Split (1)

train · 219k rows

url stringclasses 147 values	commit stringclasses 147 values	file_path stringlengths 7 101	full_name stringlengths 1 94	start stringlengths 6 10	end stringlengths 6 11	tactic stringlengths 1 11.2k	state_before stringlengths 3 2.09M	state_after stringlengths 6 2.09M	input stringlengths 73 2.09M
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isPathConnected_potential_levelset	[36, 1]	[48, 76]	exact ep	case h.mpr c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) p : ℝ p0 : 0 ≤ p p1 : p < 1 c : 𝕊 e : ℂ ep : Complex.abs e = p ec : ray d e = c ⊢ Complex.abs e = p case h.mpr c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) p : ℝ p0 : 0 ≤ p p1 : p < 1 c : 𝕊 e : ℂ ep : Complex.abs e = p ec : ray d e = c ⊢ e ∈ ball 0 1	case h.mpr c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) p : ℝ p0 : 0 ≤ p p1 : p < 1 c : 𝕊 e : ℂ ep : Complex.abs e = p ec : ray d e = c ⊢ e ∈ ball 0 1	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) p : ℝ p0 : 0 ≤ p p1 : p < 1 c : 𝕊 e : ℂ ep : Complex.abs e = p ec : ray d e = c ⊢ Complex.abs e = p case h.mpr c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) p : ℝ p0 : 0 ≤ p p1 : p < 1 c : 𝕊 e : ℂ ep : Complex.abs e = p ec : ray d e = c ⊢ e ∈ ball 0 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isPathConnected_potential_levelset	[36, 1]	[48, 76]	simp only [mem_ball, Complex.dist_eq, sub_zero, ep, p1]	case h.mpr c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) p : ℝ p0 : 0 ≤ p p1 : p < 1 c : 𝕊 e : ℂ ep : Complex.abs e = p ec : ray d e = c ⊢ e ∈ ball 0 1	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c✝ : ℂ d : ℕ inst✝ : Fact (2 ≤ d) p : ℝ p0 : 0 ≤ p p1 : p < 1 c : 𝕊 e : ℂ ep : Complex.abs e = p ec : ray d e = c ⊢ e ∈ ball 0 1 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	refine ⟨⟨((0 : ℂ) : 𝕊),?_⟩,?_⟩	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsConnected (multibrotExt d)ᶜ	case refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑0 ∈ (multibrotExt d)ᶜ case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d)ᶜ	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsConnected (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	have e : (multibrotExt d)ᶜ = ⋂ p : Ico 0 (1 : ℝ), potential d ⁻¹' Ici p := by apply Set.ext; intro z simp only [mem_compl_iff, ← potential_lt_one, mem_iInter, mem_preimage, not_lt, mem_Ici] constructor; intro p1 ⟨q, m⟩; simp only [Subtype.coe_mk, mem_Ico] at m ⊢; linarith intro h; contrapose h; simp only [not_le, not_forall] at h ⊢ rcases exists_between h with ⟨y, py, y1⟩ exact ⟨⟨y, ⟨le_trans potential_nonneg py.le, y1⟩⟩, py⟩	case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d)ᶜ	case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ IsPreconnected (multibrotExt d)ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	rw [e]	case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ IsPreconnected (multibrotExt d)ᶜ	case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ IsPreconnected (⋂ p, potential d ⁻¹' Ici ↑p)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ IsPreconnected (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	refine @IsPreconnected.directed_iInter _ _ _ _ ?_ _ ?_ ?_ ?_	case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ IsPreconnected (⋂ p, potential d ⁻¹' Ici ↑p)	case refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ Nonempty ↑(Ico 0 1) case refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ Directed Superset fun p => potential d ⁻¹' Ici ↑p case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ ∀ (a : ↑(Ico 0 1)), IsPreconnected (potential d ⁻¹' Ici ↑a) case refine_2.refine_4 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ ∀ (a : ↑(Ico 0 1)), IsCompact (potential d ⁻¹' Ici ↑a)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ IsPreconnected (⋂ p, potential d ⁻¹' Ici ↑p) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	simp only [mem_compl_iff, multibrotExt_coe, not_not, multibrot_zero]	case refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑0 ∈ (multibrotExt d)ᶜ	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑0 ∈ (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	apply Set.ext	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ∀ (x : 𝕊), x ∈ (multibrotExt d)ᶜ ↔ x ∈ ⋂ p, potential d ⁻¹' Ici ↑p	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro z	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ∀ (x : 𝕊), x ∈ (multibrotExt d)ᶜ ↔ x ∈ ⋂ p, potential d ⁻¹' Ici ↑p	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ z ∈ (multibrotExt d)ᶜ ↔ z ∈ ⋂ p, potential d ⁻¹' Ici ↑p	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ∀ (x : 𝕊), x ∈ (multibrotExt d)ᶜ ↔ x ∈ ⋂ p, potential d ⁻¹' Ici ↑p TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	simp only [mem_compl_iff, ← potential_lt_one, mem_iInter, mem_preimage, not_lt, mem_Ici]	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ z ∈ (multibrotExt d)ᶜ ↔ z ∈ ⋂ p, potential d ⁻¹' Ici ↑p	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ 1 ≤ potential d z ↔ ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ z ∈ (multibrotExt d)ᶜ ↔ z ∈ ⋂ p, potential d ⁻¹' Ici ↑p TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	constructor	