prefer "Bits" as theory name for abstract bit operations, similar to "Orderings", "Lattices", "Groups" etc.
(*
Author: Jeremy Dawson and Gerwin Klein, NICTA
Definitions and basic theorems for bit-wise logical operations
for integers expressed using Pls, Min, BIT,
and converting them to and from lists of bools.
*)
header {* Bitwise Operations on Binary Integers *}
theory Bits_Int
imports Bits Bit_Representation
begin
subsection {* Logical operations *}
text "bit-wise logical operations on the int type"
instantiation int :: bit
begin
definition int_not_def:
"bitNOT = (\<lambda>x::int. - x - 1)"
function bitAND_int where
"bitAND_int x y =
(if x = 0 then 0 else if x = -1 then y else
(bin_rest x AND bin_rest y) BIT (bin_last x \<and> bin_last y))"
by pat_completeness simp
termination
by (relation "measure (nat o abs o fst)", simp_all add: bin_rest_def)
declare bitAND_int.simps [simp del]
definition int_or_def:
"bitOR = (\<lambda>x y::int. NOT (NOT x AND NOT y))"
definition int_xor_def:
"bitXOR = (\<lambda>x y::int. (x AND NOT y) OR (NOT x AND y))"
instance ..
end
subsubsection {* Basic simplification rules *}
lemma int_not_BIT [simp]:
"NOT (w BIT b) = (NOT w) BIT (\<not> b)"
unfolding int_not_def Bit_def by (cases b, simp_all)
lemma int_not_simps [simp]:
"NOT (0::int) = -1"
"NOT (1::int) = -2"
"NOT (- 1::int) = 0"
"NOT (numeral w::int) = - numeral (w + Num.One)"
"NOT (- numeral (Num.Bit0 w)::int) = numeral (Num.BitM w)"
"NOT (- numeral (Num.Bit1 w)::int) = numeral (Num.Bit0 w)"
unfolding int_not_def by simp_all
lemma int_not_not [simp]: "NOT (NOT (x::int)) = x"
unfolding int_not_def by simp
lemma int_and_0 [simp]: "(0::int) AND x = 0"
by (simp add: bitAND_int.simps)
lemma int_and_m1 [simp]: "(-1::int) AND x = x"
by (simp add: bitAND_int.simps)
lemma int_and_Bits [simp]:
"(x BIT b) AND (y BIT c) = (x AND y) BIT (b \<and> c)"
by (subst bitAND_int.simps, simp add: Bit_eq_0_iff Bit_eq_m1_iff)
lemma int_or_zero [simp]: "(0::int) OR x = x"
unfolding int_or_def by simp
lemma int_or_minus1 [simp]: "(-1::int) OR x = -1"
unfolding int_or_def by simp
lemma int_or_Bits [simp]:
"(x BIT b) OR (y BIT c) = (x OR y) BIT (b \<or> c)"
unfolding int_or_def by simp
lemma int_xor_zero [simp]: "(0::int) XOR x = x"
unfolding int_xor_def by simp
lemma int_xor_Bits [simp]:
"(x BIT b) XOR (y BIT c) = (x XOR y) BIT ((b \<or> c) \<and> \<not> (b \<and> c))"
unfolding int_xor_def by auto
subsubsection {* Binary destructors *}
lemma bin_rest_NOT [simp]: "bin_rest (NOT x) = NOT (bin_rest x)"
by (cases x rule: bin_exhaust, simp)
lemma bin_last_NOT [simp]: "bin_last (NOT x) \<longleftrightarrow> \<not> bin_last x"
by (cases x rule: bin_exhaust, simp)
lemma bin_rest_AND [simp]: "bin_rest (x AND y) = bin_rest x AND bin_rest y"
by (cases x rule: bin_exhaust, cases y rule: bin_exhaust, simp)
lemma bin_last_AND [simp]: "bin_last (x AND y) \<longleftrightarrow> bin_last x \<and> bin_last y"
by (cases x rule: bin_exhaust, cases y rule: bin_exhaust, simp)
lemma bin_rest_OR [simp]: "bin_rest (x OR y) = bin_rest x OR bin_rest y"
by (cases x rule: bin_exhaust, cases y rule: bin_exhaust, simp)
lemma bin_last_OR [simp]: "bin_last (x OR y) \<longleftrightarrow> bin_last x \<or> bin_last y"
by (cases x rule: bin_exhaust, cases y rule: bin_exhaust, simp)
