(* Title: Pure/sign.ML
ID: $Id$
Author: Lawrence C Paulson and Markus Wenzel
The abstract type "sg" of signatures.
*)
(*base names*)
type bstring = string;
type bclass = class;
(*external forms -- partially qualified names*)
type xstring = string;
type xclass = class;
type xsort = sort;
type xtyp = typ;
type xterm = term;
signature SIGN =
sig
type sg
type sg_ref
type data
val rep_sg: sg ->
{self: sg_ref,
tsig: Type.type_sig,
const_tab: typ Symtab.table,
syn: Syntax.syntax,
path: string list option,
spaces: (string * NameSpace.T) list,
data: data}
val name_of: sg -> string
val stamp_names_of: sg -> string list
val exists_stamp: string -> sg -> bool
val tsig_of: sg -> Type.type_sig
val deref: sg_ref -> sg
val self_ref: sg -> sg_ref
val subsig: sg * sg -> bool
val joinable: sg * sg -> bool
val eq_sg: sg * sg -> bool
val same_sg: sg * sg -> bool
val is_draft: sg -> bool
val is_stale: sg -> bool
val const_type: sg -> string -> typ option
val classes: sg -> class list
val defaultS: sg -> sort
val subsort: sg -> sort * sort -> bool
val nodup_vars: term -> term
val norm_sort: sg -> sort -> sort
val of_sort: sg -> typ * sort -> bool
val witness_sorts: sg -> sort list -> sort list -> (typ * sort) list
val univ_witness: sg -> (typ * sort) option
val typ_instance: sg -> typ * typ -> bool
val classK: string
val typeK: string
val constK: string
val full_name: sg -> bstring -> string
val full_name_path: sg -> string -> bstring -> string
val base_name: string -> bstring
val intern: sg -> string -> xstring -> string
val extern: sg -> string -> string -> xstring
val cond_extern: sg -> string -> string -> xstring
val cond_extern_table: sg -> string -> 'a Symtab.table -> (xstring * 'a) list
val intern_class: sg -> xclass -> class
val intern_tycon: sg -> xstring -> string
val intern_const: sg -> xstring -> string
val intern_sort: sg -> xsort -> sort
val intern_typ: sg -> xtyp -> typ
val intern_term: sg -> xterm -> term
val intern_tycons: sg -> xtyp -> typ
val pretty_sg: sg -> Pretty.T
val str_of_sg: sg -> string
val pprint_sg: sg -> pprint_args -> unit
val pretty_term: sg -> term -> Pretty.T
val pretty_term': Syntax.syntax -> sg -> term -> Pretty.T
val pretty_typ: sg -> typ -> Pretty.T
val pretty_sort: sg -> sort -> Pretty.T
val pretty_classrel: sg -> class * class -> Pretty.T
val pretty_arity: sg -> string * sort list * sort -> Pretty.T
val string_of_term: sg -> term -> string
val string_of_typ: sg -> typ -> string
val string_of_sort: sg -> sort -> string
val str_of_sort: sg -> sort -> string
val str_of_classrel: sg -> class * class -> string
val str_of_arity: sg -> string * sort list * sort -> string
val pprint_term: sg -> term -> pprint_args -> unit
val pprint_typ: sg -> typ -> pprint_args -> unit
val certify_class: sg -> class -> class
val certify_sort: sg -> sort -> sort
val certify_typ: sg -> typ -> typ
val certify_typ_no_norm: sg -> typ -> typ
val certify_tycon: sg -> string -> string
val certify_tyabbr: sg -> string -> string
val certify_tyname: sg -> string -> string
val certify_const: sg -> string -> string
val certify_term: sg -> term -> term * typ * int
val read_sort: sg -> string -> sort
val read_raw_typ: sg * (indexname -> sort option) -> string -> typ
val read_typ: sg * (indexname -> sort option) -> string -> typ
val read_typ': Syntax.syntax -> sg * (indexname -> sort option) -> string -> typ
val read_typ_no_norm': Syntax.syntax -> sg * (indexname -> sort option) -> string -> typ
val infer_types: sg -> (indexname -> typ option) ->
(indexname -> sort option) -> string list -> bool
-> xterm list * typ -> term * (indexname * typ) list
val infer_types_simult: sg -> (indexname -> typ option) ->
(indexname -> sort option) -> string list -> bool
-> (xterm list * typ) list -> term list * (indexname * typ) list
val read_def_terms':
Syntax.syntax -> sg * (indexname -> typ option) * (indexname -> sort option) ->
string list -> bool -> (string * typ) list -> term list * (indexname * typ) list
val read_def_terms:
sg * (indexname -> typ option) * (indexname -> sort option) ->
string list -> bool -> (string * typ) list -> term list * (indexname * typ) list
val simple_read_term: sg -> typ -> string -> term
val add_classes: (bclass * xclass list) list -> sg -> sg
val add_classes_i: (bclass * class list) list -> sg -> sg
val add_classrel: (xclass * xclass) list -> sg -> sg
val add_classrel_i: (class * class) list -> sg -> sg
val add_defsort: string -> sg -> sg
val add_defsort_i: sort -> sg -> sg
val add_types: (bstring * int * mixfix) list -> sg -> sg
val add_nonterminals: bstring list -> sg -> sg
val add_tyabbrs: (bstring * string list * string * mixfix) list -> sg -> sg
val add_tyabbrs_i: (bstring * string list * typ * mixfix) list -> sg -> sg
val add_arities: (xstring * string list * string) list -> sg -> sg
