reimplementation of HOL records; only one type is created for
each record extension, instead of one type for each field. See NEWS.
(* Title: HOL/Ring_and_Field.thy
ID: $Id$
Author: Gertrud Bauer and Markus Wenzel, TU Muenchen
Lawrence C Paulson, University of Cambridge
License: GPL (GNU GENERAL PUBLIC LICENSE)
*)
header {* Ring and field structures *}
theory Ring_and_Field = Inductive:
subsection {* Abstract algebraic structures *}
subsection {* Types Classes @{text plus_ac0} and @{text times_ac1} *}
axclass plus_ac0 \<subseteq> plus, zero
commute: "x + y = y + x"
assoc: "(x + y) + z = x + (y + z)"
zero [simp]: "0 + x = x"
lemma plus_ac0_left_commute: "x + (y+z) = y + ((x+z)::'a::plus_ac0)"
by(rule mk_left_commute[of "op +",OF plus_ac0.assoc plus_ac0.commute])
lemma plus_ac0_zero_right [simp]: "x + 0 = (x ::'a::plus_ac0)"
apply (rule plus_ac0.commute [THEN trans])
apply (rule plus_ac0.zero)
done
lemmas plus_ac0 = plus_ac0.assoc plus_ac0.commute plus_ac0_left_commute
plus_ac0.zero plus_ac0_zero_right
axclass times_ac1 \<subseteq> times, one
commute: "x * y = y * x"
assoc: "(x * y) * z = x * (y * z)"
one [simp]: "1 * x = x"
theorem times_ac1_left_commute: "(x::'a::times_ac1) * ((y::'a) * z) =
y * (x * z)"
by(rule mk_left_commute[of "op *",OF times_ac1.assoc times_ac1.commute])
theorem times_ac1_one_right [simp]: "(x::'a::times_ac1) * 1 = x"
proof -
have "x * 1 = 1 * x"
by (rule times_ac1.commute)
also have "... = x"
by (rule times_ac1.one)
finally show ?thesis .
qed
theorems times_ac1 = times_ac1.assoc times_ac1.commute times_ac1_left_commute
times_ac1.one times_ac1_one_right
text{*This class is the same as @{text plus_ac0}, while using the same axiom
names as the other axclasses.*}
axclass abelian_semigroup \<subseteq> zero, plus
add_assoc: "(a + b) + c = a + (b + c)"
add_commute: "a + b = b + a"
add_0 [simp]: "0 + a = a"
text{*This class underlies both @{text semiring} and @{text ring}*}
axclass almost_semiring \<subseteq> abelian_semigroup, one, times
mult_assoc: "(a * b) * c = a * (b * c)"
mult_commute: "a * b = b * a"
mult_1 [simp]: "1 * a = a"
left_distrib: "(a + b) * c = a * c + b * c"
zero_neq_one [simp]: "0 \<noteq> 1"
axclass semiring \<subseteq> almost_semiring
add_left_imp_eq: "a + b = a + c ==> b=c"
--{*This axiom is needed for semirings only: for rings, etc., it is
redundant. Including it allows many more of the following results
to be proved for semirings too.*}
instance abelian_semigroup \<subseteq> plus_ac0
proof
fix x y z :: 'a
show "x + y = y + x" by (rule add_commute)
show "x + y + z = x + (y + z)" by (rule add_assoc)
show "0+x = x" by (rule add_0)
qed
instance almost_semiring \<subseteq> times_ac1
proof
fix x y z :: 'a
show "x * y = y * x" by (rule mult_commute)
show "x * y * z = x * (y * z)" by (rule mult_assoc)
show "1*x = x" by simp
qed
axclass abelian_group \<subseteq> abelian_semigroup, minus
left_minus [simp]: "-a + a = 0"
diff_minus: "a - b = a + -b"
axclass ring \<subseteq> almost_semiring, abelian_group
text{*Proving axiom @{text add_left_imp_eq} makes all @{text semiring}
theorems available to members of @{term ring} *}
instance ring \<subseteq> semiring
proof
fix a b c :: 'a
assume "a + b = a + c"
hence "-a + a + b = -a + a + c" by (simp only: add_assoc)
thus "b = c" by simp
qed
text{*This class underlies @{text ordered_semiring} and @{text ordered_ring}*}
axclass almost_ordered_semiring \<subseteq> semiring, linorder
add_left_mono: "a \<le> b ==> c + a \<le> c + b"
mult_strict_left_mono: "a < b ==> 0 < c ==> c * a < c * b"
axclass ordered_semiring \<subseteq> almost_ordered_semiring
zero_less_one [simp]: "0 < 1" --{*This too is needed for semirings only.*}
axclass ordered_ring \<subseteq> almost_ordered_semiring, ring
abs_if: "\<bar>a\<bar> = (if a < 0 then -a else a)"
axclass field \<subseteq> ring, inverse
left_inverse [simp]: "a \<noteq> 0 ==> inverse a * a = 1"
divide_inverse: "a / b = a * inverse b"
axclass ordered_field \<subseteq> ordered_ring, field
axclass division_by_zero \<subseteq> zero, inverse
inverse_zero [simp]: "inverse 0 = 0"
subsection {* Derived Rules for Addition *}
lemma add_0_right [simp]: "a + 0 = (a::'a::plus_ac0)"
proof -
have "a + 0 = 0 + a" by (rule plus_ac0.commute)
also have "... = a" by simp
finally show ?thesis .
qed
lemma add_left_commute: "a + (b + c) = b + (a + (c::'a::plus_ac0))"
by (rule mk_left_commute [of "op +", OF plus_ac0.assoc plus_ac0.commute])
theorems add_ac = add_assoc add_commute add_left_commute
lemma right_minus [simp]: "a + -(a::'a::abelian_group) = 0"
proof -
have "a + -a = -a + a" by (simp add: add_ac)
also have "... = 0" by simp
finally show ?thesis .
qed
lemma right_minus_eq: "(a - b = 0) = (a = (b::'a::abelian_group))"
proof
have "a = a - b + b" by (simp add: diff_minus add_ac)
also assume "a - b = 0"
finally show "a = b" by simp
next
assume "a = b"
thus "a - b = 0" by (simp add: diff_minus)
qed
lemma add_left_cancel [simp]:
"(a + b = a + c) = (b = (c::'a::semiring))"
by (blast dest: add_left_imp_eq)
lemma add_right_cancel [simp]:
"(b + a = c + a) = (b = (c::'a::semiring))"
by (simp add: add_commute)
lemma minus_minus [simp]: "- (- (a::'a::abelian_group)) = a"
apply (rule right_minus_eq [THEN iffD1])
apply (simp add: diff_minus)
done
lemma equals_zero_I: "a+b = 0 ==> -a = (b::'a::abelian_group)"
apply (rule right_minus_eq [THEN iffD1, symmetric])
apply (simp add: diff_minus add_commute)
done
lemma minus_zero [simp]: "- 0 = (0::'a::abelian_group)"
by (simp add: equals_zero_I)
lemma diff_self [simp]: "a - (a::'a::abelian_group) = 0"
by (simp add: diff_minus)
lemma diff_0 [simp]: "(0::'a::abelian_group) - a = -a"
by (simp add: diff_minus)
lemma diff_0_right [simp]: "a - (0::'a::abelian_group) = a"
by (simp add: diff_minus)
lemma diff_minus_eq_add [simp]: "a - - b = a + (b::'a::abelian_group)"
by (simp add: diff_minus)
lemma neg_equal_iff_equal [simp]: "(-a = -b) = (a = (b::'a::abelian_group))"
proof
assume "- a = - b"
hence "- (- a) = - (- b)"
by simp
thus "a=b" by simp
next
assume "a=b"
thus "-a = -b" by simp
qed
lemma neg_equal_0_iff_equal [simp]: "(-a = 0) = (a = (0::'a::abelian_group))"
by (subst neg_equal_iff_equal [symmetric], simp)
lemma neg_0_equal_iff_equal [simp]: "(0 = -a) = (0 = (a::'a::abelian_group))"
by (subst neg_equal_iff_equal [symmetric], simp)
lemma add_minus_self [simp]: "a + b - b = (a::'a::abelian_group)";
by (simp add: diff_minus add_assoc)
lemma add_minus_self_left [simp]: "a + (b - a) = (b::'a::abelian_group)";
by (simp add: diff_minus add_left_commute [of a])
lemma add_minus_self_right [simp]: "a + b - a = (b::'a::abelian_group)";
by (simp add: diff_minus add_left_commute [of a] add_assoc)
lemma minus_add_self [simp]: "a - b + b = (a::'a::abelian_group)";
by (simp add: diff_minus add_assoc)
text{*The next two equations can make the simplifier loop!*}
lemma equation_minus_iff: "(a = - b) = (b = - (a::'a::abelian_group))"
proof -
have "(- (-a) = - b) = (- a = b)" by (rule neg_equal_iff_equal)
thus ?thesis by (simp add: eq_commute)
qed
lemma minus_equation_iff: "(- a = b) = (- (b::'a::abelian_group) = a)"
proof -
have "(- a = - (-b)) = (a = -b)" by (rule neg_equal_iff_equal)
thus ?thesis by (simp add: eq_commute)
qed
subsection {* Derived rules for multiplication *}
lemma mult_1_right [simp]: "a * (1::'a::almost_semiring) = a"
proof -
have "a * 1 = 1 * a" by (simp add: mult_commute)
also have "... = a" by simp
finally show ?thesis .
qed
lemma mult_left_commute: "a * (b * c) = b * (a * (c::'a::almost_semiring))"
by (rule mk_left_commute [of "op *", OF mult_assoc mult_commute])
theorems mult_ac = mult_assoc mult_commute mult_left_commute
lemma mult_zero_left [simp]: "0 * a = (0::'a::semiring)"
proof -
have "0*a + 0*a = 0*a + 0"
by (simp add: left_distrib [symmetric])
thus ?thesis by (simp only: add_left_cancel)
qed
lemma mult_zero_right [simp]: "a * 0 = (0::'a::semiring)"
by (simp add: mult_commute)
subsection {* Distribution rules *}
lemma right_distrib: "a * (b + c) = a * b + a * (c::'a::almost_semiring)"
proof -
have "a * (b + c) = (b + c) * a" by (simp add: mult_ac)
also have "... = b * a + c * a" by (simp only: left_distrib)
also have "... = a * b + a * c" by (simp add: mult_ac)
finally show ?thesis .
