Theory SepLogHeap

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theory SepLogHeap
imports Main
begin

(*  Title:      HOL/Hoare/Heap.thy
    ID:         $Id: SepLogHeap.thy,v 1.3 2005/08/01 17:20:25 wenzelm Exp $
    Author:     Tobias Nipkow
    Copyright   2002 TUM

Heap abstractions (at the moment only Path and List)
for Separation Logic.
*)

theory SepLogHeap imports Main begin

types heap = "(nat => nat option)"

text{* @{text "Some"} means allocated, @{text "None"} means
free. Address @{text "0"} serves as the null reference. *}

subsection "Paths in the heap"

consts
 Path :: "heap => nat => nat list => nat => bool"
primrec
"Path h x [] y = (x = y)"
"Path h x (a#as) y = (x≠0 ∧ a=x ∧ (∃b. h x = Some b ∧ Path h b as y))"

lemma [iff]: "Path h 0 xs y = (xs = [] ∧ y = 0)"
by (cases xs) simp_all

lemma [simp]: "x≠0 ==> Path h x as z =
 (as = [] ∧ z = x  ∨  (∃y bs. as = x#bs ∧ h x = Some y & Path h y bs z))"
by (cases as) auto

lemma [simp]: "!!x. Path f x (as@bs) z = (∃y. Path f x as y ∧ Path f y bs z)"
by (induct as) auto

lemma Path_upd[simp]:
 "!!x. u ∉ set as ==> Path (f(u := v)) x as y = Path f x as y"
by (induct as) simp_all


subsection "Lists on the heap"

constdefs
 List :: "heap => nat => nat list => bool"
"List h x as == Path h x as 0"

lemma [simp]: "List h x [] = (x = 0)"
by (simp add: List_def)

lemma [simp]:
 "List h x (a#as) = (x≠0 ∧ a=x ∧ (∃y. h x = Some y ∧ List h y as))"
by (simp add: List_def)

lemma [simp]: "List h 0 as = (as = [])"
by (cases as) simp_all

lemma List_non_null: "a≠0 ==>
 List h a as = (∃b bs. as = a#bs ∧ h a = Some b ∧ List h b bs)"
by (cases as) simp_all

theorem notin_List_update[simp]:
 "!!x. a ∉ set as ==> List (h(a := y)) x as = List h x as"
by (induct as) simp_all

lemma List_unique: "!!x bs. List h x as ==> List h x bs ==> as = bs"
by (induct as) (auto simp add:List_non_null)

lemma List_unique1: "List h p as ==> ∃!as. List h p as"
by (blast intro: List_unique)

lemma List_app: "!!x. List h x (as@bs) = (∃y. Path h x as y ∧ List h y bs)"
by (induct as) auto

lemma List_hd_not_in_tl[simp]: "List h b as ==> h a = Some b ==> a ∉ set as"
apply (clarsimp simp add:in_set_conv_decomp)
apply(frule List_app[THEN iffD1])
apply(fastsimp dest: List_unique)
done

lemma List_distinct[simp]: "!!x. List h x as ==> distinct as"
by (induct as) (auto dest:List_hd_not_in_tl)

lemma list_in_heap: "!!p. List h p ps ==> set ps ⊆ dom h"
by (induct ps) auto

lemma list_ortho_sum1[simp]:
 "!!p. [| List h1 p ps; dom h1 ∩ dom h2 = {}|] ==> List (h1++h2) p ps"
by (induct ps) (auto simp add:map_add_def split:option.split)

lemma list_ortho_sum2[simp]:
 "!!p. [| List h2 p ps; dom h1 ∩ dom h2 = {}|] ==> List (h1++h2) p ps"
by (induct ps) (auto simp add:map_add_def split:option.split)

end

Paths in the heap

lemma

  Path h 0 xs y = (xs = [] ∧ y = 0)

lemma

  x ≠ 0
  ==> Path h x as z =
      (as = [] ∧ z = x ∨ (∃y bs. as = x # bsh x = Some y ∧ Path h y bs z))

lemma

  Path f x (as @ bs) z = (∃y. Path f x as y ∧ Path f y bs z)

lemma Path_upd:

  u ∉ set as ==> Path (f(u := v)) x as y = Path f x as y

Lists on the heap

lemma

  List h x [] = (x = 0)

lemma

  List h x (a # as) = (x ≠ 0 ∧ a = x ∧ (∃y. h x = Some y ∧ List h y as))

lemma

  List h 0 as = (as = [])

lemma List_non_null:

  a ≠ 0 ==> List h a as = (∃b bs. as = a # bsh a = Some b ∧ List h b bs)

theorem notin_List_update:

  a ∉ set as ==> List (h(a := y)) x as = List h x as

lemma List_unique:

  [| List h x as; List h x bs |] ==> as = bs

lemma List_unique1:

  List h p as ==> ∃!as. List h p as

lemma List_app:

  List h x (as @ bs) = (∃y. Path h x as y ∧ List h y bs)

lemma List_hd_not_in_tl:

  [| List h b as; h a = Some b |] ==> a ∉ set as

lemma List_distinct:

  List h x as ==> distinct as

lemma list_in_heap:

  List h p ps ==> set ps ⊆ dom h

lemma list_ortho_sum1:

  [| List h1.0 p ps; dom h1.0 ∩ dom h2.0 = {} |] ==> List (h1.0 ++ h2.0) p ps

lemma list_ortho_sum2:

  [| List h2.0 p ps; dom h1.0 ∩ dom h2.0 = {} |] ==> List (h1.0 ++ h2.0) p ps