(* Title : HOL/Hyperreal/transfer.ML
ID : $Id$
Author : Brian Huffman
Transfer principle tactic for nonstandard analysis.
*)
signature TRANSFER =
sig
val transfer_tac: Proof.context -> thm list -> int -> tactic
val add_const: string -> theory -> theory
val setup: theory -> theory
end;
structure Transfer: TRANSFER =
struct
structure TransferData = GenericDataFun
(struct
val name = "HOL/transfer";
type T = {
intros: thm list,
unfolds: thm list,
refolds: thm list,
consts: string list
};
val empty = {intros = [], unfolds = [], refolds = [], consts = []};
val extend = I;
fun merge _
({intros = intros1, unfolds = unfolds1,
refolds = refolds1, consts = consts1},
{intros = intros2, unfolds = unfolds2,
refolds = refolds2, consts = consts2}) =
{intros = Drule.merge_rules (intros1, intros2),
unfolds = Drule.merge_rules (unfolds1, unfolds2),
refolds = Drule.merge_rules (refolds1, refolds2),
consts = Library.merge (op =) (consts1, consts2)} : T;
fun print _ _ = ();
end);
val transfer_start = thm "transfer_start"
fun unstar_typ (Type ("StarDef.star",[t])) = unstar_typ t
| unstar_typ (Type (a, Ts)) = Type (a, map unstar_typ Ts)
| unstar_typ T = T
fun unstar_term consts term =
let
fun unstar (Const(a,T) $ t) = if member (op =) consts a then (unstar t)
else (Const(a,unstar_typ T) $ unstar t)
| unstar (f $ t) = unstar f $ unstar t
| unstar (Const(a,T)) = Const(a,unstar_typ T)
| unstar (Abs(a,T,t)) = Abs(a,unstar_typ T,unstar t)
| unstar t = t
in
unstar term
end
fun transfer_thm_of ctxt ths t =
let
val thy = ProofContext.theory_of ctxt;
val {intros,unfolds,refolds,consts} = TransferData.get (Context.Proof ctxt)
val meta = LocalDefs.meta_rewrite_rule ctxt
val unfolds' = map meta unfolds and refolds' = map meta refolds;
val (_$_$t') = concl_of (Tactic.rewrite true unfolds' (cterm_of thy t))
val u = unstar_term consts t'
val tac =
rewrite_goals_tac (ths @ refolds' @ unfolds') THEN
ALLGOALS ObjectLogic.full_atomize_tac THEN
match_tac [transitive_thm] 1 THEN
resolve_tac [transfer_start] 1 THEN
REPEAT_ALL_NEW (resolve_tac intros) 1 THEN
match_tac [reflexive_thm] 1
in Goal.prove ctxt [] [] (Logic.mk_equals (t,u)) (K tac) end
fun transfer_tac ctxt ths =
SUBGOAL (fn (t,i) =>
(fn th =>
let val tr = transfer_thm_of ctxt ths t
in rewrite_goals_tac [tr] th end))
local
fun map_intros f = TransferData.map
(fn {intros,unfolds,refolds,consts} =>
{intros=f intros, unfolds=unfolds, refolds=refolds, consts=consts})
fun map_unfolds f = TransferData.map
(fn {intros,unfolds,refolds,consts} =>
{intros=intros, unfolds=f unfolds, refolds=refolds, consts=consts})
fun map_refolds f = TransferData.map
(fn {intros,unfolds,refolds,consts} =>
{intros=intros, unfolds=unfolds, refolds=f refolds, consts=consts})
in
val intro_add = Thm.declaration_attribute (map_intros o Drule.add_rule);
val intro_del = Thm.declaration_attribute (map_intros o Drule.del_rule);
val unfold_add = Thm.declaration_attribute (map_unfolds o Drule.add_rule);
val unfold_del = Thm.declaration_attribute (map_unfolds o Drule.del_rule);
val refold_add = Thm.declaration_attribute (map_refolds o Drule.add_rule);
val refold_del = Thm.declaration_attribute (map_refolds o Drule.del_rule);
end
fun add_const c = Context.theory_map (TransferData.map
(fn {intros,unfolds,refolds,consts} =>
{intros=intros, unfolds=unfolds, refolds=refolds, consts=c::consts}))
val transfer_method = Method.thms_ctxt_args (fn ths => fn ctxt =>
Method.SIMPLE_METHOD' HEADGOAL (transfer_tac ctxt ths));
val setup =
TransferData.init #>
Attrib.add_attributes
[("transfer_intro", Attrib.add_del_args intro_add intro_del,
"declaration of transfer introduction rule"),
("transfer_unfold", Attrib.add_del_args unfold_add unfold_del,
"declaration of transfer unfolding rule"),
("transfer_refold", Attrib.add_del_args refold_add refold_del,
"declaration of transfer refolding rule")] #>
Method.add_method ("transfer", transfer_method, "transfer principle");
end;