1 (*  Title:      Nominal2_Atoms

     2     Authors:    Brian Huffman, Christian Urban

     3 

     4     Definitions for concrete atom types. 

     5 *)

     6 theory Nominal2_Atoms

     7 imports Nominal2_Base

     8 uses ("nominal_atoms.ML")

     9 begin

    10 

    11 section {* Concrete atom types *}

    12 

    13 text {*

    14   Class @{text at_base} allows types containing multiple sorts of atoms.

    15   Class @{text at} only allows types with a single sort.

    16 *}

    17 

    18 class at_base = pt +

    19   fixes atom :: "'a \<Rightarrow> atom"

    20   assumes atom_eq_iff [simp]: "atom a = atom b \<longleftrightarrow> a = b"

    21   assumes atom_eqvt: "p \<bullet> (atom a) = atom (p \<bullet> a)"

    22 

    23 class at = at_base +

    24   assumes sort_of_atom_eq [simp]: "sort_of (atom a) = sort_of (atom b)"

    25 

    26 instance at < at_base ..

    27 

    28 lemma supp_at_base: 

    29   fixes a::"'a::at_base"

    30   shows "supp a = {atom a}"

    31   by (simp add: supp_atom [symmetric] supp_def atom_eqvt)

    32 

    33 lemma fresh_at_base: 

    34   shows "a \<sharp> b \<longleftrightarrow> a \<noteq> atom b"

    35   unfolding fresh_def by (simp add: supp_at_base)

    36 

    37 instance at_base < fs

    38 proof qed (simp add: supp_at_base)

    39 

    40 lemma at_base_infinite [simp]:

    41   shows "infinite (UNIV :: 'a::at_base set)" (is "infinite ?U")

    42 proof

    43   obtain a :: 'a where "True" by auto

    44   assume "finite ?U"

    45   hence "finite (atom ` ?U)"

    46     by (rule finite_imageI)

    47   then obtain b where b: "b \<notin> atom ` ?U" "sort_of b = sort_of (atom a)"

    48     by (rule obtain_atom)

    49   from b(2) have "b = atom ((atom a \<rightleftharpoons> b) \<bullet> a)"

    50     unfolding atom_eqvt [symmetric]

    51     by (simp add: swap_atom)

    52   hence "b \<in> atom ` ?U" by simp

    53   with b(1) show "False" by simp

    54 qed

    55 

    56 lemma swap_at_base_simps [simp]:

    57   fixes x y::"'a::at_base"

    58   shows "sort_of (atom x) = sort_of (atom y) \<Longrightarrow> (atom x \<rightleftharpoons> atom y) \<bullet> x = y"

    59   and   "sort_of (atom x) = sort_of (atom y) \<Longrightarrow> (atom x \<rightleftharpoons> atom y) \<bullet> y = x"

    60   and   "atom x \<noteq> a \<Longrightarrow> atom x \<noteq> b \<Longrightarrow> (a \<rightleftharpoons> b) \<bullet> x = x"

    61   unfolding atom_eq_iff [symmetric]

    62   unfolding atom_eqvt [symmetric]

    63   by simp_all

    64 

    65 lemma obtain_at_base:

    66   assumes X: "finite X"

    67   obtains a::"'a::at_base" where "atom a \<notin> X"

    68 proof -

    69   have "inj (atom :: 'a \<Rightarrow> atom)"

    70     by (simp add: inj_on_def)

    71   with X have "finite (atom -` X :: 'a set)"

    72     by (rule finite_vimageI)

    73   with at_base_infinite have "atom -` X \<noteq> (UNIV :: 'a set)"

    74     by auto

    75   then obtain a :: 'a where "atom a \<notin> X"

    76     by auto

    77   thus ?thesis ..

    78 qed

    79 

    80 

    81 section {* A swapping operation for concrete atoms *}

    82   

    83 definition

    84   flip :: "'a::at_base \<Rightarrow> 'a \<Rightarrow> perm" ("'(_ \<leftrightarrow> _')")

    85 where

    86   "(a \<leftrightarrow> b) = (atom a \<rightleftharpoons> atom b)"

    87 

    88 lemma flip_self [simp]: "(a \<leftrightarrow> a) = 0"

    89   unfolding flip_def by (rule swap_self)

    90 

    91 lemma flip_commute: "(a \<leftrightarrow> b) = (b \<leftrightarrow> a)"

    92   unfolding flip_def by (rule swap_commute)

    93 

    94 lemma minus_flip [simp]: "- (a \<leftrightarrow> b) = (a \<leftrightarrow> b)"

    95   unfolding flip_def by (rule minus_swap)

