| import Mathlib | |
| set_option linter.unusedVariables.analyzeTactics true | |
| open Int Rat | |
| lemma mylemma_main_lt2 | |
| (p q r: β€) | |
| (hpl: 4 β€ p) | |
| (hql: 5 β€ q) | |
| (hrl: 6 β€ r) : | |
| (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) β€ β2 := by | |
| have hβ: (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) | |
| = (βp/β(p-1)) * (βq/β(q-1)) * (βr/β(r-1)) := by | |
| norm_cast | |
| simp | |
| have hp: (βp/β(p-1):β) β€ ((4/3):β) := by | |
| have gβ: 0 < (β(p - 1):β) := by | |
| norm_cast | |
| linarith [hpl] | |
| have gβ: βp * β(3:β) β€ β(4:β) * (β(p - 1):β) := by | |
| norm_cast | |
| linarith | |
| refine (div_le_iffβ gβ).mpr ?_ | |
| rw [div_mul_eq_mul_div] | |
| refine (le_div_iffβ ?_).mpr gβ | |
| norm_num | |
| have hq: (βq/β(q-1)) β€ ((5/4):β) := by | |
| have gβ: 0 < (β(q - 1):β) := by | |
| norm_cast | |
| linarith[hql] | |
| have gβ: βq * β(4:β) β€ β(5:β) * (β(q - 1):β) := by | |
| norm_cast | |
| linarith | |
| refine (div_le_iffβ gβ).mpr ?_ | |
| rw [div_mul_eq_mul_div] | |
| refine (le_div_iffβ ?_).mpr gβ | |
| norm_num | |
| have hr: (βr/β(r-1)) β€ ((6/5):β) := by | |
| have gβ: 0 < (β(r - 1):β) := by | |
| norm_cast | |
| linarith[hql] | |
| have gβ: βr * β(5:β) β€ β(6:β) * (β(r - 1):β) := by | |
| norm_cast | |
| linarith | |
| refine (div_le_iffβ gβ).mpr ?_ | |
| rw [div_mul_eq_mul_div] | |
| refine (le_div_iffβ ?_).mpr gβ | |
| norm_num | |
| have hub: (βp/β(p-1)) * (βq/β(q-1)) * (βr/β(r-1)) β€ (4/3:β) * ((5/4):β) * ((6/5):β) := by | |
| have hq_nonneg: 0 β€ (βq:β) := by | |
| norm_cast | |
| linarith | |
| have hq_1_nonneg: 0 β€ (β(q - 1):β) := by | |
| norm_cast | |
| linarith | |
| have hβ: 0 β€ (((q:β) / β(q - 1)):β) := by | |
| exact div_nonneg hq_nonneg hq_1_nonneg | |
| have hub1: (βp/β(p-1)) * (βq/β(q-1)) β€ ((4/3):β) * ((5/4):β) := by | |
| exact mul_le_mul hp hq hβ (by norm_num) | |
| have hr_nonneg: 0 β€ (βr:β) := by | |
| norm_cast | |
| linarith | |
| have hr_1_nonneg: 0 β€ (β(r - 1):β) := by | |
| norm_cast | |
| linarith | |
| have hβ: 0 β€ (((r:β) / β(r - 1)):β) := by | |
| exact div_nonneg hr_nonneg hr_1_nonneg | |
| exact mul_le_mul hub1 hr hβ (by norm_num) | |
| norm_num at hub | |
| rw [hβ] | |
| norm_num | |
| exact hub | |
| lemma mylemma_k_lt_2 | |
| (p q r k: β€) | |
| (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) | |
| (hpl: 4 β€ p) | |
| (hql: 5 β€ q) | |
| (hrl: 6 β€ r) | |
| (hden: 0 < (p - 1) * (q - 1) * (r - 1) ) : | |
| (k < 2) := by | |
| have hβ: (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) β€ β2 := by | |
| exact mylemma_main_lt2 p q r hpl hql hrl | |
| have hβ: βk = (β(p * q * r - 1):β) / (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| have gβ: β(p * q * r - 1) = βk * (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| norm_cast | |
| linarith | |
| symm | |
| have gβ: (β((p - 1) * (q - 1) * (r - 1)):β) β 0 := by | |
| norm_cast | |
| linarith[hden] | |
| exact (div_eq_iff gβ).mpr gβ | |
| have hβ: βk < (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| rw [hβ] | |
| have gβ: (β(p * q * r - 1):β) < (β(p * q * r):β) := by | |
