--- a/src/Pure/Isar/old_locale.ML Wed Jan 21 16:47:02 2009 +0100
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,2485 +0,0 @@
-(* Title: Pure/Isar/locale.ML
- Author: Clemens Ballarin, TU Muenchen
- Author: Markus Wenzel, LMU/TU Muenchen
-
-Locales -- Isar proof contexts as meta-level predicates, with local
-syntax and implicit structures.
-
-Draws basic ideas from Florian Kammueller's original version of
-locales, but uses the richer infrastructure of Isar instead of the raw
-meta-logic. Furthermore, structured import of contexts (with merge
-and rename operations) are provided, as well as type-inference of the
-signature parts, and predicate definitions of the specification text.
-
-Interpretation enables the reuse of theorems of locales in other
-contexts, namely those defined by theories, structured proofs and
-locales themselves.
-
-See also:
-
-[1] Clemens Ballarin. Locales and Locale Expressions in Isabelle/Isar.
- In Stefano Berardi et al., Types for Proofs and Programs: International
- Workshop, TYPES 2003, Torino, Italy, LNCS 3085, pages 34-50, 2004.
-[2] Clemens Ballarin. Interpretation of Locales in Isabelle: Managing
- Dependencies between Locales. Technical Report TUM-I0607, Technische
- Universitaet Muenchen, 2006.
-[3] Clemens Ballarin. Interpretation of Locales in Isabelle: Theories and
- Proof Contexts. In J.M. Borwein and W.M. Farmer, MKM 2006, LNAI 4108,
- pages 31-43, 2006.
-*)
-
-(* TODO:
-- beta-eta normalisation of interpretation parameters
-- dangling type frees in locales
-- test subsumption of interpretations when merging theories
-*)
-
-signature OLD_LOCALE =
-sig
- datatype expr =
- Locale of string |
- Rename of expr * (string * mixfix option) option list |
- Merge of expr list
- val empty: expr
-
- val intern: theory -> xstring -> string
- val intern_expr: theory -> expr -> expr
- val extern: theory -> string -> xstring
- val init: string -> theory -> Proof.context
-
- (* The specification of a locale *)
- val parameters_of: theory -> string -> ((string * typ) * mixfix) list
- val parameters_of_expr: theory -> expr -> ((string * typ) * mixfix) list
- val local_asms_of: theory -> string -> (Attrib.binding * term list) list
- val global_asms_of: theory -> string -> (Attrib.binding * term list) list
-
- (* Theorems *)
- val intros: theory -> string -> thm list * thm list
- val dests: theory -> string -> thm list
- (* Not part of the official interface. DO NOT USE *)
- val facts_of: theory -> string -> (Attrib.binding * (thm list * Attrib.src list) list) list list
-
- (* Not part of the official interface. DO NOT USE *)
- val declarations_of: theory -> string -> declaration list * declaration list;
-
- (* Processing of locale statements *)
- val read_context_statement: string option -> Element.context list ->
- (string * string list) list list -> Proof.context ->
- string option * Proof.context * Proof.context * (term * term list) list list
- val read_context_statement_cmd: xstring option -> Element.context list ->
- (string * string list) list list -> Proof.context ->
- string option * Proof.context * Proof.context * (term * term list) list list
- val cert_context_statement: string option -> Element.context_i list ->
- (term * term list) list list -> Proof.context ->
- string option * Proof.context * Proof.context * (term * term list) list list
- val read_expr: expr -> Element.context list -> Proof.context ->
- Element.context_i list * Proof.context
- val cert_expr: expr -> Element.context_i list -> Proof.context ->
- Element.context_i list * Proof.context
-
- (* Diagnostic functions *)
- val print_locales: theory -> unit
- val print_locale: theory -> bool -> expr -> Element.context list -> unit
- val print_registrations: bool -> string -> Proof.context -> unit
-
- val add_locale: string -> bstring -> expr -> Element.context_i list -> theory
- -> string * Proof.context
- val add_locale_cmd: bstring -> expr -> Element.context list -> theory
- -> string * Proof.context
-
- (* Tactics *)
- val intro_locales_tac: bool -> Proof.context -> thm list -> tactic
-
- (* Storing results *)
- val global_note_qualified: string ->
- ((Binding.T * attribute list) * (thm list * attribute list) list) list ->
- theory -> (string * thm list) list * theory
- val local_note_qualified: string ->
- ((Binding.T * attribute list) * (thm list * attribute list) list) list ->
- Proof.context -> (string * thm list) list * Proof.context
- val add_thmss: string -> string -> (Attrib.binding * (thm list * Attrib.src list) list) list ->
- Proof.context -> Proof.context
- val add_type_syntax: string -> declaration -> Proof.context -> Proof.context
- val add_term_syntax: string -> declaration -> Proof.context -> Proof.context
- val add_declaration: string -> declaration -> Proof.context -> Proof.context
-
- (* Interpretation *)
- val get_interpret_morph: theory -> (Binding.T -> Binding.T) -> string * string ->
- (Morphism.morphism * ((typ Vartab.table * typ list) * (term Vartab.table * term list))) ->
- string -> term list -> Morphism.morphism
- val interpretation: (Proof.context -> Proof.context) ->
- (Binding.T -> Binding.T) -> expr ->
- term option list * (Attrib.binding * term) list ->
- theory ->
- (Morphism.morphism * ((typ Vartab.table * typ list) * (term Vartab.table * term list))) * Proof.state
- val interpretation_cmd: string -> expr -> string option list * (Attrib.binding * string) list ->
- theory -> Proof.state
- val interpretation_in_locale: (Proof.context -> Proof.context) ->
- xstring * expr -> theory -> Proof.state
- val interpret: (Proof.state -> Proof.state) ->
- (Binding.T -> Binding.T) -> expr ->
- term option list * (Attrib.binding * term) list ->
- bool -> Proof.state ->
- (Morphism.morphism * ((typ Vartab.table * typ list) * (term Vartab.table * term list))) * Proof.state
- val interpret_cmd: string -> expr -> string option list * (Attrib.binding * string) list ->
- bool -> Proof.state -> Proof.state
-end;
-
-structure Old_Locale: OLD_LOCALE =
-struct
-
-(* legacy operations *)
-
-fun merge_lists _ xs [] = xs
- | merge_lists _ [] ys = ys
- | merge_lists eq xs ys = xs @ filter_out (member eq xs) ys;
-
-fun merge_alists eq xs = merge_lists (eq_fst eq) xs;
-
-
-(* auxiliary: noting name bindings with qualified base names *)
-
-fun global_note_qualified kind facts thy =
- thy
- |> Sign.qualified_names
- |> PureThy.note_thmss kind facts
- ||> Sign.restore_naming thy;
-
-fun local_note_qualified kind facts ctxt =
- ctxt
- |> ProofContext.qualified_names
- |> ProofContext.note_thmss_i kind facts
- ||> ProofContext.restore_naming ctxt;
-
-
-(** locale elements and expressions **)
-
-datatype ctxt = datatype Element.ctxt;
-
-datatype expr =
- Locale of string |
- Rename of expr * (string * mixfix option) option list |
- Merge of expr list;
-
-val empty = Merge [];
-
-datatype 'a element =
- Elem of 'a | Expr of expr;
-
-fun map_elem f (Elem e) = Elem (f e)
- | map_elem _ (Expr e) = Expr e;
-
-type decl = declaration * stamp;
-
-type locale =
- {axiom: Element.witness list,
- (* For locales that define predicates this is [A [A]], where A is the locale
- specification. Otherwise [].
- Only required to generate the right witnesses for locales with predicates. *)
- elems: (Element.context_i * stamp) list,
- (* Static content, neither Fixes nor Constrains elements *)
- params: ((string * typ) * mixfix) list, (*all term params*)
- decls: decl list * decl list, (*type/term_syntax declarations*)
- regs: ((string * string list) * Element.witness list) list,
- (* Registrations: indentifiers and witnesses of locales interpreted in the locale. *)
- intros: thm list * thm list,
- (* Introduction rules: of delta predicate and locale predicate. *)
- dests: thm list}
- (* Destruction rules: projections from locale predicate to predicates of fragments. *)
-
-(* CB: an internal (Int) locale element was either imported or included,
- an external (Ext) element appears directly in the locale text. *)
-
-datatype ('a, 'b) int_ext = Int of 'a | Ext of 'b;
-
-
-
-(** substitutions on Vars -- clone from element.ML **)
-
-(* instantiate types *)
-
-fun var_instT_type env =
- if Vartab.is_empty env then I
- else Term.map_type_tvar (fn (x, S) => the_default (TVar (x, S)) (Vartab.lookup env x));
-
-fun var_instT_term env =
- if Vartab.is_empty env then I
- else Term.map_types (var_instT_type env);
-
-fun var_inst_term (envT, env) =
- if Vartab.is_empty env then var_instT_term envT
- else
- let
- val instT = var_instT_type envT;
- fun inst (Const (x, T)) = Const (x, instT T)
- | inst (Free (x, T)) = Free(x, instT T)
- | inst (Var (xi, T)) =
- (case Vartab.lookup env xi of
- NONE => Var (xi, instT T)
- | SOME t => t)
- | inst (b as Bound _) = b
- | inst (Abs (x, T, t)) = Abs (x, instT T, inst t)
- | inst (t $ u) = inst t $ inst u;
- in Envir.beta_norm o inst end;
-
-
-(** management of registrations in theories and proof contexts **)
-
-type registration =
- {prfx: (Binding.T -> Binding.T) * (string * string),
- (* first component: interpretation name morphism;
- second component: parameter prefix *)
- exp: Morphism.morphism,
- (* maps content to its originating context *)
- imp: (typ Vartab.table * typ list) * (term Vartab.table * term list),
- (* inverse of exp *)
- wits: Element.witness list,
- (* witnesses of the registration *)
- eqns: thm Termtab.table,
- (* theorems (equations) interpreting derived concepts and indexed by lhs *)
- morph: unit
- (* interpreting morphism *)
- }
-
-structure Registrations :
- sig
- type T
- val empty: T
- val join: T * T -> T
- val dest: theory -> T ->
- (term list *
- (((Binding.T -> Binding.T) * (string * string)) *
- (Morphism.morphism * ((typ Vartab.table * typ list) * (term Vartab.table * term list))) *
- Element.witness list *
- thm Termtab.table)) list
- val test: theory -> T * term list -> bool
- val lookup: theory ->
- T * (term list * ((typ Vartab.table * typ list) * (term Vartab.table * term list))) ->
- (((Binding.T -> Binding.T) * (string * string)) * Element.witness list * thm Termtab.table) option
- val insert: theory -> term list -> ((Binding.T -> Binding.T) * (string * string)) ->
- (Morphism.morphism * ((typ Vartab.table * typ list) * (term Vartab.table * term list))) ->
- T ->
- T * (term list * (((Binding.T -> Binding.T) * (string * string)) * Element.witness list)) list
- val add_witness: term list -> Element.witness -> T -> T
- val add_equation: term list -> thm -> T -> T
-(*
- val update_morph: term list -> Morphism.morphism -> T -> T
- val get_morph: theory -> T ->
- term list * ((typ Vartab.table * typ list) * (term Vartab.table * term list)) ->
- Morphism.morphism
-*)
- end =
-struct
- (* A registration is indexed by parameter instantiation.
