Theory HOL.Bit_Operations

(*  Author:  Florian Haftmann, TUM
*)

section ‹Bit operations in suitable algebraic structures›

theory Bit_Operations
  imports Presburger Groups_List
begin

subsection ‹Abstract bit structures›

class semiring_bits = semiring_parity + semiring_modulo_trivial +
  assumes bit_induct [case_names stable rec]:
    (a. a div 2 = a  P a)
      (a b. P a  (of_bool b + 2 * a) div 2 = a  P (of_bool b + 2 * a))
         P a
  assumes bits_mod_div_trivial [simp]: a mod b div b = 0
    and half_div_exp_eq: a div 2 div 2 ^ n = a div 2 ^ Suc n
    and even_double_div_exp_iff: 2 ^ Suc n  0  even (2 * a div 2 ^ Suc n)  even (a div 2 ^ n)
  fixes bit :: 'a  nat  bool
  assumes bit_iff_odd: bit a n  odd (a div 2 ^ n)
begin

text ‹
  Having constbit as definitional class operation
  takes into account that specific instances can be implemented
  differently wrt. code generation.
›

lemma half_1 [simp]:
  1 div 2 = 0
  using even_half_succ_eq [of 0] by simp

lemma div_exp_eq_funpow_half:
  a div 2 ^ n = ((λa. a div 2) ^^ n) a
proof -
  have ((λa. a div 2) ^^ n) = (λa. a div 2 ^ n)
    by (induction n)
      (simp_all del: funpow.simps power.simps add: power_0 funpow_Suc_right half_div_exp_eq)
  then show ?thesis
    by simp
qed

lemma div_exp_eq:
  a div 2 ^ m div 2 ^ n = a div 2 ^ (m + n)
  by (simp add: div_exp_eq_funpow_half Groups.add.commute [of m] funpow_add)

lemma bit_0:
  bit a 0  odd a
  by (simp add: bit_iff_odd)

lemma bit_Suc:
  bit a (Suc n)  bit (a div 2) n
  using div_exp_eq [of a 1 n] by (simp add: bit_iff_odd)

lemma bit_rec:
  bit a n  (if n = 0 then odd a else bit (a div 2) (n - 1))
  by (cases n) (simp_all add: bit_Suc bit_0)

context
  fixes a
  assumes stable: a div 2 = a
begin

lemma bits_stable_imp_add_self:
  a + a mod 2 = 0
proof -
  have a div 2 * 2 + a mod 2 = a
    by (fact div_mult_mod_eq)
  then have a * 2 + a mod 2 = a
    by (simp add: stable)
  then show ?thesis
    by (simp add: mult_2_right ac_simps)
qed

lemma stable_imp_bit_iff_odd:
  bit a n  odd a
  by (induction n) (simp_all add: stable bit_Suc bit_0)

end

lemma bit_iff_odd_imp_stable:
  a div 2 = a if n. bit a n  odd a
using that proof (induction a rule: bit_induct)
  case (stable a)
  then show ?case
    by simp
next
  case (rec a b)
  from rec.prems [of 1] have [simp]: b = odd a
    by (simp add: rec.hyps bit_Suc bit_0)
  from rec.hyps have hyp: (of_bool (odd a) + 2 * a) div 2 = a
    by simp
  have bit a n  odd a for n
    using rec.prems [of Suc n] by (simp add: hyp bit_Suc)
  then have a div 2 = a
    by (rule rec.IH)
  then have of_bool (odd a) + 2 * a = 2 * (a div 2) + of_bool (odd a)
    by (simp add: ac_simps)
  also have  = a
    using mult_div_mod_eq [of 2 a]
    by (simp add: of_bool_odd_eq_mod_2)
  finally show ?case
    using a div 2 = a by (simp add: hyp)
qed

lemma even_succ_div_exp [simp]:
  (1 + a) div 2 ^ n = a div 2 ^ n if even a and n > 0
proof (cases n)
  case 0
  with that show ?thesis
    by simp
next
  case (Suc n)
  with even a have (1 + a) div 2 ^ Suc n = a div 2 ^ Suc n
  proof (induction n)
    case 0
    then show ?case
      by simp
  next
    case (Suc n)
    then show ?case
      using div_exp_eq [of _ 1 Suc n, symmetric]
      by simp
  qed
  with Suc show ?thesis
    by simp
qed

lemma even_succ_mod_exp [simp]:
  (1 + a) mod 2 ^ n = 1 + (a mod 2 ^ n) if even a and n > 0
  using div_mult_mod_eq [of 1 + a 2 ^ n] div_mult_mod_eq [of a 2 ^ n] that
  by simp (metis (full_types) add.left_commute add_left_imp_eq)

named_theorems bit_simps ‹Simplification rules for const‹bit››

definition possible_bit :: 'a itself  nat  bool
  where possible_bit TYPE('a) n  2 ^ n  0
  ― ‹This auxiliary avoids non-termination with extensionality.›

lemma possible_bit_0 [simp]:
  possible_bit TYPE('a) 0
  by (simp add: possible_bit_def)

lemma fold_possible_bit:
  2 ^ n = 0  ¬ possible_bit TYPE('a) n
  by (simp add: possible_bit_def)

lemma bit_imp_possible_bit:
  possible_bit TYPE('a) n if bit a n
  by (rule ccontr) (use that in auto simp add: bit_iff_odd possible_bit_def)

lemma impossible_bit:
  ¬ bit a n if ¬ possible_bit TYPE('a) n
  using that by (blast dest: bit_imp_possible_bit)

lemma possible_bit_less_imp:
  possible_bit TYPE('a) j if possible_bit TYPE('a) i j  i
  using power_add [of 2 j i - j] that mult_not_zero [of 2 ^ j 2 ^ (i - j)]
  by (simp add: possible_bit_def)

lemma possible_bit_min [simp]:
  possible_bit TYPE('a) (min i j)  possible_bit TYPE('a) i  possible_bit TYPE('a) j
  by (auto simp add: min_def elim: possible_bit_less_imp)

lemma bit_eqI:
  a = b if n. possible_bit TYPE('a) n  bit a n  bit b n
proof -
  have bit a n  bit b n for n
  proof (cases possible_bit TYPE('a) n)
    case False
    then show ?thesis
      by (simp add: impossible_bit)
  next
    case True
    then show ?thesis
      by (rule that)
  qed
  then show ?thesis proof (induction a arbitrary: b rule: bit_induct)
    case (stable a)
    from stable(2) [of 0] have **: even b  even a
      by (simp add: bit_0)
    have b div 2 = b
    proof (rule bit_iff_odd_imp_stable)
      fix n
      from stable have *: bit b n  bit a n
        by simp
      also have bit a n  odd a
        using stable by (simp add: stable_imp_bit_iff_odd)
      finally show bit b n  odd b
        by (simp add: **)
    qed
    from ** have a mod 2 = b mod 2
      by (simp add: mod2_eq_if)
    then have a mod 2 + (a + b) = b mod 2 + (a + b)
      by simp
    then have a + a mod 2 + b = b + b mod 2 + a
      by (simp add: ac_simps)
    with a div 2 = a b div 2 = b show ?case
      by (simp add: bits_stable_imp_add_self)
  next
    case (rec a p)
    from rec.prems [of 0] have [simp]: p = odd b
      by (simp add: bit_0)
    from rec.hyps have bit a n  bit (b div 2) n for n
      using rec.prems [of Suc n] by (simp add: bit_Suc)
    then have a = b div 2
      by (rule rec.IH)
    then have 2 * a = 2 * (b div 2)
      by simp
    then have b mod 2 + 2 * a = b mod 2 + 2 * (b div 2)
      by simp
    also have  = b
      by (fact mod_mult_div_eq)
    finally show ?case
      by (auto simp add: mod2_eq_if)
  qed
qed

lemma bit_eq_rec:
  a = b  (even a  even b)  a div 2 = b div 2 (is ?P = ?Q)
proof
  assume ?P
  then show ?Q
    by simp
next
  assume ?Q
  then have even a  even b and a div 2 = b div 2
    by simp_all
  show ?P
  proof (rule bit_eqI)
    fix n
    show bit a n  bit b n
    proof (cases n)
      case 0
      with even a  even b show ?thesis
        by (simp add: bit_0)
    next
      case (Suc n)
      moreover from a div 2 = b div 2 have bit (a div 2) n = bit (b div 2) n
        by simp
      ultimately show ?thesis
        by (simp add: bit_Suc)
    qed
  qed
qed

lemma bit_eq_iff:
  a = b  (n. possible_bit TYPE('a) n  bit a n  bit b n)
  by (auto intro: bit_eqI simp add: possible_bit_def)

lemma bit_0_eq [simp]:
  bit 0 = 
proof -
  have 0 div 2 ^ n = 0 for n
    unfolding div_exp_eq_funpow_half by (induction n) simp_all
  then show ?thesis
    by (simp add: fun_eq_iff bit_iff_odd)
qed

lemma bit_double_Suc_iff:
  bit (2 * a) (Suc n)  possible_bit TYPE('a) (Suc n)  bit a n
  using even_double_div_exp_iff [of n a]
  by (cases possible_bit TYPE('a) (Suc n))
    (auto simp add: bit_iff_odd possible_bit_def)

lemma bit_double_iff [bit_simps]:
  bit (2 * a) n  possible_bit TYPE('a) n  n  0  bit a (n - 1)
  by (cases n) (simp_all add: bit_0 bit_double_Suc_iff)

lemma even_bit_succ_iff:
  bit (1 + a) n  bit a n  n = 0 if even a
  using that by (cases n = 0) (simp_all add: bit_iff_odd)

lemma odd_bit_iff_bit_pred:
  bit a n  bit (a - 1) n  n = 0 if odd a
proof -
  from odd a obtain b where a = 2 * b + 1 ..
  moreover have bit (2 * b) n  n = 0  bit (1 + 2 * b) n
    using even_bit_succ_iff by simp
  ultimately show ?thesis by (simp add: ac_simps)
qed

lemma bit_exp_iff [bit_simps]:
  bit (2 ^ m) n  possible_bit TYPE('a) n  n = m
proof (cases possible_bit TYPE('a) n)
  case False
  then show ?thesis
    by (simp add: impossible_bit)
next
  case True
  then show ?thesis
  proof (induction n arbitrary: m)
    case 0
    show ?case
      by (simp add: bit_0)
  next
    case (Suc n)
    then have possible_bit TYPE('a) n
      by (simp add: possible_bit_less_imp)
    show ?case
    proof (cases m)
      case 0
      then show ?thesis
        by (simp add: bit_Suc)
    next
      case (Suc m)
      with Suc.IH [of m] possible_bit TYPE('a) n show ?thesis
        by (simp add: bit_double_Suc_iff)
    qed
  qed
qed

lemma bit_1_iff [bit_simps]:
  bit 1 n  n = 0
  using bit_exp_iff [of 0 n] by auto

lemma bit_2_iff [bit_simps]:
  bit 2 n  possible_bit TYPE('a) 1  n = 1
  using bit_exp_iff [of 1 n] by auto

lemma bit_of_bool_iff [bit_simps]:
  bit (of_bool b) n  n = 0  b
  by (simp add: bit_1_iff)

lemma bit_mod_2_iff [simp]:
  bit (a mod 2) n  n = 0  odd a
  by (simp add: mod_2_eq_odd bit_simps)

end

lemma nat_bit_induct [case_names zero even odd]:
  P n if zero: P 0
    and even: n. P n  n > 0  P (2 * n)
    and odd: n. P n  P (Suc (2 * n))
proof (induction n rule: less_induct)
  case (less n)
  show P n
  proof (cases n = 0)
    case True with zero show ?thesis by simp
  next
    case False
    with less have hyp: P (n div 2) by simp
    show ?thesis
    proof (cases even n)
      case True
      then have n  1
        by auto
      with n  0 have n div 2 > 0
        by simp
      with even n hyp even [of n div 2] show ?thesis
        by simp
    next
      case False
      with hyp odd [of n div 2] show ?thesis
        by simp
    qed
  qed
qed

instantiation nat :: semiring_bits
begin

definition bit_nat :: nat  nat  bool
  where bit_nat m n  odd (m div 2 ^ n)

instance
proof
  show P n if stable: n. n div 2 = n  P n
    and rec: n b. P n  (of_bool b + 2 * n) div 2 = n  P (of_bool b + 2 * n)
    for P and n :: nat
  proof (induction n rule: nat_bit_induct)
    case zero
    from stable [of 0] show ?case
      by simp
  next
    case (even n)
    with rec [of n False] show ?case
      by simp
  next
    case (odd n)
    with rec [of n True] show ?case
      by simp
  qed
qed (auto simp add: div_mult2_eq bit_nat_def)

end

lemma possible_bit_nat [simp]:
  possible_bit TYPE(nat) n
  by (simp add: possible_bit_def)

lemma bit_Suc_0_iff [bit_simps]:
  bit (Suc 0) n  n = 0
  using bit_1_iff [of n, where ?'a = nat] by simp

lemma not_bit_Suc_0_Suc [simp]:
  ¬ bit (Suc 0) (Suc n)
  by (simp add: bit_Suc)

lemma not_bit_Suc_0_numeral [simp]:
  ¬ bit (Suc 0) (numeral n)
  by (simp add: numeral_eq_Suc)

context semiring_bits
begin

lemma bit_of_nat_iff [bit_simps]:
  bit (of_nat m) n  possible_bit TYPE('a) n  bit m n
proof (cases possible_bit TYPE('a) n)
  case False
  then show ?thesis
    by (simp add: impossible_bit)
next
  case True
  then have bit (of_nat m) n  bit m n
  proof (induction m arbitrary: n rule: nat_bit_induct)
    case zero
    then show ?case
      by simp
  next
    case (even m)
    then show ?case
      by (cases n)
        (auto simp add: bit_double_iff Bit_Operations.bit_double_iff possible_bit_def bit_0 dest: mult_not_zero)
  next
    case (odd m)
    then show ?case
      by (cases n)
        (auto simp add: bit_double_iff even_bit_succ_iff possible_bit_def
          Bit_Operations.bit_Suc Bit_Operations.bit_0 dest: mult_not_zero)
  qed
  with True show ?thesis
    by simp
qed

end

lemma int_bit_induct [case_names zero minus even odd]:
  P k if zero_int: P 0
    and minus_int: P (- 1)
    and even_int: k. P k  k  0  P (k * 2)
    and odd_int: k. P k  k  - 1  P (1 + (k * 2)) for k :: int
proof (cases k  0)
  case True
  define n where n = nat k
  with True have k = int n
    by simp
  then show P k
  proof (induction n arbitrary: k rule: nat_bit_induct)
    case zero
    then show ?case
      by (simp add: zero_int)
  next
    case (even n)
    have P (int n * 2)
      by (rule even_int) (use even in simp_all)
    with even show ?case
      by (simp add: ac_simps)
  next
    case (odd n)
    have P (1 + (int n * 2))
      by (rule odd_int) (use odd in simp_all)
    with odd show ?case
      by (simp add: ac_simps)
  qed
next
  case False
  define n where n = nat (- k - 1)
  with False have k = - int n - 1
    by simp
  then show P k
  proof (induction n arbitrary: k rule: nat_bit_induct)
    case zero
    then show ?case
      by (simp add: minus_int)
  next
    case (even n)
    have P (1 + (- int (Suc n) * 2))
      by (rule odd_int) (use even in simp_all add: algebra_simps)
    also have  = - int (2 * n) - 1
      by (simp add: algebra_simps)
    finally show ?case
      using even.prems by simp
  next
    case (odd n)
    have P (- int (Suc n) * 2)
      by (rule even_int) (use odd in simp_all add: algebra_simps)
    also have  = - int (Suc (2 * n)) - 1
      by (simp add: algebra_simps)
    finally show ?case
      using odd.prems by simp
  qed
qed

instantiation int :: semiring_bits
begin

definition bit_int :: int  nat  bool
  where bit_int k n  odd (k div 2 ^ n)

instance
proof
  show P k if stable: k. k div 2 = k  P k
    and rec: k b. P k  (of_bool b + 2 * k) div 2 = k  P (of_bool b + 2 * k)
    for P and k :: int
  proof (induction k rule: int_bit_induct)
    case zero
    from stable [of 0] show ?case
      by simp
  next
    case minus
    from stable [of - 1] show ?case
      by simp
  next
    case (even k)
    with rec [of k False] show ?case
      by (simp add: ac_simps)
  next
    case (odd k)
    with rec [of k True] show ?case
      by (simp add: ac_simps)
  qed
qed (auto simp add: zdiv_zmult2_eq bit_int_def)

end

lemma possible_bit_int [simp]:
  possible_bit TYPE(int) n
  by (simp add: possible_bit_def)

lemma bit_nat_iff [bit_simps]:
  bit (nat k) n  k  0  bit k n
proof (cases k  0)
  case True
  moreover define m where m = nat k
  ultimately have k = int m
    by simp
  then show ?thesis
    by (simp add: bit_simps)
next
  case False
  then show ?thesis
    by simp
qed


subsection ‹Bit operations›

class semiring_bit_operations = semiring_bits +
  fixes "and" :: 'a  'a  'a  (infixr AND 64)
    and or :: 'a  'a  'a  (infixr OR 59)
    and xor :: 'a  'a  'a  (infixr XOR 59)
    and mask :: nat  'a
    and set_bit :: nat  'a  'a
    and unset_bit :: nat  'a  'a
    and flip_bit :: nat  'a  'a
    and push_bit :: nat  'a  'a
    and drop_bit :: nat  'a  'a
    and take_bit :: nat  'a  'a
  assumes and_rec: a AND b = of_bool (odd a  odd b) + 2 * ((a div 2) AND (b div 2))
    and or_rec: a OR b = of_bool (odd a  odd b) + 2 * ((a div 2) OR (b div 2))
    and xor_rec: a XOR b = of_bool (odd a  odd b) + 2 * ((a div 2) XOR (b div 2))
    and mask_eq_exp_minus_1: mask n = 2 ^ n - 1
    and set_bit_eq_or: set_bit n a = a OR push_bit n 1
    and unset_bit_eq_or_xor: unset_bit n a = (a OR push_bit n 1) XOR push_bit n 1
    and flip_bit_eq_xor: flip_bit n a = a XOR push_bit n 1
    and push_bit_eq_mult: push_bit n a = a * 2 ^ n
    and drop_bit_eq_div: drop_bit n a = a div 2 ^ n
    and take_bit_eq_mod: take_bit n a = a mod 2 ^ n
begin

text ‹
  We want the bitwise operations to bind slightly weaker
  than +› and -›.

  Logically, constpush_bit,
  constdrop_bit and consttake_bit are just aliases; having them
  as separate operations makes proofs easier, otherwise proof automation
  would fiddle with concrete expressions term2 ^ n in a way obfuscating the basic
  algebraic relationships between those operations.

