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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 *)
(************************************************************************)
(*i camlp4deps: "parsing/grammar.cma" i*)
(* $Id: extratactics.ml4 9430 2006-12-12 08:25:19Z herbelin $ *)
open Pp
open Pcoq
open Genarg
open Extraargs
open Mod_subst
open Names
(* Equality *)
open Equality
TACTIC EXTEND replace
["replace" constr(c1) "with" constr(c2) in_arg_hyp(in_hyp) by_arg_tac(tac) ]
-> [ replace_in_clause_maybe_by c1 c2 (glob_in_arg_hyp_to_clause in_hyp) (Util.option_map Tacinterp.eval_tactic tac) ]
END
TACTIC EXTEND replace_term_left
[ "replace" "->" constr(c) in_arg_hyp(in_hyp) ]
-> [ replace_multi_term (Some true) c (glob_in_arg_hyp_to_clause in_hyp)]
END
TACTIC EXTEND replace_term_right
[ "replace" "<-" constr(c) in_arg_hyp(in_hyp) ]
-> [replace_multi_term (Some false) c (glob_in_arg_hyp_to_clause in_hyp)]
END
TACTIC EXTEND replace_term
[ "replace" constr(c) in_arg_hyp(in_hyp) ]
-> [ replace_multi_term None c (glob_in_arg_hyp_to_clause in_hyp) ]
END
TACTIC EXTEND simplify_eq
[ "simplify_eq" quantified_hypothesis_opt(h) ] -> [ dEq h ]
END
TACTIC EXTEND discriminate
[ "discriminate" quantified_hypothesis_opt(h) ] -> [ discr_tac h ]
END
let h_discrHyp id = h_discriminate (Some id)
TACTIC EXTEND injection
[ "injection" quantified_hypothesis_opt(h) ] -> [ injClause [] h ]
END
TACTIC EXTEND injection_as
[ "injection" quantified_hypothesis_opt(h)
"as" simple_intropattern_list(ipat)] -> [ injClause ipat h ]
END
let h_injHyp id = h_injection (Some id)
TACTIC EXTEND conditional_rewrite
| [ "conditional" tactic(tac) "rewrite" orient(b) constr_with_bindings(c) ]
-> [ conditional_rewrite b (snd tac) c ]
| [ "conditional" tactic(tac) "rewrite" orient(b) constr_with_bindings(c)
"in" hyp(h) ]
-> [ conditional_rewrite_in b h (snd tac) c ]
END
TACTIC EXTEND dependent_rewrite
| [ "dependent" "rewrite" orient(b) constr(c) ] -> [ rewriteInConcl b c ]
| [ "dependent" "rewrite" orient(b) constr(c) "in" hyp(id) ]
-> [ rewriteInHyp b c id ]
END
TACTIC EXTEND cut_rewrite
| [ "cutrewrite" orient(b) constr(eqn) ] -> [ cutRewriteInConcl b eqn ]
| [ "cutrewrite" orient(b) constr(eqn) "in" hyp(id) ]
-> [ cutRewriteInHyp b eqn id ]
END
(* Contradiction *)
open Contradiction
TACTIC EXTEND absurd
[ "absurd" constr(c) ] -> [ absurd c ]
END
TACTIC EXTEND contradiction
[ "contradiction" constr_with_bindings_opt(c) ] -> [ contradiction c ]
END
(* AutoRewrite *)
open Autorewrite
(* J.F : old version
TACTIC EXTEND autorewrite
[ "autorewrite" "with" ne_preident_list(l) ] ->
[ autorewrite Refiner.tclIDTAC l ]
| [ "autorewrite" "with" ne_preident_list(l) "using" tactic(t) ] ->
[ autorewrite (snd t) l ]
| [ "autorewrite" "with" ne_preident_list(l) "in" hyp(id) ] ->
[ autorewrite_in id Refiner.tclIDTAC l ]
| [ "autorewrite" "with" ne_preident_list(l) "in" hyp(id) "using" tactic(t) ] ->
[ autorewrite_in id (snd t) l ]
END
*)
TACTIC EXTEND autorewrite
| [ "autorewrite" "with" ne_preident_list(l) in_arg_hyp(cl) ] ->
[ auto_multi_rewrite l (glob_in_arg_hyp_to_clause cl) ]
| [ "autorewrite" "with" ne_preident_list(l) in_arg_hyp(cl) "using" tactic(t) ] ->
[
let cl = glob_in_arg_hyp_to_clause cl in
auto_multi_rewrite_with (snd t) l cl
]
END
