y \<END>"} \end{equation} \noindent we might not care in which order the assignments @{text "x = 3"} and \mbox{@{text "y = 2"}} are given, but it would be unusual to regard \eqref{one} as $\alpha$-equivalent with % \begin{center} @{text "\<LET> x = 3 \<AND> y = 2 \<AND> z = loop \<IN> x - y \<END>"} \end{center} % \noindent Therefore we will also provide a separate binding mechanism for cases in which the order of binders does not matter, but the ``cardinality'' of the binders has to agree. However, we found that this is still not sufficient for dealing with language constructs frequently occurring in programming language research. For example in @{text "\<LET>"}s containing patterns like % \begin{equation}\label{two} @{text "\<LET> (x, y) = (3, 2) \<IN> x - y \<END>"} \end{equation} % \noindent we want to bind all variables from the pattern inside the body of the $\mathtt{let}$, but we also care about the order of these variables, since we do not want to regard \eqref{two} as $\alpha$-equivalent with % \begin{center} @{text "\<LET> (y, x) = (3, 2) \<IN> x - y \<END>"} \end{center} % \noindent As a result, we provide three general binding mechanisms each of which binds multiple variables at once, and let the user chose which one is intended in a formalisation. %%when formalising a term-calculus. By providing these general binding mechanisms, however, we have to work around a problem that has been pointed out by Pottier \cite{Pottier06} and Cheney \cite{Cheney05}: in @{text "\<LET>"}-constructs of the form % \begin{center} @{text "\<LET> x\<^isub>1 = t\<^isub>1 \<AND> \<dots> \<AND> x\<^isub>n = t\<^isub>n \<IN> s \<END>"} \end{center} % \noindent we care about the information that there are as many bound variables @{text "x\<^isub>i"} as there are @{text "t\<^isub>i"}. We lose this information if we represent the @{text "\<LET>"}-constructor by something like % \begin{center} @{text "\<LET> (\<lambda>x\<^isub>1\<dots>x\<^isub>n . s) [t\<^isub>1,\<dots>,t\<^isub>n]"} \end{center} % \noindent where the notation @{text "\<lambda>_ . _"} indicates that the list of @{text "x\<^isub>i"} becomes bound in @{text s}. In this representation the term \mbox{@{text "\<LET> (\<lambda>x . s) [t\<^isub>1, t\<^isub>2]"}} is a perfectly legal instance, but the lengths of the two lists do not agree. To exclude such terms, additional predicates about well-formed terms are needed in order to ensure that the two lists are of equal length. This can result in very messy reasoning (see for example~\cite{BengtsonParow09}). To avoid this, we will allow type specifications for @{text "\<LET>"}s as follows % \begin{center} \begin{tabular}{r@ {\hspace{2mm}}r@ {\hspace{2mm}}cl} @{text trm} & @{text "::="} & @{text "\<dots>"} & @{text "|"} @{text "\<LET> as::assn s::trm"}\hspace{2mm} \isacommand{bind} @{text "bn(as)"} \isacommand{in} @{text "s"}\\%%%[1mm] @{text assn} & @{text "::="} & @{text "\<ANIL>"} & @{text "|"} @{text "\<ACONS> name trm assn"} \end{tabular} \end{center} % \noindent where @{text assn} is an auxiliary type representing a list of assignments and @{text bn} an auxiliary function identifying the variables to be bound by the @{text "\<LET>"}. This function can be defined by recursion over @{text assn} as follows % \begin{center} @{text "bn(\<ANIL>) ="} @{term "{}"} \hspace{5mm} @{text "bn(\<ACONS> x t as) = {x} \<union> bn(as)"} \end{center} % \noindent The scope of the binding is indicated by labels given to the types, for example @{text "s::trm"}, and a binding clause, in this case \isacommand{bind} @{text "bn(as)"} \isacommand{in} @{text "s"}. This binding clause states that all the names the function @{text "bn(as)"} returns should be bound in @{text s}. This style of specifying terms and bindings is heavily inspired by the syntax of the Ott-tool \cite{ott-jfp}. %Though, Ott %has only one binding mode, namely the one where the order of %binders matters. Consequently, type-schemes with binding sets %of names cannot be modelled in Ott. However, we will not be able to cope with all specifications that are allowed by Ott. One reason is that Ott lets the user specify ``empty'' types like @{text "t ::= t t | \<lambda>x. t"} where no clause for variables is given. Arguably, such specifications make some sense in the context of Coq's type theory (which Ott supports), but not at all in a HOL-based environment where every datatype must have a non-empty set-theoretic model. % \cite{Berghofer99}. Another reason is that we establish the reasoning infrastructure for $\alpha$-\emph{equated} terms. In contrast, Ott produces a reasoning infrastructure in Isabelle/HOL for \emph{non}-$\alpha$-equated, or ``raw'', terms. While our $\alpha$-equated terms and the raw terms produced by Ott use names for bound variables, there is a key difference: working with $\alpha$-equated terms means, for example, that the two type-schemes \begin{center} @{text "\<forall>{x}. x \<rightarrow> y = \<forall>{x, z}. x \<rightarrow> y"} \end{center} \noindent are not just $\alpha$-equal, but actually \emph{equal}! As a result, we can only support specifications that make sense on the level of $\alpha$-equated terms (offending specifications, which for example bind a variable according to a variable bound somewhere else, are not excluded by Ott, but we have to). %Our insistence on reasoning with $\alpha$-equated terms comes from the %wealth of experience we gained with the older version of Nominal Isabelle: %for non-trivial properties, reasoning with $\alpha$-equated terms is much %easier than reasoning with raw terms. The fundamental reason for this is %that the HOL-logic underlying Nominal Isabelle allows us to replace %``equals-by-equals''. In contrast, replacing %``$\alpha$-equals-by-$\alpha$-equals'' in a representation based on raw terms %requires a lot of extra reasoning work. Although in informal settings a reasoning infrastructure for $\alpha$-equated terms is nearly always taken for granted, establishing it automatically in Isabelle/HOL is a rather non-trivial task. For every specification we will need to construct type(s) containing as elements the $\alpha$-equated terms. To do so, we use the standard HOL-technique of defining a new type by identifying a non-empty subset of an existing type. The construction we perform in Isabelle/HOL can be illustrated by the following picture: % \begin{center} \begin{tikzpicture}[scale=0.89] %\draw[step=2mm] (-4,-1) grid (4,1); \draw[very thick] (0.7,0.4) circle (4.25mm); \draw[rounded corners=1mm, very thick] ( 0.0,-0.8) rectangle ( 1.8, 0.9); \draw[rounded corners=1mm, very thick] (-1.95,0.85) rectangle (-2.85,-0.05); \draw (-2.0, 0.845) -- (0.7,0.845); \draw (-2.0,-0.045) -- (0.7,-0.045); \draw ( 0.7, 0.4) node {\footnotesize\begin{tabular}{@ {}c@ {}}$\alpha$-\\[-1mm]clas.\end{tabular}}; \draw (-2.4, 0.4) node {\footnotesize\begin{tabular}{@ {}c@ {}}$\alpha$-eq.\\[-1mm]terms\end{tabular}}; \draw (1.8, 0.48) node[right=-0.1mm] {\footnotesize\begin{tabular}{@ {}l@ {}}existing\\[-1mm] type\\ (sets of raw terms)\end{tabular}}; \draw (0.9, -0.35) node {\footnotesize\begin{tabular}{@ {}l@ {}}non-empty\\[-1mm]subset\end{tabular}}; \draw (-3.25, 0.55) node {\footnotesize\begin{tabular}{@ {}l@ {}}new\\[-1mm]type\end{tabular}}; \draw[<->, very thick] (-1.8, 0.3) -- (-0.1,0.3); \draw (-0.95, 0.3) node[above=0mm] {\footnotesize{}isomorphism}; \end{tikzpicture} \end{center} % \noindent We take as the starting point a definition of raw terms (defined as a datatype in Isabelle/HOL); then identify the $\alpha$-equivalence classes in the type of sets of raw terms according to our $\alpha$-equivalence relation, and finally define the new type as these $\alpha$-equivalence classes (non-emptiness is satisfied whenever the raw terms are definable as datatype in Isabelle/HOL and our relation for $\alpha$-equivalence is an equivalence relation). %The fact that we obtain an isomorphism between the new type and the %non-empty subset shows that the new type is a faithful representation of %$\alpha$-equated terms. That is not the case for example for terms using the %locally nameless representation of binders \cite{McKinnaPollack99}: in this %representation there are ``junk'' terms that need to be excluded by %reasoning about a well-formedness predicate. The problem with introducing a new type in Isabelle/HOL is that in order to be useful, a reasoning infrastructure needs to be ``lifted'' from the underlying subset to the new type. This is usually a tricky and arduous task. To ease it, we re-implemented in Isabelle/HOL the quotient package described by Homeier \cite{Homeier05} for the HOL4 system. This package allows us to lift definitions and theorems involving raw terms to definitions and theorems involving $\alpha$-equated terms. For example if we define the free-variable function over raw lambda-terms \begin{center} @{text "fv(x) = {x}"}\hspace{8mm} @{text "fv(t\<^isub>1 t\<^isub>2) = fv(t\<^isub>1) \<union> fv(t\<^isub>2)"}\hspace{8mm} @{text "fv(\<lambda>x.t) = fv(t) - {x}"} \end{center} \noindent then with the help of the quotient package we can obtain a function @{text "fv\<^sup>\<alpha>"} operating on quotients, or $\alpha$-equivalence classes of lambda-terms. This lifted function is characterised by the equations \begin{center} @{text "fv\<^sup>\<alpha>(x) = {x}"}\hspace{8mm} @{text "fv\<^sup>\<alpha>(t\<^isub>1 t\<^isub>2) = fv\<^sup>\<alpha>(t\<^isub>1) \<union> fv\<^sup>\<alpha>(t\<^isub>2)"}\hspace{8mm} @{text "fv\<^sup>\<alpha>(\<lambda>x.t) = fv\<^sup>\<alpha>(t) - {x}"} \end{center} \noindent (Note that this means also the term-constructors for variables, applications and lambda are lifted to the quotient level.) This construction, of course, only works if $\alpha$-equivalence is indeed an equivalence relation, and the ``raw'' definitions and theorems are respectful w.r.t.~$\alpha$-equivalence. %For example, we will not be able to lift a bound-variable function. Although %this function can be defined for raw terms, it does not respect %$\alpha$-equivalence and therefore cannot be lifted. To sum up, every lifting of theorems to the quotient level needs proofs of some respectfulness properties (see \cite{Homeier05}). In the paper we show that we are able to automate these proofs and as a result can automatically establish a reasoning infrastructure for $\alpha$-equated terms.\smallskip %The examples we have in mind where our reasoning infrastructure will be %helpful includes the term language of Core-Haskell. This term language %involves patterns that have lists of type-, coercion- and term-variables, %all of which are bound in @{text "\<CASE>"}-expressions. In these %patterns we do not know in advance how many variables need to %be bound. Another example is the specification of SML, which includes %includes bindings as in type-schemes.\medskip \noindent {\bf Contributions:} We provide three new definitions for when terms involving general binders are $\alpha$-equivalent. These definitions are inspired by earlier work of Pitts \cite{Pitts04}. By means of automatic proofs, we establish a reasoning infrastructure for $\alpha$-equated terms, including properties about support, freshness and equality conditions for $\alpha$-equated terms. We are also able to derive strong induction principles that have the variable convention already built in. The method behind our specification of general binders is taken from the Ott-tool, but we introduce crucial restrictions, and also extensions, so that our specifications make sense for reasoning about $\alpha$-equated terms. The main improvement over Ott is that we introduce three binding modes (only one is present in Ott), provide formalised definitions for $\alpha$-equivalence and for free variables of our terms, and also derive a reasoning infrastructure for our specifications inside Isabelle/HOL from ``first principles''. %\begin{figure} %\begin{boxedminipage}{\linewidth} %%\begin{center} %\begin{tabular}{r@ {\hspace{1mm}}r@ {\hspace{2mm}}l} %\multicolumn{3}{@ {}l}{Type Kinds}\\ %@{text "\<kappa>"} & @{text "::="} & @{text "\<star> | \<kappa>\<^isub>1 \<rightarrow> \<kappa>\<^isub>2"}\smallskip\\ %\multicolumn{3}{@ {}l}{Coercion Kinds}\\ %@{text "\<iota>"} & @{text "::="} & @{text "\<sigma>\<^isub>1 \<sim> \<sigma>\<^isub>2"}\smallskip\\ %\multicolumn{3}{@ {}l}{Types}\\ %@{text "\<sigma>"} & @{text "::="} & @{text "a | T | \<sigma>\<^isub>1 \<sigma>\<^isub>2 | S\<^isub>n"}$\;\overline{@{text "\<sigma>"}}$@{text "\<^sup>n"} %@{text "| \<forall>a:\<kappa>. \<sigma> | \<iota> \<Rightarrow> \<sigma>"}\smallskip\\ %\multicolumn{3}{@ {}l}{Coercion Types}\\ %@{text "\<gamma>"} & @{text "::="} & @{text "c | C | \<gamma>\<^isub>1 \<gamma>\<^isub>2 | S\<^isub>n"}$\;\overline{@{text "\<gamma>"}}$@{text "\<^sup>n"} %@{text "| \<forall>c:\<iota>. \<gamma> | \<iota> \<Rightarrow> \<gamma> "}\\ %& @{text "|"} & @{text "refl \<sigma> | sym \<gamma> | \<gamma>\<^isub>1 \<circ> \<gamma>\<^isub>2 | \<gamma> @ \<sigma> | left \<gamma> | right \<gamma>"}\\ %& @{text "|"} & @{text "\<gamma>\<^isub>1 \<sim> \<gamma>\<^isub>2 | rightc \<gamma> | leftc \<gamma> | \<gamma>\<^isub>1 \<triangleright> \<gamma>\<^isub>2"}\smallskip\\ %\multicolumn{3}{@ {}l}{Terms}\\ %@{text "e"} & @{text "::="} & @{text "x | K | \<Lambda>a:\<kappa>. e | \<Lambda>c:\<iota>. e | e \<sigma> | e \<gamma>"}\\ %& @{text "|"} & @{text "\<lambda>x:\<sigma>. e | e\<^isub>1 e\<^isub>2 | \<LET> x:\<sigma> = e\<^isub>1 \<IN> e\<^isub>2"}\\ %& @{text "|"} & @{text "\<CASE> e\<^isub>1 \<OF>"}$\;\overline{@{text "p \<rightarrow> e\<^isub>2"}}$ @{text "| e \<triangleright> \<gamma>"}\smallskip\\ %\multicolumn{3}{@ {}l}{Patterns}\\ %@{text "p"} & @{text "::="} & @{text "K"}$\;\overline{@{text "a:\<kappa>"}}\;\overline{@{text "c:\<iota>"}}\;\overline{@{text "x:\<sigma>"}}$\smallskip\\ %\multicolumn{3}{@ {}l}{Constants}\\ %& @{text C} & coercion constants\\ %& @{text T} & value type constructors\\ %& @{text "S\<^isub>n"} & n-ary type functions (which need to be fully applied)\\ %& @{text K} & data constructors\smallskip\\ %\multicolumn{3}{@ {}l}{Variables}\\ %& @{text a} & type variables\\ %& @{text c} & coercion variables\\ %& @{text x} & term variables\\ %\end{tabular} %\end{center} %\end{boxedminipage} %\caption{The System @{text "F\<^isub>C"} %\cite{CoreHaskell}, also often referred to as \emph{Core-Haskell}. In this %version of @{text "F\<^isub>C"} we made a modification by separating the %grammars for type kinds and coercion kinds, as well as for types and coercion %types. For this paper the interesting term-constructor is @{text "\<CASE>"}, %which binds multiple type-, coercion- and term-variables.