Theory Multiset

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theory Multiset
imports Main
begin

(*  Title:      HOL/Library/Multiset.thy
    ID:         $Id: Multiset.thy,v 1.53 2007/10/26 19:22:19 haftmann Exp $
    Author:     Tobias Nipkow, Markus Wenzel, Lawrence C Paulson, Norbert Voelker
*)

header {* Multisets *}

theory Multiset
imports Main
begin

subsection {* The type of multisets *}

typedef 'a multiset = "{f::'a => nat. finite {x . f x > 0}}"
proof
  show "(λx. 0::nat) ∈ ?multiset" by simp
qed

lemmas multiset_typedef [simp] =
    Abs_multiset_inverse Rep_multiset_inverse Rep_multiset
  and [simp] = Rep_multiset_inject [symmetric]

definition
  Mempty :: "'a multiset"  ("{#}") where
  "{#} = Abs_multiset (λa. 0)"

definition
  single :: "'a => 'a multiset"  ("{#_#}") where
  "{#a#} = Abs_multiset (λb. if b = a then 1 else 0)"

definition
  count :: "'a multiset => 'a => nat" where
  "count = Rep_multiset"

definition
  MCollect :: "'a multiset => ('a => bool) => 'a multiset" where
  "MCollect M P = Abs_multiset (λx. if P x then Rep_multiset M x else 0)"

abbreviation
  Melem :: "'a => 'a multiset => bool"  ("(_/ :# _)" [50, 51] 50) where
  "a :# M == count M a > 0"

syntax
  "_MCollect" :: "pttrn => 'a multiset => bool => 'a multiset"    ("(1{# _ : _./ _#})")
translations
  "{#x:M. P#}" == "CONST MCollect M (λx. P)"

definition
  set_of :: "'a multiset => 'a set" where
  "set_of M = {x. x :# M}"

instance multiset :: (type) "{plus, minus, zero, size}" 
  union_def: "M + N == Abs_multiset (λa. Rep_multiset M a + Rep_multiset N a)"
  diff_def: "M - N == Abs_multiset (λa. Rep_multiset M a - Rep_multiset N a)"
  Zero_multiset_def [simp]: "0 == {#}"
  size_def: "size M == setsum (count M) (set_of M)" ..

definition
  multiset_inter :: "'a multiset => 'a multiset => 'a multiset"  (infixl "#∩" 70) where
  "multiset_inter A B = A - (A - B)"


text {*
 \medskip Preservation of the representing set @{term multiset}.
*}

lemma const0_in_multiset [simp]: "(λa. 0) ∈ multiset"
  by (simp add: multiset_def)

lemma only1_in_multiset [simp]: "(λb. if b = a then 1 else 0) ∈ multiset"
  by (simp add: multiset_def)

lemma union_preserves_multiset [simp]:
    "M ∈ multiset ==> N ∈ multiset ==> (λa. M a + N a) ∈ multiset"
  apply (simp add: multiset_def)
  apply (drule (1) finite_UnI)
  apply (simp del: finite_Un add: Un_def)
  done

lemma diff_preserves_multiset [simp]:
    "M ∈ multiset ==> (λa. M a - N a) ∈ multiset"
  apply (simp add: multiset_def)
  apply (rule finite_subset)
   apply auto
  done


subsection {* Algebraic properties of multisets *}

subsubsection {* Union *}

lemma union_empty [simp]: "M + {#} = M ∧ {#} + M = M"
  by (simp add: union_def Mempty_def)

lemma union_commute: "M + N = N + (M::'a multiset)"
  by (simp add: union_def add_ac)

lemma union_assoc: "(M + N) + K = M + (N + (K::'a multiset))"
  by (simp add: union_def add_ac)

lemma union_lcomm: "M + (N + K) = N + (M + (K::'a multiset))"
proof -
  have "M + (N + K) = (N + K) + M"
    by (rule union_commute)
  also have "… = N + (K + M)"
    by (rule union_assoc)
  also have "K + M = M + K"
    by (rule union_commute)
  finally show ?thesis .
qed

lemmas union_ac = union_assoc union_commute union_lcomm

instance multiset :: (type) comm_monoid_add
proof
  fix a b c :: "'a multiset"
  show "(a + b) + c = a + (b + c)" by (rule union_assoc)
  show "a + b = b + a" by (rule union_commute)
  show "0 + a = a" by simp
qed


subsubsection {* Difference *}

lemma diff_empty [simp]: "M - {#} = M ∧ {#} - M = {#}"
  by (simp add: Mempty_def diff_def)

lemma diff_union_inverse2 [simp]: "M + {#a#} - {#a#} = M"
  by (simp add: union_def diff_def)


subsubsection {* Count of elements *}

lemma count_empty [simp]: "count {#} a = 0"
  by (simp add: count_def Mempty_def)

lemma count_single [simp]: "count {#b#} a = (if b = a then 1 else 0)"
  by (simp add: count_def single_def)

lemma count_union [simp]: "count (M + N) a = count M a + count N a"
  by (simp add: count_def union_def)

lemma count_diff [simp]: "count (M - N) a = count M a - count N a"
  by (simp add: count_def diff_def)


subsubsection {* Set of elements *}

lemma set_of_empty [simp]: "set_of {#} = {}"
  by (simp add: set_of_def)

lemma set_of_single [simp]: "set_of {#b#} = {b}"
  by (simp add: set_of_def)

lemma set_of_union [simp]: "set_of (M + N) = set_of M ∪ set_of N"
  by (auto simp add: set_of_def)

lemma set_of_eq_empty_iff [simp]: "(set_of M = {}) = (M = {#})"
  by (auto simp add: set_of_def Mempty_def count_def expand_fun_eq)

lemma mem_set_of_iff [simp]: "(x ∈ set_of M) = (x :# M)"
  by (auto simp add: set_of_def)


