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sep-sol.v
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sep-sol.v
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Require Import Bool Arith List Omega.
Require Import Recdef Morphisms.
Require Import Program.Tactics.
Require Import Relation_Operators.
Require FMapList.
Require FMapFacts.
Require Import Classical.
Require Import Coq.Classes.RelationClasses.
Require Import OrderedType OrderedTypeEx DecidableType.
Require Import Sorting.Permutation.
Import ListNotations.
Module WXFacts_fun (E:DecidableType) (Import Map:FMapInterface.WSfun E).
Module MapF := FMapFacts.WFacts_fun E Map.
Module MapProperties := FMapFacts.WProperties_fun E Map.
Section XFacts.
Notation eq_dec := E.eq_dec.
Context {elt: Type}.
Implicit Types m: t elt.
Implicit Types x y z: key.
Implicit Types e: elt.
Notation Partition := MapProperties.Partition.
Notation Disjoint := MapProperties.Disjoint.
Notation update := MapProperties.update.
Definition Submap m1 m2 :=
forall k e, MapsTo k e m1 -> MapsTo k e m2.
Lemma Submap_in:
forall {m1 m2}, Submap m1 m2 ->
forall k, In k m1 -> In k m2.
Proof.
intros m1 m2 S k I.
destruct I.
exists x.
now apply S.
Qed.
(* Pull in the library’s facts on Disjoint and Partition. *)
Lemma Disjoint_alt:
forall m m', Disjoint m m' <->
(forall k e e', MapsTo k e m ->
MapsTo k e' m' ->
False).
Proof.
apply MapProperties.Disjoint_alt.
Qed.
Lemma Disjoint_empty_r:
forall {m}, Disjoint m (Map.empty elt).
Proof.
intros; rewrite Disjoint_alt; intros.
now rewrite MapF.empty_mapsto_iff in H0.
Qed.
Lemma Disjoint_sym:
forall {m1 m2}, Disjoint m1 m2 -> Disjoint m2 m1.
Proof.
apply MapProperties.Disjoint_sym.
Qed.
Lemma Disjoint_in_nin:
forall {m1 m2}, Disjoint m1 m2 ->
forall k, In k m1 -> ~ In k m2.
Proof.
intros m1 m2 D k I1 I2; apply (D k); intuition.
Qed.
Lemma Disjoint_mapsto_nin:
forall {m1 m2}, Disjoint m1 m2 ->
forall k e, MapsTo k e m1 -> ~ In k m2.
Proof.
intros m1 m2 D k e M1 I2; apply (D k); intuition; now exists e.
Qed.
Lemma Disjoint_submap_r:
forall m1 m2 m3, Disjoint m1 m2 ->
Submap m3 m2 -> Disjoint m1 m3.
Proof.
intros m1 m2 m3 D S k I; destruct I as [I1 I2].
apply (Submap_in S) in I2; now apply (D k).
Qed.
Lemma update_in_iff:
forall m1 m2 k, In k (update m1 m2) <-> In k m1 \/ In k m2.
Proof.
apply MapProperties.update_in_iff.
Qed.
Lemma update_mapsto_iff:
forall m1 m2 k e, MapsTo k e (update m1 m2) <->
(MapsTo k e m2 \/
(MapsTo k e m1 /\ ~ In k m2)).
Proof.
apply MapProperties.update_mapsto_iff.
Qed.
Lemma disjoint_update_mapsto_iff:
forall {m1 m2}, Disjoint m1 m2 ->
forall k e, MapsTo k e (update m1 m2) <->
MapsTo k e m1 \/ MapsTo k e m2.
Proof.
intros m1 m2 D k e; rewrite update_mapsto_iff.
generalize (Disjoint_mapsto_nin D k e); intros G; intuition.
Qed.
Lemma disjoint_update_comm:
forall {m1 m2}, Disjoint m1 m2 ->
Map.Equal (update m1 m2) (update m2 m1).
Proof.
intros m1 m2 D; rewrite MapF.Equal_mapsto_iff; intros.
rewrite (disjoint_update_mapsto_iff D).
rewrite (disjoint_update_mapsto_iff (Disjoint_sym D)).
intuition.
Qed.
Lemma update_submap_r:
forall m1 m2, Submap m2 (update m1 m2).
Proof.
intros m1 m2 k e M; apply update_mapsto_iff; now left.
