--- a/src/HOL/Decision_Procs/Cooper.thy Thu Mar 06 21:33:15 2014 +0100
+++ b/src/HOL/Decision_Procs/Cooper.thy Thu Mar 06 22:10:38 2014 +0100
@@ -881,9 +881,9 @@
assumes qe_inv: "\<forall>bs p. qfree p \<longrightarrow> qfree (qe p) \<and> Ifm bbs bs (qe p) = Ifm bbs bs (E p)"
shows "\<And>bs. qfree (qelim p qe) \<and> Ifm bbs bs (qelim p qe) = Ifm bbs bs p"
using qe_inv DJ_qe[OF qe_inv]
- by(induct p rule: qelim.induct)
- (auto simp add: not disj conj iff imp not_qf disj_qf conj_qf imp_qf iff_qf
- simpfm simpfm_qf simp del: simpfm.simps)
+ by (induct p rule: qelim.induct)
+ (auto simp add: not disj conj iff imp not_qf disj_qf conj_qf imp_qf iff_qf
+ simpfm simpfm_qf simp del: simpfm.simps)
text {* Linearity for fm where Bound 0 ranges over @{text "\<int>"} *}
@@ -908,7 +908,7 @@
| "zsplit0 (Mul i a) = (let (i', a') = zsplit0 a in (i*i', Mul i a'))"
lemma zsplit0_I:
- shows "\<And>n a. zsplit0 t = (n, a) \<Longrightarrow>
+ "\<And>n a. zsplit0 t = (n, a) \<Longrightarrow>
(Inum ((x::int) # bs) (CN 0 n a) = Inum (x # bs) t) \<and> numbound0 a"
(is "\<And>n a. ?S t = (n,a) \<Longrightarrow> (?I x (CN 0 n a) = ?I x t) \<and> ?N a")
proof (induct t rule: zsplit0.induct)
@@ -930,11 +930,11 @@
moreover
{
assume m0: "m = 0"
- with abj have th: "a'=?b \<and> n=i+?j" using 3
- by (simp add: Let_def split_def)
+ with abj have th: "a' = ?b \<and> n = i + ?j"
+ using 3 by (simp add: Let_def split_def)
from abj 3 m0 have th2: "(?I x (CN 0 ?j ?b) = ?I x a) \<and> ?N ?b"
by blast
- from th have "?I x (CN 0 n a') = ?I x (CN 0 (i+?j) ?b)"
+ from th have "?I x (CN 0 n a') = ?I x (CN 0 (i + ?j) ?b)"
by simp
also from th2 have "\<dots> = ?I x (CN 0 i (CN 0 ?j ?b))"
by (simp add: distrib_right)
@@ -948,8 +948,9 @@
case (4 t n a)
let ?nt = "fst (zsplit0 t)"
let ?at = "snd (zsplit0 t)"
- have abj: "zsplit0 t = (?nt,?at)" by simp
- then have th: "a=Neg ?at \<and> n=-?nt"
+ have abj: "zsplit0 t = (?nt, ?at)"
+ by simp
+ then have th: "a = Neg ?at \<and> n = - ?nt"
using 4 by (simp add: Let_def split_def)
from abj 4 have th2: "(?I x (CN 0 ?nt ?at) = ?I x t) \<and> ?N ?at"
by blast
@@ -965,9 +966,9 @@
by simp
moreover have abjt: "zsplit0 t = (?nt, ?at)"
by simp
- ultimately have th: "a=Add ?as ?at \<and> n=?ns + ?nt"
+ ultimately have th: "a = Add ?as ?at \<and> n = ?ns + ?nt"
using 5 by (simp add: Let_def split_def)
- from abjs[symmetric] have bluddy: "\<exists>x y. (x,y) = zsplit0 s"
+ from abjs[symmetric] have bluddy: "\<exists>x y. (x, y) = zsplit0 s"
by blast
from 5 have "(\<exists>x y. (x, y) = zsplit0 s) \<longrightarrow>
(\<forall>xa xb. zsplit0 t = (xa, xb) \<longrightarrow> Inum (x # bs) (CN 0 xa xb) = Inum (x # bs) t \<and> numbound0 xb)"
@@ -988,9 +989,9 @@
by simp
moreover have abjt: "zsplit0 t = (?nt, ?at)"
by simp
- ultimately have th: "a=Sub ?as ?at \<and> n=?ns - ?nt"
+ ultimately have th: "a = Sub ?as ?at \<and> n = ?ns - ?nt"
using 6 by (simp add: Let_def split_def)
- from abjs[symmetric] have bluddy: "\<exists>x y. (x,y) = zsplit0 s"
+ from abjs[symmetric] have bluddy: "\<exists>x y. (x, y) = zsplit0 s"
by blast
from 6 have "(\<exists>x y. (x,y) = zsplit0 s) \<longrightarrow>
(\<forall>xa xb. zsplit0 t = (xa, xb) \<longrightarrow> Inum (x # bs) (CN 0 xa xb) = Inum (x # bs) t \<and> numbound0 xb)"
@@ -1007,7 +1008,7 @@
let ?at = "snd (zsplit0 t)"
have abj: "zsplit0 t = (?nt,?at)"
by simp
- then have th: "a=Mul i ?at \<and> n=i*?nt"
+ then have th: "a = Mul i ?at \<and> n = i * ?nt"
using 7 by (simp add: Let_def split_def)
from abj 7 have th2: "(?I x (CN 0 ?nt ?at) = ?I x t) \<and> ?N ?at"
by blast
@@ -1042,34 +1043,50 @@
"zlfm (Or p q) = Or (zlfm p) (zlfm q)"
"zlfm (Imp p q) = Or (zlfm (NOT p)) (zlfm q)"
"zlfm (Iff p q) = Or (And (zlfm p) (zlfm q)) (And (zlfm (NOT p)) (zlfm (NOT q)))"
- "zlfm (Lt a) = (let (c,r) = zsplit0 a in
- if c=0 then Lt r else
- if c>0 then (Lt (CN 0 c r)) else (Gt (CN 0 (- c) (Neg r))))"
- "zlfm (Le a) = (let (c,r) = zsplit0 a in
- if c=0 then Le r else
- if c>0 then (Le (CN 0 c r)) else (Ge (CN 0 (- c) (Neg r))))"
- "zlfm (Gt a) = (let (c,r) = zsplit0 a in
- if c=0 then Gt r else
- if c>0 then (Gt (CN 0 c r)) else (Lt (CN 0 (- c) (Neg r))))"
- "zlfm (Ge a) = (let (c,r) = zsplit0 a in
- if c=0 then Ge r else
- if c>0 then (Ge (CN 0 c r)) else (Le (CN 0 (- c) (Neg r))))"
- "zlfm (Eq a) = (let (c,r) = zsplit0 a in
- if c=0 then Eq r else
- if c>0 then (Eq (CN 0 c r)) else (Eq (CN 0 (- c) (Neg r))))"
- "zlfm (NEq a) = (let (c,r) = zsplit0 a in
- if c=0 then NEq r else
- if c>0 then (NEq (CN 0 c r)) else (NEq (CN 0 (- c) (Neg r))))"
- "zlfm (Dvd i a) = (if i=0 then zlfm (Eq a)
- else (let (c,r) = zsplit0 a in
- if c=0 then (Dvd (abs i) r) else
- if c>0 then (Dvd (abs i) (CN 0 c r))
- else (Dvd (abs i) (CN 0 (- c) (Neg r)))))"
- "zlfm (NDvd i a) = (if i=0 then zlfm (NEq a)
- else (let (c,r) = zsplit0 a in
- if c=0 then (NDvd (abs i) r) else
- if c>0 then (NDvd (abs i) (CN 0 c r))
