src/HOL/Int.thy
author huffman
Wed Apr 29 17:15:01 2009 -0700 (2009-04-29)
changeset 31024 0fdf666e08bf
parent 31021 53642251a04f
child 31065 d87465cbfc9e
permissions -rw-r--r--
reimplement reorientation simproc using theory data
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(*  Title:      Int.thy
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    Author:     Lawrence C Paulson, Cambridge University Computer Laboratory
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                Tobias Nipkow, Florian Haftmann, TU Muenchen
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    Copyright   1994  University of Cambridge
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*)
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header {* The Integers as Equivalence Classes over Pairs of Natural Numbers *} 
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theory Int
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imports Equiv_Relations Nat Wellfounded
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uses
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  ("Tools/numeral.ML")
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  ("Tools/numeral_syntax.ML")
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  "~~/src/Provers/Arith/assoc_fold.ML"
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  "~~/src/Provers/Arith/cancel_numerals.ML"
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  "~~/src/Provers/Arith/combine_numerals.ML"
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  ("Tools/int_arith.ML")
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begin
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subsection {* The equivalence relation underlying the integers *}
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definition intrel :: "((nat \<times> nat) \<times> (nat \<times> nat)) set" where
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  [code del]: "intrel = {((x, y), (u, v)) | x y u v. x + v = u +y }"
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typedef (Integ)
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  int = "UNIV//intrel"
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  by (auto simp add: quotient_def)
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instantiation int :: "{zero, one, plus, minus, uminus, times, ord, abs, sgn}"
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begin
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definition
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  Zero_int_def [code del]: "0 = Abs_Integ (intrel `` {(0, 0)})"
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definition
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  One_int_def [code del]: "1 = Abs_Integ (intrel `` {(1, 0)})"
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definition
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  add_int_def [code del]: "z + w = Abs_Integ
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    (\<Union>(x, y) \<in> Rep_Integ z. \<Union>(u, v) \<in> Rep_Integ w.
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      intrel `` {(x + u, y + v)})"
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definition
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  minus_int_def [code del]:
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    "- z = Abs_Integ (\<Union>(x, y) \<in> Rep_Integ z. intrel `` {(y, x)})"
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definition
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  diff_int_def [code del]:  "z - w = z + (-w \<Colon> int)"
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definition
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  mult_int_def [code del]: "z * w = Abs_Integ
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    (\<Union>(x, y) \<in> Rep_Integ z. \<Union>(u,v ) \<in> Rep_Integ w.
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      intrel `` {(x*u + y*v, x*v + y*u)})"
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definition
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  le_int_def [code del]:
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   "z \<le> w \<longleftrightarrow> (\<exists>x y u v. x+v \<le> u+y \<and> (x, y) \<in> Rep_Integ z \<and> (u, v) \<in> Rep_Integ w)"
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definition
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  less_int_def [code del]: "(z\<Colon>int) < w \<longleftrightarrow> z \<le> w \<and> z \<noteq> w"
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definition
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  zabs_def: "\<bar>i\<Colon>int\<bar> = (if i < 0 then - i else i)"
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definition
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  zsgn_def: "sgn (i\<Colon>int) = (if i=0 then 0 else if 0<i then 1 else - 1)"
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instance ..
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end
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subsection{*Construction of the Integers*}
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lemma intrel_iff [simp]: "(((x,y),(u,v)) \<in> intrel) = (x+v = u+y)"
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by (simp add: intrel_def)
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lemma equiv_intrel: "equiv UNIV intrel"
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by (simp add: intrel_def equiv_def refl_on_def sym_def trans_def)
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text{*Reduces equality of equivalence classes to the @{term intrel} relation:
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  @{term "(intrel `` {x} = intrel `` {y}) = ((x,y) \<in> intrel)"} *}
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lemmas equiv_intrel_iff [simp] = eq_equiv_class_iff [OF equiv_intrel UNIV_I UNIV_I]
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text{*All equivalence classes belong to set of representatives*}
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lemma [simp]: "intrel``{(x,y)} \<in> Integ"
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by (auto simp add: Integ_def intrel_def quotient_def)
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text{*Reduces equality on abstractions to equality on representatives:
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  @{prop "\<lbrakk>x \<in> Integ; y \<in> Integ\<rbrakk> \<Longrightarrow> (Abs_Integ x = Abs_Integ y) = (x=y)"} *}
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declare Abs_Integ_inject [simp,noatp]  Abs_Integ_inverse [simp,noatp]
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text{*Case analysis on the representation of an integer as an equivalence
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      class of pairs of naturals.*}
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lemma eq_Abs_Integ [case_names Abs_Integ, cases type: int]:
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     "(!!x y. z = Abs_Integ(intrel``{(x,y)}) ==> P) ==> P"
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apply (rule Abs_Integ_cases [of z]) 
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apply (auto simp add: Integ_def quotient_def) 
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done
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subsection {* Arithmetic Operations *}
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lemma minus: "- Abs_Integ(intrel``{(x,y)}) = Abs_Integ(intrel `` {(y,x)})"
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proof -
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  have "(\<lambda>(x,y). intrel``{(y,x)}) respects intrel"
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    by (simp add: congruent_def) 
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  thus ?thesis
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    by (simp add: minus_int_def UN_equiv_class [OF equiv_intrel])
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qed
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lemma add:
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     "Abs_Integ (intrel``{(x,y)}) + Abs_Integ (intrel``{(u,v)}) =
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      Abs_Integ (intrel``{(x+u, y+v)})"
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proof -
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  have "(\<lambda>z w. (\<lambda>(x,y). (\<lambda>(u,v). intrel `` {(x+u, y+v)}) w) z) 
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        respects2 intrel"
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    by (simp add: congruent2_def)
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  thus ?thesis
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    by (simp add: add_int_def UN_UN_split_split_eq
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                  UN_equiv_class2 [OF equiv_intrel equiv_intrel])
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qed
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text{*Congruence property for multiplication*}
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lemma mult_congruent2:
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     "(%p1 p2. (%(x,y). (%(u,v). intrel``{(x*u + y*v, x*v + y*u)}) p2) p1)
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      respects2 intrel"
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apply (rule equiv_intrel [THEN congruent2_commuteI])
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 apply (force simp add: mult_ac, clarify) 
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apply (simp add: congruent_def mult_ac)  
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apply (rename_tac u v w x y z)
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apply (subgoal_tac "u*y + x*y = w*y + v*y  &  u*z + x*z = w*z + v*z")
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apply (simp add: mult_ac)
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apply (simp add: add_mult_distrib [symmetric])
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done
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lemma mult:
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     "Abs_Integ((intrel``{(x,y)})) * Abs_Integ((intrel``{(u,v)})) =
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      Abs_Integ(intrel `` {(x*u + y*v, x*v + y*u)})"
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by (simp add: mult_int_def UN_UN_split_split_eq mult_congruent2
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              UN_equiv_class2 [OF equiv_intrel equiv_intrel])
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text{*The integers form a @{text comm_ring_1}*}
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instance int :: comm_ring_1
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proof
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  fix i j k :: int
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  show "(i + j) + k = i + (j + k)"
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    by (cases i, cases j, cases k) (simp add: add add_assoc)
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  show "i + j = j + i" 
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    by (cases i, cases j) (simp add: add_ac add)
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  show "0 + i = i"
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    by (cases i) (simp add: Zero_int_def add)
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  show "- i + i = 0"
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    by (cases i) (simp add: Zero_int_def minus add)
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  show "i - j = i + - j"
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    by (simp add: diff_int_def)
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  show "(i * j) * k = i * (j * k)"
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    by (cases i, cases j, cases k) (simp add: mult algebra_simps)
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  show "i * j = j * i"
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    by (cases i, cases j) (simp add: mult algebra_simps)
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  show "1 * i = i"
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    by (cases i) (simp add: One_int_def mult)
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  show "(i + j) * k = i * k + j * k"
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    by (cases i, cases j, cases k) (simp add: add mult algebra_simps)
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  show "0 \<noteq> (1::int)"
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    by (simp add: Zero_int_def One_int_def)
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qed
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lemma int_def: "of_nat m = Abs_Integ (intrel `` {(m, 0)})"
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by (induct m, simp_all add: Zero_int_def One_int_def add)
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subsection {* The @{text "\<le>"} Ordering *}
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lemma le:
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  "(Abs_Integ(intrel``{(x,y)}) \<le> Abs_Integ(intrel``{(u,v)})) = (x+v \<le> u+y)"
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by (force simp add: le_int_def)
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lemma less:
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  "(Abs_Integ(intrel``{(x,y)}) < Abs_Integ(intrel``{(u,v)})) = (x+v < u+y)"
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by (simp add: less_int_def le order_less_le)
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instance int :: linorder
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proof
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  fix i j k :: int
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  show antisym: "i \<le> j \<Longrightarrow> j \<le> i \<Longrightarrow> i = j"
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    by (cases i, cases j) (simp add: le)
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  show "(i < j) = (i \<le> j \<and> \<not> j \<le> i)"
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    by (auto simp add: less_int_def dest: antisym) 
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  show "i \<le> i"
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    by (cases i) (simp add: le)
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  show "i \<le> j \<Longrightarrow> j \<le> k \<Longrightarrow> i \<le> k"
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    by (cases i, cases j, cases k) (simp add: le)
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  show "i \<le> j \<or> j \<le> i"
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    by (cases i, cases j) (simp add: le linorder_linear)
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qed
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instantiation int :: distrib_lattice
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begin
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definition
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  "(inf \<Colon> int \<Rightarrow> int \<Rightarrow> int) = min"
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definition
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  "(sup \<Colon> int \<Rightarrow> int \<Rightarrow> int) = max"
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instance
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  by intro_classes
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    (auto simp add: inf_int_def sup_int_def min_max.sup_inf_distrib1)
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end
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instance int :: pordered_cancel_ab_semigroup_add
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proof
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  fix i j k :: int
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  show "i \<le> j \<Longrightarrow> k + i \<le> k + j"
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    by (cases i, cases j, cases k) (simp add: le add)
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qed
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text{*Strict Monotonicity of Multiplication*}
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text{*strict, in 1st argument; proof is by induction on k>0*}
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lemma zmult_zless_mono2_lemma:
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     "(i::int)<j ==> 0<k ==> of_nat k * i < of_nat k * j"
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apply (induct "k", simp)
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apply (simp add: left_distrib)
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apply (case_tac "k=0")
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apply (simp_all add: add_strict_mono)
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done
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lemma zero_le_imp_eq_int: "(0::int) \<le> k ==> \<exists>n. k = of_nat n"
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apply (cases k)
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apply (auto simp add: le add int_def Zero_int_def)
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apply (rule_tac x="x-y" in exI, simp)
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done
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lemma zero_less_imp_eq_int: "(0::int) < k ==> \<exists>n>0. k = of_nat n"
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apply (cases k)
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apply (simp add: less int_def Zero_int_def)
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apply (rule_tac x="x-y" in exI, simp)
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done
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lemma zmult_zless_mono2: "[| i<j;  (0::int) < k |] ==> k*i < k*j"
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apply (drule zero_less_imp_eq_int)
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apply (auto simp add: zmult_zless_mono2_lemma)
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done
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text{*The integers form an ordered integral domain*}
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instance int :: ordered_idom
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proof
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  fix i j k :: int
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  show "i < j \<Longrightarrow> 0 < k \<Longrightarrow> k * i < k * j"
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    by (rule zmult_zless_mono2)
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  show "\<bar>i\<bar> = (if i < 0 then -i else i)"
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    by (simp only: zabs_def)
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  show "sgn (i\<Colon>int) = (if i=0 then 0 else if 0<i then 1 else - 1)"
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    by (simp only: zsgn_def)
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qed
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instance int :: lordered_ring
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proof  
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  fix k :: int
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  show "abs k = sup k (- k)"
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    by (auto simp add: sup_int_def zabs_def max_def less_minus_self_iff [symmetric])
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qed
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lemma zless_imp_add1_zle: "w < z \<Longrightarrow> w + (1\<Colon>int) \<le> z"
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apply (cases w, cases z) 
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apply (simp add: less le add One_int_def)
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done
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lemma zless_iff_Suc_zadd:
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  "(w \<Colon> int) < z \<longleftrightarrow> (\<exists>n. z = w + of_nat (Suc n))"
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apply (cases z, cases w)
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apply (auto simp add: less add int_def)
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apply (rename_tac a b c d) 
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apply (rule_tac x="a+d - Suc(c+b)" in exI) 
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apply arith
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done
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lemmas int_distrib =
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  left_distrib [of "z1::int" "z2" "w", standard]
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  right_distrib [of "w::int" "z1" "z2", standard]
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  left_diff_distrib [of "z1::int" "z2" "w", standard]
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  right_diff_distrib [of "w::int" "z1" "z2", standard]
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subsection {* Embedding of the Integers into any @{text ring_1}: @{text of_int}*}
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context ring_1
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begin
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definition of_int :: "int \<Rightarrow> 'a" where
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  [code del]: "of_int z = contents (\<Union>(i, j) \<in> Rep_Integ z. { of_nat i - of_nat j })"
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lemma of_int: "of_int (Abs_Integ (intrel `` {(i,j)})) = of_nat i - of_nat j"
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proof -
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  have "(\<lambda>(i,j). { of_nat i - (of_nat j :: 'a) }) respects intrel"
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    by (simp add: congruent_def algebra_simps of_nat_add [symmetric]
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            del: of_nat_add) 
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  thus ?thesis
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    by (simp add: of_int_def UN_equiv_class [OF equiv_intrel])
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qed
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lemma of_int_0 [simp]: "of_int 0 = 0"
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by (simp add: of_int Zero_int_def)
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lemma of_int_1 [simp]: "of_int 1 = 1"
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by (simp add: of_int One_int_def)
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lemma of_int_add [simp]: "of_int (w+z) = of_int w + of_int z"
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by (cases w, cases z, simp add: algebra_simps of_int add)
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lemma of_int_minus [simp]: "of_int (-z) = - (of_int z)"
nipkow@29667
   317
by (cases z, simp add: algebra_simps of_int minus)
haftmann@25919
   318
haftmann@25919
   319
lemma of_int_diff [simp]: "of_int (w - z) = of_int w - of_int z"
nipkow@29667
   320
by (simp add: OrderedGroup.diff_minus diff_minus)
haftmann@25919
   321
haftmann@25919
   322
lemma of_int_mult [simp]: "of_int (w*z) = of_int w * of_int z"
haftmann@25919
   323
apply (cases w, cases z)
nipkow@29667
   324
apply (simp add: algebra_simps of_int mult of_nat_mult)
haftmann@25919
   325
done
haftmann@25919
   326
haftmann@25919
   327
text{*Collapse nested embeddings*}
haftmann@25919
   328
lemma of_int_of_nat_eq [simp]: "of_int (of_nat n) = of_nat n"
nipkow@29667
   329
by (induct n) auto
haftmann@25919
   330
haftmann@31015
   331
lemma of_int_power:
haftmann@31015
   332
  "of_int (z ^ n) = of_int z ^ n"
haftmann@31015
   333
  by (induct n) simp_all
haftmann@31015
   334
haftmann@25919
   335
end
haftmann@25919
   336
haftmann@25919
   337
context ordered_idom
haftmann@25919
   338
begin
haftmann@25919
   339
haftmann@25919
   340
lemma of_int_le_iff [simp]:
haftmann@25919
   341
  "of_int w \<le> of_int z \<longleftrightarrow> w \<le> z"
nipkow@29667
   342
by (cases w, cases z, simp add: of_int le minus algebra_simps of_nat_add [symmetric] del: of_nat_add)
haftmann@25919
   343
haftmann@25919
   344
text{*Special cases where either operand is zero*}
haftmann@25919
   345
lemmas of_int_0_le_iff [simp] = of_int_le_iff [of 0, simplified]
haftmann@25919
   346
lemmas of_int_le_0_iff [simp] = of_int_le_iff [of _ 0, simplified]
haftmann@25919
   347
haftmann@25919
   348
lemma of_int_less_iff [simp]:
haftmann@25919
   349
  "of_int w < of_int z \<longleftrightarrow> w < z"
haftmann@25919
   350
  by (simp add: not_le [symmetric] linorder_not_le [symmetric])
haftmann@25919
   351
haftmann@25919
   352
text{*Special cases where either operand is zero*}
haftmann@25919
   353
lemmas of_int_0_less_iff [simp] = of_int_less_iff [of 0, simplified]
haftmann@25919
   354
lemmas of_int_less_0_iff [simp] = of_int_less_iff [of _ 0, simplified]
haftmann@25919
   355
haftmann@25919
   356
end
haftmann@25919
   357
haftmann@25919
   358
text{*Class for unital rings with characteristic zero.
