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Stefan Kebekus
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@ -41,8 +41,8 @@ noncomputable def MeromorphicOn.N_infty
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theorem Nevanlinna_counting₁₁
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theorem Nevanlinna_counting₁₁
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{f : ℂ → ℂ}
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{f : ℂ → ℂ}
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{a : ℂ}
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(hf : MeromorphicOn f ⊤)
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(hf : MeromorphicOn f ⊤) :
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(a : ℂ) :
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(hf.add (MeromorphicOn.const a)).N_infty = hf.N_infty := by
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(hf.add (MeromorphicOn.const a)).N_infty = hf.N_infty := by
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funext r
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funext r
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@ -94,6 +94,19 @@ theorem Nevanlinna_counting₁₁
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clear this
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clear this
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simp [G]
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simp [G]
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theorem Nevanlinna_counting'₁₁
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{f : ℂ → ℂ}
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(hf : MeromorphicOn f ⊤)
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(a : ℂ) :
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(hf.sub (MeromorphicOn.const a)).N_infty = hf.N_infty := by
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have : (f - fun x => a) = (f + fun x => -a) := by
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funext x
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simp; ring
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have : (hf.sub (MeromorphicOn.const a)).N_infty = (hf.add (MeromorphicOn.const (-a))).N_infty := by
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simp
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rw [this]
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exact Nevanlinna_counting₁₁ hf (-a)
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theorem Nevanlinna_counting₀
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theorem Nevanlinna_counting₀
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{f : ℂ → ℂ}
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{f : ℂ → ℂ}
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@ -286,4 +299,109 @@ theorem Nevanlinna_firstMain₂
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-- See Lang, p. 168
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-- See Lang, p. 168
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sorry
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have : (h₁f.T_infty r) - ((h₁f.sub (MeromorphicOn.const a)).T_infty r) = (h₁f.m_infty r) - ((h₁f.sub (MeromorphicOn.const a)).m_infty r) := by
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unfold MeromorphicOn.T_infty
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rw [Nevanlinna_counting'₁₁ h₁f a]
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simp
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rw [this]
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clear this
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unfold MeromorphicOn.m_infty
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rw [←mul_sub]
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rw [←intervalIntegral.integral_sub]
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let g := f - (fun _ ↦ a)
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have t₀₀ (x : ℝ) : log⁺ ‖f (circleMap 0 r x)‖ ≤ log⁺ ‖g (circleMap 0 r x)‖ + log⁺ ‖a‖ + log 2 := by
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unfold g
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simp only [Pi.sub_apply]
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calc log⁺ ‖f (circleMap 0 r x)‖
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_ = log⁺ ‖g (circleMap 0 r x) + a‖ := by
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unfold g
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simp
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_ ≤ log⁺ (‖g (circleMap 0 r x)‖ + ‖a‖) := by
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apply monoOn_logpos
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refine Set.mem_Ici.mpr ?_
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apply norm_nonneg
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refine Set.mem_Ici.mpr ?_
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apply add_nonneg
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apply norm_nonneg
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apply norm_nonneg
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--
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apply norm_add_le
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_ ≤ log⁺ ‖g (circleMap 0 r x)‖ + log⁺ ‖a‖ + log 2 := by
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apply logpos_add_le_add_logpos_add_log2
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have t₁₀ (x : ℝ) : log⁺ ‖f (circleMap 0 r x)‖ - log⁺ ‖g (circleMap 0 r x)‖ ≤ log⁺ ‖a‖ + log 2 := by
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rw [sub_le_iff_le_add]
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nth_rw 1 [add_comm]
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rw [←add_assoc]
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apply t₀₀ x
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clear t₀₀
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have t₀₁ (x : ℝ) : log⁺ ‖g (circleMap 0 r x)‖ ≤ log⁺ ‖f (circleMap 0 r x)‖ + log⁺ ‖a‖ + log 2 := by
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unfold g
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simp only [Pi.sub_apply]
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calc log⁺ ‖g (circleMap 0 r x)‖
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_ = log⁺ ‖f (circleMap 0 r x) - a‖ := by
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unfold g
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simp
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_ ≤ log⁺ (‖f (circleMap 0 r x)‖ + ‖a‖) := by
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apply monoOn_logpos
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refine Set.mem_Ici.mpr ?_
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apply norm_nonneg
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refine Set.mem_Ici.mpr ?_
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apply add_nonneg
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apply norm_nonneg
