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https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_mderiv_ne_zero'
[198, 1]
[205, 11]
rw [← mderiv_ne_zero_iff' t0]
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : t ≠ 0 ⊢ mfderiv I I (↑(extChartAt I z)) w ≠ 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : t ≠ 0 ⊢ (mfderiv I I (↑(extChartAt I z)) w) t ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : t ≠ 0 ⊢ mfderiv I I (↑(extChartAt I z)) w ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_mderiv_ne_zero'
[198, 1]
[205, 11]
contrapose t0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : t ≠ 0 ⊢ (mfderiv I I (↑(extChartAt I z)) w) t ≠ 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : ¬(mfderiv I I (↑(extChartAt I z)) w) t ≠ 0 ⊢ ¬t ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : t ≠ 0 ⊢ (mfderiv I I (↑(extChartAt I z)) w) t ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_mderiv_ne_zero'
[198, 1]
[205, 11]
simp only [not_not] at t0 ⊢
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : ¬(mfderiv I I (↑(extChartAt I z)) w) t ≠ 0 ⊢ ¬t ≠ 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 ⊢ t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : ¬(mfderiv I I (↑(extChartAt I z)) w) t ≠ 0 ⊢ ¬t ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_mderiv_ne_zero'
[198, 1]
[205, 11]
have h := ContinuousLinearMap.ext_iff.mp (extChartAt_mderiv_left_inverse m) t
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 ⊢ t = 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : ((mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)).comp (mfderiv I I (↑(extChartAt I z)) w)) t = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 ⊢ t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_mderiv_ne_zero'
[198, 1]
[205, 11]
simp only [ContinuousLinearMap.comp_apply, ContinuousLinearMap.map_zero] at h
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : ((mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)).comp (mfderiv I I (↑(extChartAt I z)) w)) t = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)) ((mfderiv I I (↑(extChartAt I z)) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : ((mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)).comp (mfderiv I I (↑(extChartAt I z)) w)) t = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_mderiv_ne_zero'
[198, 1]
[205, 11]
rw [←h.trans (ContinuousLinearMap.id_apply _), ContinuousLinearMap.apply_eq_zero_of_eq_zero]
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)) ((mfderiv I I (↑(extChartAt I z)) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
case intro.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)) ((mfderiv I I (↑(extChartAt I z)) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ (mfderiv I I (↑(extChartAt I z)) w) t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)) ((mfderiv I I (↑(extChartAt I z)) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_mderiv_ne_zero'
[198, 1]
[205, 11]
exact t0
case intro.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)) ((mfderiv I I (↑(extChartAt I z)) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ (mfderiv I I (↑(extChartAt I z)) w) t = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case intro.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z w : S m : w ∈ (extChartAt I z).source t : TangentSpace I z t0 : (mfderiv I I (↑(extChartAt I z)) w) t = 0 h : (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w)) ((mfderiv I I (↑(extChartAt I z)) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ (mfderiv I I (↑(extChartAt I z)) w) t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
rcases exists_ne (0 : TangentSpace I (extChartAt I z z)) with ⟨t, t0⟩
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target ⊢ mfderiv I I (↑(extChartAt I z).symm) w ≠ 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : t ≠ 0 ⊢ mfderiv I I (↑(extChartAt I z).symm) w ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target ⊢ mfderiv I I (↑(extChartAt I z).symm) w ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
rw [← mderiv_ne_zero_iff' t0]
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : t ≠ 0 ⊢ mfderiv I I (↑(extChartAt I z).symm) w ≠ 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : t ≠ 0 ⊢ (mfderiv I I (↑(extChartAt I z).symm) w) t ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : t ≠ 0 ⊢ mfderiv I I (↑(extChartAt I z).symm) w ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
contrapose t0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : t ≠ 0 ⊢ (mfderiv I I (↑(extChartAt I z).symm) w) t ≠ 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : ¬(mfderiv I I (↑(extChartAt I z).symm) w) t ≠ 0 ⊢ ¬t ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : t ≠ 0 ⊢ (mfderiv I I (↑(extChartAt I z).symm) w) t ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
simp only [not_not] at t0 ⊢
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : ¬(mfderiv I I (↑(extChartAt I z).symm) w) t ≠ 0 ⊢ ¬t ≠ 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 ⊢ t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : ¬(mfderiv I I (↑(extChartAt I z).symm) w) t ≠ 0 ⊢ ¬t ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
have h := ContinuousLinearMap.ext_iff.mp (extChartAt_mderiv_right_inverse m) t
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 ⊢ t = 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : ((mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)).comp (mfderiv I I (↑(extChartAt I z).symm) w)) t = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 ⊢ t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
simp only [ContinuousLinearMap.comp_apply, ContinuousLinearMap.map_zero] at h
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : ((mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)).comp (mfderiv I I (↑(extChartAt I z).symm) w)) t = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : (mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)) ((mfderiv I I (↑(extChartAt I z).symm) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : ((mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)).comp (mfderiv I I (↑(extChartAt I z).symm) w)) t = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