  For the sake of code generation operations
  are specified as definitional class operations,
  taking into account that specific instances of these can be implemented
  differently wrt. code generation.
›

lemma bit_iff_odd_drop_bit:
  bit a n  odd (drop_bit n a)
  by (simp add: bit_iff_odd drop_bit_eq_div)

lemma even_drop_bit_iff_not_bit:
  even (drop_bit n a)  ¬ bit a n
  by (simp add: bit_iff_odd_drop_bit)

lemma bit_and_iff [bit_simps]:
  bit (a AND b) n  bit a n  bit b n
proof (induction n arbitrary: a b)
  case 0
  show ?case
    by (simp add: bit_0 and_rec [of a b] even_bit_succ_iff)
next
  case (Suc n)
  from Suc [of a div 2 b div 2]
  show ?case
    by (simp add: and_rec [of a b] bit_Suc)
      (auto simp flip: bit_Suc simp add: bit_double_iff dest: bit_imp_possible_bit)
qed

lemma bit_or_iff [bit_simps]:
  bit (a OR b) n  bit a n  bit b n
proof (induction n arbitrary: a b)
  case 0
  show ?case
    by (simp add: bit_0 or_rec [of a b] even_bit_succ_iff)
next
  case (Suc n)
  from Suc [of a div 2 b div 2]
  show ?case
    by (simp add: or_rec [of a b] bit_Suc)
      (auto simp flip: bit_Suc simp add: bit_double_iff dest: bit_imp_possible_bit)
qed

lemma bit_xor_iff [bit_simps]:
  bit (a XOR b) n  bit a n  bit b n
proof (induction n arbitrary: a b)
  case 0
  show ?case
    by (simp add: bit_0 xor_rec [of a b] even_bit_succ_iff)
next
  case (Suc n)
  from Suc [of a div 2 b div 2]
  show ?case
    by (simp add: xor_rec [of a b] bit_Suc)
      (auto simp flip: bit_Suc simp add: bit_double_iff dest: bit_imp_possible_bit)
qed

sublocale "and": semilattice (AND)
  by standard (auto simp add: bit_eq_iff bit_and_iff)

sublocale or: semilattice_neutr (OR) 0
  by standard (auto simp add: bit_eq_iff bit_or_iff)

sublocale xor: comm_monoid (XOR) 0
  by standard (auto simp add: bit_eq_iff bit_xor_iff)

lemma even_and_iff:
  even (a AND b)  even a  even b
  using bit_and_iff [of a b 0] by (auto simp add: bit_0)

lemma even_or_iff:
  even (a OR b)  even a  even b
  using bit_or_iff [of a b 0] by (auto simp add: bit_0)

lemma even_xor_iff:
  even (a XOR b)  (even a  even b)
  using bit_xor_iff [of a b 0] by (auto simp add: bit_0)

lemma zero_and_eq [simp]:
  0 AND a = 0
  by (simp add: bit_eq_iff bit_and_iff)

lemma and_zero_eq [simp]:
  a AND 0 = 0
  by (simp add: bit_eq_iff bit_and_iff)

lemma one_and_eq:
  1 AND a = a mod 2
  by (simp add: bit_eq_iff bit_and_iff) (auto simp add: bit_1_iff bit_0)

lemma and_one_eq:
  a AND 1 = a mod 2
  using one_and_eq [of a] by (simp add: ac_simps)

lemma one_or_eq:
  1 OR a = a + of_bool (even a)
  by (simp add: bit_eq_iff bit_or_iff add.commute [of _ 1] even_bit_succ_iff)
    (auto simp add: bit_1_iff bit_0)

lemma or_one_eq:
  a OR 1 = a + of_bool (even a)
  using one_or_eq [of a] by (simp add: ac_simps)

lemma one_xor_eq:
  1 XOR a = a + of_bool (even a) - of_bool (odd a)
  by (simp add: bit_eq_iff bit_xor_iff add.commute [of _ 1] even_bit_succ_iff)
    (auto simp add: bit_1_iff odd_bit_iff_bit_pred bit_0 elim: oddE)

lemma xor_one_eq:
  a XOR 1 = a + of_bool (even a) - of_bool (odd a)
  using one_xor_eq [of a] by (simp add: ac_simps)

lemma xor_self_eq [simp]:
  a XOR a = 0
  by (rule bit_eqI) (simp add: bit_simps)

lemma mask_0 [simp]:
  mask 0 = 0
  by (simp add: mask_eq_exp_minus_1)

lemma inc_mask_eq_exp:
  mask n + 1 = 2 ^ n
proof (induction n)
  case 0
  then show ?case
    by simp
next
  case (Suc n)
  from Suc.IH [symmetric] have 2 ^ Suc n = 2 * mask n + 2
    by (simp add: algebra_simps)
  also have  = 2 * mask n + 1 + 1
    by (simp add: add.assoc)
  finally have *: 2 ^ Suc n = 2 * mask n + 1 + 1 .
  then show ?case
    by (simp add: mask_eq_exp_minus_1)
qed

lemma mask_Suc_double:
  mask (Suc n) = 1 OR 2 * mask n
proof -
  have mask (Suc n) + 1 = (mask n + 1) + (mask n + 1)
    by (simp add: inc_mask_eq_exp mult_2)
  also have  = (1 OR 2 * mask n) + 1
    by (simp add: one_or_eq mult_2_right algebra_simps)
  finally show ?thesis
    by simp
qed

lemma bit_mask_iff [bit_simps]:
  bit (mask m) n  possible_bit TYPE('a) n  n < m
proof (cases possible_bit TYPE('a) n)
  case False
  then show ?thesis
    by (simp add: impossible_bit)
next
  case True
  then have bit (mask m) n  n < m
  proof (induction m arbitrary: n)
    case 0
    then show ?case
      by (simp add: bit_iff_odd)
  next
    case (Suc m)
    show ?case
    proof (cases n)
      case 0
      then show ?thesis
        by (simp add: bit_0 mask_Suc_double even_or_iff)
    next
      case (Suc n)
      with Suc.prems have possible_bit TYPE('a) n
        using possible_bit_less_imp by auto
      with Suc.IH [of n] have bit (mask m) n  n < m .
      with Suc.prems show ?thesis
        by (simp add: Suc mask_Suc_double bit_simps)
    qed
  qed
  with True show ?thesis
    by simp
qed

lemma even_mask_iff:
  even (mask n)  n = 0
  using bit_mask_iff [of n 0] by (auto simp add: bit_0)

lemma mask_Suc_0 [simp]:
  mask (Suc 0) = 1
  by (simp add: mask_Suc_double)

lemma mask_Suc_exp:
  mask (Suc n) = 2 ^ n OR mask n
  by (auto simp add: bit_eq_iff bit_simps)

lemma mask_numeral:
  mask (numeral n) = 1 + 2 * mask (pred_numeral n)
  by (simp add: numeral_eq_Suc mask_Suc_double one_or_eq ac_simps)

lemma push_bit_0_id [simp]:
  push_bit 0 = id
  by (simp add: fun_eq_iff push_bit_eq_mult)

lemma push_bit_Suc [simp]:
  push_bit (Suc n) a = push_bit n (a * 2)
  by (simp add: push_bit_eq_mult ac_simps)

lemma push_bit_double:
  push_bit n (a * 2) = push_bit n a * 2
  by (simp add: push_bit_eq_mult ac_simps)

lemma bit_push_bit_iff [bit_simps]:
  bit (push_bit m a) n  m  n  possible_bit TYPE('a) n  bit a (n - m)
proof (induction n arbitrary: m)
  case 0
  then show ?case
    by (auto simp add: bit_0 push_bit_eq_mult)
next
  case (Suc n)
  show ?case
  proof (cases m)
    case 0
    then show ?thesis
      by (auto simp add: bit_imp_possible_bit)
  next
    case (Suc m)
    with Suc.prems Suc.IH [of m] show ?thesis
      apply (simp add: push_bit_double)
      apply (simp add: bit_simps mult.commute [of _ 2])
      apply (auto simp add: possible_bit_less_imp)
      done
  qed
qed

lemma funpow_double_eq_push_bit:
  times 2 ^^ n = push_bit n
  by (induction n) (simp_all add: fun_eq_iff push_bit_double ac_simps)

lemma div_push_bit_of_1_eq_drop_bit:
  a div push_bit n 1 = drop_bit n a
  by (simp add: push_bit_eq_mult drop_bit_eq_div)

lemma bits_ident:
  push_bit n (drop_bit n a) + take_bit n a = a
  using div_mult_mod_eq by (simp add: push_bit_eq_mult take_bit_eq_mod drop_bit_eq_div)

lemma push_bit_push_bit [simp]:
  push_bit m (push_bit n a) = push_bit (m + n) a
  by (simp add: push_bit_eq_mult power_add ac_simps)

lemma push_bit_of_0 [simp]:
  push_bit n 0 = 0
  by (simp add: push_bit_eq_mult)

lemma push_bit_of_1 [simp]:
  push_bit n 1 = 2 ^ n
  by (simp add: push_bit_eq_mult)

lemma push_bit_add:
  push_bit n (a + b) = push_bit n a + push_bit n b
  by (simp add: push_bit_eq_mult algebra_simps)

lemma push_bit_numeral [simp]:
  push_bit (numeral l) (numeral k) = push_bit (pred_numeral l) (numeral (Num.Bit0 k))
  by (simp add: numeral_eq_Suc mult_2_right) (simp add: numeral_Bit0)

lemma bit_drop_bit_eq [bit_simps]:
  bit (drop_bit n a) = bit a  (+) n
  by rule (simp add: drop_bit_eq_div bit_iff_odd div_exp_eq)

lemma disjunctive_xor_eq_or:
  a XOR b = a OR b if a AND b = 0
  using that by (auto simp add: bit_eq_iff bit_simps)

lemma disjunctive_add_eq_or:
  a + b = a OR b if a AND b = 0
proof (rule bit_eqI)
  fix n
  assume possible_bit TYPE('a) n
  moreover from that have n. ¬ bit (a AND b) n
    by simp
  then have n. ¬ bit a n  ¬ bit b n
    by (simp add: bit_simps)
  ultimately show bit (a + b) n  bit (a OR b) n
  proof (induction n arbitrary: a b)
    case 0
    from "0"(2)[of 0] show ?case
      by (auto simp add: even_or_iff bit_0)
  next
    case (Suc n)
    from Suc.prems(2) [of 0] have even: even a  even b
      by (auto simp add: bit_0)
    have bit: ¬ bit (a div 2) n  ¬ bit (b div 2) n for n
      using Suc.prems(2) [of Suc n] by (simp add: bit_Suc)
    from Suc.prems have possible_bit TYPE('a) n
      using possible_bit_less_imp by force
    with n. ¬ bit (a div 2) n  ¬ bit (b div 2) n Suc.IH [of a div 2 b div 2]
    have IH: bit (a div 2 + b div 2) n  bit (a div 2 OR b div 2) n
      by (simp add: bit_Suc)
    have a + b = (a div 2 * 2 + a mod 2) + (b div 2 * 2 + b mod 2)
      using div_mult_mod_eq [of a 2] div_mult_mod_eq [of b 2] by simp
    also have  = of_bool (odd a  odd b) + 2 * (a div 2 + b div 2)
      using even by (auto simp add: algebra_simps mod2_eq_if)
    finally have bit ((a + b) div 2) n  bit (a div 2 + b div 2) n
      using possible_bit TYPE('a) (Suc n) by simp (simp_all flip: bit_Suc add: bit_double_iff possible_bit_def)
    also have   bit (a div 2 OR b div 2) n
      by (rule IH)
    finally show ?case
      by (simp add: bit_simps flip: bit_Suc)
  qed
qed

lemma disjunctive_add_eq_xor:
  a + b = a XOR b if a AND b = 0
  using that by (simp add: disjunctive_add_eq_or disjunctive_xor_eq_or)

lemma take_bit_0 [simp]:
  "take_bit 0 a = 0"
  by (simp add: take_bit_eq_mod)

lemma bit_take_bit_iff [bit_simps]:
  bit (take_bit m a) n  n < m  bit a n
proof -
  have push_bit m (drop_bit m a) AND take_bit m a = 0 (is ?lhs = _)
  proof (rule bit_eqI)
    fix n
    show bit ?lhs n  bit 0 n
    proof (cases m  n)
      case False
      then show ?thesis
        by (simp add: bit_simps)
    next
      case True
      moreover define q where q = n - m
      ultimately have n = m + q by simp
      moreover have ¬ bit (take_bit m a) (m + q)
        by (simp add: take_bit_eq_mod bit_iff_odd flip: div_exp_eq)
      ultimately show ?thesis
        by (simp add: bit_simps)
    qed
  qed
  then have push_bit m (drop_bit m a) XOR take_bit m a = push_bit m (drop_bit m a) + take_bit m a
    by (simp add: disjunctive_add_eq_xor)
  also have  = a
    by (simp add: bits_ident)
  finally have bit (push_bit m (drop_bit m a) XOR take_bit m a) n  bit a n
    by simp
  also have   (m  n  n < m)  bit a n
    by auto
  also have   m  n  bit a n  n < m  bit a n
    by auto
  also have m  n  bit a n  bit (push_bit m (drop_bit m a)) n
    by (auto simp add: bit_simps bit_imp_possible_bit)
  finally show ?thesis
    by (auto simp add: bit_simps)
qed

lemma take_bit_Suc:
  take_bit (Suc n) a = take_bit n (a div 2) * 2 + a mod 2 (is ?lhs = ?rhs)
proof (rule bit_eqI)
  fix m
  assume possible_bit TYPE('a) m
  then show bit ?lhs m  bit ?rhs m
    apply (cases a rule: parity_cases; cases m)
       apply (simp_all add: bit_simps even_bit_succ_iff mult.commute [of _ 2] add.commute [of _ 1] flip: bit_Suc)
     apply (simp_all add: bit_0)
    done
qed

lemma take_bit_rec:
  take_bit n a = (if n = 0 then 0 else take_bit (n - 1) (a div 2) * 2 + a mod 2)
  by (cases n) (simp_all add: take_bit_Suc)

lemma take_bit_Suc_0 [simp]:
  take_bit (Suc 0) a = a mod 2
  by (simp add: take_bit_eq_mod)

lemma take_bit_of_0 [simp]:
  take_bit n 0 = 0
  by (rule bit_eqI) (simp add: bit_simps)

lemma take_bit_of_1 [simp]:
  take_bit n 1 = of_bool (n > 0)
  by (cases n) (simp_all add: take_bit_Suc)

lemma drop_bit_of_0 [simp]:
  drop_bit n 0 = 0
  by (rule bit_eqI) (simp add: bit_simps)

lemma drop_bit_of_1 [simp]:
  drop_bit n 1 = of_bool (n = 0)
  by (rule bit_eqI) (simp add: bit_simps ac_simps)

lemma drop_bit_0 [simp]:
  drop_bit 0 = id
  by (simp add: fun_eq_iff drop_bit_eq_div)

lemma drop_bit_Suc:
  drop_bit (Suc n) a = drop_bit n (a div 2)
  using div_exp_eq [of a 1] by (simp add: drop_bit_eq_div)

lemma drop_bit_rec:
  drop_bit n a = (if n = 0 then a else drop_bit (n - 1) (a div 2))
  by (cases n) (simp_all add: drop_bit_Suc)

lemma drop_bit_half:
  drop_bit n (a div 2) = drop_bit n a div 2
  by (induction n arbitrary: a) (simp_all add: drop_bit_Suc)

lemma drop_bit_of_bool [simp]:
  drop_bit n (of_bool b) = of_bool (n = 0  b)
  by (cases n) simp_all

lemma even_take_bit_eq [simp]:
  even (take_bit n a)  n = 0  even a
  by (simp add: take_bit_rec [of n a])

lemma take_bit_take_bit [simp]:
  take_bit m (take_bit n a) = take_bit (min m n) a
  by (rule bit_eqI) (simp add: bit_simps)

lemma drop_bit_drop_bit [simp]:
  drop_bit m (drop_bit n a) = drop_bit (m + n) a
  by (simp add: drop_bit_eq_div power_add div_exp_eq ac_simps)

lemma push_bit_take_bit:
  push_bit m (take_bit n a) = take_bit (m + n) (push_bit m a)
  by (rule bit_eqI) (auto simp add: bit_simps)

lemma take_bit_push_bit:
  take_bit m (push_bit n a) = push_bit n (take_bit (m - n) a)
  by (rule bit_eqI) (auto simp add: bit_simps)

lemma take_bit_drop_bit:
  take_bit m (drop_bit n a) = drop_bit n (take_bit (m + n) a)
  by (rule bit_eqI) (auto simp add: bit_simps)

lemma drop_bit_take_bit:
  drop_bit m (take_bit n a) = take_bit (n - m) (drop_bit m a)
  by (rule bit_eqI) (auto simp add: bit_simps)

lemma even_push_bit_iff [simp]:
  even (push_bit n a)  n  0  even a
  by (simp add: push_bit_eq_mult) auto

lemma stable_imp_drop_bit_eq:
  drop_bit n a = a
  if a div 2 = a
  by (induction n) (simp_all add: that drop_bit_Suc)

lemma stable_imp_take_bit_eq:
  take_bit n a = (if even a then 0 else mask n)
    if a div 2 = a
  by (rule bit_eqI) (use that in simp add: bit_simps stable_imp_bit_iff_odd)

lemma exp_dvdE:
  assumes 2 ^ n dvd a
  obtains b where a = push_bit n b
proof -
  from assms obtain b where a = 2 ^ n * b ..
  then have a = push_bit n b
    by (simp add: push_bit_eq_mult ac_simps)
  with that show thesis .
qed

lemma take_bit_eq_0_iff:
  take_bit n a = 0  2 ^ n dvd a (is ?P  ?Q)
proof
  assume ?P
  then show ?Q
    by (simp add: take_bit_eq_mod mod_0_imp_dvd)
next
  assume ?Q
  then obtain b where a = push_bit n b
    by (rule exp_dvdE)
  then show ?P
    by (simp add: take_bit_push_bit)
qed

lemma take_bit_tightened:
  take_bit m a = take_bit m b if take_bit n a = take_bit n b and m  n
proof -
  from that have take_bit m (take_bit n a) = take_bit m (take_bit n b)
    by simp
  then have take_bit (min m n) a = take_bit (min m n) b
    by simp
  with that show ?thesis
    by (simp add: min_def)
qed

lemma take_bit_eq_self_iff_drop_bit_eq_0:
  take_bit n a = a  drop_bit n a = 0 (is ?P  ?Q)
proof
  assume ?P
  show ?Q
  proof (rule bit_eqI)
    fix m
    from ?P have a = take_bit n a ..
    also have ¬ bit (take_bit n a) (n + m)
      unfolding bit_simps
      by (simp add: bit_simps)
    finally show bit (drop_bit n a) m  bit 0 m
      by (simp add: bit_simps)
  qed
next
  assume ?Q
  show ?P
  proof (rule bit_eqI)
    fix m
    from ?Q have ¬ bit (drop_bit n a) (m - n)
      by simp
    then have ¬ bit a (n + (m - n))
      by (simp add: bit_simps)
    then show bit (take_bit n a) m  bit a m
      by (cases m < n) (auto simp add: bit_simps)
  qed
qed

lemma drop_bit_exp_eq:
  drop_bit m (2 ^ n) = of_bool (m  n  possible_bit TYPE('a) n) * 2 ^ (n - m)
  by (auto simp add: bit_eq_iff bit_simps)

lemma take_bit_and [simp]:
  take_bit n (a AND b) = take_bit n a AND take_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma take_bit_or [simp]:
  take_bit n (a OR b) = take_bit n a OR take_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma take_bit_xor [simp]:
  take_bit n (a XOR b) = take_bit n a XOR take_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma push_bit_and [simp]:
  push_bit n (a AND b) = push_bit n a AND push_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma push_bit_or [simp]:
  push_bit n (a OR b) = push_bit n a OR push_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma push_bit_xor [simp]:
  push_bit n (a XOR b) = push_bit n a XOR push_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma drop_bit_and [simp]:
  drop_bit n (a AND b) = drop_bit n a AND drop_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma drop_bit_or [simp]:
  drop_bit n (a OR b) = drop_bit n a OR drop_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma drop_bit_xor [simp]:
  drop_bit n (a XOR b) = drop_bit n a XOR drop_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma take_bit_of_mask [simp]:
  take_bit m (mask n) = mask (min m n)
  by (rule bit_eqI) (simp add: bit_simps)

lemma take_bit_eq_mask:
  take_bit n a = a AND mask n
  by (auto simp add: bit_eq_iff bit_simps)

lemma or_eq_0_iff:
  a OR b = 0  a = 0  b = 0
  by (auto simp add: bit_eq_iff bit_or_iff)

lemma bit_iff_and_drop_bit_eq_1:
  bit a n  drop_bit n a AND 1 = 1
  by (simp add: bit_iff_odd_drop_bit and_one_eq odd_iff_mod_2_eq_one)

lemma bit_iff_and_push_bit_not_eq_0:
  bit a n  a AND push_bit n 1  0
  by (cases possible_bit TYPE('a) n) (simp_all add: bit_eq_iff bit_simps impossible_bit)

lemma bit_set_bit_iff [bit_simps]:
  bit (set_bit m a) n  bit a n  (m = n  possible_bit TYPE('a) n)
  by (auto simp add: set_bit_eq_or bit_or_iff bit_exp_iff)

lemma even_set_bit_iff:
  even (set_bit m a)  even a  m  0
  using bit_set_bit_iff [of m a 0] by (auto simp add: bit_0)

lemma bit_unset_bit_iff [bit_simps]:
  bit (unset_bit m a) n  bit a n  m  n
  by (auto simp add: unset_bit_eq_or_xor bit_simps dest: bit_imp_possible_bit)

lemma even_unset_bit_iff:
  even (unset_bit m a)  even a  m = 0
  using bit_unset_bit_iff [of m a 0] by (auto simp add: bit_0)

lemma bit_flip_bit_iff [bit_simps]:
  bit (flip_bit m a) n  (m = n  ¬ bit a n)  possible_bit TYPE('a) n
  by (auto simp add: bit_eq_iff bit_simps flip_bit_eq_xor bit_imp_possible_bit)

lemma even_flip_bit_iff:
  even (flip_bit m a)  ¬ (even a  m = 0)
  using bit_flip_bit_iff [of m a 0] by (auto simp: possible_bit_def  bit_0)

lemma and_exp_eq_0_iff_not_bit:
  a AND 2 ^ n = 0  ¬ bit a n (is ?P  ?Q)
  using bit_imp_possible_bit[of a n]
  by (auto simp add: bit_eq_iff bit_simps)

lemma bit_sum_mult_2_cases:
  assumes a: j. ¬ bit a (Suc j)
  shows bit (a + 2 * b) n = (if n = 0 then odd a else bit (2 * b) n)
proof -
  from a have n = 0 if bit a n for n using that
    by (cases n) simp_all
  then have a = 0  a = 1
    by (auto simp add: bit_eq_iff bit_1_iff)
  then show ?thesis
    by (cases n) (auto simp add: bit_0 bit_double_iff even_bit_succ_iff)
qed

