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nums.ml
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nums.ml
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(* ========================================================================= *)
(* The axiom of infinity; construction of the natural numbers. *)
(* *)
(* John Harrison, University of Cambridge Computer Laboratory *)
(* *)
(* (c) Copyright, University of Cambridge 1998 *)
(* (c) Copyright, John Harrison 1998-2007 *)
(* ========================================================================= *)
needs "pair.ml";;
(* ------------------------------------------------------------------------- *)
(* Declare a new type "ind" of individuals. *)
(* ------------------------------------------------------------------------- *)
new_type ("ind",0);;
(* ------------------------------------------------------------------------- *)
(* We assert the axiom of infinity as in HOL88, but then we can forget it! *)
(* ------------------------------------------------------------------------- *)
let ONE_ONE = new_definition
`ONE_ONE(f:A->B) = !x1 x2. (f x1 = f x2) ==> (x1 = x2)`;;
let ONTO = new_definition
`ONTO(f:A->B) = !y. ?x. y = f x`;;
let INFINITY_AX = new_axiom
`?f:ind->ind. ONE_ONE f /\ ~(ONTO f)`;;
(* ------------------------------------------------------------------------- *)
(* Actually introduce constants. *)
(* ------------------------------------------------------------------------- *)
let IND_SUC_0_EXISTS = prove
(`?(f:ind->ind) z. (!x1 x2. (f x1 = f x2) = (x1 = x2)) /\ (!x. ~(f x = z))`,
X_CHOOSE_TAC `f:ind->ind` INFINITY_AX THEN EXISTS_TAC `f:ind->ind` THEN
POP_ASSUM MP_TAC THEN REWRITE_TAC[ONE_ONE; ONTO] THEN MESON_TAC[]);;
let IND_SUC_SPEC =
let th1 = new_definition
`IND_SUC = @f:ind->ind. ?z. (!x1 x2. (f x1 = f x2) = (x1 = x2)) /\
(!x. ~(f x = z))` in
let th2 = REWRITE_RULE[GSYM th1] (SELECT_RULE IND_SUC_0_EXISTS) in
let th3 = new_definition
`IND_0 = @z:ind. (!x1 x2. IND_SUC x1 = IND_SUC x2 <=> x1 = x2) /\
(!x. ~(IND_SUC x = z))` in
REWRITE_RULE[GSYM th3] (SELECT_RULE th2);;
let IND_SUC_INJ,IND_SUC_0 = CONJ_PAIR IND_SUC_SPEC;;
(* ------------------------------------------------------------------------- *)
(* Carve out the natural numbers inductively. *)
(* ------------------------------------------------------------------------- *)
let NUM_REP_RULES,NUM_REP_INDUCT,NUM_REP_CASES =
new_inductive_definition
`NUM_REP IND_0 /\
(!i. NUM_REP i ==> NUM_REP (IND_SUC i))`;;
let num_tydef = new_basic_type_definition
"num" ("mk_num","dest_num")
(CONJUNCT1 NUM_REP_RULES);;
let ZERO_DEF = new_definition
`_0 = mk_num IND_0`;;
let SUC_DEF = new_definition
`SUC n = mk_num(IND_SUC(dest_num n))`;;
(* ------------------------------------------------------------------------- *)
(* Distinctness and injectivity of constructors. *)
(* ------------------------------------------------------------------------- *)
let NOT_SUC = prove
(`!n. ~(SUC n = _0)`,
REWRITE_TAC[SUC_DEF; ZERO_DEF] THEN
MESON_TAC[NUM_REP_RULES; fst num_tydef; snd num_tydef; IND_SUC_0]);;
let SUC_INJ = prove
