(* Title: HOL/Codatatype/Tools/bnf_lfp.ML
Author: Dmitriy Traytel, TU Muenchen
Author: Andrei Popescu, TU Muenchen
Copyright 2012
Datatype construction.
*)
signature BNF_LFP =
sig
val bnf_lfp: binding list -> typ list list -> BNF_Def.BNF list -> local_theory ->
(term list * term list * thm list * thm list * thm list) * local_theory
end;
structure BNF_LFP : BNF_LFP =
struct
open BNF_Def
open BNF_Util
open BNF_Tactics
open BNF_FP_Util
open BNF_LFP_Util
open BNF_LFP_Tactics
(*all bnfs have the same lives*)
fun bnf_lfp bs Dss_insts bnfs lthy =
let
val timer = time (Timer.startRealTimer ());
val live = live_of_bnf (hd bnfs)
val n = length bnfs; (*active*)
val ks = 1 upto n
val m = live - n (*passive, if 0 don't generate a new bnf*)
val b = Binding.name (fold_rev (fn b => fn s => Binding.name_of b ^ s) bs "");
(* TODO: check if m, n etc are sane *)
val Dss = map (fn Ds => map TFree (fold Term.add_tfreesT Ds [])) Dss_insts;
val deads = distinct (op =) (flat Dss);
val names_lthy = fold Variable.declare_typ deads lthy;
(* tvars *)
val (((((((passiveAs, activeAs), allAs)), (passiveBs, activeBs)),
activeCs), passiveXs), passiveYs) = names_lthy
|> mk_TFrees live
|> apfst (`(chop m))
||> mk_TFrees live
||>> apfst (chop m)
||>> mk_TFrees n
||>> mk_TFrees m
||> fst o mk_TFrees m;
val Ass = replicate n allAs;
val allBs = passiveAs @ activeBs;
val Bss = replicate n allBs;
val allCs = passiveAs @ activeCs;
val allCs' = passiveBs @ activeCs;
val Css' = replicate n allCs';
(* typs *)
fun mk_FTs Ts = map2 (fn Ds => mk_T_of_bnf Ds Ts) Dss bnfs;
val (params, params') = `(map Term.dest_TFree) (deads @ passiveAs);
val FTsAs = mk_FTs allAs;
val FTsBs = mk_FTs allBs;
val FTsCs = mk_FTs allCs;
val ATs = map HOLogic.mk_setT passiveAs;
val BTs = map HOLogic.mk_setT activeAs;
val B'Ts = map HOLogic.mk_setT activeBs;
val B''Ts = map HOLogic.mk_setT activeCs;
val sTs = map2 (curry (op -->)) FTsAs activeAs;
val s'Ts = map2 (curry (op -->)) FTsBs activeBs;
val s''Ts = map2 (curry (op -->)) FTsCs activeCs;
val fTs = map2 (curry (op -->)) activeAs activeBs;
val inv_fTs = map2 (curry (op -->)) activeBs activeAs;
val self_fTs = map2 (curry (op -->)) activeAs activeAs;
val gTs = map2 (curry (op -->)) activeBs activeCs;
val all_gTs = map2 (curry (op -->)) allBs allCs';
val prodBsAs = map2 (curry HOLogic.mk_prodT) activeBs activeAs;
val prodFTs = mk_FTs (passiveAs @ prodBsAs);
val prod_sTs = map2 (curry (op -->)) prodFTs activeAs;
(* terms *)
val mapsAsAs = map4 mk_map_of_bnf Dss Ass Ass bnfs;
val mapsAsBs = map4 mk_map_of_bnf Dss Ass Bss bnfs;
val mapsBsAs = map4 mk_map_of_bnf Dss Bss Ass bnfs;
val mapsBsCs' = map4 mk_map_of_bnf Dss Bss Css' bnfs;
val mapsAsCs' = map4 mk_map_of_bnf Dss Ass Css' bnfs;
val map_fsts = map4 mk_map_of_bnf Dss (replicate n (passiveAs @ prodBsAs)) Bss bnfs;
val map_fsts_rev = map4 mk_map_of_bnf Dss Bss (replicate n (passiveAs @ prodBsAs)) bnfs;
fun mk_setss Ts = map3 mk_sets_of_bnf (map (replicate live) Dss)
(map (replicate live) (replicate n Ts)) bnfs;
val setssAs = mk_setss allAs;
val bds = map3 mk_bd_of_bnf Dss Ass bnfs;
val witss = map wits_of_bnf bnfs;
val (((((((((((((((((((zs, zs'), As), Bs), Bs_copy), B's), B''s), ss), prod_ss), s's), s''s),
fs), fs_copy), inv_fs), self_fs), gs), all_gs), (xFs, xFs')), (yFs, yFs')),
names_lthy) = lthy
|> mk_Frees' "z" activeAs
||>> mk_Frees "A" ATs
||>> mk_Frees "B" BTs
||>> mk_Frees "B" BTs
||>> mk_Frees "B'" B'Ts
||>> mk_Frees "B''" B''Ts
||>> mk_Frees "s" sTs
||>> mk_Frees "prods" prod_sTs
||>> mk_Frees "s'" s'Ts
||>> mk_Frees "s''" s''Ts
||>> mk_Frees "f" fTs
||>> mk_Frees "f" fTs
||>> mk_Frees "f" inv_fTs
||>> mk_Frees "f" self_fTs
||>> mk_Frees "g" gTs
||>> mk_Frees "g" all_gTs
||>> mk_Frees' "x" FTsAs
||>> mk_Frees' "y" FTsBs;
val passive_UNIVs = map HOLogic.mk_UNIV passiveAs;
val active_UNIVs = map HOLogic.mk_UNIV activeAs;
val prod_UNIVs = map HOLogic.mk_UNIV prodBsAs;
val passive_ids = map HOLogic.id_const passiveAs;
val active_ids = map HOLogic.id_const activeAs;
val fsts = map fst_const prodBsAs;
(* thms *)
val bd_card_orders = map bd_card_order_of_bnf bnfs;
val bd_Card_orders = map bd_Card_order_of_bnf bnfs;
val bd_Card_order = hd bd_Card_orders;
val bd_Cinfinite = bd_Cinfinite_of_bnf (hd bnfs);
val bd_Cnotzeros = map bd_Cnotzero_of_bnf bnfs;
val bd_Cnotzero = hd bd_Cnotzeros;
val in_bds = map in_bd_of_bnf bnfs;
val map_comp's = map map_comp'_of_bnf bnfs;
val map_congs = map map_cong_of_bnf bnfs;
val map_ids = map map_id_of_bnf bnfs;
val map_id's = map map_id'_of_bnf bnfs;
val map_wpulls = map map_wpull_of_bnf bnfs;
val set_bdss = map set_bd_of_bnf bnfs;
val set_natural'ss = map set_natural'_of_bnf bnfs;
val timer = time (timer "Extracted terms & thms");
(* nonemptiness check *)
fun new_wit X wit = subset (op =) (#I wit, (0 upto m - 1) @ map snd X);
fun enrich X = map_filter (fn i =>
(case find_first (fn (_, i') => i = i') X of
NONE =>
(case find_index (new_wit X) (nth witss (i - m)) of
~1 => NONE
| j => SOME (j, i))
| SOME ji => SOME ji)) (m upto m + n - 1);
val reachable = fixpoint (op =) enrich [];
val _ = if map snd reachable = (m upto m + n - 1) then ()
else error "The datatype could not be generated because nonemptiness could not be proved";
val wit_thms =
flat (map2 (fn bnf => fn (j, _) => nth (wit_thmss_of_bnf bnf) j) bnfs reachable);
val timer = time (timer "Checked nonemptiness");
(* derived thms *)
(*map g1 ... gm g(m+1) ... g(m+n) (map id ... id f(m+1) ... f(m+n) x)=
map g1 ... gm (g(m+1) o f(m+1)) ... (g(m+n) o f(m+n)) x*)
fun mk_map_comp_id x mapAsBs mapBsCs mapAsCs map_comp =
let
val lhs = Term.list_comb (mapBsCs, all_gs) $
(Term.list_comb (mapAsBs, passive_ids @ fs) $ x);
val rhs = Term.list_comb (mapAsCs,
take m all_gs @ map HOLogic.mk_comp (drop m all_gs ~~ fs)) $ x;
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (x :: fs @ all_gs) (mk_Trueprop_eq (lhs, rhs)))
(K (mk_map_comp_id_tac map_comp))
|> Thm.close_derivation
end;
val map_comp_id_thms = map5 mk_map_comp_id xFs mapsAsBs mapsBsCs' mapsAsCs' map_comp's;
(*forall a : set(m+1) x. f(m+1) a = a; ...; forall a : set(m+n) x. f(m+n) a = a ==>
map id ... id f(m+1) ... f(m+n) x = x*)
fun mk_map_congL x mapAsAs sets map_cong map_id' =
let
fun mk_prem set f z z' = HOLogic.mk_Trueprop
(mk_Ball (set $ x) (Term.absfree z' (HOLogic.mk_eq (f $ z, z))));
val prems = map4 mk_prem (drop m sets) self_fs zs zs';
val goal = mk_Trueprop_eq (Term.list_comb (mapAsAs, passive_ids @ self_fs) $ x, x);
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (x :: self_fs) (Logic.list_implies (prems, goal)))
(K (mk_map_congL_tac m map_cong map_id'))
|> Thm.close_derivation
end;
val map_congL_thms = map5 mk_map_congL xFs mapsAsAs setssAs map_congs map_id's;
val in_mono'_thms = map (fn bnf => in_mono_of_bnf bnf OF (replicate m subset_refl)) bnfs
val in_cong'_thms = map (fn bnf => in_cong_of_bnf bnf OF (replicate m refl)) bnfs
val timer = time (timer "Derived simple theorems");
(* algebra *)
val alg_bind = Binding.suffix_name ("_" ^ algN) b;
val alg_name = Binding.name_of alg_bind;
val alg_def_bind = (Thm.def_binding alg_bind, []);
(*forall i = 1 ... n: (\<forall>x \<in> Fi_in A1 .. Am B1 ... Bn. si x \<in> Bi)*)
val alg_spec =
let
val algT = Library.foldr (op -->) (ATs @ BTs @ sTs, HOLogic.boolT);
val ins = map3 mk_in (replicate n (As @ Bs)) setssAs FTsAs;
fun mk_alg_conjunct B s X x x' =
mk_Ball X (Term.absfree x' (HOLogic.mk_mem (s $ x, B)));
val lhs = Term.list_comb (Free (alg_name, algT), As @ Bs @ ss);
val rhs = Library.foldr1 HOLogic.mk_conj (map5 mk_alg_conjunct Bs ss ins xFs xFs')
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((alg_free, (_, alg_def_free)), (lthy, lthy_old)) =
lthy
|> Specification.definition (SOME (alg_bind, NONE, NoSyn), (alg_def_bind, alg_spec))
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
val alg = fst (Term.dest_Const (Morphism.term phi alg_free));
val alg_def = Morphism.thm phi alg_def_free;
fun mk_alg As Bs ss =
let
val args = As @ Bs @ ss;
val Ts = map fastype_of args;
val algT = Library.foldr (op -->) (Ts, HOLogic.boolT);
in
Term.list_comb (Const (alg, algT), args)
end;
val alg_set_thms =
let
val alg_prem = HOLogic.mk_Trueprop (mk_alg As Bs ss);
fun mk_prem x set B = HOLogic.mk_Trueprop (mk_subset (set $ x) B);
fun mk_concl s x B = HOLogic.mk_Trueprop (HOLogic.mk_mem (s $ x, B));
val premss = map2 ((fn x => fn sets => map2 (mk_prem x) sets (As @ Bs))) xFs setssAs;
val concls = map3 mk_concl ss xFs Bs;
val goals = map3 (fn x => fn prems => fn concl =>
fold_rev Logic.all (x :: As @ Bs @ ss)
(Logic.list_implies (alg_prem :: prems, concl))) xFs premss concls;
in
map (fn goal =>
Skip_Proof.prove lthy [] [] goal (K (mk_alg_set_tac alg_def)) |> Thm.close_derivation)
goals
end;
fun mk_talg ATs BTs = mk_alg (map HOLogic.mk_UNIV ATs) (map HOLogic.mk_UNIV BTs);
val talg_thm =
let
val goal = fold_rev Logic.all ss
(HOLogic.mk_Trueprop (mk_talg passiveAs activeAs ss))
in
Skip_Proof.prove lthy [] [] goal
(K (stac alg_def 1 THEN CONJ_WRAP (K (EVERY' [rtac ballI, rtac UNIV_I] 1)) ss))
|> Thm.close_derivation
end;
val timer = time (timer "Algebra definition & thms");
val alg_not_empty_thms =
let
val alg_prem =
HOLogic.mk_Trueprop (mk_alg passive_UNIVs Bs ss);
val concls = map (HOLogic.mk_Trueprop o mk_not_empty) Bs;
val goals =
map (fn concl =>
fold_rev Logic.all (Bs @ ss) (Logic.mk_implies (alg_prem, concl))) concls;
in
map2 (fn goal => fn alg_set =>
Skip_Proof.prove lthy [] []
goal (K (mk_alg_not_empty_tac alg_set alg_set_thms wit_thms))
|> Thm.close_derivation)
goals alg_set_thms
end;
val timer = time (timer "Proved nonemptiness");
(* morphism *)
val mor_bind = Binding.suffix_name ("_" ^ morN) b;
val mor_name = Binding.name_of mor_bind;
val mor_def_bind = (Thm.def_binding mor_bind, []);
(*fbetw) forall i = 1 ... n: (\<forall>x \<in> Bi. f x \<in> B'i)*)
(*mor) forall i = 1 ... n: (\<forall>x \<in> Fi_in UNIV ... UNIV B1 ... Bn.
