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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2017 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* TODO:
- Find an interface allowing eauto to backtrack when shelved goals remain,
e.g. to force instantiations.
*)
open Pp
open CErrors
open Util
open Names
open Term
open Termops
open EConstr
open Proof_type
open Tacmach
open Tactics
open Clenv
open Typeclasses
open Globnames
open Evd
open Locus
open Misctypes
open Proofview.Notations
open Hints
module NamedDecl = Context.Named.Declaration
(** Hint database named "typeclass_instances", now created directly in Auto *)
(** Options handling *)
let typeclasses_debug = ref 0
let typeclasses_depth = ref None
let typeclasses_modulo_eta = ref false
let set_typeclasses_modulo_eta d = (:=) typeclasses_modulo_eta d
let get_typeclasses_modulo_eta () = !typeclasses_modulo_eta
(** When this flag is enabled, the resolution of type classes tries to avoid
useless introductions. This is no longer useful since we have eta, but is
here for compatibility purposes. Another compatibility issues is that the
cost (in terms of search depth) can differ. *)
let typeclasses_limit_intros = ref true
let set_typeclasses_limit_intros d = (:=) typeclasses_limit_intros d
let get_typeclasses_limit_intros () = !typeclasses_limit_intros
let typeclasses_dependency_order = ref false
let set_typeclasses_dependency_order d = (:=) typeclasses_dependency_order d
let get_typeclasses_dependency_order () = !typeclasses_dependency_order
let typeclasses_iterative_deepening = ref false
let set_typeclasses_iterative_deepening d = (:=) typeclasses_iterative_deepening d
let get_typeclasses_iterative_deepening () = !typeclasses_iterative_deepening
(** [typeclasses_filtered_unif] governs the unification algorithm used by type
classes. If enabled, a new algorithm based on pattern filtering and refine
will be used. When disabled, the previous algorithm based on apply will be
used. *)
let typeclasses_filtered_unification = ref false
let set_typeclasses_filtered_unification d =
(:=) typeclasses_filtered_unification d
let get_typeclasses_filtered_unification () =
!typeclasses_filtered_unification
(** [typeclasses_legacy_resolution] falls back to the 8.5 resolution algorithm,
instead of the 8.6 one which uses the native backtracking facilities of the
proof engine. *)
let typeclasses_legacy_resolution = ref false
let set_typeclasses_legacy_resolution d = (:=) typeclasses_legacy_resolution d
let get_typeclasses_legacy_resolution () = !typeclasses_legacy_resolution
let set_typeclasses_debug d = (:=) typeclasses_debug (if d then 1 else 0)
let get_typeclasses_debug () = if !typeclasses_debug > 0 then true else false
let set_typeclasses_verbose =
function None -> typeclasses_debug := 0
| Some n -> (:=) typeclasses_debug n
let get_typeclasses_verbose () =
if !typeclasses_debug = 0 then None else Some !typeclasses_debug
let set_typeclasses_depth d = (:=) typeclasses_depth d
let get_typeclasses_depth () = !typeclasses_depth
open Goptions
let _ =
declare_bool_option
{ optdepr = true; (* remove in 8.8 *)
optname = "do typeclass search modulo eta conversion";
optkey = ["Typeclasses";"Modulo";"Eta"];
optread = get_typeclasses_modulo_eta;
optwrite = set_typeclasses_modulo_eta; }
let _ =
declare_bool_option
{ optdepr = false;
optname = "do typeclass search avoiding eta-expansions " ^
" in proof terms (expensive)";
optkey = ["Typeclasses";"Limit";"Intros"];
optread = get_typeclasses_limit_intros;
optwrite = set_typeclasses_limit_intros; }
let _ =
declare_bool_option
{ optdepr = false;
optname = "during typeclass resolution, solve instances according to their dependency order";
optkey = ["Typeclasses";"Dependency";"Order"];
optread = get_typeclasses_dependency_order;
optwrite = set_typeclasses_dependency_order; }
let _ =
declare_bool_option
{ optdepr = false;
optname = "use iterative deepening strategy";
optkey = ["Typeclasses";"Iterative";"Deepening"];
optread = get_typeclasses_iterative_deepening;
optwrite = set_typeclasses_iterative_deepening; }
let _ =
declare_bool_option
{ optdepr = true; (* remove in 8.8 *)
optname = "compat";
optkey = ["Typeclasses";"Legacy";"Resolution"];
optread = get_typeclasses_legacy_resolution;
optwrite = set_typeclasses_legacy_resolution; }
let _ =
declare_bool_option
{ optdepr = false;
optname = "compat";
optkey = ["Typeclasses";"Filtered";"Unification"];
optread = get_typeclasses_filtered_unification;
optwrite = set_typeclasses_filtered_unification; }
let set_typeclasses_debug =
declare_bool_option
{ optdepr = false;
optname = "debug output for typeclasses proof search";
optkey = ["Typeclasses";"Debug"];
optread = get_typeclasses_debug;
optwrite = set_typeclasses_debug; }
let _ =
declare_bool_option
{ optdepr = false;
optname = "debug output for typeclasses proof search";
optkey = ["Debug";"Typeclasses"];
optread = get_typeclasses_debug;
optwrite = set_typeclasses_debug; }
let _ =
declare_int_option
{ optdepr = false;
optname = "verbosity of debug output for typeclasses proof search";
optkey = ["Typeclasses";"Debug";"Verbosity"];
optread = get_typeclasses_verbose;
optwrite = set_typeclasses_verbose; }
let set_typeclasses_depth =
declare_int_option
{ optdepr = false;
optname = "depth for typeclasses proof search";
optkey = ["Typeclasses";"Depth"];
optread = get_typeclasses_depth;
optwrite = set_typeclasses_depth; }
type search_strategy = Dfs | Bfs
let set_typeclasses_strategy = function
| Dfs -> set_typeclasses_iterative_deepening false
| Bfs -> set_typeclasses_iterative_deepening true
let pr_ev evs ev =
Printer.pr_econstr_env (Goal.V82.env evs ev) evs (Goal.V82.concl evs ev)
(** Typeclasses instance search tactic / eauto *)
open Auto
open Unification
let auto_core_unif_flags st freeze = {
modulo_conv_on_closed_terms = Some st;
use_metas_eagerly_in_conv_on_closed_terms = true;
use_evars_eagerly_in_conv_on_closed_terms = false;
modulo_delta = st;
modulo_delta_types = st;
check_applied_meta_types = false;
use_pattern_unification = true;
use_meta_bound_pattern_unification = true;
frozen_evars = freeze;
restrict_conv_on_strict_subterms = false; (* ? *)
modulo_betaiota = true;
modulo_eta = !typeclasses_modulo_eta;
}
let auto_unif_flags freeze st =
let fl = auto_core_unif_flags st freeze in
{ core_unify_flags = fl;
merge_unify_flags = fl;
subterm_unify_flags = fl;
allow_K_in_toplevel_higher_order_unification = false;
resolve_evars = false
}
let e_give_exact flags poly (c,clenv) =
let open Tacmach.New in
Proofview.Goal.enter begin fun gl ->
let sigma = project gl in
let (c, _, _) = c in
let c, sigma =
if poly then
let clenv', subst = Clenv.refresh_undefined_univs clenv in
let evd = evars_reset_evd ~with_conv_pbs:true sigma clenv'.evd in
let c = Vars.subst_univs_level_constr subst c in
c, evd
else c, sigma
in
let (sigma, t1) = Typing.type_of (pf_env gl) sigma c in
Proofview.Unsafe.tclEVARS sigma <*>
Clenvtac.unify ~flags t1 <*> exact_no_check c
end
let clenv_unique_resolver_tac with_evars ~flags clenv' =
Proofview.Goal.enter begin fun gls ->
let resolve =
try Proofview.tclUNIT (clenv_unique_resolver ~flags clenv' gls)
with e -> Proofview.tclZERO e
in resolve >>= fun clenv' ->
Clenvtac.clenv_refine with_evars ~with_classes:false clenv'
end
let unify_e_resolve poly flags = begin fun gls (c,_,clenv) ->
let clenv', c = connect_hint_clenv poly c clenv gls in
clenv_unique_resolver_tac true ~flags clenv' end
let unify_resolve poly flags = begin fun gls (c,_,clenv) ->
let clenv', _ = connect_hint_clenv poly c clenv gls in
clenv_unique_resolver_tac false ~flags clenv'
end
(** Application of a lemma using [refine] instead of the old [w_unify] *)
let unify_resolve_refine poly flags gls ((c, t, ctx),n,clenv) =
let open Clenv in
let env = Proofview.Goal.env gls in
let concl = Proofview.Goal.concl gls in
Refine.refine ~typecheck:false begin fun sigma ->
let sigma, term, ty =
if poly then
let (subst, ctx) = Universes.fresh_universe_context_set_instance ctx in
let map c = Vars.subst_univs_level_constr subst c in
let sigma = Evd.merge_context_set Evd.univ_flexible sigma ctx in
sigma, map c, map t
else
let sigma = Evd.merge_context_set Evd.univ_flexible sigma ctx in
sigma, c, t
in
let sigma', cl = Clenv.make_evar_clause env sigma ?len:n ty in
let term = applist (term, List.map (fun x -> x.hole_evar) cl.cl_holes) in
let sigma' =
Evarconv.the_conv_x_leq env ~ts:flags.core_unify_flags.modulo_delta
cl.cl_concl concl sigma'
in (sigma', term) end
let unify_resolve_refine poly flags gl clenv =
Proofview.tclORELSE
(unify_resolve_refine poly flags gl clenv)
(fun ie ->
match fst ie with
| Evarconv.UnableToUnify _ ->
Tacticals.New.tclZEROMSG (str "Unable to unify")
| e when CErrors.noncritical e ->
Tacticals.New.tclZEROMSG (str "Unexpected error")
| _ -> iraise ie)
(** Dealing with goals of the form A -> B and hints of the form
C -> A -> B.
