(* Title: HOL/Tools/datatype_package.ML
ID: $Id$
Author: Stefan Berghofer, TU Muenchen
Datatype package for Isabelle/HOL.
*)
signature BASIC_DATATYPE_PACKAGE =
sig
val induct_tac : string -> int -> tactic
val induct_thm_tac : thm -> string -> int -> tactic
val case_tac : string -> int -> tactic
val distinct_simproc : simproc
end;
signature DATATYPE_PACKAGE =
sig
include BASIC_DATATYPE_PACKAGE
val quiet_mode : bool ref
val add_datatype : bool -> string list -> (string list * bstring * mixfix *
(bstring * string list * mixfix) list) list -> theory -> theory *
{distinct : thm list list,
inject : thm list list,
exhaustion : thm list,
rec_thms : thm list,
case_thms : thm list list,
split_thms : (thm * thm) list,
induction : thm,
size : thm list,
simps : thm list}
val add_datatype_i : bool -> bool -> string list -> (string list * bstring * mixfix *
(bstring * typ list * mixfix) list) list -> theory -> theory *
{distinct : thm list list,
inject : thm list list,
exhaustion : thm list,
rec_thms : thm list,
case_thms : thm list list,
split_thms : (thm * thm) list,
induction : thm,
size : thm list,
simps : thm list}
val rep_datatype_i : string list option -> (thm list * theory attribute list) list list ->
(thm list * theory attribute list) list list -> (thm list * theory attribute list) ->
theory -> theory *
{distinct : thm list list,
inject : thm list list,
exhaustion : thm list,
rec_thms : thm list,
case_thms : thm list list,
split_thms : (thm * thm) list,
induction : thm,
size : thm list,
simps : thm list}
val rep_datatype : string list option -> (thmref * Attrib.src list) list list ->
(thmref * Attrib.src list) list list -> thmref * Attrib.src list -> theory -> theory *
{distinct : thm list list,
inject : thm list list,
exhaustion : thm list,
rec_thms : thm list,
case_thms : thm list list,
split_thms : (thm * thm) list,
induction : thm,
size : thm list,
simps : thm list}
val get_datatypes : theory -> DatatypeAux.datatype_info Symtab.table
val print_datatypes : theory -> unit
val datatype_info : theory -> string -> DatatypeAux.datatype_info option
val datatype_info_err : theory -> string -> DatatypeAux.datatype_info
val constrs_of : theory -> string -> term list option
val case_const_of : theory -> string -> term option
val weak_case_congs_of : theory -> thm list
val setup: (theory -> theory) list
end;
structure DatatypePackage : DATATYPE_PACKAGE =
struct
open DatatypeAux;
val quiet_mode = quiet_mode;
(* data kind 'HOL/datatypes' *)
structure DatatypesData = TheoryDataFun
(struct
val name = "HOL/datatypes";
type T = datatype_info Symtab.table;
val empty = Symtab.empty;
val copy = I;
val extend = I;
fun merge _ tabs : T = Symtab.merge (K true) tabs;
fun print sg tab =
Pretty.writeln (Pretty.strs ("datatypes:" ::
map #1 (NameSpace.extern_table (Sign.type_space sg, tab))));
end);
val get_datatypes = DatatypesData.get;
val put_datatypes = DatatypesData.put;
val print_datatypes = DatatypesData.print;
(** theory information about datatypes **)
val datatype_info = Symtab.lookup o get_datatypes;
fun datatype_info_err thy name = (case datatype_info thy name of
SOME info => info
| NONE => error ("Unknown datatype " ^ quote name));
fun constrs_of thy tname = (case datatype_info thy tname of
SOME {index, descr, ...} =>
let val (_, _, constrs) = valOf (AList.lookup (op =) descr index)
in SOME (map (fn (cname, _) => Const (cname, Sign.the_const_type thy cname)) constrs)
end
| _ => NONE);
fun case_const_of thy tname = (case datatype_info thy tname of
SOME {case_name, ...} => SOME (Const (case_name, Sign.the_const_type thy case_name))
| _ => NONE);
val weak_case_congs_of = map (#weak_case_cong o #2) o Symtab.dest o get_datatypes;
fun find_tname var Bi =
let val frees = map dest_Free (term_frees Bi)
val params = rename_wrt_term Bi (Logic.strip_params Bi);
in case AList.lookup (op =) (frees @ params) var of
NONE => error ("No such variable in subgoal: " ^ quote var)
| SOME(Type (tn, _)) => tn
| _ => error ("Cannot determine type of " ^ quote var)
end;
fun infer_tname state i aterm =
let
val sign = Thm.sign_of_thm state;
val (_, _, Bi, _) = Thm.dest_state (state, i)
val params = Logic.strip_params Bi; (*params of subgoal i*)
val params = rev (rename_wrt_term Bi params); (*as they are printed*)
val (types, sorts) = types_sorts state;
fun types' (a, ~1) = (case AList.lookup (op =) params a of NONE => types(a, ~1) | sm => sm)
| types' ixn = types ixn;
val (ct, _) = read_def_cterm (sign, types', sorts) [] false (aterm, TypeInfer.logicT);
in case #T (rep_cterm ct) of
Type (tn, _) => tn
| _ => error ("Cannot determine type of " ^ quote aterm)
end;
(*Warn if the (induction) variable occurs Free among the premises, which
usually signals a mistake. But calls the tactic either way!*)
fun occs_in_prems tacf vars =
SUBGOAL (fn (Bi, i) =>
(if exists (fn Free (a, _) => a mem vars)
(foldr add_term_frees [] (#2 (strip_context Bi)))
then warning "Induction variable occurs also among premises!"
