src/HOL/MicroJava/BV/BVExample.thy
author haftmann
Fri Jun 17 16:12:49 2005 +0200 (2005-06-17)
changeset 16417 9bc16273c2d4
parent 15570 8d8c70b41bab
child 16643 39cb9fe20fe3
permissions -rw-r--r--
migrated theory headers to new format
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(*  Title:      HOL/MicroJava/BV/BVExample.thy
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    ID:         $Id$
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    Author:     Gerwin Klein
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*)
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header {* \isaheader{Example Welltypings}\label{sec:BVExample} *}
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theory BVExample imports JVMListExample BVSpecTypeSafe JVM begin
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text {*
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  This theory shows type correctness of the example program in section 
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  \ref{sec:JVMListExample} (p. \pageref{sec:JVMListExample}) by
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  explicitly providing a welltyping. It also shows that the start
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  state of the program conforms to the welltyping; hence type safe
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  execution is guaranteed.
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*}
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section "Setup"
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text {*
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  Since the types @{typ cnam}, @{text vnam}, and @{text mname} are 
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  anonymous, we describe distinctness of names in the example by axioms:
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*}
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axioms 
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  distinct_classes: "list_nam \<noteq> test_nam"
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  distinct_fields:  "val_nam \<noteq> next_nam"
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text {* Abbreviations for definitions we will have to use often in the
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proofs below: *}
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lemmas name_defs   = list_name_def test_name_def val_name_def next_name_def 
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lemmas system_defs = SystemClasses_def ObjectC_def NullPointerC_def 
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                     OutOfMemoryC_def ClassCastC_def
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lemmas class_defs  = list_class_def test_class_def
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text {* These auxiliary proofs are for efficiency: class lookup,
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subclass relation, method and field lookup are computed only once:
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*}
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lemma class_Object [simp]:
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  "class E Object = Some (arbitrary, [],[])"
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  by (simp add: class_def system_defs E_def)
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lemma class_NullPointer [simp]:
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  "class E (Xcpt NullPointer) = Some (Object, [], [])"
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  by (simp add: class_def system_defs E_def)
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lemma class_OutOfMemory [simp]:
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  "class E (Xcpt OutOfMemory) = Some (Object, [], [])"
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  by (simp add: class_def system_defs E_def)
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lemma class_ClassCast [simp]:
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  "class E (Xcpt ClassCast) = Some (Object, [], [])"
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  by (simp add: class_def system_defs E_def)
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lemma class_list [simp]:
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  "class E list_name = Some list_class"
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  by (simp add: class_def system_defs E_def name_defs distinct_classes [symmetric])
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lemma class_test [simp]:
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  "class E test_name = Some test_class"
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  by (simp add: class_def system_defs E_def name_defs distinct_classes [symmetric])
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lemma E_classes [simp]:
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  "{C. is_class E C} = {list_name, test_name, Xcpt NullPointer, 
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                        Xcpt ClassCast, Xcpt OutOfMemory, Object}"
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  by (auto simp add: is_class_def class_def system_defs E_def name_defs class_defs)
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text {* The subclass releation spelled out: *}
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lemma subcls1:
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  "subcls1 E = {(list_name,Object), (test_name,Object), (Xcpt NullPointer, Object),
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                (Xcpt ClassCast, Object), (Xcpt OutOfMemory, Object)}"
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  apply (simp add: subcls1_def2)
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  apply (simp add: name_defs class_defs system_defs E_def class_def)
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  apply (auto split: split_if_asm)
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  done
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text {* The subclass relation is acyclic; hence its converse is well founded: *}
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lemma notin_rtrancl:
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  "(a,b) \<in> r\<^sup>* \<Longrightarrow> a \<noteq> b \<Longrightarrow> (\<And>y. (a,y) \<notin> r) \<Longrightarrow> False"
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  by (auto elim: converse_rtranclE)  
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lemma acyclic_subcls1_E: "acyclic (subcls1 E)"
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  apply (rule acyclicI)
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  apply (simp add: subcls1)
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  apply (auto dest!: tranclD)
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  apply (auto elim!: notin_rtrancl simp add: name_defs distinct_classes)
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  done
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lemma wf_subcls1_E: "wf ((subcls1 E)\<inverse>)"
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  apply (rule finite_acyclic_wf_converse)
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  apply (simp add: subcls1)
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  apply (rule acyclic_subcls1_E)
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  done  
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text {* Method and field lookup: *}
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lemma method_Object [simp]:
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  "method (E, Object) = empty"
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  by (simp add: method_rec_lemma [OF class_Object wf_subcls1_E])
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lemma method_append [simp]:
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  "method (E, list_name) (append_name, [Class list_name]) =