haftmann@25919
   359
 Includes non-ordered rings like the complex numbers.*}
haftmann@25919
   360
class ring_char_0 = ring_1 + semiring_char_0
haftmann@25919
   361
begin
haftmann@25919
   362
haftmann@25919
   363
lemma of_int_eq_iff [simp]:
haftmann@25919
   364
   "of_int w = of_int z \<longleftrightarrow> w = z"
haftmann@25919
   365
apply (cases w, cases z, simp add: of_int)
haftmann@25919
   366
apply (simp only: diff_eq_eq diff_add_eq eq_diff_eq)
haftmann@25919
   367
apply (simp only: of_nat_add [symmetric] of_nat_eq_iff)
haftmann@25919
   368
done
haftmann@25919
   369
haftmann@25919
   370
text{*Special cases where either operand is zero*}
haftmann@25919
   371
lemmas of_int_0_eq_iff [simp] = of_int_eq_iff [of 0, simplified]
haftmann@25919
   372
lemmas of_int_eq_0_iff [simp] = of_int_eq_iff [of _ 0, simplified]
haftmann@25919
   373
haftmann@25919
   374
end
haftmann@25919
   375
haftmann@25919
   376
text{*Every @{text ordered_idom} has characteristic zero.*}
haftmann@25919
   377
subclass (in ordered_idom) ring_char_0 by intro_locales
haftmann@25919
   378
haftmann@25919
   379
lemma of_int_eq_id [simp]: "of_int = id"
haftmann@25919
   380
proof
haftmann@25919
   381
  fix z show "of_int z = id z"
haftmann@25919
   382
    by (cases z) (simp add: of_int add minus int_def diff_minus)
haftmann@25919
   383
qed
haftmann@25919
   384
haftmann@25919
   385
haftmann@25919
   386
subsection {* Magnitude of an Integer, as a Natural Number: @{text nat} *}
haftmann@25919
   387
haftmann@25919
   388
definition
haftmann@25919
   389
  nat :: "int \<Rightarrow> nat"
haftmann@25919
   390
where
haftmann@28562
   391
  [code del]: "nat z = contents (\<Union>(x, y) \<in> Rep_Integ z. {x-y})"
haftmann@25919
   392
haftmann@25919
   393
lemma nat: "nat (Abs_Integ (intrel``{(x,y)})) = x-y"
haftmann@25919
   394
proof -
haftmann@25919
   395
  have "(\<lambda>(x,y). {x-y}) respects intrel"
haftmann@25919
   396
    by (simp add: congruent_def) arith
haftmann@25919
   397
  thus ?thesis
haftmann@25919
   398
    by (simp add: nat_def UN_equiv_class [OF equiv_intrel])
haftmann@25919
   399
qed
haftmann@25919
   400
haftmann@25919
   401
lemma nat_int [simp]: "nat (of_nat n) = n"
haftmann@25919
   402
by (simp add: nat int_def)
haftmann@25919
   403
haftmann@25919
   404
lemma nat_zero [simp]: "nat 0 = 0"
haftmann@25919
   405
by (simp add: Zero_int_def nat)
haftmann@25919
   406
haftmann@25919
   407
lemma int_nat_eq [simp]: "of_nat (nat z) = (if 0 \<le> z then z else 0)"
haftmann@25919
   408
by (cases z, simp add: nat le int_def Zero_int_def)
haftmann@25919
   409
haftmann@25919
   410
corollary nat_0_le: "0 \<le> z ==> of_nat (nat z) = z"
haftmann@25919
   411
by simp
haftmann@25919
   412
haftmann@25919
   413
lemma nat_le_0 [simp]: "z \<le> 0 ==> nat z = 0"
haftmann@25919
   414
by (cases z, simp add: nat le Zero_int_def)
haftmann@25919
   415
haftmann@25919
   416
lemma nat_le_eq_zle: "0 < w | 0 \<le> z ==> (nat w \<le> nat z) = (w\<le>z)"
haftmann@25919
   417
apply (cases w, cases z) 
haftmann@25919
   418
apply (simp add: nat le linorder_not_le [symmetric] Zero_int_def, arith)
haftmann@25919
   419
done
haftmann@25919
   420
haftmann@25919
   421
text{*An alternative condition is @{term "0 \<le> w"} *}
haftmann@25919
   422
corollary nat_mono_iff: "0 < z ==> (nat w < nat z) = (w < z)"
haftmann@25919
   423
by (simp add: nat_le_eq_zle linorder_not_le [symmetric]) 
haftmann@25919
   424
haftmann@25919
   425
corollary nat_less_eq_zless: "0 \<le> w ==> (nat w < nat z) = (w<z)"
haftmann@25919
   426
by (simp add: nat_le_eq_zle linorder_not_le [symmetric]) 
haftmann@25919
   427
haftmann@25919
   428
lemma zless_nat_conj [simp]: "(nat w < nat z) = (0 < z & w < z)"
haftmann@25919
   429
apply (cases w, cases z) 
haftmann@25919
   430
apply (simp add: nat le Zero_int_def linorder_not_le [symmetric], arith)
haftmann@25919
   431
done
haftmann@25919
   432
haftmann@25919
   433
lemma nonneg_eq_int:
haftmann@25919
   434
  fixes z :: int
haftmann@25919
   435
  assumes "0 \<le> z" and "\<And>m. z = of_nat m \<Longrightarrow> P"
haftmann@25919
   436
  shows P
haftmann@25919
   437
  using assms by (blast dest: nat_0_le sym)
haftmann@25919
   438
haftmann@25919
   439
lemma nat_eq_iff: "(nat w = m) = (if 0 \<le> w then w = of_nat m else m=0)"
haftmann@25919
   440
by (cases w, simp add: nat le int_def Zero_int_def, arith)
haftmann@25919
   441
haftmann@25919
   442
corollary nat_eq_iff2: "(m = nat w) = (if 0 \<le> w then w = of_nat m else m=0)"
haftmann@25919
   443
by (simp only: eq_commute [of m] nat_eq_iff)
haftmann@25919
   444
haftmann@25919
   445
lemma nat_less_iff: "0 \<le> w ==> (nat w < m) = (w < of_nat m)"
haftmann@25919
   446
apply (cases w)
nipkow@29700
   447
apply (simp add: nat le int_def Zero_int_def linorder_not_le[symmetric], arith)
haftmann@25919
   448
done
haftmann@25919
   449
nipkow@29700
   450
lemma nat_0_iff[simp]: "nat(i::int) = 0 \<longleftrightarrow> i\<le>0"
nipkow@29700
   451
by(simp add: nat_eq_iff) arith
nipkow@29700
   452
haftmann@25919
   453
lemma int_eq_iff: "(of_nat m = z) = (m = nat z & 0 \<le> z)"
haftmann@25919
   454
by (auto simp add: nat_eq_iff2)
haftmann@25919
   455
haftmann@25919
   456
lemma zero_less_nat_eq [simp]: "(0 < nat z) = (0 < z)"
haftmann@25919
   457
by (insert zless_nat_conj [of 0], auto)
haftmann@25919
   458
haftmann@25919
   459
lemma nat_add_distrib:
haftmann@25919
   460
     "[| (0::int) \<le> z;  0 \<le> z' |] ==> nat (z+z') = nat z + nat z'"
haftmann@25919
   461
by (cases z, cases z', simp add: nat add le Zero_int_def)
haftmann@25919
   462
haftmann@25919
   463
lemma nat_diff_distrib:
haftmann@25919
   464
     "[| (0::int) \<le> z';  z' \<le> z |] ==> nat (z-z') = nat z - nat z'"
haftmann@25919
   465
by (cases z, cases z', 
haftmann@25919
   466
    simp add: nat add minus diff_minus le Zero_int_def)
haftmann@25919
   467
haftmann@25919
   468
lemma nat_zminus_int [simp]: "nat (- (of_nat n)) = 0"
haftmann@25919
   469
by (simp add: int_def minus nat Zero_int_def) 
haftmann@25919
   470
haftmann@25919
   471
lemma zless_nat_eq_int_zless: "(m < nat z) = (of_nat m < z)"
haftmann@25919
   472
by (cases z, simp add: nat less int_def, arith)
haftmann@25919
   473
haftmann@25919
   474
context ring_1
haftmann@25919
   475
begin
haftmann@25919
   476
haftmann@25919
   477
lemma of_nat_nat: "0 \<le> z \<Longrightarrow> of_nat (nat z) = of_int z"
haftmann@25919
   478
  by (cases z rule: eq_Abs_Integ)
haftmann@25919
   479
   (simp add: nat le of_int Zero_int_def of_nat_diff)
haftmann@25919
   480
haftmann@25919
   481
end
haftmann@25919
   482
krauss@29779
   483
text {* For termination proofs: *}
krauss@29779
   484
lemma measure_function_int[measure_function]: "is_measure (nat o abs)" ..
krauss@29779
   485
haftmann@25919
   486
haftmann@25919
   487
subsection{*Lemmas about the Function @{term of_nat} and Orderings*}
haftmann@25919
   488
haftmann@25919
   489
lemma negative_zless_0: "- (of_nat (Suc n)) < (0 \<Colon> int)"
haftmann@25919
   490
by (simp add: order_less_le del: of_nat_Suc)
haftmann@25919
   491
haftmann@25919
   492
lemma negative_zless [iff]: "- (of_nat (Suc n)) < (of_nat m \<Colon> int)"
haftmann@25919
   493
by (rule negative_zless_0 [THEN order_less_le_trans], simp)
haftmann@25919
   494
haftmann@25919
   495
lemma negative_zle_0: "- of_nat n \<le> (0 \<Colon> int)"
haftmann@25919
   496
by (simp add: minus_le_iff)
haftmann@25919
   497
haftmann@25919
   498
lemma negative_zle [iff]: "- of_nat n \<le> (of_nat m \<Colon> int)"
haftmann@25919
   499
by (rule order_trans [OF negative_zle_0 of_nat_0_le_iff])
haftmann@25919
   500
haftmann@25919
   501
lemma not_zle_0_negative [simp]: "~ (0 \<le> - (of_nat (Suc n) \<Colon> int))"
haftmann@25919
   502
by (subst le_minus_iff, simp del: of_nat_Suc)
haftmann@25919
   503
haftmann@25919
   504
lemma int_zle_neg: "((of_nat n \<Colon> int) \<le> - of_nat m) = (n = 0 & m = 0)"
haftmann@25919
   505
by (simp add: int_def le minus Zero_int_def)
haftmann@25919
   506
haftmann@25919
   507
lemma not_int_zless_negative [simp]: "~ ((of_nat n \<Colon> int) < - of_nat m)"
haftmann@25919
   508
by (simp add: linorder_not_less)
haftmann@25919
   509
haftmann@25919
   510
lemma negative_eq_positive [simp]: "((- of_nat n \<Colon> int) = of_nat m) = (n = 0 & m = 0)"
haftmann@25919
   511
by (force simp add: order_eq_iff [of "- of_nat n"] int_zle_neg)
haftmann@25919
   512
haftmann@25919
   513
lemma zle_iff_zadd: "(w\<Colon>int) \<le> z \<longleftrightarrow> (\<exists>n. z = w + of_nat n)"
haftmann@25919
   514
proof -
haftmann@25919
   515
  have "(w \<le> z) = (0 \<le> z - w)"
haftmann@25919
   516
    by (simp only: le_diff_eq add_0_left)
haftmann@25919
   517
  also have "\<dots> = (\<exists>n. z - w = of_nat n)"
haftmann@25919
   518
    by (auto elim: zero_le_imp_eq_int)
haftmann@25919
   519
  also have "\<dots> = (\<exists>n. z = w + of_nat n)"
nipkow@29667
   520
    by (simp only: algebra_simps)
haftmann@25919
   521
  finally show ?thesis .
haftmann@25919
   522
qed
haftmann@25919
   523
haftmann@25919
   524
lemma zadd_int_left: "of_nat m + (of_nat n + z) = of_nat (m + n) + (z\<Colon>int)"
haftmann@25919
   525
by simp
haftmann@25919
   526
haftmann@25919
   527
lemma int_Suc0_eq_1: "of_nat (Suc 0) = (1\<Colon>int)"
haftmann@25919
   528
by simp
haftmann@25919
   529
haftmann@25919
   530
text{*This version is proved for all ordered rings, not just integers!
haftmann@25919
   531
      It is proved here because attribute @{text arith_split} is not available
haftmann@25919
   532
      in theory @{text Ring_and_Field}.
haftmann@25919
   533
      But is it really better than just rewriting with @{text abs_if}?*}
haftmann@25919
   534
lemma abs_split [arith_split,noatp]:
haftmann@25919
   535
     "P(abs(a::'a::ordered_idom)) = ((0 \<le> a --> P a) & (a < 0 --> P(-a)))"
haftmann@25919
   536
by (force dest: order_less_le_trans simp add: abs_if linorder_not_less)
haftmann@25919
   537
haftmann@25919
   538
lemma negD: "(x \<Colon> int) < 0 \<Longrightarrow> \<exists>n. x = - (of_nat (Suc n))"
haftmann@25919
   539
apply (cases x)
haftmann@25919
   540
apply (auto simp add: le minus Zero_int_def int_def order_less_le)
haftmann@25919
   541
apply (rule_tac x="y - Suc x" in exI, arith)
haftmann@25919
   542
done
haftmann@25919
   543
haftmann@25919
   544
haftmann@25919
   545
subsection {* Cases and induction *}
haftmann@25919
   546
haftmann@25919
   547
text{*Now we replace the case analysis rule by a more conventional one:
haftmann@25919
   548
whether an integer is negative or not.*}
haftmann@25919
   549
haftmann@25919
   550
theorem int_cases [cases type: int, case_names nonneg neg]:
haftmann@25919
   551
  "[|!! n. (z \<Colon> int) = of_nat n ==> P;  !! n. z =  - (of_nat (Suc n)) ==> P |] ==> P"
haftmann@25919
   552
apply (cases "z < 0", blast dest!: negD)
haftmann@25919
   553
apply (simp add: linorder_not_less del: of_nat_Suc)
haftmann@25919
   554
apply auto
haftmann@25919
   555
apply (blast dest: nat_0_le [THEN sym])
haftmann@25919
   556
done
haftmann@25919
   557
haftmann@25919
   558
theorem int_induct [induct type: int, case_names nonneg neg]:
haftmann@25919
   559
     "[|!! n. P (of_nat n \<Colon> int);  !!n. P (- (of_nat (Suc n))) |] ==> P z"
haftmann@25919
   560
  by (cases z rule: int_cases) auto
haftmann@25919
   561
haftmann@25919
   562
text{*Contributed by Brian Huffman*}
haftmann@25919
   563
theorem int_diff_cases:
haftmann@25919
   564
  obtains (diff) m n where "(z\<Colon>int) = of_nat m - of_nat n"
haftmann@25919
   565
apply (cases z rule: eq_Abs_Integ)
haftmann@25919
   566
apply (rule_tac m=x and n=y in diff)
haftmann@25919
   567
apply (simp add: int_def diff_def minus add)
haftmann@25919
   568
done
haftmann@25919
   569
haftmann@25919
   570
haftmann@25919
   571
subsection {* Binary representation *}
haftmann@25919
   572
haftmann@25919
   573
text {*
haftmann@25919
   574
  This formalization defines binary arithmetic in terms of the integers
haftmann@25919
   575
  rather than using a datatype. This avoids multiple representations (leading
haftmann@25919
   576
  zeroes, etc.)  See @{text "ZF/Tools/twos-compl.ML"}, function @{text
haftmann@25919
   577
  int_of_binary}, for the numerical interpretation.
haftmann@25919
   578
haftmann@25919
   579
  The representation expects that @{text "(m mod 2)"} is 0 or 1,
haftmann@25919
   580
  even if m is negative;
haftmann@25919
   581
  For instance, @{text "-5 div 2 = -3"} and @{text "-5 mod 2 = 1"}; thus
haftmann@25919
   582
  @{text "-5 = (-3)*2 + 1"}.
haftmann@25919
   583
  
haftmann@25919
   584
  This two's complement binary representation derives from the paper 
haftmann@25919
   585
  "An Efficient Representation of Arithmetic for Term Rewriting" by
haftmann@25919
   586
  Dave Cohen and Phil Watson, Rewriting Techniques and Applications,
haftmann@25919
   587
  Springer LNCS 488 (240-251), 1991.
haftmann@25919
   588
*}
haftmann@25919
   589
huffman@28958
   590
subsubsection {* The constructors @{term Bit0}, @{term Bit1}, @{term Pls} and @{term Min} *}
huffman@28958
   591
haftmann@25919
   592
definition
haftmann@25919
   593
  Pls :: int where
haftmann@28562
   594
  [code del]: "Pls = 0"
haftmann@25919
   595
haftmann@25919
   596
definition
haftmann@25919
   597
  Min :: int where
haftmann@28562
   598
  [code del]: "Min = - 1"
haftmann@25919
   599
haftmann@25919
   600
definition
huffman@26086
   601
  Bit0 :: "int \<Rightarrow> int" where
haftmann@28562
   602
  [code del]: "Bit0 k = k + k"
huffman@26086
   603
huffman@26086
   604
definition
huffman@26086
   605
  Bit1 :: "int \<Rightarrow> int" where
haftmann@28562
   606
  [code del]: "Bit1 k = 1 + k + k"
haftmann@25919
   607
haftmann@29608
   608
class number = -- {* for numeric types: nat, int, real, \dots *}
haftmann@25919
   609
  fixes number_of :: "int \<Rightarrow> 'a"
haftmann@25919
   610
haftmann@25919
   611
use "Tools/numeral.ML"
haftmann@25919
   612
haftmann@25919
   613
syntax
haftmann@25919
   614
  "_Numeral" :: "num_const \<Rightarrow> 'a"    ("_")
haftmann@25919
   615
haftmann@25919
   616
use "Tools/numeral_syntax.ML"
haftmann@25919
   617
setup NumeralSyntax.setup
haftmann@25919
   618
haftmann@25919
   619
abbreviation
haftmann@25919
   620
  "Numeral0 \<equiv> number_of Pls"
haftmann@25919
   621
haftmann@25919
   622
abbreviation
huffman@26086
   623
  "Numeral1 \<equiv> number_of (Bit1 Pls)"
haftmann@25919
   624
haftmann@25919
   625
lemma Let_number_of [simp]: "Let (number_of v) f = f (number_of v)"
haftmann@25919
   626
  -- {* Unfold all @{text let}s involving constants *}
haftmann@25919
   627
  unfolding Let_def ..