else ();
tacf i));
(* generic induction tactic for datatypes *)
local
fun prep_var (Var (ixn, _), SOME x) = SOME (ixn, x)
| prep_var _ = NONE;
fun prep_inst (concl, xs) = (*exception UnequalLengths *)
let val vs = InductAttrib.vars_of concl
in List.mapPartial prep_var (Library.drop (length vs - length xs, vs) ~~ xs) end;
in
fun gen_induct_tac inst_tac (varss, opt_rule) i state =
let
val (_, _, Bi, _) = Thm.dest_state (state, i);
val {sign, ...} = Thm.rep_thm state;
val (rule, rule_name) =
(case opt_rule of
SOME r => (r, "Induction rule")
| NONE =>
let val tn = find_tname (hd (List.mapPartial I (List.concat varss))) Bi
in (#induction (datatype_info_err sign tn), "Induction rule for type " ^ tn) end);
val concls = HOLogic.dest_concls (Thm.concl_of rule);
val insts = List.concat (map prep_inst (concls ~~ varss)) handle UnequalLengths =>
error (rule_name ^ " has different numbers of variables");
in occs_in_prems (inst_tac insts rule) (map #2 insts) i state end;
fun induct_tac s =
gen_induct_tac Tactic.res_inst_tac'
(map (Library.single o SOME) (Syntax.read_idents s), NONE);
fun induct_thm_tac th s =
gen_induct_tac Tactic.res_inst_tac'
([map SOME (Syntax.read_idents s)], SOME th);
end;
(* generic case tactic for datatypes *)
fun case_inst_tac inst_tac t rule i state =
let
val _ $ Var (ixn, _) $ _ = HOLogic.dest_Trueprop
(hd (Logic.strip_assums_hyp (hd (Thm.prems_of rule))));
in inst_tac [(ixn, t)] rule i state end;
fun gen_case_tac inst_tac (t, SOME rule) i state =
case_inst_tac inst_tac t rule i state
| gen_case_tac inst_tac (t, NONE) i state =
let val tn = infer_tname state i t in
if tn = HOLogic.boolN then inst_tac [(("P", 0), t)] case_split_thm i state
else case_inst_tac inst_tac t
(#exhaustion (datatype_info_err (Thm.sign_of_thm state) tn))
i state
end handle THM _ => Seq.empty;
fun case_tac t = gen_case_tac Tactic.res_inst_tac' (t, NONE);
(** Isar tactic emulations **)
local
val rule_spec = Scan.lift (Args.$$$ "rule" -- Args.$$$ ":");
val opt_rule = Scan.option (rule_spec |-- Attrib.local_thm);
val varss =
Args.and_list (Scan.repeat (Scan.unless rule_spec (Scan.lift (Args.maybe Args.name))));
val inst_tac = Method.bires_inst_tac false;
fun induct_meth ctxt (varss, opt_rule) =
gen_induct_tac (inst_tac ctxt) (varss, opt_rule);
fun case_meth ctxt (varss, opt_rule) =
gen_case_tac (inst_tac ctxt) (varss, opt_rule);
in
val tactic_emulations =
[("induct_tac", Method.goal_args_ctxt' (varss -- opt_rule) induct_meth,
"induct_tac emulation (dynamic instantiation)"),
("case_tac", Method.goal_args_ctxt' (Scan.lift Args.name -- opt_rule) case_meth,
"case_tac emulation (dynamic instantiation)")];
end;
(** induct method setup **)
(* case names *)
local
fun dt_recs (DtTFree _) = []
| dt_recs (DtType (_, dts)) = List.concat (map dt_recs dts)
| dt_recs (DtRec i) = [i];
fun dt_cases (descr: descr) (_, args, constrs) =
let
fun the_bname i = Sign.base_name (#1 (valOf (AList.lookup (op =) descr i)));
val bnames = map the_bname (distinct (List.concat (map dt_recs args)));
in map (fn (c, _) => space_implode "_" (Sign.base_name c :: bnames)) constrs end;
fun induct_cases descr =
DatatypeProp.indexify_names (List.concat (map (dt_cases descr) (map #2 descr)));
fun exhaust_cases descr i = dt_cases descr (valOf (AList.lookup (op =) descr i));
in
fun mk_case_names_induct descr = RuleCases.case_names (induct_cases descr);
fun mk_case_names_exhausts descr new =
map (RuleCases.case_names o exhaust_cases descr o #1)
(List.filter (fn ((_, (name, _, _))) => name mem_string new) descr);
end;
fun name_notE th =
Thm.name_thm (Thm.name_of_thm th ^ "_E", th RS notE);
fun add_rules simps case_thms size_thms rec_thms inject distinct
weak_case_congs cong_att =
(#1 o PureThy.add_thmss [(("simps", simps), []),
(("", List.concat case_thms @ size_thms @
List.concat distinct @ rec_thms), [Simplifier.simp_add_global]),
(("", size_thms @ rec_thms), [RecfunCodegen.add NONE]),
(("", List.concat inject), [iff_add_global]),
(("", map name_notE (List.concat distinct)), [Classical.safe_elim_global]),
(("", weak_case_congs), [cong_att])]);
(* add_cases_induct *)
fun add_cases_induct infos induction =
let
val n = length (HOLogic.dest_concls (Thm.concl_of induction));
fun proj i thm =
if n = 1 then thm
else (if i + 1 < n then (fn th => th RS conjunct1) else I)
(Library.funpow i (fn th => th RS conjunct2) thm)
