(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* Id.compare v1 v2 | CL_CONST c1, CL_CONST c2 -> con_user_ord c1 c2 | CL_IND i1, CL_IND i2 -> ind_user_ord i1 i2 | _ -> Pervasives.compare t1 t2 (** OK *) module ClTyp = struct type t = cl_typ let compare = cl_typ_ord end module ClTypMap = Map.Make(ClTyp) module IntMap = Map.Make(Int) let cl_typ_eq t1 t2 = Int.equal (cl_typ_ord t1 t2) 0 type coe_index = coe_info_typ type inheritance_path = coe_index list (* table des classes, des coercions et graphe d'heritage *) module Bijint : sig module Index : sig type t val compare : t -> t -> int val equal : t -> t -> bool val print : t -> std_ppcmds end type 'a t val empty : 'a t val mem : cl_typ -> 'a t -> bool val map : Index.t -> 'a t -> cl_typ * 'a val revmap : cl_typ -> 'a t -> Index.t * 'a val add : cl_typ -> 'a -> 'a t -> 'a t val dom : 'a t -> cl_typ list end = struct module Index = struct include Int let print = Pp.int end type 'a t = { v : (cl_typ * 'a) IntMap.t; s : int; inv : int ClTypMap.t } let empty = { v = IntMap.empty; s = 0; inv = ClTypMap.empty } let mem y b = ClTypMap.mem y b.inv let map x b = IntMap.find x b.v let revmap y b = let n = ClTypMap.find y b.inv in (n, snd (IntMap.find n b.v)) let add x y b = { v = IntMap.add b.s (x,y) b.v; s = b.s+1; inv = ClTypMap.add x b.s b.inv } let dom b = List.rev (ClTypMap.fold (fun x _ acc -> x::acc) b.inv []) end type cl_index = Bijint.Index.t let class_tab = ref (Bijint.empty : cl_info_typ Bijint.t) let coercion_tab = ref (CoeTypMap.empty : coe_info_typ CoeTypMap.t) module ClPairOrd = struct type t = cl_index * cl_index let compare (i1, j1) (i2, j2) = let c = Bijint.Index.compare i1 i2 in if Int.equal c 0 then Bijint.Index.compare j1 j2 else c end module ClPairMap = Map.Make(ClPairOrd) let inheritance_graph = ref (ClPairMap.empty : inheritance_path ClPairMap.t) let freeze _ = (!class_tab, !coercion_tab, !inheritance_graph) let unfreeze (fcl,fco,fig) = class_tab:=fcl; coercion_tab:=fco; inheritance_graph:=fig (* ajout de nouveaux "objets" *) let add_new_class cl s = if not (Bijint.mem cl !class_tab) then class_tab := Bijint.add cl s !class_tab let add_new_coercion coe s = coercion_tab := CoeTypMap.add coe s !coercion_tab let add_new_path x y = inheritance_graph := ClPairMap.add x y !inheritance_graph let init () = class_tab:= Bijint.empty; add_new_class CL_FUN { cl_param = 0 }; add_new_class CL_SORT { cl_param = 0 }; coercion_tab:= CoeTypMap.empty; inheritance_graph:= ClPairMap.empty let _ = Summary.declare_summary "inh_graph" { Summary.freeze_function = freeze; Summary.unfreeze_function = unfreeze; Summary.init_function = init } let _ = init() (* class_info : cl_typ -> int * cl_info_typ *) let class_info cl = Bijint.revmap cl !class_tab let class_exists cl = Bijint.mem cl !class_tab (* class_info_from_index : int -> cl_typ * cl_info_typ *) let class_info_from_index i = Bijint.map i !class_tab let cl_fun_index = fst(class_info CL_FUN) let cl_sort_index = fst(class_info CL_SORT) (* coercion_info : coe_typ -> coe_info_typ *) let coercion_info coe = CoeTypMap.find coe !coercion_tab let coercion_exists coe = CoeTypMap.mem coe !coercion_tab (* find_class_type : evar_map -> constr -> cl_typ * universe_list * constr list *) let find_class_type sigma t = let t', args = Reductionops.whd_betaiotazeta_stack sigma t in match kind_of_term t' with | Var id -> CL_SECVAR id, Univ.Instance.empty, args | Const (sp,u) -> CL_CONST