Qed.
Lemma disjoint_update_submap_l:
forall {m1 m2}, Disjoint m1 m2 ->
Submap m1 (update m1 m2).
Proof.
intros m1 m2 D k e M; apply disjoint_update_mapsto_iff; intuition.
Qed.
Lemma Partition_disjoint:
forall {m m1 m2}, Partition m m1 m2 -> Disjoint m1 m2.
Proof.
unfold Partition; intuition.
Qed.
Lemma Partition_mapsto_iff:
forall {m m1 m2}, Partition m m1 m2 ->
forall k e, MapsTo k e m <->
MapsTo k e m1 \/ MapsTo k e m2.
Proof.
unfold Partition; intuition.
Qed.
Lemma Partition_mapsto_l:
forall {m m1 m2}, Partition m m1 m2 ->
forall k e, MapsTo k e m1 -> MapsTo k e m.
Proof.
intros; rewrite (Partition_mapsto_iff H); intuition.
Qed.
Lemma Partition_mapsto_r:
forall {m m1 m2}, Partition m m1 m2 ->
forall k e, MapsTo k e m2 -> MapsTo k e m.
Proof.
intros; rewrite (Partition_mapsto_iff H); intuition.
Qed.
Lemma Partition_submap_l:
forall {m m1 m2}, Partition m m1 m2 -> Submap m1 m.
Proof.
intros m m1 m2 P k e M; rewrite (Partition_mapsto_iff P); intuition.
Qed.
Lemma Partition_submap_r:
forall {m m1 m2}, Partition m m1 m2 -> Submap m2 m.
Proof.
intros m m1 m2 P k e M; rewrite (Partition_mapsto_iff P); intuition.
Qed.
Lemma Partition_in_iff:
forall {m m1 m2}, Partition m m1 m2 ->
forall k, In k m <-> In k m1 \/ In k m2.
Proof.
intros; generalize (Partition_mapsto_iff H); split; intros.
- destruct H1; rewrite H0 in H1; destruct or H1;
[ left | right ]; now exists x.
- destruct or H1; destruct H1; exists x; rewrite H0; intuition.
Qed.
Lemma Partition_in_l:
forall {m m1 m2}, Partition m m1 m2 ->
forall k, In k m1 -> In k m.
Proof.
intros; rewrite (Partition_in_iff H); intuition.
Qed.
Lemma Partition_in_r:
forall {m m1 m2}, Partition m m1 m2 ->
forall k, In k m2 -> In k m.
Proof.
intros; rewrite (Partition_in_iff H); intuition.
Qed.
Lemma Partition_refl:
forall m, Partition m m (Map.empty elt).
Proof.
intros; unfold Partition; split.
- apply Disjoint_empty_r.
- intros; rewrite MapF.empty_mapsto_iff; intuition.
Qed.
Lemma Partition_sym:
forall m m1 m2, Partition m m1 m2 -> Partition m m2 m1.
Proof.
apply MapProperties.Partition_sym.
Qed.
Lemma Partition_empty_r:
forall m m', Partition m m' (Map.empty elt) ->
Map.Equal m m'.
Proof.
intros; apply MapF.Equal_mapsto_iff; intros.
unfold Partition in *; destruct_conjs.
generalize (H0 k e); rewrite MapF.empty_mapsto_iff; intuition.
Qed.
Lemma Partition_update:
forall m m1 m2, Partition m m1 m2 ->
Map.Equal m (update m1 m2).
Proof.
intros; unfold MapProperties.Partition in *; destruct_conjs.
apply MapF.Equal_mapsto_iff; intros.
rewrite H0.
rewrite (disjoint_update_mapsto_iff H).
intuition.
Qed.
Lemma disjoint_update_partition:
forall m1 m2, Disjoint m1 m2 ->
Partition (update m1 m2) m1 m2.
Proof.
intros; unfold Partition; split; auto; intros.
rewrite (disjoint_update_mapsto_iff H); intuition.
Qed.
Lemma Partition_assoc:
forall m m1 m2 m2a m2b,
Partition m m1 m2 ->
Partition m2 m2a m2b ->
Partition m (update m1 m2a) m2b.
Proof.
intros; unfold Partition; split.
- unfold Disjoint; intros k I; destruct I as [Ia Ib].
apply update_in_iff in Ia; destruct or Ia.
