Source file pretyping.ml
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open Pp
open CErrors
open Util
open Names
open Evd
open Constr
open Context
open Termops
open Environ
open EConstr
open Vars
open Reductionops
open Type_errors
open Typing
open Evarutil
open Evardefine
open Pretype_errors
open Glob_term
open Glob_ops
open GlobEnv
open Evarconv
module NamedDecl = Context.Named.Declaration
type typing_constraint = IsType | OfType of types | WithoutTypeConstraint
let (!!) env = GlobEnv.env env
let bidi_hints =
Summary.ref (GlobRef.Map.empty : int GlobRef.Map.t) ~name:"bidirectionalityhints"
let add_bidirectionality_hint gr n =
bidi_hints := GlobRef.Map.add gr n !bidi_hints
let get_bidirectionality_hint gr =
GlobRef.Map.find_opt gr !bidi_hints
let clear_bidirectionality_hint gr =
bidi_hints := GlobRef.Map.remove gr !bidi_hints
open Inductive
open Inductiveops
exception Found of int array
let nf_fix sigma (nas, cs, ts) =
let inj c = EConstr.to_constr ~abort_on_undefined_evars:false sigma c in
(nas, Array.map inj cs, Array.map inj ts)
let search_guard ?loc env possible_indexes fixdefs =
let is_singleton = function [_] -> true | _ -> false in
if List.for_all is_singleton possible_indexes then
let indexes = Array.of_list (List.map List.hd possible_indexes) in
let fix = ((indexes, 0),fixdefs) in
(try check_fix env fix
with reraise ->
let (e, info) = Exninfo.capture reraise in
let info = Option.cata (fun loc -> Loc.add_loc info loc) info loc in
Exninfo.iraise (e, info));
indexes
else
let combinations = List.combinations possible_indexes in
if List.is_empty combinations then
user_err ?loc (Pp.str "A fixpoint needs at least one parameter.");
(try
List.iter
(fun l ->
let indexes = Array.of_list l in
let fix = ((indexes, 0),fixdefs) in
try
let flags = { (typing_flags env) with Declarations.check_guarded = true } in
let env = Environ.set_typing_flags flags env in
check_fix env fix; raise (Found indexes)
with TypeError _ -> ())
combinations;
let errmsg = "Cannot guess decreasing argument of fix." in
user_err ?loc (Pp.str errmsg)
with Found indexes -> indexes)
let esearch_guard ?loc env sigma indexes fix =
let fix = nf_fix sigma fix in
try search_guard ?loc env indexes fix
with TypeError (env,err) ->
raise (PretypeError (env,sigma,TypingError (map_ptype_error of_constr err)))
let { Goptions.get = is_strict_universe_declarations } =
Goptions.declare_bool_option_and_ref
~key:["Strict";"Universe";"Declaration"]
~value:true
()
(** Miscellaneous interpretation functions *)
let universe_level_name evd ({CAst.v=id} as lid) =
try evd, Evd.universe_of_name evd id
with Not_found ->
if not (is_strict_universe_declarations ()) then
new_univ_level_variable ?loc:lid.CAst.loc ~name:id univ_rigid evd
else user_err ?loc:lid.CAst.loc
(Pp.(str "Undeclared universe: " ++ Id.print id ++ str "."))
let level_name sigma = function
| GSProp | GProp -> None
| GSet -> Some (sigma, Univ.Level.set)
| GUniv u -> Some (sigma, u)
| GRawUniv u ->
let sigma = try Evd.add_global_univ sigma u with UGraph.AlreadyDeclared -> sigma in
Some (sigma, u)
| GLocalUniv l ->
let sigma, u = universe_level_name sigma l in
Some (sigma, u)
let glob_level ?loc evd : glob_level -> _ = function
| UAnonymous {rigid} ->
assert (rigid <> UnivFlexible true);
new_univ_level_variable ?loc rigid evd
| UNamed s ->
match level_name evd s with
| None ->
user_err ?loc
(str "Universe instances cannot contain non-Set small levels," ++ spc() ++
str "polymorphic universe instances must be greater or equal to Set.");
| Some r -> r
let glob_qvar ?loc evd : glob_qvar -> _ = function
| GQVar q -> evd, q
| GLocalQVar {v=Anonymous} ->
let evd, q = new_quality_variable ?loc evd in
evd, q
| GRawQVar q ->
let evd = Evd.merge_sort_variables ~sideff:true evd (Sorts.QVar.Set.singleton q) in
evd, q
| GLocalQVar {v=Name id; loc} ->
try evd, (Evd.quality_of_name evd id)
with Not_found ->
if not (is_strict_universe_declarations()) then
let evd, q = new_quality_variable ?loc evd in
evd, q
else user_err ?loc Pp.(str "Undeclared quality: " ++ Id.print id ++ str".")
let glob_quality ?loc evd = let open Sorts.Quality in function
| GQConstant q -> evd, QConstant q
| GQualVar (GQVar _ | GLocalQVar _ | GRawQVar _ as q) ->
let evd, q = glob_qvar ?loc evd q in
evd, QVar q
let sort_info ?loc sigma q l = match l with
| [] -> assert false
| [GSProp, 0] -> assert (Option.is_empty q); sigma, Sorts.sprop
| [GProp, 0] -> assert (Option.is_empty q); sigma, Sorts.prop
| (u, n) :: us ->
let open Pp in
let sigma, q = match q with
| None -> sigma, None
| Some q ->
let sigma, q = glob_qvar ?loc sigma q in
sigma, Some q
in
let get_level sigma u n = match level_name sigma u with
| None ->
user_err ?loc
(str "Non-Set small universes cannot be used in algebraic expressions.")
| Some (sigma, u) ->
let u = Univ.Universe.make u in
let u = match n with
| 0 -> u
| 1 -> Univ.Universe.super u
| n ->
user_err ?loc
(str "Cannot interpret universe increment +" ++ int n ++ str ".")
