import Mathlib set_option linter.unusedVariables.analyzeTactics true open Nat Real lemma imo_1997_p5_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (g : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : x ≤ y) (h₁ : (x ^ y) ^ y = y ^ x) : x ^ y ≤ y := by by_contra! hc have h₂: y^x ≤ y^y := by { exact Nat.pow_le_pow_of_le_right h₀.2 hxy } have h₃: y^y < (x^y)^y := by refine Nat.pow_lt_pow_left hc ?_ refine Nat.pos_iff_ne_zero.mp h₀.2 rw [h₁] at h₃ linarith [h₂, h₃] lemma imo_1997_p5_1_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (hxy : x ≤ y) (h₁ : (x ^ y) ^ y = y ^ x) (hc : y < x ^ y) : False := by have h₂: y^x ≤ y^y := by { exact Nat.pow_le_pow_of_le_right h₀.2 hxy } have h₃: y^y < (x^y)^y := by refine Nat.pow_lt_pow_left hc ?_ refine Nat.pos_iff_ne_zero.mp h₀.2 rw [h₁] at h₃ linarith [h₂, h₃] lemma imo_1997_p5_1_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (hxy : x ≤ y) (h₁ : (x ^ y) ^ y = y ^ x) (hc : y < x ^ y) (h₂ : y ^ x ≤ y ^ y) : False := by have h₃: y^y < (x^y)^y := by refine Nat.pow_lt_pow_left hc ?_ refine Nat.pos_iff_ne_zero.mp h₀.2 rw [h₁] at h₃ linarith [h₂, h₃] lemma imo_1997_p5_1_3 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (hxy : x ≤ y) -- (h₁ : (x ^ y) ^ y = y ^ x) (hc : y < x ^ y) : -- (h₂ : y ^ x ≤ y ^ y) : y ^ y < (x ^ y) ^ y := by refine Nat.pow_lt_pow_left hc ?_ exact Nat.pos_iff_ne_zero.mp h₀.2 lemma imo_1997_p5_2 (k : ℕ) (hk : 5 ≤ k) : 4 * k < 2 ^ k := by -- Proceed by induction on k induction' k using Nat.case_strong_induction_on with n ih -- Base case: k = 0 is not possible since 5 ≤ k -- so we start directly with k = 5 as the base case . norm_num by_cases h₀ : n < 5 . have hn: n = 4 := by linarith rw [hn] norm_num . push_neg at h₀ have ih₁ : 4 * n < 2 ^ n := ih n (le_refl n) h₀ rw [mul_add, pow_add, mul_one, pow_one, mul_two] refine Nat.add_lt_add ih₁ ?_ refine lt_trans ?_ ih₁ refine (Nat.lt_mul_iff_one_lt_right (by norm_num)).mpr ?_ refine Nat.lt_of_lt_of_le ?_ h₀ norm_num lemma imo_1997_p5_2_1 (n : ℕ) (ih : ∀ m ≤ n, 5 ≤ m → 4 * m < 2 ^ m) (hk : 5 ≤ succ n) : 4 * succ n < 2 ^ succ n := by by_cases h₀ : n < 5 . rw [succ_eq_add_one] at hk have hn: n = 4 := by linarith rw [hn] norm_num . push_neg at h₀ have ih₁ : 4 * n < 2 ^ n := ih n (le_refl n) h₀ rw [succ_eq_add_one, mul_add, pow_add, mul_one, pow_one, mul_two] refine Nat.add_lt_add ih₁ ?_ refine lt_trans ?_ ih₁ refine (Nat.lt_mul_iff_one_lt_right (by norm_num)).mpr ?_ refine Nat.lt_of_lt_of_le ?_ h₀ norm_num lemma imo_1997_p5_2_2 (n : ℕ) -- (ih : ∀ m ≤ n, 5 ≤ m → 4 * m < 2 ^ m) (hk : 5 ≤ succ n) (h₀ : n < 5) : 4 * succ n < 2 ^ succ n := by rw [succ_eq_add_one] at hk have hn: n = 4 := by linarith rw [hn] norm_num lemma imo_1997_p5_2_3 (n : ℕ) (ih : ∀ m ≤ n, 5 ≤ m → 4 * m < 2 ^ m) -- (hk : 5 ≤ succ n) (h₀ : 5 ≤ n) : 4 * succ n < 2 ^ succ n := by have ih₁ : 4 * n < 2 ^ n := ih n (le_refl n) h₀ rw [succ_eq_add_one, mul_add, pow_add, mul_one, pow_one, mul_two] refine Nat.add_lt_add ih₁ ?_ refine lt_trans ?_ ih₁ refine (Nat.lt_mul_iff_one_lt_right (by norm_num)).mpr ?_ refine Nat.lt_of_lt_of_le ?_ h₀ norm_num lemma imo_1997_p5_2_4 (n : ℕ) -- (ih : ∀ m ≤ n, 5 ≤ m → 4 * m < 2 ^ m) -- (hk : 5 ≤ succ n) (h₀ : 5 ≤ n) (ih₁ : 4 * n < 2 ^ n) : 4 * succ n < 2 ^ succ n := by rw [succ_eq_add_one, mul_add, pow_add, mul_one, pow_one, mul_two] refine Nat.add_lt_add ih₁ ?_ refine lt_trans ?_ ih₁ refine (Nat.lt_mul_iff_one_lt_right (by norm_num)).mpr ?_ refine Nat.lt_of_lt_of_le ?_ h₀ norm_num lemma imo_1997_p5_2_5 (n : ℕ) -- (ih : ∀ m ≤ n, 5 ≤ m → 4 * m < 2 ^ m) -- (hk : 5 ≤ succ n) (h₀ : 5 ≤ n) (ih₁ : 4 * n < 2 ^ n) : 4 * n + 4 < 2 ^ n + 2 ^ n := by refine Nat.add_lt_add ih₁ ?_ refine lt_trans ?_ ih₁ refine (Nat.lt_mul_iff_one_lt_right (by norm_num)).mpr ?_ refine Nat.lt_of_lt_of_le ?_ h₀ norm_num lemma imo_1997_p5_2_6 (n : ℕ) -- (ih : ∀ m ≤ n, 5 ≤ m → 4 * m < 2 ^ m) -- (hk : 5 ≤ succ n) (h₀ : 5 ≤ n) (ih₁ : 4 * n < 2 ^ n) : 4 < 2 ^ n := by refine lt_trans ?_ ih₁ refine (Nat.lt_mul_iff_one_lt_right (by norm_num)).mpr ?_ refine Nat.lt_of_lt_of_le ?_ h₀ norm_num lemma imo_1997_p5_2_7 (n : ℕ) -- (ih : ∀ m ≤ n, 5 ≤ m → 4 * m < 2 ^ m) -- (hk : 5 ≤ succ n) (h₀ : 5 ≤ n) : -- (ih₁ : 4 * n < 2 ^ n) : 4 < 4 * n := by refine (Nat.lt_mul_iff_one_lt_right (by norm_num)).mpr ?_ refine Nat.lt_of_lt_of_le ?_ h₀ norm_num lemma imo_1997_p5_3 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x^(y^2) = y^x) (g₁ : x^(y^2) = (x^y)^y) (hxy : x ≤ y) : (x, y) = (1, 1) ∨ (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by rw [g₁] at h₁ have g2: x^y ≤ y := by exact imo_1997_p5_1 x y h₀ hxy h₁ have g3: x = 1 := by by_contra! hc have g3: 2 ≤ x := by by_contra! gc interval_cases x . linarith . omega have g4: 2 ^ y ≤ x ^ y := by { exact Nat.pow_le_pow_of_le_left g3 y } have g5: y < 2 ^ y := by exact Nat.lt_two_pow_self linarith rw [g3] at h₁ simp at h₁ left norm_num exact { left := g3, right := id h₁.symm } lemma imo_1997_p5_3_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : (x ^ y) ^ y = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : x ≤ y) (g₂ : x ^ y ≤ y) : (x, y) = (1, 1) := by have g₃: x = 1 := by by_contra! hc have g3: 2 ≤ x := by by_contra! gc interval_cases x . linarith . omega have g4: 2^y ≤ x^y := by { exact Nat.pow_le_pow_of_le_left g3 y } have g5: y < 2^y := by exact Nat.lt_two_pow_self linarith rw [g₃] at h₁ simp at h₁ norm_num exact { left := g₃, right := id h₁.symm } lemma imo_1997_p5_3_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : (x ^ y) ^ y = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : x ≤ y) (g2 : x ^ y ≤ y) : x = 1 := by by_contra! hc have g₃: 2 ≤ x := by by_contra! gc interval_cases x . linarith . omega have g₄: 2^y ≤ x ^ y := by { exact Nat.pow_le_pow_of_le_left g₃ y } have g₅: y < 2 ^ y := by exact Nat.lt_two_pow_self linarith lemma imo_1997_p5_3_3 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : (x ^ y) ^ y = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : x ≤ y) (g₂ : x ^ y ≤ y) -- (hc : ¬x = 1) (g₃ : 2 ≤ x) : False := by have g₄: 2^y ≤ x ^ y := by { exact Nat.pow_le_pow_of_le_left g₃ y } have g₅: y < 2 ^ y := by exact Nat.lt_two_pow_self linarith lemma imo_1997_p5_3_4 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : (x ^ y) ^ y = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : x ≤ y) (g2 : x ^ y ≤ y) -- (hc : ¬x = 1) -- (g₃ : 2 ≤ x) (g₄ : 2 ^ y ≤ x ^ y) : False := by have g₅: y < 2 ^ y := by exact Nat.lt_two_pow_self linarith lemma imo_1997_p5_3_5 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : (x ^ y) ^ y = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : x ≤ y) -- (g2 : x ^ y ≤ y) -- (hc : ¬x = 1) (g₃ : 2 ≤ x) : -- (g4 : 2 ^ y ≤ x ^ y) : y + 2 < 2 ^ y + x := by refine lt_add_of_lt_add_left ?