+ apply (Partition_disjoint H k).
now apply (Partition_in_r H0) in Ib.
+ now apply (Partition_disjoint H0 k).
- intros; rewrite disjoint_update_mapsto_iff.
rewrite (Partition_mapsto_iff H).
rewrite (Partition_mapsto_iff H0).
split; intuition.
apply Disjoint_submap_r with (m2:=m2).
apply (Partition_disjoint H).
apply (Partition_submap_l H0).
Qed.
Lemma Partition_add_1:
forall m m1 m2 k v v1,
Partition m (Map.add k v1 m1) m2 ->
Partition (Map.add k v m) (Map.add k v m1) m2.
Proof.
intros m m1 m2 k v v1 P.
unfold Partition; split.
- intros kk I; destruct I; apply (Partition_disjoint P kk).
rewrite MapF.add_in_iff in *; intuition.
- intros kk e.
rewrite MapF.add_mapsto_iff.
rewrite (Partition_mapsto_iff P).
repeat rewrite MapF.add_mapsto_iff.
intuition.
right; split; intuition.
apply (Partition_disjoint P kk).
rewrite H in *; rewrite MapF.add_in_iff; intuition; now exists e.
Qed.
End XFacts.
End WXFacts_fun.
Module Separation.
Definition ptr := Z.
Definition ptr_eq := Z.eq_dec.
Definition value := Z.
Implicit Types v: value.
Module Heap := FMapList.Make Z_as_OT.
Module HeapF := FMapFacts.WFacts_fun Z_as_OT Heap.
Module HeapP := FMapFacts.WProperties_fun Z_as_OT Heap.
Module HeapX := WXFacts_fun Z_as_OT Heap.
Definition heap := Heap.t value.
Implicit Types h : heap.
Definition empty_heap := Heap.empty value.
Notation heap_Equal := Heap.Equal.
(* Assertions, aka heap propositions *)
Definition weak_assertion := heap -> Prop.
Definition assertion_wf (wa:weak_assertion) :=
forall h1 h2,
heap_Equal h1 h2 -> wa h1 -> wa h2.
Lemma assertion_wf_iff:
forall wa:weak_assertion,
forall wawf:assertion_wf wa,
forall h1 h2,
heap_Equal h1 h2 -> wa h1 <-> wa h2.
Proof.
split; intros; unfold assertion_wf in *.
- now apply wawf with (h1:=h1).
- apply wawf with (h1:=h2); [ symmetry | ]; auto.
Qed.
Inductive assertion : Type :=
| Assert : forall wa:weak_assertion,
forall wawf:assertion_wf wa,
assertion.
Hint Constructors assertion.
Definition asserts : assertion -> heap -> Prop :=
fun a h =>
match a with
| Assert wa _ => wa h
end.
Definition assertion_imp : assertion -> assertion -> Prop :=
fun a1 a2 =>
forall h, asserts a1 h -> asserts a2 h.
Definition assertion_iff : assertion -> assertion -> Prop :=
fun a1 a2 =>
forall h, asserts a1 h <-> asserts a2 h.
Infix "===>" := assertion_imp (at level 90) : sep_scope.
Infix "<===>" := assertion_iff (at level 90) : sep_scope.
Local Open Scope sep_scope.
Global Instance: Proper (eq ==> heap_Equal ==> iff) asserts.
Proof.
intros a1 a2 aeq h1 h2 heq.
subst; destruct a2.
unfold asserts; split; intros.
- now apply (wawf _ _ heq).
- symmetry in heq; now apply (wawf _ _ heq).
Qed.
Definition emp : assertion.
refine (Assert (fun h => heap_Equal h empty_heap) _).
unfold assertion_wf; intros.
now rewrite <- H.
Defined.
Definition pointsto : ptr -> value -> assertion.
intros p v.
refine (Assert (fun h => heap_Equal h
(Heap.add p v empty_heap)) _).
unfold assertion_wf; intros; now rewrite <- H.
Defined.
Infix "|>" := pointsto (no associativity, at level 75) : sep_scope.
Definition points : ptr -> assertion.
intros p.
refine (Assert (fun h => exists v,
heap_Equal h (Heap.add p v empty_heap)) _).
unfold assertion_wf; intros.
destruct H0; exists x; now rewrite <- H.
Defined.
Notation "p |>?" := (points p) (no associativity, at level 75) : sep_scope.