subsubsection {* Size *}

lemma size_empty [simp]: "size {#} = 0"
  by (simp add: size_def)

lemma size_single [simp]: "size {#b#} = 1"
  by (simp add: size_def)

lemma finite_set_of [iff]: "finite (set_of M)"
  using Rep_multiset [of M]
  by (simp add: multiset_def set_of_def count_def)

lemma setsum_count_Int:
    "finite A ==> setsum (count N) (A ∩ set_of N) = setsum (count N) A"
  apply (induct rule: finite_induct)
   apply simp
  apply (simp add: Int_insert_left set_of_def)
  done

lemma size_union [simp]: "size (M + N::'a multiset) = size M + size N"
  apply (unfold size_def)
  apply (subgoal_tac "count (M + N) = (λa. count M a + count N a)")
   prefer 2
   apply (rule ext, simp)
  apply (simp (no_asm_simp) add: setsum_Un_nat setsum_addf setsum_count_Int)
  apply (subst Int_commute)
  apply (simp (no_asm_simp) add: setsum_count_Int)
  done

lemma size_eq_0_iff_empty [iff]: "(size M = 0) = (M = {#})"
  apply (unfold size_def Mempty_def count_def, auto)
  apply (simp add: set_of_def count_def expand_fun_eq)
  done

lemma size_eq_Suc_imp_elem: "size M = Suc n ==> ∃a. a :# M"
  apply (unfold size_def)
  apply (drule setsum_SucD, auto)
  done


subsubsection {* Equality of multisets *}

lemma multiset_eq_conv_count_eq: "(M = N) = (∀a. count M a = count N a)"
  by (simp add: count_def expand_fun_eq)

lemma single_not_empty [simp]: "{#a#} ≠ {#} ∧ {#} ≠ {#a#}"
  by (simp add: single_def Mempty_def expand_fun_eq)

lemma single_eq_single [simp]: "({#a#} = {#b#}) = (a = b)"
  by (auto simp add: single_def expand_fun_eq)

lemma union_eq_empty [iff]: "(M + N = {#}) = (M = {#} ∧ N = {#})"
  by (auto simp add: union_def Mempty_def expand_fun_eq)

lemma empty_eq_union [iff]: "({#} = M + N) = (M = {#} ∧ N = {#})"
  by (auto simp add: union_def Mempty_def expand_fun_eq)

lemma union_right_cancel [simp]: "(M + K = N + K) = (M = (N::'a multiset))"
  by (simp add: union_def expand_fun_eq)

lemma union_left_cancel [simp]: "(K + M = K + N) = (M = (N::'a multiset))"
  by (simp add: union_def expand_fun_eq)

lemma union_is_single:
    "(M + N = {#a#}) = (M = {#a#} ∧ N={#} ∨ M = {#} ∧ N = {#a#})"
  apply (simp add: Mempty_def single_def union_def add_is_1 expand_fun_eq)
  apply blast
  done

lemma single_is_union:
     "({#a#} = M + N) = ({#a#} = M ∧ N = {#} ∨ M = {#} ∧ {#a#} = N)"
  apply (unfold Mempty_def single_def union_def)
  apply (simp add: add_is_1 one_is_add expand_fun_eq)
  apply (blast dest: sym)
  done

lemma add_eq_conv_diff:
  "(M + {#a#} = N + {#b#}) =
   (M = N ∧ a = b ∨ M = N - {#a#} + {#b#} ∧ N = M - {#b#} + {#a#})"
  using [[simproc del: neq]]
  apply (unfold single_def union_def diff_def)
  apply (simp (no_asm) add: expand_fun_eq)
  apply (rule conjI, force, safe, simp_all)
  apply (simp add: eq_sym_conv)
  done

declare Rep_multiset_inject [symmetric, simp del]

instance multiset :: (type) cancel_ab_semigroup_add
proof
  fix a b c :: "'a multiset"
  show "a + b = a + c ==> b = c" by simp
qed

subsubsection {* Intersection *}

lemma multiset_inter_count:
    "count (A #∩ B) x = min (count A x) (count B x)"
  by (simp add: multiset_inter_def min_def)

lemma multiset_inter_commute: "A #∩ B = B #∩ A"
  by (simp add: multiset_eq_conv_count_eq multiset_inter_count
    min_max.inf_commute)

lemma multiset_inter_assoc: "A #∩ (B #∩ C) = A #∩ B #∩ C"
  by (simp add: multiset_eq_conv_count_eq multiset_inter_count
    min_max.inf_assoc)

lemma multiset_inter_left_commute: "A #∩ (B #∩ C) = B #∩ (A #∩ C)"
  by (simp add: multiset_eq_conv_count_eq multiset_inter_count min_def)

lemmas multiset_inter_ac =
  multiset_inter_commute
  multiset_inter_assoc
  multiset_inter_left_commute

lemma multiset_union_diff_commute: "B #∩ C = {#} ==> A + B - C = A - C + B"
  apply (simp add: multiset_eq_conv_count_eq multiset_inter_count min_def
    split: split_if_asm)
  apply clarsimp
  apply (erule_tac x = a in allE)
  apply auto
  done


subsection {* Induction over multisets *}

lemma setsum_decr:
  "finite F ==> (0::nat) < f a ==>
    setsum (f (a := f a - 1)) F = (if a∈F then setsum f F - 1 else setsum f F)"
  apply (induct rule: finite_induct)
   apply auto
  apply (drule_tac a = a in mk_disjoint_insert, auto)
  done

