src/Pure/Isar/isar_cmd.ML
author wenzelm
Fri Nov 07 16:36:55 2014 +0100 (2014-11-07 ago)
changeset 58928 23d0ffd48006
parent 58875 ab1c65b015c3
child 58978 e42da880c61e
permissions -rw-r--r--
plain value Keywords.keywords, which might be used outside theory for bootstrap purposes;
plain value Outer_Syntax within theory: parsing requires current theory context;
clarified name of Keyword.is_literal according to its semantics;
eliminated pointless type Keyword.T;
simplified @{command_spec};
clarified bootstrap keywords and syntax: take it as basis instead of side-branch;
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(*  Title:      Pure/Isar/isar_cmd.ML
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    Author:     Markus Wenzel, TU Muenchen
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Miscellaneous Isar commands.
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*)
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signature ISAR_CMD =
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sig
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  val global_setup: Symbol_Pos.source -> theory -> theory
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  val local_setup: Symbol_Pos.source -> Proof.context -> Proof.context
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  val parse_ast_translation: Symbol_Pos.source -> theory -> theory
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  val parse_translation: Symbol_Pos.source -> theory -> theory
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  val print_translation: Symbol_Pos.source -> theory -> theory
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  val typed_print_translation: Symbol_Pos.source -> theory -> theory
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  val print_ast_translation: Symbol_Pos.source -> theory -> theory
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  val translations: (xstring * string) Syntax.trrule list -> theory -> theory
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  val no_translations: (xstring * string) Syntax.trrule list -> theory -> theory
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  val oracle: bstring * Position.T -> Symbol_Pos.source -> theory -> theory
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  val add_defs: (bool * bool) * ((binding * string) * Token.src list) list -> theory -> theory
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  val declaration: {syntax: bool, pervasive: bool} ->
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    Symbol_Pos.source -> local_theory -> local_theory
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  val simproc_setup: string * Position.T -> string list -> Symbol_Pos.source ->
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    string list -> local_theory -> local_theory
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  val have: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state
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  val hence: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state
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  val show: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state
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  val thus: (Attrib.binding * (string * string list) list) list -> bool -> Proof.state -> Proof.state
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  val qed: Method.text_range option -> Toplevel.transition -> Toplevel.transition
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  val terminal_proof: Method.text_range * Method.text_range option ->
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    Toplevel.transition -> Toplevel.transition
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  val default_proof: Toplevel.transition -> Toplevel.transition
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  val immediate_proof: Toplevel.transition -> Toplevel.transition
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  val done_proof: Toplevel.transition -> Toplevel.transition
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  val skip_proof: Toplevel.transition -> Toplevel.transition
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  val ml_diag: bool -> Symbol_Pos.source -> Toplevel.transition -> Toplevel.transition
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  val diag_state: Proof.context -> Toplevel.state
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  val diag_goal: Proof.context -> {context: Proof.context, facts: thm list, goal: thm}
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  val pretty_theorems: bool -> Toplevel.state -> Pretty.T list
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  val thy_deps: Toplevel.transition -> Toplevel.transition
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  val locale_deps: Toplevel.transition -> Toplevel.transition
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  val print_stmts: string list * (Facts.ref * Token.src list) list
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    -> Toplevel.transition -> Toplevel.transition
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  val print_thms: string list * (Facts.ref * Token.src list) list
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    -> Toplevel.transition -> Toplevel.transition
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  val print_prfs: bool -> string list * (Facts.ref * Token.src list) list option
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    -> Toplevel.transition -> Toplevel.transition
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  val print_prop: (string list * string) -> Toplevel.transition -> Toplevel.transition
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  val print_term: (string list * string) -> Toplevel.transition -> Toplevel.transition
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  val print_type: (string list * (string * string option)) ->
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    Toplevel.transition -> Toplevel.transition
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end;
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structure Isar_Cmd: ISAR_CMD =
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struct
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(** theory declarations **)
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(* generic setup *)
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fun global_setup source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source) "val setup: theory -> theory" "Context.map_theory setup"
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  |> Context.theory_map;
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fun local_setup source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source) "val setup: local_theory -> local_theory" "Context.map_proof setup"
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  |> Context.proof_map;
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(* translation functions *)
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fun parse_ast_translation source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source)
