(* Title: HOL/Word/Bits_Int.thy
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.
*)
section \<open>Bitwise Operations on integers\<close>
theory Bits_Int
imports Misc_Auxiliary Bits
begin
subsection \<open>Implicit bit representation of \<^typ>\<open>int\<close>\<close>
abbreviation (input) bin_last :: "int \<Rightarrow> bool"
where "bin_last \<equiv> odd"
lemma bin_last_def:
"bin_last w \<longleftrightarrow> w mod 2 = 1"
by (fact odd_iff_mod_2_eq_one)
abbreviation (input) bin_rest :: "int \<Rightarrow> int"
where "bin_rest w \<equiv> w div 2"
lemma BitM_inc: "Num.BitM (Num.inc w) = Num.Bit1 w"
by (induct w) simp_all
lemma bin_last_numeral_simps [simp]:
"\<not> bin_last 0"
"bin_last 1"
"bin_last (- 1)"
"bin_last Numeral1"
"\<not> bin_last (numeral (Num.Bit0 w))"
"bin_last (numeral (Num.Bit1 w))"
"\<not> bin_last (- numeral (Num.Bit0 w))"
"bin_last (- numeral (Num.Bit1 w))"
by simp_all
lemma bin_rest_numeral_simps [simp]:
"bin_rest 0 = 0"
"bin_rest 1 = 0"
"bin_rest (- 1) = - 1"
"bin_rest Numeral1 = 0"
"bin_rest (numeral (Num.Bit0 w)) = numeral w"
"bin_rest (numeral (Num.Bit1 w)) = numeral w"
"bin_rest (- numeral (Num.Bit0 w)) = - numeral w"
"bin_rest (- numeral (Num.Bit1 w)) = - numeral (w + Num.One)"
by simp_all
lemma bin_rl_eqI: "\<lbrakk>bin_rest x = bin_rest y; bin_last x = bin_last y\<rbrakk> \<Longrightarrow> x = y"
by (auto elim: oddE)
lemma [simp]:
shows bin_rest_lt0: "bin_rest i < 0 \<longleftrightarrow> i < 0"
and bin_rest_ge_0: "bin_rest i \<ge> 0 \<longleftrightarrow> i \<ge> 0"
by auto
lemma bin_rest_gt_0 [simp]: "bin_rest x > 0 \<longleftrightarrow> x > 1"
by auto
subsection \<open>Explicit bit representation of \<^typ>\<open>int\<close>\<close>
primrec bl_to_bin_aux :: "bool list \<Rightarrow> int \<Rightarrow> int"
where
Nil: "bl_to_bin_aux [] w = w"
| Cons: "bl_to_bin_aux (b # bs) w = bl_to_bin_aux bs (of_bool b + 2 * w)"
definition bl_to_bin :: "bool list \<Rightarrow> int"
where "bl_to_bin bs = bl_to_bin_aux bs 0"
primrec bin_to_bl_aux :: "nat \<Rightarrow> int \<Rightarrow> bool list \<Rightarrow> bool list"
where
Z: "bin_to_bl_aux 0 w bl = bl"
| Suc: "bin_to_bl_aux (Suc n) w bl = bin_to_bl_aux n (bin_rest w) ((bin_last w) # bl)"
definition bin_to_bl :: "nat \<Rightarrow> int \<Rightarrow> bool list"
where "bin_to_bl n w = bin_to_bl_aux n w []"
lemma bin_to_bl_aux_zero_minus_simp [simp]:
"0 < n \<Longrightarrow> bin_to_bl_aux n 0 bl = bin_to_bl_aux (n - 1) 0 (False # bl)"
by (cases n) auto
lemma bin_to_bl_aux_minus1_minus_simp [simp]:
"0 < n \<Longrightarrow> bin_to_bl_aux n (- 1) bl = bin_to_bl_aux (n - 1) (- 1) (True # bl)"
by (cases n) auto
lemma bin_to_bl_aux_one_minus_simp [simp]:
"0 < n \<Longrightarrow> bin_to_bl_aux n 1 bl = bin_to_bl_aux (n - 1) 0 (True # bl)"
by (cases n) auto
lemma bin_to_bl_aux_Bit0_minus_simp [simp]:
"0 < n \<Longrightarrow>
bin_to_bl_aux n (numeral (Num.Bit0 w)) bl = bin_to_bl_aux (n - 1) (numeral w) (False # bl)"
by (cases n) simp_all
lemma bin_to_bl_aux_Bit1_minus_simp [simp]:
"0 < n \<Longrightarrow>
bin_to_bl_aux n (numeral (Num.Bit1 w)) bl = bin_to_bl_aux (n - 1) (numeral w) (True # bl)"
by (cases n) simp_all
lemma bl_to_bin_aux_append: "bl_to_bin_aux (bs @ cs) w = bl_to_bin_aux cs (bl_to_bin_aux bs w)"
by (induct bs arbitrary: w) auto
lemma bin_to_bl_aux_append: "bin_to_bl_aux n w bs @ cs = bin_to_bl_aux n w (bs @ cs)"
by (induct n arbitrary: w bs) auto
lemma bl_to_bin_append: "bl_to_bin (bs @ cs) = bl_to_bin_aux cs (bl_to_bin bs)"
unfolding bl_to_bin_def by (rule bl_to_bin_aux_append)
lemma bin_to_bl_aux_alt: "bin_to_bl_aux n w bs = bin_to_bl n w @ bs"
by (simp add: bin_to_bl_def bin_to_bl_aux_append)
lemma bin_to_bl_0 [simp]: "bin_to_bl 0 bs = []"
by (auto simp: bin_to_bl_def)
lemma size_bin_to_bl_aux: "length (bin_to_bl_aux n w bs) = n + length bs"
by (induct n arbitrary: w bs) auto
lemma size_bin_to_bl [simp]: "length (bin_to_bl n w) = n"
by (simp add: bin_to_bl_def size_bin_to_bl_aux)
lemma bl_bin_bl': "bin_to_bl (n + length bs) (bl_to_bin_aux bs w) = bin_to_bl_aux n w bs"
apply (induct bs arbitrary: w n)
apply auto
apply (simp_all only: add_Suc [symmetric])
apply (auto simp add: bin_to_bl_def)
done
lemma bl_bin_bl [simp]: "bin_to_bl (length bs) (bl_to_bin bs) = bs"
unfolding bl_to_bin_def
apply (rule box_equals)
apply (rule bl_bin_bl')
prefer 2
apply (rule bin_to_bl_aux.Z)
apply simp
done
lemma bl_to_bin_inj: "bl_to_bin bs = bl_to_bin cs \<Longrightarrow> length bs = length cs \<Longrightarrow> bs = cs"
apply (rule_tac box_equals)
defer
apply (rule bl_bin_bl)
apply (rule bl_bin_bl)
apply simp
done
lemma bl_to_bin_False [simp]: "bl_to_bin (False # bl) = bl_to_bin bl"
by (auto simp: bl_to_bin_def)
lemma bl_to_bin_Nil [simp]: "bl_to_bin [] = 0"
by (auto simp: bl_to_bin_def)
lemma bin_to_bl_zero_aux: "bin_to_bl_aux n 0 bl = replicate n False @ bl"
by (induct n arbitrary: bl) (auto simp: replicate_app_Cons_same)
lemma bin_to_bl_zero: "bin_to_bl n 0 = replicate n False"
by (simp add: bin_to_bl_def bin_to_bl_zero_aux)
lemma bin_to_bl_minus1_aux: "bin_to_bl_aux n (- 1) bl = replicate n True @ bl"
by (induct n arbitrary: bl) (auto simp: replicate_app_Cons_same)
lemma bin_to_bl_minus1: "bin_to_bl n (- 1) = replicate n True"
by (simp add: bin_to_bl_def bin_to_bl_minus1_aux)
subsection \<open>Bit projection\<close>
abbreviation (input) bin_nth :: \<open>int \<Rightarrow> nat \<Rightarrow> bool\<close>
where \<open>bin_nth \<equiv> bit\<close>
lemma bin_nth_eq_iff: "bin_nth x = bin_nth y \<longleftrightarrow> x = y"
by (simp add: bit_eq_iff fun_eq_iff)
lemma bin_eqI:
"x = y" if "\<And>n. bin_nth x n \<longleftrightarrow> bin_nth y n"
using that bin_nth_eq_iff [of x y] by (simp add: fun_eq_iff)
lemma bin_eq_iff: "x = y \<longleftrightarrow> (\<forall>n. bin_nth x n = bin_nth y n)"
by (fact bit_eq_iff)
lemma bin_nth_zero [simp]: "\<not> bin_nth 0 n"
by simp
lemma bin_nth_1 [simp]: "bin_nth 1 n \<longleftrightarrow> n = 0"
by (cases n) (simp_all add: bit_Suc)
lemma bin_nth_minus1 [simp]: "bin_nth (- 1) n"
by (induction n) (simp_all add: bit_Suc)
lemma bin_nth_numeral: "bin_rest x = y \<Longrightarrow> bin_nth x (numeral n) = bin_nth y (pred_numeral n)"
by (simp add: numeral_eq_Suc bit_Suc)
lemmas bin_nth_numeral_simps [simp] =
bin_nth_numeral [OF bin_rest_numeral_simps(2)]
bin_nth_numeral [OF bin_rest_numeral_simps(5)]
bin_nth_numeral [OF bin_rest_numeral_simps(6)]
bin_nth_numeral [OF bin_rest_numeral_simps(7)]
bin_nth_numeral [OF bin_rest_numeral_simps(8)]
lemmas bin_nth_simps =
bit_0 bit_Suc bin_nth_zero bin_nth_minus1
bin_nth_numeral_simps
lemma nth_2p_bin: "bin_nth (2 ^ n) m = (m = n)" \<comment> \<open>for use when simplifying with \<open>bin_nth_Bit\<close>\<close>
by (auto simp add: bit_exp_iff)
lemma nth_rest_power_bin: "bin_nth ((bin_rest ^^ k) w) n = bin_nth w (n + k)"
apply (induct k arbitrary: n)
apply clarsimp
apply clarsimp
apply (simp only: bit_Suc [symmetric] add_Suc)
done
lemma bin_nth_numeral_unfold:
"bin_nth (numeral (num.Bit0 x)) n \<longleftrightarrow> n > 0 \<and> bin_nth (numeral x) (n - 1)"
"bin_nth (numeral (num.Bit1 x)) n \<longleftrightarrow> (n > 0 \<longrightarrow> bin_nth (numeral x) (n - 1))"
by (cases n; simp)+
subsection \<open>Truncating\<close>
definition bin_sign :: "int \<Rightarrow> int"
where "bin_sign k = (if k \<ge> 0 then 0 else - 1)"
lemma bin_sign_simps [simp]:
"bin_sign 0 = 0"
"bin_sign 1 = 0"
"bin_sign (- 1) = - 1"
"bin_sign (numeral k) = 0"
"bin_sign (- numeral k) = -1"
by (simp_all add: bin_sign_def)
lemma bin_sign_rest [simp]: "bin_sign (bin_rest w) = bin_sign w"
by (simp add: bin_sign_def)
abbreviation (input) bintrunc :: "nat \<Rightarrow> int \<Rightarrow> int"
where \<open>bintrunc \<equiv> take_bit\<close>
lemma bintrunc_mod2p: "bintrunc n w = w mod 2 ^ n"
by (fact take_bit_eq_mod)
primrec sbintrunc :: "nat \<Rightarrow> int \<Rightarrow> int"
where
Z : "sbintrunc 0 bin = (if odd bin then - 1 else 0)"
| Suc : "sbintrunc (Suc n) bin = of_bool (odd bin) + 2 * sbintrunc n (bin div 2)"
lemma sbintrunc_mod2p: "sbintrunc n w = (w + 2 ^ n) mod 2 ^ Suc n - 2 ^ n"
proof (induction n arbitrary: w)
case 0
then show ?case
by (auto simp add: odd_iff_mod_2_eq_one)
next
case (Suc n)
from Suc [of \<open>w div 2\<close>]
show ?case
using even_succ_mod_exp [of \<open>(b * 2 + 2 * 2 ^ n)\<close> \<open>Suc (Suc n)\<close> for b :: int]
by (auto elim!: evenE oddE simp add: mult_mod_right ac_simps)
qed
lemma sign_bintr: "bin_sign (bintrunc n w) = 0"
by (simp add: bintrunc_mod2p bin_sign_def)
lemma bintrunc_n_0 [simp]: "bintrunc n 0 = 0"
by (simp add: bintrunc_mod2p)
lemma sbintrunc_n_0 [simp]: "sbintrunc n 0 = 0"
by (simp add: sbintrunc_mod2p)
lemma sbintrunc_n_minus1 [simp]: "sbintrunc n (- 1) = -1"
by (induct n) auto
lemma bintrunc_Suc_numeral:
"bintrunc (Suc n) 1 = 1"
"bintrunc (Suc n) (- 1) = 1 + 2 * bintrunc n (- 1)"
"bintrunc (Suc n) (numeral (Num.Bit0 w)) = 2 * bintrunc n (numeral w)"
"bintrunc (Suc n) (numeral (Num.Bit1 w)) = 1 + 2 * bintrunc n (numeral w)"
"bintrunc (Suc n) (- numeral (Num.Bit0 w)) = 2 * bintrunc n (- numeral w)"