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ 1 ≤ potential d z ↔ ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ 1 ≤ potential d z → ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ 1 ≤ potential d z ↔ ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro p1 ⟨q, m⟩	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ 1 ≤ potential d z → ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 p1 : 1 ≤ potential d z q : ℝ m : q ∈ Ico 0 1 ⊢ ↑⟨q, m⟩ ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ 1 ≤ potential d z → ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	simp only [Subtype.coe_mk, mem_Ico] at m ⊢	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 p1 : 1 ≤ potential d z q : ℝ m : q ∈ Ico 0 1 ⊢ ↑⟨q, m⟩ ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 p1 : 1 ≤ potential d z q : ℝ m : 0 ≤ q ∧ q < 1 ⊢ q ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 p1 : 1 ≤ potential d z q : ℝ m : q ∈ Ico 0 1 ⊢ ↑⟨q, m⟩ ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	linarith	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 p1 : 1 ≤ potential d z q : ℝ m : 0 ≤ q ∧ q < 1 ⊢ q ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 p1 : 1 ≤ potential d z q : ℝ m : 0 ≤ q ∧ q < 1 ⊢ q ≤ potential d z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro h	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z ⊢ 1 ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 ⊢ (∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z) → 1 ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	contrapose h	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z ⊢ 1 ≤ potential d z	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : ¬1 ≤ potential d z ⊢ ¬∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : ∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z ⊢ 1 ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	simp only [not_le, not_forall] at h ⊢	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : ¬1 ≤ potential d z ⊢ ¬∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : potential d z < 1 ⊢ ∃ x, potential d z < ↑x	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : ¬1 ≤ potential d z ⊢ ¬∀ (i : ↑(Ico 0 1)), ↑i ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	rcases exists_between h with ⟨y, py, y1⟩	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : potential d z < 1 ⊢ ∃ x, potential d z < ↑x	case h.mpr.intro.intro c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : potential d z < 1 y : ℝ py : potential d z < y y1 : y < 1 ⊢ ∃ x, potential d z < ↑x	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : potential d z < 1 ⊢ ∃ x, potential d z < ↑x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact ⟨⟨y, ⟨le_trans potential_nonneg py.le, y1⟩⟩, py⟩	case h.mpr.intro.intro c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : potential d z < 1 y : ℝ py : potential d z < y y1 : y < 1 ⊢ ∃ x, potential d z < ↑x	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.intro.intro c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : 𝕊 h : potential d z < 1 y : ℝ py : potential d z < y y1 : y < 1 ⊢ ∃ x, potential d z < ↑x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact Zero.instNonempty	case refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ Nonempty ↑(Ico 0 1)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ Nonempty ↑(Ico 0 1) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro ⟨a, a0, a1⟩ ⟨b, b0, b1⟩	case refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ Directed Superset fun p => potential d ⁻¹' Ici ↑p	case refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ ∃ z, (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) z ∧ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) z	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ Directed Superset fun p => potential d ⁻¹' Ici ↑p TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	refine ⟨⟨max a b, mem_Ico.mpr ⟨le_max_of_le_left a0, max_lt a1 b1⟩⟩, ?_, ?_⟩	case refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ ∃ z, (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) z ∧ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) z	case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ ∃ z, (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) z ∧ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro z h	case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩	case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ ⊢ z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	simp only [mem_preimage, mem_Ici, Subtype.coe_mk, max_le_iff] at h ⊢	case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ ⊢ z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩	case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : a ≤ potential d z ∧ b ≤ potential d z ⊢ a ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ ⊢ z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨a, ⋯⟩ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact h.1	case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : a ≤ potential d z ∧ b ≤ potential d z ⊢ a ≤ potential d z	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2.refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : a ≤ potential d z ∧ b ≤ potential d z ⊢ a ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro z h	case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩	case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ ⊢ z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 ⊢ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩ ⊇ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	simp only [mem_preimage, mem_Ici, Subtype.coe_mk, max_le_iff] at h ⊢	case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ ⊢ z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩	case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : a ≤ potential d z ∧ b ≤ potential d z ⊢ b ≤ potential d z	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨max a b, ⋯⟩ ⊢ z ∈ (fun p => potential d ⁻¹' Ici ↑p) ⟨b, ⋯⟩ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact h.2	case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : a ≤ potential d z ∧ b ≤ potential d z ⊢ b ≤ potential d z	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_2.refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p a : ℝ a0 : 0 ≤ a a1 : a < 1 b : ℝ b0 : 0 ≤ b b1 : b < 1 z : 𝕊 h : a ≤ potential d z ∧ b ≤ potential d z ⊢ b ≤ potential d z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro ⟨p, m⟩	case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ ∀ (a : ↑(Ico 0 1)), IsPreconnected (potential d ⁻¹' Ici ↑a)	case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPreconnected (potential d ⁻¹' Ici ↑⟨p, m⟩)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ ∀ (a : ↑(Ico 0 1)), IsPreconnected (potential d ⁻¹' Ici ↑a) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	simp only [Subtype.coe_mk]	case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPreconnected (potential d ⁻¹' Ici ↑⟨p, m⟩)	case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPreconnected (potential d ⁻¹' Ici p)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPreconnected (potential d ⁻¹' Ici ↑⟨p, m⟩) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	refine IsConnected.isPreconnected (IsPathConnected.isConnected ?_)	case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPreconnected (potential d ⁻¹' Ici p)	case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' Ici p)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPreconnected (potential d ⁻¹' Ici p) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	apply IsPathConnected.of_frontier	case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' Ici p)	case refine_2.refine_3.pc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' frontier (Ici p)) case refine_2.refine_3.fc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ Continuous (potential d) case refine_2.refine_3.sc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsClosed (Ici p)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' Ici p) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	rw [frontier_Ici]	case refine_2.refine_3.pc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' frontier (Ici p))	case refine_2.refine_3.pc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' {p})	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3.pc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' frontier (Ici p)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact isPathConnected_potential_levelset _ m.1 m.2	case refine_2.refine_3.pc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' {p})	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3.pc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsPathConnected (potential d ⁻¹' {p}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact potential_continuous	case refine_2.refine_3.fc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ Continuous (potential d)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3.fc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ Continuous (potential d) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact isClosed_Ici	case refine_2.refine_3.sc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsClosed (Ici p)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_3.sc c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsClosed (Ici p) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	intro ⟨p, m⟩	case refine_2.refine_4 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ ∀ (a : ↑(Ico 0 1)), IsCompact (potential d ⁻¹' Ici ↑a)	case refine_2.refine_4 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsCompact (potential d ⁻¹' Ici ↑⟨p, m⟩)	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_4 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p ⊢ ∀ (a : ↑(Ico 0 1)), IsCompact (potential d ⁻¹' Ici ↑a) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrotExt	[52, 1]	[74, 79]	exact (isClosed_Ici.preimage potential_continuous).isCompact	case refine_2.refine_4 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsCompact (potential d ⁻¹' Ici ↑⟨p, m⟩)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2.refine_4 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : (multibrotExt d)ᶜ = ⋂ p, potential d ⁻¹' Ici ↑p p : ℝ m : p ∈ Ico 0 1 ⊢ IsCompact (potential d ⁻¹' Ici ↑⟨p, m⟩) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	rw [e]	