(* ========================================================================= *)
(* Theory of integers. *)
(* *)
(* The integers are carved out of the real numbers; hence all the *)
(* universal theorems can be derived trivially from the real analog. *)
(* *)
(* John Harrison, University of Cambridge Computer Laboratory *)
(* *)
(* (c) Copyright, University of Cambridge 1998 *)
(* (c) Copyright, John Harrison 1998-2007 *)
(* ========================================================================= *)
needs "calc_rat.ml";;
(* ------------------------------------------------------------------------- *)
(* Representing predicate. The "is_int" variant is useful for backwards *)
(* compatibility with former definition of "is_int" constant, now removed. *)
(* ------------------------------------------------------------------------- *)
let is_int = prove
(`integer(x) <=> ?n. x = &n \/ x = -- &n`,
REWRITE_TAC[integer] THEN AP_TERM_TAC THEN ABS_TAC THEN REAL_ARITH_TAC);;
(* ------------------------------------------------------------------------- *)
(* Type of integers. *)
(* ------------------------------------------------------------------------- *)
let int_tybij = new_type_definition "int" ("int_of_real","real_of_int")
(prove(`?x. integer x`,
EXISTS_TAC `&0` THEN
REWRITE_TAC[is_int; REAL_OF_NUM_EQ; EXISTS_OR_THM; GSYM EXISTS_REFL]));;
let int_abstr,int_rep =
SPEC_ALL(CONJUNCT1 int_tybij),SPEC_ALL(CONJUNCT2 int_tybij);;
let dest_int_rep = prove
(`!i. ?n. (real_of_int i = &n) \/ (real_of_int i = --(&n))`,
REWRITE_TAC[GSYM
is_int; int_rep; int_abstr]);;
(* ------------------------------------------------------------------------- *)
(* We want the following too. *)
(* ------------------------------------------------------------------------- *)
let int_eq = prove
(`!x y. (x = y) <=> (real_of_int x = real_of_int y)`,
REPEAT GEN_TAC THEN EQ_TAC THEN DISCH_TAC THEN ASM_REWRITE_TAC[] THEN
POP_ASSUM(MP_TAC o AP_TERM `int_of_real`) THEN
REWRITE_TAC[int_abstr]);;
(* ------------------------------------------------------------------------- *)
(* Set up interface map. *)
(* ------------------------------------------------------------------------- *)
do_list overload_interface
["+",`int_add:int->int->int`; "-",`int_sub:int->int->int`;
"*",`int_mul:int->int->int`; "<",`int_lt:int->int->bool`;
"<=",`int_le:int->int->bool`; ">",`int_gt:int->int->bool`;
">=",`int_ge:int->int->bool`; "--",`int_neg:int->int`;
"pow",`int_pow:int->num->int`; "abs",`int_abs:int->int`;
"max",`int_max:int->int->int`; "min",`int_min:int->int->int`;
"&",`int_of_num:num->int`];;
let prioritize_int() = prioritize_overload(mk_type("int",[]));;
(* ------------------------------------------------------------------------- *)
(* Definitions and closure derivations of all operations but "inv" and "/". *)
(* ------------------------------------------------------------------------- *)
let int_le = new_definition
`x <= y <=> (real_of_int x) <= (real_of_int y)`;;
let int_lt = new_definition
`x < y <=> (real_of_int x) < (real_of_int y)`;;
let int_ge = new_definition
`x >= y <=> (real_of_int x) >= (real_of_int y)`;;
let int_gt = new_definition
`x > y <=> (real_of_int x) > (real_of_int y)`;;
let int_of_num = new_definition
`&n = int_of_real(real_of_num n)`;;
let int_neg = new_definition
`--i = int_of_real(--(real_of_int i))`;;
let int_add = new_definition
`x + y = int_of_real((real_of_int x) + (real_of_int y))`;;
let int_sub = new_definition
`x - y = int_of_real(real_of_int x - real_of_int y)`;;
let int_mul = new_definition
`x * y = int_of_real ((real_of_int x) * (real_of_int y))`;;
let int_abs = new_definition
`abs x = int_of_real(abs(real_of_int x))`;;
let int_max = new_definition
`int_max x y = int_of_real(max (real_of_int x) (real_of_int y))`;;
let int_max_th = prove
(`!x y. real_of_int(max x y) = max (real_of_int x) (real_of_int y)`,
REPEAT GEN_TAC THEN REWRITE_TAC[
int_max;
real_max] THEN
COND_CASES_TAC THEN REWRITE_TAC[int_abstr]);;
let int_min = new_definition
`int_min x y = int_of_real(min (real_of_int x) (real_of_int y))`;;
let int_min_th = prove
(`!x y. real_of_int(min x y) = min (real_of_int x) (real_of_int y)`,
REPEAT GEN_TAC THEN REWRITE_TAC[
int_min;
real_min] THEN
COND_CASES_TAC THEN REWRITE_TAC[int_abstr]);;
let int_pow = new_definition
`x pow n = int_of_real((real_of_int x) pow n)`;;
(* ------------------------------------------------------------------------- *)
(* A couple of theorems peculiar to the integers. *)
(* ------------------------------------------------------------------------- *)
let INT_IMAGE = prove
(`!x. (?n. x = &n) \/ (?n. x = --(&n))`,
GEN_TAC THEN