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  Some (list_name, PrimT Void, 3, 0, append_ins, [(1, 2, 8, Xcpt NullPointer)])"
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  apply (insert class_list)
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  apply (unfold list_class_def)
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  apply (drule method_rec_lemma [OF _ wf_subcls1_E])
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  apply simp
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  done
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lemma method_makelist [simp]:
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  "method (E, test_name) (makelist_name, []) = 
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  Some (test_name, PrimT Void, 3, 2, make_list_ins, [])"
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  apply (insert class_test)
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  apply (unfold test_class_def)
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  apply (drule method_rec_lemma [OF _ wf_subcls1_E])
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  apply simp
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  done
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lemma field_val [simp]:
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  "field (E, list_name) val_name = Some (list_name, PrimT Integer)"
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  apply (unfold field_def)
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  apply (insert class_list)
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  apply (unfold list_class_def)
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  apply (drule fields_rec_lemma [OF _ wf_subcls1_E])
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  apply simp
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  done
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lemma field_next [simp]:
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  "field (E, list_name) next_name = Some (list_name, Class list_name)"
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  apply (unfold field_def)
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  apply (insert class_list)
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  apply (unfold list_class_def)
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  apply (drule fields_rec_lemma [OF _ wf_subcls1_E])
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  apply (simp add: name_defs distinct_fields [symmetric])
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  done
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lemma [simp]: "fields (E, Object) = []"
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   by (simp add: fields_rec_lemma [OF class_Object wf_subcls1_E])
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lemma [simp]: "fields (E, Xcpt NullPointer) = []"
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  by (simp add: fields_rec_lemma [OF class_NullPointer wf_subcls1_E])
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lemma [simp]: "fields (E, Xcpt ClassCast) = []"
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  by (simp add: fields_rec_lemma [OF class_ClassCast wf_subcls1_E])
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lemma [simp]: "fields (E, Xcpt OutOfMemory) = []"
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  by (simp add: fields_rec_lemma [OF class_OutOfMemory wf_subcls1_E])
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lemma [simp]: "fields (E, test_name) = []"
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  apply (insert class_test)
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  apply (unfold test_class_def)
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  apply (drule fields_rec_lemma [OF _ wf_subcls1_E])
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  apply simp
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  done
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lemmas [simp] = is_class_def
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text {*
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  The next definition and three proof rules implement an algorithm to
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  enumarate natural numbers. The command @{text "apply (elim pc_end pc_next pc_0"} 
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  transforms a goal of the form
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  @{prop [display] "pc < n \<Longrightarrow> P pc"} 
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  into a series of goals
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  @{prop [display] "P 0"} 
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  @{prop [display] "P (Suc 0)"} 
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  @{text "\<dots>"}
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  @{prop [display] "P n"} 
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*}
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constdefs 
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  intervall :: "nat \<Rightarrow> nat \<Rightarrow> nat \<Rightarrow> bool" ("_ \<in> [_, _')")
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  "x \<in> [a, b) \<equiv> a \<le> x \<and> x < b"
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lemma pc_0: "x < n \<Longrightarrow> (x \<in> [0, n) \<Longrightarrow> P x) \<Longrightarrow> P x"
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  by (simp add: intervall_def)
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lemma pc_next: "x \<in> [n0, n) \<Longrightarrow> P n0 \<Longrightarrow> (x \<in> [Suc n0, n) \<Longrightarrow> P x) \<Longrightarrow> P x"
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  apply (cases "x=n0")
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  apply (auto simp add: intervall_def)
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  done
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lemma pc_end: "x \<in> [n,n) \<Longrightarrow> P x" 
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  by (unfold intervall_def) arith
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section "Program structure"
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text {*
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  The program is structurally wellformed:
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*}
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lemma wf_struct:
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  "wf_prog (\<lambda>G C mb. True) E" (is "wf_prog ?mb E")
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proof -
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  have "unique E" 
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    by (simp add: system_defs E_def class_defs name_defs distinct_classes)
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  moreover
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  have "set SystemClasses \<subseteq> set E" by (simp add: system_defs E_def)
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  hence "wf_syscls E" by (rule wf_syscls)
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  moreover
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  have "wf_cdecl ?mb E ObjectC" by (simp add: wf_cdecl_def ObjectC_def)
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  moreover
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  have "wf_cdecl ?mb E NullPointerC" 
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    by (auto elim: notin_rtrancl 
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            simp add: wf_cdecl_def name_defs NullPointerC_def subcls1)
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  moreover
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  have "wf_cdecl ?mb E ClassCastC" 
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    by (auto elim: notin_rtrancl 
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            simp add: wf_cdecl_def name_defs ClassCastC_def subcls1)
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  moreover
