(* ID: $Id$
Author: Sava Krsti\'{c} and John Matthews
*)
header {* Example use if an inductive invariant to solve termination conditions *}
theory InductiveInvariant_examples imports InductiveInvariant begin
text "A simple example showing how to use an inductive invariant
to solve termination conditions generated by recdef on
nested recursive function definitions."
consts g :: "nat => nat"
recdef (permissive) g "less_than"
"g 0 = 0"
"g (Suc n) = g (g n)"
text "We can prove the unsolved termination condition for
g by showing it is an inductive invariant."
recdef_tc g_tc[simp]: g
apply (rule allI)
apply (rule_tac x=n in tfl_indinv_wfrec [OF g_def])
apply (auto simp add: indinv_def split: nat.split)
apply (frule_tac x=nat in spec)
apply (drule_tac x="f nat" in spec)
by auto
text "This declaration invokes Isabelle's simplifier to
remove any termination conditions before adding
g's rules to the simpset."
declare g.simps [simplified, simp]
text "This is an example where the termination condition generated
by recdef is not itself an inductive invariant."
consts g' :: "nat => nat"
recdef (permissive) g' "less_than"
"g' 0 = 0"
"g' (Suc n) = g' n + g' (g' n)"
thm g'.simps
text "The strengthened inductive invariant is as follows
(this invariant also works for the first example above):"
lemma g'_inv: "g' n = 0"
thm tfl_indinv_wfrec [OF g'_def]
apply (rule_tac x=n in tfl_indinv_wfrec [OF g'_def])
by (auto simp add: indinv_def split: nat.split)
recdef_tc g'_tc[simp]: g'
by (simp add: g'_inv)
text "Now we can remove the termination condition from
the rules for g' ."
thm g'.simps [simplified]
text {* Sometimes a recursive definition is partial, that is, it
is only meant to be invoked on "good" inputs. As a contrived
example, we will define a new version of g that is only
well defined for even inputs greater than zero. *}
consts g_even :: "nat => nat"
recdef (permissive) g_even "less_than"
"g_even (Suc (Suc 0)) = 3"
"g_even n = g_even (g_even (n - 2) - 1)"
text "We can prove a conditional version of the unsolved termination
condition for @{term g_even} by proving a stronger inductive invariant."
lemma g_even_indinv: "\<exists>k. n = Suc (Suc (2*k)) ==> g_even n = 3"
apply (rule_tac D="{n. \<exists>k. n = Suc (Suc (2*k))}" and x=n in tfl_indinv_on_wfrec [OF g_even_def])
apply (auto simp add: indinv_on_def split: nat.split)
by (case_tac ka, auto)
text "Now we can prove that the second recursion equation for @{term g_even}
holds, provided that n is an even number greater than two."
theorem g_even_n: "\<exists>k. n = 2*k + 4 ==> g_even n = g_even (g_even (n - 2) - 1)"
apply (subgoal_tac "(\<exists>k. n - 2 = 2*k + 2) & (\<exists>k. n = 2*k + 2)")
by (auto simp add: g_even_indinv, arith)
text "McCarthy's ninety-one function. This function requires a
non-standard measure to prove termination."
consts ninety_one :: "nat => nat"
recdef (permissive) ninety_one "measure (%n. 101 - n)"
"ninety_one x = (if 100 < x
then x - 10
else (ninety_one (ninety_one (x+11))))"
text "To discharge the termination condition, we will prove
a strengthened inductive invariant:
S x y == x < y + 11"
lemma ninety_one_inv: "n < ninety_one n + 11"
apply (rule_tac x=n in tfl_indinv_wfrec [OF ninety_one_def])
apply force
apply (auto simp add: indinv_def)
apply (frule_tac x="x+11" in spec)
apply (frule_tac x="f (x + 11)" in spec)
by arith
text "Proving the termination condition using the
strengthened inductive invariant."
recdef_tc ninety_one_tc[rule_format]: ninety_one
apply clarify
by (cut_tac n="x+11" in ninety_one_inv, arith)
text "Now we can remove the termination condition from
the simplification rule for @{term ninety_one}."
theorem def_ninety_one:
"ninety_one x = (if 100 < x
then x - 10
else ninety_one (ninety_one (x+11)))"
by (subst ninety_one.simps,
simp add: ninety_one_tc)
end