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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2016 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open CErrors
open Util
open Pp
open Evd
open Tacmach
open Tacintern
open Decl_expr
open Decl_mode
open Decl_interp
open Glob_term
open Glob_ops
open Names
open Nameops
open Declarations
open Tactics
open Tacticals
open Term
open Vars
open Termops
open Namegen
open Goptions
open Misctypes
open Sigma.Notations
open Context.Named.Declaration
(* Strictness option *)
let clear ids { it = goal; sigma } =
let ids = List.fold_left (fun accu x -> Id.Set.add x accu) Id.Set.empty ids in
let env = Goal.V82.env sigma goal in
let sign = Goal.V82.hyps sigma goal in
let cl = Goal.V82.concl sigma goal in
let evdref = ref (Evd.clear_metas sigma) in
let (hyps, concl) =
try Evarutil.clear_hyps_in_evi env evdref sign cl ids
with Evarutil.ClearDependencyError (id, _) ->
errorlabstrm "" (str "Cannot clear " ++ pr_id id)
in
let sigma = !evdref in
let (gl,ev,sigma) = Goal.V82.mk_goal sigma hyps concl (Goal.V82.extra sigma goal) in
let sigma = Goal.V82.partial_solution_to sigma goal gl ev in
{ it = [gl]; sigma }
let get_its_info gls = get_info gls.sigma gls.it
let get_strictness,set_strictness =
let strictness = ref false in
(fun () -> (!strictness)),(fun b -> strictness:=b)
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "strict proofs";
optkey = ["Strict";"Proofs"];
optread = get_strictness;
optwrite = set_strictness }
let tcl_change_info_gen info_gen =
(fun gls ->
let it = sig_it gls in
let concl = pf_concl gls in
let hyps = Goal.V82.hyps (project gls) it in
let extra = Goal.V82.extra (project gls) it in
let (gl,ev,sigma) = Goal.V82.mk_goal (project gls) hyps concl (info_gen extra) in
let sigma = Goal.V82.partial_solution sigma it ev in
{ it = [gl] ; sigma= sigma; } )
let tcl_change_info info gls =
let info_gen s = Store.set s Decl_mode.info info in
tcl_change_info_gen info_gen gls
let tcl_erase_info gls =
let info_gen s = Store.remove s Decl_mode.info in
tcl_change_info_gen info_gen gls
let special_whd gl=
let infos=CClosure.create_clos_infos CClosure.all (pf_env gl) in
(fun t -> CClosure.whd_val infos (CClosure.inject t))
let special_nf gl=
let infos=CClosure.create_clos_infos CClosure.betaiotazeta (pf_env gl) in
(fun t -> CClosure.norm_val infos (CClosure.inject t))
let is_good_inductive env ind =
let mib,oib = Inductive.lookup_mind_specif env ind in
Int.equal oib.mind_nrealargs 0 && not (Inductiveops.mis_is_recursive (ind,mib,oib))
let check_not_per pts =
if not (Proof.is_done pts) then
match get_stack pts with
Per (_,_,_,_)::_ ->
error "You are inside a proof per cases/induction.\n\
Please \"suppose\" something or \"end\" it now."
| _ -> ()
let mk_evd metalist gls =
let evd0= clear_metas (sig_sig gls) in
let add_one (meta,typ) evd =
meta_declare meta typ evd in
List.fold_right add_one metalist evd0
let is_tmp id = (Id.to_string id).[0] == '_'
let tmp_ids gls =
let ctx = pf_hyps gls in
match ctx with
[] -> []
| _::q -> List.filter is_tmp (ids_of_named_context q)
let clean_tmp gls =
let clean_id id0 gls0 =
tclTRY (clear [id0]) gls0 in
let rec clean_all = function
[] -> tclIDTAC
| id :: rest -> tclTHEN (clean_id id) (clean_all rest)
in
clean_all (tmp_ids gls) gls
let assert_postpone id t =
assert_before (Name id) t
(* start a proof *)
let start_proof_tac gls=
let info={pm_stack=[]} in
tcl_change_info info gls
let go_to_proof_mode () =
ignore (Pfedit.by (Proofview.V82.tactic start_proof_tac));
let p = Proof_global.give_me_the_proof () in
Decl_mode.focus p
(* closing gaps *)
(* spiwack: should use [Proofview.give_up] but that would require
moving the whole declarative mode into the new proof engine. It
will eventually have to be done.
As far as I can tell, [daimon_tac] is used after a [thus thesis],
it will leave uninstantiated variables instead of giving a relevant
message at [Qed]. *)
let daimon_tac gls =
set_daimon_flag ();
{it=[];sigma=sig_sig gls;}
let daimon_instr env p =
let (p,(status,_)) =
Proof.run_tactic env begin
Proofview.tclINDEPENDENT Proofview.give_up
end p
in
p,status
let do_daimon () =
let env = Global.env () in
let status =
Proof_global.with_current_proof begin fun _ p ->
daimon_instr env p
end
in
if not status then Feedback.feedback Feedback.AddedAxiom else ()
(* post-instruction focus management *)
let goto_current_focus () =
Decl_mode.unfocus ()
(* spiwack: used to catch errors indicating lack of "focusing command"
in the proof tree. In the current implementation, however, entering
the declarative mode puts a focus first, there should, therefore,
never be exception raised here. *)
let goto_current_focus_or_top () =
goto_current_focus ()
(* return *)
let close_tactic_mode () =
try do_daimon ();goto_current_focus ()
with Not_found ->
error "\"return\" cannot be used outside of Declarative Proof Mode."
let return_from_tactic_mode () =
close_tactic_mode ()
(* end proof/claim *)
let close_block bt pts =
if Proof.no_focused_goal pts then
goto_current_focus ()
else
let stack =
if Proof.is_done pts then
get_top_stack pts
else
get_stack pts
in
match bt,stack with
B_claim, Claim::_ | B_focus, Focus_claim::_ | B_proof, [] ->
do_daimon ();goto_current_focus ()
| _, Claim::_ ->
error "\"end claim\" expected."
| _, Focus_claim::_ ->
error "\"end focus\" expected."
| _, [] ->
error "\"end proof\" expected."
| _, (Per (et,_,_,_)::_|Suppose_case::Per (et,_,_,_)::_) ->
begin
match et with
ET_Case_analysis -> error "\"end cases\" expected."
| ET_Induction -> error "\"end induction\" expected."
end
| _,_ -> anomaly (Pp.str "Lonely suppose on stack.")
(* utility for suppose / suppose it is *)
let close_previous_case pts =
if
Proof.is_done pts
then
match get_top_stack pts with
Per (et,_,_,_) :: _ -> anomaly (Pp.str "Weird case occurred ...")
| Suppose_case :: Per (et,_,_,_) :: _ ->
goto_current_focus ()
| _ -> error "Not inside a proof per cases or induction."
else
match get_stack pts with
Per (et,_,_,_) :: _ -> ()
| Suppose_case :: Per (et,_,_,_) :: _ ->
do_daimon ();goto_current_focus ()
| _ -> error "Not inside a proof per cases or induction."
