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OneRuleAtATime.v
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OneRuleAtATime.v
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(*! ORAAT | Proof of the One-rule-at-a-time theorem !*)
Require Import
Koika.Common Koika.Syntax Koika.TypedSyntax
Koika.TypedSyntaxFunctions Koika.SemanticProperties.
Require Import Coq.setoid_ring.Ring_theory Coq.setoid_ring.Ring Coq.setoid_ring.Ring.
Open Scope bool_scope.
Section Proof.
Context {pos_t var_t fn_name_t rule_name_t reg_t ext_fn_t: Type}.
Context {reg_t_eq_dec: EqDec reg_t}.
Context {R: reg_t -> type}.
Context {Sigma: ext_fn_t -> ExternalSignature}.
Context {REnv: Env reg_t}.
Context (r: REnv.(env_t) R).
Context (sigma: forall f, Sig_denote (Sigma f)).
Notation Log := (Log R REnv).
Notation action := (action pos_t var_t fn_name_t R Sigma).
Notation rule := (rule pos_t var_t fn_name_t R Sigma).
Notation scheduler := (scheduler pos_t rule_name_t).
Context (rules: rule_name_t -> rule).
Fixpoint interp_scheduler'_trace
(sched_log: Log)
(s: scheduler)
{struct s} :=
let interp_try rl s1 s2 :=
match interp_rule r sigma sched_log (rules rl) with
| Some l => match interp_scheduler'_trace (log_app l sched_log) s1 with
| Some (rs, log) => Some (rl :: rs, log)
| None => None
end
| None => interp_scheduler'_trace sched_log s2
end in
match s with
| Done => Some ([], sched_log)
| Cons rl s => interp_try rl s s
| Try rl s1 s2 => interp_try rl s1 s2
| SPos _ s => interp_scheduler'_trace sched_log s
end.
Definition interp_scheduler_trace_and_update
l
(s: scheduler) :=
match interp_scheduler'_trace l s with
| Some (rs, log) => Some (rs, commit_update r log)
| None => None
end.
Definition interp_oraat r rl: REnv.(env_t) R :=
interp_cycle sigma rules (Try rl Done Done) r.
Ltac set_forallb_fns :=
repeat match goal with
| [ |- context[log_forallb _ _ ?fn] ] =>
match fn with
| (fun _ => _) => set fn
end
end.
Lemma may_read_app_sl :
forall (sl sl': Log) prt idx,
may_read (log_app sl sl') prt idx =
may_read sl prt idx && may_read sl' prt idx.
Proof.
unfold may_read; intros.
destruct prt; rewrite !log_forallb_not_existsb, !log_forallb_app;
ring_simplify; f_equal.
Qed.
Lemma may_write_app_sl :
forall (sl sl': Log) l prt idx,
may_write (log_app sl sl') l prt idx =
may_write sl l prt idx && may_write sl' l prt idx.
Proof.
unfold may_write; intros.
destruct prt; rewrite !log_forallb_not_existsb, !log_forallb_app;
ring_simplify;
repeat (destruct (log_forallb _ _ _); cbn; try reflexivity).
Qed.
Ltac bool_step :=
match goal with
| _ => progress Common.bool_step
| [ H: log_forallb (log_app _ _) _ _ = _ |- _ ] =>
rewrite log_forallb_app in H
end.
Lemma may_read0_no_writes :
forall (sl: Log) idx,
may_read sl P0 idx = true ->
latest_write sl idx = None.
Proof.
unfold may_read; intros.
rewrite !log_forallb_not_existsb in H.
repeat (cleanup_step || bool_step).
unfold log_forallb in *.
rewrite forallb_forall in *.
unfold is_write0, is_write1, latest_write, log_find in *.
apply find_none_notb.
intros a HIn.
repeat match goal with
| [ H: forall (_: LogEntry _), _ |- _ ] => specialize (H a HIn)
end.
destruct a; cbn in *; destruct kind; subst; try reflexivity.
destruct port; cbn in *; try discriminate.
Qed.
Lemma may_read1_latest_write_is_0 :
forall (l: Log) idx,
may_read l P1 idx = true ->
latest_write l idx = latest_write0 l idx.
Proof.
unfold may_read, latest_write, latest_write0, log_find, log_forallb.
intros * H.
rewrite log_forallb_not_existsb in H; unfold log_forallb in H.
set (getenv REnv l idx) as ls in *; cbn in *; clearbody ls.
set (R idx) as t in *; cbn in *.
revert H.
induction ls.
- reflexivity.
- intros * H; cbn in H.
repeat (bool_step || cleanup_step).
rewrite (IHls ltac:(eassumption)).
unfold log_latest_write_fn; cbn.
destruct a, kind, port; try discriminate; reflexivity.
Qed.
Create HintDb oraat.
Hint Unfold interp_cycle : oraat.
Hint Unfold interp_oraat : oraat.
Hint Unfold interp_rule : oraat.
Ltac t_step :=
match goal with
| _ => cleanup_step
| _ => progress autounfold with oraat in *
| [ H: context[may_read (log_app _ _) _ _] |- _ ] =>
rewrite may_read_app_sl in H
| [ H: context[may_write (log_app _ _) _ _ _] |- _ ] =>
rewrite may_write_app_sl in H
| [ H: Some _ = Some _ |- _ ] =>
inversion H; subst; clear H
| [ H: opt_bind ?x _ = Some _ |- _ ] =>
destruct x eqn:?; cbn in H; try discriminate
| [ H: match ?x with _ => _ end = Some _ |- _ ] =>
destruct x eqn:?; subst; cbn in H; try discriminate
| _ =>
bool_step
| [ H: match ?x with _ => _ end = ?c |- _ ] =>
let c_hd := constr_hd c in
is_constructor c_hd; destruct x eqn:?
| [ H: ?x = _ |- context[match ?x with _ => _ end] ] =>
rewrite H
| [ H: context[_ -> _ = Some _] |- _ ] =>
erewrite H by eauto
| _ => reflexivity
end.
