442 lines
13 KiB
Plaintext
442 lines
13 KiB
Plaintext
import Mathlib.Analysis.Analytic.Meromorphic
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import Mathlib.Algebra.Order.AddGroupWithTop
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import Nevanlinna.analyticAt
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import Nevanlinna.mathlibAddOn
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import Nevanlinna.meromorphicAt
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open Topology
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/- Strongly MeromorphicAt -/
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def StronglyMeromorphicAt
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(f : ℂ → ℂ)
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(z₀ : ℂ) :=
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(∀ᶠ (z : ℂ) in nhds z₀, f z = 0) ∨ (∃ (n : ℤ), ∃ g : ℂ → ℂ, (AnalyticAt ℂ g z₀) ∧ (g z₀ ≠ 0) ∧ (∀ᶠ (z : ℂ) in nhds z₀, f z = (z - z₀) ^ n • g z))
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/- Strongly MeromorphicAt is Meromorphic -/
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theorem StronglyMeromorphicAt.meromorphicAt
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : StronglyMeromorphicAt f z₀) :
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MeromorphicAt f z₀ := by
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rcases hf with h|h
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· use 0; simp
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rw [analyticAt_congr h]
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exact analyticAt_const
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· obtain ⟨n, g, h₁g, _, h₃g⟩ := h
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rw [meromorphicAt_congr' h₃g]
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apply MeromorphicAt.smul
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apply MeromorphicAt.zpow
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apply MeromorphicAt.sub
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apply MeromorphicAt.id
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apply MeromorphicAt.const
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exact AnalyticAt.meromorphicAt h₁g
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/- Strongly MeromorphicAt of non-negative order is analytic -/
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theorem StronglyMeromorphicAt.analytic
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(h₁f : StronglyMeromorphicAt f z₀)
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(h₂f : 0 ≤ h₁f.meromorphicAt.order):
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AnalyticAt ℂ f z₀ := by
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let h₁f' := h₁f
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rcases h₁f' with h|h
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· rw [analyticAt_congr h]
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exact analyticAt_const
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· obtain ⟨n, g, h₁g, h₂g, h₃g⟩ := h
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rw [analyticAt_congr h₃g]
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have : h₁f.meromorphicAt.order = n := by
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rw [MeromorphicAt.order_eq_int_iff]
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use g
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constructor
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· exact h₁g
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· constructor
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· exact h₂g
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· exact Filter.EventuallyEq.filter_mono h₃g nhdsWithin_le_nhds
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rw [this] at h₂f
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apply AnalyticAt.smul
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nth_rw 1 [← Int.toNat_of_nonneg (WithTop.coe_nonneg.mp h₂f)]
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apply AnalyticAt.pow
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apply AnalyticAt.sub
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apply analyticAt_id -- Warning: want apply AnalyticAt.id
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apply analyticAt_const -- Warning: want AnalyticAt.const
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exact h₁g
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/- Analytic functions are strongly meromorphic -/
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theorem AnalyticAt.stronglyMeromorphicAt
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(h₁f : AnalyticAt ℂ f z₀) :
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StronglyMeromorphicAt f z₀ := by
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by_cases h₂f : h₁f.order = ⊤
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· rw [AnalyticAt.order_eq_top_iff] at h₂f
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tauto
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· have : h₁f.order ≠ ⊤ := h₂f
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rw [← ENat.coe_toNat_eq_self] at this
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rw [eq_comm, AnalyticAt.order_eq_nat_iff] at this
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right
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use h₁f.order.toNat
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obtain ⟨g, h₁g, h₂g, h₃g⟩ := this
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use g
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tauto
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/- Strong meromorphic depends only on germ -/
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theorem stronglyMeromorphicAt_congr
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{f g : ℂ → ℂ}
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{z₀ : ℂ}
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(hfg : f =ᶠ[𝓝 z₀] g) :
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StronglyMeromorphicAt f z₀ ↔ StronglyMeromorphicAt g z₀ := by
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unfold StronglyMeromorphicAt
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constructor
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· intro h
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rcases h with h|h
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· left
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exact Filter.EventuallyEq.rw h (fun x => Eq (g x)) (id (Filter.EventuallyEq.symm hfg))
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· obtain ⟨n, h, h₁h, h₂h, h₃h⟩ := h
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right
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use n
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use h
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constructor
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· assumption
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· constructor
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· assumption
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· apply Filter.EventuallyEq.trans hfg.symm
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assumption
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· intro h
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rcases h with h|h