- else (NDvd (abs i) (CN 0 (- c) (Neg r)))))"
+ "zlfm (Lt a) =
+ (let (c, r) = zsplit0 a in
+ if c = 0 then Lt r else
+ if c > 0 then (Lt (CN 0 c r))
+ else Gt (CN 0 (- c) (Neg r)))"
+ "zlfm (Le a) =
+ (let (c, r) = zsplit0 a in
+ if c = 0 then Le r
+ else if c > 0 then Le (CN 0 c r)
+ else Ge (CN 0 (- c) (Neg r)))"
+ "zlfm (Gt a) =
+ (let (c, r) = zsplit0 a in
+ if c = 0 then Gt r else
+ if c > 0 then Gt (CN 0 c r)
+ else Lt (CN 0 (- c) (Neg r)))"
+ "zlfm (Ge a) =
+ (let (c, r) = zsplit0 a in
+ if c = 0 then Ge r
+ else if c > 0 then Ge (CN 0 c r)
+ else Le (CN 0 (- c) (Neg r)))"
+ "zlfm (Eq a) =
+ (let (c, r) = zsplit0 a in
+ if c = 0 then Eq r
+ else if c > 0 then Eq (CN 0 c r)
+ else Eq (CN 0 (- c) (Neg r)))"
+ "zlfm (NEq a) =
+ (let (c, r) = zsplit0 a in
+ if c = 0 then NEq r
+ else if c > 0 then NEq (CN 0 c r)
+ else NEq (CN 0 (- c) (Neg r)))"
+ "zlfm (Dvd i a) =
+ (if i = 0 then zlfm (Eq a)
+ else
+ let (c, r) = zsplit0 a in
+ if c = 0 then Dvd (abs i) r
+ else if c > 0 then Dvd (abs i) (CN 0 c r)
+ else Dvd (abs i) (CN 0 (- c) (Neg r)))"
+ "zlfm (NDvd i a) =
+ (if i = 0 then zlfm (NEq a)
+ else
+ let (c, r) = zsplit0 a in
+ if c = 0 then NDvd (abs i) r
+ else if c > 0 then NDvd (abs i) (CN 0 c r)
+ else NDvd (abs i) (CN 0 (- c) (Neg r)))"
"zlfm (NOT (And p q)) = Or (zlfm (NOT p)) (zlfm (NOT q))"
"zlfm (NOT (Or p q)) = And (zlfm (NOT p)) (zlfm (NOT q))"
"zlfm (NOT (Imp p q)) = And (zlfm p) (zlfm (NOT q))"
@@ -1091,7 +1108,7 @@
lemma zlfm_I:
assumes qfp: "qfree p"
- shows "(Ifm bbs (i#bs) (zlfm p) = Ifm bbs (i# bs) p) \<and> iszlfm (zlfm p)"
+ shows "(Ifm bbs (i # bs) (zlfm p) = Ifm bbs (i # bs) p) \<and> iszlfm (zlfm p)"
(is "(?I (?l p) = ?I p) \<and> ?L (?l p)")
using qfp
proof (induct p rule: zlfm.induct)
@@ -1101,10 +1118,10 @@
have spl: "zsplit0 a = (?c, ?r)"
by simp
from zsplit0_I[OF spl, where x="i" and bs="bs"]
- have Ia:"Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
+ have Ia: "Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
by auto
- let ?N = "\<lambda>t. Inum (i#bs) t"
- from 5 Ia nb show ?case
+ let ?N = "\<lambda>t. Inum (i # bs) t"
+ from 5 Ia nb show ?case
apply (auto simp add: Let_def split_def algebra_simps)
apply (cases "?r")
apply auto
@@ -1118,9 +1135,9 @@
have spl: "zsplit0 a = (?c, ?r)"
by simp
from zsplit0_I[OF spl, where x="i" and bs="bs"]
- have Ia:"Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
+ have Ia: "Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
by auto
- let ?N = "\<lambda>t. Inum (i#bs) t"
+ let ?N = "\<lambda>t. Inum (i # bs) t"
from 6 Ia nb show ?case
apply (auto simp add: Let_def split_def algebra_simps)
apply (cases "?r")
@@ -1137,7 +1154,7 @@
from zsplit0_I[OF spl, where x="i" and bs="bs"]
have Ia: "Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
by auto
- let ?N = "\<lambda>t. Inum (i#bs) t"
+ let ?N = "\<lambda>t. Inum (i # bs) t"
from 7 Ia nb show ?case
apply (auto simp add: Let_def split_def algebra_simps)
apply (cases "?r")
@@ -1152,9 +1169,9 @@
have spl: "zsplit0 a = (?c, ?r)"
by simp
from zsplit0_I[OF spl, where x="i" and bs="bs"]
- have Ia:"Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
+ have Ia: "Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
by auto
- let ?N = "\<lambda>t. Inum (i#bs) t"
+ let ?N = "\<lambda>t. Inum (i # bs) t"
from 8 Ia nb show ?case
apply (auto simp add: Let_def split_def algebra_simps)
apply (cases "?r")
@@ -1171,7 +1188,7 @@
from zsplit0_I[OF spl, where x="i" and bs="bs"]
have Ia:"Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
by auto
- let ?N = "\<lambda>t. Inum (i#bs) t"
+ let ?N = "\<lambda>t. Inum (i # bs) t"
from 9 Ia nb show ?case
apply (auto simp add: Let_def split_def algebra_simps)
apply (cases "?r")
@@ -1188,7 +1205,7 @@
from zsplit0_I[OF spl, where x="i" and bs="bs"]
have Ia: "Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
by auto
- let ?N = "\<lambda>t. Inum (i#bs) t"
+ let ?N = "\<lambda>t. Inum (i # bs) t"
from 10 Ia nb show ?case
apply (auto simp add: Let_def split_def algebra_simps)
apply (cases "?r")
@@ -1255,13 +1272,13 @@
from zsplit0_I[OF spl, where x="i" and bs="bs"]
have Ia:"Inum (i # bs) a = Inum (i #bs) (CN 0 ?c ?r)" and nb: "numbound0 ?r"
by auto
- let ?N = "\<lambda>t. Inum (i#bs) t"
+ let ?N = "\<lambda>t. Inum (i # bs) t"
have "j = 0 \<or> (j \<noteq> 0 \<and> ?c = 0) \<or> (j \<noteq> 0 \<and> ?c > 0) \<or> (j \<noteq> 0 \<and> ?c < 0)"
by arith
moreover
{
assume "j = 0"
- then have z: "zlfm (NDvd j a) = (zlfm (NEq a))"
+ then have z: "zlfm (NDvd j a) = zlfm (NEq a)"
by (simp add: Let_def)
then have ?case
using assms 12 `j = 0` by (simp del: zlfm.simps)
@@ -1484,17 +1501,17 @@
lemma minusinf_inf:
assumes linp: "iszlfm p"
and u: "d_\<beta> p 1"
- shows "\<exists>(z::int). \<forall>x < z. Ifm bbs (x#bs) (minusinf p) = Ifm bbs (x#bs) p"
+ shows "\<exists>z::int. \<forall>x < z. Ifm bbs (x # bs) (minusinf p) = Ifm bbs (x # bs) p"
