Datasets:

roozbeh-yz
/

IMO-Steps

	import Mathlib
	set_option linter.unusedVariables.analyzeTactics true

	open Real

	lemma imo_1964_p2_1
	(a b c : ℝ)
	(ha : 0 < -a + b + c)
	(hb : 0 < a - b + c)
	(hc : 0 < a + b - c)
	(g1 : (a + b - c) * (a - b + c) * (-a + b + c) ≤ a * b * c) :
	((a + b - c) * (a - b + c) * (-a + b + c)) ^ 2 ≤ (a * b * c) ^ 2 := by
	refine pow_le_pow_left₀ (le_of_lt ?_) g1 2
	exact mul_pos (mul_pos hc hb) ha

	lemma imo_1964_p2_2
	(a b c : ℝ) :
	(a + b - c) * (a + c - b) ≤ a ^ 2 := by
	have h₁: (a + b - c) * (a + c - b) = a ^ 2 - (b - c) ^ 2 := by
	linarith
	rw [h₁]
	refine sub_le_self _ ?_
	exact sq_nonneg (b - c)


	lemma imo_1964_p2_3
	(a b c : ℝ) :
	a ^ 2 - (b - c) ^ 2 ≤ a ^ 2 := by
	simp
	exact sq_nonneg (b - c)


	lemma imo_1964_p2_4
	(a b c : ℝ)
	(h₀ : 0 < a ∧ 0 < b ∧ 0 < c)
	(h₁ : c < a + b)
	(h₂ : b < a + c)
	(h₃ : a < b + c) :
	((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 ≤ (a * b * c) ^ 2 := by
	have ha : 0 < b + c - a := by exact sub_pos.mpr h₃
	have hb : 0 < a + c - b := by exact sub_pos.mpr h₂
	have hc : 0 < a + b - c := by exact sub_pos.mpr h₁
	have h₄₁: (a + b - c) * (a + c - b) ≤ a ^ 2 := by
	exact imo_1964_p2_2 a b c
	have h₄₂: (a + b - c) * (b + c - a) ≤ b ^ 2 := by
	rw [add_comm a b]
	exact imo_1964_p2_2 b a c
	have h₄₃: (a + c - b) * (b + c - a) ≤ c ^ 2 := by
	rw [add_comm a c, add_comm b c]
	exact imo_1964_p2_2 c a b
	have h₄₄: ((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 = ((a + b - c) * (a + c - b)) *
	((a + b - c) * (b + c - a)) * ((a + c - b) * (b + c - a)) := by
	linarith
	rw [h₄₄]
	repeat rw [mul_pow]
	refine mul_le_mul ?_ h₄₃ ?_ ?_
	. refine mul_le_mul h₄₁ h₄₂ ?_ ?_
	. refine le_of_lt ?_
	exact mul_pos hc ha
	. exact sq_nonneg a
	. refine le_of_lt ?_
	exact mul_pos hb ha
	. refine le_of_lt ?_
	simp_all only [sub_pos, gt_iff_lt, pow_pos, mul_pos_iff_of_pos_left]


	lemma imo_1964_p2_5
	(a b c : ℝ)
	-- (h₀ : 0 < a ∧ 0 < b ∧ 0 < c)
	-- (h₁ : c < a + b)
	-- (h₂ : b < a + c)
	-- (h₃ : a < b + c)
	(ha : 0 < b + c - a)
	(hb : 0 < a + c - b)
	(hc : 0 < a + b - c)
	(h₄₁ : (a + b - c) * (a + c - b) ≤ a ^ 2)
	(h₄₂ : (a + b - c) * (b + c - a) ≤ b ^ 2)
	(h₄₃ : (a + c - b) * (b + c - a) ≤ c ^ 2) :
	((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 ≤ (a * b * c) ^ 2 := by
	repeat rw [mul_pow]
	rw [pow_two, pow_two, pow_two]
	have h₅: ((a + b - c) * (a + c - b)) * ((a + b - c) * (b + c - a)) ≤ a ^ 2 * b ^ 2 := by
	refine mul_le_mul h₄₁ h₄₂ ?_ ?_
	. refine le_of_lt ?_
	exact mul_pos hc ha
	. exact sq_nonneg a
	have h₆: ((a + b - c) * (a + c - b)) * ((a + b - c) * (b + c - a)) * ((a + c - b) * (b + c - a))
	≤ a ^ 2 * b ^ 2 * c ^ 2 := by
	refine mul_le_mul h₅ h₄₃ ?_ ?_
	. refine le_of_lt ?_
	exact mul_pos hb ha
	. refine mul_nonneg ?_ ?_
	. exact sq_nonneg a
	. exact sq_nonneg b
	linarith