rw [←h.trans (ContinuousLinearMap.id_apply _), ContinuousLinearMap.apply_eq_zero_of_eq_zero]
case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : (mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)) ((mfderiv I I (↑(extChartAt I z).symm) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0
case intro.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : (mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)) ((mfderiv I I (↑(extChartAt I z).symm) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ (mfderiv I I (↑(extChartAt I z).symm) w) t = 0
Please generate a tactic in lean4 to solve the state. STATE: case intro S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : (mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)) ((mfderiv I I (↑(extChartAt I z).symm) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
extChartAt_symm_mderiv_ne_zero'
[208, 1]
[215, 11]
exact t0
case intro.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : (mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)) ((mfderiv I I (↑(extChartAt I z).symm) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ (mfderiv I I (↑(extChartAt I z).symm) w) t = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case intro.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S w : ℂ m : w ∈ (extChartAt I z).target t : TangentSpace I (↑(extChartAt I z) z) t0 : (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 h : (mfderiv I I (↑(extChartAt I z)) (↑(extChartAt I z).symm w)) ((mfderiv I I (↑(extChartAt I z).symm) w) t) = (ContinuousLinearMap.id ℂ (TangentSpace I w)) t ⊢ (mfderiv I I (↑(extChartAt I z).symm) w) t = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
have d : MDifferentiableAt I I (fun z ↦ z) z := mdifferentiableAt_id I
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S ⊢ mfderiv I I (fun z => z) z ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ mfderiv I I (fun z => z) z ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S ⊢ mfderiv I I (fun z => z) z ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
simp only [mfderiv, d, if_true, writtenInExtChartAt, Function.comp, ModelWithCorners.Boundaryless.range_eq_univ, fderivWithin_univ]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ mfderiv I I (fun z => z) z ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ fderiv ℂ (fun x => ↑(extChartAt I z) (↑(extChartAt I z).symm x)) (↑(extChartAt I z) z) ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ mfderiv I I (fun z => z) z ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
have e : (fun w ↦ extChartAt I z ((extChartAt I z).symm w)) =ᶠ[𝓝 (extChartAt I z z)] id := by apply ((isOpen_extChartAt_target I z).eventually_mem (mem_extChartAt_target I z)).mp refine eventually_of_forall fun w m ↦ ?_ simp only [id, PartialEquiv.right_inv _ m]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ fderiv ℂ (fun x => ↑(extChartAt I z) (↑(extChartAt I z).symm x)) (↑(extChartAt I z) z) ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z e : (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id ⊢ fderiv ℂ (fun x => ↑(extChartAt I z) (↑(extChartAt I z).symm x)) (↑(extChartAt I z) z) ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ fderiv ℂ (fun x => ↑(extChartAt I z) (↑(extChartAt I z).symm x)) (↑(extChartAt I z) z) ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
simp only [e.fderiv_eq, fderiv_id, Ne, ContinuousLinearMap.ext_iff, not_forall, ContinuousLinearMap.zero_apply, ContinuousLinearMap.id_apply]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z e : (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id ⊢ fderiv ℂ (fun x => ↑(extChartAt I z) (↑(extChartAt I z).symm x)) (↑(extChartAt I z) z) ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z e : (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id ⊢ ∃ x, ¬x = 0 x
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z e : (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id ⊢ fderiv ℂ (fun x => ↑(extChartAt I z) (↑(extChartAt I z).symm x)) (↑(extChartAt I z) z) ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
use 1, one_ne_zero
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z e : (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id ⊢ ∃ x, ¬x = 0 x
no goals
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z e : (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id ⊢ ∃ x, ¬x = 0 x TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
apply ((isOpen_extChartAt_target I z).eventually_mem (mem_extChartAt_target I z)).mp
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ ∀ᶠ (x : ℂ) in 𝓝 (↑(extChartAt I z) z), x ∈ (extChartAt I z).target → (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) x = id x
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ (𝓝 (↑(extChartAt I z) z)).EventuallyEq (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) id TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
refine eventually_of_forall fun w m ↦ ?_
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ ∀ᶠ (x : ℂ) in 𝓝 (↑(extChartAt I z) z), x ∈ (extChartAt I z).target → (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) x = id x
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z w : ℂ m : w ∈ (extChartAt I z).target ⊢ (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) w = id w
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z ⊢ ∀ᶠ (x : ℂ) in 𝓝 (↑(extChartAt I z) z), x ∈ (extChartAt I z).target → (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) x = id x TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
id_mderiv_ne_zero
[227, 1]
[237, 21]
simp only [id, PartialEquiv.right_inv _ m]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z w : ℂ m : w ∈ (extChartAt I z).target ⊢ (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) w = id w
no goals
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U z : S d : MDifferentiableAt I I (fun z => z) z w : ℂ m : w ∈ (extChartAt I z).target ⊢ (fun w => ↑(extChartAt I z) (↑(extChartAt I z).symm w)) w = id w TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
by_cases d : DifferentiableAt ℂ f z