(is "?P p" is "\<exists>(z::int). \<forall>x < z. ?I x (?M p) = ?I x p")
using linp u
proof (induct p rule: minusinf.induct)
case (1 p q)
then show ?case
- by auto (rule_tac x="min z za" in exI, simp)
+ by auto (rule_tac x = "min z za" in exI, simp)
next
case (2 p q)
then show ?case
- by auto (rule_tac x="min z za" in exI, simp)
+ by auto (rule_tac x = "min z za" in exI, simp)
next
case (3 c e)
then have c1: "c = 1" and nb: "numbound0 e"
@@ -1513,10 +1530,10 @@
then have c1: "c = 1" and nb: "numbound0 e"
by simp_all
fix a
- from 4 have "\<forall>x < (- Inum (a#bs) e). c*x + Inum (x#bs) e \<noteq> 0"
+ from 4 have "\<forall>x < (- Inum (a # bs) e). c * x + Inum (x # bs) e \<noteq> 0"
proof clarsimp
fix x
- assume "x < (- Inum (a#bs) e)" and"x + Inum (x # bs) e = 0"
+ assume "x < (- Inum (a # bs) e)" and "x + Inum (x # bs) e = 0"
with numbound0_I[OF nb, where bs="bs" and b="a" and b'="x"]
show "False" by simp
qed
@@ -1526,10 +1543,10 @@
then have c1: "c = 1" and nb: "numbound0 e"
by simp_all
fix a
- from 5 have "\<forall>x<(- Inum (a#bs) e). c*x + Inum (x#bs) e < 0"
+ from 5 have "\<forall>x<(- Inum (a # bs) e). c*x + Inum (x # bs) e < 0"
proof clarsimp
fix x
- assume "x < (- Inum (a#bs) e)"
+ assume "x < (- Inum (a # bs) e)"
with numbound0_I[OF nb, where bs="bs" and b="a" and b'="x"]
show "x + Inum (x # bs) e < 0"
by simp
@@ -1540,12 +1557,12 @@
then have c1: "c = 1" and nb: "numbound0 e"
by simp_all
fix a
- from 6 have "\<forall>x<(- Inum (a#bs) e). c*x + Inum (x#bs) e \<le> 0"
+ from 6 have "\<forall>x<(- Inum (a # bs) e). c * x + Inum (x # bs) e \<le> 0"
proof clarsimp
fix x
- assume "x < (- Inum (a#bs) e)"
+ assume "x < (- Inum (a # bs) e)"
with numbound0_I[OF nb, where bs="bs" and b="a" and b'="x"]
- show "x + Inum (x#bs) e \<le> 0" by simp
+ show "x + Inum (x # bs) e \<le> 0" by simp
qed
then show ?case by auto
next
@@ -1553,10 +1570,10 @@
then have c1: "c = 1" and nb: "numbound0 e"
by simp_all
fix a
- from 7 have "\<forall>x<(- Inum (a#bs) e). \<not> (c*x + Inum (x#bs) e > 0)"
+ from 7 have "\<forall>x<(- Inum (a # bs) e). \<not> (c * x + Inum (x # bs) e > 0)"
proof clarsimp
fix x
- assume "x < (- Inum (a#bs) e)" and"x + Inum (x#bs) e > 0"
+ assume "x < - Inum (a # bs) e" and "x + Inum (x # bs) e > 0"
with numbound0_I[OF nb, where bs="bs" and b="a" and b'="x"]
show False by simp
qed
@@ -1596,23 +1613,23 @@
(is "?ri dvd ?rc*?rx - ?rc*(?rk*?rd) + ?I x e" is "?ri dvd ?rt")
then have "\<exists>l::int. ?rt = i * l"
by (simp add: dvd_def)
- then have "\<exists>l::int. c*x+ ?I x e = i * l + c * (k * i * di)"
+ then have "\<exists>l::int. c * x + ?I x e = i * l + c * (k * i * di)"
by (simp add: algebra_simps di_def)
- then have "\<exists>l::int. c*x+ ?I x e = i*(l + c * k * di)"
+ then have "\<exists>l::int. c * x + ?I x e = i* (l + c * k * di)"
by (simp add: algebra_simps)
then have "\<exists>l::int. c * x + ?I x e = i * l"
by blast
then show "i dvd c * x + Inum (x # bs) e"
by (simp add: dvd_def)
next
- assume "i dvd c*x + Inum (x # bs) e" (is "?ri dvd ?rc * ?rx + ?e")
+ assume "i dvd c * x + Inum (x # bs) e" (is "?ri dvd ?rc * ?rx + ?e")
then have "\<exists>l::int. c * x + ?e = i * l"
by (simp add: dvd_def)
then have "\<exists>l::int. c * x - c * (k * d) + ?e = i * l - c * (k * d)"
by simp
then have "\<exists>l::int. c * x - c * (k * d) + ?e = i * l - c * (k * i * di)"
by (simp add: di_def)
- then have "\<exists>l::int. c * x - c * (k * d) + ?e = i * ((l - c * k * di))"
+ then have "\<exists>l::int. c * x - c * (k * d) + ?e = i * (l - c * k * di)"
by (simp add: algebra_simps)
then have "\<exists>l::int. c * x - c * (k * d) + ?e = i * l"
by blast
@@ -1660,7 +1677,7 @@
lemma mirror_\<alpha>_\<beta>:
assumes lp: "iszlfm p"
- shows "(Inum (i#bs)) ` set (\<alpha> p) = (Inum (i#bs)) ` set (\<beta> (mirror p))"
+ shows "Inum (i # bs) ` set (\<alpha> p) = Inum (i # bs) ` set (\<beta> (mirror p))"
using lp by (induct p rule: mirror.induct) auto
lemma mirror:
@@ -1669,27 +1686,30 @@
using lp
proof (induct p rule: iszlfm.induct)
case (9 j c e)
- then have nb: "numbound0 e" by simp
- have "Ifm bbs (x#bs) (mirror (Dvd j (CN 0 c e))) = (j dvd c*x - Inum (x#bs) e)"
+ then have nb: "numbound0 e"
+ by simp
+ have "Ifm bbs (x # bs) (mirror (Dvd j (CN 0 c e))) \<longleftrightarrow> j dvd c * x - Inum (x # bs) e"
(is "_ = (j dvd c*x - ?e)") by simp
- also have "\<dots> = (j dvd (- (c*x - ?e)))"
+ also have "\<dots> \<longleftrightarrow> j dvd (- (c * x - ?e))"
by (simp only: dvd_minus_iff)
- also have "\<dots> = (j dvd (c* (- x)) + ?e)"
+ also have "\<dots> \<longleftrightarrow> j dvd (c * (- x)) + ?e"
by (simp only: minus_mult_right[symmetric] minus_mult_left[symmetric] add_ac minus_add_distrib)
(simp add: algebra_simps)
- also have "\<dots> = Ifm bbs ((- x)#bs) (Dvd j (CN 0 c e))"
+ also have "\<dots> = Ifm bbs ((- x) # bs) (Dvd j (CN 0 c e))"
using numbound0_I[OF nb, where bs="bs" and b="x" and b'="- x"] by simp
finally show ?case .
