(* Author: Amine Chaieb, University of Cambridge, 2009
Jeremy Avigad, Carnegie Mellon University
Florian Haftmann, TU Muenchen
Simple transfer principle on theorems.
*)
signature TRANSFER =
sig
datatype selection = Direction of term * term | Hints of string list | Prop
val transfer: Context.generic -> selection -> string list -> thm -> thm list
type entry
val add: entry * entry -> thm -> Context.generic -> Context.generic
val del: thm -> Context.generic -> Context.generic
val setup: theory -> theory
end;
structure Transfer : TRANSFER =
struct
(* data administration *)
val direction_of = Thm.dest_binop o Thm.dest_arg o cprop_of;
fun check_morphism_key ctxt key =
let
val _ = (Thm.match o pairself Thm.cprop_of) (@{thm transfer_morphismI}, key)
handle Pattern.MATCH => error
("Transfer: expected theorem of the form " ^ quote (Display.string_of_thm ctxt @{thm transfer_morphismI}));
in direction_of key end;
type entry = { inj : thm list, embed : thm list, return : thm list, cong : thm list,
guess : bool, hints : string list };
fun merge_entry ({ inj = inj1, embed = embed1, return = return1, cong = cong1, guess = guess1, hints = hints1 } : entry,
{ inj = inj2, embed = embed2, return = return2, cong = cong2, guess = guess2, hints = hints2 } : entry) =
{ inj = merge Thm.eq_thm (inj1, inj2), embed = merge Thm.eq_thm (embed1, embed2),
return = merge Thm.eq_thm (return1, return2), cong = merge Thm.eq_thm (cong1, cong2),
guess = guess1 andalso guess2, hints = merge (op =) (hints1, hints2) };
structure Data = Generic_Data
(
type T = (thm * entry) list;
val empty = [];
val extend = I;
val merge = AList.join Thm.eq_thm (K merge_entry);
);
(* data lookup *)
fun get_by_direction context (a, D) =
let
val ctxt = Context.proof_of context;
val certify = Thm.cterm_of (Context.theory_of context);
val a0 = certify a;
val D0 = certify D;
fun eq_direction ((a, D), thm') =
let
val (a', D') = direction_of thm';
in a aconvc a' andalso D aconvc D' end;
in case AList.lookup eq_direction (Data.get context) (a0, D0) of
SOME e => ((a0, D0), e)
| NONE => error ("Transfer: no such instance: ("
^ Syntax.string_of_term ctxt a ^ ", " ^ Syntax.string_of_term ctxt D ^ ")")
end;
fun get_by_hints context hints =
let
val insts = map_filter (fn (k, e) => if exists (member (op =) (#hints e)) hints
then SOME (direction_of k, e) else NONE) (Data.get context);
val _ = if null insts then error ("Transfer: no such labels: " ^ commas (map quote hints)) else ();
in insts end;
fun splits P [] = []
| splits P (xs as (x :: _)) =
let
val (pss, qss) = List.partition (P x) xs;
in if null pss then [qss] else if null qss then [pss] else pss :: splits P qss end;
fun get_by_prop context t =
let
val tys = map snd (Term.add_vars t []);
val _ = if null tys then error "Transfer: unable to guess instance" else ();
val tyss = splits (curry Type.could_unify) tys;
val get_ty = typ_of o ctyp_of_term o fst o direction_of;
val insts = map_filter (fn tys => get_first (fn (k, ss) =>
if Type.could_unify (hd tys, range_type (get_ty k))
then SOME (direction_of k, ss)
else NONE) (Data.get context)) tyss;
val _ = if null insts then
error "Transfer: no instances, provide direction or hints explicitly" else ();
in insts end;
(* applying transfer data *)
fun transfer_thm inj_only a0 D0 { inj, embed, return, cong, guess = _, hints = _ }
leave ctxt0 th =
let
val ([a, D], ctxt) = apfst (map Drule.dest_term o snd)
(Variable.import true (map Drule.mk_term [a0, D0]) ctxt0);
val (aT, bT) =
let val T = typ_of (ctyp_of_term a)
in (Term.range_type T, Term.domain_type T) end;
val ctxt' = (Variable.declare_term (term_of a) o Variable.declare_term (term_of D)
o Variable.declare_thm th) ctxt;
val ns = filter (fn i => Type.could_unify (snd i, aT) andalso
not (member (op =) leave (fst (fst i)))) (Term.add_vars (prop_of th) []);
val (ins, ctxt'') = Variable.variant_fixes (map (fst o fst) ns) ctxt';
val certify = Thm.cterm_of (ProofContext.theory_of ctxt'');
val cns = map (certify o Var) ns;
val cfis = map (certify o (fn n => Free (n, bT))) ins;
val cis = map (Thm.capply a) cfis;
val (hs, ctxt''') = Assumption.add_assumes (map (fn ct =>
Thm.capply @{cterm "Trueprop"} (Thm.capply D ct)) cfis) ctxt'';
val th1 = Drule.cterm_instantiate (cns ~~ cis) th;
val th2 = fold Thm.elim_implies hs (fold_rev implies_intr (map cprop_of hs) th1);
val simpset = (Simplifier.context ctxt''' HOL_ss)
addsimps inj addsimps (if inj_only then [] else embed @ return) addcongs cong;
val th3 = Simplifier.asm_full_simplify simpset
(fold_rev implies_intr (map cprop_of hs) th2);
in hd (Variable.export ctxt''' ctxt0 [th3]) end;
fun transfer_thm_multiple inj_only insts leave ctxt thm =
map (fn ((a, D), e) => transfer_thm false a D e leave ctxt thm) insts;
datatype selection = Direction of term * term | Hints of string list | Prop;
fun insts_for context thm (Direction direction) = [get_by_direction context direction]