- NB: index is exported whereas content is internalised. *)
- type T = registration Termtab.table;
-
- fun mk_reg prfx exp imp wits eqns morph =
- {prfx = prfx, exp = exp, imp = imp, wits = wits, eqns = eqns, morph = morph};
-
- fun map_reg f reg =
- let
- val {prfx, exp, imp, wits, eqns, morph} = reg;
- val (prfx', exp', imp', wits', eqns', morph') = f (prfx, exp, imp, wits, eqns, morph);
- in mk_reg prfx' exp' imp' wits' eqns' morph' end;
-
- val empty = Termtab.empty;
-
- (* term list represented as single term, for simultaneous matching *)
- fun termify ts =
- Term.list_comb (Const ("", map fastype_of ts ---> propT), ts);
- fun untermify t =
- let fun ut (Const _) ts = ts
- | ut (s $ t) ts = ut s (t::ts)
- in ut t [] end;
-
- (* joining of registrations:
- - prefix and morphisms of right theory;
- - witnesses are equal, no attempt to subsumption testing;
- - union of equalities, if conflicting (i.e. two eqns with equal lhs)
- eqn of right theory takes precedence *)
- fun join (r1, r2) = Termtab.join (fn _ => fn ({eqns = e1, ...}, {prfx = n, exp, imp, wits = w, eqns = e2, morph = m}) =>
- mk_reg n exp imp w (Termtab.join (fn _ => fn (_, e) => e) (e1, e2)) m) (r1, r2);
-
- fun dest_transfer thy regs =
- Termtab.dest regs |> map (apsnd (map_reg (fn (n, e, i, ws, es, m) =>
- (n, e, i, map (Element.transfer_witness thy) ws, Termtab.map (transfer thy) es, m))));
-
- fun dest thy regs = dest_transfer thy regs |> map (apfst untermify) |>
- map (apsnd (fn {prfx, exp, imp, wits, eqns, ...} => (prfx, (exp, imp), wits, eqns)));
-
- (* registrations that subsume t *)
- fun subsumers thy t regs =
- filter (fn (t', _) => Pattern.matches thy (t', t)) (dest_transfer thy regs);
-
- (* test if registration that subsumes the query is present *)
- fun test thy (regs, ts) =
- not (null (subsumers thy (termify ts) regs));
-
- (* look up registration, pick one that subsumes the query *)
- fun lookup thy (regs, (ts, ((impT, _), (imp, _)))) =
- let
- val t = termify ts;
- val subs = subsumers thy t regs;
- in
- (case subs of
- [] => NONE
- | ((t', {prfx, exp = exp', imp = ((impT', domT'), (imp', dom')), wits, eqns, morph}) :: _) =>
- let
- val (tinst, inst) = Pattern.match thy (t', t) (Vartab.empty, Vartab.empty);
- val tinst' = domT' |> map (fn (T as TFree (x, _)) =>
- (x, T |> Morphism.typ exp' |> Envir.typ_subst_TVars tinst
- |> var_instT_type impT)) |> Symtab.make;
- val inst' = dom' |> map (fn (t as Free (x, _)) =>
- (x, t |> Morphism.term exp' |> Envir.subst_vars (tinst, inst)
- |> var_inst_term (impT, imp))) |> Symtab.make;
- val inst'_morph = Element.inst_morphism thy (tinst', inst');
- in SOME (prfx,
- map (Element.morph_witness inst'_morph) wits,
- Termtab.map (Morphism.thm inst'_morph) eqns)
- end)
- end;
-
- (* add registration if not subsumed by ones already present,
- additionally returns registrations that are strictly subsumed *)
- fun insert thy ts prfx (exp, imp) regs =
- let
- val t = termify ts;
- val subs = subsumers thy t regs ;
- in (case subs of
- [] => let
- val sups =
- filter (fn (t', _) => Pattern.matches thy (t, t')) (dest_transfer thy regs);
- val sups' = map (apfst untermify) sups |> map (fn (ts, {prfx, wits, ...}) => (ts, (prfx, wits)))
- in (Termtab.update (t, mk_reg prfx exp imp [] Termtab.empty ()) regs, sups') end
- | _ => (regs, []))
- end;
-
- fun gen_add f ts regs =
- let
- val t = termify ts;
- in
- Termtab.update (t, map_reg f (the (Termtab.lookup regs t))) regs
- end;
-
- (* add witness theorem to registration,
- only if instantiation is exact, otherwise exception Option raised *)
- fun add_witness ts wit regs =
- gen_add (fn (x, e, i, wits, eqns, m) => (x, e, i, Element.close_witness wit :: wits, eqns, m))
- ts regs;
-
- (* add equation to registration, replaces previous equation with same lhs;
- only if instantiation is exact, otherwise exception Option raised;
- exception TERM raised if not a meta equality *)
- fun add_equation ts thm regs =
- gen_add (fn (x, e, i, thms, eqns, m) =>
- (x, e, i, thms, Termtab.update (thm |> prop_of |> Logic.dest_equals |> fst, Thm.close_derivation thm) eqns, m))
- ts regs;
-
-end;
-
-
-(** theory data : locales **)
-
-structure LocalesData = TheoryDataFun
-(
- type T = NameSpace.T * locale Symtab.table;
- (* 1st entry: locale namespace,
- 2nd entry: locales of the theory *)
-
- val empty = NameSpace.empty_table;
- val copy = I;
- val extend = I;
-
- fun join_locales _
- ({axiom, elems, params, decls = (decls1, decls2), regs, intros, dests}: locale,
- {elems = elems', decls = (decls1', decls2'), regs = regs', ...}: locale) =
- {axiom = axiom,
- elems = merge_lists (eq_snd (op =)) elems elems',
- params = params,
- decls =
- (Library.merge (eq_snd (op =)) (decls1, decls1'),
- Library.merge (eq_snd (op =)) (decls2, decls2')),
- regs = merge_alists (op =) regs regs',
- intros = intros,
- dests = dests};
- fun merge _ = NameSpace.join_tables join_locales;
-);
-
-
-
-(** context data : registrations **)
-
-structure RegistrationsData = GenericDataFun
-(
- type T = Registrations.T Symtab.table; (*registrations, indexed by locale name*)
- val empty = Symtab.empty;
- val extend = I;
- fun merge _ = Symtab.join (K Registrations.join);
-);
-
-
-(** access locales **)
-
-val intern = NameSpace.intern o #1 o LocalesData.get;
-val extern = NameSpace.extern o #1 o LocalesData.get;
-
-fun get_locale thy name = Symtab.lookup (#2 (LocalesData.get thy)) name;
-
-fun the_locale thy name = case get_locale thy name
- of SOME loc => loc
- | NONE => error ("Unknown locale " ^ quote name);
-
-fun register_locale bname loc thy =
- thy |> LocalesData.map (NameSpace.bind (Sign.naming_of thy)
- (Binding.name bname, loc) #> snd);
-
-fun change_locale name f thy =
- let
- val {axiom, elems, params, decls, regs, intros, dests} =
- the_locale thy name;
- val (axiom', elems', params', decls', regs', intros', dests') =
- f (axiom, elems, params, decls, regs, intros, dests);
- in
- thy
- |> (LocalesData.map o apsnd) (Symtab.update (name, {axiom = axiom',
- elems = elems', params = params',
- decls = decls', regs = regs', intros = intros', dests = dests'}))
- end;
-
-fun print_locales thy =
- let val (space, locs) = LocalesData.get thy in
- Pretty.strs ("locales:" :: map #1 (NameSpace.extern_table (space, locs)))
- |> Pretty.writeln
- end;
-
-
-(* access registrations *)
-
-(* retrieve registration from theory or context *)
-
-fun get_registrations ctxt name =
- case Symtab.lookup (RegistrationsData.get ctxt) name of
- NONE => []
- | SOME reg => Registrations.dest (Context.theory_of ctxt) reg;
-
-fun get_global_registrations thy = get_registrations (Context.Theory thy);
-fun get_local_registrations ctxt = get_registrations (Context.Proof ctxt);
-
-
-fun get_registration ctxt imprt (name, ps) =
- case Symtab.lookup (RegistrationsData.get ctxt) name of
- NONE => NONE
- | SOME reg => Registrations.lookup (Context.theory_of ctxt) (reg, (ps, imprt));
-
-fun get_global_registration thy = get_registration (Context.Theory thy);
-fun get_local_registration ctxt = get_registration (Context.Proof ctxt);
-
-
-fun test_registration ctxt (name, ps) =
- case Symtab.lookup (RegistrationsData.get ctxt) name of
- NONE => false
- | SOME reg => Registrations.test (Context.theory_of ctxt) (reg, ps);
-
-fun test_global_registration thy = test_registration (Context.Theory thy);
-fun test_local_registration ctxt = test_registration (Context.Proof ctxt);
-
-
-(* add registration to theory or context, ignored if subsumed *)
-
-fun put_registration (name, ps) prfx morphs ctxt =
- RegistrationsData.map (fn regs =>
- let
- val thy = Context.theory_of ctxt;
- val reg = the_default Registrations.empty (Symtab.lookup regs name);
- val (reg', sups) = Registrations.insert thy ps prfx morphs reg;
- val _ = if not (null sups) then warning
- ("Subsumed interpretation(s) of locale " ^
- quote (extern thy name) ^
- "\nwith the following prefix(es):" ^
- commas_quote (map (fn (_, ((_, (_, s)), _)) => s) sups))
- else ();
- in Symtab.update (name, reg') regs end) ctxt;
-
-fun put_global_registration id prfx morphs =
- Context.theory_map (put_registration id prfx morphs);
-fun put_local_registration id prfx morphs =
- Context.proof_map (put_registration id prfx morphs);
-
-fun put_registration_in_locale name id =
- change_locale name (fn (axiom, elems, params, decls, regs, intros, dests) =>
- (axiom, elems, params, decls, regs @ [(id, [])], intros, dests));
-
-
-(* add witness theorem to registration, ignored if registration not present *)
-
-fun add_witness (name, ps) thm =
- RegistrationsData.map (Symtab.map_entry name (Registrations.add_witness ps thm));
-
-fun add_global_witness id thm = Context.theory_map (add_witness id thm);
-fun add_local_witness id thm = Context.proof_map (add_witness id thm);
-
-
-fun add_witness_in_locale name id thm =
- change_locale name (fn (axiom, elems, params, decls, regs, intros, dests) =>
- let
- fun add (id', thms) =
- if id = id' then (id', thm :: thms) else (id', thms);
- in (axiom, elems, params, decls, map add regs, intros, dests) end);
-
-
-(* add equation to registration, ignored if registration not present *)
-
-fun add_equation (name, ps) thm =
- RegistrationsData.map (Symtab.map_entry name (Registrations.add_equation ps thm));
-
-fun add_global_equation id thm = Context.theory_map (add_equation id thm);
-fun add_local_equation id thm = Context.proof_map (add_equation id thm);
-
-(*
-(* update morphism of registration, ignored if registration not present *)
-
-fun update_morph (name, ps) morph =
- RegistrationsData.map (Symtab.map_entry name (Registrations.update_morph ps morph));
-
-fun update_global_morph id morph = Context.theory_map (update_morph id morph);
-fun update_local_morph id morph = Context.proof_map (update_morph id morph);
-*)
-
-
-(* printing of registrations *)
-
-fun print_registrations show_wits loc ctxt =
- let
- val thy = ProofContext.theory_of ctxt;
- val prt_term = Pretty.quote o Syntax.pretty_term ctxt;
- fun prt_term' t = if !show_types
- then Pretty.block [prt_term t, Pretty.brk 1, Pretty.str "::",
- Pretty.brk 1, (Pretty.quote o Syntax.pretty_typ ctxt) (type_of t)]
- else prt_term t;
- val prt_thm = prt_term o prop_of;
- fun prt_inst ts =
- Pretty.enclose "(" ")" (Pretty.breaks (map prt_term' ts));
- fun prt_prfx ((false, prfx), param_prfx) = [Pretty.str prfx, Pretty.brk 1, Pretty.str "(optional)", Pretty.brk 1, Pretty.str param_prfx]
- | prt_prfx ((true, prfx), param_prfx) = [Pretty.str prfx, Pretty.brk 1, Pretty.str param_prfx];
- fun prt_eqns [] = Pretty.str "no equations."
- | prt_eqns eqns = Pretty.block (Pretty.str "equations:" :: Pretty.brk 1 ::
- Pretty.breaks (map prt_thm eqns));
- fun prt_core ts eqns =
- [prt_inst ts, Pretty.fbrk, prt_eqns (Termtab.dest eqns |> map snd)];
- fun prt_witns [] = Pretty.str "no witnesses."
- | prt_witns witns = Pretty.block (Pretty.str "witnesses:" :: Pretty.brk 1 ::
- Pretty.breaks (map (Element.pretty_witness ctxt) witns))
- fun prt_reg (ts, (_, _, witns, eqns)) =
- if show_wits
- then Pretty.block (prt_core ts eqns @ [Pretty.fbrk, prt_witns witns])
- else Pretty.block (prt_core ts eqns)
-
- val loc_int = intern thy loc;
- val regs = RegistrationsData.get (Context.Proof ctxt);
- val loc_regs = Symtab.lookup regs loc_int;
- in
- (case loc_regs of
- NONE => Pretty.str ("no interpretations")
- | SOME r => let
- val r' = Registrations.dest thy r;
- val r'' = Library.sort_wrt (fn (_, ((_, (_, prfx)), _, _, _)) => prfx) r';
- in Pretty.big_list ("interpretations:") (map prt_reg r'') end)
- |> Pretty.writeln
- end;
-
-
-(* diagnostics *)
-
-fun err_in_locale ctxt msg ids =
- let
- val thy = ProofContext.theory_of ctxt;
- fun prt_id (name, parms) =
- [Pretty.block (Pretty.breaks (map Pretty.str (extern thy name :: parms)))];
- val prt_ids = flat (separate [Pretty.str " +", Pretty.brk 1] (map prt_id ids));
- val err_msg =
- if forall (fn (s, _) => s = "") ids then msg
- else msg ^ "\n" ^ Pretty.string_of (Pretty.block
- (Pretty.str "The error(s) above occurred in locale:" :: Pretty.brk 1 :: prt_ids));
- in error err_msg end;
-
-fun err_in_locale' ctxt msg ids' = err_in_locale ctxt msg (map fst ids');
-
-
-fun pretty_ren NONE = Pretty.str "_"
- | pretty_ren (SOME (x, NONE)) = Pretty.str x
- | pretty_ren (SOME (x, SOME syn)) =
- Pretty.block [Pretty.str x, Pretty.brk 1, Syntax.pretty_mixfix syn];
-
-fun pretty_expr thy (Locale name) = Pretty.str (extern thy name)
- | pretty_expr thy (Rename (expr, xs)) =
- Pretty.block [pretty_expr thy expr, Pretty.brk 1, Pretty.block (map pretty_ren xs |> Pretty.breaks)]
- | pretty_expr thy (Merge es) =
- Pretty.separate "+" (map (pretty_expr thy) es) |> Pretty.block;
-
-fun err_in_expr _ msg (Merge []) = error msg
- | err_in_expr ctxt msg expr =
- error (msg ^ "\n" ^ Pretty.string_of (Pretty.block
- [Pretty.str "The error(s) above occured in locale expression:", Pretty.brk 1,
- pretty_expr (ProofContext.theory_of ctxt) expr]));
-
-
-(** structured contexts: rename + merge + implicit type instantiation **)
-
-(* parameter types *)
-
-fun frozen_tvars ctxt Ts =
- #1 (Variable.importT_inst (map Logic.mk_type Ts) ctxt)
- |> map (fn ((xi, S), T) => (xi, (S, T)));
-
-fun unify_frozen ctxt maxidx Ts Us =
- let
- fun paramify NONE i = (NONE, i)
- | paramify (SOME T) i = apfst SOME (TypeInfer.paramify_dummies T i);
-
- val (Ts', maxidx') = fold_map paramify Ts maxidx;
- val (Us', maxidx'') = fold_map paramify Us maxidx';
- val thy = ProofContext.theory_of ctxt;
-
- fun unify (SOME T, SOME U) env = (Sign.typ_unify thy (U, T) env
- handle Type.TUNIFY => raise TYPE ("unify_frozen: failed to unify types", [U, T], []))
- | unify _ env = env;
- val (unifier, _) = fold unify (Ts' ~~ Us') (Vartab.empty, maxidx'');
- val Vs = map (Option.map (Envir.norm_type unifier)) Us';
- val unifier' = fold Vartab.update_new (frozen_tvars ctxt (map_filter I Vs)) unifier;
- in map (Option.map (Envir.norm_type unifier')) Vs end;
-
-fun params_of elemss =
- distinct (eq_fst (op = : string * string -> bool)) (maps (snd o fst) elemss);
-
-fun params_of' elemss =
- distinct (eq_fst (op = : string * string -> bool)) (maps (snd o fst o fst) elemss);
-
-fun param_prefix locale_name params = (NameSpace.base locale_name ^ "_locale", space_implode "_" params);
-
-
-(* CB: param_types has the following type:
- ('a * 'b option) list -> ('a * 'b) list *)
-fun param_types ps = map_filter (fn (_, NONE) => NONE | (x, SOME T) => SOME (x, T)) ps;
-
-
-fun merge_syntax ctxt ids ss = Symtab.merge (op = : mixfix * mixfix -> bool) ss
- handle Symtab.DUP x => err_in_locale ctxt
- ("Conflicting syntax for parameter: " ^ quote x) (map fst ids);
-
-
-(* Distinction of assumed vs. derived identifiers.
