src/Pure/Isar/code.ML
author wenzelm
Fri Mar 29 22:14:27 2013 +0100 (2013-03-29)
changeset 51580 64ef8260dc60
parent 51551 88d1d19fb74f
child 51584 98029ceda8ce
permissions -rw-r--r--
Pretty.item markup for improved readability of lists of items;
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(*  Title:      Pure/Isar/code.ML
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    Author:     Florian Haftmann, TU Muenchen
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Abstract executable ingredients of theory.  Management of data
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dependent on executable ingredients as synchronized cache; purged
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on any change of underlying executable ingredients.
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*)
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signature CODE =
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sig
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  (*constants*)
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  val check_const: theory -> term -> string
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  val read_bare_const: theory -> string -> string * typ
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  val read_const: theory -> string -> string
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  val string_of_const: theory -> string -> string
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  val const_typ: theory -> string -> typ
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  val args_number: theory -> string -> int
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  (*constructor sets*)
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  val constrset_of_consts: theory -> (string * typ) list
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    -> string * ((string * sort) list * (string * ((string * sort) list * typ list)) list)
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  (*code equations and certificates*)
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  val mk_eqn: theory -> thm * bool -> thm * bool
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  val mk_eqn_warning: theory -> thm -> (thm * bool) option
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  val mk_eqn_liberal: theory -> thm -> (thm * bool) option
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  val assert_eqn: theory -> thm * bool -> thm * bool
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  val const_typ_eqn: theory -> thm -> string * typ
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  val expand_eta: theory -> int -> thm -> thm
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  type cert
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  val empty_cert: theory -> string -> cert
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  val cert_of_eqns: theory -> string -> (thm * bool) list -> cert
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  val constrain_cert: theory -> sort list -> cert -> cert
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  val conclude_cert: cert -> cert
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  val typargs_deps_of_cert: theory -> cert -> (string * sort) list * (string * typ list) list
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  val equations_of_cert: theory -> cert -> ((string * sort) list * typ)
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    * (((term * string option) list * (term * string option)) * (thm option * bool)) list
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  val bare_thms_of_cert: theory -> cert -> thm list
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  val pretty_cert: theory -> cert -> Pretty.T list
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  (*executable code*)
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  val add_datatype: (string * typ) list -> theory -> theory
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  val add_datatype_cmd: string list -> theory -> theory
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  val datatype_interpretation:
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    (string * ((string * sort) list * (string * ((string * sort) list * typ list)) list)
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      -> theory -> theory) -> theory -> theory
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  val add_abstype: thm -> theory -> theory
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  val abstype_interpretation:
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    (string * ((string * sort) list * ((string * ((string * sort) list * typ)) * (string * thm)))
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      -> theory -> theory) -> theory -> theory
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  val add_eqn: thm -> theory -> theory
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  val add_nbe_eqn: thm -> theory -> theory
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  val add_abs_eqn: thm -> theory -> theory
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  val add_default_eqn: thm -> theory -> theory
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  val add_default_eqn_attribute: attribute
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  val add_default_eqn_attrib: Attrib.src
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  val add_nbe_default_eqn: thm -> theory -> theory
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  val add_nbe_default_eqn_attribute: attribute
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  val add_nbe_default_eqn_attrib: Attrib.src
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  val del_eqn: thm -> theory -> theory
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  val del_eqns: string -> theory -> theory
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  val add_case: thm -> theory -> theory
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  val add_undefined: string -> theory -> theory
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  val get_type: theory -> string
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    -> ((string * sort) list * (string * ((string * sort) list * typ list)) list) * bool
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  val get_type_of_constr_or_abstr: theory -> string -> (string * bool) option
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  val is_constr: theory -> string -> bool
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  val is_abstr: theory -> string -> bool
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  val get_cert: theory -> { functrans: ((thm * bool) list -> (thm * bool) list option) list,
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    ss: simpset } -> string -> cert
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  val get_case_scheme: theory -> string -> (int * (int * string option list)) option
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  val get_case_cong: theory -> string -> thm option
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  val undefineds: theory -> string list
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  val print_codesetup: theory -> unit
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end;
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signature CODE_DATA_ARGS =
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sig
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  type T
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  val empty: T
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end;
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signature CODE_DATA =
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sig
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  type T
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  val change: theory option -> (T -> T) -> T
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  val change_yield: theory option -> (T -> 'a * T) -> 'a * T
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end;
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signature PRIVATE_CODE =
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sig
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  include CODE
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  val declare_data: Any.T -> serial
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  val change_yield_data: serial * ('a -> Any.T) * (Any.T -> 'a)
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    -> theory -> ('a -> 'b * 'a) -> 'b * 'a
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end;
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structure Code : PRIVATE_CODE =
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struct
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(** auxiliary **)
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(* printing *)
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fun string_of_typ thy =
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  Syntax.string_of_typ (Config.put show_sorts true (Syntax.init_pretty_global thy));
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fun string_of_const thy c =
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  let val ctxt = Proof_Context.init_global thy in
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    case AxClass.inst_of_param thy c of
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      SOME (c, tyco) =>
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        Proof_Context.extern_const ctxt c ^ " " ^ enclose "[" "]"
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          (Proof_Context.extern_type ctxt tyco)
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    | NONE => Proof_Context.extern_const ctxt c
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  end;
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(* constants *)
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fun const_typ thy = Type.strip_sorts o Sign.the_const_type thy;
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fun args_number thy = length o binder_types o const_typ thy;
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fun devarify ty =
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  let