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ IsConnected (multibrot d)	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ IsConnected ((fun z => z.toComplex) '' (multibrotExt d)ᶜ)	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ IsConnected (multibrot d) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	apply (isConnected_compl_multibrotExt d).image	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ IsConnected ((fun z => z.toComplex) '' (multibrotExt d)ᶜ)	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ ContinuousOn (fun z => z.toComplex) (multibrotExt d)ᶜ	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ IsConnected ((fun z => z.toComplex) '' (multibrotExt d)ᶜ) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	refine continuousOn_toComplex.mono ?_	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ ContinuousOn (fun z => z.toComplex) (multibrotExt d)ᶜ	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ (multibrotExt d)ᶜ ⊆ {∞}ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ ContinuousOn (fun z => z.toComplex) (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	intro z m	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ (multibrotExt d)ᶜ ⊆ {∞}ᶜ	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z ∈ (multibrotExt d)ᶜ ⊢ z ∈ {∞}ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ ⊢ (multibrotExt d)ᶜ ⊆ {∞}ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	contrapose m	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z ∈ (multibrotExt d)ᶜ ⊢ z ∈ {∞}ᶜ	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z ∉ {∞}ᶜ ⊢ z ∉ (multibrotExt d)ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z ∈ (multibrotExt d)ᶜ ⊢ z ∈ {∞}ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	simp only [mem_compl_iff, mem_singleton_iff, not_not] at m	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z ∉ {∞}ᶜ ⊢ z ∉ (multibrotExt d)ᶜ	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z = ∞ ⊢ z ∉ (multibrotExt d)ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z ∉ {∞}ᶜ ⊢ z ∉ (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	simp only [m, not_mem_compl_iff, multibrotExt_inf]	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z = ∞ ⊢ z ∉ (multibrotExt d)ᶜ	no goals	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) e : multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ z : 𝕊 m : z = ∞ ⊢ z ∉ (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	apply Set.ext	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ∀ (x : ℂ), x ∈ multibrot d ↔ x ∈ (fun z => z.toComplex) '' (multibrotExt d)ᶜ	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ multibrot d = (fun z => z.toComplex) '' (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	intro z	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ∀ (x : ℂ), x ∈ multibrot d ↔ x ∈ (fun z => z.toComplex) '' (multibrotExt d)ᶜ	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d ↔ z ∈ (fun z => z.toComplex) '' (multibrotExt d)ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ∀ (x : ℂ), x ∈ multibrot d ↔ x ∈ (fun z => z.toComplex) '' (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	simp only [mem_image, mem_compl_iff]	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d ↔ z ∈ (fun z => z.toComplex) '' (multibrotExt d)ᶜ	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d ↔ ∃ x ∉ multibrotExt d, x.toComplex = z	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d ↔ z ∈ (fun z => z.toComplex) '' (multibrotExt d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	constructor	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d ↔ ∃ x ∉ multibrotExt d, x.toComplex = z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d → ∃ x ∉ multibrotExt d, x.toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d ↔ ∃ x ∉ multibrotExt d, x.toComplex = z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	intro m	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d → ∃ x ∉ multibrotExt d, x.toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : z ∈ multibrot d ⊢ ∃ x ∉ multibrotExt d, x.toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ z ∈ multibrot d → ∃ x ∉ multibrotExt d, x.toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	use z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : z ∈ multibrot d ⊢ ∃ x ∉ multibrotExt d, x.toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : z ∈ multibrot d ⊢ ↑z ∉ multibrotExt d ∧ (↑z).toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : z ∈ multibrot d ⊢ ∃ x ∉ multibrotExt d, x.toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	simp only [multibrotExt_coe, not_not, m, toComplex_coe, true_and_iff, eq_self_iff_true]	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : z ∈ multibrot d ⊢ ↑z ∉ multibrotExt d ∧ (↑z).toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : z ∈ multibrot d ⊢ ↑z ∉ multibrotExt d ∧ (↑z).toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	intro ⟨w, m, wz⟩	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ w : 𝕊 m : w ∉ multibrotExt d wz : w.toComplex = z ⊢ z ∈ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ ⊢ (∃ x ∉ multibrotExt d, x.toComplex = z) → z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	induction w using