qed
theorems ring_distrib = right_distrib left_distrib
text{*For the @{text combine_numerals} simproc*}
lemma combine_common_factor:
"a*e + (b*e + c) = (a+b)*e + (c::'a::almost_semiring)"
by (simp add: left_distrib add_ac)
lemma minus_add_distrib [simp]: "- (a + b) = -a + -(b::'a::abelian_group)"
apply (rule equals_zero_I)
apply (simp add: plus_ac0)
done
lemma minus_mult_left: "- (a * b) = (-a) * (b::'a::ring)"
apply (rule equals_zero_I)
apply (simp add: left_distrib [symmetric])
done
lemma minus_mult_right: "- (a * b) = a * -(b::'a::ring)"
apply (rule equals_zero_I)
apply (simp add: right_distrib [symmetric])
done
lemma minus_mult_minus [simp]: "(- a) * (- b) = a * (b::'a::ring)"
by (simp add: minus_mult_left [symmetric] minus_mult_right [symmetric])
lemma minus_mult_commute: "(- a) * b = a * (- b::'a::ring)"
by (simp add: minus_mult_left [symmetric] minus_mult_right [symmetric])
lemma right_diff_distrib: "a * (b - c) = a * b - a * (c::'a::ring)"
by (simp add: right_distrib diff_minus
minus_mult_left [symmetric] minus_mult_right [symmetric])
lemma left_diff_distrib: "(a - b) * c = a * c - b * (c::'a::ring)"
by (simp add: mult_commute [of _ c] right_diff_distrib)
lemma minus_diff_eq [simp]: "- (a - b) = b - (a::'a::ring)"
by (simp add: diff_minus add_commute)
subsection {* Ordering Rules for Addition *}
lemma add_right_mono: "a \<le> (b::'a::almost_ordered_semiring) ==> a + c \<le> b + c"
by (simp add: add_commute [of _ c] add_left_mono)
text {* non-strict, in both arguments *}
lemma add_mono:
"[|a \<le> b; c \<le> d|] ==> a + c \<le> b + (d::'a::almost_ordered_semiring)"
apply (erule add_right_mono [THEN order_trans])
apply (simp add: add_commute add_left_mono)
done
lemma add_strict_left_mono:
"a < b ==> c + a < c + (b::'a::almost_ordered_semiring)"
by (simp add: order_less_le add_left_mono)
lemma add_strict_right_mono:
"a < b ==> a + c < b + (c::'a::almost_ordered_semiring)"
by (simp add: add_commute [of _ c] add_strict_left_mono)
text{*Strict monotonicity in both arguments*}
lemma add_strict_mono: "[|a<b; c<d|] ==> a + c < b + (d::'a::almost_ordered_semiring)"
apply (erule add_strict_right_mono [THEN order_less_trans])
apply (erule add_strict_left_mono)
done
lemma add_less_le_mono:
"[| a<b; c\<le>d |] ==> a + c < b + (d::'a::almost_ordered_semiring)"
apply (erule add_strict_right_mono [THEN order_less_le_trans])
apply (erule add_left_mono)
done
lemma add_le_less_mono:
"[| a\<le>b; c<d |] ==> a + c < b + (d::'a::almost_ordered_semiring)"
apply (erule add_right_mono [THEN order_le_less_trans])
apply (erule add_strict_left_mono)
done
lemma add_less_imp_less_left:
assumes less: "c + a < c + b" shows "a < (b::'a::almost_ordered_semiring)"
proof (rule ccontr)
assume "~ a < b"
hence "b \<le> a" by (simp add: linorder_not_less)
hence "c+b \<le> c+a" by (rule add_left_mono)
with this and less show False
by (simp add: linorder_not_less [symmetric])
qed
lemma add_less_imp_less_right:
"a + c < b + c ==> a < (b::'a::almost_ordered_semiring)"
apply (rule add_less_imp_less_left [of c])
apply (simp add: add_commute)
done
lemma add_less_cancel_left [simp]:
"(c+a < c+b) = (a < (b::'a::almost_ordered_semiring))"
by (blast intro: add_less_imp_less_left add_strict_left_mono)
lemma add_less_cancel_right [simp]:
"(a+c < b+c) = (a < (b::'a::almost_ordered_semiring))"
by (blast intro: add_less_imp_less_right add_strict_right_mono)
lemma add_le_cancel_left [simp]:
"(c+a \<le> c+b) = (a \<le> (b::'a::almost_ordered_semiring))"
by (simp add: linorder_not_less [symmetric])
lemma add_le_cancel_right [simp]:
"(a+c \<le> b+c) = (a \<le> (b::'a::almost_ordered_semiring))"
by (simp add: linorder_not_less [symmetric])
lemma add_le_imp_le_left:
"c + a \<le> c + b ==> a \<le> (b::'a::almost_ordered_semiring)"
by simp
lemma add_le_imp_le_right:
"a + c \<le> b + c ==> a \<le> (b::'a::almost_ordered_semiring)"
by simp
lemma add_increasing: "[|0\<le>a; b\<le>c|] ==> b \<le> a + (c::'a::almost_ordered_semiring)"
by (insert add_mono [of 0 a b c], simp)
subsection {* Ordering Rules for Unary Minus *}
lemma le_imp_neg_le:
assumes "a \<le> (b::'a::ordered_ring)" shows "-b \<le> -a"
proof -
have "-a+a \<le> -a+b"
by (rule add_left_mono)
hence "0 \<le> -a+b"
by simp
hence "0 + (-b) \<le> (-a + b) + (-b)"
by (rule add_right_mono)
thus ?thesis
by (simp add: add_assoc)
qed
lemma neg_le_iff_le [simp]: "(-b \<le> -a) = (a \<le> (b::'a::ordered_ring))"
proof
assume "- b \<le> - a"
hence "- (- a) \<le> - (- b)"
by (rule le_imp_neg_le)
thus "a\<le>b" by simp
next
assume "a\<le>b"
thus "-b \<le> -a" by (rule le_imp_neg_le)
qed
lemma neg_le_0_iff_le [simp]: "(-a \<le> 0) = (0 \<le> (a::'a::ordered_ring))"
by (subst neg_le_iff_le [symmetric], simp)
lemma neg_0_le_iff_le [simp]: "(0 \<le> -a) = (a \<le> (0::'a::ordered_ring))"
by (subst neg_le_iff_le [symmetric], simp)
lemma neg_less_iff_less [simp]: "(-b < -a) = (a < (b::'a::ordered_ring))"
by (force simp add: order_less_le)
lemma neg_less_0_iff_less [simp]: "(-a < 0) = (0 < (a::'a::ordered_ring))"
by (subst neg_less_iff_less [symmetric], simp)
lemma neg_0_less_iff_less [simp]: "(0 < -a) = (a < (0::'a::ordered_ring))"
by (subst neg_less_iff_less [symmetric], simp)
text{*The next several equations can make the simplifier loop!*}
lemma less_minus_iff: "(a < - b) = (b < - (a::'a::ordered_ring))"
proof -
have "(- (-a) < - b) = (b < - a)" by (rule neg_less_iff_less)
thus ?thesis by simp
qed
lemma minus_less_iff: "(- a < b) = (- b < (a::'a::ordered_ring))"
proof -
have "(- a < - (-b)) = (- b < a)" by (rule neg_less_iff_less)
thus ?thesis by simp
qed
lemma le_minus_iff: "(a \<le> - b) = (b \<le> - (a::'a::ordered_ring))"
apply (simp add: linorder_not_less [symmetric])
apply (rule minus_less_iff)
done
lemma minus_le_iff: "(- a \<le> b) = (- b \<le> (a::'a::ordered_ring))"
apply (simp add: linorder_not_less [symmetric])
apply (rule less_minus_iff)
done
subsection{*Subtraction Laws*}
lemma add_diff_eq: "a + (b - c) = (a + b) - (c::'a::abelian_group)"
by (simp add: diff_minus plus_ac0)
lemma diff_add_eq: "(a - b) + c = (a + c) - (b::'a::abelian_group)"
by (simp add: diff_minus plus_ac0)
lemma diff_eq_eq: "(a-b = c) = (a = c + (b::'a::abelian_group))"
by (auto simp add: diff_minus add_assoc)
lemma eq_diff_eq: "(a = c-b) = (a + (b::'a::abelian_group) = c)"
by (auto simp add: diff_minus add_assoc)
lemma diff_diff_eq: "(a - b) - c = a - (b + (c::'a::abelian_group))"
by (simp add: diff_minus plus_ac0)
lemma diff_diff_eq2: "a - (b - c) = (a + c) - (b::'a::abelian_group)"
by (simp add: diff_minus plus_ac0)
text{*Further subtraction laws for ordered rings*}
lemma less_iff_diff_less_0: "(a < b) = (a - b < (0::'a::ordered_ring))"
proof -
have "(a < b) = (a + (- b) < b + (-b))"
by (simp only: add_less_cancel_right)
also have "... = (a - b < 0)" by (simp add: diff_minus)
finally show ?thesis .
qed
lemma diff_less_eq: "(a-b < c) = (a < c + (b::'a::ordered_ring))"
apply (subst less_iff_diff_less_0)
apply (rule less_iff_diff_less_0 [of _ c, THEN ssubst])
apply (simp add: diff_minus add_ac)
done
lemma less_diff_eq: "(a < c-b) = (a + (b::'a::ordered_ring) < c)"
apply (subst less_iff_diff_less_0)
apply (rule less_iff_diff_less_0 [of _ "c-b", THEN ssubst])
apply (simp add: diff_minus add_ac)
done
lemma diff_le_eq: "(a-b \<le> c) = (a \<le> c + (b::'a::ordered_ring))"
by (simp add: linorder_not_less [symmetric] less_diff_eq)
lemma le_diff_eq: "(a \<le> c-b) = (a + (b::'a::ordered_ring) \<le> c)"
by (simp add: linorder_not_less [symmetric] diff_less_eq)
text{*This list of rewrites simplifies (in)equalities by bringing subtractions
to the top and then moving negative terms to the other side.