    96 

    97 lemma add_flip_cancel: "(a \<leftrightarrow> b) + (a \<leftrightarrow> b) = 0"

    98   unfolding flip_def by (rule swap_cancel)

    99 

   100 lemma permute_flip_cancel [simp]: "(a \<leftrightarrow> b) \<bullet> (a \<leftrightarrow> b) \<bullet> x = x"

   101   unfolding permute_plus [symmetric] add_flip_cancel by simp

   102 

   103 lemma permute_flip_cancel2 [simp]: "(a \<leftrightarrow> b) \<bullet> (b \<leftrightarrow> a) \<bullet> x = x"

   104   by (simp add: flip_commute)

   105 

   106 lemma flip_eqvt: 

   107   fixes a b c::"'a::at_base"

   108   shows "p \<bullet> (a \<leftrightarrow> b) = (p \<bullet> a \<leftrightarrow> p \<bullet> b)"

   109   unfolding flip_def

   110   by (simp add: swap_eqvt atom_eqvt)

   111 

   112 lemma flip_at_base_simps [simp]:

   113   shows "sort_of (atom a) = sort_of (atom b) \<Longrightarrow> (a \<leftrightarrow> b) \<bullet> a = b"

   114   and   "sort_of (atom a) = sort_of (atom b) \<Longrightarrow> (a \<leftrightarrow> b) \<bullet> b = a"

   115   and   "\<lbrakk>a \<noteq> c; b \<noteq> c\<rbrakk> \<Longrightarrow> (a \<leftrightarrow> b) \<bullet> c = c"

   116   and   "sort_of (atom a) \<noteq> sort_of (atom b) \<Longrightarrow> (a \<leftrightarrow> b) \<bullet> x = x"

   117   unfolding flip_def

   118   unfolding atom_eq_iff [symmetric]

   119   unfolding atom_eqvt [symmetric]

   120   by simp_all

   121 

   122 text {* the following two lemmas do not hold for at_base, 

   123   only for single sort atoms from at *}

   124 

   125 lemma permute_flip_at:

   126   fixes a b c::"'a::at"

   127   shows "(a \<leftrightarrow> b) \<bullet> c = (if c = a then b else if c = b then a else c)"

   128   unfolding flip_def

   129   apply (rule atom_eq_iff [THEN iffD1])

   130   apply (subst atom_eqvt [symmetric])

   131   apply (simp add: swap_atom)

   132   done

   133 

   134 lemma flip_at_simps [simp]:

   135   fixes a b::"'a::at"

   136   shows "(a \<leftrightarrow> b) \<bullet> a = b" 

   137   and   "(a \<leftrightarrow> b) \<bullet> b = a"

   138   unfolding permute_flip_at by simp_all

   139 

   140 

   141 subsection {* Syntax for coercing at-elements to the atom-type *}

   142 

   143 syntax

   144   "_atom_constrain" :: "logic \<Rightarrow> type \<Rightarrow> logic" ("_:::_" [4, 0] 3)

   145 

   146 translations

   147   "_atom_constrain a t" => "atom (_constrain a t)"

   148 

   149 

   150 subsection {* A lemma for proving instances of class @{text at}. *}

   151 

   152 setup {* Sign.add_const_constraint (@{const_name "permute"}, NONE) *}

   153 setup {* Sign.add_const_constraint (@{const_name "atom"}, NONE) *}

   154 

   155 text {*

   156   New atom types are defined as subtypes of @{typ atom}.

   157 *}

   158 

   159 lemma exists_eq_simple_sort: 

   160   shows "\<exists>a. a \<in> {a. sort_of a = s}"

   161   by (rule_tac x="Atom s 0" in exI, simp)

   162 

   163 lemma exists_eq_sort: 

   164   shows "\<exists>a. a \<in> {a. sort_of a \<in> range sort_fun}"

   165   by (rule_tac x="Atom (sort_fun x) y" in exI, simp)

   166 

   167 lemma at_base_class:

   168   fixes sort_fun :: "'b \<Rightarrow>atom_sort"

   169   fixes Rep :: "'a \<Rightarrow> atom" and Abs :: "atom \<Rightarrow> 'a"

   170   assumes type: "type_definition Rep Abs {a. sort_of a \<in> range sort_fun}"

   171   assumes atom_def: "\<And>a. atom a = Rep a"

   172   assumes permute_def: "\<And>p a. p \<bullet> a = Abs (p \<bullet> Rep a)"

   173   shows "OFCLASS('a, at_base_class)"

   174 proof

   175   interpret type_definition Rep Abs "{a. sort_of a \<in> range sort_fun}" by (rule type)

