First release of interpretation commands.
(* Title: Pure/Isar/proof_context.ML
ID: $Id$
Author: Markus Wenzel, TU Muenchen
Proof context information.
*)
(*Jia: changed: datatype context
affected files: make_context, map_context, init, put_data, add_syntax, map_defaults, del_bind, upd_bind, qualified, hide_thms, put_thms, reset_thms, gen_assms, map_fixes, add_cases
added: put_delta, get_delta
06/01/05
*)
val show_structs = ref false;
signature PROOF_CONTEXT =
sig
type context
type exporter
exception CONTEXT of string * context
val theory_of: context -> theory
val sign_of: context -> Sign.sg
val is_fixed: context -> string -> bool
val fixed_names_of: context -> string list
val assumptions_of: context -> (cterm list * exporter) list
val prems_of: context -> thm list
val print_proof_data: theory -> unit
val init: theory -> context
val pretty_term: context -> term -> Pretty.T
val pretty_typ: context -> typ -> Pretty.T
val pretty_sort: context -> sort -> Pretty.T
val pp: context -> Pretty.pp
val pretty_thm: context -> thm -> Pretty.T
val pretty_thms: context -> thm list -> Pretty.T
val pretty_fact: context -> string * thm list -> Pretty.T
val string_of_term: context -> term -> string
val default_type: context -> string -> typ option
val used_types: context -> string list
val read_typ: context -> string -> typ
val read_typ_raw: context -> string -> typ
val cert_typ: context -> typ -> typ
val cert_typ_raw: context -> typ -> typ
val get_skolem: context -> string -> string
val extern_skolem: context -> term -> term
val read_termTs: context -> (string -> bool) -> (indexname -> typ option)
-> (indexname -> sort option) -> string list -> (string * typ) list
-> term list * (indexname * typ) list
val read_termTs_schematic: context -> (string -> bool) -> (indexname -> typ option)
-> (indexname -> sort option) -> string list -> (string * typ) list
-> term list * (indexname * typ) list
val read_term_liberal: context -> string -> term
val read_term: context -> string -> term
val read_prop: context -> string -> term
val read_prop_schematic: context -> string -> term
val read_terms: context -> string list -> term list
val read_term_pats: typ -> context -> string list -> term list
val read_prop_pats: context -> string list -> term list
val cert_term: context -> term -> term
val cert_prop: context -> term -> term
val cert_term_pats: typ -> context -> term list -> term list
val cert_prop_pats: context -> term list -> term list
val declare_term: term -> context -> context
val declare_terms: term list -> context -> context
val warn_extra_tfrees: context -> context -> context
val generalize: context -> context -> term list -> term list
val find_free: term -> string -> term option
val export: bool -> context -> context -> thm -> thm Seq.seq
val export_standard: cterm list -> context -> context -> thm -> thm
val export_plain: cterm list -> context -> context -> thm -> thm
val drop_schematic: indexname * term option -> indexname * term option
val add_binds: (indexname * string option) list -> context -> context
val add_binds_i: (indexname * term option) list -> context -> context
val auto_bind_goal: term list -> context -> context
val auto_bind_facts: term list -> context -> context
val match_bind: bool -> (string list * string) list -> context -> context
val match_bind_i: bool -> (term list * term) list -> context -> context
val read_propp: context * (string * (string list * string list)) list list
-> context * (term * (term list * term list)) list list
val cert_propp: context * (term * (term list * term list)) list list
-> context * (term * (term list * term list)) list list
val read_propp_schematic: context * (string * (string list * string list)) list list
-> context * (term * (term list * term list)) list list
val cert_propp_schematic: context * (term * (term list * term list)) list list
-> context * (term * (term list * term list)) list list
val bind_propp: context * (string * (string list * string list)) list list
-> context * (term list list * (context -> context))
val bind_propp_i: context * (term * (term list * term list)) list list
-> context * (term list list * (context -> context))
val bind_propp_schematic: context * (string * (string list * string list)) list list
-> context * (term list list * (context -> context))
val bind_propp_schematic_i: context * (term * (term list * term list)) list list
-> context * (term list list * (context -> context))
val get_thm: context -> thmref -> thm
val get_thm_closure: context -> thmref -> thm
val get_thms: context -> thmref -> thm list
val get_thms_closure: context -> thmref -> thm list
val cond_extern: context -> string -> xstring
val qualified: bool -> context -> context
val restore_qualified: context -> context -> context
val hide_thms: bool -> string list -> context -> context
val put_thm: string * thm -> context -> context
val put_thms: string * thm list -> context -> context
val put_thmss: (string * thm list) list -> context -> context
val reset_thms: string -> context -> context
val note_thmss:
((bstring * context attribute list) *
(thmref * context attribute list) list) list ->
context -> context * (bstring * thm list) list
val note_thmss_i:
((bstring * context attribute list) *
(thm list * context attribute list) list) list ->
context -> context * (bstring * thm list) list
val note_thmss_accesses:
(string -> string list) ->
((bstring * context attribute list) *
(thmref * context attribute list) list) list ->
context -> context * (bstring * thm list) list
val note_thmss_accesses_i:
(string -> string list) ->
((bstring * context attribute list) *
(thm list * context attribute list) list) list ->
context -> context * (bstring * thm list) list
val export_assume: exporter
val export_presume: exporter
val cert_def: context -> term -> string * term
val export_def: exporter
val assume: exporter
-> ((string * context attribute list) * (string * (string list * string list)) list) list
-> context -> context * (bstring * thm list) list
val assume_i: exporter
-> ((string * context attribute list) * (term * (term list * term list)) list) list
-> context -> context * (bstring * thm list) list
val read_vars: context * (string list * string option)
-> context * (string list * typ option)
val cert_vars: context * (string list * typ option)
-> context * (string list * typ option)
val read_vars_liberal: context * (string list * string option)