_ g₃ refine add_lt_add_right ?_ 2 exact Nat.lt_two_pow_self lemma imo_1997_p5_3_6 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) (h₁ : (x ^ y) ^ y = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : x ≤ y) (g₂ : x ^ y ≤ y) (g₃ : x = 1) : y = 1 := by rw [g₃] at h₁ simp at h₁ exact id h₁.symm lemma imo_1997_p5_4 (x: ℕ) (h₀: 0 < x): (↑x = Real.exp (Real.log ↑x)):= by have hx_pos : 0 < (↑x : ℝ) := by exact Nat.cast_pos.mpr h₀ symm exact Real.exp_log hx_pos lemma imo_1997_p5_5 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) : y ^ 2 < x := by by_cases hy: 1 < y . have hx: 2 ≤ x := by linarith have h₂: y ^ x < x ^ x := by refine Nat.pow_lt_pow_left hxy ?_ exact Nat.ne_of_lt' h₀.1 rw [← h₁] at h₂ exact (Nat.pow_lt_pow_iff_right hx).mp h₂ . push_neg at hy interval_cases y . simp exact h₀.1 . simp at * assumption lemma imo_1997_p5_5_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) (hy : 1 < y) : y ^ 2 < x := by have hx: 2 ≤ x := by linarith have h₂: y ^ x < x ^ x := by refine Nat.pow_lt_pow_left hxy ?_ exact Nat.ne_of_lt' h₀.1 rw [← h₁] at h₂ exact (Nat.pow_lt_pow_iff_right hx).mp h₂ lemma imo_1997_p5_5_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) : -- (hy : 1 < y) -- (hx : 2 ≤ x) : y ^ x < x ^ x := by refine Nat.pow_lt_pow_left hxy ?_ exact Nat.ne_of_lt' h₀.1 lemma imo_1997_p5_5_3 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) (hx : 2 ≤ x) (h₂ : y ^ x < x ^ x) : y ^ 2 < x := by rw [← h₁] at h₂ exact (Nat.pow_lt_pow_iff_right hx).mp h₂ lemma imo_1997_p5_5_4 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) (hy : ¬1 < y) : y ^ 2 < x := by push_neg at hy interval_cases y . simp exact h₀.1 . simp at * assumption lemma imo_1997_p5_6 (x y: ℕ) (h₀: 0 < x ∧ 0 < y) (h₁: x ^ y ^ 2 = y ^ x) : (↑x / ↑y^2) ^ y ^ 2 = (↑y:ℝ)^ ((↑x:ℝ) - 2 * ↑y ^ 2) := by have g₁: (↑x:ℝ) ^ (↑y:ℝ) ^ 2 = (↑y:ℝ) ^ (↑x:ℝ) := by norm_cast have g₂: 0 < ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) := by norm_cast exact pow_pos h₀.2 _ have g₃: ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) := by refine (div_left_inj' ?_).mpr g₁ norm_cast refine pow_ne_zero _ ?_ linarith [h₀.2] have gy: 0 < (↑y:ℝ) := by norm_cast exact h₀.2 rw [← Real.rpow_sub gy (↑x) (2 * ↑y ^ 2)] at g₃ have g₄: ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = (↑x / ↑y^2) ^ y ^ 2 := by have g₅: (↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2) = ((↑y:ℝ) ^ 2) ^ ((↑y:ℝ) ^ 2) := by norm_cast refine pow_mul y 2 (y^2) rw [g₅] symm norm_cast have g₆: ((↑x:ℝ) / ↑y ^ 2) ^ y ^ 2 = ↑x ^ y ^ 2 / (↑y ^ 2) ^ y ^ 2 := by refine div_pow (↑x:ℝ) ((↑y:ℝ) ^ 2) (y^2) norm_cast at * rw [g₄] at g₃ norm_cast at * lemma imo_1997_p5_6_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) : -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) : 0 < ↑y ^ (2 * ↑y ^ 2) := by exact pow_pos h₀.2 _ lemma imo_1997_p5_6_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (g₁ : (↑x:ℝ) ^ (↑y:ℝ) ^ 2 = (↑y:ℝ) ^ (↑x:ℝ)) : -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) : (↑x / ↑y ^ 2) ^ y ^ 2 = (↑y:ℝ) ^ ((↑x:ℝ) - 2 * ↑y ^ 2) := by have g₃: ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) := by refine (div_left_inj' ?_).mpr g₁ norm_cast refine pow_ne_zero _ ?_ linarith [h₀.2] have gy: 0 < (↑y:ℝ) := by norm_cast exact h₀.2 rw [← Real.rpow_sub gy (↑x) (2 * ↑y ^ 2)] at g₃ have g₄: ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = (↑x / ↑y^2) ^ y ^ 2 := by have g₅: (↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2) = ((↑y:ℝ) ^ 2) ^ ((↑y:ℝ) ^ 2) := by norm_cast refine pow_mul y 2 (y^2) rw [g₅] symm norm_cast have g₆: ((↑x:ℝ) / ↑y ^ 2) ^ y ^ 2 = ↑x ^ y ^ 2 / (↑y ^ 2) ^ y ^ 2 := by refine div_pow (↑x:ℝ) ((↑y:ℝ) ^ 2) (y^2) norm_cast at * rw [g₄] at g₃ norm_cast at * lemma imo_1997_p5_6_3 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) : -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) : ↑y ^ (2 * ↑y ^ 2) ≠ 0 := by norm_cast refine pow_ne_zero _ ?_ linarith [h₀.2] lemma imo_1997_p5_6_4 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (g₁ : (↑x:ℝ) ^ (↑y:ℝ) ^ 2 = (↑y:ℝ) ^ (↑x:ℝ)) : -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) -- (g₃ : ↑x ^ ↑y ^ 2 / ↑y ^ (2 * ↑y ^ 2) = ↑y ^ ↑x / ↑y ^ (2 * ↑y ^ 2)) -- (gy : 0 < ↑y) : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) := by refine (div_left_inj' ?_).mpr g₁ norm_cast refine pow_ne_zero _ ?_ linarith [h₀.2] lemma imo_1997_p5_6_5 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) (g₃ : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2))) (gy : 0 < (↑y:ℝ)) : (↑x / ↑y ^ 2) ^ y ^ 2 = (↑y:ℝ) ^ ((↑x:ℝ) - 2 * ↑y ^ 2) := by rw [← Real.rpow_sub gy (↑x) (2 * ↑y ^ 2)] at g₃ have g₄: ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = (↑x / ↑y^2) ^ y ^ 2 := by have g₅: (↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2) = ((↑y:ℝ) ^ 2) ^ ((↑y:ℝ) ^ 2) := by norm_cast refine pow_mul y 2 (y^2) rw [g₅] symm norm_cast have g₆: ((↑x:ℝ) / ↑y ^ 2) ^ y ^ 2 = ↑x ^ y ^ 2 / (↑y ^ 2) ^ y ^ 2 := by refine div_pow (↑x:ℝ) ((↑y:ℝ) ^ 2) (y^2) norm_cast at * rw [g₄] at g₃ norm_cast at * lemma imo_1997_p5_6_6 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) (g₃ : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2))) (gy : 0 < (↑y:ℝ)) : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = (↑x / ↑y^2) ^ y ^ 2 := by have g₅: (↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2) = ((↑y:ℝ) ^ 2) ^ ((↑y:ℝ) ^ 2) := by norm_cast refine pow_mul y 2 (y^2) rw [g₅] symm norm_cast have g₆: ((↑x:ℝ) / ↑y ^ 2) ^ y ^ 2 = ↑x ^ y ^ 2 / (↑y ^ 2) ^ y ^ 2 := by refine div_pow (↑x:ℝ) ((↑y:ℝ) ^ 2) (y^2) norm_cast at * lemma imo_1997_p5_6_7 -- (x : ℕ) (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) -- (g₃ : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) -- = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2))) (hy : 0 < y) (hxy : y < x) : (↑y:ℝ) ^ (2 * (y ^ 2)) < ((↑x:ℝ) ^ 2) ^ (y ^ 2) := by rw [pow_mul (↑y:ℝ) 2 (y ^ 2)] refine pow_lt_pow_left₀ ?