(* Proof instructions *)
(* automation *)
let filter_hyps f gls =
let filter_aux id =
let id = get_id id in
if f id then
tclIDTAC
else
tclTRY (clear [id]) in
tclMAP filter_aux (pf_hyps gls) gls
let local_hyp_prefix = Id.of_string "___"
let add_justification_hyps keep items gls =
let add_aux c gls=
match kind_of_term c with
Var id ->
keep:=Id.Set.add id !keep;
tclIDTAC gls
| _ ->
let id=pf_get_new_id local_hyp_prefix gls in
keep:=Id.Set.add id !keep;
tclTHEN (Proofview.V82.of_tactic (letin_tac None (Names.Name id) c None Locusops.nowhere))
(Proofview.V82.of_tactic (clear_body [id])) gls in
tclMAP add_aux items gls
let prepare_goal items gls =
let tokeep = ref Id.Set.empty in
let auxres = add_justification_hyps tokeep items gls in
tclTHENLIST
[ (fun _ -> auxres);
filter_hyps (let keep = !tokeep in fun id -> Id.Set.mem id keep)] gls
let my_automation_tac = ref
(Proofview.tclZERO (CErrors.make_anomaly (Pp.str"No automation registered")))
let register_automation_tac tac = my_automation_tac:= tac
let automation_tac = Proofview.tclBIND (Proofview.tclUNIT ()) (fun () -> !my_automation_tac)
let warn_insufficient_justification =
CWarnings.create ~name:"declmode-insufficient-justification" ~category:"declmode"
(fun () -> strbrk "Insufficient justification.")
let justification tac gls=
tclORELSE
(tclSOLVE [tclTHEN tac (Proofview.V82.of_tactic assumption)])
(fun gls ->
if get_strictness () then
error "Insufficient justification."
else
begin
warn_insufficient_justification ();
daimon_tac gls
end) gls
let default_justification elems gls=
justification (tclTHEN (prepare_goal elems) (Proofview.V82.of_tactic automation_tac)) gls
(* code for conclusion refining *)
let constant dir s = lazy (Coqlib.gen_constant "Declarative" dir s)
let _and = constant ["Init";"Logic"] "and"
let _and_rect = constant ["Init";"Logic"] "and_rect"
let _prod = constant ["Init";"Datatypes"] "prod"
let _prod_rect = constant ["Init";"Datatypes"] "prod_rect"
let _ex = constant ["Init";"Logic"] "ex"
let _ex_ind = constant ["Init";"Logic"] "ex_ind"
let _sig = constant ["Init";"Specif"] "sig"
let _sig_rect = constant ["Init";"Specif"] "sig_rect"
let _sigT = constant ["Init";"Specif"] "sigT"
let _sigT_rect = constant ["Init";"Specif"] "sigT_rect"
type stackd_elt =
{se_meta:metavariable;
se_type:types;
se_last_meta:metavariable;
se_meta_list:(metavariable*types) list;
se_evd: evar_map}
let rec replace_in_list m l = function
[] -> raise Not_found
| c::q -> if Int.equal m (fst c) then l@q else c::replace_in_list m l q
let enstack_subsubgoals env se stack gls=
let hd,params = decompose_app (special_whd gls se.se_type) in
match kind_of_term hd with
Ind (ind,u as indu) when is_good_inductive env ind -> (* MS: FIXME *)
let mib,oib=
Inductive.lookup_mind_specif env ind in
let gentypes=
Inductive.arities_of_constructors indu (mib,oib) in
let process i gentyp =
let constructor = mkConstructU ((ind,succ i),u)
(* constructors numbering*) in
let appterm = applist (constructor,params) in
let apptype = prod_applist gentyp params in
let rc,_ = Reduction.dest_prod env apptype in
let rec meta_aux last lenv = function
[] -> (last,lenv,[])
| decl::q ->
let nlast=succ last in
let (llast,holes,metas) =
meta_aux nlast (mkMeta nlast :: lenv) q in
let open Context.Rel.Declaration in
(llast,holes,(nlast,special_nf gls (substl lenv (get_type decl)))::metas) in
let (nlast,holes,nmetas) =
meta_aux se.se_last_meta [] (List.rev rc) in
let refiner = applist (appterm,List.rev holes) in
let evd = meta_assign se.se_meta
(refiner,(Conv,TypeProcessed (* ? *))) se.se_evd in
let ncreated = replace_in_list
se.se_meta nmetas se.se_meta_list in
let evd0 = List.fold_left
(fun evd (m,typ) -> meta_declare m typ evd) evd nmetas in
List.iter (fun (m,typ) ->
Stack.push
{se_meta=m;
se_type=typ;
se_evd=evd0;
se_meta_list=ncreated;
se_last_meta=nlast} stack) (List.rev nmetas)
in
Array.iteri process gentypes
| _ -> ()
let rec nf_list evd =
function
[] -> []
| (m,typ)::others ->
if meta_defined evd m then
nf_list evd others
else
(m,Reductionops.nf_meta evd typ)::nf_list evd others
let find_subsubgoal c ctyp skip submetas gls =
let env= pf_env gls in
let concl = pf_concl gls in
let evd = mk_evd ((0,concl)::submetas) gls in
let stack = Stack.create () in
let max_meta =
List.fold_left (fun a (m,_) -> max a m) 0 submetas in
let _ = Stack.push
{se_meta=0;
se_type=concl;
se_last_meta=max_meta;
se_meta_list=[0,concl];
se_evd=evd} stack in
let rec dfs n =
let se = Stack.pop stack in
try
let unifier =
Unification.w_unify env se.se_evd Reduction.CUMUL
~flags:(Unification.elim_flags ()) ctyp se.se_type in
if n <= 0 then
{se with
se_evd=meta_assign se.se_meta
(c,(Conv,TypeNotProcessed (* ?? *))) unifier;
se_meta_list=replace_in_list
se.se_meta submetas se.se_meta_list}
else
dfs (pred n)
with e when CErrors.noncritical e ->
begin
enstack_subsubgoals env se stack gls;
dfs n
end in
let nse= try dfs skip with Stack.Empty -> raise Not_found in
nf_list nse.se_evd nse.se_meta_list,Reductionops.nf_meta nse.se_evd (mkMeta 0)
let concl_refiner metas body gls =
let concl = pf_concl gls in
let evd = sig_sig gls in
let env = pf_env gls in
let sort = family_of_sort (Typing.e_sort_of env (ref evd) concl) in
let rec aux env avoid subst = function
[] -> anomaly ~label:"concl_refiner" (Pp.str "cannot happen")
| (n,typ)::rest ->
let _A = subst_meta subst typ in
let x = id_of_name_using_hdchar env _A Anonymous in
let _x = fresh_id avoid x gls in