*)
let clenv_of_prods poly nprods (c, clenv) gl =
let (c, _, _) = c in
if poly || Int.equal nprods 0 then Some (None, clenv)
else
let sigma = Tacmach.New.project gl in
let ty = Retyping.get_type_of (Proofview.Goal.env gl) sigma c in
let diff = nb_prod sigma ty - nprods in
if Pervasives.(>=) diff 0 then
(* Was Some clenv... *)
Some (Some diff,
mk_clenv_from_n gl (Some diff) (c,ty))
else None
let with_prods nprods poly (c, clenv) f =
if get_typeclasses_limit_intros () then
Proofview.Goal.enter begin fun gl ->
try match clenv_of_prods poly nprods (c, clenv) gl with
| None -> Tacticals.New.tclZEROMSG (str"Not enough premisses")
| Some (diff, clenv') -> f gl (c, diff, clenv')
with e when CErrors.noncritical e ->
Tacticals.New.tclZEROMSG (CErrors.print e) end
else Proofview.Goal.enter
begin fun gl ->
if Int.equal nprods 0 then f gl (c, None, clenv)
else Tacticals.New.tclZEROMSG (str"Not enough premisses") end
let matches_pattern concl pat =
let matches env sigma =
match pat with
| None -> Proofview.tclUNIT ()
| Some pat ->
if Constr_matching.is_matching env sigma pat concl then
Proofview.tclUNIT ()
else
Tacticals.New.tclZEROMSG (str "pattern does not match")
in
Proofview.Goal.enter begin fun gl ->
let env = Proofview.Goal.env gl in
let sigma = Proofview.Goal.sigma gl in
matches env sigma end
(** Semantics of type class resolution lemma application:
- Use unification to find a well-typed substitution. There might
be evars in the goal and the lemma. Evars in the goal can get refined.
- Independent evars are turned into goals, whatever their kind is.
- Dependent evars of the lemma corresponding to arguments which appear
in independent goals or the conclusion are turned into subgoals iff
they are of typeclass kind.
- The remaining dependent evars not of typeclass type are shelved,
and resolution must fill them for it to succeed, otherwise we
backtrack.
*)
let pr_gls sigma gls =
prlist_with_sep spc
(fun ev -> int (Evar.repr ev) ++ spc () ++ pr_ev sigma ev) gls
(** Ensure the dependent subgoals are shelved after an apply/eapply. *)
let shelve_dependencies gls =
let open Proofview in
tclEVARMAP >>= fun sigma ->
(if !typeclasses_debug > 1 && List.length gls > 0 then
Feedback.msg_debug (str" shelving dependent subgoals: " ++ pr_gls sigma gls);
shelve_goals gls)
let hintmap_of sigma hdc secvars concl =
match hdc with
| None -> fun db -> Hint_db.map_none ~secvars db
| Some hdc ->
fun db ->
if Hint_db.use_dn db then (* Using dnet *)
Hint_db.map_eauto sigma ~secvars hdc concl db
else Hint_db.map_existential sigma ~secvars hdc concl db
(** Hack to properly solve dependent evars that are typeclasses *)
let rec e_trivial_fail_db only_classes db_list local_db secvars =
let open Tacticals.New in
let open Tacmach.New in
let trivial_fail =
Proofview.Goal.enter
begin fun gl ->
let env = Proofview.Goal.env gl in
let sigma = Tacmach.New.project gl in
let d = pf_last_hyp gl in
let hintl = make_resolve_hyp env sigma d in
let hints = Hint_db.add_list env sigma hintl local_db in
e_trivial_fail_db only_classes db_list hints secvars
end
in
let trivial_resolve =
Proofview.Goal.enter
begin fun gl ->
let tacs = e_trivial_resolve db_list local_db secvars only_classes
(project gl) (pf_concl gl) in
tclFIRST (List.map (fun (x,_,_,_,_) -> x) tacs)
end
in
let tacl =
Eauto.registered_e_assumption ::
(tclTHEN Tactics.intro trivial_fail :: [trivial_resolve])
in
tclFIRST (List.map tclCOMPLETE tacl)
and e_my_find_search db_list local_db secvars hdc complete only_classes sigma concl =
let open Proofview.Notations in
let prods, concl = EConstr.decompose_prod_assum sigma concl in
let nprods = List.length prods in
let freeze =
try
match hdc with
| Some (hd,_) when only_classes ->
let cl = Typeclasses.class_info hd in
if cl.cl_strict then
Evarutil.undefined_evars_of_term sigma concl
else Evar.Set.empty
| _ -> Evar.Set.empty
with e when CErrors.noncritical e -> Evar.Set.empty
in
let hint_of_db = hintmap_of sigma hdc secvars concl in
let hintl =
List.map_append
(fun db ->
let tacs = hint_of_db db in
let flags = auto_unif_flags freeze (Hint_db.transparent_state db) in
List.map (fun x -> (flags, x)) tacs)
(local_db::db_list)
in
let tac_of_hint =
fun (flags, {pri = b; pat = p; poly = poly; code = t; secvars; name = name}) ->
let tac = function
| Res_pf (term,cl) ->
if get_typeclasses_filtered_unification () then
let tac =
with_prods nprods poly (term,cl)
(fun gl clenv ->
matches_pattern concl p <*>
unify_resolve_refine poly flags gl clenv)
in Tacticals.New.tclTHEN tac Proofview.shelve_unifiable
else
let tac =
with_prods nprods poly (term,cl) (unify_resolve poly flags) in
if get_typeclasses_legacy_resolution () then
Tacticals.New.tclTHEN tac Proofview.shelve_unifiable
else
Proofview.tclBIND (Proofview.with_shelf tac)
(fun (gls, ()) -> shelve_dependencies gls)
| ERes_pf (term,cl) ->
if get_typeclasses_filtered_unification () then
let tac = (with_prods nprods poly (term,cl)
(fun gl clenv ->
matches_pattern concl p <*>
unify_resolve_refine poly flags gl clenv)) in
Tacticals.New.tclTHEN tac Proofview.shelve_unifiable
else
let tac =
with_prods nprods poly (term,cl) (unify_e_resolve poly flags) in
if get_typeclasses_legacy_resolution () then
Tacticals.New.tclTHEN tac Proofview.shelve_unifiable
else
Proofview.tclBIND (Proofview.with_shelf tac)
(fun (gls, ()) -> shelve_dependencies gls)
| Give_exact (c,clenv) ->
if get_typeclasses_filtered_unification () then
let tac =
matches_pattern concl p <*>
Proofview.Goal.nf_enter
(fun gl -> unify_resolve_refine poly flags gl (c,None,clenv)) in
Tacticals.New.tclTHEN tac Proofview.shelve_unifiable
else
e_give_exact flags poly (c,clenv)
| Res_pf_THEN_trivial_fail (term,cl) ->
let fst = with_prods nprods poly (term,cl) (unify_e_resolve poly flags) in
let snd = if complete then Tacticals.New.tclIDTAC