-> context * (string list * typ option)
val cert_vars_liberal: context * (string list * typ option)
-> context * (string list * typ option)
val fix: (string list * string option) list -> context -> context
val fix_i: (string list * typ option) list -> context -> context
val add_fixes: (string * typ option * Syntax.mixfix option) list -> context -> context
val add_fixes_liberal: (string * typ option * Syntax.mixfix option) list -> context -> context
val fix_frees: term list -> context -> context
val bind_skolem: context -> string list -> term -> term
val get_case: context -> string -> string option list -> RuleCases.T
val add_cases: (string * RuleCases.T) list -> context -> context
val apply_case: RuleCases.T -> context
-> context * ((indexname * term option) list * (string * term list) list)
val verbose: bool ref
val setmp_verbose: ('a -> 'b) -> 'a -> 'b
val print_syntax: context -> unit
val print_binds: context -> unit
val print_lthms: context -> unit
val print_cases: context -> unit
val prems_limit: int ref
val pretty_asms: context -> Pretty.T list
val pretty_context: context -> Pretty.T list
val thms_containing_limit: int ref
val print_thms_containing: context -> int option -> string list -> unit
val setup: (theory -> theory) list
val get_delta: context -> Object.T Symtab.table (* Jia: (claset, simpset) *)
val put_delta: Object.T Symtab.table -> context -> context
val get_delta_count_incr: context -> int
end;
signature PRIVATE_PROOF_CONTEXT =
sig
include PROOF_CONTEXT
val init_data: Object.kind -> (theory -> Object.T) * (context -> Object.T -> unit)
-> theory -> theory
val print_data: Object.kind -> context -> unit
val get_data: Object.kind -> (Object.T -> 'a) -> context -> 'a
val put_data: Object.kind -> ('a -> Object.T) -> 'a -> context -> context
end;
structure ProofContext: PRIVATE_PROOF_CONTEXT =
struct
(** datatype context **)
type exporter = bool -> cterm list -> thm -> thm Seq.seq;
(* note: another field added to context. *)
datatype context =
Context of
{thy: theory, (*current theory*)
syntax: Syntax.syntax * string list * string list, (*syntax with structs and mixfixed*)
data: Object.T Symtab.table, (*user data*)
asms:
((cterm list * exporter) list * (*assumes: A ==> _*)
(string * thm list) list) * (*prems: A |- A *)
(string * string) list, (*fixes: !!x. _*)
binds: (term * typ) option Vartab.table, (*term bindings*)
thms: bool * NameSpace.T * thm list option Symtab.table
* FactIndex.T, (*local thms*)
(*thms is of the form (q, n, t, i) where
q: indicates whether theorems with qualified names may be stored;
this is initially forbidden (false); flag may be changed with
qualified and restore_qualified;
n: theorem namespace;
t: table of theorems;
i: index for theorem lookup (cf. thms_containing) *)
cases: (string * RuleCases.T) list, (*local contexts*)
defs:
typ Vartab.table * (*type constraints*)
sort Vartab.table * (*default sorts*)
string list * (*used type variables*)
term list Symtab.table,
delta: Object.T Symtab.table (* difference between local and global claset and simpset*),
delta_count: int ref (* number of local anonymous thms *)
}; (*type variable occurrences*)
exception CONTEXT of string * context;
fun make_context (thy, syntax, data, asms, binds, thms, cases, defs, delta, delta_count) =
Context {thy = thy, syntax = syntax, data = data, asms = asms, binds = binds,
thms = thms, cases = cases, defs = defs, delta = delta, delta_count = delta_count};
fun map_context f (Context {thy, syntax, data, asms, binds, thms, cases, defs, delta, delta_count}) =
make_context (f (thy, syntax, data, asms, binds, thms, cases, defs, delta, delta_count));
fun theory_of (Context {thy, ...}) = thy;
val sign_of = Theory.sign_of o theory_of;
fun syntax_of (Context {syntax, ...}) = syntax;
fun fixes_of (Context {asms = (_, fixes), ...}) = fixes;
val fixed_names_of = map #2 o fixes_of;
fun is_fixed ctxt x = exists (equal x o #2) (fixes_of ctxt);
fun is_known (ctxt as Context {defs = (types, _, _, _), ...}) x =
isSome (Vartab.lookup (types, (x, ~1))) orelse is_fixed ctxt x;
fun type_occs (Context {defs = (_, _, _, tab), ...}) = tab;
fun assumptions_of (Context {asms = ((asms, _), _), ...}) = asms;
fun prems_of (Context {asms = ((_, prems), _), ...}) = List.concat (map #2 prems);
(** user data **)
(* errors *)
fun of_theory thy = "\nof theory " ^ Sign.str_of_sg (Theory.sign_of thy);
fun err_inconsistent kinds =
error ("Attempt to merge different versions of " ^ commas_quote kinds ^ " proof data");
fun err_dup_init thy kind =
error ("Duplicate initialization of " ^ quote kind ^ " proof data" ^ of_theory thy);
fun err_undef ctxt kind =
raise CONTEXT ("Tried to access undefined " ^ quote kind ^ " proof data", ctxt);
fun err_uninit ctxt kind =
raise CONTEXT ("Tried to access uninitialized " ^ quote kind ^ " proof data" ^
of_theory (theory_of ctxt), ctxt);
fun err_access ctxt kind =
raise CONTEXT ("Unauthorized access to " ^ quote kind ^ " proof data" ^
of_theory (theory_of ctxt), ctxt);
(* data kind 'Isar/proof_data' *)
structure ProofDataDataArgs =
struct
val name = "Isar/proof_data";
type T = (Object.kind * ((theory -> Object.T) * (context -> Object.T -> unit))) Symtab.table;
val empty = Symtab.empty;
val copy = I;
val prep_ext = I;
fun merge tabs = Symtab.merge (Object.eq_kind o pairself fst) tabs
handle Symtab.DUPS kinds => err_inconsistent kinds;
fun print _ tab = Pretty.writeln (Pretty.strs (map #1 (Symtab.dest tab)));
end;
structure ProofDataData = TheoryDataFun(ProofDataDataArgs);
val print_proof_data = ProofDataData.print;
(* init proof data *)
fun init_data kind meths thy =
let
val name = Object.name_of_kind kind;
val tab = Symtab.update_new ((name, (kind, meths)), ProofDataData.get thy)
handle Symtab.DUP _ => err_dup_init thy name;
in thy |> ProofDataData.put tab end;
(* access data *)
fun lookup_data (ctxt as Context {data, ...}) kind =
let
val thy = theory_of ctxt;
val name = Object.name_of_kind kind;
in
(case Symtab.lookup (ProofDataData.get thy, name) of
SOME (k, meths) =>
if Object.eq_kind (kind, k) then
(case Symtab.lookup (data, name) of
SOME x => (x, meths)
| NONE => err_undef ctxt name)
else err_access ctxt name
| NONE => err_uninit ctxt name)
end;
fun get_data kind f ctxt =
let val (x, _) = lookup_data ctxt kind
in f x handle Match => Object.kind_error kind end;
fun print_data kind ctxt =
let val (x, (_, prt)) = lookup_data ctxt kind
in prt ctxt x end;
