3

Consider the following silly Isabelle definition of trees and subtrees:

datatype tree = Leaf int
              | Node tree tree

fun children :: "tree ⇒ tree set" where
"children (Leaf _) = {}" |
"children (Node a b) = {a, b}"

lemma children_decreasing_size:
  assumes "c ∈ children t"
  shows   "size c < size t"
using assms
by (induction t, auto)

function subtrees :: "tree ⇒ tree set" where
"subtrees t = { s | c s. c ∈ children t ∧ s ∈ subtrees c }"
by auto
termination
apply (relation "measure size", simp)

The termination proof of subtrees gets stuck at this point although the recursive calls are only ever made on children, which are strictly smaller by the well-founded size relation (as the trivial lemma shows).

The proof state is as follows:

goal (1 subgoal):
 1. ⋀t x xa xb. (xa, t) ∈ measure size

This is impossible to prove, of course, since the information that xa is a child of t is lost. Did I do something wrong? Is there anything I can do to save the proof? I note that I can formulate the same definition using lists instead of sets:

fun children_list :: "tree ⇒ tree list" where
"children_list (Leaf _) = []" |
"children_list (Node a b) = [a, b]"

function subtrees_list :: "tree ⇒ tree list" where
"subtrees_list t = concat (map subtrees_list (children_list t))"
by auto
termination
apply (relation "measure size", simp)

and get a more informative, provable termination goal:

goal (1 subgoal):
 1. ⋀t x.
       x ∈ set (children_list t) ⟹
       (x, t) ∈ measure size

Is this some limitation in Isabelle that I should just work around by not using sets for this?

2
  • 1
    Are you aware that, according to your definition, subtrees always returns the empty set? Oct 28, 2015 at 6:46
  • Heh, good catch. This was simplified (too much) from something more complex I'm trying to do. Oct 28, 2015 at 20:11

1 Answer 1

3

The restriction to c : children t in the set comprehension for subtrees does not show up in the termination proof obligation, because the function package does not know anything a priori about &. Congruence rules can be used to achieve this. In this case, you can locally declare conj_cong as [fundef_cong] to essentially emulate a left-to-right evaluation order (although there is no such thing as evaluation in HOL). For example,

context notes conj_cong[fundef_cong] begin
fun subtrees :: ...
termination ...
end

The context block ensures that the declaration conj_cong[fundef_cong] is only in effect for this function definition.

The version with lists works because it uses the function map for which there is a congruence rule in place by default. The same should have worked for sets, if you had used the monadic bind operation on sets (rather than a set comprehension).

5
  • Another definition that works: subtrees t = (⋃c∈children t. subtrees c). However, I would argue that a primitively-recursive definition is probably easier to work with. Oct 28, 2015 at 6:45
  • @Manuel Eberl: Union is the monadic bind for sets, so your suggestion is exactly what i was referring to in my last sentence. Oct 28, 2015 at 11:57
  • Oh, right. of course. I didn't notice that. In any case, it may not be obvious to all readers. Oct 28, 2015 at 12:39
  • Thanks to both of you. After sleeping on it, I did also come up with the idea of using (⋃c∈children t. subtrees c), although I wouldn't have guessed that this is what "monadic bind" meant in this context. So thanks for the clarification. Oct 28, 2015 at 20:10
  • Actually, to be precise, Union is the monadic join for sets. But bind, can, of course be defined using join and map, where map is the set image operation. Oct 30, 2015 at 7:22

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