"bintrunc (Suc n) (- numeral (Num.Bit1 w)) = 1 + 2 * bintrunc n (- numeral (w + Num.One))"
by (simp_all add: take_bit_Suc)
lemma sbintrunc_0_numeral [simp]:
"sbintrunc 0 1 = -1"
"sbintrunc 0 (numeral (Num.Bit0 w)) = 0"
"sbintrunc 0 (numeral (Num.Bit1 w)) = -1"
"sbintrunc 0 (- numeral (Num.Bit0 w)) = 0"
"sbintrunc 0 (- numeral (Num.Bit1 w)) = -1"
by simp_all
lemma sbintrunc_Suc_numeral:
"sbintrunc (Suc n) 1 = 1"
"sbintrunc (Suc n) (numeral (Num.Bit0 w)) = 2 * sbintrunc n (numeral w)"
"sbintrunc (Suc n) (numeral (Num.Bit1 w)) = 1 + 2 * sbintrunc n (numeral w)"
"sbintrunc (Suc n) (- numeral (Num.Bit0 w)) = 2 * sbintrunc n (- numeral w)"
"sbintrunc (Suc n) (- numeral (Num.Bit1 w)) = 1 + 2 * sbintrunc n (- numeral (w + Num.One))"
by simp_all
lemma bin_sign_lem: "(bin_sign (sbintrunc n bin) = -1) = bin_nth bin n"
apply (rule sym)
apply (induct n arbitrary: bin)
apply (simp_all add: bit_Suc bin_sign_def)
done
lemma nth_bintr: "bin_nth (bintrunc m w) n \<longleftrightarrow> n < m \<and> bin_nth w n"
by (fact bit_take_bit_iff)
lemma nth_sbintr: "bin_nth (sbintrunc m w) n = (if n < m then bin_nth w n else bin_nth w m)"
apply (induct n arbitrary: w m)
apply (case_tac m)
apply simp_all
apply (case_tac m)
apply (simp_all add: bit_Suc)
done
lemma bin_nth_Bit0:
"bin_nth (numeral (Num.Bit0 w)) n \<longleftrightarrow>
(\<exists>m. n = Suc m \<and> bin_nth (numeral w) m)"
using bit_double_iff [of \<open>numeral w :: int\<close> n]
by (auto intro: exI [of _ \<open>n - 1\<close>])
lemma bin_nth_Bit1:
"bin_nth (numeral (Num.Bit1 w)) n \<longleftrightarrow>
n = 0 \<or> (\<exists>m. n = Suc m \<and> bin_nth (numeral w) m)"
using even_bit_succ_iff [of \<open>2 * numeral w :: int\<close> n]
bit_double_iff [of \<open>numeral w :: int\<close> n]
by auto
lemma bintrunc_bintrunc_l: "n \<le> m \<Longrightarrow> bintrunc m (bintrunc n w) = bintrunc n w"
by (simp add: min.absorb2)
lemma sbintrunc_sbintrunc_l: "n \<le> m \<Longrightarrow> sbintrunc m (sbintrunc n w) = sbintrunc n w"
by (rule bin_eqI) (auto simp: nth_sbintr)
lemma bintrunc_bintrunc_ge: "n \<le> m \<Longrightarrow> bintrunc n (bintrunc m w) = bintrunc n w"
by (rule bin_eqI) (auto simp: nth_bintr)
lemma bintrunc_bintrunc_min [simp]: "bintrunc m (bintrunc n w) = bintrunc (min m n) w"
by (rule bin_eqI) (auto simp: nth_bintr)
lemma sbintrunc_sbintrunc_min [simp]: "sbintrunc m (sbintrunc n w) = sbintrunc (min m n) w"
by (rule bin_eqI) (auto simp: nth_sbintr min.absorb1 min.absorb2)
lemmas sbintrunc_Suc_Pls =
sbintrunc.Suc [where bin="0", simplified bin_last_numeral_simps bin_rest_numeral_simps]
lemmas sbintrunc_Suc_Min =
sbintrunc.Suc [where bin="-1", simplified bin_last_numeral_simps bin_rest_numeral_simps]
lemmas sbintrunc_Sucs = sbintrunc_Suc_Pls sbintrunc_Suc_Min
sbintrunc_Suc_numeral
lemmas sbintrunc_Pls =
sbintrunc.Z [where bin="0", simplified bin_last_numeral_simps bin_rest_numeral_simps]
lemmas sbintrunc_Min =
sbintrunc.Z [where bin="-1", simplified bin_last_numeral_simps bin_rest_numeral_simps]
lemmas sbintrunc_0_simps =
sbintrunc_Pls sbintrunc_Min
lemmas sbintrunc_simps = sbintrunc_0_simps sbintrunc_Sucs
lemma bintrunc_minus: "0 < n \<Longrightarrow> bintrunc (Suc (n - 1)) w = bintrunc n w"
by auto
lemma sbintrunc_minus: "0 < n \<Longrightarrow> sbintrunc (Suc (n - 1)) w = sbintrunc n w"
by auto
lemmas sbintrunc_minus_simps =
sbintrunc_Sucs [THEN [2] sbintrunc_minus [symmetric, THEN trans]]
lemma sbintrunc_BIT_I:
\<open>0 < n \<Longrightarrow>
sbintrunc (n - 1) 0 = y \<Longrightarrow>
sbintrunc n 0 = 2 * y\<close>
by simp
lemma sbintrunc_Suc_Is:
\<open>sbintrunc n (- 1) = y \<Longrightarrow>
sbintrunc (Suc n) (- 1) = 1 + 2 * y\<close>
by auto
lemma sbintrunc_Suc_lem: "sbintrunc (Suc n) x = y \<Longrightarrow> m = Suc n \<Longrightarrow> sbintrunc m x = y"
by auto
lemmas sbintrunc_Suc_Ialts =
sbintrunc_Suc_Is [THEN sbintrunc_Suc_lem]
lemma sbintrunc_bintrunc_lt: "m > n \<Longrightarrow> sbintrunc n (bintrunc m w) = sbintrunc n w"
by (rule bin_eqI) (auto simp: nth_sbintr nth_bintr)
lemma bintrunc_sbintrunc_le: "m \<le> Suc n \<Longrightarrow> bintrunc m (sbintrunc n w) = bintrunc m w"
apply (rule bin_eqI)
using le_Suc_eq less_Suc_eq_le apply (auto simp: nth_sbintr nth_bintr)
done
lemmas bintrunc_sbintrunc [simp] = order_refl [THEN bintrunc_sbintrunc_le]
lemmas sbintrunc_bintrunc [simp] = lessI [THEN sbintrunc_bintrunc_lt]
lemmas bintrunc_bintrunc [simp] = order_refl [THEN bintrunc_bintrunc_l]
lemmas sbintrunc_sbintrunc [simp] = order_refl [THEN sbintrunc_sbintrunc_l]
lemma bintrunc_sbintrunc' [simp]: "0 < n \<Longrightarrow> bintrunc n (sbintrunc (n - 1) w) = bintrunc n w"
by (cases n) simp_all
lemma sbintrunc_bintrunc' [simp]: "0 < n \<Longrightarrow> sbintrunc (n - 1) (bintrunc n w) = sbintrunc (n - 1) w"
by (cases n) simp_all
lemma bin_sbin_eq_iff: "bintrunc (Suc n) x = bintrunc (Suc n) y \<longleftrightarrow> sbintrunc n x = sbintrunc n y"
apply (rule iffI)
apply (rule box_equals [OF _ sbintrunc_bintrunc sbintrunc_bintrunc])
apply simp
apply (rule box_equals [OF _ bintrunc_sbintrunc bintrunc_sbintrunc])
apply simp
done
lemma bin_sbin_eq_iff':
"0 < n \<Longrightarrow> bintrunc n x = bintrunc n y \<longleftrightarrow> sbintrunc (n - 1) x = sbintrunc (n - 1) y"
by (cases n) (simp_all add: bin_sbin_eq_iff)
lemmas bintrunc_sbintruncS0 [simp] = bintrunc_sbintrunc' [unfolded One_nat_def]
lemmas sbintrunc_bintruncS0 [simp] = sbintrunc_bintrunc' [unfolded One_nat_def]
lemmas bintrunc_bintrunc_l' = le_add1 [THEN bintrunc_bintrunc_l]
lemmas sbintrunc_sbintrunc_l' = le_add1 [THEN sbintrunc_sbintrunc_l]
(* although bintrunc_minus_simps, if added to default simpset,
tends to get applied where it's not wanted in developing the theories,
we get a version for when the word length is given literally *)
lemmas nat_non0_gr =
trans [OF iszero_def [THEN Not_eq_iff [THEN iffD2]] refl]
lemma bintrunc_numeral:
"bintrunc (numeral k) x = of_bool (odd x) + 2 * bintrunc (pred_numeral k) (x div 2)"
by (simp add: numeral_eq_Suc take_bit_Suc mod_2_eq_odd)
lemma sbintrunc_numeral:
"sbintrunc (numeral k) x = of_bool (odd x) + 2 * sbintrunc (pred_numeral k) (x div 2)"
by (simp add: numeral_eq_Suc)
lemma bintrunc_numeral_simps [simp]:
"bintrunc (numeral k) (numeral (Num.Bit0 w)) =
2 * bintrunc (pred_numeral k) (numeral w)"
"bintrunc (numeral k) (numeral (Num.Bit1 w)) =
1 + 2 * bintrunc (pred_numeral k) (numeral w)"
"bintrunc (numeral k) (- numeral (Num.Bit0 w)) =
2 * bintrunc (pred_numeral k) (- numeral w)"
"bintrunc (numeral k) (- numeral (Num.Bit1 w)) =
1 + 2 * bintrunc (pred_numeral k) (- numeral (w + Num.One))"
"bintrunc (numeral k) 1 = 1"
by (simp_all add: bintrunc_numeral)
lemma sbintrunc_numeral_simps [simp]:
"sbintrunc (numeral k) (numeral (Num.Bit0 w)) =
2 * sbintrunc (pred_numeral k) (numeral w)"
"sbintrunc (numeral k) (numeral (Num.Bit1 w)) =
1 + 2 * sbintrunc (pred_numeral k) (numeral w)"
"sbintrunc (numeral k) (- numeral (Num.Bit0 w)) =
2 * sbintrunc (pred_numeral k) (- numeral w)"
"sbintrunc (numeral k) (- numeral (Num.Bit1 w)) =
1 + 2 * sbintrunc (pred_numeral k) (- numeral (w + Num.One))"
"sbintrunc (numeral k) 1 = 1"
by (simp_all add: sbintrunc_numeral)
lemma no_bintr_alt1: "bintrunc n = (\<lambda>w. w mod 2 ^ n :: int)"
by (rule ext) (rule bintrunc_mod2p)
lemma range_bintrunc: "range (bintrunc n) = {i. 0 \<le> i \<and> i < 2 ^ n}"
apply (unfold no_bintr_alt1)
apply (auto simp add: image_iff)
apply (rule exI)
apply (rule sym)
using int_mod_lem [symmetric, of "2 ^ n"]
apply auto
done
lemma no_sbintr_alt2: "sbintrunc n = (\<lambda>w. (w + 2 ^ n) mod 2 ^ Suc n - 2 ^ n :: int)"
by (rule ext) (simp add : sbintrunc_mod2p)
lemma range_sbintrunc: "range (sbintrunc n) = {i. - (2 ^ n) \<le> i \<and> i < 2 ^ n}"
apply (unfold no_sbintr_alt2)
apply (auto simp add: image_iff eq_diff_eq)
apply (rule exI)
apply (auto intro: int_mod_lem [THEN iffD1, symmetric])
done
lemma sb_inc_lem: "a + 2^k < 0 \<Longrightarrow> a + 2^k + 2^(Suc k) \<le> (a + 2^k) mod 2^(Suc k)"
for a :: int
using int_mod_ge' [where n = "2 ^ (Suc k)" and b = "a + 2 ^ k"]
by simp
lemma sb_inc_lem': "a < - (2^k) \<Longrightarrow> a + 2^k + 2^(Suc k) \<le> (a + 2^k) mod 2^(Suc k)"
for a :: int
by (rule sb_inc_lem) simp
lemma sbintrunc_inc: "x < - (2^n) \<Longrightarrow> x + 2^(Suc n) \<le> sbintrunc n x"
unfolding no_sbintr_alt2 by (drule sb_inc_lem') simp
lemma sb_dec_lem: "0 \<le> - (2 ^ k) + a \<Longrightarrow> (a + 2 ^ k) mod (2 * 2 ^ k) \<le> - (2 ^ k) + a"
for a :: int
using int_mod_le'[where n = "2 ^ (Suc k)" and b = "a + 2 ^ k"] by simp
lemma sb_dec_lem': "2 ^ k \<le> a \<Longrightarrow> (a + 2 ^ k) mod (2 * 2 ^ k) \<le> - (2 ^ k) + a"
for a :: int
by (rule sb_dec_lem) simp
lemma sbintrunc_dec: "x \<ge> (2 ^ n) \<Longrightarrow> x - 2 ^ (Suc n) >= sbintrunc n x"
unfolding no_sbintr_alt2 by (drule sb_dec_lem') simp
lemma bintr_ge0: "0 \<le> bintrunc n w"
by (simp add: bintrunc_mod2p)
lemma bintr_lt2p: "bintrunc n w < 2 ^ n"
by (simp add: bintrunc_mod2p)
lemma bintr_Min: "bintrunc n (- 1) = 2 ^ n - 1"
by (simp add: bintrunc_mod2p m1mod2k)