|> Drule.zero_var_indexes
|> RuleCases.save thm;
fun named_rules (name, {index, exhaustion, ...}: datatype_info) =
[(("", proj index induction), [InductAttrib.induct_type_global name]),
(("", exhaustion), [InductAttrib.cases_type_global name])];
fun unnamed_rule i =
(("", proj i induction), [InductAttrib.induct_type_global ""]);
val rules = List.concat (map named_rules infos) @ map unnamed_rule (length infos upto n - 1);
in #1 o PureThy.add_thms rules end;
(**** simplification procedure for showing distinctness of constructors ****)
fun stripT (i, Type ("fun", [_, T])) = stripT (i + 1, T)
| stripT p = p;
fun stripC (i, f $ x) = stripC (i + 1, f)
| stripC p = p;
val distinctN = "constr_distinct";
exception ConstrDistinct of term;
fun distinct_proc sg ss (t as Const ("op =", _) $ t1 $ t2) =
(case (stripC (0, t1), stripC (0, t2)) of
((i, Const (cname1, T1)), (j, Const (cname2, T2))) =>
(case (stripT (0, T1), stripT (0, T2)) of
((i', Type (tname1, _)), (j', Type (tname2, _))) =>
if tname1 = tname2 andalso not (cname1 = cname2) andalso i = i' andalso j = j' then
(case (constrs_of sg tname1) of
SOME constrs => let val cnames = map (fst o dest_Const) constrs
in if cname1 mem cnames andalso cname2 mem cnames then
let val eq_t = Logic.mk_equals (t, Const ("False", HOLogic.boolT));
val eq_ct = cterm_of sg eq_t;
val Datatype_thy = theory "Datatype";
val [In0_inject, In1_inject, In0_not_In1, In1_not_In0] =
map (get_thm Datatype_thy o Name)
["In0_inject", "In1_inject", "In0_not_In1", "In1_not_In0"]
in (case (#distinct (datatype_info_err sg tname1)) of
QuickAndDirty => SOME (Thm.invoke_oracle
Datatype_thy distinctN (sg, ConstrDistinct eq_t))
| FewConstrs thms => SOME (Goal.prove sg [] [] eq_t (K
(EVERY [rtac eq_reflection 1, rtac iffI 1, rtac notE 1,
atac 2, resolve_tac thms 1, etac FalseE 1])))
| ManyConstrs (thm, simpset) => SOME (Goal.prove sg [] [] eq_t (K
(EVERY [rtac eq_reflection 1, rtac iffI 1, dtac thm 1,
full_simp_tac (Simplifier.inherit_context ss simpset) 1,
REPEAT (dresolve_tac [In0_inject, In1_inject] 1),
eresolve_tac [In0_not_In1 RS notE, In1_not_In0 RS notE] 1,
etac FalseE 1]))))
end
else NONE
end
| NONE => NONE)
else NONE
| _ => NONE)
| _ => NONE)
| distinct_proc sg _ _ = NONE;
val distinct_simproc =
Simplifier.simproc HOL.thy distinctN ["s = t"] distinct_proc;
val dist_ss = HOL_ss addsimprocs [distinct_simproc];
val simproc_setup =
[Theory.add_oracle (distinctN, fn (_, ConstrDistinct t) => t),
fn thy => ((change_simpset_of thy) (fn ss => ss addsimprocs [distinct_simproc]); thy)];
(**** translation rules for case ****)
fun case_tr sg [t, u] =
let
fun case_error s name ts = raise TERM ("Error in case expression" ^
getOpt (Option.map (curry op ^ " for datatype ") name, "") ^ ":\n" ^ s, ts);
fun dest_case1 (Const ("_case1", _) $ t $ u) = (case strip_comb t of
(Const (s, _), ts) => (Sign.intern_const sg s, ts)
| (Free (s, _), ts) => (Sign.intern_const sg s, ts)
| _ => case_error "Head is not a constructor" NONE [t, u], u)
| dest_case1 t = raise TERM ("dest_case1", [t]);
fun dest_case2 (Const ("_case2", _) $ t $ u) = t :: dest_case2 u
| dest_case2 t = [t];
val cases as ((cname, _), _) :: _ = map dest_case1 (dest_case2 u);
val tab = Symtab.dest (get_datatypes sg);
val (cases', default) = (case split_last cases of
(cases', (("dummy_pattern", []), t)) => (cases', SOME t)
| _ => (cases, NONE))
fun abstr (Free (x, T), body) = Term.absfree (x, T, body)
| abstr (Const ("_constrain", _) $ Free (x, T) $ tT, body) =
Syntax.const Syntax.constrainAbsC $ Term.absfree (x, T, body) $ tT
| abstr (Const ("Pair", _) $ x $ y, body) =
Syntax.const "split" $ abstr (x, abstr (y, body))
| abstr (t, _) = case_error "Illegal pattern" NONE [t];
in case find_first (fn (_, {descr, index, ...}) =>
exists (equal cname o fst) (#3 (snd (List.nth (descr, index))))) tab of
NONE => case_error ("Not a datatype constructor: " ^ cname) NONE [u]
| SOME (tname, {descr, case_name, index, ...}) =>
let
val _ = if exists (equal "dummy_pattern" o fst o fst) cases' then
case_error "Illegal occurrence of '_' dummy pattern" (SOME tname) [u] else ();
val (_, (_, dts, constrs)) = List.nth (descr, index);
val sorts = map (rpair [] o dest_DtTFree) dts;
fun find_case (cases, (s, dt)) =
(case find_first (equal s o fst o fst) cases' of
NONE => (case default of
NONE => case_error ("No clause for constructor " ^ s) (SOME tname) [u]
