new: Added the more advanced examples

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Sayantan Santra 2024-02-06 01:19:20 -06:00
parent eb673e816c
commit 5b38350326
Signed by: SinTan1729
GPG key ID: EB3E68BFBA25C85F
3 changed files with 384 additions and 0 deletions

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-- This module serves as the root of the `«LeanTalkSP24»` library. -- This module serves as the root of the `«LeanTalkSP24»` library.
-- Import modules here that should be built as part of the library. -- Import modules here that should be built as part of the library.
import «LeanTalkSP24».basics import «LeanTalkSP24».basics
import «LeanTalkSP24».infinitely_many_primes
import «LeanTalkSP24».polynomial_over_field_dim_one

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import Mathlib.Data.Nat.Prime
import Mathlib.Algebra.BigOperators.Order
import Mathlib.Tactic
import Mathlib.Tactic.IntervalCases
open BigOperators
theorem two_le {m : } (h0 : m ≠ 0) (h1 : m ≠ 1) : 2 ≤ m := by
have : m > 0 := Nat.pos_of_ne_zero h0
have : m >= 1 := this
have h1 : 1 ≠ m := Ne.symm h1
change ¬_ = _ at h1
have : m > 1 := Nat.lt_of_le_of_ne this h1
exact this
theorem exists_prime_factor {n : Nat} (h : 2 ≤ n) : ∃ p : Nat, p.Prime ∧ p n := by
by_cases np : n.Prime
· use n, np
induction' n using Nat.strong_induction_on with n ih
rw [Nat.prime_def_lt] at np
push_neg at np
rcases np h with ⟨m, mltn, mdvdn, mne1⟩
have : m ≠ 0 := by
intro mz
rw [mz, zero_dvd_iff] at mdvdn
linarith
have mgt2 : 2 ≤ m := two_le this mne1
by_cases mp : m.Prime
· use m, mp
. rcases ih m mltn mgt2 mp with ⟨p, pp, pdvd⟩
use p, pp
apply pdvd.trans mdvdn
theorem primes_infinite : ∀ n, ∃ p > n, Nat.Prime p := by
intro n
have : 2 ≤ Nat.factorial (n + 1) + 1 := by
apply Nat.succ_le_succ
apply Nat.succ_le_of_lt
apply Nat.factorial_pos
rcases exists_prime_factor this with ⟨p, pp, pdvd⟩
refine' ⟨p, _, pp⟩
show p > n
by_contra ple
push_neg at ple
have : p Nat.factorial (n + 1) := by
apply Nat.dvd_factorial
apply pp.pos
linarith
have : p 1 := by
convert Nat.dvd_sub' pdvd this
simp
show False
have ple1 : p ≤ 1 := Nat.le_of_dvd (Nat.lt_succ_self 0) this
have plt1 : p > 1 := pp.one_lt
linarith
open Finset
section
variable {α : Type _} [DecidableEq α] (r s t : Finset α)
example : r ∩ (s t) ⊆ r ∩ s r ∩ t := by
rw [subset_iff]
intro x
rw [mem_inter, mem_union, mem_union, mem_inter, mem_inter]
tauto
example : r ∩ (s t) ⊆ r ∩ s r ∩ t := by
simp [subset_iff]
intro x
tauto
example : r ∩ s r ∩ t ⊆ r ∩ (s t) := by
simp [subset_iff]
intro x
tauto
example : r ∩ s r ∩ t = r ∩ (s t) := by
ext x
simp
tauto
end
theorem _root_.Nat.Prime.eq_of_dvd_of_prime {p q : }
(prime_p : Nat.Prime p) (prime_q : Nat.Prime q) (h : p q) :
p = q := by
cases prime_q.eq_one_or_self_of_dvd _ h
· linarith [prime_p.two_le]
assumption
theorem mem_of_dvd_prod_primes {s : Finset } {p : } (prime_p : p.Prime) :
(∀ n ∈ s, Nat.Prime n) → (p ∏ n in s, n) → p ∈ s := by
intro h₀ h₁
