Theory IntDiv

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theory IntDiv
imports Int FunDef
begin

(*  Title:      HOL/IntDiv.thy
    ID:         $Id: IntDiv.thy,v 1.30 2008/04/24 14:53:08 haftmann Exp $
    Author:     Lawrence C Paulson, Cambridge University Computer Laboratory
    Copyright   1999  University of Cambridge

*)

header{*The Division Operators div and mod; the Divides Relation dvd*}

theory IntDiv
imports Int Divides FunDef
begin

constdefs
  quorem :: "(int*int) * (int*int) => bool"
    --{*definition of quotient and remainder*}
    [code func]: "quorem == %((a,b), (q,r)).
                      a = b*q + r &
                      (if 0 < b then 0≤r & r<b else b<r & r ≤ 0)"

  adjust :: "[int, int*int] => int*int"
    --{*for the division algorithm*}
    [code func]: "adjust b == %(q,r). if 0 ≤ r-b then (2*q + 1, r-b)
                         else (2*q, r)"

text{*algorithm for the case @{text "a≥0, b>0"}*}
function
  posDivAlg :: "int => int => int × int"
where
  "posDivAlg a b =
     (if (a<b | b≤0) then (0,a)
        else adjust b (posDivAlg a (2*b)))"
by auto
termination by (relation "measure (%(a,b). nat(a - b + 1))") auto

text{*algorithm for the case @{text "a<0, b>0"}*}
function
  negDivAlg :: "int => int => int × int"
where
  "negDivAlg a b  =
     (if (0≤a+b | b≤0) then (-1,a+b)
      else adjust b (negDivAlg a (2*b)))"
by auto
termination by (relation "measure (%(a,b). nat(- a - b))") auto

text{*algorithm for the general case @{term "b≠0"}*}
constdefs
  negateSnd :: "int*int => int*int"
    [code func]: "negateSnd == %(q,r). (q,-r)"

definition
  divAlg :: "int × int => int × int"
    --{*The full division algorithm considers all possible signs for a, b
       including the special case @{text "a=0, b<0"} because 
       @{term negDivAlg} requires @{term "a<0"}.*}
where
  "divAlg = (λ(a, b). (if 0≤a then
                  if 0≤b then posDivAlg a b
                  else if a=0 then (0, 0)
                       else negateSnd (negDivAlg (-a) (-b))
               else 
                  if 0<b then negDivAlg a b
                  else negateSnd (posDivAlg (-a) (-b))))"

instantiation int :: Divides.div
begin

definition
  div_def: "a div b = fst (divAlg (a, b))"

definition
  mod_def: "a mod b = snd (divAlg (a, b))"

instance ..

end

lemma divAlg_mod_div:
  "divAlg (p, q) = (p div q, p mod q)"
  by (auto simp add: div_def mod_def)

text{*
Here is the division algorithm in ML:

\begin{verbatim}
    fun posDivAlg (a,b) =
      if a<b then (0,a)
      else let val (q,r) = posDivAlg(a, 2*b)
               in  if 0≤r-b then (2*q+1, r-b) else (2*q, r)
           end

    fun negDivAlg (a,b) =
      if 0≤a+b then (~1,a+b)
      else let val (q,r) = negDivAlg(a, 2*b)
               in  if 0≤r-b then (2*q+1, r-b) else (2*q, r)
           end;

    fun negateSnd (q,r:int) = (q,~r);

    fun divAlg (a,b) = if 0≤a then 
                          if b>0 then posDivAlg (a,b) 
                           else if a=0 then (0,0)
                                else negateSnd (negDivAlg (~a,~b))
                       else 
                          if 0<b then negDivAlg (a,b)
                          else        negateSnd (posDivAlg (~a,~b));
\end{verbatim}
*}



subsection{*Uniqueness and Monotonicity of Quotients and Remainders*}

lemma unique_quotient_lemma:
     "[| b*q' + r'  ≤ b*q + r;  0 ≤ r';  r' < b;  r < b |]  
      ==> q' ≤ (q::int)"
apply (subgoal_tac "r' + b * (q'-q) ≤ r")
 prefer 2 apply (simp add: right_diff_distrib)
apply (subgoal_tac "0 < b * (1 + q - q') ")
apply (erule_tac [2] order_le_less_trans)
 prefer 2 apply (simp add: right_diff_distrib right_distrib)
apply (subgoal_tac "b * q' < b * (1 + q) ")
 prefer 2 apply (simp add: right_diff_distrib right_distrib)
apply (simp add: mult_less_cancel_left)
done

lemma unique_quotient_lemma_neg:
     "[| b*q' + r' ≤ b*q + r;  r ≤ 0;  b < r;  b < r' |]  
      ==> q ≤ (q'::int)"
by (rule_tac b = "-b" and r = "-r'" and r' = "-r" in unique_quotient_lemma, 
    auto)

lemma unique_quotient:
     "[| quorem ((a,b), (q,r));  quorem ((a,b), (q',r'));  b ≠ 0 |]  
      ==> q = q'"
apply (simp add: quorem_def linorder_neq_iff split: split_if_asm)
apply (blast intro: order_antisym
             dest: order_eq_refl [THEN unique_quotient_lemma] 
             order_eq_refl [THEN unique_quotient_lemma_neg] sym)+
done


lemma unique_remainder:
     "[| quorem ((a,b), (q,r));  quorem ((a,b), (q',r'));  b ≠ 0 |]  
      ==> r = r'"
apply (subgoal_tac "q = q'")
 apply (simp add: quorem_def)
apply (blast intro: unique_quotient)
done


subsection{*Correctness of @{term posDivAlg}, the Algorithm for Non-Negative Dividends*}

text{*And positive divisors*}

lemma adjust_eq [simp]:
     "adjust b (q,r) = 
      (let diff = r-b in  
        if 0 ≤ diff then (2*q + 1, diff)   
                     else (2*q, r))"
by (simp add: Let_def adjust_def)

declare posDivAlg.simps [simp del]

text{*use with a simproc to avoid repeatedly proving the premise*}
lemma posDivAlg_eqn:
     "0 < b ==>  
      posDivAlg a b = (if a<b then (0,a) else adjust b (posDivAlg a (2*b)))"
by (rule posDivAlg.simps [THEN trans], simp)

text{*Correctness of @{term posDivAlg}: it computes quotients correctly*}
theorem posDivAlg_correct:
  assumes "0 ≤ a" and "0 < b"
  shows "quorem ((a, b), posDivAlg a b)"
using prems apply (induct a b rule: posDivAlg.induct)
apply auto
apply (simp add: quorem_def)
apply (subst posDivAlg_eqn, simp add: right_distrib)
apply (case_tac "a < b")
apply simp_all
apply (erule splitE)
apply (auto simp add: right_distrib Let_def)
done


subsection{*Correctness of @{term negDivAlg}, the Algorithm for Negative Dividends*}

text{*And positive divisors*}

declare negDivAlg.simps [simp del]

text{*use with a simproc to avoid repeatedly proving the premise*}
lemma negDivAlg_eqn:
     "0 < b ==>  
      negDivAlg a b =       
       (if 0≤a+b then (-1,a+b) else adjust b (negDivAlg a (2*b)))"
by (rule negDivAlg.simps [THEN trans], simp)

(*Correctness of negDivAlg: it computes quotients correctly
  It doesn't work if a=0 because the 0/b equals 0, not -1*)
lemma negDivAlg_correct:
  assumes "a < 0" and "b > 0"
  shows "quorem ((a, b), negDivAlg a b)"
using prems apply (induct a b rule: negDivAlg.induct)
apply (auto simp add: linorder_not_le)
apply (simp add: quorem_def)
apply (subst negDivAlg_eqn, assumption)
apply (case_tac "a + b < (0::int)")
apply simp_all
apply (erule splitE)
apply (auto simp add: right_distrib Let_def)
done


subsection{*Existence Shown by Proving the Division Algorithm to be Correct*}

(*the case a=0*)
lemma quorem_0: "b ≠ 0 ==> quorem ((0,b), (0,0))"
by (auto simp add: quorem_def linorder_neq_iff)

lemma posDivAlg_0 [simp]: "posDivAlg 0 b = (0, 0)"
by (subst posDivAlg.simps, auto)

lemma negDivAlg_minus1 [simp]: "negDivAlg -1 b = (-1, b - 1)"
by (subst negDivAlg.simps, auto)

lemma negateSnd_eq [simp]: "negateSnd(q,r) = (q,-r)"
by (simp add: negateSnd_def)

lemma quorem_neg: "quorem ((-a,-b), qr) ==> quorem ((a,b), negateSnd qr)"
by (auto simp add: split_ifs quorem_def)

lemma divAlg_correct: "b ≠ 0 ==> quorem ((a,b), divAlg (a, b))"
by (force simp add: linorder_neq_iff quorem_0 divAlg_def quorem_neg
                    posDivAlg_correct negDivAlg_correct)

text{*Arbitrary definitions for division by zero.  Useful to simplify 
    certain equations.*}

lemma DIVISION_BY_ZERO [simp]: "a div (0::int) = 0 & a mod (0::int) = a"
by (simp add: div_def mod_def divAlg_def posDivAlg.simps)  


text{*Basic laws about division and remainder*}

lemma zmod_zdiv_equality: "(a::int) = b * (a div b) + (a mod b)"
apply (case_tac "b = 0", simp)
apply (cut_tac a = a and b = b in divAlg_correct)
apply (auto simp add: quorem_def div_def mod_def)
done

lemma zdiv_zmod_equality: "(b * (a div b) + (a mod b)) + k = (a::int)+k"
by(simp add: zmod_zdiv_equality[symmetric])

lemma zdiv_zmod_equality2: "((a div b) * b + (a mod b)) + k = (a::int)+k"
by(simp add: mult_commute zmod_zdiv_equality[symmetric])

text {* Tool setup *}

ML {*
local 

structure CancelDivMod = CancelDivModFun(
struct
  val div_name = @{const_name Divides.div};
  val mod_name = @{const_name Divides.mod};
  val mk_binop = HOLogic.mk_binop;
  val mk_sum = Int_Numeral_Simprocs.mk_sum HOLogic.intT;
  val dest_sum = Int_Numeral_Simprocs.dest_sum;
  val div_mod_eqs =
    map mk_meta_eq [@{thm zdiv_zmod_equality},
      @{thm zdiv_zmod_equality2}];
  val trans = trans;
  val prove_eq_sums =
    let
      val simps = @{thm diff_int_def} :: Int_Numeral_Simprocs.add_0s @ @{thms zadd_ac}
    in ArithData.prove_conv all_tac (ArithData.simp_all_tac simps) end;
end)

in

val cancel_zdiv_zmod_proc = Simplifier.simproc @{theory}
  "cancel_zdiv_zmod" ["(m::int) + n"] (K CancelDivMod.proc)

end;

