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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* The `Quote' tactic *)
(* The basic idea is to automatize the inversion of interpetation functions
in 2-level approach
Examples are given in \texttt{theories/DEMOS/DemoQuote.v}
Suppose you have a langage \texttt{L} of 'abstract terms'
and a type \texttt{A} of 'concrete terms'
and a function \texttt{f : L -> (varmap A L) -> A}.
Then, the tactic \texttt{quote f} will replace an
expression \texttt{e} of type \texttt{A} by \texttt{(f vm t)}
such that \texttt{e} and \texttt{(f vm t)} are convertible.
The problem is then inverting the function \texttt{f}.
The tactic works when:
\begin{itemize}
\item L is a simple inductive datatype. The constructors of L may
have one of the three following forms:
\begin{enumerate}
\item ordinary recursive constructors like: \verb|Cplus : L -> L -> L|
\item variable leaf like: \verb|Cvar : index -> L|
\item constant leaf like \verb|Cconst : A -> L|
\end{enumerate}
The definition of \texttt{L} must contain at most one variable
leaf and at most one constant leaf.
When there are both a variable leaf and a constant leaf, there is
an ambiguity on inversion. The term t can be either the
interpretation of \texttt{(Cconst t)} or the interpretation of
(\texttt{Cvar}~$i$) in a variable map containing the binding $i
\rightarrow$~\texttt{t}. How to discriminate between these
choices?
To solve the dilemma, one gives to \texttt{quote} a list of
\emph{constant constructors}: a term will be considered as a
constant if it is either a constant constructor or the
application of a constant constructor to constants. For example
the list \verb+[S, O]+ defines the closed natural
numbers. \texttt{(S (S O))} is a constant when \texttt{(S x)} is
not.
The definition of constants vary for each application of the
tactic, so it can even be different for two applications of
\texttt{quote} with the same function.
\item \texttt{f} is a quite simple fixpoint on
\texttt{L}. In particular, \texttt{f} must verify:
\begin{verbatim}
(f (Cvar i)) = (varmap_find vm default_value i)
\end{verbatim}
\begin{verbatim}
(f (Cconst c)) = c
\end{verbatim}
where \texttt{index} and \texttt{varmap\_find} are those defined
the \texttt{Quote} module. \emph{The tactic won't work with
user's own variables map!!} It is mandatory to use the
variable map defined in module \texttt{Quote}.
\end{itemize}
The method to proceed is then clear:
\begin{itemize}
\item Start with an empty hashtable of "registed leafs"
that maps constr to integers and a "variable counter" equal to 0.
\item Try to match the term with every right hand side of the
definition of \texttt{f}.
If there is one match, returns the correponding left hand
side and call yourself recursively to get the arguments of this
left hand side.
If there is no match, we are at a leaf. That is the
interpretation of either a variable or a constant.
If it is a constant, return \texttt{Cconst} applied to that
constant.
If not, it is a variable. Look in the hashtable
if this leaf has been already encountered. If not, increment
the variable counter and add an entry to the hashtable; then
return \texttt{(Cvar !variables\_counter)}
\end{itemize}
*)
(*i*)
open Errors
open Util
open Names
open Term
open Pattern
open Patternops
open Constr_matching
open Tacmach
open Proofview.Notations
(*i*)
(*s First, we need to access some Coq constants
We do that lazily, because this code can be linked before
the constants are loaded in the environment *)
let constant dir s = Coqlib.gen_constant "Quote" ("quote"::dir) s
let coq_Empty_vm = lazy (constant ["Quote"] "Empty_vm")
let coq_Node_vm = lazy (constant ["Quote"] "Node_vm")
let coq_varmap_find = lazy (constant ["Quote"] "varmap_find")
let coq_Right_idx = lazy (constant ["Quote"] "Right_idx")
let coq_Left_idx = lazy (constant ["Quote"] "Left_idx")
let coq_End_idx = lazy (constant ["Quote"] "End_idx")
(*s Then comes the stuff to decompose the body of interpetation function
and pre-compute the inversion data.
For a function like:
\begin{verbatim}
Fixpoint interp (vm:varmap Prop) (f:form) :=
match f with
| f_and f1 f1 f2 => (interp f1) /\ (interp f2)
| f_or f1 f1 f2 => (interp f1) \/ (interp f2)
| f_var i => varmap_find Prop default_v i vm
| f_const c => c
end.
