(*********************************************************************************** * Copyright (c) 2016-2018 The University of Sheffield, UK * * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * SPDX-License-Identifier: BSD-2-Clause ***********************************************************************************) section\Wellformedness\ text\In this theory, we discuss the wellformedness of the DOM. First, we define wellformedness and, second, we show for all functions for querying and modifying the DOM to what extend they preserve wellformendess.\ theory Core_DOM_Heap_WF imports "Core_DOM_Functions" begin locale l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs = l_get_child_nodes_defs get_child_nodes get_child_nodes_locs + l_get_disconnected_nodes_defs get_disconnected_nodes get_disconnected_nodes_locs for get_child_nodes :: "(_::linorder) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" begin definition a_owner_document_valid :: "(_) heap \ bool" where "a_owner_document_valid h \ (\node_ptr \ fset (node_ptr_kinds h). ((\document_ptr. document_ptr |\| document_ptr_kinds h \ node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r) \ (\parent_ptr. parent_ptr |\| object_ptr_kinds h \ node_ptr \ set |h \ get_child_nodes parent_ptr|\<^sub>r)))" lemma a_owner_document_valid_code [code]: "a_owner_document_valid h \ node_ptr_kinds h |\| fset_of_list (concat (map (\parent. |h \ get_child_nodes parent|\<^sub>r) (sorted_list_of_fset (object_ptr_kinds h)) @ map (\parent. |h \ get_disconnected_nodes parent|\<^sub>r) (sorted_list_of_fset (document_ptr_kinds h)))) " apply(auto simp add: a_owner_document_valid_def l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs.a_owner_document_valid_def)[1] proof - fix x assume 1: " \node_ptr\fset (node_ptr_kinds h). (\document_ptr. document_ptr |\| document_ptr_kinds h \ node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r) \ (\parent_ptr. parent_ptr |\| object_ptr_kinds h \ node_ptr \ set |h \ get_child_nodes parent_ptr|\<^sub>r)" assume 2: "x |\| node_ptr_kinds h" assume 3: "x |\| fset_of_list (concat (map (\parent. |h \ get_disconnected_nodes parent|\<^sub>r) (sorted_list_of_fset (document_ptr_kinds h))))" have "\(\document_ptr. document_ptr |\| document_ptr_kinds h \ x \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r)" using 1 2 3 by (smt UN_I fset_of_list_elem image_eqI notin_fset set_concat set_map sorted_list_of_fset_simps(1)) then have "(\parent_ptr. parent_ptr |\| object_ptr_kinds h \ x \ set |h \ get_child_nodes parent_ptr|\<^sub>r)" using 1 2 by auto then obtain parent_ptr where parent_ptr: "parent_ptr |\| object_ptr_kinds h \ x \ set |h \ get_child_nodes parent_ptr|\<^sub>r" by auto moreover have "parent_ptr \ set (sorted_list_of_fset (object_ptr_kinds h))" using parent_ptr by auto moreover have "|h \ get_child_nodes parent_ptr|\<^sub>r \ set (map (\parent. |h \ get_child_nodes parent|\<^sub>r) (sorted_list_of_fset (object_ptr_kinds h)))" using calculation(2) by auto ultimately show "x |\| fset_of_list (concat (map (\parent. |h \ get_child_nodes parent|\<^sub>r) (sorted_list_of_fset (object_ptr_kinds h))))" using fset_of_list_elem by fastforce next fix node_ptr assume 1: "node_ptr_kinds h |\| fset_of_list (concat (map (\parent. |h \ get_child_nodes parent|\<^sub>r) (sorted_list_of_fset (object_ptr_kinds h)))) |\| fset_of_list (concat (map (\parent. |h \ get_disconnected_nodes parent|\<^sub>r) (sorted_list_of_fset (document_ptr_kinds h))))" assume 2: "node_ptr |\| node_ptr_kinds h" assume 3: "\parent_ptr. parent_ptr |\| object_ptr_kinds h \ node_ptr \ set |h \ get_child_nodes parent_ptr|\<^sub>r" have "node_ptr \ set (concat (map (\parent. |h \ get_child_nodes parent|\<^sub>r) (sorted_list_of_fset (object_ptr_kinds h)))) \ node_ptr \ set (concat (map (\parent. |h \ get_disconnected_nodes parent|\<^sub>r) (sorted_list_of_fset (document_ptr_kinds h))))" using 1 2 by (meson fin_mono fset_of_list_elem funion_iff) then show "\document_ptr. document_ptr |\| document_ptr_kinds h \ node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r" using 3 by auto qed definition a_parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" where "a_parent_child_rel h = {(parent, child). parent |\| object_ptr_kinds h \ child \ cast ` set |h \ get_child_nodes parent|\<^sub>r}" lemma a_parent_child_rel_code [code]: "a_parent_child_rel h = set (concat (map (\parent. map (\child. (parent, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child)) |h \ get_child_nodes parent|\<^sub>r) (sorted_list_of_fset (object_ptr_kinds h))) )" by(auto simp add: a_parent_child_rel_def) definition a_acyclic_heap :: "(_) heap \ bool" where "a_acyclic_heap h = acyclic (a_parent_child_rel h)" definition a_all_ptrs_in_heap :: "(_) heap \ bool" where "a_all_ptrs_in_heap h \ (\ptr \ fset (object_ptr_kinds h). set |h \ get_child_nodes ptr|\<^sub>r \ fset (node_ptr_kinds h)) \ (\document_ptr \ fset (document_ptr_kinds h). set |h \ get_disconnected_nodes document_ptr|\<^sub>r \ fset (node_ptr_kinds h))" definition a_distinct_lists :: "(_) heap \ bool" where "a_distinct_lists h = distinct (concat ( (map (\ptr. |h \ get_child_nodes ptr|\<^sub>r) |h \ object_ptr_kinds_M|\<^sub>r) @ (map (\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r) |h \ document_ptr_kinds_M|\<^sub>r) ))" definition a_heap_is_wellformed :: "(_) heap \ bool" where "a_heap_is_wellformed h \ a_acyclic_heap h \ a_all_ptrs_in_heap h \ a_distinct_lists h \ a_owner_document_valid h" end locale l_heap_is_wellformed_defs = fixes heap_is_wellformed :: "(_) heap \ bool" fixes parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" global_interpretation l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs defines heap_is_wellformed = "l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs.a_heap_is_wellformed get_child_nodes get_disconnected_nodes" and parent_child_rel = "l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs.a_parent_child_rel get_child_nodes" and acyclic_heap = a_acyclic_heap and all_ptrs_in_heap = a_all_ptrs_in_heap and distinct_lists = a_distinct_lists and owner_document_valid = a_owner_document_valid . locale l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_get_child_nodes type_wf known_ptr get_child_nodes get_child_nodes_locs + l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs + l_heap_is_wellformed_defs heap_is_wellformed parent_child_rel + l_get_disconnected_nodes type_wf get_disconnected_nodes get_disconnected_nodes_locs for known_ptr :: "(_::linorder) object_ptr \ bool" and type_wf :: "(_) heap \ bool" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" + assumes heap_is_wellformed_impl: "heap_is_wellformed = a_heap_is_wellformed" assumes parent_child_rel_impl: "parent_child_rel = a_parent_child_rel" begin lemmas heap_is_wellformed_def = heap_is_wellformed_impl[unfolded a_heap_is_wellformed_def] lemmas parent_child_rel_def = parent_child_rel_impl[unfolded a_parent_child_rel_def] lemmas acyclic_heap_def = a_acyclic_heap_def[folded parent_child_rel_impl] lemma parent_child_rel_node_ptr: "(parent, child) \ parent_child_rel h \ is_node_ptr_kind child" by(auto simp add: parent_child_rel_def) lemma parent_child_rel_child_nodes: assumes "known_ptr parent" and "h \ get_child_nodes parent \\<^sub>r children" and "child \ set children" shows "(parent, cast child) \ parent_child_rel h" using assms apply(auto simp add: parent_child_rel_def is_OK_returns_result_I )[1] using get_child_nodes_ptr_in_heap by blast lemma parent_child_rel_child_nodes2: assumes "known_ptr parent" and "h \ get_child_nodes parent \\<^sub>r children" and "child \ set children" and "cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child = child_obj" shows "(parent, child_obj) \ parent_child_rel h" using assms parent_child_rel_child_nodes by blast lemma parent_child_rel_finite: "finite (parent_child_rel h)" proof - have "parent_child_rel h = (\ptr \ set |h \ object_ptr_kinds_M|\<^sub>r. (\child \ set |h \ get_child_nodes ptr|\<^sub>r. {(ptr, cast child)}))" by(auto simp add: parent_child_rel_def) moreover have "finite (\ptr \ set |h \ object_ptr_kinds_M|\<^sub>r. (\child \ set |h \ get_child_nodes ptr|\<^sub>r. {(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child)}))" by simp ultimately show ?thesis by simp qed lemma distinct_lists_no_parent: assumes "a_distinct_lists h" assumes "h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes" assumes "node_ptr \ set disc_nodes" shows "\(\parent_ptr. parent_ptr |\| object_ptr_kinds h \ node_ptr \ set |h \ get_child_nodes parent_ptr|\<^sub>r)" using assms apply(auto simp add: a_distinct_lists_def)[1] proof - fix parent_ptr :: "(_) object_ptr" assume a1: "parent_ptr |\| object_ptr_kinds h" assume a2: "(\x\fset (object_ptr_kinds h). set |h \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h). set |h \ get_disconnected_nodes x|\<^sub>r) = {}" assume a3: "h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes" assume a4: "node_ptr \ set disc_nodes" assume a5: "node_ptr \ set |h \ get_child_nodes parent_ptr|\<^sub>r" have f6: "parent_ptr \ fset (object_ptr_kinds h)" using a1 by auto have f7: "document_ptr \ fset (document_ptr_kinds h)" using a3 by (meson fmember.rep_eq get_disconnected_nodes_ptr_in_heap is_OK_returns_result_I) have "|h \ get_disconnected_nodes document_ptr|\<^sub>r = disc_nodes" using a3 by simp then show False using f7 f6 a5 a4 a2 by blast qed lemma distinct_lists_disconnected_nodes: assumes "a_distinct_lists h" and "h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes" shows "distinct disc_nodes" proof - have h1: "distinct (concat (map (\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r) |h \ document_ptr_kinds_M|\<^sub>r))" using assms(1) by(simp add: a_distinct_lists_def) then show ?thesis using concat_map_all_distinct[OF h1] assms(2) is_OK_returns_result_I get_disconnected_nodes_ok by (metis (no_types, lifting) DocumentMonad.ptr_kinds_ptr_kinds_M l_get_disconnected_nodes.get_disconnected_nodes_ptr_in_heap l_get_disconnected_nodes_axioms select_result_I2) qed lemma distinct_lists_children: assumes "a_distinct_lists h" and "known_ptr ptr" and "h \ get_child_nodes ptr \\<^sub>r children" shows "distinct children" proof (cases "children = []", simp) assume "children \ []" have h1: "distinct (concat ((map (\ptr. |h \ get_child_nodes ptr|\<^sub>r) |h \ object_ptr_kinds_M|\<^sub>r)))" using assms(1) by(simp add: a_distinct_lists_def) show ?thesis using concat_map_all_distinct[OF h1] assms(2) assms(3) by (metis (no_types, lifting) ObjectMonad.ptr_kinds_ptr_kinds_M get_child_nodes_ptr_in_heap is_OK_returns_result_I select_result_I2) qed lemma heap_is_wellformed_children_in_heap: assumes "heap_is_wellformed h" assumes "h \ get_child_nodes ptr \\<^sub>r children" assumes "child \ set children" shows "child |\| node_ptr_kinds h" using assms apply(auto simp add: heap_is_wellformed_def a_all_ptrs_in_heap_def)[1] by (metis (no_types, lifting) finite_set_in is_OK_returns_result_I local.get_child_nodes_ptr_in_heap select_result_I2 subsetD) lemma heap_is_wellformed_one_parent: assumes "heap_is_wellformed h" assumes "h \ get_child_nodes ptr \\<^sub>r children" assumes "h \ get_child_nodes ptr' \\<^sub>r children'" assumes "set children \ set children' \ {}" shows "ptr = ptr'" using assms proof (auto simp add: heap_is_wellformed_def a_distinct_lists_def)[1] fix x :: "(_) node_ptr" assume a1: "ptr \ ptr'" assume a2: "h \ get_child_nodes ptr \\<^sub>r children" assume a3: "h \ get_child_nodes ptr' \\<^sub>r children'" assume a4: "distinct (concat (map (\ptr. |h \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h)))))" have f5: "|h \ get_child_nodes ptr|\<^sub>r = children" using a2 by simp have "|h \ get_child_nodes ptr'|\<^sub>r = children'" using a3 by (meson select_result_I2) then have "ptr \ set (sorted_list_of_set (fset (object_ptr_kinds h))) \ ptr' \ set (sorted_list_of_set (fset (object_ptr_kinds h))) \ set children \ set children' = {}" using f5 a4 a1 by (meson distinct_concat_map_E(1)) then show False using a3 a2 by (metis (no_types) assms(4) finite_fset fmember.rep_eq is_OK_returns_result_I local.get_child_nodes_ptr_in_heap set_sorted_list_of_set) qed lemma parent_child_rel_child: "h \ get_child_nodes ptr \\<^sub>r children \ child \ set children \ (ptr, cast child) \ parent_child_rel h" by (simp add: is_OK_returns_result_I get_child_nodes_ptr_in_heap parent_child_rel_def) lemma parent_child_rel_acyclic: "heap_is_wellformed h \ acyclic (parent_child_rel h)" by (simp add: acyclic_heap_def local.heap_is_wellformed_def) lemma heap_is_wellformed_disconnected_nodes_distinct: "heap_is_wellformed h \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ distinct disc_nodes" using distinct_lists_disconnected_nodes local.heap_is_wellformed_def by blast lemma parent_child_rel_parent_in_heap: "(parent, child_ptr) \ parent_child_rel h \ parent |\| object_ptr_kinds h" using local.parent_child_rel_def by blast lemma parent_child_rel_child_in_heap: "heap_is_wellformed h \ type_wf h \ known_ptr parent \ (parent, child_ptr) \ parent_child_rel h \ child_ptr |\| object_ptr_kinds h" apply(auto simp add: heap_is_wellformed_def parent_child_rel_def a_all_ptrs_in_heap_def)[1] using get_child_nodes_ok by (meson finite_set_in subsetD) lemma heap_is_wellformed_disc_nodes_in_heap: "heap_is_wellformed h \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ node \ set disc_nodes \ node |\| node_ptr_kinds h" by (metis (no_types, lifting) finite_set_in is_OK_returns_result_I local.a_all_ptrs_in_heap_def local.get_disconnected_nodes_ptr_in_heap local.heap_is_wellformed_def select_result_I2 subsetD) lemma heap_is_wellformed_one_disc_parent: "heap_is_wellformed h \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ h \ get_disconnected_nodes document_ptr' \\<^sub>r disc_nodes' \ set disc_nodes \ set disc_nodes' \ {} \ document_ptr = document_ptr'" using DocumentMonad.ptr_kinds_ptr_kinds_M concat_append distinct_append distinct_concat_map_E(1) is_OK_returns_result_I local.a_distinct_lists_def local.get_disconnected_nodes_ptr_in_heap local.heap_is_wellformed_def select_result_I2 proof - assume a1: "heap_is_wellformed h" assume a2: "h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes" assume a3: "h \ get_disconnected_nodes document_ptr' \\<^sub>r disc_nodes'" assume a4: "set disc_nodes \ set disc_nodes' \ {}" have f5: "|h \ get_disconnected_nodes document_ptr|\<^sub>r = disc_nodes" using a2 by (meson select_result_I2) have f6: "|h \ get_disconnected_nodes document_ptr'|\<^sub>r = disc_nodes'" using a3 by (meson select_result_I2) have "\nss nssa. \ distinct (concat (nss @ nssa)) \ distinct (concat nssa::(_) node_ptr list)" by (metis (no_types) concat_append distinct_append) then have "distinct (concat (map (\d. |h \ get_disconnected_nodes d|\<^sub>r) |h \ document_ptr_kinds_M|\<^sub>r))" using a1 local.a_distinct_lists_def local.heap_is_wellformed_def by blast then show ?thesis using f6 f5 a4 a3 a2 by (meson DocumentMonad.ptr_kinds_ptr_kinds_M distinct_concat_map_E(1) is_OK_returns_result_I local.get_disconnected_nodes_ptr_in_heap) qed lemma heap_is_wellformed_children_disc_nodes_different: "heap_is_wellformed h \ h \ get_child_nodes ptr \\<^sub>r children \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ set children \ set disc_nodes = {}" by (metis (no_types, hide_lams) disjoint_iff_not_equal distinct_lists_no_parent is_OK_returns_result_I local.get_child_nodes_ptr_in_heap local.heap_is_wellformed_def select_result_I2) lemma heap_is_wellformed_children_disc_nodes: "heap_is_wellformed h \ node_ptr |\| node_ptr_kinds h \ \(\parent \ fset (object_ptr_kinds h). node_ptr \ set |h \ get_child_nodes parent|\<^sub>r) \ (\document_ptr \ fset (document_ptr_kinds h). node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r)" apply(auto simp add: heap_is_wellformed_def a_distinct_lists_def a_owner_document_valid_def)[1] by (meson fmember.rep_eq) lemma heap_is_wellformed_children_distinct: "heap_is_wellformed h \ h \ get_child_nodes ptr \\<^sub>r children \ distinct children" by (metis (no_types, lifting) ObjectMonad.ptr_kinds_ptr_kinds_M concat_append distinct_append distinct_concat_map_E(2) is_OK_returns_result_I local.a_distinct_lists_def local.get_child_nodes_ptr_in_heap local.heap_is_wellformed_def select_result_I2) end locale l_heap_is_wellformed = l_type_wf + l_known_ptr + l_heap_is_wellformed_defs + l_get_child_nodes_defs + l_get_disconnected_nodes_defs + assumes heap_is_wellformed_children_in_heap: "heap_is_wellformed h \ h \ get_child_nodes ptr \\<^sub>r children \ child \ set children \ child |\| node_ptr_kinds h" assumes heap_is_wellformed_disc_nodes_in_heap: "heap_is_wellformed h \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ node \ set disc_nodes \ node |\| node_ptr_kinds h" assumes heap_is_wellformed_one_parent: "heap_is_wellformed h \ h \ get_child_nodes ptr \\<^sub>r children \ h \ get_child_nodes ptr' \\<^sub>r children' \ set children \ set children' \ {} \ ptr = ptr'" assumes heap_is_wellformed_one_disc_parent: "heap_is_wellformed h \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ h \ get_disconnected_nodes document_ptr' \\<^sub>r disc_nodes' \ set disc_nodes \ set disc_nodes' \ {} \ document_ptr = document_ptr'" assumes heap_is_wellformed_children_disc_nodes_different: "heap_is_wellformed h \ h \ get_child_nodes ptr \\<^sub>r children \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ set children \ set disc_nodes = {}" assumes heap_is_wellformed_disconnected_nodes_distinct: "heap_is_wellformed h \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ distinct disc_nodes" assumes heap_is_wellformed_children_distinct: "heap_is_wellformed h \ h \ get_child_nodes ptr \\<^sub>r children \ distinct children" assumes heap_is_wellformed_children_disc_nodes: "heap_is_wellformed h \ node_ptr |\| node_ptr_kinds h \ \(\parent \ fset (object_ptr_kinds h). node_ptr \ set |h \ get_child_nodes parent|\<^sub>r) \ (\document_ptr \ fset (document_ptr_kinds h). node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r)" assumes parent_child_rel_child: "h \ get_child_nodes ptr \\<^sub>r children \ child \ set children \ (ptr, cast child) \ parent_child_rel h" assumes parent_child_rel_finite: "heap_is_wellformed h \ finite (parent_child_rel h)" assumes parent_child_rel_acyclic: "heap_is_wellformed h \ acyclic (parent_child_rel h)" assumes parent_child_rel_node_ptr: "(parent, child_ptr) \ parent_child_rel h \ is_node_ptr_kind child_ptr" assumes parent_child_rel_parent_in_heap: "(parent, child_ptr) \ parent_child_rel h \ parent |\| object_ptr_kinds h" assumes parent_child_rel_child_in_heap: "heap_is_wellformed h \ type_wf h \ known_ptr parent \ (parent, child_ptr) \ parent_child_rel h \ child_ptr |\| object_ptr_kinds h" interpretation i_heap_is_wellformed?: l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel apply(unfold_locales) by(auto simp add: heap_is_wellformed_def parent_child_rel_def) declare l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms[instances] lemma heap_is_wellformed_is_l_heap_is_wellformed [instances]: "l_heap_is_wellformed type_wf known_ptr heap_is_wellformed parent_child_rel get_child_nodes get_disconnected_nodes" apply(auto simp add: l_heap_is_wellformed_def)[1] using heap_is_wellformed_children_in_heap apply blast using heap_is_wellformed_disc_nodes_in_heap apply blast using heap_is_wellformed_one_parent apply blast using heap_is_wellformed_one_disc_parent apply blast using heap_is_wellformed_children_disc_nodes_different apply blast using heap_is_wellformed_disconnected_nodes_distinct apply blast using heap_is_wellformed_children_distinct apply blast using heap_is_wellformed_children_disc_nodes apply blast using parent_child_rel_child apply (blast) using parent_child_rel_child apply(blast) using parent_child_rel_finite apply blast using parent_child_rel_acyclic apply blast using parent_child_rel_node_ptr apply blast using parent_child_rel_parent_in_heap apply blast using parent_child_rel_child_in_heap apply blast done subsection \get\_parent\ locale l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_get_parent\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs get_parent get_parent_locs + l_heap_is_wellformed type_wf known_ptr heap_is_wellformed parent_child_rel get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs for known_ptr :: "(_::linorder) object_ptr \ bool" and type_wf :: "(_) heap \ bool" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and known_ptrs :: "(_) heap \ bool" and get_parent :: "(_) node_ptr \ ((_) heap, exception, (_) object_ptr option) prog" and get_parent_locs :: "((_) heap \ (_) heap \ bool) set" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" begin lemma child_parent_dual: assumes heap_is_wellformed: "heap_is_wellformed h" assumes "h \ get_child_nodes ptr \\<^sub>r children" assumes "child \ set children" assumes "known_ptrs h" assumes type_wf: "type_wf h" shows "h \ get_parent child \\<^sub>r Some ptr" proof - obtain ptrs where ptrs: "h \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have h1: "ptr \ set ptrs" using get_child_nodes_ok assms(2) is_OK_returns_result_I by (metis (no_types, hide_lams) ObjectMonad.ptr_kinds_ptr_kinds_M \\thesis. (\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs \ thesis) \ thesis\ get_child_nodes_ptr_in_heap returns_result_eq select_result_I2) let ?P = "(\ptr. get_child_nodes ptr \ (\children. return (child \ set children)))" let ?filter = "filter_M ?P ptrs" have "h \ ok ?filter" using ptrs type_wf using get_child_nodes_ok apply(auto intro!: filter_M_is_OK_I bind_is_OK_pure_I get_child_nodes_ok simp add: bind_pure_I)[1] using assms(4) local.known_ptrs_known_ptr by blast then obtain parent_ptrs where parent_ptrs: "h \ ?filter \\<^sub>r parent_ptrs" by auto have h5: "\!x. x \ set ptrs \ h \ Heap_Error_Monad.bind (get_child_nodes x) (\children. return (child \ set children)) \\<^sub>r True" apply(auto intro!: bind_pure_returns_result_I)[1] using heap_is_wellformed_one_parent proof - have "h \ (return (child \ set children)::((_) heap, exception, bool) prog) \\<^sub>r True" by (simp add: assms(3)) then show "\z. z \ set ptrs \ h \ Heap_Error_Monad.bind (get_child_nodes z) (\ns. return (child \ set ns)) \\<^sub>r True" by (metis (no_types) assms(2) bind_pure_returns_result_I2 h1 is_OK_returns_result_I local.get_child_nodes_pure select_result_I2) next fix x y assume 0: "x \ set ptrs" and 1: "h \ Heap_Error_Monad.bind (get_child_nodes x) (\children. return (child \ set children)) \\<^sub>r True" and 2: "y \ set ptrs" and 3: "h \ Heap_Error_Monad.bind (get_child_nodes y) (\children. return (child \ set children)) \\<^sub>r True" and 4: "(\h ptr children ptr' children'. heap_is_wellformed h \ h \ get_child_nodes ptr \\<^sub>r children \ h \ get_child_nodes ptr' \\<^sub>r children' \ set children \ set children' \ {} \ ptr = ptr')" then show "x = y" by (metis (no_types, lifting) bind_returns_result_E disjoint_iff_not_equal heap_is_wellformed return_returns_result) qed have "child |\| node_ptr_kinds h" using heap_is_wellformed_children_in_heap heap_is_wellformed assms(2) assms(3) by fast moreover have "parent_ptrs = [ptr]" apply(rule filter_M_ex1[OF parent_ptrs h1 h5]) using ptrs assms(2) assms(3) by(auto simp add: object_ptr_kinds_M_defs bind_pure_I intro!: bind_pure_returns_result_I) ultimately show ?thesis using ptrs parent_ptrs by(auto simp add: bind_pure_I get_parent_def elim!: bind_returns_result_E2 intro!: bind_pure_returns_result_I filter_M_pure_I) (*slow, ca 1min *) qed lemma parent_child_rel_parent: assumes "heap_is_wellformed h" and "h \ get_parent child_node \\<^sub>r Some parent" shows "(parent, cast child_node) \ parent_child_rel h" using assms parent_child_rel_child get_parent_child_dual by auto lemma heap_wellformed_induct [consumes 1, case_names step]: assumes "heap_is_wellformed h" and step: "\parent. (\children child. h \ get_child_nodes parent \\<^sub>r children \ child \ set children \ P (cast child)) \ P parent" shows "P ptr" proof - fix ptr have "wf ((parent_child_rel h)\)" by (simp add: assms(1) finite_acyclic_wf_converse parent_child_rel_acyclic parent_child_rel_finite) then show "?thesis" proof (induct rule: wf_induct_rule) case (less parent) then show ?case using assms parent_child_rel_child by (meson converse_iff) qed qed lemma heap_wellformed_induct2 [consumes 3, case_names not_in_heap empty_children step]: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" and not_in_heap: "\parent. parent |\| object_ptr_kinds h \ P parent" and empty_children: "\parent. h \ get_child_nodes parent \\<^sub>r [] \ P parent" and step: "\parent children child. h \ get_child_nodes parent \\<^sub>r children \ child \ set children \ P (cast child) \ P parent" shows "P ptr" proof(insert assms(1), induct rule: heap_wellformed_induct) case (step parent) then show ?case proof(cases "parent |\| object_ptr_kinds h") case True then obtain children where children: "h \ get_child_nodes parent \\<^sub>r children" using get_child_nodes_ok assms(2) assms(3) by (meson is_OK_returns_result_E local.known_ptrs_known_ptr) then show ?thesis proof (cases "children = []") case True then show ?thesis using children empty_children by simp next case False then show ?thesis using assms(6) children last_in_set step.hyps by blast qed next case False then show ?thesis by (simp add: not_in_heap) qed qed lemma heap_wellformed_induct_rev [consumes 1, case_names step]: assumes "heap_is_wellformed h" and step: "\child. (\parent child_node. cast child_node = child \ h \ get_parent child_node \\<^sub>r Some parent \ P parent) \ P child" shows "P ptr" proof - fix ptr have "wf ((parent_child_rel h))" by (simp add: assms(1) local.parent_child_rel_acyclic local.parent_child_rel_finite wf_iff_acyclic_if_finite) then show "?thesis" proof (induct rule: wf_induct_rule) case (less child) show ?case using assms get_parent_child_dual by (metis less.hyps parent_child_rel_parent) qed qed end interpretation i_get_parent_wf?: l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs get_parent get_parent_locs heap_is_wellformed parent_child_rel get_disconnected_nodes using instances by(simp add: l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) declare l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms[instances] locale l_get_parent_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs get_parent get_parent_locs heap_is_wellformed parent_child_rel get_disconnected_nodes get_disconnected_nodes_locs + l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel for known_ptr :: "(_::linorder) object_ptr \ bool" and type_wf :: "(_) heap \ bool" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and known_ptrs :: "(_) heap \ bool" and get_parent :: "(_) node_ptr \ ((_) heap, exception, (_) object_ptr option) prog" and get_parent_locs :: "((_) heap \ (_) heap \ bool) set" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" begin lemma preserves_wellformedness_writes_needed: assumes heap_is_wellformed: "heap_is_wellformed h" and "h \ f \\<^sub>h h'" and "writes SW f h h'" and preserved_get_child_nodes: "\h h' w. w \ SW \ h \ w \\<^sub>h h' \ \object_ptr. \r \ get_child_nodes_locs object_ptr. r h h'" and preserved_get_disconnected_nodes: "\h h' w. w \ SW \ h \ w \\<^sub>h h' \ \document_ptr. \r \ get_disconnected_nodes_locs document_ptr. r h h'" and preserved_object_pointers: "\h h' w. w \ SW \ h \ w \\<^sub>h h' \ \object_ptr. preserved (get_M\<^sub>O\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t object_ptr RObject.nothing) h h'" shows "heap_is_wellformed h'" proof - have object_ptr_kinds_eq3: "object_ptr_kinds h = object_ptr_kinds h'" using assms(2) assms(3) object_ptr_kinds_preserved preserved_object_pointers by blast then have object_ptr_kinds_eq: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" unfolding object_ptr_kinds_M_defs by simp then have object_ptr_kinds_eq2: "|h \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" using select_result_eq by force then have node_ptr_kinds_eq2: "|h \ node_ptr_kinds_M|\<^sub>r = |h' \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by auto then have node_ptr_kinds_eq3: "node_ptr_kinds h = node_ptr_kinds h'" by auto have document_ptr_kinds_eq2: "|h \ document_ptr_kinds_M|\<^sub>r = |h' \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_eq2 document_ptr_kinds_M_eq by auto then have document_ptr_kinds_eq3: "document_ptr_kinds h = document_ptr_kinds h'" by auto have children_eq: "\ptr children. h \ get_child_nodes ptr \\<^sub>r children = h' \ get_child_nodes ptr \\<^sub>r children" apply(rule reads_writes_preserved[OF get_child_nodes_reads assms(3) assms(2)]) using preserved_get_child_nodes by fast then have children_eq2: "\ptr. |h \ get_child_nodes ptr|\<^sub>r = |h' \ get_child_nodes ptr|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq: "\document_ptr disconnected_nodes. h \ get_disconnected_nodes document_ptr \\<^sub>r disconnected_nodes = h' \ get_disconnected_nodes document_ptr \\<^sub>r disconnected_nodes" apply(rule reads_writes_preserved[OF get_disconnected_nodes_reads assms(3) assms(2)]) using preserved_get_disconnected_nodes by fast then have disconnected_nodes_eq2: "\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r = |h' \ get_disconnected_nodes document_ptr|\<^sub>r" using select_result_eq by force have get_parent_eq: "\ptr parent. h \ get_parent ptr \\<^sub>r parent = h' \ get_parent ptr \\<^sub>r parent" apply(rule reads_writes_preserved[OF get_parent_reads assms(3) assms(2)]) using preserved_get_child_nodes preserved_object_pointers unfolding get_parent_locs_def by fast have "a_acyclic_heap h" using heap_is_wellformed by (simp add: heap_is_wellformed_def) have "parent_child_rel h' \ parent_child_rel h" proof fix x assume "x \ parent_child_rel h'" then show "x \ parent_child_rel h" by(simp add: parent_child_rel_def children_eq2 object_ptr_kinds_eq3) qed then have "a_acyclic_heap h'" using \a_acyclic_heap h\ acyclic_heap_def acyclic_subset by blast moreover have "a_all_ptrs_in_heap h" using heap_is_wellformed by (simp add: heap_is_wellformed_def) then have "a_all_ptrs_in_heap h'" by (simp add: children_eq2 disconnected_nodes_eq2 document_ptr_kinds_eq3 l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs.a_all_ptrs_in_heap_def node_ptr_kinds_eq3 object_ptr_kinds_eq3) moreover have h0: "a_distinct_lists h" using heap_is_wellformed by (simp add: heap_is_wellformed_def) have h1: "map (\ptr. |h \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h))) = map (\ptr. |h' \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h')))" by (simp add: children_eq2 object_ptr_kinds_eq3) have h2: "map (\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h))) = map (\document_ptr. |h' \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h')))" using disconnected_nodes_eq document_ptr_kinds_eq2 select_result_eq by force have "a_distinct_lists h'" using h0 by(simp add: a_distinct_lists_def h1 h2) moreover have "a_owner_document_valid h" using heap_is_wellformed by (simp add: heap_is_wellformed_def) then have "a_owner_document_valid h'" by(auto simp add: a_owner_document_valid_def children_eq2 disconnected_nodes_eq2 object_ptr_kinds_eq3 node_ptr_kinds_eq3 document_ptr_kinds_eq3) ultimately show ?thesis by (simp add: heap_is_wellformed_def) qed end interpretation i_get_parent_wf2?: l_get_parent_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs get_parent get_parent_locs heap_is_wellformed parent_child_rel get_disconnected_nodes get_disconnected_nodes_locs using l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms by (simp add: l_get_parent_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) declare l_get_parent_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms[instances] locale l_get_parent_wf = l_type_wf + l_known_ptrs + l_heap_is_wellformed_defs + l_get_child_nodes_defs + l_get_parent_defs + assumes child_parent_dual: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_child_nodes ptr \\<^sub>r children \ child \ set children \ h \ get_parent child \\<^sub>r Some ptr" assumes heap_wellformed_induct [consumes 1, case_names step]: "heap_is_wellformed h \ (\parent. (\children child. h \ get_child_nodes parent \\<^sub>r children \ child \ set children \ P (cast child)) \ P parent) \ P ptr" assumes heap_wellformed_induct_rev [consumes 1, case_names step]: "heap_is_wellformed h \ (\child. (\parent child_node. cast child_node = child \ h \ get_parent child_node \\<^sub>r Some parent \ P parent) \ P child) \ P ptr" assumes parent_child_rel_parent: "heap_is_wellformed h \ h \ get_parent child_node \\<^sub>r Some parent \ (parent, cast child_node) \ parent_child_rel h" lemma get_parent_wf_is_l_get_parent_wf [instances]: "l_get_parent_wf type_wf known_ptr known_ptrs heap_is_wellformed parent_child_rel get_child_nodes get_parent" using known_ptrs_is_l_known_ptrs apply(auto simp add: l_get_parent_wf_def l_get_parent_wf_axioms_def)[1] using child_parent_dual heap_wellformed_induct heap_wellformed_induct_rev parent_child_rel_parent by metis+ subsection \get\_disconnected\_nodes\ subsection \set\_disconnected\_nodes\ subsubsection \get\_disconnected\_nodes\ locale l_set_disconnected_nodes_get_disconnected_nodes_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_set_disconnected_nodes_get_disconnected_nodes type_wf get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs + l_heap_is_wellformed type_wf known_ptr heap_is_wellformed parent_child_rel get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs for known_ptr :: "(_) object_ptr \ bool" and type_wf :: "(_) heap \ bool" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" and set_disconnected_nodes :: "(_) document_ptr \ (_) node_ptr list \ ((_) heap, exception, unit) prog" and set_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap, exception, unit) prog set" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" begin lemma remove_from_disconnected_nodes_removes: assumes "heap_is_wellformed h" assumes "h \ get_disconnected_nodes ptr \\<^sub>r disc_nodes" assumes "h \ set_disconnected_nodes ptr (remove1 node_ptr disc_nodes) \\<^sub>h h'" assumes "h' \ get_disconnected_nodes ptr \\<^sub>r disc_nodes'" shows "node_ptr \ set disc_nodes'" using assms by (metis distinct_remove1_removeAll heap_is_wellformed_disconnected_nodes_distinct set_disconnected_nodes_get_disconnected_nodes member_remove remove_code(1) returns_result_eq) end locale l_set_disconnected_nodes_get_disconnected_nodes_wf = l_heap_is_wellformed + l_set_disconnected_nodes_get_disconnected_nodes + assumes remove_from_disconnected_nodes_removes: "heap_is_wellformed h \ h \ get_disconnected_nodes ptr \\<^sub>r disc_nodes \ h \ set_disconnected_nodes ptr (remove1 node_ptr disc_nodes) \\<^sub>h h' \ h' \ get_disconnected_nodes ptr \\<^sub>r disc_nodes' \ node_ptr \ set disc_nodes'" interpretation i_set_disconnected_nodes_get_disconnected_nodes_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M?: l_set_disconnected_nodes_get_disconnected_nodes_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs heap_is_wellformed parent_child_rel get_child_nodes using instances by (simp add: l_set_disconnected_nodes_get_disconnected_nodes_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) declare l_set_disconnected_nodes_get_disconnected_nodes_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms[instances] lemma set_disconnected_nodes_get_disconnected_nodes_wf_is_l_set_disconnected_nodes_get_disconnected_nodes_wf [instances]: "l_set_disconnected_nodes_get_disconnected_nodes_wf type_wf known_ptr heap_is_wellformed parent_child_rel get_child_nodes get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs" apply(auto simp add: l_set_disconnected_nodes_get_disconnected_nodes_wf_def l_set_disconnected_nodes_get_disconnected_nodes_wf_axioms_def instances)[1] using remove_from_disconnected_nodes_removes apply fast done subsection \get\_root\_node\ locale l_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_heap_is_wellformed type_wf known_ptr heap_is_wellformed parent_child_rel get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs + l_get_parent\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs get_parent get_parent_locs + l_get_parent_wf type_wf known_ptr known_ptrs heap_is_wellformed parent_child_rel get_child_nodes get_child_nodes_locs get_parent get_parent_locs + l_get_root_node\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M type_wf known_ptr known_ptrs get_parent get_parent_locs get_child_nodes get_child_nodes_locs get_ancestors get_ancestors_locs get_root_node get_root_node_locs for known_ptr :: "(_::linorder) object_ptr \ bool" and type_wf :: "(_) heap \ bool" and known_ptrs :: "(_) heap \ bool" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" and get_parent :: "(_) node_ptr \ ((_) heap, exception, (_) object_ptr option) prog" and get_parent_locs :: "((_) heap \ (_) heap \ bool) set" and get_ancestors :: "(_) object_ptr \ ((_) heap, exception, (_) object_ptr list) prog" and get_ancestors_locs :: "((_) heap \ (_) heap \ bool) set" and get_root_node :: "(_) object_ptr \ ((_) heap, exception, (_) object_ptr) prog" and get_root_node_locs :: "((_) heap \ (_) heap \ bool) set" begin lemma get_ancestors_reads: assumes "heap_is_wellformed h" shows "reads get_ancestors_locs (get_ancestors node_ptr) h h'" proof (insert assms(1), induct rule: heap_wellformed_induct_rev) case (step child) then show ?case using [[simproc del: Product_Type.unit_eq]] get_parent_reads[unfolded reads_def] apply(simp (no_asm) add: get_ancestors_def) by(auto simp add: get_ancestors_locs_def reads_subset[OF return_reads] get_parent_reads_pointers intro!: reads_bind_pure reads_subset[OF check_in_heap_reads] reads_subset[OF get_parent_reads] reads_subset[OF get_child_nodes_reads] split: option.splits) qed lemma get_ancestors_ok: assumes "heap_is_wellformed h" and "ptr |\| object_ptr_kinds h" and "known_ptrs h" and type_wf: "type_wf h" shows "h \ ok (get_ancestors ptr)" proof (insert assms(1) assms(2), induct rule: heap_wellformed_induct_rev) case (step child) then show ?case using assms(3) assms(4) apply(simp (no_asm) add: get_ancestors_def) apply(simp add: assms(1) get_parent_parent_in_heap) by(auto intro!: bind_is_OK_pure_I bind_pure_I get_parent_ok split: option.splits) qed lemma get_root_node_ptr_in_heap: assumes "h \ ok (get_root_node ptr)" shows "ptr |\| object_ptr_kinds h" using assms unfolding get_root_node_def using get_ancestors_ptr_in_heap by auto lemma get_root_node_ok: assumes "heap_is_wellformed h" "known_ptrs h" "type_wf h" and "ptr |\| object_ptr_kinds h" shows "h \ ok (get_root_node ptr)" unfolding get_root_node_def using assms get_ancestors_ok by auto lemma get_ancestors_parent: assumes "heap_is_wellformed h" and "h \ get_parent child \\<^sub>r Some parent" shows "h \ get_ancestors (cast child) \\<^sub>r (cast child) # parent # ancestors \ h \ get_ancestors parent \\<^sub>r parent # ancestors" proof assume a1: "h \ get_ancestors (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child # parent # ancestors" then have "h \ Heap_Error_Monad.bind (check_in_heap (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child)) (\_. Heap_Error_Monad.bind (get_parent child) (\x. Heap_Error_Monad.bind (case x of None \ return [] | Some x \ get_ancestors x) (\ancestors. return (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child # ancestors)))) \\<^sub>r cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child # parent # ancestors" by(simp add: get_ancestors_def) then show "h \ get_ancestors parent \\<^sub>r parent # ancestors" using assms(2) apply(auto elim!: bind_returns_result_E2 split: option.splits)[1] using returns_result_eq by fastforce next assume "h \ get_ancestors parent \\<^sub>r parent # ancestors" then show "h \ get_ancestors (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child # parent # ancestors" using assms(2) apply(simp (no_asm) add: get_ancestors_def) apply(auto intro!: bind_pure_returns_result_I split: option.splits)[1] by (metis (full_types) assms(2) check_in_heap_ptr_in_heap is_OK_returns_result_I local.get_parent_ptr_in_heap node_ptr_kinds_commutes old.unit.exhaust select_result_I) qed lemma get_ancestors_never_empty: assumes "heap_is_wellformed h" and "h \ get_ancestors child \\<^sub>r ancestors" shows "ancestors \ []" proof(insert assms(2), induct arbitrary: ancestors rule: heap_wellformed_induct_rev[OF assms(1)]) case (1 child) then show ?case proof (induct "cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child") case None then show ?case apply(simp add: get_ancestors_def) by(auto elim!: bind_returns_result_E2 split: option.splits) next case (Some child_node) then obtain parent_opt where parent_opt: "h \ get_parent child_node \\<^sub>r parent_opt" apply(simp add: get_ancestors_def) by(auto elim!: bind_returns_result_E2 split: option.splits) with Some show ?case proof(induct parent_opt) case None then show ?case apply(simp add: get_ancestors_def) by(auto elim!: bind_returns_result_E2 split: option.splits) next case (Some option) then show ?case apply(simp add: get_ancestors_def) by(auto elim!: bind_returns_result_E2 split: option.splits) qed qed qed lemma get_ancestors_subset: assumes "heap_is_wellformed h" and "h \ get_ancestors ptr \\<^sub>r ancestors" and "ancestor \ set ancestors" and "h \ get_ancestors ancestor \\<^sub>r ancestor_ancestors" and type_wf: "type_wf h" and known_ptrs: "known_ptrs h" shows "set ancestor_ancestors \ set ancestors" proof (insert assms(1) assms(2) assms(3), induct ptr arbitrary: ancestors rule: heap_wellformed_induct_rev) case (step child) have "child |\| object_ptr_kinds h" using get_ancestors_ptr_in_heap step(2) by auto (* then have "h \ check_in_heap child \\<^sub>r ()" using returns_result_select_result by force *) show ?case proof (induct "cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child") case None then have "ancestors = [child]" using step(2) step(3) by(auto simp add: get_ancestors_def elim!: bind_returns_result_E2) show ?case using step(2) step(3) apply(auto simp add: \ancestors = [child]\)[1] using assms(4) returns_result_eq by fastforce next case (Some child_node) note s1 = Some obtain parent_opt where parent_opt: "h \ get_parent child_node \\<^sub>r parent_opt" using \child |\| object_ptr_kinds h\ assms(1) Some[symmetric] get_parent_ok[OF type_wf known_ptrs] by (metis (no_types, lifting) is_OK_returns_result_E known_ptrs get_parent_ok l_get_parent\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms node_ptr_casts_commute node_ptr_kinds_commutes) then show ?case proof (induct parent_opt) case None then have "ancestors = [child]" using step(2) step(3) s1 apply(simp add: get_ancestors_def) by(auto elim!: bind_returns_result_E2 split: option.splits dest: returns_result_eq) show ?case using step(2) step(3) apply(auto simp add: \ancestors = [child]\)[1] using assms(4) returns_result_eq by fastforce next case (Some parent) have "h \ Heap_Error_Monad.bind (check_in_heap child) (\_. Heap_Error_Monad.bind (case cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child of None \ return [] | Some node_ptr \ Heap_Error_Monad.bind (get_parent node_ptr) (\parent_ptr_opt. case parent_ptr_opt of None \ return [] | Some x \ get_ancestors x)) (\ancestors. return (child # ancestors))) \\<^sub>r ancestors" using step(2) by(simp add: get_ancestors_def) moreover obtain tl_ancestors where tl_ancestors: "ancestors = child # tl_ancestors" using calculation by(auto elim!: bind_returns_result_E2 split: option.splits) ultimately