let nenv = Environ.push_named (LocalAssum (_x,_A)) env in
let asort = family_of_sort (Typing.e_sort_of nenv (ref evd) _A) in
let nsubst = (n,mkVar _x)::subst in
if List.is_empty rest then
asort,_A,mkNamedLambda _x _A (subst_meta nsubst body)
else
let bsort,_B,nbody =
aux nenv (_x::avoid) ((n,mkVar _x)::subst) rest in
let body = mkNamedLambda _x _A nbody in
if occur_term (mkVar _x) _B then
begin
let _P = mkNamedLambda _x _A _B in
match bsort,sort with
InProp,InProp ->
let _AxB = mkApp(Lazy.force _ex,[|_A;_P|]) in
InProp,_AxB,
mkApp(Lazy.force _ex_ind,[|_A;_P;concl;body|])
| InProp,_ ->
let _AxB = mkApp(Lazy.force _sig,[|_A;_P|]) in
let _P0 = mkLambda(Anonymous,_AxB,concl) in
InType,_AxB,
mkApp(Lazy.force _sig_rect,[|_A;_P;_P0;body|])
| _,_ ->
let _AxB = mkApp(Lazy.force _sigT,[|_A;_P|]) in
let _P0 = mkLambda(Anonymous,_AxB,concl) in
InType,_AxB,
mkApp(Lazy.force _sigT_rect,[|_A;_P;_P0;body|])
end
else
begin
match asort,bsort with
InProp,InProp ->
let _AxB = mkApp(Lazy.force _and,[|_A;_B|]) in
InProp,_AxB,
mkApp(Lazy.force _and_rect,[|_A;_B;concl;body|])
|_,_ ->
let _AxB = mkApp(Lazy.force _prod,[|_A;_B|]) in
let _P0 = mkLambda(Anonymous,_AxB,concl) in
InType,_AxB,
mkApp(Lazy.force _prod_rect,[|_A;_B;_P0;body|])
end
in
let (_,_,prf) = aux env [] [] metas in
mkApp(prf,[|mkMeta 1|])
let thus_tac c ctyp submetas gls =
let list,proof =
try
find_subsubgoal c ctyp 0 submetas gls
with Not_found ->
error "I could not relate this statement to the thesis." in
if List.is_empty list then
Proofview.V82.of_tactic (exact_check proof) gls
else
let refiner = concl_refiner list proof gls in
Tacmach.refine refiner gls
(* general forward step *)
let mk_stat_or_thesis info gls = function
This c -> c
| Thesis (For _ ) ->
error "\"thesis for ...\" is not applicable here."
| Thesis Plain -> pf_concl gls
let just_tac _then cut info gls0 =
let last_item =
if _then then
try [mkVar (get_last (pf_env gls0))]
with UserError _ ->
error "\"then\" and \"hence\" require at least one previous fact"
else []
in
let items_tac gls =
match cut.cut_by with
None -> tclIDTAC gls
| Some items -> prepare_goal (last_item@items) gls in
let method_tac gls =
match cut.cut_using with
None ->
Proofview.V82.of_tactic automation_tac gls
| Some tac ->
Proofview.V82.of_tactic (Tacinterp.tactic_of_value (Tacinterp.default_ist ()) tac) gls in
justification (tclTHEN items_tac method_tac) gls0
let instr_cut mkstat _thus _then cut gls0 =
let info = get_its_info gls0 in
let stat = cut.cut_stat in
let (c_id,_) = match stat.st_label with
Anonymous ->
pf_get_new_id (Id.of_string "_fact") gls0,false
| Name id -> id,true in
let c_stat = mkstat info gls0 stat.st_it in
let thus_tac gls=
if _thus then
thus_tac (mkVar c_id) c_stat [] gls
else tclIDTAC gls in
tclTHENS (Proofview.V82.of_tactic (assert_postpone c_id c_stat))
[tclTHEN tcl_erase_info (just_tac _then cut info);
thus_tac] gls0
(* iterated equality *)
let _eq = lazy (Universes.constr_of_global (Coqlib.glob_eq))
let decompose_eq id gls =
let typ = pf_get_hyp_typ gls id in
let whd = (special_whd gls typ) in
match kind_of_term whd with
App (f,args)->
if eq_constr f (Lazy.force _eq) && Int.equal (Array.length args) 3
then (args.(0),
args.(1),
args.(2))
else error "Previous step is not an equality."
| _ -> error "Previous step is not an equality."
let instr_rew _thus rew_side cut gls0 =
let last_id =
try get_last (pf_env gls0)
with UserError _ -> error "No previous equality."
in
let typ,lhs,rhs = decompose_eq last_id gls0 in
let items_tac gls =
match cut.cut_by with
None -> tclIDTAC gls
| Some items -> prepare_goal items gls in
let method_tac gls =
match cut.cut_using with
None ->
Proofview.V82.of_tactic automation_tac gls
| Some tac ->
Proofview.V82.of_tactic (Tacinterp.tactic_of_value (Tacinterp.default_ist ()) tac) gls in
let just_tac gls =
justification (tclTHEN items_tac method_tac) gls in
let (c_id,_) = match cut.cut_stat.st_label with
Anonymous ->
pf_get_new_id (Id.of_string "_eq") gls0,false
| Name id -> id,true in
let thus_tac new_eq gls=
if _thus then
thus_tac (mkVar c_id) new_eq [] gls
else tclIDTAC gls in
match rew_side with
Lhs ->
let new_eq = mkApp(Lazy.force _eq,[|typ;cut.cut_stat.st_it;rhs|]) in
tclTHENS (Proofview.V82.of_tactic (assert_postpone c_id new_eq))
[tclTHEN tcl_erase_info
(tclTHENS (Proofview.V82.of_tactic (transitivity lhs))
[just_tac;Proofview.V82.of_tactic (exact_check (mkVar last_id))]);
thus_tac new_eq] gls0
| Rhs ->
let new_eq = mkApp(Lazy.force _eq,[|typ;lhs;cut.cut_stat.st_it|]) in
tclTHENS (Proofview.V82.of_tactic (assert_postpone c_id new_eq))
[tclTHEN tcl_erase_info
(tclTHENS (Proofview.V82.of_tactic (transitivity rhs))
[Proofview.V82.of_tactic (exact_check (mkVar last_id));just_tac]);
thus_tac new_eq] gls0
(* tactics for claim/focus *)
let instr_claim _thus st gls0 =
let info = get_its_info gls0 in
let (id,_) = match st.st_label with
Anonymous -> pf_get_new_id (Id.of_string "_claim") gls0,false
| Name id -> id,true in
let thus_tac gls=
if _thus then
thus_tac (mkVar id) st.st_it [] gls
else tclIDTAC gls in
let ninfo1 = {pm_stack=
(if _thus then Focus_claim else Claim)::info.pm_stack} in
tclTHENS (Proofview.V82.of_tactic (assert_postpone id st.st_it))
[thus_tac;
tcl_change_info ninfo1] gls0
(* tactics for assume *)
let push_intro_tac coerce nam gls =
let (hid,_) =
match nam with
Anonymous -> pf_get_new_id (Id.of_string "_hyp") gls,false
| Name id -> id,true in
tclTHENLIST
[Proofview.V82.of_tactic (intro_mustbe_force hid);
