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516 lines
14 KiB
Markdown
516 lines
14 KiB
Markdown
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---
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title: "Working with integer sets in Lean 4"
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date: 2024-03-31T21:10:23-04:00
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draft: false
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tags: ["Formal Methods"]
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math: true
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medium_enabled: false
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---
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Recently I was convinced by [James Oswald](https://jamesoswald.dev/) to work with him on proving some lemmas about specific integer sets in Lean 4. Since we have different styles in going about Lean proofs, I present my version here.
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We'll go over three proofs today:
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- $\\{x \mid x \in \mathbb{Z} \wedge x^2 = 9\\} = \\{-3, 3\\}$
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- $\\{x \mid x \in \mathbb{Z} \wedge -4 \le n \wedge n \le 15 ∧ Even~n \\} = \\{-4, -2, 0, 2, 4, 6, 8, 10, 12, 14\\}$
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- $\\{x \mid x \in \mathbb{Z} \wedge x^2 = 6\\} = \emptyset$
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## Example 1
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First, let's define our set $A$
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```lean4
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def A : Set Int := {x : Int | x^2 = 9}
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```
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We want to prove the following lemma:
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```lean4
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lemma instA : A = ({3, -3} : Finset ℤ)
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```
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Recall that for sets, $A = S \iff A \subseteq S \wedge S \subseteq A$.
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Since we're given a specific Finset for $S$, it would be really nice if we can compute whether $S$ is a subset of $A$. In fact we can, as long as we prove a couple theorems first.
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```lean4
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instance (n: Int) : Decidable (n ∈ A) := by
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suffices Decidable (n^2 = 9) by
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rewrite [A, Set.mem_setOf_eq]
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assumption
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apply inferInstance
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```
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First as shown above, we need to decide whether an integer is in $A$. Given how $A$ is defined, this is equivalent to seeing if $n^2 = 9$. Luckily for us, the core of Lean already has a decision procedure for this. We can have Lean apply the appropriate one by calling `apply inferInstance`.
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With this, we can now use `#eval` to see if elements are in $A$ or not.
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```lean4
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#eval List.Forall (· ∈ A) [-3, 3]
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```
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To say that a finite set $S$ is a subset of $A$, is to say that all the elements of $S$ are in $A$. Using the last theorem, we can prove that checking subsets in this direction is decidable.
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```lean4
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instance (S : Finset Int) : Decidable (↑S ⊆ A) := by
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rewrite [A]
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rewrite [Set.subset_def]
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show Decidable (∀ x ∈ S, x ∈ {x | x ^ 2 = 9})
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apply inferInstance
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```
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Keep in mind that at this point it's not necessarily decidable if $A \subseteq S$. This is because we haven't established if $A$ is finite. However instead of trying to prove finiteness, let's skip to the main proof and show that $A = \\{3, -3\\}$ classically.
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```lean4
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lemma instA : A = ({3, -3} : Finset ℤ) := by
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let S : Finset ℤ := {3, -3}
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change (A = ↑S)
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```
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As stated before, set equality is making sure both are subsets of each other
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```lean4
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suffices A ⊆ ↑S ∧ ↑S ⊆ A by
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rewrite [Set.Subset.antisymm_iff]
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assumption
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```
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Lets make use of our decidability proof to show $S \subseteq A$ in one line!
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```lean4
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have H2 : ↑S ⊆ A := by decide
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```
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For the other side,
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```lean4
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have H1 : A ⊆ ↑S := by
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intro (n : ℤ)
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-- Goal is now (n ∈ A → n ∈ {3, -3})
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intro (H1_1: n ∈ A)
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```
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Let's change `H1_1` to be in a form easier to work with
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```lean4
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have H1_1 : n^2 = 9 := by
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rewrite [A, Set.mem_setOf_eq] at H1_1
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assumption
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```
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To show that $n \in \\{3, -3\\}$, then it's the same as saying that $n = 3$ or $n = -3$.