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0
case pos S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0 case neg S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
constructor
case pos S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 → deriv f z = 0 case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ deriv f z = 0 → mfderiv I I f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
have h := d.mdifferentiableAt.hasMFDerivAt
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 → deriv f z = 0
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z (mfderiv I I f z) ⊢ mfderiv I I f z = 0 → deriv f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 → deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
intro e
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z (mfderiv I I f z) ⊢ mfderiv I I f z = 0 → deriv f z = 0
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z (mfderiv I I f z) e : mfderiv I I f z = 0 ⊢ deriv f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z (mfderiv I I f z) ⊢ mfderiv I I f z = 0 → deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
rw [e] at h
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z (mfderiv I I f z) e : mfderiv I I f z = 0 ⊢ deriv f z = 0
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z 0 e : mfderiv I I f z = 0 ⊢ deriv f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z (mfderiv I I f z) e : mfderiv I I f z = 0 ⊢ deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
have p := h.hasFDerivAt.hasDerivAt
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z 0 e : mfderiv I I f z = 0 ⊢ deriv f z = 0
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z 0 e : mfderiv I I f z = 0 p : HasDerivAt f (0 1) z ⊢ deriv f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z 0 e : mfderiv I I f z = 0 ⊢ deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
exact p.deriv
case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z 0 e : mfderiv I I f z = 0 p : HasDerivAt f (0 1) z ⊢ deriv f z = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case pos.mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasMFDerivAt I I f z 0 e : mfderiv I I f z = 0 p : HasDerivAt f (0 1) z ⊢ deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
have h := d.hasDerivAt
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ deriv f z = 0 → mfderiv I I f z = 0
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f (deriv f z) z ⊢ deriv f z = 0 → mfderiv I I f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z ⊢ deriv f z = 0 → mfderiv I I f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
intro e
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f (deriv f z) z ⊢ deriv f z = 0 → mfderiv I I f z = 0
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f (deriv f z) z e : deriv f z = 0 ⊢ mfderiv I I f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f (deriv f z) z ⊢ deriv f z = 0 → mfderiv I I f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
rw [e] at h
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f (deriv f z) z e : deriv f z = 0 ⊢ mfderiv I I f z = 0
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ mfderiv I I f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f (deriv f z) z e : deriv f z = 0 ⊢ mfderiv I I f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
have s0 : (1 : ℂ →L[ℂ] ℂ).smulRight (0 : ℂ) = 0 := by apply ContinuousLinearMap.ext simp only [ContinuousLinearMap.smulRight_apply, Algebra.id.smul_eq_mul, MulZeroClass.mul_zero, ContinuousLinearMap.zero_apply, forall_const]
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ mfderiv I I f z = 0
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 ⊢ mfderiv I I f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ mfderiv I I f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
have p := h.hasFDerivAt.hasMFDerivAt
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 ⊢ mfderiv I I f z = 0
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 p : HasMFDerivAt I I f z (ContinuousLinearMap.smulRight 1 0) ⊢ mfderiv I I f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 ⊢ mfderiv I I f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
rw [s0] at p
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 p : HasMFDerivAt I I f z (ContinuousLinearMap.smulRight 1 0) ⊢ mfderiv I I f z = 0
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 p : HasMFDerivAt I I f z 0 ⊢ mfderiv I I f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 p : HasMFDerivAt I I f z (ContinuousLinearMap.smulRight 1 0) ⊢ mfderiv I I f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
exact p.mfderiv
case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 p : HasMFDerivAt I I f z 0 ⊢ mfderiv I I f z = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case pos.mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 s0 : ContinuousLinearMap.smulRight 1 0 = 0 p : HasMFDerivAt I I f z 0 ⊢ mfderiv I I f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
apply ContinuousLinearMap.ext
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ ContinuousLinearMap.smulRight 1 0 = 0
case h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ ∀ (x : ℂ), (ContinuousLinearMap.smulRight 1 0) x = 0 x
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ ContinuousLinearMap.smulRight 1 0 = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
simp only [ContinuousLinearMap.smulRight_apply, Algebra.id.smul_eq_mul, MulZeroClass.mul_zero, ContinuousLinearMap.zero_apply, forall_const]
case h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ ∀ (x : ℂ), (ContinuousLinearMap.smulRight 1 0) x = 0 x
no goals
Please generate a tactic in lean4 to solve the state. STATE: case h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : DifferentiableAt ℂ f z h : HasDerivAt f 0 z e : deriv f z = 0 ⊢ ∀ (x : ℂ), (ContinuousLinearMap.smulRight 1 0) x = 0 x TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
have d' : ¬MDifferentiableAt I I f z := by contrapose d; simp only [not_not] at d ⊢; exact d.differentiableAt
case neg S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0