Use with @{text add_ac}*}
lemmas compare_rls =
diff_minus [symmetric]
add_diff_eq diff_add_eq diff_diff_eq diff_diff_eq2
diff_less_eq less_diff_eq diff_le_eq le_diff_eq
diff_eq_eq eq_diff_eq
text{*This list of rewrites decides ring equalities by ordered rewriting.*}
lemmas ring_eq_simps =
times_ac1.assoc times_ac1.commute times_ac1_left_commute
left_distrib right_distrib left_diff_distrib right_diff_distrib
plus_ac0.assoc plus_ac0.commute plus_ac0_left_commute
add_diff_eq diff_add_eq diff_diff_eq diff_diff_eq2
diff_eq_eq eq_diff_eq
subsection{*Lemmas for the @{text cancel_numerals} simproc*}
lemma eq_iff_diff_eq_0: "(a = b) = (a-b = (0::'a::abelian_group))"
by (simp add: compare_rls)
lemma le_iff_diff_le_0: "(a \<le> b) = (a-b \<le> (0::'a::ordered_ring))"
by (simp add: compare_rls)
lemma eq_add_iff1:
"(a*e + c = b*e + d) = ((a-b)*e + c = (d::'a::ring))"
apply (simp add: diff_minus left_distrib add_ac)
apply (simp add: compare_rls minus_mult_left [symmetric])
done
lemma eq_add_iff2:
"(a*e + c = b*e + d) = (c = (b-a)*e + (d::'a::ring))"
apply (simp add: diff_minus left_distrib add_ac)
apply (simp add: compare_rls minus_mult_left [symmetric])
done
lemma less_add_iff1:
"(a*e + c < b*e + d) = ((a-b)*e + c < (d::'a::ordered_ring))"
apply (simp add: diff_minus left_distrib add_ac)
apply (simp add: compare_rls minus_mult_left [symmetric])
done
lemma less_add_iff2:
"(a*e + c < b*e + d) = (c < (b-a)*e + (d::'a::ordered_ring))"
apply (simp add: diff_minus left_distrib add_ac)
apply (simp add: compare_rls minus_mult_left [symmetric])
done
lemma le_add_iff1:
"(a*e + c \<le> b*e + d) = ((a-b)*e + c \<le> (d::'a::ordered_ring))"
apply (simp add: diff_minus left_distrib add_ac)
apply (simp add: compare_rls minus_mult_left [symmetric])
done
lemma le_add_iff2:
"(a*e + c \<le> b*e + d) = (c \<le> (b-a)*e + (d::'a::ordered_ring))"
apply (simp add: diff_minus left_distrib add_ac)
apply (simp add: compare_rls minus_mult_left [symmetric])
done
subsection {* Ordering Rules for Multiplication *}
lemma mult_strict_right_mono:
"[|a < b; 0 < c|] ==> a * c < b * (c::'a::almost_ordered_semiring)"
by (simp add: mult_commute [of _ c] mult_strict_left_mono)
lemma mult_left_mono:
"[|a \<le> b; 0 \<le> c|] ==> c * a \<le> c * (b::'a::almost_ordered_semiring)"
apply (case_tac "c=0", simp)
apply (force simp add: mult_strict_left_mono order_le_less)
done
lemma mult_right_mono:
"[|a \<le> b; 0 \<le> c|] ==> a*c \<le> b * (c::'a::almost_ordered_semiring)"
by (simp add: mult_left_mono mult_commute [of _ c])
lemma mult_left_le_imp_le:
"[|c*a \<le> c*b; 0 < c|] ==> a \<le> (b::'a::almost_ordered_semiring)"
by (force simp add: mult_strict_left_mono linorder_not_less [symmetric])
lemma mult_right_le_imp_le:
"[|a*c \<le> b*c; 0 < c|] ==> a \<le> (b::'a::almost_ordered_semiring)"
by (force simp add: mult_strict_right_mono linorder_not_less [symmetric])
lemma mult_left_less_imp_less:
"[|c*a < c*b; 0 \<le> c|] ==> a < (b::'a::almost_ordered_semiring)"
by (force simp add: mult_left_mono linorder_not_le [symmetric])
lemma mult_right_less_imp_less:
"[|a*c < b*c; 0 \<le> c|] ==> a < (b::'a::almost_ordered_semiring)"
by (force simp add: mult_right_mono linorder_not_le [symmetric])
lemma mult_strict_left_mono_neg:
"[|b < a; c < 0|] ==> c * a < c * (b::'a::ordered_ring)"
apply (drule mult_strict_left_mono [of _ _ "-c"])
apply (simp_all add: minus_mult_left [symmetric])
done
lemma mult_strict_right_mono_neg:
"[|b < a; c < 0|] ==> a * c < b * (c::'a::ordered_ring)"
apply (drule mult_strict_right_mono [of _ _ "-c"])
apply (simp_all add: minus_mult_right [symmetric])
done
subsection{* Products of Signs *}
lemma mult_pos: "[| (0::'a::almost_ordered_semiring) < a; 0 < b |] ==> 0 < a*b"
by (drule mult_strict_left_mono [of 0 b], auto)
lemma mult_pos_neg: "[| (0::'a::almost_ordered_semiring) < a; b < 0 |] ==> a*b < 0"
by (drule mult_strict_left_mono [of b 0], auto)
lemma mult_neg: "[| a < (0::'a::ordered_ring); b < 0 |] ==> 0 < a*b"
by (drule mult_strict_right_mono_neg, auto)
lemma zero_less_mult_pos:
"[| 0 < a*b; 0 < a|] ==> 0 < (b::'a::almost_ordered_semiring)"
apply (case_tac "b\<le>0")
apply (auto simp add: order_le_less linorder_not_less)
apply (drule_tac mult_pos_neg [of a b])
apply (auto dest: order_less_not_sym)
done
lemma zero_less_mult_iff:
"((0::'a::ordered_ring) < a*b) = (0 < a & 0 < b | a < 0 & b < 0)"
apply (auto simp add: order_le_less linorder_not_less mult_pos mult_neg)
apply (blast dest: zero_less_mult_pos)
apply (simp add: mult_commute [of a b])
apply (blast dest: zero_less_mult_pos)
done
text{*A field has no "zero divisors", and this theorem holds without the
assumption of an ordering. See @{text field_mult_eq_0_iff} below.*}
lemma mult_eq_0_iff [simp]: "(a*b = (0::'a::ordered_ring)) = (a = 0 | b = 0)"
apply (case_tac "a < 0")
apply (auto simp add: linorder_not_less order_le_less linorder_neq_iff)
apply (force dest: mult_strict_right_mono_neg mult_strict_right_mono)+
done
lemma zero_le_mult_iff:
"((0::'a::ordered_ring) \<le> a*b) = (0 \<le> a & 0 \<le> b | a \<le> 0 & b \<le> 0)"
by (auto simp add: eq_commute [of 0] order_le_less linorder_not_less
zero_less_mult_iff)
lemma mult_less_0_iff:
"(a*b < (0::'a::ordered_ring)) = (0 < a & b < 0 | a < 0 & 0 < b)"
apply (insert zero_less_mult_iff [of "-a" b])
apply (force simp add: minus_mult_left[symmetric])
done
lemma mult_le_0_iff:
"(a*b \<le> (0::'a::ordered_ring)) = (0 \<le> a & b \<le> 0 | a \<le> 0 & 0 \<le> b)"
apply (insert zero_le_mult_iff [of "-a" b])
apply (force simp add: minus_mult_left[symmetric])
done
lemma zero_le_square: "(0::'a::ordered_ring) \<le> a*a"
by (simp add: zero_le_mult_iff linorder_linear)
text{*Proving axiom @{text zero_less_one} makes all @{text ordered_semiring}
theorems available to members of @{term ordered_ring} *}
instance ordered_ring \<subseteq> ordered_semiring
proof
have "(0::'a) \<le> 1*1" by (rule zero_le_square)
thus "(0::'a) < 1" by (simp add: order_le_less)
qed
text{*All three types of comparision involving 0 and 1 are covered.*}
declare zero_neq_one [THEN not_sym, simp]
lemma zero_le_one [simp]: "(0::'a::ordered_semiring) \<le> 1"
by (rule zero_less_one [THEN order_less_imp_le])
lemma not_one_le_zero [simp]: "~ (1::'a::ordered_semiring) \<le> 0"
by (simp add: linorder_not_le zero_less_one)
lemma not_one_less_zero [simp]: "~ (1::'a::ordered_semiring) < 0"
by (simp add: linorder_not_less zero_le_one)
subsection{*More Monotonicity*}
lemma mult_left_mono_neg:
"[|b \<le> a; c \<le> 0|] ==> c * a \<le> c * (b::'a::ordered_ring)"
apply (drule mult_left_mono [of _ _ "-c"])
apply (simp_all add: minus_mult_left [symmetric])
done
lemma mult_right_mono_neg:
"[|b \<le> a; c \<le> 0|] ==> a * c \<le> b * (c::'a::ordered_ring)"
by (simp add: mult_left_mono_neg mult_commute [of _ c])
text{*Strict monotonicity in both arguments*}
lemma mult_strict_mono:
"[|a<b; c<d; 0<b; 0\<le>c|] ==> a * c < b * (d::'a::ordered_semiring)"
apply (case_tac "c=0")
apply (simp add: mult_pos)
apply (erule mult_strict_right_mono [THEN order_less_trans])
apply (force simp add: order_le_less)
apply (erule mult_strict_left_mono, assumption)
done
text{*This weaker variant has more natural premises*}
lemma mult_strict_mono':
"[| a<b; c<d; 0 \<le> a; 0 \<le> c|] ==> a * c < b * (d::'a::ordered_semiring)"
apply (rule mult_strict_mono)
apply (blast intro: order_le_less_trans)+
done
lemma mult_mono:
"[|a \<le> b; c \<le> d; 0 \<le> b; 0 \<le> c|]
==> a * c \<le> b * (d::'a::ordered_semiring)"
apply (erule mult_right_mono [THEN order_trans], assumption)
apply (erule mult_left_mono, assumption)
done
lemma less_1_mult: "[| 1 < m; 1 < n |] ==> 1 < m*(n::'a::ordered_semiring)"
apply (insert mult_strict_mono [of 1 m 1 n])
apply (simp add: order_less_trans [OF zero_less_one])
done
subsection{*Cancellation Laws for Relationships With a Common Factor*}
text{*Cancellation laws for @{term "c*a < c*b"} and @{term "a*c < b*c"},
also with the relations @{text "\<le>"} and equality.*}
lemma mult_less_cancel_right:
"(a*c < b*c) = ((0 < c & a < b) | (c < 0 & b < (a::'a::ordered_ring)))"
apply (case_tac "c = 0")
apply (auto simp add: linorder_neq_iff mult_strict_right_mono
mult_strict_right_mono_neg)
apply (auto simp add: linorder_not_less
linorder_not_le [symmetric, of "a*c"]
linorder_not_le [symmetric, of a])
apply (erule_tac [!] notE)
apply (auto simp add: order_less_imp_le mult_right_mono
mult_right_mono_neg)
done
lemma mult_less_cancel_left:
"(c*a < c*b) = ((0 < c & a < b) | (c < 0 & b < (a::'a::ordered_ring)))"
by (simp add: mult_commute [of c] mult_less_cancel_right)
lemma mult_le_cancel_right:
"(a*c \<le> b*c) = ((0<c --> a\<le>b) & (c<0 --> b \<le> (a::'a::ordered_ring)))"
by (simp add: linorder_not_less [symmetric] mult_less_cancel_right)
lemma mult_le_cancel_left:
"(c*a \<le> c*b) = ((0<c --> a\<le>b) & (c<0 --> b \<le> (a::'a::ordered_ring)))"
by (simp add: mult_commute [of c] mult_le_cancel_right)
lemma mult_less_imp_less_left:
assumes less: "c*a < c*b" and nonneg: "0 \<le> c"
shows "a < (b::'a::ordered_semiring)"
proof (rule ccontr)
assume "~ a < b"
hence "b \<le> a" by (simp add: linorder_not_less)
hence "c*b \<le> c*a" by (rule mult_left_mono)
with this and less show False
by (simp add: linorder_not_less [symmetric])
qed
lemma mult_less_imp_less_right:
"[|a*c < b*c; 0 \<le> c|] ==> a < (b::'a::ordered_semiring)"
by (rule mult_less_imp_less_left, simp add: mult_commute)
text{*Cancellation of equalities with a common factor*}
lemma mult_cancel_right [simp]:
"(a*c = b*c) = (c = (0::'a::ordered_ring) | a=b)"
apply (cut_tac linorder_less_linear [of 0 c])
apply (force dest: mult_strict_right_mono_neg mult_strict_right_mono
simp add: linorder_neq_iff)
done
text{*These cancellation theorems require an ordering. Versions are proved
below that work for fields without an ordering.*}
lemma mult_cancel_left [simp]:
"(c*a = c*b) = (c = (0::'a::ordered_ring) | a=b)"
by (simp add: mult_commute [of c] mult_cancel_right)
subsection {* Fields *}
lemma right_inverse [simp]:
assumes not0: "a \<noteq> 0" shows "a * inverse (a::'a::field) = 1"
proof -
have "a * inverse a = inverse a * a" by (simp add: mult_ac)
also have "... = 1" using not0 by simp
finally show ?thesis .
