(* Title: Pure/pure_thy.ML ID: $Id: pure_thy.ML,v 1.126 2005/09/28 22:58:56 wenzelm Exp $ Author: Markus Wenzel, TU Muenchen Theorem storage. The ProtoPure theory. *) signature BASIC_PURE_THY = sig datatype interval = FromTo of int * int | From of int | Single of int datatype thmref = Name of string | NameSelection of string * interval list val print_theorems: theory -> unit val print_theory: theory -> unit val get_thm: theory -> thmref -> thm val get_thms: theory -> thmref -> thm list val get_thmss: theory -> thmref list -> thm list structure ProtoPure: sig val thy: theory val Goal_def: thm end end; signature PURE_THY = sig include BASIC_PURE_THY val string_of_thmref: thmref -> string val print_theorems_diff: theory -> theory -> unit val get_thm_closure: theory -> thmref -> thm val get_thms_closure: theory -> thmref -> thm list val single_thm: string -> thm list -> thm val name_of_thmref: thmref -> string val map_name_of_thmref: (string -> string) -> thmref -> thmref val select_thm: thmref -> thm list -> thm list val selections: string * thm list -> (thmref * thm) list val theorems_of: theory -> thm list NameSpace.table val theorem_space: theory -> NameSpace.T val fact_index_of: theory -> FactIndex.T val valid_thms: theory -> thmref * thm list -> bool val thms_containing: theory -> FactIndex.spec -> (string * thm list) list val thms_containing_consts: theory -> string list -> (string * thm) list val thms_of: theory -> (string * thm) list val all_thms_of: theory -> (string * thm) list val hide_thms: bool -> string list -> theory -> theory val store_thm: (bstring * thm) * theory attribute list -> theory -> theory * thm val smart_store_thms: (bstring * thm list) -> thm list val smart_store_thms_open: (bstring * thm list) -> thm list val forall_elim_var: int -> thm -> thm val forall_elim_vars: int -> thm -> thm val add_thms: ((bstring * thm) * theory attribute list) list -> theory -> theory * thm list val add_thmss: ((bstring * thm list) * theory attribute list) list -> theory -> theory * thm list list val note_thmss: theory attribute -> ((bstring * theory attribute list) * (thmref * theory attribute list) list) list -> theory -> theory * (bstring * thm list) list val note_thmss_i: theory attribute -> ((bstring * theory attribute list) * (thm list * theory attribute list) list) list -> theory -> theory * (bstring * thm list) list val add_axioms: ((bstring * string) * theory attribute list) list -> theory -> theory * thm list val add_axioms_i: ((bstring * term) * theory attribute list) list -> theory -> theory * thm list val add_axiomss: ((bstring * string list) * theory attribute list) list -> theory -> theory * thm list list val add_axiomss_i: ((bstring * term list) * theory attribute list) list -> theory -> theory * thm list list val add_defs: bool -> ((bstring * string) * theory attribute list) list -> theory -> theory * thm list val add_defs_i: bool -> ((bstring * term) * theory attribute list) list -> theory -> theory * thm list val add_defss: bool -> ((bstring * string list) * theory attribute list) list -> theory -> theory * thm list list val add_defss_i: bool -> ((bstring * term list) * theory attribute list) list -> theory -> theory * thm list list val generic_setup: string -> theory -> theory val add_oracle: bstring * string * string -> theory -> theory end; structure PureThy: PURE_THY = struct (*** theorem database ***) (** dataype theorems **) fun pretty_theorems_diff thy prev_thms (space, thms) = let val prt_thm = Display.pretty_thm_sg thy; fun prt_thms (name, [th]) = Pretty.block [Pretty.str (name ^ ":"), Pretty.brk 1, prt_thm th] | prt_thms (name, ths) = Pretty.big_list (name ^ ":") (map prt_thm ths); val diff_thmss = Symtab.fold (fn fact => if not (Symtab.member eq_thms prev_thms fact) then cons fact else I) thms []; val thmss = diff_thmss |> map (apfst (NameSpace.extern space)) |> Library.sort_wrt #1; in Pretty.big_list "theorems:" (map prt_thms thmss) end; fun pretty_theorems thy = pretty_theorems_diff thy Symtab.empty; structure TheoremsData = TheoryDataFun (struct val name = "Pure/theorems"; type T = {theorems: thm list NameSpace.table, index: FactIndex.T} ref; fun mk_empty _ = ref {theorems = NameSpace.empty_table, index = FactIndex.empty}: T; val empty = mk_empty (); fun copy (ref x) = ref x; val extend = mk_empty; fun merge _ = mk_empty; fun print thy (ref {theorems, index}) = Pretty.writeln (pretty_theorems thy theorems); end); val get_theorems_ref = TheoremsData.get; val get_theorems = ! o get_theorems_ref; val theorems_of = #theorems o get_theorems; val theorem_space = #1 o theorems_of; val fact_index_of = #index o get_theorems; (* print theory *) val print_theorems = TheoremsData.print; fun print_theorems_diff prev_thy thy = Pretty.writeln (pretty_theorems_diff thy (#2 (theorems_of prev_thy)) (#theorems (get_theorems thy))); fun print_theory thy = Display.pretty_full_theory thy @ [pretty_theorems thy (#theorems (get_theorems thy))] |> Pretty.chunks |> Pretty.writeln; (** retrieve theorems **) fun the_thms _ (SOME thms) = thms | the_thms name NONE = error ("Unknown theorem(s) " ^ quote name); fun single_thm _ [thm] = thm | single_thm name _ = error ("Single theorem expected " ^ quote name); (* datatype interval *) datatype interval = FromTo of int * int | From of int | Single of int; fun interval _ (FromTo (i, j)) = i upto j | interval n (From i) = i upto n | interval _ (Single i) = [i]; fun string_of_interval (FromTo (i, j)) = string_of_int i ^ "-" ^ string_of_int j | string_of_interval (From i) = string_of_int i ^ "-" | string_of_interval (Single i) = string_of_int i; (* datatype thmref *) datatype thmref = Name of string | NameSelection of string * interval list; fun name_of_thmref (Name name) = name | name_of_thmref (NameSelection (name, _)) = name; fun map_name_of_thmref f (Name name) = Name (f name) | map_name_of_thmref f (NameSelection (name, is)) = NameSelection (f name, is); fun string_of_thmref (Name name) = name | string_of_thmref (NameSelection (name, is)) = name ^ enclose "(" ")" (commas (map string_of_interval is)); (* select_thm *) fun select_thm (Name _) thms = thms | select_thm (NameSelection (name, is)) thms = let val n = length thms; fun select i = if i < 1 orelse i > n then error ("Bad subscript " ^ string_of_int i ^ " for " ^ quote name ^ " (length " ^ string_of_int n ^ ")") else List.nth (thms, i - 1); in map select (List.concat (map (interval n) is)) end; (* selections *) fun selections (name, [thm]) = [(Name name, thm)] | selections (name, thms) = (1 upto length thms, thms) |> ListPair.map (fn (i, thm) => (NameSelection (name, [Single i]), thm)); (* get_thm(s)_closure -- statically scoped versions *) (*beware of proper order of evaluation!*) fun lookup_thms thy = let val thy_ref = Theory.self_ref thy; val (space, thms) = #theorems (get_theorems thy); in fn name => Option.map (map (Thm.transfer (Theory.deref thy_ref))) (*dynamic identity*) (Symtab.lookup thms (NameSpace.intern space name)) (*static content*) end; fun get_thms_closure thy = let val closures = map lookup_thms (thy :: Theory.ancestors_of thy) in fn thmref => let val name = name_of_thmref thmref in select_thm thmref (the_thms name (get_first (fn f => f name) closures)) end end; fun get_thm_closure thy = let val get = get_thms_closure thy in fn thmref => single_thm (name_of_thmref thmref) (get thmref) end; (* get_thms etc. *) fun get_thms theory thmref = let val name = name_of_thmref thmref in get_first (fn thy => lookup_thms thy name) (theory :: Theory.ancestors_of theory) |> the_thms name |> select_thm thmref |> map (Thm.transfer theory) end; fun get_thmss thy thmrefs = List.concat (map (get_thms thy) thmrefs); fun get_thm thy thmref = single_thm (name_of_thmref thmref) (get_thms thy thmref); (* thms_containing etc. *) fun valid_thms thy (thmref, ths) = (case try (transform_error (get_thms thy)) thmref of NONE => false | SOME ths' => Thm.eq_thms (ths, ths')); fun thms_containing theory spec = (theory :: Theory.ancestors_of theory) |> map (fn thy => FactIndex.find (fact_index_of thy) spec |> List.filter (fn (name, ths) => valid_thms theory (Name name, ths)) |> gen_distinct (eq_fst (op =))) |> List.concat; fun thms_containing_consts thy consts = thms_containing thy (consts, []) |> map #2 |> List.concat |> map (fn th => (Thm.name_of_thm th, th)); (* thms_of etc. *) fun thms_of thy = let val thms = #2 (theorems_of thy) in map (fn th => (Thm.name_of_thm th, th)) (List.concat (map snd (Symtab.dest thms))) end; fun all_thms_of thy = List.concat (map thms_of (thy :: Theory.ancestors_of thy)); (** store theorems **) (*DESTRUCTIVE*) (* hiding -- affects current theory node only *) fun hide_thms fully names thy = let val r as ref {theorems = (space, thms), index} = get_theorems_ref thy; val space' = fold (NameSpace.hide fully) names space; in r := {theorems = (space', thms), index = index}; thy end; (* naming *) fun gen_names j len name = map (fn i => name ^ "_" ^ string_of_int i) (j + 1 upto j + len); fun name_multi name xs = gen_names 0 (length xs) name ~~ xs; fun name_thm pre (name, thm) = if Thm.name_of_thm thm <> "" andalso pre then thm else Thm.name_thm (name, thm); fun name_thms pre name [x] = [name_thm pre (name, x)] | name_thms pre name xs = map (name_thm pre) (name_multi name xs); fun name_thmss name xs = (case filter_out (null o fst) xs of [([x], z)] => [([name_thm true (name, x)], z)] | _ => snd (foldl_map (fn (i, (ys, z)) => (i + length ys, (map (name_thm true) (gen_names i (length ys) name ~~ ys), z))) (0, xs))); (* enter_thms *) fun warn_overwrite name = warning ("Replaced old copy of theorems " ^ quote name); fun warn_same name = warning ("Theorem database already contains a copy of " ^ quote name); fun enter_thms _ _ app_att ("", thms) thy = app_att (thy, thms) | enter_thms pre_name post_name app_att (bname, thms) thy = let val name = Sign.full_name thy bname; val (thy', thms') = apsnd (post_name name) (app_att (thy, pre_name name thms)); val r as ref {theorems = (space, theorems), index} = get_theorems_ref thy'; val space' = Sign.declare_name thy' name space; val theorems' = Symtab.update (name, thms') theorems; val index' = FactIndex.add (K false) (name, thms') index; in (case Symtab.lookup theorems name of NONE => () | SOME thms'' => if Thm.eq_thms (thms', thms'') then warn_same name else warn_overwrite name); r := {theorems = (space', theorems'), index = index'}; (thy', thms') end; (* add_thms(s) *) fun add_thms_atts pre_name ((bname, thms), atts) = enter_thms pre_name (name_thms false) (Thm.applys_attributes o rpair atts) (bname, thms); fun gen_add_thmss pre_name args theory = foldl_map (fn (thy, arg) => add_thms_atts pre_name arg thy) (theory, args); fun gen_add_thms pre_name args = apsnd (map hd) o gen_add_thmss pre_name (map (apfst (apsnd single)) args); val add_thmss = gen_add_thmss (name_thms true); val add_thms = gen_add_thms (name_thms true); (* note_thmss(_i) *) local fun gen_note_thss get kind_att (thy, ((bname, more_atts), ths_atts)) = let fun app (x, (ths, atts)) = Thm.applys_attributes ((x, ths), atts); val (thy', thms) = thy |> enter_thms name_thmss (name_thms false) (apsnd List.concat o foldl_map app) (bname, map (fn (ths, atts) => (get thy ths, atts @ more_atts @ [kind_att])) ths_atts); in (thy', (bname, thms)) end; fun gen_note_thmss get kind_att args thy = foldl_map (gen_note_thss get kind_att) (thy, args); in val note_thmss = gen_note_thmss get_thms; val note_thmss_i = gen_note_thmss (K I); end; (* store_thm *) fun store_thm ((bname, thm), atts) thy = let val (thy', [th']) = add_thms_atts (name_thms true) ((bname, [thm]), atts) thy in (thy', th') end; (* smart_store_thms(_open) *) local fun smart_store _ (name, []) = error ("Cannot store empty list of theorems: " ^ quote name) | smart_store name_thm (name, [thm]) = #2 (enter_thms (name_thm true) (name_thm false) I (name, [thm]) (Thm.theory_of_thm thm)) | smart_store name_thm (name, thms) = let fun merge (thy, th) = Theory.merge (thy, Thm.theory_of_thm th); val thy = Library.foldl merge (Thm.theory_of_thm (hd thms), tl thms); in #2 (enter_thms (name_thm true) (name_thm false) I (name, thms) thy) end; in val smart_store_thms = smart_store name_thms; val smart_store_thms_open = smart_store (K (K I)); end; (* forall_elim_var(s) -- belongs to drule.ML *) fun forall_elim_vars_aux strip_vars i th = let val {thy, tpairs, prop, ...