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(***********************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA-Rocquencourt & LRI-CNRS-Orsay *)
(* \VV/ *************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(***********************************************************************)
(*i camlp4deps: "parsing/grammar.cma" i*)
(*i $Id$ i*)
open Ast
open Coqast
open Hipattern
open Names
open Libnames
open Pp
open Proof_type
open Tacticals
open Tacinterp
open Tactics
open Tacexpr
open Util
open Term
open Termops
open Declarations
let myprint env rc t=
let env2=Environ.push_rel_context rc env in
let ppstr=Printer.prterm_env env2 t in
Pp.msgnl ppstr
let tacinj tac=valueIn (VTactic (dummy_loc,tac))
let tclATMOSTn n tac1 gl=
let result=tac1 gl in
if List.length (fst result).it <= n then result
else (tclFAIL 0 "Not enough subgoals" gl)
let tclTRY_REV_HYPS (tac : constr->tactic) gl =
tclTRY_sign tac (List.rev (Tacmach.pf_hyps gl)) gl
let rec nb_prod_after n c=
match kind_of_term c with
| Prod (_,_,b) ->if n>0 then nb_prod_after (n-1) b else
1+(nb_prod_after 0 b)
| _ -> 0
let nhyps ind =
let (mib,mip) = Global.lookup_inductive ind in
let constr_types = mip.mind_nf_lc in
let nhyps = nb_prod_after mip.mind_nparams in
Array.map nhyps constr_types
let isrec ind=
let (mib,mip) = Global.lookup_inductive ind in
Inductiveops.mis_is_recursive (ind,mib,mip)
let simplif=Tauto.reduction_not_iff
let rule_axiom=assumption
let rule_rforall tac=tclTHEN intro tac
let rule_rarrow=interp <:tactic<Match Reverse Context With
| [|- ?1 -> ?2 ] -> Intro>>
let rule_larrow=
(interp <:tactic<(Match Reverse Context With
[f:?1->?2;x:?1|-?] ->
Generalize (f x);Clear f;Intro)>>)
let rule_simp_larrow tac=
let itac=tacinj tac in
(interp <:tactic<(Match Reverse Context With
[f:?1->?2|-?] ->
Assert ?1;[Solve $itac|IdTac])>>)
let rule_named_llarrow id gl=
(try let nam=destVar id in
let body=Tacmach.pf_get_hyp_typ gl nam in
let (_,cc,c)=destProd body in
if dependent (mkRel 1) c then tclFAIL 0 "" else
let (_,ta,b)=destProd cc in
if dependent (mkRel 1) b then tclFAIL 0 "" else
let tb=pop b and tc=pop c in
let d=mkLambda (Anonymous,tb,
mkApp (id,[|mkLambda (Anonymous,(lift 1 ta),(mkRel 2))|])) in
let env=Tacmach.pf_env gl in
tclTHENS (cut tc)
[tclTHEN intro (clear [nam]);
tclTHENS (cut cc)
[exact_check id; tclTHENLIST [generalize [d];intro;clear [nam]]]]
with Invalid_argument _ -> tclFAIL 0 "") gl
let rule_llarrow tac=
tclTRY_REV_HYPS
(fun id->tclTHENS (rule_named_llarrow id) [tclIDTAC;tac])
(* this rule always increases the number of goals*)
let rule_rind tac gl=
(let (hdapp,args)=decompose_app gl.it.Evd.evar_concl in
try let ind=destInd hdapp in
if isrec ind then tclFAIL 0 "Found a recursive inductive type" else
any_constructor (Some tac)
with Invalid_argument _ -> tclFAIL 0 "") gl
let rule_rind_rev (* b *) gl=
(let (hdapp,args)=decompose_app gl.it.Evd.evar_concl in
try let ind=destInd hdapp in
if (isrec ind)(* || (not b && (nhyps ind).(0)>1) *) then
tclFAIL 0 "Found a recursive inductive type"
else
simplest_split
with Invalid_argument _ -> tclFAIL 0 "") gl
(* this rule increases the number of goals
if the unique constructor has several hyps.
