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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id$ *)
(*i*)
open Pp
open Util
open Names
open Nameops
open Libnames
open Rawterm
open Term
open Mod_subst
(*i*)
(**********************************************************************)
(* This is the subtype of rawconstr allowed in syntactic extensions *)
(* For AList: first constr is iterator, second is terminator;
first id is where each argument of the list has to be substituted
in iterator and snd id is alternative name just for printing;
boolean is associativity *)
type aconstr =
(* Part common to rawconstr and cases_pattern *)
| ARef of global_reference
| AVar of identifier
| AApp of aconstr * aconstr list
| AList of identifier * identifier * aconstr * aconstr * bool
(* Part only in rawconstr *)
| ALambda of name * aconstr * aconstr
| AProd of name * aconstr * aconstr
| ALetIn of name * aconstr * aconstr
| ACases of aconstr option *
(aconstr * (name * (inductive * int * name list) option)) list *
(cases_pattern list * aconstr) list
| ALetTuple of name list * (name * aconstr option) * aconstr * aconstr
| AIf of aconstr * (name * aconstr option) * aconstr * aconstr
| ASort of rawsort
| AHole of Evd.hole_kind
| APatVar of patvar
| ACast of aconstr * cast_type * aconstr
(**********************************************************************)
(* Re-interpret a notation as a rawconstr, taking care of binders *)
let rec cases_pattern_fold_map loc g e = function
| PatVar (_,na) ->
let e',na' = name_fold_map g e na in e', PatVar (loc,na')
| PatCstr (_,cstr,patl,na) ->
let e',na' = name_fold_map g e na in
let e',patl' = list_fold_map (cases_pattern_fold_map loc g) e patl in
e', PatCstr (loc,cstr,patl',na')
let rec subst_rawvars l = function
| RVar (_,id) as r -> (try List.assoc id l with Not_found -> r)
| r -> map_rawconstr (subst_rawvars l) r (* assume: id is not binding *)
let ldots_var = id_of_string ".."
let rawconstr_of_aconstr_with_binders loc g f e = function
| AVar id -> RVar (loc,id)
| AApp (a,args) -> RApp (loc,f e a, List.map (f e) args)
| AList (x,y,iter,tail,swap) ->
let t = f e tail in let it = f e iter in
let innerl = (ldots_var,t)::(if swap then [] else [x,RVar(loc,y)]) in
let inner = RApp (loc,RVar (loc,ldots_var),[subst_rawvars innerl it]) in
let outerl = (ldots_var,inner)::(if swap then [x,RVar(loc,y)] else []) in
subst_rawvars outerl it
| ALambda (na,ty,c) ->
let e,na = name_fold_map g e na in RLambda (loc,na,f e ty,f e c)
| AProd (na,ty,c) ->
let e,na = name_fold_map g e na in RProd (loc,na,f e ty,f e c)
| ALetIn (na,b,c) ->
let e,na = name_fold_map g e na in RLetIn (loc,na,f e b,f e c)
| ACases (rtntypopt,tml,eqnl) ->
let e',tml' = List.fold_right (fun (tm,(na,t)) (e',tml') ->
let e',t' = match t with
| None -> e',None
| Some (ind,npar,nal) ->
let e',nal' = List.fold_right (fun na (e',nal) ->
let e',na' = name_fold_map g e' na in e',na'::nal) nal (e',[]) in
e',Some (loc,ind,npar,nal') in
let e',na' = name_fold_map g e' na in
(e',(f e tm,(na',t'))::tml')) tml (e,[]) in
let fold (idl,e) id = let (e,id) = g e id in ((id::idl,e),id) in
let eqnl' = List.map (fun (patl,rhs) ->
let ((idl,e),patl) =
list_fold_map (cases_pattern_fold_map loc fold) ([],e) patl in
(loc,idl,patl,f e rhs)) eqnl in
RCases (loc,option_map (f e') rtntypopt,tml',eqnl')
| ALetTuple (nal,(na,po),b,c) ->
let e,nal = list_fold_map (name_fold_map g) e nal in
let e,na = name_fold_map g e na in
RLetTuple (loc,nal,(na,option_map (f e) po),f e b,f e c)
| AIf (c,(na,po),b1,b2) ->
let e,na = name_fold_map g e na in
RIf (loc,f e c,(na,option_map (f e) po),f e b1,f e b2)
| ACast (c,k,t) -> RCast (loc,f e c, k,f e t)
| ASort x -> RSort (loc,x)
| AHole x -> RHole (loc,x)
| APatVar n -> RPatVar (loc,(false,n))
| ARef x -> RRef (loc,x)
let rec rawconstr_of_aconstr loc x =
let rec aux () x =