- The former may have axioms relating assumptions of the context to
- assumptions of the specification fragment (for locales with
- predicates). The latter have witnesses relating assumptions of the
- specification fragment to assumptions of other (assumed) specification
- fragments. *)
-
-datatype 'a mode = Assumed of 'a | Derived of 'a;
-
-fun map_mode f (Assumed x) = Assumed (f x)
- | map_mode f (Derived x) = Derived (f x);
-
-
-(* flatten expressions *)
-
-local
-
-fun unify_parms ctxt fixed_parms raw_parmss =
- let
- val thy = ProofContext.theory_of ctxt;
- val maxidx = length raw_parmss;
- val idx_parmss = (0 upto maxidx - 1) ~~ raw_parmss;
-
- fun varify i = Term.map_type_tfree (fn (a, S) => TVar ((a, i), S));
- fun varify_parms (i, ps) = map (apsnd (varify i)) (param_types ps);
- val parms = fixed_parms @ maps varify_parms idx_parmss;
-
- fun unify T U envir = Sign.typ_unify thy (U, T) envir
- handle Type.TUNIFY =>
- let
- val T' = Envir.norm_type (fst envir) T;
- val U' = Envir.norm_type (fst envir) U;
- val prt = Syntax.string_of_typ ctxt;
- in
- raise TYPE ("unify_parms: failed to unify types " ^
- prt U' ^ " and " ^ prt T', [U', T'], [])
- end;
- fun unify_list (T :: Us) = fold (unify T) Us
- | unify_list [] = I;
- val (unifier, _) = fold unify_list (map #2 (Symtab.dest (Symtab.make_list parms)))
- (Vartab.empty, maxidx);
-
- val parms' = map (apsnd (Envir.norm_type unifier)) (distinct (eq_fst (op =)) parms);
- val unifier' = fold Vartab.update_new (frozen_tvars ctxt (map #2 parms')) unifier;
-
- fun inst_parms (i, ps) =
- List.foldr OldTerm.add_typ_tfrees [] (map_filter snd ps)
- |> map_filter (fn (a, S) =>
- let val T = Envir.norm_type unifier' (TVar ((a, i), S))
- in if T = TFree (a, S) then NONE else SOME (a, T) end)
- |> Symtab.make;
- in map inst_parms idx_parmss end;
-
-in
-
-fun unify_elemss _ _ [] = []
- | unify_elemss _ [] [elems] = [elems]
- | unify_elemss ctxt fixed_parms elemss =
- let
- val thy = ProofContext.theory_of ctxt;
- val phis = unify_parms ctxt fixed_parms (map (snd o fst o fst) elemss)
- |> map (Element.instT_morphism thy);
- fun inst ((((name, ps), mode), elems), phi) =
- (((name, map (apsnd (Option.map (Morphism.typ phi))) ps),
- map_mode (map (Element.morph_witness phi)) mode),
- map (Element.morph_ctxt phi) elems);
- in map inst (elemss ~~ phis) end;
-
-
-fun renaming xs parms = zip_options parms xs
- handle Library.UnequalLengths =>
- error ("Too many arguments in renaming: " ^
- commas (map (fn NONE => "_" | SOME x => quote (fst x)) xs));
-
-
-(* params_of_expr:
- Compute parameters (with types and syntax) of locale expression.
-*)
-
-fun params_of_expr ctxt fixed_params expr (prev_parms, prev_types, prev_syn) =
- let
- val thy = ProofContext.theory_of ctxt;
-
- fun merge_tenvs fixed tenv1 tenv2 =
- let
- val [env1, env2] = unify_parms ctxt fixed
- [tenv1 |> Symtab.dest |> map (apsnd SOME),
- tenv2 |> Symtab.dest |> map (apsnd SOME)]
- in
- Symtab.merge (op =) (Symtab.map (Element.instT_type env1) tenv1,
- Symtab.map (Element.instT_type env2) tenv2)
- end;
-
- fun merge_syn expr syn1 syn2 =
- Symtab.merge (op = : mixfix * mixfix -> bool) (syn1, syn2)
- handle Symtab.DUP x => err_in_expr ctxt
- ("Conflicting syntax for parameter: " ^ quote x) expr;
-
- fun params_of (expr as Locale name) =
- let
- val {params, ...} = the_locale thy name;
- in (map (fst o fst) params, params |> map fst |> Symtab.make,
- params |> map (apfst fst) |> Symtab.make) end
- | params_of (expr as Rename (e, xs)) =
- let
- val (parms', types', syn') = params_of e;
- val ren = renaming xs parms';
- (* renaming may reduce number of parameters *)
- val new_parms = map (Element.rename ren) parms' |> distinct (op =);
- val ren_syn = syn' |> Symtab.dest |> map (Element.rename_var_name ren);
- val new_syn = fold (Symtab.insert (op =)) ren_syn Symtab.empty
- handle Symtab.DUP x =>
- err_in_expr ctxt ("Conflicting syntax for parameter: " ^ quote x) expr;
- val syn_types = map (apsnd (fn mx =>
- SOME (Type.freeze_type (#1 (TypeInfer.paramify_dummies (Syntax.mixfixT mx) 0)))))
- (Symtab.dest new_syn);
- val ren_types = types' |> Symtab.dest |> map (apfst (Element.rename ren));
- val (env :: _) = unify_parms ctxt []
- ((ren_types |> map (apsnd SOME)) :: map single syn_types);
- val new_types = fold (Symtab.insert (op =))
- (map (apsnd (Element.instT_type env)) ren_types) Symtab.empty;
- in (new_parms, new_types, new_syn) end
- | params_of (Merge es) =
- fold (fn e => fn (parms, types, syn) =>
- let
- val (parms', types', syn') = params_of e
- in
- (merge_lists (op =) parms parms', merge_tenvs [] types types',
- merge_syn e syn syn')
- end)
- es ([], Symtab.empty, Symtab.empty)
-
- val (parms, types, syn) = params_of expr;
- in
- (merge_lists (op =) prev_parms parms, merge_tenvs fixed_params prev_types types,
- merge_syn expr prev_syn syn)
- end;
-
-fun make_params_ids params = [(("", params), ([], Assumed []))];
-fun make_raw_params_elemss (params, tenv, syn) =
- [((("", map (fn p => (p, Symtab.lookup tenv p)) params), Assumed []),
- Int [Fixes (map (fn p =>
- (Binding.name p, Symtab.lookup tenv p, Symtab.lookup syn p |> the)) params)])];
-
-
-(* flatten_expr:
- Extend list of identifiers by those new in locale expression expr.
- Compute corresponding list of lists of locale elements (one entry per
- identifier).
-
- Identifiers represent locale fragments and are in an extended form:
- ((name, ps), (ax_ps, axs))
- (name, ps) is the locale name with all its parameters.
- (ax_ps, axs) is the locale axioms with its parameters;
- axs are always taken from the top level of the locale hierarchy,
- hence axioms may contain additional parameters from later fragments:
- ps subset of ax_ps. axs is either singleton or empty.
-
- Elements are enriched by identifier-like information:
- (((name, ax_ps), axs), elems)
- The parameters in ax_ps are the axiom parameters, but enriched by type
- info: now each entry is a pair of string and typ option. Axioms are
- type-instantiated.
-
-*)
-
-fun flatten_expr ctxt ((prev_idents, prev_syntax), expr) =
- let
- val thy = ProofContext.theory_of ctxt;
-
- fun rename_parms top ren ((name, ps), (parms, mode)) =
- ((name, map (Element.rename ren) ps),
- if top
- then (map (Element.rename ren) parms,
- map_mode (map (Element.morph_witness (Element.rename_morphism ren))) mode)
- else (parms, mode));
-
- (* add (name, pTs) and its registrations, recursively; adjust hyps of witnesses *)
-
- fun add_with_regs ((name, pTs), mode) (wits, ids, visited) =
- if member (fn (a, (b, _)) => a = b) visited (name, map #1 pTs)
- then (wits, ids, visited)
- else
- let
- val {params, regs, ...} = the_locale thy name;
- val pTs' = map #1 params;
- val ren = map #1 pTs' ~~ map (fn (x, _) => (x, NONE)) pTs;
- (* dummy syntax, since required by rename *)
- val pTs'' = map (fn ((p, _), (_, T)) => (p, T)) (pTs ~~ pTs');
- val [env] = unify_parms ctxt pTs [map (apsnd SOME) pTs''];
- (* propagate parameter types, to keep them consistent *)
- val regs' = map (fn ((name, ps), wits) =>
- ((name, map (Element.rename ren) ps),
- map (Element.transfer_witness thy) wits)) regs;
- val new_regs = regs';
- val new_ids = map fst new_regs;
- val new_idTs =
- map (apsnd (map (fn p => (p, (the o AList.lookup (op =) pTs) p)))) new_ids;
-
- val new_wits = new_regs |> map (#2 #> map
- (Element.morph_witness
- (Element.instT_morphism thy env $>
- Element.rename_morphism ren $>
- Element.satisfy_morphism wits)
- #> Element.close_witness));
- val new_ids' = map (fn (id, wits) =>
- (id, ([], Derived wits))) (new_ids ~~ new_wits);
- val new_idTs' = map (fn ((n, pTs), (_, ([], mode))) =>
- ((n, pTs), mode)) (new_idTs ~~ new_ids');
- val new_id = ((name, map #1 pTs), ([], mode));
- val (wits', ids', visited') = fold add_with_regs new_idTs'
- (wits @ flat new_wits, ids, visited @ [new_id]);
- in
- (wits', ids' @ [new_id], visited')
- end;
-
- (* distribute top-level axioms over assumed ids *)
-
- fun axiomify all_ps ((name, parms), (_, Assumed _)) axioms =
- let
- val {elems, ...} = the_locale thy name;
- val ts = maps
- (fn (Assumes asms, _) => maps (map #1 o #2) asms
- | _ => [])
- elems;
- val (axs1, axs2) = chop (length ts) axioms;
- in (((name, parms), (all_ps, Assumed axs1)), axs2) end
- | axiomify all_ps (id, (_, Derived ths)) axioms =
- ((id, (all_ps, Derived ths)), axioms);
-
- (* identifiers of an expression *)
-
- fun identify top (Locale name) =
- (* CB: ids_ax is a list of tuples of the form ((name, ps), axs),
- where name is a locale name, ps a list of parameter names and axs
- a list of axioms relating to the identifier, axs is empty unless
- identify at top level (top = true);
- parms is accumulated list of parameters *)
- let
- val {axiom, params, ...} = the_locale thy name;
- val ps = map (#1 o #1) params;
- val (_, ids'', _) = add_with_regs ((name, map #1 params), Assumed []) ([], [], []);
- val ids_ax = if top then fst (fold_map (axiomify ps) ids'' axiom) else ids'';
- in (ids_ax, ps) end
- | identify top (Rename (e, xs)) =
- let
- val (ids', parms') = identify top e;
- val ren = renaming xs parms'
- handle ERROR msg => err_in_locale' ctxt msg ids';
-
- val ids'' = distinct (eq_fst (op =)) (map (rename_parms top ren) ids');
- val parms'' = distinct (op =) (maps (#2 o #1) ids'');
- in (ids'', parms'') end
- | identify top (Merge es) =
- fold (fn e => fn (ids, parms) =>
- let
- val (ids', parms') = identify top e
- in
- (merge_alists (op =) ids ids', merge_lists (op =) parms parms')
- end)
- es ([], []);
-
- fun inst_wit all_params (t, th) = let
- val {hyps, prop, ...} = Thm.rep_thm th;
- val ps = map (apsnd SOME) (fold Term.add_frees (prop :: hyps) []);
- val [env] = unify_parms ctxt all_params [ps];
- val t' = Element.instT_term env t;
- val th' = Element.instT_thm thy env th;
- in (t', th') end;
-
- fun eval all_params tenv syn ((name, params), (locale_params, mode)) =
- let
- val {params = ps_mx, elems = elems_stamped, ...} = the_locale thy name;
- val elems = map fst elems_stamped;
- val ps = map fst ps_mx;
- fun lookup_syn x = (case Symtab.lookup syn x of SOME Structure => NONE | opt => opt);
- val locale_params' = map (fn p => (p, Symtab.lookup tenv p |> the)) locale_params;
- val mode' = map_mode (map (Element.map_witness (inst_wit all_params))) mode;
- val ren = map fst ps ~~ map (fn p => (p, lookup_syn p)) params;
- val [env] = unify_parms ctxt all_params [map (apfst (Element.rename ren) o apsnd SOME) ps];
- val (lprfx, pprfx) = param_prefix name params;
- val add_prefices = pprfx <> "" ? Binding.add_prefix false pprfx
- #> Binding.add_prefix false lprfx;
- val elem_morphism =
- Element.rename_morphism ren $>
- Morphism.binding_morphism add_prefices $>
- Element.instT_morphism thy env;
- val elems' = map (Element.morph_ctxt elem_morphism) elems;
- in (((name, map (apsnd SOME) locale_params'), mode'), elems') end;
-
- (* parameters, their types and syntax *)
- val (all_params', tenv, syn) = params_of_expr ctxt [] expr ([], Symtab.empty, Symtab.empty);
- val all_params = map (fn p => (p, Symtab.lookup tenv p |> the)) all_params';
- (* compute identifiers and syntax, merge with previous ones *)
- val (ids, _) = identify true expr;
- val idents = subtract (eq_fst (op =)) prev_idents ids;
- val syntax = merge_syntax ctxt ids (syn, prev_syntax);
- (* type-instantiate elements *)
- val final_elemss = map (eval all_params tenv syntax) idents;
- in ((prev_idents @ idents, syntax), final_elemss) end;
-
-end;
-
-
-(* activate elements *)
-
-local
-
-fun axioms_export axs _ As =