\end{verbatim}
With the constant constructors \texttt{C1}, \dots, \texttt{Cn}, the
corresponding scheme will be:
\begin{verbatim}
{normal_lhs_rhs =
[ "(f_and ?1 ?2)", "?1 /\ ?2";
"(f_or ?1 ?2)", " ?1 \/ ?2";];
return_type = "Prop";
constants = Some [C1,...Cn];
variable_lhs = Some "(f_var ?1)";
constant_lhs = Some "(f_const ?1)"
}
\end{verbatim}
If there is no constructor for variables in the type \texttt{form},
then [variable_lhs] is [None]. Idem for constants and
[constant_lhs]. Both cannot be equal to [None].
The metas in the RHS must correspond to those in the LHS (one cannot
exchange ?1 and ?2 in the example above)
*)
module ConstrSet = Set.Make(
struct
type t = constr
let compare = constr_ord
end)
type inversion_scheme = {
normal_lhs_rhs : (constr * constr_pattern) list;
variable_lhs : constr option;
return_type : constr;
constants : ConstrSet.t;
constant_lhs : constr option }
(*s [compute_ivs gl f cs] computes the inversion scheme associated to
[f:constr] with constants list [cs:constr list] in the context of
goal [gl]. This function uses the auxiliary functions
[i_can't_do_that], [decomp_term], [compute_lhs] and [compute_rhs]. *)
let i_can't_do_that () = error "Quote: not a simple fixpoint"
let decomp_term c = kind_of_term (strip_outer_cast c)
(*s [compute_lhs typ i nargsi] builds the term \texttt{(C ?nargsi ...
?2 ?1)}, where \texttt{C} is the [i]-th constructor of inductive
type [typ] *)
let coerce_meta_out id =
let s = Id.to_string id in
int_of_string (String.sub s 1 (String.length s - 1))
let coerce_meta_in n =
Id.of_string ("M" ^ string_of_int n)
let compute_lhs typ i nargsi =
match kind_of_term typ with
| Ind((sp,0),u) ->
let argsi = Array.init nargsi (fun j -> mkMeta (nargsi - j)) in
mkApp (mkConstructU (((sp,0),i+1),u), argsi)
| _ -> i_can't_do_that ()
(*s This function builds the pattern from the RHS. Recursive calls are
replaced by meta-variables ?i corresponding to those in the LHS *)
let compute_rhs bodyi index_of_f =
let rec aux c =
match kind_of_term c with
| App (j, args) when isRel j && Int.equal (destRel j) index_of_f (* recursive call *) ->
let i = destRel (Array.last args) in
PMeta (Some (coerce_meta_in i))
| App (f,args) ->
PApp (pattern_of_constr (Global.env()) Evd.empty f, Array.map aux args)
| Cast (c,_,_) -> aux c
| _ -> pattern_of_constr (Global.env())(*FIXME*) Evd.empty c
in
aux bodyi
(*s Now the function [compute_ivs] itself *)
let compute_ivs f cs gl =
let cst = try destConst f with DestKO -> i_can't_do_that () in
let body = Environ.constant_value_in (Global.env()) cst in
match decomp_term body with
| Fix(([| len |], 0), ([| name |], [| typ |], [| body2 |])) ->
let (args3, body3) = decompose_lam body2 in
let nargs3 = List.length args3 in
let env = Proofview.Goal.env gl in
let sigma = Tacmach.New.project gl in
let is_conv = Reductionops.is_conv env sigma in
begin match decomp_term body3 with
| Case(_,p,c,lci) -> (* <p> Case c of c1 ... cn end *)
let n_lhs_rhs = ref []
and v_lhs = ref (None : constr option)
and c_lhs = ref (None : constr option) in
Array.iteri
(fun i ci ->
let argsi, bodyi = decompose_lam ci in
let nargsi = List.length argsi in
(* REL (narg3 + nargsi + 1) is f *)
(* REL nargsi+1 to REL nargsi + nargs3 are arguments of f *)
(* REL 1 to REL nargsi are argsi (reverse order) *)
(* First we test if the RHS is the RHS for constants *)
if isRel bodyi && Int.equal (destRel bodyi) 1 then
c_lhs := Some (compute_lhs (snd (List.hd args3))
i nargsi)
(* Then we test if the RHS is the RHS for variables *)
else begin match decompose_app bodyi with
| vmf, [_; _; a3; a4 ]
when isRel a3 && isRel a4 && is_conv vmf
(Lazy.force coq_varmap_find)->
v_lhs := Some (compute_lhs
(snd (List.hd args3))
i nargsi)
(* Third case: this is a normal LHS-RHS *)
| _ ->
n_lhs_rhs :=
(compute_lhs (snd (List.hd args3)) i nargsi,
compute_rhs bodyi (nargs3 + nargsi + 1))
:: !n_lhs_rhs
end)
lci;
if Option.is_empty !c_lhs && Option.is_empty !v_lhs then i_can't_do_that ();
(* The Cases predicate is a lambda; we assume no dependency *)
let p = match kind_of_term p with
| Lambda (_,_,p) -> Termops.pop p
| _ -> p
in
{ normal_lhs_rhs = List.rev !n_lhs_rhs;
variable_lhs = !v_lhs;
return_type = p;
constants = List.fold_right ConstrSet.add cs ConstrSet.empty;
constant_lhs = !c_lhs }
| _ -> i_can't_do_that ()
end
|_ -> i_can't_do_that ()
(* TODO for that function:
\begin{itemize}
\item handle the case where the return type is an argument of the
function
\item handle the case of simple mutual inductive (for example terms
and lists of terms) formulas with the corresponding mutual
recursvive interpretation functions.