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    val tys = fold_atyps (fn TVar vi_sort => AList.update (op =) vi_sort) ty [];
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    val vs = Name.invent Name.context Name.aT (length tys);
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    val mapping = map2 (fn v => fn (vi, sort) => (vi, TFree (v, sort))) vs tys;
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  in Term.typ_subst_TVars mapping ty end;
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fun typscheme thy (c, ty) =
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  (map dest_TFree (Sign.const_typargs thy (c, ty)), Type.strip_sorts ty);
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fun typscheme_equiv (ty1, ty2) =
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  Type.raw_instance (devarify ty1, ty2) andalso Type.raw_instance (devarify ty2, ty1);
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fun check_bare_const thy t = case try dest_Const t
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 of SOME c_ty => c_ty
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  | NONE => error ("Not a constant: " ^ Syntax.string_of_term_global thy t);
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fun check_unoverload thy (c, ty) =
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  let
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    val c' = AxClass.unoverload_const thy (c, ty);
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    val ty_decl = Sign.the_const_type thy c';
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  in
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    if typscheme_equiv (ty_decl, Logic.varifyT_global ty)
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    then c'
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    else
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      error ("Type\n" ^ string_of_typ thy ty ^
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        "\nof constant " ^ quote c ^
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        "\nis too specific compared to declared type\n" ^
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        string_of_typ thy ty_decl)
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  end; 
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fun check_const thy = check_unoverload thy o check_bare_const thy;
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fun read_bare_const thy = check_bare_const thy o Syntax.read_term_global thy;
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fun read_const thy = check_unoverload thy o read_bare_const thy;
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(** data store **)
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(* datatypes *)
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datatype typ_spec = Constructors of (string * ((string * sort) list * typ list)) list *
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      string list (*references to associated case constructors*)
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  | Abstractor of (string * ((string * sort) list * typ)) * (string * thm);
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fun constructors_of (Constructors (cos, _)) = (cos, false)
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  | constructors_of (Abstractor ((co, (vs, ty)), _)) = ([(co, (vs, [ty]))], true);
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fun case_consts_of (Constructors (_, case_consts)) = case_consts
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  | case_consts_of (Abstractor _) = [];
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(* functions *)
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datatype fun_spec = Default of (thm * bool) list * (thm * bool) list lazy
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      (* (cache for default equations, lazy computation of default equations)
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         -- helps to restore natural order of default equations *)
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  | Eqns of (thm * bool) list
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  | Proj of term * string
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  | Abstr of thm * string;
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val empty_fun_spec = Default ([], Lazy.value []);
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fun is_default (Default _) = true
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  | is_default _ = false;
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fun associated_abstype (Abstr (_, tyco)) = SOME tyco
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  | associated_abstype _ = NONE;
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(* executable code data *)
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datatype spec = Spec of {
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  history_concluded: bool,
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  functions: ((bool * fun_spec) * (serial * fun_spec) list) Symtab.table
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    (*with explicit history*),
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  types: ((serial * ((string * sort) list * typ_spec)) list) Symtab.table
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    (*with explicit history*),
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  cases: ((int * (int * string option list)) * thm) Symtab.table * unit Symtab.table
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};
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fun make_spec (history_concluded, (functions, (types, cases))) =
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  Spec { history_concluded = history_concluded, functions = functions, types = types, cases = cases };
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fun map_spec f (Spec { history_concluded = history_concluded,
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  functions = functions, types = types, cases = cases }) =
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  make_spec (f (history_concluded, (functions, (types, cases))));
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fun merge_spec (Spec { history_concluded = _, functions = functions1,
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    types = types1, cases = (cases1, undefs1) },
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  Spec { history_concluded = _, functions = functions2,
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    types = types2, cases = (cases2, undefs2) }) =
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  let
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    val types = Symtab.join (K (AList.merge (op =) (K true))) (types1, types2);
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    val case_consts_of' = (maps case_consts_of o map (snd o snd o hd o snd) o Symtab.dest);
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    fun merge_functions ((_, history1), (_, history2)) =
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      let
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        val raw_history = AList.merge (op = : serial * serial -> bool)
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          (K true) (history1, history2);
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        val filtered_history = filter_out (is_default o snd) raw_history;
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        val history = if null filtered_history
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          then raw_history else filtered_history;
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      in ((false, (snd o hd) history), history) end;
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    val all_datatype_specs = map (snd o snd o hd o snd) (Symtab.dest types);
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    val all_constructors = maps (map fst o fst o constructors_of) all_datatype_specs;
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    val invalidated_case_consts = union (op =) (case_consts_of' types1) (case_consts_of' types2)
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      |> subtract (op =) (maps case_consts_of all_datatype_specs)
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    val functions = Symtab.join (K merge_functions) (functions1, functions2)
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      |> fold (fn c => Symtab.map_entry c (apfst (K (true, empty_fun_spec)))) all_constructors;
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    val cases = (Symtab.merge (K true) (cases1, cases2)
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      |> fold Symtab.delete invalidated_case_consts, Symtab.merge (K true) (undefs1, undefs2));
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  in make_spec (false, (functions, (types, cases))) end;
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fun history_concluded (Spec { history_concluded, ... }) = history_concluded;
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fun the_functions (Spec { functions, ... }) = functions;
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fun the_types (Spec { types, ... }) = types;
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fun the_cases (Spec { cases, ... }) = cases;
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val map_history_concluded = map_spec o apfst;
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val map_functions = map_spec o apsnd o apfst;
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val map_typs = map_spec o apsnd o apsnd o apfst;
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val map_cases = map_spec o apsnd o apsnd o apsnd;
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(* data slots dependent on executable code *)
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(*private copy avoids potential conflict of table exceptions*)
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structure Datatab = Table(type key = int val ord = int_ord);
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local
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type kind = { empty: Any.T };
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val kinds = Synchronized.var "Code_Data" (Datatab.empty: kind Datatab.table);