case neg S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z d' : ¬MDifferentiableAt I I f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0
Please generate a tactic in lean4 to solve the state. STATE: case neg S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
simp only [deriv_zero_of_not_differentiableAt d, mfderiv_zero_of_not_mdifferentiableAt d', eq_self_iff_true]
case neg S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z d' : ¬MDifferentiableAt I I f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case neg S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z d' : ¬MDifferentiableAt I I f z ⊢ mfderiv I I f z = 0 ↔ deriv f z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
contrapose d
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z ⊢ ¬MDifferentiableAt I I f z
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬¬MDifferentiableAt I I f z ⊢ ¬¬DifferentiableAt ℂ f z
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬DifferentiableAt ℂ f z ⊢ ¬MDifferentiableAt I I f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
simp only [not_not] at d ⊢
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬¬MDifferentiableAt I I f z ⊢ ¬¬DifferentiableAt ℂ f z
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : MDifferentiableAt I I f z ⊢ DifferentiableAt ℂ f z
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : ¬¬MDifferentiableAt I I f z ⊢ ¬¬DifferentiableAt ℂ f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_eq_zero_iff_deriv_eq_zero
[240, 1]
[256, 24]
exact d.differentiableAt
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : MDifferentiableAt I I f z ⊢ DifferentiableAt ℂ f z
no goals
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ d : MDifferentiableAt I I f z ⊢ DifferentiableAt ℂ f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_iff_deriv_ne_zero
[259, 1]
[260, 98]
rw [not_iff_not, mfderiv_eq_zero_iff_deriv_eq_zero]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ ⊢ mfderiv I I f z ≠ 0 ↔ deriv f z ≠ 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → ℂ z : ℂ ⊢ mfderiv I I f z ≠ 0 ↔ deriv f z ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
critical_iter
[271, 1]
[280, 43]
induction' n with n h
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S n : ℕ z : S fa : Holomorphic I I f c : Critical f^[n] z ⊢ Precritical f z
case zero S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f c : Critical f^[0] z ⊢ Precritical f z case succ S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : Critical f^[n + 1] z ⊢ Precritical f z
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S n : ℕ z : S fa : Holomorphic I I f c : Critical f^[n] z ⊢ Precritical f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
critical_iter
[271, 1]
[280, 43]
rw [Function.iterate_zero, Critical, mfderiv_id, ← ContinuousLinearMap.opNorm_zero_iff, ContinuousLinearMap.norm_id] at c
case zero S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f c : Critical f^[0] z ⊢ Precritical f z
case zero S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f c : 1 = 0 ⊢ Precritical f z
Please generate a tactic in lean4 to solve the state. STATE: case zero S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f c : Critical f^[0] z ⊢ Precritical f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
critical_iter
[271, 1]
[280, 43]
norm_num at c
case zero S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f c : 1 = 0 ⊢ Precritical f z
no goals
Please generate a tactic in lean4 to solve the state. STATE: case zero S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f c : 1 = 0 ⊢ Precritical f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
critical_iter
[271, 1]
[280, 43]
rw [Function.iterate_succ', Critical, mfderiv_comp z (fa _).mdifferentiableAt (fa.iter _ _).mdifferentiableAt, mderiv_comp_eq_zero_iff] at c
case succ S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : Critical f^[n + 1] z ⊢ Precritical f z
case succ S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f (f^[n] z) = 0 ∨ mfderiv I I f^[n] z = 0 ⊢ Precritical f z
Please generate a tactic in lean4 to solve the state. STATE: case succ S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : Critical f^[n + 1] z ⊢ Precritical f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
critical_iter
[271, 1]
[280, 43]
cases' c with c c
case succ S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f (f^[n] z) = 0 ∨ mfderiv I I f^[n] z = 0 ⊢ Precritical f z
case succ.inl S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f (f^[n] z) = 0 ⊢ Precritical f z case succ.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f^[n] z = 0 ⊢ Precritical f z
Please generate a tactic in lean4 to solve the state. STATE: case succ S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f (f^[n] z) = 0 ∨ mfderiv I I f^[n] z = 0 ⊢ Precritical f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
critical_iter
[271, 1]
[280, 43]
use n, c
case succ.inl S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f (f^[n] z) = 0 ⊢ Precritical f z case succ.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f^[n] z = 0 ⊢ Precritical f z
case succ.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f^[n] z = 0 ⊢ Precritical f z
Please generate a tactic in lean4 to solve the state. STATE: case succ.inl S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f (f^[n] z) = 0 ⊢ Precritical f z case succ.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f^[n] z = 0 ⊢ Precritical f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
critical_iter
[271, 1]
[280, 43]
exact h c
case succ.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f^[n] z = 0 ⊢ Precritical f z
no goals
Please generate a tactic in lean4 to solve the state. STATE: case succ.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → S z : S fa : Holomorphic I I f n : ℕ h : Critical f^[n] z → Precritical f z c : mfderiv I I f^[n] z = 0 ⊢ Precritical f z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
HolomorphicAt.inChart
[295, 1]
[302, 74]
apply HolomorphicAt.analyticAt II I
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ AnalyticAt ℂ (uncurry (_root_.inChart f c z)) (c, ↑(_root_.extChartAt I z) z)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (uncurry (_root_.inChart f c z)) (c, ↑(_root_.extChartAt I z) z)