| SOME t => (cases, list_abs (map (rpair dummyT) (DatatypeProp.make_tnames
(map (typ_of_dtyp descr sorts) dt)), t)))
| SOME (c as ((_, vs), t)) =>
if length dt <> length vs then
case_error ("Wrong number of arguments for constructor " ^ s)
(SOME tname) vs
else (cases \ c, foldr abstr t vs))
val (cases'', fs) = foldl_map find_case (cases', constrs)
in case (cases'', length constrs = length cases', default) of
([], true, SOME _) =>
case_error "Extra '_' dummy pattern" (SOME tname) [u]
| (_ :: _, _, _) =>
let val extra = distinct (map (fst o fst) cases'')
in case extra \\ map fst constrs of
[] => case_error ("More than one clause for constructor(s) " ^
commas extra) (SOME tname) [u]
| extra' => case_error ("Illegal constructor(s): " ^ commas extra')
(SOME tname) [u]
end
| _ => list_comb (Syntax.const case_name, fs) $ t
end
end
| case_tr sg ts = raise TERM ("case_tr", ts);
fun case_tr' constrs sg ts =
if length ts <> length constrs + 1 then raise Match else
let
val (fs, x) = split_last ts;
fun strip_abs 0 t = ([], t)
| strip_abs i (Abs p) =
let val (x, u) = Syntax.atomic_abs_tr' p
in apfst (cons x) (strip_abs (i-1) u) end
| strip_abs i (Const ("split", _) $ t) = (case strip_abs (i+1) t of
(v :: v' :: vs, u) => (Syntax.const "Pair" $ v $ v' :: vs, u));
fun is_dependent i t =
let val k = length (strip_abs_vars t) - i
in k < 0 orelse exists (fn j => j >= k)
(loose_bnos (strip_abs_body t))
end;
val cases = map (fn ((cname, dts), t) =>
(Sign.extern_const sg cname,
strip_abs (length dts) t, is_dependent (length dts) t))
(constrs ~~ fs);
fun count_cases (cs, (_, _, true)) = cs
| count_cases (cs, (cname, (_, body), false)) = (case AList.lookup (op =) cs body of
NONE => (body, [cname]) :: cs
| SOME cnames => AList.update (op =) (body, cnames @ [cname]) cs);
val cases' = sort (int_ord o Library.swap o pairself (length o snd))
(Library.foldl count_cases ([], cases));
fun mk_case1 (cname, (vs, body), _) = Syntax.const "_case1" $
list_comb (Syntax.const cname, vs) $ body;
in
Syntax.const "_case_syntax" $ x $
foldr1 (fn (t, u) => Syntax.const "_case2" $ t $ u) (map mk_case1
(case cases' of
[] => cases
| (default, cnames) :: _ =>
if length cnames = 1 then cases
else if length cnames = length constrs then
[hd cases, ("dummy_pattern", ([], default), false)]
else
filter_out (fn (cname, _, _) => cname mem cnames) cases @
[("dummy_pattern", ([], default), false)]))
end;
fun make_case_tr' case_names descr = List.concat (map
(fn ((_, (_, _, constrs)), case_name) => map (rpair (case_tr' constrs))
(NameSpace.accesses' case_name)) (descr ~~ case_names));
val trfun_setup =
[Theory.add_advanced_trfuns ([], [("_case_syntax", case_tr)], [], [])];
(* prepare types *)
fun read_typ sign ((Ts, sorts), str) =
let
val T = Type.no_tvars (Sign.read_typ (sign, AList.lookup (op =)
(map (apfst (rpair ~1)) sorts)) str) handle TYPE (msg, _, _) => error msg
in (Ts @ [T], add_typ_tfrees (T, sorts)) end;
fun cert_typ sign ((Ts, sorts), raw_T) =
let
val T = Type.no_tvars (Sign.certify_typ sign raw_T) handle
TYPE (msg, _, _) => error msg;
val sorts' = add_typ_tfrees (T, sorts)
in (Ts @ [T],
case duplicates (map fst sorts') of
[] => sorts'
| dups => error ("Inconsistent sort constraints for " ^ commas dups))
end;
(**** make datatype info ****)
fun make_dt_info descr induct reccomb_names rec_thms
(((((((((i, (_, (tname, _, _))), case_name), case_thms),
exhaustion_thm), distinct_thm), inject), nchotomy), case_cong), weak_case_cong) =
(tname,
{index = i,
descr = descr,
rec_names = reccomb_names,
rec_rewrites = rec_thms,
case_name = case_name,
case_rewrites = case_thms,
induction = induct,
exhaustion = exhaustion_thm,
distinct = distinct_thm,
inject = inject,
nchotomy = nchotomy,
case_cong = case_cong,
weak_case_cong = weak_case_cong});
(********************* axiomatic introduction of datatypes ********************)
fun add_and_get_axioms_atts label tnames attss ts thy =
foldr (fn (((tname, atts), t), (thy', axs)) =>
let
val (thy'', [ax]) = thy' |>
Theory.add_path tname |>
PureThy.add_axioms_i [((label, t), atts)];
in (Theory.parent_path thy'', ax::axs)
end) (thy, []) (tnames ~~ attss ~~ ts);
fun add_and_get_axioms label tnames =
add_and_get_axioms_atts label tnames (replicate (length tnames) []);
fun add_and_get_axiomss label tnames tss thy =
foldr (fn ((tname, ts), (thy', axss)) =>
let
val (thy'', [axs]) = thy' |>