| norm_cast | |
| exact sub_one_lt (p * q * r) | |
| have gβ: 0 < (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| norm_cast | |
| exact div_lt_div_of_pos_right gβ gβ | |
| have hβ: (βk:β) < β2 := by | |
| exact lt_of_lt_of_le hβ hβ | |
| norm_cast at hβ | |
| lemma mylemma_main_lt4 | |
| (p q r: β€) | |
| (hpl: 2 β€ p) | |
| (hql: 3 β€ q) | |
| (hrl: 4 β€ r) : | |
| (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) β€ β4 := by | |
| have hβ: (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) | |
| = (βp/β(p-1)) * (βq/β(q-1)) * (βr/β(r-1)) := by | |
| norm_cast | |
| simp | |
| have hp: (βp/β(p-1):β) β€ β(2:β) := by | |
| have gβ: 0 < (β(p - 1):β) := by | |
| norm_cast | |
| linarith[hpl] | |
| have gβ: βp β€ β(2:β) * (β(p - 1):β) := by | |
| norm_cast | |
| linarith | |
| exact (div_le_iffβ gβ).mpr gβ | |
| have hq: (βq/β(q-1)) β€ ((3/2):β) := by | |
| have gβ: 0 < (β(q - 1):β) := by | |
| norm_cast | |
| linarith[hql] | |
| have gβ: βq * β(2:β) β€ β(3:β) * (β(q - 1):β) := by | |
| norm_cast | |
| linarith | |
| refine (div_le_iffβ gβ).mpr ?_ | |
| rw [div_mul_eq_mul_div] | |
| refine (le_div_iffβ ?_).mpr gβ | |
| norm_num | |
| have hr: (βr/β(r-1)) β€ ((4/3):β) := by | |
| have gβ: 0 < (β(r - 1):β) := by | |
| norm_cast | |
| linarith[hql] | |
| have gβ: βr * β(3:β) β€ β(4:β) * (β(r - 1):β) := by | |
| norm_cast | |
| linarith | |
| refine (div_le_iffβ gβ).mpr ?_ | |
| rw [div_mul_eq_mul_div] | |
| refine (le_div_iffβ ?_).mpr gβ | |
| norm_num | |
| have hub: (βp/β(p-1)) * (βq/β(q-1)) * (βr/β(r-1)) β€ (2:β) * ((3/2):β) * ((4/3):β) := by | |
| have hq_nonneg: 0 β€ (βq:β) := by | |
| norm_cast | |
| linarith | |
| have hq_1_nonneg: 0 β€ (β(q - 1):β) := by | |
| norm_cast | |
| linarith | |
| have hβ: 0 β€ (((q:β) / β(q - 1)):β) := by | |
| exact div_nonneg hq_nonneg hq_1_nonneg | |
| have hub1: (βp/β(p-1)) * (βq/β(q-1)) β€ (2:β) * ((3/2):β) := by | |
| exact mul_le_mul hp hq hβ (by norm_num) | |
| have hr_nonneg: 0 β€ (βr:β) := by | |
| norm_cast | |
| linarith | |
| have hr_1_nonneg: 0 β€ (β(r - 1):β) := by | |
| norm_cast | |
| linarith | |
| have hβ: 0 β€ (((r:β) / β(r - 1)):β) := by | |
| exact div_nonneg hr_nonneg hr_1_nonneg | |
| exact mul_le_mul hub1 hr hβ (by norm_num) | |
| norm_num at hub | |
| rw [hβ] | |
| norm_num | |
| exact hub | |
| lemma mylemma_k_lt_4 | |
| (p q r k: β€) | |
| (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) | |
| (hpl: 2 β€ p) | |
| (hql: 3 β€ q) | |
| (hrl: 4 β€ r) | |
| (hden: 0 < (p - 1) * (q - 1) * (r - 1) ) : | |
| (k < 4) := by | |
| have hβ: (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) β€ β4 := by | |
| exact mylemma_main_lt4 p q r hpl hql hrl | |
| have hβ: βk = (β(p * q * r - 1):β) / (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| have gβ: β(p * q * r - 1) = βk * (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| norm_cast | |
| linarith | |
| symm | |
| have gβ: (β((p - 1) * (q - 1) * (r - 1)):β) β 0 := by | |
| norm_cast | |
| linarith [hden] | |
| exact (div_eq_iff gβ).mpr gβ | |
| have hβ: βk < (β(p * q * r) / β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| rw [hβ] | |
