# Proving the cardinality of a finite set

How can I prove in Isabelle the simple `lemma cd : "card {m∈ℕ. m <4} = 4"` statement?

`auto` doesn't help me and oddly `sledgehammer` times out (even if I use different values on the right-hand side, like `3` or `5` to make sure that I haven't overlooked some technical Isabelle details which perhaps actually make the cardinaliy evaluate to one of these numbers.)

I have the impression that I have to use some lemmas (or get inspiration) from `Set_Interval.thy` as there sets of these kind are extensively used, but so far I didn't manage to make progress.

• Please post on math.stackexchange.com. Commented Feb 19, 2017 at 11:24
• @Jameson You misunderstood the question - this is not about maths, but about *formalization" of math (in Isabelle), which is very much in the scope of this site - there are a lot of similar questions here. I added the wording "in Isabelle" to my question, if the tag didn't clarify this. Commented Feb 19, 2017 at 11:36

Just wanted to add, that if you rewrite your lemma to `"card {m::nat. m < n} = n"`, Isabelle has no problem proving it.

*Edited, thanks Manuel.

• You probably mean `card {m::nat. m < n} = n`. Good observation; maybe this is what OP had in mind. It's a very different statement though, as one can see from my answer. A good reminder that theorem proving is always an exercise in subtleties. Commented Feb 19, 2017 at 18:23

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.

• Wow, I never would have expected that `m∈ℕ` vs `n::nat` make so a big difference. Thanks a lot for the comprehensive answer. Commented Feb 19, 2017 at 18:37
• As I said, HOL is a typed logic. This is often confusing for mathematicians in the beginning. Similar issues often arise in traditional mathematics as well though: for example, how many elements does the set `[1;10]` have? Ten? Or infinitely many. Depends on whether you see it as a set of naturals or reals. Similarly, is `(0;1)` open? It is as a subset of ℝ, but not as a subset of ℂ. Commented Feb 19, 2017 at 19:36