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From iris.algebra Require Export excl local_updates.
From iris.algebra Require Import upred updates.
Local Arguments valid _ _ !_ /.
Record auth (A : Type) := Auth { authoritative : excl' A; auth_own : A }.
Add Printing Constructor auth.
Notation "◯ a" := (Auth None a) (at level 20).
Notation "● a" := (Auth (Excl' a) ∅) (at level 20).
Section cofe.
Context {A : cofeT}.
Implicit Types a : excl' A.
Implicit Types b : A.
Instance auth_equiv : Equiv (auth A) := λ x y,
authoritative x ≡ authoritative y ∧ auth_own x ≡ auth_own y.
Instance auth_dist : Dist (auth A) := λ n x y,
authoritative x ≡{n}≡ authoritative y ∧ auth_own x ≡{n}≡ auth_own y.
Global Instance Auth_ne : Proper (dist n ==> dist n ==> dist n) (@Auth A).
Global Instance Auth_proper : Proper ((≡) ==> (≡) ==> (≡)) (@Auth A).
Proof. by split. Qed.
Global Instance authoritative_ne: Proper (dist n ==> dist n) (@authoritative A).
Global Instance authoritative_proper : Proper ((≡) ==> (≡)) (@authoritative A).
Proof. by destruct 1. Qed.
Global Instance own_ne : Proper (dist n ==> dist n) (@auth_own A).
Global Instance own_proper : Proper ((≡) ==> (≡)) (@auth_own A).
Instance auth_compl : Compl (auth A) := λ c,
Auth (compl (chain_map authoritative c)) (compl (chain_map auth_own c)).
Definition auth_cofe_mixin : CofeMixin (auth A).
- intros x y; unfold dist, auth_dist, equiv, auth_equiv.
+ by intros ?; split.
+ by intros ?? [??]; split; symmetry.
+ intros ??? [??] [??]; split; etrans; eauto.
- by intros ? [??] [??] [??]; split; apply dist_S.
- intros n c; split. apply (conv_compl n (chain_map authoritative c)).
apply (conv_compl n (chain_map auth_own c)).
Canonical Structure authC := CofeT (auth A) auth_cofe_mixin.
Global Instance Auth_timeless a b :
Timeless a → Timeless b → Timeless (Auth a b).
Proof. by intros ?? [??] [??]; split; apply: timeless. Qed.
Global Instance auth_discrete : Discrete A → Discrete authC.
Proof. intros ? [??]; apply _. Qed.
Global Instance auth_leibniz : LeibnizEquiv A → LeibnizEquiv (auth A).
Proof. by intros ? [??] [??] [??]; f_equal/=; apply leibniz_equiv. Qed.
End cofe.
Arguments authC : clear implicits.
Context {A : ucmraT}.
Implicit Types a b : A.
Implicit Types x y : auth A.
Instance auth_valid : Valid (auth A) := λ x,
match authoritative x with
| Excl' a => (∀ n, auth_own x ≼{n} a) ∧ ✓ a
| None => ✓ auth_own x
end.
Global Arguments auth_valid !_ /.
Instance auth_validN : ValidN (auth A) := λ n x,
| Excl' a => auth_own x ≼{n} a ∧ ✓{n} a
| None => ✓{n} auth_own x
Global Arguments auth_validN _ !_ /.
Instance auth_pcore : PCore (auth A) := λ x,
Some (Auth (core (authoritative x)) (core (auth_own x))).
Instance auth_op : Op (auth A) := λ x y,
Auth (authoritative x ⋅ authoritative y) (auth_own x ⋅ auth_own y).
Lemma auth_included (x y : auth A) :
x ≼ y ↔ authoritative x ≼ authoritative y ∧ auth_own x ≼ auth_own y.
Proof.
split; [intros [[z1 z2] Hz]; split; [exists z1|exists z2]; apply Hz|].
intros [[z1 Hz1] [z2 Hz2]]; exists (Auth z1 z2); split; auto.
Qed.
Lemma authoritative_validN n x : ✓{n} x → ✓{n} authoritative x.
Lemma auth_own_validN n x : ✓{n} x → ✓{n} auth_own x.
Proof. destruct x as [[[]|]]; naive_solver eauto using cmra_validN_includedN. Qed.
Lemma auth_valid_discrete `{CMRADiscrete A} x :
✓ x ↔ match authoritative x with
| Excl' a => auth_own x ≼ a ∧ ✓ a
| None => ✓ auth_own x
| ExclBot' => False
end.
Proof.
destruct x as [[[?|]|] ?]; simpl; try done.
setoid_rewrite <-cmra_discrete_included_iff; naive_solver eauto using 0.