in
(sigma, u)
in
let fold (sigma, u) (l, n) =
let sigma, u' = get_level sigma l n in
(sigma, Univ.Universe.sup u u')
in
let (sigma, u) = get_level sigma u n in
let (sigma, u) = List.fold_left fold (sigma, u) us in
let s = match q with
| None -> Sorts.sort_of_univ u
| Some q -> Sorts.qsort q u
in
sigma, s
type inference_hook = env -> evar_map -> Evar.t -> (evar_map * constr) option
type use_typeclasses = NoUseTC | UseTCForConv | UseTC
type inference_flags = {
use_coercions : bool;
use_typeclasses : use_typeclasses;
solve_unification_constraints : bool;
fail_evar : bool;
expand_evars : bool;
program_mode : bool;
polymorphic : bool;
}
type pretype_flags = {
poly : bool;
resolve_tc : bool;
program_mode : bool;
use_coercions : bool;
}
type frozen_and_pending =
Frz :
'a Evar.Map.t
* Evar.Set.t Lazy.t option
-> frozen_and_pending
let frozen_and_pending_holes (sigma, sigma') =
let undefined0 = Option.cata Evd.undefined_map Evar.Map.empty sigma in
let pending =
if undefined0 == Evd.undefined_map sigma'
then None
else
Some (lazy begin
let pending, aliases =
Evar.Map.symmetric_diff_fold (fun ev v v' (pending,aliases as acc) -> match v, v' with
| None, None -> assert false
| Some _, None ->
begin match advance sigma' ev with
| None -> acc
| Some ev -> pending, Evar.Set.add ev aliases
end
| None, Some _ ->
Evar.Set.add ev pending, aliases
| Some _, Some _ -> acc)
undefined0
(Evd.undefined_map sigma')
(Evar.Set.empty, Evar.Set.empty)
in
Evar.Set.diff pending aliases;
end)
in
Frz (Evd.undefined_map sigma', pending)
let filter_frozen frozen = match frozen with
| Frz (undf, None) -> fun evk -> Evar.Map.mem evk undf
| Frz (undf, Some (lazy pending)) -> fun evk -> not (Evar.Set.mem evk pending) && Evar.Map.mem evk undf
let typeclasses_filter ~program_mode frozen =
if program_mode
then (fun evk evi -> Typeclasses.no_goals_or_obligations evk evi && not (filter_frozen frozen evk))
else (fun evk evi -> Typeclasses.no_goals evk evi && not (filter_frozen frozen evk))
let apply_typeclasses ~program_mode ~fail_evar env sigma frozen =
let sigma = Typeclasses.resolve_typeclasses
~filter:(typeclasses_filter ~program_mode frozen)
~fail:fail_evar env sigma in
let sigma = if program_mode then
Typeclasses.resolve_typeclasses
~filter:(fun evk evi -> Typeclasses.all_evars evk evi && not (filter_frozen frozen evk)) ~fail:false env sigma
else sigma in
sigma
let apply_inference_hook (hook : inference_hook) env sigma frozen = match frozen with
| Frz (_, None) -> sigma
| Frz (_, Some (lazy pending)) ->
Evar.Set.fold (fun evk sigma ->
if Evd.is_undefined sigma evk
then
match hook env sigma evk with
| Some (sigma, c) ->
Evd.define evk c sigma
| None -> sigma
else
sigma) pending sigma
let apply_heuristics env sigma =
let flags = default_flags_of (Conv_oracle.get_transp_state (Environ.oracle env)) in
try solve_unif_constraints_with_heuristics ~flags env sigma
with e when CErrors.noncritical e -> sigma
let check_typeclasses_instances_are_solved ~program_mode env sigma frozen =
let tcs = Typeclasses.get_filtered_typeclass_evars
(typeclasses_filter ~program_mode frozen)
sigma
in
if not (Evar.Set.is_empty tcs) then begin
Typeclasses.error_unresolvable env sigma tcs
end
let env current_sigma frozen = match frozen with
| Frz (_, None) -> ()
| Frz (_, Some (lazy pending)) ->
Evar.Set.iter
(fun evk ->
if not (Evd.is_defined current_sigma evk) then
let (loc,k) = evar_source (Evd.find_undefined current_sigma evk) in
match k with
| Evar_kinds.ImplicitArg (gr, (i, id), false) -> ()
| _ ->
error_unsolvable_implicit ?loc env current_sigma evk None) pending
let check_evars env ?initial sigma c =
let rec proc_rec c =
match EConstr.kind sigma c with
| Evar (evk, _) ->
(match initial with
| Some initial when Evd.mem initial evk -> ()
| _ ->
let EvarInfo evi = Evd.find sigma evk in
let (loc,k) = evar_source evi in
begin match k with
| Evar_kinds.ImplicitArg (gr, (i, id), false) -> ()
| _ -> Pretype_errors.error_unsolvable_implicit ?loc env sigma evk None
end)
| _ -> EConstr.iter sigma proc_rec c
in proc_rec c
let check_evars_are_solved ~program_mode env sigma frozen =
check_typeclasses_instances_are_solved ~program_mode env sigma frozen;
check_problems_are_solved env sigma;
check_extra_evars_are_solved env sigma frozen
let solve_remaining_evars ?hook (flags : inference_flags) env ?initial sigma =
let program_mode = flags.program_mode in
let frozen = frozen_and_pending_holes (initial, sigma) in
let sigma =
match flags.use_typeclasses with
| UseTC -> apply_typeclasses ~program_mode ~fail_evar:false env sigma frozen
| NoUseTC | UseTCForConv -> sigma
in
let frozen = frozen_and_pending_holes (initial, sigma) in
let sigma = match hook with
| None -> sigma
| Some hook -> apply_inference_hook hook env sigma frozen
in
let sigma = if flags.solve_unification_constraints
then apply_heuristics env sigma
else sigma
in
if flags.fail_evar then check_evars_are_solved ~program_mode env sigma frozen;
sigma
let check_evars_are_solved ~program_mode env ?initial current_sigma =
let frozen = frozen_and_pending_holes (initial, current_sigma) in
check_evars_are_solved ~program_mode env current_sigma frozen
let process_inference_flags flags env initial (sigma,c,cty) =
let sigma = solve_remaining_evars flags env ~initial sigma in
let c = if flags.expand_evars then nf_evar sigma c else c in
sigma,c,cty
let adjust_evar_source sigma na c =
match na, kind sigma c with
| Name id, Evar (evk,args) ->
let evi = Evd.find_undefined sigma evk in
begin match Evd.evar_source evi with
| loc, Evar_kinds.QuestionMark ({ Evar_kinds.qm_name=Anonymous } as qm) ->
let src = (loc,Evar_kinds.QuestionMark { qm with Evar_kinds.qm_name=na }) in
let (sigma, evk') = Evd.restrict evk (evar_filter evi) ~src sigma in
sigma, mkEvar (evk',args)
| _ -> sigma, c
end
| _, _ -> sigma, c
let inh_conv_coerce_to_tycon ?loc ~flags:{ program_mode; resolve_tc; use_coercions } env sigma j = function
| None -> sigma, j, Some Coercion.empty_coercion_trace
| Some t ->
Coercion.inh_conv_coerce_to ?loc ~program_mode ~resolve_tc ~use_coercions !!env sigma j t
let check_instance subst = function
| [] -> ()
| (CAst.{loc;v=id},_) :: _ ->
if List.mem_assoc id subst then
user_err ?loc (Id.print id ++ str "appears more than once.")
else
user_err ?loc (str "No such variable in the signature of the existential variable: " ++ Id.print id ++ str ".")
