isabelle: src/HOL/GCD.thy@d26d5f988d71 (annotated)

32479 521cc9bf2958 some reorganization of number theory haftmann parents: 32415 diff changeset	1	(* Authors: Christophe Tabacznyj, Lawrence C. Paulson, Amine Chaieb,
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	2	Thomas M. Rasmussen, Jeremy Avigad, Tobias Nipkow
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	3
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	4
32479 521cc9bf2958 some reorganization of number theory haftmann parents: 32415 diff changeset	5	This file deals with the functions gcd and lcm. Definitions and
521cc9bf2958 some reorganization of number theory haftmann parents: 32415 diff changeset	6	lemmas are proved uniformly for the natural numbers and integers.
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	7
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	8	This file combines and revises a number of prior developments.
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	9
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	10	The original theories "GCD" and "Primes" were by Christophe Tabacznyj
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	11	and Lawrence C. Paulson, based on \cite{davenport92}. They introduced
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	12	gcd, lcm, and prime for the natural numbers.
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	13
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	14	The original theory "IntPrimes" was by Thomas M. Rasmussen, and
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	15	extended gcd, lcm, primes to the integers. Amine Chaieb provided
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	16	another extension of the notions to the integers, and added a number
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	17	of results to "Primes" and "GCD". IntPrimes also defined and developed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	18	the congruence relations on the integers. The notion was extended to
34915 7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	19	the natural numbers by Chaieb.
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	20
32036 8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged. avigad parents: 31952 diff changeset	21	Jeremy Avigad combined all of these, made everything uniform for the
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged. avigad parents: 31952 diff changeset	22	natural numbers and the integers, and added a number of new theorems.
8a9228872fbd Moved factorial lemmas from Binomial.thy to Fact.thy and merged. avigad parents: 31952 diff changeset	23
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	24	Tobias Nipkow cleaned up a lot.
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	25	*)
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	26
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	27
34915 7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	28	header {* Greatest common divisor and least common multiple *}
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	29
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	30	theory GCD
33318 ddd97d9dfbfb moved Nat_Transfer before Divides; distributed Nat_Transfer setup accordingly haftmann parents: 33197 diff changeset	31	imports Fact Parity
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	32	begin
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	33
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	34	declare One_nat_def [simp del]
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	35
34030 829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	36	subsection {* GCD and LCM definitions *}
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	37
31992 f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	38	class gcd = zero + one + dvd +
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	39	fixes gcd :: "'a \<Rightarrow> 'a \<Rightarrow> 'a"
efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	40	and lcm :: "'a \<Rightarrow> 'a \<Rightarrow> 'a"
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	41	begin
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	42
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	43	abbreviation
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	44	coprime :: "'a \<Rightarrow> 'a \<Rightarrow> bool"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	45	where
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	46	"coprime x y == (gcd x y = 1)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	47
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	48	end
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	49
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	50	instantiation nat :: gcd
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	51	begin
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	52
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	53	fun
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	54	gcd_nat :: "nat \<Rightarrow> nat \<Rightarrow> nat"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	55	where
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	56	"gcd_nat x y =
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	57	(if y = 0 then x else gcd y (x mod y))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	58
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	59	definition
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	60	lcm_nat :: "nat \<Rightarrow> nat \<Rightarrow> nat"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	61	where
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	62	"lcm_nat x y = x * y div (gcd x y)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	63
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	64	instance proof qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	65
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	66	end
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	67
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	68	instantiation int :: gcd
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	69	begin
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	70
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	71	definition
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	72	gcd_int :: "int \<Rightarrow> int \<Rightarrow> int"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	73	where
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	74	"gcd_int x y = int (gcd (nat (abs x)) (nat (abs y)))"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	75
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	76	definition
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	77	lcm_int :: "int \<Rightarrow> int \<Rightarrow> int"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	78	where
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	79	"lcm_int x y = int (lcm (nat (abs x)) (nat (abs y)))"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	80
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	81	instance proof qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	82
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	83	end
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	84
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	85
34030 829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	86	subsection {* Transfer setup *}
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	87
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	88	lemma transfer_nat_int_gcd:
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	89	"(x::int) >= 0 \<Longrightarrow> y >= 0 \<Longrightarrow> gcd (nat x) (nat y) = nat (gcd x y)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	90	"(x::int) >= 0 \<Longrightarrow> y >= 0 \<Longrightarrow> lcm (nat x) (nat y) = nat (lcm x y)"
32479 521cc9bf2958 some reorganization of number theory haftmann parents: 32415 diff changeset	91	unfolding gcd_int_def lcm_int_def
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	92	by auto
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	93
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	94	lemma transfer_nat_int_gcd_closures:
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	95	"x >= (0::int) \<Longrightarrow> y >= 0 \<Longrightarrow> gcd x y >= 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	96	"x >= (0::int) \<Longrightarrow> y >= 0 \<Longrightarrow> lcm x y >= 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	97	by (auto simp add: gcd_int_def lcm_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	98
35644 d20cf282342e transfer: avoid camel case haftmann parents: 35368 diff changeset	99	declare transfer_morphism_nat_int[transfer add return:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	100	transfer_nat_int_gcd transfer_nat_int_gcd_closures]
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	101
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	102	lemma transfer_int_nat_gcd:
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	103	"gcd (int x) (int y) = int (gcd x y)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	104	"lcm (int x) (int y) = int (lcm x y)"
32479 521cc9bf2958 some reorganization of number theory haftmann parents: 32415 diff changeset	105	by (unfold gcd_int_def lcm_int_def, auto)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	106
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	107	lemma transfer_int_nat_gcd_closures:
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	108	"is_nat x \<Longrightarrow> is_nat y \<Longrightarrow> gcd x y >= 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	109	"is_nat x \<Longrightarrow> is_nat y \<Longrightarrow> lcm x y >= 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	110	by (auto simp add: gcd_int_def lcm_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	111
35644 d20cf282342e transfer: avoid camel case haftmann parents: 35368 diff changeset	112	declare transfer_morphism_int_nat[transfer add return:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	113	transfer_int_nat_gcd transfer_int_nat_gcd_closures]
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	114
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	115
34030 829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	116	subsection {* GCD properties *}
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	117
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	118	(* was gcd_induct *)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	119	lemma gcd_nat_induct:
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	120	fixes m n :: nat
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	121	assumes "\<And>m. P m 0"
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	122	and "\<And>m n. 0 < n \<Longrightarrow> P n (m mod n) \<Longrightarrow> P m n"
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	123	shows "P m n"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	124	apply (rule gcd_nat.induct)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	125	apply (case_tac "y = 0")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	126	using assms apply simp_all
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	127	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	128
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	129	(* specific to int *)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	130
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	131	lemma gcd_neg1_int [simp]: "gcd (-x::int) y = gcd x y"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	132	by (simp add: gcd_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	133
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	134	lemma gcd_neg2_int [simp]: "gcd (x::int) (-y) = gcd x y"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	135	by (simp add: gcd_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	136
54489 03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	137	lemma gcd_neg_numeral_1_int [simp]:
03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	138	"gcd (- numeral n :: int) x = gcd (numeral n) x"
03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	139	by (fact gcd_neg1_int)
03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	140
03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	141	lemma gcd_neg_numeral_2_int [simp]:
03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	142	"gcd x (- numeral n :: int) = gcd x (numeral n)"
03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	143	by (fact gcd_neg2_int)
03ff4d1e6784 eliminiated neg_numeral in favour of - (numeral _) haftmann parents: 54437 diff changeset	144
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	145	lemma abs_gcd_int[simp]: "abs(gcd (x::int) y) = gcd x y"
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	146	by(simp add: gcd_int_def)
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	147
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	148	lemma gcd_abs_int: "gcd (x::int) y = gcd (abs x) (abs y)"
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	149	by (simp add: gcd_int_def)
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	150
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	151	lemma gcd_abs1_int[simp]: "gcd (abs x) (y::int) = gcd x y"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	152	by (metis abs_idempotent gcd_abs_int)
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	153
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	154	lemma gcd_abs2_int[simp]: "gcd x (abs y::int) = gcd x y"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	155	by (metis abs_idempotent gcd_abs_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	156
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	157	lemma gcd_cases_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	158	fixes x :: int and y
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	159	assumes "x >= 0 \<Longrightarrow> y >= 0 \<Longrightarrow> P (gcd x y)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	160	and "x >= 0 \<Longrightarrow> y <= 0 \<Longrightarrow> P (gcd x (-y))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	161	and "x <= 0 \<Longrightarrow> y >= 0 \<Longrightarrow> P (gcd (-x) y)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	162	and "x <= 0 \<Longrightarrow> y <= 0 \<Longrightarrow> P (gcd (-x) (-y))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	163	shows "P (gcd x y)"
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	164	by (insert assms, auto, arith)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	165
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	166	lemma gcd_ge_0_int [simp]: "gcd (x::int) y >= 0"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	167	by (simp add: gcd_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	168
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	169	lemma lcm_neg1_int: "lcm (-x::int) y = lcm x y"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	170	by (simp add: lcm_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	171
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	172	lemma lcm_neg2_int: "lcm (x::int) (-y) = lcm x y"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	173	by (simp add: lcm_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	174
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	175	lemma lcm_abs_int: "lcm (x::int) y = lcm (abs x) (abs y)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	176	by (simp add: lcm_int_def)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	177
31814 7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	178	lemma abs_lcm_int [simp]: "abs (lcm i j::int) = lcm i j"
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	179	by(simp add:lcm_int_def)
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	180
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	181	lemma lcm_abs1_int[simp]: "lcm (abs x) (y::int) = lcm x y"
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	182	by (metis abs_idempotent lcm_int_def)
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	183
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	184	lemma lcm_abs2_int[simp]: "lcm x (abs y::int) = lcm x y"
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	185	by (metis abs_idempotent lcm_int_def)
7c122634da81 lcm abs lemmas nipkow parents: 31813 diff changeset	186
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	187	lemma lcm_cases_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	188	fixes x :: int and y
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	189	assumes "x >= 0 \<Longrightarrow> y >= 0 \<Longrightarrow> P (lcm x y)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	190	and "x >= 0 \<Longrightarrow> y <= 0 \<Longrightarrow> P (lcm x (-y))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	191	and "x <= 0 \<Longrightarrow> y >= 0 \<Longrightarrow> P (lcm (-x) y)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	192	and "x <= 0 \<Longrightarrow> y <= 0 \<Longrightarrow> P (lcm (-x) (-y))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	193	shows "P (lcm x y)"
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	194	using assms by (auto simp add: lcm_neg1_int lcm_neg2_int) arith
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	195
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	196	lemma lcm_ge_0_int [simp]: "lcm (x::int) y >= 0"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	197	by (simp add: lcm_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	198
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	199	(* was gcd_0, etc. *)
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	200	lemma gcd_0_nat: "gcd (x::nat) 0 = x"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	201	by simp
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	202
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	203	(* was igcd_0, etc. *)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	204	lemma gcd_0_int [simp]: "gcd (x::int) 0 = abs x"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	205	by (unfold gcd_int_def, auto)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	206
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	207	lemma gcd_0_left_nat: "gcd 0 (x::nat) = x"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	208	by simp
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	209
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	210	lemma gcd_0_left_int [simp]: "gcd 0 (x::int) = abs x"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	211	by (unfold gcd_int_def, auto)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	212
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	213	lemma gcd_red_nat: "gcd (x::nat) y = gcd y (x mod y)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	214	by (case_tac "y = 0", auto)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	215
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	216	(* weaker, but useful for the simplifier *)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	217
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	218	lemma gcd_non_0_nat: "y ~= (0::nat) \<Longrightarrow> gcd (x::nat) y = gcd y (x mod y)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	219	by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	220
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	221	lemma gcd_1_nat [simp]: "gcd (m::nat) 1 = 1"
21263 de65ce2bfb32 tuned; wenzelm parents: 21256 diff changeset	222	by simp
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	223
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	224	lemma gcd_Suc_0 [simp]: "gcd (m::nat) (Suc 0) = Suc 0"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	225	by (simp add: One_nat_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	226
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	227	lemma gcd_1_int [simp]: "gcd (m::int) 1 = 1"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	228	by (simp add: gcd_int_def)
30082 43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule huffman parents: 30042 diff changeset	229
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	230	lemma gcd_idem_nat: "gcd (x::nat) x = x"
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	231	by simp
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	232
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	233	lemma gcd_idem_int: "gcd (x::int) x = abs x"
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	234	by (auto simp add: gcd_int_def)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	235
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	236	declare gcd_nat.simps [simp del]
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	237
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	238	text {*
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	239	\medskip @{term "gcd m n"} divides @{text m} and @{text n}. The
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	240	conjunctions don't seem provable separately.