else e_trivial_fail_db only_classes db_list local_db secvars in
Tacticals.New.tclTHEN fst snd
| Unfold_nth c ->
Proofview.tclPROGRESS (unfold_in_concl [AllOccurrences,c])
| Extern tacast -> conclPattern concl p tacast
in
let tac = run_hint t tac in
let tac = if complete then Tacticals.New.tclCOMPLETE tac else tac in
let pp =
match p with
| Some pat when get_typeclasses_filtered_unification () ->
str " with pattern " ++ Printer.pr_constr_pattern pat
| _ -> mt ()
in
match repr_hint t with
| Extern _ -> (tac, b, true, name, lazy (pr_hint t ++ pp))
| _ -> (tac, b, false, name, lazy (pr_hint t ++ pp))
in List.map tac_of_hint hintl
and e_trivial_resolve db_list local_db secvars only_classes sigma concl =
let hd = try Some (decompose_app_bound sigma concl) with Bound -> None in
try
e_my_find_search db_list local_db secvars hd true only_classes sigma concl
with Not_found -> []
let e_possible_resolve db_list local_db secvars only_classes sigma concl =
let hd = try Some (decompose_app_bound sigma concl) with Bound -> None in
try
e_my_find_search db_list local_db secvars hd false only_classes sigma concl
with Not_found -> []
let cut_of_hints h =
List.fold_left (fun cut db -> PathOr (Hint_db.cut db, cut)) PathEmpty h
let catchable = function
| Refiner.FailError _ -> true
| e -> Logic.catchable_exception e
let pr_depth l =
let rec fmt elts =
match elts with
| [] -> []
| [n] -> [string_of_int n]
| n1::n2::rest ->
(string_of_int n1 ^ "." ^ string_of_int n2) :: fmt rest
in
prlist_with_sep (fun () -> str "-") str (fmt (List.rev l))
let is_Prop env sigma concl =
let ty = Retyping.get_type_of env sigma concl in
match EConstr.kind sigma ty with
| Sort s ->
begin match ESorts.kind sigma s with
| Prop Null -> true
| _ -> false
end
| _ -> false
let is_unique env sigma concl =
try
let (cl,u), args = dest_class_app env sigma concl in
cl.cl_unique
with e when CErrors.noncritical e -> false
(** Sort the undefined variables from the least-dependent to most dependent. *)
let top_sort evm undefs =
let l' = ref [] in
let tosee = ref undefs in
let rec visit ev evi =
let evs = Evarutil.undefined_evars_of_evar_info evm evi in
tosee := Evar.Map.remove ev !tosee;
Evar.Set.iter (fun ev ->
if Evar.Map.mem ev !tosee then
visit ev (Evar.Map.find ev !tosee)) evs;
l' := ev :: !l';
in
while not (Evar.Map.is_empty !tosee) do
let ev, evi = Evar.Map.min_binding !tosee in
visit ev evi
done;
List.rev !l'
(** We transform the evars that are concerned by this resolution
(according to predicate p) into goals.
Invariant: function p only manipulates and returns undefined evars
*)
let evars_to_goals p evm =
let goals = ref Evar.Map.empty in
let map ev evi =
let evi, goal = p evm ev evi in
let () = if goal then goals := Evar.Map.add ev evi !goals in
evi
in
let evm = Evd.raw_map_undefined map evm in
if Evar.Map.is_empty !goals then None
else Some (!goals, evm)
(** Making local hints *)
let make_resolve_hyp env sigma st flags only_classes pri decl =
let id = NamedDecl.get_id decl in
let cty = Evarutil.nf_evar sigma (NamedDecl.get_type decl) in
let rec iscl env ty =
let ctx, ar = decompose_prod_assum sigma ty in
match EConstr.kind sigma (fst (decompose_app sigma ar)) with
| Const (c,_) -> is_class (ConstRef c)
| Ind (i,_) -> is_class (IndRef i)
| _ ->
let env' = push_rel_context ctx env in
let ty' = Reductionops.whd_all env' sigma ar in
if not (EConstr.eq_constr sigma ty' ar) then iscl env' ty'
else false
in
let is_class = iscl env cty in
let keep = not only_classes || is_class in
if keep then
let c = mkVar id in
let name = PathHints [VarRef id] in
let hints =
if is_class then
let hints = build_subclasses ~check:false env sigma (VarRef id) empty_hint_info in
(List.map_append
(fun (path,info,c) ->
let info =
{ info with Vernacexpr.hint_pattern =
Option.map (Constrintern.intern_constr_pattern env)
info.Vernacexpr.hint_pattern }
in
make_resolves env sigma ~name:(PathHints path)
(true,false,not !Flags.quiet) info false
(IsConstr (EConstr.of_constr c,Univ.ContextSet.empty)))
hints)
else []
in
(hints @ List.map_filter
(fun f -> try Some (f (c, cty, Univ.ContextSet.empty))
with Failure _ | UserError _ -> None)
[make_exact_entry ~name env sigma pri false;
make_apply_entry ~name env sigma flags pri false])
else []
let make_hints g st only_classes sign =
let hintlist =
List.fold_left
(fun hints hyp ->
let consider =
not only_classes ||
try let t = hyp |> NamedDecl.get_id |> Global.lookup_named |> NamedDecl.get_type in
(* Section variable, reindex only if the type changed *)
not (EConstr.eq_constr (project g) (EConstr.of_constr t) (NamedDecl.get_type hyp))
with Not_found -> true
in
if consider then
let hint =
pf_apply make_resolve_hyp g st (true,false,false) only_classes empty_hint_info hyp
in hint @ hints
else hints)
([]) sign
in Hint_db.add_list (pf_env g) (project g) hintlist (Hint_db.empty st true)
(** <= 8.5 resolution *)
module V85 = struct
type autoinfo = { hints : hint_db; is_evar: existential_key option;
only_classes: bool; unique : bool;
auto_depth: int list; auto_last_tac: Pp.t Lazy.t;
auto_path : global_reference option list;
auto_cut : hints_path }
type autogoal = goal * autoinfo
type failure = NotApplicable | ReachedLimit
type 'ans fk = failure -> 'ans
type ('a,'ans) sk = 'a -> 'ans fk -> 'ans
type 'a tac = { skft : 'ans. ('a,'ans) sk -> 'ans fk -> autogoal sigma -> 'ans }
type auto_result = autogoal list sigma
type atac = auto_result tac
(* Some utility types to avoid the need of -rectypes *)
type 'a optionk =
| Nonek
| Somek of 'a * 'a optionk fk
type ('a,'b) optionk2 =
| Nonek2 of failure
| Somek2 of 'a * 'b * ('a,'b) optionk2 fk
let pf_filtered_hyps gls =
Goal.V82.hyps gls.Evd.sigma (sig_it gls)
let make_autogoal_hints =
let cache = Summary.ref ~name:"make_autogoal_hints_cache"
(true, Environ.empty_named_context_val,