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```lean4
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suffices n = 3 ∨ n = -3 by
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show n ∈ S
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rewrite [Finset.mem_insert, Finset.mem_singleton]
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assumption
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```
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We can show this using a theorem from mathlib!
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```lean4
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exact eq_or_eq_neg_of_sq_eq_sq n 3 H1_1
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```
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[(Quite the long name...)](https://leanprover-community.github.io/mathlib4_docs/Mathlib/Algebra/GroupPower/Ring.html#eq_or_eq_neg_of_sq_eq_sq)
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Lastly, we combine the two subset proofs to show equality
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```lean4
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exact And.intro H1 H2
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```
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All together the proof looks like:
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```lean4
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lemma instA : A = ({3, -3} : Finset ℤ) := by
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let S : Finset ℤ := {3, -3}
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change (A = ↑S)
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suffices A ⊆ ↑S ∧ ↑S ⊆ A by
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rewrite [Set.Subset.antisymm_iff]
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assumption
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have H1 : A ⊆ ↑S := by
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intro (n : ℤ)
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-- Goal is now (n ∈ A → n ∈ {3, -3})
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intro (H1_1: n ∈ A)
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have H1_1 : n^2 = 9 := by
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rewrite [A, Set.mem_setOf_eq] at H1_1
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assumption
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suffices n = 3 ∨ n = -3 by
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show n ∈ S
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rewrite [Finset.mem_insert, Finset.mem_singleton]
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assumption
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exact eq_or_eq_neg_of_sq_eq_sq n 3 H1_1
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have H2 : ↑S ⊆ A := by decide
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exact And.intro H1 H2
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```
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## Example 2
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We got to cheat a little by applying a `mathlib` theorem in the last example. This one will require a little more technique. First, let's start by defining our set $B$.
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```lean4
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def B : Set Int := {n | -4 ≤ n ∧ n ≤ 15 ∧ n % 2 = 0}
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```
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As before, we can show that set membership in $B$ is decidable. We can make use of the fact that each condition within it is decidable through `And.decidable`.
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```lean4
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instance (n : Int) : Decidable (n ∈ B) := by
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suffices Decidable (-4 ≤ n ∧ n ≤ 15 ∧ n % 2 = 0) by
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rewrite [B, Set.mem_setOf_eq]
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assumption
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exact And.decidable
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```
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Sanity check to see that everything works as expected.
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```lean4
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#eval List.Forall (· ∈ B) [-4, -2, 0, 2, 4, 6, 8, 10, 12, 14]
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```
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We can also show that checking if a finset is a subset of $B$ is decidable.
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```lean4
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instance (S : Finset Int) : Decidable (↑S ⊆ B) := by
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suffices Decidable (∀ x ∈ S, -4 ≤ x ∧ x ≤ 15 ∧ x % 2 = 0) by
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rewrite [Set.subset_def, B]
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assumption
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apply inferInstance
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```
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The beginning of our proof stays the same
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```lean4
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lemma instB : B = ({-4, -2, 0, 2, 4, 6, 8, 10, 12, 14} : Finset Int) := by
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let S : Finset Int := {-4, -2, 0, 2, 4, 6, 8, 10, 12, 14}
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change (B = ↑S)
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-- To show equality, we need to show that
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-- each is a subset of each other
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suffices ((B ⊆ ↑S) ∧ (↑S ⊆ B)) by
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rewrite [Set.Subset.antisymm_iff]
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assumption
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have H2 : ↑S ⊆ B := by decide
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```
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For the other direction we want to show that is $n$ meets the condition to be in $B$, then it must be in $S$.
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```lean4
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have H1 : B ⊆ ↑S := by
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intro (n : ℤ)
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intro (H : n ∈ B)
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have H1 : -4 ≤ n ∧ n ≤ 15 ∧ n % 2 = 0 := by
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rewrite [B] at H; assumption
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clear H
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show n ∈ S
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```
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Since $S$ is a finset, we can say that $n$ must be equal to one of the elements of $S$.
