mirror of
https://github.com/GTBarkley/comm_alg.git
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334 lines
11 KiB
Text
334 lines
11 KiB
Text
import Mathlib.RingTheory.Ideal.Operations
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import Mathlib.RingTheory.FiniteType
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import Mathlib.Order.Height
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import Mathlib.RingTheory.Polynomial.Quotient
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import Mathlib.RingTheory.PrincipalIdealDomain
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import Mathlib.RingTheory.DedekindDomain.Basic
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import Mathlib.RingTheory.Ideal.Quotient
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import Mathlib.RingTheory.Localization.AtPrime
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import Mathlib.AlgebraicGeometry.PrimeSpectrum.Basic
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import Mathlib.Order.ConditionallyCompleteLattice.Basic
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import CommAlg.krull
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section AddToOrder
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open List hiding le_antisymm
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open OrderDual
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universe u v
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variable {α β : Type _}
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variable [LT α] [LT β] (s t : Set α)
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namespace Set
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theorem append_mem_subchain_iff :
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l ++ l' ∈ s.subchain ↔ l ∈ s.subchain ∧ l' ∈ s.subchain ∧ ∀ a ∈ l.getLast?, ∀ b ∈ l'.head?, a < b := by
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simp [subchain, chain'_append]
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aesop
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end Set
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namespace List
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#check Option
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theorem getLast?_map (l : List α) (f : α → β) :
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(l.map f).getLast? = Option.map f (l.getLast?) := by
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cases' l with a l
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. rfl
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induction' l with b l ih
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. rfl
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. simp [List.getLast?_cons_cons, ih]
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end List
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end AddToOrder
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--trying and failing to prove ht p = dim R_p
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section Localization
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variable {R : Type _} [CommRing R] (I : PrimeSpectrum R)
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variable {S : Type _} [CommRing S] [Algebra R S] [IsLocalization.AtPrime S I.asIdeal]
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open Ideal
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open LocalRing
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open PrimeSpectrum
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#check algebraMap R (Localization.AtPrime I.asIdeal)
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#check PrimeSpectrum.comap (algebraMap R (Localization.AtPrime I.asIdeal))
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#check krullDim
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#check dim_eq_bot_iff
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#check height_le_krullDim
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variable (J₁ J₂ : PrimeSpectrum (Localization.AtPrime I.asIdeal))
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example (h : J₁ ≤ J₂) : PrimeSpectrum.comap (algebraMap R (Localization.AtPrime I.asIdeal)) J₁ ≤
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PrimeSpectrum.comap (algebraMap R (Localization.AtPrime I.asIdeal)) J₂ := by
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intro x hx
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exact h hx
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def gadslfasd' : Ideal S := (IsLocalization.AtPrime.localRing S I.asIdeal).maximalIdeal
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-- instance gadslfasd : LocalRing S := IsLocalization.AtPrime.localRing S I.asIdeal
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example (f : α → β) (hf : Function.Injective f) (h : a₁ ≠ a₂) : f a₁ ≠ f a₂ := by library_search
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instance map_prime (J : PrimeSpectrum R) (hJ : J ≤ I) :
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(Ideal.map (algebraMap R S) J.asIdeal : Ideal S).IsPrime where
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ne_top' := by
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intro h
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rw [eq_top_iff_one, map, mem_span] at h
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mem_or_mem' := sorry
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lemma comap_lt_of_lt (J₁ J₂ : PrimeSpectrum S) (J_lt : J₁ < J₂) :