haftmann@25919
   628
haftmann@25919
   629
definition
haftmann@25919
   630
  succ :: "int \<Rightarrow> int" where
haftmann@28562
   631
  [code del]: "succ k = k + 1"
haftmann@25919
   632
haftmann@25919
   633
definition
haftmann@25919
   634
  pred :: "int \<Rightarrow> int" where
haftmann@28562
   635
  [code del]: "pred k = k - 1"
haftmann@25919
   636
haftmann@25919
   637
lemmas
haftmann@25919
   638
  max_number_of [simp] = max_def
haftmann@25919
   639
    [of "number_of u" "number_of v", standard, simp]
haftmann@25919
   640
and
haftmann@25919
   641
  min_number_of [simp] = min_def 
haftmann@25919
   642
    [of "number_of u" "number_of v", standard, simp]
haftmann@25919
   643
  -- {* unfolding @{text minx} and @{text max} on numerals *}
haftmann@25919
   644
haftmann@25919
   645
lemmas numeral_simps = 
huffman@26086
   646
  succ_def pred_def Pls_def Min_def Bit0_def Bit1_def
haftmann@25919
   647
haftmann@25919
   648
text {* Removal of leading zeroes *}
haftmann@25919
   649
huffman@26086
   650
lemma Bit0_Pls [simp, code post]:
huffman@26086
   651
  "Bit0 Pls = Pls"
haftmann@25919
   652
  unfolding numeral_simps by simp
haftmann@25919
   653
huffman@26086
   654
lemma Bit1_Min [simp, code post]:
huffman@26086
   655
  "Bit1 Min = Min"
haftmann@25919
   656
  unfolding numeral_simps by simp
haftmann@25919
   657
huffman@26075
   658
lemmas normalize_bin_simps =
huffman@26086
   659
  Bit0_Pls Bit1_Min
huffman@26075
   660
haftmann@25919
   661
huffman@28958
   662
subsubsection {* Successor and predecessor functions *}
huffman@28958
   663
huffman@28958
   664
text {* Successor *}
huffman@28958
   665
huffman@28958
   666
lemma succ_Pls:
huffman@26086
   667
  "succ Pls = Bit1 Pls"
haftmann@25919
   668
  unfolding numeral_simps by simp
haftmann@25919
   669
huffman@28958
   670
lemma succ_Min:
haftmann@25919
   671
  "succ Min = Pls"
haftmann@25919
   672
  unfolding numeral_simps by simp
haftmann@25919
   673
huffman@28958
   674
lemma succ_Bit0:
huffman@26086
   675
  "succ (Bit0 k) = Bit1 k"
haftmann@25919
   676
  unfolding numeral_simps by simp
haftmann@25919
   677
huffman@28958
   678
lemma succ_Bit1:
huffman@26086
   679
  "succ (Bit1 k) = Bit0 (succ k)"
haftmann@25919
   680
  unfolding numeral_simps by simp
haftmann@25919
   681
huffman@28958
   682
lemmas succ_bin_simps [simp] =
huffman@26086
   683
  succ_Pls succ_Min succ_Bit0 succ_Bit1
huffman@26075
   684
huffman@28958
   685
text {* Predecessor *}
huffman@28958
   686
huffman@28958
   687
lemma pred_Pls:
haftmann@25919
   688
  "pred Pls = Min"
haftmann@25919
   689
  unfolding numeral_simps by simp
haftmann@25919
   690
huffman@28958
   691
lemma pred_Min:
huffman@26086
   692
  "pred Min = Bit0 Min"
haftmann@25919
   693
  unfolding numeral_simps by simp
haftmann@25919
   694
huffman@28958
   695
lemma pred_Bit0:
huffman@26086
   696
  "pred (Bit0 k) = Bit1 (pred k)"
haftmann@25919
   697
  unfolding numeral_simps by simp 
haftmann@25919
   698
huffman@28958
   699
lemma pred_Bit1:
huffman@26086
   700
  "pred (Bit1 k) = Bit0 k"
huffman@26086
   701
  unfolding numeral_simps by simp
huffman@26086
   702
huffman@28958
   703
lemmas pred_bin_simps [simp] =
huffman@26086
   704
  pred_Pls pred_Min pred_Bit0 pred_Bit1
huffman@26075
   705
huffman@28958
   706
huffman@28958
   707
subsubsection {* Binary arithmetic *}
huffman@28958
   708
huffman@28958
   709
text {* Addition *}
huffman@28958
   710
huffman@28958
   711
lemma add_Pls:
huffman@28958
   712
  "Pls + k = k"
huffman@28958
   713
  unfolding numeral_simps by simp
huffman@28958
   714
huffman@28958
   715
lemma add_Min:
huffman@28958
   716
  "Min + k = pred k"
huffman@28958
   717
  unfolding numeral_simps by simp
huffman@28958
   718
huffman@28958
   719
lemma add_Bit0_Bit0:
huffman@28958
   720
  "(Bit0 k) + (Bit0 l) = Bit0 (k + l)"
huffman@28958
   721
  unfolding numeral_simps by simp
huffman@28958
   722
huffman@28958
   723
lemma add_Bit0_Bit1:
huffman@28958
   724
  "(Bit0 k) + (Bit1 l) = Bit1 (k + l)"
huffman@28958
   725
  unfolding numeral_simps by simp
huffman@28958
   726
huffman@28958
   727
lemma add_Bit1_Bit0:
huffman@28958
   728
  "(Bit1 k) + (Bit0 l) = Bit1 (k + l)"
huffman@28958
   729
  unfolding numeral_simps by simp
huffman@28958
   730
huffman@28958
   731
lemma add_Bit1_Bit1:
huffman@28958
   732
  "(Bit1 k) + (Bit1 l) = Bit0 (k + succ l)"
huffman@28958
   733
  unfolding numeral_simps by simp
huffman@28958
   734
huffman@28958
   735
lemma add_Pls_right:
huffman@28958
   736
  "k + Pls = k"
huffman@28958
   737
  unfolding numeral_simps by simp
huffman@28958
   738
huffman@28958
   739
lemma add_Min_right:
huffman@28958
   740
  "k + Min = pred k"
huffman@28958
   741
  unfolding numeral_simps by simp
huffman@28958
   742
huffman@28958
   743
lemmas add_bin_simps [simp] =
huffman@28958
   744
  add_Pls add_Min add_Pls_right add_Min_right
huffman@28958
   745
  add_Bit0_Bit0 add_Bit0_Bit1 add_Bit1_Bit0 add_Bit1_Bit1
huffman@28958
   746
huffman@28958
   747
text {* Negation *}
huffman@28958
   748
huffman@28958
   749
lemma minus_Pls:
haftmann@25919
   750
  "- Pls = Pls"
huffman@28958
   751
  unfolding numeral_simps by simp
huffman@28958
   752
huffman@28958
   753
lemma minus_Min:
huffman@26086
   754
  "- Min = Bit1 Pls"
huffman@28958
   755
  unfolding numeral_simps by simp
huffman@28958
   756
huffman@28958
   757
lemma minus_Bit0:
huffman@26086
   758
  "- (Bit0 k) = Bit0 (- k)"
huffman@28958
   759
  unfolding numeral_simps by simp
huffman@28958
   760
huffman@28958
   761
lemma minus_Bit1:
huffman@26086
   762
  "- (Bit1 k) = Bit1 (pred (- k))"
huffman@26086
   763
  unfolding numeral_simps by simp
haftmann@25919
   764
huffman@28958
   765
lemmas minus_bin_simps [simp] =
huffman@26086
   766
  minus_Pls minus_Min minus_Bit0 minus_Bit1
huffman@26075
   767
huffman@28958
   768
text {* Subtraction *}
huffman@28958
   769
huffman@29046
   770
lemma diff_bin_simps [simp]:
huffman@29046
   771
  "k - Pls = k"
huffman@29046
   772
  "k - Min = succ k"
huffman@29046
   773
  "Pls - (Bit0 l) = Bit0 (Pls - l)"
huffman@29046
   774
  "Pls - (Bit1 l) = Bit1 (Min - l)"
huffman@29046
   775
  "Min - (Bit0 l) = Bit1 (Min - l)"
huffman@29046
   776
  "Min - (Bit1 l) = Bit0 (Min - l)"
huffman@28958
   777
  "(Bit0 k) - (Bit0 l) = Bit0 (k - l)"
huffman@28958
   778
  "(Bit0 k) - (Bit1 l) = Bit1 (pred k - l)"
huffman@28958
   779
  "(Bit1 k) - (Bit0 l) = Bit1 (k - l)"
huffman@28958
   780
  "(Bit1 k) - (Bit1 l) = Bit0 (k - l)"
huffman@29046
   781
  unfolding numeral_simps by simp_all
huffman@28958
   782
huffman@28958
   783
text {* Multiplication *}
huffman@28958
   784
huffman@28958
   785
lemma mult_Pls:
huffman@28958
   786
  "Pls * w = Pls"
huffman@26086
   787
  unfolding numeral_simps by simp
haftmann@25919
   788
huffman@28958
   789
lemma mult_Min:
haftmann@25919
   790
  "Min * k = - k"
haftmann@25919
   791
  unfolding numeral_simps by simp
haftmann@25919
   792
huffman@28958
   793
lemma mult_Bit0:
huffman@26086
   794
  "(Bit0 k) * l = Bit0 (k * l)"
huffman@26086
   795
  unfolding numeral_simps int_distrib by simp
haftmann@25919
   796
huffman@28958
   797
lemma mult_Bit1:
huffman@26086
   798
  "(Bit1 k) * l = (Bit0 (k * l)) + l"
huffman@28958
   799
  unfolding numeral_simps int_distrib by simp
huffman@28958
   800
huffman@28958
   801
lemmas mult_bin_simps [simp] =
huffman@26086
   802
  mult_Pls mult_Min mult_Bit0 mult_Bit1
huffman@26075
   803
haftmann@25919
   804
huffman@28958
   805
subsubsection {* Binary comparisons *}
huffman@28958
   806
huffman@28958
   807
text {* Preliminaries *}
huffman@28958
   808
huffman@28958
   809
lemma even_less_0_iff:
huffman@28958
   810
  "a + a < 0 \<longleftrightarrow> a < (0::'a::ordered_idom)"
huffman@28958
   811
proof -
huffman@28958
   812
  have "a + a < 0 \<longleftrightarrow> (1+1)*a < 0" by (simp add: left_distrib)
huffman@28958
   813
  also have "(1+1)*a < 0 \<longleftrightarrow> a < 0"
huffman@28958
   814
    by (simp add: mult_less_0_iff zero_less_two 
huffman@28958
   815
                  order_less_not_sym [OF zero_less_two])
huffman@28958
   816
  finally show ?thesis .
huffman@28958
   817
qed
huffman@28958
   818
huffman@28958
   819
lemma le_imp_0_less: 
huffman@28958
   820
  assumes le: "0 \<le> z"
huffman@28958
   821
  shows "(0::int) < 1 + z"
huffman@28958
   822
proof -
huffman@28958
   823
  have "0 \<le> z" by fact
huffman@28958
   824
  also have "... < z + 1" by (rule less_add_one) 
huffman@28958
   825
  also have "... = 1 + z" by (simp add: add_ac)
huffman@28958
   826
  finally show "0 < 1 + z" .
huffman@28958
   827
qed
huffman@28958
   828
huffman@28958
   829
lemma odd_less_0_iff:
huffman@28958
   830
  "(1 + z + z < 0) = (z < (0::int))"
huffman@28958
   831
proof (cases z rule: int_cases)
huffman@28958
   832
  case (nonneg n)
huffman@28958
   833
  thus ?thesis by (simp add: linorder_not_less add_assoc add_increasing
huffman@28958
   834
                             le_imp_0_less [THEN order_less_imp_le])  
huffman@28958
   835
next
huffman@28958
   836
  case (neg n)
huffman@30079
   837
  thus ?thesis by (simp del: of_nat_Suc of_nat_add of_nat_1
huffman@30079
   838
    add: algebra_simps of_nat_1 [where 'a=int, symmetric] of_nat_add [symmetric])
huffman@28958
   839
qed
huffman@28958
   840
huffman@28985
   841
lemma bin_less_0_simps:
huffman@28958
   842
  "Pls < 0 \<longleftrightarrow> False"
huffman@28958
   843
  "Min < 0 \<longleftrightarrow> True"
huffman@28958
   844
  "Bit0 w < 0 \<longleftrightarrow> w < 0"
huffman@28958
   845
  "Bit1 w < 0 \<longleftrightarrow> w < 0"
huffman@28958
   846
  unfolding numeral_simps
huffman@28958
   847
  by (simp_all add: even_less_0_iff odd_less_0_iff)
huffman@28958
   848
huffman@28958
   849
lemma less_bin_lemma: "k < l \<longleftrightarrow> k - l < (0::int)"
huffman@28958
   850
  by simp
huffman@28958
   851
huffman@28958
   852
lemma le_iff_pred_less: "k \<le> l \<longleftrightarrow> pred k < l"
huffman@28958
   853
  unfolding numeral_simps
huffman@28958
   854
  proof
huffman@28958
   855
    have "k - 1 < k" by simp
huffman@28958
   856
    also assume "k \<le> l"
huffman@28958
   857
    finally show "k - 1 < l" .
huffman@28958
   858
  next
huffman@28958
   859
    assume "k - 1 < l"
huffman@28958
   860
    hence "(k - 1) + 1 \<le> l" by (rule zless_imp_add1_zle)
huffman@28958
   861
    thus "k \<le> l" by simp
huffman@28958
   862
  qed
huffman@28958
   863
huffman@28958
   864
lemma succ_pred: "succ (pred x) = x"
huffman@28958
   865
  unfolding numeral_simps by simp
huffman@28958
   866
huffman@28958
   867
text {* Less-than *}
huffman@28958
   868
huffman@28958
   869
lemma less_bin_simps [simp]:
huffman@28958
   870
  "Pls < Pls \<longleftrightarrow> False"
huffman@28958
   871
  "Pls < Min \<longleftrightarrow> False"
huffman@28958
   872
  "Pls < Bit0 k \<longleftrightarrow> Pls < k"
huffman@28958
   873
  "Pls < Bit1 k \<longleftrightarrow> Pls \<le> k"
huffman@28958
   874
  "Min < Pls \<longleftrightarrow> True"
huffman@28958
   875
  "Min < Min \<longleftrightarrow> False"
huffman@28958
   876
  "Min < Bit0 k \<longleftrightarrow> Min < k"
huffman@28958
   877
  "Min < Bit1 k \<longleftrightarrow> Min < k"
huffman@28958
   878
  "Bit0 k < Pls \<longleftrightarrow> k < Pls"
huffman@28958
   879
  "Bit0 k < Min \<longleftrightarrow> k \<le> Min"
huffman@28958
   880
  "Bit1 k < Pls \<longleftrightarrow> k < Pls"
huffman@28958
   881
  "Bit1 k < Min \<longleftrightarrow> k < Min"
huffman@28958
   882
  "Bit0 k < Bit0 l \<longleftrightarrow> k < l"
huffman@28958
   883
  "Bit0 k < Bit1 l \<longleftrightarrow> k \<le> l"
huffman@28958
   884
  "Bit1 k < Bit0 l \<longleftrightarrow> k < l"
huffman@28958
   885
  "Bit1 k < Bit1 l \<longleftrightarrow> k < l"
huffman@28958
   886
  unfolding le_iff_pred_less
huffman@28958
   887
    less_bin_lemma [of Pls]
huffman@28958
   888
    less_bin_lemma [of Min]
huffman@28958
   889
    less_bin_lemma [of "k"]
huffman@28958
   890
    less_bin_lemma [of "Bit0 k"]
huffman@28958
   891
    less_bin_lemma [of "Bit1 k"]
huffman@28958
   892
    less_bin_lemma [of "pred Pls"]
huffman@28958
   893
    less_bin_lemma [of "pred k"]
huffman@28985
   894
  by (simp_all add: bin_less_0_simps succ_pred)
huffman@28958
   895
huffman@28958
   896
text {* Less-than-or-equal *}
huffman@28958
   897
huffman@28958
   898
lemma le_bin_simps [simp]:
huffman@28958
   899
  "Pls \<le> Pls \<longleftrightarrow> True"
huffman@28958
   900
  "Pls \<le> Min \<longleftrightarrow> False"
huffman@28958
   901
  "Pls \<le> Bit0 k \<longleftrightarrow> Pls \<le> k"
huffman@28958
   902
  "Pls \<le> Bit1 k \<longleftrightarrow> Pls \<le> k"
huffman@28958
   903
  "Min \<le> Pls \<longleftrightarrow> True"
huffman@28958
   904
  "Min \<le> Min \<longleftrightarrow> True"
huffman@28958
   905
  "Min \<le> Bit0 k \<longleftrightarrow> Min < k"
huffman@28958
   906
  "Min \<le> Bit1 k \<longleftrightarrow> Min \<le> k"
huffman@28958
   907
  "Bit0 k \<le> Pls \<longleftrightarrow> k \<le> Pls"
huffman@28958
   908
  "Bit0 k \<le> Min \<longleftrightarrow> k \<le> Min"
huffman@28958
   909
  "Bit1 k \<le> Pls \<longleftrightarrow> k < Pls"
huffman@28958
   910
  "Bit1 k \<le> Min \<longleftrightarrow> k \<le> Min"
huffman@28958
   911
  "Bit0 k \<le> Bit0 l \<longleftrightarrow> k \<le> l"
huffman@28958
   912
  "Bit0 k \<le> Bit1 l \<longleftrightarrow> k \<le> l"
huffman@28958
   913
  "Bit1 k \<le> Bit0 l \<longleftrightarrow> k < l"
huffman@28958
   914
  "Bit1 k \<le> Bit1 l \<longleftrightarrow> k \<le> l"
huffman@28958
   915
  unfolding not_less [symmetric]
huffman@28958
   916
  by (simp_all add: not_le)
huffman@28958
   917
huffman@28958
   918
text {* Equality *}
huffman@28958
   919
huffman@28958
   920
lemma eq_bin_simps [simp]:
huffman@28958
   921
  "Pls = Pls \<longleftrightarrow> True"
huffman@28958
   922
  "Pls = Min \<longleftrightarrow> False"
huffman@28958
   923
  "Pls = Bit0 l \<longleftrightarrow> Pls = l"
huffman@28958
   924
  "Pls = Bit1 l \<longleftrightarrow> False"
huffman@28958
   925
  "Min = Pls \<longleftrightarrow> False"
huffman@28958
   926
  "Min = Min \<longleftrightarrow> True"
huffman@28958
   927
  "Min = Bit0 l \<longleftrightarrow> False"
huffman@28958
   928
  "Min = Bit1 l \<longleftrightarrow> Min = l"
huffman@28958
   929
  "Bit0 k = Pls \<longleftrightarrow> k = Pls"
huffman@28958
   930
  "Bit0 k = Min \<longleftrightarrow> False"
huffman@28958
   931
  "Bit1 k = Pls \<longleftrightarrow> False"
huffman@28958
   932
  "Bit1 k = Min \<longleftrightarrow> k = Min"
huffman@28958
   933
  "Bit0 k = Bit0 l \<longleftrightarrow> k = l"
huffman@28958
   934
  "Bit0 k = Bit1 l \<longleftrightarrow> False"
huffman@28958
   935
  "Bit1 k = Bit0 l \<longleftrightarrow> False"
huffman@28958
   936
  "Bit1 k = Bit1 l \<longleftrightarrow> k = l"
huffman@28958
   937
  unfolding order_eq_iff [where 'a=int]
huffman@28958
   938
  by (simp_all add: not_less)
huffman@28958
   939
huffman@28958
   940
haftmann@25919
   941
subsection {* Converting Numerals to Rings: @{term number_of} *}
haftmann@25919
   942
haftmann@25919
   943
class number_ring = number + comm_ring_1 +
haftmann@25919
   944
  assumes number_of_eq: "number_of k = of_int k"
haftmann@25919
   945
haftmann@25919
   946
text {* self-embedding of the integers *}
haftmann@25919
   947
haftmann@25919
   948
instantiation int :: number_ring
haftmann@25919
   949
begin
haftmann@25919
   950
haftmann@28724
   951
definition int_number_of_def [code del]:
haftmann@28724
   952
  "number_of w = (of_int w \<Colon> int)"
haftmann@25919
   953
haftmann@28724
   954
instance proof
haftmann@28724
   955
qed (simp only: int_number_of_def)
haftmann@25919
   956
haftmann@25919
   957
end
haftmann@25919
   958
haftmann@25919
   959
lemma number_of_is_id:
haftmann@25919
   960
  "number_of (k::int) = k"
haftmann@25919
   961
  unfolding int_number_of_def by simp
haftmann@25919
   962
haftmann@25919
   963
lemma number_of_succ:
haftmann@25919
   964
  "number_of (succ k) = (1 + number_of k ::'a::number_ring)"
haftmann@25919
   965
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
   966
haftmann@25919
   967
lemma number_of_pred:
haftmann@25919
   968
  "number_of (pred w) = (- 1 + number_of w ::'a::number_ring)"
haftmann@25919
   969
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
   970
haftmann@25919
   971
lemma number_of_minus:
haftmann@25919
   972
  "number_of (uminus w) = (- (number_of w)::'a::number_ring)"
huffman@28958
   973
  unfolding number_of_eq by (rule of_int_minus)
haftmann@25919
   974
haftmann@25919
   975
lemma number_of_add:
haftmann@25919
   976
  "number_of (v + w) = (number_of v + number_of w::'a::number_ring)"
huffman@28958
   977
  unfolding number_of_eq by (rule of_int_add)
huffman@28958
   978
huffman@28958
   979
lemma number_of_diff:
huffman@28958
   980
  "number_of (v - w) = (number_of v - number_of w::'a::number_ring)"
huffman@28958
   981
  unfolding number_of_eq by (rule of_int_diff)
haftmann@25919
   982
haftmann@25919
   983
lemma number_of_mult:
haftmann@25919
   984
  "number_of (v * w) = (number_of v * number_of w::'a::number_ring)"
huffman@28958
   985
  unfolding number_of_eq by (rule of_int_mult)
haftmann@25919
   986
haftmann@25919
   987
text {*
haftmann@25919
   988
  The correctness of shifting.