qed
lemma right_inverse_eq: "b \<noteq> 0 ==> (a / b = 1) = (a = (b::'a::field))"
proof
assume neq: "b \<noteq> 0"
{
hence "a = (a / b) * b" by (simp add: divide_inverse mult_ac)
also assume "a / b = 1"
finally show "a = b" by simp
next
assume "a = b"
with neq show "a / b = 1" by (simp add: divide_inverse)
}
qed
lemma nonzero_inverse_eq_divide: "a \<noteq> 0 ==> inverse (a::'a::field) = 1/a"
by (simp add: divide_inverse)
lemma divide_self [simp]: "a \<noteq> 0 ==> a / (a::'a::field) = 1"
by (simp add: divide_inverse)
lemma divide_zero [simp]: "a / 0 = (0::'a::{field,division_by_zero})"
by (simp add: divide_inverse)
lemma divide_zero_left [simp]: "0/a = (0::'a::field)"
by (simp add: divide_inverse)
lemma inverse_eq_divide: "inverse (a::'a::field) = 1/a"
by (simp add: divide_inverse)
lemma add_divide_distrib: "(a+b)/(c::'a::field) = a/c + b/c"
by (simp add: divide_inverse left_distrib)
text{*Compared with @{text mult_eq_0_iff}, this version removes the requirement
of an ordering.*}
lemma field_mult_eq_0_iff [simp]: "(a*b = (0::'a::field)) = (a = 0 | b = 0)"
proof cases
assume "a=0" thus ?thesis by simp
next
assume anz [simp]: "a\<noteq>0"
{ assume "a * b = 0"
hence "inverse a * (a * b) = 0" by simp
hence "b = 0" by (simp (no_asm_use) add: mult_assoc [symmetric])}
thus ?thesis by force
qed
text{*Cancellation of equalities with a common factor*}
lemma field_mult_cancel_right_lemma:
assumes cnz: "c \<noteq> (0::'a::field)"
and eq: "a*c = b*c"
shows "a=b"
proof -
have "(a * c) * inverse c = (b * c) * inverse c"
by (simp add: eq)
thus "a=b"
by (simp add: mult_assoc cnz)
qed
lemma field_mult_cancel_right [simp]:
"(a*c = b*c) = (c = (0::'a::field) | a=b)"
proof cases
assume "c=0" thus ?thesis by simp
next
assume "c\<noteq>0"
thus ?thesis by (force dest: field_mult_cancel_right_lemma)
qed
lemma field_mult_cancel_left [simp]:
"(c*a = c*b) = (c = (0::'a::field) | a=b)"
by (simp add: mult_commute [of c] field_mult_cancel_right)
lemma nonzero_imp_inverse_nonzero: "a \<noteq> 0 ==> inverse a \<noteq> (0::'a::field)"
proof
assume ianz: "inverse a = 0"
assume "a \<noteq> 0"
hence "1 = a * inverse a" by simp
also have "... = 0" by (simp add: ianz)
finally have "1 = (0::'a::field)" .
thus False by (simp add: eq_commute)
qed
subsection{*Basic Properties of @{term inverse}*}
lemma inverse_zero_imp_zero: "inverse a = 0 ==> a = (0::'a::field)"
apply (rule ccontr)
apply (blast dest: nonzero_imp_inverse_nonzero)
done
lemma inverse_nonzero_imp_nonzero:
"inverse a = 0 ==> a = (0::'a::field)"
apply (rule ccontr)
apply (blast dest: nonzero_imp_inverse_nonzero)
done
lemma inverse_nonzero_iff_nonzero [simp]:
"(inverse a = 0) = (a = (0::'a::{field,division_by_zero}))"
by (force dest: inverse_nonzero_imp_nonzero)
lemma nonzero_inverse_minus_eq:
assumes [simp]: "a\<noteq>0" shows "inverse(-a) = -inverse(a::'a::field)"
proof -
have "-a * inverse (- a) = -a * - inverse a"
by simp
thus ?thesis
by (simp only: field_mult_cancel_left, simp)
qed
lemma inverse_minus_eq [simp]:
"inverse(-a) = -inverse(a::'a::{field,division_by_zero})";
proof cases
assume "a=0" thus ?thesis by (simp add: inverse_zero)
next
assume "a\<noteq>0"
thus ?thesis by (simp add: nonzero_inverse_minus_eq)
qed
lemma nonzero_inverse_eq_imp_eq:
assumes inveq: "inverse a = inverse b"
and anz: "a \<noteq> 0"
and bnz: "b \<noteq> 0"
shows "a = (b::'a::field)"
proof -
have "a * inverse b = a * inverse a"
by (simp add: inveq)
hence "(a * inverse b) * b = (a * inverse a) * b"
by simp
thus "a = b"
by (simp add: mult_assoc anz bnz)
qed
lemma inverse_eq_imp_eq:
"inverse a = inverse b ==> a = (b::'a::{field,division_by_zero})"
apply (case_tac "a=0 | b=0")
apply (force dest!: inverse_zero_imp_zero
simp add: eq_commute [of "0::'a"])
apply (force dest!: nonzero_inverse_eq_imp_eq)
done
lemma inverse_eq_iff_eq [simp]:
"(inverse a = inverse b) = (a = (b::'a::{field,division_by_zero}))"
by (force dest!: inverse_eq_imp_eq)
lemma nonzero_inverse_inverse_eq:
assumes [simp]: "a \<noteq> 0" shows "inverse(inverse (a::'a::field)) = a"
proof -
have "(inverse (inverse a) * inverse a) * a = a"
by (simp add: nonzero_imp_inverse_nonzero)
thus ?thesis
by (simp add: mult_assoc)
qed
lemma inverse_inverse_eq [simp]:
"inverse(inverse (a::'a::{field,division_by_zero})) = a"
proof cases
assume "a=0" thus ?thesis by simp
next
assume "a\<noteq>0"
thus ?thesis by (simp add: nonzero_inverse_inverse_eq)
qed
lemma inverse_1 [simp]: "inverse 1 = (1::'a::field)"
proof -
have "inverse 1 * 1 = (1::'a::field)"
by (rule left_inverse [OF zero_neq_one [symmetric]])
thus ?thesis by simp
qed
lemma nonzero_inverse_mult_distrib:
assumes anz: "a \<noteq> 0"
and bnz: "b \<noteq> 0"
shows "inverse(a*b) = inverse(b) * inverse(a::'a::field)"
proof -
have "inverse(a*b) * (a * b) * inverse(b) = inverse(b)"
by (simp add: field_mult_eq_0_iff anz bnz)
hence "inverse(a*b) * a = inverse(b)"
by (simp add: mult_assoc bnz)
hence "inverse(a*b) * a * inverse(a) = inverse(b) * inverse(a)"
by simp
thus ?thesis
by (simp add: mult_assoc anz)
qed
text{*This version builds in division by zero while also re-orienting
the right-hand side.*}
lemma inverse_mult_distrib [simp]:
"inverse(a*b) = inverse(a) * inverse(b::'a::{field,division_by_zero})"
proof cases
assume "a \<noteq> 0 & b \<noteq> 0"
thus ?thesis by (simp add: nonzero_inverse_mult_distrib mult_commute)
next
assume "~ (a \<noteq> 0 & b \<noteq> 0)"
thus ?thesis by force
qed
text{*There is no slick version using division by zero.*}
lemma inverse_add:
"[|a \<noteq> 0; b \<noteq> 0|]
==> inverse a + inverse b = (a+b) * inverse a * inverse (b::'a::field)"
apply (simp add: left_distrib mult_assoc)
apply (simp add: mult_commute [of "inverse a"])
apply (simp add: mult_assoc [symmetric] add_commute)
done
lemma inverse_divide [simp]:
"inverse (a/b) = b / (a::'a::{field,division_by_zero})"
by (simp add: divide_inverse mult_commute)
lemma nonzero_mult_divide_cancel_left:
assumes [simp]: "b\<noteq>0" and [simp]: "c\<noteq>0"
shows "(c*a)/(c*b) = a/(b::'a::field)"
proof -
have "(c*a)/(c*b) = c * a * (inverse b * inverse c)"
by (simp add: field_mult_eq_0_iff divide_inverse
nonzero_inverse_mult_distrib)
also have "... = a * inverse b * (inverse c * c)"
by (simp only: mult_ac)
also have "... = a * inverse b"
by simp
finally show ?thesis
by (simp add: divide_inverse)
qed
lemma mult_divide_cancel_left:
"c\<noteq>0 ==> (c*a) / (c*b) = a / (b::'a::{field,division_by_zero})"
apply (case_tac "b = 0")
apply (simp_all add: nonzero_mult_divide_cancel_left)
done
lemma nonzero_mult_divide_cancel_right:
"[|b\<noteq>0; c\<noteq>0|] ==> (a*c) / (b*c) = a/(b::'a::field)"
by (simp add: mult_commute [of _ c] nonzero_mult_divide_cancel_left)
lemma mult_divide_cancel_right:
"c\<noteq>0 ==> (a*c) / (b*c) = a / (b::'a::{field,division_by_zero})"
apply (case_tac "b = 0")
apply (simp_all add: nonzero_mult_divide_cancel_right)
done
(*For ExtractCommonTerm*)
lemma mult_divide_cancel_eq_if:
"(c*a) / (c*b) =
(if c=0 then 0 else a / (b::'a::{field,division_by_zero}))"
by (simp add: mult_divide_cancel_left)
lemma divide_1 [simp]: "a/1 = (a::'a::field)"
by (simp add: divide_inverse)
lemma times_divide_eq_right [simp]: "a * (b/c) = (a*b) / (c::'a::field)"
by (simp add: divide_inverse mult_assoc)
lemma times_divide_eq_left: "(b/c) * a = (b*a) / (c::'a::field)"
by (simp add: divide_inverse mult_ac)
lemma divide_divide_eq_right [simp]:
"a / (b/c) = (a*c) / (b::'a::{field,division_by_zero})"
by (simp add: divide_inverse mult_ac)
lemma divide_divide_eq_left [simp]:
"(a / b) / (c::'a::{field,division_by_zero}) = a / (b*c)"
by (simp add: divide_inverse mult_assoc)
subsection {* Division and Unary Minus *}
lemma nonzero_minus_divide_left: "b \<noteq> 0 ==> - (a/b) = (-a) / (b::'a::field)"
by (simp add: divide_inverse minus_mult_left)
lemma nonzero_minus_divide_right: "b \<noteq> 0 ==> - (a/b) = a / -(b::'a::field)"
by (simp add: divide_inverse nonzero_inverse_minus_eq minus_mult_right)
lemma nonzero_minus_divide_divide: "b \<noteq> 0 ==> (-a)/(-b) = a / (b::'a::field)"
by (simp add: divide_inverse nonzero_inverse_minus_eq)
lemma minus_divide_left: "- (a/b) = (-a) / (b::'a::field)"
by (simp add: divide_inverse minus_mult_left [symmetric])
lemma minus_divide_right: "- (a/b) = a / -(b::'a::{field,division_by_zero})"
by (simp add: divide_inverse minus_mult_right [symmetric])
text{*The effect is to extract signs from divisions*}
declare minus_divide_left [symmetric, simp]
declare minus_divide_right [symmetric, simp]
