Module Behaviors


Whole-program behaviors

Require Import Classical.
Require Import ClassicalEpsilon.
Require Import Coqlib.
Require Import Events.
Require Import Globalenvs.
Require Import Integers.
Require Import Smallstep.

Set Implicit Arguments.
Set Asymmetric Patterns.

Behaviors for program executions


The four possible outcomes for the execution of a program:

Inductive program_behavior: Type :=
  | Terminates: trace -> int -> program_behavior
  | Diverges: trace -> program_behavior
  | Reacts: traceinf -> program_behavior
  | Goes_wrong: trace -> program_behavior.

Operations and relations on behaviors

Definition not_wrong (beh: program_behavior) : Prop :=
  match beh with
  | Terminates _ _ => True
  | Diverges _ => True
  | Reacts _ => True
  | Goes_wrong _ => False
  end.

Definition behavior_app (t: trace) (beh: program_behavior): program_behavior :=
  match beh with
  | Terminates t1 r => Terminates (t ** t1) r
  | Diverges t1 => Diverges (t ** t1)
  | Reacts T => Reacts (t *** T)
  | Goes_wrong t1 => Goes_wrong (t ** t1)
  end.

Lemma behavior_app_assoc:
  forall t1 t2 beh,
  behavior_app (t1 ** t2) beh = behavior_app t1 (behavior_app t2 beh).
Proof.
  intros. destruct beh; simpl; f_equal; traceEq.
Qed.

Lemma behavior_app_E0:
  forall beh, behavior_app E0 beh = beh.
Proof.
  destruct beh; auto.
Qed.

Definition behavior_prefix (t: trace) (beh: program_behavior) : Prop :=
  exists beh', beh = behavior_app t beh'.

Definition behavior_improves (beh1 beh2: program_behavior) : Prop :=
  beh1 = beh2 \/ exists t, beh1 = Goes_wrong t /\ behavior_prefix t beh2.

Lemma behavior_improves_refl:
  forall beh, behavior_improves beh beh.
Proof.
  intros; red; auto.
Qed.

Lemma behavior_improves_trans:
  forall beh1 beh2 beh3,
  behavior_improves beh1 beh2 -> behavior_improves beh2 beh3 ->
  behavior_improves beh1 beh3.
Proof.
  intros. red. destruct H; destruct H0; subst; auto.
  destruct H as [t1 [EQ1 [beh2' EQ1']]].
  destruct H0 as [t2 [EQ2 [beh3' EQ2']]].
  subst. destruct beh2'; simpl in EQ2; try discriminate. inv EQ2.
  right. exists t1; split; auto. exists (behavior_app t beh3'). apply behavior_app_assoc.
Qed.

Lemma behavior_improves_bot:
  forall beh, behavior_improves (Goes_wrong E0) beh.
Proof.
  intros. right. exists E0; split; auto. exists beh. rewrite behavior_app_E0; auto.
Qed.

Lemma behavior_improves_app:
  forall t beh1 beh2,
  behavior_improves beh1 beh2 ->
  behavior_improves (behavior_app t beh1) (behavior_app t beh2).
Proof.
  intros. red; destruct H. left; congruence.
  destruct H as [t' [A [beh' B]]]. subst.
  right; exists (t ** t'); split; auto. exists beh'. rewrite behavior_app_assoc; auto.
Qed.

Associating behaviors to programs.

Section PROGRAM_BEHAVIORS.

Variable L: semantics.

Inductive state_behaves (s: state L): program_behavior -> Prop :=
  | state_terminates: forall t s' r,
      Star L s t s' ->
      final_state L s' r ->
      state_behaves s (Terminates t r)
  | state_diverges: forall t s',
      Star L s t s' -> Forever_silent L s' ->
      state_behaves s (Diverges t)
  | state_reacts: forall T,
      Forever_reactive L s T ->
      state_behaves s (Reacts T)
  | state_goes_wrong: forall t s',
      Star L s t s' ->
      Nostep L s' ->
      (forall r, ~final_state L s' r) ->
      state_behaves s (Goes_wrong t).

Inductive program_behaves: program_behavior -> Prop :=
  | program_runs: forall s beh,
      initial_state L s -> state_behaves s beh ->
      program_behaves beh
  | program_goes_initially_wrong:
      (forall s, ~initial_state L s) ->
      program_behaves (Goes_wrong E0).