lemma bin_rest_XOR [simp]: "bin_rest (x XOR y) = bin_rest x XOR bin_rest y"
by (cases x rule: bin_exhaust, cases y rule: bin_exhaust, simp)
lemma bin_last_XOR [simp]: "bin_last (x XOR y) \<longleftrightarrow> (bin_last x \<or> bin_last y) \<and> \<not> (bin_last x \<and> bin_last y)"
by (cases x rule: bin_exhaust, cases y rule: bin_exhaust, simp)
lemma bin_nth_ops:
"!!x y. bin_nth (x AND y) n = (bin_nth x n & bin_nth y n)"
"!!x y. bin_nth (x OR y) n = (bin_nth x n | bin_nth y n)"
"!!x y. bin_nth (x XOR y) n = (bin_nth x n ~= bin_nth y n)"
"!!x. bin_nth (NOT x) n = (~ bin_nth x n)"
by (induct n) auto
subsubsection {* Derived properties *}
lemma int_xor_minus1 [simp]: "(-1::int) XOR x = NOT x"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_xor_extra_simps [simp]:
"w XOR (0::int) = w"
"w XOR (-1::int) = NOT w"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_or_extra_simps [simp]:
"w OR (0::int) = w"
"w OR (-1::int) = -1"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_and_extra_simps [simp]:
"w AND (0::int) = 0"
"w AND (-1::int) = w"
by (auto simp add: bin_eq_iff bin_nth_ops)
(* commutativity of the above *)
lemma bin_ops_comm:
shows
int_and_comm: "!!y::int. x AND y = y AND x" and
int_or_comm: "!!y::int. x OR y = y OR x" and
int_xor_comm: "!!y::int. x XOR y = y XOR x"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bin_ops_same [simp]:
"(x::int) AND x = x"
"(x::int) OR x = x"
"(x::int) XOR x = 0"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemmas bin_log_esimps =
int_and_extra_simps int_or_extra_simps int_xor_extra_simps
int_and_0 int_and_m1 int_or_zero int_or_minus1 int_xor_zero int_xor_minus1
(* basic properties of logical (bit-wise) operations *)
lemma bbw_ao_absorb:
"!!y::int. x AND (y OR x) = x & x OR (y AND x) = x"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bbw_ao_absorbs_other:
"x AND (x OR y) = x \<and> (y AND x) OR x = (x::int)"
"(y OR x) AND x = x \<and> x OR (x AND y) = (x::int)"
"(x OR y) AND x = x \<and> (x AND y) OR x = (x::int)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemmas bbw_ao_absorbs [simp] = bbw_ao_absorb bbw_ao_absorbs_other
lemma int_xor_not:
"!!y::int. (NOT x) XOR y = NOT (x XOR y) &
x XOR (NOT y) = NOT (x XOR y)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_and_assoc:
"(x AND y) AND (z::int) = x AND (y AND z)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_or_assoc:
"(x OR y) OR (z::int) = x OR (y OR z)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_xor_assoc:
"(x XOR y) XOR (z::int) = x XOR (y XOR z)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemmas bbw_assocs = int_and_assoc int_or_assoc int_xor_assoc
(* BH: Why are these declared as simp rules??? *)
lemma bbw_lcs [simp]:
"(y::int) AND (x AND z) = x AND (y AND z)"
"(y::int) OR (x OR z) = x OR (y OR z)"
"(y::int) XOR (x XOR z) = x XOR (y XOR z)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bbw_not_dist:
"!!y::int. NOT (x OR y) = (NOT x) AND (NOT y)"
"!!y::int. NOT (x AND y) = (NOT x) OR (NOT y)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bbw_oa_dist:
"!!y z::int. (x AND y) OR z =
(x OR z) AND (y OR z)"
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bbw_ao_dist:
"!!y z::int. (x OR y) AND z =
(x AND z) OR (y AND z)"
by (auto simp add: bin_eq_iff bin_nth_ops)
(*
Why were these declared simp???
