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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: impargs.ml 11282 2008-07-28 11:51:53Z msozeau $ *)
open Util
open Names
open Libnames
open Term
open Reduction
open Declarations
open Environ
open Inductive
open Libobject
open Lib
open Nametab
open Pp
open Topconstr
open Termops
(*s Flags governing the computation of implicit arguments *)
type implicits_flags = {
main : bool;
manual : bool; (* automatic or manual only *)
strict : bool; (* true = strict *)
strongly_strict : bool; (* true = strongly strict *)
reversible_pattern : bool;
contextual : bool; (* true = contextual *)
maximal : bool
}
(* les implicites sont stricts par défaut en v8 *)
let implicit_args = ref {
main = false;
manual = false;
strict = true;
strongly_strict = false;
reversible_pattern = false;
contextual = false;
maximal = false;
}
let make_implicit_args flag =
implicit_args := { !implicit_args with main = flag }
let make_manual_implicit_args flag =
implicit_args := { !implicit_args with main = if flag then true else !implicit_args.main;
manual = flag }
let make_strict_implicit_args flag =
implicit_args := { !implicit_args with strict = flag }
let make_strongly_strict_implicit_args flag =
implicit_args := { !implicit_args with strongly_strict = flag }
let make_reversible_pattern_implicit_args flag =
implicit_args := { !implicit_args with reversible_pattern = flag }
let make_contextual_implicit_args flag =
implicit_args := { !implicit_args with contextual = flag }
let make_maximal_implicit_args flag =
implicit_args := { !implicit_args with maximal = flag }
let is_implicit_args () = !implicit_args.main
let is_manual_implicit_args () = !implicit_args.manual
let is_strict_implicit_args () = !implicit_args.strict
let is_strongly_strict_implicit_args () = !implicit_args.strongly_strict
let is_reversible_pattern_implicit_args () = !implicit_args.reversible_pattern
let is_contextual_implicit_args () = !implicit_args.contextual
let is_maximal_implicit_args () = !implicit_args.maximal
let with_implicits flags f x =
let oflags = !implicit_args in
try
implicit_args := flags;
let rslt = f x in
implicit_args := oflags;
rslt
with e -> begin
implicit_args := oflags;
raise e
end
let set_maximality imps b =
(* Force maximal insertion on ending implicits (compatibility) *)
b || List.for_all ((<>) None) imps
(*s Computation of implicit arguments *)
(* We remember various information about why an argument is
inferable as implicit
- [DepRigid] means that the implicit argument can be found by
unification along a rigid path (we do not print the arguments of
this kind if there is enough arguments to infer them)
- [DepFlex] means that the implicit argument can be found by unification
along a collapsable path only (e.g. as x in (P x) where P is another
argument) (we do (defensively) print the arguments of this kind)
- [DepFlexAndRigid] means that the least argument from which the
implicit argument can be inferred is following a collapsable path
but there is a greater argument from where the implicit argument is
inferable following a rigid path (useful to know how to print a
partial application)
- [Manual] means the argument has been explicitely set as implicit.
We also consider arguments inferable from the conclusion but it is
operational only if [conclusion_matters] is true.