| have gβ: (β(p * q * r - 1):β) < (β(p * q * r):β) := by | |
| norm_cast | |
| exact sub_one_lt (p * q * r) | |
| have gβ: 0 < (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| norm_cast | |
| exact div_lt_div_of_pos_right gβ gβ | |
| have hβ: (βk:β) < β4 := by | |
| exact lt_of_lt_of_le hβ hβ | |
| norm_cast at hβ | |
| lemma mylemma_k_gt_1 | |
| (p q r k: β€) | |
| (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) | |
| (hβ: βk = (β(p * q * r - 1):β) / (β((p - 1) * (q - 1) * (r - 1)):β)) | |
| (hpl: 2 β€ p) | |
| (hql: 3 β€ q) | |
| (hrl: 4 β€ r) | |
| (hden: 0 < (p - 1) * (q - 1) * (r - 1) ) : | |
| (1 < k) := by | |
| have hk0: 0 < (βk:β) := by | |
| have gβ: 2*3*4 β€ p * q * r := by | |
| have gβ: 2*3 β€ p * q := by | |
| exact mul_le_mul hpl hql (by norm_num) (by linarith[hpl]) | |
| exact mul_le_mul gβ hrl (by norm_num) (by linarith[gβ]) | |
| have gβ: 0 < (β(p * q * r - 1):β) := by | |
| norm_cast | |
| linarith[gβ] | |
| have gβ: 0 < (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| norm_cast | |
| rw [hβ] | |
| exact div_pos gβ gβ | |
| norm_cast at hk0 | |
| by_contra hc | |
| push_neg at hc | |
| interval_cases k | |
| simp at hk | |
| exfalso | |
| have gβ: p*q + q*r + r*p = p+q+r := by linarith | |
| have gβ: p < p*q := by exact lt_mul_right (by linarith) (by linarith) | |
| have gβ: q < q*r := by exact lt_mul_right (by linarith) (by linarith) | |
| have gβ: r < r*p := by exact lt_mul_right (by linarith) (by linarith) | |
| have gβ : p+q+r < p*q + q*r + r*p := by linarith[gβ,gβ,gβ] | |
| linarith [gβ,gβ ] | |
| lemma mylemma_p_lt_4 | |
| (p q r k: β€) | |
| (hβ : 1 < p β§ p < q β§ q < r) | |
| (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * k) | |
| (hβ: βk = (β(p * q * r - 1):β) / (β((p - 1) * (q - 1) * (r - 1)):β)) | |
| (hpl: 2 β€ p) | |
| (hql: 3 β€ q) | |
| (hrl: 4 β€ r) | |
| (hden: 0 < (p - 1) * (q - 1) * (r - 1) ) : | |
| (p < 4) := by | |
| by_contra hcp | |
| push_neg at hcp | |
| have hcq: 5 β€ q := by linarith | |
| have hcr: 6 β€ r := by linarith | |
| have hβ: k < 2 := by exact mylemma_k_lt_2 p q r k hk hcp hcq hcr hden | |
| have hβ: 1 < k := by exact mylemma_k_gt_1 p q r k hk hβ hpl hql hrl hden | |
| linarith | |
| lemma q_r_divisor_of_prime | |
| (q r : β€) | |
| (p: β) | |
| (hβ : q * r = βp) | |
| (hβ: Nat.Prime p) : | |
| q = -1 β¨ q = 1 β¨ q = -p β¨ q = p := by | |
| have hq : q β 0 := by | |
| intro h | |
| rw [h] at hβ | |
| simp at hβ | |
| symm at hβ | |
| norm_cast at hβ | |
| rw [hβ] at hβ | |
| exact Nat.not_prime_zero hβ | |
| have hr : r β 0 := by | |
| intro h | |
| rw [h] at hβ | |
| simp at hβ | |
| norm_cast at hβ | |
| rw [β hβ] at hβ | |
| exact Nat.not_prime_zero hβ | |
| have hqr : abs q * abs r = p := by | |
| have hβ: abs q = q.natAbs := by exact abs_eq_natAbs q | |
| have hβ: abs r = r.natAbs := by exact abs_eq_natAbs r | |
| rw [hβ,hβ] | |
| norm_cast | |
| exact Int.natAbs_mul_natAbs_eq hβ | |
| have h_abs: abs (β(q.natAbs):β€) = 1 β¨ abs q = p := by | |
| cases' Int.natAbs_eq q with h_1 h_2 | |
| . rw [h_1] at hqr | |