declare bin_ops_comm [simp] bbw_assocs [simp]
*)
subsubsection {* Simplification with numerals *}
text {* Cases for @{text "0"} and @{text "-1"} are already covered by
other simp rules. *}
lemma bin_rl_eqI: "\<lbrakk>bin_rest x = bin_rest y; bin_last x = bin_last y\<rbrakk> \<Longrightarrow> x = y"
by (metis (mono_tags) BIT_eq_iff bin_ex_rl bin_last_BIT bin_rest_BIT)
lemma bin_rest_neg_numeral_BitM [simp]:
"bin_rest (- numeral (Num.BitM w)) = - numeral w"
by (simp only: BIT_bin_simps [symmetric] bin_rest_BIT)
lemma bin_last_neg_numeral_BitM [simp]:
"bin_last (- numeral (Num.BitM w))"
by (simp only: BIT_bin_simps [symmetric] bin_last_BIT)
text {* FIXME: The rule sets below are very large (24 rules for each
operator). Is there a simpler way to do this? *}
lemma int_and_numerals [simp]:
"numeral (Num.Bit0 x) AND numeral (Num.Bit0 y) = (numeral x AND numeral y) BIT False"
"numeral (Num.Bit0 x) AND numeral (Num.Bit1 y) = (numeral x AND numeral y) BIT False"
"numeral (Num.Bit1 x) AND numeral (Num.Bit0 y) = (numeral x AND numeral y) BIT False"
"numeral (Num.Bit1 x) AND numeral (Num.Bit1 y) = (numeral x AND numeral y) BIT True"
"numeral (Num.Bit0 x) AND - numeral (Num.Bit0 y) = (numeral x AND - numeral y) BIT False"
"numeral (Num.Bit0 x) AND - numeral (Num.Bit1 y) = (numeral x AND - numeral (y + Num.One)) BIT False"
"numeral (Num.Bit1 x) AND - numeral (Num.Bit0 y) = (numeral x AND - numeral y) BIT False"
"numeral (Num.Bit1 x) AND - numeral (Num.Bit1 y) = (numeral x AND - numeral (y + Num.One)) BIT True"
"- numeral (Num.Bit0 x) AND numeral (Num.Bit0 y) = (- numeral x AND numeral y) BIT False"
"- numeral (Num.Bit0 x) AND numeral (Num.Bit1 y) = (- numeral x AND numeral y) BIT False"
"- numeral (Num.Bit1 x) AND numeral (Num.Bit0 y) = (- numeral (x + Num.One) AND numeral y) BIT False"
"- numeral (Num.Bit1 x) AND numeral (Num.Bit1 y) = (- numeral (x + Num.One) AND numeral y) BIT True"
"- numeral (Num.Bit0 x) AND - numeral (Num.Bit0 y) = (- numeral x AND - numeral y) BIT False"
"- numeral (Num.Bit0 x) AND - numeral (Num.Bit1 y) = (- numeral x AND - numeral (y + Num.One)) BIT False"
"- numeral (Num.Bit1 x) AND - numeral (Num.Bit0 y) = (- numeral (x + Num.One) AND - numeral y) BIT False"
"- numeral (Num.Bit1 x) AND - numeral (Num.Bit1 y) = (- numeral (x + Num.One) AND - numeral (y + Num.One)) BIT True"
"(1::int) AND numeral (Num.Bit0 y) = 0"
"(1::int) AND numeral (Num.Bit1 y) = 1"
"(1::int) AND - numeral (Num.Bit0 y) = 0"
"(1::int) AND - numeral (Num.Bit1 y) = 1"
"numeral (Num.Bit0 x) AND (1::int) = 0"
"numeral (Num.Bit1 x) AND (1::int) = 1"
"- numeral (Num.Bit0 x) AND (1::int) = 0"
"- numeral (Num.Bit1 x) AND (1::int) = 1"
by (rule bin_rl_eqI, simp, simp)+