coerce hid]
gls
let assume_tac hyps gls =
List.fold_right
(fun (Hvar st | Hprop st) ->
tclTHEN
(push_intro_tac
(fun id ->
Proofview.V82.of_tactic (convert_hyp (LocalAssum (id,st.st_it)))) st.st_label))
hyps tclIDTAC gls
let assume_hyps_or_theses hyps gls =
List.fold_right
(function
(Hvar {st_label=nam;st_it=c} | Hprop {st_label=nam;st_it=This c}) ->
tclTHEN
(push_intro_tac
(fun id ->
Proofview.V82.of_tactic (convert_hyp (LocalAssum (id,c)))) nam)
| Hprop {st_label=nam;st_it=Thesis (tk)} ->
tclTHEN
(push_intro_tac
(fun id -> tclIDTAC) nam))
hyps tclIDTAC gls
let assume_st hyps gls =
List.fold_right
(fun st ->
tclTHEN
(push_intro_tac
(fun id -> Proofview.V82.of_tactic (convert_hyp (LocalAssum (id,st.st_it)))) st.st_label))
hyps tclIDTAC gls
let assume_st_letin hyps gls =
List.fold_right
(fun st ->
tclTHEN
(push_intro_tac
(fun id ->
Proofview.V82.of_tactic (convert_hyp (LocalDef (id, fst st.st_it, snd st.st_it)))) st.st_label))
hyps tclIDTAC gls
(* suffices *)
let rec metas_from n hyps =
match hyps with
_ :: q -> n :: metas_from (succ n) q
| [] -> []
let rec build_product args body =
match args with
(Hprop st| Hvar st )::rest ->
let pprod= lift 1 (build_product rest body) in
let lbody =
match st.st_label with
Anonymous -> pprod
| Name id -> subst_term (mkVar id) pprod in
mkProd (st.st_label, st.st_it, lbody)
| [] -> body
let rec build_applist prod = function
[] -> [],prod
| n::q ->
let (_,typ,_) = destProd prod in
let ctx,head = build_applist (prod_applist prod [mkMeta n]) q in
(n,typ)::ctx,head
let instr_suffices _then cut gls0 =
let info = get_its_info gls0 in
let c_id = pf_get_new_id (Id.of_string "_cofact") gls0 in
let ctx,hd = cut.cut_stat in
let c_stat = build_product ctx (mk_stat_or_thesis info gls0 hd) in
let metas = metas_from 1 ctx in
let c_ctx,c_head = build_applist c_stat metas in
let c_term = applist (mkVar c_id,List.map mkMeta metas) in
let thus_tac gls=
thus_tac c_term c_head c_ctx gls in
tclTHENS (Proofview.V82.of_tactic (assert_postpone c_id c_stat))
[tclTHENLIST
[ assume_tac ctx;
tcl_erase_info;
just_tac _then cut info];
thus_tac] gls0
(* tactics for consider/given *)
let conjunction_arity id gls =
let typ = pf_get_hyp_typ gls id in
let hd,params = decompose_app (special_whd gls typ) in
let env =pf_env gls in
match kind_of_term hd with
Ind (ind,u as indu) when is_good_inductive env ind ->
let mib,oib=
Inductive.lookup_mind_specif env ind in
let gentypes=
Inductive.arities_of_constructors indu (mib,oib) in
let _ = if not (Int.equal (Array.length gentypes) 1) then raise Not_found in
let apptype = prod_applist gentypes.(0) params in
let rc,_ = Reduction.dest_prod env apptype in
List.length rc
| _ -> raise Not_found
let rec intron_then n ids ltac gls =
if n<=0 then
ltac ids gls
else
let id = pf_get_new_id (Id.of_string "_tmp") gls in
tclTHEN
(Proofview.V82.of_tactic (intro_mustbe_force id))
(intron_then (pred n) (id::ids) ltac) gls
let rec consider_match may_intro introduced available expected gls =
match available,expected with
[],[] ->
tclIDTAC gls
| _,[] -> error "Last statements do not match a complete hypothesis."
(* should tell which ones *)
| [],hyps ->
if may_intro then
begin
let id = pf_get_new_id (Id.of_string "_tmp") gls in
tclIFTHENELSE
(Proofview.V82.of_tactic (intro_mustbe_force id))
(consider_match true [] [id] hyps)
(fun _ ->
error "Not enough sub-hypotheses to match statements.")
gls
end
else
error "Not enough sub-hypotheses to match statements."
(* should tell which ones *)
| id::rest_ids,(Hvar st | Hprop st)::rest ->
tclIFTHENELSE (Proofview.V82.of_tactic (convert_hyp (LocalAssum (id,st.st_it))))
begin
match st.st_label with
Anonymous ->
consider_match may_intro ((id,false)::introduced) rest_ids rest
| Name hid ->
tclTHENLIST
[Proofview.V82.of_tactic (rename_hyp [id,hid]);
consider_match may_intro ((hid,true)::introduced) rest_ids rest]
end
begin
(fun gls ->
let nhyps =
try conjunction_arity id gls with
Not_found -> error "Matching hypothesis not found." in
tclTHENLIST
[Proofview.V82.of_tactic (simplest_case (mkVar id));
intron_then nhyps []
(fun l -> consider_match may_intro introduced
(List.rev_append l rest_ids) expected)] gls)
end
gls
let consider_tac c hyps gls =
match kind_of_term (strip_outer_cast c) with
Var id ->
consider_match false [] [id] hyps gls
| _ ->
let id = pf_get_new_id (Id.of_string "_tmp") gls in
tclTHEN
(Proofview.V82.of_tactic (pose_proof (Name id) c))
(consider_match false [] [id] hyps) gls
let given_tac hyps gls =
consider_match true [] [] hyps gls
(* tactics for take *)
let rec take_tac wits gls =
match wits with
[] -> tclIDTAC gls
| wit::rest ->
let typ = pf_unsafe_type_of gls wit in
tclTHEN (thus_tac wit typ []) (take_tac rest) gls
(* tactics for define *)
let rec build_function args body =
match args with
st::rest ->
let pfun= lift 1 (build_function rest body) in
let id = match st.st_label with
Anonymous -> assert false
| Name id -> id in
mkLambda (Name id, st.st_it, subst_term (mkVar id) pfun)
| [] -> body
let define_tac id args body gls =
let t = build_function args body in
Proofview.V82.of_tactic (letin_tac None (Name id) t None Locusops.nowhere) gls
(* tactics for reconsider *)
let cast_tac id_or_thesis typ gls =
match id_or_thesis with
This id ->
let body = pf_get_hyp gls id |> get_value in
Proofview.V82.of_tactic (convert_hyp (of_tuple (id,body,typ))) gls
| Thesis (For _ ) ->
error "\"thesis for ...\" is not applicable here."
