(*  Title:      Pure/Isar/isar_cmd.ML

    Author:     Markus Wenzel, TU Muenchen

Miscellaneous Isar commands.

*)

signature ISAR_CMD =

sig

  val global_setup: Symbol_Pos.text * Position.T -> theory -> theory

  val local_setup: Symbol_Pos.text * Position.T -> Proof.context -> Proof.context

  val parse_ast_translation: bool * (Symbol_Pos.text * Position.T) -> theory -> theory

  val parse_translation: bool * (Symbol_Pos.text * Position.T) -> theory -> theory

  val print_translation: bool * (Symbol_Pos.text * Position.T) -> theory -> theory

  val typed_print_translation: bool * (Symbol_Pos.text * Position.T) -> theory -> theory

  val print_ast_translation: bool * (Symbol_Pos.text * Position.T) -> theory -> theory

  val oracle: bstring * Position.T -> Symbol_Pos.text * Position.T -> theory -> theory

  val add_axioms: (Attrib.binding * string) list -> theory -> theory

  val add_defs: (bool * bool) * ((binding * string) * Attrib.src list) list -> theory -> theory

  val declaration: {syntax: bool, pervasive: bool} ->

    Symbol_Pos.text * Position.T -> local_theory -> local_theory

  val simproc_setup: string -> string list -> Symbol_Pos.text * Position.T -> string list ->

    local_theory -> local_theory

  val hide_class: bool -> xstring list -> theory -> theory

  val hide_type: bool -> xstring list -> theory -> theory

  val hide_const: bool -> xstring list -> theory -> theory

  val hide_fact: bool -> xstring list -> theory -> theory

  val have: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state

  val hence: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state

  val show: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state

  val thus: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state

  val qed: Method.text option -> Toplevel.transition -> Toplevel.transition

  val terminal_proof: Method.text * Method.text option ->

    Toplevel.transition -> Toplevel.transition

  val default_proof: Toplevel.transition -> Toplevel.transition

  val immediate_proof: Toplevel.transition -> Toplevel.transition

  val done_proof: Toplevel.transition -> Toplevel.transition

  val skip_proof: Toplevel.transition -> Toplevel.transition

  val ml_diag: bool -> Symbol_Pos.text * Position.T -> Toplevel.transition -> Toplevel.transition

  val diag_state: unit -> Toplevel.state

  val diag_goal: unit -> {context: Proof.context, facts: thm list, goal: thm}

  val display_drafts: Path.T list -> Toplevel.transition -> Toplevel.transition

  val print_drafts: Path.T list -> Toplevel.transition -> Toplevel.transition

  val print_context: Toplevel.transition -> Toplevel.transition

  val print_theory: bool -> Toplevel.transition -> Toplevel.transition

  val print_syntax: Toplevel.transition -> Toplevel.transition

  val print_abbrevs: Toplevel.transition -> Toplevel.transition

  val print_facts: Toplevel.transition -> Toplevel.transition

  val print_configs: Toplevel.transition -> Toplevel.transition

  val print_theorems: bool -> Toplevel.transition -> Toplevel.transition

  val print_locales: Toplevel.transition -> Toplevel.transition

  val print_locale: bool * xstring -> Toplevel.transition -> Toplevel.transition

  val print_registrations: string -> Toplevel.transition -> Toplevel.transition

  val print_dependencies: bool * Expression.expression -> Toplevel.transition

    -> Toplevel.transition

  val print_attributes: Toplevel.transition -> Toplevel.transition

  val print_simpset: Toplevel.transition -> Toplevel.transition

  val print_rules: Toplevel.transition -> Toplevel.transition

  val print_trans_rules: Toplevel.transition -> Toplevel.transition

  val print_methods: Toplevel.transition -> Toplevel.transition

  val print_antiquotations: Toplevel.transition -> Toplevel.transition

  val class_deps: Toplevel.transition -> Toplevel.transition

  val thy_deps: Toplevel.transition -> Toplevel.transition

  val thm_deps: (Facts.ref * Attrib.src list) list -> Toplevel.transition -> Toplevel.transition

  val unused_thms: (string list * string list option) option ->

    Toplevel.transition -> Toplevel.transition

  val print_binds: Toplevel.transition -> Toplevel.transition

  val print_cases: Toplevel.transition -> Toplevel.transition

  val print_stmts: string list * (Facts.ref * Attrib.src list) list

    -> Toplevel.transition -> Toplevel.transition

  val print_thms: string list * (Facts.ref * Attrib.src list) list

    -> Toplevel.transition -> Toplevel.transition

  val print_prfs: bool -> string list * (Facts.ref * Attrib.src list) list option

    -> Toplevel.transition -> Toplevel.transition

  val print_prop: (string list * string) -> Toplevel.transition -> Toplevel.transition