lemma sbintr_ge: "- (2 ^ n) \<le> sbintrunc n w"
by (simp add: sbintrunc_mod2p)
lemma sbintr_lt: "sbintrunc n w < 2 ^ n"
by (simp add: sbintrunc_mod2p)
lemma sign_Pls_ge_0: "bin_sign bin = 0 \<longleftrightarrow> bin \<ge> 0"
for bin :: int
by (simp add: bin_sign_def)
lemma sign_Min_lt_0: "bin_sign bin = -1 \<longleftrightarrow> bin < 0"
for bin :: int
by (simp add: bin_sign_def)
lemma bin_rest_trunc: "bin_rest (bintrunc n bin) = bintrunc (n - 1) (bin_rest bin)"
by (simp add: take_bit_rec [of n bin])
lemma bin_rest_power_trunc:
"(bin_rest ^^ k) (bintrunc n bin) = bintrunc (n - k) ((bin_rest ^^ k) bin)"
by (induct k) (auto simp: bin_rest_trunc)
lemma bin_rest_trunc_i: "bintrunc n (bin_rest bin) = bin_rest (bintrunc (Suc n) bin)"
by (auto simp add: take_bit_Suc)
lemma bin_rest_strunc: "bin_rest (sbintrunc (Suc n) bin) = sbintrunc n (bin_rest bin)"
by (induct n arbitrary: bin) auto
lemma bintrunc_rest [simp]: "bintrunc n (bin_rest (bintrunc n bin)) = bin_rest (bintrunc n bin)"
by (induct n arbitrary: bin) (simp_all add: take_bit_Suc)
lemma sbintrunc_rest [simp]: "sbintrunc n (bin_rest (sbintrunc n bin)) = bin_rest (sbintrunc n bin)"
by (induct n arbitrary: bin) simp_all
lemma bintrunc_rest': "bintrunc n \<circ> bin_rest \<circ> bintrunc n = bin_rest \<circ> bintrunc n"
by (rule ext) auto
lemma sbintrunc_rest': "sbintrunc n \<circ> bin_rest \<circ> sbintrunc n = bin_rest \<circ> sbintrunc n"
by (rule ext) auto
lemma rco_lem: "f \<circ> g \<circ> f = g \<circ> f \<Longrightarrow> f \<circ> (g \<circ> f) ^^ n = g ^^ n \<circ> f"
apply (rule ext)
apply (induct_tac n)
apply (simp_all (no_asm))
apply (drule fun_cong)
apply (unfold o_def)
apply (erule trans)
apply simp
done
lemmas rco_bintr = bintrunc_rest'
[THEN rco_lem [THEN fun_cong], unfolded o_def]
lemmas rco_sbintr = sbintrunc_rest'
[THEN rco_lem [THEN fun_cong], unfolded o_def]
subsection \<open>Splitting and concatenation\<close>
definition bin_split :: \<open>nat \<Rightarrow> int \<Rightarrow> int \<times> int\<close>
where [simp]: \<open>bin_split n k = (drop_bit n k, take_bit n k)\<close>
lemma [code]:
"bin_split (Suc n) w = (let (w1, w2) = bin_split n (w div 2) in (w1, of_bool (odd w) + 2 * w2))"
"bin_split 0 w = (w, 0)"
by (simp_all add: drop_bit_Suc take_bit_Suc mod_2_eq_odd)
primrec bin_cat :: "int \<Rightarrow> nat \<Rightarrow> int \<Rightarrow> int"
where
Z: "bin_cat w 0 v = w"
| Suc: "bin_cat w (Suc n) v = of_bool (odd v) + 2 * bin_cat w n (v div 2)"
lemma bin_cat_eq_push_bit_add_take_bit:
\<open>bin_cat k n l = push_bit n k + take_bit n l\<close>
by (induction n arbitrary: k l)
(simp_all add: take_bit_Suc push_bit_double mod_2_eq_odd)
lemma bin_sign_cat: "bin_sign (bin_cat x n y) = bin_sign x"
proof -
have \<open>0 \<le> x\<close> if \<open>0 \<le> x * 2 ^ n + y mod 2 ^ n\<close>
proof -
from that have \<open>x \<noteq> - 1\<close>
using int_mod_le' [of \<open>y mod 2 ^ n\<close> \<open>2 ^ n\<close>] by auto
have *: \<open>- 1 \<le> (- (y mod 2 ^ n)) div 2 ^ n\<close>
by (simp add: zdiv_zminus1_eq_if)
from that have \<open>- (y mod 2 ^ n) \<le> x * 2 ^ n\<close>
by simp
then have \<open>(- (y mod 2 ^ n)) div 2 ^ n \<le> (x * 2 ^ n) div 2 ^ n\<close>
using zdiv_mono1 zero_less_numeral zero_less_power by blast
with * have \<open>- 1 \<le> x * 2 ^ n div 2 ^ n\<close> by simp
with \<open>x \<noteq> - 1\<close> show ?thesis
by simp
qed
then show ?thesis
by (simp add: bin_sign_def not_le not_less bin_cat_eq_push_bit_add_take_bit push_bit_eq_mult take_bit_eq_mod)
qed
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)
apply clarsimp
apply (case_tac m, auto)
done
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 \<or> 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 \<or> 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_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 simp
apply (case_tac n)
apply (simp_all add: bit_Suc)
done
lemma bin_nth_drop_bit_iff:
\<open>bin_nth (drop_bit n c) k \<longleftrightarrow> bin_nth c (n + k)\<close>
by (simp add: bit_drop_bit_eq)
lemma bin_nth_take_bit_iff:
\<open>bin_nth (take_bit n c) k \<longleftrightarrow> k < n \<and> bin_nth c k\<close>
by (fact bit_take_bit_iff)
lemma bin_nth_split:
"bin_split n c = (a, b) \<Longrightarrow>
(\<forall>k. bin_nth a k = bin_nth c (n + k)) \<and>
(\<forall>k. bin_nth b k = (k < n \<and> bin_nth c k))"
by (auto simp add: bin_nth_drop_bit_iff bin_nth_take_bit_iff)
lemma bin_cat_zero [simp]: "bin_cat 0 n w = bintrunc n w"
by (simp add: bin_cat_eq_push_bit_add_take_bit)
lemma bintr_cat1: "bintrunc (k + n) (bin_cat a n b) = bin_cat (bintrunc k a) n b"
by (metis bin_cat_assoc bin_cat_zero)
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 (simp add: bin_cat_eq_push_bit_add_take_bit)
lemma split_bintrunc: "bin_split n c = (a, b) \<Longrightarrow> b = bintrunc n c"
by simp
lemma bin_cat_split: "bin_split n w = (u, v) \<Longrightarrow> w = bin_cat u n v"
by (auto simp add: bin_cat_eq_push_bit_add_take_bit bits_ident)
lemma drop_bit_bin_cat_eq:
\<open>drop_bit n (bin_cat v n w) = v\<close>
by (induct n arbitrary: w)
(simp_all add: drop_bit_Suc)
lemma take_bit_bin_cat_eq:
\<open>take_bit n (bin_cat v n w) = take_bit n w\<close>
by (induct n arbitrary: w)
(simp_all add: take_bit_Suc mod_2_eq_odd)
lemma bin_split_cat: "bin_split n (bin_cat v n w) = (v, bintrunc n w)"
by (simp add: drop_bit_bin_cat_eq take_bit_bin_cat_eq)
lemma bin_split_zero [simp]: "bin_split n 0 = (0, 0)"
by simp
lemma bin_split_minus1 [simp]:
"bin_split n (- 1) = (- 1, bintrunc n (- 1))"
by simp
lemma bin_split_trunc:
"bin_split (min m n) c = (a, b) \<Longrightarrow>
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 drop_bit_Suc take_bit_Suc mod_2_eq_odd split: prod.split_asm)
done
lemma bin_split_trunc1:
"bin_split n c = (a, b) \<Longrightarrow>
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 drop_bit_Suc take_bit_Suc mod_2_eq_odd split: prod.split_asm)
done
lemma bin_cat_num: "bin_cat a n b = a * 2 ^ n + bintrunc n b"
by (simp add: bin_cat_eq_push_bit_add_take_bit push_bit_eq_mult)
lemma bin_split_num: "bin_split n b = (b div 2 ^ n, b mod 2 ^ n)"
by (simp add: drop_bit_eq_div take_bit_eq_mod)
lemmas bin_rsplit_aux_simps = bin_rsplit_aux.simps bin_rsplitl_aux.simps
lemmas rsplit_aux_simps = bin_rsplit_aux_simps
lemmas th_if_simp1 = if_split [where P = "(=) l", THEN iffD1, THEN conjunct1, THEN mp] for l
lemmas th_if_simp2 = if_split [where P = "(=) l", THEN iffD1, THEN conjunct2, THEN mp] for l
lemmas rsplit_aux_simp1s = rsplit_aux_simps [THEN th_if_simp1]
lemmas rsplit_aux_simp2ls = rsplit_aux_simps [THEN th_if_simp2]
\<comment> \<open>these safe to \<open>[simp add]\<close> as require calculating \<open>m - n\<close>\<close>
lemmas bin_rsplit_aux_simp2s [simp] = rsplit_aux_simp2ls [unfolded Let_def]
lemmas rbscl = bin_rsplit_aux_simp2s (2)
lemmas rsplit_aux_0_simps [simp] =
rsplit_aux_simp1s [OF disjI1] rsplit_aux_simp1s [OF disjI2]
lemma bin_rsplit_aux_append: "bin_rsplit_aux n m c (bs @ cs) = bin_rsplit_aux n m c bs @ cs"
apply (induct n m c bs rule: bin_rsplit_aux.induct)
apply (subst bin_rsplit_aux.simps)
apply (subst bin_rsplit_aux.simps)
apply (clarsimp split: prod.split)
done
lemma bin_rsplitl_aux_append: "bin_rsplitl_aux n m c (bs @ cs) = bin_rsplitl_aux n m c bs @ cs"
apply (induct n m c bs rule: bin_rsplitl_aux.induct)
apply (subst bin_rsplitl_aux.simps)
apply (subst bin_rsplitl_aux.simps)
apply (clarsimp split: prod.split)
done
lemmas rsplit_aux_apps [where bs = "[]"] =
bin_rsplit_aux_append bin_rsplitl_aux_append
lemmas rsplit_def_auxs = bin_rsplit_def bin_rsplitl_def
lemmas rsplit_aux_alts = rsplit_aux_apps
[unfolded append_Nil rsplit_def_auxs [symmetric]]
lemma bin_split_minus: "0 < n \<Longrightarrow> bin_split (Suc (n - 1)) w = bin_split n w"
by auto
lemma bin_split_pred_simp [simp]:
"(0::nat) < numeral bin \<Longrightarrow>
bin_split (numeral bin) w =
(let (w1, w2) = bin_split (numeral bin - 1) (bin_rest w)
in (w1, of_bool (odd w) + 2 * w2))"
by (simp add: take_bit_rec drop_bit_rec mod_2_eq_odd)
lemma bin_rsplit_aux_simp_alt:
"bin_rsplit_aux n m c bs =
(if m = 0 \<or> n = 0 then bs
else let (a, b) = bin_split n c in bin_rsplit n (m - n, a) @ b # bs)"
apply (simp add: bin_rsplit_aux.simps [of n m c bs])
apply (subst rsplit_aux_alts)
apply (simp add: bin_rsplit_def)
done
lemmas bin_rsplit_simp_alt =
trans [OF bin_rsplit_def bin_rsplit_aux_simp_alt]
lemmas bthrs = bin_rsplit_simp_alt [THEN [2] trans]
lemma bin_rsplit_size_sign' [rule_format]:
"n > 0 \<Longrightarrow> rev sw = bin_rsplit n (nw, w) \<Longrightarrow> \<forall>v\<in>set sw. bintrunc n v = v"
apply (induct sw arbitrary: nw w)
apply clarsimp
apply clarsimp
apply (drule bthrs)
apply (simp (no_asm_use) add: Let_def split: prod.split_asm if_split_asm)
apply clarify
apply simp
done
lemmas bin_rsplit_size_sign = bin_rsplit_size_sign' [OF asm_rl
rev_rev_ident [THEN trans] set_rev [THEN equalityD2 [THEN subsetD]]]
lemma bin_nth_rsplit [rule_format] :
"n > 0 \<Longrightarrow> m < n \<Longrightarrow>
\<forall>w k nw.