f (s1 x) = s1' (Fi_map id ... id f1 ... fn x))*)
val mor_spec =
let
val morT = Library.foldr (op -->) (BTs @ sTs @ B'Ts @ s'Ts @ fTs, HOLogic.boolT);
fun mk_fbetw f B1 B2 z z' =
mk_Ball B1 (Term.absfree z' (HOLogic.mk_mem (f $ z, B2)));
fun mk_mor sets mapAsBs f s s' T x x' =
mk_Ball (mk_in (passive_UNIVs @ Bs) sets T)
(Term.absfree x' (HOLogic.mk_eq (f $ (s $ x), s' $
(Term.list_comb (mapAsBs, passive_ids @ fs) $ x))));
val lhs = Term.list_comb (Free (mor_name, morT), Bs @ ss @ B's @ s's @ fs);
val rhs = HOLogic.mk_conj
(Library.foldr1 HOLogic.mk_conj (map5 mk_fbetw fs Bs B's zs zs'),
Library.foldr1 HOLogic.mk_conj
(map8 mk_mor setssAs mapsAsBs fs ss s's FTsAs xFs xFs'))
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((mor_free, (_, mor_def_free)), (lthy, lthy_old)) =
lthy
|> Specification.definition (SOME (mor_bind, NONE, NoSyn), (mor_def_bind, mor_spec))
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
val mor = fst (Term.dest_Const (Morphism.term phi mor_free));
val mor_def = Morphism.thm phi mor_def_free;
fun mk_mor Bs1 ss1 Bs2 ss2 fs =
let
val args = Bs1 @ ss1 @ Bs2 @ ss2 @ fs;
val Ts = map fastype_of (Bs1 @ ss1 @ Bs2 @ ss2 @ fs);
val morT = Library.foldr (op -->) (Ts, HOLogic.boolT);
in
Term.list_comb (Const (mor, morT), args)
end;
val (mor_image_thms, morE_thms) =
let
val prem = HOLogic.mk_Trueprop (mk_mor Bs ss B's s's fs);
fun mk_image_goal f B1 B2 = fold_rev Logic.all (Bs @ ss @ B's @ s's @ fs)
(Logic.mk_implies (prem, HOLogic.mk_Trueprop (mk_subset (mk_image f $ B1) B2)));
val image_goals = map3 mk_image_goal fs Bs B's;
fun mk_elim_prem sets x T = HOLogic.mk_Trueprop
(HOLogic.mk_mem (x, mk_in (passive_UNIVs @ Bs) sets T));
fun mk_elim_goal sets mapAsBs f s s' x T =
fold_rev Logic.all (x :: Bs @ ss @ B's @ s's @ fs)
(Logic.list_implies ([prem, mk_elim_prem sets x T],
mk_Trueprop_eq (f $ (s $ x), s' $ Term.list_comb (mapAsBs, passive_ids @ fs @ [x]))));
val elim_goals = map7 mk_elim_goal setssAs mapsAsBs fs ss s's xFs FTsAs;
fun prove goal =
Skip_Proof.prove lthy [] [] goal (K (mk_mor_elim_tac mor_def)) |> Thm.close_derivation;
in
(map prove image_goals, map prove elim_goals)
end;
val mor_incl_thm =
let
val prems = map2 (HOLogic.mk_Trueprop oo mk_subset) Bs Bs_copy;
val concl = HOLogic.mk_Trueprop (mk_mor Bs ss Bs_copy ss active_ids);
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ Bs_copy) (Logic.list_implies (prems, concl)))
(K (mk_mor_incl_tac mor_def map_id's))
|> Thm.close_derivation
end;
val mor_comp_thm =
let
val prems =
[HOLogic.mk_Trueprop (mk_mor Bs ss B's s's fs),
HOLogic.mk_Trueprop (mk_mor B's s's B''s s''s gs)];
val concl =
HOLogic.mk_Trueprop (mk_mor Bs ss B''s s''s (map2 (curry HOLogic.mk_comp) gs fs));
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ B's @ s's @ B''s @ s''s @ fs @ gs)
(Logic.list_implies (prems, concl)))
(K (mk_mor_comp_tac mor_def set_natural'ss map_comp_id_thms))
|> Thm.close_derivation
end;
val mor_inv_thm =
let
fun mk_inv_prem f inv_f B B' = HOLogic.mk_conj (mk_subset (mk_image inv_f $ B') B,
HOLogic.mk_conj (mk_inver inv_f f B, mk_inver f inv_f B'));
val prems = map HOLogic.mk_Trueprop
([mk_mor Bs ss B's s's fs,
mk_alg passive_UNIVs Bs ss,
mk_alg passive_UNIVs B's s's] @
map4 mk_inv_prem fs inv_fs Bs B's);
val concl = HOLogic.mk_Trueprop (mk_mor B's s's Bs ss inv_fs);
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ B's @ s's @ fs @ inv_fs)
(Logic.list_implies (prems, concl)))
(K (mk_mor_inv_tac alg_def mor_def
set_natural'ss morE_thms map_comp_id_thms map_congL_thms))
|> Thm.close_derivation
end;
val mor_cong_thm =
let
val prems = map HOLogic.mk_Trueprop
(map2 (curry HOLogic.mk_eq) fs_copy fs @ [mk_mor Bs ss B's s's fs])
val concl = HOLogic.mk_Trueprop (mk_mor Bs ss B's s's fs_copy);
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ B's @ s's @ fs @ fs_copy)
(Logic.list_implies (prems, concl)))
(K ((hyp_subst_tac THEN' atac) 1))
|> Thm.close_derivation
end;
val mor_str_thm =
let
val maps = map2 (fn Ds => fn bnf => Term.list_comb
(mk_map_of_bnf Ds (passiveAs @ FTsAs) allAs bnf, passive_ids @ ss)) Dss bnfs;
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all ss (HOLogic.mk_Trueprop
(mk_mor (map HOLogic.mk_UNIV FTsAs) maps active_UNIVs ss ss)))
(K (mk_mor_str_tac ks mor_def))
|> Thm.close_derivation
end;
val mor_convol_thm =
let
val maps = map3 (fn s => fn prod_s => fn map =>
mk_convol (HOLogic.mk_comp (s, Term.list_comb (map, passive_ids @ fsts)), prod_s))
s's prod_ss map_fsts;
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (s's @ prod_ss) (HOLogic.mk_Trueprop
(mk_mor prod_UNIVs maps (map HOLogic.mk_UNIV activeBs) s's fsts)))
(K (mk_mor_convol_tac ks mor_def))
|> Thm.close_derivation
end;
val mor_UNIV_thm =
let
fun mk_conjunct mapAsBs f s s' = HOLogic.mk_eq
(HOLogic.mk_comp (f, s),
HOLogic.mk_comp (s', Term.list_comb (mapAsBs, passive_ids @ fs)));
val lhs = mk_mor active_UNIVs ss (map HOLogic.mk_UNIV activeBs) s's fs;
val rhs = Library.foldr1 HOLogic.mk_conj (map4 mk_conjunct mapsAsBs fs ss s's);
in
Skip_Proof.prove lthy [] [] (fold_rev Logic.all (ss @ s's @ fs) (mk_Trueprop_eq (lhs, rhs)))
(K (mk_mor_UNIV_tac m morE_thms mor_def))
|> Thm.close_derivation
end;
val timer = time (timer "Morphism definition & thms");
(* isomorphism *)
(*mor Bs1 ss1 Bs2 ss2 fs \<and> (\<exists>gs. mor Bs2 ss2 Bs1 ss1 fs \<and>
forall i = 1 ... n. (inver gs[i] fs[i] Bs1[i] \<and> inver fs[i] gs[i] Bs2[i]))*)
fun mk_iso Bs1 ss1 Bs2 ss2 fs gs =
let
val ex_inv_mor = list_exists_free gs
(HOLogic.mk_conj (mk_mor Bs2 ss2 Bs1 ss1 gs,
Library.foldr1 HOLogic.mk_conj (map2 (curry HOLogic.mk_conj)
(map3 mk_inver gs fs Bs1) (map3 mk_inver fs gs Bs2))));
in
HOLogic.mk_conj (mk_mor Bs1 ss1 Bs2 ss2 fs, ex_inv_mor)
end;
val iso_alt_thm =
let
val prems = map HOLogic.mk_Trueprop
[mk_alg passive_UNIVs Bs ss,
mk_alg passive_UNIVs B's s's]
val concl = mk_Trueprop_eq (mk_iso Bs ss B's s's fs inv_fs,
HOLogic.mk_conj (mk_mor Bs ss B's s's fs,
Library.foldr1 HOLogic.mk_conj (map3 mk_bij_betw fs Bs B's)));
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ B's @ s's @ fs) (Logic.list_implies (prems, concl)))
(K (mk_iso_alt_tac mor_image_thms mor_inv_thm))
|> Thm.close_derivation
end;
val timer = time (timer "Isomorphism definition & thms");
(* algebra copies *)
val (copy_alg_thm, ex_copy_alg_thm) =
let
val prems = map HOLogic.mk_Trueprop
(mk_alg passive_UNIVs Bs ss :: map3 mk_bij_betw inv_fs B's Bs);
val inver_prems = map HOLogic.mk_Trueprop
(map3 mk_inver inv_fs fs Bs @ map3 mk_inver fs inv_fs B's);
val all_prems = prems @ inver_prems;
fun mk_s f s mapT y y' = Term.absfree y' (f $ (s $
(Term.list_comb (mapT, passive_ids @ inv_fs) $ y)));
val alg = HOLogic.mk_Trueprop
(mk_alg passive_UNIVs B's (map5 mk_s fs ss mapsBsAs yFs yFs'));
val copy_str_thm = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ B's @ inv_fs @ fs)
(Logic.list_implies (all_prems, alg)))
(K (mk_copy_str_tac set_natural'ss alg_def alg_set_thms))
|> Thm.close_derivation;
val iso = HOLogic.mk_Trueprop
(mk_iso B's (map5 mk_s fs ss mapsBsAs yFs yFs') Bs ss inv_fs fs_copy);
val copy_alg_thm = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ B's @ inv_fs @ fs)
(Logic.list_implies (all_prems, iso)))
(K (mk_copy_alg_tac set_natural'ss alg_set_thms mor_def iso_alt_thm copy_str_thm))
|> Thm.close_derivation;
val ex = HOLogic.mk_Trueprop
(list_exists_free s's
(HOLogic.mk_conj (mk_alg passive_UNIVs B's s's,
mk_iso B's s's Bs ss inv_fs fs_copy)));
val ex_copy_alg_thm = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss @ B's @ inv_fs @ fs)
(Logic.list_implies (prems, ex)))
(K (mk_ex_copy_alg_tac n copy_str_thm copy_alg_thm))
|> Thm.close_derivation;
in
(copy_alg_thm, ex_copy_alg_thm)
end;
val timer = time (timer "Copy thms");
(* bounds *)
val sum_Card_order = if n = 1 then bd_Card_order else @{thm Card_order_csum};
val sum_Cnotzero = if n = 1 then bd_Cnotzero else bd_Cnotzero RS @{thm csum_Cnotzero1};
