Source file tac2intern.ml
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open Pp
open Util
open CAst
open CErrors
open Names
open Libnames
open Locus
open Tac2env
open Tac2print
open Tac2expr
open Tac2typing_env
(** Hardwired types and constants *)
let coq_type n = KerName.make Tac2env.coq_prefix (Label.make n)
let ltac1_kn n = KerName.make Tac2env.ltac1_prefix (Label.make n)
let t_int = coq_type "int"
let t_string = coq_type "string"
let t_constr = coq_type "constr"
let t_ltac1 = ltac1_kn "t"
let ltac1_lamdba = ltac1_kn "lambda"
let t_preterm = coq_type "preterm"
let t_pattern = coq_type "pattern"
let t_bool = coq_type "bool"
let ltac2_env : Tac2typing_env.t Genintern.Store.field =
Genintern.Store.field "ltac2_env"
let drop_ltac2_env store =
Genintern.Store.remove store ltac2_env
let error_nargs_mismatch ?loc kn nargs nfound =
let cstr = Tac2env.shortest_qualid_of_constructor kn in
user_err ?loc (str "Constructor " ++ pr_qualid cstr ++ str " expects " ++
int nargs ++ str " arguments, but is applied to " ++ int nfound ++
str " arguments")
let error_nparams_mismatch ?loc nargs nfound =
user_err ?loc (str "Type expects " ++ int nargs ++
str " arguments, but is applied to " ++ int nfound ++
str " arguments")
let rec intern_type env ({loc;v=t} : raw_typexpr) : TVar.t glb_typexpr = match t with
| CTypVar (Name id) -> GTypVar (get_alias (CAst.make ?loc id) env)
| CTypVar Anonymous -> GTypVar (fresh_id env)
| CTypRef (rel, args) ->
let (kn, nparams) = match rel with
| RelId qid ->
begin match (if qualid_is_ident qid then find_rec_var (qualid_basename qid) env else None) with
| Some (kn, n) ->
(Other kn, n)
| None ->
let kn =
try Tac2env.locate_type qid
with Not_found ->
user_err ?loc (str "Unbound type constructor " ++ pr_qualid qid)
in
let (nparams, _) = Tac2env.interp_type kn in
(Other kn, nparams)
end
| AbsKn (Other kn) ->
let (nparams, _) = Tac2env.interp_type kn in
(Other kn, nparams)
| AbsKn (Tuple n) ->
(Tuple n, n)
in
let nargs = List.length args in
let () =
if not (Int.equal nparams nargs) then
let qid = match rel with
| RelId lid -> lid
| AbsKn (Other kn) -> shortest_qualid_of_type ?loc kn
| AbsKn (Tuple _) -> assert false
in
user_err ?loc (strbrk "The type constructor " ++ pr_qualid qid ++
strbrk " expects " ++ int nparams ++ strbrk " argument(s), but is here \
applied to " ++ int nargs ++ strbrk "argument(s)")
in
GTypRef (kn, List.map (fun t -> intern_type env t) args)
| CTypArrow (t1, t2) -> GTypArrow (intern_type env t1, intern_type env t2)
let fresh_type_scheme env (t : type_scheme) : TVar.t glb_typexpr =
let (n, t) = t in
let subst = Array.init n (fun _ -> fresh_id env) in
let substf i = GTypVar subst.(i) in
subst_type substf t
let fresh_mix_type_scheme env (t : mix_type_scheme) : TVar.t glb_typexpr =
let (n, t) = t in
let subst = Array.init n (fun _ -> fresh_id env) in
let substf = function
| LVar i -> GTypVar subst.(i)
| GVar n -> GTypVar n
in
subst_type substf t
(** Term typing *)
let is_pure_constructor kn =
match snd (Tac2env.interp_type kn) with
| GTydAlg _ | GTydOpn -> true
| GTydRec fields ->
let is_pure (_, mut, _) = not mut in
List.for_all is_pure fields
| GTydDef _ -> assert false (** Type definitions have no constructors *)
let is_pure_field kn i =
match snd (Tac2env.interp_type kn) with
| GTydRec fields ->
let is_pure (_, mut, _) = not mut in
is_pure (List.nth fields i)
| GTydAlg _ | GTydOpn | GTydDef _ -> assert false
let rec is_value = function
| GTacAtm (AtmInt _) | GTacVar _ | GTacPrm _ -> true
| GTacFun (bnd,_) -> assert (not (CList.is_empty bnd)); true
| GTacAtm (AtmStr _) | GTacApp _ -> false
| GTacRef kn -> not (Tac2env.interp_global kn).gdata_mutable
| GTacCst (Tuple _, _, el) -> List.for_all is_value el
| GTacCst (_, _, []) -> true
| GTacOpn (_, el) -> List.for_all is_value el
| GTacCst (Other kn, _, el) -> is_pure_constructor kn && List.for_all is_value el
| GTacLet (_, bnd, e) ->
is_value e && List.for_all (fun (_, e) -> is_value e) bnd
| GTacPrj (kn,e,i) -> is_pure_field kn i && is_value e
| GTacCse _ | GTacSet _ | GTacExt _
| GTacWth _ | GTacFullMatch _ -> false
let is_rec_rhs = function
| GTacFun _ -> true
| GTacAtm _ | GTacVar _ | GTacRef _ | GTacApp _ | GTacLet _ | GTacPrj _
| GTacSet _ | GTacExt _ | GTacPrm _ | GTacCst _
| GTacCse _ | GTacOpn _ | GTacWth _ | GTacFullMatch _-> false
let warn_not_unit =
CWarnings.create ~name:"not-unit" ~category:CWarnings.CoreCategories.ltac2
(fun (env, t) ->
strbrk "This expression should have type unit but has type " ++
pr_glbtype env t ++ str ".")
let check_elt_unit loc env t =
let maybe_unit = match kind env t with
| GTypVar _ -> true
| GTypArrow _ -> false
| GTypRef (Tuple 0, []) -> true
| GTypRef _ -> false
in
if not maybe_unit then warn_not_unit ?loc (env, t)
let is_empty_type env t = match kind env t with
| GTypVar _ | GTypArrow _ | GTypRef (Tuple _, _) -> false
| GTypRef (Other kn, _) ->
let def = Tac2env.interp_type kn in
match def with
| _, GTydAlg { galg_constructors = [] } -> true
| _ -> false
let check_elt_empty loc env t = match kind env t with
| GTypVar _ ->
user_err ?loc (str "Cannot infer an empty type for this expression")
| GTypArrow _ | GTypRef (Tuple _, _) ->
user_err ?loc (str "Type" ++ spc () ++ pr_glbtype env t ++ spc () ++ str "is not an empty type")
| GTypRef (Other kn, _) ->
let def = Tac2env.interp_type kn in
match def with
| _, GTydAlg { galg_constructors = [] } -> kn
| _ ->
user_err ?loc (str "Type" ++ spc () ++ pr_glbtype env t ++ spc () ++ str "is not an empty type")
let check_unit ?loc t =
let env = empty_env () in
let t = fresh_type_scheme env t in
let maybe_unit = match kind env t with
| GTypVar _ -> true
| GTypArrow _ -> false
| GTypRef (Tuple 0, []) -> true
| GTypRef _ -> false
in
if not maybe_unit then warn_not_unit ?loc (env, t)
let get_constructor env var = match var with
| RelId qid ->
let c = try Some (Tac2env.locate_constructor qid) with Not_found -> None in
begin match c with
| Some knc -> Other knc
| None ->
CErrors.user_err ?loc:qid.CAst.loc (str "Unbound constructor " ++ pr_qualid qid)
end
| AbsKn knc -> knc
let get_projection var = match var with
| RelId qid ->
let kn = try Tac2env.locate_projection qid with Not_found ->
user_err ?loc:qid.CAst.loc (pr_qualid qid ++ str " is not a projection")
in
Tac2env.interp_projection kn
| AbsKn kn ->
Tac2env.interp_projection kn
let intern_atm env = function
| AtmInt n -> (GTacAtm (AtmInt n), GTypRef (Other t_int, []))
| AtmStr s -> (GTacAtm (AtmStr s), GTypRef (Other t_string, []))
(** Internalization *)
(** Used to generate a fresh tactic variable for pattern-expansion *)
let fresh_var avoid =
let bad id =
Id.Set.mem id avoid ||
(try ignore (locate_ltac (qualid_of_ident id)); true with Not_found -> false)
in
Namegen.next_ident_away_from (Id.of_string "p") bad
let add_name accu = function
| Name id -> Id.Set.add id accu
| Anonymous -> accu
let loc_of_relid = function
| RelId {loc} -> loc
| AbsKn _ -> None
let is_unit_pattern = function
| CPatRef (AbsKn (Tuple 0), []) -> true
| _ -> false
let ({loc;v=p} as pat) = match p with
| CPatCnv (pat, ty) -> pat, Some ty
| CPatAtm _ | CPatVar _ | CPatRef _ | CPatOr _ | CPatAs _ | CPatRecord _ ->
if is_unit_pattern p then
let t_unit = CAst.make ?loc @@ CTypRef (AbsKn (Tuple 0), []) in
pat, Some t_unit
else pat, None
(** Expand pattern: [p => t] becomes [x => match x with p => t end] *)
let expand_pattern avoid bnd =
let fold (avoid, bnd) (pat, t) =
let na, expand = match pat.v with
| CPatVar na ->
na, None
| _ ->
if is_unit_pattern pat.v then
Anonymous, None
else
let id = fresh_var avoid in
let qid = RelId (qualid_of_ident ?loc:pat.loc id) in
Name id, Some qid
in
let avoid = ids_of_pattern avoid pat in
let avoid = add_name avoid na in
(avoid, (na, pat, expand) :: bnd)
in
let (_, bnd) = List.fold_left fold (avoid, []) bnd in
let fold e (na, pat, expand) = match expand with
| None -> e
| Some qid ->
let loc = loc_of_relid qid in
CAst.make ?loc @@ CTacCse (CAst.make ?loc @@ CTacRef qid, [pat, e])
in
let expand e = List.fold_left fold e bnd in
let nas = List.rev_map (fun (na, _, _) -> na) bnd in
(nas, expand)
let is_alias env qid = match get_variable env qid with
| ArgArg (TacAlias _) -> true
| ArgVar _ | (ArgArg (TacConstant _)) -> false
let is_user_name qid = match qid with
| AbsKn _ -> false
| RelId _ -> true
let deprecated_ltac2_alias =
Deprecation.create_warning
~object_name:"Ltac2 alias"
~warning_name_if_no_since:"deprecated-ltac2-alias"
(fun kn -> pr_qualid (Tac2env.shortest_qualid_of_ltac Id.Set.empty (TacAlias kn)))
let deprecated_ltac2_def =
Deprecation.create_warning
~object_name:"Ltac2 definition"
~warning_name_if_no_since:"deprecated-ltac2-definition"
(fun kn -> pr_qualid (Tac2env.shortest_qualid_of_ltac Id.Set.empty (TacConstant kn)))
let check_deprecated_ltac2 ?loc qid def =
if is_user_name qid then match def with
| TacAlias kn ->
begin match (Tac2env.interp_alias kn).alias_depr with
| None -> ()