have "h \ get_ancestors parent \\<^sub>r tl_ancestors" using s1 Some by(auto elim!: bind_returns_result_E2 split: option.splits dest: returns_result_eq) show ?case using step(1)[OF s1[symmetric, simplified] Some \h \ get_ancestors parent \\<^sub>r tl_ancestors\] step(3) apply(auto simp add: tl_ancestors)[1] by (metis assms(4) insert_iff list.simps(15) local.step(2) returns_result_eq tl_ancestors) qed qed qed lemma get_ancestors_also_parent: assumes "heap_is_wellformed h" and "h \ get_ancestors some_ptr \\<^sub>r ancestors" and "cast child \ set ancestors" and "h \ get_parent child \\<^sub>r Some parent" and type_wf: "type_wf h" and known_ptrs: "known_ptrs h" shows "parent \ set ancestors" proof - obtain child_ancestors where child_ancestors: "h \ get_ancestors (cast child) \\<^sub>r child_ancestors" by (meson assms(1) assms(4) get_ancestors_ok is_OK_returns_result_I known_ptrs local.get_parent_ptr_in_heap node_ptr_kinds_commutes returns_result_select_result type_wf) then have "parent \ set child_ancestors" apply(simp add: get_ancestors_def) by(auto elim!: bind_returns_result_E2 split: option.splits dest!: returns_result_eq[OF assms(4)] get_ancestors_ptr) then show ?thesis using assms child_ancestors get_ancestors_subset by blast qed lemma get_ancestors_obtains_children: assumes "heap_is_wellformed h" and "ancestor \ ptr" and "ancestor \ set ancestors" and "h \ get_ancestors ptr \\<^sub>r ancestors" and type_wf: "type_wf h" and known_ptrs: "known_ptrs h" obtains children ancestor_child where "h \ get_child_nodes ancestor \\<^sub>r children" and "ancestor_child \ set children" and "cast ancestor_child \ set ancestors" proof - assume 0: "(\children ancestor_child. h \ get_child_nodes ancestor \\<^sub>r children \ ancestor_child \ set children \ cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ancestor_child \ set ancestors \ thesis)" have "\child. h \ get_parent child \\<^sub>r Some ancestor \ cast child \ set ancestors" proof (insert assms(1) assms(2) assms(3) assms(4), induct ptr arbitrary: ancestors rule: heap_wellformed_induct_rev) case (step child) have "child |\| object_ptr_kinds h" using get_ancestors_ptr_in_heap step(4) by auto show ?case proof (induct "cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child") case None then have "ancestors = [child]" using step(3) step(4) by(auto simp add: get_ancestors_def elim!: bind_returns_result_E2) show ?case using step(2) step(3) step(4) by(auto simp add: \ancestors = [child]\) next case (Some child_node) note s1 = Some obtain parent_opt where parent_opt: "h \ get_parent child_node \\<^sub>r parent_opt" using \child |\| object_ptr_kinds h\ assms(1) Some[symmetric] using get_parent_ok known_ptrs type_wf by (metis (no_types, lifting) is_OK_returns_result_E node_ptr_casts_commute node_ptr_kinds_commutes) then show ?case proof (induct parent_opt) case None then have "ancestors = [child]" using step(2) step(3) step(4) s1 apply(simp add: get_ancestors_def) by(auto elim!: bind_returns_result_E2 split: option.splits dest: returns_result_eq) show ?case using step(2) step(3) step(4) by(auto simp add: \ancestors = [child]\) next case (Some parent) have "h \ Heap_Error_Monad.bind (check_in_heap child) (\_. Heap_Error_Monad.bind (case cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child of None \ return [] | Some node_ptr \ Heap_Error_Monad.bind (get_parent node_ptr) (\parent_ptr_opt. case parent_ptr_opt of None \ return [] | Some x \ get_ancestors x)) (\ancestors. return (child # ancestors))) \\<^sub>r ancestors" using step(4) by(simp add: get_ancestors_def) moreover obtain tl_ancestors where tl_ancestors: "ancestors = child # tl_ancestors" using calculation by(auto elim!: bind_returns_result_E2 split: option.splits) ultimately have "h \ get_ancestors parent \\<^sub>r tl_ancestors" using s1 Some by(auto elim!: bind_returns_result_E2 split: option.splits dest: returns_result_eq) (* have "ancestor \ parent" *) have "ancestor \ set tl_ancestors" using tl_ancestors step(2) step(3) by auto show ?case proof (cases "ancestor \ parent") case True show ?thesis using step(1)[OF s1[symmetric, simplified] Some True \ancestor \ set tl_ancestors\ \h \ get_ancestors parent \\<^sub>r tl_ancestors\] using tl_ancestors by auto next case False have "child \ set ancestors" using step(4) get_ancestors_ptr by simp then show ?thesis using Some False s1[symmetric] by(auto) qed qed qed qed then obtain child where child: "h \ get_parent child \\<^sub>r Some ancestor" and in_ancestors: "cast child \ set ancestors" by auto then obtain children where children: "h \ get_child_nodes ancestor \\<^sub>r children" and child_in_children: "child \ set children" using get_parent_child_dual by blast show thesis using 0[OF children child_in_children] child assms(3) in_ancestors by blast qed lemma get_ancestors_parent_child_rel: assumes "heap_is_wellformed h" and "h \ get_ancestors child \\<^sub>r ancestors" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "(ptr, child) \ (parent_child_rel h)\<^sup>* \ ptr \ set ancestors" proof (safe) assume 3: "(ptr, child) \ (parent_child_rel h)\<^sup>*" show "ptr \ set ancestors" proof (insert 3, induct ptr rule: heap_wellformed_induct[OF assms(1)]) case (1 ptr) then show ?case proof (cases "ptr = child") case True then show ?thesis by (metis (no_types, lifting) assms(2) bind_returns_result_E get_ancestors_def in_set_member member_rec(1) return_returns_result) next case False obtain ptr_child where ptr_child: "(ptr, ptr_child) \ (parent_child_rel h) \ (ptr_child, child) \ (parent_child_rel h)\<^sup>*" using converse_rtranclE[OF 1(2)] \ptr \ child\ by metis then obtain ptr_child_node where ptr_child_ptr_child_node: "ptr_child = cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr_child_node" using ptr_child node_ptr_casts_commute3 parent_child_rel_node_ptr by (metis ) then obtain children where children: "h \ get_child_nodes ptr \\<^sub>r children" and ptr_child_node: "ptr_child_node \ set children" proof - assume a1: "\children. \h \ get_child_nodes ptr \\<^sub>r children; ptr_child_node \ set children\ \ thesis" have "ptr |\| object_ptr_kinds h" using local.parent_child_rel_parent_in_heap ptr_child by blast moreover have "ptr_child_node \ set |h \ get_child_nodes ptr|\<^sub>r" by (metis calculation known_ptrs local.get_child_nodes_ok local.known_ptrs_known_ptr local.parent_child_rel_child ptr_child ptr_child_ptr_child_node returns_result_select_result type_wf) ultimately show ?thesis using a1 get_child_nodes_ok type_wf known_ptrs by (meson local.known_ptrs_known_ptr returns_result_select_result) qed moreover have "(cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr_child_node, child) \ (parent_child_rel h)\<^sup>*" using ptr_child ptr_child_ptr_child_node by auto ultimately have "cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr_child_node \ set ancestors" using 1 by auto moreover have "h \ get_parent ptr_child_node \\<^sub>r Some ptr" using assms(1) children ptr_child_node child_parent_dual using known_ptrs type_wf by blast ultimately show ?thesis using get_ancestors_also_parent assms type_wf by blast qed qed next assume 3: "ptr \ set ancestors" show "(ptr, child) \ (parent_child_rel h)\<^sup>*" proof (insert 3, induct ptr rule: heap_wellformed_induct[OF assms(1)]) case (1 ptr) then show ?case proof (cases "ptr = child") case True then show ?thesis by simp next case False then obtain children ptr_child_node where children: "h \ get_child_nodes ptr \\<^sub>r children" and ptr_child_node: "ptr_child_node \ set children" and ptr_child_node_in_ancestors: "cast ptr_child_node \ set ancestors" using 1(2) assms(2) get_ancestors_obtains_children assms(1) using known_ptrs type_wf by blast then have "(cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr_child_node, child) \ (parent_child_rel h)\<^sup>*" using 1(1) by blast moreover have "(ptr, cast ptr_child_node) \ parent_child_rel h" using children ptr_child_node assms(1) parent_child_rel_child_nodes2 using child_parent_dual known_ptrs parent_child_rel_parent type_wf by blast ultimately show ?thesis by auto qed qed qed lemma get_root_node_parent_child_rel: assumes "heap_is_wellformed h" and "h \ get_root_node child \\<^sub>r root" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "(root, child) \ (parent_child_rel h)\<^sup>*" using assms get_ancestors_parent_child_rel apply(auto simp add: get_root_node_def elim!: bind_returns_result_E2)[1] using get_ancestors_never_empty last_in_set by blast lemma get_ancestors_eq: assumes "heap_is_wellformed h" and "heap_is_wellformed h'" and "\object_ptr w. object_ptr \ ptr \ w \ get_child_nodes_locs object_ptr \ w h h'" and pointers_preserved: "\object_ptr. preserved (get_M\<^sub>O\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t object_ptr RObject.nothing) h h'" and known_ptrs: "known_ptrs h" and known_ptrs': "known_ptrs h'" and "h \ get_ancestors ptr \\<^sub>r ancestors" and type_wf: "type_wf h" and type_wf': "type_wf h'" shows "h' \ get_ancestors ptr \\<^sub>r ancestors" proof - have object_ptr_kinds_eq3: "object_ptr_kinds h = object_ptr_kinds h'" using pointers_preserved object_ptr_kinds_preserved_small by blast then have object_ptr_kinds_M_eq: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_eq: "|h \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" by(simp) have "h' \ ok (get_ancestors ptr)" using get_ancestors_ok get_ancestors_ptr_in_heap object_ptr_kinds_eq3 assms(1) known_ptrs known_ptrs' assms(2) assms(7) type_wf' by blast then obtain ancestors' where ancestors': "h' \ get_ancestors ptr \\<^sub>r ancestors'" by auto obtain root where root: "h \ get_root_node ptr \\<^sub>r root" proof - assume 0: "(\root. h \ get_root_node ptr \\<^sub>r root \ thesis)" show thesis apply(rule 0) using assms(7) by(auto simp add: get_root_node_def elim!: bind_returns_result_E2 split: option.splits) qed have children_eq: "\p children. p \ ptr \ h \ get_child_nodes p \\<^sub>r children = h' \ get_child_nodes p \\<^sub>r children" using get_child_nodes_reads assms(3) apply(simp add: reads_def reflp_def transp_def preserved_def) by blast have "acyclic (parent_child_rel h)" using assms(1) local.parent_child_rel_acyclic by auto have "acyclic (parent_child_rel h')" using assms(2) local.parent_child_rel_acyclic by blast have 2: "\c parent_opt. cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c \ set ancestors \ set ancestors' \ h \ get_parent c \\<^sub>r parent_opt = h' \ get_parent c \\<^sub>r parent_opt" proof - fix c parent_opt assume 1: " cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c \ set ancestors \ set ancestors'" obtain ptrs where ptrs: "h \ object_ptr_kinds_M \\<^sub>r ptrs" by simp let ?P = "(\ptr. Heap_Error_Monad.bind (get_child_nodes ptr) (\children. return (c \ set children)))" have children_eq_True: "\p. p \ set ptrs \ h \ ?P p \\<^sub>r True \ h' \ ?P p \\<^sub>r True" proof - fix p assume "p \ set ptrs" then show "h \ ?P p \\<^sub>r True \ h' \ ?P p \\<^sub>r True" proof (cases "p = ptr") case True have "(cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c, ptr) \ (parent_child_rel h)\<^sup>*" using get_ancestors_parent_child_rel 1 assms by blast then have "(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \ (parent_child_rel h)" proof (cases "cast c = ptr") case True then show ?thesis using \acyclic (parent_child_rel h)\ by(auto simp add: acyclic_def) next case False then have "(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \ (parent_child_rel h)\<^sup>*" using \acyclic (parent_child_rel h)\ False rtrancl_eq_or_trancl rtrancl_trancl_trancl \(cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c, ptr) \ (parent_child_rel h)\<^sup>*\ by (metis acyclic_def) then show ?thesis using r_into_rtrancl by auto qed obtain children where children: "h \ get_child_nodes ptr \\<^sub>r children" using type_wf by (metis \h' \ ok get_ancestors ptr\ assms(1) get_ancestors_ptr_in_heap get_child_nodes_ok heap_is_wellformed_def is_OK_returns_result_E known_ptrs local.known_ptrs_known_ptr object_ptr_kinds_eq3) then have "c \ set children" using \(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \ (parent_child_rel h)\ assms(1) using parent_child_rel_child_nodes2 using child_parent_dual known_ptrs parent_child_rel_parent type_wf by blast with children have "h \ ?P p \\<^sub>r False" by(auto simp add: True) moreover have "(cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c, ptr) \ (parent_child_rel h')\<^sup>*" using get_ancestors_parent_child_rel assms(2) ancestors' 1 known_ptrs' type_wf type_wf' by blast then have "(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \ (parent_child_rel h')" proof (cases "cast c = ptr") case True then show ?thesis using \acyclic (parent_child_rel h')\ by(auto simp add: acyclic_def) next case False then have "(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \ (parent_child_rel h')\<^sup>*" using \acyclic (parent_child_rel h')\ False rtrancl_eq_or_trancl rtrancl_trancl_trancl \(cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c, ptr) \ (parent_child_rel h')\<^sup>*\ by (metis acyclic_def) then show ?thesis using r_into_rtrancl by auto qed then have "(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \ (parent_child_rel h')" using r_into_rtrancl by auto obtain children' where children': "h' \ get_child_nodes ptr \\<^sub>r children'" using type_wf type_wf' by (meson \h' \ ok (get_ancestors ptr)\ assms(2) get_ancestors_ptr_in_heap get_child_nodes_ok is_OK_returns_result_E known_ptrs' local.known_ptrs_known_ptr) then have "c \ set children'" using \(ptr, cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \ (parent_child_rel h')\ assms(2) type_wf type_wf' using parent_child_rel_child_nodes2 child_parent_dual known_ptrs' parent_child_rel_parent by auto with children' have "h' \ ?P p \\<^sub>r False" by(auto simp add: True) ultimately show ?thesis by (metis returns_result_eq) next case False then show ?thesis using children_eq ptrs by (metis (no_types, lifting) bind_pure_returns_result_I bind_returns_result_E get_child_nodes_pure return_returns_result) qed qed have "\pa. pa \ set ptrs \ h \ ok (get_child_nodes pa \ (\children. return (c \ set children))) = h' \ ok ( get_child_nodes pa \ (\children. return (c \ set children)))" using assms(1) assms(2) object_ptr_kinds_eq ptrs type_wf type_wf' by (metis (no_types, lifting) ObjectMonad.ptr_kinds_ptr_kinds_M bind_is_OK_pure_I get_child_nodes_ok get_child_nodes_pure known_ptrs' local.known_ptrs_known_ptr return_ok select_result_I2) have children_eq_False: "\pa. pa \ set ptrs \ h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False = h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False" proof fix pa assume "pa \ set ptrs" and "h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False" have "h \ ok (get_child_nodes pa \ (\children. return (c \ set children))) \ h' \ ok ( get_child_nodes pa \ (\children. return (c \ set children)))" using \pa \ set ptrs\ \\pa. pa \ set ptrs \ h \ ok (get_child_nodes pa \ (\children. return (c \ set children))) = h' \ ok ( get_child_nodes pa \ (\children. return (c \ set children)))\ by auto moreover have "h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False \ h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False" by (metis (mono_tags, lifting) \\pa. pa \ set ptrs \ h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r True = h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r True\ \pa \ set ptrs\ calculation is_OK_returns_result_I returns_result_eq returns_result_select_result) ultimately show "h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False" using \h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False\ by auto next fix pa assume "pa \ set ptrs" and "h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False" have "h' \ ok (get_child_nodes pa \ (\children. return (c \ set children))) \ h \ ok ( get_child_nodes pa \ (\children. return (c \ set children)))" using \pa \ set ptrs\ \\pa. pa \ set ptrs \ h \ ok (get_child_nodes pa \ (\children. return (c \ set children))) = h' \ ok ( get_child_nodes pa \ (\children. return (c \ set children)))\ by auto moreover have "h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False \ h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False" by (metis (mono_tags, lifting) \\pa. pa \ set ptrs \ h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r True = h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r True\ \pa \ set ptrs\ calculation is_OK_returns_result_I returns_result_eq returns_result_select_result) ultimately show "h \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False" using \h' \ get_child_nodes pa \ (\children. return (c \ set children)) \\<^sub>r False\ by blast qed have filter_eq: "\xs. h \ filter_M ?P ptrs \\<^sub>r xs = h' \ filter_M ?P ptrs \\<^sub>r xs" proof (rule filter_M_eq) show "\xs x. pure (Heap_Error_Monad.bind (get_child_nodes x) (\children. return (c \ set children))) h" by(auto intro!: bind_pure_I) next show "\xs x. pure (Heap_Error_Monad.bind (get_child_nodes x) (\children. return (c \ set children))) h'" by(auto intro!: bind_pure_I) next fix xs b x assume 0: "x \ set ptrs" then show "h \ Heap_Error_Monad.bind (get_child_nodes x) (\children. return (c \ set children)) \\<^sub>r b = h' \ Heap_Error_Monad.bind (get_child_nodes x) (\children. return (c \ set children)) \\<^sub>r b" apply(induct b) using children_eq_True apply blast using children_eq_False apply blast done qed show "h \ get_parent c \\<^sub>r parent_opt = h' \ get_parent c \\<^sub>r parent_opt" apply(simp add: get_parent_def) apply(rule bind_cong_2) apply(simp) apply(simp) apply(simp add: check_in_heap_def node_ptr_kinds_def object_ptr_kinds_eq3) apply(rule bind_cong_2) apply(auto simp add: object_ptr_kinds_M_eq object_ptr_kinds_eq3)[1] apply(auto simp add: object_ptr_kinds_M_eq object_ptr_kinds_eq3)[1] apply(auto simp add: object_ptr_kinds_M_eq object_ptr_kinds_eq3)[1] apply(rule bind_cong_2) apply(auto intro!: filter_M_pure_I bind_pure_I)[1] apply(auto intro!: filter_M_pure_I bind_pure_I)[1] apply(auto simp add: filter_eq (* dest!: returns_result_eq[OF ptrs] *))[1] using filter_eq ptrs apply auto[1] using filter_eq ptrs by auto qed have "ancestors = ancestors'" proof(insert assms(1) assms(7) ancestors' 2, induct ptr arbitrary: ancestors ancestors' rule: heap_wellformed_induct_rev) case (step child) show ?case using step(2) step(3) step(4) apply(simp add: get_ancestors_def) apply(auto intro!: elim!: bind_returns_result_E2 split: option.splits)[1] using returns_result_eq apply fastforce apply (meson option.simps(3) returns_result_eq) by (metis IntD1 IntD2 option.inject returns_result_eq step.hyps) qed then show ?thesis using assms(5) ancestors' by simp qed lemma get_ancestors_remains_not_in_ancestors: assumes "heap_is_wellformed h" and "heap_is_wellformed h'" and "h \ get_ancestors ptr \\<^sub>r ancestors" and "h' \ get_ancestors ptr \\<^sub>r ancestors'" and "\p children children'. h \ get_child_nodes p \\<^sub>r children \ h' \ get_child_nodes p \\<^sub>r children' \ set children' \ set children" and "node \ set ancestors" and object_ptr_kinds_eq3: "object_ptr_kinds h = object_ptr_kinds h'" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" and type_wf': "type_wf h'" shows "node \ set ancestors'" proof - have object_ptr_kinds_M_eq: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" using object_ptr_kinds_eq3 by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_eq: "|h \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" by(simp) show ?thesis proof (insert assms(1) assms(3) assms(4) assms(6), induct ptr arbitrary: ancestors ancestors' rule: heap_wellformed_induct_rev) case (step child) have 1: "\p parent. h' \ get_parent p \\<^sub>r Some parent \ h \ get_parent p \\<^sub>r Some parent" proof - fix p parent assume "h' \ get_parent p \\<^sub>r Some parent" then obtain children' where children': "h' \ get_child_nodes parent \\<^sub>r children'" and p_in_children': "p \ set children'" using get_parent_child_dual by blast obtain children where children: "h \ get_child_nodes parent \\<^sub>r children" using get_child_nodes_ok assms(1) get_child_nodes_ptr_in_heap object_ptr_kinds_eq children' known_ptrs using type_wf type_wf' by (metis \h' \ get_parent p \\<^sub>r Some parent\ get_parent_parent_in_heap is_OK_returns_result_E local.known_ptrs_known_ptr object_ptr_kinds_eq3) have "p \ set children" using assms(5) children children' p_in_children' by blast then show "h \ get_parent p \\<^sub>r Some parent" using child_parent_dual assms(1) children known_ptrs type_wf by blast qed have "node \ child" using assms(1) get_ancestors_parent_child_rel step.prems(1) step.prems(3) known_ptrs using type_wf type_wf' by blast then show ?case using step(2) step(3) apply(simp add: get_ancestors_def) using step(4) apply(auto elim!: bind_returns_result_E2 split: option.splits)[1] using 1 apply (meson option.distinct(1) returns_result_eq) by (metis "1" option.inject returns_result_eq step.hyps) qed qed lemma get_ancestors_ptrs_in_heap: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_ancestors ptr \\<^sub>r ancestors" assumes "ptr' \ set ancestors" shows "ptr' |\| object_ptr_kinds h" proof (insert assms(4) assms(5), induct ancestors arbitrary: ptr) case Nil then show ?case by(auto) next case (Cons a ancestors) then obtain x where x: "h \ get_ancestors x \\<^sub>r a # ancestors" by(auto simp add: get_ancestors_def[of a] elim!: bind_returns_result_E2 split: option.splits) then have "x = a" by(auto simp add: get_ancestors_def[of x] elim!: bind_returns_result_E2 split: option.splits) then show ?case using Cons.hyps Cons.prems(2) get_ancestors_ptr_in_heap x by (metis assms(1) assms(2) assms(3) get_ancestors_obtains_children get_child_nodes_ptr_in_heap is_OK_returns_result_I) qed lemma get_ancestors_prefix: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_ancestors ptr \\<^sub>r ancestors" assumes "ptr' \ set ancestors" assumes "h \ get_ancestors ptr' \\<^sub>r ancestors'" shows "\pre. ancestors = pre @ ancestors'" proof (insert assms(1) assms(5) assms(6), induct ptr' arbitrary: ancestors' rule: heap_wellformed_induct) case (step parent) then show ?case proof (cases "parent \ ptr" ) case True then obtain children ancestor_child where "h \ get_child_nodes parent \\<^sub>r children" and "ancestor_child \ set children" and "cast ancestor_child \ set ancestors" using assms(1) assms(2) assms(3) assms(4) get_ancestors_obtains_children step.prems(1) by blast then have "h \ get_parent ancestor_child \\<^sub>r Some parent" using assms(1) assms(2) assms(3) child_parent_dual by blast then have "h \ get_ancestors (cast ancestor_child) \\<^sub>r cast ancestor_child # ancestors'" apply(simp add: get_ancestors_def) using \h \ get_ancestors parent \\<^sub>r ancestors'\ get_parent_ptr_in_heap by(auto simp add: check_in_heap_def is_OK_returns_result_I intro!: bind_pure_returns_result_I) then show ?thesis using step(1) \h \ get_child_nodes parent \\<^sub>r children\ \ancestor_child \ set children\ \cast ancestor_child \ set ancestors\ \h \ get_ancestors (cast ancestor_child) \\<^sub>r cast ancestor_child # ancestors'\ by fastforce next case False then show ?thesis by (metis append_Nil assms(4) returns_result_eq step.prems(2)) qed qed lemma get_ancestors_same_root_node: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_ancestors ptr \\<^sub>r ancestors" assumes "ptr' \ set ancestors" assumes "ptr'' \ set ancestors" shows "h \ get_root_node ptr' \\<^sub>r root_ptr \ h \ get_root_node ptr'' \\<^sub>r root_ptr" proof - have "ptr' |\| object_ptr_kinds h" by (metis assms(1) assms(2) assms(3) assms(4) assms(5) get_ancestors_obtains_children get_ancestors_ptr_in_heap get_child_nodes_ptr_in_heap is_OK_returns_result_I) then obtain ancestors' where ancestors': "h \ get_ancestors ptr' \\<^sub>r ancestors'" by (meson assms(1) assms(2) assms(3) get_ancestors_ok is_OK_returns_result_E) then have "\pre. ancestors = pre @ ancestors'" using get_ancestors_prefix assms by blast moreover have "ptr'' |\| object_ptr_kinds h" by (metis assms(1) assms(2) assms(3) assms(4) assms(6) get_ancestors_obtains_children get_ancestors_ptr_in_heap get_child_nodes_ptr_in_heap is_OK_returns_result_I) then obtain ancestors'' where ancestors'': "h \ get_ancestors ptr'' \\<^sub>r ancestors''" by (meson assms(1) assms(2) assms(3) get_ancestors_ok is_OK_returns_result_E) then have "\pre. ancestors = pre @ ancestors''" using get_ancestors_prefix assms by blast ultimately show ?thesis using ancestors' ancestors'' apply(auto simp add: get_root_node_def elim!: bind_returns_result_E2 intro!: bind_pure_returns_result_I)[1] apply (metis (no_types, lifting) assms(1) get_ancestors_never_empty last_appendR returns_result_eq) by (metis assms(1) get_ancestors_never_empty last_appendR returns_result_eq) qed lemma get_root_node_parent_same: assumes "h \ get_parent child \\<^sub>r Some ptr" shows "h \ get_root_node (cast child) \\<^sub>r root \ h \ get_root_node ptr \\<^sub>r root" proof assume 1: " h \ get_root_node (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r root" show "h \ get_root_node ptr \\<^sub>r root" using 1[unfolded get_root_node_def] assms apply(simp add: get_ancestors_def) apply(auto simp add: get_root_node_def dest: returns_result_eq elim!: bind_returns_result_E2 intro!: bind_pure_returns_result_I split: option.splits)[1] using returns_result_eq apply fastforce using get_ancestors_ptr by fastforce next assume 1: " h \ get_root_node ptr \\<^sub>r root" show "h \ get_root_node (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r root" apply(simp add: get_root_node_def) using assms 1 apply(simp add: get_ancestors_def) apply(auto simp add: get_root_node_def dest: returns_result_eq elim!: bind_returns_result_E2 intro!: bind_pure_returns_result_I split: option.splits)[1] apply (simp add: check_in_heap_def is_OK_returns_result_I) using get_ancestors_ptr get_parent_ptr_in_heap apply (simp add: is_OK_returns_result_I) by (meson list.distinct(1) list.set_cases local.get_ancestors_ptr) qed lemma get_root_node_same_no_parent: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_root_node ptr \\<^sub>r cast child" shows "h \ get_parent child \\<^sub>r None" proof (insert assms(1) assms(4), induct ptr rule: heap_wellformed_induct_rev) case (step c) then show ?case proof (cases "cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r c") case None then have "c = cast child" using step(2) by(auto simp add: get_root_node_def get_ancestors_def[of c] elim!: bind_returns_result_E2) then show ?thesis using None by auto next case (Some child_node) note s = this then obtain parent_opt where parent_opt: "h \ get_parent child_node \\<^sub>r parent_opt" by (metis (no_types, lifting) assms(2) assms(3) get_root_node_ptr_in_heap is_OK_returns_result_I local.get_parent_ok node_ptr_casts_commute node_ptr_kinds_commutes returns_result_select_result step.prems) then show ?thesis proof(induct parent_opt) case None then show ?case using Some get_root_node_no_parent returns_result_eq step.prems by fastforce next case (Some parent) then show ?case using step s apply(auto simp add: get_root_node_def get_ancestors_def[of c] elim!: bind_returns_result_E2 split: option.splits list.splits)[1] using get_root_node_parent_same step.hyps step.prems by auto qed qed qed lemma get_root_node_not_node_same: assumes "ptr |\| object_ptr_kinds h" assumes "\is_node_ptr_kind ptr" shows "h \ get_root_node ptr \\<^sub>r ptr" using assms apply(simp add: get_root_node_def get_ancestors_def) by(auto simp add: get_root_node_def dest: returns_result_eq elim!: bind_returns_result_E2 intro!: bind_pure_returns_result_I split: option.splits) lemma get_root_node_root_in_heap: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_root_node ptr \\<^sub>r root" shows "root |\| object_ptr_kinds h" using assms apply(auto simp add: get_root_node_def elim!: bind_returns_result_E2)[1] by (simp add: get_ancestors_never_empty get_ancestors_ptrs_in_heap) lemma get_root_node_same_no_parent_parent_child_rel: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_root_node ptr' \\<^sub>r ptr'" shows "\(\p. (p, ptr') \ (parent_child_rel h))" by (metis (no_types, lifting) assms(1) assms(2) assms(3) assms(4) get_root_node_same_no_parent l_heap_is_wellformed.parent_child_rel_child local.child_parent_dual local.get_child_nodes_ok local.known_ptrs_known_ptr local.l_heap_is_wellformed_axioms local.parent_child_rel_node_ptr local.parent_child_rel_parent_in_heap node_ptr_casts_commute3 option.simps(3) returns_result_eq returns_result_select_result) end locale l_get_ancestors_wf = l_heap_is_wellformed_defs + l_known_ptrs + l_type_wf + l_get_ancestors_defs + l_get_child_nodes_defs + l_get_parent_defs + assumes get_ancestors_never_empty: "heap_is_wellformed h \ h \ get_ancestors child \\<^sub>r ancestors \ ancestors \ []" assumes get_ancestors_ok: "heap_is_wellformed h \ ptr |\| object_ptr_kinds h \ known_ptrs h \ type_wf h \ h \ ok (get_ancestors ptr)" assumes get_ancestors_reads: "heap_is_wellformed h \ reads get_ancestors_locs (get_ancestors node_ptr) h h'" assumes get_ancestors_ptrs_in_heap: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_ancestors ptr \\<^sub>r ancestors \ ptr' \ set ancestors \ ptr' |\| object_ptr_kinds h" assumes get_ancestors_remains_not_in_ancestors: "heap_is_wellformed h \ heap_is_wellformed h' \ h \ get_ancestors ptr \\<^sub>r ancestors \ h' \ get_ancestors ptr \\<^sub>r ancestors' \ (\p children children'. h \ get_child_nodes p \\<^sub>r children \ h' \ get_child_nodes p \\<^sub>r children' \ set children' \ set children) \ node \ set ancestors \ object_ptr_kinds h = object_ptr_kinds h' \ known_ptrs h \ type_wf h \ type_wf h' \ node \ set ancestors'" assumes get_ancestors_also_parent: "heap_is_wellformed h \ h \ get_ancestors some_ptr \\<^sub>r ancestors \ cast child_node \ set ancestors \ h \ get_parent child_node \\<^sub>r Some parent \ type_wf h \ known_ptrs h \ parent \ set ancestors" assumes get_ancestors_obtains_children: "heap_is_wellformed h \ ancestor \ ptr \ ancestor \ set ancestors \ h \ get_ancestors ptr \\<^sub>r ancestors \ type_wf h \ known_ptrs h \ (\children ancestor_child . h \ get_child_nodes ancestor \\<^sub>r children \ ancestor_child \ set children \ cast ancestor_child \ set ancestors \ thesis) \ thesis" assumes get_ancestors_parent_child_rel: "heap_is_wellformed h \ h \ get_ancestors child \\<^sub>r ancestors \ known_ptrs h \ type_wf h \ (ptr, child) \ (parent_child_rel h)\<^sup>* \ ptr \ set ancestors" locale l_get_root_node_wf = l_heap_is_wellformed_defs + l_get_root_node_defs + l_type_wf + l_known_ptrs + l_get_ancestors_defs + l_get_parent_defs + assumes get_root_node_ok: "heap_is_wellformed h \ known_ptrs h \ type_wf h \ ptr |\| object_ptr_kinds h \ h \ ok (get_root_node ptr)" assumes get_root_node_ptr_in_heap: "h \ ok (get_root_node ptr) \ ptr |\| object_ptr_kinds h" assumes get_root_node_root_in_heap: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_root_node ptr \\<^sub>r root \ root |\| object_ptr_kinds h" assumes get_ancestors_same_root_node: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_ancestors ptr \\<^sub>r ancestors \ ptr' \ set ancestors \ ptr'' \ set ancestors \ h \ get_root_node ptr' \\<^sub>r root_ptr \ h \ get_root_node ptr'' \\<^sub>r root_ptr" assumes get_root_node_same_no_parent: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_root_node ptr \\<^sub>r cast child \ h \ get_parent child \\<^sub>r None" assumes get_root_node_parent_same: "h \ get_parent child \\<^sub>r Some ptr \ h \ get_root_node (cast child) \\<^sub>r root \ h \ get_root_node ptr \\<^sub>r root" interpretation i_get_root_node_wf?: l_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf known_ptrs heap_is_wellformed parent_child_rel get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs get_parent get_parent_locs get_ancestors get_ancestors_locs get_root_node get_root_node_locs using instances by(simp add: l_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) declare l_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms[instances] lemma get_ancestors_wf_is_l_get_ancestors_wf [instances]: "l_get_ancestors_wf heap_is_wellformed parent_child_rel known_ptr known_ptrs type_wf get_ancestors get_ancestors_locs get_child_nodes get_parent" using known_ptrs_is_l_known_ptrs apply(auto simp add: l_get_ancestors_wf_def l_get_ancestors_wf_axioms_def)[1] using get_ancestors_never_empty apply blast using get_ancestors_ok apply blast using get_ancestors_reads apply blast using get_ancestors_ptrs_in_heap apply blast using get_ancestors_remains_not_in_ancestors apply blast using get_ancestors_also_parent apply blast using get_ancestors_obtains_children apply blast using get_ancestors_parent_child_rel apply blast using get_ancestors_parent_child_rel apply blast done lemma get_root_node_wf_is_l_get_root_node_wf [instances]: "l_get_root_node_wf heap_is_wellformed get_root_node type_wf known_ptr known_ptrs get_ancestors get_parent" using known_ptrs_is_l_known_ptrs apply(auto simp add: l_get_root_node_wf_def l_get_root_node_wf_axioms_def)[1] using get_root_node_ok apply blast using get_root_node_ptr_in_heap apply blast using get_root_node_root_in_heap apply blast using get_ancestors_same_root_node apply(blast, blast) using get_root_node_same_no_parent apply blast using get_root_node_parent_same apply (blast, blast) done subsection \to\_tree\_order\ locale l_to_tree_order_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_to_tree_order\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_parent + l_get_parent_wf + l_heap_is_wellformed (* l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M *) begin lemma to_tree_order_ptr_in_heap: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ ok (to_tree_order ptr)" shows "ptr |\| object_ptr_kinds h" proof(insert assms(1) assms(4), induct rule: heap_wellformed_induct) case (step parent) then show ?case apply(auto simp add: to_tree_order_def[of parent] map_M_pure_I elim!: bind_is_OK_E3)[1] using get_child_nodes_ptr_in_heap by blast qed lemma to_tree_order_either_ptr_or_in_children: assumes "h \ to_tree_order ptr \\<^sub>r nodes" and "node \ set nodes" and "h \ get_child_nodes ptr \\<^sub>r children" and "node \ ptr" obtains child child_to where "child \ set children" and "h \ to_tree_order (cast child) \\<^sub>r child_to" and "node \ set child_to" proof - obtain treeorders where treeorders: "h \ map_M to_tree_order (map cast children) \\<^sub>r treeorders" using assms apply(auto simp add: to_tree_order_def elim!: bind_returns_result_E)[1] using pure_returns_heap_eq returns_result_eq by fastforce then have "node \ set (concat treeorders)" using assms[simplified to_tree_order_def] by(auto elim!: bind_returns_result_E4 dest: pure_returns_heap_eq) then obtain treeorder where "treeorder \ set treeorders" and node_in_treeorder: "node \ set treeorder" by auto then obtain child where "h \ to_tree_order (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r treeorder" and "child \ set children" using assms[simplified to_tree_order_def] treeorders by(auto elim!: map_M_pure_E2) then show ?thesis using node_in_treeorder returns_result_eq that by auto qed lemma to_tree_order_ptrs_in_heap: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ to_tree_order ptr \\<^sub>r to" assumes "ptr' \ set to" shows "ptr' |\| object_ptr_kinds h" proof(insert assms(1) assms(4) assms(5), induct ptr arbitrary: to rule: heap_wellformed_induct) case (step parent) have "parent |\| object_ptr_kinds h" using assms(1) assms(2) assms(3) step.prems(1) to_tree_order_ptr_in_heap by blast then obtain children where children: "h \ get_child_nodes parent \\<^sub>r children" by (meson assms(2) assms(3) get_child_nodes_ok is_OK_returns_result_E local.known_ptrs_known_ptr) then show ?case proof (cases "children = []") case True then have "to = [parent]" using step(2) children apply(auto simp add: to_tree_order_def[of parent] map_M_pure_I elim!: bind_returns_result_E2)[1] by (metis list.distinct(1) list.map_disc_iff list.set_cases map_M_pure_E2 returns_result_eq) then show ?thesis using \parent |\| object_ptr_kinds h\ step.prems(2) by auto next case False note f = this then show ?thesis using children step to_tree_order_either_ptr_or_in_children proof (cases "ptr' = parent") case True then show ?thesis using \parent |\| object_ptr_kinds h\ by blast next case False then show ?thesis using children step.hyps to_tree_order_either_ptr_or_in_children by (metis step.prems(1) step.prems(2)) qed qed qed lemma to_tree_order_ok: assumes wellformed: "heap_is_wellformed h" and "ptr |\| object_ptr_kinds h" and "known_ptrs h" and type_wf: "type_wf h" shows "h \ ok (to_tree_order ptr)" proof(insert assms(1) assms(2), induct rule: heap_wellformed_induct) case (step parent) then show ?case using assms(3) type_wf apply(simp add: to_tree_order_def) apply(auto simp add: heap_is_wellformed_def intro!: map_M_ok_I bind_is_OK_pure_I map_M_pure_I)[1] using get_child_nodes_ok known_ptrs_known_ptr apply blast by (simp add: local.heap_is_wellformed_children_in_heap local.to_tree_order_def wellformed) qed lemma to_tree_order_child_subset: assumes "heap_is_wellformed h" and "h \ to_tree_order ptr \\<^sub>r nodes" and "h \ get_child_nodes ptr \\<^sub>r children" and "node \ set children" and "h \ to_tree_order (cast node) \\<^sub>r nodes'" shows "set nodes' \ set nodes" proof fix x assume a1: "x \ set nodes'" moreover obtain treeorders where treeorders: "h \ map_M to_tree_order (map cast children) \\<^sub>r treeorders" using assms(2) assms(3) apply(auto simp add: to_tree_order_def elim!: bind_returns_result_E)[1] using pure_returns_heap_eq returns_result_eq by fastforce then have "nodes' \ set treeorders" using assms(4) assms(5) by(auto elim!: map_M_pure_E dest: returns_result_eq) moreover have "set (concat treeorders) \ set nodes" using treeorders assms(2) assms(3) by(auto simp add: to_tree_order_def elim!: bind_returns_result_E4 dest: pure_returns_heap_eq) ultimately show "x \ set nodes" by auto qed lemma to_tree_order_ptr_in_result: assumes "h \ to_tree_order ptr \\<^sub>r nodes" shows "ptr \ set nodes" using assms apply(simp add: to_tree_order_def) by(auto elim!: bind_returns_result_E2 intro!: map_M_pure_I bind_pure_I) lemma to_tree_order_subset: assumes "heap_is_wellformed h" and "h \ to_tree_order ptr \\<^sub>r nodes" and "node \ set nodes" and "h \ to_tree_order node \\<^sub>r nodes'" and "known_ptrs h" and type_wf: "type_wf h" shows "set nodes' \ set nodes" proof - have "\nodes. h \ to_tree_order ptr \\<^sub>r nodes \ (\node. node \ set nodes \ (\nodes'. h \ to_tree_order node \\<^sub>r nodes' \ set nodes' \ set nodes))" proof(insert assms(1), induct ptr rule: heap_wellformed_induct) case (step parent) then show ?case proof safe fix nodes node nodes' x assume 1: "(\children child. h \ get_child_nodes parent \\<^sub>r children \ child \ set children \ \nodes. h \ to_tree_order (cast child) \\<^sub>r nodes \ (\node. node \ set nodes \ (\nodes'. h \ to_tree_order node \\<^sub>r nodes' \ set nodes' \ set nodes)))" and 2: "h \ to_tree_order parent \\<^sub>r nodes" and 3: "node \ set nodes" and "h \ to_tree_order node \\<^sub>r nodes'" and "x \ set nodes'" have h1: "(\children child nodes node nodes'. h \ get_child_nodes parent \\<^sub>r children \ child \ set children \ h \ to_tree_order (cast child) \\<^sub>r nodes \ (node \ set nodes \ (h \ to_tree_order node \\<^sub>r nodes' \ set nodes' \ set nodes)))" using 1 by blast obtain children where children: "h \ get_child_nodes parent \\<^sub>r children" using 2 by(auto simp add: to_tree_order_def elim!: bind_returns_result_E) then have "set nodes' \ set nodes" proof (cases "children = []") case True then show ?thesis by (metis "2" "3" \h \ to_tree_order node \\<^sub>r nodes'\ children empty_iff list.set(1) subsetI to_tree_order_either_ptr_or_in_children) next case False then show ?thesis proof (cases "node = parent") case True then show ?thesis using "2" \h \ to_tree_order node \\<^sub>r nodes'\ returns_result_eq by fastforce next case False then obtain child nodes_of_child where "child \ set children" and "h \ to_tree_order (cast child) \\<^sub>r nodes_of_child" and "node \ set nodes_of_child" using 2[simplified to_tree_order_def] 3 to_tree_order_either_ptr_or_in_children[where node=node and ptr=parent] children apply(auto elim!: bind_returns_result_E2 intro: map_M_pure_I)[1] using is_OK_returns_result_E 2 a_all_ptrs_in_heap_def assms(1) heap_is_wellformed_def using "3" by blast then have "set nodes' \ set nodes_of_child" using h1 using \h \ to_tree_order node \\<^sub>r nodes'\ children by blast moreover have "set nodes_of_child \ set nodes" using "2" \child \ set children\ \h \ to_tree_order (cast child) \\<^sub>r nodes_of_child\ assms children to_tree_order_child_subset by auto ultimately show ?thesis by blast qed qed then show "x \ set nodes" using \x \ set nodes'\ by blast qed qed then show ?thesis using assms by blast qed lemma to_tree_order_parent: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ to_tree_order ptr \\<^sub>r nodes" assumes "h \ get_parent child \\<^sub>r Some parent" assumes "parent \ set nodes" shows "cast child \ set nodes" proof - obtain nodes' where nodes': "h \ to_tree_order parent \\<^sub>r nodes'" using assms to_tree_order_ok get_parent_parent_in_heap by (meson get_parent_parent_in_heap is_OK_returns_result_E) then have "set nodes' \ set nodes" using to_tree_order_subset assms by blast moreover obtain children where children: "h \ get_child_nodes parent \\<^sub>r children" and child: "child \ set children" using assms get_parent_child_dual by blast then obtain child_to where child_to: "h \ to_tree_order (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r child_to" by (meson assms(1) assms(2) assms(3) assms(5) is_OK_returns_result_E is_OK_returns_result_I get_parent_ptr_in_heap node_ptr_kinds_commutes to_tree_order_ok) then have "cast child \ set child_to" apply(simp add: to_tree_order_def) by(auto elim!: bind_returns_result_E2 map_M_pure_E dest!: bind_returns_result_E3[rotated, OF children, rotated] intro!: map_M_pure_I) have "cast child \ set nodes'" using nodes' child apply(simp add: to_tree_order_def) apply(auto elim!: bind_returns_result_E2 map_M_pure_E dest!: bind_returns_result_E3[rotated, OF children, rotated] intro!: map_M_pure_I)[1] using child_to \cast child \ set child_to\ returns_result_eq by fastforce ultimately show ?thesis by auto qed lemma to_tree_order_child: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ to_tree_order ptr \\<^sub>r nodes" assumes "h \ get_child_nodes parent \\<^sub>r children" assumes "cast child \ ptr" assumes "child \ set children" assumes "cast child \ set nodes" shows "parent \ set nodes" proof(insert assms(1) assms(4) assms(6) assms(8), induct ptr arbitrary: nodes rule: heap_wellformed_induct) case (step p) have "p |\| object_ptr_kinds h" using \h \ to_tree_order p \\<^sub>r nodes\ to_tree_order_ptr_in_heap using assms(1) assms(2) assms(3) by blast then obtain children where children: "h \ get_child_nodes p \\<^sub>r children" by (meson assms(2) assms(3) get_child_nodes_ok is_OK_returns_result_E local.known_ptrs_known_ptr) then show ?case proof (cases "children = []") case True then show ?thesis using step(2) step(3) step(4) children by(auto simp add: to_tree_order_def[of p] map_M_pure_I elim!: bind_returns_result_E2 dest!: bind_returns_result_E3[rotated, OF children, rotated]) next case False then obtain c child_to where child: "c \ set children" and child_to: "h \ to_tree_order (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \\<^sub>r child_to" and "cast child \ set child_to" using step(2) children apply(auto simp add: to_tree_order_def[of p] map_M_pure_I elim!: bind_returns_result_E2 dest!: bind_returns_result_E3[rotated, OF children, rotated])[1] by (metis (full_types) assms(1) assms(2) assms(3) get_parent_ptr_in_heap is_OK_returns_result_I l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M.child_parent_dual l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms node_ptr_kinds_commutes returns_result_select_result step.prems(1) step.prems(2) step.prems(3) to_tree_order_either_ptr_or_in_children to_tree_order_ok) then have "set child_to \ set nodes" using assms(1) child children step.prems(1) to_tree_order_child_subset by auto show ?thesis proof (cases "c = child") case True then have "parent = p" using step(3) children child assms(5) assms(7) by (meson assms(1) assms(2) assms(3) child_parent_dual option.inject returns_result_eq) then show ?thesis using step.prems(1) to_tree_order_ptr_in_result by blast next case False then show ?thesis using step(1)[OF children child child_to] step(3) step(4) using \set child_to \ set nodes\ using \cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child \ set child_to\ by auto qed qed qed lemma to_tree_order_node_ptrs: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ to_tree_order ptr \\<^sub>r nodes" assumes "ptr' \ ptr" assumes "ptr' \ set nodes" shows "is_node_ptr_kind ptr'" proof(insert assms(1) assms(4) assms(5) assms(6), induct ptr arbitrary: nodes rule: heap_wellformed_induct) case (step p) have "p |\| object_ptr_kinds h" using \h \ to_tree_order p \\<^sub>r nodes\ to_tree_order_ptr_in_heap using assms(1) assms(2) assms(3) by blast then obtain children where children: "h \ get_child_nodes p \\<^sub>r children" by (meson assms(2) assms(3) get_child_nodes_ok is_OK_returns_result_E local.known_ptrs_known_ptr) then show ?case proof (cases "children = []") case True then show ?thesis using step(2) step(3) step(4) children by(auto simp add: to_tree_order_def[of p] map_M_pure_I elim!: bind_returns_result_E2 dest!: bind_returns_result_E3[rotated, OF children, rotated])[1] next case False then obtain c child_to where child: "c \ set children" and child_to: "h \ to_tree_order (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \\<^sub>r child_to" and "ptr' \ set child_to" using step(2) children apply(auto simp add: to_tree_order_def[of p] map_M_pure_I elim!: bind_returns_result_E2 dest!: bind_returns_result_E3[rotated, OF children, rotated])[1] using step.prems(1) step.prems(2) step.prems(3) to_tree_order_either_ptr_or_in_children by blast then have "set child_to \ set nodes" using assms(1) child children step.prems(1) to_tree_order_child_subset by auto show ?thesis proof (cases "cast c = ptr") case True then show ?thesis using step \ptr' \ set child_to\ assms(5) child child_to children by blast next case False then show ?thesis using \ptr' \ set child_to\ child child_to children is_node_ptr_kind_cast step.hyps by blast qed qed qed lemma to_tree_order_child2: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ to_tree_order ptr \\<^sub>r nodes" assumes "cast child \ ptr" assumes "cast child \ set nodes" obtains parent where "h \ get_parent child \\<^sub>r Some parent" and "parent \ set nodes" proof - assume 1: "(\parent. h \ get_parent child \\<^sub>r Some parent \ parent \ set nodes \ thesis)" show thesis proof(insert assms(1) assms(4) assms(5) assms(6) 1, induct ptr arbitrary: nodes rule: heap_wellformed_induct) case (step p) have "p |\| object_ptr_kinds h" using \h \ to_tree_order p \\<^sub>r nodes\ to_tree_order_ptr_in_heap using assms(1) assms(2) assms(3) by blast then obtain children where children: "h \ get_child_nodes p \\<^sub>r children" by (meson assms(2) assms(3) get_child_nodes_ok is_OK_returns_result_E local.known_ptrs_known_ptr) then show ?case proof (cases "children = []") case True then show ?thesis using step(2) step(3) step(4) children by(auto simp add: to_tree_order_def[of p] map_M_pure_I elim!: bind_returns_result_E2 dest!: bind_returns_result_E3[rotated, OF children, rotated]) next case False then obtain c child_to where child: "c \ set children" and child_to: "h \ to_tree_order (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r c) \\<^sub>r child_to" and "cast child \ set child_to" using step(2) children apply(auto simp add: to_tree_order_def[of p] map_M_pure_I elim!: bind_returns_result_E2 dest!: bind_returns_result_E3[rotated, OF children, rotated])[1] using step.prems(1) step.prems(2) step.prems(3) to_tree_order_either_ptr_or_in_children by blast then have "set child_to \ set nodes" using assms(1) child children step.prems(1) to_tree_order_child_subset by auto have "cast child |\| object_ptr_kinds h" using assms(1) assms(2) assms(3) assms(4) assms(6) to_tree_order_ptrs_in_heap by blast then obtain parent_opt where parent_opt: "h \ get_parent child \\<^sub>r parent_opt" by (meson assms(2) assms(3) is_OK_returns_result_E get_parent_ok node_ptr_kinds_commutes) then show ?thesis proof (induct parent_opt) case None then show ?case by (metis \cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child \ set child_to\ assms(1) assms(2) assms(3) cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_inject child child_parent_dual child_to children option.distinct(1) returns_result_eq step.hyps) next case (Some option) then show ?case by (meson assms(1) assms(2) assms(3) get_parent_child_dual step.prems(1) step.prems(2) step.prems(3) step.prems(4) to_tree_order_child) qed qed qed qed lemma to_tree_order_parent_child_rel: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ to_tree_order ptr \\<^sub>r to" shows "(ptr, child) \ (parent_child_rel h)\<^sup>* \ child \ set to" proof assume 3: "(ptr, child) \ (parent_child_rel h)\<^sup>*" show "child \ set to" proof (insert 3, induct child rule: heap_wellformed_induct_rev[OF assms(1)]) case (1 child) then show ?case proof (cases "ptr = child") case True then show ?thesis using assms(4) apply(simp add: to_tree_order_def) by(auto simp add: map_M_pure_I elim!: bind_returns_result_E2) next case False obtain child_parent where "(ptr, child_parent) \ (parent_child_rel h)\<^sup>*" and "(child_parent, child) \ (parent_child_rel h)" using \ptr \ child\ by (metis "1.prems" rtranclE) obtain child_node where child_node: "cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child_node = child" using \(child_parent, child) \ parent_child_rel h\ node_ptr_casts_commute3 parent_child_rel_node_ptr by blast then have "h \ get_parent child_node \\<^sub>r Some child_parent" using \(child_parent, child) \ (parent_child_rel h)\ by (meson assms(1) assms(2) assms(3) is_OK_returns_result_E l_get_parent_wf.child_parent_dual l_heap_is_wellformed.parent_child_rel_child local.get_child_nodes_ok local.known_ptrs_known_ptr local.l_get_parent_wf_axioms local.l_heap_is_wellformed_axioms local.parent_child_rel_parent_in_heap) then show ?thesis using 1(1) child_node \(ptr, child_parent) \ (parent_child_rel h)\<^sup>*\ using assms(1) assms(2) assms(3) assms(4) to_tree_order_parent by blast qed qed next assume "child \ set to" then show "(ptr, child) \ (parent_child_rel h)\<^sup>*" proof (induct child rule: heap_wellformed_induct_rev[OF assms(1)]) case (1 child) then show ?case proof (cases "ptr = child") case True then show ?thesis by simp next case False then have "\parent. (parent, child) \ (parent_child_rel h)" using 1(2) assms(4) to_tree_order_child2[OF assms(1) assms(2) assms(3) assms(4)] to_tree_order_node_ptrs by (metis assms(1) assms(2) assms(3) node_ptr_casts_commute3 parent_child_rel_parent) then obtain child_node where child_node: "cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child_node = child" using node_ptr_casts_commute3 parent_child_rel_node_ptr by blast then obtain child_parent where child_parent: "h \ get_parent child_node \\<^sub>r Some child_parent" using \\parent. (parent, child) \ (parent_child_rel h)\ by (metis "1.prems" False assms(1) assms(2) assms(3) assms(4) to_tree_order_child2) then have "(child_parent, child) \ (parent_child_rel h)" using assms(1) child_node parent_child_rel_parent by blast moreover have "child_parent \ set to" by (metis "1.prems" False assms(1) assms(2) assms(3) assms(4) child_node child_parent get_parent_child_dual to_tree_order_child) then have "(ptr, child_parent) \ (parent_child_rel h)\<^sup>*" using 1 child_node child_parent by blast ultimately show ?thesis by auto qed qed qed end interpretation i_to_tree_order_wf?: l_to_tree_order_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs to_tree_order known_ptrs get_parent get_parent_locs heap_is_wellformed parent_child_rel get_disconnected_nodes get_disconnected_nodes_locs using instances apply(simp add: l_to_tree_order_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) done declare l_to_tree_order_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] locale l_to_tree_order_wf = l_heap_is_wellformed_defs + l_type_wf + l_known_ptrs + l_to_tree_order_defs + l_get_parent_defs + l_get_child_nodes_defs + assumes to_tree_order_ok: "heap_is_wellformed h \ ptr |\| object_ptr_kinds h \ known_ptrs h \ type_wf h \ h \ ok (to_tree_order ptr)" assumes to_tree_order_ptrs_in_heap: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ to_tree_order ptr \\<^sub>r to \ ptr' \ set to \ ptr' |\| object_ptr_kinds h" assumes to_tree_order_parent_child_rel: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ to_tree_order ptr \\<^sub>r to \ (ptr, child_ptr) \ (parent_child_rel h)\<^sup>* \ child_ptr \ set to" assumes to_tree_order_child2: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ to_tree_order ptr \\<^sub>r nodes \ cast child \ ptr \ cast child \ set nodes \ (\parent. h \ get_parent child \\<^sub>r Some parent \ parent \ set nodes \ thesis) \ thesis" assumes to_tree_order_node_ptrs: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ to_tree_order ptr \\<^sub>r nodes \ ptr' \ ptr \ ptr' \ set nodes \ is_node_ptr_kind ptr'" assumes to_tree_order_child: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ to_tree_order ptr \\<^sub>r nodes \ h \ get_child_nodes parent \\<^sub>r children \ cast child \ ptr \ child \ set children \ cast child \ set nodes \ parent \ set nodes" assumes to_tree_order_ptr_in_result: "h \ to_tree_order ptr \\<^sub>r nodes \ ptr \ set nodes" assumes to_tree_order_parent: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ to_tree_order ptr \\<^sub>r nodes \ h \ get_parent child \\<^sub>r Some parent \ parent \ set nodes \ cast child \ set nodes" assumes to_tree_order_subset: "heap_is_wellformed h \ h \ to_tree_order ptr \\<^sub>r nodes \ node \ set nodes \ h \ to_tree_order node \\<^sub>r nodes' \ known_ptrs h \ type_wf h \ set nodes' \ set nodes" lemma to_tree_order_wf_is_l_to_tree_order_wf [instances]: "l_to_tree_order_wf heap_is_wellformed parent_child_rel type_wf known_ptr known_ptrs to_tree_order get_parent get_child_nodes" using instances apply(auto simp add: l_to_tree_order_wf_def l_to_tree_order_wf_axioms_def)[1] using to_tree_order_ok apply blast using to_tree_order_ptrs_in_heap apply blast using to_tree_order_parent_child_rel apply(blast, blast) using to_tree_order_child2 apply blast using to_tree_order_node_ptrs apply blast using to_tree_order_child apply blast using to_tree_order_ptr_in_result apply blast using to_tree_order_parent apply blast using to_tree_order_subset apply blast done subsubsection \get\_root\_node\ locale l_to_tree_order_wf_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_to_tree_order_wf begin lemma to_tree_order_get_root_node: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ to_tree_order ptr \\<^sub>r to" assumes "ptr' \ set to" assumes "h \ get_root_node ptr' \\<^sub>r root_ptr" assumes "ptr'' \ set to" shows "h \ get_root_node ptr'' \\<^sub>r root_ptr" proof - obtain ancestors' where ancestors': "h \ get_ancestors ptr' \\<^sub>r ancestors'" by (meson assms(1) assms(2) assms(3) assms(4) assms(5) get_ancestors_ok is_OK_returns_result_E to_tree_order_ptrs_in_heap ) moreover have "ptr \ set ancestors'" using \h \ get_ancestors ptr' \\<^sub>r ancestors'\ using assms(1) assms(2) assms(3) assms(4) assms(5) get_ancestors_parent_child_rel to_tree_order_parent_child_rel by blast ultimately have "h \ get_root_node ptr \\<^sub>r root_ptr" using \h \ get_root_node ptr' \\<^sub>r root_ptr\ using assms(1) assms(2) assms(3) get_ancestors_ptr get_ancestors_same_root_node by blast obtain ancestors'' where ancestors'': "h \ get_ancestors ptr'' \\<^sub>r ancestors''" by (meson assms(1) assms(2) assms(3) assms(4) assms(7) get_ancestors_ok is_OK_returns_result_E to_tree_order_ptrs_in_heap) moreover have "ptr \ set ancestors''" using \h \ get_ancestors ptr'' \\<^sub>r ancestors''\ using assms(1) assms(2) assms(3) assms(4) assms(7) get_ancestors_parent_child_rel to_tree_order_parent_child_rel by blast ultimately show ?thesis using \h \ get_root_node ptr \\<^sub>r root_ptr\ assms(1) assms(2) assms(3) get_ancestors_ptr get_ancestors_same_root_node by blast qed lemma to_tree_order_same_root: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_root_node ptr \\<^sub>r root_ptr" assumes "h \ to_tree_order root_ptr \\<^sub>r to" assumes "ptr' \ set to" shows "h \ get_root_node ptr' \\<^sub>r root_ptr" proof (insert assms(1)(* assms(4) assms(5) *) assms(6), induct ptr' rule: heap_wellformed_induct_rev) case (step child) then show ?case proof (cases "h \ get_root_node child \\<^sub>r child") case True then have "child = root_ptr" using assms(1) assms(2) assms(3) assms(5) step.prems by (metis (no_types, lifting) get_root_node_same_no_parent node_ptr_casts_commute3 option.simps(3) returns_result_eq to_tree_order_child2 to_tree_order_node_ptrs) then show ?thesis using True by blast next case False then obtain child_node parent where "cast child_node = child" and "h \ get_parent child_node \\<^sub>r Some parent" by (metis assms(1) assms(2) assms(3) assms(4) assms(5) local.get_root_node_no_parent local.get_root_node_not_node_same local.get_root_node_same_no_parent local.to_tree_order_child2 local.to_tree_order_ptrs_in_heap node_ptr_casts_commute3 step.prems) then show ?thesis proof (cases "child = root_ptr") case True then have "h \ get_root_node root_ptr \\<^sub>r root_ptr" using assms(4) using \cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child_node = child\ assms(1) assms(2) assms(3) get_root_node_no_parent get_root_node_same_no_parent by blast then show ?thesis using step assms(4) using True by blast next case False then have "parent \ set to" using assms(5) step(2) to_tree_order_child \h \ get_parent child_node \\<^sub>r Some parent\ \cast child_node = child\ by (metis False assms(1) assms(2) assms(3) get_parent_child_dual) then show ?thesis using \cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child_node = child\ \h \ get_parent child_node \\<^sub>r Some parent\ get_root_node_parent_same using step.hyps by blast qed qed qed end interpretation i_to_tree_order_wf_get_root_node_wf?: l_to_tree_order_wf_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf known_ptrs heap_is_wellformed parent_child_rel get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs get_parent get_parent_locs get_ancestors get_ancestors_locs get_root_node get_root_node_locs to_tree_order using instances by(simp add: l_to_tree_order_wf_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) locale l_to_tree_order_wf_get_root_node_wf = l_type_wf + l_known_ptrs + l_to_tree_order_defs + l_get_root_node_defs + l_heap_is_wellformed_defs + assumes to_tree_order_get_root_node: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ to_tree_order ptr \\<^sub>r to \ ptr' \ set to \ h \ get_root_node ptr' \\<^sub>r root_ptr \ ptr'' \ set to \ h \ get_root_node ptr'' \\<^sub>r root_ptr" assumes to_tree_order_same_root: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_root_node ptr \\<^sub>r root_ptr \ h \ to_tree_order root_ptr \\<^sub>r to \ ptr' \ set to \ h \ get_root_node ptr' \\<^sub>r root_ptr" lemma to_tree_order_wf_get_root_node_wf_is_l_to_tree_order_wf_get_root_node_wf [instances]: "l_to_tree_order_wf_get_root_node_wf type_wf known_ptr known_ptrs to_tree_order get_root_node heap_is_wellformed" using instances apply(auto simp add: l_to_tree_order_wf_get_root_node_wf_def l_to_tree_order_wf_get_root_node_wf_axioms_def)[1] using to_tree_order_get_root_node apply blast using to_tree_order_same_root apply blast done subsection \get\_owner\_document\ locale l_get_owner_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_known_ptrs + l_heap_is_wellformed + l_get_root_node\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_ancestors + l_get_ancestors_wf + l_get_parent + l_get_parent_wf + l_get_root_node_wf + l_get_owner_document\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M begin lemma get_owner_document_disconnected_nodes: assumes "heap_is_wellformed h" assumes "h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes" assumes "node_ptr \ set disc_nodes" assumes known_ptrs: "known_ptrs h" assumes type_wf: "type_wf h" shows "h \ get_owner_document (cast node_ptr) \\<^sub>r document_ptr" proof - have 2: "node_ptr |\| node_ptr_kinds h" using assms heap_is_wellformed_disc_nodes_in_heap by blast have 3: "document_ptr |\| document_ptr_kinds h" using assms(2) get_disconnected_nodes_ptr_in_heap by blast have 0: "\!document_ptr\set |h \ document_ptr_kinds_M|\<^sub>r. node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r" by (metis (no_types, lifting) "3" DocumentMonad.ptr_kinds_ptr_kinds_M assms(1) assms(2) assms(3) disjoint_iff_not_equal l_heap_is_wellformed.heap_is_wellformed_one_disc_parent local.get_disconnected_nodes_ok local.l_heap_is_wellformed_axioms returns_result_select_result select_result_I2 type_wf) have "h \ get_parent node_ptr \\<^sub>r None" using heap_is_wellformed_children_disc_nodes_different child_parent_dual assms using "2" disjoint_iff_not_equal local.get_parent_child_dual local.get_parent_ok returns_result_select_result split_option_ex by (metis (no_types, lifting)) then have 4: "h \ get_root_node (cast node_ptr) \\<^sub>r cast node_ptr" using 2 get_root_node_no_parent by blast obtain document_ptrs where document_ptrs: "h \ document_ptr_kinds_M \\<^sub>r document_ptrs" by simp then have "h \ ok (filter_M (\document_ptr. do { disconnected_nodes \ get_disconnected_nodes document_ptr; return (((cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr)) \ cast ` set disconnected_nodes) }) document_ptrs)" using assms(1) get_disconnected_nodes_ok type_wf unfolding heap_is_wellformed_def by(auto intro!: bind_is_OK_I2 filter_M_is_OK_I bind_pure_I) then obtain candidates where candidates: "h \ filter_M (\document_ptr. do { disconnected_nodes \ get_disconnected_nodes document_ptr; return (((cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr)) \ cast ` set disconnected_nodes) }) document_ptrs \\<^sub>r candidates" by auto have eq: "\document_ptr. document_ptr |\| document_ptr_kinds h \ node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r \ |h \ do { disconnected_nodes \ get_disconnected_nodes document_ptr; return (((cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr)) \ cast ` set disconnected_nodes) }|\<^sub>r" apply(auto dest!: get_disconnected_nodes_ok[OF type_wf] intro!: select_result_I[where P=id, simplified] elim!: bind_returns_result_E2)[1] apply(drule select_result_E[where P=id, simplified]) by(auto elim!: bind_returns_result_E2) have filter: "filter (\document_ptr. |h \ do { disconnected_nodes \ get_disconnected_nodes document_ptr; return (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr \ cast ` set disconnected_nodes) }|\<^sub>r) document_ptrs = [document_ptr]" apply(rule filter_ex1) using 0 document_ptrs apply(simp)[1] using eq using local.get_disconnected_nodes_ok apply auto[1] using assms(2) assms(3) apply(auto intro!: intro!: select_result_I[where P=id, simplified] elim!: bind_returns_result_E2)[1] using returns_result_eq apply fastforce using document_ptrs 3 apply(simp) using document_ptrs by simp have "h \ filter_M (\document_ptr. do { disconnected_nodes \ get_disconnected_nodes document_ptr; return (((cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr)) \ cast ` set disconnected_nodes) }) document_ptrs \\<^sub>r [document_ptr]" apply(rule filter_M_filter2) using get_disconnected_nodes_ok document_ptrs 3 assms(1) type_wf filter unfolding heap_is_wellformed_def by(auto intro: bind_pure_I bind_is_OK_I2) with 4 document_ptrs have "h \ a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr () \\<^sub>r document_ptr" by(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def intro!: bind_pure_returns_result_I filter_M_pure_I bind_pure_I split: option.splits)[1] moreover have "known_ptr (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr)" using "4" assms(1) known_ptrs type_wf known_ptrs_known_ptr "2" node_ptr_kinds_commutes by blast ultimately show ?thesis using 2 apply(auto simp add: known_ptr_impl get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits, (rule conjI | rule impI)+)+ apply(drule(1) known_ptr_not_document_ptr[folded known_ptr_impl]) apply(drule(1) known_ptr_not_character_data_ptr) apply(drule(1) known_ptr_not_element_ptr) apply(simp add: NodeClass.known_ptr_defs) by(auto split: option.splits intro!: bind_pure_returns_result_I) qed lemma in_disconnected_nodes_no_parent: assumes "heap_is_wellformed h" and "h \ get_parent node_ptr \\<^sub>r None" and "h \ get_owner_document (cast node_ptr) \\<^sub>r owner_document" and "h \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "node_ptr \ set disc_nodes" proof - have 2: "cast node_ptr |\| object_ptr_kinds h" using assms(3) get_owner_document_ptr_in_heap by fast then have 3: "h \ get_root_node (cast node_ptr) \\<^sub>r cast node_ptr" using assms(2) local.get_root_node_no_parent by blast have "\(\parent_ptr. parent_ptr |\| object_ptr_kinds h \ node_ptr \ set |h \ get_child_nodes parent_ptr|\<^sub>r)" apply(auto)[1] using assms(2) child_parent_dual[OF assms(1)] type_wf assms(1) assms(5) get_child_nodes_ok known_ptrs_known_ptr option.simps(3) returns_result_eq returns_result_select_result by (metis (no_types, hide_lams)) moreover have "node_ptr |\| node_ptr_kinds h" using assms(2) get_parent_ptr_in_heap by blast ultimately have 0: "\document_ptr\set |h \ document_ptr_kinds_M|\<^sub>r. node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r" by (metis DocumentMonad.ptr_kinds_ptr_kinds_M assms(1) finite_set_in heap_is_wellformed_children_disc_nodes) then obtain document_ptr where document_ptr: "document_ptr\set |h \ document_ptr_kinds_M|\<^sub>r" and node_ptr_in_disc_nodes: "node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r" by auto then show ?thesis using get_owner_document_disconnected_nodes known_ptrs type_wf assms using DocumentMonad.ptr_kinds_ptr_kinds_M assms(1) assms(3) assms(4) get_disconnected_nodes_ok returns_result_select_result select_result_I2 by (metis (no_types, hide_lams) ) qed lemma get_owner_document_owner_document_in_heap: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_owner_document ptr \\<^sub>r owner_document" shows "owner_document |\| document_ptr_kinds h" using assms apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_split_asm)+ proof - assume "h \ invoke [] ptr () \\<^sub>r owner_document" then show "owner_document |\| document_ptr_kinds h" by (meson invoke_empty is_OK_returns_result_I) next assume "h \ Heap_Error_Monad.bind (check_in_heap ptr) (\_. (local.a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r \ the \ cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r) ptr ()) \\<^sub>r owner_document" then show "owner_document |\| document_ptr_kinds h" by(auto simp add: a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 split: if_splits) next assume 0: "heap_is_wellformed h" and 1: "type_wf h" and 2: "known_ptrs h" and 3: "\ is_element_ptr\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr" and 4: "is_character_data_ptr\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr" and 5: "h \ Heap_Error_Monad.bind (check_in_heap ptr) (\_. (local.a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r \ the \ cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r) ptr ()) \\<^sub>r owner_document" then obtain root where root: "h \ get_root_node ptr \\<^sub>r root" by(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 split: option.splits) then show ?thesis proof (cases "is_document_ptr root") case True then show ?thesis using 4 5 root apply(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 intro!: filter_M_pure_I bind_pure_I split: option.splits)[1] apply(drule(1) returns_result_eq) apply(auto)[1] using "0" "1" "2" document_ptr_kinds_commutes local.get_root_node_root_in_heap by blast next case False have "known_ptr root" using "0" "1" "2" local.get_root_node_root_in_heap local.known_ptrs_known_ptr root by blast have "root |\| object_ptr_kinds h" using root using "0" "1" "2" local.get_root_node_root_in_heap by blast then have "is_node_ptr_kind root" using False \known_ptr root\ apply(simp add: known_ptr_impl known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs) using is_node_ptr_kind_none by force then have "(\document_ptr \ fset (document_ptr_kinds h). root \ cast ` set |h \ get_disconnected_nodes document_ptr|\<^sub>r)" by (metis (no_types, lifting) "0" "1" "2" \root |\| object_ptr_kinds h\ local.child_parent_dual local.get_child_nodes_ok local.get_root_node_same_no_parent local.heap_is_wellformed_children_disc_nodes local.known_ptrs_known_ptr node_ptr_casts_commute3 node_ptr_inclusion node_ptr_kinds_commutes notin_fset option.distinct(1) returns_result_eq returns_result_select_result root) then obtain some_owner_document where "some_owner_document |\| document_ptr_kinds h" and "root \ cast ` set |h \ get_disconnected_nodes some_owner_document|\<^sub>r" by auto then obtain candidates where candidates: "h \ filter_M (\document_ptr. Heap_Error_Monad.bind (get_disconnected_nodes document_ptr) (\disconnected_nodes. return (root \ cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ` set disconnected_nodes))) (sorted_list_of_set (fset (document_ptr_kinds h))) \\<^sub>r candidates" by (metis (no_types, lifting) "1" bind_is_OK_I2 bind_pure_I filter_M_is_OK_I finite_fset is_OK_returns_result_E local.get_disconnected_nodes_ok local.get_disconnected_nodes_pure notin_fset return_ok return_pure sorted_list_of_set(1)) then have "some_owner_document \ set candidates" apply(rule filter_M_in_result_if_ok) using \some_owner_document |\| document_ptr_kinds h\ \root \ cast ` set |h \ get_disconnected_nodes some_owner_document|\<^sub>r\ apply(auto intro!: bind_pure_I bind_pure_returns_result_I)[1] apply (simp add: \some_owner_document |\| document_ptr_kinds h\) using "1" \root \ cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ` set |h \ get_disconnected_nodes some_owner_document|\<^sub>r\ \some_owner_document |\| document_ptr_kinds h\ local.get_disconnected_nodes_ok by auto then have "candidates \ []" by auto then have "owner_document \ set candidates" using 5 root 4 apply(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 intro!: filter_M_pure_I bind_pure_I split: option.splits)[1] apply (metis candidates list.set_sel(1) returns_result_eq) by (metis \is_node_ptr_kind root\ node_ptr_no_document_ptr_cast returns_result_eq) then show ?thesis using candidates by (meson bind_pure_I bind_returns_result_E2 filter_M_holds_for_result is_OK_returns_result_I local.get_disconnected_nodes_ptr_in_heap local.get_disconnected_nodes_pure return_pure) qed next assume 0: "heap_is_wellformed h" and 1: "type_wf h" and 2: "known_ptrs h" and 3: "is_element_ptr\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr" and 4: "h \ Heap_Error_Monad.bind (check_in_heap ptr) (\_. (local.a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r \ the \ cast\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r) ptr ()) \\<^sub>r owner_document" then obtain root where root: "h \ get_root_node ptr \\<^sub>r root" by(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 split: option.splits) then show ?thesis proof (cases "is_document_ptr root") case True then show ?thesis using 3 4 root apply(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 intro!: filter_M_pure_I bind_pure_I split: option.splits)[1] apply(drule(1) returns_result_eq) apply(auto)[1] using "0" "1" "2" document_ptr_kinds_commutes local.get_root_node_root_in_heap by blast next case False have "known_ptr root" using "0" "1" "2" local.get_root_node_root_in_heap local.known_ptrs_known_ptr root by blast have "root |\| object_ptr_kinds h" using root using "0" "1" "2" local.get_root_node_root_in_heap by blast then have "is_node_ptr_kind root" using False \known_ptr root\ apply(simp add: known_ptr_impl known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs) using is_node_ptr_kind_none by force then have "(\document_ptr \ fset (document_ptr_kinds h). root \ cast ` set |h \ get_disconnected_nodes document_ptr|\<^sub>r)" by (metis (no_types, lifting) "0" "1" "2" \root |\| object_ptr_kinds h\ local.child_parent_dual local.get_child_nodes_ok local.get_root_node_same_no_parent local.heap_is_wellformed_children_disc_nodes local.known_ptrs_known_ptr node_ptr_casts_commute3 node_ptr_inclusion node_ptr_kinds_commutes notin_fset option.distinct(1) returns_result_eq returns_result_select_result root) then obtain some_owner_document where "some_owner_document |\| document_ptr_kinds h" and "root \ cast ` set |h \ get_disconnected_nodes some_owner_document|\<^sub>r" by auto then obtain candidates where candidates: "h \ filter_M (\document_ptr. Heap_Error_Monad.bind (get_disconnected_nodes document_ptr) (\disconnected_nodes. return (root \ cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ` set disconnected_nodes))) (sorted_list_of_set (fset (document_ptr_kinds h))) \\<^sub>r candidates" by (metis (no_types, lifting) "1" bind_is_OK_I2 bind_pure_I filter_M_is_OK_I finite_fset is_OK_returns_result_E local.get_disconnected_nodes_ok local.get_disconnected_nodes_pure notin_fset return_ok return_pure sorted_list_of_set(1)) then have "some_owner_document \ set candidates" apply(rule filter_M_in_result_if_ok) using \some_owner_document |\| document_ptr_kinds h\ \root \ cast ` set |h \ get_disconnected_nodes some_owner_document|\<^sub>r\ apply(auto intro!: bind_pure_I bind_pure_returns_result_I)[1] using \some_owner_document |\| document_ptr_kinds h\ \root \ cast ` set |h \ get_disconnected_nodes some_owner_document|\<^sub>r\ apply(auto intro!: bind_pure_I bind_pure_returns_result_I)[1] using \some_owner_document |\| document_ptr_kinds h\ \root \ cast ` set |h \ get_disconnected_nodes some_owner_document|\<^sub>r\ apply(auto intro!: bind_pure_I bind_pure_returns_result_I)[1] by (simp add: "1" local.get_disconnected_nodes_ok) then have "candidates \ []" by auto then have "owner_document \ set candidates" using 4 root 3 apply(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 intro!: filter_M_pure_I bind_pure_I split: option.splits)[1] apply (metis candidates list.set_sel(1) returns_result_eq) by (metis \is_node_ptr_kind root\ node_ptr_no_document_ptr_cast returns_result_eq) then show ?thesis using candidates by (meson bind_pure_I bind_returns_result_E2 filter_M_holds_for_result is_OK_returns_result_I local.get_disconnected_nodes_ptr_in_heap local.get_disconnected_nodes_pure return_pure) qed qed lemma get_owner_document_ok: assumes "heap_is_wellformed h" "known_ptrs h" "type_wf h" assumes "ptr |\| object_ptr_kinds h" shows "h \ ok (get_owner_document ptr)" proof - have "known_ptr ptr" using assms(2) assms(4) local.known_ptrs_known_ptr by blast then show ?thesis apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits, (rule conjI | rule impI)+)+ apply(auto simp add: known_ptr_impl)[1] using NodeClass.a_known_ptr_def known_ptr_not_character_data_ptr known_ptr_not_document_ptr known_ptr_not_element_ptr apply blast using assms(4) apply(auto simp add: a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def intro!: bind_is_OK_pure_I)[1] apply (metis (no_types, lifting) document_ptr_casts_commute3 document_ptr_kinds_commutes is_document_ptr_kind_none option.case_eq_if) using assms(4) apply(auto simp add: a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def intro!: bind_is_OK_pure_I)[1] apply (metis (no_types, lifting) assms(1) assms(2) assms(3) is_node_ptr_kind_none local.get_root_node_ok node_ptr_casts_commute3 option.case_eq_if) using assms(4) apply(auto simp add: a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def intro!: bind_is_OK_pure_I)[1] apply(auto split: option.splits intro!: bind_is_OK_pure_I filter_M_pure_I bind_pure_I filter_M_is_OK_I)[1] using assms(3) local.get_disconnected_nodes_ok apply blast apply (simp add: assms(1) assms(2) assms(3) local.get_root_node_ok) using assms(4) apply(auto simp add: a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def intro!: bind_is_OK_pure_I)[1] apply(auto split: option.splits intro!: bind_is_OK_pure_I filter_M_pure_I bind_pure_I filter_M_is_OK_I)[1] apply (simp add: assms(1) assms(2) assms(3) local.get_root_node_ok)[1] apply(auto split: option.splits intro!: bind_is_OK_pure_I filter_M_pure_I bind_pure_I filter_M_is_OK_I)[1] using assms(3) local.get_disconnected_nodes_ok by blast qed lemma get_owner_document_child_same: assumes "heap_is_wellformed h" "known_ptrs h" "type_wf h" assumes "h \ get_child_nodes ptr \\<^sub>r children" assumes "child \ set children" shows "h \ get_owner_document ptr \\<^sub>r owner_document \ h \ get_owner_document (cast child) \\<^sub>r owner_document" proof - have "ptr |\| object_ptr_kinds h" by (meson assms(4) is_OK_returns_result_I local.get_child_nodes_ptr_in_heap) then have "known_ptr ptr" using assms(2) local.known_ptrs_known_ptr by blast have "cast child |\| object_ptr_kinds h" using assms(1) assms(4) assms(5) local.heap_is_wellformed_children_in_heap node_ptr_kinds_commutes by blast then have "known_ptr (cast child)" using assms(2) local.known_ptrs_known_ptr by blast obtain root where root: "h \ get_root_node ptr \\<^sub>r root" by (meson \ptr |\| object_ptr_kinds h\ assms(1) assms(2) assms(3) is_OK_returns_result_E local.get_root_node_ok) then have "h \ get_root_node (cast child) \\<^sub>r root" using assms(1) assms(2) assms(3) assms(4) assms(5) local.child_parent_dual local.get_root_node_parent_same by blast have "h \ get_owner_document ptr \\<^sub>r owner_document \ h \ a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child () \\<^sub>r owner_document" proof (cases "is_document_ptr ptr") case True then obtain document_ptr where document_ptr: "cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r document_ptr = ptr" using case_optionE document_ptr_casts_commute by blast then have "root = cast document_ptr" using root by(auto simp add: get_root_node_def get_ancestors_def elim!: bind_returns_result_E2 split: option.splits) then have "h \ a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r document_ptr () \\<^sub>r owner_document \ h \ a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child () \\<^sub>r owner_document" using document_ptr \h \ get_root_node (cast child) \\<^sub>r root\[simplified \root = cast document_ptr\ document_ptr] apply(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 dest!: bind_returns_result_E3[rotated, OF \h \ get_root_node (cast child) \\<^sub>r root\ [simplified \root = cast document_ptr\ document_ptr], rotated] intro!: bind_pure_returns_result_I filter_M_pure_I bind_pure_I split: if_splits option.splits)[1] using \ptr |\| object_ptr_kinds h\ document_ptr_kinds_commutes by blast then show ?thesis using \known_ptr ptr\ apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def known_ptr_impl)[1] apply(split invoke_splits, ((rule conjI | rule impI)+)?)+ apply(drule(1) known_ptr_not_document_ptr[folded known_ptr_impl]) apply(drule(1) known_ptr_not_character_data_ptr) apply(drule(1) known_ptr_not_element_ptr) apply(simp add: NodeClass.known_ptr_defs) using \ptr |\| object_ptr_kinds h\ True by(auto simp add: document_ptr[symmetric] intro!: bind_pure_returns_result_I split: option.splits) next case False then obtain node_ptr where node_ptr: "cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr = ptr" using \known_ptr ptr\ by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) then have "h \ a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr () \\<^sub>r owner_document \ h \ a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child () \\<^sub>r owner_document" using root \h \ get_root_node (cast child) \\<^sub>r root\ unfolding a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def by (meson bind_pure_returns_result_I bind_returns_result_E3 local.get_root_node_pure) then show ?thesis using \known_ptr ptr\ apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def known_ptr_impl)[1] apply(split invoke_splits, ((rule conjI | rule impI)+)?)+ apply(drule(1) known_ptr_not_document_ptr[folded known_ptr_impl]) apply(drule(1) known_ptr_not_character_data_ptr) apply(drule(1) known_ptr_not_element_ptr) apply(simp add: NodeClass.known_ptr_defs) using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ False apply(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ False apply(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ False apply(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ False apply(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] apply(split invoke_splits, ((rule conjI | rule impI)+)?)+ apply(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] apply (meson invoke_empty is_OK_returns_result_I) apply(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] apply(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] by(auto simp add: node_ptr[symmetric] intro!: bind_pure_returns_result_I split: )[1] qed then show ?thesis using \known_ptr (cast child)\ apply(auto simp add: get_owner_document_def[of "cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child"] a_get_owner_document_tups_def known_ptr_impl)[1] apply(split invoke_splits, ((rule conjI | rule impI)+)?)