lemma rep_multiset_induct_aux:
  assumes 1: "P (λa. (0::nat))"
    and 2: "!!f b. f ∈ multiset ==> P f ==> P (f (b := f b + 1))"
  shows "∀f. f ∈ multiset --> setsum f {x. f x ≠ 0} = n --> P f"
  apply (unfold multiset_def)
  apply (induct_tac n, simp, clarify)
   apply (subgoal_tac "f = (λa.0)")
    apply simp
    apply (rule 1)
   apply (rule ext, force, clarify)
  apply (frule setsum_SucD, clarify)
  apply (rename_tac a)
  apply (subgoal_tac "finite {x. (f (a := f a - 1)) x > 0}")
   prefer 2
   apply (rule finite_subset)
    prefer 2
    apply assumption
   apply simp
   apply blast
  apply (subgoal_tac "f = (f (a := f a - 1))(a := (f (a := f a - 1)) a + 1)")
   prefer 2
   apply (rule ext)
   apply (simp (no_asm_simp))
   apply (erule ssubst, rule 2 [unfolded multiset_def], blast)
  apply (erule allE, erule impE, erule_tac [2] mp, blast)
  apply (simp (no_asm_simp) add: setsum_decr del: fun_upd_apply One_nat_def)
  apply (subgoal_tac "{x. x ≠ a --> f x ≠ 0} = {x. f x ≠ 0}")
   prefer 2
   apply blast
  apply (subgoal_tac "{x. x ≠ a ∧ f x ≠ 0} = {x. f x ≠ 0} - {a}")
   prefer 2
   apply blast
  apply (simp add: le_imp_diff_is_add setsum_diff1_nat cong: conj_cong)
  done

theorem rep_multiset_induct:
  "f ∈ multiset ==> P (λa. 0) ==>
    (!!f b. f ∈ multiset ==> P f ==> P (f (b := f b + 1))) ==> P f"
  using rep_multiset_induct_aux by blast

theorem multiset_induct [case_names empty add, induct type: multiset]:
  assumes empty: "P {#}"
    and add: "!!M x. P M ==> P (M + {#x#})"
  shows "P M"
proof -
  note defns = union_def single_def Mempty_def
  show ?thesis
    apply (rule Rep_multiset_inverse [THEN subst])
    apply (rule Rep_multiset [THEN rep_multiset_induct])
     apply (rule empty [unfolded defns])
    apply (subgoal_tac "f(b := f b + 1) = (λa. f a + (if a=b then 1 else 0))")
     prefer 2
     apply (simp add: expand_fun_eq)
    apply (erule ssubst)
    apply (erule Abs_multiset_inverse [THEN subst])
    apply (erule add [unfolded defns, simplified])
    done
qed

lemma MCollect_preserves_multiset:
    "M ∈ multiset ==> (λx. if P x then M x else 0) ∈ multiset"
  apply (simp add: multiset_def)
  apply (rule finite_subset, auto)
  done

lemma count_MCollect [simp]:
    "count {# x:M. P x #} a = (if P a then count M a else 0)"
  by (simp add: count_def MCollect_def MCollect_preserves_multiset)

lemma set_of_MCollect [simp]: "set_of {# x:M. P x #} = set_of M ∩ {x. P x}"
  by (auto simp add: set_of_def)

lemma multiset_partition: "M = {# x:M. P x #} + {# x:M. ¬ P x #}"
  by (subst multiset_eq_conv_count_eq, auto)

lemma add_eq_conv_ex:
  "(M + {#a#} = N + {#b#}) =
    (M = N ∧ a = b ∨ (∃K. M = K + {#b#} ∧ N = K + {#a#}))"
  by (auto simp add: add_eq_conv_diff)

declare multiset_typedef [simp del]


subsection {* Multiset orderings *}

subsubsection {* Well-foundedness *}

definition
  mult1 :: "('a × 'a) set => ('a multiset × 'a multiset) set" where
  "mult1 r =
    {(N, M). ∃a M0 K. M = M0 + {#a#} ∧ N = M0 + K ∧
      (∀b. b :# K --> (b, a) ∈ r)}"

definition
  mult :: "('a × 'a) set => ('a multiset × 'a multiset) set" where
  "mult r = (mult1 r)+"

lemma not_less_empty [iff]: "(M, {#}) ∉ mult1 r"
  by (simp add: mult1_def)

lemma less_add: "(N, M0 + {#a#}) ∈ mult1 r ==>
    (∃M. (M, M0) ∈ mult1 r ∧ N = M + {#a#}) ∨
    (∃K. (∀b. b :# K --> (b, a) ∈ r) ∧ N = M0 + K)"
  (is "_ ==> ?case1 (mult1 r) ∨ ?case2")
proof (unfold mult1_def)
  let ?r = "λK a. ∀b. b :# K --> (b, a) ∈ r"
  let ?R = "λN M. ∃a M0 K. M = M0 + {#a#} ∧ N = M0 + K ∧ ?r K a"
  let ?case1 = "?case1 {(N, M). ?R N M}"

  assume "(N, M0 + {#a#}) ∈ {(N, M). ?R N M}"
  then have "∃a' M0' K.
      M0 + {#a#} = M0' + {#a'#} ∧ N = M0' + K ∧ ?r K a'" by simp
  then show "?case1 ∨ ?case2"
  proof (elim exE conjE)
    fix a' M0' K
    assume N: "N = M0' + K" and r: "?r K a'"
    assume "M0 + {#a#} = M0' + {#a'#}"
    then have "M0 = M0' ∧ a = a' ∨
        (∃K'. M0 = K' + {#a'#} ∧ M0' = K' + {#a#})"
      by (simp only: add_eq_conv_ex)
    then show ?thesis
    proof (elim disjE conjE exE)
      assume "M0 = M0'" "a = a'"
      with N r have "?r K a ∧ N = M0 + K" by simp
      then have ?case2 .. then show ?thesis ..
    next
      fix K'
      assume "M0' = K' + {#a#}"
      with N have n: "N = K' + K + {#a#}" by (simp add: union_ac)

      assume "M0 = K' + {#a'#}"
      with r have "?R (K' + K) M0" by blast
      with n have ?case1 by simp then show ?thesis ..
    qed
  qed
qed