haftmann@25919
   989
  But it doesn't seem to give a measurable speed-up.
haftmann@25919
   990
*}
haftmann@25919
   991
huffman@26086
   992
lemma double_number_of_Bit0:
huffman@26086
   993
  "(1 + 1) * number_of w = (number_of (Bit0 w) ::'a::number_ring)"
haftmann@25919
   994
  unfolding number_of_eq numeral_simps left_distrib by simp
haftmann@25919
   995
haftmann@25919
   996
text {*
haftmann@25919
   997
  Converting numerals 0 and 1 to their abstract versions.
haftmann@25919
   998
*}
haftmann@25919
   999
haftmann@25919
  1000
lemma numeral_0_eq_0 [simp]:
haftmann@25919
  1001
  "Numeral0 = (0::'a::number_ring)"
haftmann@25919
  1002
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1003
haftmann@25919
  1004
lemma numeral_1_eq_1 [simp]:
haftmann@25919
  1005
  "Numeral1 = (1::'a::number_ring)"
haftmann@25919
  1006
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1007
haftmann@25919
  1008
text {*
haftmann@25919
  1009
  Special-case simplification for small constants.
haftmann@25919
  1010
*}
haftmann@25919
  1011
haftmann@25919
  1012
text{*
haftmann@25919
  1013
  Unary minus for the abstract constant 1. Cannot be inserted
haftmann@25919
  1014
  as a simprule until later: it is @{text number_of_Min} re-oriented!
haftmann@25919
  1015
*}
haftmann@25919
  1016
haftmann@25919
  1017
lemma numeral_m1_eq_minus_1:
haftmann@25919
  1018
  "(-1::'a::number_ring) = - 1"
haftmann@25919
  1019
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1020
haftmann@25919
  1021
lemma mult_minus1 [simp]:
haftmann@25919
  1022
  "-1 * z = -(z::'a::number_ring)"
haftmann@25919
  1023
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1024
haftmann@25919
  1025
lemma mult_minus1_right [simp]:
haftmann@25919
  1026
  "z * -1 = -(z::'a::number_ring)"
haftmann@25919
  1027
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1028
haftmann@25919
  1029
(*Negation of a coefficient*)
haftmann@25919
  1030
lemma minus_number_of_mult [simp]:
haftmann@25919
  1031
   "- (number_of w) * z = number_of (uminus w) * (z::'a::number_ring)"
haftmann@25919
  1032
   unfolding number_of_eq by simp
haftmann@25919
  1033
haftmann@25919
  1034
text {* Subtraction *}
haftmann@25919
  1035
haftmann@25919
  1036
lemma diff_number_of_eq:
haftmann@25919
  1037
  "number_of v - number_of w =
haftmann@25919
  1038
    (number_of (v + uminus w)::'a::number_ring)"
haftmann@25919
  1039
  unfolding number_of_eq by simp
haftmann@25919
  1040
haftmann@25919
  1041
lemma number_of_Pls:
haftmann@25919
  1042
  "number_of Pls = (0::'a::number_ring)"
haftmann@25919
  1043
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1044
haftmann@25919
  1045
lemma number_of_Min:
haftmann@25919
  1046
  "number_of Min = (- 1::'a::number_ring)"
haftmann@25919
  1047
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1048
huffman@26086
  1049
lemma number_of_Bit0:
huffman@26086
  1050
  "number_of (Bit0 w) = (0::'a::number_ring) + (number_of w) + (number_of w)"
huffman@26086
  1051
  unfolding number_of_eq numeral_simps by simp
huffman@26086
  1052
huffman@26086
  1053
lemma number_of_Bit1:
huffman@26086
  1054
  "number_of (Bit1 w) = (1::'a::number_ring) + (number_of w) + (number_of w)"
huffman@26086
  1055
  unfolding number_of_eq numeral_simps by simp
haftmann@25919
  1056
haftmann@25919
  1057
huffman@28958
  1058
subsubsection {* Equality of Binary Numbers *}
haftmann@25919
  1059
haftmann@25919
  1060
text {* First version by Norbert Voelker *}
haftmann@25919
  1061
haftmann@25919
  1062
definition (*for simplifying equalities*)
haftmann@25919
  1063
  iszero :: "'a\<Colon>semiring_1 \<Rightarrow> bool"
haftmann@25919
  1064
where
haftmann@25919
  1065
  "iszero z \<longleftrightarrow> z = 0"
haftmann@25919
  1066
haftmann@25919
  1067
lemma iszero_0: "iszero 0"
haftmann@25919
  1068
by (simp add: iszero_def)
haftmann@25919
  1069
haftmann@25919
  1070
lemma not_iszero_1: "~ iszero 1"
haftmann@25919
  1071
by (simp add: iszero_def eq_commute)
haftmann@25919
  1072
haftmann@25919
  1073
lemma eq_number_of_eq:
haftmann@25919
  1074
  "((number_of x::'a::number_ring) = number_of y) =
haftmann@25919
  1075
   iszero (number_of (x + uminus y) :: 'a)"
nipkow@29667
  1076
unfolding iszero_def number_of_add number_of_minus
nipkow@29667
  1077
by (simp add: algebra_simps)
haftmann@25919
  1078
haftmann@25919
  1079
lemma iszero_number_of_Pls:
haftmann@25919
  1080
  "iszero ((number_of Pls)::'a::number_ring)"
nipkow@29667
  1081
unfolding iszero_def numeral_0_eq_0 ..
haftmann@25919
  1082
haftmann@25919
  1083
lemma nonzero_number_of_Min:
haftmann@25919
  1084
  "~ iszero ((number_of Min)::'a::number_ring)"
nipkow@29667
  1085
unfolding iszero_def numeral_m1_eq_minus_1 by simp
haftmann@25919
  1086
haftmann@25919
  1087
huffman@28958
  1088
subsubsection {* Comparisons, for Ordered Rings *}
haftmann@25919
  1089
haftmann@25919
  1090
lemmas double_eq_0_iff = double_zero
haftmann@25919
  1091
haftmann@25919
  1092
lemma odd_nonzero:
haftmann@25919
  1093
  "1 + z + z \<noteq> (0::int)";
haftmann@25919
  1094
proof (cases z rule: int_cases)
haftmann@25919
  1095
  case (nonneg n)
haftmann@25919
  1096
  have le: "0 \<le> z+z" by (simp add: nonneg add_increasing) 
haftmann@25919
  1097
  thus ?thesis using  le_imp_0_less [OF le]
haftmann@25919
  1098
    by (auto simp add: add_assoc) 
haftmann@25919
  1099
next
haftmann@25919
  1100
  case (neg n)
haftmann@25919
  1101
  show ?thesis
haftmann@25919
  1102
  proof
haftmann@25919
  1103
    assume eq: "1 + z + z = 0"
haftmann@25919
  1104
    have "(0::int) < 1 + (of_nat n + of_nat n)"
haftmann@25919
  1105
      by (simp add: le_imp_0_less add_increasing) 
haftmann@25919
  1106
    also have "... = - (1 + z + z)" 
haftmann@25919
  1107
      by (simp add: neg add_assoc [symmetric]) 
haftmann@25919
  1108
    also have "... = 0" by (simp add: eq) 
haftmann@25919
  1109
    finally have "0<0" ..
haftmann@25919
  1110
    thus False by blast
haftmann@25919
  1111
  qed
haftmann@25919
  1112
qed
haftmann@25919
  1113
huffman@26086
  1114
lemma iszero_number_of_Bit0:
huffman@26086
  1115
  "iszero (number_of (Bit0 w)::'a) = 
huffman@26086
  1116
   iszero (number_of w::'a::{ring_char_0,number_ring})"
haftmann@25919
  1117
proof -
haftmann@25919
  1118
  have "(of_int w + of_int w = (0::'a)) \<Longrightarrow> (w = 0)"
haftmann@25919
  1119
  proof -
haftmann@25919
  1120
    assume eq: "of_int w + of_int w = (0::'a)"
haftmann@25919
  1121
    then have "of_int (w + w) = (of_int 0 :: 'a)" by simp
haftmann@25919
  1122
    then have "w + w = 0" by (simp only: of_int_eq_iff)
haftmann@25919
  1123
    then show "w = 0" by (simp only: double_eq_0_iff)
haftmann@25919
  1124
  qed
huffman@26086
  1125
  thus ?thesis
huffman@26086
  1126
    by (auto simp add: iszero_def number_of_eq numeral_simps)
huffman@26086
  1127
qed
huffman@26086
  1128
huffman@26086
  1129
lemma iszero_number_of_Bit1:
huffman@26086
  1130
  "~ iszero (number_of (Bit1 w)::'a::{ring_char_0,number_ring})"
huffman@26086
  1131
proof -
huffman@26086
  1132
  have "1 + of_int w + of_int w \<noteq> (0::'a)"
haftmann@25919
  1133
  proof
haftmann@25919
  1134
    assume eq: "1 + of_int w + of_int w = (0::'a)"
haftmann@25919
  1135
    hence "of_int (1 + w + w) = (of_int 0 :: 'a)" by simp 
haftmann@25919
  1136
    hence "1 + w + w = 0" by (simp only: of_int_eq_iff)
haftmann@25919
  1137
    with odd_nonzero show False by blast
haftmann@25919
  1138
  qed
huffman@26086
  1139
  thus ?thesis
huffman@26086
  1140
    by (auto simp add: iszero_def number_of_eq numeral_simps)
haftmann@25919
  1141
qed
haftmann@25919
  1142
huffman@28985
  1143
lemmas iszero_simps =
huffman@28985
  1144
  iszero_0 not_iszero_1
huffman@28985
  1145
  iszero_number_of_Pls nonzero_number_of_Min
huffman@28985
  1146
  iszero_number_of_Bit0 iszero_number_of_Bit1
huffman@28985
  1147
(* iszero_number_of_Pls would never normally be used
huffman@28985
  1148
   because its lhs simplifies to "iszero 0" *)
haftmann@25919
  1149
huffman@28958
  1150
subsubsection {* The Less-Than Relation *}
haftmann@25919
  1151
haftmann@25919
  1152
lemma double_less_0_iff:
haftmann@25919
  1153
  "(a + a < 0) = (a < (0::'a::ordered_idom))"
haftmann@25919
  1154
proof -
haftmann@25919
  1155
  have "(a + a < 0) = ((1+1)*a < 0)" by (simp add: left_distrib)
haftmann@25919
  1156
  also have "... = (a < 0)"
haftmann@25919
  1157
    by (simp add: mult_less_0_iff zero_less_two 
haftmann@25919
  1158
                  order_less_not_sym [OF zero_less_two]) 
haftmann@25919
  1159
  finally show ?thesis .
haftmann@25919
  1160
qed
haftmann@25919
  1161
haftmann@25919
  1162
lemma odd_less_0:
haftmann@25919
  1163
  "(1 + z + z < 0) = (z < (0::int))";
haftmann@25919
  1164
proof (cases z rule: int_cases)
haftmann@25919
  1165
  case (nonneg n)
haftmann@25919
  1166
  thus ?thesis by (simp add: linorder_not_less add_assoc add_increasing
haftmann@25919
  1167
                             le_imp_0_less [THEN order_less_imp_le])  
haftmann@25919
  1168
next
haftmann@25919
  1169
  case (neg n)
huffman@30079
  1170
  thus ?thesis by (simp del: of_nat_Suc of_nat_add of_nat_1
huffman@30079
  1171
    add: algebra_simps of_nat_1 [where 'a=int, symmetric] of_nat_add [symmetric])
haftmann@25919
  1172
qed
haftmann@25919
  1173
haftmann@25919
  1174
text {* Less-Than or Equals *}
haftmann@25919
  1175
haftmann@25919
  1176
text {* Reduces @{term "a\<le>b"} to @{term "~ (b<a)"} for ALL numerals. *}
haftmann@25919
  1177
haftmann@25919
  1178
lemmas le_number_of_eq_not_less =
haftmann@25919
  1179
  linorder_not_less [of "number_of w" "number_of v", symmetric, 
haftmann@25919
  1180
  standard]
haftmann@25919
  1181
haftmann@25919
  1182
haftmann@25919
  1183
text {* Absolute value (@{term abs}) *}
haftmann@25919
  1184
haftmann@25919
  1185
lemma abs_number_of:
haftmann@25919
  1186
  "abs(number_of x::'a::{ordered_idom,number_ring}) =
haftmann@25919
  1187
   (if number_of x < (0::'a) then -number_of x else number_of x)"
haftmann@25919
  1188
  by (simp add: abs_if)
haftmann@25919
  1189
haftmann@25919
  1190
haftmann@25919
  1191
text {* Re-orientation of the equation nnn=x *}
haftmann@25919
  1192
haftmann@25919
  1193
lemma number_of_reorient:
haftmann@25919
  1194
  "(number_of w = x) = (x = number_of w)"
haftmann@25919
  1195
  by auto
haftmann@25919
  1196
haftmann@25919
  1197
huffman@28958
  1198
subsubsection {* Simplification of arithmetic operations on integer constants. *}
haftmann@25919
  1199
haftmann@25919
  1200
lemmas arith_extra_simps [standard, simp] =
haftmann@25919
  1201
  number_of_add [symmetric]
huffman@28958
  1202
  number_of_minus [symmetric]
huffman@28958
  1203
  numeral_m1_eq_minus_1 [symmetric]
haftmann@25919
  1204
  number_of_mult [symmetric]
haftmann@25919
  1205
  diff_number_of_eq abs_number_of 
haftmann@25919
  1206
haftmann@25919
  1207
text {*
haftmann@25919
  1208
  For making a minimal simpset, one must include these default simprules.
haftmann@25919
  1209
  Also include @{text simp_thms}.