X_CHOOSE_THEN `n:num` DISJ_CASES_TAC (SPEC `x:int`
dest_int_rep) THEN
POP_ASSUM(MP_TAC o AP_TERM `int_of_real`) THEN REWRITE_TAC[int_abstr] THEN
DISCH_THEN SUBST1_TAC THEN REWRITE_TAC[
int_of_num;
int_neg] THENL
[DISJ1_TAC; DISJ2_TAC] THEN
EXISTS_TAC `n:num` THEN REWRITE_TAC[int_abstr] THEN
REWRITE_TAC[GSYM
int_of_num;
int_of_num_th]);;
(* ------------------------------------------------------------------------- *)
(* Conversions of integer constants to and from OCaml numbers. *)
(* ------------------------------------------------------------------------- *)
let is_intconst tm =
match tm with
Comb(Const("int_of_num",_),n) -> is_numeral n
| Comb(Const("int_neg",_),Comb(Const("int_of_num",_),n)) ->
is_numeral n & not(dest_numeral n = num_0)
| _ -> false;;
let dest_intconst tm =
match tm with
Comb(Const("int_of_num",_),n) -> dest_numeral n
| Comb(Const("int_neg",_),Comb(Const("int_of_num",_),n)) ->
let nn = dest_numeral n in
if nn <>/ num_0 then minus_num(dest_numeral n)
else failwith "dest_intconst"
| _ -> failwith "dest_intconst";;
let mk_intconst =
let cast_tm = `int_of_num` and neg_tm = `int_neg` in
let mk_numconst n = mk_comb(cast_tm,mk_numeral n) in
fun x -> if x </ num_0 then mk_comb(neg_tm,mk_numconst(minus_num x))
else mk_numconst x;;
(* ------------------------------------------------------------------------- *)
(* A simple procedure to lift most universal real theorems to integers. *)
(* For a more complete procedure, give required term to INT_ARITH (below). *)
(* ------------------------------------------------------------------------- *)
let INT_OF_REAL_THM =
let dest = `real_of_int`
and real_ty = `:real`
and int_ty = `:int`
and cond_th = prove
(`real_of_int(if b then x else y) =
if b then real_of_int x else real_of_int y`,
COND_CASES_TAC THEN REWRITE_TAC[]) in
let thlist = map GSYM
[int_eq; int_le; int_lt; int_ge; int_gt;
int_of_num_th; int_neg_th; int_add_th; int_mul_th; int_sgn_th;
int_sub_th; int_abs_th; int_max_th; int_min_th; int_pow_th; cond_th] in
let REW_RULE = GEN_REWRITE_RULE DEPTH_CONV thlist in
let int_tm_of_real_var v =
let s,ty = dest_var v in
if ty = real_ty then mk_comb(dest,mk_var(s,int_ty)) else v in
let int_of_real_var v =
let s,ty = dest_var v in
if ty = real_ty then mk_var(s,int_ty) else v in
let INT_OF_REAL_THM1 th =
let newavs = subtract (frees (concl th)) (freesl (hyp th)) in
let avs,bod = strip_forall(concl th) in
let allavs = newavs@avs in
let avs' = map int_tm_of_real_var allavs in
let avs'' = map int_of_real_var avs in
GENL avs'' (REW_RULE(SPECL avs' (GENL newavs th))) in
let rec INT_OF_REAL_THM th =
if is_conj(concl th) then CONJ (INT_OF_REAL_THM (CONJUNCT1 th))
(INT_OF_REAL_THM (CONJUNCT2 th))
else INT_OF_REAL_THM1 th in
INT_OF_REAL_THM;;
(* ------------------------------------------------------------------------- *)
(* Collect together all the theorems derived automatically. *)
(* ------------------------------------------------------------------------- *)
(* ------------------------------------------------------------------------- *)
(* More useful "image" theorems. *)
(* ------------------------------------------------------------------------- *)
(* ------------------------------------------------------------------------- *)
(* Sometimes handy in number-theoretic applications. *)
(* ------------------------------------------------------------------------- *)
let INT_WOP = prove
(`(?x. &0 <= x /\ P x) <=>
(?x. &0 <= x /\ P x /\ !y. &0 <= y /\ P y ==> x <= y)`,
(* ------------------------------------------------------------------------- *)
(* A few "pseudo definitions". *)
(* ------------------------------------------------------------------------- *)
let INT_POW = prove
(`(x pow 0 = &1) /\
(!n. x pow (SUC n) = x * x pow n)`,
REWRITE_TAC(map INT_OF_REAL_THM (CONJUNCTS
real_pow)));;
let INT_ABS = prove
(`!x. abs(x) = if &0 <= x then x else --x`,
GEN_TAC THEN MP_TAC(INT_OF_REAL_THM(SPEC `x:real`
real_abs)) THEN
COND_CASES_TAC THEN REWRITE_TAC[
int_eq]);;
(* ------------------------------------------------------------------------- *)
(* Now a decision procedure for the integers. *)
(* ------------------------------------------------------------------------- *)
let INT_ARITH =
let atom_CONV =
let pth = prove
(`(~(x <= y) <=> y + &1 <= x) /\
(~(x < y) <=> y <= x) /\
(~(x = y) <=> x + &1 <= y \/ y + &1 <= x) /\
(x < y <=> x + &1 <= y)`,
REWRITE_TAC[
INT_NOT_LE;
INT_NOT_LT;
INT_NOT_EQ;
INT_LT_DISCRETE]) in
GEN_REWRITE_CONV I [pth]
and bub_CONV = GEN_REWRITE_CONV TOP_SWEEP_CONV
[
int_eq;
int_le;
int_lt;
int_ge;
int_gt;
int_of_num_th;
int_neg_th;
int_add_th;
int_mul_th;
int_sub_th;
int_pow_th;
int_abs_th;
int_max_th;
int_min_th] in