rev sw = bin_rsplit n (nw, w) \<longrightarrow>
k < size sw \<longrightarrow> bin_nth (sw ! k) m = bin_nth w (k * n + m)"
apply (induct sw)
apply clarsimp
apply clarsimp
apply (drule bthrs)
apply (simp (no_asm_use) add: Let_def split: prod.split_asm if_split_asm)
apply (erule allE, erule impE, erule exI)
apply (case_tac k)
apply clarsimp
prefer 2
apply clarsimp
apply (erule allE)
apply (erule (1) impE)
apply (simp add: bit_drop_bit_eq ac_simps)
apply (simp add: bit_take_bit_iff ac_simps)
done
lemma bin_rsplit_all: "0 < nw \<Longrightarrow> nw \<le> n \<Longrightarrow> bin_rsplit n (nw, w) = [bintrunc n w]"
by (auto simp: bin_rsplit_def rsplit_aux_simp2ls split: prod.split dest!: split_bintrunc)
lemma bin_rsplit_l [rule_format]:
"\<forall>bin. bin_rsplitl n (m, bin) = bin_rsplit n (m, bintrunc m bin)"
apply (rule_tac a = "m" in wf_less_than [THEN wf_induct])
apply (simp (no_asm) add: bin_rsplitl_def bin_rsplit_def)
apply (rule allI)
apply (subst bin_rsplitl_aux.simps)
apply (subst bin_rsplit_aux.simps)
apply (clarsimp simp: Let_def split: prod.split)
apply (simp add: ac_simps)
apply (subst rsplit_aux_alts(1))
apply (subst rsplit_aux_alts(2))
apply clarsimp
unfolding bin_rsplit_def bin_rsplitl_def
apply (simp add: drop_bit_take_bit)
apply (case_tac \<open>x < n\<close>)
apply (simp_all add: not_less min_def)
done
lemma bin_rsplit_rcat [rule_format]:
"n > 0 \<longrightarrow> bin_rsplit n (n * size ws, bin_rcat n ws) = map (bintrunc n) ws"
apply (unfold bin_rsplit_def bin_rcat_def)
apply (rule_tac xs = ws in rev_induct)
apply clarsimp
apply clarsimp
apply (subst rsplit_aux_alts)
apply (simp add: drop_bit_bin_cat_eq take_bit_bin_cat_eq)
done
lemma bin_rsplit_aux_len_le [rule_format] :
"\<forall>ws m. n \<noteq> 0 \<longrightarrow> ws = bin_rsplit_aux n nw w bs \<longrightarrow>
length ws \<le> m \<longleftrightarrow> nw + length bs * n \<le> m * n"
proof -
have *: R
if d: "i \<le> j \<or> m < j'"
and R1: "i * k \<le> j * k \<Longrightarrow> R"
and R2: "Suc m * k' \<le> j' * k' \<Longrightarrow> R"
for i j j' k k' m :: nat and R
using d
apply safe
apply (rule R1, erule mult_le_mono1)
apply (rule R2, erule Suc_le_eq [THEN iffD2 [THEN mult_le_mono1]])
done
have **: "0 < sc \<Longrightarrow> sc - n + (n + lb * n) \<le> m * n \<longleftrightarrow> sc + lb * n \<le> m * n"
for sc m n lb :: nat
apply safe
apply arith
apply (case_tac "sc \<ge> n")
apply arith
apply (insert linorder_le_less_linear [of m lb])
apply (erule_tac k=n and k'=n in *)
apply arith
apply simp
done
show ?thesis
apply (induct n nw w bs rule: bin_rsplit_aux.induct)
apply (subst bin_rsplit_aux.simps)
apply (simp add: ** Let_def split: prod.split)
done
qed
lemma bin_rsplit_len_le: "n \<noteq> 0 \<longrightarrow> ws = bin_rsplit n (nw, w) \<longrightarrow> length ws \<le> m \<longleftrightarrow> nw \<le> m * n"
by (auto simp: bin_rsplit_def bin_rsplit_aux_len_le)
lemma bin_rsplit_aux_len:
"n \<noteq> 0 \<Longrightarrow> length (bin_rsplit_aux n nw w cs) = (nw + n - 1) div n + length cs"
apply (induct n nw w cs rule: bin_rsplit_aux.induct)
apply (subst bin_rsplit_aux.simps)
apply (clarsimp simp: Let_def split: prod.split)
apply (erule thin_rl)
apply (case_tac m)
apply simp
apply (case_tac "m \<le> n")
apply (auto simp add: div_add_self2)
done
lemma bin_rsplit_len: "n \<noteq> 0 \<Longrightarrow> length (bin_rsplit n (nw, w)) = (nw + n - 1) div n"
by (auto simp: bin_rsplit_def bin_rsplit_aux_len)
lemma bin_rsplit_aux_len_indep:
"n \<noteq> 0 \<Longrightarrow> length bs = length cs \<Longrightarrow>
length (bin_rsplit_aux n nw v bs) =
length (bin_rsplit_aux n nw w cs)"
proof (induct n nw w cs arbitrary: v bs rule: bin_rsplit_aux.induct)
case (1 n m w cs v bs)
show ?case
proof (cases "m = 0")
case True
with \<open>length bs = length cs\<close> show ?thesis by simp
next
case False
from "1.hyps" [of \<open>bin_split n w\<close> \<open>drop_bit n w\<close> \<open>take_bit n w\<close>] \<open>m \<noteq> 0\<close> \<open>n \<noteq> 0\<close>
have hyp: "\<And>v bs. length bs = Suc (length cs) \<Longrightarrow>
length (bin_rsplit_aux n (m - n) v bs) =
length (bin_rsplit_aux n (m - n) (drop_bit n w) (take_bit n w # cs))"
using bin_rsplit_aux_len by fastforce
from \<open>length bs = length cs\<close> \<open>n \<noteq> 0\<close> show ?thesis
by (auto simp add: bin_rsplit_aux_simp_alt Let_def bin_rsplit_len split: prod.split)
qed
qed
lemma bin_rsplit_len_indep:
"n \<noteq> 0 \<Longrightarrow> length (bin_rsplit n (nw, v)) = length (bin_rsplit n (nw, w))"
apply (unfold bin_rsplit_def)
apply (simp (no_asm))
apply (erule bin_rsplit_aux_len_indep)
apply (rule refl)
done
subsection \<open>Logical operations\<close>
primrec bin_sc :: "nat \<Rightarrow> bool \<Rightarrow> int \<Rightarrow> int"
where
Z: "bin_sc 0 b w = of_bool b + 2 * bin_rest w"
| Suc: "bin_sc (Suc n) b w = of_bool (odd w) + 2 * bin_sc n b (w div 2)"
lemma bin_nth_sc [simp]: "bit (bin_sc n b w) n \<longleftrightarrow> b"
by (induction n arbitrary: w) (simp_all add: bit_Suc)
lemma bin_sc_sc_same [simp]: "bin_sc n c (bin_sc n b w) = bin_sc n c w"
by (induction n arbitrary: w) (simp_all add: bit_Suc)
lemma bin_sc_sc_diff: "m \<noteq> n \<Longrightarrow> 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)"
apply (induct n arbitrary: w m)
apply (case_tac m; simp add: bit_Suc)
apply (case_tac m; simp add: bit_Suc)
done
lemma bin_sc_eq:
\<open>bin_sc n False = unset_bit n\<close>
\<open>bin_sc n True = Bit_Operations.set_bit n\<close>
by (simp_all add: fun_eq_iff bit_eq_iff)
(simp_all add: bin_nth_sc_gen bit_set_bit_iff bit_unset_bit_iff)
lemma bin_sc_nth [simp]: "bin_sc n (bin_nth w n) w = w"
by (rule bit_eqI) (simp add: bin_nth_sc_gen)
lemma bin_sign_sc [simp]: "bin_sign (bin_sc n b w) = bin_sign w"
proof (induction n arbitrary: w)
case 0
then show ?case
by (auto simp add: bin_sign_def) (use bin_rest_ge_0 in fastforce)
next
case (Suc n)
from Suc [of \<open>w div 2\<close>]
show ?case by (auto simp add: bin_sign_def split: if_splits)
qed
lemma bin_sc_bintr [simp]:
"bintrunc m (bin_sc n x (bintrunc m w)) = bintrunc m (bin_sc n x w)"
apply (cases x)
apply (simp_all add: bin_sc_eq bit_eq_iff)
apply (auto simp add: bit_take_bit_iff bit_set_bit_iff bit_unset_bit_iff)
done
lemma bin_clr_le: "bin_sc n False w \<le> w"
by (simp add: bin_sc_eq unset_bit_less_eq)
lemma bin_set_ge: "bin_sc n True w \<ge> w"
by (simp add: bin_sc_eq set_bit_greater_eq)
lemma bintr_bin_clr_le: "bintrunc n (bin_sc m False w) \<le> bintrunc n w"
by (simp add: bin_sc_eq take_bit_unset_bit_eq unset_bit_less_eq)
lemma bintr_bin_set_ge: "bintrunc n (bin_sc m True w) \<ge> bintrunc n w"
by (simp add: bin_sc_eq take_bit_set_bit_eq set_bit_greater_eq)
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 \<Longrightarrow> 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 =
of_bool (odd w) + 2 * bin_sc (pred_numeral k) b (w div 2)"
by (simp add: numeral_eq_Suc)
instantiation int :: bit_operations
begin
definition [iff]: "i !! n \<longleftrightarrow> bin_nth i n"
definition "lsb i = i !! 0" for i :: int
definition "set_bit i n b = bin_sc n b i"
definition "shiftl x n = x * 2 ^ n" for x :: int
definition "shiftr x n = x div 2 ^ n" for x :: int
definition "msb x \<longleftrightarrow> x < 0" for x :: int
instance ..
end
lemma shiftl_eq_push_bit:
\<open>k << n = push_bit n k\<close> for k :: int
by (simp add: shiftl_int_def push_bit_eq_mult)
lemma shiftr_eq_drop_bit:
\<open>k >> n = drop_bit n k\<close> for k :: int
by (simp add: shiftr_int_def drop_bit_eq_div)
subsubsection \<open>Basic simplification rules\<close>
lemmas int_not_def = not_int_def
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)"
by (simp_all add: not_int_def)
lemma int_not_not: "NOT (NOT x) = x"
for x :: int
by (fact bit.double_compl)
lemma int_and_0 [simp]: "0 AND x = 0"
for x :: int
by (fact bit.conj_zero_left)
lemma int_and_m1 [simp]: "-1 AND x = x"
for x :: int
by (fact bit.conj_one_left)
lemma int_or_zero [simp]: "0 OR x = x"
for x :: int
by (fact bit.disj_zero_left)
lemma int_or_minus1 [simp]: "-1 OR x = -1"
for x :: int
by (fact bit.disj_one_left)
lemma int_xor_zero [simp]: "0 XOR x = x"
for x :: int
by (fact bit.xor_zero_left)
subsubsection \<open>Binary destructors\<close>
lemma bin_rest_NOT [simp]: "bin_rest (NOT x) = NOT (bin_rest x)"
by (fact not_int_div_2)
lemma bin_last_NOT [simp]: "bin_last (NOT x) \<longleftrightarrow> \<not> bin_last x"
by simp
lemma bin_rest_AND [simp]: "bin_rest (x AND y) = bin_rest x AND bin_rest y"
by (subst and_int_rec) auto
lemma bin_last_AND [simp]: "bin_last (x AND y) \<longleftrightarrow> bin_last x \<and> bin_last y"
by (subst and_int_rec) auto
lemma bin_rest_OR [simp]: "bin_rest (x OR y) = bin_rest x OR bin_rest y"
by (subst or_int_rec) auto
lemma bin_last_OR [simp]: "bin_last (x OR y) \<longleftrightarrow> bin_last x \<or> bin_last y"
by (subst or_int_rec) auto
lemma bin_rest_XOR [simp]: "bin_rest (x XOR y) = bin_rest x XOR bin_rest y"
by (subst xor_int_rec) auto
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 (subst xor_int_rec) auto
lemma bin_nth_ops:
"\<And>x y. bin_nth (x AND y) n \<longleftrightarrow> bin_nth x n \<and> bin_nth y n"
"\<And>x y. bin_nth (x OR y) n \<longleftrightarrow> bin_nth x n \<or> bin_nth y n"
"\<And>x y. bin_nth (x XOR y) n \<longleftrightarrow> bin_nth x n \<noteq> bin_nth y n"
"\<And>x. bin_nth (NOT x) n \<longleftrightarrow> \<not> bin_nth x n"
by (simp_all add: bit_and_iff bit_or_iff bit_xor_iff bit_not_iff)
subsubsection \<open>Derived properties\<close>
lemma int_xor_minus1 [simp]: "-1 XOR x = NOT x"
for x :: int
by (fact bit.xor_one_left)
lemma int_xor_extra_simps [simp]:
"w XOR 0 = w"
"w XOR -1 = NOT w"
for w :: int
by simp_all
lemma int_or_extra_simps [simp]:
"w OR 0 = w"
"w OR -1 = -1"
for w :: int
by simp_all
lemma int_and_extra_simps [simp]:
"w AND 0 = 0"
"w AND -1 = w"
for w :: int
by simp_all
text \<open>Commutativity of the above.\<close>
lemma bin_ops_comm:
fixes x y :: int
shows int_and_comm: "x AND y = y AND x"
and int_or_comm: "x OR y = y OR x"
and int_xor_comm: "x XOR y = y XOR x"
by (simp_all add: ac_simps)
lemma bin_ops_same [simp]:
"x AND x = x"
"x OR x = x"
"x XOR x = 0"
for x :: int
by simp_all
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
subsubsection \<open>Basic properties of logical (bit-wise) operations\<close>
lemma bbw_ao_absorb: "x AND (y OR x) = x \<and> x OR (y AND x) = x"
for x y :: int
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"
"(y OR x) AND x = x \<and> x OR (x AND y) = x"
"(x OR y) AND x = x \<and> (x AND y) OR x = x"
for x y :: 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: "(NOT x) XOR y = NOT (x XOR y) \<and> x XOR (NOT y) = NOT (x XOR y)"
for x y :: int
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_and_assoc: "(x AND y) AND z = x AND (y AND z)"
for x y z :: int
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_or_assoc: "(x OR y) OR z = x OR (y OR z)"
for x y z :: int
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma int_xor_assoc: "(x XOR y) XOR z = x XOR (y XOR z)"
for x y z :: int
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 AND (x AND z) = x AND (y AND z)"
"y OR (x OR z) = x OR (y OR z)"
"y XOR (x XOR z) = x XOR (y XOR z)"
for x y :: int
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bbw_not_dist:
"NOT (x OR y) = (NOT x) AND (NOT y)"
"NOT (x AND y) = (NOT x) OR (NOT y)"
for x y :: int
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bbw_oa_dist: "(x AND y) OR z = (x OR z) AND (y OR z)"
for x y z :: int
by (auto simp add: bin_eq_iff bin_nth_ops)
lemma bbw_ao_dist: "(x OR y) AND z = (x AND z) OR (y AND z)"
for x y z :: int
by (auto simp add: bin_eq_iff bin_nth_ops)
(*
Why were these declared simp???