| Some depr -> deprecated_ltac2_alias ?loc (kn, depr)
end
| TacConstant kn ->
begin match (Tac2env.interp_global kn).gdata_deprecation with
| None -> ()
| Some depr -> deprecated_ltac2_def ?loc (kn, depr)
end
type ('a,'b) field =
| PresentField of 'a
| MissingField of 'b
let intern_record env loc fs =
let map (proj, e) =
let loc = match proj with
| RelId {CAst.loc} -> loc
| AbsKn _ -> None
in
let proj = get_projection proj in
(loc, proj, e)
in
let fs = List.map map fs in
let kn = match fs with
| [] -> user_err ?loc (str "Cannot infer the corresponding record type")
| (_, proj, _) :: _ -> proj.pdata_type
in
let params, typdef = match Tac2env.interp_type kn with
| n, GTydRec def -> n, def
| _ -> assert false
in
let subst = Array.init params (fun _ -> fresh_id env) in
let args = Array.make (List.length typdef) None in
let iter (loc, pinfo, e) =
if KerName.equal kn pinfo.pdata_type then
let index = pinfo.pdata_indx in
match args.(index) with
| None ->
let exp = subst_type (fun i -> GTypVar subst.(i)) pinfo.pdata_ptyp in
args.(index) <- Some (e, exp)
| Some _ ->
let (name, _, _) = List.nth typdef pinfo.pdata_indx in
user_err ?loc (str "Field " ++ Id.print name ++ str " is defined \
several times")
else
user_err ?loc (str "Field " ++ str " does not \
pertain to record definition " ++ pr_typref pinfo.pdata_type)
in
let () = List.iter iter fs in
let args = Array.mapi (fun i arg -> match arg with
| None ->
let field, _, typ = List.nth typdef i in
let typ' = subst_type (fun i -> GTypVar subst.(i)) typ in
MissingField (i, field, typ, typ')
| Some arg -> PresentField arg)
args
in
let tparam = List.init params (fun i -> GTypVar subst.(i)) in
kn, tparam, args
let ctor_data_for_patterns kn data = {
ctyp = Some data.cdata_type;
cnargs = List.length data.cdata_args;
cindx = match data.cdata_indx with None -> Open kn | Some i -> Closed i;
}
let ctor_data_of_tuple n = {
ctyp = None;
cnargs = n;
cindx = Closed 0;
}
type wip_pat_r =
| PatVar of Name.t
| PatAtm of atom
| PatRef of ctor_data_for_patterns * wip_pat list
| PatOr of wip_pat list
| PatAs of wip_pat * lident
and wip_pat = wip_pat_r CAst.t
let catchall = CAst.make (PatVar Anonymous)
let pat_or ?loc = function
| [] -> assert false
| [x] -> x
| pats -> CAst.make ?loc (PatOr pats)
let rec intern_pat_rec env cpat t =
let loc = cpat.loc in
match cpat.v with
| CPatVar x -> begin match x with
| Anonymous -> Id.Map.empty, CAst.make ?loc (PatVar x)
| Name id ->
let patvars = Id.Map.singleton id (loc,t) in
patvars, CAst.make ?loc (PatVar x)
end
| CPatAtm atm ->
let _, t' = intern_atm env atm in
let () = unify ?loc env t t' in
Id.Map.empty, CAst.make ?loc (PatAtm atm)
| CPatAs (p, x) ->
let patvars, p = intern_pat_rec env p t in
let patvars = Id.Map.update x.v (function
| Some _ ->
CErrors.user_err ?loc
Pp.(str "Variable " ++ Id.print x.v ++
str " is bound several times in this matching.")
| None -> Some (x.loc,t))
patvars
in
patvars, CAst.make ?loc (PatAs (p, x))
| CPatRef (ctor,args) ->
let ctor = get_constructor env ctor in
let ctor, argts =
let nargs = List.length args in
match ctor with
| Tuple n ->
assert (Int.equal nargs n);
let ts = List.init n (fun _ -> GTypVar (fresh_id env)) in
let () = unify ?loc env t (GTypRef (ctor, ts)) in
ctor_data_of_tuple n, ts
| Other kn ->
let data = interp_constructor kn in
let nexpectargs = List.length data.cdata_args in
if not (Int.equal nargs nexpectargs) then error_nargs_mismatch ?loc kn nexpectargs nargs;
let subst = Array.init data.cdata_prms (fun _ -> fresh_id env) in
let substf i = GTypVar subst.(i) in
let types = List.map (fun t -> subst_type substf t) data.cdata_args in
let targs = List.init data.cdata_prms substf in
let ans = GTypRef (Other data.cdata_type, targs) in
let () = unify ?loc env t ans in
ctor_data_for_patterns kn data, types
in
let patvars, args = CList.fold_left2_map (fun patvars arg argt ->
let argvars, arg = intern_pat_rec env arg argt in
let patvars = Id.Map.union (fun id _ (loc,_) ->
CErrors.user_err ?loc
Pp.(str "Variable " ++ Id.print id ++
str " is bound several times in this matching."))
patvars argvars
in
patvars, arg)
Id.Map.empty
args
argts
in
patvars, CAst.make ?loc (PatRef (ctor,args))
| CPatRecord pats ->
let kn, tparam, args = intern_record env loc pats in
let () = unify ?loc env t (GTypRef (Other kn, tparam)) in
let args = Array.to_list args in
let patvars, args = CList.fold_left_map (fun patvars -> function
| MissingField _ -> patvars, catchall
| PresentField (arg, argty) ->
let (argvars,arg) = intern_pat_rec env arg argty in
let patvars = Id.Map.union (fun id _ (loc,_) ->
CErrors.user_err ?loc
Pp.(str "Variable " ++ Id.print id ++
str " is bound several times in this matching."))
patvars argvars
in
patvars, arg)
Id.Map.empty
args
in
let ctor = { ctyp = Some kn; cnargs = List.length args; cindx = Closed 0 } in
patvars, CAst.make ?loc (PatRef (ctor, args))
| CPatCnv (pat,typ) ->
let typ = intern_type env typ in
let () = unify ?loc env t typ in
intern_pat_rec env pat typ
| CPatOr [] -> assert false
| CPatOr (first::rest) ->
let patvars, first = intern_pat_rec env first t in
let rest = List.map (fun pat ->
let patvars', pat = intern_pat_rec env pat t in
if not (Id.Map.equal (fun (_,t) (loc,t') ->
unify ?loc env t t';
true)
patvars patvars')
then CErrors.user_err ?loc Pp.(str "These patterns do not bind the same variables.");
pat)
rest
in
patvars, CAst.make ?loc (PatOr (first::rest))
let intern_pat env cpat t =
let patvars, pat = intern_pat_rec env cpat t in
Id.Map.map (fun (_,v) -> monomorphic v) patvars, pat
let rec glb_of_wip_pat_r = function
| PatVar x -> GPatVar x
| PatAtm atm -> GPatAtm atm
| PatRef (ctor,pats) -> GPatRef (ctor, List.map glb_of_wip_pat pats)
| PatOr pats -> GPatOr (List.map glb_of_wip_pat pats)
| PatAs (p,x) -> GPatAs (glb_of_wip_pat p, x.v)
and glb_of_wip_pat pat = glb_of_wip_pat_r pat.CAst.v
(** Pattern analysis for non-exhaustiveness and (TODO) useless patterns based on
"Warnings for pattern matching", Luc Maranget, Journal of Functional Programming, 17(3), 2007 *)
let default_matrix =
let rec default_row = function
| [] -> assert false
| {v=PatRef _ | PatAtm _} :: _ -> []
| {v=PatVar _} :: rest -> [rest]
| {v=PatOr pats} :: rest -> List.map_append default_row (List.map (fun x -> x::rest) pats)
| {v=PatAs (p,_)} :: rest -> default_row (p::rest)
in
List.map_append default_row
type generalized_ctor =
| AtomCtor of atom
| OtherCtor of ctor_data_for_patterns
let rec root_ctors = function
| {v=PatVar _} -> []
| {v=PatRef (ctor,_)} -> [OtherCtor ctor]
| {v=PatAtm a} -> [AtomCtor a]
| {v=PatOr pats} -> List.map_append root_ctors pats
| {v=PatAs (p,_)} -> root_ctors p
type missing_ctors =
| Unknown
| Extension of { example : atom option }
| Known of ctor_data_for_patterns list
type maybe_missing_ctors =
| Missing of missing_ctors
| NoMissing of ctor_data_for_patterns list
let make_ctor ctyp tdata is_const n =
let cnargs = if is_const then 0 else
let rec find n = function
| [] -> assert false
| (_, []) :: rem ->
find n rem
| (_, argtys) :: rem ->
if Int.equal n 0 then List.length argtys
else find (pred n) rem
in
find n tdata.galg_constructors
in
{
ctyp;
cindx = Closed n;
cnargs;
}
let make_int_example ints =
let rec aux i = if Int.Set.mem i ints then aux (i+1) else i
in aux 0
let make_string_example strings =
let rec aux s = if String.Set.mem s strings then aux (s^"*") else s
in aux ""
let make_atom_example = function
| AtomCtor (AtmInt i) :: rest ->
let ints = List.fold_left (fun ints c -> match c with
| AtomCtor (AtmInt i) -> Int.Set.add i ints
| _ -> assert false)
(Int.Set.singleton i)
rest
in
AtmInt (make_int_example ints)
| AtomCtor (AtmStr s) :: rest ->
let strings = List.fold_left (fun strings c -> match c with
| AtomCtor (AtmStr s) -> String.Set.add s strings
| _ -> assert false)
(String.Set.singleton s)
rest
in
AtmStr (make_string_example strings)
| OtherCtor _ :: _ | [] -> assert false
let missing_ctors_from env t = function
| [] ->
if is_empty_type env t then NoMissing []
else Missing Unknown
| AtomCtor _ :: _ as l -> Missing (Extension {example=Some (make_atom_example l)})
| OtherCtor {ctyp=None; cnargs} :: _ ->
NoMissing [ctor_data_of_tuple cnargs]
| OtherCtor {cindx=Open _} :: _ -> Missing (Extension {example=None})
| OtherCtor ({ctyp=Some ctyp} as data) :: _ as ctors ->
let _, tdata = interp_type ctyp in
match tdata with
| GTydOpn | GTydDef _ -> assert false
| GTydRec _ -> NoMissing [data]
| GTydAlg tdata ->
let const = Array.make tdata.galg_nconst false in
let nonconst = Array.make tdata.galg_nnonconst false in
let () = List.iter (function
| OtherCtor {cindx=Closed i; cnargs} ->
let which = if Int.equal 0 cnargs then const else nonconst in
which.(i) <- true
| AtomCtor _ | OtherCtor {cindx=Open _} -> assert false)
ctors
in
let fold is_const i (missing, present) ispresent =
let ctor = (make_ctor data.ctyp tdata is_const i) in
if ispresent then missing, ctor :: present
else ctor :: missing, present