sp, u, args | Ind (ind_sp,u) -> CL_IND ind_sp, u, args | Prod (_,_,_) -> CL_FUN, Univ.Instance.empty, [] | Sort _ -> CL_SORT, Univ.Instance.empty, [] | _ -> raise Not_found let subst_cl_typ subst ct = match ct with CL_SORT | CL_FUN | CL_SECVAR _ -> ct | CL_CONST c -> let c',t = subst_con_kn subst c in if c' == c then ct else pi1 (find_class_type Evd.empty t) | CL_IND i -> let i' = subst_ind subst i in if i' == i then ct else CL_IND i' (*CSC: here we should change the datatype for coercions: it should be possible to declare any term as a coercion *) let subst_coe_typ subst t = subst_global_reference subst t (* class_of : Term.constr -> int *) let class_of env sigma t = let (t, n1, i, u, args) = try let (cl, u, args) = find_class_type sigma t in let (i, { cl_param = n1 } ) = class_info cl in (t, n1, i, u, args) with Not_found -> let t = Tacred.hnf_constr env sigma t in let (cl, u, args) = find_class_type sigma t in let (i, { cl_param = n1 } ) = class_info cl in (t, n1, i, u, args) in if Int.equal (List.length args) n1 then t, i else raise Not_found let inductive_class_of ind = fst (class_info (CL_IND ind)) let class_args_of env sigma c = pi3 (find_class_type sigma c) let string_of_class = function | CL_FUN -> "Funclass" | CL_SORT -> "Sortclass" | CL_CONST sp -> string_of_qualid (shortest_qualid_of_global Id.Set.empty (ConstRef sp)) | CL_IND sp -> string_of_qualid (shortest_qualid_of_global Id.Set.empty (IndRef sp)) | CL_SECVAR sp -> string_of_qualid (shortest_qualid_of_global Id.Set.empty (VarRef sp)) let pr_class x = str (string_of_class x) (* lookup paths *) let lookup_path_between_class (s,t) = ClPairMap.find (s,t) !inheritance_graph let lookup_path_to_fun_from_class s = lookup_path_between_class (s,cl_fun_index) let lookup_path_to_sort_from_class s = lookup_path_between_class (s,cl_sort_index) (* advanced path lookup *) let apply_on_class_of env sigma t cont = try let (cl,u,args) = find_class_type sigma t in let (i, { cl_param = n1 } ) = class_info cl in if not (Int.equal (List.length args) n1) then raise Not_found; t, cont i with Not_found -> (* Is it worth to be more incremental on the delta steps? *) let t = Tacred.hnf_constr env sigma t in let (cl, u, args) = find_class_type sigma t in let (i, { cl_param = n1 } ) = class_info cl in if not (Int.equal (List.length args) n1) then raise Not_found; t, cont i let lookup_path_between env sigma (s,t) = let (s,(t,p)) = apply_on_class_of env sigma s (fun i -> apply_on_class_of env sigma t (fun j -> lookup_path_between_class (i,j))) in (s,t,p) let lookup_path_to_fun_from env sigma s = apply_on_class_of env sigma s lookup_path_to_fun_from_class let lookup_path_to_sort_from env sigma s = apply_on_class_of env sigma s lookup_path_to_sort_from_class let get_coercion_constructor coe = let c, _ = Reductionops.whd_betadeltaiota_stack (Global.env()) Evd.empty coe.coe_value in match kind_of_term c with | Construct (cstr,u) -> (cstr, Inductiveops.constructor_nrealargs (Global.env()) cstr -1) | _ -> raise Not_found let lookup_pattern_path_between (s,t) = let i = inductive_class_of s in let j = inductive_class_of t in List.map get_coercion_constructor (ClPairMap.find (i,j) !inheritance_graph) (* coercion_value : coe_index -> unsafe_judgment * bool *) let coercion_value { coe_value = c; coe_type = t; coe_context = ctx; coe_is_identity = b; coe_is_projection = b' } = let subst, ctx = Universes.fresh_universe_context_set_instance