	lemma imo_1964_p2_6
	(a b c : ℝ)
	-- (h₀ : 0 < a ∧ 0 < b ∧ 0 < c)
	-- h₁ : c < a + b
	-- h₂ : b < a + c
	-- h₃ : a < b + c
	(ha : 0 < b + c - a)
	(hb : 0 < a + c - b)
	(hc : 0 < a + b - c)
	(h₄₁ : (a + b - c) * (a + c - b) ≤ a ^ 2)
	(h₄₂ : (a + b - c) * (b + c - a) ≤ b ^ 2)
	(h₄₃ : (a + c - b) * (b + c - a) ≤ c ^ 2)
	(h₄₄ : ((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 =
	(a + b - c) * (a + c - b) * ((a + b - c) * (b + c - a)) * ((a + c - b) * (b + c - a))) :
	((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 ≤ a ^ 2 * b ^ 2 * c ^ 2 := by
	rw [h₄₄]
	have h₅: ((a + b - c) * (a + c - b)) * ((a + b - c) * (b + c - a)) ≤ a ^ 2 * b ^ 2 := by
	refine mul_le_mul h₄₁ h₄₂ ?_ ?_
	. refine le_of_lt ?_
	exact mul_pos hc ha
	. exact sq_nonneg a
	have h₆: ((a + b - c) * (a + c - b)) * ((a + b - c) * (b + c - a)) * ((a + c - b) * (b + c - a))
	≤ a ^ 2 * b ^ 2 * c ^ 2 := by
	refine mul_le_mul h₅ h₄₃ ?_ ?_
	. refine le_of_lt ?_
	exact mul_pos hb ha
	. refine mul_nonneg ?_ ?_
	. exact sq_nonneg a
	. exact sq_nonneg b
	linarith


	lemma imo_1964_p2_7
	(a b c : ℝ)
	-- (h₀ : 0 < a ∧ 0 < b ∧ 0 < c)
	-- (h₁ : c < a + b)
	-- (h₂ : b < a + c)
	-- (h₃ : a < b + c)
	(ha : 0 < b + c - a)
	-- (hb : 0 < a + c - b)
	(hc : 0 < a + b - c)
	(h₄₁ : (a + b - c) * (a + c - b) ≤ a ^ 2)
	(h₄₂ : (a + b - c) * (b + c - a) ≤ b ^ 2) :
	-- (h₄₃ : (a + c - b) * (b + c - a) ≤ c ^ 2)
	-- (h₄₄ : ((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 =
	-- (a + b - c) * (a + c - b) * ((a + b - c) * (b + c - a)) * ((a + c - b) * (b + c - a))) :
	(a + b - c) * (a + c - b) * ((a + b - c) * (b + c - a)) ≤ a ^ 2 * b ^ 2 := by
	refine mul_le_mul h₄₁ h₄₂ ?_ ?_
	. refine le_of_lt ?_
	exact mul_pos hc ha
	. exact sq_nonneg a


	lemma imo_1964_p2_8
	(a b c : ℝ)
	(h₀ : 0 < a ∧ 0 < b ∧ 0 < c)
	-- (h₁ : c < a + b)
	-- (h₂ : b < a + c)
	-- (h₃ : a < b + c)
	-- (ha : 0 < b + c - a)
	-- (hb : 0 < a + c - b)
	-- (hc : 0 < a + b - c)
	(h₄ : ((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 ≤ (a * b * c) ^ 2) :
	(a + b - c) * (a + c - b) * (b + c - a) ≤ a * b * c := by
	refine le_of_pow_le_pow_left₀ ?_ ?_ h₄
	. norm_num
	. refine le_of_lt ?_
	refine mul_pos ?_ h₀.2.2
	exact mul_pos h₀.1 h₀.2.1


	lemma imo_1964_p2_9
	(a b c : ℝ)
	-- (h₀ : 0 < a ∧ 0 < b ∧ 0 < c)
	-- (h₁ : c < a + b)
	-- (h₂ : b < a + c)
	-- (h₃ : a < b + c)
	-- (ha : 0 < b + c - a)
	-- (hb : 0 < a + c - b)
	-- (hc : 0 < a + b - c)
	-- (h₄ : ((a + b - c) * (a + c - b) * (b + c - a)) ^ 2 ≤ (a * b * c) ^ 2)
	(h₅ : (a + b - c) * (a + c - b) * (b + c - a) ≤ a * b * c) :
	a ^ 2 * (b + c - a) + b ^ 2 * (c + a - b) + c ^ 2 * (a + b - c) ≤ 3 * a * b * c := by
	repeat rw [mul_sub]
	repeat rw [mul_add]
	linarith