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.)