lemma int_or_numerals [simp]:
"numeral (Num.Bit0 x) OR numeral (Num.Bit0 y) = (numeral x OR numeral y) BIT False"
"numeral (Num.Bit0 x) OR numeral (Num.Bit1 y) = (numeral x OR numeral y) BIT True"
"numeral (Num.Bit1 x) OR numeral (Num.Bit0 y) = (numeral x OR numeral y) BIT True"
"numeral (Num.Bit1 x) OR numeral (Num.Bit1 y) = (numeral x OR numeral y) BIT True"
"numeral (Num.Bit0 x) OR - numeral (Num.Bit0 y) = (numeral x OR - numeral y) BIT False"
"numeral (Num.Bit0 x) OR - numeral (Num.Bit1 y) = (numeral x OR - numeral (y + Num.One)) BIT True"
"numeral (Num.Bit1 x) OR - numeral (Num.Bit0 y) = (numeral x OR - numeral y) BIT True"
"numeral (Num.Bit1 x) OR - numeral (Num.Bit1 y) = (numeral x OR - numeral (y + Num.One)) BIT True"
"- numeral (Num.Bit0 x) OR numeral (Num.Bit0 y) = (- numeral x OR numeral y) BIT False"
"- numeral (Num.Bit0 x) OR numeral (Num.Bit1 y) = (- numeral x OR numeral y) BIT True"
"- numeral (Num.Bit1 x) OR numeral (Num.Bit0 y) = (- numeral (x + Num.One) OR numeral y) BIT True"
"- numeral (Num.Bit1 x) OR numeral (Num.Bit1 y) = (- numeral (x + Num.One) OR numeral y) BIT True"
"- numeral (Num.Bit0 x) OR - numeral (Num.Bit0 y) = (- numeral x OR - numeral y) BIT False"
"- numeral (Num.Bit0 x) OR - numeral (Num.Bit1 y) = (- numeral x OR - numeral (y + Num.One)) BIT True"
"- numeral (Num.Bit1 x) OR - numeral (Num.Bit0 y) = (- numeral (x + Num.One) OR - numeral y) BIT True"
"- numeral (Num.Bit1 x) OR - numeral (Num.Bit1 y) = (- numeral (x + Num.One) OR - numeral (y + Num.One)) BIT True"
"(1::int) OR numeral (Num.Bit0 y) = numeral (Num.Bit1 y)"
"(1::int) OR numeral (Num.Bit1 y) = numeral (Num.Bit1 y)"
"(1::int) OR - numeral (Num.Bit0 y) = - numeral (Num.BitM y)"
"(1::int) OR - numeral (Num.Bit1 y) = - numeral (Num.Bit1 y)"
"numeral (Num.Bit0 x) OR (1::int) = numeral (Num.Bit1 x)"
"numeral (Num.Bit1 x) OR (1::int) = numeral (Num.Bit1 x)"
"- numeral (Num.Bit0 x) OR (1::int) = - numeral (Num.BitM x)"
"- numeral (Num.Bit1 x) OR (1::int) = - numeral (Num.Bit1 x)"
by (rule bin_rl_eqI, simp, simp)+
lemma int_xor_numerals [simp]:
"numeral (Num.Bit0 x) XOR numeral (Num.Bit0 y) = (numeral x XOR numeral y) BIT False"
"numeral (Num.Bit0 x) XOR numeral (Num.Bit1 y) = (numeral x XOR numeral y) BIT True"
"numeral (Num.Bit1 x) XOR numeral (Num.Bit0 y) = (numeral x XOR numeral y) BIT True"
"numeral (Num.Bit1 x) XOR numeral (Num.Bit1 y) = (numeral x XOR numeral y) BIT False"
"numeral (Num.Bit0 x) XOR - numeral (Num.Bit0 y) = (numeral x XOR - numeral y) BIT False"
"numeral (Num.Bit0 x) XOR - numeral (Num.Bit1 y) = (numeral x XOR - numeral (y + Num.One)) BIT True"
"numeral (Num.Bit1 x) XOR - numeral (Num.Bit0 y) = (numeral x XOR - numeral y) BIT True"
