(* Title: HOL/Tools/BNF/bnf_comp.ML
Author: Dmitriy Traytel, TU Muenchen
Author: Jasmin Blanchette, TU Muenchen
Copyright 2012
Composition of bounded natural functors.
*)
val inline_ref = Unsynchronized.ref true;
signature BNF_COMP =
sig
val ID_bnf: BNF_Def.bnf
val DEADID_bnf: BNF_Def.bnf
type comp_cache
type unfold_set
val empty_comp_cache: comp_cache
val empty_unfolds: unfold_set
exception BAD_DEAD of typ * typ
val bnf_of_typ: BNF_Def.inline_policy -> (binding -> binding) ->
((string * sort) list list -> (string * sort) list) -> (string * sort) list ->
(string * sort) list -> typ -> (comp_cache * unfold_set) * local_theory ->
(BNF_Def.bnf * (typ list * typ list)) * ((comp_cache * unfold_set) * local_theory)
val default_comp_sort: (string * sort) list list -> (string * sort) list
val normalize_bnfs: (int -> binding -> binding) -> ''a list list -> ''a list ->
(''a list list -> ''a list) -> BNF_Def.bnf list -> (comp_cache * unfold_set) * local_theory ->
(int list list * ''a list) * (BNF_Def.bnf list * ((comp_cache * unfold_set) * local_theory))
type absT_info =
{absT: typ,
repT: typ,
abs: term,
rep: term,
abs_inject: thm,
abs_inverse: thm,
type_definition: thm}
val morph_absT_info: morphism -> absT_info -> absT_info
val mk_absT: theory -> typ -> typ -> typ -> typ
val mk_repT: typ -> typ -> typ -> typ
val mk_abs: typ -> term -> term
val mk_rep: typ -> term -> term
val seal_bnf: (binding -> binding) -> unfold_set -> binding -> typ list -> BNF_Def.bnf ->
local_theory -> (BNF_Def.bnf * (typ list * absT_info)) * local_theory
end;
structure BNF_Comp : BNF_COMP =
struct
open BNF_Def
open BNF_Util
open BNF_Tactics
open BNF_Comp_Tactics
val ID_bnf = the (bnf_of @{context} "Basic_BNFs.ID");
val DEADID_bnf = the (bnf_of @{context} "Basic_BNFs.DEADID");
type comp_cache = (bnf * (typ list * typ list)) Typtab.table;
fun key_of_types s Ts = Type (s, Ts);
fun key_of_typess s = key_of_types s o map (key_of_types "");
fun typ_of_int n = Type (string_of_int n, []);
fun typ_of_bnf bnf =
key_of_typess "" [[T_of_bnf bnf], lives_of_bnf bnf, sort Term_Ord.typ_ord (deads_of_bnf bnf)];
fun key_of_kill n bnf = key_of_types "k" [typ_of_int n, typ_of_bnf bnf];
fun key_of_lift n bnf = key_of_types "l" [typ_of_int n, typ_of_bnf bnf];
fun key_of_permute src dest bnf =
key_of_types "p" (map typ_of_int src @ map typ_of_int dest @ [typ_of_bnf bnf]);
fun key_of_compose oDs Dss Ass outer inners =
key_of_types "c" (map (key_of_typess "") [[oDs], Dss, Ass, [map typ_of_bnf (outer :: inners)]]);
fun cache_comp_simple key cache (bnf, (unfold_set, lthy)) =
(bnf, ((Typtab.update (key, (bnf, ([], []))) cache, unfold_set), lthy));
fun cache_comp key (bnf_Ds_As, ((cache, unfold_set), lthy)) =
(bnf_Ds_As, ((Typtab.update (key, bnf_Ds_As) cache, unfold_set), lthy));
(* TODO: Replace by "BNF_Defs.defs list"? *)
type unfold_set = {
map_unfolds: thm list,
set_unfoldss: thm list list,
rel_unfolds: thm list
};
val empty_comp_cache = Typtab.empty;
val empty_unfolds = {map_unfolds = [], set_unfoldss = [], rel_unfolds = []};
fun add_to_thms thms new = thms |> not (Thm.is_reflexive new) ? insert Thm.eq_thm new;
fun adds_to_thms thms news = insert (eq_set Thm.eq_thm) (no_reflexive news) thms;
fun add_to_unfolds map sets rel
{map_unfolds, set_unfoldss, rel_unfolds} =
{map_unfolds = add_to_thms map_unfolds map,
set_unfoldss = adds_to_thms set_unfoldss sets,
rel_unfolds = add_to_thms rel_unfolds rel};
fun add_bnf_to_unfolds bnf =
add_to_unfolds (map_def_of_bnf bnf) (set_defs_of_bnf bnf) (rel_def_of_bnf bnf);
val bdTN = "bdT";
fun mk_killN n = "_kill" ^ string_of_int n;
fun mk_liftN n = "_lift" ^ string_of_int n;
fun mk_permuteN src dest =
"_permute_" ^ implode (map string_of_int src) ^ "_" ^ implode (map string_of_int dest);
(*copied from Envir.expand_term_free*)
fun expand_term_const defs =
let
val eqs = map ((fn ((x, U), u) => (x, (U, u))) o apfst dest_Const) defs;
val get = fn Const (x, _) => AList.lookup (op =) eqs x | _ => NONE;
in Envir.expand_term get end;
fun is_sum_prod_natLeq (Const (@{const_name csum}, _) $ t $ u) = forall is_sum_prod_natLeq [t, u]
| is_sum_prod_natLeq (Const (@{const_name cprod}, _) $ t $ u) = forall is_sum_prod_natLeq [t, u]
| is_sum_prod_natLeq t = t aconv @{term natLeq};
fun clean_compose_bnf const_policy qualify b outer inners (unfold_set, lthy) =