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	241	*}
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	242
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	243	lemma gcd_dvd1_nat [iff]: "(gcd (m::nat)) n dvd m"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	244	and gcd_dvd2_nat [iff]: "(gcd m n) dvd n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	245	apply (induct m n rule: gcd_nat_induct)
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	246	apply (simp_all add: gcd_non_0_nat gcd_0_nat)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	247	apply (blast dest: dvd_mod_imp_dvd)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	248	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	249
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	250	lemma gcd_dvd1_int [iff]: "gcd (x::int) y dvd x"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	251	by (metis gcd_int_def int_dvd_iff gcd_dvd1_nat)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	252
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	253	lemma gcd_dvd2_int [iff]: "gcd (x::int) y dvd y"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	254	by (metis gcd_int_def int_dvd_iff gcd_dvd2_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	255
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	256	lemma dvd_gcd_D1_nat: "k dvd gcd m n \<Longrightarrow> (k::nat) dvd m"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	257	by(metis gcd_dvd1_nat dvd_trans)
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	258
d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	259	lemma dvd_gcd_D2_nat: "k dvd gcd m n \<Longrightarrow> (k::nat) dvd n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	260	by(metis gcd_dvd2_nat dvd_trans)
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	261
d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	262	lemma dvd_gcd_D1_int: "i dvd gcd m n \<Longrightarrow> (i::int) dvd m"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	263	by(metis gcd_dvd1_int dvd_trans)
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	264
d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	265	lemma dvd_gcd_D2_int: "i dvd gcd m n \<Longrightarrow> (i::int) dvd n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	266	by(metis gcd_dvd2_int dvd_trans)
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	267
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	268	lemma gcd_le1_nat [simp]: "a \<noteq> 0 \<Longrightarrow> gcd (a::nat) b \<le> a"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	269	by (rule dvd_imp_le, auto)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	270
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	271	lemma gcd_le2_nat [simp]: "b \<noteq> 0 \<Longrightarrow> gcd (a::nat) b \<le> b"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	272	by (rule dvd_imp_le, auto)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	273
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	274	lemma gcd_le1_int [simp]: "a > 0 \<Longrightarrow> gcd (a::int) b \<le> a"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	275	by (rule zdvd_imp_le, auto)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	276
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	277	lemma gcd_le2_int [simp]: "b > 0 \<Longrightarrow> gcd (a::int) b \<le> b"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	278	by (rule zdvd_imp_le, auto)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	279
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	280	lemma gcd_greatest_nat: "(k::nat) dvd m \<Longrightarrow> k dvd n \<Longrightarrow> k dvd gcd m n"
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	281	by (induct m n rule: gcd_nat_induct) (simp_all add: gcd_non_0_nat dvd_mod gcd_0_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	282
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	283	lemma gcd_greatest_int:
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	284	"(k::int) dvd m \<Longrightarrow> k dvd n \<Longrightarrow> k dvd gcd m n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	285	apply (subst gcd_abs_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	286	apply (subst abs_dvd_iff [symmetric])
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	287	apply (rule gcd_greatest_nat [transferred])
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	288	apply auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	289	done
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	290
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	291	lemma gcd_greatest_iff_nat [iff]: "(k dvd gcd (m::nat) n) =
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	292	(k dvd m & k dvd n)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	293	by (blast intro!: gcd_greatest_nat intro: dvd_trans)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	294
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	295	lemma gcd_greatest_iff_int: "((k::int) dvd gcd m n) = (k dvd m & k dvd n)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	296	by (blast intro!: gcd_greatest_int intro: dvd_trans)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	297
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	298	lemma gcd_zero_nat [simp]: "(gcd (m::nat) n = 0) = (m = 0 & n = 0)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	299	by (simp only: dvd_0_left_iff [symmetric] gcd_greatest_iff_nat)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	300
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	301	lemma gcd_zero_int [simp]: "(gcd (m::int) n = 0) = (m = 0 & n = 0)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	302	by (auto simp add: gcd_int_def)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	303
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	304	lemma gcd_pos_nat [simp]: "(gcd (m::nat) n > 0) = (m ~= 0 \| n ~= 0)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	305	by (insert gcd_zero_nat [of m n], arith)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	306
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	307	lemma gcd_pos_int [simp]: "(gcd (m::int) n > 0) = (m ~= 0 \| n ~= 0)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	308	by (insert gcd_zero_int [of m n], insert gcd_ge_0_int [of m n], arith)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	309
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	310	lemma gcd_unique_nat: "(d::nat) dvd a \<and> d dvd b \<and>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	311	(\<forall>e. e dvd a \<and> e dvd b \<longrightarrow> e dvd d) \<longleftrightarrow> d = gcd a b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	312	apply auto
33657 a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	313	apply (rule dvd_antisym)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	314	apply (erule (1) gcd_greatest_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	315	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	316	done
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	317
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	318	lemma gcd_unique_int: "d >= 0 & (d::int) dvd a \<and> d dvd b \<and>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	319	(\<forall>e. e dvd a \<and> e dvd b \<longrightarrow> e dvd d) \<longleftrightarrow> d = gcd a b"
33657 a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	320	apply (case_tac "d = 0")
a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	321	apply simp
a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	322	apply (rule iffI)
a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	323	apply (rule zdvd_antisym_nonneg)
a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	324	apply (auto intro: gcd_greatest_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	325	done
30082 43c5b7bfc791 make more proofs work whether or not One_nat_def is a simp rule huffman parents: 30042 diff changeset	326
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	327	interpretation gcd_nat: abel_semigroup "gcd :: nat \<Rightarrow> nat \<Rightarrow> nat"
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	328	+ gcd_nat: semilattice_neutr_order "gcd :: nat \<Rightarrow> nat \<Rightarrow> nat" 0 "op dvd" "(\<lambda>m n. m dvd n \<and> \<not> n dvd m)"
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	329	apply default
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	330	apply (auto intro: dvd_antisym dvd_trans)[4]
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	331	apply (metis dvd.dual_order.refl gcd_unique_nat)
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	332	apply (auto intro: dvdI elim: dvdE)
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	333	done
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	334
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	335	interpretation gcd_int: abel_semigroup "gcd :: int \<Rightarrow> int \<Rightarrow> int"
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	336	proof
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	337	qed (simp_all add: gcd_int_def gcd_nat.assoc gcd_nat.commute gcd_nat.left_commute)
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	338
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	339	lemmas gcd_assoc_nat = gcd_nat.assoc
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	340	lemmas gcd_commute_nat = gcd_nat.commute
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	341	lemmas gcd_left_commute_nat = gcd_nat.left_commute
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	342	lemmas gcd_assoc_int = gcd_int.assoc
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	343	lemmas gcd_commute_int = gcd_int.commute
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	344	lemmas gcd_left_commute_int = gcd_int.left_commute
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	345
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	346	lemmas gcd_ac_nat = gcd_assoc_nat gcd_commute_nat gcd_left_commute_nat
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	347
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	348	lemmas gcd_ac_int = gcd_assoc_int gcd_commute_int gcd_left_commute_int
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	349
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	350	lemma gcd_proj1_if_dvd_nat [simp]: "(x::nat) dvd y \<Longrightarrow> gcd x y = x"
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	351	by (fact gcd_nat.absorb1)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	352
fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	353	lemma gcd_proj2_if_dvd_nat [simp]: "(y::nat) dvd x \<Longrightarrow> gcd x y = y"
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	354	by (fact gcd_nat.absorb2)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	355
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	356	lemma gcd_proj1_if_dvd_int [simp]: "x dvd y \<Longrightarrow> gcd (x::int) y = abs x"
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	357	by (metis abs_dvd_iff gcd_0_left_int gcd_abs_int gcd_unique_int)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	358
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	359	lemma gcd_proj2_if_dvd_int [simp]: "y dvd x \<Longrightarrow> gcd (x::int) y = abs y"
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	360	by (metis gcd_proj1_if_dvd_int gcd_commute_int)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	361
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	362	text {*
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	363	\medskip Multiplication laws
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	364	*}
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	365
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	366	lemma gcd_mult_distrib_nat: "(k::nat) * gcd m n = gcd (k * m) (k * n)"
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	367	-- {* \cite[page 27]{davenport92} *}
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	368	apply (induct m n rule: gcd_nat_induct)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	369	apply simp
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	370	apply (case_tac "k = 0")
45270 d5b5c9259afd fix bug in cancel_factor simprocs so they will work on goals like 'x * y < x * z' where the common term is already on the left huffman parents: 45264 diff changeset	371	apply (simp_all add: gcd_non_0_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	372	done
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	373
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	374	lemma gcd_mult_distrib_int: "abs (k::int) * gcd m n = gcd (k * m) (k * n)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	375	apply (subst (1 2) gcd_abs_int)
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	376	apply (subst (1 2) abs_mult)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	377	apply (rule gcd_mult_distrib_nat [transferred])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	378	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	379	done
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	380
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	381	lemma coprime_dvd_mult_nat: "coprime (k::nat) n \<Longrightarrow> k dvd m * n \<Longrightarrow> k dvd m"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	382	apply (insert gcd_mult_distrib_nat [of m k n])
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	383	apply simp
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	384	apply (erule_tac t = m in ssubst)
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	385	apply simp
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	386	done
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	387
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	388	lemma coprime_dvd_mult_int:
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	389	"coprime (k::int) n \<Longrightarrow> k dvd m * n \<Longrightarrow> k dvd m"
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	390	apply (subst abs_dvd_iff [symmetric])
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	391	apply (subst dvd_abs_iff [symmetric])
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	392	apply (subst (asm) gcd_abs_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	393	apply (rule coprime_dvd_mult_nat [transferred])
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	394	prefer 4 apply assumption
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	395	apply auto
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	396	apply (subst abs_mult [symmetric], auto)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	397	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	398
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	399	lemma coprime_dvd_mult_iff_nat: "coprime (k::nat) n \<Longrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	400	(k dvd m * n) = (k dvd m)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	401	by (auto intro: coprime_dvd_mult_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	402
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	403	lemma coprime_dvd_mult_iff_int: "coprime (k::int) n \<Longrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	404	(k dvd m * n) = (k dvd m)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	405	by (auto intro: coprime_dvd_mult_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	406
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	407	lemma gcd_mult_cancel_nat: "coprime k n \<Longrightarrow> gcd ((k::nat) * m) n = gcd m n"
33657 a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	408	apply (rule dvd_antisym)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	409	apply (rule gcd_greatest_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	410	apply (rule_tac n = k in coprime_dvd_mult_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	411	apply (simp add: gcd_assoc_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	412	apply (simp add: gcd_commute_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	413	apply (simp_all add: mult_commute)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	414	done
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	415
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	416	lemma gcd_mult_cancel_int:
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	417	"coprime (k::int) n \<Longrightarrow> gcd (k * m) n = gcd m n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	418	apply (subst (1 2) gcd_abs_int)
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	419	apply (subst abs_mult)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	420	apply (rule gcd_mult_cancel_nat [transferred], auto)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	421	done
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	422
35368 19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	423	lemma coprime_crossproduct_nat:
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	424	fixes a b c d :: nat
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	425	assumes "coprime a d" and "coprime b c"
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	426	shows "a * c = b * d \<longleftrightarrow> a = b \<and> c = d" (is "?lhs \<longleftrightarrow> ?rhs")
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	427	proof
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	428	assume ?rhs then show ?lhs by simp
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	429	next
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	430	assume ?lhs
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	431	from `?lhs` have "a dvd b * d" by (auto intro: dvdI dest: sym)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	432	with `coprime a d` have "a dvd b" by (simp add: coprime_dvd_mult_iff_nat)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	433	from `?lhs` have "b dvd a * c" by (auto intro: dvdI dest: sym)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	434	with `coprime b c` have "b dvd a" by (simp add: coprime_dvd_mult_iff_nat)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	435	from `?lhs` have "c dvd d * b" by (auto intro: dvdI dest: sym simp add: mult_commute)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	436	with `coprime b c` have "c dvd d" by (simp add: coprime_dvd_mult_iff_nat gcd_commute_nat)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	437	from `?lhs` have "d dvd c * a" by (auto intro: dvdI dest: sym simp add: mult_commute)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	438	with `coprime a d` have "d dvd c" by (simp add: coprime_dvd_mult_iff_nat gcd_commute_nat)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	439	from `a dvd b` `b dvd a` have "a = b" by (rule Nat.dvd.antisym)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	440	moreover from `c dvd d` `d dvd c` have "c = d" by (rule Nat.dvd.antisym)
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	441	ultimately show ?rhs ..