   176   have sort_of_Rep: "\<And>a. sort_of (Rep a) \<in> range sort_fun" using Rep by simp

   177   fix a b :: 'a and p p1 p2 :: perm

   178   show "0 \<bullet> a = a"

   179     unfolding permute_def by (simp add: Rep_inverse)

   180   show "(p1 + p2) \<bullet> a = p1 \<bullet> p2 \<bullet> a"

   181     unfolding permute_def by (simp add: Abs_inverse sort_of_Rep)

   182   show "atom a = atom b \<longleftrightarrow> a = b"

   183     unfolding atom_def by (simp add: Rep_inject)

   184   show "p \<bullet> atom a = atom (p \<bullet> a)"

   185     unfolding permute_def atom_def by (simp add: Abs_inverse sort_of_Rep)

   186 qed

   187 

   188 (*

   189 lemma at_class:

   190   fixes s :: atom_sort

   191   fixes Rep :: "'a \<Rightarrow> atom" and Abs :: "atom \<Rightarrow> 'a"

   192   assumes type: "type_definition Rep Abs {a. sort_of a \<in> range (\<lambda>x::unit. s)}"

   193   assumes atom_def: "\<And>a. atom a = Rep a"

   194   assumes permute_def: "\<And>p a. p \<bullet> a = Abs (p \<bullet> Rep a)"

   195   shows "OFCLASS('a, at_class)"

   196 proof

   197   interpret type_definition Rep Abs "{a. sort_of a \<in> range (\<lambda>x::unit. s)}" by (rule type)

   198   have sort_of_Rep: "\<And>a. sort_of (Rep a) = s" using Rep by (simp add: image_def)

   199   fix a b :: 'a and p p1 p2 :: perm

   200   show "0 \<bullet> a = a"

   201     unfolding permute_def by (simp add: Rep_inverse)

   202   show "(p1 + p2) \<bullet> a = p1 \<bullet> p2 \<bullet> a"

   203     unfolding permute_def by (simp add: Abs_inverse sort_of_Rep)

   204   show "sort_of (atom a) = sort_of (atom b)"

   205     unfolding atom_def by (simp add: sort_of_Rep)

   206   show "atom a = atom b \<longleftrightarrow> a = b"

   207     unfolding atom_def by (simp add: Rep_inject)

   208   show "p \<bullet> atom a = atom (p \<bullet> a)"

   209     unfolding permute_def atom_def by (simp add: Abs_inverse sort_of_Rep)

   210 qed

   211 *)

   212 

   213 lemma at_class:

   214   fixes s :: atom_sort

   215   fixes Rep :: "'a \<Rightarrow> atom" and Abs :: "atom \<Rightarrow> 'a"

   216   assumes type: "type_definition Rep Abs {a. sort_of a = s}"

   217   assumes atom_def: "\<And>a. atom a = Rep a"

   218   assumes permute_def: "\<And>p a. p \<bullet> a = Abs (p \<bullet> Rep a)"

   219   shows "OFCLASS('a, at_class)"

   220 proof

   221   interpret type_definition Rep Abs "{a. sort_of a = s}" by (rule type)

   222   have sort_of_Rep: "\<And>a. sort_of (Rep a) = s" using Rep by (simp add: image_def)

   223   fix a b :: 'a and p p1 p2 :: perm

   224   show "0 \<bullet> a = a"

   225     unfolding permute_def by (simp add: Rep_inverse)

   226   show "(p1 + p2) \<bullet> a = p1 \<bullet> p2 \<bullet> a"

   227     unfolding permute_def by (simp add: Abs_inverse sort_of_Rep)

   228   show "sort_of (atom a) = sort_of (atom b)"

   229     unfolding atom_def by (simp add: sort_of_Rep)

   230   show "atom a = atom b \<longleftrightarrow> a = b"

   231     unfolding atom_def by (simp add: Rep_inject)

   232   show "p \<bullet> atom a = atom (p \<bullet> a)"

   233     unfolding permute_def atom_def by (simp add: Abs_inverse sort_of_Rep)

   234 qed

   235 

   236 setup {* Sign.add_const_constraint

   237   (@{const_name "permute"}, SOME @{typ "perm \<Rightarrow> 'a::pt \<Rightarrow> 'a"}) *}

   238 setup {* Sign.add_const_constraint

   239   (@{const_name "atom"}, SOME @{typ "'a::at_base \<Rightarrow> atom"}) *}

   240 

   241 

   242 section {* Automation for creating concrete atom types *}

   243 

   244 text {* at the moment only single-sort concrete atoms are supported *}

   245 

   246 use "nominal_atoms.ML"

   247 

   248 

   249 

   250 

   251 end