let add_rewrite_hint name ort t lcsr =
let env = Global.env() and sigma = Evd.empty in
let f c = Constrintern.interp_constr sigma env c, ort, t in
add_rew_rules name (List.map f lcsr)
VERNAC COMMAND EXTEND HintRewrite
[ "Hint" "Rewrite" orient(o) ne_constr_list(l) ":" preident(b) ] ->
[ add_rewrite_hint b o (Tacexpr.TacId []) l ]
| [ "Hint" "Rewrite" orient(o) ne_constr_list(l) "using" tactic(t)
":" preident(b) ] ->
[ add_rewrite_hint b o t l ]
END
(* Refine *)
open Refine
TACTIC EXTEND refine
[ "refine" casted_open_constr(c) ] -> [ refine c ]
END
let refine_tac = h_refine
(* Setoid_replace *)
open Setoid_replace
TACTIC EXTEND setoid_replace
[ "setoid_replace" constr(c1) "with" constr(c2) by_arg_tac(tac)] ->
[ setoid_replace (Util.option_map Tacinterp.eval_tactic tac) None c1 c2 ~new_goals:[] ]
| [ "setoid_replace" constr(c1) "with" constr(c2) "using" "relation" constr(rel) by_arg_tac(tac)] ->
[ setoid_replace (Util.option_map Tacinterp.eval_tactic tac) (Some rel) c1 c2 ~new_goals:[] ]
| [ "setoid_replace" constr(c1) "with" constr(c2) "generate" "side" "conditions" constr_list(l) by_arg_tac(tac) ] ->
[ setoid_replace (Util.option_map Tacinterp.eval_tactic tac) None c1 c2 ~new_goals:l ]
| [ "setoid_replace" constr(c1) "with" constr(c2) "using" "relation" constr(rel) "generate" "side" "conditions" constr_list(l) by_arg_tac(tac) ] ->
[ setoid_replace (Util.option_map Tacinterp.eval_tactic tac) (Some rel) c1 c2 ~new_goals:l ]
| [ "setoid_replace" constr(c1) "with" constr(c2) "in" hyp(h) by_arg_tac(tac) ] ->
[ setoid_replace_in (Util.option_map Tacinterp.eval_tactic tac) h None c1 c2 ~new_goals:[] ]
| [ "setoid_replace" constr(c1) "with" constr(c2) "in" hyp(h) "using" "relation" constr(rel) by_arg_tac(tac)] ->
[ setoid_replace_in (Util.option_map Tacinterp.eval_tactic tac) h (Some rel) c1 c2 ~new_goals:[] ]
| [ "setoid_replace" constr(c1) "with" constr(c2) "in" hyp(h) "generate" "side" "conditions" constr_list(l) by_arg_tac(tac)] ->
[ setoid_replace_in (Util.option_map Tacinterp.eval_tactic tac) h None c1 c2 ~new_goals:l ]
| [ "setoid_replace" constr(c1) "with" constr(c2) "in" hyp(h) "using" "relation" constr(rel) "generate" "side" "conditions" constr_list(l) by_arg_tac(tac)] ->
[ setoid_replace_in (Util.option_map Tacinterp.eval_tactic tac) h (Some rel) c1 c2 ~new_goals:l ]
END
TACTIC EXTEND setoid_rewrite
[ "setoid_rewrite" orient(b) constr(c) ]
-> [ general_s_rewrite b c ~new_goals:[] ]
| [ "setoid_rewrite" orient(b) constr(c) "generate" "side" "conditions" constr_list(l) ]
-> [ general_s_rewrite b c ~new_goals:l ]
| [ "setoid_rewrite" orient(b) constr(c) "in" hyp(h) ] ->
[ general_s_rewrite_in h b c ~new_goals:[] ]
| [ "setoid_rewrite" orient(b) constr(c) "in" hyp(h) "generate" "side" "conditions" constr_list(l) ] ->
[ general_s_rewrite_in h b c ~new_goals:l ]
END
VERNAC COMMAND EXTEND AddSetoid1
[ "Add" "Setoid" constr(a) constr(aeq) constr(t) "as" ident(n) ] ->
[ add_setoid n a aeq t ]
| [ "Add" "Morphism" constr(m) ":" ident(n) ] ->
[ new_named_morphism n m None ]
| [ "Add" "Morphism" constr(m) "with" "signature" morphism_signature(s) "as" ident(n) ] ->
[ new_named_morphism n m (Some s)]
END
VERNAC COMMAND EXTEND AddRelation1
[ "Add" "Relation" constr(a) constr(aeq) "reflexivity" "proved" "by" constr(t) "symmetry" "proved" "by" constr(t') "as" ident(n) ] ->