i.e if (nhyps ind).(0)>1 *)
let rule_named_false id gl=
(try let nam=destVar id in
let body=Tacmach.pf_get_hyp_typ gl nam in
if is_empty_type body then (simplest_elim id)
else tclFAIL 0 "Found an non empty type"
with Invalid_argument _ -> tclFAIL 0 "") gl
let rule_false=tclTRY_REV_HYPS rule_named_false
let rule_named_lind (*b*) id gl=
(try let nam=destVar id in
let body=Tacmach.pf_get_hyp_typ gl nam in
let (hdapp,args) = decompose_app body in
let ind=destInd hdapp in
(*let nconstr=
if b then 0 else
Array.length (snd (Global.lookup_inductive ind)).mind_consnames in *)
if (isrec ind) (*|| (nconstr>1)*) then
tclFAIL 0 "Found a recursive inductive type"
else
let l=nhyps ind in
let f n= tclDO n intro in
tclTHENSV (tclTHEN (simplest_elim id) (clear [nam])) (Array.map f l)
with Invalid_argument _ -> tclFAIL 0 "") gl
let rule_lind (* b *) =
tclTRY_REV_HYPS (rule_named_lind (* b *))
(* number of goals increases if ind has several constructors *)
let rule_named_llind id gl=
(try let nam=destVar id in
let body=Tacmach.pf_get_hyp_typ gl nam in
let (_,xind,b) =destProd body in
if dependent (mkRel 1) b then tclFAIL 0 "Found a dependent product" else
let (hdapp,args) = decompose_app xind in
let vargs=Array.of_list args in
let ind=destInd hdapp in
if isrec ind then tclFAIL 0 "" else
let (mib,mip) = Global.lookup_inductive ind in
let n=mip.mind_nparams in
if n<>(List.length args) then tclFAIL 0 "" else
let p=nhyps ind in
let types= mip.mind_nf_lc in
let names= mip.mind_consnames in
(* construire le terme H->B, le generaliser etc *)
let myterm i=
let env=Tacmach.pf_env gl and emap=Tacmach.project gl in
let t1=Reductionops.hnf_prod_appvect env emap types.(i) vargs in
let (rc,_)=Sign.decompose_prod_n_assum p.(i) t1 in
let cstr=mkApp ((mkConstruct (ind,(i+1))),vargs) in
let vars=Array.init p.(i) (fun j->mkRel (p.(i)-j)) in
let capply=mkApp ((lift p.(i) cstr),vars) in
let head=mkApp ((lift p.(i) id),[|capply|]) in
Sign.it_mkLambda_or_LetIn head rc in
let newhyps=List.map myterm (interval 0 ((Array.length p)-1)) in
tclTHEN (generalize newhyps)
(tclTHEN (clear [nam]) (tclDO (Array.length p) intro))
with Invalid_argument _ ->tclFAIL 0 "") gl
let rule_llind=tclTRY_REV_HYPS rule_named_llind
let default_stac = interp(<:tactic< Auto with * >>)
let rec newtauto b stac gl=
let wrap tac=if b then tac else
tclATMOSTn 1 (tclTHEN tac (tclSOLVE [stac])) in
(tclTHEN simplif
(tclORELSE
(tclTHEN
(tclFIRST [
rule_axiom;
rule_false;
rule_rarrow;
wrap rule_lind;
rule_larrow;
rule_llind;
wrap rule_rind_rev;
rule_llarrow (tclSOLVE [newtauto b stac]);
rule_rind (tclSOLVE [newtauto b stac]);
rule_rforall (tclSOLVE [newtauto b stac]);
if b then tclFAIL 0 "" else (rule_simp_larrow stac)])
(tclPROGRESS (newtauto b stac)))
stac)) gl
let q_elim tac=
let vtac=Tacexpr.TacArg (valueIn (VTactic (dummy_loc,tac))) in
interp <:tactic<
Match Context With
[x:?1;H:?1->?|-?]->
Generalize (H x);Clear H;$vtac>>
let rec lfo n=
if n=0 then (tclFAIL 0 "NewLinearIntuition failed") else
let p=if n<0 then n else (n-1) in
let lfo_rec=q_elim (fun gl->lfo p gl) in
newtauto true lfo_rec
let lfo_wrap n gl=
try lfo n gl
with
Refiner.FailError _ | UserError _ ->
errorlabstrm "NewLinearIntuition" [< str "NewLinearIntuition failed." >]
TACTIC EXTEND NewIntuition
[ "NewIntuition" ] -> [ newtauto true default_stac ]
|[ "NewIntuition" tactic(t)] -> [ newtauto true (snd t) ]
END
TACTIC EXTEND Intuition1
[ "Intuition1" ] -> [ newtauto false default_stac ]
|[ "Intuition1" tactic(t)] -> [ newtauto false (snd t) ]
END
TACTIC EXTEND NewTauto
[ "NewTauto" ] -> [ newtauto true (tclFAIL 0 "NewTauto failed") ]
END
TACTIC EXTEND NewLinearIntuition
[ "NewLinearIntuition" ] -> [ lfo_wrap (-1) ]
| [ "NewLinearIntuition" integer(n)] -> [ lfo_wrap n ]
END
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