(`!m n. SUC m = SUC n <=> m = n`,
REPEAT GEN_TAC THEN REWRITE_TAC[SUC_DEF] THEN
EQ_TAC THEN DISCH_TAC THEN ASM_REWRITE_TAC[] THEN
POP_ASSUM(MP_TAC o AP_TERM `dest_num`) THEN
SUBGOAL_THEN `!p. NUM_REP (IND_SUC (dest_num p))` MP_TAC THENL
[GEN_TAC THEN MATCH_MP_TAC (CONJUNCT2 NUM_REP_RULES); ALL_TAC] THEN
REWRITE_TAC[fst num_tydef; snd num_tydef] THEN
DISCH_TAC THEN ASM_REWRITE_TAC[IND_SUC_INJ] THEN
DISCH_THEN(MP_TAC o AP_TERM `mk_num`) THEN
REWRITE_TAC[fst num_tydef]);;
(* ------------------------------------------------------------------------- *)
(* Induction. *)
(* ------------------------------------------------------------------------- *)
let num_INDUCTION = prove
(`!P. P(_0) /\ (!n. P(n) ==> P(SUC n)) ==> !n. P n`,
REPEAT STRIP_TAC THEN
MP_TAC(SPEC `\i. NUM_REP i /\ P(mk_num i):bool` NUM_REP_INDUCT) THEN
ASM_REWRITE_TAC[GSYM ZERO_DEF; NUM_REP_RULES] THEN
W(C SUBGOAL_THEN (fun t -> REWRITE_TAC[t]) o funpow 2 lhand o snd) THENL
[REPEAT STRIP_TAC THENL
[MATCH_MP_TAC(CONJUNCT2 NUM_REP_RULES) THEN ASM_REWRITE_TAC[];
SUBGOAL_THEN `mk_num(IND_SUC i) = SUC(mk_num i)` SUBST1_TAC THENL
[REWRITE_TAC[SUC_DEF] THEN REPEAT AP_TERM_TAC THEN
CONV_TAC SYM_CONV THEN REWRITE_TAC[GSYM(snd num_tydef)] THEN
FIRST_ASSUM MATCH_ACCEPT_TAC;
FIRST_ASSUM MATCH_MP_TAC THEN FIRST_ASSUM MATCH_ACCEPT_TAC]];
DISCH_THEN(MP_TAC o SPEC `dest_num n`) THEN
REWRITE_TAC[fst num_tydef; snd num_tydef]]);;
(* ------------------------------------------------------------------------- *)
(* Recursion. *)
(* ------------------------------------------------------------------------- *)
let num_Axiom = prove
(`!(e:A) f. ?!fn. (fn _0 = e) /\
(!n. fn (SUC n) = f (fn n) n)`,
REPEAT GEN_TAC THEN ONCE_REWRITE_TAC[EXISTS_UNIQUE_THM] THEN CONJ_TAC THENL
[(MP_TAC o prove_inductive_relations_exist)
`PRG _0 e /\ (!b:A n:num. PRG n b ==> PRG (SUC n) (f b n))` THEN
DISCH_THEN(CHOOSE_THEN (CONJUNCTS_THEN2 ASSUME_TAC MP_TAC)) THEN
DISCH_THEN(CONJUNCTS_THEN2 ASSUME_TAC (ASSUME_TAC o GSYM)) THEN
SUBGOAL_THEN `!n:num. ?!y:A. PRG n y` MP_TAC THENL
[MATCH_MP_TAC num_INDUCTION THEN REPEAT STRIP_TAC THEN
FIRST_ASSUM(fun th -> GEN_REWRITE_TAC BINDER_CONV [GSYM th]) THEN
REWRITE_TAC[GSYM NOT_SUC; NOT_SUC; SUC_INJ; EXISTS_UNIQUE_REFL] THEN
REWRITE_TAC[UNWIND_THM1] THEN
UNDISCH_TAC `?!y. PRG (n:num) (y:A)` THEN
REWRITE_TAC[EXISTS_UNIQUE_THM] THEN
DISCH_THEN(CONJUNCTS_THEN2 (X_CHOOSE_TAC `y:A`) ASSUME_TAC) THEN
REPEAT STRIP_TAC THEN ASM_REWRITE_TAC[] THENL
[MAP_EVERY EXISTS_TAC [`(f:A->num->A) y n`; `y:A`];
AP_THM_TAC THEN AP_TERM_TAC THEN FIRST_ASSUM MATCH_MP_TAC] THEN
ASM_REWRITE_TAC[];
REWRITE_TAC[UNIQUE_SKOLEM_ALT] THEN
DISCH_THEN(X_CHOOSE_THEN `fn:num->A` (ASSUME_TAC o GSYM)) THEN
EXISTS_TAC `fn:num->A` THEN ASM_REWRITE_TAC[] THEN
GEN_TAC THEN FIRST_ASSUM(MATCH_MP_TAC o CONJUNCT2) THEN
FIRST_ASSUM(fun th -> GEN_REWRITE_TAC I [GSYM th]) THEN REFL_TAC];
REPEAT STRIP_TAC THEN ONCE_REWRITE_TAC[FUN_EQ_THM] THEN
MATCH_MP_TAC num_INDUCTION THEN ASM_REWRITE_TAC[] THEN
REPEAT STRIP_TAC THEN ASM_REWRITE_TAC[]]);;
(* ------------------------------------------------------------------------- *)