*)
type argument_position =
| Conclusion
| Hyp of int
type implicit_explanation =
| DepRigid of argument_position
| DepFlex of argument_position
| DepFlexAndRigid of (*flex*) argument_position * (*rig*) argument_position
| Manual
let argument_less = function
| Hyp n, Hyp n' -> n<n'
| Hyp _, Conclusion -> true
| Conclusion, _ -> false
let update pos rig (na,st) =
let e =
if rig then
match st with
| None -> DepRigid pos
| Some (DepRigid n as x) ->
if argument_less (pos,n) then DepRigid pos else x
| Some (DepFlexAndRigid (fpos,rpos) as x) ->
if argument_less (pos,fpos) or pos=fpos then DepRigid pos else
if argument_less (pos,rpos) then DepFlexAndRigid (fpos,pos) else x
| Some (DepFlex fpos) ->
if argument_less (pos,fpos) or pos=fpos then DepRigid pos
else DepFlexAndRigid (fpos,pos)
| Some Manual -> assert false
else
match st with
| None -> DepFlex pos
| Some (DepRigid rpos as x) ->
if argument_less (pos,rpos) then DepFlexAndRigid (pos,rpos) else x
| Some (DepFlexAndRigid (fpos,rpos) as x) ->
if argument_less (pos,fpos) then DepFlexAndRigid (pos,rpos) else x
| Some (DepFlex fpos as x) ->
if argument_less (pos,fpos) then DepFlex pos else x
| Some Manual -> assert false
in na, Some e
(* modified is_rigid_reference with a truncated env *)
let is_flexible_reference env bound depth f =
match kind_of_term f with
| Rel n when n >= bound+depth -> (* inductive type *) false
| Rel n when n >= depth -> (* previous argument *) true
| Rel n -> (* since local definitions have been expanded *) false
| Const kn ->
let cb = Environ.lookup_constant kn env in
cb.const_body <> None & not cb.const_opaque
| Var id ->
let (_,value,_) = Environ.lookup_named id env in value <> None
| Ind _ | Construct _ -> false
| _ -> true
let push_lift d (e,n) = (push_rel d e,n+1)
let is_reversible_pattern bound depth f l =
isRel f & let n = destRel f in (n < bound+depth) & (n >= depth) &
array_for_all (fun c -> isRel c & destRel c < depth) l &
array_distinct l
(* Precondition: rels in env are for inductive types only *)
let add_free_rels_until strict strongly_strict revpat bound env m pos acc =
let rec frec rig (env,depth as ed) c =
let hd = if strict then whd_betadeltaiota env c else c in
let c = if strongly_strict then hd else c in
match kind_of_term hd with
| Rel n when (n < bound+depth) & (n >= depth) ->
let i = bound + depth - n - 1 in
acc.(i) <- update pos rig acc.(i)
| App (f,l) when revpat & is_reversible_pattern bound depth f l ->
let i = bound + depth - destRel f - 1 in
acc.(i) <- update pos rig acc.(i)
| App (f,_) when rig & is_flexible_reference env bound depth f ->
if strict then () else
iter_constr_with_full_binders push_lift (frec false) ed c
| Case _ when rig ->
if strict then () else
iter_constr_with_full_binders push_lift (frec false) ed c
| Evar _ -> ()
| _ ->
iter_constr_with_full_binders push_lift (frec rig) ed c
in
frec true (env,1) m; acc
(* calcule la liste des arguments implicites *)
let concrete_name avoid_flags l env_names n all c =
if n = Anonymous & noccurn 1 c then
(Anonymous,l)
else
let fresh_id = next_name_not_occuring avoid_flags n l env_names c in
let idopt = if not all && noccurn 1 c then Anonymous else Name fresh_id in
(idopt, fresh_id::l)
let compute_implicits_gen strict strongly_strict revpat contextual all env t =
let rec aux env avoid n names t =
let t = whd_betadeltaiota env t in
match kind_of_term t with
| Prod (na,a,b) ->
let na',avoid' = concrete_name None avoid names na all b in
add_free_rels_until strict strongly_strict revpat n env a (Hyp (n+1))
(aux (push_rel (na',None,a) env) avoid' (n+1) (na'::names) b)
| _ ->
let names = List.rev names in
let v = Array.map (fun na -> na,None) (Array.of_list names) in
if contextual then
add_free_rels_until strict strongly_strict revpat n env t Conclusion v
else v
in
match kind_of_term (whd_betadeltaiota env t) with
| Prod (na,a,b) ->
let na',avoid = concrete_name None [] [] na all b in
