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/- Copyright (c) 2020 Anne Baanen. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anne Baanen, Kexing Ying, Eric Wieser -/ import Mathlib.Data.Finset.Sym import Mathlib.LinearAlgebra.BilinearMap import Mathlib.LinearAlgebra.FiniteDimensional.Lemmas import Mathlib.LinearAlgebra.Matrix.Determinant.Basic import Mathlib.LinearAlgebra.Matrix.SesquilinearForm import Mathlib.LinearAlgebra.Matrix.Symmetric /-! # Quadratic maps This file defines quadratic maps on an `R`-module `M`, taking values in an `R`-module `N`. An `N`-valued quadratic map on a module `M` over a commutative ring `R` is a map `Q : M → N` such that: * `QuadraticMap.map_smul`: `Q (a • x) = (a * a) • Q x` * `QuadraticMap.polar_add_left`, `QuadraticMap.polar_add_right`, `QuadraticMap.polar_smul_left`, `QuadraticMap.polar_smul_right`: the map `QuadraticMap.polar Q := fun x y ↦ Q (x + y) - Q x - Q y` is bilinear. This notion generalizes to commutative semirings using the approach in [izhakian2016][] which requires that there be a (possibly non-unique) companion bilinear map `B` such that `∀ x y, Q (x + y) = Q x + Q y + B x y`. Over a ring, this `B` is precisely `QuadraticMap.polar Q`. To build a `QuadraticMap` from the `polar` axioms, use `QuadraticMap.ofPolar`. Quadratic maps come with a scalar multiplication, `(a • Q) x = a • Q x`, and composition with linear maps `f`, `Q.comp f x = Q (f x)`. ## Main definitions * `QuadraticMap.ofPolar`: a more familiar constructor that works on rings * `QuadraticMap.associated`: associated bilinear map * `QuadraticMap.PosDef`: positive definite quadratic maps * `QuadraticMap.Anisotropic`: anisotropic quadratic maps * `QuadraticMap.discr`: discriminant of a quadratic map * `QuadraticMap.IsOrtho`: orthogonality of vectors with respect to a quadratic map. ## Main statements * `QuadraticMap.associated_left_inverse`, * `QuadraticMap.associated_rightInverse`: in a commutative ring where 2 has an inverse, there is a correspondence between quadratic maps and symmetric bilinear forms * `LinearMap.BilinForm.exists_orthogonal_basis`: There exists an orthogonal basis with respect to any nondegenerate, symmetric bilinear map `B`. ## Notation In this file, the variable `R` is used when a `CommSemiring` structure is available. The variable `S` is used when `R` itself has a `•` action. ## Implementation notes While the definition and many results make sense if we drop commutativity assumptions, the correct definition of a quadratic maps in the noncommutative setting would require substantial refactors from the current version, such that $Q(rm) = rQ(m)r^$ for some suitable conjugation $r^$. The [Zulip thread](https://leanprover.zulipchat.com/#narrow/stream/116395-maths/topic/Quadratic.20Maps/near/395529867) has some further discussion. ## References * https://en.wikipedia.org/wiki/Quadratic_form * https://en.wikipedia.org/wiki/Discriminant#Quadratic_forms ## Tags quadratic map, homogeneous polynomial, quadratic polynomial -/ universe u v w variable {S T : Type} variable {R : Type} {M N P A : Type} open LinearMap (BilinMap BilinForm) section Polar variable [CommRing R] [AddCommGroup M] [AddCommGroup N] namespace QuadraticMap /-- Up to a factor 2, `Q.polar` is the associated bilinear map for a quadratic map `Q`. Source of this name: https://en.wikipedia.org/wiki/Quadratic_form#Generalization -/ def polar (f : M → N) (x y : M) := f (x + y) - f x - f y protected theorem map_add (f : M → N) (x y : M) : f (x + y) = f x + f y + polar f x y := by rw [polar] abel theorem polar_add (f g : M → N) (x y : M) : polar (f + g) x y = polar f x y + polar g x y := by simp only [polar, Pi.add_apply] abel theorem polar_neg (f : M → N) (x y : M) : polar (-f) x y = -polar f x y := by simp only [polar, Pi.neg_apply, sub_eq_add_neg, neg_add] theorem polar_smul [Monoid S] [DistribMulAction S N] (f : M → N) (s : S) (x y : M) : polar (s • f) x y = s • polar f x y := by simp only [polar, Pi.smul_apply, smul_sub] theorem polar_comm (f : M → N) (x y : M) : polar f x y = polar f y x := by rw [polar, polar, add_comm, sub_sub, sub_sub, add_comm (f x) (f y)] /-- Auxiliary lemma to express bilinearity of `QuadraticMap.polar` without subtraction. -/ theorem polar_add_left_iff {f : M → N} {x x' y : M} : polar f (x + x') y = polar f x y + polar f x' y ↔ f (x + x' + y) + (f x + f x' + f y) = f (x + x') + f (x' + y) + f (y + x) := by simp only [← add_assoc] simp only [polar, sub_eq_iff_eq_add, eq_sub_iff_add_eq, sub_add_eq_add_sub, add_sub] simp only [add_right_comm _ (f y) _, add_right_comm _ (f x') (f x)] rw [add_comm y x, add_right_comm _ _ (f (x + y)), add_comm _ (f (x + y)), add_right_comm (f (x + y)), add_left_inj] theorem polar_comp {F : Type} [AddCommGroup S] [FunLike F N S] [AddMonoidHomClass F N S] (f : M → N) (g : F) (x y : M) : polar (g ∘ f) x y = g (polar f x y) := by simp only [polar, Pi.smul_apply, Function.comp_apply, map_sub] /-- `QuadraticMap.polar` as a function from `Sym2`. -/ def polarSym2 (f : M → N) : Sym2 M → N := Sym2.lift ⟨polar f, polar_comm _⟩ @[simp] lemma polarSym2_sym2Mk (f : M → N) (xy : M × M) : polarSym2 f (.mk xy) = polar f xy.1 xy.2 := rfl end QuadraticMap end Polar /-- A quadratic map on a module. For a more familiar constructor when `R` is a ring, see `QuadraticMap.ofPolar`. -/ structure QuadraticMap (R : Type u) (M : Type v) (N : Type w) [CommSemiring R] [AddCommMonoid M] [Module R M] [AddCommMonoid N] [Module R N] where toFun : M → N toFun_smul : ∀ (a : R) (x : M), toFun (a • x) = (a * a) • toFun x exists_companion' : ∃ B : BilinMap R M N, ∀ x y, toFun (x + y) = toFun x + toFun y + B x y section QuadraticForm variable (R : Type u) (M : Type v) [CommSemiring R] [AddCommMonoid M] [Module R M] /-- A quadratic form on a module. -/ abbrev QuadraticForm : Type _ := QuadraticMap R M R end QuadraticForm namespace QuadraticMap section DFunLike variable [CommSemiring R] [AddCommMonoid M] [Module R M] [AddCommMonoid N] [Module R N] variable {Q Q' : QuadraticMap R M N} instance instFunLike : FunLike (QuadraticMap R M N) M N where coe := toFun coe_injective' x y h := by cases x; cases y; congr variable (Q) /-- The `simp` normal form for a quadratic map is `DFunLike.coe`, not `toFun`. -/ @[simp] theorem toFun_eq_coe : Q.toFun = ⇑Q := rfl -- this must come after the coe_to_fun definition initialize_simps_projections QuadraticMap (toFun → apply) variable {Q} @[ext] theorem ext (H : ∀ x : M, Q x = Q' x) : Q = Q' := DFunLike.ext _ _ H theorem congr_fun (h : Q = Q') (x : M) : Q x = Q' x := DFunLike.congr_fun h _ /-- Copy of a `QuadraticMap` with a new `toFun` equal to the old one. Useful to fix definitional equalities. -/ protected def copy (Q : QuadraticMap R M N) (Q' : M → N) (h : Q' = ⇑Q) : QuadraticMap R M N where toFun := Q' toFun_smul := h.symm ▸ Q.toFun_smul exists_companion' := h.symm ▸ Q.exists_companion' @[simp] theorem coe_copy (Q : QuadraticMap R M N) (Q' : M → N) (h : Q' = ⇑Q) : ⇑(Q.copy Q' h) = Q' := rfl theorem copy_eq (Q : QuadraticMap R M N) (Q' : M → N) (h : Q' = ⇑Q) : Q.copy Q' h = Q := DFunLike.ext' h end DFunLike section CommSemiring variable [CommSemiring R] [AddCommMonoid M] [Module R M] [AddCommMonoid N] [Module R N] variable (Q : QuadraticMap R M N) protected theorem map_smul (a : R) (x : M) : Q (a • x) = (a * a) • Q x := Q.toFun_smul a x theorem exists_companion : ∃ B : BilinMap R M N, ∀ x y, Q (x + y) = Q x + Q y + B x y := Q.exists_companion' theorem map_add_add_add_map (x y z : M) : Q (x + y + z) + (Q x + Q y + Q z) = Q (x + y) + Q (y + z) + Q (z + x) := by obtain ⟨B, h⟩ := Q.exists_companion rw [add_comm z x] simp only [h, LinearMap.map_add₂] abel theorem map_add_self (x : M) : Q (x + x) = 4 • Q x := by rw [← two_smul R x, Q.map_smul, ← Nat.cast_smul_eq_nsmul R] norm_num -- not @[simp] because it is superseded by `ZeroHomClass.map_zero` protected theorem map_zero : Q 0 = 0 := by rw [← @zero_smul R _ _ _ _ (0 : M), Q.map_smul, zero_mul, zero_smul] instance zeroHomClass : ZeroHomClass (QuadraticMap R M N) M N := { QuadraticMap.instFunLike (R := R) (M := M) (N := N) with map_zero := QuadraticMap.map_zero } theorem map_smul_of_tower [CommSemiring S] [Algebra S R] [SMul S M] [IsScalarTower S R M] [Module S N] [IsScalarTower S R N] (a : S) (x : M) : Q (a • x) = (a * a) • Q x := by rw [← IsScalarTower.algebraMap_smul R a x, Q.map_smul, ← RingHom.map_mul, algebraMap_smul] end CommSemiring section CommRing variable [CommRing R] [AddCommGroup M] [AddCommGroup N] variable [Module R M] [Module R N] (Q : QuadraticMap R M N) @[simp] protected theorem map_neg (x : M) : Q (-x) = Q x := by rw [← @neg_one_smul R _ _ _ _ x, Q.map_smul, neg_one_mul, neg_neg, one_smul] protected theorem map_sub (x y : M) : Q (x - y) = Q (y - x) := by rw [← neg_sub, Q.map_neg] @[simp] theorem polar_zero_left (y : M) : polar Q 0 y = 0 := by simp only [polar, zero_add, QuadraticMap.map_zero, sub_zero, sub_self] @[simp] theorem polar_add_left (x x' y : M) : polar Q (x + x') y = polar Q x y + polar Q x' y := polar_add_left_iff.mpr <\| Q.map_add_add_add_map x x' y @[simp] theorem polar_smul_left (a : R) (x y : M) : polar Q (a • x) y = a • polar Q x y := by obtain ⟨B, h⟩ := Q.exists_companion simp_rw [polar, h, Q.map_smul, LinearMap.map_smul₂, sub_sub, add_sub_cancel_left] @[simp] theorem polar_neg_left (x y : M) : polar Q (-x) y = -polar Q x y := by rw [← neg_one_smul R x, polar_smul_left, neg_one_smul] @[simp] theorem polar_sub_left (x x' y : M) : polar Q (x - x') y = polar Q x y - polar Q x' y := by rw [sub_eq_add_neg, sub_eq_add_neg, polar_add_left, polar_neg_left] @[simp] theorem polar_zero_right (y : M) : polar Q y 0 = 0 := by simp only [add_zero, polar, QuadraticMap.map_zero, sub_self] @[simp] theorem polar_add_right (x y y' : M) : polar Q x (y + y') = polar Q x y + polar Q x y' := by rw [polar_comm Q x, polar_comm Q x, polar_comm Q x, polar_add_left] @[simp] theorem polar_smul_right (a : R) (x y : M) : polar Q x (a • y) = a • polar Q x y := by rw [polar_comm Q x, polar_comm Q x, polar_smul_left] @[simp] theorem polar_neg_right (x y : M) : polar Q x (-y) = -polar Q x y := by rw [← neg_one_smul R y, polar_smul_right, neg_one_smul] @[simp] theorem polar_sub_right (x y y' : M) : polar Q x (y - y') = polar Q x y - polar Q x y' := by rw [sub_eq_add_neg, sub_eq_add_neg, polar_add_right, polar_neg_right] @[simp] theorem polar_self (x : M) : polar Q x x = 2 • Q x := by rw [polar, map_add_self, sub_sub, sub_eq_iff_eq_add, ← two_smul ℕ, ← two_smul ℕ, ← mul_smul] norm_num /-- `QuadraticMap.polar` as a bilinear map -/ @[simps!] def polarBilin : BilinMap R M N := LinearMap.mk₂ R (polar Q) (polar_add_left Q) (polar_smul_left Q) (polar_add_right Q) (polar_smul_right Q) lemma polarSym2_map_smul {ι} (Q : QuadraticMap R M N) (g : ι → M) (l : ι → R) (p : Sym2 ι) : polarSym2 Q (p.map (l • g)) = (p.map l).mul • polarSym2 Q (p.map g) := by obtain ⟨_, _⟩ := p; simp [← smul_assoc, mul_comm] variable [CommSemiring S] [Algebra S R] [Module S M] [IsScalarTower S R M] [Module S N] [IsScalarTower S R N] @[simp] theorem polar_smul_left_of_tower (a : S) (x y : M) : polar Q (a • x) y = a • polar Q x y := by rw [← IsScalarTower.algebraMap_smul R a x, polar_smul_left, algebraMap_smul] @[simp] theorem polar_smul_right_of_tower (a : S) (x y : M) : polar Q x (a • y) = a • polar Q x y := by rw [← IsScalarTower.algebraMap_smul R a y, polar_smul_right, algebraMap_smul] /-- An alternative constructor to `QuadraticMap.mk`, for rings where `polar` can be used. -/ @[simps] def ofPolar (toFun : M → N) (toFun_smul : ∀ (a : R) (x : M), toFun (a • x) = (a * a) • toFun x) (polar_add_left : ∀ x x' y : M, polar toFun (x + x') y = polar toFun x y + polar toFun x' y) (polar_smul_left : ∀ (a : R) (x y : M), polar toFun (a • x) y = a • polar toFun x y) : QuadraticMap R M N := { toFun toFun_smul exists_companion' := ⟨LinearMap.mk₂ R (polar toFun) (polar_add_left) (polar_smul_left) (fun x _ _ ↦ by simp_rw [polar_comm _ x, polar_add_left]) (fun _ _ _ ↦ by rw [polar_comm, polar_smul_left, polar_comm]), fun _ _ ↦ by simp only [LinearMap.mk₂_apply] rw [polar, sub_sub, add_sub_cancel]⟩ } /-- In a ring the companion bilinear form is unique and equal to `QuadraticMap.polar`. -/ theorem choose_exists_companion : Q.exists_companion.choose = polarBilin Q := LinearMap.ext₂ fun x y => by rw [polarBilin_apply_apply, polar, Q.exists_companion.choose_spec, sub_sub, add_sub_cancel_left] protected theorem map_sum {ι} [DecidableEq ι] (Q : QuadraticMap R M N) (s : Finset ι) (f : ι → M) : Q (∑ i ∈ s, f i) = ∑ i ∈ s, Q (f i) + ∑ ij ∈ s.sym2 with ¬ ij.IsDiag, polarSym2 Q (ij.map f) := by induction s using Finset.cons_induction with \| empty => simp \| cons a s ha ih => simp_rw [Finset.sum_cons, QuadraticMap.map_add, ih, add_assoc, Finset.sym2_cons, Finset.sum_filter, Finset.sum_disjUnion, Finset.sum_map, Finset.sum_cons, Sym2.mkEmbedding_apply, Sym2.isDiag_iff_proj_eq, not_true, if_false, zero_add, Sym2.map_pair_eq, polarSym2_sym2Mk, ← polarBilin_apply_apply, _root_.map_sum, polarBilin_apply_apply] congr 2 rw [add_comm] congr! with i hi rw [if_pos (ne_of_mem_of_not_mem hi ha).symm] protected theorem map_sum' {ι} (Q : QuadraticMap R M N) (s : Finset ι) (f : ι → M) : Q (∑ i ∈ s, f i) = ∑ ij ∈ s.sym2, polarSym2 Q (ij.map f) - ∑ i ∈ s, Q (f i) := by induction s using Finset.cons_induction with \| empty => simp \| cons a s ha ih => simp_rw [Finset.sum_cons, QuadraticMap.map_add Q, ih, add_assoc, Finset.sym2_cons, Finset.sum_disjUnion, Finset.sum_map, Finset.sum_cons, Sym2.mkEmbedding_apply, Sym2.map_pair_eq, polarSym2_sym2Mk, ← polarBilin_apply_apply, _root_.map_sum, polarBilin_apply_apply, polar_self] abel_nf end CommRing section SemiringOperators variable [CommSemiring R] [AddCommMonoid M] [Module R M] [AddCommMonoid N] [Module R N] section SMul variable [Monoid S] [Monoid T] [DistribMulAction S N] [DistribMulAction T N] variable [SMulCommClass S R N] [SMulCommClass T R N] /-- `QuadraticMap R M N` inherits the scalar action from any algebra over `R`. This provides an `R`-action via `Algebra.id`. -/ instance : SMul S (QuadraticMap R M N) := ⟨fun a Q => { toFun := a • ⇑Q toFun_smul := fun b x => by rw [Pi.smul_apply, Q.map_smul, Pi.smul_apply, smul_comm] exists_companion' := let ⟨B, h⟩ := Q.exists_companion letI := SMulCommClass.symm S R N ⟨a • B, by simp [h]⟩ }⟩ @[simp] theorem coeFn_smul (a : S) (Q : QuadraticMap R M N) : ⇑(a • Q) = a • ⇑Q := rfl @[simp] theorem smul_apply (a : S) (Q : QuadraticMap R M N) (x : M) : (a • Q) x = a • Q x := rfl instance [SMulCommClass S T N] : SMulCommClass S T (QuadraticMap R M N) where smul_comm _s _t _q := ext fun _ => smul_comm _ _ _ instance [SMul S T] [IsScalarTower S T N] : IsScalarTower S T (QuadraticMap R M N) where smul_assoc _s _t _q := ext fun _ => smul_assoc _ _ _ end SMul instance : Zero (QuadraticMap R M N) := ⟨{ toFun := fun _ => 0 toFun_smul := fun a _ => by simp only [smul_zero] exists_companion' := ⟨0, fun _ _ => by simp only [add_zero, LinearMap.zero_apply]⟩ }⟩ @[simp] theorem coeFn_zero : ⇑(0 : QuadraticMap R M N) = 0 := rfl @[simp] theorem zero_apply (x : M) : (0 : QuadraticMap R M N) x = 0 := rfl instance : Inhabited (QuadraticMap R M N) := ⟨0⟩ instance : Add (QuadraticMap R M N) := ⟨fun Q Q' => { toFun := Q + Q' toFun_smul := fun a x => by simp only [Pi.add_apply, smul_add, QuadraticMap.map_smul] exists_companion' := let ⟨B, h⟩ := Q.exists_companion let ⟨B', h'⟩ := Q'.exists_companion ⟨B + B', fun x y => by simp_rw [Pi.add_apply, h, h', LinearMap.add_apply, add_add_add_comm]⟩ }⟩ @[simp] theorem coeFn_add (Q Q' : QuadraticMap R M N) : ⇑(Q + Q') = Q + Q' := rfl @[simp] theorem add_apply (Q Q' : QuadraticMap R M N) (x : M) : (Q + Q') x = Q x + Q' x := rfl instance : AddCommMonoid (QuadraticMap R M N) := DFunLike.coe_injective.addCommMonoid _ coeFn_zero coeFn_add fun _ _ => coeFn_smul _ _ /-- `@CoeFn (QuadraticMap R M)` as an `AddMonoidHom`. This API mirrors `AddMonoidHom.coeFn`. -/ @[simps apply] def coeFnAddMonoidHom : QuadraticMap R M N →+ M → N where toFun := DFunLike.coe map_zero' := coeFn_zero map_add' := coeFn_add /-- Evaluation on a particular element of the module `M` is an additive map on quadratic maps. -/ @[simps! apply] def evalAddMonoidHom (m : M) : QuadraticMap R M N →+ N := (Pi.evalAddMonoidHom _ m).comp coeFnAddMonoidHom section Sum @[simp] theorem coeFn_sum {ι : Type} (Q : ι → QuadraticMap R M N) (s : Finset ι) : ⇑(∑ i ∈ s, Q i) = ∑ i ∈ s, ⇑(Q i) := map_sum coeFnAddMonoidHom Q s @[simp] theorem sum_apply {ι : Type} (Q : ι → QuadraticMap R M N) (s : Finset ι) (x : M) : (∑ i ∈ s, Q i) x = ∑ i ∈ s, Q i x := map_sum (evalAddMonoidHom x : _ →+ N) Q s end Sum instance [Monoid S] [DistribMulAction S N] [SMulCommClass S R N] : DistribMulAction S (QuadraticMap R M N) where mul_smul a b Q := ext fun x => by simp only [smul_apply, mul_smul] one_smul Q := ext fun x => by simp only [QuadraticMap.smul_apply, one_smul] smul_add a Q Q' := by ext simp only [add_apply, smul_apply, smul_add] smul_zero a := by ext simp only [zero_apply, smul_apply, smul_zero] instance [Semiring S] [Module S N] [SMulCommClass S R N] : Module S (QuadraticMap R M N) where zero_smul Q := by ext simp only [zero_apply, smul_apply, zero_smul] add_smul a b Q := by ext simp only [add_apply, smul_apply, add_smul] end SemiringOperators section RingOperators variable [CommRing R] [AddCommGroup M] [Module R M] [AddCommGroup N] [Module R N] instance : Neg (QuadraticMap R M N) := ⟨fun Q => { toFun := -Q toFun_smul := fun a x => by simp only [Pi.neg_apply, Q.map_smul, smul_neg] exists_companion' := let ⟨B, h⟩ := Q.exists_companion ⟨-B, fun x y => by simp_rw [Pi.neg_apply, h, LinearMap.neg_apply, neg_add]⟩ }⟩ @[simp] theorem coeFn_neg (Q : QuadraticMap R M N) : ⇑(-Q) = -Q := rfl @[simp] theorem neg_apply (Q : QuadraticMap R M N) (x : M) : (-Q) x = -Q x := rfl instance : Sub (QuadraticMap R M N) := ⟨fun Q Q' => (Q + -Q').copy (Q - Q') (sub_eq_add_neg _ _)⟩ @[simp] theorem coeFn_sub (Q Q' : QuadraticMap R M N) : ⇑(Q - Q') = Q - Q' := rfl @[simp] theorem sub_apply (Q Q' : QuadraticMap R M N) (x : M) : (Q - Q') x = Q x - Q' x := rfl instance : AddCommGroup (QuadraticMap R M N) := DFunLike.coe_injective.addCommGroup _ coeFn_zero coeFn_add coeFn_neg coeFn_sub (fun _ _ => coeFn_smul _ _) fun _ _ => coeFn_smul _ _ end RingOperators section restrictScalars variable [CommSemiring R] [CommSemiring S] [AddCommMonoid M] [Module R M] [AddCommMonoid N] [Module R N] [Module S M] [Module S N] [Algebra S R] variable [IsScalarTower S R M] [IsScalarTower S R N] /-- If `Q : M → N` is a quadratic map of `R`-modules and `R` is an `S`-algebra, then the restriction of scalars is a quadratic map of `S`-modules. -/ @[simps!] def restrictScalars (Q : QuadraticMap R M N) : QuadraticMap S M N where toFun x := Q x toFun_smul a x := by simp [map_smul_of_tower] exists_companion' := let ⟨B, h⟩ := Q.exists_companion ⟨B.restrictScalars₁₂ (S := R) (R' := S) (S' := S), fun x y => by simp only [LinearMap.restrictScalars₁₂_apply_apply, h]⟩ end restrictScalars section Comp variable [CommSemiring R] [AddCommMonoid M] [Module R M] [AddCommMonoid N] [Module R N] variable [AddCommMonoid P] [Module R P] /-- Compose the quadratic map with a linear function on the right. -/ def comp (Q : QuadraticMap R N P) (f : M →ₗ[R] N) : QuadraticMap R M P where toFun x := Q (f x) toFun_smul a x := by simp only [Q.map_smul, map_smul] exists_companion' := let ⟨B, h⟩ := Q.exists_companion ⟨B.compl₁₂ f f, fun x y => by simp_rw [f.map_add]; exact h (f x) (f y)⟩ @[simp] theorem comp_apply (Q : QuadraticMap R N P) (f : M →ₗ[R] N) (x : M) : (Q.comp f) x = Q (f x) := rfl /-- Compose a quadratic map with a linear function on the left. -/ @[simps +simpRhs] def _root_.LinearMap.compQuadraticMap (f : N →ₗ[R] P) (Q : QuadraticMap R M N) : QuadraticMap R M P where toFun x := f (Q x) toFun_smul b x := by simp only [Q.map_smul, map_smul] exists_companion' := let ⟨B, h⟩ := Q.exists_companion ⟨B.compr₂ f, fun x y => by simp only [h, map_add, LinearMap.compr₂_apply]⟩ /-- Compose a quadratic map with a linear function on the left. -/ @[simps! +simpRhs] def _root_.LinearMap.compQuadraticMap' [CommSemiring S] [Algebra S R] [Module S N] [Module S M] [IsScalarTower S R N] [IsScalarTower S R M] [Module S P] (f : N →ₗ[S] P) (Q : QuadraticMap R M N) : QuadraticMap S M P := _root_.LinearMap.compQuadraticMap f Q.restrictScalars /-- When `N` and `P` are equivalent, quadratic maps on `M` into `N` are equivalent to quadratic maps on `M` into `P`. See `LinearMap.BilinMap.congr₂` for the bilinear map version. -/ @[simps] def _root_.LinearEquiv.congrQuadraticMap (e : N ≃ₗ[R] P) : QuadraticMap R M N ≃ₗ[R] QuadraticMap R M P where toFun Q := e.compQuadraticMap Q invFun Q := e.symm.compQuadraticMap Q left_inv _ := ext fun _ => e.symm_apply_apply _ right_inv _ := ext fun _ => e.apply_symm_apply _ map_add' _ _ := ext fun _ => map_add e _ _ map_smul' _ _ := ext fun _ => e.map_smul _ _ @[simp] theorem _root_.LinearEquiv.congrQuadraticMap_refl : LinearEquiv.congrQuadraticMap (.refl R N) = .refl R (QuadraticMap R M N) := rfl @[simp] theorem _root_.LinearEquiv.congrQuadraticMap_symm (e : N ≃ₗ[R] P) : (LinearEquiv.congrQuadraticMap e (M := M)).symm = e.symm.congrQuadraticMap := rfl end Comp section NonUnitalNonAssocSemiring variable [CommSemiring R] [NonUnitalNonAssocSemiring A] [AddCommMonoid M] [Module R M] variable [Module R A] [SMulCommClass R A A] [IsScalarTower R A A] /-- The product of linear maps into an `R`-algebra is a quadratic map. -/ def linMulLin (f g : M →ₗ[R] A) : QuadraticMap R M A where toFun := f * g toFun_smul a x := by rw [Pi.mul_apply, Pi.mul_apply, LinearMap.map_smulₛₗ, RingHom.id_apply, LinearMap.map_smulₛₗ, RingHom.id_apply, smul_mul_assoc, mul_smul_comm, ← smul_assoc, smul_eq_mul] exists_companion' := ⟨(LinearMap.mul R A).compl₁₂ f g + (LinearMap.mul R A).flip.compl₁₂ g f, fun x y => by simp only [Pi.mul_apply, map_add, left_distrib, right_distrib, LinearMap.add_apply, LinearMap.compl₁₂_apply, LinearMap.mul_apply', LinearMap.flip_apply] abel_nf⟩ @[simp] theorem linMulLin_apply (f g : M →ₗ[R] A) (x) : linMulLin f g x = f x * g x := rfl @[simp] theorem add_linMulLin (f g h : M →ₗ[R] A) : linMulLin (f + g) h = linMulLin f h + linMulLin g h := ext fun _ => add_mul _ _ _ @[simp] theorem linMulLin_add (f g h : M →ₗ[R] A) : linMulLin f (g + h) = linMulLin f g + linMulLin f h := ext fun _ => mul_add _ _ _ variable {N' : Type} [AddCommMonoid N'] [Module R N'] @[simp] theorem linMulLin_comp (f g : M →ₗ[R] A) (h : N' →ₗ[R] M) : (linMulLin f g).comp h = linMulLin (f.comp h) (g.comp h) := rfl variable {n : Type} /-- `sq` is the quadratic map sending the vector `x : A` to `x * x` -/ @[simps!] def sq : QuadraticMap R A A := linMulLin LinearMap.id LinearMap.id /-- `proj i j` is the quadratic map sending the vector `x : n → R` to `x i * x j` -/ def proj (i j : n) : QuadraticMap R (n → A) A := linMulLin (@LinearMap.proj _ _ _ (fun _ => A) _ _ i) (@LinearMap.proj _ _ _ (fun _ => A) _ _ j) @[simp] theorem proj_apply (i j : n) (x : n → A) : proj (R := R) i j x = x i * x j := rfl end NonUnitalNonAssocSemiring end QuadraticMap /-! ### Associated bilinear maps If multiplication by 2 is invertible on the target module `N` of `QuadraticMap R M N`, then there is a linear bijection `QuadraticMap.associated` between quadratic maps `Q` over `R` from `M` to `N` and symmetric bilinear maps `B : M →ₗ[R] M →ₗ[R] → N` such that `BilinMap.toQuadraticMap B = Q` (see `QuadraticMap.associated_rightInverse`). The associated bilinear map is half `Q.polarBilin` (see `QuadraticMap.two_nsmul_associated`); this is where the invertibility condition comes from. We spell the condition as `[Invertible (2 : Module.End R N)]`. Note that this makes the bijection available in more cases than the simpler condition `Invertible (2 : R)`, e.g., when `R = ℤ` and `N = ℝ`. -/ namespace LinearMap namespace BilinMap open QuadraticMap open LinearMap (BilinMap) section Semiring variable [CommSemiring R] [AddCommMonoid M] [Module R M] [AddCommMonoid N] [Module R N] variable {N' : Type} [AddCommMonoid N'] [Module R N'] /-- A bilinear map gives a quadratic map by applying the argument twice. -/ def toQuadraticMap (B : BilinMap R M N) : QuadraticMap R M N where toFun x := B x x toFun_smul a x := by simp only [map_smul, LinearMap.smul_apply, smul_smul] exists_companion' := ⟨B + LinearMap.flip B, fun x y => by simp [add_add_add_comm, add_comm]⟩ @[simp] theorem toQuadraticMap_apply (B : BilinMap R M N) (x : M) : B.toQuadraticMap x = B x x := rfl theorem toQuadraticMap_comp_same (B : BilinMap R M N) (f : N' →ₗ[R] M) : BilinMap.toQuadraticMap (B.compl₁₂ f f) = B.toQuadraticMap.comp f := rfl section variable (R M) @[simp] theorem toQuadraticMap_zero : (0 : BilinMap R M N).toQuadraticMap = 0 := rfl end @[simp] theorem toQuadraticMap_add (B₁ B₂ : BilinMap R M N) : (B₁ + B₂).toQuadraticMap = B₁.toQuadraticMap + B₂.toQuadraticMap := rfl @[simp] theorem toQuadraticMap_smul [Monoid S] [DistribMulAction S N] [SMulCommClass S R N] [SMulCommClass R S N] (a : S) (B : BilinMap R M N) : (a • B).toQuadraticMap = a • B.toQuadraticMap := rfl section variable (S R M) /-- `LinearMap.BilinMap.toQuadraticMap` as an additive homomorphism -/ @[simps] def toQuadraticMapAddMonoidHom : (BilinMap R M N) →+ QuadraticMap R M N where toFun := toQuadraticMap map_zero' := toQuadraticMap_zero _ _ map_add' := toQuadraticMap_add /-- `LinearMap.BilinMap.toQuadraticMap` as a linear map -/ @[simps!] def toQuadraticMapLinearMap [Semiring S] [Module S N] [SMulCommClass S R N] [SMulCommClass R S N] : (BilinMap R M N) →ₗ[S] QuadraticMap R M N where toFun := toQuadraticMap map_smul' := toQuadraticMap_smul map_add' := toQuadraticMap_add end @[simp] theorem toQuadraticMap_list_sum (B : List (BilinMap R M N)) : B.sum.toQuadraticMap = (B.map toQuadraticMap).sum := map_list_sum (toQuadraticMapAddMonoidHom R M) B @[simp] theorem toQuadraticMap_multiset_sum (B : Multiset (BilinMap R M N)) : B.sum.toQuadraticMap = (B.map toQuadraticMap).sum := map_multiset_sum (toQuadraticMapAddMonoidHom R M) B @[simp] theorem toQuadraticMap_sum {ι : Type} (s : Finset ι) (B : ι → (BilinMap R M N)) : (∑ i ∈ s, B i).toQuadraticMap = ∑ i ∈ s, (B i).toQuadraticMap := map_sum (toQuadraticMapAddMonoidHom R M) B s @[simp] theorem toQuadraticMap_eq_zero {B : BilinMap R M N} : B.toQuadraticMap = 0 ↔ B.IsAlt := QuadraticMap.ext_iff end Semiring section Ring variable [CommRing R] [AddCommGroup M] [AddCommGroup N] [Module R M] [Module R N] variable {B : BilinMap R M N} @[simp] theorem toQuadraticMap_neg (B : BilinMap R M N) : (-B).toQuadraticMap = -B.toQuadraticMap := rfl @[simp] theorem toQuadraticMap_sub (B₁ B₂ : BilinMap R M N) : (B₁ - B₂).toQuadraticMap = B₁.toQuadraticMap - B₂.toQuadraticMap := rfl theorem polar_toQuadraticMap (x y : M) : polar (toQuadraticMap B) x y = B x y + B y x := by simp only [polar, toQuadraticMap_apply, map_add, add_apply, add_assoc, add_comm (B y x) _, add_sub_cancel_left, sub_eq_add_neg _ (B y y), add_neg_cancel_left] theorem polarBilin_toQuadraticMap : polarBilin (toQuadraticMap B) = B + flip B := LinearMap.ext₂ polar_toQuadraticMap @[simp] theorem _root_.QuadraticMap.toQuadraticMap_polarBilin (Q : QuadraticMap R M N) : toQuadraticMap (polarBilin Q) = 2 • Q := QuadraticMap.ext fun x => (polar_self _ x).trans <\| by simp theorem _root_.QuadraticMap.polarBilin_injective (h : IsUnit (2 : R)) : Function.Injective (polarBilin : QuadraticMap R M N → _) := by intro Q₁ Q₂ h₁₂ apply h.smul_left_cancel.mp rw [show (2 : R) = (2 : ℕ) by rfl] simp_rw [Nat.cast_smul_eq_nsmul R, ← QuadraticMap.toQuadraticMap_polarBilin] exact congrArg toQuadraticMap h₁₂ section variable {N' : Type} [AddCommGroup N'] [Module R N'] theorem _root_.QuadraticMap.polarBilin_comp (Q : QuadraticMap R N' N) (f : M →ₗ[R] N') : polarBilin (Q.comp f) = LinearMap.compl₁₂ (polarBilin Q) f f := LinearMap.ext₂ <\| fun x y => by simp [polar] end variable {N' : Type} [AddCommGroup N'] theorem _root_.LinearMap.compQuadraticMap_polar [CommSemiring S] [Algebra S R] [Module S N] [Module S N'] [IsScalarTower S R N] [Module S M] [IsScalarTower S R M] (f : N →ₗ[S] N') (Q : QuadraticMap R M N) (x y : M) : polar (f.compQuadraticMap' Q) x y = f (polar Q x y) := by simp [polar] variable [Module R N'] theorem _root_.LinearMap.compQuadraticMap_polarBilin (f : N →ₗ[R] N') (Q : QuadraticMap R M N) : (f.compQuadraticMap' Q).polarBilin = Q.polarBilin.compr₂ f := by ext rw [polarBilin_apply_apply, compr₂_apply, polarBilin_apply_apply, LinearMap.compQuadraticMap_polar] end Ring end BilinMap end LinearMap namespace QuadraticMap open LinearMap (BilinMap) section variable [Semiring R] [AddCommMonoid M] [Module R M] instance : SMulCommClass R (Submonoid.center R) M where smul_comm r r' m := by simp_rw [Submonoid.smul_def, smul_smul, (Set.mem_center_iff.1 r'.prop).1] /-- If `2` is invertible in `R`, then it is also invertible in `End R M`. -/ instance [Invertible (2 : R)] : Invertible (2 : Module.End R M) where invOf := (⟨⅟2, Set.invOf_mem_center (Set.ofNat_mem_center _ _)⟩ : Submonoid.center R) • (1 : Module.End R M) invOf_mul_self := by ext m dsimp [Submonoid.smul_def] rw [← ofNat_smul_eq_nsmul R, invOf_smul_smul (2 : R) m] mul_invOf_self := by ext m dsimp [Submonoid.smul_def] rw [← ofNat_smul_eq_nsmul R, smul_invOf_smul (2 : R) m] /-- If `2` is invertible in `R`, then applying the inverse of `2` in `End R M` to an element of `M` is the same as multiplying by the inverse of `2` in `R`. -/ @[simp] lemma half_moduleEnd_apply_eq_half_smul [Invertible (2 : R)] (x : M) : ⅟ (2 : Module.End R M) x = ⅟ (2 : R) • x := rfl end section AssociatedHom variable [CommRing R] [AddCommGroup M] [Module R M] variable [AddCommGroup N] [Module R N] variable (S) [CommSemiring S] [Algebra S R] [Module S N] [IsScalarTower S R N] -- the requirement that multiplication by `2` is invertible on the target module `N` variable [Invertible (2 : Module.End R N)] /-- `associatedHom` is the map that sends a quadratic map on a module `M` over `R` to its associated symmetric bilinear map. As provided here, this has the structure of an `S`-linear map where `S` is a commutative ring and `R` is an `S`-algebra. Over a commutative ring, use `QuadraticMap.associated`, which gives an `R`-linear map. Over a general ring with no nontrivial distinguished commutative subring, use `QuadraticMap.associated'`, which gives an additive homomorphism (or more precisely a `ℤ`-linear map.) -/ def associatedHom : QuadraticMap R M N →ₗ[S] (BilinMap R M N) where toFun Q := ⅟ (2 : Module.End R N) • polarBilin Q map_add' _ _ := LinearMap.ext₂ fun _ _ ↦ by simp [polar_add] map_smul' _ _ := LinearMap.ext₂ fun _ _ ↦ by simp [polar_smul] variable (Q : QuadraticMap R M N) @[simp] theorem associated_apply (x y : M) : associatedHom S Q x y = ⅟ (2 : Module.End R N) • (Q (x + y) - Q x - Q y) := rfl /-- Twice the associated bilinear map of `Q` is the same as the polar of `Q`. -/ @[simp] theorem two_nsmul_associated : 2 • associatedHom S Q = Q.polarBilin := by ext dsimp rw [← LinearMap.smul_apply, nsmul_eq_mul, Nat.cast_ofNat, mul_invOf_self', Module.End.one_apply, polar] theorem associated_isSymm (Q : QuadraticMap R M N) (x y : M) : associatedHom S Q x y = associatedHom S Q y x := by simp only [associated_apply, sub_eq_add_neg, add_assoc, add_comm, add_left_comm] theorem _root_.QuadraticForm.associated_isSymm (Q : QuadraticForm R M) [Invertible (2 : R)] : (associatedHom S Q).IsSymm := QuadraticMap.associated_isSymm S Q /-- A version of `QuadraticMap.associated_isSymm` for general targets (using `flip` because `IsSymm` does not apply here). -/ lemma associated_flip : (associatedHom S Q).flip = associatedHom S Q := by ext simp only [LinearMap.flip_apply, associated_apply, add_comm, sub_eq_add_neg, add_left_comm, add_assoc] @[simp] theorem associated_comp {N' : Type*} [AddCommGroup N'] [Module R N'] (f : N' →ₗ[R] M) : associatedHom S (Q.comp f) = (associatedHom S Q).compl₁₂ f f := by ext simp only [associated_apply, comp_apply, map_add, LinearMap.compl₁₂_apply] theorem associated_toQuadraticMap (B : BilinMap R M N) (x y : M) : associatedHom S B.toQuadraticMap x y = ⅟ (2 : Module.End R N) • (B x y + B y x) := by simp only [associated_apply, BilinMap.toQuadraticMap_apply, map_add, LinearMap.add_apply, Module.End.smul_def, map_sub] abel_nf theorem associated_left_inverse {B₁ : BilinMap R M N} (h : ∀ x y, B₁ x y = B₁ y x) : associatedHom S B₁.toQuadraticMap = B₁ := LinearMap.ext₂ fun x y ↦ by rw [associated_toQuadraticMap, ← h x y, ← two_smul R, invOf_smul_eq_iff, two_smul, two_smul] /-- A version of `QuadraticMap.associated_left_inverse` for general targets. -/ lemma associated_left_inverse' {B₁ : BilinMap R M N} (hB₁ : B₁.flip = B₁) : associatedHom S B₁.toQuadraticMap = B₁ := by ext _ y rw [associated_toQuadraticMap, ← LinearMap.flip_apply _ y, hB₁, invOf_smul_eq_iff, two_smul] theorem associated_eq_self_apply (x : M) : associatedHom S Q x x = Q x := by rw [associated_apply, map_add_self, ← three_add_one_eq_four, ← two_add_one_eq_three, add_smul, add_smul, one_smul, add_sub_cancel_right, add_sub_cancel_right, two_smul, ← two_smul R, invOf_smul_eq_iff, two_smul, two_smul] theorem toQuadraticMap_associated : (associatedHom S Q).toQuadraticMap = Q := QuadraticMap.ext <\| associated_eq_self_apply S Q -- note: usually `rightInverse` lemmas are named the other way around, but this is consistent -- with historical naming in this file. theorem associated_rightInverse : Function.RightInverse (associatedHom S) (BilinMap.toQuadraticMap : _ → QuadraticMap R M N) := toQuadraticMap_associated S /-- `associated'` is the `ℤ`-linear map that sends a quadratic form on a module `M` over `R` to its associated symmetric bilinear form. -/ abbrev associated' : QuadraticMap R M N →ₗ[ℤ] BilinMap R M N := associatedHom ℤ /-- Symmetric bilinear forms can be lifted to quadratic forms -/ instance canLift [Invertible (2 : R)] : CanLift (BilinMap R M R) (QuadraticForm R M) (associatedHom ℕ) LinearMap.IsSymm where prf B hB := ⟨B.toQuadraticMap, associated_left_inverse _ hB⟩ /-- Symmetric bilinear maps can be lifted to quadratic maps -/ instance canLift' : CanLift (BilinMap R M N) (QuadraticMap R M N) (associatedHom ℕ) fun B ↦ B.flip = B where prf B hB := ⟨B.toQuadraticMap, associated_left_inverse' _ hB⟩ /-- There exists a non-null vector with respect to any quadratic form `Q` whose associated bilinear form is non-zero, i.e. there exists `x` such that `Q x ≠ 0`. -/ theorem exists_quadraticMap_ne_zero {Q : QuadraticMap R M N} -- Porting note: added implicit argument (hB₁ : associated' (N := N) Q ≠ 0) : ∃ x, Q x ≠ 0 := by rw [← not_forall] intro h apply hB₁ rw [(QuadraticMap.ext h : Q = 0), LinearMap.map_zero] end AssociatedHom section Associated variable [CommSemiring S] [CommRing R] [AddCommGroup M] [Algebra S R] [Module R M] variable [AddCommGroup N] [Module R N] [Module S N] [IsScalarTower S R N]	variable [Invertible (2 : Module.End R N)] -- Note: When possible, rather than writing lemmas about `associated`, write a lemma applying to	Mathlib/LinearAlgebra/QuadraticForm/Basic.lean	986	988
/- Copyright (c) 2021 Eric Rodriguez. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Eric Rodriguez -/ import Mathlib.Algebra.Notation.Defs import Mathlib.Logic.Basic import Mathlib.Order.Defs.PartialOrder /-! # `NeZero` typeclass We give basic facts about the `NeZero n` typeclass. -/ variable {R : Type} [Zero R] theorem not_neZero {n : R} : ¬NeZero n ↔ n = 0 := by simp [neZero_iff] theorem eq_zero_or_neZero (a : R) : a = 0 ∨ NeZero a := (eq_or_ne a 0).imp_right NeZero.mk section variable {α : Type} [Zero α] @[simp] lemma zero_ne_one [One α] [NeZero (1 : α)] : (0 : α) ≠ 1 := NeZero.ne' (1 : α) @[simp] lemma one_ne_zero [One α] [NeZero (1 : α)] : (1 : α) ≠ 0 := NeZero.ne (1 : α) lemma ne_zero_of_eq_one [One α] [NeZero (1 : α)] {a : α} (h : a = 1) : a ≠ 0 := h ▸ one_ne_zero @[field_simps] lemma two_ne_zero [OfNat α 2] [NeZero (2 : α)] : (2 : α) ≠ 0 := NeZero.ne (2 : α) @[field_simps] lemma three_ne_zero [OfNat α 3] [NeZero (3 : α)] : (3 : α) ≠ 0 := NeZero.ne (3 : α) @[field_simps] lemma four_ne_zero [OfNat α 4] [NeZero (4 : α)] : (4 : α) ≠ 0 := NeZero.ne (4 : α) variable (α) lemma zero_ne_one' [One α] [NeZero (1 : α)] : (0 : α) ≠ 1 := zero_ne_one		Mathlib/Algebra/NeZero.lean	45	45
/- Copyright (c) 2021 Anne Baanen. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anne Baanen, Ashvni Narayanan -/ import Mathlib.FieldTheory.RatFunc.Degree import Mathlib.RingTheory.DedekindDomain.IntegralClosure import Mathlib.RingTheory.IntegralClosure.IntegrallyClosed import Mathlib.Topology.Algebra.Valued.ValuedField /-! # Function fields This file defines a function field and the ring of integers corresponding to it. ## Main definitions - `FunctionField Fq F` states that `F` is a function field over the (finite) field `Fq`, i.e. it is a finite extension of the field of rational functions in one variable over `Fq`. - `FunctionField.ringOfIntegers` defines the ring of integers corresponding to a function field as the integral closure of `Fq[X]` in the function field. - `FunctionField.inftyValuation` : The place at infinity on `Fq(t)` is the nonarchimedean valuation on `Fq(t)` with uniformizer `1/t`. - `FunctionField.FqtInfty` : The completion `Fq((t⁻¹))` of `Fq(t)` with respect to the valuation at infinity. ## Implementation notes The definitions that involve a field of fractions choose a canonical field of fractions, but are independent of that choice. We also omit assumptions like `Finite Fq` or `IsScalarTower Fq[X] (FractionRing Fq[X]) F` in definitions, adding them back in lemmas when they are needed. ## References * [D. Marcus, Number Fields][marcus1977number] * [J.W.S. Cassels, A. Fröhlich, Algebraic Number Theory][cassels1967algebraic] * [P. Samuel, Algebraic Theory of Numbers][samuel1967] ## Tags function field, ring of integers -/ noncomputable section open scoped nonZeroDivisors Polynomial Multiplicative variable (Fq F : Type) [Field Fq] [Field F] /-- `F` is a function field over the finite field `Fq` if it is a finite extension of the field of rational functions in one variable over `Fq`. Note that `F` can be a function field over multiple, non-isomorphic, `Fq`. -/ abbrev FunctionField [Algebra (RatFunc Fq) F] : Prop := FiniteDimensional (RatFunc Fq) F /-- `F` is a function field over `Fq` iff it is a finite extension of `Fq(t)`. -/ theorem functionField_iff (Fqt : Type) [Field Fqt] [Algebra Fq[X] Fqt] [IsFractionRing Fq[X] Fqt] [Algebra (RatFunc Fq) F] [Algebra Fqt F] [Algebra Fq[X] F] [IsScalarTower Fq[X] Fqt F] [IsScalarTower Fq[X] (RatFunc Fq) F] : FunctionField Fq F ↔ FiniteDimensional Fqt F := by let e := IsLocalization.algEquiv Fq[X]⁰ (RatFunc Fq) Fqt have : ∀ (c) (x : F), e c • x = c • x := by intro c x rw [Algebra.smul_def, Algebra.smul_def] congr refine congr_fun (f := fun c => algebraMap Fqt F (e c)) ?_ c refine IsLocalization.ext (nonZeroDivisors Fq[X]) _ _ ?_ ?_ ?_ ?_ ?_ <;> intros <;> simp only [map_one, map_mul, AlgEquiv.commutes, ← IsScalarTower.algebraMap_apply] constructor <;> intro h · let b := Module.finBasis (RatFunc Fq) F exact FiniteDimensional.of_fintype_basis (b.mapCoeffs e this) · let b := Module.finBasis Fqt F refine FiniteDimensional.of_fintype_basis (b.mapCoeffs e.symm ?_) intro c x; convert (this (e.symm c) x).symm; simp only [e.apply_symm_apply] namespace FunctionField theorem algebraMap_injective [Algebra Fq[X] F] [Algebra (RatFunc Fq) F] [IsScalarTower Fq[X] (RatFunc Fq) F] : Function.Injective (⇑(algebraMap Fq[X] F)) := by rw [IsScalarTower.algebraMap_eq Fq[X] (RatFunc Fq) F] exact (algebraMap (RatFunc Fq) F).injective.comp (IsFractionRing.injective Fq[X] (RatFunc Fq)) @[deprecated (since := "2025-03-03")] alias _root_.algebraMap_injective := FunctionField.algebraMap_injective /-- The function field analogue of `NumberField.ringOfIntegers`: `FunctionField.ringOfIntegers Fq Fqt F` is the integral closure of `Fq[t]` in `F`. We don't actually assume `F` is a function field over `Fq` in the definition, only when proving its properties. -/ def ringOfIntegers [Algebra Fq[X] F] := integralClosure Fq[X] F namespace ringOfIntegers variable [Algebra Fq[X] F] instance : IsDomain (ringOfIntegers Fq F) := (ringOfIntegers Fq F).isDomain instance : IsIntegralClosure (ringOfIntegers Fq F) Fq[X] F := integralClosure.isIntegralClosure _ _ variable [Algebra (RatFunc Fq) F] [IsScalarTower Fq[X] (RatFunc Fq) F] theorem algebraMap_injective : Function.Injective (⇑(algebraMap Fq[X] (ringOfIntegers Fq F))) := by have hinj : Function.Injective (⇑(algebraMap Fq[X] F)) := by rw [IsScalarTower.algebraMap_eq Fq[X] (RatFunc Fq) F] exact (algebraMap (RatFunc Fq) F).injective.comp (IsFractionRing.injective Fq[X] (RatFunc Fq)) rw [injective_iff_map_eq_zero (algebraMap Fq[X] (↥(ringOfIntegers Fq F)))] intro p hp rw [← Subtype.coe_inj, Subalgebra.coe_zero] at hp rw [injective_iff_map_eq_zero (algebraMap Fq[X] F)] at hinj exact hinj p hp theorem not_isField : ¬IsField (ringOfIntegers Fq F) := by simpa [← (IsIntegralClosure.isIntegral_algebra Fq[X] F).isField_iff_isField (algebraMap_injective Fq F)] using Polynomial.not_isField Fq variable [FunctionField Fq F] instance : IsFractionRing (ringOfIntegers Fq F) F := integralClosure.isFractionRing_of_finite_extension (RatFunc Fq) F instance : IsIntegrallyClosed (ringOfIntegers Fq F) := integralClosure.isIntegrallyClosedOfFiniteExtension (RatFunc Fq) instance [Algebra.IsSeparable (RatFunc Fq) F] : IsNoetherian Fq[X] (ringOfIntegers Fq F) := IsIntegralClosure.isNoetherian _ (RatFunc Fq) F _ instance [Algebra.IsSeparable (RatFunc Fq) F] : IsDedekindDomain (ringOfIntegers Fq F) := IsIntegralClosure.isDedekindDomain Fq[X] (RatFunc Fq) F _ end ringOfIntegers /-! ### The place at infinity on Fq(t) -/ section InftyValuation variable [DecidableEq (RatFunc Fq)] /-- The valuation at infinity is the nonarchimedean valuation on `Fq(t)` with uniformizer `1/t`. Explicitly, if `f/g ∈ Fq(t)` is a nonzero quotient of polynomials, its valuation at infinity is `Multiplicative.ofAdd(degree(f) - degree(g))`. -/ def inftyValuationDef (r : RatFunc Fq) : ℤₘ₀ := if r = 0 then 0 else ↑(Multiplicative.ofAdd r.intDegree) theorem InftyValuation.map_zero' : inftyValuationDef Fq 0 = 0 := if_pos rfl theorem InftyValuation.map_one' : inftyValuationDef Fq 1 = 1 := (if_neg one_ne_zero).trans <\| by rw [RatFunc.intDegree_one, ofAdd_zero, WithZero.coe_one] theorem InftyValuation.map_mul' (x y : RatFunc Fq) : inftyValuationDef Fq (x * y) = inftyValuationDef Fq x * inftyValuationDef Fq y := by rw [inftyValuationDef, inftyValuationDef, inftyValuationDef] by_cases hx : x = 0 · rw [hx, zero_mul, if_pos (Eq.refl _), zero_mul] · by_cases hy : y = 0	· rw [hy, mul_zero, if_pos (Eq.refl _), mul_zero] · rw [if_neg hx, if_neg hy, if_neg (mul_ne_zero hx hy), ← WithZero.coe_mul, WithZero.coe_inj,	Mathlib/NumberTheory/FunctionField.lean	163	164
/- Copyright (c) 2022 Andrew Yang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.CategoryTheory.Extensive import Mathlib.CategoryTheory.Limits.Shapes.KernelPair import Mathlib.CategoryTheory.Limits.Constructions.EpiMono /-! # Adhesive categories ## Main definitions - `CategoryTheory.IsPushout.IsVanKampen`: A convenience formulation for a pushout being a van Kampen colimit. - `CategoryTheory.Adhesive`: A category is adhesive if it has pushouts and pullbacks along monomorphisms, and such pushouts are van Kampen. ## Main Results - `CategoryTheory.Type.adhesive`: The category of `Type` is adhesive. - `CategoryTheory.Adhesive.isPullback_of_isPushout_of_mono_left`: In adhesive categories, pushouts along monomorphisms are pullbacks. - `CategoryTheory.Adhesive.mono_of_isPushout_of_mono_left`: In adhesive categories, monomorphisms are stable under pushouts. - `CategoryTheory.Adhesive.toRegularMonoCategory`: Monomorphisms in adhesive categories are regular (this implies that adhesive categories are balanced). - `CategoryTheory.adhesive_functor`: The category `C ⥤ D` is adhesive if `D` has all pullbacks and all pushouts and is adhesive ## References - https://ncatlab.org/nlab/show/adhesive+category - [Stephen Lack and Paweł Sobociński, Adhesive Categories][adhesive2004] -/ namespace CategoryTheory open Limits universe v' u' v u variable {J : Type v'} [Category.{u'} J] {C : Type u} [Category.{v} C] variable {W X Y Z : C} {f : W ⟶ X} {g : W ⟶ Y} {h : X ⟶ Z} {i : Y ⟶ Z} -- This only makes sense when the original diagram is a pushout. /-- A convenience formulation for a pushout being a van Kampen colimit. See `IsPushout.isVanKampen_iff` below. -/ @[nolint unusedArguments] def IsPushout.IsVanKampen (_ : IsPushout f g h i) : Prop := ∀ ⦃W' X' Y' Z' : C⦄ (f' : W' ⟶ X') (g' : W' ⟶ Y') (h' : X' ⟶ Z') (i' : Y' ⟶ Z') (αW : W' ⟶ W) (αX : X' ⟶ X) (αY : Y' ⟶ Y) (αZ : Z' ⟶ Z) (_ : IsPullback f' αW αX f) (_ : IsPullback g' αW αY g) (_ : CommSq h' αX αZ h) (_ : CommSq i' αY αZ i) (_ : CommSq f' g' h' i'), IsPushout f' g' h' i' ↔ IsPullback h' αX αZ h ∧ IsPullback i' αY αZ i theorem IsPushout.IsVanKampen.flip {H : IsPushout f g h i} (H' : H.IsVanKampen) : H.flip.IsVanKampen := by introv W' hf hg hh hi w simpa only [IsPushout.flip_iff, IsPullback.flip_iff, and_comm] using H' g' f' i' h' αW αY αX αZ hg hf hi hh w.flip theorem IsPushout.isVanKampen_iff (H : IsPushout f g h i) : H.IsVanKampen ↔ IsVanKampenColimit (PushoutCocone.mk h i H.w) := by constructor · intro H F' c' α fα eα hα refine Iff.trans ?_ ((H (F'.map WalkingSpan.Hom.fst) (F'.map WalkingSpan.Hom.snd) (c'.ι.app _) (c'.ι.app _) (α.app _) (α.app _) (α.app _) fα (by convert hα WalkingSpan.Hom.fst) (by convert hα WalkingSpan.Hom.snd) ?_ ?_ ?_).trans ?_) · have : F'.map WalkingSpan.Hom.fst ≫ c'.ι.app WalkingSpan.left = F'.map WalkingSpan.Hom.snd ≫ c'.ι.app WalkingSpan.right := by simp only [Cocone.w] rw [(IsColimit.equivOfNatIsoOfIso (diagramIsoSpan F') c' (PushoutCocone.mk _ _ this) _).nonempty_congr] · exact ⟨fun h => ⟨⟨this⟩, h⟩, fun h => h.2⟩ · refine Cocones.ext (Iso.refl c'.pt) ?_ rintro (_ \| _ \| _) <;> dsimp <;> simp only [c'.w, Category.assoc, Category.id_comp, Category.comp_id] · exact ⟨NatTrans.congr_app eα.symm _⟩ · exact ⟨NatTrans.congr_app eα.symm _⟩ · exact ⟨by simp⟩ constructor · rintro ⟨h₁, h₂⟩ (_ \| _ \| _) · rw [← c'.w WalkingSpan.Hom.fst]; exact (hα WalkingSpan.Hom.fst).paste_horiz h₁ exacts [h₁, h₂] · intro h; exact ⟨h _, h _⟩ · introv H W' hf hg hh hi w refine Iff.trans ?_ ((H w.cocone ⟨by rintro (_ \| _ \| _); exacts [αW, αX, αY], ?_⟩ αZ ?_ ?_).trans ?