\end{itemize}
*)
(*s Stuff to build variables map, currently implemented as complete
binary search trees (see file \texttt{Quote.v}) *)
(* First the function to distinghish between constants (closed terms)
and variables (open terms) *)
let rec closed_under cset t =
(ConstrSet.mem t cset) ||
(match (kind_of_term t) with
| Cast(c,_,_) -> closed_under cset c
| App(f,l) -> closed_under cset f && Array.for_all (closed_under cset) l
| _ -> false)
(*s [btree_of_array [| c1; c2; c3; c4; c5 |]] builds the complete
binary search tree containing the [ci], that is:
\begin{verbatim}
c1
/ \
c2 c3
/ \
c4 c5
\end{verbatim}
The second argument is a constr (the common type of the [ci])
*)
let btree_of_array a ty =
let size_of_a = Array.length a in
let semi_size_of_a = size_of_a lsr 1 in
let node = Lazy.force coq_Node_vm
and empty = mkApp (Lazy.force coq_Empty_vm, [| ty |]) in
let rec aux n =
if n > size_of_a
then empty
else if n > semi_size_of_a
then mkApp (node, [| ty; a.(n-1); empty; empty |])
else mkApp (node, [| ty; a.(n-1); aux (2*n); aux (2*n+1) |])
in
aux 1
(*s [btree_of_array] and [path_of_int] verify the following invariant:\\
{\tt (varmap\_find A dv }[(path_of_int n)] [(btree_of_array a ty)]
= [a.(n)]\\
[n] must be [> 0] *)
let path_of_int n =
(* returns the list of digits of n in reverse order with
initial 1 removed *)
let rec digits_of_int n =
if Int.equal n 1 then []
else (Int.equal (n mod 2) 1)::(digits_of_int (n lsr 1))
in
List.fold_right
(fun b c -> mkApp ((if b then Lazy.force coq_Right_idx
else Lazy.force coq_Left_idx),
[| c |]))
(List.rev (digits_of_int n))
(Lazy.force coq_End_idx)
(*s The tactic works with a list of subterms sharing the same
variables map. We need to sort terms in order to avoid than
strange things happen during replacement of terms by their
'abstract' counterparties. *)
(* [subterm t t'] tests if constr [t'] occurs in [t] *)
(* This function does not descend under binders (lambda and Cases) *)
let rec subterm gl (t : constr) (t' : constr) =
(pf_conv_x gl t t') ||
(match (kind_of_term t) with
| App (f,args) -> Array.exists (fun t -> subterm gl t t') args
| Cast(t,_,_) -> (subterm gl t t')
| _ -> false)
(*s We want to sort the list according to reverse subterm order. *)
(* Since it's a partial order the algoritm of Sort.list won't work !! *)
let rec sort_subterm gl l =
let rec insert c = function
| [] -> [c]
| (h::t as l) when eq_constr c h -> l (* Avoid doing the same work twice *)
| h::t -> if subterm gl c h then c::h::t else h::(insert c t)
in
match l with
| [] -> []
| h::t -> insert h (sort_subterm gl t)
module Constrhash = Hashtbl.Make
(struct type t = constr
let equal = eq_constr
let hash = hash_constr
end)
(*s Now we are able to do the inversion itself.