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  have "wf_cdecl ?mb E OutOfMemoryC" 
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    by (auto elim: notin_rtrancl 
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            simp add: wf_cdecl_def name_defs OutOfMemoryC_def subcls1)
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  moreover
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  have "wf_cdecl ?mb E (list_name, list_class)"
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    apply (auto elim!: notin_rtrancl 
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            simp add: wf_cdecl_def wf_fdecl_def list_class_def 
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                      wf_mdecl_def wf_mhead_def subcls1)
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    apply (auto simp add: name_defs distinct_classes distinct_fields)
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    done    
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  moreover
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  have "wf_cdecl ?mb E (test_name, test_class)" 
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    apply (auto elim!: notin_rtrancl 
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            simp add: wf_cdecl_def wf_fdecl_def test_class_def 
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                      wf_mdecl_def wf_mhead_def subcls1)
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    apply (auto simp add: name_defs distinct_classes distinct_fields)
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    done       
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  ultimately
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  show ?thesis 
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    by (simp add: wf_prog_def ws_prog_def wf_cdecl_mrT_cdecl_mdecl E_def SystemClasses_def)
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qed
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section "Welltypings"
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text {*
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  We show welltypings of the methods @{term append_name} in class @{term list_name}, 
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  and @{term makelist_name} in class @{term test_name}:
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*}
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lemmas eff_simps [simp] = eff_def norm_eff_def xcpt_eff_def
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declare appInvoke [simp del]
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constdefs
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  phi_append :: method_type ("\<phi>\<^sub>a")
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  "\<phi>\<^sub>a \<equiv> map (\<lambda>(x,y). Some (x, map OK y)) [ 
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   (                                    [], [Class list_name, Class list_name]),
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   (                     [Class list_name], [Class list_name, Class list_name]),
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   (                     [Class list_name], [Class list_name, Class list_name]),
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   (    [Class list_name, Class list_name], [Class list_name, Class list_name]),
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   ([NT, Class list_name, Class list_name], [Class list_name, Class list_name]),
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   (                     [Class list_name], [Class list_name, Class list_name]),
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   (    [Class list_name, Class list_name], [Class list_name, Class list_name]),
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   (                          [PrimT Void], [Class list_name, Class list_name]),
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   (                        [Class Object], [Class list_name, Class list_name]),
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   (                                    [], [Class list_name, Class list_name]),
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   (                     [Class list_name], [Class list_name, Class list_name]),
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   (    [Class list_name, Class list_name], [Class list_name, Class list_name]),
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   (                                    [], [Class list_name, Class list_name]),
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   (                          [PrimT Void], [Class list_name, Class list_name])]"
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lemma bounded_append [simp]:
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  "check_bounded append_ins [(Suc 0, 2, 8, Xcpt NullPointer)]"
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  apply (simp add: check_bounded_def)
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  apply (simp add: nat_number append_ins_def)
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  apply (rule allI, rule impI)
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  apply (elim pc_end pc_next pc_0)
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  apply auto
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  done
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lemma types_append [simp]: "check_types E 3 (Suc (Suc 0)) (map OK \<phi>\<^sub>a)"
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  apply (auto simp add: check_types_def phi_append_def JVM_states_unfold)
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  apply (unfold list_def)
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  apply auto
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  done
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lemma wt_append [simp]:
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  "wt_method E list_name [Class list_name] (PrimT Void) 3 0 append_ins
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             [(Suc 0, 2, 8, Xcpt NullPointer)] \<phi>\<^sub>a"
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  apply (simp add: wt_method_def wt_start_def wt_instr_def)
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  apply (simp add: phi_append_def append_ins_def)
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  apply clarify
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  apply (elim pc_end pc_next pc_0)
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  apply simp
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  apply (fastsimp simp add: match_exception_entry_def sup_state_conv subcls1)
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  apply simp
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  apply simp
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  apply (fastsimp simp add: sup_state_conv subcls1)
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  apply simp
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  apply (simp add: app_def xcpt_app_def)
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  apply simp
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  apply simp
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  apply simp
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  apply (simp add: match_exception_entry_def)
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  apply (simp add: match_exception_entry_def)
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  apply simp
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  apply simp
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  done
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text {* Some abbreviations for readability *} 
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syntax
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  Clist :: ty 
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  Ctest :: ty
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translations