rawconstr_of_aconstr_with_binders loc (fun () id -> ((),id)) aux () x
in aux () x
(****************************************************************************)
(* Translating a rawconstr into a notation, interpreting recursive patterns *)
let add_name r = function
| Anonymous -> ()
| Name id -> r := id :: !r
let has_ldots =
List.exists
(function RApp (_,RVar(_,v),_) when v = ldots_var -> true | _ -> false)
let compare_rawconstr f t1 t2 = match t1,t2 with
| RRef (_,r1), RRef (_,r2) -> r1 = r2
| RVar (_,v1), RVar (_,v2) -> v1 = v2
| RApp (_,f1,l1), RApp (_,f2,l2) -> f f1 f2 & List.for_all2 f l1 l2
| RLambda (_,na1,ty1,c1), RLambda (_,na2,ty2,c2) when na1 = na2 ->
f ty1 ty2 & f c1 c2
| RProd (_,na1,ty1,c1), RProd (_,na2,ty2,c2) when na1 = na2 ->
f ty1 ty2 & f c1 c2
| RHole _, RHole _ -> true
| RSort (_,s1), RSort (_,s2) -> s1 = s2
| (RLetIn _ | RCases _ | RRec _ | RDynamic _
| RPatVar _ | REvar _ | RLetTuple _ | RIf _ | RCast _),_
| _,(RLetIn _ | RCases _ | RRec _ | RDynamic _
| RPatVar _ | REvar _ | RLetTuple _ | RIf _ | RCast _)
-> error "Unsupported construction in recursive notations"
| (RRef _ | RVar _ | RApp _ | RLambda _ | RProd _ | RHole _ | RSort _), _
-> false
let rec eq_rawconstr t1 t2 = compare_rawconstr eq_rawconstr t1 t2
let discriminate_patterns foundvars nl l1 l2 =
let diff = ref None in
let rec aux n c1 c2 = match c1,c2 with
| RVar (_,v1), RVar (_,v2) when v1<>v2 ->
if !diff = None then (diff := Some (v1,v2,(n>=nl)); true)
else
!diff = Some (v1,v2,(n>=nl)) or !diff = Some (v2,v1,(n<nl))
or (error
"Both ends of the recursive pattern differ in more than one place")
| _ -> compare_rawconstr (aux (n+1)) c1 c2 in
let l = list_map2_i aux 0 l1 l2 in
if not (List.for_all ((=) true) l) then
error "Both ends of the recursive pattern differ";
match !diff with
| None -> error "Both ends of the recursive pattern are the same"
| Some (x,y,_ as discr) ->
List.iter (fun id ->
if List.mem id !foundvars
then error "Variables used in the recursive part of a pattern are not allowed to occur outside of the recursive part";
foundvars := id::!foundvars) [x;y];
discr
let aconstr_and_vars_of_rawconstr a =
let found = ref [] in
let rec aux = function
| RVar (_,id) -> found := id::!found; AVar id
| RApp (_,f,args) when has_ldots args -> make_aconstr_list f args
| RApp (_,RVar (_,f),[RApp (_,t,[c]);d]) when f = ldots_var ->
(* Special case for alternative (recursive) notation of application *)
let x,y,lassoc = discriminate_patterns found 0 [c] [d] in
found := ldots_var :: !found; assert lassoc;
AList (x,y,AApp (AVar ldots_var,[AVar x]),aux t,lassoc)
| RApp (_,g,args) -> AApp (aux g, List.map aux args)
| RLambda (_,na,ty,c) -> add_name found na; ALambda (na,aux ty,aux c)
| RProd (_,na,ty,c) -> add_name found na; AProd (na,aux ty,aux c)
| RLetIn (_,na,b,c) -> add_name found na; ALetIn (na,aux b,aux c)
| RCases (_,rtntypopt,tml,eqnl) ->
let f (_,idl,pat,rhs) = found := idl@(!found); (pat,aux rhs) in
ACases (option_map aux rtntypopt,
List.map (fun (tm,(na,x)) ->
add_name found na;
option_iter
(fun (_,_,_,nl) -> List.iter (add_name found) nl) x;
(aux tm,(na,option_map (fun (_,ind,n,nal) -> (ind,n,nal)) x))) tml,
List.map f eqnl)
| RLetTuple (loc,nal,(na,po),b,c) ->
add_name found na;
List.iter (add_name found) nal;
ALetTuple (nal,(na,option_map aux po),aux b,aux c)
| RIf (loc,c,(na,po),b1,b2) ->
add_name found na;
AIf (aux c,(na,option_map aux po),aux b1,aux b2)
| RCast (_,c,k,t) -> ACast (aux c,k,aux t)
| RSort (_,s) -> ASort s
| RHole (_,w) -> AHole w
| RRef (_,r) -> ARef r
| RPatVar (_,(_,n)) -> APatVar n
| RDynamic _ | RRec _ | REvar _ ->
error "Fixpoints, cofixpoints, existential variables and pattern-matching not \
allowed in abbreviatable expressions"
(* Recognizing recursive notations *)
and terminator_of_pat f1 ll1 lr1 = function
| RApp (loc,f2,l2) ->
if not (eq_rawconstr f1 f2) then error