induction' s using Finset.induction_on with a s ans ih
· simp at h₁
linarith [prime_p.two_le]
simp [Finset.prod_insert ans, prime_p.dvd_mul] at h₀ h₁
rw [mem_insert]
cases' h₁ with h₁ h₁
· left
exact prime_p.eq_of_dvd_of_prime h₀.1 h₁
right
exact ih h₀.2 h₁
theorem primes_infinite' : ∀ s : Finset Nat, ∃ p, Nat.Prime p ∧ p ∉ s := by
intro s
by_contra h
push_neg at h
set s' := s.filter Nat.Prime with s'_def
have mem_s' : ∀ {n : }, n ∈ s' ↔ n.Prime := by
intro n
simp [s'_def]
apply h
have : 2 ≤ (∏ i in s', i) + 1 := by
apply Nat.succ_le_succ
apply Nat.succ_le_of_lt
apply Finset.prod_pos
intro n ns'
apply (mem_s'.mp ns').pos
rcases exists_prime_factor this with ⟨p, pp, pdvd⟩
have : p ∏ i in s', i := by
apply dvd_prod_of_mem
rw [mem_s']
apply pp
have : p 1 := by
convert Nat.dvd_sub' pdvd this
simp
show False
have := Nat.le_of_dvd zero_lt_one this
linarith [pp.two_le]
theorem bounded_of_ex_finset (Q : → Prop) :
(∃ s : Finset , ∀ k, Q k → k ∈ s) → ∃ n, ∀ k, Q k → k < n := by
rintro ⟨s, hs⟩
use s.sup id + 1
intro k Qk
apply Nat.lt_succ_of_le
show id k ≤ s.sup id
apply le_sup (hs k Qk)
theorem ex_finset_of_bounded (Q : → Prop) [DecidablePred Q] :
(∃ n, ∀ k, Q k → k ≤ n) → ∃ s : Finset , ∀ k, Q k ↔ k ∈ s := by
rintro ⟨n, hn⟩
use (range (n + 1)).filter Q
intro k
simp [Nat.lt_succ_iff]
exact hn k
theorem mod_4_eq_3_or_mod_4_eq_3 {m n : } (h : m * n % 4 = 3) : m % 4 = 3 n % 4 = 3 := by
revert h
rw [Nat.mul_mod]
have : m % 4 < 4 := Nat.mod_lt m (by norm_num)
interval_cases hm : m % 4 <;> simp [hm]
have : n % 4 < 4 := Nat.mod_lt n (by norm_num)
interval_cases hn : n % 4 <;> simp [hn]
theorem two_le_of_mod_4_eq_3 {n : } (h : n % 4 = 3) : 2 ≤ n := by
apply two_le <;>
· intro neq
rw [neq] at h
norm_num at h
theorem aux {m n : } (h₀ : m n) (h₁ : 2 ≤ m) (h₂ : m < n) : n / m n ∧ n / m < n := by
constructor
· exact Nat.div_dvd_of_dvd h₀
exact Nat.div_lt_self (lt_of_le_of_lt (zero_le _) h₂) h₁
theorem exists_prime_factor_mod_4_eq_3 {n : Nat} (h : n % 4 = 3) :
∃ p : Nat, p.Prime ∧ p n ∧ p % 4 = 3 := by
by_cases np : n.Prime
· use n
induction' n using Nat.strong_induction_on with n ih
rw [Nat.prime_def_lt] at np
push_neg at np
rcases np (two_le_of_mod_4_eq_3 h) with ⟨m, mltn, mdvdn, mne1⟩
have mge2 : 2 ≤ m := by
apply two_le _ mne1
intro mz
rw [mz, zero_dvd_iff] at mdvdn
linarith
have neq : m * (n / m) = n := Nat.mul_div_cancel' mdvdn
have : m % 4 = 3 n / m % 4 = 3 := by
apply mod_4_eq_3_or_mod_4_eq_3
rw [neq, h]
cases' this with h1 h1
· by_cases mp : m.Prime
· use m
rcases ih m mltn h1 mp with ⟨p, pp, pdvd, p4eq⟩
use p
exact ⟨pp, pdvd.trans mdvdn, p4eq⟩
obtain ⟨nmdvdn, nmltn⟩ := aux mdvdn mge2 mltn
by_cases nmp : (n / m).Prime
· use n / m
rcases ih (n / m) nmltn h1 nmp with ⟨p, pp, pdvd, p4eq⟩
use p
exact ⟨pp, pdvd.trans nmdvdn, p4eq⟩
theorem primes_mod_4_eq_3_infinite : ∀ n, ∃ p > n, Nat.Prime p ∧ p % 4 = 3 := by
by_contra h
push_neg at h
cases' h with n hn
have : ∃ s : Finset Nat, ∀ p : , p.Prime ∧ p % 4 = 3 ↔ p ∈ s := by
apply ex_finset_of_bounded