val add_arities_i: (string * sort list * sort) list -> sg -> sg
val add_consts: (bstring * string * mixfix) list -> sg -> sg
val add_consts_i: (bstring * typ * mixfix) list -> sg -> sg
val add_syntax: (bstring * string * mixfix) list -> sg -> sg
val add_syntax_i: (bstring * typ * mixfix) list -> sg -> sg
val add_modesyntax: (string * bool) * (bstring * string * mixfix) list -> sg -> sg
val add_modesyntax_i: (string * bool) * (bstring * typ * mixfix) list -> sg -> sg
val add_trfuns:
(string * (ast list -> ast)) list *
(string * (term list -> term)) list *
(string * (term list -> term)) list *
(string * (ast list -> ast)) list -> sg -> sg
val add_trfunsT:
(string * (bool -> typ -> term list -> term)) list -> sg -> sg
val add_tokentrfuns:
(string * string * (string -> string * real)) list -> sg -> sg
val add_trrules: (xstring * string) Syntax.trrule list -> sg -> sg
val add_trrules_i: ast Syntax.trrule list -> sg -> sg
val add_path: string -> sg -> sg
val add_space: string * string list -> sg -> sg
val hide_space: bool -> string * string list -> sg -> sg
val hide_space_i: bool -> string * string list -> sg -> sg
val add_name: string -> sg -> sg
val data_kinds: data -> string list
val merge_refs: sg_ref * sg_ref -> sg_ref
val merge: sg * sg -> sg
val copy: sg -> sg
val prep_ext: sg -> sg
val PureN: string
val CPureN: string
val nontriv_merge: sg * sg -> sg
val pre_pure: sg
val const_of_class: class -> string
val class_of_const: string -> class
end;
signature PRIVATE_SIGN =
sig
include SIGN
val init_data: Object.kind * (Object.T * (Object.T -> Object.T) * (Object.T -> Object.T) *
(Object.T * Object.T -> Object.T) * (sg -> Object.T -> unit)) -> sg -> sg
val get_data: Object.kind -> (Object.T -> 'a) -> sg -> 'a
val put_data: Object.kind -> ('a -> Object.T) -> 'a -> sg -> sg
val print_data: Object.kind -> sg -> unit
end;
structure Sign: PRIVATE_SIGN =
struct
(** datatype sg **)
(* types sg, data, sg_ref *)
datatype sg =
Sg of
{id: string ref, (*id*)
stamps: string ref list} * (*unique theory indentifier*)
{self: sg_ref, (*mutable self reference*)
tsig: Type.type_sig, (*order-sorted signature of types*)
const_tab: typ Symtab.table, (*type schemes of constants*)
syn: Syntax.syntax, (*syntax for parsing and printing*)
path: string list option, (*current name space entry prefix*)
spaces: (string * NameSpace.T) list, (*name spaces for consts, types etc.*)
data: data} (*anytype data*)
and data =
Data of
(Object.kind * (*kind (for authorization)*)
(Object.T * (*value*)
((Object.T -> Object.T) * (*copy method*)
(Object.T -> Object.T) * (*prepare extend method*)
(Object.T * Object.T -> Object.T) * (*merge and prepare extend method*)
(sg -> Object.T -> unit)))) (*print method*)
Symtab.table
and sg_ref =
SgRef of sg ref option;
(*make signature*)
fun make_sign (id, self, tsig, const_tab, syn, path, spaces, data, stamps) =
Sg ({id = id, stamps = stamps}, {self = self, tsig = tsig, const_tab = const_tab,
syn = syn, path = path, spaces = spaces, data = data});
(* basic operations *)
fun rep_sg (Sg (_, args)) = args;
(*show stamps*)
fun stamp_names_of (Sg ({stamps, ...}, _)) = rev (map ! stamps);
fun exists_stamp name (Sg ({stamps, ...}, _)) = exists (equal name o !) stamps;
fun pretty_sg sg = Pretty.str_list "{" "}" (stamp_names_of sg);
val str_of_sg = Pretty.str_of o pretty_sg;
val pprint_sg = Pretty.pprint o pretty_sg;
val tsig_of = #tsig o rep_sg;
val syn_of = #syn o rep_sg;
fun const_type (Sg (_, {const_tab, ...})) c = Symtab.lookup (const_tab, c);
(* id and self *)
fun check_stale (sg as Sg ({id, ...},
{self = SgRef (Some (ref (Sg ({id = id', ...}, _)))), ...})) =
if id = id' then sg
else raise TERM ("Stale signature: " ^ str_of_sg sg, [])
| check_stale _ = sys_error "Sign.check_stale";
fun is_stale sg = (check_stale sg; false) handle TERM _ => true;
fun self_ref (sg as Sg (_, {self, ...})) = (check_stale sg; self);
fun deref (SgRef (Some (ref sg))) = sg
| deref (SgRef None) = sys_error "Sign.deref";
fun name_of (sg as Sg ({id = ref name, ...}, _)) =
if name = "" orelse ord name = ord "#" then
raise TERM ("Nameless signature " ^ str_of_sg sg, [])
else name;
(* inclusion and equality *)
local
(*avoiding polymorphic equality: factor 10 speedup*)
fun mem_stamp (_:string ref, []) = false
| mem_stamp (x, y :: ys) = x = y orelse mem_stamp (x, ys);
fun subset_stamp ([], ys) = true
| subset_stamp (x :: xs, ys) =
mem_stamp (x, ys) andalso subset_stamp (xs, ys);
(*fast partial test*)
fun fast_sub ([]: string ref list, _) = true
| fast_sub (_, []) = false
| fast_sub (x :: xs, y :: ys) =
if x = y then fast_sub (xs, ys)
else fast_sub (x :: xs, ys);
in
fun eq_sg (sg1 as Sg ({id = id1, ...}, _), sg2 as Sg ({id = id2, ...}, _)) =
(check_stale sg1; check_stale sg2; id1 = id2);