let orelse_name name name' = match name with
| Anonymous -> name'
| _ -> name
let pretype_id pretype loc env sigma id =
try
let (n,_,typ) = lookup_rel_id id (rel_context !!env) in
sigma, { uj_val = mkRel n; uj_type = lift n typ }
with Not_found ->
try
GlobEnv.interp_ltac_variable ?loc (fun env -> pretype env sigma) env sigma id
with Not_found ->
try
sigma, { uj_val = mkVar id; uj_type = NamedDecl.get_type (lookup_named id !!env) }
with Not_found ->
error_var_not_found ?loc !!env sigma id
let instance ?loc evd (ql,ul) =
let evd, ql' =
List.fold_left
(fun (evd, quals) l ->
let evd, l = glob_quality ?loc evd l in
(evd, l :: quals)) (evd, [])
ql
in
let evd, ul' =
List.fold_left
(fun (evd, univs) l ->
let evd, l = glob_level ?loc evd l in
(evd, l :: univs)) (evd, [])
ul
in
evd, Some (UVars.Instance.of_array (Array.rev_of_list ql', Array.rev_of_list ul'))
let pretype_global ?loc rigid env evd gr us =
let evd, instance =
match us with
| None -> evd, None
| Some l -> instance ?loc evd l
in
Evd.fresh_global ?loc ~rigid ?names:instance !!env evd gr
let pretype_ref ?loc sigma env ref us =
match ref with
| GlobRef.VarRef id ->
(try
let ty = NamedDecl.get_type (lookup_named id !!env) in
(match us with
| None | Some ([],[]) -> ()
| Some (qs,us) ->
let open UnivGen in
Loc.raise ?loc (UniverseLengthMismatch {
actual = List.length qs, List.length us;
expect = 0, 0;
}));
sigma, make_judge (mkVar id) ty
with Not_found ->
Pretype_errors.error_var_not_found ?loc !!env sigma id)
| ref ->
let sigma, c = pretype_global ?loc univ_flexible env sigma ref us in
let sigma, ty = type_of !!env sigma c in
sigma, make_judge c ty
let sort ?loc evd : glob_sort -> _ = function
| UAnonymous {rigid} ->
let evd, l = new_univ_level_variable ?loc rigid evd in
evd, ESorts.make (Sorts.sort_of_univ (Univ.Universe.make l))
| UNamed (q, l) ->
let evd, s = sort_info ?loc evd q l in
evd, ESorts.make s
let judge_of_sort ?loc evd s =
let judge =
{ uj_val = mkSort s; uj_type = mkSort (ESorts.super evd s) }
in
evd, judge
let pretype_sort ?loc sigma s =
match s with
| UNamed (None, [GSProp, 0]) -> sigma, judge_of_sprop
| UNamed (None, [GProp, 0]) -> sigma, judge_of_prop
| UNamed (None, [GSet, 0]) -> sigma, judge_of_set
| _ ->
let sigma, s = sort ?loc sigma s in
judge_of_sort ?loc sigma s
let new_typed_evar env sigma ?naming ~src tycon =
match tycon with
| Some ty ->
let sigma, c = new_evar env sigma ~src ?naming ty in
sigma, c, ty
| None ->
let sigma, ty = new_type_evar env sigma ~src in
let sigma, c = new_evar env sigma ~src ?naming ty in
let evk = fst (destEvar sigma c) in
let ido = Evd.evar_ident evk sigma in
let src = (fst src,Evar_kinds.EvarType (ido,evk)) in
let sigma = update_source sigma (fst (destEvar sigma ty)) src in
sigma, c, ty
let mark_obligation_evar sigma k evc =
match k with
| Evar_kinds.QuestionMark _
| Evar_kinds.ImplicitArg (_, _, false) ->
Evd.set_obligation_evar sigma (fst (destEvar sigma evc))
| _ -> sigma
type 'a pretype_fun = ?loc:Loc.t -> flags:pretype_flags -> type_constraint -> GlobEnv.t -> evar_map -> evar_map * 'a
type pretyper = {
pretype_ref : pretyper -> GlobRef.t * glob_instance option -> unsafe_judgment pretype_fun;
pretype_var : pretyper -> Id.t -> unsafe_judgment pretype_fun;
pretype_evar : pretyper -> existential_name CAst.t * (lident * glob_constr) list -> unsafe_judgment pretype_fun;
pretype_patvar : pretyper -> Evar_kinds.matching_var_kind -> unsafe_judgment pretype_fun;
pretype_app : pretyper -> glob_constr * glob_constr list -> unsafe_judgment pretype_fun;
pretype_proj : pretyper -> (Constant.t * glob_instance option) * glob_constr list * glob_constr -> unsafe_judgment pretype_fun;
pretype_lambda : pretyper -> Name.t * binding_kind * glob_constr * glob_constr -> unsafe_judgment pretype_fun;
pretype_prod : pretyper -> Name.t * binding_kind * glob_constr * glob_constr -> unsafe_judgment pretype_fun;
pretype_letin : pretyper -> Name.t * glob_constr * glob_constr option * glob_constr -> unsafe_judgment pretype_fun;
pretype_cases : pretyper -> Constr.case_style * glob_constr option * tomatch_tuples * cases_clauses -> unsafe_judgment pretype_fun;
pretype_lettuple : pretyper -> Name.t list * (Name.t * glob_constr option) * glob_constr * glob_constr -> unsafe_judgment pretype_fun;
pretype_if : pretyper -> glob_constr * (Name.t * glob_constr option) * glob_constr * glob_constr -> unsafe_judgment pretype_fun;
pretype_rec : pretyper -> glob_fix_kind * Id.t array * glob_decl list array * glob_constr array * glob_constr array -> unsafe_judgment pretype_fun;
pretype_sort : pretyper -> glob_sort -> unsafe_judgment pretype_fun;
pretype_hole : pretyper -> Evar_kinds.glob_evar_kind -> unsafe_judgment pretype_fun;
pretype_genarg : pretyper -> Genarg.glob_generic_argument -> unsafe_judgment pretype_fun;
pretype_cast : pretyper -> glob_constr * cast_kind option * glob_constr -> unsafe_judgment pretype_fun;
pretype_int : pretyper -> Uint63.t -> unsafe_judgment pretype_fun;
pretype_float : pretyper -> Float64.t -> unsafe_judgment pretype_fun;
pretype_array : pretyper -> glob_instance option * glob_constr array * glob_constr * glob_constr -> unsafe_judgment pretype_fun;
pretype_type : pretyper -> glob_constr -> unsafe_type_judgment pretype_fun;
}
(** Tie the loop *)
let eval_pretyper self ~flags tycon env sigma t =
let loc = t.CAst.loc in
match DAst.get t with
| GRef (ref,u) ->
self.pretype_ref self (ref, u) ?loc ~flags tycon env sigma
| GVar id ->
self.pretype_var self id ?loc ~flags tycon env sigma
| GEvar (evk, args) ->
self.pretype_evar self (evk, args) ?loc ~flags tycon env sigma
| GPatVar knd ->
self.pretype_patvar self knd ?loc ~flags tycon env sigma
| GApp (c, args) ->
self.pretype_app self (c, args) ?loc ~flags tycon env sigma
| GProj (hd, args, c) ->
self.pretype_proj self (hd, args, c) ?loc ~flags tycon env sigma
| GLambda (na, bk, t, c) ->
self.pretype_lambda self (na, bk, t, c) ?loc ~flags tycon env sigma
| GProd (na, bk, t, c) ->
self.pretype_prod self (na, bk, t, c) ?loc ~flags tycon env sigma
| GLetIn (na, b, t, c) ->
self.pretype_letin self (na, b, t, c) ?loc ~flags tycon env sigma
| GCases (st, c, tm, cl) ->
self.pretype_cases self (st, c, tm, cl) ?loc ~flags tycon env sigma
| GLetTuple (na, b, t, c) ->
self.pretype_lettuple self (na, b, t, c) ?loc ~flags tycon env sigma
| GIf (c, r, t1, t2) ->
self.pretype_if self (c, r, t1, t2) ?loc ~flags tycon env sigma
| GRec (knd, nas, decl, c, t) ->
self.pretype_rec self (knd, nas, decl, c, t) ?loc ~flags tycon env sigma
| GSort s ->
self.pretype_sort self s ?loc ~flags tycon env sigma
| GHole knd ->
self.pretype_hole self knd ?loc ~flags tycon env sigma
| GGenarg arg ->
self.pretype_genarg self arg ?loc ~flags tycon env sigma
| GCast (c, k, t) ->
self.pretype_cast self (c, k, t) ?loc ~flags tycon env sigma
| GInt n ->
self.pretype_int self n ?loc ~flags tycon env sigma
| GFloat f ->
self.pretype_float self f ?loc ~flags tycon env sigma
| GArray (u,t,def,ty) ->
self.pretype_array self (u,t,def,ty) ?loc ~flags tycon env sigma
let eval_type_pretyper self ~flags tycon env sigma t =
self.pretype_type self t ~flags tycon env sigma
let pretype_instance self ~flags env sigma loc hyps evk update =
let f decl (subst,update,sigma) =
let id = NamedDecl.get_id decl in
let b = Option.map (replace_vars sigma subst) (NamedDecl.get_value decl) in
let t = replace_vars sigma subst (NamedDecl.get_type decl) in
let check_body sigma id c =
match b, c with
| Some b, Some c ->
if not (is_conv !!env sigma b c) then
user_err ?loc (str "Cannot interpret " ++
pr_existential_key !!env sigma evk ++
strbrk " in current context: binding for " ++ Id.print id ++
strbrk " is not convertible to its expected definition (cannot unify " ++
quote (Termops.Internal.print_constr_env !!env sigma b) ++
strbrk " and " ++
quote (Termops.Internal.print_constr_env !!env sigma c) ++
str ").")
| Some b, None ->
user_err ?loc (str "Cannot interpret " ++
pr_existential_key !!env sigma evk ++
strbrk " in current context: " ++ Id.print id ++
strbrk " should be bound to a local definition.")