"numeral (Num.Bit1 x) XOR - numeral (Num.Bit1 y) = (numeral x XOR - numeral (y + Num.One)) BIT False"
"- numeral (Num.Bit0 x) XOR numeral (Num.Bit0 y) = (- numeral x XOR numeral y) BIT False"
"- numeral (Num.Bit0 x) XOR numeral (Num.Bit1 y) = (- numeral x XOR numeral y) BIT True"
"- numeral (Num.Bit1 x) XOR numeral (Num.Bit0 y) = (- numeral (x + Num.One) XOR numeral y) BIT True"
"- numeral (Num.Bit1 x) XOR numeral (Num.Bit1 y) = (- numeral (x + Num.One) XOR numeral y) BIT False"
"- numeral (Num.Bit0 x) XOR - numeral (Num.Bit0 y) = (- numeral x XOR - numeral y) BIT False"
"- numeral (Num.Bit0 x) XOR - numeral (Num.Bit1 y) = (- numeral x XOR - numeral (y + Num.One)) BIT True"
"- numeral (Num.Bit1 x) XOR - numeral (Num.Bit0 y) = (- numeral (x + Num.One) XOR - numeral y) BIT True"
"- numeral (Num.Bit1 x) XOR - numeral (Num.Bit1 y) = (- numeral (x + Num.One) XOR - numeral (y + Num.One)) BIT False"
"(1::int) XOR numeral (Num.Bit0 y) = numeral (Num.Bit1 y)"
"(1::int) XOR numeral (Num.Bit1 y) = numeral (Num.Bit0 y)"
"(1::int) XOR - numeral (Num.Bit0 y) = - numeral (Num.BitM y)"
"(1::int) XOR - numeral (Num.Bit1 y) = - numeral (Num.Bit0 (y + Num.One))"
"numeral (Num.Bit0 x) XOR (1::int) = numeral (Num.Bit1 x)"
"numeral (Num.Bit1 x) XOR (1::int) = numeral (Num.Bit0 x)"
"- numeral (Num.Bit0 x) XOR (1::int) = - numeral (Num.BitM x)"
"- numeral (Num.Bit1 x) XOR (1::int) = - numeral (Num.Bit0 (x + Num.One))"
by (rule bin_rl_eqI, simp, simp)+
subsubsection {* Interactions with arithmetic *}
lemma plus_and_or [rule_format]:
"ALL y::int. (x AND y) + (x OR y) = x + y"
apply (induct x rule: bin_induct)
apply clarsimp
apply clarsimp
apply clarsimp
apply (case_tac y rule: bin_exhaust)
apply clarsimp
apply (unfold Bit_def)
apply clarsimp
apply (erule_tac x = "x" in allE)
apply simp
done
lemma le_int_or:
"bin_sign (y::int) = 0 ==> x <= x OR y"
apply (induct y arbitrary: x rule: bin_induct)
apply clarsimp
apply clarsimp
apply (case_tac x rule: bin_exhaust)
apply (case_tac b)
apply (case_tac [!] bit)
apply (auto simp: le_Bits)
done
lemmas int_and_le =
xtrans(3) [OF bbw_ao_absorbs (2) [THEN conjunct2, symmetric] le_int_or]
(* interaction between bit-wise and arithmetic *)
(* good example of bin_induction *)
lemma bin_add_not: "x + NOT x = (-1::int)"
apply (induct x rule: bin_induct)
apply clarsimp
apply clarsimp
apply (case_tac bit, auto)
done
subsubsection {* Truncating results of bit-wise operations *}
lemma bin_trunc_ao:
"!!x y. (bintrunc n x) AND (bintrunc n y) = bintrunc n (x AND y)"
"!!x y. (bintrunc n x) OR (bintrunc n y) = bintrunc n (x OR y)"
by (auto simp add: bin_eq_iff bin_nth_ops nth_bintr)
lemma bin_trunc_xor:
"!!x y. bintrunc n (bintrunc n x XOR bintrunc n y) =
