2023-10-29 00:07:15 +02:00
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import Learning.Nat
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2023-10-29 00:02:10 +02:00
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macro "nat_ring_all" : tactic => `(simp_all [Nat.mul_assoc, Nat.mul_comm, Nat.mul_left_comm, Nat.add_assoc, Nat.add_left_comm, Nat.add_comm, Nat.left_distrib, Nat.right_distrib])
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macro "nat_ring" : tactic => `(simp [Nat.mul_assoc, Nat.mul_comm, Nat.mul_left_comm, Nat.add_assoc, Nat.add_left_comm, Nat.add_comm, Nat.left_distrib, Nat.right_distrib])
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macro "quotient_madness" : tactic => `(simp [Quotient.mk', Quotient.mk, Quotient.liftOn₂, Quotient.lift₂, Quotient.lift])
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structure RawInt where
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pos : Nat
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neg : Nat
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deriving Repr
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private def eqv : (x y: RawInt) → Prop
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| ⟨a, b⟩, ⟨c, d⟩ => a + d = c + b
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infix:50 " ~ " => eqv
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private theorem eqv.refl (x: RawInt) : x ~ x := rfl
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private theorem eqv.symm {x y: RawInt} (xy: x ~ y): y ~ x := Eq.symm xy
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/-
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a - b c - d e - f
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a + d = c + b
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c + f = e + d
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=> a + f = e + b -- the target
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a + d + c + f = c + b + e + d
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a + f + e + b -- done
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-/
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private theorem eqv.trans {x y z: RawInt} (xy: x ~ y) (yz: y ~ z): x ~ z := by
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have summed: _ := Nat.add_equations xy yz
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apply @Nat.add_right_cancel _ (y.pos + y.neg) _
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nat_ring_all
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private theorem is_equivalence: Equivalence eqv :=
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{ refl := eqv.refl, symm := eqv.symm, trans := eqv.trans }
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instance rawIntSetoid: Setoid RawInt where
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r := eqv
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iseqv := is_equivalence
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def MyInt: Type :=
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Quotient rawIntSetoid
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private theorem eqv.sound: x ~ y → Quotient.mk' x = Quotient.mk' y := Quot.sound
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@[simp]
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def MyInt.mk (pos neg: Nat): MyInt := Quotient.mk' ⟨pos, neg⟩
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notation "{ " a₁ ", " a₂ " }" => MyInt.mk a₁ a₂
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@[simp, inline]
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private def MyInt.ofRawInt(raw: RawInt) := MyInt.mk raw.pos raw.neg
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@[simp, inline]
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private def RawInt.ofNat(nat: Nat): RawInt := ⟨nat, 0⟩
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@[simp, inline]
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private def MyInt.ofNat(nat: Nat): MyInt := {nat, 0}
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private instance rawIntOfNat: OfNat RawInt n where
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ofNat := RawInt.ofNat n
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instance myIntOfNat: OfNat MyInt n where
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ofNat := MyInt.ofNat n
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namespace MyInt
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private def negateRawInt: RawInt → MyInt
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| ⟨pos, neg⟩ => {neg, pos}
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/-
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a - b = c - d
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a + d = c + b
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b + c = d + a
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b - a = d - c
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-/
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private theorem negateRawInt.respects {x y: RawInt} (xy: x ~ y): negateRawInt x = negateRawInt y := by
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apply eqv.sound
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simp_all [eqv, Nat.add_comm]
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def negate (τ: MyInt): MyInt :=
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Quotient.liftOn τ negateRawInt @negateRawInt.respects
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instance negMyInt: Neg MyInt where
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neg := negate
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private theorem double_neg_elim: ∀x, x = negate (negate x) := by
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intro x
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induction x using Quotient.ind
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rfl
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private def addRawInts: RawInt → RawInt → MyInt
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| ⟨a, b⟩, ⟨c, d⟩ => {a + c, b + d}
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private theorem addRawInts.respects
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{a b c d: RawInt}
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(ac: a ~ c)
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(bd: b ~ d): addRawInts a b = addRawInts c d := by
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have summed: _ := Nat.add_equations ac bd
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apply eqv.sound
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simp [eqv] at summed ⊢
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nat_ring_all
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private theorem addRawInts.comm (a b: RawInt): addRawInts a b = addRawInts b a := by
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simp_all [addRawInts, Nat.add_comm]
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def add (τ β: MyInt): MyInt :=
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Quotient.liftOn₂ τ β addRawInts @addRawInts.respects
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private instance hAddRawInts: HAdd RawInt RawInt MyInt where
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hAdd := addRawInts
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instance addMyInts: Add MyInt where
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add := add
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def sub (a b: MyInt): MyInt := a + (-b)
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instance subMyInt: Sub MyInt where
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sub := sub
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@[simp]
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theorem sub.x_minus_x_is_zero (a: MyInt): a - a = 0 := by
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simp_all [HSub.hSub, sub, HAdd.hAdd, add, negate, Neg.neg, MyInt.ofNat]
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induction a using Quotient.ind
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apply eqv.sound
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simp [eqv]
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apply Nat.add_comm
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theorem add.comm: ∀x y: MyInt, x + y = y + x := by
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intro x y
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simp_all [HAdd.hAdd, add]
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induction x, y using Quotient.ind₂
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quotient_madness
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apply addRawInts.comm
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theorem add.assoc(x y z: MyInt): x + (y + z) = (x + y) + z := by