"Cannot recognize the same head to both ends of the recursive pattern";
let nl = List.length ll1 in
let nr = List.length lr1 in
if List.length l2 <> nl + nr + 1 then
error "Both ends of the recursive pattern have different lengths";
let ll2,l2' = list_chop nl l2 in
let t = List.hd l2' and lr2 = List.tl l2' in
let x,y,order = discriminate_patterns found nl (ll1@lr1) (ll2@lr2) in
let iter =
if order then RApp (loc,f2,ll2@RVar (loc,ldots_var)::lr2)
else RApp (loc,f1,ll1@RVar (loc,ldots_var)::lr1) in
(if order then y else x),(if order then x else y), aux iter, aux t, order
| _ -> error "One end of the recursive pattern is not an application"
and make_aconstr_list f args =
let rec find_patterns acc = function
| RApp(_,RVar (_,a),[c]) :: l when a = ldots_var ->
(* We've found the recursive part *)
let x,y,iter,term,lassoc = terminator_of_pat f (List.rev acc) l c in
AList (x,y,iter,term,lassoc)
| a::l -> find_patterns (a::acc) l
| [] -> error "Ill-formed recursive notation"
in find_patterns [] args
in
let t = aux a in
(* Side effect *)
t, !found
let aconstr_of_rawconstr vars a =
let a,foundvars = aconstr_and_vars_of_rawconstr a in
let check_type x =
if not (List.mem x foundvars) then
error ((string_of_id x)^" is unbound in the right-hand-side") in
List.iter check_type vars;
a
(* Substitution of kernel names, avoiding a list of bound identifiers *)
let aconstr_of_constr avoiding t =
aconstr_of_rawconstr [] (Detyping.detype false avoiding [] t)
let rec subst_pat subst pat =
match pat with
| PatVar _ -> pat
| PatCstr (loc,((kn,i),j),cpl,n) ->
let kn' = subst_kn subst kn
and cpl' = list_smartmap (subst_pat subst) cpl in
if kn' == kn && cpl' == cpl then pat else
PatCstr (loc,((kn',i),j),cpl',n)
let rec subst_aconstr subst bound raw =
match raw with
| ARef ref ->
let ref',t = subst_global subst ref in
if ref' == ref then raw else
aconstr_of_constr bound t
| AVar _ -> raw
| AApp (r,rl) ->
let r' = subst_aconstr subst bound r
and rl' = list_smartmap (subst_aconstr subst bound) rl in
if r' == r && rl' == rl then raw else
AApp(r',rl')
| AList (id1,id2,r1,r2,b) ->
let r1' = subst_aconstr subst bound r1
and r2' = subst_aconstr subst bound r2 in
if r1' == r1 && r2' == r2 then raw else
AList (id1,id2,r1',r2',b)
| ALambda (n,r1,r2) ->
let r1' = subst_aconstr subst bound r1
and r2' = subst_aconstr subst bound r2 in
if r1' == r1 && r2' == r2 then raw else
ALambda (n,r1',r2')
| AProd (n,r1,r2) ->
let r1' = subst_aconstr subst bound r1
and r2' = subst_aconstr subst bound r2 in
if r1' == r1 && r2' == r2 then raw else
AProd (n,r1',r2')
| ALetIn (n,r1,r2) ->
let r1' = subst_aconstr subst bound r1
and r2' = subst_aconstr subst bound r2 in
if r1' == r1 && r2' == r2 then raw else
ALetIn (n,r1',r2')
| ACases (rtntypopt,rl,branches) ->
let rtntypopt' = option_smartmap (subst_aconstr subst bound) rtntypopt
and rl' = list_smartmap
(fun (a,(n,signopt) as x) ->
let a' = subst_aconstr subst bound a in
let signopt' = option_map (fun ((indkn,i),n,nal as z) ->
let indkn' = subst_kn subst indkn in
if indkn == indkn' then z else ((indkn',i),n,nal)) signopt in
if a' == a && signopt' == signopt then x else (a',(n,signopt')))
rl
and branches' = list_smartmap
(fun (cpl,r as branch) ->
let cpl' = list_smartmap (subst_pat subst) cpl
and r' = subst_aconstr subst bound r in
if cpl' == cpl && r' == r then branch else
(cpl',r'))
branches
in
if rtntypopt' == rtntypopt && rtntypopt == rtntypopt' &
rl' == rl && branches' == branches then raw else
ACases (rtntypopt',rl',branches')
| ALetTuple (nal,(na,po),b,c) ->
let po' = option_smartmap (subst_aconstr subst bound) po
and b' = subst_aconstr subst bound b
and c' = subst_aconstr subst bound c in
if po' == po && b' == b && c' == c then raw else
ALetTuple (nal,(na,po'),b',c')
| AIf (c,(na,po),b1,b2) ->
let po' = option_smartmap (subst_aconstr subst bound) po
and b1' = subst_aconstr subst bound b1
and b2' = subst_aconstr subst bound b2