Definition weak_star : assertion -> assertion ->
weak_assertion :=
fun a1 a2 =>
fun h =>
exists h1 h2, HeapP.Partition h h1 h2 /\
asserts a1 h1 /\
asserts a2 h2.
Definition star : assertion -> assertion ->
assertion.
intros a1 a2.
refine (Assert (weak_star a1 a2) _).
unfold assertion_wf; unfold weak_star; intros; destruct_conjs.
exists H0, H1; rewrite <- H; intuition.
Defined.
Infix "**" := star (right associativity, at level 80) : sep_scope.
Definition heq : heap -> assertion.
intros h.
refine (Assert (fun h' => Heap.Equal h h') _).
unfold assertion_wf; intros; transitivity h1; auto.
Defined.
Definition weak_imp : assertion -> assertion ->
weak_assertion :=
fun a1 a2 =>
fun h => asserts a1 h -> asserts a2 h.
Definition imp : assertion -> assertion ->
assertion.
intros a1 a2.
refine (Assert (weak_imp a1 a2) _).
unfold assertion_wf. unfold weak_imp. intros.
rewrite H in *. auto.
Qed.
Definition weak_magic_wand : assertion -> assertion ->
weak_assertion :=
fun a1 a2 =>
fun h =>
forall h', HeapP.Disjoint h h' ->
asserts a1 h' ->
asserts a2 (HeapP.update h h').
Definition magic_wand : assertion -> assertion ->
assertion.
intros a1 a2.
refine (Assert (weak_magic_wand a1 a2) _).
unfold assertion_wf. unfold weak_magic_wand. intros.
assert (HeapP.Disjoint h1 h') by (now rewrite H).
apply (H0 _ H3) in H2.
assert (heap_Equal (HeapP.update h2 h') (HeapP.update h1 h'))
by (now rewrite H).
now rewrite H4.
Qed.
Lemma emp_empty_heap:
asserts emp empty_heap.
Proof.
unfold asserts; unfold emp; reflexivity.
Qed.
Lemma emp_equals_iff h:
asserts emp h <-> heap_Equal h empty_heap.
split; intros.
- auto.
- rewrite H; apply emp_empty_heap.
Qed.
Lemma heq_equals_iff h1 h:
asserts (heq h1) h <-> heap_Equal h1 h.
Proof.
split; intros.
- auto.
- unfold asserts; unfold heq; auto.
Qed.
Lemma pointsto_equals_iff a v h:
asserts (pointsto a v) h <->
heap_Equal h (Heap.add a v empty_heap).
Proof.
split; intros.
- auto.
- unfold asserts; unfold pointsto; auto.
Qed.
Lemma points_equals_iff a h:
asserts (points a) h <-> exists v, heap_Equal h (Heap.add a v empty_heap).
Proof.
split; intros.
- auto.
- unfold asserts; unfold points; auto.
Qed.
Lemma star_iff :
forall a1 a2 h, asserts (a1 ** a2) h <->
exists h1 h2, HeapP.Partition h h1 h2
/\ asserts a1 h1 /\ asserts a2 h2.
Proof.
unfold asserts at 1; unfold star; unfold weak_star; intuition.
Qed.
Ltac destruct_star :=
match goal with
| [ |- context [ asserts (?a1 ** ?a2) ?h ] ] => rewrite (star_iff a1 a2 h)
end.
Ltac destruct_star_in H :=
match goal with
| [ H : context [ asserts (?a1 ** ?a2) ?h ] |- _ ] => rewrite (star_iff a1 a2) in H
end.
Lemma add_emp_r :
forall a, a <===> a ** emp.
Proof.
split; intros.
- destruct_star.
exists h, empty_heap; split; [ | split].
+ apply HeapX.Partition_refl.
+ auto.
+ apply emp_empty_heap.
- destruct_star_in H.
destruct_conjs.
rewrite emp_equals_iff in H3.
rewrite H3 in H1.
apply HeapX.Partition_empty_r in H1.
now rewrite H1.
Qed.
Lemma star_comm :
forall a1 a2, a1 ** a2 <===> a2 ** a1.
Proof.
intros a1 a2 h; split; intros I.
all: rewrite star_iff in *; destruct_conjs.
all: exists H, I; intuition.
all: now apply HeapX.Partition_sym.