let base_CONV = TRY_CONV atom_CONV THENC bub_CONV in
let NNF_NORM_CONV = GEN_NNF_CONV false
(base_CONV,fun t -> base_CONV t,base_CONV(mk_neg t)) in
let init_CONV =
TOP_DEPTH_CONV BETA_CONV THENC
PRESIMP_CONV THENC
GEN_REWRITE_CONV DEPTH_CONV [
INT_GT;
INT_GE] THENC
NNF_CONV THENC DEPTH_BINOP_CONV `(\/)` CONDS_ELIM_CONV THENC
NNF_NORM_CONV in
let p_tm = `p:bool`
and not_tm = `(~)` in
let pth = TAUT(mk_eq(mk_neg(mk_neg p_tm),p_tm)) in
fun tm ->
let th0 = INST [tm,p_tm] pth
and th1 = init_CONV (mk_neg tm) in
let th2 = REAL_ARITH(mk_neg(rand(concl th1))) in
EQ_MP th0 (EQ_MP (AP_TERM not_tm (SYM th1)) th2);;
let INT_ARITH_TAC = CONV_TAC(EQT_INTRO o INT_ARITH);;
let ASM_INT_ARITH_TAC =
REPEAT(FIRST_X_ASSUM(MP_TAC o check (not o is_forall o concl))) THEN
INT_ARITH_TAC;;
(* ------------------------------------------------------------------------- *)
(* Some pseudo-definitions. *)
(* ------------------------------------------------------------------------- *)
let INT_SUB = INT_ARITH `!x y. x - y = x + --y`;;
let INT_MAX = INT_ARITH `!x y. max x y = if x <= y then y else x`;;
let INT_MIN = INT_ARITH `!x y. min x y = if x <= y then x else y`;;
(* ------------------------------------------------------------------------- *)
(* Another useful lemma. *)
(* ------------------------------------------------------------------------- *)
(* ------------------------------------------------------------------------- *)
(* Archimedian property for the integers. *)
(* ------------------------------------------------------------------------- *)
let INT_ARCH = prove
(`!x d. ~(d = &0) ==> ?c. x < c * d`,
SUBGOAL_THEN `!x. &0 <= x ==> ?n. x <= &n` ASSUME_TAC THENL
[REWRITE_TAC[GSYM
INT_FORALL_POS;
INT_OF_NUM_LE] THEN MESON_TAC[
LE_REFL];
ALL_TAC] THEN
SUBGOAL_THEN `!x. ?n. x <= &n` ASSUME_TAC THENL
[ASM_MESON_TAC[
INT_LE_TOTAL]; ALL_TAC] THEN
SUBGOAL_THEN `!x d. &0 < d ==> ?c. x < c * d` ASSUME_TAC THENL
[REPEAT GEN_TAC THEN REWRITE_TAC[
INT_LT_DISCRETE;
INT_ADD_LID] THEN
ASM_MESON_TAC[
INT_POS;
INT_LE_LMUL; INT_ARITH
`x + &1 <= &n /\ &n * &1 <= &n * d ==> x + &1 <= &n * d`];
ALL_TAC] THEN
SUBGOAL_THEN `!x d. ~(d = &0) ==> ?c. x < c * d` ASSUME_TAC THENL
[ASM_MESON_TAC[INT_ARITH `--x * y = x * --y`;
INT_ARITH `~(d = &0) ==> &0 < d \/ &0 < --d`];
ALL_TAC] THEN
ASM_MESON_TAC[INT_ARITH `--x * y = x * --y`;
INT_ARITH `~(d = &0) ==> &0 < d \/ &0 < --d`]);;
(* ------------------------------------------------------------------------- *)
(* Definitions of ("Euclidean") integer division and remainder. *)
(* ------------------------------------------------------------------------- *)
let INT_DIVMOD_EXIST_0 = prove
(`!m n:int. ?q r. if n = &0 then q = &0 /\ r = m
else &0 <= r /\ r < abs(n) /\ m = q * n + r`,
REPEAT GEN_TAC THEN ASM_CASES_TAC `n = &0` THEN
ASM_REWRITE_TAC[
RIGHT_EXISTS_AND_THM;
EXISTS_REFL] THEN
GEN_REWRITE_TAC I [
SWAP_EXISTS_THM] THEN
SUBGOAL_THEN `?r. &0 <= r /\ ?q:int. m = n * q + r` MP_TAC THENL
[FIRST_ASSUM(MP_TAC o SPEC `--m:int` o MATCH_MP
INT_ARCH) THEN
DISCH_THEN(X_CHOOSE_TAC `s:int`) THEN
EXISTS_TAC `m + s * n:int` THEN CONJ_TAC THENL
[ASM_INT_ARITH_TAC; EXISTS_TAC `--s:int` THEN INT_ARITH_TAC];
GEN_REWRITE_TAC LAND_CONV [
INT_WOP] THEN
MATCH_MP_TAC
MONO_EXISTS THEN X_GEN_TAC `r:int` THEN
REWRITE_TAC[
LEFT_AND_EXISTS_THM;
RIGHT_AND_EXISTS_THM] THEN
MATCH_MP_TAC
MONO_EXISTS THEN X_GEN_TAC `q:int` THEN STRIP_TAC THEN
ASM_REWRITE_TAC[] THEN FIRST_X_ASSUM(MP_TAC o SPEC `r - abs n`) THEN
REWRITE_TAC[
LEFT_IMP_EXISTS_THM] THEN
DISCH_THEN(MP_TAC o SPEC `if &0 <= n then q + &1 else q - &1`) THEN
ASM_INT_ARITH_TAC]);;
parse_as_infix("div",(22,"left"));;
parse_as_infix("rem",(22,"left"));;
"rem"]
(REWRITE_RULE[SKOLEM_THM] INT_DIVMOD_EXIST_0);;
let INT_DIVISION = prove
(`!m n. ~(n = &0)
==> m = m div n * n + m rem n /\ &0 <= m rem n /\ m rem n < abs n`,
(* ------------------------------------------------------------------------- *)
(* Arithmetic operations on integers. Essentially a clone of stuff for reals *)
(* in the file "calc_int.ml", except for div and rem, which are more like N. *)
(* ------------------------------------------------------------------------- *)
let INT_LE_CONV,INT_LT_CONV,INT_GE_CONV,INT_GT_CONV,INT_EQ_CONV =
let tth =
TAUT `(F /\ F <=> F) /\ (F /\ T <=> F) /\
(T /\ F <=> F) /\ (T /\ T <=> T)` in
let nth = TAUT `(~T <=> F) /\ (~F <=> T)` in
let NUM2_EQ_CONV = BINOP_CONV NUM_EQ_CONV THENC GEN_REWRITE_CONV I [tth] in
let NUM2_NE_CONV =
RAND_CONV NUM2_EQ_CONV THENC
GEN_REWRITE_CONV I [nth] in
let [pth_le1; pth_le2a; pth_le2b; pth_le3] = (CONJUNCTS o prove)
(`(--(&m) <= &n <=> T) /\
(&m <= &n <=> m <= n) /\
(--(&m) <= --(&n) <=> n <= m) /\