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	442	qed
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	443
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	444	lemma coprime_crossproduct_int:
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	445	fixes a b c d :: int
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	446	assumes "coprime a d" and "coprime b c"
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	447	shows "\<bar>a\<bar> * \<bar>c\<bar> = \<bar>b\<bar> * \<bar>d\<bar> \<longleftrightarrow> \<bar>a\<bar> = \<bar>b\<bar> \<and> \<bar>c\<bar> = \<bar>d\<bar>"
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	448	using assms by (intro coprime_crossproduct_nat [transferred]) auto
19b340c3f1ff crossproduct coprimality lemmas haftmann parents: 35216 diff changeset	449
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	450	text {* \medskip Addition laws *}
47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	451
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	452	lemma gcd_add1_nat [simp]: "gcd ((m::nat) + n) n = gcd m n"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	453	apply (case_tac "n = 0")
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	454	apply (simp_all add: gcd_non_0_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	455	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	456
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	457	lemma gcd_add2_nat [simp]: "gcd (m::nat) (m + n) = gcd m n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	458	apply (subst (1 2) gcd_commute_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	459	apply (subst add_commute)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	460	apply simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	461	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	462
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	463	(* to do: add the other variations? *)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	464
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	465	lemma gcd_diff1_nat: "(m::nat) >= n \<Longrightarrow> gcd (m - n) n = gcd m n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	466	by (subst gcd_add1_nat [symmetric], auto)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	467
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	468	lemma gcd_diff2_nat: "(n::nat) >= m \<Longrightarrow> gcd (n - m) n = gcd m n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	469	apply (subst gcd_commute_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	470	apply (subst gcd_diff1_nat [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	471	apply auto
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	472	apply (subst gcd_commute_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	473	apply (subst gcd_diff1_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	474	apply assumption
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	475	apply (rule gcd_commute_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	476	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	477
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	478	lemma gcd_non_0_int: "(y::int) > 0 \<Longrightarrow> gcd x y = gcd y (x mod y)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	479	apply (frule_tac b = y and a = x in pos_mod_sign)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	480	apply (simp del: pos_mod_sign add: gcd_int_def abs_if nat_mod_distrib)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	481	apply (auto simp add: gcd_non_0_nat nat_mod_distrib [symmetric]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	482	zmod_zminus1_eq_if)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	483	apply (frule_tac a = x in pos_mod_bound)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	484	apply (subst (1 2) gcd_commute_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	485	apply (simp del: pos_mod_bound add: nat_diff_distrib gcd_diff2_nat
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	486	nat_le_eq_zle)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	487	done
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	488
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	489	lemma gcd_red_int: "gcd (x::int) y = gcd y (x mod y)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	490	apply (case_tac "y = 0")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	491	apply force
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	492	apply (case_tac "y > 0")
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	493	apply (subst gcd_non_0_int, auto)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	494	apply (insert gcd_non_0_int [of "-y" "-x"])
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	495	apply auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	496	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	497
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	498	lemma gcd_add1_int [simp]: "gcd ((m::int) + n) n = gcd m n"
44821 a92f65e174cf avoid using legacy theorem names huffman parents: 44766 diff changeset	499	by (metis gcd_red_int mod_add_self1 add_commute)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	500
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	501	lemma gcd_add2_int [simp]: "gcd m ((m::int) + n) = gcd m n"
44821 a92f65e174cf avoid using legacy theorem names huffman parents: 44766 diff changeset	502	by (metis gcd_add1_int gcd_commute_int add_commute)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	503
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	504	lemma gcd_add_mult_nat: "gcd (m::nat) (k * m + n) = gcd m n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	505	by (metis mod_mult_self3 gcd_commute_nat gcd_red_nat)
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	506
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	507	lemma gcd_add_mult_int: "gcd (m::int) (k * m + n) = gcd m n"
44821 a92f65e174cf avoid using legacy theorem names huffman parents: 44766 diff changeset	508	by (metis gcd_commute_int gcd_red_int mod_mult_self1 add_commute)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	509
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	510
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	511	(* to do: differences, and all variations of addition rules
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	512	as simplification rules for nat and int *)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	513
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	514	(* FIXME remove iff *)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	515	lemma gcd_dvd_prod_nat [iff]: "gcd (m::nat) n dvd k * n"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	516	using mult_dvd_mono [of 1] by auto
22027 e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	517
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	518	(* to do: add the three variations of these, and for ints? *)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	519
31992 f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	520	lemma finite_divisors_nat[simp]:
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	521	assumes "(m::nat) ~= 0" shows "finite{d. d dvd m}"
31734 a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	522	proof-
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	523	have "finite{d. d <= m}" by(blast intro: bounded_nat_set_is_finite)
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	524	from finite_subset[OF _ this] show ?thesis using assms
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	525	by(bestsimp intro!:dvd_imp_le)
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	526	qed
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	527
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	528	lemma finite_divisors_int[simp]:
31734 a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	529	assumes "(i::int) ~= 0" shows "finite{d. d dvd i}"
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	530	proof-
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	531	have "{d. abs d <= abs i} = {- abs i .. abs i}" by(auto simp:abs_if)
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	532	hence "finite{d. abs d <= abs i}" by simp
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	533	from finite_subset[OF _ this] show ?thesis using assms
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	534	by(bestsimp intro!:dvd_imp_le_int)
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	535	qed
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	536
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	537	lemma Max_divisors_self_nat[simp]: "n\<noteq>0 \<Longrightarrow> Max{d::nat. d dvd n} = n"
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	538	apply(rule antisym)
44890 22f665a2e91c new fastforce replacing fastsimp - less confusing name nipkow parents: 44845 diff changeset	539	apply (fastforce intro: Max_le_iff[THEN iffD2] simp: dvd_imp_le)
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	540	apply simp
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	541	done
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	542
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	543	lemma Max_divisors_self_int[simp]: "n\<noteq>0 \<Longrightarrow> Max{d::int. d dvd n} = abs n"
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	544	apply(rule antisym)
44278 1220ecb81e8f observe distinction between sets and predicates more properly haftmann parents: 42871 diff changeset	545	apply(rule Max_le_iff [THEN iffD2])
1220ecb81e8f observe distinction between sets and predicates more properly haftmann parents: 42871 diff changeset	546	apply (auto intro: abs_le_D1 dvd_imp_le_int)
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	547	done
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	548
31734 a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	549	lemma gcd_is_Max_divisors_nat:
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	550	"m ~= 0 \<Longrightarrow> n ~= 0 \<Longrightarrow> gcd (m::nat) n = (Max {d. d dvd m & d dvd n})"
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	551	apply(rule Max_eqI[THEN sym])
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	552	apply (metis finite_Collect_conjI finite_divisors_nat)
31734 a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	553	apply simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	554	apply(metis Suc_diff_1 Suc_neq_Zero dvd_imp_le gcd_greatest_iff_nat gcd_pos_nat)
31734 a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	555	apply simp
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	556	done
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	557
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	558	lemma gcd_is_Max_divisors_int:
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	559	"m ~= 0 ==> n ~= 0 ==> gcd (m::int) n = (Max {d. d dvd m & d dvd n})"
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	560	apply(rule Max_eqI[THEN sym])
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	561	apply (metis finite_Collect_conjI finite_divisors_int)
31734 a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	562	apply simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	563	apply (metis gcd_greatest_iff_int gcd_pos_int zdvd_imp_le)
31734 a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	564	apply simp
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	565	done
a4a79836d07b new lemmas nipkow parents: 31730 diff changeset	566
34030 829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	567	lemma gcd_code_int [code]:
829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	568	"gcd k l = \<bar>if l = (0::int) then k else gcd l (\<bar>k\<bar> mod \<bar>l\<bar>)\<bar>"
829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	569	by (simp add: gcd_int_def nat_mod_distrib gcd_non_0_nat)
829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	570
22027 e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	571
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	572	subsection {* Coprimality *}
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	573
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	574	lemma div_gcd_coprime_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	575	assumes nz: "(a::nat) \<noteq> 0 \<or> b \<noteq> 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	576	shows "coprime (a div gcd a b) (b div gcd a b)"
22367 6860f09242bf tuned document; wenzelm parents: 22027 diff changeset	577	proof -
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	578	let ?g = "gcd a b"
22027 e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	579	let ?a' = "a div ?g"
e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	580	let ?b' = "b div ?g"
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	581	let ?g' = "gcd ?a' ?b'"
22027 e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	582	have dvdg: "?g dvd a" "?g dvd b" by simp_all
e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	583	have dvdg': "?g' dvd ?a'" "?g' dvd ?b'" by simp_all
22367 6860f09242bf tuned document; wenzelm parents: 22027 diff changeset	584	from dvdg dvdg' obtain ka kb ka' kb' where
6860f09242bf tuned document; wenzelm parents: 22027 diff changeset	585	kab: "a = ?g * ka" "b = ?g * kb" "?a' = ?g' * ka'" "?b' = ?g' * kb'"
22027 e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	586	unfolding dvd_def by blast
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	587	then have "?g * ?a' = (?g * ?g') * ka'" "?g * ?b' = (?g * ?g') * kb'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	588	by simp_all
22367 6860f09242bf tuned document; wenzelm parents: 22027 diff changeset	589	then have dvdgg':"?g * ?g' dvd a" "?g* ?g' dvd b"
6860f09242bf tuned document; wenzelm parents: 22027 diff changeset	590	by (auto simp add: dvd_mult_div_cancel [OF dvdg(1)]
6860f09242bf tuned document; wenzelm parents: 22027 diff changeset	591	dvd_mult_div_cancel [OF dvdg(2)] dvd_def)
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	592	have "?g \<noteq> 0" using nz by simp
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	593	then have gp: "?g > 0" by arith
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	594	from gcd_greatest_nat [OF dvdgg'] have "?g * ?g' dvd ?g" .
22367 6860f09242bf tuned document; wenzelm parents: 22027 diff changeset	595	with dvd_mult_cancel1 [OF gp] show "?g' = 1" by simp
22027 e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	596	qed
e4a08629c4bd A few lemmas about relative primes when dividing trough gcd chaieb parents: 21404 diff changeset	597
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	598	lemma div_gcd_coprime_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	599	assumes nz: "(a::int) \<noteq> 0 \<or> b \<noteq> 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	600	shows "coprime (a div gcd a b) (b div gcd a b)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	601	apply (subst (1 2 3) gcd_abs_int)
31813 4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	602	apply (subst (1 2) abs_div)
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	603	apply simp
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	604	apply simp
4df828bbc411 gcd abs lemmas nipkow parents: 31798 diff changeset	605	apply(subst (1 2) abs_gcd_int)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	606	apply (rule div_gcd_coprime_nat [transferred])
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	607	using nz apply (auto simp add: gcd_abs_int [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	608	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	609
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	610	lemma coprime_nat: "coprime (a::nat) b \<longleftrightarrow> (\<forall>d. d dvd a \<and> d dvd b \<longleftrightarrow> d = 1)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	611	using gcd_unique_nat[of 1 a b, simplified] by auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	612
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	613	lemma coprime_Suc_0_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	614	"coprime (a::nat) b \<longleftrightarrow> (\<forall>d. d dvd a \<and> d dvd b \<longleftrightarrow> d = Suc 0)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	615	using coprime_nat by (simp add: One_nat_def)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	616
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	617	lemma coprime_int: "coprime (a::int) b \<longleftrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	618	(\<forall>d. d >= 0 \<and> d dvd a \<and> d dvd b \<longleftrightarrow> d = 1)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	619	using gcd_unique_int [of 1 a b]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	620	apply clarsimp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	621	apply (erule subst)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	622	apply (rule iffI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	623	apply force
48562 f6d6d58fa318 tuned proofs -- avoid odd situations of polymorphic Frees in goal state; wenzelm parents: 45992 diff changeset	624	apply (drule_tac x = "abs ?e" in exI)
f6d6d58fa318 tuned proofs -- avoid odd situations of polymorphic Frees in goal state; wenzelm parents: 45992 diff changeset	625	apply (case_tac "(?e::int) >= 0")
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	626	apply force
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	627	apply force
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	628	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	629
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	630	lemma gcd_coprime_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	631	assumes z: "gcd (a::nat) b \<noteq> 0" and a: "a = a' * gcd a b" and
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	632	b: "b = b' * gcd a b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	633	shows "coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	634
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	635	apply (subgoal_tac "a' = a div gcd a b")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	636	apply (erule ssubst)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	637	apply (subgoal_tac "b' = b div gcd a b")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	638	apply (erule ssubst)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	639	apply (rule div_gcd_coprime_nat)
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	640	using z apply force
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	641	apply (subst (1) b)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	642	using z apply force
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	643	apply (subst (1) a)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	644	using z apply force
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	645	done
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	646
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	647	lemma gcd_coprime_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	648	assumes z: "gcd (a::int) b \<noteq> 0" and a: "a = a' * gcd a b" and
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	649	b: "b = b' * gcd a b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	650	shows "coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	651
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	652	apply (subgoal_tac "a' = a div gcd a b")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	653	apply (erule ssubst)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	654	apply (subgoal_tac "b' = b div gcd a b")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	655	apply (erule ssubst)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	656	apply (rule div_gcd_coprime_int)
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	657	using z apply force
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	658	apply (subst (1) b)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	659	using z apply force
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	660	apply (subst (1) a)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	661	using z apply force
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	662	done
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	663
