(* Title: ZF/ex/Primes.thy
Author: Christophe Tabacznyj and Lawrence C Paulson
Copyright 1996 University of Cambridge
*)
section‹The Divides Relation
and Euclid
's algorithm for the GCD\
theory Primes
imports ZF
begin
definition
divides ::
"[i,i]\o" (
infixl ‹dvd
› 50)
where
"m dvd n \ m \ nat \ n \ nat \ (\k \ nat. n = m#*k)"
definition
is_gcd ::
"[i,i,i]\o" 🍋 ‹definition of great common divisor
› where
"is_gcd(p,m,n) \ ((p dvd m) \ (p dvd n)) \
(
∀d
∈nat. (d dvd m)
∧ (d dvd n)
⟶ d dvd p)
"
definition
gcd ::
"[i,i]\i" 🍋 ‹Euclid
's algorithm for the gcd\ where
"gcd(m,n) \ transrec(natify(n),
λn f. λm
∈ nat.
if n=0
then m else f`(m mod n)`n) ` natify(m)
"
definition
coprime ::
"[i,i]\o" 🍋 ‹the coprime relation
› where
"coprime(m,n) \ gcd(m,n) = 1"
definition
prime :: i
🍋 ‹the set of prime numbers
› where
"prime \ {p \ nat. 1 (\m \ nat. m dvd p \ m=1 | m=p)}"
subsection‹The Divides Relation
›
lemma dvdD:
"m dvd n \ m \ nat \ n \ nat \ (\k \ nat. n = m#*k)"
by (unfold divides_def, assumption)
lemma dvdE:
"\m dvd n; \k. \m \ nat; n \ nat; k \ nat; n = m#*k\ \ P\ \ P"
by (blast dest!: dvdD)
lemmas dvd_imp_nat1 = dvdD [
THEN conjunct1]
lemmas dvd_imp_nat2 = dvdD [
THEN conjunct2,
THEN conjunct1]
lemma dvd_0_right [simp]:
"m \ nat \ m dvd 0"
apply (simp add: divides_def)
apply (fast intro: nat_0I mult_0_right [symmetric])
done
lemma dvd_0_left:
"0 dvd m \ m = 0"
by (simp add: divides_def)
lemma dvd_refl [simp]:
"m \ nat \ m dvd m"
apply (simp add: divides_def)
apply (fast intro: nat_1I mult_1_right [symmetric])
done
lemma dvd_trans:
"\m dvd n; n dvd p\ \ m dvd p"
by (auto simp add: divides_def intro: mult_assoc mult_type)
lemma dvd_anti_sym:
"\m dvd n; n dvd m\ \ m=n"
apply (simp add: divides_def)
apply (force dest: mult_eq_self_implies_10
simp add: mult_assoc mult_eq_1_iff)
done
lemma dvd_mult_left:
"\(i#*j) dvd k; i \ nat\ \ i dvd k"
by (auto simp add: divides_def mult_assoc)
lemma dvd_mult_right:
"\(i#*j) dvd k; j \ nat\ \ j dvd k"
apply (simp add: divides_def, clarify)
apply (rule_tac x =
"i#*ka" in bexI)
apply (simp add: mult_ac)
apply (rule mult_type)
done
subsection‹Euclid
's Algorithm for the GCD\
lemma gcd_0 [simp]:
"gcd(m,0) = natify(m)"
apply (simp add: gcd_def)
apply (subst transrec, simp)
done
lemma gcd_natify1 [simp]:
"gcd(natify(m),n) = gcd(m,n)"
by (simp add: gcd_def)
lemma gcd_natify2 [simp]:
"gcd(m, natify(n)) = gcd(m,n)"
by (simp add: gcd_def)
lemma gcd_non_0_raw:
"\0 nat\ \ gcd(m,n) = gcd(n, m mod n)"
apply (simp add: gcd_def)
apply (rule_tac P =
"\z. left (z) = right" for left right
in transrec [
THEN ssubst])
apply (simp add: ltD [
THEN mem_imp_not_eq,
THEN not_sym]
mod_less_divisor [
THEN ltD])
done
lemma gcd_non_0:
"0 < natify(n) \ gcd(m,n) = gcd(n, m mod n)"
apply (cut_tac m = m
and n =
"natify (n) " in gcd_non_0_raw)
apply auto
done
lemma gcd_1 [simp]:
"gcd(m,1) = 1"
by (simp (no_asm_simp) add: gcd_non_0)
lemma dvd_add:
"\k dvd a; k dvd b\ \ k dvd (a #+ b)"
apply (simp add: divides_def)
apply (fast intro: add_mult_distrib_left [symmetric] add_type)
done
lemma dvd_mult:
"k dvd n \ k dvd (m #* n)"
apply (simp add: divides_def)