haftmann@25919
  1210
*}
haftmann@25919
  1211
haftmann@25919
  1212
lemmas arith_simps = 
huffman@26075
  1213
  normalize_bin_simps pred_bin_simps succ_bin_simps
huffman@26075
  1214
  add_bin_simps minus_bin_simps mult_bin_simps
haftmann@25919
  1215
  abs_zero abs_one arith_extra_simps
haftmann@25919
  1216
haftmann@25919
  1217
text {* Simplification of relational operations *}
haftmann@25919
  1218
huffman@28962
  1219
lemma less_number_of [simp]:
huffman@28962
  1220
  "(number_of x::'a::{ordered_idom,number_ring}) < number_of y \<longleftrightarrow> x < y"
huffman@28962
  1221
  unfolding number_of_eq by (rule of_int_less_iff)
huffman@28962
  1222
huffman@28962
  1223
lemma le_number_of [simp]:
huffman@28962
  1224
  "(number_of x::'a::{ordered_idom,number_ring}) \<le> number_of y \<longleftrightarrow> x \<le> y"
huffman@28962
  1225
  unfolding number_of_eq by (rule of_int_le_iff)
huffman@28962
  1226
huffman@28967
  1227
lemma eq_number_of [simp]:
huffman@28967
  1228
  "(number_of x::'a::{ring_char_0,number_ring}) = number_of y \<longleftrightarrow> x = y"
huffman@28967
  1229
  unfolding number_of_eq by (rule of_int_eq_iff)
huffman@28967
  1230
haftmann@25919
  1231
lemmas rel_simps [simp] = 
huffman@28962
  1232
  less_number_of less_bin_simps
huffman@28962
  1233
  le_number_of le_bin_simps
huffman@28988
  1234
  eq_number_of_eq eq_bin_simps
huffman@29039
  1235
  iszero_simps
haftmann@25919
  1236
haftmann@25919
  1237
huffman@28958
  1238
subsubsection {* Simplification of arithmetic when nested to the right. *}
haftmann@25919
  1239
haftmann@25919
  1240
lemma add_number_of_left [simp]:
haftmann@25919
  1241
  "number_of v + (number_of w + z) =
haftmann@25919
  1242
   (number_of(v + w) + z::'a::number_ring)"
haftmann@25919
  1243
  by (simp add: add_assoc [symmetric])
haftmann@25919
  1244
haftmann@25919
  1245
lemma mult_number_of_left [simp]:
haftmann@25919
  1246
  "number_of v * (number_of w * z) =
haftmann@25919
  1247
   (number_of(v * w) * z::'a::number_ring)"
haftmann@25919
  1248
  by (simp add: mult_assoc [symmetric])
haftmann@25919
  1249
haftmann@25919
  1250
lemma add_number_of_diff1:
haftmann@25919
  1251
  "number_of v + (number_of w - c) = 
haftmann@25919
  1252
  number_of(v + w) - (c::'a::number_ring)"
haftmann@25919
  1253
  by (simp add: diff_minus add_number_of_left)
haftmann@25919
  1254
haftmann@25919
  1255
lemma add_number_of_diff2 [simp]:
haftmann@25919
  1256
  "number_of v + (c - number_of w) =
haftmann@25919
  1257
   number_of (v + uminus w) + (c::'a::number_ring)"
nipkow@29667
  1258
by (simp add: algebra_simps diff_number_of_eq [symmetric])
haftmann@25919
  1259
haftmann@25919
  1260
haftmann@30652
  1261
haftmann@30652
  1262
haftmann@25919
  1263
subsection {* The Set of Integers *}
haftmann@25919
  1264
haftmann@25919
  1265
context ring_1
haftmann@25919
  1266
begin
haftmann@25919
  1267
haftmann@30652
  1268
definition Ints  :: "'a set" where
haftmann@28562
  1269
  [code del]: "Ints = range of_int"
haftmann@25919
  1270
haftmann@25919
  1271
notation (xsymbols)
haftmann@25919
  1272
  Ints  ("\<int>")
haftmann@25919
  1273
haftmann@25919
  1274
lemma Ints_0 [simp]: "0 \<in> \<int>"
haftmann@25919
  1275
apply (simp add: Ints_def)
haftmann@25919
  1276
apply (rule range_eqI)
haftmann@25919
  1277
apply (rule of_int_0 [symmetric])
haftmann@25919
  1278
done
haftmann@25919
  1279
haftmann@25919
  1280
lemma Ints_1 [simp]: "1 \<in> \<int>"
haftmann@25919
  1281
apply (simp add: Ints_def)
haftmann@25919
  1282
apply (rule range_eqI)
haftmann@25919
  1283
apply (rule of_int_1 [symmetric])
haftmann@25919
  1284
done
haftmann@25919
  1285
haftmann@25919
  1286
lemma Ints_add [simp]: "a \<in> \<int> \<Longrightarrow> b \<in> \<int> \<Longrightarrow> a + b \<in> \<int>"
haftmann@25919
  1287
apply (auto simp add: Ints_def)
haftmann@25919
  1288
apply (rule range_eqI)
haftmann@25919
  1289
apply (rule of_int_add [symmetric])
haftmann@25919
  1290
done
haftmann@25919
  1291
haftmann@25919
  1292
lemma Ints_minus [simp]: "a \<in> \<int> \<Longrightarrow> -a \<in> \<int>"
haftmann@25919
  1293
apply (auto simp add: Ints_def)
haftmann@25919
  1294
apply (rule range_eqI)
haftmann@25919
  1295
apply (rule of_int_minus [symmetric])
haftmann@25919
  1296
done
haftmann@25919
  1297
haftmann@25919
  1298
lemma Ints_mult [simp]: "a \<in> \<int> \<Longrightarrow> b \<in> \<int> \<Longrightarrow> a * b \<in> \<int>"
haftmann@25919
  1299
apply (auto simp add: Ints_def)
haftmann@25919
  1300
apply (rule range_eqI)
haftmann@25919
  1301
apply (rule of_int_mult [symmetric])
haftmann@25919
  1302
done
haftmann@25919
  1303
haftmann@25919
  1304
lemma Ints_cases [cases set: Ints]:
haftmann@25919
  1305
  assumes "q \<in> \<int>"
haftmann@25919
  1306
  obtains (of_int) z where "q = of_int z"
haftmann@25919
  1307
  unfolding Ints_def
haftmann@25919
  1308
proof -
haftmann@25919
  1309
  from `q \<in> \<int>` have "q \<in> range of_int" unfolding Ints_def .
haftmann@25919
  1310
  then obtain z where "q = of_int z" ..
haftmann@25919
  1311
  then show thesis ..
haftmann@25919
  1312
qed
haftmann@25919
  1313
haftmann@25919
  1314
lemma Ints_induct [case_names of_int, induct set: Ints]:
haftmann@25919
  1315
  "q \<in> \<int> \<Longrightarrow> (\<And>z. P (of_int z)) \<Longrightarrow> P q"
haftmann@25919
  1316
  by (rule Ints_cases) auto
haftmann@25919
  1317
haftmann@25919
  1318
end
haftmann@25919
  1319
haftmann@25919
  1320
lemma Ints_diff [simp]: "a \<in> \<int> \<Longrightarrow> b \<in> \<int> \<Longrightarrow> a-b \<in> \<int>"
haftmann@25919
  1321
apply (auto simp add: Ints_def)
haftmann@25919
  1322
apply (rule range_eqI)
haftmann@25919
  1323
apply (rule of_int_diff [symmetric])
haftmann@25919
  1324
done
haftmann@25919
  1325
haftmann@25919
  1326
text {* The premise involving @{term Ints} prevents @{term "a = 1/2"}. *}
haftmann@25919
  1327
haftmann@25919
  1328
lemma Ints_double_eq_0_iff:
haftmann@25919
  1329
  assumes in_Ints: "a \<in> Ints"
haftmann@25919
  1330
  shows "(a + a = 0) = (a = (0::'a::ring_char_0))"
haftmann@25919
  1331
proof -
haftmann@25919
  1332
  from in_Ints have "a \<in> range of_int" unfolding Ints_def [symmetric] .
haftmann@25919
  1333
  then obtain z where a: "a = of_int z" ..
haftmann@25919
  1334
  show ?thesis
haftmann@25919
  1335
  proof
haftmann@25919
  1336
    assume "a = 0"
haftmann@25919
  1337
    thus "a + a = 0" by simp
haftmann@25919
  1338
  next
haftmann@25919
  1339
    assume eq: "a + a = 0"
haftmann@25919
  1340
    hence "of_int (z + z) = (of_int 0 :: 'a)" by (simp add: a)
haftmann@25919
  1341
    hence "z + z = 0" by (simp only: of_int_eq_iff)
haftmann@25919
  1342
    hence "z = 0" by (simp only: double_eq_0_iff)
haftmann@25919
  1343
    thus "a = 0" by (simp add: a)
haftmann@25919
  1344
  qed
haftmann@25919
  1345
qed
haftmann@25919
  1346
haftmann@25919
  1347
lemma Ints_odd_nonzero:
haftmann@25919
  1348
  assumes in_Ints: "a \<in> Ints"
haftmann@25919
  1349
  shows "1 + a + a \<noteq> (0::'a::ring_char_0)"
haftmann@25919
  1350
proof -
haftmann@25919
  1351
  from in_Ints have "a \<in> range of_int" unfolding Ints_def [symmetric] .
haftmann@25919
  1352
  then obtain z where a: "a = of_int z" ..
haftmann@25919
  1353
  show ?thesis
haftmann@25919
  1354
  proof
haftmann@25919
  1355
    assume eq: "1 + a + a = 0"
haftmann@25919
  1356
    hence "of_int (1 + z + z) = (of_int 0 :: 'a)" by (simp add: a)
haftmann@25919
  1357
    hence "1 + z + z = 0" by (simp only: of_int_eq_iff)
haftmann@25919
  1358
    with odd_nonzero show False by blast
haftmann@25919
  1359
  qed
haftmann@25919
  1360
qed 
haftmann@25919
  1361
haftmann@25919
  1362
lemma Ints_number_of:
haftmann@25919
  1363
  "(number_of w :: 'a::number_ring) \<in> Ints"
haftmann@25919
  1364
  unfolding number_of_eq Ints_def by simp
haftmann@25919
  1365
haftmann@25919
  1366
lemma Ints_odd_less_0: 
haftmann@25919
  1367
  assumes in_Ints: "a \<in> Ints"
haftmann@25919
  1368
  shows "(1 + a + a < 0) = (a < (0::'a::ordered_idom))";
haftmann@25919
  1369
proof -
haftmann@25919
  1370
  from in_Ints have "a \<in> range of_int" unfolding Ints_def [symmetric] .
haftmann@25919
  1371
  then obtain z where a: "a = of_int z" ..
haftmann@25919
  1372
  hence "((1::'a) + a + a < 0) = (of_int (1 + z + z) < (of_int 0 :: 'a))"
haftmann@25919
  1373
    by (simp add: a)
haftmann@25919
  1374
  also have "... = (z < 0)" by (simp only: of_int_less_iff odd_less_0)
haftmann@25919
  1375
  also have "... = (a < 0)" by (simp add: a)
haftmann@25919
  1376
  finally show ?thesis .
haftmann@25919
  1377
qed
haftmann@25919
  1378
haftmann@25919
  1379
haftmann@25919
  1380
subsection {* @{term setsum} and @{term setprod} *}
haftmann@25919
  1381
haftmann@25919
  1382
lemma of_nat_setsum: "of_nat (setsum f A) = (\<Sum>x\<in>A. of_nat(f x))"
haftmann@25919
  1383
  apply (cases "finite A")
haftmann@25919
  1384
  apply (erule finite_induct, auto)
haftmann@25919
  1385
  done
haftmann@25919
  1386
haftmann@25919
  1387
lemma of_int_setsum: "of_int (setsum f A) = (\<Sum>x\<in>A. of_int(f x))"
haftmann@25919
  1388
  apply (cases "finite A")
haftmann@25919
  1389
  apply (erule finite_induct, auto)
haftmann@25919
  1390
  done
haftmann@25919
  1391
haftmann@25919
  1392
lemma of_nat_setprod: "of_nat (setprod f A) = (\<Prod>x\<in>A. of_nat(f x))"
haftmann@25919
  1393
  apply (cases "finite A")
haftmann@25919
  1394
  apply (erule finite_induct, auto simp add: of_nat_mult)
haftmann@25919
  1395
  done
haftmann@25919
  1396
haftmann@25919
  1397
lemma of_int_setprod: "of_int (setprod f A) = (\<Prod>x\<in>A. of_int(f x))"
haftmann@25919
  1398
  apply (cases "finite A")
haftmann@25919
  1399
  apply (erule finite_induct, auto)
haftmann@25919
  1400
  done
haftmann@25919
  1401
haftmann@25919
  1402
lemmas int_setsum = of_nat_setsum [where 'a=int]
haftmann@25919
  1403
lemmas int_setprod = of_nat_setprod [where 'a=int]
haftmann@25919
  1404
haftmann@25919
  1405
haftmann@25919
  1406
subsection{*Inequality Reasoning for the Arithmetic Simproc*}
haftmann@25919
  1407
haftmann@25919
  1408
lemma add_numeral_0: "Numeral0 + a = (a::'a::number_ring)"
haftmann@25919
  1409
by simp 
haftmann@25919
  1410
haftmann@25919
  1411
lemma add_numeral_0_right: "a + Numeral0 = (a::'a::number_ring)"
haftmann@25919
  1412
by simp
haftmann@25919
  1413
haftmann@25919
  1414
lemma mult_numeral_1: "Numeral1 * a = (a::'a::number_ring)"
haftmann@25919
  1415
by simp 
haftmann@25919
  1416
haftmann@25919
  1417
lemma mult_numeral_1_right: "a * Numeral1 = (a::'a::number_ring)"
haftmann@25919
  1418
by simp
haftmann@25919
  1419
haftmann@25919
  1420
lemma divide_numeral_1: "a / Numeral1 = (a::'a::{number_ring,field})"
haftmann@25919
  1421
by simp
haftmann@25919
  1422
haftmann@25919
  1423
lemma inverse_numeral_1:
haftmann@25919
  1424
  "inverse Numeral1 = (Numeral1::'a::{number_ring,field})"
haftmann@25919
  1425
by simp
haftmann@25919
  1426
haftmann@25919
  1427
text{*Theorem lists for the cancellation simprocs. The use of binary numerals
haftmann@25919
  1428
for 0 and 1 reduces the number of special cases.*}
haftmann@25919
  1429
haftmann@25919
  1430
lemmas add_0s = add_numeral_0 add_numeral_0_right
haftmann@25919
  1431
lemmas mult_1s = mult_numeral_1 mult_numeral_1_right 
haftmann@25919
  1432
                 mult_minus1 mult_minus1_right
haftmann@25919
  1433
haftmann@25919
  1434
haftmann@25919
  1435
subsection{*Special Arithmetic Rules for Abstract 0 and 1*}
haftmann@25919
  1436
haftmann@25919
  1437
text{*Arithmetic computations are defined for binary literals, which leaves 0
haftmann@25919
  1438
and 1 as special cases. Addition already has rules for 0, but not 1.
haftmann@25919
  1439
Multiplication and unary minus already have rules for both 0 and 1.*}
haftmann@25919
  1440
haftmann@25919
  1441
haftmann@25919
  1442
lemma binop_eq: "[|f x y = g x y; x = x'; y = y'|] ==> f x' y' = g x' y'"
haftmann@25919
  1443
by simp
haftmann@25919
  1444
haftmann@25919
  1445
haftmann@25919
  1446
lemmas add_number_of_eq = number_of_add [symmetric]
haftmann@25919
  1447
haftmann@25919
  1448
text{*Allow 1 on either or both sides*}
haftmann@25919
  1449
lemma one_add_one_is_two: "1 + 1 = (2::'a::number_ring)"
haftmann@25919
  1450
by (simp del: numeral_1_eq_1 add: numeral_1_eq_1 [symmetric] add_number_of_eq)
haftmann@25919
  1451
haftmann@25919
  1452
lemmas add_special =
haftmann@25919
  1453
    one_add_one_is_two
haftmann@25919
  1454
    binop_eq [of "op +", OF add_number_of_eq numeral_1_eq_1 refl, standard]
haftmann@25919
  1455
    binop_eq [of "op +", OF add_number_of_eq refl numeral_1_eq_1, standard]
haftmann@25919
  1456
haftmann@25919
  1457
text{*Allow 1 on either or both sides (1-1 already simplifies to 0)*}
haftmann@25919
  1458
lemmas diff_special =
haftmann@25919
  1459
    binop_eq [of "op -", OF diff_number_of_eq numeral_1_eq_1 refl, standard]
haftmann@25919
  1460
    binop_eq [of "op -", OF diff_number_of_eq refl numeral_1_eq_1, standard]
haftmann@25919
  1461
haftmann@25919
  1462
text{*Allow 0 or 1 on either side with a binary numeral on the other*}
haftmann@25919
  1463
lemmas eq_special =
haftmann@25919
  1464
    binop_eq [of "op =", OF eq_number_of_eq numeral_0_eq_0 refl, standard]
haftmann@25919
  1465
    binop_eq [of "op =", OF eq_number_of_eq numeral_1_eq_1 refl, standard]
haftmann@25919
  1466
    binop_eq [of "op =", OF eq_number_of_eq refl numeral_0_eq_0, standard]
haftmann@25919
  1467
    binop_eq [of "op =", OF eq_number_of_eq refl numeral_1_eq_1, standard]
haftmann@25919
  1468
haftmann@25919
  1469
text{*Allow 0 or 1 on either side with a binary numeral on the other*}
haftmann@25919
  1470
lemmas less_special =
huffman@28984
  1471
  binop_eq [of "op <", OF less_number_of numeral_0_eq_0 refl, standard]
huffman@28984
  1472
  binop_eq [of "op <", OF less_number_of numeral_1_eq_1 refl, standard]
huffman@28984
  1473
  binop_eq [of "op <", OF less_number_of refl numeral_0_eq_0, standard]
huffman@28984
  1474
  binop_eq [of "op <", OF less_number_of refl numeral_1_eq_1, standard]
haftmann@25919
  1475
haftmann@25919
  1476
text{*Allow 0 or 1 on either side with a binary numeral on the other*}
haftmann@25919
  1477
lemmas le_special =
huffman@28984
  1478
    binop_eq [of "op \<le>", OF le_number_of numeral_0_eq_0 refl, standard]
huffman@28984
  1479
    binop_eq [of "op \<le>", OF le_number_of numeral_1_eq_1 refl, standard]
huffman@28984
  1480
    binop_eq [of "op \<le>", OF le_number_of refl numeral_0_eq_0, standard]
huffman@28984
  1481
    binop_eq [of "op \<le>", OF le_number_of refl numeral_1_eq_1, standard]
haftmann@25919
  1482
haftmann@25919
  1483
lemmas arith_special[simp] = 
haftmann@25919
  1484
       add_special diff_special eq_special less_special le_special
haftmann@25919
  1485
haftmann@25919
  1486
haftmann@25919
  1487
lemma min_max_01: "min (0::int) 1 = 0 & min (1::int) 0 = 0 &
haftmann@25919
  1488
                   max (0::int) 1 = 1 & max (1::int) 0 = 1"
haftmann@25919
  1489
by(simp add:min_def max_def)
haftmann@25919
  1490
haftmann@25919
  1491
lemmas min_max_special[simp] =
haftmann@25919
  1492
 min_max_01
haftmann@25919
  1493
 max_def[of "0::int" "number_of v", standard, simp]
haftmann@25919
  1494
 min_def[of "0::int" "number_of v", standard, simp]
haftmann@25919
  1495
 max_def[of "number_of u" "0::int", standard, simp]
haftmann@25919
  1496
 min_def[of "number_of u" "0::int", standard, simp]
haftmann@25919
  1497
 max_def[of "1::int" "number_of v", standard, simp]
haftmann@25919
  1498
 min_def[of "1::int" "number_of v", standard, simp]
haftmann@25919
  1499
 max_def[of "number_of u" "1::int", standard, simp]
haftmann@25919
  1500
 min_def[of "number_of u" "1::int", standard, simp]
haftmann@25919
  1501
haftmann@25919
  1502
text {* Legacy theorems *}
haftmann@25919
  1503
haftmann@25919
  1504
lemmas zle_int = of_nat_le_iff [where 'a=int]
haftmann@25919
  1505
lemmas int_int_eq = of_nat_eq_iff [where 'a=int]
haftmann@25919
  1506
huffman@30802
  1507
subsection {* Setting up simplification procedures *}
huffman@30802
  1508
huffman@30802
  1509
lemmas int_arith_rules =
huffman@30802
  1510
  neg_le_iff_le numeral_0_eq_0 numeral_1_eq_1
huffman@30802
  1511
  minus_zero diff_minus left_minus right_minus
huffman@30802
  1512
  mult_zero_left mult_zero_right mult_Bit1 mult_1_right
huffman@30802
  1513
  mult_minus_left mult_minus_right
huffman@30802
  1514
  minus_add_distrib minus_minus mult_assoc
huffman@30802
  1515
  of_nat_0 of_nat_1 of_nat_Suc of_nat_add of_nat_mult
huffman@30802
  1516
  of_int_0 of_int_1 of_int_add of_int_mult
huffman@30802
  1517
haftmann@28952
  1518
use "Tools/int_arith.ML"
haftmann@30496
  1519
declaration {* K Int_Arith.setup *}
haftmann@25919
  1520
huffman@31024
  1521
setup {*
huffman@31024
  1522
  ReorientProc.add
huffman@31024
  1523
    (fn Const(@{const_name number_of}, _) $ _ => true | _ => false)
huffman@31024
  1524
*}
huffman@31024
  1525
huffman@31024
  1526
simproc_setup reorient_numeral ("number_of w = x") = ReorientProc.proc
huffman@31024
  1527
haftmann@25919
  1528
haftmann@25919
  1529
subsection{*Lemmas About Small Numerals*}
haftmann@25919
  1530
haftmann@25919
  1531
lemma of_int_m1 [simp]: "of_int -1 = (-1 :: 'a :: number_ring)"
haftmann@25919
  1532
proof -
haftmann@25919
  1533
  have "(of_int -1 :: 'a) = of_int (- 1)" by simp
haftmann@25919
  1534
  also have "... = - of_int 1" by (simp only: of_int_minus)
haftmann@25919
  1535
  also have "... = -1" by simp
haftmann@25919
  1536
  finally show ?thesis .