bintrunc n (x XOR y)"
by (auto simp add: bin_eq_iff bin_nth_ops nth_bintr)
lemma bin_trunc_not:
"!!x. bintrunc n (NOT (bintrunc n x)) = bintrunc n (NOT x)"
by (auto simp add: bin_eq_iff bin_nth_ops nth_bintr)
(* want theorems of the form of bin_trunc_xor *)
lemma bintr_bintr_i:
"x = bintrunc n y ==> bintrunc n x = bintrunc n y"
by auto
lemmas bin_trunc_and = bin_trunc_ao(1) [THEN bintr_bintr_i]
lemmas bin_trunc_or = bin_trunc_ao(2) [THEN bintr_bintr_i]
subsection {* Setting and clearing bits *}
primrec
bin_sc :: "nat => bool => int => int"
where
Z: "bin_sc 0 b w = bin_rest w BIT b"
| Suc: "bin_sc (Suc n) b w = bin_sc n b (bin_rest w) BIT bin_last w"
(** nth bit, set/clear **)
lemma bin_nth_sc [simp]:
"bin_nth (bin_sc n b w) n \<longleftrightarrow> b"
by (induct n arbitrary: w) auto
lemma bin_sc_sc_same [simp]:
"bin_sc n c (bin_sc n b w) = bin_sc n c w"
by (induct n arbitrary: w) auto
lemma bin_sc_sc_diff:
"m ~= n ==>
bin_sc m c (bin_sc n b w) = bin_sc n b (bin_sc m c w)"
apply (induct n arbitrary: w m)
apply (case_tac [!] m)
apply auto
done
lemma bin_nth_sc_gen:
"bin_nth (bin_sc n b w) m = (if m = n then b else bin_nth w m)"
by (induct n arbitrary: w m) (case_tac [!] m, auto)
lemma bin_sc_nth [simp]:
"(bin_sc n (bin_nth w n) w) = w"
by (induct n arbitrary: w) auto
lemma bin_sign_sc [simp]:
"bin_sign (bin_sc n b w) = bin_sign w"
by (induct n arbitrary: w) auto
lemma bin_sc_bintr [simp]:
"bintrunc m (bin_sc n x (bintrunc m (w))) = bintrunc m (bin_sc n x w)"
apply (induct n arbitrary: w m)
apply (case_tac [!] w rule: bin_exhaust)
apply (case_tac [!] m, auto)
done
lemma bin_clr_le:
"bin_sc n False w <= w"
apply (induct n arbitrary: w)
apply (case_tac [!] w rule: bin_exhaust)
apply (auto simp: le_Bits)
done
lemma bin_set_ge:
"bin_sc n True w >= w"
apply (induct n arbitrary: w)
apply (case_tac [!] w rule: bin_exhaust)
apply (auto simp: le_Bits)
done
lemma bintr_bin_clr_le:
"bintrunc n (bin_sc m False w) <= bintrunc n w"
apply (induct n arbitrary: w m)
apply simp
apply (case_tac w rule: bin_exhaust)
apply (case_tac m)
apply (auto simp: le_Bits)
done
lemma bintr_bin_set_ge:
"bintrunc n (bin_sc m True w) >= bintrunc n w"
apply (induct n arbitrary: w m)
apply simp
apply (case_tac w rule: bin_exhaust)
apply (case_tac m)
apply (auto simp: le_Bits)
done
lemma bin_sc_FP [simp]: "bin_sc n False 0 = 0"
by (induct n) auto
lemma bin_sc_TM [simp]: "bin_sc n True -1 = -1"
by (induct n) auto
lemmas bin_sc_simps = bin_sc.Z bin_sc.Suc bin_sc_TM bin_sc_FP
lemma bin_sc_minus:
"0 < n ==> bin_sc (Suc (n - 1)) b w = bin_sc n b w"
by auto
lemmas bin_sc_Suc_minus =
trans [OF bin_sc_minus [symmetric] bin_sc.Suc]
lemma bin_sc_numeral [simp]:
"bin_sc (numeral k) b w =