Lemma state_behaves_app:
  forall s1 t s2 beh,
  Star L s1 t s2 -> state_behaves s2 beh -> state_behaves s1 (behavior_app t beh).
Proof.
  intros. inv H0; simpl; econstructor; eauto; try (eapply star_trans; eauto).
  eapply star_forever_reactive; eauto.
Qed.

Existence of behaviors


We now show that any program admits at least one behavior. The proof requires classical logic: the axiom of excluded middle and an axiom of description.

The most difficult part of the proof is to show the existence of an infinite trace in the case of reactive divergence.

Section TRACEINF_REACTS.

Variable s0: state L.

Hypothesis reacts:
  forall s1 t1, Star L s0 t1 s1 ->
  exists s2, exists t2, Star L s1 t2 s2 /\ t2 <> E0.

Lemma reacts':
  forall s1 t1, Star L s0 t1 s1 ->
  { s2 : state L & { t2 : trace | Star L s1 t2 s2 /\ t2 <> E0 } }.
Proof.
  intros.
  destruct (constructive_indefinite_description _ (reacts H)) as [s2 A].
  destruct (constructive_indefinite_description _ A) as [t2 [B C]].
  exists s2; exists t2; auto.
Qed.

CoFixpoint build_traceinf' (s1: state L) (t1: trace) (ST: Star L s0 t1 s1) : traceinf' :=
  match reacts' ST with
  | existT s2 (exist t2 (conj A B)) =>
      Econsinf' t2
                (build_traceinf' (star_trans ST A (eq_refl _)))
                B
  end.

Lemma reacts_forever_reactive_rec:
  forall s1 t1 (ST: Star L s0 t1 s1),
  Forever_reactive L s1 (traceinf_of_traceinf' (build_traceinf' ST)).
Proof.
  cofix COINDHYP; intros.
  rewrite (unroll_traceinf' (build_traceinf' ST)). simpl.
  destruct (reacts' ST) as [s2 [t2 [A B]]].
  rewrite traceinf_traceinf'_app.
  econstructor. eexact A. auto. apply COINDHYP.
Qed.

Lemma reacts_forever_reactive:
  exists T, Forever_reactive L s0 T.
Proof.
  exists (traceinf_of_traceinf' (build_traceinf' (star_refl (step L) (globalenv L) s0))).
  apply reacts_forever_reactive_rec.
Qed.

End TRACEINF_REACTS.

Lemma diverges_forever_silent:
  forall s0,
  (forall s1 t1, Star L s0 t1 s1 -> exists s2, Step L s1 E0 s2) ->
  Forever_silent L s0.
Proof.
  cofix COINDHYP; intros.
  destruct (H s0 E0) as [s1 ST]. constructor.
  econstructor. eexact ST. apply COINDHYP.
  intros. eapply H. eapply star_left; eauto.
Qed.

Lemma state_behaves_exists:
  forall s, exists beh, state_behaves s beh.
Proof.
  intros s0.
  destruct (classic (forall s1 t1, Star L s0 t1 s1 -> exists s2, exists t2, Step L s1 t2 s2)).
(* 1 Divergence (silent or reactive) *)
  destruct (classic (exists s1, exists t1, Star L s0 t1 s1 /\
                       (forall s2 t2, Star L s1 t2 s2 ->
                        exists s3, Step L s2 E0 s3))).
(* 1.1 Silent divergence *)
  destruct H0 as [s1 [t1 [A B]]].
  exists (Diverges t1); econstructor; eauto.
  apply diverges_forever_silent; auto.
(* 1.2 Reactive divergence *)
  destruct (@reacts_forever_reactive s0) as [T FR].
  intros.
  generalize (not_ex_all_not _ _ H0 s1). intro A; clear H0.
  generalize (not_ex_all_not _ _ A t1). intro B; clear A.
  destruct (not_and_or _ _ B). contradiction.
  destruct (not_all_ex_not _ _ H0) as [s2 C]; clear H0.
  destruct (not_all_ex_not _ _ C) as [t2 D]; clear C.
  destruct (imply_to_and _ _ D) as [E F]; clear D.
  destruct (H s2 (t1 ** t2)) as [s3 [t3 G]]. eapply star_trans; eauto.
  exists s3; exists (t2 ** t3); split.
  eapply star_right; eauto.
  red; intros. destruct (app_eq_nil t2 t3 H0). subst. elim F. exists s3; auto.
  exists (Reacts T); econstructor; eauto.
(* 2 Termination (normal or by going wrong) *)
  destruct (not_all_ex_not _ _ H) as [s1 A]; clear H.
  destruct (not_all_ex_not _ _ A) as [t1 B]; clear A.
  destruct (imply_to_and _ _ B) as [C D]; clear B.
  destruct (classic (exists r, final_state L s1 r)) as [[r FINAL] | NOTFINAL].
(* 2.1 Normal termination *)
  exists (Terminates t1 r); econstructor; eauto.
(* 2.2 Going wrong *)
  exists (Goes_wrong t1); econstructor; eauto. red. intros.
  generalize (not_ex_all_not _ _ D s'); intros.
  generalize (not_ex_all_not _ _ H t); intros.
  auto.
Qed.