_) rotate_left · rintro i _ (_ \| _ \| _) · dsimp; simp only [Functor.map_id, Category.comp_id, Category.id_comp] exacts [hf.w, hg.w] · ext (_ \| _ \| _) · dsimp rw [PushoutCocone.condition_zero, Category.assoc] erw [hh.w] rw [hf.w_assoc] exacts [hh.w.symm, hi.w.symm] · rintro i _ (_ \| _ \| _) · dsimp; simp_rw [Functor.map_id] exact IsPullback.of_horiz_isIso ⟨by rw [Category.comp_id, Category.id_comp]⟩ exacts [hf, hg] · constructor · intro h; exact ⟨h WalkingCospan.left, h WalkingCospan.right⟩ · rintro ⟨h₁, h₂⟩ (_ \| _ \| _) · dsimp; rw [PushoutCocone.condition_zero]; exact hf.paste_horiz h₁ exacts [h₁, h₂] · exact ⟨fun h => h.2, fun h => ⟨w, h⟩⟩ theorem is_coprod_iff_isPushout {X E Y YE : C} (c : BinaryCofan X E) (hc : IsColimit c) {f : X ⟶ Y} {iY : Y ⟶ YE} {fE : c.pt ⟶ YE} (H : CommSq f c.inl iY fE) : Nonempty (IsColimit (BinaryCofan.mk (c.inr ≫ fE) iY)) ↔ IsPushout f c.inl iY fE := by constructor · rintro ⟨h⟩ refine ⟨H, ⟨Limits.PushoutCocone.isColimitAux' _ ?_⟩⟩ intro s dsimp only [PushoutCocone.inr, PushoutCocone.mk] -- Porting note: Originally `dsimp` refine ⟨h.desc (BinaryCofan.mk (c.inr ≫ s.inr) s.inl), h.fac _ ⟨WalkingPair.right⟩, ?_, ?_⟩ · apply BinaryCofan.IsColimit.hom_ext hc · rw [← H.w_assoc]; erw [h.fac _ ⟨WalkingPair.right⟩]; exact s.condition · rw [← Category.assoc]; exact h.fac _ ⟨WalkingPair.left⟩ · intro m e₁ e₂ apply BinaryCofan.IsColimit.hom_ext h · dsimp only [BinaryCofan.mk, id] -- Porting note: Originally `dsimp` rw [Category.assoc, e₂, eq_comm]; exact h.fac _ ⟨WalkingPair.left⟩ · refine e₁.trans (Eq.symm ?_); exact h.fac _ _ · refine fun H => ⟨?_⟩ fapply Limits.BinaryCofan.isColimitMk · exact fun s => H.isColimit.desc (PushoutCocone.mk s.inr _ <\| (hc.fac (BinaryCofan.mk (f ≫ s.inr) s.inl) ⟨WalkingPair.left⟩).symm) · intro s rw [Category.assoc] erw [H.isColimit.fac _ WalkingSpan.right] erw [hc.fac] rfl · intro s; exact H.isColimit.fac _ WalkingSpan.left · intro s m e₁ e₂ apply PushoutCocone.IsColimit.hom_ext H.isColimit · symm; exact (H.isColimit.fac _ WalkingSpan.left).trans e₂.symm · rw [H.isColimit.fac _ WalkingSpan.right] apply BinaryCofan.IsColimit.hom_ext hc · erw [hc.fac] erw [← H.w_assoc] rw [e₂] rfl · refine ((Category.assoc _ _ _).symm.trans e₁).trans ?_; symm; exact hc.fac _ _ theorem IsPushout.isVanKampen_inl {W E X Z : C} (c : BinaryCofan W E) [FinitaryExtensive C] [HasPullbacks C] (hc : IsColimit c) (f : W ⟶ X) (h : X ⟶ Z) (i : c.pt ⟶ Z) (H : IsPushout f c.inl h i) : H.IsVanKampen := by obtain ⟨hc₁⟩ := (is_coprod_iff_isPushout c hc H.1).mpr H introv W' hf hg hh hi w obtain ⟨hc₂⟩ := ((BinaryCofan.isVanKampen_iff _).mp (FinitaryExtensive.vanKampen c hc) (BinaryCofan.mk _ (pullback.fst _ _)) _ _ _ hg.w.symm pullback.condition.symm).mpr ⟨hg, IsPullback.of_hasPullback αY c.inr⟩ refine (is_coprod_iff_isPushout _ hc₂ w).symm.trans ?_ refine ((BinaryCofan.isVanKampen_iff _).mp (FinitaryExtensive.vanKampen _ hc₁) (BinaryCofan.mk _ _) (pullback.snd _ _) _ _ ?_ hh.w.symm).trans ?_ · dsimp; rw [← pullback.condition_assoc, Category.assoc, hi.w] constructor · rintro ⟨hc₃, hc₄⟩ refine ⟨hc₄, ?_⟩ let Y'' := pullback αZ i let cmp : Y' ⟶ Y'' := pullback.lift i' αY hi.w have e₁ : (g' ≫ cmp) ≫ pullback.snd _ _ = αW ≫ c.inl := by rw [Category.assoc, pullback.lift_snd, hg.w] have e₂ : (pullback.fst _ _ ≫ cmp : pullback αY c.inr ⟶ _) ≫ pullback.snd _ _ = pullback.snd _ _ ≫ c.inr := by rw [Category.assoc, pullback.lift_snd, pullback.condition] obtain ⟨hc₄⟩ := ((BinaryCofan.isVanKampen_iff _).mp (FinitaryExtensive.vanKampen c hc) (BinaryCofan.mk _ _) αW _ _ e₁.symm e₂.symm).mpr <\| by constructor · apply IsPullback.of_right _ e₁ (IsPullback.of_hasPullback _ _) rw [Category.assoc, pullback.lift_fst, ← H.w, ← w.w]; exact hf.paste_horiz hc₄ · apply IsPullback.of_right _ e₂ (IsPullback.of_hasPullback _ _) rw [Category.assoc, pullback.lift_fst]; exact hc₃ rw [← Category.id_comp αZ, ← show cmp ≫ pullback.snd _ _ = αY from pullback.lift_snd _ _ _] apply IsPullback.paste_vert _ (IsPullback.of_hasPullback αZ i) have : cmp = (hc₂.coconePointUniqueUpToIso hc₄).hom := by apply BinaryCofan.IsColimit.hom_ext hc₂ exacts [(hc₂.comp_coconePointUniqueUpToIso_hom hc₄ ⟨WalkingPair.left⟩).symm, (hc₂.comp_coconePointUniqueUpToIso_hom hc₄ ⟨WalkingPair.right⟩).symm] rw [this] exact IsPullback.of_vert_isIso ⟨by rw [← this, Category.comp_id, pullback.lift_fst]⟩ · rintro ⟨hc₃, hc₄⟩ exact ⟨(IsPullback.of_hasPullback αY c.inr).paste_horiz hc₄, hc₃⟩ theorem IsPushout.IsVanKampen.isPullback_of_mono_left [Mono f] {H : IsPushout f g h i} (H' : H.IsVanKampen) : IsPullback f g h i := ((H' (𝟙 _) g g (𝟙 Y) (𝟙 _) f (𝟙 _) i (IsKernelPair.id_of_mono f) (IsPullback.of_vert_isIso ⟨by simp⟩) H.1.flip ⟨rfl⟩ ⟨by simp⟩).mp (IsPushout.of_horiz_isIso ⟨by simp⟩)).1.flip theorem IsPushout.IsVanKampen.isPullback_of_mono_right [Mono g] {H : IsPushout f g h i} (H' : H.IsVanKampen) : IsPullback f g h i := ((H' f (𝟙 _) (𝟙 _) f (𝟙 _) (𝟙 _) g h (IsPullback.of_vert_isIso ⟨by simp⟩) (IsKernelPair.id_of_mono g) ⟨rfl⟩ H.1 ⟨by simp⟩).mp (IsPushout.of_vert_isIso ⟨by simp⟩)).2 theorem IsPushout.IsVanKampen.mono_of_mono_left [Mono f] {H : IsPushout f g h i} (H' : H.IsVanKampen) : Mono i := IsKernelPair.mono_of_isIso_fst ((H' (𝟙 _) g g (𝟙 Y) (𝟙 _) f (𝟙 _) i (IsKernelPair.id_of_mono f) (IsPullback.of_vert_isIso ⟨by simp⟩) H.1.flip ⟨rfl⟩ ⟨by simp⟩).mp (IsPushout.of_horiz_isIso ⟨by simp⟩)).2 theorem IsPushout.IsVanKampen.mono_of_mono_right [Mono g] {H : IsPushout f g h i} (H' : H.IsVanKampen) : Mono h := IsKernelPair.mono_of_isIso_fst ((H' f (𝟙 _) (𝟙 _) f (𝟙 _) (𝟙 _) g h (IsPullback.of_vert_isIso ⟨by simp⟩) (IsKernelPair.id_of_mono g) ⟨rfl⟩ H.1 ⟨by simp⟩).mp (IsPushout.of_vert_isIso ⟨by simp⟩)).1 /-- A category is adhesive if it has pushouts and pullbacks along monomorphisms, and such pushouts are van Kampen. -/ class Adhesive (C : Type u) [Category.{v} C] : Prop where [hasPullback_of_mono_left : ∀ {X Y S : C} (f : X ⟶ S) (g : Y ⟶ S) [Mono f], HasPullback f g] [hasPushout_of_mono_left : ∀ {X Y S : C} (f : S ⟶ X) (g : S ⟶ Y) [Mono f], HasPushout f g] van_kampen : ∀ {W X Y Z : C} {f : W ⟶ X} {g : W ⟶ Y} {h : X ⟶ Z} {i : Y ⟶ Z} [Mono f] (H : IsPushout f g h i), H.IsVanKampen attribute [instance] Adhesive.hasPullback_of_mono_left Adhesive.hasPushout_of_mono_left theorem Adhesive.van_kampen' [Adhesive C] [Mono g] (H : IsPushout f g h i) : H.IsVanKampen := (Adhesive.van_kampen H.flip).flip theorem Adhesive.isPullback_of_isPushout_of_mono_left [Adhesive C] (H : IsPushout f g h i) [Mono f] : IsPullback f g h i := (Adhesive.van_kampen H).isPullback_of_mono_left theorem Adhesive.isPullback_of_isPushout_of_mono_right [Adhesive C] (H : IsPushout f g h i) [Mono g] : IsPullback f g h i := (Adhesive.van_kampen' H).isPullback_of_mono_right theorem Adhesive.mono_of_isPushout_of_mono_left [Adhesive C] (H : IsPushout f g h i) [Mono f] : Mono i := (Adhesive.van_kampen H).mono_of_mono_left theorem Adhesive.mono_of_isPushout_of_mono_right [Adhesive C] (H : IsPushout f g h i) [Mono g] : Mono h := (Adhesive.van_kampen' H).mono_of_mono_right instance Type.adhesive : Adhesive (Type u) := ⟨fun {_ _ _ _ f _ _ _ _} H => (IsPushout.isVanKampen_inl _ (Types.isCoprodOfMono f) _ _ _ H.flip).flip⟩ noncomputable instance (priority := 100) Adhesive.toRegularMonoCategory [Adhesive C] : IsRegularMonoCategory C := ⟨fun f _ => ⟨{ Z := pushout f f left := pushout.inl _ _ right := pushout.inr _ _ w := pushout.condition isLimit := (Adhesive.isPullback_of_isPushout_of_mono_left (IsPushout.of_hasPushout f f)).isLimitFork }⟩⟩ -- This then implies that adhesive categories are balanced example [Adhesive C] : Balanced C := inferInstance section functor universe v'' u'' variable {D : Type u''} [Category.{v''} D] instance adhesive_functor [Adhesive C] [HasPullbacks C] [HasPushouts C] : Adhesive (D ⥤ C) := by constructor intros W X Y Z f g h i hf H rw [IsPushout.isVanKampen_iff] apply isVanKampenColimit_of_evaluation intro x refine (IsVanKampenColimit.precompose_isIso_iff (diagramIsoSpan _).inv).mp ?_ refine IsVanKampenColimit.of_iso ?_ (PushoutCocone.isoMk _).symm refine (IsPushout.isVanKampen_iff (H.map ((evaluation _ _).obj x))).mp ?_ apply Adhesive.van_kampen theorem adhesive_of_preserves_and_reflects (F : C ⥤ D) [Adhesive D] [H₁ : ∀ {X Y S : C} (f : X ⟶ S) (g : Y ⟶ S) [Mono f], HasPullback f g] [H₂ : ∀ {X Y S : C} (f : S ⟶ X) (g : S ⟶ Y) [Mono f], HasPushout f g] [PreservesLimitsOfShape WalkingCospan F] [ReflectsLimitsOfShape WalkingCospan F] [PreservesColimitsOfShape WalkingSpan F] [ReflectsColimitsOfShape WalkingSpan F] : Adhesive C := by apply Adhesive.mk (hasPullback_of_mono_left := H₁) (hasPushout_of_mono_left := H₂) intros W X Y Z f g h i hf H rw [IsPushout.isVanKampen_iff] refine IsVanKampenColimit.of_mapCocone F ?_ refine (IsVanKampenColimit.precompose_isIso_iff (diagramIsoSpan _).inv).mp ?_ refine IsVanKampenColimit.of_iso ?_ (PushoutCocone.isoMk _).symm refine (IsPushout.isVanKampen_iff (H.map F)).mp ?_ apply Adhesive.van_kampen theorem adhesive_of_preserves_and_reflects_isomorphism (F : C ⥤ D) [Adhesive D] [HasPullbacks C] [HasPushouts C] [PreservesLimitsOfShape WalkingCospan F] [PreservesColimitsOfShape WalkingSpan F] [F.ReflectsIsomorphisms] : Adhesive C := by haveI : ReflectsLimitsOfShape WalkingCospan F := reflectsLimitsOfShape_of_reflectsIsomorphisms haveI : ReflectsColimitsOfShape WalkingSpan F := reflectsColimitsOfShape_of_reflectsIsomorphisms exact adhesive_of_preserves_and_reflects F theorem adhesive_of_reflective [HasPullbacks D] [Adhesive C] [HasPullbacks C] [HasPushouts C] [H₂ : ∀ {X Y S : D} (f : S ⟶ X) (g : S ⟶ Y) [Mono f], HasPushout f g] {Gl : C ⥤ D} {Gr : D ⥤ C} (adj : Gl ⊣ Gr) [Gr.Full] [Gr.Faithful] [PreservesLimitsOfShape WalkingCospan Gl] : Adhesive D := by have := adj.leftAdjoint_preservesColimits have := adj.rightAdjoint_preservesLimits apply Adhesive.mk (hasPushout_of_mono_left := H₂) intro W X Y Z f g h i _ H	have := Adhesive.van_kampen (IsPushout.of_hasPushout (Gr.map f) (Gr.map g)) rw [IsPushout.isVanKampen_iff] at this ⊢ refine (IsVanKampenColimit.precompose_isIso_iff (isoWhiskerLeft _ (asIso adj.counit) ≪≫ Functor.rightUnitor _).hom).mp ?_ refine ((this.precompose_isIso (spanCompIso _ _ _).hom).map_reflective adj).of_iso (IsColimit.uniqueUpToIso ?_ ?_) · exact isColimitOfPreserves Gl ((IsColimit.precomposeHomEquiv _ _).symm <\| pushoutIsPushout _ _) · exact (IsColimit.precomposeHomEquiv _ _).symm H.isColimit end functor end CategoryTheory	Mathlib/CategoryTheory/Adhesive.lean	319	335
/- Copyright (c) 2023 Peter Nelson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Peter Nelson -/ import Mathlib.SetTheory.Cardinal.Finite import Mathlib.Data.Set.Finite.Powerset /-! # Noncomputable Set Cardinality We define the cardinality of set `s` as a term `Set.encard s : ℕ∞` and a term `Set.ncard s : ℕ`. The latter takes the junk value of zero if `s` is infinite. Both functions are noncomputable, and are defined in terms of `ENat.card` (which takes a type as its argument); this file can be seen as an API for the same function in the special case where the type is a coercion of a `Set`, allowing for smoother interactions with the `Set` API. `Set.encard` never takes junk values, so is more mathematically natural than `Set.ncard`, even though it takes values in a less convenient type. It is probably the right choice in settings where one is concerned with the cardinalities of sets that may or may not be infinite. `Set.ncard` has a nicer codomain, but when using it, `Set.Finite` hypotheses are normally needed to make sure its values are meaningful. More generally, `Set.ncard` is intended to be used over the obvious alternative `Finset.card` when finiteness is 'propositional' rather than 'structural'. When working with sets that are finite by virtue of their definition, then `Finset.card` probably makes more sense. One setting where `Set.ncard` works nicely is in a type `α` with `[Finite α]`, where every set is automatically finite. In this setting, we use default arguments and a simple tactic so that finiteness goals are discharged automatically in `Set.ncard` theorems. ## Main Definitions * `Set.encard s` is the cardinality of the set `s` as an extended natural number, with value `⊤` if `s` is infinite. * `Set.ncard s` is the cardinality of the set `s` as a natural number, provided `s` is Finite. If `s` is Infinite, then `Set.ncard s = 0`. * `toFinite_tac` is a tactic that tries to synthesize a `Set.Finite s` argument with `Set.toFinite`. This will work for `s : Set α` where there is a `Finite α` instance. ## Implementation Notes The theorems in this file are very similar to those in `Data.Finset.Card`, but with `Set` operations instead of `Finset`. We first prove all the theorems for `Set.encard`, and then derive most of the `Set.ncard` results as a consequence. Things are done this way to avoid reliance on the `Finset` API for theorems about infinite sets, and to allow for a refactor that removes or modifies `Set.ncard` in the future. Nearly all the theorems for `Set.ncard` require finiteness of one or more of their arguments. We provide this assumption with a default argument of the form `(hs : s.Finite := by toFinite_tac)`, where `toFinite_tac` will find an `s.Finite` term in the cases where `s` is a set in a `Finite` type. Often, where there are two set arguments `s` and `t`, the finiteness of one follows from the other in the context of the theorem, in which case we only include the ones that are needed, and derive the other inside the proof. A few of the theorems, such as `ncard_union_le` do not require finiteness arguments; they are true by coincidence due to junk values. -/ namespace Set variable {α β : Type} {s t : Set α} /-- The cardinality of a set as a term in `ℕ∞` -/ noncomputable def encard (s : Set α) : ℕ∞ := ENat.card s @[simp] theorem encard_univ_coe (s : Set α) : encard (univ : Set s) = encard s := by rw [encard, encard, ENat.card_congr (Equiv.Set.univ ↑s)] theorem encard_univ (α : Type) :	encard (univ : Set α) = ENat.card α := by rw [encard, ENat.card_congr (Equiv.Set.univ α)]	Mathlib/Data/Set/Card.lean	69	71