let
val olive = live_of_bnf outer;
val onwits = nwits_of_bnf outer;
val odead = dead_of_bnf outer;
val inner = hd inners;
val ilive = live_of_bnf inner;
val ideads = map dead_of_bnf inners;
val inwitss = map nwits_of_bnf inners;
(* TODO: check olive = length inners > 0,
forall inner from inners. ilive = live,
forall inner from inners. idead = dead *)
val (oDs, lthy1) = apfst (map TFree)
(Variable.invent_types (replicate odead HOLogic.typeS) lthy);
val (Dss, lthy2) = apfst (map (map TFree))
(fold_map Variable.invent_types (map (fn n => replicate n HOLogic.typeS) ideads) lthy1);
val (Ass, lthy3) = apfst (replicate ilive o map TFree)
(Variable.invent_types (replicate ilive HOLogic.typeS) lthy2);
val As = if ilive > 0 then hd Ass else [];
val Ass_repl = replicate olive As;
val (Bs, names_lthy) = apfst (map TFree)
(Variable.invent_types (replicate ilive HOLogic.typeS) lthy3);
val Bss_repl = replicate olive Bs;
val ((((fs', Qs'), Asets), xs), _) = names_lthy
|> apfst snd o mk_Frees' "f" (map2 (curry op -->) As Bs)
||>> apfst snd o mk_Frees' "Q" (map2 mk_pred2T As Bs)
||>> mk_Frees "A" (map HOLogic.mk_setT As)
||>> mk_Frees "x" As;
val CAs = map3 mk_T_of_bnf Dss Ass_repl inners;
val CCA = mk_T_of_bnf oDs CAs outer;
val CBs = map3 mk_T_of_bnf Dss Bss_repl inners;
val outer_sets = mk_sets_of_bnf (replicate olive oDs) (replicate olive CAs) outer;
val inner_setss = map3 mk_sets_of_bnf (map (replicate ilive) Dss) (replicate olive Ass) inners;
val inner_bds = map3 mk_bd_of_bnf Dss Ass_repl inners;
val outer_bd = mk_bd_of_bnf oDs CAs outer;
(*%f1 ... fn. outer.map (inner_1.map f1 ... fn) ... (inner_m.map f1 ... fn)*)
val mapx = fold_rev Term.abs fs'
(Term.list_comb (mk_map_of_bnf oDs CAs CBs outer,
map2 (fn Ds => (fn f => Term.list_comb (f, map Bound (ilive - 1 downto 0))) o
mk_map_of_bnf Ds As Bs) Dss inners));
(*%Q1 ... Qn. outer.rel (inner_1.rel Q1 ... Qn) ... (inner_m.rel Q1 ... Qn)*)
val rel = fold_rev Term.abs Qs'
(Term.list_comb (mk_rel_of_bnf oDs CAs CBs outer,
map2 (fn Ds => (fn f => Term.list_comb (f, map Bound (ilive - 1 downto 0))) o
mk_rel_of_bnf Ds As Bs) Dss inners));
(*Union o collect {outer.set_1 ... outer.set_m} o outer.map inner_1.set_i ... inner_m.set_i*)
(*Union o collect {image inner_1.set_i o outer.set_1 ... image inner_m.set_i o outer.set_m}*)
fun mk_set i =
let
val (setTs, T) = `(replicate olive o HOLogic.mk_setT) (nth As i);
val outer_set = mk_collect
(mk_sets_of_bnf (replicate olive oDs) (replicate olive setTs) outer)
(mk_T_of_bnf oDs setTs outer --> HOLogic.mk_setT T);
val inner_sets = map (fn sets => nth sets i) inner_setss;
val outer_map = mk_map_of_bnf oDs CAs setTs outer;
val map_inner_sets = Term.list_comb (outer_map, inner_sets);
val collect_image = mk_collect
(map2 (fn f => fn set => HOLogic.mk_comp (mk_image f, set)) inner_sets outer_sets)
(CCA --> HOLogic.mk_setT T);
in
(Library.foldl1 HOLogic.mk_comp [mk_Union T, outer_set, map_inner_sets],
HOLogic.mk_comp (mk_Union T, collect_image))
end;
val (sets, sets_alt) = map_split mk_set (0 upto ilive - 1);
fun mk_simplified_set set =
let
val setT = fastype_of set;
val var_set' = Const (@{const_name id_bnf_comp}, setT --> setT) $ Var ((Name.uu, 0), setT);
val goal = mk_Trueprop_eq (var_set', set);
fun tac {context = ctxt, prems = _} = mk_simplified_set_tac ctxt;
val set'_eq_set =
Goal.prove names_lthy [] [] goal tac
|> Thm.close_derivation;
val set' = fst (HOLogic.dest_eq (HOLogic.dest_Trueprop (Thm.prop_of set'_eq_set)));
in
(set', set'_eq_set)
end;
val (sets', set'_eq_sets) =
map_split mk_simplified_set sets
||> Proof_Context.export names_lthy lthy;
(*(inner_1.bd +c ... +c inner_m.bd) *c outer.bd*)
val bd = mk_cprod (Library.foldr1 (uncurry mk_csum) inner_bds) outer_bd;
val (bd', bd_ordIso_natLeq_thm_opt) =
if is_sum_prod_natLeq bd then
let
val bd' = @{term natLeq};
val bd_bd' = HOLogic.mk_prod (bd, bd');
val ordIso = Const (@{const_name ordIso}, HOLogic.mk_setT (fastype_of bd_bd'));
val goal = HOLogic.mk_Trueprop (HOLogic.mk_mem (bd_bd', ordIso));
in
(bd', SOME (Goal.prove_sorry lthy [] [] goal (K bd_ordIso_natLeq_tac)
|> Thm.close_derivation))
end
else
(bd, NONE);
fun map_id0_tac _ =
mk_comp_map_id0_tac (map_id0_of_bnf outer) (map_cong0_of_bnf outer)
(map map_id0_of_bnf inners);
fun map_comp0_tac _ =
mk_comp_map_comp0_tac (map_comp0_of_bnf outer) (map_cong0_of_bnf outer)