declare bin_ops_comm [simp] bbw_assocs [simp]
*)
subsubsection \<open>Simplification with numerals\<close>
text \<open>Cases for \<open>0\<close> and \<open>-1\<close> are already covered by other simp rules.\<close>
lemma bin_rest_neg_numeral_BitM [simp]:
"bin_rest (- numeral (Num.BitM w)) = - numeral w"
by simp
lemma bin_last_neg_numeral_BitM [simp]:
"bin_last (- numeral (Num.BitM w))"
by simp
(* 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) = (2 :: int) * (numeral x AND numeral y)"
"numeral (Num.Bit0 x) AND numeral (Num.Bit1 y) = (2 :: int) * (numeral x AND numeral y)"
"numeral (Num.Bit1 x) AND numeral (Num.Bit0 y) = (2 :: int) * (numeral x AND numeral y)"
"numeral (Num.Bit1 x) AND numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x AND numeral y)"
"numeral (Num.Bit0 x) AND - numeral (Num.Bit0 y) = (2 :: int) * (numeral x AND - numeral y)"
"numeral (Num.Bit0 x) AND - numeral (Num.Bit1 y) = (2 :: int) * (numeral x AND - numeral (y + Num.One))"
"numeral (Num.Bit1 x) AND - numeral (Num.Bit0 y) = (2 :: int) * (numeral x AND - numeral y)"
"numeral (Num.Bit1 x) AND - numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x AND - numeral (y + Num.One))"
"- numeral (Num.Bit0 x) AND numeral (Num.Bit0 y) = (2 :: int) * (- numeral x AND numeral y)"
"- numeral (Num.Bit0 x) AND numeral (Num.Bit1 y) = (2 :: int) * (- numeral x AND numeral y)"
"- numeral (Num.Bit1 x) AND numeral (Num.Bit0 y) = (2 :: int) * (- numeral (x + Num.One) AND numeral y)"
"- numeral (Num.Bit1 x) AND numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral (x + Num.One) AND numeral y)"
"- numeral (Num.Bit0 x) AND - numeral (Num.Bit0 y) = (2 :: int) * (- numeral x AND - numeral y)"
"- numeral (Num.Bit0 x) AND - numeral (Num.Bit1 y) = (2 :: int) * (- numeral x AND - numeral (y + Num.One))"
"- numeral (Num.Bit1 x) AND - numeral (Num.Bit0 y) = (2 :: int) * (- numeral (x + Num.One) AND - numeral y)"
"- numeral (Num.Bit1 x) AND - numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral (x + Num.One) AND - numeral (y + Num.One))"
"(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)+
lemma int_or_numerals [simp]:
"numeral (Num.Bit0 x) OR numeral (Num.Bit0 y) = (2 :: int) * (numeral x OR numeral y)"
"numeral (Num.Bit0 x) OR numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x OR numeral y)"
"numeral (Num.Bit1 x) OR numeral (Num.Bit0 y) = 1 + (2 :: int) * (numeral x OR numeral y)"
"numeral (Num.Bit1 x) OR numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x OR numeral y)"
"numeral (Num.Bit0 x) OR - numeral (Num.Bit0 y) = (2 :: int) * (numeral x OR - numeral y)"
"numeral (Num.Bit0 x) OR - numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x OR - numeral (y + Num.One))"
"numeral (Num.Bit1 x) OR - numeral (Num.Bit0 y) = 1 + (2 :: int) * (numeral x OR - numeral y)"
"numeral (Num.Bit1 x) OR - numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x OR - numeral (y + Num.One))"
"- numeral (Num.Bit0 x) OR numeral (Num.Bit0 y) = (2 :: int) * (- numeral x OR numeral y)"
"- numeral (Num.Bit0 x) OR numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral x OR numeral y)"
"- numeral (Num.Bit1 x) OR numeral (Num.Bit0 y) = 1 + (2 :: int) * (- numeral (x + Num.One) OR numeral y)"
"- numeral (Num.Bit1 x) OR numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral (x + Num.One) OR numeral y)"
"- numeral (Num.Bit0 x) OR - numeral (Num.Bit0 y) = (2 :: int) * (- numeral x OR - numeral y)"
"- numeral (Num.Bit0 x) OR - numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral x OR - numeral (y + Num.One))"
"- numeral (Num.Bit1 x) OR - numeral (Num.Bit0 y) = 1 + (2 :: int) * (- numeral (x + Num.One) OR - numeral y)"
"- numeral (Num.Bit1 x) OR - numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral (x + Num.One) OR - numeral (y + Num.One))"
"(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)+
lemma int_xor_numerals [simp]:
"numeral (Num.Bit0 x) XOR numeral (Num.Bit0 y) = (2 :: int) * (numeral x XOR numeral y)"
"numeral (Num.Bit0 x) XOR numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x XOR numeral y)"
"numeral (Num.Bit1 x) XOR numeral (Num.Bit0 y) = 1 + (2 :: int) * (numeral x XOR numeral y)"
"numeral (Num.Bit1 x) XOR numeral (Num.Bit1 y) = (2 :: int) * (numeral x XOR numeral y)"
"numeral (Num.Bit0 x) XOR - numeral (Num.Bit0 y) = (2 :: int) * (numeral x XOR - numeral y)"
"numeral (Num.Bit0 x) XOR - numeral (Num.Bit1 y) = 1 + (2 :: int) * (numeral x XOR - numeral (y + Num.One))"
"numeral (Num.Bit1 x) XOR - numeral (Num.Bit0 y) = 1 + (2 :: int) * (numeral x XOR - numeral y)"
"numeral (Num.Bit1 x) XOR - numeral (Num.Bit1 y) = (2 :: int) * (numeral x XOR - numeral (y + Num.One))"
"- numeral (Num.Bit0 x) XOR numeral (Num.Bit0 y) = (2 :: int) * (- numeral x XOR numeral y)"
"- numeral (Num.Bit0 x) XOR numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral x XOR numeral y)"
"- numeral (Num.Bit1 x) XOR numeral (Num.Bit0 y) = 1 + (2 :: int) * (- numeral (x + Num.One) XOR numeral y)"
"- numeral (Num.Bit1 x) XOR numeral (Num.Bit1 y) = (2 :: int) * (- numeral (x + Num.One) XOR numeral y)"
"- numeral (Num.Bit0 x) XOR - numeral (Num.Bit0 y) = (2 :: int) * (- numeral x XOR - numeral y)"
"- numeral (Num.Bit0 x) XOR - numeral (Num.Bit1 y) = 1 + (2 :: int) * (- numeral x XOR - numeral (y + Num.One))"
"- numeral (Num.Bit1 x) XOR - numeral (Num.Bit0 y) = 1 + (2 :: int) * (- numeral (x + Num.One) XOR - numeral y)"
"- numeral (Num.Bit1 x) XOR - numeral (Num.Bit1 y) = (2 :: int) * (- numeral (x + Num.One) XOR - numeral (y + Num.One))"
"(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)+
subsubsection \<open>Interactions with arithmetic\<close>
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 \<open>y div 2\<close>]
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 \<open>y div 2\<close>]
show ?case
by (auto simp add: and_int_rec [of _ y] or_int_rec [of _ y] elim: oddE)
qed
lemma le_int_or: "bin_sign y = 0 \<Longrightarrow> x \<le> x OR y"
for x y :: int
by (simp add: bin_sign_def or_greater_eq split: if_splits)
lemmas int_and_le =
xtrans(3) [OF bbw_ao_absorbs (2) [THEN conjunct2, symmetric] le_int_or]
text \<open>Interaction between bit-wise and arithmetic: good example of \<open>bin_induction\<close>.\<close>
lemma bin_add_not: "x + NOT x = (-1::int)"
by (simp add: not_int_def)
lemma AND_mod: "x AND (2 ^ n - 1) = x mod 2 ^ n"
for x :: int
by (simp flip: take_bit_eq_mod add: take_bit_eq_mask mask_eq_exp_minus_1)
subsubsection \<open>Comparison\<close>
lemma AND_lower [simp]: \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
fixes x y :: int
assumes "0 \<le> x"
shows "0 \<le> x AND y"
using assms by simp
lemma OR_lower [simp]: \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
fixes x y :: int
assumes "0 \<le> x" "0 \<le> y"
shows "0 \<le> x OR y"
using assms by simp
lemma XOR_lower [simp]: \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
fixes x y :: int
assumes "0 \<le> x" "0 \<le> y"
shows "0 \<le> x XOR y"
using assms by simp
lemma AND_upper1 [simp]: \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
fixes x y :: int
assumes "0 \<le> x"
shows "x AND y \<le> x"
using assms by (induction x arbitrary: y rule: int_bit_induct)
(simp_all add: and_int_rec [of \<open>_ * 2\<close>] and_int_rec [of \<open>1 + _ * 2\<close>] add_increasing)
lemmas AND_upper1' [simp] = order_trans [OF AND_upper1] \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
lemmas AND_upper1'' [simp] = order_le_less_trans [OF AND_upper1] \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
lemma AND_upper2 [simp]: \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
fixes x y :: int
assumes "0 \<le> y"
shows "x AND y \<le> y"
using assms AND_upper1 [of y x] by (simp add: ac_simps)
lemmas AND_upper2' [simp] = order_trans [OF AND_upper2] \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
lemmas AND_upper2'' [simp] = order_le_less_trans [OF AND_upper2] \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
lemma OR_upper: \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
fixes x y :: int
assumes "0 \<le> x" "x < 2 ^ n" "y < 2 ^ n"
shows "x OR y < 2 ^ n"
using assms 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 \<open>n - 1\<close> \<open>y div 2\<close>] even.prems even.hyps
show ?case
by (cases n) (auto simp add: or_int_rec [of \<open>_ * 2\<close>] elim: oddE)
next
case (odd x)
from odd.IH [of \<open>n - 1\<close> \<open>y div 2\<close>] odd.prems odd.hyps
show ?case
by (cases n) (auto simp add: or_int_rec [of \<open>1 + _ * 2\<close>], linarith)
qed
lemma XOR_upper: \<^marker>\<open>contributor \<open>Stefan Berghofer\<close>\<close>
fixes x y :: int
assumes "0 \<le> x" "x < 2 ^ n" "y < 2 ^ n"
shows "x XOR y < 2 ^ n"
using assms 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 \<open>n - 1\<close> \<open>y div 2\<close>] even.prems even.hyps
show ?case
by (cases n) (auto simp add: xor_int_rec [of \<open>_ * 2\<close>] elim: oddE)
next
case (odd x)
from odd.IH [of \<open>n - 1\<close> \<open>y div 2\<close>] odd.prems odd.hyps
show ?case
by (cases n) (auto simp add: xor_int_rec [of \<open>1 + _ * 2\<close>])
qed
subsubsection \<open>Truncating results of bit-wise operations\<close>
lemma bin_trunc_ao:
"bintrunc n x AND bintrunc n y = bintrunc n (x AND 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: "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: "bintrunc n (NOT (bintrunc n x)) = bintrunc n (NOT x)"
by (auto simp add: bin_eq_iff bin_nth_ops nth_bintr)
text \<open>Want theorems of the form of \<open>bin_trunc_xor\<close>.\<close>
lemma bintr_bintr_i: "x = bintrunc n y \<Longrightarrow> 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]
subsubsection \<open>More lemmas\<close>
lemma not_int_cmp_0 [simp]:
fixes i :: int shows