text{*Also, extract signs from products*}
declare minus_mult_left [symmetric, simp]
declare minus_mult_right [symmetric, simp]
lemma minus_divide_divide [simp]:
"(-a)/(-b) = a / (b::'a::{field,division_by_zero})"
apply (case_tac "b=0", simp)
apply (simp add: nonzero_minus_divide_divide)
done
lemma diff_divide_distrib: "(a-b)/(c::'a::field) = a/c - b/c"
by (simp add: diff_minus add_divide_distrib)
subsection {* Ordered Fields *}
lemma positive_imp_inverse_positive:
assumes a_gt_0: "0 < a" shows "0 < inverse (a::'a::ordered_field)"
proof -
have "0 < a * inverse a"
by (simp add: a_gt_0 [THEN order_less_imp_not_eq2] zero_less_one)
thus "0 < inverse a"
by (simp add: a_gt_0 [THEN order_less_not_sym] zero_less_mult_iff)
qed
lemma negative_imp_inverse_negative:
"a < 0 ==> inverse a < (0::'a::ordered_field)"
by (insert positive_imp_inverse_positive [of "-a"],
simp add: nonzero_inverse_minus_eq order_less_imp_not_eq)
lemma inverse_le_imp_le:
assumes invle: "inverse a \<le> inverse b"
and apos: "0 < a"
shows "b \<le> (a::'a::ordered_field)"
proof (rule classical)
assume "~ b \<le> a"
hence "a < b"
by (simp add: linorder_not_le)
hence bpos: "0 < b"
by (blast intro: apos order_less_trans)
hence "a * inverse a \<le> a * inverse b"
by (simp add: apos invle order_less_imp_le mult_left_mono)
hence "(a * inverse a) * b \<le> (a * inverse b) * b"
by (simp add: bpos order_less_imp_le mult_right_mono)
thus "b \<le> a"
by (simp add: mult_assoc apos bpos order_less_imp_not_eq2)
qed
lemma inverse_positive_imp_positive:
assumes inv_gt_0: "0 < inverse a"
and [simp]: "a \<noteq> 0"
shows "0 < (a::'a::ordered_field)"
proof -
have "0 < inverse (inverse a)"
by (rule positive_imp_inverse_positive)
thus "0 < a"
by (simp add: nonzero_inverse_inverse_eq)
qed
lemma inverse_positive_iff_positive [simp]:
"(0 < inverse a) = (0 < (a::'a::{ordered_field,division_by_zero}))"
apply (case_tac "a = 0", simp)
apply (blast intro: inverse_positive_imp_positive positive_imp_inverse_positive)
done
lemma inverse_negative_imp_negative:
assumes inv_less_0: "inverse a < 0"
and [simp]: "a \<noteq> 0"
shows "a < (0::'a::ordered_field)"
proof -
have "inverse (inverse a) < 0"
by (rule negative_imp_inverse_negative)
thus "a < 0"
by (simp add: nonzero_inverse_inverse_eq)
qed
lemma inverse_negative_iff_negative [simp]:
"(inverse a < 0) = (a < (0::'a::{ordered_field,division_by_zero}))"
apply (case_tac "a = 0", simp)
apply (blast intro: inverse_negative_imp_negative negative_imp_inverse_negative)
done
lemma inverse_nonnegative_iff_nonnegative [simp]:
"(0 \<le> inverse a) = (0 \<le> (a::'a::{ordered_field,division_by_zero}))"
by (simp add: linorder_not_less [symmetric])
lemma inverse_nonpositive_iff_nonpositive [simp]:
"(inverse a \<le> 0) = (a \<le> (0::'a::{ordered_field,division_by_zero}))"
by (simp add: linorder_not_less [symmetric])
subsection{*Anti-Monotonicity of @{term inverse}*}
lemma less_imp_inverse_less:
assumes less: "a < b"
and apos: "0 < a"
shows "inverse b < inverse (a::'a::ordered_field)"
proof (rule ccontr)
assume "~ inverse b < inverse a"
hence "inverse a \<le> inverse b"
by (simp add: linorder_not_less)
hence "~ (a < b)"
by (simp add: linorder_not_less inverse_le_imp_le [OF _ apos])
thus False
by (rule notE [OF _ less])
qed
lemma inverse_less_imp_less:
"[|inverse a < inverse b; 0 < a|] ==> b < (a::'a::ordered_field)"
apply (simp add: order_less_le [of "inverse a"] order_less_le [of "b"])
apply (force dest!: inverse_le_imp_le nonzero_inverse_eq_imp_eq)
done
text{*Both premises are essential. Consider -1 and 1.*}
lemma inverse_less_iff_less [simp]:
"[|0 < a; 0 < b|]
==> (inverse a < inverse b) = (b < (a::'a::ordered_field))"
by (blast intro: less_imp_inverse_less dest: inverse_less_imp_less)
lemma le_imp_inverse_le:
"[|a \<le> b; 0 < a|] ==> inverse b \<le> inverse (a::'a::ordered_field)"
by (force simp add: order_le_less less_imp_inverse_less)
lemma inverse_le_iff_le [simp]:
"[|0 < a; 0 < b|]
==> (inverse a \<le> inverse b) = (b \<le> (a::'a::ordered_field))"
by (blast intro: le_imp_inverse_le dest: inverse_le_imp_le)
text{*These results refer to both operands being negative. The opposite-sign
case is trivial, since inverse preserves signs.*}
lemma inverse_le_imp_le_neg:
"[|inverse a \<le> inverse b; b < 0|] ==> b \<le> (a::'a::ordered_field)"
apply (rule classical)
apply (subgoal_tac "a < 0")
prefer 2 apply (force simp add: linorder_not_le intro: order_less_trans)
apply (insert inverse_le_imp_le [of "-b" "-a"])
apply (simp add: order_less_imp_not_eq nonzero_inverse_minus_eq)
done
lemma less_imp_inverse_less_neg:
"[|a < b; b < 0|] ==> inverse b < inverse (a::'a::ordered_field)"
apply (subgoal_tac "a < 0")
prefer 2 apply (blast intro: order_less_trans)
apply (insert less_imp_inverse_less [of "-b" "-a"])
apply (simp add: order_less_imp_not_eq nonzero_inverse_minus_eq)
done
lemma inverse_less_imp_less_neg:
"[|inverse a < inverse b; b < 0|] ==> b < (a::'a::ordered_field)"
apply (rule classical)
apply (subgoal_tac "a < 0")
prefer 2
apply (force simp add: linorder_not_less intro: order_le_less_trans)
apply (insert inverse_less_imp_less [of "-b" "-a"])
apply (simp add: order_less_imp_not_eq nonzero_inverse_minus_eq)
done
lemma inverse_less_iff_less_neg [simp]:
"[|a < 0; b < 0|]
==> (inverse a < inverse b) = (b < (a::'a::ordered_field))"
apply (insert inverse_less_iff_less [of "-b" "-a"])
apply (simp del: inverse_less_iff_less
add: order_less_imp_not_eq nonzero_inverse_minus_eq)
done
lemma le_imp_inverse_le_neg:
"[|a \<le> b; b < 0|] ==> inverse b \<le> inverse (a::'a::ordered_field)"
by (force simp add: order_le_less less_imp_inverse_less_neg)
lemma inverse_le_iff_le_neg [simp]:
"[|a < 0; b < 0|]
==> (inverse a \<le> inverse b) = (b \<le> (a::'a::ordered_field))"
by (blast intro: le_imp_inverse_le_neg dest: inverse_le_imp_le_neg)
subsection{*Inverses and the Number One*}
lemma one_less_inverse_iff:
"(1 < inverse x) = (0 < x & x < (1::'a::{ordered_field,division_by_zero}))"proof cases
assume "0 < x"
with inverse_less_iff_less [OF zero_less_one, of x]
show ?thesis by simp
next
assume notless: "~ (0 < x)"
have "~ (1 < inverse x)"
proof
assume "1 < inverse x"
also with notless have "... \<le> 0" by (simp add: linorder_not_less)
also have "... < 1" by (rule zero_less_one)
finally show False by auto
qed
with notless show ?thesis by simp
qed
lemma inverse_eq_1_iff [simp]:
"(inverse x = 1) = (x = (1::'a::{field,division_by_zero}))"
by (insert inverse_eq_iff_eq [of x 1], simp)
lemma one_le_inverse_iff:
"(1 \<le> inverse x) = (0 < x & x \<le> (1::'a::{ordered_field,division_by_zero}))"
by (force simp add: order_le_less one_less_inverse_iff zero_less_one
eq_commute [of 1])
lemma inverse_less_1_iff:
"(inverse x < 1) = (x \<le> 0 | 1 < (x::'a::{ordered_field,division_by_zero}))"
by (simp add: linorder_not_le [symmetric] one_le_inverse_iff)
lemma inverse_le_1_iff:
"(inverse x \<le> 1) = (x \<le> 0 | 1 \<le> (x::'a::{ordered_field,division_by_zero}))"
by (simp add: linorder_not_less [symmetric] one_less_inverse_iff)
subsection{*Division and Signs*}
lemma zero_less_divide_iff:
"((0::'a::{ordered_field,division_by_zero}) < a/b) = (0 < a & 0 < b | a < 0 & b < 0)"
by (simp add: divide_inverse zero_less_mult_iff)
lemma divide_less_0_iff:
"(a/b < (0::'a::{ordered_field,division_by_zero})) =
(0 < a & b < 0 | a < 0 & 0 < b)"
by (simp add: divide_inverse mult_less_0_iff)
lemma zero_le_divide_iff:
"((0::'a::{ordered_field,division_by_zero}) \<le> a/b) =
(0 \<le> a & 0 \<le> b | a \<le> 0 & b \<le> 0)"
by (simp add: divide_inverse zero_le_mult_iff)
lemma divide_le_0_iff:
"(a/b \<le> (0::'a::{ordered_field,division_by_zero})) =
(0 \<le> a & b \<le> 0 | a \<le> 0 & 0 \<le> b)"
by (simp add: divide_inverse mult_le_0_iff)
lemma divide_eq_0_iff [simp]:
"(a/b = 0) = (a=0 | b=(0::'a::{field,division_by_zero}))"
by (simp add: divide_inverse field_mult_eq_0_iff)
subsection{*Simplification of Inequalities Involving Literal Divisors*}
lemma pos_le_divide_eq: "0 < (c::'a::ordered_field) ==> (a \<le> b/c) = (a*c \<le> b)"
proof -
assume less: "0<c"
hence "(a \<le> b/c) = (a*c \<le> (b/c)*c)"
by (simp add: mult_le_cancel_right order_less_not_sym [OF less])
also have "... = (a*c \<le> b)"
by (simp add: order_less_imp_not_eq2 [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma neg_le_divide_eq: "c < (0::'a::ordered_field) ==> (a \<le> b/c) = (b \<le> a*c)"
proof -
assume less: "c<0"
hence "(a \<le> b/c) = ((b/c)*c \<le> a*c)"
by (simp add: mult_le_cancel_right order_less_not_sym [OF less])