Addsimprocs [cancel_zdiv_zmod_proc]
*}

lemma pos_mod_conj : "(0::int) < b ==> 0 ≤ a mod b & a mod b < b"
apply (cut_tac a = a and b = b in divAlg_correct)
apply (auto simp add: quorem_def mod_def)
done

lemmas pos_mod_sign  [simp] = pos_mod_conj [THEN conjunct1, standard]
   and pos_mod_bound [simp] = pos_mod_conj [THEN conjunct2, standard]

lemma neg_mod_conj : "b < (0::int) ==> a mod b ≤ 0 & b < a mod b"
apply (cut_tac a = a and b = b in divAlg_correct)
apply (auto simp add: quorem_def div_def mod_def)
done

lemmas neg_mod_sign  [simp] = neg_mod_conj [THEN conjunct1, standard]
   and neg_mod_bound [simp] = neg_mod_conj [THEN conjunct2, standard]



subsection{*General Properties of div and mod*}

lemma quorem_div_mod: "b ≠ 0 ==> quorem ((a, b), (a div b, a mod b))"
apply (cut_tac a = a and b = b in zmod_zdiv_equality)
apply (force simp add: quorem_def linorder_neq_iff)
done

lemma quorem_div: "[| quorem((a,b),(q,r));  b ≠ 0 |] ==> a div b = q"
by (simp add: quorem_div_mod [THEN unique_quotient])

lemma quorem_mod: "[| quorem((a,b),(q,r));  b ≠ 0 |] ==> a mod b = r"
by (simp add: quorem_div_mod [THEN unique_remainder])

lemma div_pos_pos_trivial: "[| (0::int) ≤ a;  a < b |] ==> a div b = 0"
apply (rule quorem_div)
apply (auto simp add: quorem_def)
done

lemma div_neg_neg_trivial: "[| a ≤ (0::int);  b < a |] ==> a div b = 0"
apply (rule quorem_div)
apply (auto simp add: quorem_def)
done

lemma div_pos_neg_trivial: "[| (0::int) < a;  a+b ≤ 0 |] ==> a div b = -1"
apply (rule quorem_div)
apply (auto simp add: quorem_def)
done

(*There is no div_neg_pos_trivial because  0 div b = 0 would supersede it*)

lemma mod_pos_pos_trivial: "[| (0::int) ≤ a;  a < b |] ==> a mod b = a"
apply (rule_tac q = 0 in quorem_mod)
apply (auto simp add: quorem_def)
done

lemma mod_neg_neg_trivial: "[| a ≤ (0::int);  b < a |] ==> a mod b = a"
apply (rule_tac q = 0 in quorem_mod)
apply (auto simp add: quorem_def)
done

lemma mod_pos_neg_trivial: "[| (0::int) < a;  a+b ≤ 0 |] ==> a mod b = a+b"
apply (rule_tac q = "-1" in quorem_mod)
apply (auto simp add: quorem_def)
done

text{*There is no @{text mod_neg_pos_trivial}.*}


(*Simpler laws such as -a div b = -(a div b) FAIL, but see just below*)
lemma zdiv_zminus_zminus [simp]: "(-a) div (-b) = a div (b::int)"
apply (case_tac "b = 0", simp)
apply (simp add: quorem_div_mod [THEN quorem_neg, simplified, 
                                 THEN quorem_div, THEN sym])

done

(*Simpler laws such as -a mod b = -(a mod b) FAIL, but see just below*)
lemma zmod_zminus_zminus [simp]: "(-a) mod (-b) = - (a mod (b::int))"
apply (case_tac "b = 0", simp)
apply (subst quorem_div_mod [THEN quorem_neg, simplified, THEN quorem_mod],
       auto)
done


subsection{*Laws for div and mod with Unary Minus*}

lemma zminus1_lemma:
     "quorem((a,b),(q,r))  
      ==> quorem ((-a,b), (if r=0 then -q else -q - 1),  
                          (if r=0 then 0 else b-r))"
by (force simp add: split_ifs quorem_def linorder_neq_iff right_diff_distrib)


lemma zdiv_zminus1_eq_if:
     "b ≠ (0::int)  
      ==> (-a) div b =  
          (if a mod b = 0 then - (a div b) else  - (a div b) - 1)"
by (blast intro: quorem_div_mod [THEN zminus1_lemma, THEN quorem_div])

lemma zmod_zminus1_eq_if:
     "(-a::int) mod b = (if a mod b = 0 then 0 else  b - (a mod b))"
apply (case_tac "b = 0", simp)
apply (blast intro: quorem_div_mod [THEN zminus1_lemma, THEN quorem_mod])
done

lemma zdiv_zminus2: "a div (-b) = (-a::int) div b"
by (cut_tac a = "-a" in zdiv_zminus_zminus, auto)

lemma zmod_zminus2: "a mod (-b) = - ((-a::int) mod b)"
by (cut_tac a = "-a" and b = b in zmod_zminus_zminus, auto)

lemma zdiv_zminus2_eq_if:
     "b ≠ (0::int)  
      ==> a div (-b) =  
          (if a mod b = 0 then - (a div b) else  - (a div b) - 1)"
by (simp add: zdiv_zminus1_eq_if zdiv_zminus2)

lemma zmod_zminus2_eq_if:
     "a mod (-b::int) = (if a mod b = 0 then 0 else  (a mod b) - b)"
by (simp add: zmod_zminus1_eq_if zmod_zminus2)


subsection{*Division of a Number by Itself*}

lemma self_quotient_aux1: "[| (0::int) < a; a = r + a*q; r < a |] ==> 1 ≤ q"
apply (subgoal_tac "0 < a*q")
 apply (simp add: zero_less_mult_iff, arith)
done

lemma self_quotient_aux2: "[| (0::int) < a; a = r + a*q; 0 ≤ r |] ==> q ≤ 1"
apply (subgoal_tac "0 ≤ a* (1-q) ")
 apply (simp add: zero_le_mult_iff)
apply (simp add: right_diff_distrib)
done

lemma self_quotient: "[| quorem((a,a),(q,r));  a ≠ (0::int) |] ==> q = 1"
apply (simp add: split_ifs quorem_def linorder_neq_iff)
apply (rule order_antisym, safe, simp_all)
apply (rule_tac [3] a = "-a" and r = "-r" in self_quotient_aux1)
apply (rule_tac a = "-a" and r = "-r" in self_quotient_aux2)
apply (force intro: self_quotient_aux1 self_quotient_aux2 simp add: add_commute)+
done

lemma self_remainder: "[| quorem((a,a),(q,r));  a ≠ (0::int) |] ==> r = 0"
apply (frule self_quotient, assumption)
apply (simp add: quorem_def)
done

lemma zdiv_self [simp]: "a ≠ 0 ==> a div a = (1::int)"
by (simp add: quorem_div_mod [THEN self_quotient])

(*Here we have 0 mod 0 = 0, also assumed by Knuth (who puts m mod 0 = 0) *)
lemma zmod_self [simp]: "a mod a = (0::int)"
apply (case_tac "a = 0", simp)
apply (simp add: quorem_div_mod [THEN self_remainder])
done


subsection{*Computation of Division and Remainder*}

lemma zdiv_zero [simp]: "(0::int) div b = 0"
by (simp add: div_def divAlg_def)

lemma div_eq_minus1: "(0::int) < b ==> -1 div b = -1"
by (simp add: div_def divAlg_def)

lemma zmod_zero [simp]: "(0::int) mod b = 0"
by (simp add: mod_def divAlg_def)

lemma zdiv_minus1: "(0::int) < b ==> -1 div b = -1"
by (simp add: div_def divAlg_def)

lemma zmod_minus1: "(0::int) < b ==> -1 mod b = b - 1"
by (simp add: mod_def divAlg_def)

text{*a positive, b positive *}

lemma div_pos_pos: "[| 0 < a;  0 ≤ b |] ==> a div b = fst (posDivAlg a b)"
by (simp add: div_def divAlg_def)

lemma mod_pos_pos: "[| 0 < a;  0 ≤ b |] ==> a mod b = snd (posDivAlg a b)"
by (simp add: mod_def divAlg_def)

text{*a negative, b positive *}

lemma div_neg_pos: "[| a < 0;  0 < b |] ==> a div b = fst (negDivAlg a b)"
by (simp add: div_def divAlg_def)

lemma mod_neg_pos: "[| a < 0;  0 < b |] ==> a mod b = snd (negDivAlg a b)"
by (simp add: mod_def divAlg_def)

text{*a positive, b negative *}

lemma div_pos_neg:
     "[| 0 < a;  b < 0 |] ==> a div b = fst (negateSnd (negDivAlg (-a) (-b)))"
by (simp add: div_def divAlg_def)

lemma mod_pos_neg:
     "[| 0 < a;  b < 0 |] ==> a mod b = snd (negateSnd (negDivAlg (-a) (-b)))"
by (simp add: mod_def divAlg_def)

text{*a negative, b negative *}

lemma div_neg_neg:
     "[| a < 0;  b ≤ 0 |] ==> a div b = fst (negateSnd (posDivAlg (-a) (-b)))"
by (simp add: div_def divAlg_def)

lemma mod_neg_neg:
     "[| a < 0;  b ≤ 0 |] ==> a mod b = snd (negateSnd (posDivAlg (-a) (-b)))"
by (simp add: mod_def divAlg_def)

text {*Simplify expresions in which div and mod combine numerical constants*}

lemma quoremI:
  "[|a == b * q + r; if 0 < b then 0 ≤ r ∧ r < b else b < r ∧ r ≤ 0|]
    ==> quorem ((a, b), (q, r))"
  unfolding quorem_def by simp

lemmas quorem_div_eq = quoremI [THEN quorem_div, THEN eq_reflection]
lemmas quorem_mod_eq = quoremI [THEN quorem_mod, THEN eq_reflection]
lemmas arithmetic_simps =
  arith_simps
  add_special
  OrderedGroup.add_0_left
  OrderedGroup.add_0_right
  mult_zero_left
  mult_zero_right
  mult_1_left
  mult_1_right

(* simprocs adapted from HOL/ex/Binary.thy *)
ML {*
local
  infix ==;
  val op == = Logic.mk_equals;
  fun plus m n = @{term "plus :: int => int => int"} $ m $ n;
  fun mult m n = @{term "times :: int => int => int"} $ m $ n;

  val binary_ss = HOL_basic_ss addsimps @{thms arithmetic_simps};
  fun prove ctxt prop =
    Goal.prove ctxt [] [] prop (fn _ => ALLGOALS (full_simp_tac binary_ss));

  fun binary_proc proc ss ct =
    (case Thm.term_of ct of
      _ $ t $ u =>
      (case try (pairself (`(snd o HOLogic.dest_number))) (t, u) of
        SOME args => proc (Simplifier.the_context ss) args
      | NONE => NONE)
    | _ => NONE);
in

fun divmod_proc rule = binary_proc (fn ctxt => fn ((m, t), (n, u)) =>
  if n = 0 then NONE
  else
    let val (k, l) = Integer.div_mod m n;
        fun mk_num x = HOLogic.mk_number HOLogic.intT x;
    in SOME (rule OF [prove ctxt (t == plus (mult u (mk_num k)) (mk_num l))])
    end);

end;
*}

simproc_setup binary_int_div ("number_of m div number_of n :: int") =
  {* K (divmod_proc (@{thm quorem_div_eq})) *}

simproc_setup binary_int_mod ("number_of m mod number_of n :: int") =
  {* K (divmod_proc (@{thm quorem_mod_eq})) *}

(* The following 8 lemmas are made unnecessary by the above simprocs: *)

lemmas div_pos_pos_number_of =
    div_pos_pos [of "number_of v" "number_of w", standard]

lemmas div_neg_pos_number_of =
    div_neg_pos [of "number_of v" "number_of w", standard]

lemmas div_pos_neg_number_of =
    div_pos_neg [of "number_of v" "number_of w", standard]

lemmas div_neg_neg_number_of =
    div_neg_neg [of "number_of v" "number_of w", standard]


lemmas mod_pos_pos_number_of =
    mod_pos_pos [of "number_of v" "number_of w", standard]

lemmas mod_neg_pos_number_of =
    mod_neg_pos [of "number_of v" "number_of w", standard]

lemmas mod_pos_neg_number_of =
    mod_pos_neg [of "number_of v" "number_of w", standard]

lemmas mod_neg_neg_number_of =
    mod_neg_neg [of "number_of v" "number_of w", standard]


lemmas posDivAlg_eqn_number_of [simp] =
    posDivAlg_eqn [of "number_of v" "number_of w", standard]

lemmas negDivAlg_eqn_number_of [simp] =
    negDivAlg_eqn [of "number_of v" "number_of w", standard]


text{*Special-case simplification *}

lemma zmod_1 [simp]: "a mod (1::int) = 0"
apply (cut_tac a = a and b = 1 in pos_mod_sign)
apply (cut_tac [2] a = a and b = 1 in pos_mod_bound)
apply (auto simp del:pos_mod_bound pos_mod_sign)
done

lemma zdiv_1 [simp]: "a div (1::int) = a"
by (cut_tac a = a and b = 1 in zmod_zdiv_equality, auto)

lemma zmod_minus1_right [simp]: "a mod (-1::int) = 0"
apply (cut_tac a = a and b = "-1" in neg_mod_sign)
apply (cut_tac [2] a = a and b = "-1" in neg_mod_bound)
apply (auto simp del: neg_mod_sign neg_mod_bound)
done

lemma zdiv_minus1_right [simp]: "a div (-1::int) = -a"
by (cut_tac a = a and b = "-1" in zmod_zdiv_equality, auto)