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fun invoke f k =
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  (case Datatab.lookup (Synchronized.value kinds) k of
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    SOME kind => f kind
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  | NONE => raise Fail "Invalid code data identifier");
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in
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fun declare_data empty =
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  let
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    val k = serial ();
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    val kind = { empty = empty };
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    val _ = Synchronized.change kinds (Datatab.update (k, kind));
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  in k end;
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fun invoke_init k = invoke (fn kind => #empty kind) k;
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end; (*local*)
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(* theory store *)
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local
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type data = Any.T Datatab.table;
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fun empty_dataref () = Synchronized.var "code data" (NONE : (data * theory_ref) option);
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structure Code_Data = Theory_Data
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(
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  type T = spec * (data * theory_ref) option Synchronized.var;
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  val empty = (make_spec (false, (Symtab.empty,
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    (Symtab.empty, (Symtab.empty, Symtab.empty)))), empty_dataref ());
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  val extend : T -> T = apsnd (K (empty_dataref ()));
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  fun merge ((spec1, _), (spec2, _)) =
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    (merge_spec (spec1, spec2), empty_dataref ());
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);
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in
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(* access to executable code *)
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val the_exec : theory -> spec = fst o Code_Data.get;
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fun map_exec_purge f = Code_Data.map (fn (exec, _) => (f exec, empty_dataref ()));
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fun change_fun_spec delete c f = (map_exec_purge o map_functions
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  o (if delete then Symtab.map_entry c else Symtab.map_default (c, ((false, empty_fun_spec), [])))
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    o apfst) (fn (_, spec) => (true, f spec));
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(* tackling equation history *)
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fun continue_history thy = if (history_concluded o the_exec) thy
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  then thy
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    |> (Code_Data.map o apfst o map_history_concluded) (K false)
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    |> SOME
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  else NONE;
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fun conclude_history thy = if (history_concluded o the_exec) thy
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  then NONE
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  else thy
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    |> (Code_Data.map o apfst)
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        ((map_functions o Symtab.map) (fn _ => fn ((changed, current), history) =>
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          ((false, current),
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            if changed then (serial (), current) :: history else history))
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        #> map_history_concluded (K true))
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    |> SOME;
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val _ = Context.>> (Context.map_theory (Theory.at_begin continue_history #> Theory.at_end conclude_history));
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(* access to data dependent on abstract executable code *)
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fun change_yield_data (kind, mk, dest) theory f =
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  let
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    val dataref = (snd o Code_Data.get) theory;
haftmann@34251
   332
    val (datatab, thy_ref) = case Synchronized.value dataref
haftmann@34251
   333
     of SOME (datatab, thy_ref) => if Theory.eq_thy (theory, Theory.deref thy_ref)
haftmann@34251
   334
          then (datatab, thy_ref)
haftmann@34251
   335
          else (Datatab.empty, Theory.check_thy theory)
haftmann@34251
   336
      | NONE => (Datatab.empty, Theory.check_thy theory)
haftmann@34244
   337
    val data = case Datatab.lookup datatab kind
haftmann@34244
   338
     of SOME data => data
haftmann@34244
   339
      | NONE => invoke_init kind;
haftmann@40758
   340
    val result as (_, data') = f (dest data);
haftmann@34244
   341
    val _ = Synchronized.change dataref
haftmann@34244
   342
      ((K o SOME) (Datatab.update (kind, mk data') datatab, thy_ref));
haftmann@34244
   343
  in result end;
haftmann@31962
   344
haftmann@31962
   345
end; (*local*)
haftmann@31962
   346
haftmann@31962
   347
haftmann@31962
   348
(** foundation **)
haftmann@31962
   349
haftmann@31962
   350
(* datatypes *)
haftmann@31156
   351
haftmann@35226
   352
fun no_constr thy s (c, ty) = error ("Not a datatype constructor:\n" ^ string_of_const thy c
haftmann@35226
   353
  ^ " :: " ^ string_of_typ thy ty ^ "\n" ^ enclose "(" ")" s);
haftmann@35226
   354
haftmann@45987
   355
fun analyze_constructor thy (c, ty) =
haftmann@31156
   356
  let
haftmann@45987
   357
    val _ = Thm.cterm_of thy (Const (c, ty));
wenzelm@45344
   358
    val ty_decl = Logic.unvarifyT_global (const_typ thy c);
haftmann@31156
   359
    fun last_typ c_ty ty =
haftmann@31156
   360
      let
haftmann@33531
   361
        val tfrees = Term.add_tfreesT ty [];
wenzelm@40844
   362
        val (tyco, vs) = (apsnd o map) dest_TFree (dest_Type (body_type ty))
haftmann@35226
   363
          handle TYPE _ => no_constr thy "bad type" c_ty
haftmann@36112
   364
        val _ = if tyco = "fun" then no_constr thy "bad type" c_ty else ();
wenzelm@45344
   365
        val _ =
wenzelm@45344
   366
          if has_duplicates (eq_fst (op =)) vs
haftmann@35226
   367
          then no_constr thy "duplicate type variables in datatype" c_ty else ();
wenzelm@45344
   368
        val _ =
wenzelm@45344
   369
          if length tfrees <> length vs
haftmann@35226
   370
          then no_constr thy "type variables missing in datatype" c_ty else ();
haftmann@31156
   371
      in (tyco, vs) end;
haftmann@35226
   372
    val (tyco, _) = last_typ (c, ty) ty_decl;
haftmann@35226
   373
    val (_, vs) = last_typ (c, ty) ty;
haftmann@35226
   374
  in ((tyco, map snd vs), (c, (map fst vs, ty))) end;
haftmann@35226
   375
haftmann@49904
   376
fun constrset_of_consts thy consts =
haftmann@35226
   377
  let
haftmann@35226
   378
    val _ = map (fn (c, _) => if (is_some o AxClass.class_of_param thy) c
haftmann@49904
   379
      then error ("Is a class parameter: " ^ string_of_const thy c) else ()) consts;
haftmann@49904
   380
    val raw_constructors = map (analyze_constructor thy) consts;
haftmann@49904
   381
    val tyco = case distinct (op =) (map (fst o fst) raw_constructors)
haftmann@49904
   382
     of [tyco] => tyco
haftmann@49904
   383
      | [] => error "Empty constructor set"
haftmann@49904
   384
      | tycos => error ("Different type constructors in constructor set: " ^ commas_quote tycos)
haftmann@49904
   385
    val vs = Name.invent Name.context Name.aT (Sign.arity_number thy tyco);
haftmann@31156
   386
    fun inst vs' (c, (vs, ty)) =
haftmann@31156
   387
      let
haftmann@31156
   388
        val the_v = the o AList.lookup (op =) (vs ~~ vs');
haftmann@49904
   389
        val ty' = map_type_tfree (fn (v, _) => TFree (the_v v, [])) ty;
haftmann@49904
   390
        val (vs'', ty'') = typscheme thy (c, ty');
haftmann@49904
   391
      in (c, (vs'', binder_types ty'')) end;
haftmann@49904
   392
    val constructors = map (inst vs o snd) raw_constructors;
haftmann@49904
   393
  in (tyco, (map (rpair []) vs, constructors)) end;
haftmann@31156
   394
haftmann@35299
   395
fun get_type_entry thy tyco = case these (Symtab.lookup ((the_types o the_exec) thy) tyco)
haftmann@35226
   396
 of (_, entry) :: _ => SOME entry
haftmann@35226
   397
  | _ => NONE;
haftmann@31962
   398
haftmann@40726
   399
fun get_type thy tyco = case get_type_entry thy tyco
haftmann@35226
   400
 of SOME (vs, spec) => apfst (pair vs) (constructors_of spec)
haftmann@45987
   401
  | NONE => Sign.arity_number thy tyco
wenzelm@43329
   402
      |> Name.invent Name.context Name.aT
haftmann@35226
   403
      |> map (rpair [])
haftmann@35226
   404
      |> rpair []
haftmann@35226
   405
      |> rpair false;
haftmann@35226
   406
haftmann@35299
   407
fun get_abstype_spec thy tyco = case get_type_entry thy tyco
haftmann@35226
   408
 of SOME (vs, Abstractor spec) => (vs, spec)
haftmann@36122
   409
  | _ => error ("Not an abstract type: " ^ tyco);
haftmann@35226
   410
 
haftmann@35299
   411
fun get_type_of_constr_or_abstr thy c =
wenzelm@40844
   412
  case (body_type o const_typ thy) c
haftmann@40758
   413
   of Type (tyco, _) => let val ((_, cos), abstract) = get_type thy tyco
haftmann@35226
   414
        in if member (op =) (map fst cos) c then SOME (tyco, abstract) else NONE end
haftmann@31962
   415
    | _ => NONE;
haftmann@31962
   416
haftmann@35299
   417
fun is_constr thy c = case get_type_of_constr_or_abstr thy c
haftmann@35226
   418
 of SOME (_, false) => true
haftmann@35226
   419
   | _ => false;
haftmann@35226