lemma all_accessible: "wf r ==> ∀M. M ∈ acc (mult1 r)"
proof
  let ?R = "mult1 r"
  let ?W = "acc ?R"
  {
    fix M M0 a
    assume M0: "M0 ∈ ?W"
      and wf_hyp: "!!b. (b, a) ∈ r ==> (∀M ∈ ?W. M + {#b#} ∈ ?W)"
      and acc_hyp: "∀M. (M, M0) ∈ ?R --> M + {#a#} ∈ ?W"
    have "M0 + {#a#} ∈ ?W"
    proof (rule accI [of "M0 + {#a#}"])
      fix N
      assume "(N, M0 + {#a#}) ∈ ?R"
      then have "((∃M. (M, M0) ∈ ?R ∧ N = M + {#a#}) ∨
          (∃K. (∀b. b :# K --> (b, a) ∈ r) ∧ N = M0 + K))"
        by (rule less_add)
      then show "N ∈ ?W"
      proof (elim exE disjE conjE)
        fix M assume "(M, M0) ∈ ?R" and N: "N = M + {#a#}"
        from acc_hyp have "(M, M0) ∈ ?R --> M + {#a#} ∈ ?W" ..
        from this and `(M, M0) ∈ ?R` have "M + {#a#} ∈ ?W" ..
        then show "N ∈ ?W" by (simp only: N)
      next
        fix K
        assume N: "N = M0 + K"
        assume "∀b. b :# K --> (b, a) ∈ r"
        then have "M0 + K ∈ ?W"
        proof (induct K)
          case empty
          from M0 show "M0 + {#} ∈ ?W" by simp
        next
          case (add K x)
          from add.prems have "(x, a) ∈ r" by simp
          with wf_hyp have "∀M ∈ ?W. M + {#x#} ∈ ?W" by blast
          moreover from add have "M0 + K ∈ ?W" by simp
          ultimately have "(M0 + K) + {#x#} ∈ ?W" ..
          then show "M0 + (K + {#x#}) ∈ ?W" by (simp only: union_assoc)
        qed
        then show "N ∈ ?W" by (simp only: N)
      qed
    qed
  } note tedious_reasoning = this

  assume wf: "wf r"
  fix M
  show "M ∈ ?W"
  proof (induct M)
    show "{#} ∈ ?W"
    proof (rule accI)
      fix b assume "(b, {#}) ∈ ?R"
      with not_less_empty show "b ∈ ?W" by contradiction
    qed

    fix M a assume "M ∈ ?W"
    from wf have "∀M ∈ ?W. M + {#a#} ∈ ?W"
    proof induct
      fix a
      assume r: "!!b. (b, a) ∈ r ==> (∀M ∈ ?W. M + {#b#} ∈ ?W)"
      show "∀M ∈ ?W. M + {#a#} ∈ ?W"
      proof
        fix M assume "M ∈ ?W"
        then show "M + {#a#} ∈ ?W"
          by (rule acc_induct) (rule tedious_reasoning [OF _ r])
      qed
    qed
    from this and `M ∈ ?W` show "M + {#a#} ∈ ?W" ..
  qed
qed

theorem wf_mult1: "wf r ==> wf (mult1 r)"
  by (rule acc_wfI) (rule all_accessible)

theorem wf_mult: "wf r ==> wf (mult r)"
  unfolding mult_def by (rule wf_trancl) (rule wf_mult1)


subsubsection {* Closure-free presentation *}

(*Badly needed: a linear arithmetic procedure for multisets*)

lemma diff_union_single_conv: "a :# J ==> I + J - {#a#} = I + (J - {#a#})"
  by (simp add: multiset_eq_conv_count_eq)

text {* One direction. *}

lemma mult_implies_one_step:
  "trans r ==> (M, N) ∈ mult r ==>
    ∃I J K. N = I + J ∧ M = I + K ∧ J ≠ {#} ∧
    (∀k ∈ set_of K. ∃j ∈ set_of J. (k, j) ∈ r)"
  apply (unfold mult_def mult1_def set_of_def)
  apply (erule converse_trancl_induct, clarify)
   apply (rule_tac x = M0 in exI, simp, clarify)
  apply (case_tac "a :# K")
   apply (rule_tac x = I in exI)
   apply (simp (no_asm))
   apply (rule_tac x = "(K - {#a#}) + Ka" in exI)
   apply (simp (no_asm_simp) add: union_assoc [symmetric])
   apply (drule_tac f = "λM. M - {#a#}" in arg_cong)
   apply (simp add: diff_union_single_conv)
   apply (simp (no_asm_use) add: trans_def)
   apply blast
  apply (subgoal_tac "a :# I")
   apply (rule_tac x = "I - {#a#}" in exI)
   apply (rule_tac x = "J + {#a#}" in exI)
   apply (rule_tac x = "K + Ka" in exI)
   apply (rule conjI)
    apply (simp add: multiset_eq_conv_count_eq split: nat_diff_split)
   apply (rule conjI)
    apply (drule_tac f = "λM. M - {#a#}" in arg_cong, simp)
    apply (simp add: multiset_eq_conv_count_eq split: nat_diff_split)
   apply (simp (no_asm_use) add: trans_def)
   apply blast
  apply (subgoal_tac "a :# (M0 + {#a#})")
   apply simp
  apply (simp (no_asm))
  done

lemma elem_imp_eq_diff_union: "a :# M ==> M = M - {#a#} + {#a#}"
  by (simp add: multiset_eq_conv_count_eq)

lemma size_eq_Suc_imp_eq_union: "size M = Suc n ==> ∃a N. M = N + {#a#}"
  apply (erule size_eq_Suc_imp_elem [THEN exE])
  apply (drule elem_imp_eq_diff_union, auto)
  done