Hint_db.empty full_transparent_state true)
in
fun only_classes ?(st=full_transparent_state) g ->
let sign = pf_filtered_hyps g in
let (onlyc, sign', cached_hints) = !cache in
if onlyc == only_classes &&
(sign == sign' || Environ.eq_named_context_val sign sign')
&& Hint_db.transparent_state cached_hints == st
then
cached_hints
else
let hints = make_hints g st only_classes (EConstr.named_context_of_val sign)
in
cache := (only_classes, sign, hints); hints
let lift_tactic tac (f : goal list sigma -> autoinfo -> autogoal list sigma) : 'a tac =
{ skft = fun sk fk {it = gl,hints; sigma=s;} ->
let res = try Some (tac {it=gl; sigma=s;})
with e when catchable e -> None in
match res with
| Some gls -> sk (f gls hints) fk
| None -> fk NotApplicable }
let intro_tac : atac =
let tac {it = gls; sigma = s} info =
let gls' =
List.map (fun g' ->
let env = Goal.V82.env s g' in
let context = EConstr.named_context_of_val (Goal.V82.hyps s g') in
let hint = make_resolve_hyp env s (Hint_db.transparent_state info.hints)
(true,false,false) info.only_classes empty_hint_info (List.hd context) in
let ldb = Hint_db.add_list env s hint info.hints in
(g', { info with is_evar = None; hints = ldb;
auto_last_tac = lazy (str"intro") })) gls
in {it = gls'; sigma = s;}
in
lift_tactic (Proofview.V82.of_tactic Tactics.intro) tac
let normevars_tac : atac =
{ skft = fun sk fk {it = (gl, info); sigma = s;} ->
let gl', sigma' = Goal.V82.nf_evar s gl in
let info' = { info with auto_last_tac = lazy (str"normevars") } in
sk {it = [gl', info']; sigma = sigma';} fk }
let merge_failures x y =
match x, y with
| _, ReachedLimit
| ReachedLimit, _ -> ReachedLimit
| NotApplicable, NotApplicable -> NotApplicable
let or_tac (x : 'a tac) (y : 'a tac) : 'a tac =
{ skft = fun sk fk gls -> x.skft sk
(fun f -> y.skft sk (fun f' -> fk (merge_failures f f')) gls) gls }
let or_else_tac (x : 'a tac) (y : failure -> 'a tac) : 'a tac =
{ skft = fun sk fk gls -> x.skft sk
(fun f -> (y f).skft sk fk gls) gls }
let needs_backtrack env evd oev concl =
if Option.is_empty oev || is_Prop env evd concl then
occur_existential evd concl
else true
let hints_tac hints sk fk {it = gl,info; sigma = s} =
let env = Goal.V82.env s gl in
let concl = Goal.V82.concl s gl in
let tacgl = {it = gl; sigma = s;} in
let secvars = secvars_of_hyps (Environ.named_context_of_val (Goal.V82.hyps s gl)) in
let poss = e_possible_resolve hints info.hints secvars info.only_classes s concl in
let unique = is_unique env s concl in
let rec aux i foundone = function
| (tac, _, extern, name, pp) :: tl ->
let derivs = path_derivate info.auto_cut name in
let res =
try
if path_matches derivs [] then None
else Some (Proofview.V82.of_tactic tac tacgl)
with e when catchable e -> None
in
(match res with
| None -> aux i foundone tl
| Some {it = gls; sigma = s';} ->
if !typeclasses_debug > 0 then
Feedback.msg_debug
(pr_depth (i :: info.auto_depth) ++ str": " ++ Lazy.force pp
++ str" on" ++ spc () ++ pr_ev s gl);
let sgls =
evars_to_goals
(fun evm ev evi ->
if Typeclasses.is_resolvable evi && not (Evd.is_undefined s ev) &&
(not info.only_classes || Typeclasses.is_class_evar evm evi)
then Typeclasses.mark_unresolvable evi, true
else evi, false) s'
in
let newgls, s' =
let gls' = List.map (fun g -> (None, g)) gls in
match sgls with
| None -> gls', s'
| Some (evgls, s') ->
if not !typeclasses_dependency_order then
(gls' @ List.map (fun (ev,_) -> (Some ev, ev)) (Evar.Map.bindings evgls), s')
else
(* Reorder with dependent subgoals. *)
let evm = List.fold_left
(fun acc g -> Evar.Map.add g (Evd.find_undefined s' g) acc) evgls gls in
let gls = top_sort s' evm in
(List.map (fun ev -> Some ev, ev) gls, s')
in
let reindex g =
let open Goal.V82 in
extern && not (Environ.eq_named_context_val
(hyps s' g) (hyps s' gl))
in
let gl' j (evar, g) =
let hints' =
if reindex g then
make_autogoal_hints
info.only_classes
~st:(Hint_db.transparent_state info.hints)
{it = g; sigma = s';}
else info.hints
in
{ info with
auto_depth = j :: i :: info.auto_depth;
auto_last_tac = pp;
is_evar = evar;
hints = hints';
auto_cut = derivs }
in
let gls' = List.map_i (fun i g -> snd g, gl' i g) 1 newgls in
let glsv = {it = gls'; sigma = s';} in
let fk' =
(fun e ->
let do_backtrack =
if unique then occur_existential tacgl.sigma concl
else if info.unique then true
else if List.is_empty gls' then
needs_backtrack env tacgl.sigma info.is_evar concl
else true
in
let e' = match foundone with None -> e
| Some e' -> merge_failures e e' in
if !typeclasses_debug > 0 then
Feedback.msg_debug
((if do_backtrack then str"Backtracking after "
else str "Not backtracking after ")
++ Lazy.force pp);
if do_backtrack then aux (succ i) (Some e') tl
else fk e')
in
sk glsv fk')
| [] ->
if foundone == None && !typeclasses_debug > 0 then
Feedback.msg_debug
(pr_depth info.auto_depth ++ str": no match for " ++
Printer.pr_econstr_env (Goal.V82.env s gl) s concl ++
spc () ++ str ", " ++ int (List.length poss) ++
str" possibilities");
match foundone with
| Some e -> fk e
| None -> fk NotApplicable
in aux 1 None poss
let hints_tac hints =
{ skft = fun sk fk gls -> hints_tac hints sk fk gls }
let then_list (second : atac) (sk : (auto_result, 'a) sk) : (auto_result, 'a) sk =
let rec aux s (acc : autogoal list list) fk = function
| (gl,info) :: gls ->
Control.check_for_interrupt ();
(match info.is_evar with
| Some ev when Evd.is_defined s ev -> aux s acc fk gls
| _ ->
second.skft
(fun {it=gls';sigma=s'} fk' ->
let fk'' =
if not info.unique && List.is_empty gls' &&
not (needs_backtrack (Goal.V82.env s gl) s
info.is_evar (Goal.V82.concl s gl))
then fk
else fk'
in
aux s' (gls'::acc) fk'' gls)
fk {it = (gl,info); sigma = s; })
| [] -> Somek2 (List.rev acc, s, fk)
in fun {it = gls; sigma = s; } fk ->
let rec aux' = function
| Nonek2 e -> fk e