haftmann@25919
  1537
qed
haftmann@25919
  1538
haftmann@25919
  1539
lemma abs_minus_one [simp]: "abs (-1) = (1::'a::{ordered_idom,number_ring})"
haftmann@25919
  1540
by (simp add: abs_if)
haftmann@25919
  1541
haftmann@25919
  1542
lemma abs_power_minus_one [simp]:
haftmann@31001
  1543
  "abs(-1 ^ n) = (1::'a::{ordered_idom,number_ring})"
haftmann@25919
  1544
by (simp add: power_abs)
haftmann@25919
  1545
huffman@30000
  1546
lemma of_int_number_of_eq [simp]:
haftmann@25919
  1547
     "of_int (number_of v) = (number_of v :: 'a :: number_ring)"
haftmann@25919
  1548
by (simp add: number_of_eq) 
haftmann@25919
  1549
haftmann@25919
  1550
text{*Lemmas for specialist use, NOT as default simprules*}
haftmann@25919
  1551
lemma mult_2: "2 * z = (z+z::'a::number_ring)"
haftmann@25919
  1552
proof -
haftmann@25919
  1553
  have "2*z = (1 + 1)*z" by simp
haftmann@25919
  1554
  also have "... = z+z" by (simp add: left_distrib)
haftmann@25919
  1555
  finally show ?thesis .
haftmann@25919
  1556
qed
haftmann@25919
  1557
haftmann@25919
  1558
lemma mult_2_right: "z * 2 = (z+z::'a::number_ring)"
haftmann@25919
  1559
by (subst mult_commute, rule mult_2)
haftmann@25919
  1560
haftmann@25919
  1561
haftmann@25919
  1562
subsection{*More Inequality Reasoning*}
haftmann@25919
  1563
haftmann@25919
  1564
lemma zless_add1_eq: "(w < z + (1::int)) = (w<z | w=z)"
haftmann@25919
  1565
by arith
haftmann@25919
  1566
haftmann@25919
  1567
lemma add1_zle_eq: "(w + (1::int) \<le> z) = (w<z)"
haftmann@25919
  1568
by arith
haftmann@25919
  1569
haftmann@25919
  1570
lemma zle_diff1_eq [simp]: "(w \<le> z - (1::int)) = (w<z)"
haftmann@25919
  1571
by arith
haftmann@25919
  1572
haftmann@25919
  1573
lemma zle_add1_eq_le [simp]: "(w < z + (1::int)) = (w\<le>z)"
haftmann@25919
  1574
by arith
haftmann@25919
  1575
haftmann@25919
  1576
lemma int_one_le_iff_zero_less: "((1::int) \<le> z) = (0 < z)"
haftmann@25919
  1577
by arith
haftmann@25919
  1578
haftmann@25919
  1579
huffman@28958
  1580
subsection{*The functions @{term nat} and @{term int}*}
haftmann@25919
  1581
haftmann@25919
  1582
text{*Simplify the terms @{term "int 0"}, @{term "int(Suc 0)"} and
haftmann@25919
  1583
  @{term "w + - z"}*}
haftmann@25919
  1584
declare Zero_int_def [symmetric, simp]
haftmann@25919
  1585
declare One_int_def [symmetric, simp]
haftmann@25919
  1586
haftmann@25919
  1587
lemmas diff_int_def_symmetric = diff_int_def [symmetric, simp]
haftmann@25919
  1588
haftmann@25919
  1589
lemma nat_0: "nat 0 = 0"
haftmann@25919
  1590
by (simp add: nat_eq_iff)
haftmann@25919
  1591
haftmann@25919
  1592
lemma nat_1: "nat 1 = Suc 0"
haftmann@25919
  1593
by (subst nat_eq_iff, simp)
haftmann@25919
  1594
haftmann@25919
  1595
lemma nat_2: "nat 2 = Suc (Suc 0)"
haftmann@25919
  1596
by (subst nat_eq_iff, simp)
haftmann@25919
  1597
haftmann@25919
  1598
lemma one_less_nat_eq [simp]: "(Suc 0 < nat z) = (1 < z)"
haftmann@25919
  1599
apply (insert zless_nat_conj [of 1 z])
haftmann@25919
  1600
apply (auto simp add: nat_1)
haftmann@25919
  1601
done
haftmann@25919
  1602
haftmann@25919
  1603
text{*This simplifies expressions of the form @{term "int n = z"} where
haftmann@25919
  1604
      z is an integer literal.*}
haftmann@25919
  1605
lemmas int_eq_iff_number_of [simp] = int_eq_iff [of _ "number_of v", standard]
haftmann@25919
  1606
haftmann@25919
  1607
lemma split_nat [arith_split]:
haftmann@25919
  1608
  "P(nat(i::int)) = ((\<forall>n. i = of_nat n \<longrightarrow> P n) & (i < 0 \<longrightarrow> P 0))"
haftmann@25919
  1609
  (is "?P = (?L & ?R)")
haftmann@25919
  1610
proof (cases "i < 0")
haftmann@25919
  1611
  case True thus ?thesis by auto
haftmann@25919
  1612
next
haftmann@25919
  1613
  case False
haftmann@25919
  1614
  have "?P = ?L"
haftmann@25919
  1615
  proof
haftmann@25919
  1616
    assume ?P thus ?L using False by clarsimp
haftmann@25919
  1617
  next
haftmann@25919
  1618
    assume ?L thus ?P using False by simp
haftmann@25919
  1619
  qed
haftmann@25919
  1620
  with False show ?thesis by simp
haftmann@25919
  1621
qed
haftmann@25919
  1622
haftmann@25919
  1623
context ring_1
haftmann@25919
  1624
begin
haftmann@25919
  1625
blanchet@29955
  1626
lemma of_int_of_nat [nitpick_const_simp]:
haftmann@25919
  1627
  "of_int k = (if k < 0 then - of_nat (nat (- k)) else of_nat (nat k))"
haftmann@25919
  1628
proof (cases "k < 0")
haftmann@25919
  1629
  case True then have "0 \<le> - k" by simp
haftmann@25919
  1630
  then have "of_nat (nat (- k)) = of_int (- k)" by (rule of_nat_nat)
haftmann@25919
  1631
  with True show ?thesis by simp
haftmann@25919
  1632
next
haftmann@25919
  1633
  case False then show ?thesis by (simp add: not_less of_nat_nat)
haftmann@25919
  1634
qed
haftmann@25919
  1635
haftmann@25919
  1636
end
haftmann@25919
  1637
haftmann@25919
  1638
lemma nat_mult_distrib:
haftmann@25919
  1639
  fixes z z' :: int
haftmann@25919
  1640
  assumes "0 \<le> z"
haftmann@25919
  1641
  shows "nat (z * z') = nat z * nat z'"
haftmann@25919
  1642
proof (cases "0 \<le> z'")
haftmann@25919
  1643
  case False with assms have "z * z' \<le> 0"
haftmann@25919
  1644
    by (simp add: not_le mult_le_0_iff)
haftmann@25919
  1645
  then have "nat (z * z') = 0" by simp
haftmann@25919
  1646
  moreover from False have "nat z' = 0" by simp
haftmann@25919
  1647
  ultimately show ?thesis by simp
haftmann@25919
  1648
next
haftmann@25919
  1649
  case True with assms have ge_0: "z * z' \<ge> 0" by (simp add: zero_le_mult_iff)
haftmann@25919
  1650
  show ?thesis
haftmann@25919
  1651
    by (rule injD [of "of_nat :: nat \<Rightarrow> int", OF inj_of_nat])
haftmann@25919
  1652
      (simp only: of_nat_mult of_nat_nat [OF True]
haftmann@25919
  1653
         of_nat_nat [OF assms] of_nat_nat [OF ge_0], simp)
haftmann@25919
  1654
qed
haftmann@25919
  1655
haftmann@25919
  1656
lemma nat_mult_distrib_neg: "z \<le> (0::int) ==> nat(z*z') = nat(-z) * nat(-z')"
haftmann@25919
  1657
apply (rule trans)
haftmann@25919
  1658
apply (rule_tac [2] nat_mult_distrib, auto)
haftmann@25919
  1659
done
haftmann@25919
  1660
haftmann@25919
  1661
lemma nat_abs_mult_distrib: "nat (abs (w * z)) = nat (abs w) * nat (abs z)"
haftmann@25919
  1662
apply (cases "z=0 | w=0")
haftmann@25919
  1663
apply (auto simp add: abs_if nat_mult_distrib [symmetric] 
haftmann@25919
  1664
                      nat_mult_distrib_neg [symmetric] mult_less_0_iff)
haftmann@25919
  1665
done
haftmann@25919
  1666
haftmann@25919
  1667
haftmann@25919
  1668
subsection "Induction principles for int"
haftmann@25919
  1669
haftmann@25919
  1670
text{*Well-founded segments of the integers*}
haftmann@25919
  1671
haftmann@25919
  1672
definition
haftmann@25919
  1673
  int_ge_less_than  ::  "int => (int * int) set"
haftmann@25919
  1674
where
haftmann@25919
  1675
  "int_ge_less_than d = {(z',z). d \<le> z' & z' < z}"
haftmann@25919
  1676
haftmann@25919
  1677
theorem wf_int_ge_less_than: "wf (int_ge_less_than d)"
haftmann@25919
  1678
proof -
haftmann@25919
  1679
  have "int_ge_less_than d \<subseteq> measure (%z. nat (z-d))"
haftmann@25919
  1680
    by (auto simp add: int_ge_less_than_def)
haftmann@25919
  1681
  thus ?thesis 
haftmann@25919
  1682
    by (rule wf_subset [OF wf_measure]) 
haftmann@25919
  1683
qed
haftmann@25919
  1684
haftmann@25919
  1685
text{*This variant looks odd, but is typical of the relations suggested
haftmann@25919
  1686
by RankFinder.*}
haftmann@25919
  1687
haftmann@25919
  1688
definition
haftmann@25919
  1689
  int_ge_less_than2 ::  "int => (int * int) set"
haftmann@25919
  1690
where
haftmann@25919
  1691
  "int_ge_less_than2 d = {(z',z). d \<le> z & z' < z}"
haftmann@25919
  1692
haftmann@25919
  1693
theorem wf_int_ge_less_than2: "wf (int_ge_less_than2 d)"
haftmann@25919
  1694
proof -
haftmann@25919
  1695
  have "int_ge_less_than2 d \<subseteq> measure (%z. nat (1+z-d))" 
haftmann@25919
  1696
    by (auto simp add: int_ge_less_than2_def)
haftmann@25919
  1697
  thus ?thesis 
haftmann@25919
  1698
    by (rule wf_subset [OF wf_measure]) 
haftmann@25919
  1699
qed
haftmann@25919
  1700
haftmann@25919
  1701
abbreviation
haftmann@25919
  1702
  int :: "nat \<Rightarrow> int"
haftmann@25919
  1703
where
haftmann@25919
  1704
  "int \<equiv> of_nat"
haftmann@25919
  1705
haftmann@25919
  1706
(* `set:int': dummy construction *)
haftmann@25919
  1707
theorem int_ge_induct [case_names base step, induct set: int]:
haftmann@25919
  1708
  fixes i :: int
haftmann@25919
  1709
  assumes ge: "k \<le> i" and
haftmann@25919
  1710
    base: "P k" and
haftmann@25919
  1711
    step: "\<And>i. k \<le> i \<Longrightarrow> P i \<Longrightarrow> P (i + 1)"
haftmann@25919
  1712
  shows "P i"
haftmann@25919
  1713
proof -
haftmann@25919
  1714
  { fix n have "\<And>i::int. n = nat(i-k) \<Longrightarrow> k \<le> i \<Longrightarrow> P i"
haftmann@25919
  1715
    proof (induct n)
haftmann@25919
  1716
      case 0
haftmann@25919
  1717
      hence "i = k" by arith
haftmann@25919
  1718
      thus "P i" using base by simp
haftmann@25919
  1719
    next
haftmann@25919
  1720
      case (Suc n)
haftmann@25919
  1721
      then have "n = nat((i - 1) - k)" by arith
haftmann@25919
  1722
      moreover
haftmann@25919
  1723
      have ki1: "k \<le> i - 1" using Suc.prems by arith
haftmann@25919
  1724
      ultimately
haftmann@25919
  1725
      have "P(i - 1)" by(rule Suc.hyps)
haftmann@25919
  1726
      from step[OF ki1 this] show ?case by simp
haftmann@25919
  1727
    qed
haftmann@25919
  1728
  }
haftmann@25919
  1729
  with ge show ?thesis by fast
haftmann@25919
  1730
qed
haftmann@25919
  1731
haftmann@25928
  1732
(* `set:int': dummy construction *)
haftmann@25928
  1733
theorem int_gr_induct [case_names base step, induct set: int]:
haftmann@25919
  1734
  assumes gr: "k < (i::int)" and
haftmann@25919
  1735
        base: "P(k+1)" and
haftmann@25919
  1736
        step: "\<And>i. \<lbrakk>k < i; P i\<rbrakk> \<Longrightarrow> P(i+1)"
haftmann@25919
  1737
  shows "P i"
haftmann@25919
  1738
apply(rule int_ge_induct[of "k + 1"])
haftmann@25919
  1739
  using gr apply arith
haftmann@25919
  1740
 apply(rule base)
haftmann@25919
  1741
apply (rule step, simp+)
haftmann@25919
  1742
done
haftmann@25919
  1743
haftmann@25919
  1744
theorem int_le_induct[consumes 1,case_names base step]:
haftmann@25919
  1745
  assumes le: "i \<le> (k::int)" and
haftmann@25919
  1746
        base: "P(k)" and
haftmann@25919
  1747
        step: "\<And>i. \<lbrakk>i \<le> k; P i\<rbrakk> \<Longrightarrow> P(i - 1)"
haftmann@25919
  1748
  shows "P i"
haftmann@25919
  1749
proof -
haftmann@25919
  1750
  { fix n have "\<And>i::int. n = nat(k-i) \<Longrightarrow> i \<le> k \<Longrightarrow> P i"
haftmann@25919
  1751
    proof (induct n)
haftmann@25919
  1752
      case 0
haftmann@25919
  1753
      hence "i = k" by arith
haftmann@25919
  1754
      thus "P i" using base by simp
haftmann@25919
  1755
    next
haftmann@25919
  1756
      case (Suc n)
haftmann@25919
  1757
      hence "n = nat(k - (i+1))" by arith
haftmann@25919
  1758
      moreover
haftmann@25919
  1759
      have ki1: "i + 1 \<le> k" using Suc.prems by arith
haftmann@25919
  1760
      ultimately
haftmann@25919
  1761
      have "P(i+1)" by(rule Suc.hyps)
haftmann@25919
  1762
      from step[OF ki1 this] show ?case by simp
haftmann@25919
  1763
    qed
haftmann@25919
  1764
  }
haftmann@25919
  1765
  with le show ?thesis by fast
haftmann@25919
  1766
qed
haftmann@25919
  1767
haftmann@25919
  1768
theorem int_less_induct [consumes 1,case_names base step]:
haftmann@25919
  1769
  assumes less: "(i::int) < k" and
haftmann@25919
  1770
        base: "P(k - 1)" and
haftmann@25919
  1771
        step: "\<And>i. \<lbrakk>i < k; P i\<rbrakk> \<Longrightarrow> P(i - 1)"
haftmann@25919
  1772
  shows "P i"
haftmann@25919
  1773
apply(rule int_le_induct[of _ "k - 1"])
haftmann@25919
  1774
  using less apply arith
haftmann@25919
  1775
 apply(rule base)
haftmann@25919
  1776
apply (rule step, simp+)
haftmann@25919
  1777
done
haftmann@25919
  1778
haftmann@25919
  1779
subsection{*Intermediate value theorems*}
haftmann@25919
  1780
haftmann@25919
  1781
lemma int_val_lemma:
haftmann@25919
  1782
     "(\<forall>i<n::nat. abs(f(i+1) - f i) \<le> 1) -->  
haftmann@25919
  1783
      f 0 \<le> k --> k \<le> f n --> (\<exists>i \<le> n. f i = (k::int))"
huffman@30079
  1784
unfolding One_nat_def
haftmann@27106
  1785
apply (induct n, simp)
haftmann@25919
  1786
apply (intro strip)
haftmann@25919
  1787
apply (erule impE, simp)
haftmann@25919
  1788
apply (erule_tac x = n in allE, simp)
huffman@30079
  1789
apply (case_tac "k = f (Suc n)")
haftmann@27106
  1790
apply force
haftmann@25919
  1791
apply (erule impE)
haftmann@25919
  1792
 apply (simp add: abs_if split add: split_if_asm)
haftmann@25919
  1793
apply (blast intro: le_SucI)
haftmann@25919
  1794
done
haftmann@25919
  1795
haftmann@25919
  1796
lemmas nat0_intermed_int_val = int_val_lemma [rule_format (no_asm)]
haftmann@25919
  1797
haftmann@25919
  1798
lemma nat_intermed_int_val:
haftmann@25919
  1799
     "[| \<forall>i. m \<le> i & i < n --> abs(f(i + 1::nat) - f i) \<le> 1; m < n;  