Theorem program_behaves_exists:
  exists beh, program_behaves beh.
Proof.
  destruct (classic (exists s, initial_state L s)) as [[s0 INIT] | NOTINIT].
(* 1. Initial state is defined. *)
  destruct (state_behaves_exists s0) as [beh SB].
  exists beh; econstructor; eauto.
(* 2. Initial state is undefined *)
  exists (Goes_wrong E0). apply program_goes_initially_wrong.
  intros. eapply not_ex_all_not; eauto.
Qed.

End PROGRAM_BEHAVIORS.

Forward simulations and program behaviors


Section FORWARD_SIMULATIONS.

Context L1 L2 index order match_states (S: fsim_properties L1 L2 index order match_states).

Lemma forward_simulation_state_behaves:
  forall i s1 s2 beh1,
  match_states i s1 s2 -> state_behaves L1 s1 beh1 ->
  exists beh2, state_behaves L2 s2 beh2 /\ behavior_improves beh1 beh2.
Proof.
  intros. inv H0.
- (* termination *)
  exploit simulation_star; eauto. intros [i' [s2' [A B]]].
  exists (Terminates t r); split.
  econstructor; eauto. eapply fsim_match_final_states; eauto.
  apply behavior_improves_refl.
- (* silent divergence *)
  exploit simulation_star; eauto. intros [i' [s2' [A B]]].
  exists (Diverges t); split.
  econstructor; eauto. eapply simulation_forever_silent; eauto.
  apply behavior_improves_refl.
- (* reactive divergence *)
  exists (Reacts T); split.
  econstructor. eapply simulation_forever_reactive; eauto.
  apply behavior_improves_refl.
- (* going wrong *)
  exploit simulation_star; eauto. intros [i' [s2' [A B]]].
  destruct (state_behaves_exists L2 s2') as [beh' SB].
  exists (behavior_app t beh'); split.
  eapply state_behaves_app; eauto.
  replace (Goes_wrong t) with (behavior_app t (Goes_wrong E0)).
  apply behavior_improves_app. apply behavior_improves_bot.
  simpl. decEq. traceEq.
Qed.

End FORWARD_SIMULATIONS.

Theorem forward_simulation_behavior_improves:
  forall L1 L2, forward_simulation L1 L2 ->
  forall beh1, program_behaves L1 beh1 ->
  exists beh2, program_behaves L2 beh2 /\ behavior_improves beh1 beh2.
Proof.
  intros L1 L2 FS. destruct FS as [init order match_states S]. intros. inv H.
- (* initial state defined *)
  exploit (fsim_match_initial_states S); eauto. intros [i [s' [INIT MATCH]]].
  exploit forward_simulation_state_behaves; eauto. intros [beh2 [A B]].
  exists beh2; split; auto. econstructor; eauto.
- (* initial state undefined *)
  destruct (classic (exists s', initial_state L2 s')).
  destruct H as [s' INIT].
  destruct (state_behaves_exists L2 s') as [beh' SB].
  exists beh'; split. econstructor; eauto. apply behavior_improves_bot.
  exists (Goes_wrong E0); split.
  apply program_goes_initially_wrong.
  intros; red; intros. elim H; exists s; auto.
  apply behavior_improves_refl.
Qed.

Corollary forward_simulation_same_safe_behavior:
  forall L1 L2, forward_simulation L1 L2 ->
  forall beh,
  program_behaves L1 beh -> not_wrong beh ->
  program_behaves L2 beh.
Proof.
  intros. exploit forward_simulation_behavior_improves; eauto.
  intros [beh' [A B]]. destruct B.
  congruence.
  destruct H2 as [t [C D]]. subst. contradiction.
Qed.

Backward simulations and program behaviors


Section BACKWARD_SIMULATIONS.

Context L1 L2 index order match_states (S: bsim_properties L1 L2 index order match_states).

