Theory Queue_2Lists
section ‹Queue Implementation via 2 Lists›
theory Queue_2Lists
imports
Queue_Spec
Reverse
begin
text ‹Definitions:›
type_synonym 'a queue = "'a list × 'a list"
fun norm :: "'a queue ⇒ 'a queue" where
"norm (fs,rs) = (if fs = [] then (itrev rs [], []) else (fs,rs))"
fun enq :: "'a ⇒ 'a queue ⇒ 'a queue" where
"enq a (fs,rs) = norm(fs, a # rs)"
fun deq :: "'a queue ⇒ 'a queue" where
"deq (fs,rs) = (if fs = [] then (fs,rs) else norm(tl fs,rs))"
fun first :: "'a queue ⇒ 'a" where
"first (a # fs,rs) = a"
fun is_empty :: "'a queue ⇒ bool" where
"is_empty (fs,rs) = (fs = [])"
fun list :: "'a queue ⇒ 'a list" where
"list (fs,rs) = fs @ rev rs"
fun invar :: "'a queue ⇒ bool" where
"invar (fs,rs) = (fs = [] ⟶ rs = [])"
text ‹Implementation correctness:›
interpretation Queue
where empty = "([],[])" and enq = enq and deq = deq and first = first
and is_empty = is_empty and list = list and invar = invar
proof (standard, goal_cases)
case 1 show ?case by (simp)
next
case (2 q) thus ?case by(cases q) (simp)
next
case (3 q) thus ?case by(cases q) (simp add: itrev_Nil)
next
case (4 q) thus ?case by(cases q) (auto simp: neq_Nil_conv)
next
case (5 q) thus ?case by(cases q) (auto)
next
case 6 show ?case by(simp)
next
case (7 q) thus ?case by(cases q) (simp)
next
case (8 q) thus ?case by(cases q) (simp)
qed
text ‹Running times:›
time_fun norm
time_fun enq
time_fun tl
time_fun deq
lemma T_tl_0: "T_tl xs = 0"
by(cases xs)auto
text ‹Amortized running times:›
fun Φ :: "'a queue ⇒ nat" where
"Φ(fs,rs) = length rs"
lemma a_enq: "T_enq a (fs,rs) + Φ(enq a (fs,rs)) - Φ(fs,rs) ≤ 2"
by(auto simp: T_itrev)
lemma a_deq: "T_deq (fs,rs) + Φ(deq (fs,rs)) - Φ(fs,rs) ≤ 1"
by(auto simp: T_itrev T_tl_0)
end