next
- case (10 j c e) then have nb: "numbound0 e" by simp
- have "Ifm bbs (x#bs) (mirror (Dvd j (CN 0 c e))) = (j dvd c*x - Inum (x#bs) e)"
- (is "_ = (j dvd c*x - ?e)") by simp
- also have "\<dots> = (j dvd (- (c*x - ?e)))"
+ case (10 j c e)
+ then have nb: "numbound0 e"
+ by simp
+ have "Ifm bbs (x # bs) (mirror (Dvd j (CN 0 c e))) \<longleftrightarrow> j dvd c * x - Inum (x # bs) e"
+ (is "_ = (j dvd c * x - ?e)") by simp
+ also have "\<dots> \<longleftrightarrow> j dvd (- (c * x - ?e))"
by (simp only: dvd_minus_iff)
- also have "\<dots> = (j dvd (c* (- x)) + ?e)"
+ also have "\<dots> \<longleftrightarrow> j dvd (c * (- x)) + ?e"
by (simp only: minus_mult_right[symmetric] minus_mult_left[symmetric] add_ac minus_add_distrib)
(simp add: algebra_simps)
- also have "\<dots> = Ifm bbs ((- x)#bs) (Dvd j (CN 0 c e))"
+ also have "\<dots> \<longleftrightarrow> Ifm bbs ((- x) # bs) (Dvd j (CN 0 c e))"
using numbound0_I[OF nb, where bs="bs" and b="x" and b'="- x"] by simp
finally show ?case by simp
qed (auto simp add: numbound0_I[where bs="bs" and b="x" and b'="- x"] gr0_conv_Suc)
@@ -1702,7 +1722,7 @@
lemma \<beta>_numbound0:
assumes lp: "iszlfm p"
- shows "\<forall>b\<in> set (\<beta> p). numbound0 b"
+ shows "\<forall>b \<in> set (\<beta> p). numbound0 b"
using lp by (induct p rule: \<beta>.induct) auto
lemma d_\<beta>_mono:
@@ -1724,29 +1744,37 @@
using linp
proof (induct p rule: iszlfm.induct)
case (1 p q)
- from 1 have dl1: "\<zeta> p dvd lcm (\<zeta> p) (\<zeta> q)" by simp
- from 1 have dl2: "\<zeta> q dvd lcm (\<zeta> p) (\<zeta> q)" by simp
+ from 1 have dl1: "\<zeta> p dvd lcm (\<zeta> p) (\<zeta> q)"
+ by simp
+ from 1 have dl2: "\<zeta> q dvd lcm (\<zeta> p) (\<zeta> q)"
+ by simp
from 1 d_\<beta>_mono[where p = "p" and l="\<zeta> p" and l'="lcm (\<zeta> p) (\<zeta> q)"]
- d_\<beta>_mono[where p = "q" and l="\<zeta> q" and l'="lcm (\<zeta> p) (\<zeta> q)"]
- dl1 dl2 show ?case by (auto simp add: lcm_pos_int)
+ d_\<beta>_mono[where p = "q" and l="\<zeta> q" and l'="lcm (\<zeta> p) (\<zeta> q)"]
+ dl1 dl2
+ show ?case
+ by (auto simp add: lcm_pos_int)
next
case (2 p q)
- from 2 have dl1: "\<zeta> p dvd lcm (\<zeta> p) (\<zeta> q)" by simp
- from 2 have dl2: "\<zeta> q dvd lcm (\<zeta> p) (\<zeta> q)" by simp
+ from 2 have dl1: "\<zeta> p dvd lcm (\<zeta> p) (\<zeta> q)"
+ by simp
+ from 2 have dl2: "\<zeta> q dvd lcm (\<zeta> p) (\<zeta> q)"
+ by simp
from 2 d_\<beta>_mono[where p = "p" and l="\<zeta> p" and l'="lcm (\<zeta> p) (\<zeta> q)"]
- d_\<beta>_mono[where p = "q" and l="\<zeta> q" and l'="lcm (\<zeta> p) (\<zeta> q)"]
- dl1 dl2 show ?case by (auto simp add: lcm_pos_int)
+ d_\<beta>_mono[where p = "q" and l="\<zeta> q" and l'="lcm (\<zeta> p) (\<zeta> q)"]
+ dl1 dl2
+ show ?case
+ by (auto simp add: lcm_pos_int)
qed (auto simp add: lcm_pos_int)
lemma a_\<beta>:
assumes linp: "iszlfm p"
and d: "d_\<beta> p l"
and lp: "l > 0"
- shows "iszlfm (a_\<beta> p l) \<and> d_\<beta> (a_\<beta> p l) 1 \<and> (Ifm bbs (l*x #bs) (a_\<beta> p l) = Ifm bbs (x#bs) p)"
+ shows "iszlfm (a_\<beta> p l) \<and> d_\<beta> (a_\<beta> p l) 1 \<and> Ifm bbs (l * x # bs) (a_\<beta> p l) = Ifm bbs (x # bs) p"
using linp d
proof (induct p rule: iszlfm.induct)
case (5 c e)
- then have cp: "c>0" and be: "numbound0 e" and d': "c dvd l"
+ then have cp: "c > 0" and be: "numbound0 e" and d': "c dvd l"
by simp_all
from lp cp have clel: "c \<le> l"
by (simp add: zdvd_imp_le [OF d' lp])
@@ -1760,15 +1788,17 @@
using d' dvd_eq_mod_eq_0[of "c" "l"] by simp
then have cl: "c * (l div c) =l"
using zmod_zdiv_equality[where a="l" and b="c", symmetric] by simp
- then have "(l*x + (l div c) * Inum (x # bs) e < 0) =
+ then have "(l * x + (l div c) * Inum (x # bs) e < 0) \<longleftrightarrow>
((c * (l div c)) * x + (l div c) * Inum (x # bs) e < 0)"
by simp
- also have "\<dots> = ((l div c) * (c*x + Inum (x # bs) e) < (l div c) * 0)"
+ also have "\<dots> \<longleftrightarrow> (l div c) * (c*x + Inum (x # bs) e) < (l div c) * 0"
by (simp add: algebra_simps)
- also have "\<dots> = (c*x + Inum (x # bs) e < 0)"
- using mult_less_0_iff [where a="(l div c)" and b="c*x + Inum (x # bs) e"] ldcp by simp
+ also have "\<dots> \<longleftrightarrow> c * x + Inum (x # bs) e < 0"
+ using mult_less_0_iff [where a="(l div c)" and b="c*x + Inum (x # bs) e"] ldcp
+ by simp
finally show ?case
