Library Coq.Program.Tactics
This module implements various tactics used to simplify the goals produced by Program,
which are also generally useful.
Debugging tactics to show the goal during evaluation.
Ltac show_goal := match goal with [ |- ?T ] => idtac T end.
Ltac show_hyp id :=
match goal with
| [ H := ?b : ?T |- _ ] =>
match H with
| id => idtac id ":=" b ":" T
end
| [ H : ?T |- _ ] =>
match H with
| id => idtac id ":" T
end
end.
Ltac show_hyps :=
try match reverse goal with
| [ H : ?T |- _ ] => show_hyp H ; fail
end.
The do tactic but using a Coq-side nat.
Do something on the last hypothesis, or fail
Ltac on_last_hyp tac :=
lazymatch goal with [ H : _ |- _ ] => tac H end.
Destructs one pair, without care regarding naming.
Ltac destruct_one_pair :=
match goal with
| [H : (_ /\ _) |- _] => destruct H
| [H : prod _ _ |- _] => destruct H
end.
Repeateadly destruct pairs.
Ltac destruct_pairs := repeat (destruct_one_pair).
Destruct one existential package, keeping the name of the hypothesis for the first component.
Ltac destruct_one_ex :=
let tac H := let ph := fresh "H" in (destruct H as [H ph]) in
let tac2 H := let ph := fresh "H" in let ph' := fresh "H" in
(destruct H as [H ph ph'])
in
let tacT H := let ph := fresh "X" in (destruct H as [H ph]) in
let tacT2 H := let ph := fresh "X" in let ph' := fresh "X" in
(destruct H as [H ph ph'])
in
match goal with
| [H : (ex _) |- _] => tac H
| [H : (sig ?P) |- _ ] => tac H
| [H : (sigT ?P) |- _ ] => tacT H
| [H : (ex2 _ _) |- _] => tac2 H
| [H : (sig2 ?P _) |- _ ] => tac2 H
| [H : (sigT2 ?P _) |- _ ] => tacT2 H
end.
Repeateadly destruct existentials.
Ltac destruct_exists := repeat (destruct_one_ex).
Repeateadly destruct conjunctions and existentials.
Ltac destruct_conjs := repeat (destruct_one_pair || destruct_one_ex).
Destruct an existential hypothesis t keeping its name for the first component
and using Ht for the second
Tactic Notation "destruct" "exist" ident(t) ident(Ht) := destruct t as [t Ht].
Destruct a disjunction keeping its name in both subgoals.
Tactic Notation "destruct" "or" ident(H) := destruct H as [H|H].
Discriminate that also work on a x <> x hypothesis.
Ltac discriminates :=
match goal with
| [ H : ?x <> ?x |- _ ] => elim H ; reflexivity
| _ => discriminate
end.
Revert the last hypothesis.
Ltac revert_last :=
match goal with
[ H : _ |- _ ] => revert H
end.
Repeatedly reverse the last hypothesis, putting everything in the goal.
Ltac reverse := repeat revert_last.
Reverse everything up to hypothesis id (not included).
Ltac revert_until id :=
on_last_hyp ltac:(fun id' =>
match id' with
| id => idtac
| _ => revert id' ; revert_until id
end).
Clear duplicated hypotheses
Ltac clear_dup :=
match goal with
| [ H : ?X |- _ ] =>
match goal with
| [ H' : ?Y |- _ ] =>
match H with
| H' => fail 2
| _ => unify X Y ; (clear H' || clear H)
end
end
end.
Ltac clear_dups := repeat clear_dup.
Try to clear everything except some hyp
Ltac clear_except hyp :=
repeat match goal with [ H : _ |- _ ] =>
match H with
| hyp => fail 1
| _ => clear H
end
end.
A non-failing subst that substitutes as much as possible.
Ltac subst_no_fail :=
repeat (match goal with
[ H : ?X = ?Y |- _ ] => subst X || subst Y
end).
Tactic Notation "subst" "*" := subst_no_fail.
Ltac on_application f tac T :=
match T with
| context [f ?x ?y ?z ?w ?v ?u ?a ?b ?c] => tac (f x y z w v u a b c)
| context [f ?x ?y ?z ?w ?v ?u ?a ?b] => tac (f x y z w v u a b)
| context [f ?x ?y ?z ?w ?v ?u ?a] => tac (f x y z w v u a)
| context [f ?x ?y ?z ?w ?v ?u] => tac (f x y z w v u)
| context [f ?x ?y ?z ?w ?v] => tac (f x y z w v)
| context [f ?x ?y ?z ?w] => tac (f x y z w)
| context [f ?x ?y ?z] => tac (f x y z)
| context [f ?x ?y] => tac (f x y)
| context [f ?x] => tac (f x)
end.