fun subsig (sg1 as Sg ({stamps = s1, ...}, _), sg2 as Sg ({stamps = s2, ...}, _)) =
eq_sg (sg1, sg2) orelse subset_stamp (s1, s2);
fun fast_subsig (sg1 as Sg ({stamps = s1, ...}, _), sg2 as Sg ({stamps = s2, ...}, _)) =
eq_sg (sg1, sg2) orelse fast_sub (s1, s2);
end;
fun joinable (sg1, sg2) = subsig (sg1, sg2) orelse subsig (sg2, sg1);
(*test if same theory names are contained in signatures' stamps,
i.e. if signatures belong to same theory but not necessarily to the
same version of it*)
fun same_sg (sg1 as Sg ({stamps = s1, ...}, _), sg2 as Sg ({stamps = s2, ...}, _)) =
eq_sg (sg1, sg2) orelse eq_set_string (pairself (map (op !)) (s1, s2));
(*test for drafts*)
fun is_draft (Sg ({stamps = ref name :: _, ...}, _)) = name = "" orelse ord name = ord "#";
(* classes and sorts *)
val classes = Type.classes o tsig_of;
val defaultS = Type.defaultS o tsig_of;
val subsort = Type.subsort o tsig_of;
val norm_sort = Type.norm_sort o tsig_of;
val of_sort = Type.of_sort o tsig_of;
val witness_sorts = Type.witness_sorts o tsig_of;
val univ_witness = Type.univ_witness o tsig_of;
fun typ_instance sg (T, U) = Type.typ_instance (tsig_of sg, T, U);
(** signature data **)
(* errors *)
fun of_theory sg = "\nof theory " ^ str_of_sg sg;
fun err_inconsistent kinds =
error ("Attempt to merge different versions of " ^ commas_quote kinds ^ " data");
fun err_method name kind e =
(writeln ("Error while invoking " ^ quote kind ^ " " ^ name ^ " method"); raise e);
fun err_dup_init sg kind =
error ("Duplicate initialization of " ^ quote kind ^ " data" ^ of_theory sg);
fun err_uninit sg kind =
error ("Tried to access uninitialized " ^ quote kind ^ " data" ^
of_theory sg);
(*Trying to access theory data using get / put operations from a different
instance of the TheoryDataFun result. Typical cure: re-load all files*)
fun err_access sg kind =
error ("Unauthorized access to " ^ quote kind ^ " data" ^ of_theory sg);
(* prepare data *)
val empty_data = Data Symtab.empty;
fun merge_data (Data tab1, Data tab2) =
let
val data1 = map snd (Symtab.dest tab1);
val data2 = map snd (Symtab.dest tab2);
val all_data = data1 @ data2;
val kinds = gen_distinct Object.eq_kind (map fst all_data);
fun entry data kind =
(case gen_assoc Object.eq_kind (data, kind) of
None => []
| Some x => [(kind, x)]);
fun merge_entries [(kind, (e, mths as (_, ext, _, _)))] =
(kind, (ext e handle exn => err_method "prep_ext" (Object.name_of_kind kind) exn, mths))
| merge_entries [(kind, (e1, mths as (_, _, mrg, _))), (_, (e2, _))] =
(kind, (mrg (e1, e2)
handle exn => err_method "merge" (Object.name_of_kind kind) exn, mths))
| merge_entries _ = sys_error "merge_entries";
val data = map (fn k => merge_entries (entry data1 k @ entry data2 k)) kinds;
val data_idx = map (fn (k, x) => (Object.name_of_kind k, (k, x))) data;
in
Data (Symtab.make data_idx)
handle Symtab.DUPS dups => err_inconsistent dups
end;
fun prep_ext_data data = merge_data (data, empty_data);
fun init_data_sg sg (Data tab) kind e cp ext mrg prt =
let val name = Object.name_of_kind kind in
Data (Symtab.update_new ((name, (kind, (e, (cp, ext, mrg, prt)))), tab))
handle Symtab.DUP _ => err_dup_init sg name
end;
(* access data *)
fun data_kinds (Data tab) = map fst (Symtab.dest tab);
fun lookup_data sg tab kind =
let val name = Object.name_of_kind kind in
(case Symtab.lookup (tab, name) of
Some (k, x) =>
if Object.eq_kind (kind, k) then x
else err_access sg name
| None => err_uninit sg name)
end;
fun get_data kind f (sg as Sg (_, {data = Data tab, ...})) =
let val x = fst (lookup_data sg tab kind)
in f x handle Match => Object.kind_error kind end;
fun print_data kind (sg as Sg (_, {data = Data tab, ...})) =
let val (e, (_, _, _, prt)) = lookup_data sg tab kind
in prt sg e handle exn => err_method ("print" ^ of_theory sg) (Object.name_of_kind kind) exn end;
fun put_data_sg sg (Data tab) kind f x =
Data (Symtab.update ((Object.name_of_kind kind,
(kind, (f x, snd (lookup_data sg tab kind)))), tab));
(** build signatures **)
fun ext_stamps stamps (id as ref name) =
let val stmps = (case stamps of ref "#" :: ss => ss | ss => ss) in
if exists (equal name o !) stmps then
error ("Theory already contains a " ^ quote name ^ " component")
else id :: stmps
end;
fun create_sign self stamps name (syn, tsig, ctab, (path, spaces), data) =
let
val id = ref name;
val sign =
make_sign (id, self, tsig, ctab, syn, path, spaces, data, ext_stamps stamps id);
in
(case self of
SgRef (Some r) => r := sign
| _ => sys_error "Sign.create_sign");
sign
end;
fun extend_sign keep extfun name decls
(sg as Sg ({id = _, stamps}, {self, tsig, const_tab, syn, path, spaces, data})) =
let
val _ = check_stale sg;
val (self', data') =
if is_draft sg andalso keep then (self, data)
else (SgRef (Some (ref sg)), prep_ext_data data);
in
create_sign self' stamps name