Ltac t :=
repeat t_step.
Lemma interp_action_commit:
forall {sig tau} (a: action sig tau) (Gamma: tcontext sig) (sl sl': Log) action_log lv,
interp_action r sigma Gamma (log_app sl sl') action_log a = Some lv ->
interp_action (commit_update r sl') sigma Gamma sl action_log a = Some lv.
Proof.
fix IH 3; destruct a; cbn;
intros Gamma sl sl' action_log lv HSome; try congruence.
- (* Assign *) t.
- (* Seq *) t.
- (* Bind *) t.
- (* If *) t.
- destruct port; t.
+ (* Read0 *)
erewrite getenv_commit_update by eassumption.
erewrite may_read0_no_writes by eauto.
reflexivity.
+ (* Read1 *)
rewrite log_app_assoc.
rewrite (latest_write0_app (log_app action_log sl) sl').
destruct latest_write0.
* reflexivity.
* erewrite getenv_commit_update by eassumption.
rewrite may_read1_latest_write_is_0 by eassumption.
reflexivity.
- (* Write *) t.
- (* UnOp *) t.
- (* BinOp *) t.
- (* ExternalCall *) t.
- (* InternalCall *)
assert (let interp_action r sigma :=
@interp_action pos_t var_t fn_name_t reg_t ext_fn_t R Sigma REnv r sigma in
forall argspec (args: acontext sig argspec) (Gamma: tcontext sig) (sl sl': Log) action_log lv,
interp_args' (interp_action r sigma) Gamma (log_app sl sl') action_log args = Some lv ->
interp_args' (interp_action (commit_update r sl') sigma) Gamma sl action_log args = Some lv).
{ clear -IH; intro.
fix IHargs 2; destruct args; cbn;
intros Gamma sl sl' action_log lv **.
+ t.
+ t. }
t.
- (* APos *) t.
Qed.
Lemma OneRuleAtATime':
forall s rs r' l0,
interp_scheduler_trace_and_update l0 s = Some (rs, r') ->
List.fold_left interp_oraat rs (commit_update r l0) = r'.
Proof.
induction s; cbn;
unfold interp_scheduler_trace_and_update; cbn.
- (* Done *) inversion 1; subst; cbn in *; eauto.
- (* Cons *) intros; t.
+ erewrite interp_action_commit by (rewrite log_app_empty_r; eassumption);
cbn.
rewrite log_app_empty_l.
rewrite commit_update_assoc.
eapply IHs.
unfold interp_scheduler_trace_and_update.
rewrite Heqo1; reflexivity.
+ eapply IHs.
unfold interp_scheduler_trace_and_update; rewrite Heqo.
reflexivity.
- (* Try *) intros; t.
+ erewrite interp_action_commit by (rewrite log_app_empty_r; eassumption);
cbn.
rewrite log_app_empty_l.
rewrite commit_update_assoc.
eapply IHs1.
unfold interp_scheduler_trace_and_update.
rewrite Heqo1; reflexivity.
+ eapply IHs2.
unfold interp_scheduler_trace_and_update; rewrite Heqo.
reflexivity.
- (* SPos *) eauto.
Qed.
Lemma interp_scheduler_trace_correct :
forall s l0 log,
interp_scheduler' r sigma rules l0 s = log ->
exists rs, interp_scheduler'_trace l0 s = Some (rs, log).
Proof.
induction s; cbn.
- (* Done *) inversion 1; subst; eauto.
- (* Cons *) intros * Heq. destruct interp_rule as [log' | ] eqn:?.
+ destruct (IHs _ _ Heq) as (rs & Heq').
rewrite Heq'; eauto.
+ destruct (IHs _ _ Heq) as (rs & Heq').
rewrite Heq'; eauto.
- (* Try *) intros * Heq. destruct interp_rule as [log' | ] eqn:?.
+ destruct (IHs1 _ _ Heq) as (rs & Heq').
rewrite Heq'; eauto.
+ destruct (IHs2 _ _ Heq) as (rs & Heq').
rewrite Heq'; eauto.
- (* SPos *) eauto.
Qed.
Lemma scheduler_trace_in_scheduler :
forall s log l0 rs,
interp_scheduler'_trace l0 s = Some (rs, log) ->
(forall r : rule_name_t, In r rs -> In r (scheduler_rules s)).
Proof.
induction s; cbn in *.
- (* Done *) inversion 1; subst; inversion 1.
- (* Cons *) intros * H * H'; t.
+ inversion H'; subst; eauto.
+ eauto.
- (* Try *) intros * H * H'; rewrite in_app_iff; t.
+ inversion H'; subst; eauto.
+ eauto.
- (* SPos *) eauto.
Qed.
Theorem OneRuleAtATime:
forall s log,
interp_scheduler r sigma rules s = log ->
exists rs,
(forall rl, List.In rl rs -> List.In rl (scheduler_rules s)) /\
List.fold_left interp_oraat rs r = commit_update r log.
Proof.
intros * H.
apply interp_scheduler_trace_correct in H; destruct H as (rs & H).
exists rs; split.
- eauto using scheduler_trace_in_scheduler.
- rewrite <- (commit_update_empty r) at 1.
eapply OneRuleAtATime'.
unfold interp_scheduler_trace_and_update; rewrite H; reflexivity.
Qed.
End Proof.