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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 *)
(************************************************************************)
Require Import Notations.
Require Import Logic.
Require Import Specif.
(** * Useful tactics *)
(** Ex falso quodlibet : a tactic for proving False instead of the current goal.
This is just a nicer name for tactics such as [elimtype False]
and other [cut False]. *)
Ltac exfalso := elimtype False.
(** A tactic for proof by contradiction. With contradict H,
- H:~A |- B gives |- A
- H:~A |- ~B gives H: B |- A
- H: A |- B gives |- ~A
- H: A |- ~B gives H: B |- ~A
- H:False leads to a resolved subgoal.
Moreover, negations may be in unfolded forms,
and A or B may live in Type *)
Ltac contradict H :=
let save tac H := let x:=fresh in intro x; tac H; rename x into H
in
let negpos H := case H; clear H
in
let negneg H := save negpos H
in
let pospos H :=
let A := type of H in (exfalso; revert H; try fold (~A))
in
let posneg H := save pospos H
in
let neg H := match goal with
| |- (~_) => negneg H
| |- (_->False) => negneg H
| |- _ => negpos H
end in
let pos H := match goal with
| |- (~_) => posneg H
| |- (_->False) => posneg H
| |- _ => pospos H
end in
match type of H with
| (~_) => neg H
| (_->False) => neg H
| _ => (elim H;fail) || pos H
end.
(* To contradict an hypothesis without copying its type. *)
Ltac absurd_hyp H :=
idtac "absurd_hyp is OBSOLETE: use contradict instead.";
let T := type of H in
absurd T.
(* A useful complement to contradict. Here H:A while G allows concluding ~A *)
Ltac false_hyp H G :=
let T := type of H in absurd T; [ apply G | assumption ].
(* A case with no loss of information. *)
Ltac case_eq x := generalize (eq_refl x); pattern x at -1; case x.
(* use either discriminate or injection on a hypothesis *)
Ltac destr_eq H := discriminate H || (try (injection H as H)).
(* Similar variants of destruct *)
Tactic Notation "destruct_with_eqn" constr(x) :=
destruct x eqn:?.
Tactic Notation "destruct_with_eqn" ident(n) :=
try intros until n; destruct n eqn:?.
Tactic Notation "destruct_with_eqn" ":" ident(H) constr(x) :=
destruct x eqn:H.
Tactic Notation "destruct_with_eqn" ":" ident(H) ident(n) :=
try intros until n; destruct n eqn:H.
(** Break every hypothesis of a certain type *)
Ltac destruct_all t :=
match goal with
| x : t |- _ => destruct x; destruct_all t
| _ => idtac
end.
(* Rewriting in all hypothesis several times everywhere *)
Tactic Notation "rewrite_all" constr(eq) := repeat rewrite eq in *.
Tactic Notation "rewrite_all" "<-" constr(eq) := repeat rewrite <- eq in *.
(** Tactics for applying equivalences.
The following code provides tactics "apply -> t", "apply <- t",
"apply -> t in H" and "apply <- t in H". Here t is a term whose type
consists of nested dependent and nondependent products with an
equivalence A <-> B as the conclusion. The tactics with "->" in their
names apply A -> B while those with "<-" in the name apply B -> A. *)
(* The idea of the tactics is to first provide a term in the context
whose type is the implication (in one of the directions), and then
apply it. The first idea is to produce a statement "forall ..., A ->
B" (call this type T) and then do "assert (H : T)" for a fresh H.
Thus, T can be proved from the original equivalence and then used to
perform the application. However, currently in Ltac it is difficult
to produce such T from the original formula.
