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quot.ml
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quot.ml
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(* ========================================================================= *)
(* Tools for defining quotient types and lifting first order theorems. *)
(* *)
(* John Harrison, University of Cambridge Computer Laboratory *)
(* *)
(* (c) Copyright, University of Cambridge 1998 *)
(* (c) Copyright, John Harrison 1998-2007 *)
(* ========================================================================= *)
needs "thecops.ml";;
(* ------------------------------------------------------------------------- *)
(* Given a type name "ty" and a curried binary relation R, this defines *)
(* a new type "ty" of R-equivalence classes. The abstraction and *)
(* representation functions for the new type are called "mk_ty" and *)
(* "dest_ty". The type bijections (after beta-conversion) are returned: *)
(* *)
(* |- mk_ty (dest_ty a) = a *)
(* *)
(* |- (?x. r = R x) <=> (dest_ty (mk_ty r) = r) *)
(* ------------------------------------------------------------------------- *)
let define_quotient_type =
fun tyname (absname,repname) eqv ->
let ty = hd(snd(dest_type(type_of eqv))) in
let pty = mk_fun_ty ty bool_ty in
let s = mk_var("s",pty) and x = mk_var("x",ty) in
let eqvx = mk_comb(eqv,x) in
let pred = mk_abs(s,mk_exists(x,mk_eq(s,eqvx))) in
let th0 = BETA_CONV(mk_comb(pred,eqvx)) in
let th1 = EXISTS(rand(concl th0),x) (REFL eqvx) in
let th2 = EQ_MP (SYM th0) th1 in
let abs,rep = new_basic_type_definition tyname (absname,repname) th2 in
abs,CONV_RULE(LAND_CONV BETA_CONV) rep;;
(* ------------------------------------------------------------------------- *)
(* Given a welldefinedness theorem for a curried function f, of the form: *)
(* *)
(* |- !x1 x1' .. xn xn'. (x1 == x1') /\ ... /\ (xn == xn') *)
(* ==> (f x1 .. xn == f x1' .. f nx') *)
(* *)
(* where each "==" is either equality or some fixed binary relation R, a *)
(* new operator called "opname" is introduced which lifts "f" up to the *)
(* R-equivalence classes. Two theorems are returned: the actual definition *)
(* and a useful consequence for lifting theorems. *)
(* *)
(* The function also needs the second (more complicated) type bijection, and *)
(* the reflexivity and transitivity (not symmetry!) of the equivalence *)
(* relation. The use also gives a name for the new function. *)
(* ------------------------------------------------------------------------- *)
let lift_function =
let SELECT_LEMMA = prove
(`!x:A. (@y. x = y) = x`,
GEN_TAC THEN GEN_REWRITE_TAC (LAND_CONV o BINDER_CONV) [EQ_SYM_EQ] THEN
MATCH_ACCEPT_TAC SELECT_REFL) in
fun tybij2 ->
let tybl,tybr = dest_comb(concl tybij2) in
let eqvx = rand(body(rand(rand tybl))) in
let eqv,xtm = dest_comb eqvx in
let dmr,rtm = dest_eq tybr in
let dest,mrt = dest_comb dmr in
let mk = rator mrt in
let ety = type_of mrt in
fun (refl_th,trans_th) fname wth ->
let wtm = repeat (snd o dest_forall) (concl wth) in
let wfvs = frees wtm in
let hyps,con = try (conjuncts F_F I) (dest_imp wtm)
with Failure _ -> [],wtm in
let eqs,rels = partition is_eq hyps in
let rvs = map lhand rels in
let qvs = map lhs eqs in
let evs =
variants wfvs (map (fun v -> mk_var(fst(dest_var v),ety)) rvs) in
let mems = map2 (fun rv ev -> mk_comb(mk_comb(dest,ev),rv)) rvs evs in
let lcon,rcon = dest_comb con in