- using numbound0_I[OF be,where b="l*x" and b'="x" and bs="bs"] be by simp
+ using numbound0_I[OF be,where b="l*x" and b'="x" and bs="bs"] be
+ by simp
next
case (6 c e)
then have cp: "c > 0" and be: "numbound0 e" and d': "c dvd l"
@@ -1777,20 +1807,20 @@
by (simp add: zdvd_imp_le [OF d' lp])
from cp have cnz: "c \<noteq> 0"
by simp
- have "c div c\<le> l div c"
+ have "c div c \<le> l div c"
by (simp add: zdiv_mono1[OF clel cp])
then have ldcp:"0 < l div c"
by (simp add: div_self[OF cnz])
- have "c * (l div c) = c* (l div c) + l mod c"
+ have "c * (l div c) = c * (l div c) + l mod c"
using d' dvd_eq_mod_eq_0[of "c" "l"] by simp
then have cl: "c * (l div c) = l"
using zmod_zdiv_equality[where a="l" and b="c", symmetric] by simp
- then have "(l*x + (l div c) * Inum (x# bs) e \<le> 0) =
- ((c * (l div c)) * x + (l div c) * Inum (x # bs) e \<le> 0)"
+ then have "l * x + (l div c) * Inum (x # bs) e \<le> 0 \<longleftrightarrow>
+ (c * (l div c)) * x + (l div c) * Inum (x # bs) e \<le> 0"
by simp
- also have "\<dots> = ((l div c) * (c * x + Inum (x # bs) e) \<le> ((l div c)) * 0)"
+ also have "\<dots> \<longleftrightarrow> (l div c) * (c * x + Inum (x # bs) e) \<le> (l div c) * 0"
by (simp add: algebra_simps)
- also have "\<dots> = (c*x + Inum (x # bs) e \<le> 0)"
+ also have "\<dots> \<longleftrightarrow> c * x + Inum (x # bs) e \<le> 0"
using mult_le_0_iff [where a="(l div c)" and b="c*x + Inum (x # bs) e"] ldcp by simp
finally show ?case
using numbound0_I[OF be,where b="l*x" and b'="x" and bs="bs"] be by simp
@@ -1804,18 +1834,18 @@
by simp
have "c div c \<le> l div c"
by (simp add: zdiv_mono1[OF clel cp])
- then have ldcp:"0 < l div c"
+ then have ldcp: "0 < l div c"
by (simp add: div_self[OF cnz])
- have "c * (l div c) = c* (l div c) + l mod c"
+ have "c * (l div c) = c * (l div c) + l mod c"
using d' dvd_eq_mod_eq_0[of "c" "l"] by simp
- then have cl:"c * (l div c) = l"
+ then have cl: "c * (l div c) = l"
using zmod_zdiv_equality[where a="l" and b="c", symmetric] by simp
- then have "(l * x + (l div c) * Inum (x # bs) e > 0) =
- ((c * (l div c)) * x + (l div c) * Inum (x # bs) e > 0)"
+ then have "l * x + (l div c) * Inum (x # bs) e > 0 \<longleftrightarrow>
+ (c * (l div c)) * x + (l div c) * Inum (x # bs) e > 0"
by simp
- also have "\<dots> = ((l div c) * (c * x + Inum (x # bs) e) > ((l div c)) * 0)"
+ also have "\<dots> \<longleftrightarrow> (l div c) * (c * x + Inum (x # bs) e) > (l div c) * 0"
by (simp add: algebra_simps)
- also have "\<dots> = (c * x + Inum (x # bs) e > 0)"
+ also have "\<dots> \<longleftrightarrow> c * x + Inum (x # bs) e > 0"
using zero_less_mult_iff [where a="(l div c)" and b="c * x + Inum (x # bs) e"] ldcp
by simp
finally show ?case
@@ -1833,17 +1863,17 @@
by (simp add: zdiv_mono1[OF clel cp])
then have ldcp: "0 < l div c"
by (simp add: div_self[OF cnz])
- have "c * (l div c) = c* (l div c) + l mod c"
+ have "c * (l div c) = c * (l div c) + l mod c"
using d' dvd_eq_mod_eq_0[of "c" "l"] by simp
then have cl: "c * (l div c) =l"
using zmod_zdiv_equality[where a="l" and b="c", symmetric]
by simp
- then have "(l*x + (l div c)* Inum (x # bs) e \<ge> 0) =
- ((c*(l div c))*x + (l div c)* Inum (x # bs) e \<ge> 0)"
+ then have "l * x + (l div c) * Inum (x # bs) e \<ge> 0 \<longleftrightarrow>
+ (c * (l div c)) * x + (l div c) * Inum (x # bs) e \<ge> 0"
by simp
- also have "\<dots> = ((l div c)*(c*x + Inum (x # bs) e) \<ge> ((l div c)) * 0)"
+ also have "\<dots> \<longleftrightarrow> (l div c) * (c * x + Inum (x # bs) e) \<ge> (l div c) * 0"
by (simp add: algebra_simps)
- also have "\<dots> = (c*x + Inum (x # bs) e \<ge> 0)"
+ also have "\<dots> \<longleftrightarrow> c * x + Inum (x # bs) e \<ge> 0"
using ldcp zero_le_mult_iff [where a="l div c" and b="c*x + Inum (x # bs) e"]
by simp
finally show ?case
@@ -1861,16 +1891,16 @@
by (simp add: zdiv_mono1[OF clel cp])
then have ldcp:"0 < l div c"
by (simp add: div_self[OF cnz])
- have "c * (l div c) = c* (l div c) + l mod c"
+ have "c * (l div c) = c * (l div c) + l mod c"
using d' dvd_eq_mod_eq_0[of "c" "l"] by simp
then have cl:"c * (l div c) =l" using zmod_zdiv_equality[where a="l" and b="c", symmetric]
by simp
- then have "(l * x + (l div c) * Inum (x # bs) e = 0) =
- ((c * (l div c)) * x + (l div c) * Inum (x # bs) e = 0)"