(&m <= --(&n) <=> (m = 0) /\ (n = 0))`,
REWRITE_TAC[INT_LE_NEG2] THEN
REWRITE_TAC[INT_LE_LNEG; INT_LE_RNEG] THEN
REWRITE_TAC[INT_OF_NUM_ADD; INT_OF_NUM_LE; LE_0] THEN
REWRITE_TAC[LE; ADD_EQ_0]) in
let INT_LE_CONV = FIRST_CONV
[GEN_REWRITE_CONV I [pth_le1];
GEN_REWRITE_CONV I [pth_le2a; pth_le2b] THENC NUM_LE_CONV;
GEN_REWRITE_CONV I [pth_le3] THENC NUM2_EQ_CONV] in
let [pth_lt1; pth_lt2a; pth_lt2b; pth_lt3] = (CONJUNCTS o prove)
(`(&m < --(&n) <=> F) /\
(&m < &n <=> m < n) /\
(--(&m) < --(&n) <=> n < m) /\
(--(&m) < &n <=> ~((m = 0) /\ (n = 0)))`,
REWRITE_TAC[pth_le1; pth_le2a; pth_le2b; pth_le3;
GSYM NOT_LE; INT_LT] THEN
CONV_TAC TAUT) in
let INT_LT_CONV = FIRST_CONV
[GEN_REWRITE_CONV I [pth_lt1];
GEN_REWRITE_CONV I [pth_lt2a; pth_lt2b] THENC NUM_LT_CONV;
GEN_REWRITE_CONV I [pth_lt3] THENC NUM2_NE_CONV] in
let [pth_ge1; pth_ge2a; pth_ge2b; pth_ge3] = (CONJUNCTS o prove)
(`(&m >= --(&n) <=> T) /\
(&m >= &n <=> n <= m) /\
(--(&m) >= --(&n) <=> m <= n) /\
(--(&m) >= &n <=> (m = 0) /\ (n = 0))`,
REWRITE_TAC[pth_le1; pth_le2a; pth_le2b; pth_le3; INT_GE] THEN
CONV_TAC TAUT) in
let INT_GE_CONV = FIRST_CONV
[GEN_REWRITE_CONV I [pth_ge1];
GEN_REWRITE_CONV I [pth_ge2a; pth_ge2b] THENC NUM_LE_CONV;
GEN_REWRITE_CONV I [pth_ge3] THENC NUM2_EQ_CONV] in
let [pth_gt1; pth_gt2a; pth_gt2b; pth_gt3] = (CONJUNCTS o prove)
(`(--(&m) > &n <=> F) /\
(&m > &n <=> n < m) /\
(--(&m) > --(&n) <=> m < n) /\
(&m > --(&n) <=> ~((m = 0) /\ (n = 0)))`,
REWRITE_TAC[pth_lt1; pth_lt2a; pth_lt2b; pth_lt3; INT_GT] THEN
CONV_TAC TAUT) in
let INT_GT_CONV = FIRST_CONV
[GEN_REWRITE_CONV I [pth_gt1];
GEN_REWRITE_CONV I [pth_gt2a; pth_gt2b] THENC NUM_LT_CONV;
GEN_REWRITE_CONV I [pth_gt3] THENC NUM2_NE_CONV] in
let [pth_eq1a; pth_eq1b; pth_eq2a; pth_eq2b] = (CONJUNCTS o prove)
(`((&m = &n) <=> (m = n)) /\
((--(&m) = --(&n)) <=> (m = n)) /\
((--(&m) = &n) <=> (m = 0) /\ (n = 0)) /\
((&m = --(&n)) <=> (m = 0) /\ (n = 0))`,
REWRITE_TAC[GSYM INT_LE_ANTISYM; GSYM LE_ANTISYM] THEN
REWRITE_TAC[pth_le1; pth_le2a; pth_le2b; pth_le3; LE; LE_0] THEN
CONV_TAC TAUT) in
let INT_EQ_CONV = FIRST_CONV
[GEN_REWRITE_CONV I [pth_eq1a; pth_eq1b] THENC NUM_EQ_CONV;
GEN_REWRITE_CONV I [pth_eq2a; pth_eq2b] THENC NUM2_EQ_CONV] in
INT_LE_CONV,INT_LT_CONV,
INT_GE_CONV,INT_GT_CONV,INT_EQ_CONV;;
let INT_NEG_CONV =
let INT_MUL_CONV =
let pth0 = prove
(`(&0 * &x = &0) /\
(&0 * --(&x) = &0) /\
(&x * &0 = &0) /\
(--(&x) * &0 = &0)`,
REWRITE_TAC[
INT_MUL_LZERO;
INT_MUL_RZERO])
and pth1,pth2 = (CONJ_PAIR o
prove)
(`((&m * &n = &(m * n)) /\
(--(&m) * --(&n) = &(m * n))) /\
((--(&m) * &n = --(&(m * n))) /\
(&m * --(&n) = --(&(m * n))))`,
REWRITE_TAC[
INT_MUL_LNEG;
INT_MUL_RNEG;
INT_NEG_NEG] THEN
REWRITE_TAC[
INT_OF_NUM_MUL]) in
FIRST_CONV
[GEN_REWRITE_CONV I [pth0];
GEN_REWRITE_CONV I [pth1] THENC RAND_CONV NUM_MULT_CONV;
GEN_REWRITE_CONV I [pth2] THENC RAND_CONV(RAND_CONV NUM_MULT_CONV)];;
let INT_ADD_CONV =
let neg_tm = `(--)` in
let amp_tm = `&` in
let add_tm = `(+)` in
let dest = dest_binop `(+)` in
let m_tm = `m:num` and n_tm = `n:num` in
let pth0 = prove
(`(--(&m) + &m = &0) /\
(&m + --(&m) = &0)`,
REWRITE_TAC[
INT_ADD_LINV;
INT_ADD_RINV]) in
let [pth1; pth2; pth3; pth4; pth5; pth6] = (CONJUNCTS o
prove)
(`(--(&m) + --(&n) = --(&(m + n))) /\
(--(&m) + &(m + n) = &n) /\
(--(&(m + n)) + &m = --(&n)) /\
(&(m + n) + --(&m) = &n) /\
(&m + --(&(m + n)) = --(&n)) /\
(&m + &n = &(m + n))`,
REWRITE_TAC[GSYM
INT_OF_NUM_ADD;
INT_NEG_ADD] THEN
REWRITE_TAC[
INT_ADD_ASSOC;
INT_ADD_LINV;
INT_ADD_LID] THEN
REWRITE_TAC[
INT_ADD_RINV;
INT_ADD_LID] THEN
ONCE_REWRITE_TAC[
INT_ADD_SYM] THEN
REWRITE_TAC[
INT_ADD_ASSOC;
INT_ADD_LINV;
INT_ADD_LID] THEN
REWRITE_TAC[
INT_ADD_RINV;
INT_ADD_LID]) in
GEN_REWRITE_CONV I [pth0] ORELSEC
(fun tm ->
try let l,r = dest tm in
if rator l = neg_tm then
if rator r = neg_tm then
let th1 = INST [rand(rand l),m_tm; rand(rand r),n_tm] pth1 in
let tm1 = rand(rand(rand(concl th1))) in
let th2 = AP_TERM neg_tm (AP_TERM amp_tm (NUM_ADD_CONV tm1)) in
TRANS th1 th2
else
let m = rand(rand l) and n = rand r in
let m' = dest_numeral m and n' = dest_numeral n in
if m' <=/ n' then
let p = mk_numeral (n' -/ m') in
let th1 = INST [m,m_tm; p,n_tm] pth2 in
let th2 = NUM_ADD_CONV (rand(rand(lhand(concl th1)))) in
let th3 = AP_TERM (rator tm) (AP_TERM amp_tm (SYM th2)) in
TRANS th3 th1
else
let p = mk_numeral (m' -/ n') in
let th1 = INST [n,m_tm; p,n_tm] pth3 in
let th2 = NUM_ADD_CONV (rand(rand(lhand(lhand(concl th1))))) in
let th3 = AP_TERM neg_tm (AP_TERM amp_tm (SYM th2)) in
let th4 = AP_THM (AP_TERM add_tm th3) (rand tm) in
TRANS th4 th1
else
if rator r = neg_tm then
let m = rand l and n = rand(rand r) in