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apply norm_nonneg
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--
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apply norm_sub_le
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_ ≤ log⁺ ‖f (circleMap 0 r x)‖ + log⁺ ‖a‖ + log 2 := by
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apply logpos_add_le_add_logpos_add_log2
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have t₁₁ (x : ℝ) : log⁺ ‖g (circleMap 0 r x)‖ - log⁺ ‖f (circleMap 0 r x)‖ ≤ log⁺ ‖a‖ + log 2 := by
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rw [sub_le_iff_le_add]
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nth_rw 1 [add_comm]
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rw [←add_assoc]
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apply t₀₁ x
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clear t₀₁
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have t₂ {x : ℝ} : ‖log⁺ ‖f (circleMap 0 r x)‖ - log⁺ ‖g (circleMap 0 r x)‖‖ ≤ log⁺ ‖a‖ + log 2 := by
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by_cases h : 0 ≤ log⁺ ‖f (circleMap 0 r x)‖ - log⁺ ‖g (circleMap 0 r x)‖
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· rw [norm_of_nonneg h]
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exact t₁₀ x
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· rw [norm_of_nonpos (by linarith)]
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rw [neg_sub]
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exact t₁₁ x
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clear t₁₀ t₁₁
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have : ‖∫ (x : ℝ) in (0)..(2 * π), log⁺ ‖f (circleMap 0 r x)‖ - log⁺ ‖g (circleMap 0 r x)‖‖ ≤ (log⁺ ‖a‖ + log 2) * |2 * π - 0| := by
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apply intervalIntegral.norm_integral_le_of_norm_le_const
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intro x hx
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exact t₂
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clear t₂
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simp only [norm_eq_abs, sub_zero] at this
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rw [abs_mul]
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calc |(2 * π)⁻¹| * |∫ (x : ℝ) in (0)..(2 * π), log⁺ ‖f (circleMap 0 r x)‖ - log⁺ ‖g (circleMap 0 r x)‖|
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_ = |(2 * π)⁻¹| * ‖∫ (x : ℝ) in (0)..(2 * π), log⁺ ‖f (circleMap 0 r x)‖ - log⁺ ‖g (circleMap 0 r x)‖‖ := by
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sorry
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_ ≤ |(2 * π)⁻¹| * ((log⁺ ‖a‖ + log 2) * |2 * π|) := by
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apply?
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sorry
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_ = log⁺ ‖a‖ + log 2 := by
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simp [pi_ne_zero]
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--
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apply MeromorphicOn.integrable_logpos_abs_f
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exact fun x a => h₁f x trivial
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--
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apply MeromorphicOn.integrable_logpos_abs_f
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apply MeromorphicOn.sub
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exact fun x a => h₁f x trivial
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apply MeromorphicOn.const a
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@ -35,6 +35,14 @@ theorem logpos_norm {r : ℝ} : log⁺ r = 2⁻¹ * (log r + ‖log r‖) := by
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rw [this]
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rw [this]
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ring
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ring
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theorem logpos_nonneg
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{x : ℝ} :
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0 ≤ log⁺ x := by
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unfold logpos
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simp
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theorem logpos_abs
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theorem logpos_abs
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{x : ℝ} :
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{x : ℝ} :
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log⁺ x = log⁺ |x| := by
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log⁺ x = log⁺ |x| := by
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@ -125,3 +133,27 @@ theorem logpos_add_le_add_logpos_add_log2
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· rw [add_comm a b, add_comm (log⁺ a) (log⁺ b)]
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· rw [add_comm a b, add_comm (log⁺ a) (log⁺ b)]
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apply logpos_add_le_add_logpos_add_log2₀
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apply logpos_add_le_add_logpos_add_log2₀
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exact le_of_not_ge h
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exact le_of_not_ge h
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theorem monoOn_logpos :
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MonotoneOn log⁺ (Set.Ici 0) := by
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intro x hx y hy hxy
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by_cases h₁x : x = 0
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· rw [h₁x]
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unfold logpos
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simp
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simp at hx hy
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unfold logpos
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simp
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by_cases h₂x : log x ≤ 0
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· tauto
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· simp [h₂x]
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simp at h₂x
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have : log x ≤ log y := by
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apply log_le_log
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exact lt_of_le_of_ne hx fun a => h₁x (id (Eq.symm a))
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assumption
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simp [this]
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calc 0
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_ ≤ log x := by exact le_of_lt h₂x
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_ ≤ log y := this
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