/- Copyright (c) 2020 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson, Jalex Stark -/ import Mathlib.Algebra.Polynomial.Monic /-! # Lemmas for the interaction between polynomials and `∑` and `∏`. Recall that `∑` and `∏` are notation for `Finset.sum` and `Finset.prod` respectively. ## Main results - `Polynomial.natDegree_prod_of_monic` : the degree of a product of monic polynomials is the product of degrees. We prove this only for `[CommSemiring R]`, but it ought to be true for `[Semiring R]` and `List.prod`. - `Polynomial.natDegree_prod` : for polynomials over an integral domain, the degree of the product is the sum of degrees. - `Polynomial.leadingCoeff_prod` : for polynomials over an integral domain, the leading coefficient is the product of leading coefficients. - `Polynomial.prod_X_sub_C_coeff_card_pred` carries most of the content for computing the second coefficient of the characteristic polynomial. -/ open Finset open Multiset open Polynomial universe u w variable {R : Type u} {ι : Type w} namespace Polynomial variable (s : Finset ι) section Semiring variable {S : Type} [Semiring S] theorem natDegree_list_sum_le (l : List S[X]) : natDegree l.sum ≤ (l.map natDegree).foldr max 0 := by apply List.sum_le_foldr_max natDegree · simp · exact natDegree_add_le theorem natDegree_multiset_sum_le (l : Multiset S[X]) : natDegree l.sum ≤ (l.map natDegree).foldr max 0 := Quotient.inductionOn l (by simpa using natDegree_list_sum_le) theorem natDegree_sum_le (f : ι → S[X]) : natDegree (∑ i ∈ s, f i) ≤ s.fold max 0 (natDegree ∘ f) := by simpa using natDegree_multiset_sum_le (s.val.map f) lemma natDegree_sum_le_of_forall_le {n : ℕ} (f : ι → S[X]) (h : ∀ i ∈ s, natDegree (f i) ≤ n) : natDegree (∑ i ∈ s, f i) ≤ n := le_trans (natDegree_sum_le s f) <\| (Finset.fold_max_le n).mpr <\| by simpa theorem degree_list_sum_le_of_forall_degree_le (l : List S[X]) (n : WithBot ℕ) (hl : ∀ p ∈ l, degree p ≤ n) : degree l.sum ≤ n := by induction l with \| nil => simp \| cons hd tl ih => simp only [List.mem_cons, forall_eq_or_imp] at hl rcases hl with ⟨hhd, htl⟩ rw [List.sum_cons] exact le_trans (degree_add_le hd tl.sum) (max_le hhd (ih htl)) theorem degree_list_sum_le (l : List S[X]) : degree l.sum ≤ (l.map natDegree).maximum := by apply degree_list_sum_le_of_forall_degree_le intros p hp by_cases h : p = 0 · subst h simp · rw [degree_eq_natDegree h] apply List.le_maximum_of_mem' rw [List.mem_map] use p simp [hp] theorem natDegree_list_prod_le (l : List S[X]) : natDegree l.prod ≤ (l.map natDegree).sum := by induction' l with hd tl IH · simp · simpa using natDegree_mul_le.trans (add_le_add_left IH _) theorem degree_list_prod_le (l : List S[X]) : degree l.prod ≤ (l.map degree).sum := by induction' l with hd tl IH · simp · simpa using (degree_mul_le _ _).trans (add_le_add_left IH _) theorem coeff_list_prod_of_natDegree_le (l : List S[X]) (n : ℕ) (hl : ∀ p ∈ l, natDegree p ≤ n) : coeff (List.prod l) (l.length n) = (l.map fun p => coeff p n).prod := by induction' l with hd tl IH · simp · have hl' : ∀ p ∈ tl, natDegree p ≤ n := fun p hp => hl p (List.mem_cons_of_mem _ hp) simp only [List.prod_cons, List.map, List.length] rw [add_mul, one_mul, add_comm, ← IH hl', mul_comm tl.length] have h : natDegree tl.prod ≤ n * tl.length := by refine (natDegree_list_prod_le _).trans ?_ rw [← tl.length_map natDegree, mul_comm] refine List.sum_le_card_nsmul _ _ ?_ simpa using hl' exact coeff_mul_add_eq_of_natDegree_le (hl _ List.mem_cons_self) h end Semiring section CommSemiring variable [CommSemiring R] (f : ι → R[X]) (t : Multiset R[X]) theorem natDegree_multiset_prod_le : t.prod.natDegree ≤ (t.map natDegree).sum := Quotient.inductionOn t (by simpa using natDegree_list_prod_le) theorem natDegree_prod_le : (∏ i ∈ s, f i).natDegree ≤ ∑ i ∈ s, (f i).natDegree := by simpa using natDegree_multiset_prod_le (s.1.map f) /-- The degree of a product of polynomials is at most the sum of the degrees, where the degree of the zero polynomial is ⊥. -/ theorem degree_multiset_prod_le : t.prod.degree ≤ (t.map Polynomial.degree).sum := Quotient.inductionOn t (by simpa using degree_list_prod_le) theorem degree_prod_le : (∏ i ∈ s, f i).degree ≤ ∑ i ∈ s, (f i).degree := by simpa only [Multiset.map_map] using degree_multiset_prod_le (s.1.map f) /-- The leading coefficient of a product of polynomials is equal to the product of the leading coefficients, provided that this product is nonzero. See `Polynomial.leadingCoeff_multiset_prod` (without the `'`) for a version for integral domains,	where this condition is automatically satisfied. -/	Mathlib/Algebra/Polynomial/BigOperators.lean	135	136
/- Copyright (c) 2024 Emilie Burgun. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Emilie Burgun -/ import Mathlib.Algebra.Group.Action.Pointwise.Set.Basic import Mathlib.Algebra.Group.Commute.Basic import Mathlib.Dynamics.PeriodicPts.Defs import Mathlib.GroupTheory.GroupAction.Defs /-! # Properties of `fixedPoints` and `fixedBy` This module contains some useful properties of `MulAction.fixedPoints` and `MulAction.fixedBy` that don't directly belong to `Mathlib.GroupTheory.GroupAction.Basic`. ## Main theorems * `MulAction.fixedBy_mul`: `fixedBy α (g * h) ⊆ fixedBy α g ∪ fixedBy α h` * `MulAction.fixedBy_conj` and `MulAction.smul_fixedBy`: the pointwise group action of `h` on `fixedBy α g` is equal to the `fixedBy` set of the conjugation of `h` with `g` (`fixedBy α (h * g * h⁻¹)`). * `MulAction.set_mem_fixedBy_of_movedBy_subset` shows that if a set `s` is a superset of `(fixedBy α g)ᶜ`, then the group action of `g` cannot send elements of `s` outside of `s`. This is expressed as `s ∈ fixedBy (Set α) g`, and `MulAction.set_mem_fixedBy_iff` allows one to convert the relationship back to `g • x ∈ s ↔ x ∈ s`. * `MulAction.not_commute_of_disjoint_smul_movedBy` allows one to prove that `g` and `h` do not commute from the disjointness of the `(fixedBy α g)ᶜ` set and `h • (fixedBy α g)ᶜ`, which is a property used in the proof of Rubin's theorem. The theorems above are also available for `AddAction`. ## Pointwise group action and `fixedBy (Set α) g` Since `fixedBy α g = { x \| g • x = x }` by definition, properties about the pointwise action of a set `s : Set α` can be expressed using `fixedBy (Set α) g`. To properly use theorems using `fixedBy (Set α) g`, you should `open Pointwise` in your file. `s ∈ fixedBy (Set α) g` means that `g • s = s`, which is equivalent to say that `∀ x, g • x ∈ s ↔ x ∈ s` (the translation can be done using `MulAction.set_mem_fixedBy_iff`). `s ∈ fixedBy (Set α) g` is a weaker statement than `s ⊆ fixedBy α g`: the latter requires that all points in `s` are fixed by `g`, whereas the former only requires that `g • x ∈ s`. -/ namespace MulAction open Pointwise variable {α : Type} variable {G : Type} [Group G] [MulAction G α] variable {M : Type*} [Monoid M] [MulAction M α] section FixedPoints variable (α) in /-- In a multiplicative group action, the points fixed by `g` are also fixed by `g⁻¹` -/ @[to_additive (attr := simp) "In an additive group action, the points fixed by `g` are also fixed by `g⁻¹`"] theorem fixedBy_inv (g : G) : fixedBy α g⁻¹ = fixedBy α g := by ext rw [mem_fixedBy, mem_fixedBy, inv_smul_eq_iff, eq_comm] @[to_additive] theorem smul_mem_fixedBy_iff_mem_fixedBy {a : α} {g : G} : g • a ∈ fixedBy α g ↔ a ∈ fixedBy α g := by rw [mem_fixedBy, smul_left_cancel_iff] rfl @[to_additive] theorem smul_inv_mem_fixedBy_iff_mem_fixedBy {a : α} {g : G} : g⁻¹ • a ∈ fixedBy α g ↔ a ∈ fixedBy α g := by rw [← fixedBy_inv, smul_mem_fixedBy_iff_mem_fixedBy, fixedBy_inv] @[to_additive minimalPeriod_eq_one_iff_fixedBy] theorem minimalPeriod_eq_one_iff_fixedBy {a : α} {g : G} : Function.minimalPeriod (fun x => g • x) a = 1 ↔ a ∈ fixedBy α g := Function.minimalPeriod_eq_one_iff_isFixedPt variable (α) in @[to_additive] theorem fixedBy_subset_fixedBy_zpow (g : G) (j : ℤ) : fixedBy α g ⊆ fixedBy α (g ^ j) := by intro a a_in_fixedBy rw [mem_fixedBy, zpow_smul_eq_iff_minimalPeriod_dvd, minimalPeriod_eq_one_iff_fixedBy.mpr a_in_fixedBy, Int.natCast_one] exact one_dvd j variable (M α) in @[to_additive (attr := simp)] theorem fixedBy_one_eq_univ : fixedBy α (1 : M) = Set.univ := Set.eq_univ_iff_forall.mpr <\| one_smul M variable (α) in @[to_additive]	theorem fixedBy_mul (m₁ m₂ : M) : fixedBy α m₁ ∩ fixedBy α m₂ ⊆ fixedBy α (m₁ * m₂) := by intro a ⟨h₁, h₂⟩ rw [mem_fixedBy, mul_smul, h₂, h₁]	Mathlib/GroupTheory/GroupAction/FixedPoints.lean	96	98
/- Copyright (c) 2020 Eric Wieser. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Eric Wieser -/ import Mathlib.Algebra.Module.Defs import Mathlib.Data.SetLike.Basic import Mathlib.Data.Setoid.Basic import Mathlib.GroupTheory.GroupAction.Defs import Mathlib.GroupTheory.GroupAction.Hom /-! # Sets invariant to a `MulAction` In this file we define `SubMulAction R M`; a subset of a `MulAction R M` which is closed with respect to scalar multiplication. For most uses, typically `Submodule R M` is more powerful. ## Main definitions * `SubMulAction.mulAction` - the `MulAction R M` transferred to the subtype. * `SubMulAction.mulAction'` - the `MulAction S M` transferred to the subtype when `IsScalarTower S R M`. * `SubMulAction.isScalarTower` - the `IsScalarTower S R M` transferred to the subtype. * `SubMulAction.inclusion` — the inclusion of a submulaction, as an equivariant map ## Tags submodule, mul_action -/ open Function universe u u' u'' v variable {S : Type u'} {T : Type u''} {R : Type u} {M : Type v} /-- `SMulMemClass S R M` says `S` is a type of subsets `s ≤ M` that are closed under the scalar action of `R` on `M`. Note that only `R` is marked as an `outParam` here, since `M` is supplied by the `SetLike` class instead. -/ class SMulMemClass (S : Type) (R : outParam Type) (M : Type) [SMul R M] [SetLike S M] : Prop where /-- Multiplication by a scalar on an element of the set remains in the set. -/ smul_mem : ∀ {s : S} (r : R) {m : M}, m ∈ s → r • m ∈ s /-- `VAddMemClass S R M` says `S` is a type of subsets `s ≤ M` that are closed under the additive action of `R` on `M`. Note that only `R` is marked as an `outParam` here, since `M` is supplied by the `SetLike` class instead. -/ class VAddMemClass (S : Type) (R : outParam Type) (M : Type) [VAdd R M] [SetLike S M] : Prop where /-- Addition by a scalar with an element of the set remains in the set. -/ vadd_mem : ∀ {s : S} (r : R) {m : M}, m ∈ s → r +ᵥ m ∈ s attribute [to_additive] SMulMemClass attribute [aesop safe 10 apply (rule_sets := [SetLike])] SMulMemClass.smul_mem VAddMemClass.vadd_mem /-- Not registered as an instance because `R` is an `outParam` in `SMulMemClass S R M`. -/ lemma AddSubmonoidClass.nsmulMemClass {S M : Type} [AddMonoid M] [SetLike S M] [AddSubmonoidClass S M] : SMulMemClass S ℕ M where smul_mem n _x hx := nsmul_mem hx n /-- Not registered as an instance because `R` is an `outParam` in `SMulMemClass S R M`. -/ lemma AddSubgroupClass.zsmulMemClass {S M : Type} [SubNegMonoid M] [SetLike S M] [AddSubgroupClass S M] : SMulMemClass S ℤ M where smul_mem n _x hx := zsmul_mem hx n namespace SetLike open SMulMemClass section SMul variable [SMul R M] [SetLike S M] [hS : SMulMemClass S R M] (s : S) -- lower priority so other instances are found first /-- A subset closed under the scalar action inherits that action. -/ @[to_additive "A subset closed under the additive action inherits that action."] instance (priority := 50) smul : SMul R s := ⟨fun r x => ⟨r • x.1, smul_mem r x.2⟩⟩ /-- This can't be an instance because Lean wouldn't know how to find `N`, but we can still use this to manually derive `SMulMemClass` on specific types. -/ @[to_additive] theorem _root_.SMulMemClass.ofIsScalarTower (S M N α : Type) [SetLike S α] [SMul M N] [SMul M α] [Monoid N] [MulAction N α] [SMulMemClass S N α] [IsScalarTower M N α] : SMulMemClass S M α := { smul_mem := fun m a ha => smul_one_smul N m a ▸ SMulMemClass.smul_mem _ ha } instance instIsScalarTower [Mul M] [MulMemClass S M] [IsScalarTower R M M] (s : S) : IsScalarTower R s s where smul_assoc r x y := Subtype.ext <\| smul_assoc r (x : M) (y : M) instance instSMulCommClass [Mul M] [MulMemClass S M] [SMulCommClass R M M] (s : S) : SMulCommClass R s s where smul_comm r x y := Subtype.ext <\| smul_comm r (x : M) (y : M) -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO lower priority not actually there -- lower priority so later simp lemmas are used first; to appease simp_nf @[to_additive (attr := simp, norm_cast)] protected theorem val_smul (r : R) (x : s) : (↑(r • x) : M) = r • (x : M) := rfl -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO lower priority not actually there -- lower priority so later simp lemmas are used first; to appease simp_nf @[to_additive (attr := simp)] theorem mk_smul_mk (r : R) (x : M) (hx : x ∈ s) : r • (⟨x, hx⟩ : s) = ⟨r • x, smul_mem r hx⟩ := rfl @[to_additive] theorem smul_def (r : R) (x : s) : r • x = ⟨r • x, smul_mem r x.2⟩ := rfl @[simp] theorem forall_smul_mem_iff {R M S : Type} [Monoid R] [MulAction R M] [SetLike S M] [SMulMemClass S R M] {N : S} {x : M} : (∀ a : R, a • x ∈ N) ↔ x ∈ N := ⟨fun h => by simpa using h 1, fun h a => SMulMemClass.smul_mem a h⟩ end SMul section OfTower variable {N α : Type} [SetLike S α] [SMul M N] [SMul M α] [Monoid N] [MulAction N α] [SMulMemClass S N α] [IsScalarTower M N α] (s : S) -- lower priority so other instances are found first /-- A subset closed under the scalar action inherits that action. -/ @[to_additive "A subset closed under the additive action inherits that action."] instance (priority := 50) smul' : SMul M s where smul r x := ⟨r • x.1, smul_one_smul N r x.1 ▸ smul_mem _ x.2⟩ instance (priority := 50) : IsScalarTower M N s where smul_assoc m n x := Subtype.ext (smul_assoc m n x.1) @[to_additive (attr := simp, norm_cast)] protected theorem val_smul_of_tower (r : M) (x : s) : (↑(r • x) : α) = r • (x : α) := rfl @[to_additive (attr := simp)] theorem mk_smul_of_tower_mk (r : M) (x : α) (hx : x ∈ s) : r • (⟨x, hx⟩ : s) = ⟨r • x, smul_one_smul N r x ▸ smul_mem _ hx⟩ := rfl @[to_additive] theorem smul_of_tower_def (r : M) (x : s) : r • x = ⟨r • x, smul_one_smul N r x.1 ▸ smul_mem _ x.2⟩ := rfl end OfTower end SetLike /-- A SubAddAction is a set which is closed under scalar multiplication. -/ structure SubAddAction (R : Type u) (M : Type v) [VAdd R M] : Type v where /-- The underlying set of a `SubAddAction`. -/ carrier : Set M /-- The carrier set is closed under scalar multiplication. -/ vadd_mem' : ∀ (c : R) {x : M}, x ∈ carrier → c +ᵥ x ∈ carrier /-- A SubMulAction is a set which is closed under scalar multiplication. -/ @[to_additive] structure SubMulAction (R : Type u) (M : Type v) [SMul R M] : Type v where /-- The underlying set of a `SubMulAction`. -/ carrier : Set M /-- The carrier set is closed under scalar multiplication. -/ smul_mem' : ∀ (c : R) {x : M}, x ∈ carrier → c • x ∈ carrier namespace SubMulAction variable [SMul R M] @[to_additive] instance : SetLike (SubMulAction R M) M := ⟨SubMulAction.carrier, fun p q h => by cases p; cases q; congr⟩ @[to_additive] instance : SMulMemClass (SubMulAction R M) R M where smul_mem := smul_mem' _ @[to_additive (attr := simp)] theorem mem_carrier {p : SubMulAction R M} {x : M} : x ∈ p.carrier ↔ x ∈ (p : Set M) := Iff.rfl @[to_additive (attr := ext)] theorem ext {p q : SubMulAction R M} (h : ∀ x, x ∈ p ↔ x ∈ q) : p = q := SetLike.ext h /-- Copy of a sub_mul_action with a new `carrier` equal to the old one. Useful to fix definitional equalities. -/ @[to_additive "Copy of a sub_mul_action with a new `carrier` equal to the old one. Useful to fix definitional equalities."] protected def copy (p : SubMulAction R M) (s : Set M) (hs : s = ↑p) : SubMulAction R M where carrier := s smul_mem' := hs.symm ▸ p.smul_mem' @[to_additive (attr := simp)] theorem coe_copy (p : SubMulAction R M) (s : Set M) (hs : s = ↑p) : (p.copy s hs : Set M) = s := rfl @[to_additive] theorem copy_eq (p : SubMulAction R M) (s : Set M) (hs : s = ↑p) : p.copy s hs = p := SetLike.coe_injective hs @[to_additive] instance : Bot (SubMulAction R M) where bot := { carrier := ∅ smul_mem' := fun _c h => Set.not_mem_empty h } @[to_additive] instance : Inhabited (SubMulAction R M) := ⟨⊥⟩ end SubMulAction namespace SubMulAction section SMul variable [SMul R M] variable (p : SubMulAction R M) variable {r : R} {x : M} @[to_additive] theorem smul_mem (r : R) (h : x ∈ p) : r • x ∈ p := p.smul_mem' r h @[to_additive] instance : SMul R p where smul c x := ⟨c • x.1, smul_mem _ c x.2⟩ variable {p} in @[to_additive (attr := norm_cast, simp)] theorem val_smul (r : R) (x : p) : (↑(r • x) : M) = r • (x : M) := rfl -- Porting note: no longer needed because of defeq structure eta /-- Embedding of a submodule `p` to the ambient space `M`. -/ @[to_additive "Embedding of a submodule `p` to the ambient space `M`."] protected def subtype : p →[R] M where toFun := Subtype.val map_smul' := by simp [val_smul] variable {p} in @[to_additive (attr := simp)] theorem subtype_apply (x : p) : p.subtype x = x := rfl lemma subtype_injective : Function.Injective p.subtype := Subtype.coe_injective @[to_additive] theorem subtype_eq_val : (SubMulAction.subtype p : p → M) = Subtype.val := rfl end SMul namespace SMulMemClass variable [Monoid R] [MulAction R M] {A : Type} [SetLike A M] variable [hA : SMulMemClass A R M] (S' : A) -- Prefer subclasses of `MulAction` over `SMulMemClass`. /-- A `SubMulAction` of a `MulAction` is a `MulAction`. -/ @[to_additive "A `SubAddAction` of an `AddAction` is an `AddAction`."] instance (priority := 75) toMulAction : MulAction R S' := Subtype.coe_injective.mulAction Subtype.val (SetLike.val_smul S') /-- The natural `MulActionHom` over `R` from a `SubMulAction` of `M` to `M`. -/ @[to_additive "The natural `AddActionHom` over `R` from a `SubAddAction` of `M` to `M`."] protected def subtype : S' →[R] M where toFun := Subtype.val; map_smul' _ _ := rfl variable {S'} in @[simp] lemma subtype_apply (x : S') : SMulMemClass.subtype S' x = x := rfl lemma subtype_injective : Function.Injective (SMulMemClass.subtype S') := Subtype.coe_injective @[to_additive (attr := simp)] protected theorem coe_subtype : (SMulMemClass.subtype S' : S' → M) = Subtype.val := rfl @[deprecated (since := "2025-02-18")] protected alias coeSubtype := SubMulAction.SMulMemClass.coe_subtype @[deprecated (since := "2025-02-18")]	protected alias _root_.SubAddAction.SMulMemClass.coeSubtype := SubAddAction.SMulMemClass.coe_subtype end SMulMemClass	Mathlib/GroupTheory/GroupAction/SubMulAction.lean	297	299
