import Mathlib set_option linter.unusedVariables.analyzeTactics true open Int Rat lemma imo_1992_p1_1 (p q r: ℤ) (hpl: 4 ≤ p) (hql: 5 ≤ q) (hrl: 6 ≤ r) : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2 := by have h₁: (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) = (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) := by norm_cast simp have hp: (↑p/↑(p-1):ℚ) ≤ ((4/3):ℚ) := by have g₁: 0 < (↑(p - 1):ℚ) := by norm_cast linarith [hpl] have g₂: ↑p * ↑(3:ℚ) ≤ ↑(4:ℚ) * (↑(p - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num have hq: (↑q/↑(q-1)) ≤ ((5/4):ℚ) := by have g₁: 0 < (↑(q - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑q * ↑(4:ℚ) ≤ ↑(5:ℚ) * (↑(q - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num have hr: (↑r/↑(r-1)) ≤ ((6/5):ℚ) := by have g₁: 0 < (↑(r - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑r * ↑(5:ℚ) ≤ ↑(6:ℚ) * (↑(r - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num have hub: (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (4/3:ℚ) * ((5/4):ℚ) * ((6/5):ℚ) := by have hq_nonneg: 0 ≤ (↑q:ℚ) := by norm_cast linarith have hq_1_nonneg: 0 ≤ (↑(q - 1):ℚ) := by norm_cast linarith have h₂: 0 ≤ (((q:ℚ) / ↑(q - 1)):ℚ) := by exact div_nonneg hq_nonneg hq_1_nonneg have hub1: (↑p/↑(p-1)) * (↑q/↑(q-1)) ≤ ((4/3):ℚ) * ((5/4):ℚ) := by exact mul_le_mul hp hq h₂ (by norm_num) have hr_nonneg: 0 ≤ (↑r:ℚ) := by norm_cast linarith have hr_1_nonneg: 0 ≤ (↑(r - 1):ℚ) := by norm_cast linarith have h₃: 0 ≤ (((r:ℚ) / ↑(r - 1)):ℚ) := by exact div_nonneg hr_nonneg hr_1_nonneg exact mul_le_mul hub1 hr h₃ (by norm_num) norm_num at hub rw [h₁] norm_num exact hub lemma imo_1992_p1_1_1 (p : ℤ) (hpl : 4 ≤ p) : ↑p / ↑(p - 1) ≤ ((4/3):ℚ) := by have g₁: 0 < (↑(p - 1):ℚ) := by norm_cast linarith [hpl] have g₂: ↑p * ↑(3:ℚ) ≤ ↑(4:ℚ) * (↑(p - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_1_2 (p : ℤ) -- (q r : ℤ) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) (g₁ : 0 < (↑(p - 1):ℚ)) (g₂ : ↑p * ↑(3:ℚ) ≤ ↑(4:ℚ) * (↑(p - 1):ℚ)) : ↑p / ↑(p - 1) ≤ ((4/3):ℚ) := by refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_1_3 -- (p r : ℤ) (q: ℤ) -- (hpl : 4 ≤ p) (hql : 5 ≤ q) : -- (hrl : 6 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 4 / 3) : ↑q / ↑(q - 1) ≤ ((5 / 4):ℚ) := by have g₁: 0 < (↑(q - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑q * ↑(4:ℚ) ≤ ↑(5:ℚ) * (↑(q - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_1_4 -- (p r : ℤ) (q: ℤ) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 4 / 3) (g₁ : 0 < (↑(q - 1):ℚ)) (g₂ : ↑q * ↑(4:ℚ) ≤ ↑(5:ℚ) * (↑(q - 1):ℚ)) : ↑q / ↑(q - 1) ≤ ((5 / 4):ℚ) := by refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_1_5 (p q r : ℤ) -- (hpl : 4 ≤ p) (hql : 5 ≤ q) (hrl : 6 ≤ r) (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) = (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1))) (hp : ↑p / ↑(p - 1) ≤ ((4 / 3):ℚ)) (hq : ↑q / ↑(q - 1) ≤ ((5 / 4):ℚ)) : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2 := by have hr: (↑r/↑(r-1)) ≤ ((6/5):ℚ) := by have g₁: 0 < (↑(r - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑r * ↑(5:ℚ) ≤ ↑(6:ℚ) * (↑(r - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num have hub: (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (4/3:ℚ) * ((5/4):ℚ) * ((6/5):ℚ) := by have hq_nonneg: 0 ≤ (↑q:ℚ) := by norm_cast linarith have hq_1_nonneg: 0 ≤ (↑(q - 1):ℚ) := by norm_cast linarith have h₂: 0 ≤ (((q:ℚ) / ↑(q - 1)):ℚ) := by exact div_nonneg hq_nonneg hq_1_nonneg have hub1: (↑p/↑(p-1)) * (↑q/↑(q-1)) ≤ ((4/3):ℚ) * ((5/4):ℚ) := by exact mul_le_mul hp hq h₂ (by norm_num) have hr_nonneg: 0 ≤ (↑r:ℚ) := by norm_cast linarith have hr_1_nonneg: 0 ≤ (↑(r - 1):ℚ) := by norm_cast linarith have h₃: 0 ≤ (((r:ℚ) / ↑(r - 1)):ℚ) := by exact div_nonneg hr_nonneg hr_1_nonneg exact mul_le_mul hub1 hr h₃ (by norm_num) norm_num at hub rw [h₁] norm_num exact hub lemma imo_1992_p1_1_6 -- (p : ℤ) (q r : ℤ) -- (hpl : 4 ≤ p) (hql : 5 ≤ q) (hrl : 6 ≤ r) : -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 4 / 3) -- (hq : ↑q / ↑(q - 1) ≤ 5 / 4) : ↑r / ↑(r - 1) ≤ ((6/5):ℚ) := by have g₁: 0 < (↑(r - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑r * ↑(5:ℚ) ≤ ↑(6:ℚ) * (↑(r - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_1_7 -- (p q : ℤ) (r : ℤ) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 4 / 3) -- (hq : ↑q / ↑(q - 1) ≤ 5 / 4) (g₁ : 0 < (↑(r - 1):ℚ)) (g₂ : ↑r * ↑(5:ℚ) ≤ ↑(6:ℚ) * (↑(r - 1):ℚ)) : ↑r / ↑(r - 1) ≤ ((6/5):ℚ) := by refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_1_8 (p q r : ℤ) -- (hpl : 4 ≤ p) (hql : 5 ≤ q) (hrl : 6 ≤ r) (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) = (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1))) (hp : ↑p / ↑(p - 1) ≤ ((4/3):ℚ)) (hq : ↑q / ↑(q - 1) ≤ ((5/4):ℚ)) (hr : ↑r / ↑(r - 1) ≤ ((6/5):ℚ)) : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2 := by have hub: (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (4/3:ℚ) * ((5/4):ℚ) * ((6/5):ℚ) := by have hq_nonneg: 0 ≤ (↑q:ℚ) := by norm_cast linarith have hq_1_nonneg: 0 ≤ (↑(q - 1):ℚ) := by norm_cast linarith have h₂: 0 ≤ (((q:ℚ) / ↑(q - 1)):ℚ) := by exact div_nonneg hq_nonneg hq_1_nonneg have hub1: (↑p/↑(p-1)) * (↑q/↑(q-1)) ≤ ((4/3):ℚ) * ((5/4):ℚ) := by exact mul_le_mul hp hq h₂ (by norm_num) have hr_nonneg: 0 ≤ (↑r:ℚ) := by norm_cast linarith have hr_1_nonneg: 0 ≤ (↑(r - 1):ℚ) := by norm_cast linarith have h₃: 0 ≤ (((r:ℚ) / ↑(r - 1)):ℚ) := by exact div_nonneg hr_nonneg hr_1_nonneg exact mul_le_mul hub1 hr h₃ (by norm_num) norm_num at hub rw [h₁] norm_num exact hub lemma imo_1992_p1_1_9 (p q r : ℤ) -- (hpl : 4 ≤ p) (hql : 5 ≤ q) (hrl : 6 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) (hp : ↑p / ↑(p - 1) ≤ ((4 / 3):ℚ)) (hq : ↑q / ↑(q - 1) ≤ ((5 / 4):ℚ)) (hr : ↑r / ↑(r - 1) ≤ ((6 / 5):ℚ)) : (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (4/3:ℚ) * ((5/4):ℚ) * ((6/5):ℚ) := by have hq_nonneg: 0 ≤ (↑q:ℚ) := by norm_cast linarith have hq_1_nonneg: 0 ≤ (↑(q - 1):ℚ) := by norm_cast linarith have h₂: 0 ≤ (((q:ℚ) / ↑(q - 1)):ℚ) := by exact div_nonneg hq_nonneg hq_1_nonneg have hub1: (↑p/↑(p-1)) * (↑q/↑(q-1)) ≤ ((4/3):ℚ) * ((5/4):ℚ) := by exact mul_le_mul hp hq h₂ (by norm_num) have hr_nonneg: 0 ≤ (↑r:ℚ) := by norm_cast linarith have hr_1_nonneg: 0 ≤ (↑(r - 1):ℚ) := by norm_cast linarith have h₃: 0 ≤ (((r:ℚ) / ↑(r - 1)):ℚ) := by exact div_nonneg hr_nonneg hr_1_nonneg exact mul_le_mul hub1 hr h₃ (by norm_num) lemma imo_1992_p1_1_10 -- (p r : ℤ) (q : ℤ) -- (hpl : 4 ≤ p) (hql : 5 ≤ q) : -- (hrl : 6 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 4 / 3) -- (hq : ↑q / ↑(q - 1) ≤ 5 / 4) -- (hr : ↑r / ↑(r - 1) ≤ 6 / 5) : -- hq_nonneg : 0 ≤ ↑q -- hq_1_nonneg : 0 ≤ ↑(q - 1) 0 ≤ (((q:ℚ) / ↑(q - 1)):ℚ) := by have hq_nonneg: 0 ≤ (↑q:ℚ) := by norm_cast linarith have hq_1_nonneg: 0 ≤ (↑(q - 1):ℚ) := by norm_cast linarith exact div_nonneg hq_nonneg hq_1_nonneg lemma imo_1992_p1_1_11 (p q r : ℤ) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) = (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1))) -- (hp : ↑p / ↑(p - 1) ≤ 4 / 3) -- (hq : ↑q / ↑(q - 1) ≤ 5 / 4) -- (hr : ↑r / ↑(r - 1) ≤ 6 / 5) (hub : (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (4/3:ℚ) * ((5/4):ℚ) * ((6/5):ℚ)) : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2 := by rw [h₁] norm_num norm_num at hub exact hub lemma imo_1992_p1_1_12 (p q r : ℤ) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) -- -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 4 / 3) -- (hq : ↑q / ↑(q - 1) ≤ 5 / 4) -- (hr : ↑r / ↑(r - 1) ≤ 6 / 5) (hub : (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (4/3:ℚ) * ((5/4):ℚ) * ((6/5):ℚ)) : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2 := by have h₁: (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) = (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) := by norm_cast simp rw [h₁] norm_num norm_num at hub exact hub lemma imo_1992_p1_2 (p q r k: ℤ) (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (hpl: 4 ≤ p) (hql: 5 ≤ q) (hrl: 6 ≤ r) (hden: 0 < (p - 1) * (q - 1) * (r - 1) ) : (k < 2) := by have h₁: (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2 := by exact imo_1992_p1_1 p q r hpl hql hrl have h₂: ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by have g₁: ↑(p * q * r - 1) = ↑k * (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast linarith symm have g₂: (↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≠ 0 := by norm_cast linarith[hden] exact (div_eq_iff g₂).mpr g₁ have h₃: ↑k < (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by rw [h₂] have g₁: (↑(p * q * r - 1):ℚ) < (↑(p * q * r):ℚ) := by norm_cast exact sub_one_lt (p * q * r) have g₂: 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast exact div_lt_div_of_pos_right g₁ g₂ have h₄: (↑k:ℚ) < ↑2 := by exact lt_of_lt_of_le h₃ h₁ norm_cast at h₄ lemma imo_1992_p1_2_1 (p q r k : ℤ) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ 2) : k < 2 := by have h₂: ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by have g₁: ↑(p * q * r - 1) = ↑k * (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast linarith symm have g₂: (↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≠ 0 := by norm_cast linarith[hden] exact (div_eq_iff g₂).mpr g₁ have h₃: ↑k < (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by rw [h₂] have g₁: (↑(p * q * r - 1):ℚ) < (↑(p * q * r):ℚ) := by norm_cast exact sub_one_lt (p * q * r) have g₂: 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast exact div_lt_div_of_pos_right g₁ g₂ have h₄: (↑k:ℚ) < ↑2 := by exact lt_of_lt_of_le h₃ h₁ norm_cast at h₄ lemma imo_1992_p1_2_2 (p q r k : ℤ) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) (hden : 0 < (p - 1) * (q - 1) * (r - 1)) : -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) ≤ 2) : ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by have g₁: ↑(p * q * r - 1) = ↑k * (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast linarith symm have g₂: (↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≠ 0 := by norm_cast linarith[hden] exact (div_eq_iff g₂).mpr g₁ lemma imo_1992_p1_2_3 (p q r k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2) (h₂ : ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ)) : k < 2 := by have h₃: ↑k < (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by rw [h₂] have g₁: (↑(p * q * r - 1):ℚ) < (↑(p * q * r):ℚ) := by norm_cast exact sub_one_lt (p * q * r) have g₂: 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast exact div_lt_div_of_pos_right g₁ g₂ have h₄: (↑k:ℚ) < ↑2 := by exact lt_of_lt_of_le h₃ h₁ norm_cast at h₄ lemma imo_1992_p1_2_4 (p q r k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) (hden : 0 < (p - 1) * (q - 1) * (r - 1)) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) ≤ 2) (h₂ : ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ)) : ↑k < (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by rw [h₂] have g₁: (↑(p * q * r - 1):ℚ) < (↑(p * q * r):ℚ) := by norm_cast exact sub_one_lt (p * q * r) have g₂: 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast exact div_lt_div_of_pos_right g₁ g₂ lemma imo_1992_p1_2_5 (p q r k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 4 ≤ p) -- (hql : 5 ≤ q) -- (hrl : 6 ≤ r) -- (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑2) -- (h₂ : ↑k = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) (h₃ : ↑k < (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ)) : k < 2 := by have h₄: (↑k:ℚ) < ↑2 := by exact lt_of_lt_of_le h₃ h₁ norm_cast at