use n
contrapose! hn
rcases hn with ⟨p, ⟨pp, p4⟩, pltn⟩
exact ⟨p, pltn, pp, p4⟩
cases' this with s hs
have h₁ : ((4 * ∏ i in erase s 3, i) + 3) % 4 = 3 := by
rw [add_comm, Nat.add_mul_mod_self_left]
norm_num
rcases exists_prime_factor_mod_4_eq_3 h₁ with ⟨p, pp, pdvd, p4eq⟩
have ps : p ∈ s := by
rw [← hs p]
exact ⟨pp, p4eq⟩
have pne3 : p ≠ 3 := by
intro peq
rw [peq, ← Nat.dvd_add_iff_left (dvd_refl 3)] at pdvd
rw [Nat.prime_three.dvd_mul] at pdvd
norm_num at pdvd
have : 3 ∈ s.erase 3 := by
apply mem_of_dvd_prod_primes Nat.prime_three _ pdvd
intro n
simp [← hs n]
tauto
simp at this
have : p 4 * ∏ i in erase s 3, i := by
apply dvd_trans _ (dvd_mul_left _ _)
apply dvd_prod_of_mem
simp
constructor <;> assumption
have : p 3 := by
convert Nat.dvd_sub' pdvd this
simp
have : p = 3 := by
apply pp.eq_of_dvd_of_prime Nat.prime_three this
contradiction

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import Mathlib.RingTheory.Ideal.Operations
import Mathlib.Order.Height
import Mathlib.RingTheory.PrincipalIdealDomain
import Mathlib.RingTheory.DedekindDomain.Basic
import Mathlib.AlgebraicGeometry.PrimeSpectrum.Basic
namespace Ideal
namespace Ideal
open LocalRing
variable {R : Type _} [CommRing R] (I : PrimeSpectrum R)
/-- Definitions -/
noncomputable def height : ℕ∞ := Set.chainHeight {J : PrimeSpectrum R | J < I}
noncomputable def krullDim (R : Type _) [CommRing R] : WithBot ℕ∞ := ⨆ (I : PrimeSpectrum R), height I
noncomputable def codimension (J : Ideal R) : WithBot ℕ∞ := ⨅ I ∈ {I : PrimeSpectrum R | J ≤ I.asIdeal}, height I
lemma height_def : height I = Set.chainHeight {J : PrimeSpectrum R | J < I} := rfl
lemma krullDim_def (R : Type _) [CommRing R] : krullDim R = (⨆ (I : PrimeSpectrum R), height I : WithBot ℕ∞) := rfl
lemma krullDim_def' (R : Type _) [CommRing R] : krullDim R = iSup (λ I : PrimeSpectrum R => (height I : WithBot ℕ∞)) := rfl
/-- A lattice structure on WithBot ℕ∞. -/
noncomputable instance : CompleteLattice (WithBot (ℕ∞)) := WithBot.WithTop.completeLattice
/-- Singleton sets have chainHeight 1 -/
lemma singleton_chainHeight_one {α : Type _} {x : α} [Preorder α] : Set.chainHeight {x} = 1 := by
have le : Set.chainHeight {x} ≤ 1 := by
unfold Set.chainHeight
simp only [iSup_le_iff, Nat.cast_le_one]
intro L h
unfold Set.subchain at h
simp only [Set.mem_singleton_iff, Set.mem_setOf_eq] at h
rcases L with (_ | ⟨a,L⟩)
. simp only [List.length_nil, zero_le]
rcases L with (_ | ⟨b,L⟩)
. simp only [List.length_singleton, le_refl]
simp only [List.chain'_cons, List.find?, List.mem_cons, forall_eq_or_imp] at h
rcases h with ⟨⟨h1, _⟩, ⟨rfl, rfl, _⟩⟩
exact absurd h1 (lt_irrefl _)
suffices : Set.chainHeight {x} > 0
· change _ < _ at this
rw [←ENat.one_le_iff_pos] at this
apply le_antisymm <;> trivial
by_contra x
simp only [gt_iff_lt, not_lt, nonpos_iff_eq_zero, Set.chainHeight_eq_zero_iff, Set.singleton_ne_empty] at x
/-- In a domain, the height of a prime ideal is Bot (0 in this case) iff it's the Bot ideal. -/