- (Element.satisfy_thm axs #> Drule.implies_intr_list (Library.drop (length axs, As)), fn t => t);
-
-
-(* NB: derived ids contain only facts at this stage *)
-
-fun activate_elem _ _ (Fixes fixes) (ctxt, mode) =
- ([], (ctxt |> ProofContext.add_fixes_i fixes |> snd, mode))
- | activate_elem _ _ (Constrains _) (ctxt, mode) =
- ([], (ctxt, mode))
- | activate_elem ax_in_ctxt _ (Assumes asms) (ctxt, Assumed axs) =
- let
- val asms' = Attrib.map_specs (Attrib.attribute_i (ProofContext.theory_of ctxt)) asms;
- val ts = maps (map #1 o #2) asms';
- val (ps, qs) = chop (length ts) axs;
- val (_, ctxt') =
- ctxt |> fold Variable.auto_fixes ts
- |> ProofContext.add_assms_i (axioms_export (if ax_in_ctxt then ps else [])) asms';
- in ([], (ctxt', Assumed qs)) end
- | activate_elem _ _ (Assumes asms) (ctxt, Derived ths) =
- ([], (ctxt, Derived ths))
- | activate_elem _ _ (Defines defs) (ctxt, Assumed axs) =
- let
- val defs' = Attrib.map_specs (Attrib.attribute_i (ProofContext.theory_of ctxt)) defs;
- val asms = defs' |> map (fn ((name, atts), (t, ps)) =>
- let val ((c, _), t') = LocalDefs.cert_def ctxt t
- in (t', ((Binding.map_base (Thm.def_name_optional c) name, atts), [(t', ps)])) end);
- val (_, ctxt') =
- ctxt |> fold (Variable.auto_fixes o #1) asms
- |> ProofContext.add_assms_i LocalDefs.def_export (map #2 asms);
- in ([], (ctxt', Assumed axs)) end
- | activate_elem _ _ (Defines defs) (ctxt, Derived ths) =
- ([], (ctxt, Derived ths))
- | activate_elem _ is_ext (Notes (kind, facts)) (ctxt, mode) =
- let
- val facts' = Attrib.map_facts (Attrib.attribute_i (ProofContext.theory_of ctxt)) facts;
- val (res, ctxt') = ctxt |> local_note_qualified kind facts';
- in (if is_ext then (map (#1 o #1) facts' ~~ map #2 res) else [], (ctxt', mode)) end;
-
-fun activate_elems ax_in_ctxt (((name, ps), mode), elems) ctxt =
- let
- val thy = ProofContext.theory_of ctxt;
- val (res, (ctxt', _)) = fold_map (activate_elem ax_in_ctxt (name = ""))
- elems (ProofContext.qualified_names ctxt, mode)
- handle ERROR msg => err_in_locale ctxt msg [(name, map fst ps)];
- val ctxt'' = if name = "" then ctxt'
- else let
- val ps' = map (fn (n, SOME T) => Free (n, T)) ps;
- in if test_local_registration ctxt' (name, ps') then ctxt'
- else let
- val ctxt'' = put_local_registration (name, ps') (I, (NameSpace.base name, ""))
- (Morphism.identity, ((Vartab.empty, []), (Vartab.empty, []) )) ctxt'
- in case mode of
- Assumed axs =>
- fold (add_local_witness (name, ps') o
- Element.assume_witness thy o Element.witness_prop) axs ctxt''
- | Derived ths =>
- fold (add_local_witness (name, ps')) ths ctxt''
- end
- end
- in (ProofContext.restore_naming ctxt ctxt'', res) end;
-
-fun activate_elemss ax_in_ctxt prep_facts =
- fold_map (fn (((name, ps), mode), raw_elems) => fn ctxt =>
- let
- val elems = map (prep_facts ctxt) raw_elems;
- val (ctxt', res) = apsnd flat
- (activate_elems ax_in_ctxt (((name, ps), mode), elems) ctxt);
- val elems' = elems |> map (Element.map_ctxt_attrib Args.closure);
- in (((((name, ps), mode), elems'), res), ctxt') end);
-
-in
-
-(* CB: activate_facts prep_facts elemss ctxt,
- where elemss is a list of pairs consisting of identifiers and
- context elements, extends ctxt by the context elements yielding
- ctxt' and returns ((elemss', facts), ctxt').
- Identifiers in the argument are of the form ((name, ps), axs) and
- assumptions use the axioms in the identifiers to set up exporters
- in ctxt'. elemss' does not contain identifiers and is obtained
- from elemss and the intermediate context with prep_facts.
- If read_facts or cert_facts is used for prep_facts, these also remove
- the internal/external markers from elemss. *)
-
-fun activate_facts ax_in_ctxt prep_facts args =
- activate_elemss ax_in_ctxt prep_facts args
- #>> (apsnd flat o split_list);
-
-end;
-
-
-
-(** prepare locale elements **)
-
-(* expressions *)
-
-fun intern_expr thy (Locale xname) = Locale (intern thy xname)
- | intern_expr thy (Merge exprs) = Merge (map (intern_expr thy) exprs)
- | intern_expr thy (Rename (expr, xs)) = Rename (intern_expr thy expr, xs);
-
-
-(* propositions and bindings *)
-
-(* flatten (ctxt, prep_expr) ((ids, syn), expr)
- normalises expr (which is either a locale
- expression or a single context element) wrt.
- to the list ids of already accumulated identifiers.
- It returns ((ids', syn'), elemss) where ids' is an extension of ids
- with identifiers generated for expr, and elemss is the list of
- context elements generated from expr.
- syn and syn' are symtabs mapping parameter names to their syntax. syn'
- is an extension of syn.
- For details, see flatten_expr.
-
- Additionally, for a locale expression, the elems are grouped into a single
- Int; individual context elements are marked Ext. In this case, the
- identifier-like information of the element is as follows:
- - for Fixes: (("", ps), []) where the ps have type info NONE
- - for other elements: (("", []), []).
- The implementation of activate_facts relies on identifier names being
- empty strings for external elements.
-*)
-
-fun flatten (ctxt, _) ((ids, syn), Elem (Fixes fixes)) = let
- val ids' = ids @ [(("", map (Binding.base_name o #1) fixes), ([], Assumed []))]
- in
- ((ids',
- merge_syntax ctxt ids'
- (syn, Symtab.make (map (fn fx => (Binding.base_name (#1 fx), #3 fx)) fixes))
- handle Symtab.DUP x => err_in_locale ctxt
- ("Conflicting syntax for parameter: " ^ quote x)
- (map #1 ids')),
- [((("", map (rpair NONE o Binding.base_name o #1) fixes), Assumed []), Ext (Fixes fixes))])
- end
- | flatten _ ((ids, syn), Elem elem) =
- ((ids @ [(("", []), ([], Assumed []))], syn), [((("", []), Assumed []), Ext elem)])
- | flatten (ctxt, prep_expr) ((ids, syn), Expr expr) =
- apsnd (map (apsnd Int)) (flatten_expr ctxt ((ids, syn), prep_expr expr));
-
-local
-
-local
-
-fun declare_int_elem (Fixes fixes) ctxt =
- ([], ctxt |> ProofContext.add_fixes_i (map (fn (x, T, mx) =>
- (x, Option.map (Term.map_type_tfree (TypeInfer.param 0)) T, mx)) fixes) |> snd)
- | declare_int_elem _ ctxt = ([], ctxt);
-
-fun declare_ext_elem prep_vars (Fixes fixes) ctxt =
- let val (vars, _) = prep_vars fixes ctxt
- in ([], ctxt |> ProofContext.add_fixes_i vars |> snd) end
- | declare_ext_elem prep_vars (Constrains csts) ctxt =
- let val (_, ctxt') = prep_vars (map (fn (x, T) => (Binding.name x, SOME T, NoSyn)) csts) ctxt
- in ([], ctxt') end
- | declare_ext_elem _ (Assumes asms) ctxt = (map #2 asms, ctxt)
- | declare_ext_elem _ (Defines defs) ctxt = (map (fn (_, (t, ps)) => [(t, ps)]) defs, ctxt)
- | declare_ext_elem _ (Notes _) ctxt = ([], ctxt);
-
-fun declare_elems prep_vars (((name, ps), Assumed _), elems) ctxt = ((case elems
- of Int es => fold_map declare_int_elem es ctxt
- | Ext e => declare_ext_elem prep_vars e ctxt |>> single)
- handle ERROR msg => err_in_locale ctxt msg [(name, map fst ps)])
- | declare_elems _ ((_, Derived _), elems) ctxt = ([], ctxt);
-
-in
-
-fun declare_elemss prep_vars fixed_params raw_elemss ctxt =
- let
- (* CB: fix of type bug of goal in target with context elements.
- Parameters new in context elements must receive types that are
- distinct from types of parameters in target (fixed_params). *)
- val ctxt_with_fixed =
- fold Variable.declare_term (map Free fixed_params) ctxt;
- val int_elemss =
- raw_elemss
- |> map_filter (fn (id, Int es) => SOME (id, es) | _ => NONE)
- |> unify_elemss ctxt_with_fixed fixed_params;
- val (raw_elemss', _) =
- fold_map (curry (fn ((id, Int _), (_, es) :: elemss) => ((id, Int es), elemss) | x => x))
- raw_elemss int_elemss;
- in fold_map (declare_elems prep_vars) raw_elemss' ctxt end;
-
-end;
-
-local
-
-val norm_term = Envir.beta_norm oo Term.subst_atomic;
-
-fun abstract_thm thy eq =
- Thm.assume (Thm.cterm_of thy eq) |> Drule.gen_all |> Drule.abs_def;
-
-fun bind_def ctxt (name, ps) eq (xs, env, ths) =
- let
- val ((y, T), b) = LocalDefs.abs_def eq;
- val b' = norm_term env b;
- val th = abstract_thm (ProofContext.theory_of ctxt) eq;
- fun err msg = err_in_locale ctxt (msg ^ ": " ^ quote y) [(name, map fst ps)];
- in
- exists (fn (x, _) => x = y) xs andalso
- err "Attempt to define previously specified variable";
- exists (fn (Free (y', _), _) => y = y' | _ => false) env andalso
- err "Attempt to redefine variable";
- (Term.add_frees b' xs, (Free (y, T), b') :: env, th :: ths)
- end;
-
-
-(* CB: for finish_elems (Int and Ext),
- extracts specification, only of assumed elements *)
-
-fun eval_text _ _ _ (Fixes _) text = text
- | eval_text _ _ _ (Constrains _) text = text
- | eval_text _ (_, Assumed _) is_ext (Assumes asms)
- (((exts, exts'), (ints, ints')), (xs, env, defs)) =
- let
- val ts = maps (map #1 o #2) asms;
- val ts' = map (norm_term env) ts;
- val spec' =
- if is_ext then ((exts @ ts, exts' @ ts'), (ints, ints'))
- else ((exts, exts'), (ints @ ts, ints' @ ts'));
- in (spec', (fold Term.add_frees ts' xs, env, defs)) end
- | eval_text _ (_, Derived _) _ (Assumes _) text = text
- | eval_text ctxt (id, Assumed _) _ (Defines defs) (spec, binds) =
- (spec, fold (bind_def ctxt id o #1 o #2) defs binds)
- | eval_text _ (_, Derived _) _ (Defines _) text = text
- | eval_text _ _ _ (Notes _) text = text;
-
-
-(* for finish_elems (Int),
- remove redundant elements of derived identifiers,
- turn assumptions and definitions into facts,
- satisfy hypotheses of facts *)
-
-fun finish_derived _ _ (Assumed _) (Fixes fixes) = SOME (Fixes fixes)
- | finish_derived _ _ (Assumed _) (Constrains csts) = SOME (Constrains csts)
- | finish_derived _ _ (Assumed _) (Assumes asms) = SOME (Assumes asms)
- | finish_derived _ _ (Assumed _) (Defines defs) = SOME (Defines defs)
-
- | finish_derived _ _ (Derived _) (Fixes _) = NONE
- | finish_derived _ _ (Derived _) (Constrains _) = NONE
- | finish_derived sign satisfy (Derived _) (Assumes asms) = asms
- |> map (apsnd (map (fn (a, _) => ([Thm.assume (cterm_of sign a)], []))))
- |> pair Thm.assumptionK |> Notes
- |> Element.morph_ctxt satisfy |> SOME
- | finish_derived sign satisfy (Derived _) (Defines defs) = defs
- |> map (apsnd (fn (d, _) => [([Thm.assume (cterm_of sign d)], [])]))
- |> pair Thm.definitionK |> Notes
- |> Element.morph_ctxt satisfy |> SOME
-
- | finish_derived _ satisfy _ (Notes facts) = Notes facts
- |> Element.morph_ctxt satisfy |> SOME;
-
-(* CB: for finish_elems (Ext) *)
-
-fun closeup _ false elem = elem
- | closeup ctxt true elem =
- let
- fun close_frees t =
- let
- val rev_frees =
- Term.fold_aterms (fn Free (x, T) =>
- if Variable.is_fixed ctxt x then I else insert (op =) (x, T) | _ => I) t [];
- in Term.list_all_free (rev rev_frees, t) end;
-
- fun no_binds [] = []
- | no_binds _ = error "Illegal term bindings in locale element";
- in
- (case elem of
- Assumes asms => Assumes (asms |> map (fn (a, propps) =>
- (a, map (fn (t, ps) => (close_frees t, no_binds ps)) propps)))
- | Defines defs => Defines (defs |> map (fn (a, (t, ps)) =>
- (a, (close_frees (#2 (LocalDefs.cert_def ctxt t)), no_binds ps))))
- | e => e)
- end;
-
-
-fun finish_ext_elem parms _ (Fixes fixes, _) = Fixes (map (fn (b, _, mx) =>
- let val x = Binding.base_name b
- in (b, AList.lookup (op =) parms x, mx) end) fixes)
- | finish_ext_elem parms _ (Constrains _, _) = Constrains []
- | finish_ext_elem _ close (Assumes asms, propp) =
- close (Assumes (map #1 asms ~~ propp))
- | finish_ext_elem _ close (Defines defs, propp) =
- close (Defines (map #1 defs ~~ map (fn [(t, ps)] => (t, ps)) propp))
- | finish_ext_elem _ _ (Notes facts, _) = Notes facts;
-
-
-(* CB: finish_parms introduces type info from parms to identifiers *)
-(* CB: only needed for types that have been NONE so far???