_ ?_ ?_ . norm_cast exact Nat.pow_lt_pow_left hxy (by decide) . exact sq_nonneg (↑y:ℝ) . symm refine Nat.ne_of_lt ?_ exact pos_pow_of_pos 2 hy lemma imo_1997_p5_6_8 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) (g₃ : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2))) (gy : 0 < (↑y:ℝ)) (g₅ : (↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2) = ((↑y:ℝ) ^ 2) ^ ((↑y:ℝ) ^ 2)) : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = (↑x / ↑y^2) ^ y ^ 2 := by rw [g₅] symm norm_cast have g₆: ((↑x:ℝ) / ↑y ^ 2) ^ y ^ 2 = ↑x ^ y ^ 2 / (↑y ^ 2) ^ y ^ 2 := by refine div_pow (↑x:ℝ) ((↑y:ℝ) ^ 2) (y^2) norm_cast at * lemma imo_1997_p5_6_9 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) (g₃ : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = ((↑y:ℝ) ^ (↑x:ℝ)) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2))) (gy : 0 < (↑y:ℝ)) (g₅ : (↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2) = ((↑y:ℝ) ^ 2) ^ ((↑y:ℝ) ^ 2)) : ((↑x:ℝ) ^ (↑y:ℝ) ^ 2) / ((↑y:ℝ) ^ (2 * (↑y:ℝ) ^ 2)) = (↑x / ↑y^2) ^ y ^ 2 := by rw [g₅] symm norm_cast have g₆: ((↑x:ℝ) / ↑y ^ 2) ^ y ^ 2 = ↑x ^ y ^ 2 / (↑y ^ 2) ^ y ^ 2 := by refine div_pow (↑x:ℝ) ((↑y:ℝ) ^ 2) (y^2) norm_cast at * lemma imo_1997_p5_6_10 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : ↑x ^ ↑y ^ 2 = ↑y ^ ↑x) -- (g₂ : 0 < ↑y ^ (2 * ↑y ^ 2)) (g₃ : ↑x ^ ↑y ^ 2 / ↑y ^ (2 * ↑y ^ 2) = ↑y ^ (↑x - 2 * ↑y ^ 2)) (gy : 0 < ↑y) (g₄ : ↑x ^ ↑y ^ 2 / ↑y ^ (2 * ↑y ^ 2) = (↑x / ↑y ^ 2) ^ y ^ 2) : (↑x / ↑y ^ 2) ^ y ^ 2 = ↑y ^ (↑x - 2 * ↑y ^ 2) := by rw [g₄] at g₃ norm_cast at * lemma imo_1997_p5_7 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) : 2 * y ^ 2 < x := by by_cases hy1: y = 1 . rw [hy1] norm_num by_contra! hc interval_cases x . linarith . linarith . rw [hy1] at h₁ simp at h₁ . have hy: 1 < y := by contrapose! hy1 linarith clear hy1 have h₂: (↑y:ℝ) ^ 2 < ↑x := by norm_cast exact imo_1997_p5_5 x y h₀ h₁ hxy have h₃: 1 < ↑x / (↑y:ℝ) ^ 2 := by refine (one_lt_div ?_).mpr h₂ norm_cast exact pow_pos h₀.2 2 have h₄: 1 < (↑x / (↑y:ℝ)^2)^(y^2) := by refine one_lt_pow₀ h₃ ?_ refine Nat.ne_of_gt ?_ refine sq_pos_of_pos ?_ exact lt_of_succ_lt hy have h₅: (↑x/ (↑y:ℝ)^2)^(y^2) = (↑y:ℝ)^((↑x:ℝ) - 2*(↑y:ℝ)^2) := by exact imo_1997_p5_6 x y h₀ h₁ rw [h₅] at h₄ have h₆: 0 < (↑x:ℝ) - 2 * (↑y:ℝ) ^ 2 := by by_contra! hc cases' lt_or_eq_of_le hc with hlt heq . have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] . rw [heq] at h₄ simp at h₄ simp at h₆ norm_cast at h₆ lemma imo_1997_p5_7_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) (hy1 : y = 1) : 2 * y ^ 2 < x := by rw [hy1] norm_num by_contra! hc interval_cases x . linarith . linarith . rw [hy1] at h₁ simp at h₁ lemma imo_1997_p5_7_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) (hy1 : y = 1) : 2 < x := by by_contra! hc interval_cases x . linarith . linarith . rw [hy1] at h₁ simp at h₁ lemma imo_1997_p5_7_3 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) (hy1 : y = 1) (hc : x ≤ 2) : False := by interval_cases x . linarith . linarith . rw [hy1] at h₁ simp at h₁ lemma imo_1997_p5_7_4 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) (hy : 1 < y) : 2 * y ^ 2 < x := by have h₂: (↑y:ℝ) ^ 2 < ↑x := by norm_cast exact imo_1997_p5_5 x y h₀ h₁ hxy have h₃: 1 < ↑x / (↑y:ℝ) ^ 2 := by refine (one_lt_div ?_).mpr h₂ norm_cast exact pow_pos h₀.2 2 have h₄: 1 < (↑x / (↑y:ℝ)^2)^(y^2) := by refine one_lt_pow₀ h₃ ?_ refine Nat.ne_of_gt ?_ refine sq_pos_of_pos ?_ exact lt_of_succ_lt hy have h₅: (↑x/ (↑y:ℝ)^2)^(y^2) = (↑y:ℝ)^((↑x:ℝ) - 2*(↑y:ℝ)^2) := by exact imo_1997_p5_6 x y h₀ h₁ rw [h₅] at h₄ have h₆: 0 < (↑x:ℝ) - 2 * (↑y:ℝ) ^ 2 := by by_contra! hc cases' lt_or_eq_of_le hc with hlt heq . have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] . rw [heq] at h₄ simp at h₄ simp at h₆ norm_cast at h₆ lemma imo_1997_p5_7_5 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (hy : 1 < y) (h₂ : (↑y:ℝ) ^ 2 < ↑x) : 2 * y ^ 2 < x := by have h₃: 1 < ↑x / (↑y:ℝ) ^ 2 := by refine (one_lt_div ?_).mpr h₂ norm_cast exact pow_pos h₀.2 2 have h₄: 1 < (↑x / (↑y:ℝ)^2)^(y^2) := by refine one_lt_pow₀ h₃ ?_ refine Nat.ne_of_gt ?_ refine sq_pos_of_pos ?_ exact lt_of_succ_lt hy have h₅: (↑x/ (↑y:ℝ)^2)^(y^2) = (↑y:ℝ)^((↑x:ℝ) - 2*(↑y:ℝ)^2) := by exact imo_1997_p5_6 x y h₀ h₁ rw [h₅] at h₄ have h₆: 0 < (↑x:ℝ) - 2 * (↑y:ℝ) ^ 2 := by by_contra! hc cases' lt_or_eq_of_le hc with hlt heq . have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] . rw [heq] at h₄ simp at h₄ simp at h₆ norm_cast at h₆ lemma imo_1997_p5_7_6 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) (h₂ : (↑y:ℝ) ^ 2 < ↑x) : 1 < ↑x / (↑y:ℝ) ^ 2 := by refine (one_lt_div ?_).mpr h₂ norm_cast exact pow_pos h₀.2 2 lemma imo_1997_p5_7_7 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) (h₃ : 1 < ↑x / (↑y:ℝ) ^ 2) : 2 * y ^ 2 < x := by have h₄: 1 < (↑x / (↑y:ℝ)^2)^(y^2) := by refine one_lt_pow₀ h₃ ?_ refine Nat.ne_of_gt ?_ refine sq_pos_of_pos ?_ exact lt_of_succ_lt hy have h₅: (↑x/ (↑y:ℝ)^2)^(y^2) = (↑y:ℝ)^((↑x:ℝ) - 2*(↑y:ℝ)^2) := by exact imo_1997_p5_6 x y h₀ h₁ rw [h₅] at h₄ have h₆: 0 < (↑x:ℝ) - 2 * (↑y:ℝ) ^ 2 := by by_contra! hc cases' lt_or_eq_of_le hc with hlt heq . have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] . rw [heq] at h₄ simp at h₄ simp at h₆ norm_cast at h₆ lemma imo_1997_p5_7_8 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) (h₃ : 1 < ↑x / ↑y ^ 2) : 1 < (↑x / ↑y ^ 2) ^ y ^ 2 := by refine one_lt_pow₀ h₃ ?_ refine Nat.ne_of_gt ?_ refine sq_pos_of_pos ?