val sum_Cinfinite = if n = 1 then bd_Cinfinite else bd_Cinfinite RS @{thm Cinfinite_csum1};
fun mk_set_bd_sums i bd_Card_order bds =
if n = 1 then bds
else map (fn thm => bd_Card_order RS mk_ordLeq_csum n i thm) bds;
val set_bd_sumss = map3 mk_set_bd_sums ks bd_Card_orders set_bdss;
fun mk_in_bd_sum i Co Cnz bd =
if n = 1 then bd
else Cnz RS ((Co RS mk_ordLeq_csum n i (Co RS @{thm ordLeq_refl})) RS
(bd RS @{thm ordLeq_transitive[OF _
cexp_mono2_Cnotzero[OF _ csum_Cnotzero2[OF ctwo_Cnotzero]]]}));
val in_bd_sums = map4 mk_in_bd_sum ks bd_Card_orders bd_Cnotzeros in_bds;
val sum_bd = Library.foldr1 (uncurry mk_csum) bds;
val suc_bd = mk_cardSuc sum_bd;
val field_suc_bd = mk_Field suc_bd;
val suc_bdT = fst (dest_relT (fastype_of suc_bd));
fun mk_Asuc_bd [] = mk_cexp ctwo suc_bd
| mk_Asuc_bd As =
mk_cexp (mk_csum (Library.foldr1 (uncurry mk_csum) (map mk_card_of As)) ctwo) suc_bd;
val suc_bd_Card_order = if n = 1 then bd_Card_order RS @{thm cardSuc_Card_order}
else @{thm cardSuc_Card_order[OF Card_order_csum]};
val suc_bd_Cinfinite = if n = 1 then bd_Cinfinite RS @{thm Cinfinite_cardSuc}
else bd_Cinfinite RS @{thm Cinfinite_cardSuc[OF Cinfinite_csum1]};
val suc_bd_Cnotzero = suc_bd_Cinfinite RS @{thm Cinfinite_Cnotzero};
val suc_bd_worel = suc_bd_Card_order RS @{thm Card_order_wo_rel}
val basis_Asuc = if m = 0 then @{thm ordLeq_refl[OF Card_order_ctwo]}
else @{thm ordLeq_csum2[OF Card_order_ctwo]};
val Asuc_bd_Cinfinite = suc_bd_Cinfinite RS (basis_Asuc RS @{thm Cinfinite_cexp});
val Asuc_bd_Cnotzero = Asuc_bd_Cinfinite RS @{thm Cinfinite_Cnotzero};
val suc_bd_Asuc_bd = @{thm ordLess_ordLeq_trans[OF
ordLess_ctwo_cexp
cexp_mono1_Cnotzero[OF _ ctwo_Cnotzero]]} OF
[suc_bd_Card_order, basis_Asuc, suc_bd_Card_order];
val Asuc_bdT = fst (dest_relT (fastype_of (mk_Asuc_bd As)));
val II_BTs = replicate n (HOLogic.mk_setT Asuc_bdT);
val II_sTs = map2 (fn Ds => fn bnf =>
mk_T_of_bnf Ds (passiveAs @ replicate n Asuc_bdT) bnf --> Asuc_bdT) Dss bnfs;
val (((((((idxs, Asi_name), (idx, idx')), (jdx, jdx')), II_Bs), II_ss), Asuc_fs),
names_lthy) = names_lthy
|> mk_Frees "i" (replicate n suc_bdT)
||>> (fn ctxt => apfst the_single (mk_fresh_names ctxt 1 "Asi"))
||>> yield_singleton (apfst (op ~~) oo mk_Frees' "i") suc_bdT
||>> yield_singleton (apfst (op ~~) oo mk_Frees' "j") suc_bdT
||>> mk_Frees "IIB" II_BTs
||>> mk_Frees "IIs" II_sTs
||>> mk_Frees "f" (map (fn T => Asuc_bdT --> T) activeAs);
val suc_bd_limit_thm =
let
val prem = HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map (fn idx => HOLogic.mk_mem (idx, field_suc_bd)) idxs));
fun mk_conjunct idx = HOLogic.mk_conj (mk_not_eq idx jdx,
HOLogic.mk_mem (HOLogic.mk_prod (idx, jdx), suc_bd));
val concl = HOLogic.mk_Trueprop (mk_Bex field_suc_bd
(Term.absfree jdx' (Library.foldr1 HOLogic.mk_conj (map mk_conjunct idxs))));
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all idxs (Logic.list_implies ([prem], concl)))
(K (mk_bd_limit_tac n suc_bd_Cinfinite))
|> Thm.close_derivation
end;
val timer = time (timer "Bounds");
(* minimal algebra *)
fun mk_minG Asi i k = mk_UNION (mk_underS suc_bd $ i)
(Term.absfree jdx' (mk_nthN n (Asi $ jdx) k));
fun mk_minH_component As Asi i sets Ts s k =
HOLogic.mk_binop @{const_name "sup"}
(mk_minG Asi i k, mk_image s $ mk_in (As @ map (mk_minG Asi i) ks) sets Ts);
fun mk_min_algs As ss =
let
val BTs = map (range_type o fastype_of) ss;
val Ts = map (HOLogic.dest_setT o fastype_of) As @ BTs;
val (Asi, Asi') = `Free (Asi_name, suc_bdT -->
Library.foldr1 HOLogic.mk_prodT (map HOLogic.mk_setT BTs));
in
mk_worec suc_bd (Term.absfree Asi' (Term.absfree idx' (HOLogic.mk_tuple
(map4 (mk_minH_component As Asi idx) (mk_setss Ts) (mk_FTs Ts) ss ks))))
end;
val (min_algs_thms, min_algs_mono_thms, card_of_min_algs_thm, least_min_algs_thm) =
let
val i_field = HOLogic.mk_mem (idx, field_suc_bd);
val min_algs = mk_min_algs As ss;
val min_algss = map (fn k => mk_nthN n (min_algs $ idx) k) ks;
val concl = HOLogic.mk_Trueprop
(HOLogic.mk_eq (min_algs $ idx, HOLogic.mk_tuple
(map4 (mk_minH_component As min_algs idx) setssAs FTsAs ss ks)));
val goal = fold_rev Logic.all (idx :: As @ ss)
(Logic.mk_implies (HOLogic.mk_Trueprop i_field, concl));
val min_algs_thm = Skip_Proof.prove lthy [] [] goal
(K (mk_min_algs_tac suc_bd_worel in_cong'_thms))
|> Thm.close_derivation;
val min_algs_thms = map (fn k => min_algs_thm RS mk_nthI n k) ks;
fun mk_mono_goal min_alg =
fold_rev Logic.all (As @ ss) (HOLogic.mk_Trueprop (mk_relChain suc_bd
(Term.absfree idx' min_alg)));
val monos =
map2 (fn goal => fn min_algs =>
Skip_Proof.prove lthy [] [] goal (K (mk_min_algs_mono_tac min_algs))
|> Thm.close_derivation)
(map mk_mono_goal min_algss) min_algs_thms;
val Asuc_bd = mk_Asuc_bd As;
fun mk_card_conjunct min_alg = mk_ordLeq (mk_card_of min_alg) Asuc_bd;
val card_conjunction = Library.foldr1 HOLogic.mk_conj (map mk_card_conjunct min_algss);
val card_cT = certifyT lthy suc_bdT;
val card_ct = certify lthy (Term.absfree idx' card_conjunction);
val card_of = singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] []
(HOLogic.mk_Trueprop (HOLogic.mk_imp (i_field, card_conjunction)))
(K (mk_min_algs_card_of_tac card_cT card_ct
m suc_bd_worel min_algs_thms in_bd_sums
sum_Card_order sum_Cnotzero suc_bd_Card_order suc_bd_Cinfinite suc_bd_Cnotzero
suc_bd_Asuc_bd Asuc_bd_Cinfinite Asuc_bd_Cnotzero)))
|> Thm.close_derivation;
val least_prem = HOLogic.mk_Trueprop (mk_alg As Bs ss);
val least_conjunction = Library.foldr1 HOLogic.mk_conj (map2 mk_subset min_algss Bs);
val least_cT = certifyT lthy suc_bdT;
val least_ct = certify lthy (Term.absfree idx' least_conjunction);
val least = singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] []
(Logic.mk_implies (least_prem,
HOLogic.mk_Trueprop (HOLogic.mk_imp (i_field, least_conjunction))))
(K (mk_min_algs_least_tac least_cT least_ct
suc_bd_worel min_algs_thms alg_set_thms)))
|> Thm.close_derivation;
in
(min_algs_thms, monos, card_of, least)
end;
val timer = time (timer "min_algs definition & thms");
fun min_alg_bind i = Binding.suffix_name
("_" ^ min_algN ^ (if n = 1 then "" else string_of_int i)) b;
val min_alg_name = Binding.name_of o min_alg_bind;
val min_alg_def_bind = rpair [] o Thm.def_binding o min_alg_bind;
fun min_alg_spec i =
let
val min_algT =
Library.foldr (op -->) (ATs @ sTs, HOLogic.mk_setT (nth activeAs (i - 1)));
val lhs = Term.list_comb (Free (min_alg_name i, min_algT), As @ ss);
val rhs = mk_UNION (field_suc_bd)
(Term.absfree idx' (mk_nthN n (mk_min_algs As ss $ idx) i));
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((min_alg_frees, (_, min_alg_def_frees)), (lthy, lthy_old)) =
lthy
|> fold_map (fn i => Specification.definition
(SOME (min_alg_bind i, NONE, NoSyn), (min_alg_def_bind i, min_alg_spec i))) ks
|>> apsnd split_list o split_list
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
val min_algs = map (fst o Term.dest_Const o Morphism.term phi) min_alg_frees;
val min_alg_defs = map (Morphism.thm phi) min_alg_def_frees;
fun mk_min_alg As ss i =
let
val T = HOLogic.mk_setT (range_type (fastype_of (nth ss (i - 1))))
val args = As @ ss;
val Ts = map fastype_of args;
val min_algT = Library.foldr (op -->) (Ts, T);
in
Term.list_comb (Const (nth min_algs (i - 1), min_algT), args)
end;
val (alg_min_alg_thm, card_of_min_alg_thms, least_min_alg_thms, mor_incl_min_alg_thm) =
let
val min_algs = map (mk_min_alg As ss) ks;
val goal = fold_rev Logic.all (As @ ss) (HOLogic.mk_Trueprop (mk_alg As min_algs ss));
val alg_min_alg = Skip_Proof.prove lthy [] [] goal
(K (mk_alg_min_alg_tac m alg_def min_alg_defs suc_bd_limit_thm sum_Cinfinite
set_bd_sumss min_algs_thms min_algs_mono_thms))
|> Thm.close_derivation;
val Asuc_bd = mk_Asuc_bd As;
fun mk_card_of_thm min_alg def = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (As @ ss)
(HOLogic.mk_Trueprop (mk_ordLeq (mk_card_of min_alg) Asuc_bd)))
(K (mk_card_of_min_alg_tac def card_of_min_algs_thm