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	664	lemma coprime_mult_nat: assumes da: "coprime (d::nat) a" and db: "coprime d b"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	665	shows "coprime d (a * b)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	666	apply (subst gcd_commute_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	667	using da apply (subst gcd_mult_cancel_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	668	apply (subst gcd_commute_nat, assumption)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	669	apply (subst gcd_commute_nat, rule db)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	670	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	671
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	672	lemma coprime_mult_int: assumes da: "coprime (d::int) a" and db: "coprime d b"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	673	shows "coprime d (a * b)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	674	apply (subst gcd_commute_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	675	using da apply (subst gcd_mult_cancel_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	676	apply (subst gcd_commute_int, assumption)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	677	apply (subst gcd_commute_int, rule db)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	678	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	679
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	680	lemma coprime_lmult_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	681	assumes dab: "coprime (d::nat) (a * b)" shows "coprime d a"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	682	proof -
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	683	have "gcd d a dvd gcd d (a * b)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	684	by (rule gcd_greatest_nat, auto)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	685	with dab show ?thesis
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	686	by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	687	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	688
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	689	lemma coprime_lmult_int:
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	690	assumes "coprime (d::int) (a * b)" shows "coprime d a"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	691	proof -
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	692	have "gcd d a dvd gcd d (a * b)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	693	by (rule gcd_greatest_int, auto)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	694	with assms show ?thesis
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	695	by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	696	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	697
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	698	lemma coprime_rmult_nat:
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	699	assumes "coprime (d::nat) (a * b)" shows "coprime d b"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	700	proof -
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	701	have "gcd d b dvd gcd d (a * b)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	702	by (rule gcd_greatest_nat, auto intro: dvd_mult)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	703	with assms show ?thesis
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	704	by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	705	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	706
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	707	lemma coprime_rmult_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	708	assumes dab: "coprime (d::int) (a * b)" shows "coprime d b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	709	proof -
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	710	have "gcd d b dvd gcd d (a * b)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	711	by (rule gcd_greatest_int, auto intro: dvd_mult)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	712	with dab show ?thesis
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	713	by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	714	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	715
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	716	lemma coprime_mul_eq_nat: "coprime (d::nat) (a * b) \<longleftrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	717	coprime d a \<and> coprime d b"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	718	using coprime_rmult_nat[of d a b] coprime_lmult_nat[of d a b]
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	719	coprime_mult_nat[of d a b]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	720	by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	721
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	722	lemma coprime_mul_eq_int: "coprime (d::int) (a * b) \<longleftrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	723	coprime d a \<and> coprime d b"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	724	using coprime_rmult_int[of d a b] coprime_lmult_int[of d a b]
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	725	coprime_mult_int[of d a b]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	726	by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	727
52397 e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	728	lemma coprime_power_int:
e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	729	assumes "0 < n" shows "coprime (a :: int) (b ^ n) \<longleftrightarrow> coprime a b"
e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	730	using assms
e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	731	proof (induct n)
e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	732	case (Suc n) then show ?case
e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	733	by (cases n) (simp_all add: coprime_mul_eq_int)
e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	734	qed simp
e95f6b4b1bcf added coprimality lemma noschinl parents: 51547 diff changeset	735
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	736	lemma gcd_coprime_exists_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	737	assumes nz: "gcd (a::nat) b \<noteq> 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	738	shows "\<exists>a' b'. a = a' * gcd a b \<and> b = b' * gcd a b \<and> coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	739	apply (rule_tac x = "a div gcd a b" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	740	apply (rule_tac x = "b div gcd a b" in exI)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	741	using nz apply (auto simp add: div_gcd_coprime_nat dvd_div_mult)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	742	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	743
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	744	lemma gcd_coprime_exists_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	745	assumes nz: "gcd (a::int) b \<noteq> 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	746	shows "\<exists>a' b'. a = a' * gcd a b \<and> b = b' * gcd a b \<and> coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	747	apply (rule_tac x = "a div gcd a b" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	748	apply (rule_tac x = "b div gcd a b" in exI)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	749	using nz apply (auto simp add: div_gcd_coprime_int dvd_div_mult_self)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	750	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	751
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	752	lemma coprime_exp_nat: "coprime (d::nat) a \<Longrightarrow> coprime d (a^n)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	753	by (induct n, simp_all add: coprime_mult_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	754
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	755	lemma coprime_exp_int: "coprime (d::int) a \<Longrightarrow> coprime d (a^n)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	756	by (induct n, simp_all add: coprime_mult_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	757
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	758	lemma coprime_exp2_nat [intro]: "coprime (a::nat) b \<Longrightarrow> coprime (a^n) (b^m)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	759	apply (rule coprime_exp_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	760	apply (subst gcd_commute_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	761	apply (rule coprime_exp_nat)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	762	apply (subst gcd_commute_nat, assumption)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	763	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	764
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	765	lemma coprime_exp2_int [intro]: "coprime (a::int) b \<Longrightarrow> coprime (a^n) (b^m)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	766	apply (rule coprime_exp_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	767	apply (subst gcd_commute_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	768	apply (rule coprime_exp_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	769	apply (subst gcd_commute_int, assumption)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	770	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	771
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	772	lemma gcd_exp_nat: "gcd ((a::nat)^n) (b^n) = (gcd a b)^n"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	773	proof (cases)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	774	assume "a = 0 & b = 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	775	thus ?thesis by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	776	next assume "~(a = 0 & b = 0)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	777	hence "coprime ((a div gcd a b)^n) ((b div gcd a b)^n)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	778	by (auto simp:div_gcd_coprime_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	779	hence "gcd ((a div gcd a b)^n * (gcd a b)^n)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	780	((b div gcd a b)^n * (gcd a b)^n) = (gcd a b)^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	781	apply (subst (1 2) mult_commute)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	782	apply (subst gcd_mult_distrib_nat [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	783	apply simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	784	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	785	also have "(a div gcd a b)^n * (gcd a b)^n = a^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	786	apply (subst div_power)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	787	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	788	apply (rule dvd_div_mult_self)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	789	apply (rule dvd_power_same)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	790	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	791	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	792	also have "(b div gcd a b)^n * (gcd a b)^n = b^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	793	apply (subst div_power)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	794	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	795	apply (rule dvd_div_mult_self)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	796	apply (rule dvd_power_same)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	797	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	798	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	799	finally show ?thesis .
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	800	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	801
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	802	lemma gcd_exp_int: "gcd ((a::int)^n) (b^n) = (gcd a b)^n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	803	apply (subst (1 2) gcd_abs_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	804	apply (subst (1 2) power_abs)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	805	apply (rule gcd_exp_nat [where n = n, transferred])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	806	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	807	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	808
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	809	lemma division_decomp_nat: assumes dc: "(a::nat) dvd b * c"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	810	shows "\<exists>b' c'. a = b' * c' \<and> b' dvd b \<and> c' dvd c"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	811	proof-
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	812	let ?g = "gcd a b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	813	{assume "?g = 0" with dc have ?thesis by auto}
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	814	moreover
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	815	{assume z: "?g \<noteq> 0"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	816	from gcd_coprime_exists_nat[OF z]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	817	obtain a' b' where ab': "a = a' * ?g" "b = b' * ?g" "coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	818	by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	819	have thb: "?g dvd b" by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	820	from ab'(1) have "a' dvd a" unfolding dvd_def by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	821	with dc have th0: "a' dvd bc" using dvd_trans[of a' a "bc"] by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	822	from dc ab'(1,2) have "a'?g dvd (b'?g) *c" by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	823	hence "?ga' dvd ?g (b' * c)" by (simp add: mult_assoc)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	824	with z have th_1: "a' dvd b' * c" by auto
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	825	from coprime_dvd_mult_nat[OF ab'(3)] th_1
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	826	have thc: "a' dvd c" by (subst (asm) mult_commute, blast)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	827	from ab' have "a = ?g*a'" by algebra
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	828	with thb thc have ?thesis by blast }
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	829	ultimately show ?thesis by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	830	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	831
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	832	lemma division_decomp_int: assumes dc: "(a::int) dvd b * c"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	833	shows "\<exists>b' c'. a = b' * c' \<and> b' dvd b \<and> c' dvd c"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	834	proof-
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	835	let ?g = "gcd a b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	836	{assume "?g = 0" with dc have ?thesis by auto}
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	837	moreover
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	838	{assume z: "?g \<noteq> 0"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	839	from gcd_coprime_exists_int[OF z]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	840	obtain a' b' where ab': "a = a' * ?g" "b = b' * ?g" "coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	841	by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	842	have thb: "?g dvd b" by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	843	from ab'(1) have "a' dvd a" unfolding dvd_def by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	844	with dc have th0: "a' dvd b*c"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	845	using dvd_trans[of a' a "b*c"] by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	846	from dc ab'(1,2) have "a'?g dvd (b'?g) *c" by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	847	hence "?ga' dvd ?g (b' * c)" by (simp add: mult_assoc)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	848	with z have th_1: "a' dvd b' * c" by auto
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	849	from coprime_dvd_mult_int[OF ab'(3)] th_1
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	850	have thc: "a' dvd c" by (subst (asm) mult_commute, blast)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	851	from ab' have "a = ?g*a'" by algebra
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	852	with thb thc have ?thesis by blast }
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	853	ultimately show ?thesis by blast
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	854	qed
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	855
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	856	lemma pow_divides_pow_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	857	assumes ab: "(a::nat) ^ n dvd b ^n" and n:"n \<noteq> 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	858	shows "a dvd b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	859	proof-
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	860	let ?g = "gcd a b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	861	from n obtain m where m: "n = Suc m" by (cases n, simp_all)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	862	{assume "?g = 0" with ab n have ?thesis by auto }
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	863	moreover
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	864	{assume z: "?g \<noteq> 0"
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	865	hence zn: "?g ^ n \<noteq> 0" using n by simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	866	from gcd_coprime_exists_nat[OF z]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	867	obtain a' b' where ab': "a = a' * ?g" "b = b' * ?g" "coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	868	by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	869	from ab have "(a' * ?g) ^ n dvd (b' * ?g)^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	870	by (simp add: ab'(1,2)[symmetric])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	871	hence "?g^na'^n dvd ?g^n b'^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	872	by (simp only: power_mult_distrib mult_commute)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	873	with zn z n have th0:"a'^n dvd b'^n" by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	874	have "a' dvd a'^n" by (simp add: m)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	875	with th0 have "a' dvd b'^n" using dvd_trans[of a' "a'^n" "b'^n"] by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	876	hence th1: "a' dvd b'^m * b'" by (simp add: m mult_commute)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	877	from coprime_dvd_mult_nat[OF coprime_exp_nat [OF ab'(3), of m]] th1
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	878	have "a' dvd b'" by (subst (asm) mult_commute, blast)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	879	hence "a'?g dvd b'?g" by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	880	with ab'(1,2) have ?thesis by simp }
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	881	ultimately show ?thesis by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	882	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	883
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	884	lemma pow_divides_pow_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	885	assumes ab: "(a::int) ^ n dvd b ^n" and n:"n \<noteq> 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	886	shows "a dvd b"
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	887	proof-
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	888	let ?g = "gcd a b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	889	from n obtain m where m: "n = Suc m" by (cases n, simp_all)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	890	{assume "?g = 0" with ab n have ?thesis by auto }
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	891	moreover
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	892	{assume z: "?g \<noteq> 0"
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	893	hence zn: "?g ^ n \<noteq> 0" using n by simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	894	from gcd_coprime_exists_int[OF z]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	895	obtain a' b' where ab': "a = a' * ?g" "b = b' * ?g" "coprime a' b'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	896	by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	897	from ab have "(a' * ?g) ^ n dvd (b' * ?g)^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	898	by (simp add: ab'(1,2)[symmetric])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	899	hence "?g^na'^n dvd ?g^n b'^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	900	by (simp only: power_mult_distrib mult_commute)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	901	with zn z n have th0:"a'^n dvd b'^n" by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	902	have "a' dvd a'^n" by (simp add: m)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	903	with th0 have "a' dvd b'^n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	904	using dvd_trans[of a' "a'^n" "b'^n"] by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	905	hence th1: "a' dvd b'^m * b'" by (simp add: m mult_commute)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	906	from coprime_dvd_mult_int[OF coprime_exp_int [OF ab'(3), of m]] th1