(** The last remaining special cases for constant arithmetic:
    1 div z and 1 mod z **)

lemmas div_pos_pos_1_number_of [simp] =
    div_pos_pos [OF int_0_less_1, of "number_of w", standard]

lemmas div_pos_neg_1_number_of [simp] =
    div_pos_neg [OF int_0_less_1, of "number_of w", standard]

lemmas mod_pos_pos_1_number_of [simp] =
    mod_pos_pos [OF int_0_less_1, of "number_of w", standard]

lemmas mod_pos_neg_1_number_of [simp] =
    mod_pos_neg [OF int_0_less_1, of "number_of w", standard]


lemmas posDivAlg_eqn_1_number_of [simp] =
    posDivAlg_eqn [of concl: 1 "number_of w", standard]

lemmas negDivAlg_eqn_1_number_of [simp] =
    negDivAlg_eqn [of concl: 1 "number_of w", standard]



subsection{*Monotonicity in the First Argument (Dividend)*}

lemma zdiv_mono1: "[| a ≤ a';  0 < (b::int) |] ==> a div b ≤ a' div b"
apply (cut_tac a = a and b = b in zmod_zdiv_equality)
apply (cut_tac a = a' and b = b in zmod_zdiv_equality)
apply (rule unique_quotient_lemma)
apply (erule subst)
apply (erule subst, simp_all)
done

lemma zdiv_mono1_neg: "[| a ≤ a';  (b::int) < 0 |] ==> a' div b ≤ a div b"
apply (cut_tac a = a and b = b in zmod_zdiv_equality)
apply (cut_tac a = a' and b = b in zmod_zdiv_equality)
apply (rule unique_quotient_lemma_neg)
apply (erule subst)
apply (erule subst, simp_all)
done


subsection{*Monotonicity in the Second Argument (Divisor)*}

lemma q_pos_lemma:
     "[| 0 ≤ b'*q' + r'; r' < b';  0 < b' |] ==> 0 ≤ (q'::int)"
apply (subgoal_tac "0 < b'* (q' + 1) ")
 apply (simp add: zero_less_mult_iff)
apply (simp add: right_distrib)
done

lemma zdiv_mono2_lemma:
     "[| b*q + r = b'*q' + r';  0 ≤ b'*q' + r';   
         r' < b';  0 ≤ r;  0 < b';  b' ≤ b |]   
      ==> q ≤ (q'::int)"
apply (frule q_pos_lemma, assumption+) 
apply (subgoal_tac "b*q < b* (q' + 1) ")
 apply (simp add: mult_less_cancel_left)
apply (subgoal_tac "b*q = r' - r + b'*q'")
 prefer 2 apply simp
apply (simp (no_asm_simp) add: right_distrib)
apply (subst add_commute, rule zadd_zless_mono, arith)
apply (rule mult_right_mono, auto)
done

lemma zdiv_mono2:
     "[| (0::int) ≤ a;  0 < b';  b' ≤ b |] ==> a div b ≤ a div b'"
apply (subgoal_tac "b ≠ 0")
 prefer 2 apply arith
apply (cut_tac a = a and b = b in zmod_zdiv_equality)
apply (cut_tac a = a and b = b' in zmod_zdiv_equality)
apply (rule zdiv_mono2_lemma)
apply (erule subst)
apply (erule subst, simp_all)
done

lemma q_neg_lemma:
     "[| b'*q' + r' < 0;  0 ≤ r';  0 < b' |] ==> q' ≤ (0::int)"
apply (subgoal_tac "b'*q' < 0")
 apply (simp add: mult_less_0_iff, arith)
done

lemma zdiv_mono2_neg_lemma:
     "[| b*q + r = b'*q' + r';  b'*q' + r' < 0;   
         r < b;  0 ≤ r';  0 < b';  b' ≤ b |]   
      ==> q' ≤ (q::int)"
apply (frule q_neg_lemma, assumption+) 
apply (subgoal_tac "b*q' < b* (q + 1) ")
 apply (simp add: mult_less_cancel_left)
apply (simp add: right_distrib)
apply (subgoal_tac "b*q' ≤ b'*q'")
 prefer 2 apply (simp add: mult_right_mono_neg, arith)
done

lemma zdiv_mono2_neg:
     "[| a < (0::int);  0 < b';  b' ≤ b |] ==> a div b' ≤ a div b"
apply (cut_tac a = a and b = b in zmod_zdiv_equality)
apply (cut_tac a = a and b = b' in zmod_zdiv_equality)
apply (rule zdiv_mono2_neg_lemma)
apply (erule subst)
apply (erule subst, simp_all)
done


subsection{*More Algebraic Laws for div and mod*}

text{*proving (a*b) div c = a * (b div c) + a * (b mod c) *}

lemma zmult1_lemma:
     "[| quorem((b,c),(q,r));  c ≠ 0 |]  
      ==> quorem ((a*b, c), (a*q + a*r div c, a*r mod c))"
by (force simp add: split_ifs quorem_def linorder_neq_iff right_distrib)

lemma zdiv_zmult1_eq: "(a*b) div c = a*(b div c) + a*(b mod c) div (c::int)"
apply (case_tac "c = 0", simp)
apply (blast intro: quorem_div_mod [THEN zmult1_lemma, THEN quorem_div])
done

lemma zmod_zmult1_eq: "(a*b) mod c = a*(b mod c) mod (c::int)"
apply (case_tac "c = 0", simp)
apply (blast intro: quorem_div_mod [THEN zmult1_lemma, THEN quorem_mod])
done

lemma zmod_zmult1_eq': "(a*b) mod (c::int) = ((a mod c) * b) mod c"
apply (rule trans)
apply (rule_tac s = "b*a mod c" in trans)
apply (rule_tac [2] zmod_zmult1_eq)
apply (simp_all add: mult_commute)
done

lemma zmod_zmult_distrib: "(a*b) mod (c::int) = ((a mod c) * (b mod c)) mod c"
apply (rule zmod_zmult1_eq' [THEN trans])
apply (rule zmod_zmult1_eq)
done

lemma zdiv_zmult_self1 [simp]: "b ≠ (0::int) ==> (a*b) div b = a"
by (simp add: zdiv_zmult1_eq)

instance int :: semiring_div
  by intro_classes auto

lemma zdiv_zmult_self2 [simp]: "b ≠ (0::int) ==> (b*a) div b = a"
by (subst mult_commute, erule zdiv_zmult_self1)

lemma zmod_zmult_self1 [simp]: "(a*b) mod b = (0::int)"
by (simp add: zmod_zmult1_eq)

lemma zmod_zmult_self2 [simp]: "(b*a) mod b = (0::int)"
by (simp add: mult_commute zmod_zmult1_eq)

lemma zmod_eq_0_iff: "(m mod d = 0) = (EX q::int. m = d*q)"
proof
  assume "m mod d = 0"
  with zmod_zdiv_equality[of m d] show "EX q::int. m = d*q" by auto
next
  assume "EX q::int. m = d*q"
  thus "m mod d = 0" by auto
qed

lemmas zmod_eq_0D [dest!] = zmod_eq_0_iff [THEN iffD1]

text{*proving (a+b) div c = a div c + b div c + ((a mod c + b mod c) div c) *}

lemma zadd1_lemma:
     "[| quorem((a,c),(aq,ar));  quorem((b,c),(bq,br));  c ≠ 0 |]  
      ==> quorem ((a+b, c), (aq + bq + (ar+br) div c, (ar+br) mod c))"
by (force simp add: split_ifs quorem_def linorder_neq_iff right_distrib)

(*NOT suitable for rewriting: the RHS has an instance of the LHS*)
lemma zdiv_zadd1_eq:
     "(a+b) div (c::int) = a div c + b div c + ((a mod c + b mod c) div c)"
apply (case_tac "c = 0", simp)
apply (blast intro: zadd1_lemma [OF quorem_div_mod quorem_div_mod] quorem_div)
done

lemma zmod_zadd1_eq: "(a+b) mod (c::int) = (a mod c + b mod c) mod c"
apply (case_tac "c = 0", simp)
apply (blast intro: zadd1_lemma [OF quorem_div_mod quorem_div_mod] quorem_mod)
done

lemma mod_div_trivial [simp]: "(a mod b) div b = (0::int)"
apply (case_tac "b = 0", simp)
apply (auto simp add: linorder_neq_iff div_pos_pos_trivial div_neg_neg_trivial)
done

lemma mod_mod_trivial [simp]: "(a mod b) mod b = a mod (b::int)"
apply (case_tac "b = 0", simp)
apply (force simp add: linorder_neq_iff mod_pos_pos_trivial mod_neg_neg_trivial)
done

lemma zmod_zadd_left_eq: "(a+b) mod (c::int) = ((a mod c) + b) mod c"
apply (rule trans [symmetric])
apply (rule zmod_zadd1_eq, simp)
apply (rule zmod_zadd1_eq [symmetric])
done

lemma zmod_zadd_right_eq: "(a+b) mod (c::int) = (a + (b mod c)) mod c"
apply (rule trans [symmetric])
apply (rule zmod_zadd1_eq, simp)
apply (rule zmod_zadd1_eq [symmetric])
done

lemma zdiv_zadd_self1[simp]: "a ≠ (0::int) ==> (a+b) div a = b div a + 1"
by (simp add: zdiv_zadd1_eq)

lemma zdiv_zadd_self2[simp]: "a ≠ (0::int) ==> (b+a) div a = b div a + 1"
by (simp add: zdiv_zadd1_eq)

lemma zmod_zadd_self1[simp]: "(a+b) mod a = b mod (a::int)"
apply (case_tac "a = 0", simp)
apply (simp add: zmod_zadd1_eq)
done

lemma zmod_zadd_self2[simp]: "(b+a) mod a = b mod (a::int)"
apply (case_tac "a = 0", simp)
apply (simp add: zmod_zadd1_eq)
done


lemma zmod_zdiff1_eq: fixes a::int
  shows "(a - b) mod c = (a mod c - b mod c) mod c" (is "?l = ?r")
proof -
  have "?l = (c + (a mod c - b mod c)) mod c"
    using zmod_zadd1_eq[of a "-b" c] by(simp add:ring_simps zmod_zminus1_eq_if)
  also have "… = ?r" by simp
  finally show ?thesis .
qed

subsection{*Proving  @{term "a div (b*c) = (a div b) div c"} *}

(*The condition c>0 seems necessary.  Consider that 7 div ~6 = ~2 but
  7 div 2 div ~3 = 3 div ~3 = ~1.  The subcase (a div b) mod c = 0 seems
  to cause particular problems.*)