suc_bd_Card_order suc_bd_Asuc_bd Asuc_bd_Cinfinite))
|> Thm.close_derivation;
val least_prem = HOLogic.mk_Trueprop (mk_alg As Bs ss);
fun mk_least_thm min_alg B def = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (As @ Bs @ ss)
(Logic.mk_implies (least_prem, HOLogic.mk_Trueprop (mk_subset min_alg B))))
(K (mk_least_min_alg_tac def least_min_algs_thm))
|> Thm.close_derivation;
val leasts = map3 mk_least_thm min_algs Bs min_alg_defs;
val incl_prem = HOLogic.mk_Trueprop (mk_alg passive_UNIVs Bs ss);
val incl_min_algs = map (mk_min_alg passive_UNIVs ss) ks;
val incl = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss)
(Logic.mk_implies (incl_prem,
HOLogic.mk_Trueprop (mk_mor incl_min_algs ss Bs ss active_ids))))
(K (EVERY' (rtac mor_incl_thm :: map etac leasts) 1))
|> Thm.close_derivation;
in
(alg_min_alg, map2 mk_card_of_thm min_algs min_alg_defs, leasts, incl)
end;
val timer = time (timer "Minimal algebra definition & thms");
val II_repT = HOLogic.mk_prodT (HOLogic.mk_tupleT II_BTs, HOLogic.mk_tupleT II_sTs);
val IIT_bind = Binding.suffix_name ("_" ^ IITN) b;
val ((IIT_name, (IIT_glob_info, IIT_loc_info)), lthy) =
typedef true NONE (IIT_bind, params, NoSyn)
(HOLogic.mk_UNIV II_repT) NONE (EVERY' [rtac exI, rtac UNIV_I] 1) lthy;
val IIT = Type (IIT_name, params');
val Abs_IIT = Const (#Abs_name IIT_glob_info, II_repT --> IIT);
val Rep_IIT = Const (#Rep_name IIT_glob_info, IIT --> II_repT);
val Abs_IIT_inverse_thm =
mk_Abs_inverse_thm (the (#set_def IIT_loc_info)) (#Abs_inverse IIT_loc_info);
val initT = IIT --> Asuc_bdT;
val active_initTs = replicate n initT;
val init_FTs = map2 (fn Ds => mk_T_of_bnf Ds (passiveAs @ active_initTs)) Dss bnfs;
val init_fTs = map (fn T => initT --> T) activeAs;
val (((((((iidx, iidx'), init_xs), (init_xFs, init_xFs')),
init_fs), init_fs_copy), init_phis), names_lthy) = names_lthy
|> yield_singleton (apfst (op ~~) oo mk_Frees' "i") IIT
||>> mk_Frees "ix" active_initTs
||>> mk_Frees' "x" init_FTs
||>> mk_Frees "f" init_fTs
||>> mk_Frees "f" init_fTs
||>> mk_Frees "phi" (replicate n (initT --> HOLogic.boolT));
val II = HOLogic.mk_Collect (fst iidx', IIT, list_exists_free (II_Bs @ II_ss)
(HOLogic.mk_conj (HOLogic.mk_eq (iidx,
Abs_IIT $ (HOLogic.mk_prod (HOLogic.mk_tuple II_Bs, HOLogic.mk_tuple II_ss))),
mk_alg passive_UNIVs II_Bs II_ss)));
val select_Bs = map (mk_nthN n (HOLogic.mk_fst (Rep_IIT $ iidx))) ks;
val select_ss = map (mk_nthN n (HOLogic.mk_snd (Rep_IIT $ iidx))) ks;
fun str_init_bind i = Binding.suffix_name ("_" ^ str_initN ^ (if n = 1 then "" else
string_of_int i)) b;
val str_init_name = Binding.name_of o str_init_bind;
val str_init_def_bind = rpair [] o Thm.def_binding o str_init_bind;
fun str_init_spec i =
let
val T = nth init_FTs (i - 1);
val init_xF = nth init_xFs (i - 1)
val select_s = nth select_ss (i - 1);
val map = mk_map_of_bnf (nth Dss (i - 1))
(passiveAs @ active_initTs) (passiveAs @ replicate n Asuc_bdT)
(nth bnfs (i - 1));
val map_args = passive_ids @ replicate n (mk_rapp iidx Asuc_bdT);
val str_initT = T --> IIT --> Asuc_bdT;
val lhs = Term.list_comb (Free (str_init_name i, str_initT), [init_xF, iidx]);
val rhs = select_s $ (Term.list_comb (map, map_args) $ init_xF);
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((str_init_frees, (_, str_init_def_frees)), (lthy, lthy_old)) =
lthy
|> fold_map (fn i => Specification.definition
(SOME (str_init_bind i, NONE, NoSyn), (str_init_def_bind i, str_init_spec i))) ks
|>> apsnd split_list o split_list
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
val str_inits =
map (Term.subst_atomic_types (map (`(Morphism.typ phi)) params') o Morphism.term phi)
str_init_frees;
val str_init_defs = map (Morphism.thm phi) str_init_def_frees;
val car_inits = map (mk_min_alg passive_UNIVs str_inits) ks;
(*TODO: replace with instantiate? (problem: figure out right type instantiation)*)
val alg_init_thm = Skip_Proof.prove lthy [] []
(HOLogic.mk_Trueprop (mk_alg passive_UNIVs car_inits str_inits))
(K (rtac alg_min_alg_thm 1))
|> Thm.close_derivation;
val alg_select_thm = Skip_Proof.prove lthy [] []
(HOLogic.mk_Trueprop (mk_Ball II
(Term.absfree iidx' (mk_alg passive_UNIVs select_Bs select_ss))))
(mk_alg_select_tac Abs_IIT_inverse_thm)
|> Thm.close_derivation;
val mor_select_thm =
let
val alg_prem = HOLogic.mk_Trueprop (mk_alg passive_UNIVs Bs ss);
val i_prem = HOLogic.mk_Trueprop (HOLogic.mk_mem (iidx, II));
val mor_prem = HOLogic.mk_Trueprop (mk_mor select_Bs select_ss Bs ss Asuc_fs);
val prems = [alg_prem, i_prem, mor_prem];
val concl = HOLogic.mk_Trueprop
(mk_mor car_inits str_inits Bs ss
(map (fn f => HOLogic.mk_comp (f, mk_rapp iidx Asuc_bdT)) Asuc_fs));
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all (iidx :: Bs @ ss @ Asuc_fs) (Logic.list_implies (prems, concl)))
(K (mk_mor_select_tac mor_def mor_cong_thm mor_comp_thm mor_incl_min_alg_thm alg_def
alg_select_thm alg_set_thms set_natural'ss str_init_defs))
|> Thm.close_derivation
end;
val (init_ex_mor_thm, init_unique_mor_thms) =
let
val prem = HOLogic.mk_Trueprop (mk_alg passive_UNIVs Bs ss);
val concl = HOLogic.mk_Trueprop
(list_exists_free init_fs (mk_mor car_inits str_inits Bs ss init_fs));
val ex_mor = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (Bs @ ss) (Logic.mk_implies (prem, concl)))
(mk_init_ex_mor_tac Abs_IIT_inverse_thm ex_copy_alg_thm alg_min_alg_thm
card_of_min_alg_thms mor_comp_thm mor_select_thm mor_incl_min_alg_thm)
|> Thm.close_derivation;
val prems = map2 (HOLogic.mk_Trueprop oo curry HOLogic.mk_mem) init_xs car_inits
val mor_prems = map HOLogic.mk_Trueprop
[mk_mor car_inits str_inits Bs ss init_fs,
mk_mor car_inits str_inits Bs ss init_fs_copy];
fun mk_fun_eq f g x = HOLogic.mk_eq (f $ x, g $ x);
val unique = HOLogic.mk_Trueprop
(Library.foldr1 HOLogic.mk_conj (map3 mk_fun_eq init_fs init_fs_copy init_xs));
val unique_mor = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (init_xs @ Bs @ ss @ init_fs @ init_fs_copy)
(Logic.list_implies (prems @ mor_prems, unique)))
(K (mk_init_unique_mor_tac m alg_def alg_init_thm least_min_alg_thms
in_mono'_thms alg_set_thms morE_thms map_congs))
|> Thm.close_derivation;
in
(ex_mor, split_conj_thm unique_mor)
end;
val init_setss = mk_setss (passiveAs @ active_initTs);
val active_init_setss = map (drop m) init_setss;
val init_ins = map2 (fn sets => mk_in (passive_UNIVs @ car_inits) sets) init_setss init_FTs;
fun mk_closed phis =
let
fun mk_conjunct phi str_init init_sets init_in x x' =
let
val prem = Library.foldr1 HOLogic.mk_conj
(map2 (fn set => mk_Ball (set $ x)) init_sets phis);
val concl = phi $ (str_init $ x);
in
mk_Ball init_in (Term.absfree x' (HOLogic.mk_imp (prem, concl)))
end;
in
Library.foldr1 HOLogic.mk_conj
(map6 mk_conjunct phis str_inits active_init_setss init_ins init_xFs init_xFs')
end;
val init_induct_thm =
let
val prem = HOLogic.mk_Trueprop (mk_closed init_phis);
val concl = HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map2 mk_Ball car_inits init_phis));
in
Skip_Proof.prove lthy [] []
(fold_rev Logic.all init_phis (Logic.mk_implies (prem, concl)))
(K (mk_init_induct_tac m alg_def alg_init_thm least_min_alg_thms alg_set_thms))
|> Thm.close_derivation
end;
val timer = time (timer "Initiality definition & thms");
val ((T_names, (T_glob_infos, T_loc_infos)), lthy) =
lthy
|> fold_map2 (fn b => fn car_init => typedef true NONE (b, params, NoSyn) car_init NONE
(EVERY' [rtac ssubst, rtac @{thm ex_in_conv}, resolve_tac alg_not_empty_thms,
rtac alg_init_thm] 1)) bs car_inits
|>> apsnd split_list o split_list;
val Ts = map (fn name => Type (name, params')) T_names;
fun mk_Ts passive = map (Term.typ_subst_atomic (passiveAs ~~ passive)) Ts;
val Ts' = mk_Ts passiveBs;
val Rep_Ts = map2 (fn info => fn T => Const (#Rep_name info, T --> initT)) T_glob_infos Ts;
val Abs_Ts = map2 (fn info => fn T => Const (#Abs_name info, initT --> T)) T_glob_infos Ts;