(extfun (syn, tsig, const_tab, (path, spaces), data') decls)
end;
(** name spaces **)
(* kinds *)
val classK = "class";
val typeK = "type";
val constK = "const";
(* declare and retrieve names *)
fun space_of spaces kind =
if_none (assoc (spaces, kind)) NameSpace.empty;
(*input and output of qualified names*)
fun intrn spaces kind = NameSpace.intern (space_of spaces kind);
fun extrn spaces kind = NameSpace.extern (space_of spaces kind);
fun cond_extrn spaces kind = NameSpace.cond_extern (space_of spaces kind);
fun cond_extrn_table spaces kind tab = NameSpace.cond_extern_table (space_of spaces kind) tab;
(*add / hide names*)
fun change_space f spaces kind x = overwrite (spaces, (kind, f (space_of spaces kind, x)));
fun add_names x = change_space NameSpace.extend x;
fun hide_names b x = change_space (NameSpace.hide b) x;
(*make full names*)
fun full _ "" = error "Attempt to declare empty name \"\""
| full None name = name
| full (Some path) name =
if NameSpace.is_qualified name then
error ("Attempt to declare qualified name " ^ quote name)
else NameSpace.pack (path @ [name]);
(*base name*)
val base_name = NameSpace.base;
(* intern / extern names *)
local
(*prepare mapping of names*)
fun mapping f add_xs t =
let
fun f' x = let val y = f x in if x = y then None else Some (x, y) end;
val table = mapfilter f' (add_xs (t, []));
fun lookup x = if_none (assoc (table, x)) x;
in lookup end;
(*intern / extern typ*)
fun trn_typ trn T =
T |> map_typ
(mapping (trn classK) add_typ_classes T)
(mapping (trn typeK) add_typ_tycons T);
(*intern / extern term*)
fun trn_term trn t =
t |> map_term
(mapping (trn classK) add_term_classes t)
(mapping (trn typeK) add_term_tycons t)
(mapping (trn constK) add_term_consts t);
val spaces_of = #spaces o rep_sg;
in
fun intrn_class spaces = intrn spaces classK;
fun extrn_class spaces = extrn spaces classK;
val intrn_sort = map o intrn_class;
val intrn_typ = trn_typ o intrn;
val intrn_term = trn_term o intrn;
val extrn_sort = map o extrn_class;
val extrn_typ = trn_typ o extrn;
val extrn_term = trn_term o extrn;
fun intrn_tycons spaces T =
map_typ I (mapping (intrn spaces typeK) add_typ_tycons T) T;
val intern = intrn o spaces_of;
val extern = extrn o spaces_of;
val cond_extern = cond_extrn o spaces_of;
fun cond_extern_table sg = cond_extrn_table (spaces_of sg);
val intern_class = intrn_class o spaces_of;
val intern_sort = intrn_sort o spaces_of;
val intern_typ = intrn_typ o spaces_of;
val intern_term = intrn_term o spaces_of;
fun intern_tycon sg = intrn (spaces_of sg) typeK;
fun intern_const sg = intrn (spaces_of sg) constK;
val intern_tycons = intrn_tycons o spaces_of;
val full_name = full o #path o rep_sg;
fun full_name_path sg elems =
full (Some (if_none (#path (rep_sg sg)) [] @ NameSpace.unpack elems));
end;
(** pretty printing of terms, types etc. **)
fun pretty_term' syn (sg as Sg ({stamps, ...}, {spaces, ...})) t =
Syntax.pretty_term syn
(exists (equal "CPure" o !) stamps)
(if ! NameSpace.long_names then t else extrn_term spaces t);
fun pretty_term sg = pretty_term' (syn_of sg) sg;
fun pretty_typ (Sg (_, {syn, spaces, ...})) T =
Syntax.pretty_typ syn
(if ! NameSpace.long_names then T else extrn_typ spaces T);
fun pretty_sort (Sg (_, {syn, spaces, ...})) S =
Syntax.pretty_sort syn
(if ! NameSpace.long_names then S else extrn_sort spaces S);
fun pretty_classrel sg (c1, c2) = Pretty.block
[pretty_sort sg [c1], Pretty.str " <", Pretty.brk 1, pretty_sort sg [c2]];
fun pretty_arity sg (t, Ss, S) =
let
val t' = cond_extern sg typeK t;
val dom =
if null Ss then []
else [Pretty.list "(" ")" (map (pretty_sort sg) Ss), Pretty.brk 1];
in
Pretty.block
([Pretty.str (t' ^ " ::"), Pretty.brk 1] @ dom @ [pretty_sort sg S])
end;
fun string_of_term sg t = Pretty.string_of (pretty_term sg t);
fun string_of_typ sg T = Pretty.string_of (pretty_typ sg T);
fun string_of_sort sg S = Pretty.string_of (pretty_sort sg S);
fun str_of_sort sg S = Pretty.str_of (pretty_sort sg S);
fun str_of_classrel sg c1_c2 = Pretty.str_of (pretty_classrel sg c1_c2);
fun str_of_arity sg ar = Pretty.str_of (pretty_arity sg ar);
fun pprint_term sg = Pretty.pprint o Pretty.quote o (pretty_term sg);
fun pprint_typ sg = Pretty.pprint o Pretty.quote o (pretty_typ sg);
(** read sorts **) (*exception ERROR*)
fun err_in_sort s =
error ("The error(s) above occurred in sort " ^ quote s);
fun rd_sort syn tsig spaces str =
let val S = intrn_sort spaces (Syntax.read_sort syn str handle ERROR => err_in_sort str)
in Type.cert_sort tsig S handle TYPE (msg, _, _) => (error_msg msg; err_in_sort str) end;
(*read and certify sort wrt a signature*)
fun read_sort (sg as Sg (_, {tsig, syn, spaces, ...})) str =
(check_stale sg; rd_sort syn tsig spaces str);
fun cert_sort _ tsig _ = Type.cert_sort tsig;
(** read types **) (*exception ERROR*)