| Thesis Plain ->
Proofview.V82.of_tactic (convert_concl typ DEFAULTcast) gls
(* per cases *)
let is_rec_pos (main_ind,wft) =
match main_ind with
None -> false
| Some index ->
match fst (Rtree.dest_node wft) with
Mrec (_,i) when Int.equal i index -> true
| _ -> false
let rec constr_trees (main_ind,wft) ind =
match Rtree.dest_node wft with
Norec,_ ->
let itree =
(snd (Global.lookup_inductive ind)).mind_recargs in
constr_trees (None,itree) ind
| _,constrs -> main_ind,constrs
let ind_args rp ind =
let main_ind,constrs = constr_trees rp ind in
let args ctree =
Array.map (fun t -> main_ind,t) (snd (Rtree.dest_node ctree)) in
Array.map args constrs
let init_tree ids ind rp nexti =
let indargs = ind_args rp ind in
let do_i i arp = (Array.map is_rec_pos arp),nexti i arp in
Split_patt (ids,ind,Array.mapi do_i indargs)
let map_tree_rp rp id_fun mapi = function
Split_patt (ids,ind,branches) ->
let indargs = ind_args rp ind in
let do_i i (recargs,bri) = recargs,mapi i indargs.(i) bri in
Split_patt (id_fun ids,ind,Array.mapi do_i branches)
| _ -> failwith "map_tree_rp: not a splitting node"
let map_tree id_fun mapi = function
Split_patt (ids,ind,branches) ->
let do_i i (recargs,bri) = recargs,mapi i bri in
Split_patt (id_fun ids,ind,Array.mapi do_i branches)
| _ -> failwith "map_tree: not a splitting node"
let start_tree env ind rp =
init_tree Id.Set.empty ind rp (fun _ _ -> None)
let build_per_info etype casee gls =
let concl=pf_concl gls in
let env=pf_env gls in
let ctyp=pf_unsafe_type_of gls casee in
let is_dep = dependent casee concl in
let hd,args = decompose_app (special_whd gls ctyp) in
let (ind,u) =
try
destInd hd
with DestKO ->
error "Case analysis must be done on an inductive object." in
let mind,oind = Global.lookup_inductive ind in
let nparams,index =
match etype with
ET_Induction -> mind.mind_nparams_rec,Some (snd ind)
| _ -> mind.mind_nparams,None in
let params,real_args = List.chop nparams args in
let abstract_obj c body =
let typ=pf_unsafe_type_of gls c in
lambda_create env (typ,subst_term c body) in
let pred= List.fold_right abstract_obj
real_args (lambda_create env (ctyp,subst_term casee concl)) in
is_dep,
{per_casee=casee;
per_ctype=ctyp;
per_ind=ind;
per_pred=pred;
per_args=real_args;
per_params=params;
per_nparams=nparams;
per_wf=index,oind.mind_recargs}
let per_tac etype casee gls=
let env=pf_env gls in
let info = get_its_info gls in
match casee with
Real c ->
let is_dep,per_info = build_per_info etype c gls in
let ek =
if is_dep then
EK_dep (start_tree env per_info.per_ind per_info.per_wf)
else EK_unknown in
tcl_change_info
{pm_stack=
Per(etype,per_info,ek,[])::info.pm_stack} gls
| Virtual cut ->
assert (cut.cut_stat.st_label == Anonymous);
let id = pf_get_new_id (Id.of_string "anonymous_matched") gls in
let c = mkVar id in
let modified_cut =
{cut with cut_stat={cut.cut_stat with st_label=Name id}} in
tclTHEN
(instr_cut (fun _ _ c -> c) false false modified_cut)
(fun gls0 ->
let is_dep,per_info = build_per_info etype c gls0 in
assert (not is_dep);
tcl_change_info
{pm_stack=
Per(etype,per_info,EK_unknown,[])::info.pm_stack} gls0)
gls
(* suppose *)
let register_nodep_subcase id= function
Per(et,pi,ek,clauses)::s ->
begin
match ek with
EK_unknown -> clauses,Per(et,pi,EK_nodep,id::clauses)::s
| EK_nodep -> clauses,Per(et,pi,EK_nodep,id::clauses)::s
| EK_dep _ -> error "Do not mix \"suppose\" with \"suppose it is\"."
end
| _ -> anomaly (Pp.str "wrong stack state")
let suppose_tac hyps gls0 =
let info = get_its_info gls0 in
let thesis = pf_concl gls0 in
let id = pf_get_new_id (Id.of_string "subcase_") gls0 in
let clause = build_product hyps thesis in
let ninfo1 = {pm_stack=Suppose_case::info.pm_stack} in
let old_clauses,stack = register_nodep_subcase id info.pm_stack in
let ninfo2 = {pm_stack=stack} in
tclTHENS (Proofview.V82.of_tactic (assert_postpone id clause))
[tclTHENLIST [tcl_change_info ninfo1;
assume_tac hyps;
clear old_clauses];
tcl_change_info ninfo2] gls0
(* suppose it is ... *)
(* pattern matching compiling *)
let rec skip_args rest ids n =
if n <= 0 then
Close_patt rest
else
Skip_patt (ids,skip_args rest ids (pred n))
let rec tree_of_pats ((id,_) as cpl) pats =
match pats with
[] -> End_patt cpl
| args::stack ->
match args with
[] -> Close_patt (tree_of_pats cpl stack)
| (patt,rp) :: rest_args ->
match patt with
PatVar (_,v) ->
Skip_patt (Id.Set.singleton id,
tree_of_pats cpl (rest_args::stack))
| PatCstr (_,(ind,cnum),args,nam) ->
let nexti i ati =
if Int.equal i (pred cnum) then
let nargs =
List.map_i (fun j a -> (a,ati.(j))) 0 args in
Some (Id.Set.singleton id,
tree_of_pats cpl (nargs::rest_args::stack))
else None
in init_tree Id.Set.empty ind rp nexti
let rec add_branch ((id,_) as cpl) pats tree=
match pats with
[] ->
begin
match tree with
End_patt cpl0 -> End_patt cpl0
(* this ensures precedence for overlapping patterns *)
| _ -> anomaly (Pp.str "tree is expected to end here")
end
| args::stack ->
match args with
[] ->
begin
match tree with
Close_patt t ->
Close_patt (add_branch cpl stack t)
| _ -> anomaly (Pp.str "we should pop here")
end
| (patt,rp) :: rest_args ->
match patt with
PatVar (_,v) ->
begin
match tree with
Skip_patt (ids,t) ->
Skip_patt (Id.Set.add id ids,
add_branch cpl (rest_args::stack) t)
| Split_patt (_,_,_) ->
map_tree (Id.Set.add id)
(fun i bri ->
append_branch cpl 1 (rest_args::stack) bri)
tree
| _ -> anomaly (Pp.str "No pop/stop expected here")
end
| PatCstr (_,(ind,cnum),args,nam) ->
match tree with