| None, _ -> () in
let check_type sigma id t' =
if not (is_conv !!env sigma t t') then
user_err ?loc (str "Cannot interpret " ++
pr_existential_key !!env sigma evk ++
strbrk " in current context: binding for " ++ Id.print id ++
strbrk " is not well-typed.") in
let sigma, c, update =
try
let c = snd (List.find (fun (CAst.{v=id'},c) -> Id.equal id id') update) in
let sigma, c = eval_pretyper self ~flags (mk_tycon t) env sigma c in
check_body sigma id (Some c.uj_val);
sigma, c.uj_val, List.remove_first (fun (CAst.{v=id'},_) -> Id.equal id id') update
with Not_found ->
try
let (n,b',t') = lookup_rel_id id (rel_context !!env) in
check_type sigma id (lift n t');
check_body sigma id (Option.map (lift n) b');
sigma, mkRel n, update
with Not_found ->
try
let decl = lookup_named id !!env in
check_type sigma id (NamedDecl.get_type decl);
check_body sigma id (NamedDecl.get_value decl);
sigma, mkVar id, update
with Not_found ->
user_err ?loc (str "Cannot interpret " ++
pr_existential_key !!env sigma evk ++
str " in current context: no binding for " ++ Id.print id ++ str ".") in
((id,c)::subst, update, sigma) in
let subst,inst,sigma = List.fold_right f hyps ([],update,sigma) in
check_instance subst inst;
sigma, List.map snd subst
module Default =
struct
let discard_trace (sigma,t,otrace) = sigma, t
let pretype_ref self (ref, u) =
fun ?loc ~flags tycon env sigma ->
let sigma, t_ref = pretype_ref ?loc sigma env ref u in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma t_ref tycon
let pretype_var self id =
fun ?loc ~flags tycon env sigma ->
let pretype tycon env sigma t = eval_pretyper self ~flags tycon env sigma t in
let sigma, t_id = pretype_id (fun e r t -> pretype tycon e r t) loc env sigma id in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma t_id tycon
let pretype_evar self (CAst.{v=id;loc=locid}, inst) ?loc ~flags tycon env sigma =
let id = interp_ltac_id env id in
let evk =
try Evd.evar_key id sigma
with Not_found -> error_evar_not_found ?loc:locid !!env sigma id in
let EvarInfo evi = Evd.find sigma evk in
let hyps = evar_filtered_context evi in
let sigma, args = pretype_instance self ~flags env sigma loc hyps evk inst in
let c = mkLEvar sigma (evk, args) in
let j = Retyping.get_judgment_of !!env sigma c in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma j tycon
let pretype_patvar self kind ?loc ~flags tycon env sigma =
let k = Evar_kinds.MatchingVar kind in
let sigma, uj_val, uj_type = new_typed_evar env sigma ~src:(loc,k) tycon in
sigma, { uj_val; uj_type }
let pretype_hole self k ?loc ~flags tycon env sigma =
let open Namegen in
let naming = naming_of_glob_kind k in
let naming = match naming with
| IntroIdentifier id -> IntroIdentifier (interp_ltac_id env id)
| IntroAnonymous -> IntroAnonymous
| IntroFresh id -> IntroFresh (interp_ltac_id env id) in
let k = kind_of_glob_kind k in
let sigma, uj_val, uj_type = new_typed_evar env sigma ~src:(loc,k) ~naming tycon in
let sigma = if flags.program_mode then mark_obligation_evar sigma k uj_val else sigma in
sigma, { uj_val; uj_type }
let pretype_genarg self arg ?loc ~flags tycon env sigma =
let j, sigma = GlobEnv.interp_glob_genarg ?loc ~poly:flags.poly env sigma tycon arg in
sigma, j
let pretype_rec self (fixkind, names, bl, lar, vdef) =
fun ?loc ~flags tycon env sigma ->
let open Context.Rel.Declaration in
let pretype tycon env sigma c = eval_pretyper self ~flags tycon env sigma c in
let pretype_type tycon env sigma c = eval_type_pretyper self ~flags tycon env sigma c in
let vars = VarSet.variables (Global.env ()) in
let hypnaming = if flags.program_mode then ProgramNaming vars else RenameExistingBut vars in
let rec type_bl env sigma ctxt = function
| [] -> sigma, ctxt
| (na,bk,None,ty)::bl ->
let sigma, ty' = pretype_type empty_valcon env sigma ty in
let rty' = ESorts.relevance_of_sort sigma ty'.utj_type in
let dcl = LocalAssum (make_annot na rty', ty'.utj_val) in
let dcl', env = push_rel ~hypnaming sigma dcl env in
type_bl env sigma (Context.Rel.add dcl' ctxt) bl
| (na,bk,Some bd,ty)::bl ->
let sigma, ty' = pretype_type empty_valcon env sigma ty in
let rty' = ESorts.relevance_of_sort sigma ty'.utj_type in
let sigma, bd' = pretype (mk_tycon ty'.utj_val) env sigma bd in
let dcl = LocalDef (make_annot na rty', bd'.uj_val, ty'.utj_val) in
let dcl', env = push_rel ~hypnaming sigma dcl env in
type_bl env sigma (Context.Rel.add dcl' ctxt) bl in
let sigma, ctxtv = Array.fold_left_map (fun sigma -> type_bl env sigma Context.Rel.empty) sigma bl in
let sigma, larj =
Array.fold_left2_map
(fun sigma e ar ->
pretype_type empty_valcon (snd (push_rel_context ~hypnaming sigma e env)) sigma ar)
sigma ctxtv lar in
let lara = Array.map (fun a -> a.utj_val) larj in
let ftys = Array.map2 (fun e a -> it_mkProd_or_LetIn a e) ctxtv lara in
let nbfix = Array.length lar in
let names = Array.map (fun id -> Name id) names in
let sigma =
match tycon with
| Some t ->
let fixi = match fixkind with
| GFix (vn,i) -> i
| GCoFix i -> i
in
begin match Evarconv.unify_delay !!env sigma ftys.(fixi) t with
| exception Evarconv.UnableToUnify _ -> sigma
| sigma -> sigma
end
| None -> sigma
in
let names = Array.map2 (fun na t ->
make_annot na (Retyping.relevance_of_type !!(env) sigma t))
names ftys
in
let names,newenv = push_rec_types ~hypnaming sigma (names,ftys) env in
let sigma, vdefj =
Array.fold_left2_map_i
(fun i sigma ctxt def ->
let (ctxt,ty) =
decompose_prod_n_decls sigma (Context.Rel.length ctxt)
(lift nbfix ftys.(i)) in
let ctxt,nenv = push_rel_context ~hypnaming sigma ctxt newenv in
let sigma, j = pretype (mk_tycon ty) nenv sigma def in
sigma, { uj_val = it_mkLambda_or_LetIn j.uj_val ctxt;
uj_type = it_mkProd_or_LetIn j.uj_type ctxt })
sigma ctxtv vdef in
let sigma = Typing.check_type_fixpoint ?loc !!env sigma names ftys vdefj in
let nf c = nf_evar sigma c in
let ftys = Array.map nf ftys in
let fdefs = Array.map (fun x -> nf (j_val x)) vdefj in
let fixj = match fixkind with
| GFix (vn,i) ->
let possible_indexes =
Array.to_list (Array.mapi
(fun i annot -> match annot with
| Some n -> [n]
| None -> List.interval 0 (Context.Rel.nhyps ctxtv.(i) - 1))
vn)
in
let fixdecls = (names,ftys,fdefs) in
let indexes = esearch_guard ?loc !!env sigma possible_indexes fixdecls in
make_judge (mkFix ((indexes,i),fixdecls)) ftys.(i)
| GCoFix i ->
let fixdecls = (names,ftys,fdefs) in
let cofix = (i, fixdecls) in
(try check_cofix !!env (i, nf_fix sigma fixdecls)
with reraise ->
let (e, info) = Exninfo.capture reraise in