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simp_all [HAdd.hAdd, add]
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induction x, y using Quotient.ind₂
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induction z using Quotient.ind
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apply eqv.sound
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simp [eqv]
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nat_ring_all
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@[simp]
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theorem add.zero(x: MyInt): x + 0 = x := by
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simp_all [HAdd.hAdd, add]
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induction x using Quotient.ind
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apply eqv.sound
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simp [eqv]
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/-
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(a - b) * (c - d)
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ac - bc - ad + bd
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-/
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private def multiplyRawInts: RawInt → RawInt → MyInt
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| ⟨a, b⟩, ⟨c, d⟩ => {a * c + b * d, b * c + a * d}
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/-
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ac : c.neg + a.pos = a.neg + c.pos
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bd : d.neg + b.pos = b.neg + d.pos
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⊢ a.neg * b.neg + (a.pos * b.pos + (c.pos * d.neg + c.neg * d.pos)) =
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c.neg * d.neg + (a.pos * b.neg + (a.neg * b.pos + c.pos * d.pos))
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a - b c - d e - f g - h
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f + a = b + e
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h + c = d + g
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bd + ac + eh + fg = fh + ad + bc + eg
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bd + ac + fc + eh + fg + ec = fh + ad + bc + ec + eg + fc
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+ cf + ce
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bd + c(a + f) + eh + fg + ec = fh + ad + c(b + e) + eg + fc
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bd + eh + fg + ec = fh + ad + eg + fc
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bd + e(h + c) + fg = f(h + c) + ad + eg
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+ bg + ag
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b(d + g) + e(h + c) + fg + ag = f(h + c) + a(d + g) + bg + eg
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(h + c)(b + e) + g(a + f) = (h + c)(f + a) + g(b + e)
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-/
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private theorem multiplyRawInts.respects: ∀
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{x y z w: RawInt}
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(xz: x ~ z)
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(yw: y ~ w), (multiplyRawInts x y = multiplyRawInts z w)
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| ⟨a, b⟩, ⟨c, d⟩, ⟨e, f⟩, ⟨g, h⟩ => by
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intro xz yw
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apply eqv.sound
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simp_all [eqv]
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have first: (c + h) * (b + e) + g * (a + f) + c * (a + f)
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= (c + h) * (f + a) + g * (b + e) + c * (b + e) := by
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simp [Nat.add_comm, xz, yw]
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have second: b * (d + g) + e * (c + h) + c * (a + f) + f * g + a * g
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= f * (c + h) + a * (d + g) + c * (b + e) + b * g + e * g := by
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simp [yw, xz] at first ⊢
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conv at first in g * (e + b) => rw [<-xz]
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conv at first => tactic => nat_ring
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nat_ring
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exact first
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conv at second => tactic => nat_ring
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apply @Nat.subtract_to_equation_left _ _
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(a * g + b * g + c * f + c * e)
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nat_ring_all
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def multiply (τ β: MyInt): MyInt :=
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Quotient.liftOn₂ τ β multiplyRawInts @multiplyRawInts.respects
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private instance hMulRawInt: HMul RawInt RawInt MyInt where
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hMul := multiplyRawInts
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instance mulMyInt: Mul MyInt where
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mul := multiply
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private theorem multiplyRawInts.comm (a b: RawInt): a * b = b * a := by
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apply eqv.sound
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simp [eqv]
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simp_all [multiplyRawInts, Nat.mul_comm]
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nat_ring_all
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theorem multiply.comm (a b: MyInt): a * b = b * a := by
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simp_all [Mul.mul, multiply]
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induction a, b using Quotient.ind₂
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quotient_madness
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apply multiplyRawInts.comm
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theorem multiply.assoc(x y z: MyInt): x * (y * z) = (x * y) * z := by
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simp_all [Mul.mul, multiply]
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induction x, y using Quotient.ind₂
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induction z using Quotient.ind
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apply eqv.sound
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simp [eqv]
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nat_ring_all
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@[simp]
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theorem multiply.one(x: MyInt): x * 1 = 1 * x := by
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simp_all [Mul.mul, multiply]
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induction x using Quotient.ind
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apply eqv.sound
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simp [eqv]
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@[simp]
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theorem multiply.zero(x: MyInt): x * 0 = 0 := by
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simp_all [Mul.mul, multiply]
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induction x using Quotient.ind
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apply eqv.sound
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simp [eqv]
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theorem left_distrib(x y z: MyInt): x * (y + z) = x * y + x * z := by
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simp_all [Mul.mul, Add.add, add, multiply]
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induction x, y using Quotient.ind₂
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induction z using Quotient.ind
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apply eqv.sound
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simp [eqv]
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nat_ring_all
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theorem right_distrib(x y z: MyInt): (x + y) * z = x * z + y * z := by
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simp_all [Mul.mul, Add.add, add, multiply]
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induction x, y using Quotient.ind₂
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induction z using Quotient.ind
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apply eqv.sound
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simp [eqv]
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nat_ring_all
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/-
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notes on division?