and c' = subst_aconstr subst bound c in
if po' == po && b1' == b1 && b2' == b2 && c' == c then raw else
AIf (c',(na,po'),b1',b2')
| APatVar _ | ASort _ -> raw
| AHole (Evd.ImplicitArg (ref,i)) ->
let ref',t = subst_global subst ref in
if ref' == ref then raw else
AHole (Evd.InternalHole)
| AHole (Evd.BinderType _ | Evd.QuestionMark | Evd.CasesType |
Evd.InternalHole | Evd.TomatchTypeParameter _) -> raw
| ACast (r1,k,r2) ->
let r1' = subst_aconstr subst bound r1
and r2' = subst_aconstr subst bound r2 in
if r1' == r1 && r2' == r2 then raw else
ACast (r1',k,r2')
let encode_list_value l = RApp (dummy_loc,RVar (dummy_loc,ldots_var),l)
(* Pattern-matching rawconstr and aconstr *)
let abstract_return_type_context pi mklam tml rtno =
option_map (fun rtn ->
let nal =
List.flatten (List.map (fun (_,(na,t)) ->
match t with Some x -> (pi x)@[na] | None -> [na]) tml) in
List.fold_right mklam nal rtn)
rtno
let abstract_return_type_context_rawconstr =
abstract_return_type_context (fun (_,_,_,nal) -> nal)
(fun na c -> RLambda(dummy_loc,na,RHole(dummy_loc,Evd.InternalHole),c))
let abstract_return_type_context_aconstr =
abstract_return_type_context pi3
(fun na c -> ALambda(na,AHole Evd.InternalHole,c))
let rec adjust_scopes = function
| _,[] -> []
| [],a::args -> (None,a) :: adjust_scopes ([],args)
| sc::scopes,a::args -> (sc,a) :: adjust_scopes (scopes,args)
exception No_match
let rec alpha_var id1 id2 = function
| (i1,i2)::_ when i1=id1 -> i2 = id2
| (i1,i2)::_ when i2=id2 -> i1 = id1
| _::idl -> alpha_var id1 id2 idl
| [] -> id1 = id2
let alpha_eq_val (x,y) = x = y
let bind_env alp sigma var v =
try
let vvar = List.assoc var sigma in
if alpha_eq_val (v,vvar) then sigma
else raise No_match
with Not_found ->
(* Check that no capture of binding variables occur *)
if List.exists (fun (id,_) ->occur_rawconstr id v) alp then raise No_match;
(* TODO: handle the case of multiple occs in different scopes *)
(var,v)::sigma
let match_opt f sigma t1 t2 = match (t1,t2) with
| None, None -> sigma
| Some t1, Some t2 -> f sigma t1 t2
| _ -> raise No_match
let match_names metas (alp,sigma) na1 na2 = match (na1,na2) with
| (Name id1,Name id2) when List.mem id2 metas ->
alp, bind_env alp sigma id2 (RVar (dummy_loc,id1))
| (Name id1,Name id2) -> (id1,id2)::alp,sigma
| (Anonymous,Anonymous) -> alp,sigma
| _ -> raise No_match
let rec match_cases_pattern metas acc pat1 pat2 =
match (pat1,pat2) with
| PatVar (_,na1), PatVar (_,na2) -> match_names metas acc na1 na2
| PatCstr (_,c1,patl1,na1), PatCstr (_,c2,patl2,na2)
when c1 = c2 & List.length patl1 = List.length patl2 ->
List.fold_left2 (match_cases_pattern metas)
(match_names metas acc na1 na2) patl1 patl2
| _ -> raise No_match
let rec match_ alp metas sigma a1 a2 = match (a1,a2) with
| r1, AVar id2 when List.mem id2 metas -> bind_env alp sigma id2 r1
| RVar (_,id1), AVar id2 when alpha_var id1 id2 alp -> sigma
| RRef (_,r1), ARef r2 when r1 = r2 -> sigma
| RPatVar (_,(_,n1)), APatVar n2 when n1=n2 -> sigma
| RApp (_,f1,l1), AApp (f2,l2) when List.length l1 = List.length l2 ->
List.fold_left2 (match_ alp metas) (match_ alp metas sigma f1 f2) l1 l2
| RApp (_,f1,l1), AList (x,_,(AApp (f2,l2) as iter),termin,lassoc)
when List.length l1 = List.length l2 ->
match_alist alp metas sigma (f1::l1) (f2::l2) x iter termin lassoc
| RLambda (_,na1,t1,b1), ALambda (na2,t2,b2) ->
match_binders alp metas na1 na2 (match_ alp metas sigma t1 t2) b1 b2
| RProd (_,na1,t1,b1), AProd (na2,t2,b2) ->
match_binders alp metas na1 na2 (match_ alp metas sigma t1 t2) b1 b2
| RLetIn (_,na1,t1,b1), ALetIn (na2,t2,b2) ->
match_binders alp metas na1 na2 (match_ alp metas sigma t1 t2) b1 b2
| RCases (_,rtno1,tml1,eqnl1), ACases (rtno2,tml2,eqnl2)
when List.length tml1 = List.length tml2
& List.length eqnl1 = List.length eqnl2 ->
let rtno1' = abstract_return_type_context_rawconstr tml1 rtno1 in