Theory.add_path tname |>
PureThy.add_axiomss_i [((label, ts), [])];
in (Theory.parent_path thy'', axs::axss)
end) (thy, []) (tnames ~~ tss);
fun add_datatype_axm flat_names new_type_names descr sorts types_syntax constr_syntax dt_info
case_names_induct case_names_exhausts thy =
let
val descr' = List.concat descr;
val recTs = get_rec_types descr' sorts;
val used = foldr add_typ_tfree_names [] recTs;
val newTs = Library.take (length (hd descr), recTs);
val no_size = exists (fn (_, (_, _, constrs)) => exists (fn (_, cargs) => exists
(fn dt => is_rec_type dt andalso not (null (fst (strip_dtyp dt))))
cargs) constrs) descr';
(**** declare new types and constants ****)
val tyvars = map (fn (_, (_, Ts, _)) => map dest_DtTFree Ts) (hd descr);
val constr_decls = map (fn (((_, (_, _, constrs)), T), constr_syntax') =>
map (fn ((_, cargs), (cname, mx)) =>
(cname, map (typ_of_dtyp descr' sorts) cargs ---> T, mx))
(constrs ~~ constr_syntax')) ((hd descr) ~~ newTs ~~ constr_syntax);
val (rec_result_Ts, reccomb_fn_Ts) = DatatypeProp.make_primrec_Ts descr sorts used;
val big_reccomb_name = (space_implode "_" new_type_names) ^ "_rec";
val reccomb_names = if length descr' = 1 then [big_reccomb_name] else
(map ((curry (op ^) (big_reccomb_name ^ "_")) o string_of_int)
(1 upto (length descr')));
val size_names = DatatypeProp.indexify_names
(map (fn T => name_of_typ T ^ "_size") (Library.drop (length (hd descr), recTs)));
val freeT = TFree (variant used "'t", HOLogic.typeS);
val case_fn_Ts = map (fn (i, (_, _, constrs)) =>
map (fn (_, cargs) =>
let val Ts = map (typ_of_dtyp descr' sorts) cargs
in Ts ---> freeT end) constrs) (hd descr);
val case_names = map (fn s => (s ^ "_case")) new_type_names;
val thy2' = thy |>
(** new types **)
curry (Library.foldr (fn (((name, mx), tvs), thy') => thy' |>
TypedefPackage.add_typedecls [(name, tvs, mx)]))
(types_syntax ~~ tyvars) |>
add_path flat_names (space_implode "_" new_type_names) |>
(** primrec combinators **)
Theory.add_consts_i (map (fn ((name, T), T') =>
(name, reccomb_fn_Ts @ [T] ---> T', NoSyn))
(reccomb_names ~~ recTs ~~ rec_result_Ts)) |>
(** case combinators **)
Theory.add_consts_i (map (fn ((name, T), Ts) =>
(name, Ts @ [T] ---> freeT, NoSyn))
(case_names ~~ newTs ~~ case_fn_Ts));
val reccomb_names' = map (Sign.intern_const thy2') reccomb_names;
val case_names' = map (Sign.intern_const thy2') case_names;
val thy2 = thy2' |>
(** size functions **)
(if no_size then I else Theory.add_consts_i (map (fn (s, T) =>
(Sign.base_name s, T --> HOLogic.natT, NoSyn))
(size_names ~~ Library.drop (length (hd descr), recTs)))) |>
(** constructors **)
parent_path flat_names |>
curry (Library.foldr (fn (((((_, (_, _, constrs)), T), tname),
constr_syntax'), thy') => thy' |>
add_path flat_names tname |>
Theory.add_consts_i (map (fn ((_, cargs), (cname, mx)) =>
(cname, map (typ_of_dtyp descr' sorts) cargs ---> T, mx))
(constrs ~~ constr_syntax')) |>
parent_path flat_names))
(hd descr ~~ newTs ~~ new_type_names ~~ constr_syntax);
(**** introduction of axioms ****)
val rec_axs = DatatypeProp.make_primrecs new_type_names descr sorts thy2;
val size_axs = if no_size then [] else DatatypeProp.make_size descr sorts thy2;
val (thy3, (([induct], [rec_thms]), inject)) =
thy2 |>
Theory.add_path (space_implode "_" new_type_names) |>
PureThy.add_axioms_i [(("induct", DatatypeProp.make_ind descr sorts),
[case_names_induct])] |>>>
PureThy.add_axiomss_i [(("recs", rec_axs), [])] |>>
(if no_size then I else #1 o PureThy.add_axiomss_i [(("size", size_axs), [])]) |>>
Theory.parent_path |>>>
add_and_get_axiomss "inject" new_type_names
(DatatypeProp.make_injs descr sorts);
val size_thms = if no_size then [] else get_thms thy3 (Name "size");
val (thy4, distinct) = add_and_get_axiomss "distinct" new_type_names
(DatatypeProp.make_distincts new_type_names descr sorts thy3) thy3;
val exhaust_ts = DatatypeProp.make_casedists descr sorts;
val (thy5, exhaustion) = add_and_get_axioms_atts "exhaust" new_type_names
(map Library.single case_names_exhausts) exhaust_ts thy4;
val (thy6, case_thms) = add_and_get_axiomss "cases" new_type_names
(DatatypeProp.make_cases new_type_names descr sorts thy5) thy5;
val (split_ts, split_asm_ts) = ListPair.unzip
(DatatypeProp.make_splits new_type_names descr sorts thy6);
val (thy7, split) = add_and_get_axioms "split" new_type_names split_ts thy6;