| Somek2 (res, s', fk') ->
let goals' = List.concat res in
sk {it = goals'; sigma = s'; } (fun e -> aux' (fk' e))
in aux' (aux s [] (fun e -> Nonek2 e) gls)
let then_tac (first : atac) (second : atac) : atac =
{ skft = fun sk fk -> first.skft (then_list second sk) fk }
let run_tac (t : 'a tac) (gl : autogoal sigma) : auto_result option =
t.skft (fun x _ -> Some x) (fun _ -> None) gl
type run_list_res = auto_result optionk
let run_list_tac (t : 'a tac) p goals (gl : autogoal list sigma) : run_list_res =
(then_list t (fun x fk -> Somek (x, fk)))
gl
(fun _ -> Nonek)
let fail_tac reason : atac =
{ skft = fun sk fk _ -> fk reason }
let rec fix (t : 'a tac) : 'a tac =
then_tac t { skft = fun sk fk -> (fix t).skft sk fk }
let rec fix_limit limit (t : 'a tac) : 'a tac =
if Int.equal limit 0 then fail_tac ReachedLimit
else then_tac t { skft = fun sk fk -> (fix_limit (pred limit) t).skft sk fk }
let fix_iterative t =
let rec aux depth =
or_else_tac (fix_limit depth t)
(function
| NotApplicable as e -> fail_tac e
| ReachedLimit -> aux (succ depth))
in aux 1
let fix_iterative_limit limit (t : 'a tac) : 'a tac =
let rec aux depth =
if Int.equal limit depth then fail_tac ReachedLimit
else or_tac (fix_limit depth t)
{ skft = fun sk fk -> (aux (succ depth)).skft sk fk }
in aux 1
let make_autogoal ?(only_classes=true) ?(unique=false) ?(st=full_transparent_state)
cut ev g =
let hints = make_autogoal_hints only_classes ~st g in
(g.it, { hints = hints ; is_evar = ev; unique = unique;
only_classes = only_classes; auto_depth = [];
auto_last_tac = lazy (str"none");
auto_path = []; auto_cut = cut })
let make_autogoals ?(only_classes=true) ?(unique=false)
?(st=full_transparent_state) hints gs evm' =
let cut = cut_of_hints hints in
let gl i g =
let (gl, auto) = make_autogoal ~only_classes ~unique
~st cut (Some g) {it = g; sigma = evm'; } in
(gl, { auto with auto_depth = [i]})
in { it = List.map_i gl 1 gs; sigma = evm' }
let get_result r =
match r with
| Nonek -> None
| Somek (gls, fk) -> Some (gls.sigma,fk)
let run_on_evars ?(only_classes=true) ?(unique=false) ?(st=full_transparent_state)
p evm hints tac =
match evars_to_goals p evm with
| None -> None (* This happens only because there's no evar having p *)
| Some (goals, evm') ->
let goals =
if !typeclasses_dependency_order then
top_sort evm' goals
else List.map (fun (ev, _) -> ev) (Evar.Map.bindings goals)
in
let res = run_list_tac tac p goals
(make_autogoals ~only_classes ~unique ~st hints goals evm') in
match get_result res with
| None -> raise Not_found
| Some (evm', fk) ->
Some (evars_reset_evd ~with_conv_pbs:true ~with_univs:false evm' evm, fk)
let eauto_tac hints =
then_tac normevars_tac (or_tac (hints_tac hints) intro_tac)
let eauto_tac strategy depth hints =
match strategy with
| Bfs ->
begin match depth with
| None -> fix_iterative (eauto_tac hints)
| Some depth -> fix_iterative_limit depth (eauto_tac hints) end
| Dfs ->
match depth with
| None -> fix (eauto_tac hints)
| Some depth -> fix_limit depth (eauto_tac hints)
let real_eauto ?depth strategy unique st hints p evd =
let res =
run_on_evars ~st ~unique p evd hints (eauto_tac strategy depth hints)
in
match res with
| None -> evd
| Some (evd', fk) ->
if unique then
(match get_result (fk NotApplicable) with
| Some (evd'', fk') -> user_err Pp.(str "Typeclass resolution gives multiple solutions")
| None -> evd')
else evd'
let resolve_all_evars_once debug depth unique p evd =
let db = searchtable_map typeclasses_db in
let strategy = if get_typeclasses_iterative_deepening () then Bfs else Dfs in
real_eauto ?depth strategy unique (Hint_db.transparent_state db) [db] p evd
let eauto85 ?(only_classes=true) ?st ?strategy depth hints g =
let strategy =
match strategy with
| None -> if get_typeclasses_iterative_deepening () then Bfs else Dfs
| Some s -> s
in
let gl = { it = make_autogoal ~only_classes ?st
(cut_of_hints hints) None g; sigma = project g; } in
match run_tac (eauto_tac strategy depth hints) gl with
| None -> raise Not_found
| Some {it = goals; sigma = s; } ->
{it = List.map fst goals; sigma = s;}
end
(** 8.6 resolution *)
module Search = struct
type autoinfo =
{ search_depth : int list;
last_tac : Pp.t Lazy.t;
search_dep : bool;
search_only_classes : bool;
search_cut : hints_path;
search_hints : hint_db; }
(** Local hints *)
let autogoal_cache = Summary.ref ~name:"autogoal_cache"
(DirPath.empty, true, Context.Named.empty,
Hint_db.empty full_transparent_state true)
let make_autogoal_hints only_classes ?(st=full_transparent_state) g =
let open Proofview in
let open Tacmach.New in
let sign = Goal.hyps g in
let (dir, onlyc, sign', cached_hints) = !autogoal_cache in
let cwd = Lib.cwd () in
let eq c1 c2 = EConstr.eq_constr (project g) c1 c2 in
if DirPath.equal cwd dir &&
(onlyc == only_classes) &&
Context.Named.equal eq sign sign' &&
Hint_db.transparent_state cached_hints == st
then cached_hints
else
let hints = make_hints {it = Goal.goal (Proofview.Goal.assume g); sigma = project g}
st only_classes sign
in
autogoal_cache := (cwd, only_classes, sign, hints); hints
let make_autogoal ?(st=full_transparent_state) only_classes dep cut i g =
let hints = make_autogoal_hints only_classes ~st g in
{ search_hints = hints;
search_depth = [i]; last_tac = lazy (str"none");
search_dep = dep;
search_only_classes = only_classes;
search_cut = cut }
(** In the proof engine failures are represented as exceptions *)
exception ReachedLimitEx
exception NoApplicableEx
(** ReachedLimitEx has priority over NoApplicableEx to handle
iterative deepening: it should fail when no hints are applicable,
but go to a deeper depth otherwise. *)
let merge_exceptions e e' =
match fst e, fst e' with
| ReachedLimitEx, _ -> e
| _, ReachedLimitEx -> e'
| _, _ -> e
(** Determine if backtracking is needed for this goal.
