Working with Isabelle's code generator: Data refinement and higher order functions

This is a follow-up on Isabelle's Code generation: Abstraction lemmas for containers?:

I want to generate code for `the_question` in the following theory:

``````theory Scratch imports Main begin

typedef small = "{x::nat. x < 10}" morphisms to_nat small
by (rule exI[where x = 0], simp)
code_datatype small
lemma [code abstype]: "small (to_nat x) = x" by (rule to_nat_inverse)

definition a_pred :: "small ⇒ bool"
where "a_pred = undefined"

definition "smaller j = [small i . i <- [0 ..< to_nat j]]"

definition "the_question j = (∀i ∈ set (smaller j). a_pred j)"
``````

The problem is that the equation for `smaller` is not suitable for code generation, as it mentions the abstraction function `small`.

Now according to Andreas’ answer to my last question and the paper on data refinement, the next step is to introduce a type for sets of small numbers, and create a definition for `smaller` in that type:

``````typedef small_list = "{l. ∀x∈ set l. (x::nat) < 10}" by (rule exI[where x = "[]"], auto)
code_datatype Abs_small_list
lemma [code abstype]: "Abs_small_list (Rep_small_list x) = x" by (rule Rep_small_list_inverse)

definition "smaller' j = Abs_small_list [ i . i <- [0 ..< to_nat j]]"
lemma smaller'_code[code abstract]: "Rep_small_list (smaller' j) = [ i . i <- [0 ..< to_nat j]]"
unfolding smaller'_def
by (rule Abs_small_list_inverse, cases j, auto elim: less_trans simp add: small_inverse)
``````

Now `smaller'` is executable. From what I understand I need to redefine operations on `small list` as operations on `small_list`:

``````definition "small_list_all P l = list_all P (map small (Rep_small_list l))"

lemma[code]: "the_question j = small_list_all a_pred (smaller' j)"
unfolding small_list_all_def the_question_def smaller'_code smaller_def Ball_set by simp
``````

I can define a good looking code equation for `the_question`. But the definition of `small_list_all` is not suitable for code generation, as it mentions the abstraction morphism`small`. How do I make `small_list_all` executable?

(Note that I cannot unfold the code equation of `a_pred`, as the problem actually occurs in the code equation of the actually recursive `a_pred`. Also, I’d like to avoid hacks that involve re-checking the invariant at runtime.)

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I don't have a good solution to the general problem, but here's an idea that will let you generate code for `the_question` in this particular case.

First, define a function `predecessor :: "small ⇒ small` with an abstract code equation (possibly using `lift_definition` from `λn::nat. n - 1`).

Now you can prove a new code equation for `smaller` whose rhs uses if-then-else, `predecessor` and normal list operations:

``````lemma smaller_code [code]:
"smaller j = (if to_nat j = 0 then []
else let k = predecessor j in smaller k @ [k])"
``````

(More efficient implementations are of course possible if you're willing to define an auxiliary function.)

Code generation should now work for `smaller`, since this code equation doesn't use function `small`.

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Thanks for the suggestion. I don’t think it works well for my real use case, but at least it’s another work-around to add to my toolbox. –  Joachim Breitner May 1 '13 at 14:22

The short answer is no, it does not work.

The long answer is that there are often workarounds possible. One is shown by Brian in his answer. The general idea seems to be

Separate the function that has the abstract type in covariant positions besides the final return value (i.e. higher order functions or functions returning containers of abstract values) into multiple helper functions so that abstract values are only constructed as a single return value of one of the helper function.

In Brian’s example, this function is `predecessor`. Or, as another simple example, assume a function

``````definition smallPrime :: "nat ⇒ small option"
where "smallPrime n = (if n ∈ {2,3,5,7} then Some (small n) else None)"
``````

This definition is not a valid code equation, due to the occurrence of `small`. But this derives one:

``````definition smallPrimeHelper :: "nat ⇒ small"
where "smallPrimeHelper n = (if n ∈ {2,3,5,7} then small n else small 0)"
lemma [code abstract]: "to_nat (smallPrimeHelper n) = (if n ∈ {2,3,5,7} then n else 0)"
by (auto simp add: smallPrimeHelper_def intro: small_inverse)
lemma [code_unfold]: "smallPrime n = (if n ∈ {2,3,5,7} then Some (smallPrimeHelper n) else None)"
unfolding smallPrime_def smallPrimeHelper_def by simp
``````

If one wants to avoid the redundant calculation of the predicate (which might be more complex than just `∈ {2,3,5,7}`, one can make the return type of the helper smarter by introducing an abstract view, i.e. a type that contains both the result of the computation, and the information needed to construct the abstract type from it:

``````typedef smallPrime_view = "{(x::nat, b::bool). x < 10 ∧ b = (x ∈ {2,3,5,7})}"
by (rule exI[where x = "(2, True)"], auto)
setup_lifting type_definition_small
setup_lifting type_definition_smallPrime_view
``````

For the view we have a function building it and accessors that take the result apart, with some lemmas about them:

``````lift_definition smallPrimeHelper' :: "nat ⇒ smallPrime_view"
is "λ n. if n ∈ {2,3,5,7} then (n, True) else (0, False)" by simp
lift_definition smallPrimeView_pred :: "smallPrime_view ⇒ bool"
is "λ spv :: (nat × bool) . snd spv" by auto
lift_definition smallPrimeView_small :: "smallPrime_view ⇒ small"
is "λ spv :: (nat × bool) . fst spv" by auto
lemma [simp]: "smallPrimeView_pred (smallPrimeHelper' n) ⟷ (n ∈ {2,3,5,7})"
by transfer simp
lemma [simp]: "n ∈ {2,3,5,7} ⟹ to_nat (smallPrimeView_small (smallPrimeHelper' n)) = n"
by transfer auto
lemma [simp]: "n ∈ {2,3,5,7} ⟹ smallPrimeView_small (smallPrimeHelper' n) = small n"
by (auto intro: iffD1[OF to_nat_inject] simp add: small_inverse)
``````

With that we can derive a code equation that does the check only once:

``````lemma [code]: "smallPrime n =
(let spv = smallPrimeHelper' n in
(if smallPrimeView_pred spv
then Some (smallPrimeView_small spv)
else None))"
by (auto simp add: smallPrime_def Let_def)
``````
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