+ apply(drule(1) known_ptr_not_document_ptr[folded known_ptr_impl]) apply(drule(1) known_ptr_not_character_data_ptr) apply(drule(1) known_ptr_not_element_ptr) apply(simp add: NodeClass.known_ptr_defs) using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ apply(auto intro!: bind_pure_returns_result_I split: option.splits)[1] using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ apply(auto intro!: bind_pure_returns_result_I split: option.splits)[1] using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ apply(auto intro!: bind_pure_returns_result_I split: option.splits)[1] using \cast child |\| object_ptr_kinds h\ \ptr |\| object_ptr_kinds h\ apply(auto intro!: bind_pure_returns_result_I split: option.splits)[1] by (smt \cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child |\| object_ptr_kinds h\ cast_document_ptr_not_node_ptr(1) comp_apply invoke_empty invoke_not invoke_returns_result is_OK_returns_result_I node_ptr_casts_commute2 option.sel) qed end locale l_get_owner_document_wf = l_heap_is_wellformed_defs + l_type_wf + l_known_ptrs + l_get_disconnected_nodes_defs + l_get_owner_document_defs + l_get_parent_defs + assumes get_owner_document_disconnected_nodes: "heap_is_wellformed h \ known_ptrs h \ type_wf h \ h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes \ node_ptr \ set disc_nodes \ h \ get_owner_document (cast node_ptr) \\<^sub>r document_ptr" assumes in_disconnected_nodes_no_parent: "heap_is_wellformed h \ h \ get_parent node_ptr \\<^sub>r None\ h \ get_owner_document (cast node_ptr) \\<^sub>r owner_document \ h \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes \ known_ptrs h \ type_wf h\ node_ptr \ set disc_nodes" assumes get_owner_document_owner_document_in_heap: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_owner_document ptr \\<^sub>r owner_document \ owner_document |\| document_ptr_kinds h" assumes get_owner_document_ok: "heap_is_wellformed h \ known_ptrs h \ type_wf h \ ptr |\| object_ptr_kinds h \ h \ ok (get_owner_document ptr)" interpretation i_get_owner_document_wf?: l_get_owner_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr known_ptrs type_wf heap_is_wellformed parent_child_rel get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs get_parent get_parent_locs get_ancestors get_ancestors_locs get_root_node get_root_node_locs get_owner_document by(auto simp add: l_get_owner_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) declare l_get_owner_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] lemma get_owner_document_wf_is_l_get_owner_document_wf [instances]: "l_get_owner_document_wf heap_is_wellformed type_wf known_ptr known_ptrs get_disconnected_nodes get_owner_document get_parent" using known_ptrs_is_l_known_ptrs apply(auto simp add: l_get_owner_document_wf_def l_get_owner_document_wf_axioms_def)[1] using get_owner_document_disconnected_nodes apply fast using in_disconnected_nodes_no_parent apply fast using get_owner_document_owner_document_in_heap apply fast using get_owner_document_ok apply fast done subsubsection \get\_root\_node\ locale l_get_owner_document_wf_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_get_root_node\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_root_node_wf + l_get_owner_document\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_owner_document_wf begin lemma get_root_node_document: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_root_node ptr \\<^sub>r root" assumes "is_document_ptr_kind root" shows "h \ get_owner_document ptr \\<^sub>r the (cast root)" proof - have "ptr |\| object_ptr_kinds h" using assms(4) by (meson is_OK_returns_result_I local.get_root_node_ptr_in_heap) then have "known_ptr ptr" using assms(3) local.known_ptrs_known_ptr by blast { assume "is_document_ptr_kind ptr" then have "ptr = root" using assms(4) by(auto simp add: get_root_node_def get_ancestors_def elim!: bind_returns_result_E2 split: option.splits) then have ?thesis using \is_document_ptr_kind ptr\ \known_ptr ptr\ \ptr |\| object_ptr_kinds h\ apply(auto simp add: known_ptr_impl get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits, (rule conjI | rule impI)+)+ apply(drule(1) known_ptr_not_document_ptr[folded known_ptr_impl]) apply(drule(1) known_ptr_not_character_data_ptr) apply(drule(1) known_ptr_not_element_ptr) apply(simp add: NodeClass.known_ptr_defs) by(auto simp add: a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def intro!: bind_pure_returns_result_I split: option.splits) } moreover { assume "is_node_ptr_kind ptr" then have ?thesis using \known_ptr ptr\ \ptr |\| object_ptr_kinds h\ apply(auto simp add: known_ptr_impl get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits, (rule conjI | rule impI)+)+ apply(drule(1) known_ptr_not_document_ptr[folded known_ptr_impl]) apply(drule(1) known_ptr_not_character_data_ptr) apply(drule(1) known_ptr_not_element_ptr) apply(simp add: NodeClass.known_ptr_defs) apply(auto split: option.splits)[1] using \h \ get_root_node ptr \\<^sub>r root\ assms(5) by(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def is_document_ptr_kind_def intro!: bind_pure_returns_result_I split: option.splits)[2] } ultimately show ?thesis using \known_ptr ptr\ by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) qed lemma get_root_node_same_owner_document: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_root_node ptr \\<^sub>r root" shows "h \ get_owner_document ptr \\<^sub>r owner_document \ h \ get_owner_document root \\<^sub>r owner_document" proof - have "ptr |\| object_ptr_kinds h" by (meson assms(4) is_OK_returns_result_I local.get_root_node_ptr_in_heap) have "root |\| object_ptr_kinds h" using assms(1) assms(2) assms(3) assms(4) local.get_root_node_root_in_heap by blast have "known_ptr ptr" using \ptr |\| object_ptr_kinds h\ assms(3) local.known_ptrs_known_ptr by blast have "known_ptr root" using \root |\| object_ptr_kinds h\ assms(3) local.known_ptrs_known_ptr by blast show ?thesis proof (cases "is_document_ptr_kind ptr") case True then have "ptr = root" using assms(4) apply(auto simp add: get_root_node_def elim!: bind_returns_result_E2)[1] by (metis document_ptr_casts_commute3 last_ConsL local.get_ancestors_not_node node_ptr_no_document_ptr_cast) then show ?thesis by auto next case False then have "is_node_ptr_kind ptr" using \known_ptr ptr\ by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) then obtain node_ptr where node_ptr: "ptr = cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr" by (metis node_ptr_casts_commute3) show ?thesis proof assume "h \ get_owner_document ptr \\<^sub>r owner_document" then have "h \ local.a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr () \\<^sub>r owner_document" using node_ptr apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits)+ apply (meson invoke_empty is_OK_returns_result_I) by(auto elim!: bind_returns_result_E2 split: option.splits) show "h \ get_owner_document root \\<^sub>r owner_document" proof (cases "is_document_ptr_kind root") case True have "is_document_ptr root" using True \known_ptr root\ by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) have "root = cast owner_document" using True by (smt \h \ get_owner_document ptr \\<^sub>r owner_document\ assms(1) assms(2) assms(3) assms(4) document_ptr_casts_commute3 get_root_node_document returns_result_eq) then show ?thesis apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits, (rule conjI | rule impI)+)+ using \is_document_ptr\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r root\ apply blast using \root |\| object_ptr_kinds h\ by(auto simp add: a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def is_node_ptr_kind_none) next case False then have "is_node_ptr_kind root" using \known_ptr root\ by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) then obtain root_node_ptr where root_node_ptr: "root = cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r root_node_ptr" by (metis node_ptr_casts_commute3) then have "h \ local.a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r root_node_ptr () \\<^sub>r owner_document" using \h \ local.a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr () \\<^sub>r owner_document\ assms(4) apply(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 intro!: bind_pure_returns_result_I filter_M_pure_I bind_pure_I split: option.splits)[1] apply (metis assms(1) assms(2) assms(3) local.get_root_node_no_parent local.get_root_node_same_no_parent node_ptr returns_result_eq) using \is_node_ptr_kind root\ node_ptr returns_result_eq by fastforce then show ?thesis apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits, (rule conjI | rule impI)+)+ using \is_node_ptr_kind root\ \known_ptr root\ apply(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits)[1] apply(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits)[1] using \root |\| object_ptr_kinds h\ by(auto simp add: root_node_ptr) qed next assume "h \ get_owner_document root \\<^sub>r owner_document" show "h \ get_owner_document ptr \\<^sub>r owner_document" proof (cases "is_document_ptr_kind root") case True have "root = cast owner_document" using \h \ get_owner_document root \\<^sub>r owner_document\ apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits)+ apply (meson invoke_empty is_OK_returns_result_I) apply(auto simp add: True a_get_owner_document\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 split: if_splits)[1] apply (metis True cast_document_ptr_not_node_ptr(2) is_document_ptr_kind_obtains is_node_ptr_kind_none node_ptr_casts_commute3 option.case_eq_if) by (metis True cast_document_ptr_not_node_ptr(1) document_ptr_casts_commute3 is_node_ptr_kind_none node_ptr_casts_commute3 option.case_eq_if) then show ?thesis using assms(1) assms(2) assms(3) assms(4) get_root_node_document by fastforce next case False then have "is_node_ptr_kind root" using \known_ptr root\ by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) then obtain root_node_ptr where root_node_ptr: "root = cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r root_node_ptr" by (metis node_ptr_casts_commute3) then have "h \ local.a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r root_node_ptr () \\<^sub>r owner_document" using \h \ get_owner_document root \\<^sub>r owner_document\ apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits)+ apply (meson invoke_empty is_OK_returns_result_I) by(auto simp add: is_document_ptr_kind_none elim!: bind_returns_result_E2) then have "h \ local.a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r node_ptr () \\<^sub>r owner_document" apply(auto simp add: a_get_owner_document\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 intro!: bind_pure_returns_result_I filter_M_pure_I bind_pure_I split: option.splits)[1] using assms(1) assms(2) assms(3) assms(4) local.get_root_node_no_parent local.get_root_node_same_no_parent node_ptr returns_result_eq root_node_ptr by fastforce+ then show ?thesis apply(auto simp add: get_owner_document_def a_get_owner_document_tups_def)[1] apply(split invoke_splits, (rule conjI | rule impI)+)+ using node_ptr \known_ptr ptr\ \ptr |\| object_ptr_kinds h\ by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs intro!: bind_pure_returns_result_I split: option.splits) qed qed qed qed end interpretation get_owner_document_wf_get_root_node_wf?: l_get_owner_document_wf_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M type_wf known_ptr known_ptrs get_parent get_parent_locs get_child_nodes get_child_nodes_locs get_ancestors get_ancestors_locs get_root_node get_root_node_locs heap_is_wellformed parent_child_rel get_disconnected_nodes get_disconnected_nodes_locs get_owner_document by(auto simp add: l_get_owner_document_wf_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) declare l_get_owner_document_wf_get_root_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] locale l_get_owner_document_wf_get_root_node_wf = l_heap_is_wellformed_defs + l_type_wf + l_known_ptrs + l_get_root_node_defs + l_get_owner_document_defs + assumes get_root_node_document: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_root_node ptr \\<^sub>r root \ is_document_ptr_kind root \ h \ get_owner_document ptr \\<^sub>r the (cast root)" assumes get_root_node_same_owner_document: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_root_node ptr \\<^sub>r root \ h \ get_owner_document ptr \\<^sub>r owner_document \ h \ get_owner_document root \\<^sub>r owner_document" lemma get_owner_document_wf_get_root_node_wf_is_l_get_owner_document_wf_get_root_node_wf [instances]: "l_get_owner_document_wf_get_root_node_wf heap_is_wellformed type_wf known_ptr known_ptrs get_root_node get_owner_document" apply(auto simp add: l_get_owner_document_wf_get_root_node_wf_def l_get_owner_document_wf_get_root_node_wf_axioms_def instances)[1] using get_root_node_document apply blast using get_root_node_same_owner_document apply (blast, blast) done subsection \Preserving heap-wellformedness\ subsection \set\_attribute\ locale l_set_attribute_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_get_parent_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_set_attribute\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_set_attribute_get_disconnected_nodes + l_set_attribute_get_child_nodes begin lemma set_attribute_preserves_wellformedness: assumes "heap_is_wellformed h" and "h \ set_attribute element_ptr k v \\<^sub>h h'" shows "heap_is_wellformed h'" thm preserves_wellformedness_writes_needed apply(rule preserves_wellformedness_writes_needed[OF assms set_attribute_writes]) using set_attribute_get_child_nodes apply(fast) using set_attribute_get_disconnected_nodes apply(fast) by(auto simp add: all_args_def set_attribute_locs_def) end subsection \remove\_child\ locale l_remove_child_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_remove_child\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_heap_is_wellformed + l_set_disconnected_nodes_get_child_nodes begin lemma remove_child_removes_parent: assumes wellformed: "heap_is_wellformed h" and remove_child: "h \ remove_child ptr child \\<^sub>h h2" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "h2 \ get_parent child \\<^sub>r None" proof - obtain children where children: "h \ get_child_nodes ptr \\<^sub>r children" using remove_child remove_child_def by auto then have "child \ set children" using remove_child remove_child_def by(auto elim!: bind_returns_heap_E dest: returns_result_eq split: if_splits) then have h1: "\other_ptr other_children. other_ptr \ ptr \ h \ get_child_nodes other_ptr \\<^sub>r other_children \ child \ set other_children" using assms(1) known_ptrs type_wf child_parent_dual by (meson child_parent_dual children option.inject returns_result_eq) have known_ptr: "known_ptr ptr" using known_ptrs by (meson is_OK_returns_heap_I l_known_ptrs.known_ptrs_known_ptr l_known_ptrs_axioms remove_child remove_child_ptr_in_heap) obtain owner_document disc_nodes h' where owner_document: "h \ get_owner_document (cast child) \\<^sub>r owner_document" and disc_nodes: "h \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes" and h': "h \ set_disconnected_nodes owner_document (child # disc_nodes) \\<^sub>h h'" and h2: "h' \ set_child_nodes ptr (remove1 child children) \\<^sub>h h2" using assms children unfolding remove_child_def apply(auto split: if_splits elim!: bind_returns_heap_E)[1] by (metis (full_types) get_child_nodes_pure get_disconnected_nodes_pure get_owner_document_pure pure_returns_heap_eq returns_result_eq) have "object_ptr_kinds h = object_ptr_kinds h2" using remove_child_writes remove_child unfolding remove_child_locs_def apply(rule writes_small_big) using set_disconnected_nodes_pointers_preserved set_child_nodes_pointers_preserved by(auto simp add: reflp_def transp_def) then have "|h \ object_ptr_kinds_M|\<^sub>r = |h2 \ object_ptr_kinds_M|\<^sub>r" unfolding object_ptr_kinds_M_defs by simp have "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h'] using set_disconnected_nodes_types_preserved type_wf by(auto simp add: reflp_def transp_def) have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF remove_child_writes remove_child] unfolding remove_child_locs_def using set_disconnected_nodes_types_preserved set_child_nodes_types_preserved type_wf apply(auto simp add: reflp_def transp_def)[1] by blast then obtain children' where children': "h2 \ get_child_nodes ptr \\<^sub>r children'" using h2 set_child_nodes_get_child_nodes known_ptr by (metis \object_ptr_kinds h = object_ptr_kinds h2\ children get_child_nodes_ok get_child_nodes_ptr_in_heap is_OK_returns_result_E is_OK_returns_result_I) have "child \ set children'" by (metis (mono_tags, lifting) \type_wf h'\ children children' distinct_remove1_removeAll h2 known_ptr local.heap_is_wellformed_children_distinct local.set_child_nodes_get_child_nodes member_remove remove_code(1) select_result_I2 wellformed) moreover have "\other_ptr other_children. other_ptr \ ptr \ h' \ get_child_nodes other_ptr \\<^sub>r other_children \ child \ set other_children" proof - fix other_ptr other_children assume a1: "other_ptr \ ptr" and a3: "h' \ get_child_nodes other_ptr \\<^sub>r other_children" have "h \ get_child_nodes other_ptr \\<^sub>r other_children" using get_child_nodes_reads set_disconnected_nodes_writes h' a3 apply(rule reads_writes_separate_backwards) using set_disconnected_nodes_get_child_nodes by fast show "child \ set other_children" using \h \ get_child_nodes other_ptr \\<^sub>r other_children\ a1 h1 by blast qed then have "\other_ptr other_children. other_ptr \ ptr \ h2 \ get_child_nodes other_ptr \\<^sub>r other_children \ child \ set other_children" proof - fix other_ptr other_children assume a1: "other_ptr \ ptr" and a3: "h2 \ get_child_nodes other_ptr \\<^sub>r other_children" have "h' \ get_child_nodes other_ptr \\<^sub>r other_children" using get_child_nodes_reads set_child_nodes_writes h2 a3 apply(rule reads_writes_separate_backwards) using set_disconnected_nodes_get_child_nodes a1 set_child_nodes_get_child_nodes_different_pointers by metis then show "child \ set other_children" using \\other_ptr other_children. \other_ptr \ ptr; h' \ get_child_nodes other_ptr \\<^sub>r other_children\ \ child \ set other_children\ a1 by blast qed ultimately have ha: "\other_ptr other_children. h2 \ get_child_nodes other_ptr \\<^sub>r other_children \ child \ set other_children" by (metis (full_types) children' returns_result_eq) moreover obtain ptrs where ptrs: "h2 \ object_ptr_kinds_M \\<^sub>r ptrs" by (simp add: object_ptr_kinds_M_defs) moreover have "\ptr. ptr \ set ptrs \ h2 \ ok (get_child_nodes ptr)" using \type_wf h2\ ptrs get_child_nodes_ok known_ptr using \object_ptr_kinds h = object_ptr_kinds h2\ known_ptrs local.known_ptrs_known_ptr by auto ultimately show "h2 \ get_parent child \\<^sub>r None" apply(auto simp add: get_parent_def intro!: bind_pure_returns_result_I filter_M_pure_I bind_pure_I)[1] proof - have "cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child |\| object_ptr_kinds h" using get_owner_document_ptr_in_heap owner_document by blast then show "h2 \ check_in_heap (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r ()" by (simp add: \object_ptr_kinds h = object_ptr_kinds h2\ check_in_heap_def) next show "(\other_ptr other_children. h2 \ get_child_nodes other_ptr \\<^sub>r other_children \ child \ set other_children) \ ptrs = sorted_list_of_set (fset (object_ptr_kinds h2)) \ (\ptr. ptr |\| object_ptr_kinds h2 \ h2 \ ok get_child_nodes ptr) \ h2 \ filter_M (\ptr. Heap_Error_Monad.bind (get_child_nodes ptr) (\children. return (child \ set children))) (sorted_list_of_set (fset (object_ptr_kinds h2))) \\<^sub>r []" by(auto intro!: filter_M_empty_I bind_pure_I) qed qed end locale l_remove_child_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_remove_child_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M begin lemma remove_child_parent_child_rel_subset: assumes "heap_is_wellformed h" and "h \ remove_child ptr child \\<^sub>h h'" and "known_ptrs h" and type_wf: "type_wf h" shows "parent_child_rel h' \ parent_child_rel h" proof (standard, safe) obtain owner_document children_h h2 disconnected_nodes_h where owner_document: "h \ get_owner_document (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r owner_document" and children_h: "h \ get_child_nodes ptr \\<^sub>r children_h" and child_in_children_h: "child \ set children_h" and disconnected_nodes_h: "h \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h" and h2: "h \ set_disconnected_nodes owner_document (child # disconnected_nodes_h) \\<^sub>h h2" and h': "h2 \ set_child_nodes ptr (remove1 child children_h) \\<^sub>h h'" using assms(2) apply(auto simp add: remove_child_def elim!: bind_returns_heap_E dest!: pure_returns_heap_eq[rotated, OF get_owner_document_pure] pure_returns_heap_eq[rotated, OF get_child_nodes_pure] split: if_splits)[1] using pure_returns_heap_eq by fastforce have object_ptr_kinds_eq3: "object_ptr_kinds h = object_ptr_kinds h'" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_child_writes assms(2)]) unfolding remove_child_locs_def using set_disconnected_nodes_pointers_preserved set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_eq: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" unfolding object_ptr_kinds_M_defs by simp then have object_ptr_kinds_eq2: "|h \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" using select_result_eq by force then have node_ptr_kinds_eq2: "|h \ node_ptr_kinds_M|\<^sub>r = |h' \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by auto then have node_ptr_kinds_eq3: "node_ptr_kinds h = node_ptr_kinds h'" using node_ptr_kinds_M_eq by auto have document_ptr_kinds_eq2: "|h \ document_ptr_kinds_M|\<^sub>r = |h' \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_eq2 document_ptr_kinds_M_eq by auto then have document_ptr_kinds_eq3: "document_ptr_kinds h = document_ptr_kinds h'" using document_ptr_kinds_M_eq by auto have children_eq: "\ptr' children. ptr \ ptr' \ h \ get_child_nodes ptr' \\<^sub>r children =h' \ get_child_nodes ptr' \\<^sub>r children" apply(rule reads_writes_preserved[OF get_child_nodes_reads remove_child_writes assms(2)]) unfolding remove_child_locs_def using set_disconnected_nodes_get_child_nodes set_child_nodes_get_child_nodes_different_pointers by fast then have children_eq2: "\ptr' children. ptr \ ptr' \ |h \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq: "\document_ptr disconnected_nodes. document_ptr \ owner_document \ h \ get_disconnected_nodes document_ptr \\<^sub>r disconnected_nodes = h' \ get_disconnected_nodes document_ptr \\<^sub>r disconnected_nodes" apply(rule reads_writes_preserved[OF get_disconnected_nodes_reads remove_child_writes assms(2)]) unfolding remove_child_locs_def using set_child_nodes_get_disconnected_nodes set_disconnected_nodes_get_disconnected_nodes_different_pointers by (metis (no_types, lifting) Un_iff owner_document select_result_I2) then have disconnected_nodes_eq2: "\document_ptr. document_ptr \ owner_document \ |h \ get_disconnected_nodes document_ptr|\<^sub>r = |h' \ get_disconnected_nodes document_ptr|\<^sub>r" using select_result_eq by force have "h2 \ get_child_nodes ptr \\<^sub>r children_h" apply(rule reads_writes_separate_forwards[OF get_child_nodes_reads set_disconnected_nodes_writes h2 children_h] ) by (simp add: set_disconnected_nodes_get_child_nodes) have "known_ptr ptr" using assms(3) using children_h get_child_nodes_ptr_in_heap local.known_ptrs_known_ptr by blast have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h2] using set_disconnected_nodes_types_preserved type_wf by(auto simp add: reflp_def transp_def) then have "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_child_nodes_writes h'] using set_child_nodes_types_preserved by(auto simp add: reflp_def transp_def) have children_h': "h' \ get_child_nodes ptr \\<^sub>r remove1 child children_h" using assms(2) owner_document h2 disconnected_nodes_h children_h apply(auto simp add: remove_child_def split: if_splits)[1] apply(drule bind_returns_heap_E3) apply(auto split: if_splits)[1] apply(simp) apply(auto split: if_splits)[1] apply(drule bind_returns_heap_E3) apply(auto)[1] apply(simp) apply(drule bind_returns_heap_E3) apply(auto)[1] apply(simp) apply(drule bind_returns_heap_E4) apply(auto)[1] apply(simp) using \type_wf h2\ set_child_nodes_get_child_nodes \known_ptr ptr\ h' by blast fix parent child assume a1: "(parent, child) \ parent_child_rel h'" then show "(parent, child) \ parent_child_rel h" proof (cases "parent = ptr") case True then show ?thesis using a1 remove_child_removes_parent[OF assms(1) assms(2)] children_h children_h' get_child_nodes_ptr_in_heap apply(auto simp add: parent_child_rel_def object_ptr_kinds_eq )[1] by (metis notin_set_remove1) next case False then show ?thesis using a1 by(auto simp add: parent_child_rel_def object_ptr_kinds_eq3 children_eq2) qed qed lemma remove_child_heap_is_wellformed_preserved: assumes "heap_is_wellformed h" and "h \ remove_child ptr child \\<^sub>h h'" and "known_ptrs h" and type_wf: "type_wf h" shows "type_wf h'" and "known_ptrs h'" and "heap_is_wellformed h'" proof - obtain owner_document children_h h2 disconnected_nodes_h where owner_document: "h \ get_owner_document (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r owner_document" and children_h: "h \ get_child_nodes ptr \\<^sub>r children_h" and child_in_children_h: "child \ set children_h" and disconnected_nodes_h: "h \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h" and h2: "h \ set_disconnected_nodes owner_document (child # disconnected_nodes_h) \\<^sub>h h2" and h': "h2 \ set_child_nodes ptr (remove1 child children_h) \\<^sub>h h'" using assms(2) apply(auto simp add: remove_child_def elim!: bind_returns_heap_E dest!: pure_returns_heap_eq[rotated, OF get_owner_document_pure] pure_returns_heap_eq[rotated, OF get_child_nodes_pure] split: if_splits)[1] using pure_returns_heap_eq by fastforce have object_ptr_kinds_eq3: "object_ptr_kinds h = object_ptr_kinds h'" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_child_writes assms(2)]) unfolding remove_child_locs_def using set_disconnected_nodes_pointers_preserved set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_eq: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" unfolding object_ptr_kinds_M_defs by simp then have object_ptr_kinds_eq2: "|h \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" using select_result_eq by force then have node_ptr_kinds_eq2: "|h \ node_ptr_kinds_M|\<^sub>r = |h' \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by auto then have node_ptr_kinds_eq3: "node_ptr_kinds h = node_ptr_kinds h'" using node_ptr_kinds_M_eq by auto have document_ptr_kinds_eq2: "|h \ document_ptr_kinds_M|\<^sub>r = |h' \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_eq2 document_ptr_kinds_M_eq by auto then have document_ptr_kinds_eq3: "document_ptr_kinds h = document_ptr_kinds h'" using document_ptr_kinds_M_eq by auto have children_eq: "\ptr' children. ptr \ ptr' \ h \ get_child_nodes ptr' \\<^sub>r children = h' \ get_child_nodes ptr' \\<^sub>r children" apply(rule reads_writes_preserved[OF get_child_nodes_reads remove_child_writes assms(2)]) unfolding remove_child_locs_def using set_disconnected_nodes_get_child_nodes set_child_nodes_get_child_nodes_different_pointers by fast then have children_eq2: "\ptr' children. ptr \ ptr' \ |h \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq: "\document_ptr disconnected_nodes. document_ptr \ owner_document \ h \ get_disconnected_nodes document_ptr \\<^sub>r disconnected_nodes = h' \ get_disconnected_nodes document_ptr \\<^sub>r disconnected_nodes" apply(rule reads_writes_preserved[OF get_disconnected_nodes_reads remove_child_writes assms(2)]) unfolding remove_child_locs_def using set_child_nodes_get_disconnected_nodes set_disconnected_nodes_get_disconnected_nodes_different_pointers by (metis (no_types, lifting) Un_iff owner_document select_result_I2) then have disconnected_nodes_eq2: "\document_ptr. document_ptr \ owner_document \ |h \ get_disconnected_nodes document_ptr|\<^sub>r = |h' \ get_disconnected_nodes document_ptr|\<^sub>r" using select_result_eq by force have "h2 \ get_child_nodes ptr \\<^sub>r children_h" apply(rule reads_writes_separate_forwards[OF get_child_nodes_reads set_disconnected_nodes_writes h2 children_h] ) by (simp add: set_disconnected_nodes_get_child_nodes) show "known_ptrs h'" using object_ptr_kinds_eq3 known_ptrs_preserved \known_ptrs h\ by blast have "known_ptr ptr" using assms(3) using children_h get_child_nodes_ptr_in_heap local.known_ptrs_known_ptr by blast have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h2] using set_disconnected_nodes_types_preserved type_wf by(auto simp add: reflp_def transp_def) then show "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_child_nodes_writes h'] using set_child_nodes_types_preserved by(auto simp add: reflp_def transp_def) have children_h': "h' \ get_child_nodes ptr \\<^sub>r remove1 child children_h" using assms(2) owner_document h2 disconnected_nodes_h children_h apply(auto simp add: remove_child_def split: if_splits)[1] apply(drule bind_returns_heap_E3) apply(auto split: if_splits)[1] apply(simp) apply(auto split: if_splits)[1] apply(drule bind_returns_heap_E3) apply(auto)[1] apply(simp) apply(drule bind_returns_heap_E3) apply(auto)[1] apply(simp) apply(drule bind_returns_heap_E4) apply(auto)[1] apply simp using \type_wf h2\ set_child_nodes_get_child_nodes \known_ptr ptr\ h' by blast have disconnected_nodes_h2: "h2 \ get_disconnected_nodes owner_document \\<^sub>r child # disconnected_nodes_h" using owner_document assms(2) h2 disconnected_nodes_h apply (auto simp add: remove_child_def split: if_splits)[1] apply(drule bind_returns_heap_E2) apply(auto split: if_splits)[1] apply(simp) by(auto simp add: local.set_disconnected_nodes_get_disconnected_nodes split: if_splits) then have disconnected_nodes_h': "h' \ get_disconnected_nodes owner_document \\<^sub>r child # disconnected_nodes_h" apply(rule reads_writes_separate_forwards[OF get_disconnected_nodes_reads set_child_nodes_writes h']) by (simp add: set_child_nodes_get_disconnected_nodes) moreover have "a_acyclic_heap h" using assms(1) by (simp add: heap_is_wellformed_def) have "parent_child_rel h' \ parent_child_rel h" proof (standard, safe) fix parent child assume a1: "(parent, child) \ parent_child_rel h'" then show "(parent, child) \ parent_child_rel h" proof (cases "parent = ptr") case True then show ?thesis using a1 remove_child_removes_parent[OF assms(1) assms(2)] children_h children_h' get_child_nodes_ptr_in_heap apply(auto simp add: parent_child_rel_def object_ptr_kinds_eq )[1] by (metis imageI notin_set_remove1) next case False then show ?thesis using a1 by(auto simp add: parent_child_rel_def object_ptr_kinds_eq3 children_eq2) qed qed then have "a_acyclic_heap h'" using \a_acyclic_heap h\ acyclic_heap_def acyclic_subset by blast moreover have "a_all_ptrs_in_heap h" using assms(1) by (simp add: heap_is_wellformed_def) then have "a_all_ptrs_in_heap h'" apply(auto simp add: a_all_ptrs_in_heap_def node_ptr_kinds_eq3 disconnected_nodes_eq)[1] apply (metis (no_types, lifting) \type_wf h'\ assms(2) assms(3) local.get_child_nodes_ok local.known_ptrs_known_ptr local.remove_child_children_subset notin_fset object_ptr_kinds_eq3 returns_result_select_result subset_code(1) type_wf) apply (metis (no_types, lifting) assms(2) disconnected_nodes_eq2 disconnected_nodes_h disconnected_nodes_h' document_ptr_kinds_eq3 finite_set_in local.remove_child_child_in_heap node_ptr_kinds_eq3 select_result_I2 set_ConsD subset_code(1)) done moreover have "a_owner_document_valid h" using assms(1) by (simp add: heap_is_wellformed_def) then have "a_owner_document_valid h'" apply(auto simp add: a_owner_document_valid_def object_ptr_kinds_eq3 document_ptr_kinds_eq3 node_ptr_kinds_eq3)[1] proof - fix node_ptr assume 0: "\node_ptr\fset (node_ptr_kinds h'). (\document_ptr. document_ptr |\| document_ptr_kinds h' \ node_ptr \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r) \ (\parent_ptr. parent_ptr |\| object_ptr_kinds h' \ node_ptr \ set |h \ get_child_nodes parent_ptr|\<^sub>r)" and 1: "node_ptr |\| node_ptr_kinds h'" and 2: "\parent_ptr. parent_ptr |\| object_ptr_kinds h' \ node_ptr \ set |h' \ get_child_nodes parent_ptr|\<^sub>r" then show "\document_ptr. document_ptr |\| document_ptr_kinds h' \ node_ptr \ set |h' \ get_disconnected_nodes document_ptr|\<^sub>r" proof (cases "node_ptr = child") case True show ?thesis apply(rule exI[where x=owner_document]) using children_eq2 disconnected_nodes_eq2 children_h children_h' disconnected_nodes_h' True by (metis (no_types, lifting) get_disconnected_nodes_ptr_in_heap is_OK_returns_result_I list.set_intros(1) select_result_I2) next case False then show ?thesis using 0 1 2 children_eq2 children_h children_h' disconnected_nodes_eq2 disconnected_nodes_h disconnected_nodes_h' apply(auto simp add: children_eq2 disconnected_nodes_eq2 dest!: select_result_I2)[1] by (metis children_eq2 disconnected_nodes_eq2 finite_set_in in_set_remove1 list.set_intros(2)) qed qed moreover { have h0: "a_distinct_lists h" using assms(1) by (simp add: heap_is_wellformed_def) moreover have ha1: "(\x\set |h \ object_ptr_kinds_M|\<^sub>r. set |h \ get_child_nodes x|\<^sub>r) \ (\x\set |h \ document_ptr_kinds_M|\<^sub>r. set |h \ get_disconnected_nodes x|\<^sub>r) = {}" using \a_distinct_lists h\ unfolding a_distinct_lists_def by(auto) have ha2: "ptr |\| object_ptr_kinds h" using children_h get_child_nodes_ptr_in_heap by blast have ha3: "child \ set |h \ get_child_nodes ptr|\<^sub>r" using child_in_children_h children_h by(simp) have child_not_in: "\document_ptr. document_ptr |\| document_ptr_kinds h \ child \ set |h \ get_disconnected_nodes document_ptr|\<^sub>r" using ha1 ha2 ha3 apply(simp) using IntI by fastforce moreover have "distinct |h \ object_ptr_kinds_M|\<^sub>r" apply(rule select_result_I) by(auto simp add: object_ptr_kinds_M_defs) moreover have "distinct |h \ document_ptr_kinds_M|\<^sub>r" apply(rule select_result_I) by(auto simp add: document_ptr_kinds_M_defs) ultimately have "a_distinct_lists h'" proof(simp (no_asm) add: a_distinct_lists_def, safe) assume 1: "a_distinct_lists h" and 3: "distinct |h \ object_ptr_kinds_M|\<^sub>r" assume 1: "a_distinct_lists h" and 3: "distinct |h \ object_ptr_kinds_M|\<^sub>r" have 4: "distinct (concat ((map (\ptr. |h \ get_child_nodes ptr|\<^sub>r) |h \ object_ptr_kinds_M|\<^sub>r)))" using 1 by(auto simp add: a_distinct_lists_def) show "distinct (concat (map (\ptr. |h' \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h')))))" proof(rule distinct_concat_map_I[OF 3[unfolded object_ptr_kinds_eq2], simplified]) fix x assume 5: "x |\| object_ptr_kinds h'" then have 6: "distinct |h \ get_child_nodes x|\<^sub>r" using 4 distinct_concat_map_E object_ptr_kinds_eq2 by fastforce obtain children where children: "h \ get_child_nodes x \\<^sub>r children" and distinct_children: "distinct children" by (metis "5" "6" type_wf assms(3) get_child_nodes_ok local.known_ptrs_known_ptr object_ptr_kinds_eq3 select_result_I) obtain children' where children': "h' \ get_child_nodes x \\<^sub>r children'" using children children_eq children_h' by fastforce then have "distinct children'" proof (cases "ptr = x") case True then show ?thesis using children distinct_children children_h children_h' by (metis children' distinct_remove1 returns_result_eq) next case False then show ?thesis using children distinct_children children_eq[OF False] using children' distinct_lists_children h0 using select_result_I2 by fastforce qed then show "distinct |h' \ get_child_nodes x|\<^sub>r" using children' by(auto simp add: ) next fix x y assume 5: "x |\| object_ptr_kinds h'" and 6: "y |\| object_ptr_kinds h'" and 7: "x \ y" obtain children_x where children_x: "h \ get_child_nodes x \\<^sub>r children_x" by (metis "5" type_wf assms(3) get_child_nodes_ok is_OK_returns_result_E local.known_ptrs_known_ptr object_ptr_kinds_eq3) obtain children_y where children_y: "h \ get_child_nodes y \\<^sub>r children_y" by (metis "6" type_wf assms(3) get_child_nodes_ok is_OK_returns_result_E local.known_ptrs_known_ptr object_ptr_kinds_eq3) obtain children_x' where children_x': "h' \ get_child_nodes x \\<^sub>r children_x'" using children_eq children_h' children_x by fastforce obtain children_y' where children_y': "h' \ get_child_nodes y \\<^sub>r children_y'" using children_eq children_h' children_y by fastforce have "distinct (concat (map (\ptr. |h \ get_child_nodes ptr|\<^sub>r) |h \ object_ptr_kinds_M|\<^sub>r))" using h0 by(auto simp add: a_distinct_lists_def) then have 8: "set children_x \ set children_y = {}" using "7" assms(1) children_x children_y local.heap_is_wellformed_one_parent by blast have "set children_x' \ set children_y' = {}" proof (cases "ptr = x") case True then have "ptr \ y" by(simp add: 7) have "children_x' = remove1 child children_x" using children_h children_h' children_x children_x' True returns_result_eq by fastforce moreover have "children_y' = children_y" using children_y children_y' children_eq[OF \ptr \ y\] by auto ultimately show ?thesis using 8 set_remove1_subset by fastforce next case False then show ?thesis proof (cases "ptr = y") case True have "children_y' = remove1 child children_y" using children_h children_h' children_y children_y' True returns_result_eq by fastforce moreover have "children_x' = children_x" using children_x children_x' children_eq[OF \ptr \ x\] by auto ultimately show ?thesis using 8 set_remove1_subset by fastforce next case False have "children_x' = children_x" using children_x children_x' children_eq[OF \ptr \ x\] by auto moreover have "children_y' = children_y" using children_y children_y' children_eq[OF \ptr \ y\] by auto ultimately show ?thesis using 8 by simp qed qed then show "set |h' \ get_child_nodes x|\<^sub>r \ set |h' \ get_child_nodes y|\<^sub>r = {}" using children_x' children_y' by (metis (no_types, lifting) select_result_I2) qed next assume 2: "distinct |h \ document_ptr_kinds_M|\<^sub>r" then have 4: "distinct (sorted_list_of_set (fset (document_ptr_kinds h')))" by simp have 3: "distinct (concat (map (\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h')))))" using h0 by(simp add: a_distinct_lists_def document_ptr_kinds_eq3) show "distinct (concat (map (\document_ptr. |h' \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h')))))" proof(rule distinct_concat_map_I[OF 4[unfolded document_ptr_kinds_eq3]]) fix x assume 4: "x \ set (sorted_list_of_set (fset (document_ptr_kinds h')))" have 5: "distinct |h \ get_disconnected_nodes x|\<^sub>r" using distinct_lists_disconnected_nodes[OF h0] 4 get_disconnected_nodes_ok by (simp add: type_wf document_ptr_kinds_eq3 select_result_I) show "distinct |h' \ get_disconnected_nodes x|\<^sub>r" proof (cases "x = owner_document") case True have "child \ set |h \ get_disconnected_nodes x|\<^sub>r" using child_not_in document_ptr_kinds_eq2 "4" by fastforce moreover have "|h' \ get_disconnected_nodes x|\<^sub>r = child # |h \ get_disconnected_nodes x|\<^sub>r" using disconnected_nodes_h' disconnected_nodes_h unfolding True by(simp) ultimately show ?thesis using 5 unfolding True by simp next case False show ?thesis using "5" False disconnected_nodes_eq2 by auto qed next fix x y assume 4: "x \ set (sorted_list_of_set (fset (document_ptr_kinds h')))" and 5: "y \ set (sorted_list_of_set (fset (document_ptr_kinds h')))" and "x \ y" obtain disc_nodes_x where disc_nodes_x: "h \ get_disconnected_nodes x \\<^sub>r disc_nodes_x" using 4 get_disconnected_nodes_ok[OF \type_wf h\, of x] document_ptr_kinds_eq2 by auto obtain disc_nodes_y where disc_nodes_y: "h \ get_disconnected_nodes y \\<^sub>r disc_nodes_y" using 5 get_disconnected_nodes_ok[OF \type_wf h\, of y] document_ptr_kinds_eq2 by auto obtain disc_nodes_x' where disc_nodes_x': "h' \ get_disconnected_nodes x \\<^sub>r disc_nodes_x'" using 4 get_disconnected_nodes_ok[OF \type_wf h'\, of x] document_ptr_kinds_eq2 by auto obtain disc_nodes_y' where disc_nodes_y': "h' \ get_disconnected_nodes y \\<^sub>r disc_nodes_y'" using 5 get_disconnected_nodes_ok[OF \type_wf h'\, of y] document_ptr_kinds_eq2 by auto have "distinct (concat (map (\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r) |h \ document_ptr_kinds_M|\<^sub>r))" using h0 by (simp add: a_distinct_lists_def) then have 6: "set disc_nodes_x \ set disc_nodes_y = {}" using \x \ y\ assms(1) disc_nodes_x disc_nodes_y local.heap_is_wellformed_one_disc_parent by blast have "set disc_nodes_x' \ set disc_nodes_y' = {}" proof (cases "x = owner_document") case True then have "y \ owner_document" using \x \ y\ by simp then have "disc_nodes_y' = disc_nodes_y" using disconnected_nodes_eq[OF \y \ owner_document\] disc_nodes_y disc_nodes_y' by auto have "disc_nodes_x' = child # disc_nodes_x" using disconnected_nodes_h' disc_nodes_x disc_nodes_x' True disconnected_nodes_h returns_result_eq by fastforce have "child \ set disc_nodes_y" using child_not_in disc_nodes_y 5 using document_ptr_kinds_eq2 by fastforce then show ?thesis apply(unfold \disc_nodes_x' = child # disc_nodes_x\ \disc_nodes_y' = disc_nodes_y\) using 6 by auto next case False then show ?thesis proof (cases "y = owner_document") case True then have "disc_nodes_x' = disc_nodes_x" using disconnected_nodes_eq[OF \x \ owner_document\] disc_nodes_x disc_nodes_x' by auto have "disc_nodes_y' = child # disc_nodes_y" using disconnected_nodes_h' disc_nodes_y disc_nodes_y' True disconnected_nodes_h returns_result_eq by fastforce have "child \ set disc_nodes_x" using child_not_in disc_nodes_x 4 using document_ptr_kinds_eq2 by fastforce then show ?thesis apply(unfold \disc_nodes_y' = child # disc_nodes_y\ \disc_nodes_x' = disc_nodes_x\) using 6 by auto next case False have "disc_nodes_x' = disc_nodes_x" using disconnected_nodes_eq[OF \x \ owner_document\] disc_nodes_x disc_nodes_x' by auto have "disc_nodes_y' = disc_nodes_y" using disconnected_nodes_eq[OF \y \ owner_document\] disc_nodes_y disc_nodes_y' by auto then show ?thesis apply(unfold \disc_nodes_y' = disc_nodes_y\ \disc_nodes_x' = disc_nodes_x\) using 6 by auto qed qed then show "set |h' \ get_disconnected_nodes x|\<^sub>r \ set |h' \ get_disconnected_nodes y|\<^sub>r = {}" using disc_nodes_x' disc_nodes_y' by auto qed next fix x xa xb assume 1: "xa \ fset (object_ptr_kinds h')" and 2: "x \ set |h' \ get_child_nodes xa|\<^sub>r" and 3: "xb \ fset (document_ptr_kinds h')" and 4: "x \ set |h' \ get_disconnected_nodes xb|\<^sub>r" obtain disc_nodes where disc_nodes: "h \ get_disconnected_nodes xb \\<^sub>r disc_nodes" using 3 get_disconnected_nodes_ok[OF \type_wf h\, of xb] document_ptr_kinds_eq2 by auto obtain disc_nodes' where disc_nodes': "h' \ get_disconnected_nodes xb \\<^sub>r disc_nodes'" using 3 get_disconnected_nodes_ok[OF \type_wf h'\, of xb] document_ptr_kinds_eq2 by auto obtain children where children: "h \ get_child_nodes xa \\<^sub>r children" by (metis "1" type_wf assms(3) finite_set_in get_child_nodes_ok is_OK_returns_result_E local.known_ptrs_known_ptr object_ptr_kinds_eq3) obtain children' where children': "h' \ get_child_nodes xa \\<^sub>r children'" using children children_eq children_h' by fastforce have "\x. x \ set |h \ get_child_nodes xa|\<^sub>r \ x \ set |h \ get_disconnected_nodes xb|\<^sub>r \ False" using 1 3 apply(fold \ object_ptr_kinds h = object_ptr_kinds h'\) apply(fold \ document_ptr_kinds h = document_ptr_kinds h'\) using children disc_nodes h0 apply(auto simp add: a_distinct_lists_def)[1] by (metis (no_types, lifting) h0 local.distinct_lists_no_parent select_result_I2) then have 5: "\x. x \ set children \ x \ set disc_nodes \ False" using children disc_nodes by fastforce have 6: "|h' \ get_child_nodes xa|\<^sub>r = children'" using children' by (simp add: ) have 7: "|h' \ get_disconnected_nodes xb|\<^sub>r = disc_nodes'" using disc_nodes' by (simp add: ) have "False" proof (cases "xa = ptr") case True have "distinct children_h" using children_h distinct_lists_children h0 \known_ptr ptr\ by blast have "|h' \ get_child_nodes ptr|\<^sub>r = remove1 child children_h" using children_h' by(simp add: ) have "children = children_h" using True children children_h by auto show ?thesis using disc_nodes' children' 5 2 4 children_h \distinct children_h\ disconnected_nodes_h' apply(auto simp add: 6 7 \xa = ptr\ \|h' \ get_child_nodes ptr|\<^sub>r = remove1 child children_h\ \children = children_h\)[1] by (metis (no_types, lifting) disc_nodes disconnected_nodes_eq2 disconnected_nodes_h select_result_I2 set_ConsD) next case False have "children' = children" using children' children children_eq[OF False[symmetric]] by auto then show ?thesis proof (cases "xb = owner_document") case True then show ?thesis using disc_nodes disconnected_nodes_h disconnected_nodes_h' using "2" "4" "5" "6" "7" False \children' = children\ assms(1) child_in_children_h child_parent_dual children children_h disc_nodes' get_child_nodes_ptr_in_heap list.set_cases list.simps(3) option.simps(1) returns_result_eq set_ConsD by (metis (no_types, hide_lams) assms(3) type_wf) next case False then show ?thesis using "2" "4" "5" "6" "7" \children' = children\ disc_nodes disc_nodes' disconnected_nodes_eq returns_result_eq by metis qed qed then show "x \ {}" by simp qed } ultimately show "heap_is_wellformed h'" using heap_is_wellformed_def by blast qed lemma remove_heap_is_wellformed_preserved: assumes "heap_is_wellformed h" and "h \ remove child \\<^sub>h h'" and "known_ptrs h" and type_wf: "type_wf h" shows "type_wf h'" and "known_ptrs h'" and "heap_is_wellformed h'" using assms by(auto simp add: remove_def intro: remove_child_heap_is_wellformed_preserved elim!: bind_returns_heap_E2 split: option.splits) lemma remove_child_removes_child: assumes wellformed: "heap_is_wellformed h" and remove_child: "h \ remove_child ptr' child \\<^sub>h h'" and children: "h' \ get_child_nodes ptr \\<^sub>r children" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "child \ set children" proof - obtain owner_document children_h h2 disconnected_nodes_h where owner_document: "h \ get_owner_document (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r owner_document" and children_h: "h \ get_child_nodes ptr' \\<^sub>r children_h" and child_in_children_h: "child \ set children_h" and disconnected_nodes_h: "h \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h" and h2: "h \ set_disconnected_nodes owner_document (child # disconnected_nodes_h) \\<^sub>h h2" and h': "h2 \ set_child_nodes ptr' (remove1 child children_h) \\<^sub>h h'" using assms(2) apply(auto simp add: remove_child_def elim!: bind_returns_heap_E dest!: pure_returns_heap_eq[rotated, OF get_owner_document_pure] pure_returns_heap_eq[rotated, OF get_child_nodes_pure] split: if_splits)[1] using pure_returns_heap_eq by fastforce have "object_ptr_kinds h = object_ptr_kinds h'" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_child_writes remove_child]) unfolding remove_child_locs_def using set_child_nodes_pointers_preserved set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) moreover have "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF remove_child_writes assms(2)] using set_child_nodes_types_preserved set_disconnected_nodes_types_preserved type_wf unfolding remove_child_locs_def apply(auto simp add: reflp_def transp_def)[1] by blast ultimately show ?thesis using remove_child_removes_parent remove_child_heap_is_wellformed_preserved child_parent_dual by (meson children known_ptrs local.known_ptrs_preserved option.distinct(1) remove_child returns_result_eq type_wf wellformed) qed lemma remove_child_removes_first_child: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_child_nodes ptr \\<^sub>r node_ptr # children" assumes "h \ remove_child ptr node_ptr \\<^sub>h h'" shows "h' \ get_child_nodes ptr \\<^sub>r children" proof - obtain h2 disc_nodes owner_document where "h \ get_owner_document (cast node_ptr) \\<^sub>r owner_document" and "h \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes" and h2: "h \ set_disconnected_nodes owner_document (node_ptr # disc_nodes) \\<^sub>h h2" and "h2 \ set_child_nodes ptr children \\<^sub>h h'" using assms(5) apply(auto simp add: remove_child_def dest!: bind_returns_heap_E3[rotated, OF assms(4) get_child_nodes_pure, rotated])[1] by(auto elim!: bind_returns_heap_E bind_returns_heap_E2[rotated,OF get_owner_document_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated]) have "known_ptr ptr" by (meson assms(3) assms(4) is_OK_returns_result_I get_child_nodes_ptr_in_heap known_ptrs_known_ptr) moreover have "h2 \ get_child_nodes ptr \\<^sub>r node_ptr # children" apply(rule reads_writes_separate_forwards[OF get_child_nodes_reads set_disconnected_nodes_writes h2 assms(4)]) using set_disconnected_nodes_get_child_nodes