\label{corehas}} %\end{figure}*}section {* A Short Review of the Nominal Logic Work *}text {* At its core, Nominal Isabelle is an adaption of the nominal logic work by Pitts \cite{Pitts03}. This adaptation for Isabelle/HOL is described in \cite{HuffmanUrban10} (including proofs). We shall briefly review this work to aid the description of what follows. Two central notions in the nominal logic work are sorted atoms and sort-respecting permutations of atoms. We will use the letters @{text "a, b, c, \<dots>"} to stand for atoms and @{text "p, q, \<dots>"} to stand for permutations. The purpose of atoms is to represent variables, be they bound or free. The sorts of atoms can be used to represent different kinds of variables, such as the term-, coercion- and type-variables in Core-Haskell. It is assumed that there is an infinite supply of atoms for each sort. In the interest of brevity, we shall restrict ourselves in what follows to only one sort of atoms. Permutations are bijective functions from atoms to atoms that are the identity everywhere except on a finite number of atoms. There is a two-place permutation operation written @{text "_ \<bullet> _ :: perm \<Rightarrow> \<beta> \<Rightarrow> \<beta>"} where the generic type @{text "\<beta>"} is the type of the object over which the permutation acts. In Nominal Isabelle, the identity permutation is written as @{term "0::perm"}, the composition of two permutations @{term p} and @{term q} as \mbox{@{term "p + q"}}, and the inverse permutation of @{term p} as @{text "- p"}. The permutation operation is defined over the type-hierarchy \cite{HuffmanUrban10}; for example permutations acting on products, lists, sets, functions and booleans are given by: % %\begin{equation}\label{permute} %\mbox{\begin{tabular}{@ {}c@ {\hspace{10mm}}c@ {}} %\begin{tabular}{@ {}l@ {}} %@{thm permute_prod.simps[no_vars, THEN eq_reflection]}\\[2mm] %@{thm permute_list.simps(1)[no_vars, THEN eq_reflection]}\\ %@{thm permute_list.simps(2)[no_vars, THEN eq_reflection]}\\ %\end{tabular} & %\begin{tabular}{@ {}l@ {}} %@{thm permute_set_eq[no_vars, THEN eq_reflection]}\\ %@{text "p \<bullet> f \<equiv> \<lambda>x. p \<bullet> (f (- p \<bullet> x))"}\\ %@{thm permute_bool_def[no_vars, THEN eq_reflection]} %\end{tabular} %\end{tabular}} %\end{equation} % \begin{center} \mbox{\begin{tabular}{@ {}c@ {\hspace{4mm}}c@ {\hspace{4mm}}c@ {}} \begin{tabular}{@ {}l@ {}} @{thm permute_prod.simps[no_vars, THEN eq_reflection]}\\ @{thm permute_bool_def[no_vars, THEN eq_reflection]} \end{tabular} & \begin{tabular}{@ {}l@ {}} @{thm permute_list.simps(1)[no_vars, THEN eq_reflection]}\\ @{thm permute_list.simps(2)[no_vars, THEN eq_reflection]}\\ \end{tabular} & \begin{tabular}{@ {}l@ {}} @{thm permute_set_eq[no_vars, THEN eq_reflection]}\\ @{text "p \<bullet> f \<equiv> \<lambda>x. p \<bullet> (f (- p \<bullet> x))"}\\ \end{tabular} \end{tabular}} \end{center} \noindent Concrete permutations in Nominal Isabelle are built up from swappings, written as \mbox{@{text "(a b)"}}, which are permutations that behave as follows: % \begin{center} @{text "(a b) = \<lambda>c. if a = c then b else if b = c then a else c"} \end{center} The most original aspect of the nominal logic work of Pitts is a general definition for the notion of the ``set of free variables of an object @{text "x"}''. This notion, written @{term "supp x"}, is general in the sense that it applies not only to lambda-terms ($\alpha$-equated or not), but also to lists, products, sets and even functions. The definition depends only on the permutation operation and on the notion of equality defined for the type of @{text x}, namely: % \begin{equation}\label{suppdef} @{thm supp_def[no_vars, THEN eq_reflection]} \end{equation} \noindent There is also the derived notion for when an atom @{text a} is \emph{fresh} for an @{text x}, defined as @{thm fresh_def[no_vars]}. We use for sets of atoms the abbreviation @{thm (lhs) fresh_star_def[no_vars]}, defined as @{thm (rhs) fresh_star_def[no_vars]}. A striking consequence of these definitions is that we can prove without knowing anything about the structure of @{term x} that swapping two fresh atoms, say @{text a} and @{text b}, leaves @{text x} unchanged, namely if @{text "a \<FRESH> x"} and @{text "b \<FRESH> x"} then @{term "(a \<rightleftharpoons> b) \<bullet> x"}. % %\begin{myproperty}\label{swapfreshfresh} %@{thm[mode=IfThen] swap_fresh_fresh[no_vars]} %\end{myproperty} % %While often the support of an object can be relatively easily %described, for example for atoms, products, lists, function applications, %booleans and permutations as follows %% %\begin{center} %\begin{tabular}{c@ {\hspace{10mm}}c} %\begin{tabular}{rcl} %@{term "supp a"} & $=$ & @{term "{a}"}\\ %@{term "supp (x, y)"} & $=$ & @{term "supp x \<union> supp y"}\\ %@{term "supp []"} & $=$ & @{term "{}"}\\ %@{term "supp (x#xs)"} & $=$ & @{term "supp x \<union> supp xs"}\\ %\end{tabular} %& %\begin{tabular}{rcl} %@{text "supp (f x)"} & @{text "\<subseteq>"} & @{term "supp f \<union> supp x"}\\ %@{term "supp b"} & $=$ & @{term "{}"}\\ %@{term "supp p"} & $=$ & @{term "{a. p \<bullet> a \<noteq> a}"} %\end{tabular} %\end{tabular} %\end{center} % %\noindent %in some cases it can be difficult to characterise the support precisely, and %only an approximation can be established (as for functions above). % %Reasoning about %such approximations can be simplified with the notion \emph{supports}, defined %as follows: % %\begin{definition} %A set @{text S} \emph{supports} @{text x} if for all atoms @{text a} and @{text b} %not in @{text S} we have @{term "(a \<rightleftharpoons> b) \<bullet> x = x"}. %\end{definition} % %\noindent %The main point of @{text supports} is that we can establish the following %two properties. % %\begin{myproperty}\label{supportsprop} %Given a set @{text "as"} of atoms. %{\it (i)} @{thm[mode=IfThen] supp_is_subset[where S="as", no_vars]} %{\it (ii)} @{thm supp_supports[no_vars]}. %\end{myproperty} % %Another important notion in the nominal logic work is \emph{equivariance}. %For a function @{text f}, say of type @{text "\<alpha> \<Rightarrow> \<beta>"}, to be equivariant %it is required that every permutation leaves @{text f} unchanged, that is %% %\begin{equation}\label{equivariancedef} %@{term "\<forall>p. p \<bullet> f = f"} %\end{equation} % %\noindent or equivalently that a permutation applied to the application %@{text "f x"} can be moved to the argument @{text x}. That means for equivariant %functions @{text f}, we have for all permutations @{text p}: %% %\begin{equation}\label{equivariance} %@{text "p \<bullet> f = f"} \;\;\;\textit{if and only if}\;\;\; %@{text "p \<bullet> (f x) = f (p \<bullet> x)"} %\end{equation} % %\noindent %From property \eqref{equivariancedef} and the definition of @{text supp}, we %can easily deduce that equivariant functions have empty support. There is %also a similar notion for equivariant relations, say @{text R}, namely the property %that %% %\begin{center} %@{text "x R y"} \;\;\textit{implies}\;\; @{text "(p \<bullet> x) R (p \<bullet> y)"} %\end{center} % %Using freshness, the nominal logic work provides us with general means for renaming %binders. % %\noindent While in the older version of Nominal Isabelle, we used extensively %Property~\ref{swapfreshfresh} this property to rename single binders, it %%this property proved too unwieldy for dealing with multiple binders. For such binders the following generalisations turned out to be easier to use. \begin{myproperty}\label{supppermeq} @{thm[mode=IfThen] supp_perm_eq[no_vars]} \end{myproperty} \begin{myproperty}\label{avoiding} For a finite set @{text as} and a finitely supported @{text x} with @{term "as \<sharp>* x"} and also a finitely supported @{text c}, there exists a permutation @{text p} such that @{term "(p \<bullet> as) \<sharp>* c"} and @{term "supp x \<sharp>* p"}. \end{myproperty} \noindent The idea behind the second property is that given a finite set @{text as} of binders (being bound, or fresh, in @{text x} is ensured by the assumption @{term "as \<sharp>* x"}), then there exists a permutation @{text p} such that the renamed binders @{term "p \<bullet> as"} avoid @{text c} (which can be arbitrarily chosen as long as it is finitely supported) and also @{text "p"} does not affect anything in the support of @{text x} (that is @{term "supp x \<sharp>* p"}). The last fact and Property~\ref{supppermeq} allow us to ``rename'' just the binders @{text as} in @{text x}, because @{term "p \<bullet> x = x"}. Most properties given in this section are described in detail in \cite{HuffmanUrban10} and all are formalised in Isabelle/HOL. In the next sections we will make extensive use of these properties in order to define $\alpha$-equivalence in the presence of multiple binders.*}section {* General Bindings\label{sec:binders} *}text {* In Nominal Isabelle, the user is expected to write down a specification of a term-calculus and then a reasoning infrastructure is automatically derived from this specification (remember that Nominal Isabelle is a definitional extension of Isabelle/HOL, which does not introduce any new axioms). In order to keep our work with deriving the reasoning infrastructure manageable, we will wherever possible state definitions and perform proofs on the ``user-level'' of Isabelle/HOL, as opposed to write custom ML-code. % that %generates them anew for each specification. To that end, we will consider first pairs @{text "(as, x)"} of type @{text "(atom set) \<times> \<beta>"}. These pairs are intended to represent the abstraction, or binding, of the set of atoms @{text "as"} in the body @{text "x"}. The first question we have to answer is when two pairs @{text "(as, x)"} and @{text "(bs, y)"} are $\alpha$-equivalent? (For the moment we are interested in the notion of $\alpha$-equivalence that is \emph{not} preserved by adding vacuous binders.) To answer this question, we identify four conditions: {\it (i)} given a free-atom function @{text "fa"} of type \mbox{@{text "\<beta> \<Rightarrow> atom set"}}, then @{text x} and @{text y} need to have the same set of free atoms; moreover there must be a permutation @{text p} such that {\it (ii)} @{text p} leaves the free atoms of @{text x} and @{text y} unchanged, but {\it (iii)} ``moves'' their bound names so that we obtain modulo a relation, say \mbox{@{text "_ R _"}}, two equivalent terms. We also require that {\it (iv)} @{text p} makes the sets of abstracted atoms @{text as} and @{text bs} equal. The requirements {\it (i)} to {\it (iv)} can be stated formally as the conjunction of: % \begin{equation}\label{alphaset} \begin{array}{@ {\hspace{10mm}}l@ {\hspace{5mm}}l@ {\hspace{10mm}}l@ {\hspace{5mm}}l} \multicolumn{4}{l}{@{term "(as, x) \<approx>set R fa p (bs, y)"}\hspace{2mm}@{text "\<equiv>"}}\\[1mm] \mbox{\it (i)} & @{term "fa(x) - as = fa(y) - bs"} & \mbox{\it (iii)} & @{text "(p \<bullet> x) R y"} \\ \mbox{\it (ii)} & @{term "(fa(x) - as) \<sharp>* p"} & \mbox{\it (iv)} & @{term "(p \<bullet> as) = bs"} \\ \end{array} \end{equation} % \noindent Note that this relation depends on the permutation @{text "p"}; $\alpha$-equivalence between two pairs is then the relation where we existentially quantify over this @{text "p"}. Also note that the relation is dependent on a free-atom function @{text "fa"} and a relation @{text "R"}. The reason for this extra generality is that we will use $\approx_{\,\textit{set}}$ for both ``raw'' terms and $\alpha$-equated terms. In the latter case, @{text R} will be replaced by equality @{text "="} and we will prove that @{text "fa"} is equal to @{text "supp"}. The definition in \eqref{alphaset} does not make any distinction between the order of abstracted atoms. If we want this, then we can define $\alpha$-equivalence for pairs of the form \mbox{@{text "(as, x)"}} with type @{text "(atom list) \<times> \<beta>"} as follows % \begin{equation}\label{alphalist} \begin{array}{@ {\hspace{10mm}}l@ {\hspace{5mm}}l@ {\hspace{10mm}}l@ {\hspace{5mm}}l} \multicolumn{4}{l}{@{term "(as, x) \<approx>lst R fa p (bs, y)"}\hspace{2mm}@{text "\<equiv>"}}\\[1mm] \mbox{\it (i)} & @{term "fa(x) - (set