let v = aux (push_rel (na',None,a) env) avoid 1 [na'] b in
Array.to_list v
| _ -> []
let rec prepare_implicits f = function
| [] -> []
| (Anonymous, Some _)::_ -> anomaly "Unnamed implicit"
| (Name id, Some imp)::imps ->
let imps' = prepare_implicits f imps in
Some (id,imp,set_maximality imps' f.maximal) :: imps'
| _::imps -> None :: prepare_implicits f imps
let compute_implicits_flags env f all t =
compute_implicits_gen
(f.strict or f.strongly_strict) f.strongly_strict
f.reversible_pattern f.contextual all env t
let set_implicit id imp insmax =
(id,(match imp with None -> Manual | Some imp -> imp),insmax)
let rec assoc_by_pos k = function
(ExplByPos (k', x), b) :: tl when k = k' -> (x,b), tl
| hd :: tl -> let (x, tl) = assoc_by_pos k tl in x, hd :: tl
| [] -> raise Not_found
let compute_manual_implicits env flags t enriching l =
let autoimps =
if enriching then compute_implicits_flags env flags true t
else compute_implicits_gen false false false true true env t in
let n = List.length autoimps in
let try_forced k l =
try
let (id, (b, f)), l' = assoc_by_pos k l in
if f then
let id = match id with Some id -> id | None -> id_of_string ("arg_" ^ string_of_int k) in
l', Some (id,Manual,b)
else l, None
with Not_found -> l, None
in
if not (list_distinct l) then
error ("Some parameters are referred more than once");
(* Compare with automatic implicits to recover printing data and names *)
let rec merge k l = function
| (Name id,imp)::imps ->
let l',imp,m =
try
let (b, f) = List.assoc (ExplByName id) l in
List.remove_assoc (ExplByName id) l, (Some Manual), (Some b)
with Not_found ->
try
let (id, (b, f)), l' = assoc_by_pos k l in
l', (Some Manual), (Some b)
with Not_found ->
l,imp, if enriching && imp <> None then Some flags.maximal else None
in
let imps' = merge (k+1) l' imps in
let m = Option.map (set_maximality imps') m in
Option.map (set_implicit id imp) m :: imps'
| (Anonymous,imp)::imps ->
let l', forced = try_forced k l in
forced :: merge (k+1) l' imps
| [] when l = [] -> []
| [] ->
List.iter (function
| ExplByName id,(b,forced) ->
if not forced then
error ("Wrong or not dependent implicit argument name: "^(string_of_id id))
| ExplByPos (i,_id),_t ->
if i<1 or i>n then
error ("Bad implicit argument number: "^(string_of_int i))
else
errorlabstrm ""
(str "Cannot set implicit argument number " ++ int i ++
str ": it has no name"))
l; []
in
merge 1 l autoimps
let const v _ = v
let compute_implicits_auto env f manual t =
match manual with
| [] ->
let l = compute_implicits_flags env f false t in
if f.manual then List.map (const None) l
else prepare_implicits f l
| _ -> compute_manual_implicits env f t (not f.manual) manual
let compute_implicits env t = compute_implicits_auto env !implicit_args [] t
type maximal_insertion = bool (* true = maximal contextual insertion *)
type implicit_status =
(* None = Not implicit *)
(identifier * implicit_explanation * maximal_insertion) option
type implicits_list = implicit_status list
let is_status_implicit = function
| None -> false
| _ -> true
let name_of_implicit = function
| None -> anomaly "Not an implicit argument"
| Some (id,_,_) -> id
let maximal_insertion_of = function
| Some (_,_,b) -> b
| None -> anomaly "Not an implicit argument"
(* [in_ctx] means we know the expected type, [n] is the index of the argument *)
let is_inferable_implicit in_ctx n = function
| None -> false
| Some (_,DepRigid (Hyp p),_) -> in_ctx or n >= p
| Some (_,DepFlex (Hyp p),_) -> false
| Some (_,DepFlexAndRigid (_,Hyp q),_) -> in_ctx or n >= q
| Some (_,DepRigid Conclusion,_) -> in_ctx
| Some (_,DepFlex Conclusion,_) -> false
| Some (_,DepFlexAndRigid (_,Conclusion),_) -> in_ctx
| Some (_,Manual,_) -> true
let positions_of_implicits =
let rec aux n = function
[] -> []
| Some _ :: l -> n :: aux (n+1) l
| None :: l -> aux (n+1) l
in aux 1
(*s Constants. *)
let compute_constant_implicits flags manual cst =
let env = Global.env () in