   420
haftmann@35299
   421
fun is_abstr thy c = case get_type_of_constr_or_abstr thy c
haftmann@35226
   422
 of SOME (_, true) => true
haftmann@35226
   423
   | _ => false;
haftmann@31962
   424
haftmann@31156
   425
haftmann@34874
   426
(* bare code equations *)
haftmann@31156
   427
haftmann@35226
   428
(* convention for variables:
haftmann@35226
   429
    ?x ?'a   for free-floating theorems (e.g. in the data store)
haftmann@35226
   430
    ?x  'a   for certificates
haftmann@35226
   431
     x  'a   for final representation of equations
haftmann@35226
   432
*)
haftmann@35226
   433
haftmann@31156
   434
exception BAD_THM of string;
haftmann@31156
   435
fun bad_thm msg = raise BAD_THM msg;
haftmann@49760
   436
fun error_thm f thy (thm, proper) = f (thm, proper)
haftmann@49760
   437
  handle BAD_THM msg => error (msg ^ ", in theorem:\n" ^ Display.string_of_thm_global thy thm);
haftmann@49760
   438
fun error_abs_thm f thy thm = f thm
haftmann@49760
   439
  handle BAD_THM msg => error (msg ^ ", in theorem:\n" ^ Display.string_of_thm_global thy thm);
haftmann@49760
   440
fun warning_thm f thy (thm, proper) = SOME (f (thm, proper))
haftmann@49760
   441
  handle BAD_THM msg => (warning (msg ^ ", in theorem:\n" ^ Display.string_of_thm_global thy thm); NONE)
haftmann@49760
   442
fun try_thm f thm_proper = SOME (f thm_proper)
haftmann@49760
   443
  handle BAD_THM _ => NONE;
haftmann@31156
   444
haftmann@31156
   445
fun is_linear thm =
haftmann@31156
   446
  let val (_, args) = (strip_comb o fst o Logic.dest_equals o Thm.plain_prop_of) thm
haftmann@31156
   447
  in not (has_duplicates (op =) ((fold o fold_aterms)
haftmann@31156
   448
    (fn Var (v, _) => cons v | _ => I) args [])) end;
haftmann@31156
   449
haftmann@36209
   450
fun check_decl_ty thy (c, ty) =
haftmann@36209
   451
  let
haftmann@36209
   452
    val ty_decl = Sign.the_const_type thy c;
haftmann@49534
   453
  in if typscheme_equiv (ty_decl, ty) then ()
haftmann@36209
   454
    else bad_thm ("Type\n" ^ string_of_typ thy ty
haftmann@36209
   455
      ^ "\nof constant " ^ quote c
haftmann@40362
   456
      ^ "\nis too specific compared to declared type\n"
haftmann@36209
   457
      ^ string_of_typ thy ty_decl)
haftmann@36209
   458
  end; 
haftmann@36209
   459
haftmann@35226
   460
fun check_eqn thy { allow_nonlinear, allow_consts, allow_pats } thm (lhs, rhs) =
haftmann@31156
   461
  let
haftmann@31156
   462
    fun vars_of t = fold_aterms (fn Var (v, _) => insert (op =) v
haftmann@49760
   463
      | Free _ => bad_thm "Illegal free variable"
haftmann@31156
   464
      | _ => I) t [];
haftmann@31156
   465
    fun tvars_of t = fold_term_types (fn _ =>
haftmann@31156
   466
      fold_atyps (fn TVar (v, _) => insert (op =) v
haftmann@49760
   467
        | TFree _ => bad_thm "Illegal free type variable")) t [];
haftmann@31156
   468
    val lhs_vs = vars_of lhs;
haftmann@31156
   469
    val rhs_vs = vars_of rhs;
haftmann@31156
   470
    val lhs_tvs = tvars_of lhs;
haftmann@31156
   471
    val rhs_tvs = tvars_of rhs;
haftmann@31156
   472
    val _ = if null (subtract (op =) lhs_vs rhs_vs)
haftmann@31156
   473
      then ()
haftmann@49760
   474
      else bad_thm "Free variables on right hand side of equation";
haftmann@31156
   475
    val _ = if null (subtract (op =) lhs_tvs rhs_tvs)
haftmann@31156
   476
      then ()
haftmann@49760
   477
      else bad_thm "Free type variables on right hand side of equation";
haftmann@34894
   478
    val (head, args) = strip_comb lhs;
haftmann@31156
   479
    val (c, ty) = case head
haftmann@31156
   480
     of Const (c_ty as (_, ty)) => (AxClass.unoverload_const thy c_ty, ty)
haftmann@49760
   481
      | _ => bad_thm "Equation not headed by constant";
haftmann@49760
   482
    fun check _ (Abs _) = bad_thm "Abstraction on left hand side of equation"
haftmann@31156
   483
      | check 0 (Var _) = ()
haftmann@49760
   484
      | check _ (Var _) = bad_thm "Variable with application on left hand side of equation"
haftmann@31156
   485
      | check n (t1 $ t2) = (check (n+1) t1; check 0 t2)
haftmann@34894
   486
      | check n (Const (c_ty as (c, ty))) =
haftmann@35226
   487
          if allow_pats then let
haftmann@33940
   488
            val c' = AxClass.unoverload_const thy c_ty
haftmann@45987
   489
          in if n = (length o binder_types) ty
haftmann@35226
   490
            then if allow_consts orelse is_constr thy c'
haftmann@33940
   491
              then ()
haftmann@49760
   492
              else bad_thm (quote c ^ " is not a constructor, on left hand side of equation")
haftmann@49760
   493
            else bad_thm ("Partially applied constant " ^ quote c ^ " on left hand side of equation")
haftmann@49760
   494
          end else bad_thm ("Pattern not allowed here, but constant " ^ quote c ^ " encountered on left hand side of equation")
haftmann@31156
   495
    val _ = map (check 0) args;
haftmann@35226
   496
    val _ = if allow_nonlinear orelse is_linear thm then ()
haftmann@49760
   497
      else bad_thm "Duplicate variables on left hand side of equation";
haftmann@34894
   498
    val _ = if (is_none o AxClass.class_of_param thy) c then ()
haftmann@49760
   499
      else bad_thm "Overloaded constant as head in equation";
haftmann@34894
   500
    val _ = if not (is_constr thy c) then ()
haftmann@49760
   501
      else bad_thm "Constructor as head in equation";
haftmann@35226
   502
    val _ = if not (is_abstr thy c) then ()
haftmann@49760
   503
      else bad_thm "Abstractor as head in equation";
haftmann@36209
   504
    val _ = check_decl_ty thy (c, ty);
haftmann@35226
   505
  in () end;
haftmann@35226
   506
haftmann@35226
   507
fun gen_assert_eqn thy check_patterns (thm, proper) =
haftmann@35226
   508
  let
haftmann@35226
   509
    val (lhs, rhs) = (Logic.dest_equals o Thm.plain_prop_of) thm
haftmann@49760
   510
      handle TERM _ => bad_thm "Not an equation"
haftmann@49760
   511
           | THM _ => bad_thm "Not a proper equation";
haftmann@35226
   512
    val _ = check_eqn thy { allow_nonlinear = not proper,
haftmann@35226
   513
      allow_consts = not (proper andalso check_patterns), allow_pats = true } thm (lhs, rhs);
haftmann@31156
   514
  in (thm, proper) end;
haftmann@31156
   515
haftmann@35226
   516
fun assert_abs_eqn thy some_tyco thm =
haftmann@35226
   517
  let
haftmann@35226
   518
    val (full_lhs, rhs) = (Logic.dest_equals o Thm.plain_prop_of) thm
haftmann@49760
   519
      handle TERM _ => bad_thm "Not an equation"
haftmann@49760
   520
           | THM _ => bad_thm "Not a proper equation";
haftmann@35226
   521
    val (rep, lhs) = dest_comb full_lhs
haftmann@49760
   522
      handle TERM _ => bad_thm "Not an abstract equation";
haftmann@46513
   523
    val (rep_const, ty) = dest_Const rep
haftmann@49760
   524
      handle TERM _ => bad_thm "Not an abstract equation";
haftmann@40187
   525
    val (tyco, Ts) = (dest_Type o domain_type) ty
haftmann@49760
   526
      handle TERM _ => bad_thm "Not an abstract equation"
haftmann@49760
   527
           | TYPE _ => bad_thm "Not an abstract equation";
haftmann@35226
   528
    val _ = case some_tyco of SOME tyco' => if tyco = tyco' then ()
haftmann@49760
   529
          else bad_thm ("Abstract type mismatch:" ^ quote tyco ^ " vs. " ^ quote tyco')
haftmann@35226
   530
      | NONE => ();
haftmann@36202
   531
    val (vs', (_, (rep', _))) = get_abstype_spec thy tyco;
haftmann@35226
   532
    val _ = if rep_const = rep' then ()
haftmann@49760
   533
      else bad_thm ("Projection mismatch: " ^ quote rep_const ^ " vs. " ^ quote rep');
haftmann@35226
   534
    val _ = check_eqn thy { allow_nonlinear = false,
haftmann@35226
   535
      allow_consts = false, allow_pats = false } thm (lhs, rhs);
haftmann@40564
   536
    val _ = if forall2 (fn T => fn (_, sort) => Sign.of_sort thy (T, sort)) Ts vs' then ()
haftmann@40187
   537
      else error ("Type arguments do not satisfy sort constraints of abstype certificate.");
haftmann@35226
   538
  in (thm, tyco) end;
haftmann@35226
   539
haftmann@49760
   540
fun assert_eqn thy = error_thm (gen_assert_eqn thy true) thy;
haftmann@31962
   541
wenzelm@42360
   542
fun meta_rewrite thy = Local_Defs.meta_rewrite_rule (Proof_Context.init_global thy);
haftmann@31156
   543
haftmann@49760
   544
fun mk_eqn thy = error_thm (gen_assert_eqn thy false) thy o
haftmann@31962
   545
  apfst (meta_rewrite thy);
haftmann@31962
   546
haftmann@31962
   547
fun mk_eqn_warning thy = Option.map (fn (thm, _) => (thm, is_linear thm))
haftmann@49760
   548
  o warning_thm (gen_assert_eqn thy false) thy o rpair false o meta_rewrite thy;
haftmann@31962
   549
haftmann@31962
   550
fun mk_eqn_liberal thy = Option.map (fn (thm, _) => (thm, is_linear thm))
haftmann@34894
   551
  o try_thm (gen_assert_eqn thy false) o rpair false o meta_rewrite thy;
haftmann@31156
   552
haftmann@49760
   553
fun mk_abs_eqn thy = error_abs_thm (assert_abs_eqn thy NONE) thy o meta_rewrite thy;
haftmann@35226
   554
haftmann@33940
   555
val head_eqn = dest_Const o fst o strip_comb o fst o Logic.dest_equals o Thm.plain_prop_of;
haftmann@31156
   556
haftmann@31957
   557
fun const_typ_eqn thy thm =
haftmann@31156
   558
  let
haftmann@32640
   559
    val (c, ty) = head_eqn thm;
haftmann@31156
   560
    val c' = AxClass.unoverload_const thy (c, ty);
haftmann@33940
   561
      (*permissive wrt. to overloaded constants!*)
haftmann@31156
   562
  in (c', ty) end;
haftmann@33940
   563
haftmann@31957
   564
fun const_eqn thy = fst o const_typ_eqn thy;
haftmann@31156
   565
haftmann@35226
   566
fun const_abs_eqn thy = AxClass.unoverload_const thy o dest_Const o fst o strip_comb o snd
haftmann@35226
   567
  o dest_comb o fst o Logic.dest_equals o Thm.plain_prop_of;
haftmann@35226
   568
haftmann@35226
   569
fun mk_proj tyco vs ty abs rep =
haftmann@35226
   570
  let
haftmann@35226
   571
    val ty_abs = Type (tyco, map TFree vs);
haftmann@35226
   572
    val xarg = Var (("x", 0), ty);
haftmann@35226
   573
  in Logic.mk_equals (Const (rep, ty_abs --> ty) $ (Const (abs, ty --> ty_abs) $ xarg), xarg) end;
haftmann@35226
   574
haftmann@34895
   575
haftmann@34895
   576
(* technical transformations of code equations *)
haftmann@34895
   577
haftmann@34895
   578
fun expand_eta thy k thm =
haftmann@34895
   579
  let
haftmann@34895
   580
    val (lhs, rhs) = (Logic.dest_equals o Thm.plain_prop_of) thm;
