The problem with your statement is that it is not true. Look at the definition of ℕ with `thm Nats_def`

: `ℕ = range of_nat`

`of_nat`

is the canonical homomorphism from the naturals into a `semiring_1`

, i.e. a semiring that has a 1. The definition of ℕ basically says that ℕ consists of all the elements of the ring that are of the form `of_nat n`

for a natural number `n`

. If you look at the type of `{m∈ℕ. m <4}`

, you will see that it is `'a`

, or if you do a `declare [[show_sorts]]`

before it, `'a :: {ord, semiring_1}`

, i.e. a semiring with a 1 and some kind of ordering on it. This ordering does *not* have to be compatible with the ring structure, nor does it have to be linear.

You may think that the set you defined is always the set `{0, 1, 2, 3}`

, but because the ordering is not required to be compatible with the ring structure, this is not the case. The ordering could be trivially true, so you'll get *all* natural numbers.

Furthermore, even when the set *is* `{0, 1, 2, 3}`

, its cardinality is not necessarily 4. (Think of the ring ℤ/2ℤ – then that set will be equal to `{0, 1}`

, so the cardinality is 2)

You will probably want to restrict the type of your expression a bit. I think the right type class here is `linordered_semidom`

, i.e. a semiring with a 1, no zero divisors, and a linear ordering that is compatible to the ring structure. Then you can do:

```
lemma cd : "card {m∈ℕ. m < (4 :: 'a :: linordered_semidom)} = 4"
proof -
have "{m∈ℕ. m < (4 :: 'a)} = {m∈ℕ. m < (of_nat 4 :: 'a)}" by simp
also have "… = of_nat ` {m. m < 4}"
unfolding Nats_def by (auto simp del: of_nat_numeral)
also have "card … = 4" by (auto simp: inj_on_def card_image)
finally show ?thesis .
qed
```

The proof is a bit ugly considering how intuitively obvious the proposition is; the solution here is not to write down the set you want to describe in this relatively inconvenient way in the first place. It takes a bit of experience to know how to write things in a convenient way.