  val print_term: (string list * string) -> Toplevel.transition -> Toplevel.transition

  val print_type: (string list * string) -> Toplevel.transition -> Toplevel.transition

  val header_markup: Symbol_Pos.text * Position.T -> Toplevel.transition -> Toplevel.transition

  val local_theory_markup: xstring option * (Symbol_Pos.text * Position.T) ->

    Toplevel.transition -> Toplevel.transition

  val proof_markup: Symbol_Pos.text * Position.T -> Toplevel.transition -> Toplevel.transition

end;

structure Isar_Cmd: ISAR_CMD =

struct

(** theory declarations **)

(* generic setup *)

fun global_setup (txt, pos) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos "val setup: theory -> theory" "Context.map_theory setup"

  |> Context.theory_map;

fun local_setup (txt, pos) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos "val setup: local_theory -> local_theory" "Context.map_proof setup"

  |> Context.proof_map;

(* translation functions *)

local

fun advancedT false = ""

  | advancedT true = "Proof.context -> ";

fun advancedN false = ""

  | advancedN true = "advanced_";

in

fun parse_ast_translation (a, (txt, pos)) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos

    ("val parse_ast_translation: (string * (" ^ advancedT a ^

      "Syntax.ast list -> Syntax.ast)) list")

    ("Context.map_theory (Sign.add_" ^ advancedN a ^ "trfuns (parse_ast_translation, [], [], []))")

  |> Context.theory_map;

fun parse_translation (a, (txt, pos)) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos

    ("val parse_translation: (string * (" ^ advancedT a ^

      "term list -> term)) list")

    ("Context.map_theory (Sign.add_" ^ advancedN a ^ "trfuns ([], parse_translation, [], []))")

  |> Context.theory_map;

fun print_translation (a, (txt, pos)) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos

    ("val print_translation: (string * (" ^ advancedT a ^

      "term list -> term)) list")

    ("Context.map_theory (Sign.add_" ^ advancedN a ^ "trfuns ([], [], print_translation, []))")

  |> Context.theory_map;

fun print_ast_translation (a, (txt, pos)) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos

    ("val print_ast_translation: (string * (" ^ advancedT a ^

      "Syntax.ast list -> Syntax.ast)) list")

    ("Context.map_theory (Sign.add_" ^ advancedN a ^ "trfuns ([], [], [], print_ast_translation))")

  |> Context.theory_map;

fun typed_print_translation (a, (txt, pos)) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos

    ("val typed_print_translation: (string * (" ^ advancedT a ^

      "bool -> typ -> term list -> term)) list")

    ("Context.map_theory (Sign.add_" ^ advancedN a ^ "trfunsT typed_print_translation)")

  |> Context.theory_map;

end;

(* oracles *)

fun oracle (name, pos) (body_txt, body_pos) =

  let

    val body = ML_Lex.read body_pos body_txt;

    val ants =

      ML_Lex.read Position.none

       ("local\n\

        \  val binding = " ^ ML_Syntax.make_binding (name, pos) ^ ";\n\

        \  val body = ") @ body @ ML_Lex.read Position.none (";\n\

        \in\n\

        \  val " ^ name ^ " = snd (Context.>>> (Context.map_theory_result (Thm.add_oracle (binding, body))));\n\

        \end;\n");

  in Context.theory_map (ML_Context.exec (fn () => ML_Context.eval false body_pos ants)) end;

(* old-style axioms *)

val add_axioms = fold (snd oo Specification.axiom_cmd);

fun add_defs ((unchecked, overloaded), args) thy =

  thy |>

    (if unchecked then Global_Theory.add_defs_unchecked_cmd else Global_Theory.add_defs_cmd)

      overloaded (map (fn ((b, ax), srcs) => ((b, ax), map (Attrib.attribute thy) srcs)) args)

  |> snd;

(* declarations *)

fun declaration {syntax, pervasive} (txt, pos) =

  ML_Lex.read pos txt

  |> ML_Context.expression pos

    "val declaration: Morphism.declaration"

    ("Context.map_proof (Local_Theory." ^

      (if syntax then "syntax_declaration" else "declaration") ^ " " ^

      Bool.toString pervasive ^ " declaration)")

  |> Context.proof_map;