let info = Option.cata (Loc.add_loc info) info loc in
Exninfo.iraise (e, info));
make_judge (mkCoFix cofix) ftys.(i)
in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma fixj tycon
let pretype_sort self s =
fun ?loc ~flags tycon env sigma ->
let sigma, j = pretype_sort ?loc sigma s in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma j tycon
let pretype_app self (f, args) =
fun ?loc ~flags tycon env sigma ->
let pretype tycon env sigma c = eval_pretyper self ~flags tycon env sigma c in
let sigma, fj = pretype empty_tycon env sigma f in
let floc = loc_of_glob_constr f in
let length = List.length args in
let nargs_before_bidi =
if Option.is_empty tycon then length
else
try
let (gr,_) = destRef sigma fj.uj_val in
Option.default length @@ get_bidirectionality_hint gr
with DestKO ->
length
in
let candargs =
if flags.program_mode && length > 0 && isConstruct sigma fj.uj_val then
match tycon with
| None -> []
| Some ty ->
let ((ind, i), u) = destConstruct sigma fj.uj_val in
let npars = inductive_nparams !!env ind in
if Int.equal npars 0 then []
else
try
let IndType (indf, args) = find_rectype !!env sigma ty in
let ((ind',u'),pars) = dest_ind_family indf in
if QInd.equal !!env ind ind' then List.map EConstr.of_constr pars
else []
with Not_found -> []
else []
in
let refresh_template env sigma resj =
match EConstr.kind sigma resj.uj_val with
| App (f,args) ->
if Termops.is_template_polymorphic_ind !!env sigma f then
let c = mkApp (f, args) in
let sigma, c = Evarsolve.refresh_universes (Some true) !!env sigma c in
let t = Retyping.get_type_of !!env sigma c in
sigma, make_judge c t
else sigma, resj
| _ -> sigma, resj
in
let rec apply_rec env sigma n body (subs, typ) val_before_bidi candargs bidiargs = function
| [] ->
let typ = Vars.esubst Vars.lift_substituend subs typ in
let body = Coercion.force_app_body body in
let resj = { uj_val = body; uj_type = typ } in
sigma, resj, val_before_bidi, List.rev bidiargs
| c::rest ->
let bidi = n >= nargs_before_bidi in
let argloc = loc_of_glob_constr c in
let sigma, body, na, c1, subs, c2, trace = match EConstr.kind sigma typ with
| Prod (na, c1, c2) ->
let c1 = Vars.esubst Vars.lift_substituend subs c1 in
sigma, body, na, c1, subs, c2, Coercion.empty_coercion_trace
| _ ->
let typ = Vars.esubst Vars.lift_substituend subs typ in
let sigma, body, typ, trace = Coercion.inh_app_fun ~program_mode:flags.program_mode ~resolve_tc:flags.resolve_tc ~use_coercions:flags.use_coercions !!env sigma body typ in
let resty = whd_all !!env sigma typ in
let na, c1, c2 = match EConstr.kind sigma resty with
| Prod (na, c1, c2) -> (na, c1, c2)
| _ ->
let sigma, hj = pretype empty_tycon env sigma c in
let resj = { uj_val = Coercion.force_app_body body; uj_type = typ } in
error_cant_apply_not_functional
?loc:(Loc.merge_opt floc argloc) !!env sigma resj [|hj|]
in
sigma, body, na, c1, Esubst.subs_id 0, c2, trace
in
let (sigma, hj), bidiargs =
if bidi then
let sigma, c_hole = new_evar env sigma ~src:(loc,Evar_kinds.InternalHole) c1 in
(sigma, make_judge c_hole c1), (c_hole, c1, c, trace) :: bidiargs
else
let tycon = Some c1 in
pretype tycon env sigma c, bidiargs
in
let sigma, candargs, ujval =
match candargs with
| [] -> sigma, [], j_val hj
| arg :: args ->
begin match Evarconv.unify_delay !!env sigma (j_val hj) arg with
| exception Evarconv.UnableToUnify (sigma,e) ->
raise (PretypeError (!!env,sigma,CannotUnify (j_val hj, arg, Some e)))
| sigma ->
sigma, args, nf_evar sigma (j_val hj)
end
in
let sigma, ujval = adjust_evar_source sigma na.binder_name ujval in
let subs = Esubst.subs_cons (Vars.make_substituend ujval) subs in
let body = Coercion.push_arg body ujval in
let val_before_bidi = if bidi then val_before_bidi else body in
apply_rec env sigma (n+1) body (subs, c2) val_before_bidi candargs bidiargs rest
in
let typ = (Esubst.subs_id 0, fj.uj_type) in
let body = (Coercion.start_app_body sigma fj.uj_val) in
let sigma, resj, val_before_bidi, bidiargs =
apply_rec env sigma 0 body typ body candargs [] args
in
let sigma, resj = refresh_template env sigma resj in
let sigma, resj, otrace = inh_conv_coerce_to_tycon ?loc ~flags env sigma resj tycon in
let refine_arg n (sigma,t) (newarg,ty,origarg,trace) =
let sigma, j = pretype (Some ty) env sigma origarg in
let sigma = try Evarconv.unify_delay !!env sigma newarg (j_val j)
with Evarconv.UnableToUnify (sigma,e) ->
raise (PretypeError (!!env,sigma,CannotUnify (newarg,j_val j,Some e)))
in
sigma, Coercion.push_arg (Coercion.reapply_coercions_body sigma trace t) (j_val j)
in
let t = val_before_bidi in
let sigma, t = List.fold_left_i refine_arg nargs_before_bidi (sigma,t) bidiargs in
let t = Coercion.force_app_body t in
let resj =
match otrace with
| None -> resj
| Some trace ->
let resj = { resj with uj_val = t } in
let sigma, resj = refresh_template env sigma resj in
{ resj with uj_val = Coercion.reapply_coercions sigma trace t }
in
(sigma, resj)
let pretype_proj self ((f,us), args, c) =
fun ?loc ~flags tycon env sigma ->
pretype_app self (DAst.make ?loc (GRef (GlobRef.ConstRef f,us)), args @ [c])
?loc ~flags tycon env sigma
let pretype_lambda self (name, bk, c1, c2) =
fun ?loc ~flags tycon env sigma ->
let open Context.Rel.Declaration in
let tycon' = if flags.program_mode && flags.use_coercions
then Option.map (Coercion.remove_subset !!env sigma) tycon
else tycon
in
let sigma,name',dom,rng =
match tycon' with
| None -> sigma,Anonymous, None, None
| Some ty ->
let sigma, ty = Evardefine.presplit !!env sigma ty in
match EConstr.kind sigma ty with
| Prod (na,dom,rng) ->
sigma, na.binder_name, Some dom, Some rng
| Evar ev ->
let s = Retyping.get_sort_of !!env sigma ty in
if Environ.is_impredicative_sort !!env (ESorts.kind sigma s)
|| Evd.check_leq sigma ESorts.type1 s
then
let sigma, prod = define_evar_as_product !!env sigma ev in
let na,dom,rng = destProd sigma prod in
sigma, na.binder_name, Some dom, Some rng
else
sigma, Anonymous, None, None
| _ ->
if Reductionops.is_head_evar !!env sigma ty then sigma, Anonymous, None, None
else
error_not_product ?loc !!env sigma ty
in
let dom_valcon = valcon_of_tycon dom in
let sigma, j = eval_type_pretyper self ~flags dom_valcon env sigma c1 in
let name = {binder_name=name; binder_relevance=ESorts.relevance_of_sort sigma j.utj_type} in
let var = LocalAssum (name, j.utj_val) in
let vars = VarSet.variables (Global.env ()) in
let hypnaming = if flags.program_mode then ProgramNaming vars else RenameExistingBut vars in