fun put_data kind f x ctxt =
(lookup_data ctxt kind;
map_context (fn (thy, syntax, data, asms, binds, thms, cases, defs, delta,delta_count) =>
(thy, syntax, Symtab.update ((Object.name_of_kind kind, f x), data),
asms, binds, thms, cases, defs, delta, delta_count)) ctxt);
(* added get_delta and put_delta *)
fun get_delta (ctxt as Context {delta, ...}) = delta;
fun get_delta_count (ctxt as Context {delta_count, ...}) = !delta_count;
fun get_delta_count_incr (ctxt as Context {delta_count, ...}) =
let val current_delta_count = !delta_count
in
(delta_count:=(!delta_count)+1;current_delta_count)
end;
fun incr_delta_count (ctxt as Context {delta_count, ...}) = (delta_count:=(!delta_count)+1);
(* replace the old delta by new delta *)
(* count not changed! *)
fun put_delta new_delta ctxt =
map_context (fn (thy, syntax, data, asms, binds, thms, cases, defs,delta, delta_count) =>
(thy, syntax, data, asms, binds, thms, cases, defs, new_delta,delta_count)) ctxt;
(* init context *)
fun init thy =
let val data = Symtab.map (fn (_, (f, _)) => f thy) (ProofDataData.get thy) in
make_context (thy, (Theory.syn_of thy, [], []), data, (([], []), []), Vartab.empty,
(false, NameSpace.empty, Symtab.empty, FactIndex.empty), [],
(Vartab.empty, Vartab.empty, [], Symtab.empty), Symtab.empty, ref 0)
end;
(** local syntax **)
val fixedN = "\\<^fixed>";
val structN = "\\<^struct>";
(* translation functions *)
fun fixed_tr x = (fixedN ^ x, curry Term.list_comb (Syntax.free x));
fun context_tr' ctxt =
let
val (_, structs, mixfixed) = syntax_of ctxt;
fun tr' (t $ u) = tr' t $ tr' u
| tr' (Abs (x, T, t)) = Abs (x, T, tr' t)
| tr' (t as Free (x, T)) =
let val i = Library.find_index_eq x structs + 1 in
if i = 0 andalso x mem_string mixfixed then Const (fixedN ^ x, T)
else if i = 1 andalso not (! show_structs) then
Syntax.const "_struct" $ Syntax.const "_indexdefault"
else t
end
| tr' a = a;
in tr' end;
(* add syntax *)
fun mixfix_type mx = replicate (Syntax.mixfix_args mx) TypeInfer.logicT ---> TypeInfer.logicT;
local
fun mixfix x NONE mx = (fixedN ^ x, mixfix_type mx, Syntax.fix_mixfix x mx)
| mixfix x (SOME T) mx = (fixedN ^ x, T, Syntax.fix_mixfix x mx);
fun prep_mixfix (_, _, NONE) = NONE
| prep_mixfix (x, opt_T, SOME mx) = SOME (mixfix x opt_T mx);
fun prep_mixfix' (_, _, NONE) = NONE
| prep_mixfix' (x, _, SOME Syntax.NoSyn) = NONE
| prep_mixfix' (x, opt_T, _) = SOME (x, mixfix x opt_T (Syntax.literal x));
fun prep_struct (x, _, NONE) = SOME x
| prep_struct _ = NONE;
in
fun add_syntax decls =
map_context (fn (thy, (syn, structs, mixfixed), data, asms, binds, thms, cases, defs, delta, delta_count) =>
let
val is_logtype = Sign.is_logtype (Theory.sign_of thy);
val structs' = structs @ List.mapPartial prep_struct decls;
val mxs = List.mapPartial prep_mixfix decls;
val (fixed, mxs_output) = Library.split_list (List.mapPartial prep_mixfix' decls);
val trs = map fixed_tr fixed;
val syn' = syn
|> Syntax.extend_const_gram is_logtype ("", false) mxs_output
|> Syntax.extend_const_gram is_logtype ("", true) mxs
|> Syntax.extend_trfuns ([], trs, [], []);
in (thy, (syn', structs', fixed @ mixfixed), data, asms, binds, thms, cases, defs, delta, delta_count) end)
fun syn_of (Context {syntax = (syn, structs, _), ...}) =
syn |> Syntax.extend_trfuns (Syntax.struct_trfuns structs);
end;
(** pretty printing **)
fun pretty_term ctxt t = Sign.pretty_term' (syn_of ctxt) (sign_of ctxt) (context_tr' ctxt t);
fun pretty_typ ctxt T = Sign.pretty_typ (sign_of ctxt) T;
fun pretty_sort ctxt S = Sign.pretty_sort (sign_of ctxt) S;
fun pretty_classrel ctxt cs = Sign.pretty_classrel (sign_of ctxt) cs;
fun pretty_arity ctxt ar = Sign.pretty_arity (sign_of ctxt) ar;
fun pp ctxt = Pretty.pp (pretty_term ctxt, pretty_typ ctxt, pretty_sort ctxt,
pretty_classrel ctxt, pretty_arity ctxt);
val string_of_term = Pretty.string_of oo pretty_term;
fun pretty_thm ctxt thm =
if ! Display.show_hyps then
Display.pretty_thm_aux (pp ctxt) false thm
else pretty_term ctxt (Thm.prop_of thm);
fun pretty_thms ctxt [th] = pretty_thm ctxt th
| pretty_thms ctxt ths = Pretty.blk (0, Pretty.fbreaks (map (pretty_thm ctxt) ths));
fun pretty_fact ctxt ("", ths) = pretty_thms ctxt ths
| pretty_fact ctxt (a, [th]) =
Pretty.block [Pretty.str (a ^ ":"), Pretty.brk 1, pretty_thm ctxt th]
| pretty_fact ctxt (a, ths) =
Pretty.block (Pretty.fbreaks (Pretty.str (a ^ ":") :: map (pretty_thm ctxt) ths));
(** default sorts and types **)
fun def_sort (Context {defs = (_, sorts, _, _), ...}) xi = Vartab.lookup (sorts, xi);
fun def_type (Context {binds, defs = (types, _, _, _), ...}) pattern xi =
(case Vartab.lookup (types, xi) of
NONE =>
if pattern then NONE else
(case Vartab.lookup (binds, xi) of
SOME (SOME (_, T)) => SOME (TypeInfer.polymorphicT T)
| _ => NONE)
| some => some);
fun default_type (Context {defs = (types, _, _, _), ...}) x = Vartab.lookup (types, (x, ~1));
fun used_types (Context {defs = (_, _, used, _), ...}) = used;
(** prepare types **)
local
fun read_typ_aux read ctxt s =
transform_error (read (syn_of ctxt) (sign_of ctxt, def_sort ctxt)) s
handle ERROR_MESSAGE msg => raise CONTEXT (msg, ctxt);
fun cert_typ_aux cert ctxt raw_T =
cert (sign_of ctxt) raw_T
handle TYPE (msg, _, _) => raise CONTEXT (msg, ctxt);
in
(* Read/certify type, using default sort information from context. *)
val read_typ = read_typ_aux Sign.read_typ';
val read_typ_raw = read_typ_aux Sign.read_typ_raw';
val cert_typ = cert_typ_aux Sign.certify_typ;
val cert_typ_raw = cert_typ_aux Sign.certify_typ_raw;
end;
(* internalize Skolem constants *)
fun lookup_skolem ctxt x = assoc (fixes_of ctxt, x);
fun get_skolem ctxt x = getOpt (lookup_skolem ctxt x, x);
fun no_skolem internal ctxt x =
if can Syntax.dest_skolem x then
raise CONTEXT ("Illegal reference to internal Skolem constant: " ^ quote x, ctxt)
else if not internal andalso can Syntax.dest_internal x then
raise CONTEXT ("Illegal reference to internal variable: " ^ quote x, ctxt)
else x;
fun intern_skolem ctxt internal =
let
fun intern (t as Free (x, T)) =
if internal x then t
else
(case lookup_skolem ctxt (no_skolem false ctxt x) of
SOME x' => Free (x', T)
| NONE => t)
| intern (t $ u) = intern t $ intern u
| intern (Abs (x, T, t)) = Abs (x, T, intern t)
| intern a = a;
in intern end;
(* externalize Skolem constants -- for printing purposes only *)
fun extern_skolem ctxt =
let
val rev_fixes = map Library.swap (fixes_of ctxt);
fun extern (t as Free (x, T)) =