apply (fast intro: mult_left_commute mult_type)
done
lemma dvd_mult2:
"k dvd m \ k dvd (m #* n)"
apply (subst mult_commute)
apply (blast intro: dvd_mult)
done
(* k dvd (m*k) *)
lemmas dvdI1 [simp] = dvd_refl [
THEN dvd_mult]
lemmas dvdI2 [simp] = dvd_refl [
THEN dvd_mult2]
lemma dvd_mod_imp_dvd_raw:
"\a \ nat; b \ nat; k dvd b; k dvd (a mod b)\ \ k dvd a"
apply (case_tac
"b=0")
apply (simp add: DIVISION_BY_ZERO_MOD)
apply (blast intro: mod_div_equality [
THEN subst]
elim: dvdE
intro!: dvd_add dvd_mult mult_type mod_type div_type)
done
lemma dvd_mod_imp_dvd:
"\k dvd (a mod b); k dvd b; a \ nat\ \ k dvd a"
apply (cut_tac b =
"natify (b)" in dvd_mod_imp_dvd_raw)
apply auto
apply (simp add: divides_def)
done
(*Imitating TFL*)
lemma gcd_induct_lemma [rule_format (no_asm)]:
"\n \ nat;
∀m
∈ nat. P(m,0);
∀m
∈ nat.
∀n
∈ nat. 0<n
⟶ P(n, m mod n)
⟶ P(m,n)
]
==> ∀m
∈ nat. P (m,n)
"
apply (erule_tac i = n
in complete_induct)
apply (case_tac
"x=0")
apply (simp (no_asm_simp))
apply clarify
apply (drule_tac x1 = m
and x = x
in bspec [
THEN bspec])
apply (simp_all add: Ord_0_lt_iff)
apply (blast intro: mod_less_divisor [
THEN ltD])
done
lemma gcd_induct:
"\P. \m \ nat; n \ nat;
∧m. m
∈ nat
==> P(m,0);
∧m n.
[m
∈ nat; n
∈ nat; 0<n; P(n, m mod n)
] ==> P(m,n)
]
==> P (m,n)
"
by (blast intro: gcd_induct_lemma)
subsection‹Basic Properties of
🍋‹gcd
››
text‹type of gcd
›
lemma gcd_type [simp,TC]:
"gcd(m, n) \ nat"
apply (subgoal_tac
"gcd (natify (m), natify (n)) \ nat")
apply simp
apply (rule_tac m =
"natify (m)" and n =
"natify (n)" in gcd_induct)
apply auto
apply (simp add: gcd_non_0)
done
text‹Property 1: gcd(a,b) divides a
and b
›
lemma gcd_dvd_both:
"\m \ nat; n \ nat\ \ gcd (m, n) dvd m \ gcd (m, n) dvd n"
apply (rule_tac m = m
and n = n
in gcd_induct)
apply (simp_all add: gcd_non_0)
apply (blast intro: dvd_mod_imp_dvd_raw nat_into_Ord [
THEN Ord_0_lt])
done
lemma gcd_dvd1 [simp]:
"m \ nat \ gcd(m,n) dvd m"
apply (cut_tac m =
"natify (m)" and n =
"natify (n)" in gcd_dvd_both)
apply auto
done
lemma gcd_dvd2 [simp]:
"n \ nat \ gcd(m,n) dvd n"
apply (cut_tac m =
"natify (m)" and n =
"natify (n)" in gcd_dvd_both)
apply auto
done
text‹if f divides a
and b
then f divides gcd(a,b)
›
lemma dvd_mod:
"\f dvd a; f dvd b\ \ f dvd (a mod b)"
apply (simp add: divides_def)
apply (case_tac
"b=0")
apply (simp add: DIVISION_BY_ZERO_MOD, auto)
apply (blast intro: mod_mult_distrib2 [symmetric])
done
text‹Property 2:
for all a,b,f naturals,
if f divides a
and f divides b
then f divides gcd(a,b)
›
lemma gcd_greatest_raw [rule_format]:
"\m \ nat; n \ nat; f \ nat\
==> (f dvd m)
⟶ (f dvd n)
⟶ f dvd gcd(m,n)
"
apply (rule_tac m = m
and n = n
in gcd_induct)
apply (simp_all add: gcd_non_0 dvd_mod)
done
lemma gcd_greatest:
"\f dvd m; f dvd n; f \ nat\ \ f dvd gcd(m,n)"
apply (rule gcd_greatest_raw)
apply (auto simp add: divides_def)
done
lemma gcd_greatest_iff [simp]:
"\k \ nat; m \ nat; n \ nat\
==> (k dvd gcd (m, n))
⟷ (k dvd m
∧ k dvd n)
"
by (blast intro!: gcd_greatest gcd_dvd1 gcd_dvd2 intro: dvd_trans)
subsection‹The Greatest Common Divisor
›
text‹The GCD exists
and function gcd computes it.