fun err_in_type s =
error ("The error(s) above occurred in type " ^ quote s);
fun rd_raw_typ syn tsig spaces def_sort str =
intrn_tycons spaces
(Syntax.read_typ syn (Type.get_sort tsig def_sort (intrn_sort spaces)) (intrn_sort spaces) str
handle ERROR => err_in_type str);
fun read_raw_typ' syn (sg as Sg (_, {tsig, spaces, ...}), def_sort) str =
(check_stale sg; rd_raw_typ syn tsig spaces def_sort str);
fun read_raw_typ (sg, def_sort) = read_raw_typ' (syn_of sg) (sg, def_sort);
(*read and certify typ wrt a signature*)
local
fun read_typ_aux rd cert (sg, def_sort) str =
(cert (tsig_of sg) (rd (sg, def_sort) str)
handle TYPE (msg, _, _) => (error_msg msg; err_in_type str));
in
val read_typ = read_typ_aux read_raw_typ Type.cert_typ;
val read_typ_no_norm = read_typ_aux read_raw_typ Type.cert_typ_no_norm;
fun read_typ' syn = read_typ_aux (read_raw_typ' syn) Type.cert_typ;
fun read_typ_no_norm' syn = read_typ_aux (read_raw_typ' syn) Type.cert_typ_no_norm;
end;
(** certify classes, sorts, types and terms **) (*exception TYPE*)
val certify_class = Type.cert_class o tsig_of;
val certify_sort = Type.cert_sort o tsig_of;
val certify_typ = Type.cert_typ o tsig_of;
val certify_typ_no_norm = Type.cert_typ_no_norm o tsig_of;
fun certify_tycon sg c =
if is_some (Symtab.lookup (#tycons (Type.rep_tsig (tsig_of sg)), c)) then c
else raise TYPE ("Undeclared type constructor " ^ quote c, [], []);
fun certify_tyabbr sg c =
if is_some (Symtab.lookup (#abbrs (Type.rep_tsig (tsig_of sg)), c)) then c
else raise TYPE ("Unknown type abbreviation " ^ quote c, [], []);
fun certify_tyname sg c =
certify_tycon sg c handle TYPE _ => certify_tyabbr sg c handle TYPE _ =>
raise TYPE ("Unknown type name " ^ quote c, [], []);
fun certify_const sg c =
if is_some (const_type sg c) then c else raise TYPE ("Undeclared constant " ^ quote c, [], []);
(* certify_term *)
(*check for duplicate occurrences of TFree/TVar with distinct sorts*)
fun nodup_tvars (env, Type (_, Ts)) = nodup_tvars_list (env, Ts)
| nodup_tvars (env as (tfrees, tvars), T as TFree (v as (a, S))) =
(case assoc_string (tfrees, a) of
Some S' =>
if S = S' then env
else raise TYPE ("Type variable " ^ quote a ^
" has two distinct sorts", [TFree (a, S'), T], [])
| None => (v :: tfrees, tvars))
| nodup_tvars (env as (tfrees, tvars), T as TVar (v as (a, S))) =
(case assoc_string_int (tvars, a) of
Some S' =>
if S = S' then env
else raise TYPE ("Type variable " ^ quote (Syntax.string_of_vname a) ^
" has two distinct sorts", [TVar (a, S'), T], [])
| None => (tfrees, v :: tvars))
(*equivalent to foldl nodup_tvars_list, but 3X faster under Poly/ML*)
and nodup_tvars_list (env, []) = env
| nodup_tvars_list (env, T :: Ts) = nodup_tvars_list (nodup_tvars (env, T), Ts);
(*check for duplicate occurrences of Free/Var with distinct types*)
fun nodup_vars tm =
let
fun nodups (envs as (env as (frees, vars), envT)) tm =
(case tm of
Const (c, T) => (env, nodup_tvars (envT, T))
| Free (v as (a, T)) =>
(case assoc_string (frees, a) of
Some T' =>
if T = T' then (env, nodup_tvars (envT, T))
else raise TYPE ("Variable " ^ quote a ^
" has two distinct types", [T', T], [])
| None => ((v :: frees, vars), nodup_tvars (envT, T)))
| Var (v as (ixn, T)) =>
(case assoc_string_int (vars, ixn) of
Some T' =>
if T = T' then (env, nodup_tvars (envT, T))
else raise TYPE ("Variable " ^ quote (Syntax.string_of_vname ixn) ^
" has two distinct types", [T', T], [])
| None => ((frees, v :: vars), nodup_tvars (envT, T)))
| Bound _ => envs
| Abs (_, T, t) => nodups (env, nodup_tvars (envT, T)) t
| s $ t => nodups (nodups envs s) t)
in nodups (([], []), ([], [])) tm; tm end;
(*compute and check type of the term*)
fun type_check sg tm =
let
val prt = setmp Syntax.show_brackets true (pretty_term sg);
val prT = pretty_typ sg;
fun err_appl why bs t T u U =
let
val xs = map Free bs; (*we do not rename here*)
val t' = subst_bounds (xs, t);
val u' = subst_bounds (xs, u);
val text = cat_lines (TypeInfer.appl_error prt prT why t' T u' U);
in raise TYPE (text, [T, U], [t', u']) end;
fun typ_of (_, Const (_, T)) = T
| typ_of (_, Free (_, T)) = T
| typ_of (_, Var (_, T)) = T
| typ_of (bs, Bound i) = snd (nth_elem (i, bs) handle LIST _ =>
raise TYPE ("Loose bound variable: B." ^ string_of_int i, [], [Bound i]))
| typ_of (bs, Abs (x, T, body)) = T --> typ_of ((x, T) :: bs, body)
| typ_of (bs, t $ u) =
let val T = typ_of (bs, t) and U = typ_of (bs, u) in
(case T of
Type ("fun", [T1, T2]) =>
if T1 = U then T2 else err_appl "Incompatible operand type." bs t T u U
| _ => err_appl "Operator not of function type." bs t T u U)
end;
in typ_of ([], tm) end;
fun certify_term sg tm =
let
val _ = check_stale sg;
val tsig = tsig_of sg;
fun show_const a T = quote a ^ " :: " ^ quote (string_of_typ sg T);
fun atom_err (errs, Const (a, T)) =