(case assoc (rev_fixes, x) of
SOME x' => Free (if lookup_skolem ctxt x' = SOME x then x' else NameSpace.hidden x', T)
| NONE => t)
| extern (t $ u) = extern t $ extern u
| extern (Abs (x, T, t)) = Abs (x, T, extern t)
| extern a = a;
in extern end
(** prepare terms and propositions **)
(*
(1) read / certify wrt. signature of context
(2) intern Skolem constants
(3) expand term bindings
*)
(* read / certify wrt. signature *) (*exception ERROR*) (*exception TERM*)
fun read_def_termTs freeze pp syn sg (types, sorts, used) sTs =
Sign.read_def_terms' pp (Sign.is_logtype sg) syn (sg, types, sorts) used freeze sTs;
fun read_def_termT freeze pp syn sg defs sT =
apfst hd (read_def_termTs freeze pp syn sg defs [sT]);
fun read_term_sg freeze pp syn sg defs s =
#1 (read_def_termT freeze pp syn sg defs (s, TypeInfer.logicT));
fun read_prop_sg freeze pp syn sg defs s =
#1 (read_def_termT freeze pp syn sg defs (s, propT));
fun read_terms_sg freeze pp syn sg defs =
#1 o read_def_termTs freeze pp syn sg defs o map (rpair TypeInfer.logicT);
fun read_props_sg freeze pp syn sg defs =
#1 o read_def_termTs freeze pp syn sg defs o map (rpair propT);
fun cert_term_sg pp sg t = #1 (Sign.certify_term pp sg t);
fun cert_prop_sg pp sg tm =
let val (t, T, _) = Sign.certify_term pp sg tm
in if T = propT then t else raise TERM ("Term not of type prop", [t]) end;
(* norm_term *)
(*beta normal form for terms (not eta normal form), chase variables in
bindings environment (code taken from Pure/envir.ML)*)
fun unifyT ctxt (T, U) =
let val maxidx = Int.max (Term.maxidx_of_typ T, Term.maxidx_of_typ U)
in #1 (Type.unify (Sign.tsig_of (sign_of ctxt)) (Vartab.empty, maxidx) (T, U)) end;
fun norm_term (ctxt as Context {binds, ...}) schematic =
let
(*raised when norm has no effect on a term, to do sharing instead of copying*)
exception SAME;
fun norm (t as Var (xi, T)) =
(case Vartab.lookup (binds, xi) of
SOME (SOME (u, U)) =>
let
val env = unifyT ctxt (T, U) handle Type.TUNIFY =>
raise TYPE ("norm_term: ill-typed variable assignment", [T, U], [t, u]);
val u' = Term.subst_TVars_Vartab env u;
in norm u' handle SAME => u' end
| _ =>
if schematic then raise SAME
else raise CONTEXT ("Unbound schematic variable: " ^ Syntax.string_of_vname xi, ctxt))
| norm (Abs (a, T, body)) = Abs (a, T, norm body)
| norm (Abs (_, _, body) $ t) = normh (subst_bound (t, body))
| norm (f $ t) =
((case norm f of
Abs (_, _, body) => normh (subst_bound (t, body))
| nf => nf $ (norm t handle SAME => t)) handle SAME => f $ norm t)
| norm _ = raise SAME
and normh t = norm t handle SAME => t
in normh end;
(* dummy patterns *)
fun prepare_dummies t = #2 (Term.replace_dummy_patterns (1, t));
fun reject_dummies ctxt t = Term.no_dummy_patterns t
handle TERM _ => raise CONTEXT ("Illegal dummy pattern(s) in term", ctxt);
(* read terms *)
local
fun append_env e1 e2 x = (case e2 x of NONE => e1 x | some => some);
fun gen_read' read app pattern dummies schematic
ctxt internal more_types more_sorts more_used s =
let
val types = append_env (def_type ctxt pattern) more_types;
val sorts = append_env (def_sort ctxt) more_sorts;
val used = used_types ctxt @ more_used;
in
(transform_error (read (pp ctxt) (syn_of ctxt) (sign_of ctxt) (types, sorts, used)) s
handle TERM (msg, _) => raise CONTEXT (msg, ctxt)
| ERROR_MESSAGE msg => raise CONTEXT (msg, ctxt))
|> app (intern_skolem ctxt internal)
|> app (if pattern then I else norm_term ctxt schematic)
|> app (if pattern then prepare_dummies else if dummies then I else reject_dummies ctxt)
end;
fun gen_read read app pattern dummies schematic ctxt =
gen_read' read app pattern dummies schematic ctxt (K false) (K NONE) (K NONE) [];
in
(* CB: for attribute where. See attrib.ML. *)
val read_termTs = gen_read' (read_def_termTs false) (apfst o map) false false false;
(* CB: for rule_tac etc. See method.ML. *)
val read_termTs_schematic = gen_read' (read_def_termTs false) (apfst o map) false false true;
fun read_term_pats T ctxt =
#1 o gen_read (read_def_termTs false) (apfst o map) true false false ctxt o map (rpair T);
val read_prop_pats = read_term_pats propT;
fun read_term_liberal ctxt =
gen_read' (read_term_sg true) I false false false ctxt (K true) (K NONE) (K NONE) [];
val read_term = gen_read (read_term_sg true) I false false false;
val read_term_dummies = gen_read (read_term_sg true) I false true false;
val read_prop = gen_read (read_prop_sg true) I false false false;
val read_prop_schematic = gen_read (read_prop_sg true) I false false true;
val read_terms = gen_read (read_terms_sg true) map false false false;
fun read_props schematic = gen_read (read_props_sg true) map false false schematic;
end;
(* certify terms *)
local
fun gen_cert cert pattern schematic ctxt t = t
|> (if pattern then I else norm_term ctxt schematic)
|> (fn t' => cert (pp ctxt) (sign_of ctxt) t'
handle TERM (msg, _) => raise CONTEXT (msg, ctxt));
in
val cert_term = gen_cert cert_term_sg false false;
val cert_prop = gen_cert cert_prop_sg false false;
val cert_props = map oo gen_cert cert_prop_sg false;
fun cert_term_pats _ = map o gen_cert cert_term_sg true false;
val cert_prop_pats = map o gen_cert cert_prop_sg true false;
end;
(* declare terms *)
local
val ins_types = foldl_aterms
(fn (types, Free (x, T)) => Vartab.update (((x, ~1), T), types)
| (types, Var v) => Vartab.update (v, types)
| (types, _) => types);
val ins_sorts = foldl_types (foldl_atyps
(fn (sorts, TFree (x, S)) => Vartab.update (((x, ~1), S), sorts)
| (sorts, TVar v) => Vartab.update (v, sorts)
| (sorts, _) => sorts));
val ins_used = foldl_term_types (fn t => foldl_atyps
(fn (used, TFree (x, _)) => x ins_string used
| (used, _) => used));
val ins_occs = foldl_term_types (fn t => foldl_atyps
(fn (tab, TFree (x, _)) => Symtab.update_multi ((x, t), tab) | (tab, _) => tab));
fun ins_skolem def_ty = foldr
(fn ((x, x'), types) =>
(case def_ty x' of
SOME T => Vartab.update (((x, ~1), T), types)
| NONE => types));
fun map_defaults f = map_context (fn (thy, syntax, data, asms, binds, thms, cases, defs, delta, delta_count) =>
(thy, syntax, data, asms, binds, thms, cases, f defs, delta, delta_count));
fun declare_syn (ctxt, t) =
ctxt
|> map_defaults (fn (types, sorts, used, occ) => (ins_types (types, t), sorts, used, occ))
|> map_defaults (fn (types, sorts, used, occ) => (types, ins_sorts (sorts, t), used, occ))
|> map_defaults (fn (types, sorts, used, occ) => (types, sorts, ins_used (used, t), occ));