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    "val parse_ast_translation: (string * (Proof.context -> Ast.ast list -> Ast.ast)) list"
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    "Context.map_theory (Sign.parse_ast_translation parse_ast_translation)"
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  |> Context.theory_map;
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fun parse_translation source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source)
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    "val parse_translation: (string * (Proof.context -> term list -> term)) list"
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    "Context.map_theory (Sign.parse_translation parse_translation)"
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  |> Context.theory_map;
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fun print_translation source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source)
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    "val print_translation: (string * (Proof.context -> term list -> term)) list"
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    "Context.map_theory (Sign.print_translation print_translation)"
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  |> Context.theory_map;
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fun typed_print_translation source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source)
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    "val typed_print_translation: (string * (Proof.context -> typ -> term list -> term)) list"
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    "Context.map_theory (Sign.typed_print_translation typed_print_translation)"
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  |> Context.theory_map;
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fun print_ast_translation source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source)
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    "val print_ast_translation: (string * (Proof.context -> Ast.ast list -> Ast.ast)) list"
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    "Context.map_theory (Sign.print_ast_translation print_ast_translation)"
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  |> Context.theory_map;
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(* translation rules *)
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fun read_trrules thy raw_rules =
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  let
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    val ctxt = Proof_Context.init_global thy;
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    val read_root =
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      #1 o dest_Type o Proof_Context.read_type_name {proper = true, strict = false} ctxt;
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  in
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    raw_rules
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    |> map (Syntax.map_trrule (fn (r, s) => Syntax_Phases.parse_ast_pattern ctxt (read_root r, s)))
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  end;
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fun translations args thy = Sign.add_trrules (read_trrules thy args) thy;
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fun no_translations args thy = Sign.del_trrules (read_trrules thy args) thy;
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(* oracles *)
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fun oracle (name, pos) source =
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  let
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    val body = ML_Lex.read_source false source;
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    val ants =
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      ML_Lex.read Position.none
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       ("local\n\
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        \  val binding = " ^ ML_Syntax.make_binding (name, pos) ^ ";\n\
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        \  val body = ") @ body @ ML_Lex.read Position.none (";\n\
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        \in\n\
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        \  val " ^ name ^
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        " = snd (Context.>>> (Context.map_theory_result (Thm.add_oracle (binding, body))));\n\
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        \end;\n");
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  in
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    Context.theory_map
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      (ML_Context.exec (fn () => ML_Context.eval ML_Compiler.flags (#pos source) ants))
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  end;
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(* old-style defs *)
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fun add_defs ((unchecked, overloaded), args) thy =
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 (legacy_feature "Old 'defs' command -- use 'definition' (with 'overloading') instead";
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  thy |>
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    (if unchecked then Global_Theory.add_defs_unchecked_cmd else Global_Theory.add_defs_cmd)
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      overloaded
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      (map (fn ((b, ax), srcs) => ((b, ax), map (Attrib.attribute_cmd_global thy) srcs)) args)
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  |> snd);
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(* declarations *)
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fun declaration {syntax, pervasive} source =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source)
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    "val declaration: Morphism.declaration"
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    ("Context.map_proof (Local_Theory.declaration {syntax = " ^ Bool.toString syntax ^ ", \
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      \pervasive = " ^ Bool.toString pervasive ^ "} declaration)")
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  |> Context.proof_map;
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(* simprocs *)
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fun simproc_setup name lhss source identifier =
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  ML_Lex.read_source false source
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  |> ML_Context.expression (#pos source)
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    "val proc: Morphism.morphism -> Proof.context -> cterm -> thm option"
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    ("Context.map_proof (Simplifier.def_simproc_cmd {name = " ^ ML_Syntax.make_binding name ^ ", \
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      \lhss = " ^ ML_Syntax.print_strings lhss ^ ", proc = proc, \