lemma set_bit_0 [simp]:
  set_bit 0 a = 1 + 2 * (a div 2)
  by (auto simp add: bit_eq_iff bit_simps even_bit_succ_iff simp flip: bit_Suc)

lemma set_bit_Suc:
  set_bit (Suc n) a = a mod 2 + 2 * set_bit n (a div 2)
  by (auto simp add: bit_eq_iff bit_sum_mult_2_cases bit_simps bit_0 simp flip: bit_Suc
    elim: possible_bit_less_imp)

lemma unset_bit_0 [simp]:
  unset_bit 0 a = 2 * (a div 2)
  by (auto simp add: bit_eq_iff bit_simps simp flip: bit_Suc)

lemma unset_bit_Suc:
  unset_bit (Suc n) a = a mod 2 + 2 * unset_bit n (a div 2)
  by (auto simp add: bit_eq_iff bit_sum_mult_2_cases bit_simps bit_0 simp flip: bit_Suc)

lemma flip_bit_0 [simp]:
  flip_bit 0 a = of_bool (even a) + 2 * (a div 2)
  by (auto simp add: bit_eq_iff bit_simps even_bit_succ_iff bit_0 simp flip: bit_Suc)

lemma flip_bit_Suc:
  flip_bit (Suc n) a = a mod 2 + 2 * flip_bit n (a div 2)
  by (auto simp add: bit_eq_iff bit_sum_mult_2_cases bit_simps bit_0 simp flip: bit_Suc
    elim: possible_bit_less_imp)

lemma flip_bit_eq_if:
  flip_bit n a = (if bit a n then unset_bit else set_bit) n a
  by (rule bit_eqI) (auto simp add: bit_set_bit_iff bit_unset_bit_iff bit_flip_bit_iff)

lemma take_bit_set_bit_eq:
  take_bit n (set_bit m a) = (if n  m then take_bit n a else set_bit m (take_bit n a))
  by (rule bit_eqI) (auto simp add: bit_take_bit_iff bit_set_bit_iff)

lemma take_bit_unset_bit_eq:
  take_bit n (unset_bit m a) = (if n  m then take_bit n a else unset_bit m (take_bit n a))
  by (rule bit_eqI) (auto simp add: bit_take_bit_iff bit_unset_bit_iff)

lemma take_bit_flip_bit_eq:
  take_bit n (flip_bit m a) = (if n  m then take_bit n a else flip_bit m (take_bit n a))
  by (rule bit_eqI) (auto simp add: bit_take_bit_iff bit_flip_bit_iff)

lemma bit_1_0 [simp]:
  bit 1 0
  by (simp add: bit_0)

lemma not_bit_1_Suc [simp]:
  ¬ bit 1 (Suc n)
  by (simp add: bit_Suc)

lemma push_bit_Suc_numeral [simp]:
  push_bit (Suc n) (numeral k) = push_bit n (numeral (Num.Bit0 k))
  by (simp add: numeral_eq_Suc mult_2_right) (simp add: numeral_Bit0)

lemma mask_eq_0_iff [simp]:
  mask n = 0  n = 0
  by (cases n) (simp_all add: mask_Suc_double or_eq_0_iff)

lemma bit_horner_sum_bit_iff [bit_simps]:
  bit (horner_sum of_bool 2 bs) n  possible_bit TYPE('a) n  n < length bs  bs ! n
proof (induction bs arbitrary: n)
  case Nil
  then show ?case
    by simp
next
  case (Cons b bs)
  show ?case
  proof (cases n)
    case 0
    then show ?thesis
      by (simp add: bit_0)
  next
    case (Suc m)
    with bit_rec [of _ n] Cons.prems Cons.IH [of m]
    show ?thesis
      by (simp add: bit_simps)
        (auto simp add: possible_bit_less_imp bit_simps simp flip: bit_Suc)
  qed
qed

lemma horner_sum_bit_eq_take_bit:
  horner_sum of_bool 2 (map (bit a) [0..<n]) = take_bit n a
  by (rule bit_eqI) (auto simp add: bit_simps)

lemma take_bit_horner_sum_bit_eq:
  take_bit n (horner_sum of_bool 2 bs) = horner_sum of_bool 2 (take n bs)
  by (auto simp add: bit_eq_iff bit_take_bit_iff bit_horner_sum_bit_iff)

lemma take_bit_sum:
  take_bit n a = (k = 0..<n. push_bit k (of_bool (bit a k)))
  by (simp flip: horner_sum_bit_eq_take_bit add: horner_sum_eq_sum push_bit_eq_mult)

lemma set_bit_eq:
  set_bit n a = a + of_bool (¬ bit a n) * 2 ^ n
proof -
  have a AND of_bool (¬ bit a n) * 2 ^ n = 0
    by (auto simp add: bit_eq_iff bit_simps)
  then show ?thesis
    by (auto simp add: bit_eq_iff bit_simps disjunctive_add_eq_or)
qed

end

class ring_bit_operations = semiring_bit_operations + ring_parity +
  fixes not :: 'a  'a  (NOT)
  assumes not_eq_complement: NOT a = - a - 1
begin

text ‹
  For the sake of code generation constnot is specified as
  definitional class operation.  Note that constnot has no
  sensible definition for unlimited but only positive bit strings
  (type typnat).
›

lemma bits_minus_1_mod_2_eq [simp]:
  (- 1) mod 2 = 1
  by (simp add: mod_2_eq_odd)

lemma minus_eq_not_plus_1:
  - a = NOT a + 1
  using not_eq_complement [of a] by simp

lemma minus_eq_not_minus_1:
  - a = NOT (a - 1)
  using not_eq_complement [of a - 1] by simp (simp add: algebra_simps)

lemma not_rec:
  NOT a = of_bool (even a) + 2 * NOT (a div 2)
  by (simp add: not_eq_complement algebra_simps mod_2_eq_odd flip: minus_mod_eq_mult_div)

lemma decr_eq_not_minus:
  a - 1 = NOT (- a)
  using not_eq_complement [of - a] by simp

lemma even_not_iff [simp]:
  even (NOT a)  odd a
  by (simp add: not_eq_complement)

lemma bit_not_iff [bit_simps]:
  bit (NOT a) n  possible_bit TYPE('a) n  ¬ bit a n
proof (cases possible_bit TYPE('a) n)
  case False
  then show ?thesis
    by (auto dest: bit_imp_possible_bit)
next
  case True
  moreover have bit (NOT a) n  ¬ bit a n
  using possible_bit TYPE('a) n proof (induction n arbitrary: a)
    case 0
    then show ?case
      by (simp add: bit_0)
  next
    case (Suc n)
    from Suc.prems Suc.IH [of a div 2]
    show ?case
      by (simp add: impossible_bit possible_bit_less_imp not_rec [of a] even_bit_succ_iff bit_double_iff flip: bit_Suc)
  qed
  ultimately show ?thesis
    by simp
qed

lemma bit_not_exp_iff [bit_simps]:
  bit (NOT (2 ^ m)) n  possible_bit TYPE('a) n  n  m
  by (auto simp add: bit_not_iff bit_exp_iff)

lemma bit_minus_iff [bit_simps]:
  bit (- a) n  possible_bit TYPE('a) n  ¬ bit (a - 1) n
  by (simp add: minus_eq_not_minus_1 bit_not_iff)

lemma bit_minus_1_iff [simp]:
  bit (- 1) n  possible_bit TYPE('a) n
  by (simp add: bit_minus_iff)

lemma bit_minus_exp_iff [bit_simps]:
  bit (- (2 ^ m)) n  possible_bit TYPE('a) n  n  m
  by (auto simp add: bit_simps simp flip: mask_eq_exp_minus_1)

lemma bit_minus_2_iff [simp]:
  bit (- 2) n  possible_bit TYPE('a) n  n > 0
  by (simp add: bit_minus_iff bit_1_iff)

lemma bit_decr_iff:
  bit (a - 1) n  possible_bit TYPE('a) n  ¬ bit (- a) n
  by (simp add: decr_eq_not_minus bit_not_iff)

lemma bit_not_iff_eq:
  bit (NOT a) n  2 ^ n  0  ¬ bit a n
  by (simp add: bit_simps possible_bit_def)

lemma not_one_eq [simp]:
  NOT 1 = - 2
  by (simp add: bit_eq_iff bit_not_iff) (simp add: bit_1_iff)

sublocale "and": semilattice_neutr (AND) - 1
  by standard (rule bit_eqI, simp add: bit_and_iff)

sublocale bit: abstract_boolean_algebra (AND) (OR) NOT 0 - 1
  by standard (auto simp add: bit_and_iff bit_or_iff bit_not_iff intro: bit_eqI)

sublocale bit: abstract_boolean_algebra_sym_diff (AND) (OR) NOT 0 - 1 (XOR)
  apply standard
  apply (rule bit_eqI)
  apply (auto simp add: bit_simps)
  done

lemma and_eq_not_not_or:
  a AND b = NOT (NOT a OR NOT b)
  by simp

lemma or_eq_not_not_and:
  a OR b = NOT (NOT a AND NOT b)
  by simp

lemma not_add_distrib:
  NOT (a + b) = NOT a - b
  by (simp add: not_eq_complement algebra_simps)

lemma not_diff_distrib:
  NOT (a - b) = NOT a + b
  using not_add_distrib [of a - b] by simp

lemma and_eq_minus_1_iff:
  a AND b = - 1  a = - 1  b = - 1
  by (auto simp: bit_eq_iff bit_simps)

lemma disjunctive_and_not_eq_xor:
  a AND NOT b = a XOR b if NOT a AND b = 0
  using that by (auto simp add: bit_eq_iff bit_simps)

lemma disjunctive_diff_eq_and_not:
  a - b = a AND NOT b if NOT a AND b = 0
proof -
  from that have NOT a + b = NOT a OR b
    by (rule disjunctive_add_eq_or)
  then have NOT (NOT a + b) = NOT (NOT a OR b)
    by simp
  then show ?thesis
    by (simp add: not_add_distrib)
qed

lemma disjunctive_diff_eq_xor:
  a AND NOT b = a XOR b if NOT a AND b = 0
  using that by (simp add: disjunctive_and_not_eq_xor disjunctive_diff_eq_and_not)

lemma push_bit_minus:
  push_bit n (- a) = - push_bit n a
  by (simp add: push_bit_eq_mult)

lemma take_bit_not_take_bit:
  take_bit n (NOT (take_bit n a)) = take_bit n (NOT a)
  by (auto simp add: bit_eq_iff bit_take_bit_iff bit_not_iff)

lemma take_bit_not_iff:
  take_bit n (NOT a) = take_bit n (NOT b)  take_bit n a = take_bit n b
  by (auto simp add: bit_eq_iff bit_simps)

lemma take_bit_not_eq_mask_diff:
  take_bit n (NOT a) = mask n - take_bit n a
proof -
  have NOT (mask n) AND take_bit n a = 0
    by (simp add: bit_eq_iff bit_simps)
  moreover have take_bit n (NOT a) = mask n AND NOT (take_bit n a)
    by (auto simp add: bit_eq_iff bit_simps)
  ultimately show ?thesis
    by (simp add: disjunctive_diff_eq_and_not)
qed

lemma mask_eq_take_bit_minus_one:
  mask n = take_bit n (- 1)
  by (simp add: bit_eq_iff bit_mask_iff bit_take_bit_iff conj_commute)

lemma take_bit_minus_one_eq_mask [simp]:
  take_bit n (- 1) = mask n
  by (simp add: mask_eq_take_bit_minus_one)

lemma minus_exp_eq_not_mask:
  - (2 ^ n) = NOT (mask n)
  by (rule bit_eqI) (simp add: bit_minus_iff bit_not_iff flip: mask_eq_exp_minus_1)

lemma push_bit_minus_one_eq_not_mask [simp]:
  push_bit n (- 1) = NOT (mask n)
  by (simp add: push_bit_eq_mult minus_exp_eq_not_mask)

lemma take_bit_not_mask_eq_0:
  take_bit m (NOT (mask n)) = 0 if n  m
  by (rule bit_eqI) (use that in simp add: bit_take_bit_iff bit_not_iff bit_mask_iff)

lemma unset_bit_eq_and_not:
  unset_bit n a = a AND NOT (push_bit n 1)
  by (rule bit_eqI) (auto simp add: bit_simps)

lemma push_bit_Suc_minus_numeral [simp]:
  push_bit (Suc n) (- numeral k) = push_bit n (- numeral (Num.Bit0 k))
  apply (simp only: numeral_Bit0)
  apply simp
  apply (simp only: numeral_mult mult_2_right numeral_add)
  done

lemma push_bit_minus_numeral [simp]:
  push_bit (numeral l) (- numeral k) = push_bit (pred_numeral l) (- numeral (Num.Bit0 k))
  by (simp only: numeral_eq_Suc push_bit_Suc_minus_numeral)

lemma take_bit_Suc_minus_1_eq:
  take_bit (Suc n) (- 1) = 2 ^ Suc n - 1
  by (simp add: mask_eq_exp_minus_1)

lemma take_bit_numeral_minus_1_eq:
  take_bit (numeral k) (- 1) = 2 ^ numeral k - 1
  by (simp add: mask_eq_exp_minus_1)

lemma push_bit_mask_eq:
  push_bit m (mask n) = mask (n + m) AND NOT (mask m)
  by (rule bit_eqI) (auto simp add: bit_simps not_less possible_bit_less_imp)

lemma slice_eq_mask:
  push_bit n (take_bit m (drop_bit n a)) = a AND mask (m + n) AND NOT (mask n)
  by (rule bit_eqI) (auto simp add: bit_simps)

lemma push_bit_numeral_minus_1 [simp]:
  push_bit (numeral n) (- 1) = - (2 ^ numeral n)
  by (simp add: push_bit_eq_mult)

lemma unset_bit_eq:
  unset_bit n a = a - of_bool (bit a n) * 2 ^ n
proof -
  have NOT a AND of_bool (bit a n) * 2 ^ n = 0
    by (auto simp add: bit_eq_iff bit_simps)
  moreover have unset_bit n a = a AND NOT (of_bool (bit a n) * 2 ^ n)
    by (auto simp add: bit_eq_iff bit_simps)
  ultimately show ?thesis
    by (simp add: disjunctive_diff_eq_and_not)
qed

end


subsection ‹Common algebraic structure›

class linordered_euclidean_semiring_bit_operations =
  linordered_euclidean_semiring + semiring_bit_operations
begin

lemma possible_bit [simp]:
  possible_bit TYPE('a) n
  by (simp add: possible_bit_def)

lemma take_bit_of_exp [simp]:
  take_bit m (2 ^ n) = of_bool (n < m) * 2 ^ n
  by (simp add: take_bit_eq_mod exp_mod_exp)

lemma take_bit_of_2 [simp]:
  take_bit n 2 = of_bool (2  n) * 2
  using take_bit_of_exp [of n 1] by simp

lemma push_bit_eq_0_iff [simp]:
  push_bit n a = 0  a = 0
  by (simp add: push_bit_eq_mult)

lemma take_bit_add:
  take_bit n (take_bit n a + take_bit n b) = take_bit n (a + b)
  by (simp add: take_bit_eq_mod mod_simps)

lemma take_bit_of_1_eq_0_iff [simp]:
  take_bit n 1 = 0  n = 0
  by (simp add: take_bit_eq_mod)

lemma drop_bit_Suc_bit0 [simp]:
  drop_bit (Suc n) (numeral (Num.Bit0 k)) = drop_bit n (numeral k)
  by (simp add: drop_bit_Suc numeral_Bit0_div_2)

lemma drop_bit_Suc_bit1 [simp]:
  drop_bit (Suc n) (numeral (Num.Bit1 k)) = drop_bit n (numeral k)
  by (simp add: drop_bit_Suc numeral_Bit1_div_2)

lemma drop_bit_numeral_bit0 [simp]:
  drop_bit (numeral l) (numeral (Num.Bit0 k)) = drop_bit (pred_numeral l) (numeral k)
  by (simp add: drop_bit_rec numeral_Bit0_div_2)

lemma drop_bit_numeral_bit1 [simp]:
  drop_bit (numeral l) (numeral (Num.Bit1 k)) = drop_bit (pred_numeral l) (numeral k)
  by (simp add: drop_bit_rec numeral_Bit1_div_2)

lemma take_bit_Suc_1 [simp]:
  take_bit (Suc n) 1 = 1
  by (simp add: take_bit_Suc)

lemma take_bit_Suc_bit0:
  take_bit (Suc n) (numeral (Num.Bit0 k)) = take_bit n (numeral k) * 2
  by (simp add: take_bit_Suc numeral_Bit0_div_2)

lemma take_bit_Suc_bit1:
  take_bit (Suc n) (numeral (Num.Bit1 k)) = take_bit n (numeral k) * 2 + 1
  by (simp add: take_bit_Suc numeral_Bit1_div_2 mod_2_eq_odd)

lemma take_bit_numeral_1 [simp]:
  take_bit (numeral l) 1 = 1
  by (simp add: take_bit_rec [of numeral l 1])

lemma take_bit_numeral_bit0:
  take_bit (numeral l) (numeral (Num.Bit0 k)) = take_bit (pred_numeral l) (numeral k) * 2
  by (simp add: take_bit_rec numeral_Bit0_div_2)

lemma take_bit_numeral_bit1:
  take_bit (numeral l) (numeral (Num.Bit1 k)) = take_bit (pred_numeral l) (numeral k) * 2 + 1
  by (simp add: take_bit_rec numeral_Bit1_div_2 mod_2_eq_odd)

lemma bit_of_nat_iff_bit [bit_simps]:
  bit (of_nat m) n  bit m n
proof -
  have even (m div 2 ^ n)  even (of_nat (m div 2 ^ n))
    by simp
  also have of_nat (m div 2 ^ n) = of_nat m div of_nat (2 ^ n)
    by (simp add: of_nat_div)
  finally show ?thesis
    by (simp add: bit_iff_odd semiring_bits_class.bit_iff_odd)
qed

lemma drop_bit_mask_eq:
  drop_bit m (mask n) = mask (n - m)
  by (rule bit_eqI) (auto simp add: bit_simps possible_bit_def)

lemma bit_push_bit_iff':
  bit (push_bit m a) n  m  n  bit a (n - m)
  by (simp add: bit_simps)

lemma mask_half:
  mask n div 2 = mask (n - 1)
  by (cases n) (simp_all add: mask_Suc_double one_or_eq)

lemma take_bit_Suc_from_most:
  take_bit (Suc n) a = 2 ^ n * of_bool (bit a n) + take_bit n a
  using mod_mult2_eq' [of a 2 ^ n 2]
  by (simp only: take_bit_eq_mod power_Suc2)
    (simp_all add: bit_iff_odd odd_iff_mod_2_eq_one)

lemma take_bit_nonnegative [simp]:
  0  take_bit n a
  using horner_sum_nonnegative by (simp flip: horner_sum_bit_eq_take_bit)

lemma not_take_bit_negative [simp]:
  ¬ take_bit n a < 0
  by (simp add: not_less)

lemma bit_imp_take_bit_positive:
  0 < take_bit m a if n < m and bit a n
proof (rule ccontr)
  assume ¬ 0 < take_bit m a
  then have take_bit m a = 0
    by (auto simp add: not_less intro: order_antisym)
  then have bit (take_bit m a) n = bit 0 n
    by simp
  with that show False
    by (simp add: bit_take_bit_iff)
qed

lemma take_bit_mult:
  take_bit n (take_bit n a * take_bit n b) = take_bit n (a * b)
  by (simp add: take_bit_eq_mod mod_mult_eq)

lemma drop_bit_push_bit:
  drop_bit m (push_bit n a) = drop_bit (m - n) (push_bit (n - m) a)
  by (cases m  n)
    (auto simp add: mult.left_commute [of _ 2 ^ n] mult.commute [of _ 2 ^ n] mult.assoc
    mult.commute [of a] drop_bit_eq_div push_bit_eq_mult not_le power_add Orderings.not_le dest!: le_Suc_ex less_imp_Suc_add)

end


subsection ‹Instance typint

locale fold2_bit_int =
  fixes f :: bool  bool  bool
begin

context
begin

function F :: int  int  int
  where F k l = (if k  {0, - 1}  l  {0, - 1}
    then - of_bool (f (odd k) (odd l))
    else of_bool (f (odd k) (odd l)) + 2 * (F (k div 2) (l div 2)))
  by auto

private termination proof (relation measure (λ(k, l). nat (¦k¦ + ¦l¦)))
  have less_eq: ¦k div 2¦  ¦k¦ for k :: int
    by (cases k) (simp_all add: divide_int_def nat_add_distrib)
  then have less: ¦k div 2¦ < ¦k¦ if k  {0, - 1} for k :: int
    using that by (auto simp add: less_le [of k])
  show wf (measure (λ(k, l). nat (¦k¦ + ¦l¦)))
    by simp
  show ((k div 2, l div 2), k, l)  measure (λ(k, l). nat (¦k¦ + ¦l¦))
    if ¬ (k  {0, - 1}  l  {0, - 1}) for k l
  proof -
    from that have *: k  {0, - 1}  l  {0, - 1}
      by simp
    then have 0 < ¦k¦ + ¦l¦
      by auto
    moreover from * have ¦k div 2¦ + ¦l div 2¦ < ¦k¦ + ¦l¦
    proof
      assume k  {0, - 1}
      then have ¦k div 2¦ < ¦k¦
        by (rule less)
      with less_eq [of l] show ?thesis
        by auto
    next
      assume l  {0, - 1}
      then have ¦l div 2¦ < ¦l¦
        by (rule less)
      with less_eq [of k] show ?thesis
        by auto
    qed
    ultimately show ?thesis
      by (simp only: in_measure split_def fst_conv snd_conv nat_mono_iff)
  qed
qed

declare F.simps [simp del]

lemma rec:
  F k l = of_bool (f (odd k) (odd l)) + 2 * (F (k div 2) (l div 2))
    for k l :: int
proof (cases k  {0, - 1}  l  {0, - 1})
  case True
  then show ?thesis
    by (auto simp add: F.simps [of 0] F.simps [of - 1])
next
  case False
  then show ?thesis
    by (auto simp add: ac_simps F.simps [of k l])
qed

lemma bit_iff:
  bit (F k l) n  f (bit k n) (bit l n) for k l :: int
proof (induction n arbitrary: k l)
  case 0
  then show ?case
    by (simp add: rec [of k l] bit_0)
next
  case (Suc n)
  then show ?case
    by (simp add: rec [of k l] bit_Suc)
qed

end

end

instantiation int :: ring_bit_operations
begin

definition not_int :: int  int
  where not_int k = - k - 1

global_interpretation and_int: fold2_bit_int (∧)
  defines and_int = and_int.F .

