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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id: rules.ml,v 1.24.2.1 2004/07/16 19:30:10 herbelin Exp $ *)
open Util
open Names
open Term
open Tacmach
open Tactics
open Tacticals
open Termops
open Declarations
open Formula
open Sequent
open Libnames
type seqtac= (Sequent.t -> tactic) -> Sequent.t -> tactic
type lseqtac= global_reference -> seqtac
type 'a with_backtracking = tactic -> 'a
let wrap n b continue seq gls=
check_for_interrupt ();
let nc=pf_hyps gls in
let env=pf_env gls in
let rec aux i nc ctx=
if i<=0 then seq else
match nc with
[]->anomaly "Not the expected number of hyps"
| ((id,_,typ) as nd)::q->
if occur_var env id (pf_concl gls) ||
List.exists (occur_var_in_decl env id) ctx then
(aux (i-1) q (nd::ctx))
else
add_formula Hyp (VarRef id) typ (aux (i-1) q (nd::ctx)) gls in
let seq1=aux n nc [] in
let seq2=if b then
add_formula Concl dummy_id (pf_concl gls) seq1 gls else seq1 in
continue seq2 gls
let id_of_global=function
VarRef id->id
| _->assert false
let clear_global=function
VarRef id->clear [id]
| _->tclIDTAC
(* connection rules *)
let axiom_tac t seq=
try exact_no_check (constr_of_reference (find_left t seq))
with Not_found->tclFAIL 0 "No axiom link"
let ll_atom_tac a backtrack id continue seq=
tclIFTHENELSE
(try
tclTHENLIST
[generalize [mkApp(constr_of_reference id,
[|constr_of_reference (find_left a seq)|])];
clear_global id;
intro]
with Not_found->tclFAIL 0 "No link")
(wrap 1 false continue seq) backtrack
(* right connectives rules *)
let and_tac backtrack continue seq=
tclIFTHENELSE simplest_split (wrap 0 true continue seq) backtrack
let or_tac backtrack continue seq=
tclORELSE
(any_constructor (Some (tclCOMPLETE (wrap 0 true continue seq))))
backtrack
let arrow_tac backtrack continue seq=
tclIFTHENELSE intro (wrap 1 true continue seq)
(tclORELSE
(tclTHEN introf (tclCOMPLETE (wrap 1 true continue seq)))
backtrack)
(* left connectives rules *)
let left_and_tac ind backtrack id continue seq gls=
let n=(construct_nhyps ind gls).(0) in
tclIFTHENELSE
(tclTHENLIST
[simplest_elim (constr_of_reference id);
clear_global id;
tclDO n intro])
(wrap n false continue seq)
backtrack gls
let left_or_tac ind backtrack id continue seq gls=
let v=construct_nhyps ind gls in
let f n=
tclTHENLIST
[clear_global id;
tclDO n intro;
wrap n false continue seq] in
tclIFTHENSVELSE
(simplest_elim (constr_of_reference id))
(Array.map f v)
backtrack gls
let left_false_tac id=
simplest_elim (constr_of_reference id)
(* left arrow connective rules *)
(* We use this function for false, and, or, exists *)
let ll_ind_tac ind largs backtrack id continue seq gl=
let rcs=ind_hyps 0 ind largs gl in
let vargs=Array.of_list largs in
(* construire le terme H->B, le generaliser etc *)
let myterm i=
let rc=rcs.(i) in
let p=List.length rc in
let cstr=mkApp ((mkConstruct (ind,(i+1))),vargs) in
let vars=Array.init p (fun j->mkRel (p-j)) in
let capply=mkApp ((lift p cstr),vars) in
let head=mkApp ((lift p (constr_of_reference id)),[|capply|]) in
Sign.it_mkLambda_or_LetIn head rc in
let lp=Array.length rcs in
let newhyps=list_tabulate myterm lp in
tclIFTHENELSE
(tclTHENLIST
[generalize newhyps;
clear_global id;
tclDO lp intro])
(wrap lp false continue seq) backtrack gl
let ll_arrow_tac a b c backtrack id continue seq=
let cc=mkProd(Anonymous,a,(lift 1 b)) in
let d=mkLambda (Anonymous,b,
mkApp ((constr_of_reference id),
[|mkLambda (Anonymous,(lift 1 a),(mkRel 2))|])) in
tclORELSE
(tclTHENS (cut c)
[tclTHENLIST
[introf;
clear_global id;
wrap 1 false continue seq];
tclTHENS (cut cc)
[exact_no_check (constr_of_reference id);
tclTHENLIST
[generalize [d];
clear_global id;
introf;
introf;
tclCOMPLETE (wrap 2 true continue seq)]]])
backtrack
(* quantifier rules (easy side) *)
let forall_tac backtrack continue seq=
tclORELSE
(tclIFTHENELSE intro (wrap 0 true continue seq)
(tclORELSE
(tclTHEN introf (tclCOMPLETE (wrap 0 true continue seq)))
backtrack))
(if !qflag then
tclFAIL 0 "reversible in 1st order mode"
else
backtrack)
let left_exists_tac ind id continue seq gls=
let n=(construct_nhyps ind gls).(0) in
tclTHENLIST
[simplest_elim (constr_of_reference id);
clear_global id;
tclDO n intro;
(wrap (n-1) false continue seq)] gls
let ll_forall_tac prod backtrack id continue seq=
tclORELSE
(tclTHENS (cut prod)
[tclTHENLIST
[intro;
(fun gls->
let id0=pf_nth_hyp_id gls 1 in
let term=mkApp((constr_of_reference id),[|mkVar(id0)|]) in
tclTHEN (generalize [term]) (clear [id0]) gls);
clear_global id;
intro;
tclCOMPLETE (wrap 1 false continue (deepen seq))];
tclCOMPLETE (wrap 0 true continue (deepen seq))])
backtrack
(* rules for instantiation with unification moved to instances.ml *)
(* special for compatibility with old Intuition *)
let constant str = Coqlib.gen_constant "User" ["Init";"Logic"] str
let defined_connectives=lazy
[[],EvalConstRef (destConst (constant "not"));
[],EvalConstRef (destConst (constant "iff"))]
let normalize_evaluables=
onAllClauses
(function
None->unfold_in_concl (Lazy.force defined_connectives)
| Some (id,_,_)->
unfold_in_hyp (Lazy.force defined_connectives)
(id,[],(Tacexpr.InHypTypeOnly,ref None)))
|