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```lean4
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repeat rewrite [Finset.mem_insert]
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rewrite [Finset.mem_singleton]
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```
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At this point, the problem is integer arithmetic and we can call the `omega` tactic to finish the subproof.
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```lean4
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omega
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```
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With both sides subset proven, we use and introduction to prove the goal
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```lean4
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exact show ((B ⊆ ↑S) ∧ (↑S ⊆ B)) from And.intro H1 H2
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```
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The full proof is below.
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```lean4
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lemma instB : B = ({-4, -2, 0, 2, 4, 6, 8, 10, 12, 14} : Finset Int) := by
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let S : Finset Int := {-4, -2, 0, 2, 4, 6, 8, 10, 12, 14}
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change (B = ↑S)
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-- To show equality, we need to show that
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-- each is a subset of each other
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suffices ((B ⊆ ↑S) ∧ (↑S ⊆ B)) by
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rewrite [Set.Subset.antisymm_iff]
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assumption
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have H1 : B ⊆ ↑S := by
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intro (n : ℤ)
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intro (H : n ∈ B)
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have H1 : -4 ≤ n ∧ n ≤ 15 ∧ n % 2 = 0 := by
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rewrite [B] at H; assumption
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clear H
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show n ∈ S
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repeat rewrite [Finset.mem_insert]
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rewrite [Finset.mem_singleton]
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omega
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have H2 : ↑S ⊆ B := by decide
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exact show ((B ⊆ ↑S) ∧ (↑S ⊆ B)) from And.intro H1 H2
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```
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## Example 3
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Finally let's define our last set.
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```lean4
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def C : Set Int := {n | n^2 = 6}
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```
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We're aiming to show that $C$ is equivalent to the empty set. Therefore, we don't have a need to show decidability for membership or finite subsets. We can't make use of the mathlib theorem from Example 1, so how will we go about proving this?
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Analyzing the last example more carefully, we had upper and lower bounds to work with. We can similarly identify these bounds for this example.
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Let's define the integer squared to be the upper bound.
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```lean4
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lemma IntPow2GeSelf (H : (a : Int)^2 = z) : a ≤ z := by
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have H1 : a ≤ a ^ 2 := Int.le_self_sq a
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rewrite [H] at H1
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assumption
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```
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For the lower bound, take its negation.
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```lean4
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lemma NegIntPow2LeSelf (H : (a : Int)^2 = z) : a ≥ -z := by
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```
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To prove the lower bound, split up between positives and negatives using the law of excluded middle
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```lean4
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have H1 : a ≥ 0 ∨ a < 0 := le_or_lt 0 a
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```
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For a positive $a$, we can rely on the `linarith` tactic
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```lean4
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have H_LEFT : a ≥ 0 → a ≥ -z := by
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have HL1 : a ≤ z := IntPow2GeSelf H
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intro (HL2 : a ≥ 0)
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linarith
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```
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For a negative $a$, we need to prove it by induction
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```lean4
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have H_RIGHT : a < 0 → a ≥ -z := by
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intro (HR1: a < 0)
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have HR1 : a ≤ -1 := Int.le_sub_one_iff.mpr HR1
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revert HR1
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suffices a ≤ -1 → a ≥ -(a^2) by
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rewrite [<- H]; assumption
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let P : ℤ → Prop := fun x => x ≥ -(x^2)
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have H_base : P (-1) := by decide
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have H_ind : ∀ (n : ℤ), n ≤ -1 → P n → P (n - 1) := by
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intro (n : ℤ)
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intro (H21 : n ≤ -1)
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intro (H22 : P n)
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simp_all
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linarith
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exact Int.le_induction_down H_base H_ind a
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```
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We have shown that this lower bound holds for both positive and negative $a$, therefore we can show that it holds for all $a$.