val (thy8, split_asm) = add_and_get_axioms "split_asm" new_type_names
split_asm_ts thy7;
val (thy9, nchotomys) = add_and_get_axioms "nchotomy" new_type_names
(DatatypeProp.make_nchotomys descr sorts) thy8;
val (thy10, case_congs) = add_and_get_axioms "case_cong" new_type_names
(DatatypeProp.make_case_congs new_type_names descr sorts thy9) thy9;
val (thy11, weak_case_congs) = add_and_get_axioms "weak_case_cong" new_type_names
(DatatypeProp.make_weak_case_congs new_type_names descr sorts thy10) thy10;
val dt_infos = map (make_dt_info descr' induct reccomb_names' rec_thms)
((0 upto length (hd descr) - 1) ~~ (hd descr) ~~ case_names' ~~ case_thms ~~
exhaustion ~~ replicate (length (hd descr)) QuickAndDirty ~~ inject ~~
nchotomys ~~ case_congs ~~ weak_case_congs);
val simps = List.concat (distinct @ inject @ case_thms) @ size_thms @ rec_thms;
val split_thms = split ~~ split_asm;
val thy12 = thy11 |>
Theory.add_advanced_trfuns ([], [], make_case_tr' case_names' (hd descr), []) |>
Theory.add_path (space_implode "_" new_type_names) |>
add_rules simps case_thms size_thms rec_thms inject distinct
weak_case_congs Simplifier.cong_add_global |>
put_datatypes (fold Symtab.update dt_infos dt_info) |>
add_cases_induct dt_infos induct |>
Theory.parent_path |>
(#1 o store_thmss "splits" new_type_names (map (fn (x, y) => [x, y]) split_thms)) |>
DatatypeRealizer.add_dt_realizers sorts (map snd dt_infos);
in
(thy12,
{distinct = distinct,
inject = inject,
exhaustion = exhaustion,
rec_thms = rec_thms,
case_thms = case_thms,
split_thms = split_thms,
induction = induct,
size = size_thms,
simps = simps})
end;
(******************* definitional introduction of datatypes *******************)
fun add_datatype_def flat_names new_type_names descr sorts types_syntax constr_syntax dt_info
case_names_induct case_names_exhausts thy =
let
val _ = message ("Proofs for datatype(s) " ^ commas_quote new_type_names);
val (thy2, inject, distinct, dist_rewrites, simproc_dists, induct) = thy |>
DatatypeRepProofs.representation_proofs flat_names dt_info new_type_names descr sorts
types_syntax constr_syntax case_names_induct;
val (thy3, casedist_thms) = DatatypeAbsProofs.prove_casedist_thms new_type_names descr
sorts induct case_names_exhausts thy2;
val (thy4, (reccomb_names, rec_thms)) = DatatypeAbsProofs.prove_primrec_thms
flat_names new_type_names descr sorts dt_info inject dist_rewrites dist_ss induct thy3;
val (thy6, (case_thms, case_names)) = DatatypeAbsProofs.prove_case_thms
flat_names new_type_names descr sorts reccomb_names rec_thms thy4;
val (thy7, split_thms) = DatatypeAbsProofs.prove_split_thms new_type_names
descr sorts inject dist_rewrites casedist_thms case_thms thy6;
val (thy8, nchotomys) = DatatypeAbsProofs.prove_nchotomys new_type_names
descr sorts casedist_thms thy7;
val (thy9, case_congs) = DatatypeAbsProofs.prove_case_congs new_type_names
descr sorts nchotomys case_thms thy8;
val (thy10, weak_case_congs) = DatatypeAbsProofs.prove_weak_case_congs new_type_names
descr sorts thy9;
val (thy11, size_thms) = DatatypeAbsProofs.prove_size_thms flat_names new_type_names
descr sorts reccomb_names rec_thms thy10;
val dt_infos = map (make_dt_info (List.concat descr) induct reccomb_names rec_thms)
((0 upto length (hd descr) - 1) ~~ (hd descr) ~~ case_names ~~ case_thms ~~
casedist_thms ~~ simproc_dists ~~ inject ~~ nchotomys ~~ case_congs ~~ weak_case_congs);
val simps = List.concat (distinct @ inject @ case_thms) @ size_thms @ rec_thms;
val thy12 = thy11 |>
Theory.add_advanced_trfuns ([], [], make_case_tr' case_names (hd descr), []) |>
Theory.add_path (space_implode "_" new_type_names) |>
add_rules simps case_thms size_thms rec_thms inject distinct
weak_case_congs (Simplifier.change_global_ss (op addcongs)) |>
put_datatypes (fold Symtab.update dt_infos dt_info) |>
add_cases_induct dt_infos induct |>
Theory.parent_path |>
(#1 o store_thmss "splits" new_type_names (map (fn (x, y) => [x, y]) split_thms)) |>
DatatypeRealizer.add_dt_realizers sorts (map snd dt_infos);
in
(thy12,
{distinct = distinct,
inject = inject,
exhaustion = casedist_thms,
rec_thms = rec_thms,
case_thms = case_thms,
split_thms = split_thms,
induction = induct,
size = size_thms,
simps = simps})
end;
(*********************** declare existing type as datatype *********************)
fun gen_rep_datatype apply_theorems alt_names raw_distinct raw_inject raw_induction thy0 =