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ AnalyticAt ℂ (uncurry (_root_.inChart f c z)) (c, ↑(_root_.extChartAt I z) z) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
HolomorphicAt.inChart
[295, 1]
[302, 74]
apply (HolomorphicAt.extChartAt (mem_extChartAt_source I (f c z))).comp_of_eq
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (uncurry (_root_.inChart f c z)) (c, ↑(_root_.extChartAt I z) z)
case gh S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (fun x => f x.1 (↑(_root_.extChartAt I z).symm x.2)) (c, ↑(_root_.extChartAt I z) z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (uncurry (_root_.inChart f c z)) (c, ↑(_root_.extChartAt I z) z) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
HolomorphicAt.inChart
[295, 1]
[302, 74]
apply fa.comp₂_of_eq holomorphicAt_fst
case gh S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (fun x => f x.1 (↑(_root_.extChartAt I z).symm x.2)) (c, ↑(_root_.extChartAt I z) z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z
case gh.ga S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (fun x => ↑(_root_.extChartAt I z).symm x.2) (c, ↑(_root_.extChartAt I z) z) case gh.e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ((c, ↑(_root_.extChartAt I z) z).1, ↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = (c, z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z
Please generate a tactic in lean4 to solve the state. STATE: case gh S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (fun x => f x.1 (↑(_root_.extChartAt I z).symm x.2)) (c, ↑(_root_.extChartAt I z) z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
HolomorphicAt.inChart
[295, 1]
[302, 74]
apply (HolomorphicAt.extChartAt_symm (mem_extChartAt_target I z)).comp_of_eq holomorphicAt_snd
case gh.ga S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (fun x => ↑(_root_.extChartAt I z).symm x.2) (c, ↑(_root_.extChartAt I z) z) case gh.e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ((c, ↑(_root_.extChartAt I z) z).1, ↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = (c, z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z
case gh.ga S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ (c, ↑(_root_.extChartAt I z) z).2 = ↑(_root_.extChartAt I z) z case gh.e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ((c, ↑(_root_.extChartAt I z) z).1, ↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = (c, z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z
Please generate a tactic in lean4 to solve the state. STATE: case gh.ga S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ HolomorphicAt (I.prod I) I (fun x => ↑(_root_.extChartAt I z).symm x.2) (c, ↑(_root_.extChartAt I z) z) case gh.e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ((c, ↑(_root_.extChartAt I z) z).1, ↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = (c, z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
HolomorphicAt.inChart
[295, 1]
[302, 74]
repeat' simp only [PartialEquiv.left_inv _ (mem_extChartAt_source I z)]
case gh.ga S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ (c, ↑(_root_.extChartAt I z) z).2 = ↑(_root_.extChartAt I z) z case gh.e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ((c, ↑(_root_.extChartAt I z) z).1, ↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = (c, z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z
no goals
Please generate a tactic in lean4 to solve the state. STATE: case gh.ga S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ (c, ↑(_root_.extChartAt I z) z).2 = ↑(_root_.extChartAt I z) z case gh.e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ((c, ↑(_root_.extChartAt I z) z).1, ↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = (c, z) case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
HolomorphicAt.inChart
[295, 1]
[302, 74]
simp only [PartialEquiv.left_inv _ (mem_extChartAt_source I z)]
case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z
no goals
Please generate a tactic in lean4 to solve the state. STATE: case e S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ f (c, ↑(_root_.extChartAt I z) z).1 (↑(_root_.extChartAt I z).symm (c, ↑(_root_.extChartAt I z) z).2) = f c z TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
apply (fa.continuousAt.eventually_mem ((isOpen_extChartAt_source I (f c z)).mem_nhds (mem_extChartAt_source I (f c z)))).mp
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (x : ℂ × S) in 𝓝 (c, z), uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0)
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
apply ((isOpen_extChartAt_source II (c, z)).eventually_mem (mem_extChartAt_source _ _)).mp
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (x : ℂ × S) in 𝓝 (c, z), uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (x : ℂ × S) in 𝓝 (c, z), x ∈ (extChartAt (I.prod I) (c, z)).source → uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0)
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (x : ℂ × S) in 𝓝 (c, z), uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
refine fa.eventually.mp (eventually_of_forall ?_)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (x : ℂ × S) in 𝓝 (c, z), x ∈ (extChartAt (I.prod I) (c, z)).source → uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ (x : ℂ × S), HolomorphicAt (I.prod I) I (uncurry f) x → x ∈ (extChartAt (I.prod I) (c, z)).source → uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0)
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ᶠ (x : ℂ × S) in 𝓝 (c, z), x ∈ (extChartAt (I.prod I) (c, z)).source → uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
intro ⟨e, w⟩ fa m fm
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ (x : ℂ × S), HolomorphicAt (I.prod I) I (uncurry f) x → x ∈ (extChartAt (I.prod I) (c, z)).source → uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) m : (e, w) ∈ (extChartAt (I.prod I) (c, z)).source fm : uncurry f (e, w) ∈ (extChartAt I (f c z)).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) ⊢ ∀ (x : ℂ × S), HolomorphicAt (I.prod I) I (uncurry f) x → x ∈ (extChartAt (I.prod I) (c, z)).source → uncurry f x ∈ (extChartAt I (f c z)).source → (mfderiv I I (f x.1) x.2 = 0 ↔ deriv (inChart f c z x.1) (↑(extChartAt I z) x.2) = 0) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simp only [extChartAt_prod, PartialEquiv.prod_source, extChartAt_eq_refl, PartialEquiv.refl_source, mem_prod, mem_univ, true_and_iff] at m