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes -/ import Mathlib.Algebra.Group.Equiv.Basic import Mathlib.Data.ENat.Lattice import Mathlib.Data.Part import Mathlib.Tactic.NormNum /-! # Natural numbers with infinity The natural numbers and an extra `top` element `⊤`. This implementation uses `Part ℕ` as an implementation. Use `ℕ∞` instead unless you care about computability. ## Main definitions The following instances are defined: * `OrderedAddCommMonoid PartENat` * `CanonicallyOrderedAdd PartENat` * `CompleteLinearOrder PartENat` There is no additive analogue of `MonoidWithZero`; if there were then `PartENat` could be an `AddMonoidWithTop`. * `toWithTop` : the map from `PartENat` to `ℕ∞`, with theorems that it plays well with `+` and `≤`. * `withTopAddEquiv : PartENat ≃+ ℕ∞` * `withTopOrderIso : PartENat ≃o ℕ∞` ## Implementation details `PartENat` is defined to be `Part ℕ`. `+` and `≤` are defined on `PartENat`, but there is an issue with `` because it's not clear what `0 ⊤` should be. `mul` is hence left undefined. Similarly `⊤ - ⊤` is ambiguous so there is no `-` defined on `PartENat`. Before the `open scoped Classical` line, various proofs are made with decidability assumptions. This can cause issues -- see for example the non-simp lemma `toWithTopZero` proved by `rfl`, followed by `@[simp] lemma toWithTopZero'` whose proof uses `convert`. ## Tags PartENat, ℕ∞ -/ open Part hiding some /-- Type of natural numbers with infinity (`⊤`) -/ def PartENat : Type := Part ℕ namespace PartENat /-- The computable embedding `ℕ → PartENat`. This coincides with the coercion `coe : ℕ → PartENat`, see `PartENat.some_eq_natCast`. -/ @[coe] def some : ℕ → PartENat := Part.some instance : Zero PartENat := ⟨some 0⟩ instance : Inhabited PartENat := ⟨0⟩ instance : One PartENat := ⟨some 1⟩ instance : Add PartENat := ⟨fun x y => ⟨x.Dom ∧ y.Dom, fun h => get x h.1 + get y h.2⟩⟩ instance (n : ℕ) : Decidable (some n).Dom := isTrue trivial @[simp] theorem dom_some (x : ℕ) : (some x).Dom := trivial instance addCommMonoid : AddCommMonoid PartENat where add := (· + ·) zero := 0 add_comm _ _ := Part.ext' and_comm fun _ _ => add_comm _ _ zero_add _ := Part.ext' (iff_of_eq (true_and _)) fun _ _ => zero_add _ add_zero _ := Part.ext' (iff_of_eq (and_true _)) fun _ _ => add_zero _ add_assoc _ _ _ := Part.ext' and_assoc fun _ _ => add_assoc _ _ _ nsmul := nsmulRec instance : AddCommMonoidWithOne PartENat := { PartENat.addCommMonoid with one := 1 natCast := some natCast_zero := rfl natCast_succ := fun _ => Part.ext' (iff_of_eq (true_and _)).symm fun _ _ => rfl } theorem some_eq_natCast (n : ℕ) : some n = n := rfl instance : CharZero PartENat where cast_injective := Part.some_injective /-- Alias of `Nat.cast_inj` specialized to `PartENat` -/ theorem natCast_inj {x y : ℕ} : (x : PartENat) = y ↔ x = y := Nat.cast_inj @[simp] theorem dom_natCast (x : ℕ) : (x : PartENat).Dom := trivial @[simp] theorem dom_ofNat (x : ℕ) [x.AtLeastTwo] : (ofNat(x) : PartENat).Dom := trivial @[simp] theorem dom_zero : (0 : PartENat).Dom := trivial @[simp] theorem dom_one : (1 : PartENat).Dom := trivial instance : CanLift PartENat ℕ (↑) Dom := ⟨fun n hn => ⟨n.get hn, Part.some_get _⟩⟩ instance : LE PartENat := ⟨fun x y => ∃ h : y.Dom → x.Dom, ∀ hy : y.Dom, x.get (h hy) ≤ y.get hy⟩ instance : Top PartENat := ⟨none⟩ instance : Bot PartENat := ⟨0⟩ instance : Max PartENat := ⟨fun x y => ⟨x.Dom ∧ y.Dom, fun h => x.get h.1 ⊔ y.get h.2⟩⟩ theorem le_def (x y : PartENat) : x ≤ y ↔ ∃ h : y.Dom → x.Dom, ∀ hy : y.Dom, x.get (h hy) ≤ y.get hy := Iff.rfl @[elab_as_elim] protected theorem casesOn' {P : PartENat → Prop} : ∀ a : PartENat, P ⊤ → (∀ n : ℕ, P (some n)) → P a := Part.induction_on @[elab_as_elim] protected theorem casesOn {P : PartENat → Prop} : ∀ a : PartENat, P ⊤ → (∀ n : ℕ, P n) → P a := by exact PartENat.casesOn' -- not a simp lemma as we will provide a `LinearOrderedAddCommMonoidWithTop` instance later theorem top_add (x : PartENat) : ⊤ + x = ⊤ := Part.ext' (iff_of_eq (false_and _)) fun h => h.left.elim -- not a simp lemma as we will provide a `LinearOrderedAddCommMonoidWithTop` instance later theorem add_top (x : PartENat) : x + ⊤ = ⊤ := by rw [add_comm, top_add] @[simp] theorem natCast_get {x : PartENat} (h : x.Dom) : (x.get h : PartENat) = x := by exact Part.ext' (iff_of_true trivial h) fun _ _ => rfl @[simp, norm_cast] theorem get_natCast' (x : ℕ) (h : (x : PartENat).Dom) : get (x : PartENat) h = x := by rw [← natCast_inj, natCast_get] theorem get_natCast {x : ℕ} : get (x : PartENat) (dom_natCast x) = x := get_natCast' _ _ theorem coe_add_get {x : ℕ} {y : PartENat} (h : ((x : PartENat) + y).Dom) : get ((x : PartENat) + y) h = x + get y h.2 := by rfl @[simp] theorem get_add {x y : PartENat} (h : (x + y).Dom) : get (x + y) h = x.get h.1 + y.get h.2 := rfl @[simp] theorem get_zero (h : (0 : PartENat).Dom) : (0 : PartENat).get h = 0 := rfl @[simp] theorem get_one (h : (1 : PartENat).Dom) : (1 : PartENat).get h = 1 := rfl @[simp] theorem get_ofNat' (x : ℕ) [x.AtLeastTwo] (h : (ofNat(x) : PartENat).Dom) : Part.get (ofNat(x) : PartENat) h = ofNat(x) := get_natCast' x h nonrec theorem get_eq_iff_eq_some {a : PartENat} {ha : a.Dom} {b : ℕ} : a.get ha = b ↔ a = some b := get_eq_iff_eq_some theorem get_eq_iff_eq_coe {a : PartENat} {ha : a.Dom} {b : ℕ} : a.get ha = b ↔ a = b := by rw [get_eq_iff_eq_some] rfl theorem dom_of_le_of_dom {x y : PartENat} : x ≤ y → y.Dom → x.Dom := fun ⟨h, _⟩ => h theorem dom_of_le_some {x : PartENat} {y : ℕ} (h : x ≤ some y) : x.Dom := dom_of_le_of_dom h trivial theorem dom_of_le_natCast {x : PartENat} {y : ℕ} (h : x ≤ y) : x.Dom := by exact dom_of_le_some h instance decidableLe (x y : PartENat) [Decidable x.Dom] [Decidable y.Dom] : Decidable (x ≤ y) := if hx : x.Dom then decidable_of_decidable_of_iff (le_def x y).symm else if hy : y.Dom then isFalse fun h => hx <\| dom_of_le_of_dom h hy else isTrue ⟨fun h => (hy h).elim, fun h => (hy h).elim⟩ instance partialOrder : PartialOrder PartENat where le := (· ≤ ·) le_refl _ := ⟨id, fun _ => le_rfl⟩ le_trans := fun _ _ _ ⟨hxy₁, hxy₂⟩ ⟨hyz₁, hyz₂⟩ => ⟨hxy₁ ∘ hyz₁, fun _ => le_trans (hxy₂ _) (hyz₂ _)⟩ lt_iff_le_not_le _ _ := Iff.rfl le_antisymm := fun _ _ ⟨hxy₁, hxy₂⟩ ⟨hyx₁, hyx₂⟩ => Part.ext' ⟨hyx₁, hxy₁⟩ fun _ _ => le_antisymm (hxy₂ _) (hyx₂ _) theorem lt_def (x y : PartENat) : x < y ↔ ∃ hx : x.Dom, ∀ hy : y.Dom, x.get hx < y.get hy := by rw [lt_iff_le_not_le, le_def, le_def, not_exists] constructor · rintro ⟨⟨hyx, H⟩, h⟩ by_cases hx : x.Dom · use hx intro hy specialize H hy specialize h fun _ => hy rw [not_forall] at h obtain ⟨hx', h⟩ := h rw [not_le] at h exact h · specialize h fun hx' => (hx hx').elim rw [not_forall] at h obtain ⟨hx', h⟩ := h exact (hx hx').elim · rintro ⟨hx, H⟩ exact ⟨⟨fun _ => hx, fun hy => (H hy).le⟩, fun hxy h => not_lt_of_le (h _) (H _)⟩ noncomputable instance isOrderedAddMonoid : IsOrderedAddMonoid PartENat := { add_le_add_left := fun a b ⟨h₁, h₂⟩ c => PartENat.casesOn c (by simp [top_add]) fun c => ⟨fun h => And.intro (dom_natCast _) (h₁ h.2), fun h => by simpa only [coe_add_get] using add_le_add_left (h₂ _) c⟩ } instance semilatticeSup : SemilatticeSup PartENat := { PartENat.partialOrder with sup := (· ⊔ ·) le_sup_left := fun _ _ => ⟨And.left, fun _ => le_sup_left⟩ le_sup_right := fun _ _ => ⟨And.right, fun _ => le_sup_right⟩ sup_le := fun _ _ _ ⟨hx₁, hx₂⟩ ⟨hy₁, hy₂⟩ => ⟨fun hz => ⟨hx₁ hz, hy₁ hz⟩, fun _ => sup_le (hx₂ _) (hy₂ _)⟩ } instance orderBot : OrderBot PartENat where bot := ⊥ bot_le _ := ⟨fun _ => trivial, fun _ => Nat.zero_le _⟩ instance orderTop : OrderTop PartENat where top := ⊤ le_top _ := ⟨fun h => False.elim h, fun hy => False.elim hy⟩ instance : ZeroLEOneClass PartENat where zero_le_one := bot_le /-- Alias of `Nat.cast_le` specialized to `PartENat` -/ theorem coe_le_coe {x y : ℕ} : (x : PartENat) ≤ y ↔ x ≤ y := Nat.cast_le /-- Alias of `Nat.cast_lt` specialized to `PartENat` -/ theorem coe_lt_coe {x y : ℕ} : (x : PartENat) < y ↔ x < y := Nat.cast_lt @[simp] theorem get_le_get {x y : PartENat} {hx : x.Dom} {hy : y.Dom} : x.get hx ≤ y.get hy ↔ x ≤ y := by conv => lhs rw [← coe_le_coe, natCast_get, natCast_get] theorem le_coe_iff (x : PartENat) (n : ℕ) : x ≤ n ↔ ∃ h : x.Dom, x.get h ≤ n := by show (∃ h : True → x.Dom, _) ↔ ∃ h : x.Dom, x.get h ≤ n simp only [forall_prop_of_true, dom_natCast, get_natCast'] theorem lt_coe_iff (x : PartENat) (n : ℕ) : x < n ↔ ∃ h : x.Dom, x.get h < n := by simp only [lt_def, forall_prop_of_true, get_natCast', dom_natCast] theorem coe_le_iff (n : ℕ) (x : PartENat) : (n : PartENat) ≤ x ↔ ∀ h : x.Dom, n ≤ x.get h := by rw [← some_eq_natCast] simp only [le_def, exists_prop_of_true, dom_some, forall_true_iff] rfl theorem coe_lt_iff (n : ℕ) (x : PartENat) : (n : PartENat) < x ↔ ∀ h : x.Dom, n < x.get h := by rw [← some_eq_natCast] simp only [lt_def, exists_prop_of_true, dom_some, forall_true_iff] rfl nonrec theorem eq_zero_iff {x : PartENat} : x = 0 ↔ x ≤ 0 := eq_bot_iff theorem ne_zero_iff {x : PartENat} : x ≠ 0 ↔ ⊥ < x := bot_lt_iff_ne_bot.symm theorem dom_of_lt {x y : PartENat} : x < y → x.Dom := PartENat.casesOn x not_top_lt fun _ _ => dom_natCast _ theorem top_eq_none : (⊤ : PartENat) = Part.none := rfl @[simp] theorem natCast_lt_top (x : ℕ) : (x : PartENat) < ⊤ := Ne.lt_top fun h => absurd (congr_arg Dom h) <\| by simp only [dom_natCast]; exact true_ne_false @[simp] theorem zero_lt_top : (0 : PartENat) < ⊤ := natCast_lt_top 0 @[simp] theorem one_lt_top : (1 : PartENat) < ⊤ := natCast_lt_top 1 @[simp] theorem ofNat_lt_top (x : ℕ) [x.AtLeastTwo] : (ofNat(x) : PartENat) < ⊤ := natCast_lt_top x @[simp] theorem natCast_ne_top (x : ℕ) : (x : PartENat) ≠ ⊤ := ne_of_lt (natCast_lt_top x) @[simp] theorem zero_ne_top : (0 : PartENat) ≠ ⊤ := natCast_ne_top 0 @[simp] theorem one_ne_top : (1 : PartENat) ≠ ⊤ := natCast_ne_top 1 @[simp] theorem ofNat_ne_top (x : ℕ) [x.AtLeastTwo] : (ofNat(x) : PartENat) ≠ ⊤ := natCast_ne_top x theorem not_isMax_natCast (x : ℕ) : ¬IsMax (x : PartENat) := not_isMax_of_lt (natCast_lt_top x) theorem ne_top_iff {x : PartENat} : x ≠ ⊤ ↔ ∃ n : ℕ, x = n := by simpa only [← some_eq_natCast] using Part.ne_none_iff theorem ne_top_iff_dom {x : PartENat} : x ≠ ⊤ ↔ x.Dom := by classical exact not_iff_comm.1 Part.eq_none_iff'.symm theorem not_dom_iff_eq_top {x : PartENat} : ¬x.Dom ↔ x = ⊤ := Iff.not_left ne_top_iff_dom.symm theorem ne_top_of_lt {x y : PartENat} (h : x < y) : x ≠ ⊤ := ne_of_lt <\| lt_of_lt_of_le h le_top theorem eq_top_iff_forall_lt (x : PartENat) : x = ⊤ ↔ ∀ n : ℕ, (n : PartENat) < x := by constructor · rintro rfl n exact natCast_lt_top _ · contrapose! rw [ne_top_iff] rintro ⟨n, rfl⟩ exact ⟨n, irrefl _⟩ theorem eq_top_iff_forall_le (x : PartENat) : x = ⊤ ↔ ∀ n : ℕ, (n : PartENat) ≤ x := (eq_top_iff_forall_lt x).trans ⟨fun h n => (h n).le, fun h n => lt_of_lt_of_le (coe_lt_coe.mpr n.lt_succ_self) (h (n + 1))⟩ theorem pos_iff_one_le {x : PartENat} : 0 < x ↔ 1 ≤ x := PartENat.casesOn x (by simp only [le_top, natCast_lt_top, ← @Nat.cast_zero PartENat]) fun n => by rw [← Nat.cast_zero, ← Nat.cast_one, PartENat.coe_lt_coe, PartENat.coe_le_coe] rfl instance isTotal : IsTotal PartENat (· ≤ ·) where total x y := PartENat.casesOn (P := fun z => z ≤ y ∨ y ≤ z) x (Or.inr le_top) (PartENat.casesOn y (fun _ => Or.inl le_top) fun x y => (le_total x y).elim (Or.inr ∘ coe_le_coe.2) (Or.inl ∘ coe_le_coe.2)) noncomputable instance linearOrder : LinearOrder PartENat := { PartENat.partialOrder with le_total := IsTotal.total toDecidableLE := Classical.decRel _ max := (· ⊔ ·) max_def a b := congr_fun₂ (@sup_eq_maxDefault PartENat _ (_) _) _ _ } instance boundedOrder : BoundedOrder PartENat := { PartENat.orderTop, PartENat.orderBot with } noncomputable instance lattice : Lattice PartENat := { PartENat.semilatticeSup with inf := min inf_le_left := min_le_left inf_le_right := min_le_right le_inf := fun _ _ _ => le_min } instance : CanonicallyOrderedAdd PartENat := { le_self_add := fun a b => PartENat.casesOn b (le_top.trans_eq (add_top _).symm) fun _ => PartENat.casesOn a (top_add _).ge fun _ => (coe_le_coe.2 le_self_add).trans_eq (Nat.cast_add _ _) exists_add_of_le := fun {a b} => PartENat.casesOn b (fun _ => ⟨⊤, (add_top _).symm⟩) fun b => PartENat.casesOn a (fun h => ((natCast_lt_top _).not_le h).elim) fun a h => ⟨(b - a : ℕ), by rw [← Nat.cast_add, natCast_inj, add_comm, tsub_add_cancel_of_le (coe_le_coe.1 h)]⟩ } theorem eq_natCast_sub_of_add_eq_natCast {x y : PartENat} {n : ℕ} (h : x + y = n) : x = ↑(n - y.get (dom_of_le_natCast ((le_add_left le_rfl).trans_eq h))) := by lift x to ℕ using dom_of_le_natCast ((le_add_right le_rfl).trans_eq h) lift y to ℕ using dom_of_le_natCast ((le_add_left le_rfl).trans_eq h) rw [← Nat.cast_add, natCast_inj] at h rw [get_natCast, natCast_inj, eq_tsub_of_add_eq h] protected theorem add_lt_add_right {x y z : PartENat} (h : x < y) (hz : z ≠ ⊤) : x + z < y + z := by rcases ne_top_iff.mp (ne_top_of_lt h) with ⟨m, rfl⟩ rcases ne_top_iff.mp hz with ⟨k, rfl⟩ induction y using PartENat.casesOn · rw [top_add] exact_mod_cast natCast_lt_top _ norm_cast at h exact_mod_cast add_lt_add_right h _ protected theorem add_lt_add_iff_right {x y z : PartENat} (hz : z ≠ ⊤) : x + z < y + z ↔ x < y := ⟨lt_of_add_lt_add_right, fun h => PartENat.add_lt_add_right h hz⟩ protected theorem add_lt_add_iff_left {x y z : PartENat} (hz : z ≠ ⊤) : z + x < z + y ↔ x < y := by rw [add_comm z, add_comm z, PartENat.add_lt_add_iff_right hz] protected theorem lt_add_iff_pos_right {x y : PartENat} (hx : x ≠ ⊤) : x < x + y ↔ 0 < y := by conv_rhs => rw [← PartENat.add_lt_add_iff_left hx] rw [add_zero] theorem lt_add_one {x : PartENat} (hx : x ≠ ⊤) : x < x + 1 := by rw [PartENat.lt_add_iff_pos_right hx] norm_cast theorem le_of_lt_add_one {x y : PartENat} (h : x < y + 1) : x ≤ y := by induction y using PartENat.casesOn · apply le_top rcases ne_top_iff.mp (ne_top_of_lt h) with ⟨m, rfl⟩ exact_mod_cast Nat.le_of_lt_succ (by norm_cast at h) theorem add_one_le_of_lt {x y : PartENat} (h : x < y) : x + 1 ≤ y := by induction y using PartENat.casesOn · apply le_top rcases ne_top_iff.mp (ne_top_of_lt h) with ⟨m, rfl⟩ exact_mod_cast Nat.succ_le_of_lt (by norm_cast at h) theorem add_one_le_iff_lt {x y : PartENat} (hx : x ≠ ⊤) : x + 1 ≤ y ↔ x < y := by refine ⟨fun h => ?_, add_one_le_of_lt⟩ rcases ne_top_iff.mp hx with ⟨m, rfl⟩ induction y using PartENat.casesOn · apply natCast_lt_top exact_mod_cast Nat.lt_of_succ_le (by norm_cast at h) theorem coe_succ_le_iff {n : ℕ} {e : PartENat} : ↑n.succ ≤ e ↔ ↑n < e := by rw [Nat.succ_eq_add_one n, Nat.cast_add, Nat.cast_one, add_one_le_iff_lt (natCast_ne_top n)] theorem lt_add_one_iff_lt {x y : PartENat} (hx : x ≠ ⊤) : x < y + 1 ↔ x ≤ y := by refine ⟨le_of_lt_add_one, fun h => ?