OnePoint.rec	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ w : 𝕊 m : w ∉ multibrotExt d wz : w.toComplex = z ⊢ z ∈ multibrot d	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : ∞ ∉ multibrotExt d wz : ∞.toComplex = z ⊢ z ∈ multibrot d case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z x✝ : ℂ m : ↑x✝ ∉ multibrotExt d wz : (↑x✝).toComplex = z ⊢ z ∈ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ w : 𝕊 m : w ∉ multibrotExt d wz : w.toComplex = z ⊢ z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	contrapose m	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : ∞ ∉ multibrotExt d wz : ∞.toComplex = z ⊢ z ∈ multibrot d	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ wz : ∞.toComplex = z m : ¬z ∈ multibrot d ⊢ ¬∞ ∉ multibrotExt d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ m : ∞ ∉ multibrotExt d wz : ∞.toComplex = z ⊢ z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	clear m	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ wz : ∞.toComplex = z m : ¬z ∈ multibrot d ⊢ ¬∞ ∉ multibrotExt d	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ wz : ∞.toComplex = z ⊢ ¬∞ ∉ multibrotExt d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ wz : ∞.toComplex = z m : ¬z ∈ multibrot d ⊢ ¬∞ ∉ multibrotExt d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	simp only [not_not, multibrotExt_inf]	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ wz : ∞.toComplex = z ⊢ ¬∞ ∉ multibrotExt d	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z : ℂ wz : ∞.toComplex = z ⊢ ¬∞ ∉ multibrotExt d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	simp only [multibrotExt_coe, not_not, toComplex_coe] at m wz	case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z x✝ : ℂ m : ↑x✝ ∉ multibrotExt d wz : (↑x✝).toComplex = z ⊢ z ∈ multibrot d	case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z x✝ : ℂ wz : x✝ = z m : x✝ ∈ multibrot d ⊢ z ∈ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z x✝ : ℂ m : ↑x✝ ∉ multibrotExt d wz : (↑x✝).toComplex = z ⊢ z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_multibrot	[77, 1]	[89, 53]	rwa [← wz]	case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z x✝ : ℂ wz : x✝ = z m : x✝ ∈ multibrot d ⊢ z ∈ multibrot d	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) z x✝ : ℂ wz : x✝ = z m : x✝ ∈ multibrot d ⊢ z ∈ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	rw [e]	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ IsConnected (multibrot d)ᶜ	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ IsConnected ((fun z => z.toComplex) '' (multibrotExt d \ {∞}))	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ IsConnected (multibrot d)ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	apply dc.image	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ IsConnected ((fun z => z.toComplex) '' (multibrotExt d \ {∞}))	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ ContinuousOn (fun z => z.toComplex) (multibrotExt d \ {∞})	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ IsConnected ((fun z => z.toComplex) '' (multibrotExt d \ {∞})) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	refine continuousOn_toComplex.mono ?_	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ ContinuousOn (fun z => z.toComplex) (multibrotExt d \ {∞})	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ multibrotExt d \ {∞} ⊆ {∞}ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ ContinuousOn (fun z => z.toComplex) (multibrotExt d \ {∞}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	intro z ⟨_, i⟩	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ multibrotExt d \ {∞} ⊆ {∞}ᶜ	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) z : 𝕊 left✝ : z ∈ multibrotExt d i : z ∉ {∞} ⊢ z ∈ {∞}ᶜ	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) ⊢ multibrotExt d \ {∞} ⊆ {∞}ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	simp only [mem_singleton_iff, mem_compl_iff] at i ⊢	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) z : 𝕊 left✝ : z ∈ multibrotExt d i : z ∉ {∞} ⊢ z ∈ {∞}ᶜ	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) z : 𝕊 left✝ : z ∈ multibrotExt d i : ¬z = ∞ ⊢ ¬z = ∞	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) z : 𝕊 left✝ : z ∈ multibrotExt d i : z ∉ {∞} ⊢ z ∈ {∞}ᶜ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	exact i	case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) z : 𝕊 left✝ : z ∈ multibrotExt d i : ¬z = ∞ ⊢ ¬z = ∞	no goals	Please generate a tactic in lean4 to solve the state. STATE: case hf c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) e : (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) z : 𝕊 left✝ : z ∈ multibrotExt d i : ¬z = ∞ ⊢ ¬z = ∞ TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	refine ⟨⟨(((3 : ℝ) : ℂ) : 𝕊),?_⟩,?