h₄ lemma imo_1992_p1_3 (p q r: ℤ) (hpl: 2 ≤ p) (hql: 3 ≤ q) (hrl: 4 ≤ r) : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑4 := by have h₁: (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) = (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) := by norm_cast simp have hp: (↑p/↑(p-1):ℚ) ≤ ↑(2:ℚ) := by have g₁: 0 < (↑(p - 1):ℚ) := by norm_cast linarith[hpl] have g₂: ↑p ≤ ↑(2:ℚ) * (↑(p - 1):ℚ) := by norm_cast linarith exact (div_le_iff₀ g₁).mpr g₂ have hq: (↑q/↑(q-1)) ≤ ((3/2):ℚ) := by have g₁: 0 < (↑(q - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑q * ↑(2:ℚ) ≤ ↑(3:ℚ) * (↑(q - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num have hr: (↑r/↑(r-1)) ≤ ((4/3):ℚ) := by have g₁: 0 < (↑(r - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑r * ↑(3:ℚ) ≤ ↑(4:ℚ) * (↑(r - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num have hub: (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (2:ℚ) * ((3/2):ℚ) * ((4/3):ℚ) := by have hq_nonneg: 0 ≤ (↑q:ℚ) := by norm_cast linarith have hq_1_nonneg: 0 ≤ (↑(q - 1):ℚ) := by norm_cast linarith have h₂: 0 ≤ (((q:ℚ) / ↑(q - 1)):ℚ) := by exact div_nonneg hq_nonneg hq_1_nonneg have hub1: (↑p/↑(p-1)) * (↑q/↑(q-1)) ≤ (2:ℚ) * ((3/2):ℚ) := by exact mul_le_mul hp hq h₂ (by norm_num) have hr_nonneg: 0 ≤ (↑r:ℚ) := by norm_cast linarith have hr_1_nonneg: 0 ≤ (↑(r - 1):ℚ) := by norm_cast linarith have h₃: 0 ≤ (((r:ℚ) / ↑(r - 1)):ℚ) := by exact div_nonneg hr_nonneg hr_1_nonneg exact mul_le_mul hub1 hr h₃ (by norm_num) norm_num at hub rw [h₁] norm_num exact hub lemma imo_1992_p1_3_1 (p : ℤ) -- (q r : ℤ) (hpl : 2 ≤ p) : -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) -- = (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1))) : (↑p/↑(p-1):ℚ) ≤ ↑(2:ℚ) := by have g₁: 0 < (↑(p - 1):ℚ) := by norm_cast linarith[hpl] have g₂: ↑p ≤ ↑(2:ℚ) * (↑(p - 1):ℚ) := by norm_cast linarith exact (div_le_iff₀ g₁).mpr g₂ lemma imo_1992_p1_3_2 (p : ℤ) -- (q r : ℤ) (hpl : 2 ≤ p) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) (g₁ : 0 < (↑(p - 1):ℚ)) : (↑p/↑(p-1):ℚ) ≤ ↑(2:ℚ) := by have g₂: ↑p ≤ ↑(2:ℚ) * (↑(p - 1):ℚ) := by norm_cast linarith exact (div_le_iff₀ g₁).mpr g₂ lemma imo_1992_p1_3_3 -- (p r : ℤ) (q : ℤ) -- (hpl : 2 ≤ p) (hql : 3 ≤ q) : -- (hrl : 4 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 2) : (↑q/↑(q-1)) ≤ ((3/2):ℚ) := by have g₁: 0 < (↑(q - 1):ℚ) := by norm_cast linarith[hql] have g₂: ↑q * ↑(2:ℚ) ≤ ↑(3:ℚ) * (↑(q - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_3_4 -- (p r : ℤ) (q : ℤ) -- (hpl : 2 ≤ p) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 2) (g₁ : 0 < (↑(q - 1):ℚ)) (g₂ : ↑q * ↑(2:ℚ) ≤ ↑(3:ℚ) * (↑(q - 1):ℚ)) : (↑q/↑(q-1)) ≤ ((3/2):ℚ) := by refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_3_5 -- (p q : ℤ) (r : ℤ) -- (hpl : 2 ≤ p) -- (hql : 3 ≤ q) (hrl : 4 ≤ r) : -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 2) -- (hq : ↑q / ↑(q - 1) ≤ 3 / 2) : ↑r / ↑(r - 1) ≤ ((4 / 3):ℚ) := by have g₁: 0 < (↑(r - 1):ℚ) := by norm_cast linarith have g₂: ↑r * ↑(3:ℚ) ≤ ↑(4:ℚ) * (↑(r - 1):ℚ) := by norm_cast linarith refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_3_6 -- (p q : ℤ) (r : ℤ) -- (hpl : 2 ≤ p) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 2) -- (hq : ↑q / ↑(q - 1) ≤ 3 / 2) (g₁ : 0 < (↑(r - 1):ℚ)) (g₂ : ↑r * ↑(3:ℚ) ≤ ↑(4:ℚ) * (↑(r - 1):ℚ)) : ↑r / ↑(r - 1) ≤ ((4 / 3):ℚ) := by refine (div_le_iff₀ g₁).mpr ?_ rw [div_mul_eq_mul_div] refine (le_div_iff₀ ?_).mpr g₂ norm_num lemma imo_1992_p1_3_7 (p q r : ℤ) -- (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) -- (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) (hp : (↑p/↑(p-1):ℚ) ≤ ↑(2:ℚ)) (hq : ↑q / ↑(q - 1) ≤ ((3 / 2):ℚ)) (hr : ↑r / ↑(r - 1) ≤ ((4 / 3):ℚ)) : (↑p/↑(p-1)) * (↑q/↑(q-1)) * (↑r/↑(r-1)) ≤ (2:ℚ) * ((3/2):ℚ) * ((4/3):ℚ) := by have hq_nonneg: 0 ≤ (↑q:ℚ) := by norm_cast linarith have hq_1_nonneg: 0 ≤ (↑(q - 1):ℚ) := by norm_cast linarith have h₂: 0 ≤ (((q:ℚ) / ↑(q - 1)):ℚ) := by exact div_nonneg hq_nonneg hq_1_nonneg have hub1: (↑p/↑(p-1)) * (↑q/↑(q-1)) ≤ (2:ℚ) * ((3/2):ℚ) := by exact mul_le_mul hp hq h₂ (by norm_num) have hr_nonneg: 0 ≤ (↑r:ℚ) := by norm_cast linarith have hr_1_nonneg: 0 ≤ (↑(r - 1):ℚ) := by norm_cast linarith have h₃: 0 ≤ (((r:ℚ) / ↑(r - 1)):ℚ) := by exact div_nonneg hr_nonneg hr_1_nonneg exact mul_le_mul hub1 hr h₃ (by norm_num) lemma imo_1992_p1_3_8 (p q r : ℤ) -- (hpl : 2 ≤ p) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (h₁ : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) = ↑p / ↑(p - 1) * (↑q / ↑(q - 1)) * (↑r / ↑(r - 1))) -- (hp : ↑p / ↑(p - 1) ≤ 2) -- (hq : ↑q / ↑(q - 1) ≤ 3 / 2) -- (hr : ↑r / ↑(r - 1) ≤ 4 / 3) (hub : ↑p / (↑p - 1) * (↑q / (↑q - 1)) * (↑r / (↑r - 1)) ≤ 4) : ↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)) ≤ 4 := by rw [h₁] exact hub lemma imo_1992_p1_4 (p q r k: ℤ) (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (hpl: 2 ≤ p) (hql: 3 ≤ q) (hrl: 4 ≤ r) (hden: 0 < (p - 1) * (q - 1) * (r - 1) ) : (k < 4) := by have h₁: (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑4 := by exact imo_1992_p1_3 p q r hpl hql hrl have h₂: ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by have g₁: ↑(p * q * r - 1) = ↑k * (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast linarith symm have g₂: (↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≠ 0 := by norm_cast linarith [hden] exact (div_eq_iff g₂).mpr g₁ have h₃: ↑k < (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by rw [h₂] have g₁: (↑(p * q * r - 1):ℚ) < (↑(p * q * r):ℚ) := by norm_cast exact sub_one_lt (p * q * r) have g₂: 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast exact div_lt_div_of_pos_right g₁ g₂ have h₄: (↑k:ℚ) < ↑4 := by exact lt_of_lt_of_le h₃ h₁ norm_cast at h₄ lemma imo_1992_p1_4_1 (p q r k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 2 ≤ p) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (h₁ : (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≤ ↑4) -- (h₂ : ↑k = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) (h₃ : ↑k < (↑(p * q * r) / ↑((p - 1) * (q - 1) * (r - 1)):ℚ)) : k < 4 := by have h₄: (↑k:ℚ) < ↑4 := by exact lt_of_lt_of_le h₃ h₁ norm_cast at h₄ lemma imo_1992_p1_5 (p q r k: ℤ) (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (h₁: ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ)) (hpl: 2 ≤ p) (hql: 3 ≤ q) (hrl: 4 ≤ r) (hden: 0 < (p - 1) * (q - 1) * (r - 1)) : (1 < k) := by have hk0: 0 < (↑k:ℚ) := by have g₁: 2 * 3 * 4 ≤ p * q * r := by have g₂: 2 * 3 ≤ p * q := by exact mul_le_mul hpl hql (by norm_num) (by linarith[hpl]) exact mul_le_mul g₂ hrl (by norm_num) (by linarith[g₂]) have g₂: 0 < (↑(p * q * r - 1):ℚ) := by norm_cast linarith[g₁] have g₃: 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast rw [h₁] exact div_pos g₂ g₃ norm_cast at hk0 by_contra! hc interval_cases k simp at hk have g₁: p*q + q*r + r*p = p+q+r := by linarith have g₂: p < p*q := by exact lt_mul_right (by linarith) (by linarith) have g₃: q < q*r := by exact lt_mul_right (by linarith) (by linarith) have g₄: r < r*p := by exact lt_mul_right (by linarith) (by linarith) have g₅: p+q+r < p*q + q*r + r*p := by linarith[g₂,g₃,g₄] linarith [g₁,g₅] lemma imo_1992_p1_5_1 (p q r k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (h₁ : ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ)) (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) (hden: 0 < (p - 1) * (q - 1) * (r - 1)) : 0 < (↑k:ℚ) := by have g₁: 2 * 3 * 4 ≤ p * q * r := by have g₂: 2 * 3 ≤ p * q := by exact mul_le_mul hpl hql (by norm_num) (by linarith[hpl]) exact mul_le_mul g₂ hrl (by norm_num) (by linarith[g₂]) have g₂: 0 < (↑(p * q * r - 1):ℚ) := by norm_cast linarith[g₁] have g₃: 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast rw [h₁] exact div_pos g₂ g₃ lemma imo_1992_p1_5_2 (p q r : ℤ) -- (k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (h₁ : ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ)) (hpl : 0 < (p - 1)) (hql : 0 < (q - 1)) (hrl : 0 < (r - 1)) : -- (hden: 0 < (p - 1) * (q - 1) * (r - 1)) : -- (g₁ : 2 * 3 * 4 ≤ p * q * r) -- (g₂ : 0 < (↑(p * q * r - 1):ℚ)) : 0 < (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast refine mul_pos ?_ hrl exact mul_pos hpl hql lemma imo_1992_p1_5_3 (p q r : ℤ) -- (k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (h₁ : ↑k = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) : 0 < ↑(p * q * r - 1) := by have g₁: 2 * 3 * 4 ≤ p * q * r := by have g₂: 2 * 3 ≤ p * q := by exact mul_le_mul hpl hql (by norm_num) (by linarith[hpl]) exact mul_le_mul g₂ hrl (by norm_num) (by linarith[g₂]) norm_cast linarith[g₁] lemma imo_1992_p1_5_4 (p q r k : ℤ) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (h₁ : ↑k = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) -- (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (hk0 : 0 < k) : 1 < k := by by_contra! hc interval_cases k simp at hk have g₁: p*q + q*r + r*p = p+q+r := by linarith have g₂: p < p*q := by exact lt_mul_right (by linarith) (by linarith) have g₃: q < q*r := by exact lt_mul_right (by linarith) (by linarith) have g₄: r < r*p := by exact lt_mul_right (by linarith) (by linarith) have g₅: p+q+r < p*q + q*r + r*p := by linarith[g₂,g₃,g₄] linarith [g₁,g₅] lemma imo_1992_p1_5_5 (p q r : ℤ) -- (k : ℤ) (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) -- (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * 1) : -- (h₁ : ↑1 = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) -- (hk0 : 0 < 1) -- (hc : 1 ≤ 1) : False := by simp at hk have g₁: p * q + q * r + r * p = p + q + r := by linarith have g₂: p < p * q := by exact lt_mul_right (by linarith) (by linarith) have g₃: q < q * r := by exact lt_mul_right (by linarith) (by linarith) have g₄: r < r * p := by exact lt_mul_right (by linarith) (by linarith) have g₅: p + q + r < p * q + q * r + r * p := by linarith[g₂,g₃,g₄] linarith [g₁,g₅] lemma imo_1992_p1_5_6 (p q r : ℤ) -- (k : ℤ) (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) -- (hden : 0 < (p - 1) * (q - 1) * (r - 1)) -- (h₁ : ↑1 = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) -- (hk0 : 0 < 1) -- (hc : 1 ≤ 1) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1)) (g₁ : p * q + q * r + r * p = p + q + r) : False := by have g₂: p < p * q := by exact lt_mul_right (by linarith) (by linarith) have g₃: q < q * r := by exact lt_mul_right (by linarith) (by linarith) have g₄: r < r * p := by exact lt_mul_right (by linarith) (by linarith) have g₅: p + q + r < p * q + q * r + r * p := by linarith[g₂,g₃,g₄] linarith [g₁,g₅] lemma imo_1992_p1_5_7 (p q r : ℤ) -- (k : ℤ) (hpl : 2 ≤ p) -- (hql : 3 ≤ q) (hrl : 4 ≤ r) -- (hden : 0 < (p - 1) * (q - 1) * (r - 1)) -- (h₁ : ↑1 = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) -- (hk0 : 0 < 1) -- (hc : 1 ≤ 1) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1)) (g₁ : p * q + q * r + r * p = p + q + r) (g₂: p < p * q) (g₃: q < q * r) : False := by have g₄: r < r * p := by exact lt_mul_right (by linarith) (by linarith) have g₅: p + q + r < p * q + q * r + r * p := by linarith[g₂,g₃,g₄] linarith [g₁,g₅] lemma imo_1992_p1_6 (p q r k: ℤ) (h₀ : 1 < p ∧ p < q ∧ q < r) (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (h₁: ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ)) (hpl: 2 ≤ p) (hql: 3 ≤ q) (hrl: 4 ≤ r) (hden: 0 < (p - 1) * (q - 1) * (r - 1) ) : (p < 4) := by by_contra! hcp have hcq: 5 ≤ q := by linarith have hcr: 6 ≤ r := by linarith have h₃: k < 2 := by exact imo_1992_p1_2 p q r k hk hcp hcq hcr hden have h₄: 1 < k := by exact imo_1992_p1_5 p q r k hk h₁ hpl hql hrl hden linarith lemma imo_1992_p1_6_1 (p q r k : ℤ) (h₀ : 1 < p ∧ p < q ∧ q < r) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (h₁ : ↑k = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (hcp : 4 ≤ p) (hcq : 5 ≤ q) (hcr : 6 ≤ r) (h₃ : k < 2) (h₄ : 1 < k) : p < 4 := by linarith lemma imo_1992_p1_7 (q r : ℤ) (p: ℕ) (h₀ : q * r = ↑p) (h₁: Nat.Prime p) : q = -1 ∨ q = 1 ∨ q = -p ∨ q = p := by have hq : q ≠ 0 := by intro h rw [h] at h₀ simp at h₀ symm at h₀ norm_cast at h₀ rw [h₀] at h₁ exact Nat.not_prime_zero h₁ have hr : r ≠ 0 := by intro h rw [h] at h₀ simp at h₀ norm_cast at h₀ rw [← h₀] at h₁ exact Nat.not_prime_zero h₁ have hqr : abs q * abs r = p := by have h₃: abs q = q.natAbs := by exact abs_eq_natAbs q have h₄: abs r = r.natAbs := by exact abs_eq_natAbs r rw [h₃,h₄] norm_cast exact Int.natAbs_mul_natAbs_eq h₀ have h_abs: abs (↑(q.natAbs):ℤ) = 1 ∨ abs q = p := by cases' Int.natAbs_eq q with h_1 h_2 . rw [h_1] at hqr have h₂: abs (↑(q.natAbs):ℤ) ∣ p := by exact Dvd.intro (abs r) hqr have h₃: (↑(q.natAbs):ℕ) ∣ p := by norm_cast at * have h₄: (↑(q.natAbs):ℕ) = 1 ∨ (↑(q.natAbs):ℕ) = p := by exact Nat.Prime.eq_one_or_self_of_dvd h₁ (↑(q.natAbs):ℕ) h₃ cases' h₄ with h₄₀ h₄₁ . left norm_cast at * . have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast at * . rw [h_2] at hqr rw [abs_neg _] at hqr have h₂: abs (↑(q.natAbs):ℤ) ∣ p := by exact Dvd.intro (abs r) hqr have h₃: (↑(q.natAbs):ℕ) ∣ p := by norm_cast at * have h₄: (↑(q.natAbs):ℕ) = 1 ∨ (↑(q.natAbs):ℕ) = p := by exact Nat.Prime.eq_one_or_self_of_dvd h₁ (↑(q.natAbs):ℕ) h₃ cases' h₄ with h₄₀ h₄₁ . left norm_cast at * . have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast cases' h_abs with hq_abs hq_abs . norm_cast at * have h₄: q = ↑(q.natAbs) ∨ q = -↑(q.natAbs) := by exact Int.natAbs_eq q rw [hq_abs] at h₄ norm_cast at h₄ cases' h₄ with h₄₀ h₄₁ . right left exact h₄₀ . left exact h₄₁ . right right have h₂: abs q = q.natAbs := by exact abs_eq_natAbs q rw [h₂] at hq_abs norm_cast at hq_abs refine or_comm.mp ?_ refine (Int.natAbs_eq_natAbs_iff).mp ?_ norm_cast lemma imo_1992_p1_7_1 (q r : ℤ) (p : ℕ) (h₀ : q * r = ↑p) (h₁ : Nat.Prime p) : q ≠ 0 := by intro h rw [h] at h₀ simp at h₀ symm at h₀ norm_cast at h₀ rw [h₀] at h₁ exact Nat.not_prime_zero h₁ lemma imo_1992_p1_7_2 (q r : ℤ) (p : ℕ) (h₀ : q * r = ↑p) (h₁ : Nat.Prime p) (hq : q ≠ 0) : r ≠ 0 := by intro h rw [h] at h₀ simp at h₀ norm_cast at h₀ rw [← h₀] at h₁ exact Nat.not_prime_zero h₁ lemma imo_1992_p1_7_3 (q r : ℤ) (p : ℕ) (h₀ : q * r = ↑p) : -- (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) : |q| * |r| = ↑p := by have h₃: abs q = q.natAbs := by exact abs_eq_natAbs q have h₄: abs r = r.natAbs := by exact abs_eq_natAbs r rw [h₃,h₄] norm_cast exact Int.natAbs_mul_natAbs_eq h₀ lemma imo_1992_p1_7_4 (q r : ℤ) (p : ℕ) (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) (h₃ : |q| = ↑(natAbs q)) (h₄ : |r| = ↑(natAbs r)) : |q| * |r| = ↑p := by rw [h₃,h₄] norm_cast exact Int.natAbs_mul_natAbs_eq h₀ lemma imo_1992_p1_7_5 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) (h₁ : Nat.Prime p) (hq : q ≠ 0) (hr : r ≠ 0) (hqr : |q| * |r| = ↑p) : |(↑(natAbs q):ℤ)| = 1 ∨ |q| = ↑p := by cases' Int.natAbs_eq q with h_1 h_2 . rw [h_1] at hqr have h₂: abs (↑(q.natAbs):ℤ) ∣ p := by exact Dvd.intro (abs r) hqr have h₃: (↑(q.natAbs):ℕ) ∣ p := by norm_cast at * have h₄: (↑(q.natAbs):ℕ) = 1 ∨ (↑(q.natAbs):ℕ) = p := by exact Nat.Prime.eq_one_or_self_of_dvd h₁ (↑(q.natAbs):ℕ) h₃ cases' h₄ with h₄₀ h₄₁ . left norm_cast at * . have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast at * . rw [h_2] at hqr rw [abs_neg _] at hqr have h₂: abs (↑(q.natAbs):ℤ) ∣ p := by exact Dvd.intro (abs r) hqr have h₃: (↑(q.natAbs):ℕ) ∣ p := by norm_cast at * have h₄: (↑(q.natAbs):ℕ) = 1 ∨ (↑(q.natAbs):ℕ) = p := by exact Nat.Prime.eq_one_or_self_of_dvd h₁ (↑(q.natAbs):ℕ) h₃ cases' h₄ with h₄₀ h₄₁ . left norm_cast at * . have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast lemma imo_1992_p1_7_6 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) (h₁ : Nat.Prime p) (hq : q ≠ 0) (hr : r ≠ 0) (hqr : |q| * |r| = ↑p) (h_1 : q = ↑(natAbs q)) : |(↑(natAbs q):ℤ)| = 1 ∨ |q| = ↑p := by rw [h_1] at hqr have h₂: abs (↑(q.natAbs):ℤ) ∣ p := by exact Dvd.intro (abs r) hqr have h₃: (↑(q.natAbs):ℕ) ∣ p := by norm_cast at * have h₄: (↑(q.natAbs):ℕ) = 1 ∨ (↑(q.natAbs):ℕ) = p := by exact Nat.Prime.eq_one_or_self_of_dvd h₁ (↑(q.natAbs):ℕ) h₃ cases' h₄ with h₄₀ h₄₁ . left norm_cast at * . have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast at * lemma imo_1992_p1_7_7 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) (hq : q ≠ 0) (hr : r ≠ 0) (hqr : |↑(natAbs q)| * |r| = ↑p) (h_1 : q = ↑(natAbs q)) (h₂ : |(↑(natAbs q):ℤ)| ∣ ↑p) -- (h₃ : natAbs q ∣ p) (h₄ : natAbs q = 1 ∨ natAbs q = p) : |(↑(natAbs q):ℤ)| = 1 ∨ |q| = ↑p := by cases' h₄ with h₄₀ h₄₁ . left norm_cast at * . have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast at * lemma imo_1992_p1_7_8 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) (hq : q ≠ 0) (hr : r ≠ 0) (hqr : |↑(natAbs q)| * |r| = ↑p) (h_1 : q = ↑(natAbs q)) (h₂ : |(↑(natAbs q):ℤ)| ∣ ↑p) -- (h₃ : natAbs q ∣ p) (h₄₁ : natAbs q = p) : |(↑(natAbs q):ℤ)| = 1 ∨ |q| = ↑p := by have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast at * lemma imo_1992_p1_7_9 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) (h₁ : Nat.Prime p) (hq : q ≠ 0) (hr : r ≠ 0) (hqr : |q| * |r| = ↑p) (h_2 : q = -↑(natAbs q)) : |(↑(natAbs q):ℤ)| = 1 ∨ |q| = ↑p := by rw [h_2] at hqr rw [abs_neg _] at hqr have h₂: abs (↑(q.natAbs):ℤ) ∣ p := by exact Dvd.intro (abs r) hqr have h₃: (↑(q.natAbs):ℕ) ∣ p := by norm_cast at * have h₄: (↑(q.natAbs):ℕ) = 1 ∨ (↑(q.natAbs):ℕ) = p := by exact Nat.Prime.eq_one_or_self_of_dvd h₁ (↑(q.natAbs):ℕ) h₃ cases' h₄ with h₄₀ h₄₁ . left norm_cast at * . have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q right rw [h₅] norm_cast lemma imo_1992_p1_7_10 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) (hqr : |(↑(natAbs q):ℤ)| * |r| = ↑p) (h_2 : q = (-↑(q.natAbs):ℤ)) : |(↑(natAbs q):ℤ)| ∣ ↑p := by refine Dvd.intro (abs r) ?