bin_sc (pred_numeral k) b (bin_rest w) BIT bin_last w"
by (simp add: numeral_eq_Suc)
subsection {* Splitting and concatenation *}
definition bin_rcat :: "nat \<Rightarrow> int list \<Rightarrow> int"
where
"bin_rcat n = foldl (\<lambda>u v. bin_cat u n v) 0"
fun bin_rsplit_aux :: "nat \<Rightarrow> nat \<Rightarrow> int \<Rightarrow> int list \<Rightarrow> int list"
where
"bin_rsplit_aux n m c bs =
(if m = 0 | n = 0 then bs else
let (a, b) = bin_split n c
in bin_rsplit_aux n (m - n) a (b # bs))"
definition bin_rsplit :: "nat \<Rightarrow> nat \<times> int \<Rightarrow> int list"
where
"bin_rsplit n w = bin_rsplit_aux n (fst w) (snd w) []"
fun bin_rsplitl_aux :: "nat \<Rightarrow> nat \<Rightarrow> int \<Rightarrow> int list \<Rightarrow> int list"
where
"bin_rsplitl_aux n m c bs =
(if m = 0 | n = 0 then bs else
let (a, b) = bin_split (min m n) c
in bin_rsplitl_aux n (m - n) a (b # bs))"
definition bin_rsplitl :: "nat \<Rightarrow> nat \<times> int \<Rightarrow> int list"
where
"bin_rsplitl n w = bin_rsplitl_aux n (fst w) (snd w) []"
declare bin_rsplit_aux.simps [simp del]
declare bin_rsplitl_aux.simps [simp del]
lemma bin_sign_cat:
"bin_sign (bin_cat x n y) = bin_sign x"
by (induct n arbitrary: y) auto
lemma bin_cat_Suc_Bit:
"bin_cat w (Suc n) (v BIT b) = bin_cat w n v BIT b"
by auto
lemma bin_nth_cat:
"bin_nth (bin_cat x k y) n =
(if n < k then bin_nth y n else bin_nth x (n - k))"
apply (induct k arbitrary: n y)
apply clarsimp
apply (case_tac n, auto)
done
lemma bin_nth_split:
"bin_split n c = (a, b) ==>
(ALL k. bin_nth a k = bin_nth c (n + k)) &
(ALL k. bin_nth b k = (k < n & bin_nth c k))"
apply (induct n arbitrary: b c)
apply clarsimp
apply (clarsimp simp: Let_def split: prod.split_asm)
apply (case_tac k)
apply auto
done
lemma bin_cat_assoc:
"bin_cat (bin_cat x m y) n z = bin_cat x (m + n) (bin_cat y n z)"
by (induct n arbitrary: z) auto
lemma bin_cat_assoc_sym:
"bin_cat x m (bin_cat y n z) = bin_cat (bin_cat x (m - n) y) (min m n) z"
apply (induct n arbitrary: z m, clarsimp)
apply (case_tac m, auto)
done
lemma bin_cat_zero [simp]: "bin_cat 0 n w = bintrunc n w"
by (induct n arbitrary: w) auto
lemma bintr_cat1:
"bintrunc (k + n) (bin_cat a n b) = bin_cat (bintrunc k a) n b"
by (induct n arbitrary: b) auto
lemma bintr_cat: "bintrunc m (bin_cat a n b) =
bin_cat (bintrunc (m - n) a) n (bintrunc (min m n) b)"
by (rule bin_eqI) (auto simp: bin_nth_cat nth_bintr)
lemma bintr_cat_same [simp]:
"bintrunc n (bin_cat a n b) = bintrunc n b"
by (auto simp add : bintr_cat)
lemma cat_bintr [simp]:
"bin_cat a n (bintrunc n b) = bin_cat a n b"
by (induct n arbitrary: b) auto
lemma split_bintrunc:
"bin_split n c = (a, b) ==> b = bintrunc n c"