+ then have "l * x + (l div c) * Inum (x # bs) e = 0 \<longleftrightarrow>
+ (c * (l div c)) * x + (l div c) * Inum (x # bs) e = 0"
by simp
- also have "\<dots> = ((l div c) * (c * x + Inum (x # bs) e) = ((l div c)) * 0)"
+ also have "\<dots> \<longleftrightarrow> (l div c) * (c * x + Inum (x # bs) e) = ((l div c)) * 0"
by (simp add: algebra_simps)
- also have "\<dots> = (c * x + Inum (x # bs) e = 0)"
+ also have "\<dots> \<longleftrightarrow> c * x + Inum (x # bs) e = 0"
using mult_eq_0_iff [where a="(l div c)" and b="c * x + Inum (x # bs) e"] ldcp
by simp
finally show ?case
@@ -1888,11 +1918,11 @@
by (simp add: zdiv_mono1[OF clel cp])
then have ldcp:"0 < l div c"
by (simp add: div_self[OF cnz])
- have "c * (l div c) = c* (l div c) + l mod c"
+ have "c * (l div c) = c * (l div c) + l mod c"
using d' dvd_eq_mod_eq_0[of "c" "l"] by simp
then have cl: "c * (l div c) = l"
using zmod_zdiv_equality[where a="l" and b="c", symmetric] by simp
- then have "(l * x + (l div c) * Inum (x # bs) e \<noteq> 0) \<longleftrightarrow>
+ then have "l * x + (l div c) * Inum (x # bs) e \<noteq> 0 \<longleftrightarrow>
(c * (l div c)) * x + (l div c) * Inum (x # bs) e \<noteq> 0"
by simp
also have "\<dots> \<longleftrightarrow> (l div c) * (c * x + Inum (x # bs) e) \<noteq> (l div c) * 0"
@@ -1914,14 +1944,14 @@
by (simp add: zdiv_mono1[OF clel cp])
then have ldcp:"0 < l div c"
by (simp add: div_self[OF cnz])
- have "c * (l div c) = c* (l div c) + l mod c"
+ have "c * (l div c) = c * (l div c) + l mod c"
using d' dvd_eq_mod_eq_0[of "c" "l"] by simp
then have cl: "c * (l div c) = l"
using zmod_zdiv_equality[where a="l" and b="c", symmetric] by simp
then have "(\<exists>k::int. l * x + (l div c) * Inum (x # bs) e = ((l div c) * j) * k) \<longleftrightarrow>
- (\<exists>(k::int). (c * (l div c)) * x + (l div c) * Inum (x # bs) e = ((l div c) * j) * k)"
+ (\<exists>k::int. (c * (l div c)) * x + (l div c) * Inum (x # bs) e = ((l div c) * j) * k)"
by simp
- also have "\<dots> \<longleftrightarrow> (\<exists>(k::int). (l div c) * (c * x + Inum (x # bs) e - j * k) = (l div c) * 0)"
+ also have "\<dots> \<longleftrightarrow> (\<exists>k::int. (l div c) * (c * x + Inum (x # bs) e - j * k) = (l div c) * 0)"
by (simp add: algebra_simps)
also
fix k
@@ -1958,10 +1988,10 @@
by (simp add: algebra_simps)
also
fix k
- have "\<dots> = (\<exists>k::int. c * x + Inum (x # bs) e - j * k = 0)"
+ have "\<dots> \<longleftrightarrow> (\<exists>k::int. c * x + Inum (x # bs) e - j * k = 0)"
using zero_le_mult_iff [where a="(l div c)" and b="c * x + Inum (x # bs) e - j * k"] ldcp
by simp
- also have "\<dots> = (\<exists>k::int. c * x + Inum (x # bs) e = j * k)"
+ also have "\<dots> \<longleftrightarrow> (\<exists>k::int. c * x + Inum (x # bs) e = j * k)"
by simp
finally show ?case
using numbound0_I[OF be,where b="(l * x)" and b'="x" and bs="bs"] be
@@ -1988,15 +2018,15 @@
and u: "d_\<beta> p 1"
and d: "d_\<delta> p d"
and dp: "d > 0"
- and nob: "\<not>(\<exists>(j::int) \<in> {1 .. d}. \<exists>b\<in> (Inum (a#bs)) ` set(\<beta> p). x = b + j)"
- and p: "Ifm bbs (x#bs) p" (is "?P x")
+ and nob: "\<not> (\<exists>j::int \<in> {1 .. d}. \<exists>b \<in> Inum (a # bs) ` set (\<beta> p). x = b + j)"
+ and p: "Ifm bbs (x # bs) p" (is "?P x")
shows "?P (x - d)"
using lp u d dp nob p
proof (induct p rule: iszlfm.induct)
case (5 c e)
then have c1: "c = 1" and bn: "numbound0 e"
by simp_all
- with dp p c1 numbound0_I[OF bn,where b="(x-d)" and b'="x" and bs="bs"] 5
+ with dp p c1 numbound0_I[OF bn,where b = "(x - d)" and b' = "x" and bs = "bs"] 5
show ?case by simp
next
case (6 c e)
@@ -2006,29 +2036,30 @@
show ?case by simp
next
case (7 c e)
- then have p: "Ifm bbs (x #bs) (Gt (CN 0 c e))" and c1: "c=1" and bn: "numbound0 e"
+ then have p: "Ifm bbs (x # bs) (Gt (CN 0 c e))" and c1: "c=1" and bn: "numbound0 e"
by simp_all
let ?e = "Inum (x # bs) e"
{
- assume "(x-d) +?e > 0"
+ assume "(x - d) + ?e > 0"
then have ?case
using c1 numbound0_I[OF bn,where b="(x-d)" and b'="x" and bs="bs"] by simp
}
moreover
{
- assume H: "\<not> (x-d) + ?e > 0"
- let ?v="Neg e"
- have vb: "?v \<in> set (\<beta> (Gt (CN 0 c e)))" by simp
+ assume H: "\<not> (x - d) + ?e > 0"
+ let ?v = "Neg e"
+ have vb: "?v \<in> set (\<beta> (Gt (CN 0 c e)))"
+ by simp
from 7(5)[simplified simp_thms Inum.simps \<beta>.simps set_simps bex_simps numbound0_I[OF bn,where b="a" and b'="x" and bs="bs"]]