let m' = dest_numeral m and n' = dest_numeral n in
if n' <=/ m' then
let p = mk_numeral (m' -/ n') in
let th1 = INST [n,m_tm; p,n_tm] pth4 in
let th2 = NUM_ADD_CONV (rand(lhand(lhand(concl th1)))) in
let th3 = AP_TERM add_tm (AP_TERM amp_tm (SYM th2)) in
let th4 = AP_THM th3 (rand tm) in
TRANS th4 th1
else
let p = mk_numeral (n' -/ m') in
let th1 = INST [m,m_tm; p,n_tm] pth5 in
let th2 = NUM_ADD_CONV (rand(rand(rand(lhand(concl th1))))) in
let th3 = AP_TERM neg_tm (AP_TERM amp_tm (SYM th2)) in
let th4 = AP_TERM (rator tm) th3 in
TRANS th4 th1
else
let th1 = INST [rand l,m_tm; rand r,n_tm] pth6 in
let tm1 = rand(rand(concl th1)) in
let th2 = AP_TERM amp_tm (NUM_ADD_CONV tm1) in
TRANS th1 th2
with Failure _ -> failwith "INT_ADD_CONV");;
let INT_SUB_CONV =
GEN_REWRITE_CONV I [INT_SUB] THENC
TRY_CONV(RAND_CONV INT_NEG_CONV) THENC
INT_ADD_CONV;;
let INT_POW_CONV =
let pth1,pth2 = (CONJ_PAIR o prove)
(`(&x pow n = &(x EXP n)) /\
((--(&x)) pow n = if EVEN n then &(x EXP n) else --(&(x EXP n)))`,
REWRITE_TAC[INT_OF_NUM_POW; INT_POW_NEG]) in
let tth = prove
(`((if T then x:int else y) = x) /\ ((if F then x:int else y) = y)`,
REWRITE_TAC[]) in
let neg_tm = `(--)` in
(GEN_REWRITE_CONV I [pth1] THENC RAND_CONV NUM_EXP_CONV) ORELSEC
(GEN_REWRITE_CONV I [pth2] THENC
RATOR_CONV(RATOR_CONV(RAND_CONV NUM_EVEN_CONV)) THENC
GEN_REWRITE_CONV I [tth] THENC
(fun tm -> if rator tm = neg_tm then RAND_CONV(RAND_CONV NUM_EXP_CONV) tm
else RAND_CONV NUM_EXP_CONV tm));;
let INT_ABS_CONV =
let INT_MAX_CONV =
REWR_CONV INT_MAX THENC
RATOR_CONV(RATOR_CONV(RAND_CONV INT_LE_CONV)) THENC
GEN_REWRITE_CONV I [COND_CLAUSES];;
let INT_MIN_CONV =
REWR_CONV INT_MIN THENC
RATOR_CONV(RATOR_CONV(RAND_CONV INT_LE_CONV)) THENC
GEN_REWRITE_CONV I [COND_CLAUSES];;
(* ------------------------------------------------------------------------- *)
(* Instantiate the normalizer. *)
(* ------------------------------------------------------------------------- *)
let INT_POLY_CONV =
let sth = prove
(`(!x y z. x + (y + z) = (x + y) + z) /\
(!x y. x + y = y + x) /\
(!x. &0 + x = x) /\
(!x y z. x * (y * z) = (x * y) * z) /\
(!x y. x * y = y * x) /\
(!x. &1 * x = x) /\
(!x. &0 * x = &0) /\
(!x y z. x * (y + z) = x * y + x * z) /\
(!x. x pow 0 = &1) /\
(!x n. x pow (SUC n) = x * x pow n)`,
REWRITE_TAC[
INT_POW] THEN INT_ARITH_TAC)
and rth =
prove
(`(!x. --x = --(&1) * x) /\
(!x y. x - y = x + --(&1) * y)`,
INT_ARITH_TAC)
and is_semiring_constant = is_intconst
and SEMIRING_ADD_CONV = INT_ADD_CONV
and SEMIRING_MUL_CONV = INT_MUL_CONV
and SEMIRING_POW_CONV = INT_POW_CONV in
let _,_,_,_,_,INT_POLY_CONV =
SEMIRING_NORMALIZERS_CONV sth rth
(is_semiring_constant,
SEMIRING_ADD_CONV,SEMIRING_MUL_CONV,SEMIRING_POW_CONV)
(<) in
INT_POLY_CONV;;
(* ------------------------------------------------------------------------- *)
(* Instantiate the ring and ideal procedures. *)
(* ------------------------------------------------------------------------- *)
let INT_RING,int_ideal_cofactors =
let INT_INTEGRAL = prove
(`(!x. &0 * x = &0) /\
(!x y z. (x + y = x + z) <=> (y = z)) /\
(!w x y z. (w * y + x * z = w * z + x * y) <=> (w = x) \/ (y = z))`,
REWRITE_TAC[
MULT_CLAUSES;
EQ_ADD_LCANCEL] THEN
REWRITE_TAC[GSYM
INT_OF_NUM_EQ;
GSYM
INT_OF_NUM_ADD; GSYM
INT_OF_NUM_MUL] THEN
ONCE_REWRITE_TAC[GSYM
INT_SUB_0] THEN
REWRITE_TAC[GSYM
INT_ENTIRE] THEN INT_ARITH_TAC)
and int_ty = `:int` in
let pure,ideal =
RING_AND_IDEAL_CONV
(dest_intconst,mk_intconst,INT_EQ_CONV,
`(--):int->int`,`(+):int->int->int`,`(-):int->int->int`,
genvar bool_ty,`(*):int->int->int`,genvar bool_ty,
`(pow):int->num->int`,
INT_INTEGRAL,TRUTH,INT_POLY_CONV) in
pure,
(fun tms tm -> if forall (fun t -> type_of t = int_ty) (tm::tms)
then ideal tms tm
else failwith
"int_ideal_cofactors: not all terms have type :int");;
(* ------------------------------------------------------------------------- *)
(* Arithmetic operations also on div and rem, hence the whole lot. *)
(* ------------------------------------------------------------------------- *)
let INT_DIVMOD_UNIQ = prove
(`!m n q r:int. m = q * n + r /\ &0 <= r /\ r < abs n
==> m div n = q /\ m rem n = r`,
REPEAT GEN_TAC THEN STRIP_TAC THEN
SUBGOAL_THEN `~(n = &0)` MP_TAC THENL [ASM_INT_ARITH_TAC; ALL_TAC] THEN
DISCH_THEN(STRIP_ASSUME_TAC o SPEC `m:int` o MATCH_MP INT_DIVISION) THEN
ASM_CASES_TAC `m div n = q` THENL
[REPEAT(POP_ASSUM MP_TAC) THEN CONV_TAC INT_RING; ALL_TAC] THEN
SUBGOAL_THEN `abs(m rem n - r) < abs n` MP_TAC THENL
[ASM_INT_ARITH_TAC; MATCH_MP_TAC(TAUT `~p ==> p ==> q`)] THEN
MATCH_MP_TAC(INT_ARITH
`&1 * abs n <= abs(q - m div n) * abs n /\
abs(m rem n - r) = abs((q - m div n) * n)
==> ~(abs(m rem n - r) < abs n)`) THEN