global_interpretation or_int: fold2_bit_int (∨)
  defines or_int = or_int.F .

global_interpretation xor_int: fold2_bit_int (≠)
  defines xor_int = xor_int.F .

definition mask_int :: nat  int
  where mask n = (2 :: int) ^ n - 1

definition push_bit_int :: nat  int  int
  where push_bit_int n k = k * 2 ^ n

definition drop_bit_int :: nat  int  int
  where drop_bit_int n k = k div 2 ^ n

definition take_bit_int :: nat  int  int
  where take_bit_int n k = k mod 2 ^ n

definition set_bit_int :: nat  int  int
  where set_bit n k = k OR push_bit n 1 for k :: int

definition unset_bit_int :: nat  int  int
  where unset_bit n k = k AND NOT (push_bit n 1) for k :: int

definition flip_bit_int :: nat  int  int
  where flip_bit n k = k XOR push_bit n 1 for k :: int

lemma not_int_div_2:
  NOT k div 2 = NOT (k div 2) for k :: int
  by (simp add: not_int_def)

lemma bit_not_int_iff:
  bit (NOT k) n  ¬ bit k n for k :: int
proof (rule sym, induction n arbitrary: k)
  case 0
  then show ?case
    by (simp add: bit_0 not_int_def)
next
  case (Suc n)
  then show ?case
    by (simp add: bit_Suc not_int_div_2)
qed

instance proof
  fix k l :: int and m n :: nat
  show unset_bit n k = (k OR push_bit n 1) XOR push_bit n 1
    by (rule bit_eqI)
      (auto simp add: unset_bit_int_def
        and_int.bit_iff or_int.bit_iff xor_int.bit_iff bit_not_int_iff push_bit_int_def bit_simps)
qed (fact and_int.rec or_int.rec xor_int.rec mask_int_def set_bit_int_def flip_bit_int_def
  push_bit_int_def drop_bit_int_def take_bit_int_def not_int_def)+

end

instance int :: linordered_euclidean_semiring_bit_operations ..

context ring_bit_operations
begin

lemma even_of_int_iff:
  even (of_int k)  even k
  by (induction k rule: int_bit_induct) simp_all

lemma bit_of_int_iff [bit_simps]:
  bit (of_int k) n  possible_bit TYPE('a) n  bit k n
proof (cases possible_bit TYPE('a) n)
  case False
  then show ?thesis
    by (simp add: impossible_bit)
next
  case True
  then have bit (of_int k) n  bit k n
  proof (induction k arbitrary: n rule: int_bit_induct)
    case zero
    then show ?case
      by simp
  next
    case minus
    then show ?case
      by simp
  next
    case (even k)
    then show ?case
      using bit_double_iff [of of_int k n] Bit_Operations.bit_double_iff [of k n]
      by (cases n) (auto simp add: ac_simps possible_bit_def dest: mult_not_zero)
  next
    case (odd k)
    then show ?case
      using bit_double_iff [of of_int k n]
      by (cases n)
        (auto simp add: ac_simps bit_double_iff even_bit_succ_iff Bit_Operations.bit_0 Bit_Operations.bit_Suc
          possible_bit_def dest: mult_not_zero)
  qed
  with True show ?thesis
    by simp
qed

lemma push_bit_of_int:
  push_bit n (of_int k) = of_int (push_bit n k)
  by (simp add: push_bit_eq_mult Bit_Operations.push_bit_eq_mult)

lemma of_int_push_bit:
  of_int (push_bit n k) = push_bit n (of_int k)
  by (simp add: push_bit_eq_mult Bit_Operations.push_bit_eq_mult)

lemma take_bit_of_int:
  take_bit n (of_int k) = of_int (take_bit n k)
  by (rule bit_eqI) (simp add: bit_take_bit_iff Bit_Operations.bit_take_bit_iff bit_of_int_iff)

lemma of_int_take_bit:
  of_int (take_bit n k) = take_bit n (of_int k)
  by (rule bit_eqI) (simp add: bit_take_bit_iff Bit_Operations.bit_take_bit_iff bit_of_int_iff)

lemma of_int_not_eq:
  of_int (NOT k) = NOT (of_int k)
  by (rule bit_eqI) (simp add: bit_not_iff Bit_Operations.bit_not_iff bit_of_int_iff)

lemma of_int_not_numeral:
  of_int (NOT (numeral k)) = NOT (numeral k)
  by (simp add: local.of_int_not_eq)

lemma of_int_and_eq:
  of_int (k AND l) = of_int k AND of_int l
  by (rule bit_eqI) (simp add: bit_of_int_iff bit_and_iff Bit_Operations.bit_and_iff)

lemma of_int_or_eq:
  of_int (k OR l) = of_int k OR of_int l
  by (rule bit_eqI) (simp add: bit_of_int_iff bit_or_iff Bit_Operations.bit_or_iff)

lemma of_int_xor_eq:
  of_int (k XOR l) = of_int k XOR of_int l
  by (rule bit_eqI) (simp add: bit_of_int_iff bit_xor_iff Bit_Operations.bit_xor_iff)

lemma of_int_mask_eq:
  of_int (mask n) = mask n
  by (induction n) (simp_all add: mask_Suc_double Bit_Operations.mask_Suc_double of_int_or_eq)

end

lemma take_bit_int_less_exp [simp]:
  take_bit n k < 2 ^ n for k :: int
  by (simp add: take_bit_eq_mod)

lemma take_bit_int_eq_self_iff:
  take_bit n k = k  0  k  k < 2 ^ n (is ?P  ?Q)
  for k :: int
proof
  assume ?P
  moreover note take_bit_int_less_exp [of n k] take_bit_nonnegative [of n k]
  ultimately show ?Q
    by simp
next
  assume ?Q
  then show ?P
    by (simp add: take_bit_eq_mod)
qed

lemma take_bit_int_eq_self:
  take_bit n k = k if 0  k k < 2 ^ n for k :: int
  using that by (simp add: take_bit_int_eq_self_iff)

lemma mask_nonnegative_int [simp]:
  mask n  (0::int)
  by (simp add: mask_eq_exp_minus_1 add_le_imp_le_diff)

lemma not_mask_negative_int [simp]:
  ¬ mask n < (0::int)
  by (simp add: not_less)

lemma not_nonnegative_int_iff [simp]:
  NOT k  0  k < 0 for k :: int
  by (simp add: not_int_def)

lemma not_negative_int_iff [simp]:
  NOT k < 0  k  0 for k :: int
  by (subst Not_eq_iff [symmetric]) (simp add: not_less not_le)

lemma and_nonnegative_int_iff [simp]:
  k AND l  0  k  0  l  0 for k l :: int
proof (induction k arbitrary: l rule: int_bit_induct)
  case zero
  then show ?case
    by simp
next
  case minus
  then show ?case
    by simp
next
  case (even k)
  then show ?case
    using and_int.rec [of k * 2 l]
    by (simp add: pos_imp_zdiv_nonneg_iff zero_le_mult_iff)
next
  case (odd k)
  from odd have 0  k AND l div 2  0  k  0  l div 2
    by simp
  then have 0  (1 + k * 2) div 2 AND l div 2  0  (1 + k * 2) div 2  0  l div 2
    by simp
  with and_int.rec [of 1 + k * 2 l]
  show ?case
    by (auto simp add: zero_le_mult_iff not_le)
qed

lemma and_negative_int_iff [simp]:
  k AND l < 0  k < 0  l < 0 for k l :: int
  by (subst Not_eq_iff [symmetric]) (simp add: not_less)

lemma and_less_eq:
  k AND l  k if l < 0 for k l :: int
using that proof (induction k arbitrary: l rule: int_bit_induct)
  case zero
  then show ?case
    by simp
next
  case minus
  then show ?case
    by simp
next
  case (even k)
  from even.IH [of l div 2] even.hyps even.prems
  show ?case
    by (simp add: and_int.rec [of _ l])
next
  case (odd k)
  from odd.IH [of l div 2] odd.hyps odd.prems
  show ?case
    by (simp add: and_int.rec [of _ l])
qed

lemma or_nonnegative_int_iff [simp]:
  k OR l  0  k  0  l  0 for k l :: int
  by (simp only: or_eq_not_not_and not_nonnegative_int_iff) simp

lemma or_negative_int_iff [simp]:
  k OR l < 0  k < 0  l < 0 for k l :: int
  by (subst Not_eq_iff [symmetric]) (simp add: not_less)

lemma or_greater_eq:
  k OR l  k if l  0 for k l :: int
using that proof (induction k arbitrary: l rule: int_bit_induct)
  case zero
  then show ?case
    by simp
next
  case minus
  then show ?case
    by simp
next
  case (even k)
  from even.IH [of l div 2] even.hyps even.prems
  show ?case
    by (simp add: or_int.rec [of _ l])
next
  case (odd k)
  from odd.IH [of l div 2] odd.hyps odd.prems
  show ?case
    by (simp add: or_int.rec [of _ l])
qed

lemma xor_nonnegative_int_iff [simp]:
  k XOR l  0  (k  0  l  0) for k l :: int
  by (simp only: bit.xor_def or_nonnegative_int_iff) auto

lemma xor_negative_int_iff [simp]:
  k XOR l < 0  (k < 0)  (l < 0) for k l :: int
  by (subst Not_eq_iff [symmetric]) (auto simp add: not_less)

lemma OR_upper: contributor ‹Stefan Berghofer›
  x OR y < 2 ^ n if 0  x x < 2 ^ n y < 2 ^ n for x y :: int
using that proof (induction x arbitrary: y n rule: int_bit_induct)
  case zero
  then show ?case
    by simp
next
  case minus
  then show ?case
    by simp
next
  case (even x)
  from even.IH [of n - 1 y div 2] even.prems even.hyps
  show ?case
    by (cases n) (auto simp add: or_int.rec [of _ * 2] elim: oddE)
next
  case (odd x)
  from odd.IH [of n - 1 y div 2] odd.prems odd.hyps
  show ?case
    by (cases n) (auto simp add: or_int.rec [of 1 + _ * 2], linarith)
qed

lemma XOR_upper: contributor ‹Stefan Berghofer›
  x XOR y < 2 ^ n if 0  x x < 2 ^ n y < 2 ^ n for x y :: int
using that proof (induction x arbitrary: y n rule: int_bit_induct)
  case zero
  then show ?case
    by simp
next
  case minus
  then show ?case
    by simp
next
  case (even x)
  from even.IH [of n - 1 y div 2] even.prems even.hyps
  show ?case
    by (cases n) (auto simp add: xor_int.rec [of _ * 2] elim: oddE)
next
  case (odd x)
  from odd.IH [of n - 1 y div 2] odd.prems odd.hyps
  show ?case
    by (cases n) (auto simp add: xor_int.rec [of 1 + _ * 2])
qed

lemma AND_lower [simp]: contributor ‹Stefan Berghofer›
  0  x AND y if 0  x for x y :: int
  using that by simp

lemma OR_lower [simp]: contributor ‹Stefan Berghofer›
  0  x OR y if 0  x 0  y for x y :: int
  using that by simp

lemma XOR_lower [simp]: contributor ‹Stefan Berghofer›
  0  x XOR y if 0  x 0  y for x y :: int
  using that by simp

lemma AND_upper1 [simp]: contributor ‹Stefan Berghofer›
  x AND y  x if 0  x for x y :: int
using that proof (induction x arbitrary: y rule: int_bit_induct)
  case (odd k)
  then have k AND y div 2  k
    by simp
  then show ?case
    by (simp add: and_int.rec [of 1 + _ * 2])
qed (simp_all add: and_int.rec [of _ * 2])

lemma AND_upper1' [simp]: contributor ‹Stefan Berghofer›
  y AND x  z if 0  y y  z for x y z :: int
  using _ y  z by (rule order_trans) (use 0  y in simp)

lemma AND_upper1'' [simp]: contributor ‹Stefan Berghofer›
  y AND x < z if 0  y y < z for x y z :: int
  using _ y < z by (rule order_le_less_trans) (use 0  y in simp)

lemma AND_upper2 [simp]: contributor ‹Stefan Berghofer›
  x AND y  y if 0  y for x y :: int
  using that AND_upper1 [of y x] by (simp add: ac_simps)

lemma AND_upper2' [simp]: contributor ‹Stefan Berghofer›
  x AND y  z if 0  y y  z for x y :: int
  using that AND_upper1' [of y z x] by (simp add: ac_simps)

lemma AND_upper2'' [simp]: contributor ‹Stefan Berghofer›
  x AND y < z if 0  y y < z for x y :: int
  using that AND_upper1'' [of y z x] by (simp add: ac_simps)

lemma plus_and_or:
  (x AND y) + (x OR y) = x + y for x y :: int
proof (induction x arbitrary: y rule: int_bit_induct)
  case zero
  then show ?case
    by simp
next
  case minus
  then show ?case
    by simp
next
  case (even x)
  from even.IH [of y div 2]
  show ?case
    by (auto simp add: and_int.rec [of _ y] or_int.rec [of _ y] elim: oddE)
next
  case (odd x)
  from odd.IH [of y div 2]
  show ?case
    by (auto simp add: and_int.rec [of _ y] or_int.rec [of _ y] elim: oddE)
qed

lemma push_bit_minus_one:
  push_bit n (- 1 :: int) = - (2 ^ n)
  by (simp add: push_bit_eq_mult)

lemma minus_1_div_exp_eq_int:
  - 1 div (2 :: int) ^ n = - 1
  by (induction n) (use div_exp_eq [symmetric, of - 1 :: int 1] in simp_all add: ac_simps)

lemma drop_bit_minus_one [simp]:
  drop_bit n (- 1 :: int) = - 1
  by (simp add: drop_bit_eq_div minus_1_div_exp_eq_int)

lemma take_bit_minus:
  take_bit n (- take_bit n k) = take_bit n (- k)
    for k :: int
  by (simp add: take_bit_eq_mod mod_minus_eq)

lemma take_bit_diff:
  take_bit n (take_bit n k - take_bit n l) = take_bit n (k - l)
    for k l :: int
  by (simp add: take_bit_eq_mod mod_diff_eq)

lemma (in ring_1) of_nat_nat_take_bit_eq [simp]:
  of_nat (nat (take_bit n k)) = of_int (take_bit n k)
  by simp

lemma take_bit_minus_small_eq:
  take_bit n (- k) = 2 ^ n - k if 0 < k k  2 ^ n for k :: int
proof -
  define m where m = nat k
  with that have k = int m and 0 < m and m  2 ^ n
    by simp_all
  have (2 ^ n - m) mod 2 ^ n = 2 ^ n - m
    using 0 < m by simp
  then have int ((2 ^ n - m) mod 2 ^ n) = int (2 ^ n - m)
    by simp
  then have (2 ^ n - int m) mod 2 ^ n = 2 ^ n - int m
    using m  2 ^ n by (simp only: of_nat_mod of_nat_diff) simp
  with k = int m have (2 ^ n - k) mod 2 ^ n = 2 ^ n - k
    by simp
  then show ?thesis
    by (simp add: take_bit_eq_mod)
qed

lemma push_bit_nonnegative_int_iff [simp]:
  push_bit n k  0  k  0 for k :: int
  by (simp add: push_bit_eq_mult zero_le_mult_iff power_le_zero_eq)

lemma push_bit_negative_int_iff [simp]:
  push_bit n k < 0  k < 0 for k :: int
  by (subst Not_eq_iff [symmetric]) (simp add: not_less)

lemma drop_bit_nonnegative_int_iff [simp]:
  drop_bit n k  0  k  0 for k :: int
  by (induction n) (auto simp add: drop_bit_Suc drop_bit_half)

lemma drop_bit_negative_int_iff [simp]:
  drop_bit n k < 0  k < 0 for k :: int
  by (subst Not_eq_iff [symmetric]) (simp add: not_less)

lemma set_bit_nonnegative_int_iff [simp]:
  set_bit n k  0  k  0 for k :: int
  by (simp add: set_bit_eq_or)

lemma set_bit_negative_int_iff [simp]:
  set_bit n k < 0  k < 0 for k :: int
  by (simp add: set_bit_eq_or)

lemma unset_bit_nonnegative_int_iff [simp]:
  unset_bit n k  0  k  0 for k :: int
  by (simp add: unset_bit_eq_and_not)

lemma unset_bit_negative_int_iff [simp]:
  unset_bit n k < 0  k < 0 for k :: int
  by (simp add: unset_bit_eq_and_not)

lemma flip_bit_nonnegative_int_iff [simp]:
  flip_bit n k  0  k  0 for k :: int
  by (simp add: flip_bit_eq_xor)

lemma flip_bit_negative_int_iff [simp]:
  flip_bit n k < 0  k < 0 for k :: int
  by (simp add: flip_bit_eq_xor)

lemma set_bit_greater_eq:
  set_bit n k  k for k :: int
  by (simp add: set_bit_eq_or or_greater_eq)

lemma unset_bit_less_eq:
  unset_bit n k  k for k :: int
  by (simp add: unset_bit_eq_and_not and_less_eq)

lemma and_int_unfold:
  k AND l = (if k = 0  l = 0 then 0 else if k = - 1 then l else if l = - 1 then k
    else (k mod 2) * (l mod 2) + 2 * ((k div 2) AND (l div 2))) for k l :: int
  by (auto simp add: and_int.rec [of k l] zmult_eq_1_iff elim: oddE)

lemma or_int_unfold:
  k OR l = (if k = - 1  l = - 1 then - 1 else if k = 0 then l else if l = 0 then k
    else max (k mod 2) (l mod 2) + 2 * ((k div 2) OR (l div 2))) for k l :: int
  by (auto simp add: or_int.rec [of k l] elim: oddE)

lemma xor_int_unfold:
  k XOR l = (if k = - 1 then NOT l else if l = - 1 then NOT k else if k = 0 then l else if l = 0 then k
    else ¦k mod 2 - l mod 2¦ + 2 * ((k div 2) XOR (l div 2))) for k l :: int
  by (auto simp add: xor_int.rec [of k l] not_int_def elim!: oddE)

lemma bit_minus_int_iff:
  bit (- k) n  bit (NOT (k - 1)) n for k :: int
  by (simp add: bit_simps)

lemma take_bit_incr_eq:
  take_bit n (k + 1) = 1 + take_bit n k if take_bit n k  2 ^ n - 1 for k :: int
proof -
  from that have 2 ^ n  k mod 2 ^ n + 1
    by (simp add: take_bit_eq_mod)
  moreover have k mod 2 ^ n < 2 ^ n
    by simp
  ultimately have *: k mod 2 ^ n + 1 < 2 ^ n
    by linarith
  have (k + 1) mod 2 ^ n = (k mod 2 ^ n + 1) mod 2 ^ n
    by (simp add: mod_simps)
  also have  = k mod 2 ^ n + 1
    using * by (simp add: zmod_trivial_iff)
  finally have (k + 1) mod 2 ^ n = k mod 2 ^ n + 1 .
  then show ?thesis
    by (simp add: take_bit_eq_mod)
qed