_ simp at * exact hqr lemma imo_1992_p1_7_11 (q : ℤ) -- (r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) -- (hqr : |↑(natAbs q)| * |r| = ↑p) -- (h_2 : q = -↑(natAbs q)) (h₂ : |(↑(natAbs q):ℤ)| ∣ ↑p) : natAbs q = 1 ∨ natAbs q = p := by have h₃: (↑(q.natAbs):ℕ) ∣ p := by norm_cast at * exact Nat.Prime.eq_one_or_self_of_dvd h₁ (↑(q.natAbs):ℕ) h₃ lemma imo_1992_p1_7_12 (q : ℤ) -- (r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) -- (hqr : |↑(natAbs q)| * |r| = ↑p) -- (h_2 : q = -↑(natAbs q)) -- (h₂ : |(↑(natAbs q):ℤ)| ∣ ↑p) -- (h₃ : natAbs q ∣ p) (h₄₁ : natAbs q = p) : |q| = ↑p := by have h₅: abs q = q.natAbs := by exact abs_eq_natAbs q rw [h₅] norm_cast lemma imo_1992_p1_7_13 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) (hq : q ≠ 0) (hr : r ≠ 0) -- (hqr : |q| * |r| = ↑p) (h_abs : |(↑(natAbs q):ℤ)| = 1 ∨ |q| = ↑p) : q = -1 ∨ q = 1 ∨ q = -↑p ∨ q = ↑p := by cases' h_abs with hq_abs hq_abs . norm_cast at * have h₄: q = ↑(q.natAbs) ∨ q = -↑(q.natAbs) := by exact Int.natAbs_eq q rw [hq_abs] at h₄ norm_cast at h₄ cases' h₄ with h₄₀ h₄₁ . right left exact h₄₀ . left exact h₄₁ . right right have h₂: abs q = q.natAbs := by exact abs_eq_natAbs q rw [h₂] at hq_abs norm_cast at hq_abs refine or_comm.mp ?_ refine (Int.natAbs_eq_natAbs_iff).mp ?_ norm_cast lemma imo_1992_p1_7_14 (q r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) (hq : q ≠ 0) (hr : r ≠ 0) -- (hqr : |q| * |r| = ↑p) (hq_abs : |(↑(natAbs q):ℤ)| = 1) : q = -1 ∨ q = 1 ∨ q = -↑p ∨ q = ↑p := by norm_cast at * have h₄: q = ↑(q.natAbs) ∨ q = -↑(q.natAbs) := by exact Int.natAbs_eq q rw [hq_abs] at h₄ norm_cast at h₄ cases' h₄ with h₄₀ h₄₁ . right left exact h₄₀ . left exact h₄₁ lemma imo_1992_p1_7_15 (q r : ℤ) -- (p : ℕ) (hrq: r = q) : -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) -- (hqr : |q| * |r| = ↑p) -- (hq : ¬q = 0) -- (hr : ¬r = 0) -- (hq_abs : natAbs q = 1) : r = ↑(natAbs q) ∨ r = -↑(natAbs q) := by rw [← hrq] exact Int.natAbs_eq r lemma imo_1992_p1_7_16 (q : ℤ) -- (r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) -- (hqr : |q| * |r| = ↑p) (hq_abs : |q| = ↑p) : q = -1 ∨ q = 1 ∨ q = -↑p ∨ q = ↑p := by right right have h₂: abs q = q.natAbs := by exact abs_eq_natAbs q rw [h₂] at hq_abs norm_cast at hq_abs refine or_comm.mp ?_ refine (Int.natAbs_eq_natAbs_iff).mp ?_ norm_cast lemma imo_1992_p1_7_17 (q : ℤ) -- (r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) -- (hqr : |q| * |r| = ↑p) (hq_abs : |q| = ↑p) : q = -↑p ∨ q = ↑p := by have h₂: abs q = q.natAbs := by exact abs_eq_natAbs q rw [h₂] at hq_abs norm_cast at hq_abs refine or_comm.mp ?_ refine (Int.natAbs_eq_natAbs_iff).mp ?_ norm_cast lemma imo_1992_p1_7_18 (q : ℤ) -- (r : ℤ) (p : ℕ) -- (h₀ : q * r = ↑p) -- (h₁ : Nat.Prime p) -- (hq : q ≠ 0) -- (hr : r ≠ 0) -- (hqr : |q| * |r| = ↑p) -- (h₂ : |q| = ↑(natAbs q)) (hq_abs : natAbs q = p) : q = -↑p ∨ q = ↑p := by refine or_comm.mp ?_ refine (Int.natAbs_eq_natAbs_iff).mp ?_ norm_cast -- my_case_k_2 lemma imo_1992_p1_8 (p q r: ℤ) (h₀: 1 < p ∧ p < q ∧ q < r) (hpl: 2 ≤ p) (hql: 3 ≤ q) (hrl: 4 ≤ r) (hpu: p < 4) (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * 2) : (p, q, r) = (2, 4, 8) ∨ (p, q, r) = (3, 5, 15) := by interval_cases p . exfalso norm_num at * have g₁: 2*q + 2*r = 3 := by linarith linarith [g₁,hql,hrl] . right norm_num at * have g₂: (4-q)*(4-r) = 11 := by linarith have g₃: (4-q) = -1 ∨ (4-q) = 1 ∨ (4-q) = -11 ∨ (4-q) = 11 := by refine imo_1992_p1_7 (4-q) (4-r) 11 g₂ ?_ decide cases' g₃ with g₃₁ g₃₂ . have hq: q = 5 := by linarith constructor . exact hq . rw [hq] at g₂ linarith[g₂] . exfalso cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 3 := by linarith[g₃₂] rw [hq] at g₂ have hr: r = -7 := by linarith[g₂] linarith[hrl,hr] . cases' g₃₃ with g₃₃ g₃₄ . have hq: q = 15 := by linarith[g₃₃] rw [hq] at g₂ have hr: r = 5 := by linarith[g₂] linarith[hq,hr,h₀.2] . have hq: q = -7 := by linarith[g₃₄] linarith[hq,hql] lemma imo_1992_p1_8_1 (p q r : ℤ) (h₀ : 1 < p ∧ p < q ∧ q < r) (hpl : p = 2) (hql : 3 ≤ q) (hrl : 4 ≤ r) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * 2) : False := by rw [hpl] at * norm_num at * have g₁: 2 * q + 2 * r = 3 := by linarith linarith [g₁,hql,hrl] lemma imo_1992_p1_8_2 -- (p : ℤ) (q r : ℤ) -- (hql : 3 s≤ q) (hrl : 4 ≤ r) (h₀ : 1 < 3 ∧ 3 < q ∧ q < r) -- (hpl : 2 ≤ 3) -- (hpu : 3 < 4) (hk : 3 * q * r - 1 = (3 - 1) * (q - 1) * (r - 1) * 2) : (3, q, r) = (3, 5, 15) := by norm_num at * have g₂: (4-q)*(4-r) = 11 := by linarith have g₃: (4-q) = -1 ∨ (4-q) = 1 ∨ (4-q) = -11 ∨ (4-q) = 11 := by refine imo_1992_p1_7 (4-q) (4-r) 11 g₂ ?_ decide cases' g₃ with g₃₁ g₃₂ . have hq: q = 5 := by linarith constructor . exact hq . rw [hq] at g₂ linarith[g₂] . exfalso cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 3 := by linarith[g₃₂] rw [hq] at g₂ have hr: r = -7 := by linarith[g₂] linarith[hrl,hr] . cases' g₃₃ with g₃₃ g₃₄ . have hq: q = 15 := by linarith[g₃₃] rw [hq] at g₂ have hr: r = 5 := by linarith[g₂] linarith[hq,hr,h₀.2] . linarith lemma imo_1992_p1_8_3 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 2) -- g₁ : q * r - 4 * q - 4 * r + 5 = 0 (g₂ : (4 - q) * (4 - r) = 11) : 4 - q = -1 ∨ 4 - q = 1 ∨ 4 - q = -11 ∨ 4 - q = 11 := by refine imo_1992_p1_7 (4-q) (4-r) 11 g₂ ?