in
let acc = CArray.fold_left_i (fold false) ([],[]) nonconst in
let missing, present = CArray.fold_left_i (fold true) acc const in
if List.is_empty missing then NoMissing present
else Missing (Known missing)
let specialized_types env ts ctor = match ts with
| [] -> assert false
| t :: rest ->
let argts = match ctor with
| AtomCtor _ -> []
| OtherCtor {ctyp=None; cnargs=n} ->
let argts = List.init n (fun _ -> GTypVar (fresh_id env)) in
let () = unify env t (GTypRef (Tuple n, argts)) in
argts
| OtherCtor {cindx=Open kn} ->
let data = interp_constructor kn in
let subst = Array.init data.cdata_prms (fun _ -> fresh_id env) in
let substf i = GTypVar subst.(i) in
let types = List.map (fun t -> subst_type substf t) data.cdata_args in
let targs = List.init data.cdata_prms substf in
let ans = GTypRef (Other data.cdata_type, targs) in
let () = unify env t ans in
types
| OtherCtor {ctyp=Some ctyp; cnargs; cindx=Closed i} ->
let ntargs, tdata = interp_type ctyp in
match tdata with
| GTydOpn | GTydDef _ -> assert false
| GTydRec tdata ->
let subst = Array.init ntargs (fun _ -> fresh_id env) in
let substf i = GTypVar subst.(i) in
let types = List.map (fun (_,_,t) -> subst_type substf t) tdata in
let targs = List.init ntargs substf in
let ans = GTypRef (Other ctyp, targs) in
let () = unify env t ans in
types
| GTydAlg tdata ->
let ctors = List.filter (fun (_,argts) ->
if cnargs = 0
then List.is_empty argts
else not (List.is_empty argts))
tdata.galg_constructors
in
let _, argts = List.nth ctors i in
let subst = Array.init ntargs (fun _ -> fresh_id env) in
let substf i = GTypVar subst.(i) in
let types = List.map (fun t -> subst_type substf t) argts in
let targs = List.init ntargs substf in
let ans = GTypRef (Other ctyp, targs) in
let () = unify env t ans in
types
in
List.append argts rest
let specialized_multi_matrix (patsP, patsQ, patsR) ctor =
let same_atom atm atm' = match atm, atm' with
| AtmInt i, AtmInt j -> Int.equal i j
| AtmStr i, AtmStr j -> String.equal i j
| AtmInt _, AtmStr _ | AtmStr _, AtmInt _ -> assert false
in
let same_ctor_indx i j = match i, j with
| Closed i, Closed j -> Int.equal i j
| Open kn, Open kn' -> KerName.equal kn kn'
| Closed _, Open _ | Open _, Closed _ -> false
in
let same_ctor ctor ctor' = match ctor, ctor' with
| AtomCtor atm, AtomCtor atm' -> same_atom atm atm'
| OtherCtor ctor, OtherCtor ctor' ->
Int.equal ctor.cnargs ctor'.cnargs
&& same_ctor_indx ctor.cindx ctor'.cindx
| AtomCtor _, OtherCtor _ | OtherCtor _, AtomCtor _ -> assert false
in
let rec special_row rowP rowQ rowR = match rowP with
| [] -> assert false
| {v=PatRef (ctor',args)} :: rest ->
if same_ctor ctor (OtherCtor ctor') then [List.append args rest, rowQ, rowR]
else []
| {v=PatAtm atm} :: rest ->
if same_ctor ctor (AtomCtor atm) then [rest, rowQ, rowR]
else []
| {v=PatVar _} :: rest -> begin match ctor with
| OtherCtor ctor -> [List.append (List.make ctor.cnargs catchall) rest, rowQ, rowR]
| AtomCtor _ -> [rest, rowQ, rowR]
end
| {v=PatOr pats} :: rest ->
List.map_append (fun x -> special_row (x::rest) rowQ rowR) pats
| {v=PatAs (p,_)} :: rest -> special_row (p::rest) rowQ rowR
in
let res = List.flatten (List.map3 special_row patsP patsQ patsR) in
List.split3 res
let specialized_matrix pats ctor =
let dummy = List.make (List.length pats) () in
let pats, _, _ = specialized_multi_matrix (pats, dummy, dummy) ctor in
pats
let rec lift_interned_pat pat = CAst.map lift_interned_pat_r pat
and lift_interned_pat_r = let open PartialPat in function
| PatVar x -> Var x
| PatAtm a -> Atom a
| PatRef (ctor, pats) -> Ref (ctor, List.map lift_interned_pat pats)
| PatOr pats -> Or (List.map lift_interned_pat pats)
| PatAs (p,x) -> As (lift_interned_pat p, x.v)
let rec missing_matches env ts pats n =
match n with
| 0 -> begin match pats with [] -> Some [] | _::_ -> None end
| _ ->
let root_ctors = List.map_append root_ctors (List.map List.hd pats) in
match missing_ctors_from env (List.hd ts) root_ctors with
| NoMissing ctors -> specialized_missing_matches env ts pats n ctors
| Missing missing_ctors ->
match missing_matches env (List.tl ts) (default_matrix pats) (n-1) with
| None -> None
| Some missing -> match missing_ctors with
| Unknown -> Some (lift_interned_pat catchall :: missing)
| Extension {example} -> Some (CAst.make (PartialPat.Extension {example}) :: missing)
| Known missing_ctors ->
let misspats = List.map (fun ctor ->
CAst.make (PatRef (ctor, List.make ctor.cnargs catchall)))
missing_ctors
in
Some (lift_interned_pat (pat_or misspats) :: missing)
and specialized_missing_matches env ts pats n = function
| [] -> None
| ctor :: rest ->
match missing_matches env
(specialized_types env ts (OtherCtor ctor))
(specialized_matrix pats (OtherCtor ctor))
(ctor.cnargs + n - 1)
with
| None -> specialized_missing_matches env ts pats n rest
| Some missing ->
let args, missing = List.chop ctor.cnargs missing in
Some (CAst.make (PartialPat.Ref (ctor, args)) :: missing)
let check_no_missing_pattern env t pats =
match missing_matches env [t] (List.map (fun x -> [x]) pats) 1 with
| None -> ()
| Some missing ->
let missing = match missing with [x] -> x | _ -> assert false in
CErrors.user_err Pp.(
str "Non exhaustive match. Values in this pattern are not matched:" ++ fnl() ++
pr_partial_pat missing)
type utility =
| Useless
| PartiallyUseless of Loc.t option list
let combine_utilities us =
let fold (all_useless, useless_locs) = function
| _, None -> (false, useless_locs)
| loc, Some Useless -> (all_useless, [loc]::useless_locs)
| _, Some (PartiallyUseless locs) -> (false, locs::useless_locs)
in
let all_useless, useless_locs = List.fold_left fold (true,[]) us in
if List.is_empty useless_locs then None
else if all_useless then Some Useless
else Some (PartiallyUseless (List.flatten (List.rev useless_locs)))
let rec simple_utility env ts pats q =
match q with
| [] -> begin match pats with [] -> true | _::_ -> false end
| pat :: q -> match pat.CAst.v with
| PatAs (p, _) -> simple_utility env ts pats (p :: q)
| PatRef (ctor, args) ->
let ctor = OtherCtor ctor in
simple_utility env (specialized_types env ts ctor)
(specialized_matrix pats ctor)
(args @ q)
| PatAtm atm ->
let ctor = AtomCtor atm in
simple_utility env (specialized_types env ts ctor)
(specialized_matrix pats ctor)
q
| PatOr ps -> List.exists (fun p -> simple_utility env ts pats (p :: q)) ps
| PatVar _ ->
let root_ctors = List.map_append root_ctors (List.map List.hd pats) in
match missing_ctors_from env (List.hd ts) root_ctors with
| NoMissing ctors ->
List.exists (fun ctor ->
let gctor = OtherCtor ctor in
simple_utility env (specialized_types env ts gctor)
(specialized_matrix pats gctor)
(List.make ctor.cnargs catchall @ q))
ctors
| Missing _ -> simple_utility env (List.tl ts) (default_matrix pats) q
let rec utility env ((tP, tQ, tR) as t) ((preP, preQ, preR) as prefix) (p, q, r) =
match p with
| p1 :: p -> begin match p1.CAst.v with
| PatAs (p1, _) -> utility env t prefix (p1 :: p, q, r)
| PatRef (ctor, pats) ->
let ctor = OtherCtor ctor in
let t = specialized_types env tP ctor, tQ, tR in
let prefix = specialized_multi_matrix prefix ctor in
utility env t prefix (pats @ p, q, r)
| PatAtm atm ->
let ctor = AtomCtor atm in
let t = specialized_types env tP ctor, tQ, tR in
let prefix = specialized_multi_matrix prefix ctor in
utility env t prefix (p, q, r)
| PatVar _ ->
let t = (List.tl tP, List.hd tP :: tQ, tR) in
let prefix =
(List.map List.tl preP,
List.map2 (fun preP preQ -> List.hd preP :: preQ) preP preQ,
preR)
in
utility env t prefix (p, p1 :: q, r)
| PatOr _ ->
let t = (List.tl tP, tQ, List.hd tP :: tR) in
let prefix =
(List.map List.tl preP,
preQ,
List.map2 (fun preP preR -> List.hd preP :: preR) preP preR)
in
utility env t prefix (p, q, p1 :: r)
end
| [] -> match r with
| [] -> if simple_utility env tQ preQ q then None else Some Useless
| _ :: _ ->
let utilities = List.map_i (fun j rj ->
let t = ([List.nth tR j], (List.filteri (fun j' _ -> not (Int.equal j j')) tR) @ tQ, []) in
let r_no_j = List.filteri (fun j' _ -> not (Int.equal j j')) r in
let preRj = List.map (fun x -> [List.nth x j]) preR in
let preR_no_j = List.map (fun x -> List.filteri (fun j' _ -> not (Int.equal j j')) x) preR in
let r_no_j_plus_q = r_no_j @ q in
let pats = match rj.v with
| PatOr pats -> pats
| _ -> assert false
in
let fold ((preP, preQ, preR) as prefix) pat =
let u = utility env t prefix ([pat], r_no_j_plus_q, []) in
let prefix = (preP @ [[pat]], preQ @ [r_no_j_plus_q], [] :: preR) in
prefix, (pat.loc, u)
in
let prefix = (preRj, List.map2 (@) preR_no_j preQ, List.make (List.length preRj) []) in
let _, us = List.fold_left_map fold prefix pats in
rj.loc, combine_utilities us)
0 r
in
combine_utilities utilities
let warn_redundant_pattern =
CWarnings.create ~name:"redundant-pattern" ~category:CWarnings.CoreCategories.ltac2
(fun partial -> str ("This " ^ (if partial then "pattern" else "clause") ^ " is redundant."))