_ exact lt_of_succ_lt hy lemma imo_1997_p5_7_9 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) -- (h₃ : 1 < ↑x / ↑y ^ 2) (h₄ : 1 < (↑x / (↑y:ℝ)^2)^(y^2)) (h₅ : (↑x/ (↑y:ℝ)^2)^(y^2) = (↑y:ℝ)^((↑x:ℝ) - 2*(↑y:ℝ)^2)) : 2 * y ^ 2 < x := by rw [h₅] at h₄ have h₆: 0 < (↑x:ℝ) - 2 * (↑y:ℝ) ^ 2 := by by_contra! hc cases' lt_or_eq_of_le hc with hlt heq . have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] . rw [heq] at h₄ simp at h₄ simp at h₆ norm_cast at h₆ lemma imo_1997_p5_7_10 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) -- (h₃ : 1 < ↑x / ↑y ^ 2) (h₄ : 1 < ↑y ^ (↑x - 2 * ↑y ^ 2)) (h₅ : (↑x / ↑y ^ 2) ^ y ^ 2 = ↑y ^ (↑x - 2 * ↑y ^ 2)) : 0 < ↑x - 2 * ↑y ^ 2 := by by_contra! hc cases' lt_or_eq_of_le hc with hlt heq . have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] . rw [heq] at h₄ simp at h₄ lemma imo_1997_p5_7_11 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) -- (h₃ : 1 < ↑x / ↑y ^ 2) (h₄ : 1 < ↑y ^ (↑x - 2 * ↑y ^ 2)) (h₅ : (↑x / ↑y ^ 2) ^ y ^ 2 = ↑y ^ (↑x - 2 * ↑y ^ 2)) (hc : ↑x - 2 * ↑y ^ 2 ≤ 0) : False := by cases' lt_or_eq_of_le hc with hlt heq . have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] . rw [heq] at h₄ simp at h₄ lemma imo_1997_p5_7_12 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) -- (h₃ : 1 < ↑x / ↑y ^ 2) (h₄ : 1 < ↑y ^ (↑x - 2 * ↑y ^ 2)) -- (h₅ : (↑x / ↑y ^ 2) ^ y ^ 2 = ↑y ^ (↑x - 2 * ↑y ^ 2)) -- (hc : ↑x - 2 * ↑y ^ 2 ≤ 0) (hlt : ↑x - 2 * ↑y ^ 2 < 0) : False := by have gy: 1 < (↑y:ℝ) := by norm_cast have glt: (↑x:ℝ) - 2*(↑y:ℝ)^2 < (↑0:ℝ) := by norm_cast at * have g₁: (↑y:ℝ) ^ ((↑x:ℝ) - 2*(↑y:ℝ)^2) < (↑y:ℝ) ^ (↑0:ℝ) := by exact Real.rpow_lt_rpow_of_exponent_lt gy glt simp at g₁ linarith[ h₄,g₁] lemma imo_1997_p5_7_13 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) -- (h₃ : 1 < ↑x / ↑y ^ 2) (h₄ : 1 < ↑y ^ (↑x - 2 * ↑y ^ 2)) -- (h₅ : (↑x / ↑y ^ 2) ^ y ^ 2 = ↑y ^ (↑x - 2 * ↑y ^ 2)) -- (hc : ↑x - 2 * ↑y ^ 2 ≤ 0) -- (hlt : ↑x - 2 * ↑y ^ 2 < 0) (gy : 1 < ↑y) -- (glt : ↑x - 2 * ↑y ^ 2 < 0) (g₁ : ↑y ^ (↑x - 2 * ↑y ^ 2) < ↑y ^ 0) : False := by simp at g₁ linarith[ h₄,g₁] lemma imo_1997_p5_7_14 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) -- (h₃ : 1 < ↑x / ↑y ^ 2) (h₄ : 1 < ↑y ^ (↑x - 2 * ↑y ^ 2)) (h₅ : (↑x / ↑y ^ 2) ^ y ^ 2 = ↑y ^ (↑x - 2 * ↑y ^ 2)) (hc : ↑x - 2 * ↑y ^ 2 ≤ 0) (heq : ↑x - 2 * ↑y ^ 2 = 0) : False := by rw [heq] at h₄ simp at h₄ lemma imo_1997_p5_7_15 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (hy : 1 < y) -- (h₂ : ↑y ^ 2 < ↑x) -- (h₃ : 1 < ↑x / ↑y ^ 2) -- (h₄ : 1 < ↑y ^ (↑x - 2 * ↑y ^ 2)) -- (h₅ : (↑x / ↑y ^ 2) ^ y ^ 2 = ↑y ^ (↑x - 2 * ↑y ^ 2)) (h₆ : 0 < ↑x - 2 * ↑y ^ 2) : 2 * y ^ 2 < x := by simp at h₆ norm_cast at h₆ lemma imo_1997_p5_8 (x y: ℕ) (h₀: 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hyx: y < x) : (y^2 ∣ x) := by have h₂: (x ^ y ^ 2).factorization = (y^x).factorization := by exact congr_arg Nat.factorization h₁ simp at h₂ symm at h₂ have hxy1: 2 * y^2 ≤ x := by exact le_of_lt (imo_1997_p5_7 x y h₀ h₁ hyx) have hxy: 2 • y^2 ≤ x := by exact hxy1 have h₃: 2 • y^2 • x.factorization ≤ x • x.factorization := by rw [← smul_assoc] refine nsmul_le_nsmul_left ?_ hxy norm_num rw [← h₂] at h₃ have h₄: 2 • x • y.factorization = x • (2 • y.factorization) := by rw [← smul_assoc, ← smul_assoc] have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] rw [h₄] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) (h₂ : Nat.factorization (x ^ y ^ 2) = Nat.factorization (y ^ x)) : y ^ 2 ∣ x := by simp at h₂ symm at h₂ have hxy1: 2 * y^2 ≤ x := by exact le_of_lt (imo_1997_p5_7 x y h₀ h₁ hyx) have hxy: 2 • y^2 ≤ x := by exact hxy1 have h₃: 2 • y^2 • x.factorization ≤ x • x.factorization := by rw [← smul_assoc] refine nsmul_le_nsmul_left ?_ hxy norm_num rw [← h₂] at h₃ have h₄: 2 • x • y.factorization = x • (2 • y.factorization) := by rw [← smul_assoc, ← smul_assoc] have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] rw [h₄] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) : y ^ 2 ∣ x := by have hxy1: 2 * y^2 ≤ x := by exact le_of_lt (imo_1997_p5_7 x y h₀ h₁ hyx) have hxy: 2 • y^2 ≤ x := by exact hxy1 have h₃: 2 • y^2 • x.factorization ≤ x • x.factorization := by rw [← smul_assoc] refine nsmul_le_nsmul_left ?_ hxy norm_num rw [← h₂] at h₃ have h₄: 2 • x • y.factorization = x • (2 • y.factorization) := by rw [← smul_assoc, ← smul_assoc] have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] rw [h₄] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_3 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) (hxy : 2 • y ^ 2 ≤ x) : y ^ 2 ∣ x := by have h₃: 2 • y^2 • x.factorization ≤ x • x.factorization := by rw [← smul_assoc] refine nsmul_le_nsmul_left ?_ hxy norm_num rw [← h₂] at h₃ have h₄: 2 • x • y.factorization = x • (2 • y.factorization) := by rw [← smul_assoc, ← smul_assoc] have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] rw [h₄] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_4 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) (hxy : 2 • y ^ 2 ≤ x) : 2 • y ^ 2 • Nat.factorization x ≤ x • Nat.factorization x := by rw [← smul_assoc] refine nsmul_le_nsmul_left ?_ hxy norm_num lemma imo_1997_p5_8_5 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) (hxy : 2 • y ^ 2 ≤ x) : (2 • y ^ 2) • Nat.factorization x ≤ x • Nat.factorization x := by refine nsmul_le_nsmul_left ?_ hxy norm_num lemma imo_1997_p5_8_6 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) (hxy1 : 2 * y ^ 2 ≤ x) (hxy : 2 • y ^ 2 ≤ x) : 0 ≤ Nat.factorization x := by exact _root_.zero_le x.factorization lemma imo_1997_p5_8_7 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) (h₃ : 2 • y ^ 2 • Nat.factorization x ≤ x • Nat.factorization x) : y ^ 2 ∣ x := by rw [← h₂] at h₃ have h₄: 2 • x • y.factorization = x • (2 • y.factorization) := by rw [← smul_assoc, ← smul_assoc] have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] rw [h₄] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_8 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) (h₃ : 2 • x • Nat.factorization y ≤ x • Nat.factorization x) : y ^ 2 ∣ x := by have h₄: 2 • x • y.factorization = x • (2 • y.factorization) := by rw [← smul_assoc, ← smul_assoc] have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] rw [h₄] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_9 (x y : ℕ) : -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) -- (h₃ : 2 • x • Nat.factorization y ≤ x • Nat.factorization x) : 2 • x • Nat.factorization y = x • 2 • Nat.factorization y := by rw [← smul_assoc, ← smul_assoc] have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] lemma imo_1997_p5_8_10 (x y : ℕ) : -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) -- (h₃ : 2 • x • Nat.factorization y ≤ x • Nat.factorization x) : (2 • x) • Nat.factorization y = (x • 2) • Nat.factorization y := by have g₄: 2 • x = x • 2 := by simp exact mul_comm 2 x rw [g₄] lemma imo_1997_p5_8_11 (x : ℕ) : -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) -- (h₃ : 2 • x • Nat.factorization y ≤ x • Nat.factorization x) : 2 • x = x • 2 := by rw [smul_eq_mul, smul_eq_mul] exact Nat.mul_comm 2 x lemma imo_1997_p5_8_12 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) (h₃ : 2 • x • Nat.factorization y ≤ x • Nat.factorization x) (h₄ : 2 • x • Nat.factorization y = x • 2 • Nat.factorization y) : y ^ 2 ∣ x := by rw [h₄] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ rw [← Nat.factorization_pow] at h₃ have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_13 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) (h₃ : Nat.factorization ((y ^ 2) ^ x) ≤ Nat.factorization (x ^ x)) : -- (h₄ : 2 • x • Nat.factorization y = x • 2 • Nat.factorization y) : y ^ 2 ∣ x := by have h₅: (y ^ 2) ^ x ∣ x^x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_8_14 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) (h₃ : Nat.factorization ((y ^ 2) ^ x) ≤ Nat.factorization (x ^ x)) : -- (h₄ : 2 • x • Nat.factorization y = x • 2 • Nat.factorization y) : (y ^ 2) ^ x ∣ x ^ x := by have g₁: (y ^ 2) ^ x ≠ 0 := by refine pow_ne_zero x ?