compute_implicits_auto env flags manual (Typeops.type_of_constant env cst)
(*s Inductives and constructors. Their implicit arguments are stored
in an array, indexed by the inductive number, of pairs $(i,v)$ where
$i$ are the implicit arguments of the inductive and $v$ the array of
implicit arguments of the constructors. *)
let compute_mib_implicits flags manual kn =
let env = Global.env () in
let mib = lookup_mind kn env in
let ar =
Array.to_list
(Array.map (* No need to lift, arities contain no de Bruijn *)
(fun mip ->
(Name mip.mind_typename, None, type_of_inductive env (mib,mip)))
mib.mind_packets) in
let env_ar = push_rel_context ar env in
let imps_one_inductive i mip =
let ind = (kn,i) in
let ar = type_of_inductive env (mib,mip) in
((IndRef ind,compute_implicits_auto env flags manual ar),
Array.mapi (fun j c ->
(ConstructRef (ind,j+1),compute_implicits_auto env_ar flags manual c))
mip.mind_nf_lc)
in
Array.mapi imps_one_inductive mib.mind_packets
let compute_all_mib_implicits flags manual kn =
let imps = compute_mib_implicits flags manual kn in
List.flatten
(array_map_to_list (fun (ind,cstrs) -> ind::Array.to_list cstrs) imps)
(*s Variables. *)
let compute_var_implicits flags manual id =
let env = Global.env () in
let (_,_,ty) = lookup_named id env in
compute_implicits_auto env flags manual ty
(* Implicits of a global reference. *)
let compute_global_implicits flags manual = function
| VarRef id -> compute_var_implicits flags manual id
| ConstRef kn -> compute_constant_implicits flags manual kn
| IndRef (kn,i) ->
let ((_,imps),_) = (compute_mib_implicits flags manual kn).(i) in imps
| ConstructRef ((kn,i),j) ->
let (_,cimps) = (compute_mib_implicits flags manual kn).(i) in snd cimps.(j-1)
(* Merge a manual explicitation with an implicit_status list *)
let list_split_at index l =
let rec aux i acc = function
tl when i = index -> (List.rev acc), tl
| hd :: tl -> aux (succ i) (hd :: acc) tl
| [] -> failwith "list_split_at: Invalid argument"
in aux 0 [] l
let merge_impls oldimpls newimpls =
let (before, news), olds =
let len = List.length newimpls - List.length oldimpls in
if len >= 0 then list_split_at len newimpls, oldimpls
else
let before, after = list_split_at (-len) oldimpls in
(before, newimpls), after
in
before @ (List.map2 (fun orig ni ->
match orig with
| Some (_, Manual, _) -> orig
| _ -> ni) olds news)
(* Caching implicits *)
type implicit_interactive_request =
| ImplAuto
| ImplManual of implicit_status list
type implicit_discharge_request =
| ImplLocal
| ImplConstant of constant * implicits_flags
| ImplMutualInductive of kernel_name * implicits_flags
| ImplInteractive of global_reference * implicits_flags *
implicit_interactive_request
let implicits_table = ref Refmap.empty
let implicits_of_global ref =
try Refmap.find ref !implicits_table with Not_found -> []
let cache_implicits_decl (ref,imps) =
implicits_table := Refmap.add ref imps !implicits_table
let load_implicits _ (_,(_,l)) = List.iter cache_implicits_decl l
let cache_implicits o =
load_implicits 1 o
let subst_implicits_decl subst (r,imps as o) =
let r' = fst (subst_global subst r) in if r==r' then o else (r',imps)
let subst_implicits (_,subst,(req,l)) =
(ImplLocal,list_smartmap (subst_implicits_decl subst) l)
let impls_of_context ctx =
List.rev_map (fun (id,impl,_,_) -> if impl = Lib.Implicit then Some (id, Manual, true) else None)
(List.filter (fun (_,_,b,_) -> b = None) ctx)
let section_segment_of_reference = function
| ConstRef con -> section_segment_of_constant con
| IndRef (kn,_) | ConstructRef ((kn,_),_) ->
section_segment_of_mutual_inductive kn
| _ -> []
let discharge_implicits (_,(req,l)) =
match req with
| ImplLocal -> None
| ImplInteractive (ref,flags,exp) ->
let vars = section_segment_of_reference ref in
let ref' = pop_global_reference ref in
let l' = [ref', impls_of_context vars @ snd (List.hd l)] in
Some (ImplInteractive (ref',flags,exp),l')
| ImplConstant (con,flags) ->