let check_redundant_clauses env t pats =
let fold (prefix, dummies) pat =
let () = match utility env ([t],[],[]) (prefix,dummies,dummies) ([pat],[],[]) with
| None -> ()
| Some Useless -> warn_redundant_pattern ?loc:pat.loc false
| Some (PartiallyUseless locs) -> List.iter (fun loc -> warn_redundant_pattern ?loc true) locs
in
prefix @ [[pat]], [] :: dummies
in
let _, _ = List.fold_left fold ([],[]) pats in
()
(** Pattern view *)
type glb_patexpr =
| GEPatVar of Name.t
| GEPatRef of ctor_data_for_patterns * glb_patexpr list
exception HardCase
let rec to_patexpr env {loc;v=pat} = match pat with
| PatVar na -> GEPatVar na
| PatRef (ctor, pl) ->
GEPatRef (ctor, List.map (fun p -> to_patexpr env p) pl)
| PatAtm _ | PatOr _ | PatAs _ ->
raise HardCase
type pattern_kind =
| PKind_empty
| PKind_variant of type_constant or_tuple
| PKind_open
| PKind_any
let get_pattern_kind env pl = match pl with
| [] -> PKind_empty
| p :: pl ->
let rec get_kind ((p:wip_pat), _) pl = match to_patexpr env p with
| GEPatVar _ ->
begin match pl with
| [] -> PKind_any
| p :: pl -> get_kind p pl
end
| GEPatRef ({ctyp=Some ctyp} as kn, pl) -> begin match kn.cindx with
| Open kn -> PKind_open
| Closed _ -> PKind_variant (Other ctyp)
end
| GEPatRef ({ctyp=None; cnargs=k}, tp) -> PKind_variant (Tuple k)
in
get_kind p pl
(** For now, patterns recognized by the pattern-matching compiling are limited
to depth-one where leaves are either variables or catch-all *)
let to_simple_case env ?loc (e,t) pl =
let todo () = raise HardCase in
match get_pattern_kind env pl with
| PKind_any ->
let (pat, b) = List.hd pl in
let na = match to_patexpr env pat with
| GEPatVar na -> na
| _ -> assert false
in
GTacLet (false, [na, e], b)
| PKind_empty ->
let kn = check_elt_empty loc env t in
GTacCse (e, Other kn, [||], [||])
| PKind_variant kn ->
let (nconst, nnonconst, arities) = match kn with
| Tuple 0 -> 1, 0, [0]
| Tuple n -> 0, 1, [n]
| Other kn ->
let (_, def) = Tac2env.interp_type kn in
let galg = match def with
| GTydAlg c -> c
| GTydRec _ -> raise HardCase
| _ -> assert false
in
let arities = List.map (fun (_, args) -> List.length args) galg.galg_constructors in
galg.galg_nconst, galg.galg_nnonconst, arities
in
let const = Array.make nconst None in
let nonconst = Array.make nnonconst None in
let rec intern_branch = function
| [] -> ()
| (pat, br) :: rem ->
let () = match pat.v with
| PatAtm _ | PatOr _ | PatAs _ ->
raise HardCase
| PatVar (Name _) -> todo ()
| PatVar Anonymous ->
let fill (ncst, narg) arity =
if Int.equal arity 0 then
let () =
if Option.is_empty const.(ncst) then const.(ncst) <- Some br
in
(succ ncst, narg)
else
let () =
if Option.is_empty nonconst.(narg) then
let ids = Array.make arity Anonymous in
nonconst.(narg) <- Some (ids, br)
in
(ncst, succ narg)
in
let _, _ = List.fold_left fill (0, 0) arities in
()
| PatRef (ctor, args) ->
let index = match ctor.cindx with
| Closed i -> i
| Open _ -> assert false
in
let get_id pat = match pat.v with
| PatVar na -> na
| _ -> todo ()
in
let ids = List.map get_id args in
let () =
if List.is_empty args then
if Option.is_empty const.(index) then const.(index) <- Some br
else ()
else
let ids = Array.of_list ids in
if Option.is_empty nonconst.(index) then nonconst.(index) <- Some (ids, br)
else ()
in
()
in
intern_branch rem
in
let () = intern_branch pl in
let map n is_const = function
| None -> assert false
| Some x -> x
in
let const = Array.mapi (fun i o -> map i true o) const in
let nonconst = Array.mapi (fun i o -> map i false o) nonconst in
GTacCse (e, kn, const, nonconst)
| PKind_open ->
let rec intern_branch map = function
| [] ->
user_err ?loc (str "Missing default case")
| (pat, br) :: rem ->
match to_patexpr env pat with
| GEPatVar na ->
let def = (na, br) in
(map, def)
| GEPatRef (knc, args) ->
let get = function
| GEPatVar na -> na
| GEPatRef _ -> todo ()
in
let knc = match knc.cindx with
| Open knc -> knc
| Closed _ -> assert false
in
let ids = List.map get args in
let map =
if KNmap.mem knc map then
map
else
KNmap.add knc (Anonymous, Array.of_list ids, br) map
in
intern_branch map rem
in
let (map, def) = intern_branch KNmap.empty pl in
GTacWth { opn_match = e; opn_branch = map; opn_default = def }
let check ?loc env tycon (e,t as et) =
match tycon with
| None -> et
| Some tycon ->
let () = unify ?loc env t tycon in
e,tycon
let tycon_fun_body ?loc env tycon dom =
match kind env tycon with
| GTypVar _ ->
let codom = GTypVar (fresh_id env) in
let () = unify ?loc env (GTypArrow (dom,codom)) tycon in
codom
| GTypArrow (dom',codom) ->
let () = unify ?loc env (GTypArrow (dom,codom)) tycon in
codom
| GTypRef _ ->
CErrors.user_err ?loc
Pp.(str "This expression should not be a function, the expected type is" ++ spc() ++
pr_glbtype env tycon ++ str ".")
let tycon_app ?loc env ~ft t =
match kind env t with
| GTypVar _ ->
let dom = GTypVar (fresh_id env) in
let codom = GTypVar (fresh_id env) in
let () = unify ?loc env (GTypArrow (dom,codom)) t in
dom, codom
| GTypArrow (dom,codom) -> dom, codom
| GTypRef _ ->
let is_fun = match kind env ft with
| GTypArrow _ -> true
| _ -> false
in
if is_fun then
CErrors.user_err ?loc
Pp.(str "This function has type" ++ spc() ++ pr_glbtype env ft ++
spc() ++ str "and is applied to too many arguments.")
else
CErrors.user_err ?loc
Pp.(str "This expression has type" ++ spc() ++ pr_glbtype env ft ++ str"." ++
spc() ++ str "It is not a function and cannot be applied.")
let warn_useless_record_with = CWarnings.create ~name:"ltac2-useless-record-with" ~default:AsError
~category:CWarnings.CoreCategories.ltac2
Pp.(fun () ->
str "All the fields are explicitly listed in this record:" ++
spc() ++ str "the 'with' clause is useless.")
let expand_notation ?loc el kn =
match Tac2env.interp_notation kn with
| UntypedNota body ->
let el = List.map (fun (pat, e) -> CAst.map (fun na -> CPatVar na) pat, e) el in
let v = if CList.is_empty el then body else CAst.make ?loc @@ CTacLet(false, el, body) in
v
| TypedNota {nota_prms=prms; nota_argtys=argtys; nota_ty=ty; nota_body=body} ->
let argtys, el = List.fold_left_map (fun argtys (na,arg) ->
let argty, argtys = match na.CAst.v with
| Anonymous -> None, argtys
| Name id -> Some (Id.Map.get id argtys), Id.Map.remove id argtys
in
argtys ,(na, arg, argty))
argtys
el
in
assert (Id.Map.is_empty argtys);
CAst.make ?loc @@ CTacGlb (prms, el, body, ty)
let warn_unused_variables = CWarnings.create ~name:"ltac2-unused-variable"
~category:CWarnings.CoreCategories.ltac2
Pp.(fun ids -> str "Unused " ++ str (String.lplural ids "variable") ++ str ":" ++ spc() ++ prlist_with_sep spc Id.print ids ++ str ".")