let var',env' = push_rel ~hypnaming sigma var env in
let sigma, j' = eval_pretyper self ~flags rng env' sigma c2 in
let name = get_name var' in
let resj = judge_of_abstraction !!env sigma (orelse_name name name') j j' in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma resj tycon
let pretype_prod self (name, bk, c1, c2) =
fun ?loc ~flags tycon env sigma ->
let open Context.Rel.Declaration in
let pretype_type tycon env sigma c = eval_type_pretyper self ~flags tycon env sigma c in
let sigma, j = pretype_type empty_valcon env sigma c1 in
let vars = VarSet.variables (Global.env ()) in
let hypnaming = if flags.program_mode then ProgramNaming vars else RenameExistingBut vars in
let sigma, name, j' = match name with
| Anonymous ->
let sigma, j = pretype_type empty_valcon env sigma c2 in
sigma, name, { j with utj_val = lift 1 j.utj_val }
| Name _ ->
let r = ESorts.relevance_of_sort sigma j.utj_type in
let var = LocalAssum (make_annot name r, j.utj_val) in
let var, env' = push_rel ~hypnaming sigma var env in
let sigma, c2_j = pretype_type empty_valcon env' sigma c2 in
sigma, get_name var, c2_j
in
let resj =
try
judge_of_product !!env sigma name j j'
with TypeError _ as e ->
let (e, info) = Exninfo.capture e in
let info = Option.cata (Loc.add_loc info) info loc in
Exninfo.iraise (e, info) in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma resj tycon
let pretype_letin self (name, c1, t, c2) =
fun ?loc ~flags tycon env sigma ->
let open Context.Rel.Declaration in
let pretype tycon env sigma c = eval_pretyper self ~flags tycon env sigma c in
let pretype_type tycon env sigma c = eval_type_pretyper self ~flags tycon env sigma c in
let sigma, tycon1 =
match t with
| Some t ->
let sigma, t_j = pretype_type empty_valcon env sigma t in
sigma, mk_tycon t_j.utj_val
| None ->
sigma, empty_tycon in
let sigma, j = pretype tycon1 env sigma c1 in
let sigma, t = Evarsolve.refresh_universes
~onlyalg:true ~status:Evd.univ_flexible (Some false) !!env sigma j.uj_type in
let r = Retyping.relevance_of_term !!env sigma j.uj_val in
let var = LocalDef (make_annot name r, j.uj_val, t) in
let tycon = lift_tycon 1 tycon in
let vars = VarSet.variables (Global.env ()) in
let hypnaming = if flags.program_mode then ProgramNaming vars else RenameExistingBut vars in
let var, env = push_rel ~hypnaming sigma var env in
let sigma, j' = pretype tycon env sigma c2 in
let name = get_name var in
sigma, { uj_val = mkLetIn (make_annot name r, j.uj_val, t, j'.uj_val) ;
uj_type = subst1 j.uj_val j'.uj_type }
let pretype_lettuple self (nal, (na, po), c, d) =
fun ?loc ~flags tycon env sigma ->
let open Context.Rel.Declaration in
let pretype tycon env sigma c = eval_pretyper self ~flags tycon env sigma c in
let pretype_type tycon env sigma c = eval_type_pretyper self ~flags tycon env sigma c in
let sigma, cj = pretype empty_tycon env sigma c in
let (IndType (indf,realargs)) as indty =
try find_rectype !!env sigma cj.uj_type
with Not_found ->
let cloc = loc_of_glob_constr c in
error_case_not_inductive ?loc:cloc !!env sigma cj
in
let ind = fst (fst (dest_ind_family indf)) in
let cstrs = get_constructors !!env indf in
if not (Int.equal (Array.length cstrs) 1) then
user_err ?loc (str "Destructing let is only for inductive types" ++
str " with one constructor.");
let cs = cstrs.(0) in
if not (Int.equal (List.length nal) cs.cs_nargs) then
user_err ?loc:loc (str "Destructing let on this type expects " ++
int cs.cs_nargs ++ str " variables.");
let fsign, record =
let set_name na d = set_name na (map_rel_decl EConstr.of_constr d) in
match Environ.get_projections !!env ind with
| None ->
List.map2 set_name (List.rev nal) cs.cs_args, false
| Some ps ->
let rec aux n k names l =
match names, l with
| na :: names, (LocalAssum (na', t) :: l) ->
let t = EConstr.of_constr t in
let proj = Projection.make (fst ps.(cs.cs_nargs - k)) true in
LocalDef ({na' with binder_name = na},
lift (cs.cs_nargs - n) (mkProj (proj, na'.binder_relevance, cj.uj_val)), t)
:: aux (n+1) (k + 1) names l
| na :: names, (decl :: l) ->
set_name na decl :: aux (n+1) k names l
| [], [] -> []
| _ -> assert false
in aux 1 1 (List.rev nal) cs.cs_args, true in
let fsign = Context.Rel.map (whd_betaiota !!env sigma) fsign in
let vars = VarSet.variables (Global.env ()) in
let hypnaming = if flags.program_mode then ProgramNaming vars else RenameExistingBut vars in
let fsign,env_f = push_rel_context ~hypnaming sigma fsign env in
let obj indt rci p v f =
if not record then
let f = it_mkLambda_or_LetIn f fsign in
let ci = make_case_info !!env (ind_of_ind_type indt) LetStyle in
mkCase (EConstr.contract_case !!env sigma (ci, (p,rci), make_case_invert !!env indt ~case_relevance:rci ci, cj.uj_val,[|f|]))
else it_mkLambda_or_LetIn f fsign
in
let arsgn, indr =
let arsgn = get_arity !!env indf in
List.map (set_name Anonymous) arsgn, Inductiveops.relevance_of_inductive_family !!env indf
in
let indt = build_dependent_inductive !!env indf in
let psign = LocalAssum (make_annot na indr, indt) :: arsgn in
let psign = List.map (fun d -> map_rel_decl EConstr.of_constr d) psign in
let predenv = Cases.make_return_predicate_ltac_lvar env sigma na c cj.uj_val in
let nar = List.length arsgn in
let psign',env_p = push_rel_context ~hypnaming ~force_names:true sigma psign predenv in
(match po with
| Some p ->
let sigma, pj = pretype_type empty_valcon env_p sigma p in
let ccl = nf_evar sigma pj.utj_val in
let p = it_mkLambda_or_LetIn ccl psign' in
let inst =
(Array.map_to_list EConstr.of_constr cs.cs_concl_realargs)
@[EConstr.of_constr (build_dependent_constructor cs)] in
let lp = lift cs.cs_nargs p in
let fty = hnf_lam_applist !!env sigma lp inst in
let sigma, fj = pretype (mk_tycon fty) env_f sigma d in
let v =
let ind,_ = dest_ind_family indf in
let rci = Typing.check_allowed_sort !!env sigma ind cj.uj_val p in
obj indty rci p cj.uj_val fj.uj_val
in
sigma, { uj_val = v; uj_type = (substl (realargs@[cj.uj_val]) ccl) }
| None ->
let tycon = lift_tycon cs.cs_nargs tycon in
let sigma, fj = pretype tycon env_f sigma d in
let ccl = nf_evar sigma fj.uj_type in
let ccl =
if noccur_between sigma 1 cs.cs_nargs ccl then
lift (- cs.cs_nargs) ccl
else
error_cant_find_case_type ?loc !!env sigma
cj.uj_val in
let p = it_mkLambda_or_LetIn (lift (nar+1) ccl) psign' in
let v =
let ind,_ = dest_ind_family indf in
let rci = Typing.check_allowed_sort !!env sigma ind cj.uj_val p in
obj indty rci p cj.uj_val fj.uj_val
in sigma, { uj_val = v; uj_type = ccl })
let pretype_cases self (sty, po, tml, eqns) =