by (induct n arbitrary: b c) (auto simp: Let_def split: prod.split_asm)
lemma bin_cat_split:
"bin_split n w = (u, v) ==> w = bin_cat u n v"
by (induct n arbitrary: v w) (auto simp: Let_def split: prod.split_asm)
lemma bin_split_cat:
"bin_split n (bin_cat v n w) = (v, bintrunc n w)"
by (induct n arbitrary: w) auto
lemma bin_split_zero [simp]: "bin_split n 0 = (0, 0)"
by (induct n) auto
lemma bin_split_minus1 [simp]:
"bin_split n -1 = (-1, bintrunc n -1)"
by (induct n) auto
lemma bin_split_trunc:
"bin_split (min m n) c = (a, b) ==>
bin_split n (bintrunc m c) = (bintrunc (m - n) a, b)"
apply (induct n arbitrary: m b c, clarsimp)
apply (simp add: bin_rest_trunc Let_def split: prod.split_asm)
apply (case_tac m)
apply (auto simp: Let_def split: prod.split_asm)
done
lemma bin_split_trunc1:
"bin_split n c = (a, b) ==>
bin_split n (bintrunc m c) = (bintrunc (m - n) a, bintrunc m b)"
apply (induct n arbitrary: m b c, clarsimp)
apply (simp add: bin_rest_trunc Let_def split: prod.split_asm)
apply (case_tac m)
apply (auto simp: Let_def split: prod.split_asm)
done
lemma bin_cat_num:
"bin_cat a n b = a * 2 ^ n + bintrunc n b"
apply (induct n arbitrary: b, clarsimp)
apply (simp add: Bit_def)
done
lemma bin_split_num:
"bin_split n b = (b div 2 ^ n, b mod 2 ^ n)"
apply (induct n arbitrary: b, simp)
apply (simp add: bin_rest_def zdiv_zmult2_eq)
apply (case_tac b rule: bin_exhaust)
apply simp
apply (simp add: Bit_def mod_mult_mult1 p1mod22k)
done
subsection {* Miscellaneous lemmas *}
lemma nth_2p_bin:
"bin_nth (2 ^ n) m = (m = n)"
apply (induct n arbitrary: m)
apply clarsimp
apply safe
apply (case_tac m)
apply (auto simp: Bit_B0_2t [symmetric])
done
(* for use when simplifying with bin_nth_Bit *)
lemma ex_eq_or:
"(EX m. n = Suc m & (m = k | P m)) = (n = Suc k | (EX m. n = Suc m & P m))"
by auto
lemma power_BIT: "2 ^ (Suc n) - 1 = (2 ^ n - 1) BIT True"
unfolding Bit_B1
by (induct n) simp_all
lemma mod_BIT:
"bin BIT bit mod 2 ^ Suc n = (bin mod 2 ^ n) BIT bit"
proof -
have "bin mod 2 ^ n < 2 ^ n" by simp
then have "bin mod 2 ^ n \<le> 2 ^ n - 1" by simp
then have "2 * (bin mod 2 ^ n) \<le> 2 * (2 ^ n - 1)"
by (rule mult_left_mono) simp
then have "2 * (bin mod 2 ^ n) + 1 < 2 * 2 ^ n" by simp
then show ?thesis
by (auto simp add: Bit_def mod_mult_mult1 mod_add_left_eq [of "2 * bin"]
mod_pos_pos_trivial)
qed
lemma AND_mod:
fixes x :: int
shows "x AND 2 ^ n - 1 = x mod 2 ^ n"
proof (induct x arbitrary: n rule: bin_induct)
case 1
then show ?case
by simp
next
case 2
then show ?case
by (simp, simp add: m1mod2k)
next
case (3 bin bit)
show ?case
proof (cases n)
case 0
then show ?thesis by simp
next
case (Suc m)
with 3 show ?thesis
by (simp only: power_BIT mod_BIT int_and_Bits) simp
qed
qed
end