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) m : (e, w) ∈ (extChartAt (I.prod I) (c, z)).source fm : uncurry f (e, w) ∈ (extChartAt I (f c z)).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : uncurry f (e, w) ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) m : (e, w) ∈ (extChartAt (I.prod I) (c, z)).source fm : uncurry f (e, w) ∈ (extChartAt I (f c z)).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simp only [uncurry] at fm
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : uncurry f (e, w) ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : uncurry f (e, w) ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
have m' := PartialEquiv.map_source _ m
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simp only [← mfderiv_eq_zero_iff_deriv_eq_zero]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target ⊢ mfderiv I I (f (e, w).1) (e, w).2 = 0 ↔ deriv (inChart f c z (e, w).1) (↑(extChartAt I z) (e, w).2) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
have cd : HolomorphicAt I I (extChartAt I (f c z)) (f e w) := HolomorphicAt.extChartAt fm
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
have fd : HolomorphicAt I I (f e ∘ (extChartAt I z).symm) (extChartAt I z w) := by simp only [Function.comp] exact HolomorphicAt.comp_of_eq fa.along_snd (HolomorphicAt.extChartAt_symm m') (PartialEquiv.right_inv _ m)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
have ce : inChart f c z e = extChartAt I (f c z) ∘ f e ∘ (extChartAt I z).symm := rfl
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
rw [ce, mfderiv_comp_of_eq cd.mdifferentiableAt fd.mdifferentiableAt ?blah, mfderiv_comp_of_eq fa.along_snd.mdifferentiableAt (HolomorphicAt.extChartAt_symm m').mdifferentiableAt]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ (mfderiv I I (↑(extChartAt I (f c z))) ((f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w))).comp ((mfderiv I I (fun y => f e y) (↑(extChartAt I z).symm (↑(extChartAt I z) w))).comp (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w))) = 0 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ ↑(extChartAt I z).symm (↑(extChartAt I z) w) = w case blah S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) = f e w
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (inChart f c z e) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simp only [Function.comp]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ HolomorphicAt I I (fun x => f e (↑(extChartAt I z).symm x)) (↑(extChartAt I z) w)
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
exact HolomorphicAt.comp_of_eq fa.along_snd (HolomorphicAt.extChartAt_symm m') (PartialEquiv.right_inv _ m)
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ HolomorphicAt I I (fun x => f e (↑(extChartAt I z).symm x)) (↑(extChartAt I z) w)
no goals
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) ⊢ HolomorphicAt I I (fun x => f e (↑(extChartAt I z).symm x)) (↑(extChartAt I z) w) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simp only [mderiv_comp_eq_zero_iff, Function.comp]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ (mfderiv I I (↑(extChartAt I (f c z))) ((f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w))).comp ((mfderiv I I (fun y => f e y) (↑(extChartAt I z).symm (↑(extChartAt I z) w))).comp (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w))) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (↑(extChartAt I (f c z))) (f e (↑(extChartAt I z).symm (↑(extChartAt I z) w))) = 0 ∨ mfderiv I I (fun y => f e y) (↑(extChartAt I z).symm (↑(extChartAt I z) w)) = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ (mfderiv I I (↑(extChartAt I (f c z))) ((f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w))).comp ((mfderiv I I (fun y => f e y) (↑(extChartAt I z).symm (↑(extChartAt I z) w))).comp (mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w))) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
rw [(extChartAt I z).left_inv m]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (↑(extChartAt I (f c z))) (f e (↑(extChartAt I z).symm (↑(extChartAt I z) w))) = 0 ∨ mfderiv I I (fun y => f e y) (↑(extChartAt I z).symm (↑(extChartAt I z) w)) = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (↑(extChartAt I (f c z))) (f e w) = 0 ∨ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (↑(extChartAt I (f c z))) (f e (↑(extChartAt I z).symm (↑(extChartAt I z) w))) = 0 ∨ mfderiv I I (fun y => f e y) (↑(extChartAt I z).symm (↑(extChartAt I z) w)) = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simp only [extChartAt_mderiv_ne_zero' fm, false_or]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (↑(extChartAt I (f c z))) (f e w) = 0 ∨ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (↑(extChartAt I (f c z))) (f e w) = 0 ∨ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
constructor
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
case mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 → mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 case mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 → mfderiv I I (f e) w = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 ↔ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
intro h
case mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 → mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
case mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (f e) w = 0 ⊢ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
Please generate a tactic in lean4 to solve the state. STATE: case mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (f e) w = 0 → mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
left
case mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (f e) w = 0 ⊢ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0
case mp.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (f e) w = 0 ⊢ mfderiv I I (fun y => f e y) w = 0