let rtno2' = abstract_return_type_context_aconstr tml2 rtno2 in
let sigma = option_fold_left2 (match_ alp metas) sigma rtno1' rtno2' in
let sigma = List.fold_left2
(fun s (tm1,_) (tm2,_) -> match_ alp metas s tm1 tm2) sigma tml1 tml2 in
List.fold_left2 (match_equations alp metas) sigma eqnl1 eqnl2
| RIf (_,a1,(na1,to1),b1,c1), AIf (a2,(na2,to2),b2,c2) ->
let sigma = match_opt (match_binders alp metas na1 na2) sigma to1 to2 in
List.fold_left2 (match_ alp metas) sigma [a1;b1;c1] [a2;b2;c2]
| RLetTuple (_,nal1,(na1,to1),b1,c1), ALetTuple (nal2,(na2,to2),b2,c2)
when List.length nal1 = List.length nal2 ->
let sigma = match_opt (match_binders alp metas na1 na2) sigma to1 to2 in
let sigma = match_ alp metas sigma b1 b2 in
let (alp,sigma) =
List.fold_left2 (match_names metas) (alp,sigma) nal1 nal2 in
match_ alp metas sigma c1 c2
| RCast(_,c1,_,t1), ACast(c2,_,t2) ->
match_ alp metas (match_ alp metas sigma c1 c2) t1 t2
| RSort (_,s1), ASort s2 when s1 = s2 -> sigma
| RPatVar _, AHole _ -> (*Don't hide Metas, they bind in ltac*) raise No_match
| a, AHole _ -> sigma
| (RDynamic _ | RRec _ | REvar _), _
| _,_ -> raise No_match
and match_alist alp metas sigma l1 l2 x iter termin lassoc =
(* match the iterator at least once *)
let sigma = List.fold_left2 (match_ alp (ldots_var::metas)) sigma l1 l2 in
(* Recover the recursive position *)
let rest = List.assoc ldots_var sigma in
(* Recover the first element *)
let t1 = List.assoc x sigma in
let sigma = List.remove_assoc x (List.remove_assoc ldots_var sigma) in
(* try to find the remaining elements or the terminator *)
let rec match_alist_tail alp metas sigma acc rest =
try
let sigma = match_ alp (ldots_var::metas) sigma rest iter in
let rest = List.assoc ldots_var sigma in
let t = List.assoc x sigma in
let sigma = List.remove_assoc x (List.remove_assoc ldots_var sigma) in
match_alist_tail alp metas sigma (t::acc) rest
with No_match ->
List.rev acc, match_ alp metas sigma rest termin in
let tl,sigma = match_alist_tail alp metas sigma [t1] rest in
(x,encode_list_value (if lassoc then List.rev tl else tl))::sigma
and match_binders alp metas na1 na2 sigma b1 b2 =
let (alp,sigma) = match_names metas (alp,sigma) na1 na2 in
match_ alp metas sigma b1 b2
and match_equations alp metas sigma (_,_,patl1,rhs1) (patl2,rhs2) =
(* patl1 and patl2 have the same length because they respectively
correspond to some tml1 and tml2 that have the same length *)
let (alp,sigma) =
List.fold_left2 (match_cases_pattern metas) (alp,sigma) patl1 patl2 in
match_ alp metas sigma rhs1 rhs2
type scope_name = string
type tmp_scope_name = scope_name
type interpretation =
(identifier * (tmp_scope_name option * scope_name list)) list * aconstr
let match_aconstr c (metas_scl,pat) =
let subst = match_ [] (List.map fst metas_scl) [] c pat in
(* Reorder canonically the substitution *)
let find x subst =
try List.assoc x subst
with Not_found ->
(* Happens for binders bound to Anonymous *)
(* Find a better way to propagate Anonymous... *)
RVar (dummy_loc,x) in
List.map (fun (x,scl) -> (find x subst,scl)) metas_scl
(**********************************************************************)
(*s Concrete syntax for terms *)
type notation = string
type explicitation = ExplByPos of int | ExplByName of identifier
type proj_flag = int option (* [Some n] = proj of the n-th visible argument *)
type prim_token = Numeral of Bigint.bigint | String of string
type cases_pattern_expr =
| CPatAlias of loc * cases_pattern_expr * identifier
| CPatCstr of loc * reference * cases_pattern_expr list
| CPatAtom of loc * reference option
| CPatOr of loc * cases_pattern_expr list
| CPatNotation of loc * notation * cases_pattern_expr list
| CPatPrim of loc * prim_token
| CPatDelimiters of loc * string * cases_pattern_expr
type constr_expr =
| CRef of reference
| CFix of loc * identifier located * fixpoint_expr list