(map map_comp0_of_bnf inners);
fun mk_single_set_map0_tac i ctxt =
mk_comp_set_map0_tac ctxt (nth set'_eq_sets i) (map_comp0_of_bnf outer)
(map_cong0_of_bnf outer) (collect_set_map_of_bnf outer)
(map ((fn thms => nth thms i) o set_map0_of_bnf) inners);
val set_map0_tacs = map mk_single_set_map0_tac (0 upto ilive - 1);
fun bd_card_order_tac _ =
mk_comp_bd_card_order_tac (map bd_card_order_of_bnf inners) (bd_card_order_of_bnf outer);
fun bd_cinfinite_tac _ =
mk_comp_bd_cinfinite_tac (bd_cinfinite_of_bnf inner) (bd_cinfinite_of_bnf outer);
val set_alt_thms =
if Config.get lthy quick_and_dirty then
[]
else
map (fn goal =>
Goal.prove_sorry lthy [] [] goal
(fn {context = ctxt, prems = _} =>
mk_comp_set_alt_tac ctxt (collect_set_map_of_bnf outer))
|> Thm.close_derivation)
(map2 (curry (HOLogic.mk_Trueprop o HOLogic.mk_eq)) sets sets_alt);
fun map_cong0_tac ctxt =
mk_comp_map_cong0_tac ctxt set'_eq_sets set_alt_thms (map_cong0_of_bnf outer)
(map map_cong0_of_bnf inners);
val set_bd_tacs =
if Config.get lthy quick_and_dirty then
replicate ilive (K all_tac)
else
let
val outer_set_bds = set_bd_of_bnf outer;
val inner_set_bdss = map set_bd_of_bnf inners;
val inner_bd_Card_orders = map bd_Card_order_of_bnf inners;
fun single_set_bd_thm i j =
@{thm comp_single_set_bd} OF [nth inner_bd_Card_orders j, nth (nth inner_set_bdss j) i,
nth outer_set_bds j]
val single_set_bd_thmss =
map ((fn f => map f (0 upto olive - 1)) o single_set_bd_thm) (0 upto ilive - 1);
in
map3 (fn set'_eq_set => fn set_alt => fn single_set_bds => fn ctxt =>
mk_comp_set_bd_tac ctxt set'_eq_set bd_ordIso_natLeq_thm_opt set_alt single_set_bds)
set'_eq_sets set_alt_thms single_set_bd_thmss
end;
val in_alt_thm =
let
val inx = mk_in Asets sets CCA;
val in_alt = mk_in (map2 (mk_in Asets) inner_setss CAs) outer_sets CCA;
val goal = fold_rev Logic.all Asets (mk_Trueprop_eq (inx, in_alt));
in
Goal.prove_sorry lthy [] [] goal
(fn {context = ctxt, prems = _} => mk_comp_in_alt_tac ctxt set_alt_thms)
|> Thm.close_derivation
end;
fun le_rel_OO_tac _ = mk_le_rel_OO_tac (le_rel_OO_of_bnf outer) (rel_mono_of_bnf outer)
(map le_rel_OO_of_bnf inners);
fun rel_OO_Grp_tac ctxt =
let
val outer_rel_Grp = rel_Grp_of_bnf outer RS sym;
val outer_rel_cong = rel_cong_of_bnf outer;
val thm =
(trans OF [in_alt_thm RS @{thm OO_Grp_cong},
trans OF [@{thm arg_cong2[of _ _ _ _ relcompp]} OF
[trans OF [outer_rel_Grp RS @{thm arg_cong[of _ _ conversep]},
rel_conversep_of_bnf outer RS sym], outer_rel_Grp],
trans OF [rel_OO_of_bnf outer RS sym, outer_rel_cong OF
(map (fn bnf => rel_OO_Grp_of_bnf bnf RS sym) inners)]]] RS sym);
in
unfold_thms_tac ctxt set'_eq_sets THEN rtac thm 1
end;
val tacs = zip_axioms map_id0_tac map_comp0_tac map_cong0_tac set_map0_tacs bd_card_order_tac
bd_cinfinite_tac set_bd_tacs le_rel_OO_tac rel_OO_Grp_tac;
val outer_wits = mk_wits_of_bnf (replicate onwits oDs) (replicate onwits CAs) outer;
val inner_witss = map (map (fn (I, wit) => Term.list_comb (wit, map (nth xs) I)))
(map3 (fn Ds => fn n => mk_wits_of_bnf (replicate n Ds) (replicate n As))
Dss inwitss inners);
val inner_witsss = map (map (nth inner_witss) o fst) outer_wits;
val wits = (inner_witsss, (map (single o snd) outer_wits))
|-> map2 (fold (map_product (fn iwit => fn owit => owit $ iwit)))
|> flat
|> map (`(fn t => Term.add_frees t []))
|> minimize_wits
|> map (fn (frees, t) => fold absfree frees t);
fun wit_tac ctxt =
mk_comp_wit_tac ctxt set'_eq_sets (wit_thms_of_bnf outer) (collect_set_map_of_bnf outer)
(maps wit_thms_of_bnf inners);
val (bnf', lthy') =
bnf_def const_policy (K Dont_Note) qualify tacs wit_tac (SOME (oDs @ flat Dss)) Binding.empty
Binding.empty [] ((((((b, CCA), mapx), sets'), bd'), wits), SOME rel) lthy;
val phi =
Morphism.thm_morphism "BNF" (unfold_thms lthy' @{thms id_bnf_comp_def})
$> Morphism.term_morphism "BNF" (Raw_Simplifier.rewrite_term (Proof_Context.theory_of lthy')
@{thms id_bnf_comp_def[abs_def]} []);
val bnf'' = morph_bnf phi bnf';
in
(bnf'', (add_bnf_to_unfolds bnf'' unfold_set, lthy'))
end;
(* Killing live variables *)
fun raw_kill_bnf qualify n bnf (accum as (unfold_set, lthy)) =
if n = 0 then (bnf, accum) else
let
val b = Binding.suffix_name (mk_killN n) (name_of_bnf bnf);
val live = live_of_bnf bnf;
val dead = dead_of_bnf bnf;
