Cofe and cFunctor for sigT

parent 472aa3bc
...@@ -208,6 +208,8 @@ s/\bgnameC/gnameO/g; ...@@ -208,6 +208,8 @@ s/\bgnameC/gnameO/g;
s/\bcoPset\_disjC/coPset\_disjO/g; s/\bcoPset\_disjC/coPset\_disjO/g;
' $(find theories -name "*.v") ' $(find theories -name "*.v")
``` ```
- Add a COFE construction (and functor) on dependent pairs `sigTO`, dual to
`discrete_funO`.
## Iris 3.1.0 (released 2017-12-19) ## Iris 3.1.0 (released 2017-12-19)
......
...@@ -1284,3 +1284,160 @@ Section sigma. ...@@ -1284,3 +1284,160 @@ Section sigma.
End sigma. End sigma.
Arguments sigO {_} _. Arguments sigO {_} _.
(** Ofe for [sigT]. The first component must be discrete
and use Leibniz equality, while the second component might be any OFE. *)
Section sigmaT.
Import EqNotations.
Local Set Default Proof Using "Type*".
(* For this construction we need UIP (Uniqueness of Identity Proofs) on [A]
(i.e. [∀ x y : A, ProofIrrel (x = y)]. UIP is most commonly obtained from
decidable equality (by Hedberg’s theorem, see [stdpp.proof_irrel.eq_pi]). *)
Context {A : Type} `{! a b : A, ProofIrrel (a = b)} {P : A ofeT}.
Implicit Types x : sigT P.
(**
The equality/distance for [{ a : A & P }] uses Leibniz equality on [A] to
transport the second components to the same type,
and then step-indexed equality/distance on the second component.
Unlike in the topos of trees, with (C)OFEs we cannot use step-indexed equality
on the first component.
*)
Instance sigT_equiv : Equiv (sigT P) := λ x1 x2,
eq : projT1 x1 = projT1 x2, rew eq in projT2 x1 projT2 x2.
Instance sigT_dist : Dist (sigT P) := λ n x1 x2,
eq : projT1 x1 = projT1 x2, rew eq in projT2 x1 {n} projT2 x2.
(** Unfolding lemmas.
Written with [↔] not [=] to avoid https://github.com/coq/coq/issues/3814. *)
Definition sigT_equiv_eq x1 x2 : (x1 x2)
eq : projT1 x1 = projT1 x2, rew eq in projT2 x1 projT2 x2 :=
reflexivity _.
Definition sigT_dist_eq x1 x2 n : (x1 {n} x2)
eq : projT1 x1 = projT1 x2, rew eq in projT2 x1 {n} projT2 x2 :=
reflexivity _.
Definition sigT_equiv_proj1 x y : x y projT1 x = projT1 y := proj1_ex.
Definition sigT_dist_proj1 n {x y} : x {n} y projT1 x = projT1 y := proj1_ex.
(** [existT] is "non-expansive". *)
Lemma existT_ne n {i1 i2} {v1 : P i1} {v2 : P i2} :
(eq : i1 = i2), (rew f_equal P eq in v1 {n} v2)
existT i1 v1 {n} existT i2 v2.
Proof. intros ->; simpl. exists eq_refl => /=. done. Qed.
Definition sigT_ofe_mixin : OfeMixin (sigT P).
Proof.
split.
- move => [x Px] [y Py] /=.
setoid_rewrite sigT_dist_eq; rewrite sigT_equiv_eq /=; split.
+ destruct 1 as [-> Heq]. exists eq_refl => /=.
by apply equiv_dist.
+ intros Heq. destruct (Heq 0) as [-> _]. exists eq_refl => /=.
apply equiv_dist => n. case: (Heq n) => [Hrefl].
have -> //=: Hrefl = eq_refl y. exact: proof_irrel.
- move => n; split; hnf; setoid_rewrite sigT_dist_eq.
+ intros. by exists eq_refl.
+ move => [xa x] [ya y] /=. destruct 1 as [-> Heq].
by exists eq_refl.
+ move => [xa x] [ya y] [za z] /=.
destruct 1 as [-> Heq1].
destruct 1 as [-> Heq2]. exists eq_refl => /=. by trans y.
- setoid_rewrite sigT_dist_eq.
move => n [xa x] [ya y] /=. destruct 1 as [-> Heq].
exists eq_refl. exact: dist_S.