let con' = pop_con con in
let l' = [ConstRef con',impls_of_context (section_segment_of_constant con) @ snd (List.hd l)] in
Some (ImplConstant (con',flags),l')
| ImplMutualInductive (kn,flags) ->
let l' = List.map (fun (gr, l) ->
let vars = section_segment_of_reference gr in
(pop_global_reference gr, impls_of_context vars @ l)) l
in
Some (ImplMutualInductive (pop_kn kn,flags),l')
let rebuild_implicits (req,l) =
let l' = match req with
| ImplLocal -> assert false
| ImplConstant (con,flags) ->
let oldimpls = snd (List.hd l) in
let newimpls = compute_constant_implicits flags [] con in
[ConstRef con, merge_impls oldimpls newimpls]
| ImplMutualInductive (kn,flags) ->
let newimpls = compute_all_mib_implicits flags [] kn in
let rec aux olds news =
match olds, news with
| (_, oldimpls) :: old, (gr, newimpls) :: tl ->
(gr, merge_impls oldimpls newimpls) :: aux old tl
| [], [] -> []
| _, _ -> assert false
in aux l newimpls
| ImplInteractive (ref,flags,o) ->
match o with
| ImplAuto ->
let oldimpls = snd (List.hd l) in
let newimpls = compute_global_implicits flags [] ref in
[ref,merge_impls oldimpls newimpls]
| ImplManual m ->
let oldimpls = snd (List.hd l) in
let auto =
if flags.main then
let newimpls = compute_global_implicits flags [] ref in
merge_impls oldimpls newimpls
else oldimpls
in
let l' = merge_impls auto m in [ref,l']
in (req,l')
let export_implicits (req,_ as x) =
if req = ImplLocal then None else Some x
let (inImplicits, _) =
declare_object {(default_object "IMPLICITS") with
cache_function = cache_implicits;
load_function = load_implicits;
subst_function = subst_implicits;
classify_function = (fun (_,x) -> Substitute x);
discharge_function = discharge_implicits;
rebuild_function = rebuild_implicits;
export_function = export_implicits }
let declare_implicits_gen req flags ref =
let imps = compute_global_implicits flags [] ref in
add_anonymous_leaf (inImplicits (req,[ref,imps]))
let declare_implicits local ref =
let flags = { !implicit_args with main = true } in
let req =
if local then ImplLocal else ImplInteractive(ref,flags,ImplAuto) in
declare_implicits_gen req flags ref
let declare_var_implicits id =
if !implicit_args.main then
declare_implicits_gen ImplLocal !implicit_args (VarRef id)
let declare_constant_implicits con =
if !implicit_args.main then
let flags = !implicit_args in
declare_implicits_gen (ImplConstant (con,flags)) flags (ConstRef con)
let declare_mib_implicits kn =
if !implicit_args.main then
let flags = !implicit_args in
let imps = array_map_to_list
(fun (ind,cstrs) -> ind::(Array.to_list cstrs))
(compute_mib_implicits flags [] kn) in
add_anonymous_leaf
(inImplicits (ImplMutualInductive (kn,flags),List.flatten imps))
(* Declare manual implicits *)
type manual_explicitation = Topconstr.explicitation * (bool * bool)
let compute_implicits_with_manual env typ enriching l =
compute_manual_implicits env !implicit_args typ enriching l
let declare_manual_implicits local ref enriching l =
let flags = !implicit_args in
let env = Global.env () in
let t = Global.type_of_global ref in
let l' = compute_manual_implicits env flags t enriching l in
let req =
if local or isVarRef ref then ImplLocal
else ImplInteractive(ref,flags,ImplManual l')
in
add_anonymous_leaf (inImplicits (req,[ref,l']))
let maybe_declare_manual_implicits local ref enriching l =
if l = [] then ()
else declare_manual_implicits local ref enriching l
let lift_implicits n =
List.map (fun x ->
match fst x with
ExplByPos (k, id) -> ExplByPos (k + n, id), snd x
| _ -> x)
(*s Registration as global tables *)
let init () = implicits_table := Refmap.empty
let freeze () = !implicits_table
let unfreeze t = implicits_table := t
let _ =
Summary.declare_summary "implicits"
{ Summary.freeze_function = freeze;
Summary.unfreeze_function = unfreeze;
Summary.init_function = init;
Summary.survive_module = false;
Summary.survive_section = false }
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