(* Title: ZF/ex/Primes.thy ID: $Id: Primes.thy,v 1.6 2002/02/04 12:16:54 paulson Exp $ Author: Christophe Tabacznyj and Lawrence C Paulson Copyright 1996 University of Cambridge The "divides" relation, the greatest common divisor and Euclid's algorithm *) theory Primes = Main: constdefs divides :: "[i,i]=>o" (infixl "dvd" 50) "m dvd n == m \ nat & n \ nat & (\k \ nat. n = m#*k)" is_gcd :: "[i,i,i]=>o" (* great common divisor *) "is_gcd(p,m,n) == ((p dvd m) & (p dvd n)) & (\d\nat. (d dvd m) & (d dvd n) --> d dvd p)" gcd :: "[i,i]=>i" (* gcd by Euclid's algorithm *) "gcd(m,n) == transrec(natify(n), %n f. \m \ nat. if n=0 then m else f`(m mod n)`n) ` natify(m)" coprime :: "[i,i]=>o" (* coprime relation *) "coprime(m,n) == gcd(m,n) = 1" prime :: i (* set of prime numbers *) "prime == {p \ nat. 1

m \ nat. m dvd p --> m=1 | m=p)}" (************************************************) (** Divides Relation **) (************************************************) lemma dvdD: "m dvd n ==> m \ nat & n \ nat & (\k \ nat. n = m#*k)" apply (unfold divides_def) apply assumption done 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, standard] lemmas dvd_imp_nat2 = dvdD [THEN conjunct2, THEN conjunct1, standard] lemma dvd_0_right [simp]: "m \ nat ==> m dvd 0" apply (unfold divides_def) apply (fast intro: nat_0I mult_0_right [symmetric]) done lemma dvd_0_left: "0 dvd m ==> m = 0" by (unfold divides_def, force) lemma dvd_refl [simp]: "m \ nat ==> m dvd m" apply (unfold divides_def) apply (fast intro: nat_1I mult_1_right [symmetric]) done lemma dvd_trans: "[| m dvd n; n dvd p |] ==> m dvd p" apply (unfold divides_def) apply (fast intro: mult_assoc mult_type) done lemma dvd_anti_sym: "[| m dvd n; n dvd m |] ==> m=n" apply (unfold 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" apply (unfold divides_def) apply (simp add: mult_assoc) apply blast done lemma dvd_mult_right: "[|(i#*j) dvd k; j \ nat|] ==> j dvd k" apply (unfold divides_def) apply clarify apply (rule_tac x = "i#*k" in bexI) apply (simp add: mult_ac) apply (rule mult_type) done (************************************************) (** Greatest Common Divisor **) (************************************************) (* GCD by Euclid's Algorithm *) lemma gcd_0 [simp]: "gcd(m,0) = natify(m)" apply (unfold gcd_def) apply (subst transrec) apply 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 (unfold gcd_def) apply (rule_tac P = "%z. ?left (z) = ?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 (unfold divides_def) apply (fast intro: add_mult_distrib_left [symmetric] add_type) done lemma dvd_mult: "k dvd n ==> k dvd (m #* n)" apply (unfold 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, standard] lemmas dvdI2 [simp] = dvd_refl [THEN dvd_mult2, standard] lemma dvd_mod_imp_dvd_raw: "[| a \ nat; b \ nat; k dvd b; k dvd (a mod b) |] ==> k dvd a" apply (tactic "div_undefined_case_tac \"b=0\" 1") 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 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 P(m,n) |] ==> P (m,n)" by (blast intro: gcd_induct_lemma) (* gcd type *) 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 (* 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 (* 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 (unfold divides_def) apply (tactic "div_undefined_case_tac \"b=0\" 1") apply auto apply (blast intro: mod_mult_distrib2 [symmetric]) done (* 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) (* GCD PROOF: GCD exists and gcd fits the definition *) lemma is_gcd: "[| m \ nat; n \ nat |] ==> is_gcd(gcd(m,n), m, n)" by (simp add: is_gcd_def) (* GCD is unique *) lemma is_gcd_unique: "[|is_gcd(m,a,b); is_gcd(n,a,b); m\nat; n\nat|] ==> m=n" apply (unfold 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 (unfold 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) apply 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]) (* 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) apply assumption apply (simp) apply (case_tac "k = 0") apply 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)" apply (cut_tac k = "k" and m = "1" and n = "n" in gcd_mult_distrib2) apply auto done lemma gcd_self [simp]: "gcd (k, k) = natify(k)" apply (cut_tac k = "k" and n = "1" in gcd_mult) apply auto done 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) apply 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 (unfold prime_def) apply clarify apply (drule_tac x = "gcd (p,n) " in bspec) apply auto apply (cut_tac m = "p" and n = "n" in gcd_dvd2) apply auto done lemma prime_into_nat: "p \ prime ==> p \ nat" by (unfold prime_def, auto) lemma prime_nonzero: "p \ prime \ p\0" by (unfold prime_def, auto) (*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) (** 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) apply 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 (* More multiplication laws *) 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 (*** 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) apply clarify apply (frule prime_dvd_other_side) apply 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