_ refine pow_ne_zero 2 ?_ linarith have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ lemma imo_1997_p5_8_15 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) (h₃ : Nat.factorization ((y ^ 2) ^ x) ≤ Nat.factorization (x ^ x)) -- (h₄ : 2 • x • Nat.factorization y = x • 2 • Nat.factorization y) (g₁ : (y ^ 2) ^ x ≠ 0) : (y ^ 2) ^ x ∣ x ^ x := by have g₂: x ^ x ≠ 0 := by refine pow_ne_zero x ?_ linarith exact (Nat.factorization_le_iff_dvd g₁ g₂).mp h₃ lemma imo_1997_p5_8_16 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) (h₃ : Nat.factorization ((y ^ 2) ^ x) ≤ Nat.factorization (x ^ x)) -- (h₄ : 2 • x • Nat.factorization y = x • 2 • Nat.factorization y) (g₁ : y = 0 → x = 0) : (y ^ 2) ^ x ∣ x ^ x := by refine (Nat.factorization_le_iff_dvd ?_ ?_).mp h₃ . simp_all only [Nat.factorization_pow, ne_eq, pow_eq_zero_iff', OfNat.ofNat_ne_zero, not_false_eq_true,] omega . simp_all only [ne_eq, pow_eq_zero_iff', and_not_self, not_false_eq_true] lemma imo_1997_p5_8_17 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hyx : y < x) -- (h₂ : x • Nat.factorization y = y ^ 2 • Nat.factorization x) -- (hxy1 : 2 * y ^ 2 ≤ x) -- (hxy : 2 • y ^ 2 ≤ x) -- (h₃ : Nat.factorization ((y ^ 2) ^ x) ≤ Nat.factorization (x ^ x)) -- (h₄ : 2 • x • Nat.factorization y = x • 2 • Nat.factorization y) (h₅ : (y ^ 2) ^ x ∣ x ^ x) : y ^ 2 ∣ x := by refine (Nat.pow_dvd_pow_iff ?_).mp h₅ exact Nat.ne_of_gt h₀.1 lemma imo_1997_p5_9 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (h₂ : Real.log (↑x:ℝ) = Real.log ↑y * ↑x / (↑(y ^ 2:ℕ ):ℝ) ) (hxy : y < x) : x = y ^ (x / y ^ 2) := by have h_exp : Real.exp (Real.log ↑x) = Real.exp (Real.log ↑y * (↑x:ℝ) / ((↑y:ℝ)) ^ 2) := by rw [h₂] norm_cast rw [← imo_1997_p5_4 x h₀.1] at h_exp rw [← mul_div] at h_exp rw [Real.exp_mul] at h_exp rw [← imo_1997_p5_4 y h₀.2] at h_exp have h₃: (↑x:ℝ) / ((↑y:ℝ)^2) = (↑(x / y^2:ℕ):ℝ) := by norm_cast symm have g₂: y^2 ∣ x := by exact imo_1997_p5_8 x y h₀ h₁ hxy have h₃: (↑(y^(2:ℕ)):ℝ) ≠ 0 := by norm_cast exact pow_ne_zero 2 ( by linarith) exact Nat.cast_div g₂ h₃ have h₄ : (↑(y ^ (x / y ^ (2:ℕ))):ℝ) = (↑y:ℝ)^((↑x:ℝ) / ((↑y:ℝ)^2)) := by rw [Nat.cast_pow, h₃] norm_cast rw [←h₄] at h_exp exact Nat.cast_inj.mp h_exp lemma imo_1997_p5_9_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) (hxy : y < x) (h_exp : rexp (Real.log ↑x) = rexp (Real.log ↑y * ↑x / ↑y ^ 2)) : x = y ^ (x / y ^ 2) := by rw [← imo_1997_p5_4 x h₀.1] at h_exp rw [← mul_div] at h_exp rw [Real.exp_mul] at h_exp rw [← imo_1997_p5_4 y h₀.2] at h_exp have h₃: (↑x:ℝ) / ((↑y:ℝ)^2) = (↑(x / y^2:ℕ):ℝ) := by norm_cast symm have g₂: y^2 ∣ x := by exact imo_1997_p5_8 x y h₀ h₁ hxy have h₃: (↑(y^(2:ℕ)):ℝ) ≠ 0 := by norm_cast exact pow_ne_zero 2 ( by linarith) exact Nat.cast_div g₂ h₃ have h₄ : (↑(y ^ (x / y ^ (2:ℕ))):ℝ) = (↑y:ℝ)^((↑x:ℝ) / ((↑y:ℝ)^2)) := by rw [Nat.cast_pow, h₃] norm_cast rw [←h₄] at h_exp exact Nat.cast_inj.mp h_exp lemma imo_1997_p5_9_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) (hxy : y < x) (h_exp : ↑x = rexp (Real.log ↑y * (↑x / ↑y ^ 2))) : x = y ^ (x / y ^ 2) := by rw [Real.exp_mul] at h_exp rw [← imo_1997_p5_4 y h₀.2] at h_exp have h₃: (↑x:ℝ) / ((↑y:ℝ)^2) = (↑(x / y^2:ℕ):ℝ) := by norm_cast symm have g₂: y^2 ∣ x := by exact imo_1997_p5_8 x y h₀ h₁ hxy have h₃: (↑(y^(2:ℕ)):ℝ) ≠ 0 := by norm_cast exact pow_ne_zero 2 ( by linarith) exact Nat.cast_div g₂ h₃ have h₄ : (↑(y ^ (x / y ^ (2:ℕ))):ℝ) = (↑y:ℝ)^((↑x:ℝ) / ((↑y:ℝ)^2)) := by rw [Nat.cast_pow, h₃] norm_cast rw [←h₄] at h_exp exact Nat.cast_inj.mp h_exp lemma imo_1997_p5_9_3 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) (hxy : y < x) (h_exp : ↑x = rexp (Real.log ↑y) ^ (↑x / (↑y:ℝ) ^ 2)) : x = y ^ (x / y ^ 2) := by rw [← imo_1997_p5_4 y h₀.2] at h_exp have h₃: (↑x:ℝ) / ((↑y:ℝ)^2) = (↑(x / y^2:ℕ):ℝ) := by norm_cast symm have g₂: y^2 ∣ x := by exact imo_1997_p5_8 x y h₀ h₁ hxy have h₃: (↑(y^(2:ℕ)):ℝ) ≠ 0 := by norm_cast exact pow_ne_zero 2 ( by linarith) exact Nat.cast_div g₂ h₃ have h₄ : (↑(y ^ (x / y ^ (2:ℕ))):ℝ) = (↑y:ℝ)^((↑x:ℝ) / ((↑y:ℝ)^2)) := by rw [Nat.cast_pow, h₃] norm_cast rw [←h₄] at h_exp exact Nat.cast_inj.mp h_exp lemma imo_1997_p5_9_4 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) (hxy : y < x) (h_exp : (↑x:ℝ) = (↑y:ℝ) ^ ((↑x:ℝ) / (↑y:ℝ) ^ 2)) : x = y ^ (x / y ^ 2) := by have h₃: (↑x:ℝ) / ((↑y:ℝ)^2) = (↑(x / y^2:ℕ)) := by norm_cast symm have g₂: y^2 ∣ x := by exact imo_1997_p5_8 x y h₀ h₁ hxy have h₃: (↑(y^(2:ℕ)):ℝ) ≠ 0 := by norm_cast exact pow_ne_zero 2 ( by linarith) exact Nat.cast_div g₂ h₃ have h₄ : (↑(y ^ (x / y ^ (2:ℕ))):ℝ) = (↑y:ℝ)^((↑x:ℝ) / ((↑y:ℝ)^2)) := by rw [Nat.cast_pow, h₃] norm_cast rw [←h₄] at h_exp exact Nat.cast_inj.mp h_exp lemma imo_1997_p5_9_5 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) (hxy : y < x) : -- (h_exp : ↑x = ↑y ^ (↑x / ↑y ^ 2:ℕ)) : (↑x:ℝ) / ((↑y:ℝ)^2) = (↑(x / y^2:ℕ):ℝ) := by norm_cast symm have g₂: y^2 ∣ x := by exact imo_1997_p5_8 x y h₀ h₁ hxy have h₃: (↑(y^(2:ℕ)):ℝ) ≠ 0 := by norm_cast exact pow_ne_zero 2 ( by linarith) exact Nat.cast_div g₂ h₃ lemma imo_1997_p5_9_6 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) -- (hxy : y < x) -- (h_exp : ↑x = ↑y ^ (↑x / ↑y ^ 2)) (g₂ : y ^ 2 ∣ x) : (↑(x / y^2:ℕ):ℝ) = (↑x:ℝ) / (↑(y^2:ℕ)) := by have h₃: (↑(y^(2:ℕ)):ℝ) ≠ 0 := by norm_cast exact pow_ne_zero 2 ( by linarith) exact Nat.cast_div g₂ h₃ lemma imo_1997_p5_9_7 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (h₂ : Real.log (↑x:ℝ) = Real.log ↑y * ↑x / (↑(y ^ 2:ℕ ):ℝ) ) : (↑x:ℝ) = (↑y:ℝ) ^ ((↑x:ℝ) / (↑y:ℝ) ^ 2) := by have h_exp : Real.exp (Real.log ↑x) = Real.exp (Real.log ↑y * (↑x:ℝ) / ((↑y:ℝ)) ^ 2) := by rw [h₂] norm_cast rw [← imo_1997_p5_4 x h₀.1] at h_exp rw [← mul_div] at h_exp rw [Real.exp_mul] at h_exp rw [← imo_1997_p5_4 y h₀.2] at h_exp exact h_exp lemma imo_1997_p5_9_8 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (h₂ : Real.log (↑x:ℝ) = Real.log ↑y * ↑x / (↑(y ^ 2:ℕ ):ℝ) ) : ↑x = rexp (Real.log ↑y * (↑x / ↑y ^ 2)) := by have h_exp : Real.exp (Real.log ↑x) = Real.exp (Real.log ↑y * (↑x:ℝ) / ((↑y:ℝ)) ^ 2) := by rw [h₂] norm_cast rw [← imo_1997_p5_4 x h₀.1] at h_exp rw [← mul_div] at h_exp exact h_exp lemma imo_1997_p5_9_9 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) -- (hxy : y < x) (h_exp : (↑x:ℝ) = (↑y:ℝ) ^ ((↑x:ℝ) / (↑y:ℝ) ^ 2)) (h₃ : (↑x:ℝ) / ((↑y:ℝ)^2) = (↑(x / y^2:ℕ))) : x = y ^ (x / y ^ 2) := by have h₄ : (↑(y ^ (x / y ^ (2:ℕ))):ℝ) = (↑y:ℝ)^((↑x:ℝ) / ((↑y:ℝ)^2)) := by rw [Nat.cast_pow, h₃] norm_cast rw [←h₄] at h_exp exact Nat.cast_inj.mp h_exp lemma imo_1997_p5_9_10 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) -- (hxy : y < x) -- (h_exp : ↑x = ↑y ^ (↑x / ↑y ^ 2)) (h₃ : (↑x:ℝ) / ((↑y:ℝ)^2) = ↑(x / y^2:ℕ)) : (↑(y ^ (x / y ^ (2:ℕ))):ℝ) = (↑y:ℝ) ^ ((↑x:ℝ) / ((↑y:ℝ)^2)) := by rw [Nat.cast_pow, h₃] norm_cast lemma imo_1997_p5_9_11 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (h₂ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) -- (hxy : y < x) (h_exp : ↑x = ↑(y ^ (x / y ^ 2))) (h₃ : ↑x / ↑y ^ 2 = ↑(x / y ^ 2)) (h₄ : ↑(y ^ (x / y ^ 2)) = ↑y ^ (↑x / ↑y ^ 2)) : x = y ^ (x / y ^ 2) := by rw [←h₄] at h_exp exact Nat.cast_inj.mp h_exp lemma imo_1997_p5_10 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) : x = y ^ (x / y ^ 2) := by -- sketch: y^2 * log x = x * log y have h₃: Real.log (x^(y^2)) = Real.log (y^x) := by norm_cast rw [h₁] have h₄: (↑(y ^ (2:ℕ)):ℝ) * Real.log x = ↑x * Real.log y := by have h41: Real.log (y^x) = (↑x:ℝ) * Real.log (y) := by exact Real.log_pow y x have h42: Real.log (x^(y^2)) = (↑(y ^ (2:ℕ)):ℝ) * Real.log x := by exact Real.log_pow x (y^2) rw [h41,h42] at h₃ exact h₃ have h₅: Real.log ↑x = Real.log ↑y * ↑x / (↑(y ^ (2:ℕ)):ℝ) := by by_contra! hc rw [mul_comm (Real.log ↑y) (↑x)] at hc rw [← h₄, mul_comm, ← mul_div] at hc rw [div_self, mul_one] at hc . apply hc norm_cast . norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 have h₆: x = y ^ (x / y ^ 2) := by exact imo_1997_p5_9 x y h₀ h₁ h₅ hxy exact h₆ lemma imo_1997_p5_10_1 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) : x = y ^ (x / y ^ 2) := by have h₄: (↑(y ^ (2:ℕ)):ℝ) * Real.log x = ↑x * Real.log y := by have h41: Real.log (y^x) = (↑x:ℝ) * Real.log (y) := by exact Real.log_pow y x have h42: Real.log (x^(y^2)) = (↑(y ^ (2:ℕ)):ℝ) * Real.log x := by exact Real.log_pow x (y^2) rw [h41,h42] at h₃ exact h₃ have h₅: Real.log ↑x = Real.log ↑y * ↑x / (↑(y ^ (2:ℕ)):ℝ) := by by_contra! hc rw [mul_comm (Real.log ↑y) (↑x)] at hc rw [← h₄, mul_comm, ← mul_div] at hc rw [div_self, mul_one] at hc . apply hc norm_cast . norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 have h₆: x = y ^ (x / y ^ 2) := by exact imo_1997_p5_9 x y h₀ h₁ h₅ hxy exact h₆ lemma imo_1997_p5_10_2 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y := by have h41: Real.log (y^x) = (↑x:ℝ) * Real.log (y) := by exact Real.log_pow y x have h42: Real.log (x^(y^2)) = (↑(y ^ (2:ℕ)):ℝ) * Real.log x := by exact Real.log_pow x (y^2) rw [h41,h42] at h₃ exact h₃ lemma imo_1997_p5_10_3 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) (h₄₁ : Real.log (↑y ^ x) = ↑x * Real.log ↑y) : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y := by have h₄₂: Real.log (x^(y^2)) = (↑(y ^ (2:ℕ)):ℝ) * Real.log x := by exact Real.log_pow x (y^2) rw [h₄₁,h₄₂] at h₃ exact h₃ lemma imo_1997_p5_10_4 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) (h₄₁ : Real.log (↑y ^ x) = ↑x * Real.log ↑y) (h₄₂ : Real.log (↑x ^ y ^ 2) = ↑(y ^ 2:ℕ) * Real.log ↑x) : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y := by rw [h₄₁,h₄₂] at h₃ exact h₃ lemma imo_1997_p5_10_5 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) -- (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) (h₄ : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y) : x = y ^ (x / y ^ 2) := by have h₅: Real.log ↑x = Real.log ↑y * ↑x / (↑(y ^ (2:ℕ)):ℝ) := by by_contra! hc rw [mul_comm (Real.log ↑y) (↑x)] at hc rw [← h₄, mul_comm, ← mul_div] at hc rw [div_self, mul_one] at hc . apply hc norm_cast . norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 have h₆: x = y ^ (x / y ^ 2) := by exact imo_1997_p5_9 x y h₀ h₁ h₅ hxy exact h₆ lemma imo_1997_p5_10_6 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) (h₄ : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y) : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ) := by by_contra! hc rw [mul_comm (Real.log ↑y) (↑x)] at hc rw [← h₄, mul_comm, ← mul_div] at hc rw [div_self, mul_one] at hc . apply hc norm_cast . norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 lemma imo_1997_p5_10_7 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) (h₄ : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y) (hc : ¬Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) : False := by rw [mul_comm (Real.log ↑y) (↑x)] at hc rw [← h₄, mul_comm, ← mul_div] at hc rw [div_self, mul_one] at hc . apply hc norm_cast . norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 lemma imo_1997_p5_10_8 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) (h₄ : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y) (hc : ¬Real.log ↑x = ↑x * Real.log ↑y / ↑(y ^ 2:ℕ)) : False := by rw [← h₄, mul_comm, ← mul_div] at hc rw [div_self, mul_one] at hc . apply hc norm_cast . norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 lemma imo_1997_p5_10_9 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) -- (h₄ : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y) (hc : ¬Real.log ↑x = Real.log ↑x * (↑(y ^ 2:ℕ) / ↑(y ^ 2:ℕ))) : False := by rw [div_self, mul_one] at hc . apply hc norm_cast . norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 lemma imo_1997_p5_10_10 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (hxy : y < x) -- (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) -- (h₄ : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y) (hc : ¬Real.log ↑x = Real.log ↑x * (↑(y ^ 2:ℕ) / ↑(y ^ 2:ℕ))) : ↑((y ^ 2):ℝ) ≠ 0 := by norm_cast push_neg refine pow_ne_zero 2 ?