haftmann@34895
   581
    val (_, args) = strip_comb lhs;
haftmann@34895
   582
    val l = if k = ~1
haftmann@34895
   583
      then (length o fst o strip_abs) rhs
haftmann@34895
   584
      else Int.max (0, k - length args);
haftmann@34895
   585
    val (raw_vars, _) = Term.strip_abs_eta l rhs;
haftmann@34895
   586
    val vars = burrow_fst (Name.variant_list (map (fst o fst) (Term.add_vars lhs [])))
haftmann@34895
   587
      raw_vars;
haftmann@34895
   588
    fun expand (v, ty) thm = Drule.fun_cong_rule thm
haftmann@34895
   589
      (Thm.cterm_of thy (Var ((v, 0), ty)));
haftmann@34895
   590
  in
haftmann@34895
   591
    thm
haftmann@34895
   592
    |> fold expand vars
haftmann@34895
   593
    |> Conv.fconv_rule Drule.beta_eta_conversion
haftmann@34895
   594
  end;
haftmann@34895
   595
haftmann@34895
   596
fun same_arity thy thms =
haftmann@31962
   597
  let
haftmann@34895
   598
    val num_args_of = length o snd o strip_comb o fst o Logic.dest_equals;
haftmann@34895
   599
    val k = fold (Integer.max o num_args_of o Thm.prop_of) thms 0;
haftmann@34895
   600
  in map (expand_eta thy k) thms end;
haftmann@34895
   601
haftmann@34895
   602
fun mk_desymbolization pre post mk vs =
haftmann@34895
   603
  let
haftmann@34895
   604
    val names = map (pre o fst o fst) vs
haftmann@34895
   605
      |> map (Name.desymbolize false)
haftmann@34895
   606
      |> Name.variant_list []
haftmann@34895
   607
      |> map post;
haftmann@34895
   608
  in map_filter (fn (((v, i), x), v') =>
haftmann@34895
   609
    if v = v' andalso i = 0 then NONE
haftmann@34895
   610
    else SOME (((v, i), x), mk ((v', 0), x))) (vs ~~ names)
haftmann@34895
   611
  end;
haftmann@34895
   612
haftmann@40758
   613
fun desymbolize_tvars thms =
haftmann@34895
   614
  let
haftmann@34895
   615
    val tvs = fold (Term.add_tvars o Thm.prop_of) thms [];
haftmann@34895
   616
    val tvar_subst = mk_desymbolization (unprefix "'") (prefix "'") TVar tvs;
haftmann@34895
   617
  in map (Thm.certify_instantiate (tvar_subst, [])) thms end;
haftmann@34895
   618
haftmann@40758
   619
fun desymbolize_vars thm =
haftmann@34895
   620
  let
haftmann@34895
   621
    val vs = Term.add_vars (Thm.prop_of thm) [];
haftmann@34895
   622
    val var_subst = mk_desymbolization I I Var vs;
haftmann@34895
   623
  in Thm.certify_instantiate ([], var_subst) thm end;
haftmann@34895
   624
haftmann@40758
   625
fun canonize_thms thy = desymbolize_tvars #> same_arity thy #> map desymbolize_vars;
haftmann@31156
   626
haftmann@34874
   627
haftmann@36112
   628
(* abstype certificates *)
haftmann@36112
   629
haftmann@36112
   630
fun check_abstype_cert thy proto_thm =
haftmann@36112
   631
  let
haftmann@36209
   632
    val thm = (AxClass.unoverload thy o meta_rewrite thy) proto_thm;
haftmann@36112
   633
    val (lhs, rhs) = Logic.dest_equals (Thm.plain_prop_of thm)
haftmann@49760
   634
      handle TERM _ => bad_thm "Not an equation"
haftmann@49760
   635
           | THM _ => bad_thm "Not a proper equation";
haftmann@36209
   636
    val ((abs, raw_ty), ((rep, rep_ty), param)) = (apsnd (apfst dest_Const o dest_comb)
haftmann@36112
   637
        o apfst dest_Const o dest_comb) lhs
haftmann@49760
   638
      handle TERM _ => bad_thm "Not an abstype certificate";
haftmann@36209
   639
    val _ = pairself (fn c => if (is_some o AxClass.class_of_param thy) c
haftmann@36209
   640
      then error ("Is a class parameter: " ^ string_of_const thy c) else ()) (abs, rep);
haftmann@36209
   641
    val _ = check_decl_ty thy (abs, raw_ty);
haftmann@36209
   642
    val _ = check_decl_ty thy (rep, rep_ty);
haftmann@48068
   643
    val _ = if length (binder_types raw_ty) = 1
haftmann@48068
   644
      then ()
haftmann@49760
   645
      else bad_thm "Bad type for abstract constructor";
haftmann@40758
   646
    val _ = (fst o dest_Var) param
haftmann@49760
   647
      handle TERM _ => bad_thm "Not an abstype certificate";
haftmann@49760
   648
    val _ = if param = rhs then () else bad_thm "Not an abstype certificate";
wenzelm@45344
   649
    val ((tyco, sorts), (abs, (vs, ty'))) =
wenzelm@45344
   650
      analyze_constructor thy (abs, Logic.unvarifyT_global raw_ty);
haftmann@36112
   651
    val ty = domain_type ty';
haftmann@49534
   652
    val (vs', _) = typscheme thy (abs, ty');
haftmann@40726
   653
  in (tyco, (vs ~~ sorts, ((abs, (vs', ty)), (rep, thm)))) end;
haftmann@36112
   654
haftmann@36112
   655
haftmann@34874
   656
(* code equation certificates *)
haftmann@34874
   657
haftmann@34895
   658
fun build_head thy (c, ty) =
haftmann@34895
   659
  Thm.cterm_of thy (Logic.mk_equals (Free ("HEAD", ty), Const (c, ty)));
haftmann@34874
   660
haftmann@34895
   661
fun get_head thy cert_thm =
haftmann@34895
   662
  let
haftmann@34895
   663
    val [head] = (#hyps o Thm.crep_thm) cert_thm;
haftmann@34895
   664
    val (_, Const (c, ty)) = (Logic.dest_equals o Thm.term_of) head;
haftmann@34895
   665
  in (typscheme thy (c, ty), head) end;
haftmann@34895
   666
haftmann@35226
   667
fun typscheme_projection thy =
haftmann@35226
   668
  typscheme thy o dest_Const o fst o dest_comb o fst o Logic.dest_equals;
haftmann@35226
   669
haftmann@35226
   670
fun typscheme_abs thy =
haftmann@35226
   671
  typscheme thy o dest_Const o fst o strip_comb o snd o dest_comb o fst o Logic.dest_equals o Thm.prop_of;
haftmann@35226
   672
haftmann@35226
   673
fun constrain_thm thy vs sorts thm =
haftmann@35226
   674
  let
haftmann@35226
   675
    val mapping = map2 (fn (v, sort) => fn sort' =>
haftmann@35226
   676
      (v, Sorts.inter_sort (Sign.classes_of thy) (sort, sort'))) vs sorts;
haftmann@35226
   677
    val inst = map2 (fn (v, sort) => fn (_, sort') =>
haftmann@35226
   678
      (((v, 0), sort), TFree (v, sort'))) vs mapping;
haftmann@40803
   679
    val subst = (map_types o map_type_tfree)
haftmann@40803
   680
      (fn (v, _) => TFree (v, the (AList.lookup (op =) mapping v)));
haftmann@35226
   681
  in
haftmann@35226
   682
    thm
wenzelm@35845
   683
    |> Thm.varifyT_global
haftmann@35226
   684
    |> Thm.certify_instantiate (inst, [])
haftmann@35226
   685
    |> pair subst
haftmann@35226
   686
  end;
haftmann@35226
   687
haftmann@35226
   688
fun concretify_abs thy tyco abs_thm =
haftmann@35226
   689
  let
haftmann@40758
   690
    val (_, ((c, _), (_, cert))) = get_abstype_spec thy tyco;
haftmann@35226
   691
    val lhs = (fst o Logic.dest_equals o Thm.prop_of) abs_thm
haftmann@35226
   692
    val ty = fastype_of lhs;
haftmann@35226
   693
    val ty_abs = (fastype_of o snd o dest_comb) lhs;
haftmann@35226
   694
    val abs = Thm.cterm_of thy (Const (c, ty --> ty_abs));
haftmann@35226
   695
    val raw_concrete_thm = Drule.transitive_thm OF [Thm.symmetric cert, Thm.combination (Thm.reflexive abs) abs_thm];
wenzelm@35845
   696
  in (c, (Thm.varifyT_global o zero_var_indexes) raw_concrete_thm) end;
haftmann@35226
   697
haftmann@35226
   698
fun add_rhss_of_eqn thy t =
haftmann@35226
   699
  let
haftmann@45987
   700
    val (args, rhs) = (apfst (snd o strip_comb) o Logic.dest_equals) t;
haftmann@35226
   701
    fun add_const (Const (c, ty)) = insert (op =) (c, Sign.const_typargs thy (c, ty))
haftmann@35226
   702
      | add_const _ = I
haftmann@39568
   703
    val add_consts = fold_aterms add_const
haftmann@39568
   704
  in add_consts rhs o fold add_consts args end;
haftmann@35226
   705
haftmann@46513
   706
val dest_eqn = apfst (snd o strip_comb) o Logic.dest_equals o Logic.unvarify_global;
haftmann@35226
   707
haftmann@35226
   708
abstype cert = Equations of thm * bool list
haftmann@35226
   709
  | Projection of term * string
haftmann@35226
   710
  | Abstract of thm * string
haftmann@35226
   711
with
haftmann@34891
   712
haftmann@34891
   713
fun empty_cert thy c = 
haftmann@34891
   714
  let
haftmann@40761
   715
    val raw_ty = Logic.unvarifyT_global (const_typ thy c);
haftmann@49534
   716
    val (vs, _) = typscheme thy (c, raw_ty);
haftmann@40761
   717
    val sortargs = case AxClass.class_of_param thy c
haftmann@40761
   718
     of SOME class => [[class]]
haftmann@40761
   719
      | NONE => (case get_type_of_constr_or_abstr thy c
haftmann@40761
   720
         of SOME (tyco, _) => (map snd o fst o the)
haftmann@40761
   721
              (AList.lookup (op =) ((snd o fst o get_type thy) tyco) c)
haftmann@40761
   722
          | NONE => replicate (length vs) []);
haftmann@40761
   723
    val the_sort = the o AList.lookup (op =) (map fst vs ~~ sortargs);
haftmann@40761
   724
    val ty = map_type_tfree (fn (v, _) => TFree (v, the_sort v)) raw_ty
haftmann@34895
   725
    val chead = build_head thy (c, ty);
haftmann@35226
   726
  in Equations (Thm.weaken chead Drule.dummy_thm, []) end;
haftmann@34891
   727
haftmann@34891
   728
fun cert_of_eqns thy c [] = empty_cert thy c
haftmann@34895
   729
  | cert_of_eqns thy c raw_eqns = 
haftmann@34874
   730
      let
haftmann@34895
   731
        val eqns = burrow_fst (canonize_thms thy) raw_eqns;
haftmann@34895
   732
        val _ = map (assert_eqn thy) eqns;
haftmann@34891
   733
        val (thms, propers) = split_list eqns;
haftmann@34895
   734
        val _ = map (fn thm => if c = const_eqn thy thm then ()
haftmann@34895
   735
          else error ("Wrong head of code equation,\nexpected constant "
haftmann@34895
   736
            ^ string_of_const thy c ^ "\n" ^ Display.string_of_thm_global thy thm)) thms;
haftmann@34891
   737
        fun tvars_of T = rev (Term.add_tvarsT T []);
haftmann@34891
   738
        val vss = map (tvars_of o snd o head_eqn) thms;
haftmann@34891
   739
        fun inter_sorts vs =
haftmann@34891
   740
          fold (curry (Sorts.inter_sort (Sign.classes_of thy)) o snd) vs [];
haftmann@34891
   741
        val sorts = map_transpose inter_sorts vss;
wenzelm@43329
   742
        val vts = Name.invent_names Name.context Name.aT sorts;
haftmann@40758
   743
        val thms' =
haftmann@34891
   744
          map2 (fn vs => Thm.certify_instantiate (vs ~~ map TFree vts, [])) vss thms;
haftmann@40758
   745
        val head_thm = Thm.symmetric (Thm.assume (build_head thy (head_eqn (hd thms'))));
haftmann@34874
   746
        fun head_conv ct = if can Thm.dest_comb ct
haftmann@34874
   747
          then Conv.fun_conv head_conv ct
haftmann@34874
   748
          else Conv.rewr_conv head_thm ct;
haftmann@34874
   749