(* The basic numeral tag; rewrite existing instances of "_0". *)
(* ------------------------------------------------------------------------- *)
let NUMERAL =
let num_ty = type_of(lhand(concl ZERO_DEF)) in
let funn_ty = mk_fun_ty num_ty num_ty in
let numeral_tm = mk_var("NUMERAL",funn_ty) in
let n_tm = mk_var("n",num_ty) in
new_definition(mk_eq(mk_comb(numeral_tm,n_tm),n_tm));;
let [NOT_SUC; num_INDUCTION; num_Axiom] =
let th = prove(`_0 = 0`,REWRITE_TAC[NUMERAL]) in
map (GEN_REWRITE_RULE DEPTH_CONV [th])
[NOT_SUC; num_INDUCTION; num_Axiom];;
(* ------------------------------------------------------------------------- *)
(* Induction tactic. *)
(* ------------------------------------------------------------------------- *)
let (INDUCT_TAC:tactic) =
MATCH_MP_TAC num_INDUCTION THEN
CONJ_TAC THENL [ALL_TAC; GEN_TAC THEN DISCH_TAC];;
let num_RECURSION =
let avs = fst(strip_forall(concl num_Axiom)) in
GENL avs (EXISTENCE (SPECL avs num_Axiom));;
(* ------------------------------------------------------------------------- *)
(* Cases theorem. *)
(* ------------------------------------------------------------------------- *)
let num_CASES = prove
(`!m. (m = 0) \/ (?n. m = SUC n)`,
INDUCT_TAC THEN MESON_TAC[]);;
(* ------------------------------------------------------------------------- *)
(* Augmenting inductive type store. *)
(* ------------------------------------------------------------------------- *)
inductive_type_store :=
("num",(2,num_INDUCTION,num_RECURSION))::(!inductive_type_store);;
(* ------------------------------------------------------------------------- *)
(* "Bitwise" binary representation of numerals. *)
(* ------------------------------------------------------------------------- *)
let BIT0_DEF =
let funn_ty = type_of(rator(lhand(snd(dest_forall(concl NUMERAL))))) in
let bit0_tm = mk_var("BIT0",funn_ty) in
let def = new_definition
(mk_eq(bit0_tm,`@fn. fn 0 = 0 /\ (!n. fn (SUC n) = SUC (SUC(fn n)))`))
and th = BETA_RULE(ISPECL [`0`; `\m n:num. SUC(SUC m)`] num_RECURSION) in
REWRITE_RULE[GSYM def] (SELECT_RULE th);;
let BIT1_DEF =
let funn_ty = type_of(rator(lhand(lhand(concl BIT0_DEF)))) in
let num_ty = snd(dest_fun_ty funn_ty) in
let n_tm = mk_var("n",num_ty) in
let bit1_tm = mk_var("BIT1",funn_ty) in
new_definition(mk_eq(mk_comb(bit1_tm,n_tm),`SUC (BIT0 n)`));;
(* ------------------------------------------------------------------------- *)
(* Syntax operations on numerals. *)
(* ------------------------------------------------------------------------- *)
let mk_numeral =
let pow24 = pow2 24 and num_0 = Int 0
and zero_tm = mk_const("_0",[])
and BIT0_tm = mk_const("BIT0",[])
and BIT1_tm = mk_const("BIT1",[])
and NUMERAL_tm = mk_const("NUMERAL",[]) in
let rec stripzeros l = match l with false::t -> stripzeros t | _ -> l in
let rec raw_list_of_num l n =
if n =/ num_0 then stripzeros l else
let h = Num.int_of_num(mod_num n pow24) in
raw_list_of_num
((h land 8388608 <> 0)::(h land 4194304 <> 0)::(h land 2097152 <> 0)::
(h land 1048576 <> 0)::(h land 524288 <> 0)::(h land 262144 <> 0)::