as) = fa(y) - (set bs)"} & \mbox{\it (iii)} & @{text "(p \<bullet> x) R y"}\\ \mbox{\it (ii)} & @{term "(fa(x) - set as) \<sharp>* p"} & \mbox{\it (iv)} & @{term "(p \<bullet> as) = bs"}\\ \end{array} \end{equation} % \noindent where @{term set} is the function that coerces a list of atoms into a set of atoms. Now the last clause ensures that the order of the binders matters (since @{text as} and @{text bs} are lists of atoms). If we do not want to make any difference between the order of binders \emph{and} also allow vacuous binders, that means \emph{restrict} names, then we keep sets of binders, but drop condition {\it (iv)} in \eqref{alphaset}: % \begin{equation}\label{alphares} \begin{array}{@ {\hspace{10mm}}l@ {\hspace{5mm}}l@ {\hspace{10mm}}l@ {\hspace{5mm}}l} \multicolumn{2}{l}{@{term "(as, x) \<approx>res R fa p (bs, y)"}\hspace{2mm}@{text "\<equiv>"}}\\[1mm] \mbox{\it (i)} & @{term "fa(x) - as = fa(y) - bs"} & \mbox{\it (iii)} & @{text "(p \<bullet> x) R y"}\\ \mbox{\it (ii)} & @{term "(fa(x) - as) \<sharp>* p"}\\ \end{array} \end{equation} It might be useful to consider first some examples how these definitions of $\alpha$-equivalence pan out in practice. For this consider the case of abstracting a set of atoms over types (as in type-schemes). We set @{text R} to be the usual equality @{text "="} and for @{text "fa(T)"} we define % \begin{center} @{text "fa(x) = {x}"} \hspace{5mm} @{text "fa(T\<^isub>1 \<rightarrow> T\<^isub>2) = fa(T\<^isub>1) \<union> fa(T\<^isub>2)"} \end{center} \noindent Now recall the examples shown in \eqref{ex1}, \eqref{ex2} and \eqref{ex3}. It can be easily checked that @{text "({x, y}, x \<rightarrow> y)"} and @{text "({y, x}, y \<rightarrow> x)"} are $\alpha$-equivalent according to $\approx_{\,\textit{set}}$ and $\approx_{\,\textit{res}}$ by taking @{text p} to be the swapping @{term "(x \<rightleftharpoons> y)"}. In case of @{text "x \<noteq> y"}, then @{text "([x, y], x \<rightarrow> y)"} $\not\approx_{\,\textit{list}}$ @{text "([y, x], x \<rightarrow> y)"} since there is no permutation that makes the lists @{text "[x, y]"} and @{text "[y, x]"} equal, and also leaves the type \mbox{@{text "x \<rightarrow> y"}} unchanged. Another example is @{text "({x}, x)"} $\approx_{\,\textit{res}}$ @{text "({x, y}, x)"} which holds by taking @{text p} to be the identity permutation. However, if @{text "x \<noteq> y"}, then @{text "({x}, x)"} $\not\approx_{\,\textit{set}}$ @{text "({x, y}, x)"} since there is no permutation that makes the sets @{text "{x}"} and @{text "{x, y}"} equal (similarly for $\approx_{\,\textit{list}}$). It can also relatively easily be shown that all three notions of $\alpha$-equivalence coincide, if we only abstract a single atom. In the rest of this section we are going to introduce three abstraction types. For this we define % \begin{equation} @{term "abs_set (as, x) (bs, x) \<equiv> \<exists>p. alpha_set (as, x) equal supp p (bs, x)"} \end{equation} \noindent (similarly for $\approx_{\,\textit{abs\_res}}$ and $\approx_{\,\textit{abs\_list}}$). We can show that these relations are equivalence relations. %% and equivariant. \begin{lemma}\label{alphaeq} The relations $\approx_{\,\textit{abs\_set}}$, $\approx_{\,\textit{abs\_list}}$ and $\approx_{\,\textit{abs\_res}}$ are equivalence relations. %, and if %@{term "abs_set (as, x) (bs, y)"} then also %@{term "abs_set (p \<bullet> as, p \<bullet> x) (p \<bullet> bs, p \<bullet> y)"} (similarly for the other two relations). \end{lemma} \begin{proof} Reflexivity is by taking @{text "p"} to be @{text "0"}. For symmetry we have a permutation @{text p} and for the proof obligation take @{term "-p"}. In case of transitivity, we have two permutations @{text p} and @{text q}, and for the proof obligation use @{text "q + p"}. All conditions are then by simple calculations. \end{proof} \noindent This lemma allows us to use our quotient package for introducing new types @{text "\<beta> abs_set"}, @{text "\<beta> abs_res"} and @{text "\<beta> abs_list"} representing $\alpha$-equivalence classes of pairs of type @{text "(atom set) \<times> \<beta>"} (in the first two cases) and of type @{text "(atom list) \<times> \<beta>"} (in the third case). The elements in these types will be, respectively, written as % %\begin{center} @{term "Abs_set as x"}, %\hspace{5mm} @{term "Abs_res as x"} and %\hspace{5mm} @{term "Abs_lst as x"}, %\end{center} % %\noindent indicating that a set (or list) of atoms @{text as} is abstracted in @{text x}. We will call the types \emph{abstraction types} and their elements \emph{abstractions}. The important property we need to derive is the support of abstractions, namely: \begin{theorem}[Support of Abstractions]\label{suppabs} Assuming @{text x} has finite support, then \begin{center} \begin{tabular}{l} @{thm (lhs) supp_Abs(1)[no_vars]} $=$ @{thm supp_Abs(2)[no_vars]}, and\\ @{thm supp_Abs(3)[where bs="as", no_vars]} \end{tabular} \end{center} \end{theorem} \noindent This theorem states that the bound names do not appear in the support. For brevity we omit the proof and again refer the reader to our formalisation in Isabelle/HOL (or the appendix). %\noindent %Below we will show the first equation. The others %follow by similar arguments. By definition of the abstraction type @{text "abs_set"} %we have %% %\begin{equation}\label{abseqiff} %@{thm (lhs) Abs_eq_iff(1)[where bs="as" and cs="bs", no_vars]} \;\;\text{if and only if}\;\; %@{thm (rhs) Abs_eq_iff(1)[where bs="as" and cs="bs", no_vars]} %\end{equation} % %\noindent %and also % %\begin{equation}\label{absperm} %%@%{%thm %permute_Abs[no_vars]}% %\end{equation} %\noindent %The second fact derives from the definition of permutations acting on pairs %\eqref{permute} and $\alpha$-equivalence being equivariant %(see Lemma~\ref{alphaeq}). With these two facts at our disposal, we can show %the following lemma about swapping two atoms in an abstraction. % %\begin{lemma} %@{thm[mode=IfThen] Abs_swap1(1)[where bs="as", no_vars]} %\end{lemma} % %\begin{proof} %This lemma is straightforward using \eqref{abseqiff} and observing that %the assumptions give us @{term "(a \<rightleftharpoons> b) \<bullet> (supp x - as) = (supp x - as)"}. %Moreover @{text supp} and set difference are equivariant (see \cite{HuffmanUrban10}). %\end{proof} % %\noindent %Assuming that @{text "x"} has finite support, this lemma together %with \eqref{absperm} allows us to show % %\begin{equation}\label{halfone} %@{thm Abs_supports(1)[no_vars]} %\end{equation} % %\noindent %which by Property~\ref{supportsprop} gives us ``one half'' of %Theorem~\ref{suppabs}. The ``other half'' is a bit more involved. To establish %it, we use a trick from \cite{Pitts04} and first define an auxiliary %function @{text aux}, taking an abstraction as argument: %@{thm supp_set.simps[THEN eq_reflection, no_vars]}. % %Using the second equation in \eqref{equivariance}, we can show that %@{text "aux"} is equivariant (since @{term "p \<bullet> (supp x - as) = (supp (p \<bullet> x)) - (p \<bullet> as)"}) %and therefore has empty support. %This in turn means % %\begin{center} %@{term "supp (supp_gen (Abs_set as x)) \<subseteq> supp (Abs_set as x)"} %\end{center} % %\noindent %using \eqref{suppfun}. Assuming @{term "supp x - as"} is a finite set, %we further obtain % %\begin{equation}\label{halftwo} %@{thm (concl) Abs_supp_subset1(1)[no_vars]} %\end{equation} % %\noindent %since for finite sets of atoms, @{text "bs"}, we have %@{thm (concl) supp_finite_atom_set[where S="bs", no_vars]}. %Finally, taking \eqref{halfone} and \eqref{halftwo} together establishes %Theorem~\ref{suppabs}. The method of first considering abstractions of the form @{term "Abs_set as x"} etc is motivated by the fact that we can conveniently establish at the Isabelle/HOL level properties about them. It would be laborious to write custom ML-code that derives automatically such properties for every term-constructor that binds some atoms. Also the generality of the definitions for $\alpha$-equivalence will help us in the next sections.*}section {* Specifying General Bindings\label{sec:spec} *}text {* Our choice of syntax for specifications is influenced by the existing datatype package of Isabelle/HOL %\cite{Berghofer99} and by the syntax of the Ott-tool \cite{ott-jfp}. For us a specification of a term-calculus is a collection of (possibly mutual recursive) type declarations, say @{text "ty\<AL>\<^isub>1, \<dots>, ty\<AL>\<^isub>n"}, and an associated collection of binding functions, say @{text "bn\<AL>\<^isub>1, \<dots>, bn\<AL>\<^isub>m"}. The syntax in Nominal Isabelle for such specifications is roughly as follows: % \begin{equation}\label{scheme} \mbox{\begin{tabular}{@ {}p{2.5cm}l} type \mbox{declaration part} & $\begin{cases} \mbox{\small\begin{tabular}{l} \isacommand{nominal\_datatype} @{text "ty\<AL>\<^isub>1 = \<dots>"}\\ \isacommand{and} @{text "ty\<AL>\<^isub>2 = \<dots>"}\\ \raisebox{2mm}{$\ldots$}\\[-2mm] \isacommand{and} @{text "ty\<AL>\<^isub>n = \<dots>"}\\ \end{tabular}} \end{cases}$\\ binding \mbox{function part} & $\begin{cases} \mbox{\small\begin{tabular}{l} \isacommand{binder} @{text "bn\<AL>\<^isub>1"} \isacommand{and} \ldots \isacommand{and} @{text "bn\<AL>\<^isub>m"}\\ \isacommand{where}\\ \raisebox{2mm}{$\ldots$}\\[-2mm] \end{tabular}} \end{cases}$\\ \end{tabular}} \end{equation} \noindent Every type declaration @{text ty}$^\alpha_{1..n}$ consists of a collection of term-constructors, each of which comes with a list of labelled types that stand for the types of the arguments of the term-constructor. For example a term-constructor @{text "C\<^sup>\<alpha>"} might be specified with \begin{center} @{text "C\<^sup>\<alpha> label\<^isub>1::ty"}$'_1$ @{text "\<dots> label\<^isub>l::ty"}$'_l\;\;$ @{text "binding_clauses"} \end{center} \noindent whereby some of the @{text ty}$'_{1..l}$ %%(or their components) can be contained in the collection of @{text ty}$^\alpha_{1..n}$ declared in \eqref{scheme}. In this case we will call the corresponding argument a \emph{recursive argument} of @{text "C\<^sup>\<alpha>"}. %The types of such recursive %arguments need to satisfy a ``positivity'' %restriction, which ensures that the type has a set-theoretic semantics %\cite{Berghofer99}. The labels annotated on the types are optional. Their purpose is to be used in the (possibly empty) list of \emph{binding clauses}, which indicate the binders and their scope in a term-constructor. They come in three \emph{modes}: % \begin{center} \begin{tabular}{@ {}l@ {}} \isacommand{bind} {\it binders} \isacommand{in} {\it bodies}\;\;\;\; \isacommand{bind (set)} {\it binders} \isacommand{in} {\it bodies}\;\;\;\; \isacommand{bind (res)} {\it binders} \isacommand{in} {\it bodies} \end{tabular} \end{center} % \noindent The first mode is for binding lists of atoms (the order of binders matters); the second is for sets of binders (the order does not matter, but the cardinality does) and the last is for sets of binders (with vacuous binders preserving $\alpha$-equivalence). As indicated, the labels in the ``\isacommand{in}-part'' of a binding clause will be called \emph{bodies}; the ``\isacommand{bind}-part'' will be called \emph{binders}. In contrast to Ott, we allow multiple labels in binders and bodies. %For example we allow %binding clauses of the form: % %\begin{center} %\begin{tabular}{@ {}ll@ {}} %@{text "Foo\<^isub>1 x::name y::name t::trm s::trm"} & % \isacommand{bind} @{text "x y"} \isacommand{in} @{text "t s"}\\ %@{text "Foo\<^isub>2 x::name y::name t::trm s::trm"} & % \isacommand{bind} @{text "x y"} \isacommand{in} @{text "t"}, % \isacommand{bind} @{text "x y"} \isacommand{in} @{text "s"}\\ %\end{tabular} %\end{center} \noindent %Similarly for the other binding modes. %Interestingly, in case of \isacommand{bind (set)} %and \isacommand{bind (res)} the binding clauses above will make a difference to the semantics %of the specifications (the corresponding $\alpha$-equivalence will differ). We will %show this later with an example. There are also some restrictions we need to impose on our binding clauses in comparison to the ones of Ott. The main idea behind these restrictions is that we obtain a sensible notion of $\alpha$-equivalence where it is ensured that within a given scope an atom occurrence cannot be both bound and free at the same time. The first restriction is that a body can only occur in \emph{one} binding clause of a term constructor (this ensures that the bound atoms of a body cannot be free at the same time by specifying an alternative binder for the same body). For binders we distinguish between \emph{shallow} and \emph{deep} binders. Shallow binders are just labels. The restriction we need to impose on them is that in case of \isacommand{bind (set)} and \isacommand{bind (res)} the labels must either refer to atom types or to sets of atom types; in case of \isacommand{bind} the labels must refer to atom types or lists of atom types. Two examples for the use of shallow binders are the specification of lambda-terms, where a single name is bound, and type-schemes, where a finite set of names is bound: \begin{center}\small \begin{tabular}{@ {}c@ {\hspace{10mm}}c@ {}} \begin{tabular}{@ {}l} \isacommand{nominal\_datatype} @{text lam} $=$\\ \hspace{5mm}\phantom{$\mid$}~@{text "Var name"}\\ \hspace{5mm}$\mid$~@{text "App lam lam"}\\ \hspace{5mm}$\mid$~@{text "Lam x::name t::lam"}\\ \hspace{24mm}\isacommand{bind} @{text x} \isacommand{in} @{text t}\\ \end{tabular} & \begin{tabular}{@ {}l@ {}} \isacommand{nominal\_datatype}~@{text ty} $=$\\ \hspace{5mm}\phantom{$\mid$}~@{text "TVar name"}\\ \hspace{5mm}$\mid$~@{text "TFun ty ty"}\\ \isacommand{and}~@{text "tsc = All xs::(name fset) T::ty"}\\ \hspace{29mm}\isacommand{bind (res)} @{text xs} \isacommand{in} @{text T}\\ \end{tabular} \end{tabular} \end{center} \noindent In these specifications @{text "name"} refers to an atom type, and @{text "fset"} to the type of finite sets. Note that for @{text lam} it does not matter which binding mode we use. The reason is that we bind only a single @{text name}. However, having \isacommand{bind (set)} or \isacommand{bind} in the second case makes a difference to the semantics of the specification (which we will define in the next section). A \emph{deep} binder uses an auxiliary binding function that ``picks'' out the atoms in one argument of the term-constructor, which can be bound in other arguments and also in the same argument (we will call such binders \emph{recursive}, see below). The binding functions are expected to return either a set of atoms (for \isacommand{bind (set)} and \isacommand{bind (res)}) or a list of atoms (for \isacommand{bind}). They can be defined by recursion over the corresponding type; the equations must be given in the binding function part of the scheme shown in \eqref{scheme}. For example a term-calculus containing @{text "Let"}s with tuple patterns might be specified as: % \begin{equation}\label{letpat} \mbox{\small% \begin{tabular}{l} \isacommand{nominal\_datatype} @{text trm} $=$\\ \hspace{5mm}\phantom{$\mid$}~@{term "Var name"}\\ \hspace{5mm}$\mid$~@{term "App trm trm"}\\ \hspace{5mm}$\mid$~@{text "Lam x::name t::trm"} \;\;\isacommand{bind} @{text x} \isacommand{in} @{text t}\\ \hspace{5mm}$\mid$~@{text "Let p::pat trm t::trm"} \;\;\isacommand{bind} @{text "bn(p)"} \isacommand{in} @{text t}\\ \isacommand{and} @{text pat} $=$ @{text PNil} $\mid$~@{text "PVar name"} $\mid$~@{text "PTup pat pat"}\\ \isacommand{binder}~@{text "bn::pat \<Rightarrow> atom list"}\\ \isacommand{where}~@{text "bn(PNil) = []"}\\ \hspace{5mm}$\mid$~@{text "bn(PVar x) = [atom x]"}\\ \hspace{5mm}$\mid$~@{text "bn(PTup p\<^isub>1 p\<^isub>2) = bn(p\<^isub>1) @ bn(p\<^isub>2)"}\smallskip\\ \end{tabular}} \end{equation} % \noindent In this specification the function @{text "bn"} determines which atoms of the pattern @{text p} are bound in the argument @{text "t"}. Note that in the second-last @{text bn}-clause the function @{text "atom"} coerces a name into the generic atom type of Nominal Isabelle \cite{HuffmanUrban10}. This allows us to treat binders of different atom type uniformly. As said above, for deep binders we allow binding clauses such as % %\begin{center} %\begin{tabular}{ll} @{text "Bar p::pat t::trm"} %%%& \isacommand{bind} @{text "bn(p)"} \isacommand{in} @{text "p t"} %%\\ %\end{tabular} %\end{center} % %\noindent where the argument of the deep binder also occurs in the body. We call such binders \emph{recursive}. To see the purpose of such recursive binders, compare ``plain'' @{text "Let"}s and @{text "Let_rec"}s in the following specification: % \begin{equation}\label{letrecs} \mbox{\small% \begin{tabular}{@ {}l@ {}} \isacommand{nominal\_datatype}~@{text "trm ="}~\ldots\\ \hspace{5mm}$\mid$~@{text "Let as::assn t::trm"} \;\;\isacommand{bind} @{text "bn(as)"} \isacommand{in} @{text t}\\ \hspace{5mm}$\mid$~@{text "Let_rec as::assn t::trm"} \;\;\isacommand{bind} @{text "bn(as)"} \isacommand{in} @{text "as t"}\\ \isacommand{and} @{text "assn"} $=$ @{text "ANil"} $\mid$~@{text "ACons name trm assn"}\\ \isacommand{binder} @{text "bn::assn \<Rightarrow> atom list"}\\ \isacommand{where}~@{text "bn(ANil) = []"}\\ \hspace{5mm}$\mid$~@{text "bn(ACons a t as) = [atom a] @ bn(as)"}\\ \end{tabular}} \end{equation} % \noindent The difference is that with @{text Let} we only want to bind the atoms @{text "bn(as)"} in the term @{text t}, but with @{text "Let_rec"} we also want to bind the atoms inside the assignment. This difference has consequences for the associated notions of free-atoms and $\alpha$-equivalence. To make sure that atoms bound by deep binders cannot be free at the same time, we cannot have more than one binding function for a deep binder. Consequently we exclude specifications such as % \begin{center} \begin{tabular}{@ {}l@ {\hspace{2mm}}l@ {}} @{text "Baz\<^isub>1 p::pat t::trm"} & \isacommand{bind} @{text "bn\<^isub>1(p) bn\<^isub>2(p)"} \isacommand{in} @{text t}\\ @{text "Baz\<^isub>2 p::pat t\<^isub>1::trm t\<^isub>2::trm"} & \isacommand{bind} @{text "bn\<^isub>1(p)"} \isacommand{in} @{text "t\<^isub>1"}, \isacommand{bind} @{text "bn\<^isub>2(p)"} \isacommand{in} @{text "t\<^isub>2"}\\ \end{tabular} \end{center} \noindent Otherwise it is possible that @{text "bn\<^isub>1"} and @{text "bn\<^isub>2"} pick out different atoms to become bound, respectively be free, in @{text "p"}. (Since the Ott-tool does not derive a reasoning infrastructure for $\alpha$-equated terms with deep binders, it can permit such specifications.) We also need to restrict the form of the binding functions in order to ensure the @{text "bn"}-functions can be defined for $\alpha$-equated terms. The main restriction is that we cannot return an atom in a binding function that is also bound in the corresponding term-constructor. That means in \eqref{letpat} that the term-constructors @{text PVar} and @{text PTup} may not have a binding clause (all arguments are used to define @{text "bn"}). In contrast, in case of \eqref{letrecs} the term-constructor @{text ACons} may have a binding clause involving the argument @{text t} (the only one that is \emph{not} used in the definition of the binding function). This restriction is sufficient for lifting the binding function to $\alpha$-equated terms. In the version of Nominal Isabelle described here, we also adopted the restriction from the Ott-tool that binding functions can only return: the empty set or empty list (as in case @{text PNil}), a singleton set or singleton list containing an atom (case @{text PVar}), or unions of atom sets or appended atom lists (case @{text PTup}). This restriction will simplify some automatic definitions and proofs later on. In order to simplify our definitions of free atoms and $\alpha$-equivalence, we shall assume specifications of term-calculi are implicitly \emph{completed}. By this we mean that for every argument of a term-constructor that is \emph{not} already part of a binding clause given by the user, we add implicitly a special \emph{empty} binding clause, written \isacommand{bind}~@{term "{}"}~\isacommand{in}~@{text "labels"}. In case of the lambda-terms, the completion produces \begin{center}\small \begin{tabular}{@ {}l@ {\hspace{-1mm}}} \isacommand{nominal\_datatype} @{text lam} =\\ \hspace{5mm}\phantom{$\mid$}~@{text "Var x::name"} \;\;\isacommand{bind}~@{term "{}"}~\isacommand{in}~@{text "x"}\\ \hspace{5mm}$\mid$~@{text "App t\<^isub>1::lam t\<^isub>2::lam"} \;\;\isacommand{bind}~@{term "{}"}~\isacommand{in}~@{text "t\<^isub>1 t\<^isub>2"}\\ \hspace{5mm}$\mid$~@{text "Lam x::name t::lam"} \;\;\isacommand{bind}~@{text x} \isacommand{in} @{text t}\\ \end{tabular} \end{center} \noindent The point of completion is that we can make definitions over the binding clauses and be sure to have captured all arguments of a term constructor. *}section {* Alpha-Equivalence and Free Atoms\label{sec:alpha} *}text {* Having dealt with all syntax matters, the problem now is how we can turn specifications into actual type definitions in Isabelle/HOL and then establish a reasoning infrastructure for them. As Pottier and Cheney pointed out \cite{Pottier06,Cheney05}, just re-arranging the arguments of term-constructors so that binders and their bodies are next to each other will result in inadequate representations in cases like @{text "Let x\<^isub>1 = t\<^isub>1\<dots>x\<^isub>n = t\<^isub>n in s"}. Therefore we will first extract ``raw'' datatype definitions from the specification and then define explicitly an $\alpha$-equivalence relation over them. We subsequently quotient the datatypes according to our $\alpha$-equivalence. The ``raw'' datatype definition can be obtained by stripping off the binding clauses and the labels from the types. We also have to invent new names for the types @{text "ty\<^sup>\<alpha>"} and term-constructors @{text "C\<^sup>\<alpha>"} given by the user. In our implementation we just use the affix ``@{text "_raw"}''. But for the purpose of this paper, we use the superscript @{text "_\<^sup>\<alpha>"} to indicate that a notion is given for $\alpha$-equivalence classes and leave it out for the corresponding notion given on the ``raw'' level. So for example we have @{text "ty\<^sup>\<alpha> \<mapsto> ty"} and @{text "C\<^sup>\<alpha> \<mapsto> C"} where @{term ty} is the type used in the quotient construction for @{text "ty\<^sup>\<alpha>"} and @{text "C"} is the term-constructor on the ``raw'' type @{text "ty"}. %The resulting datatype definition is legal in Isabelle/HOL provided the datatypes are %non-empty and the types in the constructors only occur in positive %position (see \cite{Berghofer99} for an in-depth description of the datatype package %in Isabelle/HOL). We subsequently define each of the user-specified binding functions @{term "bn"}$_{1..m}$ by recursion over the corresponding raw datatype. We can also easily define permutation operations by recursion so that for each term constructor @{text "C"} we have that % \begin{equation}\label{ceqvt} @{text "p \<bullet> (C z\<^isub>1 \<dots> z\<^isub>n) = C (p \<bullet> z\<^isub>1) \<dots> (p \<bullet> z\<^isub>n)"} \end{equation} The first non-trivial step we have to perform is the generation of free-atom functions from the specification. For the \emph{raw} types @{text "ty"}$_{1..n}$ we define the free-atom functions % %\begin{equation}\label{fvars} @{text "fa_ty\<^isub>"}$_{1..n}$ %\end{equation} % %\noindent by recursion. We define these functions together with auxiliary free-atom functions for the binding functions. Given raw binding functions @{text "bn"}$_{1..m}$ we define % %\begin{center} @{text "fa_bn\<^isub>"}$_{1..m}$. %\end{center} % %\noindent The reason for this setup is that in a deep binder not all atoms have to be bound, as we saw in the example with ``plain'' @{text Let}s. We need therefore a function that calculates those free atoms in a deep binder. While the idea behind these free-atom functions is clear (they just collect all atoms that are not bound), because of our rather complicated binding mechanisms their definitions are somewhat involved. Given a term-constructor @{text "C"} of type @{text ty} and some associated binding clauses @{text "bc\<^isub>1\<dots>bc\<^isub>k"}, the result of @{text "fa_ty (C z\<^isub>1 \<dots> z\<^isub>n)"} will be the union @{text "fa(bc\<^isub>1) \<union> \<dots> \<union> fa(bc\<^isub>k)"} where we will define below what @{text "fa"} for a binding clause means. We only show the details for the mode \isacommand{bind (set)} (the other modes are similar). Suppose the binding clause @{text bc\<^isub>i} is of the form % %\begin{center} \mbox{\isacommand{bind (set)} @{text "b\<^isub>1\<dots>b\<^isub>p"} \isacommand{in} @{text "d\<^isub>1\<dots>d\<^isub>q"}} %\end{center} % %\noindent in which the body-labels @{text "d"}$_{1..q}$ refer to types @{text ty}$_{1..q}$, and the binders @{text b}$_{1..p}$ either refer to labels of atom types (in case of shallow binders) or to binding functions taking a single label as argument (in case of deep binders). Assuming @{text "D"} stands for the set of free atoms of the bodies, @{text B} for the set of binding atoms in the binders and @{text "B'"} for the set of free atoms in non-recursive deep binders, then the free atoms of the binding clause @{text bc\<^isub>i} are\\[-2mm] % \begin{equation}\label{fadef} \mbox{@{text "fa(bc\<^isub>i) \<equiv> (D - B) \<union> B'"}}. \end{equation} % \noindent The set @{text D} is formally defined as % %\begin{center} @{text "D \<equiv> fa_ty\<^isub>1 d\<^isub>1 \<union> ... \<union> fa_ty\<^isub>q d\<^isub>q"} %\end{center} % %\noindent where in case @{text "d\<^isub>i"} refers to one of the raw types @{text "ty"}$_{1..n}$ from the specification, the function @{text "fa_ty\<^isub>i"} is the corresponding free-atom function we are defining by recursion; %(see \eqref{fvars}); otherwise we set @{text "fa_ty\<^isub>i d\<^isub>i = supp d\<^isub>i"}. In order to formally define the set @{text B} we use the following auxiliary @{text "bn"}-functions for atom types to which shallow binders may refer\\[-4mm] % %\begin{center} %\begin{tabular}{r@ {\hspace{2mm}}c@ {\hspace{2mm}}l} %@{text "bn_atom a"} & @{text "\<equiv>"} & @{text "{atom a}"}\\ %@{text "bn_atom_set as"} & @{text "\<equiv>"} & @{text "atoms as"}\\ %@{text "bn_atom_list as"} & @{text "\<equiv>"} & @{text "atoms (set as)"} %\end{tabular} %\end{center} % \begin{center} @{text "bn\<^bsub>atom\<^esub> a \<equiv> {atom a}"}\hfill @{text "bn\<^bsub>atom_set\<^esub> as \<equiv> atoms as"}\hfill @{text "bn\<^bsub>atom_list\<^esub> as \<equiv> atoms (set as)"} \end{center} % \noindent Like the function @{text atom}, the function @{text "atoms"} coerces a set of atoms to a set of the generic atom type. %It is defined as @{text "atoms as \<equiv> {atom a | a \<in> as}"}. The set @{text B} is then formally defined as\\[-4mm] % \begin{center} @{text "B \<equiv> bn_ty\<^isub>1 b\<^isub>1 \<union> ... \<union> bn_ty\<^isub>p b\<^isub>p"} \end{center} % \noindent where we use the auxiliary binding functions for shallow binders. The set @{text "B'"} collects all free atoms in non-recursive deep binders. Let us assume these binders in @{text "bc\<^isub>i"} are % %\begin{center} \mbox{@{text "bn\<^isub>1 l\<^isub>1, \<dots>, bn\<^isub>r l\<^isub>r"}} %\end{center} % %\noindent with @{text "l"}$_{1..r}$ $\subseteq$ @{text "b"}$_{1..p}$ and none of the @{text "l"}$_{1..r}$ being among the bodies @{text "d"}$_{1..q}$. The set @{text "B'"} is defined as\\[-5mm] % \begin{center} @{text "B' \<equiv> fa_bn\<^isub>1 l\<^isub>1 \<union> ... \<union> fa_bn\<^isub>r l\<^isub>r"}\\[-9mm] \end{center} % \noindent This completes the definition of the free-atom functions @{text "fa_ty"}$_{1..n}$. Note that for non-recursive deep binders, we have to add in \eqref{fadef} the set of atoms that are left unbound by the binding functions @{text "bn"}$_{1..m}$. We used for the definition of this set the functions @{text "fa_bn"}$_{1..m}$, which are also defined by mutual recursion. Assume the user specified a @{text bn}-clause of the form % %\begin{center} @{text "bn (C z\<^isub>1 \<dots> z\<^isub>s) = rhs"} %\end{center} % %\noindent where the @{text "z"}$_{1..s}$ are of types @{text "ty"}$_{1..s}$. For each of the arguments we calculate the free atoms as follows: % \begin{center} \begin{tabular}{c@ {\hspace{2mm}}p{0.9\textwidth}} $\bullet$ & @{term "fa_ty\<^isub>i z\<^isub>i"} provided @{text "z\<^isub>i"} does not occur in @{text "rhs"} (that means nothing is bound in @{text "z\<^isub>i"} by the binding function),\\ $\bullet$ & @{term "fa_bn\<^isub>i z\<^isub>i"} provided @{text "z\<^isub>i"} occurs in @{text "rhs"} with the recursive call @{text "bn\<^isub>i z\<^isub>i"}, and\\ $\bullet$ & @{term "{}"} provided @{text "z\<^isub>i"} occurs in @{text "rhs"}, but without a recursive call. \end{tabular} \end{center} % \noindent For defining @{text "fa_bn (C z\<^isub>1 \<dots> z\<^isub>n)"} we just union up all these sets. To see how these definitions work in practice, let us reconsider the term-constructors @{text "Let"} and @{text "Let_rec"} shown in \eqref{letrecs} together with the term-constructors for assignments @{text "ANil"} and @{text "ACons"}. Since there is a binding function defined for assignments, we have three free-atom functions, namely @{text "fa\<^bsub>trm\<^esub>"}, @{text "fa\<^bsub>assn\<^esub>"} and @{text "fa\<^bsub>bn\<^esub>"} as follows: % \begin{center}\small \begin{tabular}{@ {}l@ {\hspace{1mm}}c@ {\hspace{1mm}}l@ {}} @{text "fa\<^bsub>trm\<^esub> (Let as t)"} & @{text "="} & @{text "(fa\<^bsub>trm\<^esub> t - set (bn as)) \<union> fa\<^bsub>bn\<^esub> as"}\\ @{text "fa\<^bsub>trm\<^esub> (Let_rec as t)"} & @{text "="} & @{text "(fa\<^bsub>assn\<^esub> as \<union> fa\<^bsub>trm\<^esub> t) - set (bn as)"}\\[1mm] @{text "fa\<^bsub>assn\<^esub> (ANil)"} & @{text "="} & @{term "{}"}\\ @{text "fa\<^bsub>assn\<^esub> (ACons a t as)"} & @{text "="} & @{text "(supp a) \<union> (fa\<^bsub>trm\<^esub> t) \<union> (fa\<^bsub>assn\<^esub> as)"}\\[1mm] @{text "fa\<^bsub>bn\<^esub> (ANil)"} & @{text "="} & @{term "{}"}\\ @{text "fa\<^bsub>bn\<^esub> (ACons a t as)"} & @{text "="} & @{text "(fa\<^bsub>trm\<^esub> t) \<union> (fa\<^bsub>bn\<^esub> as)"} \end{tabular} \end{center} \noindent Recall that @{text ANil} and @{text "ACons"} have no binding clause in the specification. The corresponding free-atom function @{text "fa\<^bsub>assn\<^esub>"} therefore returns all free atoms of an assignment (in case of @{text "ACons"}, they are given in terms of @{text supp}, @{text "fa\<^bsub>trm\<^esub>"} and @{text "fa\<^bsub>assn\<^esub>"}). The binding only takes place in @{text Let} and @{text "Let_rec"}. In case of @{text "Let"}, the binding clause specifies that all atoms given by @{text "set (bn as)"} have to be bound in @{text t}. Therefore we have to subtract @{text "set (bn as)"} from @{text "fa\<^bsub>trm\<^esub> t"}. However, we also need to add all atoms that are free in @{text "as"}. This is in contrast with @{text "Let_rec"} where we have a recursive binder to bind all occurrences of the atoms in @{text "set (bn as)"} also inside @{text "as"}. Therefore we have to subtract @{text "set (bn as)"} from both @{text "fa\<^bsub>trm\<^esub> t"} and @{text "fa\<^bsub>assn\<^esub> as"}. %Like the function @{text "bn"}, the function @{text "fa\<^bsub>bn\<^esub>"} traverses the %list of assignments, but instead returns the free atoms, which means in this %example the free atoms in the argument @{text "t"}. An interesting point in this example is that a ``naked'' assignment (@{text "ANil"} or @{text "ACons"}) does not bind any atoms, even if the binding function is specified over assignments. Only in the context of a @{text Let} or @{text "Let_rec"}, where the binding clauses are given, will some atoms actually become bound. This is a phenomenon that has also been pointed out in \cite{ott-jfp}. For us this observation is crucial, because we would not be able to lift the @{text "bn"}-functions to $\alpha$-equated terms if they act on atoms that are bound. In that case, these functions would \emph{not} respect $\alpha$-equivalence. Next we define the $\alpha$-equivalence relations for the raw types @{text "ty"}$_{1..n}$ from the specification. We write them as % %\begin{center} @{text "\<approx>ty"}$_{1..n}$. %\end{center} % %\noindent Like with the free-atom functions, we also need to define auxiliary $\alpha$-equivalence relations % %\begin{center} @{text "\<approx>bn\<^isub>"}$_{1..m}$ %\end{center} % %\noindent for the binding functions @{text "bn"}$_{1..m}$, To simplify our definitions we will use the following abbreviations for \emph{compound equivalence relations} and \emph{compound free-atom functions} acting on tuples. % \begin{center} \begin{tabular}{r@ {\hspace{2mm}}c@ {\hspace{2mm}}l} @{text "(x\<^isub>1,\<dots>, x\<^isub>n) (R\<^isub>1,\<dots>, R\<^isub>n) (x\<PRIME>\<^isub>1,\<dots>, x\<PRIME>\<^isub>n)"} & @{text "\<equiv>"} & @{text "x\<^isub>1 R\<^isub>1 x\<PRIME>\<^isub>1 \<and> \<dots> \<and> x\<^isub>n R\<^isub>n x\<PRIME>\<^isub>n"}\\ @{text "(fa\<^isub>1,\<dots>, fa\<^isub>n) (x\<^isub>1,\<dots>, x\<^isub>n)"} & @{text "\<equiv>"} & @{text "fa\<^isub>1 x\<^isub>1 \<union> \<dots> \<union> fa\<^isub>n x\<^isub>n"}\\ \end{tabular} \end{center} The $\alpha$-equivalence relations are defined as inductive predicates having a single clause for each term-constructor. Assuming a term-constructor @{text C} is of type @{text ty} and has the binding clauses @{term "bc"}$_{1..k}$, then the $\alpha$-equivalence clause has the form % \begin{center} \mbox{\infer{@{text "C z\<^isub>1 \<dots> z\<^isub>n \<approx>ty C z\<PRIME>\<^isub>1 \<dots> z\<PRIME>\<^isub>n"}} {@{text "prems(bc\<^isub>1) \<dots> prems(bc\<^isub>k)"}}} \end{center} \noindent The task below is to specify what the premises of a binding clause are. As a special instance, we first treat the case where @{text "bc\<^isub>i"} is the empty binding clause of the form % \begin{center} \mbox{\isacommand{bind (set)} @{term "{}"} \isacommand{in} @{text "d\<^isub>1\<dots>d\<^isub>q"}.} \end{center} \noindent In this binding clause no atom is bound and we only have to $\alpha$-relate the bodies. For this we build first the tuples @{text "D \<equiv> (d\<^isub>1,\<dots>, d\<^isub>q)"} and @{text "D' \<equiv> (d\<PRIME>\<^isub>1,\<dots>, d\<PRIME>\<^isub>q)"} whereby the labels @{text "d"}$_{1..q}$ refer to arguments @{text "z"}$_{1..n}$ and respectively @{text "d\<PRIME>"}$_{1..q}$ to @{text "z\<PRIME>"}$_{1..n}$. In order to relate two such tuples we define the compound $\alpha$-equivalence relation @{text "R"} as follows % \begin{equation}\label{rempty} \mbox{@{text "R \<equiv> (R\<^isub>1,\<dots>, R\<^isub>q)"}} \end{equation} \noindent with @{text "R\<^isub>i"} being @{text "\<approx>ty\<^isub>i"} if the corresponding labels @{text "d\<^isub>i"} and @{text "d\<PRIME>\<^isub>i"} refer to a recursive argument of @{text C} with type @{text "ty\<^isub>i"}; otherwise we take @{text "R\<^isub>i"} to be the equality @{text "="}. This lets us define the premise for an empty binding clause succinctly as @{text "prems(bc\<^isub>i) \<equiv> D R D'"}, which can be unfolded to the series of premises % %\begin{center} @{text "d\<^isub>1 R\<^isub>1 d\<PRIME>\<^isub>1 \<dots> d\<^isub>q R\<^isub>q d\<PRIME>\<^isub>q"}. %\end{center} % %\noindent We will use the unfolded version in the examples below. Now suppose the binding clause @{text "bc\<^isub>i"} is of the general form % \begin{equation}\label{nonempty} \mbox{\isacommand{bind (set)} @{text "b\<^isub>1\<dots>b\<^isub>p"} \isacommand{in} @{text "d\<^isub>1\<dots>d\<^isub>q"}.} \end{equation} \noindent In this case we define a premise @{text P} using the relation $\approx_{\,\textit{set}}$ given in Section~\ref{sec:binders} (similarly $\approx_{\,\textit{res}}$ and $\approx_{\,\textit{list}}$ for the other binding modes). This premise defines $\alpha$-equivalence of two abstractions involving multiple binders. As above, we first build the tuples @{text "D"} and @{text "D'"} for the bodies @{text "d"}$_{1..q}$, and the corresponding compound $\alpha$-relation @{text "R"} (shown in \eqref{rempty}). For $\approx_{\,\textit{set}}$ we also need a compound free-atom function for the bodies defined as % \begin{center} \mbox{@{text "fa \<equiv> (fa_ty\<^isub>1,\<dots>, fa_ty\<^isub>q)"}} \end{center} \noindent with the assumption that the @{text "d"}$_{1..q}$ refer to arguments of types @{text "ty"}$_{1..q}$. The last ingredient we need are the sets of atoms bound in the bodies. For this we take \begin{center} @{text "B \<equiv> bn_ty\<^isub>1 b\<^isub>1 \<union> \<dots> \<union> bn_ty\<^isub>p b\<^isub>p"}\;.\\ \end{center} \noindent Similarly for @{text "B'"} using the labels @{text "b\<PRIME>"}$_{1..p}$. This lets us formally define the premise @{text P} for a non-empty binding clause as: % \begin{center} \mbox{@{term "P \<equiv> \<exists>p. (B, D) \<approx>set R fa p (B', D')"}}\;. \end{center} \noindent This premise accounts for $\alpha$-equivalence of the bodies of the binding clause. However, in case the binders have non-recursive deep binders, this premise is not enough: we also have to ``propagate'' $\alpha$-equivalence inside the structure of these binders. An example is @{text "Let"} where we have to make sure the right-hand sides of assignments are $\alpha$-equivalent. For this we use relations @{text "\<approx>bn"}$_{1..m}$ (which we will formally define shortly). Let us assume the non-recursive deep binders in @{text "bc\<^isub>i"} are % %\begin{center} @{text "bn\<^isub>1 l\<^isub>1, \<dots>, bn\<^isub>r l\<^isub>r"}. %\end{center} % %\noindent The tuple @{text L} is then @{text "(l\<^isub>1,\<dots>,l\<^isub>r)"} (similarly @{text "L'"}) and the compound equivalence relation @{text "R'"} is @{text "(\<approx>bn\<^isub>1,\<dots>,\<approx>bn\<^isub>r)"}. All premises for @{text "bc\<^isub>i"} are then given by % \begin{center} @{text "prems(bc\<^isub>i) \<equiv> P \<and> L R' L'"} \end{center} \noindent The auxiliary $\alpha$-equivalence relations @{text "\<approx>bn"}$_{1..m}$ in @{text "R'"} are defined as follows: assuming a @{text bn}-clause is of the form % %\begin{center} @{text "bn (C z\<^isub>1 \<dots> z\<^isub>s) = rhs"} %\end{center} % %\noindent where the @{text "z"}$_{1..s}$ are of types @{text "ty"}$_{1..s}$, then the corresponding $\alpha$-equivalence clause for @{text "\<approx>bn"} has the form % \begin{center} \mbox{\infer{@{text "C z\<^isub>1 \<dots> z\<^isub>s \<approx>bn C z\<PRIME>\<^isub>1 \<dots> z\<PRIME>\<^isub>s"}} {@{text "z\<^isub>1 R\<^isub>1 z\<PRIME>\<^isub>1 \<dots> z\<^isub>s R\<^isub>s z\<PRIME>\<^isub>s"}}} \end{center} \noindent In this clause the relations @{text "R"}$_{1..s}$ are given by \begin{center} \begin{tabular}{c@ {\hspace{2mm}}p{0.9\textwidth}} $\bullet$ & @{text "z\<^isub>i \<approx>ty z\<PRIME>\<^isub>i"} provided @{text "z\<^isub>i"} does not occur in @{text rhs} and is a recursive argument of @{text C},\\ $\bullet$ & @{text "z\<^isub>i = z\<PRIME>\<^isub>i"} provided @{text "z\<^isub>i"} does not occur in @{text rhs} and is a non-recursive argument of @{text C},\\ $\bullet$ & @{text "z\<^isub>i \<approx>bn\<^isub>i z\<PRIME>\<^isub>i"} provided @{text "z\<^isub>i"} occurs in @{text rhs} with the recursive call @{text "bn\<^isub>i x\<^isub>i"} and\\ $\bullet$ & @{text True} provided @{text "z\<^isub>i"} occurs in @{text rhs} but without a recursive call. \end{tabular} \end{center} \noindent This completes the definition of $\alpha$-equivalence. As a sanity check, we can show that the premises of empty binding clauses are a special case of the clauses for non-empty ones (we just have to unfold the definition of $\approx_{\,\textit{set}}$ and take @{text "0"} for the existentially quantified permutation). Again let us take a look at a concrete example for these definitions. For \eqref{letrecs} we have three relations $\approx_{\textit{trm}}$, $\approx_{\textit{assn}}$ and $\approx_{\textit{bn}}$ with the following clauses: \begin{center}\small \begin{tabular}{@ {}c @ {}} \infer{@{text "Let as t \<approx>\<^bsub>trm\<^esub> Let as' t'"}} {@{term "\<exists>p. (bn as, t) \<approx>lst