Tactical on_call f tac applies tac on any application of f in the hypothesis or goal.
Ltac on_call f tac :=
match goal with
| |- ?T => on_application f tac T
| H : ?T |- _ => on_application f tac T
end.
Ltac destruct_call f :=
let tac t := (destruct t) in on_call f tac.
Ltac destruct_calls f := repeat destruct_call f.
Ltac destruct_call_in f H :=
let tac t := (destruct t) in
let T := type of H in
on_application f tac T.
Ltac destruct_call_as f l :=
let tac t := (destruct t as l) in on_call f tac.
Ltac destruct_call_as_in f l H :=
let tac t := (destruct t as l) in
let T := type of H in
on_application f tac T.
Tactic Notation "destruct_call" constr(f) := destruct_call f.
Permit to name the results of destructing the call to f.
Tactic Notation "destruct_call" constr(f) "as" simple_intropattern(l) :=
destruct_call_as f l.
Specify the hypothesis in which the call occurs as well.
Tactic Notation "destruct_call" constr(f) "in" hyp(id) :=
destruct_call_in f id.
Tactic Notation "destruct_call" constr(f) "as" simple_intropattern(l) "in" hyp(id) :=
destruct_call_as_in f l id.
A marker for prototypes to destruct.
Definition fix_proto {A : Type} (a : A) := a.
Register fix_proto as program.tactic.fix_proto.
Ltac destruct_rec_calls :=
match goal with
| [ H : fix_proto _ |- _ ] => destruct_calls H ; clear H
end.
Ltac destruct_all_rec_calls :=
repeat destruct_rec_calls ; unfold fix_proto in *.
Try to inject any potential constructor equality hypothesis.
Ltac autoinjection tac :=
match goal with
| [ H : ?f ?a = ?f' ?a' |- _ ] => tac H
end.
Ltac inject H := progress (inversion H ; subst*; clear_dups) ; clear H.
Ltac autoinjections := repeat (clear_dups ; autoinjection ltac:(inject)).
Destruct an hypothesis by first copying it to avoid dependencies.
Ltac destruct_nondep H := let H0 := fresh "H" in assert(H0 := H); destruct H0.
If bang appears in the goal, it means that we have a proof of False and the goal is solved.
A tactic to show contradiction by first asserting an automatically provable hypothesis.
Tactic Notation "contradiction" "by" constr(t) :=
let H := fresh in assert t as H by auto with * ; contradiction.
let H := fresh in assert t as H by auto with * ; contradiction.
A tactic that adds H:=p:typeof(p) to the context if no hypothesis of the same type appears in the goal.
Useful to do saturation using tactics.
Ltac add_hypothesis H' p :=
match type of p with
?X =>
match goal with
| [ H : X |- _ ] => fail 1
| _ => set (H':=p) ; try (change p with H') ; clearbody H'
end
end.
A tactic to replace an hypothesis by another term.
Ltac replace_hyp H c :=
let H' := fresh "H" in
assert(H' := c) ; clear H ; rename H' into H.
A tactic to refine an hypothesis by supplying some of its arguments.
Ltac refine_hyp c :=
let tac H := replace_hyp H c in
match c with
| ?H _ => tac H
| ?H _ _ => tac H
| ?H _ _ _ => tac H
| ?H _ _ _ _ => tac H
| ?H _ _ _ _ _ => tac H
| ?H _ _ _ _ _ _ => tac H
| ?H _ _ _ _ _ _ _ => tac H
| ?H _ _ _ _ _ _ _ _ => tac H
end.
The default simplification tactic used by Program is defined by program_simpl, sometimes auto
is not enough, better rebind using Obligation Tactic := tac in this case,
possibly using program_simplify to use standard goal-cleaning tactics.
Ltac program_simplify :=
simpl; intros ; destruct_all_rec_calls ; repeat (destruct_conjs; simpl proj1_sig in * );
subst*; autoinjections ; try discriminates ;
try (solve [ red ; intros ; destruct_conjs ; autoinjections ; discriminates ]).
Restrict automation to propositional obligations.
Ltac program_solve_wf :=
match goal with
| |- well_founded _ => auto with *
| |- ?T => match type of T with Prop => auto end
end.
Create HintDb program discriminated.
Ltac program_simpl := program_simplify ; try typeclasses eauto 10 with program ; try program_solve_wf.
#[global] Obligation Tactic := program_simpl.
#[export] Obligation Tactic := program_simpl.