invariants.v 4.56 KB
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From iris.base_logic.lib Require Export fancy_updates namespaces.
From iris.base_logic.lib Require Import wsat.
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From iris.algebra Require Import gmap.
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From iris.proofmode Require Import tactics coq_tactics intro_patterns.
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Set Default Proof Using "Type".
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Import uPred.
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(** Derived forms and lemmas about them. *)
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Definition inv_def `{invG Σ} (N : namespace) (P : iProp Σ) : iProp Σ :=
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  ( i, i  N  ownI i P)%I.
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Definition inv_aux : seal (@inv_def). by eexists. Qed.
Definition inv {Σ i} := unseal inv_aux Σ i.
Definition inv_eq : @inv = @inv_def := seal_eq inv_aux.
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Instance: Params (@inv) 3.
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Typeclasses Opaque inv.
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Section inv.
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Context `{invG Σ}.
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Implicit Types i : positive.
Implicit Types N : namespace.
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Implicit Types P Q R : iProp Σ.
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Global Instance inv_contractive N : Contractive (inv N).
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Proof.
  rewrite inv_eq=> n ???. apply exist_ne=>i. by apply and_ne, ownI_contractive.
Qed.
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Global Instance inv_persistent N P : PersistentP (inv N P).
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Proof. rewrite inv_eq /inv; apply _. Qed.
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Lemma fresh_inv_name (E : gset positive) N :  i, i  E  i  N.
Proof.
  exists (coPpick ( N  coPset.of_gset E)).
  rewrite -coPset.elem_of_of_gset (comm and) -elem_of_difference.
  apply coPpick_elem_of=> Hfin.
  eapply nclose_infinite, (difference_finite_inv _ _), Hfin.
  apply of_gset_finite.
Qed.

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Lemma inv_alloc N E P :  P ={E}= inv N P.
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Proof.
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  rewrite inv_eq /inv_def fupd_eq /fupd_def. iIntros "HP [Hw $]".
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  iMod (ownI_alloc (  N) P with "[$HP $Hw]")
    as (i) "(% & $ & ?)"; auto using fresh_inv_name.
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Qed.
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Lemma inv_alloc_open N E P :
  N  E  True ={E, E∖↑N}= inv N P  (P ={E∖↑N, E}= True).
Proof.
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  rewrite inv_eq /inv_def fupd_eq /fupd_def. iIntros (Sub) "[Hw HE]".
  iMod (ownI_alloc_open (  N) P with "Hw")
    as (i) "(% & Hw & #Hi & HD)"; auto using fresh_inv_name.
  iAssert (ownE {[i]}  ownE ( N  {[i]})  ownE (E   N))%I
    with "[HE]" as "(HEi & HEN\i & HE\N)".
  { rewrite -?ownE_op; [|set_solver..].
    rewrite assoc_L -!union_difference_L //. set_solver. }
  do 2 iModIntro. iFrame "HE\N". iSplitL "Hw HEi"; first by iApply "Hw".
  iSplitL "Hi"; first by eauto. iIntros "HP [Hw HE\N]".
  iDestruct (ownI_close with "[$Hw $Hi $HP $HD]") as "[$ HEi]".
  do 2 iModIntro. iSplitL; [|done].
  iCombine "HEi" "HEN\i" as "HEN"; iCombine "HEN" "HE\N" as "HE".
  rewrite -?ownE_op; [|set_solver..].
  rewrite -!union_difference_L //; set_solver.
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Qed.

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Lemma inv_open E N P :
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  N  E  inv N P ={E,E∖↑N}=  P  ( P ={E∖↑N,E}= True).
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Proof.
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  rewrite inv_eq /inv_def fupd_eq /fupd_def; iDestruct 1 as (i) "[Hi #HiP]".
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  iDestruct "Hi" as % ?%elem_of_subseteq_singleton.
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  rewrite {1 4}(union_difference_L ( N) E) // ownE_op; last set_solver.
  rewrite {1 5}(union_difference_L {[ i ]} ( N)) // ownE_op; last set_solver.
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  iIntros "(Hw & [HE $] & $) !> !>".
  iDestruct (ownI_open i P with "[$Hw $HE $HiP]") as "($ & $ & HD)".
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  iIntros "HP [Hw $] !> !>". iApply ownI_close; by iFrame.
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Qed.

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Lemma inv_open_timeless E N P `{!TimelessP P} :
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  N  E  inv N P ={E,E∖↑N}= P  (P ={E∖↑N,E}= True).
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Proof.
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  iIntros (?) "Hinv". iMod (inv_open with "Hinv") as "[>HP Hclose]"; auto.
  iIntros "!> {$HP} HP". iApply "Hclose"; auto.
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Qed.
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End inv.
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Tactic Notation "iInvCore" constr(N) "as" tactic(tac) constr(Hclose) :=
  let Htmp := iFresh in
  let patback := intro_pat.parse_one Hclose in
  let pat := constr:(IList [[IName Htmp; patback]]) in
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  iMod (inv_open _ N with "[#]") as pat;
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    [idtac|iAssumption || fail "iInv: invariant" N "not found"|idtac];
    [solve_ndisj || match goal with |- ?P => fail "iInv: cannot solve" P end
    |tac Htmp].

Tactic Notation "iInv" constr(N) "as" constr(pat) constr(Hclose) :=
   iInvCore N as (fun H => iDestruct H as pat) Hclose.
Tactic Notation "iInv" constr(N) "as" "(" simple_intropattern(x1) ")"
    constr(pat) constr(Hclose) :=
   iInvCore N as (fun H => iDestruct H as (x1) pat) Hclose.
Tactic Notation "iInv" constr(N) "as" "(" simple_intropattern(x1)
    simple_intropattern(x2) ")" constr(pat) constr(Hclose) :=
   iInvCore N as (fun H => iDestruct H as (x1 x2) pat) Hclose.
Tactic Notation "iInv" constr(N) "as" "(" simple_intropattern(x1)
    simple_intropattern(x2) simple_intropattern(x3) ")"
    constr(pat) constr(Hclose) :=
   iInvCore N as (fun H => iDestruct H as (x1 x2 x3) pat) Hclose.
Tactic Notation "iInv" constr(N) "as" "(" simple_intropattern(x1)
    simple_intropattern(x2) simple_intropattern(x3) simple_intropattern(x4) ")"
    constr(pat) constr(Hclose) :=
   iInvCore N as (fun H => iDestruct H as (x1 x2 x3 x4) pat) Hclose.