alpha_trm fa_trm p (bn as', t')"} & @{text "as \<approx>\<^bsub>bn\<^esub> as'"}}\smallskip\\ \makebox[0mm]{\infer{@{text "Let_rec as t \<approx>\<^bsub>trm\<^esub> Let_rec as' t'"}} {@{term "\<exists>p. (bn as, ast) \<approx>lst alpha_trm2 fa_trm2 p (bn as', ast')"}}} \end{tabular} \end{center} \begin{center}\small \begin{tabular}{@ {}c @ {}} \infer{@{text "ANil \<approx>\<^bsub>assn\<^esub> ANil"}}{}\hspace{9mm} \infer{@{text "ACons a t as \<approx>\<^bsub>assn\<^esub> ACons a' t' as"}} {@{text "a = a'"} & @{text "t \<approx>\<^bsub>trm\<^esub> t'"} & @{text "as \<approx>\<^bsub>assn\<^esub> as'"}} \end{tabular} \end{center} \begin{center}\small \begin{tabular}{@ {}c @ {}} \infer{@{text "ANil \<approx>\<^bsub>bn\<^esub> ANil"}}{}\hspace{9mm} \infer{@{text "ACons a t as \<approx>\<^bsub>bn\<^esub> ACons a' t' as"}} {@{text "t \<approx>\<^bsub>trm\<^esub> t'"} & @{text "as \<approx>\<^bsub>bn\<^esub> as'"}} \end{tabular} \end{center} \noindent Note the difference between $\approx_{\textit{assn}}$ and $\approx_{\textit{bn}}$: the latter only ``tracks'' $\alpha$-equivalence of the components in an assignment that are \emph{not} bound. This is needed in the clause for @{text "Let"} (which has a non-recursive binder). %The underlying reason is that the terms inside an assignment are not meant %to be ``under'' the binder. Such a premise is \emph{not} needed in @{text "Let_rec"}, %because there all components of an assignment are ``under'' the binder. *}section {* Establishing the Reasoning Infrastructure *}text {* Having made all necessary definitions for raw terms, we can start with establishing the reasoning infrastructure for the $\alpha$-equated types @{text "ty\<AL>"}$_{1..n}$, that is the types the user originally specified. We sketch in this section the proofs we need for establishing this infrastructure. One main point of our work is that we have completely automated these proofs in Isabelle/HOL. First we establish that the $\alpha$-equivalence relations defined in the previous section are equivalence relations. \begin{lemma}\label{equiv} Given the raw types @{text "ty"}$_{1..n}$ and binding functions @{text "bn"}$_{1..m}$, the relations @{text "\<approx>ty"}$_{1..n}$ and @{text "\<approx>bn"}$_{1..m}$ are equivalence relations.%% and equivariant. \end{lemma} \begin{proof} The proof is by mutual induction over the definitions. The non-trivial cases involve premises built up by $\approx_{\textit{set}}$, $\approx_{\textit{res}}$ and $\approx_{\textit{list}}$. They can be dealt with as in Lemma~\ref{alphaeq}. \end{proof} \noindent We can feed this lemma into our quotient package and obtain new types @{text "ty"}$^\alpha_{1..n}$ representing $\alpha$-equated terms of types @{text "ty"}$_{1..n}$. We also obtain definitions for the term-constructors @{text "C"}$^\alpha_{1..k}$ from the raw term-constructors @{text "C"}$_{1..k}$, and similar definitions for the free-atom functions @{text "fa_ty"}$^\alpha_{1..n}$ and @{text "fa_bn"}$^\alpha_{1..m}$ as well as the binding functions @{text "bn"}$^\alpha_{1..m}$. However, these definitions are not really useful to the user, since they are given in terms of the isomorphisms we obtained by creating new types in Isabelle/HOL (recall the picture shown in the Introduction). The first useful property for the user is the fact that distinct term-constructors are not equal, that is % \begin{equation}\label{distinctalpha} \mbox{@{text "C"}$^\alpha$~@{text "x\<^isub>1 \<dots> x\<^isub>r"}~@{text "\<noteq>"}~% @{text "D"}$^\alpha$~@{text "y\<^isub>1 \<dots> y\<^isub>s"}} \end{equation} \noindent whenever @{text "C"}$^\alpha$~@{text "\<noteq>"}~@{text "D"}$^\alpha$. In order to derive this fact, we use the definition of $\alpha$-equivalence and establish that % \begin{equation}\label{distinctraw} \mbox{@{text "C x\<^isub>1 \<dots> x\<^isub>r"}\;$\not\approx$@{text ty}\;@{text "D y\<^isub>1 \<dots> y\<^isub>s"}} \end{equation} \noindent holds for the corresponding raw term-constructors. In order to deduce \eqref{distinctalpha} from \eqref{distinctraw}, our quotient package needs to know that the raw term-constructors @{text "C"} and @{text "D"} are \emph{respectful} w.r.t.~the $\alpha$-equivalence relations (see \cite{Homeier05}). Assuming, for example, @{text "C"} is of type @{text "ty"} with argument types @{text "ty"}$_{1..r}$, respectfulness amounts to showing that % \begin{center} @{text "C x\<^isub>1 \<dots> x\<^isub>r \<approx>ty C x\<PRIME>\<^isub>1 \<dots> x\<PRIME>\<^isub>r"} \end{center} \noindent holds under the assumptions that we have \mbox{@{text "x\<^isub>i \<approx>ty\<^isub>i x\<PRIME>\<^isub>i"}} whenever @{text "x\<^isub>i"} and @{text "x\<PRIME>\<^isub>i"} are recursive arguments of @{text C} and @{text "x\<^isub>i = x\<PRIME>\<^isub>i"} whenever they are non-recursive arguments. We can prove this implication by applying the corresponding rule in our $\alpha$-equivalence definition and by establishing the following auxiliary implications %facts % \begin{equation}\label{fnresp} \mbox{% \begin{tabular}{ll@ {\hspace{7mm}}ll} \mbox{\it (i)} & @{text "x \<approx>ty\<^isub>i x\<PRIME>"}~~@{text "\<Rightarrow>"}~~@{text "fa_ty\<^isub>i x = fa_ty\<^isub>i x\<PRIME>"} & \mbox{\it (iii)} & @{text "x \<approx>ty\<^isub>j x\<PRIME>"}~~@{text "\<Rightarrow>"}~~@{text "bn\<^isub>j x = bn\<^isub>j x\<PRIME>"}\\ \mbox{\it (ii)} & @{text "x \<approx>ty\<^isub>j x\<PRIME>"}~~@{text "\<Rightarrow>"}~~@{text "fa_bn\<^isub>j x = fa_bn\<^isub>j x\<PRIME>"} & \mbox{\it (iv)} & @{text "x \<approx>ty\<^isub>j x\<PRIME>"}~~@{text "\<Rightarrow>"}~~@{text "x \<approx>bn\<^isub>j x\<PRIME>"}\\ \end{tabular}} \end{equation} \noindent They can be established by induction on @{text "\<approx>ty"}$_{1..n}$. Whereas the first, second and last implication are true by how we stated our definitions, the third \emph{only} holds because of our restriction imposed on the form of the binding functions---namely \emph{not} returning any bound atoms. In Ott, in contrast, the user may define @{text "bn"}$_{1..m}$ so that they return bound atoms and in this case the third implication is \emph{not} true. A result is that the lifing of the corresponding binding functions in Ott to $\alpha$-equated terms is impossible. Having established respectfulness for the raw term-constructors, the quotient package is able to automatically deduce \eqref{distinctalpha} from \eqref{distinctraw}. Having the facts \eqref{fnresp} at our disposal, we can also lift properties that characterise when two raw terms of the form % \begin{center} @{text "C x\<^isub>1 \<dots> x\<^isub>r \<approx>ty C x\<PRIME>\<^isub>1 \<dots> x\<PRIME>\<^isub>r"} \end{center} \noindent are $\alpha$-equivalent. This gives us conditions when the corresponding $\alpha$-equated terms are \emph{equal}, namely % %\begin{center} @{text "C\<^sup>\<alpha> x\<^isub>1 \<dots> x\<^isub>r = C\<^sup>\<alpha> x\<PRIME>\<^isub>1 \<dots> x\<PRIME>\<^isub>r"}. %\end{center} % %\noindent We call these conditions as \emph{quasi-injectivity}. They correspond to the premises in our $\alpha$-equivalence relations. Next we can lift the permutation operations defined in \eqref{ceqvt}. In order to make this lifting to go through, we have to show that the permutation operations are respectful. This amounts to showing that the $\alpha$-equivalence relations are equivariant \cite{HuffmanUrban10}. %, which we already established %in Lemma~\ref{equiv}. As a result we can add the equations % \begin{equation}\label{calphaeqvt} @{text "p \<bullet> (C\<^sup>\<alpha> x\<^isub>1 \<dots> x\<^isub>r) = C\<^sup>\<alpha> (p \<bullet> x\<^isub>1) \<dots> (p \<bullet> x\<^isub>r)"} \end{equation} \noindent to our infrastructure. In a similar fashion we can lift the defining equations of the free-atom functions @{text "fn_ty\<AL>"}$_{1..n}$ and @{text "fa_bn\<AL>"}$_{1..m}$ as well as of the binding functions @{text "bn\<AL>"}$_{1..m}$ and the size functions @{text "size_ty\<AL>"}$_{1..n}$. The latter are defined automatically for the raw types @{text "ty"}$_{1..n}$ by the datatype package of Isabelle/HOL. Finally we can add to our infrastructure a cases lemma (explained in the next section) and a structural induction principle for the types @{text "ty\<AL>"}$_{i..n}$. The conclusion of the induction principle is of the form % %\begin{equation}\label{weakinduct} \mbox{@{text "P\<^isub>1 x\<^isub>1 \<and> \<dots> \<and> P\<^isub>n x\<^isub>n "}} %\end{equation} % %\noindent whereby the @{text P}$_{1..n}$ are predicates and the @{text x}$_{1..n}$ have types @{text "ty\<AL>"}$_{1..n}$. This induction principle has for each term constructor @{text "C"}$^\alpha$ a premise of the form % \begin{equation}\label{weakprem} \mbox{@{text "\<forall>x\<^isub>1\<dots>x\<^isub>r. P\<^isub>i x\<^isub>i \<and> \<dots> \<and> P\<^isub>j x\<^isub>j \<Rightarrow> P (C\<^sup>\<alpha> x\<^isub>1 \<dots> x\<^isub>r)"}} \end{equation} \noindent in which the @{text "x"}$_{i..j}$ @{text "\<subseteq>"} @{text "x"}$_{1..r}$ are the recursive arguments of @{text "C\<AL>"}. By working now completely on the $\alpha$-equated level, we can first show that the free-atom functions and binding functions are equivariant, namely % \begin{center} \begin{tabular}{rcl@ {\hspace{10mm}}rcl} @{text "p \<bullet> (fa_ty\<AL>\<^isub>i x)"} & $=$ & @{text "fa_ty\<AL>\<^isub>i (p \<bullet> x)"} & @{text "p \<bullet> (bn\<AL>\<^isub>j x)"} & $=$ & @{text "bn\<AL>\<^isub>j (p \<bullet> x)"}\\ @{text "p \<bullet> (fa_bn\<AL>\<^isub>j x)"} & $=$ & @{text "fa_bn\<AL>\<^isub>j (p \<bullet> x)"}\\ \end{tabular} \end{center} % \noindent These properties can be established using the induction principle. %%in \eqref{weakinduct}. Having these equivariant properties established, we can show that the support of term-constructors @{text "C\<^sup>\<alpha>"} is included in the support of its arguments, that means \begin{center} @{text "supp (C\<^sup>\<alpha> x\<^isub>1 \<dots> x\<^isub>r) \<subseteq> (supp x\<^isub>1 \<union> \<dots> \<union> supp x\<^isub>r)"} \end{center} \noindent holds. This allows us to prove by induction that every @{text x} of type @{text "ty\<AL>"}$_{1..n}$ is finitely supported. %This can be again shown by induction %over @{text "ty\<AL>"}$_{1..n}$. Lastly, we can show that the support of elements in @{text "ty\<AL>"}$_{1..n}$ is the same as @{text "fa_ty\<AL>"}$_{1..n}$. This fact is important in a nominal setting, but also provides evidence that our notions of free-atoms and $\alpha$-equivalence are correct. \begin{theorem} For @{text "x"}$_{1..n}$ with type @{text "ty\<AL>"}$_{1..n}$, we have @{text "supp x\<^isub>i = fa_ty\<AL>\<^isub>i x\<^isub>i"}. \end{theorem} \begin{proof} The proof is by induction. In each case we unfold the definition of @{text "supp"}, move the swapping inside the term-constructors and then use the quasi-injectivity lemmas in order to complete the proof. For the abstraction cases we use the facts derived in Theorem~\ref{suppabs}. \end{proof} \noindent To sum up this section, we can establish automatically a reasoning infrastructure for the types @{text "ty\<AL>"}$_{1..n}$ by first lifting definitions from the raw level to the quotient level and then by establishing facts about these lifted definitions. All necessary proofs are generated automatically by custom ML-code. %This code can deal with %specifications such as the one shown in Figure~\ref{nominalcorehas} for Core-Haskell. %\begin{figure}[t!] %\begin{boxedminipage}{\linewidth} %\small %\begin{tabular}{l} %\isacommand{atom\_decl}~@{text "var cvar tvar"}\\[1mm] %\isacommand{nominal\_datatype}~@{text "tkind ="}\\ %\phantom{$|$}~@{text "KStar"}~$|$~@{text "KFun tkind tkind"}\\ %\isacommand{and}~@{text "ckind ="}\\ %\phantom{$|$}~@{text "CKSim ty ty"}\\ %\isacommand{and}~@{text "ty ="}\\ %\phantom{$|$}~@{text "TVar tvar"}~$|$~@{text "T string"}~$|$~@{text "TApp ty ty"}\\ %$|$~@{text "TFun string ty_list"}~% %$|$~@{text "TAll tv::tvar tkind ty::ty"} \isacommand{bind}~@{text "tv"}~\isacommand{in}~@{text ty}\\ %$|$~@{text "TArr ckind ty"}\\ %\isacommand{and}~@{text "ty_lst ="}\\ %\phantom{$|$}~@{text "TNil"}~$|$~@{text "TCons ty ty_lst"}\\ %\isacommand{and}~@{text "cty ="}\\ %\phantom{$|$}~@{text "CVar cvar"}~% %$|$~@{text "C string"}~$|$~@{text "CApp cty cty"}~$|$~@{text "CFun string co_lst"}\\ %$|$~@{text "CAll cv::cvar ckind cty::cty"} \isacommand{bind}~@{text "cv"}~\isacommand{in}~@{text cty}\\ %$|$~@{text "CArr ckind cty"}~$|$~@{text "CRefl ty"}~$|$~@{text "CSym cty"}~$|$~@{text "CCirc cty cty"}\\ %$|$~@{text "CAt cty ty"}~$|$~@{text "CLeft cty"}~$|$~@{text "CRight cty"}~$|$~@{text "CSim cty cty"}\\ %$|$~@{text "CRightc cty"}~$|$~@{text "CLeftc cty"}~$|$~@{text "Coerce cty cty"}\\ %\isacommand{and}~@{text "co_lst ="}\\ %\phantom{$|$}@{text "CNil"}~$|$~@{text "CCons cty co_lst"}\\ %\isacommand{and}~@{text "trm ="}\\ %\phantom{$|$}~@{text "Var var"}~$|$~@{text "K string"}\\ %$|$~@{text "LAM_ty tv::tvar tkind t::trm"} \isacommand{bind}~@{text "tv"}~\isacommand{in}~@{text t}\\ %$|$~@{text "LAM_cty cv::cvar ckind t::trm"} \isacommand{bind}~@{text "cv"}~\isacommand{in}~@{text t}\\ %$|$~@{text "App_ty trm ty"}~$|$~@{text "App_cty trm cty"}~$|$~@{text "App trm trm"}\\ %$|$~@{text "Lam v::var ty t::trm"} \isacommand{bind}~@{text "v"}~\isacommand{in}~@{text t}\\ %$|$~@{text "Let x::var ty trm t::trm"} \isacommand{bind}~@{text x}~\isacommand{in}~@{text t}\\ %$|$~@{text "Case trm assoc_lst"}~$|$~@{text "Cast trm co"}\\ %\isacommand{and}~@{text "assoc_lst ="}\\ %\phantom{$|$}~@{text ANil}~% %$|$~@{text "ACons p::pat t::trm assoc_lst"} \isacommand{bind}~@{text "bv p"}~\isacommand{in}~@{text t}\\ %\isacommand{and}~@{text "pat ="}\\ %\phantom{$|$}~@{text "Kpat string tvtk_lst tvck_lst vt_lst"}\\ %\isacommand{and}~@{text "vt_lst ="}\\ %\phantom{$|$}~@{text VTNil}~$|$~@{text "VTCons var ty vt_lst"}\\ %\isacommand{and}~@{text "tvtk_lst ="}\\ %\phantom{$|$}~@{text TVTKNil}~$|$~@{text "TVTKCons tvar tkind tvtk_lst"}\\ %\isacommand{and}~@{text "tvck_lst ="}\\ %\phantom{$|$}~@{text TVCKNil}~$|$ @{text "TVCKCons cvar ckind tvck_lst"}\\ %\isacommand{binder}\\ %@{text "bv :: pat \<Rightarrow> atom list"}~\isacommand{and}~% %@{text "bv1 :: vt_lst \<Rightarrow> atom list"}~\isacommand{and}\\ %@{text "bv2 :: tvtk_lst \<Rightarrow> atom list"}~\isacommand{and}~% %@{text "bv3 :: tvck_lst \<Rightarrow> atom list"}\\ %\isacommand{where}\\ %\phantom{$|$}~@{text "bv (K s tvts tvcs vs) = (bv3 tvts) @ (bv2 tvcs) @ (bv1 vs)"}\\ %$|$~@{text "bv1 VTNil = []"}\\ %$|$~@{text "bv1 (VTCons x ty tl) = (atom x)::(bv1 tl)"}\\ %$|$~@{text "bv2 TVTKNil = []"}\\ %$|$~@{text "bv2 (TVTKCons a ty tl) = (atom a)::(bv2 tl)"}\\ %$|$~@{text "bv3 TVCKNil = []"}\\ %$|$~@{text "bv3 (TVCKCons c cty tl) = (atom c)::(bv3 tl)"}\\ %\end{tabular} %\end{boxedminipage} %\caption{The nominal datatype declaration for Core-Haskell. For the moment we %do not support nested types; therefore we explicitly have to unfold the %lists @{text "co_lst"}, @{text "assoc_lst"} and so on. This will be improved %in a future version of Nominal Isabelle. Apart from that, the %declaration follows closely the original in Figure~\ref{corehas}. The %point of our work is that having made such a declaration in Nominal Isabelle, %one obtains automatically a reasoning infrastructure for Core-Haskell. %\label{nominalcorehas}} %\end{figure}*}section {* Strong Induction Principles *}text {* In the previous section we derived induction principles for $\alpha$-equated terms. We call such induction principles \emph{weak}, because for a term-constructor \mbox{@{text "C\<^sup>\<alpha> x\<^isub>1\<dots>x\<^isub>r"}} the induction hypothesis requires us to establish the implications \eqref{weakprem}. The problem with these implications is that in general they are difficult to establish. The reason is that we cannot make any assumption about the binders that might be in @{text "C\<^sup>\<alpha>"}. %%(for example we cannot assume the variable convention for them). In \cite{UrbanTasson05} we introduced a method for automatically strengthening weak induction principles for terms containing single binders. These stronger induction principles allow the user to make additional assumptions about binders. %These additional assumptions amount to a formal %version of the informal variable convention for binders. To sketch how this strengthening extends to the case of multiple binders, we use as running example the term-constructors @{text "Lam"} and @{text "Let"} from example \eqref{letpat}. Instead of establishing @{text " P\<^bsub>trm\<^esub> t \<and> P\<^bsub>pat\<^esub> p"}, the stronger induction principle for \eqref{letpat} establishes properties @{text " P\<^bsub>trm\<^esub> c t \<and> P\<^bsub>pat\<^esub> c p"} where the additional parameter @{text c} controls which freshness assumptions the binders should satisfy. For the two term constructors this means that the user has to establish in inductions the implications % \begin{center} \begin{tabular}{l} @{text "\<forall>a t c. {atom a} \<FRESH>\<^sup>* c \<and> (\<forall>d. P\<^bsub>trm\<^esub> d t) \<Rightarrow> P\<^bsub>trm\<^esub> c (Lam a t)"}\\ @{text "\<forall>p t c. (set (bn p)) \<FRESH>\<^sup>* c \<and> (\<forall>d. P\<^bsub>pat\<^esub> d p) \<and> (\<forall>d. P\<^bsub>trm\<^esub> d t) \<and> \<Rightarrow> P\<^bsub>trm\<^esub> c (Let p t)"}\\%[-0mm] \end{tabular} \end{center} In \cite{UrbanTasson05} we showed how the weaker induction principles imply the stronger ones. This was done by some quite complicated, nevertheless automated, induction proofs. In this paper we simplify this work by leveraging the automated proof methods from the function package of Isabelle/HOL. The reasoning principle these methods employ is well-founded induction. To use them in our setting, we have to discharge two proof obligations: one is that we have well-founded measures (for each type @{text "ty"}$^\alpha_{1..n}$) that decrease in every induction step and the other is that we have covered all cases. As measures we use the size functions @{text "size_ty"}$^\alpha_{1..n}$, which we lifted in the previous section and which are all well-founded. It is straightforward to establish that these measures decrease in every induction step. What is left to show is that we covered all cases. To do so, we use a cases lemma derived for each type. For the terms in \eqref{letpat} this lemma is of the form % \begin{equation}\label{weakcases} \infer{@{text "P\<^bsub>trm\<^esub>"}} {\begin{array}{l@ {\hspace{9mm}}l} @{text "\<forall>x. t = Var x \<Rightarrow> P\<^bsub>trm\<^esub>"} & @{text "\<forall>a t'. t = Lam a t' \<Rightarrow> P\<^bsub>trm\<^esub>"}\\ @{text "\<forall>t\<^isub>1 t\<^isub>2. t = App t\<^isub>1 t\<^isub>2 \<Rightarrow> P\<^bsub>trm\<^esub>"} & @{text "\<forall>p t'. t = Let p t' \<Rightarrow> P\<^bsub>trm\<^esub>"}\\ \end{array}}\\[-1mm] \end{equation} % where we have a premise for each term-constructor. The idea behind such cases lemmas is that we can conclude with a property @{text "P\<^bsub>trm\<^esub>"}, provided we can show that this property holds if we substitute for @{text "t"} all possible term-constructors. The only remaining difficulty is that in order to derive the stronger induction principles conveniently, the cases lemma in \eqref{weakcases} is too weak. For this note that in order to apply this lemma, we have to establish @{text "P\<^bsub>trm\<^esub>"} for \emph{all} @{text Lam}- and \emph{all} @{text Let}-terms. What we need instead is a cases rule where we only have to consider terms that have binders that are fresh w.r.t.~a context @{text "c"}. This gives the implications % \begin{center} \begin{tabular}{l} @{text "\<forall>a t'. t = Lam a t' \<and> {atom a} \<FRESH>\<^sup>* c \<Rightarrow> P\<^bsub>trm\<^esub>"}\\ @{text "\<forall>p t'. t = Let p t' \<and> (set (bn p)) \<FRESH>\<^sup>* c \<Rightarrow> P\<^bsub>trm\<^esub>"}\\%[-2mm] \end{tabular} \end{center} % \noindent which however can be relatively easily be derived from the implications in \eqref{weakcases} by a renaming using Properties \ref{supppermeq} and \ref{avoiding}. In the first case we know that @{text "{atom a} \<FRESH>\<^sup>* Lam a t"}. Property \eqref{avoiding} provides us therefore with a permutation @{text q}, such that @{text "{atom (q \<bullet> a)} \<FRESH>\<^sup>* c"} and @{text "supp (Lam a t) \<FRESH>\<^sup>* q"} hold. By using Property \ref{supppermeq}, we can infer from the latter that @{text "Lam (q \<bullet> a) (q \<bullet> t) = Lam a t"} and we are done with this case. The @{text Let}-case involving a (non-recursive) deep binder is a bit more complicated. The reason is that the we cannot apply Property \ref{avoiding} to the whole term @{text "Let p t"}, because @{text p} might contain names that are bound (by @{text bn}) and so are free. To solve this problem we have to introduce a permutation function that only permutes names bound by @{text bn} and leaves the other names unchanged. We do this again by lifting. For a clause @{text "bn (C x\<^isub>1 \<dots> x\<^isub>r) = rhs"}, we define % \begin{center} @{text "p \<bullet>\<^bsub>bn\<^esub> (C x\<^isub>1 \<dots> x\<^isub>r) \<equiv> C y\<^isub>1 \<dots> y\<^isub>r"} \;\; with $\begin{cases} \text{@{text "y\<^isub>i \<equiv> x\<^isub>i"} provided @{text "x\<^isub>i"} does not occur in @{text "rhs"}}\\ \text{@{text "y\<^isub>i \<equiv> p \<bullet>\<^bsub>bn'\<^esub> x\<^isub>i"} provided @{text "bn' x\<^isub>i"} is in @{text "rhs"}}\\ \text{@{text "y\<^isub>i \<equiv> p \<bullet> x\<^isub>i"} otherwise} \end{cases}$ \end{center} % %\noindent %with @{text "y\<^isub>i"} determined as follows: % %\begin{center} %\begin{tabular}{c@ {\hspace{2mm}}p{0.9\textwidth}} %$\bullet$ & @{text "y\<^isub>i \<equiv> x\<^isub>i"} provided @{text "x\<^isub>i"} does not occur in @{text "rhs"}\\ %$\bullet$ & @{text "y\<^isub>i \<equiv> p \<bullet>\<^bsub>bn'\<^esub> x\<^isub>i"} provided @{text "bn' x\<^isub>i"} is in @{text "rhs"}\\ %$\bullet$ & @{text "y\<^isub>i \<equiv> p \<bullet> x\<^isub>i"} otherwise %\end{tabular} %\end{center} % \noindent Now Properties \ref{supppermeq} and \ref{avoiding} give us a permutation @{text q} such that @{text "(set (bn (q \<bullet>\<^bsub>bn\<^esub> p)) \<FRESH>\<^sup>* c"} holds and such that @{text "[q \<bullet>\<^bsub>bn\<^esub> p]\<^bsub>list\<^esub>.(q \<bullet> t)"} is equal to @{text "[p]\<^bsub>list\<^esub>. t"}. We can also show that @{text "(q \<bullet>\<^bsub>bn\<^esub> p) \<approx>\<^bsub>bn\<^esub> p"}. These facts establish that @{text "Let (q \<bullet>\<^bsub>bn\<^esub> p) (p \<bullet> t) = Let p t"}, as we need. This completes the non-trivial cases in \eqref{letpat} for strengthening the corresponding induction principle. %A natural question is %whether we can also strengthen the weak induction principles involving %the general binders presented here. We will indeed be able to so, but for this we need an %additional notion for permuting deep binders. %Given a binding function @{text "bn"} we define an auxiliary permutation %operation @{text "_ \<bullet>\<^bsub>bn\<^esub> _"} which permutes only bound arguments in a deep binder. %Assuming a clause of @{text bn} is given as % %\begin{center} %@{text "bn (C x\<^isub>1 \<dots> x\<^isub>r) = rhs"}, %\end{center} %\noindent %then we define % %\begin{center} %@{text "p \<bullet>\<^bsub>bn\<^esub> (C x\<^isub>1 \<dots> x\<^isub>r) \<equiv> C y\<^isub>1 \<dots> y\<^isub>r"} %\end{center} %\noindent %with @{text "y\<^isub>i"} determined as follows: % %\begin{center} %\begin{tabular}{c@ {\hspace{2mm}}p{7cm}} %$\bullet$ & @{text "y\<^isub>i \<equiv> x\<^isub>i"} provided @{text "x\<^isub>i"} does not occur in @{text "rhs"}\\ %$\bullet$ & @{text "y\<^isub>i \<equiv> p \<bullet>\<^bsub>bn'\<^esub> x\<^isub>i"} provided @{text "bn' x\<^isub>i"} is in @{text "rhs"}\\ %$\bullet$ & @{text "y\<^isub>i \<equiv> p \<bullet> x\<^isub>i"} otherwise %\end{tabular} %\end{center} %\noindent %Using again the quotient package we can lift the @{text "_ \<bullet>\<^bsub>bn\<^esub> _"} function to %$\alpha$-equated terms. We can then prove the following two facts %\begin{lemma}\label{permutebn} %Given a binding function @{text "bn\<^sup>\<alpha>"} then for all @{text p} %{\it (i)} @{text "p \<bullet> (bn\<^sup>\<alpha> x) = bn\<^sup>\<alpha> (p \<bullet>\<AL>\<^bsub>bn\<^esub> x)"} and {\it (ii)} % @{text "fa_bn\<^isup>\<alpha> x = fa_bn\<^isup>\<alpha> (p \<bullet>\<AL>\<^bsub>bn\<^esub> x)"}. %\end{lemma} %\begin{proof} %By induction on @{text x}. The equations follow by simple unfolding %of the definitions. %\end{proof} %\noindent %The first property states that a permutation applied to a binding function is %equivalent to first permuting the binders and then calculating the bound %atoms. The second amounts to the fact that permuting the binders has no %effect on the free-atom function. The main point of this permutation %function, however, is that if we have a permutation that is fresh %for the support of an object @{text x}, then we can use this permutation %to rename the binders in @{text x}, without ``changing'' @{text x}. In case of the %@{text "Let"} term-constructor from the example shown %in \eqref{letpat} this means for a permutation @{text "r"} %% %\begin{equation}\label{renaming} %\begin{array}{l} %\mbox{if @{term "supp (Abs_lst (bn p) t\<^isub>2) \<sharp>* r"}}\\ %\qquad\mbox{then @{text "Let p t\<^isub>1 t\<^isub>2 = Let (r \<bullet>\<AL>\<^bsub>bn_pat\<^esub> p) t\<^isub>1 (r \<bullet> t\<^isub>2)"}} %\end{array} %\end{equation} %\noindent %This fact will be crucial when establishing the strong induction principles below. %In our running example about @{text "Let"}, the strong induction %principle means that instead %of establishing the implication % %\begin{center} %@{text "\<forall>p t\<^isub>1 t\<^isub>2. P\<^bsub>pat\<^esub> p \<and> P\<^bsub>trm\<^esub> t\<^isub>1 \<and> P\<^bsub>trm\<^esub> t\<^isub>2 \<Rightarrow> P\<^bsub>trm\<^esub> (Let p t\<^isub>1 t\<^isub>2)"} %\end{center} % %\noindent %it is sufficient to establish the following implication % %\begin{equation}\label{strong} %\mbox{\begin{tabular}{l} %@{text "\<forall>p t\<^isub>1 t\<^isub>2 c."