›
lemma is_gcd:
"\m \ nat; n \ nat\ \ is_gcd(gcd(m,n), m, n)"
by (simp add: is_gcd_def)
text‹The GCD
is unique
›
lemma is_gcd_unique:
"\is_gcd(m,a,b); is_gcd(n,a,b); m\nat; n\nat\ \ m=n"
apply (simp add: is_gcd_def)
apply (blast intro: dvd_anti_sym)
done
lemma is_gcd_commute:
"is_gcd(k,m,n) \ is_gcd(k,n,m)"
by (simp add: is_gcd_def, blast)
lemma gcd_commute_raw:
"\m \ nat; n \ nat\ \ gcd(m,n) = gcd(n,m)"
apply (rule is_gcd_unique)
apply (rule is_gcd)
apply (rule_tac [3] is_gcd_commute [
THEN iffD1])
apply (rule_tac [3] is_gcd, auto)
done
lemma gcd_commute:
"gcd(m,n) = gcd(n,m)"
apply (cut_tac m =
"natify (m)" and n =
"natify (n)" in gcd_commute_raw)
apply auto
done
lemma gcd_assoc_raw:
"\k \ nat; m \ nat; n \ nat\
==> gcd (gcd (k, m), n) = gcd (k, gcd (m, n))
"
apply (rule is_gcd_unique)
apply (rule is_gcd)
apply (simp_all add: is_gcd_def)
apply (blast intro: gcd_dvd1 gcd_dvd2 gcd_type intro: dvd_trans)
done
lemma gcd_assoc:
"gcd (gcd (k, m), n) = gcd (k, gcd (m, n))"
apply (cut_tac k =
"natify (k)" and m =
"natify (m)" and n =
"natify (n) "
in gcd_assoc_raw)
apply auto
done
lemma gcd_0_left [simp]:
"gcd (0, m) = natify(m)"
by (simp add: gcd_commute [of 0])
lemma gcd_1_left [simp]:
"gcd (1, m) = 1"
by (simp add: gcd_commute [of 1])
subsection‹Addition laws
›
lemma gcd_add1 [simp]:
"gcd (m #+ n, n) = gcd (m, n)"
apply (subgoal_tac
"gcd (m #+ natify (n), natify (n)) = gcd (m, natify (n))")
apply simp
apply (case_tac
"natify (n) = 0")
apply (auto simp add: Ord_0_lt_iff gcd_non_0)
done
lemma gcd_add2 [simp]:
"gcd (m, m #+ n) = gcd (m, n)"
apply (rule gcd_commute [
THEN trans])
apply (subst add_commute, simp)
apply (rule gcd_commute)
done
lemma gcd_add2
' [simp]: "gcd (m, n #+ m) = gcd (m, n)"
by (subst add_commute, rule gcd_add2)
lemma gcd_add_mult_raw:
"k \ nat \ gcd (m, k #* m #+ n) = gcd (m, n)"
apply (erule nat_induct)
apply (auto simp add: gcd_add2 add_assoc)
done
lemma gcd_add_mult:
"gcd (m, k #* m #+ n) = gcd (m, n)"
apply (cut_tac k =
"natify (k)" in gcd_add_mult_raw)
apply auto
done
subsection‹Multiplication Laws
›
lemma gcd_mult_distrib2_raw:
"\k \ nat; m \ nat; n \ nat\
==> k #* gcd (m, n) = gcd (k #* m, k #* n)
"
apply (erule_tac m = m
and n = n
in gcd_induct, assumption)
apply simp
apply (case_tac
"k = 0", simp)
apply (simp add: mod_geq gcd_non_0 mod_mult_distrib2 Ord_0_lt_iff)
done
lemma gcd_mult_distrib2:
"k #* gcd (m, n) = gcd (k #* m, k #* n)"
apply (cut_tac k =
"natify (k)" and m =
"natify (m)" and n =
"natify (n) "
in gcd_mult_distrib2_raw)
apply auto
done
lemma gcd_mult [simp]:
"gcd (k, k #* n) = natify(k)"
by (cut_tac k = k
and m = 1
and n = n
in gcd_mult_distrib2, auto)
lemma gcd_self [simp]:
"gcd (k, k) = natify(k)"