_ exact Nat.ne_of_gt h₀.2 lemma imo_1997_p5_10_11 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (hxy : y < x) -- (h₃ : Real.log (↑x ^ y ^ 2) = Real.log (↑y ^ x)) -- (h₄ : ↑(y ^ 2:ℕ) * Real.log ↑x = ↑x * Real.log ↑y) (h₅ : Real.log ↑x = Real.log ↑y * ↑x / ↑(y ^ 2:ℕ)) : x = y ^ (x / y ^ 2) := by exact imo_1997_p5_9 x y h₀ h₁ h₅ hxy lemma imo_1997_p5_11_1 (x y : ℕ) : -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) : x ^ y ^ 2 = (x ^ y) ^ y := by rw [Nat.pow_two] exact Nat.pow_mul x y y lemma imo_1997_p5_11_2 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : y < x) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by have h₃: x = y ^ (x / y ^ 2) := by exact imo_1997_p5_10 x y h₀ h₁ hxy let k:ℕ := x / y^2 have hk_def: k = x / y^2 := by exact rfl by_cases hk: k < 2 . rw [← hk_def] at h₃ interval_cases k . exfalso simp at h₃ linarith . exfalso simp at * linarith [hxy,h₃] . push_neg at hk rw [← hk_def] at h₃ have h₅: k = y^(k-2) := by rw [h₃] at hk_def nth_rewrite 1 [hk_def] exact Nat.pow_div hk h₀.2 by_cases hk5: k < 5 . interval_cases k . exfalso simp at h₅ . right norm_num simp at h₅ symm at h₅ rw [h₅] at h₃ norm_num at h₃ exact { left := h₃, right := h₅ } . simp at h₅ symm at h₅ have g₂: y^4 = y^2 * y^2 := by ring_nf rw [g₂, h₅] at h₃ norm_num at h₃ left norm_num constructor . exact h₃ . have h₆ : y ^ 2 = 2 ^ 2 := by norm_num exact h₅ have h₇: 0 ≤ y := by linarith exact (sq_eq_sq₀ h₇ (by linarith)).mp (h₆) push_neg at hk5 by_cases hy: 2 ≤ y . have h₅₁: k < y^(k-2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₇: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith exfalso linarith . push_neg at hy interval_cases y . linarith . simp at h₅ simp at h₃ linarith lemma imo_1997_p5_11_3 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : y < x) (h₃ : x = y ^ (x / y ^ 2)) (hk_def : k = x / y ^ 2) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by by_cases hk: k < 2 . rw [← hk_def] at h₃ interval_cases k . exfalso simp at h₃ linarith . exfalso simp at * linarith [hxy,h₃] . push_neg at hk rw [← hk_def] at h₃ have h₅: k = y^(k-2) := by rw [h₃] at hk_def nth_rewrite 1 [hk_def] exact Nat.pow_div hk h₀.2 by_cases hk5: k < 5 . interval_cases k . exfalso simp at h₅ . right norm_num simp at h₅ symm at h₅ rw [h₅] at h₃ norm_num at h₃ exact { left := h₃, right := h₅ } . simp at h₅ symm at h₅ have g₂: y^4 = y^2 * y^2 := by ring_nf rw [g₂, h₅] at h₃ norm_num at h₃ left norm_num constructor . exact h₃ . have h₆ : y ^ 2 = 2 ^ 2 := by norm_num exact h₅ have h₇: 0 ≤ y := by linarith exact (sq_eq_sq₀ h₇ (by linarith)).mp (h₆) push_neg at hk5 by_cases hy: 2 ≤ y . have h₅₁: k < y^(k-2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 refine (Nat.pow_le_pow_iff_left ?_).mpr hy have h₆₀: 2 < k - 2 := by exact hk1 exact Nat.not_eq_zero_of_lt h₆₀ have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₇: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith exfalso linarith . push_neg at hy interval_cases y . linarith . simp at h₅ simp at h₃ linarith lemma imo_1997_p5_11_4 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : y < x) (h₃ : x = y ^ (x / y ^ 2)) (hk_def : k = x / y ^ 2) (hk : k < 2) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by rw [← hk_def] at h₃ interval_cases k . exfalso simp at h₃ linarith . exfalso simp at * linarith [hxy,h₃] lemma imo_1997_p5_11_5 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : y < x) (h₃ : x = y ^ (x / y ^ 2)) (hk_def : k = x / y ^ 2) (hk : k < 2) : False := by rw [← hk_def] at h₃ interval_cases k . simp at h₃ linarith . simp at * linarith [hxy,h₃] lemma imo_1997_p5_11_6 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : y < x) (h₃ : x = y ^ (x / y ^ 2)) (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by rw [← hk_def] at h₃ have h₅: k = y^(k-2) := by rw [h₃] at hk_def nth_rewrite 1 [hk_def] exact Nat.pow_div hk h₀.2 by_cases hk5: k < 5 . interval_cases k . exfalso simp at h₅ . right norm_num simp at h₅ symm at h₅ rw [h₅] at h₃ norm_num at h₃ exact { left := h₃, right := h₅ } . simp at h₅ symm at h₅ have g₂: y^4 = y^2 * y^2 := by ring_nf rw [g₂, h₅] at h₃ norm_num at h₃ left norm_num constructor . exact h₃ . have h₆ : y ^ 2 = 2 ^ 2 := by norm_num exact h₅ have h₇: 0 ≤ y := by linarith exact (sq_eq_sq₀ h₇ (by linarith)).mp (h₆) push_neg at hk5 by_cases hy: 2 ≤ y . have h₅₁: k < y^(k-2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₇: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith exfalso linarith . push_neg at hy interval_cases y . linarith . simp at h₅ simp at h₃ linarith lemma imo_1997_p5_11_7 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) (h₃ : x = y ^ k) (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) : k = y ^ (k - 2) := by rw [h₃] at hk_def nth_rewrite 1 [hk_def] exact Nat.pow_div hk h₀.2 lemma imo_1997_p5_11_8 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) (h₃ : x = y ^ k) (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) (hk5 : k < 5) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by interval_cases k . exfalso simp at h₅ . right norm_num simp at h₅ symm at h₅ rw [h₅] at h₃ norm_num at h₃ exact { left := h₃, right := h₅ } . simp at h₅ symm at h₅ have g₂: y^4 = y^2 * y^2 := by ring_nf rw [g₂, h₅] at h₃ norm_num at h₃ left norm_num constructor . exact h₃ . have h₆ : y ^ 2 = 2 ^ 2 := by norm_num exact h₅ have h₇: 0 ≤ y := by linarith exact (sq_eq_sq₀ h₇ (by linarith)).mp (h₆) lemma imo_1997_p5_11_9 (x y : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) (h₃ : x = y ^ 3) (hk_def : 3 = x / y ^ 2) (hk : 2 ≤ 3) (h₅ : 3 = y ^ (3 - 2)) (hk5 : 3 < 5) : (x, y) = (27, 3) := by norm_num simp at h₅ symm at h₅ rw [h₅] at h₃ norm_num at h₃ exact { left := h₃, right := h₅ } lemma imo_1997_p5_11_10 (x y : ℕ) (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) (h₃ : x = y ^ 4) (hk_def : 4 = x / y ^ 2) (hk : 2 ≤ 4) (h₅ : 4 = y ^ (4 - 2)) (hk5 : 4 < 5) : (x, y) = (16, 2) := by simp at h₅ symm at h₅ have g₂: y^4 = y^2 * y^2 := by ring_nf rw [g₂, h₅] at h₃ norm_num at h₃ norm_num constructor . exact h₃ . have h₆ : y ^ 2 = 2 ^ 2 := by norm_num exact h₅ have h₇: 0 ≤ y := by linarith exact (sq_eq_sq₀ h₇ (by linarith)).mp (h₆) lemma imo_1997_p5_11_11 (y: ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (hk_def : 4 = x / y ^ 2) -- (hk : 2 ≤ 4) -- (hk5 : 4 < 5) (h₅ : y ^ 2 = 4) (g₂ : y ^ 4 = y ^ 2 * y ^ 2) : -- (h₃ : x = 16) : y = 2 := by rw [pow_two] at h₅ refine ((fun {m n} => Nat.mul_self_inj.mp) (?