(case const_type sg a of
None => ("Undeclared constant " ^ show_const a T) :: errs
| Some U =>
if typ_instance sg (T, U) then errs
else ("Illegal type for constant " ^ show_const a T) :: errs)
| atom_err (errs, Var ((x, i), _)) =
if i < 0 then ("Negative index for Var " ^ quote x) :: errs else errs
| atom_err (errs, _) = errs;
val norm_tm =
(case it_term_types (Type.typ_errors tsig) (tm, []) of
[] => Type.norm_term tsig tm
| errs => raise TYPE (cat_lines errs, [], [tm]));
val _ = nodup_vars norm_tm;
in
(case foldl_aterms atom_err ([], norm_tm) of
[] => (norm_tm, type_check sg norm_tm, maxidx_of_term norm_tm)
| errs => raise TYPE (cat_lines errs, [], [norm_tm]))
end;
(** infer_types **) (*exception ERROR*)
(*
def_type: partial map from indexnames to types (constrains Frees, Vars)
def_sort: partial map from indexnames to sorts (constrains TFrees, TVars)
used: list of already used type variables
freeze: if true then generated parameters are turned into TFrees, else TVars
termss: lists of alternative parses (only one combination should be type-correct)
typs: expected types
*)
fun infer_types_simult sg def_type def_sort used freeze args =
let
val tsig = tsig_of sg;
val prt = setmp Syntax.show_brackets true (pretty_term sg);
val prT = pretty_typ sg;
val termss = foldr multiply (map fst args, [[]]);
val typs =
map (fn (_, T) => certify_typ sg T handle TYPE (msg, _, _) => error msg) args;
fun infer ts = OK
(Type.infer_types prt prT tsig (const_type sg) def_type def_sort
(intern_const sg) (intern_tycons sg) (intern_sort sg) used freeze typs ts)
handle TYPE (msg, _, _) => Error msg;
val err_results = map infer termss;
val errs = mapfilter get_error err_results;
val results = mapfilter get_ok err_results;
val ambiguity = length termss; (* FIXME !? *)
(* FIXME to syntax.ML!? *)
fun ambig_msg () =
if ambiguity > 1 andalso ambiguity <= ! Syntax.ambiguity_level
then
error_msg "Got more than one parse tree.\n\
\Retry with smaller Syntax.ambiguity_level for more information."
else ();
in
if null results then (ambig_msg (); error (cat_lines errs))
else if length results = 1 then
(if ambiguity > ! Syntax.ambiguity_level then
warning "Fortunately, only one parse tree is type correct.\n\
\You may still want to disambiguate your grammar or your input."
else (); hd results)
else (ambig_msg (); error ("More than one term is type correct:\n" ^
(cat_lines (map (Pretty.string_of o prt) (flat (map fst results))))))
end;
fun infer_types sg def_type def_sort used freeze tsT =
apfst hd (infer_types_simult sg def_type def_sort used freeze [tsT]);
(** read_def_terms **)
(*read terms, infer types*)
fun read_def_terms' syn (sign, types, sorts) used freeze sTs =
let
fun read (s, T) =
let val T' = certify_typ sign T handle TYPE (msg, _, _) => error msg
in (Syntax.read syn T' s, T') end;
val tsTs = map read sTs;
in infer_types_simult sign types sorts used freeze tsTs end;
fun read_def_terms (sign, types, sorts) = read_def_terms' (syn_of sign) (sign, types, sorts);
fun simple_read_term sign T s =
(read_def_terms (sign, K None, K None) [] true [(s, T)]
handle ERROR => error ("The error(s) above occurred for " ^ s)) |> #1 |> hd;
(** extend signature **) (*exception ERROR*)
(** signature extension functions **) (*exception ERROR*)
fun decls_of path name_of mfixs =
map (fn (x, y, mx) => (full path (name_of x mx), y)) mfixs;
fun no_read _ _ _ decl = decl;
(* add default sort *)
fun ext_defS prep_sort (syn, tsig, ctab, (path, spaces), data) S =
(syn, Type.ext_tsig_defsort tsig (prep_sort syn tsig spaces S), ctab, (path, spaces), data);
fun ext_defsort arg = ext_defS rd_sort arg;
fun ext_defsort_i arg = ext_defS cert_sort arg;
(* add type constructors *)
fun ext_types (syn, tsig, ctab, (path, spaces), data) types =
let val decls = decls_of path Syntax.type_name types in
(Syntax.extend_type_gram types syn,
Type.ext_tsig_types tsig decls, ctab,
(path, add_names spaces typeK (map fst decls)), data)
end;
fun ext_nonterminals sg nonterms =
ext_types sg (map (fn n => (n, 0, Syntax.NoSyn)) nonterms);
(* add type abbreviations *)
fun read_abbr syn tsig spaces (t, vs, rhs_src) =
(t, vs, rd_raw_typ syn tsig spaces (K None) rhs_src)
handle ERROR => error ("in type abbreviation " ^ t);
fun ext_abbrs rd_abbr (syn, tsig, ctab, (path, spaces), data) abbrs =
let
fun mfix_of (t, vs, _, mx) = (t, length vs, mx);
val syn' = Syntax.extend_type_gram (map mfix_of abbrs) syn;
val abbrs' =
map (fn (t, vs, rhs, mx) =>
(full path (Syntax.type_name t mx), vs, rhs)) abbrs;
val spaces' = add_names spaces typeK (map #1 abbrs');
val decls = map (rd_abbr syn' tsig spaces') abbrs';
in
(syn', Type.ext_tsig_abbrs tsig decls, ctab, (path, spaces'), data)
end;
fun ext_tyabbrs abbrs = ext_abbrs read_abbr abbrs;
fun ext_tyabbrs_i abbrs = ext_abbrs no_read abbrs;