- have nob: "\<not> (\<exists>j\<in> {1 ..d}. x = - ?e + j)"
+ have nob: "\<not> (\<exists>j\<in> {1 ..d}. x = - ?e + j)"
by auto
from H p have "x + ?e > 0 \<and> x + ?e \<le> d"
by (simp add: c1)
then have "x + ?e \<ge> 1 \<and> x + ?e \<le> d"
by simp
- then have "\<exists>(j::int) \<in> {1 .. d}. j = x + ?e"
+ then have "\<exists>j::int \<in> {1 .. d}. j = x + ?e"
by simp
- then have "\<exists>(j::int) \<in> {1 .. d}. x = (- ?e + j)"
+ then have "\<exists>j::int \<in> {1 .. d}. x = (- ?e + j)"
by (simp add: algebra_simps)
with nob have ?case
by auto
@@ -2059,9 +2090,9 @@
by (simp add: c1)
then have "x + ?e +1 \<ge> 1 \<and> x + ?e + 1 \<le> d"
by simp
- then have "\<exists>(j::int) \<in> {1 .. d}. j = x + ?e + 1"
+ then have "\<exists>j::int \<in> {1 .. d}. j = x + ?e + 1"
by simp
- then have "\<exists>(j::int) \<in> {1 .. d}. x= - ?e - 1 + j"
+ then have "\<exists>j::int \<in> {1 .. d}. x= - ?e - 1 + j"
by (simp add: algebra_simps)
with nob have ?case
by simp
@@ -2072,35 +2103,38 @@
case (3 c e)
then
have p: "Ifm bbs (x #bs) (Eq (CN 0 c e))" (is "?p x")
- and c1: "c=1"
+ and c1: "c = 1"
and bn: "numbound0 e"
by simp_all
let ?e = "Inum (x # bs) e"
let ?v="(Sub (C -1) e)"
have vb: "?v \<in> set (\<beta> (Eq (CN 0 c e)))"
by simp
- from p have "x= - ?e" by (simp add: c1) with 3(5) show ?case
+ from p have "x= - ?e"
+ by (simp add: c1) with 3(5)
+ show ?case
using dp
by simp (erule ballE[where x="1"],
simp_all add:algebra_simps numbound0_I[OF bn,where b="x"and b'="a"and bs="bs"])
next
case (4 c e)
then
- have p: "Ifm bbs (x #bs) (NEq (CN 0 c e))" (is "?p x")
+ have p: "Ifm bbs (x # bs) (NEq (CN 0 c e))" (is "?p x")
and c1: "c = 1"
and bn: "numbound0 e"
by simp_all
let ?e = "Inum (x # bs) e"
let ?v="Neg e"
- have vb: "?v \<in> set (\<beta> (NEq (CN 0 c e)))" by simp
+ have vb: "?v \<in> set (\<beta> (NEq (CN 0 c e)))"
+ by simp
{
assume "x - d + Inum (((x -d)) # bs) e \<noteq> 0"
then have ?case by (simp add: c1)
}
moreover
{
- assume H: "x - d + Inum (((x -d)) # bs) e = 0"
- then have "x = - Inum (((x -d)) # bs) e + d"
+ assume H: "x - d + Inum ((x - d) # bs) e = 0"
+ then have "x = - Inum ((x - d) # bs) e + d"
by simp
then have "x = - Inum (a # bs) e + d"
by (simp add: numbound0_I[OF bn,where b="x - d"and b'="a"and bs="bs"])
@@ -2119,9 +2153,9 @@
let ?e = "Inum (x # bs) e"
from 9 have id: "j dvd d"
by simp
- from c1 have "?p x = (j dvd (x + ?e))"
+ from c1 have "?p x \<longleftrightarrow> j dvd (x + ?e)"
by simp
- also have "\<dots> = (j dvd x - d + ?e)"
+ also have "\<dots> \<longleftrightarrow> j dvd x - d + ?e"
using zdvd_period[OF id, where x="x" and c="-1" and t="?e"]
by simp
finally show ?case
@@ -2130,16 +2164,16 @@
next
case (10 j c e)
then
- have p: "Ifm bbs (x #bs) (NDvd j (CN 0 c e))" (is "?p x")
+ have p: "Ifm bbs (x # bs) (NDvd j (CN 0 c e))" (is "?p x")
and c1: "c = 1"
and bn: "numbound0 e"
by simp_all
let ?e = "Inum (x # bs) e"
from 10 have id: "j dvd d"
by simp
- from c1 have "?p x = (\<not> j dvd (x + ?e))"
+ from c1 have "?p x \<longleftrightarrow> \<not> j dvd (x + ?e)"
by simp
- also have "\<dots> = (\<not> j dvd x - d + ?e)"
+ also have "\<dots> \<longleftrightarrow> \<not> j dvd x - d + ?e"
using zdvd_period[OF id, where x="x" and c="-1" and t="?e"]
by simp
finally show ?case
@@ -2152,13 +2186,13 @@
and u: "d_\<beta> p 1"
and d: "d_\<delta> p d"
and dp: "d > 0"
- shows "\<forall>x. \<not> (\<exists>(j::int) \<in> {1 .. d}. \<exists>b\<in> set(\<beta> p). Ifm bbs ((Inum (a#bs) b + j) #bs) p) \<longrightarrow>
- Ifm bbs (x#bs) p \<longrightarrow> Ifm bbs ((x - d)#bs) p" (is "\<forall>x. ?b \<longrightarrow> ?P x \<longrightarrow> ?P (x - d)")
+ shows "\<forall>x. \<not> (\<exists>j::int \<in> {1 .. d}. \<exists>b \<in> set(\<beta> p). Ifm bbs ((Inum (a#bs) b + j) #bs) p) \<longrightarrow>
+ Ifm bbs (x # bs) p \<longrightarrow> Ifm bbs ((x - d) # bs) p" (is "\<forall>x. ?b \<longrightarrow> ?P x \<longrightarrow> ?P (x - d)")
proof clarify
fix x
assume nb: "?b"
and px: "?P x"
- then have nb2: "\<not>(\<exists>(j::int) \<in> {1 .. d}. \<exists>b\<in> (Inum (a#bs)) ` set(\<beta> p). x = b + j)"
+ then have nb2: "\<not> (\<exists>j::int \<in> {1 .. d}. \<exists>b \<in> Inum (a # bs) ` set (\<beta> p). x = b + j)"
by auto
from \<beta>[OF lp u d dp nb2 px] show "?P (x -d )" .