Therefore, we first pose the original equivalence as H. If the type of
H is a dependent product, we create an existential variable and apply
H to this variable. If the type of H has the form C -> D, then we do a
cut on C. Once we eliminate all products, we split (i.e., destruct)
the conjunction into two parts and apply the relevant one. *)
Ltac find_equiv H :=
let T := type of H in
lazymatch T with
| ?A -> ?B =>
let H1 := fresh in
let H2 := fresh in
cut A;
[intro H1; pose proof (H H1) as H2; clear H H1;
rename H2 into H; find_equiv H |
clear H]
| forall x : ?t, _ =>
let a := fresh "a" with
H1 := fresh "H" in
evar (a : t); pose proof (H a) as H1; unfold a in H1;
clear a; clear H; rename H1 into H; find_equiv H
| ?A <-> ?B => idtac
| _ => fail "The given statement does not seem to end with an equivalence."
end.
Ltac bapply lemma todo :=
let H := fresh in
pose proof lemma as H;
find_equiv H; [todo H; clear H | .. ].
Tactic Notation "apply" "->" constr(lemma) :=
bapply lemma ltac:(fun H => destruct H as [H _]; apply H).
Tactic Notation "apply" "<-" constr(lemma) :=
bapply lemma ltac:(fun H => destruct H as [_ H]; apply H).
Tactic Notation "apply" "->" constr(lemma) "in" hyp(J) :=
bapply lemma ltac:(fun H => destruct H as [H _]; apply H in J).
Tactic Notation "apply" "<-" constr(lemma) "in" hyp(J) :=
bapply lemma ltac:(fun H => destruct H as [_ H]; apply H in J).
(** An experimental tactic simpler than auto that is useful for ending
proofs "in one step" *)
Ltac easy :=
let rec use_hyp H :=
match type of H with
| _ /\ _ => exact H || destruct_hyp H
| _ => try solve [inversion H]
end
with do_intro := let H := fresh in intro H; use_hyp H
with destruct_hyp H := case H; clear H; do_intro; do_intro in
let rec use_hyps :=
match goal with
| H : _ /\ _ |- _ => exact H || (destruct_hyp H; use_hyps)
| H : _ |- _ => solve [inversion H]
| _ => idtac
end in
let do_atom :=
solve [ trivial with eq_true | reflexivity | symmetry; trivial | contradiction ] in
let rec do_ccl :=
try do_atom;
repeat (do_intro; try do_atom);
solve [ split; do_ccl ] in
solve [ do_atom | use_hyps; do_ccl ] ||
fail "Cannot solve this goal".
Tactic Notation "now" tactic(t) := t; easy.
(** Slightly more than [easy]*)
Ltac easy' := repeat split; simpl; easy || now destruct 1.
(** A tactic to document or check what is proved at some point of a script *)
Ltac now_show c := change c.
(** Support for rewriting decidability statements *)
Set Implicit Arguments.
Lemma decide_left : forall (C:Prop) (decide:{C}+{~C}),
C -> forall P:{C}+{~C}->Prop, (forall H:C, P (left _ H)) -> P decide.
Proof.
intros; destruct decide. apply H0. contradiction.
Qed.
Lemma decide_right : forall (C:Prop) (decide:{C}+{~C}),
~C -> forall P:{C}+{~C}->Prop, (forall H:~C, P (right _ H)) -> P decide.
Proof.
intros; destruct decide. contradiction. apply H0.
Qed.
Tactic Notation "decide" constr(lemma) "with" constr(H) :=
let try_to_merge_hyps H :=
try (clear H; intro H) ||
(let H' := fresh H "bis" in intro H'; try clear H') ||
(let H' := fresh in intro H'; try clear H') in
match type of H with
| ~ ?C => apply (decide_right lemma H); try_to_merge_hyps H
| ?C -> False => apply (decide_right lemma H); try_to_merge_hyps H
| _ => apply (decide_left lemma H); try_to_merge_hyps H
end.
(** Clear an hypothesis and its dependencies *)
Tactic Notation "clear" "dependent" hyp(h) :=
let rec depclear h :=
clear h ||
match goal with
| H : context [ h ] |- _ => depclear H; depclear h
end ||
fail "hypothesis to clear is used in the conclusion (maybe indirectly)"
in depclear h.