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```lean4
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exact Or.elim H1 H_LEFT H_RIGHT
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```
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All together the lower bound proof is the following
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```lean4
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lemma NegIntPow2LeSelf (H : (a : Int)^2 = z) : a ≥ -z := by
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have H1 : a ≥ 0 ∨ a < 0 := by omega
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have H_LEFT : a ≥ 0 → a ≥ -z := by
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have HL1 : a ≤ z := IntPow2GeSelf H
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intro (HL2 : a ≥ 0)
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linarith
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have H_RIGHT : a < 0 → a ≥ -z := by
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intro (HR1: a < 0)
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have HR1 : a ≤ -1 := Int.le_sub_one_iff.mpr HR1
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revert HR1
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suffices a ≤ -1 → a ≥ -(a^2) by
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rewrite [<- H]; assumption
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let P : ℤ → Prop := fun x => x ≥ -(x^2)
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have H_base : P (-1) := by decide
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have H_ind : ∀ (n : ℤ), n ≤ -1 → P n → P (n - 1) := by
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intro (n : ℤ)
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intro (H21 : n ≤ -1)
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intro (H22 : P n)
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simp_all
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linarith
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exact Int.le_induction_down H_base H_ind a
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exact Or.elim H1 H_LEFT H_RIGHT
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```
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With our lower and upper bounds in place, we can look at the original problem. That is, we want to prove that $C = \emptyset$. We'll start the same proof like before.
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```lean4
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example : C = (∅ : Set Int) := by
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suffices C ⊆ ∅ ∧ ∅ ⊆ C by
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rewrite [Set.Subset.antisymm_iff]
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assumption
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have H2 : ∅ ⊆ C := Set.empty_subset C
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```
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We start the other direction the same as well.
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```lean4
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have H1 : C ⊆ ∅ := by
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intro (n : ℤ)
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intro (H1_1 : n ∈ C)
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have H1_1 : n^2 = 6 := by
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rewrite [C, Set.mem_setOf_eq] at H1_1
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assumption
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```
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Now bring in our bounds
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```lean4
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have H1_2 : n ≤ 6 := by apply IntPow2GeSelf H1_1
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|
have H2_3 : n ≥ -6 := by apply NegIntPow2LeSelf H1_1
|
|||
|
```
|
|||
|
|
|||
|
We can use `omega` to show that if the integer is within these bounds then $n$ must equal one of the integers.
|
|||
|
|
|||
|
```lean4
|
|||
|
have H1_4 : n ∈ ({-6, -5, -4, -3, -2, -1, 0, 1, 2, 3, 4, 5, 6} : Finset ℤ) := by
|
|||
|
repeat rewrite [Finset.mem_insert]
|
|||
|
rewrite [Finset.mem_singleton]
|
|||
|
omega
|
|||
|
```
|
|||
|
|
|||
|
Turn this set into a disjunction
|
|||
|
|
|||
|
```lean4
|
|||
|
-- Make H1_4 a disjunction (n = -6 ∨ ... ∨ n = 6)
|
|||
|
repeat rewrite [Finset.mem_insert] at H1_4
|
|||
|
rewrite [Finset.mem_singleton] at H1_4
|
|||
|
```
|
|||
|
|
|||
|
Trying to show that $n$ is within the empty set is the same as trying to prove a contradiction
|
|||
|
|
|||
|
```lean4
|
|||
|
show False
|
|||
|
```
|
|||
|
|
|||
|
So let's go through each disjunct in `H1_4` and show that we derive a contradiction.