fun ?loc ~flags tycon env sigma ->
let pretype tycon env sigma c = eval_pretyper self ~flags tycon env sigma c in
Cases.compile_cases ?loc ~program_mode:flags.program_mode sty (pretype, sigma) tycon env (po,tml,eqns)
let pretype_if self (c, (na, po), b1, b2) =
fun ?loc ~flags tycon env sigma ->
let open Context.Rel.Declaration in
let pretype tycon env sigma c = eval_pretyper self ~flags tycon env sigma c in
let sigma, cj = pretype empty_tycon env sigma c in
let (IndType (indf,realargs)) as indty =
try find_rectype !!env sigma cj.uj_type
with Not_found ->
let cloc = loc_of_glob_constr c in
error_case_not_inductive ?loc:cloc !!env sigma cj in
let cstrs = get_constructors !!env indf in
if not (Int.equal (Array.length cstrs) 2) then
user_err ?loc
(str "If is only for inductive types with two constructors.");
let arsgn, indr =
let arsgn = get_arity !!env indf in
List.map (set_name Anonymous) arsgn, Inductiveops.relevance_of_inductive_family !!env indf
in
let nar = List.length arsgn in
let indt = build_dependent_inductive !!env indf in
let psign = LocalAssum (make_annot na indr, indt) :: arsgn in
let psign = List.map (fun d -> map_rel_decl EConstr.of_constr d) psign in
let predenv = Cases.make_return_predicate_ltac_lvar env sigma na c cj.uj_val in
let vars = VarSet.variables (Global.env ()) in
let hypnaming = if flags.program_mode then ProgramNaming vars else RenameExistingBut vars in
let psign,env_p = push_rel_context ~hypnaming sigma psign predenv in
let sigma, pred, p = match po with
| Some p ->
let sigma, pj = eval_type_pretyper self ~flags empty_valcon env_p sigma p in
let ccl = nf_evar sigma pj.utj_val in
let pred = it_mkLambda_or_LetIn ccl psign in
let typ = lift (- nar) (beta_applist sigma (pred,[cj.uj_val])) in
sigma, pred, typ
| None ->
let sigma, p = match tycon with
| Some ty -> sigma, ty
| None -> new_type_evar env sigma ~src:(loc,Evar_kinds.CasesType false)
in
sigma, it_mkLambda_or_LetIn (lift (nar+1) p) psign, p in
let pred = nf_evar sigma pred in
let p = nf_evar sigma p in
let f sigma cs b =
let n = Context.Rel.length cs.cs_args in
let pi = lift n pred in
let pi = beta_applist sigma (pi, [EConstr.of_constr (build_dependent_constructor cs)]) in
let cs_args = List.map (fun d -> map_rel_decl EConstr.of_constr d) cs.cs_args in
let cs_args = Context.Rel.map (whd_betaiota !!env sigma) cs_args in
let csgn =
List.map (set_name Anonymous) cs_args
in
let _,env_c = push_rel_context ~hypnaming sigma csgn env in
let sigma, bj = pretype (mk_tycon pi) env_c sigma b in
sigma, it_mkLambda_or_LetIn bj.uj_val cs_args in
let sigma, b1 = f sigma cstrs.(0) b1 in
let sigma, b2 = f sigma cstrs.(1) b2 in
let v =
let ind,_ = dest_ind_family indf in
let pred = nf_evar sigma pred in
let rci = Typing.check_allowed_sort !!env sigma ind cj.uj_val pred in
let ci = make_case_info !!env (fst ind) IfStyle in
mkCase (EConstr.contract_case !!env sigma
(ci, (pred,rci),
make_case_invert !!env indty ~case_relevance:rci ci, cj.uj_val,
[|b1;b2|]))
in
let cj = { uj_val = v; uj_type = p } in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma cj tycon
let pretype_cast self (c, k, t) =
fun ?loc ~flags tycon env sigma ->
let pretype tycon env sigma c = eval_pretyper self ~flags tycon env sigma c in
let sigma, cj =
let sigma, tj = eval_type_pretyper self ~flags empty_valcon env sigma t in
let sigma, tval = Evarsolve.refresh_universes
~onlyalg:true ~status:Evd.univ_flexible (Some false) !!env sigma tj.utj_val in
let tval = nf_evar sigma tval in
let (sigma, cj), tval = match k with
| Some VMcast ->
let sigma, cj = pretype empty_tycon env sigma c in
let cty = nf_evar sigma cj.uj_type and tval = nf_evar sigma tval in
begin match Reductionops.vm_infer_conv !!env sigma cty tval with
| Some sigma -> (sigma, cj), tval
| None ->
error_actual_type ?loc !!env sigma cj tval
(ConversionFailed (!!env,cty,tval))
end
| Some NATIVEcast ->
let sigma, cj = pretype empty_tycon env sigma c in
let cty = nf_evar sigma cj.uj_type and tval = nf_evar sigma tval in
begin
match Reductionops.native_infer_conv !!env sigma cty tval with
| Some sigma -> (sigma, cj), tval
| None ->
error_actual_type ?loc !!env sigma cj tval
(ConversionFailed (!!env,cty,tval))
end
| None | Some DEFAULTcast ->
pretype (mk_tycon tval) env sigma c, tval
in
let v = match k with
| None -> cj.uj_val
| Some k -> mkCast (cj.uj_val, k, tval)
in
sigma, { uj_val = v; uj_type = tval }
in discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma cj tycon
let pretype_type self c ?loc ~flags valcon (env : GlobEnv.t) sigma = match DAst.get c with
| GHole knd ->
let loc = loc_of_glob_constr c in
let naming = naming_of_glob_kind knd in
let knd = kind_of_glob_kind knd in
(match valcon with
| Some v ->
let sigma, s =
let t = Retyping.get_type_of !!env sigma v in
match EConstr.kind sigma (whd_all !!env sigma t) with
| Sort s ->
sigma, s
| Evar ev when is_Type sigma (existential_type sigma ev) ->
define_evar_as_sort !!env sigma ev
| _ -> anomaly (Pp.str "Found a type constraint which is not a type.")
in
let sigma, evkt = new_evar env sigma ~src:(loc, knd) ~naming (mkSort s) in
let ev,_ = destEvar sigma evkt in
let sigma = Evd.define ev (nf_evar sigma v) sigma in
sigma, { utj_val = v;
utj_type = s }
| None ->
let sigma, s = new_sort_variable univ_flexible_alg sigma in
let sigma, utj_val = new_evar env sigma ~src:(loc, knd) ~naming (mkSort s) in
let sigma = if flags.program_mode then mark_obligation_evar sigma knd utj_val else sigma in
sigma, { utj_val; utj_type = s})
| _ ->
let sigma, j = eval_pretyper self ~flags empty_tycon env sigma c in
let loc = loc_of_glob_constr c in
let sigma, tj =
let use_coercions = flags.use_coercions in
Coercion.inh_coerce_to_sort ?loc ~use_coercions !!env sigma j in
match valcon with
| None -> sigma, tj
| Some v ->
begin match Evarconv.unify_leq_delay !!env sigma v tj.utj_val with
| sigma -> sigma, tj
| exception Evarconv.UnableToUnify (sigma,e) ->
error_unexpected_type
?loc:(loc_of_glob_constr c) !!env sigma tj.utj_val v e
end
let pretype_int self i =
fun ?loc ~flags tycon env sigma ->
let resj =
try Typing.judge_of_int !!env i
with Invalid_argument _ ->
user_err ?loc (str "Type of int63 should be registered first.")
in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma resj tycon
let pretype_float self f =
fun ?loc ~flags tycon env sigma ->
let resj =
try Typing.judge_of_float !!env f
with Invalid_argument _ ->
user_err ?loc (str "Type of float should be registered first.")