val nwits = nwits_of_bnf bnf;
(* TODO: check 0 < n <= live *)
val (Ds, lthy1) = apfst (map TFree)
(Variable.invent_types (replicate dead HOLogic.typeS) lthy);
val ((killedAs, As), lthy2) = apfst (`(take n) o map TFree)
(Variable.invent_types (replicate live HOLogic.typeS) lthy1);
val (Bs, _(*lthy3*)) = apfst (append killedAs o map TFree)
(Variable.invent_types (replicate (live - n) HOLogic.typeS) lthy2);
val ((Asets, lives), _(*names_lthy*)) = lthy
|> mk_Frees "A" (map HOLogic.mk_setT (drop n As))
||>> mk_Frees "x" (drop n As);
val xs = map (fn T => HOLogic.choice_const T $ absdummy T @{term True}) killedAs @ lives;
val T = mk_T_of_bnf Ds As bnf;
(*bnf.map id ... id*)
val mapx = Term.list_comb (mk_map_of_bnf Ds As Bs bnf, map HOLogic.id_const killedAs);
(*bnf.rel (op =) ... (op =)*)
val rel = Term.list_comb (mk_rel_of_bnf Ds As Bs bnf, map HOLogic.eq_const killedAs);
val bnf_sets = mk_sets_of_bnf (replicate live Ds) (replicate live As) bnf;
val sets = drop n bnf_sets;
val bd = mk_bd_of_bnf Ds As bnf;
fun map_id0_tac _ = rtac (map_id0_of_bnf bnf) 1;
fun map_comp0_tac ctxt =
unfold_thms_tac ctxt ((map_comp0_of_bnf bnf RS sym) ::
@{thms comp_assoc id_comp comp_id}) THEN rtac refl 1;
fun map_cong0_tac ctxt =
mk_kill_map_cong0_tac ctxt n (live - n) (map_cong0_of_bnf bnf);
val set_map0_tacs = map (fn thm => fn _ => rtac thm 1) (drop n (set_map0_of_bnf bnf));
fun bd_card_order_tac _ = rtac (bd_card_order_of_bnf bnf) 1;
fun bd_cinfinite_tac _ = rtac (bd_cinfinite_of_bnf bnf) 1;
val set_bd_tacs = map (fn thm => fn _ => rtac thm 1) (drop n (set_bd_of_bnf bnf));
val in_alt_thm =
let
val inx = mk_in Asets sets T;
val in_alt = mk_in (map HOLogic.mk_UNIV killedAs @ Asets) bnf_sets T;
val goal = fold_rev Logic.all Asets (mk_Trueprop_eq (inx, in_alt));
in
Goal.prove_sorry lthy [] [] goal (K kill_in_alt_tac) |> Thm.close_derivation
end;
fun le_rel_OO_tac ctxt =
EVERY' [rtac @{thm ord_le_eq_trans}, rtac (le_rel_OO_of_bnf bnf)] 1 THEN
unfold_thms_tac ctxt @{thms eq_OO} THEN rtac refl 1;
fun rel_OO_Grp_tac _ =
let
val rel_Grp = rel_Grp_of_bnf bnf RS sym
val thm =
(trans OF [in_alt_thm RS @{thm OO_Grp_cong},
trans OF [@{thm arg_cong2[of _ _ _ _ relcompp]} OF
[trans OF [rel_Grp RS @{thm arg_cong[of _ _ conversep]},
rel_conversep_of_bnf bnf RS sym], rel_Grp],
trans OF [rel_OO_of_bnf bnf RS sym, rel_cong_of_bnf bnf OF
(replicate n @{thm trans[OF Grp_UNIV_id[OF refl] eq_alt[symmetric]]} @
replicate (live - n) @{thm Grp_fst_snd})]]] RS sym);
in
rtac thm 1
end;
val tacs = zip_axioms map_id0_tac map_comp0_tac map_cong0_tac set_map0_tacs bd_card_order_tac
bd_cinfinite_tac set_bd_tacs le_rel_OO_tac rel_OO_Grp_tac;
val bnf_wits = mk_wits_of_bnf (replicate nwits Ds) (replicate nwits As) bnf;
val wits = map (fn t => fold absfree (Term.add_frees t []) t)
(map (fn (I, wit) => Term.list_comb (wit, map (nth xs) I)) bnf_wits);
fun wit_tac _ = mk_simple_wit_tac (wit_thms_of_bnf bnf);
val (bnf', lthy') =
bnf_def Smart_Inline (K Dont_Note) qualify tacs wit_tac (SOME (killedAs @ Ds)) Binding.empty
Binding.empty [] ((((((b, T), mapx), sets), bd), wits), SOME rel) lthy;
in
(bnf', (add_bnf_to_unfolds bnf' unfold_set, lthy'))
end;
fun kill_bnf qualify n bnf (accum as ((cache, unfold_set), lthy)) =
let val key = key_of_kill n bnf in
(case Typtab.lookup cache key of
SOME (bnf, _) => (bnf, accum)
| NONE => cache_comp_simple key cache (raw_kill_bnf qualify n bnf (unfold_set, lthy)))
end;
(* Adding dummy live variables *)
fun raw_lift_bnf qualify n bnf (accum as (unfold_set, lthy)) =
if n = 0 then (bnf, accum) else
let
val b = Binding.suffix_name (mk_liftN n) (name_of_bnf bnf);
val live = live_of_bnf bnf;
val dead = dead_of_bnf bnf;
val nwits = nwits_of_bnf bnf;
(* TODO: check 0 < n *)
val (Ds, lthy1) = apfst (map TFree)
(Variable.invent_types (replicate dead HOLogic.typeS) lthy);
val ((newAs, As), lthy2) = apfst (chop n o map TFree)
(Variable.invent_types (replicate (n + live) HOLogic.typeS) lthy1);
val ((newBs, Bs), _(*lthy3*)) = apfst (chop n o map TFree)
(Variable.invent_types (replicate (n + live) HOLogic.typeS) lthy2);
val (Asets, _(*names_lthy*)) = lthy
|> mk_Frees "A" (map HOLogic.mk_setT (newAs @ As));
val T = mk_T_of_bnf Ds As bnf;
(*%f1 ... fn. bnf.map*)
val mapx =
fold_rev Term.absdummy (map2 (curry op -->) newAs newBs) (mk_map_of_bnf Ds As Bs bnf);
(*%Q1 ... Qn. bnf.rel*)