CONJ_TAC THENL
[MATCH_MP_TAC INT_LE_RMUL THEN ASM_INT_ARITH_TAC;
AP_TERM_TAC THEN REPEAT(POP_ASSUM MP_TAC) THEN CONV_TAC INT_RING]);;
let INT_DIV_CONV,INT_REM_CONV =
let pth = prove
(`q * n + r = m ==> &0 <= r ==> r < abs n ==> m div n = q /\ m rem n = r`,
MESON_TAC[
INT_DIVMOD_UNIQ])
and m = `m:int` and n = `n:int` and q = `q:int` and r = `r:int`
and dtm = `(div)` and mtm = `(rem)` in
let emod_num x y =
let r = mod_num x y in
if r </ Int 0 then r +/ abs_num y else r in
let equo_num x y = quo_num (x -/ emod_num x y) y in
let INT_DIVMOD_CONV x y =
let k = equo_num x y
and l = emod_num x y in
let th0 = INST [mk_intconst x,m; mk_intconst y,n;
mk_intconst k,q; mk_intconst l,r] pth in
let tm0 = lhand(lhand(concl th0)) in
let th1 = (LAND_CONV INT_MUL_CONV THENC INT_ADD_CONV) tm0 in
let th2 = MP th0 th1 in
let tm2 = lhand(concl th2) in
let th3 = MP th2 (EQT_ELIM(INT_LE_CONV tm2)) in
let tm3 = lhand(concl th3) in
MP th3 (EQT_ELIM((RAND_CONV INT_ABS_CONV THENC INT_LT_CONV) tm3)) in
(fun tm -> try let l,r = dest_binop dtm tm in
CONJUNCT1(INT_DIVMOD_CONV (dest_intconst l) (dest_intconst r))
with Failure _ -> failwith "INT_DIV_CONV"),
(fun tm -> try let l,r = dest_binop mtm tm in
CONJUNCT2(INT_DIVMOD_CONV (dest_intconst l) (dest_intconst r))
with Failure _ -> failwith "INT_MOD_CONV");;
let INT_RED_CONV =
let gconv_net = itlist (uncurry net_of_conv)
[`x <= y`,INT_LE_CONV;
`x < y`,INT_LT_CONV;
`x >= y`,INT_GE_CONV;
`x > y`,INT_GT_CONV;
`x:int = y`,INT_EQ_CONV;
`--x`,CHANGED_CONV INT_NEG_CONV;
`abs(x)`,INT_ABS_CONV;
`x + y`,INT_ADD_CONV;
`x - y`,INT_SUB_CONV;
`x * y`,INT_MUL_CONV;
`x div y`,INT_DIV_CONV;
`x rem y`,INT_REM_CONV;
`x pow n`,INT_POW_CONV;
`max x y`,INT_MAX_CONV;
`min x y`,INT_MIN_CONV]
(basic_net()) in
REWRITES_CONV gconv_net;;
let INT_REDUCE_CONV = DEPTH_CONV INT_RED_CONV;;
(* ------------------------------------------------------------------------- *)
(* Set up overloading so we can use same symbols for N, Z and even R. *)
(* ------------------------------------------------------------------------- *)
make_overloadable "divides" `:A->A->bool`;;
make_overloadable "mod" `:A->A->A->bool`;;
make_overloadable "coprime" `:A#A->bool`;;
make_overloadable "gcd" `:A#A->A`;;
(* ------------------------------------------------------------------------- *)
(* The general notion of congruence: just syntax for equivalence relation. *)
(* ------------------------------------------------------------------------- *)
parse_as_infix("==",(10,"right"));;
(* ------------------------------------------------------------------------- *)
(* Get real moduli defined and out of the way first. *)
(* ------------------------------------------------------------------------- *)
overload_interface ("mod",`real_mod`);;
(* ------------------------------------------------------------------------- *)
(* Integer divisibility. *)
(* ------------------------------------------------------------------------- *)
parse_as_infix("divides",(12,"right"));;
overload_interface("divides",`int_divides:int->int->bool`);;
(* ------------------------------------------------------------------------- *)
(* Integer congruences. *)
(* ------------------------------------------------------------------------- *)
parse_as_prefix "mod";;
overload_interface ("mod",`int_mod:int->int->int->bool`);;
let int_mod = new_definition
`(mod n) x y = n divides (x - y)`;;
(* ------------------------------------------------------------------------- *)
(* Integer coprimality. *)
(* ------------------------------------------------------------------------- *)
overload_interface("coprime",`int_coprime:int#int->bool`);;
let int_coprime = new_definition
`!a b. coprime(a,b) <=> ?x y. a * x + b * y = &1`;;
(* ------------------------------------------------------------------------- *)
(* A tactic for simple divisibility/congruence/coprimality goals. *)
(* ------------------------------------------------------------------------- *)
let INTEGER_TAC =
let int_ty = `:int` in
let INT_POLYEQ_CONV =
GEN_REWRITE_CONV I [GSYM INT_SUB_0] THENC LAND_CONV INT_POLY_CONV in
let ISOLATE_VARIABLE =
let pth = INT_ARITH `!a x. a = &0 <=> x = x + a` in
let is_defined v t =
let mons = striplist(dest_binary "int_add") t in
mem v mons & forall (fun m -> v = m or not(free_in v m)) mons in
fun vars tm ->
let th = INT_POLYEQ_CONV tm
and th' = (SYM_CONV THENC INT_POLYEQ_CONV) tm in
let v,th1 =
try find (fun v -> is_defined v (lhand(rand(concl th)))) vars,th'
with Failure _ ->
find (fun v -> is_defined v (lhand(rand(concl th')))) vars,th in
let th2 = TRANS th1 (SPECL [lhs(rand(concl th1)); v] pth) in
CONV_RULE(RAND_CONV(RAND_CONV INT_POLY_CONV)) th2 in