        val rewrite_head = Conv.fconv_rule (Conv.arg1_conv head_conv);
haftmann@40758
   750
        val cert_thm = Conjunction.intr_balanced (map rewrite_head thms');
haftmann@35226
   751
      in Equations (cert_thm, propers) end;
haftmann@34891
   752
haftmann@35226
   753
fun cert_of_proj thy c tyco =
haftmann@35226
   754
  let
haftmann@40758
   755
    val (vs, ((abs, (_, ty)), (rep, _))) = get_abstype_spec thy tyco;
haftmann@35226
   756
    val _ = if c = rep then () else
haftmann@35226
   757
      error ("Wrong head of projection,\nexpected constant " ^ string_of_const thy rep);
haftmann@35226
   758
  in Projection (mk_proj tyco vs ty abs rep, tyco) end;
haftmann@35226
   759
haftmann@35226
   760
fun cert_of_abs thy tyco c raw_abs_thm =
haftmann@34874
   761
  let
haftmann@35226
   762
    val abs_thm = singleton (canonize_thms thy) raw_abs_thm;
haftmann@35226
   763
    val _ = assert_abs_eqn thy (SOME tyco) abs_thm;
haftmann@35226
   764
    val _ = if c = const_abs_eqn thy abs_thm then ()
haftmann@35226
   765
      else error ("Wrong head of abstract code equation,\nexpected constant "
haftmann@35226
   766
        ^ string_of_const thy c ^ "\n" ^ Display.string_of_thm_global thy abs_thm);
wenzelm@36615
   767
  in Abstract (Thm.legacy_freezeT abs_thm, tyco) end;
haftmann@34874
   768
haftmann@35226
   769
fun constrain_cert thy sorts (Equations (cert_thm, propers)) =
haftmann@35226
   770
      let
haftmann@35226
   771
        val ((vs, _), head) = get_head thy cert_thm;
haftmann@35226
   772
        val (subst, cert_thm') = cert_thm
haftmann@35226
   773
          |> Thm.implies_intr head
haftmann@35226
   774
          |> constrain_thm thy vs sorts;
haftmann@35226
   775
        val head' = Thm.term_of head
haftmann@35226
   776
          |> subst
haftmann@35226
   777
          |> Thm.cterm_of thy;
haftmann@35226
   778
        val cert_thm'' = cert_thm'
haftmann@35226
   779
          |> Thm.elim_implies (Thm.assume head');
haftmann@35226
   780
      in Equations (cert_thm'', propers) end
haftmann@35226
   781
  | constrain_cert thy _ (cert as Projection _) =
haftmann@35226
   782
      cert
haftmann@35226
   783
  | constrain_cert thy sorts (Abstract (abs_thm, tyco)) =
haftmann@35226
   784
      Abstract (snd (constrain_thm thy (fst (typscheme_abs thy abs_thm)) sorts abs_thm), tyco);
haftmann@35226
   785
haftmann@49971
   786
fun conclude_cert (Equations (cert_thm, propers)) =
haftmann@49971
   787
      (Equations (Thm.close_derivation cert_thm, propers))
haftmann@49971
   788
  | conclude_cert (cert as Projection _) =
haftmann@49971
   789
      cert
haftmann@49971
   790
  | conclude_cert (Abstract (abs_thm, tyco)) =
haftmann@49971
   791
      (Abstract (Thm.close_derivation abs_thm, tyco));
haftmann@49971
   792
haftmann@35226
   793
fun typscheme_of_cert thy (Equations (cert_thm, _)) =
haftmann@35226
   794
      fst (get_head thy cert_thm)
haftmann@35226
   795
  | typscheme_of_cert thy (Projection (proj, _)) =
haftmann@35226
   796
      typscheme_projection thy proj
haftmann@35226
   797
  | typscheme_of_cert thy (Abstract (abs_thm, _)) =
haftmann@35226
   798
      typscheme_abs thy abs_thm;
haftmann@34874
   799
haftmann@35226
   800
fun typargs_deps_of_cert thy (Equations (cert_thm, propers)) =
haftmann@35226
   801
      let
haftmann@35226
   802
        val vs = (fst o fst) (get_head thy cert_thm);
haftmann@35226
   803
        val equations = if null propers then [] else
haftmann@35226
   804
          Thm.prop_of cert_thm
haftmann@35226
   805
          |> Logic.dest_conjunction_balanced (length propers);
haftmann@35226
   806
      in (vs, fold (add_rhss_of_eqn thy) equations []) end
haftmann@40758
   807
  | typargs_deps_of_cert thy (Projection (t, _)) =
haftmann@35226
   808
      (fst (typscheme_projection thy t), add_rhss_of_eqn thy t [])
haftmann@35226
   809
  | typargs_deps_of_cert thy (Abstract (abs_thm, tyco)) =
haftmann@35226
   810
      let
haftmann@35226
   811
        val vs = fst (typscheme_abs thy abs_thm);
haftmann@35226
   812
        val (_, concrete_thm) = concretify_abs thy tyco abs_thm;
wenzelm@45344
   813
      in (vs, add_rhss_of_eqn thy (Logic.unvarify_types_global (Thm.prop_of concrete_thm)) []) end;
haftmann@34895
   814
haftmann@35226
   815
fun equations_of_cert thy (cert as Equations (cert_thm, propers)) =
haftmann@35226
   816
      let
haftmann@35226
   817
        val tyscm = typscheme_of_cert thy cert;
haftmann@35226
   818
        val thms = if null propers then [] else
haftmann@35226
   819
          cert_thm
wenzelm@35624
   820
          |> Local_Defs.expand [snd (get_head thy cert_thm)]
wenzelm@35845
   821
          |> Thm.varifyT_global
haftmann@35226
   822
          |> Conjunction.elim_balanced (length propers);
haftmann@36209
   823
        fun abstractions (args, rhs) = (map (rpair NONE) args, (rhs, NONE));
haftmann@46513
   824
      in (tyscm, map (abstractions o dest_eqn o Thm.prop_of) thms ~~ (map SOME thms ~~ propers)) end
haftmann@35226
   825
  | equations_of_cert thy (Projection (t, tyco)) =
haftmann@35226
   826
      let
haftmann@35226
   827
        val (_, ((abs, _), _)) = get_abstype_spec thy tyco;
haftmann@35226
   828
        val tyscm = typscheme_projection thy t;
wenzelm@45344
   829
        val t' = Logic.varify_types_global t;
haftmann@36209
   830
        fun abstractions (args, rhs) = (map (rpair (SOME abs)) args, (rhs, NONE));
haftmann@46513
   831
      in (tyscm, [((abstractions o dest_eqn) t', (NONE, true))]) end
haftmann@35226
   832
  | equations_of_cert thy (Abstract (abs_thm, tyco)) =
haftmann@35226
   833
      let
haftmann@35226
   834
        val tyscm = typscheme_abs thy abs_thm;
haftmann@35226
   835
        val (abs, concrete_thm) = concretify_abs thy tyco abs_thm;
haftmann@36209
   836
        fun abstractions (args, rhs) = (map (rpair NONE) args, (rhs, (SOME abs)));
wenzelm@35845
   837
      in
haftmann@46513
   838
        (tyscm, [((abstractions o dest_eqn o Thm.prop_of) concrete_thm,
haftmann@36209
   839
          (SOME (Thm.varifyT_global abs_thm), true))])
wenzelm@35845
   840
      end;
haftmann@34895
   841
haftmann@35226
   842
fun pretty_cert thy (cert as Equations _) =
haftmann@35226
   843
      (map_filter (Option.map (Display.pretty_thm_global thy o AxClass.overload thy) o fst o snd)
haftmann@35226
   844
         o snd o equations_of_cert thy) cert
haftmann@35226
   845
  | pretty_cert thy (Projection (t, _)) =
wenzelm@45344
   846
      [Syntax.pretty_term_global thy (Logic.varify_types_global t)]
haftmann@40758
   847
  | pretty_cert thy (Abstract (abs_thm, _)) =
wenzelm@35845
   848
      [(Display.pretty_thm_global thy o AxClass.overload thy o Thm.varifyT_global) abs_thm];
haftmann@35226
   849
haftmann@35226
   850
fun bare_thms_of_cert thy (cert as Equations _) =
haftmann@35226
   851
      (map_filter (fn (_, (some_thm, proper)) => if proper then some_thm else NONE)
haftmann@35226
   852
        o snd o equations_of_cert thy) cert
haftmann@35376
   853
  | bare_thms_of_cert thy (Projection _) = []
haftmann@35376
   854
  | bare_thms_of_cert thy (Abstract (abs_thm, tyco)) =
wenzelm@35845
   855
      [Thm.varifyT_global (snd (concretify_abs thy tyco abs_thm))];
haftmann@34895
   856
haftmann@34895
   857
end;
haftmann@34891
   858
haftmann@34874
   859
haftmann@35226
   860
(* code certificate access *)
haftmann@35226
   861
haftmann@35226
   862
fun retrieve_raw thy c =
haftmann@35226
   863
  Symtab.lookup ((the_functions o the_exec) thy) c
haftmann@35226
   864
  |> Option.map (snd o fst)
haftmann@37460
   865
  |> the_default empty_fun_spec
haftmann@34874
   866
haftmann@48075
   867
fun eqn_conv conv ct =
haftmann@48075
   868
  let
haftmann@48075
   869
    fun lhs_conv ct = if can Thm.dest_comb ct
haftmann@48075
   870
      then Conv.combination_conv lhs_conv conv ct
haftmann@48075
   871
      else Conv.all_conv ct;
haftmann@48075
   872
  in Conv.combination_conv (Conv.arg_conv lhs_conv) conv ct end;
haftmann@48075
   873
haftmann@48075
   874
fun rewrite_eqn thy conv ss =
haftmann@48075
   875
  let
haftmann@48075
   876
    val ctxt = Proof_Context.init_global thy;
haftmann@48075
   877
    val rewrite = Conv.fconv_rule (conv (Simplifier.rewrite ss));
haftmann@48075
   878
  in singleton (Variable.trade (K (map rewrite)) ctxt) end;
haftmann@48075
   879
haftmann@48075
   880
fun cert_of_eqns_preprocess thy functrans ss c =
haftmann@48075
   881
  (map o apfst) (Thm.transfer thy)
haftmann@48075
   882
  #> perhaps (perhaps_loop (perhaps_apply functrans))
haftmann@48075
   883
  #> (map o apfst) (rewrite_eqn thy eqn_conv ss) 
haftmann@48075
   884
  #> (map o apfst) (AxClass.unoverload thy)
haftmann@48075
   885
  #> cert_of_eqns thy c;
haftmann@48075
   886
haftmann@48075
   887
fun get_cert thy { functrans, ss } c =
haftmann@48075
   888
  case retrieve_raw thy c
haftmann@48075
   889
   of Default (_, eqns_lazy) => Lazy.force eqns_lazy
haftmann@48075
   890
        |> cert_of_eqns_preprocess thy functrans ss c
haftmann@48075
   891
    | Eqns eqns => eqns
haftmann@48075
   892
        |> cert_of_eqns_preprocess thy functrans ss c
haftmann@48075
   893
    | Proj (_, tyco) =>
haftmann@48075
   894
        cert_of_proj thy c tyco
haftmann@48075
   895
    | Abstr (abs_thm, tyco) => abs_thm
haftmann@48075
   896
        |> Thm.transfer thy
haftmann@48075
   897
        |> rewrite_eqn thy Conv.arg_conv ss
haftmann@48075
   898
        |> AxClass.unoverload thy
haftmann@48075
   899
        |> cert_of_abs thy tyco c;
haftmann@31962
   900
haftmann@31962
   901
haftmann@31962
   902
(* cases *)
haftmann@31156
   903
haftmann@31156
   904
fun case_certificate thm =
haftmann@31156
   905
  let
haftmann@31156
   906
    val ((head, raw_case_expr), cases) = (apfst Logic.dest_equals
haftmann@32640
   907
      o apsnd Logic.dest_conjunctions o Logic.dest_implies o Thm.plain_prop_of) thm;
haftmann@31156
   908
    val _ = case head of Free _ => true
haftmann@31156
   909
      | Var _ => true
haftmann@31156
   910
      | _ => raise TERM ("case_cert", []);
haftmann@31156
   911
    val ([(case_var, _)], case_expr) = Term.strip_abs_eta 1 raw_case_expr;
haftmann@31156
   912
    val (Const (case_const, _), raw_params) = strip_comb case_expr;
haftmann@31156
   913
    val n = find_index (fn Free (v, _) => v = case_var | _ => false) raw_params;
haftmann@31156
   914
    val _ = if n = ~1 then raise TERM ("case_cert", []) else ();