also have "... = (b \<le> a*c)"
by (simp add: order_less_imp_not_eq [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma le_divide_eq:
"(a \<le> b/c) =
(if 0 < c then a*c \<le> b
else if c < 0 then b \<le> a*c
else a \<le> (0::'a::{ordered_field,division_by_zero}))"
apply (case_tac "c=0", simp)
apply (force simp add: pos_le_divide_eq neg_le_divide_eq linorder_neq_iff)
done
lemma pos_divide_le_eq: "0 < (c::'a::ordered_field) ==> (b/c \<le> a) = (b \<le> a*c)"
proof -
assume less: "0<c"
hence "(b/c \<le> a) = ((b/c)*c \<le> a*c)"
by (simp add: mult_le_cancel_right order_less_not_sym [OF less])
also have "... = (b \<le> a*c)"
by (simp add: order_less_imp_not_eq2 [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma neg_divide_le_eq: "c < (0::'a::ordered_field) ==> (b/c \<le> a) = (a*c \<le> b)"
proof -
assume less: "c<0"
hence "(b/c \<le> a) = (a*c \<le> (b/c)*c)"
by (simp add: mult_le_cancel_right order_less_not_sym [OF less])
also have "... = (a*c \<le> b)"
by (simp add: order_less_imp_not_eq [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma divide_le_eq:
"(b/c \<le> a) =
(if 0 < c then b \<le> a*c
else if c < 0 then a*c \<le> b
else 0 \<le> (a::'a::{ordered_field,division_by_zero}))"
apply (case_tac "c=0", simp)
apply (force simp add: pos_divide_le_eq neg_divide_le_eq linorder_neq_iff)
done
lemma pos_less_divide_eq:
"0 < (c::'a::ordered_field) ==> (a < b/c) = (a*c < b)"
proof -
assume less: "0<c"
hence "(a < b/c) = (a*c < (b/c)*c)"
by (simp add: mult_less_cancel_right order_less_not_sym [OF less])
also have "... = (a*c < b)"
by (simp add: order_less_imp_not_eq2 [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma neg_less_divide_eq:
"c < (0::'a::ordered_field) ==> (a < b/c) = (b < a*c)"
proof -
assume less: "c<0"
hence "(a < b/c) = ((b/c)*c < a*c)"
by (simp add: mult_less_cancel_right order_less_not_sym [OF less])
also have "... = (b < a*c)"
by (simp add: order_less_imp_not_eq [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma less_divide_eq:
"(a < b/c) =
(if 0 < c then a*c < b
else if c < 0 then b < a*c
else a < (0::'a::{ordered_field,division_by_zero}))"
apply (case_tac "c=0", simp)
apply (force simp add: pos_less_divide_eq neg_less_divide_eq linorder_neq_iff)
done
lemma pos_divide_less_eq:
"0 < (c::'a::ordered_field) ==> (b/c < a) = (b < a*c)"
proof -
assume less: "0<c"
hence "(b/c < a) = ((b/c)*c < a*c)"
by (simp add: mult_less_cancel_right order_less_not_sym [OF less])
also have "... = (b < a*c)"
by (simp add: order_less_imp_not_eq2 [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma neg_divide_less_eq:
"c < (0::'a::ordered_field) ==> (b/c < a) = (a*c < b)"
proof -
assume less: "c<0"
hence "(b/c < a) = (a*c < (b/c)*c)"
by (simp add: mult_less_cancel_right order_less_not_sym [OF less])
also have "... = (a*c < b)"
by (simp add: order_less_imp_not_eq [OF less] divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma divide_less_eq:
"(b/c < a) =
(if 0 < c then b < a*c
else if c < 0 then a*c < b
else 0 < (a::'a::{ordered_field,division_by_zero}))"
apply (case_tac "c=0", simp)
apply (force simp add: pos_divide_less_eq neg_divide_less_eq linorder_neq_iff)
done
lemma nonzero_eq_divide_eq: "c\<noteq>0 ==> ((a::'a::field) = b/c) = (a*c = b)"
proof -
assume [simp]: "c\<noteq>0"
have "(a = b/c) = (a*c = (b/c)*c)"
by (simp add: field_mult_cancel_right)
also have "... = (a*c = b)"
by (simp add: divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma eq_divide_eq:
"((a::'a::{field,division_by_zero}) = b/c) = (if c\<noteq>0 then a*c = b else a=0)"
by (simp add: nonzero_eq_divide_eq)
lemma nonzero_divide_eq_eq: "c\<noteq>0 ==> (b/c = (a::'a::field)) = (b = a*c)"
proof -
assume [simp]: "c\<noteq>0"
have "(b/c = a) = ((b/c)*c = a*c)"
by (simp add: field_mult_cancel_right)
also have "... = (b = a*c)"
by (simp add: divide_inverse mult_assoc)
finally show ?thesis .
qed
lemma divide_eq_eq:
"(b/c = (a::'a::{field,division_by_zero})) = (if c\<noteq>0 then b = a*c else a=0)"
by (force simp add: nonzero_divide_eq_eq)
subsection{*Cancellation Laws for Division*}
lemma divide_cancel_right [simp]:
"(a/c = b/c) = (c = 0 | a = (b::'a::{field,division_by_zero}))"
apply (case_tac "c=0", simp)
apply (simp add: divide_inverse field_mult_cancel_right)
done
lemma divide_cancel_left [simp]:
"(c/a = c/b) = (c = 0 | a = (b::'a::{field,division_by_zero}))"
apply (case_tac "c=0", simp)
apply (simp add: divide_inverse field_mult_cancel_left)
done
subsection {* Division and the Number One *}
text{*Simplify expressions equated with 1*}
lemma divide_eq_1_iff [simp]:
"(a/b = 1) = (b \<noteq> 0 & a = (b::'a::{field,division_by_zero}))"
apply (case_tac "b=0", simp)
apply (simp add: right_inverse_eq)
done
lemma one_eq_divide_iff [simp]:
"(1 = a/b) = (b \<noteq> 0 & a = (b::'a::{field,division_by_zero}))"
by (simp add: eq_commute [of 1])
lemma zero_eq_1_divide_iff [simp]:
"((0::'a::{ordered_field,division_by_zero}) = 1/a) = (a = 0)"
apply (case_tac "a=0", simp)
apply (auto simp add: nonzero_eq_divide_eq)
done
lemma one_divide_eq_0_iff [simp]:
"(1/a = (0::'a::{ordered_field,division_by_zero})) = (a = 0)"
apply (case_tac "a=0", simp)
apply (insert zero_neq_one [THEN not_sym])
apply (auto simp add: nonzero_divide_eq_eq)
done
text{*Simplify expressions such as @{text "0 < 1/x"} to @{text "0 < x"}*}
declare zero_less_divide_iff [of "1", simp]
declare divide_less_0_iff [of "1", simp]
declare zero_le_divide_iff [of "1", simp]
declare divide_le_0_iff [of "1", simp]
subsection {* Ordering Rules for Division *}
lemma divide_strict_right_mono:
"[|a < b; 0 < c|] ==> a / c < b / (c::'a::ordered_field)"
by (simp add: order_less_imp_not_eq2 divide_inverse mult_strict_right_mono
positive_imp_inverse_positive)
lemma divide_right_mono:
"[|a \<le> b; 0 \<le> c|] ==> a/c \<le> b/(c::'a::{ordered_field,division_by_zero})"
by (force simp add: divide_strict_right_mono order_le_less)
text{*The last premise ensures that @{term a} and @{term b}
have the same sign*}
lemma divide_strict_left_mono:
"[|b < a; 0 < c; 0 < a*b|] ==> c / a < c / (b::'a::ordered_field)"
by (force simp add: zero_less_mult_iff divide_inverse mult_strict_left_mono
order_less_imp_not_eq order_less_imp_not_eq2
less_imp_inverse_less less_imp_inverse_less_neg)
lemma divide_left_mono:
"[|b \<le> a; 0 \<le> c; 0 < a*b|] ==> c / a \<le> c / (b::'a::ordered_field)"
apply (subgoal_tac "a \<noteq> 0 & b \<noteq> 0")
prefer 2
apply (force simp add: zero_less_mult_iff order_less_imp_not_eq)
apply (case_tac "c=0", simp add: divide_inverse)
apply (force simp add: divide_strict_left_mono order_le_less)
done
lemma divide_strict_left_mono_neg:
"[|a < b; c < 0; 0 < a*b|] ==> c / a < c / (b::'a::ordered_field)"
apply (subgoal_tac "a \<noteq> 0 & b \<noteq> 0")
prefer 2
apply (force simp add: zero_less_mult_iff order_less_imp_not_eq)
apply (drule divide_strict_left_mono [of _ _ "-c"])
apply (simp_all add: mult_commute nonzero_minus_divide_left [symmetric])
done
lemma divide_strict_right_mono_neg:
"[|b < a; c < 0|] ==> a / c < b / (c::'a::ordered_field)"
apply (drule divide_strict_right_mono [of _ _ "-c"], simp)
apply (simp add: order_less_imp_not_eq nonzero_minus_divide_right [symmetric])
done
subsection {* Ordered Fields are Dense *}
lemma less_add_one: "a < (a+1::'a::ordered_semiring)"
proof -
have "a+0 < (a+1::'a::ordered_semiring)"
by (blast intro: zero_less_one add_strict_left_mono)
thus ?thesis by simp
qed
lemma zero_less_two: "0 < (1+1::'a::ordered_semiring)"
by (blast intro: order_less_trans zero_less_one less_add_one)
lemma less_half_sum: "a < b ==> a < (a+b) / (1+1::'a::ordered_field)"
by (simp add: zero_less_two pos_less_divide_eq right_distrib)
lemma gt_half_sum: "a < b ==> (a+b)/(1+1::'a::ordered_field) < b"
by (simp add: zero_less_two pos_divide_less_eq right_distrib)
lemma dense: "a < b ==> \<exists>r::'a::ordered_field. a < r & r < b"
by (blast intro!: less_half_sum gt_half_sum)
subsection {* Absolute Value *}
lemma abs_zero [simp]: "abs 0 = (0::'a::ordered_ring)"
by (simp add: abs_if)
lemma abs_one [simp]: "abs 1 = (1::'a::ordered_ring)"
by (simp add: abs_if zero_less_one [THEN order_less_not_sym])
lemma abs_mult: "abs (a * b) = abs a * abs (b::'a::ordered_ring)"
apply (case_tac "a=0 | b=0", force)
apply (auto elim: order_less_asym
simp add: abs_if mult_less_0_iff linorder_neq_iff
minus_mult_left [symmetric] minus_mult_right [symmetric])
done
lemma abs_mult_self: "abs a * abs a = a * (a::'a::ordered_ring)"
by (simp add: abs_if)