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PrimeSpectrum.comap (algebraMap R S) J₁ < PrimeSpectrum.comap (algebraMap R S) J₂ := by
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apply lt_of_le_of_ne
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apply comap_mono (le_of_lt J_lt)
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sorry
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lemma lt_of_comap_lt (J₁ J₂ : PrimeSpectrum S)
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(hJ : PrimeSpectrum.comap (algebraMap R S) J₁ < PrimeSpectrum.comap (algebraMap R S) J₂) :
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J₁ < J₂ := by
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apply lt_of_le_of_ne
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sorry
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/- If S = R_p, then height p = dim S -/
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lemma height_eq_height_comap (J : PrimeSpectrum S) :
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height (PrimeSpectrum.comap (algebraMap R S) J) = height J := by
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simp [height]
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have H : {J_1 | J_1 < (PrimeSpectrum.comap (algebraMap R S)) J} =
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(PrimeSpectrum.comap (algebraMap R S))'' {J_2 | J_2 < J}
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. sorry
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rw [H]
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apply Set.chainHeight_image
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intro x y
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constructor
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apply comap_lt_of_lt
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apply lt_of_comap_lt
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lemma disjoint_primeCompl (I : PrimeSpectrum R) :
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{ p | Disjoint (I.asIdeal.primeCompl : Set R) p.asIdeal} = {p | p ≤ I} := by
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ext p; apply Set.disjoint_compl_left_iff_subset
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theorem localizationPrime_comap_range [Algebra R S] (I : PrimeSpectrum R) [IsLocalization.AtPrime S I.asIdeal] :
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Set.range (PrimeSpectrum.comap (algebraMap R S)) = { p | p ≤ I} := by
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rw [← disjoint_primeCompl]
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apply localization_comap_range
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#check Set.chainHeight_image
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lemma height_eq_dim_localization : height I = krullDim S := by
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--first show height I = height gadslfasd'
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simp [@krullDim_eq_height _ _ (IsLocalization.AtPrime.localRing S I.asIdeal)]
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simp [height]
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let f := (PrimeSpectrum.comap (algebraMap R S))
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have H : {J | J < I} = f '' {J | J < closedPoint S}
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lemma height_eq_dim_localization' :
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height I = krullDim (Localization.AtPrime I.asIdeal) := Ideal.height_eq_dim_localization I
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end Localization
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section Polynomial
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open Ideal Polynomial
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variables {R : Type _} [CommRing R]
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variable (J : Ideal R[X])
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#check Ideal.comap C J
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--given ideals I J, I ⊔ J is their sum
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--given a in R, span {a} is the ideal generated by a
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--the map R → R[X] is C →+*
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--to show p[x] is prime, show p[x] is the kernel of the map R[x] → R → R/p
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#check RingHom.ker_isPrime
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def adj_x_map (I : Ideal R) : R[X] →+* R ⧸ I := (Ideal.Quotient.mk I).comp constantCoeff
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--def adj_x_map' (I : Ideal R) : R[X] →+* R ⧸ I := (Ideal.Quotient.mk I).comp (evalRingHom 0)
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def adjoin_x (I : Ideal R) : Ideal (Polynomial R) := RingHom.ker (adj_x_map I)
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def adjoin_x' (I : PrimeSpectrum R) : PrimeSpectrum (Polynomial R) where
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asIdeal := adjoin_x I.asIdeal
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IsPrime := RingHom.ker_isPrime _
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/- This somehow isn't in Mathlib? -/
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@[simp]
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theorem span_singleton_one : span ({0} : Set R) = ⊥ := by simp only [span_singleton_eq_bot]
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theorem coeff_C_eq : RingHom.comp constantCoeff C = RingHom.id R := by ext; simp