let UNWIND_POLYS_CONV tm =
let vars,bod = strip_exists tm in
let cjs = conjuncts bod in
let th1 = tryfind (ISOLATE_VARIABLE vars) cjs in
let eq = lhand(concl th1) in
let bod' = list_mk_conj(eq::(subtract cjs [eq])) in
let th2 = CONJ_ACI_RULE(mk_eq(bod,bod')) in
let th3 = TRANS th2 (MK_CONJ th1 (REFL(rand(rand(concl th2))))) in
let v = lhs(lhand(rand(concl th3))) in
let vars' = (subtract vars [v]) @ [v] in
let th4 = CONV_RULE(RAND_CONV(REWR_CONV UNWIND_THM2)) (MK_EXISTS v th3) in
let IMP_RULE v v' =
DISCH_ALL(itlist SIMPLE_CHOOSE v (itlist SIMPLE_EXISTS v' (ASSUME bod))) in
let th5 = IMP_ANTISYM_RULE (IMP_RULE vars vars') (IMP_RULE vars' vars) in
TRANS th5 (itlist MK_EXISTS (subtract vars [v]) th4) in
let zero_tm = `&0` and one_tm = `&1` in
let isolate_monomials =
let mul_tm = `(int_mul)` and add_tm = `(int_add)`
and neg_tm = `(int_neg)` in
let dest_mul = dest_binop mul_tm
and dest_add = dest_binop add_tm
and mk_mul = mk_binop mul_tm
and mk_add = mk_binop add_tm in
let scrub_var v m =
let ps = striplist dest_mul m in
let ps' = subtract ps [v] in
if ps' = [] then one_tm else end_itlist mk_mul ps' in
let find_multipliers v mons =
let mons1 = filter (fun m -> free_in v m) mons in
let mons2 = map (scrub_var v) mons1 in
if mons2 = [] then zero_tm else end_itlist mk_add mons2 in
fun vars tm ->
let cmons,vmons =
partition (fun m -> intersect (frees m) vars = [])
(striplist dest_add tm) in
let cofactors = map (fun v -> find_multipliers v vmons) vars
and cnc = if cmons = [] then zero_tm
else mk_comb(neg_tm,end_itlist mk_add cmons) in
cofactors,cnc in
let isolate_variables evs ps eq =
let vars = filter (fun v -> vfree_in v eq) evs in
let qs,p = isolate_monomials vars eq in
let rs = filter (fun t -> type_of t = int_ty) (qs @ ps) in
let rs = int_ideal_cofactors rs p in
eq,zip (fst(chop_list(length qs) rs)) vars in
let subst_in_poly i p = rhs(concl(INT_POLY_CONV (vsubst i p))) in
let rec solve_idealism evs ps eqs =
if evs = [] then [] else
let eq,cfs = tryfind (isolate_variables evs ps) eqs in
let evs' = subtract evs (map snd cfs)
and eqs' = map (subst_in_poly cfs) (subtract eqs [eq]) in
cfs @ solve_idealism evs' ps eqs' in
let rec GENVAR_EXISTS_CONV tm =
if not(is_exists tm) then REFL tm else
let ev,bod = dest_exists tm in
let gv = genvar(type_of ev) in
(GEN_ALPHA_CONV gv THENC BINDER_CONV GENVAR_EXISTS_CONV) tm in
let EXISTS_POLY_TAC (asl,w as gl) =
let evs,bod = strip_exists w
and ps = mapfilter (check (fun t -> type_of t = int_ty) o
lhs o concl o snd) asl in
let cfs = solve_idealism evs ps (map lhs (conjuncts bod)) in
(MAP_EVERY EXISTS_TAC(map (fun v -> rev_assocd v cfs zero_tm) evs) THEN
REPEAT(POP_ASSUM MP_TAC) THEN CONV_TAC INT_RING) gl in
let SCRUB_NEQ_TAC = MATCH_MP_TAC o MATCH_MP (MESON[]
`~(x = y) ==> x = y \/ p ==> p`) in
REWRITE_TAC[int_coprime; int_congruent; int_divides] THEN
REPEAT(STRIP_TAC ORELSE EQ_TAC) THEN
REWRITE_TAC[LEFT_AND_EXISTS_THM; RIGHT_AND_EXISTS_THM;
LEFT_OR_EXISTS_THM; RIGHT_OR_EXISTS_THM] THEN
CONV_TAC(REPEATC UNWIND_POLYS_CONV) THEN
REPEAT(FIRST_X_ASSUM SCRUB_NEQ_TAC) THEN
REWRITE_TAC[LEFT_AND_EXISTS_THM; RIGHT_AND_EXISTS_THM;
LEFT_OR_EXISTS_THM; RIGHT_OR_EXISTS_THM] THEN
REPEAT(FIRST_X_ASSUM(MP_TAC o SYM)) THEN
CONV_TAC(ONCE_DEPTH_CONV INT_POLYEQ_CONV) THEN
REWRITE_TAC[GSYM INT_ENTIRE;
TAUT `a \/ (b /\ c) <=> (a \/ b) /\ (a \/ c)`] THEN
POP_ASSUM_LIST(K ALL_TAC) THEN
REPEAT DISCH_TAC THEN CONV_TAC GENVAR_EXISTS_CONV THEN
CONV_TAC(ONCE_DEPTH_CONV INT_POLYEQ_CONV) THEN EXISTS_POLY_TAC;;
let INTEGER_RULE tm = prove(tm,INTEGER_TAC);;
(* ------------------------------------------------------------------------- *)
(* Existence of integer gcd, and the Bezout identity. *)
(* ------------------------------------------------------------------------- *)
let WF_INT_MEASURE = prove
(`!P m. (!x. &0 <= m(x)) /\ (!x. (!y. m(y) < m(x) ==> P(y)) ==> P(x))
==> !x:A. P(x)`,
REPEAT STRIP_TAC THEN SUBGOAL_THEN `!n x:A. m(x) = &n ==> P(x)` MP_TAC THENL
[MATCH_MP_TAC
num_WF; ALL_TAC] THEN
REWRITE_TAC[GSYM
INT_OF_NUM_LT;
INT_FORALL_POS] THEN ASM_MESON_TAC[]);;
let WF_INT_MEASURE_2 = prove
(`!P m. (!x y. &0 <= m x y) /\
(!x y. (!x' y'. m x' y' < m x y ==> P x' y') ==> P x y)
==> !x:A y:B. P x y`,
let INT_GCD_EXISTS = prove
(`!a b. ?d. d divides a /\ d divides b /\ ?x y. d = a * x + b * y`,
let INT_GCD_EXISTS_CASES = INT_ARITH
`(a = &0 \/ b = &0) \/
abs(a - b) + abs b < abs a + abs b \/ abs(a + b) + abs b < abs a + abs b \/
abs a + abs(b - a) < abs a + abs b \/ abs a + abs(b + a) < abs a + abs b` in
MATCH_MP_TAC
WF_INT_MEASURE_2 THEN EXISTS_TAC `\x y. abs(x) + abs(y)` THEN
REWRITE_TAC[] THEN REPEAT STRIP_TAC THENL [INT_ARITH_TAC; ALL_TAC] THEN