(* simprocs *)

fun simproc_setup name lhss (txt, pos) identifier =

  ML_Lex.read pos txt

  |> ML_Context.expression pos

    "val proc: Morphism.morphism -> Simplifier.simpset -> cterm -> thm option"

    ("Context.map_proof (Simplifier.def_simproc {name = " ^ ML_Syntax.print_string name ^ ", \

      \lhss = " ^ ML_Syntax.print_strings lhss ^ ", proc = proc, \

      \identifier = Library.maps ML_Context.thms " ^ ML_Syntax.print_strings identifier ^ "})")

  |> Context.proof_map;

(* hide names *)

fun hide_names intern check hide fully xnames thy =

  let

    val names = map (intern thy) xnames;

    val bads = filter_out (check thy) names;

  in

    if null bads then fold (hide fully) names thy

    else error ("Attempt to hide undeclared item(s): " ^ commas_quote bads)

  end;

val hide_class = hide_names Sign.intern_class (can o Sign.certify_class) Sign.hide_class;

val hide_type = hide_names Sign.intern_type Sign.declared_tyname Sign.hide_type;

val hide_const = hide_names Sign.intern_const Sign.declared_const Sign.hide_const;

val hide_fact =

  hide_names Global_Theory.intern_fact Global_Theory.defined_fact Global_Theory.hide_fact;

(* goals *)

fun goal opt_chain goal stmt int =

  opt_chain #> goal NONE (K I) stmt int;

val have = goal I Proof.have_cmd;

val hence = goal Proof.chain Proof.have_cmd;

val show = goal I Proof.show_cmd;

val thus = goal Proof.chain Proof.show_cmd;

(* local endings *)

fun local_qed m = Toplevel.proof (Proof.local_qed (m, true));

val local_terminal_proof = Toplevel.proof' o Proof.local_future_terminal_proof;

val local_default_proof = Toplevel.proof Proof.local_default_proof;

val local_immediate_proof = Toplevel.proof Proof.local_immediate_proof;

val local_done_proof = Toplevel.proof Proof.local_done_proof;

val local_skip_proof = Toplevel.proof' Proof.local_skip_proof;

val skip_local_qed = Toplevel.skip_proof (fn i => if i > 1 then i - 1 else raise Toplevel.UNDEF);

(* global endings *)

fun global_qed m = Toplevel.end_proof (K (Proof.global_qed (m, true)));

val global_terminal_proof = Toplevel.end_proof o K o Proof.global_terminal_proof;

val global_default_proof = Toplevel.end_proof (K Proof.global_default_proof);

val global_immediate_proof = Toplevel.end_proof (K Proof.global_immediate_proof);

val global_skip_proof = Toplevel.end_proof Proof.global_skip_proof;

val global_done_proof = Toplevel.end_proof (K Proof.global_done_proof);

val skip_global_qed = Toplevel.skip_proof_to_theory (fn n => n = 1);

(* common endings *)

fun qed m = local_qed m o global_qed m o skip_local_qed o skip_global_qed;

fun terminal_proof m = local_terminal_proof m o global_terminal_proof m;

val default_proof = local_default_proof o global_default_proof;

val immediate_proof = local_immediate_proof o global_immediate_proof;

val done_proof = local_done_proof o global_done_proof;

val skip_proof = local_skip_proof o global_skip_proof;

(* diagnostic ML evaluation *)

structure Diag_State = Proof_Data

(

  type T = Toplevel.state;

  fun init _ = Toplevel.toplevel;

);

fun ml_diag verbose (txt, pos) = Toplevel.keep (fn state =>

  let val opt_ctxt =

    try Toplevel.generic_theory_of state

    |> Option.map (Context.proof_of #> Diag_State.put state)

  in ML_Context.eval_text_in opt_ctxt verbose pos txt end);

fun diag_state () = Diag_State.get (ML_Context.the_local_context ());

fun diag_goal () =

  Proof.goal (Toplevel.proof_of (diag_state ()))

    handle Toplevel.UNDEF => error "No goal present";

val _ = ML_Antiquote.value "Isar.state" (Scan.succeed "Isar_Cmd.diag_state ()");

val _ = ML_Antiquote.value "Isar.goal" (Scan.succeed "Isar_Cmd.diag_goal ()");