val rel = fold_rev Term.absdummy (map2 mk_pred2T newAs newBs) (mk_rel_of_bnf Ds As Bs bnf);
val bnf_sets = mk_sets_of_bnf (replicate live Ds) (replicate live As) bnf;
val sets = map (fn A => absdummy T (HOLogic.mk_set A [])) newAs @ bnf_sets;
val bd = mk_bd_of_bnf Ds As bnf;
fun map_id0_tac _ = rtac (map_id0_of_bnf bnf) 1;
fun map_comp0_tac ctxt =
unfold_thms_tac ctxt ((map_comp0_of_bnf bnf RS sym) ::
@{thms comp_assoc id_comp comp_id}) THEN rtac refl 1;
fun map_cong0_tac ctxt =
rtac (map_cong0_of_bnf bnf) 1 THEN REPEAT_DETERM_N live (Goal.assume_rule_tac ctxt 1);
val set_map0_tacs =
if Config.get lthy quick_and_dirty then
replicate (n + live) (K all_tac)
else
replicate n (K empty_natural_tac) @
map (fn thm => fn _ => rtac thm 1) (set_map0_of_bnf bnf);
fun bd_card_order_tac _ = rtac (bd_card_order_of_bnf bnf) 1;
fun bd_cinfinite_tac _ = rtac (bd_cinfinite_of_bnf bnf) 1;
val set_bd_tacs =
if Config.get lthy quick_and_dirty then
replicate (n + live) (K all_tac)
else
replicate n (K (mk_lift_set_bd_tac (bd_Card_order_of_bnf bnf))) @
(map (fn thm => fn _ => rtac thm 1) (set_bd_of_bnf bnf));
val in_alt_thm =
let
val inx = mk_in Asets sets T;
val in_alt = mk_in (drop n Asets) bnf_sets T;
val goal = fold_rev Logic.all Asets (mk_Trueprop_eq (inx, in_alt));
in
Goal.prove_sorry lthy [] [] goal (K lift_in_alt_tac) |> Thm.close_derivation
end;
fun le_rel_OO_tac _ = rtac (le_rel_OO_of_bnf bnf) 1;
fun rel_OO_Grp_tac _ = mk_simple_rel_OO_Grp_tac (rel_OO_Grp_of_bnf bnf) in_alt_thm;
val tacs = zip_axioms map_id0_tac map_comp0_tac map_cong0_tac set_map0_tacs bd_card_order_tac
bd_cinfinite_tac set_bd_tacs le_rel_OO_tac rel_OO_Grp_tac;
val wits = map snd (mk_wits_of_bnf (replicate nwits Ds) (replicate nwits As) bnf);
fun wit_tac _ = mk_simple_wit_tac (wit_thms_of_bnf bnf);
val (bnf', lthy') =
bnf_def Smart_Inline (K Dont_Note) qualify tacs wit_tac (SOME Ds) Binding.empty Binding.empty
[] ((((((b, T), mapx), sets), bd), wits), SOME rel) lthy;
in
(bnf', (add_bnf_to_unfolds bnf' unfold_set, lthy'))
end;
fun lift_bnf qualify n bnf (accum as ((cache, unfold_set), lthy)) =
let val key = key_of_lift n bnf in
(case Typtab.lookup cache key of
SOME (bnf, _) => (bnf, accum)
| NONE => cache_comp_simple key cache (raw_lift_bnf qualify n bnf (unfold_set, lthy)))
end;
(* Changing the order of live variables *)
fun raw_permute_bnf qualify src dest bnf (accum as (unfold_set, lthy)) =
if src = dest then (bnf, accum) else
let
val b = Binding.suffix_name (mk_permuteN src dest) (name_of_bnf bnf);
val live = live_of_bnf bnf;
val dead = dead_of_bnf bnf;
val nwits = nwits_of_bnf bnf;
fun permute xs = permute_like_unique (op =) src dest xs;
fun unpermute xs = permute_like_unique (op =) dest src xs;
val (Ds, lthy1) = apfst (map TFree)
(Variable.invent_types (replicate dead HOLogic.typeS) lthy);
val (As, lthy2) = apfst (map TFree)
(Variable.invent_types (replicate live HOLogic.typeS) lthy1);
val (Bs, _(*lthy3*)) = apfst (map TFree)
(Variable.invent_types (replicate live HOLogic.typeS) lthy2);
val (Asets, _(*names_lthy*)) = lthy
|> mk_Frees "A" (map HOLogic.mk_setT (permute As));
val T = mk_T_of_bnf Ds As bnf;
(*%f(1) ... f(n). bnf.map f\<sigma>(1) ... f\<sigma>(n)*)
val mapx = fold_rev Term.absdummy (permute (map2 (curry op -->) As Bs))
(Term.list_comb (mk_map_of_bnf Ds As Bs bnf, unpermute (map Bound (live - 1 downto 0))));
(*%Q(1) ... Q(n). bnf.rel Q\<sigma>(1) ... Q\<sigma>(n)*)
val rel = fold_rev Term.absdummy (permute (map2 mk_pred2T As Bs))
(Term.list_comb (mk_rel_of_bnf Ds As Bs bnf, unpermute (map Bound (live - 1 downto 0))));
val bnf_sets = mk_sets_of_bnf (replicate live Ds) (replicate live As) bnf;
val sets = permute bnf_sets;
val bd = mk_bd_of_bnf Ds As bnf;
fun map_id0_tac _ = rtac (map_id0_of_bnf bnf) 1;
fun map_comp0_tac _ = rtac (map_comp0_of_bnf bnf) 1;
fun map_cong0_tac ctxt =
rtac (map_cong0_of_bnf bnf) 1 THEN REPEAT_DETERM_N live (Goal.assume_rule_tac ctxt 1);
val set_map0_tacs = permute (map (fn thm => fn _ => rtac thm 1) (set_map0_of_bnf bnf));
fun bd_card_order_tac _ = rtac (bd_card_order_of_bnf bnf) 1;
fun bd_cinfinite_tac _ = rtac (bd_cinfinite_of_bnf bnf) 1;
val set_bd_tacs = permute (map (fn thm => fn _ => rtac thm 1) (set_bd_of_bnf bnf));
val in_alt_thm =
let
val inx = mk_in Asets sets T;
val in_alt = mk_in (unpermute Asets) bnf_sets T;