_⟩ rcases ne_top_iff.mp hx with ⟨m, rfl⟩ induction y using PartENat.casesOn · rw [top_add] apply natCast_lt_top exact_mod_cast Nat.lt_succ_of_le (by norm_cast at h) lemma lt_coe_succ_iff_le {x : PartENat} {n : ℕ} (hx : x ≠ ⊤) : x < n.succ ↔ x ≤ n := by rw [Nat.succ_eq_add_one n, Nat.cast_add, Nat.cast_one, lt_add_one_iff_lt hx] theorem add_eq_top_iff {a b : PartENat} : a + b = ⊤ ↔ a = ⊤ ∨ b = ⊤ := by refine PartENat.casesOn a ?_ ?_ <;> refine PartENat.casesOn b ?_ ?_ <;> simp [top_add, add_top] simp only [← Nat.cast_add, PartENat.natCast_ne_top, forall_const, not_false_eq_true] protected theorem add_right_cancel_iff {a b c : PartENat} (hc : c ≠ ⊤) : a + c = b + c ↔ a = b := by rcases ne_top_iff.1 hc with ⟨c, rfl⟩ refine PartENat.casesOn a ?_ ?_ <;> refine PartENat.casesOn b ?_ ?_ <;> simp [add_eq_top_iff, natCast_ne_top, @eq_comm _ (⊤ : PartENat), top_add] simp only [← Nat.cast_add, add_left_cancel_iff, PartENat.natCast_inj, add_comm, forall_const] protected theorem add_left_cancel_iff {a b c : PartENat} (ha : a ≠ ⊤) : a + b = a + c ↔ b = c := by rw [add_comm a, add_comm a, PartENat.add_right_cancel_iff ha] section WithTop /-- Computably converts a `PartENat` to a `ℕ∞`. -/ def toWithTop (x : PartENat) [Decidable x.Dom] : ℕ∞ := x.toOption theorem toWithTop_top : have : Decidable (⊤ : PartENat).Dom := Part.noneDecidable toWithTop ⊤ = ⊤ := rfl @[simp] theorem toWithTop_top' {h : Decidable (⊤ : PartENat).Dom} : toWithTop ⊤ = ⊤ := by convert toWithTop_top theorem toWithTop_zero : have : Decidable (0 : PartENat).Dom := someDecidable 0 toWithTop 0 = 0 := rfl @[simp] theorem toWithTop_zero' {h : Decidable (0 : PartENat).Dom} : toWithTop 0 = 0 := by convert toWithTop_zero theorem toWithTop_one : have : Decidable (1 : PartENat).Dom := someDecidable 1 toWithTop 1 = 1 := rfl @[simp] theorem toWithTop_one' {h : Decidable (1 : PartENat).Dom} : toWithTop 1 = 1 := by convert toWithTop_one theorem toWithTop_some (n : ℕ) : toWithTop (some n) = n := rfl theorem toWithTop_natCast (n : ℕ) {_ : Decidable (n : PartENat).Dom} : toWithTop n = n := by simp only [← toWithTop_some] congr @[simp] theorem toWithTop_natCast' (n : ℕ) {_ : Decidable (n : PartENat).Dom} : toWithTop (n : PartENat) = n := by rw [toWithTop_natCast n] @[simp] theorem toWithTop_ofNat (n : ℕ) [n.AtLeastTwo] {_ : Decidable (OfNat.ofNat n : PartENat).Dom} : toWithTop (ofNat(n) : PartENat) = OfNat.ofNat n := toWithTop_natCast' n @[simp] theorem toWithTop_le {x y : PartENat} [hx : Decidable x.Dom] [hy : Decidable y.Dom] : toWithTop x ≤ toWithTop y ↔ x ≤ y := by induction y using PartENat.casesOn generalizing hy · simp induction x using PartENat.casesOn generalizing hx · simp · simp @[simp] theorem toWithTop_lt {x y : PartENat} [Decidable x.Dom] [Decidable y.Dom] : toWithTop x < toWithTop y ↔ x < y := lt_iff_lt_of_le_iff_le toWithTop_le end WithTop /-- Coercion from `ℕ∞` to `PartENat`. -/ @[coe] def ofENat : ℕ∞ → PartENat := fun x => match x with \| Option.none => none \| Option.some n => some n instance : Coe ℕ∞ PartENat := ⟨ofENat⟩ example (n : ℕ) : ((n : ℕ∞) : PartENat) = ↑n := rfl @[simp, norm_cast] lemma ofENat_top : ofENat ⊤ = ⊤ := rfl @[simp, norm_cast] lemma ofENat_coe (n : ℕ) : ofENat n = n := rfl @[simp, norm_cast] theorem ofENat_zero : ofENat 0 = 0 := rfl @[simp, norm_cast] theorem ofENat_one : ofENat 1 = 1 := rfl @[simp, norm_cast] theorem ofENat_ofNat (n : Nat) [n.AtLeastTwo] : ofENat ofNat(n) = OfNat.ofNat n := rfl @[simp, norm_cast] theorem toWithTop_ofENat (n : ℕ∞) {_ : Decidable (n : PartENat).Dom} : toWithTop (↑n) = n := by cases n with \| top => simp \| coe n => simp @[simp, norm_cast] theorem ofENat_toWithTop (x : PartENat) {_ : Decidable (x : PartENat).Dom} : toWithTop x = x := by induction x using PartENat.casesOn <;> simp @[simp, norm_cast] theorem ofENat_le {x y : ℕ∞} : ofENat x ≤ ofENat y ↔ x ≤ y := by classical rw [← toWithTop_le, toWithTop_ofENat, toWithTop_ofENat] @[simp, norm_cast] theorem ofENat_lt {x y : ℕ∞} : ofENat x < ofENat y ↔ x < y := by classical rw [← toWithTop_lt, toWithTop_ofENat, toWithTop_ofENat] section WithTopEquiv open scoped Classical in @[simp] theorem toWithTop_add {x y : PartENat} : toWithTop (x + y) = toWithTop x + toWithTop y := by refine PartENat.casesOn y ?_ ?_ <;> refine PartENat.casesOn x ?_ ?_ <;> simp [add_top, top_add, ← Nat.cast_add, ← ENat.coe_add] open scoped Classical in /-- `Equiv` between `PartENat` and `ℕ∞` (for the order isomorphism see `withTopOrderIso`). -/ @[simps] noncomputable def withTopEquiv : PartENat ≃ ℕ∞ where toFun x := toWithTop x invFun x := ↑x left_inv x := by simp right_inv x := by simp theorem withTopEquiv_top : withTopEquiv ⊤ = ⊤ := by simp theorem withTopEquiv_natCast (n : Nat) : withTopEquiv n = n := by simp theorem withTopEquiv_zero : withTopEquiv 0 = 0 := by simp theorem withTopEquiv_one : withTopEquiv 1 = 1 := by simp theorem withTopEquiv_ofNat (n : Nat) [n.AtLeastTwo] : withTopEquiv ofNat(n) = OfNat.ofNat n := by simp theorem withTopEquiv_le {x y : PartENat} : withTopEquiv x ≤ withTopEquiv y ↔ x ≤ y := by simp theorem withTopEquiv_lt {x y : PartENat} : withTopEquiv x < withTopEquiv y ↔ x < y := by simp theorem withTopEquiv_symm_top : withTopEquiv.symm ⊤ = ⊤ := by simp theorem withTopEquiv_symm_coe (n : Nat) : withTopEquiv.symm n = n := by simp theorem withTopEquiv_symm_zero : withTopEquiv.symm 0 = 0 := by simp theorem withTopEquiv_symm_one : withTopEquiv.symm 1 = 1 := by simp theorem withTopEquiv_symm_ofNat (n : Nat) [n.AtLeastTwo] : withTopEquiv.symm ofNat(n) = OfNat.ofNat n := by simp theorem withTopEquiv_symm_le {x y : ℕ∞} : withTopEquiv.symm x ≤ withTopEquiv.symm y ↔ x ≤ y := by simp theorem withTopEquiv_symm_lt {x y : ℕ∞} : withTopEquiv.symm x < withTopEquiv.symm y ↔ x < y := by simp /-- `toWithTop` induces an order isomorphism between `PartENat` and `ℕ∞`. -/ noncomputable def withTopOrderIso : PartENat ≃o ℕ∞ := { withTopEquiv with map_rel_iff' := @fun _ _ => withTopEquiv_le } /-- `toWithTop` induces an additive monoid isomorphism between `PartENat` and `ℕ∞`. -/ noncomputable def withTopAddEquiv : PartENat ≃+ ℕ∞ := { withTopEquiv with map_add' := fun x y => by simp only [withTopEquiv] exact toWithTop_add } end WithTopEquiv theorem lt_wf : @WellFounded PartENat (· < ·) := by classical change WellFounded fun a b : PartENat => a < b simp_rw [← withTopEquiv_lt] exact InvImage.wf _ wellFounded_lt instance : WellFoundedLT PartENat := ⟨lt_wf⟩ instance wellFoundedRelation : WellFoundedRelation PartENat := ⟨(· < ·), lt_wf⟩ section Find variable (P : ℕ → Prop) [DecidablePred P] /-- The smallest `PartENat` satisfying a (decidable) predicate `P : ℕ → Prop` -/ def find : PartENat := ⟨∃ n, P n, Nat.find⟩ @[simp] theorem find_get (h : (find P).Dom) : (find P).get h = Nat.find h := rfl theorem find_dom (h : ∃ n, P n) : (find P).Dom := h	theorem lt_find (n : ℕ) (h : ∀ m ≤ n, ¬P m) : (n : PartENat) < find P := by rw [coe_lt_iff] intro h₁	Mathlib/Data/Nat/PartENat.lean	706	709
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Yury Kudryashov -/ import Mathlib.Topology.Order.IsLUB /-! # Order topology on a densely ordered set -/ open Set Filter TopologicalSpace Topology Function open OrderDual (toDual ofDual) variable {α β : Type*} section DenselyOrdered variable [TopologicalSpace α] [LinearOrder α] [OrderTopology α] [DenselyOrdered α] {a b : α} {s : Set α} /-- The closure of the interval `(a, +∞)` is the closed interval `[a, +∞)`, unless `a` is a top element. -/ theorem closure_Ioi' {a : α} (h : (Ioi a).Nonempty) : closure (Ioi a) = Ici a := by apply Subset.antisymm · exact closure_minimal Ioi_subset_Ici_self isClosed_Ici · rw [← diff_subset_closure_iff, Ici_diff_Ioi_same, singleton_subset_iff] exact isGLB_Ioi.mem_closure h /-- The closure of the interval `(a, +∞)` is the closed interval `[a, +∞)`. -/ @[simp] theorem closure_Ioi (a : α) [NoMaxOrder α] : closure (Ioi a) = Ici a := closure_Ioi' nonempty_Ioi /-- The closure of the interval `(-∞, a)` is the closed interval `(-∞, a]`, unless `a` is a bottom element. -/ theorem closure_Iio' (h : (Iio a).Nonempty) : closure (Iio a) = Iic a := closure_Ioi' (α := αᵒᵈ) h /-- The closure of the interval `(-∞, a)` is the interval `(-∞, a]`. -/ @[simp] theorem closure_Iio (a : α) [NoMinOrder α] : closure (Iio a) = Iic a := closure_Iio' nonempty_Iio /-- The closure of the open interval `(a, b)` is the closed interval `[a, b]`. -/ @[simp] theorem closure_Ioo {a b : α} (hab : a ≠ b) : closure (Ioo a b) = Icc a b := by apply Subset.antisymm · exact closure_minimal Ioo_subset_Icc_self isClosed_Icc · rcases hab.lt_or_lt with hab \| hab · rw [← diff_subset_closure_iff, Icc_diff_Ioo_same hab.le] have hab' : (Ioo a b).Nonempty := nonempty_Ioo.2 hab simp only [insert_subset_iff, singleton_subset_iff] exact ⟨(isGLB_Ioo hab).mem_closure hab', (isLUB_Ioo hab).mem_closure hab'⟩ · rw [Icc_eq_empty_of_lt hab] exact empty_subset _ /-- The closure of the interval `(a, b]` is the closed interval `[a, b]`. -/ @[simp] theorem closure_Ioc {a b : α} (hab : a ≠ b) : closure (Ioc a b) = Icc a b := by apply Subset.antisymm · exact closure_minimal Ioc_subset_Icc_self isClosed_Icc · apply Subset.trans _ (closure_mono Ioo_subset_Ioc_self) rw [closure_Ioo hab] /-- The closure of the interval `[a, b)` is the closed interval `[a, b]`. -/ @[simp] theorem closure_Ico {a b : α} (hab : a ≠ b) : closure (Ico a b) = Icc a b := by apply Subset.antisymm · exact closure_minimal Ico_subset_Icc_self isClosed_Icc · apply Subset.trans _ (closure_mono Ioo_subset_Ico_self) rw [closure_Ioo hab] @[simp] theorem interior_Ici' {a : α} (ha : (Iio a).Nonempty) : interior (Ici a) = Ioi a := by rw [← compl_Iio, interior_compl, closure_Iio' ha, compl_Iic] theorem interior_Ici [NoMinOrder α] {a : α} : interior (Ici a) = Ioi a := interior_Ici' nonempty_Iio @[simp] theorem interior_Iic' {a : α} (ha : (Ioi a).Nonempty) : interior (Iic a) = Iio a := interior_Ici' (α := αᵒᵈ) ha theorem interior_Iic [NoMaxOrder α] {a : α} : interior (Iic a) = Iio a := interior_Iic' nonempty_Ioi @[simp] theorem interior_Icc [NoMinOrder α] [NoMaxOrder α] {a b : α} : interior (Icc a b) = Ioo a b := by rw [← Ici_inter_Iic, interior_inter, interior_Ici, interior_Iic, Ioi_inter_Iio] @[simp] theorem Icc_mem_nhds_iff [NoMinOrder α] [NoMaxOrder α] {a b x : α} : Icc a b ∈ 𝓝 x ↔ x ∈ Ioo a b := by rw [← interior_Icc, mem_interior_iff_mem_nhds] @[simp] theorem interior_Ico [NoMinOrder α] {a b : α} : interior (Ico a b) = Ioo a b := by rw [← Ici_inter_Iio, interior_inter, interior_Ici, interior_Iio, Ioi_inter_Iio] @[simp] theorem Ico_mem_nhds_iff [NoMinOrder α] {a b x : α} : Ico a b ∈ 𝓝 x ↔ x ∈ Ioo a b := by rw [← interior_Ico, mem_interior_iff_mem_nhds] @[simp] theorem interior_Ioc [NoMaxOrder α] {a b : α} : interior (Ioc a b) = Ioo a b := by rw [← Ioi_inter_Iic, interior_inter, interior_Ioi, interior_Iic, Ioi_inter_Iio] @[simp] theorem Ioc_mem_nhds_iff [NoMaxOrder α] {a b x : α} : Ioc a b ∈ 𝓝 x ↔ x ∈ Ioo a b := by rw [← interior_Ioc, mem_interior_iff_mem_nhds] theorem closure_interior_Icc {a b : α} (h : a ≠ b) : closure (interior (Icc a b)) = Icc a b := (closure_minimal interior_subset isClosed_Icc).antisymm <\| calc Icc a b = closure (Ioo a b) := (closure_Ioo h).symm _ ⊆ closure (interior (Icc a b)) := closure_mono (interior_maximal Ioo_subset_Icc_self isOpen_Ioo) theorem Ioc_subset_closure_interior (a b : α) : Ioc a b ⊆ closure (interior (Ioc a b)) := by rcases eq_or_ne a b with (rfl \| h) · simp · calc Ioc a b ⊆ Icc a b := Ioc_subset_Icc_self _ = closure (Ioo a b) := (closure_Ioo h).symm _ ⊆ closure (interior (Ioc a b)) := closure_mono (interior_maximal Ioo_subset_Ioc_self isOpen_Ioo) theorem Ico_subset_closure_interior (a b : α) : Ico a b ⊆ closure (interior (Ico a b)) := by simpa only [Ioc_toDual] using Ioc_subset_closure_interior (OrderDual.toDual b) (OrderDual.toDual a) @[simp] theorem frontier_Ici' {a : α} (ha : (Iio a).Nonempty) : frontier (Ici a) = {a} := by simp [frontier, ha] theorem frontier_Ici [NoMinOrder α] {a : α} : frontier (Ici a) = {a} := frontier_Ici' nonempty_Iio @[simp] theorem frontier_Iic' {a : α} (ha : (Ioi a).Nonempty) : frontier (Iic a) = {a} := by simp [frontier, ha] theorem frontier_Iic [NoMaxOrder α] {a : α} : frontier (Iic a) = {a} := frontier_Iic' nonempty_Ioi @[simp] theorem frontier_Ioi' {a : α} (ha : (Ioi a).Nonempty) : frontier (Ioi a) = {a} := by simp [frontier, closure_Ioi' ha, Iic_diff_Iio, Icc_self] theorem frontier_Ioi [NoMaxOrder α] {a : α} : frontier (Ioi a) = {a} := frontier_Ioi' nonempty_Ioi @[simp] theorem frontier_Iio' {a : α} (ha : (Iio a).Nonempty) : frontier (Iio a) = {a} := by simp [frontier, closure_Iio' ha, Iic_diff_Iio, Icc_self] theorem frontier_Iio [NoMinOrder α] {a : α} : frontier (Iio a) = {a} := frontier_Iio' nonempty_Iio @[simp] theorem frontier_Icc [NoMinOrder α] [NoMaxOrder α] {a b : α} (h : a ≤ b) : frontier (Icc a b) = {a, b} := by simp [frontier, h, Icc_diff_Ioo_same] @[simp] theorem frontier_Ioo {a b : α} (h : a < b) : frontier (Ioo a b) = {a, b} := by rw [frontier, closure_Ioo h.ne, interior_Ioo, Icc_diff_Ioo_same h.le] @[simp] theorem frontier_Ico [NoMinOrder α] {a b : α} (h : a < b) : frontier (Ico a b) = {a, b} := by rw [frontier, closure_Ico h.ne, interior_Ico, Icc_diff_Ioo_same h.le] @[simp] theorem frontier_Ioc [NoMaxOrder α] {a b : α} (h : a < b) : frontier (Ioc a b) = {a, b} := by rw [frontier, closure_Ioc h.ne, interior_Ioc, Icc_diff_Ioo_same h.le] theorem nhdsWithin_Ioi_neBot' {a b : α} (H₁ : (Ioi a).Nonempty) (H₂ : a ≤ b) : NeBot (𝓝[Ioi a] b) := mem_closure_iff_nhdsWithin_neBot.1 <\| by rwa [closure_Ioi' H₁] theorem nhdsWithin_Ioi_neBot [NoMaxOrder α] {a b : α} (H : a ≤ b) : NeBot (𝓝[Ioi a] b) := nhdsWithin_Ioi_neBot' nonempty_Ioi H theorem nhdsGT_neBot_of_exists_gt {a : α} (H : ∃ b, a < b) : NeBot (𝓝[>] a) := nhdsWithin_Ioi_neBot' H (le_refl a) @[deprecated (since := "2024-12-22")] alias nhdsWithin_Ioi_self_neBot' := nhdsGT_neBot_of_exists_gt instance nhdsGT_neBot [NoMaxOrder α] (a : α) : NeBot (𝓝[>] a) := nhdsWithin_Ioi_neBot le_rfl @[deprecated nhdsGT_neBot (since := "2024-12-22")] theorem nhdsWithin_Ioi_self_neBot [NoMaxOrder α] (a : α) : NeBot (𝓝[>] a) := nhdsGT_neBot a theorem nhdsWithin_Iio_neBot' {b c : α} (H₁ : (Iio c).Nonempty) (H₂ : b ≤ c) : NeBot (𝓝[Iio c] b) := mem_closure_iff_nhdsWithin_neBot.1 <\| by rwa [closure_Iio' H₁] theorem nhdsWithin_Iio_neBot [NoMinOrder α] {a b : α} (H : a ≤ b) : NeBot (𝓝[Iio b] a) := nhdsWithin_Iio_neBot' nonempty_Iio H theorem nhdsWithin_Iio_self_neBot' {b : α} (H : (Iio b).Nonempty) : NeBot (𝓝[<] b) := nhdsWithin_Iio_neBot' H (le_refl b) instance nhdsLT_neBot [NoMinOrder α] (a : α) : NeBot (𝓝[<] a) := nhdsWithin_Iio_neBot (le_refl a) @[deprecated nhdsLT_neBot (since := "2024-12-22")] theorem nhdsWithin_Iio_self_neBot [NoMinOrder α] (a : α) : NeBot (𝓝[<] a) := nhdsLT_neBot a theorem right_nhdsWithin_Ico_neBot {a b : α} (H : a < b) : NeBot (𝓝[Ico a b] b) := (isLUB_Ico H).nhdsWithin_neBot (nonempty_Ico.2 H) theorem left_nhdsWithin_Ioc_neBot {a b : α} (H : a < b) : NeBot (𝓝[Ioc a b] a) := (isGLB_Ioc H).nhdsWithin_neBot (nonempty_Ioc.2 H) theorem left_nhdsWithin_Ioo_neBot {a b : α} (H : a < b) : NeBot (𝓝[Ioo a b] a) := (isGLB_Ioo H).nhdsWithin_neBot (nonempty_Ioo.2 H) theorem right_nhdsWithin_Ioo_neBot {a b : α} (H : a < b) : NeBot (𝓝[Ioo a b] b) := (isLUB_Ioo H).nhdsWithin_neBot (nonempty_Ioo.2 H) theorem comap_coe_nhdsLT_of_Ioo_subset (hb : s ⊆ Iio b) (hs : s.Nonempty → ∃ a < b, Ioo a b ⊆ s) : comap ((↑) : s → α) (𝓝[<] b) = atTop := by nontriviality haveI : Nonempty s := nontrivial_iff_nonempty.1 ‹_› rcases hs (nonempty_subtype.1 ‹_›) with ⟨a, h, hs⟩ ext u; constructor · rintro ⟨t, ht, hts⟩ obtain ⟨x, ⟨hxa : a ≤ x, hxb : x < b⟩, hxt : Ioo x b ⊆ t⟩ := (mem_nhdsLT_iff_exists_mem_Ico_Ioo_subset h).mp ht obtain ⟨y, hxy, hyb⟩ := exists_between hxb refine mem_of_superset (mem_atTop ⟨y, hs ⟨hxa.trans_lt hxy, hyb⟩⟩) ?