Skip_patt (ids,t) ->
let nexti i ati =
if Int.equal i (pred cnum) then
let nargs =
List.map_i (fun j a -> (a,ati.(j))) 0 args in
Some (Id.Set.add id ids,
add_branch cpl (nargs::rest_args::stack)
(skip_args t ids (Array.length ati)))
else
Some (ids,
skip_args t ids (Array.length ati))
in init_tree ids ind rp nexti
| Split_patt (_,ind0,_) ->
if (not (eq_ind ind ind0)) then error
(* this can happen with coercions *)
"Case pattern belongs to wrong inductive type.";
let mapi i ati bri =
if Int.equal i (pred cnum) then
let nargs =
List.map_i (fun j a -> (a,ati.(j))) 0 args in
append_branch cpl 0
(nargs::rest_args::stack) bri
else bri in
map_tree_rp rp (fun ids -> ids) mapi tree
| _ -> anomaly (Pp.str "No pop/stop expected here")
and append_branch ((id,_) as cpl) depth pats = function
Some (ids,tree) ->
Some (Id.Set.add id ids,append_tree cpl depth pats tree)
| None ->
Some (Id.Set.singleton id,tree_of_pats cpl pats)
and append_tree ((id,_) as cpl) depth pats tree =
if depth<=0 then add_branch cpl pats tree
else match tree with
Close_patt t ->
Close_patt (append_tree cpl (pred depth) pats t)
| Skip_patt (ids,t) ->
Skip_patt (Id.Set.add id ids,append_tree cpl depth pats t)
| End_patt _ -> anomaly (Pp.str "Premature end of branch")
| Split_patt (_,_,_) ->
map_tree (Id.Set.add id)
(fun i bri -> append_branch cpl (succ depth) pats bri) tree
(* suppose it is *)
let rec st_assoc id = function
[] -> raise Not_found
| st::_ when Name.equal st.st_label id -> st.st_it
| _ :: rest -> st_assoc id rest
let thesis_for obj typ per_info env=
let rc,hd1=decompose_prod typ in
let cind,all_args=decompose_app typ in
let ind,u = destInd cind in
let _ = if not (eq_ind ind per_info.per_ind) then
errorlabstrm "thesis_for"
((Printer.pr_constr_env env Evd.empty obj) ++ spc () ++
str"cannot give an induction hypothesis (wrong inductive type).") in
let params,args = List.chop per_info.per_nparams all_args in
let _ = if not (List.for_all2 eq_constr params per_info.per_params) then
errorlabstrm "thesis_for"
((Printer.pr_constr_env env Evd.empty obj) ++ spc () ++
str "cannot give an induction hypothesis (wrong parameters).") in
let hd2 = (applist ((lift (List.length rc) per_info.per_pred),args@[obj])) in
compose_prod rc (Reductionops.whd_beta Evd.empty hd2)
let rec build_product_dep pat_info per_info args body gls =
match args with
(Hprop {st_label=nam;st_it=This c}
| Hvar {st_label=nam;st_it=c})::rest ->
let pprod=
lift 1 (build_product_dep pat_info per_info rest body gls) in
let lbody =
match nam with
Anonymous -> body
| Name id -> subst_var id pprod in
mkProd (nam,c,lbody)
| Hprop ({st_it=Thesis tk} as st)::rest ->
let pprod=
lift 1 (build_product_dep pat_info per_info rest body gls) in
let lbody =
match st.st_label with
Anonymous -> body
| Name id -> subst_var id pprod in
let ptyp =
match tk with
For id ->
let obj = mkVar id in
let typ =
try st_assoc (Name id) pat_info.pat_vars
with Not_found ->
snd (st_assoc (Name id) pat_info.pat_aliases) in
thesis_for obj typ per_info (pf_env gls)
| Plain -> pf_concl gls in
mkProd (st.st_label,ptyp,lbody)
| [] -> body
let build_dep_clause params pat_info per_info hyps gls =
let concl=
thesis_for pat_info.pat_constr pat_info.pat_typ per_info (pf_env gls) in
let open_clause =
build_product_dep pat_info per_info hyps concl gls in
let prod_one st body =
match st.st_label with
Anonymous -> mkProd(Anonymous,st.st_it,lift 1 body)
| Name id -> mkNamedProd id st.st_it (lift 1 body) in
let let_one_in st body =
match st.st_label with
Anonymous -> mkLetIn(Anonymous,fst st.st_it,snd st.st_it,lift 1 body)
| Name id ->
mkNamedLetIn id (fst st.st_it) (snd st.st_it) (lift 1 body) in
let aliased_clause =
List.fold_right let_one_in pat_info.pat_aliases open_clause in
List.fold_right prod_one (params@pat_info.pat_vars) aliased_clause
let rec register_dep_subcase id env per_info pat = function
EK_nodep -> error "Only \"suppose it is\" can be used here."
| EK_unknown ->
register_dep_subcase id env per_info pat
(EK_dep (start_tree env per_info.per_ind per_info.per_wf))
| EK_dep tree -> EK_dep (add_branch id [[pat,per_info.per_wf]] tree)
let case_tac params pat_info hyps gls0 =
let info = get_its_info gls0 in
let id = pf_get_new_id (Id.of_string "subcase_") gls0 in
let et,per_info,ek,old_clauses,rest =
match info.pm_stack with
Per (et,pi,ek,old_clauses)::rest -> (et,pi,ek,old_clauses,rest)
| _ -> anomaly (Pp.str "wrong place for cases") in
let clause = build_dep_clause params pat_info per_info hyps gls0 in
let ninfo1 = {pm_stack=Suppose_case::info.pm_stack} in
let nek =
register_dep_subcase (id,(List.length params,List.length hyps))
(pf_env gls0) per_info pat_info.pat_pat ek in
let ninfo2 = {pm_stack=Per(et,per_info,nek,id::old_clauses)::rest} in
tclTHENS (Proofview.V82.of_tactic (assert_postpone id clause))
[tclTHENLIST
[tcl_change_info ninfo1;
assume_st (params@pat_info.pat_vars);
assume_st_letin pat_info.pat_aliases;
assume_hyps_or_theses hyps;
clear old_clauses];
tcl_change_info ninfo2] gls0
(* end cases *)
type ('a, 'b) instance_stack =
('b * (('a option * constr list) list)) list
let initial_instance_stack ids : (_, _) instance_stack =
List.map (fun id -> id,[None,[]]) ids
let push_one_arg arg = function
[] -> anomaly (Pp.str "impossible")
| (head,args) :: ctx ->
((head,(arg::args)) :: ctx)
let push_arg arg stacks =
List.map (fun (id,stack) -> (id,push_one_arg arg stack)) stacks
let push_one_head c ids (id,stack) =
let head = if Id.Set.mem id ids then Some c else None in