Definition safe_along_behavior (s: state L1) (b: program_behavior) : Prop :=
  forall t1 s' b2, Star L1 s t1 s' -> b = behavior_app t1 b2 ->
     (exists r, final_state L1 s' r)
  \/ (exists t2, exists s'', Step L1 s' t2 s'').

Remark safe_along_safe:
  forall s b, safe_along_behavior s b -> safe L1 s.
Proof.
  intros; red; intros. eapply H; eauto. symmetry; apply behavior_app_E0.
Qed.

Remark star_safe_along:
  forall s b t1 s' b2,
  safe_along_behavior s b ->
  Star L1 s t1 s' -> b = behavior_app t1 b2 ->
  safe_along_behavior s' b2.
Proof.
  intros; red; intros. eapply H. eapply star_trans; eauto.
  subst. rewrite behavior_app_assoc. eauto.
Qed.

Remark not_safe_along_behavior:
  forall s b,
  ~ safe_along_behavior s b ->
  exists t, exists s',
     behavior_prefix t b
  /\ Star L1 s t s'
  /\ Nostep L1 s'
  /\ (forall r, ~(final_state L1 s' r)).
Proof.
  intros.
  destruct (not_all_ex_not _ _ H) as [t1 A]; clear H.
  destruct (not_all_ex_not _ _ A) as [s' B]; clear A.
  destruct (not_all_ex_not _ _ B) as [b2 C]; clear B.
  destruct (imply_to_and _ _ C) as [D E]; clear C.
  destruct (imply_to_and _ _ E) as [F G]; clear E.
  destruct (not_or_and _ _ G) as [P Q]; clear G.
  exists t1; exists s'.
  split. exists b2; auto.
  split. auto.
  split. red; intros; red; intros. elim Q. exists t; exists s'0; auto.
  intros; red; intros. elim P. exists r; auto.
Qed.

Lemma backward_simulation_star:
  forall s2 t s2', Star L2 s2 t s2' ->
  forall i s1 b, match_states i s1 s2 -> safe_along_behavior s1 (behavior_app t b) ->
  exists i', exists s1', Star L1 s1 t s1' /\ match_states i' s1' s2'.
Proof.
  induction 1; intros.
  exists i; exists s1; split; auto. apply star_refl.
  exploit (bsim_simulation S); eauto. eapply safe_along_safe; eauto.
  intros [i' [s1' [A B]]].
  assert (Star L1 s0 t1 s1'). intuition. apply plus_star; auto.
  exploit IHstar; eauto. eapply star_safe_along; eauto.
  subst t; apply behavior_app_assoc.
  intros [i'' [s2'' [C D]]].
  exists i''; exists s2''; split; auto. eapply star_trans; eauto.
Qed.

Lemma backward_simulation_forever_silent:
  forall i s1 s2,
  Forever_silent L2 s2 -> match_states i s1 s2 -> safe L1 s1 ->
  Forever_silent L1 s1.
Proof.
  assert (forall i s1 s2,
         Forever_silent L2 s2 -> match_states i s1 s2 -> safe L1 s1 ->
         forever_silent_N (step L1) order (globalenv L1) i s1).
    cofix COINDHYP; intros.
    inv H. destruct (bsim_simulation S _ _ _ H2 _ H0 H1) as [i' [s2' [A B]]].
    destruct A as [C | [C D]].
    eapply forever_silent_N_plus; eauto. eapply COINDHYP; eauto.
      eapply star_safe; eauto. apply plus_star; auto.
    eapply forever_silent_N_star; eauto. eapply COINDHYP; eauto.
      eapply star_safe; eauto.
  intros. eapply forever_silent_N_forever; eauto. eapply bsim_order_wf; eauto.
Qed.

Lemma backward_simulation_forever_reactive:
  forall i s1 s2 T,
  Forever_reactive L2 s2 T -> match_states i s1 s2 -> safe_along_behavior s1 (Reacts T) ->
  Forever_reactive L1 s1 T.
Proof.
  cofix COINDHYP; intros. inv H.
  destruct (backward_simulation_star H2 (Reacts T0) H0) as [i' [s1' [A B]]]; eauto.
  econstructor; eauto. eapply COINDHYP; eauto. eapply star_safe_along; eauto.
Qed.