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· left
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exact Filter.EventuallyEq.rw h (fun x => Eq (f x)) hfg
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· obtain ⟨n, h, h₁h, h₂h, h₃h⟩ := h
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right
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use n
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use h
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constructor
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· assumption
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· constructor
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· assumption
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· apply Filter.EventuallyEq.trans hfg
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assumption
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theorem StronglyMeromorphicAt.order_eq_zero_iff
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : StronglyMeromorphicAt f z₀) :
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hf.meromorphicAt.order = 0 ↔ f z₀ ≠ 0 := by
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constructor
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· intro h₁f
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let A := hf.analytic (le_of_eq (id (Eq.symm h₁f)))
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apply A.order_eq_zero_iff.1
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let B := A.meromorphicAt_order
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rw [h₁f] at B
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apply WithTopCoe
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rw [eq_comm]
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exact B
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· intro h
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have hf' := hf
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rcases hf with h₁|h₁
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· have : f z₀ = 0 := by
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apply Filter.EventuallyEq.eq_of_nhds h₁
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tauto
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· obtain ⟨n, g, h₁g, h₂g, h₃g⟩ := h₁
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have : n = 0 := by
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by_contra hContra
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let A := Filter.EventuallyEq.eq_of_nhds h₃g
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have : (0 : ℂ) ^ n = 0 := by
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exact zero_zpow n hContra
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simp at A
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simp_rw [this] at A
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simp at A
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tauto
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rw [this] at h₃g
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simp at h₃g
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have : hf'.meromorphicAt.order = 0 := by
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apply (hf'.meromorphicAt.order_eq_int_iff 0).2
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use g
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constructor
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· assumption
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· constructor
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· assumption
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· simp
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apply Filter.EventuallyEq.filter_mono h₃g
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exact nhdsWithin_le_nhds
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exact this
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theorem StronglyMeromorphicAt.localIdentity
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{f g : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : StronglyMeromorphicAt f z₀)
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(hg : StronglyMeromorphicAt g z₀) :
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f =ᶠ[𝓝[≠] z₀] g → f =ᶠ[𝓝 z₀] g := by
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intro h
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have t₀ : hf.meromorphicAt.order = hg.meromorphicAt.order := by
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exact hf.meromorphicAt.order_congr h
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by_cases cs : hf.meromorphicAt.order = 0
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· rw [cs] at t₀
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have h₁f := hf.analytic (le_of_eq (id (Eq.symm cs)))
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have h₁g := hg.analytic (le_of_eq t₀)
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exact h₁f.localIdentity h₁g h
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· apply Mnhds h
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let A := cs
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rw [hf.order_eq_zero_iff] at A
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simp at A
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let B := cs
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rw [t₀] at B
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rw [hg.order_eq_zero_iff] at B
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simp at B
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rw [A, B]
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/- Make strongly MeromorphicAt -/
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noncomputable def MeromorphicAt.makeStronglyMeromorphicAt
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : MeromorphicAt f z₀) :
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ℂ → ℂ := by
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intro z
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by_cases z = z₀
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· by_cases h₁f : hf.order = (0 : ℤ)
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· rw [hf.order_eq_int_iff] at h₁f
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exact (Classical.choose h₁f) z₀
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· exact 0
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· exact f z
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lemma m₁
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : MeromorphicAt f z₀) :
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∀ z ≠ z₀, f z = hf.makeStronglyMeromorphicAt z := by
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intro z hz
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unfold MeromorphicAt.makeStronglyMeromorphicAt
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simp [hz]
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lemma m₂
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : MeromorphicAt f z₀) :
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f =ᶠ[𝓝[≠] z₀] hf.makeStronglyMeromorphicAt := by
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apply eventually_nhdsWithin_of_forall
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exact fun x a => m₁ hf x a
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theorem StronglyMeromorphicAt_of_makeStronglyMeromorphic