| CCoFix of loc * identifier located * cofixpoint_expr list
| CArrow of loc * constr_expr * constr_expr
| CProdN of loc * (name located list * constr_expr) list * constr_expr
| CLambdaN of loc * (name located list * constr_expr) list * constr_expr
| CLetIn of loc * name located * constr_expr * constr_expr
| CAppExpl of loc * (proj_flag * reference) * constr_expr list
| CApp of loc * (proj_flag * constr_expr) *
(constr_expr * explicitation located option) list
| CCases of loc * constr_expr option *
(constr_expr * (name option * constr_expr option)) list *
(loc * cases_pattern_expr list list * constr_expr) list
| CLetTuple of loc * name list * (name option * constr_expr option) *
constr_expr * constr_expr
| CIf of loc * constr_expr * (name option * constr_expr option)
* constr_expr * constr_expr
| CHole of loc
| CPatVar of loc * (bool * patvar)
| CEvar of loc * existential_key
| CSort of loc * rawsort
| CCast of loc * constr_expr * cast_type * constr_expr
| CNotation of loc * notation * constr_expr list
| CPrim of loc * prim_token
| CDelimiters of loc * string * constr_expr
| CDynamic of loc * Dyn.t
and fixpoint_expr =
identifier * (int option * recursion_order_expr) * local_binder list * constr_expr * constr_expr
and local_binder =
| LocalRawDef of name located * constr_expr
| LocalRawAssum of name located list * constr_expr
and cofixpoint_expr =
identifier * local_binder list * constr_expr * constr_expr
and recursion_order_expr =
| CStructRec
| CWfRec of constr_expr
| CMeasureRec of constr_expr
(***********************)
(* For binders parsing *)
let rec local_binders_length = function
| [] -> 0
| LocalRawDef _::bl -> 1 + local_binders_length bl
| LocalRawAssum (idl,_)::bl -> List.length idl + local_binders_length bl
let rec local_assums_length = function
| [] -> 0
| LocalRawDef _::bl -> local_binders_length bl
| LocalRawAssum (idl,_)::bl -> List.length idl + local_binders_length bl
let names_of_local_assums bl =
List.flatten (List.map (function LocalRawAssum(l,_)->l|_->[]) bl)
let names_of_local_binders bl =
List.flatten (List.map (function LocalRawAssum(l,_)->l|LocalRawDef(l,_)->[l]) bl)
(**********************************************************************)
(* Functions on constr_expr *)
let constr_loc = function
| CRef (Ident (loc,_)) -> loc
| CRef (Qualid (loc,_)) -> loc
| CFix (loc,_,_) -> loc
| CCoFix (loc,_,_) -> loc
| CArrow (loc,_,_) -> loc
| CProdN (loc,_,_) -> loc
| CLambdaN (loc,_,_) -> loc
| CLetIn (loc,_,_,_) -> loc
| CAppExpl (loc,_,_) -> loc
| CApp (loc,_,_) -> loc
| CCases (loc,_,_,_) -> loc
| CLetTuple (loc,_,_,_,_) -> loc
| CIf (loc,_,_,_,_) -> loc
| CHole loc -> loc
| CPatVar (loc,_) -> loc
| CEvar (loc,_) -> loc
| CSort (loc,_) -> loc
| CCast (loc,_,_,_) -> loc
| CNotation (loc,_,_) -> loc
| CPrim (loc,_) -> loc
| CDelimiters (loc,_,_) -> loc
| CDynamic _ -> dummy_loc
let cases_pattern_expr_loc = function
| CPatAlias (loc,_,_) -> loc
| CPatCstr (loc,_,_) -> loc
| CPatAtom (loc,_) -> loc
| CPatOr (loc,_) -> loc
| CPatNotation (loc,_,_) -> loc
| CPatPrim (loc,_) -> loc
| CPatDelimiters (loc,_,_) -> loc
let occur_var_constr_ref id = function
| Ident (loc,id') -> id = id'
| Qualid _ -> false
let ids_of_cases_indtype =
let add_var ids = function CRef (Ident (_,id)) -> id::ids | _ -> ids in
let rec vars_of = function
(* We deal only with the regular cases *)
| CApp (_,_,l) -> List.fold_left add_var [] (List.map fst l)
| CNotation (_,_,l)
(* assume the ntn is applicative and does not instantiate the head !! *)
| CAppExpl (_,_,l) -> List.fold_left add_var [] l
| CDelimiters(_,_,c) -> vars_of c
| _ -> [] in
vars_of
let ids_of_cases_tomatch tms =
List.fold_right
(fun (_,(ona,indnal)) l ->
option_fold_right (fun t -> (@) (ids_of_cases_indtype t))
indnal (option_fold_right name_cons ona l))
tms []
let is_constructor id =
try ignore (Nametab.extended_locate (make_short_qualid id)); true