We destructurate the term and use an imperative hashtable
to store leafs that are already encountered.
The type of arguments is:\\
[ivs : inversion_scheme]\\
[lc: constr list]\\
[gl: goal sigma]\\ *)
let quote_terms ivs lc =
Coqlib.check_required_library ["Coq";"quote";"Quote"];
let varhash = (Constrhash.create 17 : constr Constrhash.t) in
let varlist = ref ([] : constr list) in (* list of variables *)
let counter = ref 1 in (* number of variables created + 1 *)
let rec aux c =
let rec auxl l =
match l with
| (lhs, rhs)::tail ->
begin try
let s1 = Id.Map.bindings (matches (Global.env ()) Evd.empty rhs c) in
let s2 = List.map (fun (i,c_i) -> (coerce_meta_out i,aux c_i)) s1
in
Termops.subst_meta s2 lhs
with PatternMatchingFailure -> auxl tail
end
| [] ->
begin match ivs.variable_lhs with
| None ->
begin match ivs.constant_lhs with
| Some c_lhs -> Termops.subst_meta [1, c] c_lhs
| None -> anomaly (Pp.str "invalid inversion scheme for quote")
end
| Some var_lhs ->
begin match ivs.constant_lhs with
| Some c_lhs when closed_under ivs.constants c ->
Termops.subst_meta [1, c] c_lhs
| _ ->
begin
try Constrhash.find varhash c
with Not_found ->
let newvar =
Termops.subst_meta [1, (path_of_int !counter)]
var_lhs in
begin
incr counter;
varlist := c :: !varlist;
Constrhash.add varhash c newvar;
newvar
end
end
end
end
in
auxl ivs.normal_lhs_rhs
in
let lp = List.map aux lc in
(lp, (btree_of_array (Array.of_list (List.rev !varlist))
ivs.return_type ))
(*s actually we could "quote" a list of terms instead of a single
term. Ring for example needs that, but Ring doesn't use Quote
yet. *)
let quote f lid =
Proofview.Goal.nf_enter { enter = begin fun gl ->
let f = Tacmach.New.pf_global f gl in
let cl = List.map (fun id -> Tacmach.New.pf_global id gl) lid in
let ivs = compute_ivs f cl gl in
let concl = Proofview.Goal.concl gl in
let quoted_terms = quote_terms ivs [concl] in
let (p, vm) = match quoted_terms with
| [p], vm -> (p,vm)
| _ -> assert false
in
match ivs.variable_lhs with
| None -> Tactics.convert_concl (mkApp (f, [| p |])) DEFAULTcast
| Some _ -> Tactics.convert_concl (mkApp (f, [| vm; p |])) DEFAULTcast
end }
let gen_quote cont c f lid =
Proofview.Goal.nf_enter { enter = begin fun gl ->
let f = Tacmach.New.pf_global f gl in
let cl = List.map (fun id -> Tacmach.New.pf_global id gl) lid in
let ivs = compute_ivs f cl gl in
let quoted_terms = quote_terms ivs [c] in
let (p, vm) = match quoted_terms with
| [p], vm -> (p,vm)
| _ -> assert false
in
match ivs.variable_lhs with
| None -> cont (mkApp (f, [| p |]))
| Some _ -> cont (mkApp (f, [| vm; p |]))
end }
(*i
Just testing ...
#use "include.ml";;
open Quote;;
let r = glob_constr_of_string;;
let ivs = {
normal_lhs_rhs =
[ r "(f_and ?1 ?2)", r "?1/\?2";
r "(f_not ?1)", r "~?1"];
variable_lhs = Some (r "(f_atom ?1)");
return_type = r "Prop";
constants = ConstrSet.empty;
constant_lhs = (r "nat")
};;
let t1 = r "True/\(True /\ ~False)";;
let t2 = r "True/\~~False";;
quote_term ivs () t1;;
quote_term ivs () t2;;
let ivs2 =
normal_lhs_rhs =
[ r "(f_and ?1 ?2)", r "?1/\?2";
r "(f_not ?1)", r "~?1"
r "True", r "f_true"];
variable_lhs = Some (r "(f_atom ?1)");
return_type = r "Prop";
constants = ConstrSet.empty;
constant_lhs = (r "nat")
i*)
|