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	907	have "a' dvd b'" by (subst (asm) mult_commute, blast)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	908	hence "a'?g dvd b'?g" by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	909	with ab'(1,2) have ?thesis by simp }
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	910	ultimately show ?thesis by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	911	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	912
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	913	lemma pow_divides_eq_nat [simp]: "n ~= 0 \<Longrightarrow> ((a::nat)^n dvd b^n) = (a dvd b)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	914	by (auto intro: pow_divides_pow_nat dvd_power_same)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	915
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	916	lemma pow_divides_eq_int [simp]: "n ~= 0 \<Longrightarrow> ((a::int)^n dvd b^n) = (a dvd b)"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	917	by (auto intro: pow_divides_pow_int dvd_power_same)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	918
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	919	lemma divides_mult_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	920	assumes mr: "(m::nat) dvd r" and nr: "n dvd r" and mn:"coprime m n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	921	shows "m * n dvd r"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	922	proof-
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	923	from mr nr obtain m' n' where m': "r = mm'" and n': "r = nn'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	924	unfolding dvd_def by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	925	from mr n' have "m dvd n'*n" by (simp add: mult_commute)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	926	hence "m dvd n'" using coprime_dvd_mult_iff_nat[OF mn] by simp
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	927	then obtain k where k: "n' = m*k" unfolding dvd_def by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	928	from n' k show ?thesis unfolding dvd_def by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	929	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	930
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	931	lemma divides_mult_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	932	assumes mr: "(m::int) dvd r" and nr: "n dvd r" and mn:"coprime m n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	933	shows "m * n dvd r"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	934	proof-
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	935	from mr nr obtain m' n' where m': "r = mm'" and n': "r = nn'"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	936	unfolding dvd_def by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	937	from mr n' have "m dvd n'*n" by (simp add: mult_commute)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	938	hence "m dvd n'" using coprime_dvd_mult_iff_int[OF mn] by simp
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	939	then obtain k where k: "n' = m*k" unfolding dvd_def by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	940	from n' k show ?thesis unfolding dvd_def by auto
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	941	qed
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	942
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	943	lemma coprime_plus_one_nat [simp]: "coprime ((n::nat) + 1) n"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	944	apply (subgoal_tac "gcd (n + 1) n dvd (n + 1 - n)")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	945	apply force
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	946	apply (rule dvd_diff_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	947	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	948	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	949
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	950	lemma coprime_Suc_nat [simp]: "coprime (Suc n) n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	951	using coprime_plus_one_nat by (simp add: One_nat_def)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	952
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	953	lemma coprime_plus_one_int [simp]: "coprime ((n::int) + 1) n"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	954	apply (subgoal_tac "gcd (n + 1) n dvd (n + 1 - n)")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	955	apply force
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	956	apply (rule dvd_diff)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	957	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	958	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	959
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	960	lemma coprime_minus_one_nat: "(n::nat) \<noteq> 0 \<Longrightarrow> coprime (n - 1) n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	961	using coprime_plus_one_nat [of "n - 1"]
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	962	gcd_commute_nat [of "n - 1" n] by auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	963
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	964	lemma coprime_minus_one_int: "coprime ((n::int) - 1) n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	965	using coprime_plus_one_int [of "n - 1"]
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	966	gcd_commute_int [of "n - 1" n] by auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	967
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	968	lemma setprod_coprime_nat [rule_format]:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	969	"(ALL i: A. coprime (f i) (x::nat)) --> coprime (PROD i:A. f i) x"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	970	apply (case_tac "finite A")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	971	apply (induct set: finite)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	972	apply (auto simp add: gcd_mult_cancel_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	973	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	974
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	975	lemma setprod_coprime_int [rule_format]:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	976	"(ALL i: A. coprime (f i) (x::int)) --> coprime (PROD i:A. f i) x"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	977	apply (case_tac "finite A")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	978	apply (induct set: finite)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	979	apply (auto simp add: gcd_mult_cancel_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	980	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	981
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	982	lemma coprime_common_divisor_nat: "coprime (a::nat) b \<Longrightarrow> x dvd a \<Longrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	983	x dvd b \<Longrightarrow> x = 1"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	984	apply (subgoal_tac "x dvd gcd a b")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	985	apply simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	986	apply (erule (1) gcd_greatest_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	987	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	988
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	989	lemma coprime_common_divisor_int: "coprime (a::int) b \<Longrightarrow> x dvd a \<Longrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	990	x dvd b \<Longrightarrow> abs x = 1"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	991	apply (subgoal_tac "x dvd gcd a b")
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	992	apply simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	993	apply (erule (1) gcd_greatest_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	994	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	995
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	996	lemma coprime_divisors_nat: "(d::int) dvd a \<Longrightarrow> e dvd b \<Longrightarrow> coprime a b \<Longrightarrow>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	997	coprime d e"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	998	apply (auto simp add: dvd_def)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	999	apply (frule coprime_lmult_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1000	apply (subst gcd_commute_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1001	apply (subst (asm) (2) gcd_commute_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1002	apply (erule coprime_lmult_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1003	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1004
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1005	lemma invertible_coprime_nat: "(x::nat) * y mod m = 1 \<Longrightarrow> coprime x m"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1006	apply (metis coprime_lmult_nat gcd_1_nat gcd_commute_nat gcd_red_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1007	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1008
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1009	lemma invertible_coprime_int: "(x::int) * y mod m = 1 \<Longrightarrow> coprime x m"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1010	apply (metis coprime_lmult_int gcd_1_int gcd_commute_int gcd_red_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1011	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1012
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1013
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1014	subsection {* Bezout's theorem *}
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1015
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1016	(* Function bezw returns a pair of witnesses to Bezout's theorem --
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1017	see the theorems that follow the definition. *)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1018	fun
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1019	bezw :: "nat \<Rightarrow> nat \<Rightarrow> int * int"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1020	where
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1021	"bezw x y =
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1022	(if y = 0 then (1, 0) else
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1023	(snd (bezw y (x mod y)),
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1024	fst (bezw y (x mod y)) - snd (bezw y (x mod y)) * int(x div y)))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1025
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1026	lemma bezw_0 [simp]: "bezw x 0 = (1, 0)" by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1027
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1028	lemma bezw_non_0: "y > 0 \<Longrightarrow> bezw x y = (snd (bezw y (x mod y)),
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1029	fst (bezw y (x mod y)) - snd (bezw y (x mod y)) * int(x div y))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1030	by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1031
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1032	declare bezw.simps [simp del]
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1033
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1034	lemma bezw_aux [rule_format]:
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1035	"fst (bezw x y) * int x + snd (bezw x y) * int y = int (gcd x y)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1036	proof (induct x y rule: gcd_nat_induct)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1037	fix m :: nat
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1038	show "fst (bezw m 0) * int m + snd (bezw m 0) * int 0 = int (gcd m 0)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1039	by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1040	next fix m :: nat and n
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1041	assume ngt0: "n > 0" and
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1042	ih: "fst (bezw n (m mod n)) * int n +
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1043	snd (bezw n (m mod n)) * int (m mod n) =
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1044	int (gcd n (m mod n))"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1045	thus "fst (bezw m n) * int m + snd (bezw m n) * int n = int (gcd m n)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1046	apply (simp add: bezw_non_0 gcd_non_0_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1047	apply (erule subst)
36350 bc7982c54e37 dropped group_simps, ring_simps, field_eq_simps haftmann parents: 35726 diff changeset	1048	apply (simp add: field_simps)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1049	apply (subst mod_div_equality [of m n, symmetric])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1050	(* applying simp here undoes the last substitution!
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1051	what is procedure cancel_div_mod? *)
44821 a92f65e174cf avoid using legacy theorem names huffman parents: 44766 diff changeset	1052	apply (simp only: field_simps of_nat_add of_nat_mult)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1053	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1054	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1055
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1056	lemma bezout_int:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1057	fixes x y
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1058	shows "EX u v. u * (x::int) + v * y = gcd x y"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1059	proof -
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1060	have bezout_aux: "!!x y. x \<ge> (0::int) \<Longrightarrow> y \<ge> 0 \<Longrightarrow>
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1061	EX u v. u * x + v * y = gcd x y"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1062	apply (rule_tac x = "fst (bezw (nat x) (nat y))" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1063	apply (rule_tac x = "snd (bezw (nat x) (nat y))" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1064	apply (unfold gcd_int_def)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1065	apply simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1066	apply (subst bezw_aux [symmetric])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1067	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1068	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1069	have "(x \<ge> 0 \<and> y \<ge> 0) \| (x \<ge> 0 \<and> y \<le> 0) \| (x \<le> 0 \<and> y \<ge> 0) \|
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1070	(x \<le> 0 \<and> y \<le> 0)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1071	by auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1072	moreover have "x \<ge> 0 \<Longrightarrow> y \<ge> 0 \<Longrightarrow> ?thesis"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1073	by (erule (1) bezout_aux)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1074	moreover have "x >= 0 \<Longrightarrow> y <= 0 \<Longrightarrow> ?thesis"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1075	apply (insert bezout_aux [of x "-y"])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1076	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1077	apply (rule_tac x = u in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1078	apply (rule_tac x = "-v" in exI)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1079	apply (subst gcd_neg2_int [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1080	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1081	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1082	moreover have "x <= 0 \<Longrightarrow> y >= 0 \<Longrightarrow> ?thesis"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1083	apply (insert bezout_aux [of "-x" y])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1084	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1085	apply (rule_tac x = "-u" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1086	apply (rule_tac x = v in exI)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1087	apply (subst gcd_neg1_int [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1088	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1089	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1090	moreover have "x <= 0 \<Longrightarrow> y <= 0 \<Longrightarrow> ?thesis"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1091	apply (insert bezout_aux [of "-x" "-y"])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1092	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1093	apply (rule_tac x = "-u" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1094	apply (rule_tac x = "-v" in exI)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1095	apply (subst gcd_neg1_int [symmetric])
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1096	apply (subst gcd_neg2_int [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1097	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1098	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1099	ultimately show ?thesis by blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1100	qed
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1101
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1102	text {* versions of Bezout for nat, by Amine Chaieb *}
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1103
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1104	lemma ind_euclid:
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1105	assumes c: " \<forall>a b. P (a::nat) b \<longleftrightarrow> P b a" and z: "\<forall>a. P a 0"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1106	and add: "\<forall>a b. P a b \<longrightarrow> P a (a + b)"
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1107	shows "P a b"
34915 7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1108	proof(induct "a + b" arbitrary: a b rule: less_induct)
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1109	case less
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1110	have "a = b \<or> a < b \<or> b < a" by arith
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1111	moreover {assume eq: "a= b"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1112	from add[rule_format, OF z[rule_format, of a]] have "P a b" using eq
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1113	by simp}
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1114	moreover
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1115	{assume lt: "a < b"
34915 7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1116	hence "a + b - a < a + b \<or> a = 0" by arith
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1117	moreover
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1118	{assume "a =0" with z c have "P a b" by blast }
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1119	moreover
34915 7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1120	{assume "a + b - a < a + b"
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1121	also have th0: "a + b - a = a + (b - a)" using lt by arith
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1122	finally have "a + (b - a) < a + b" .
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1123	then have "P a (a + (b - a))" by (rule add[rule_format, OF less])
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1124	then have "P a b" by (simp add: th0[symmetric])}
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1125	ultimately have "P a b" by blast}
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1126	moreover
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1127	{assume lt: "a > b"
34915 7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1128	hence "b + a - b < a + b \<or> b = 0" by arith
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1129	moreover
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1130	{assume "b =0" with z c have "P a b" by blast }
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1131	moreover
34915 7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1132	{assume "b + a - b < a + b"
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1133	also have th0: "b + a - b = b + (a - b)" using lt by arith
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1134	finally have "b + (a - b) < a + b" .