text{*first, four lemmas to bound the remainder for the cases b<0 and b>0 *}

lemma zmult2_lemma_aux1: "[| (0::int) < c;  b < r;  r ≤ 0 |] ==> b*c < b*(q mod c) + r"
apply (subgoal_tac "b * (c - q mod c) < r * 1")
apply (simp add: right_diff_distrib)
apply (rule order_le_less_trans)
apply (erule_tac [2] mult_strict_right_mono)
apply (rule mult_left_mono_neg)
apply (auto simp add: compare_rls add_commute [of 1]
                      add1_zle_eq pos_mod_bound)
done

lemma zmult2_lemma_aux2:
     "[| (0::int) < c;   b < r;  r ≤ 0 |] ==> b * (q mod c) + r ≤ 0"
apply (subgoal_tac "b * (q mod c) ≤ 0")
 apply arith
apply (simp add: mult_le_0_iff)
done

lemma zmult2_lemma_aux3: "[| (0::int) < c;  0 ≤ r;  r < b |] ==> 0 ≤ b * (q mod c) + r"
apply (subgoal_tac "0 ≤ b * (q mod c) ")
apply arith
apply (simp add: zero_le_mult_iff)
done

lemma zmult2_lemma_aux4: "[| (0::int) < c; 0 ≤ r; r < b |] ==> b * (q mod c) + r < b * c"
apply (subgoal_tac "r * 1 < b * (c - q mod c) ")
apply (simp add: right_diff_distrib)
apply (rule order_less_le_trans)
apply (erule mult_strict_right_mono)
apply (rule_tac [2] mult_left_mono)
apply (auto simp add: compare_rls add_commute [of 1]
                      add1_zle_eq pos_mod_bound)
done

lemma zmult2_lemma: "[| quorem ((a,b), (q,r));  b ≠ 0;  0 < c |]  
      ==> quorem ((a, b*c), (q div c, b*(q mod c) + r))"
by (auto simp add: mult_ac quorem_def linorder_neq_iff
                   zero_less_mult_iff right_distrib [symmetric] 
                   zmult2_lemma_aux1 zmult2_lemma_aux2 zmult2_lemma_aux3 zmult2_lemma_aux4)

lemma zdiv_zmult2_eq: "(0::int) < c ==> a div (b*c) = (a div b) div c"
apply (case_tac "b = 0", simp)
apply (force simp add: quorem_div_mod [THEN zmult2_lemma, THEN quorem_div])
done

lemma zmod_zmult2_eq:
     "(0::int) < c ==> a mod (b*c) = b*(a div b mod c) + a mod b"
apply (case_tac "b = 0", simp)
apply (force simp add: quorem_div_mod [THEN zmult2_lemma, THEN quorem_mod])
done


subsection{*Cancellation of Common Factors in div*}

lemma zdiv_zmult_zmult1_aux1:
     "[| (0::int) < b;  c ≠ 0 |] ==> (c*a) div (c*b) = a div b"
by (subst zdiv_zmult2_eq, auto)

lemma zdiv_zmult_zmult1_aux2:
     "[| b < (0::int);  c ≠ 0 |] ==> (c*a) div (c*b) = a div b"
apply (subgoal_tac " (c * (-a)) div (c * (-b)) = (-a) div (-b) ")
apply (rule_tac [2] zdiv_zmult_zmult1_aux1, auto)
done

lemma zdiv_zmult_zmult1: "c ≠ (0::int) ==> (c*a) div (c*b) = a div b"
apply (case_tac "b = 0", simp)
apply (auto simp add: linorder_neq_iff zdiv_zmult_zmult1_aux1 zdiv_zmult_zmult1_aux2)
done

lemma zdiv_zmult_zmult1_if[simp]:
  "(k*m) div (k*n) = (if k = (0::int) then 0 else m div n)"
by (simp add:zdiv_zmult_zmult1)

(*
lemma zdiv_zmult_zmult2: "c ≠ (0::int) ==> (a*c) div (b*c) = a div b"
apply (drule zdiv_zmult_zmult1)
apply (auto simp add: mult_commute)
done
*)


subsection{*Distribution of Factors over mod*}

lemma zmod_zmult_zmult1_aux1:
     "[| (0::int) < b;  c ≠ 0 |] ==> (c*a) mod (c*b) = c * (a mod b)"
by (subst zmod_zmult2_eq, auto)

lemma zmod_zmult_zmult1_aux2:
     "[| b < (0::int);  c ≠ 0 |] ==> (c*a) mod (c*b) = c * (a mod b)"
apply (subgoal_tac " (c * (-a)) mod (c * (-b)) = c * ((-a) mod (-b))")
apply (rule_tac [2] zmod_zmult_zmult1_aux1, auto)
done

lemma zmod_zmult_zmult1: "(c*a) mod (c*b) = (c::int) * (a mod b)"
apply (case_tac "b = 0", simp)
apply (case_tac "c = 0", simp)
apply (auto simp add: linorder_neq_iff zmod_zmult_zmult1_aux1 zmod_zmult_zmult1_aux2)
done

lemma zmod_zmult_zmult2: "(a*c) mod (b*c) = (a mod b) * (c::int)"
apply (cut_tac c = c in zmod_zmult_zmult1)
apply (auto simp add: mult_commute)
done

lemma zmod_zmod_cancel:
assumes "n dvd m" shows "(k::int) mod m mod n = k mod n"
proof -
  from `n dvd m` obtain r where "m = n*r" by(auto simp:dvd_def)
  have "k mod n = (m * (k div m) + k mod m) mod n"
    using zmod_zdiv_equality[of k m] by simp
  also have "… = (m * (k div m) mod n + k mod m mod n) mod n"
    by(subst zmod_zadd1_eq, rule refl)
  also have "m * (k div m) mod n = 0" using `m = n*r`
    by(simp add:mult_ac)
  finally show ?thesis by simp
qed


subsection {*Splitting Rules for div and mod*}

text{*The proofs of the two lemmas below are essentially identical*}

lemma split_pos_lemma:
 "0<k ==> 
    P(n div k :: int)(n mod k) = (∀i j. 0≤j & j<k & n = k*i + j --> P i j)"
apply (rule iffI, clarify)
 apply (erule_tac P="P ?x ?y" in rev_mp)  
 apply (subst zmod_zadd1_eq) 
 apply (subst zdiv_zadd1_eq) 
 apply (simp add: div_pos_pos_trivial mod_pos_pos_trivial)  
txt{*converse direction*}
apply (drule_tac x = "n div k" in spec) 
apply (drule_tac x = "n mod k" in spec, simp)
done

lemma split_neg_lemma:
 "k<0 ==>
    P(n div k :: int)(n mod k) = (∀i j. k<j & j≤0 & n = k*i + j --> P i j)"
apply (rule iffI, clarify)
 apply (erule_tac P="P ?x ?y" in rev_mp)  
 apply (subst zmod_zadd1_eq) 
 apply (subst zdiv_zadd1_eq) 
 apply (simp add: div_neg_neg_trivial mod_neg_neg_trivial)  
txt{*converse direction*}
apply (drule_tac x = "n div k" in spec) 
apply (drule_tac x = "n mod k" in spec, simp)
done

lemma split_zdiv:
 "P(n div k :: int) =
  ((k = 0 --> P 0) & 
   (0<k --> (∀i j. 0≤j & j<k & n = k*i + j --> P i)) & 
   (k<0 --> (∀i j. k<j & j≤0 & n = k*i + j --> P i)))"
apply (case_tac "k=0", simp)
apply (simp only: linorder_neq_iff)
apply (erule disjE) 
 apply (simp_all add: split_pos_lemma [of concl: "%x y. P x"] 
                      split_neg_lemma [of concl: "%x y. P x"])
done

lemma split_zmod:
 "P(n mod k :: int) =
  ((k = 0 --> P n) & 
   (0<k --> (∀i j. 0≤j & j<k & n = k*i + j --> P j)) & 
   (k<0 --> (∀i j. k<j & j≤0 & n = k*i + j --> P j)))"
apply (case_tac "k=0", simp)
apply (simp only: linorder_neq_iff)
apply (erule disjE) 
 apply (simp_all add: split_pos_lemma [of concl: "%x y. P y"] 
                      split_neg_lemma [of concl: "%x y. P y"])
done

(* Enable arith to deal with div 2 and mod 2: *)
declare split_zdiv [of _ _ "number_of k", simplified, standard, arith_split]
declare split_zmod [of _ _ "number_of k", simplified, standard, arith_split]


subsection{*Speeding up the Division Algorithm with Shifting*}

text{*computing div by shifting *}

lemma pos_zdiv_mult_2: "(0::int) ≤ a ==> (1 + 2*b) div (2*a) = b div a"
proof cases
  assume "a=0"
    thus ?thesis by simp
next
  assume "a≠0" and le_a: "0≤a"   
  hence a_pos: "1 ≤ a" by arith
  hence one_less_a2: "1 < 2*a" by arith
  hence le_2a: "2 * (1 + b mod a) ≤ 2 * a"
    by (simp add: mult_le_cancel_left add_commute [of 1] add1_zle_eq)
  with a_pos have "0 ≤ b mod a" by simp
  hence le_addm: "0 ≤ 1 mod (2*a) + 2*(b mod a)"
    by (simp add: mod_pos_pos_trivial one_less_a2)
  with  le_2a
  have "(1 mod (2*a) + 2*(b mod a)) div (2*a) = 0"
    by (simp add: div_pos_pos_trivial le_addm mod_pos_pos_trivial one_less_a2
                  right_distrib) 
  thus ?thesis
    by (subst zdiv_zadd1_eq,
        simp add: zdiv_zmult_zmult1 zmod_zmult_zmult1 one_less_a2
                  div_pos_pos_trivial)
qed

lemma neg_zdiv_mult_2: "a ≤ (0::int) ==> (1 + 2*b) div (2*a) = (b+1) div a"
apply (subgoal_tac " (1 + 2* (-b - 1)) div (2 * (-a)) = (-b - 1) div (-a) ")
apply (rule_tac [2] pos_zdiv_mult_2)
apply (auto simp add: minus_mult_right [symmetric] right_diff_distrib)
apply (subgoal_tac " (-1 - (2 * b)) = - (1 + (2 * b))")
apply (simp only: zdiv_zminus_zminus diff_minus minus_add_distrib [symmetric],
       simp) 
done