"0 < NOT i \<longleftrightarrow> i < -1"
"0 \<le> NOT i \<longleftrightarrow> i < 0"
"NOT i < 0 \<longleftrightarrow> i \<ge> 0"
"NOT i \<le> 0 \<longleftrightarrow> i \<ge> -1"
by(simp_all add: int_not_def) arith+
lemma bbw_ao_dist2: "(x :: int) AND (y OR z) = x AND y OR x AND z"
by (fact bit.conj_disj_distrib)
lemmas int_and_ac = bbw_lcs(1) int_and_comm int_and_assoc
lemma int_nand_same [simp]: fixes x :: int shows "x AND NOT x = 0"
by simp
lemma int_nand_same_middle: fixes x :: int shows "x AND y AND NOT x = 0"
by (simp add: bit_eq_iff bit_and_iff bit_not_iff)
lemma and_xor_dist: fixes x :: int shows
"x AND (y XOR z) = (x AND y) XOR (x AND z)"
by (fact bit.conj_xor_distrib)
lemma int_and_lt0 [simp]:
\<open>x AND y < 0 \<longleftrightarrow> x < 0 \<and> y < 0\<close> for x y :: int
by (fact and_negative_int_iff)
lemma int_and_ge0 [simp]:
\<open>x AND y \<ge> 0 \<longleftrightarrow> x \<ge> 0 \<or> y \<ge> 0\<close> for x y :: int
by (fact and_nonnegative_int_iff)
lemma int_and_1: fixes x :: int shows "x AND 1 = x mod 2"
by (fact and_one_eq)
lemma int_1_and: fixes x :: int shows "1 AND x = x mod 2"
by (fact one_and_eq)
lemma int_or_lt0 [simp]:
\<open>x OR y < 0 \<longleftrightarrow> x < 0 \<or> y < 0\<close> for x y :: int
by (fact or_negative_int_iff)
lemma int_or_ge0 [simp]:
\<open>x OR y \<ge> 0 \<longleftrightarrow> x \<ge> 0 \<and> y \<ge> 0\<close> for x y :: int
by (fact or_nonnegative_int_iff)
lemma int_xor_lt0 [simp]:
\<open>x XOR y < 0 \<longleftrightarrow> (x < 0) \<noteq> (y < 0)\<close> for x y :: int
by (fact xor_negative_int_iff)
lemma int_xor_ge0 [simp]:
\<open>x XOR y \<ge> 0 \<longleftrightarrow> (x \<ge> 0 \<longleftrightarrow> y \<ge> 0)\<close> for x y :: int
by (fact xor_nonnegative_int_iff)
lemma even_conv_AND:
\<open>even i \<longleftrightarrow> i AND 1 = 0\<close> for i :: int
by (simp add: and_one_eq mod2_eq_if)
lemma bin_last_conv_AND:
"bin_last i \<longleftrightarrow> i AND 1 \<noteq> 0"
by (simp add: and_one_eq mod2_eq_if)
lemma bitval_bin_last:
"of_bool (bin_last i) = i AND 1"
by (simp add: and_one_eq mod2_eq_if)
lemma bin_sign_and:
"bin_sign (i AND j) = - (bin_sign i * bin_sign j)"
by(simp add: bin_sign_def)
lemma int_not_neg_numeral: "NOT (- numeral n) = (Num.sub n num.One :: int)"
by(simp add: int_not_def)
lemma int_neg_numeral_pOne_conv_not: "- numeral (n + num.One) = (NOT (numeral n) :: int)"
by(simp add: int_not_def)
subsection \<open>Setting and clearing bits\<close>
lemma bin_last_conv_lsb: "bin_last = lsb"
by(clarsimp simp add: lsb_int_def fun_eq_iff)
lemma int_lsb_numeral [simp]:
"lsb (0 :: int) = False"
"lsb (1 :: int) = True"
"lsb (Numeral1 :: int) = True"
"lsb (- 1 :: int) = True"
"lsb (- Numeral1 :: int) = True"
"lsb (numeral (num.Bit0 w) :: int) = False"
"lsb (numeral (num.Bit1 w) :: int) = True"
"lsb (- numeral (num.Bit0 w) :: int) = False"
"lsb (- numeral (num.Bit1 w) :: int) = True"
by (simp_all add: lsb_int_def)
lemma int_set_bit_0 [simp]: fixes x :: int shows
"set_bit x 0 b = of_bool b + 2 * (x div 2)"
by (auto simp add: set_bit_int_def intro: bin_rl_eqI)
lemma int_set_bit_Suc: fixes x :: int shows
"set_bit x (Suc n) b = of_bool (odd x) + 2 * set_bit (x div 2) n b"
by (auto simp add: set_bit_int_def intro: bin_rl_eqI)
lemma bin_last_set_bit:
"bin_last (set_bit x n b) = (if n > 0 then bin_last x else b)"
by (cases n) (simp_all add: int_set_bit_Suc)
lemma bin_rest_set_bit:
"bin_rest (set_bit x n b) = (if n > 0 then set_bit (x div 2) (n - 1) b else x div 2)"
by (cases n) (simp_all add: int_set_bit_Suc)
lemma int_set_bit_numeral: fixes x :: int shows
"set_bit x (numeral w) b = of_bool (odd x) + 2 * set_bit (x div 2) (pred_numeral w) b"
by (simp add: set_bit_int_def)
lemmas int_set_bit_numerals [simp] =
int_set_bit_numeral[where x="numeral w'"]
int_set_bit_numeral[where x="- numeral w'"]
int_set_bit_numeral[where x="Numeral1"]
int_set_bit_numeral[where x="1"]
int_set_bit_numeral[where x="0"]
int_set_bit_Suc[where x="numeral w'"]
int_set_bit_Suc[where x="- numeral w'"]
int_set_bit_Suc[where x="Numeral1"]
int_set_bit_Suc[where x="1"]
int_set_bit_Suc[where x="0"]
for w'
lemma int_shiftl_BIT: fixes x :: int
shows int_shiftl0 [simp]: "x << 0 = x"
and int_shiftl_Suc [simp]: "x << Suc n = 2 * (x << n)"
by (auto simp add: shiftl_int_def)
lemma int_0_shiftl [simp]: "0 << n = (0 :: int)"
by(induct n) simp_all
lemma bin_last_shiftl: "bin_last (x << n) \<longleftrightarrow> n = 0 \<and> bin_last x"
by(cases n)(simp_all)
lemma bin_rest_shiftl: "bin_rest (x << n) = (if n > 0 then x << (n - 1) else bin_rest x)"
by(cases n)(simp_all)
lemma bin_nth_shiftl [simp]: "bin_nth (x << n) m \<longleftrightarrow> n \<le> m \<and> bin_nth x (m - n)"
by (simp add: bit_push_bit_iff_int shiftl_eq_push_bit)
lemma bin_last_shiftr: "odd (x >> n) \<longleftrightarrow> x !! n" for x :: int
by (simp add: shiftr_eq_drop_bit bit_iff_odd_drop_bit)
lemma bin_rest_shiftr [simp]: "bin_rest (x >> n) = x >> Suc n"
by (simp add: bit_eq_iff shiftr_eq_drop_bit drop_bit_Suc bit_drop_bit_eq drop_bit_half)
lemma bin_nth_shiftr [simp]: "bin_nth (x >> n) m = bin_nth x (n + m)"
by (simp add: shiftr_eq_drop_bit bit_drop_bit_eq)
lemma bin_nth_conv_AND:
fixes x :: int shows
"bin_nth x n \<longleftrightarrow> x AND (1 << n) \<noteq> 0"
by (simp add: bit_eq_iff)
(auto simp add: shiftl_eq_push_bit bit_and_iff bit_push_bit_iff bit_exp_iff)
lemma int_shiftl_numeral [simp]:
"(numeral w :: int) << numeral w' = numeral (num.Bit0 w) << pred_numeral w'"
"(- numeral w :: int) << numeral w' = - numeral (num.Bit0 w) << pred_numeral w'"
by(simp_all add: numeral_eq_Suc shiftl_int_def)
(metis add_One mult_inc semiring_norm(11) semiring_norm(13) semiring_norm(2) semiring_norm(6) semiring_norm(87))+
lemma int_shiftl_One_numeral [simp]:
"(1 :: int) << numeral w = 2 << pred_numeral w"
using int_shiftl_numeral [of Num.One w] by simp
lemma shiftl_ge_0 [simp]: fixes i :: int shows "i << n \<ge> 0 \<longleftrightarrow> i \<ge> 0"
by(induct n) simp_all
lemma shiftl_lt_0 [simp]: fixes i :: int shows "i << n < 0 \<longleftrightarrow> i < 0"
by (metis not_le shiftl_ge_0)
lemma int_shiftl_test_bit: "(n << i :: int) !! m \<longleftrightarrow> m \<ge> i \<and> n !! (m - i)"
by simp
lemma int_0shiftr [simp]: "(0 :: int) >> x = 0"
by(simp add: shiftr_int_def)
lemma int_minus1_shiftr [simp]: "(-1 :: int) >> x = -1"
by(simp add: shiftr_int_def div_eq_minus1)
lemma int_shiftr_ge_0 [simp]: fixes i :: int shows "i >> n \<ge> 0 \<longleftrightarrow> i \<ge> 0"
by (simp add: shiftr_eq_drop_bit)
lemma int_shiftr_lt_0 [simp]: fixes i :: int shows "i >> n < 0 \<longleftrightarrow> i < 0"
by (metis int_shiftr_ge_0 not_less)
lemma int_shiftr_numeral [simp]:
"(1 :: int) >> numeral w' = 0"
"(numeral num.One :: int) >> numeral w' = 0"
"(numeral (num.Bit0 w) :: int) >> numeral w' = numeral w >> pred_numeral w'"
"(numeral (num.Bit1 w) :: int) >> numeral w' = numeral w >> pred_numeral w'"
"(- numeral (num.Bit0 w) :: int) >> numeral w' = - numeral w >> pred_numeral w'"
"(- numeral (num.Bit1 w) :: int) >> numeral w' = - numeral (Num.inc w) >> pred_numeral w'"
by (simp_all add: shiftr_eq_drop_bit numeral_eq_Suc add_One drop_bit_Suc)
lemma int_shiftr_numeral_Suc0 [simp]:
"(1 :: int) >> Suc 0 = 0"
"(numeral num.One :: int) >> Suc 0 = 0"
"(numeral (num.Bit0 w) :: int) >> Suc 0 = numeral w"
"(numeral (num.Bit1 w) :: int) >> Suc 0 = numeral w"
"(- numeral (num.Bit0 w) :: int) >> Suc 0 = - numeral w"
"(- numeral (num.Bit1 w) :: int) >> Suc 0 = - numeral (Num.inc w)"
by (simp_all add: shiftr_eq_drop_bit drop_bit_Suc add_One)
lemma bin_nth_minus_p2:
assumes sign: "bin_sign x = 0"
and y: "y = 1 << n"
and m: "m < n"
and x: "x < y"
shows "bin_nth (x - y) m = bin_nth x m"
proof -
from sign y x have \<open>x \<ge> 0\<close> and \<open>y = 2 ^ n\<close> and \<open>x < 2 ^ n\<close>
by (simp_all add: bin_sign_def shiftl_eq_push_bit push_bit_eq_mult split: if_splits)
from \<open>0 \<le> x\<close> \<open>x < 2 ^ n\<close> \<open>m < n\<close> have \<open>bit x m \<longleftrightarrow> bit (x - 2 ^ n) m\<close>
proof (induction m arbitrary: x n)
case 0
then show ?case
by simp
next
case (Suc m)
moreover define q where \<open>q = n - 1\<close>
ultimately have n: \<open>n = Suc q\<close>
by simp
have \<open>(x - 2 ^ Suc q) div 2 = x div 2 - 2 ^ q\<close>
by simp
moreover from Suc.IH [of \<open>x div 2\<close> q] Suc.prems
have \<open>bit (x div 2) m \<longleftrightarrow> bit (x div 2 - 2 ^ q) m\<close>
by (simp add: n)
ultimately show ?case
by (simp add: bit_Suc n)
qed
with \<open>y = 2 ^ n\<close> show ?thesis
by simp
qed
lemma bin_clr_conv_NAND:
"bin_sc n False i = i AND NOT (1 << n)"
by (induct n arbitrary: i) (rule bin_rl_eqI; simp)+
lemma bin_set_conv_OR:
"bin_sc n True i = i OR (1 << n)"
by (induct n arbitrary: i) (rule bin_rl_eqI; simp)+
lemma msb_conv_bin_sign: "msb x \<longleftrightarrow> bin_sign x = -1"
by(simp add: bin_sign_def not_le msb_int_def)
lemma msb_bin_rest [simp]: "msb (bin_rest x) = msb x"
by(simp add: msb_int_def)
lemma int_msb_and [simp]: "msb ((x :: int) AND y) \<longleftrightarrow> msb x \<and> msb y"
by(simp add: msb_int_def)
lemma int_msb_or [simp]: "msb ((x :: int) OR y) \<longleftrightarrow> msb x \<or> msb y"
by(simp add: msb_int_def)
lemma int_msb_xor [simp]: "msb ((x :: int) XOR y) \<longleftrightarrow> msb x \<noteq> msb y"
by(simp add: msb_int_def)
lemma int_msb_not [simp]: "msb (NOT (x :: int)) \<longleftrightarrow> \<not> msb x"
by(simp add: msb_int_def not_less)
lemma msb_shiftl [simp]: "msb ((x :: int) << n) \<longleftrightarrow> msb x"
by(simp add: msb_int_def)
lemma msb_shiftr [simp]: "msb ((x :: int) >> r) \<longleftrightarrow> msb x"
by(simp add: msb_int_def)
lemma msb_bin_sc [simp]: "msb (bin_sc n b x) \<longleftrightarrow> msb x"
by(simp add: msb_conv_bin_sign)