fun declare_occ (ctxt as Context {asms = (_, fixes), ...}, t) =
declare_syn (ctxt, t)
|> map_defaults (fn (types, sorts, used, occ) => (types, sorts, used, ins_occs (occ, t)))
|> map_defaults (fn (types, sorts, used, occ) =>
(ins_skolem (fn x => Vartab.lookup (types, (x, ~1))) types fixes, sorts, used, occ));
in
fun declare_term t ctxt = declare_occ (ctxt, t);
fun declare_terms ts ctxt = Library.foldl declare_occ (ctxt, ts);
fun declare_terms_syntax ts ctxt = Library.foldl declare_syn (ctxt, ts);
end;
(** Hindley-Milner polymorphism **)
(* warn_extra_tfrees *)
fun warn_extra_tfrees
(ctxt1 as Context {defs = (_, _, _, occ1), ...})
(ctxt2 as Context {defs = (_, _, _, occ2), ...}) =
let
fun known_tfree a (Type (_, Ts)) = exists (known_tfree a) Ts
| known_tfree a (TFree (a', _)) = a = a'
| known_tfree _ _ = false;
val extras =
Library.gen_rems Library.eq_fst (Symtab.dest occ2, Symtab.dest occ1)
|> map (fn (a, ts) => map (pair a) (List.mapPartial (try (#1 o Term.dest_Free)) ts)) |> List.concat
|> List.mapPartial (fn (a, x) =>
(case def_type ctxt1 false (x, ~1) of NONE => SOME (a, x)
| SOME T => if known_tfree a T then NONE else SOME (a, x)));
val tfrees = map #1 extras |> Library.sort_strings |> Library.unique_strings;
val frees = map #2 extras |> Library.sort_strings |> Library.unique_strings;
in
if null extras then ()
else warning ("Just introduced free type variable(s): " ^ commas tfrees ^ " in " ^
space_implode " or " frees);
ctxt2
end;
(* generalize type variables *)
fun generalize_tfrees inner outer =
let
val extra_fixes = fixed_names_of inner \\ fixed_names_of outer;
fun still_fixed (Free (x, _)) = not (x mem_string extra_fixes)
| still_fixed _ = false;
val occs_inner = type_occs inner;
val occs_outer = type_occs outer;
fun add (gen, a) =
if isSome (Symtab.lookup (occs_outer, a)) orelse
exists still_fixed (Symtab.lookup_multi (occs_inner, a))
then gen else a :: gen;
in fn tfrees => Library.foldl add ([], tfrees) end;
fun generalize inner outer ts =
let
val tfrees = generalize_tfrees inner outer (foldr Term.add_term_tfree_names [] ts);
fun gen (x, S) = if x mem_string tfrees then TVar ((x, 0), S) else TFree (x, S);
in map (Term.map_term_types (Term.map_type_tfree gen)) ts end;
(** export theorems **)
fun get_free x (NONE, t as Free (y, _)) = if x = y then SOME t else NONE
| get_free _ (opt, _) = opt;
fun find_free t x = foldl_aterms (get_free x) (NONE, t);
fun export_view view is_goal inner outer =
let
val gen = generalize_tfrees inner outer;
val fixes = fixed_names_of inner \\ fixed_names_of outer;
val asms = Library.drop (length (assumptions_of outer), assumptions_of inner);
val exp_asms = map (fn (cprops, exp) => exp is_goal cprops) asms;
in fn thm => thm
|> Tactic.norm_hhf_rule
|> Seq.EVERY (rev exp_asms)
|> Seq.map (Drule.implies_intr_list view)
|> Seq.map (fn rule =>
let
val {sign, prop, ...} = Thm.rep_thm rule;
val frees = map (Thm.cterm_of sign) (List.mapPartial (find_free prop) fixes);
val tfrees = gen (Term.add_term_tfree_names (prop, []));
in
rule
|> Drule.forall_intr_list frees
|> Tactic.norm_hhf_rule
|> (#1 o Drule.tvars_intr_list tfrees)
end)
end;
(* without varification *)
fun export_view' view is_goal inner outer =
let
val asms = Library.drop (length (assumptions_of outer), assumptions_of inner);
val exp_asms = map (fn (cprops, exp) => exp is_goal cprops) asms;
in fn thm =>thm
|> Tactic.norm_hhf_plain
|> Seq.EVERY (rev exp_asms)
|> Seq.map (Drule.implies_intr_list view)
|> Seq.map Tactic.norm_hhf_plain
end;
val export = export_view [];
fun gen_export_std exp_view view inner outer =
let val exp = exp_view view false inner outer in
fn th =>
(case Seq.pull (exp th) of
SOME (th', _) => th' |> Drule.local_standard
| NONE => raise CONTEXT ("Internal failure while exporting theorem", inner))
end;
val export_standard = gen_export_std export_view;
val export_plain = gen_export_std export_view';
(** bindings **)
(* update_binds *)
fun del_bind (ctxt, xi) =
ctxt
|> map_context (fn (thy, syntax, data, asms, binds, thms, cases, defs, delta, delta_count) =>
(thy, syntax, data, asms, Vartab.update ((xi, NONE), binds), thms, cases, defs, delta, delta_count));
fun upd_bind (ctxt, ((x, i), t)) =
let
val T = Term.fastype_of t;
val t' =
if null (Term.term_tvars t \\ Term.typ_tvars T) then t
else Var ((x ^ "_has_extra_type_vars_on_rhs", i), T);
in
ctxt
|> declare_term t'
|> map_context (fn (thy, syntax, data, asms, binds, thms, cases, defs, delta, delta_count) =>
(thy, syntax, data, asms, Vartab.update (((x, i), SOME (t', T)), binds), thms, cases, defs, delta, delta_count))
end;
fun del_upd_bind (ctxt, (xi, NONE)) = del_bind (ctxt, xi)
| del_upd_bind (ctxt, (xi, SOME t)) = upd_bind (ctxt, (xi, t));
fun update_binds bs ctxt = Library.foldl upd_bind (ctxt, bs);
fun delete_update_binds bs ctxt = Library.foldl del_upd_bind (ctxt, bs);
(* simult_matches *)
fun simult_matches ctxt [] = []
| simult_matches ctxt pairs =
let
fun fail () = raise CONTEXT ("Pattern match failed!", ctxt);
val maxidx = Library.foldl (fn (i, (t1, t2)) =>
Int.max (i, Int.max (Term.maxidx_of_term t1, Term.maxidx_of_term t2))) (~1, pairs);
val envs = Unify.smash_unifiers (sign_of ctxt, Envir.empty maxidx,
map swap pairs); (*prefer assignment of variables from patterns*)
val env =
(case Seq.pull envs of
NONE => fail ()
| SOME (env, _) => env); (*ignore further results*)
val domain =
filter_out Term.is_replaced_dummy_pattern (map #1 (Drule.vars_of_terms (map #1 pairs)));
val _ = (*may not assign variables from text*)
if null (map #1 (Envir.alist_of env) inter (map #1 (Drule.vars_of_terms (map #2 pairs))))
then () else fail ();
fun norm_bind (xi, t) = if xi mem domain then SOME (xi, Envir.norm_term env t) else NONE;
in List.mapPartial norm_bind (Envir.alist_of env) end;
(* add_binds(_i) *)
local
fun gen_bind prep (ctxt, (xi as (x, _), raw_t)) =
ctxt |> delete_update_binds [(xi, Option.map (prep ctxt) raw_t)];
fun gen_binds prep binds ctxt = Library.foldl (gen_bind prep) (ctxt, binds);
in
fun drop_schematic (b as (xi, SOME t)) = if null (Term.term_vars t) then b else (xi, NONE)
| drop_schematic b = b;
val add_binds = gen_binds read_term;
val add_binds_i = gen_binds cert_term;
fun auto_bind f ts ctxt = ctxt |> add_binds_i (map drop_schematic (f (sign_of ctxt) ts));
val auto_bind_goal = auto_bind AutoBind.goal;
val auto_bind_facts = auto_bind AutoBind.facts;
end;
(* match_bind(_i) *)