set_child_nodes_get_child_nodes_different_pointers by fast moreover have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h2] using \type_wf h\ set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) ultimately show ?thesis using set_child_nodes_get_child_nodes\h2 \ set_child_nodes ptr children \\<^sub>h h'\ by fast qed lemma remove_removes_child: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_child_nodes ptr \\<^sub>r node_ptr # children" assumes "h \ remove node_ptr \\<^sub>h h'" shows "h' \ get_child_nodes ptr \\<^sub>r children" proof - have "h \ get_parent node_ptr \\<^sub>r Some ptr" using child_parent_dual assms by fastforce show ?thesis using assms remove_child_removes_first_child by(auto simp add: remove_def dest!: bind_returns_heap_E3[rotated, OF \h \ get_parent node_ptr \\<^sub>r Some ptr\, rotated] bind_returns_heap_E3[rotated, OF assms(4) get_child_nodes_pure, rotated]) qed lemma remove_for_all_empty_children: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_child_nodes ptr \\<^sub>r children" assumes "h \ forall_M remove children \\<^sub>h h'" shows "h' \ get_child_nodes ptr \\<^sub>r []" using assms proof(induct children arbitrary: h h') case Nil then show ?case by simp next case (Cons a children) have "h \ get_parent a \\<^sub>r Some ptr" using child_parent_dual Cons by fastforce with Cons show ?case proof(auto elim!: bind_returns_heap_E)[1] fix h2 assume 0: "(\h h'. heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_child_nodes ptr \\<^sub>r children \ h \ forall_M remove children \\<^sub>h h' \ h' \ get_child_nodes ptr \\<^sub>r [])" and 1: "heap_is_wellformed h" and 2: "type_wf h" and 3: "known_ptrs h" and 4: "h \ get_child_nodes ptr \\<^sub>r a # children" and 5: "h \ get_parent a \\<^sub>r Some ptr" and 7: "h \ remove a \\<^sub>h h2" and 8: "h2 \ forall_M remove children \\<^sub>h h'" then have "h2 \ get_child_nodes ptr \\<^sub>r children" using remove_removes_child by blast moreover have "heap_is_wellformed h2" using 7 1 2 3 remove_child_heap_is_wellformed_preserved(3) by(auto simp add: remove_def elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] split: option.splits) moreover have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF remove_writes 7] using \type_wf h\ remove_child_types_preserved by(auto simp add: a_remove_child_locs_def reflp_def transp_def) moreover have "object_ptr_kinds h = object_ptr_kinds h2" using 7 apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_writes]) using remove_child_pointers_preserved by (auto simp add: reflp_def transp_def) then have "known_ptrs h2" using 3 known_ptrs_preserved by blast ultimately show "h' \ get_child_nodes ptr \\<^sub>r []" using 0 8 by fast qed qed end locale l_remove_child_wf2 = l_type_wf + l_known_ptrs + l_remove_child_defs + l_heap_is_wellformed_defs + l_get_child_nodes_defs + l_remove_defs + assumes remove_child_preserves_type_wf: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ remove_child ptr child \\<^sub>h h' \ type_wf h'" assumes remove_child_preserves_known_ptrs: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ remove_child ptr child \\<^sub>h h' \ known_ptrs h'" assumes remove_child_heap_is_wellformed_preserved: "type_wf h \ known_ptrs h \ heap_is_wellformed h \ h \ remove_child ptr child \\<^sub>h h' \ heap_is_wellformed h'" assumes remove_preserves_type_wf: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ remove child \\<^sub>h h' \ type_wf h'" assumes remove_preserves_known_ptrs: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ remove child \\<^sub>h h' \ known_ptrs h'" assumes remove_heap_is_wellformed_preserved: "type_wf h \ known_ptrs h \ heap_is_wellformed h \ h \ remove child \\<^sub>h h' \ heap_is_wellformed h'" assumes remove_child_removes_child: "heap_is_wellformed h \ h \ remove_child ptr' child \\<^sub>h h' \ h' \ get_child_nodes ptr \\<^sub>r children \ known_ptrs h \ type_wf h \ child \ set children" assumes remove_child_removes_first_child: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_child_nodes ptr \\<^sub>r node_ptr # children \ h \ remove_child ptr node_ptr \\<^sub>h h' \ h' \ get_child_nodes ptr \\<^sub>r children" assumes remove_removes_child: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_child_nodes ptr \\<^sub>r node_ptr # children \ h \ remove node_ptr \\<^sub>h h' \ h' \ get_child_nodes ptr \\<^sub>r children" assumes remove_for_all_empty_children: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_child_nodes ptr \\<^sub>r children \ h \ forall_M remove children \\<^sub>h h' \ h' \ get_child_nodes ptr \\<^sub>r []" interpretation i_remove_child_wf2?: l_remove_child_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_child_nodes get_child_nodes_locs set_child_nodes set_child_nodes_locs get_parent get_parent_locs get_owner_document get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs remove_child remove_child_locs remove type_wf known_ptr known_ptrs heap_is_wellformed parent_child_rel by unfold_locales lemma remove_child_wf2_is_l_remove_child_wf2 [instances]: "l_remove_child_wf2 type_wf known_ptr known_ptrs remove_child heap_is_wellformed get_child_nodes remove" apply(auto simp add: l_remove_child_wf2_def l_remove_child_wf2_axioms_def instances)[1] using remove_child_heap_is_wellformed_preserved apply(fast, fast, fast) using remove_heap_is_wellformed_preserved apply(fast, fast, fast) using remove_child_removes_child apply fast using remove_child_removes_first_child apply fast using remove_removes_child apply fast using remove_for_all_empty_children apply fast done subsection \adopt\_node\ locale l_adopt_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_adopt_node\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_parent_wf + l_get_owner_document_wf + l_remove_child_wf2 + l_heap_is_wellformed begin lemma adopt_node_removes_first_child: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ adopt_node owner_document node \\<^sub>h h'" assumes "h \ get_child_nodes ptr' \\<^sub>r node # children" shows "h' \ get_child_nodes ptr' \\<^sub>r children" proof - obtain old_document parent_opt h2 where old_document: "h \ get_owner_document (cast node) \\<^sub>r old_document" and parent_opt: "h \ get_parent node \\<^sub>r parent_opt" and h2: "h \ (case parent_opt of Some parent \ do { remove_child parent node } | None \ do { return ()}) \\<^sub>h h2" and h': "h2 \ (if owner_document \ old_document then do { old_disc_nodes \ get_disconnected_nodes old_document; set_disconnected_nodes old_document (remove1 node old_disc_nodes); disc_nodes \ get_disconnected_nodes owner_document; set_disconnected_nodes owner_document (node # disc_nodes) } else do { return () }) \\<^sub>h h'" using assms(4) by(auto simp add: adopt_node_def elim!: bind_returns_heap_E dest!: pure_returns_heap_eq[rotated, OF get_owner_document_pure] pure_returns_heap_eq[rotated, OF get_parent_pure]) have "h2 \ get_child_nodes ptr' \\<^sub>r children" using h2 remove_child_removes_first_child assms(1) assms(2) assms(3) assms(5) by (metis list.set_intros(1) local.child_parent_dual option.simps(5) parent_opt returns_result_eq) then show ?thesis using h' by(auto elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] dest!: reads_writes_separate_forwards[OF get_child_nodes_reads set_disconnected_nodes_writes] split: if_splits) qed lemma adopt_node_document_in_heap: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ ok (adopt_node owner_document node)" shows "owner_document |\| document_ptr_kinds h" proof - obtain old_document parent_opt h2 h' where old_document: "h \ get_owner_document (cast node) \\<^sub>r old_document" and parent_opt: "h \ get_parent node \\<^sub>r parent_opt" and h2: "h \ (case parent_opt of Some parent \ do { remove_child parent node } | None \ do { return ()}) \\<^sub>h h2" and h': "h2 \ (if owner_document \ old_document then do { old_disc_nodes \ get_disconnected_nodes old_document; set_disconnected_nodes old_document (remove1 node old_disc_nodes); disc_nodes \ get_disconnected_nodes owner_document; set_disconnected_nodes owner_document (node # disc_nodes) } else do { return () }) \\<^sub>h h'" using assms(4) by(auto simp add: adopt_node_def elim!: bind_returns_heap_E dest!: pure_returns_heap_eq[rotated, OF get_owner_document_pure] pure_returns_heap_eq[rotated, OF get_parent_pure]) show ?thesis proof (cases "owner_document = old_document") case True then show ?thesis using old_document get_owner_document_owner_document_in_heap assms(1) assms(2) assms(3) by auto next case False then obtain h3 old_disc_nodes disc_nodes where old_disc_nodes: "h2 \ get_disconnected_nodes old_document \\<^sub>r old_disc_nodes" and h3: "h2 \ set_disconnected_nodes old_document (remove1 node old_disc_nodes) \\<^sub>h h3" and old_disc_nodes: "h3 \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes" and h': "h3 \ set_disconnected_nodes owner_document (node # disc_nodes) \\<^sub>h h'" using h' by(auto elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] ) then have "owner_document |\| document_ptr_kinds h3" by (meson is_OK_returns_result_I local.get_disconnected_nodes_ptr_in_heap) moreover have "object_ptr_kinds h = object_ptr_kinds h2" using h2 apply(simp split: option.splits) apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_child_writes]) using remove_child_pointers_preserved by (auto simp add: reflp_def transp_def) moreover have "object_ptr_kinds h2 = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h3]) using set_disconnected_nodes_pointers_preserved set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) ultimately show ?thesis by(auto simp add: document_ptr_kinds_def) qed qed end locale l_adopt_node_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_adopt_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_adopt_node\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_parent_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_root_node + l_get_owner_document_wf + l_remove_child_wf2 + l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M begin lemma adopt_node_removes_child_step: assumes wellformed: "heap_is_wellformed h" and adopt_node: "h \ adopt_node owner_document node_ptr \\<^sub>h h2" and children: "h2 \ get_child_nodes ptr \\<^sub>r children" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "node_ptr \ set children" proof - obtain old_document parent_opt h' where old_document: "h \ get_owner_document (cast node_ptr) \\<^sub>r old_document" and parent_opt: "h \ get_parent node_ptr \\<^sub>r parent_opt" and h': "h \ (case parent_opt of Some parent \ remove_child parent node_ptr | None \ return () ) \\<^sub>h h'" using adopt_node get_parent_pure by(auto simp add: adopt_node_def elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_owner_document_pure, rotated] bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] split: if_splits) then have "h' \ get_child_nodes ptr \\<^sub>r children" using adopt_node apply(auto simp add: adopt_node_def dest!: bind_returns_heap_E3[rotated, OF old_document, rotated] bind_returns_heap_E3[rotated, OF parent_opt, rotated] elim!: bind_returns_heap_E4[rotated, OF h', rotated])[1] apply(auto split: if_splits elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated])[1] apply (simp add: set_disconnected_nodes_get_child_nodes children reads_writes_preserved[OF get_child_nodes_reads set_disconnected_nodes_writes]) using children by blast show ?thesis proof(insert parent_opt h', induct parent_opt) case None then show ?case using child_parent_dual wellformed known_ptrs type_wf \h' \ get_child_nodes ptr \\<^sub>r children\ returns_result_eq by fastforce next case (Some option) then show ?case using remove_child_removes_child \h' \ get_child_nodes ptr \\<^sub>r children\ known_ptrs type_wf wellformed by auto qed qed lemma adopt_node_removes_child: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ adopt_node owner_document node_ptr \\<^sub>h h'" shows "\ptr' children'. h' \ get_child_nodes ptr' \\<^sub>r children' \ node_ptr \ set children'" using adopt_node_removes_child_step assms by blast lemma adopt_node_preserves_wellformedness: assumes "heap_is_wellformed h" and "h \ adopt_node document_ptr child \\<^sub>h h'" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "heap_is_wellformed h'" and "known_ptrs h'" and "type_wf h'" proof - obtain old_document parent_opt h2 where old_document: "h \ get_owner_document (cast child) \\<^sub>r old_document" and parent_opt: "h \ get_parent child \\<^sub>r parent_opt" and h2: "h \ (case parent_opt of Some parent \ remove_child parent child | None \ return ()) \\<^sub>h h2" and h': "h2 \ (if document_ptr \ old_document then do { old_disc_nodes \ get_disconnected_nodes old_document; set_disconnected_nodes old_document (remove1 child old_disc_nodes); disc_nodes \ get_disconnected_nodes document_ptr; set_disconnected_nodes document_ptr (child # disc_nodes) } else do { return () }) \\<^sub>h h'" using assms(2) by(auto simp add: adopt_node_def elim!: bind_returns_heap_E dest!: pure_returns_heap_eq[rotated, OF get_owner_document_pure] pure_returns_heap_eq[rotated, OF get_parent_pure]) have object_ptr_kinds_h_eq3: "object_ptr_kinds h = object_ptr_kinds h2" using h2 apply(simp split: option.splits) apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_child_writes]) using remove_child_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h2 \ object_ptr_kinds_M \\<^sub>r ptrs" unfolding object_ptr_kinds_M_defs by simp then have object_ptr_kinds_eq_h: "|h \ object_ptr_kinds_M|\<^sub>r = |h2 \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq_h: "|h \ node_ptr_kinds_M|\<^sub>r = |h2 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have wellformed_h2: "heap_is_wellformed h2" using h2 remove_child_heap_is_wellformed_preserved known_ptrs type_wf by (metis (no_types, lifting) assms(1) option.case_eq_if pure_returns_heap_eq return_pure) have "type_wf h2" using h2 remove_child_preserves_type_wf known_ptrs type_wf by (metis (no_types, lifting) assms(1) option.case_eq_if pure_returns_heap_eq return_pure) have "known_ptrs h2" using h2 remove_child_preserves_known_ptrs known_ptrs type_wf by (metis (no_types, lifting) assms(1) option.case_eq_if pure_returns_heap_eq return_pure) have "heap_is_wellformed h' \ known_ptrs h' \ type_wf h'" proof(cases "document_ptr = old_document") case True then show ?thesis using h' wellformed_h2 \type_wf h2\ \known_ptrs h2\ by auto next case False then obtain h3 old_disc_nodes disc_nodes_document_ptr_h3 where docs_neq: "document_ptr \ old_document" and old_disc_nodes: "h2 \ get_disconnected_nodes old_document \\<^sub>r old_disc_nodes" and h3: "h2 \ set_disconnected_nodes old_document (remove1 child old_disc_nodes) \\<^sub>h h3" and disc_nodes_document_ptr_h3: "h3 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_document_ptr_h3" and h': "h3 \ set_disconnected_nodes document_ptr (child # disc_nodes_document_ptr_h3) \\<^sub>h h'" using h' by(auto elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] ) have object_ptr_kinds_h2_eq3: "object_ptr_kinds h2 = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h3]) using set_disconnected_nodes_pointers_preserved set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h2: "\ptrs. h2 \ object_ptr_kinds_M \\<^sub>r ptrs = h3 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_eq_h2: "|h2 \ object_ptr_kinds_M|\<^sub>r = |h3 \ object_ptr_kinds_M|\<^sub>r" by(simp) then have node_ptr_kinds_eq_h2: "|h2 \ node_ptr_kinds_M|\<^sub>r = |h3 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast then have node_ptr_kinds_eq3_h2: "node_ptr_kinds h2 = node_ptr_kinds h3" by auto have document_ptr_kinds_eq2_h2: "|h2 \ document_ptr_kinds_M|\<^sub>r = |h3 \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_eq_h2 document_ptr_kinds_M_eq by auto then have document_ptr_kinds_eq3_h2: "document_ptr_kinds h2 = document_ptr_kinds h3" using object_ptr_kinds_eq_h2 document_ptr_kinds_M_eq by auto have children_eq_h2: "\ptr children. h2 \ get_child_nodes ptr \\<^sub>r children = h3 \ get_child_nodes ptr \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h2: "\ptr. |h2 \ get_child_nodes ptr|\<^sub>r = |h3 \ get_child_nodes ptr|\<^sub>r" using select_result_eq by force have object_ptr_kinds_h3_eq3: "object_ptr_kinds h3 = object_ptr_kinds h'" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h']) using set_disconnected_nodes_pointers_preserved set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h3: "\ptrs. h3 \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_eq_h3: "|h3 \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" by(simp) then have node_ptr_kinds_eq_h3: "|h3 \ node_ptr_kinds_M|\<^sub>r = |h' \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast then have node_ptr_kinds_eq3_h3: "node_ptr_kinds h3 = node_ptr_kinds h'" by auto have document_ptr_kinds_eq2_h3: "|h3 \ document_ptr_kinds_M|\<^sub>r = |h' \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_eq_h3 document_ptr_kinds_M_eq by auto then have document_ptr_kinds_eq3_h3: "document_ptr_kinds h3 = document_ptr_kinds h'" using object_ptr_kinds_eq_h3 document_ptr_kinds_M_eq by auto have children_eq_h3: "\ptr children. h3 \ get_child_nodes ptr \\<^sub>r children = h' \ get_child_nodes ptr \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h' apply(rule reads_writes_preserved) by (simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h3: "\ptr. |h3 \ get_child_nodes ptr|\<^sub>r = |h' \ get_child_nodes ptr|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq_h2: "\doc_ptr disc_nodes. old_document \ doc_ptr \ h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (simp add: set_disconnected_nodes_get_disconnected_nodes_different_pointers) then have disconnected_nodes_eq2_h2: "\doc_ptr. old_document \ doc_ptr \ |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force obtain disc_nodes_old_document_h2 where disc_nodes_old_document_h2: "h2 \ get_disconnected_nodes old_document \\<^sub>r disc_nodes_old_document_h2" using old_disc_nodes by blast then have disc_nodes_old_document_h3: "h3 \ get_disconnected_nodes old_document \\<^sub>r remove1 child disc_nodes_old_document_h2" using h3 old_disc_nodes returns_result_eq set_disconnected_nodes_get_disconnected_nodes by fastforce have "distinct disc_nodes_old_document_h2" using disc_nodes_old_document_h2 local.heap_is_wellformed_disconnected_nodes_distinct wellformed_h2 by blast have "type_wf h2" proof (insert h2, induct parent_opt) case None then show ?case using type_wf by simp next case (Some option) then show ?case using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF remove_child_writes] type_wf remove_child_types_preserved by (simp add: reflp_def transp_def) qed then have "type_wf h3" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h3] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) then have "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h'] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) have "known_ptrs h3" using known_ptrs local.known_ptrs_preserved object_ptr_kinds_h2_eq3 object_ptr_kinds_h_eq3 by blast then have "known_ptrs h'" using local.known_ptrs_preserved object_ptr_kinds_h3_eq3 by blast have disconnected_nodes_eq_h3: "\doc_ptr disc_nodes. document_ptr \ doc_ptr \ h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h' \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_disconnected_nodes_writes h' apply(rule reads_writes_preserved) by (simp add: set_disconnected_nodes_get_disconnected_nodes_different_pointers) then have disconnected_nodes_eq2_h3: "\doc_ptr. document_ptr \ doc_ptr \ |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have disc_nodes_document_ptr_h2: "h2 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_document_ptr_h3" using disconnected_nodes_eq_h2 docs_neq disc_nodes_document_ptr_h3 by auto have disc_nodes_document_ptr_h': " h' \ get_disconnected_nodes document_ptr \\<^sub>r child # disc_nodes_document_ptr_h3" using h' disc_nodes_document_ptr_h3 using set_disconnected_nodes_get_disconnected_nodes by blast have document_ptr_in_heap: "document_ptr |\| document_ptr_kinds h2" using disc_nodes_document_ptr_h3 document_ptr_kinds_eq2_h2 get_disconnected_nodes_ok assms(1) unfolding heap_is_wellformed_def using disc_nodes_document_ptr_h2 get_disconnected_nodes_ptr_in_heap by blast have old_document_in_heap: "old_document |\| document_ptr_kinds h2" using disc_nodes_old_document_h3 document_ptr_kinds_eq2_h2 get_disconnected_nodes_ok assms(1) unfolding heap_is_wellformed_def using get_disconnected_nodes_ptr_in_heap old_disc_nodes by blast have "child \ set disc_nodes_old_document_h2" proof (insert parent_opt h2, induct parent_opt) case None then have "h = h2" by(auto) moreover have "a_owner_document_valid h" using assms(1) heap_is_wellformed_def by(simp add: heap_is_wellformed_def) ultimately show ?case using old_document disc_nodes_old_document_h2 None(1) child_parent_dual[OF assms(1)] in_disconnected_nodes_no_parent assms(1) known_ptrs type_wf by blast next case (Some option) then show ?case apply(simp split: option.splits) using assms(1) disc_nodes_old_document_h2 old_document remove_child_in_disconnected_nodes known_ptrs by blast qed have "child \ set (remove1 child disc_nodes_old_document_h2)" using disc_nodes_old_document_h3 h3 known_ptrs wellformed_h2 \distinct disc_nodes_old_document_h2\ by auto have "child \ set disc_nodes_document_ptr_h3" proof - have "a_distinct_lists h2" using heap_is_wellformed_def wellformed_h2 by blast then have 0: "distinct (concat (map (\document_ptr. |h2 \ get_disconnected_nodes document_ptr|\<^sub>r) |h2 \ document_ptr_kinds_M|\<^sub>r))" by(simp add: a_distinct_lists_def) show ?thesis using distinct_concat_map_E(1)[OF 0] \child \ set disc_nodes_old_document_h2\ disc_nodes_old_document_h2 disc_nodes_document_ptr_h2 by (meson \type_wf h2\ docs_neq known_ptrs local.get_owner_document_disconnected_nodes local.known_ptrs_preserved object_ptr_kinds_h_eq3 returns_result_eq wellformed_h2) qed have child_in_heap: "child |\| node_ptr_kinds h" using get_owner_document_ptr_in_heap[OF is_OK_returns_result_I[OF old_document]] node_ptr_kinds_commutes by blast have "a_acyclic_heap h2" using wellformed_h2 by (simp add: heap_is_wellformed_def) have "parent_child_rel h' \ parent_child_rel h2" proof fix x assume "x \ parent_child_rel h'" then show "x \ parent_child_rel h2" using object_ptr_kinds_h2_eq3 object_ptr_kinds_h3_eq3 children_eq2_h2 children_eq2_h3 mem_Collect_eq object_ptr_kinds_M_eq_h3 select_result_eq split_cong unfolding parent_child_rel_def by(simp) qed then have "a_acyclic_heap h'" using \a_acyclic_heap h2\ acyclic_heap_def acyclic_subset by blast moreover have "a_all_ptrs_in_heap h2" using wellformed_h2 by (simp add: heap_is_wellformed_def) then have "a_all_ptrs_in_heap h3" apply(auto simp add: a_all_ptrs_in_heap_def node_ptr_kinds_eq3_h2 children_eq_h2)[1] apply (simp add: children_eq2_h2 object_ptr_kinds_h2_eq3 subset_code(1)) by (metis (no_types, lifting) \child \ set disc_nodes_old_document_h2\ \type_wf h2\ disc_nodes_old_document_h2 disc_nodes_old_document_h3 disconnected_nodes_eq2_h2 document_ptr_kinds_eq3_h2 in_set_remove1 local.get_disconnected_nodes_ok local.heap_is_wellformed_disc_nodes_in_heap node_ptr_kinds_eq3_h2 returns_result_select_result select_result_I2 wellformed_h2) then have "a_all_ptrs_in_heap h'" apply(auto simp add: a_all_ptrs_in_heap_def node_ptr_kinds_eq3_h3 children_eq_h3)[1] apply (simp add: children_eq2_h3 object_ptr_kinds_h3_eq3 subset_code(1)) by (metis (no_types, lifting) \child \ set disc_nodes_old_document_h2\ disc_nodes_document_ptr_h' disc_nodes_document_ptr_h2 disc_nodes_old_document_h2 disconnected_nodes_eq2_h3 document_ptr_kinds_eq3_h3 finite_set_in local.heap_is_wellformed_disc_nodes_in_heap node_ptr_kinds_eq3_h2 node_ptr_kinds_eq3_h3 select_result_I2 set_ConsD subset_code(1) wellformed_h2) moreover have "a_owner_document_valid h2" using wellformed_h2 by (simp add: heap_is_wellformed_def) then have "a_owner_document_valid h'" apply(simp add: a_owner_document_valid_def node_ptr_kinds_eq_h2 node_ptr_kinds_eq3_h3 object_ptr_kinds_eq_h2 object_ptr_kinds_eq_h3 document_ptr_kinds_eq2_h2 document_ptr_kinds_eq2_h3 children_eq2_h2 children_eq2_h3 ) by (smt disc_nodes_document_ptr_h' disc_nodes_document_ptr_h2 disc_nodes_old_document_h2 disc_nodes_old_document_h3 disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 document_ptr_in_heap document_ptr_kinds_eq3_h2 document_ptr_kinds_eq3_h3 in_set_remove1 list.set_intros(1) list.set_intros(2) node_ptr_kinds_eq3_h2 node_ptr_kinds_eq3_h3 object_ptr_kinds_h2_eq3 object_ptr_kinds_h3_eq3 select_result_I2) have a_distinct_lists_h2: "a_distinct_lists h2" using wellformed_h2 by (simp add: heap_is_wellformed_def) then have "a_distinct_lists h'" apply(auto simp add: a_distinct_lists_def object_ptr_kinds_eq_h3 object_ptr_kinds_eq_h2 children_eq2_h2 children_eq2_h3)[1] proof - assume 1: "distinct (concat (map (\ptr. |h' \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h')))))" and 2: "distinct (concat (map (\document_ptr. |h2 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h2)))))" and 3: "(\x\fset (object_ptr_kinds h'). set |h' \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h2). set |h2 \ get_disconnected_nodes x|\<^sub>r) = {}" show "distinct (concat (map (\document_ptr. |h' \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h')))))" proof(rule distinct_concat_map_I) show "distinct (sorted_list_of_set (fset (document_ptr_kinds h')))" by(auto simp add: document_ptr_kinds_M_def ) next fix x assume a1: "x \ set (sorted_list_of_set (fset (document_ptr_kinds h')))" have 4: "distinct |h2 \ get_disconnected_nodes x|\<^sub>r" using a_distinct_lists_h2 "2" a1 concat_map_all_distinct document_ptr_kinds_eq2_h2 document_ptr_kinds_eq2_h3 by fastforce then show "distinct |h' \ get_disconnected_nodes x|\<^sub>r" proof (cases "old_document \ x") case True then show ?thesis proof (cases "document_ptr \ x") case True then show ?thesis using disconnected_nodes_eq2_h2[OF \old_document \ x\] disconnected_nodes_eq2_h3[OF \document_ptr \ x\] 4 by(auto) next case False then show ?thesis using disc_nodes_document_ptr_h3 disc_nodes_document_ptr_h' 4 \child \ set disc_nodes_document_ptr_h3\ by(auto simp add: disconnected_nodes_eq2_h2[OF \old_document \ x\] ) qed next case False then show ?thesis by (metis (no_types, hide_lams) \distinct disc_nodes_old_document_h2\ disc_nodes_old_document_h3 disconnected_nodes_eq2_h3 distinct_remove1 docs_neq select_result_I2) qed next fix x y assume a0: "x \ set (sorted_list_of_set (fset (document_ptr_kinds h')))" and a1: "y \ set (sorted_list_of_set (fset (document_ptr_kinds h')))" and a2: "x \ y" moreover have 5: "set |h2 \ get_disconnected_nodes x|\<^sub>r \ set |h2 \ get_disconnected_nodes y|\<^sub>r = {}" using 2 calculation by (auto simp add: document_ptr_kinds_eq3_h2 document_ptr_kinds_eq3_h3 dest: distinct_concat_map_E(1)) ultimately show "set |h' \ get_disconnected_nodes x|\<^sub>r \ set |h' \ get_disconnected_nodes y|\<^sub>r = {}" proof(cases "old_document = x") case True have "old_document \ y" using \x \ y\ \old_document = x\ by simp have "document_ptr \ x" using docs_neq \old_document = x\ by auto show ?thesis proof(cases "document_ptr = y") case True then show ?thesis using 5 True select_result_I2[OF disc_nodes_document_ptr_h'] select_result_I2[OF disc_nodes_document_ptr_h2] select_result_I2[OF disc_nodes_old_document_h2] select_result_I2[OF disc_nodes_old_document_h3] \old_document = x\ by (metis (no_types, lifting) \child \ set (remove1 child disc_nodes_old_document_h2)\ \document_ptr \ x\ disconnected_nodes_eq2_h3 disjoint_iff_not_equal notin_set_remove1 set_ConsD) next case False then show ?thesis using 5 select_result_I2[OF disc_nodes_document_ptr_h'] select_result_I2[OF disc_nodes_document_ptr_h2] select_result_I2[OF disc_nodes_old_document_h2] select_result_I2[OF disc_nodes_old_document_h3] disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 \old_document = x\ docs_neq \old_document \ y\ by (metis (no_types, lifting) disjoint_iff_not_equal notin_set_remove1) qed next case False then show ?thesis proof(cases "old_document = y") case True then show ?thesis proof(cases "document_ptr = x") case True show ?thesis using 5 select_result_I2[OF disc_nodes_document_ptr_h'] select_result_I2[OF disc_nodes_document_ptr_h2] select_result_I2[OF disc_nodes_old_document_h2] select_result_I2[OF disc_nodes_old_document_h3] \old_document \ x\ \old_document = y\ \document_ptr = x\ apply(simp) by (metis (no_types, lifting) \child \ set (remove1 child disc_nodes_old_document_h2)\ disconnected_nodes_eq2_h3 disjoint_iff_not_equal notin_set_remove1) next case False then show ?thesis using 5 select_result_I2[OF disc_nodes_document_ptr_h'] select_result_I2[OF disc_nodes_document_ptr_h2] select_result_I2[OF disc_nodes_old_document_h2] select_result_I2[OF disc_nodes_old_document_h3] \old_document \ x\ \old_document = y\ \document_ptr \ x\ by (metis (no_types, lifting) disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 disjoint_iff_not_equal docs_neq notin_set_remove1) qed next case False have "set |h2 \ get_disconnected_nodes y|\<^sub>r \ set disc_nodes_old_document_h2 = {}" by (metis DocumentMonad.ptr_kinds_M_ok DocumentMonad.ptr_kinds_M_ptr_kinds False \type_wf h2\ a1 disc_nodes_old_document_h2 document_ptr_kinds_M_def document_ptr_kinds_eq2_h2 document_ptr_kinds_eq2_h3 l_ptr_kinds_M.ptr_kinds_ptr_kinds_M local.get_disconnected_nodes_ok local.heap_is_wellformed_one_disc_parent returns_result_select_result wellformed_h2) then show ?thesis proof(cases "document_ptr = x") case True then have "document_ptr \ y" using \x \ y\ by auto have "set |h2 \ get_disconnected_nodes y|\<^sub>r \ set disc_nodes_old_document_h2 = {}" using \set |h2 \ get_disconnected_nodes y|\<^sub>r \ set disc_nodes_old_document_h2 = {}\ by blast then show ?thesis using 5 select_result_I2[OF disc_nodes_document_ptr_h'] select_result_I2[OF disc_nodes_document_ptr_h2] select_result_I2[OF disc_nodes_old_document_h2] select_result_I2[OF disc_nodes_old_document_h3] \old_document \ x\ \old_document \ y\ \document_ptr = x\ \document_ptr \ y\ \child \ set disc_nodes_old_document_h2\ disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 \set |h2 \ get_disconnected_nodes y|\<^sub>r \ set disc_nodes_old_document_h2 = {}\ by(auto) next case False then show ?thesis proof(cases "document_ptr = y") case True have f1: "set |h2 \ get_disconnected_nodes x|\<^sub>r \ set disc_nodes_document_ptr_h3 = {}" using 2 a1 document_ptr_in_heap document_ptr_kinds_eq2_h2 document_ptr_kinds_eq2_h3 \document_ptr \ x\ select_result_I2[OF disc_nodes_document_ptr_h3, symmetric] disconnected_nodes_eq2_h2[OF docs_neq[symmetric], symmetric] by (simp add: "5" True) moreover have f1: "set |h2 \ get_disconnected_nodes x|\<^sub>r \ set |h2 \ get_disconnected_nodes old_document|\<^sub>r = {}" using 2 a1 old_document_in_heap document_ptr_kinds_eq2_h2 document_ptr_kinds_eq2_h3 \old_document \ x\ by (metis (no_types, lifting) a0 distinct_concat_map_E(1) document_ptr_kinds_eq3_h2 document_ptr_kinds_eq3_h3 finite_fset fmember.rep_eq set_sorted_list_of_set) ultimately show ?thesis using 5 select_result_I2[OF disc_nodes_document_ptr_h'] select_result_I2[OF disc_nodes_old_document_h2] \old_document \ x\ \document_ptr \ x\ \document_ptr = y\ \child \ set disc_nodes_old_document_h2\ disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 by auto next case False then show ?thesis using 5 select_result_I2[OF disc_nodes_old_document_h2] \old_document \ x\ \document_ptr \ x\ \document_ptr \ y\ \child \ set disc_nodes_old_document_h2\ disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 by (metis \set |h2 \ get_disconnected_nodes y|\<^sub>r \ set disc_nodes_old_document_h2 = {}\ empty_iff inf.idem) qed qed qed qed qed next fix x xa xb assume 0: "distinct (concat (map (\ptr. |h' \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h')))))" and 1: "distinct (concat (map (\document_ptr. |h2 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h2)))))" and 2: "(\x\fset (object_ptr_kinds h'). set |h' \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h2). set |h2 \ get_disconnected_nodes x|\<^sub>r) = {}" and 3: "xa |\| object_ptr_kinds h'" and 4: "x \ set |h' \ get_child_nodes xa|\<^sub>r" and 5: "xb |\| document_ptr_kinds h'" and 6: "x \ set |h' \ get_disconnected_nodes xb|\<^sub>r" then show False using \child \ set disc_nodes_old_document_h2\ disc_nodes_document_ptr_h' disc_nodes_document_ptr_h2 disc_nodes_old_document_h2 disc_nodes_old_document_h3 disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 document_ptr_kinds_eq2_h2 document_ptr_kinds_eq2_h3 old_document_in_heap apply(auto)[1] apply(cases "xb = old_document") proof - assume a1: "xb = old_document" assume a2: "h2 \ get_disconnected_nodes old_document \\<^sub>r disc_nodes_old_document_h2" assume a3: "h3 \ get_disconnected_nodes old_document \\<^sub>r remove1 child disc_nodes_old_document_h2" assume a4: "x \ set |h' \ get_child_nodes xa|\<^sub>r" assume "document_ptr_kinds h2 = document_ptr_kinds h'" assume a5: "(\x\fset (object_ptr_kinds h'). set |h' \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h'). set |h2 \ get_disconnected_nodes x|\<^sub>r) = {}" have f6: "old_document |\| document_ptr_kinds h'" using a1 \xb |\| document_ptr_kinds h'\ by blast have f7: "|h2 \ get_disconnected_nodes old_document|\<^sub>r = disc_nodes_old_document_h2" using a2 by simp have "x \ set disc_nodes_old_document_h2" using f6 a3 a1 by (metis (no_types) \type_wf h'\ \x \ set |h' \ get_disconnected_nodes xb|\<^sub>r\ disconnected_nodes_eq_h3 docs_neq get_disconnected_nodes_ok returns_result_eq returns_result_select_result set_remove1_subset subsetCE) then have "set |h' \ get_child_nodes xa|\<^sub>r \ set |h2 \ get_disconnected_nodes xb|\<^sub>r = {}" using f7 f6 a5 a4 \xa |\| object_ptr_kinds h'\ by fastforce then show ?thesis using \x \ set disc_nodes_old_document_h2\ a1 a4 f7 by blast next assume a1: "xb \ old_document" assume a2: "h2 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_document_ptr_h3" assume a3: "h2 \ get_disconnected_nodes old_document \\<^sub>r disc_nodes_old_document_h2" assume a4: "xa |\| object_ptr_kinds h'" assume a5: "h' \ get_disconnected_nodes document_ptr \\<^sub>r child # disc_nodes_document_ptr_h3" assume a6: "old_document |\| document_ptr_kinds h'" assume a7: "x \ set |h' \ get_disconnected_nodes xb|\<^sub>r" assume a8: "x \ set |h' \ get_child_nodes xa|\<^sub>r" assume a9: "document_ptr_kinds h2 = document_ptr_kinds h'" assume a10: "\doc_ptr. old_document \ doc_ptr \ |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r" assume a11: "\doc_ptr. document_ptr \ doc_ptr \ |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" assume a12: "(\x\fset (object_ptr_kinds h'). set |h' \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h'). set |h2 \ get_disconnected_nodes x|\<^sub>r) = {}" have f13: "\d. d \ set |h' \ document_ptr_kinds_M|\<^sub>r \ h2 \ ok get_disconnected_nodes d" using a9 \type_wf h2\ get_disconnected_nodes_ok by simp then have f14: "|h2 \ get_disconnected_nodes old_document|\<^sub>r = disc_nodes_old_document_h2" using a6 a3 by simp have "x \ set |h2 \ get_disconnected_nodes xb|\<^sub>r" using a12 a8 a4 \xb |\| document_ptr_kinds h'\ by (meson UN_I disjoint_iff_not_equal fmember.rep_eq) then have "x = child" using f13 a11 a10 a7 a5 a2 a1 by (metis (no_types, lifting) select_result_I2 set_ConsD) then have "child \ set disc_nodes_old_document_h2" using f14 a12 a8 a6 a4 by (metis \type_wf h'\ adopt_node_removes_child assms(1) assms(2) type_wf get_child_nodes_ok known_ptrs local.known_ptrs_known_ptr object_ptr_kinds_h2_eq3 object_ptr_kinds_h3_eq3 object_ptr_kinds_h_eq3 returns_result_select_result) then show ?thesis using \child \ set disc_nodes_old_document_h2\ by fastforce qed qed ultimately show ?thesis using \type_wf h'\ \known_ptrs h'\ \a_owner_document_valid h'\ heap_is_wellformed_def by blast qed then show "heap_is_wellformed h'" and "known_ptrs h'" and "type_wf h'" by auto qed lemma adopt_node_node_in_disconnected_nodes: assumes wellformed: "heap_is_wellformed h" and adopt_node: "h \ adopt_node owner_document node_ptr \\<^sub>h h'" and "h' \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "node_ptr \ set disc_nodes" proof - obtain old_document parent_opt h2 where old_document: "h \ get_owner_document (cast node_ptr) \\<^sub>r old_document" and parent_opt: "h \ get_parent node_ptr \\<^sub>r parent_opt" and h2: "h \ (case parent_opt of Some parent \ remove_child parent node_ptr | None \ return ()) \\<^sub>h h2" and h': "h2 \ (if owner_document \ old_document then do { old_disc_nodes \ get_disconnected_nodes old_document; set_disconnected_nodes old_document (remove1 node_ptr old_disc_nodes); disc_nodes \ get_disconnected_nodes owner_document; set_disconnected_nodes owner_document (node_ptr # disc_nodes) } else do { return () }) \\<^sub>h h'" using assms(2) by(auto simp add: adopt_node_def elim!: bind_returns_heap_E dest!: pure_returns_heap_eq[rotated, OF get_owner_document_pure] pure_returns_heap_eq[rotated, OF get_parent_pure]) show ?thesis proof (cases "owner_document = old_document") case True then show ?thesis proof (insert parent_opt h2, induct parent_opt) case None then have "h = h'" using h2 h' by(auto) then show ?case using in_disconnected_nodes_no_parent assms None old_document by blast next case (Some parent) then show ?case using remove_child_in_disconnected_nodes known_ptrs True h' assms(3) old_document by auto qed next case False then show ?thesis using assms(3) h' list.set_intros(1) select_result_I2 set_disconnected_nodes_get_disconnected_nodes apply(auto elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated])[1] proof - fix x and h'a and xb assume a1: "h' \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes" assume a2: "\h document_ptr disc_nodes h'. h \ set_disconnected_nodes document_ptr disc_nodes \\<^sub>h h' \ h' \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes" assume "h'a \ set_disconnected_nodes owner_document (node_ptr # xb) \\<^sub>h h'" then have "node_ptr # xb = disc_nodes" using a2 a1 by (meson returns_result_eq) then show ?thesis by (meson list.set_intros(1)) qed qed qed end interpretation i_adopt_node_wf?: l_adopt_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_owner_document get_parent get_parent_locs remove_child remove_child_locs get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs adopt_node adopt_node_locs known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs set_child_nodes set_child_nodes_locs remove heap_is_wellformed parent_child_rel by(simp add: l_adopt_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) declare l_adopt_node_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms[instances] interpretation i_adopt_node_wf2?: l_adopt_node_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_owner_document get_parent get_parent_locs remove_child remove_child_locs get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs adopt_node adopt_node_locs known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs set_child_nodes set_child_nodes_locs remove heap_is_wellformed parent_child_rel get_root_node get_root_node_locs by(simp add: l_adopt_node_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) declare l_adopt_node_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms[instances] locale l_adopt_node_wf = l_heap_is_wellformed + l_known_ptrs + l_type_wf + l_adopt_node_defs + l_get_child_nodes_defs + l_get_disconnected_nodes_defs + assumes adopt_node_preserves_wellformedness: "heap_is_wellformed h \ h \ adopt_node document_ptr child \\<^sub>h h' \ known_ptrs h \ type_wf h \ heap_is_wellformed h'" assumes adopt_node_removes_child: "heap_is_wellformed h \ h \ adopt_node owner_document node_ptr \\<^sub>h h2 \ h2 \ get_child_nodes ptr \\<^sub>r children \ known_ptrs h \ type_wf h \ node_ptr \ set children" assumes adopt_node_node_in_disconnected_nodes: "heap_is_wellformed h \ h \ adopt_node owner_document node_ptr \\<^sub>h h' \ h' \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes \ known_ptrs h \ type_wf h \ node_ptr \ set disc_nodes" assumes adopt_node_removes_first_child: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ adopt_node owner_document node \\<^sub>h h' \ h \ get_child_nodes ptr' \\<^sub>r node # children \ h' \ get_child_nodes ptr' \\<^sub>r children" assumes adopt_node_document_in_heap: "heap_is_wellformed h \ known_ptrs h \ type_wf h \ h \ ok (adopt_node owner_document node) \ owner_document |\| document_ptr_kinds h" assumes adopt_node_preserves_type_wf: "heap_is_wellformed h \ h \ adopt_node document_ptr child \\<^sub>h h' \ known_ptrs h \ type_wf h \ type_wf h'" assumes adopt_node_preserves_known_ptrs: "heap_is_wellformed h \ h \ adopt_node document_ptr child \\<^sub>h h' \ known_ptrs h \ type_wf h \ known_ptrs h'" lemma adopt_node_wf_is_l_adopt_node_wf [instances]: "l_adopt_node_wf type_wf known_ptr heap_is_wellformed parent_child_rel get_child_nodes get_disconnected_nodes known_ptrs adopt_node" using heap_is_wellformed_is_l_heap_is_wellformed known_ptrs_is_l_known_ptrs apply(auto simp add: l_adopt_node_wf_def l_adopt_node_wf_axioms_def)[1] using adopt_node_preserves_wellformedness apply blast using adopt_node_removes_child apply blast using adopt_node_node_in_disconnected_nodes apply blast using adopt_node_removes_first_child apply blast using adopt_node_document_in_heap apply blast using adopt_node_preserves_wellformedness apply blast using adopt_node_preserves_wellformedness apply blast done subsection \insert\_before\ locale l_insert_before_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_insert_before\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_adopt_node_wf + l_set_disconnected_nodes_get_child_nodes + l_heap_is_wellformed begin lemma insert_before_removes_child: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "ptr \ ptr'" assumes "h \ insert_before ptr node child \\<^sub>h h'" assumes "h \ get_child_nodes ptr' \\<^sub>r node # children" shows "h' \ get_child_nodes ptr' \\<^sub>r children" proof - obtain owner_document h2 h3 disc_nodes reference_child where "h \ (if Some node = child then a_next_sibling node else return child) \\<^sub>r reference_child" and "h \ get_owner_document ptr \\<^sub>r owner_document" and h2: "h \ adopt_node owner_document node \\<^sub>h h2" and "h2 \ get_disconnected_nodes owner_document \\<^sub>r disc_nodes" and h3: "h2 \ set_disconnected_nodes owner_document (remove1 node disc_nodes) \\<^sub>h h3" and h': "h3 \ a_insert_node ptr node reference_child \\<^sub>h h'" using assms(5) by(auto simp add: insert_before_def a_ensure_pre_insertion_validity_def elim!: bind_returns_heap_E bind_returns_result_E bind_returns_heap_E2[rotated, OF get_child_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] bind_returns_heap_E2[rotated, OF get_ancestors_pure, rotated] bind_returns_heap_E2[rotated, OF get_owner_document_pure, rotated] bind_returns_heap_E2[rotated, OF next_sibling_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] split: if_splits option.splits) have "h2 \ get_child_nodes ptr' \\<^sub>r children" using h2 adopt_node_removes_first_child assms(1) assms(2) assms(3) assms(6) by simp then have "h3 \ get_child_nodes ptr' \\<^sub>r children" using h3 by(auto simp add: set_disconnected_nodes_get_child_nodes dest!: reads_writes_separate_forwards[OF get_child_nodes_reads set_disconnected_nodes_writes]) then show ?thesis using h' assms(4) apply(auto