id,(head,[]) :: stack
let push_head c ids stacks =
List.map (push_one_head c ids) stacks
let pop_one (id,stack) =
let nstack=
match stack with
[] -> anomaly (Pp.str "impossible")
| [c] as l -> l
| (Some head,args)::(head0,args0)::ctx ->
let arg = applist (head,(List.rev args)) in
(head0,(arg::args0))::ctx
| (None,args)::(head0,args0)::ctx ->
(head0,(args@args0))::ctx
in id,nstack
let pop_stacks stacks =
List.map pop_one stacks
let hrec_for fix_id per_info gls obj_id =
let obj=mkVar obj_id in
let typ=pf_get_hyp_typ gls obj_id in
let rc,hd1=decompose_prod typ in
let cind,all_args=decompose_app typ in
let ind,u = destInd cind in assert (eq_ind ind per_info.per_ind);
let params,args= List.chop per_info.per_nparams all_args in
assert begin
try List.for_all2 eq_constr params per_info.per_params with
Invalid_argument _ -> false end;
let hd2 = applist (mkVar fix_id,args@[obj]) in
compose_lam rc (Reductionops.whd_beta gls.sigma hd2)
let warn_missing_case =
CWarnings.create ~name:"declmode-missing-case" ~category:"declmode"
(fun () -> strbrk "missing case")
let rec execute_cases fix_name per_info tacnext args objs nhrec tree gls =
match tree, objs with
Close_patt t,_ ->
let args0 = pop_stacks args in
execute_cases fix_name per_info tacnext args0 objs nhrec t gls
| Skip_patt (_,t),skipped::next_objs ->
let args0 = push_arg skipped args in
execute_cases fix_name per_info tacnext args0 next_objs nhrec t gls
| End_patt (id,(nparams,nhyps)),[] ->
begin
match Id.List.assoc id args with
[None,br_args] ->
let all_metas =
List.init (nparams + nhyps) (fun n -> mkMeta (succ n)) in
let param_metas,hyp_metas = List.chop nparams all_metas in
tclTHEN
(tclDO nhrec (Proofview.V82.of_tactic introf))
(tacnext
(applist (mkVar id,
List.append param_metas
(List.rev_append br_args hyp_metas)))) gls
| _ -> anomaly (Pp.str "wrong stack size")
end
| Split_patt (ids,ind,br), casee::next_objs ->
let (mind,oind) as spec = Global.lookup_inductive ind in
let nparams = mind.mind_nparams in
let concl=pf_concl gls in
let env=pf_env gls in
let ctyp=pf_unsafe_type_of gls casee in
let hd,all_args = decompose_app (special_whd gls ctyp) in
let ind', u = destInd hd in
let _ = assert (eq_ind ind' ind) in (* just in case *)
let params,real_args = List.chop nparams all_args in
let abstract_obj c body =
let typ=pf_unsafe_type_of gls c in
lambda_create env (typ,subst_term c body) in
let elim_pred = List.fold_right abstract_obj
real_args (lambda_create env (ctyp,subst_term casee concl)) in
let case_info = Inductiveops.make_case_info env ind RegularStyle in
let gen_arities = Inductive.arities_of_constructors (ind,u) spec in
let f_ids typ =
let sign =
(prod_assum (prod_applist typ params)) in
find_intro_names sign gls in
let constr_args_ids = Array.map f_ids gen_arities in
let case_term =
mkCase(case_info,elim_pred,casee,
Array.mapi (fun i _ -> mkMeta (succ i)) constr_args_ids) in
let branch_tac i (recargs,bro) gls0 =
let args_ids = constr_args_ids.(i) in
let rec aux n = function
[] ->
assert (Int.equal n (Array.length recargs));
next_objs,[],nhrec
| id :: q ->
let objs,recs,nrec = aux (succ n) q in
if recargs.(n)
then (mkVar id::objs),(id::recs),succ nrec
else (mkVar id::objs),recs,nrec in
let objs,recs,nhrec = aux 0 args_ids in
tclTHENLIST
[tclMAP (fun id -> Proofview.V82.of_tactic (intro_mustbe_force id)) args_ids;
begin
fun gls1 ->
let hrecs =
List.map
(fun id ->
hrec_for (out_name fix_name) per_info gls1 id)
recs in
Proofview.V82.of_tactic (generalize hrecs) gls1
end;
match bro with
None ->
warn_missing_case ();
tacnext (mkMeta 1)
| Some (sub_ids,tree) ->
let br_args =
List.filter
(fun (id,_) -> Id.Set.mem id sub_ids) args in
let construct =
applist (mkConstruct(ind,succ i),params) in
let p_args =
push_head construct ids br_args in
execute_cases fix_name per_info tacnext
p_args objs nhrec tree] gls0 in
tclTHENSV
(refine case_term)
(Array.mapi branch_tac br) gls
| Split_patt (_, _, _) , [] ->
anomaly ~label:"execute_cases " (Pp.str "Nothing to split")
| Skip_patt _ , [] ->
anomaly ~label:"execute_cases " (Pp.str "Nothing to skip")
| End_patt (_,_) , _ :: _ ->
anomaly ~label:"execute_cases " (Pp.str "End of branch with garbage left")
let understand_my_constr env sigma c concl =
let env = env in
let rawc = Detyping.detype false [] env Evd.empty c in
let rec frob = function
| GEvar _ -> GHole (Loc.ghost,Evar_kinds.QuestionMark Evar_kinds.Expand,Misctypes.IntroAnonymous,None)
| rc -> map_glob_constr frob rc
in
Pretyping.understand_tcc env sigma ~expected_type:(Pretyping.OfType concl) (frob rawc)
let my_refine c gls =
let oc = { run = begin fun sigma ->
let sigma = Sigma.to_evar_map sigma in
let (sigma, c) = understand_my_constr (pf_env gls) sigma c (pf_concl gls) in
Sigma.Unsafe.of_pair (c, sigma)
end } in
Proofview.V82.of_tactic (Tactics.New.refine oc) gls
(* end focus/claim *)
let end_tac et2 gls =
let info = get_its_info gls in
let et1,pi,ek,clauses =
match info.pm_stack with
Suppose_case::_ ->
anomaly (Pp.str "This case should already be trapped")
| Claim::_ ->
error "\"end claim\" expected."
| Focus_claim::_ ->
error "\"end focus\" expected."
| Per(et',pi,ek,clauses)::_ -> (et',pi,ek,clauses)
| [] ->
anomaly (Pp.str "This case should already be trapped") in
let et = match et1, et2 with
| ET_Case_analysis, ET_Case_analysis -> et1
| ET_Induction, ET_Induction -> et1
| ET_Case_analysis, _ -> error "\"end cases\" expected."
| ET_Induction, _ -> error "\"end induction\" expected."