- If so, which are these??? *)
-
-fun finish_parms parms (((name, ps), mode), elems) =
- (((name, map (fn (x, _) => (x, AList.lookup (op = : string * string -> bool) parms x)) ps), mode), elems);
-
-fun finish_elems ctxt parms _ ((text, wits), ((id, Int e), _)) =
- let
- val [(id' as (_, mode), es)] = unify_elemss ctxt parms [(id, e)];
- val wits' = case mode of Assumed _ => wits | Derived ths => wits @ ths;
- val text' = fold (eval_text ctxt id' false) es text;
- val es' = map_filter
- (finish_derived (ProofContext.theory_of ctxt) (Element.satisfy_morphism wits') mode) es;
- in ((text', wits'), (id', map Int es')) end
- | finish_elems ctxt parms do_close ((text, wits), ((id, Ext e), [propp])) =
- let
- val e' = finish_ext_elem parms (closeup ctxt do_close) (e, propp);
- val text' = eval_text ctxt id true e' text;
- in ((text', wits), (id, [Ext e'])) end
-
-in
-
-(* CB: only called by prep_elemss *)
-
-fun finish_elemss ctxt parms do_close =
- foldl_map (apsnd (finish_parms parms) o finish_elems ctxt parms do_close);
-
-end;
-
-
-(* Remove duplicate Defines elements: temporary workaround to fix Afp/Category. *)
-
-fun defs_ord (defs1, defs2) =
- list_ord (fn ((_, (d1, _)), (_, (d2, _))) =>
- TermOrd.fast_term_ord (d1, d2)) (defs1, defs2);
-structure Defstab =
- TableFun(type key = (Attrib.binding * (term * term list)) list val ord = defs_ord);
-
-fun rem_dup_defs es ds =
- fold_map (fn e as (Defines defs) => (fn ds =>
- if Defstab.defined ds defs
- then (Defines [], ds)
- else (e, Defstab.update (defs, ()) ds))
- | e => (fn ds => (e, ds))) es ds;
-fun rem_dup_elemss (Int es) ds = apfst Int (rem_dup_defs es ds)
- | rem_dup_elemss (Ext e) ds = (Ext e, ds);
-fun rem_dup_defines raw_elemss =
- fold_map (fn (id as (_, (Assumed _)), es) => (fn ds =>
- apfst (pair id) (rem_dup_elemss es ds))
- | (id as (_, (Derived _)), es) => (fn ds =>
- ((id, es), ds))) raw_elemss Defstab.empty |> #1;
-
-(* CB: type inference and consistency checks for locales.
-
- Works by building a context (through declare_elemss), extracting the
- required information and adjusting the context elements (finish_elemss).
- Can also universally close free vars in assms and defs. This is only
- needed for Ext elements and controlled by parameter do_close.
-
- Only elements of assumed identifiers are considered.
-*)
-
-fun prep_elemss prep_vars prepp do_close context fixed_params raw_elemss raw_concl =
- let
- (* CB: contexts computed in the course of this function are discarded.
- They are used for type inference and consistency checks only. *)
- (* CB: fixed_params are the parameters (with types) of the target locale,
- empty list if there is no target. *)
- (* CB: raw_elemss are list of pairs consisting of identifiers and
- context elements, the latter marked as internal or external. *)
- val raw_elemss = rem_dup_defines raw_elemss;
- val (raw_proppss, raw_ctxt) = declare_elemss prep_vars fixed_params raw_elemss context;
- (* CB: raw_ctxt is context with additional fixed variables derived from
- the fixes elements in raw_elemss,
- raw_proppss contains assumptions and definitions from the
- external elements in raw_elemss. *)
- fun prep_prop raw_propp (raw_ctxt, raw_concl) =
- let
- (* CB: add type information from fixed_params to context (declare_term) *)
- (* CB: process patterns (conclusion and external elements only) *)
- val (ctxt, all_propp) =
- prepp (fold Variable.declare_term (map Free fixed_params) raw_ctxt, raw_concl @ raw_propp);
- (* CB: add type information from conclusion and external elements to context *)
- val ctxt = fold Variable.declare_term (maps (map fst) all_propp) ctxt;
- (* CB: resolve schematic variables (patterns) in conclusion and external elements. *)
- val all_propp' = map2 (curry (op ~~))
- (#1 (#2 (ProofContext.bind_propp_schematic_i (ctxt, all_propp)))) (map (map snd) all_propp);
- val (concl, propp) = chop (length raw_concl) all_propp';
- in (propp, (ctxt, concl)) end
-
- val (proppss, (ctxt, concl)) =
- (fold_burrow o fold_burrow) prep_prop raw_proppss (raw_ctxt, raw_concl);
-
- (* CB: obtain all parameters from identifier part of raw_elemss *)
- val xs = map #1 (params_of' raw_elemss);
- val typing = unify_frozen ctxt 0
- (map (Variable.default_type raw_ctxt) xs)
- (map (Variable.default_type ctxt) xs);
- val parms = param_types (xs ~~ typing);
- (* CB: parms are the parameters from raw_elemss, with correct typing. *)
-
- (* CB: extract information from assumes and defines elements
- (fixes, constrains and notes in raw_elemss don't have an effect on
- text and elemss), compute final form of context elements. *)
- val ((text, _), elemss) = finish_elemss ctxt parms do_close
- ((((([], []), ([], [])), ([], [], [])), []), raw_elemss ~~ proppss);
- (* CB: text has the following structure:
- (((exts, exts'), (ints, ints')), (xs, env, defs))
- where
- exts: external assumptions (terms in external assumes elements)
- exts': dito, normalised wrt. env
- ints: internal assumptions (terms in internal assumes elements)
- ints': dito, normalised wrt. env
- xs: the free variables in exts' and ints' and rhss of definitions,
- this includes parameters except defined parameters
- env: list of term pairs encoding substitutions, where the first term
- is a free variable; substitutions represent defines elements and
- the rhs is normalised wrt. the previous env
- defs: theorems representing the substitutions from defines elements
- (thms are normalised wrt. env).
- elemss is an updated version of raw_elemss:
- - type info added to Fixes and modified in Constrains
- - axiom and definition statement replaced by corresponding one
- from proppss in Assumes and Defines
- - Facts unchanged
- *)
- in ((parms, elemss, concl), text) end;
-
-in
-
-fun read_elemss x = prep_elemss ProofContext.read_vars ProofContext.read_propp_schematic x;
-fun cert_elemss x = prep_elemss ProofContext.cert_vars ProofContext.cert_propp_schematic x;
-
-end;
-
-
-(* facts and attributes *)
-
-local
-
-fun check_name name =
- if NameSpace.is_qualified name then error ("Illegal qualified name: " ^ quote name)
- else name;
-
-fun prep_facts _ _ _ ctxt (Int elem) = elem
- |> Element.morph_ctxt (Morphism.thm_morphism (Thm.transfer (ProofContext.theory_of ctxt)))
- | prep_facts prep_name get intern ctxt (Ext elem) = elem |> Element.map_ctxt
- {var = I, typ = I, term = I,
- binding = Binding.map_base prep_name,
- fact = get ctxt,
- attrib = Args.assignable o intern (ProofContext.theory_of ctxt)};
-
-in
-
-fun read_facts x = prep_facts check_name ProofContext.get_fact Attrib.intern_src x;
-fun cert_facts x = prep_facts I (K I) (K I) x;
-
-end;
-
-
-(* Get the specification of a locale *)
-
-(*The global specification is made from the parameters and global
- assumptions, the local specification from the parameters and the
- local assumptions.*)
-
-local
-
-fun gen_asms_of get thy name =
- let
- val ctxt = ProofContext.init thy;
- val (_, raw_elemss) = flatten (ctxt, I) (([], Symtab.empty), Expr (Locale name));
- val ((_, elemss, _), _) = read_elemss false ctxt [] raw_elemss [];
- in
- elemss |> get
- |> maps (fn (_, es) => map (fn Int e => e) es)
- |> maps (fn Assumes asms => asms | _ => [])
- |> map (apsnd (map fst))
- end;
-
-in
-
-fun parameters_of thy = #params o the_locale thy;
-
-fun intros thy = #intros o the_locale thy;
- (*returns introduction rule for delta predicate and locale predicate
- as a pair of singleton lists*)
-
-fun dests thy = #dests o the_locale thy;
-
-fun facts_of thy = map_filter (fn (Element.Notes (_, facts), _) => SOME facts
- | _ => NONE) o #elems o the_locale thy;
-
-fun parameters_of_expr thy expr =
- let
- val ctxt = ProofContext.init thy;
- val pts = params_of_expr ctxt [] (intern_expr thy expr)
- ([], Symtab.empty, Symtab.empty);
- val raw_params_elemss = make_raw_params_elemss pts;
- val ((_, syn), raw_elemss) = flatten (ctxt, intern_expr thy)
- (([], Symtab.empty), Expr expr);
- val ((parms, _, _), _) =
- read_elemss false ctxt [] (raw_params_elemss @ raw_elemss) [];
- in map (fn p as (n, _) => (p, Symtab.lookup syn n |> the)) parms end;
-
-fun local_asms_of thy name =
- gen_asms_of (single o Library.last_elem) thy name;
-
-fun global_asms_of thy name =
- gen_asms_of I thy name;
-
-end;
-
-
-(* full context statements: imports + elements + conclusion *)
-
-local
-
-fun prep_context_statement prep_expr prep_elemss prep_facts
- do_close fixed_params imports elements raw_concl context =
- let
- val thy = ProofContext.theory_of context;
-
- val (import_params, import_tenv, import_syn) =
- params_of_expr context fixed_params (prep_expr thy imports)
- ([], Symtab.empty, Symtab.empty);
- val includes = map_filter (fn Expr e => SOME e | Elem _ => NONE) elements;
- val (incl_params, incl_tenv, incl_syn) = fold (params_of_expr context fixed_params)
- (map (prep_expr thy) includes) (import_params, import_tenv, import_syn);
-
- val ((import_ids, _), raw_import_elemss) =
- flatten (context, prep_expr thy) (([], Symtab.empty), Expr imports);
- (* CB: normalise "includes" among elements *)
- val ((ids, syn), raw_elemsss) = foldl_map (flatten (context, prep_expr thy))
- ((import_ids, incl_syn), elements);
-
- val raw_elemss = flat raw_elemsss;
- (* CB: raw_import_elemss @ raw_elemss is the normalised list of
- context elements obtained from import and elements. *)
- (* Now additional elements for parameters are inserted. *)
- val import_params_ids = make_params_ids import_params;
- val incl_params_ids =
- make_params_ids (incl_params \\ import_params);
- val raw_import_params_elemss =
- make_raw_params_elemss (import_params, incl_tenv, incl_syn);
- val raw_incl_params_elemss =
- make_raw_params_elemss (incl_params \\ import_params, incl_tenv, incl_syn);
- val ((parms, all_elemss, concl), (spec, (_, _, defs))) = prep_elemss do_close
- context fixed_params
- (raw_import_params_elemss @ raw_import_elemss @ raw_incl_params_elemss @ raw_elemss) raw_concl;
-
- (* replace extended ids (for axioms) by ids *)
- val (import_ids', incl_ids) = chop (length import_ids) ids;
- val all_ids = import_params_ids @ import_ids' @ incl_params_ids @ incl_ids;
- val all_elemss' = map (fn (((_, ps), _), (((n, ps'), mode), elems)) =>
- (((n, map (fn p => (p, (the o AList.lookup (op =) ps') p)) ps), mode), elems))
- (all_ids ~~ all_elemss);
- (* CB: all_elemss and parms contain the correct parameter types *)
-
- val (ps, qs) = chop (length raw_import_params_elemss + length raw_import_elemss) all_elemss';
- val ((import_elemss, _), import_ctxt) =
- activate_facts false prep_facts ps context;
-
- val ((elemss, _), ctxt) =
- activate_facts false prep_facts qs (ProofContext.set_stmt true import_ctxt);
- in
- ((((import_ctxt, import_elemss), (ctxt, elemss, syn)),
- (parms, spec, defs)), concl)
- end;
-
-fun prep_statement prep_locale prep_ctxt raw_locale elems concl ctxt =
- let
- val thy = ProofContext.theory_of ctxt;
- val locale = Option.map (prep_locale thy) raw_locale;
- val (fixed_params, imports) =
- (case locale of
- NONE => ([], empty)
- | SOME name =>