lemma one_step_implies_mult_aux:
  "trans r ==>
    ∀I J K. (size J = n ∧ J ≠ {#} ∧ (∀k ∈ set_of K. ∃j ∈ set_of J. (k, j) ∈ r))
      --> (I + K, I + J) ∈ mult r"
  apply (induct_tac n, auto)
  apply (frule size_eq_Suc_imp_eq_union, clarify)
  apply (rename_tac "J'", simp)
  apply (erule notE, auto)
  apply (case_tac "J' = {#}")
   apply (simp add: mult_def)
   apply (rule r_into_trancl)
   apply (simp add: mult1_def set_of_def, blast)
  txt {* Now we know @{term "J' ≠ {#}"}. *}
  apply (cut_tac M = K and P = "λx. (x, a) ∈ r" in multiset_partition)
  apply (erule_tac P = "∀k ∈ set_of K. ?P k" in rev_mp)
  apply (erule ssubst)
  apply (simp add: Ball_def, auto)
  apply (subgoal_tac
    "((I + {# x : K. (x, a) ∈ r #}) + {# x : K. (x, a) ∉ r #},
      (I + {# x : K. (x, a) ∈ r #}) + J') ∈ mult r")
   prefer 2
   apply force
  apply (simp (no_asm_use) add: union_assoc [symmetric] mult_def)
  apply (erule trancl_trans)
  apply (rule r_into_trancl)
  apply (simp add: mult1_def set_of_def)
  apply (rule_tac x = a in exI)
  apply (rule_tac x = "I + J'" in exI)
  apply (simp add: union_ac)
  done

lemma one_step_implies_mult:
  "trans r ==> J ≠ {#} ==> ∀k ∈ set_of K. ∃j ∈ set_of J. (k, j) ∈ r
    ==> (I + K, I + J) ∈ mult r"
  using one_step_implies_mult_aux by blast


subsubsection {* Partial-order properties *}

instance multiset :: (type) ord ..

defs (overloaded)
  less_multiset_def: "M' < M == (M', M) ∈ mult {(x', x). x' < x}"
  le_multiset_def: "M' <= M == M' = M ∨ M' < (M::'a multiset)"

lemma trans_base_order: "trans {(x', x). x' < (x::'a::order)}"
  unfolding trans_def by (blast intro: order_less_trans)

text {*
 \medskip Irreflexivity.
*}

lemma mult_irrefl_aux:
    "finite A ==> (∀x ∈ A. ∃y ∈ A. x < (y::'a::order)) ==> A = {}"
  by (induct rule: finite_induct) (auto intro: order_less_trans)

lemma mult_less_not_refl: "¬ M < (M::'a::order multiset)"
  apply (unfold less_multiset_def, auto)
  apply (drule trans_base_order [THEN mult_implies_one_step], auto)
  apply (drule finite_set_of [THEN mult_irrefl_aux [rule_format (no_asm)]])
  apply (simp add: set_of_eq_empty_iff)
  done

lemma mult_less_irrefl [elim!]: "M < (M::'a::order multiset) ==> R"
  using insert mult_less_not_refl by fast


text {* Transitivity. *}

theorem mult_less_trans: "K < M ==> M < N ==> K < (N::'a::order multiset)"
  unfolding less_multiset_def mult_def by (blast intro: trancl_trans)

text {* Asymmetry. *}

theorem mult_less_not_sym: "M < N ==> ¬ N < (M::'a::order multiset)"
  apply auto
  apply (rule mult_less_not_refl [THEN notE])
  apply (erule mult_less_trans, assumption)
  done

theorem mult_less_asym:
    "M < N ==> (¬ P ==> N < (M::'a::order multiset)) ==> P"
  by (insert mult_less_not_sym, blast)

theorem mult_le_refl [iff]: "M <= (M::'a::order multiset)"
  unfolding le_multiset_def by auto

text {* Anti-symmetry. *}

theorem mult_le_antisym:
    "M <= N ==> N <= M ==> M = (N::'a::order multiset)"
  unfolding le_multiset_def by (blast dest: mult_less_not_sym)

text {* Transitivity. *}

theorem mult_le_trans:
    "K <= M ==> M <= N ==> K <= (N::'a::order multiset)"
  unfolding le_multiset_def by (blast intro: mult_less_trans)

theorem mult_less_le: "(M < N) = (M <= N ∧ M ≠ (N::'a::order multiset))"
  unfolding le_multiset_def by auto

text {* Partial order. *}

instance multiset :: (order) order
  apply intro_classes
  apply (rule mult_less_le)
  apply (rule mult_le_refl)
  apply (erule mult_le_trans, assumption)
  apply (erule mult_le_antisym, assumption)
  done


subsubsection {* Monotonicity of multiset union *}

lemma mult1_union:
    "(B, D) ∈ mult1 r ==> trans r ==> (C + B, C + D) ∈ mult1 r"
  apply (unfold mult1_def, auto)
  apply (rule_tac x = a in exI)
  apply (rule_tac x = "C + M0" in exI)
  apply (simp add: union_assoc)
  done

lemma union_less_mono2: "B < D ==> C + B < C + (D::'a::order multiset)"
  apply (unfold less_multiset_def mult_def)
  apply (erule trancl_induct)
   apply (blast intro: mult1_union transI order_less_trans r_into_trancl)
  apply (blast intro: mult1_union transI order_less_trans r_into_trancl trancl_trans)
  done

lemma union_less_mono1: "B < D ==> B + C < D + (C::'a::order multiset)"
  apply (subst union_commute [of B C])
  apply (subst union_commute [of D C])
  apply (erule union_less_mono2)
  done

lemma union_less_mono:
    "A < C ==> B < D ==> A + B < C + (D::'a::order multiset)"
  apply (blast intro!: union_less_mono1 union_less_mono2 mult_less_trans)
  done

lemma union_le_mono:
    "A <= C ==> B <= D ==> A + B <= C + (D::'a::order multiset)"
  unfolding le_multiset_def
  by (blast intro: union_less_mono union_less_mono1 union_less_mono2)