in
tclTHEN
tcl_erase_info
begin
match et,ek with
_,EK_unknown ->
tclSOLVE [Proofview.V82.of_tactic (simplest_elim pi.per_casee)]
| ET_Case_analysis,EK_nodep ->
tclTHEN
(Proofview.V82.of_tactic (simplest_case pi.per_casee))
(default_justification (List.map mkVar clauses))
| ET_Induction,EK_nodep ->
tclTHENLIST
[Proofview.V82.of_tactic (generalize (pi.per_args@[pi.per_casee]));
Proofview.V82.of_tactic (simple_induct (AnonHyp (succ (List.length pi.per_args))));
default_justification (List.map mkVar clauses)]
| ET_Case_analysis,EK_dep tree ->
execute_cases Anonymous pi
(fun c -> tclTHENLIST
[my_refine c;
clear clauses;
justification (Proofview.V82.of_tactic assumption)])
(initial_instance_stack clauses) [pi.per_casee] 0 tree
| ET_Induction,EK_dep tree ->
let nargs = (List.length pi.per_args) in
tclTHEN (Proofview.V82.of_tactic (generalize (pi.per_args@[pi.per_casee])))
begin
fun gls0 ->
let fix_id =
pf_get_new_id (Id.of_string "_fix") gls0 in
let c_id =
pf_get_new_id (Id.of_string "_main_arg") gls0 in
tclTHENLIST
[Proofview.V82.of_tactic (fix (Some fix_id) (succ nargs));
tclDO nargs (Proofview.V82.of_tactic introf);
Proofview.V82.of_tactic (intro_mustbe_force c_id);
execute_cases (Name fix_id) pi
(fun c ->
tclTHENLIST
[clear [fix_id];
my_refine c;
clear clauses;
justification (Proofview.V82.of_tactic assumption)])
(initial_instance_stack clauses)
[mkVar c_id] 0 tree] gls0
end
end gls
(* escape *)
let escape_tac gls =
(* spiwack: sets an empty info stack to avoid interferences.
We could erase the info altogether, but that doesn't play
well with the Decl_mode.focus (used in post_processing). *)
let info={pm_stack=[]} in
tcl_change_info info gls
(* General instruction engine *)
let rec do_proof_instr_gen _thus _then instr =
match instr with
Pthus i ->
assert (not _thus);
do_proof_instr_gen true _then i
| Pthen i ->
assert (not _then);
do_proof_instr_gen _thus true i
| Phence i ->
assert (not (_then || _thus));
do_proof_instr_gen true true i
| Pcut c ->
instr_cut mk_stat_or_thesis _thus _then c
| Psuffices c ->
instr_suffices _then c
| Prew (s,c) ->
assert (not _then);
instr_rew _thus s c
| Pconsider (c,hyps) -> consider_tac c hyps
| Pgiven hyps -> given_tac hyps
| Passume hyps -> assume_tac hyps
| Plet hyps -> assume_tac hyps
| Pclaim st -> instr_claim false st
| Pfocus st -> instr_claim true st
| Ptake witl -> take_tac witl
| Pdefine (id,args,body) -> define_tac id args body
| Pcast (id,typ) -> cast_tac id typ
| Pper (et,cs) -> per_tac et cs
| Psuppose hyps -> suppose_tac hyps
| Pcase (params,pat_info,hyps) -> case_tac params pat_info hyps
| Pend (B_elim et) -> end_tac et
| Pend _ -> anomaly (Pp.str "Not applicable")
| Pescape -> escape_tac
let eval_instr {instr=instr} =
do_proof_instr_gen false false instr
let rec preprocess pts instr =
match instr with
Phence i |Pthus i | Pthen i -> preprocess pts i
| Psuffices _ | Pcut _ | Passume _ | Plet _ | Pclaim _ | Pfocus _
| Pconsider (_,_) | Pcast (_,_) | Pgiven _ | Ptake _
| Pdefine (_,_,_) | Pper _ | Prew _ ->
check_not_per pts;
true
| Pescape ->
check_not_per pts;
true
| Pcase _ | Psuppose _ | Pend (B_elim _) ->
close_previous_case pts ;
true
| Pend bt ->
close_block bt pts ;
false
let rec postprocess pts instr =
match instr with
Phence i | Pthus i | Pthen i -> postprocess pts i
| Pcut _ | Psuffices _ | Passume _ | Plet _ | Pconsider (_,_) | Pcast (_,_)
| Pgiven _ | Ptake _ | Pdefine (_,_,_) | Prew (_,_) -> ()
| Pclaim _ | Pfocus _ | Psuppose _ | Pcase _ | Pper _ ->
Decl_mode.focus pts
| Pescape ->
Decl_mode.focus pts;
Proof_global.set_proof_mode "Classic"
| Pend (B_elim ET_Induction) ->
begin
let pfterm = List.hd (Proof.partial_proof pts) in
let { it = gls ; sigma = sigma } = Proof.V82.subgoals pts in
let env = try
Goal.V82.env sigma (List.hd gls)
with Failure "hd" ->
Global.env ()
in
try
Inductiveops.control_only_guard env pfterm;
goto_current_focus_or_top ()
with
Type_errors.TypeError(env,
Type_errors.IllFormedRecBody(_,_,_,_,_)) ->
anomaly (Pp.str "\"end induction\" generated an ill-formed fixpoint")
end
| Pend (B_elim ET_Case_analysis) -> goto_current_focus ()
| Pend B_proof -> Proof_global.set_proof_mode "Classic"
| Pend _ -> ()
let do_instr raw_instr pts =
let has_tactic = preprocess pts raw_instr.instr in
(* spiwack: hack! [preprocess] assumes that the [pts] is indeed the
current proof (and, actually so does [do_instr] later one, so
it's ok to do the same here. Ideally the proof should be properly
threaded through the commands here, but since the are interleaved
with actions on the proof mode, which is attached to the global
proof environment, it is not possible without heavy lifting. *)
let pts = Proof_global.give_me_the_proof () in
let pts =
if has_tactic then
let { it=gls ; sigma=sigma; } = Proof.V82.subgoals pts in
let gl = { it=List.hd gls ; sigma=sigma; } in
let env= pf_env gl in
let ist = {ltacvars = Id.Set.empty; genv = env} in
let glob_instr = intern_proof_instr ist raw_instr in
let instr =
interp_proof_instr (get_its_info gl) env sigma glob_instr in
let (pts',_) = Proof.run_tactic (Global.env())
(Proofview.V82.tactic (tclTHEN (eval_instr instr) clean_tmp)) pts in
pts'
else pts
in
Proof_global.simple_with_current_proof (fun _ _ -> pts);
postprocess pts raw_instr.instr
let proof_instr raw_instr =
let p = Proof_global.give_me_the_proof () in
do_instr raw_instr p
(*
(* STUFF FOR ITERATED RELATIONS *)
let decompose_bin_app t=
let hd,args = destApp
let identify_transitivity_lemma c =
let varx,tx,c1 = destProd c in
let vary,ty,c2 = destProd (pop c1) in
let varz,tz,c3 = destProd (pop c2) in
let _,p1,c4 = destProd (pop c3) in
let _,lp2,lp3 = destProd (pop c4) in
let p2=pop lp2 in
let p3=pop lp3 in
*)
|