_ decide lemma imo_1992_p1_8_4 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 2) -- (g₁ : q * r - 4 * q - 4 * r + 5 = 0) (g₂ : (4 - q) * (4 - r) = 11) (g₃₁ : 4 - q = -1) : q = 5 ∧ r = 15 := by have hq: q = 5 := by linarith constructor . exact hq . rw [hq] at g₂ linarith[g₂] lemma imo_1992_p1_8_5 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 2) -- (g₁ : q * r - 4 * q - 4 * r + 5 = 0) (g₂ : (4 - q) * (4 - r) = 11) (g₃₂ : 4 - q = 1 ∨ 4 - q = -11 ∨ 4 - q = 11) : False := by cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 3 := by linarith[g₃₂] rw [hq] at g₂ have hr: r = -7 := by linarith[g₂] linarith[hrl,hr] . cases' g₃₃ with g₃₃ g₃₄ . have hq: q = 15 := by linarith[g₃₃] rw [hq] at g₂ have hr: r = 5 := by linarith[g₂] linarith[hq,hr,h₀.2] . linarith lemma imo_1992_p1_8_6 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 2) -- (g₁ : q * r - 4 * q - 4 * r + 5 = 0) (g₂ : (4 - q) * (4 - r) = 11) (g₃₂ : 4 - q = 1) : False := by have hq: q = 3 := by linarith[g₃₂] rw [hq] at g₂ have hr: r = -7 := by linarith[g₂] linarith[hrl,hr] lemma imo_1992_p1_8_7 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 2) -- (g₁ : q * r - 4 * q - 4 * r + 5 = 0) (g₂ : (4 - q) * (4 - r) = 11) (g₃₃ : 4 - q = -11) : False := by have hq: q = 15 := by linarith[g₃₃] rw [hq] at g₂ have hr: r = 5 := by linarith[g₂] linarith[hq,hr,h₀.2] lemma imo_1992_p1_8_8 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (h₀ : q < r) (h₁ : 6 < -r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 2) -- (g₁ : q * r - 4 * q - 4 * r + 5 = 0) -- (g₂ : (4 - q) * (4 - r) = 11) (g₃₄ : 4 - q = 11) : False := by have h₂: q = -7 := by exact (Int.sub_right_inj 4).mp g₃₄ have h₃: -6 ≤ r := by rw [h₂] at h₀ exact h₀ apply neg_le_neg at h₃ exact Lean.Omega.Int.le_lt_asymm h₃ h₁ lemma imo_1992_p1_9 (p q r: ℤ) (h₀: 1 < p ∧ p < q ∧ q < r) (hpl: 2 ≤ p) (hql: 3 ≤ q) (hrl: 4 ≤ r) (hpu: p < 4) (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * 3) : (p, q, r) = (2, 4, 8) ∨ (p, q, r) = (3, 5, 15) := by interval_cases p -- p = 2 . norm_num at * have g₂: (q - 3) * (r - 3) = 5 := by linarith have g₃: (q - 3) = -1 ∨ (q - 3) = 1 ∨ (q - 3) = -5 ∨ (q - 3) = 5 := by refine imo_1992_p1_7 (q - 3) (r - 3) 5 g₂ ?_ decide cases' g₃ with g₃₁ g₃₂ . exfalso linarith [hql,g₃₁] . cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 4 := by linarith rw [hq] at g₂ have hr: r = 8 := by linarith[g₂] exact { left := hq, right := hr } . exfalso cases' g₃₃ with g₃₃ g₃₄ . linarith[hql,g₃₃] . have hq: q = 8 := by linarith rw [hq] at g₂ norm_num at g₂ have hr: r = 4 := by linarith linarith[hrl,hr] . right norm_num at * have g₂: (6 - 3*q) * (2 - r) = 5 := by linarith have g₃: (6 - 3*q) = -1 ∨ (6 - 3*q) = 1 ∨ (6 - 3*q) = -5 ∨ (6 - 3*q) = 5 := by refine imo_1992_p1_7 (6 - 3*q) (2 - r) 5 g₂ ?_ decide exfalso cases' g₃ with g₃₁ g₃₂ . linarith[g₃₁,q] . cases' g₃₂ with g₃₂ g₃₃ . linarith[g₃₂,q] . cases' g₃₃ with g₃₃ g₃₄ . linarith[g₃₃,q] . linarith[g₃₄,q] lemma imo_1992_p1_9_1 (q r : ℤ) (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 2 < q ∧ q < r) (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) : q = 4 ∧ r = 8 := by have g₂: (q - 3) * (r - 3) = 5 := by linarith have g₃: (q - 3) = -1 ∨ (q - 3) = 1 ∨ (q - 3) = -5 ∨ (q - 3) = 5 := by refine imo_1992_p1_7 (q - 3) (r - 3) 5 g₂ ?_ decide cases' g₃ with g₃₁ g₃₂ . exfalso linarith [hql,g₃₁] . cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 4 := by linarith rw [hq] at g₂ have hr: r = 8 := by linarith[g₂] exact { left := hq, right := hr } . exfalso cases' g₃₃ with g₃₃ g₃₄ . linarith[hql,g₃₃] . have hq: q = 8 := by linarith rw [hq] at g₂ norm_num at g₂ have hr: r = 4 := by linarith linarith[hrl,hr] lemma imo_1992_p1_9_2 (q r : ℤ) (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 2 < q ∧ q < r) (g₂ : (q - 3) * (r - 3) = 5) : q = 4 ∧ r = 8 := by have g₃: (q - 3) = -1 ∨ (q - 3) = 1 ∨ (q - 3) = -5 ∨ (q - 3) = 5 := by refine imo_1992_p1_7 (q - 3) (r - 3) 5 g₂ ?_ decide cases' g₃ with g₃₁ g₃₂ . exfalso linarith [hql,g₃₁] . cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 4 := by linarith rw [hq] at g₂ have hr: r = 8 := by linarith[g₂] exact { left := hq, right := hr } . exfalso cases' g₃₃ with g₃₃ g₃₄ . linarith[hql,g₃₃] . have hq: q = 8 := by linarith rw [hq] at g₂ norm_num at g₂ have hr: r = 4 := by linarith linarith[hrl,hr] lemma imo_1992_p1_9_3 (q r : ℤ) (g₂ : (q - 3) * (r - 3) = 5) : q - 3 = -1 ∨ q - 3 = 1 ∨ q - 3 = -5 ∨ q - 3 = 5 := by refine imo_1992_p1_7 (q - 3) (r - 3) 5 g₂ ?_ decide lemma imo_1992_p1_9_4 -- (p : ℤ) (q r : ℤ) (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) (g₂ : (q - 3) * (r - 3) = 5) (g₃ : q - 3 = -1 ∨ q - 3 = 1 ∨ q - 3 = -5 ∨ q - 3 = 5) : q = 4 ∧ r = 8 := by cases' g₃ with g₃₁ g₃₂ . exfalso linarith [hql,g₃₁] . cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 4 := by linarith rw [hq] at g₂ have hr: r = 8 := by linarith[g₂] exact { left := hq, right := hr } . exfalso cases' g₃₃ with g₃₃ g₃₄ . linarith[hql,g₃₃] . have hq: q = 8 := by linarith rw [hq] at g₂ norm_num at g₂ have hr: r = 4 := by linarith linarith[hrl,hr] lemma imo_1992_p1_9_5 -- (p : ℤ) (q r : ℤ) (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) -- (g₂ : (q - 3) * (r - 3) = 5) (g₃₁ : q - 3 = -1) : q = 4 ∧ r = 8 := by exfalso linarith [hql,g₃₁] lemma imo_1992_p1_9_6 -- (p r : ℤ) (q r : ℤ) (hql : 3 ≤ q) (hrl : 4 ≤ r) -- (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) -- (g₂ : (q - 3) * (r - 3) = 5) (g₃₁ : r * (q - 4) < r * (3 - r)) : False := by have h₀: 3 - r ≤ q - 4 := by exact sub_le_sub hql hrl have h₀: r * (3 - r) ≤ r * (q - 4) := by refine (mul_le_mul_left ?