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      \identifier = Library.maps ML_Context.thms " ^ ML_Syntax.print_strings identifier ^ "})")
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  |> Context.proof_map;
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(* goals *)
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fun goal opt_chain goal stmt int =
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  opt_chain #> goal NONE (K I) stmt int;
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val have = goal I Proof.have_cmd;
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val hence = goal Proof.chain Proof.have_cmd;
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val show = goal I Proof.show_cmd;
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val thus = goal Proof.chain Proof.show_cmd;
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(* local endings *)
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fun local_qed m = Toplevel.proof (Proof.local_qed (m, true));
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val local_terminal_proof = Toplevel.proof' o Proof.local_future_terminal_proof;
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val local_default_proof = Toplevel.proof Proof.local_default_proof;
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val local_immediate_proof = Toplevel.proof Proof.local_immediate_proof;
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val local_done_proof = Toplevel.proof Proof.local_done_proof;
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val local_skip_proof = Toplevel.proof' Proof.local_skip_proof;
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val skip_local_qed = Toplevel.skip_proof (fn i => if i > 1 then i - 1 else raise Toplevel.UNDEF);
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(* global endings *)
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fun global_qed m = Toplevel.end_proof (K (Proof.global_qed (m, true)));
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val global_terminal_proof = Toplevel.end_proof o Proof.global_future_terminal_proof;
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val global_default_proof = Toplevel.end_proof (K Proof.global_default_proof);
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val global_immediate_proof = Toplevel.end_proof (K Proof.global_immediate_proof);
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val global_skip_proof = Toplevel.end_proof Proof.global_skip_proof;
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val global_done_proof = Toplevel.end_proof (K Proof.global_done_proof);
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val skip_global_qed = Toplevel.skip_proof_to_theory (fn n => n = 1);
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(* common endings *)
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fun qed m = local_qed m o global_qed m o skip_local_qed o skip_global_qed;
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fun terminal_proof m = local_terminal_proof m o global_terminal_proof m;
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val default_proof = local_default_proof o global_default_proof;
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val immediate_proof = local_immediate_proof o global_immediate_proof;
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val done_proof = local_done_proof o global_done_proof;
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val skip_proof = local_skip_proof o global_skip_proof;
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(* diagnostic ML evaluation *)
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structure Diag_State = Proof_Data
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(
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  type T = Toplevel.state;
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  fun init _ = Toplevel.toplevel;
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);
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fun ml_diag verbose source = Toplevel.keep (fn state =>
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  let
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    val opt_ctxt =
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      try Toplevel.generic_theory_of state
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      |> Option.map (Context.proof_of #> Diag_State.put state);
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    val flags = ML_Compiler.verbose verbose ML_Compiler.flags;
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  in ML_Context.eval_source_in opt_ctxt flags source end);
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val diag_state = Diag_State.get;
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fun diag_goal ctxt =
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  Proof.goal (Toplevel.proof_of (diag_state ctxt))
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    handle Toplevel.UNDEF => error "No goal present";
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val _ = Theory.setup
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  (ML_Antiquotation.value (Binding.qualify true "Isar" @{binding state})
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    (Scan.succeed "Isar_Cmd.diag_state ML_context") #>
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   ML_Antiquotation.value (Binding.qualify true "Isar" @{binding goal})
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    (Scan.succeed "Isar_Cmd.diag_goal ML_context"));
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(* theorems of theory or proof context *)
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fun pretty_theorems verbose st =
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  if Toplevel.is_proof st then
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    Proof_Context.pretty_local_facts (Toplevel.context_of st) verbose
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  else
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    let
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      val thy = Toplevel.theory_of st;
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      val prev_thys =
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        (case Toplevel.previous_context_of st of
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          SOME prev => [Proof_Context.theory_of prev]
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        | NONE => Theory.parents_of thy);
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    in Proof_Display.pretty_theorems_diff verbose prev_thys thy end;
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(* display dependencies *)
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val thy_deps = Toplevel.unknown_theory o Toplevel.keep (fn state =>
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  let
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    val thy = Toplevel.theory_of state;
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    val thy_session = Present.session_name thy;