(*Not clear why this must be proved separately; probably number_of causes
  simplification problems*)
lemma not_0_le_lemma: "~ 0 ≤ x ==> x ≤ (0::int)"
by auto

lemma zdiv_number_of_Bit0 [simp]:
     "number_of (Int.Bit0 v) div number_of (Int.Bit0 w) =  
          number_of v div (number_of w :: int)"
by (simp only: number_of_eq numeral_simps) simp

lemma zdiv_number_of_Bit1 [simp]:
     "number_of (Int.Bit1 v) div number_of (Int.Bit0 w) =  
          (if (0::int) ≤ number_of w                    
           then number_of v div (number_of w)     
           else (number_of v + (1::int)) div (number_of w))"
apply (simp only: number_of_eq numeral_simps UNIV_I split: split_if) 
apply (simp add: zdiv_zmult_zmult1 pos_zdiv_mult_2 neg_zdiv_mult_2 add_ac)
done


subsection{*Computing mod by Shifting (proofs resemble those for div)*}

lemma pos_zmod_mult_2:
     "(0::int) ≤ a ==> (1 + 2*b) mod (2*a) = 1 + 2 * (b mod a)"
apply (case_tac "a = 0", simp)
apply (subgoal_tac "1 < a * 2")
 prefer 2 apply arith
apply (subgoal_tac "2* (1 + b mod a) ≤ 2*a")
 apply (rule_tac [2] mult_left_mono)
apply (auto simp add: add_commute [of 1] mult_commute add1_zle_eq 
                      pos_mod_bound)
apply (subst zmod_zadd1_eq)
apply (simp add: zmod_zmult_zmult2 mod_pos_pos_trivial)
apply (rule mod_pos_pos_trivial)
apply (auto simp add: mod_pos_pos_trivial ring_distribs)
apply (subgoal_tac "0 ≤ b mod a", arith, simp)
done

lemma neg_zmod_mult_2:
     "a ≤ (0::int) ==> (1 + 2*b) mod (2*a) = 2 * ((b+1) mod a) - 1"
apply (subgoal_tac "(1 + 2* (-b - 1)) mod (2* (-a)) = 
                    1 + 2* ((-b - 1) mod (-a))")
apply (rule_tac [2] pos_zmod_mult_2)
apply (auto simp add: minus_mult_right [symmetric] right_diff_distrib)
apply (subgoal_tac " (-1 - (2 * b)) = - (1 + (2 * b))")
 prefer 2 apply simp 
apply (simp only: zmod_zminus_zminus diff_minus minus_add_distrib [symmetric])
done

lemma zmod_number_of_Bit0 [simp]:
     "number_of (Int.Bit0 v) mod number_of (Int.Bit0 w) =  
      (2::int) * (number_of v mod number_of w)"
apply (simp only: number_of_eq numeral_simps) 
apply (simp add: zmod_zmult_zmult1 pos_zmod_mult_2 
                 not_0_le_lemma neg_zmod_mult_2 add_ac)
done

lemma zmod_number_of_Bit1 [simp]:
     "number_of (Int.Bit1 v) mod number_of (Int.Bit0 w) =  
      (if (0::int) ≤ number_of w  
                then 2 * (number_of v mod number_of w) + 1     
                else 2 * ((number_of v + (1::int)) mod number_of w) - 1)"
apply (simp only: number_of_eq numeral_simps) 
apply (simp add: zmod_zmult_zmult1 pos_zmod_mult_2 
                 not_0_le_lemma neg_zmod_mult_2 add_ac)
done


subsection{*Quotients of Signs*}

lemma div_neg_pos_less0: "[| a < (0::int);  0 < b |] ==> a div b < 0"
apply (subgoal_tac "a div b ≤ -1", force)
apply (rule order_trans)
apply (rule_tac a' = "-1" in zdiv_mono1)
apply (auto simp add: zdiv_minus1)
done

lemma div_nonneg_neg_le0: "[| (0::int) ≤ a;  b < 0 |] ==> a div b ≤ 0"
by (drule zdiv_mono1_neg, auto)

lemma pos_imp_zdiv_nonneg_iff: "(0::int) < b ==> (0 ≤ a div b) = (0 ≤ a)"
apply auto
apply (drule_tac [2] zdiv_mono1)
apply (auto simp add: linorder_neq_iff)
apply (simp (no_asm_use) add: linorder_not_less [symmetric])
apply (blast intro: div_neg_pos_less0)
done

lemma neg_imp_zdiv_nonneg_iff:
     "b < (0::int) ==> (0 ≤ a div b) = (a ≤ (0::int))"
apply (subst zdiv_zminus_zminus [symmetric])
apply (subst pos_imp_zdiv_nonneg_iff, auto)
done

(*But not (a div b ≤ 0 iff a≤0); consider a=1, b=2 when a div b = 0.*)
lemma pos_imp_zdiv_neg_iff: "(0::int) < b ==> (a div b < 0) = (a < 0)"
by (simp add: linorder_not_le [symmetric] pos_imp_zdiv_nonneg_iff)

(*Again the law fails for ≤: consider a = -1, b = -2 when a div b = 0*)
lemma neg_imp_zdiv_neg_iff: "b < (0::int) ==> (a div b < 0) = (0 < a)"
by (simp add: linorder_not_le [symmetric] neg_imp_zdiv_nonneg_iff)


subsection {* The Divides Relation *}

lemma zdvd_iff_zmod_eq_0: "(m dvd n) = (n mod m = (0::int))"
  by (simp add: dvd_def zmod_eq_0_iff)

lemmas zdvd_iff_zmod_eq_0_number_of [simp] =
  zdvd_iff_zmod_eq_0 [of "number_of x" "number_of y", standard]

lemma zdvd_0_right [iff]: "(m::int) dvd 0"
  by (simp add: dvd_def)

lemma zdvd_0_left [iff,noatp]: "(0 dvd (m::int)) = (m = 0)"
  by (simp add: dvd_def)

lemma zdvd_1_left [iff]: "1 dvd (m::int)"
  by (simp add: dvd_def)

lemma zdvd_refl [simp]: "m dvd (m::int)"
  by (auto simp add: dvd_def intro: zmult_1_right [symmetric])

lemma zdvd_trans: "m dvd n ==> n dvd k ==> m dvd (k::int)"
  by (auto simp add: dvd_def intro: mult_assoc)

lemma zdvd_zminus_iff: "(m dvd -n) = (m dvd (n::int))"
  apply (simp add: dvd_def, auto)
   apply (rule_tac [!] x = "-k" in exI, auto)
  done

lemma zdvd_zminus2_iff: "(-m dvd n) = (m dvd (n::int))"
  apply (simp add: dvd_def, auto)
   apply (rule_tac [!] x = "-k" in exI, auto)
  done
lemma zdvd_abs1: "( ¦i::int¦ dvd j) = (i dvd j)" 
  apply (cases "i > 0", simp)
  apply (simp add: dvd_def)
  apply (rule iffI)
  apply (erule exE)
  apply (rule_tac x="- k" in exI, simp)
  apply (erule exE)
  apply (rule_tac x="- k" in exI, simp)
  done
lemma zdvd_abs2: "( (i::int) dvd ¦j¦) = (i dvd j)" 
  apply (cases "j > 0", simp)
  apply (simp add: dvd_def)
  apply (rule iffI)
  apply (erule exE)
  apply (rule_tac x="- k" in exI, simp)
  apply (erule exE)
  apply (rule_tac x="- k" in exI, simp)
  done

lemma zdvd_anti_sym:
    "0 < m ==> 0 < n ==> m dvd n ==> n dvd m ==> m = (n::int)"
  apply (simp add: dvd_def, auto)
  apply (simp add: mult_assoc zero_less_mult_iff zmult_eq_1_iff)
  done

lemma zdvd_zadd: "k dvd m ==> k dvd n ==> k dvd (m + n :: int)"
  apply (simp add: dvd_def)
  apply (blast intro: right_distrib [symmetric])
  done

lemma zdvd_dvd_eq: assumes anz:"a ≠ 0" and ab: "(a::int) dvd b" and ba:"b dvd a" 
  shows "¦a¦ = ¦b¦"
proof-
  from ab obtain k where k:"b = a*k" unfolding dvd_def by blast 
  from ba obtain k' where k':"a = b*k'" unfolding dvd_def by blast 
  from k k' have "a = a*k*k'" by simp
  with mult_cancel_left1[where c="a" and b="k*k'"]
  have kk':"k*k' = 1" using anz by (simp add: mult_assoc)
  hence "k = 1 ∧ k' = 1 ∨ k = -1 ∧ k' = -1" by (simp add: zmult_eq_1_iff)
  thus ?thesis using k k' by auto
qed

lemma zdvd_zdiff: "k dvd m ==> k dvd n ==> k dvd (m - n :: int)"
  apply (simp add: dvd_def)
  apply (blast intro: right_diff_distrib [symmetric])
  done

lemma zdvd_zdiffD: "k dvd m - n ==> k dvd n ==> k dvd (m::int)"
  apply (subgoal_tac "m = n + (m - n)")
   apply (erule ssubst)
   apply (blast intro: zdvd_zadd, simp)
  done

lemma zdvd_zmult: "k dvd (n::int) ==> k dvd m * n"
  apply (simp add: dvd_def)
  apply (blast intro: mult_left_commute)
  done

lemma zdvd_zmult2: "k dvd (m::int) ==> k dvd m * n"
  apply (subst mult_commute)
  apply (erule zdvd_zmult)
  done

lemma zdvd_triv_right [iff]: "(k::int) dvd m * k"
  apply (rule zdvd_zmult)
  apply (rule zdvd_refl)
  done

lemma zdvd_triv_left [iff]: "(k::int) dvd k * m"
  apply (rule zdvd_zmult2)
  apply (rule zdvd_refl)
  done

lemma zdvd_zmultD2: "j * k dvd n ==> j dvd (n::int)"
  apply (simp add: dvd_def)
  apply (simp add: mult_assoc, blast)
  done

lemma zdvd_zmultD: "j * k dvd n ==> k dvd (n::int)"
  apply (rule zdvd_zmultD2)
  apply (subst mult_commute, assumption)
  done

lemma zdvd_zmult_mono: "i dvd m ==> j dvd (n::int) ==> i * j dvd m * n"
  apply (simp add: dvd_def, clarify)
  apply (rule_tac x = "k * ka" in exI)
  apply (simp add: mult_ac)
  done

lemma zdvd_reduce: "(k dvd n + k * m) = (k dvd (n::int))"
  apply (rule iffI)
   apply (erule_tac [2] zdvd_zadd)
   apply (subgoal_tac "n = (n + k * m) - k * m")
    apply (erule ssubst)
    apply (erule zdvd_zdiff, simp_all)
  done

lemma zdvd_zmod: "f dvd m ==> f dvd (n::int) ==> f dvd m mod n"
  apply (simp add: dvd_def)
  apply (auto simp add: zmod_zmult_zmult1)
  done

lemma zdvd_zmod_imp_zdvd: "k dvd m mod n ==> k dvd n ==> k dvd (m::int)"
  apply (subgoal_tac "k dvd n * (m div n) + m mod n")
   apply (simp add: zmod_zdiv_equality [symmetric])
  apply (simp only: zdvd_zadd zdvd_zmult2)
  done

lemma zdvd_not_zless: "0 < m ==> m < n ==> ¬ n dvd (m::int)"
  apply (simp add: dvd_def, auto)
  apply (subgoal_tac "0 < n")
   prefer 2
   apply (blast intro: order_less_trans)
  apply (simp add: zero_less_mult_iff)
  apply (subgoal_tac "n * k < n * 1")
   apply (drule mult_less_cancel_left [THEN iffD1], auto)
  done
lemma zmult_div_cancel: "(n::int) * (m div n) = m - (m mod n)"
  using zmod_zdiv_equality[where a="m" and b="n"]
  by (simp add: ring_simps)

lemma zdvd_mult_div_cancel:"(n::int) dvd m ==> n * (m div n) = m"
apply (subgoal_tac "m mod n = 0")
 apply (simp add: zmult_div_cancel)
apply (simp only: zdvd_iff_zmod_eq_0)
done

lemma zdvd_mult_cancel: assumes d:"k * m dvd k * n" and kz:"k ≠ (0::int)"
  shows "m dvd n"
proof-
  from d obtain h where h: "k*n = k*m * h" unfolding dvd_def by blast
  {assume "n ≠ m*h" hence "k* n ≠ k* (m*h)" using kz by simp
    with h have False by (simp add: mult_assoc)}
  hence "n = m * h" by blast
  thus ?thesis by blast
qed

lemma zdvd_zmult_cancel_disj[simp]:
  "(k*m) dvd (k*n) = (k=0 | m dvd (n::int))"
by (auto simp: zdvd_zmult_mono dest: zdvd_mult_cancel)


theorem ex_nat: "(∃x::nat. P x) = (∃x::int. 0 <= x ∧ P (nat x))"
apply (simp split add: split_nat)
apply (rule iffI)
apply (erule exE)
apply (rule_tac x = "int x" in exI)
apply simp
apply (erule exE)
apply (rule_tac x = "nat x" in exI)
apply (erule conjE)
apply (erule_tac x = "nat x" in allE)
apply simp
done