qed
@@ -2191,16 +2225,18 @@
and u: "d_\<beta> p 1"
and d: "d_\<delta> p d"
and dp: "d > 0"
- shows "(\<exists>(x::int). Ifm bbs (x #bs) p) = (\<exists>j\<in> {1.. d}. Ifm bbs (j #bs) (minusinf p) \<or> (\<exists>b \<in> set (\<beta> p). Ifm bbs ((Inum (i#bs) b + j) #bs) p))"
+ shows "(\<exists>(x::int). Ifm bbs (x # bs) p) \<longleftrightarrow>
+ (\<exists>j \<in> {1.. d}. Ifm bbs (j # bs) (minusinf p) \<or>
+ (\<exists>b \<in> set (\<beta> p). Ifm bbs ((Inum (i # bs) b + j) # bs) p))"
(is "(\<exists>(x::int). ?P (x)) = (\<exists>j\<in> ?D. ?M j \<or> (\<exists>b\<in> ?B. ?P (?I b + j)))")
proof -
from minusinf_inf[OF lp u]
- have th: "\<exists>(z::int). \<forall>x<z. ?P (x) = ?M x"
+ have th: "\<exists>z::int. \<forall>x<z. ?P (x) = ?M x"
by blast
- let ?B' = "{?I b | b. b\<in> ?B}"
- have BB': "(\<exists>j\<in>?D. \<exists>b\<in> ?B. ?P (?I b +j)) = (\<exists>j \<in> ?D. \<exists>b \<in> ?B'. ?P (b + j))"
+ let ?B' = "{?I b | b. b \<in> ?B}"
+ have BB': "(\<exists>j\<in>?D. \<exists>b \<in> ?B. ?P (?I b + j)) \<longleftrightarrow> (\<exists>j \<in> ?D. \<exists>b \<in> ?B'. ?P (b + j))"
by auto
- then have th2: "\<forall>x. \<not> (\<exists>j \<in> ?D. \<exists>b \<in> ?B'. ?P ((b + j))) \<longrightarrow> ?P (x) \<longrightarrow> ?P ((x - d))"
+ then have th2: "\<forall>x. \<not> (\<exists>j \<in> ?D. \<exists>b \<in> ?B'. ?P (b + j)) \<longrightarrow> ?P x \<longrightarrow> ?P (x - d)"
using \<beta>'[OF lp u d dp, where a="i" and bbs = "bbs"] by blast
from minusinf_repeats[OF d lp]
have th3: "\<forall>x k. ?M x = ?M (x-k*d)"
@@ -2214,31 +2250,50 @@
assumes lp: "iszlfm p"
shows "(\<exists>x. Ifm bbs (x#bs) (mirror p)) = (\<exists>x. Ifm bbs (x#bs) p)"
(is "(\<exists>x. ?I x ?mp) = (\<exists>x. ?I x p)")
-proof(auto)
- fix x assume "?I x ?mp" then have "?I (- x) p" using mirror[OF lp] by blast
- then show "\<exists>x. ?I x p" by blast
+proof auto
+ fix x
+ assume "?I x ?mp"
+ then have "?I (- x) p"
+ using mirror[OF lp] by blast
+ then show "\<exists>x. ?I x p"
+ by blast
next
- fix x assume "?I x p" then have "?I (- x) ?mp"
+ fix x
+ assume "?I x p"
+ then have "?I (- x) ?mp"
using mirror[OF lp, where x="- x", symmetric] by auto
- then show "\<exists>x. ?I x ?mp" by blast
+ then show "\<exists>x. ?I x ?mp"
+ by blast
qed
-
lemma cp_thm':
assumes lp: "iszlfm p"
- and up: "d_\<beta> p 1" and dd: "d_\<delta> p d" and dp: "d > 0"
- shows "(\<exists>x. Ifm bbs (x#bs) p) = ((\<exists>j\<in> {1 .. d}. Ifm bbs (j#bs) (minusinf p)) \<or> (\<exists>j\<in> {1.. d}. \<exists>b\<in> (Inum (i#bs)) ` set (\<beta> p). Ifm bbs ((b+j)#bs) p))"
+ and up: "d_\<beta> p 1"
+ and dd: "d_\<delta> p d"
+ and dp: "d > 0"
+ shows "(\<exists>x. Ifm bbs (x # bs) p) \<longleftrightarrow>
+ ((\<exists>j\<in> {1 .. d}. Ifm bbs (j#bs) (minusinf p)) \<or>
+ (\<exists>j\<in> {1.. d}. \<exists>b\<in> (Inum (i#bs)) ` set (\<beta> p). Ifm bbs ((b + j) # bs) p))"
using cp_thm[OF lp up dd dp,where i="i"] by auto
definition unit :: "fm \<Rightarrow> fm \<times> num list \<times> int"
where
- "unit p = (let p' = zlfm p ; l = \<zeta> p' ; q = And (Dvd l (CN 0 1 (C 0))) (a_\<beta> p' l); d = \<delta> q;
- B = remdups (map simpnum (\<beta> q)) ; a = remdups (map simpnum (\<alpha> q))
- in if length B \<le> length a then (q,B,d) else (mirror q, a,d))"
+ "unit p =
+ (let
+ p' = zlfm p;
+ l = \<zeta> p';
+ q = And (Dvd l (CN 0 1 (C 0))) (a_\<beta> p' l);
+ d = \<delta> q;
+ B = remdups (map simpnum (\<beta> q));
+ a = remdups (map simpnum (\<alpha> q))
+ in if length B \<le> length a then (q, B, d) else (mirror q, a, d))"
lemma unit:
assumes qf: "qfree p"
- shows "\<And>q B d. unit p = (q,B,d) \<Longrightarrow> ((\<exists>x. Ifm bbs (x#bs) p) = (\<exists>x. Ifm bbs (x#bs) q)) \<and> (Inum (i#bs)) ` set B = (Inum (i#bs)) ` set (\<beta> q) \<and> d_\<beta> q 1 \<and> d_\<delta> q d \<and> d >0 \<and> iszlfm q \<and> (\<forall>b\<in> set B. numbound0 b)"
+ shows "\<And>q B d. unit p = (q, B, d) \<Longrightarrow>
+ ((\<exists>x. Ifm bbs (x # bs) p) \<longleftrightarrow> (\<exists>x. Ifm bbs (x # bs) q)) \<and>
+ (Inum (i # bs)) ` set B = (Inum (i # bs)) ` set (\<beta> q) \<and> d_\<beta> q 1 \<and> d_\<delta> q d \<and> d > 0 \<and>
+ iszlfm q \<and> (\<forall>b\<in> set B. numbound0 b)"
proof -
fix q B d
assume qBd: "unit p = (q,B,d)"