let
val _ = Theory.requires thy0 "Inductive" "datatype representations";
fun app_thmss srcs thy = foldl_map (fn (thy, x) => apply_theorems x thy) (thy, srcs);
fun app_thm src thy = apsnd hd (apply_theorems [src] thy);
val (((thy1, induction), inject), distinct) = thy0
|> app_thmss raw_distinct
|> apfst (app_thmss raw_inject)
|> apfst (apfst (app_thm raw_induction));
val sign = Theory.sign_of thy1;
val induction' = freezeT induction;
fun err t = error ("Ill-formed predicate in induction rule: " ^
Sign.string_of_term sign t);
fun get_typ (t as _ $ Var (_, Type (tname, Ts))) =
((tname, map dest_TFree Ts) handle TERM _ => err t)
| get_typ t = err t;
val dtnames = map get_typ (HOLogic.dest_conj (HOLogic.dest_Trueprop (Thm.concl_of induction')));
val new_type_names = getOpt (alt_names, map fst dtnames);
fun get_constr t = (case Logic.strip_assums_concl t of
_ $ (_ $ t') => (case head_of t' of
Const (cname, cT) => (case strip_type cT of
(Ts, Type (tname, _)) => (tname, (cname, map (dtyp_of_typ dtnames) Ts))
| _ => err t)
| _ => err t)
| _ => err t);
fun make_dt_spec [] _ _ = []
| make_dt_spec ((tname, tvs)::dtnames') i constrs =
let val (constrs', constrs'') = take_prefix (equal tname o fst) constrs
in (i, (tname, map DtTFree tvs, map snd constrs'))::
(make_dt_spec dtnames' (i + 1) constrs'')
end;
val descr = make_dt_spec dtnames 0 (map get_constr (prems_of induction'));
val sorts = add_term_tfrees (concl_of induction', []);
val dt_info = get_datatypes thy1;
val case_names_induct = mk_case_names_induct descr;
val case_names_exhausts = mk_case_names_exhausts descr (map #1 dtnames);
val _ = message ("Proofs for datatype(s) " ^ commas_quote new_type_names);
val (thy2, casedist_thms) = thy1 |>
DatatypeAbsProofs.prove_casedist_thms new_type_names [descr] sorts induction
case_names_exhausts;
val (thy3, (reccomb_names, rec_thms)) = DatatypeAbsProofs.prove_primrec_thms
false new_type_names [descr] sorts dt_info inject distinct dist_ss induction thy2;
val (thy4, (case_thms, case_names)) = DatatypeAbsProofs.prove_case_thms false
new_type_names [descr] sorts reccomb_names rec_thms thy3;
val (thy5, split_thms) = DatatypeAbsProofs.prove_split_thms
new_type_names [descr] sorts inject distinct casedist_thms case_thms thy4;
val (thy6, nchotomys) = DatatypeAbsProofs.prove_nchotomys new_type_names
[descr] sorts casedist_thms thy5;
val (thy7, case_congs) = DatatypeAbsProofs.prove_case_congs new_type_names
[descr] sorts nchotomys case_thms thy6;
val (thy8, weak_case_congs) = DatatypeAbsProofs.prove_weak_case_congs new_type_names
[descr] sorts thy7;
val (thy9, size_thms) =
if Context.exists_name "NatArith" thy8 then
DatatypeAbsProofs.prove_size_thms false new_type_names
[descr] sorts reccomb_names rec_thms thy8
else (thy8, []);
val (thy10, [induction']) = thy9 |>
(#1 o store_thmss "inject" new_type_names inject) |>
(#1 o store_thmss "distinct" new_type_names distinct) |>
Theory.add_path (space_implode "_" new_type_names) |>
PureThy.add_thms [(("induct", induction), [case_names_induct])];
val dt_infos = map (make_dt_info descr induction' reccomb_names rec_thms)
((0 upto length descr - 1) ~~ descr ~~ case_names ~~ case_thms ~~ casedist_thms ~~
map FewConstrs distinct ~~ inject ~~ nchotomys ~~ case_congs ~~ weak_case_congs);
val simps = List.concat (distinct @ inject @ case_thms) @ size_thms @ rec_thms;
val thy11 = thy10 |>
Theory.add_advanced_trfuns ([], [], make_case_tr' case_names descr, []) |>
add_rules simps case_thms size_thms rec_thms inject distinct
weak_case_congs (Simplifier.change_global_ss (op addcongs)) |>
put_datatypes (fold Symtab.update dt_infos dt_info) |>
add_cases_induct dt_infos induction' |>
Theory.parent_path |>
(#1 o store_thmss "splits" new_type_names (map (fn (x, y) => [x, y]) split_thms)) |>
DatatypeRealizer.add_dt_realizers sorts (map snd dt_infos);
in
(thy11,
{distinct = distinct,
inject = inject,
exhaustion = casedist_thms,
rec_thms = rec_thms,
case_thms = case_thms,
split_thms = split_thms,
induction = induction',
size = size_thms,
simps = simps})
end;
val rep_datatype = gen_rep_datatype IsarThy.apply_theorems;
val rep_datatype_i = gen_rep_datatype IsarThy.apply_theorems_i;
(******************************** add datatype ********************************)
fun gen_add_datatype prep_typ err flat_names new_type_names dts thy =
let