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  "Clist" == "Class list_name"
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  "Ctest" == "Class test_name"
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constdefs
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  phi_makelist :: method_type ("\<phi>\<^sub>m")
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  "\<phi>\<^sub>m \<equiv> map (\<lambda>(x,y). Some (x, y)) [ 
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    (                                   [], [OK Ctest, Err     , Err     ]),
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    (                              [Clist], [OK Ctest, Err     , Err     ]),
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    (                       [Clist, Clist], [OK Ctest, Err     , Err     ]),
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    (                              [Clist], [OK Clist, Err     , Err     ]),
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    (               [PrimT Integer, Clist], [OK Clist, Err     , Err     ]),
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    (                                   [], [OK Clist, Err     , Err     ]),
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    (                              [Clist], [OK Clist, Err     , Err     ]),
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    (                       [Clist, Clist], [OK Clist, Err     , Err     ]),
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    (                              [Clist], [OK Clist, OK Clist, Err     ]),
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    (               [PrimT Integer, Clist], [OK Clist, OK Clist, Err     ]),
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    (                                   [], [OK Clist, OK Clist, Err     ]),
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    (                              [Clist], [OK Clist, OK Clist, Err     ]),
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    (                       [Clist, Clist], [OK Clist, OK Clist, Err     ]),
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    (                              [Clist], [OK Clist, OK Clist, OK Clist]),
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    (               [PrimT Integer, Clist], [OK Clist, OK Clist, OK Clist]),
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    (                                   [], [OK Clist, OK Clist, OK Clist]),
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    (                              [Clist], [OK Clist, OK Clist, OK Clist]),
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    (                       [Clist, Clist], [OK Clist, OK Clist, OK Clist]),
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    (                         [PrimT Void], [OK Clist, OK Clist, OK Clist]),
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    (                                   [], [OK Clist, OK Clist, OK Clist]),
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    (                              [Clist], [OK Clist, OK Clist, OK Clist]),
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    (                       [Clist, Clist], [OK Clist, OK Clist, OK Clist]),
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    (                         [PrimT Void], [OK Clist, OK Clist, OK Clist])]"
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lemma bounded_makelist [simp]: "check_bounded make_list_ins []"
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  apply (simp add: check_bounded_def)
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  apply (simp add: nat_number make_list_ins_def)
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  apply (rule allI, rule impI)
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  apply (elim pc_end pc_next pc_0)
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  apply auto
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  done
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lemma types_makelist [simp]: "check_types E 3 (Suc (Suc (Suc 0))) (map OK \<phi>\<^sub>m)"
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  apply (auto simp add: check_types_def phi_makelist_def JVM_states_unfold)
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  apply (unfold list_def)
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  apply auto
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  done
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lemma wt_makelist [simp]:
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  "wt_method E test_name [] (PrimT Void) 3 2 make_list_ins [] \<phi>\<^sub>m"
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  apply (simp add: wt_method_def)
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  apply (simp add: make_list_ins_def phi_makelist_def)
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  apply (simp add: wt_start_def nat_number)
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  apply (simp add: wt_instr_def)
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  apply clarify
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  apply (elim pc_end pc_next pc_0)
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  apply (simp add: match_exception_entry_def)
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  apply simp
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  apply simp
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  apply simp
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  apply (simp add: match_exception_entry_def)
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  apply (simp add: match_exception_entry_def) 
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  apply simp
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  apply simp
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  apply simp
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  apply (simp add: match_exception_entry_def)
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  apply (simp add: match_exception_entry_def) 
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  apply simp
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  apply simp
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  apply simp
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  apply (simp add: match_exception_entry_def)
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  apply (simp add: match_exception_entry_def) 
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  apply simp
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  apply (simp add: app_def xcpt_app_def)
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  apply simp 
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  apply simp
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  apply simp
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  apply (simp add: app_def xcpt_app_def) 
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  apply simp
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  done
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text {* The whole program is welltyped: *}
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constdefs 
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  Phi :: prog_type ("\<Phi>")
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  "\<Phi> C sg \<equiv> if C = test_name \<and> sg = (makelist_name, []) then \<phi>\<^sub>m else          
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             if C = list_name \<and> sg = (append_name, [Class list_name]) then \<phi>\<^sub>a else []"
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lemma wf_prog:
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  "wt_jvm_prog E \<Phi>" 
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  apply (unfold wt_jvm_prog_def)
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  apply (rule wf_mb'E [OF wf_struct])
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  apply (simp add: E_def)
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  apply clarify