lemma abs_eq_0 [simp]: "(abs a = 0) = (a = (0::'a::ordered_ring))"
by (simp add: abs_if)
lemma zero_less_abs_iff [simp]: "(0 < abs a) = (a \<noteq> (0::'a::ordered_ring))"
by (simp add: abs_if linorder_neq_iff)
lemma abs_not_less_zero [simp]: "~ abs a < (0::'a::ordered_ring)"
apply (simp add: abs_if)
by (simp add: abs_if order_less_not_sym [of a 0])
lemma abs_le_zero_iff [simp]: "(abs a \<le> (0::'a::ordered_ring)) = (a = 0)"
by (simp add: order_le_less)
lemma abs_minus_cancel [simp]: "abs (-a) = abs(a::'a::ordered_ring)"
apply (auto simp add: abs_if linorder_not_less order_less_not_sym [of 0 a])
apply (drule order_antisym, assumption, simp)
done
lemma abs_ge_zero [simp]: "(0::'a::ordered_ring) \<le> abs a"
apply (simp add: abs_if order_less_imp_le)
apply (simp add: linorder_not_less)
done
lemma abs_idempotent [simp]: "abs (abs a) = abs (a::'a::ordered_ring)"
by (force elim: order_less_asym simp add: abs_if)
lemma abs_zero_iff [simp]: "(abs a = 0) = (a = (0::'a::ordered_ring))"
by (simp add: abs_if)
lemma abs_ge_self: "a \<le> abs (a::'a::ordered_ring)"
apply (simp add: abs_if)
apply (simp add: order_less_imp_le order_trans [of _ 0])
done
lemma abs_ge_minus_self: "-a \<le> abs (a::'a::ordered_ring)"
by (insert abs_ge_self [of "-a"], simp)
lemma nonzero_abs_inverse:
"a \<noteq> 0 ==> abs (inverse (a::'a::ordered_field)) = inverse (abs a)"
apply (auto simp add: linorder_neq_iff abs_if nonzero_inverse_minus_eq
negative_imp_inverse_negative)
apply (blast intro: positive_imp_inverse_positive elim: order_less_asym)
done
lemma abs_inverse [simp]:
"abs (inverse (a::'a::{ordered_field,division_by_zero})) =
inverse (abs a)"
apply (case_tac "a=0", simp)
apply (simp add: nonzero_abs_inverse)
done
lemma nonzero_abs_divide:
"b \<noteq> 0 ==> abs (a / (b::'a::ordered_field)) = abs a / abs b"
by (simp add: divide_inverse abs_mult nonzero_abs_inverse)
lemma abs_divide:
"abs (a / (b::'a::{ordered_field,division_by_zero})) = abs a / abs b"
apply (case_tac "b=0", simp)
apply (simp add: nonzero_abs_divide)
done
lemma abs_leI: "[|a \<le> b; -a \<le> b|] ==> abs a \<le> (b::'a::ordered_ring)"
by (simp add: abs_if)
lemma le_minus_self_iff: "(a \<le> -a) = (a \<le> (0::'a::ordered_ring))"
proof
assume ale: "a \<le> -a"
show "a\<le>0"
apply (rule classical)
apply (simp add: linorder_not_le)
apply (blast intro: ale order_trans order_less_imp_le
neg_0_le_iff_le [THEN iffD1])
done
next
assume "a\<le>0"
hence "0 \<le> -a" by (simp only: neg_0_le_iff_le)
thus "a \<le> -a" by (blast intro: prems order_trans)
qed
lemma minus_le_self_iff: "(-a \<le> a) = (0 \<le> (a::'a::ordered_ring))"
by (insert le_minus_self_iff [of "-a"], simp)
lemma eq_minus_self_iff: "(a = -a) = (a = (0::'a::ordered_ring))"
by (force simp add: order_eq_iff le_minus_self_iff minus_le_self_iff)
lemma less_minus_self_iff: "(a < -a) = (a < (0::'a::ordered_ring))"
by (simp add: order_less_le le_minus_self_iff eq_minus_self_iff)
lemma abs_le_D1: "abs a \<le> b ==> a \<le> (b::'a::ordered_ring)"
apply (simp add: abs_if split: split_if_asm)
apply (rule order_trans [of _ "-a"])
apply (simp add: less_minus_self_iff order_less_imp_le, assumption)
done
lemma abs_le_D2: "abs a \<le> b ==> -a \<le> (b::'a::ordered_ring)"
by (insert abs_le_D1 [of "-a"], simp)
lemma abs_le_iff: "(abs a \<le> b) = (a \<le> b & -a \<le> (b::'a::ordered_ring))"
by (blast intro: abs_leI dest: abs_le_D1 abs_le_D2)
lemma abs_less_iff: "(abs a < b) = (a < b & -a < (b::'a::ordered_ring))"
apply (simp add: order_less_le abs_le_iff)
apply (auto simp add: abs_if minus_le_self_iff eq_minus_self_iff)
apply (simp add: le_minus_self_iff linorder_neq_iff)
done
(*
apply (simp add: order_less_le abs_le_iff)
apply (auto simp add: abs_if minus_le_self_iff eq_minus_self_iff)
apply (simp add: linorder_not_less [symmetric])
apply (simp add: le_minus_self_iff linorder_neq_iff)
apply (simp add: linorder_not_less [symmetric])
done
*)
lemma abs_triangle_ineq: "abs (a+b) \<le> abs a + abs (b::'a::ordered_ring)"
by (force simp add: abs_le_iff abs_ge_self abs_ge_minus_self add_mono)
lemma abs_diff_triangle_ineq:
"\<bar>(a::'a::ordered_ring) + b - (c+d)\<bar> \<le> \<bar>a-c\<bar> + \<bar>b-d\<bar>"
proof -
have "\<bar>a + b - (c+d)\<bar> = \<bar>(a-c) + (b-d)\<bar>" by (simp add: diff_minus add_ac)
also have "... \<le> \<bar>a-c\<bar> + \<bar>b-d\<bar>" by (rule abs_triangle_ineq)
finally show ?thesis .
qed
lemma abs_mult_less:
"[| abs a < c; abs b < d |] ==> abs a * abs b < c*(d::'a::ordered_ring)"
proof -
assume ac: "abs a < c"
hence cpos: "0<c" by (blast intro: order_le_less_trans abs_ge_zero)
assume "abs b < d"
thus ?thesis by (simp add: ac cpos mult_strict_mono)
qed
text{*Moving this up spoils many proofs using @{text mult_le_cancel_right}*}
declare times_divide_eq_left [simp]
ML
{*
val add_assoc = thm"add_assoc";
val add_commute = thm"add_commute";
val mult_assoc = thm"mult_assoc";
val mult_commute = thm"mult_commute";
val zero_neq_one = thm"zero_neq_one";
val diff_minus = thm"diff_minus";
val abs_if = thm"abs_if";
val divide_inverse = thm"divide_inverse";
val inverse_zero = thm"inverse_zero";
val divide_zero = thm"divide_zero";
val add_0 = thm"add_0";
val add_0_right = thm"add_0_right";
val add_zero_left = thm"add_0";
val add_zero_right = thm"add_0_right";
val add_left_commute = thm"add_left_commute";
val left_minus = thm"left_minus";
val right_minus = thm"right_minus";
val right_minus_eq = thm"right_minus_eq";
val add_left_cancel = thm"add_left_cancel";
val add_right_cancel = thm"add_right_cancel";
val minus_minus = thm"minus_minus";
val equals_zero_I = thm"equals_zero_I";
val minus_zero = thm"minus_zero";
val diff_self = thm"diff_self";
val diff_0 = thm"diff_0";
val diff_0_right = thm"diff_0_right";
val diff_minus_eq_add = thm"diff_minus_eq_add";
val neg_equal_iff_equal = thm"neg_equal_iff_equal";
val neg_equal_0_iff_equal = thm"neg_equal_0_iff_equal";
val neg_0_equal_iff_equal = thm"neg_0_equal_iff_equal";
val equation_minus_iff = thm"equation_minus_iff";
val minus_equation_iff = thm"minus_equation_iff";
val mult_1 = thm"mult_1";
val mult_1_right = thm"mult_1_right";
val mult_left_commute = thm"mult_left_commute";
val mult_zero_left = thm"mult_zero_left";
val mult_zero_right = thm"mult_zero_right";
val left_distrib = thm "left_distrib";
val right_distrib = thm"right_distrib";
val combine_common_factor = thm"combine_common_factor";
val minus_add_distrib = thm"minus_add_distrib";
val minus_mult_left = thm"minus_mult_left";
val minus_mult_right = thm"minus_mult_right";
val minus_mult_minus = thm"minus_mult_minus";
val minus_mult_commute = thm"minus_mult_commute";
val right_diff_distrib = thm"right_diff_distrib";
val left_diff_distrib = thm"left_diff_distrib";
val minus_diff_eq = thm"minus_diff_eq";
val add_left_mono = thm"add_left_mono";
val add_right_mono = thm"add_right_mono";
val add_mono = thm"add_mono";
val add_strict_left_mono = thm"add_strict_left_mono";
val add_strict_right_mono = thm"add_strict_right_mono";
val add_strict_mono = thm"add_strict_mono";
val add_less_le_mono = thm"add_less_le_mono";
val add_le_less_mono = thm"add_le_less_mono";
val add_less_imp_less_left = thm"add_less_imp_less_left";
val add_less_imp_less_right = thm"add_less_imp_less_right";
val add_less_cancel_left = thm"add_less_cancel_left";
val add_less_cancel_right = thm"add_less_cancel_right";
val add_le_cancel_left = thm"add_le_cancel_left";
val add_le_cancel_right = thm"add_le_cancel_right";
val add_le_imp_le_left = thm"add_le_imp_le_left";
val add_le_imp_le_right = thm"add_le_imp_le_right";
val le_imp_neg_le = thm"le_imp_neg_le";
val neg_le_iff_le = thm"neg_le_iff_le";
val neg_le_0_iff_le = thm"neg_le_0_iff_le";
val neg_0_le_iff_le = thm"neg_0_le_iff_le";
val neg_less_iff_less = thm"neg_less_iff_less";
val neg_less_0_iff_less = thm"neg_less_0_iff_less";
val neg_0_less_iff_less = thm"neg_0_less_iff_less";
val less_minus_iff = thm"less_minus_iff";
val minus_less_iff = thm"minus_less_iff";
val le_minus_iff = thm"le_minus_iff";
val minus_le_iff = thm"minus_le_iff";
val add_diff_eq = thm"add_diff_eq";
val diff_add_eq = thm"diff_add_eq";
val diff_eq_eq = thm"diff_eq_eq";
val eq_diff_eq = thm"eq_diff_eq";
val diff_diff_eq = thm"diff_diff_eq";
val diff_diff_eq2 = thm"diff_diff_eq2";
val less_iff_diff_less_0 = thm"less_iff_diff_less_0";
val diff_less_eq = thm"diff_less_eq";
val less_diff_eq = thm"less_diff_eq";
val diff_le_eq = thm"diff_le_eq";
val le_diff_eq = thm"le_diff_eq";
val eq_iff_diff_eq_0 = thm"eq_iff_diff_eq_0";
val le_iff_diff_le_0 = thm"le_iff_diff_le_0";