_)).symm exact h₅.symm lemma imo_1997_p5_11_12 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : y < x) (h₃ : x = y ^ k) (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) (hk5 : 5 ≤ k) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by by_cases hy: 2 ≤ y . have h₅₁: k < y^(k-2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₇: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith exfalso linarith . push_neg at hy interval_cases y . linarith . simp at h₅ simp at h₃ linarith lemma imo_1997_p5_11_13 (x y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) (hk5 : 5 ≤ k) (hy : 2 ≤ y) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by have h₅₁: k < y^(k-2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₇: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith exfalso linarith lemma imo_1997_p5_11_14 (x y k : ℕ) (h₀ : 0 < x ∧ 0 < y) (h₁ : x ^ y ^ 2 = y ^ x) (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) (hxy : y < x) (h₃ : x = y ^ k) (hk_def : k = x / y ^ 2) -- (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) (hk5 : 5 ≤ k) (hy : y < 2) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by interval_cases y . linarith . simp at h₅ simp at h₃ linarith lemma imo_1997_p5_11_15 (x y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) (hk5 : 5 ≤ k) (hy : 2 ≤ y) : (x, y) = (16, 2) ∨ (x, y) = (27, 3) := by have h₅₁: k < y^(k-2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₈: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith exfalso linarith lemma imo_1997_p5_11_16 (y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) (hk5 : 5 ≤ k) (hy : 2 ≤ y) : False := by have h₅₁: k < y^(k-2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₈: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith nth_rw 1 [← h₅] at h₅₁ apply Nat.ne_of_lt at h₅₁ refine false_of_ne h₅₁ lemma imo_1997_p5_11_17 (y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) (hk5 : 5 ≤ k) (hy : 2 ≤ y) : k < y ^ (k - 2) := by have h₆: 2^(k-2) ≤ y^(k-2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy have h₇: 4*k < 2^k := by exact imo_1997_p5_2 k hk5 have h₈: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith lemma imo_1997_p5_11_18 (y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) -- (hk : 2 ≤ k) -- (h₅ : k = y ^ (k - 2)) (hk5 : 5 ≤ k) (hy : 2 ≤ y) : 2 ^ (k - 2) ≤ y ^ (k - 2) := by have hk1: 3 ≤ k - 2 := by exact Nat.sub_le_sub_right hk5 2 exact (Nat.pow_le_pow_iff_left (by linarith)).mpr hy lemma imo_1997_p5_11_19 (y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) (h₇ : 4 * k < 2 ^ k) : k < y ^ (k - 2) := by have h₈: k < 2^(k-2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith linarith lemma imo_1997_p5_11_20 (y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) (h₇ : 4 * k < 2 ^ k) : k < 2 ^ (k - 2) := by have h₈ : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith lemma imo_1997_p5_11_21 (k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) -- (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) -- (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) (h₇ : 4 * k < 2 ^ k) : k < 2 ^ k / 4 := by have h81: 4 ∣ 2^k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) exact (Nat.lt_div_iff_mul_lt' h81 k).mpr h₇ lemma imo_1997_p5_11_22 -- (x y : ℕ) (k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) : -- (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) -- (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) -- (h₇ : 4 * k < 2 ^ k) : 4 ∣ 2 ^ k := by have h82: 2^k = 4*2^(k-2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) lemma imo_1997_p5_11_23 -- (x y : ℕ) (k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) : -- (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) -- (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) -- (h₇ : 4 * k < 2 ^ k) : 2 ^ k = 4 * 2 ^ (k - 2) := by have h83: k = 2 + (k -2) := by ring_nf exact (add_sub_of_le hk).symm nth_rewrite 1 [h83] rw [pow_add] norm_num lemma imo_1997_p5_11_24 -- (x y : ℕ) (k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) -- (hk : 2 ≤ k) -- (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) -- (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) -- (h₇ : 4 * k < 2 ^ k) (h₈₃ : k = 2 + (k - 2)) : 2 ^ k = 4 * 2 ^ (k - 2) := by nth_rewrite 1 [h₈₃] rw [pow_add] norm_num lemma imo_1997_p5_11_25 -- (x y : ℕ) (k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) -- (hk : 2 ≤ k) -- (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) -- (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) -- (h₇ : 4 * k < 2 ^ k) (h82 : 2 ^ k = 4 * 2 ^ (k - 2)) : 4 ∣ 2 ^ k := by rw [h82] exact Nat.dvd_mul_right 4 (2^(k-2)) lemma imo_1997_p5_11_26 -- (x : ℕ) (y k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) -- (h₇ : 4 * k < 2 ^ k) (h₈ : k < 2 ^ k / 4) : k < 2 ^ (k - 2) := by have h₉: 2 ^ k / 4 = 2 ^ (k-2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp linarith lemma imo_1997_p5_11_27 -- (x y : ℕ) (k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) (hk : 2 ≤ k) : -- (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) -- (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) -- (h₇ : 4 * k < 2 ^ k) -- (h₈ : k < 2 ^ k / 4) : 2 ^ k / 4 = 2 ^ (k - 2) := by have g2: k = k - 2 + 2 := by exact (Nat.sub_eq_iff_eq_add hk).mp rfl have h1: 2^k = 2^(k - 2 + 2) := by exact congrArg (HPow.hPow 2) g2 have h2: 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2 := by rw [pow_add] rw [h1, h2] ring_nf simp lemma imo_1997_p5_11_28 -- (x y : ℕ) (k : ℕ) -- (h₀ : 0 < x ∧ 0 < y) -- (h₁ : x ^ y ^ 2 = y ^ x) -- (g₁ : x ^ y ^ 2 = (x ^ y) ^ y) -- (hxy : y < x) -- (h₃ : x = y ^ k) -- (hk_def : k = x / y ^ 2) -- (hk : 2 ≤ k) -- (h₅ : k = y ^ (k - 2)) -- (hk5 : 5 ≤ k) -- (hy : 2 ≤ y) -- (h₆ : 2 ^ (k - 2) ≤ y ^ (k - 2)) -- (h₇ : 4 * k < 2 ^ k) -- (h₈ : k < 2 ^ k / 4) -- (g2 : k = k - 2 + 2) (h1 : 2 ^ k = 2 ^ (k - 2 + 2)) (h2 : 2 ^ (k - 2 + 2) = 2 ^ (k - 2) * 2 ^ 2) : 2 ^ k / 4 = 2 ^ (k - 2) := by rw [h1, h2] ring_nf simp