Please generate a tactic in lean4 to solve the state. STATE: case mp S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (f e) w = 0 ⊢ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
exact h
case mp.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (f e) w = 0 ⊢ mfderiv I I (fun y => f e y) w = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case mp.h S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (f e) w = 0 ⊢ mfderiv I I (fun y => f e y) w = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
intro h
case mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 → mfderiv I I (f e) w = 0
case mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0
Please generate a tactic in lean4 to solve the state. STATE: case mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 → mfderiv I I (f e) w = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
cases' h with h h
case mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0
case mpr.inl S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (fun y => f e y) w = 0 ⊢ mfderiv I I (f e) w = 0 case mpr.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0
Please generate a tactic in lean4 to solve the state. STATE: case mpr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (fun y => f e y) w = 0 ∨ mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
exact h
case mpr.inl S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (fun y => f e y) w = 0 ⊢ mfderiv I I (f e) w = 0 case mpr.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0
case mpr.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0
Please generate a tactic in lean4 to solve the state. STATE: case mpr.inl S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (fun y => f e y) w = 0 ⊢ mfderiv I I (f e) w = 0 case mpr.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simpa only using extChartAt_symm_mderiv_ne_zero' m' h
case mpr.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case mpr.inr S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm h : mfderiv I I (↑(extChartAt I z).symm) (↑(extChartAt I z) w) = 0 ⊢ mfderiv I I (f e) w = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
exact PartialEquiv.left_inv _ m
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ ↑(extChartAt I z).symm (↑(extChartAt I z) w) = w
no goals
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ ↑(extChartAt I z).symm (↑(extChartAt I z) w) = w TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
inChart_critical
[305, 1]
[334, 57]
simp only [Function.comp, PartialEquiv.left_inv _ m]
case blah S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) = f e w
no goals
Please generate a tactic in lean4 to solve the state. STATE: case blah S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa✝ : HolomorphicAt (I.prod I) I (uncurry f) (c, z) e : ℂ w : S fa : HolomorphicAt (I.prod I) I (uncurry f) (e, w) fm : f e w ∈ (extChartAt I (f c z)).source m : w ∈ (extChartAt I z).source m' : ↑(extChartAt I z) w ∈ (extChartAt I z).target cd : HolomorphicAt I I (↑(extChartAt I (f c z))) (f e w) fd : HolomorphicAt I I (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) ce : inChart f c z e = ↑(extChartAt I (f c z)) ∘ f e ∘ ↑(extChartAt I z).symm ⊢ (f e ∘ ↑(extChartAt I z).symm) (↑(extChartAt I z) w) = f e w TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
set g := inChart f c z
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
have g0 := inChart_critical fa
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
refine g0.mp (g0n.mp (eventually_of_forall fun w g0 e ↦ ?_))
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0✝ : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 w : ℂ × S g0 : deriv (g w.1) (↑(extChartAt I z) w.2) ≠ 0 e : mfderiv I I (f w.1) w.2 = 0 ↔ deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0 ⊢ mfderiv I I (f w.1) w.2 ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
rw [Ne, e]
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0✝ : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 w : ℂ × S g0 : deriv (g w.1) (↑(extChartAt I z) w.2) ≠ 0 e : mfderiv I I (f w.1) w.2 = 0 ↔ deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0 ⊢ mfderiv I I (f w.1) w.2 ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0✝ : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 w : ℂ × S g0 : deriv (g w.1) (↑(extChartAt I z) w.2) ≠ 0 e : mfderiv I I (f w.1) w.2 = 0 ↔ deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0 ⊢ ¬deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0✝ : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 w : ℂ × S g0 : deriv (g w.1) (↑(extChartAt I z) w.2) ≠ 0 e : mfderiv I I (f w.1) w.2 = 0 ↔ deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0 ⊢ mfderiv I I (f w.1) w.2 ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
exact g0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0✝ : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 w : ℂ × S g0 : deriv (g w.1) (↑(extChartAt I z) w.2) ≠ 0 e : mfderiv I I (f w.1) w.2 = 0 ↔ deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0 ⊢ ¬deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0✝ : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 g0n : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 w : ℂ × S g0 : deriv (g w.1) (↑(extChartAt I z) w.2) ≠ 0 e : mfderiv I I (f w.1) w.2 = 0 ↔ deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0 ⊢ ¬deriv (inChart f c z w.1) (↑(extChartAt I z) w.2) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
refine ContinuousAt.eventually_ne ?_ ?_
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0
case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ ContinuousAt (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) (c, z) case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ deriv (g (c, z).1) (↑(extChartAt I z) (c, z).2) ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), deriv (g p.1) (↑(extChartAt I z) p.2) ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
have e : (fun p : ℂ × S ↦ deriv (g p.1) (extChartAt I z p.2)) = (fun p : ℂ × ℂ ↦ deriv (g p.1) p.2) ∘ fun p : ℂ × S ↦ (p.1, extChartAt I z p.2) := rfl