val set_defs = map (the o #set_def) T_loc_infos;
val type_defs = map #type_definition T_loc_infos;
val Reps = map #Rep T_loc_infos;
val Rep_casess = map #Rep_cases T_loc_infos;
val Rep_injects = map #Rep_inject T_loc_infos;
val Rep_inverses = map #Rep_inverse T_loc_infos;
val Abs_inverses = map #Abs_inverse T_loc_infos;
val T_subset1s = map mk_T_subset1 set_defs;
val T_subset2s = map mk_T_subset2 set_defs;
fun mk_inver_thm mk_tac rep abs X thm =
Skip_Proof.prove lthy [] []
(HOLogic.mk_Trueprop (mk_inver rep abs X))
(K (EVERY' [rtac ssubst, rtac @{thm inver_def}, rtac ballI, mk_tac thm] 1))
|> Thm.close_derivation;
val inver_Reps = map4 (mk_inver_thm rtac) Abs_Ts Rep_Ts (map HOLogic.mk_UNIV Ts) Rep_inverses;
val inver_Abss = map4 (mk_inver_thm etac) Rep_Ts Abs_Ts car_inits
(map2 (curry op RS) T_subset1s Abs_inverses);
val timer = time (timer "THE TYPEDEFs & Rep/Abs thms");
val UNIVs = map HOLogic.mk_UNIV Ts;
val FTs = mk_FTs (passiveAs @ Ts);
val FTs' = mk_FTs (passiveBs @ Ts');
fun mk_set_Ts T = passiveAs @ replicate n (HOLogic.mk_setT T);
val setFTss = map (mk_FTs o mk_set_Ts) passiveAs;
val FTs_setss = mk_setss (passiveAs @ Ts);
val FTs'_setss = mk_setss (passiveBs @ Ts');
val map_FT_inits = map2 (fn Ds =>
mk_map_of_bnf Ds (passiveAs @ Ts) (passiveAs @ active_initTs)) Dss bnfs;
val fTs = map2 (curry op -->) Ts activeAs;
val iterT = Library.foldr1 HOLogic.mk_prodT (map2 (curry op -->) Ts activeAs);
val rec_sTs = map (Term.typ_subst_atomic (activeBs ~~ Ts)) prod_sTs;
val rec_maps = map (Term.subst_atomic_types (activeBs ~~ Ts)) map_fsts;
val rec_maps_rev = map (Term.subst_atomic_types (activeBs ~~ Ts)) map_fsts_rev;
val rec_fsts = map (Term.subst_atomic_types (activeBs ~~ Ts)) fsts;
val (((((((((((Izs, (Izs1, Izs1')), (Izs2, Izs2')), (xFs, xFs')), yFs), (AFss, AFss')),
(iter_f, iter_f')), fs), phis), phi2s), rec_ss), names_lthy) = names_lthy
|> mk_Frees "z" Ts
||>> mk_Frees' "z1" Ts
||>> mk_Frees' "z2" Ts'
||>> mk_Frees' "x" FTs
||>> mk_Frees "y" FTs'
||>> mk_Freess' "z" setFTss
||>> yield_singleton (apfst (op ~~) oo mk_Frees' "f") iterT
||>> mk_Frees "f" fTs
||>> mk_Frees "phi" (map (fn T => T --> HOLogic.boolT) Ts)
||>> mk_Frees "phi" (map2 (fn T => fn U => T --> U --> HOLogic.boolT) Ts Ts')
||>> mk_Frees "s" rec_sTs;
fun fld_bind i = Binding.suffix_name ("_" ^ fldN) (nth bs (i - 1));
val fld_name = Binding.name_of o fld_bind;
val fld_def_bind = rpair [] o Thm.def_binding o fld_bind;
fun fld_spec i abs str map_FT_init x x' =
let
val fldT = nth FTs (i - 1) --> nth Ts (i - 1);
val lhs = Free (fld_name i, fldT);
val rhs = Term.absfree x' (abs $ (str $
(Term.list_comb (map_FT_init, map HOLogic.id_const passiveAs @ Rep_Ts) $ x)));
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((fld_frees, (_, fld_def_frees)), (lthy, lthy_old)) =
lthy
|> fold_map6 (fn i => fn abs => fn str => fn map => fn x => fn x' =>
Specification.definition
(SOME (fld_bind i, NONE, NoSyn), (fld_def_bind i, fld_spec i abs str map x x')))
ks Abs_Ts str_inits map_FT_inits xFs xFs'
|>> apsnd split_list o split_list
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
fun mk_flds passive =
map (Term.subst_atomic_types (map (Morphism.typ phi) params' ~~ (deads @ passive)) o
Morphism.term phi) fld_frees;
val flds = mk_flds passiveAs;
val fld's = mk_flds passiveBs;
val fld_defs = map (Morphism.thm phi) fld_def_frees;
val (mor_Rep_thm, mor_Abs_thm) =
let
val copy = alg_init_thm RS copy_alg_thm;
fun mk_bij inj subset1 subset2 Rep cases = @{thm bij_betwI'} OF
[inj, Rep RS subset2, subset1 RS cases];
val bijs = map5 mk_bij Rep_injects T_subset1s T_subset2s Reps Rep_casess;
val mor_Rep =
Skip_Proof.prove lthy [] []
(HOLogic.mk_Trueprop (mk_mor UNIVs flds car_inits str_inits Rep_Ts))
(mk_mor_Rep_tac fld_defs copy bijs inver_Abss inver_Reps)
|> Thm.close_derivation;
val inv = mor_inv_thm OF [mor_Rep, talg_thm, alg_init_thm];
val mor_Abs =
Skip_Proof.prove lthy [] []
(HOLogic.mk_Trueprop (mk_mor car_inits str_inits UNIVs flds Abs_Ts))
(K (mk_mor_Abs_tac inv inver_Abss inver_Reps))
|> Thm.close_derivation;
in
(mor_Rep, mor_Abs)
end;
val timer = time (timer "fld definitions & thms");
val iter_fun = Term.absfree iter_f'
(mk_mor UNIVs flds active_UNIVs ss (map (mk_nthN n iter_f) ks));
val iter = HOLogic.choice_const iterT $ iter_fun;
fun iter_bind i = Binding.suffix_name ("_" ^ iterN) (nth bs (i - 1));
val iter_name = Binding.name_of o iter_bind;
val iter_def_bind = rpair [] o Thm.def_binding o iter_bind;
fun iter_spec i T AT =
let
val iterT = Library.foldr (op -->) (sTs, T --> AT);
val lhs = Term.list_comb (Free (iter_name i, iterT), ss);
val rhs = mk_nthN n iter i;
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((iter_frees, (_, iter_def_frees)), (lthy, lthy_old)) =
lthy
|> fold_map3 (fn i => fn T => fn AT =>
Specification.definition
(SOME (iter_bind i, NONE, NoSyn), (iter_def_bind i, iter_spec i T AT)))
ks Ts activeAs
|>> apsnd split_list o split_list
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
val iters = map (fst o dest_Const o Morphism.term phi) iter_frees;
fun mk_iter Ts ss i = Term.list_comb (Const (nth iters (i - 1), Library.foldr (op -->)
(map fastype_of ss, nth Ts (i - 1) --> range_type (fastype_of (nth ss (i - 1))))), ss);
val iter_defs = map (Morphism.thm phi) iter_def_frees;
val mor_iter_thm =
let
val ex_mor = talg_thm RS init_ex_mor_thm;
val mor_cong = mor_cong_thm OF (map (mk_nth_conv n) ks);
val mor_comp = mor_Rep_thm RS mor_comp_thm;
val cT = certifyT lthy iterT;
val ct = certify lthy iter_fun
in
singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] []
(HOLogic.mk_Trueprop (mk_mor UNIVs flds active_UNIVs ss (map (mk_iter Ts ss) ks)))
(K (mk_mor_iter_tac cT ct iter_defs ex_mor (mor_comp RS mor_cong))))
|> Thm.close_derivation
end;
val iter_thms = map (fn morE => rule_by_tactic lthy
((rtac CollectI THEN' CONJ_WRAP' (K (rtac @{thm subset_UNIV})) (1 upto m + n)) 1)
(mor_iter_thm RS morE)) morE_thms;
val (iter_unique_mor_thms, iter_unique_mor_thm) =
let
val prem = HOLogic.mk_Trueprop (mk_mor UNIVs flds active_UNIVs ss fs);
fun mk_fun_eq f i = HOLogic.mk_eq (f, mk_iter Ts ss i);
val unique = HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj (map2 mk_fun_eq fs ks));
val unique_mor = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (ss @ fs) (Logic.mk_implies (prem, unique)))
(K (mk_iter_unique_mor_tac type_defs init_unique_mor_thms T_subset2s Reps
mor_comp_thm mor_Abs_thm mor_iter_thm))
|> Thm.close_derivation;
in
`split_conj_thm unique_mor
end;
val (iter_unique_thms, iter_unique_thm) =
`split_conj_thm (mk_conjIN n RS
(mor_UNIV_thm RS @{thm ssubst[of _ _ "%x. x"]} RS iter_unique_mor_thm))
val iter_fld_thms =
map (fn thm => (mor_incl_thm OF replicate n @{thm subset_UNIV}) RS thm RS sym)
iter_unique_mor_thms;
val fld_o_iter_thms =
let
val mor = mor_comp_thm OF [mor_iter_thm, mor_str_thm];
in
map2 (fn unique => fn iter_fld =>
trans OF [mor RS unique, iter_fld]) iter_unique_mor_thms iter_fld_thms
end;
val timer = time (timer "iter definitions & thms");
val map_flds = map2 (fn Ds => fn bnf =>
Term.list_comb (mk_map_of_bnf Ds (passiveAs @ FTs) (passiveAs @ Ts) bnf,
map HOLogic.id_const passiveAs @ flds)) Dss bnfs;
fun unf_bind i = Binding.suffix_name ("_" ^ unfN) (nth bs (i - 1));
val unf_name = Binding.name_of o unf_bind;
val unf_def_bind = rpair [] o Thm.def_binding o unf_bind;
fun unf_spec i FT T =
let
val unfT = T --> FT;
val lhs = Free (unf_name i, unfT);
val rhs = mk_iter Ts map_flds i;
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((unf_frees, (_, unf_def_frees)), (lthy, lthy_old)) =
lthy
|> fold_map3 (fn i => fn FT => fn T =>
Specification.definition
(SOME (unf_bind i, NONE, NoSyn), (unf_def_bind i, unf_spec i FT T))) ks FTs Ts
|>> apsnd split_list o split_list
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
fun mk_unfs params =
map (Term.subst_atomic_types (map (Morphism.typ phi) params' ~~ params) o Morphism.term phi)