val eq_add_iff1 = thm"eq_add_iff1";
val eq_add_iff2 = thm"eq_add_iff2";
val less_add_iff1 = thm"less_add_iff1";
val less_add_iff2 = thm"less_add_iff2";
val le_add_iff1 = thm"le_add_iff1";
val le_add_iff2 = thm"le_add_iff2";
val mult_strict_left_mono = thm"mult_strict_left_mono";
val mult_strict_right_mono = thm"mult_strict_right_mono";
val mult_left_mono = thm"mult_left_mono";
val mult_right_mono = thm"mult_right_mono";
val mult_left_le_imp_le = thm"mult_left_le_imp_le";
val mult_right_le_imp_le = thm"mult_right_le_imp_le";
val mult_left_less_imp_less = thm"mult_left_less_imp_less";
val mult_right_less_imp_less = thm"mult_right_less_imp_less";
val mult_strict_left_mono_neg = thm"mult_strict_left_mono_neg";
val mult_strict_right_mono_neg = thm"mult_strict_right_mono_neg";
val mult_pos = thm"mult_pos";
val mult_pos_neg = thm"mult_pos_neg";
val mult_neg = thm"mult_neg";
val zero_less_mult_pos = thm"zero_less_mult_pos";
val zero_less_mult_iff = thm"zero_less_mult_iff";
val mult_eq_0_iff = thm"mult_eq_0_iff";
val zero_le_mult_iff = thm"zero_le_mult_iff";
val mult_less_0_iff = thm"mult_less_0_iff";
val mult_le_0_iff = thm"mult_le_0_iff";
val zero_le_square = thm"zero_le_square";
val zero_less_one = thm"zero_less_one";
val zero_le_one = thm"zero_le_one";
val not_one_less_zero = thm"not_one_less_zero";
val not_one_le_zero = thm"not_one_le_zero";
val mult_left_mono_neg = thm"mult_left_mono_neg";
val mult_right_mono_neg = thm"mult_right_mono_neg";
val mult_strict_mono = thm"mult_strict_mono";
val mult_strict_mono' = thm"mult_strict_mono'";
val mult_mono = thm"mult_mono";
val mult_less_cancel_right = thm"mult_less_cancel_right";
val mult_less_cancel_left = thm"mult_less_cancel_left";
val mult_le_cancel_right = thm"mult_le_cancel_right";
val mult_le_cancel_left = thm"mult_le_cancel_left";
val mult_less_imp_less_left = thm"mult_less_imp_less_left";
val mult_less_imp_less_right = thm"mult_less_imp_less_right";
val mult_cancel_right = thm"mult_cancel_right";
val mult_cancel_left = thm"mult_cancel_left";
val left_inverse = thm "left_inverse";
val right_inverse = thm"right_inverse";
val right_inverse_eq = thm"right_inverse_eq";
val nonzero_inverse_eq_divide = thm"nonzero_inverse_eq_divide";
val divide_self = thm"divide_self";
val inverse_divide = thm"inverse_divide";
val divide_zero_left = thm"divide_zero_left";
val inverse_eq_divide = thm"inverse_eq_divide";
val add_divide_distrib = thm"add_divide_distrib";
val field_mult_eq_0_iff = thm"field_mult_eq_0_iff";
val field_mult_cancel_right = thm"field_mult_cancel_right";
val field_mult_cancel_left = thm"field_mult_cancel_left";
val nonzero_imp_inverse_nonzero = thm"nonzero_imp_inverse_nonzero";
val inverse_zero_imp_zero = thm"inverse_zero_imp_zero";
val inverse_nonzero_imp_nonzero = thm"inverse_nonzero_imp_nonzero";
val inverse_nonzero_iff_nonzero = thm"inverse_nonzero_iff_nonzero";
val nonzero_inverse_minus_eq = thm"nonzero_inverse_minus_eq";
val inverse_minus_eq = thm"inverse_minus_eq";
val nonzero_inverse_eq_imp_eq = thm"nonzero_inverse_eq_imp_eq";
val inverse_eq_imp_eq = thm"inverse_eq_imp_eq";
val inverse_eq_iff_eq = thm"inverse_eq_iff_eq";
val nonzero_inverse_inverse_eq = thm"nonzero_inverse_inverse_eq";
val inverse_inverse_eq = thm"inverse_inverse_eq";
val inverse_1 = thm"inverse_1";
val nonzero_inverse_mult_distrib = thm"nonzero_inverse_mult_distrib";
val inverse_mult_distrib = thm"inverse_mult_distrib";
val inverse_add = thm"inverse_add";
val nonzero_mult_divide_cancel_left = thm"nonzero_mult_divide_cancel_left";
val mult_divide_cancel_left = thm"mult_divide_cancel_left";
val nonzero_mult_divide_cancel_right = thm"nonzero_mult_divide_cancel_right";
val mult_divide_cancel_right = thm"mult_divide_cancel_right";
val mult_divide_cancel_eq_if = thm"mult_divide_cancel_eq_if";
val divide_1 = thm"divide_1";
val times_divide_eq_right = thm"times_divide_eq_right";
val times_divide_eq_left = thm"times_divide_eq_left";
val divide_divide_eq_right = thm"divide_divide_eq_right";
val divide_divide_eq_left = thm"divide_divide_eq_left";
val nonzero_minus_divide_left = thm"nonzero_minus_divide_left";
val nonzero_minus_divide_right = thm"nonzero_minus_divide_right";
val nonzero_minus_divide_divide = thm"nonzero_minus_divide_divide";
val minus_divide_left = thm"minus_divide_left";
val minus_divide_right = thm"minus_divide_right";
val minus_divide_divide = thm"minus_divide_divide";
val positive_imp_inverse_positive = thm"positive_imp_inverse_positive";
val negative_imp_inverse_negative = thm"negative_imp_inverse_negative";
val inverse_le_imp_le = thm"inverse_le_imp_le";
val inverse_positive_imp_positive = thm"inverse_positive_imp_positive";
val inverse_positive_iff_positive = thm"inverse_positive_iff_positive";
val inverse_negative_imp_negative = thm"inverse_negative_imp_negative";
val inverse_negative_iff_negative = thm"inverse_negative_iff_negative";
val inverse_nonnegative_iff_nonnegative = thm"inverse_nonnegative_iff_nonnegative";
val inverse_nonpositive_iff_nonpositive = thm"inverse_nonpositive_iff_nonpositive";
val less_imp_inverse_less = thm"less_imp_inverse_less";
val inverse_less_imp_less = thm"inverse_less_imp_less";
val inverse_less_iff_less = thm"inverse_less_iff_less";
val le_imp_inverse_le = thm"le_imp_inverse_le";
val inverse_le_iff_le = thm"inverse_le_iff_le";
val inverse_le_imp_le_neg = thm"inverse_le_imp_le_neg";
val less_imp_inverse_less_neg = thm"less_imp_inverse_less_neg";
val inverse_less_imp_less_neg = thm"inverse_less_imp_less_neg";
val inverse_less_iff_less_neg = thm"inverse_less_iff_less_neg";
val le_imp_inverse_le_neg = thm"le_imp_inverse_le_neg";
val inverse_le_iff_le_neg = thm"inverse_le_iff_le_neg";
val zero_less_divide_iff = thm"zero_less_divide_iff";
val divide_less_0_iff = thm"divide_less_0_iff";
val zero_le_divide_iff = thm"zero_le_divide_iff";
val divide_le_0_iff = thm"divide_le_0_iff";
val divide_eq_0_iff = thm"divide_eq_0_iff";
val pos_le_divide_eq = thm"pos_le_divide_eq";
val neg_le_divide_eq = thm"neg_le_divide_eq";
val le_divide_eq = thm"le_divide_eq";
val pos_divide_le_eq = thm"pos_divide_le_eq";
val neg_divide_le_eq = thm"neg_divide_le_eq";
val divide_le_eq = thm"divide_le_eq";
val pos_less_divide_eq = thm"pos_less_divide_eq";
val neg_less_divide_eq = thm"neg_less_divide_eq";
val less_divide_eq = thm"less_divide_eq";
val pos_divide_less_eq = thm"pos_divide_less_eq";
val neg_divide_less_eq = thm"neg_divide_less_eq";
val divide_less_eq = thm"divide_less_eq";
val nonzero_eq_divide_eq = thm"nonzero_eq_divide_eq";
val eq_divide_eq = thm"eq_divide_eq";
val nonzero_divide_eq_eq = thm"nonzero_divide_eq_eq";
val divide_eq_eq = thm"divide_eq_eq";
val divide_cancel_right = thm"divide_cancel_right";
val divide_cancel_left = thm"divide_cancel_left";
val divide_strict_right_mono = thm"divide_strict_right_mono";
val divide_right_mono = thm"divide_right_mono";
val divide_strict_left_mono = thm"divide_strict_left_mono";
val divide_left_mono = thm"divide_left_mono";
val divide_strict_left_mono_neg = thm"divide_strict_left_mono_neg";
val divide_strict_right_mono_neg = thm"divide_strict_right_mono_neg";
val zero_less_two = thm"zero_less_two";
val less_half_sum = thm"less_half_sum";
val gt_half_sum = thm"gt_half_sum";
val dense = thm"dense";
val abs_zero = thm"abs_zero";
val abs_one = thm"abs_one";
val abs_mult = thm"abs_mult";
val abs_mult_self = thm"abs_mult_self";
val abs_eq_0 = thm"abs_eq_0";
val zero_less_abs_iff = thm"zero_less_abs_iff";
val abs_not_less_zero = thm"abs_not_less_zero";
val abs_le_zero_iff = thm"abs_le_zero_iff";
val abs_minus_cancel = thm"abs_minus_cancel";
val abs_ge_zero = thm"abs_ge_zero";
val abs_idempotent = thm"abs_idempotent";
val abs_zero_iff = thm"abs_zero_iff";
val abs_ge_self = thm"abs_ge_self";
val abs_ge_minus_self = thm"abs_ge_minus_self";
val nonzero_abs_inverse = thm"nonzero_abs_inverse";
val abs_inverse = thm"abs_inverse";
val nonzero_abs_divide = thm"nonzero_abs_divide";
val abs_divide = thm"abs_divide";
val abs_leI = thm"abs_leI";
val le_minus_self_iff = thm"le_minus_self_iff";
val minus_le_self_iff = thm"minus_le_self_iff";
val eq_minus_self_iff = thm"eq_minus_self_iff";
val less_minus_self_iff = thm"less_minus_self_iff";
val abs_le_D1 = thm"abs_le_D1";
val abs_le_D2 = thm"abs_le_D2";
val abs_le_iff = thm"abs_le_iff";
val abs_less_iff = thm"abs_less_iff";
val abs_triangle_ineq = thm"abs_triangle_ineq";
val abs_mult_less = thm"abs_mult_less";
val compare_rls = thms"compare_rls";
*}
end