Lemma backward_simulation_state_behaves:
  forall i s1 s2 beh2,
  match_states i s1 s2 -> state_behaves L2 s2 beh2 ->
  exists beh1, state_behaves L1 s1 beh1 /\ behavior_improves beh1 beh2.
Proof.
  intros. destruct (classic (safe_along_behavior s1 beh2)).
- (* 1. Safe along *)
  exists beh2; split; [idtac|apply behavior_improves_refl].
  inv H0.
+ (* termination *)
  assert (Terminates t r = behavior_app t (Terminates E0 r)).
    simpl. rewrite E0_right; auto.
  rewrite H0 in H1.
  exploit backward_simulation_star; eauto.
  intros [i' [s1' [A B]]].
  exploit (bsim_match_final_states S); eauto.
    eapply safe_along_safe. eapply star_safe_along; eauto.
  intros [s1'' [C D]].
  econstructor. eapply star_trans; eauto. traceEq. auto.
+ (* silent divergence *)
  assert (Diverges t = behavior_app t (Diverges E0)).
    simpl. rewrite E0_right; auto.
  rewrite H0 in H1.
  exploit backward_simulation_star; eauto.
  intros [i' [s1' [A B]]].
  econstructor. eauto. eapply backward_simulation_forever_silent; eauto.
  eapply safe_along_safe. eapply star_safe_along; eauto.
+ (* reactive divergence *)
  econstructor. eapply backward_simulation_forever_reactive; eauto.
+ (* goes wrong *)
  assert (Goes_wrong t = behavior_app t (Goes_wrong E0)).
    simpl. rewrite E0_right; auto.
  rewrite H0 in H1.
  exploit backward_simulation_star; eauto.
  intros [i' [s1' [A B]]].
  exploit (bsim_progress S); eauto. eapply safe_along_safe. eapply star_safe_along; eauto.
  intros [[r FIN] | [t' [s2' STEP2]]].
  elim (H4 _ FIN).
  elim (H3 _ _ STEP2).

- (* 2. Not safe along *)
  exploit not_safe_along_behavior; eauto.
  intros [t [s1' [PREF [STEPS [NOSTEP NOFIN]]]]].
  exists (Goes_wrong t); split.
  econstructor; eauto.
  right. exists t; auto.
Qed.

End BACKWARD_SIMULATIONS.

Theorem backward_simulation_behavior_improves:
  forall L1 L2, backward_simulation L1 L2 ->
  forall beh2, program_behaves L2 beh2 ->
  exists beh1, program_behaves L1 beh1 /\ behavior_improves beh1 beh2.
Proof.
  intros L1 L2 S beh2 H. destruct S as [index order match_states S]. inv H.
- (* L2's initial state is defined. *)
  destruct (classic (exists s1, initial_state L1 s1)) as [[s1 INIT] | NOINIT].
+ (* L1's initial state is defined too. *)
  exploit (bsim_match_initial_states S); eauto. intros [i [s1' [INIT1' MATCH]]].
  exploit backward_simulation_state_behaves; eauto. intros [beh1 [A B]].
  exists beh1; split; auto. econstructor; eauto.
+ (* L1 has no initial state *)
  exists (Goes_wrong E0); split.
  apply program_goes_initially_wrong.
  intros; red; intros. elim NOINIT; exists s0; auto.
  apply behavior_improves_bot.
- (* L2 has no initial state *)
  exists (Goes_wrong E0); split.
  apply program_goes_initially_wrong.
  intros; red; intros.
  exploit (bsim_initial_states_exist S); eauto. intros [s2 INIT2].
  elim (H0 s2); auto.
  apply behavior_improves_refl.
Qed.

Corollary backward_simulation_same_safe_behavior:
  forall L1 L2, backward_simulation L1 L2 ->
  (forall beh, program_behaves L1 beh -> not_wrong beh) ->
  (forall beh, program_behaves L2 beh -> program_behaves L1 beh).
Proof.
  intros. exploit backward_simulation_behavior_improves; eauto.
  intros [beh' [A B]]. destruct B.
  congruence.
  destruct H2 as [t [C D]]. subst. elim (H0 (Goes_wrong t)). auto.
Qed.

Program behaviors for the "atomic" construction


Section ATOMIC.

Variable L: semantics.
Hypothesis Lwb: well_behaved_traces L.

Remark atomic_finish: forall s t, output_trace t -> Star (atomic L) (t, s) t (E0, s).
Proof.
  induction t; intros.
  apply star_refl.
  simpl in H; destruct H. eapply star_left; eauto.
  simpl. apply atomic_step_continue; auto. simpl; auto. auto.
Qed.