_⟩	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsConnected (multibrotExt d \ {∞})	case refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∈ multibrotExt d \ {∞} case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d \ {∞})	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsConnected (multibrotExt d \ {∞}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	constructor	case refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∈ multibrotExt d \ {∞} case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d \ {∞})	case refine_1.left c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∈ multibrotExt d case refine_1.right c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∉ {∞} case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d \ {∞})	Please generate a tactic in lean4 to solve the state. STATE: case refine_1 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∈ multibrotExt d \ {∞} case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d \ {∞}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	simp only [multibrotExt_coe, mem_compl_iff]	case refine_1.left c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∈ multibrotExt d	case refine_1.left c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑3 ∉ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case refine_1.left c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∈ multibrotExt d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	apply multibrot_two_lt	case refine_1.left c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑3 ∉ multibrot d	case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 2 < Complex.abs ↑3	Please generate a tactic in lean4 to solve the state. STATE: case refine_1.left c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑3 ∉ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	rw [Complex.abs_ofReal, abs_of_pos]	case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 2 < Complex.abs ↑3	case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 2 < 3 case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 0 < 3	Please generate a tactic in lean4 to solve the state. STATE: case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 2 < Complex.abs ↑3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	norm_num	case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 2 < 3 case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 0 < 3	case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 0 < 3	Please generate a tactic in lean4 to solve the state. STATE: case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 2 < 3 case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 0 < 3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	norm_num	case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 0 < 3	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_1.left.a c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ 0 < 3 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	simp only [mem_singleton_iff, coe_ne_inf, not_false_iff]	case refine_1.right c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∉ {∞}	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_1.right c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ ↑↑3 ∉ {∞} TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	exact (isPathConnected_multibrotExt d).isConnected.isPreconnected.open_diff_singleton isOpen_multibrotExt _	case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d \ {∞})	no goals	Please generate a tactic in lean4 to solve the state. STATE: case refine_2 c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) ⊢ IsPreconnected (multibrotExt d \ {∞}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	apply Set.ext	c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) ⊢ (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞})	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) ⊢ ∀ (x : ℂ), x ∈ (multibrot d)ᶜ ↔ x ∈ (fun z => z.toComplex) '' (multibrotExt d \ {∞})	Please generate a tactic in lean4 to solve the state. STATE: c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) ⊢ (multibrot d)ᶜ = (fun z => z.toComplex) '' (multibrotExt d \ {∞}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	intro z	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) ⊢ ∀ (x : ℂ), x ∈ (multibrot d)ᶜ ↔ x ∈ (fun z => z.toComplex) '' (multibrotExt d \ {∞})	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∈ (multibrot d)ᶜ ↔ z ∈ (fun z => z.toComplex) '' (multibrotExt d \ {∞})	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) ⊢ ∀ (x : ℂ), x ∈ (multibrot d)ᶜ ↔ x ∈ (fun z => z.toComplex) '' (multibrotExt d \ {∞}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	simp only [mem_compl_iff, mem_image]	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∈ (multibrot d)ᶜ ↔ z ∈ (fun z => z.toComplex) '' (multibrotExt d \ {∞})	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∉ multibrot d ↔ ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∈ (multibrot d)ᶜ ↔ z ∈ (fun z => z.toComplex) '' (multibrotExt d \ {∞}) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	constructor	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∉ multibrot d ↔ ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∉ multibrot d → ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ (∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z) → z ∉ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∉ multibrot d ↔ ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	intro m	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∉ multibrot d → ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : z ∉ multibrot d ⊢ ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z	Please generate a tactic in lean4 to solve the state. STATE: case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ z ∉ multibrot d → ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	use z	case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : z ∉ multibrot d ⊢ ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : z ∉ multibrot d ⊢ ↑z ∈ multibrotExt d \ {∞} ∧ (↑z).toComplex = z	Please generate a tactic in lean4 to solve the state. STATE: case h.mp c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : z ∉ multibrot d ⊢ ∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	simp only [multibrotExt_coe, m, true_and_iff, toComplex_coe, not_false_iff, true_and_iff, mem_diff, eq_self_iff_true, and_true_iff, mem_singleton_iff, coe_ne_inf]	case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : z ∉ multibrot d ⊢ ↑z ∈ multibrotExt d \ {∞} ∧ (↑z).toComplex = z	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : z ∉ multibrot d ⊢ ↑z ∈ multibrotExt d \ {∞} ∧ (↑z).toComplex = z TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	intro ⟨w, ⟨m, wi⟩, wz⟩	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ (∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z) → z ∉ multibrot d	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ w : 𝕊 m : w ∈ multibrotExt d wi : w ∉ {∞} wz : w.toComplex = z ⊢ z ∉ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ ⊢ (∃ x ∈ multibrotExt d \ {∞}, x.toComplex = z) → z ∉ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	induction w using OnePoint.rec	case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ w : 𝕊 m : w ∈ multibrotExt d wi : w ∉ {∞} wz : w.toComplex = z ⊢ z ∉ multibrot d	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wi : ∞ ∉ {∞} wz : ∞.toComplex = z ⊢ z ∉ multibrot d case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z x✝ : ℂ m : ↑x✝ ∈ multibrotExt d wi : ↑x✝ ∉ {∞} wz : (↑x✝).toComplex = z ⊢ z ∉ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ w : 𝕊 m : w ∈ multibrotExt d wi : w ∉ {∞} wz : w.toComplex = z ⊢ z ∉ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	contrapose wi	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wi : ∞ ∉ {∞} wz : ∞.toComplex = z ⊢ z ∉ multibrot d	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wz : ∞.toComplex = z wi : ¬z ∉ multibrot d ⊢ ¬∞ ∉ {∞}	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wi : ∞ ∉ {∞} wz : ∞.toComplex = z ⊢ z ∉ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	clear wi	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wz : ∞.toComplex = z wi : ¬z ∉ multibrot d ⊢ ¬∞ ∉ {∞}	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wz : ∞.toComplex = z ⊢ ¬∞ ∉ {∞}	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wz : ∞.toComplex = z wi : ¬z ∉ multibrot d ⊢ ¬∞ ∉ {∞} TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	simp only [mem_singleton_iff, not_not]	case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wz : ∞.toComplex = z ⊢ ¬∞ ∉ {∞}	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₁ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z : ℂ m : ∞ ∈ multibrotExt d wz : ∞.toComplex = z ⊢ ¬∞ ∉ {∞} TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	simp only [multibrotExt_coe, toComplex_coe, mem_diff] at m wz	case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z x✝ : ℂ m : ↑x✝ ∈ multibrotExt d wi : ↑x✝ ∉ {∞} wz : (↑x✝).toComplex = z ⊢ z ∉ multibrot d	case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z x✝ : ℂ wi : ↑x✝ ∉ {∞} wz : x✝ = z m : x✝ ∉ multibrot d ⊢ z ∉ multibrot d	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z x✝ : ℂ m : ↑x✝ ∈ multibrotExt d wi : ↑x✝ ∉ {∞} wz : (↑x✝).toComplex = z ⊢ z ∉ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Dynamics/Multibrot/Connected.lean	isConnected_compl_multibrot	[92, 1]	[111, 63]	rwa [← wz]	case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z x✝ : ℂ wi : ↑x✝ ∉ {∞} wz : x✝ = z m : x✝ ∉ multibrot d ⊢ z ∉ multibrot d	no goals	Please generate a tactic in lean4 to solve the state. STATE: case h.mpr.h₂ c : ℂ d✝ : ℕ inst✝¹ : Fact (2 ≤ d✝) d : ℕ inst✝ : Fact (2 ≤ d) dc : IsConnected (multibrotExt d \ {∞}) z x✝ : ℂ wi : ↑x✝ ∉ {∞} wz : x✝ = z m : x✝ ∉ multibrot d ⊢ z ∉ multibrot d TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	simp only [Filter.EventuallyEq, Pi.sdiff_apply, eq_iff_iff]	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 ⊢ volume.ae.EventuallyEq s (s \ t)	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 ⊢ volume.ae.EventuallyEq s (s \ t) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	have e : ∀ x, x ∉ t → (x ∈ s ↔ x ∈ s \ t) := by intro x h; simp only [Set.mem_diff, h, not_false_iff, and_true_iff]	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ x ∉ t, x ∈ s ↔ x ∈ s \ t ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	simp_rw [Set.mem_def] at e	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ x ∉ t, x ∈ s ↔ x ∈ s \ t ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ x ∉ t, x ∈ s ↔ x ∈ s \ t ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	refine Filter.Eventually.mono ?