let check_unused_variables ?loc env to_name bnd =
let unused = List.filter_map (fun bnd -> match to_name bnd with
| Anonymous -> None
| Name id ->
if CString.is_prefix "_" (Id.to_string id)
|| is_used_var id env
then None
else Some id)
bnd
in
if CList.is_empty unused then ()
else warn_unused_variables ?loc unused
let rec intern_rec env tycon {loc;v=e} =
let check et = check ?loc env tycon et in
match e with
| CTacAtm atm -> check (intern_atm env atm)
| CTacRef qid ->
begin match get_variable env qid with
| ArgVar {CAst.v=id} ->
let sch = find_var id env in
check (GTacVar id, fresh_mix_type_scheme env sch)
| ArgArg (TacConstant kn) ->
let { Tac2env.gdata_type = sch; gdata_deprecation = depr } =
try Tac2env.interp_global kn
with Not_found ->
CErrors.anomaly (str "Missing hardwired primitive " ++ KerName.print kn)
in
let () = check_deprecated_ltac2 ?loc qid (TacConstant kn) in
check (GTacRef kn, fresh_type_scheme env sch)
| ArgArg (TacAlias kn) ->
let e =
try Tac2env.interp_alias kn
with Not_found ->
CErrors.anomaly (str "Missing hardwired alias " ++ KerName.print kn)
in
let () = check_deprecated_ltac2 ?loc qid (TacAlias kn) in
intern_rec env tycon e.alias_body
end
| CTacCst qid ->
let kn = get_constructor env qid in
intern_constructor env loc tycon kn []
| CTacFun (bnd, e) ->
let bnd = List.map extract_pattern_type bnd in
let map (_, t) = match t with
| None -> GTypVar (fresh_id env)
| Some t -> intern_type env t
in
let tl = List.map map bnd in
let (nas, exp) = expand_pattern (bound_vars env) bnd in
let env, tycon = List.fold_left2 (fun (env,tycon) na t ->
let tycon = Option.map (fun tycon -> tycon_fun_body ?loc env tycon t) tycon in
let env = push_name na (monomorphic t) env in
env, tycon) (env,tycon) nas tl
in
let (e, t) = intern_rec env tycon (exp e) in
let () =
check_unused_variables ?loc env (fun x -> x) nas
in
let t = match tycon with
| None -> List.fold_right (fun t accu -> GTypArrow (t, accu)) tl t
| Some tycon -> tycon
in
(GTacFun (nas, e), t)
| CTacApp ({loc;v=CTacCst qid}, args) ->
let kn = get_constructor env qid in
intern_constructor env loc tycon kn args
| CTacApp ({v=CTacRef qid; loc=aloc}, args) when is_alias env qid ->
let kn = match get_variable env qid with
| ArgArg (TacAlias kn) -> kn
| ArgVar _ | (ArgArg (TacConstant _)) -> assert false
in
let e = Tac2env.interp_alias kn in
let () = check_deprecated_ltac2 ?loc:aloc qid (TacAlias kn) in
let map arg =
let loc = arg.loc in
let t_unit = CAst.make ?loc @@ CTypRef (AbsKn (Tuple 0), []) in
let var = CAst.make ?loc @@ CPatCnv (CAst.make ?loc @@ CPatVar Anonymous, t_unit) in
CAst.make ?loc @@ CTacFun ([var], arg)
in
let args = List.map map args in
intern_rec env tycon (CAst.make ?loc @@ CTacApp (e.alias_body, args))
| CTacApp (f, args) ->
let loc = f.loc in
let (f, ft) = intern_rec env None f in
let fold t arg =
let dom, codom = tycon_app ?loc env ~ft t in
let arg = intern_rec_with_constraint env arg dom in
(codom, arg)
in
let (t, args) = CList.fold_left_map fold ft args in
check (GTacApp (f, args), t)
| CTacLet (is_rec, el, e) ->
let map (pat, e) =
let (pat, ty) = extract_pattern_type pat in
(pat, ty, e)
in
let el = List.map map el in
let fold accu (pat, _, e) =
let ids = ids_of_pattern Id.Set.empty pat in
let common = Id.Set.inter ids accu in
if Id.Set.is_empty common then Id.Set.union ids accu
else
let id = Id.Set.choose common in
user_err ?loc:pat.loc (str "Variable " ++ Id.print id ++ str " is bound several \
times in this matching")
in
let ids = List.fold_left fold Id.Set.empty el in
if is_rec then intern_let_rec env loc el tycon e
else intern_let env loc ids el tycon e
| CTacSyn (el, kn) ->
let v = expand_notation ?loc el kn in
intern_rec env tycon v
| CTacCnv (e, tc) ->
let tc = intern_type env tc in
let e = intern_rec_with_constraint env e tc in
check (e, tc)
| CTacSeq (e1, e2) ->
let loc1 = e1.loc in
let (e1, t1) = intern_rec env None e1 in
let (e2, t2) = intern_rec env tycon e2 in
let () = check_elt_unit loc1 env t1 in
(GTacLet (false, [Anonymous, e1], e2), t2)
| CTacIft (e, e1, e2) ->
let e = intern_rec_with_constraint env e (GTypRef (Other t_bool, [])) in
let (e1, t1) = intern_rec env tycon e1 in
let t = Option.default t1 tycon in
let e2 = intern_rec_with_constraint env e2 t in
(GTacCse (e, Other t_bool, [|e1; e2|], [||]), t)
| CTacCse (e, pl) ->
let e,brs,rt = intern_case env loc e tycon pl in
begin try
let cse = to_simple_case env ?loc e brs in
cse, rt
with HardCase ->
let e, _ = e in
let brs = List.map (fun (p,br) -> glb_of_wip_pat p, br) brs in
GTacFullMatch (e,brs), rt
end
| CTacRec (def, fs) ->
let kn, tparam, args = intern_record env loc fs in
let def, args = match def with
| None ->
let args = Array.map (function
| PresentField _ as arg -> arg
| MissingField (_, field, _, _) -> user_err ?loc (str "Field " ++ Id.print field ++ str " is undefined"))
args
in
None, args
| Some def ->
let deftparam = Array.init (List.length tparam) (fun _ -> GTypVar (fresh_id env)) in
let used = ref false in
let args = Array.map (function
| PresentField _ as arg -> arg
| MissingField (i, _, ftyp, expectedtyp) ->
used := true;
let deftyp = subst_type (fun i -> deftparam.(i)) ftyp in
let () = unify ?loc env deftyp expectedtyp in
MissingField i)
args
in
let () = if not !used then warn_useless_record_with ?loc (); in
let def = intern_rec_with_constraint env def (GTypRef (Other kn, Array.to_list deftparam)) in
let var = match def with
| GTacVar _ | GTacRef _ -> None
| _ -> Some (fresh_var (bound_vars env))
in
Some (var, def), args
in
let args = CArray.map_to_list (function
| PresentField (arg,argty) -> intern_rec_with_constraint env arg argty
| MissingField i -> match def with
| None -> assert false
| Some (None, def) -> GTacPrj (kn, def, i)
| Some (Some var, _) -> GTacPrj (kn, GTacVar var, i))
args
in
let e = GTacCst (Other kn, 0, args) in
let e = match def with
| None -> e
| Some (None, _) -> e
| Some (Some var, def) ->
GTacLet (false, [Name var, def], e)
in
check (e, GTypRef (Other kn, tparam))
| CTacPrj (e, proj) ->
let pinfo = get_projection proj in
let loc = e.loc in
let (e, t) = intern_rec env None e in
let subst = Array.init pinfo.pdata_prms (fun _ -> fresh_id env) in
let params = Array.map_to_list (fun i -> GTypVar i) subst in
let exp = GTypRef (Other pinfo.pdata_type, params) in
let () = unify ?loc env t exp in
let substf i = GTypVar subst.(i) in
let ret = subst_type substf pinfo.pdata_ptyp in
check (GTacPrj (pinfo.pdata_type, e, pinfo.pdata_indx), ret)
| CTacSet (e, proj, r) ->
let pinfo = get_projection proj in
let () =
if not pinfo.pdata_mutb then
let loc = match proj with
| RelId {CAst.loc} -> loc
| AbsKn _ -> None
in
user_err ?loc (str "Field is not mutable")
in
let subst = Array.init pinfo.pdata_prms (fun _ -> fresh_id env) in
let params = Array.map_to_list (fun i -> GTypVar i) subst in
let exp = GTypRef (Other pinfo.pdata_type, params) in
let e = intern_rec_with_constraint env e exp in
let substf i = GTypVar subst.(i) in
let ret = subst_type substf pinfo.pdata_ptyp in
let r = intern_rec_with_constraint env r ret in
check (GTacSet (pinfo.pdata_type, e, pinfo.pdata_indx, r), GTypRef (Tuple 0, []))
| CTacExt (tag, arg) ->
let open Genintern in
let self ist e =
let env = match Store.get ist.extra ltac2_env with
| None -> empty_env ()
| Some env -> env
in
intern_rec env None e
in
let obj = interp_ml_object tag in
let genv = Global.env_of_context Environ.empty_named_context_val in
let ist = empty_glob_sign ~strict:(env_strict env) genv in
let ist = { ist with extra = Store.set ist.extra ltac2_env env } in
let arg, tpe = obj.ml_intern self ist arg in
let e = match arg with
| GlbVal arg -> GTacExt (tag, arg)
| GlbTacexpr e -> e
in
check (e, tpe)
| CTacGlb (prms, args, body, ty) ->
let tysubst = Array.init prms (fun _ -> fresh_id env) in
let tysubst i = GTypVar tysubst.(i) in
let ty = subst_type tysubst ty in
let ty = match tycon with
| None -> ty
| Some tycon ->
let () = unify ?loc env ty tycon in
tycon
in
let args = List.map (fun (na, arg, ty) ->
let ty = Option.map (subst_type tysubst) ty in
let () = match na.CAst.v, ty with
| Anonymous, None | Name _, Some _ -> ()
| Anonymous, Some _ | Name _, None -> assert false
in
let e, _ = intern_rec env ty arg in
na.CAst.v, e)
args
in
if CList.is_empty args then body, ty
else GTacLet (false, args, body), ty
and intern_rec_with_constraint env e exp =
let (er, t) = intern_rec env (Some exp) e in