Lemma step_atomic_plus:
  forall s1 t s2, Step L s1 t s2 -> Plus (atomic L) (E0,s1) t (E0,s2).
Proof.
  intros. destruct t.
  apply plus_one. simpl; apply atomic_step_silent; auto.
  exploit Lwb; eauto. simpl; intros.
  eapply plus_left. eapply atomic_step_start; eauto. eapply atomic_finish; eauto. auto.
Qed.

Lemma star_atomic_star:
  forall s1 t s2, Star L s1 t s2 -> Star (atomic L) (E0,s1) t (E0,s2).
Proof.
  induction 1. apply star_refl. eapply star_trans with (s2 := (E0,s2)).
  apply plus_star. eapply step_atomic_plus; eauto. eauto. auto.
Qed.

Lemma atomic_forward_simulation: forward_simulation L (atomic L).
Proof.
  set (ms := fun (s: state L) (ts: state (atomic L)) => ts = (E0,s)).
  apply forward_simulation_plus with ms; intros.
  auto.
  exists (E0,s1); split. simpl; auto. red; auto.
  red in H. subst s2. simpl; auto.
  red in H0. subst s2. exists (E0,s1'); split.
  apply step_atomic_plus; auto. red; auto.
Qed.

Lemma atomic_star_star_gen:
  forall ts1 t ts2, Star (atomic L) ts1 t ts2 ->
  exists t', Star L (snd ts1) t' (snd ts2) /\ fst ts1 ** t' = t ** fst ts2.
Proof.
  induction 1.
  exists E0; split. apply star_refl. traceEq.
  destruct IHstar as [t' [A B]].
  simpl in H; inv H; simpl in *.
  exists t'; split. eapply star_left; eauto. auto.
  exists (ev :: t0 ** t'); split. eapply star_left; eauto. rewrite B; auto.
  exists t'; split. auto. rewrite B; auto.
Qed.

Lemma atomic_star_star:
  forall s1 t s2, Star (atomic L) (E0,s1) t (E0,s2) -> Star L s1 t s2.
Proof.
  intros. exploit atomic_star_star_gen; eauto. intros [t' [A B]].
  simpl in *. replace t with t'. auto. subst; traceEq.
Qed.

Lemma atomic_forever_silent_forever_silent:
  forall s, Forever_silent (atomic L) s -> Forever_silent L (snd s).
Proof.
  cofix COINDHYP; intros. inv H. inv H0.
  apply forever_silent_intro with (snd (E0, s')). auto. apply COINDHYP; auto.
Qed.

Remark star_atomic_output_trace:
  forall s t t' s',
  Star (atomic L) (E0, s) t (t', s') -> output_trace t'.
Proof.
  assert (forall ts1 t ts2, Star (atomic L) ts1 t ts2 ->
          output_trace (fst ts1) -> output_trace (fst ts2)).
  induction 1; intros. auto. inv H; simpl in *.
  apply IHstar. auto.
  apply IHstar. exploit Lwb; eauto.
  destruct H2. apply IHstar. auto.
  intros. change t' with (fst (t',s')). eapply H; eauto. simpl; auto.
Qed.

Lemma atomic_forever_reactive_forever_reactive:
  forall s T, Forever_reactive (atomic L) (E0,s) T -> Forever_reactive L s T.
Proof.
  assert (forall t s T, Forever_reactive (atomic L) (t,s) T ->
          exists T', Forever_reactive (atomic L) (E0,s) T' /\ T = t *** T').
  induction t; intros. exists T; auto.
  inv H. inv H0. congruence. simpl in H; inv H.
  destruct (IHt s (t2***T0)) as [T' [A B]]. eapply star_forever_reactive; eauto.
  exists T'; split; auto. simpl. congruence.

  cofix COINDHYP; intros. inv H0. destruct s2 as [t2 s2].
  destruct (H _ _ _ H3) as [T' [A B]].
  assert (Star (atomic L) (E0, s) (t**t2) (E0, s2)).
    eapply star_trans. eauto. apply atomic_finish. eapply star_atomic_output_trace; eauto. auto.
  replace (t *** T0) with ((t ** t2) *** T'). apply forever_reactive_intro with s2.
  apply atomic_star_star; auto. destruct t; simpl in *; unfold E0 in *; congruence.
  apply COINDHYP. auto.
  subst T0; traceEq.
Qed.