(h land 131072 <> 0)::(h land 65536 <> 0)::(h land 32768 <> 0)::
(h land 16384 <> 0)::(h land 8192 <> 0)::(h land 4096 <> 0)::
(h land 2048 <> 0)::(h land 1024 <> 0)::(h land 512 <> 0)::
(h land 256 <> 0)::(h land 128 <> 0)::(h land 64 <> 0)::
(h land 32 <> 0)::(h land 16 <> 0)::(h land 8 <> 0)::(h land 4 <> 0)::
(h land 2 <> 0)::(h land 1 <> 0)::l) (quo_num n pow24) in
let rec numeral_of_list t l =
match l with
[] -> t
| b::r -> numeral_of_list(mk_comb((if b then BIT1_tm else BIT0_tm),t)) r in
let mk_raw_numeral n = numeral_of_list zero_tm (raw_list_of_num [] n) in
fun n -> if n </ num_0 then failwith "mk_numeral: negative argument" else
mk_comb(NUMERAL_tm,mk_raw_numeral n);;
let mk_small_numeral n = mk_numeral(Int n);;
let dest_small_numeral t = Num.int_of_num(dest_numeral t);;
let is_numeral = can dest_numeral;;
(* ------------------------------------------------------------------------- *)
(* Derived principles of definition based on existence. *)
(* *)
(* This is put here because we use numerals as tags to force different *)
(* constants specified with equivalent theorems to have different underlying *)
(* definitions, ensuring that there are no provable equalities between them *)
(* and so in some sense the constants are "underspecified" as the user might *)
(* want for some applications. *)
(* ------------------------------------------------------------------------- *)
let the_specifications = ref ([]: ((string list * thm) * thm) list);;
let new_specification =
let code c = mk_small_numeral (Char.ord (String.sub c 0)) in
let mk_code name =
end_itlist (curry mk_pair) (map code (explode name)) in
let check_distinct l =
try itlist (fun t res -> if mem t res then fail() else t::res) l []; true
with Failure _ -> false in
let specify name th =
let ntm = mk_code name in
let gv = genvar(type_of ntm) in
let th0 = CONV_RULE(REWR_CONV SKOLEM_THM) (GEN gv th) in
let th1 = CONV_RULE(RATOR_CONV (REWR_CONV EXISTS_THM) THENC
BETA_CONV) th0 in
let l,r = dest_comb(concl th1) in
let rn = mk_comb(r,ntm) in
let ty = type_of rn in
let th2 = new_definition(mk_eq(mk_var(name,ty),rn)) in
GEN_REWRITE_RULE ONCE_DEPTH_CONV [GSYM th2]
(SPEC ntm (CONV_RULE BETA_CONV th1)) in
let rec specifies names th =
match names with
[] -> th
| name::onames -> let th' = specify name th in
specifies onames th' in
fun names th ->
let asl,c = dest_thm th in
if not (asl = []) then
failwith "new_specification: Assumptions not allowed in theorem" else
if not (frees c = []) then
failwith "new_specification: Free variables in predicate" else
let avs = fst(strip_exists c) in
if length names = 0 || length names > length avs then
failwith "new_specification: Unsuitable number of constant names" else
if not (check_distinct names) then
failwith "new_specification: Constant names not distinct"
else
try let sth = snd(find (fun ((names',th'),sth') ->
names' = names && aconv (concl th') (concl th))
(!the_specifications)) in
warn true ("Benign respecification"); sth
with Failure _ ->
let sth = specifies names th in
the_specifications := ((names,th),sth)::(!the_specifications);
sth;;