Theory List_Ins_Del

(* Author: Tobias Nipkow *)

section ‹List Insertion and Deletion›

theory List_Ins_Del
imports Sorted_Less
begin

subsection ‹Elements in a list›

lemma sorted_Cons_iff:
  "sorted(x # xs) = ((y  set xs. x < y)  sorted xs)"
by(simp add: sorted_wrt_Cons)

lemma sorted_snoc_iff:
  "sorted(xs @ [x]) = (sorted xs  (y  set xs. y < x))"
by(simp add: sorted_wrt_append)
(*
text‹The above two rules introduce quantifiers. It turns out
that in practice this is not a problem because of the simplicity of
the "isin" functions that implement @{const set}. Nevertheless
it is possible to avoid the quantifiers with the help of some rewrite rules:›

lemma sorted_ConsD: "sorted (y # xs) ⟹ x ≤ y ⟹ x ∉ set xs"
by (auto simp: sorted_Cons_iff)

lemma sorted_snocD: "sorted (xs @ [y]) ⟹ y ≤ x ⟹ x ∉ set xs"
by (auto simp: sorted_snoc_iff)

lemmas isin_simps2 = sorted_lems sorted_ConsD sorted_snocD
*)

lemmas isin_simps = sorted_mid_iff' sorted_Cons_iff sorted_snoc_iff


subsection ‹Inserting into an ordered list without duplicates:›

fun ins_list :: "'a::linorder  'a list  'a list" where
"ins_list x [] = [x]" |
"ins_list x (a#xs) =
  (if x < a then x#a#xs else if x=a then a#xs else a # ins_list x xs)"

lemma set_ins_list: "set (ins_list x xs) = set xs  {x}"
by(induction xs) auto

lemma sorted_ins_list: "sorted xs  sorted(ins_list x xs)"
by(induction xs rule: induct_list012) auto

lemma ins_list_sorted: "sorted (xs @ [a]) 
  ins_list x (xs @ a # ys) =
  (if x < a then ins_list x xs @ (a#ys) else xs @ ins_list x (a#ys))"
by(induction xs) (auto simp: sorted_lems)

text‹In principle, @{thm ins_list_sorted} suffices, but the following two
corollaries speed up proofs.›

corollary ins_list_sorted1: "sorted (xs @ [a])  a  x 
  ins_list x (xs @ a # ys) = xs @ ins_list x (a#ys)"
by(auto simp add: ins_list_sorted)

corollary ins_list_sorted2: "sorted (xs @ [a])  x < a 
  ins_list x (xs @ a # ys) = ins_list x xs @ (a#ys)"
by(auto simp: ins_list_sorted)

lemmas ins_list_simps = sorted_lems ins_list_sorted1 ins_list_sorted2

text‹Splay trees need two additional constins_list lemmas:›

lemma ins_list_Cons: "sorted (x # xs)  ins_list x xs = x # xs"
by (induction xs) auto

lemma ins_list_snoc: "sorted (xs @ [x])  ins_list x xs = xs @ [x]"
by(induction xs) (auto simp add: sorted_mid_iff2)


subsection ‹Delete one occurrence of an element from a list:›

fun del_list :: "'a  'a list  'a list" where
"del_list x [] = []" |
"del_list x (a#xs) = (if x=a then xs else a # del_list x xs)"

lemma del_list_idem: "x  set xs  del_list x xs = xs"
by (induct xs) simp_all

lemma set_del_list:
  "sorted xs  set (del_list x xs) = set xs - {x}"
by(induct xs) (auto simp: sorted_Cons_iff)

lemma sorted_del_list: "sorted xs  sorted(del_list x xs)"
apply(induction xs rule: induct_list012)
apply auto
by (meson order.strict_trans sorted_Cons_iff)

lemma del_list_sorted: "sorted (xs @ a # ys) 
  del_list x (xs @ a # ys) = (if x < a then del_list x xs @ a # ys else xs @ del_list x (a # ys))"
by(induction xs)
  (fastforce simp: sorted_lems sorted_Cons_iff intro!: del_list_idem)+

text‹In principle, @{thm del_list_sorted} suffices, but the following
corollaries speed up proofs.›

corollary del_list_sorted1: "sorted (xs @ a # ys)  a  x 
  del_list x (xs @ a # ys) = xs @ del_list x (a # ys)"
by (auto simp: del_list_sorted)

corollary del_list_sorted2: "sorted (xs @ a # ys)  x < a 
  del_list x (xs @ a # ys) = del_list x xs @ a # ys"
by (auto simp: del_list_sorted)

corollary del_list_sorted3:
  "sorted (xs @ a # ys @ b # zs)  x < b 
  del_list x (xs @ a # ys @ b # zs) = del_list x (xs @ a # ys) @ b # zs"
by (auto simp: del_list_sorted sorted_lems)

corollary del_list_sorted4:
  "sorted (xs @ a # ys @ b # zs @ c # us)  x < c 
  del_list x (xs @ a # ys @ b # zs @ c # us) = del_list x (xs @ a # ys @ b # zs) @ c # us"
by (auto simp: del_list_sorted sorted_lems)

corollary del_list_sorted5:
  "sorted (xs @ a # ys @ b # zs @ c # us @ d # vs)  x < d 
   del_list x (xs @ a # ys @ b # zs @ c # us @ d # vs) =
   del_list x (xs @ a # ys @ b # zs @ c # us) @ d # vs" 
by (auto simp: del_list_sorted sorted_lems)

lemmas del_list_simps = sorted_lems
  del_list_sorted1
  del_list_sorted2
  del_list_sorted3
  del_list_sorted4
  del_list_sorted5

text‹Splay trees need two additional constdel_list lemmas:›

lemma del_list_notin_Cons: "sorted (x # xs)  del_list x xs = xs"
by(induction xs)(fastforce simp: sorted_Cons_iff)+

lemma del_list_sorted_app:
  "sorted(xs @ [x])  del_list x (xs @ ys) = xs @ del_list x ys"
by (induction xs) (auto simp: sorted_mid_iff2)

end