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1135	then have "P b (b + (a - b))" by (rule add[rule_format, OF less])
7894c7dab132 Adapted to changes in induct method. berghofe parents: 34223 diff changeset	1136	then have "P b a" by (simp add: th0[symmetric])
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1137	hence "P a b" using c by blast }
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1138	ultimately have "P a b" by blast}
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1139	ultimately show "P a b" by blast
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1140	qed
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1141
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1142	lemma bezout_lemma_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1143	assumes ex: "\<exists>(d::nat) x y. d dvd a \<and> d dvd b \<and>
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1144	(a * x = b * y + d \<or> b * x = a * y + d)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1145	shows "\<exists>d x y. d dvd a \<and> d dvd a + b \<and>
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1146	(a * x = (a + b) * y + d \<or> (a + b) * x = a * y + d)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1147	using ex
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1148	apply clarsimp
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	1149	apply (rule_tac x="d" in exI, simp)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1150	apply (case_tac "a * x = b * y + d" , simp_all)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1151	apply (rule_tac x="x + y" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1152	apply (rule_tac x="y" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1153	apply algebra
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1154	apply (rule_tac x="x" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1155	apply (rule_tac x="x + y" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1156	apply algebra
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1157	done
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1158
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1159	lemma bezout_add_nat: "\<exists>(d::nat) x y. d dvd a \<and> d dvd b \<and>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1160	(a * x = b * y + d \<or> b * x = a * y + d)"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1161	apply(induct a b rule: ind_euclid)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1162	apply blast
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1163	apply clarify
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	1164	apply (rule_tac x="a" in exI, simp)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1165	apply clarsimp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1166	apply (rule_tac x="d" in exI)
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	1167	apply (case_tac "a * x = b * y + d", simp_all)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1168	apply (rule_tac x="x+y" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1169	apply (rule_tac x="y" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1170	apply algebra
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1171	apply (rule_tac x="x" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1172	apply (rule_tac x="x+y" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1173	apply algebra
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1174	done
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1175
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1176	lemma bezout1_nat: "\<exists>(d::nat) x y. d dvd a \<and> d dvd b \<and>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1177	(a * x - b * y = d \<or> b * x - a * y = d)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1178	using bezout_add_nat[of a b]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1179	apply clarsimp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1180	apply (rule_tac x="d" in exI, simp)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1181	apply (rule_tac x="x" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1182	apply (rule_tac x="y" in exI)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1183	apply auto
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1184	done
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1185
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1186	lemma bezout_add_strong_nat: assumes nz: "a \<noteq> (0::nat)"
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1187	shows "\<exists>d x y. d dvd a \<and> d dvd b \<and> a * x = b * y + d"
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1188	proof-
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1189	from nz have ap: "a > 0" by simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1190	from bezout_add_nat[of a b]
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1191	have "(\<exists>d x y. d dvd a \<and> d dvd b \<and> a * x = b * y + d) \<or>
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1192	(\<exists>d x y. d dvd a \<and> d dvd b \<and> b * x = a * y + d)" by blast
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1193	moreover
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1194	{fix d x y assume H: "d dvd a" "d dvd b" "a * x = b * y + d"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1195	from H have ?thesis by blast }
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1196	moreover
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1197	{fix d x y assume H: "d dvd a" "d dvd b" "b * x = a * y + d"
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1198	{assume b0: "b = 0" with H have ?thesis by simp}
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1199	moreover
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1200	{assume b: "b \<noteq> 0" hence bp: "b > 0" by simp
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1201	from b dvd_imp_le [OF H(2)] have "d < b \<or> d = b"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1202	by auto
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1203	moreover
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1204	{assume db: "d=b"
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	1205	with nz H have ?thesis apply simp
32960 69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1206	apply (rule exI[where x = b], simp)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1207	apply (rule exI[where x = b])
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1208	by (rule exI[where x = "a - 1"], simp add: diff_mult_distrib2)}
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1209	moreover
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1210	{assume db: "d < b"
41550 efa734d9b221 eliminated global prems; wenzelm parents: 37770 diff changeset	1211	{assume "x=0" hence ?thesis using nz H by simp }
32960 69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1212	moreover
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1213	{assume x0: "x \<noteq> 0" hence xp: "x > 0" by simp
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1214	from db have "d \<le> b - 1" by simp
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1215	hence "db \<le> b(b - 1)" by simp
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1216	with xp mult_mono[of "1" "x" "db" "b(b - 1)"]
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1217	have dble: "db \<le> xb*(b - 1)" using bp by simp
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1218	from H (3) have "d + (b - 1) * (bx) = d + (b - 1) (a*y + d)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1219	by simp
32960 69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1220	hence "d + (b - 1) * a * y + (b - 1) * d = d + (b - 1) * b * x"
49962 a8cc904a6820 Renamed {left,right}_distrib to distrib_{right,left}. webertj parents: 48562 diff changeset	1221	by (simp only: mult_assoc distrib_left)
32960 69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1222	hence "a * ((b - 1) * y) + d * (b - 1 + 1) = d + xb(b - 1)"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1223	by algebra
32960 69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1224	hence "a * ((b - 1) * y) = d + xb(b - 1) - d*b" using bp by simp
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1225	hence "a * ((b - 1) * y) = d + (xb(b - 1) - d*b)"
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1226	by (simp only: diff_add_assoc[OF dble, of d, symmetric])
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1227	hence "a * ((b - 1) * y) = b(x(b - 1) - d) + d"
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1228	by (simp only: diff_mult_distrib2 add_commute mult_ac)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1229	hence ?thesis using H(1,2)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1230	apply -
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1231	apply (rule exI[where x=d], simp)
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1232	apply (rule exI[where x="(b - 1) * y"])
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1233	by (rule exI[where x="x*(b - 1) - d"], simp)}
69916a850301 eliminated hard tabulators, guessing at each author's individual tab-width; wenzelm parents: 32879 diff changeset	1234	ultimately have ?thesis by blast}
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1235	ultimately have ?thesis by blast}
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1236	ultimately have ?thesis by blast}
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1237	ultimately show ?thesis by blast
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1238	qed
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1239
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1240	lemma bezout_nat: assumes a: "(a::nat) \<noteq> 0"
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1241	shows "\<exists>x y. a * x = b * y + gcd a b"
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1242	proof-
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1243	let ?g = "gcd a b"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1244	from bezout_add_strong_nat[OF a, of b]
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1245	obtain d x y where d: "d dvd a" "d dvd b" "a * x = b * y + d" by blast
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1246	from d(1,2) have "d dvd ?g" by simp
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1247	then obtain k where k: "?g = d*k" unfolding dvd_def by blast
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1248	from d(3) have "a * x * k = (b * y + d) *k " by auto
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1249	hence "a * (x * k) = b * (y*k) + ?g" by (algebra add: k)
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1250	thus ?thesis by blast
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1251	qed
4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1252
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1253
34030 829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	1254	subsection {* LCM properties *}
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1255
34030 829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	1256	lemma lcm_altdef_int [code]: "lcm (a::int) b = (abs a) * (abs b) div gcd a b"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1257	by (simp add: lcm_int_def lcm_nat_def zdiv_int
44821 a92f65e174cf avoid using legacy theorem names huffman parents: 44766 diff changeset	1258	of_nat_mult gcd_int_def)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1259
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1260	lemma prod_gcd_lcm_nat: "(m::nat) * n = gcd m n * lcm m n"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1261	unfolding lcm_nat_def
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1262	by (simp add: dvd_mult_div_cancel [OF gcd_dvd_prod_nat])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1263
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1264	lemma prod_gcd_lcm_int: "abs(m::int) * abs n = gcd m n * lcm m n"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1265	unfolding lcm_int_def gcd_int_def
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1266	apply (subst int_mult [symmetric])
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1267	apply (subst prod_gcd_lcm_nat [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1268	apply (subst nat_abs_mult_distrib [symmetric])
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1269	apply (simp, simp add: abs_mult)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1270	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1271
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1272	lemma lcm_0_nat [simp]: "lcm (m::nat) 0 = 0"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1273	unfolding lcm_nat_def by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1274
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1275	lemma lcm_0_int [simp]: "lcm (m::int) 0 = 0"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1276	unfolding lcm_int_def by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1277
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1278	lemma lcm_0_left_nat [simp]: "lcm (0::nat) n = 0"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1279	unfolding lcm_nat_def by simp
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1280
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1281	lemma lcm_0_left_int [simp]: "lcm (0::int) n = 0"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1282	unfolding lcm_int_def by simp
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1283
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1284	lemma lcm_pos_nat:
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1285	"(m::nat) > 0 \<Longrightarrow> n>0 \<Longrightarrow> lcm m n > 0"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1286	by (metis gr0I mult_is_0 prod_gcd_lcm_nat)
27669 4b1642284dd7 Tuned and simplified proofs; Rules added to presburger's and algebra's context; moved Bezout theorems from Primes.thy chaieb parents: 27651 diff changeset	1287
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1288	lemma lcm_pos_int:
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1289	"(m::int) ~= 0 \<Longrightarrow> n ~= 0 \<Longrightarrow> lcm m n > 0"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1290	apply (subst lcm_abs_int)
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1291	apply (rule lcm_pos_nat [transferred])
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1292	apply auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1293	done
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1294
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1295	lemma dvd_pos_nat:
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1296	fixes n m :: nat
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1297	assumes "n > 0" and "m dvd n"
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1298	shows "m > 0"
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1299	using assms by (cases m) auto
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1300
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1301	lemma lcm_least_nat:
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1302	assumes "(m::nat) dvd k" and "n dvd k"
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1303	shows "lcm m n dvd k"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1304	proof (cases k)
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1305	case 0 then show ?thesis by auto
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1306	next
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1307	case (Suc _) then have pos_k: "k > 0" by auto
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1308	from assms dvd_pos_nat [OF this] have pos_mn: "m > 0" "n > 0" by auto
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1309	with gcd_zero_nat [of m n] have pos_gcd: "gcd m n > 0" by simp
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1310	from assms obtain p where k_m: "k = m * p" using dvd_def by blast
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1311	from assms obtain q where k_n: "k = n * q" using dvd_def by blast
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1312	from pos_k k_m have pos_p: "p > 0" by auto
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1313	from pos_k k_n have pos_q: "q > 0" by auto
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1314	have "k * k * gcd q p = k * gcd (k * q) (k * p)"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1315	by (simp add: mult_ac gcd_mult_distrib_nat)
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1316	also have "\<dots> = k * gcd (m * p * q) (n * q * p)"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1317	by (simp add: k_m [symmetric] k_n [symmetric])
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1318	also have "\<dots> = k * p * q * gcd m n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1319	by (simp add: mult_ac gcd_mult_distrib_nat)
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1320	finally have "(m * p) * (n * q) * gcd q p = k * p * q * gcd m n"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1321	by (simp only: k_m [symmetric] k_n [symmetric])
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1322	then have "p * q * m * n * gcd q p = p * q * k * gcd m n"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1323	by (simp add: mult_ac)
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1324	with pos_p pos_q have "m * n * gcd q p = k * gcd m n"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1325	by simp
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1326	with prod_gcd_lcm_nat [of m n]
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1327	have "lcm m n * gcd q p * gcd m n = k * gcd m n"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1328	by (simp add: mult_ac)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1329	with pos_gcd have "lcm m n * gcd q p = k" by auto
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1330	then show ?thesis using dvd_def by auto
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1331	qed
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1332
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1333	lemma lcm_least_int:
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1334	"(m::int) dvd k \<Longrightarrow> n dvd k \<Longrightarrow> lcm m n dvd k"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1335	apply (subst lcm_abs_int)
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1336	apply (rule dvd_trans)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1337	apply (rule lcm_least_nat [transferred, of _ "abs k" _])
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1338	apply auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1339	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1340
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1341	lemma lcm_dvd1_nat: "(m::nat) dvd lcm m n"
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1342	proof (cases m)
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1343	case 0 then show ?thesis by simp
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1344	next
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1345	case (Suc _)
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1346	then have mpos: "m > 0" by simp
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1347	show ?thesis
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1348	proof (cases n)
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1349	case 0 then show ?thesis by simp
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1350	next
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1351	case (Suc _)
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1352	then have npos: "n > 0" by simp
27556 292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1353	have "gcd m n dvd n" by simp
292098f2efdf unified curried gcd, lcm, zgcd, zlcm haftmann parents: 27487 diff changeset	1354	then obtain k where "n = gcd m n * k" using dvd_def by auto
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1355	then have "m * n div gcd m n = m * (gcd m n * k) div gcd m n"
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1356	by (simp add: mult_ac)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1357	also have "\<dots> = m * k" using mpos npos gcd_zero_nat by simp
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1358	finally show ?thesis by (simp add: lcm_nat_def)
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1359	qed
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1360	qed
06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1361
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1362	lemma lcm_dvd1_int: "(m::int) dvd lcm m n"
40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1363	apply (subst lcm_abs_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1364	apply (rule dvd_trans)
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1365	prefer 2
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1366	apply (rule lcm_dvd1_nat [transferred])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1367	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1368	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1369
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1370	lemma lcm_dvd2_nat: "(n::nat) dvd lcm m n"
35726 059d2f7b979f tuned prefixes of ac interpretations haftmann parents: 35644 diff changeset	1371	using lcm_dvd1_nat [of n m] by (simp only: lcm_nat_def mult.commute gcd_nat.commute)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1372