[ add_relation n a aeq (Some t) (Some t') None ]
| [ "Add" "Relation" constr(a) constr(aeq) "reflexivity" "proved" "by" constr(t) "as" ident(n) ] ->
[ add_relation n a aeq (Some t) None None ]
| [ "Add" "Relation" constr(a) constr(aeq) "as" ident(n) ] ->
[ add_relation n a aeq None None None ]
END
VERNAC COMMAND EXTEND AddRelation2
[ "Add" "Relation" constr(a) constr(aeq) "symmetry" "proved" "by" constr(t') "as" ident(n) ] ->
[ add_relation n a aeq None (Some t') None ]
| [ "Add" "Relation" constr(a) constr(aeq) "symmetry" "proved" "by" constr(t') "transitivity" "proved" "by" constr(t'') "as" ident(n) ] ->
[ add_relation n a aeq None (Some t') (Some t'') ]
END
VERNAC COMMAND EXTEND AddRelation3
[ "Add" "Relation" constr(a) constr(aeq) "reflexivity" "proved" "by" constr(t) "transitivity" "proved" "by" constr(t') "as" ident(n) ] ->
[ add_relation n a aeq (Some t) None (Some t') ]
| [ "Add" "Relation" constr(a) constr(aeq) "reflexivity" "proved" "by" constr(t) "symmetry" "proved" "by" constr(t') "transitivity" "proved" "by" constr(t'') "as" ident(n) ] ->
[ add_relation n a aeq (Some t) (Some t') (Some t'') ]
| [ "Add" "Relation" constr(a) constr(aeq) "transitivity" "proved" "by" constr(t) "as" ident(n) ] ->
[ add_relation n a aeq None None (Some t) ]
END
TACTIC EXTEND setoid_symmetry
[ "setoid_symmetry" ] -> [ setoid_symmetry ]
| [ "setoid_symmetry" "in" hyp(n) ] -> [ setoid_symmetry_in n ]
END
TACTIC EXTEND setoid_reflexivity
[ "setoid_reflexivity" ] -> [ setoid_reflexivity ]
END
TACTIC EXTEND setoid_transitivity
[ "setoid_transitivity" constr(t) ] -> [ setoid_transitivity t ]
END
(* Inversion lemmas (Leminv) *)
open Inv
open Leminv
VERNAC COMMAND EXTEND DeriveInversionClear
[ "Derive" "Inversion_clear" ident(na) hyp(id) ]
-> [ inversion_lemma_from_goal 1 na id Term.mk_Prop false inv_clear_tac ]
| [ "Derive" "Inversion_clear" natural(n) ident(na) hyp(id) ]
-> [ inversion_lemma_from_goal n na id Term.mk_Prop false inv_clear_tac ]
| [ "Derive" "Inversion_clear" ident(na) "with" constr(c) "Sort" sort(s) ]
-> [ add_inversion_lemma_exn na c s false inv_clear_tac ]
| [ "Derive" "Inversion_clear" ident(na) "with" constr(c) ]
-> [ add_inversion_lemma_exn na c (Rawterm.RProp Term.Null) false inv_clear_tac ]
END
open Term
open Rawterm
VERNAC COMMAND EXTEND DeriveInversion
| [ "Derive" "Inversion" ident(na) "with" constr(c) "Sort" sort(s) ]
-> [ add_inversion_lemma_exn na c s false inv_tac ]
| [ "Derive" "Inversion" ident(na) "with" constr(c) ]
-> [ add_inversion_lemma_exn na c (RProp Null) false inv_tac ]
| [ "Derive" "Inversion" ident(na) hyp(id) ]
-> [ inversion_lemma_from_goal 1 na id Term.mk_Prop false inv_tac ]
| [ "Derive" "Inversion" natural(n) ident(na) hyp(id) ]
-> [ inversion_lemma_from_goal n na id Term.mk_Prop false inv_tac ]
END
VERNAC COMMAND EXTEND DeriveDependentInversion
| [ "Derive" "Dependent" "Inversion" ident(na) "with" constr(c) "Sort" sort(s) ]
-> [ add_inversion_lemma_exn na c s true dinv_tac ]
END
VERNAC COMMAND EXTEND DeriveDependentInversionClear
| [ "Derive" "Dependent" "Inversion_clear" ident(na) "with" constr(c) "Sort" sort(s) ]
-> [ add_inversion_lemma_exn na c s true dinv_clear_tac ]
END
(* Subst *)
TACTIC EXTEND subst
| [ "subst" ne_var_list(l) ] -> [ subst l ]