| insts_for context thm (Hints hints) = get_by_hints context hints
| insts_for context thm Prop = get_by_prop context (Thm.prop_of thm);
fun transfer context selection leave thm =
transfer_thm_multiple false (insts_for context thm selection) leave (Context.proof_of context) thm;
(* maintaining transfer data *)
fun merge_update eq m (k, v) [] = [(k, v)]
| merge_update eq m (k, v) ((k', v') :: al) =
if eq (k, k') then (k', m (v, v')) :: al else (k', v') :: merge_update eq m (k, v) al;
(*? fun merge_update eq m (k, v) = AList.map_entry eq k (fn v' => m (v, v'));*)
fun merge_entries {inj = inj0, embed = embed0, return = return0, cong = cong0, guess = guess0, hints = hints0}
({inj = inj1, embed = embed1, return = return1, cong = cong1, guess = guess1, hints = hints1},
{inj = inj2, embed = embed2, return = return2, cong = cong2, guess = guess2, hints = hints2} : entry) =
let
fun h xs0 xs ys = subtract Thm.eq_thm xs0 (merge Thm.eq_thm (xs, ys))
in
{inj = h inj0 inj1 inj2, embed = h embed0 embed1 embed2,
return = h return0 return1 return2, cong = h cong0 cong1 cong2, guess = guess1 andalso guess2,
hints = subtract (op =) hints0 (union (op =) hints1 hints2) }
end;
fun add (e0 as {inj = inja, embed = embeda, return = returna, cong = conga, guess = guess, hints = hintsa},
ed as {inj = injd, embed = embedd, return = returnd, cong = congd, guess = _, hints = hintsd}) key context =
context
|> Data.map (fn al =>
let
val ctxt = Context.proof_of context;
val (a0, D0) = check_morphism_key ctxt key;
val entry = if guess then
let
val inj' = if null inja then #inj
(case AList.lookup Thm.eq_thm al key of SOME e => e
| NONE => error "Transfer: cannot generate return rules on the fly, either add injectivity axiom or force manual mode with mode: manual")
else inja
val return' = merge Thm.eq_thm (returna, map
(fn th => transfer_thm true a0 D0 {inj = inj', embed = [], return = [], cong = conga,
guess = guess, hints = hintsa} [] ctxt th RS sym) embeda);
in {inj = inja, embed = embeda, return = return', cong = conga, guess = guess, hints = hintsa} end
else e0;
in merge_update Thm.eq_thm (merge_entries ed) (key, entry) al end);
fun del key = Data.map (remove (eq_fst Thm.eq_thm) (key, []));
(* syntax *)
local
fun these scan = Scan.optional scan [];
fun these_pair scan = Scan.optional scan ([], []);
fun keyword k = Scan.lift (Args.$$$ k) >> K ();
fun keyword_colon k = Scan.lift (Args.$$$ k -- Args.colon) >> K ();
val addN = "add";
val delN = "del";
val modeN = "mode";
val automaticN = "automatic";
val manualN = "manual";
val injN = "inj";
val embedN = "embed";
val returnN = "return";
val congN = "cong";
val labelsN = "labels";
val leavingN = "leaving";
val directionN = "direction";
val any_keyword = keyword_colon addN || keyword_colon delN || keyword_colon modeN
|| keyword_colon injN || keyword_colon embedN || keyword_colon returnN
|| keyword_colon congN || keyword_colon labelsN
|| keyword_colon leavingN || keyword_colon directionN;
val thms = Scan.repeat (Scan.unless any_keyword Attrib.multi_thm) >> flat;
val names = Scan.repeat (Scan.unless any_keyword (Scan.lift Args.name))
val mode = keyword_colon modeN |-- ((Scan.lift (Args.$$$ manualN) >> K false)
|| (Scan.lift (Args.$$$ automaticN) >> K true));
val inj = (keyword_colon injN |-- thms) -- these (keyword_colon delN |-- thms);
val embed = (keyword_colon embedN |-- thms) -- these (keyword_colon delN |-- thms);
val return = (keyword_colon returnN |-- thms) -- these (keyword_colon delN |-- thms);
val cong = (keyword_colon congN |-- thms) -- these (keyword_colon delN |-- thms);
val labels = (keyword_colon labelsN |-- names) -- these (keyword_colon delN |-- names);
val entry_pair = Scan.optional mode true -- these_pair inj -- these_pair embed
-- these_pair return -- these_pair cong -- these_pair labels
>> (fn (((((g, (inja, injd)), (embeda, embedd)), (returna, returnd)), (conga, congd)),
(hintsa, hintsd)) =>
({inj = inja, embed = embeda, return = returna, cong = conga, guess = g, hints = hintsa},
{inj = injd, embed = embedd, return = returnd, cong = congd, guess = g, hints = hintsd}));
val selection = (keyword_colon directionN |-- (Args.term -- Args.term) >> Direction)
|| these names >> (fn hints => if null hints then Prop else Hints hints);
in
val transfer_attribute = Scan.lift (Args.$$$ delN >> K (Thm.declaration_attribute del))
|| Scan.unless any_keyword (keyword addN) |-- entry_pair
>> (fn entry_pair => Thm.declaration_attribute (add entry_pair))
val transferred_attribute = selection -- these (keyword_colon leavingN |-- names)
>> (fn (selection, leave) => Thm.rule_attribute (fn context =>
Conjunction.intr_balanced o transfer context selection leave));
end;
(* theory setup *)
val setup =
Attrib.setup @{binding transfer} transfer_attribute
"Installs transfer data" #>
Attrib.setup @{binding transferred} transferred_attribute
"Transfers theorems";
end;