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1373	lemma lcm_dvd2_int: "(n::int) dvd lcm m n"
35726 059d2f7b979f tuned prefixes of ac interpretations haftmann parents: 35644 diff changeset	1374	using lcm_dvd1_int [of n m] by (simp only: lcm_int_def lcm_nat_def mult.commute gcd_nat.commute)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1375
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	1376	lemma dvd_lcm_I1_nat[simp]: "(k::nat) dvd m \<Longrightarrow> k dvd lcm m n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1377	by(metis lcm_dvd1_nat dvd_trans)
31729 b9299916d618 new lemmas and tuning nipkow parents: 31709 diff changeset	1378
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	1379	lemma dvd_lcm_I2_nat[simp]: "(k::nat) dvd n \<Longrightarrow> k dvd lcm m n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1380	by(metis lcm_dvd2_nat dvd_trans)
31729 b9299916d618 new lemmas and tuning nipkow parents: 31709 diff changeset	1381
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	1382	lemma dvd_lcm_I1_int[simp]: "(i::int) dvd m \<Longrightarrow> i dvd lcm m n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1383	by(metis lcm_dvd1_int dvd_trans)
31729 b9299916d618 new lemmas and tuning nipkow parents: 31709 diff changeset	1384
31730 d74830dc3e4a added lemmas; tuned nipkow parents: 31729 diff changeset	1385	lemma dvd_lcm_I2_int[simp]: "(i::int) dvd n \<Longrightarrow> i dvd lcm m n"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1386	by(metis lcm_dvd2_int dvd_trans)
31729 b9299916d618 new lemmas and tuning nipkow parents: 31709 diff changeset	1387
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1388	lemma lcm_unique_nat: "(a::nat) dvd d \<and> b dvd d \<and>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1389	(\<forall>e. a dvd e \<and> b dvd e \<longrightarrow> d dvd e) \<longleftrightarrow> d = lcm a b"
33657 a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	1390	by (auto intro: dvd_antisym lcm_least_nat lcm_dvd1_nat lcm_dvd2_nat)
27568 9949dc7a24de Theorem names as in IntPrimes.thy, also several theorems moved from there chaieb parents: 27556 diff changeset	1391
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1392	lemma lcm_unique_int: "d >= 0 \<and> (a::int) dvd d \<and> b dvd d \<and>
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1393	(\<forall>e. a dvd e \<and> b dvd e \<longrightarrow> d dvd e) \<longleftrightarrow> d = lcm a b"
33657 a4179bf442d1 renamed lemmas "anti_sym" -> "antisym" nipkow parents: 33318 diff changeset	1394	by (auto intro: dvd_antisym [transferred] lcm_least_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1395
37770 cddb3106adb8 avoid explicit mandatory prefix markers when prefixes are mandatory implicitly haftmann parents: 36350 diff changeset	1396	interpretation lcm_nat: abel_semigroup "lcm :: nat \<Rightarrow> nat \<Rightarrow> nat"
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1397	+ lcm_nat: semilattice_neutr "lcm :: nat \<Rightarrow> nat \<Rightarrow> nat" 1
34973 ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1398	proof
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1399	fix n m p :: nat
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1400	show "lcm (lcm n m) p = lcm n (lcm m p)"
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1401	by (rule lcm_unique_nat [THEN iffD1]) (metis dvd.order_trans lcm_unique_nat)
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1402	show "lcm m n = lcm n m"
36350 bc7982c54e37 dropped group_simps, ring_simps, field_eq_simps haftmann parents: 35726 diff changeset	1403	by (simp add: lcm_nat_def gcd_commute_nat field_simps)
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1404	show "lcm m m = m"
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1405	by (metis dvd.order_refl lcm_unique_nat)
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1406	show "lcm m 1 = m"
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1407	by (metis dvd.dual_order.refl lcm_unique_nat one_dvd)
34973 ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1408	qed
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1409
37770 cddb3106adb8 avoid explicit mandatory prefix markers when prefixes are mandatory implicitly haftmann parents: 36350 diff changeset	1410	interpretation lcm_int: abel_semigroup "lcm :: int \<Rightarrow> int \<Rightarrow> int"
34973 ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1411	proof
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1412	fix n m p :: int
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1413	show "lcm (lcm n m) p = lcm n (lcm m p)"
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1414	by (rule lcm_unique_int [THEN iffD1]) (metis dvd_trans lcm_unique_int)
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1415	show "lcm m n = lcm n m"
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1416	by (simp add: lcm_int_def lcm_nat.commute)
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1417	qed
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1418
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1419	lemmas lcm_assoc_nat = lcm_nat.assoc
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1420	lemmas lcm_commute_nat = lcm_nat.commute
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1421	lemmas lcm_left_commute_nat = lcm_nat.left_commute
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1422	lemmas lcm_assoc_int = lcm_int.assoc
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1423	lemmas lcm_commute_int = lcm_int.commute
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1424	lemmas lcm_left_commute_int = lcm_int.left_commute
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1425
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1426	lemmas lcm_ac_nat = lcm_assoc_nat lcm_commute_nat lcm_left_commute_nat
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1427	lemmas lcm_ac_int = lcm_assoc_int lcm_commute_int lcm_left_commute_int
ae634fad947e dropped mk_left_commute; use interpretation of locale abel_semigroup instead haftmann parents: 34915 diff changeset	1428
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1429	lemma lcm_proj2_if_dvd_nat [simp]: "(x::nat) dvd y \<Longrightarrow> lcm x y = y"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1430	apply (rule sym)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1431	apply (subst lcm_unique_nat [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1432	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1433	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1434
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1435	lemma lcm_proj2_if_dvd_int [simp]: "(x::int) dvd y \<Longrightarrow> lcm x y = abs y"
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1436	apply (rule sym)
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1437	apply (subst lcm_unique_int [symmetric])
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1438	apply auto
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1439	done
1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1440
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1441	lemma lcm_proj1_if_dvd_nat [simp]: "(x::nat) dvd y \<Longrightarrow> lcm y x = y"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1442	by (subst lcm_commute_nat, erule lcm_proj2_if_dvd_nat)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1443
31798 fe9a3043d36c Cleaned up GCD nipkow parents: 31766 diff changeset	1444	lemma lcm_proj1_if_dvd_int [simp]: "(x::int) dvd y \<Longrightarrow> lcm y x = abs y"
31952 40501bb2d57c renamed lemmas: nat_xyz/int_xyz -> xyz_nat/xyz_int nipkow parents: 31814 diff changeset	1445	by (subst lcm_commute_int, erule lcm_proj2_if_dvd_int)
31706 1db0c8f235fb new GCD library, courtesy of Jeremy Avigad huffman parents: 30738 diff changeset	1446
31992 f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1447	lemma lcm_proj1_iff_nat[simp]: "lcm m n = (m::nat) \<longleftrightarrow> n dvd m"
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1448	by (metis lcm_proj1_if_dvd_nat lcm_unique_nat)
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1449
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1450	lemma lcm_proj2_iff_nat[simp]: "lcm m n = (n::nat) \<longleftrightarrow> m dvd n"
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1451	by (metis lcm_proj2_if_dvd_nat lcm_unique_nat)
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1452
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1453	lemma lcm_proj1_iff_int[simp]: "lcm m n = abs(m::int) \<longleftrightarrow> n dvd m"
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1454	by (metis dvd_abs_iff lcm_proj1_if_dvd_int lcm_unique_int)
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1455
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1456	lemma lcm_proj2_iff_int[simp]: "lcm m n = abs(n::int) \<longleftrightarrow> m dvd n"
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1457	by (metis dvd_abs_iff lcm_proj2_if_dvd_int lcm_unique_int)
27568 9949dc7a24de Theorem names as in IntPrimes.thy, also several theorems moved from there chaieb parents: 27556 diff changeset	1458
42871 1c0b99f950d9 names of fold_set locales resemble name of characteristic property more closely haftmann parents: 41792 diff changeset	1459	lemma comp_fun_idem_gcd_nat: "comp_fun_idem (gcd :: nat\<Rightarrow>nat\<Rightarrow>nat)"
31992 f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1460	proof qed (auto simp add: gcd_ac_nat)
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1461
42871 1c0b99f950d9 names of fold_set locales resemble name of characteristic property more closely haftmann parents: 41792 diff changeset	1462	lemma comp_fun_idem_gcd_int: "comp_fun_idem (gcd :: int\<Rightarrow>int\<Rightarrow>int)"
31992 f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1463	proof qed (auto simp add: gcd_ac_int)
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1464
42871 1c0b99f950d9 names of fold_set locales resemble name of characteristic property more closely haftmann parents: 41792 diff changeset	1465	lemma comp_fun_idem_lcm_nat: "comp_fun_idem (lcm :: nat\<Rightarrow>nat\<Rightarrow>nat)"
31992 f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1466	proof qed (auto simp add: lcm_ac_nat)
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1467
42871 1c0b99f950d9 names of fold_set locales resemble name of characteristic property more closely haftmann parents: 41792 diff changeset	1468	lemma comp_fun_idem_lcm_int: "comp_fun_idem (lcm :: int\<Rightarrow>int\<Rightarrow>int)"
31992 f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1469	proof qed (auto simp add: lcm_ac_int)
f8aed98faae7 More about gcd/lcm, and some cleaning up nipkow parents: 31952 diff changeset	1470
23687 06884f7ffb18 extended - convers now basic lcm properties also haftmann parents: 23431 diff changeset	1471
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1472	(* FIXME introduce selimattice_bot/top and derive the following lemmas in there: *)
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1473
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1474	lemma lcm_0_iff_nat[simp]: "lcm (m::nat) n = 0 \<longleftrightarrow> m=0 \<or> n=0"
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1475	by (metis lcm_0_left_nat lcm_0_nat mult_is_0 prod_gcd_lcm_nat)
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1476
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1477	lemma lcm_0_iff_int[simp]: "lcm (m::int) n = 0 \<longleftrightarrow> m=0 \<or> n=0"
44766 d4d33a4d7548 avoid using legacy theorem names huffman parents: 44278 diff changeset	1478	by (metis lcm_0_int lcm_0_left_int lcm_pos_int less_le)
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1479
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1480	lemma lcm_1_iff_nat[simp]: "lcm (m::nat) n = 1 \<longleftrightarrow> m=1 \<and> n=1"
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1481	by (metis gcd_1_nat lcm_unique_nat nat_mult_1 prod_gcd_lcm_nat)
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1482
8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1483	lemma lcm_1_iff_int[simp]: "lcm (m::int) n = 1 \<longleftrightarrow> (m=1 \<or> m = -1) \<and> (n=1 \<or> n = -1)"
31996 1d93369079c4 Tuned proof of lcm_1_iff_int, because metis produced enormous proof term. berghofe parents: 31995 diff changeset	1484	by (auto simp add: abs_mult_self trans [OF lcm_unique_int eq_commute, symmetric] zmult_eq_1_iff)
31995 8f37cf60b885 more gcd/lcm lemmas nipkow parents: 31992 diff changeset	1485
34030 829eb528b226 resorted code equations from "old" number theory version haftmann parents: 33946 diff changeset	1486
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1487	subsection {* The complete divisibility lattice *}
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1488
44845 5e51075cbd97 added syntactic classes for "inf" and "sup" krauss parents: 44821 diff changeset	1489	interpretation gcd_semilattice_nat: semilattice_inf gcd "op dvd" "(%m n::nat. m dvd n & ~ n dvd m)"
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1490	proof
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1491	case goal3 thus ?case by(metis gcd_unique_nat)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1492	qed auto
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1493
44845 5e51075cbd97 added syntactic classes for "inf" and "sup" krauss parents: 44821 diff changeset	1494	interpretation lcm_semilattice_nat: semilattice_sup lcm "op dvd" "(%m n::nat. m dvd n & ~ n dvd m)"
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1495	proof
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1496	case goal3 thus ?case by(metis lcm_unique_nat)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1497	qed auto
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1498
44845 5e51075cbd97 added syntactic classes for "inf" and "sup" krauss parents: 44821 diff changeset	1499	interpretation gcd_lcm_lattice_nat: lattice gcd "op dvd" "(%m n::nat. m dvd n & ~ n dvd m)" lcm ..
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1500
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1501	text{* Lifting gcd and lcm to sets (Gcd/Lcm).
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1502	Gcd is defined via Lcm to facilitate the proof that we have a complete lattice.
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1503	*}
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1504
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1505	class Gcd = gcd +
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1506	fixes Gcd :: "'a set \<Rightarrow> 'a"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1507	fixes Lcm :: "'a set \<Rightarrow> 'a"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1508
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1509	instantiation nat :: Gcd
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1510	begin
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1511
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1512	definition
51489 f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1513	"Lcm (M::nat set) = (if finite M then semilattice_neutr_set.F lcm 1 M else 0)"
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1514
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1515	interpretation semilattice_neutr_set lcm "1::nat" ..
c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1516
51489 f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1517	lemma Lcm_nat_infinite:
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1518	"\<not> finite M \<Longrightarrow> Lcm M = (0::nat)"
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1519	by (simp add: Lcm_nat_def)
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1520
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1521	lemma Lcm_nat_empty:
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1522	"Lcm {} = (1::nat)"
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1523	by (simp add: Lcm_nat_def)
51489 f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1524
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1525	lemma Lcm_nat_insert:
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1526	"Lcm (insert n M) = lcm (n::nat) (Lcm M)"
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1527	by (cases "finite M") (simp_all add: Lcm_nat_def Lcm_nat_infinite)
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1528
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1529	definition
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1530	"Gcd (M::nat set) = Lcm {d. \<forall>m\<in>M. d dvd m}"
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1531
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1532	instance ..
51489 f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1533
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1534	end
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1535
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1536	lemma dvd_Lcm_nat [simp]:
51489 f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1537	fixes M :: "nat set"
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1538	assumes "m \<in> M"
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1539	shows "m dvd Lcm M"
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1540	proof (cases "finite M")
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1541	case False then show ?thesis by (simp add: Lcm_nat_infinite)
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1542	next
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1543	case True then show ?thesis using assms by (induct M) (auto simp add: Lcm_nat_insert)
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1544	qed
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1545
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1546	lemma Lcm_dvd_nat [simp]:
51489 f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1547	fixes M :: "nat set"
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1548	assumes "\<forall>m\<in>M. m dvd n"
f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1549	shows "Lcm M dvd n"
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1550	proof (cases "n = 0")
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1551	assume "n \<noteq> 0"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1552	hence "finite {d. d dvd n}" by (rule finite_divisors_nat)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1553	moreover have "M \<subseteq> {d. d dvd n}" using assms by fast
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1554	ultimately have "finite M" by (rule rev_finite_subset)
51489 f738e6dbd844 fundamental revision of big operators on sets haftmann parents: 49962 diff changeset	1555	then show ?thesis using assms by (induct M) (simp_all add: Lcm_nat_empty Lcm_nat_insert)
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1556	qed simp
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1557
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1558	interpretation gcd_lcm_complete_lattice_nat:
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1559	complete_lattice Gcd Lcm gcd Rings.dvd "\<lambda>m n. m dvd n \<and> \<not> n dvd m" lcm 1 "0::nat"
604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1560	where
54257 5c7a3b6b05a9 generalize SUP and INF to the syntactic type classes Sup and Inf hoelzl parents: 52729 diff changeset	1561	"Inf.INFI Gcd A f = Gcd (f ` A :: nat set)"
5c7a3b6b05a9 generalize SUP and INF to the syntactic type classes Sup and Inf hoelzl parents: 52729 diff changeset	1562	and "Sup.SUPR Lcm A f = Lcm (f ` A)"
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1563	proof -
604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1564	show "class.complete_lattice Gcd Lcm gcd Rings.dvd (\<lambda>m n. m dvd n \<and> \<not> n dvd m) lcm 1 (0::nat)"
604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1565	proof
52729 412c9e0381a1 factored syntactic type classes for bot and top (by Alessandro Coglio) haftmann parents: 52397 diff changeset	1566	case goal1 thus ?case by (simp add: Gcd_nat_def)
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1567	next
52729 412c9e0381a1 factored syntactic type classes for bot and top (by Alessandro Coglio) haftmann parents: 52397 diff changeset	1568	case goal2 thus ?case by (simp add: Gcd_nat_def)
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1569	next
52729 412c9e0381a1 factored syntactic type classes for bot and top (by Alessandro Coglio) haftmann parents: 52397 diff changeset	1570	case goal5 show ?case by (simp add: Gcd_nat_def Lcm_nat_infinite)
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1571	next
52729 412c9e0381a1 factored syntactic type classes for bot and top (by Alessandro Coglio) haftmann parents: 52397 diff changeset	1572	case goal6 show ?case by (simp add: Lcm_nat_empty)
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1573	next
52729 412c9e0381a1 factored syntactic type classes for bot and top (by Alessandro Coglio) haftmann parents: 52397 diff changeset	1574	case goal3 thus ?case by simp
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1575	next
52729 412c9e0381a1 factored syntactic type classes for bot and top (by Alessandro Coglio) haftmann parents: 52397 diff changeset	1576	case goal4 thus ?case by simp
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1577	qed
604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1578	then interpret gcd_lcm_complete_lattice_nat:
604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1579	complete_lattice Gcd Lcm gcd Rings.dvd "\<lambda>m n. m dvd n \<and> \<not> n dvd m" lcm 1 "0::nat" .