Qed.
Canonical Structure sigTO : ofeT := OfeT (sigT P) sigT_ofe_mixin.
Implicit Types (c : chain sigTO).
Global Instance sigT_discrete x : Discrete (projT2 x) Discrete x.
Proof.
move: x => [xa x] ? [ya y].
rewrite sigT_dist_eq sigT_equiv_eq /=. destruct 1 as [-> Hxy].
exists eq_refl. move: Hxy => /=. exact: discrete _.
Qed.
Global Instance sigT_ofe_discrete : ( a, OfeDiscrete (P a)) OfeDiscrete sigTO.
Proof. intros ??. apply _. Qed.
Lemma sigT_chain_const_proj1 c n : projT1 (c n) = projT1 (c 0).
Proof. refine (sigT_dist_proj1 _ (chain_cauchy c 0 n _)). lia. Qed.
Program Definition chain_map_snd c : chain (P (projT1 (c 0))) :=
{| chain_car n := rew (sigT_chain_const_proj1 c n) in projT2 (c n) |}.
Next Obligation.
move => c n i Hle /=.
(* [Hgoal] is our thesis, up to casts: *)
case: (chain_cauchy c n i Hle) => [Heqin Hgoal] /=.
(* Pretty delicate. We have two casts to [projT1 (c 0)].
We replace those by one cast. *)
move: (sigT_chain_const_proj1 c i) (sigT_chain_const_proj1 c n)
=> Heqi0 Heqn0.
(* Rewrite [projT1 (c 0)] to [projT1 (c n)] in goal and [Heqi0]: *)
destruct Heqn0; cbn.
have {Heqi0} -> /= : Heqi0 = Heqin; first exact: proof_irrel.
exact Hgoal.
Qed.
Section cofe.
Context `{! a, Cofe (P a)}.
Definition sigT_compl : Compl sigTO :=
λ c, existT (projT1 (chain_car c 0)) (compl (chain_map_snd c)).
Global Program Instance sigT_cofe : Cofe sigTO := { compl := sigT_compl }.
Next Obligation.
intros n c. rewrite /sigT_compl sigT_dist_eq /=.
exists (symmetry (sigT_chain_const_proj1 c n)).
(* Our thesis, up to casts: *)
pose proof (conv_compl n (chain_map_snd c)) as Hgoal.
move: (compl (chain_map_snd c)) Hgoal => pc0 /=.
destruct (sigT_chain_const_proj1 c n); simpl. done.
Qed.
End cofe.
End sigmaT.
Arguments sigTO {_ _} _.
Section sigTOF.
Context {A : Type} `{! x y : A, ProofIrrel (x = y)} .
Program Definition sigT_map {P1 P2 : A ofeT} :
discrete_funO (λ a, P1 a -n> P2 a) -n>
sigTO P1 -n> sigTO P2 :=
λne f xpx, existT _ (f _ (projT2 xpx)).
Next Obligation.
move => ?? f n [x px] [y py] [/= Heq]. destruct Heq; simpl.
exists eq_refl => /=. by f_equiv.
Qed.
Next Obligation.
move => ?? n f g Heq [x px] /=. exists eq_refl => /=. apply Heq.
Qed.
Program Definition sigTOF (F : A oFunctor) : oFunctor := {|
oFunctor_car A CA B CB := sigTO (λ a, oFunctor_car (F a) A _ B CB);
oFunctor_map A1 _ A2 _ B1 _ B2 _ fg := sigT_map (λ a, oFunctor_map (F a) fg)
|}.
Next Obligation.
repeat intro. exists eq_refl => /=. solve_proper.
Qed.
Next Obligation.
intros; exists eq_refl => /=. apply oFunctor_id.
Qed.
Next Obligation.
intros; exists eq_refl => /=. apply oFunctor_compose.
Qed.
Global Instance sigTOF_contractive {F} :
( a, oFunctorContractive (F a)) oFunctorContractive (sigTOF F).
Proof.
repeat intro. apply sigT_map => a. exact: oFunctor_contractive.
Qed.
End sigTOF.
Arguments sigTOF {_ _} _%OF.
Notation "{ x & P }" := (sigTOF (λ x, P%OF)) : oFunctor_scope.
Notation "{ x : A & P }" := (@sigTOF A%type (λ x, P%OF)) : oFunctor_scope.
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