er
and intern_let env loc ids el tycon e =
let avoid = Id.Set.union ids (bound_vars env) in
let fold avoid (pat, t, e) =
let nas, exp = expand_pattern avoid [pat, t] in
let na = match nas with [x] -> x | _ -> assert false in
let avoid = List.fold_left add_name avoid nas in
(avoid, (na, exp, t, e))
in
let (_, el) = List.fold_left_map fold avoid el in
let fold body (na, exp, tc, e) =
let tc = Option.map (intern_type env) tc in
let (e, t) = intern_rec env tc e in
let t = if is_value e then abstract_var env t else monomorphic t in
(exp body, (na, e, t))
in
let (e, elp) = List.fold_left_map fold e el in
let env = List.fold_left (fun accu (na, _, t) -> push_name na t accu) env elp in
let (e, t) = intern_rec env tycon e in
let () = check_unused_variables ?loc env pi1 elp in
let el = List.map (fun (na, e, _) -> na, e) elp in
(GTacLet (false, el, e), t)
and intern_let_rec env loc el tycon e =
let map env (pat, t, e) =
let na = match pat.v with
| CPatVar na -> na
| CPatAtm _ | CPatRef _ | CPatCnv _ | CPatOr _ | CPatAs _ | CPatRecord _ ->
user_err ?loc:pat.loc (str "This kind of pattern is forbidden in let-rec bindings")
in
let t = match t with
| None -> GTypVar (fresh_id env)
| Some t -> intern_type env t
in
let env = push_name na (monomorphic t) env in
(env, (na, t, e))
in
let (env, el) = List.fold_left_map map env el in
let map (na, t, e) = match e.v with
| CTacCnv (e',t') ->
let t' = intern_type env t' in
let () = unify ?loc:e.loc env t' t in
na, t', e'
| CTacFun (bnd,e') ->
let bnd = List.map extract_pattern_type bnd in
let map (_, t) = match t with
| None -> GTypVar (fresh_id env)
| Some t -> intern_type env t
in
let tl = List.map map bnd in
let nas, exp = expand_pattern (bound_vars env) bnd in
let t = List.fold_left2 (fun t na tna -> tycon_fun_body ?loc:e.loc env t tna) t nas tl in
let e', t' = match e'.v with
| CTacCnv (e',t') ->
let t' = intern_type env t' in
let () = unify ?loc:e'.loc env t' t in
e', t'
| _ -> e', t
in
let t' = List.fold_right (fun tna t' -> GTypArrow (tna, t')) tl t' in
let pats = List.map (fun na -> CAst.make (CPatVar na)) nas in
let e' = exp e' in
(na, t', CAst.make ?loc:e.loc (CTacFun (pats, e')))
| _ -> (na, t, e)
in
let el = List.map map el in
let map (na, tc, e) =
let loc_e = e.loc in
let e = intern_rec_with_constraint env e tc in
let () =
if not (is_rec_rhs e) then
user_err ?loc:loc_e (str "This kind of expression is not allowed as \
right-hand side of a recursive binding")
in
(na, e)
in
let el = List.map map el in
let (e, t) = intern_rec env tycon e in
let () =
check_unused_variables ?loc env fst el
in
(GTacLet (true, el, e), t)
and intern_constructor env loc tycon kn args = match kn with
| Other kn ->
let cstr = interp_constructor kn in
let nargs = List.length cstr.cdata_args in
if Int.equal nargs (List.length args) then
let subst = Array.init cstr.cdata_prms (fun _ -> fresh_id env) in
let substf i = GTypVar subst.(i) in
let types = List.map (fun t -> subst_type substf t) cstr.cdata_args in
let targs = List.init cstr.cdata_prms (fun i -> GTypVar subst.(i)) in
let ans = GTypRef (Other cstr.cdata_type, targs) in
let ans = match tycon with
| None -> ans
| Some tycon ->
let () = unify ?loc env ans tycon in
tycon
in
let map arg tpe = intern_rec_with_constraint env arg tpe in
let args = List.map2 map args types in
match cstr.cdata_indx with
| Some idx ->
(GTacCst (Other cstr.cdata_type, idx, args), ans)
| None ->
(GTacOpn (kn, args), ans)
else
error_nargs_mismatch ?loc kn nargs (List.length args)
| Tuple n ->
let () = if not (Int.equal n (List.length args)) then begin
if Int.equal 0 n then
let t = GTypRef (Tuple 0, []) in
CErrors.user_err ?loc Pp.(
str "This expression has type" ++ spc () ++ pr_glbtype env t ++
spc () ++ str "and is not a function")
else assert false
end
in
let types = List.init n (fun i -> GTypVar (fresh_id env)) in
let ans = GTypRef (Tuple n, types) in
let ans = match tycon with
| None -> ans
| Some tycon ->
let () = unify ?loc env ans tycon in
tycon
in
let map arg tpe = intern_rec_with_constraint env arg tpe in
let args = List.map2 map args types in
GTacCst (Tuple n, 0, args), ans
and intern_case env loc e tycon pl =
let e, et = intern_rec env None e in
let rt = match tycon with
| Some t -> t
| None -> GTypVar (fresh_id env)
in
let pl = List.map (fun (cpat,cbr) ->
let patvars, pat = intern_pat env cpat et in
let patenv = push_ids patvars env in
let br = intern_rec_with_constraint patenv cbr rt in
let () = check_unused_variables ?loc patenv (fun (id,_) -> Name id) (Id.Map.bindings patvars) in
pat, br)
pl
in
let just_patterns = List.map fst pl in
let () = check_no_missing_pattern env et just_patterns in
let () = check_redundant_clauses env et just_patterns in
((e,et),pl,rt)
type context = (Id.t * type_scheme) list
let intern ~strict ctx e =
let env = empty_env ~strict () in
let fold accu (id, t) = push_name (Name id) (polymorphic t) accu in
let env = List.fold_left fold env ctx in
let (e, t) = intern_rec env None e in
let count = ref 0 in
let vars = ref TVar.Map.empty in
let t = normalize env (count, vars) t in
(e, (!count, t))
let intern_typedef self (ids, t) : glb_quant_typedef =
let env = set_rec self (empty_env ()) in
let map id = get_alias id env in
let ids = List.map map ids in
let count = ref (List.length ids) in
let vars = ref TVar.Map.empty in
let iter n id = vars := TVar.Map.add id (GTypVar n) !vars in
let () = List.iteri iter ids in
let env = reject_unbound_tvar env in
let intern t =
let t = intern_type env t in
normalize env (count, vars) t
in
let count = !count in
match t with
| CTydDef None -> (count, GTydDef None)
| CTydDef (Some t) -> (count, GTydDef (Some (intern t)))
| CTydAlg constrs ->
let map (c, t) = (c, List.map intern t) in
let constrs = List.map map constrs in
let getn (const, nonconst) (c, args) = match args with
| [] -> (succ const, nonconst)
| _ :: _ -> (const, succ nonconst)
in
let nconst, nnonconst = List.fold_left getn (0, 0) constrs in
let galg = {
galg_constructors = constrs;
galg_nconst = nconst;
galg_nnonconst = nnonconst;
} in
(count, GTydAlg galg)
| CTydRec fields ->
let map (c, mut, t) = (c, mut, intern t) in
let fields = List.map map fields in
(count, GTydRec fields)
| CTydOpn -> (count, GTydOpn)
let intern_open_type t =
let env = empty_env () in
let t = intern_type env t in
let count = ref 0 in
let vars = ref TVar.Map.empty in
let t = normalize env (count, vars) t in
(!count, t)
(** Subtyping *)
let check_subtype t1 t2 =
let env = empty_env () in
let t1 = fresh_type_scheme env t1 in
let rigid i = GTypRef (Tuple (i + 1), []) in
let (n, t2) = t2 in
let subst = Array.init n rigid in
let substf i = subst.(i) in
let t2 = subst_type substf t2 in
try unify0 env t1 t2; true with CannotUnify _ -> false
(** Globalization *)
let get_projection0 var = match var with
| RelId qid ->
let kn = try Tac2env.locate_projection qid with Not_found ->
user_err ?loc:qid.CAst.loc (pr_qualid qid ++ str " is not a projection")
in
kn
| AbsKn kn -> kn
type raw_ext = RawExt : ('a, _) Tac2dyn.Arg.tag * 'a -> raw_ext
let globalize_gen ~tacext ids tac =
let rec globalize ids ({loc;v=er} as e) = match er with
| CTacAtm _ -> e
| CTacRef ref ->
let mem id = Id.Set.mem id ids in
begin match get_variable0 mem ref with
| ArgVar _ -> e
| ArgArg kn ->
let () = check_deprecated_ltac2 ?loc ref kn in
CAst.make ?loc @@ CTacRef (AbsKn kn)
end
| CTacCst qid ->
let knc = get_constructor () qid in
CAst.make ?loc @@ CTacCst (AbsKn knc)
| CTacFun (bnd, e) ->
let fold (pats, accu) pat =
let accu = ids_of_pattern accu pat in
let pat = globalize_pattern ids pat in
(pat :: pats, accu)
in
let bnd, ids = List.fold_left fold ([], ids) bnd in
let bnd = List.rev bnd in
let e = globalize ids e in
CAst.make ?loc @@ CTacFun (bnd, e)
| CTacApp (e, el) ->
let e = globalize ids e in
let el = List.map (fun e -> globalize ids e) el in
CAst.make ?loc @@ CTacApp (e, el)
| CTacLet (isrec, bnd, e) ->
let fold accu (pat, _) = ids_of_pattern accu pat in
let ext = List.fold_left fold Id.Set.empty bnd in
let eids = Id.Set.union ext ids in
let e = globalize eids e in
let map (qid, e) =
let ids = if isrec then eids else ids in
let qid = globalize_pattern ids qid in
(qid, globalize ids e)
in
let bnd = List.map map bnd in
CAst.make ?loc @@ CTacLet (isrec, bnd, e)
| CTacSyn (el, kn) ->
let v = expand_notation ?loc el kn in
globalize ids v
| CTacCnv (e, t) ->
let e = globalize ids e in