(* present draft files *)

fun display_drafts files = Toplevel.imperative (fn () =>

  let val outfile = File.shell_path (Present.drafts (getenv "ISABELLE_DOC_FORMAT") files)

  in Isabelle_System.isabelle_tool "display" ("-c " ^ outfile ^ " &"); () end);

fun print_drafts files = Toplevel.imperative (fn () =>

  let val outfile = File.shell_path (Present.drafts "ps" files)

  in Isabelle_System.isabelle_tool "print" ("-c " ^ outfile); () end);

(* print parts of theory and proof context *)

val print_context = Toplevel.keep Toplevel.print_state_context;

fun print_theory verbose = Toplevel.unknown_theory o

  Toplevel.keep (Pretty.writeln o Proof_Display.pretty_full_theory verbose o Toplevel.theory_of);

val print_syntax = Toplevel.unknown_context o

  Toplevel.keep (ProofContext.print_syntax o Toplevel.context_of);

val print_abbrevs = Toplevel.unknown_context o

  Toplevel.keep (ProofContext.print_abbrevs o Toplevel.context_of);

val print_facts = Toplevel.unknown_context o

  Toplevel.keep (ProofContext.print_lthms o Toplevel.context_of);

val print_configs = Toplevel.unknown_context o

  Toplevel.keep (Attrib.print_configs o Toplevel.context_of);

val print_theorems_proof =

  Toplevel.keep (ProofContext.print_lthms o Proof.context_of o Toplevel.proof_of);

fun print_theorems_theory verbose = Toplevel.keep (fn state =>

  Toplevel.theory_of state |>

  (case Toplevel.previous_context_of state of

    SOME prev => Proof_Display.print_theorems_diff verbose (ProofContext.theory_of prev)

  | NONE => Proof_Display.print_theorems verbose));

fun print_theorems verbose =

  Toplevel.unknown_context o print_theorems_theory verbose o print_theorems_proof;

val print_locales = Toplevel.unknown_theory o

  Toplevel.keep (Locale.print_locales o Toplevel.theory_of);

fun print_locale (verbose, name) = Toplevel.unknown_theory o

  Toplevel.keep (fn state => Locale.print_locale (Toplevel.theory_of state) verbose name);

fun print_registrations name = Toplevel.unknown_context o

  Toplevel.keep (fn state =>

    Locale.print_registrations (Toplevel.context_of state) name);

fun print_dependencies (clean, expression) = Toplevel.unknown_context o

  Toplevel.keep (fn state =>

    Expression.print_dependencies (Toplevel.context_of state) clean expression);

val print_attributes = Toplevel.unknown_theory o

  Toplevel.keep (Attrib.print_attributes o Toplevel.theory_of);

val print_simpset = Toplevel.unknown_context o

  Toplevel.keep (fn state =>

    let val ctxt = Toplevel.context_of state

    in Pretty.writeln (Simplifier.pretty_ss ctxt (simpset_of ctxt)) end);

val print_rules = Toplevel.unknown_context o

  Toplevel.keep (Context_Rules.print_rules o Toplevel.context_of);

val print_trans_rules = Toplevel.unknown_context o

  Toplevel.keep (Calculation.print_rules o Toplevel.context_of);

val print_methods = Toplevel.unknown_theory o

  Toplevel.keep (Method.print_methods o Toplevel.theory_of);

val print_antiquotations = Toplevel.imperative Thy_Output.print_antiquotations;

val thy_deps = Toplevel.unknown_theory o Toplevel.keep (fn state =>

  let

    val thy = Toplevel.theory_of state;

    val thy_session = Present.session_name thy;

    val all_thys = rev (thy :: Theory.ancestors_of thy);

    val gr = all_thys |> map (fn node =>

      let

        val name = Context.theory_name node;

        val parents = map Context.theory_name (Theory.parents_of node);

        val session = Present.session_name node;

        val unfold = (session = thy_session);

      in {name = name, ID = name, parents = parents, dir = session, unfold = unfold, path = ""} end);

  in Present.display_graph gr end);

val class_deps = Toplevel.unknown_theory o Toplevel.keep (fn state =>

  let

    val thy = Toplevel.theory_of state;

    val {classes = (space, algebra), ...} = Type.rep_tsig (Sign.tsig_of thy);

    val classes = Sorts.classes_of algebra;

    fun entry (c, (i, (_, cs))) =

      (i, {name = Name_Space.extern space c, ID = c, parents = cs,

            dir = "", unfold = true, path = ""});

    val gr =

      Graph.fold (cons o entry) classes []

      |> sort (int_ord o pairself #1) |> map #2;

  in Present.display_graph gr end);

fun thm_deps args = Toplevel.unknown_theory o Toplevel.keep (fn state =>

  Thm_Deps.thm_deps (Toplevel.theory_of state)