}\\ %\hspace{5mm}@{text "set (bn p) #\<^sup>* c \<and>"}\\ %\hspace{5mm}@{text "(\<forall>d. P\<^bsub>pat\<^esub> d p) \<and> (\<forall>d. P\<^bsub>trm\<^esub> d t\<^isub>1) \<and> (\<forall>d. P\<^bsub>trm\<^esub> d t\<^isub>2)"}\\ %\hspace{15mm}@{text "\<Rightarrow> P\<^bsub>trm\<^esub> c (Let p t\<^isub>1 t\<^isub>2)"} %\end{tabular}} %\end{equation} % %\noindent %While this implication contains an additional argument, namely @{text c}, and %also additional universal quantifications, it is usually easier to establish. %The reason is that we have the freshness %assumption @{text "set (bn\<^sup>\<alpha> p) #\<^sup>* c"}, whereby @{text c} can be arbitrarily %chosen by the user as long as it has finite support. % %Let us now show how we derive the strong induction principles from the %weak ones. In case of the @{text "Let"}-example we derive by the weak %induction the following two properties % %\begin{equation}\label{hyps} %@{text "\<forall>q c. P\<^bsub>trm\<^esub> c (q \<bullet> t)"} \hspace{4mm} %@{text "\<forall>q\<^isub>1 q\<^isub>2 c. P\<^bsub>pat\<^esub> (q\<^isub>1 \<bullet>\<AL>\<^bsub>bn\<^esub> (q\<^isub>2 \<bullet> p))"} %\end{equation} % %\noindent %For the @{text Let} term-constructor we therefore have to establish @{text "P\<^bsub>trm\<^esub> c (q \<bullet> Let p t\<^isub>1 t\<^isub>2)"} %assuming \eqref{hyps} as induction hypotheses (the first for @{text t\<^isub>1} and @{text t\<^isub>2}). %By Property~\ref{avoiding} we %obtain a permutation @{text "r"} such that % %\begin{equation}\label{rprops} %@{term "(r \<bullet> set (bn (q \<bullet> p))) \<sharp>* c "}\hspace{4mm} %@{term "supp (Abs_lst (bn (q \<bullet> p)) (q \<bullet> t\<^isub>2)) \<sharp>* r"} %\end{equation} % %\noindent %hold. The latter fact and \eqref{renaming} give us %% %\begin{center} %\begin{tabular}{l} %@{text "Let (q \<bullet> p) (q \<bullet> t\<^isub>1) (q \<bullet> t\<^isub>2) ="} \\ %\hspace{15mm}@{text "Let (r \<bullet>\<AL>\<^bsub>bn\<^esub> (q \<bullet> p)) (q \<bullet> t\<^isub>1) (r \<bullet> (q \<bullet> t\<^isub>2))"} %\end{tabular} %\end{center} % %\noindent %So instead of proving @{text "P\<^bsub>trm\<^esub> c (q \<bullet> Let p t\<^isub>1 t\<^isub>2)"}, we can equally %establish @{text "P\<^bsub>trm\<^esub> c (Let (r \<bullet>\<AL>\<^bsub>bn\<^esub> (q \<bullet> p)) (q \<bullet> t\<^isub>1) (r \<bullet> (q \<bullet> t\<^isub>2)))"}. %To do so, we will use the implication \eqref{strong} of the strong induction %principle, which requires us to discharge %the following four proof obligations: %% %\begin{center} %\begin{tabular}{rl} %{\it (i)} & @{text "set (bn (r \<bullet>\<AL>\<^bsub>bn\<^esub> (q \<bullet> p))) #\<^sup>* c"}\\ %{\it (ii)} & @{text "\<forall>d. P\<^bsub>pat\<^esub> d (r \<bullet>\<AL>\<^bsub>bn\<^esub> (q \<bullet> p))"}\\ %{\it (iii)} & @{text "\<forall>d. P\<^bsub>trm\<^esub> d (q \<bullet> t\<^isub>1)"}\\ %{\it (iv)} & @{text "\<forall>d. P\<^bsub>trm\<^esub> d (r \<bullet> (q \<bullet> t\<^isub>2))"}\\ %\end{tabular} %\end{center} % %\noindent %The first follows from \eqref{rprops} and Lemma~\ref{permutebn}.{\it (i)}; the %others from the induction hypotheses in \eqref{hyps} (in the fourth case %we have to use the fact that @{term "(r \<bullet> (q \<bullet> t\<^isub>2)) = (r + q) \<bullet> t\<^isub>2"}). % %Taking now the identity permutation @{text 0} for the permutations in \eqref{hyps}, %we can establish our original goals, namely @{text "P\<^bsub>trm\<^esub> c t"} and \mbox{@{text "P\<^bsub>pat\<^esub> c p"}}. %This completes the proof showing that the weak induction principles imply %the strong induction principles. *}section {* Related Work *}text {* To our knowledge the earliest usage of general binders in a theorem prover is described in \cite{NaraschewskiNipkow99} about a formalisation of the algorithm W. This formalisation implements binding in type-schemes using a de-Bruijn indices representation. Since type-schemes in W contain only a single place where variables are bound, different indices do not refer to different binders (as in the usual de-Bruijn representation), but to different bound variables. A similar idea has been recently explored for general binders in the locally nameless approach to binding \cite{chargueraud09}. There, de-Bruijn indices consist of two numbers, one referring to the place where a variable is bound, and the other to which variable is bound. The reasoning infrastructure for both representations of bindings comes for free in theorem provers like Isabelle/HOL or Coq, since the corresponding term-calculi can be implemented as ``normal'' datatypes. However, in both approaches it seems difficult to achieve our fine-grained control over the ``semantics'' of bindings (i.e.~whether the order of binders should matter, or vacuous binders should be taken into account). %To do so, one would require additional predicates that filter out %unwanted terms. Our guess is that such predicates result in rather %intricate formal reasoning. Another technique for representing binding is higher-order abstract syntax (HOAS). %, which for example is implemented in the Twelf system. This %%representation technique supports very elegantly many aspects of \emph{single} binding, and impressive work has been done that uses HOAS for mechanising the metatheory of SML~\cite{LeeCraryHarper07}. We are, however, not aware how multiple binders of SML are represented in this work. Judging from the submitted Twelf-solution for the POPLmark challenge, HOAS cannot easily deal with binding constructs where the number of bound variables is not fixed. %For example In the second part of this challenge, @{text "Let"}s involve patterns that bind multiple variables at once. In such situations, HOAS seems to have to resort to the iterated-single-binders-approach with all the unwanted consequences when reasoning about the resulting terms. %Two formalisations involving general binders have been %performed in older %versions of Nominal Isabelle (one about Psi-calculi and one about algorithm W %\cite{BengtsonParow09,UrbanNipkow09}). Both %use the approach based on iterated single binders. Our experience with %the latter formalisation has been disappointing. The major pain arose from %the need to ``unbind'' variables. This can be done in one step with our %general binders described in this paper, but needs a cumbersome %iteration with single binders. The resulting formal reasoning turned out to %be rather unpleasant. The hope is that the extension presented in this paper %is a substantial improvement. The most closely related work to the one presented here is the Ott-tool \cite{ott-jfp} and the C$\alpha$ml language \cite{Pottier06}. Ott is a nifty front-end for creating \LaTeX{} documents from specifications of term-calculi involving general binders. For a subset of the specifications Ott can also generate theorem prover code using a raw representation of terms, and in Coq also a locally nameless representation. The developers of this tool have also put forward (on paper) a definition for $\alpha$-equivalence of terms that can be specified in Ott. This definition is rather different from ours, not using any nominal techniques. To our knowledge there is also no concrete mathematical result concerning this notion of $\alpha$-equivalence. Also the definition for the notion of free variables is work in progress. Although we were heavily inspired by the syntax of Ott, its definition of $\alpha$-equivalence is unsuitable for our extension of Nominal Isabelle. First, it is far too complicated to be a basis for automated proofs implemented on the ML-level of Isabelle/HOL. Second, it covers cases of binders depending on other binders, which just do not make sense for our $\alpha$-equated terms. Third, it allows empty types that have no meaning in a HOL-based theorem prover. We also had to generalise slightly Ott's binding clauses. In Ott you specify binding clauses with a single body; we allow more than one. We have to do this, because this makes a difference for our notion of $\alpha$-equivalence in case of \isacommand{bind (set)} and \isacommand{bind (res)}. % %Consider the examples % %\begin{center} %\begin{tabular}{@ {}l@ {\hspace{2mm}}l@ {}} %@{text "Foo\<^isub>1 xs::name fset t::trm s::trm"} & % \isacommand{bind (set)} @{text "xs"} \isacommand{in} @{text "t s"}\\ %@{text "Foo\<^isub>2 xs::name fset t::trm s::trm"} & % \isacommand{bind (set)} @{text "xs"} \isacommand{in} @{text "t"}, % \isacommand{bind (set)} @{text "xs"} \isacommand{in} @{text "s"}\\ %\end{tabular} %\end{center} % %\noindent %In the first term-constructor we have a single %body that happens to be ``spread'' over two arguments; in the second term-constructor we have %two independent bodies in which the same variables are bound. As a result we %have % %\begin{center} %\begin{tabular}{r@ {\hspace{1.5mm}}c@ {\hspace{1.5mm}}l} %@{text "Foo\<^isub>1 {a, b} (a, b) (a, b)"} & $\not=$ & %@{text "Foo\<^isub>1 {a, b} (a, b) (b, a)"}\\ %@{text "Foo\<^isub>2 {a, b} (a, b) (a, b)"} & $=$ & %@{text "Foo\<^isub>2 {a, b} (a, b) (b, a)"}\\ %\end{tabular} %\end{center} % %\noindent %and therefore need the extra generality to be able to distinguish between %both specifications. Because of how we set up our definitions, we also had to impose some restrictions (like a single binding function for a deep binder) that are not present in Ott. %Our %expectation is that we can still cover many interesting term-calculi from %programming language research, for example Core-Haskell. Pottier presents in \cite{Pottier06} a language, called C$\alpha$ml, for representing terms with general binders inside OCaml. This language is implemented as a front-end that can be translated to OCaml with the help of a library. He presents a type-system in which the scope of general binders can be specified using special markers, written @{text "inner"} and @{text "outer"}. It seems our and his specifications can be inter-translated as long as ours use the binding mode \isacommand{bind} only. However, we have not proved this. Pottier gives a definition for $\alpha$-equivalence, which also uses a permutation operation (like ours). Still, this definition is rather different from ours and he only proves that it defines an equivalence relation. A complete reasoning infrastructure is well beyond the purposes of his language. Similar work for Haskell with similar results was reported by Cheney \cite{Cheney05a}. In a slightly different domain (programming with dependent types), the paper \cite{Altenkirch10} presents a calculus with a notion of $\alpha$-equivalence related to our binding mode \isacommand{bind (res)}. The definition in \cite{Altenkirch10} is similar to the one by Pottier, except that it has a more operational flavour and calculates a partial (renaming) map. In this way, the definition can deal with vacuous binders. However, to our best knowledge, no concrete mathematical result concerning this definition of $\alpha$-equivalence has been proved.\\[-7mm] *}section {* Conclusion *}text {* We have presented an extension of Nominal Isabelle for dealing with general binders, that is term-constructors having multiple bound variables. For this extension we introduced new definitions of $\alpha$-equivalence and automated all necessary proofs in Isabelle/HOL. To specify general binders we used the specifications from Ott, but extended them in some places and restricted them in others so that they make sense in the context of $\alpha$-equated terms. We also introduced two binding modes (set and res) that do not exist in Ott. We have tried out the extension with calculi such as Core-Haskell, type-schemes and approximately a dozen of other typical examples from programming language research~\cite{SewellBestiary}. The code will eventually become part of the next Isabelle distribution.\footnote{For the moment it can be downloaded from the Mercurial repository linked at \href{http://isabelle.in.tum.de/nominal/download} {http://isabelle.in.tum.de/nominal/download}.} We have left out a discussion about how functions can be defined over $\alpha$-equated terms involving general binders. In earlier versions of Nominal Isabelle \cite{UrbanBerghofer06} this turned out to be a thorny issue. We hope to do better this time by using the function package that has recently been implemented in Isabelle/HOL and also by restricting function definitions to equivariant functions (for such functions we can provide more automation). %There are some restrictions we imposed in this paper that we would like to lift in %future work. One is the exclusion of nested datatype definitions. Nested %datatype definitions allow one to specify, for instance, the function kinds %in Core-Haskell as @{text "TFun string (ty list)"} instead of the unfolded %version @{text "TFun string ty_list"} (see Figure~\ref{nominalcorehas}). To %achieve this, we need a slightly more clever implementation than we have at the moment. %A more interesting line of investigation is whether we can go beyond the %simple-minded form of binding functions that we adopted from Ott. At the moment, binding %functions can only return the empty set, a singleton atom set or unions %of atom sets (similarly for lists). It remains to be seen whether %properties like %% %\begin{center} %@{text "fa_ty x = bn x \<union> fa_bn x"}. %\end{center} % %\noindent %allow us to support more interesting binding functions. % %We have also not yet played with other binding modes. For example we can %imagine that there is need for a binding mode %where instead of lists, we abstract lists of distinct elements. %Once we feel confident about such binding modes, our implementation %can be easily extended to accommodate them. % \smallskip \noindent {\bf Acknowledgements:} %We are very grateful to Andrew Pitts for %many discussions about Nominal Isabelle. We thank Peter Sewell for making the informal notes \cite{SewellBestiary} available to us and also for patiently explaining some of the finer points of the work on the Ott-tool. %Stephanie Weirich suggested to separate the subgrammars %of kinds and types in our Core-Haskell example. \\[-6mm] *}(*<*)end(*>*)