(** Revert an hypothesis and its dependencies :
this is actually generalize dependent... *)
Tactic Notation "revert" "dependent" hyp(h) :=
generalize dependent h.
(** Provide an error message for dependent induction that reports an import is
required to use it. Importing Coq.Program.Equality will shadow this notation
with the actual [dependent induction] tactic. *)
Tactic Notation "dependent" "induction" ident(H) :=
fail "To use dependent induction, first [Require Import Coq.Program.Equality.]".
(** *** [inversion_sigma] *)
(** The built-in [inversion] will frequently leave equalities of
dependent pairs. When the first type in the pair is an hProp or
otherwise simplifies, [inversion_sigma] is useful; it will replace
the equality of pairs with a pair of equalities, one involving a
term casted along the other. This might also prove useful for
writing a version of [inversion] / [dependent destruction] which
does not lose information, i.e., does not turn a goal which is
provable into one which requires axiom K / UIP. *)
Ltac simpl_proj_exist_in H :=
repeat match type of H with
| context G[proj1_sig (exist _ ?x ?p)]
=> let G' := context G[x] in change G' in H
| context G[proj2_sig (exist _ ?x ?p)]
=> let G' := context G[p] in change G' in H
| context G[projT1 (existT _ ?x ?p)]
=> let G' := context G[x] in change G' in H
| context G[projT2 (existT _ ?x ?p)]
=> let G' := context G[p] in change G' in H
| context G[proj3_sig (exist2 _ _ ?x ?p ?q)]
=> let G' := context G[q] in change G' in H
| context G[projT3 (existT2 _ _ ?x ?p ?q)]
=> let G' := context G[q] in change G' in H
| context G[sig_of_sig2 (@exist2 ?A ?P ?Q ?x ?p ?q)]
=> let G' := context G[@exist A P x p] in change G' in H
| context G[sigT_of_sigT2 (@existT2 ?A ?P ?Q ?x ?p ?q)]
=> let G' := context G[@existT A P x p] in change G' in H
end.
Ltac induction_sigma_in_using H rect :=
let H0 := fresh H in
let H1 := fresh H in
induction H as [H0 H1] using (rect _ _ _ _);
simpl_proj_exist_in H0;
simpl_proj_exist_in H1.
Ltac induction_sigma2_in_using H rect :=
let H0 := fresh H in
let H1 := fresh H in
let H2 := fresh H in
induction H as [H0 H1 H2] using (rect _ _ _ _ _);
simpl_proj_exist_in H0;
simpl_proj_exist_in H1;
simpl_proj_exist_in H2.
Ltac inversion_sigma_step :=
match goal with
| [ H : _ = exist _ _ _ |- _ ]
=> induction_sigma_in_using H @eq_sig_rect
| [ H : _ = existT _ _ _ |- _ ]
=> induction_sigma_in_using H @eq_sigT_rect
| [ H : exist _ _ _ = _ |- _ ]
=> induction_sigma_in_using H @eq_sig_rect
| [ H : existT _ _ _ = _ |- _ ]
=> induction_sigma_in_using H @eq_sigT_rect
| [ H : _ = exist2 _ _ _ _ _ |- _ ]
=> induction_sigma2_in_using H @eq_sig2_rect
| [ H : _ = existT2 _ _ _ _ _ |- _ ]
=> induction_sigma2_in_using H @eq_sigT2_rect
| [ H : exist2 _ _ _ _ _ = _ |- _ ]
=> induction_sigma_in_using H @eq_sig2_rect
| [ H : existT2 _ _ _ _ _ = _ |- _ ]
=> induction_sigma_in_using H @eq_sigT2_rect
end.
Ltac inversion_sigma := repeat inversion_sigma_step.
(** A version of [time] that works for constrs *)
Ltac time_constr tac :=
let eval_early := match goal with _ => restart_timer end in
let ret := tac () in
let eval_early := match goal with _ => finish_timing ( "Tactic evaluation" ) end in
ret.
|