lemma empty_leI [iff]: "{#} <= (M::'a::order multiset)"
  apply (unfold le_multiset_def less_multiset_def)
  apply (case_tac "M = {#}")
   prefer 2
   apply (subgoal_tac "({#} + {#}, {#} + M) ∈ mult (Collect (split op <))")
    prefer 2
    apply (rule one_step_implies_mult)
      apply (simp only: trans_def, auto)
  done

lemma union_upper1: "A <= A + (B::'a::order multiset)"
proof -
  have "A + {#} <= A + B" by (blast intro: union_le_mono)
  then show ?thesis by simp
qed

lemma union_upper2: "B <= A + (B::'a::order multiset)"
  by (subst union_commute) (rule union_upper1)

instance multiset :: (order) pordered_ab_semigroup_add
apply intro_classes
apply(erule union_le_mono[OF mult_le_refl])
done

subsection {* Link with lists *}

consts
  multiset_of :: "'a list => 'a multiset"
primrec
  "multiset_of [] = {#}"
  "multiset_of (a # x) = multiset_of x + {# a #}"

lemma multiset_of_zero_iff[simp]: "(multiset_of x = {#}) = (x = [])"
  by (induct x) auto

lemma multiset_of_zero_iff_right[simp]: "({#} = multiset_of x) = (x = [])"
  by (induct x) auto

lemma set_of_multiset_of[simp]: "set_of(multiset_of x) = set x"
  by (induct x) auto

lemma mem_set_multiset_eq: "x ∈ set xs = (x :# multiset_of xs)"
  by (induct xs) auto

lemma multiset_of_append [simp]:
    "multiset_of (xs @ ys) = multiset_of xs + multiset_of ys"
  by (induct xs arbitrary: ys) (auto simp: union_ac)

lemma surj_multiset_of: "surj multiset_of"
  apply (unfold surj_def, rule allI)
  apply (rule_tac M=y in multiset_induct, auto)
  apply (rule_tac x = "x # xa" in exI, auto)
  done

lemma set_count_greater_0: "set x = {a. count (multiset_of x) a > 0}"
  by (induct x) auto

lemma distinct_count_atmost_1:
   "distinct x = (! a. count (multiset_of x) a = (if a ∈ set x then 1 else 0))"
   apply (induct x, simp, rule iffI, simp_all)
   apply (rule conjI)
   apply (simp_all add: set_of_multiset_of [THEN sym] del: set_of_multiset_of)
   apply (erule_tac x=a in allE, simp, clarify)
   apply (erule_tac x=aa in allE, simp)
   done

lemma multiset_of_eq_setD:
  "multiset_of xs = multiset_of ys ==> set xs = set ys"
  by (rule) (auto simp add:multiset_eq_conv_count_eq set_count_greater_0)

lemma set_eq_iff_multiset_of_eq_distinct:
  "[|distinct x; distinct y|]
   ==> (set x = set y) = (multiset_of x = multiset_of y)"
  by (auto simp: multiset_eq_conv_count_eq distinct_count_atmost_1)

lemma set_eq_iff_multiset_of_remdups_eq:
   "(set x = set y) = (multiset_of (remdups x) = multiset_of (remdups y))"
  apply (rule iffI)
  apply (simp add: set_eq_iff_multiset_of_eq_distinct[THEN iffD1])
  apply (drule distinct_remdups[THEN distinct_remdups
                      [THEN set_eq_iff_multiset_of_eq_distinct[THEN iffD2]]])
  apply simp
  done

lemma multiset_of_compl_union [simp]:
    "multiset_of [x\<leftarrow>xs. P x] + multiset_of [x\<leftarrow>xs. ¬P x] = multiset_of xs"
  by (induct xs) (auto simp: union_ac)

lemma count_filter:
    "count (multiset_of xs) x = length [y \<leftarrow> xs. y = x]"
  by (induct xs) auto


subsection {* Pointwise ordering induced by count *}

definition
mset_le :: "'a multiset => 'a multiset => bool"  (infix "≤#" 50) where
"(A ≤# B) = (∀a. count A a ≤ count B a)"
definition
mset_less :: "'a multiset => 'a multiset => bool"  (infix "<#" 50) where
"(A <# B) = (A ≤# B ∧ A ≠ B)"

lemma mset_le_refl[simp]: "A ≤# A"
  unfolding mset_le_def by auto

lemma mset_le_trans: "[| A ≤# B; B ≤# C |] ==> A ≤# C"
  unfolding mset_le_def by (fast intro: order_trans)

lemma mset_le_antisym: "[| A ≤# B; B ≤# A |] ==> A = B"
  apply (unfold mset_le_def)
  apply (rule multiset_eq_conv_count_eq[THEN iffD2])
  apply (blast intro: order_antisym)
  done

lemma mset_le_exists_conv:
  "(A ≤# B) = (∃C. B = A + C)"
  apply (unfold mset_le_def, rule iffI, rule_tac x = "B - A" in exI)
  apply (auto intro: multiset_eq_conv_count_eq [THEN iffD2])
  done

lemma mset_le_mono_add_right_cancel[simp]: "(A + C ≤# B + C) = (A ≤# B)"
  unfolding mset_le_def by auto

lemma mset_le_mono_add_left_cancel[simp]: "(C + A ≤# C + B) = (A ≤# B)"
  unfolding mset_le_def by auto

lemma mset_le_mono_add: "[| A ≤# B; C ≤# D |] ==> A + C ≤# B + D"
  apply (unfold mset_le_def)
  apply auto
  apply (erule_tac x=a in allE)+
  apply auto
  done

lemma mset_le_add_left[simp]: "A ≤# A + B"
  unfolding mset_le_def by auto

lemma mset_le_add_right[simp]: "B ≤# A + B"
  unfolding mset_le_def by auto

lemma multiset_of_remdups_le: "multiset_of (remdups xs) ≤# multiset_of xs"
apply (induct xs)
 apply auto
apply (rule mset_le_trans)
 apply auto
done