| have hβ: abs (β(q.natAbs):β€) β£ p := by exact Dvd.intro (abs r) hqr | |
| have hβ: (β(q.natAbs):β) β£ p := by | |
| norm_cast at * | |
| have hβ: (β(q.natAbs):β) = 1 β¨ (β(q.natAbs):β) = p := by | |
| exact Nat.Prime.eq_one_or_self_of_dvd hβ (β(q.natAbs):β) hβ | |
| cases' hβ with hββ hββ | |
| . left | |
| norm_cast at * | |
| have hβ : abs q = q.natAbs := by exact abs_eq_natAbs q | |
| right | |
| rw [hβ ] | |
| norm_cast at * | |
| . rw [h_2] at hqr | |
| rw [abs_neg _] at hqr | |
| have hβ: abs (β(q.natAbs):β€) β£ p := by exact Dvd.intro (abs r) hqr | |
| have hβ: (β(q.natAbs):β) β£ p := by | |
| norm_cast at * | |
| have hβ: (β(q.natAbs):β) = 1 β¨ (β(q.natAbs):β) = p := by | |
| exact Nat.Prime.eq_one_or_self_of_dvd hβ (β(q.natAbs):β) hβ | |
| cases' hβ with hββ hββ | |
| . left | |
| norm_cast at * | |
| . have hβ : abs q = q.natAbs := by exact abs_eq_natAbs q | |
| right | |
| rw [hβ ] | |
| norm_cast | |
| cases' h_abs with hq_abs hq_abs | |
| . norm_cast at * | |
| have hβ: q = β(q.natAbs) β¨ q = -β(q.natAbs) := by | |
| exact Int.natAbs_eq q | |
| rw [hq_abs] at hβ | |
| norm_cast at hβ | |
| cases' hβ with hββ hββ | |
| . right | |
| left | |
| exact hββ | |
| . left | |
| exact hββ | |
| . right | |
| right | |
| have hβ: abs q = q.natAbs := by exact abs_eq_natAbs q | |
| rw [hβ] at hq_abs | |
| norm_cast at hq_abs | |
| refine or_comm.mp ?_ | |
| refine (Int.natAbs_eq_natAbs_iff).mp ?_ | |
| norm_cast | |
| lemma mylemma_qr_11 | |
| (q r: β€) | |
| (hβ: (4 - q) * (4 - r) = 11) : | |
| (4 - q = -1 β¨ 4 - q = 1 β¨ 4 - q = -11 β¨ 4 - q = 11) := by | |
| have hβ: Nat.Prime (11) := by decide | |
| exact q_r_divisor_of_prime (4-q) (4-r) 11 hβ hβ | |
| lemma mylemma_qr_5 | |
| (q r: β€) | |
| (hβ: (q - 3) * (r - 3) = 5) : | |
| (q - 3 = -1 β¨ q - 3 = 1 β¨ q - 3 = -5 β¨ q - 3 = 5) := by | |
| have hβ: Nat.Prime (5) := by decide | |
| exact q_r_divisor_of_prime (q - 3) (r - 3) 5 hβ hβ | |
| lemma mylemma_63qr_5 | |
| (q r: β€) | |
| (hβ: (6 - 3*q) * (2 - r) = 5) : | |
| (6 - 3*q = -1 β¨ 6 - 3*q = 1 β¨ 6 - 3*q = -5 β¨ 6 - 3*q = 5) := by | |
| have hβ: Nat.Prime (5) := by decide | |
| exact q_r_divisor_of_prime (6 - 3*q) (2 - r) 5 hβ hβ | |
| lemma mylemma_case_k_2 | |
| (p q r: β€) | |
| (hβ: 1 < p β§ p < q β§ q < r) | |
| (hpl: 2 β€ p) | |
| (hql: 3 β€ q) | |
| (hrl: 4 β€ r) | |
| (hpu: p < 4) | |
| (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * 2) : | |
| (p, q, r) = (2, 4, 8) β¨ (p, q, r) = (3, 5, 15) := by | |
| interval_cases p | |
| . exfalso | |
| norm_num at * | |
| have gβ: 2*q + 2*r = 3 := by linarith | |
| linarith [gβ,hql,hrl] | |
| . right | |
| norm_num at * | |
| -- have gβ: q*r - 4*q - 4*r + 5 = 0 := by linarith | |
| have gβ: (4-q)*(4-r) = 11 := by linarith | |
| have gβ: (4-q) = -1 β¨ (4-q) = 1 β¨ (4-q) = -11 β¨ (4-q) = 11 := by | |
| exact mylemma_qr_11 q r gβ | |
| cases' gβ with gββ gββ | |
| . have hq: q = 5 := by linarith | |
| constructor | |
| . exact hq | |
| . rw [hq] at gβ | |
| linarith[gβ] | |
| . exfalso | |
| cases' gββ with gββ gββ | |
| . have hq: q = 3 := by linarith[gββ] | |