lemma msb_set_bit [simp]: "msb (set_bit (x :: int) n b) \<longleftrightarrow> msb x"
by(simp add: msb_conv_bin_sign set_bit_int_def)
lemma msb_0 [simp]: "msb (0 :: int) = False"
by(simp add: msb_int_def)
lemma msb_1 [simp]: "msb (1 :: int) = False"
by(simp add: msb_int_def)
lemma msb_numeral [simp]:
"msb (numeral n :: int) = False"
"msb (- numeral n :: int) = True"
by(simp_all add: msb_int_def)
subsection \<open>Semantic interpretation of \<^typ>\<open>bool list\<close> as \<^typ>\<open>int\<close>\<close>
lemma bin_bl_bin': "bl_to_bin (bin_to_bl_aux n w bs) = bl_to_bin_aux bs (bintrunc n w)"
by (induct n arbitrary: w bs) (auto simp: bl_to_bin_def take_bit_Suc ac_simps mod_2_eq_odd)
lemma bin_bl_bin [simp]: "bl_to_bin (bin_to_bl n w) = bintrunc n w"
by (auto simp: bin_to_bl_def bin_bl_bin')
lemma bl_to_bin_rep_F: "bl_to_bin (replicate n False @ bl) = bl_to_bin bl"
by (simp add: bin_to_bl_zero_aux [symmetric] bin_bl_bin') (simp add: bl_to_bin_def)
lemma bin_to_bl_trunc [simp]: "n \<le> m \<Longrightarrow> bin_to_bl n (bintrunc m w) = bin_to_bl n w"
by (auto intro: bl_to_bin_inj)
lemma bin_to_bl_aux_bintr:
"bin_to_bl_aux n (bintrunc m bin) bl =
replicate (n - m) False @ bin_to_bl_aux (min n m) bin bl"
apply (induct n arbitrary: m bin bl)
apply clarsimp
apply clarsimp
apply (case_tac "m")
apply (clarsimp simp: bin_to_bl_zero_aux)
apply (erule thin_rl)
apply (induct_tac n)
apply (auto simp add: take_bit_Suc)
done
lemma bin_to_bl_bintr:
"bin_to_bl n (bintrunc m bin) = replicate (n - m) False @ bin_to_bl (min n m) bin"
unfolding bin_to_bl_def by (rule bin_to_bl_aux_bintr)
lemma bl_to_bin_rep_False: "bl_to_bin (replicate n False) = 0"
by (induct n) auto
lemma len_bin_to_bl_aux: "length (bin_to_bl_aux n w bs) = n + length bs"
by (fact size_bin_to_bl_aux)
lemma len_bin_to_bl: "length (bin_to_bl n w) = n"
by (fact size_bin_to_bl) (* FIXME: duplicate *)
lemma sign_bl_bin': "bin_sign (bl_to_bin_aux bs w) = bin_sign w"
by (induction bs arbitrary: w) (simp_all add: bin_sign_def)
lemma sign_bl_bin: "bin_sign (bl_to_bin bs) = 0"
by (simp add: bl_to_bin_def sign_bl_bin')
lemma bl_sbin_sign_aux: "hd (bin_to_bl_aux (Suc n) w bs) = (bin_sign (sbintrunc n w) = -1)"
by (induction n arbitrary: w bs) (simp_all add: bin_sign_def)
lemma bl_sbin_sign: "hd (bin_to_bl (Suc n) w) = (bin_sign (sbintrunc n w) = -1)"
unfolding bin_to_bl_def by (rule bl_sbin_sign_aux)
lemma bin_nth_of_bl_aux:
"bin_nth (bl_to_bin_aux bl w) n =
(n < size bl \<and> rev bl ! n \<or> n \<ge> length bl \<and> bin_nth w (n - size bl))"
apply (induction bl arbitrary: w)
apply simp_all
apply safe
apply (simp_all add: not_le nth_append bit_double_iff even_bit_succ_iff split: if_splits)
done
lemma bin_nth_of_bl: "bin_nth (bl_to_bin bl) n = (n < length bl \<and> rev bl ! n)"
by (simp add: bl_to_bin_def bin_nth_of_bl_aux)
lemma bin_nth_bl: "n < m \<Longrightarrow> bin_nth w n = nth (rev (bin_to_bl m w)) n"
apply (induct n arbitrary: m w)
apply clarsimp
apply (case_tac m, clarsimp)
apply (clarsimp simp: bin_to_bl_def)
apply (simp add: bin_to_bl_aux_alt)
apply (case_tac m, clarsimp)
apply (clarsimp simp: bin_to_bl_def)
apply (simp add: bin_to_bl_aux_alt bit_Suc)
done
lemma nth_bin_to_bl_aux:
"n < m + length bl \<Longrightarrow> (bin_to_bl_aux m w bl) ! n =
(if n < m then bin_nth w (m - 1 - n) else bl ! (n - m))"
apply (induction bl arbitrary: w)
apply simp_all
apply (metis add.right_neutral bin_nth_bl bin_to_bl_def diff_Suc_less less_Suc_eq_0_disj less_imp_Suc_add list.size(3) nth_rev_alt size_bin_to_bl_aux)
apply (metis One_nat_def Suc_pred add_diff_cancel_left' add_diff_cancel_right' bin_to_bl_aux_alt bin_to_bl_def cancel_comm_monoid_add_class.diff_cancel diff_Suc_Suc diff_is_0_eq diff_zero le_add_diff_inverse le_eq_less_or_eq less_Suc_eq_0_disj less_antisym less_imp_Suc_add list.size(3) nat_less_le nth_append order_refl size_bin_to_bl_aux)
done
lemma nth_bin_to_bl: "n < m \<Longrightarrow> (bin_to_bl m w) ! n = bin_nth w (m - Suc n)"
by (simp add: bin_to_bl_def nth_bin_to_bl_aux)
lemma bl_to_bin_lt2p_aux: "bl_to_bin_aux bs w < (w + 1) * (2 ^ length bs)"
proof (induction bs arbitrary: w)
case Nil
then show ?case
by simp
next
case (Cons b bs)
from Cons.IH [of \<open>1 + 2 * w\<close>] Cons.IH [of \<open>2 * w\<close>]
show ?case
apply (auto simp add: algebra_simps)
apply (subst mult_2 [of \<open>2 ^ length bs\<close>])
apply (simp only: add.assoc)
apply (rule pos_add_strict)
apply simp_all
done
qed
lemma bl_to_bin_lt2p_drop: "bl_to_bin bs < 2 ^ length (dropWhile Not bs)"
proof (induct bs)
case Nil
then show ?case by simp
next
case (Cons b bs)
with bl_to_bin_lt2p_aux[where w=1] show ?case
by (simp add: bl_to_bin_def)
qed
lemma bl_to_bin_lt2p: "bl_to_bin bs < 2 ^ length bs"
by (metis bin_bl_bin bintr_lt2p bl_bin_bl)
lemma bl_to_bin_ge2p_aux: "bl_to_bin_aux bs w \<ge> w * (2 ^ length bs)"
proof (induction bs arbitrary: w)
case Nil
then show ?case
by simp
next
case (Cons b bs)
from Cons.IH [of \<open>1 + 2 * w\<close>] Cons.IH [of \<open>2 * w\<close>]
show ?case
apply (auto simp add: algebra_simps)
apply (rule add_le_imp_le_left [of \<open>2 ^ length bs\<close>])
apply (rule add_increasing)
apply simp_all
done
qed
lemma bl_to_bin_ge0: "bl_to_bin bs \<ge> 0"
apply (unfold bl_to_bin_def)
apply (rule xtrans(4))
apply (rule bl_to_bin_ge2p_aux)
apply simp
done
lemma butlast_rest_bin: "butlast (bin_to_bl n w) = bin_to_bl (n - 1) (bin_rest w)"
apply (unfold bin_to_bl_def)
apply (cases n, clarsimp)
apply clarsimp
apply (auto simp add: bin_to_bl_aux_alt)
done
lemma butlast_bin_rest: "butlast bl = bin_to_bl (length bl - Suc 0) (bin_rest (bl_to_bin bl))"
using butlast_rest_bin [where w="bl_to_bin bl" and n="length bl"] by simp
lemma butlast_rest_bl2bin_aux:
"bl \<noteq> [] \<Longrightarrow> bl_to_bin_aux (butlast bl) w = bin_rest (bl_to_bin_aux bl w)"
by (induct bl arbitrary: w) auto
lemma butlast_rest_bl2bin: "bl_to_bin (butlast bl) = bin_rest (bl_to_bin bl)"
by (cases bl) (auto simp: bl_to_bin_def butlast_rest_bl2bin_aux)
lemma trunc_bl2bin_aux:
"bintrunc m (bl_to_bin_aux bl w) =
bl_to_bin_aux (drop (length bl - m) bl) (bintrunc (m - length bl) w)"
proof (induct bl arbitrary: w)
case Nil
show ?case by simp
next
case (Cons b bl)
show ?case
proof (cases "m - length bl")
case 0
then have "Suc (length bl) - m = Suc (length bl - m)" by simp
with Cons show ?thesis by simp
next
case (Suc n)
then have "m - Suc (length bl) = n" by simp
with Cons Suc show ?thesis by (simp add: take_bit_Suc ac_simps)
qed
qed
lemma trunc_bl2bin: "bintrunc m (bl_to_bin bl) = bl_to_bin (drop (length bl - m) bl)"
by (simp add: bl_to_bin_def trunc_bl2bin_aux)
lemma trunc_bl2bin_len [simp]: "bintrunc (length bl) (bl_to_bin bl) = bl_to_bin bl"
by (simp add: trunc_bl2bin)
lemma bl2bin_drop: "bl_to_bin (drop k bl) = bintrunc (length bl - k) (bl_to_bin bl)"
apply (rule trans)
prefer 2
apply (rule trunc_bl2bin [symmetric])
apply (cases "k \<le> length bl")
apply auto
done
lemma take_rest_power_bin: "m \<le> n \<Longrightarrow> take m (bin_to_bl n w) = bin_to_bl m ((bin_rest ^^ (n - m)) w)"
apply (rule nth_equalityI)
apply simp
apply (clarsimp simp add: nth_bin_to_bl nth_rest_power_bin)
done
lemma last_bin_last': "size xs > 0 \<Longrightarrow> last xs \<longleftrightarrow> bin_last (bl_to_bin_aux xs w)"
by (induct xs arbitrary: w) auto
lemma last_bin_last: "size xs > 0 \<Longrightarrow> last xs \<longleftrightarrow> bin_last (bl_to_bin xs)"
unfolding bl_to_bin_def by (erule last_bin_last')
lemma bin_last_last: "bin_last w \<longleftrightarrow> last (bin_to_bl (Suc n) w)"
by (simp add: bin_to_bl_def) (auto simp: bin_to_bl_aux_alt)
lemma drop_bin2bl_aux:
"drop m (bin_to_bl_aux n bin bs) =
bin_to_bl_aux (n - m) bin (drop (m - n) bs)"
apply (induction n arbitrary: m bin bs)
apply auto
apply (case_tac "m \<le> n")
apply (auto simp add: not_le Suc_diff_le)
apply (case_tac "m - n")
apply auto
apply (use Suc_diff_Suc in fastforce)
done
lemma drop_bin2bl: "drop m (bin_to_bl n bin) = bin_to_bl (n - m) bin"
by (simp add: bin_to_bl_def drop_bin2bl_aux)
lemma take_bin2bl_lem1: "take m (bin_to_bl_aux m w bs) = bin_to_bl m w"
apply (induct m arbitrary: w bs)
apply clarsimp
apply clarsimp
apply (simp add: bin_to_bl_aux_alt)
apply (simp add: bin_to_bl_def)
apply (simp add: bin_to_bl_aux_alt)
done
lemma take_bin2bl_lem: "take m (bin_to_bl_aux (m + n) w bs) = take m (bin_to_bl (m + n) w)"
by (induct n arbitrary: w bs) (simp_all (no_asm) add: bin_to_bl_def take_bin2bl_lem1, simp)
lemma bin_split_take: "bin_split n c = (a, b) \<Longrightarrow> bin_to_bl m a = take m (bin_to_bl (m + n) c)"
apply (induct n arbitrary: b c)
apply clarsimp
apply (clarsimp simp: Let_def split: prod.split_asm)
apply (simp add: bin_to_bl_def)
apply (simp add: take_bin2bl_lem drop_bit_Suc)
done
lemma bin_to_bl_drop_bit:
"k = m + n \<Longrightarrow> bin_to_bl m (drop_bit n c) = take m (bin_to_bl k c)"
using bin_split_take by simp
lemma bin_split_take1:
"k = m + n \<Longrightarrow> bin_split n c = (a, b) \<Longrightarrow> bin_to_bl m a = take m (bin_to_bl k c)"
using bin_split_take by simp
lemma takefill_bintrunc: "takefill False n bl = rev (bin_to_bl n (bl_to_bin (rev bl)))"
apply (rule nth_equalityI)
apply simp
apply (clarsimp simp: nth_takefill nth_rev nth_bin_to_bl bin_nth_of_bl)
done
lemma bl_bin_bl_rtf: "bin_to_bl n (bl_to_bin bl) = rev (takefill False n (rev bl))"
by (simp add: takefill_bintrunc)
lemma bl_bin_bl_rep_drop:
"bin_to_bl n (bl_to_bin bl) =
replicate (n - length bl) False @ drop (length bl - n) bl"
by (simp add: bl_bin_bl_rtf takefill_alt rev_take)
lemma bl_to_bin_aux_cat:
"bl_to_bin_aux bs (bin_cat w nv v) =
bin_cat w (nv + length bs) (bl_to_bin_aux bs v)"
by (rule bit_eqI)
(auto simp add: bin_nth_of_bl_aux bin_nth_cat algebra_simps)
lemma bin_to_bl_aux_cat:
"\<And>w bs. bin_to_bl_aux (nv + nw) (bin_cat v nw w) bs =