@[simp]
lemma height_zero_iff_bot {D: Type _} [CommRing D] [IsDomain D] {P : PrimeSpectrum D} : height P = 0 ↔ P = ⊥ := by
constructor
· intro h
unfold height at h
simp only [Set.chainHeight_eq_zero_iff] at h
apply eq_bot_of_minimal
intro I
by_contra x
have : I ∈ {J | J < P} := x
rw [h] at this
contradiction
· intro h
unfold height
simp only [bot_eq_zero', Set.chainHeight_eq_zero_iff]
by_contra spec
change _ ≠ _ at spec
rw [← Set.nonempty_iff_ne_empty] at spec
obtain ⟨J, JlP : J < P⟩ := spec
have JneP : J ≠ P := ne_of_lt JlP
rw [h, ←bot_lt_iff_ne_bot, ←h] at JneP
have := not_lt_of_lt JneP
contradiction
/-- The ring of polynomials over a field has dimension one. -/
-- It's the exact same lemma as in krull.lean, added ' to avoid conflict
lemma polynomial_over_field_dim_one {K : Type} [Nontrivial K] [Field K] : krullDim (Polynomial K) = 1 := by
rw [le_antisymm_iff]
let X := @Polynomial.X K _
constructor
· unfold krullDim
apply @iSup_le (WithBot ℕ∞) _ _ _ _
intro I
have PIR : IsPrincipalIdealRing (Polynomial K) := by infer_instance
by_cases h: I = ⊥
· rw [← height_zero_iff_bot] at h
simp only [WithBot.coe_le_one, ge_iff_le]
rw [h]
exact bot_le
· push_neg at h
have : I.asIdeal ≠ ⊥ := by
by_contra a
have : I = ⊥ := PrimeSpectrum.ext I ⊥ a
contradiction
have maxI := IsPrime.to_maximal_ideal this
have sngletn : ∀P, P ∈ {J | J < I} ↔ P = ⊥ := by
intro P
constructor
· intro H
simp only [Set.mem_setOf_eq] at H
by_contra x
push_neg at x
have : P.asIdeal ≠ ⊥ := by
by_contra a
have : P = ⊥ := PrimeSpectrum.ext P ⊥ a
contradiction
have maxP := IsPrime.to_maximal_ideal this
have IneTop := IsMaximal.ne_top maxI
have : P ≤ I := le_of_lt H
rw [←PrimeSpectrum.asIdeal_le_asIdeal] at this
have : P.asIdeal = I.asIdeal := Ideal.IsMaximal.eq_of_le maxP IneTop this
have : P = I := PrimeSpectrum.ext P I this
replace H : P ≠ I := ne_of_lt H
contradiction
· intro pBot
simp only [Set.mem_setOf_eq, pBot]
exact lt_of_le_of_ne bot_le h.symm
replace sngletn : {J | J < I} = {⊥} := Set.ext sngletn
unfold height
rw [sngletn]
simp only [WithBot.coe_le_one, ge_iff_le]
exact le_of_eq singleton_chainHeight_one
· suffices : ∃I : PrimeSpectrum (Polynomial K), 1 ≤ (height I : WithBot ℕ∞)
· obtain ⟨I, h⟩ := this
have : (height I : WithBot ℕ∞) ≤ ⨆ (I : PrimeSpectrum (Polynomial K)), ↑(height I) := by
apply @le_iSup (WithBot ℕ∞) _ _ _ I
exact le_trans h this
have primeX : Prime Polynomial.X := @Polynomial.prime_X K _ _
have : IsPrime (span {X}) := by
refine (span_singleton_prime ?hp).mpr primeX
exact Polynomial.X_ne_zero
let P := PrimeSpectrum.mk (span {X}) this
unfold height
use P
have : ⊥ ∈ {J | J < P} := by
simp only [Set.mem_setOf_eq, bot_lt_iff_ne_bot]
suffices : P.asIdeal ≠ ⊥
· by_contra x
rw [PrimeSpectrum.ext_iff] at x
contradiction
by_contra x
simp only [span_singleton_eq_bot] at x
have := @Polynomial.X_ne_zero K _ _
contradiction
have : {J | J < P}.Nonempty := Set.nonempty_of_mem this
rwa [←Set.one_le_chainHeight_iff, ←WithBot.one_le_coe] at this