simp add: a_insert_node_def elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_child_nodes_pure, rotated])[1] by(auto simp add: set_child_nodes_get_child_nodes_different_pointers elim!: reads_writes_separate_forwards[OF get_child_nodes_reads set_child_nodes_writes]) qed end locale l_insert_before_wf = l_heap_is_wellformed_defs + l_type_wf + l_known_ptrs + l_insert_before_defs + l_get_child_nodes_defs + assumes insert_before_removes_child: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ ptr \ ptr' \ h \ insert_before ptr node child \\<^sub>h h' \ h \ get_child_nodes ptr' \\<^sub>r node # children \ h' \ get_child_nodes ptr' \\<^sub>r children" interpretation i_insert_before_wf?: l_insert_before_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_parent get_parent_locs get_child_nodes get_child_nodes_locs set_child_nodes set_child_nodes_locs get_ancestors get_ancestors_locs adopt_node adopt_node_locs set_disconnected_nodes set_disconnected_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs get_owner_document insert_before insert_before_locs append_child type_wf known_ptr known_ptrs heap_is_wellformed parent_child_rel by(simp add: l_insert_before_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) declare l_insert_before_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] lemma insert_before_wf_is_l_insert_before_wf [instances]: "l_insert_before_wf heap_is_wellformed type_wf known_ptr known_ptrs insert_before get_child_nodes" apply(auto simp add: l_insert_before_wf_def l_insert_before_wf_axioms_def instances)[1] using insert_before_removes_child apply fast done locale l_insert_before_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_insert_before_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_set_child_nodes_get_disconnected_nodes + l_remove_child + l_get_root_node_wf + l_set_disconnected_nodes_get_disconnected_nodes_wf + l_set_disconnected_nodes_get_ancestors + l_get_ancestors_wf + l_get_owner_document + l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_get_owner_document_wf begin lemma insert_before_preserves_acyclitity: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ insert_before ptr node child \\<^sub>h h'" shows "acyclic (parent_child_rel h')" proof - obtain ancestors reference_child owner_document h2 h3 disconnected_nodes_h2 where ancestors: "h \ get_ancestors ptr \\<^sub>r ancestors" and node_not_in_ancestors: "cast node \ set ancestors" and reference_child: "h \ (if Some node = child then a_next_sibling node else return child) \\<^sub>r reference_child" and owner_document: "h \ get_owner_document ptr \\<^sub>r owner_document" and h2: "h \ adopt_node owner_document node \\<^sub>h h2" and disconnected_nodes_h2: "h2 \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h2" and h3: "h2 \ set_disconnected_nodes owner_document (remove1 node disconnected_nodes_h2) \\<^sub>h h3" and h': "h3 \ a_insert_node ptr node reference_child \\<^sub>h h'" using assms(4) by(auto simp add: insert_before_def a_ensure_pre_insertion_validity_def elim!: bind_returns_heap_E bind_returns_result_E bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] bind_returns_heap_E2[rotated, OF get_child_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_ancestors_pure, rotated] bind_returns_heap_E2[rotated, OF next_sibling_pure, rotated] bind_returns_heap_E2[rotated, OF get_owner_document_pure, rotated] split: if_splits option.splits) have "known_ptr ptr" by (meson get_owner_document_ptr_in_heap is_OK_returns_result_I assms l_known_ptrs.known_ptrs_known_ptr l_known_ptrs_axioms owner_document) have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF adopt_node_writes h2] using assms adopt_node_types_preserved by(auto simp add: a_remove_child_locs_def reflp_def transp_def) then have "type_wf h3" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h3] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) then have "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF insert_node_writes h'] using set_child_nodes_types_preserved by(auto simp add: reflp_def transp_def) have object_ptr_kinds_M_eq3_h: "object_ptr_kinds h = object_ptr_kinds h2" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF adopt_node_writes h2]) using adopt_node_pointers_preserved apply blast by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h2 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs ) then have object_ptr_kinds_M_eq2_h: "|h \ object_ptr_kinds_M|\<^sub>r = |h2 \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h: "|h \ node_ptr_kinds_M|\<^sub>r = |h2 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have "known_ptrs h2" using assms object_ptr_kinds_M_eq3_h known_ptrs_preserved by blast have wellformed_h2: "heap_is_wellformed h2" using adopt_node_preserves_wellformedness[OF assms(1) h2] assms by simp have object_ptr_kinds_M_eq3_h2: "object_ptr_kinds h2 = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h3]) unfolding a_remove_child_locs_def using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h2: "\ptrs. h2 \ object_ptr_kinds_M \\<^sub>r ptrs = h3 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_M_eq2_h2: "|h2 \ object_ptr_kinds_M|\<^sub>r = |h3 \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h2: "|h2 \ node_ptr_kinds_M|\<^sub>r = |h3 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have document_ptr_kinds_eq2_h2: "|h2 \ document_ptr_kinds_M|\<^sub>r = |h3 \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_M_eq2_h2 document_ptr_kinds_M_eq by auto have "known_ptrs h3" using object_ptr_kinds_M_eq3_h2 known_ptrs_preserved \known_ptrs h2\ by blast have object_ptr_kinds_M_eq3_h': "object_ptr_kinds h3 = object_ptr_kinds h'" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF insert_node_writes h']) unfolding a_remove_child_locs_def using set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h3: "\ptrs. h3 \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_M_eq2_h3: "|h3 \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h3: "|h3 \ node_ptr_kinds_M|\<^sub>r = |h' \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have document_ptr_kinds_eq2_h3: "|h3 \ document_ptr_kinds_M|\<^sub>r = |h' \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_M_eq2_h3 document_ptr_kinds_M_eq by auto have "known_ptrs h'" using object_ptr_kinds_M_eq3_h' known_ptrs_preserved \known_ptrs h3\ by blast have disconnected_nodes_eq_h2: "\doc_ptr disc_nodes. owner_document \ doc_ptr \ h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (auto simp add: set_disconnected_nodes_get_disconnected_nodes_different_pointers) then have disconnected_nodes_eq2_h2: "\doc_ptr. doc_ptr \ owner_document \ |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have disconnected_nodes_h3: "h3 \ get_disconnected_nodes owner_document \\<^sub>r remove1 node disconnected_nodes_h2" using h3 set_disconnected_nodes_get_disconnected_nodes by blast have disconnected_nodes_eq_h3: "\doc_ptr disc_nodes. h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h' \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads insert_node_writes h' apply(rule reads_writes_preserved) using set_child_nodes_get_disconnected_nodes by fast then have disconnected_nodes_eq2_h3: "\doc_ptr. |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have children_eq_h2: "\ptr' children. h2 \ get_child_nodes ptr' \\<^sub>r children = h3 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (auto simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h2: "\ptr'. |h2 \ get_child_nodes ptr'|\<^sub>r = |h3 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have children_eq_h3: "\ptr' children. ptr \ ptr' \ h3 \ get_child_nodes ptr' \\<^sub>r children = h' \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads insert_node_writes h' apply(rule reads_writes_preserved) by (auto simp add: set_child_nodes_get_child_nodes_different_pointers) then have children_eq2_h3: "\ptr'. ptr \ ptr' \ |h3 \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force obtain children_h3 where children_h3: "h3 \ get_child_nodes ptr \\<^sub>r children_h3" using h' a_insert_node_def by auto have children_h': "h' \ get_child_nodes ptr \\<^sub>r insert_before_list node reference_child children_h3" using h' \type_wf h3\ \known_ptr ptr\ by(auto simp add: a_insert_node_def elim!: bind_returns_heap_E2 dest!: set_child_nodes_get_child_nodes returns_result_eq[OF children_h3]) have ptr_in_heap: "ptr |\| object_ptr_kinds h3" using children_h3 get_child_nodes_ptr_in_heap by blast have node_in_heap: "node |\| node_ptr_kinds h" using h2 adopt_node_child_in_heap by fast have child_not_in_any_children: "\p children. h2 \ get_child_nodes p \\<^sub>r children \ node \ set children" using assms h2 adopt_node_removes_child by auto have "node \ set disconnected_nodes_h2" using disconnected_nodes_h2 h2 adopt_node_node_in_disconnected_nodes assms(1) \type_wf h\ \known_ptrs h\ by blast have node_not_in_disconnected_nodes: "\d. d |\| document_ptr_kinds h3 \ node \ set |h3 \ get_disconnected_nodes d|\<^sub>r" proof - fix d assume "d |\| document_ptr_kinds h3" show "node \ set |h3 \ get_disconnected_nodes d|\<^sub>r" proof (cases "d = owner_document") case True then show ?thesis using disconnected_nodes_h2 wellformed_h2 h3 remove_from_disconnected_nodes_removes wellformed_h2 \d |\| document_ptr_kinds h3\ disconnected_nodes_h3 by fastforce next case False then have "set |h2 \ get_disconnected_nodes d|\<^sub>r \ set |h2 \ get_disconnected_nodes owner_document|\<^sub>r = {}" using distinct_concat_map_E(1) wellformed_h2 by (metis (no_types, lifting) \d |\| document_ptr_kinds h3\ \type_wf h2\ disconnected_nodes_h2 document_ptr_kinds_M_def document_ptr_kinds_eq2_h2 l_ptr_kinds_M.ptr_kinds_ptr_kinds_M local.get_disconnected_nodes_ok local.heap_is_wellformed_one_disc_parent returns_result_select_result select_result_I2) then show ?thesis using disconnected_nodes_eq2_h2[OF False] \node \ set disconnected_nodes_h2\ disconnected_nodes_h2 by fastforce qed qed have "cast node \ ptr" using ancestors node_not_in_ancestors get_ancestors_ptr by fast obtain ancestors_h2 where ancestors_h2: "h2 \ get_ancestors ptr \\<^sub>r ancestors_h2" using get_ancestors_ok object_ptr_kinds_M_eq2_h2 \known_ptrs h2\ \type_wf h2\ by (metis is_OK_returns_result_E object_ptr_kinds_M_eq3_h2 ptr_in_heap wellformed_h2) have ancestors_h3: "h3 \ get_ancestors ptr \\<^sub>r ancestors_h2" using get_ancestors_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_separate_forwards) using \heap_is_wellformed h2\ ancestors_h2 by (auto simp add: set_disconnected_nodes_get_ancestors) have node_not_in_ancestors_h2: "cast node \ set ancestors_h2" apply(rule get_ancestors_remains_not_in_ancestors[OF assms(1) wellformed_h2 ancestors ancestors_h2]) using adopt_node_children_subset using h2 \known_ptrs h\ \ type_wf h\ apply(blast) using node_not_in_ancestors apply(blast) using object_ptr_kinds_M_eq3_h apply(blast) using \known_ptrs h\ apply(blast) using \type_wf h\ apply(blast) using \type_wf h2\ by blast have "acyclic (parent_child_rel h2)" using wellformed_h2 by (simp add: heap_is_wellformed_def acyclic_heap_def) then have "acyclic (parent_child_rel h3)" by(auto simp add: parent_child_rel_def object_ptr_kinds_M_eq3_h2 children_eq2_h2) moreover have "cast node \ {x. (x, ptr) \ (parent_child_rel h2)\<^sup>*}" using adopt_node_removes_child using ancestors node_not_in_ancestors using \known_ptrs h2\ \type_wf h2\ ancestors_h2 local.get_ancestors_parent_child_rel node_not_in_ancestors_h2 wellformed_h2 by blast then have "cast node \ {x. (x, ptr) \ (parent_child_rel h3)\<^sup>*}" by(auto simp add: parent_child_rel_def object_ptr_kinds_M_eq3_h2 children_eq2_h2) moreover have "parent_child_rel h' = insert (ptr, cast node) ((parent_child_rel h3))" using children_h3 children_h' ptr_in_heap apply(auto simp add: parent_child_rel_def object_ptr_kinds_M_eq3_h' children_eq2_h3 insert_before_list_node_in_set)[1] apply (metis (no_types, lifting) children_eq2_h3 insert_before_list_in_set select_result_I2) by (metis (no_types, lifting) children_eq2_h3 imageI insert_before_list_in_set select_result_I2) ultimately show "acyclic (parent_child_rel h')" by (auto simp add: heap_is_wellformed_def) qed lemma insert_before_heap_is_wellformed_preserved: assumes wellformed: "heap_is_wellformed h" and insert_before: "h \ insert_before ptr node child \\<^sub>h h'" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "heap_is_wellformed h'" and "type_wf h'" and "known_ptrs h'" proof - obtain ancestors reference_child owner_document h2 h3 disconnected_nodes_h2 where ancestors: "h \ get_ancestors ptr \\<^sub>r ancestors" and node_not_in_ancestors: "cast node \ set ancestors" and reference_child: "h \ (if Some node = child then a_next_sibling node else return child) \\<^sub>r reference_child" and owner_document: "h \ get_owner_document ptr \\<^sub>r owner_document" and h2: "h \ adopt_node owner_document node \\<^sub>h h2" and disconnected_nodes_h2: "h2 \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h2" and h3: "h2 \ set_disconnected_nodes owner_document (remove1 node disconnected_nodes_h2) \\<^sub>h h3" and h': "h3 \ a_insert_node ptr node reference_child \\<^sub>h h'" using assms(2) by(auto simp add: insert_before_def a_ensure_pre_insertion_validity_def elim!: bind_returns_heap_E bind_returns_result_E bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] bind_returns_heap_E2[rotated, OF get_child_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_ancestors_pure, rotated] bind_returns_heap_E2[rotated, OF next_sibling_pure, rotated] bind_returns_heap_E2[rotated, OF get_owner_document_pure, rotated] split: if_splits option.splits) have "known_ptr ptr" by (meson get_owner_document_ptr_in_heap is_OK_returns_result_I known_ptrs l_known_ptrs.known_ptrs_known_ptr l_known_ptrs_axioms owner_document) have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF adopt_node_writes h2] using type_wf adopt_node_types_preserved by(auto simp add: a_remove_child_locs_def reflp_def transp_def) then have "type_wf h3" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h3] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) then show "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF insert_node_writes h'] using set_child_nodes_types_preserved by(auto simp add: reflp_def transp_def) have object_ptr_kinds_M_eq3_h: "object_ptr_kinds h = object_ptr_kinds h2" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF adopt_node_writes h2]) using adopt_node_pointers_preserved apply blast by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h2 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs ) then have object_ptr_kinds_M_eq2_h: "|h \ object_ptr_kinds_M|\<^sub>r = |h2 \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h: "|h \ node_ptr_kinds_M|\<^sub>r = |h2 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have "known_ptrs h2" using known_ptrs object_ptr_kinds_M_eq3_h known_ptrs_preserved by blast have wellformed_h2: "heap_is_wellformed h2" using adopt_node_preserves_wellformedness[OF wellformed h2] known_ptrs type_wf . have object_ptr_kinds_M_eq3_h2: "object_ptr_kinds h2 = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h3]) unfolding a_remove_child_locs_def using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h2: "\ptrs. h2 \ object_ptr_kinds_M \\<^sub>r ptrs = h3 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_M_eq2_h2: "|h2 \ object_ptr_kinds_M|\<^sub>r = |h3 \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h2: "|h2 \ node_ptr_kinds_M|\<^sub>r = |h3 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have document_ptr_kinds_eq2_h2: "|h2 \ document_ptr_kinds_M|\<^sub>r = |h3 \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_M_eq2_h2 document_ptr_kinds_M_eq by auto have "known_ptrs h3" using object_ptr_kinds_M_eq3_h2 known_ptrs_preserved \known_ptrs h2\ by blast have object_ptr_kinds_M_eq3_h': "object_ptr_kinds h3 = object_ptr_kinds h'" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF insert_node_writes h']) unfolding a_remove_child_locs_def using set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h3: "\ptrs. h3 \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_M_eq2_h3: "|h3 \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h3: "|h3 \ node_ptr_kinds_M|\<^sub>r = |h' \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have document_ptr_kinds_eq2_h3: "|h3 \ document_ptr_kinds_M|\<^sub>r = |h' \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_M_eq2_h3 document_ptr_kinds_M_eq by auto show "known_ptrs h'" using object_ptr_kinds_M_eq3_h' known_ptrs_preserved \known_ptrs h3\ by blast have disconnected_nodes_eq_h2: "\doc_ptr disc_nodes. owner_document \ doc_ptr \ h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (auto simp add: set_disconnected_nodes_get_disconnected_nodes_different_pointers) then have disconnected_nodes_eq2_h2: "\doc_ptr. doc_ptr \ owner_document \ |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have disconnected_nodes_h3: "h3 \ get_disconnected_nodes owner_document \\<^sub>r remove1 node disconnected_nodes_h2" using h3 set_disconnected_nodes_get_disconnected_nodes by blast have disconnected_nodes_eq_h3: "\doc_ptr disc_nodes. h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h' \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads insert_node_writes h' apply(rule reads_writes_preserved) using set_child_nodes_get_disconnected_nodes by fast then have disconnected_nodes_eq2_h3: "\doc_ptr. |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have children_eq_h2: "\ptr' children. h2 \ get_child_nodes ptr' \\<^sub>r children = h3 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (auto simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h2: "\ptr'. |h2 \ get_child_nodes ptr'|\<^sub>r = |h3 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have children_eq_h3: "\ptr' children. ptr \ ptr' \ h3 \ get_child_nodes ptr' \\<^sub>r children = h' \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads insert_node_writes h' apply(rule reads_writes_preserved) by (auto simp add: set_child_nodes_get_child_nodes_different_pointers) then have children_eq2_h3: "\ptr'. ptr \ ptr' \ |h3 \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force obtain children_h3 where children_h3: "h3 \ get_child_nodes ptr \\<^sub>r children_h3" using h' a_insert_node_def by auto have children_h': "h' \ get_child_nodes ptr \\<^sub>r insert_before_list node reference_child children_h3" using h' \type_wf h3\ \known_ptr ptr\ by(auto simp add: a_insert_node_def elim!: bind_returns_heap_E2 dest!: set_child_nodes_get_child_nodes returns_result_eq[OF children_h3]) have ptr_in_heap: "ptr |\| object_ptr_kinds h3" using children_h3 get_child_nodes_ptr_in_heap by blast have node_in_heap: "node |\| node_ptr_kinds h" using h2 adopt_node_child_in_heap by fast have child_not_in_any_children: "\p children. h2 \ get_child_nodes p \\<^sub>r children \ node \ set children" using wellformed h2 adopt_node_removes_child \type_wf h\ \known_ptrs h\ by auto have "node \ set disconnected_nodes_h2" using disconnected_nodes_h2 h2 adopt_node_node_in_disconnected_nodes assms(1) \type_wf h\ \known_ptrs h\ by blast have node_not_in_disconnected_nodes: "\d. d |\| document_ptr_kinds h3 \ node \ set |h3 \ get_disconnected_nodes d|\<^sub>r" proof - fix d assume "d |\| document_ptr_kinds h3" show "node \ set |h3 \ get_disconnected_nodes d|\<^sub>r" proof (cases "d = owner_document") case True then show ?thesis using disconnected_nodes_h2 wellformed_h2 h3 remove_from_disconnected_nodes_removes wellformed_h2 \d |\| document_ptr_kinds h3\ disconnected_nodes_h3 by fastforce next case False then have "set |h2 \ get_disconnected_nodes d|\<^sub>r \ set |h2 \ get_disconnected_nodes owner_document|\<^sub>r = {}" using distinct_concat_map_E(1) wellformed_h2 by (metis (no_types, lifting) \d |\| document_ptr_kinds h3\ \type_wf h2\ disconnected_nodes_h2 document_ptr_kinds_M_def document_ptr_kinds_eq2_h2 l_ptr_kinds_M.ptr_kinds_ptr_kinds_M local.get_disconnected_nodes_ok local.heap_is_wellformed_one_disc_parent returns_result_select_result select_result_I2) then show ?thesis using disconnected_nodes_eq2_h2[OF False] \node \ set disconnected_nodes_h2\ disconnected_nodes_h2 by fastforce qed qed have "cast node \ ptr" using ancestors node_not_in_ancestors get_ancestors_ptr by fast obtain ancestors_h2 where ancestors_h2: "h2 \ get_ancestors ptr \\<^sub>r ancestors_h2" using get_ancestors_ok object_ptr_kinds_M_eq2_h2 \known_ptrs h2\ \type_wf h2\ by (metis is_OK_returns_result_E object_ptr_kinds_M_eq3_h2 ptr_in_heap wellformed_h2) have ancestors_h3: "h3 \ get_ancestors ptr \\<^sub>r ancestors_h2" using get_ancestors_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_separate_forwards) using \heap_is_wellformed h2\ ancestors_h2 by (auto simp add: set_disconnected_nodes_get_ancestors) have node_not_in_ancestors_h2: "cast node \ set ancestors_h2" apply(rule get_ancestors_remains_not_in_ancestors[OF assms(1) wellformed_h2 ancestors ancestors_h2]) using adopt_node_children_subset using h2 \known_ptrs h\ \ type_wf h\ apply(blast) using node_not_in_ancestors apply(blast) using object_ptr_kinds_M_eq3_h apply(blast) using \known_ptrs h\ apply(blast) using \type_wf h\ apply(blast) using \type_wf h2\ by blast moreover have "a_acyclic_heap h'" proof - have "acyclic (parent_child_rel h2)" using wellformed_h2 by (simp add: heap_is_wellformed_def acyclic_heap_def) then have "acyclic (parent_child_rel h3)" by(auto simp add: parent_child_rel_def object_ptr_kinds_M_eq3_h2 children_eq2_h2) moreover have "cast node \ {x. (x, ptr) \ (parent_child_rel h2)\<^sup>*}" using get_ancestors_parent_child_rel node_not_in_ancestors_h2 \known_ptrs h2\ \type_wf h2\ using ancestors_h2 wellformed_h2 by blast then have "cast node \ {x. (x, ptr) \ (parent_child_rel h3)\<^sup>*}" by(auto simp add: parent_child_rel_def object_ptr_kinds_M_eq3_h2 children_eq2_h2) moreover have "parent_child_rel h' = insert (ptr, cast node) ((parent_child_rel h3))" using children_h3 children_h' ptr_in_heap apply(auto simp add: parent_child_rel_def object_ptr_kinds_M_eq3_h' children_eq2_h3 insert_before_list_node_in_set)[1] apply (metis (no_types, lifting) children_eq2_h3 insert_before_list_in_set select_result_I2) by (metis (no_types, lifting) children_eq2_h3 imageI insert_before_list_in_set select_result_I2) ultimately show ?thesis by(auto simp add: acyclic_heap_def) qed moreover have "a_all_ptrs_in_heap h2" using wellformed_h2 by (simp add: heap_is_wellformed_def) have "a_all_ptrs_in_heap h'" proof - have "a_all_ptrs_in_heap h3" using \a_all_ptrs_in_heap h2\ apply(auto simp add: a_all_ptrs_in_heap_def object_ptr_kinds_M_eq2_h2 node_ptr_kinds_eq2_h2 children_eq_h2)[1] using disconnected_nodes_eq2_h2 disconnected_nodes_h2 disconnected_nodes_h3 using node_ptr_kinds_eq2_h2 apply auto[1] apply (metis \known_ptrs h2\ \type_wf h3\ children_eq_h2 local.get_child_nodes_ok local.heap_is_wellformed_children_in_heap local.known_ptrs_known_ptr object_ptr_kinds_M_eq3_h2 returns_result_select_result wellformed_h2) by (metis (no_types, lifting) disconnected_nodes_eq2_h2 disconnected_nodes_h2 disconnected_nodes_h3 document_ptr_kinds_commutes finite_set_in node_ptr_kinds_commutes object_ptr_kinds_M_eq3_h2 select_result_I2 set_remove1_subset subsetD) have "set children_h3 \ set |h' \ node_ptr_kinds_M|\<^sub>r" using children_h3 \a_all_ptrs_in_heap h3\ apply(auto simp add: a_all_ptrs_in_heap_def node_ptr_kinds_eq2_h3)[1] by (metis children_eq_h2 l_heap_is_wellformed.heap_is_wellformed_children_in_heap local.l_heap_is_wellformed_axioms node_ptr_kinds_commutes object_ptr_kinds_M_eq3_h' object_ptr_kinds_M_eq3_h2 wellformed_h2) then have "set (insert_before_list node reference_child children_h3) \ set |h' \ node_ptr_kinds_M|\<^sub>r" using node_in_heap apply(auto simp add: node_ptr_kinds_eq2_h node_ptr_kinds_eq2_h2 node_ptr_kinds_eq2_h3)[1] by (metis (no_types, hide_lams) contra_subsetD finite_set_in insert_before_list_in_set node_ptr_kinds_commutes object_ptr_kinds_M_eq3_h object_ptr_kinds_M_eq3_h' object_ptr_kinds_M_eq3_h2) then show ?thesis using \a_all_ptrs_in_heap h3\ apply(auto simp add: object_ptr_kinds_M_eq3_h' a_all_ptrs_in_heap_def node_ptr_kinds_def node_ptr_kinds_eq2_h3 disconnected_nodes_eq_h3)[1] using children_eq_h3 children_h' apply (metis (no_types, lifting) children_eq2_h3 finite_set_in select_result_I2 subsetD) by (metis (no_types) \type_wf h'\ disconnected_nodes_eq2_h3 disconnected_nodes_eq_h3 finite_set_in is_OK_returns_result_I local.get_disconnected_nodes_ok local.get_disconnected_nodes_ptr_in_heap returns_result_select_result subsetD) qed moreover have "a_distinct_lists h2" using wellformed_h2 by (simp add: heap_is_wellformed_def) then have "a_distinct_lists h3" proof(auto simp add: a_distinct_lists_def object_ptr_kinds_M_eq2_h2 document_ptr_kinds_eq2_h2 children_eq2_h2 intro!: distinct_concat_map_I)[1] fix x assume 1: "x |\| document_ptr_kinds h3" and 2: "distinct (concat (map (\document_ptr. |h2 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h3)))))" show "distinct |h3 \ get_disconnected_nodes x|\<^sub>r" using distinct_concat_map_E(2)[OF 2] select_result_I2[OF disconnected_nodes_h3] disconnected_nodes_eq2_h2 select_result_I2[OF disconnected_nodes_h2] 1 by (metis (full_types) distinct_remove1 finite_fset fmember.rep_eq set_sorted_list_of_set) next fix x y xa assume 1: "distinct (concat (map (\document_ptr. |h2 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h3)))))" and 2: "x |\| document_ptr_kinds h3" and 3: "y |\| document_ptr_kinds h3" and 4: "x \ y" and 5: "xa \ set |h3 \ get_disconnected_nodes x|\<^sub>r" and 6: "xa \ set |h3 \ get_disconnected_nodes y|\<^sub>r" show False proof (cases "x = owner_document") case True then have "y \ owner_document" using 4 by simp show ?thesis using distinct_concat_map_E(1)[OF 1] using 2 3 4 5 6 select_result_I2[OF disconnected_nodes_h3] select_result_I2[OF disconnected_nodes_h2] apply(auto simp add: True disconnected_nodes_eq2_h2[OF \y \ owner_document\])[1] by (metis (no_types, hide_lams) disconnected_nodes_eq2_h2 disjoint_iff_not_equal notin_set_remove1) next case False then show ?thesis proof (cases "y = owner_document") case True then show ?thesis using distinct_concat_map_E(1)[OF 1] using 2 3 4 5 6 select_result_I2[OF disconnected_nodes_h3] select_result_I2[OF disconnected_nodes_h2] apply(auto simp add: True disconnected_nodes_eq2_h2[OF \x \ owner_document\])[1] by (metis (no_types, hide_lams) disconnected_nodes_eq2_h2 disjoint_iff_not_equal notin_set_remove1) next case False then show ?thesis using distinct_concat_map_E(1)[OF 1, simplified, OF 2 3 4] 5 6 using disconnected_nodes_eq2_h2 disconnected_nodes_h2 disconnected_nodes_h3 disjoint_iff_not_equal finite_fset fmember.rep_eq notin_set_remove1 select_result_I2 set_sorted_list_of_set by (metis (no_types, lifting)) qed qed next fix x xa xb assume 1: "(\x\fset (object_ptr_kinds h3). set |h3 \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h3). set |h2 \ get_disconnected_nodes x|\<^sub>r) = {}" and 2: "xa |\| object_ptr_kinds h3" and 3: "x \ set |h3 \ get_child_nodes xa|\<^sub>r" and 4: "xb |\| document_ptr_kinds h3" and 5: "x \ set |h3 \ get_disconnected_nodes xb|\<^sub>r" have 6: "set |h3 \ get_child_nodes xa|\<^sub>r \ set |h2 \ get_disconnected_nodes xb|\<^sub>r = {}" using 1 2 4 by (metis \type_wf h2\ children_eq2_h2 document_ptr_kinds_commutes known_ptrs local.get_child_nodes_ok local.get_disconnected_nodes_ok local.heap_is_wellformed_children_disc_nodes_different local.known_ptrs_known_ptr object_ptr_kinds_M_eq3_h object_ptr_kinds_M_eq3_h2 returns_result_select_result wellformed_h2) show False proof (cases "xb = owner_document") case True then show ?thesis using select_result_I2[OF disconnected_nodes_h3,folded select_result_I2[OF disconnected_nodes_h2]] by (metis (no_types, lifting) "3" "5" "6" disjoint_iff_not_equal notin_set_remove1) next case False show ?thesis using 2 3 4 5 6 unfolding disconnected_nodes_eq2_h2[OF False] by auto qed qed then have "a_distinct_lists h'" proof(auto simp add: a_distinct_lists_def document_ptr_kinds_eq2_h3 object_ptr_kinds_M_eq2_h3 disconnected_nodes_eq2_h3 intro!: distinct_concat_map_I)[1] fix x assume 1: "distinct (concat (map (\ptr. |h3 \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h')))))" and 2: "x |\| object_ptr_kinds h'" have 3: "\p. p |\| object_ptr_kinds h' \ distinct |h3 \ get_child_nodes p|\<^sub>r" using 1 by (auto elim: distinct_concat_map_E) show "distinct |h' \ get_child_nodes x|\<^sub>r" proof(cases "ptr = x") case True show ?thesis using 3[OF 2] children_h3 children_h' by(auto simp add: True insert_before_list_distinct dest: child_not_in_any_children[unfolded children_eq_h2]) next case False show ?thesis using children_eq2_h3[OF False] 3[OF 2] by auto qed next fix x y xa assume 1: "distinct (concat (map (\ptr. |h3 \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h')))))" and 2: "x |\| object_ptr_kinds h'" and 3: "y |\| object_ptr_kinds h'" and 4: "x \ y" and 5: "xa \ set |h' \ get_child_nodes x|\<^sub>r" and 6: "xa \ set |h' \ get_child_nodes y|\<^sub>r" have 7:"set |h3 \ get_child_nodes x|\<^sub>r \ set |h3 \ get_child_nodes y|\<^sub>r = {}" using distinct_concat_map_E(1)[OF 1] 2 3 4 by auto show False proof (cases "ptr = x") case True then have "ptr \ y" using 4 by simp then show ?thesis using children_h3 children_h' child_not_in_any_children[unfolded children_eq_h2] 5 6 apply(auto simp add: True children_eq2_h3[OF \ptr \ y\])[1] by (metis (no_types, hide_lams) "3" "7" \type_wf h3\ children_eq2_h3 disjoint_iff_not_equal get_child_nodes_ok insert_before_list_in_set known_ptrs local.known_ptrs_known_ptr object_ptr_kinds_M_eq3_h object_ptr_kinds_M_eq3_h' object_ptr_kinds_M_eq3_h2 returns_result_select_result select_result_I2) next case False then show ?thesis proof (cases "ptr = y") case True then show ?thesis using children_h3 children_h' child_not_in_any_children[unfolded children_eq_h2] 5 6 apply(auto simp add: True children_eq2_h3[OF \ptr \ x\])[1] by (metis (no_types, hide_lams) "2" "4" "7" IntI \known_ptrs h3\ \type_wf h'\ children_eq_h3 empty_iff insert_before_list_in_set local.get_child_nodes_ok local.known_ptrs_known_ptr object_ptr_kinds_M_eq3_h' returns_result_select_result select_result_I2) next case False then show ?thesis using children_eq2_h3[OF \ptr \ x\] children_eq2_h3[OF \ptr \ y\] 5 6 7 by auto qed qed next fix x xa xb assume 1: " (\x\fset (object_ptr_kinds h'). set |h3 \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h'). set |h' \ get_disconnected_nodes x|\<^sub>r) = {} " and 2: "xa |\| object_ptr_kinds h'" and 3: "x \ set |h' \ get_child_nodes xa|\<^sub>r" and 4: "xb |\| document_ptr_kinds h'" and 5: "x \ set |h' \ get_disconnected_nodes xb|\<^sub>r" have 6: "set |h3 \ get_child_nodes xa|\<^sub>r \ set |h' \ get_disconnected_nodes xb|\<^sub>r = {}" using 1 2 3 4 5 proof - have "\h d. \ type_wf h \ d |\| document_ptr_kinds h \ h \ ok get_disconnected_nodes d" using local.get_disconnected_nodes_ok by satx then have "h' \ ok get_disconnected_nodes xb" using "4" \type_wf h'\ by fastforce then have f1: "h3 \ get_disconnected_nodes xb \\<^sub>r |h' \ get_disconnected_nodes xb|\<^sub>r" by (simp add: disconnected_nodes_eq_h3) have "xa |\| object_ptr_kinds h3" using "2" object_ptr_kinds_M_eq3_h' by blast then show ?thesis using f1 \local.a_distinct_lists h3\ local.distinct_lists_no_parent by fastforce qed show False proof (cases "ptr = xa") case True show ?thesis using 6 node_not_in_disconnected_nodes 3 4 5 select_result_I2[OF children_h'] select_result_I2[OF children_h3] True disconnected_nodes_eq2_h3 by (metis (no_types, lifting) "2" DocumentMonad.ptr_kinds_ptr_kinds_M \a_distinct_lists h3\ \type_wf h'\ disconnected_nodes_eq_h3 distinct_lists_no_parent document_ptr_kinds_eq2_h3 get_disconnected_nodes_ok insert_before_list_in_set object_ptr_kinds_M_eq3_h' returns_result_select_result) next case False then show ?thesis using 1 2 3 4 5 children_eq2_h3[OF False] by fastforce qed qed moreover have "a_owner_document_valid h2" using wellformed_h2 by (simp add: heap_is_wellformed_def) then have "a_owner_document_valid h'" apply(auto simp add: a_owner_document_valid_def object_ptr_kinds_M_eq2_h2 object_ptr_kinds_M_eq2_h3 node_ptr_kinds_eq2_h2 node_ptr_kinds_eq2_h3 document_ptr_kinds_eq2_h2 document_ptr_kinds_eq2_h3 children_eq2_h2)[1] apply(auto simp add: document_ptr_kinds_eq2_h2[simplified] document_ptr_kinds_eq2_h3[simplified] object_ptr_kinds_M_eq2_h2[simplified] object_ptr_kinds_M_eq2_h3[simplified] node_ptr_kinds_eq2_h2[simplified] node_ptr_kinds_eq2_h3[simplified])[1] apply(auto simp add: disconnected_nodes_eq2_h3[symmetric])[1] by (smt children_eq2_h3 children_h' children_h3 disconnected_nodes_eq2_h2 disconnected_nodes_h2 disconnected_nodes_h3 finite_set_in in_set_remove1 insert_before_list_in_set object_ptr_kinds_M_eq3_h' ptr_in_heap select_result_I2) ultimately show "heap_is_wellformed h'" by (simp add: heap_is_wellformed_def) qed lemma adopt_node_children_remain_distinct: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ adopt_node owner_document node_ptr \\<^sub>h h'" shows "\ptr' children'. h' \ get_child_nodes ptr' \\<^sub>r children' \ distinct children'" using assms(1) assms(2) assms(3) assms(4) local.adopt_node_preserves_wellformedness local.heap_is_wellformed_children_distinct by blast lemma insert_node_children_remain_distinct: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ a_insert_node ptr new_child reference_child_opt \\<^sub>h h'" assumes "h \ get_child_nodes ptr \\<^sub>r children" assumes "new_child \ set children" shows "\children'. h' \ get_child_nodes ptr \\<^sub>r children' \ distinct children'" proof - fix children' assume a1: "h' \ get_child_nodes ptr \\<^sub>r children'" have "h' \ get_child_nodes ptr \\<^sub>r (insert_before_list new_child reference_child_opt children)" using assms(4) assms(5) apply(auto simp add: a_insert_node_def elim!: bind_returns_heap_E)[1] using returns_result_eq set_child_nodes_get_child_nodes assms(2) assms(3) by (metis is_OK_returns_result_I local.get_child_nodes_ptr_in_heap local.get_child_nodes_pure local.known_ptrs_known_ptr pure_returns_heap_eq) moreover have "a_distinct_lists h" using assms local.heap_is_wellformed_def by blast then have "\children. h \ get_child_nodes ptr \\<^sub>r children \ distinct children" using assms local.heap_is_wellformed_children_distinct by blast ultimately show "h' \ get_child_nodes ptr \\<^sub>r children' \ distinct children'" using assms(5) assms(6) insert_before_list_distinct returns_result_eq by fastforce qed lemma insert_before_children_remain_distinct: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ insert_before ptr new_child child_opt \\<^sub>h h'" shows "\ptr' children'. h' \ get_child_nodes ptr' \\<^sub>r children' \ distinct children'" proof - obtain reference_child owner_document h2 h3 disconnected_nodes_h2 where reference_child: "h \ (if Some new_child = child_opt then a_next_sibling new_child else return child_opt) \\<^sub>r reference_child" and owner_document: "h \ get_owner_document ptr \\<^sub>r owner_document" and h2: "h \ adopt_node owner_document new_child \\<^sub>h h2" and disconnected_nodes_h2: "h2 \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h2" and h3: "h2 \ set_disconnected_nodes owner_document (remove1 new_child disconnected_nodes_h2) \\<^sub>h h3" and h': "h3 \ a_insert_node ptr new_child reference_child \\<^sub>h h'" using assms(4) by(auto simp add: insert_before_def a_ensure_pre_insertion_validity_def elim!: bind_returns_heap_E bind_returns_result_E bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] bind_returns_heap_E2[rotated, OF get_child_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_ancestors_pure, rotated] bind_returns_heap_E2[rotated, OF next_sibling_pure, rotated] bind_returns_heap_E2[rotated, OF get_owner_document_pure, rotated] split: if_splits option.splits) have "\ptr children. h2 \ get_child_nodes ptr \\<^sub>r children \ distinct children" using adopt_node_children_remain_distinct using assms(1) assms(2) assms(3) h2 by blast moreover have "\ptr children. h2 \ get_child_nodes ptr \\<^sub>r children \ new_child \ set children" using adopt_node_removes_child using assms(1) assms(2) assms(3) h2 by blast moreover have "\ptr children. h2 \ get_child_nodes ptr \\<^sub>r children = h3 \ get_child_nodes ptr \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (auto simp add: set_disconnected_nodes_get_child_nodes) ultimately show "\ptr children. h' \ get_child_nodes ptr \\<^sub>r children \ distinct children" using insert_node_children_remain_distinct by (meson assms(1) assms(2) assms(3) assms(4) insert_before_heap_is_wellformed_preserved(1) local.heap_is_wellformed_children_distinct) qed lemma insert_before_removes_child: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ insert_before ptr node child \\<^sub>h h'" assumes "ptr \ ptr'" shows "\children'. h' \ get_child_nodes ptr' \\<^sub>r children' \ node \ set children'" proof - fix children' assume a1: "h' \ get_child_nodes ptr' \\<^sub>r children'" obtain ancestors reference_child owner_document h2 h3 disconnected_nodes_h2 where ancestors: "h \ get_ancestors ptr \\<^sub>r ancestors" and node_not_in_ancestors: "cast node \ set ancestors" and reference_child: "h \ (if Some node = child then a_next_sibling node else return child) \\<^sub>r reference_child" and owner_document: "h \ get_owner_document ptr \\<^sub>r owner_document" and h2: "h \ adopt_node owner_document node \\<^sub>h h2" and disconnected_nodes_h2: "h2 \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h2" and h3: "h2 \ set_disconnected_nodes owner_document (remove1 node disconnected_nodes_h2) \\<^sub>h h3" and h': "h3 \ a_insert_node ptr node reference_child \\<^sub>h h'" using assms(4) by(auto simp add: insert_before_def a_ensure_pre_insertion_validity_def elim!: bind_returns_heap_E bind_returns_result_E bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] bind_returns_heap_E2[rotated, OF get_child_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_ancestors_pure, rotated] bind_returns_heap_E2[rotated, OF next_sibling_pure, rotated] bind_returns_heap_E2[rotated, OF get_owner_document_pure, rotated] split: if_splits option.splits) have "known_ptr ptr" by (meson get_owner_document_ptr_in_heap is_OK_returns_result_I assms(2) l_known_ptrs.known_ptrs_known_ptr l_known_ptrs_axioms owner_document) have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF adopt_node_writes h2] using assms(3) adopt_node_types_preserved by(auto simp add: a_remove_child_locs_def reflp_def transp_def) then have "type_wf h3" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h3] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) then have "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF insert_node_writes h'] using set_child_nodes_types_preserved by(auto simp add: reflp_def transp_def) have object_ptr_kinds_M_eq3_h: "object_ptr_kinds h = object_ptr_kinds h2" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF adopt_node_writes h2]) using adopt_node_pointers_preserved apply blast by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h: "\ptrs. h \ object_ptr_kinds_M \\<^sub>r ptrs = h2 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs ) then have object_ptr_kinds_M_eq2_h: "|h \ object_ptr_kinds_M|\<^sub>r = |h2 \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h: "|h \ node_ptr_kinds_M|\<^sub>r = |h2 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have "known_ptrs h2" using assms object_ptr_kinds_M_eq3_h known_ptrs_preserved by blast have wellformed_h2: "heap_is_wellformed h2" using adopt_node_preserves_wellformedness[OF assms(1) h2] assms by simp have object_ptr_kinds_M_eq3_h2: "object_ptr_kinds h2 = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h3]) unfolding a_remove_child_locs_def using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h2: "\ptrs. h2 \ object_ptr_kinds_M \\<^sub>r ptrs = h3 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_M_eq2_h2: "|h2 \ object_ptr_kinds_M|\<^sub>r = |h3 \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h2: "|h2 \ node_ptr_kinds_M|\<^sub>r = |h3 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have document_ptr_kinds_eq2_h2: "|h2 \ document_ptr_kinds_M|\<^sub>r = |h3 \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_M_eq2_h2 document_ptr_kinds_M_eq by auto have "known_ptrs h3" using object_ptr_kinds_M_eq3_h2 known_ptrs_preserved \known_ptrs h2\ by blast have object_ptr_kinds_M_eq3_h': "object_ptr_kinds h3 = object_ptr_kinds h'" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF insert_node_writes h']) unfolding a_remove_child_locs_def using set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h3: "\ptrs. h3 \ object_ptr_kinds_M \\<^sub>r ptrs = h' \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_M_eq2_h3: "|h3 \ object_ptr_kinds_M|\<^sub>r = |h' \ object_ptr_kinds_M|\<^sub>r" by simp then have node_ptr_kinds_eq2_h3: "|h3 \ node_ptr_kinds_M|\<^sub>r = |h' \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast have document_ptr_kinds_eq2_h3: "|h3 \ document_ptr_kinds_M|\<^sub>r = |h' \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_M_eq2_h3 document_ptr_kinds_M_eq by auto have "known_ptrs h'" using object_ptr_kinds_M_eq3_h' known_ptrs_preserved \known_ptrs h3\ by blast have disconnected_nodes_eq_h2: "\doc_ptr disc_nodes. owner_document \ doc_ptr \ h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (auto simp add: set_disconnected_nodes_get_disconnected_nodes_different_pointers) then have disconnected_nodes_eq2_h2: "\doc_ptr. doc_ptr \ owner_document \ |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have disconnected_nodes_h3: "h3 \ get_disconnected_nodes owner_document \\<^sub>r remove1 node disconnected_nodes_h2" using h3 set_disconnected_nodes_get_disconnected_nodes by blast have disconnected_nodes_eq_h3: "\doc_ptr disc_nodes. h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h' \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads insert_node_writes h' apply(rule reads_writes_preserved) using set_child_nodes_get_disconnected_nodes by fast then have disconnected_nodes_eq2_h3: "\doc_ptr. |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have children_eq_h2: "\ptr' children. h2 \ get_child_nodes ptr' \\<^sub>r children = h3 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (auto simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h2: "\ptr'. |h2 \ get_child_nodes ptr'|\<^sub>r = |h3 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have children_eq_h3: "\ptr' children. ptr \ ptr' \ h3 \ get_child_nodes ptr' \\<^sub>r children = h' \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads insert_node_writes h' apply(rule reads_writes_preserved) by (auto simp add: set_child_nodes_get_child_nodes_different_pointers) then have children_eq2_h3: "\ptr'. ptr \ ptr' \ |h3 \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force obtain children_h3 where children_h3: "h3 \ get_child_nodes ptr \\<^sub>r children_h3" using h' a_insert_node_def by auto have children_h': "h' \ get_child_nodes ptr \\<^sub>r insert_before_list node reference_child children_h3" using h' \type_wf h3\ \known_ptr ptr\ by(auto simp add: a_insert_node_def elim!: bind_returns_heap_E2 dest!: set_child_nodes_get_child_nodes returns_result_eq[OF children_h3]) have ptr_in_heap: "ptr |\| object_ptr_kinds h3" using children_h3 get_child_nodes_ptr_in_heap by blast have node_in_heap: "node |\| node_ptr_kinds