Qed.
Lemma star_assoc :
forall a1 a2 a3 h, asserts (a1 ** a2 ** a3) h <->
asserts ((a1 ** a2) ** a3) h.
Proof.
split; intros.
- destruct_star_in H; destruct_conjs.
destruct_star_in H3; destruct_conjs.
destruct_star; exists (HeapP.update H H3), H4.
split; [ | split ].
+ now apply HeapX.Partition_assoc with (m2:=H0).
+ destruct_star; exists H, H3; split; auto.
apply HeapX.disjoint_update_partition.
unfold HeapP.Partition in *; destruct_conjs.
rewrite HeapP.Disjoint_alt in *; intros.
assert (Heap.MapsTo k e' H0). rewrite H8; now left.
apply (H1 _ _ _ H10 H12).
+ auto.
- destruct_star_in H; destruct_conjs.
destruct_star_in H2; destruct_conjs.
destruct_star; exists H2, (HeapP.update H4 H0).
assert (HeapP.Disjoint H0 H4). {
unfold HeapP.Partition in *; destruct_conjs.
intros k I; destruct_conjs.
destruct H10, H11.
assert (Heap.MapsTo k x0 H).
rewrite H8; now right.
apply (H1 k); split; [now exists x0 | now exists x].
}
split; [ | split ].
+ apply HeapP.Partition_sym.
rewrite HeapX.disjoint_update_comm.
apply HeapX.Partition_assoc with (m2:=H).
now apply HeapP.Partition_sym.
now apply HeapP.Partition_sym.
now apply HeapP.Disjoint_sym.
+ auto.
+ destruct_star; exists H4, H0; split; [ | split ]; auto.
apply HeapX.disjoint_update_partition.
now apply HeapP.Disjoint_sym.
Qed.
Lemma star_imp:
forall {a1 a2}, a1 ===> a2 ->
forall x, a1 ** x ===> a2 ** x.
Proof.
intros a1 a2 I x h L.
unfold asserts in *; unfold star in *; unfold weak_star in *.
destruct_conjs.
apply I in H1.
exists L, H; intuition.
Qed.
Lemma pointsto_find:
forall {p v h}, asserts (p |> v) h -> Heap.find p h = Some v.
Proof.
intros p v h A.
unfold asserts in *; unfold pointsto in *.
rewrite A.
apply Heap.find_1; now apply Heap.add_1.
Qed.
Lemma star_pointsto_find:
forall {p v a h}, asserts (p |> v ** a) h -> Heap.find p h = Some v.
Proof.
intros p v a h A.
rewrite star_iff in A; destruct_conjs.
apply pointsto_find in H1.
apply Heap.find_1; apply (HeapX.Partition_mapsto_l H0); now apply Heap.find_2.
Qed.
Lemma points_find:
forall {p h}, asserts (p |>?) h -> exists v, Heap.find p h = Some v.
Proof.
intros p h A.
unfold asserts in *; unfold points in *.
destruct A.
exists x; rewrite H; apply Heap.find_1; now apply Heap.add_1.
Qed.
Lemma star_points_find:
forall {p a h}, asserts (p |>? ** a) h -> exists v, Heap.find p h = Some v.
Proof.
intros p a h A.
rewrite star_iff in A; destruct_conjs.
apply points_find in H1; destruct H1; exists x.
apply Heap.find_1; apply (HeapX.Partition_mapsto_l H0); now apply Heap.find_2.
Qed.
Definition Cmd := heap -> option heap.
Definition sep_triple (p:assertion) (c:Cmd) (q:assertion) :=
forall rest h,
asserts (p ** heq rest) h ->
exists h', c h = Some h' /\ asserts (q ** heq rest) h'. (* NB stuff about termination *)
Notation "{{ P }} c {{ Q }}" := (sep_triple P c Q) (at level 90) : sep_scope.
Lemma consequence:
forall p p' c q q',
{{p}} c {{q}} ->
p' ===> p ->
q ===> q' ->
{{p'}} c {{q'}}.
Proof.
unfold sep_triple; intros.
apply star_imp with (x:=heq rest) in H0.
apply star_imp with (x:=heq rest) in H1.
apply H0 in H2.
apply H in H2.
destruct_conjs.
apply H1 in H4.
exists H2; intuition.
Qed.