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variable (I : PrimeSpectrum R)
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#check RingHom.ker (C.comp (Ideal.Quotient.mk I.asIdeal))
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--#check Ideal.Quotient.mk I.asIdeal
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def map_prime' (I : PrimeSpectrum R) : IsPrime (I.asIdeal.map C) := Ideal.isPrime_map_C_of_isPrime I.IsPrime
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def map_prime'' (I : PrimeSpectrum R) : PrimeSpectrum R[X] := ⟨I.asIdeal.map C, map_prime' I⟩
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@[simp]
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lemma adj_x_comp_C (I : Ideal R) : RingHom.comp (adj_x_map I) C = Ideal.Quotient.mk I := by
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ext x; simp [adj_x_map]
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-- ideal.mem_quotient_iff_mem_sup
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lemma adjoin_x_eq (I : Ideal R) : adjoin_x I = I.map C ⊔ Ideal.span {X} := by
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apply le_antisymm
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. rintro p hp
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have h : ∃ q r, p = C r + X * q := ⟨p.divX, p.coeff 0, p.divX_mul_X_add.symm.trans $ by ring⟩
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obtain ⟨q, r, rfl⟩ := h
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suffices : r ∈ I
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. simp only [Submodule.mem_sup, Ideal.mem_span_singleton]
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refine' ⟨C r, Ideal.mem_map_of_mem C this, X * q, ⟨q, rfl⟩, rfl⟩
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rw [adjoin_x, adj_x_map, RingHom.mem_ker, RingHom.comp_apply] at hp
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rw [constantCoeff_apply, coeff_add, coeff_C_zero, coeff_X_mul_zero, add_zero] at hp
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rwa [←RingHom.mem_ker, Ideal.mk_ker] at hp
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. rw [sup_le_iff]
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constructor
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. simp [adjoin_x, RingHom.ker, ←map_le_iff_le_comap, Ideal.map_map]
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. simp [span_le, adjoin_x, RingHom.mem_ker, adj_x_map]
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lemma adjoin_x_inj {I J : Ideal R} (h : adjoin_x I = adjoin_x J) : I = J := by
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simp [adjoin_x_eq] at h
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have H : Ideal.map constantCoeff (Ideal.map C I ⊔ span {X}) =
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Ideal.map constantCoeff (Ideal.map C J ⊔ span {X}) := by rw [h]
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simp [Ideal.map_sup, Ideal.map_span, Ideal.map_map, coeff_C_eq] at H
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exact H
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lemma map_lt_adjoin_x (I : PrimeSpectrum R) : map_prime'' I < adjoin_x' I := by
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simp [map_prime'', adjoin_x', adjoin_x_eq]
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show Ideal.map C I.asIdeal < Ideal.map C I.asIdeal ⊔ span {X}
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simp [Ideal.span_le, mem_map_C_iff]
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use 1
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simp
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intro h
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apply I.IsPrime.ne_top'
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rw [Ideal.eq_top_iff_one]
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exact h
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lemma map_inj {I J : Ideal R} (h : I.map C = J.map C) : I = J := by
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have H : Ideal.map constantCoeff (Ideal.map C I) =
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Ideal.map constantCoeff (Ideal.map C J) := by rw [h]
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simp [Ideal.map_map, coeff_C_eq] at H
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exact H
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lemma map_strictmono (I J : Ideal R) (h : I < J) : I.map C < J.map C := by
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rw [lt_iff_le_and_ne] at h ⊢
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constructor
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. apply map_mono h.1
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. intro H
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exact h.2 (map_inj H)
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lemma adjoin_x_strictmono (I J : Ideal R) (h : I < J) : adjoin_x I < adjoin_x J := by
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rw [lt_iff_le_and_ne] at h ⊢
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constructor
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. rw [adjoin_x_eq, adjoin_x_eq]
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apply sup_le_sup_right
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apply map_mono h.1
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. intro H
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exact h.2 (adjoin_x_inj H)
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example (n : ℕ∞) : n + 0 = n := by simp?