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t * (c - d) + r = a - b
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t * c + b + r = a + t * d
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-/
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@[simp]
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def is_even(x: MyInt) := ∃h, h + h = x
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@[simp]
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def is_odd(x: MyInt) := ∃h, h + h + 1 = x
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theorem double_is_even(x: MyInt): is_even (2 * x) := by
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simp
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exists x
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induction x using Quotient.ind
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apply eqv.sound
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simp [eqv, Nat.double.addition_is_multiplication]
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theorem raw_int_induction
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(P: MyInt → Prop)
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(pz: P 0)
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(pn: ∀k, P k ↔ P (k + 1)):
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(x: RawInt) → ∃k, k ~ x ∧ P (MyInt.ofRawInt k)
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| ⟨0, 0⟩ => ⟨0, ⟨rfl, pz⟩⟩
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| ⟨Nat.succ a, 0⟩ => by
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have ⟨⟨kp, kn⟩, pk⟩ := raw_int_induction P pz pn ⟨a, 0⟩
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exists (⟨kp + 1, kn⟩ : RawInt)
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apply And.intro
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. simp [eqv, Nat.succ_add]
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rw [<-pk.left]
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simp [Nat.add_zero]
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. apply (@pn {kp, kn}).mp
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exact pk.right
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| ⟨Nat.succ a, Nat.succ b⟩ => by
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have ⟨k, pk⟩ := raw_int_induction P pz pn ⟨a, b⟩
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exists k
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apply And.intro
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. simp [eqv, Nat.succ_add]
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rw [<-pk.left]
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simp_arith
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. exact pk.right
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| ⟨0, Nat.succ a⟩ => by
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have ⟨⟨kp, kn⟩, pk⟩ := raw_int_induction P pz pn ⟨0, a⟩
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exists (⟨kp, kn + 1⟩ : RawInt)
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apply And.intro
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. have pkl := pk.left
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simp [eqv, Nat.succ_add, Nat.add_zero] at pkl ⊢
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rw [<-pkl]
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simp_arith
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. have recurse := (@pn {kp, kn + 1}).mpr
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have rewriter: {kp, kn + 1} + 1 = {kp, kn} := by
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apply eqv.sound
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simp [eqv]
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simp_arith
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rw [rewriter] at recurse
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exact (recurse pk.right)
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theorem int_induction
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(P: MyInt → Prop)
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(zero: P 0)
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(succ: ∀k, P k ↔ P (k + 1)):
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∀k, P k := by
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intro k
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induction k using Quotient.ind
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rename RawInt => kRaw
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have ⟨e, ⟨eIsK, proof⟩⟩ := raw_int_induction P zero succ kRaw
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have eIsKQuot : MyInt.ofRawInt e = MyInt.ofRawInt kRaw := by
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exact (eqv.sound eIsK)
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simp [Quotient.mk'] at eIsKQuot
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rw [<-eIsKQuot]
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exact proof
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theorem add_left_cancel {a b c: MyInt}: a + b = a + c → b = c := by
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intro hip
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induction b, c using Quotient.ind₂
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induction a using Quotient.ind
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rename RawInt => c
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simp_all [HAdd.hAdd, Add.add, add]
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conv at hip => tactic => quotient_madness
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/- apply eqv.sound -/
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/- simp [eqv] -/
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/- nat_ring -/
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simp_all [MyInt.addRawInts, Quotient.mk', Quotient.mk]
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sorry
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/- induction a using int_induction with -/
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/- | zero => -/
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/- rw [add.comm 0 c, add.comm 0 b] -/
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/- simp_all -/
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/- | succ k => -/
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/- apply Iff.intro -/
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/- . intro win -/
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/- intro previous -/
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/- have p: k + b = k + c := by -/
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/- rw [add.comm k 1] at previous -/
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/- induction b, c using Quotient.ind₂ -/
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/- induction k using Quotient.ind -/
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/- rename RawInt => c -/
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/- simp [HAdd.hAdd, Add.add, add] -/
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/- apply eqv.sound -/
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/- simp [eqv] -/
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/- nat_ring -/
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/- -/
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/- sorry -/
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/- exact (win p) -/
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/- . sorry -/
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/- -/
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theorem odd_and_even_contradict(x: MyInt): ¬(is_odd x ∧ is_even x)
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| ⟨⟨h₁, oddProof⟩, ⟨h₂, evenProof⟩⟩ => by
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have wrong: (1: MyInt) = 0 := by
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apply @add_left_cancel (h₁ + h₂)
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exact oddProof.trans evenProof.symm
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sorry
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contradiction
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theorem odds_not_even(x: MyInt): is_odd x ↔ ¬(is_even x) := by
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apply Iff.intro
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case mp =>
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intro oddProof
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intro evenProof
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apply odd_and_even_contradict x
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exact ⟨oddProof, evenProof⟩
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case mpr =>
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simp [is_even, is_odd]
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sorry
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end MyInt
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