haftmann@25919
  1800
         f m \<le> k; k \<le> f n |] ==> ? i. m \<le> i & i \<le> n & f i = (k::int)"
haftmann@25919
  1801
apply (cut_tac n = "n-m" and f = "%i. f (i+m) " and k = k 
haftmann@25919
  1802
       in int_val_lemma)
huffman@30079
  1803
unfolding One_nat_def
haftmann@25919
  1804
apply simp
haftmann@25919
  1805
apply (erule exE)
haftmann@25919
  1806
apply (rule_tac x = "i+m" in exI, arith)
haftmann@25919
  1807
done
haftmann@25919
  1808
haftmann@25919
  1809
haftmann@25919
  1810
subsection{*Products and 1, by T. M. Rasmussen*}
haftmann@25919
  1811
haftmann@25919
  1812
lemma zabs_less_one_iff [simp]: "(\<bar>z\<bar> < 1) = (z = (0::int))"
haftmann@25919
  1813
by arith
haftmann@25919
  1814
haftmann@25919
  1815
lemma abs_zmult_eq_1: "(\<bar>m * n\<bar> = 1) ==> \<bar>m\<bar> = (1::int)"
haftmann@25919
  1816
apply (cases "\<bar>n\<bar>=1") 
haftmann@25919
  1817
apply (simp add: abs_mult) 
haftmann@25919
  1818
apply (rule ccontr) 
haftmann@25919
  1819
apply (auto simp add: linorder_neq_iff abs_mult) 
haftmann@25919
  1820
apply (subgoal_tac "2 \<le> \<bar>m\<bar> & 2 \<le> \<bar>n\<bar>")
haftmann@25919
  1821
 prefer 2 apply arith 
haftmann@25919
  1822
apply (subgoal_tac "2*2 \<le> \<bar>m\<bar> * \<bar>n\<bar>", simp) 
haftmann@25919
  1823
apply (rule mult_mono, auto) 
haftmann@25919
  1824
done
haftmann@25919
  1825
haftmann@25919
  1826
lemma pos_zmult_eq_1_iff_lemma: "(m * n = 1) ==> m = (1::int) | m = -1"
haftmann@25919
  1827
by (insert abs_zmult_eq_1 [of m n], arith)
haftmann@25919
  1828
haftmann@25919
  1829
lemma pos_zmult_eq_1_iff: "0 < (m::int) ==> (m * n = 1) = (m = 1 & n = 1)"
haftmann@25919
  1830
apply (auto dest: pos_zmult_eq_1_iff_lemma) 
haftmann@25919
  1831
apply (simp add: mult_commute [of m]) 
haftmann@25919
  1832
apply (frule pos_zmult_eq_1_iff_lemma, auto) 
haftmann@25919
  1833
done
haftmann@25919
  1834
haftmann@25919
  1835
lemma zmult_eq_1_iff: "(m*n = (1::int)) = ((m = 1 & n = 1) | (m = -1 & n = -1))"
haftmann@25919
  1836
apply (rule iffI) 
haftmann@25919
  1837
 apply (frule pos_zmult_eq_1_iff_lemma)
haftmann@25919
  1838
 apply (simp add: mult_commute [of m]) 
haftmann@25919
  1839
 apply (frule pos_zmult_eq_1_iff_lemma, auto) 
haftmann@25919
  1840
done
haftmann@25919
  1841
haftmann@25919
  1842
(* Could be simplified but Presburger only becomes available too late *)
haftmann@25919
  1843
lemma infinite_UNIV_int: "~finite(UNIV::int set)"
haftmann@25919
  1844
proof
haftmann@25919
  1845
  assume "finite(UNIV::int set)"
haftmann@25919
  1846
  moreover have "~(EX i::int. 2*i = 1)"
haftmann@25919
  1847
    by (auto simp: pos_zmult_eq_1_iff)
haftmann@25919
  1848
  ultimately show False using finite_UNIV_inj_surj[of "%n::int. n+n"]
haftmann@25919
  1849
    by (simp add:inj_on_def surj_def) (blast intro:sym)
haftmann@25919
  1850
qed
haftmann@25919
  1851
haftmann@25919
  1852
haftmann@30652
  1853
subsection {* Further theorems on numerals *}
haftmann@30652
  1854
haftmann@30652
  1855
subsubsection{*Special Simplification for Constants*}
haftmann@30652
  1856
haftmann@30652
  1857
text{*These distributive laws move literals inside sums and differences.*}
haftmann@30652
  1858
haftmann@30652
  1859
lemmas left_distrib_number_of [simp] =
haftmann@30652
  1860
  left_distrib [of _ _ "number_of v", standard]
haftmann@30652
  1861
haftmann@30652
  1862
lemmas right_distrib_number_of [simp] =
haftmann@30652
  1863
  right_distrib [of "number_of v", standard]
haftmann@30652
  1864
haftmann@30652
  1865
lemmas left_diff_distrib_number_of [simp] =
haftmann@30652
  1866
  left_diff_distrib [of _ _ "number_of v", standard]
haftmann@30652
  1867
haftmann@30652
  1868
lemmas right_diff_distrib_number_of [simp] =
haftmann@30652
  1869
  right_diff_distrib [of "number_of v", standard]
haftmann@30652
  1870
haftmann@30652
  1871
text{*These are actually for fields, like real: but where else to put them?*}
haftmann@30652
  1872
haftmann@30652
  1873
lemmas zero_less_divide_iff_number_of [simp, noatp] =
haftmann@30652
  1874
  zero_less_divide_iff [of "number_of w", standard]
haftmann@30652
  1875
haftmann@30652
  1876
lemmas divide_less_0_iff_number_of [simp, noatp] =
haftmann@30652
  1877
  divide_less_0_iff [of "number_of w", standard]
haftmann@30652
  1878
haftmann@30652
  1879
lemmas zero_le_divide_iff_number_of [simp, noatp] =
haftmann@30652
  1880
  zero_le_divide_iff [of "number_of w", standard]
haftmann@30652
  1881
haftmann@30652
  1882
lemmas divide_le_0_iff_number_of [simp, noatp] =
haftmann@30652
  1883
  divide_le_0_iff [of "number_of w", standard]
haftmann@30652
  1884
haftmann@30652
  1885
haftmann@30652
  1886
text {*Replaces @{text "inverse #nn"} by @{text "1/#nn"}.  It looks
haftmann@30652
  1887
  strange, but then other simprocs simplify the quotient.*}
haftmann@30652
  1888
haftmann@30652
  1889
lemmas inverse_eq_divide_number_of [simp] =
haftmann@30652
  1890
  inverse_eq_divide [of "number_of w", standard]
haftmann@30652
  1891
haftmann@30652
  1892
text {*These laws simplify inequalities, moving unary minus from a term
haftmann@30652
  1893
into the literal.*}
haftmann@30652
  1894
haftmann@30652
  1895
lemmas less_minus_iff_number_of [simp, noatp] =
haftmann@30652
  1896
  less_minus_iff [of "number_of v", standard]
haftmann@30652
  1897
haftmann@30652
  1898
lemmas le_minus_iff_number_of [simp, noatp] =
haftmann@30652
  1899
  le_minus_iff [of "number_of v", standard]
haftmann@30652
  1900
haftmann@30652
  1901
lemmas equation_minus_iff_number_of [simp, noatp] =
haftmann@30652
  1902
  equation_minus_iff [of "number_of v", standard]
haftmann@30652
  1903
haftmann@30652
  1904
lemmas minus_less_iff_number_of [simp, noatp] =
haftmann@30652
  1905
  minus_less_iff [of _ "number_of v", standard]
haftmann@30652
  1906
haftmann@30652
  1907
lemmas minus_le_iff_number_of [simp, noatp] =
haftmann@30652
  1908
  minus_le_iff [of _ "number_of v", standard]
haftmann@30652
  1909
haftmann@30652
  1910
lemmas minus_equation_iff_number_of [simp, noatp] =
haftmann@30652
  1911
  minus_equation_iff [of _ "number_of v", standard]
haftmann@30652
  1912
haftmann@30652
  1913
haftmann@30652
  1914
text{*To Simplify Inequalities Where One Side is the Constant 1*}
haftmann@30652
  1915
haftmann@30652
  1916
lemma less_minus_iff_1 [simp,noatp]:
haftmann@30652
  1917
  fixes b::"'b::{ordered_idom,number_ring}"
haftmann@30652
  1918
  shows "(1 < - b) = (b < -1)"
haftmann@30652
  1919
by auto
haftmann@30652
  1920
haftmann@30652
  1921
lemma le_minus_iff_1 [simp,noatp]:
haftmann@30652
  1922
  fixes b::"'b::{ordered_idom,number_ring}"
haftmann@30652
  1923
  shows "(1 \<le> - b) = (b \<le> -1)"
haftmann@30652
  1924
by auto
haftmann@30652
  1925
haftmann@30652
  1926
lemma equation_minus_iff_1 [simp,noatp]:
haftmann@30652
  1927
  fixes b::"'b::number_ring"
haftmann@30652
  1928
  shows "(1 = - b) = (b = -1)"
haftmann@30652
  1929
by (subst equation_minus_iff, auto)
haftmann@30652
  1930
haftmann@30652
  1931
lemma minus_less_iff_1 [simp,noatp]:
haftmann@30652
  1932
  fixes a::"'b::{ordered_idom,number_ring}"
haftmann@30652
  1933
  shows "(- a < 1) = (-1 < a)"
haftmann@30652
  1934
by auto
haftmann@30652
  1935
haftmann@30652
  1936
lemma minus_le_iff_1 [simp,noatp]:
haftmann@30652
  1937
  fixes a::"'b::{ordered_idom,number_ring}"
haftmann@30652
  1938
  shows "(- a \<le> 1) = (-1 \<le> a)"
haftmann@30652
  1939
by auto
haftmann@30652
  1940
haftmann@30652
  1941
lemma minus_equation_iff_1 [simp,noatp]:
haftmann@30652
  1942
  fixes a::"'b::number_ring"
haftmann@30652
  1943
  shows "(- a = 1) = (a = -1)"
haftmann@30652
  1944
by (subst minus_equation_iff, auto)
haftmann@30652
  1945
haftmann@30652
  1946
haftmann@30652
  1947
text {*Cancellation of constant factors in comparisons (@{text "<"} and @{text "\<le>"}) *}
haftmann@30652
  1948
haftmann@30652
  1949
lemmas mult_less_cancel_left_number_of [simp, noatp] =
haftmann@30652
  1950
  mult_less_cancel_left [of "number_of v", standard]
haftmann@30652
  1951
haftmann@30652
  1952
lemmas mult_less_cancel_right_number_of [simp, noatp] =
haftmann@30652
  1953
  mult_less_cancel_right [of _ "number_of v", standard]
haftmann@30652
  1954
haftmann@30652
  1955
lemmas mult_le_cancel_left_number_of [simp, noatp] =
haftmann@30652
  1956
  mult_le_cancel_left [of "number_of v", standard]
haftmann@30652
  1957
haftmann@30652
  1958
lemmas mult_le_cancel_right_number_of [simp, noatp] =
haftmann@30652
  1959
  mult_le_cancel_right [of _ "number_of v", standard]
haftmann@30652
  1960
haftmann@30652
  1961
haftmann@30652
  1962
text {*Multiplying out constant divisors in comparisons (@{text "<"}, @{text "\<le>"} and @{text "="}) *}
haftmann@30652
  1963
haftmann@30652
  1964
lemmas le_divide_eq_number_of1 [simp] = le_divide_eq [of _ _ "number_of w", standard]
haftmann@30652
  1965
lemmas divide_le_eq_number_of1 [simp] = divide_le_eq [of _ "number_of w", standard]
haftmann@30652
  1966
lemmas less_divide_eq_number_of1 [simp] = less_divide_eq [of _ _ "number_of w", standard]
haftmann@30652
  1967
lemmas divide_less_eq_number_of1 [simp] = divide_less_eq [of _ "number_of w", standard]
haftmann@30652
  1968
lemmas eq_divide_eq_number_of1 [simp] = eq_divide_eq [of _ _ "number_of w", standard]
haftmann@30652
  1969
lemmas divide_eq_eq_number_of1 [simp] = divide_eq_eq [of _ "number_of w", standard]
haftmann@30652
  1970
haftmann@30652
  1971
haftmann@30652
  1972
subsubsection{*Optional Simplification Rules Involving Constants*}
haftmann@30652
  1973
haftmann@30652
  1974
text{*Simplify quotients that are compared with a literal constant.*}
haftmann@30652
  1975
haftmann@30652
  1976
lemmas le_divide_eq_number_of = le_divide_eq [of "number_of w", standard]
haftmann@30652
  1977
lemmas divide_le_eq_number_of = divide_le_eq [of _ _ "number_of w", standard]
haftmann@30652
  1978
lemmas less_divide_eq_number_of = less_divide_eq [of "number_of w", standard]
haftmann@30652
  1979
lemmas divide_less_eq_number_of = divide_less_eq [of _ _ "number_of w", standard]
haftmann@30652
  1980
lemmas eq_divide_eq_number_of = eq_divide_eq [of "number_of w", standard]
haftmann@30652
  1981
lemmas divide_eq_eq_number_of = divide_eq_eq [of _ _ "number_of w", standard]
haftmann@30652
  1982
haftmann@30652
  1983
haftmann@30652
  1984
text{*Not good as automatic simprules because they cause case splits.*}
haftmann@30652
  1985
lemmas divide_const_simps =
haftmann@30652
  1986
  le_divide_eq_number_of divide_le_eq_number_of less_divide_eq_number_of
haftmann@30652
  1987
  divide_less_eq_number_of eq_divide_eq_number_of divide_eq_eq_number_of
haftmann@30652
  1988
  le_divide_eq_1 divide_le_eq_1 less_divide_eq_1 divide_less_eq_1
haftmann@30652
  1989
haftmann@30652
  1990
text{*Division By @{text "-1"}*}
haftmann@30652
  1991
haftmann@30652
  1992
lemma divide_minus1 [simp]:
haftmann@30652
  1993
     "x/-1 = -(x::'a::{field,division_by_zero,number_ring})"
haftmann@30652
  1994
by simp
haftmann@30652
  1995
haftmann@30652
  1996
lemma minus1_divide [simp]:
haftmann@30652
  1997
     "-1 / (x::'a::{field,division_by_zero,number_ring}) = - (1/x)"
haftmann@30652
  1998
by (simp add: divide_inverse inverse_minus_eq)
haftmann@30652
  1999
haftmann@30652
  2000
lemma half_gt_zero_iff:
haftmann@30652
  2001
     "(0 < r/2) = (0 < (r::'a::{ordered_field,division_by_zero,number_ring}))"
haftmann@30652
  2002
by auto
haftmann@30652
  2003
haftmann@30652
  2004
lemmas half_gt_zero [simp] = half_gt_zero_iff [THEN iffD2, standard]
haftmann@30652
  2005
haftmann@30652
  2006
haftmann@25919
  2007
subsection {* Configuration of the code generator *}
haftmann@25919
  2008
haftmann@26507
  2009
code_datatype Pls Min Bit0 Bit1 "number_of \<Colon> int \<Rightarrow> int"
haftmann@26507
  2010
haftmann@28562
  2011
lemmas pred_succ_numeral_code [code] =
haftmann@26507
  2012
  pred_bin_simps succ_bin_simps
haftmann@26507
  2013
haftmann@28562
  2014
lemmas plus_numeral_code [code] =
haftmann@26507
  2015
  add_bin_simps
haftmann@26507
  2016
  arith_extra_simps(1) [where 'a = int]
haftmann@26507
  2017
haftmann@28562
  2018
lemmas minus_numeral_code [code] =
haftmann@26507
  2019
  minus_bin_simps
haftmann@26507
  2020
  arith_extra_simps(2) [where 'a = int]
haftmann@26507
  2021
  arith_extra_simps(5) [where 'a = int]
haftmann@26507
  2022
haftmann@28562
  2023
lemmas times_numeral_code [code] =
haftmann@26507
  2024
  mult_bin_simps
haftmann@26507
  2025
  arith_extra_simps(4) [where 'a = int]
haftmann@26507
  2026
haftmann@26507
  2027
instantiation int :: eq
haftmann@26507
  2028
begin
haftmann@26507
  2029
haftmann@28562
  2030
definition [code del]: "eq_class.eq k l \<longleftrightarrow> k - l = (0\<Colon>int)"
haftmann@26507
  2031
haftmann@26507
  2032
instance by default (simp add: eq_int_def)
haftmann@26507
  2033
haftmann@26507
  2034
end
haftmann@26507
  2035
haftmann@28562
  2036
lemma eq_number_of_int_code [code]:
haftmann@26732
  2037
  "eq_class.eq (number_of k \<Colon> int) (number_of l) \<longleftrightarrow> eq_class.eq k l"
haftmann@26507
  2038
  unfolding eq_int_def number_of_is_id ..
