(* Title: HOL/ex/Adder.thy
ID: $Id$
Author: Sergey Tverdyshev (Universitaet des Saarlandes)
*)
header {* Implementation of carry chain incrementor and adder *}
theory Adder imports Main Word begin
lemma [simp]: "bv_to_nat [b] = bitval b"
by (simp add: bv_to_nat_helper)
lemma bv_to_nat_helper':
"bv \<noteq> [] ==> bv_to_nat bv = bitval (hd bv) * 2 ^ (length bv - 1) + bv_to_nat (tl bv)"
by (cases bv) (simp_all add: bv_to_nat_helper)
definition
half_adder :: "[bit, bit] => bit list" where
"half_adder a b = [a bitand b, a bitxor b]"
lemma half_adder_correct: "bv_to_nat (half_adder a b) = bitval a + bitval b"
apply (simp add: half_adder_def)
apply (cases a, auto)
apply (cases b, auto)
done
lemma [simp]: "length (half_adder a b) = 2"
by (simp add: half_adder_def)
definition
full_adder :: "[bit, bit, bit] => bit list" where
"full_adder a b c =
(let x = a bitxor b in [a bitand b bitor c bitand x, x bitxor c])"
lemma full_adder_correct:
"bv_to_nat (full_adder a b c) = bitval a + bitval b + bitval c"
apply (simp add: full_adder_def Let_def)
apply (cases a, auto)
apply (case_tac [!] b, auto)
apply (case_tac [!] c, auto)
done
lemma [simp]: "length (full_adder a b c) = 2"
by (simp add: full_adder_def Let_def)
subsection {* Carry chain incrementor *}
consts
carry_chain_inc :: "[bit list, bit] => bit list"
primrec
"carry_chain_inc [] c = [c]"
"carry_chain_inc (a#as) c =
(let chain = carry_chain_inc as c
in half_adder a (hd chain) @ tl chain)"
lemma cci_nonnull: "carry_chain_inc as c \<noteq> []"
by (cases as) (auto simp add: Let_def half_adder_def)
lemma cci_length [simp]: "length (carry_chain_inc as c) = length as + 1"
by (induct as) (simp_all add: Let_def)
lemma cci_correct: "bv_to_nat (carry_chain_inc as c) = bv_to_nat as + bitval c"
apply (induct as)
apply (cases c, simp_all add: Let_def bv_to_nat_dist_append)
apply (simp add: half_adder_correct bv_to_nat_helper' [OF cci_nonnull]
ring_distribs bv_to_nat_helper)
done
consts
carry_chain_adder :: "[bit list, bit list, bit] => bit list"
primrec
"carry_chain_adder [] bs c = [c]"
"carry_chain_adder (a # as) bs c =
(let chain = carry_chain_adder as (tl bs) c
in full_adder a (hd bs) (hd chain) @ tl chain)"
lemma cca_nonnull: "carry_chain_adder as bs c \<noteq> []"
by (cases as) (auto simp add: full_adder_def Let_def)
lemma cca_length: "length as = length bs \<Longrightarrow>
length (carry_chain_adder as bs c) = Suc (length bs)"
by (induct as arbitrary: bs) (auto simp add: Let_def)
theorem cca_correct:
"length as = length bs \<Longrightarrow>
bv_to_nat (carry_chain_adder as bs c) =
bv_to_nat as + bv_to_nat bs + bitval c"
proof (induct as arbitrary: bs)
case Nil
then show ?case by simp
next
case (Cons a as xs)
note ind = Cons.hyps
from Cons.prems have len: "Suc (length as) = length xs" by simp
show ?case
proof (cases xs)
case Nil
with len show ?thesis by simp
next
case (Cons b bs)
with len have len': "length as = length bs" by simp
then have "bv_to_nat (carry_chain_adder as bs c) = bv_to_nat as + bv_to_nat bs + bitval c"
by (rule ind)
with len' and Cons
show ?thesis
apply (simp add: Let_def)
apply (subst bv_to_nat_dist_append)
apply (simp add: full_adder_correct bv_to_nat_helper' [OF cca_nonnull]
ring_distribs bv_to_nat_helper cca_length)
done
qed
qed
end