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#eval List.Chain' (· < ·) [2,3]
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example : [4,5] ++ [2] = [4,5,2] := rfl
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#eval [2,4,5].map (λ n => n + n)
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/- Given an ideal p in R, define the ideal p[x] in R[x] -/
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lemma ht_adjoin_x_eq_ht_add_one [Nontrivial R] (I : PrimeSpectrum R) : height I + 1 ≤ height (adjoin_x' I) := by
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suffices H : height I + (1 : ℕ) ≤ height (adjoin_x' I) + (0 : ℕ)
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. norm_cast at H; rw [add_zero] at H; exact H
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rw [height, height, Set.chainHeight_add_le_chainHeight_add {J | J < I} _ 1 0]
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intro l hl
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use ((l.map map_prime'') ++ [map_prime'' I])
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constructor
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. simp [Set.append_mem_subchain_iff]
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refine' ⟨_,_,_⟩
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. show (List.map map_prime'' l).Chain' (· < ·) ∧ ∀ i ∈ _, i ∈ _
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constructor
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. apply List.chain'_map_of_chain' map_prime''
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intro a b hab
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apply map_strictmono a.asIdeal b.asIdeal
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exact hab
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exact hl.1
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. intro i hi
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rw [List.mem_map] at hi
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obtain ⟨a, ha, rfl⟩ := hi
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show map_prime'' a < adjoin_x' I
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calc map_prime'' a < map_prime'' I := by apply map_strictmono; apply hl.2; apply ha
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_ < adjoin_x' I := by apply map_lt_adjoin_x
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. apply map_lt_adjoin_x
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. intro a ha
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have H : ∃ b : PrimeSpectrum R, b ∈ l ∧ map_prime'' b = a
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. have H2 : l ≠ []
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. intro h
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rw [h] at ha
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tauto
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use l.getLast H2
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refine' ⟨List.getLast_mem H2, _⟩
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have H3 : l.map map_prime'' ≠ []
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. intro hl
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apply H2
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apply List.eq_nil_of_map_eq_nil hl
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rw [List.getLast?_eq_getLast _ H3, Option.some_inj] at ha
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simp [←ha, List.getLast_map _ H2]
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obtain ⟨b, hb, rfl⟩ := H
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apply map_strictmono
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apply hl.2
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exact hb
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. simp
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lemma ne_bot_iff_exists' (n : WithBot ℕ∞) : n ≠ ⊥ ↔ ∃ m : ℕ∞, n = m := by
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convert WithBot.ne_bot_iff_exists using 3
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exact comm
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lemma dim_le_dim_polynomial_add_one [Nontrivial R] :
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krullDim R + (1 : ℕ∞) ≤ krullDim (Polynomial R) := by
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cases' krullDim_nonneg_of_nontrivial R with n hn
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rw [hn]
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change ↑(n + 1) ≤ krullDim R[X]
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have hn' := le_of_eq hn.symm
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rw [le_krullDim_iff'] at hn' ⊢
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cases' hn' with I hI
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use adjoin_x' I
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apply WithBot.coe_mono
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calc n + 1 ≤ height I + 1 := by
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apply add_le_add_right
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rw [WithBot.coe_le_coe] at hI
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exact hI
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_ ≤ height (adjoin_x' I) := ht_adjoin_x_eq_ht_add_one I
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end Polynomial
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open Ideal
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variable {R : Type _} [CommRing R]
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lemma height_le_top_iff_exists {I : PrimeSpectrum R} (hI : height I ≤ ⊤) :
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∃ n : ℕ, true := by
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sorry
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lemma eq_of_height_eq_of_le {I J : PrimeSpectrum R} (I_le_J : I ≤ J) (hJ : height J < ⊤)
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(ht_eq : height I = height J) : I = J := by
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by_cases h : I = J
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. exact h
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. have I_lt_J := lt_of_le_of_ne I_le_J h
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exfalso
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sorry
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section Quotient
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variables {R : Type _} [CommRing R] (I : Ideal R)
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#check List.map <| PrimeSpectrum.comap <| Ideal.Quotient.mk I
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lemma comap_chain {l : List (PrimeSpectrum (R ⧸ I))} (hl : l.Chain' (· < ·)) :
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List.Chain' (. < .) ((List.map <| PrimeSpectrum.comap <| Ideal.Quotient.mk I) l) := by
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lemma dim_quotient_le_dim : krullDim (R ⧸ I) ≤ krullDim R := by
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end Quotient
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