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  apply (fold E_def)
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  apply (simp add: system_defs class_defs Phi_def) 
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  apply auto
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  done 
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section "Conformance"
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text {* Execution of the program will be typesafe, because its
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  start state conforms to the welltyping: *}
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lemma "E,\<Phi> \<turnstile>JVM start_state E test_name makelist_name \<surd>"
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  apply (rule BV_correct_initial)
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    apply (rule wf_prog)
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   apply simp
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  apply simp
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  done
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   407
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section "Example for code generation: inferring method types"
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constdefs
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  test_kil :: "jvm_prog \<Rightarrow> cname \<Rightarrow> ty list \<Rightarrow> ty \<Rightarrow> nat \<Rightarrow> nat \<Rightarrow> 
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             exception_table \<Rightarrow> instr list \<Rightarrow> JVMType.state list"
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  "test_kil G C pTs rT mxs mxl et instr ==
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   (let first  = Some ([],(OK (Class C))#((map OK pTs))@(replicate mxl Err));
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        start  = OK first#(replicate (size instr - 1) (OK None))
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    in  kiljvm G mxs (1+size pTs+mxl) rT et instr start)"
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   417
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lemma [code]:
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  "unstables r step ss = (UN p:{..<size ss}. if \<not>stable r step ss p then {p} else {})"
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  apply (unfold unstables_def)
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   421
  apply (rule equalityI)
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   422
  apply (rule subsetI)
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   423
  apply (erule CollectE)
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   424
  apply (erule conjE)
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   425
  apply (rule UN_I)
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   426
  apply simp
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   427
  apply simp
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   428
  apply (rule subsetI)
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   429
  apply (erule UN_E)
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   430
  apply (case_tac "\<not> stable r step ss p")
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   431
  apply simp+
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   432
  done
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   433
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   434
lemmas [code] = lessThan_0 lessThan_Suc
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   435
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   436
constdefs
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   437
  some_elem :: "'a set \<Rightarrow> 'a"
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   438
  "some_elem == (%S. SOME x. x : S)"
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   439
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   440
lemma [code]:
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   441
"iter f step ss w =
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   442
 while (%(ss,w). w \<noteq> {})
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       (%(ss,w). let p = some_elem w
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   444
                 in propa f (step p (ss!p)) ss (w-{p}))
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   445
       (ss,w)"
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  by (unfold iter_def some_elem_def, rule refl)
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   447
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   448
types_code
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   449
  set ("_ list")
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   450
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   451
consts_code
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   452
  "{}"     ("[]")
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   453
  "insert" ("(_ ins _)")
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   454
  "op :"   ("(_ mem _)")
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   455
  "op Un"  ("(_ union _)")
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   456
  "image"  ("map")
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   457
  "UNION"  ("(fn A => fn f => List.concat (map f A))")
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  "Bex"    ("(fn A => fn f => exists f A)")
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   459
  "Ball"   ("(fn A => fn f => forall f A)")
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   460
  "some_elem" ("hd")
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   461
  "op -" :: "'a set \<Rightarrow> 'a set \<Rightarrow> 'a set"  ("(_ \\\\ _)")
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   462
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   463
lemma JVM_sup_unfold [code]:
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   464
 "JVMType.sup S m n = lift2 (Opt.sup
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   465
       (Product.sup (Listn.sup (JType.sup S))
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   466
         (\<lambda>x y. OK (map2 (lift2 (JType.sup S)) x y))))" 
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   467
  apply (unfold JVMType.sup_def JVMType.sl_def Opt.esl_def Err.sl_def
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   468
         stk_esl_def reg_sl_def Product.esl_def  
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   469
         Listn.sl_def upto_esl_def JType.esl_def Err.esl_def) 
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   470
  by simp
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   471
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   472
lemmas [code] =
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   473
  meta_eq_to_obj_eq [OF JType.sup_def [unfolded exec_lub_def]]
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   474
  meta_eq_to_obj_eq [OF JVM_le_unfold]
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   475
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   476
lemmas [code ind] = rtrancl_refl converse_rtrancl_into_rtrancl
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   477
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   478
generate_code 
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   479
  test1 = "test_kil E list_name [Class list_name] (PrimT Void) 3 0
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   480
    [(Suc 0, 2, 8, Xcpt NullPointer)] append_ins"
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   481
  test2 = "test_kil E test_name [] (PrimT Void) 3 2 [] make_list_ins"
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   482
berghofe@13092
   483
ML test1
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   484
ML test2
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   485
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   486
end