local
fun prep_bind prep_pats (ctxt, (raw_pats, t)) =
let
val ctxt' = declare_term t ctxt;
val pats = prep_pats (fastype_of t) ctxt' raw_pats;
val binds = simult_matches ctxt' (map (rpair t) pats);
in (ctxt', binds) end;
fun gen_binds prep_terms prep_pats gen raw_binds ctxt =
let
val ts = prep_terms ctxt (map snd raw_binds);
val (ctxt', binds) =
apsnd List.concat (foldl_map (prep_bind prep_pats) (ctxt, map fst raw_binds ~~ ts));
val binds' =
if gen then map #1 binds ~~ generalize ctxt' ctxt (map #2 binds)
else binds;
val binds'' = map (apsnd SOME) binds';
in
warn_extra_tfrees ctxt
(if gen then ctxt (*sic!*) |> declare_terms (map #2 binds') |> add_binds_i binds''
else ctxt' |> add_binds_i binds'')
end;
in
val match_bind = gen_binds read_terms read_term_pats;
val match_bind_i = gen_binds (map o cert_term) cert_term_pats;
end;
(* propositions with patterns *)
local
fun prep_propp schematic prep_props prep_pats (context, args) =
let
fun prep ((ctxt, prop :: props), (_, (raw_pats1, raw_pats2))) =
let
val ctxt' = declare_term prop ctxt;
val pats = prep_pats ctxt' (raw_pats1 @ raw_pats2); (*simultaneous type inference!*)
in ((ctxt', props), (prop, splitAt(length raw_pats1, pats))) end
| prep _ = sys_error "prep_propp";
val ((context', _), propp) = foldl_map (foldl_map prep)
((context, prep_props schematic context (List.concat (map (map fst) args))), args);
in (context', propp) end;
fun matches ctxt (prop, (pats1, pats2)) =
simult_matches ctxt (map (rpair prop) pats1 @ map (rpair (Logic.strip_imp_concl prop)) pats2);
fun gen_bind_propp prepp (ctxt, raw_args) =
let
val (ctxt', args) = prepp (ctxt, raw_args);
val binds = List.concat (List.concat (map (map (matches ctxt')) args));
val propss = map (map #1) args;
(*generalize result: context evaluated now, binds added later*)
val gen = generalize ctxt' ctxt;
fun gen_binds c = c |> add_binds_i (map #1 binds ~~ map SOME (gen (map #2 binds)));
in (ctxt' |> add_binds_i (map (apsnd SOME) binds), (propss, gen_binds)) end;
in
val read_propp = prep_propp false read_props read_prop_pats;
val cert_propp = prep_propp false cert_props cert_prop_pats;
val read_propp_schematic = prep_propp true read_props read_prop_pats;
val cert_propp_schematic = prep_propp true cert_props cert_prop_pats;
val bind_propp = gen_bind_propp read_propp;
val bind_propp_i = gen_bind_propp cert_propp;
val bind_propp_schematic = gen_bind_propp read_propp_schematic;
val bind_propp_schematic_i = gen_bind_propp cert_propp_schematic;
end;
(** theorems **)
(* get_thm(s) *)
(*beware of proper order of evaluation!*)
fun retrieve_thms f g (ctxt as Context {thy, thms = (_, space, tab, _), ...}) =
let
val sg_ref = Sign.self_ref (Theory.sign_of thy);
val get_from_thy = f thy;
in
fn xnamei as (xname, _) =>
(case Symtab.lookup (tab, NameSpace.intern space xname) of
SOME (SOME ths) => map (Thm.transfer_sg (Sign.deref sg_ref))
(PureThy.select_thm xnamei ths)
| _ => get_from_thy xnamei) |> g xname
end;
val get_thm = retrieve_thms PureThy.get_thms PureThy.single_thm;
val get_thm_closure = retrieve_thms PureThy.get_thms_closure PureThy.single_thm;
val get_thms = retrieve_thms PureThy.get_thms (K I);
val get_thms_closure = retrieve_thms PureThy.get_thms_closure (K I);
(* name space operations *)
fun cond_extern (Context {thms = (_, space, _, _), ...}) = NameSpace.cond_extern space;
fun qualified q = map_context (fn (thy, syntax, data, asms, binds,
(_, space, tab, index), cases, defs, delta, delta_count) =>
(thy, syntax, data, asms, binds, (q, space, tab, index), cases, defs, delta, delta_count));
fun restore_qualified (Context {thms, ...}) = qualified (#1 thms);
fun hide_thms fully names =
map_context (fn (thy, syntax, data, asms, binds, (q, space, tab, index), cases, defs, delta, delta_count) =>
(thy, syntax, data, asms, binds, (q, NameSpace.hide fully (space, names), tab, index),
cases, defs, delta, delta_count));
(* put_thm(s) *)
fun gen_put_thms _ _ ("", _) ctxt = ctxt
| gen_put_thms override_q acc (name, ths) ctxt = ctxt |> map_context
(fn (thy, syntax, data, asms, binds, (q, space, tab, index), cases, defs, delta, delta_count) =>
if not override_q andalso not q andalso NameSpace.is_qualified name then
raise CONTEXT ("Attempt to declare qualified name " ^ quote name, ctxt)
else (thy, syntax, data, asms, binds, (q, NameSpace.extend' acc (space, [name]),
Symtab.update ((name, SOME ths), tab),
FactIndex.add (is_known ctxt) (index, (name, ths))), cases, defs, delta, delta_count));
fun gen_put_thm q acc (name, th) = gen_put_thms q acc (name, [th]);
fun gen_put_thmss q acc [] ctxt = ctxt
| gen_put_thmss q acc (th :: ths) ctxt =
ctxt |> gen_put_thms q acc th |> gen_put_thmss q acc ths;
val put_thm = gen_put_thm false NameSpace.accesses;
val put_thms = gen_put_thms false NameSpace.accesses;
val put_thmss = gen_put_thmss false NameSpace.accesses;
(* reset_thms *)
fun reset_thms name =
map_context (fn (thy, syntax, data, asms, binds, (q, space, tab, index), cases, defs, delta, delta_count) =>
(thy, syntax, data, asms, binds, (q, space, Symtab.update ((name, NONE), tab), index),
cases, defs, delta,delta_count));
(* note_thmss *)
local
fun gen_note_thss get acc (ctxt, ((name, more_attrs), ths_attrs)) =
let
fun app ((ct, ths), (th, attrs)) =
let val (ct', th') = Thm.applys_attributes ((ct, get ctxt th), attrs @ more_attrs)
in (ct', th' :: ths) end;
val (ctxt', rev_thms) = Library.foldl app ((ctxt, []), ths_attrs);
val thms = List.concat (rev rev_thms);
in (ctxt' |> gen_put_thms true acc (name, thms), (name, thms)) end;
fun gen_note_thmss get acc args ctxt =
foldl_map (gen_note_thss get acc) (ctxt, args);
in
val note_thmss = gen_note_thmss get_thms NameSpace.accesses;
val note_thmss_i = gen_note_thmss (K I) NameSpace.accesses;
val note_thmss_accesses = gen_note_thmss get_thms;
val note_thmss_accesses_i = gen_note_thmss (K I);
end;
(** assumptions **)
(* basic exporters *)
fun export_assume true = Seq.single oo Drule.implies_intr_goals
| export_assume false = Seq.single oo Drule.implies_intr_list;
fun export_presume _ = export_assume false;
(* defs *)
fun cert_def ctxt eq =
let
fun err msg = raise CONTEXT (msg ^
"\nThe error(s) above occurred in local definition: " ^ string_of_term ctxt eq, ctxt);
val (lhs, rhs) = Logic.dest_equals (Term.strip_all_body eq)
handle TERM _ => err "Not a meta-equality (==)";
val (f, xs) = Term.strip_comb lhs;
val (c, _) = Term.dest_Free f handle TERM _ =>