lemma take_bit_decr_eq:
  take_bit n (k - 1) = take_bit n k - 1 if take_bit n k  0 for k :: int
proof -
  from that have k mod 2 ^ n  0
    by (simp add: take_bit_eq_mod)
  moreover have k mod 2 ^ n  0 k mod 2 ^ n < 2 ^ n
    by simp_all
  ultimately have *: k mod 2 ^ n > 0
    by linarith
  have (k - 1) mod 2 ^ n = (k mod 2 ^ n - 1) mod 2 ^ n
    by (simp add: mod_simps)
  also have  = k mod 2 ^ n - 1
    by (simp add: zmod_trivial_iff)
      (use k mod 2 ^ n < 2 ^ n * in linarith)
  finally have (k - 1) mod 2 ^ n = k mod 2 ^ n - 1 .
  then show ?thesis
    by (simp add: take_bit_eq_mod)
qed

lemma take_bit_int_greater_eq:
  k + 2 ^ n  take_bit n k if k < 0 for k :: int
proof -
  have k + 2 ^ n  take_bit n (k + 2 ^ n)
  proof (cases k > - (2 ^ n))
    case False
    then have k + 2 ^ n  0
      by simp
    also note take_bit_nonnegative
    finally show ?thesis .
  next
    case True
    with that have 0  k + 2 ^ n and k + 2 ^ n < 2 ^ n
      by simp_all
    then show ?thesis
      by (simp only: take_bit_eq_mod mod_pos_pos_trivial)
  qed
  then show ?thesis
    by (simp add: take_bit_eq_mod)
qed

lemma take_bit_int_less_eq:
  take_bit n k  k - 2 ^ n if 2 ^ n  k and n > 0 for k :: int
  using that zmod_le_nonneg_dividend [of k - 2 ^ n 2 ^ n]
  by (simp add: take_bit_eq_mod)

lemma take_bit_int_less_eq_self_iff:
  take_bit n k  k  0  k (is ?P  ?Q) for k :: int
proof
  assume ?P
  show ?Q
  proof (rule ccontr)
    assume ¬ 0  k
    then have k < 0
      by simp
    with ?P
    have take_bit n k < 0
      by (rule le_less_trans)
    then show False
      by simp
  qed
next
  assume ?Q
  then show ?P
    by (simp add: take_bit_eq_mod zmod_le_nonneg_dividend)
qed

lemma take_bit_int_less_self_iff:
  take_bit n k < k  2 ^ n  k for k :: int
  by (auto simp add: less_le take_bit_int_less_eq_self_iff take_bit_int_eq_self_iff
    intro: order_trans [of 0 2 ^ n k])

lemma take_bit_int_greater_self_iff:
  k < take_bit n k  k < 0 for k :: int
  using take_bit_int_less_eq_self_iff [of n k] by auto

lemma take_bit_int_greater_eq_self_iff:
  k  take_bit n k  k < 2 ^ n for k :: int
  by (auto simp add: le_less take_bit_int_greater_self_iff take_bit_int_eq_self_iff
    dest: sym not_sym intro: less_trans [of k 0 2 ^ n])

lemma take_bit_tightened_less_eq_int:
  take_bit m k  take_bit n k if m  n for k :: int
proof -
  have take_bit m (take_bit n k)  take_bit n k
    by (simp only: take_bit_int_less_eq_self_iff take_bit_nonnegative)
  with that show ?thesis
    by simp
qed

lemma not_exp_less_eq_0_int [simp]:
  ¬ 2 ^ n  (0::int)
  by (simp add: power_le_zero_eq)

lemma int_bit_bound:
  fixes k :: int
  obtains n where m. n  m  bit k m  bit k n
    and n > 0  bit k (n - 1)  bit k n
proof -
  obtain q where *: m. q  m  bit k m  bit k q
  proof (cases k  0)
    case True
    moreover from power_gt_expt [of 2 nat k]
    have nat k < 2 ^ nat k
      by simp
    then have int (nat k) < int (2 ^ nat k)
      by (simp only: of_nat_less_iff)
    ultimately have *: k div 2 ^ nat k = 0
      by simp
    show thesis
    proof (rule that [of nat k])
      fix m
      assume nat k  m
      then show bit k m  bit k (nat k)
        by (auto simp add: * bit_iff_odd power_add zdiv_zmult2_eq dest!: le_Suc_ex)
    qed
  next
    case False
    moreover from power_gt_expt [of 2 nat (- k)]
    have nat (- k) < 2 ^ nat (- k)
      by simp
    then have int (nat (- k)) < int (2 ^ nat (- k))
      by (simp only: of_nat_less_iff)
    ultimately have - k div - (2 ^ nat (- k)) = - 1
      by (subst div_pos_neg_trivial) simp_all
    then have *: k div 2 ^ nat (- k) = - 1
      by simp
    show thesis
    proof (rule that [of nat (- k)])
      fix m
      assume nat (- k)  m
      then show bit k m  bit k (nat (- k))
        by (auto simp add: * bit_iff_odd power_add zdiv_zmult2_eq minus_1_div_exp_eq_int dest!: le_Suc_ex)
    qed
  qed
  show thesis
  proof (cases m. bit k m  bit k q)
    case True
    then have bit k 0  bit k q
      by blast
    with True that [of 0] show thesis
      by simp
  next
    case False
    then obtain r where **: bit k r  bit k q
      by blast
    have r < q
      by (rule ccontr) (use * [of r] ** in simp)
    define N where N = {n. n < q  bit k n  bit k q}
    moreover have finite N r  N
      using ** N_def r < q by auto
    moreover define n where n = Suc (Max N)
    ultimately have m. n  m  bit k m  bit k n
      apply auto
         apply (metis (full_types, lifting) "*" Max_ge_iff Suc_n_not_le_n finite N all_not_in_conv mem_Collect_eq not_le)
        apply (metis "*" Max_ge Suc_n_not_le_n finite N linorder_not_less mem_Collect_eq)
        apply (metis "*" Max_ge Suc_n_not_le_n finite N linorder_not_less mem_Collect_eq)
      apply (metis (full_types, lifting) "*" Max_ge_iff Suc_n_not_le_n finite N all_not_in_conv mem_Collect_eq not_le)
      done
    have bit k (Max N)  bit k n
      by (metis (mono_tags, lifting) "*" Max_in N_def m. n  m  bit k m = bit k n finite N r  N empty_iff le_cases mem_Collect_eq)
    show thesis apply (rule that [of n])
      using m. n  m  bit k m = bit k n apply blast
      using bit k (Max N)  bit k n n_def by auto
  qed
qed


subsection ‹Instance typnat

instantiation nat :: semiring_bit_operations
begin

definition and_nat :: nat  nat  nat
  where m AND n = nat (int m AND int n) for m n :: nat

definition or_nat :: nat  nat  nat
  where m OR n = nat (int m OR int n) for m n :: nat

definition xor_nat :: nat  nat  nat
  where m XOR n = nat (int m XOR int n) for m n :: nat

definition mask_nat :: nat  nat
  where mask n = (2 :: nat) ^ n - 1

definition push_bit_nat :: nat  nat  nat
  where push_bit_nat n m = m * 2 ^ n

definition drop_bit_nat :: nat  nat  nat
  where drop_bit_nat n m = m div 2 ^ n

definition take_bit_nat :: nat  nat  nat
  where take_bit_nat n m = m mod 2 ^ n

definition set_bit_nat :: nat  nat  nat
  where set_bit m n = n OR push_bit m 1 for m n :: nat

definition unset_bit_nat :: nat  nat  nat
  where unset_bit m n = (n OR push_bit m 1) XOR push_bit m 1 for m n :: nat

definition flip_bit_nat :: nat  nat  nat
  where flip_bit m n = n XOR push_bit m 1 for m n :: nat

instance proof
  fix m n :: nat
  show m AND n = of_bool (odd m  odd n) + 2 * (m div 2 AND n div 2)
    by (simp add: and_nat_def and_rec [of int m int n] nat_add_distrib of_nat_div)
  show m OR n = of_bool (odd m  odd n) + 2 * (m div 2 OR n div 2)
    by (simp add: or_nat_def or_rec [of int m int n] nat_add_distrib of_nat_div)
  show m XOR n = of_bool (odd m  odd n) + 2 * (m div 2 XOR n div 2)
    by (simp add: xor_nat_def xor_rec [of int m int n] nat_add_distrib of_nat_div)
qed (simp_all add: mask_nat_def set_bit_nat_def unset_bit_nat_def flip_bit_nat_def
  push_bit_nat_def drop_bit_nat_def take_bit_nat_def)

end

instance nat :: linordered_euclidean_semiring_bit_operations ..

context semiring_bit_operations
begin

lemma push_bit_of_nat:
  push_bit n (of_nat m) = of_nat (push_bit n m)
  by (simp add: push_bit_eq_mult Bit_Operations.push_bit_eq_mult)

lemma of_nat_push_bit:
  of_nat (push_bit m n) = push_bit m (of_nat n)
  by (simp add: push_bit_eq_mult Bit_Operations.push_bit_eq_mult)

lemma take_bit_of_nat:
  take_bit n (of_nat m) = of_nat (take_bit n m)
  by (rule bit_eqI) (simp add: bit_take_bit_iff Bit_Operations.bit_take_bit_iff bit_of_nat_iff)

lemma of_nat_take_bit:
  of_nat (take_bit n m) = take_bit n (of_nat m)
  by (rule bit_eqI) (simp add: bit_take_bit_iff Bit_Operations.bit_take_bit_iff bit_of_nat_iff)

lemma of_nat_and_eq:
  of_nat (m AND n) = of_nat m AND of_nat n
  by (rule bit_eqI) (simp add: bit_of_nat_iff bit_and_iff Bit_Operations.bit_and_iff)

lemma of_nat_or_eq:
  of_nat (m OR n) = of_nat m OR of_nat n
  by (rule bit_eqI) (simp add: bit_of_nat_iff bit_or_iff Bit_Operations.bit_or_iff)

lemma of_nat_xor_eq:
  of_nat (m XOR n) = of_nat m XOR of_nat n
  by (rule bit_eqI) (simp add: bit_of_nat_iff bit_xor_iff Bit_Operations.bit_xor_iff)

lemma of_nat_mask_eq:
  of_nat (mask n) = mask n
  by (induction n) (simp_all add: mask_Suc_double Bit_Operations.mask_Suc_double of_nat_or_eq)

end

context linordered_euclidean_semiring_bit_operations
begin

lemma drop_bit_of_nat:
  "drop_bit n (of_nat m) = of_nat (drop_bit n m)"
  by (simp add: drop_bit_eq_div Bit_Operations.drop_bit_eq_div of_nat_div [of m "2 ^ n"])

lemma of_nat_drop_bit:
  of_nat (drop_bit m n) = drop_bit m (of_nat n)
  by (simp add: drop_bit_eq_div Bit_Operations.drop_bit_eq_div of_nat_div)

end

lemma take_bit_nat_less_exp [simp]:
  take_bit n m < 2 ^ n for n m :: nat
  by (simp add: take_bit_eq_mod)

lemma take_bit_nat_eq_self_iff:
  take_bit n m = m  m < 2 ^ n (is ?P  ?Q) for n m :: nat
proof
  assume ?P
  moreover note take_bit_nat_less_exp [of n m]
  ultimately show ?Q
    by simp
next
  assume ?Q
  then show ?P
    by (simp add: take_bit_eq_mod)
qed

lemma take_bit_nat_eq_self:
  take_bit n m = m if m < 2 ^ n for m n :: nat
  using that by (simp add: take_bit_nat_eq_self_iff)

lemma take_bit_nat_less_eq_self [simp]:
  take_bit n m  m for n m :: nat
  by (simp add: take_bit_eq_mod)

lemma take_bit_nat_less_self_iff:
  take_bit n m < m  2 ^ n  m (is ?P  ?Q) for m n :: nat
proof
  assume ?P
  then have take_bit n m  m
    by simp
  then show ?Q
    by (simp add: take_bit_nat_eq_self_iff)
next
  have take_bit n m < 2 ^ n
    by (fact take_bit_nat_less_exp)
  also assume ?Q
  finally show ?P .
qed

lemma Suc_0_and_eq [simp]:
  Suc 0 AND n = n mod 2
  using one_and_eq [of n] by simp

lemma and_Suc_0_eq [simp]:
  n AND Suc 0 = n mod 2
  using and_one_eq [of n] by simp

lemma Suc_0_or_eq:
  Suc 0 OR n = n + of_bool (even n)
  using one_or_eq [of n] by simp

lemma or_Suc_0_eq:
  n OR Suc 0 = n + of_bool (even n)
  using or_one_eq [of n] by simp

lemma Suc_0_xor_eq:
  Suc 0 XOR n = n + of_bool (even n) - of_bool (odd n)
  using one_xor_eq [of n] by simp

lemma xor_Suc_0_eq:
  n XOR Suc 0 = n + of_bool (even n) - of_bool (odd n)
  using xor_one_eq [of n] by simp

lemma and_nat_unfold [code]:
  m AND n = (if m = 0  n = 0 then 0 else (m mod 2) * (n mod 2) + 2 * ((m div 2) AND (n div 2)))
    for m n :: nat
  by (auto simp add: and_rec [of m n] elim: oddE)

lemma or_nat_unfold [code]:
  m OR n = (if m = 0 then n else if n = 0 then m
    else max (m mod 2) (n mod 2) + 2 * ((m div 2) OR (n div 2))) for m n :: nat
  by (auto simp add: or_rec [of m n] elim: oddE)

lemma xor_nat_unfold [code]:
  m XOR n = (if m = 0 then n else if n = 0 then m
    else (m mod 2 + n mod 2) mod 2 + 2 * ((m div 2) XOR (n div 2))) for m n :: nat
  by (auto simp add: xor_rec [of m n] elim!: oddE)

lemma [code]:
  unset_bit 0 m = 2 * (m div 2)
  unset_bit (Suc n) m = m mod 2 + 2 * unset_bit n (m div 2) for m n :: nat
  by (simp_all add: unset_bit_Suc)

lemma push_bit_of_Suc_0 [simp]:
  push_bit n (Suc 0) = 2 ^ n
  using push_bit_of_1 [where ?'a = nat] by simp

lemma take_bit_of_Suc_0 [simp]:
  take_bit n (Suc 0) = of_bool (0 < n)
  using take_bit_of_1 [where ?'a = nat] by simp

lemma drop_bit_of_Suc_0 [simp]:
  drop_bit n (Suc 0) = of_bool (n = 0)
  using drop_bit_of_1 [where ?'a = nat] by simp

lemma Suc_mask_eq_exp:
  Suc (mask n) = 2 ^ n
  by (simp add: mask_eq_exp_minus_1)

lemma less_eq_mask:
  n  mask n
  by (simp add: mask_eq_exp_minus_1 le_diff_conv2)
    (metis Suc_mask_eq_exp diff_Suc_1 diff_le_diff_pow diff_zero le_refl not_less_eq_eq power_0)

lemma less_mask:
  n < mask n if Suc 0 < n
proof -
  define m where m = n - 2
  with that have *: n = m + 2
    by simp
  have Suc (Suc (Suc m)) < 4 * 2 ^ m
    by (induction m) simp_all
  then have Suc (m + 2) < Suc (mask (m + 2))
    by (simp add: Suc_mask_eq_exp)
  then have m + 2 < mask (m + 2)
    by (simp add: less_le)
  with * show ?thesis
    by simp
qed

lemma mask_nat_less_exp [simp]:
  (mask n :: nat) < 2 ^ n
  by (simp add: mask_eq_exp_minus_1)

lemma mask_nat_positive_iff [simp]:
  (0::nat) < mask n  0 < n
proof (cases n = 0)
  case True
  then show ?thesis
    by simp
next
  case False
  then have 0 < n
    by simp
  then have (0::nat) < mask n
    using less_eq_mask [of n] by (rule order_less_le_trans)
  with 0 < n show ?thesis
    by simp
qed

lemma take_bit_tightened_less_eq_nat:
  take_bit m q  take_bit n q if m  n for q :: nat
proof -
  have take_bit m (take_bit n q)  take_bit n q
    by (rule take_bit_nat_less_eq_self)
  with that show ?thesis
    by simp
qed

lemma push_bit_nat_eq:
  push_bit n (nat k) = nat (push_bit n k)
  by (cases k  0) (simp_all add: push_bit_eq_mult nat_mult_distrib not_le mult_nonneg_nonpos2)

lemma drop_bit_nat_eq:
  drop_bit n (nat k) = nat (drop_bit n k)
  apply (cases k  0)
   apply (simp_all add: drop_bit_eq_div nat_div_distrib nat_power_eq not_le)
  apply (simp add: divide_int_def)
  done

lemma take_bit_nat_eq:
  take_bit n (nat k) = nat (take_bit n k) if k  0
  using that by (simp add: take_bit_eq_mod nat_mod_distrib nat_power_eq)

lemma nat_take_bit_eq:
  nat (take_bit n k) = take_bit n (nat k)
  if k  0
  using that by (simp add: take_bit_eq_mod nat_mod_distrib nat_power_eq)

lemma nat_mask_eq:
  nat (mask n) = mask n
  by (simp add: nat_eq_iff of_nat_mask_eq)


subsection ‹Symbolic computations on numeral expressions›

context semiring_bits
begin

lemma not_bit_numeral_Bit0_0 [simp]:
  ¬ bit (numeral (Num.Bit0 m)) 0
  by (simp add: bit_0)

lemma bit_numeral_Bit1_0 [simp]:
  bit (numeral (Num.Bit1 m)) 0
  by (simp add: bit_0)

lemma bit_numeral_Bit0_iff:
  bit (numeral (num.Bit0 m)) n
     possible_bit TYPE('a) n  n > 0  bit (numeral m) (n - 1)
  by (simp only: numeral_Bit0_eq_double [of m] bit_simps) simp

lemma bit_numeral_Bit1_Suc_iff:
  bit (numeral (num.Bit1 m)) (Suc n)
     possible_bit TYPE('a) (Suc n)  bit (numeral m) n
  using even_bit_succ_iff [of 2 * numeral m Suc n]
  by (simp only: numeral_Bit1_eq_inc_double [of m] bit_simps) simp

end

context ring_bit_operations
begin

lemma not_bit_minus_numeral_Bit0_0 [simp]:
  ¬ bit (- numeral (Num.Bit0 m)) 0
  by (simp add: bit_0)

lemma bit_minus_numeral_Bit1_0 [simp]:
  bit (- numeral (Num.Bit1 m)) 0
  by (simp add: bit_0)

lemma bit_minus_numeral_Bit0_Suc_iff:
  bit (- numeral (num.Bit0 m)) (Suc n)
     possible_bit TYPE('a) (Suc n)  bit (- numeral m) n
  by (simp only: numeral_Bit0_eq_double [of m] minus_mult_right bit_simps) auto

lemma bit_minus_numeral_Bit1_Suc_iff:
  bit (- numeral (num.Bit1 m)) (Suc n)
     possible_bit TYPE('a) (Suc n)  ¬ bit (numeral m) n
  by (simp only: numeral_Bit1_eq_inc_double [of m] minus_add_distrib minus_mult_right add_uminus_conv_diff
    bit_decr_iff bit_double_iff)
    auto

lemma bit_numeral_BitM_0 [simp]:
  bit (numeral (Num.BitM m)) 0
  by (simp only: numeral_BitM bit_decr_iff not_bit_minus_numeral_Bit0_0) simp

lemma bit_numeral_BitM_Suc_iff:
  bit (numeral (Num.BitM m)) (Suc n)  possible_bit TYPE('a) (Suc n)  ¬ bit (- numeral m) n
  by (simp_all only: numeral_BitM bit_decr_iff bit_minus_numeral_Bit0_Suc_iff) auto

end

context linordered_euclidean_semiring_bit_operations
begin

lemma bit_numeral_iff:
  bit (numeral m) n  bit (numeral m :: nat) n
  using bit_of_nat_iff_bit [of numeral m n] by simp

lemma bit_numeral_Bit0_Suc_iff [simp]:
  bit (numeral (Num.Bit0 m)) (Suc n)  bit (numeral m) n
  by (simp add: bit_Suc numeral_Bit0_div_2)

lemma bit_numeral_Bit1_Suc_iff [simp]:
  bit (numeral (Num.Bit1 m)) (Suc n)  bit (numeral m) n
  by (simp add: bit_Suc numeral_Bit1_div_2)

lemma bit_numeral_rec:
  bit (numeral (Num.Bit0 w)) n  (case n of 0  False | Suc m  bit (numeral w) m)
  bit (numeral (Num.Bit1 w)) n  (case n of 0  True | Suc m  bit (numeral w) m)
  by (cases n; simp add: bit_0)+

lemma bit_numeral_simps [simp]:
  ¬ bit 1 (numeral n)
  bit (numeral (Num.Bit0 w)) (numeral n)  bit (numeral w) (pred_numeral n)
  bit (numeral (Num.Bit1 w)) (numeral n)  bit (numeral w) (pred_numeral n)
  by (simp_all add: bit_1_iff numeral_eq_Suc)