val goal = fold_rev Logic.all Asets (mk_Trueprop_eq (inx, in_alt));
in
Goal.prove_sorry lthy [] [] goal (K (mk_permute_in_alt_tac src dest))
|> Thm.close_derivation
end;
fun le_rel_OO_tac _ = rtac (le_rel_OO_of_bnf bnf) 1;
fun rel_OO_Grp_tac _ = mk_simple_rel_OO_Grp_tac (rel_OO_Grp_of_bnf bnf) in_alt_thm;
val tacs = zip_axioms map_id0_tac map_comp0_tac map_cong0_tac set_map0_tacs bd_card_order_tac
bd_cinfinite_tac set_bd_tacs le_rel_OO_tac rel_OO_Grp_tac;
val wits = map snd (mk_wits_of_bnf (replicate nwits Ds) (replicate nwits As) bnf);
fun wit_tac _ = mk_simple_wit_tac (wit_thms_of_bnf bnf);
val (bnf', lthy') =
bnf_def Smart_Inline (K Dont_Note) qualify tacs wit_tac (SOME Ds) Binding.empty Binding.empty
[] ((((((b, T), mapx), sets), bd), wits), SOME rel) lthy;
in
(bnf', (add_bnf_to_unfolds bnf' unfold_set, lthy'))
end;
fun permute_bnf qualify src dest bnf (accum as ((cache, unfold_set), lthy)) =
let val key = key_of_permute src dest bnf in
(case Typtab.lookup cache key of
SOME (bnf, _) => (bnf, accum)
| NONE => cache_comp_simple key cache (raw_permute_bnf qualify src dest bnf (unfold_set, lthy)))
end;
(* Composition pipeline *)
fun permute_and_kill qualify n src dest bnf =
permute_bnf qualify src dest bnf
#> uncurry (kill_bnf qualify n);
fun lift_and_permute qualify n src dest bnf =
lift_bnf qualify n bnf
#> uncurry (permute_bnf qualify src dest);
fun normalize_bnfs qualify Ass Ds sort bnfs accum =
let
val before_kill_src = map (fn As => 0 upto (length As - 1)) Ass;
val kill_poss = map (find_indices op = Ds) Ass;
val live_poss = map2 (subtract op =) kill_poss before_kill_src;
val before_kill_dest = map2 append kill_poss live_poss;
val kill_ns = map length kill_poss;
val (inners', accum') =
fold_map5 (fn i => permute_and_kill (qualify i))
(if length bnfs = 1 then [0] else (1 upto length bnfs))
kill_ns before_kill_src before_kill_dest bnfs accum;
val Ass' = map2 (map o nth) Ass live_poss;
val As = sort Ass';
val after_lift_dest = replicate (length Ass') (0 upto (length As - 1));
val old_poss = map (map (fn x => find_index (fn y => x = y) As)) Ass';
val new_poss = map2 (subtract op =) old_poss after_lift_dest;
val after_lift_src = map2 append new_poss old_poss;
val lift_ns = map (fn xs => length As - length xs) Ass';
in
((kill_poss, As), fold_map5 (fn i => lift_and_permute (qualify i))
(if length bnfs = 1 then [0] else 1 upto length bnfs)
lift_ns after_lift_src after_lift_dest inners' accum')
end;
fun default_comp_sort Ass =
Library.sort (Term_Ord.typ_ord o pairself TFree) (fold (fold (insert (op =))) Ass []);
fun raw_compose_bnf const_policy qualify sort outer inners oDs Dss tfreess accum =
let
val b = name_of_bnf outer;
val Ass = map (map Term.dest_TFree) tfreess;
val Ds = fold (fold Term.add_tfreesT) (oDs :: Dss) [];
val ((kill_poss, As), (inners', ((cache', unfold_set'), lthy'))) =
normalize_bnfs qualify Ass Ds sort inners accum;
val Ds = oDs @ flat (map3 (append oo map o nth) tfreess kill_poss Dss);
val As = map TFree As;
in
apfst (rpair (Ds, As))
(apsnd (apfst (pair cache'))
(clean_compose_bnf const_policy (qualify 0) b outer inners' (unfold_set', lthy')))
end;
fun compose_bnf const_policy qualify sort outer inners oDs Dss tfreess (accum as ((cache, _), _)) =
let val key = key_of_compose oDs Dss tfreess outer inners in
(case Typtab.lookup cache key of
SOME bnf_Ds_As => (bnf_Ds_As, accum)
| NONE =>
cache_comp key (raw_compose_bnf const_policy qualify sort outer inners oDs Dss tfreess accum))
end;
(* Hide the type of the bound (optimization) and unfold the definitions (nicer to the user) *)
type absT_info =
{absT: typ,
repT: typ,
abs: term,
rep: term,
abs_inject: thm,
abs_inverse: thm,
type_definition: thm};
fun morph_absT_info phi
{absT, repT, abs, rep, abs_inject, abs_inverse, type_definition} =
{absT = Morphism.typ phi absT,
repT = Morphism.typ phi repT,
abs = Morphism.term phi abs,
rep = Morphism.term phi rep,
abs_inject = Morphism.thm phi abs_inject,
abs_inverse = Morphism.thm phi abs_inverse,
type_definition = Morphism.thm phi type_definition};
fun mk_absT thy repT absT repU =
let
val rho = Vartab.fold (cons o apsnd snd) (Sign.typ_match thy (repT, repU) Vartab.empty) [];
in Term.typ_subst_TVars rho absT end
handle Type.TYPE_MATCH => raise Term.TYPE ("mk_absT", [repT, absT, repU], []);