ctx in let c' = Vars.subst_univs_level_constr subst c and t' = Vars.subst_univs_level_constr subst t in (make_judge c' t', b, b'), ctx (* pretty-print functions are now in Pretty *) (* rajouter une coercion dans le graphe *) let path_printer = ref (fun _ -> str "" : (Bijint.Index.t * Bijint.Index.t) * inheritance_path -> std_ppcmds) let install_path_printer f = path_printer := f let print_path x = !path_printer x let message_ambig l = (str"Ambiguous paths:" ++ spc () ++ prlist_with_sep fnl (fun ijp -> print_path ijp) l) (* add_coercion_in_graph : coe_index * cl_index * cl_index -> unit coercion,source,target *) let different_class_params i = let ci = class_info_from_index i in if (snd ci).cl_param > 0 then true else match fst ci with | CL_IND i -> Global.is_polymorphic (IndRef i) | CL_CONST c -> Global.is_polymorphic (ConstRef c) | _ -> false let add_coercion_in_graph (ic,source,target) = let old_inheritance_graph = !inheritance_graph in let ambig_paths = (ref [] : ((cl_index * cl_index) * inheritance_path) list ref) in let try_add_new_path (i,j as ij) p = try if Bijint.Index.equal i j then begin if different_class_params i then begin let _ = lookup_path_between_class ij in ambig_paths := (ij,p)::!ambig_paths end end else begin let _ = lookup_path_between_class ij in ambig_paths := (ij,p)::!ambig_paths end; false with Not_found -> begin add_new_path ij p; true end in let try_add_new_path1 ij p = let _ = try_add_new_path ij p in () in if try_add_new_path (source,target) [ic] then begin ClPairMap.iter (fun (s,t) p -> if not (Bijint.Index.equal s t) then begin if Bijint.Index.equal t source then begin try_add_new_path1 (s,target) (p@[ic]); ClPairMap.iter (fun (u,v) q -> if not (Bijint.Index.equal u v) && Bijint.Index.equal u target && not (List.equal coe_info_typ_equal p q) then try_add_new_path1 (s,v) (p@[ic]@q)) old_inheritance_graph end; if Bijint.Index.equal s target then try_add_new_path1 (source,t) (ic::p) end) old_inheritance_graph end; let is_ambig = match !ambig_paths with [] -> false | _ -> true in if is_ambig && is_verbose () then msg_warning (message_ambig !ambig_paths) type coercion = { coercion_type : coe_typ; coercion_local : bool; coercion_is_id : bool; coercion_is_proj : bool; coercion_source : cl_typ; coercion_target : cl_typ; coercion_params : int; } (* Calcul de l'arit้ d'une classe *) let reference_arity_length ref = let t,_ = Universes.type_of_global ref in List.length (fst (Reductionops.splay_arity (Global.env()) Evd.empty t)) let class_params = function | CL_FUN | CL_SORT -> 0 | CL_CONST sp -> reference_arity_length (ConstRef sp) | CL_SECVAR sp -> reference_arity_length (VarRef sp) | CL_IND sp -> reference_arity_length (IndRef sp) (* add_class : cl_typ -> locality_flag option -> bool -> unit *) let add_class cl = add_new_class cl { cl_param = class_params cl } let automatically_import_coercions = ref false open Goptions let _ = declare_bool_option { optsync = true; optdepr = false; optname = "automatic import of coercions"; optkey = ["Automatic";"Coercions";"Import"]; optread = (fun () -> !automatically_import_coercions); optwrite = (:=) automatically_import_coercions } let cache_coercion (_, c) = let () = add_class c.coercion_source in let () = add_class c.coercion_target in let is, _ = class_info c.coercion_source in let it, _ = class_info c.coercion_target in let value, ctx = Universes.fresh_global_instance (Global.env()) c.coercion_type