Qed.
Lemma authoritative_valid x : ✓ x → ✓ authoritative x.
Proof. by destruct x as [[[]|]]. Qed.
Lemma auth_own_valid `{CMRADiscrete A} x : ✓ x → ✓ auth_own x.
Proof.
rewrite auth_valid_discrete.
destruct x as [[[]|]]; naive_solver eauto using cmra_valid_included.
Qed.
Lemma auth_cmra_mixin : CMRAMixin (auth A).
- by intros n x y1 y2 [Hy Hy']; split; simpl; rewrite ?Hy ?Hy'.
- by intros n y1 y2 [Hy Hy']; split; simpl; rewrite ?Hy ?Hy'.
- intros n [x a] [y b] [Hx Ha]; simpl in *.
destruct Hx as [?? Hx|]; first destruct Hx; intros ?; cofe_subst; auto.
- intros [[[?|]|] ?]; rewrite /= ?cmra_included_includedN ?cmra_valid_validN;
naive_solver eauto using O.
- intros n [[[]|] ?] ?; naive_solver eauto using cmra_includedN_S, cmra_validN_S.
- by split; simpl; rewrite assoc.
- by split; simpl; rewrite comm.
- by split; simpl; rewrite ?cmra_core_l.
- by split; simpl; rewrite ?cmra_core_idemp.
- intros ??; rewrite! auth_included; intros [??].
by split; simpl; apply cmra_core_mono.
- assert (∀ n (a b1 b2 : A), b1 ⋅ b2 ≼{n} a → b1 ≼{n} a).
{ intros n a b1 b2 <-; apply cmra_includedN_l. }
naive_solver eauto using cmra_validN_op_l, cmra_validN_includedN.
- intros n x y1 y2 ? [??]; simpl in *.
destruct (cmra_extend n (authoritative x) (authoritative y1)
(authoritative y2)) as (ea1&ea2&?&?&?); auto using authoritative_validN.
destruct (cmra_extend n (auth_own x) (auth_own y1) (auth_own y2))
as (b1&b2&?&?&?); auto using auth_own_validN.
by exists (Auth ea1 b1), (Auth ea2 b2).
Canonical Structure authR := CMRAT (auth A) auth_cofe_mixin auth_cmra_mixin.
Global Instance auth_cmra_discrete : CMRADiscrete A → CMRADiscrete authR.
Proof.
split; first apply _.
intros [[[?|]|] ?]; rewrite /= /cmra_valid /cmra_validN /=; auto.
- setoid_rewrite <-cmra_discrete_included_iff.
rewrite -cmra_discrete_valid_iff. tauto.
- by rewrite -cmra_discrete_valid_iff.
Qed.
Instance auth_empty : Empty (auth A) := Auth ∅ ∅.
Lemma auth_ucmra_mixin : UCMRAMixin (auth A).
Proof.
split; simpl.
- apply (@ucmra_unit_valid A).
- by intros x; constructor; rewrite /= left_id.
- do 2 constructor; simpl; apply (persistent_core _).
Qed.
Canonical Structure authUR :=
UCMRAT (auth A) auth_cofe_mixin auth_cmra_mixin auth_ucmra_mixin.
Global Instance auth_frag_persistent a : Persistent a → Persistent (◯ a).
Proof. do 2 constructor; simpl; auto. by apply persistent_core. Qed.
(** Internalized properties *)
Lemma auth_equivI {M} (x y : auth A) :
x ≡ y ⊣⊢ (authoritative x ≡ authoritative y ∧ auth_own x ≡ auth_own y : uPred M).
Lemma auth_validI {M} (x : auth A) :
Robbert Krebbers
committed
✓ x ⊣⊢ (match authoritative x with
| Excl' a => (∃ b, a ≡ auth_own x ⋅ b) ∧ ✓ a
| None => ✓ auth_own x
Robbert Krebbers
committed
| ExclBot' => False
end : uPred M).
Proof. uPred.unseal. by destruct x as [[[]|]]. Qed.
Lemma auth_frag_op a b : ◯ (a ⋅ b) ≡ ◯ a ⋅ ◯ b.
Lemma auth_both_op a b : Auth (Excl' a) b ≡ ● a ⋅ ◯ b.
Proof. by rewrite /op /auth_op /= left_id. Qed.
a ~l~> b @ Some af → ● (a ⋅ af) ⋅ ◯ a ~~> ● (b ⋅ af) ⋅ ◯ b.
intros [Hab Hab']; apply cmra_total_update.
move=> n [[[?|]|] bf1] // =>-[[bf2 Ha] ?]; do 2 red; simpl in *.
move: Ha; rewrite !left_id=> Hm; split; auto.
exists bf2. rewrite -assoc.
apply (Hab' _ (Some _)); auto. by rewrite /= assoc.