If the type class is unique or in Prop
and there are no evars in the goal then we do
NOT backtrack. *)
let needs_backtrack env evd unique concl =
if unique || is_Prop env evd concl then
occur_existential evd concl
else true
let mark_unresolvables sigma goals =
List.fold_left
(fun sigma gl ->
let evi = Evd.find_undefined sigma gl in
let evi' = Typeclasses.mark_unresolvable evi in
Evd.add sigma gl evi')
sigma goals
let fail_if_nonclass info =
Proofview.Goal.enter begin fun gl ->
let gl = Proofview.Goal.assume gl in
let sigma = Proofview.Goal.sigma gl in
if is_class_type sigma (Proofview.Goal.concl gl) then
Proofview.tclUNIT ()
else (if !typeclasses_debug > 1 then
Feedback.msg_debug (pr_depth info.search_depth ++
str": failure due to non-class subgoal " ++
pr_ev sigma (Proofview.Goal.goal gl));
Proofview.tclZERO NoApplicableEx) end
(** The general hint application tactic.
tac1 + tac2 .... The choice of OR or ORELSE is determined
depending on the dependencies of the goal and the unique/Prop
status *)
let hints_tac_gl hints info kont gl : unit Proofview.tactic =
let open Proofview in
let open Proofview.Notations in
let env = Goal.env gl in
let concl = Goal.concl gl in
let sigma = Goal.sigma gl in
let unique = not info.search_dep || is_unique env sigma concl in
let backtrack = needs_backtrack env sigma unique concl in
if !typeclasses_debug > 0 then
Feedback.msg_debug
(pr_depth info.search_depth ++ str": looking for " ++
Printer.pr_econstr_env (Goal.env gl) sigma concl ++
(if backtrack then str" with backtracking"
else str" without backtracking"));
let secvars = compute_secvars gl in
let poss =
e_possible_resolve hints info.search_hints secvars info.search_only_classes sigma concl in
(* If no goal depends on the solution of this one or the
instances are irrelevant/assumed to be unique, then
we don't need to backtrack, as long as no evar appears in the goal
This is an overapproximation. Evars could appear in this goal only
and not any other *)
let ortac = if backtrack then Proofview.tclOR else Proofview.tclORELSE in
let idx = ref 1 in
let foundone = ref false in
let rec onetac e (tac, pat, b, name, pp) tl =
let derivs = path_derivate info.search_cut name in
let pr_error ie =
if !typeclasses_debug > 1 then
let idx = if fst ie == NoApplicableEx then pred !idx else !idx in
let header =
pr_depth (idx :: info.search_depth) ++ str": " ++
Lazy.force pp ++
(if !foundone != true then
str" on" ++ spc () ++ pr_ev sigma (Proofview.Goal.goal (Proofview.Goal.assume gl))
else mt ())
in
let msg =
match fst ie with
| Pretype_errors.PretypeError (env, evd, Pretype_errors.CannotUnify (x,y,_)) ->
str"Cannot unify " ++ print_constr_env env evd x ++ str" and " ++
print_constr_env env evd y
| ReachedLimitEx -> str "Proof-search reached its limit."
| NoApplicableEx -> str "Proof-search failed."
| e -> CErrors.iprint ie
in
Feedback.msg_debug (header ++ str " failed with: " ++ msg)
else ()
in
let tac_of gls i j = Goal.enter begin fun gl' ->
let sigma' = Goal.sigma gl' in
let _concl = Goal.concl gl' in
if !typeclasses_debug > 0 then
Feedback.msg_debug
(pr_depth (succ j :: i :: info.search_depth) ++ str" : " ++
pr_ev sigma' (Proofview.Goal.goal (Proofview.Goal.assume gl')));
let eq c1 c2 = EConstr.eq_constr sigma' c1 c2 in
let hints' =
if b && not (Context.Named.equal eq (Goal.hyps gl') (Goal.hyps gl))
then
let st = Hint_db.transparent_state info.search_hints in
make_autogoal_hints info.search_only_classes ~st gl'
else info.search_hints
in
let dep' = info.search_dep || Proofview.unifiable sigma' (Goal.goal (Proofview.Goal.assume gl')) gls in
let info' =
{ search_depth = succ j :: i :: info.search_depth;
last_tac = pp;
search_dep = dep';
search_only_classes = info.search_only_classes;
search_hints = hints';
search_cut = derivs }
in kont info' end
in
let rec result (shelf, ()) i k =
foundone := true;
Proofview.Unsafe.tclGETGOALS >>= fun gls ->
let j = List.length gls in
(if !typeclasses_debug > 0 then
Feedback.msg_debug
(pr_depth (i :: info.search_depth) ++ str": " ++ Lazy.force pp
++ str" on" ++ spc () ++ pr_ev sigma (Proofview.Goal.goal (Proofview.Goal.assume gl))
++ str", " ++ int j ++ str" subgoal(s)" ++
(Option.cata (fun k -> str " in addition to the first " ++ int k)
(mt()) k)));
let res =
if j = 0 then tclUNIT ()
else tclDISPATCH
(List.init j (fun j' -> (tac_of gls i (Option.default 0 k + j'))))
in
let finish nestedshelf sigma =
let filter ev =
try
let evi = Evd.find_undefined sigma ev in
if info.search_only_classes then
Some (ev, not (is_class_evar sigma evi))
else Some (ev, true)
with Not_found -> None
in
let remaining = CList.map_filter filter shelf in
(if !typeclasses_debug > 1 then
let prunsolved (ev, _) =
int (Evar.repr ev) ++ spc () ++ pr_ev sigma ev in
let unsolved = prlist_with_sep spc prunsolved remaining in
Feedback.msg_debug
(pr_depth (i :: info.search_depth) ++
str": after " ++ Lazy.force pp ++ str" finished, " ++
int (List.length remaining) ++
str " goals are shelved and unsolved ( " ++
unsolved ++ str")"));
begin
(* Some existentials produced by the original tactic were not solved
in the subgoals, turn them into subgoals now. *)
let shelved, goals = List.partition (fun (ev, s) -> s) remaining in
let shelved = List.map fst shelved @ nestedshelf and goals = List.map fst goals in
if !typeclasses_debug > 1 && not (List.is_empty shelved && List.is_empty goals) then
Feedback.msg_debug
(str"Adding shelved subgoals to the search: " ++
prlist_with_sep spc (pr_ev sigma) goals ++
str" while shelving " ++
prlist_with_sep spc (pr_ev sigma) shelved);
shelve_goals shelved <*>
(if List.is_empty goals then tclUNIT ()
else
let sigma' = mark_unresolvables sigma goals in
with_shelf (Unsafe.tclEVARS sigma' <*> Unsafe.tclNEWGOALS goals) >>=
fun s -> result s i (Some (Option.default 0 k + j)))
end
in with_shelf res >>= fun (sh, ()) ->
tclEVARMAP >>= finish sh
in
if path_matches derivs [] then aux e tl
else
let filter =
if false (* in 8.6, still allow non-class subgoals
info.search_only_classes *) then fail_if_nonclass info
else Proofview.tclUNIT ()
in
ortac
(with_shelf (tac <*> filter) >>= fun s ->
let i = !idx in incr idx; result s i None)
(fun e' ->
if CErrors.noncritical (fst e') then
(pr_error e'; aux (merge_exceptions e e') tl)
else iraise e')
and aux e = function
| x :: xs -> onetac e x xs
| [] ->
if !foundone == false && !typeclasses_debug > 0 then
Feedback.msg_debug
(pr_depth info.search_depth ++ str": no match for " ++
Printer.pr_econstr_env (Goal.env gl) sigma concl ++
str ", " ++ int (List.length poss) ++
str" possibilities");
match e with
| (ReachedLimitEx,ie) -> Proofview.tclZERO ~info:ie ReachedLimitEx
| (_,ie) -> Proofview.tclZERO ~info:ie NoApplicableEx
in
if backtrack then aux (NoApplicableEx,Exninfo.null) poss
else tclONCE (aux (NoApplicableEx,Exninfo.null) poss)
let hints_tac hints info kont : unit Proofview.tactic =
Proofview.Goal.enter
(fun gl -> hints_tac_gl hints info kont gl)
let intro_tac info kont gl =
let open Proofview in
let env = Goal.env gl in
let sigma = Goal.sigma gl in
let decl = Tacmach.New.pf_last_hyp gl in
let hint =
make_resolve_hyp env sigma (Hint_db.transparent_state info.search_hints)
(true,false,false) info.search_only_classes empty_hint_info decl in
let ldb = Hint_db.add_list env sigma hint info.search_hints in
let info' =
{ info with search_hints = ldb; last_tac = lazy (str"intro");
search_depth = 1 :: 1 :: info.search_depth }
in kont info'
let intro info kont =
Proofview.tclBIND Tactics.intro
(fun _ -> Proofview.Goal.enter (fun gl -> intro_tac info kont gl))
let rec search_tac hints limit depth =
let kont info =
Proofview.numgoals >>= fun i ->
if !typeclasses_debug > 1 then
Feedback.msg_debug
(str"calling eauto recursively at depth " ++ int (succ depth)
++ str" on " ++ int i ++ str" subgoals");
search_tac hints limit (succ depth) info
in
fun info ->
if Int.equal depth (succ limit) then Proofview.tclZERO ReachedLimitEx
else
Proofview.tclOR (hints_tac hints info kont)
(fun e -> Proofview.tclOR (intro info kont)
(fun e' -> let (e, info) = merge_exceptions e e' in
Proofview.tclZERO ~info e))
let search_tac_gl ?st only_classes dep hints depth i sigma gls gl :
unit Proofview.tactic =
let open Proofview in
if false (* In 8.6, still allow non-class goals only_classes && not (is_class_type sigma (Goal.concl gl)) *) then
Tacticals.New.tclZEROMSG (str"Not a subgoal for a class")
else
let dep = dep || Proofview.unifiable sigma (Goal.goal (Proofview.Goal.assume gl)) gls in
let info = make_autogoal ?st only_classes dep (cut_of_hints hints) i gl in
search_tac hints depth 1 info
let search_tac ?(st=full_transparent_state) only_classes dep hints depth =
let open Proofview in
let tac sigma gls i =
Goal.enter
begin fun gl ->
search_tac_gl ~st only_classes dep hints depth (succ i) sigma gls gl end
in
Proofview.Unsafe.tclGETGOALS >>= fun gls ->
Proofview.tclEVARMAP >>= fun sigma ->
let j = List.length gls in
(tclDISPATCH (List.init j (fun i -> tac sigma gls i)))
let fix_iterative t =
let rec aux depth =
Proofview.tclOR
(t depth)
(function
| (ReachedLimitEx,_) -> aux (succ depth)
| (e,ie) -> Proofview.tclZERO ~info:ie e)
in aux 1
let fix_iterative_limit limit t =
let open Proofview in
let rec aux depth =
if Int.equal depth (succ limit) then tclZERO ReachedLimitEx
else tclOR (t depth) (function (ReachedLimitEx, _) -> aux (succ depth)
| (e,ie) -> Proofview.tclZERO ~info:ie e)
in aux 1
let eauto_tac ?(st=full_transparent_state) ?(unique=false)
~only_classes ?strategy ~depth ~dep hints =
let open Proofview in
let tac =
let search = search_tac ~st only_classes dep hints in
let dfs =
match strategy with
| None -> not (get_typeclasses_iterative_deepening ())
| Some Dfs -> true
| Some Bfs -> false
in
if dfs then
let depth = match depth with None -> -1 | Some d -> d in
search depth
else
match depth with
| None -> fix_iterative search
| Some l -> fix_iterative_limit l search
in
let error (e, ie) =
match e with
| ReachedLimitEx ->
Tacticals.New.tclFAIL 0 (str"Proof search reached its limit")
| NoApplicableEx ->
Tacticals.New.tclFAIL 0 (str"Proof search failed" ++
(if Option.is_empty depth then mt()
else str" without reaching its limit"))
| Proofview.MoreThanOneSuccess ->
Tacticals.New.tclFAIL 0 (str"Proof search failed: " ++
str"more than one success found")
| e -> Proofview.tclZERO ~info:ie e
in
let tac = Proofview.tclOR tac error in
let tac =
if unique then
Proofview.tclEXACTLY_ONCE Proofview.MoreThanOneSuccess tac
else tac
in
with_shelf numgoals >>= fun (initshelf, i) ->
(if !typeclasses_debug > 1 then
Feedback.msg_debug (str"Starting resolution with " ++ int i ++
str" goal(s) under focus and " ++
int (List.length initshelf) ++ str " shelved goal(s)" ++
(if only_classes then str " in only_classes mode" else str " in regular mode") ++
match depth with None -> str ", unbounded"
| Some i -> str ", with depth limit " ++ int i));
tac
let run_on_evars env evm p tac =
match evars_to_goals p evm with
| None -> None (* This happens only because there's no evar having p *)
| Some (goals, evm') ->
let goals =
if !typeclasses_dependency_order then
top_sort evm' goals
else List.map (fun (ev, _) -> ev) (Evar.Map.bindings goals)
in
let fgoals = Evd.future_goals evm in
let pgoal = Evd.principal_future_goal evm in
let _, pv = Proofview.init evm' [] in
let pv = Proofview.unshelve goals pv in
try
let (), pv', (unsafe, shelved, gaveup), _ =
Proofview.apply env tac pv
in
if Proofview.finished pv' then
let evm' = Proofview.return pv' in
assert(Evd.fold_undefined (fun ev _ acc ->
let okev = Evd.mem evm ev || List.mem ev shelved in
if not okev then
Feedback.msg_debug
(str "leaking evar " ++ int (Evar.repr ev) ++
spc () ++ pr_ev evm' ev);
acc && okev) evm' true);
let evm' = Evd.restore_future_goals evm' (shelved @ fgoals) pgoal in
let evm' = evars_reset_evd ~with_conv_pbs:true ~with_univs:false evm' evm in
Some evm'
else raise Not_found
with Logic_monad.TacticFailure _ -> raise Not_found
let evars_eauto env evd depth only_classes unique dep st hints p =
let eauto_tac = eauto_tac ~st ~unique ~only_classes ~depth ~dep:(unique || dep) hints in
let res = run_on_evars env evd p eauto_tac in
match res with
| None -> evd
| Some evd' -> evd'
let typeclasses_eauto env evd ?depth unique st hints p =
evars_eauto env evd depth true unique false st hints p
(** Typeclasses eauto is an eauto which tries to resolve only
goals of typeclass type, and assumes that the initially selected
evars in evd are independent of the rest of the evars *)
let typeclasses_resolve env evd debug depth unique p =
let db = searchtable_map typeclasses_db in
typeclasses_eauto env evd ?depth unique (Hint_db.transparent_state db) [db] p
end
(** Binding to either V85 or Search implementations. *)
let typeclasses_eauto ?(only_classes=false) ?(st=full_transparent_state)
?strategy ~depth dbs =
let dbs = List.map_filter
(fun db -> try Some (searchtable_map db)
with e when CErrors.noncritical e -> None)
dbs
in
let st = match dbs with x :: _ -> Hint_db.transparent_state x | _ -> st in
let depth = match depth with None -> get_typeclasses_depth () | Some l -> Some l in
if get_typeclasses_legacy_resolution () then
Proofview.V82.tactic
(fun gl ->
try V85.eauto85 depth ~only_classes ~st ?strategy dbs gl
with Not_found ->
Refiner.tclFAIL 0 (str"Proof search failed") gl)
else Search.eauto_tac ~st ~only_classes ?strategy ~depth ~dep:true dbs
(** We compute dependencies via a union-find algorithm.
Beware of the imperative effects on the partition structure,
it should not be shared, but only used locally. *)
module Intpart = Unionfind.Make(Evar.Set)(Evar.Map)
let deps_of_constraints cstrs evm p =
List.iter (fun (_, _, x, y) ->
let evx = Evarutil.undefined_evars_of_term evm (EConstr.of_constr x) in
let evy = Evarutil.undefined_evars_of_term evm (EConstr.of_constr y) in
Intpart.union_set (Evar.Set.union evx evy) p)
cstrs
let evar_dependencies pred evm p =
Evd.fold_undefined
(fun ev evi _ ->
if Typeclasses.is_resolvable evi && pred evm ev evi then
let evars = Evar.Set.add ev (Evarutil.undefined_evars_of_evar_info evm evi)
in Intpart.union_set evars p
else ())
evm ()
(** [split_evars] returns groups of undefined evars according to dependencies *)
let split_evars pred evm =
let p = Intpart.create () in
evar_dependencies pred evm p;
deps_of_constraints (snd (extract_all_conv_pbs evm)) evm p;
Intpart.partition p
let is_inference_forced p evd ev =
try
let evi = Evd.find_undefined evd ev in
if Typeclasses.is_resolvable evi && snd (p ev evi)
then
let (loc, k) = evar_source ev evd in
match k with
| Evar_kinds.ImplicitArg (_, _, b) -> b
| Evar_kinds.QuestionMark _ -> false
| _ -> true
else true
with Not_found -> assert false
let is_mandatory p comp evd =
Evar.Set.exists (is_inference_forced p evd) comp
(** In case of unsatisfiable constraints, build a nice error message *)
let error_unresolvable env comp evd =
let is_part ev = match comp with
| None -> true
| Some s -> Evar.Set.mem ev s
in
let fold ev evi (found, accu) =
let ev_class = class_of_constr evd (EConstr.of_constr evi.evar_concl) in
if not (Option.is_empty ev_class) && is_part ev then
(* focus on one instance if only one was searched for *)
if not found then (true, Some ev)
else (found, None)
else (found, accu)
in
let (_, ev) = Evd.fold_undefined fold evd (true, None) in
Pretype_errors.unsatisfiable_constraints env evd ev comp
(** Check if an evar is concerned by the current resolution attempt,
(and in particular is in the current component), and also update
its evar_info.
Invariant : this should only be applied to undefined evars,
and return undefined evar_info *)
let select_and_update_evars p oevd in_comp evd ev evi =
assert (evi.evar_body == Evar_empty);
try
let oevi = Evd.find_undefined oevd ev in
if Typeclasses.is_resolvable oevi then
Typeclasses.mark_unresolvable evi,
(in_comp ev && p evd ev evi)
else evi, false
with Not_found ->
Typeclasses.mark_unresolvable evi, p evd ev evi
(** Do we still have unresolved evars that should be resolved ? *)
let has_undefined p oevd evd =
let check ev evi = snd (p oevd ev evi) in
Evar.Map.exists check (Evd.undefined_map evd)
(** Revert the resolvability status of evars after resolution,
potentially unprotecting some evars that were set unresolvable
just for this call to resolution. *)
let revert_resolvability oevd evd =
let map ev evi =
try
if not (Typeclasses.is_resolvable evi) then
let evi' = Evd.find_undefined oevd ev in
if Typeclasses.is_resolvable evi' then
Typeclasses.mark_resolvable evi
else evi
else evi
with Not_found -> evi
in
Evd.raw_map_undefined map evd
exception Unresolved
(** If [do_split] is [true], we try to separate the problem in
several components and then solve them separately *)
let resolve_all_evars debug depth unique env p oevd do_split fail =
let split = if do_split then split_evars p oevd else [Evar.Set.empty] in
let in_comp comp ev = if do_split then Evar.Set.mem ev comp else true
in
let rec docomp evd = function
| [] -> revert_resolvability oevd evd
| comp :: comps ->
let p = select_and_update_evars p oevd (in_comp comp) in
try
let evd' =
if get_typeclasses_legacy_resolution () then
V85.resolve_all_evars_once debug depth unique p evd
else
Search.typeclasses_resolve env evd debug depth unique p
in
if has_undefined p oevd evd' then raise Unresolved;
docomp evd' comps
with Unresolved | Not_found ->
if fail && (not do_split || is_mandatory (p evd) comp evd)
then (* Unable to satisfy the constraints. *)
let comp = if do_split then Some comp else None in
error_unresolvable env comp evd
else (* Best effort: do nothing on this component *)
docomp evd comps
in docomp oevd split
let initial_select_evars filter =
fun evd ev evi ->
filter ev (snd evi.Evd.evar_source) &&
Typeclasses.is_class_evar evd evi
let resolve_typeclass_evars debug depth unique env evd filter split fail =
let evd =
try Evarconv.solve_unif_constraints_with_heuristics
~ts:(Typeclasses.classes_transparent_state ()) env evd
with e when CErrors.noncritical e -> evd
in
resolve_all_evars debug depth unique env
(initial_select_evars filter) evd split fail
let solve_inst env evd filter unique split fail =
resolve_typeclass_evars
(get_typeclasses_debug ())
(get_typeclasses_depth ())
unique env evd filter split fail
let _ =
Hook.set Typeclasses.solve_all_instances_hook solve_inst
let resolve_one_typeclass env ?(sigma=Evd.empty) gl unique =
let nc, gl, subst, _, _ = Evarutil.push_rel_context_to_named_context env sigma gl in
let (gl,t,sigma) =
Goal.V82.mk_goal sigma nc gl Store.empty in
let (ev, _) = destEvar sigma t in
let gls = { it = gl ; sigma = sigma; } in
let hints = searchtable_map typeclasses_db in
let st = Hint_db.transparent_state hints in
let depth = get_typeclasses_depth () in
let gls' =
if get_typeclasses_legacy_resolution () then
V85.eauto85 depth ~st [hints] gls
else
try
Proofview.V82.of_tactic
(Search.eauto_tac ~st ~only_classes:true ~depth [hints] ~dep:true) gls
with Refiner.FailError _ -> raise Not_found
in
let evd = sig_sig gls' in
let t' = mkEvar (ev, Array.of_list subst) in
let term = Evarutil.nf_evar evd t' in
evd, term
let _ =
Hook.set Typeclasses.solve_one_instance_hook
(fun x y z w -> resolve_one_typeclass x ~sigma:y z w)
(** Take the head of the arity of a constr.
Used in the partial application tactic. *)
let rec head_of_constr sigma t =
let t = strip_outer_cast sigma (collapse_appl sigma t) in
match EConstr.kind sigma t with
| Prod (_,_,c2) -> head_of_constr sigma c2
| LetIn (_,_,_,c2) -> head_of_constr sigma c2
| App (f,args) -> head_of_constr sigma f
| _ -> t
let head_of_constr h c =
Proofview.tclEVARMAP >>= fun sigma ->
let c = head_of_constr sigma c in
letin_tac None (Name h) c None Locusops.allHyps
let not_evar c =
Proofview.tclEVARMAP >>= fun sigma ->
match EConstr.kind sigma c with
| Evar _ -> Tacticals.New.tclFAIL 0 (str"Evar")
| _ -> Proofview.tclUNIT ()
let is_ground c =
let open Tacticals.New in
Proofview.tclEVARMAP >>= fun sigma ->
if Evarutil.is_ground_term sigma c then tclIDTAC
else tclFAIL 0 (str"Not ground")
let autoapply c i =
let open Proofview.Notations in
Proofview.Goal.enter begin fun gl ->
let flags = auto_unif_flags Evar.Set.empty
(Hints.Hint_db.transparent_state (Hints.searchtable_map i)) in
let cty = Tacmach.New.pf_unsafe_type_of gl c in
let ce = mk_clenv_from gl (c,cty) in
unify_e_resolve false flags gl
((c,cty,Univ.ContextSet.empty),0,ce) <*>
Proofview.tclEVARMAP >>= (fun sigma ->
let sigma = Typeclasses.mark_unresolvables ~filter:Typeclasses.all_goals sigma in
Proofview.Unsafe.tclEVARS sigma) end
|