54257 5c7a3b6b05a9 generalize SUP and INF to the syntactic type classes Sup and Inf hoelzl parents: 52729 diff changeset	1580	from gcd_lcm_complete_lattice_nat.INF_def show "Inf.INFI Gcd A f = Gcd (f ` A)" .
5c7a3b6b05a9 generalize SUP and INF to the syntactic type classes Sup and Inf hoelzl parents: 52729 diff changeset	1581	from gcd_lcm_complete_lattice_nat.SUP_def show "Sup.SUPR Lcm A f = Lcm (f ` A)" .
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1582	qed
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1583
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1584	lemma Lcm_empty_nat: "Lcm {} = (1::nat)"
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1585	by (fact Lcm_nat_empty)
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1586
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1587	lemma Gcd_empty_nat: "Gcd {} = (0::nat)"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1588	by (fact gcd_lcm_complete_lattice_nat.Inf_empty) (* already simp *)
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1589
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1590	lemma Lcm_insert_nat [simp]:
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1591	shows "Lcm (insert (n::nat) N) = lcm n (Lcm N)"
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1592	by (fact gcd_lcm_complete_lattice_nat.Sup_insert)
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1593
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1594	lemma Gcd_insert_nat [simp]:
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1595	shows "Gcd (insert (n::nat) N) = gcd n (Gcd N)"
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1596	by (fact gcd_lcm_complete_lattice_nat.Inf_insert)
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1597
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1598	lemma Lcm0_iff[simp]: "finite (M::nat set) \<Longrightarrow> M \<noteq> {} \<Longrightarrow> Lcm M = 0 \<longleftrightarrow> 0 : M"
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1599	by(induct rule:finite_ne_induct) auto
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1600
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1601	lemma Lcm_eq_0[simp]: "finite (M::nat set) \<Longrightarrow> 0 : M \<Longrightarrow> Lcm M = 0"
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1602	by (metis Lcm0_iff empty_iff)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1603
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1604	lemma Gcd_dvd_nat [simp]:
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1605	fixes M :: "nat set"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1606	assumes "m \<in> M" shows "Gcd M dvd m"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1607	using assms by (fact gcd_lcm_complete_lattice_nat.Inf_lower)
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1608
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1609	lemma dvd_Gcd_nat[simp]:
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1610	fixes M :: "nat set"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1611	assumes "\<forall>m\<in>M. n dvd m" shows "n dvd Gcd M"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1612	using assms by (simp only: gcd_lcm_complete_lattice_nat.Inf_greatest)
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1613
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1614	text{* Alternative characterizations of Gcd: *}
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1615
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1616	lemma Gcd_eq_Max: "finite(M::nat set) \<Longrightarrow> M \<noteq> {} \<Longrightarrow> 0 \<notin> M \<Longrightarrow> Gcd M = Max(\<Inter>m\<in>M. {d. d dvd m})"
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1617	apply(rule antisym)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1618	apply(rule Max_ge)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1619	apply (metis all_not_in_conv finite_divisors_nat finite_INT)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1620	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1621	apply (rule Max_le_iff[THEN iffD2])
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1622	apply (metis all_not_in_conv finite_divisors_nat finite_INT)
44890 22f665a2e91c new fastforce replacing fastsimp - less confusing name nipkow parents: 44845 diff changeset	1623	apply fastforce
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1624	apply clarsimp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1625	apply (metis Gcd_dvd_nat Max_in dvd_0_left dvd_Gcd_nat dvd_imp_le linorder_antisym_conv3 not_less0)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1626	done
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1627
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1628	lemma Gcd_remove0_nat: "finite M \<Longrightarrow> Gcd M = Gcd (M - {0::nat})"
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1629	apply(induct pred:finite)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1630	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1631	apply(case_tac "x=0")
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1632	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1633	apply(subgoal_tac "insert x F - {0} = insert x (F - {0})")
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1634	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1635	apply blast
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1636	done
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1637
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1638	lemma Lcm_in_lcm_closed_set_nat:
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1639	"finite M \<Longrightarrow> M \<noteq> {} \<Longrightarrow> ALL m n :: nat. m:M \<longrightarrow> n:M \<longrightarrow> lcm m n : M \<Longrightarrow> Lcm M : M"
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1640	apply(induct rule:finite_linorder_min_induct)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1641	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1642	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1643	apply(subgoal_tac "ALL m n :: nat. m:A \<longrightarrow> n:A \<longrightarrow> lcm m n : A")
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1644	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1645	apply(case_tac "A={}")
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1646	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1647	apply simp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1648	apply (metis lcm_pos_nat lcm_unique_nat linorder_neq_iff nat_dvd_not_less not_less0)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1649	done
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1650
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1651	lemma Lcm_eq_Max_nat:
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1652	"finite M \<Longrightarrow> M \<noteq> {} \<Longrightarrow> 0 \<notin> M \<Longrightarrow> ALL m n :: nat. m:M \<longrightarrow> n:M \<longrightarrow> lcm m n : M \<Longrightarrow> Lcm M = Max M"
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1653	apply(rule antisym)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1654	apply(rule Max_ge, assumption)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1655	apply(erule (2) Lcm_in_lcm_closed_set_nat)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1656	apply clarsimp
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1657	apply (metis Lcm0_iff dvd_Lcm_nat dvd_imp_le neq0_conv)
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1658	done
6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1659
54437 0060957404c7 proper code equations for Gcd and Lcm on nat and int haftmann parents: 54257 diff changeset	1660	lemma Lcm_set_nat [code, code_unfold]:
45992 15d14fa805b2 prefer canonical fold on lists haftmann parents: 45270 diff changeset	1661	"Lcm (set ns) = fold lcm ns (1::nat)"
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1662	by (fact gcd_lcm_complete_lattice_nat.Sup_set_fold)
32112 6da9c2a49fed Made dvd/gcd/lcm a complete lattice by introducing Gcd/GCD/Lcm/LCM nipkow parents: 32111 diff changeset	1663
54437 0060957404c7 proper code equations for Gcd and Lcm on nat and int haftmann parents: 54257 diff changeset	1664	lemma Gcd_set_nat [code, code_unfold]:
45992 15d14fa805b2 prefer canonical fold on lists haftmann parents: 45270 diff changeset	1665	"Gcd (set ns) = fold gcd ns (0::nat)"
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1666	by (fact gcd_lcm_complete_lattice_nat.Inf_set_fold)
34222 e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1667
e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1668	lemma mult_inj_if_coprime_nat:
e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1669	"inj_on f A \<Longrightarrow> inj_on g B \<Longrightarrow> ALL a:A. ALL b:B. coprime (f a) (g b)
e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1670	\<Longrightarrow> inj_on (%(a,b). f a * g b::nat) (A \<times> B)"
e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1671	apply(auto simp add:inj_on_def)
35216 7641e8d831d2 get rid of many duplicate simp rule warnings huffman parents: 35028 diff changeset	1672	apply (metis coprime_dvd_mult_iff_nat dvd.neq_le_trans dvd_triv_left)
34223 dce32a1e05fe added lemmas nipkow parents: 34222 diff changeset	1673	apply (metis gcd_semilattice_nat.inf_commute coprime_dvd_mult_iff_nat
dce32a1e05fe added lemmas nipkow parents: 34222 diff changeset	1674	dvd.neq_le_trans dvd_triv_right mult_commute)
34222 e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1675	done
e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1676
e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1677	text{* Nitpick: *}
e33ee7369ecb added lemma nipkow parents: 34221 diff changeset	1678
41792 ff3cb0c418b7 renamed "nitpick\_def" to "nitpick_unfold" to reflect its new semantics blanchet parents: 41550 diff changeset	1679	lemma gcd_eq_nitpick_gcd [nitpick_unfold]: "gcd x y = Nitpick.nat_gcd x y"
ff3cb0c418b7 renamed "nitpick\_def" to "nitpick_unfold" to reflect its new semantics blanchet parents: 41550 diff changeset	1680	by (induct x y rule: nat_gcd.induct)
ff3cb0c418b7 renamed "nitpick\_def" to "nitpick_unfold" to reflect its new semantics blanchet parents: 41550 diff changeset	1681	(simp add: gcd_nat.simps Nitpick.nat_gcd.simps)
33197 de6285ebcc05 continuation of Nitpick's integration into Isabelle; blanchet parents: 32960 diff changeset	1682
41792 ff3cb0c418b7 renamed "nitpick\_def" to "nitpick_unfold" to reflect its new semantics blanchet parents: 41550 diff changeset	1683	lemma lcm_eq_nitpick_lcm [nitpick_unfold]: "lcm x y = Nitpick.nat_lcm x y"
33197 de6285ebcc05 continuation of Nitpick's integration into Isabelle; blanchet parents: 32960 diff changeset	1684	by (simp only: lcm_nat_def Nitpick.nat_lcm_def gcd_eq_nitpick_gcd)
de6285ebcc05 continuation of Nitpick's integration into Isabelle; blanchet parents: 32960 diff changeset	1685
54867 c21a2465cac1 prefer ephemeral interpretation over interpretation in proof contexts; haftmann parents: 54489 diff changeset	1686
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1687	subsubsection {* Setwise gcd and lcm for integers *}
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1688
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1689	instantiation int :: Gcd
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1690	begin
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1691
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1692	definition
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1693	"Lcm M = int (Lcm (nat ` abs ` M))"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1694
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1695	definition
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1696	"Gcd M = int (Gcd (nat ` abs ` M))"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1697
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1698	instance ..
21256 47195501ecf7 moved theories Parity, GCD, Binomial to Library; wenzelm parents: diff changeset	1699	end
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1700
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1701	lemma Lcm_empty_int [simp]: "Lcm {} = (1::int)"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1702	by (simp add: Lcm_int_def)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1703
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1704	lemma Gcd_empty_int [simp]: "Gcd {} = (0::int)"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1705	by (simp add: Gcd_int_def)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1706
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1707	lemma Lcm_insert_int [simp]:
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1708	shows "Lcm (insert (n::int) N) = lcm n (Lcm N)"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1709	by (simp add: Lcm_int_def lcm_int_def)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1710
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1711	lemma Gcd_insert_int [simp]:
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1712	shows "Gcd (insert (n::int) N) = gcd n (Gcd N)"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1713	by (simp add: Gcd_int_def gcd_int_def)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1714
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1715	lemma dvd_int_iff: "x dvd y \<longleftrightarrow> nat (abs x) dvd nat (abs y)"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1716	by (simp add: zdvd_int)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1717
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1718	lemma dvd_Lcm_int [simp]:
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1719	fixes M :: "int set" assumes "m \<in> M" shows "m dvd Lcm M"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1720	using assms by (simp add: Lcm_int_def dvd_int_iff)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1721
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1722	lemma Lcm_dvd_int [simp]:
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1723	fixes M :: "int set"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1724	assumes "\<forall>m\<in>M. m dvd n" shows "Lcm M dvd n"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1725	using assms by (simp add: Lcm_int_def dvd_int_iff)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1726
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1727	lemma Gcd_dvd_int [simp]:
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1728	fixes M :: "int set"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1729	assumes "m \<in> M" shows "Gcd M dvd m"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1730	using assms by (simp add: Gcd_int_def dvd_int_iff)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1731
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1732	lemma dvd_Gcd_int[simp]:
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1733	fixes M :: "int set"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1734	assumes "\<forall>m\<in>M. n dvd m" shows "n dvd Gcd M"
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1735	using assms by (simp add: Gcd_int_def dvd_int_iff)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1736
54437 0060957404c7 proper code equations for Gcd and Lcm on nat and int haftmann parents: 54257 diff changeset	1737	lemma Lcm_set_int [code, code_unfold]:
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1738	"Lcm (set xs) = fold lcm xs (1::int)"
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1739	by (induct xs rule: rev_induct, simp_all add: lcm_commute_int)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1740
54437 0060957404c7 proper code equations for Gcd and Lcm on nat and int haftmann parents: 54257 diff changeset	1741	lemma Gcd_set_int [code, code_unfold]:
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1742	"Gcd (set xs) = fold gcd xs (0::int)"
45264 3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1743	by (induct xs rule: rev_induct, simp_all add: gcd_commute_int)
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1744
3b2c770f6631 merge Gcd/GCD and Lcm/LCM huffman parents: 44890 diff changeset	1745	end
51547 604d73671fa7 avoid odd foundational terms after interpretation; haftmann parents: 51489 diff changeset	1746

author	nipkow
	Mon, 10 Feb 2014 21:50:50 +0100
changeset 55375	d26d5f988d71
parent 54867	c21a2465cac1
child 56166	9a241bc276cd
permissions	-rw-r--r--