    (Attrib.eval_thms (Toplevel.context_of state) args));

(* find unused theorems *)

fun unused_thms opt_range = Toplevel.keep (fn state =>

  let

    val thy = Toplevel.theory_of state;

    val ctxt = Toplevel.context_of state;

    fun pretty_thm (a, th) = ProofContext.pretty_fact ctxt (a, [th]);

    val get_theory = Context.get_theory thy;

  in

    Thm_Deps.unused_thms

      (case opt_range of

        NONE => (Theory.parents_of thy, [thy])

      | SOME (xs, NONE) => (map get_theory xs, [thy])

      | SOME (xs, SOME ys) => (map get_theory xs, map get_theory ys))

    |> map pretty_thm |> Pretty.chunks |> Pretty.writeln

  end);

(* print proof context contents *)

val print_binds = Toplevel.unknown_context o

  Toplevel.keep (ProofContext.print_binds o Toplevel.context_of);

val print_cases = Toplevel.unknown_context o

  Toplevel.keep (ProofContext.print_cases o Toplevel.context_of);

(* print theorems, terms, types etc. *)

local

fun string_of_stmts ctxt args =

  Attrib.eval_thms ctxt args

  |> map (Element.pretty_statement ctxt Thm.theoremK)

  |> Pretty.chunks2 |> Pretty.string_of;

fun string_of_thms ctxt args =

  Pretty.string_of (Display.pretty_thms ctxt (Attrib.eval_thms ctxt args));

fun string_of_prfs full state arg =

  Pretty.string_of

    (case arg of

      NONE =>

        let

          val {context = ctxt, goal = thm} = Proof.simple_goal (Toplevel.proof_of state);

          val thy = ProofContext.theory_of ctxt;

          val prf = Thm.proof_of thm;

          val prop = Thm.full_prop_of thm;

          val prf' = Proofterm.rewrite_proof_notypes ([], []) prf;

        in

          Proof_Syntax.pretty_proof ctxt

            (if full then Reconstruct.reconstruct_proof thy prop prf' else prf')

        end

    | SOME srcs =>

        let val ctxt = Toplevel.context_of state

        in map (Proof_Syntax.pretty_proof_of ctxt full) (Attrib.eval_thms ctxt srcs) end

        |> Pretty.chunks);

fun string_of_prop ctxt s =

  let

    val prop = Syntax.read_prop ctxt s;

    val ctxt' = Variable.auto_fixes prop ctxt;

  in Pretty.string_of (Pretty.quote (Syntax.pretty_term ctxt' prop)) end;

fun string_of_term ctxt s =

  let

    val t = Syntax.read_term ctxt s;

    val T = Term.type_of t;

    val ctxt' = Variable.auto_fixes t ctxt;

  in

    Pretty.string_of

      (Pretty.block [Pretty.quote (Syntax.pretty_term ctxt' t), Pretty.fbrk,

        Pretty.str "::", Pretty.brk 1, Pretty.quote (Syntax.pretty_typ ctxt' T)])

  end;

fun string_of_type ctxt s =

  let val T = Syntax.read_typ ctxt s

  in Pretty.string_of (Pretty.quote (Syntax.pretty_typ ctxt T)) end;

fun print_item string_of (modes, arg) = Toplevel.keep (fn state =>

  Print_Mode.with_modes modes (fn () => writeln (string_of state arg)) ());

in

val print_stmts = print_item (string_of_stmts o Toplevel.context_of);

val print_thms = print_item (string_of_thms o Toplevel.context_of);

val print_prfs = print_item o string_of_prfs;

val print_prop = print_item (string_of_prop o Toplevel.context_of);

val print_term = print_item (string_of_term o Toplevel.context_of);

val print_type = print_item (string_of_type o Toplevel.context_of);

end;

(* markup commands *)

fun check_text (txt, pos) state =

 (Position.report pos Markup.doc_source;

  ignore (Thy_Output.eval_antiquote (#1 (Keyword.get_lexicons ())) state (txt, pos)));

fun header_markup txt = Toplevel.keep (fn state =>

  if Toplevel.is_toplevel state then check_text txt state

  else raise Toplevel.UNDEF);

fun local_theory_markup (loc, txt) = Toplevel.present_local_theory loc (check_text txt);

val proof_markup = Toplevel.present_proof o check_text;

end;