Lemma frame:
forall p c q r,
{{p}} c {{q}} ->
{{p ** r}} c {{q ** r}}.
Proof.
unfold sep_triple; intros.
rewrite <- star_assoc in H0.
rewrite star_iff in H0.
destruct_conjs.
assert (asserts (p ** heq H1) h).
rewrite star_iff.
exists H0, H1; intuition.
unfold asserts; unfold heq; reflexivity.
apply H in H5.
destruct_conjs.
exists H5.
intuition.
rewrite <- star_assoc.
rewrite star_iff in H7; destruct_conjs.
rewrite star_iff.
exists H7, H1.
rewrite heq_equals_iff in H11.
repeat rewrite H11 in *.
intuition.
Qed.
Inductive expr :=
| Ev : Z -> expr
| Ebin : expr -> expr -> (Z -> Z -> Z) -> expr
| Eread : expr -> expr
| Ewrite : expr -> expr -> expr.
Fixpoint estepf (e:expr) (h:heap) : option (expr * heap) :=
match e with
| Ebin (Ev v1) (Ev v2) op => Some (Ev (op v1 v2), h)
| Ebin (Ev v1) e2 op => match estepf e2 h with
| Some (e2',h') => Some (Ebin (Ev v1) e2' op, h')
| _ => None
end
| Ebin e1 e2 op => match estepf e1 h with
| Some (e1',h') => Some (Ebin e1' e2 op, h')
| _ => None
end
| Eread (Ev a) => match Heap.find a h with
| Some v => Some (Ev v, h)
| _ => None
end
| Eread e => match estepf e h with
| Some (e',h') => Some (Eread e', h')
| _ => None
end
| Ewrite (Ev a) (Ev v) => match Heap.find a h with
| Some _ => Some (Ev v, Heap.add a v h)
| _ => None
end
| Ewrite (Ev a) e => match estepf e h with
| Some (e',h') => Some (Ewrite (Ev a) e', h')
| _ => None
end
| Ewrite a e => match estepf a h with
| Some (a',h') => Some (Ewrite a' e, h')
| _ => None
end
| _ => None
end.
Definition ecmd : expr -> Cmd :=
fun e h =>
match estepf e h with
| Some (e', h') => Some h'
| _ => None
end.
Hint Resolve ecmd.
Lemma ecmd_estepf_iff e h h':
ecmd e h = Some h' <-> exists e', estepf e h = Some (e', h').
Proof.
split; intros.
unfold ecmd in *; remember (estepf e h) as s; destruct s.
destruct p; exists e0; inversion H; intuition.
discriminate.
unfold ecmd in *; destruct H as [e' H]; rewrite H; auto.
Qed.
Lemma readv_tc:
forall a v,
{{ a |> v }} ecmd (Eread (Ev a)) {{ a |> v }}.
Proof.
intros a v rest h A; exists h.
unfold ecmd; simpl.
rewrite (star_pointsto_find A).
unfold asserts in A; unfold star in A.
intuition.
Qed.
Lemma writev_tc:
forall a v,
{{ a |>? }} ecmd (Ewrite (Ev a) (Ev v)) {{ a |> v }}.
intros a v rest h A; exists (Heap.add a v h).
unfold ecmd; simpl.
generalize (star_points_find A); intros G; destruct G.
rewrite H; intuition.
exists (Heap.add a v empty_heap), rest; split; [ | split ].
- rewrite star_iff in A; destruct_conjs.
rewrite points_equals_iff in H2; destruct H2 as [xx H2]; rewrite H2 in H1.
apply HeapX.Partition_add_1 with (v1:=xx).
rewrite heq_equals_iff in H3; now rewrite H3.
- rewrite pointsto_equals_iff; reflexivity.
- rewrite heq_equals_iff; reflexivity.
Qed.
Lemma reads_tc:
forall a1 a2 e1,
{{a1}} ecmd e1 {{a2}} ->
{{a1}} ecmd (Eread e1) {{a2}}.
Proof.
intros a1 a2 e1 H rest h A.
generalize (H rest h A); intro G; destruct G as [hg [G1 G2]].
exists hg; split; auto.
rewrite ecmd_estepf_iff in G1; destruct G1 as [e' G1].
destruct e1; try discriminate.
all: rewrite ecmd_estepf_iff; exists (Eread e').
all: simpl in *; rewrite G1; auto.
Qed.
End Separation.