haftmann@31156
   915
    val params = map (fst o dest_Var) (nth_drop n raw_params);
haftmann@31156
   916
    fun dest_case t =
haftmann@31156
   917
      let
haftmann@31156
   918
        val (head' $ t_co, rhs) = Logic.dest_equals t;
haftmann@31156
   919
        val _ = if head' = head then () else raise TERM ("case_cert", []);
haftmann@31156
   920
        val (Const (co, _), args) = strip_comb t_co;
haftmann@31156
   921
        val (Var (param, _), args') = strip_comb rhs;
haftmann@31156
   922
        val _ = if args' = args then () else raise TERM ("case_cert", []);
haftmann@31156
   923
      in (param, co) end;
haftmann@31156
   924
    fun analyze_cases cases =
haftmann@31156
   925
      let
haftmann@31156
   926
        val co_list = fold (AList.update (op =) o dest_case) cases [];
Andreas@47437
   927
      in map (AList.lookup (op =) co_list) params end;
haftmann@31156
   928
    fun analyze_let t =
haftmann@31156
   929
      let
haftmann@31156
   930
        val (head' $ arg, Var (param', _) $ arg') = Logic.dest_equals t;
haftmann@31156
   931
        val _ = if head' = head then () else raise TERM ("case_cert", []);
haftmann@31156
   932
        val _ = if arg' = arg then () else raise TERM ("case_cert", []);
haftmann@31156
   933
        val _ = if [param'] = params then () else raise TERM ("case_cert", []);
haftmann@31156
   934
      in [] end;
haftmann@31156
   935
    fun analyze (cases as [let_case]) =
haftmann@31156
   936
          (analyze_cases cases handle Bind => analyze_let let_case)
haftmann@31156
   937
      | analyze cases = analyze_cases cases;
haftmann@31156
   938
  in (case_const, (n, analyze cases)) end;
haftmann@31156
   939
haftmann@31156
   940
fun case_cert thm = case_certificate thm
haftmann@31156
   941
  handle Bind => error "bad case certificate"
haftmann@31156
   942
       | TERM _ => error "bad case certificate";
haftmann@31156
   943
haftmann@37438
   944
fun get_case_scheme thy = Option.map fst o Symtab.lookup ((fst o the_cases o the_exec) thy);
haftmann@37438
   945
fun get_case_cong thy = Option.map snd o Symtab.lookup ((fst o the_cases o the_exec) thy);
haftmann@24219
   946
haftmann@31962
   947
val undefineds = Symtab.keys o snd o the_cases o the_exec;
haftmann@24219
   948
haftmann@24219
   949
haftmann@31962
   950
(* diagnostic *)
haftmann@24219
   951
haftmann@24219
   952
fun print_codesetup thy =
haftmann@24219
   953
  let
wenzelm@42360
   954
    val ctxt = Proof_Context.init_global thy;
haftmann@24844
   955
    val exec = the_exec thy;
haftmann@35226
   956
    fun pretty_equations const thms =
haftmann@24219
   957
      (Pretty.block o Pretty.fbreaks) (
wenzelm@51580
   958
        Pretty.str (string_of_const thy const) ::
wenzelm@51580
   959
          map (Pretty.item o single o Display.pretty_thm ctxt) thms
haftmann@24219
   960
      );
wenzelm@51580
   961
    fun pretty_function (const, Default (_, eqns_lazy)) =
wenzelm@51580
   962
          pretty_equations const (map fst (Lazy.force eqns_lazy))
haftmann@35226
   963
      | pretty_function (const, Eqns eqns) = pretty_equations const (map fst eqns)
haftmann@35226
   964
      | pretty_function (const, Proj (proj, _)) = Pretty.block
haftmann@35226
   965
          [Pretty.str (string_of_const thy const), Pretty.fbrk, Syntax.pretty_term ctxt proj]
haftmann@35226
   966
      | pretty_function (const, Abstr (thm, _)) = pretty_equations const [thm];
haftmann@35226
   967
    fun pretty_typ (tyco, vs) = Pretty.str
haftmann@35226
   968
      (string_of_typ thy (Type (tyco, map TFree vs)));
haftmann@35226
   969
    fun pretty_typspec (typ, (cos, abstract)) = if null cos
haftmann@35226
   970
      then pretty_typ typ
haftmann@35226
   971
      else (Pretty.block o Pretty.breaks) (
haftmann@35226
   972
        pretty_typ typ
haftmann@35226
   973
        :: Pretty.str "="
haftmann@35226
   974
        :: (if abstract then [Pretty.str "(abstract)"] else [])
haftmann@40726
   975
        @ separate (Pretty.str "|") (map (fn (c, (_, [])) => Pretty.str (string_of_const thy c)
haftmann@40726
   976
             | (c, (_, tys)) =>
haftmann@35226
   977
                 (Pretty.block o Pretty.breaks)
haftmann@35226
   978
                    (Pretty.str (string_of_const thy c)
haftmann@35226
   979
                      :: Pretty.str "of"
haftmann@35226
   980
                      :: map (Pretty.quote o Syntax.pretty_typ_global thy) tys)) cos)
haftmann@35226
   981
      );
haftmann@47555
   982
    fun pretty_caseparam NONE = "<ignored>"
haftmann@47555
   983
      | pretty_caseparam (SOME c) = string_of_const thy c
haftmann@37438
   984
    fun pretty_case (const, ((_, (_, [])), _)) = Pretty.str (string_of_const thy const)
haftmann@37438
   985
      | pretty_case (const, ((_, (_, cos)), _)) = (Pretty.block o Pretty.breaks) [
haftmann@34901
   986
          Pretty.str (string_of_const thy const), Pretty.str "with",
haftmann@47555
   987
          (Pretty.block o Pretty.commas o map (Pretty.str o pretty_caseparam)) cos];
haftmann@35226
   988
    val functions = the_functions exec
haftmann@24423
   989
      |> Symtab.dest
haftmann@28695
   990
      |> (map o apsnd) (snd o fst)
haftmann@24219
   991
      |> sort (string_ord o pairself fst);
haftmann@35299
   992
    val datatypes = the_types exec
haftmann@24219
   993
      |> Symtab.dest
haftmann@35226
   994
      |> map (fn (tyco, (_, (vs, spec)) :: _) =>
haftmann@35226
   995
          ((tyco, vs), constructors_of spec))
haftmann@35226
   996
      |> sort (string_ord o pairself (fst o fst));
haftmann@34901
   997
    val cases = Symtab.dest ((fst o the_cases o the_exec) thy);
haftmann@34901
   998
    val undefineds = Symtab.keys ((snd o the_cases o the_exec) thy);
haftmann@24219
   999
  in
haftmann@24219
  1000
    (Pretty.writeln o Pretty.chunks) [
haftmann@24219
  1001
      Pretty.block (
haftmann@34901
  1002
        Pretty.str "code equations:" :: Pretty.fbrk
haftmann@35226
  1003
        :: (Pretty.fbreaks o map pretty_function) functions
haftmann@24219
  1004
      ),
haftmann@25968
  1005
      Pretty.block (
haftmann@34901
  1006
        Pretty.str "datatypes:" :: Pretty.fbrk
haftmann@35226
  1007
        :: (Pretty.fbreaks o map pretty_typspec) datatypes
haftmann@34901
  1008
      ),
haftmann@34901
  1009
      Pretty.block (
haftmann@34901
  1010
        Pretty.str "cases:" :: Pretty.fbrk
haftmann@34901
  1011
        :: (Pretty.fbreaks o map pretty_case) cases
haftmann@34901
  1012
      ),
haftmann@34901
  1013
      Pretty.block (
haftmann@34901
  1014
        Pretty.str "undefined:" :: Pretty.fbrk
haftmann@34901
  1015
        :: (Pretty.commas o map (Pretty.str o string_of_const thy)) undefineds
haftmann@24219
  1016
      )
haftmann@24219
  1017
    ]
haftmann@24219
  1018
  end;
haftmann@24219
  1019
haftmann@24219
  1020
haftmann@31962
  1021
(** declaring executable ingredients **)
haftmann@31962
  1022
haftmann@31962
  1023
(* code equations *)
haftmann@31962
  1024
haftmann@35226
  1025
fun gen_add_eqn default (raw_thm, proper) thy =
haftmann@33075
  1026
  let
haftmann@35226
  1027
    val thm = Thm.close_derivation raw_thm;
haftmann@35226
  1028
    val c = const_eqn thy thm;
haftmann@37460
  1029
    fun update_subsume thy (thm, proper) eqns = 
haftmann@37460
  1030
      let
wenzelm@48902
  1031
        val args_of = snd o take_prefix is_Var o rev o snd o strip_comb
haftmann@39791
  1032
          o map_types Type.strip_sorts o fst o Logic.dest_equals o Thm.plain_prop_of;
haftmann@37460
  1033
        val args = args_of thm;
haftmann@37460
  1034
        val incr_idx = Logic.incr_indexes ([], Thm.maxidx_of thm + 1);
haftmann@39794
  1035
        fun matches_args args' =
haftmann@39794
  1036
          let
haftmann@39794
  1037
            val k = length args' - length args
haftmann@39794
  1038
          in if k >= 0
haftmann@39794
  1039
            then Pattern.matchess thy (args, (map incr_idx o drop k) args')
haftmann@39794
  1040
            else false
haftmann@39794
  1041
          end;
haftmann@37460
  1042
        fun drop (thm', proper') = if (proper orelse not proper')
haftmann@37460
  1043
          andalso matches_args (args_of thm') then 
haftmann@37460
  1044
            (warning ("Code generator: dropping subsumed code equation\n" ^
haftmann@37460
  1045
                Display.string_of_thm_global thy thm'); true)
haftmann@37460
  1046
          else false;
haftmann@37460
  1047
      in (thm, proper) :: filter_out drop eqns end;
haftmann@37460
  1048
    fun natural_order thy_ref eqns =
haftmann@37460
  1049
      (eqns, Lazy.lazy (fn () => fold (update_subsume (Theory.deref thy_ref)) eqns []))
haftmann@37460
  1050
    fun add_eqn' true (Default (eqns, _)) =
haftmann@37460
  1051
          Default (natural_order (Theory.check_thy thy) ((thm, proper) :: eqns))
haftmann@37460
  1052
          (*this restores the natural order and drops syntactic redundancies*)
haftmann@39794
  1053
      | add_eqn' true fun_spec = fun_spec
haftmann@39794
  1054
      | add_eqn' false (Eqns eqns) = Eqns (update_subsume thy (thm, proper) eqns)
haftmann@35226
  1055
      | add_eqn' false _ = Eqns [(thm, proper)];
haftmann@35226
  1056
  in change_fun_spec false c (add_eqn' default) thy end;
haftmann@31962
  1057
haftmann@31962
  1058
fun add_eqn thm thy =
haftmann@31962
  1059
  gen_add_eqn false (mk_eqn thy (thm, true)) thy;
haftmann@31962
  1060
haftmann@31962
  1061
fun add_warning_eqn thm thy =
haftmann@31962
  1062
  case mk_eqn_warning thy thm
haftmann@31962
  1063
   of SOME eqn => gen_add_eqn false eqn thy
haftmann@31962
  1064
    | NONE => thy;
haftmann@31962
  1065
haftmann@37425
  1066
fun add_nbe_eqn thm thy =
haftmann@37425
  1067
  gen_add_eqn false (mk_eqn thy (thm, false)) thy;
haftmann@37425
  1068
haftmann@31962
  1069
fun add_default_eqn thm thy =
haftmann@31962
  1070
  case mk_eqn_liberal thy thm
haftmann@31962
  1071
   of SOME eqn => gen_add_eqn true eqn thy
haftmann@31962
  1072
    | NONE => thy;
haftmann@31962
  1073
haftmann@31962
  1074
val add_default_eqn_attribute = Thm.declaration_attribute
haftmann@31962
  1075
  (fn thm => Context.mapping (add_default_eqn thm) I);
haftmann@31962
  1076
val add_default_eqn_attrib = Attrib.internal (K add_default_eqn_attribute);
haftmann@31962
  1077
haftmann@37425
  1078
fun add_nbe_default_eqn thm thy =
haftmann@37425
  1079
  gen_add_eqn true (mk_eqn thy (thm, false)) thy;