- let val {params = ps, ...} = the_locale thy name
- in (map fst ps, Locale name) end);
- val ((((locale_ctxt, _), (elems_ctxt, _, _)), _), concl') =
- prep_ctxt false fixed_params imports (map Elem elems) concl ctxt;
- in (locale, locale_ctxt, elems_ctxt, concl') end;
-
-fun prep_expr prep imports body ctxt =
- let
- val (((_, import_elemss), (ctxt', elemss, _)), _) = prep imports body ctxt;
- val all_elems = maps snd (import_elemss @ elemss);
- in (all_elems, ctxt') end;
-
-in
-
-val read_ctxt = prep_context_statement intern_expr read_elemss read_facts;
-val cert_ctxt = prep_context_statement (K I) cert_elemss cert_facts;
-
-fun read_context imports body ctxt = #1 (read_ctxt true [] imports (map Elem body) [] ctxt);
-fun cert_context imports body ctxt = #1 (cert_ctxt true [] imports (map Elem body) [] ctxt);
-
-val read_expr = prep_expr read_context;
-val cert_expr = prep_expr cert_context;
-
-fun read_context_statement loc = prep_statement (K I) read_ctxt loc;
-fun read_context_statement_cmd loc = prep_statement intern read_ctxt loc;
-fun cert_context_statement loc = prep_statement (K I) cert_ctxt loc;
-
-end;
-
-
-(* init *)
-
-fun init loc =
- ProofContext.init
- #> #2 o cert_context_statement (SOME loc) [] [];
-
-
-(* print locale *)
-
-fun print_locale thy show_facts imports body =
- let val (all_elems, ctxt) = read_expr imports body (ProofContext.init thy) in
- Pretty.big_list "locale elements:" (all_elems
- |> (if show_facts then I else filter (fn Notes _ => false | _ => true))
- |> map (Element.pretty_ctxt ctxt) |> filter_out null
- |> map Pretty.chunks)
- |> Pretty.writeln
- end;
-
-
-
-(** store results **)
-
-(* join equations of an id with already accumulated ones *)
-
-fun join_eqns get_reg id eqns =
- let
- val eqns' = case get_reg id
- of NONE => eqns
- | SOME (_, _, eqns') => Termtab.join (fn _ => fn (_, e) => e) (eqns, eqns')
- (* prefer equations from eqns' *)
- in ((id, eqns'), eqns') end;
-
-
-(* collect witnesses and equations up to a particular target for a
- registration; requires parameters and flattened list of identifiers
- instead of recomputing it from the target *)
-
-fun collect_witnesses ctxt (imprt as ((impT, _), (imp, _))) parms ids ext_ts = let
-
- val thy = ProofContext.theory_of ctxt;
-
- val ts = map (var_inst_term (impT, imp)) ext_ts;
- val (parms, parmTs) = split_list parms;
- val parmvTs = map Logic.varifyT parmTs;
- val vtinst = fold (Sign.typ_match thy) (parmvTs ~~ map Term.fastype_of ts) Vartab.empty;
- val tinst = Vartab.dest vtinst |> map (fn ((x, 0), (_, T)) => (x, T))
- |> Symtab.make;
- val inst = Symtab.make (parms ~~ ts);
-
- (* instantiate parameter names in ids *)
- val ext_inst = Symtab.make (parms ~~ ext_ts);
- fun ext_inst_names ps = map (the o Symtab.lookup ext_inst) ps;
- val inst_ids = map (apfst (apsnd ext_inst_names)) ids;
- val assumed_ids = map_filter (fn (id, (_, Assumed _)) => SOME id | _ => NONE) inst_ids;
- val wits = maps (#2 o the o get_local_registration ctxt imprt) assumed_ids;
- val eqns =
- fold_map (join_eqns (get_local_registration ctxt imprt))
- (map fst inst_ids) Termtab.empty |> snd |> Termtab.dest |> map snd;
- in ((tinst, inst), wits, eqns) end;
-
-
-(* compute and apply morphism *)
-
-fun name_morph phi_name (lprfx, pprfx) b =
- b
- |> (if not (Binding.is_empty b) andalso pprfx <> ""
- then Binding.add_prefix false pprfx else I)
- |> (if not (Binding.is_empty b)
- then Binding.add_prefix false lprfx else I)
- |> phi_name;
-
-fun inst_morph thy phi_name param_prfx insts prems eqns export =
- let
- (* standardise export morphism *)
- val exp_fact = Drule.zero_var_indexes_list o map Thm.strip_shyps o Morphism.fact export;
- val exp_term = TermSubst.zero_var_indexes o Morphism.term export;
- (* FIXME sync with exp_fact *)
- val exp_typ = Logic.type_map exp_term;
- val export' =
- Morphism.morphism {binding = I, var = I, typ = exp_typ, term = exp_term, fact = exp_fact};
- in
- Morphism.binding_morphism (name_morph phi_name param_prfx) $>
- Element.inst_morphism thy insts $>
- Element.satisfy_morphism prems $>
- Morphism.term_morphism (MetaSimplifier.rewrite_term thy eqns []) $>
- Morphism.thm_morphism (MetaSimplifier.rewrite_rule eqns) $>
- export'
- end;
-
-fun activate_note thy phi_name param_prfx attrib insts prems eqns exp =
- (Element.facts_map o Element.morph_ctxt)
- (inst_morph thy phi_name param_prfx insts prems eqns exp)
- #> Attrib.map_facts attrib;
-
-
-(* public interface to interpretation morphism *)
-
-fun get_interpret_morph thy phi_name param_prfx (exp, imp) target ext_ts =
- let
- val parms = the_locale thy target |> #params |> map fst;
- val ids = flatten (ProofContext.init thy, intern_expr thy)
- (([], Symtab.empty), Expr (Locale target)) |> fst |> fst;
- val (insts, prems, eqns) = collect_witnesses (ProofContext.init thy) imp parms ids ext_ts;
- in
- inst_morph thy phi_name param_prfx insts prems eqns exp
- end;
-
-(* store instantiations of args for all registered interpretations
- of the theory *)
-
-fun note_thmss_registrations target (kind, args) thy =
- let
- val parms = the_locale thy target |> #params |> map fst;
- val ids = flatten (ProofContext.init thy, intern_expr thy)
- (([], Symtab.empty), Expr (Locale target)) |> fst |> fst;
-
- val regs = get_global_registrations thy target;
- (* add args to thy for all registrations *)
-
- fun activate (ext_ts, ((phi_name, param_prfx), (exp, imp), _, _)) thy =
- let
- val (insts, prems, eqns) = collect_witnesses (ProofContext.init thy) imp parms ids ext_ts;
- val args' = args
- |> activate_note thy phi_name param_prfx
- (Attrib.attribute_i thy) insts prems eqns exp;
- in
- thy
- |> global_note_qualified kind args'
- |> snd
- end;
- in fold activate regs thy end;
-
-
-(* locale results *)
-
-fun add_thmss loc kind args ctxt =
- let
- val (([(_, [Notes args'])], _), ctxt') =
- activate_facts true cert_facts
- [((("", []), Assumed []), [Ext (Notes (kind, args))])] ctxt;
- val ctxt'' = ctxt' |> ProofContext.theory
- (change_locale loc
- (fn (axiom, elems, params, decls, regs, intros, dests) =>
- (axiom, elems @ [(Notes args', stamp ())],
- params, decls, regs, intros, dests))
- #> note_thmss_registrations loc args');
- in ctxt'' end;
-
-
-(* declarations *)
-
-local
-
-fun decl_attrib decl phi = Thm.declaration_attribute (K (decl phi));
-
-fun add_decls add loc decl =
- ProofContext.theory (change_locale loc
- (fn (axiom, elems, params, decls, regs, intros, dests) =>
- (axiom, elems, params, add (decl, stamp ()) decls, regs, intros, dests))) #>
- add_thmss loc Thm.internalK
- [((Binding.empty, [Attrib.internal (decl_attrib decl)]), [([Drule.dummy_thm], [])])];
-
-in
-
-val add_type_syntax = add_decls (apfst o cons);
-val add_term_syntax = add_decls (apsnd o cons);
-val add_declaration = add_decls (K I);
-
-fun declarations_of thy loc =
- the_locale thy loc |> #decls |> apfst (map fst) |> apsnd (map fst);
-
-end;
-
-
-
-(** define locales **)
-
-(* predicate text *)
-(* CB: generate locale predicates and delta predicates *)
-
-local
-
-(* introN: name of theorems for introduction rules of locale and
- delta predicates;
- axiomsN: name of theorem set with destruct rules for locale predicates,
- also name suffix of delta predicates. *)
-
-val introN = "intro";
-val axiomsN = "axioms";
-
-fun atomize_spec thy ts =
- let
- val t = Logic.mk_conjunction_balanced ts;
- val body = ObjectLogic.atomize_term thy t;
- val bodyT = Term.fastype_of body;
- in
- if bodyT = propT then (t, propT, Thm.reflexive (Thm.cterm_of thy t))
- else (body, bodyT, ObjectLogic.atomize (Thm.cterm_of thy t))
- end;
-
-fun aprop_tr' n c = (Syntax.constN ^ c, fn ctxt => fn args =>
- if length args = n then
- Syntax.const "_aprop" $
- Term.list_comb (Syntax.free (Consts.extern (ProofContext.consts_of ctxt) c), args)
- else raise Match);
-
-(* CB: define one predicate including its intro rule and axioms
- - bname: predicate name
- - parms: locale parameters
- - defs: thms representing substitutions from defines elements
- - ts: terms representing locale assumptions (not normalised wrt. defs)
- - norm_ts: terms representing locale assumptions (normalised wrt. defs)
- - thy: the theory
-*)
-
-fun def_pred bname parms defs ts norm_ts thy =
- let
- val name = Sign.full_bname thy bname;
-
- val (body, bodyT, body_eq) = atomize_spec thy norm_ts;
- val env = Term.add_free_names body [];
- val xs = filter (member (op =) env o #1) parms;
- val Ts = map #2 xs;
- val extraTs =
- (Term.add_tfrees body [] \\ fold Term.add_tfreesT Ts [])
- |> Library.sort_wrt #1 |> map TFree;
- val predT = map Term.itselfT extraTs ---> Ts ---> bodyT;
-
- val args = map Logic.mk_type extraTs @ map Free xs;
- val head = Term.list_comb (Const (name, predT), args);
- val statement = ObjectLogic.ensure_propT thy head;
-
- val ([pred_def], defs_thy) =
- thy
- |> bodyT = propT ? Sign.add_advanced_trfuns ([], [], [aprop_tr' (length args) name], [])
- |> Sign.declare_const [] ((Binding.name bname, predT), NoSyn) |> snd
- |> PureThy.add_defs false
- [((Thm.def_name bname, Logic.mk_equals (head, body)), [Thm.kind_internal])];
- val defs_ctxt = ProofContext.init defs_thy |> Variable.declare_term head;
-
- val cert = Thm.cterm_of defs_thy;
-
- val intro = Goal.prove_global defs_thy [] norm_ts statement (fn _ =>
- MetaSimplifier.rewrite_goals_tac [pred_def] THEN
- Tactic.compose_tac (false, body_eq RS Drule.equal_elim_rule1, 1) 1 THEN
- Tactic.compose_tac (false,
- Conjunction.intr_balanced (map (Thm.assume o cert) norm_ts), 0) 1);
-
- val conjuncts =
- (Drule.equal_elim_rule2 OF [body_eq,
- MetaSimplifier.rewrite_rule [pred_def] (Thm.assume (cert statement))])
- |> Conjunction.elim_balanced (length ts);
- val axioms = ts ~~ conjuncts |> map (fn (t, ax) =>
- Element.prove_witness defs_ctxt t
- (MetaSimplifier.rewrite_goals_tac defs THEN
- Tactic.compose_tac (false, ax, 0) 1));
- in ((statement, intro, axioms), defs_thy) end;
-
-fun assumes_to_notes (Assumes asms) axms =
- fold_map (fn (a, spec) => fn axs =>
- let val (ps, qs) = chop (length spec) axs
- in ((a, [(ps, [])]), qs) end) asms axms
- |> apfst (curry Notes Thm.assumptionK)
- | assumes_to_notes e axms = (e, axms);
-
-(* CB: the following two change only "new" elems, these have identifier ("", _). *)
-
-(* turn Assumes into Notes elements *)
-
-fun change_assumes_elemss axioms elemss =
- let
- val satisfy = Element.morph_ctxt (Element.satisfy_morphism axioms);
- fun change (id as ("", _), es) =
- fold_map assumes_to_notes (map satisfy es)
- #-> (fn es' => pair (id, es'))
- | change e = pair e;
- in
- fst (fold_map change elemss (map Element.conclude_witness axioms))
- end;
-
-(* adjust hyps of Notes elements *)
-
-fun change_elemss_hyps axioms elemss =
- let
- val satisfy = Element.morph_ctxt (Element.satisfy_morphism axioms);
- fun change (id as ("", _), es) = (id, map (fn e as Notes _ => satisfy e | e => e) es)
- | change e = e;
- in map change elemss end;
-
-in
-
-(* CB: main predicate definition function *)
-
-fun define_preds pname (parms, ((exts, exts'), (ints, ints')), defs) elemss thy =
- let