DISJ_CASES_THEN MP_TAC INT_GCD_EXISTS_CASES THENL
[STRIP_TAC THEN ASM_REWRITE_TAC[INTEGER_RULE `d divides &0`] THEN
REWRITE_TAC[
INT_MUL_LZERO;
INT_ADD_LID;
INT_ADD_RID] THEN
MESON_TAC[INTEGER_RULE `d divides d`;
INT_MUL_RID];
DISCH_THEN(REPEAT_TCL DISJ_CASES_THEN (ANTE_RES_THEN MP_TAC)) THEN
MATCH_MP_TAC
MONO_EXISTS THEN INTEGER_TAC]);;
let INT_GCD_EXISTS_POS = prove
(`!a b. ?d. &0 <= d /\ d divides a /\ d divides b /\ ?x y. d = a * x + b * y`,
REPEAT GEN_TAC THEN
X_CHOOSE_TAC `d:int` (SPECL [`a:int`; `b:int`]
INT_GCD_EXISTS) THEN
DISJ_CASES_TAC(SPEC `d:int`
INT_LE_NEGTOTAL) THEN
ASM_MESON_TAC[INTEGER_RULE `(--d) divides x <=> d divides x`;
INT_ARITH `a * --x + b * --y = --(a * x + b * y)`]);;
(* ------------------------------------------------------------------------- *)
(* Hence define (positive) gcd function; add elimination to INTEGER_TAC. *)
(* ------------------------------------------------------------------------- *)
overload_interface("gcd",`int_gcd:int#int->int`);;
let INTEGER_TAC =
let GCD_ELIM_TAC =
let gcd_tm = `gcd` in
let dest_gcd tm =
let l,r = dest_comb tm in
if l = gcd_tm then dest_pair r else failwith "dest_gcd" in
REPEAT GEN_TAC THEN
W(fun (asl,w) ->
let gts = find_terms (can dest_gcd) w in
let ths = map
(fun tm -> let a,b = dest_gcd tm in SPECL [a;b] int_gcd) gts in
MAP_EVERY MP_TAC ths THEN
MAP_EVERY SPEC_TAC (zip gts (map (genvar o type_of) gts))) in
REPEAT(GEN_TAC ORELSE CONJ_TAC) THEN GCD_ELIM_TAC THEN INTEGER_TAC;;
let INTEGER_RULE tm = prove(tm,INTEGER_TAC);;
(* ------------------------------------------------------------------------- *)
(* Mapping from nonnegative integers back to natural numbers. *)
(* ------------------------------------------------------------------------- *)
(* ------------------------------------------------------------------------- *)
(* Now define similar notions over the natural numbers. *)
(* ------------------------------------------------------------------------- *)
overload_interface("divides",`num_divides:num->num->bool`);;
overload_interface ("mod",`num_mod:num->num->num->bool`);;
overload_interface("coprime",`num_coprime:num#num->bool`);;
overload_interface("gcd",`num_gcd:num#num->num`);;
let num_mod = new_definition
`(mod n) x y <=> (mod &n) (&x) (&y)`;;
(* ------------------------------------------------------------------------- *)
(* Map an assertion over N to an integer equivalent. *)
(* To make this work nicely, all variables of type num should be quantified. *)
(* ------------------------------------------------------------------------- *)
let NUM_TO_INT_CONV =
let pth_relativize = prove
(`((!n. P(&n)) <=> (!i. ~(&0 <= i) \/ P i)) /\
((?n. P(&n)) <=> (?i. &0 <= i /\ P i))`,
(* ------------------------------------------------------------------------- *)
(* Linear decision procedure for the naturals at last! *)
(* ------------------------------------------------------------------------- *)
let ARITH_RULE =
let init_conv =
NUM_SIMPLIFY_CONV THENC
GEN_REWRITE_CONV DEPTH_CONV [ADD1] THENC
PROP_ATOM_CONV (BINOP_CONV NUM_NORMALIZE_CONV) THENC
PRENEX_CONV THENC
(GEN_REWRITE_CONV TOP_SWEEP_CONV o map GSYM)
[INT_OF_NUM_EQ; INT_OF_NUM_LE; INT_OF_NUM_LT; INT_OF_NUM_GE;
INT_OF_NUM_GT; INT_OF_NUM_ADD; SPEC `NUMERAL k` INT_OF_NUM_MUL;
INT_OF_NUM_MAX; INT_OF_NUM_MIN]
and is_numimage t =
match t with
Comb(Const("int_of_num",_),n) when not(is_numeral n) -> true
| _ -> false in
fun tm ->
let th1 = init_conv tm in
let tm1 = rand(concl th1) in
let avs,bod = strip_forall tm1 in
let nim = setify(find_terms is_numimage bod) in
let gvs = map (genvar o type_of) nim in
let pths = map (fun v -> SPEC (rand v) INT_POS) nim in
let ibod = itlist (curry mk_imp o concl) pths bod in
let gbod = subst (zip gvs nim) ibod in
let th2 = INST (zip nim gvs) (INT_ARITH gbod) in
let th3 = GENL avs (rev_itlist (C MP) pths th2) in
EQ_MP (SYM th1) th3;;
let ARITH_TAC = CONV_TAC(EQT_INTRO o ARITH_RULE);;
let ASM_ARITH_TAC =
REPEAT(FIRST_X_ASSUM(MP_TAC o check (not o is_forall o concl))) THEN
ARITH_TAC;;
(* ------------------------------------------------------------------------- *)
(* Also a similar divisibility procedure for natural numbers. *)
(* ------------------------------------------------------------------------- *)
let NUMBER_TAC =
let pth_relativize = prove
(`((!n. P(&n)) <=> (!i. &0 <= i ==> P i)) /\
((?n. P(&n)) <=> (?i. &0 <= i /\ P i))`,
let NUMBER_RULE tm = prove(tm,NUMBER_TAC);;
(* ------------------------------------------------------------------------- *)
(* Make sure we give priority to N. *)
(* ------------------------------------------------------------------------- *)
prioritize_num();;