Lemma auth_update_no_frame a b : a ~l~> b @ Some ∅ → ● a ⋅ ◯ a ~~> ● b ⋅ ◯ b.
Proof.
intros. rewrite -{1}(right_id _ _ a) -{1}(right_id _ _ b).
by apply auth_update.
Qed.
Lemma auth_update_no_frag af b : ∅ ~l~> b @ Some af → ● af ~~> ● (b ⋅ af) ⋅ ◯ b.
Proof.
intros. rewrite -{1}(left_id _ _ af) -{1}(right_id _ _ (● _)).
by apply auth_update.
Qed.
Arguments authR : clear implicits.
Arguments authUR : clear implicits.
Definition auth_map {A B} (f : A → B) (x : auth A) : auth B :=
Auth (excl_map f <$> authoritative x) (f (auth_own x)).
Lemma auth_map_id {A} (x : auth A) : auth_map id x = x.
Lemma auth_map_compose {A B C} (f : A → B) (g : B → C) (x : auth A) :
auth_map (g ∘ f) x = auth_map g (auth_map f x).
Lemma auth_map_ext {A B : cofeT} (f g : A → B) x :
(∀ x, f x ≡ g x) → auth_map f x ≡ auth_map g x.
Proof.
constructor; simpl; auto.
apply option_fmap_setoid_ext=> a; by apply excl_map_ext.
Qed.
Instance auth_map_ne {A B : cofeT} n :
Proper ((dist n ==> dist n) ==> dist n ==> dist n) (@auth_map A B).
intros f g Hf [??] [??] [??]; split; simpl in *; [|by apply Hf].
apply option_fmap_ne; [|done]=> x y ?; by apply excl_map_ne.
Instance auth_map_cmra_monotone {A B : ucmraT} (f : A → B) :
CMRAMonotone f → CMRAMonotone (auth_map f).
- intros n [[[a|]|] b]; rewrite /= /cmra_validN /=; try
naive_solver eauto using cmra_monotoneN, validN_preserving.
- by intros [x a] [y b]; rewrite !auth_included /=;
intros [??]; split; simpl; apply: cmra_monotone.
Definition authC_map {A B} (f : A -n> B) : authC A -n> authC B :=
CofeMor (auth_map f).
Lemma authC_map_ne A B n : Proper (dist n ==> dist n) (@authC_map A B).
Proof. intros f f' Hf [[[a|]|] b]; repeat constructor; apply Hf. Qed.
Program Definition authRF (F : urFunctor) : rFunctor := {|
rFunctor_car A B := authR (urFunctor_car F A B);
rFunctor_map A1 A2 B1 B2 fg := authC_map (urFunctor_map F fg)
|}.
Next Obligation.
by intros F A1 A2 B1 B2 n f g Hfg; apply authC_map_ne, urFunctor_ne.
Qed.
Next Obligation.
intros F A B x. rewrite /= -{2}(auth_map_id x).
apply auth_map_ext=>y; apply urFunctor_id.
Qed.
Next Obligation.
intros F A1 A2 A3 B1 B2 B3 f g f' g' x. rewrite /= -auth_map_compose.
apply auth_map_ext=>y; apply urFunctor_compose.
Qed.
Instance authRF_contractive F :
urFunctorContractive F → rFunctorContractive (authRF F).
Proof.
by intros ? A1 A2 B1 B2 n f g Hfg; apply authC_map_ne, urFunctor_contractive.
Qed.
Program Definition authURF (F : urFunctor) : urFunctor := {|
urFunctor_car A B := authUR (urFunctor_car F A B);
urFunctor_map A1 A2 B1 B2 fg := authC_map (urFunctor_map F fg)
by intros F A1 A2 B1 B2 n f g Hfg; apply authC_map_ne, urFunctor_ne.
intros F A B x. rewrite /= -{2}(auth_map_id x).
apply auth_map_ext=>y; apply urFunctor_id.
intros F A1 A2 A3 B1 B2 B3 f g f' g' x. rewrite /= -auth_map_compose.
apply auth_map_ext=>y; apply urFunctor_compose.
Instance authURF_contractive F :
urFunctorContractive F → urFunctorContractive (authURF F).
Proof.
by intros ? A1 A2 B1 B2 n f g Hfg; apply authC_map_ne, urFunctor_contractive.