lemma and_numerals [simp]:
  1 AND numeral (Num.Bit0 y) = 0
  1 AND numeral (Num.Bit1 y) = 1
  numeral (Num.Bit0 x) AND numeral (Num.Bit0 y) = 2 * (numeral x AND numeral y)
  numeral (Num.Bit0 x) AND numeral (Num.Bit1 y) = 2 * (numeral x AND numeral y)
  numeral (Num.Bit0 x) AND 1 = 0
  numeral (Num.Bit1 x) AND numeral (Num.Bit0 y) = 2 * (numeral x AND numeral y)
  numeral (Num.Bit1 x) AND numeral (Num.Bit1 y) = 1 + 2 * (numeral x AND numeral y)
  numeral (Num.Bit1 x) AND 1 = 1
  by (simp_all add: bit_eq_iff) (simp_all add: bit_0 bit_simps bit_Suc bit_numeral_rec split: nat.splits)

lemma or_numerals [simp]:
  1 OR numeral (Num.Bit0 y) = numeral (Num.Bit1 y)
  1 OR numeral (Num.Bit1 y) = numeral (Num.Bit1 y)
  numeral (Num.Bit0 x) OR numeral (Num.Bit0 y) = 2 * (numeral x OR numeral y)
  numeral (Num.Bit0 x) OR numeral (Num.Bit1 y) = 1 + 2 * (numeral x OR numeral y)
  numeral (Num.Bit0 x) OR 1 = numeral (Num.Bit1 x)
  numeral (Num.Bit1 x) OR numeral (Num.Bit0 y) = 1 + 2 * (numeral x OR numeral y)
  numeral (Num.Bit1 x) OR numeral (Num.Bit1 y) = 1 + 2 * (numeral x OR numeral y)
  numeral (Num.Bit1 x) OR 1 = numeral (Num.Bit1 x)
  by (simp_all add: bit_eq_iff) (simp_all add: bit_0 bit_simps bit_Suc bit_numeral_rec split: nat.splits)

lemma xor_numerals [simp]:
  1 XOR numeral (Num.Bit0 y) = numeral (Num.Bit1 y)
  1 XOR numeral (Num.Bit1 y) = numeral (Num.Bit0 y)
  numeral (Num.Bit0 x) XOR numeral (Num.Bit0 y) = 2 * (numeral x XOR numeral y)
  numeral (Num.Bit0 x) XOR numeral (Num.Bit1 y) = 1 + 2 * (numeral x XOR numeral y)
  numeral (Num.Bit0 x) XOR 1 = numeral (Num.Bit1 x)
  numeral (Num.Bit1 x) XOR numeral (Num.Bit0 y) = 1 + 2 * (numeral x XOR numeral y)
  numeral (Num.Bit1 x) XOR numeral (Num.Bit1 y) = 2 * (numeral x XOR numeral y)
  numeral (Num.Bit1 x) XOR 1 = numeral (Num.Bit0 x)
  by (simp_all add: bit_eq_iff) (simp_all add: bit_0 bit_simps bit_Suc bit_numeral_rec split: nat.splits)

end

lemma drop_bit_Suc_minus_bit0 [simp]:
  drop_bit (Suc n) (- numeral (Num.Bit0 k)) = drop_bit n (- numeral k :: int)
  by (simp add: drop_bit_Suc numeral_Bit0_div_2)

lemma drop_bit_Suc_minus_bit1 [simp]:
  drop_bit (Suc n) (- numeral (Num.Bit1 k)) = drop_bit n (- numeral (Num.inc k) :: int)
  by (simp add: drop_bit_Suc numeral_Bit1_div_2 add_One)

lemma drop_bit_numeral_minus_bit0 [simp]:
  drop_bit (numeral l) (- numeral (Num.Bit0 k)) = drop_bit (pred_numeral l) (- numeral k :: int)
  by (simp add: numeral_eq_Suc numeral_Bit0_div_2)

lemma drop_bit_numeral_minus_bit1 [simp]:
  drop_bit (numeral l) (- numeral (Num.Bit1 k)) = drop_bit (pred_numeral l) (- numeral (Num.inc k) :: int)
  by (simp add: numeral_eq_Suc numeral_Bit1_div_2)

lemma take_bit_Suc_minus_bit0:
  take_bit (Suc n) (- numeral (Num.Bit0 k)) = take_bit n (- numeral k) * (2 :: int)
  by (simp add: take_bit_Suc numeral_Bit0_div_2)

lemma take_bit_Suc_minus_bit1:
  take_bit (Suc n) (- numeral (Num.Bit1 k)) = take_bit n (- numeral (Num.inc k)) * 2 + (1 :: int)
  by (simp add: take_bit_Suc numeral_Bit1_div_2 add_One)

lemma take_bit_numeral_minus_bit0:
  take_bit (numeral l) (- numeral (Num.Bit0 k)) = take_bit (pred_numeral l) (- numeral k) * (2 :: int)
  by (simp add: numeral_eq_Suc numeral_Bit0_div_2 take_bit_Suc_minus_bit0)

lemma take_bit_numeral_minus_bit1:
  take_bit (numeral l) (- numeral (Num.Bit1 k)) = take_bit (pred_numeral l) (- numeral (Num.inc k)) * 2 + (1 :: int)
  by (simp add: numeral_eq_Suc numeral_Bit1_div_2 take_bit_Suc_minus_bit1)

lemma and_nat_numerals [simp]:
  Suc 0 AND numeral (Num.Bit0 y) = 0
  Suc 0 AND numeral (Num.Bit1 y) = 1
  numeral (Num.Bit0 x) AND Suc 0 = 0
  numeral (Num.Bit1 x) AND Suc 0 = 1
  by (simp_all only: and_numerals flip: One_nat_def)

lemma or_nat_numerals [simp]:
  Suc 0 OR numeral (Num.Bit0 y) = numeral (Num.Bit1 y)
  Suc 0 OR numeral (Num.Bit1 y) = numeral (Num.Bit1 y)
  numeral (Num.Bit0 x) OR Suc 0 = numeral (Num.Bit1 x)
  numeral (Num.Bit1 x) OR Suc 0 = numeral (Num.Bit1 x)
  by (simp_all only: or_numerals flip: One_nat_def)

lemma xor_nat_numerals [simp]:
  Suc 0 XOR numeral (Num.Bit0 y) = numeral (Num.Bit1 y)
  Suc 0 XOR numeral (Num.Bit1 y) = numeral (Num.Bit0 y)
  numeral (Num.Bit0 x) XOR Suc 0 = numeral (Num.Bit1 x)
  numeral (Num.Bit1 x) XOR Suc 0 = numeral (Num.Bit0 x)
  by (simp_all only: xor_numerals flip: One_nat_def)

context ring_bit_operations
begin

lemma minus_numeral_inc_eq:
  - numeral (Num.inc n) = NOT (numeral n)
  by (simp add: not_eq_complement sub_inc_One_eq add_One)

lemma sub_one_eq_not_neg:
  Num.sub n num.One = NOT (- numeral n)
  by (simp add: not_eq_complement)

lemma minus_numeral_eq_not_sub_one:
  - numeral n = NOT (Num.sub n num.One)
  by (simp add: not_eq_complement)

lemma not_numeral_eq [simp]:
  NOT (numeral n) = - numeral (Num.inc n)
  by (simp add: minus_numeral_inc_eq)

lemma not_minus_numeral_eq [simp]:
  NOT (- numeral n) = Num.sub n num.One
  by (simp add: sub_one_eq_not_neg)

lemma minus_not_numeral_eq [simp]:
  - (NOT (numeral n)) = numeral (Num.inc n)
  by simp

lemma not_numeral_BitM_eq:
  NOT (numeral (Num.BitM n)) =  - numeral (num.Bit0 n)
  by (simp add: inc_BitM_eq)

lemma not_numeral_Bit0_eq:
  NOT (numeral (Num.Bit0 n)) =  - numeral (num.Bit1 n)
  by simp

end

lemma bit_minus_numeral_int [simp]:
  bit (- numeral (num.Bit0 w) :: int) (numeral n)  bit (- numeral w :: int) (pred_numeral n)
  bit (- numeral (num.Bit1 w) :: int) (numeral n)  ¬ bit (numeral w :: int) (pred_numeral n)
  by (simp_all add: bit_minus_iff bit_not_iff numeral_eq_Suc bit_Suc add_One sub_inc_One_eq)

lemma bit_minus_numeral_Bit0_Suc_iff [simp]:
  bit (- numeral (num.Bit0 w) :: int) (Suc n)  bit (- numeral w :: int) n
  by (simp add: bit_Suc)

lemma bit_minus_numeral_Bit1_Suc_iff [simp]:
  bit (- numeral (num.Bit1 w) :: int) (Suc n)  ¬ bit (numeral w :: int) n
  by (simp add: bit_Suc add_One flip: bit_not_int_iff)

lemma and_not_numerals:
  1 AND NOT 1 = (0 :: int)
  1 AND NOT (numeral (Num.Bit0 n)) = (1 :: int)
  1 AND NOT (numeral (Num.Bit1 n)) = (0 :: int)
  numeral (Num.Bit0 m) AND NOT (1 :: int) = numeral (Num.Bit0 m)
  numeral (Num.Bit0 m) AND NOT (numeral (Num.Bit0 n)) = (2 :: int) * (numeral m AND NOT (numeral n))
  numeral (Num.Bit0 m) AND NOT (numeral (Num.Bit1 n)) = (2 :: int) * (numeral m AND NOT (numeral n))
  numeral (Num.Bit1 m) AND NOT (1 :: int) = numeral (Num.Bit0 m)
  numeral (Num.Bit1 m) AND NOT (numeral (Num.Bit0 n)) = 1 + (2 :: int) * (numeral m AND NOT (numeral n))
  numeral (Num.Bit1 m) AND NOT (numeral (Num.Bit1 n)) = (2 :: int) * (numeral m AND NOT (numeral n))
  by (simp_all add: bit_eq_iff) (auto simp add: bit_0 bit_simps bit_Suc bit_numeral_rec BitM_inc_eq sub_inc_One_eq split: nat.split)

fun and_not_num :: num  num  num option contributor ‹Andreas Lochbihler›
where
  and_not_num num.One num.One = None
| and_not_num num.One (num.Bit0 n) = Some num.One
| and_not_num num.One (num.Bit1 n) = None
| and_not_num (num.Bit0 m) num.One = Some (num.Bit0 m)
| and_not_num (num.Bit0 m) (num.Bit0 n) = map_option num.Bit0 (and_not_num m n)
| and_not_num (num.Bit0 m) (num.Bit1 n) = map_option num.Bit0 (and_not_num m n)
| and_not_num (num.Bit1 m) num.One = Some (num.Bit0 m)
| and_not_num (num.Bit1 m) (num.Bit0 n) = (case and_not_num m n of None  Some num.One | Some n'  Some (num.Bit1 n'))
| and_not_num (num.Bit1 m) (num.Bit1 n) = map_option num.Bit0 (and_not_num m n)

lemma int_numeral_and_not_num:
  numeral m AND NOT (numeral n) = (case and_not_num m n of None  0 :: int | Some n'  numeral n')
  by (induction m n rule: and_not_num.induct) (simp_all del: not_numeral_eq not_one_eq add: and_not_numerals split: option.splits)

lemma int_numeral_not_and_num:
  NOT (numeral m) AND numeral n = (case and_not_num n m of None  0 :: int | Some n'  numeral n')
  using int_numeral_and_not_num [of n m] by (simp add: ac_simps)

lemma and_not_num_eq_None_iff:
  and_not_num m n = None  numeral m AND NOT (numeral n) = (0 :: int)
  by (simp del: not_numeral_eq add: int_numeral_and_not_num split: option.split)

lemma and_not_num_eq_Some_iff:
  and_not_num m n = Some q  numeral m AND NOT (numeral n) = (numeral q :: int)
  by (simp del: not_numeral_eq add: int_numeral_and_not_num split: option.split)

lemma and_minus_numerals [simp]:
  1 AND - (numeral (num.Bit0 n)) = (0::int)
  1 AND - (numeral (num.Bit1 n)) = (1::int)
  numeral m AND - (numeral (num.Bit0 n)) = (case and_not_num m (Num.BitM n) of None  0 :: int | Some n'  numeral n')
  numeral m AND - (numeral (num.Bit1 n)) = (case and_not_num m (Num.Bit0 n) of None  0 :: int | Some n'  numeral n')
  - (numeral (num.Bit0 n)) AND 1 = (0::int)
  - (numeral (num.Bit1 n)) AND 1 = (1::int)
  - (numeral (num.Bit0 n)) AND numeral m = (case and_not_num m (Num.BitM n) of None  0 :: int | Some n'  numeral n')
  - (numeral (num.Bit1 n)) AND numeral m = (case and_not_num m (Num.Bit0 n) of None  0 :: int | Some n'  numeral n')
  by (simp_all del: not_numeral_eq add: ac_simps
    and_not_numerals one_and_eq not_numeral_BitM_eq not_numeral_Bit0_eq and_not_num_eq_None_iff and_not_num_eq_Some_iff split: option.split)

lemma and_minus_minus_numerals [simp]:
  - (numeral m :: int) AND - (numeral n :: int) = NOT ((numeral m - 1) OR (numeral n - 1))
  by (simp add: minus_numeral_eq_not_sub_one)

lemma or_not_numerals:
  1 OR NOT 1 = NOT (0 :: int)
  1 OR NOT (numeral (Num.Bit0 n)) = NOT (numeral (Num.Bit0 n) :: int)
  1 OR NOT (numeral (Num.Bit1 n)) = NOT (numeral (Num.Bit0 n) :: int)
  numeral (Num.Bit0 m) OR NOT (1 :: int) = NOT (1 :: int)
  numeral (Num.Bit0 m) OR NOT (numeral (Num.Bit0 n)) = 1 + (2 :: int) * (numeral m OR NOT (numeral n))
  numeral (Num.Bit0 m) OR NOT (numeral (Num.Bit1 n)) = (2 :: int) * (numeral m OR NOT (numeral n))
  numeral (Num.Bit1 m) OR NOT (1 :: int) = NOT (0 :: int)
  numeral (Num.Bit1 m) OR NOT (numeral (Num.Bit0 n)) = 1 + (2 :: int) * (numeral m OR NOT (numeral n))
  numeral (Num.Bit1 m) OR NOT (numeral (Num.Bit1 n)) = 1 + (2 :: int) * (numeral m OR NOT (numeral n))
  by (simp_all add: bit_eq_iff)
    (auto simp add: bit_0 bit_simps bit_Suc bit_numeral_rec sub_inc_One_eq split: nat.split)

fun or_not_num_neg :: num  num  num contributor ‹Andreas Lochbihler›
where
  or_not_num_neg num.One num.One = num.One
| or_not_num_neg num.One (num.Bit0 m) = num.Bit1 m
| or_not_num_neg num.One (num.Bit1 m) = num.Bit1 m
| or_not_num_neg (num.Bit0 n) num.One = num.Bit0 num.One
| or_not_num_neg (num.Bit0 n) (num.Bit0 m) = Num.BitM (or_not_num_neg n m)
| or_not_num_neg (num.Bit0 n) (num.Bit1 m) = num.Bit0 (or_not_num_neg n m)
| or_not_num_neg (num.Bit1 n) num.One = num.One
| or_not_num_neg (num.Bit1 n) (num.Bit0 m) = Num.BitM (or_not_num_neg n m)
| or_not_num_neg (num.Bit1 n) (num.Bit1 m) = Num.BitM (or_not_num_neg n m)

lemma int_numeral_or_not_num_neg:
  numeral m OR NOT (numeral n :: int) = - numeral (or_not_num_neg m n)
  by (induction m n rule: or_not_num_neg.induct) (simp_all del: not_numeral_eq not_one_eq add: or_not_numerals, simp_all)

lemma int_numeral_not_or_num_neg:
  NOT (numeral m) OR (numeral n :: int) = - numeral (or_not_num_neg n m)
  using int_numeral_or_not_num_neg [of n m] by (simp add: ac_simps)

lemma numeral_or_not_num_eq:
  numeral (or_not_num_neg m n) = - (numeral m OR NOT (numeral n :: int))
  using int_numeral_or_not_num_neg [of m n] by simp

lemma or_minus_numerals [simp]:
  1 OR - (numeral (num.Bit0 n)) = - (numeral (or_not_num_neg num.One (Num.BitM n)) :: int)
  1 OR - (numeral (num.Bit1 n)) = - (numeral (num.Bit1 n) :: int)
  numeral m OR - (numeral (num.Bit0 n)) = - (numeral (or_not_num_neg m (Num.BitM n)) :: int)
  numeral m OR - (numeral (num.Bit1 n)) = - (numeral (or_not_num_neg m (Num.Bit0 n)) :: int)
  - (numeral (num.Bit0 n)) OR 1 = - (numeral (or_not_num_neg num.One (Num.BitM n)) :: int)
  - (numeral (num.Bit1 n)) OR 1 = - (numeral (num.Bit1 n) :: int)
  - (numeral (num.Bit0 n)) OR numeral m = - (numeral (or_not_num_neg m (Num.BitM n)) :: int)
  - (numeral (num.Bit1 n)) OR numeral m = - (numeral (or_not_num_neg m (Num.Bit0 n)) :: int)
  by (simp_all only: or.commute [of _ 1] or.commute [of _ numeral m]
    minus_numeral_eq_not_sub_one or_not_numerals
    numeral_or_not_num_eq arith_simps minus_minus numeral_One)

lemma or_minus_minus_numerals [simp]:
  - (numeral m :: int) OR - (numeral n :: int) = NOT ((numeral m - 1) AND (numeral n - 1))
  by (simp add: minus_numeral_eq_not_sub_one)

lemma xor_minus_numerals [simp]:
  - numeral n XOR k = NOT (neg_numeral_class.sub n num.One XOR k)
  k XOR - numeral n = NOT (k XOR (neg_numeral_class.sub n num.One)) for k :: int
  by (simp_all add: minus_numeral_eq_not_sub_one)

definition take_bit_num :: nat  num  num option
  where take_bit_num n m =
    (if take_bit n (numeral m :: nat) = 0 then None else Some (num_of_nat (take_bit n (numeral m :: nat))))

lemma take_bit_num_simps:
  take_bit_num 0 m = None
  take_bit_num (Suc n) Num.One =
    Some Num.One
  take_bit_num (Suc n) (Num.Bit0 m) =
    (case take_bit_num n m of None  None | Some q  Some (Num.Bit0 q))
  take_bit_num (Suc n) (Num.Bit1 m) =
    Some (case take_bit_num n m of None  Num.One | Some q  Num.Bit1 q)
  take_bit_num (numeral r) Num.One =
    Some Num.One
  take_bit_num (numeral r) (Num.Bit0 m) =
    (case take_bit_num (pred_numeral r) m of None  None | Some q  Some (Num.Bit0 q))
  take_bit_num (numeral r) (Num.Bit1 m) =
    Some (case take_bit_num (pred_numeral r) m of None  Num.One | Some q  Num.Bit1 q)
  by (auto simp add: take_bit_num_def ac_simps mult_2 num_of_nat_double
    take_bit_Suc_bit0 take_bit_Suc_bit1 take_bit_numeral_bit0 take_bit_numeral_bit1)

lemma take_bit_num_code [code]:
  ― ‹Ocaml-style pattern matching is more robust wrt. different representations of typnat
  take_bit_num n m = (case (n, m)
   of (0, _)  None
    | (Suc n, Num.One)  Some Num.One
    | (Suc n, Num.Bit0 m)  (case take_bit_num n m of None  None | Some q  Some (Num.Bit0 q))
    | (Suc n, Num.Bit1 m)  Some (case take_bit_num n m of None  Num.One | Some q  Num.Bit1 q))
  by (cases n; cases m) (simp_all add: take_bit_num_simps)

context semiring_bit_operations
begin

lemma take_bit_num_eq_None_imp:
  take_bit m (numeral n) = 0 if take_bit_num m n = None
proof -
  from that have take_bit m (numeral n :: nat) = 0
    by (simp add: take_bit_num_def split: if_splits)
  then have of_nat (take_bit m (numeral n)) = of_nat 0
    by simp
  then show ?thesis
    by (simp add: of_nat_take_bit)
qed

lemma take_bit_num_eq_Some_imp:
  take_bit m (numeral n) = numeral q if take_bit_num m n = Some q
proof -
  from that have take_bit m (numeral n :: nat) = numeral q
    by (auto simp add: take_bit_num_def Num.numeral_num_of_nat_unfold split: if_splits)
  then have of_nat (take_bit m (numeral n)) = of_nat (numeral q)
    by simp
  then show ?thesis
    by (simp add: of_nat_take_bit)
qed