h" using h2 adopt_node_child_in_heap by fast have child_not_in_any_children: "\p children. h2 \ get_child_nodes p \\<^sub>r children \ node \ set children" using assms(1) assms(2) assms(3) h2 local.adopt_node_removes_child by blast show "node \ set children'" using a1 assms(5) child_not_in_any_children children_eq_h2 children_eq_h3 by blast qed lemma ensure_pre_insertion_validity_ok: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "ptr |\| object_ptr_kinds h" assumes "\is_character_data_ptr_kind parent" assumes "cast node \ set |h \ get_ancestors parent|\<^sub>r" assumes "h \ get_parent ref \\<^sub>r Some parent" assumes "is_document_ptr parent \ h \ get_child_nodes parent \\<^sub>r []" assumes "is_document_ptr parent \ \is_character_data_ptr_kind node" shows "h \ ok (a_ensure_pre_insertion_validity node parent (Some ref))" proof - have "h \ (if is_character_data_ptr_kind parent then error HierarchyRequestError else return ()) \\<^sub>r ()" using assms by (simp add: assms(4)) moreover have "h \ do { ancestors \ get_ancestors parent; (if cast node \ set ancestors then error HierarchyRequestError else return ()) } \\<^sub>r ()" using assms(6) apply(auto intro!: bind_pure_returns_result_I)[1] using assms(1) assms(2) assms(3) assms(7) local.get_ancestors_ok local.get_parent_parent_in_heap by auto moreover have "h \ do { (case Some ref of Some child \ do { child_parent \ get_parent child; (if child_parent \ Some parent then error NotFoundError else return ())} | None \ return ()) } \\<^sub>r ()" using assms(7) by(auto split: option.splits) moreover have "h \ do { children \ get_child_nodes parent; (if children \ [] \ is_document_ptr parent then error HierarchyRequestError else return ()) } \\<^sub>r ()" using assms(8) by (smt assms(5) assms(7) bind_pure_returns_result_I2 calculation(1) is_OK_returns_result_I local.get_child_nodes_pure local.get_parent_child_dual returns_result_eq) moreover have "h \ do { (if is_character_data_ptr node \ is_document_ptr parent then error HierarchyRequestError else return ()) } \\<^sub>r ()" using assms using is_character_data_ptr_kind_none by force ultimately show ?thesis unfolding a_ensure_pre_insertion_validity_def apply(intro bind_is_OK_pure_I) apply auto[1] apply auto[1] apply auto[1] using assms(1) assms(2) assms(3) assms(7) local.get_ancestors_ok local.get_parent_parent_in_heap apply blast apply auto[1] apply auto[1] using assms(6) apply auto[1] using assms(1) assms(2) assms(3) assms(7) local.get_ancestors_ok local.get_parent_parent_in_heap apply auto[1] apply (smt bind_returns_heap_E is_OK_returns_heap_E local.get_parent_pure pure_def pure_returns_heap_eq return_returns_heap returns_result_eq) apply(blast) using local.get_child_nodes_pure apply blast apply (meson assms(7) is_OK_returns_result_I local.get_parent_child_dual) apply (simp) apply (smt assms(5) assms(8) is_OK_returns_result_I returns_result_eq) by(auto) qed end locale l_insert_before_wf2 = l_type_wf + l_known_ptrs + l_insert_before_defs + l_heap_is_wellformed_defs + l_get_child_nodes_defs + l_remove_defs + assumes insert_before_preserves_type_wf: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ insert_before ptr child ref \\<^sub>h h' \ type_wf h'" assumes insert_before_preserves_known_ptrs: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ insert_before ptr child ref \\<^sub>h h' \ known_ptrs h'" assumes insert_before_heap_is_wellformed_preserved: "type_wf h \ known_ptrs h \ heap_is_wellformed h \ h \ insert_before ptr child ref \\<^sub>h h' \ heap_is_wellformed h'" interpretation i_insert_before_wf2?: l_insert_before_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_parent get_parent_locs get_child_nodes get_child_nodes_locs set_child_nodes set_child_nodes_locs get_ancestors get_ancestors_locs adopt_node adopt_node_locs set_disconnected_nodes set_disconnected_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs get_owner_document insert_before insert_before_locs append_child type_wf known_ptr known_ptrs heap_is_wellformed parent_child_rel remove_child remove_child_locs get_root_node get_root_node_locs by(simp add: l_insert_before_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) declare l_insert_before_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] lemma insert_before_wf2_is_l_insert_before_wf2 [instances]: "l_insert_before_wf2 type_wf known_ptr known_ptrs insert_before heap_is_wellformed" apply(auto simp add: l_insert_before_wf2_def l_insert_before_wf2_axioms_def instances)[1] using insert_before_heap_is_wellformed_preserved apply(fast, fast, fast) done locale l_insert_before_wf3\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_insert_before_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_adopt_node\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_set_child_nodes_get_child_nodes\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_remove_child_wf2 begin lemma next_sibling_ok: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "node_ptr |\| node_ptr_kinds h" shows "h \ ok (a_next_sibling node_ptr)" proof - have "known_ptr (cast node_ptr)" using assms(2) assms(4) local.known_ptrs_known_ptr node_ptr_kinds_commutes by blast then show ?thesis using assms apply(auto simp add: a_next_sibling_def intro!: bind_is_OK_pure_I split: option.splits list.splits)[1] using get_child_nodes_ok local.get_parent_parent_in_heap local.known_ptrs_known_ptr by blast qed lemma remove_child_ok: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "h \ get_child_nodes ptr \\<^sub>r children" assumes "child \ set children" shows "h \ ok (remove_child ptr child)" proof - have "ptr |\| object_ptr_kinds h" using assms(4) local.get_child_nodes_ptr_in_heap by blast have "child |\| node_ptr_kinds h" using assms(1) assms(4) assms(5) local.heap_is_wellformed_children_in_heap by blast have "\is_character_data_ptr ptr" proof (rule ccontr, simp) assume "is_character_data_ptr ptr" then have "h \ get_child_nodes ptr \\<^sub>r []" using \ptr |\| object_ptr_kinds h\ apply(simp add: get_child_nodes_def a_get_child_nodes_tups_def) apply(split invoke_splits)+ by(auto simp add: get_child_nodes\<^sub>c\<^sub>h\<^sub>a\<^sub>r\<^sub>a\<^sub>c\<^sub>t\<^sub>e\<^sub>r\<^sub>_\<^sub>d\<^sub>a\<^sub>t\<^sub>a\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def intro!: bind_pure_returns_result_I split: option.splits) then show False using assms returns_result_eq by fastforce qed have "is_character_data_ptr child \ \is_document_ptr_kind ptr" proof (rule ccontr, simp) assume "is_character_data_ptr\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r child" and "is_document_ptr_kind ptr" then show False using assms using \ptr |\| object_ptr_kinds h\ apply(simp add: get_child_nodes_def a_get_child_nodes_tups_def) apply(split invoke_splits)+ apply(auto split: option.splits)[1] apply (meson invoke_empty is_OK_returns_result_I) apply (meson invoke_empty is_OK_returns_result_I) by(auto simp add: get_child_nodes\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 split: option.splits) qed obtain owner_document where owner_document: "h \ get_owner_document (cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r child) \\<^sub>r owner_document" by (meson \child |\| node_ptr_kinds h\ assms(1) assms(2) assms(3) is_OK_returns_result_E local.get_owner_document_ok node_ptr_kinds_commutes) obtain disconnected_nodes_h where disconnected_nodes_h: "h \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h" by (meson assms(1) assms(2) assms(3) is_OK_returns_result_E local.get_disconnected_nodes_ok local.get_owner_document_owner_document_in_heap owner_document) obtain h2 where h2: "h \ set_disconnected_nodes owner_document (child # disconnected_nodes_h) \\<^sub>h h2" by (meson assms(1) assms(2) assms(3) is_OK_returns_heap_E l_set_disconnected_nodes.set_disconnected_nodes_ok local.get_owner_document_owner_document_in_heap local.l_set_disconnected_nodes_axioms owner_document) have "known_ptr ptr" using assms(2) assms(4) local.known_ptrs_known_ptr using \ptr |\| object_ptr_kinds h\ by blast have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h2] using set_disconnected_nodes_types_preserved assms(3) by(auto simp add: reflp_def transp_def) have "object_ptr_kinds h = object_ptr_kinds h2" using h2 apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes]) using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) have "h2 \ ok (set_child_nodes ptr (remove1 child children))" proof (cases "is_element_ptr_kind ptr") case True then show ?thesis using set_child_nodes_element_ok \known_ptr ptr\ \object_ptr_kinds h = object_ptr_kinds h2\ \type_wf h2\ assms(4) using \ptr |\| object_ptr_kinds h\ by blast next case False then have "is_document_ptr_kind ptr" using \known_ptr ptr\ \ptr |\| object_ptr_kinds h\ \\is_character_data_ptr ptr\ by(auto simp add:known_ptr_impl known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) moreover have "is_document_ptr ptr" using \known_ptr ptr\ \ptr |\| object_ptr_kinds h\ False \\is_character_data_ptr ptr\ by(auto simp add: known_ptr_impl known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) ultimately show ?thesis using assms(4) apply(auto simp add: get_child_nodes_def a_get_child_nodes_tups_def)[1] apply(split invoke_splits)+ apply(auto elim!: bind_returns_result_E2 split: option.splits)[1] apply(auto simp add: get_child_nodes\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_def elim!: bind_returns_result_E2 split: option.splits)[1] using assms(5) apply auto[1] using \is_document_ptr_kind ptr\ \known_ptr ptr\ \object_ptr_kinds h = object_ptr_kinds h2\ \ptr |\| object_ptr_kinds h\ \type_wf h2\ local.set_child_nodes_document1_ok apply blast using \is_document_ptr_kind ptr\ \known_ptr ptr\ \object_ptr_kinds h = object_ptr_kinds h2\ \ptr |\| object_ptr_kinds h\ \type_wf h2\ is_element_ptr_kind_cast local.set_child_nodes_document2_ok apply blast using \\ is_character_data_ptr\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r ptr\ apply blast by (metis False is_element_ptr_implies_kind option.case_eq_if) qed then obtain h' where h': "h2 \ set_child_nodes ptr (remove1 child children) \\<^sub>h h'" by auto show ?thesis using assms apply(auto simp add: remove_child_def simp add: is_OK_returns_heap_I[OF h2] is_OK_returns_heap_I[OF h'] is_OK_returns_result_I[OF assms(4)] is_OK_returns_result_I[OF owner_document] is_OK_returns_result_I[OF disconnected_nodes_h] intro!: bind_is_OK_pure_I[OF get_owner_document_pure] bind_is_OK_pure_I[OF get_child_nodes_pure] bind_is_OK_pure_I[OF get_disconnected_nodes_pure] bind_is_OK_I[rotated, OF h2] dest!: returns_result_eq[OF assms(4)] returns_result_eq[OF owner_document] returns_result_eq[OF disconnected_nodes_h] )[1] using h2 returns_result_select_result by force qed lemma adopt_node_ok: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "document_ptr |\| document_ptr_kinds h" assumes "child |\| node_ptr_kinds h" shows "h \ ok (adopt_node document_ptr child)" proof - obtain old_document where old_document: "h \ get_owner_document (cast child) \\<^sub>r old_document" by (meson assms(1) assms(2) assms(3) assms(5) is_OK_returns_result_E local.get_owner_document_ok node_ptr_kinds_commutes) then have "h \ ok (get_owner_document (cast child))" by auto obtain parent_opt where parent_opt: "h \ get_parent child \\<^sub>r parent_opt" by (meson assms(2) assms(3) is_OK_returns_result_I l_get_owner_document.get_owner_document_ptr_in_heap local.get_parent_ok local.l_get_owner_document_axioms node_ptr_kinds_commutes old_document returns_result_select_result) then have "h \ ok (get_parent child)" by auto have "h \ ok (case parent_opt of Some parent \ remove_child parent child | None \ return ())" apply(auto split: option.splits)[1] using remove_child_ok by (metis assms(1) assms(2) assms(3) local.get_parent_child_dual parent_opt) then obtain h2 where h2: "h \ (case parent_opt of Some parent \ remove_child parent child | None \ return ()) \\<^sub>h h2" by auto have "object_ptr_kinds h = object_ptr_kinds h2" using h2 apply(simp split: option.splits) apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_child_writes]) using remove_child_pointers_preserved by (auto simp add: reflp_def transp_def) then have "old_document |\| document_ptr_kinds h2" using assms(1) assms(2) assms(3) document_ptr_kinds_commutes local.get_owner_document_owner_document_in_heap old_document by blast have wellformed_h2: "heap_is_wellformed h2" using h2 remove_child_heap_is_wellformed_preserved assms by(auto split: option.splits) have "type_wf h2" using h2 remove_child_preserves_type_wf assms by(auto split: option.splits) have "known_ptrs h2" using h2 remove_child_preserves_known_ptrs assms by(auto split: option.splits) have "object_ptr_kinds h = object_ptr_kinds h2" using h2 apply(simp split: option.splits) apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF remove_child_writes]) using remove_child_pointers_preserved by (auto simp add: reflp_def transp_def) then have "document_ptr_kinds h = document_ptr_kinds h2" by(auto simp add: document_ptr_kinds_def) have "h2 \ ok (if document_ptr \ old_document then do { old_disc_nodes \ get_disconnected_nodes old_document; set_disconnected_nodes old_document (remove1 child old_disc_nodes); disc_nodes \ get_disconnected_nodes document_ptr; set_disconnected_nodes document_ptr (child # disc_nodes) } else do { return () })" proof(cases "document_ptr = old_document") case True then show ?thesis by simp next case False then have "h2 \ ok (get_disconnected_nodes old_document)" by (simp add: \old_document |\| document_ptr_kinds h2\ \type_wf h2\ local.get_disconnected_nodes_ok) then obtain old_disc_nodes where old_disc_nodes: "h2 \ get_disconnected_nodes old_document \\<^sub>r old_disc_nodes" by auto have "h2 \ ok (set_disconnected_nodes old_document (remove1 child old_disc_nodes))" by (simp add: \old_document |\| document_ptr_kinds h2\ \type_wf h2\ local.set_disconnected_nodes_ok) then obtain h3 where h3: "h2 \ set_disconnected_nodes old_document (remove1 child old_disc_nodes) \\<^sub>h h3" by auto have object_ptr_kinds_h2_eq3: "object_ptr_kinds h2 = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h3]) using set_disconnected_nodes_pointers_preserved set_child_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have object_ptr_kinds_M_eq_h2: "\ptrs. h2 \ object_ptr_kinds_M \\<^sub>r ptrs = h3 \ object_ptr_kinds_M \\<^sub>r ptrs" by(simp add: object_ptr_kinds_M_defs) then have object_ptr_kinds_eq_h2: "|h2 \ object_ptr_kinds_M|\<^sub>r = |h3 \ object_ptr_kinds_M|\<^sub>r" by(simp) then have node_ptr_kinds_eq_h2: "|h2 \ node_ptr_kinds_M|\<^sub>r = |h3 \ node_ptr_kinds_M|\<^sub>r" using node_ptr_kinds_M_eq by blast then have node_ptr_kinds_eq3_h2: "node_ptr_kinds h2 = node_ptr_kinds h3" by auto have document_ptr_kinds_eq2_h2: "|h2 \ document_ptr_kinds_M|\<^sub>r = |h3 \ document_ptr_kinds_M|\<^sub>r" using object_ptr_kinds_eq_h2 document_ptr_kinds_M_eq by auto then have document_ptr_kinds_eq3_h2: "document_ptr_kinds h2 = document_ptr_kinds h3" using object_ptr_kinds_eq_h2 document_ptr_kinds_M_eq by auto have children_eq_h2: "\ptr children. h2 \ get_child_nodes ptr \\<^sub>r children = h3 \ get_child_nodes ptr \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h3 apply(rule reads_writes_preserved) by (simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h2: "\ptr. |h2 \ get_child_nodes ptr|\<^sub>r = |h3 \ get_child_nodes ptr|\<^sub>r" using select_result_eq by force have "type_wf h3" using \type_wf h2\ using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h3] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) moreover have "document_ptr |\| document_ptr_kinds h3" using \document_ptr_kinds h = document_ptr_kinds h2\ assms(4) document_ptr_kinds_eq3_h2 by auto ultimately have "h3 \ ok (get_disconnected_nodes document_ptr)" by (simp add: local.get_disconnected_nodes_ok) then obtain disc_nodes where disc_nodes: "h3 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes" by auto have "h3 \ ok (set_disconnected_nodes document_ptr (child # disc_nodes))" using \document_ptr |\| document_ptr_kinds h3\ \type_wf h3\ local.set_disconnected_nodes_ok by auto then obtain h' where h': "h3 \ set_disconnected_nodes document_ptr (child # disc_nodes) \\<^sub>h h'" by auto then show ?thesis using False using \h2 \ ok get_disconnected_nodes old_document\ using \h3 \ ok get_disconnected_nodes document_ptr\ apply(auto dest!: returns_result_eq[OF old_disc_nodes] returns_result_eq[OF disc_nodes] intro!: bind_is_OK_I[rotated, OF h3] bind_is_OK_pure_I[OF get_disconnected_nodes_pure] )[1] using \h2 \ ok set_disconnected_nodes old_document (remove1 child old_disc_nodes)\ by auto qed then obtain h' where h': "h2 \ (if document_ptr \ old_document then do { old_disc_nodes \ get_disconnected_nodes old_document; set_disconnected_nodes old_document (remove1 child old_disc_nodes); disc_nodes \ get_disconnected_nodes document_ptr; set_disconnected_nodes document_ptr (child # disc_nodes) } else do { return () }) \\<^sub>h h'" by auto show ?thesis using \h \ ok (get_owner_document (cast child))\ using \h \ ok (get_parent child)\ using h2 h' apply(auto simp add: adopt_node_def simp add: is_OK_returns_heap_I[OF h2] intro!: bind_is_OK_pure_I[OF get_owner_document_pure] bind_is_OK_pure_I[OF get_parent_pure] bind_is_OK_I[rotated, OF h2] dest!: returns_result_eq[OF parent_opt] returns_result_eq[OF old_document])[1] using \h \ ok (case parent_opt of None \ return () | Some parent \ remove_child parent child)\ by auto qed lemma insert_node_ok: assumes "known_ptr parent" and "type_wf h" assumes "parent |\| object_ptr_kinds h" assumes "\is_character_data_ptr_kind parent" assumes "is_document_ptr parent \ h \ get_child_nodes parent \\<^sub>r []" assumes "is_document_ptr parent \ \is_character_data_ptr_kind node" assumes "known_ptr (cast node)" shows "h \ ok (a_insert_node parent node ref)" proof(auto simp add: a_insert_node_def get_child_nodes_ok[OF assms(1) assms(2) assms(3)] intro!: bind_is_OK_pure_I) fix children' assume "h \ get_child_nodes parent \\<^sub>r children'" show "h \ ok set_child_nodes parent (insert_before_list node ref children')" proof (cases "is_element_ptr_kind parent") case True then show ?thesis using set_child_nodes_element_ok using assms(1) assms(2) assms(3) by blast next case False then have "is_document_ptr_kind parent" using assms(4) assms(1) by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) then have "is_document_ptr parent" using assms(1) by(auto simp add: known_ptr_impl DocumentClass.known_ptr_defs CharacterDataClass.known_ptr_defs ElementClass.known_ptr_defs NodeClass.known_ptr_defs split: option.splits) then obtain children where children: "h \ get_child_nodes parent \\<^sub>r children" and "children = []" using assms(5) by blast have "insert_before_list node ref children' = [node]" by (metis \children = []\ \h \ get_child_nodes parent \\<^sub>r children'\ append.left_neutral children insert_Nil l_insert_before\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs.insert_before_list.elims l_insert_before\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_defs.insert_before_list.simps(3) neq_Nil_conv returns_result_eq) moreover have "\is_character_data_ptr_kind node" using \is_document_ptr\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r parent\ assms(6) by blast then have "is_element_ptr_kind node" by (metis (no_types, lifting) CharacterDataClass.a_known_ptr_def DocumentClass.a_known_ptr_def ElementClass.a_known_ptr_def NodeClass.a_known_ptr_def assms(7) cast\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r_inject document_ptr_no_node_ptr_cast is_character_data_ptr_kind_none is_document_ptr_kind_none is_element_ptr_implies_kind is_node_ptr_kind_cast local.known_ptr_impl node_ptr_casts_commute3 option.case_eq_if) ultimately show ?thesis using set_child_nodes_document2_ok by (metis \is_document_ptr\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r parent\ assms(1) assms(2) assms(3) assms(5) is_document_ptr_kind_none option.case_eq_if) qed qed lemma insert_before_ok: assumes "heap_is_wellformed h" and "known_ptrs h" and "type_wf h" assumes "parent |\| object_ptr_kinds h" assumes "node |\| node_ptr_kinds h" assumes "\is_character_data_ptr_kind parent" assumes "cast node \ set |h \ get_ancestors parent|\<^sub>r" assumes "h \ get_parent ref \\<^sub>r Some parent" assumes "is_document_ptr parent \ h \ get_child_nodes parent \\<^sub>r []" assumes "is_document_ptr parent \ \is_character_data_ptr_kind node" shows "h \ ok (insert_before parent node (Some ref))" proof - have "h \ ok (a_ensure_pre_insertion_validity node parent (Some ref))" using assms ensure_pre_insertion_validity_ok by blast have "h \ ok (if Some node = Some ref then a_next_sibling node else return (Some ref))" (is "h \ ok ?P") apply(auto split: if_splits)[1] using assms(1) assms(2) assms(3) assms(5) next_sibling_ok by blast then obtain reference_child where reference_child: "h \ ?P \\<^sub>r reference_child" by auto obtain owner_document where owner_document: "h \ get_owner_document parent \\<^sub>r owner_document" using assms get_owner_document_ok by (meson returns_result_select_result) then have "h \ ok (get_owner_document parent)" by auto have "owner_document |\| document_ptr_kinds h" using assms(1) assms(2) assms(3) local.get_owner_document_owner_document_in_heap owner_document by blast obtain h2 where h2: "h \ adopt_node owner_document node \\<^sub>h h2" by (meson assms(1) assms(2) assms(3) assms(5) is_OK_returns_heap_E adopt_node_ok l_insert_before_wf2\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms local.get_owner_document_owner_document_in_heap owner_document) then have "h \ ok (adopt_node owner_document node)" by auto have "object_ptr_kinds h = object_ptr_kinds h2" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF adopt_node_writes h2]) using adopt_node_pointers_preserved apply blast by (auto simp add: reflp_def transp_def) then have "document_ptr_kinds h = document_ptr_kinds h2" by(auto simp add: document_ptr_kinds_def) have "heap_is_wellformed h2" using h2 adopt_node_preserves_wellformedness assms by blast have "known_ptrs h2" using h2 adopt_node_preserves_known_ptrs assms by blast have "type_wf h2" using h2 adopt_node_preserves_type_wf assms by blast obtain disconnected_nodes_h2 where disconnected_nodes_h2: "h2 \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h2" by (metis \document_ptr_kinds h = document_ptr_kinds h2\ \type_wf h2\ assms(1) assms(2) assms(3) is_OK_returns_result_E local.get_disconnected_nodes_ok local.get_owner_document_owner_document_in_heap owner_document) obtain h3 where h3: "h2 \ set_disconnected_nodes owner_document (remove1 node disconnected_nodes_h2) \\<^sub>h h3" by (metis \document_ptr_kinds h = document_ptr_kinds h2\ \owner_document |\| document_ptr_kinds h\ \type_wf h2\ document_ptr_kinds_def is_OK_returns_heap_E l_set_disconnected_nodes.set_disconnected_nodes_ok local.l_set_disconnected_nodes_axioms) have "type_wf h3" using \type_wf h2\ using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h3] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) have object_ptr_kinds_M_eq3_h2: "object_ptr_kinds h2 = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h = object_ptr_kinds h'", OF set_disconnected_nodes_writes h3]) unfolding a_remove_child_locs_def using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) have "parent |\| object_ptr_kinds h3" using \object_ptr_kinds h = object_ptr_kinds h2\ assms(4) object_ptr_kinds_M_eq3_h2 by blast moreover have "known_ptr parent" using assms(2) assms(4) local.known_ptrs_known_ptr by blast moreover have "known_ptr (cast node)" using assms(2) assms(5) local.known_ptrs_known_ptr node_ptr_kinds_commutes by blast moreover have "is_document_ptr parent \ h3 \ get_child_nodes parent \\<^sub>r []" by (metis assms(8) assms(9) distinct.simps(2) distinct_singleton local.get_parent_child_dual returns_result_eq) ultimately obtain h' where h': "h3 \ a_insert_node parent node reference_child \\<^sub>h h'" using insert_node_ok \type_wf h3\ assms by blast show ?thesis using \h \ ok (a_ensure_pre_insertion_validity node parent (Some ref))\ using reference_child \h \ ok (get_owner_document parent)\ \h \ ok (adopt_node owner_document node)\ h3 h' apply(auto simp add: insert_before_def simp add: is_OK_returns_result_I[OF disconnected_nodes_h2] simp add: is_OK_returns_heap_I[OF h3] is_OK_returns_heap_I[OF h'] intro!: bind_is_OK_I2 bind_is_OK_pure_I[OF ensure_pre_insertion_validity_pure] bind_is_OK_pure_I[OF next_sibling_pure] bind_is_OK_pure_I[OF get_owner_document_pure] bind_is_OK_pure_I[OF get_disconnected_nodes_pure] dest!: returns_result_eq[OF owner_document] returns_result_eq[OF disconnected_nodes_h2] returns_heap_eq[OF h2] returns_heap_eq[OF h3] dest!: sym[of node ref] )[1] using returns_result_eq by fastforce qed end interpretation i_insert_before_wf3?: l_insert_before_wf3\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_parent get_parent_locs get_child_nodes get_child_nodes_locs set_child_nodes set_child_nodes_locs get_ancestors get_ancestors_locs adopt_node adopt_node_locs set_disconnected_nodes set_disconnected_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs get_owner_document insert_before insert_before_locs append_child type_wf known_ptr known_ptrs heap_is_wellformed parent_child_rel remove_child remove_child_locs get_root_node get_root_node_locs remove by(auto simp add: l_insert_before_wf3\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) declare l_insert_before_wf3\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] locale l_append_child_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_adopt_node\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_insert_before\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_append_child\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M + l_insert_before_wf + l_insert_before_wf2 + l_get_child_nodes begin lemma append_child_heap_is_wellformed_preserved: assumes wellformed: "heap_is_wellformed h" and append_child: "h \ append_child ptr node \\<^sub>h h'" and known_ptrs: "known_ptrs h" and type_wf: "type_wf h" shows "heap_is_wellformed h'" and "type_wf h'" and "known_ptrs h'" using assms by(auto simp add: append_child_def intro: insert_before_preserves_type_wf insert_before_preserves_known_ptrs insert_before_heap_is_wellformed_preserved) lemma append_child_children: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_child_nodes ptr \\<^sub>r xs" assumes "h \ append_child ptr node \\<^sub>h h'" assumes "node \ set xs" shows "h' \ get_child_nodes ptr \\<^sub>r xs @ [node]" proof - obtain ancestors owner_document h2 h3 disconnected_nodes_h2 where ancestors: "h \ get_ancestors ptr \\<^sub>r ancestors" and node_not_in_ancestors: "cast node \ set ancestors" and owner_document: "h \ get_owner_document ptr \\<^sub>r owner_document" and h2: "h \ adopt_node owner_document node \\<^sub>h h2" and disconnected_nodes_h2: "h2 \ get_disconnected_nodes owner_document \\<^sub>r disconnected_nodes_h2" and h3: "h2 \ set_disconnected_nodes owner_document (remove1 node disconnected_nodes_h2) \\<^sub>h h3" and h': "h3 \ a_insert_node ptr node None \\<^sub>h h'" using assms(5) by(auto simp add: append_child_def insert_before_def a_ensure_pre_insertion_validity_def elim!: bind_returns_heap_E bind_returns_result_E bind_returns_heap_E2[rotated, OF get_parent_pure, rotated] bind_returns_heap_E2[rotated, OF get_child_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] bind_returns_heap_E2[rotated, OF get_ancestors_pure, rotated] bind_returns_heap_E2[rotated, OF next_sibling_pure, rotated] bind_returns_heap_E2[rotated, OF get_owner_document_pure, rotated] split: if_splits option.splits) have "\parent. |h \ get_parent node|\<^sub>r = Some parent \ parent \ ptr" using assms(1) assms(4) assms(6) by (metis (no_types, lifting) assms(2) assms(3) h2 is_OK_returns_heap_I is_OK_returns_result_E local.adopt_node_child_in_heap local.get_parent_child_dual local.get_parent_ok select_result_I2) have "h2 \ get_child_nodes ptr \\<^sub>r xs" using get_child_nodes_reads adopt_node_writes h2 assms(4) apply(rule reads_writes_separate_forwards) using \\parent. |h \ get_parent node|\<^sub>r = Some parent \ parent \ ptr\ apply(auto simp add: adopt_node_locs_def remove_child_locs_def)[1] by (meson local.set_child_nodes_get_child_nodes_different_pointers) have "h3 \ get_child_nodes ptr \\<^sub>r xs" using get_child_nodes_reads set_disconnected_nodes_writes h3 \h2 \ get_child_nodes ptr \\<^sub>r xs\ apply(rule reads_writes_separate_forwards) by(auto) have "ptr |\| object_ptr_kinds h" by (meson ancestors is_OK_returns_result_I local.get_ancestors_ptr_in_heap) then have "known_ptr ptr" using assms(3) using local.known_ptrs_known_ptr by blast have "type_wf h2" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF adopt_node_writes h2] using adopt_node_types_preserved \type_wf h\ by(auto simp add: adopt_node_locs_def remove_child_locs_def reflp_def transp_def split: if_splits) then have "type_wf h3" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h3] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) show "h' \ get_child_nodes ptr \\<^sub>r xs@[node]" using h' apply(auto simp add: a_insert_node_def dest!: bind_returns_heap_E3[rotated, OF \h3 \ get_child_nodes ptr \\<^sub>r xs\ get_child_nodes_pure, rotated])[1] using \type_wf h3\ set_child_nodes_get_child_nodes \known_ptr ptr\ by metis qed lemma append_child_for_all_on_children: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_child_nodes ptr \\<^sub>r xs" assumes "h \ forall_M (append_child ptr) nodes \\<^sub>h h'" assumes "set nodes \ set xs = {}" assumes "distinct nodes" shows "h' \ get_child_nodes ptr \\<^sub>r xs@nodes" using assms apply(induct nodes arbitrary: h xs) apply(simp) proof(auto elim!: bind_returns_heap_E)[1]fix a nodes h xs h'a assume 0: "(\h xs. heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ get_child_nodes ptr \\<^sub>r xs \ h \ forall_M (append_child ptr) nodes \\<^sub>h h' \ set nodes \ set xs = {} \ h' \ get_child_nodes ptr \\<^sub>r xs @ nodes)" and 1: "heap_is_wellformed h" and 2: "type_wf h" and 3: "known_ptrs h" and 4: "h \ get_child_nodes ptr \\<^sub>r xs" and 5: "h \ append_child ptr a \\<^sub>r ()" and 6: "h \ append_child ptr a \\<^sub>h h'a" and 7: "h'a \ forall_M (append_child ptr) nodes \\<^sub>h h'" and 8: "a \ set xs" and 9: "set nodes \ set xs = {}" and 10: "a \ set nodes" and 11: "distinct nodes" then have "h'a \ get_child_nodes ptr \\<^sub>r xs @ [a]" using append_child_children 6 using "1" "2" "3" "4" "8" by blast moreover have "heap_is_wellformed h'a" and "type_wf h'a" and "known_ptrs h'a" using insert_before_heap_is_wellformed_preserved insert_before_preserves_known_ptrs insert_before_preserves_type_wf 1 2 3 6 append_child_def by metis+ moreover have "set nodes \ set (xs @ [a]) = {}" using 9 10 by auto ultimately show "h' \ get_child_nodes ptr \\<^sub>r xs @ a # nodes" using 0 7 by fastforce qed lemma append_child_for_all_on_no_children: assumes "heap_is_wellformed h" and "type_wf h" and "known_ptrs h" assumes "h \ get_child_nodes ptr \\<^sub>r []" assumes "h \ forall_M (append_child ptr) nodes \\<^sub>h h'" assumes "distinct nodes" shows "h' \ get_child_nodes ptr \\<^sub>r nodes" using assms append_child_for_all_on_children by force end locale l_append_child_wf = l_type_wf + l_known_ptrs + l_append_child_defs + l_heap_is_wellformed_defs + assumes append_child_preserves_type_wf: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ append_child ptr child \\<^sub>h h' \ type_wf h'" assumes append_child_preserves_known_ptrs: "heap_is_wellformed h \ type_wf h \ known_ptrs h \ h \ append_child ptr child \\<^sub>h h' \ known_ptrs h'" assumes append_child_heap_is_wellformed_preserved: "type_wf h \ known_ptrs h \ heap_is_wellformed h \ h \ append_child ptr child \\<^sub>h h' \ heap_is_wellformed h'" interpretation i_append_child_wf?: l_append_child_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_owner_document get_parent get_parent_locs remove_child remove_child_locs get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs adopt_node adopt_node_locs known_ptr type_wf get_child_nodes get_child_nodes_locs known_ptrs set_child_nodes set_child_nodes_locs remove get_ancestors get_ancestors_locs insert_before insert_before_locs append_child heap_is_wellformed parent_child_rel by(auto simp add: l_append_child_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def instances) lemma append_child_wf_is_l_append_child_wf [instances]: "l_append_child_wf type_wf known_ptr known_ptrs append_child heap_is_wellformed" apply(auto simp add: l_append_child_wf_def l_append_child_wf_axioms_def instances)[1] using append_child_heap_is_wellformed_preserved by fast+ subsection \create\_element\ locale l_create_element_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel + l_new_element_get_disconnected_nodes get_disconnected_nodes get_disconnected_nodes_locs + l_set_tag_name_get_disconnected_nodes type_wf set_tag_name set_tag_name_locs get_disconnected_nodes get_disconnected_nodes_locs + l_create_element\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs set_tag_name set_tag_name_locs type_wf create_element known_ptr + l_new_element_get_child_nodes type_wf known_ptr get_child_nodes get_child_nodes_locs + l_set_tag_name_get_child_nodes type_wf set_tag_name set_tag_name_locs known_ptr get_child_nodes get_child_nodes_locs + l_set_disconnected_nodes_get_child_nodes set_disconnected_nodes set_disconnected_nodes_locs get_child_nodes get_child_nodes_locs + l_set_disconnected_nodes type_wf set_disconnected_nodes set_disconnected_nodes_locs + l_set_disconnected_nodes_get_disconnected_nodes type_wf get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs + l_new_element type_wf + l_known_ptrs known_ptr known_ptrs for known_ptr :: "(_::linorder) object_ptr \ bool" and known_ptrs :: "(_) heap \ bool" and type_wf :: "(_) heap \ bool" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" and set_tag_name :: "(_) element_ptr \ char list \ ((_) heap, exception, unit) prog" and set_tag_name_locs :: "(_) element_ptr \ ((_) heap, exception, unit) prog set" and set_disconnected_nodes :: "(_) document_ptr \ (_) node_ptr list \ ((_) heap, exception, unit) prog" and set_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap, exception, unit) prog set" and create_element :: "(_) document_ptr \ char list \ ((_) heap, exception, (_) element_ptr) prog" begin lemma create_element_preserves_wellformedness: assumes "heap_is_wellformed h" and "h \ create_element document_ptr tag \\<^sub>h h'" and "type_wf h" and "known_ptrs h" shows "heap_is_wellformed h'" and "type_wf h'" and "known_ptrs h'" proof - obtain new_element_ptr h2 h3 disc_nodes_h3 where new_element_ptr: "h \ new_element \\<^sub>r new_element_ptr" and h2: "h \ new_element \\<^sub>h h2" and h3: "h2 \ set_tag_name new_element_ptr tag \\<^sub>h h3" and disc_nodes_h3: "h3 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_h3" and h': "h3 \ set_disconnected_nodes document_ptr (cast new_element_ptr # disc_nodes_h3) \\<^sub>h h'" using assms(2) by(auto simp add: create_element_def elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] ) then have "h \ create_element document_ptr tag \\<^sub>r new_element_ptr" apply(auto simp add: create_element_def intro!: bind_returns_result_I)[1] apply (metis is_OK_returns_heap_I is_OK_returns_result_E old.unit.exhaust) apply (metis is_OK_returns_heap_E is_OK_returns_result_I local.get_disconnected_nodes_pure pure_returns_heap_eq) by (metis is_OK_returns_heap_I is_OK_returns_result_E old.unit.exhaust) have "new_element_ptr \ set |h \ element_ptr_kinds_M|\<^sub>r" using new_element_ptr ElementMonad.ptr_kinds_ptr_kinds_M h2 using new_element_ptr_not_in_heap by blast then have "cast new_element_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r" by simp then have "cast new_element_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r" by simp have object_ptr_kinds_eq_h: "object_ptr_kinds h2 = object_ptr_kinds h |\| {|cast new_element_ptr|}" using new_element_new_ptr h2 new_element_ptr by blast then have node_ptr_kinds_eq_h: "node_ptr_kinds h2 = node_ptr_kinds h |\| {|cast new_element_ptr|}" apply(simp add: node_ptr_kinds_def) by force then have element_ptr_kinds_eq_h: "element_ptr_kinds h2 = element_ptr_kinds h |\| {|new_element_ptr|}" apply(simp add: element_ptr_kinds_def) by force have character_data_ptr_kinds_eq_h: "character_data_ptr_kinds h2 = character_data_ptr_kinds h" using object_ptr_kinds_eq_h by(auto simp add: node_ptr_kinds_def character_data_ptr_kinds_def) have document_ptr_kinds_eq_h: "document_ptr_kinds h2 = document_ptr_kinds h" using object_ptr_kinds_eq_h by(auto simp add: document_ptr_kinds_def) have object_ptr_kinds_eq_h2: "object_ptr_kinds h3 = object_ptr_kinds h2" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h' = object_ptr_kinds h", OF set_tag_name_writes h3]) using set_tag_name_pointers_preserved by (auto simp add: reflp_def transp_def) then have document_ptr_kinds_eq_h2: "document_ptr_kinds h3 = document_ptr_kinds h2" by (auto simp add: document_ptr_kinds_def) have node_ptr_kinds_eq_h2: "node_ptr_kinds h3 = node_ptr_kinds h2" using object_ptr_kinds_eq_h2 by(auto simp add: node_ptr_kinds_def) have object_ptr_kinds_eq_h3: "object_ptr_kinds h' = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h' = object_ptr_kinds h", OF set_disconnected_nodes_writes h']) using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have document_ptr_kinds_eq_h3: "document_ptr_kinds h' = document_ptr_kinds h3" by (auto simp add: document_ptr_kinds_def) have node_ptr_kinds_eq_h3: "node_ptr_kinds h' = node_ptr_kinds h3" using object_ptr_kinds_eq_h3 by(auto simp add: node_ptr_kinds_def) have "known_ptr (cast new_element_ptr)" using \h \ create_element document_ptr tag \\<^sub>r new_element_ptr\ local.create_element_known_ptr by blast then have "known_ptrs h2" using known_ptrs_new_ptr object_ptr_kinds_eq_h \known_ptrs h\ h2 by blast then have "known_ptrs h3" using known_ptrs_preserved object_ptr_kinds_eq_h2 by blast then show "known_ptrs h'" using known_ptrs_preserved object_ptr_kinds_eq_h3 by blast have "document_ptr |\| document_ptr_kinds h" using disc_nodes_h3 document_ptr_kinds_eq_h object_ptr_kinds_eq_h2 get_disconnected_nodes_ptr_in_heap \type_wf h\ document_ptr_kinds_def by (metis is_OK_returns_result_I) have children_eq_h: "\(ptr'::(_) object_ptr) children. ptr' \ cast new_element_ptr \ h \ get_child_nodes ptr' \\<^sub>r children = h2 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads h2 get_child_nodes_new_element[rotated, OF new_element_ptr h2] apply(auto simp add: reads_def reflp_def transp_def preserved_def)[1] by blast+ then have children_eq2_h: "\ptr'. ptr' \ cast new_element_ptr \ |h \ get_child_nodes ptr'|\<^sub>r = |h2 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have "h2 \ get_child_nodes (cast new_element_ptr) \\<^sub>r []" using new_element_ptr h2 new_element_ptr_in_heap[OF h2 new_element_ptr] new_element_is_element_ptr[OF new_element_ptr] new_element_no_child_nodes by blast have disconnected_nodes_eq_h: "\doc_ptr disc_nodes. h \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads h2 get_disconnected_nodes_new_element[OF new_element_ptr h2] apply(auto simp add: reads_def reflp_def transp_def preserved_def)[1] by blast+ then have disconnected_nodes_eq2_h: "\doc_ptr. |h \ get_disconnected_nodes doc_ptr|\<^sub>r = |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have children_eq_h2: "\ptr' children. h2 \ get_child_nodes ptr' \\<^sub>r children = h3 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads set_tag_name_writes h3 apply(rule reads_writes_preserved) by(auto simp add: set_tag_name_get_child_nodes) then have children_eq2_h2: "\ptr'. |h2 \ get_child_nodes ptr'|\<^sub>r = |h3 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq_h2: "\doc_ptr disc_nodes. h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_tag_name_writes h3 apply(rule reads_writes_preserved) by(auto simp add: set_tag_name_get_disconnected_nodes) then have disconnected_nodes_eq2_h2: "\doc_ptr. |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have "type_wf h2" using \type_wf h\ new_element_types_preserved h2 by blast then have "type_wf h3" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_tag_name_writes h3] using set_tag_name_types_preserved by(auto simp add: reflp_def transp_def) then show "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h'] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) have children_eq_h3: "\ptr' children. h3 \ get_child_nodes ptr' \\<^sub>r children = h' \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h' apply(rule reads_writes_preserved) by(auto simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h3: "\ptr'. |h3 \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq_h3: "\doc_ptr disc_nodes. document_ptr \ doc_ptr \ h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h' \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_disconnected_nodes_writes h' apply(rule reads_writes_preserved) by(auto simp add: set_disconnected_nodes_get_disconnected_nodes_different_pointers) then have disconnected_nodes_eq2_h3: "\doc_ptr. document_ptr \ doc_ptr \ |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have disc_nodes_document_ptr_h2: "h2 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_h3" using disconnected_nodes_eq_h2 disc_nodes_h3 by auto then have disc_nodes_document_ptr_h: "h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_h3" using disconnected_nodes_eq_h by auto then have "cast new_element_ptr \ set disc_nodes_h3" using \heap_is_wellformed h\ using \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ a_all_ptrs_in_heap_def heap_is_wellformed_def using NodeMonad.ptr_kinds_ptr_kinds_M local.heap_is_wellformed_disc_nodes_in_heap by blast have "acyclic (parent_child_rel h)" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def acyclic_heap_def) also have "parent_child_rel h = parent_child_rel h2" proof(auto simp add: parent_child_rel_def)[1] fix a x assume 0: "a |\| object_ptr_kinds h" and 1: "x \ set |h \ get_child_nodes a|\<^sub>r" then show "a |\| object_ptr_kinds h2" by (simp add: object_ptr_kinds_eq_h) next fix a x assume 0: "a |\| object_ptr_kinds h" and 1: "x \ set |h \ get_child_nodes a|\<^sub>r" then show "x \ set |h2 \ get_child_nodes a|\<^sub>r" by (metis ObjectMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\ children_eq2_h) next fix a x assume 0: "a |\| object_ptr_kinds h2" and 1: "x \ set |h2 \ get_child_nodes a|\<^sub>r" then show "a |\| object_ptr_kinds h" using object_ptr_kinds_eq_h \h2 \ get_child_nodes (cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr) \\<^sub>r []\ by(auto) next fix a x assume 0: "a |\| object_ptr_kinds h2" and 1: "x \ set |h2 \ get_child_nodes a|\<^sub>r" then show "x \ set |h \ get_child_nodes a|\<^sub>r" by (metis (no_types, lifting) \h2 \ get_child_nodes (cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr) \\<^sub>r []\ children_eq2_h empty_iff empty_set image_eqI select_result_I2) qed also have "\ = parent_child_rel h3" by(auto simp add: parent_child_rel_def object_ptr_kinds_eq_h2 children_eq2_h2) also have "\ = parent_child_rel h'" by(auto simp add: parent_child_rel_def object_ptr_kinds_eq_h3 children_eq2_h3) finally have "a_acyclic_heap h'" by (simp add: acyclic_heap_def) have "a_all_ptrs_in_heap h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_all_ptrs_in_heap h2" apply(auto simp