let u = variant (evs @ wfvs) (mk_var("u",type_of rcon)) in
let ucon = mk_comb(lcon,u) in
let dbod = list_mk_conj(ucon::mems) in
let detm = list_mk_exists(rvs,dbod) in
let datm = mk_abs(u,detm) in
let def =
if is_eq con then list_mk_icomb "@" [datm] else mk_comb(mk,datm) in
let newargs = map
(fun e -> try lhs e with Failure _ -> assoc (lhand e) (zip rvs evs)) hyps in
let rdef = list_mk_abs(newargs,def) in
let ldef = mk_var(fname,type_of rdef) in
let dth = new_definition(mk_eq(ldef,rdef)) in
let eth = rev_itlist
(fun v th -> CONV_RULE(RAND_CONV BETA_CONV) (AP_THM th v))
newargs dth in
let targs = map (fun v -> mk_comb(mk,mk_comb(eqv,v))) rvs in
let dme_th =
let th = INST [eqvx,rtm] tybij2 in
EQ_MP th (EXISTS(lhs(concl th),xtm) (REFL eqvx)) in
let ith = INST (zip targs evs) eth in
let jth = SUBS (map (fun v -> INST[v,xtm] dme_th) rvs) ith in
let apop,uxtm = dest_comb(rand(concl jth)) in
let extm = body uxtm in
let evs,bod = strip_exists extm in
let th1 = ASSUME bod in
let th2 =
if evs = [] then th1 else
let th2a,th2b = CONJ_PAIR th1 in
let ethlist = CONJUNCTS th2b @ map REFL qvs in
let th2c = end_itlist CONJ (map
(fun v -> find ((=) (lhand v) o lhand o concl) ethlist) hyps) in
let th2d = MATCH_MP wth th2c in
let th2e = try TRANS th2d th2a
with Failure _ -> MATCH_MP trans_th (CONJ th2d th2a) in
itlist SIMPLE_CHOOSE evs th2e in
let th3 = ASSUME(concl th2) in
let th4 = end_itlist CONJ (th3::(map (C SPEC refl_th) rvs)) in
let th5 = itlist SIMPLE_EXISTS evs (ASSUME bod) in
let th6 = MATCH_MP (DISCH_ALL th5) th4 in
let th7 = IMP_ANTISYM_RULE (DISCH_ALL th2) (DISCH_ALL th6) in
let th8 = TRANS jth (AP_TERM apop (ABS u th7)) in
let fconv = if is_eq con then REWR_CONV SELECT_LEMMA
else RAND_CONV ETA_CONV in
let th9 = CONV_RULE (RAND_CONV fconv) th8 in
eth,GSYM th9;;
(* ------------------------------------------------------------------------- *)
(* Lifts a theorem. This can be done by higher order rewriting alone. *)
(* *)
(* NB! All and only the first order variables must be bound by quantifiers. *)
(* ------------------------------------------------------------------------- *)
let lift_theorem =
let pth = prove
(`(!x:Repty. R x x) /\
(!x y. R x y <=> R y x) /\
(!x y z. R x y /\ R y z ==> R x z) /\
(!a. mk(dest a) = a) /\
(!r. (?x. r = R x) <=> (dest(mk r) = r))
==> (!x y. R x y <=> (mk(R x) = mk(R y))) /\
(!P. (!x. P(mk(R x))) <=> (!x. P x)) /\
(!P. (?x. P(mk(R x))) <=> (?x. P x)) /\
(!x:Absty. mk(R((@)(dest x))) = x)`,
STRIP_TAC THEN
SUBGOAL_THEN
`!x y. (mk((R:Repty->Repty->bool) x):Absty = mk(R y)) <=> (R x = R y)`
ASSUME_TAC THENL [ASM_MESON_TAC[]; ALL_TAC] THEN
MATCH_MP_TAC(TAUT `(a /\ b /\ c) /\ (b ==> a ==> d)
==> a /\ b /\ c /\ d`) THEN
CONJ_TAC THENL
[ASM_REWRITE_TAC[] THEN REWRITE_TAC[FUN_EQ_THM] THEN ASM_MESON_TAC[];
ALL_TAC] THEN
REPEAT(DISCH_THEN(fun th -> REWRITE_TAC[GSYM th])) THEN
X_GEN_TAC `x:Repty` THEN
SUBGOAL_THEN `dest(mk((R:Repty->Repty->bool) x):Absty) = R x`
SUBST1_TAC THENL [ASM_MESON_TAC[]; ALL_TAC] THEN
GEN_REWRITE_TAC (LAND_CONV o RAND_CONV) [GSYM ETA_AX] THEN
FIRST_ASSUM(fun th -> GEN_REWRITE_TAC I [th]) THEN
CONV_TAC SELECT_CONV THEN ASM_MESON_TAC[]) in
fun tybij (refl_th,sym_th,trans_th) ->
let tybij1 = GEN_ALL (fst tybij)
and tybij2 = GEN_ALL (snd tybij) in
let cth = end_itlist CONJ [refl_th; sym_th; trans_th; tybij1; tybij2] in
let ith = MATCH_MP pth cth in
fun trths ->
REWRITE_RULE (ith::trths);;