CAst.make ?loc @@ CTacCnv (e, t)
| CTacSeq (e1, e2) ->
let e1 = globalize ids e1 in
let e2 = globalize ids e2 in
CAst.make ?loc @@ CTacSeq (e1, e2)
| CTacIft (e, e1, e2) ->
let e = globalize ids e in
let e1 = globalize ids e1 in
let e2 = globalize ids e2 in
CAst.make ?loc @@ CTacIft (e, e1, e2)
| CTacCse (e, bl) ->
let e = globalize ids e in
let bl = List.map (fun b -> globalize_case ids b) bl in
CAst.make ?loc @@ CTacCse (e, bl)
| CTacRec (def, r) ->
let def = Option.map (globalize ids) def in
let map (p, e) =
let p = get_projection0 p in
let e = globalize ids e in
(AbsKn p, e)
in
CAst.make ?loc @@ CTacRec (def, List.map map r)
| CTacPrj (e, p) ->
let e = globalize ids e in
let p = get_projection0 p in
CAst.make ?loc @@ CTacPrj (e, AbsKn p)
| CTacSet (e, p, e') ->
let e = globalize ids e in
let p = get_projection0 p in
let e' = globalize ids e' in
CAst.make ?loc @@ CTacSet (e, AbsKn p, e')
| CTacExt (tag, arg) -> tacext ?loc (RawExt (tag, arg))
| CTacGlb (prms, args, body, ty) ->
let args = List.map (fun (na, arg, ty) -> na, globalize ids arg, ty) args in
CAst.make ?loc @@ CTacGlb (prms, args, body, ty)
and globalize_case ids (p, e) =
(globalize_pattern ids p, globalize ids e)
and globalize_pattern ids ({loc;v=pr} as p) = match pr with
| CPatVar _ | CPatAtm _ -> p
| CPatRef (cst, pl) ->
let knc = get_constructor () cst in
let cst = AbsKn knc in
let pl = List.map (fun p -> globalize_pattern ids p) pl in
CAst.make ?loc @@ CPatRef (cst, pl)
| CPatCnv (pat, ty) ->
let pat = globalize_pattern ids pat in
CAst.make ?loc @@ CPatCnv (pat, ty)
| CPatOr pl ->
let pl = List.map (fun p -> globalize_pattern ids p) pl in
CAst.make ?loc @@ CPatOr pl
| CPatAs (p,x) ->
CAst.make ?loc @@ CPatAs (globalize_pattern ids p, x)
| CPatRecord pats ->
let map (p, e) =
let p = get_projection0 p in
let e = globalize_pattern ids e in
(AbsKn p, e)
in
CAst.make ?loc @@ CPatRecord (List.map map pats)
in
globalize ids tac
let globalize ids tac =
let tacext ?loc (RawExt (tag,_)) =
let arg = str (Tac2dyn.Arg.repr tag) in
CErrors.user_err ?loc (str "Cannot globalize generic arguments of type" ++ spc () ++ arg)
in
globalize_gen ~tacext ids tac
let debug_globalize_allow_ext ids tac =
let tacext ?loc (RawExt (tag,arg)) = CAst.make ?loc @@ CTacExt (tag,arg) in
globalize_gen ~tacext ids tac
let { Goptions.get = typed_notations } =
Goptions.declare_bool_option_and_ref
~key:["Ltac2";"Typed";"Notations"] ~value:true ()
let intern_notation_data ids body =
if typed_notations () then
let env = empty_env ~strict:true () in
let fold id (env,argtys) =
let ty = GTypVar (fresh_id env) in
let env = push_name (Name id) (monomorphic ty) env in
env, Id.Map.add id ty argtys
in
let env, argtys = Id.Set.fold fold ids (env,Id.Map.empty) in
let body, ty = intern_rec env None body in
let () = check_unused_variables env (fun (id,_) -> Name id) (Id.Map.bindings argtys) in
let count = ref 0 in
let vars = ref TVar.Map.empty in
let argtys = Id.Map.map (fun ty -> normalize env (count, vars) ty) argtys in
let ty = normalize env (count, vars) ty in
let prms = !count in
Tac2env.TypedNota {
nota_prms = prms;
nota_argtys = argtys;
nota_ty = ty;
nota_body = body;
}
else
let body = globalize ids body in
Tac2env.UntypedNota body
(** Kernel substitution *)
open Mod_subst
let subst_or_tuple f subst o = match o with
| Tuple _ -> o
| Other v ->
let v' = f subst v in
if v' == v then o else Other v'
let rec subst_type subst t = match t with
| GTypVar _ -> t
| GTypArrow (t1, t2) ->
let t1' = subst_type subst t1 in
let t2' = subst_type subst t2 in
if t1' == t1 && t2' == t2 then t
else GTypArrow (t1', t2')
| GTypRef (kn, tl) ->
let kn' = subst_or_tuple subst_kn subst kn in
let tl' = List.Smart.map (fun t -> subst_type subst t) tl in
if kn' == kn && tl' == tl then t else GTypRef (kn', tl')
let rec subst_glb_pat subst = function
| (GPatVar _ | GPatAtm _) as pat0 -> pat0
| GPatRef (ctor,pats) as pat0 ->
let ctor' =
let ctyp' = Option.Smart.map (subst_kn subst) ctor.ctyp in
if ctyp' == ctor.ctyp then ctor
else {ctor with ctyp = ctyp'}
in
let pats' = List.Smart.map (subst_glb_pat subst) pats in
if ctor' == ctor && pats' == pats then pat0
else GPatRef (ctor', pats')
| GPatOr pats as pat0 ->
let pats' = List.Smart.map (subst_glb_pat subst) pats in
if pats' == pats then pat0
else GPatOr pats'
| GPatAs (p,x) as pat0 ->
let p' = subst_glb_pat subst p in
if p' == p then pat0
else GPatAs (p',x)
let rec subst_expr subst e = match e with
| GTacAtm _ | GTacVar _ | GTacPrm _ -> e
| GTacRef kn -> GTacRef (subst_kn subst kn)
| GTacFun (ids, e) -> GTacFun (ids, subst_expr subst e)
| GTacApp (f, args) ->
GTacApp (subst_expr subst f, List.map (fun e -> subst_expr subst e) args)
| GTacLet (r, bs, e) ->
let bs = List.map (fun (na, e) -> (na, subst_expr subst e)) bs in
GTacLet (r, bs, subst_expr subst e)
| GTacCst (t, n, el) as e0 ->
let t' = subst_or_tuple subst_kn subst t in
let el' = List.Smart.map (fun e -> subst_expr subst e) el in
if t' == t && el' == el then e0 else GTacCst (t', n, el')
| GTacCse (e, ci, cse0, cse1) ->
let cse0' = Array.map (fun e -> subst_expr subst e) cse0 in
let cse1' = Array.map (fun (ids, e) -> (ids, subst_expr subst e)) cse1 in
let ci' = subst_or_tuple subst_kn subst ci in
GTacCse (subst_expr subst e, ci', cse0', cse1')
| GTacWth { opn_match = e; opn_branch = br; opn_default = (na, def) } as e0 ->
let e' = subst_expr subst e in
let def' = subst_expr subst def in
let fold kn (self, vars, p) accu =
let kn' = subst_kn subst kn in
let p' = subst_expr subst p in
if kn' == kn && p' == p then accu
else KNmap.add kn' (self, vars, p') (KNmap.remove kn accu)
in
let br' = KNmap.fold fold br br in
if e' == e && br' == br && def' == def then e0
else GTacWth { opn_match = e'; opn_default = (na, def'); opn_branch = br' }
| GTacFullMatch (e,brs) as e0 ->
let e' = subst_expr subst e in
let brs' = List.Smart.map (fun (pat,br as pbr) ->
let pat' = subst_glb_pat subst pat in
let br' = subst_expr subst br in
if pat' == pat && br' == br then pbr
else (pat',br'))
brs
in
if e' == e && brs' == brs then e0
else GTacFullMatch (e', brs')
| GTacPrj (kn, e, p) as e0 ->
let kn' = subst_kn subst kn in
let e' = subst_expr subst e in
if kn' == kn && e' == e then e0 else GTacPrj (kn', e', p)
| GTacSet (kn, e, p, r) as e0 ->
let kn' = subst_kn subst kn in
let e' = subst_expr subst e in
let r' = subst_expr subst r in
if kn' == kn && e' == e && r' == r then e0 else GTacSet (kn', e', p, r')
| GTacExt (tag, arg) ->
let tpe = interp_ml_object tag in
let arg' = tpe.ml_subst subst arg in
if arg' == arg then e else GTacExt (tag, arg')
| GTacOpn (kn, el) as e0 ->
let kn' = subst_kn subst kn in
let el' = List.Smart.map (fun e -> subst_expr subst e) el in
if kn' == kn && el' == el then e0 else GTacOpn (kn', el')
let subst_typedef subst e = match e with
| GTydDef t ->
let t' = Option.Smart.map (fun t -> subst_type subst t) t in
if t' == t then e else GTydDef t'
| GTydAlg galg ->
let map (c, tl as p) =
let tl' = List.Smart.map (fun t -> subst_type subst t) tl in
if tl' == tl then p else (c, tl')
in
let constrs' = List.Smart.map map galg.galg_constructors in
if constrs' == galg.galg_constructors then e
else GTydAlg { galg with galg_constructors = constrs' }
| GTydRec fields ->
let map (c, mut, t as p) =
let t' = subst_type subst t in
if t' == t then p else (c, mut, t')
in
let fields' = List.Smart.map map fields in
if fields' == fields then e else GTydRec fields'
| GTydOpn -> GTydOpn
let subst_quant_typedef subst (prm, def as qdef) =
let def' = subst_typedef subst def in
if def' == def then qdef else (prm, def')
let subst_type_scheme subst (prm, t as sch) =
let t' = subst_type subst t in
if t' == t then sch else (prm, t')
let subst_or_relid subst ref = match ref with
| RelId _ -> ref
| AbsKn kn ->
let kn' = subst_or_tuple subst_kn subst kn in
if kn' == kn then ref else AbsKn kn'
let rec subst_rawtype subst ({loc;v=tr} as t) = match tr with
| CTypVar _ -> t
| CTypArrow (t1, t2) ->
let t1' = subst_rawtype subst t1 in
let t2' = subst_rawtype subst t2 in
if t1' == t1 && t2' == t2 then t else CAst.make ?loc @@ CTypArrow (t1', t2')
| CTypRef (ref, tl) ->
let ref' = subst_or_relid subst ref in
let tl' = List.Smart.map (fun t -> subst_rawtype subst t) tl in
if ref' == ref && tl' == tl then t else CAst.make ?loc @@ CTypRef (ref', tl')
let subst_tacref subst ref = match ref with
| RelId _ -> ref
| AbsKn (TacConstant kn) ->