|
|||
|
|
|||
|
```lean4
|
|||
|
repeat (
|
|||
|
cases' H1_4 with H1_4H H1_4
|
|||
|
-- Plug in n = ?? to n^2 = 6
|
|||
|
rewrite [H1_4H] at H1_1
|
|||
|
contradiction
|
|||
|
)
|
|||
|
```
|
|||
|
|
|||
|
The last $n = 6$ is under a different name
|
|||
|
|
|||
|
```lean4
|
|||
|
rewrite [H1_4] at H1_1
|
|||
|
contradiction
|
|||
|
```
|
|||
|
|
|||
|
We can finally put it all together with and introduction
|
|||
|
|
|||
|
```lean4
|
|||
|
exact show C ⊆ ∅ ∧ ∅ ⊆ C from And.intro H1 H2
|
|||
|
```
|
|||
|
|
|||
|
All together it's the following:
|
|||
|
|
|||
|
```lean4
|
|||
|
example : C = (∅ : Set Int) := by
|
|||
|
|
|||
|
suffices C ⊆ ∅ ∧ ∅ ⊆ C by
|
|||
|
rewrite [Set.Subset.antisymm_iff]
|
|||
|
assumption
|
|||
|
|
|||
|
have H1 : C ⊆ ∅ := by
|
|||
|
intro (n : ℤ)
|
|||
|
intro (H1_1 : n ∈ C)
|
|||
|
have H1_1 : n^2 = 6 := by
|
|||
|
rewrite [C, Set.mem_setOf_eq] at H1_1
|
|||
|
assumption
|
|||
|
|
|||
|
show False
|
|||
|
|
|||
|
have H1_2 : n ≤ 6 := by apply IntPow2GeSelf H1_1
|
|||
|
have H2_3 : n ≥ -6 := by apply NegIntPow2LeSelf H1_1
|
|||
|
|
|||
|
|
|||
|
have H1_4 : n ∈ ({-6, -5, -4, -3, -2, -1, 0, 1, 2, 3, 4, 5, 6} : Finset ℤ) := by
|
|||
|
repeat rewrite [Finset.mem_insert]
|
|||
|
rewrite [Finset.mem_singleton]
|
|||
|
omega
|
|||
|
|
|||
|
-- Make H3 a disjunction (n = -6 ∨ ... ∨ n = 6)
|
|||
|
repeat rewrite [Finset.mem_insert] at H1_4
|
|||
|
rewrite [Finset.mem_singleton] at H1_4
|
|||
|
|
|||
|
-- Try each one, plug in n = a into n^2 = 6 and show it doesn't work
|
|||
|
repeat (
|
|||
|
cases' H1_4 with H1_4H H1_4
|
|||
|
rewrite [H1_4H] at H1_1
|
|||
|
contradiction
|
|||
|
)
|
|||
|
|
|||
|
-- Last n = 6 has a different name
|
|||
|
rewrite [H1_4] at H1_1
|
|||
|
contradiction
|
|||
|
|
|||
|
|
|||
|
have H2 : ∅ ⊆ C := Set.empty_subset C
|
|||
|
|
|||
|
exact show C ⊆ ∅ ∧ ∅ ⊆ C from And.intro H1 H2
|
|||
|
```
|
|||
|
|
|||
|
## Conclusion
|
|||
|
|
|||
|
We gave three examples on working with finite integer sets. The two key lessons from this post are:
|
|||
|
|
|||
|
**1. If the set is equal to a non-empty finite set, then try to prove decidability of membership and if a finset is a subset of it.**
|
|||
|
|
|||
|
If you're looking at a set of integers and this set is constructed with conditions that are mostly built-in (such as the `<` relation), then this is hopefully not too difficult. Unfold the definitions of your set using `rewrite` and have Lean auto-infer which decidability instance to call using `apply inferInstance`
|
|||
|
|
|||
|
**2. Try to establish a lower and upper bound for the elements of your set.**
|
|||
|
|
|||
|
This gives the `omega` tactic something additional to work with. In the second example, `omega` was able to close out the goal completely given the linear inequalities presented. In our last example, we only used `omega` to construct a finite set of possible integers.
|
|||
|
|
|||
|
If you develop any other general techniques for dealing with integer sets let me know. Otherwise, feel free to get in touch with any questions you have.
|
|||
|
|