haftmann@26507
  2039
haftmann@28562
  2040
lemma eq_int_code [code]:
haftmann@26732
  2041
  "eq_class.eq Int.Pls Int.Pls \<longleftrightarrow> True"
haftmann@26732
  2042
  "eq_class.eq Int.Pls Int.Min \<longleftrightarrow> False"
haftmann@26732
  2043
  "eq_class.eq Int.Pls (Int.Bit0 k2) \<longleftrightarrow> eq_class.eq Int.Pls k2"
haftmann@26732
  2044
  "eq_class.eq Int.Pls (Int.Bit1 k2) \<longleftrightarrow> False"
haftmann@26732
  2045
  "eq_class.eq Int.Min Int.Pls \<longleftrightarrow> False"
haftmann@26732
  2046
  "eq_class.eq Int.Min Int.Min \<longleftrightarrow> True"
haftmann@26732
  2047
  "eq_class.eq Int.Min (Int.Bit0 k2) \<longleftrightarrow> False"
haftmann@26732
  2048
  "eq_class.eq Int.Min (Int.Bit1 k2) \<longleftrightarrow> eq_class.eq Int.Min k2"
huffman@28958
  2049
  "eq_class.eq (Int.Bit0 k1) Int.Pls \<longleftrightarrow> eq_class.eq k1 Int.Pls"
haftmann@26732
  2050
  "eq_class.eq (Int.Bit1 k1) Int.Pls \<longleftrightarrow> False"
haftmann@26732
  2051
  "eq_class.eq (Int.Bit0 k1) Int.Min \<longleftrightarrow> False"
huffman@28958
  2052
  "eq_class.eq (Int.Bit1 k1) Int.Min \<longleftrightarrow> eq_class.eq k1 Int.Min"
haftmann@26732
  2053
  "eq_class.eq (Int.Bit0 k1) (Int.Bit0 k2) \<longleftrightarrow> eq_class.eq k1 k2"
haftmann@26732
  2054
  "eq_class.eq (Int.Bit0 k1) (Int.Bit1 k2) \<longleftrightarrow> False"
haftmann@26732
  2055
  "eq_class.eq (Int.Bit1 k1) (Int.Bit0 k2) \<longleftrightarrow> False"
haftmann@26732
  2056
  "eq_class.eq (Int.Bit1 k1) (Int.Bit1 k2) \<longleftrightarrow> eq_class.eq k1 k2"
huffman@28958
  2057
  unfolding eq_equals by simp_all
haftmann@25919
  2058
haftmann@28351
  2059
lemma eq_int_refl [code nbe]:
haftmann@28351
  2060
  "eq_class.eq (k::int) k \<longleftrightarrow> True"
haftmann@28351
  2061
  by (rule HOL.eq_refl)
haftmann@28351
  2062
haftmann@28562
  2063
lemma less_eq_number_of_int_code [code]:
haftmann@26507
  2064
  "(number_of k \<Colon> int) \<le> number_of l \<longleftrightarrow> k \<le> l"
haftmann@26507
  2065
  unfolding number_of_is_id ..
haftmann@26507
  2066
haftmann@28562
  2067
lemma less_eq_int_code [code]:
haftmann@26507
  2068
  "Int.Pls \<le> Int.Pls \<longleftrightarrow> True"
haftmann@26507
  2069
  "Int.Pls \<le> Int.Min \<longleftrightarrow> False"
haftmann@26507
  2070
  "Int.Pls \<le> Int.Bit0 k \<longleftrightarrow> Int.Pls \<le> k"
haftmann@26507
  2071
  "Int.Pls \<le> Int.Bit1 k \<longleftrightarrow> Int.Pls \<le> k"
haftmann@26507
  2072
  "Int.Min \<le> Int.Pls \<longleftrightarrow> True"
haftmann@26507
  2073
  "Int.Min \<le> Int.Min \<longleftrightarrow> True"
haftmann@26507
  2074
  "Int.Min \<le> Int.Bit0 k \<longleftrightarrow> Int.Min < k"
haftmann@26507
  2075
  "Int.Min \<le> Int.Bit1 k \<longleftrightarrow> Int.Min \<le> k"
haftmann@26507
  2076
  "Int.Bit0 k \<le> Int.Pls \<longleftrightarrow> k \<le> Int.Pls"
haftmann@26507
  2077
  "Int.Bit1 k \<le> Int.Pls \<longleftrightarrow> k < Int.Pls"
haftmann@26507
  2078
  "Int.Bit0 k \<le> Int.Min \<longleftrightarrow> k \<le> Int.Min"
haftmann@26507
  2079
  "Int.Bit1 k \<le> Int.Min \<longleftrightarrow> k \<le> Int.Min"
haftmann@26507
  2080
  "Int.Bit0 k1 \<le> Int.Bit0 k2 \<longleftrightarrow> k1 \<le> k2"
haftmann@26507
  2081
  "Int.Bit0 k1 \<le> Int.Bit1 k2 \<longleftrightarrow> k1 \<le> k2"
haftmann@26507
  2082
  "Int.Bit1 k1 \<le> Int.Bit0 k2 \<longleftrightarrow> k1 < k2"
haftmann@26507
  2083
  "Int.Bit1 k1 \<le> Int.Bit1 k2 \<longleftrightarrow> k1 \<le> k2"
huffman@28958
  2084
  by simp_all
haftmann@26507
  2085
haftmann@28562
  2086
lemma less_number_of_int_code [code]:
haftmann@26507
  2087
  "(number_of k \<Colon> int) < number_of l \<longleftrightarrow> k < l"
haftmann@26507
  2088
  unfolding number_of_is_id ..
haftmann@26507
  2089
haftmann@28562
  2090
lemma less_int_code [code]:
haftmann@26507
  2091
  "Int.Pls < Int.Pls \<longleftrightarrow> False"
haftmann@26507
  2092
  "Int.Pls < Int.Min \<longleftrightarrow> False"
haftmann@26507
  2093
  "Int.Pls < Int.Bit0 k \<longleftrightarrow> Int.Pls < k"
haftmann@26507
  2094
  "Int.Pls < Int.Bit1 k \<longleftrightarrow> Int.Pls \<le> k"
haftmann@26507
  2095
  "Int.Min < Int.Pls \<longleftrightarrow> True"
haftmann@26507
  2096
  "Int.Min < Int.Min \<longleftrightarrow> False"
haftmann@26507
  2097
  "Int.Min < Int.Bit0 k \<longleftrightarrow> Int.Min < k"
haftmann@26507
  2098
  "Int.Min < Int.Bit1 k \<longleftrightarrow> Int.Min < k"
haftmann@26507
  2099
  "Int.Bit0 k < Int.Pls \<longleftrightarrow> k < Int.Pls"
haftmann@26507
  2100
  "Int.Bit1 k < Int.Pls \<longleftrightarrow> k < Int.Pls"
haftmann@26507
  2101
  "Int.Bit0 k < Int.Min \<longleftrightarrow> k \<le> Int.Min"
haftmann@26507
  2102
  "Int.Bit1 k < Int.Min \<longleftrightarrow> k < Int.Min"
haftmann@26507
  2103
  "Int.Bit0 k1 < Int.Bit0 k2 \<longleftrightarrow> k1 < k2"
haftmann@26507
  2104
  "Int.Bit0 k1 < Int.Bit1 k2 \<longleftrightarrow> k1 \<le> k2"
haftmann@26507
  2105
  "Int.Bit1 k1 < Int.Bit0 k2 \<longleftrightarrow> k1 < k2"
haftmann@26507
  2106
  "Int.Bit1 k1 < Int.Bit1 k2 \<longleftrightarrow> k1 < k2"
huffman@28958
  2107
  by simp_all
haftmann@25919
  2108
haftmann@25919
  2109
definition
haftmann@25919
  2110
  nat_aux :: "int \<Rightarrow> nat \<Rightarrow> nat" where
haftmann@25919
  2111
  "nat_aux i n = nat i + n"
haftmann@25919
  2112
haftmann@25919
  2113
lemma [code]:
haftmann@25919
  2114
  "nat_aux i n = (if i \<le> 0 then n else nat_aux (i - 1) (Suc n))"  -- {* tail recursive *}
haftmann@25919
  2115
  by (auto simp add: nat_aux_def nat_eq_iff linorder_not_le order_less_imp_le
haftmann@25919
  2116
    dest: zless_imp_add1_zle)
haftmann@25919
  2117
haftmann@25919
  2118
lemma [code]: "nat i = nat_aux i 0"
haftmann@25919
  2119
  by (simp add: nat_aux_def)
haftmann@25919
  2120
haftmann@28514
  2121
hide (open) const nat_aux
haftmann@25928
  2122
haftmann@28562
  2123
lemma zero_is_num_zero [code, code inline, symmetric, code post]:
haftmann@25919
  2124
  "(0\<Colon>int) = Numeral0" 
haftmann@25919
  2125
  by simp
haftmann@25919
  2126
haftmann@28562
  2127
lemma one_is_num_one [code, code inline, symmetric, code post]:
haftmann@25919
  2128
  "(1\<Colon>int) = Numeral1" 
haftmann@25961
  2129
  by simp
haftmann@25919
  2130
haftmann@25919
  2131
code_modulename SML
haftmann@25928
  2132
  Int Integer
haftmann@25919
  2133
haftmann@25919
  2134
code_modulename OCaml
haftmann@25928
  2135
  Int Integer
haftmann@25919
  2136
haftmann@25919
  2137
code_modulename Haskell
haftmann@25928
  2138
  Int Integer
haftmann@25919
  2139
haftmann@25919
  2140
types_code
haftmann@25919
  2141
  "int" ("int")
haftmann@25919
  2142
attach (term_of) {*
haftmann@25919
  2143
val term_of_int = HOLogic.mk_number HOLogic.intT;
haftmann@25919
  2144
*}
haftmann@25919
  2145
attach (test) {*
haftmann@25919
  2146
fun gen_int i =
haftmann@25919
  2147
  let val j = one_of [~1, 1] * random_range 0 i
haftmann@25919
  2148
  in (j, fn () => term_of_int j) end;
haftmann@25919
  2149
*}
haftmann@25919
  2150
haftmann@25919
  2151
setup {*
haftmann@25919
  2152
let
haftmann@25919
  2153
haftmann@25919
  2154
fun strip_number_of (@{term "Int.number_of :: int => int"} $ t) = t
haftmann@25919
  2155
  | strip_number_of t = t;
haftmann@25919
  2156
haftmann@28537
  2157
fun numeral_codegen thy defs dep module b t gr =
haftmann@25919
  2158
  let val i = HOLogic.dest_numeral (strip_number_of t)
haftmann@25919
  2159
  in
haftmann@28537
  2160
    SOME (Codegen.str (string_of_int i),
haftmann@28537
  2161
      snd (Codegen.invoke_tycodegen thy defs dep module false HOLogic.intT gr))
haftmann@25919
  2162
  end handle TERM _ => NONE;
haftmann@25919
  2163
haftmann@25919
  2164
in
haftmann@25919
  2165
haftmann@25919
  2166
Codegen.add_codegen "numeral_codegen" numeral_codegen
haftmann@25919
  2167
haftmann@25919
  2168
end
haftmann@25919
  2169
*}
haftmann@25919
  2170
haftmann@25919
  2171
consts_code
haftmann@25919
  2172
  "number_of :: int \<Rightarrow> int"    ("(_)")
haftmann@25919
  2173
  "0 :: int"                   ("0")
haftmann@25919
  2174
  "1 :: int"                   ("1")
haftmann@25919
  2175
  "uminus :: int => int"       ("~")
haftmann@25919
  2176
  "op + :: int => int => int"  ("(_ +/ _)")
haftmann@25919
  2177
  "op * :: int => int => int"  ("(_ */ _)")
haftmann@25919
  2178
  "op \<le> :: int => int => bool" ("(_ <=/ _)")
haftmann@25919
  2179
  "op < :: int => int => bool" ("(_ </ _)")
haftmann@25919
  2180
haftmann@25919
  2181
quickcheck_params [default_type = int]
haftmann@25919
  2182
huffman@26086
  2183
hide (open) const Pls Min Bit0 Bit1 succ pred
haftmann@25919
  2184
haftmann@25919
  2185
haftmann@25919
  2186
subsection {* Legacy theorems *}
haftmann@25919
  2187
haftmann@25919
  2188
lemmas zminus_zminus = minus_minus [of "z::int", standard]
haftmann@25919
  2189
lemmas zminus_0 = minus_zero [where 'a=int]
haftmann@25919
  2190
lemmas zminus_zadd_distrib = minus_add_distrib [of "z::int" "w", standard]
haftmann@25919
  2191
lemmas zadd_commute = add_commute [of "z::int" "w", standard]
haftmann@25919
  2192
lemmas zadd_assoc = add_assoc [of "z1::int" "z2" "z3", standard]
haftmann@25919
  2193
lemmas zadd_left_commute = add_left_commute [of "x::int" "y" "z", standard]
haftmann@25919
  2194
lemmas zadd_ac = zadd_assoc zadd_commute zadd_left_commute
haftmann@25919
  2195
lemmas zmult_ac = OrderedGroup.mult_ac
haftmann@25919
  2196
lemmas zadd_0 = OrderedGroup.add_0_left [of "z::int", standard]
haftmann@25919
  2197
lemmas zadd_0_right = OrderedGroup.add_0_left [of "z::int", standard]
haftmann@25919
  2198
lemmas zadd_zminus_inverse2 = left_minus [of "z::int", standard]
haftmann@25919
  2199
lemmas zmult_zminus = mult_minus_left [of "z::int" "w", standard]
haftmann@25919
  2200
lemmas zmult_commute = mult_commute [of "z::int" "w", standard]
haftmann@25919
  2201
lemmas zmult_assoc = mult_assoc [of "z1::int" "z2" "z3", standard]
haftmann@25919
  2202
lemmas zadd_zmult_distrib = left_distrib [of "z1::int" "z2" "w", standard]
haftmann@25919
  2203
lemmas zadd_zmult_distrib2 = right_distrib [of "w::int" "z1" "z2", standard]
haftmann@25919
  2204
lemmas zdiff_zmult_distrib = left_diff_distrib [of "z1::int" "z2" "w", standard]
haftmann@25919
  2205
lemmas zdiff_zmult_distrib2 = right_diff_distrib [of "w::int" "z1" "z2", standard]
haftmann@25919
  2206
haftmann@25919
  2207
lemmas zmult_1 = mult_1_left [of "z::int", standard]
haftmann@25919
  2208
lemmas zmult_1_right = mult_1_right [of "z::int", standard]
haftmann@25919
  2209
haftmann@25919
  2210
lemmas zle_refl = order_refl [of "w::int", standard]
haftmann@25919
  2211
lemmas zle_trans = order_trans [where 'a=int and x="i" and y="j" and z="k", standard]
haftmann@25919
  2212
lemmas zle_anti_sym = order_antisym [of "z::int" "w", standard]
haftmann@25919
  2213
lemmas zle_linear = linorder_linear [of "z::int" "w", standard]
haftmann@25919
  2214
lemmas zless_linear = linorder_less_linear [where 'a = int]
haftmann@25919
  2215
haftmann@25919
  2216
lemmas zadd_left_mono = add_left_mono [of "i::int" "j" "k", standard]
haftmann@25919
  2217
lemmas zadd_strict_right_mono = add_strict_right_mono [of "i::int" "j" "k", standard]
haftmann@25919
  2218
lemmas zadd_zless_mono = add_less_le_mono [of "w'::int" "w" "z'" "z", standard]
haftmann@25919
  2219
haftmann@25919
  2220
lemmas int_0_less_1 = zero_less_one [where 'a=int]
haftmann@25919
  2221
lemmas int_0_neq_1 = zero_neq_one [where 'a=int]
haftmann@25919
  2222
haftmann@25919
  2223
lemmas inj_int = inj_of_nat [where 'a=int]
haftmann@25919
  2224
lemmas zadd_int = of_nat_add [where 'a=int, symmetric]
haftmann@25919
  2225
lemmas int_mult = of_nat_mult [where 'a=int]
haftmann@25919
  2226
lemmas zmult_int = of_nat_mult [where 'a=int, symmetric]
haftmann@25919
  2227
lemmas int_eq_0_conv = of_nat_eq_0_iff [where 'a=int and m="n", standard]
haftmann@25919
  2228
lemmas zless_int = of_nat_less_iff [where 'a=int]
haftmann@25919
  2229
lemmas int_less_0_conv = of_nat_less_0_iff [where 'a=int and m="k", standard]
haftmann@25919
  2230
lemmas zero_less_int_conv = of_nat_0_less_iff [where 'a=int]
haftmann@25919
  2231
lemmas zero_zle_int = of_nat_0_le_iff [where 'a=int]
haftmann@25919
  2232
lemmas int_le_0_conv = of_nat_le_0_iff [where 'a=int and m="n", standard]
haftmann@25919
  2233
lemmas int_0 = of_nat_0 [where 'a=int]
haftmann@25919
  2234
lemmas int_1 = of_nat_1 [where 'a=int]
haftmann@25919
  2235
lemmas int_Suc = of_nat_Suc [where 'a=int]
haftmann@25919
  2236
lemmas abs_int_eq = abs_of_nat [where 'a=int and n="m", standard]
haftmann@25919
  2237
lemmas of_int_int_eq = of_int_of_nat_eq [where 'a=int]
haftmann@25919
  2238
lemmas zdiff_int = of_nat_diff [where 'a=int, symmetric]
haftmann@25919
  2239
lemmas zless_le = less_int_def
haftmann@25919
  2240
lemmas int_eq_of_nat = TrueI
haftmann@25919
  2241
haftmann@30960
  2242
lemma zpower_zadd_distrib:
haftmann@30960
  2243
  "x ^ (y + z) = ((x ^ y) * (x ^ z)::int)"
haftmann@30960
  2244
  by (rule power_add)
haftmann@30960
  2245
haftmann@30960
  2246
lemma zero_less_zpower_abs_iff:
haftmann@30960
  2247
  "(0 < abs x ^ n) \<longleftrightarrow> (x \<noteq> (0::int) | n = 0)"
haftmann@30960
  2248
  by (rule zero_less_power_abs_iff)
haftmann@30960
  2249
haftmann@30960
  2250
lemma zero_le_zpower_abs: "(0::int) \<le> abs x ^ n"
haftmann@30960
  2251
  by (rule zero_le_power_abs)
haftmann@30960
  2252
haftmann@31015
  2253
lemma zpower_zpower:
haftmann@31015
  2254
  "(x ^ y) ^ z = (x ^ (y * z)::int)"
haftmann@31015
  2255
  by (rule power_mult [symmetric])
haftmann@31015
  2256
haftmann@31015
  2257
lemma int_power:
haftmann@31015
  2258
  "int (m ^ n) = int m ^ n"
haftmann@31015
  2259
  by (rule of_nat_power)
haftmann@31015
  2260
haftmann@31015
  2261
lemmas zpower_int = int_power [symmetric]
haftmann@31015
  2262
haftmann@25919
  2263
end