lemma take_bit_numeral_numeral:
  take_bit (numeral m) (numeral n) =
    (case take_bit_num (numeral m) n of None  0 | Some q  numeral q)
  by (auto split: option.split dest: take_bit_num_eq_None_imp take_bit_num_eq_Some_imp)

end

lemma take_bit_numeral_minus_numeral_int:
  take_bit (numeral m) (- numeral n :: int) =
    (case take_bit_num (numeral m) n of None  0 | Some q  take_bit (numeral m) (2 ^ numeral m - numeral q)) (is ?lhs = ?rhs)
proof (cases take_bit_num (numeral m) n)
  case None
  then show ?thesis
    by (auto dest: take_bit_num_eq_None_imp [where ?'a = int] simp add: take_bit_eq_0_iff)
next
  case (Some q)
  then have q: take_bit (numeral m) (numeral n :: int) = numeral q
    by (auto dest: take_bit_num_eq_Some_imp)
  let ?T = take_bit (numeral m) :: int  int
  have *: ?T (2 ^ numeral m) = ?T (?T 0)
    by (simp add: take_bit_eq_0_iff)
  have ?lhs = ?T (0 - numeral n)
    by simp
  also have  = ?T (?T (?T 0) - ?T (?T (numeral n)))
    by (simp only: take_bit_diff)
  also have  = ?T (2 ^ numeral m - ?T (numeral n))
    by (simp only: take_bit_diff flip: *)
  also have  = ?rhs
    by (simp add: q Some)
  finally show ?thesis .
qed

declare take_bit_num_simps [simp]
  take_bit_numeral_numeral [simp]
  take_bit_numeral_minus_numeral_int [simp]


subsection ‹Symbolic computations for code generation›

lemma bit_int_code [code]:
  bit (0::int)               n       False
  bit (Int.Neg num.One)      n       True
  bit (Int.Pos num.One)      0       True
  bit (Int.Pos (num.Bit0 m)) 0       False
  bit (Int.Pos (num.Bit1 m)) 0       True
  bit (Int.Neg (num.Bit0 m)) 0       False
  bit (Int.Neg (num.Bit1 m)) 0       True
  bit (Int.Pos num.One)      (Suc n)  False
  bit (Int.Pos (num.Bit0 m)) (Suc n)  bit (Int.Pos m) n
  bit (Int.Pos (num.Bit1 m)) (Suc n)  bit (Int.Pos m) n
  bit (Int.Neg (num.Bit0 m)) (Suc n)  bit (Int.Neg m) n
  bit (Int.Neg (num.Bit1 m)) (Suc n)  bit (Int.Neg (Num.inc m)) n
  by (simp_all add: Num.add_One bit_0 bit_Suc)

lemma not_int_code [code]:
  NOT (0 :: int) = - 1
  NOT (Int.Pos n) = Int.Neg (Num.inc n)
  NOT (Int.Neg n) = Num.sub n num.One
  by (simp_all add: Num.add_One not_int_def)

fun and_num :: num  num  num option contributor ‹Andreas Lochbihler›
where
  and_num num.One num.One = Some num.One
| and_num num.One (num.Bit0 n) = None
| and_num num.One (num.Bit1 n) = Some num.One
| and_num (num.Bit0 m) num.One = None
| and_num (num.Bit0 m) (num.Bit0 n) = map_option num.Bit0 (and_num m n)
| and_num (num.Bit0 m) (num.Bit1 n) = map_option num.Bit0 (and_num m n)
| and_num (num.Bit1 m) num.One = Some num.One
| and_num (num.Bit1 m) (num.Bit0 n) = map_option num.Bit0 (and_num m n)
| and_num (num.Bit1 m) (num.Bit1 n) = (case and_num m n of None  Some num.One | Some n'  Some (num.Bit1 n'))

context linordered_euclidean_semiring_bit_operations
begin

lemma numeral_and_num:
  numeral m AND numeral n = (case and_num m n of None  0 | Some n'  numeral n')
  by (induction m n rule: and_num.induct) (simp_all add: split: option.split)

lemma and_num_eq_None_iff:
  and_num m n = None  numeral m AND numeral n = 0
  by (simp add: numeral_and_num split: option.split)

lemma and_num_eq_Some_iff:
  and_num m n = Some q  numeral m AND numeral n = numeral q
  by (simp add: numeral_and_num split: option.split)

end

lemma and_int_code [code]:
  fixes i j :: int shows
  0 AND j = 0
  i AND 0 = 0
  Int.Pos n AND Int.Pos m = (case and_num n m of None  0 | Some n'  Int.Pos n')
  Int.Neg n AND Int.Neg m = NOT (Num.sub n num.One OR Num.sub m num.One)
  Int.Pos n AND Int.Neg num.One = Int.Pos n
  Int.Pos n AND Int.Neg (num.Bit0 m) = Num.sub (or_not_num_neg (Num.BitM m) n) num.One
  Int.Pos n AND Int.Neg (num.Bit1 m) = Num.sub (or_not_num_neg (num.Bit0 m) n) num.One
  Int.Neg num.One AND Int.Pos m = Int.Pos m
  Int.Neg (num.Bit0 n) AND Int.Pos m = Num.sub (or_not_num_neg (Num.BitM n) m) num.One
  Int.Neg (num.Bit1 n) AND Int.Pos m = Num.sub (or_not_num_neg (num.Bit0 n) m) num.One
  apply (auto simp add: and_num_eq_None_iff [where ?'a = int] and_num_eq_Some_iff [where ?'a = int]
    split: option.split)
     apply (simp_all only: sub_one_eq_not_neg numeral_or_not_num_eq minus_minus and_not_numerals
       bit.de_Morgan_disj bit.double_compl and_not_num_eq_None_iff and_not_num_eq_Some_iff ac_simps)
  done

context linordered_euclidean_semiring_bit_operations
begin

fun or_num :: num  num  num contributor ‹Andreas Lochbihler›
where
  or_num num.One num.One = num.One
| or_num num.One (num.Bit0 n) = num.Bit1 n
| or_num num.One (num.Bit1 n) = num.Bit1 n
| or_num (num.Bit0 m) num.One = num.Bit1 m
| or_num (num.Bit0 m) (num.Bit0 n) = num.Bit0 (or_num m n)
| or_num (num.Bit0 m) (num.Bit1 n) = num.Bit1 (or_num m n)
| or_num (num.Bit1 m) num.One = num.Bit1 m
| or_num (num.Bit1 m) (num.Bit0 n) = num.Bit1 (or_num m n)
| or_num (num.Bit1 m) (num.Bit1 n) = num.Bit1 (or_num m n)

lemma numeral_or_num:
  numeral m OR numeral n = numeral (or_num m n)
  by (induction m n rule: or_num.induct) simp_all

lemma numeral_or_num_eq:
  numeral (or_num m n) = numeral m OR numeral n
  by (simp add: numeral_or_num)

end

lemma or_int_code [code]:
  fixes i j :: int shows
  0 OR j = j
  i OR 0 = i
  Int.Pos n OR Int.Pos m = Int.Pos (or_num n m)
  Int.Neg n OR Int.Neg m = NOT (Num.sub n num.One AND Num.sub m num.One)
  Int.Pos n OR Int.Neg num.One = Int.Neg num.One
  Int.Pos n OR Int.Neg (num.Bit0 m) = (case and_not_num (Num.BitM m) n of None  -1 | Some n'  Int.Neg (Num.inc n'))
  Int.Pos n OR Int.Neg (num.Bit1 m) = (case and_not_num (num.Bit0 m) n of None  -1 | Some n'  Int.Neg (Num.inc n'))
  Int.Neg num.One OR Int.Pos m = Int.Neg num.One
  Int.Neg (num.Bit0 n) OR Int.Pos m = (case and_not_num (Num.BitM n) m of None  -1 | Some n'  Int.Neg (Num.inc n'))
  Int.Neg (num.Bit1 n) OR Int.Pos m = (case and_not_num (num.Bit0 n) m of None  -1 | Some n'  Int.Neg (Num.inc n'))
  apply (auto simp add: numeral_or_num_eq split: option.splits)
         apply (simp_all only: and_not_num_eq_None_iff and_not_num_eq_Some_iff and_not_numerals
           numeral_or_not_num_eq or_eq_not_not_and bit.double_compl ac_simps flip: numeral_eq_iff [where ?'a = int])
         apply simp_all
  done

fun xor_num :: num  num  num option contributor ‹Andreas Lochbihler›
where
  xor_num num.One num.One = None
| xor_num num.One (num.Bit0 n) = Some (num.Bit1 n)
| xor_num num.One (num.Bit1 n) = Some (num.Bit0 n)
| xor_num (num.Bit0 m) num.One = Some (num.Bit1 m)
| xor_num (num.Bit0 m) (num.Bit0 n) = map_option num.Bit0 (xor_num m n)
| xor_num (num.Bit0 m) (num.Bit1 n) = Some (case xor_num m n of None  num.One | Some n'  num.Bit1 n')
| xor_num (num.Bit1 m) num.One = Some (num.Bit0 m)
| xor_num (num.Bit1 m) (num.Bit0 n) = Some (case xor_num m n of None  num.One | Some n'  num.Bit1 n')
| xor_num (num.Bit1 m) (num.Bit1 n) = map_option num.Bit0 (xor_num m n)

context linordered_euclidean_semiring_bit_operations
begin

lemma numeral_xor_num:
  numeral m XOR numeral n = (case xor_num m n of None  0 | Some n'  numeral n')
  by (induction m n rule: xor_num.induct) (simp_all split: option.split)

lemma xor_num_eq_None_iff:
  xor_num m n = None  numeral m XOR numeral n = 0
  by (simp add: numeral_xor_num split: option.split)

lemma xor_num_eq_Some_iff:
  xor_num m n = Some q  numeral m XOR numeral n = numeral q
  by (simp add: numeral_xor_num split: option.split)

end

lemma xor_int_code [code]:
  fixes i j :: int shows
  0 XOR j = j
  i XOR 0 = i
  Int.Pos n XOR Int.Pos m = (case xor_num n m of None  0 | Some n'  Int.Pos n')
  Int.Neg n XOR Int.Neg m = Num.sub n num.One XOR Num.sub m num.One
  Int.Neg n XOR Int.Pos m = NOT (Num.sub n num.One XOR Int.Pos m)
  Int.Pos n XOR Int.Neg m = NOT (Int.Pos n XOR Num.sub m num.One)
  by (simp_all add: xor_num_eq_None_iff [where ?'a = int] xor_num_eq_Some_iff [where ?'a = int] split: option.split)

lemma push_bit_int_code [code]:
  push_bit 0 i = i
  push_bit (Suc n) i = push_bit n (Int.dup i)
  by (simp_all add: ac_simps)

lemma drop_bit_int_code [code]:
  fixes i :: int shows
  drop_bit 0 i = i
  drop_bit (Suc n) 0 = (0 :: int)
  drop_bit (Suc n) (Int.Pos num.One) = 0
  drop_bit (Suc n) (Int.Pos (num.Bit0 m)) = drop_bit n (Int.Pos m)
  drop_bit (Suc n) (Int.Pos (num.Bit1 m)) = drop_bit n (Int.Pos m)
  drop_bit (Suc n) (Int.Neg num.One) = - 1
  drop_bit (Suc n) (Int.Neg (num.Bit0 m)) = drop_bit n (Int.Neg m)
  drop_bit (Suc n) (Int.Neg (num.Bit1 m)) = drop_bit n (Int.Neg (Num.inc m))
  by (simp_all add: drop_bit_Suc add_One)


subsection ‹More properties›

lemma take_bit_eq_mask_iff:
  take_bit n k = mask n  take_bit n (k + 1) = 0 (is ?P  ?Q)
  for k :: int
proof
  assume ?P
  then have take_bit n (take_bit n k + take_bit n 1) = 0
    by (simp add: mask_eq_exp_minus_1 take_bit_eq_0_iff)
  then show ?Q
    by (simp only: take_bit_add)
next
  assume ?Q
  then have take_bit n (k + 1) - 1 = - 1
    by simp
  then have take_bit n (take_bit n (k + 1) - 1) = take_bit n (- 1)
    by simp
  moreover have take_bit n (take_bit n (k + 1) - 1) = take_bit n k
    by (simp add: take_bit_eq_mod mod_simps)
  ultimately show ?P
    by simp
qed

lemma take_bit_eq_mask_iff_exp_dvd:
  take_bit n k = mask n  2 ^ n dvd k + 1
  for k :: int
  by (simp add: take_bit_eq_mask_iff flip: take_bit_eq_0_iff)


subsection ‹Bit concatenation›

definition concat_bit :: nat  int  int  int
  where concat_bit n k l = take_bit n k OR push_bit n l

lemma bit_concat_bit_iff [bit_simps]:
  bit (concat_bit m k l) n  n < m  bit k n  m  n  bit l (n - m)
  by (simp add: concat_bit_def bit_or_iff bit_and_iff bit_take_bit_iff bit_push_bit_iff ac_simps)

lemma concat_bit_eq:
  concat_bit n k l = take_bit n k + push_bit n l
proof -
  have take_bit n k AND push_bit n l = 0
    by (simp add: bit_eq_iff bit_simps)
  then show ?thesis
    by (simp add: bit_eq_iff bit_simps disjunctive_add_eq_or)
qed

lemma concat_bit_0 [simp]:
  concat_bit 0 k l = l
  by (simp add: concat_bit_def)

lemma concat_bit_Suc:
  concat_bit (Suc n) k l = k mod 2 + 2 * concat_bit n (k div 2) l
  by (simp add: concat_bit_eq take_bit_Suc push_bit_double)

lemma concat_bit_of_zero_1 [simp]:
  concat_bit n 0 l = push_bit n l
  by (simp add: concat_bit_def)

lemma concat_bit_of_zero_2 [simp]:
  concat_bit n k 0 = take_bit n k
  by (simp add: concat_bit_def take_bit_eq_mask)

lemma concat_bit_nonnegative_iff [simp]:
  concat_bit n k l  0  l  0
  by (simp add: concat_bit_def)

lemma concat_bit_negative_iff [simp]:
  concat_bit n k l < 0  l < 0
  by (simp add: concat_bit_def)

lemma concat_bit_assoc:
  concat_bit n k (concat_bit m l r) = concat_bit (m + n) (concat_bit n k l) r
  by (rule bit_eqI) (auto simp add: bit_concat_bit_iff ac_simps)

lemma concat_bit_assoc_sym:
  concat_bit m (concat_bit n k l) r = concat_bit (min m n) k (concat_bit (m - n) l r)
  by (rule bit_eqI) (auto simp add: bit_concat_bit_iff ac_simps min_def)

lemma concat_bit_eq_iff:
  concat_bit n k l = concat_bit n r s
     take_bit n k = take_bit n r  l = s (is ?P  ?Q)
proof
  assume ?Q
  then show ?P
    by (simp add: concat_bit_def)
next
  assume ?P
  then have *: bit (concat_bit n k l) m = bit (concat_bit n r s) m for m
    by (simp add: bit_eq_iff)
  have take_bit n k = take_bit n r
  proof (rule bit_eqI)
    fix m
    from * [of m]
    show bit (take_bit n k) m  bit (take_bit n r) m
      by (auto simp add: bit_take_bit_iff bit_concat_bit_iff)
  qed
  moreover have push_bit n l = push_bit n s
  proof (rule bit_eqI)
    fix m
    from * [of m]
    show bit (push_bit n l) m  bit (push_bit n s) m
      by (auto simp add: bit_push_bit_iff bit_concat_bit_iff)
  qed
  then have l = s
    by (simp add: push_bit_eq_mult)
  ultimately show ?Q
    by (simp add: concat_bit_def)
qed

lemma take_bit_concat_bit_eq:
  take_bit m (concat_bit n k l) = concat_bit (min m n) k (take_bit (m - n) l)
  by (rule bit_eqI)
    (auto simp add: bit_take_bit_iff bit_concat_bit_iff min_def)

lemma concat_bit_take_bit_eq:
  concat_bit n (take_bit n b) = concat_bit n b
  by (simp add: concat_bit_def [abs_def])


subsection ‹Taking bits with sign propagation›

context ring_bit_operations
begin

definition signed_take_bit :: nat  'a  'a
  where signed_take_bit n a = take_bit n a OR (of_bool (bit a n) * NOT (mask n))

lemma signed_take_bit_eq_if_positive:
  signed_take_bit n a = take_bit n a if ¬ bit a n
  using that by (simp add: signed_take_bit_def)

lemma signed_take_bit_eq_if_negative:
  signed_take_bit n a = take_bit n a OR NOT (mask n) if bit a n
  using that by (simp add: signed_take_bit_def)

lemma even_signed_take_bit_iff:
  even (signed_take_bit m a)  even a
  by (auto simp add: bit_0 signed_take_bit_def even_or_iff even_mask_iff bit_double_iff)

lemma bit_signed_take_bit_iff [bit_simps]:
  bit (signed_take_bit m a) n  possible_bit TYPE('a) n  bit a (min m n)
  by (simp add: signed_take_bit_def bit_take_bit_iff bit_or_iff bit_not_iff bit_mask_iff min_def not_le)
    (blast dest: bit_imp_possible_bit)

lemma signed_take_bit_0 [simp]:
  signed_take_bit 0 a = - (a mod 2)
  by (simp add: bit_0 signed_take_bit_def odd_iff_mod_2_eq_one)

lemma signed_take_bit_Suc:
  signed_take_bit (Suc n) a = a mod 2 + 2 * signed_take_bit n (a div 2)
  by (simp add: bit_eq_iff bit_sum_mult_2_cases bit_simps bit_0 possible_bit_less_imp flip: bit_Suc min_Suc_Suc)

lemma signed_take_bit_of_0 [simp]:
  signed_take_bit n 0 = 0
  by (simp add: signed_take_bit_def)

lemma signed_take_bit_of_minus_1 [simp]:
  signed_take_bit n (- 1) = - 1
  by (simp add: signed_take_bit_def mask_eq_exp_minus_1 possible_bit_def)

lemma signed_take_bit_Suc_1 [simp]:
  signed_take_bit (Suc n) 1 = 1
  by (simp add: signed_take_bit_Suc)

lemma signed_take_bit_numeral_of_1 [simp]:
  signed_take_bit (numeral k) 1 = 1
  by (simp add: bit_1_iff signed_take_bit_eq_if_positive)

lemma signed_take_bit_rec:
  signed_take_bit n a = (if n = 0 then - (a mod 2) else a mod 2 + 2 * signed_take_bit (n - 1) (a div 2))
  by (cases n) (simp_all add: signed_take_bit_Suc)

lemma signed_take_bit_eq_iff_take_bit_eq:
  signed_take_bit n a = signed_take_bit n b  take_bit (Suc n) a = take_bit (Suc n) b
proof -
  have bit (signed_take_bit n a) = bit (signed_take_bit n b)  bit (take_bit (Suc n) a) = bit (take_bit (Suc n) b)
    by (simp add: fun_eq_iff bit_signed_take_bit_iff bit_take_bit_iff not_le less_Suc_eq_le min_def)
      (use bit_imp_possible_bit in fastforce)
  then show ?thesis
    by (auto simp add: fun_eq_iff intro: bit_eqI)
qed

lemma signed_take_bit_signed_take_bit [simp]:
  signed_take_bit m (signed_take_bit n a) = signed_take_bit (min m n) a
  by (auto simp add: bit_eq_iff bit_simps ac_simps)

lemma signed_take_bit_take_bit:
  signed_take_bit m (take_bit n a) = (if n  m then take_bit n else signed_take_bit m) a
  by (rule bit_eqI) (auto simp add: bit_signed_take_bit_iff min_def bit_take_bit_iff)

lemma take_bit_signed_take_bit:
  take_bit m (signed_take_bit n a) = take_bit m a if m  Suc n
  using that by (rule le_SucE; intro bit_eqI)
   (auto simp add: bit_take_bit_iff bit_signed_take_bit_iff min_def less_Suc_eq)

lemma signed_take_bit_eq_take_bit_add:
  signed_take_bit n k = take_bit (Suc n) k + NOT (mask (Suc n)) * of_bool (bit k n)
proof (cases bit k n)
  case False
  show ?thesis
    by (rule bit_eqI) (simp add: False bit_simps min_def less_Suc_eq)
next
  case True
  have signed_take_bit n k = take_bit (Suc n) k OR NOT (mask (Suc n))
    by (rule bit_eqI) (auto simp add: bit_signed_take_bit_iff min_def bit_take_bit_iff bit_or_iff bit_not_iff bit_mask_iff less_Suc_eq True)
  also have  = take_bit (Suc n) k + NOT (mask (Suc n))
    by (simp add: disjunctive_add_eq_or bit_eq_iff bit_simps)
  finally show ?thesis
    by (simp add: True)
qed

lemma signed_take_bit_eq_take_bit_minus:
  signed_take_bit n k = take_bit (Suc n) k - 2 ^ Suc n * of_bool (bit k n)
  by (simp add: signed_take_bit_eq_take_bit_add flip: minus_exp_eq_not_mask)