fun mk_repT absT repT absU =
if absT = repT then absU
else
(case (absT, absU) of
(Type (C, Ts), Type (C', Us)) =>
if C = C' then Term.typ_subst_atomic (Ts ~~ Us) repT
else raise Term.TYPE ("mk_repT", [absT, repT, absT], [])
| _ => raise Term.TYPE ("mk_repT", [absT, repT, absT], []));
fun mk_abs_or_rep _ absU (Const (@{const_name id_bnf_comp}, _)) =
Const (@{const_name id_bnf_comp}, absU --> absU)
| mk_abs_or_rep getT (Type (_, Us)) abs =
let val Ts = snd (dest_Type (getT (fastype_of abs)))
in Term.subst_atomic_types (Ts ~~ Us) abs end;
val mk_abs = mk_abs_or_rep range_type;
val mk_rep = mk_abs_or_rep domain_type;
val smart_max_inline_type_size = 5; (*FUDGE*)
fun maybe_typedef (b, As, mx) set opt_morphs tac =
let
val repT = HOLogic.dest_setT (fastype_of set);
val inline = Term.size_of_typ repT <= smart_max_inline_type_size;
in
if inline then
pair (repT,
(@{const_name id_bnf_comp}, @{const_name id_bnf_comp},
@{thm type_definition_id_bnf_comp_UNIV},
@{thm type_definition.Abs_inverse[OF type_definition_id_bnf_comp_UNIV]},
@{thm type_definition.Abs_inject[OF type_definition_id_bnf_comp_UNIV]}))
else
typedef (b, As, mx) set opt_morphs tac
#>> (fn (T_name, ({Rep_name, Abs_name, ...},
{type_definition, Abs_inverse, Abs_inject, ...}) : Typedef.info) =>
(Type (T_name, map TFree As), (Rep_name, Abs_name, type_definition, Abs_inverse, Abs_inject)))
end;
fun seal_bnf qualify (unfold_set : unfold_set) b Ds bnf lthy =
let
val live = live_of_bnf bnf;
val nwits = nwits_of_bnf bnf;
val (As, lthy1) = apfst (map TFree)
(Variable.invent_types (replicate live HOLogic.typeS) (fold Variable.declare_typ Ds lthy));
val (Bs, _) = apfst (map TFree)
(Variable.invent_types (replicate live HOLogic.typeS) lthy1);
val (((fs, fs'), (Rs, Rs')), _(*names_lthy*)) = lthy
|> mk_Frees' "f" (map2 (curry op -->) As Bs)
||>> mk_Frees' "R" (map2 mk_pred2T As Bs)
val map_unfolds = #map_unfolds unfold_set;
val set_unfoldss = #set_unfoldss unfold_set;
val rel_unfolds = #rel_unfolds unfold_set;
val expand_maps =
fold expand_term_const (map (single o Logic.dest_equals o Thm.prop_of) map_unfolds);
val expand_sets =
fold expand_term_const (map (map (Logic.dest_equals o Thm.prop_of)) set_unfoldss);
val expand_rels =
fold expand_term_const (map (single o Logic.dest_equals o Thm.prop_of) rel_unfolds);
fun unfold_maps ctxt = fold (unfold_thms ctxt o single) map_unfolds;
fun unfold_sets ctxt = fold (unfold_thms ctxt) set_unfoldss;
fun unfold_rels ctxt = unfold_thms ctxt rel_unfolds;
fun unfold_all ctxt = unfold_sets ctxt o unfold_maps ctxt o unfold_rels ctxt;
val repTA = mk_T_of_bnf Ds As bnf;
val T_bind = qualify b;
val TA_params = Term.add_tfreesT repTA [];
val ((TA, (Rep_name, Abs_name, type_definition, Abs_inverse, Abs_inject)), lthy) =
maybe_typedef (T_bind, TA_params, NoSyn)
(HOLogic.mk_UNIV repTA) NONE (EVERY' [rtac exI, rtac UNIV_I] 1) lthy;
val repTB = mk_T_of_bnf Ds Bs bnf;
val TB = Term.typ_subst_atomic (As ~~ Bs) TA;
val RepA = Const (Rep_name, TA --> repTA);
val RepB = Const (Rep_name, TB --> repTB);
val AbsA = Const (Abs_name, repTA --> TA);
val AbsB = Const (Abs_name, repTB --> TB);
val Abs_inject' = Abs_inject OF @{thms UNIV_I UNIV_I};
val Abs_inverse' = Abs_inverse OF @{thms UNIV_I};
val absT_info = {absT = TA, repT = repTA, abs = AbsA, rep = RepA, abs_inject = Abs_inject',
abs_inverse = Abs_inverse', type_definition = type_definition};
val bnf_map = fold_rev Term.absfree fs' (HOLogic.mk_comp (HOLogic.mk_comp (AbsB,
Term.list_comb (expand_maps (mk_map_of_bnf Ds As Bs bnf), fs)), RepA));
val bnf_sets = map ((fn t => HOLogic.mk_comp (t, RepA)) o expand_maps o expand_sets)
(mk_sets_of_bnf (replicate live Ds) (replicate live As) bnf);
val bnf_bd = mk_bd_of_bnf Ds As bnf;
val bnf_rel = fold_rev Term.absfree Rs' (mk_vimage2p RepA RepB $
(Term.list_comb (expand_rels (mk_rel_of_bnf Ds As Bs bnf), Rs)));
(*bd may depend only on dead type variables*)
val bd_repT = fst (dest_relT (fastype_of bnf_bd));
val bdT_bind = qualify (Binding.suffix_name ("_" ^ bdTN) b);
val params = Term.add_tfreesT bd_repT [];
val deads = map TFree params;
val all_deads = map TFree (fold Term.add_tfreesT Ds []);
val ((bdT_name, (bdT_glob_info, bdT_loc_info)), lthy) =
typedef (bdT_bind, params, NoSyn)
(HOLogic.mk_UNIV bd_repT) NONE (EVERY' [rtac exI, rtac UNIV_I] 1) lthy;
val bnf_bd' = mk_dir_image bnf_bd