haftmann@37425
  1080
haftmann@37425
  1081
val add_nbe_default_eqn_attribute = Thm.declaration_attribute
haftmann@37425
  1082
  (fn thm => Context.mapping (add_nbe_default_eqn thm) I);
haftmann@37425
  1083
val add_nbe_default_eqn_attrib = Attrib.internal (K add_nbe_default_eqn_attribute);
haftmann@37425
  1084
haftmann@35226
  1085
fun add_abs_eqn raw_thm thy =
haftmann@35226
  1086
  let
haftmann@35226
  1087
    val (abs_thm, tyco) = (apfst Thm.close_derivation o mk_abs_eqn thy) raw_thm;
haftmann@35226
  1088
    val c = const_abs_eqn thy abs_thm;
haftmann@35226
  1089
  in change_fun_spec false c (K (Abstr (abs_thm, tyco))) thy end;
haftmann@35226
  1090
haftmann@31962
  1091
fun del_eqn thm thy = case mk_eqn_liberal thy thm
haftmann@35226
  1092
 of SOME (thm, _) => let
haftmann@40758
  1093
        fun del_eqn' (Default _) = empty_fun_spec
haftmann@35226
  1094
          | del_eqn' (Eqns eqns) =
haftmann@35226
  1095
              Eqns (filter_out (fn (thm', _) => Thm.eq_thm_prop (thm, thm')) eqns)
haftmann@35226
  1096
          | del_eqn' spec = spec
haftmann@35226
  1097
      in change_fun_spec true (const_eqn thy thm) del_eqn' thy end
haftmann@31962
  1098
  | NONE => thy;
haftmann@31962
  1099
haftmann@35226
  1100
fun del_eqns c = change_fun_spec true c (K empty_fun_spec);
haftmann@34244
  1101
haftmann@34244
  1102
haftmann@34244
  1103
(* cases *)
haftmann@34244
  1104
haftmann@40758
  1105
fun case_cong thy case_const (num_args, (pos, _)) =
haftmann@37438
  1106
  let
wenzelm@43326
  1107
    val ([x, y], ctxt) = fold_map Name.variant ["A", "A'"] Name.context;
wenzelm@43326
  1108
    val (zs, _) = fold_map Name.variant (replicate (num_args - 1) "") ctxt;
haftmann@37438
  1109
    val (ws, vs) = chop pos zs;
haftmann@37448
  1110
    val T = Logic.unvarifyT_global (Sign.the_const_type thy case_const);
wenzelm@40844
  1111
    val Ts = binder_types T;
haftmann@37438
  1112
    val T_cong = nth Ts pos;
haftmann@37438
  1113
    fun mk_prem z = Free (z, T_cong);
haftmann@37438
  1114
    fun mk_concl z = list_comb (Const (case_const, T), map2 (curry Free) (ws @ z :: vs) Ts);
haftmann@37438
  1115
    val (prem, concl) = pairself Logic.mk_equals (pairself mk_prem (x, y), pairself mk_concl (x, y));
haftmann@37521
  1116
    fun tac { context, prems } = Simplifier.rewrite_goals_tac prems
wenzelm@42360
  1117
      THEN ALLGOALS (Proof_Context.fact_tac [Drule.reflexive_thm]);
wenzelm@51551
  1118
  in Goal.prove_sorry_global thy (x :: y :: zs) [prem] concl tac end;
haftmann@37438
  1119
haftmann@34244
  1120
fun add_case thm thy =
haftmann@34244
  1121
  let
haftmann@43634
  1122
    val (case_const, (k, cos)) = case_cert thm;
haftmann@47555
  1123
    val _ = case (filter_out (is_constr thy) o map_filter I) cos
haftmann@34244
  1124
     of [] => ()
wenzelm@45430
  1125
      | cs => error ("Non-constructor(s) in case certificate: " ^ commas_quote cs);
haftmann@43634
  1126
    val entry = (1 + Int.max (1, length cos), (k, cos));
haftmann@43634
  1127
    fun register_case cong = (map_cases o apfst)
haftmann@43634
  1128
      (Symtab.update (case_const, (entry, cong)));
haftmann@43634
  1129
    fun register_for_constructors (Constructors (cos', cases)) =
haftmann@43634
  1130
         Constructors (cos',
Andreas@47437
  1131
           if exists (fn (co, _) => member (op =) cos (SOME co)) cos'
haftmann@43634
  1132
           then insert (op =) case_const cases
haftmann@43634
  1133
           else cases)
haftmann@43634
  1134
      | register_for_constructors (x as Abstractor _) = x;
haftmann@43634
  1135
    val register_type = (map_typs o Symtab.map)
haftmann@43634
  1136
      (K ((map o apsnd o apsnd) register_for_constructors));
haftmann@37438
  1137
  in
haftmann@37438
  1138
    thy
haftmann@37438
  1139
    |> Theory.checkpoint
haftmann@37438
  1140
    |> `(fn thy => case_cong thy case_const entry)
haftmann@43634
  1141
    |-> (fn cong => map_exec_purge (register_case cong #> register_type))
haftmann@37438
  1142
  end;
haftmann@34244
  1143
haftmann@34244
  1144
fun add_undefined c thy =
haftmann@34244
  1145
  (map_exec_purge o map_cases o apsnd) (Symtab.update (c, ())) thy;
haftmann@34244
  1146
haftmann@34244
  1147
haftmann@35299
  1148
(* types *)
haftmann@34244
  1149
haftmann@35299
  1150
fun register_type (tyco, vs_spec) thy =
haftmann@34244
  1151
  let
haftmann@35226
  1152
    val (old_constrs, some_old_proj) =
haftmann@35299
  1153
      case these (Symtab.lookup ((the_types o the_exec) thy) tyco)
haftmann@43634
  1154
       of (_, (_, Constructors (cos, _))) :: _ => (map fst cos, NONE)
haftmann@36209
  1155
        | (_, (_, Abstractor ((co, _), (proj, _)))) :: _ => ([co], SOME proj)
haftmann@43636
  1156
        | [] => ([], NONE);
haftmann@43636
  1157
    val outdated_funs1 = (map fst o fst o constructors_of o snd) vs_spec;
haftmann@43636
  1158
    val outdated_funs2 = case some_old_proj
haftmann@43636
  1159
     of NONE => []
haftmann@35226
  1160
      | SOME old_proj => Symtab.fold
haftmann@36209
  1161
          (fn (c, ((_, spec), _)) =>
haftmann@36209
  1162
            if member (op =) (the_list (associated_abstype spec)) tyco
haftmann@35226
  1163
            then insert (op =) c else I)
haftmann@43637
  1164
            ((the_functions o the_exec) thy) [old_proj];
haftmann@34244
  1165
    fun drop_outdated_cases cases = fold Symtab.delete_safe
haftmann@37438
  1166
      (Symtab.fold (fn (c, ((_, (_, cos)), _)) =>
Andreas@47437
  1167
        if exists (member (op =) old_constrs) (map_filter I cos)
haftmann@34244
  1168
          then insert (op =) c else I) cases []) cases;
haftmann@34244
  1169
  in
haftmann@34244
  1170
    thy
haftmann@43636
  1171
    |> fold del_eqns (outdated_funs1 @ outdated_funs2)
haftmann@34244
  1172
    |> map_exec_purge
haftmann@35226
  1173
        ((map_typs o Symtab.map_default (tyco, [])) (cons (serial (), vs_spec))
haftmann@34244
  1174
        #> (map_cases o apfst) drop_outdated_cases)
haftmann@34244
  1175
  end;
haftmann@34244
  1176
haftmann@35299
  1177
fun unoverload_const_typ thy (c, ty) = (AxClass.unoverload_const thy (c, ty), ty);
haftmann@34244
  1178
haftmann@35299
  1179
structure Datatype_Interpretation =
haftmann@35299
  1180
  Interpretation(type T = string * serial val eq = eq_snd (op =) : T * T -> bool);
haftmann@35299
  1181
haftmann@35299
  1182
fun datatype_interpretation f = Datatype_Interpretation.interpretation
haftmann@40726
  1183
  (fn (tyco, _) => fn thy => f (tyco, fst (get_type thy tyco)) thy);
haftmann@35226
  1184
haftmann@35226
  1185
fun add_datatype proto_constrs thy =
haftmann@35226
  1186
  let
haftmann@35226
  1187
    val constrs = map (unoverload_const_typ thy) proto_constrs;
haftmann@35226
  1188
    val (tyco, (vs, cos)) = constrset_of_consts thy constrs;
haftmann@35226
  1189
  in
haftmann@35226
  1190
    thy
haftmann@43634
  1191
    |> register_type (tyco, (vs, Constructors (cos, [])))
haftmann@35299
  1192
    |> Datatype_Interpretation.data (tyco, serial ())
haftmann@35226
  1193
  end;
haftmann@35226
  1194
haftmann@35226
  1195
fun add_datatype_cmd raw_constrs thy =
haftmann@35226
  1196
  add_datatype (map (read_bare_const thy) raw_constrs) thy;
haftmann@35226
  1197
haftmann@35299
  1198
structure Abstype_Interpretation =
haftmann@35299
  1199
  Interpretation(type T = string * serial val eq = eq_snd (op =) : T * T -> bool);
haftmann@35299
  1200
haftmann@35299
  1201
fun abstype_interpretation f = Abstype_Interpretation.interpretation
haftmann@35299
  1202
  (fn (tyco, _) => fn thy => f (tyco, get_abstype_spec thy tyco) thy);
haftmann@35299
  1203
haftmann@36112
  1204
fun add_abstype proto_thm thy =
haftmann@34244
  1205
  let
haftmann@40726
  1206
    val (tyco, (vs, (abs_ty as (abs, (_, ty)), (rep, cert)))) =
haftmann@49760
  1207
      error_abs_thm (check_abstype_cert thy) thy proto_thm;
haftmann@35226
  1208
  in
haftmann@35226
  1209
    thy
haftmann@36112
  1210
    |> register_type (tyco, (vs, Abstractor (abs_ty, (rep, cert))))
wenzelm@45344
  1211
    |> change_fun_spec false rep
wenzelm@45344
  1212
      (K (Proj (Logic.varify_types_global (mk_proj tyco vs ty abs rep), tyco)))
haftmann@36112
  1213
    |> Abstype_Interpretation.data (tyco, serial ())
haftmann@35226
  1214
  end;
haftmann@34244
  1215
haftmann@35226
  1216
haftmann@32070
  1217
(* setup *)
haftmann@31998
  1218
haftmann@31962
  1219
val _ = Context.>> (Context.map_theory
haftmann@31962
  1220
  (let
haftmann@31962
  1221
    fun mk_attribute f = Thm.declaration_attribute (fn thm => Context.mapping (f thm) I);
haftmann@31998
  1222
    val code_attribute_parser =
haftmann@31998
  1223
      Args.del |-- Scan.succeed (mk_attribute del_eqn)
haftmann@31998
  1224
      || Args.$$$ "nbe" |-- Scan.succeed (mk_attribute add_nbe_eqn)
haftmann@36112
  1225
      || Args.$$$ "abstype" |-- Scan.succeed (mk_attribute add_abstype)
haftmann@35226
  1226
      || Args.$$$ "abstract" |-- Scan.succeed (mk_attribute add_abs_eqn)
haftmann@31998
  1227
      || Scan.succeed (mk_attribute add_warning_eqn);
haftmann@31962
  1228
  in
haftmann@35299
  1229
    Datatype_Interpretation.init
haftmann@31998
  1230
    #> Attrib.setup (Binding.name "code") (Scan.lift code_attribute_parser)
haftmann@31998
  1231
        "declare theorems for code generation"
haftmann@31962
  1232
  end));
haftmann@31962
  1233
haftmann@24219
  1234
end; (*struct*)
haftmann@24219
  1235
haftmann@24219
  1236
haftmann@35226
  1237
(* type-safe interfaces for data dependent on executable code *)
haftmann@24219
  1238
haftmann@34173
  1239
functor Code_Data(Data: CODE_DATA_ARGS): CODE_DATA =
haftmann@24219
  1240
struct
haftmann@24219
  1241
haftmann@24219
  1242
type T = Data.T;
haftmann@24219
  1243
exception Data of T;
haftmann@24219
  1244
fun dest (Data x) = x
haftmann@24219
  1245
haftmann@34173
  1246
val kind = Code.declare_data (Data Data.empty);
haftmann@24219
  1247
haftmann@24219
  1248
val data_op = (kind, Data, dest);
haftmann@24219
  1249
haftmann@39397
  1250
fun change_yield (SOME thy) f = Code.change_yield_data data_op thy f
haftmann@39397
  1251
  | change_yield NONE f = f Data.empty
haftmann@39397
  1252
haftmann@39397
  1253
fun change some_thy f = snd (change_yield some_thy (pair () o f));
haftmann@24219
  1254
haftmann@24219
  1255
end;
haftmann@24219
  1256
haftmann@28143
  1257
structure Code : CODE = struct open Code; end;