with Not_found -> true
let rec cases_pattern_fold_names f a = function
| CPatAlias (_,pat,id) -> f id a
| CPatCstr (_,_,patl) | CPatOr (_,patl) | CPatNotation (_,_,patl) ->
List.fold_left (cases_pattern_fold_names f) a patl
| CPatDelimiters (_,_,pat) -> cases_pattern_fold_names f a pat
| CPatAtom (_,Some (Ident (_,id))) when not (is_constructor id) -> f id a
| CPatPrim _ | CPatAtom _ -> a
let ids_of_pattern_list =
List.fold_left (List.fold_left (cases_pattern_fold_names Idset.add))
Idset.empty
let rec fold_constr_expr_binders g f n acc b = function
| (nal,t)::l ->
let nal = snd (List.split nal) in
let n' = List.fold_right (name_fold g) nal n in
f n (fold_constr_expr_binders g f n' acc b l) t
| [] ->
f n acc b
let rec fold_local_binders g f n acc b = function
| LocalRawAssum (nal,t)::l ->
let nal = snd (List.split nal) in
let n' = List.fold_right (name_fold g) nal n in
f n (fold_local_binders g f n' acc b l) t
| LocalRawDef ((_,na),t)::l ->
f n (fold_local_binders g f (name_fold g na n) acc b l) t
| _ ->
f n acc b
let fold_constr_expr_with_binders g f n acc = function
| CArrow (loc,a,b) -> f n (f n acc a) b
| CAppExpl (loc,(_,_),l) -> List.fold_left (f n) acc l
| CApp (loc,(_,t),l) -> List.fold_left (f n) (f n acc t) (List.map fst l)
| CProdN (_,l,b) | CLambdaN (_,l,b) -> fold_constr_expr_binders g f n acc b l
| CLetIn (_,na,a,b) -> fold_constr_expr_binders g f n acc b [[na],a]
| CCast (loc,a,_,b) -> f n (f n acc a) b
| CNotation (_,_,l) -> List.fold_left (f n) acc l
| CDelimiters (loc,_,a) -> f n acc a
| CHole _ | CEvar _ | CPatVar _ | CSort _ | CPrim _ | CDynamic _ | CRef _ ->
acc
| CCases (loc,rtnpo,al,bl) ->
let ids = ids_of_cases_tomatch al in
let acc = option_fold_left (f (List.fold_right g ids n)) acc rtnpo in
let acc = List.fold_left (f n) acc (List.map fst al) in
List.fold_right (fun (loc,patl,rhs) acc ->
let ids = ids_of_pattern_list patl in
f (Idset.fold g ids n) acc rhs) bl acc
| CLetTuple (loc,nal,(ona,po),b,c) ->
let n' = List.fold_right (name_fold g) nal n in
f (option_fold_right (name_fold g) ona n') (f n acc b) c
| CIf (_,c,(ona,po),b1,b2) ->
let acc = f n (f n (f n acc b1) b2) c in
option_fold_left (f (option_fold_right (name_fold g) ona n)) acc po
| CFix (loc,_,l) ->
let n' = List.fold_right (fun (id,_,_,_,_) -> g id) l n in
List.fold_right (fun (_,(_,o),lb,t,c) acc ->
fold_local_binders g f n'
(fold_local_binders g f n acc t lb) c lb) l acc
| CCoFix (loc,_,_) ->
Pp.warning "Capture check in multiple binders not done"; acc
let free_vars_of_constr_expr c =
let rec aux bdvars l = function
| CRef (Ident (_,id)) -> if List.mem id bdvars then l else Idset.add id l
| c -> fold_constr_expr_with_binders (fun a l -> a::l) aux bdvars l c
in aux [] Idset.empty c
let occur_var_constr_expr id c = Idset.mem id (free_vars_of_constr_expr c)
let mkIdentC id = CRef (Ident (dummy_loc, id))
let mkRefC r = CRef r
let mkAppC (f,l) = CApp (dummy_loc, (None,f), List.map (fun x -> (x,None)) l)
let mkCastC (a,k,b) = CCast (dummy_loc,a,k,b)
let mkLambdaC (idl,a,b) = CLambdaN (dummy_loc,[idl,a],b)
let mkLetInC (id,a,b) = CLetIn (dummy_loc,id,a,b)
let mkProdC (idl,a,b) = CProdN (dummy_loc,[idl,a],b)
let rec mkCProdN loc bll c =
match bll with
| LocalRawAssum ((loc1,_)::_ as idl,t) :: bll ->
CProdN (loc,[idl,t],mkCProdN (join_loc loc1 loc) bll c)
| LocalRawDef ((loc1,_) as id,b) :: bll ->
CLetIn (loc,id,b,mkCProdN (join_loc loc1 loc) bll c)
| [] -> c
| LocalRawAssum ([],_) :: bll -> mkCProdN loc bll c
let rec mkCLambdaN loc bll c =
match bll with
| LocalRawAssum ((loc1,_)::_ as idl,t) :: bll ->
CLambdaN (loc,[idl,t],mkCLambdaN (join_loc loc1 loc) bll c)
| LocalRawDef ((loc1,_) as id,b) :: bll ->
CLetIn (loc,id,b,mkCLambdaN (join_loc loc1 loc) bll c)
| [] -> c
| LocalRawAssum ([],_) :: bll -> mkCLambdaN loc bll c
let rec abstract_constr_expr c = function
| [] -> c