in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma resj tycon
let pretype_array self (u,t,def,ty) =
fun ?loc ~flags tycon env sigma ->
let sigma, u = match u with
| None -> sigma, None
| Some ([],[u]) ->
let sigma, u = glob_level ?loc sigma u in
sigma, Some u
| Some (qs,us) ->
let open UnivGen in
Loc.raise ?loc (UniverseLengthMismatch {
actual = List.length qs, List.length us;
expect = 0, 1;
})
in
let sigma, tycon' = split_as_array !!env sigma tycon in
let sigma, jty = eval_type_pretyper self ~flags tycon' env sigma ty in
let sigma, u = match u with
| Some u -> sigma, u
| None -> Evd.new_univ_level_variable UState.univ_flexible sigma
in
let sigma = Evd.set_leq_sort !!env sigma jty.utj_type (ESorts.make (Sorts.sort_of_univ (Univ.Universe.make u))) in
let sigma, jdef = eval_pretyper self ~flags (mk_tycon jty.utj_val) env sigma def in
let pretype_elem = eval_pretyper self ~flags (mk_tycon jty.utj_val) env in
let sigma, jt = Array.fold_left_map pretype_elem sigma t in
let u = UVars.Instance.of_array ([||],[| u |]) in
let ta = EConstr.of_constr @@ Typeops.type_of_array !!env u in
let j = {
uj_val = EConstr.mkArray(EInstance.make u, Array.map (fun j -> j.uj_val) jt, jdef.uj_val, jty.utj_val);
uj_type = EConstr.mkApp(ta,[|jdef.uj_type|])
} in
discard_trace @@ inh_conv_coerce_to_tycon ?loc ~flags env sigma j tycon
end
let default_pretyper =
let open Default in
{
pretype_ref = pretype_ref;
pretype_var = pretype_var;
pretype_evar = pretype_evar;
pretype_patvar = pretype_patvar;
pretype_app = pretype_app;
pretype_proj = pretype_proj;
pretype_lambda = pretype_lambda;
pretype_prod = pretype_prod;
pretype_letin = pretype_letin;
pretype_cases = pretype_cases;
pretype_lettuple = pretype_lettuple;
pretype_if = pretype_if;
pretype_rec = pretype_rec;
pretype_sort = pretype_sort;
pretype_hole = pretype_hole;
pretype_genarg = pretype_genarg;
pretype_cast = pretype_cast;
pretype_int = pretype_int;
pretype_float = pretype_float;
pretype_array = pretype_array;
pretype_type = pretype_type;
}
let pretype ~flags tycon env sigma c =
eval_pretyper default_pretyper ~flags tycon env sigma c
let pretype_type ~flags tycon env sigma c =
eval_type_pretyper default_pretyper ~flags tycon env sigma c
let ise_pretype_gen (flags : inference_flags) env sigma lvar kind c =
let pretype_flags = {
program_mode = flags.program_mode;
use_coercions = flags.use_coercions;
poly = flags.polymorphic;
resolve_tc = match flags.use_typeclasses with
| NoUseTC -> false
| UseTC | UseTCForConv -> true
} in
let vars = VarSet.variables (Global.env ()) in
let hypnaming = if flags.program_mode then ProgramNaming vars else RenameExistingBut vars in
let env = GlobEnv.make ~hypnaming env sigma lvar in
let sigma', c', c'_ty = match kind with
| WithoutTypeConstraint ->
let sigma, j = pretype ~flags:pretype_flags empty_tycon env sigma c in
sigma, j.uj_val, j.uj_type
| OfType exptyp ->
let sigma, j = pretype ~flags:pretype_flags (mk_tycon exptyp) env sigma c in
sigma, j.uj_val, j.uj_type
| IsType ->
let sigma, tj = pretype_type ~flags:pretype_flags empty_valcon env sigma c in
sigma, tj.utj_val, mkSort tj.utj_type
in
process_inference_flags flags !!env sigma (sigma',c',c'_ty)
let ise_pretype_gen flags env sigma lvar kind c : _ * _ * _ =
NewProfile.profile "pretyping" (fun () ->
ise_pretype_gen flags env sigma lvar kind c)
()
let default_inference_flags fail = {
use_coercions = true;
use_typeclasses = UseTC;
solve_unification_constraints = true;
fail_evar = fail;
expand_evars = true;
program_mode = false;
polymorphic = false;
}
let no_classes_no_fail_inference_flags = {
use_coercions = true;
use_typeclasses = NoUseTC;
solve_unification_constraints = true;
fail_evar = false;
expand_evars = true;
program_mode = false;
polymorphic = false;
}
let all_and_fail_flags = default_inference_flags true
let all_no_fail_flags = default_inference_flags false
let ise_pretype_gen_ctx flags env sigma lvar kind c =
let sigma, c, _ = ise_pretype_gen flags env sigma lvar kind c in
c, Evd.evar_universe_context sigma
(** Entry points of the high-level type synthesis algorithm *)
let understand
?(flags=all_and_fail_flags)
?(expected_type=WithoutTypeConstraint)
env sigma c =
ise_pretype_gen_ctx flags env sigma empty_lvar expected_type c
let understand_tcc_ty ?(flags=all_no_fail_flags) env sigma ?(expected_type=WithoutTypeConstraint) c =
ise_pretype_gen flags env sigma empty_lvar expected_type c
let understand_tcc ?flags env sigma ?expected_type c =
let sigma, c, _ = understand_tcc_ty ?flags env sigma ?expected_type c in
sigma, c
let understand_ltac flags env sigma lvar kind c =
let (sigma, c, _) = ise_pretype_gen flags env sigma lvar kind c in
(sigma, c)
let understand_ltac_ty flags env sigma lvar kind c =
ise_pretype_gen flags env sigma lvar kind c
let understand_uconstr ?(flags = all_and_fail_flags)
?(expected_type = WithoutTypeConstraint) env sigma c =
let open Ltac_pretype in
let { closure; term } = c in
let vars = {
ltac_constrs = closure.typed;
ltac_uconstrs = closure.untyped;
ltac_idents = closure.idents;
ltac_genargs = closure.genargs;
} in
understand_ltac flags env sigma vars expected_type term
let path_convertible env sigma cl p q =
let open Coercionops in
let mkGRef ref = DAst.make @@ Glob_term.GRef(ref,None) in
let mkGVar id = DAst.make @@ Glob_term.GVar(id) in
let mkGApp(rt,rtl) = DAst.make @@ Glob_term.GApp(rt,rtl) in
let mkGLambda(n,t,b) = DAst.make @@ Glob_term.GLambda(n,Explicit,t,b) in
let mkGSort u = DAst.make @@ Glob_term.GSort u in
let mkGHole () = DAst.make @@ Glob_term.GHole (GBinderType Anonymous) in
let path_to_gterm p =
match p with
| ic :: p' ->
let names =
List.init (ic.coe_param + 1)
(fun n -> Id.of_string ("x" ^ string_of_int n))
in
List.fold_right
(fun id t -> mkGLambda (Name id, mkGHole (), t)) names @@
List.fold_left
(fun t ic ->
mkGApp (mkGRef ic.coe_value,
List.make ic.coe_param (mkGHole ()) @ [t]))
(mkGApp (mkGRef ic.coe_value, List.map mkGVar names))
p'
| [] ->
let params = class_nparams cl in
let clty =
match cl with
| CL_SORT -> mkGSort (Glob_term.UAnonymous {rigid=UnivFlexible false})
| CL_FUN -> anomaly (str "A source class must not be Funclass.")
| CL_SECVAR v -> mkGRef (GlobRef.VarRef v)
| CL_CONST c -> mkGRef (GlobRef.ConstRef c)
| CL_IND i -> mkGRef (GlobRef.IndRef i)
| CL_PROJ p -> mkGRef (GlobRef.ConstRef (Projection.Repr.constant p))
in
let names =
List.init params (fun n -> Id.of_string ("x" ^ string_of_int n))
in
List.fold_right
(fun id t -> mkGLambda (Name id, mkGHole (), t)) names @@
mkGLambda (Name (Id.of_string "x"),
mkGApp (clty, List.map mkGVar names),
mkGVar (Id.of_string "x"))
in
try
let sigma,tp = understand_tcc env sigma (path_to_gterm p) in
let sigma,tq = understand_tcc env sigma (path_to_gterm q) in
if Evd.has_undefined sigma then
false
else
let _ = Evarconv.unify_delay env sigma tp tq in true
with Evarconv.UnableToUnify _ | PretypeError _ -> false
let _ = Coercionops.install_path_comparator path_convertible