in let typ = Retyping.get_type_of (Global.env ()) Evd.empty value in let xf = { coe_value = value; coe_type = typ; coe_context = ctx; coe_local = c.coercion_local; coe_is_identity = c.coercion_is_id; coe_is_projection = c.coercion_is_proj; coe_param = c.coercion_params } in let () = add_new_coercion c.coercion_type xf in add_coercion_in_graph (xf,is,it) let load_coercion _ o = if !automatically_import_coercions || Flags.version_less_or_equal Flags.V8_2 then cache_coercion o let open_coercion i o = if Int.equal i 1 && not (!automatically_import_coercions || Flags.version_less_or_equal Flags.V8_2) then cache_coercion o let subst_coercion (subst, c) = let coe = subst_coe_typ subst c.coercion_type in let cls = subst_cl_typ subst c.coercion_source in let clt = subst_cl_typ subst c.coercion_target in if c.coercion_type == coe && c.coercion_source == cls && c.coercion_target == clt then c else { c with coercion_type = coe; coercion_source = cls; coercion_target = clt } let discharge_cl = function | CL_CONST kn -> CL_CONST (Lib.discharge_con kn) | CL_IND ind -> CL_IND (Lib.discharge_inductive ind) | cl -> cl let discharge_coercion (_, c) = if c.coercion_local then None else let n = try let ins = Lib.section_instance c.coercion_type in Array.length (snd ins) with Not_found -> 0 in let nc = { c with coercion_type = Lib.discharge_global c.coercion_type; coercion_source = discharge_cl c.coercion_source; coercion_target = discharge_cl c.coercion_target; coercion_params = n + c.coercion_params; } in Some nc let classify_coercion obj = if obj.coercion_local then Dispose else Substitute obj let inCoercion : coercion -> obj = declare_object {(default_object "COERCION") with open_function = open_coercion; load_function = load_coercion; cache_function = cache_coercion; subst_function = subst_coercion; classify_function = classify_coercion; discharge_function = discharge_coercion } let declare_coercion coef ?(local = false) ~isid ~src:cls ~target:clt ~params:ps = let isproj = match coef with | ConstRef c -> Environ.is_projection c (Global.env ()) | _ -> false in let c = { coercion_type = coef; coercion_local = local; coercion_is_id = isid; coercion_is_proj = isproj; coercion_source = cls; coercion_target = clt; coercion_params = ps; } in Lib.add_anonymous_leaf (inCoercion c) (* For printing purpose *) let get_coercion_value v = v.coe_value let pr_cl_index = Bijint.Index.print let classes () = Bijint.dom !class_tab let coercions () = List.rev (CoeTypMap.fold (fun _ y acc -> y::acc) !coercion_tab []) let inheritance_graph () = ClPairMap.bindings !inheritance_graph let coercion_of_reference r = let ref = Nametab.global r in if not (coercion_exists ref) then errorlabstrm "try_add_coercion" (Nametab.pr_global_env Id.Set.empty ref ++ str" is not a coercion."); ref module CoercionPrinting = struct type t = coe_typ let compare = RefOrdered.compare let encode = coercion_of_reference let subst = subst_coe_typ let printer x = pr_global_env Id.Set.empty x let key = ["Printing";"Coercion"] let title = "Explicitly printed coercions: " let member_message x b = str "Explicit printing of coercion " ++ printer x ++ str (if b then " is set" else " is unset") let synchronous = true end module PrintingCoercion = Goptions.MakeRefTable(CoercionPrinting) let hide_coercion coe = if not (PrintingCoercion.active coe) then let coe_info = coercion_info coe in Some coe_info.coe_param else None