_).mpr h₀ linarith linarith lemma imo_1992_p1_9_7 -- (p : ℤ) (q r : ℤ) (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) (g₂ : (q - 3) * (r - 3) = 5) (g₃₂ : q - 3 = 1 ∨ q - 3 = -5 ∨ q - 3 = 5) : q = 4 ∧ r = 8 := by cases' g₃₂ with g₃₂ g₃₃ . have hq: q = 4 := by linarith rw [hq] at g₂ have hr: r = 8 := by linarith[g₂] exact { left := hq, right := hr } . exfalso cases' g₃₃ with g₃₃ g₃₄ . linarith[hql,g₃₃] . have hq: q = 8 := by linarith rw [hq] at g₂ norm_num at g₂ have hr: r = 4 := by linarith linarith[hrl,hr] lemma imo_1992_p1_9_8 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) (g₂ : (q - 3) * (r - 3) = 5) (g₃₂ : q - 3 = 1) : q = 4 ∧ r = 8 := by have hq: q = 4 := by linarith rw [hq] at g₂ have hr: r = 8 := by linarith[g₂] exact { left := hq, right := hr } lemma imo_1992_p1_9_9 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) (g₂ : (q - 3) * (r - 3) = 5) (g₃₂ : q - 3 = 1) (hq : q = 4) : q = 4 ∧ r = 8 := by rw [hq] at g₂ have hr: r = 8 := by linarith[g₂] exact { left := hq, right := hr } lemma imo_1992_p1_9_10 -- (p : ℤ) (q r : ℤ) (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) (g₂ : (q - 3) * (r - 3) = 5) (g₃₃ : q - 3 = -5 ∨ q - 3 = 5) : False := by cases' g₃₃ with g₃₃ g₃₄ . linarith[hql,g₃₃] . have hq: q = 8 := by linarith rw [hq] at g₂ norm_num at g₂ have hr: r = 4 := by linarith linarith[hrl,hr] lemma imo_1992_p1_9_11 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) (hrl : 4 ≤ r) (h₀ : 2 < q ∧ q < r) -- (hk : 2 * q * r - 1 = (q - 1) * (r - 1) * 3) -- (g₁ : q * r - 3 * q - 3 * r + 4 = 0) (g₂ : (q - 3) * (r - 3) = 5) (g₃₄ : q - 3 = 5) : False := by have hq: q = 8 := by linarith rw [hq] at g₂ norm_num at g₂ have hr: r = 4 := by linarith linarith[hrl,hr] lemma imo_1992_p1_9_12 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (h₀ : 3 < q ∧ q < r) (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 3) : q = 5 ∧ r = 15 := by have g₂: (6 - 3*q) * (2 - r) = 5 := by linarith have g₃: (6 - 3*q) = -1 ∨ (6 - 3*q) = 1 ∨ (6 - 3*q) = -5 ∨ (6 - 3*q) = 5 := by refine imo_1992_p1_7 (6 - 3*q) (2 - r) 5 g₂ ?_ decide exfalso cases' g₃ with g₃₁ g₃₂ . linarith[g₃₁,q] . cases' g₃₂ with g₃₂ g₃₃ . linarith[g₃₂,q] . cases' g₃₃ with g₃₃ g₃₄ . linarith[g₃₃,q] . linarith[g₃₄,q] lemma imo_1992_p1_9_13 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 3) -- (g₁ : 3 * q * r - 6 * q - 6 * r + 7 = 0) (g₂ : (6 - 3 * q) * (2 - r) = 5) : False := by have g₃: (6 - 3*q) = -1 ∨ (6 - 3*q) = 1 ∨ (6 - 3*q) = -5 ∨ (6 - 3*q) = 5 := by refine imo_1992_p1_7 (6 - 3*q) (2 - r) 5 g₂ ?_ decide exfalso cases' g₃ with g₃₁ g₃₂ . linarith[g₃₁,q] . cases' g₃₂ with g₃₂ g₃₃ . linarith[g₃₂,q] . cases' g₃₃ with g₃₃ g₃₄ . linarith[g₃₃,q] . linarith[g₃₄,q] lemma imo_1992_p1_9_14 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) -- (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 3) -- (g₁ : 3 * q * r - 6 * q - 6 * r + 7 = 0) (g₂ : (6 - 3 * q) * (2 - r) = 5) : 6 - 3 * q = -1 ∨ 6 - 3 * q = 1 ∨ 6 - 3 * q = -5 ∨ 6 - 3 * q = 5 := by refine imo_1992_p1_7 (6 - 3*q) (2 - r) 5 g₂ ?_ decide lemma imo_1992_p1_9_15 -- (p : ℤ) (q r : ℤ) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (h₀ : 3 < q ∧ q < r) -- (hk : 3 * q * r - 1 = 2 * (q - 1) * (r - 1) * 3) -- (g₁ : 3 * q * r - 6 * q - 6 * r + 7 = 0) -- (g₂ : (6 - 3 * q) * (2 - r) = 5) (g₃ : 6 - 3 * q = -1 ∨ 6 - 3 * q = 1 ∨ 6 - 3 * q = -5 ∨ 6 - 3 * q = 5) : False := by exfalso cases' g₃ with g₃₁ g₃₂ . linarith[g₃₁,q] . cases' g₃₂ with g₃₂ g₃₃ . linarith[g₃₂,q] . cases' g₃₃ with g₃₃ g₃₄ . linarith[g₃₃,q] . linarith[g₃₄,q] lemma q_of_qr_eq_11_nat (q r : ℕ) (h₀ : q * r = 11) : q = 1 ∨ q = 11 := by have h₁: Nat.Prime (11:ℕ) := by decide have h₂: ↑q ∣ 11 := by exact Dvd.intro r h₀ exact Nat.Prime.eq_one_or_self_of_dvd h₁ q h₂ lemma abs_q_r_product (q r : ℤ) (h₀ : q * r = 11) : q.natAbs * r.natAbs = (11:ℕ) := by exact Int.natAbs_mul_natAbs_eq h₀ -- Since q * r = 11, taking the absolute value of both sides gives |q * r| = 11. -- By properties of absolute values, |q * r| = |q| * |r|. lemma myprime5 : Nat.Prime 5 := by rw [Nat.prime_def_lt'] constructor . norm_num . intros m hm mu interval_cases m all_goals {try norm_num } lemma abs_q_r_product_2 (q r : ℤ) (h₀ : q * r = (11:ℕ)) : abs q * abs r = 11 := by have h₁: q.natAbs * r.natAbs = (11:ℕ) := by exact Int.natAbs_mul_natAbs_eq h₀ have h₃: abs q = q.natAbs := by exact abs_eq_natAbs q have h₄: abs r = r.natAbs := by exact abs_eq_natAbs r rw [h₃,h₄] norm_cast lemma imo_1992_p1_19_1 (p q r : ℤ) -- (h₀ : 1 < p ∧ p < q ∧ q < r) (k : ℤ) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 2 ≤ p) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (hden : 0 < (p - 1) * (q - 1) * (r - 1)) : ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by have g₁: ↑(p * q * r - 1) = ↑k * (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by norm_cast linarith symm have g₂: (↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≠ 0 := by norm_cast linarith[hden] exact (div_eq_iff g₂).mpr g₁ lemma imo_1992_p1_19_2 (p q r : ℤ) -- (h₀ : 1 < p ∧ p < q ∧ q < r) (k : ℤ) -- (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) -- (hpl : 2 ≤ p) -- (hql : 3 ≤ q) -- (hrl : 4 ≤ r) (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (g₁ : ↑(p * q * r - 1) = ↑k * (↑((p - 1) * (q - 1) * (r - 1)):ℚ)) : ↑k = (↑(p * q * r - 1):ℚ) / (↑((p - 1) * (q - 1) * (r - 1)):ℚ) := by symm have g₂: (↑((p - 1) * (q - 1) * (r - 1)):ℚ) ≠ 0 := by norm_cast linarith[hden] exact (div_eq_iff g₂).mpr g₁ lemma imo_1992_p1_19_3 (p q r : ℤ) (h₀ : 1 < p ∧ p < q ∧ q < r) (k : ℤ) (hk : p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) (hpl : 2 ≤ p) (hql : 3 ≤ q) (hrl : 4 ≤ r) -- (hden : 0 < (p - 1) * (q - 1) * (r - 1)) (h₁ : ↑k = ↑(p * q * r - 1) / ↑((p - 1) * (q - 1) * (r - 1))) (hk4 : k < 4) (hk1 : 1 < k) (hpu : p < 4) : (p, q, r) = (2, 4, 8) ∨ (p, q, r) = (3, 5, 15) := by interval_cases k . exact imo_1992_p1_8 p q r h₀ hpl hql hrl hpu hk . exact imo_1992_p1_9 p q r h₀ hpl hql hrl hpu hk