unf_frees;
val unfs = mk_unfs params';
val unf_defs = map (Morphism.thm phi) unf_def_frees;
val fld_o_unf_thms = map2 (Local_Defs.fold lthy o single) unf_defs fld_o_iter_thms;
val unf_o_fld_thms =
let
fun mk_goal unf fld FT = mk_Trueprop_eq (HOLogic.mk_comp (unf, fld), HOLogic.id_const FT);
val goals = map3 mk_goal unfs flds FTs;
in
map5 (fn goal => fn unf_def => fn iter => fn map_comp_id => fn map_congL =>
Skip_Proof.prove lthy [] [] goal
(K (mk_unf_o_fld_tac unf_def iter map_comp_id map_congL fld_o_iter_thms))
|> Thm.close_derivation)
goals unf_defs iter_thms map_comp_id_thms map_congL_thms
end;
val unf_fld_thms = map (fn thm => thm RS @{thm pointfree_idE}) unf_o_fld_thms;
val fld_unf_thms = map (fn thm => thm RS @{thm pointfree_idE}) fld_o_unf_thms;
val bij_unf_thms =
map2 (fn thm1 => fn thm2 => @{thm o_bij} OF [thm1, thm2]) fld_o_unf_thms unf_o_fld_thms;
val inj_unf_thms = map (fn thm => thm RS @{thm bij_is_inj}) bij_unf_thms;
val surj_unf_thms = map (fn thm => thm RS @{thm bij_is_surj}) bij_unf_thms;
val unf_nchotomy_thms = map (fn thm => thm RS @{thm surjD}) surj_unf_thms;
val unf_inject_thms = map (fn thm => thm RS @{thm inj_eq}) inj_unf_thms;
val unf_exhaust_thms = map (fn thm => thm RS exE) unf_nchotomy_thms;
val bij_fld_thms =
map2 (fn thm1 => fn thm2 => @{thm o_bij} OF [thm1, thm2]) unf_o_fld_thms fld_o_unf_thms;
val inj_fld_thms = map (fn thm => thm RS @{thm bij_is_inj}) bij_fld_thms;
val surj_fld_thms = map (fn thm => thm RS @{thm bij_is_surj}) bij_fld_thms;
val fld_nchotomy_thms = map (fn thm => thm RS @{thm surjD}) surj_fld_thms;
val fld_inject_thms = map (fn thm => thm RS @{thm inj_eq}) inj_fld_thms;
val fld_exhaust_thms = map (fn thm => thm RS exE) fld_nchotomy_thms;
val timer = time (timer "unf definitions & thms");
val fst_rec_pair_thms =
let
val mor = mor_comp_thm OF [mor_iter_thm, mor_convol_thm];
in
map2 (fn unique => fn iter_fld =>
trans OF [mor RS unique, iter_fld]) iter_unique_mor_thms iter_fld_thms
end;
fun rec_bind i = Binding.suffix_name ("_" ^ recN) (nth bs (i - 1));
val rec_name = Binding.name_of o rec_bind;
val rec_def_bind = rpair [] o Thm.def_binding o rec_bind;
fun rec_spec i T AT =
let
val recT = Library.foldr (op -->) (rec_sTs, T --> AT);
val maps = map3 (fn fld => fn prod_s => fn map =>
mk_convol (HOLogic.mk_comp (fld, Term.list_comb (map, passive_ids @ rec_fsts)), prod_s))
flds rec_ss rec_maps;
val lhs = Term.list_comb (Free (rec_name i, recT), rec_ss);
val rhs = HOLogic.mk_comp (snd_const (HOLogic.mk_prodT (T, AT)), mk_iter Ts maps i);
in
mk_Trueprop_eq (lhs, rhs)
end;
val ((rec_frees, (_, rec_def_frees)), (lthy, lthy_old)) =
lthy
|> fold_map3 (fn i => fn T => fn AT =>
Specification.definition
(SOME (rec_bind i, NONE, NoSyn), (rec_def_bind i, rec_spec i T AT)))
ks Ts activeAs
|>> apsnd split_list o split_list
||> `Local_Theory.restore;
(*transforms defined frees into consts*)
val phi = Proof_Context.export_morphism lthy_old lthy;
val recs = map (fst o dest_Const o Morphism.term phi) rec_frees;
fun mk_rec ss i = Term.list_comb (Const (nth recs (i - 1), Library.foldr (op -->)
(map fastype_of ss, nth Ts (i - 1) --> range_type (fastype_of (nth ss (i - 1))))), ss);
val rec_defs = map (Morphism.thm phi) rec_def_frees;
val convols = map2 (fn T => fn i => mk_convol (HOLogic.id_const T, mk_rec rec_ss i)) Ts ks;
val rec_thms =
let
fun mk_goal i rec_s rec_map fld x =
let
val lhs = mk_rec rec_ss i $ (fld $ x);
val rhs = rec_s $ (Term.list_comb (rec_map, passive_ids @ convols) $ x);
in
fold_rev Logic.all (x :: rec_ss) (mk_Trueprop_eq (lhs, rhs))
end;
val goals = map5 mk_goal ks rec_ss rec_maps_rev flds xFs;
in
map2 (fn goal => fn iter =>
Skip_Proof.prove lthy [] [] goal (mk_rec_tac rec_defs iter fst_rec_pair_thms)
|> Thm.close_derivation)
goals iter_thms
end;
val timer = time (timer "rec definitions & thms");
val (fld_induct_thm, induct_params) =
let
fun mk_prem phi fld sets x =
let
fun mk_IH phi set z =
let
val prem = HOLogic.mk_Trueprop (HOLogic.mk_mem (z, set $ x));
val concl = HOLogic.mk_Trueprop (phi $ z);
in
Logic.all z (Logic.mk_implies (prem, concl))
end;
val IHs = map3 mk_IH phis (drop m sets) Izs;
val concl = HOLogic.mk_Trueprop (phi $ (fld $ x));
in
Logic.all x (Logic.list_implies (IHs, concl))
end;
val prems = map4 mk_prem phis flds FTs_setss xFs;
fun mk_concl phi z = phi $ z;
val concl =
HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj (map2 mk_concl phis Izs));
val goal = Logic.list_implies (prems, concl);
in
(Skip_Proof.prove lthy [] []
(fold_rev Logic.all (phis @ Izs) goal)
(K (mk_fld_induct_tac m set_natural'ss init_induct_thm morE_thms mor_Abs_thm
Rep_inverses Abs_inverses Reps T_subset1s T_subset2s))
|> Thm.close_derivation,
rev (Term.add_tfrees goal []))
end;
val cTs = map (SOME o certifyT lthy o TFree) induct_params;
val weak_fld_induct_thms =
let fun insts i = (replicate (i - 1) TrueI) @ (@{thm asm_rl} :: replicate (n - i) TrueI);
in map (fn i => (fld_induct_thm OF insts i) RS mk_conjunctN n i) ks end;
val (fld_induct2_thm, induct2_params) =
let
fun mk_prem phi fld fld' sets sets' x y =
let
fun mk_IH phi set set' z1 z2 =
let
val prem1 = HOLogic.mk_Trueprop (HOLogic.mk_mem (z1, (set $ x)));
val prem2 = HOLogic.mk_Trueprop (HOLogic.mk_mem (z2, (set' $ y)));
val concl = HOLogic.mk_Trueprop (phi $ z1 $ z2);
in
fold_rev Logic.all [z1, z2] (Logic.list_implies ([prem1, prem2], concl))
end;
val IHs = map5 mk_IH phi2s (drop m sets) (drop m sets') Izs1 Izs2;
val concl = HOLogic.mk_Trueprop (phi $ (fld $ x) $ (fld' $ y));
in
fold_rev Logic.all [x, y] (Logic.list_implies (IHs, concl))
end;
val prems = map7 mk_prem phi2s flds fld's FTs_setss FTs'_setss xFs yFs;
fun mk_concl phi z1 z2 = phi $ z1 $ z2;
val concl = HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map3 mk_concl phi2s Izs1 Izs2));
fun mk_t phi (z1, z1') (z2, z2') =
Term.absfree z1' (HOLogic.mk_all (fst z2', snd z2', phi $ z1 $ z2));
val cts = map3 (SOME o certify lthy ooo mk_t) phi2s (Izs1 ~~ Izs1') (Izs2 ~~ Izs2');
val goal = Logic.list_implies (prems, concl);
in
(singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] [] goal
(mk_fld_induct2_tac cTs cts fld_induct_thm weak_fld_induct_thms))
|> Thm.close_derivation,
rev (Term.add_tfrees goal []))
end;
val timer = time (timer "induction");
(*register new datatypes as BNFs*)
val lthy = if m = 0 then lthy else
let
val fTs = map2 (curry op -->) passiveAs passiveBs;
val f1Ts = map2 (curry op -->) passiveAs passiveYs;
val f2Ts = map2 (curry op -->) passiveBs passiveYs;
val p1Ts = map2 (curry op -->) passiveXs passiveAs;
val p2Ts = map2 (curry op -->) passiveXs passiveBs;
val uTs = map2 (curry op -->) Ts Ts';
val B1Ts = map HOLogic.mk_setT passiveAs;
val B2Ts = map HOLogic.mk_setT passiveBs;
val AXTs = map HOLogic.mk_setT passiveXs;
val XTs = mk_Ts passiveXs;
val YTs = mk_Ts passiveYs;
val IRTs = map2 (curry mk_relT) passiveAs passiveBs;
val IphiTs = map2 (fn T => fn U => T --> U --> HOLogic.boolT) passiveAs passiveBs;
val (((((((((((((((fs, fs'), fs_copy), us),
B1s), B2s), AXs), (xs, xs')), f1s), f2s), p1s), p2s), (ys, ys')), IRs), Iphis),
names_lthy) = names_lthy
|> mk_Frees' "f" fTs
||>> mk_Frees "f" fTs
||>> mk_Frees "u" uTs
||>> mk_Frees "B1" B1Ts
||>> mk_Frees "B2" B2Ts
||>> mk_Frees "A" AXTs
||>> mk_Frees' "x" XTs
||>> mk_Frees "f1" f1Ts
||>> mk_Frees "f2" f2Ts
||>> mk_Frees "p1" p1Ts
||>> mk_Frees "p2" p2Ts
||>> mk_Frees' "y" passiveAs
||>> mk_Frees "R" IRTs
||>> mk_Frees "phi" IphiTs;
val map_FTFT's = map2 (fn Ds =>
mk_map_of_bnf Ds (passiveAs @ Ts) (passiveBs @ Ts')) Dss bnfs;
fun mk_passive_maps ATs BTs Ts =
map2 (fn Ds => mk_map_of_bnf Ds (ATs @ Ts) (BTs @ Ts)) Dss bnfs;
fun mk_map_iter_arg fs Ts fld fmap =
HOLogic.mk_comp (fld, Term.list_comb (fmap, fs @ map HOLogic.id_const Ts));
fun mk_map Ts fs Ts' flds mk_maps =
mk_iter Ts (map2 (mk_map_iter_arg fs Ts') flds (mk_maps Ts'));
val pmapsABT' = mk_passive_maps passiveAs passiveBs;