bin_to_bl_aux nv v (bin_to_bl_aux nw w bs)"
by (induct nw) auto
lemma bl_to_bin_aux_alt: "bl_to_bin_aux bs w = bin_cat w (length bs) (bl_to_bin bs)"
using bl_to_bin_aux_cat [where nv = "0" and v = "0"]
by (simp add: bl_to_bin_def [symmetric])
lemma bin_to_bl_cat:
"bin_to_bl (nv + nw) (bin_cat v nw w) =
bin_to_bl_aux nv v (bin_to_bl nw w)"
by (simp add: bin_to_bl_def bin_to_bl_aux_cat)
lemmas bl_to_bin_aux_app_cat =
trans [OF bl_to_bin_aux_append bl_to_bin_aux_alt]
lemmas bin_to_bl_aux_cat_app =
trans [OF bin_to_bl_aux_cat bin_to_bl_aux_alt]
lemma bl_to_bin_app_cat:
"bl_to_bin (bsa @ bs) = bin_cat (bl_to_bin bsa) (length bs) (bl_to_bin bs)"
by (simp only: bl_to_bin_aux_app_cat bl_to_bin_def)
lemma bin_to_bl_cat_app:
"bin_to_bl (n + nw) (bin_cat w nw wa) = bin_to_bl n w @ bin_to_bl nw wa"
by (simp only: bin_to_bl_def bin_to_bl_aux_cat_app)
text \<open>\<open>bl_to_bin_app_cat_alt\<close> and \<open>bl_to_bin_app_cat\<close> are easily interderivable.\<close>
lemma bl_to_bin_app_cat_alt: "bin_cat (bl_to_bin cs) n w = bl_to_bin (cs @ bin_to_bl n w)"
by (simp add: bl_to_bin_app_cat)
lemma mask_lem: "(bl_to_bin (True # replicate n False)) = bl_to_bin (replicate n True) + 1"
apply (unfold bl_to_bin_def)
apply (induct n)
apply simp
apply (simp only: Suc_eq_plus1 replicate_add append_Cons [symmetric] bl_to_bin_aux_append)
apply simp
done
lemma bin_exhaust:
"(\<And>x b. bin = of_bool b + 2 * x \<Longrightarrow> Q) \<Longrightarrow> Q" for bin :: int
apply (cases \<open>even bin\<close>)
apply (auto elim!: evenE oddE)
apply fastforce
apply fastforce
done
primrec rbl_succ :: "bool list \<Rightarrow> bool list"
where
Nil: "rbl_succ Nil = Nil"
| Cons: "rbl_succ (x # xs) = (if x then False # rbl_succ xs else True # xs)"
primrec rbl_pred :: "bool list \<Rightarrow> bool list"
where
Nil: "rbl_pred Nil = Nil"
| Cons: "rbl_pred (x # xs) = (if x then False # xs else True # rbl_pred xs)"
primrec rbl_add :: "bool list \<Rightarrow> bool list \<Rightarrow> bool list"
where \<comment> \<open>result is length of first arg, second arg may be longer\<close>
Nil: "rbl_add Nil x = Nil"
| Cons: "rbl_add (y # ys) x =
(let ws = rbl_add ys (tl x)
in (y \<noteq> hd x) # (if hd x \<and> y then rbl_succ ws else ws))"
primrec rbl_mult :: "bool list \<Rightarrow> bool list \<Rightarrow> bool list"
where \<comment> \<open>result is length of first arg, second arg may be longer\<close>
Nil: "rbl_mult Nil x = Nil"
| Cons: "rbl_mult (y # ys) x =
(let ws = False # rbl_mult ys x
in if y then rbl_add ws x else ws)"
lemma size_rbl_pred: "length (rbl_pred bl) = length bl"
by (induct bl) auto
lemma size_rbl_succ: "length (rbl_succ bl) = length bl"
by (induct bl) auto
lemma size_rbl_add: "length (rbl_add bl cl) = length bl"
by (induct bl arbitrary: cl) (auto simp: Let_def size_rbl_succ)
lemma size_rbl_mult: "length (rbl_mult bl cl) = length bl"
by (induct bl arbitrary: cl) (auto simp add: Let_def size_rbl_add)
lemmas rbl_sizes [simp] =
size_rbl_pred size_rbl_succ size_rbl_add size_rbl_mult
lemmas rbl_Nils =
rbl_pred.Nil rbl_succ.Nil rbl_add.Nil rbl_mult.Nil
lemma rbl_add_app2: "length blb \<ge> length bla \<Longrightarrow> rbl_add bla (blb @ blc) = rbl_add bla blb"
apply (induct bla arbitrary: blb)
apply simp
apply clarsimp
apply (case_tac blb, clarsimp)
apply (clarsimp simp: Let_def)
done
lemma rbl_add_take2:
"length blb \<ge> length bla \<Longrightarrow> rbl_add bla (take (length bla) blb) = rbl_add bla blb"
apply (induct bla arbitrary: blb)
apply simp
apply clarsimp
apply (case_tac blb, clarsimp)
apply (clarsimp simp: Let_def)
done
lemma rbl_mult_app2: "length blb \<ge> length bla \<Longrightarrow> rbl_mult bla (blb @ blc) = rbl_mult bla blb"
apply (induct bla arbitrary: blb)
apply simp
apply clarsimp
apply (case_tac blb, clarsimp)
apply (clarsimp simp: Let_def rbl_add_app2)
done
lemma rbl_mult_take2:
"length blb \<ge> length bla \<Longrightarrow> rbl_mult bla (take (length bla) blb) = rbl_mult bla blb"
apply (rule trans)
apply (rule rbl_mult_app2 [symmetric])
apply simp
apply (rule_tac f = "rbl_mult bla" in arg_cong)
apply (rule append_take_drop_id)
done
lemma rbl_add_split:
"P (rbl_add (y # ys) (x # xs)) =
(\<forall>ws. length ws = length ys \<longrightarrow> ws = rbl_add ys xs \<longrightarrow>
(y \<longrightarrow> ((x \<longrightarrow> P (False # rbl_succ ws)) \<and> (\<not> x \<longrightarrow> P (True # ws)))) \<and>
(\<not> y \<longrightarrow> P (x # ws)))"
by (cases y) (auto simp: Let_def)
lemma rbl_mult_split:
"P (rbl_mult (y # ys) xs) =
(\<forall>ws. length ws = Suc (length ys) \<longrightarrow> ws = False # rbl_mult ys xs \<longrightarrow>
(y \<longrightarrow> P (rbl_add ws xs)) \<and> (\<not> y \<longrightarrow> P ws))"
by (auto simp: Let_def)
lemma rbl_pred: "rbl_pred (rev (bin_to_bl n bin)) = rev (bin_to_bl n (bin - 1))"
proof (unfold bin_to_bl_def, induction n arbitrary: bin)
case 0
then show ?case
by simp
next
case (Suc n)
obtain b k where \<open>bin = of_bool b + 2 * k\<close>
using bin_exhaust by blast
moreover have \<open>(2 * k - 1) div 2 = k - 1\<close>
using even_succ_div_2 [of \<open>2 * (k - 1)\<close>]
by simp
ultimately show ?case
using Suc [of \<open>bin div 2\<close>]
by simp (simp add: bin_to_bl_aux_alt)
qed
lemma rbl_succ: "rbl_succ (rev (bin_to_bl n bin)) = rev (bin_to_bl n (bin + 1))"
apply (unfold bin_to_bl_def)
apply (induction n arbitrary: bin)
apply simp_all
apply (case_tac bin rule: bin_exhaust)
apply simp
apply (simp add: bin_to_bl_aux_alt ac_simps)
done
lemma rbl_add:
"\<And>bina binb. rbl_add (rev (bin_to_bl n bina)) (rev (bin_to_bl n binb)) =
rev (bin_to_bl n (bina + binb))"
apply (unfold bin_to_bl_def)
apply (induct n)
apply simp
apply clarsimp
apply (case_tac bina rule: bin_exhaust)
apply (case_tac binb rule: bin_exhaust)
apply (case_tac b)
apply (case_tac [!] "ba")
apply (auto simp: rbl_succ bin_to_bl_aux_alt Let_def ac_simps)
done
lemma rbl_add_long:
"m \<ge> n \<Longrightarrow> rbl_add (rev (bin_to_bl n bina)) (rev (bin_to_bl m binb)) =
rev (bin_to_bl n (bina + binb))"
apply (rule box_equals [OF _ rbl_add_take2 rbl_add])
apply (rule_tac f = "rbl_add (rev (bin_to_bl n bina))" in arg_cong)
apply (rule rev_swap [THEN iffD1])
apply (simp add: rev_take drop_bin2bl)
apply simp
done
lemma rbl_mult_gt1:
"m \<ge> length bl \<Longrightarrow>
rbl_mult bl (rev (bin_to_bl m binb)) =
rbl_mult bl (rev (bin_to_bl (length bl) binb))"
apply (rule trans)
apply (rule rbl_mult_take2 [symmetric])
apply simp_all
apply (rule_tac f = "rbl_mult bl" in arg_cong)
apply (rule rev_swap [THEN iffD1])
apply (simp add: rev_take drop_bin2bl)
done
lemma rbl_mult_gt:
"m > n \<Longrightarrow>
rbl_mult (rev (bin_to_bl n bina)) (rev (bin_to_bl m binb)) =
rbl_mult (rev (bin_to_bl n bina)) (rev (bin_to_bl n binb))"
by (auto intro: trans [OF rbl_mult_gt1])
lemmas rbl_mult_Suc = lessI [THEN rbl_mult_gt]
lemma rbbl_Cons: "b # rev (bin_to_bl n x) = rev (bin_to_bl (Suc n) (of_bool b + 2 * x))"
by (simp add: bin_to_bl_def) (simp add: bin_to_bl_aux_alt)
lemma rbl_mult:
"rbl_mult (rev (bin_to_bl n bina)) (rev (bin_to_bl n binb)) =
rev (bin_to_bl n (bina * binb))"
apply (induct n arbitrary: bina binb)
apply simp_all
apply (unfold bin_to_bl_def)
apply clarsimp
apply (case_tac bina rule: bin_exhaust)
apply (case_tac binb rule: bin_exhaust)
apply simp
apply (simp add: bin_to_bl_aux_alt)
apply (simp add: rbbl_Cons rbl_mult_Suc rbl_add algebra_simps)
done
lemma sclem: "size (concat (map (bin_to_bl n) xs)) = length xs * n"
by (induct xs) auto
lemma bin_cat_foldl_lem:
"foldl (\<lambda>u. bin_cat u n) x xs =
bin_cat x (size xs * n) (foldl (\<lambda>u. bin_cat u n) y xs)"
apply (induct xs arbitrary: x)
apply simp
apply (simp (no_asm))
apply (frule asm_rl)
apply (drule meta_spec)
apply (erule trans)
apply (drule_tac x = "bin_cat y n a" in meta_spec)
apply (simp add: bin_cat_assoc_sym min.absorb2)
done
lemma bin_rcat_bl: "bin_rcat n wl = bl_to_bin (concat (map (bin_to_bl n) wl))"
apply (unfold bin_rcat_def)
apply (rule sym)
apply (induct wl)
apply (auto simp add: bl_to_bin_append)
apply (simp add: bl_to_bin_aux_alt sclem)
apply (simp add: bin_cat_foldl_lem [symmetric])
done
lemma bin_last_bl_to_bin: "bin_last (bl_to_bin bs) \<longleftrightarrow> bs \<noteq> [] \<and> last bs"
by(cases "bs = []")(auto simp add: bl_to_bin_def last_bin_last'[where w=0])
lemma bin_rest_bl_to_bin: "bin_rest (bl_to_bin bs) = bl_to_bin (butlast bs)"
by(cases "bs = []")(simp_all add: bl_to_bin_def butlast_rest_bl2bin_aux)
lemma bl_xor_aux_bin:
"map2 (\<lambda>x y. x \<noteq> y) (bin_to_bl_aux n v bs) (bin_to_bl_aux n w cs) =
bin_to_bl_aux n (v XOR w) (map2 (\<lambda>x y. x \<noteq> y) bs cs)"
apply (induction n arbitrary: v w bs cs)
apply auto
apply (case_tac v rule: bin_exhaust)
apply (case_tac w rule: bin_exhaust)
apply clarsimp
done
lemma bl_or_aux_bin:
"map2 (\<or>) (bin_to_bl_aux n v bs) (bin_to_bl_aux n w cs) =
bin_to_bl_aux n (v OR w) (map2 (\<or>) bs cs)"
by (induct n arbitrary: v w bs cs) simp_all
lemma bl_and_aux_bin:
"map2 (\<and>) (bin_to_bl_aux n v bs) (bin_to_bl_aux n w cs) =
bin_to_bl_aux n (v AND w) (map2 (\<and>) bs cs)"
by (induction n arbitrary: v w bs cs) simp_all
lemma bl_not_aux_bin: "map Not (bin_to_bl_aux n w cs) = bin_to_bl_aux n (NOT w) (map Not cs)"
by (induct n arbitrary: w cs) auto
lemma bl_not_bin: "map Not (bin_to_bl n w) = bin_to_bl n (NOT w)"
by (simp add: bin_to_bl_def bl_not_aux_bin)
lemma bl_and_bin: "map2 (\<and>) (bin_to_bl n v) (bin_to_bl n w) = bin_to_bl n (v AND w)"
by (simp add: bin_to_bl_def bl_and_aux_bin)
lemma bl_or_bin: "map2 (\<or>) (bin_to_bl n v) (bin_to_bl n w) = bin_to_bl n (v OR w)"
by (simp add: bin_to_bl_def bl_or_aux_bin)
lemma bl_xor_bin: "map2 (\<noteq>) (bin_to_bl n v) (bin_to_bl n w) = bin_to_bl n (v XOR w)"
using bl_xor_aux_bin by (simp add: bin_to_bl_def)
end