by (cut_tac k = k
and n = 1
in gcd_mult, auto)
lemma relprime_dvd_mult:
"\gcd (k,n) = 1; k dvd (m #* n); m \ nat\ \ k dvd m"
apply (cut_tac k = m
and m = k
and n = n
in gcd_mult_distrib2, auto)
apply (erule_tac b = m
in ssubst)
apply (simp add: dvd_imp_nat1)
done
lemma relprime_dvd_mult_iff:
"\gcd (k,n) = 1; m \ nat\ \ k dvd (m #* n) \ k dvd m"
by (blast intro: dvdI2 relprime_dvd_mult dvd_trans)
lemma prime_imp_relprime:
"\p \ prime; \ (p dvd n); n \ nat\ \ gcd (p, n) = 1"
apply (simp add: prime_def, clarify)
apply (drule_tac x =
"gcd (p,n)" in bspec)
apply auto
apply (cut_tac m = p
and n = n
in gcd_dvd2, auto)
done
lemma prime_into_nat:
"p \ prime \ p \ nat"
by (simp add: prime_def)
lemma prime_nonzero:
"p \ prime \ p\0"
by (auto simp add: prime_def)
text‹This
theorem leads immediately
to a
proof of the uniqueness of
factorization.
If 🍋‹p
› divides a product of primes
then it
is
one of those primes.
›
lemma prime_dvd_mult:
"\p dvd m #* n; p \ prime; m \ nat; n \ nat\ \ p dvd m \ p dvd n"
by (blast intro: relprime_dvd_mult prime_imp_relprime prime_into_nat)
lemma gcd_mult_cancel_raw:
"\gcd (k,n) = 1; m \ nat; n \ nat\ \ gcd (k #* m, n) = gcd (m, n)"
apply (rule dvd_anti_sym)
apply (rule gcd_greatest)
apply (rule relprime_dvd_mult [of _ k])
apply (simp add: gcd_assoc)
apply (simp add: gcd_commute)
apply (simp_all add: mult_commute)
apply (blast intro: dvdI1 gcd_dvd1 dvd_trans)
done
lemma gcd_mult_cancel:
"gcd (k,n) = 1 \ gcd (k #* m, n) = gcd (m, n)"
apply (cut_tac m =
"natify (m)" and n =
"natify (n)" in gcd_mult_cancel_raw)
apply auto
done
subsection‹The Square Root of a Prime
is Irrational: Key
Lemma›
lemma prime_dvd_other_side:
"\n#*n = p#*(k#*k); p \ prime; n \ nat\ \ p dvd n"
apply (subgoal_tac
"p dvd n#*n")
apply (blast dest: prime_dvd_mult)
apply (rule_tac j =
"k#*k" in dvd_mult_left)
apply (auto simp add: prime_def)
done
lemma reduction:
"\k#*k = p#*(j#*j); p \ prime; 0 < k; j \ nat; k \ nat\
==> k < p#*j
∧ 0 < j
"
apply (rule ccontr)
apply (simp add: not_lt_iff_le prime_into_nat)
apply (erule disjE)
apply (frule mult_le_mono, assumption+)
apply (simp add: mult_ac)
apply (auto dest!: natify_eqE
simp add: not_lt_iff_le prime_into_nat mult_le_cancel_le1)
apply (simp add: prime_def)
apply (blast dest: lt_trans1)
done
lemma rearrange:
"j #* (p#*j) = k#*k \ k#*k = p#*(j#*j)"
by (simp add: mult_ac)
lemma prime_not_square:
"\m \ nat; p \ prime\ \ \k \ nat. 0 m#*m \ p#*(k#*k)"
apply (erule complete_induct, clarify)
apply (frule prime_dvd_other_side, assumption)
apply assumption
apply (erule dvdE)
apply (simp add: mult_assoc mult_cancel1 prime_nonzero prime_into_nat)
apply (blast dest: rearrange reduction ltD)
done
end
