Apply changes requested by @jung

d9402cba · Rodolphe Lepigre · 56f311a9 · d9402cba · d9402cba · d9402cba
Verified Commit d9402cba authored 6 years ago by Rodolphe Lepigre
--- a/_CoqProject
+++ b/_CoqProject
@@ -67,6 +67,7 @@ theories/base_logic/lib/na_invariants.v
 theories/base_logic/lib/cancelable_invariants.v
 theories/base_logic/lib/gen_heap.v
 theories/base_logic/lib/fancy_updates_from_vs.v
+theories/base_logic/lib/proph_map.v
 theories/program_logic/adequacy.v
 theories/program_logic/lifting.v
 theories/program_logic/weakestpre.v
@@ -89,7 +90,6 @@ theories/heap_lang/notation.v
 theories/heap_lang/proofmode.v
 theories/heap_lang/adequacy.v
 theories/heap_lang/total_adequacy.v
-theories/heap_lang/proph_map.v
 theories/heap_lang/lib/spawn.v
 theories/heap_lang/lib/par.v
 theories/heap_lang/lib/assert.v

--- a/theories/heap_lang/proph_map.v
+++ b/theories/heap_lang/proph_map.v
@@ -37,18 +37,18 @@ Section definitions.
  Implicit Types p : P.

  (** The list of resolves for [p] in [pvs]. *)
-  Fixpoint list_resolves pvs p : list V :=
+  Fixpoint proph_list_resolves pvs p : list V :=
    match pvs with
    | []         => []
-    | (q,v)::pvs => if decide (p = q) then v :: list_resolves pvs p
-                    else list_resolves pvs p
+    | (q,v)::pvs => if decide (p = q) then v :: proph_list_resolves pvs p
+                    else proph_list_resolves pvs p
    end.

-  Definition resolves_in_list R pvs :=
-    map_Forall (λ p vs, vs = list_resolves pvs p) R.
+  Definition proph_resolves_in_list R pvs :=
+    map_Forall (λ p vs, vs = proph_list_resolves pvs p) R.

  Definition proph_map_ctx pvs (ps : gset P) : iProp Σ :=
-    (∃ R, ⌜resolves_in_list R pvs ∧
+    (∃ R, ⌜proph_resolves_in_list R pvs ∧
          dom (gset _) R ⊆ ps⌝ ∗
          own (proph_map_name pG) (● (to_proph_map R)))%I.

@@ -67,9 +67,9 @@ Section list_resolves.
  Implicit Type R : proph_map P V.

  Lemma resolves_insert pvs p R :
-    resolves_in_list R pvs →
+    proph_resolves_in_list R pvs →
    p ∉ dom (gset _) R →
-    resolves_in_list (<[p := list_resolves pvs p]> R) pvs.
+    proph_resolves_in_list (<[p := proph_list_resolves pvs p]> R) pvs.
  Proof.
    intros Hinlist Hp q vs HEq.
    destruct (decide (p = q)) as [->|NEq].
@@ -107,7 +107,7 @@ Section to_proph_map.
  Qed.
 End to_proph_map.

-Lemma proph_map_init `{proph_mapPreG P V PVS} pvs ps :
+Lemma proph_map_init `{Countable P, !proph_mapPreG P V PVS} pvs ps :
  (|==> ∃ _ : proph_mapG P V PVS, proph_map_ctx pvs ps)%I.
 Proof.
  iMod (own_alloc (● to_proph_map ∅)) as (γ) "Hh".
@@ -131,7 +131,7 @@ Section proph_map.
  Lemma proph_map_new_proph p ps pvs :
    p ∉ ps →
    proph_map_ctx pvs ps ==∗
-    proph_map_ctx pvs ({[p]} ∪ ps) ∗ proph p (list_resolves pvs p).
+    proph_map_ctx pvs ({[p]} ∪ ps) ∗ proph p (proph_list_resolves pvs p).
  Proof.
    iIntros (Hp) "HR". iDestruct "HR" as (R) "[[% %] H●]".
    rewrite proph_eq /proph_def.
@@ -141,7 +141,7 @@ Section proph_map.
      apply (not_elem_of_dom (D:=gset P)). set_solver.
    }
    iModIntro. iFrame.
-    iExists (<[p := list_resolves pvs p]> R). iSplitR "H●".
+    iExists (<[p := proph_list_resolves pvs p]> R). iSplitR "H●".
    - iPureIntro. split.
      + apply resolves_insert; first done. set_solver.
      + rewrite dom_insert. set_solver.
@@ -155,16 +155,16 @@ Section proph_map.
    iIntros "[HR Hp]". iDestruct "HR" as (R) "[HP H●]". iDestruct "HP" as %[Hres Hdom].
    rewrite /proph_map_ctx proph_eq /proph_def.
    iDestruct (own_valid_2 with "H● Hp") as %[HR%proph_map_singleton_included _]%auth_valid_discrete_2.
-    assert (vs = v :: list_resolves pvs p) as ->. {
+    assert (vs = v :: proph_list_resolves pvs p) as ->. {
      rewrite (Hres p vs HR). simpl. rewrite decide_True; done.
    }
    iMod (own_update_2 with "H● Hp") as "[H● H◯]". {
      eapply auth_update. apply: singleton_local_update.
      - unfold to_proph_map. rewrite lookup_fmap. rewrite HR. done.
-      - apply (exclusive_local_update _ (Excl (list_resolves pvs p : list (leibnizC V)))). done.
+      - apply (exclusive_local_update _ (Excl (proph_list_resolves pvs p : list (leibnizC V)))). done.
    }
    unfold to_proph_map. rewrite -fmap_insert.
-    iModIntro. iExists (list_resolves pvs p). iFrame. iSplitR.
+    iModIntro. iExists (proph_list_resolves pvs p). iFrame. iSplitR.
    - iPureIntro. done.
    - iExists _. iFrame. iPureIntro. split.
      + intros q ws HEq. destruct (decide (p = q)) as [<-|NEq].

--- a/theories/heap_lang/adequacy.v
+++ b/theories/heap_lang/adequacy.v
 From iris.program_logic Require Export weakestpre adequacy.
 From iris.algebra Require Import auth.
-From iris.heap_lang Require Import proofmode notation proph_map.
+From iris.heap_lang Require Import proofmode notation.
+From iris.base_logic.lib Require Import proph_map.
 From iris.proofmode Require Import tactics.
 Set Default Proof Using "Type".


--- a/theories/heap_lang/lifting.v
+++ b/theories/heap_lang/lifting.v
 From iris.algebra Require Import auth gmap.
 From iris.base_logic Require Export gen_heap.
+From iris.base_logic.lib Require Export proph_map.
 From iris.program_logic Require Export weakestpre.
 From iris.program_logic Require Import ectx_lifting total_ectx_lifting.
-From iris.heap_lang Require Export lang proph_map.
+From iris.heap_lang Require Export lang.
 From iris.heap_lang Require Import tactics.
 From iris.proofmode Require Import tactics.
 From stdpp Require Import fin_maps.