add: a_all_ptrs_in_heap_def)[1] apply (metis \known_ptrs h2\ \parent_child_rel h = parent_child_rel h2\ \type_wf h2\ assms(1) assms(3) funion_iff local.get_child_nodes_ok local.known_ptrs_known_ptr local.parent_child_rel_child_in_heap local.parent_child_rel_child_nodes2 node_ptr_kinds_commutes node_ptr_kinds_eq_h returns_result_select_result) by (metis assms(1) assms(3) disconnected_nodes_eq2_h document_ptr_kinds_eq_h funion_iff local.get_disconnected_nodes_ok local.heap_is_wellformed_disc_nodes_in_heap node_ptr_kinds_eq_h returns_result_select_result) then have "a_all_ptrs_in_heap h3" by (simp add: children_eq2_h2 disconnected_nodes_eq2_h2 document_ptr_kinds_eq_h2 local.a_all_ptrs_in_heap_def node_ptr_kinds_eq_h2 object_ptr_kinds_eq_h2) then have "a_all_ptrs_in_heap h'" by (smt \h2 \ get_child_nodes (cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr) \\<^sub>r []\ children_eq2_h3 disc_nodes_document_ptr_h2 disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 document_ptr_kinds_eq_h3 finite_set_in h' is_OK_returns_result_I set_disconnected_nodes_get_disconnected_nodes local.a_all_ptrs_in_heap_def local.get_child_nodes_ptr_in_heap node_ptr_kinds_commutes object_ptr_kinds_eq_h2 object_ptr_kinds_eq_h3 select_result_I2 set_ConsD subset_code(1)) have "\p. p |\| object_ptr_kinds h \ cast new_element_ptr \ set |h \ get_child_nodes p|\<^sub>r" using \heap_is_wellformed h\ \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ heap_is_wellformed_children_in_heap by (meson NodeMonad.ptr_kinds_ptr_kinds_M a_all_ptrs_in_heap_def assms(3) assms(4) fset_mp fset_of_list_elem get_child_nodes_ok known_ptrs_known_ptr returns_result_select_result) then have "\p. p |\| object_ptr_kinds h2 \ cast new_element_ptr \ set |h2 \ get_child_nodes p|\<^sub>r" using children_eq2_h apply(auto simp add: object_ptr_kinds_eq_h)[1] using \h2 \ get_child_nodes (cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr) \\<^sub>r []\ apply auto[1] by (metis ObjectMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\) then have "\p. p |\| object_ptr_kinds h3 \ cast new_element_ptr \ set |h3 \ get_child_nodes p|\<^sub>r" using object_ptr_kinds_eq_h2 children_eq2_h2 by auto then have new_element_ptr_not_in_any_children: "\p. p |\| object_ptr_kinds h' \ cast new_element_ptr \ set |h' \ get_child_nodes p|\<^sub>r" using object_ptr_kinds_eq_h3 children_eq2_h3 by auto have "a_distinct_lists h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_distinct_lists h2" using \h2 \ get_child_nodes (cast new_element_ptr) \\<^sub>r []\ apply(auto simp add: a_distinct_lists_def object_ptr_kinds_eq_h document_ptr_kinds_eq_h disconnected_nodes_eq2_h intro!: distinct_concat_map_I)[1] apply (metis distinct_sorted_list_of_set finite_fset sorted_list_of_set_insert) apply(case_tac "x=cast new_element_ptr") apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] apply (metis IntI assms(1) assms(3) assms(4) empty_iff local.get_child_nodes_ok local.heap_is_wellformed_one_parent local.known_ptrs_known_ptr returns_result_select_result) apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] by (metis \local.a_distinct_lists h\ \type_wf h2\ disconnected_nodes_eq_h document_ptr_kinds_eq_h local.distinct_lists_no_parent local.get_disconnected_nodes_ok returns_result_select_result) then have "a_distinct_lists h3" by(auto simp add: a_distinct_lists_def disconnected_nodes_eq2_h2 document_ptr_kinds_eq_h2 children_eq2_h2 object_ptr_kinds_eq_h2) then have "a_distinct_lists h'" proof(auto simp add: a_distinct_lists_def disconnected_nodes_eq2_h3 children_eq2_h3 object_ptr_kinds_eq_h3 document_ptr_kinds_eq_h3 intro!: distinct_concat_map_I)[1] fix x assume "distinct (concat (map (\document_ptr. |h3 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h3)))))" and "x |\| document_ptr_kinds h3" then show "distinct |h' \ get_disconnected_nodes x|\<^sub>r" using document_ptr_kinds_eq_h3 disconnected_nodes_eq_h3 h' set_disconnected_nodes_get_disconnected_nodes by (metis (no_types, lifting) \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set disc_nodes_h3\ \a_distinct_lists h3\ \type_wf h'\ disc_nodes_h3 distinct.simps(2) distinct_lists_disconnected_nodes get_disconnected_nodes_ok returns_result_eq returns_result_select_result) next fix x y xa assume "distinct (concat (map (\document_ptr. |h3 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h3)))))" and "x |\| document_ptr_kinds h3" and "y |\| document_ptr_kinds h3" and "x \ y" and "xa \ set |h' \ get_disconnected_nodes x|\<^sub>r" and "xa \ set |h' \ get_disconnected_nodes y|\<^sub>r" moreover have "set |h3 \ get_disconnected_nodes x|\<^sub>r \ set |h3 \ get_disconnected_nodes y|\<^sub>r = {}" using calculation by(auto dest: distinct_concat_map_E(1)) ultimately show "False" apply(-) apply(cases "x = document_ptr") apply (smt NodeMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ \local.a_all_ptrs_in_heap h\ disc_nodes_h3 disconnected_nodes_eq2_h disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 disjoint_iff_not_equal document_ptr_kinds_eq_h document_ptr_kinds_eq_h2 finite_set_in h' l_set_disconnected_nodes_get_disconnected_nodes.set_disconnected_nodes_get_disconnected_nodes local.a_all_ptrs_in_heap_def local.l_set_disconnected_nodes_get_disconnected_nodes_axioms select_result_I2 set_ConsD subsetD) by (smt NodeMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ \local.a_all_ptrs_in_heap h\ disc_nodes_document_ptr_h2 disconnected_nodes_eq2_h disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 disjoint_iff_not_equal document_ptr_kinds_eq_h document_ptr_kinds_eq_h2 finite_set_in h' l_set_disconnected_nodes_get_disconnected_nodes.set_disconnected_nodes_get_disconnected_nodes local.a_all_ptrs_in_heap_def local.l_set_disconnected_nodes_get_disconnected_nodes_axioms select_result_I2 set_ConsD subsetD) next fix x xa xb assume 2: "(\x\fset (object_ptr_kinds h3). set |h' \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h3). set |h3 \ get_disconnected_nodes x|\<^sub>r) = {}" and 3: "xa |\| object_ptr_kinds h3" and 4: "x \ set |h' \ get_child_nodes xa|\<^sub>r" and 5: "xb |\| document_ptr_kinds h3" and 6: "x \ set |h' \ get_disconnected_nodes xb|\<^sub>r" show "False" using disc_nodes_document_ptr_h disconnected_nodes_eq2_h3 apply - apply(cases "xb = document_ptr") apply (metis (no_types, hide_lams) "3" "4" "6" \\p. p |\| object_ptr_kinds h3 \ cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h3 \ get_child_nodes p|\<^sub>r\ \a_distinct_lists h3\ children_eq2_h3 disc_nodes_h3 distinct_lists_no_parent h' select_result_I2 set_ConsD set_disconnected_nodes_get_disconnected_nodes) by (metis "3" "4" "5" "6" \a_distinct_lists h3\ \type_wf h3\ children_eq2_h3 distinct_lists_no_parent get_disconnected_nodes_ok returns_result_select_result) qed have "a_owner_document_valid h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_owner_document_valid h'" using disc_nodes_h3 \document_ptr |\| document_ptr_kinds h\ apply(auto simp add: a_owner_document_valid_def)[1] apply(auto simp add: object_ptr_kinds_eq_h object_ptr_kinds_eq_h3 )[1] apply(auto simp add: object_ptr_kinds_eq_h2)[1] apply(auto simp add: document_ptr_kinds_eq_h document_ptr_kinds_eq_h3 )[1] apply(auto simp add: document_ptr_kinds_eq_h2)[1] apply(auto simp add: node_ptr_kinds_eq_h node_ptr_kinds_eq_h3 )[1] apply(auto simp add: node_ptr_kinds_eq_h2 node_ptr_kinds_eq_h )[1] apply(auto simp add: children_eq2_h2[symmetric] children_eq2_h3[symmetric] disconnected_nodes_eq2_h disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3)[1] apply (metis (no_types, lifting) document_ptr_kinds_eq_h h' list.set_intros(1) local.set_disconnected_nodes_get_disconnected_nodes select_result_I2) apply(simp add: object_ptr_kinds_eq_h) by (smt ObjectMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>e\<^sub>l\<^sub>e\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_element_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\ children_eq2_h children_eq2_h2 children_eq2_h3 disconnected_nodes_eq2_h disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 document_ptr_kinds_eq_h finite_set_in h' list.set_intros(2) local.set_disconnected_nodes_get_disconnected_nodes select_result_I2) show "heap_is_wellformed h'" using \a_acyclic_heap h'\ \a_all_ptrs_in_heap h'\ \a_distinct_lists h'\ \a_owner_document_valid h'\ by(simp add: heap_is_wellformed_def) qed end interpretation i_create_element_wf?: l_create_element_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr known_ptrs type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel set_tag_name set_tag_name_locs set_disconnected_nodes set_disconnected_nodes_locs create_element using instances by(auto simp add: l_create_element_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) declare l_create_element_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] subsection \create\_character\_data\ locale l_create_character_data_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel + l_new_character_data_get_disconnected_nodes get_disconnected_nodes get_disconnected_nodes_locs + l_set_val_get_disconnected_nodes type_wf set_val set_val_locs get_disconnected_nodes get_disconnected_nodes_locs + l_create_character_data\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs set_val set_val_locs type_wf create_character_data known_ptr + l_new_character_data_get_child_nodes type_wf known_ptr get_child_nodes get_child_nodes_locs + l_set_val_get_child_nodes type_wf set_val set_val_locs known_ptr get_child_nodes get_child_nodes_locs + l_set_disconnected_nodes_get_child_nodes set_disconnected_nodes set_disconnected_nodes_locs get_child_nodes get_child_nodes_locs + l_set_disconnected_nodes type_wf set_disconnected_nodes set_disconnected_nodes_locs + l_set_disconnected_nodes_get_disconnected_nodes type_wf get_disconnected_nodes get_disconnected_nodes_locs set_disconnected_nodes set_disconnected_nodes_locs + l_new_character_data type_wf + l_known_ptrs known_ptr known_ptrs for known_ptr :: "(_::linorder) object_ptr \ bool" and type_wf :: "(_) heap \ bool" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" and set_val :: "(_) character_data_ptr \ char list \ ((_) heap, exception, unit) prog" and set_val_locs :: "(_) character_data_ptr \ ((_) heap, exception, unit) prog set" and set_disconnected_nodes :: "(_) document_ptr \ (_) node_ptr list \ ((_) heap, exception, unit) prog" and set_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap, exception, unit) prog set" and create_character_data :: "(_) document_ptr \ char list \ ((_) heap, exception, (_) character_data_ptr) prog" and known_ptrs :: "(_) heap \ bool" begin lemma create_character_data_preserves_wellformedness: assumes "heap_is_wellformed h" and "h \ create_character_data document_ptr text \\<^sub>h h'" and "type_wf h" and "known_ptrs h" shows "heap_is_wellformed h'" and "type_wf h'" and "known_ptrs h'" proof - obtain new_character_data_ptr h2 h3 disc_nodes_h3 where new_character_data_ptr: "h \ new_character_data \\<^sub>r new_character_data_ptr" and h2: "h \ new_character_data \\<^sub>h h2" and h3: "h2 \ set_val new_character_data_ptr text \\<^sub>h h3" and disc_nodes_h3: "h3 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_h3" and h': "h3 \ set_disconnected_nodes document_ptr (cast new_character_data_ptr # disc_nodes_h3) \\<^sub>h h'" using assms(2) by(auto simp add: create_character_data_def elim!: bind_returns_heap_E bind_returns_heap_E2[rotated, OF get_disconnected_nodes_pure, rotated] ) then have "h \ create_character_data document_ptr text \\<^sub>r new_character_data_ptr" apply(auto simp add: create_character_data_def intro!: bind_returns_result_I)[1] apply (metis is_OK_returns_heap_I is_OK_returns_result_E old.unit.exhaust) apply (metis is_OK_returns_heap_E is_OK_returns_result_I local.get_disconnected_nodes_pure pure_returns_heap_eq) by (metis is_OK_returns_heap_I is_OK_returns_result_E old.unit.exhaust) have "new_character_data_ptr \ set |h \ character_data_ptr_kinds_M|\<^sub>r" using new_character_data_ptr CharacterDataMonad.ptr_kinds_ptr_kinds_M h2 using new_character_data_ptr_not_in_heap by blast then have "cast new_character_data_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r" by simp then have "cast new_character_data_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r" by simp have object_ptr_kinds_eq_h: "object_ptr_kinds h2 = object_ptr_kinds h |\| {|cast new_character_data_ptr|}" using new_character_data_new_ptr h2 new_character_data_ptr by blast then have node_ptr_kinds_eq_h: "node_ptr_kinds h2 = node_ptr_kinds h |\| {|cast new_character_data_ptr|}" apply(simp add: node_ptr_kinds_def) by force then have character_data_ptr_kinds_eq_h: "character_data_ptr_kinds h2 = character_data_ptr_kinds h |\| {|new_character_data_ptr|}" apply(simp add: character_data_ptr_kinds_def) by force have element_ptr_kinds_eq_h: "element_ptr_kinds h2 = element_ptr_kinds h" using object_ptr_kinds_eq_h by(auto simp add: node_ptr_kinds_def element_ptr_kinds_def) have document_ptr_kinds_eq_h: "document_ptr_kinds h2 = document_ptr_kinds h" using object_ptr_kinds_eq_h by(auto simp add: document_ptr_kinds_def) have object_ptr_kinds_eq_h2: "object_ptr_kinds h3 = object_ptr_kinds h2" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h' = object_ptr_kinds h", OF set_val_writes h3]) using set_val_pointers_preserved by (auto simp add: reflp_def transp_def) then have document_ptr_kinds_eq_h2: "document_ptr_kinds h3 = document_ptr_kinds h2" by (auto simp add: document_ptr_kinds_def) have node_ptr_kinds_eq_h2: "node_ptr_kinds h3 = node_ptr_kinds h2" using object_ptr_kinds_eq_h2 by(auto simp add: node_ptr_kinds_def) have object_ptr_kinds_eq_h3: "object_ptr_kinds h' = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h' = object_ptr_kinds h", OF set_disconnected_nodes_writes h']) using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have document_ptr_kinds_eq_h3: "document_ptr_kinds h' = document_ptr_kinds h3" by (auto simp add: document_ptr_kinds_def) have node_ptr_kinds_eq_h3: "node_ptr_kinds h' = node_ptr_kinds h3" using object_ptr_kinds_eq_h3 by(auto simp add: node_ptr_kinds_def) have "document_ptr |\| document_ptr_kinds h" using disc_nodes_h3 document_ptr_kinds_eq_h object_ptr_kinds_eq_h2 get_disconnected_nodes_ptr_in_heap \type_wf h\ document_ptr_kinds_def by (metis is_OK_returns_result_I) have children_eq_h: "\(ptr'::(_) object_ptr) children. ptr' \ cast new_character_data_ptr \ h \ get_child_nodes ptr' \\<^sub>r children = h2 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads h2 get_child_nodes_new_character_data[rotated, OF new_character_data_ptr h2] apply(auto simp add: reads_def reflp_def transp_def preserved_def)[1] by blast+ then have children_eq2_h: "\ptr'. ptr' \ cast new_character_data_ptr \ |h \ get_child_nodes ptr'|\<^sub>r = |h2 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have object_ptr_kinds_eq_h: "object_ptr_kinds h2 = object_ptr_kinds h |\| {|cast new_character_data_ptr|}" using new_character_data_new_ptr h2 new_character_data_ptr by blast then have node_ptr_kinds_eq_h: "node_ptr_kinds h2 = node_ptr_kinds h |\| {|cast new_character_data_ptr|}" apply(simp add: node_ptr_kinds_def) by force then have character_data_ptr_kinds_eq_h: "character_data_ptr_kinds h2 = character_data_ptr_kinds h |\| {|new_character_data_ptr|}" apply(simp add: character_data_ptr_kinds_def) by force have element_ptr_kinds_eq_h: "element_ptr_kinds h2 = element_ptr_kinds h" using object_ptr_kinds_eq_h by(auto simp add: node_ptr_kinds_def element_ptr_kinds_def) have document_ptr_kinds_eq_h: "document_ptr_kinds h2 = document_ptr_kinds h" using object_ptr_kinds_eq_h by(auto simp add: document_ptr_kinds_def) have object_ptr_kinds_eq_h2: "object_ptr_kinds h3 = object_ptr_kinds h2" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h' = object_ptr_kinds h", OF set_val_writes h3]) using set_val_pointers_preserved by (auto simp add: reflp_def transp_def) then have document_ptr_kinds_eq_h2: "document_ptr_kinds h3 = document_ptr_kinds h2" by (auto simp add: document_ptr_kinds_def) have node_ptr_kinds_eq_h2: "node_ptr_kinds h3 = node_ptr_kinds h2" using object_ptr_kinds_eq_h2 by(auto simp add: node_ptr_kinds_def) have object_ptr_kinds_eq_h3: "object_ptr_kinds h' = object_ptr_kinds h3" apply(rule writes_small_big[where P="\h h'. object_ptr_kinds h' = object_ptr_kinds h", OF set_disconnected_nodes_writes h']) using set_disconnected_nodes_pointers_preserved by (auto simp add: reflp_def transp_def) then have document_ptr_kinds_eq_h3: "document_ptr_kinds h' = document_ptr_kinds h3" by (auto simp add: document_ptr_kinds_def) have node_ptr_kinds_eq_h3: "node_ptr_kinds h' = node_ptr_kinds h3" using object_ptr_kinds_eq_h3 by(auto simp add: node_ptr_kinds_def) have "document_ptr |\| document_ptr_kinds h" using disc_nodes_h3 document_ptr_kinds_eq_h object_ptr_kinds_eq_h2 get_disconnected_nodes_ptr_in_heap \type_wf h\ document_ptr_kinds_def by (metis is_OK_returns_result_I) have children_eq_h: "\(ptr'::(_) object_ptr) children. ptr' \ cast new_character_data_ptr \ h \ get_child_nodes ptr' \\<^sub>r children = h2 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads h2 get_child_nodes_new_character_data[rotated, OF new_character_data_ptr h2] apply(auto simp add: reads_def reflp_def transp_def preserved_def)[1] by blast+ then have children_eq2_h: "\ptr'. ptr' \ cast new_character_data_ptr \ |h \ get_child_nodes ptr'|\<^sub>r = |h2 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have "h2 \ get_child_nodes (cast new_character_data_ptr) \\<^sub>r []" using new_character_data_ptr h2 new_character_data_ptr_in_heap[OF h2 new_character_data_ptr] new_character_data_is_character_data_ptr[OF new_character_data_ptr] new_character_data_no_child_nodes by blast have disconnected_nodes_eq_h: "\doc_ptr disc_nodes. h \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads h2 get_disconnected_nodes_new_character_data[OF new_character_data_ptr h2] apply(auto simp add: reads_def reflp_def transp_def preserved_def)[1] by blast+ then have disconnected_nodes_eq2_h: "\doc_ptr. |h \ get_disconnected_nodes doc_ptr|\<^sub>r = |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have children_eq_h2: "\ptr' children. h2 \ get_child_nodes ptr' \\<^sub>r children = h3 \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads set_val_writes h3 apply(rule reads_writes_preserved) by(auto simp add: set_val_get_child_nodes) then have children_eq2_h2: "\ptr'. |h2 \ get_child_nodes ptr'|\<^sub>r = |h3 \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq_h2: "\doc_ptr disc_nodes. h2 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_val_writes h3 apply(rule reads_writes_preserved) by(auto simp add: set_val_get_disconnected_nodes) then have disconnected_nodes_eq2_h2: "\doc_ptr. |h2 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have "type_wf h2" using \type_wf h\ new_character_data_types_preserved h2 by blast then have "type_wf h3" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_val_writes h3] using set_val_types_preserved by(auto simp add: reflp_def transp_def) then show "type_wf h'" using writes_small_big[where P="\h h'. type_wf h \ type_wf h'", OF set_disconnected_nodes_writes h'] using set_disconnected_nodes_types_preserved by(auto simp add: reflp_def transp_def) have children_eq_h3: "\ptr' children. h3 \ get_child_nodes ptr' \\<^sub>r children = h' \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads set_disconnected_nodes_writes h' apply(rule reads_writes_preserved) by(auto simp add: set_disconnected_nodes_get_child_nodes) then have children_eq2_h3: " \ptr'. |h3 \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have disconnected_nodes_eq_h3: "\doc_ptr disc_nodes. document_ptr \ doc_ptr \ h3 \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h' \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads set_disconnected_nodes_writes h' apply(rule reads_writes_preserved) by(auto simp add: set_disconnected_nodes_get_disconnected_nodes_different_pointers) then have disconnected_nodes_eq2_h3: "\doc_ptr. document_ptr \ doc_ptr \ |h3 \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have disc_nodes_document_ptr_h2: "h2 \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_h3" using disconnected_nodes_eq_h2 disc_nodes_h3 by auto then have disc_nodes_document_ptr_h: "h \ get_disconnected_nodes document_ptr \\<^sub>r disc_nodes_h3" using disconnected_nodes_eq_h by auto then have "cast new_character_data_ptr \ set disc_nodes_h3" using \heap_is_wellformed h\ using \cast new_character_data_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ a_all_ptrs_in_heap_def heap_is_wellformed_def using NodeMonad.ptr_kinds_ptr_kinds_M local.heap_is_wellformed_disc_nodes_in_heap by blast have "acyclic (parent_child_rel h)" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def acyclic_heap_def) also have "parent_child_rel h = parent_child_rel h2" proof(auto simp add: parent_child_rel_def)[1] fix a x assume 0: "a |\| object_ptr_kinds h" and 1: "x \ set |h \ get_child_nodes a|\<^sub>r" then show "a |\| object_ptr_kinds h2" by (simp add: object_ptr_kinds_eq_h) next fix a x assume 0: "a |\| object_ptr_kinds h" and 1: "x \ set |h \ get_child_nodes a|\<^sub>r" then show "x \ set |h2 \ get_child_nodes a|\<^sub>r" by (metis ObjectMonad.ptr_kinds_ptr_kinds_M \cast new_character_data_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\ children_eq2_h) next fix a x assume 0: "a |\| object_ptr_kinds h2" and 1: "x \ set |h2 \ get_child_nodes a|\<^sub>r" then show "a |\| object_ptr_kinds h" using object_ptr_kinds_eq_h \h2 \ get_child_nodes (cast new_character_data_ptr) \\<^sub>r []\ by(auto) next fix a x assume 0: "a |\| object_ptr_kinds h2" and 1: "x \ set |h2 \ get_child_nodes a|\<^sub>r" then show "x \ set |h \ get_child_nodes a|\<^sub>r" by (metis (no_types, lifting) \h2 \ get_child_nodes (cast new_character_data_ptr) \\<^sub>r []\ children_eq2_h empty_iff empty_set image_eqI select_result_I2) qed also have "\ = parent_child_rel h3" by(auto simp add: parent_child_rel_def object_ptr_kinds_eq_h2 children_eq2_h2) also have "\ = parent_child_rel h'" by(auto simp add: parent_child_rel_def object_ptr_kinds_eq_h3 children_eq2_h3) finally have "a_acyclic_heap h'" by (simp add: acyclic_heap_def) have "a_all_ptrs_in_heap h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_all_ptrs_in_heap h2" apply(auto simp add: a_all_ptrs_in_heap_def)[1] using node_ptr_kinds_eq_h \cast new_character_data_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ \h2 \ get_child_nodes (cast new_character_data_ptr) \\<^sub>r []\ apply (metis (no_types, lifting) NodeMonad.ptr_kinds_ptr_kinds_M \parent_child_rel h = parent_child_rel h2\ children_eq2_h finite_set_in finsert_iff funion_finsert_right local.parent_child_rel_child local.parent_child_rel_parent_in_heap node_ptr_kinds_commutes object_ptr_kinds_eq_h select_result_I2 subsetD sup_bot.right_neutral) by (metis assms(1) assms(3) disconnected_nodes_eq2_h document_ptr_kinds_eq_h funionI1 local.get_disconnected_nodes_ok local.heap_is_wellformed_disc_nodes_in_heap node_ptr_kinds_eq_h returns_result_select_result) then have "a_all_ptrs_in_heap h3" by (simp add: children_eq2_h2 disconnected_nodes_eq2_h2 document_ptr_kinds_eq_h2 local.a_all_ptrs_in_heap_def node_ptr_kinds_eq_h2 object_ptr_kinds_eq_h2) then have "a_all_ptrs_in_heap h'" by (smt character_data_ptr_kinds_commutes children_eq2_h3 disc_nodes_document_ptr_h2 disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 document_ptr_kinds_eq_h3 finite_set_in h' h2 local.a_all_ptrs_in_heap_def local.set_disconnected_nodes_get_disconnected_nodes new_character_data_ptr new_character_data_ptr_in_heap node_ptr_kinds_eq_h2 node_ptr_kinds_eq_h3 object_ptr_kinds_eq_h3 select_result_I2 set_ConsD subset_code(1)) have "\p. p |\| object_ptr_kinds h \ cast new_character_data_ptr \ set |h \ get_child_nodes p|\<^sub>r" using \heap_is_wellformed h\ \cast new_character_data_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ heap_is_wellformed_children_in_heap by (meson NodeMonad.ptr_kinds_ptr_kinds_M a_all_ptrs_in_heap_def assms(3) assms(4) fset_mp fset_of_list_elem get_child_nodes_ok known_ptrs_known_ptr returns_result_select_result) then have "\p. p |\| object_ptr_kinds h2 \ cast new_character_data_ptr \ set |h2 \ get_child_nodes p|\<^sub>r" using children_eq2_h apply(auto simp add: object_ptr_kinds_eq_h)[1] using \h2 \ get_child_nodes (cast new_character_data_ptr) \\<^sub>r []\ apply auto[1] by (metis ObjectMonad.ptr_kinds_ptr_kinds_M \cast new_character_data_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\) then have "\p. p |\| object_ptr_kinds h3 \ cast new_character_data_ptr \ set |h3 \ get_child_nodes p|\<^sub>r" using object_ptr_kinds_eq_h2 children_eq2_h2 by auto then have new_character_data_ptr_not_in_any_children: "\p. p |\| object_ptr_kinds h' \ cast new_character_data_ptr \ set |h' \ get_child_nodes p|\<^sub>r" using object_ptr_kinds_eq_h3 children_eq2_h3 by auto have "a_distinct_lists h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_distinct_lists h2" using \h2 \ get_child_nodes (cast new_character_data_ptr) \\<^sub>r []\ apply(auto simp add: a_distinct_lists_def object_ptr_kinds_eq_h document_ptr_kinds_eq_h disconnected_nodes_eq2_h intro!: distinct_concat_map_I)[1] apply (metis distinct_sorted_list_of_set finite_fset sorted_list_of_set_insert) apply(case_tac "x=cast new_character_data_ptr") apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] apply (metis IntI assms(1) assms(3) assms(4) empty_iff local.get_child_nodes_ok local.heap_is_wellformed_one_parent local.known_ptrs_known_ptr returns_result_select_result) apply(auto simp add: children_eq2_h[symmetric] insort_split dest: distinct_concat_map_E(2))[1] by (metis \local.a_distinct_lists h\ \type_wf h2\ disconnected_nodes_eq_h document_ptr_kinds_eq_h local.distinct_lists_no_parent local.get_disconnected_nodes_ok returns_result_select_result) then have "a_distinct_lists h3" by(auto simp add: a_distinct_lists_def disconnected_nodes_eq2_h2 document_ptr_kinds_eq_h2 children_eq2_h2 object_ptr_kinds_eq_h2)[1] then have "a_distinct_lists h'" proof(auto simp add: a_distinct_lists_def disconnected_nodes_eq2_h3 children_eq2_h3 object_ptr_kinds_eq_h3 document_ptr_kinds_eq_h3 intro!: distinct_concat_map_I)[1] fix x assume "distinct (concat (map (\document_ptr. |h3 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h3)))))" and "x |\| document_ptr_kinds h3" then show "distinct |h' \ get_disconnected_nodes x|\<^sub>r" using document_ptr_kinds_eq_h3 disconnected_nodes_eq_h3 h' set_disconnected_nodes_get_disconnected_nodes by (metis (no_types, lifting) \cast new_character_data_ptr \ set disc_nodes_h3\ \a_distinct_lists h3\ \type_wf h'\ disc_nodes_h3 distinct.simps(2) distinct_lists_disconnected_nodes get_disconnected_nodes_ok returns_result_eq returns_result_select_result) next fix x y xa assume "distinct (concat (map (\document_ptr. |h3 \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h3)))))" and "x |\| document_ptr_kinds h3" and "y |\| document_ptr_kinds h3" and "x \ y" and "xa \ set |h' \ get_disconnected_nodes x|\<^sub>r" and "xa \ set |h' \ get_disconnected_nodes y|\<^sub>r" moreover have "set |h3 \ get_disconnected_nodes x|\<^sub>r \ set |h3 \ get_disconnected_nodes y|\<^sub>r = {}" using calculation by(auto dest: distinct_concat_map_E(1)) ultimately show "False" by (smt NodeMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>c\<^sub>h\<^sub>a\<^sub>r\<^sub>a\<^sub>c\<^sub>t\<^sub>e\<^sub>r\<^sub>_\<^sub>d\<^sub>a\<^sub>t\<^sub>a\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>n\<^sub>o\<^sub>d\<^sub>e\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_character_data_ptr \ set |h \ node_ptr_kinds_M|\<^sub>r\ \local.a_all_ptrs_in_heap h\ disc_nodes_document_ptr_h2 disconnected_nodes_eq2_h disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3 disjoint_iff_not_equal document_ptr_kinds_eq_h document_ptr_kinds_eq_h2 finite_set_in h' l_set_disconnected_nodes_get_disconnected_nodes.set_disconnected_nodes_get_disconnected_nodes local.a_all_ptrs_in_heap_def local.l_set_disconnected_nodes_get_disconnected_nodes_axioms select_result_I2 set_ConsD subsetD) next fix x xa xb assume 2: "(\x\fset (object_ptr_kinds h3). set |h' \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h3). set |h3 \ get_disconnected_nodes x|\<^sub>r) = {}" and 3: "xa |\| object_ptr_kinds h3" and 4: "x \ set |h' \ get_child_nodes xa|\<^sub>r" and 5: "xb |\| document_ptr_kinds h3" and 6: "x \ set |h' \ get_disconnected_nodes xb|\<^sub>r" show "False" using disc_nodes_document_ptr_h disconnected_nodes_eq2_h3 apply(cases "xb = document_ptr") apply (metis (no_types, hide_lams) "3" "4" "6" \\p. p |\| object_ptr_kinds h3 \ cast new_character_data_ptr \ set |h3 \ get_child_nodes p|\<^sub>r\ \a_distinct_lists h3\ children_eq2_h3 disc_nodes_h3 distinct_lists_no_parent h' select_result_I2 set_ConsD set_disconnected_nodes_get_disconnected_nodes) by (metis "3" "4" "5" "6" \a_distinct_lists h3\ \type_wf h3\ children_eq2_h3 distinct_lists_no_parent get_disconnected_nodes_ok returns_result_select_result) qed have "a_owner_document_valid h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_owner_document_valid h'" using disc_nodes_h3 \document_ptr |\| document_ptr_kinds h\ apply(simp add: a_owner_document_valid_def) apply(simp add: object_ptr_kinds_eq_h object_ptr_kinds_eq_h3 ) apply(simp add: object_ptr_kinds_eq_h2) apply(simp add: document_ptr_kinds_eq_h document_ptr_kinds_eq_h3 ) apply(simp add: document_ptr_kinds_eq_h2) apply(simp add: node_ptr_kinds_eq_h node_ptr_kinds_eq_h3 ) apply(simp add: node_ptr_kinds_eq_h2 node_ptr_kinds_eq_h ) apply(auto simp add: children_eq2_h2[symmetric] children_eq2_h3[symmetric] disconnected_nodes_eq2_h disconnected_nodes_eq2_h2 disconnected_nodes_eq2_h3)[1] apply (metis (no_types, lifting) document_ptr_kinds_eq_h h' list.set_intros(1) local.set_disconnected_nodes_get_disconnected_nodes select_result_I2) apply(simp add: object_ptr_kinds_eq_h) by (smt ObjectMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>c\<^sub>h\<^sub>a\<^sub>r\<^sub>a\<^sub>c\<^sub>t\<^sub>e\<^sub>r\<^sub>_\<^sub>d\<^sub>a\<^sub>t\<^sub>a\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_character_data_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\ children_eq2_h disconnected_nodes_eq2_h3 document_ptr_kinds_eq_h finite_set_in h' list.set_intros(2) local.set_disconnected_nodes_get_disconnected_nodes select_result_I2) have "known_ptr (cast new_character_data_ptr)" using \h \ create_character_data document_ptr text \\<^sub>r new_character_data_ptr\ local.create_character_data_known_ptr by blast then have "known_ptrs h2" using known_ptrs_new_ptr object_ptr_kinds_eq_h \known_ptrs h\ h2 by blast then have "known_ptrs h3" using known_ptrs_preserved object_ptr_kinds_eq_h2 by blast then show "known_ptrs h'" using known_ptrs_preserved object_ptr_kinds_eq_h3 by blast show "heap_is_wellformed h'" using \a_acyclic_heap h'\ \a_all_ptrs_in_heap h'\ \a_distinct_lists h'\ \a_owner_document_valid h'\ by(simp add: heap_is_wellformed_def) qed end interpretation i_create_character_data_wf?: l_create_character_data_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel set_val set_val_locs set_disconnected_nodes set_disconnected_nodes_locs create_character_data known_ptrs using instances by (auto simp add: l_create_character_data_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) declare l_create_character_data_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] subsection \create\_document\ locale l_create_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M = l_heap_is_wellformed\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel + l_new_document_get_disconnected_nodes get_disconnected_nodes get_disconnected_nodes_locs + l_create_document\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M create_document + l_new_document_get_child_nodes type_wf known_ptr get_child_nodes get_child_nodes_locs + l_new_document type_wf + l_known_ptrs known_ptr known_ptrs for known_ptr :: "(_::linorder) object_ptr \ bool" and type_wf :: "(_) heap \ bool" and get_child_nodes :: "(_) object_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_child_nodes_locs :: "(_) object_ptr \ ((_) heap \ (_) heap \ bool) set" and get_disconnected_nodes :: "(_) document_ptr \ ((_) heap, exception, (_) node_ptr list) prog" and get_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap \ (_) heap \ bool) set" and heap_is_wellformed :: "(_) heap \ bool" and parent_child_rel :: "(_) heap \ ((_) object_ptr \ (_) object_ptr) set" and set_val :: "(_) character_data_ptr \ char list \ ((_) heap, exception, unit) prog" and set_val_locs :: "(_) character_data_ptr \ ((_) heap, exception, unit) prog set" and set_disconnected_nodes :: "(_) document_ptr \ (_) node_ptr list \ ((_) heap, exception, unit) prog" and set_disconnected_nodes_locs :: "(_) document_ptr \ ((_) heap, exception, unit) prog set" and create_document :: "((_) heap, exception, (_) document_ptr) prog" and known_ptrs :: "(_) heap \ bool" begin lemma create_document_preserves_wellformedness: assumes "heap_is_wellformed h" and "h \ create_document \\<^sub>h h'" and "type_wf h" and "known_ptrs h" shows "heap_is_wellformed h'" proof - obtain new_document_ptr where new_document_ptr: "h \ new_document \\<^sub>r new_document_ptr" and h': "h \ new_document \\<^sub>h h'" using assms(2) apply(simp add: create_document_def) using new_document_ok by blast have "new_document_ptr \ set |h \ document_ptr_kinds_M|\<^sub>r" using new_document_ptr DocumentMonad.ptr_kinds_ptr_kinds_M using new_document_ptr_not_in_heap h' by blast then have "cast new_document_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r" by simp have "new_document_ptr |\| document_ptr_kinds h" using new_document_ptr DocumentMonad.ptr_kinds_ptr_kinds_M using new_document_ptr_not_in_heap h' by blast then have "cast new_document_ptr |\| object_ptr_kinds h" by simp have object_ptr_kinds_eq: "object_ptr_kinds h' = object_ptr_kinds h |\| {|cast new_document_ptr|}" using new_document_new_ptr h' new_document_ptr by blast then have node_ptr_kinds_eq: "node_ptr_kinds h' = node_ptr_kinds h" apply(simp add: node_ptr_kinds_def) by force then have character_data_ptr_kinds_eq_h: "character_data_ptr_kinds h' = character_data_ptr_kinds h" by(simp add: character_data_ptr_kinds_def) have element_ptr_kinds_eq_h: "element_ptr_kinds h' = element_ptr_kinds h" using object_ptr_kinds_eq by(auto simp add: node_ptr_kinds_def element_ptr_kinds_def) have document_ptr_kinds_eq_h: "document_ptr_kinds h' = document_ptr_kinds h |\| {|new_document_ptr|}" using object_ptr_kinds_eq apply(auto simp add: document_ptr_kinds_def)[1] by (metis (no_types, lifting) document_ptr_kinds_commutes document_ptr_kinds_def finsertI1 fset.map_comp) have children_eq: "\(ptr'::(_) object_ptr) children. ptr' \ cast new_document_ptr \ h \ get_child_nodes ptr' \\<^sub>r children = h' \ get_child_nodes ptr' \\<^sub>r children" using get_child_nodes_reads h' get_child_nodes_new_document[rotated, OF new_document_ptr h'] apply(auto simp add: reads_def reflp_def transp_def preserved_def)[1] by blast+ then have children_eq2: "\ptr'. ptr' \ cast new_document_ptr \ |h \ get_child_nodes ptr'|\<^sub>r = |h' \ get_child_nodes ptr'|\<^sub>r" using select_result_eq by force have "h' \ get_child_nodes (cast new_document_ptr) \\<^sub>r []" using new_document_ptr h' new_document_ptr_in_heap[OF h' new_document_ptr] new_document_is_document_ptr[OF new_document_ptr] new_document_no_child_nodes by blast have disconnected_nodes_eq_h: "\doc_ptr disc_nodes. doc_ptr \ new_document_ptr \ h \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes = h' \ get_disconnected_nodes doc_ptr \\<^sub>r disc_nodes" using get_disconnected_nodes_reads h' get_disconnected_nodes_new_document_different_pointers new_document_ptr apply(auto simp add: reads_def reflp_def transp_def preserved_def)[1] by (metis(full_types) \\thesis. (\new_document_ptr. \h \ new_document \\<^sub>r new_document_ptr; h \ new_document \\<^sub>h h'\ \ thesis) \ thesis\ local.get_disconnected_nodes_new_document_different_pointers new_document_ptr)+ then have disconnected_nodes_eq2_h: "\doc_ptr. doc_ptr \ new_document_ptr \ |h \ get_disconnected_nodes doc_ptr|\<^sub>r = |h' \ get_disconnected_nodes doc_ptr|\<^sub>r" using select_result_eq by force have "h' \ get_disconnected_nodes new_document_ptr \\<^sub>r []" using h' local.new_document_no_disconnected_nodes new_document_ptr by blast have "type_wf h'" using \type_wf h\ new_document_types_preserved h' by blast have "acyclic (parent_child_rel h)" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def acyclic_heap_def) also have "parent_child_rel h = parent_child_rel h'" proof(auto simp add: parent_child_rel_def)[1] fix a x assume 0: "a |\| object_ptr_kinds h" and 1: "x \ set |h \ get_child_nodes a|\<^sub>r" then show "a |\| object_ptr_kinds h'" by (simp add: object_ptr_kinds_eq) next fix a x assume 0: "a |\| object_ptr_kinds h" and 1: "x \ set |h \ get_child_nodes a|\<^sub>r" then show "x \ set |h' \ get_child_nodes a|\<^sub>r" by (metis ObjectMonad.ptr_kinds_ptr_kinds_M \cast new_document_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\ children_eq2) next fix a x assume 0: "a |\| object_ptr_kinds h'" and 1: "x \ set |h' \ get_child_nodes a|\<^sub>r" then show "a |\| object_ptr_kinds h" using object_ptr_kinds_eq \h' \ get_child_nodes (cast new_document_ptr) \\<^sub>r []\ by(auto) next fix a x assume 0: "a |\| object_ptr_kinds h'" and 1: "x \ set |h' \ get_child_nodes a|\<^sub>r" then show "x \ set |h \ get_child_nodes a|\<^sub>r" by (metis (no_types, lifting) \h' \ get_child_nodes (cast new_document_ptr) \\<^sub>r []\ children_eq2 empty_iff empty_set image_eqI select_result_I2) qed finally have "a_acyclic_heap h'" by (simp add: acyclic_heap_def) have "a_all_ptrs_in_heap h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_all_ptrs_in_heap h'" apply(auto simp add: a_all_ptrs_in_heap_def)[1] using ObjectMonad.ptr_kinds_ptr_kinds_M \cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_document_ptr \ set |h \ object_ptr_kinds_M|\<^sub>r\ \parent_child_rel h = parent_child_rel h'\ assms(1) children_eq fset_of_list_elem local.heap_is_wellformed_children_in_heap local.parent_child_rel_child local.parent_child_rel_parent_in_heap node_ptr_kinds_eq apply (metis (no_types, lifting) \h' \ get_child_nodes (cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_document_ptr) \\<^sub>r []\ children_eq2 finite_set_in finsert_iff funion_finsert_right object_ptr_kinds_eq select_result_I2 subsetD sup_bot.right_neutral) by (metis (no_types, lifting) \cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_document_ptr |\| object_ptr_kinds h\ \h' \ get_child_nodes (cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_document_ptr) \\<^sub>r []\ \h' \ get_disconnected_nodes new_document_ptr \\<^sub>r []\ \parent_child_rel h = parent_child_rel h'\ \type_wf h'\ assms(1) disconnected_nodes_eq_h local.get_disconnected_nodes_ok local.heap_is_wellformed_disc_nodes_in_heap local.parent_child_rel_child local.parent_child_rel_parent_in_heap node_ptr_kinds_eq returns_result_select_result select_result_I2) have "a_distinct_lists h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_distinct_lists h'" using \h' \ get_disconnected_nodes new_document_ptr \\<^sub>r []\ \h' \ get_child_nodes (cast new_document_ptr) \\<^sub>r []\ apply(auto simp add: children_eq2[symmetric] a_distinct_lists_def insort_split object_ptr_kinds_eq document_ptr_kinds_eq_h disconnected_nodes_eq2_h intro!: distinct_concat_map_I)[1] apply (metis distinct_sorted_list_of_set finite_fset sorted_list_of_set_insert) apply(auto simp add: dest: distinct_concat_map_E)[1] apply(auto simp add: dest: distinct_concat_map_E)[1] using \new_document_ptr |\| document_ptr_kinds h\ apply(auto simp add: distinct_insort dest: distinct_concat_map_E)[1] using disconnected_nodes_eq_h apply (metis assms(1) assms(3) disconnected_nodes_eq2_h local.get_disconnected_nodes_ok local.heap_is_wellformed_disconnected_nodes_distinct returns_result_select_result) proof - fix x :: "(_) document_ptr" and y :: "(_) document_ptr" and xa :: "(_) node_ptr" assume a1: "x \ y" assume a2: "x |\| document_ptr_kinds h" assume a3: "x \ new_document_ptr" assume a4: "y |\| document_ptr_kinds h" assume a5: "y \ new_document_ptr" assume a6: "distinct (concat (map (\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h)))))" assume a7: "xa \ set |h' \ get_disconnected_nodes x|\<^sub>r" assume a8: "xa \ set |h' \ get_disconnected_nodes y|\<^sub>r" have f9: "xa \ set |h \ get_disconnected_nodes x|\<^sub>r" using a7 a3 disconnected_nodes_eq2_h by presburger have f10: "xa \ set |h \ get_disconnected_nodes y|\<^sub>r" using a8 a5 disconnected_nodes_eq2_h by presburger have f11: "y \ set (sorted_list_of_set (fset (document_ptr_kinds h)))" using a4 by simp have "x \ set (sorted_list_of_set (fset (document_ptr_kinds h)))" using a2 by simp then show False using f11 f10 f9 a6 a1 by (meson disjoint_iff_not_equal distinct_concat_map_E(1)) next fix x xa xb assume 0: "h' \ get_disconnected_nodes new_document_ptr \\<^sub>r []" and 1: "h' \ get_child_nodes (cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_document_ptr) \\<^sub>r []" and 2: "distinct (concat (map (\ptr. |h \ get_child_nodes ptr|\<^sub>r) (sorted_list_of_set (fset (object_ptr_kinds h)))))" and 3: "distinct (concat (map (\document_ptr. |h \ get_disconnected_nodes document_ptr|\<^sub>r) (sorted_list_of_set (fset (document_ptr_kinds h)))))" and 4: "(\x\fset (object_ptr_kinds h). set |h \ get_child_nodes x|\<^sub>r) \ (\x\fset (document_ptr_kinds h). set |h \ get_disconnected_nodes x|\<^sub>r) = {}" and 5: "x \ set |h \ get_child_nodes xa|\<^sub>r" and 6: "x \ set |h' \ get_disconnected_nodes xb|\<^sub>r" and 7: "xa |\| object_ptr_kinds h" and 8: "xa \ cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_document_ptr" and 9: "xb |\| document_ptr_kinds h" and 10: "xb \ new_document_ptr" then show "False" by (metis \local.a_distinct_lists h\ assms(3) disconnected_nodes_eq2_h local.distinct_lists_no_parent local.get_disconnected_nodes_ok returns_result_select_result) qed have "a_owner_document_valid h" using \heap_is_wellformed h\ by (simp add: heap_is_wellformed_def) then have "a_owner_document_valid h'" apply(auto simp add: a_owner_document_valid_def)[1] by (metis \cast\<^sub>d\<^sub>o\<^sub>c\<^sub>u\<^sub>m\<^sub>e\<^sub>n\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r\<^sub>2\<^sub>o\<^sub>b\<^sub>j\<^sub>e\<^sub>c\<^sub>t\<^sub>_\<^sub>p\<^sub>t\<^sub>r new_document_ptr |\| object_ptr_kinds h\ children_eq2 disconnected_nodes_eq2_h document_ptr_kinds_commutes finite_set_in funion_iff node_ptr_kinds_eq object_ptr_kinds_eq) show "heap_is_wellformed h'" using \a_acyclic_heap h'\ \a_all_ptrs_in_heap h'\ \a_distinct_lists h'\ \a_owner_document_valid h'\ by(simp add: heap_is_wellformed_def) qed end interpretation i_create_document_wf?: l_create_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M known_ptr type_wf get_child_nodes get_child_nodes_locs get_disconnected_nodes get_disconnected_nodes_locs heap_is_wellformed parent_child_rel set_val set_val_locs set_disconnected_nodes set_disconnected_nodes_locs create_document known_ptrs using instances by (auto simp add: l_create_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_def) declare l_create_document_wf\<^sub>C\<^sub>o\<^sub>r\<^sub>e\<^sub>_\<^sub>D\<^sub>O\<^sub>M_axioms [instances] end