- val ((elemss', more_ts), a_elem, a_intro, thy'') =
- if null exts then ((elemss, []), [], [], thy)
- else
- let
- val aname = if null ints then pname else pname ^ "_" ^ axiomsN;
- val ((statement, intro, axioms), thy') =
- thy
- |> def_pred aname parms defs exts exts';
- val elemss' = change_assumes_elemss axioms elemss;
- val a_elem = [(("", []),
- [Assumes [((Binding.name (pname ^ "_" ^ axiomsN), []), [(statement, [])])]])];
- val (_, thy'') =
- thy'
- |> Sign.add_path aname
- |> Sign.no_base_names
- |> PureThy.note_thmss Thm.internalK [((Binding.name introN, []), [([intro], [])])]
- ||> Sign.restore_naming thy';
- in ((elemss', [statement]), a_elem, [intro], thy'') end;
- val (predicate, stmt', elemss'', b_intro, thy'''') =
- if null ints then (([], []), more_ts, elemss' @ a_elem, [], thy'')
- else
- let
- val ((statement, intro, axioms), thy''') =
- thy''
- |> def_pred pname parms defs (ints @ more_ts) (ints' @ more_ts);
- val cstatement = Thm.cterm_of thy''' statement;
- val elemss'' = change_elemss_hyps axioms elemss';
- val b_elem = [(("", []),
- [Assumes [((Binding.name (pname ^ "_" ^ axiomsN), []), [(statement, [])])]])];
- val (_, thy'''') =
- thy'''
- |> Sign.add_path pname
- |> Sign.no_base_names
- |> PureThy.note_thmss Thm.internalK
- [((Binding.name introN, []), [([intro], [])]),
- ((Binding.name axiomsN, []),
- [(map (Drule.standard o Element.conclude_witness) axioms, [])])]
- ||> Sign.restore_naming thy''';
- in (([cstatement], axioms), [statement], elemss'' @ b_elem, [intro], thy'''') end;
- in (((elemss'', predicate, stmt'), (a_intro, b_intro)), thy'''') end;
-
-end;
-
-
-(* add_locale(_i) *)
-
-local
-
-(* turn Defines into Notes elements, accumulate definition terms *)
-
-fun defines_to_notes is_ext thy (Defines defs) defns =
- let
- val defs' = map (fn (_, (def, _)) => (Attrib.empty_binding, (def, []))) defs
- val notes = map (fn (a, (def, _)) =>
- (a, [([assume (cterm_of thy def)], [])])) defs
- in
- (if is_ext then SOME (Notes (Thm.definitionK, notes)) else NONE, defns @ [Defines defs'])
- end
- | defines_to_notes _ _ e defns = (SOME e, defns);
-
-fun change_defines_elemss thy elemss defns =
- let
- fun change (id as (n, _), es) defns =
- let
- val (es', defns') = fold_map (defines_to_notes (n="") thy) es defns
- in ((id, map_filter I es'), defns') end
- in fold_map change elemss defns end;
-
-fun gen_add_locale prep_ctxt prep_expr
- predicate_name bname raw_imports raw_body thy =
- (* predicate_name: "" - locale with predicate named as locale
- "name" - locale with predicate named "name" *)
- let
- val thy_ctxt = ProofContext.init thy;
- val name = Sign.full_bname thy bname;
- val _ = is_some (get_locale thy name) andalso
- error ("Duplicate definition of locale " ^ quote name);
-
- val (((import_ctxt, import_elemss), (body_ctxt, body_elemss, syn)),
- text as (parms, ((_, exts'), _), defs)) =
- prep_ctxt raw_imports raw_body thy_ctxt;
- val elemss = import_elemss @ body_elemss |>
- map_filter (fn ((id, Assumed axs), elems) => SOME (id, elems) | _ => NONE);
-
- val extraTs = List.foldr OldTerm.add_term_tfrees [] exts' \\
- List.foldr OldTerm.add_typ_tfrees [] (map snd parms);
- val _ = if null extraTs then ()
- else warning ("Additional type variable(s) in locale specification " ^ quote bname);
-
- val predicate_name' = case predicate_name of "" => bname | _ => predicate_name;
- val (elemss', defns) = change_defines_elemss thy elemss [];
- val elemss'' = elemss' @ [(("", []), defns)];
- val (((elemss''', predicate as (pred_statement, pred_axioms), stmt'), intros), thy') =
- define_preds predicate_name' text elemss'' thy;
- val regs = pred_axioms
- |> fold_map (fn (id, elems) => fn wts => let
- val ts = flat (map_filter (fn (Assumes asms) =>
- SOME (maps (map #1 o #2) asms) | _ => NONE) elems);
- val (wts1, wts2) = chop (length ts) wts;
- in ((apsnd (map fst) id, wts1), wts2) end) elemss'''
- |> fst
- |> map_filter (fn (("", _), _) => NONE | e => SOME e);
- fun axiomify axioms elemss =
- (axioms, elemss) |> foldl_map (fn (axs, (id, elems)) => let
- val ts = flat (map_filter (fn (Assumes asms) =>
- SOME (maps (map #1 o #2) asms) | _ => NONE) elems);
- val (axs1, axs2) = chop (length ts) axs;
- in (axs2, ((id, Assumed axs1), elems)) end)
- |> snd;
- val ((_, facts), ctxt) = activate_facts true (K I)
- (axiomify pred_axioms elemss''') (ProofContext.init thy');
- val view_ctxt = Assumption.add_view thy_ctxt pred_statement ctxt;
- val export = Thm.close_derivation o Goal.norm_result o
- singleton (ProofContext.export view_ctxt thy_ctxt);
- val facts' = facts |> map (fn (a, ths) => ((a, []), [(map export ths, [])]));
- val elems' = maps #2 (filter (fn ((s, _), _) => s = "") elemss''');
- val elems'' = map_filter (fn (Fixes _) => NONE | e => SOME e) elems';
- val axs' = map (Element.assume_witness thy') stmt';
- val loc_ctxt = thy'
- |> Sign.add_path bname
- |> Sign.no_base_names
- |> PureThy.note_thmss Thm.assumptionK facts' |> snd
- |> Sign.restore_naming thy'
- |> register_locale bname {axiom = axs',
- elems = map (fn e => (e, stamp ())) elems'',
- params = params_of elemss''' |> map (fn (x, SOME T) => ((x, T), the (Symtab.lookup syn x))),
- decls = ([], []),
- regs = regs,
- intros = intros,
- dests = map Element.conclude_witness pred_axioms}
- |> init name;
- in (name, loc_ctxt) end;
-
-in
-
-val add_locale = gen_add_locale cert_context (K I);
-val add_locale_cmd = gen_add_locale read_context intern_expr "";
-
-end;
-
-val _ = Context.>> (Context.map_theory
- (add_locale "" "var" empty [Fixes [(Binding.name (Name.internal "x"), NONE, NoSyn)]] #>
- snd #> ProofContext.theory_of #>
- add_locale "" "struct" empty [Fixes [(Binding.name (Name.internal "S"), NONE, Structure)]] #>
- snd #> ProofContext.theory_of));
-
-
-
-
-(** Normalisation of locale statements ---
- discharges goals implied by interpretations **)
-
-local
-
-fun locale_assm_intros thy =
- Symtab.fold (fn (_, {intros = (a, _), ...}) => fn intros => (a @ intros))
- (#2 (LocalesData.get thy)) [];
-fun locale_base_intros thy =
- Symtab.fold (fn (_, {intros = (_, b), ...}) => fn intros => (b @ intros))
- (#2 (LocalesData.get thy)) [];
-
-fun all_witnesses ctxt =
- let
- val thy = ProofContext.theory_of ctxt;
- fun get registrations = Symtab.fold (fn (_, regs) => fn thms =>
- (Registrations.dest thy regs |> map (fn (_, (_, (exp, _), wits, _)) =>
- map (Element.conclude_witness #> Morphism.thm exp) wits) |> flat) @ thms)
- registrations [];
- in get (RegistrationsData.get (Context.Proof ctxt)) end;
-
-in
-
-fun intro_locales_tac eager ctxt facts st =
- let
- val wits = all_witnesses ctxt;
- val thy = ProofContext.theory_of ctxt;
- val intros = locale_base_intros thy @ (if eager then locale_assm_intros thy else []);
- in
- Method.intros_tac (wits @ intros) facts st
- end;
-
-end;
-
-
-(** Interpretation commands **)
-
-local
-
-(* extract proof obligations (assms and defs) from elements *)
-
-fun extract_asms_elems ((id, Assumed _), elems) = (id, maps Element.prems_of elems)
- | extract_asms_elems ((id, Derived _), _) = (id, []);
-
-
-(* activate instantiated facts in theory or context *)
-
-fun gen_activate_facts_elemss mk_ctxt note attrib put_reg add_wit add_eqn
- phi_name all_elemss pss propss eq_attns (exp, imp) thmss thy_ctxt =
- let
- val ctxt = mk_ctxt thy_ctxt;
- fun get_reg thy_ctxt = get_local_registration (mk_ctxt thy_ctxt);
- fun test_reg thy_ctxt = test_local_registration (mk_ctxt thy_ctxt);
-
- val (all_propss, eq_props) = chop (length all_elemss) propss;
- val (all_thmss, eq_thms) = chop (length all_elemss) thmss;
-
- (* Filter out fragments already registered. *)
-
- val (new_elemss, xs) = split_list (filter_out (fn (((id, _), _), _) =>
- test_reg thy_ctxt id) (all_elemss ~~ (pss ~~ (all_propss ~~ all_thmss))));
- val (new_pss, ys) = split_list xs;
- val (new_propss, new_thmss) = split_list ys;
-
- val thy_ctxt' = thy_ctxt
- (* add registrations *)
- |> fold2 (fn ((id as (loc, _), _), _) => fn ps => put_reg id (phi_name, param_prefix loc ps) (exp, imp))
- new_elemss new_pss
- (* add witnesses of Assumed elements (only those generate proof obligations) *)
- |> fold2 (fn (id, _) => fold (add_wit id)) new_propss new_thmss
- (* add equations *)
- |> fold2 (fn (id, _) => fold (add_eqn id)) eq_props
- ((map o map) (Drule.abs_def o LocalDefs.meta_rewrite_rule ctxt o
- Element.conclude_witness) eq_thms);
-
- val prems = flat (map_filter
- (fn ((id, Assumed _), _) => Option.map #2 (get_reg thy_ctxt' imp id)
- | ((_, Derived _), _) => NONE) all_elemss);
-
- val thy_ctxt'' = thy_ctxt'
- (* add witnesses of Derived elements *)
- |> fold (fn (id, thms) => fold
- (add_wit id o Element.morph_witness (Element.satisfy_morphism prems)) thms)
- (map_filter (fn ((_, Assumed _), _) => NONE
- | ((id, Derived thms), _) => SOME (id, thms)) new_elemss)
-
- fun activate_elem phi_name param_prfx insts prems eqns exp (Notes (kind, facts)) thy_ctxt =
- let
- val ctxt = mk_ctxt thy_ctxt;
- val thy = ProofContext.theory_of ctxt;
- val facts' = facts
- |> activate_note thy phi_name param_prfx
- (attrib thy_ctxt) insts prems eqns exp;
- in
- thy_ctxt
- |> note kind facts'
- |> snd
- end
- | activate_elem _ _ _ _ _ _ _ thy_ctxt = thy_ctxt;
-
- fun activate_elems (((loc, ext_ts), _), _) ps thy_ctxt =
- let
- val ctxt = mk_ctxt thy_ctxt;
- val thy = ProofContext.theory_of ctxt;
- val {params, elems, ...} = the_locale thy loc;
- val parms = map fst params;
- val param_prfx = param_prefix loc ps;
- val ids = flatten (ProofContext.init thy, intern_expr thy)
- (([], Symtab.empty), Expr (Locale loc)) |> fst |> fst;
- val (insts, prems, eqns) = collect_witnesses ctxt imp parms ids ext_ts;
- in
- thy_ctxt
- |> fold (activate_elem phi_name param_prfx insts prems eqns exp o fst) elems
- end;
-
- in
- thy_ctxt''
- (* add equations as lemmas to context *)
- |> (fold2 o fold2) (fn attn => fn thm => snd o yield_singleton (note Thm.lemmaK)
- ((apsnd o map) (attrib thy_ctxt'') attn, [([Element.conclude_witness thm], [])]))
- (unflat eq_thms eq_attns) eq_thms
- (* add interpreted facts *)
- |> fold2 activate_elems new_elemss new_pss
- end;
-
-fun global_activate_facts_elemss x = gen_activate_facts_elemss
- ProofContext.init
- global_note_qualified
- Attrib.attribute_i
- put_global_registration
- add_global_witness
- add_global_equation
- x;
-
-fun local_activate_facts_elemss x = gen_activate_facts_elemss
- I
- local_note_qualified
- (Attrib.attribute_i o ProofContext.theory_of)
- put_local_registration
- add_local_witness
- add_local_equation
- x;
-
-fun prep_instantiations parse_term parse_prop ctxt parms (insts, eqns) =
- let
- (* parameters *)
- val (parm_names, parm_types) = parms |> split_list
- ||> map (TypeInfer.paramify_vars o Logic.varifyT);
- val type_parms = fold Term.add_tvarsT parm_types [] |> map (Logic.mk_type o TVar);
- val type_parm_names = fold Term.add_tfreesT (map snd parms) [] |> map fst;
-
- (* parameter instantiations *)
- val d = length parms - length insts;
- val insts =
- if d < 0 then error "More arguments than parameters in instantiation."