val fs_maps = map (mk_map Ts fs Ts' fld's pmapsABT') ks;
val fs_copy_maps = map (mk_map Ts fs_copy Ts' fld's pmapsABT') ks;
val Yflds = mk_flds passiveYs;
val f1s_maps = map (mk_map Ts f1s YTs Yflds (mk_passive_maps passiveAs passiveYs)) ks;
val f2s_maps = map (mk_map Ts' f2s YTs Yflds (mk_passive_maps passiveBs passiveYs)) ks;
val p1s_maps = map (mk_map XTs p1s Ts flds (mk_passive_maps passiveXs passiveAs)) ks;
val p2s_maps = map (mk_map XTs p2s Ts' fld's (mk_passive_maps passiveXs passiveBs)) ks;
val (map_simp_thms, map_thms) =
let
fun mk_goal fs_map map fld fld' = fold_rev Logic.all fs
(mk_Trueprop_eq (HOLogic.mk_comp (fs_map, fld),
HOLogic.mk_comp (fld', Term.list_comb (map, fs @ fs_maps))));
val goals = map4 mk_goal fs_maps map_FTFT's flds fld's;
val maps =
map4 (fn goal => fn iter => fn map_comp_id => fn map_cong =>
Skip_Proof.prove lthy [] [] goal (K (mk_map_tac m n iter map_comp_id map_cong))
|> Thm.close_derivation)
goals iter_thms map_comp_id_thms map_congs;
in
map_split (fn thm => (thm RS @{thm pointfreeE}, thm)) maps
end;
val (map_unique_thms, map_unique_thm) =
let
fun mk_prem u map fld fld' =
mk_Trueprop_eq (HOLogic.mk_comp (u, fld),
HOLogic.mk_comp (fld', Term.list_comb (map, fs @ us)));
val prems = map4 mk_prem us map_FTFT's flds fld's;
val goal =
HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map2 (curry HOLogic.mk_eq) us fs_maps));
val unique = Skip_Proof.prove lthy [] []
(fold_rev Logic.all (us @ fs) (Logic.list_implies (prems, goal)))
(K (mk_map_unique_tac m mor_def iter_unique_mor_thm map_comp_id_thms map_congs))
|> Thm.close_derivation;
in
`split_conj_thm unique
end;
val timer = time (timer "map functions for the new datatypes");
val bd = mk_cpow sum_bd;
val bd_Cinfinite = sum_Cinfinite RS @{thm Cinfinite_cpow};
fun mk_cpow_bd thm = @{thm ordLeq_transitive} OF
[thm, sum_Card_order RS @{thm cpow_greater_eq}];
val set_bd_cpowss = map (map mk_cpow_bd) set_bd_sumss;
val timer = time (timer "bounds for the new datatypes");
val ls = 1 upto m;
val setsss = map (mk_setss o mk_set_Ts) passiveAs;
val map_setss = map (fn T => map2 (fn Ds =>
mk_map_of_bnf Ds (passiveAs @ Ts) (mk_set_Ts T)) Dss bnfs) passiveAs;
fun mk_col l T z z' sets =
let
fun mk_UN set = mk_Union T $ (set $ z);
in
Term.absfree z'
(mk_union (nth sets (l - 1) $ z,
Library.foldl1 mk_union (map mk_UN (drop m sets))))
end;
val colss = map5 (fn l => fn T => map3 (mk_col l T)) ls passiveAs AFss AFss' setsss;
val setss_by_range = map (fn cols => map (mk_iter Ts cols) ks) colss;
val setss_by_bnf = transpose setss_by_range;
val (set_simp_thmss, set_thmss) =
let
fun mk_goal sets fld set col map =
mk_Trueprop_eq (HOLogic.mk_comp (set, fld),
HOLogic.mk_comp (col, Term.list_comb (map, passive_ids @ sets)));
val goalss =
map3 (fn sets => map4 (mk_goal sets) flds sets) setss_by_range colss map_setss;
val setss = map (map2 (fn iter => fn goal =>
Skip_Proof.prove lthy [] [] goal (K (mk_set_tac iter)) |> Thm.close_derivation)
iter_thms) goalss;
fun mk_simp_goal pas_set act_sets sets fld z set =
Logic.all z (mk_Trueprop_eq (set $ (fld $ z),
mk_union (pas_set $ z,
Library.foldl1 mk_union (map2 (fn X => mk_UNION (X $ z)) act_sets sets))));
val simp_goalss =
map2 (fn i => fn sets =>
map4 (fn Fsets => mk_simp_goal (nth Fsets (i - 1)) (drop m Fsets) sets)
FTs_setss flds xFs sets)
ls setss_by_range;
val set_simpss = map3 (fn i => map3 (fn set_nats => fn goal => fn set =>
Skip_Proof.prove lthy [] [] goal
(K (mk_set_simp_tac set (nth set_nats (i - 1)) (drop m set_nats)))
|> Thm.close_derivation)
set_natural'ss) ls simp_goalss setss;
in
(set_simpss, setss)
end;
fun mk_set_thms set_simp = (@{thm xt1(3)} OF [set_simp, @{thm Un_upper1}]) ::
map (fn i => (@{thm xt1(3)} OF [set_simp, @{thm Un_upper2}]) RS
(mk_Un_upper n i RS subset_trans) RSN
(2, @{thm UN_upper} RS subset_trans))
(1 upto n);
val Fset_set_thmsss = transpose (map (map mk_set_thms) set_simp_thmss);
val timer = time (timer "set functions for the new datatypes");
val cxs = map (SOME o certify lthy) Izs;
val setss_by_bnf' =
map (map (Term.subst_atomic_types (passiveAs ~~ passiveBs))) setss_by_bnf;
val setss_by_range' = transpose setss_by_bnf';
val set_natural_thmss =
let
fun mk_set_natural f map z set set' =
HOLogic.mk_eq (mk_image f $ (set $ z), set' $ (map $ z));
fun mk_cphi f map z set set' = certify lthy
(Term.absfree (dest_Free z) (mk_set_natural f map z set set'));
val csetss = map (map (certify lthy)) setss_by_range';
val cphiss = map3 (fn f => fn sets => fn sets' =>
(map4 (mk_cphi f) fs_maps Izs sets sets')) fs setss_by_range setss_by_range';
val inducts = map (fn cphis =>
Drule.instantiate' cTs (map SOME cphis @ cxs) fld_induct_thm) cphiss;
val goals =
map3 (fn f => fn sets => fn sets' =>
HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map4 (mk_set_natural f) fs_maps Izs sets sets')))
fs setss_by_range setss_by_range';
fun mk_tac induct = mk_set_nat_tac m (rtac induct) set_natural'ss map_simp_thms;
val thms =
map5 (fn goal => fn csets => fn set_simps => fn induct => fn i =>
singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] [] goal (mk_tac induct csets set_simps i))
|> Thm.close_derivation)
goals csetss set_simp_thmss inducts ls;
in
map split_conj_thm thms
end;
val set_bd_thmss =
let
fun mk_set_bd z set = mk_ordLeq (mk_card_of (set $ z)) bd;
fun mk_cphi z set = certify lthy (Term.absfree (dest_Free z) (mk_set_bd z set));
val cphiss = map (map2 mk_cphi Izs) setss_by_range;
val inducts = map (fn cphis =>
Drule.instantiate' cTs (map SOME cphis @ cxs) fld_induct_thm) cphiss;
val goals =
map (fn sets =>
HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map2 mk_set_bd Izs sets))) setss_by_range;
fun mk_tac induct = mk_set_bd_tac m (rtac induct) bd_Cinfinite set_bd_cpowss;
val thms =
map4 (fn goal => fn set_simps => fn induct => fn i =>
singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] [] goal (mk_tac induct set_simps i))
|> Thm.close_derivation)
goals set_simp_thmss inducts ls;
in
map split_conj_thm thms
end;
val map_cong_thms =
let
fun mk_prem z set f g y y' =
mk_Ball (set $ z) (Term.absfree y' (HOLogic.mk_eq (f $ y, g $ y)));
fun mk_map_cong sets z fmap gmap =
HOLogic.mk_imp
(Library.foldr1 HOLogic.mk_conj (map5 (mk_prem z) sets fs fs_copy ys ys'),
HOLogic.mk_eq (fmap $ z, gmap $ z));
fun mk_cphi sets z fmap gmap =
certify lthy (Term.absfree (dest_Free z) (mk_map_cong sets z fmap gmap));
val cphis = map4 mk_cphi setss_by_bnf Izs fs_maps fs_copy_maps;
val induct = Drule.instantiate' cTs (map SOME cphis @ cxs) fld_induct_thm;
val goal =
HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map4 mk_map_cong setss_by_bnf Izs fs_maps fs_copy_maps));
val thm = singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] [] goal
(mk_mcong_tac (rtac induct) Fset_set_thmsss map_congs map_simp_thms))
|> Thm.close_derivation;
in
split_conj_thm thm
end;
val in_incl_min_alg_thms =
let
fun mk_prem z sets =
HOLogic.mk_mem (z, mk_in As sets (fastype_of z));
fun mk_incl z sets i =
HOLogic.mk_imp (mk_prem z sets, HOLogic.mk_mem (z, mk_min_alg As flds i));
fun mk_cphi z sets i =
certify lthy (Term.absfree (dest_Free z) (mk_incl z sets i));
val cphis = map3 mk_cphi Izs setss_by_bnf ks;
val induct = Drule.instantiate' cTs (map SOME cphis @ cxs) fld_induct_thm;
val goal =
HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj
(map3 mk_incl Izs setss_by_bnf ks));
val thm = singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] [] goal
(mk_incl_min_alg_tac (rtac induct) Fset_set_thmsss alg_set_thms alg_min_alg_thm))
|> Thm.close_derivation;
in
split_conj_thm thm
end;
val Xsetss = map (map (Term.subst_atomic_types (passiveAs ~~ passiveXs))) setss_by_bnf;
val map_wpull_thms =
let
val cTs = map (SOME o certifyT lthy o TFree) induct2_params;
val cxs = map (SOME o certify lthy) (interleave Izs1 Izs2);
fun mk_prem z1 z2 sets1 sets2 map1 map2 =
HOLogic.mk_conj
(HOLogic.mk_mem (z1, mk_in B1s sets1 (fastype_of z1)),