(Const (#Abs_name bdT_glob_info, bd_repT --> Type (bdT_name, deads)))
val Abs_bdT_inj = mk_Abs_inj_thm (#Abs_inject bdT_loc_info);
val Abs_bdT_bij = mk_Abs_bij_thm lthy Abs_bdT_inj (#Abs_cases bdT_loc_info);
val bd_ordIso = @{thm dir_image} OF [Abs_bdT_inj, bd_Card_order_of_bnf bnf];
val bd_card_order =
@{thm card_order_dir_image} OF [Abs_bdT_bij, bd_card_order_of_bnf bnf];
val bd_cinfinite =
(@{thm Cinfinite_cong} OF [bd_ordIso, bd_Cinfinite_of_bnf bnf]) RS conjunct1;
fun map_id0_tac ctxt =
rtac (@{thm type_copy_map_id0} OF [type_definition, unfold_maps ctxt (map_id0_of_bnf bnf)]) 1;
fun map_comp0_tac ctxt =
rtac (@{thm type_copy_map_comp0} OF
[type_definition, unfold_maps ctxt (map_comp0_of_bnf bnf)]) 1;
fun map_cong0_tac ctxt =
EVERY' (rtac @{thm type_copy_map_cong0} :: rtac (unfold_all ctxt (map_cong0_of_bnf bnf)) ::
map (fn i => EVERY' [select_prem_tac live (dtac meta_spec) i, etac meta_mp,
etac (o_apply RS equalityD2 RS set_mp)]) (1 upto live)) 1;
fun set_map0_tac thm ctxt =
rtac (@{thm type_copy_set_map0} OF [type_definition, unfold_all ctxt thm]) 1;
val set_bd_tacs = map (fn thm => fn ctxt => rtac (@{thm ordLeq_ordIso_trans} OF
[unfold_sets ctxt thm, bd_ordIso] RS @{thm type_copy_set_bd}) 1)
(set_bd_of_bnf bnf);
fun le_rel_OO_tac ctxt =
rtac (unfold_rels ctxt (le_rel_OO_of_bnf bnf) RS @{thm vimage2p_relcompp_mono}) 1;
fun rel_OO_Grp_tac ctxt =
(rtac (unfold_all ctxt (rel_OO_Grp_of_bnf bnf) RS @{thm vimage2p_cong} RS trans) THEN'
SELECT_GOAL (unfold_thms_tac ctxt [o_apply,
type_definition RS @{thm type_copy_vimage2p_Grp_Rep},
type_definition RS @{thm vimage2p_relcompp_converse}]) THEN' rtac refl) 1;
val tacs = zip_axioms map_id0_tac map_comp0_tac map_cong0_tac
(map set_map0_tac (set_map0_of_bnf bnf)) (K (rtac bd_card_order 1)) (K (rtac bd_cinfinite 1))
set_bd_tacs le_rel_OO_tac rel_OO_Grp_tac;
val bnf_wits = map (fn (I, t) =>
fold Term.absdummy (map (nth As) I)
(AbsA $ Term.list_comb (t, map Bound (0 upto length I - 1))))
(mk_wits_of_bnf (replicate nwits Ds) (replicate nwits As) bnf);
fun wit_tac ctxt = ALLGOALS (dtac (type_definition RS @{thm type_copy_wit})) THEN
mk_simple_wit_tac (map (unfold_all ctxt) (wit_thms_of_bnf bnf));
val (bnf', lthy') =
bnf_def Hardly_Inline (user_policy Dont_Note) qualify tacs wit_tac (SOME all_deads)
Binding.empty Binding.empty []
((((((b, TA), bnf_map), bnf_sets), bnf_bd'), bnf_wits), SOME bnf_rel) lthy;
in
((bnf', (all_deads, absT_info)), lthy')
end;
exception BAD_DEAD of typ * typ;
fun bnf_of_typ _ _ _ _ Ds0 (T as TFree T') accum =
(if member (op =) Ds0 T' then (DEADID_bnf, ([T], [])) else (ID_bnf, ([], [T])), accum)
| bnf_of_typ _ _ _ _ _ (TVar _) _ = error "Unexpected schematic variable"
| bnf_of_typ const_policy qualify' sort Xs Ds0 (T as Type (C, Ts)) (accum as (_, lthy)) =
let
fun check_bad_dead ((_, (deads, _)), _) =
let val Ds = fold Term.add_tfreesT deads [] in
(case Library.inter (op =) Ds Xs of [] => ()
| X :: _ => raise BAD_DEAD (TFree X, T))
end;
val tfrees = subtract (op =) Ds0 (Term.add_tfreesT T []);
val bnf_opt = if null tfrees then NONE else bnf_of lthy C;
in
(case bnf_opt of
NONE => ((DEADID_bnf, ([T], [])), accum)
| SOME bnf =>
if forall (can Term.dest_TFree) Ts andalso length Ts = length tfrees then
let
val T' = T_of_bnf bnf;
val deads = deads_of_bnf bnf;
val lives = lives_of_bnf bnf;
val tvars' = Term.add_tvarsT T' [];
val Ds_As =
pairself (map (Term.typ_subst_TVars (map fst tvars' ~~ map TFree tfrees)))
(deads, lives);
in ((bnf, Ds_As), accum) end
else
let
val name = Long_Name.base_name C;
fun qualify i =
let val namei = name ^ nonzero_string_of_int i;
in qualify' o Binding.qualify true namei end;
val odead = dead_of_bnf bnf;
val olive = live_of_bnf bnf;
val oDs_pos = find_indices op = [TFree ("dead", [])] (snd (Term.dest_Type
(mk_T_of_bnf (replicate odead (TFree ("dead", []))) (replicate olive dummyT) bnf)));
val oDs = map (nth Ts) oDs_pos;
val Ts' = map (nth Ts) (subtract (op =) oDs_pos (0 upto length Ts - 1));
val ((inners, (Dss, Ass)), (accum', lthy')) =
apfst (apsnd split_list o split_list)
(fold_map2 (fn i => bnf_of_typ Smart_Inline (qualify i) sort Xs Ds0)
(if length Ts' = 1 then [0] else (1 upto length Ts')) Ts' accum);
in
compose_bnf const_policy qualify sort bnf inners oDs Dss Ass (accum', lthy')
end)
|> tap check_bad_dead
end;
end;