err "Head of lhs must be a free/fixed variable";
fun is_free (Free (x, _)) = not (is_fixed ctxt x)
| is_free _ = false;
val extra_frees = List.filter is_free (term_frees rhs) \\ xs;
in
conditional (not (forall (is_Bound orf is_free) xs andalso null (duplicates xs))) (fn () =>
err "Arguments of lhs must be distinct free/bound variables");
conditional (f mem Term.term_frees rhs) (fn () =>
err "Element to be defined occurs on rhs");
conditional (not (null extra_frees)) (fn () =>
err ("Extra free variables on rhs: " ^ commas_quote (map (#1 o dest_Free) extra_frees)));
(c, Term.list_all_free (List.mapPartial (try Term.dest_Free) xs, eq))
end;
fun head_of_def cprop =
#1 (Term.strip_comb (#1 (Logic.dest_equals (Term.strip_all_body (Thm.term_of cprop)))))
|> Thm.cterm_of (Thm.sign_of_cterm cprop);
fun export_def _ cprops thm =
thm
|> Drule.implies_intr_list cprops
|> Drule.forall_intr_list (map head_of_def cprops)
|> Drule.forall_elim_vars 0
|> RANGE (replicate (length cprops) (Tactic.rtac Drule.reflexive_thm)) 1;
(* assume *)
local
fun add_assm (ctxt, ((name, attrs), props)) =
let
val cprops = map (Thm.cterm_of (sign_of ctxt)) props;
val asms = map (Tactic.norm_hhf_rule o Thm.assume) cprops;
val ths = map (fn th => ([th], [])) asms;
val (ctxt', [(_, thms)]) =
ctxt
|> auto_bind_facts props
|> note_thmss_i [((name, attrs), ths)];
in (ctxt', (cprops, (name, asms), (name, thms))) end;
fun gen_assms prepp exp args ctxt =
let
val (ctxt1, propss) = prepp (ctxt, map snd args);
val (ctxt2, results) = foldl_map add_assm (ctxt1, map fst args ~~ propss);
val cprops = List.concat (map #1 results);
val asmss = map #2 results;
val thmss = map #3 results;
val ctxt3 = ctxt2 |> map_context
(fn (thy, syntax, data, ((asms_ct, asms_th), fixes), binds, thms, cases, defs, delta, delta_count) =>
(thy, syntax, data, ((asms_ct @ [(cprops, exp)], asms_th @ asmss), fixes), binds, thms,
cases, defs, delta, delta_count));
val ctxt4 = ctxt3 |> put_thms ("prems", prems_of ctxt3);
in (warn_extra_tfrees ctxt ctxt4, thmss) end;
in
val assume = gen_assms (apsnd #1 o bind_propp);
val assume_i = gen_assms (apsnd #1 o bind_propp_i);
end;
(* variables *)
local
fun prep_vars prep_typ internal liberal (ctxt, (xs, raw_T)) =
let
fun cond_tvars T =
if internal then T
else Type.no_tvars T handle TYPE (msg, _, _) => raise CONTEXT (msg, ctxt);
val _ = if liberal then () else
(case List.filter (not o Syntax.is_identifier) (map (no_skolem internal ctxt) xs) of
[] => () | bads => raise CONTEXT ("Bad variable name(s): " ^ commas_quote bads, ctxt));
val opt_T = Option.map (cond_tvars o prep_typ ctxt) raw_T;
val T = getOpt (opt_T, TypeInfer.logicT);
val ctxt' = ctxt |> declare_terms_syntax (map (fn x => Free (x, T)) xs);
in (ctxt', (xs, opt_T)) end;
in
val read_vars = prep_vars read_typ false false;
val cert_vars = prep_vars cert_typ true false;
val read_vars_liberal = prep_vars read_typ false true;
val cert_vars_liberal = prep_vars cert_typ true true;
end;
(* fix *)
local
fun map_fixes f =
map_context (fn (thy, syntax, data, (assumes, fixes), binds, thms, cases, defs, delta, delta_count) =>
(thy, syntax, data, (assumes, f fixes), binds, thms, cases, defs, delta, delta_count));
fun err_dups ctxt xs = raise CONTEXT ("Duplicate variable(s): " ^ commas_quote xs, ctxt);
val declare =
declare_terms_syntax o List.mapPartial (fn (_, NONE) => NONE | (x, SOME T) => SOME (Free (x, T)));
fun add_vars xs Ts ctxt =
let val xs' = Term.variantlist (map Syntax.skolem xs, map #2 (fixes_of ctxt)) in
ctxt
|> declare (xs' ~~ Ts)
|> map_fixes (fn fixes => (xs ~~ xs') @ fixes)
end;
fun add_vars_direct xs Ts ctxt =
ctxt
|> declare (xs ~~ Ts)
|> map_fixes (fn fixes =>
(case xs inter_string map #1 fixes of
[] => (xs ~~ xs) @ fixes
| dups => err_dups ctxt dups));
fun gen_fix prep add raw_vars ctxt =
let
val (ctxt', varss) = foldl_map prep (ctxt, raw_vars);
val vars = rev (List.concat (map (fn (xs, T) => map (rpair T) xs) varss));
val xs = map #1 vars;
val Ts = map #2 vars;
in
(case Library.duplicates xs of [] => () | dups => err_dups ctxt dups);
ctxt' |> add xs Ts
end;
fun prep_type (x, NONE, SOME mx) = ([x], SOME (mixfix_type mx))
| prep_type (x, opt_T, _) = ([x], opt_T);
in
val fix = gen_fix read_vars add_vars;
val fix_i = gen_fix cert_vars add_vars;
fun fix_direct liberal =
gen_fix (if liberal then cert_vars_liberal else cert_vars) add_vars_direct;
fun add_fixes decls = add_syntax decls o fix_direct false (map prep_type decls);
fun add_fixes_liberal decls = add_syntax decls o fix_direct true (map prep_type decls);
end;
fun fix_frees ts ctxt =
let
val frees = Library.foldl Term.add_frees ([], ts);
fun new (x, T) = if is_fixed ctxt x then NONE else SOME ([x], SOME T);
in fix_direct false (rev (List.mapPartial new frees)) ctxt end;
(*Note: improper use may result in variable capture / dynamic scoping!*)
fun bind_skolem ctxt xs =
let
val ctxt' = ctxt |> fix_i [(xs, NONE)];
fun bind (t as Free (x, T)) =
if x mem_string xs then
(case lookup_skolem ctxt' x of SOME x' => Free (x', T) | NONE => t)
else t
| bind (t $ u) = bind t $ bind u
| bind (Abs (x, T, t)) = Abs (x, T, bind t)
| bind a = a;
in bind end;
(** cases **)
fun prep_case ctxt name xs {fixes, assumes, binds} =
let
fun replace (opt_x :: xs) ((y, T) :: ys) = (getOpt (opt_x,y), T) :: replace xs ys
| replace [] ys = ys
| replace (_ :: _) [] = raise CONTEXT ("Too many parameters for case " ^ quote name, ctxt);
in
if null (foldr Term.add_typ_tvars [] (map snd fixes)) andalso
null (foldr Term.add_term_vars [] (List.concat (map snd assumes))) then
{fixes = replace xs fixes, assumes = assumes, binds = map drop_schematic binds}
else raise CONTEXT ("Illegal schematic variable(s) in case " ^ quote name, ctxt)
end;
fun get_case (ctxt as Context {cases, ...}) name xs =
(case assoc (cases, name) of
NONE => raise CONTEXT ("Unknown case: " ^ quote name, ctxt)
| SOME c => prep_case ctxt name xs c);
fun add_cases xs = map_context (fn (thy, syntax, data, asms, binds, thms, cases, defs, delta, delta_count) =>
(thy, syntax, data, asms, binds, thms, rev (filter_out (equal "" o #1) xs) @ cases, defs, delta, delta_count));
(** print context information **)
val verbose = ref false;
fun verb f x = if ! verbose then f (x ()) else [];
fun verb_single x = verb Library.single x;
fun setmp_verbose f x = Library.setmp verbose true f x;
fun pretty_items prt name items =
let
fun prt_itms (name, [x]) = Pretty.block [Pretty.str (name ^ ":"), Pretty.brk 1, prt x]