Theorem atomic_behaviors:
  forall beh, program_behaves L beh <-> program_behaves (atomic L) beh.
Proof.
  intros; split; intros.
- (* L -> atomic L *)
  exploit forward_simulation_behavior_improves. eapply atomic_forward_simulation. eauto.
  intros [beh2 [A B]]. red in B. destruct B as [EQ | [t [C D]]].
  congruence.
  subst beh. inv H. inv H1.
  apply program_runs with (E0,s). simpl; auto.
  apply state_goes_wrong with (E0,s'). apply star_atomic_star; auto.
  red; intros; red; intros. inv H. eelim H3; eauto. eelim H3; eauto.
  intros; red; intros. simpl in H. destruct H. eelim H4; eauto.
  apply program_goes_initially_wrong.
  intros; red; intros. simpl in H; destruct H. eelim H1; eauto.
- (* atomic L -> L *)
  inv H.
+ (* initial state defined *)
  destruct s as [t s]. simpl in H0. destruct H0; subst t.
  apply program_runs with s; auto.
  inv H1.
* (* termination *)
  destruct s' as [t' s']. simpl in H2; destruct H2; subst t'.
  econstructor. eapply atomic_star_star; eauto. auto.
* (* silent divergence *)
  destruct s' as [t' s'].
  assert (t' = E0). inv H2. inv H1; auto. subst t'.
  econstructor. eapply atomic_star_star; eauto.
  change s' with (snd (E0,s')). apply atomic_forever_silent_forever_silent. auto.
* (* reactive divergence *)
  econstructor. apply atomic_forever_reactive_forever_reactive. auto.
* (* going wrong *)
  destruct s' as [t' s'].
  assert (t' = E0).
    destruct t'; auto. eelim H2. simpl. apply atomic_step_continue.
    eapply star_atomic_output_trace; eauto.
  subst t'. econstructor. apply atomic_star_star; eauto.
  red; intros; red; intros. destruct t0.
  elim (H2 E0 (E0,s'0)). constructor; auto.
  elim (H2 (e::nil) (t0,s'0)). constructor; auto.
  intros; red; intros. elim (H3 r). simpl; auto.
+ (* initial state undefined *)
  apply program_goes_initially_wrong.
  intros; red; intros. elim (H0 (E0,s)); simpl; auto.
Qed.

End ATOMIC.

Additional results about infinite reduction sequences


We now show that any infinite sequence of reductions is either of the "reactive" kind or of the "silent" kind (after a finite number of non-silent transitions). The proof necessitates the axiom of excluded middle. This result is used below to relate the coinductive big-step semantics for divergence with the small-step notions of divergence.

Unset Implicit Arguments.

Section INF_SEQ_DECOMP.

Variable genv: Type.
Variable state: Type.
Variable step: genv -> state -> trace -> state -> Prop.

Variable ge: genv.

Inductive tstate: Type :=
  ST: forall (s: state) (T: traceinf), forever step ge s T -> tstate.

Definition state_of_tstate (S: tstate): state :=
  match S with ST s T F => s end.
Definition traceinf_of_tstate (S: tstate) : traceinf :=
  match S with ST s T F => T end.

Inductive tstep: trace -> tstate -> tstate -> Prop :=
  | tstep_intro: forall s1 t T s2 S F,
      tstep t (ST s1 (t *** T) (@forever_intro genv state step ge s1 t s2 T S F))
              (ST s2 T F).

Inductive tsteps: tstate -> tstate -> Prop :=
  | tsteps_refl: forall S, tsteps S S
  | tsteps_left: forall t S1 S2 S3, tstep t S1 S2 -> tsteps S2 S3 -> tsteps S1 S3.

Remark tsteps_trans:
  forall S1 S2, tsteps S1 S2 -> forall S3, tsteps S2 S3 -> tsteps S1 S3.
Proof.
  induction 1; intros. auto. econstructor; eauto.
Qed.

Let treactive (S: tstate) : Prop :=
  forall S1,
  tsteps S S1 ->
  exists S2, exists S3, exists t, tsteps S1 S2 /\ tstep t S2 S3 /\ t <> E0.

Let tsilent (S: tstate) : Prop :=
  forall S1 t S2, tsteps S S1 -> tstep t S1 S2 -> t = E0.

Lemma treactive_or_tsilent:
  forall S, treactive S \/ (exists S', tsteps S S' /\ tsilent S').
Proof.
  intros. destruct (classic (exists S', tsteps S S' /\ tsilent S')).
  auto.
  left. red; intros.
  generalize (not_ex_all_not _ _ H S1). intros.
  destruct (not_and_or _ _ H1). contradiction.
  unfold tsilent in H2.
  generalize (not_all_ex_not _ _ H2). intros [S2 A].
  generalize (not_all_ex_not _ _ A). intros [t B].
  generalize (not_all_ex_not _ _ B). intros [S3 C].
  generalize (imply_to_and _ _ C). intros [D F].
  generalize (imply_to_and _ _ F). intros [G J].
  exists S2; exists S3; exists t. auto.
Qed.