} = Thm.rep_thm th; val add_used = Term.fold_aterms (fn Var ((x, j), _) => if i = j then curry (op ins_string) x else I | _ => I); val used = fold (fn (t, u) => add_used t o add_used u) tpairs (add_used prop []); val vars = strip_vars prop; val cvars = (Term.variantlist (map #1 vars, used), vars) |> ListPair.map (fn (x, (_, T)) => Thm.cterm_of thy (Var ((x, i), T))); in fold Thm.forall_elim cvars th end; val forall_elim_vars = forall_elim_vars_aux Term.strip_all_vars; fun forall_elim_var i th = forall_elim_vars_aux (fn Const ("all", _) $ Abs (a, T, _) => [(a, T)] | _ => raise THM ("forall_elim_vars", i, [th])) i th; (* store axioms as theorems *) local fun get_ax thy (name, _) = Thm.get_axiom_i thy (Sign.full_name thy name); fun get_axs thy named_axs = map (forall_elim_vars 0 o get_ax thy) named_axs; fun add_single add (thy, ((name, ax), atts)) = let val named_ax = [(name, ax)]; val thy' = add named_ax thy; val thm = hd (get_axs thy' named_ax); in apsnd hd (gen_add_thms (K I) [((name, thm), atts)] thy') end; fun add_multi add (thy, ((name, axs), atts)) = let val named_axs = name_multi name axs; val thy' = add named_axs thy; val thms = get_axs thy' named_axs; in apsnd hd (gen_add_thmss (K I) [((name, thms), atts)] thy') end; fun add_singles add args thy = foldl_map (add_single add) (thy, args); fun add_multis add args thy = foldl_map (add_multi add) (thy, args); in val add_axioms = add_singles Theory.add_axioms; val add_axioms_i = add_singles Theory.add_axioms_i; val add_axiomss = add_multis Theory.add_axioms; val add_axiomss_i = add_multis Theory.add_axioms_i; val add_defs = add_singles o Theory.add_defs; val add_defs_i = add_singles o Theory.add_defs_i; val add_defss = add_multis o Theory.add_defs; val add_defss_i = add_multis o Theory.add_defs_i; end; (*** ML setup ***) (* generic_setup *) val generic_setup = Context.use_let "val setup: (theory -> theory) list" "Library.apply setup"; (* add_oracle *) fun add_oracle (name, T, oracle) = let val txt = "local\n\ \ type T = " ^ T ^ ";\n\ \ val oracle: theory -> T -> term = " ^ oracle ^ ";\n\ \ val name = " ^ quote name ^ ";\n\ \ exception Arg of T;\n\ \ val _ = Context.>> (Theory.add_oracle (name, fn (thy, Arg x) => oracle thy x));\n\ \ val thy = Context.the_context ();\n\ \ val invoke_" ^ name ^ " = Thm.invoke_oracle_i thy (Sign.full_name thy name);\n\ \in\n\ \ fun " ^ name ^ " thy x = invoke_" ^ name ^ " (thy, Arg x);\n\ \end;\n"; in Context.use_mltext_theory txt false end; (*** the ProtoPure theory ***) val aT = TFree ("'a", []); val A = Free ("A", propT); val proto_pure = Context.pre_pure_thy |> Compress.init_data |> Sign.init_data |> Theory.init_data |> Proofterm.init_data |> TheoremsData.init |> Theory.add_types [("fun", 2, NoSyn), ("prop", 0, NoSyn), ("itself", 1, NoSyn), ("dummy", 0, NoSyn)] |> Theory.add_nonterminals Syntax.pure_nonterms |> Theory.add_syntax Syntax.pure_syntax |> Theory.add_syntax Syntax.pure_appl_syntax |> Theory.add_modesyntax (Symbol.xsymbolsN, true) Syntax.pure_xsym_syntax |> Theory.add_syntax [("==>", "prop => prop => prop", Delimfix "op ==>"), (Term.dummy_patternN, "aprop", Delimfix "'_")] |> Theory.add_consts [("==", "'a => 'a => prop", InfixrName ("==", 2)), ("==>", "prop => prop => prop", Mixfix ("(_/ ==> _)", [2, 1], 1)), ("all", "('a => prop) => prop", Binder ("!!", 0, 0)), ("Goal", "prop => prop", NoSyn), ("TYPE", "'a itself", NoSyn), (Term.dummy_patternN, "'a", Delimfix "'_")] |> Theory.add_finals_i false [Const ("==", [aT, aT] ---> propT), Const ("==>", [propT, propT] ---> propT), Const ("all", (aT --> propT) --> propT), Const ("TYPE", a_itselfT), Const (Term.dummy_patternN, aT)] |> Theory.add_modesyntax ("", false) (Syntax.pure_syntax_output @ Syntax.pure_appl_syntax) |> Theory.add_trfuns Syntax.pure_trfuns |> Theory.add_trfunsT Syntax.pure_trfunsT |> Sign.local_path |> (#1 oo (add_defs_i false o map Thm.no_attributes)) [("Goal_def", Logic.mk_equals (Logic.mk_goal A, A))] |> (#1 o add_thmss [(("nothing", []), [])]) |> Theory.add_axioms_i Proofterm.equality_axms |> Theory.end_theory; structure ProtoPure = struct val thy = proto_pure; val Goal_def = get_axiom thy "Goal_def"; end; end; structure BasicPureThy: BASIC_PURE_THY = PureThy; open BasicPureThy;