HOLogic.mk_conj
(HOLogic.mk_mem (z2, mk_in B2s sets2 (fastype_of z2)),
HOLogic.mk_eq (map1 $ z1, map2 $ z2)));
val prems = map6 mk_prem Izs1 Izs2 setss_by_bnf setss_by_bnf' f1s_maps f2s_maps;
fun mk_concl z1 z2 sets map1 map2 T x x' =
mk_Bex (mk_in AXs sets T) (Term.absfree x'
(HOLogic.mk_conj (HOLogic.mk_eq (map1 $ x, z1), HOLogic.mk_eq (map2 $ x, z2))));
val concls = map8 mk_concl Izs1 Izs2 Xsetss p1s_maps p2s_maps XTs xs xs';
val goals = map2 (curry HOLogic.mk_imp) prems concls;
fun mk_cphi z1 z2 goal = certify lthy (Term.absfree z1 (Term.absfree z2 goal));
val cphis = map3 mk_cphi Izs1' Izs2' goals;
val induct = Drule.instantiate' cTs (map SOME cphis @ cxs) fld_induct2_thm;
val goal = Logic.list_implies (map HOLogic.mk_Trueprop
(map8 mk_wpull AXs B1s B2s f1s f2s (replicate m NONE) p1s p2s),
HOLogic.mk_Trueprop (Library.foldr1 HOLogic.mk_conj goals));
val thm = singleton (Proof_Context.export names_lthy lthy)
(Skip_Proof.prove lthy [] [] goal
(K (mk_lfp_map_wpull_tac m (rtac induct) map_wpulls map_simp_thms
(transpose set_simp_thmss) Fset_set_thmsss fld_inject_thms)))
|> Thm.close_derivation;
in
split_conj_thm thm
end;
val timer = time (timer "helpers for BNF properties");
val map_id_tacs = map (K o mk_map_id_tac map_ids) map_unique_thms;
val map_comp_tacs =
map2 (K oo mk_map_comp_tac map_comp's map_simp_thms) map_unique_thms ks;
val map_cong_tacs = map (mk_map_cong_tac m) map_cong_thms;
val set_nat_tacss = map (map (K o mk_set_natural_tac)) (transpose set_natural_thmss);
val bd_co_tacs = replicate n (K (mk_bd_card_order_tac bd_card_orders));
val bd_cinf_tacs = replicate n (K (rtac (bd_Cinfinite RS conjunct1) 1));
val set_bd_tacss = map (map (fn thm => K (rtac thm 1))) (transpose set_bd_thmss);
val in_bd_tacs = map2 (K oo mk_in_bd_tac sum_Card_order suc_bd_Cnotzero)
in_incl_min_alg_thms card_of_min_alg_thms;
val map_wpull_tacs = map (K o mk_wpull_tac) map_wpull_thms;
val tacss = map9 mk_tactics map_id_tacs map_comp_tacs map_cong_tacs set_nat_tacss bd_co_tacs
bd_cinf_tacs set_bd_tacss in_bd_tacs map_wpull_tacs;
val fld_witss =
let
val witss = map2 (fn Ds => fn bnf => mk_wits_of_bnf
(replicate (nwits_of_bnf bnf) Ds)
(replicate (nwits_of_bnf bnf) (passiveAs @ Ts)) bnf) Dss bnfs;
fun close_wit (I, wit) = fold_rev Term.absfree (map (nth ys') I) wit;
fun wit_apply (arg_I, arg_wit) (fun_I, fun_wit) =
(union (op =) arg_I fun_I, fun_wit $ arg_wit);
fun gen_arg support i =
if i < m then [([i], nth ys i)]
else maps (mk_wit support (nth flds (i - m)) (i - m)) (nth support (i - m))
and mk_wit support fld i (I, wit) =
let val args = map (gen_arg (nth_map i (remove (op =) (I, wit)) support)) I;
in
(args, [([], wit)])
|-> fold (map_product wit_apply)
|> map (apsnd (fn t => fld $ t))
|> minimize_wits
end;
in
map3 (fn fld => fn i => map close_wit o minimize_wits o maps (mk_wit witss fld i))
flds (0 upto n - 1) witss
end;
fun wit_tac _ = mk_wit_tac n (flat set_simp_thmss) (maps wit_thms_of_bnf bnfs);
val (Ibnfs, lthy) =
fold_map6 (fn tacs => fn b => fn map => fn sets => fn T => fn wits =>
bnf_def Dont_Inline user_policy I tacs wit_tac (SOME deads)
((((b, fold_rev Term.absfree fs' map), sets), absdummy T bd), wits))
tacss bs fs_maps setss_by_bnf Ts fld_witss lthy;
val fold_maps = Local_Defs.fold lthy (map (fn bnf =>
mk_unabs_def m (map_def_of_bnf bnf RS @{thm meta_eq_to_obj_eq})) Ibnfs);
val fold_sets = Local_Defs.fold lthy (maps (fn bnf =>
map (fn thm => thm RS @{thm meta_eq_to_obj_eq}) (set_defs_of_bnf bnf)) Ibnfs);
val timer = time (timer "registered new datatypes as BNFs");
val rels = map2 (fn Ds => mk_rel_of_bnf Ds (passiveAs @ Ts) (passiveBs @ Ts')) Dss bnfs;
val Irels = map (mk_rel_of_bnf deads passiveAs passiveBs) Ibnfs;
val preds = map2 (fn Ds => mk_pred_of_bnf Ds (passiveAs @ Ts) (passiveBs @ Ts')) Dss bnfs;
val Ipreds = map (mk_pred_of_bnf deads passiveAs passiveBs) Ibnfs;
val IrelRs = map (fn Irel => Term.list_comb (Irel, IRs)) Irels;
val relRs = map (fn rel => Term.list_comb (rel, IRs @ IrelRs)) rels;
val Ipredphis = map (fn Irel => Term.list_comb (Irel, Iphis)) Ipreds;
val predphis = map (fn rel => Term.list_comb (rel, Iphis @ Ipredphis)) preds;
val in_rels = map in_rel_of_bnf bnfs;
val in_Irels = map in_rel_of_bnf Ibnfs;
val pred_defs = map pred_def_of_bnf bnfs;
val Ipred_defs =
map (Drule.abs_def o (fn thm => thm RS @{thm eq_reflection}) o pred_def_of_bnf) Ibnfs;
val set_incl_thmss = map (map (fold_sets o hd)) Fset_set_thmsss;
val set_set_incl_thmsss = map (transpose o map (map fold_sets o tl)) Fset_set_thmsss;
val folded_map_simp_thms = map fold_maps map_simp_thms;
val folded_set_simp_thmss = map (map fold_sets) set_simp_thmss;
val folded_set_simp_thmss' = transpose folded_set_simp_thmss;
val Irel_unfold_thms =
let
fun mk_goal xF yF fld fld' IrelR relR = fold_rev Logic.all (xF :: yF :: IRs)
(mk_Trueprop_eq (HOLogic.mk_mem (HOLogic.mk_prod (fld $ xF, fld' $ yF), IrelR),
HOLogic.mk_mem (HOLogic.mk_prod (xF, yF), relR)));
val goals = map6 mk_goal xFs yFs flds fld's IrelRs relRs;
in
map12 (fn i => fn goal => fn in_rel => fn map_comp => fn map_cong =>
fn map_simp => fn set_simps => fn fld_inject => fn fld_unf =>
fn set_naturals => fn set_incls => fn set_set_inclss =>
Skip_Proof.prove lthy [] [] goal
(K (mk_rel_unfold_tac in_Irels i in_rel map_comp map_cong map_simp set_simps
fld_inject fld_unf set_naturals set_incls set_set_inclss))
|> Thm.close_derivation)
ks goals in_rels map_comp's map_congs folded_map_simp_thms folded_set_simp_thmss'
fld_inject_thms fld_unf_thms set_natural'ss set_incl_thmss set_set_incl_thmsss
end;
val Ipred_unfold_thms =
let
fun mk_goal xF yF fld fld' Ipredphi predphi = fold_rev Logic.all (xF :: yF :: Iphis)
(mk_Trueprop_eq (Ipredphi $ (fld $ xF) $ (fld' $ yF), predphi $ xF $ yF));
val goals = map6 mk_goal xFs yFs flds fld's Ipredphis predphis;
in
map3 (fn goal => fn pred_def => fn Irel_unfold =>
Skip_Proof.prove lthy [] [] goal (mk_pred_unfold_tac pred_def Ipred_defs Irel_unfold)
|> Thm.close_derivation)
goals pred_defs Irel_unfold_thms
end;
val timer = time (timer "additional properties");
val ls' = if m = 1 then [0] else ls
val Ibnf_common_notes =
[(map_uniqueN, [fold_maps map_unique_thm])]
|> map (fn (thmN, thms) =>
((Binding.qualify true (Binding.name_of b) (Binding.name thmN), []), [(thms, [])]));
val Ibnf_notes =
[(map_simpsN, map single folded_map_simp_thms),
(set_inclN, set_incl_thmss),
(set_set_inclN, map flat set_set_incl_thmsss), (* nicer names? *)
(rel_unfoldN, map single Irel_unfold_thms),
(pred_unfoldN, map single Ipred_unfold_thms)] @
map2 (fn i => fn thms => (mk_set_simpsN i, map single thms)) ls' folded_set_simp_thmss
|> maps (fn (thmN, thmss) =>
map2 (fn b => fn thms =>
((Binding.qualify true (Binding.name_of b) (Binding.name thmN), []), [(thms, [])]))
bs thmss)
in
lthy |> Local_Theory.notes (Ibnf_common_notes @ Ibnf_notes) |> snd
end;
val common_notes =
[(fld_inductN, [fld_induct_thm]),
(fld_induct2N, [fld_induct2_thm])]
|> map (fn (thmN, thms) =>
((Binding.qualify true (Binding.name_of b) (Binding.name thmN), []), [(thms, [])]));
val notes =
[(iterN, iter_thms),
(iter_uniqueN, iter_unique_thms),
(recN, rec_thms),
(unf_fldN, unf_fld_thms),
(fld_unfN, fld_unf_thms),
(unf_injectN, unf_inject_thms),
(unf_exhaustN, unf_exhaust_thms),
(fld_injectN, fld_inject_thms),
(fld_exhaustN, fld_exhaust_thms)]
|> map (apsnd (map single))
|> maps (fn (thmN, thmss) =>
map2 (fn b => fn thms =>
((Binding.qualify true (Binding.name_of b) (Binding.name thmN), []), [(thms, [])]))
bs thmss)
in
((unfs, flds, unf_fld_thms, fld_unf_thms, fld_inject_thms),
lthy |> Local_Theory.notes (common_notes @ notes) |> snd)
end;
val _ =
Outer_Syntax.local_theory @{command_spec "data_raw"} "least fixed points for BNF equations"
(Parse.and_list1
((Parse.binding --| Parse.$$$ ":") -- (Parse.typ --| Parse.$$$ "=" -- Parse.typ)) >>
(snd oo fp_bnf_cmd bnf_lfp o apsnd split_list o split_list));
end;