_ e	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ∀ᵐ (x : X), ¬t x	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ∀ᵐ (x : X), s x ↔ s x \ t x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	rw [ae_iff]	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ∀ᵐ (x : X), ¬t x	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ↑volume {a \| ¬¬t a} = 0	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ∀ᵐ (x : X), ¬t x TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	simpa [Set.setOf_set]	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ↑volume {a \| ¬¬t a} = 0	no goals	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 e : ∀ (x : X), ¬t x → (s x ↔ (s \ t) x) ⊢ ↑volume {a \| ¬¬t a} = 0 TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	intro x h	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 ⊢ ∀ x ∉ t, x ∈ s ↔ x ∈ s \ t	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 x : X h : x ∉ t ⊢ x ∈ s ↔ x ∈ s \ t	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 ⊢ ∀ x ∉ t, x ∈ s ↔ x ∈ s \ t TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	ae_minus_null	[31, 1]	[37, 37]	simp only [Set.mem_diff, h, not_false_iff, and_true_iff]	E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 x : X h : x ∉ t ⊢ x ∈ s ↔ x ∈ s \ t	no goals	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹³ : NormedAddCommGroup E inst✝¹² : NormedSpace ℝ E inst✝¹¹ : CompleteSpace E inst✝¹⁰ : SecondCountableTopology E F : Type inst✝⁹ : NormedAddCommGroup F inst✝⁸ : NormedSpace ℝ F inst✝⁷ : CompleteSpace F X : Type inst✝⁶ : MeasureSpace X inst✝⁵ : MetricSpace X inst✝⁴ : BorelSpace X Y : Type inst✝³ : MeasureSpace Y inst✝² : MetricSpace Y inst✝¹ : BorelSpace Y A : Type inst✝ : TopologicalSpace A s t : Set X tz : ↑volume t = 0 x : X h : x ∉ t ⊢ x ∈ s ↔ x ∈ s \ t TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	TendstoUniformlyOn.integral_tendsto	[107, 1]	[117, 95]	rcases u.uniformCauchySeqOn.bounded fc sc with ⟨b, _, bh⟩	E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s ⊢ Tendsto (fun n => ∫ (x : X) in s, f n x) atTop (𝓝 (∫ (x : X) in s, g x))	case intro.intro E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ Tendsto (fun n => ∫ (x : X) in s, f n x) atTop (𝓝 (∫ (x : X) in s, g x))	Please generate a tactic in lean4 to solve the state. STATE: E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s ⊢ Tendsto (fun n => ∫ (x : X) in s, f n x) atTop (𝓝 (∫ (x : X) in s, g x)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	TendstoUniformlyOn.integral_tendsto	[107, 1]	[117, 95]	apply tendsto_integral_of_dominated_convergence (F := f) (f := g) (fun _ ↦ b)	case intro.intro E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ Tendsto (fun n => ∫ (x : X) in s, f n x) atTop (𝓝 (∫ (x : X) in s, g x))	case intro.intro.F_measurable E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ ∀ (n : ℕ), AEStronglyMeasurable (f n) (volume.restrict s) case intro.intro.bound_integrable E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ Integrable (fun x => b) (volume.restrict s) case intro.intro.h_bound E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ ∀ (n : ℕ), ∀ᵐ (a : X) ∂volume.restrict s, ‖f n a‖ ≤ b case intro.intro.h_lim E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ ∀ᵐ (a : X) ∂volume.restrict s, Tendsto (fun n => f n a) atTop (𝓝 (g a))	Please generate a tactic in lean4 to solve the state. STATE: case intro.intro E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ Tendsto (fun n => ∫ (x : X) in s, f n x) atTop (𝓝 (∫ (x : X) in s, g x)) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	TendstoUniformlyOn.integral_tendsto	[107, 1]	[117, 95]	intro n	case intro.intro.F_measurable E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ ∀ (n : ℕ), AEStronglyMeasurable (f n) (volume.restrict s)	case intro.intro.F_measurable E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b n : ℕ ⊢ AEStronglyMeasurable (f n) (volume.restrict s)	Please generate a tactic in lean4 to solve the state. STATE: case intro.intro.F_measurable E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b ⊢ ∀ (n : ℕ), AEStronglyMeasurable (f n) (volume.restrict s) TACTIC:
https://github.com/girving/ray.git	0be790285dd0fce78913b0cb9bddaffa94bd25f9	Ray/Misc/Measure.lean	TendstoUniformlyOn.integral_tendsto	[107, 1]	[117, 95]	exact (fc n).aestronglyMeasurable sc.measurableSet	case intro.intro.F_measurable E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b n : ℕ ⊢ AEStronglyMeasurable (f n) (volume.restrict s)	no goals	Please generate a tactic in lean4 to solve the state. STATE: case intro.intro.F_measurable E : Type inst✝¹⁴ : NormedAddCommGroup E inst✝¹³ : NormedSpace ℝ E inst✝¹² : CompleteSpace E inst✝¹¹ : SecondCountableTopology E F : Type inst✝¹⁰ : NormedAddCommGroup F inst✝⁹ : NormedSpace ℝ F inst✝⁸ : CompleteSpace F X : Type inst✝⁷ : MeasureSpace X inst✝⁶ : MetricSpace X inst✝⁵ : BorelSpace X Y : Type inst✝⁴ : MeasureSpace Y inst✝³ : MetricSpace Y inst✝² : BorelSpace Y A : Type inst✝¹ : TopologicalSpace A f : ℕ → X → E g : X → E s : Set X inst✝ : IsLocallyFiniteMeasure volume u : TendstoUniformlyOn f g atTop s fc : ∀ (n : ℕ), ContinuousOn (f n) s sc : IsCompact s b : ℝ left✝ : 0 ≤ b bh : ∀ (n : ℕ), ∀ x ∈ s, ‖f n x‖ ≤ b n : ℕ ⊢ AEStronglyMeasurable (f n) (volume.restrict s) TACTIC:

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