case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ ContinuousAt (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) (c, z)
case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 e : (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) = (fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2) ⊢ ContinuousAt (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) (c, z)
Please generate a tactic in lean4 to solve the state. STATE: case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ ContinuousAt (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) (c, z) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
rw [e]
case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 e : (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) = (fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2) ⊢ ContinuousAt (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) (c, z)
case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 e : (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) = (fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2) ⊢ ContinuousAt ((fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2)) (c, z)
Please generate a tactic in lean4 to solve the state. STATE: case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 e : (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) = (fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2) ⊢ ContinuousAt (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) (c, z) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
exact fa.inChart.deriv2.continuousAt.comp_of_eq (continuousAt_fst.prod ((continuousAt_extChartAt I z).comp_of_eq continuousAt_snd rfl)) rfl
case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 e : (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) = (fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2) ⊢ ContinuousAt ((fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2)) (c, z)
no goals
Please generate a tactic in lean4 to solve the state. STATE: case refine_1 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 e : (fun p => deriv (g p.1) (↑(extChartAt I z) p.2)) = (fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2) ⊢ ContinuousAt ((fun p => deriv (g p.1) p.2) ∘ fun p => (p.1, ↑(extChartAt I z) p.2)) (c, z) TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
contrapose f0
case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ deriv (g (c, z).1) (↑(extChartAt I z) (c, z).2) ≠ 0
case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : ¬deriv (g (c, z).1) (↑(extChartAt I z) (c, z).2) ≠ 0 ⊢ ¬mfderiv I I (f c) z ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) f0 : mfderiv I I (f c) z ≠ 0 g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 ⊢ deriv (g (c, z).1) (↑(extChartAt I z) (c, z).2) ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
simp only [not_not, Function.comp] at f0 ⊢
case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : ¬deriv (g (c, z).1) (↑(extChartAt I z) (c, z).2) ≠ 0 ⊢ ¬mfderiv I I (f c) z ≠ 0
case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : deriv (g c) (↑(extChartAt I z) z) = 0 ⊢ mfderiv I I (f c) z = 0
Please generate a tactic in lean4 to solve the state. STATE: case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : ¬deriv (g (c, z).1) (↑(extChartAt I z) (c, z).2) ≠ 0 ⊢ ¬mfderiv I I (f c) z ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
rw [g0.self_of_nhds]
case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : deriv (g c) (↑(extChartAt I z) z) = 0 ⊢ mfderiv I I (f c) z = 0
case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : deriv (g c) (↑(extChartAt I z) z) = 0 ⊢ deriv (inChart f c z (c, z).1) (↑(extChartAt I z) (c, z).2) = 0
Please generate a tactic in lean4 to solve the state. STATE: case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : deriv (g c) (↑(extChartAt I z) z) = 0 ⊢ mfderiv I I (f c) z = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually'
[337, 1]
[352, 23]
exact f0
case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : deriv (g c) (↑(extChartAt I z) z) = 0 ⊢ deriv (inChart f c z (c, z).1) (↑(extChartAt I z) (c, z).2) = 0
no goals
Please generate a tactic in lean4 to solve the state. STATE: case refine_2 S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : ℂ → S → T c : ℂ z : S fa : HolomorphicAt (I.prod I) I (uncurry f) (c, z) g : ℂ → ℂ → ℂ := inChart f c z g0 : ∀ᶠ (p : ℂ × S) in 𝓝 (c, z), mfderiv I I (f p.1) p.2 = 0 ↔ deriv (inChart f c z p.1) (↑(extChartAt I z) p.2) = 0 f0 : deriv (g c) (↑(extChartAt I z) z) = 0 ⊢ deriv (inChart f c z (c, z).1) (↑(extChartAt I z) (c, z).2) = 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually
[355, 1]
[363, 58]
set c : ℂ := 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → T z : S fa : HolomorphicAt I I f z f0 : mfderiv I I f z ≠ 0 ⊢ ∀ᶠ (w : S) in 𝓝 z, mfderiv I I f w ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → T z : S fa : HolomorphicAt I I f z f0 : mfderiv I I f z ≠ 0 c : ℂ := 0 ⊢ ∀ᶠ (w : S) in 𝓝 z, mfderiv I I f w ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → T z : S fa : HolomorphicAt I I f z f0 : mfderiv I I f z ≠ 0 ⊢ ∀ᶠ (w : S) in 𝓝 z, mfderiv I I f w ≠ 0 TACTIC:
https://github.com/girving/ray.git
0be790285dd0fce78913b0cb9bddaffa94bd25f9
Ray/AnalyticManifold/OneDimension.lean
mfderiv_ne_zero_eventually
[355, 1]
[363, 58]
set g : ℂ → S → T := fun _ z ↦ f z
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → T z : S fa : HolomorphicAt I I f z f0 : mfderiv I I f z ≠ 0 c : ℂ := 0 ⊢ ∀ᶠ (w : S) in 𝓝 z, mfderiv I I f w ≠ 0
S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → T z : S fa : HolomorphicAt I I f z f0 : mfderiv I I f z ≠ 0 c : ℂ := 0 g : ℂ → S → T := fun x z => f z ⊢ ∀ᶠ (w : S) in 𝓝 z, mfderiv I I f w ≠ 0
Please generate a tactic in lean4 to solve the state. STATE: S : Type inst✝⁵ : TopologicalSpace S cs : ChartedSpace ℂ S inst✝⁴ : AnalyticManifold I S T : Type inst✝³ : TopologicalSpace T ct : ChartedSpace ℂ T inst✝² : AnalyticManifold I T U : Type inst✝¹ : TopologicalSpace U cu : ChartedSpace ℂ U inst✝ : AnalyticManifold I U f : S → T z : S fa : HolomorphicAt I I f z f0 : mfderiv I I f z ≠ 0 c : ℂ := 0 ⊢ ∀ᶠ (w : S) in 𝓝 z, mfderiv I I f w ≠ 0 TACTIC: