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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 *)
(************************************************************************)
(* This file is (C) Copyright 2006-2015 Microsoft Corporation and Inria. *)
open Names
open Pp
open Term
open Tactics
open Tacticals
open Tacmach
open Coqlib
open Util
open Evd
open Printer
open Ssrmatching_plugin
open Ssrmatching
open Ssrast
open Ssrprinters
open Ssrcommon
open Ssrequality
open Ssrview
open Ssrelim
open Ssrbwd
module RelDecl = Context.Rel.Declaration
(** Extended intro patterns {{{ ***********************************************)
(* There are two ways of "applying" a view to term: *)
(* 1- using a view hint if the view is an instance of some *)
(* (reflection) inductive predicate. *)
(* 2- applying the view if it coerces to a function, adding *)
(* implicit arguments. *)
(* They require guessing the view hints and the number of *)
(* implicits, respectively, which we do by brute force. *)
let apply_type x xs = Proofview.V82.of_tactic (apply_type x xs)
let new_tac = Proofview.V82.of_tactic
let with_top tac gl =
tac_ctx
(tclTHENLIST [ introid top_id; tac (EConstr.mkVar top_id); new_tac (clear [top_id])])
gl
let tclTHENS_nonstrict tac tacl taclname gl =
let tacres = tac gl in
let n_gls = List.length (sig_it tacres) in
let n_tac = List.length tacl in
if n_gls = n_tac then tclTHENS_a (fun _ -> tacres) tacl gl else
if n_gls = 0 then tacres else
let pr_only n1 n2 = if n1 < n2 then str "only " else mt () in
let pr_nb n1 n2 name =
pr_only n1 n2 ++ int n1 ++ str (" " ^ String.plural n1 name) in
errorstrm (pr_nb n_tac n_gls taclname ++ spc ()
++ str "for " ++ pr_nb n_gls n_tac "subgoal")
let rec nat_of_n n =
if n = 0 then EConstr.mkConstruct path_of_O
else EConstr.mkApp (EConstr.mkConstruct path_of_S, [|nat_of_n (n-1)|])
let ssr_abstract_id = Summary.ref ~name:"SSR:abstractid" 0
let mk_abstract_id () = incr ssr_abstract_id; nat_of_n !ssr_abstract_id
let ssrmkabs id gl =
let env, concl = pf_env gl, Tacmach.pf_concl gl in
let step = begin fun sigma ->
let (sigma, (abstract_proof, abstract_ty)) =
let (sigma, (ty, _)) =
Evarutil.new_type_evar env sigma Evd.univ_flexible_alg in
let (sigma, ablock) = mkSsrConst "abstract_lock" env sigma in
let (sigma, lock) = Evarutil.new_evar env sigma ablock in
let (sigma, abstract) = mkSsrConst "abstract" env sigma in
let abstract_ty = EConstr.mkApp(abstract, [|ty;mk_abstract_id ();lock|]) in
let (sigma, m) = Evarutil.new_evar env sigma abstract_ty in
(sigma, (m, abstract_ty)) in
let sigma, kont =
let rd = RelDecl.LocalAssum (Name id, abstract_ty) in
let (sigma, ev) = Evarutil.new_evar (EConstr.push_rel rd env) sigma concl in
(sigma, ev)
in
(* pp(lazy(pr_econstr concl)); *)
let term = EConstr.(mkApp (mkLambda(Name id,abstract_ty,kont) ,[|abstract_proof|])) in
let sigma, _ = Typing.type_of env sigma term in
(sigma, term)
end in
Proofview.V82.of_tactic
(Proofview.tclTHEN
(Tactics.New.refine ~typecheck:false step)
(Proofview.tclFOCUS 1 3 Proofview.shelve)) gl
let ssrmkabstac ids =
List.fold_right (fun id tac -> tclTHENFIRST (ssrmkabs id) tac) ids tclIDTAC
(* introstac: for "move" and "clear", tclEQINTROS: for "case" and "elim" *)
(* This block hides the spaghetti-code needed to implement the only two *)
(* tactics that should be used to process intro patters. *)
(* The difficulty is that we don't want to always rename, but we can *)
(* compute needeed renamings only at runtime, so we theread a tree like *)
(* imperativestructure so that outer renamigs are inherited by inner *)
(* ipts and that the cler performed at the end of ipatstac clears hyps *)
(* eventually renamed at runtime. *)
let delayed_clear force rest clr gl =
let gl, ctx = pull_ctx gl in
let hyps = pf_hyps gl in
let () = if not force then List.iter (check_hyp_exists hyps) clr in
if List.exists (fun x -> force || is_name_in_ipats (hyp_id x) rest) clr then
let ren_clr, ren =
List.split (List.map (fun x ->
let x = hyp_id x in
let x' = mk_anon_id (Id.to_string x) gl in
x', (x, x')) clr) in
let ctx = { ctx with delayed_clears = ren_clr @ ctx.delayed_clears } in
let gl = push_ctx ctx gl in
tac_ctx (Proofview.V82.of_tactic (rename_hyp ren)) gl
else
let ctx = { ctx with delayed_clears = hyps_ids clr @ ctx.delayed_clears } in
let gl = push_ctx ctx gl in
tac_ctx tclIDTAC gl
(* Common code to handle generalization lists along with the defective case *)
let with_defective maintac deps clr ist gl =
let top_id =
match EConstr.kind_of_type (project gl) (pf_concl gl) with
| ProdType (Name id, _, _)
when has_discharged_tag (Id.to_string id) -> id
| _ -> top_id in
let top_gen = mkclr clr, cpattern_of_id top_id in
tclTHEN (introid top_id) (maintac deps top_gen ist) gl
let with_defective_a maintac deps clr ist gl =
let sigma = sig_sig gl in
let top_id =
match EConstr.kind_of_type sigma (without_ctx pf_concl gl) with
| ProdType (Name id, _, _)
when has_discharged_tag (Id.to_string id) -> id
| _ -> top_id in
let top_gen = mkclr clr, cpattern_of_id top_id in
tclTHEN_a (tac_ctx (introid top_id)) (maintac deps top_gen ist) gl
let with_dgens (gensl, clr) maintac ist = match gensl with
| [deps; []] -> with_defective maintac deps clr ist
| [deps; gen :: gens] ->
tclTHEN (genstac (gens, clr) ist) (maintac deps gen ist)
| [gen :: gens] -> tclTHEN (genstac (gens, clr) ist) (maintac [] gen ist)
| _ -> with_defective maintac [] clr ist
let viewmovetac_aux ?(next=ref []) clear name_ref (_, vl as v) _ gen ist gl =
let cl, c, clr, gl, gen_pat =
let gl, ctx = pull_ctx gl in
let _, gen_pat, a, b, c, ucst, gl = pf_interp_gen_aux ist gl false gen in
a, b ,c, push_ctx ctx (pf_merge_uc ucst gl), gen_pat in
let clr = if clear then clr else [] in
name_ref := (match id_of_pattern gen_pat with Some id -> id | _ -> top_id);
let clr = if clear then clr else [] in
if vl = [] then tac_ctx (genclrtac cl [c] clr) gl
else
let _, _, gl =
pfa_with_view ist ~next v cl c
(fun cl c -> tac_ctx (genclrtac cl [c] clr)) clr gl in
gl
let move_top_with_view ~next c r v =
with_defective_a (viewmovetac_aux ~next c r v) [] []
type block_names = (int * EConstr.types array) option
let (introstac : ?ist:Tacinterp.interp_sign -> ssripats -> Tacmach.tactic),
(tclEQINTROS : ?ind:block_names ref -> ?ist:Tacinterp.interp_sign ->
Tacmach.tactic -> Tacmach.tactic -> ssripats ->
Tacmach.tactic)
=
let rec ipattac ?ist ~next p : tac_ctx tac_a = fun gl ->
(* pp(lazy(str"ipattac: " ++ pr_ipat p)); *)
match p with
| IPatAnon Drop ->
let id, gl = with_ctx new_wild_id gl in
tac_ctx (introid id) gl
| IPatAnon All -> tac_ctx intro_all gl
(* TODO
| IPatAnon Temporary ->
let (id, orig), gl = with_ctx new_tmp_id gl in
introid_a ~orig id gl
*)
| IPatCase(iorpat) ->
tclIORPAT ?ist (with_top (ssrscasetac false)) iorpat gl
| IPatInj iorpat ->
tclIORPAT ?ist (with_top (ssrscasetac true)) iorpat gl
| IPatRewrite (occ, dir) ->
with_top (ipat_rewrite occ dir) gl
| IPatId id -> tac_ctx (introid id) gl
| IPatNewHidden idl -> tac_ctx (ssrmkabstac idl) gl
| IPatSimpl sim ->
tac_ctx (simpltac sim) gl
| IPatClear clr ->
delayed_clear false !next clr gl
| IPatAnon One -> tac_ctx intro_anon gl
| IPatNoop -> tac_ctx tclIDTAC gl
| IPatView v ->
let ist =
match ist with Some x -> x | _ -> anomaly "ipat: view with no ist" in
let next_keeps =
match !next with (IPatCase _ | IPatRewrite _)::_ -> false | _ -> true in
let top_id = ref top_id in
tclTHENLIST_a [
(move_top_with_view ~next next_keeps top_id (next_keeps,v) ist);
(fun gl ->
let hyps = without_ctx pf_hyps gl in
if not next_keeps && test_hypname_exists hyps !top_id then
delayed_clear true !next [SsrHyp (Loc.tag !top_id)] gl
else tac_ctx tclIDTAC gl)]
gl
and tclIORPAT ?ist tac = function
| [[]] -> tac
| orp -> tclTHENS_nonstrict tac (List.map (ipatstac ?ist) orp) "intro pattern"
and ipatstac ?ist ipats gl =
let rec aux ipats gl =
match ipats with
| [] -> tac_ctx tclIDTAC gl
| p :: ps ->
let next = ref ps in
let gl = ipattac ?ist ~next p gl in
tac_on_all gl (aux !next)
in
aux ipats gl
in
let rec split_itacs ?ist ~ind tac' = function
| (IPatSimpl _ | IPatClear _ as spat) :: ipats' ->
let tac = ipattac ?ist ~next:(ref ipats') spat in
split_itacs ?ist ~ind (tclTHEN_a tac' tac) ipats'
| IPatCase iorpat :: ipats' ->
tclIORPAT ?ist tac' iorpat, ipats'
| ipats' -> tac', ipats' in
let combine_tacs tac eqtac ipats ?ist ~ind gl =
let tac1, ipats' = split_itacs ?ist ~ind tac ipats in
let tac2 = ipatstac ?ist ipats' in
tclTHENLIST_a [ tac1; eqtac; tac2 ] gl in
(* Exported code *)
let introstac ?ist ipats gl =
with_fresh_ctx (tclTHENLIST_a [
ipatstac ?ist ipats;
gen_tmp_ids ?ist;
clear_wilds_and_tmp_and_delayed_ids
]) gl in
let tclEQINTROS ?(ind=ref None) ?ist tac eqtac ipats gl =
with_fresh_ctx (tclTHENLIST_a [
combine_tacs (tac_ctx tac) (tac_ctx eqtac) ipats ?ist ~ind;
gen_tmp_ids ?ist;
clear_wilds_and_tmp_and_delayed_ids;
]) gl in
introstac, tclEQINTROS
;;
(* Intro patterns processing for elim tactic*)
let elim_intro_tac ipats ?ist what eqid ssrelim is_rec clr gl =
(* Utils of local interest only *)
let iD s ?t gl = let t = match t with None -> pf_concl gl | Some x -> x in
ppdebug(lazy Pp.(str s ++ pr_econstr t)); Tacticals.tclIDTAC gl in
let protectC, gl = pf_mkSsrConst "protect_term" gl in
let eq, gl = pf_fresh_global (Coqlib.build_coq_eq ()) gl in
let eq = EConstr.of_constr eq in
let fire_subst gl t = Reductionops.nf_evar (project gl) t in
let intro_eq =
match eqid with
| Some (IPatId ipat) when not is_rec ->
let rec intro_eq gl = match EConstr.kind_of_type (project gl) (pf_concl gl) with
| ProdType (_, src, tgt) ->
(match EConstr.kind_of_type (project gl) src with
| AtomicType (hd, _) when EConstr.eq_constr (project gl) hd protectC ->
Tacticals.tclTHENLIST [unprotecttac; introid ipat] gl
| _ -> Tacticals.tclTHENLIST [ iD "IA"; Ssrcommon.intro_anon; intro_eq] gl)
|_ -> errorstrm (Pp.str "Too many names in intro pattern") in
intro_eq
| Some (IPatId ipat) ->
let name gl = mk_anon_id "K" gl in
let intro_lhs gl =
let elim_name = match clr, what with
| [SsrHyp(_, x)], _ -> x
| _, `EConstr(_,_,t) when EConstr.isVar (project gl) t -> EConstr.destVar (project gl) t
| _ -> name gl in
if is_name_in_ipats elim_name ipats then introid (name gl) gl
else introid elim_name gl
in
let rec gen_eq_tac gl =
let concl = pf_concl gl in
let ctx, last = EConstr.decompose_prod_assum (project gl) concl in
let args = match EConstr.kind_of_type (project gl) last with
| AtomicType (hd, args) -> assert(EConstr.eq_constr (project gl) hd protectC); args
| _ -> assert false in
let case = args.(Array.length args-1) in
if not(EConstr.Vars.closed0 (project gl) case) then Tacticals.tclTHEN Ssrcommon.intro_anon gen_eq_tac gl
else
let gl, case_ty = pfe_type_of gl case in
let refl = EConstr.mkApp (eq, [|EConstr.Vars.lift 1 case_ty; EConstr.mkRel 1; EConstr.Vars.lift 1 case|]) in
let new_concl = fire_subst gl
EConstr.(mkProd (Name (name gl), case_ty, mkArrow refl (Vars.lift 2 concl))) in
let erefl, gl = mkRefl case_ty case gl in
let erefl = fire_subst gl erefl in
apply_type new_concl [case;erefl] gl in
Tacticals.tclTHENLIST [gen_eq_tac; intro_lhs; introid ipat]
| _ -> Tacticals.tclIDTAC in
let unprot = if eqid <> None && is_rec then unprotecttac else Tacticals.tclIDTAC in
tclEQINTROS ?ist ssrelim (Tacticals.tclTHENLIST [intro_eq; unprot]) ipats gl
(* General case *)
let tclINTROS ist t ip = tclEQINTROS ~ist (t ist) tclIDTAC ip
(* }}} *)
let viewmovetac ?next v deps gen ist gl =
with_fresh_ctx
(tclTHEN_a
(viewmovetac_aux ?next true (ref top_id) v deps gen ist)
clear_wilds_and_tmp_and_delayed_ids)
gl
let mkCoqEq gl =
let sigma = project gl in
let (sigma, eq) = EConstr.fresh_global (pf_env gl) sigma (build_coq_eq_data()).eq in
let gl = { gl with sigma } in
eq, gl
let mkEq dir cl c t n gl =
let open EConstr in
let eqargs = [|t; c; c|] in eqargs.(dir_org dir) <- mkRel n;
let eq, gl = mkCoqEq gl in
let refl, gl = mkRefl t c gl in
mkArrow (mkApp (eq, eqargs)) (EConstr.Vars.lift 1 cl), refl, gl
let pushmoveeqtac cl c gl =
let open EConstr in
let x, t, cl1 = destProd (project gl) cl in
let cl2, eqc, gl = mkEq R2L cl1 c t 1 gl in
apply_type (mkProd (x, t, cl2)) [c; eqc] gl
let eqmovetac _ gen ist gl =
let cl, c, _, gl = pf_interp_gen ist gl false gen in pushmoveeqtac cl c gl
let movehnftac gl = match EConstr.kind (project gl) (pf_concl gl) with
| Prod _ | LetIn _ -> tclIDTAC gl
| _ -> new_tac hnf_in_concl gl
let rec eqmoveipats eqpat = function
| (IPatSimpl _ | IPatClear _ as ipat) :: ipats -> ipat :: eqmoveipats eqpat ipats
| (IPatAnon All :: _ | []) as ipats -> IPatAnon One :: eqpat :: ipats
| ipat :: ipats -> ipat :: eqpat :: ipats
let ssrmovetac ist = function
| _::_ as view, (_, (dgens, ipats)) ->
let next = ref ipats in
let dgentac = with_dgens dgens (viewmovetac ~next (true, view)) ist in
tclTHEN dgentac (fun gl -> introstac ~ist !next gl)
| _, (Some pat, (dgens, ipats)) ->
let dgentac = with_dgens dgens eqmovetac ist in
tclTHEN dgentac (introstac ~ist (eqmoveipats pat ipats))
| _, (_, (([gens], clr), ipats)) ->
let gentac = genstac (gens, clr) ist in
tclTHEN gentac (introstac ~ist ipats)
| _, (_, ((_, clr), ipats)) ->
tclTHENLIST [movehnftac; cleartac clr; introstac ~ist ipats]
let ssrcasetac ist (view, (eqid, (dgens, ipats))) =
let ndefectcasetac view eqid ipats deps ((_, occ), _ as gen) ist gl =
let simple = (eqid = None && deps = [] && occ = None) in
let cl, c, clr, gl = pf_interp_gen ist gl true gen in
let _,vc, gl =
if view = [] then c,c, gl else pf_with_view_linear ist gl (false, view) cl c in
if simple && is_injection_case vc gl then
tclTHENLIST [perform_injection vc; cleartac clr; introstac ~ist ipats] gl
else
(* macro for "case/v E: x" ---> "case E: x / (v x)" *)
let deps, clr, occ =
if view <> [] && eqid <> None && deps = [] then [gen], [], None
else deps, clr, occ in
ssrelim ~is_case:true ~ist deps (`EConstr (clr,occ, vc)) eqid (elim_intro_tac ipats) gl
in
with_dgens dgens (ndefectcasetac view eqid ipats) ist
let ssrapplytac ist (views, (_, ((gens, clr), intros))) =
tclINTROS ist (inner_ssrapplytac views gens clr) intros
(* vim: set filetype=ocaml foldmethod=marker: *)
|