| LocalRawDef (x,b)::bl -> mkLetInC(x,b,abstract_constr_expr c bl)
| LocalRawAssum (idl,t)::bl ->
List.fold_right (fun x b -> mkLambdaC([x],t,b)) idl
(abstract_constr_expr c bl)
let rec prod_constr_expr c = function
| [] -> c
| LocalRawDef (x,b)::bl -> mkLetInC(x,b,prod_constr_expr c bl)
| LocalRawAssum (idl,t)::bl ->
List.fold_right (fun x b -> mkProdC([x],t,b)) idl
(prod_constr_expr c bl)
let coerce_to_id = function
| CRef (Ident (loc,id)) -> (loc,id)
| a -> user_err_loc
(constr_loc a,"coerce_to_id",
str "This expression should be a simple identifier")
(* Used in correctness and interface *)
let map_binder g e nal = List.fold_right (fun (_,na) -> name_fold g na) nal e
let map_binders f g e bl =
(* TODO: avoid variable capture in [t] by some [na] in [List.tl nal] *)
let h (e,bl) (nal,t) = (map_binder g e nal,(nal,f e t)::bl) in
let (e,rbl) = List.fold_left h (e,[]) bl in
(e, List.rev rbl)
let map_local_binders f g e bl =
(* TODO: avoid variable capture in [t] by some [na] in [List.tl nal] *)
let h (e,bl) = function
LocalRawAssum(nal,ty) ->
(map_binder g e nal, LocalRawAssum(nal,f e ty)::bl)
| LocalRawDef((loc,na),ty) ->
(name_fold g na e, LocalRawDef((loc,na),f e ty)::bl) in
let (e,rbl) = List.fold_left h (e,[]) bl in
(e, List.rev rbl)
let map_constr_expr_with_binders g f e = function
| CArrow (loc,a,b) -> CArrow (loc,f e a,f e b)
| CAppExpl (loc,r,l) -> CAppExpl (loc,r,List.map (f e) l)
| CApp (loc,(p,a),l) ->
CApp (loc,(p,f e a),List.map (fun (a,i) -> (f e a,i)) l)
| CProdN (loc,bl,b) ->
let (e,bl) = map_binders f g e bl in CProdN (loc,bl,f e b)
| CLambdaN (loc,bl,b) ->
let (e,bl) = map_binders f g e bl in CLambdaN (loc,bl,f e b)
| CLetIn (loc,na,a,b) -> CLetIn (loc,na,f e a,f (name_fold g (snd na) e) b)
| CCast (loc,a,k,b) -> CCast (loc,f e a,k,f e b)
| CNotation (loc,n,l) -> CNotation (loc,n,List.map (f e) l)
| CDelimiters (loc,s,a) -> CDelimiters (loc,s,f e a)
| CHole _ | CEvar _ | CPatVar _ | CSort _
| CPrim _ | CDynamic _ | CRef _ as x -> x
| CCases (loc,rtnpo,a,bl) ->
(* TODO: apply g on the binding variables in pat... *)
let bl = List.map (fun (loc,pat,rhs) -> (loc,pat,f e rhs)) bl in
let ids = ids_of_cases_tomatch a in
let po = option_map (f (List.fold_right g ids e)) rtnpo in
CCases (loc, po, List.map (fun (tm,x) -> (f e tm,x)) a,bl)
| CLetTuple (loc,nal,(ona,po),b,c) ->
let e' = List.fold_right (name_fold g) nal e in
let e'' = option_fold_right (name_fold g) ona e in
CLetTuple (loc,nal,(ona,option_map (f e'') po),f e b,f e' c)
| CIf (loc,c,(ona,po),b1,b2) ->
let e' = option_fold_right (name_fold g) ona e in
CIf (loc,f e c,(ona,option_map (f e') po),f e b1,f e b2)
| CFix (loc,id,dl) ->
CFix (loc,id,List.map (fun (id,n,bl,t,d) ->
let (e',bl') = map_local_binders f g e bl in
let t' = f e' t in
(* Note: fix names should be inserted before the arguments... *)
let e'' = List.fold_left (fun e (id,_,_,_,_) -> g id e) e' dl in
let d' = f e'' d in
(id,n,bl',t',d')) dl)
| CCoFix (loc,id,dl) ->
CCoFix (loc,id,List.map (fun (id,bl,t,d) ->
let (e',bl') = map_local_binders f g e bl in
let t' = f e' t in
let e'' = List.fold_left (fun e (id,_,_,_) -> g id e) e' dl in
let d' = f e'' d in
(id,bl',t',d')) dl)
(* Used in constrintern *)
let rec replace_vars_constr_expr l = function
| CRef (Ident (loc,id)) as x ->
(try CRef (Ident (loc,List.assoc id l)) with Not_found -> x)
| c -> map_constr_expr_with_binders List.remove_assoc
replace_vars_constr_expr l c
(**********************************************************************)
(* Concrete syntax for modules and modules types *)
type with_declaration_ast =
| CWith_Module of identifier list located * qualid located
| CWith_Definition of identifier list located * constr_expr
type module_type_ast =
| CMTEident of qualid located
| CMTEwith of module_type_ast * with_declaration_ast
type module_ast =
| CMEident of qualid located
| CMEapply of module_ast * module_ast
|