end

text ‹Modulus centered around 0›

lemma signed_take_bit_eq_concat_bit:
  signed_take_bit n k = concat_bit n k (- of_bool (bit k n))
  by (simp add: concat_bit_def signed_take_bit_def)

lemma signed_take_bit_add:
  signed_take_bit n (signed_take_bit n k + signed_take_bit n l) = signed_take_bit n (k + l)
  for k l :: int
proof -
  have take_bit (Suc n)
     (take_bit (Suc n) (signed_take_bit n k) +
      take_bit (Suc n) (signed_take_bit n l)) =
    take_bit (Suc n) (k + l)
    by (simp add: take_bit_signed_take_bit take_bit_add)
  then show ?thesis
    by (simp only: signed_take_bit_eq_iff_take_bit_eq take_bit_add)
qed

lemma signed_take_bit_diff:
  signed_take_bit n (signed_take_bit n k - signed_take_bit n l) = signed_take_bit n (k - l)
  for k l :: int
proof -
  have take_bit (Suc n)
     (take_bit (Suc n) (signed_take_bit n k) -
      take_bit (Suc n) (signed_take_bit n l)) =
    take_bit (Suc n) (k - l)
    by (simp add: take_bit_signed_take_bit take_bit_diff)
  then show ?thesis
    by (simp only: signed_take_bit_eq_iff_take_bit_eq take_bit_diff)
qed

lemma signed_take_bit_minus:
  signed_take_bit n (- signed_take_bit n k) = signed_take_bit n (- k)
  for k :: int
proof -
  have take_bit (Suc n)
     (- take_bit (Suc n) (signed_take_bit n k)) =
    take_bit (Suc n) (- k)
    by (simp add: take_bit_signed_take_bit take_bit_minus)
  then show ?thesis
    by (simp only: signed_take_bit_eq_iff_take_bit_eq take_bit_minus)
qed

lemma signed_take_bit_mult:
  signed_take_bit n (signed_take_bit n k * signed_take_bit n l) = signed_take_bit n (k * l)
  for k l :: int
proof -
  have take_bit (Suc n)
     (take_bit (Suc n) (signed_take_bit n k) *
      take_bit (Suc n) (signed_take_bit n l)) =
    take_bit (Suc n) (k * l)
    by (simp add: take_bit_signed_take_bit take_bit_mult)
  then show ?thesis
    by (simp only: signed_take_bit_eq_iff_take_bit_eq take_bit_mult)
qed

lemma signed_take_bit_eq_take_bit_shift:
  signed_take_bit n k = take_bit (Suc n) (k + 2 ^ n) - 2 ^ n (is ?lhs = ?rhs)
  for k :: int
proof -
  have take_bit n k AND 2 ^ n = 0
    by (rule bit_eqI) (simp add: bit_simps)
  then have *: take_bit n k OR 2 ^ n = take_bit n k + 2 ^ n
    by (simp add: disjunctive_add_eq_or)
  have take_bit n k - 2 ^ n = take_bit n k + NOT (mask n)
    by (simp add: minus_exp_eq_not_mask)
  also have  = take_bit n k OR NOT (mask n)
    by (rule disjunctive_add_eq_or) (simp add: bit_eq_iff bit_simps)
  finally have **: take_bit n k - 2 ^ n = take_bit n k OR NOT (mask n) .
  have take_bit (Suc n) (k + 2 ^ n) = take_bit (Suc n) (take_bit (Suc n) k + take_bit (Suc n) (2 ^ n))
    by (simp only: take_bit_add)
  also have take_bit (Suc n) k = 2 ^ n * of_bool (bit k n) + take_bit n k
    by (simp add: take_bit_Suc_from_most)
  finally have take_bit (Suc n) (k + 2 ^ n) = take_bit (Suc n) (2 ^ (n + of_bool (bit k n)) + take_bit n k)
    by (simp add: ac_simps)
  also have 2 ^ (n + of_bool (bit k n)) + take_bit n k = 2 ^ (n + of_bool (bit k n)) OR take_bit n k
    by (rule disjunctive_add_eq_or, rule bit_eqI) (simp add: bit_simps)
  finally show ?thesis
    using * ** by (simp add: signed_take_bit_def concat_bit_Suc min_def ac_simps)
qed

lemma signed_take_bit_nonnegative_iff [simp]:
  0  signed_take_bit n k  ¬ bit k n
  for k :: int
  by (simp add: signed_take_bit_def not_less concat_bit_def)

lemma signed_take_bit_negative_iff [simp]:
  signed_take_bit n k < 0  bit k n
  for k :: int
  by (simp add: signed_take_bit_def not_less concat_bit_def)

lemma signed_take_bit_int_greater_eq_minus_exp [simp]:
  - (2 ^ n)  signed_take_bit n k
  for k :: int
  by (simp add: signed_take_bit_eq_take_bit_shift)

lemma signed_take_bit_int_less_exp [simp]:
  signed_take_bit n k < 2 ^ n
  for k :: int
  using take_bit_int_less_exp [of Suc n]
  by (simp add: signed_take_bit_eq_take_bit_shift)

lemma signed_take_bit_int_eq_self_iff:
  signed_take_bit n k = k  - (2 ^ n)  k  k < 2 ^ n
  for k :: int
  by (auto simp add: signed_take_bit_eq_take_bit_shift take_bit_int_eq_self_iff algebra_simps)

lemma signed_take_bit_int_eq_self:
  signed_take_bit n k = k if - (2 ^ n)  k k < 2 ^ n
  for k :: int
  using that by (simp add: signed_take_bit_int_eq_self_iff)

lemma signed_take_bit_int_less_eq_self_iff:
  signed_take_bit n k  k  - (2 ^ n)  k
  for k :: int
  by (simp add: signed_take_bit_eq_take_bit_shift take_bit_int_less_eq_self_iff algebra_simps)
    linarith

lemma signed_take_bit_int_less_self_iff:
  signed_take_bit n k < k  2 ^ n  k
  for k :: int
  by (simp add: signed_take_bit_eq_take_bit_shift take_bit_int_less_self_iff algebra_simps)

lemma signed_take_bit_int_greater_self_iff:
  k < signed_take_bit n k  k < - (2 ^ n)
  for k :: int
  by (simp add: signed_take_bit_eq_take_bit_shift take_bit_int_greater_self_iff algebra_simps)
    linarith

lemma signed_take_bit_int_greater_eq_self_iff:
  k  signed_take_bit n k  k < 2 ^ n
  for k :: int
  by (simp add: signed_take_bit_eq_take_bit_shift take_bit_int_greater_eq_self_iff algebra_simps)

lemma signed_take_bit_int_greater_eq:
  k + 2 ^ Suc n  signed_take_bit n k if k < - (2 ^ n)
  for k :: int
  using that take_bit_int_greater_eq [of k + 2 ^ n Suc n]
  by (simp add: signed_take_bit_eq_take_bit_shift)

lemma signed_take_bit_int_less_eq:
  signed_take_bit n k  k - 2 ^ Suc n if k  2 ^ n
  for k :: int
  using that take_bit_int_less_eq [of Suc n k + 2 ^ n]
  by (simp add: signed_take_bit_eq_take_bit_shift)

lemma signed_take_bit_Suc_bit0 [simp]:
  signed_take_bit (Suc n) (numeral (Num.Bit0 k)) = signed_take_bit n (numeral k) * (2 :: int)
  by (simp add: signed_take_bit_Suc)

lemma signed_take_bit_Suc_bit1 [simp]:
  signed_take_bit (Suc n) (numeral (Num.Bit1 k)) = signed_take_bit n (numeral k) * 2 + (1 :: int)
  by (simp add: signed_take_bit_Suc)

lemma signed_take_bit_Suc_minus_bit0 [simp]:
  signed_take_bit (Suc n) (- numeral (Num.Bit0 k)) = signed_take_bit n (- numeral k) * (2 :: int)
  by (simp add: signed_take_bit_Suc)

lemma signed_take_bit_Suc_minus_bit1 [simp]:
  signed_take_bit (Suc n) (- numeral (Num.Bit1 k)) = signed_take_bit n (- numeral k - 1) * 2 + (1 :: int)
  by (simp add: signed_take_bit_Suc)

lemma signed_take_bit_numeral_bit0 [simp]:
  signed_take_bit (numeral l) (numeral (Num.Bit0 k)) = signed_take_bit (pred_numeral l) (numeral k) * (2 :: int)
  by (simp add: signed_take_bit_rec)

lemma signed_take_bit_numeral_bit1 [simp]:
  signed_take_bit (numeral l) (numeral (Num.Bit1 k)) = signed_take_bit (pred_numeral l) (numeral k) * 2 + (1 :: int)
  by (simp add: signed_take_bit_rec)

lemma signed_take_bit_numeral_minus_bit0 [simp]:
  signed_take_bit (numeral l) (- numeral (Num.Bit0 k)) = signed_take_bit (pred_numeral l) (- numeral k) * (2 :: int)
  by (simp add: signed_take_bit_rec)

lemma signed_take_bit_numeral_minus_bit1 [simp]:
  signed_take_bit (numeral l) (- numeral (Num.Bit1 k)) = signed_take_bit (pred_numeral l) (- numeral k - 1) * 2 + (1 :: int)
  by (simp add: signed_take_bit_rec)

lemma signed_take_bit_code [code]:
  signed_take_bit n a =
  (let l = take_bit (Suc n) a
   in if bit l n then l + push_bit (Suc n) (- 1) else l)
  by (simp add: signed_take_bit_eq_take_bit_add bit_simps)


subsection ‹Key ideas of bit operations›

text ‹
  When formalizing bit operations, it is tempting to represent
  bit values as explicit lists over a binary type. This however
  is a bad idea, mainly due to the inherent ambiguities in
  representation concerning repeating leading bits.

  Hence this approach avoids such explicit lists altogether
  following an algebraic path:

   Bit values are represented by numeric types: idealized
    unbounded bit values can be represented by type typint,
    bounded bit values by quotient types over typint.

   (A special case are idealized unbounded bit values ending
    in @{term [source] 0} which can be represented by type typnat but
    only support a restricted set of operations).

   From this idea follows that

       multiplication by term2 :: int is a bit shift to the left and

       division by term2 :: int is a bit shift to the right.

   Concerning bounded bit values, iterated shifts to the left
    may result in eliminating all bits by shifting them all
    beyond the boundary.  The property prop(2 :: int) ^ n  0
    represents that termn is ‹not› beyond that boundary.

   The projection on a single bit is then @{thm bit_iff_odd [where ?'a = int, no_vars]}.

   This leads to the most fundamental properties of bit values:

       Equality rule: @{thm bit_eqI [where ?'a = int, no_vars]}

       Induction rule: @{thm bit_induct [where ?'a = int, no_vars]}

   Typical operations are characterized as follows:

       Singleton termnth bit: term(2 :: int) ^ n

       Bit mask upto bit termn: @{thm mask_eq_exp_minus_1 [where ?'a = int, no_vars]}

       Left shift: @{thm push_bit_eq_mult [where ?'a = int, no_vars]}

       Right shift: @{thm drop_bit_eq_div [where ?'a = int, no_vars]}

       Truncation: @{thm take_bit_eq_mod [where ?'a = int, no_vars]}

       Negation: @{thm bit_not_iff [where ?'a = int, no_vars]}

       And: @{thm bit_and_iff [where ?'a = int, no_vars]}

       Or: @{thm bit_or_iff [where ?'a = int, no_vars]}

       Xor: @{thm bit_xor_iff [where ?'a = int, no_vars]}

       Set a single bit: @{thm set_bit_eq_or [where ?'a = int, no_vars]}

       Unset a single bit: @{thm unset_bit_eq_and_not [where ?'a = int, no_vars]}

       Flip a single bit: @{thm flip_bit_eq_xor [where ?'a = int, no_vars]}

       Signed truncation, or modulus centered around term0::int: @{thm signed_take_bit_def [no_vars]}

       Bit concatenation: @{thm concat_bit_def [no_vars]}

       (Bounded) conversion from and to a list of bits: @{thm horner_sum_bit_eq_take_bit [where ?'a = int, no_vars]}


subsection ‹Lemma duplicates and other›

context semiring_bits
begin

lemma exp_div_exp_eq:
  2 ^ m div 2 ^ n = of_bool (2 ^ m  0  m  n) * 2 ^ (m - n)
  apply (rule bit_eqI)
  using bit_exp_iff div_exp_eq apply (auto simp add: bit_iff_odd possible_bit_def)
  done

lemma bits_1_div_2:
  1 div 2 = 0
  by (fact half_1)

lemma bits_1_div_exp:
  1 div 2 ^ n = of_bool (n = 0)
  using div_exp_eq [of 1 1] by (cases n) simp_all

lemma exp_add_not_zero_imp:
  2 ^ m  0 and 2 ^ n  0 if 2 ^ (m + n)  0
proof -
  have ¬ (2 ^ m = 0  2 ^ n = 0)
  proof (rule notI)
    assume 2 ^ m = 0  2 ^ n = 0
    then have 2 ^ (m + n) = 0
      by (rule disjE) (simp_all add: power_add)
    with that show False ..
  qed
  then show 2 ^ m  0 and 2 ^ n  0
    by simp_all
qed

lemma
  exp_add_not_zero_imp_left: 2 ^ m  0
  and exp_add_not_zero_imp_right: 2 ^ n  0
  if 2 ^ (m + n)  0
proof -
  have ¬ (2 ^ m = 0  2 ^ n = 0)
  proof (rule notI)
    assume 2 ^ m = 0  2 ^ n = 0
    then have 2 ^ (m + n) = 0
      by (rule disjE) (simp_all add: power_add)
    with that show False ..
  qed
  then show 2 ^ m  0 and 2 ^ n  0
    by simp_all
qed

lemma exp_not_zero_imp_exp_diff_not_zero:
  2 ^ (n - m)  0 if 2 ^ n  0
proof (cases m  n)
  case True
  moreover define q where q = n - m
  ultimately have n = m + q
    by simp
  with that show ?thesis
    by (simp add: exp_add_not_zero_imp_right)
next
  case False
  with that show ?thesis
    by simp
qed

lemma exp_eq_0_imp_not_bit:
  ¬ bit a n if 2 ^ n = 0
  using that by (simp add: bit_iff_odd)

lemma bit_disjunctive_add_iff:
  bit (a + b) n  bit a n  bit b n
  if n. ¬ bit a n  ¬ bit b n
proof (cases possible_bit TYPE('a) n)
  case False
  then show ?thesis
    by (auto dest: impossible_bit)
next
  case True
  with that show ?thesis proof (induction n arbitrary: a b)
    case 0
    from "0.prems"(1) [of 0] show ?case
      by (auto simp add: bit_0)
  next
    case (Suc n)
    from Suc.prems(1) [of 0] have even: even a  even b
      by (auto simp add: bit_0)
    have bit: ¬ bit (a div 2) n  ¬ bit (b div 2) n for n
      using Suc.prems(1) [of Suc n] by (simp add: bit_Suc)
    from Suc.prems(2) have possible_bit TYPE('a) (Suc n) possible_bit TYPE('a) n
      by (simp_all add: possible_bit_less_imp)
    have a + b = (a div 2 * 2 + a mod 2) + (b div 2 * 2 + b mod 2)
      using div_mult_mod_eq [of a 2] div_mult_mod_eq [of b 2] by simp
    also have  = of_bool (odd a  odd b) + 2 * (a div 2 + b div 2)
      using even by (auto simp add: algebra_simps mod2_eq_if)
    finally have bit ((a + b) div 2) n  bit (a div 2 + b div 2) n
      using possible_bit TYPE('a) (Suc n) by simp (simp_all flip: bit_Suc add: bit_double_iff possible_bit_def)
    also have   bit (a div 2) n  bit (b div 2) n
      using bit possible_bit TYPE('a) n by (rule Suc.IH)
    finally show ?case
      by (simp add: bit_Suc)
  qed
qed

end

context semiring_bit_operations
begin

lemma even_mask_div_iff:
  even ((2 ^ m - 1) div 2 ^ n)  2 ^ n = 0  m  n
  using bit_mask_iff [of m n] by (auto simp add: mask_eq_exp_minus_1 bit_iff_odd possible_bit_def)

lemma mod_exp_eq:
  a mod 2 ^ m mod 2 ^ n = a mod 2 ^ min m n
  by (simp flip: take_bit_eq_mod add: ac_simps)

lemma mult_exp_mod_exp_eq:
  m  n  (a * 2 ^ m) mod (2 ^ n) = (a mod 2 ^ (n - m)) * 2 ^ m
  by (simp flip: push_bit_eq_mult take_bit_eq_mod add: push_bit_take_bit)

lemma div_exp_mod_exp_eq:
  a div 2 ^ n mod 2 ^ m = a mod (2 ^ (n + m)) div 2 ^ n
  by (simp flip: drop_bit_eq_div take_bit_eq_mod add: drop_bit_take_bit)

lemma even_mult_exp_div_exp_iff:
  even (a * 2 ^ m div 2 ^ n)  m > n  2 ^ n = 0  (m  n  even (a div 2 ^ (n - m)))
  by (simp flip: push_bit_eq_mult drop_bit_eq_div add: even_drop_bit_iff_not_bit bit_simps possible_bit_def) auto

lemma mod_exp_div_exp_eq_0:
  a mod 2 ^ n div 2 ^ n = 0
  by (simp flip: take_bit_eq_mod drop_bit_eq_div add: drop_bit_take_bit)

lemmas bits_one_mod_two_eq_one = one_mod_two_eq_one

lemmas set_bit_def = set_bit_eq_or

lemmas unset_bit_def = unset_bit_eq_and_not

lemmas flip_bit_def = flip_bit_eq_xor

lemma disjunctive_add:
  a + b = a OR b if n. ¬ bit a n  ¬ bit b n
  by (rule disjunctive_add_eq_or) (use that in simp add: bit_eq_iff bit_simps)

lemma even_mod_exp_div_exp_iff:
  even (a mod 2 ^ m div 2 ^ n)  m  n  even (a div 2 ^ n)
  by (auto simp add: even_drop_bit_iff_not_bit bit_simps simp flip: drop_bit_eq_div take_bit_eq_mod)

end

context ring_bit_operations
begin

lemma disjunctive_diff:
  a - b = a AND NOT b if n. bit b n  bit a n
proof -
  have NOT a + b = NOT a OR b
    by (rule disjunctive_add) (auto simp add: bit_not_iff dest: that)
  then have NOT (NOT a + b) = NOT (NOT a OR b)
    by simp
  then show ?thesis
    by (simp add: not_add_distrib)
qed

end

lemma and_nat_rec:
  m AND n = of_bool (odd m  odd n) + 2 * ((m div 2) AND (n div 2)) for m n :: nat
  by (fact and_rec)

lemma or_nat_rec:
  m OR n = of_bool (odd m  odd n) + 2 * ((m div 2) OR (n div 2)) for m n :: nat
  by (fact or_rec)

lemma xor_nat_rec:
  m XOR n = of_bool (odd m  odd n) + 2 * ((m div 2) XOR (n div 2)) for m n :: nat
  by (fact xor_rec)

lemma bit_push_bit_iff_nat:
  bit (push_bit m q) n  m  n  bit q (n - m) for q :: nat
  by (fact bit_push_bit_iff')

lemma mask_half_int:
  mask n div 2 = (mask (n - 1) :: int)
  by (fact mask_half)

lemma not_int_rec:
  NOT k = of_bool (even k) + 2 * NOT (k div 2) for k :: int
  by (fact not_rec)

lemma even_not_iff_int:
  even (NOT k)  odd k for k :: int
  by (fact even_not_iff)

lemma bit_not_int_iff':
  bit (- k - 1) n  ¬ bit k n for k :: int
  by (simp flip: not_eq_complement add: bit_simps)

lemmas and_int_rec = and_int.rec

lemma even_and_iff_int:
  even (k AND l)  even k  even l for k l :: int
  by (fact even_and_iff)

lemmas bit_and_int_iff = and_int.bit_iff

lemmas or_int_rec = or_int.rec

lemmas bit_or_int_iff = or_int.bit_iff

lemmas xor_int_rec = xor_int.rec

lemmas bit_xor_int_iff = xor_int.bit_iff

lemma drop_bit_push_bit_int:
  drop_bit m (push_bit n k) = drop_bit (m - n) (push_bit (n - m) k) for k :: int
  by (fact drop_bit_push_bit)

lemma bit_push_bit_iff_int:
  bit (push_bit m k) n  m  n  bit k (n - m) for k :: int
  by (fact bit_push_bit_iff')

no_notation
  not  (NOT)
    and "and"  (infixr AND 64)
    and or  (infixr OR  59)
    and xor  (infixr XOR 59)

bundle bit_operations_syntax
begin

notation
  not  (NOT)
    and "and"  (infixr AND 64)
    and or  (infixr OR  59)
    and xor  (infixr XOR 59)

end

end