(* add type arities *)
fun ext_ars int prep_sort (syn, tsig, ctab, (path, spaces), data) arities =
let
val prepS = prep_sort syn tsig spaces;
fun prep_arity (c, Ss, S) =
(if int then intrn spaces typeK c else c, map prepS Ss, prepS S);
val tsig' = Type.ext_tsig_arities tsig (map prep_arity arities);
val log_types = Type.logical_types tsig';
in
(Syntax.extend_log_types log_types syn, tsig', ctab, (path, spaces), data)
end;
fun ext_arities arg = ext_ars true rd_sort arg;
fun ext_arities_i arg = ext_ars false cert_sort arg;
(* add term constants and syntax *)
fun const_name path c mx =
full path (Syntax.const_name c mx);
fun err_in_const c =
error ("in declaration of constant " ^ quote c);
fun err_dup_consts cs =
error ("Duplicate declaration of constant(s) " ^ commas_quote cs);
fun read_const syn tsig (path, spaces) (c, ty_src, mx) =
(c, rd_raw_typ syn tsig spaces (K None) ty_src, mx)
handle ERROR => err_in_const (const_name path c mx);
fun ext_cnsts rd_const syn_only prmode (syn, tsig, ctab, (path, spaces), data) raw_consts =
let
fun prep_const (c, ty, mx) =
(c, compress_type (Type.varifyT (Type.cert_typ tsig (Type.no_tvars ty))), mx)
handle TYPE (msg, _, _) =>
(error_msg msg; err_in_const (const_name path c mx));
val consts = map (prep_const o rd_const syn tsig (path, spaces)) raw_consts;
val decls =
if syn_only then []
else decls_of path Syntax.const_name consts;
in
(Syntax.extend_const_gram prmode consts syn, tsig,
Symtab.extend (ctab, decls)
handle Symtab.DUPS cs => err_dup_consts cs,
(path, add_names spaces constK (map fst decls)), data)
end;
fun ext_consts_i sg = ext_cnsts no_read false ("", true) sg;
fun ext_consts sg = ext_cnsts read_const false ("", true) sg;
fun ext_syntax_i sg = ext_cnsts no_read true ("", true) sg;
fun ext_syntax sg = ext_cnsts read_const true ("", true) sg;
fun ext_modesyntax_i sg (prmode, consts) = ext_cnsts no_read true prmode sg consts;
fun ext_modesyntax sg (prmode, consts) = ext_cnsts read_const true prmode sg consts;
(* add type classes *)
fun const_of_class c = c ^ "_class";
fun class_of_const c_class =
let
val c = implode (take (size c_class - size "_class", explode c_class));
in
if const_of_class c = c_class then c
else raise TERM ("class_of_const: bad name " ^ quote c_class, [])
end;
fun ext_classes int (syn, tsig, ctab, (path, spaces), data) classes =
let
val names = map fst classes;
val consts =
map (fn c => (const_of_class c, a_itselfT --> propT, NoSyn)) names;
val full_names = map (full path) names;
val spaces' = add_names spaces classK full_names;
val intrn = if int then map (intrn_class spaces') else I;
val classes' =
ListPair.map (fn (c, (_, cs)) => (c, intrn cs)) (full_names, classes);
in
ext_consts_i
(Syntax.extend_consts names syn,
Type.ext_tsig_classes tsig classes', ctab, (path, spaces'), data)
consts
end;
(* add to classrel *)
fun ext_classrel int (syn, tsig, ctab, (path, spaces), data) pairs =
let val intrn = if int then map (pairself (intrn_class spaces)) else I in
(syn, Type.ext_tsig_classrel tsig (intrn pairs), ctab, (path, spaces), data)
end;
(* add translation rules *)
fun ext_trrules (syn, tsig, ctab, (path, spaces), data) args =
(syn |> Syntax.extend_trrules
(map (Syntax.map_trrule (fn (root, str) => (intrn spaces typeK root, str))) args),
tsig, ctab, (path, spaces), data);
(* add to syntax *)
fun ext_syn extfun (syn, tsig, ctab, names, data) args =
(extfun args syn, tsig, ctab, names, data);
(* add to path *)
fun ext_path (syn, tsig, ctab, (path, spaces), data) elems =
let
val path' =
if elems = "//" then None
else if elems = "/" then Some []
else if elems = ".." andalso is_some path andalso path <> Some [] then
Some (fst (split_last (the path)))
else Some (if_none path [] @ NameSpace.unpack elems);
in
(syn, tsig, ctab, (path', spaces), data)
end;
(* change name space *)
fun ext_add_space (syn, tsig, ctab, (path, spaces), data) (kind, names) =
(syn, tsig, ctab, (path, add_names spaces kind names), data);
fun ext_hide_space (syn, tsig, ctab, (path, spaces), data) (b, (kind, xnames)) =
(syn, tsig, ctab, (path, hide_names b spaces kind (map (intrn spaces kind) xnames)), data);
fun ext_hide_space_i (syn, tsig, ctab, (path, spaces), data) (b, (kind, names)) =
(syn, tsig, ctab, (path, hide_names b spaces kind names), data);
(* signature data *)
fun ext_init_data sg (syn, tsig, ctab, names, data) (kind, (e, cp, ext, mrg, prt)) =
(syn, tsig, ctab, names, init_data_sg sg data kind e cp ext mrg prt);
fun ext_put_data sg (syn, tsig, ctab, names, data) (kind, f, x) =
(syn, tsig, ctab, names, put_data_sg sg data kind f x);
fun copy_data (k, (e, mths as (cp, _, _, _))) =
(k, (cp e handle exn => err_method "copy" (Object.name_of_kind k) exn, mths));
fun copy (sg as Sg ({id = _, stamps}, {self, tsig, const_tab, syn, path, spaces, data})) =