interpretation mset_order:
  order ["op ≤#" "op <#"]
  by (auto intro: order.intro mset_le_refl mset_le_antisym
    mset_le_trans simp: mset_less_def)

interpretation mset_order_cancel_semigroup:
  pordered_cancel_ab_semigroup_add ["op ≤#" "op <#" "op +"]
  by unfold_locales (erule mset_le_mono_add [OF mset_le_refl])

interpretation mset_order_semigroup_cancel:
  pordered_ab_semigroup_add_imp_le ["op ≤#" "op <#" "op +"]
  by (unfold_locales) simp

end

The type of multisets

lemma multiset_typedef:

  y ∈ multiset ==> Rep_multiset (Abs_multiset y) = y
  Abs_multiset (Rep_multiset x) = x
  Rep_multiset x ∈ multiset

and

  (x = y) = (Rep_multiset x = Rep_multiset y)

lemma const0_in_multiset:

  a. 0) ∈ multiset

lemma only1_in_multiset:

  b. if b = a then 1 else 0) ∈ multiset

lemma union_preserves_multiset:

  [| M ∈ multiset; N ∈ multiset |] ==> (λa. M a + N a) ∈ multiset

lemma diff_preserves_multiset:

  M ∈ multiset ==> (λa. M a - N a) ∈ multiset

Algebraic properties of multisets

Union

lemma union_empty:

  M + {#} = M{#} + M = M

lemma union_commute:

  M + N = N + M

lemma union_assoc:

  M + N + K = M + (N + K)

lemma union_lcomm:

  M + (N + K) = N + (M + K)

lemma union_ac:

  M + N + K = M + (N + K)
  M + N = N + M
  M + (N + K) = N + (M + K)

Difference

lemma diff_empty:

  M - {#} = M{#} - M = {#}

lemma diff_union_inverse2:

  M + {#a#} - {#a#} = M

Count of elements

lemma count_empty:

  count {#} a = 0

lemma count_single:

  count {#b#} a = (if b = a then 1 else 0)

lemma count_union:

  count (M + N) a = count M a + count N a

lemma count_diff:

  count (M - N) a = count M a - count N a

Set of elements

lemma set_of_empty:

  set_of {#} = {}

lemma set_of_single:

  set_of {#b#} = {b}

lemma set_of_union:

  set_of (M + N) = set_of Mset_of N

lemma set_of_eq_empty_iff:

  (set_of M = {}) = (M = {#})

lemma mem_set_of_iff:

  (xset_of M) = (0 < count M x)

Size

lemma size_empty:

  size {#} = 0

lemma size_single:

  size {#b#} = 1

lemma finite_set_of:

  finite (set_of M)

lemma setsum_count_Int:

  finite A ==> setsum (count N) (Aset_of N) = setsum (count N) A

lemma size_union:

  size (M + N) = size M + size N

lemma size_eq_0_iff_empty:

  (size M = 0) = (M = {#})

lemma size_eq_Suc_imp_elem:

  size M = Suc n ==> ∃a. 0 < count M a

Equality of multisets

lemma multiset_eq_conv_count_eq:

  (M = N) = (∀a. count M a = count N a)

lemma single_not_empty:

  {#a#}  {#}{#}  {#a#}

lemma single_eq_single:

  ({#a#} = {#b#}) = (a = b)

lemma union_eq_empty:

  (M + N = {#}) = (M = {#}N = {#})

lemma empty_eq_union:

  ({#} = M + N) = (M = {#}N = {#})

lemma union_right_cancel:

  (M + K = N + K) = (M = N)

lemma union_left_cancel:

  (K + M = K + N) = (M = N)

lemma union_is_single:

  (M + N = {#a#}) = (M = {#a#}N = {#}M = {#}N = {#a#})

lemma single_is_union:

  ({#a#} = M + N) = ({#a#} = MN = {#}M = {#}{#a#} = N)

lemma add_eq_conv_diff:

  (M + {#a#} = N + {#b#}) =
  (M = Na = bM = N - {#a#} + {#b#}N = M - {#b#} + {#a#})

Intersection

lemma multiset_inter_count:

  count (A #∩ B) x = min (count A x) (count B x)

lemma multiset_inter_commute:

  A #∩ B = B #∩ A

lemma multiset_inter_assoc:

  A #∩ (B #∩ C) = A #∩ B #∩ C

lemma multiset_inter_left_commute:

  A #∩ (B #∩ C) = B #∩ (A #∩ C)

lemma multiset_inter_ac:

  A #∩ B = B #∩ A
  A #∩ (B #∩ C) = A #∩ B #∩ C
  A #∩ (B #∩ C) = B #∩ (A #∩ C)

lemma multiset_union_diff_commute:

  B #∩ C = {#} ==> A + B - C = A - C + B

Induction over multisets

lemma setsum_decr:

  [| finite F; 0 < f a |]
  ==> setsum (f(a := f a - 1)) F = (if aF then setsum f F - 1 else setsum f F)

lemma rep_multiset_induct_aux:

  [| Pa. 0); !!f b. [| f ∈ multiset; P f |] ==> P (f(b := f b + 1)) |]
  ==> ∀f. f ∈ multiset --> setsum f {x. f x  0} = n --> P f

theorem rep_multiset_induct:

  [| f ∈ multiset; Pa. 0);
     !!f b. [| f ∈ multiset; P f |] ==> P (f(b := f b + 1)) |]
  ==> P f

theorem multiset_induct:

  [| P {#}; !!M x. P M ==> P (M + {#x#}) |] ==> P M

lemma MCollect_preserves_multiset:

  M ∈ multiset ==> (λx. if P x then M x else 0) ∈ multiset

lemma count_MCollect:

  count (MCollect M P) a = (if P a then count M a else 0)

lemma set_of_MCollect:

  set_of (MCollect M P) = set_of M ∩ {x. P x}

lemma multiset_partition:

  M = MCollect M P + {# x : M. ¬ P x#}

lemma add_eq_conv_ex:

  (M + {#a#} = N + {#b#}) = (M = Na = b ∨ (∃K. M = K + {#b#}N = K + {#a#}))

Multiset orderings

Well-foundedness

lemma not_less_empty:

  (M, {#})  mult1 r

lemma less_add:

  (N, M0.0 + {#a#}) ∈ mult1 r
  ==> (∃M. (M, M0.0) ∈ mult1 rN = M + {#a#}) ∨
      (∃K. (∀b. 0 < count K b --> (b, a) ∈ r) ∧ N = M0.0 + K)

lemma all_accessible:

  wf r ==> ∀M. Macc (mult1 r)

theorem wf_mult1:

  wf r ==> wf (mult1 r)

theorem wf_mult:

  wf r ==> wf (mult r)

Closure-free presentation

lemma diff_union_single_conv:

  0 < count J a ==> I + J - {#a#} = I + (J - {#a#})

lemma mult_implies_one_step:

  [| trans r; (M, N) ∈ mult r |]
  ==> ∃I J K.
         N = I + JM = I + KJ  {#} ∧ (∀kset_of K. ∃jset_of J. (k, j) ∈ r)

lemma elem_imp_eq_diff_union:

  0 < count M a ==> M = M - {#a#} + {#a#}

lemma size_eq_Suc_imp_eq_union:

  size M = Suc n ==> ∃a N. M = N + {#a#}

lemma one_step_implies_mult_aux:

  trans r
  ==> ∀I J K.
         size J = nJ  {#} ∧ (∀kset_of K. ∃jset_of J. (k, j) ∈ r) -->
         (I + K, I + J) ∈ mult r

lemma one_step_implies_mult:

  [| trans r; J  {#}; ∀kset_of K. ∃jset_of J. (k, j) ∈ r |]
  ==> (I + K, I + J) ∈ mult r

Partial-order properties

lemma trans_base_order:

  transP op <

lemma mult_irrefl_aux:

  [| finite A; ∀xA. ∃yA. x < y |] ==> A = {}

lemma mult_less_not_refl:

  ¬ M < M

lemma mult_less_irrefl:

  M < M ==> R

theorem mult_less_trans:

  [| K < M; M < N |] ==> K < N

theorem mult_less_not_sym:

  M < N ==> ¬ N < M

theorem mult_less_asym:

  [| M < N; ¬ P ==> N < M |] ==> P

theorem mult_le_refl:

  M  M

theorem mult_le_antisym:

  [| M  N; N  M |] ==> M = N

theorem mult_le_trans:

  [| K  M; M  N |] ==> K  N

theorem mult_less_le:

  (M < N) = (M  NM  N)

Monotonicity of multiset union

lemma mult1_union:

  [| (B, D) ∈ mult1 r; trans r |] ==> (C + B, C + D) ∈ mult1 r

lemma union_less_mono2:

  B < D ==> C + B < C + D

lemma union_less_mono1:

  B < D ==> B + C < D + C

lemma union_less_mono:

  [| A < C; B < D |] ==> A + B < C + D

lemma union_le_mono:

  [| A  C; B  D |] ==> A + B  C + D

lemma empty_leI:

  {#}  M

lemma union_upper1:

  A  A + B

lemma union_upper2:

  B  A + B

Link with lists

lemma multiset_of_zero_iff:

  (multiset_of x = {#}) = (x = [])

lemma multiset_of_zero_iff_right:

  ({#} = multiset_of x) = (x = [])

lemma set_of_multiset_of:

  set_of (multiset_of x) = set x

lemma mem_set_multiset_eq:

  (x ∈ set xs) = (0 < count (multiset_of xs) x)

lemma multiset_of_append:

  multiset_of (xs @ ys) = multiset_of xs + multiset_of ys

lemma surj_multiset_of:

  surj multiset_of

lemma set_count_greater_0:

  set x = {a. 0 < count (multiset_of x) a}

lemma distinct_count_atmost_1:

  distinct x = (∀a. count (multiset_of x) a = (if a ∈ set x then 1 else 0))

lemma multiset_of_eq_setD:

  multiset_of xs = multiset_of ys ==> set xs = set ys

lemma set_eq_iff_multiset_of_eq_distinct:

  [| distinct x; distinct y |]
  ==> (set x = set y) = (multiset_of x = multiset_of y)

lemma set_eq_iff_multiset_of_remdups_eq:

  (set x = set y) = (multiset_of (remdups x) = multiset_of (remdups y))

lemma multiset_of_compl_union:

  multiset_of (filter P xs) + multiset_of [x\<leftarrow>xs . ¬ P x] =
  multiset_of xs

lemma count_filter:

  count (multiset_of xs) x = length [y\<leftarrow>xs . y = x]

Pointwise ordering induced by count

lemma mset_le_refl:

  A ≤# A

lemma mset_le_trans:

  [| A ≤# B; B ≤# C |] ==> A ≤# C

lemma mset_le_antisym:

  [| A ≤# B; B ≤# A |] ==> A = B

lemma mset_le_exists_conv:

  (A ≤# B) = (∃C. B = A + C)

lemma mset_le_mono_add_right_cancel:

  (A + C ≤# B + C) = (A ≤# B)

lemma mset_le_mono_add_left_cancel:

  (C + A ≤# C + B) = (A ≤# B)

lemma mset_le_mono_add:

  [| A ≤# B; C ≤# D |] ==> A + C ≤# B + D

lemma mset_le_add_left:

  A ≤# A + B

lemma mset_le_add_right:

  B ≤# A + B

lemma multiset_of_remdups_le:

  multiset_of (remdups xs) ≤# multiset_of xs