| [ "subst" ] -> [ subst_all ]
END
open Evar_tactics
(* evar creation *)
TACTIC EXTEND evar
[ "evar" "(" ident(id) ":" lconstr(typ) ")" ] -> [ let_evar (Name id) typ ]
| [ "evar" constr(typ) ] -> [ let_evar Anonymous typ ]
END
open Tacexpr
TACTIC EXTEND instantiate
[ "instantiate" "(" integer(i) ":=" raw(c) ")" hloc(hl) ] ->
[instantiate i c hl ]
END
(** Nijmegen "step" tactic for setoid rewriting *)
open Tacticals
open Tactics
open Tactics
open Libnames
open Rawterm
open Summary
open Libobject
open Lib
(* Registered lemmas are expected to be of the form
x R y -> y == z -> x R z (in the right table)
x R y -> x == z -> z R y (in the left table)
*)
let transitivity_right_table = ref []
let transitivity_left_table = ref []
(* [step] tries to apply a rewriting lemma; then apply [tac] intended to
complete to proof of the last hypothesis (assumed to state an equality) *)
let step left x tac =
let l =
List.map (fun lem ->
tclTHENLAST
(apply_with_bindings (lem, ImplicitBindings [x]))
tac)
!(if left then transitivity_left_table else transitivity_right_table)
in
tclFIRST l
(* Main function to push lemmas in persistent environment *)
let cache_transitivity_lemma (_,(left,lem)) =
if left then
transitivity_left_table := lem :: !transitivity_left_table
else
transitivity_right_table := lem :: !transitivity_right_table
let subst_transitivity_lemma (_,subst,(b,ref)) = (b,subst_mps subst ref)
let (inTransitivity,_) =
declare_object {(default_object "TRANSITIVITY-STEPS") with
cache_function = cache_transitivity_lemma;
open_function = (fun i o -> if i=1 then cache_transitivity_lemma o);
subst_function = subst_transitivity_lemma;
classify_function = (fun (_,o) -> Substitute o);
export_function = (fun x -> Some x) }
(* Synchronisation with reset *)
let freeze () = !transitivity_left_table, !transitivity_right_table
let unfreeze (l,r) =
transitivity_left_table := l;
transitivity_right_table := r
let init () =
transitivity_left_table := [];
transitivity_right_table := []
let _ =
declare_summary "transitivity-steps"
{ freeze_function = freeze;
unfreeze_function = unfreeze;
init_function = init;
survive_module = false;
survive_section = false }
(* Main entry points *)
let add_transitivity_lemma left lem =
let lem' = Constrintern.interp_constr Evd.empty (Global.env ()) lem in
add_anonymous_leaf (inTransitivity (left,lem'))
(* Vernacular syntax *)
TACTIC EXTEND stepl
| ["stepl" constr(c) "by" tactic(tac) ] -> [ step true c (snd tac) ]
| ["stepl" constr(c) ] -> [ step true c tclIDTAC ]
END
TACTIC EXTEND stepr
| ["stepr" constr(c) "by" tactic(tac) ] -> [ step false c (snd tac) ]
| ["stepr" constr(c) ] -> [ step false c tclIDTAC ]
END
VERNAC COMMAND EXTEND AddStepl
| [ "Declare" "Left" "Step" constr(t) ] ->
[ add_transitivity_lemma true t ]
END
VERNAC COMMAND EXTEND AddStepr
| [ "Declare" "Right" "Step" constr(t) ] ->
[ add_transitivity_lemma false t ]
END
VERNAC COMMAND EXTEND ImplicitTactic
| [ "Declare" "Implicit" "Tactic" tactic(tac) ] ->
[ Tacinterp.declare_implicit_tactic (Tacinterp.interp tac) ]
END
TACTIC EXTEND apply_in
| ["apply" constr_with_bindings(c) "in" hyp(id) ] -> [ apply_in id [c] ]
| ["apply" constr_with_bindings(c) "," constr_with_bindings_list_sep(cl,",")
"in" hyp(id) ] -> [ apply_in id (c::cl) ]
END
|