theorem zdvd_int: "(x dvd y) = (int x dvd int y)"
apply (simp only: dvd_def ex_nat int_int_eq [symmetric] zmult_int [symmetric]
    nat_0_le cong add: conj_cong)
apply (rule iffI)
apply iprover
apply (erule exE)
apply (case_tac "x=0")
apply (rule_tac x=0 in exI)
apply simp
apply (case_tac "0 ≤ k")
apply iprover
apply (simp add: neq0_conv linorder_not_le)
apply (drule mult_strict_left_mono_neg [OF iffD2 [OF zero_less_int_conv]])
apply assumption
apply (simp add: mult_ac)
done

lemma zdvd1_eq[simp]: "(x::int) dvd 1 = ( ¦x¦ = 1)"
proof
  assume d: "x dvd 1" hence "int (nat ¦x¦) dvd int (nat 1)" by (simp add: zdvd_abs1)
  hence "nat ¦x¦ dvd 1" by (simp add: zdvd_int)
  hence "nat ¦x¦ = 1"  by simp
  thus "¦x¦ = 1" by (cases "x < 0", auto)
next
  assume "¦x¦=1" thus "x dvd 1" 
    by(cases "x < 0",simp_all add: minus_equation_iff zdvd_iff_zmod_eq_0)
qed
lemma zdvd_mult_cancel1: 
  assumes mp:"m ≠(0::int)" shows "(m * n dvd m) = (¦n¦ = 1)"
proof
  assume n1: "¦n¦ = 1" thus "m * n dvd m" 
    by (cases "n >0", auto simp add: zdvd_zminus2_iff minus_equation_iff)
next
  assume H: "m * n dvd m" hence H2: "m * n dvd m * 1" by simp
  from zdvd_mult_cancel[OF H2 mp] show "¦n¦ = 1" by (simp only: zdvd1_eq)
qed

lemma int_dvd_iff: "(int m dvd z) = (m dvd nat (abs z))"
  apply (auto simp add: dvd_def nat_abs_mult_distrib)
  apply (auto simp add: nat_eq_iff abs_if split add: split_if_asm)
   apply (rule_tac x = "-(int k)" in exI)
  apply (auto simp add: int_mult)
  done

lemma dvd_int_iff: "(z dvd int m) = (nat (abs z) dvd m)"
  apply (auto simp add: dvd_def abs_if int_mult)
    apply (rule_tac [3] x = "nat k" in exI)
    apply (rule_tac [2] x = "-(int k)" in exI)
    apply (rule_tac x = "nat (-k)" in exI)
    apply (cut_tac [3] k = m in int_less_0_conv)
    apply (cut_tac k = m in int_less_0_conv)
    apply (auto simp add: zero_le_mult_iff mult_less_0_iff
      nat_mult_distrib [symmetric] nat_eq_iff2)
  done

lemma nat_dvd_iff: "(nat z dvd m) = (if 0 ≤ z then (z dvd int m) else m = 0)"
  apply (auto simp add: dvd_def int_mult)
  apply (rule_tac x = "nat k" in exI)
  apply (cut_tac k = m in int_less_0_conv)
  apply (auto simp add: zero_le_mult_iff mult_less_0_iff
    nat_mult_distrib [symmetric] nat_eq_iff2)
  done

lemma zminus_dvd_iff [iff]: "(-z dvd w) = (z dvd (w::int))"
  apply (auto simp add: dvd_def)
   apply (rule_tac [!] x = "-k" in exI, auto)
  done

lemma dvd_zminus_iff [iff]: "(z dvd -w) = (z dvd (w::int))"
  apply (auto simp add: dvd_def)
   apply (drule minus_equation_iff [THEN iffD1])
   apply (rule_tac [!] x = "-k" in exI, auto)
  done

lemma zdvd_imp_le: "[| z dvd n; 0 < n |] ==> z ≤ (n::int)"
  apply (rule_tac z=n in int_cases)
  apply (auto simp add: dvd_int_iff)
  apply (rule_tac z=z in int_cases)
  apply (auto simp add: dvd_imp_le)
  done

lemma zpower_zmod: "((x::int) mod m)^y mod m = x^y mod m"
apply (induct "y", auto)
apply (rule zmod_zmult1_eq [THEN trans])
apply (simp (no_asm_simp))
apply (rule zmod_zmult_distrib [symmetric])
done

lemma zdiv_int: "int (a div b) = (int a) div (int b)"
apply (subst split_div, auto)
apply (subst split_zdiv, auto)
apply (rule_tac a="int (b * i) + int j" and b="int b" and r="int j" and r'=ja in IntDiv.unique_quotient)
apply (auto simp add: IntDiv.quorem_def of_nat_mult)
done

lemma zmod_int: "int (a mod b) = (int a) mod (int b)"
apply (subst split_mod, auto)
apply (subst split_zmod, auto)
apply (rule_tac a="int (b * i) + int j" and b="int b" and q="int i" and q'=ia 
       in unique_remainder)
apply (auto simp add: IntDiv.quorem_def of_nat_mult)
done

text{*Suggested by Matthias Daum*}
lemma int_power_div_base:
     "[|0 < m; 0 < k|] ==> k ^ m div k = (k::int) ^ (m - Suc 0)"
apply (subgoal_tac "k ^ m = k ^ ((m - 1) + 1)")
 apply (erule ssubst)
 apply (simp only: power_add)
 apply simp_all
done

text {* by Brian Huffman *}
lemma zminus_zmod: "- ((x::int) mod m) mod m = - x mod m"
by (simp only: zmod_zminus1_eq_if mod_mod_trivial)

lemma zdiff_zmod_left: "(x mod m - y) mod m = (x - y) mod (m::int)"
by (simp only: diff_def zmod_zadd_left_eq [symmetric])

lemma zdiff_zmod_right: "(x - y mod m) mod m = (x - y) mod (m::int)"
proof -
  have "(x + - (y mod m) mod m) mod m = (x + - y mod m) mod m"
    by (simp only: zminus_zmod)
  hence "(x + - (y mod m)) mod m = (x + - y) mod m"
    by (simp only: zmod_zadd_right_eq [symmetric])
  thus "(x - y mod m) mod m = (x - y) mod m"
    by (simp only: diff_def)
qed

lemmas zmod_simps =
  IntDiv.zmod_zadd_left_eq  [symmetric]
  IntDiv.zmod_zadd_right_eq [symmetric]
  IntDiv.zmod_zmult1_eq     [symmetric]
  IntDiv.zmod_zmult1_eq'    [symmetric]
  IntDiv.zpower_zmod
  zminus_zmod zdiff_zmod_left zdiff_zmod_right

text {* code generator setup *}

context ring_1
begin

lemma of_int_num [code func]:
  "of_int k = (if k = 0 then 0 else if k < 0 then
     - of_int (- k) else let
       (l, m) = divAlg (k, 2);
       l' = of_int l
     in if m = 0 then l' + l' else l' + l' + 1)"
proof -
  have aux1: "k mod (2::int) ≠ (0::int) ==> 
    of_int k = of_int (k div 2 * 2 + 1)"
  proof -
    have "k mod 2 < 2" by (auto intro: pos_mod_bound)
    moreover have "0 ≤ k mod 2" by (auto intro: pos_mod_sign)
    moreover assume "k mod 2 ≠ 0"
    ultimately have "k mod 2 = 1" by arith
    moreover have "of_int k = of_int (k div 2 * 2 + k mod 2)" by simp
    ultimately show ?thesis by auto
  qed
  have aux2: "!!x. of_int 2 * x = x + x"
  proof -
    fix x
    have int2: "(2::int) = 1 + 1" by arith
    show "of_int 2 * x = x + x"
    unfolding int2 of_int_add left_distrib by simp
  qed
  have aux3: "!!x. x * of_int 2 = x + x"
  proof -
    fix x
    have int2: "(2::int) = 1 + 1" by arith
    show "x * of_int 2 = x + x" 
    unfolding int2 of_int_add right_distrib by simp
  qed
  from aux1 show ?thesis by (auto simp add: divAlg_mod_div Let_def aux2 aux3)
qed

end

code_modulename SML
  IntDiv Integer

code_modulename OCaml
  IntDiv Integer

code_modulename Haskell
  IntDiv Integer

end

lemma divAlg_mod_div:

  divAlg (p, q) = (p div q, p mod q)

Uniqueness and Monotonicity of Quotients and Remainders

lemma unique_quotient_lemma:

  [| b * q' + r'  b * q + r; 0  r'; r' < b; r < b |] ==> q'  q

lemma unique_quotient_lemma_neg:

  [| b * q' + r'  b * q + r; r  0; b < r; b < r' |] ==> q  q'

lemma unique_quotient:

  [| quorem ((a, b), q, r); quorem ((a, b), q', r'); b  0 |] ==> q = q'

lemma unique_remainder:

  [| quorem ((a, b), q, r); quorem ((a, b), q', r'); b  0 |] ==> r = r'

Correctness of @{term posDivAlg}, the Algorithm for Non-Negative Dividends

lemma adjust_eq:

  adjust b (q, r) =
  (let diff = r - b in if 0  diff then (2 * q + 1, diff) else (2 * q, r))

lemma posDivAlg_eqn:

  0 < b
  ==> posDivAlg a b = (if a < b then (0, a) else adjust b (posDivAlg a (2 * b)))

theorem posDivAlg_correct:

  [| 0  a; 0 < b |] ==> quorem ((a, b), posDivAlg a b)

Correctness of @{term negDivAlg}, the Algorithm for Negative Dividends

lemma negDivAlg_eqn:

  0 < b
  ==> negDivAlg a b =
      (if 0  a + b then (-1, a + b) else adjust b (negDivAlg a (2 * b)))

lemma negDivAlg_correct:

  [| a < 0; 0 < b |] ==> quorem ((a, b), negDivAlg a b)

Existence Shown by Proving the Division Algorithm to be Correct

lemma quorem_0:

  b  0 ==> quorem ((0, b), 0, 0)

lemma posDivAlg_0:

  posDivAlg 0 b = (0, 0)

lemma negDivAlg_minus1:

  negDivAlg -1 b = (-1, b - 1)

lemma negateSnd_eq:

  negateSnd (q, r) = (q, - r)

lemma quorem_neg:

  quorem ((- a, - b), qr) ==> quorem ((a, b), negateSnd qr)

lemma divAlg_correct:

  b  0 ==> quorem ((a, b), divAlg (a, b))

lemma DIVISION_BY_ZERO:

  a div 0 = 0a mod 0 = a

lemma zmod_zdiv_equality:

  a = b * (a div b) + a mod b

lemma zdiv_zmod_equality:

  b * (a div b) + a mod b + k = a + k

lemma zdiv_zmod_equality2:

  a div b * b + a mod b + k = a + k

lemma pos_mod_conj:

  0 < b ==> 0  a mod ba mod b < b

lemma pos_mod_sign:

  0 < b ==> 0  a mod b

and pos_mod_bound:

  0 < b ==> a mod b < b

lemma neg_mod_conj:

  b < 0 ==> a mod b  0b < a mod b

lemma neg_mod_sign:

  b < 0 ==> a mod b  0

and neg_mod_bound:

  b < 0 ==> b < a mod b

General Properties of div and mod

lemma quorem_div_mod:

  b  0 ==> quorem ((a, b), a div b, a mod b)

lemma quorem_div:

  [| quorem ((a, b), q, r); b  0 |] ==> a div b = q

lemma quorem_mod:

  [| quorem ((a, b), q, r); b  0 |] ==> a mod b = r

lemma div_pos_pos_trivial:

  [| 0  a; a < b |] ==> a div b = 0

lemma div_neg_neg_trivial:

  [| a  0; b < a |] ==> a div b = 0

lemma div_pos_neg_trivial:

  [| 0 < a; a + b  0 |] ==> a div b = -1

lemma mod_pos_pos_trivial:

  [| 0  a; a < b |] ==> a mod b = a

lemma mod_neg_neg_trivial:

  [| a  0; b < a |] ==> a mod b = a

lemma mod_pos_neg_trivial:

  [| 0 < a; a + b  0 |] ==> a mod b = a + b

lemma zdiv_zminus_zminus:

  - a div - b = a div b

lemma zmod_zminus_zminus:

  - a mod - b = - (a mod b)

Laws for div and mod with Unary Minus

lemma zminus1_lemma:

  quorem ((a, b), q, r)
  ==> quorem
       ((- a, b), if r = 0 then - q else - q - 1, if r = 0 then 0 else b - r)

lemma zdiv_zminus1_eq_if:

  b  0 ==> - a div b = (if a mod b = 0 then - (a div b) else - (a div b) - 1)

lemma zmod_zminus1_eq_if:

  - a mod b = (if a mod b = 0 then 0 else b - a mod b)

lemma zdiv_zminus2:

  a div - b = - a div b

lemma zmod_zminus2:

  a mod - b = - (- a mod b)

lemma zdiv_zminus2_eq_if:

  b  0 ==> a div - b = (if a mod b = 0 then - (a div b) else - (a div b) - 1)

lemma zmod_zminus2_eq_if:

  a mod - b = (if a mod b = 0 then 0 else a mod b - b)

Division of a Number by Itself

lemma self_quotient_aux1:

  [| 0 < a; a = r + a * q; r < a |] ==> 1  q

lemma self_quotient_aux2:

  [| 0 < a; a = r + a * q; 0  r |] ==> q  1

lemma self_quotient:

  [| quorem ((a, a), q, r); a  0 |] ==> q = 1

lemma self_remainder:

  [| quorem ((a, a), q, r); a  0 |] ==> r = 0

lemma zdiv_self:

  a  0 ==> a div a = 1

lemma zmod_self:

  a mod a = 0

Computation of Division and Remainder

lemma zdiv_zero:

  0 div b = 0

lemma div_eq_minus1:

  0 < b ==> -1 div b = -1

lemma zmod_zero:

  0 mod b = 0

lemma zdiv_minus1:

  0 < b ==> -1 div b = -1

lemma zmod_minus1:

  0 < b ==> -1 mod b = b - 1

lemma div_pos_pos:

  [| 0 < a; 0  b |] ==> a div b = fst (posDivAlg a b)

lemma mod_pos_pos:

  [| 0 < a; 0  b |] ==> a mod b = snd (posDivAlg a b)

lemma div_neg_pos:

  [| a < 0; 0 < b |] ==> a div b = fst (negDivAlg a b)

lemma mod_neg_pos:

  [| a < 0; 0 < b |] ==> a mod b = snd (negDivAlg a b)

lemma div_pos_neg:

  [| 0 < a; b < 0 |] ==> a div b = fst (negateSnd (negDivAlg (- a) (- b)))

lemma mod_pos_neg:

  [| 0 < a; b < 0 |] ==> a mod b = snd (negateSnd (negDivAlg (- a) (- b)))

lemma div_neg_neg:

  [| a < 0; b  0 |] ==> a div b = fst (negateSnd (posDivAlg (- a) (- b)))

lemma mod_neg_neg:

  [| a < 0; b  0 |] ==> a mod b = snd (negateSnd (posDivAlg (- a) (- b)))

lemma quoremI:

  [| a == b * q + r; if 0 < b then 0  rr < b else b < rr  0 |]
  ==> quorem ((a, b), q, r)

lemma quorem_div_eq:

  [| a1 == b1 * y + r1; if 0 < b1 then 0  r1r1 < b1 else b1 < r1r1  0;
     b1  0 |]
  ==> a1 div b1 == y

lemma quorem_mod_eq:

  [| a1 == b1 * q1 + y; if 0 < b1 then 0  yy < b1 else b1 < yy  0;
     b1  0 |]
  ==> a1 mod b1 == y

lemma arithmetic_simps:

  Int.Bit0 Int.Pls = Int.Pls
  Int.Bit1 Int.Min = Int.Min
  Int.pred Int.Pls = Int.Min
  Int.pred Int.Min = Int.Bit0 Int.Min
  Int.pred (Int.Bit0 k) = Int.Bit1 (Int.pred k)
  Int.pred (Int.Bit1 k) = Int.Bit0 k
  Int.succ Int.Pls = Int.Bit1 Int.Pls
  Int.succ Int.Min = Int.Pls
  Int.succ (Int.Bit0 k) = Int.Bit1 k
  Int.succ (Int.Bit1 k) = Int.Bit0 (Int.succ k)
  Int.Pls + k = k
  Int.Min + k = Int.pred k
  k + Int.Pls = k
  k + Int.Min = Int.pred k
  Int.Bit0 k + Int.Bit0 l = Int.Bit0 (k + l)
  Int.Bit0 k + Int.Bit1 l = Int.Bit1 (k + l)
  Int.Bit1 k + Int.Bit0 l = Int.Bit1 (k + l)
  Int.Bit1 k + Int.Bit1 l = Int.Bit0 (k + Int.succ l)
  - Int.Pls = Int.Pls
  - Int.Min = Int.Bit1 Int.Pls
  - Int.Bit0 k = Int.Bit0 (- k)
  - Int.Bit1 k = Int.Bit1 (Int.pred (- k))
  Int.Pls * w = Int.Pls
  Int.Min * k = - k
  Int.Bit0 k * l = Int.Bit0 (k * l)
  Int.Bit1 k * l = Int.Bit0 (k * l) + l
  ¦0::'a¦ = (0::'a)
  ¦1::'a¦ = (1::'a)
  number_of v + number_of w = number_of (v + w)
  - number_of w = number_of (- w)
  - (1::'a) = (-1::'a)
  number_of v * number_of w = number_of (v * w)
  number_of v - number_of w = number_of (v + - w)
  ¦number_of x¦ = (if number_of x < (0::'a) then - number_of x else number_of x)
  (1::'a) + (1::'a) = (2::'a)
  (1::'a) + number_of w = number_of (Int.Bit1 Int.Pls + w)
  number_of v + (1::'a) = number_of (v + Int.Bit1 Int.Pls)
  (0::'a) + a = a
  a + (0::'a) = a
  (0::'a) * a = (0::'a)
  a * (0::'a) = (0::'a)
  (1::'a) * a = a
  a * (1::'a) = a

lemma div_pos_pos_number_of:

  [| 0 < number_of v; 0  number_of w |]
  ==> number_of v div number_of w = fst (posDivAlg (number_of v) (number_of w))

lemma div_neg_pos_number_of:

  [| number_of v < 0; 0 < number_of w |]
  ==> number_of v div number_of w = fst (negDivAlg (number_of v) (number_of w))

lemma div_pos_neg_number_of:

  [| 0 < number_of v; number_of w < 0 |]
  ==> number_of v div number_of w =
      fst (negateSnd (negDivAlg (- number_of v) (- number_of w)))

lemma div_neg_neg_number_of:

  [| number_of v < 0; number_of w  0 |]
  ==> number_of v div number_of w =
      fst (negateSnd (posDivAlg (- number_of v) (- number_of w)))

lemma mod_pos_pos_number_of:

  [| 0 < number_of v; 0  number_of w |]
  ==> number_of v mod number_of w = snd (posDivAlg (number_of v) (number_of w))

lemma mod_neg_pos_number_of:

  [| number_of v < 0; 0 < number_of w |]
  ==> number_of v mod number_of w = snd (negDivAlg (number_of v) (number_of w))

lemma mod_pos_neg_number_of:

  [| 0 < number_of v; number_of w < 0 |]
  ==> number_of v mod number_of w =
      snd (negateSnd (negDivAlg (- number_of v) (- number_of w)))

lemma mod_neg_neg_number_of:

  [| number_of v < 0; number_of w  0 |]
  ==> number_of v mod number_of w =
      snd (negateSnd (posDivAlg (- number_of v) (- number_of w)))

lemma posDivAlg_eqn_number_of:

  0 < number_of v
  ==> posDivAlg (number_of w) (number_of v) =
      (if number_of w < number_of v then (0, number_of w)
       else adjust (number_of v) (posDivAlg (number_of w) (2 * number_of v)))

lemma negDivAlg_eqn_number_of:

  0 < number_of v
  ==> negDivAlg (number_of w) (number_of v) =
      (if 0  number_of w + number_of v then (-1, number_of w + number_of v)
       else adjust (number_of v) (negDivAlg (number_of w) (2 * number_of v)))

lemma zmod_1:

  a mod 1 = 0

lemma zdiv_1:

  a div 1 = a

lemma zmod_minus1_right:

  a mod -1 = 0

lemma zdiv_minus1_right:

  a div -1 = - a

lemma div_pos_pos_1_number_of:

  0  number_of w ==> 1 div number_of w = fst (posDivAlg 1 (number_of w))

lemma div_pos_neg_1_number_of:

  number_of w < 0
  ==> 1 div number_of w = fst (negateSnd (negDivAlg (- 1) (- number_of w)))

lemma mod_pos_pos_1_number_of:

  0  number_of w ==> 1 mod number_of w = snd (posDivAlg 1 (number_of w))

lemma mod_pos_neg_1_number_of:

  number_of w < 0
  ==> 1 mod number_of w = snd (negateSnd (negDivAlg (- 1) (- number_of w)))

lemma posDivAlg_eqn_1_number_of:

  0 < number_of w
  ==> posDivAlg 1 (number_of w) =
      (if 1 < number_of w then (0, 1)
       else adjust (number_of w) (posDivAlg 1 (2 * number_of w)))

lemma negDivAlg_eqn_1_number_of:

  0 < number_of w
  ==> negDivAlg 1 (number_of w) =
      (if 0  1 + number_of w then (-1, 1 + number_of w)
       else adjust (number_of w) (negDivAlg 1 (2 * number_of w)))

Monotonicity in the First Argument (Dividend)

lemma zdiv_mono1:

  [| a  a'; 0 < b |] ==> a div b  a' div b

lemma zdiv_mono1_neg:

  [| a  a'; b < 0 |] ==> a' div b  a div b

Monotonicity in the Second Argument (Divisor)

lemma q_pos_lemma:

  [| 0  b' * q' + r'; r' < b'; 0 < b' |] ==> 0  q'

lemma zdiv_mono2_lemma:

  [| b * q + r = b' * q' + r'; 0  b' * q' + r'; r' < b'; 0  r; 0 < b'; b'  b |]
  ==> q  q'

lemma zdiv_mono2:

  [| 0  a; 0 < b'; b'  b |] ==> a div b  a div b'

lemma q_neg_lemma:

  [| b' * q' + r' < 0; 0  r'; 0 < b' |] ==> q'  0

lemma zdiv_mono2_neg_lemma:

  [| b * q + r = b' * q' + r'; b' * q' + r' < 0; r < b; 0  r'; 0 < b'; b'  b |]
  ==> q'  q

lemma zdiv_mono2_neg:

  [| a < 0; 0 < b'; b'  b |] ==> a div b'  a div b

More Algebraic Laws for div and mod

lemma zmult1_lemma:

  [| quorem ((b, c), q, r); c  0 |]
  ==> quorem ((a * b, c), a * q + a * r div c, a * r mod c)

lemma zdiv_zmult1_eq:

  a * b div c = a * (b div c) + a * (b mod c) div c

lemma zmod_zmult1_eq:

  a * b mod c = a * (b mod c) mod c

lemma zmod_zmult1_eq':

  a * b mod c = a mod c * b mod c

lemma zmod_zmult_distrib:

  a * b mod c = a mod c * (b mod c) mod c

lemma zdiv_zmult_self1:

  b  0 ==> a * b div b = a

lemma zdiv_zmult_self2:

  b  0 ==> b * a div b = a

lemma zmod_zmult_self1:

  a * b mod b = 0

lemma zmod_zmult_self2:

  b * a mod b = 0

lemma zmod_eq_0_iff:

  (m mod d = 0) = (∃q. m = d * q)

lemma zmod_eq_0D:

  m1 mod d1 = 0 ==> ∃q. m1 = d1 * q

lemma zadd1_lemma:

  [| quorem ((a, c), aq, ar); quorem ((b, c), bq, br); c  0 |]
  ==> quorem ((a + b, c), aq + bq + (ar + br) div c, (ar + br) mod c)

lemma zdiv_zadd1_eq:

  (a + b) div c = a div c + b div c + (a mod c + b mod c) div c

lemma zmod_zadd1_eq:

  (a + b) mod c = (a mod c + b mod c) mod c

lemma mod_div_trivial:

  a mod b div b = 0

lemma mod_mod_trivial:

  a mod b mod b = a mod b

lemma zmod_zadd_left_eq:

  (a + b) mod c = (a mod c + b) mod c

lemma zmod_zadd_right_eq:

  (a + b) mod c = (a + b mod c) mod c

lemma zdiv_zadd_self1:

  a  0 ==> (a + b) div a = b div a + 1

lemma zdiv_zadd_self2:

  a  0 ==> (b + a) div a = b div a + 1

lemma zmod_zadd_self1:

  (a + b) mod a = b mod a

lemma zmod_zadd_self2:

  (b + a) mod a = b mod a

lemma zmod_zdiff1_eq:

  (a - b) mod c = (a mod c - b mod c) mod c

Proving @{term "a div (b*c) = (a div b) div c"}

lemma zmult2_lemma_aux1:

  [| 0 < c; b < r; r  0 |] ==> b * c < b * (q mod c) + r

lemma zmult2_lemma_aux2:

  [| 0 < c; b < r; r  0 |] ==> b * (q mod c) + r  0

lemma zmult2_lemma_aux3:

  [| 0 < c; 0  r; r < b |] ==> 0  b * (q mod c) + r

lemma zmult2_lemma_aux4:

  [| 0 < c; 0  r; r < b |] ==> b * (q mod c) + r < b * c

lemma zmult2_lemma:

  [| quorem ((a, b), q, r); b  0; 0 < c |]
  ==> quorem ((a, b * c), q div c, b * (q mod c) + r)

lemma zdiv_zmult2_eq:

  0 < c ==> a div (b * c) = a div b div c

lemma zmod_zmult2_eq:

  0 < c ==> a mod (b * c) = b * (a div b mod c) + a mod b

Cancellation of Common Factors in div

lemma zdiv_zmult_zmult1_aux1:

  [| 0 < b; c  0 |] ==> c * a div (c * b) = a div b

lemma zdiv_zmult_zmult1_aux2:

  [| b < 0; c  0 |] ==> c * a div (c * b) = a div b

lemma zdiv_zmult_zmult1:

  c  0 ==> c * a div (c * b) = a div b

lemma zdiv_zmult_zmult1_if:

  k * m div (k * n) = (if k = 0 then 0 else m div n)

Distribution of Factors over mod

lemma zmod_zmult_zmult1_aux1:

  [| 0 < b; c  0 |] ==> c * a mod (c * b) = c * (a mod b)

lemma zmod_zmult_zmult1_aux2:

  [| b < 0; c  0 |] ==> c * a mod (c * b) = c * (a mod b)

lemma zmod_zmult_zmult1:

  c * a mod (c * b) = c * (a mod b)

lemma zmod_zmult_zmult2:

  a * c mod (b * c) = a mod b * c

lemma zmod_zmod_cancel:

  n dvd m ==> k mod m mod n = k mod n

Splitting Rules for div and mod

lemma split_pos_lemma:

  0 < k
  ==> P (n div k) (n mod k) = (∀i j. 0  jj < kn = k * i + j --> P i j)

lemma split_neg_lemma:

  k < 0
  ==> P (n div k) (n mod k) = (∀i j. k < jj  0n = k * i + j --> P i j)

lemma split_zdiv:

  P (n div k) =
  ((k = 0 --> P 0) ∧
   (0 < k --> (∀i j. 0  jj < kn = k * i + j --> P i)) ∧
   (k < 0 --> (∀i j. k < jj  0n = k * i + j --> P i)))

lemma split_zmod:

  P (n mod k) =
  ((k = 0 --> P n) ∧
   (0 < k --> (∀i j. 0  jj < kn = k * i + j --> P j)) ∧
   (k < 0 --> (∀i j. k < jj  0n = k * i + j --> P j)))

Speeding up the Division Algorithm with Shifting

lemma pos_zdiv_mult_2:

  0  a ==> (1 + 2 * b) div (2 * a) = b div a

lemma neg_zdiv_mult_2:

  a  0 ==> (1 + 2 * b) div (2 * a) = (b + 1) div a

lemma not_0_le_lemma:

  ¬ 0  x ==> x  0

lemma zdiv_number_of_Bit0:

  number_of (Int.Bit0 v) div number_of (Int.Bit0 w) = number_of v div number_of w

lemma zdiv_number_of_Bit1:

  number_of (Int.Bit1 v) div number_of (Int.Bit0 w) =
  (if 0  number_of w then number_of v div number_of w
   else (number_of v + 1) div number_of w)

Computing mod by Shifting (proofs resemble those for div)

lemma pos_zmod_mult_2:

  0  a ==> (1 + 2 * b) mod (2 * a) = 1 + 2 * (b mod a)

lemma neg_zmod_mult_2:

  a  0 ==> (1 + 2 * b) mod (2 * a) = 2 * ((b + 1) mod a) - 1

lemma zmod_number_of_Bit0:

  number_of (Int.Bit0 v) mod number_of (Int.Bit0 w) =
  2 * (number_of v mod number_of w)

lemma zmod_number_of_Bit1:

  number_of (Int.Bit1 v) mod number_of (Int.Bit0 w) =
  (if 0  number_of w then 2 * (number_of v mod number_of w) + 1
   else 2 * ((number_of v + 1) mod number_of w) - 1)

Quotients of Signs

lemma div_neg_pos_less0:

  [| a < 0; 0 < b |] ==> a div b < 0

lemma div_nonneg_neg_le0:

  [| 0  a; b < 0 |] ==> a div b  0

lemma pos_imp_zdiv_nonneg_iff:

  0 < b ==> (0  a div b) = (0  a)

lemma neg_imp_zdiv_nonneg_iff:

  b < 0 ==> (0  a div b) = (a  0)

lemma pos_imp_zdiv_neg_iff:

  0 < b ==> (a div b < 0) = (a < 0)

lemma neg_imp_zdiv_neg_iff:

  b < 0 ==> (a div b < 0) = (0 < a)

The Divides Relation

lemma zdvd_iff_zmod_eq_0:

  (m dvd n) = (n mod m = 0)

lemma zdvd_iff_zmod_eq_0_number_of:

  (number_of x dvd number_of y) = (number_of y mod number_of x = 0)

lemma zdvd_0_right:

  m dvd 0

lemma zdvd_0_left:

  (0 dvd m) = (m = 0)

lemma zdvd_1_left:

  1 dvd m

lemma zdvd_refl:

  m dvd m

lemma zdvd_trans:

  [| m dvd n; n dvd k |] ==> m dvd k

lemma zdvd_zminus_iff:

  (m dvd - n) = (m dvd n)

lemma zdvd_zminus2_iff:

  (- m dvd n) = (m dvd n)

lemma zdvd_abs1:

  (¦i¦ dvd j) = (i dvd j)

lemma zdvd_abs2:

  (i dvd ¦j¦) = (i dvd j)

lemma zdvd_anti_sym:

  [| 0 < m; 0 < n; m dvd n; n dvd m |] ==> m = n

lemma zdvd_zadd:

  [| k dvd m; k dvd n |] ==> k dvd m + n

lemma zdvd_dvd_eq:

  [| a  0; a dvd b; b dvd a |] ==> ¦a¦ = ¦b¦

lemma zdvd_zdiff:

  [| k dvd m; k dvd n |] ==> k dvd m - n

lemma zdvd_zdiffD:

  [| k dvd m - n; k dvd n |] ==> k dvd m

lemma zdvd_zmult:

  k dvd n ==> k dvd m * n

lemma zdvd_zmult2:

  k dvd m ==> k dvd m * n

lemma zdvd_triv_right:

  k dvd m * k

lemma zdvd_triv_left:

  k dvd k * m

lemma zdvd_zmultD2:

  j * k dvd n ==> j dvd n

lemma zdvd_zmultD:

  j * k dvd n ==> k dvd n

lemma zdvd_zmult_mono:

  [| i dvd m; j dvd n |] ==> i * j dvd m * n

lemma zdvd_reduce:

  (k dvd n + k * m) = (k dvd n)

lemma zdvd_zmod:

  [| f dvd m; f dvd n |] ==> f dvd m mod n

lemma zdvd_zmod_imp_zdvd:

  [| k dvd m mod n; k dvd n |] ==> k dvd m

lemma zdvd_not_zless:

  [| 0 < m; m < n |] ==> ¬ n dvd m

lemma zmult_div_cancel:

  n * (m div n) = m - m mod n

lemma zdvd_mult_div_cancel:

  n dvd m ==> n * (m div n) = m

lemma zdvd_mult_cancel:

  [| k * m dvd k * n; k  0 |] ==> m dvd n

lemma zdvd_zmult_cancel_disj:

  (k * m dvd k * n) = (k = 0m dvd n)

theorem ex_nat:

  (∃x. P x) = (∃x0. P (nat x))

theorem zdvd_int:

  (x dvd y) = (int x dvd int y)

lemma zdvd1_eq:

  (x dvd 1) = (¦x¦ = 1)

lemma zdvd_mult_cancel1:

  m  0 ==> (m * n dvd m) = (¦n¦ = 1)

lemma int_dvd_iff:

  (int m dvd z) = (m dvd nat ¦z¦)

lemma dvd_int_iff:

  (z dvd int m) = (nat ¦z¦ dvd m)

lemma nat_dvd_iff:

  (nat z dvd m) = (if 0  z then z dvd int m else m = 0)

lemma zminus_dvd_iff:

  (- z dvd w) = (z dvd w)

lemma dvd_zminus_iff:

  (z dvd - w) = (z dvd w)

lemma zdvd_imp_le:

  [| z dvd n; 0 < n |] ==> z  n

lemma zpower_zmod:

  (x mod m) ^ y mod m = x ^ y mod m

lemma zdiv_int:

  int (a div b) = int a div int b

lemma zmod_int:

  int (a mod b) = int a mod int b

lemma int_power_div_base:

  [| 0 < m; 0 < k |] ==> k ^ m div k = k ^ (m - Suc 0)

lemma zminus_zmod:

  - (x mod m) mod m = - x mod m

lemma zdiff_zmod_left:

  (x mod m - y) mod m = (x - y) mod m

lemma zdiff_zmod_right:

  (x - y mod m) mod m = (x - y) mod m

lemma zmod_simps:

  (a mod c + b) mod c = (a + b) mod c
  (a + b mod c) mod c = (a + b) mod c
  a * (b mod c) mod c = a * b mod c
  a mod c * b mod c = a * b mod c
  (x mod m) ^ y mod m = x ^ y mod m
  - (x mod m) mod m = - x mod m
  (x mod m - y) mod m = (x - y) mod m
  (x - y mod m) mod m = (x - y) mod m

lemma of_int_num:

  of_int k =
  (if k = 0 then 0::'a
   else if k < 0 then - of_int (- k)
        else let (l, m) = divAlg (k, 2); l' = of_int l
             in if m = 0 then l' + l' else l' + l' + (1::'a))