- else insts @ replicate d NONE;
- val (given_ps, given_insts) =
- ((parm_names ~~ parm_types) ~~ insts) |> map_filter
- (fn (_, NONE) => NONE
- | ((n, T), SOME inst) => SOME ((n, T), inst))
- |> split_list;
- val (given_parm_names, given_parm_types) = given_ps |> split_list;
-
- (* parse insts / eqns *)
- val given_insts' = map (parse_term ctxt) given_insts;
- val eqns' = map (parse_prop ctxt) eqns;
-
- (* type inference and contexts *)
- val arg = type_parms @ map2 TypeInfer.constrain given_parm_types given_insts' @ eqns';
- val res = Syntax.check_terms ctxt arg;
- val ctxt' = ctxt |> fold Variable.auto_fixes res;
-
- (* instantiation *)
- val (type_parms'', res') = chop (length type_parms) res;
- val (given_insts'', eqns'') = chop (length given_insts) res';
- val instT = Symtab.make (type_parm_names ~~ map Logic.dest_type type_parms'');
- val inst = Symtab.make (given_parm_names ~~ given_insts'');
-
- (* export from eigencontext *)
- val export = Variable.export_morphism ctxt' ctxt;
-
- (* import, its inverse *)
- val domT = fold Term.add_tfrees res [] |> map TFree;
- val importT = domT |> map (fn x => (Morphism.typ export x, x))
- |> map_filter (fn (TFree _, _) => NONE (* fixed point of export *)
- | (TVar y, x) => SOME (fst y, x)
- | _ => error "internal: illegal export in interpretation")
- |> Vartab.make;
- val dom = fold Term.add_frees res [] |> map Free;
- val imprt = dom |> map (fn x => (Morphism.term export x, x))
- |> map_filter (fn (Free _, _) => NONE (* fixed point of export *)
- | (Var y, x) => SOME (fst y, x)
- | _ => error "internal: illegal export in interpretation")
- |> Vartab.make;
- in (((instT, inst), eqns''), (export, ((importT, domT), (imprt, dom)))) end;
-
-val read_instantiations = prep_instantiations Syntax.parse_term Syntax.parse_prop;
-val check_instantiations = prep_instantiations (K I) (K I);
-
-fun gen_prep_registration mk_ctxt test_reg activate
- prep_attr prep_expr prep_insts
- thy_ctxt phi_name raw_expr raw_insts =
- let
- val ctxt = mk_ctxt thy_ctxt;
- val thy = ProofContext.theory_of ctxt;
- val ctxt' = ProofContext.init thy;
- fun prep_attn attn = (apsnd o map)
- (Attrib.crude_closure ctxt o Args.assignable o prep_attr thy) attn;
-
- val expr = prep_expr thy raw_expr;
-
- val pts = params_of_expr ctxt' [] expr ([], Symtab.empty, Symtab.empty);
- val params_ids = make_params_ids (#1 pts);
- val raw_params_elemss = make_raw_params_elemss pts;
- val ((ids, _), raw_elemss) = flatten (ctxt', I) (([], Symtab.empty), Expr expr);
- val ((parms, all_elemss, _), (_, (_, defs, _))) =
- read_elemss false ctxt' [] (raw_params_elemss @ raw_elemss) [];
-
- (** compute instantiation **)
-
- (* consistency check: equations need to be stored in a particular locale,
- therefore if equations are present locale expression must be a name *)
-
- val _ = case (expr, snd raw_insts) of
- (Locale _, _) => () | (_, []) => ()
- | (_, _) => error "Interpretations with `where' only permitted if locale expression is a name.";
-
- (* read or certify instantiation *)
- val (raw_insts', raw_eqns) = raw_insts;
- val (raw_eq_attns, raw_eqns') = split_list raw_eqns;
- val (((instT, inst1), eqns), morphs) = prep_insts ctxt parms (raw_insts', raw_eqns');
- val eq_attns = map prep_attn raw_eq_attns;
-
- (* defined params without given instantiation *)
- val not_given = filter_out (Symtab.defined inst1 o fst) parms;
- fun add_def (p, pT) inst =
- let
- val (t, T) = case find_first (fn (Free (a, _), _) => a = p) defs of
- NONE => error ("Instance missing for parameter " ^ quote p)
- | SOME (Free (_, T), t) => (t, T);
- val d = Element.inst_term (instT, inst) t;
- in Symtab.update_new (p, d) inst end;
- val inst2 = fold add_def not_given inst1;
- val inst_morphism = Element.inst_morphism thy (instT, inst2);
- (* Note: insts contain no vars. *)
-
- (** compute proof obligations **)
-
- (* restore "small" ids *)
- val ids' = map (fn ((n, ps), (_, mode)) =>
- ((n, map (fn p => Free (p, (the o AList.lookup (op =) parms) p)) ps), mode))
- ids;
- val (_, all_elemss') = chop (length raw_params_elemss) all_elemss
- (* instantiate ids and elements *)
- val inst_elemss = (ids' ~~ all_elemss') |> map (fn (((n, ps), _), ((_, mode), elems)) =>
- ((n, map (Morphism.term (inst_morphism $> fst morphs)) ps),
- map (fn Int e => Element.morph_ctxt inst_morphism e) elems)
- |> apfst (fn id => (id, map_mode (map (Element.morph_witness inst_morphism)) mode)));
-
- (* equations *)
- val eqn_elems = if null eqns then []
- else [(Library.last_elem inst_elemss |> fst |> fst, eqns)];
-
- val propss = map extract_asms_elems inst_elemss @ eqn_elems;
-
- in
- (propss, activate phi_name inst_elemss (map (snd o fst) ids) propss eq_attns morphs, morphs)
- end;
-
-fun gen_prep_global_registration mk_ctxt = gen_prep_registration ProofContext.init
- test_global_registration
- global_activate_facts_elemss mk_ctxt;
-
-fun gen_prep_local_registration mk_ctxt = gen_prep_registration I
- test_local_registration
- local_activate_facts_elemss mk_ctxt;
-
-val prep_global_registration = gen_prep_global_registration
- (K I) (K I) check_instantiations;
-val prep_global_registration_cmd = gen_prep_global_registration
- Attrib.intern_src intern_expr read_instantiations;
-
-val prep_local_registration = gen_prep_local_registration
- (K I) (K I) check_instantiations;
-val prep_local_registration_cmd = gen_prep_local_registration
- Attrib.intern_src intern_expr read_instantiations;
-
-fun prep_registration_in_locale target expr thy =
- (* target already in internal form *)
- let
- val ctxt = ProofContext.init thy;
- val ((raw_target_ids, target_syn), _) = flatten (ctxt, I)
- (([], Symtab.empty), Expr (Locale target));
- val fixed = the_locale thy target |> #params |> map #1;
- val ((all_ids, syn), raw_elemss) = flatten (ctxt, intern_expr thy)
- ((raw_target_ids, target_syn), Expr expr);
- val (target_ids, ids) = chop (length raw_target_ids) all_ids;
- val ((parms, elemss, _), _) = read_elemss false ctxt fixed raw_elemss [];
-
- (** compute proof obligations **)
-
- (* restore "small" ids, with mode *)
- val ids' = map (apsnd snd) ids;
- (* remove Int markers *)
- val elemss' = map (fn (_, es) =>
- map (fn Int e => e) es) elemss
- (* extract assumptions and defs *)
- val ids_elemss = ids' ~~ elemss';
- val propss = map extract_asms_elems ids_elemss;
-
- (** activation function:
- - add registrations to the target locale
- - add induced registrations for all global registrations of
- the target, unless already present
- - add facts of induced registrations to theory **)
-
- fun activate thmss thy =
- let
- val satisfy = Element.satisfy_thm (flat thmss);
- val ids_elemss_thmss = ids_elemss ~~ thmss;
- val regs = get_global_registrations thy target;
-
- fun activate_id (((id, Assumed _), _), thms) thy =
- thy |> put_registration_in_locale target id
- |> fold (add_witness_in_locale target id) thms
- | activate_id _ thy = thy;
-
- fun activate_reg (ext_ts, ((phi_name, param_prfx), (exp, imp), _, _)) thy =
- let
- val (insts, wits, _) = collect_witnesses (ProofContext.init thy) imp fixed target_ids ext_ts;
- val inst_parms = map (the o AList.lookup (op =) (map #1 fixed ~~ ext_ts));
- val disch = Element.satisfy_thm wits;
- val new_elemss = filter (fn (((name, ps), _), _) =>
- not (test_global_registration thy (name, inst_parms ps))) (ids_elemss);
- fun activate_assumed_id (((_, Derived _), _), _) thy = thy
- | activate_assumed_id ((((name, ps), Assumed _), _), thms) thy = let
- val ps' = inst_parms ps;
- in
- if test_global_registration thy (name, ps')
- then thy
- else thy
- |> put_global_registration (name, ps') (phi_name, param_prefix name ps) (exp, imp)
- |> fold (fn witn => fn thy => add_global_witness (name, ps')
- (Element.morph_witness (Element.inst_morphism thy insts) witn) thy) thms
- end;
-
- fun activate_derived_id ((_, Assumed _), _) thy = thy
- | activate_derived_id (((name, ps), Derived ths), _) thy = let
- val ps' = inst_parms ps;
- in
- if test_global_registration thy (name, ps')
- then thy
- else thy
- |> put_global_registration (name, ps') (phi_name, param_prefix name ps) (exp, imp)
- |> fold (fn witn => fn thy => add_global_witness (name, ps')
- (witn |> Element.map_witness (fn (t, th) => (* FIXME *)
- (Element.inst_term insts t,
- disch (Element.inst_thm thy insts (satisfy th))))) thy) ths
- end;
-
- fun activate_elem (loc, ps) (Notes (kind, facts)) thy =
- let
- val att_morphism =
- Morphism.binding_morphism (name_morph phi_name param_prfx) $>
- Morphism.thm_morphism satisfy $>
- Element.inst_morphism thy insts $>
- Morphism.thm_morphism disch;
- val facts' = facts
- |> Attrib.map_facts (Attrib.attribute_i thy o Args.morph_values att_morphism)
- |> (map o apsnd o map o apfst o map) (disch o Element.inst_thm thy insts o satisfy)
- |> (map o apfst o apfst) (name_morph phi_name param_prfx);
- in
- thy
- |> global_note_qualified kind facts'
- |> snd
- end
- | activate_elem _ _ thy = thy;
-
- fun activate_elems ((id, _), elems) thy = fold (activate_elem id) elems thy;
-
- in thy |> fold activate_assumed_id ids_elemss_thmss
- |> fold activate_derived_id ids_elemss
- |> fold activate_elems new_elemss end;
- in
- thy |> fold activate_id ids_elemss_thmss
- |> fold activate_reg regs
- end;
-
- in (propss, activate) end;
-
-fun prep_propp propss = propss |> map (fn (_, props) =>
- map (rpair [] o Element.mark_witness) props);
-
-fun prep_result propps thmss =
- ListPair.map (fn ((_, props), thms) => map2 Element.make_witness props thms) (propps, thmss);
-
-fun gen_interpretation prep_registration after_qed prfx raw_expr raw_insts thy =
- let
- val (propss, activate, morphs) = prep_registration thy prfx raw_expr raw_insts;
- fun after_qed' results =
- ProofContext.theory (activate (prep_result propss results))
- #> after_qed;
- in
- thy
- |> ProofContext.init
- |> Proof.theorem_i NONE after_qed' (prep_propp propss)
- |> Element.refine_witness
- |> Seq.hd
- |> pair morphs
- end;
-
-fun gen_interpret prep_registration after_qed name_morph expr insts int state =
- let
- val _ = Proof.assert_forward_or_chain state;
- val ctxt = Proof.context_of state;
- val (propss, activate, morphs) = prep_registration ctxt name_morph expr insts;
- fun after_qed' results =
- Proof.map_context (K (ctxt |> activate (prep_result propss results)))
- #> Proof.put_facts NONE
- #> after_qed;
- in
- state
- |> Proof.local_goal (ProofDisplay.print_results int) (K I) ProofContext.bind_propp_i
- "interpret" NONE after_qed' (map (pair (Binding.empty, [])) (prep_propp propss))
- |> Element.refine_witness |> Seq.hd
- |> pair morphs
- end;
-
-fun standard_name_morph interp_prfx b =
- if Binding.is_empty b then b
- else Binding.map_prefix (fn ((lprfx, _) :: pprfx) =>
- fold (Binding.add_prefix false o fst) pprfx
- #> interp_prfx <> "" ? Binding.add_prefix true interp_prfx
- #> Binding.add_prefix false lprfx
- ) b;
-
-in
-
-val interpretation = gen_interpretation prep_global_registration;
-fun interpretation_cmd interp_prfx = snd ooo gen_interpretation prep_global_registration_cmd
- I (standard_name_morph interp_prfx);
-
-fun interpretation_in_locale after_qed (raw_target, expr) thy =
- let
- val target = intern thy raw_target;
- val (propss, activate) = prep_registration_in_locale target expr thy;
- val raw_propp = prep_propp propss;
-
- val (_, _, goal_ctxt, propp) = thy
- |> ProofContext.init
- |> cert_context_statement (SOME target) [] raw_propp;
-
- fun after_qed' results =
- ProofContext.theory (activate (prep_result propss results))
- #> after_qed;
- in
- goal_ctxt
- |> Proof.theorem_i NONE after_qed' propp
- |> Element.refine_witness |> Seq.hd
- end;
-
-val interpret = gen_interpret prep_local_registration;
-fun interpret_cmd interp_prfx = snd oooo gen_interpret prep_local_registration_cmd
- I (standard_name_morph interp_prfx);
-
-end;
-
-end;