| rw [hq] at gβ | |
| have hr: r = -7 := by linarith[gβ] | |
| linarith[hrl,hr] | |
| . cases' gββ with gββ gββ | |
| . have hq: q = 15 := by linarith[gββ] | |
| rw [hq] at gβ | |
| have hr: r = 5 := by linarith[gβ] | |
| linarith[hq,hr,hβ.2] | |
| . have hq: q = -7 := by linarith[gββ] | |
| linarith[hq,hql] | |
| lemma mylemma_case_k_3 | |
| (p q r: β€) | |
| (hβ: 1 < p β§ p < q β§ q < r) | |
| (hpl: 2 β€ p) | |
| (hql: 3 β€ q) | |
| (hrl: 4 β€ r) | |
| (hpu: p < 4) | |
| (hk: p * q * r - 1 = (p - 1) * (q - 1) * (r - 1) * 3) : | |
| (p, q, r) = (2, 4, 8) β¨ (p, q, r) = (3, 5, 15) := by | |
| interval_cases p | |
| -- p = 2 | |
| . norm_num at * | |
| -- have gβ: q*r - 3*q - 3*r + 4 = 0 := by linarith | |
| have gβ: (q-3)*(r-3) = 5 := by linarith | |
| have gβ: (q-3) = -1 β¨ (q-3) = 1 β¨ (q-3) = -5 β¨ (q-3) = 5 := by | |
| exact mylemma_qr_5 q r gβ | |
| cases' gβ with gββ gββ | |
| . exfalso | |
| linarith [hql,gββ] | |
| . cases' gββ with gββ gββ | |
| . have hq: q = 4 := by linarith | |
| rw [hq] at gβ | |
| have hr: r = 8 := by linarith[gβ] | |
| exact { left := hq, right := hr } | |
| . exfalso | |
| cases' gββ with gββ gββ | |
| . linarith[hql,gββ] | |
| . have hq: q = 8 := by linarith | |
| rw [hq] at gβ | |
| norm_num at gβ | |
| have hr: r = 4 := by linarith | |
| linarith[hrl,hr] | |
| -- p = 3 | |
| . right | |
| norm_num at * | |
| -- have gβ: 3 * q * r - 6 * q - 6 * r + 7 = 0 := by linarith | |
| have gβ: (6 - 3*q) * (2 - r) = 5 := by linarith | |
| have gβ: (6 - 3*q) = -1 β¨ (6 - 3*q) = 1 β¨ (6 - 3*q) = -5 β¨ (6 - 3*q) = 5 := by | |
| exact mylemma_63qr_5 q r gβ | |
| exfalso | |
| cases' gβ with gββ gββ | |
| . linarith[gββ,q] | |
| . cases' gββ with gββ gββ | |
| . linarith[gββ,q] | |
| . cases' gββ with gββ gββ | |
| . linarith[gββ,q] | |
| . linarith[gββ,q] | |
| theorem imo_1992_p1 | |
| (p q r : β€) | |
| (hβ : 1 < p β§ p < q β§ q < r) | |
| (hβ : (p - 1) * (q - 1) * (r - 1)β£(p * q * r - 1)) : | |
| (p, q, r) = (2, 4, 8) β¨ (p, q, r) = (3, 5, 15) := by | |
| cases' hβ with k hk | |
| have hpl: 2 β€ p := by linarith | |
| have hql: 3 β€ q := by linarith | |
| have hrl: 4 β€ r := by linarith | |
| have hden: 0 < (((p - 1) * (q - 1)) * (r - 1)) := by | |
| have gp: 0 < (p - 1) := by linarith | |
| have gq: 0 < (q - 1) := by linarith | |
| have gr: 0 < (r - 1) := by linarith | |
| exact mul_pos (mul_pos gp gq) gr | |
| have hβ: βk = (β(p * q * r - 1):β) / (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| have gβ: β(p * q * r - 1) = βk * (β((p - 1) * (q - 1) * (r - 1)):β) := by | |
| norm_cast | |
| linarith | |
| symm | |
| have gβ: (β((p - 1) * (q - 1) * (r - 1)):β) β 0 := by | |
| norm_cast | |
| linarith[hden] | |
| exact (div_eq_iff gβ).mpr gβ | |
| have hk4: k < 4 := by exact mylemma_k_lt_4 p q r k hk hpl hql hrl hden | |
| have hk1: 1 < k := by exact mylemma_k_gt_1 p q r k hk hβ hpl hql hrl hden | |
| have hpu: p < 4 := by exact mylemma_p_lt_4 p q r k hβ hk hβ hpl hql hrl hden | |
| interval_cases k | |
| . exact mylemma_case_k_2 p q r hβ hpl hql hrl hpu hk | |
| . exact mylemma_case_k_3 p q r hβ hpl hql hrl hpu hk | |