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : MeromorphicAt f z₀) :
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StronglyMeromorphicAt hf.makeStronglyMeromorphicAt z₀ := by
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by_cases h₂f : hf.order = ⊤
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· have : hf.makeStronglyMeromorphicAt =ᶠ[𝓝 z₀] 0 := by
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apply Mnhds
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· apply Filter.EventuallyEq.trans (Filter.EventuallyEq.symm (m₂ hf))
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exact (MeromorphicAt.order_eq_top_iff hf).1 h₂f
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· unfold MeromorphicAt.makeStronglyMeromorphicAt
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simp [h₂f]
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apply AnalyticAt.stronglyMeromorphicAt
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rw [analyticAt_congr this]
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apply analyticAt_const
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· let n := hf.order.untop h₂f
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have : hf.order = n := by
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exact Eq.symm (WithTop.coe_untop hf.order h₂f)
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rw [hf.order_eq_int_iff] at this
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obtain ⟨g, h₁g, h₂g, h₃g⟩ := this
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right
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use n
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use g
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constructor
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· assumption
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· constructor
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· assumption
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· apply Mnhds
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· apply Filter.EventuallyEq.trans (Filter.EventuallyEq.symm (m₂ hf))
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exact h₃g
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· unfold MeromorphicAt.makeStronglyMeromorphicAt
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simp
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by_cases h₃f : hf.order = (0 : ℤ)
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· let h₄f := (hf.order_eq_int_iff 0).1 h₃f
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simp [h₃f]
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obtain ⟨h₁G, h₂G, h₃G⟩ := Classical.choose_spec h₄f
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simp at h₃G
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have hn : n = 0 := Eq.symm ((fun {α} {a} {b} h => (WithTop.eq_untop_iff h).mpr) h₂f (id (Eq.symm h₃f)))
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rw [hn]
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rw [hn] at h₃g; simp at h₃g
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simp
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have : g =ᶠ[𝓝 z₀] (Classical.choose h₄f) := by
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apply h₁g.localIdentity h₁G
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exact Filter.EventuallyEq.trans (Filter.EventuallyEq.symm h₃g) h₃G
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rw [Filter.EventuallyEq.eq_of_nhds this]
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· have : hf.order ≠ 0 := h₃f
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simp [this]
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left
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apply zero_zpow n
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dsimp [n]
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rwa [WithTop.untop_eq_iff h₂f]
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theorem makeStronglyMeromorphic_id
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(hf : StronglyMeromorphicAt f z₀) :
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f = hf.meromorphicAt.makeStronglyMeromorphicAt := by
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funext z
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by_cases hz : z = z₀
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· rw [hz]
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unfold MeromorphicAt.makeStronglyMeromorphicAt
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simp
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have h₀f := hf
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rcases hf with h₁f|h₁f
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· have A : f =ᶠ[𝓝[≠] z₀] 0 := by
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apply Filter.EventuallyEq.filter_mono h₁f
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exact nhdsWithin_le_nhds
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let B := (MeromorphicAt.order_eq_top_iff h₀f.meromorphicAt).2 A
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simp [B]
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exact Filter.EventuallyEq.eq_of_nhds h₁f
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· obtain ⟨n, g, h₁g, h₂g, h₃g⟩ := h₁f
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rw [Filter.EventuallyEq.eq_of_nhds h₃g]
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have : h₀f.meromorphicAt.order = n := by
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rw [MeromorphicAt.order_eq_int_iff (StronglyMeromorphicAt.meromorphicAt h₀f) n]
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use g
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constructor
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· assumption
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· constructor
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· assumption
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· exact eventually_nhdsWithin_of_eventually_nhds h₃g
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by_cases h₃f : h₀f.meromorphicAt.order = 0
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· simp [h₃f]
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have hn : n = (0 : ℤ) := by
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rw [h₃f] at this
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exact WithTop.coe_eq_zero.mp (id (Eq.symm this))
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simp_rw [hn]
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simp
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let t₀ : h₀f.meromorphicAt.order = (0 : ℤ) := by
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exact h₃f
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let A := (h₀f.meromorphicAt.order_eq_int_iff 0).1 t₀
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have : g =ᶠ[𝓝 z₀] (Classical.choose A) := by
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obtain ⟨h₀, h₁, h₂⟩ := Classical.choose_spec A
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apply h₁g.localIdentity h₀
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rw [hn] at h₃g
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simp at h₃g
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simp at h₂
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have h₄g : f =ᶠ[𝓝[≠] z₀] g := by
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apply Filter.EventuallyEq.filter_mono h₃g