val _ = Theory.requires thy "Datatype_Universe" "datatype definitions";
(* this theory is used just for parsing *)
val tmp_thy = thy |>
Theory.copy |>
Theory.add_types (map (fn (tvs, tname, mx, _) =>
(tname, length tvs, mx)) dts);
val sign = Theory.sign_of tmp_thy;
val (tyvars, _, _, _)::_ = dts;
val (new_dts, types_syntax) = ListPair.unzip (map (fn (tvs, tname, mx, _) =>
let val full_tname = Sign.full_name sign (Syntax.type_name tname mx)
in (case duplicates tvs of
[] => if eq_set (tyvars, tvs) then ((full_tname, tvs), (tname, mx))
else error ("Mutually recursive datatypes must have same type parameters")
| dups => error ("Duplicate parameter(s) for datatype " ^ full_tname ^
" : " ^ commas dups))
end) dts);
val _ = (case duplicates (map fst new_dts) @ duplicates new_type_names of
[] => () | dups => error ("Duplicate datatypes: " ^ commas dups));
fun prep_dt_spec ((dts', constr_syntax, sorts, i), (tvs, tname, mx, constrs)) =
let
fun prep_constr ((constrs, constr_syntax', sorts'), (cname, cargs, mx')) =
let
val (cargs', sorts'') = Library.foldl (prep_typ sign) (([], sorts'), cargs);
val _ = (case foldr add_typ_tfree_names [] cargs' \\ tvs of
[] => ()
| vs => error ("Extra type variables on rhs: " ^ commas vs))
in (constrs @ [((if flat_names then Sign.full_name sign else
Sign.full_name_path sign tname) (Syntax.const_name cname mx'),
map (dtyp_of_typ new_dts) cargs')],
constr_syntax' @ [(cname, mx')], sorts'')
end handle ERROR =>
error ("The error above occured in constructor " ^ cname ^
" of datatype " ^ tname);
val (constrs', constr_syntax', sorts') =
Library.foldl prep_constr (([], [], sorts), constrs)
in
case duplicates (map fst constrs') of
[] =>
(dts' @ [(i, (Sign.full_name sign (Syntax.type_name tname mx),
map DtTFree tvs, constrs'))],
constr_syntax @ [constr_syntax'], sorts', i + 1)
| dups => error ("Duplicate constructors " ^ commas dups ^
" in datatype " ^ tname)
end;
val (dts', constr_syntax, sorts', i) = Library.foldl prep_dt_spec (([], [], [], 0), dts);
val sorts = sorts' @ (map (rpair (Sign.defaultS sign)) (tyvars \\ map fst sorts'));
val dt_info = get_datatypes thy;
val (descr, _) = unfold_datatypes sign dts' sorts dt_info dts' i;
val _ = check_nonempty descr handle (exn as Datatype_Empty s) =>
if err then error ("Nonemptiness check failed for datatype " ^ s)
else raise exn;
val descr' = List.concat descr;
val case_names_induct = mk_case_names_induct descr';
val case_names_exhausts = mk_case_names_exhausts descr' (map #1 new_dts);
in
(if (!quick_and_dirty) then add_datatype_axm else add_datatype_def)
flat_names new_type_names descr sorts types_syntax constr_syntax dt_info
case_names_induct case_names_exhausts thy
end;
val add_datatype_i = gen_add_datatype cert_typ;
val add_datatype = gen_add_datatype read_typ true;
(** package setup **)
(* setup theory *)
val setup = [DatatypesData.init, Method.add_methods tactic_emulations] @ simproc_setup @ trfun_setup;
(* outer syntax *)
local structure P = OuterParse and K = OuterKeyword in
val datatype_decl =
Scan.option (P.$$$ "(" |-- P.name --| P.$$$ ")") -- P.type_args -- P.name -- P.opt_infix --
(P.$$$ "=" |-- P.enum1 "|" (P.name -- Scan.repeat P.typ -- P.opt_mixfix));
fun mk_datatype args =
let
val names = map (fn ((((NONE, _), t), _), _) => t | ((((SOME t, _), _), _), _) => t) args;
val specs = map (fn ((((_, vs), t), mx), cons) =>
(vs, t, mx, map (fn ((x, y), z) => (x, y, z)) cons)) args;
in #1 o add_datatype false names specs end;
val datatypeP =
OuterSyntax.command "datatype" "define inductive datatypes" K.thy_decl
(P.and_list1 datatype_decl >> (Toplevel.theory o mk_datatype));
val rep_datatype_decl =
Scan.option (Scan.repeat1 P.name) --
Scan.optional (P.$$$ "distinct" |-- P.!!! (P.and_list1 P.xthms1)) [[]] --
Scan.optional (P.$$$ "inject" |-- P.!!! (P.and_list1 P.xthms1)) [[]] --
(P.$$$ "induction" |-- P.!!! P.xthm);
fun mk_rep_datatype (((opt_ts, dss), iss), ind) = #1 o rep_datatype opt_ts dss iss ind;
val rep_datatypeP =
OuterSyntax.command "rep_datatype" "represent existing types inductively" K.thy_decl
(rep_datatype_decl >> (Toplevel.theory o mk_rep_datatype));
val _ = OuterSyntax.add_keywords ["distinct", "inject", "induction"];
val _ = OuterSyntax.add_parsers [datatypeP, rep_datatypeP];
end;
end;
structure BasicDatatypePackage: BASIC_DATATYPE_PACKAGE = DatatypePackage;
open BasicDatatypePackage;