let kn' = subst_kn subst kn in
if kn' == kn then ref else AbsKn (TacConstant kn')
| AbsKn (TacAlias kn) ->
let kn' = subst_kn subst kn in
if kn' == kn then ref else AbsKn (TacAlias kn')
let subst_projection subst prj = match prj with
| RelId _ -> prj
| AbsKn kn ->
let kn' = subst_kn subst kn in
if kn' == kn then prj else AbsKn kn'
let rec subst_rawpattern subst ({loc;v=pr} as p) = match pr with
| CPatVar _ | CPatAtm _ -> p
| CPatRef (c, pl) ->
let pl' = List.Smart.map (fun p -> subst_rawpattern subst p) pl in
let c' = subst_or_relid subst c in
if pl' == pl && c' == c then p else CAst.make ?loc @@ CPatRef (c', pl')
| CPatCnv (pat, ty) ->
let pat' = subst_rawpattern subst pat in
let ty' = subst_rawtype subst ty in
if pat' == pat && ty' == ty then p else CAst.make ?loc @@ CPatCnv (pat', ty')
| CPatOr pl ->
let pl' = List.Smart.map (fun p -> subst_rawpattern subst p) pl in
if pl' == pl then p else CAst.make ?loc @@ CPatOr pl'
| CPatAs (pat,x) ->
let pat' = subst_rawpattern subst pat in
if pat' == pat then p else CAst.make ?loc @@ CPatAs (pat', x)
| CPatRecord el ->
let map (prj, e as p) =
let prj' = subst_projection subst prj in
let e' = subst_rawpattern subst e in
if prj' == prj && e' == e then p else (prj', e')
in
let el' = List.Smart.map map el in
if el' == el then p else CAst.make ?loc @@ CPatRecord el'
(** Used for notations *)
let rec subst_rawexpr subst ({loc;v=tr} as t) = match tr with
| CTacAtm _ -> t
| CTacRef ref ->
let ref' = subst_tacref subst ref in
if ref' == ref then t else CAst.make ?loc @@ CTacRef ref'
| CTacCst ref ->
let ref' = subst_or_relid subst ref in
if ref' == ref then t else CAst.make ?loc @@ CTacCst ref'
| CTacFun (bnd, e) ->
let map pat = subst_rawpattern subst pat in
let bnd' = List.Smart.map map bnd in
let e' = subst_rawexpr subst e in
if bnd' == bnd && e' == e then t else CAst.make ?loc @@ CTacFun (bnd', e')
| CTacApp (e, el) ->
let e' = subst_rawexpr subst e in
let el' = List.Smart.map (fun e -> subst_rawexpr subst e) el in
if e' == e && el' == el then t else CAst.make ?loc @@ CTacApp (e', el')
| CTacLet (isrec, bnd, e) ->
let map (na, e as p) =
let na' = subst_rawpattern subst na in
let e' = subst_rawexpr subst e in
if na' == na && e' == e then p else (na', e')
in
let bnd' = List.Smart.map map bnd in
let e' = subst_rawexpr subst e in
if bnd' == bnd && e' == e then t else CAst.make ?loc @@ CTacLet (isrec, bnd', e')
| CTacCnv (e, c) ->
let e' = subst_rawexpr subst e in
let c' = subst_rawtype subst c in
if c' == c && e' == e then t else CAst.make ?loc @@ CTacCnv (e', c')
| CTacSeq (e1, e2) ->
let e1' = subst_rawexpr subst e1 in
let e2' = subst_rawexpr subst e2 in
if e1' == e1 && e2' == e2 then t else CAst.make ?loc @@ CTacSeq (e1', e2')
| CTacIft (e, e1, e2) ->
let e' = subst_rawexpr subst e in
let e1' = subst_rawexpr subst e1 in
let e2' = subst_rawexpr subst e2 in
if e' == e && e1' == e1 && e2' == e2 then t else CAst.make ?loc @@ CTacIft (e', e1', e2')
| CTacCse (e, bl) ->
let map (p, e as x) =
let p' = subst_rawpattern subst p in
let e' = subst_rawexpr subst e in
if p' == p && e' == e then x else (p', e')
in
let e' = subst_rawexpr subst e in
let bl' = List.Smart.map map bl in
if e' == e && bl' == bl then t else CAst.make ?loc @@ CTacCse (e', bl')
| CTacRec (def, el) ->
let def' = Option.Smart.map (subst_rawexpr subst) def in
let map (prj, e as p) =
let prj' = subst_projection subst prj in
let e' = subst_rawexpr subst e in
if prj' == prj && e' == e then p else (prj', e')
in
let el' = List.Smart.map map el in
if def' == def && el' == el then t else CAst.make ?loc @@ CTacRec (def',el')
| CTacPrj (e, prj) ->
let prj' = subst_projection subst prj in
let e' = subst_rawexpr subst e in
if prj' == prj && e' == e then t else CAst.make ?loc @@ CTacPrj (e', prj')
| CTacSet (e, prj, r) ->
let prj' = subst_projection subst prj in
let e' = subst_rawexpr subst e in
let r' = subst_rawexpr subst r in
if prj' == prj && e' == e && r' == r then t else CAst.make ?loc @@ CTacSet (e', prj', r')
| CTacGlb (prms, args, body, ty) ->
let args' = List.Smart.map (fun (na, arg, ty as o) ->
let arg' = subst_rawexpr subst arg in
let ty' = Option.Smart.map (subst_type subst) ty in
if arg' == arg && ty' == ty then o
else (na, arg', ty'))
args
in
let body' = subst_expr subst body in
let ty' = subst_type subst ty in
if args' == args && body' == body && ty' == ty then t
else CAst.make ?loc @@ CTacGlb (prms, args', body', ty')
| CTacSyn _ | CTacExt _ -> assert false (** Should not be generated by globalization *)
(** Registering *)
let () =
let open Genintern in
let intern ist (ids, tac) =
let ids = List.map (fun { CAst.v = id } -> id) ids in
let env = match Genintern.Store.get ist.extra ltac2_env with
| None ->
empty_env ~strict:ist.strict_check ()
| Some env -> env
in
let fold env id =
push_name (Name id) (monomorphic (GTypRef (Other t_ltac1, []))) env
in
let env = List.fold_left fold env ids in
let loc = tac.loc in
let (tac, t) = intern_rec env None tac in
let () = check_unused_variables ?loc env (fun x -> Name x) ids in
let () = check_elt_unit loc env t in
(ist, (ids, tac))
in
Genintern.register_intern0 wit_ltac2in1 intern
let () =
let open Genintern in
let add_lambda id tac =
let pat = CAst.make ?loc:id.CAst.loc (CPatVar (Name id.v)) in
let loc = tac.CAst.loc in
let mk v = CAst.make ?loc v in
let lam = mk @@ CTacFun ([pat], tac) in
mk @@ CTacApp (mk @@ CTacRef (AbsKn (TacConstant ltac1_lamdba)), [lam])
in
let intern ist (bnd,tac) =
let env = match Genintern.Store.get ist.extra ltac2_env with
| None ->
empty_env ~strict:ist.strict_check ()
| Some env -> env
in
let tac = List.fold_right add_lambda bnd tac in
let tac = intern_rec_with_constraint env tac (GTypRef (Other t_ltac1, [])) in
(ist, tac)
in
Genintern.register_intern0 wit_ltac2in1_val intern
let () =
let open Genintern in
let intern ist tac =
let env = match Genintern.Store.get ist.extra ltac2_env with
| None ->
empty_env ~strict:ist.strict_check ()
| Some env -> env
in
let fold id _ (ids, env) =
let () = assert (not @@ mem_var id env) in
let t = monomorphic (GTypRef (Other t_preterm, [])) in
let env = push_name (Name id) t env in
(Id.Set.add id ids, env)
in
let ntn_vars = ist.intern_sign.notation_variable_status in
let ids, env = Id.Map.fold fold ntn_vars (Id.Set.empty, env) in
let loc = tac.loc in
let (tac, t) = intern_rec env None tac in
let () = check_elt_unit loc env t in
(ist, (ids, tac))
in
Genintern.register_intern0 wit_ltac2_constr intern
let () = Gensubst.register_subst0 wit_ltac2in1 (fun s (ids, e) -> ids, subst_expr s e)
let () = Gensubst.register_subst0 wit_ltac2in1_val subst_expr
let () = Gensubst.register_subst0 wit_ltac2_constr (fun s (ids, e) -> ids, subst_expr s e)
let intern_var_quotation_gen ~ispat ist (kind, { CAst.v = id; loc }) =
let open Genintern in
let kind = match kind with
| None -> ConstrVar
| Some kind -> match Id.to_string kind.CAst.v with
| "constr" -> ConstrVar
| "preterm" -> PretermVar
| "pattern" -> PatternVar
| _ ->
CErrors.user_err ?loc:kind.loc
Pp.(str "Unknown Ltac2 variable quotation kind" ++ spc() ++ Id.print kind.v)
in
let typ = match kind with
| ConstrVar ->
if ispat
then CErrors.user_err ?loc Pp.(str "constr quotations not supported in tactic patterns.")
else t_constr
| PretermVar ->
if ispat
then CErrors.user_err ?loc Pp.(str "preterm quotations not supported in tactic patterns.")
else t_preterm
| PatternVar ->
if not ispat
then CErrors.user_err ?loc Pp.(str "pattern quotations not supported outside tactic patterns.")
else t_pattern
in
let env = match Genintern.Store.get ist.extra ltac2_env with
| None ->
empty_env ~strict:ist.strict_check ()
| Some env -> env
in
let () =
if Id.Map.mem id ist.intern_sign.notation_variable_status then
unify ?loc env (GTypRef (Other t_preterm, [])) (GTypRef (Other typ, []))
in
let t =
try find_var id env
with Not_found ->
CErrors.user_err ?loc (str "Unbound value " ++ Id.print id)
in
let t = fresh_mix_type_scheme env t in
let () = unify ?loc env t (GTypRef (Other typ, [])) in
(ist, (kind, id))
let intern_var_quotation = intern_var_quotation_gen ~ispat:false
let () = Genintern.register_intern0 wit_ltac2_var_quotation intern_var_quotation
let intern_var_quotation_pat ?loc ist v =
intern_var_quotation_gen ~ispat:true ist v
let () = Genintern.register_intern_pat wit_ltac2_var_quotation
intern_var_quotation_pat
let () = Gensubst.register_subst0 wit_ltac2_var_quotation (fun _ v -> v)