| prt_itms (name, xs) = Pretty.big_list (name ^ ":") (map prt xs);
in
if null items andalso not (! verbose) then []
else [Pretty.big_list name (map prt_itms items)]
end;
(* local syntax *)
val print_syntax = Syntax.print_syntax o syn_of;
(* term bindings *)
val smash_option = fn (_, NONE) => NONE | (xi, SOME b) => SOME (xi, b);
fun pretty_binds (ctxt as Context {binds, ...}) =
let
fun prt_bind (xi, (t, T)) = pretty_term ctxt (Logic.mk_equals (Var (xi, T), t));
val bs = List.mapPartial smash_option (Vartab.dest binds);
in
if null bs andalso not (! verbose) then []
else [Pretty.big_list "term bindings:" (map prt_bind bs)]
end;
val print_binds = Pretty.writeln o Pretty.chunks o pretty_binds;
(* local theorems *)
fun pretty_lthms (ctxt as Context {thms = (_, space, tab, _), ...}) =
pretty_items (pretty_thm ctxt) "facts:"
(List.mapPartial smash_option (NameSpace.cond_extern_table space tab));
val print_lthms = Pretty.writeln o Pretty.chunks o pretty_lthms;
(* local contexts *)
fun apply_case ({fixes, assumes, binds}: RuleCases.T) ctxt =
let
fun bind (c, (x, T)) = (c |> fix_i [([x], SOME T)], bind_skolem c [x] (Free (x, T)));
val (ctxt', xs) = foldl_map bind (ctxt, fixes);
fun app t = Library.foldl Term.betapply (t, xs);
in (ctxt', (map (apsnd (Option.map app)) binds, map (apsnd (map app)) assumes)) end;
fun pretty_cases (ctxt as Context {cases, ...}) =
let
val prt_term = pretty_term ctxt;
fun prt_let (xi, t) = Pretty.block
[Pretty.quote (prt_term (Var (xi, Term.fastype_of t))), Pretty.str " =", Pretty.brk 1,
Pretty.quote (prt_term t)];
fun prt_asm (a, ts) = Pretty.block (Pretty.breaks
((if a = "" then [] else [Pretty.str (a ^ ":")]) @ map (Pretty.quote o prt_term) ts));
fun prt_sect _ _ _ [] = []
| prt_sect s sep prt xs = [Pretty.block (Pretty.breaks (Pretty.str s ::
List.concat (Library.separate sep (map (Library.single o prt) xs))))];
fun prt_case (name, (fixes, (lets, asms))) = Pretty.block (Pretty.fbreaks
(Pretty.str (name ^ ":") ::
prt_sect "fix" [] (Pretty.str o fst) fixes @
prt_sect "let" [Pretty.str "and"] prt_let
(List.mapPartial (fn (xi, SOME t) => SOME (xi, t) | _ => NONE) lets) @
(if forall (null o #2) asms then []
else prt_sect "assume" [Pretty.str "and"] prt_asm asms)));
val cases' = rev (Library.gen_distinct Library.eq_fst cases);
in
if null cases andalso not (! verbose) then []
else [Pretty.big_list "cases:"
(map (prt_case o apsnd (fn c => (#fixes c, #2 (apply_case c ctxt)))) cases')]
end;
val print_cases = Pretty.writeln o Pretty.chunks o pretty_cases;
(* core context *)
val prems_limit = ref 10;
fun pretty_asms ctxt =
let
val prt_term = pretty_term ctxt;
(*structures*)
val (_, structs, _) = syntax_of ctxt;
val prt_structs = if null structs then []
else [Pretty.block (Pretty.str "structures:" :: Pretty.brk 1 ::
Pretty.commas (map Pretty.str structs))];
(*fixes*)
fun prt_fix (x, x') =
if x = x' then Pretty.str x
else Pretty.block [Pretty.str x, Pretty.str " =", Pretty.brk 1, prt_term (Syntax.free x')];
val fixes = rev (filter_out
((can Syntax.dest_internal o #1) orf (fn (_, x') => x' mem_string structs)) (fixes_of ctxt));
val prt_fixes = if null fixes then []
else [Pretty.block (Pretty.str "fixed variables:" :: Pretty.brk 1 ::
Pretty.commas (map prt_fix fixes))];
(*prems*)
val limit = ! prems_limit;
val prems = prems_of ctxt;
val len = length prems;
val prt_prems = if null prems then []
else [Pretty.big_list "prems:" ((if len <= limit then [] else [Pretty.str "..."]) @
map (pretty_thm ctxt) (Library.drop (len - limit, prems)))];
in prt_structs @ prt_fixes @ prt_prems end;
(* main context *)
fun pretty_context (ctxt as Context {cases, defs = (types, sorts, used, _), ...}) =
let
val prt_term = pretty_term ctxt;
val prt_typ = pretty_typ ctxt;
val prt_sort = pretty_sort ctxt;
(*theory*)
val pretty_thy = Pretty.block
[Pretty.str "Theory:", Pretty.brk 1, Sign.pretty_sg (sign_of ctxt)];
(*defaults*)
fun prt_atom prt prtT (x, X) = Pretty.block
[prt x, Pretty.str " ::", Pretty.brk 1, prtT X];
fun prt_var (x, ~1) = prt_term (Syntax.free x)
| prt_var xi = prt_term (Syntax.var xi);
fun prt_varT (x, ~1) = prt_typ (TFree (x, []))
| prt_varT xi = prt_typ (TVar (xi, []));
val prt_defT = prt_atom prt_var prt_typ;
val prt_defS = prt_atom prt_varT prt_sort;
in
verb_single (K pretty_thy) @
pretty_asms ctxt @
verb pretty_binds (K ctxt) @
verb pretty_lthms (K ctxt) @
verb pretty_cases (K ctxt) @
verb_single (fn () => Pretty.big_list "type constraints:" (map prt_defT (Vartab.dest types))) @
verb_single (fn () => Pretty.big_list "default sorts:" (map prt_defS (Vartab.dest sorts))) @
verb_single (fn () => Pretty.strs ("used type variable names:" :: used))
end;
(* print_thms_containing *)
fun lthms_containing (ctxt as Context {thms = (_, _, _, index), ...}) idx =
let
fun valid (name, ths) =
(case try (transform_error (fn () => get_thms ctxt (name, NONE))) () of
NONE => false
| SOME ths' => Library.equal_lists Thm.eq_thm (ths, ths'));
in gen_distinct eq_fst (List.filter valid (FactIndex.find idx index)) end;
val thms_containing_limit = ref 40;
fun print_thms_containing ctxt opt_limit ss =
let
val prt_term = pretty_term ctxt;
val prt_fact = pretty_fact ctxt;
fun prt_consts [] = []
| prt_consts cs = [Pretty.block (Pretty.breaks (Pretty.str "constants" ::
map (Pretty.quote o prt_term o Syntax.const) cs))];
fun prt_frees [] = []
| prt_frees xs = [Pretty.block (Pretty.breaks (Pretty.str "variables" ::
map (Pretty.quote o prt_term o Syntax.free) xs))];
val (cs, xs) = Library.foldl (FactIndex.index_term (is_known ctxt))
(([], []), map (read_term_dummies ctxt) ss);
val empty_idx = null cs andalso null xs;
val header =
if empty_idx then [Pretty.block [Pretty.str "Known facts:", Pretty.fbrk]]
else [Pretty.block (Pretty.breaks (Pretty.str "Facts containing" ::
separate (Pretty.str "and") (prt_consts cs @ prt_frees xs)) @
[Pretty.str ":", Pretty.fbrk])]
val facts =
PureThy.thms_containing (theory_of ctxt) (cs, xs) @ lthms_containing ctxt (cs, xs)
|> sort_wrt #1;
val len = length facts;
val limit = getOpt (opt_limit, ! thms_containing_limit);
in
if empty_idx andalso not (null ss) then
warning "thms_containing: no consts/frees in specification"
else (header @ (if len <= limit then [] else [Pretty.str "..."]) @
map prt_fact (Library.drop (len - limit, facts))) |> Pretty.chunks |> Pretty.writeln
end;
(** theory setup **)
val setup = [ProofDataData.init];
end;