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    val gr = rev (Theory.nodes_of thy) |> map (fn node =>
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      let
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        val name = Context.theory_name node;
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        val parents = map Context.theory_name (Theory.parents_of node);
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        val session = Present.session_name node;
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        val unfold = (session = thy_session);
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      in
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       {name = name, ID = name, parents = parents, dir = session,
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        unfold = unfold, path = "", content = []}
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      end);
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  in Graph_Display.display_graph gr end);
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val locale_deps = Toplevel.unknown_theory o Toplevel.keep (fn state =>
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  let
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    val thy = Toplevel.theory_of state;
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    val gr = Locale.pretty_locale_deps thy |> map (fn {name, parents, body} =>
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     {name = Locale.extern thy name, ID = name, parents = parents,
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      dir = "", unfold = true, path = "", content = [body]});
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  in Graph_Display.display_graph gr end);
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(* print theorems, terms, types etc. *)
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local
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fun string_of_stmts ctxt args =
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  Attrib.eval_thms ctxt args
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  |> map (Element.pretty_statement ctxt Thm.theoremK)
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  |> Pretty.chunks2 |> Pretty.string_of;
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fun string_of_thms ctxt args =
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  Pretty.string_of (Proof_Context.pretty_fact ctxt ("", Attrib.eval_thms ctxt args));
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fun string_of_prfs full state arg =
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  Pretty.string_of
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    (case arg of
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      NONE =>
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        let
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          val {context = ctxt, goal = thm} = Proof.simple_goal (Toplevel.proof_of state);
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          val thy = Proof_Context.theory_of ctxt;
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          val prf = Thm.proof_of thm;
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          val prop = Thm.full_prop_of thm;
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          val prf' = Proofterm.rewrite_proof_notypes ([], []) prf;
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        in
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          Proof_Syntax.pretty_proof ctxt
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            (if full then Reconstruct.reconstruct_proof thy prop prf' else prf')
berghofe@12125
   322
        end
wenzelm@38331
   323
    | SOME srcs =>
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        let val ctxt = Toplevel.context_of state
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   325
        in map (Proof_Syntax.pretty_proof_of ctxt full) (Attrib.eval_thms ctxt srcs) end
wenzelm@38331
   326
        |> Pretty.chunks);
berghofe@11524
   327
wenzelm@38331
   328
fun string_of_prop ctxt s =
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   329
  let
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   330
    val prop = Syntax.read_prop ctxt s;
wenzelm@26704
   331
    val ctxt' = Variable.auto_fixes prop ctxt;
wenzelm@26704
   332
  in Pretty.string_of (Pretty.quote (Syntax.pretty_term ctxt' prop)) end;
wenzelm@5831
   333
wenzelm@38331
   334
fun string_of_term ctxt s =
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   335
  let
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   336
    val t = Syntax.read_term ctxt s;
wenzelm@5831
   337
    val T = Term.type_of t;
wenzelm@26704
   338
    val ctxt' = Variable.auto_fixes t ctxt;
wenzelm@5831
   339
  in
wenzelm@19385
   340
    Pretty.string_of
wenzelm@26704
   341
      (Pretty.block [Pretty.quote (Syntax.pretty_term ctxt' t), Pretty.fbrk,
wenzelm@26704
   342
        Pretty.str "::", Pretty.brk 1, Pretty.quote (Syntax.pretty_typ ctxt' T)])
wenzelm@9128
   343
  end;
wenzelm@5831
   344
wenzelm@48792
   345
fun string_of_type ctxt (s, NONE) =
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   346
      let val T = Syntax.read_typ ctxt s
wenzelm@48792
   347
      in Pretty.string_of (Pretty.quote (Syntax.pretty_typ ctxt T)) end
wenzelm@48792
   348
  | string_of_type ctxt (s1, SOME s2) =
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   349
      let
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   350
        val ctxt' = Config.put show_sorts true ctxt;
wenzelm@48792
   351
        val raw_T = Syntax.parse_typ ctxt' s1;
wenzelm@48792
   352
        val S = Syntax.read_sort ctxt' s2;
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   353
        val T =
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   354
          Syntax.check_term ctxt'
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   355
            (Logic.mk_type raw_T |> Type.constraint (Term.itselfT (Type_Infer.anyT S)))
wenzelm@48792
   356
          |> Logic.dest_type;
wenzelm@48792
   357
      in Pretty.string_of (Pretty.quote (Syntax.pretty_typ ctxt' T)) end;
wenzelm@9128
   358
wenzelm@23935
   359
fun print_item string_of (modes, arg) = Toplevel.keep (fn state =>
wenzelm@38331
   360
  Print_Mode.with_modes modes (fn () => writeln (string_of state arg)) ());
wenzelm@19385
   361
wenzelm@19385
   362
in
wenzelm@9128
   363
wenzelm@38331
   364
val print_stmts = print_item (string_of_stmts o Toplevel.context_of);
wenzelm@38331
   365
val print_thms = print_item (string_of_thms o Toplevel.context_of);
wenzelm@19385
   366
val print_prfs = print_item o string_of_prfs;
wenzelm@38331
   367
val print_prop = print_item (string_of_prop o Toplevel.context_of);
wenzelm@38331
   368
val print_term = print_item (string_of_term o Toplevel.context_of);
wenzelm@38331
   369
val print_type = print_item (string_of_type o Toplevel.context_of);
wenzelm@5831
   370
wenzelm@19385
   371
end;
wenzelm@19385
   372
wenzelm@5831
   373
end;