Lemma tsteps_star:
  forall S1 S2, tsteps S1 S2 ->
  exists t, star step ge (state_of_tstate S1) t (state_of_tstate S2)
         /\ traceinf_of_tstate S1 = t *** traceinf_of_tstate S2.
Proof.
  induction 1.
  exists E0; split. apply star_refl. auto.
  inv H. destruct IHtsteps as [t' [A B]].
  exists (t ** t'); split.
  simpl; eapply star_left; eauto.
  simpl in *. subst T. traceEq.
Qed.

Lemma tsilent_forever_silent:
  forall S,
  tsilent S -> forever_silent step ge (state_of_tstate S).
Proof.
  cofix COINDHYP; intro S. case S. intros until f. simpl. case f. intros.
  assert (tstep t (ST s1 (t *** T0) (forever_intro s1 t s0 f0))
                  (ST s2 T0 f0)).
    constructor.
  assert (t = E0).
    red in H. eapply H; eauto. apply tsteps_refl.
  apply forever_silent_intro with (state_of_tstate (ST s2 T0 f0)).
  rewrite <- H1. assumption.
  apply COINDHYP.
  red; intros. eapply H. eapply tsteps_left; eauto. eauto.
Qed.

Lemma treactive_forever_reactive:
  forall S,
  treactive S -> forever_reactive step ge (state_of_tstate S) (traceinf_of_tstate S).
Proof.
  cofix COINDHYP; intros.
  destruct (H S) as [S1 [S2 [t [A [B C]]]]]. apply tsteps_refl.
  destruct (tsteps_star _ _ A) as [t' [P Q]].
  inv B. simpl in *. rewrite Q. rewrite <- Eappinf_assoc.
  apply forever_reactive_intro with s2.
  eapply star_right; eauto.
  red; intros. destruct (Eapp_E0_inv _ _ H0). contradiction.
  change (forever_reactive step ge (state_of_tstate (ST s2 T F)) (traceinf_of_tstate (ST s2 T F))).
  apply COINDHYP.
  red; intros. apply H.
  eapply tsteps_trans. eauto.
  eapply tsteps_left. constructor. eauto.
Qed.

Theorem forever_silent_or_reactive:
  forall s T,
  forever step ge s T ->
  forever_reactive step ge s T \/
  exists t, exists s', exists T',
  star step ge s t s' /\ forever_silent step ge s' /\ T = t *** T'.
Proof.
  intros.
  destruct (treactive_or_tsilent (ST s T H)).
  left.
  change (forever_reactive step ge (state_of_tstate (ST s T H)) (traceinf_of_tstate (ST s T H))).
  apply treactive_forever_reactive. auto.
  destruct H0 as [S' [A B]].
  exploit tsteps_star; eauto. intros [t [C D]]. simpl in *.
  right. exists t; exists (state_of_tstate S'); exists (traceinf_of_tstate S').
  split. auto.
  split. apply tsilent_forever_silent. auto.
  auto.
Qed.

End INF_SEQ_DECOMP.

Set Implicit Arguments.

Big-step semantics and program behaviors


Section BIGSTEP_BEHAVIORS.

Variable B: bigstep_semantics.
Variable L: semantics.
Hypothesis sound: bigstep_sound B L.

Lemma behavior_bigstep_terminates:
  forall t r,
  bigstep_terminates B t r -> program_behaves L (Terminates t r).
Proof.
  intros. exploit (bigstep_terminates_sound sound); eauto.
  intros [s1 [s2 [P [Q R]]]].
  econstructor; eauto. econstructor; eauto.
Qed.

Lemma behavior_bigstep_diverges:
  forall T,
  bigstep_diverges B T ->
  program_behaves L (Reacts T)
  \/ exists t, program_behaves L (Diverges t) /\ traceinf_prefix t T.
Proof.
  intros. exploit (bigstep_diverges_sound sound); eauto. intros [s1 [P Q]].
  exploit forever_silent_or_reactive; eauto. intros [X | [t [s' [T' [X [Y Z]]]]]].
  left. econstructor; eauto. constructor; auto.
  right. exists t; split. econstructor; eauto. econstructor; eauto. exists T'; auto.
Qed.

End BIGSTEP_BEHAVIORS.
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