let
val _ = check_stale sg;
val self' = SgRef (Some (ref sg));
val Data tab = data;
val data' = Data (Symtab.map copy_data tab);
in create_sign self' stamps "#" (syn, tsig, const_tab, (path, spaces), data') end;
(* the external interfaces *)
val add_classes = extend_sign true (ext_classes true) "#";
val add_classes_i = extend_sign true (ext_classes false) "#";
val add_classrel = extend_sign true (ext_classrel true) "#";
val add_classrel_i = extend_sign true (ext_classrel false) "#";
val add_defsort = extend_sign true ext_defsort "#";
val add_defsort_i = extend_sign true ext_defsort_i "#";
val add_types = extend_sign true ext_types "#";
val add_nonterminals = extend_sign true ext_nonterminals "#";
val add_tyabbrs = extend_sign true ext_tyabbrs "#";
val add_tyabbrs_i = extend_sign true ext_tyabbrs_i "#";
val add_arities = extend_sign true ext_arities "#";
val add_arities_i = extend_sign true ext_arities_i "#";
val add_consts = extend_sign true ext_consts "#";
val add_consts_i = extend_sign true ext_consts_i "#";
val add_syntax = extend_sign true ext_syntax "#";
val add_syntax_i = extend_sign true ext_syntax_i "#";
val add_modesyntax = extend_sign true ext_modesyntax "#";
val add_modesyntax_i = extend_sign true ext_modesyntax_i "#";
val add_trfuns = extend_sign true (ext_syn Syntax.extend_trfuns) "#";
val add_trfunsT = extend_sign true (ext_syn Syntax.extend_trfunsT) "#";
val add_tokentrfuns = extend_sign true (ext_syn Syntax.extend_tokentrfuns) "#";
val add_trrules = extend_sign true ext_trrules "#";
val add_trrules_i = extend_sign true (ext_syn Syntax.extend_trrules_i) "#";
val add_path = extend_sign true ext_path "#";
val add_space = extend_sign true ext_add_space "#";
val hide_space = curry (extend_sign true ext_hide_space "#");
val hide_space_i = curry (extend_sign true ext_hide_space_i "#");
fun init_data arg sg = extend_sign true (ext_init_data sg) "#" arg sg;
fun put_data k f x sg = extend_sign true (ext_put_data sg) "#" (k, f, x) sg;
fun add_name name sg = extend_sign true K name () sg;
fun prep_ext sg = extend_sign false K "#" () sg;
(** merge signatures **) (*exception TERM*)
(* merge_stamps *)
fun merge_stamps stamps1 stamps2 =
let val stamps = merge_lists' stamps1 stamps2 in
(case duplicates (map ! stamps) of
[] => stamps
| dups => raise TERM ("Attempt to merge different versions of theories "
^ commas_quote dups, []))
end;
(* implicit merge -- trivial only *)
fun merge_refs (sgr1 as SgRef (Some (ref (sg1 as Sg ({stamps = s1, ...}, _)))),
sgr2 as SgRef (Some (ref (sg2 as Sg ({stamps = s2, ...}, _))))) =
if fast_subsig (sg2, sg1) then sgr1
else if fast_subsig (sg1, sg2) then sgr2
else if subsig (sg2, sg1) then sgr1
else if subsig (sg1, sg2) then sgr2
else (merge_stamps s1 s2; (*check for different versions*)
raise TERM ("Attempt to do non-trivial merge of signatures", []))
| merge_refs _ = sys_error "Sign.merge_refs";
val merge = deref o merge_refs o pairself self_ref;
(* proper merge *) (*exception TERM/ERROR*)
val PureN = "Pure";
val CPureN = "CPure";
fun nontriv_merge (sg1, sg2) =
if subsig (sg2, sg1) then sg1
else if subsig (sg1, sg2) then sg2
else if is_draft sg1 orelse is_draft sg2 then
raise TERM ("Attempt to merge draft signatures", [])
else if exists_stamp PureN sg1 andalso exists_stamp CPureN sg2 orelse
exists_stamp CPureN sg1 andalso exists_stamp PureN sg2 then
raise TERM ("Cannot merge Pure and CPure signatures", [])
else
(*neither is union already; must form union*)
let
val Sg ({id = _, stamps = stamps1}, {self = _, tsig = tsig1, const_tab = const_tab1,
syn = syn1, path = _, spaces = spaces1, data = data1}) = sg1;
val Sg ({id = _, stamps = stamps2}, {self = _, tsig = tsig2, const_tab = const_tab2,
syn = syn2, path = _, spaces = spaces2, data = data2}) = sg2;
val id = ref "";
val self_ref = ref sg1; (*dummy value*)
val self = SgRef (Some self_ref);
val stamps = merge_stamps stamps1 stamps2;
val tsig = Type.merge_tsigs (tsig1, tsig2);
val const_tab = Symtab.merge (op =) (const_tab1, const_tab2)
handle Symtab.DUPS cs =>
raise TERM ("Incompatible types for constant(s) " ^ commas_quote cs, []);
val syn = Syntax.merge_syntaxes syn1 syn2;
val path = Some [];
val kinds = distinct (map fst (spaces1 @ spaces2));
val spaces =
kinds ~~
ListPair.map NameSpace.merge
(map (space_of spaces1) kinds, map (space_of spaces2) kinds);
val data = merge_data (data1, data2);
val sign = make_sign (id, self, tsig, const_tab, syn, path, spaces, data, stamps);
in
self_ref := sign; sign
end;
(** partial Pure signature **)
val dummy_sg = make_sign (ref "", SgRef None, Type.tsig0,
Symtab.empty, Syntax.pure_syn, Some [], [], empty_data, []);
val pre_pure =
create_sign (SgRef (Some (ref dummy_sg))) [] "#"
(Syntax.pure_syn, Type.tsig0, Symtab.empty, (Some [], []), empty_data);
end;