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exact nhdsWithin_le_nhds
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exact Filter.EventuallyEq.trans (Filter.EventuallyEq.symm h₄g) h₂
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exact Filter.EventuallyEq.eq_of_nhds this
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· simp [h₃f]
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left
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apply zero_zpow n
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by_contra hn
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rw [hn] at this
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tauto
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· exact m₁ (StronglyMeromorphicAt.meromorphicAt hf) z hz
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theorem StronglyMeromorphicAt.decompose
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{f : ℂ → ℂ}
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{z₀ : ℂ}
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(h₁f : StronglyMeromorphicAt f z₀)
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(h₂f : h₁f.meromorphicAt.order ≠ ⊤) :
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∃ g : ℂ → ℂ, (AnalyticAt ℂ g z₀)
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∧ (g z₀ ≠ 0)
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∧ (f = (fun z ↦ (z-z₀) ^ (h₁f.meromorphicAt.order.untop h₂f)) * g) := by
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let n := - h₁f.meromorphicAt.order.untop h₂f
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let g₁ := (fun z ↦ (z-z₀) ^ (-h₁f.meromorphicAt.order.untop h₂f)) * f
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let g₁₁ := fun z ↦ (z-z₀) ^ (-h₁f.meromorphicAt.order.untop h₂f)
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have h₁g₁₁ : MeromorphicAt g₁₁ z₀ := by
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apply MeromorphicAt.zpow
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apply AnalyticAt.meromorphicAt
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apply AnalyticAt.sub
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apply analyticAt_id
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exact analyticAt_const
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have h₂g₁₁ : h₁g₁₁.order = - h₁f.meromorphicAt.order.untop h₂f := by
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rw [← WithTop.LinearOrderedAddCommGroup.coe_neg]
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rw [h₁g₁₁.order_eq_int_iff]
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use 1
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constructor
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· exact analyticAt_const
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· constructor
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· simp
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· apply eventually_nhdsWithin_of_forall
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simp [g₁₁]
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have h₁g₁ : MeromorphicAt g₁ z₀ := h₁g₁₁.mul h₁f.meromorphicAt
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have h₂g₁ : h₁g₁.order = 0 := by
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rw [h₁g₁₁.order_mul h₁f.meromorphicAt]
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rw [h₂g₁₁]
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simp
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rw [add_comm]
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rw [LinearOrderedAddCommGroupWithTop.add_neg_cancel_of_ne_top h₂f]
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let g := h₁g₁.makeStronglyMeromorphicAt
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use g
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have h₁g : StronglyMeromorphicAt g z₀ := by
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exact StronglyMeromorphicAt_of_makeStronglyMeromorphic h₁g₁
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have h₂g : h₁g.meromorphicAt.order = 0 := by
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rw [← h₁g₁.order_congr (m₂ h₁g₁)]
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exact h₂g₁
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constructor
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· apply analytic
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· rw [h₂g]
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· exact h₁g
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· constructor
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· rwa [← h₁g.order_eq_zero_iff]
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· funext z
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by_cases hz : z = z₀
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· by_cases hOrd : h₁f.meromorphicAt.order.untop h₂f = 0
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· simp [hOrd]
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have : StronglyMeromorphicAt g₁ z₀ := by
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unfold g₁
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simp [hOrd]
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have : (fun z => 1) * f = f := by
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funext z
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simp
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rwa [this]
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rw [hz]
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unfold g
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let A := makeStronglyMeromorphic_id this
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rw [← A]
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unfold g₁
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rw [hOrd]
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simp
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· have : h₁f.meromorphicAt.order ≠ 0 := by
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by_contra hC
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simp_rw [hC] at hOrd
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tauto
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let A := h₁f.order_eq_zero_iff.not.1 this
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simp at A
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rw [hz, A]
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simp
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left
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rw [zpow_eq_zero_iff]
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assumption
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· simp
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have : g z = g₁ z := by
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exact Eq.symm (m₁ h₁g₁ z hz)
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rw [this]
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unfold g₁
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simp [hz]
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rw [← mul_assoc]
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rw [mul_inv_cancel₀]
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simp
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apply zpow_ne_zero
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exact sub_ne_zero_of_ne hz
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