_ rintro ⟨z, hzs⟩ (hyz : y ≤ z) exact hts (hxt ⟨hxy.trans_le hyz, hb hzs⟩) · intro hu obtain ⟨x : s, hx : ∀ z, x ≤ z → z ∈ u⟩ := mem_atTop_sets.1 hu exact ⟨Ioo x b, Ioo_mem_nhdsLT (hb x.2), fun z hz => hx _ hz.1.le⟩ @[deprecated (since := "2024-12-22")] alias comap_coe_nhdsWithin_Iio_of_Ioo_subset := comap_coe_nhdsLT_of_Ioo_subset theorem comap_coe_nhdsGT_of_Ioo_subset (ha : s ⊆ Ioi a) (hs : s.Nonempty → ∃ b > a, Ioo a b ⊆ s) : comap ((↑) : s → α) (𝓝[>] a) = atBot := by apply comap_coe_nhdsLT_of_Ioo_subset (show ofDual ⁻¹' s ⊆ Iio (toDual a) from ha) simp only [OrderDual.exists, Ioo_toDual] exact hs @[deprecated (since := "2024-12-22")] alias comap_coe_nhdsWithin_Ioi_of_Ioo_subset := comap_coe_nhdsGT_of_Ioo_subset theorem map_coe_atTop_of_Ioo_subset (hb : s ⊆ Iio b) (hs : ∀ a' < b, ∃ a < b, Ioo a b ⊆ s) : map ((↑) : s → α) atTop = 𝓝[<] b := by rcases eq_empty_or_nonempty (Iio b) with (hb' \| ⟨a, ha⟩) · have : IsEmpty s := ⟨fun x => hb'.subset (hb x.2)⟩ rw [filter_eq_bot_of_isEmpty atTop, Filter.map_bot, hb', nhdsWithin_empty] · rw [← comap_coe_nhdsLT_of_Ioo_subset hb fun _ => hs a ha, map_comap_of_mem] rw [Subtype.range_val] exact (mem_nhdsLT_iff_exists_Ioo_subset' ha).2 (hs a ha) theorem map_coe_atBot_of_Ioo_subset (ha : s ⊆ Ioi a) (hs : ∀ b' > a, ∃ b > a, Ioo a b ⊆ s) : map ((↑) : s → α) atBot = 𝓝[>] a := by -- the elaborator gets stuck without `(... :)` refine (map_coe_atTop_of_Ioo_subset (show ofDual ⁻¹' s ⊆ Iio (toDual a) from ha) fun b' hb' => ?_ :) simpa using hs b' hb' /-- The `atTop` filter for an open interval `Ioo a b` comes from the left-neighbourhoods filter at the right endpoint in the ambient order. -/ theorem comap_coe_Ioo_nhdsLT (a b : α) : comap ((↑) : Ioo a b → α) (𝓝[<] b) = atTop := comap_coe_nhdsLT_of_Ioo_subset Ioo_subset_Iio_self fun h => ⟨a, nonempty_Ioo.1 h, Subset.refl _⟩ @[deprecated (since := "2024-12-22")] alias comap_coe_Ioo_nhdsWithin_Iio := comap_coe_Ioo_nhdsLT /-- The `atBot` filter for an open interval `Ioo a b` comes from the right-neighbourhoods filter at the left endpoint in the ambient order. -/ theorem comap_coe_Ioo_nhdsGT (a b : α) : comap ((↑) : Ioo a b → α) (𝓝[>] a) = atBot := comap_coe_nhdsGT_of_Ioo_subset Ioo_subset_Ioi_self fun h => ⟨b, nonempty_Ioo.1 h, Subset.refl _⟩ @[deprecated (since := "2024-12-22")] alias comap_coe_Ioo_nhdsWithin_Ioi := comap_coe_Ioo_nhdsGT theorem comap_coe_Ioi_nhdsGT (a : α) : comap ((↑) : Ioi a → α) (𝓝[>] a) = atBot := comap_coe_nhdsGT_of_Ioo_subset (Subset.refl _) fun ⟨x, hx⟩ => ⟨x, hx, Ioo_subset_Ioi_self⟩ @[deprecated (since := "2024-12-22")] alias comap_coe_Ioi_nhdsWithin_Ioi := comap_coe_Ioi_nhdsGT theorem comap_coe_Iio_nhdsLT (a : α) : comap ((↑) : Iio a → α) (𝓝[<] a) = atTop := comap_coe_Ioi_nhdsGT (α := αᵒᵈ) a @[deprecated (since := "2024-12-22")] alias comap_coe_Iio_nhdsWithin_Iio := comap_coe_Iio_nhdsLT @[simp] theorem map_coe_Ioo_atTop {a b : α} (h : a < b) : map ((↑) : Ioo a b → α) atTop = 𝓝[<] b := map_coe_atTop_of_Ioo_subset Ioo_subset_Iio_self fun _ _ => ⟨_, h, Subset.refl _⟩ @[simp] theorem map_coe_Ioo_atBot {a b : α} (h : a < b) : map ((↑) : Ioo a b → α) atBot = 𝓝[>] a := map_coe_atBot_of_Ioo_subset Ioo_subset_Ioi_self fun _ _ => ⟨_, h, Subset.refl _⟩ @[simp] theorem map_coe_Ioi_atBot (a : α) : map ((↑) : Ioi a → α) atBot = 𝓝[>] a := map_coe_atBot_of_Ioo_subset (Subset.refl _) fun b hb => ⟨b, hb, Ioo_subset_Ioi_self⟩ @[simp] theorem map_coe_Iio_atTop (a : α) : map ((↑) : Iio a → α) atTop = 𝓝[<] a := map_coe_Ioi_atBot (α := αᵒᵈ) _ variable {l : Filter β} {f : α → β} @[simp] theorem tendsto_comp_coe_Ioo_atTop (h : a < b) : Tendsto (fun x : Ioo a b => f x) atTop l ↔ Tendsto f (𝓝[<] b) l := by rw [← map_coe_Ioo_atTop h, tendsto_map'_iff]; rfl @[simp] theorem tendsto_comp_coe_Ioo_atBot (h : a < b) : Tendsto (fun x : Ioo a b => f x) atBot l ↔ Tendsto f (𝓝[>] a) l := by rw [← map_coe_Ioo_atBot h, tendsto_map'_iff]; rfl @[simp] theorem tendsto_comp_coe_Ioi_atBot : Tendsto (fun x : Ioi a => f x) atBot l ↔ Tendsto f (𝓝[>] a) l := by rw [← map_coe_Ioi_atBot, tendsto_map'_iff]; rfl @[simp] theorem tendsto_comp_coe_Iio_atTop : Tendsto (fun x : Iio a => f x) atTop l ↔ Tendsto f (𝓝[<] a) l := by rw [← map_coe_Iio_atTop, tendsto_map'_iff]; rfl @[simp] theorem tendsto_Ioo_atTop {f : β → Ioo a b} : Tendsto f l atTop ↔ Tendsto (fun x => (f x : α)) l (𝓝[<] b) := by rw [← comap_coe_Ioo_nhdsLT, tendsto_comap_iff]; rfl @[simp] theorem tendsto_Ioo_atBot {f : β → Ioo a b} : Tendsto f l atBot ↔ Tendsto (fun x => (f x : α)) l (𝓝[>] a) := by rw [← comap_coe_Ioo_nhdsGT, tendsto_comap_iff]; rfl @[simp] theorem tendsto_Ioi_atBot {f : β → Ioi a} : Tendsto f l atBot ↔ Tendsto (fun x => (f x : α)) l (𝓝[>] a) := by rw [← comap_coe_Ioi_nhdsGT, tendsto_comap_iff]; rfl @[simp] theorem tendsto_Iio_atTop {f : β → Iio a} : Tendsto f l atTop ↔ Tendsto (fun x => (f x : α)) l (𝓝[<] a) := by rw [← comap_coe_Iio_nhdsLT, tendsto_comap_iff]; rfl instance (x : α) [Nontrivial α] : NeBot (𝓝[≠] x) := by refine forall_mem_nonempty_iff_neBot.1 fun s hs => ?_ obtain ⟨u, u_open, xu, us⟩ : ∃ u : Set α, IsOpen u ∧ x ∈ u ∧ u ∩ {x}ᶜ ⊆ s := mem_nhdsWithin.1 hs obtain ⟨a, b, a_lt_b, hab⟩ : ∃ a b : α, a < b ∧ Ioo a b ⊆ u := u_open.exists_Ioo_subset ⟨x, xu⟩ obtain ⟨y, hy⟩ : ∃ y, a < y ∧ y < b := exists_between a_lt_b rcases ne_or_eq x y with (xy \| rfl) · exact ⟨y, us ⟨hab hy, xy.symm⟩⟩ obtain ⟨z, hz⟩ : ∃ z, a < z ∧ z < x := exists_between hy.1 exact ⟨z, us ⟨hab ⟨hz.1, hz.2.trans hy.2⟩, hz.2.ne⟩⟩ /-- Let `s` be a dense set in a nontrivial dense linear order `α`. If `s` is a separable space (e.g., if `α` has a second countable topology), then there exists a countable dense subset `t ⊆ s` such that `t` does not contain bottom/top elements of `α`. -/ theorem Dense.exists_countable_dense_subset_no_bot_top [Nontrivial α] {s : Set α} [SeparableSpace s] (hs : Dense s) : ∃ t, t ⊆ s ∧ t.Countable ∧ Dense t ∧ (∀ x, IsBot x → x ∉ t) ∧ ∀ x, IsTop x → x ∉ t := by rcases hs.exists_countable_dense_subset with ⟨t, hts, htc, htd⟩ refine ⟨t \ ({ x \| IsBot x } ∪ { x \| IsTop x }), ?_, ?_, ?_, fun x hx => ?_, fun x hx => ?_⟩ · exact diff_subset.trans hts · exact htc.mono diff_subset · exact htd.diff_finite ((subsingleton_isBot α).finite.union (subsingleton_isTop α).finite) · simp [hx] · simp [hx] variable (α) in /-- If `α` is a nontrivial separable dense linear order, then there exists a countable dense set `s : Set α` that contains neither top nor bottom elements of `α`. For a dense set containing both bot and top elements, see `exists_countable_dense_bot_top`. -/ theorem exists_countable_dense_no_bot_top [SeparableSpace α] [Nontrivial α] : ∃ s : Set α, s.Countable ∧ Dense s ∧ (∀ x, IsBot x → x ∉ s) ∧ ∀ x, IsTop x → x ∉ s := by simpa using dense_univ.exists_countable_dense_subset_no_bot_top /-- `Set.Ico a b` is only closed if it is empty. -/ @[simp] theorem isClosed_Ico_iff {a b : α} : IsClosed (Set.Ico a b) ↔ b ≤ a := by refine ⟨fun h => le_of_not_lt fun hab => ?_, by simp_all⟩ have := h.closure_eq rw [closure_Ico hab.ne, Icc_eq_Ico_same_iff] at this exact this hab.le /-- `Set.Ioc a b` is only closed if it is empty. -/ @[simp] theorem isClosed_Ioc_iff {a b : α} : IsClosed (Set.Ioc a b) ↔ b ≤ a := by refine ⟨fun h => le_of_not_lt fun hab => ?_, by simp_all⟩ have := h.closure_eq rw [closure_Ioc hab.ne, Icc_eq_Ioc_same_iff] at this exact this hab.le /-- `Set.Ioo a b` is only closed if it is empty. -/ @[simp] theorem isClosed_Ioo_iff {a b : α} : IsClosed (Set.Ioo a b) ↔ b ≤ a := by refine ⟨fun h => le_of_not_lt fun hab => ?_, by simp_all⟩ have := h.closure_eq rw [closure_Ioo hab.ne, Icc_eq_Ioo_same_iff] at this exact this hab.le end DenselyOrdered		Mathlib/Topology/Order/DenselyOrdered.lean	426	428
/- Copyright (c) 2022 Yakov Pechersky. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Kenny Lau, Johan Commelin, Mario Carneiro, Kevin Buzzard, Amelia Livingston, Yury Kudryashov, Yakov Pechersky, Jireh Loreaux -/ import Mathlib.Algebra.Group.Prod import Mathlib.Algebra.Group.Subsemigroup.Basic import Mathlib.Algebra.Group.TypeTags.Basic /-! # Operations on `Subsemigroup`s In this file we define various operations on `Subsemigroup`s and `MulHom`s. ## Main definitions ### Conversion between multiplicative and additive definitions * `Subsemigroup.toAddSubsemigroup`, `Subsemigroup.toAddSubsemigroup'`, `AddSubsemigroup.toSubsemigroup`, `AddSubsemigroup.toSubsemigroup'`: convert between multiplicative and additive subsemigroups of `M`, `Multiplicative M`, and `Additive M`. These are stated as `OrderIso`s. ### (Commutative) semigroup structure on a subsemigroup * `Subsemigroup.toSemigroup`, `Subsemigroup.toCommSemigroup`: a subsemigroup inherits a (commutative) semigroup structure. ### Operations on subsemigroups * `Subsemigroup.comap`: preimage of a subsemigroup under a semigroup homomorphism as a subsemigroup of the domain; * `Subsemigroup.map`: image of a subsemigroup under a semigroup homomorphism as a subsemigroup of the codomain; * `Subsemigroup.prod`: product of two subsemigroups `s : Subsemigroup M` and `t : Subsemigroup N` as a subsemigroup of `M × N`; ### Semigroup homomorphisms between subsemigroups * `Subsemigroup.subtype`: embedding of a subsemigroup into the ambient semigroup. * `Subsemigroup.inclusion`: given two subsemigroups `S`, `T` such that `S ≤ T`, `S.inclusion T` is the inclusion of `S` into `T` as a semigroup homomorphism; * `MulEquiv.subsemigroupCongr`: converts a proof of `S = T` into a semigroup isomorphism between `S` and `T`. * `Subsemigroup.prodEquiv`: semigroup isomorphism between `s.prod t` and `s × t`; ### Operations on `MulHom`s * `MulHom.srange`: range of a semigroup homomorphism as a subsemigroup of the codomain; * `MulHom.restrict`: restrict a semigroup homomorphism to a subsemigroup; * `MulHom.codRestrict`: restrict the codomain of a semigroup homomorphism to a subsemigroup; * `MulHom.srangeRestrict`: restrict a semigroup homomorphism to its range; ### Implementation notes This file follows closely `GroupTheory/Submonoid/Operations.lean`, omitting only that which is necessary. ## Tags subsemigroup, range, product, map, comap -/ assert_not_exists MonoidWithZero variable {M N P σ : Type} /-! ### Conversion to/from `Additive`/`Multiplicative` -/ section variable [Mul M] /-- Subsemigroups of semigroup `M` are isomorphic to additive subsemigroups of `Additive M`. -/ @[simps] def Subsemigroup.toAddSubsemigroup : Subsemigroup M ≃o AddSubsemigroup (Additive M) where toFun S := { carrier := Additive.toMul ⁻¹' S add_mem' := S.mul_mem' } invFun S := { carrier := Additive.ofMul ⁻¹' S mul_mem' := S.add_mem' } left_inv _ := rfl right_inv _ := rfl map_rel_iff' := Iff.rfl /-- Additive subsemigroups of an additive semigroup `Additive M` are isomorphic to subsemigroups of `M`. -/ abbrev AddSubsemigroup.toSubsemigroup' : AddSubsemigroup (Additive M) ≃o Subsemigroup M := Subsemigroup.toAddSubsemigroup.symm theorem Subsemigroup.toAddSubsemigroup_closure (S : Set M) : Subsemigroup.toAddSubsemigroup (Subsemigroup.closure S) = AddSubsemigroup.closure (Additive.toMul ⁻¹' S) := le_antisymm (Subsemigroup.toAddSubsemigroup.le_symm_apply.1 <\| Subsemigroup.closure_le.2 (AddSubsemigroup.subset_closure (M := Additive M))) (AddSubsemigroup.closure_le.2 (Subsemigroup.subset_closure (M := M))) theorem AddSubsemigroup.toSubsemigroup'_closure (S : Set (Additive M)) : AddSubsemigroup.toSubsemigroup' (AddSubsemigroup.closure S) = Subsemigroup.closure (Additive.ofMul ⁻¹' S) := le_antisymm (AddSubsemigroup.toSubsemigroup'.le_symm_apply.1 <\| AddSubsemigroup.closure_le.2 (Subsemigroup.subset_closure (M := M))) (Subsemigroup.closure_le.2 <\| AddSubsemigroup.subset_closure (M := Additive M)) end section variable {A : Type} [Add A] /-- Additive subsemigroups of an additive semigroup `A` are isomorphic to multiplicative subsemigroups of `Multiplicative A`. -/ @[simps] def AddSubsemigroup.toSubsemigroup : AddSubsemigroup A ≃o Subsemigroup (Multiplicative A) where toFun S := { carrier := Multiplicative.toAdd ⁻¹' S mul_mem' := S.add_mem' } invFun S := { carrier := Multiplicative.ofAdd ⁻¹' S add_mem' := S.mul_mem' } left_inv _ := rfl right_inv _ := rfl map_rel_iff' := Iff.rfl /-- Subsemigroups of a semigroup `Multiplicative A` are isomorphic to additive subsemigroups of `A`. -/ abbrev Subsemigroup.toAddSubsemigroup' : Subsemigroup (Multiplicative A) ≃o AddSubsemigroup A := AddSubsemigroup.toSubsemigroup.symm theorem AddSubsemigroup.toSubsemigroup_closure (S : Set A) : AddSubsemigroup.toSubsemigroup (AddSubsemigroup.closure S) = Subsemigroup.closure (Multiplicative.toAdd ⁻¹' S) := le_antisymm (AddSubsemigroup.toSubsemigroup.to_galoisConnection.l_le <\| AddSubsemigroup.closure_le.2 <\| Subsemigroup.subset_closure (M := Multiplicative A)) (Subsemigroup.closure_le.2 <\| AddSubsemigroup.subset_closure (M := A)) theorem Subsemigroup.toAddSubsemigroup'_closure (S : Set (Multiplicative A)) : Subsemigroup.toAddSubsemigroup' (Subsemigroup.closure S) = AddSubsemigroup.closure (Multiplicative.ofAdd ⁻¹' S) := le_antisymm (Subsemigroup.toAddSubsemigroup'.to_galoisConnection.l_le <\| Subsemigroup.closure_le.2 <\| AddSubsemigroup.subset_closure (M := A)) (AddSubsemigroup.closure_le.2 <\| Subsemigroup.subset_closure (M := Multiplicative A)) end namespace Subsemigroup open Set /-! ### `comap` and `map` -/ variable [Mul M] [Mul N] [Mul P] (S : Subsemigroup M) /-- The preimage of a subsemigroup along a semigroup homomorphism is a subsemigroup. -/ @[to_additive "The preimage of an `AddSubsemigroup` along an `AddSemigroup` homomorphism is an `AddSubsemigroup`."] def comap (f : M →ₙ* N) (S : Subsemigroup N) : Subsemigroup M where carrier := f ⁻¹' S mul_mem' ha hb := show f (_ * _) ∈ S by rw [map_mul]; exact mul_mem ha hb @[to_additive (attr := simp)] theorem coe_comap (S : Subsemigroup N) (f : M →ₙ* N) : (S.comap f : Set M) = f ⁻¹' S := rfl @[to_additive (attr := simp)] theorem mem_comap {S : Subsemigroup N} {f : M →ₙ* N} {x : M} : x ∈ S.comap f ↔ f x ∈ S := Iff.rfl @[to_additive] theorem comap_comap (S : Subsemigroup P) (g : N →ₙ* P) (f : M →ₙ* N) : (S.comap g).comap f = S.comap (g.comp f) := rfl @[to_additive (attr := simp)] theorem comap_id (S : Subsemigroup P) : S.comap (MulHom.id _) = S := ext (by simp) /-- The image of a subsemigroup along a semigroup homomorphism is a subsemigroup. -/ @[to_additive "The image of an `AddSubsemigroup` along an `AddSemigroup` homomorphism is an `AddSubsemigroup`."] def map (f : M →ₙ* N) (S : Subsemigroup M) : Subsemigroup N where carrier := f '' S mul_mem' := by rintro _ _ ⟨x, hx, rfl⟩ ⟨y, hy, rfl⟩ exact ⟨x * y, @mul_mem (Subsemigroup M) M _ _ _ _ _ _ hx hy, by rw [map_mul]⟩ @[to_additive (attr := simp)] theorem coe_map (f : M →ₙ* N) (S : Subsemigroup M) : (S.map f : Set N) = f '' S := rfl @[to_additive (attr := simp)] theorem mem_map {f : M →ₙ* N} {S : Subsemigroup M} {y : N} : y ∈ S.map f ↔ ∃ x ∈ S, f x = y := mem_image _ _ _ @[to_additive] theorem mem_map_of_mem (f : M →ₙ* N) {S : Subsemigroup M} {x : M} (hx : x ∈ S) : f x ∈ S.map f := mem_image_of_mem f hx @[to_additive] theorem apply_coe_mem_map (f : M →ₙ* N) (S : Subsemigroup M) (x : S) : f x ∈ S.map f := mem_map_of_mem f x.prop @[to_additive] theorem map_map (g : N →ₙ* P) (f : M →ₙ* N) : (S.map f).map g = S.map (g.comp f) := SetLike.coe_injective <\| image_image _ _ _ -- The simpNF linter says that the LHS can be simplified via `Subsemigroup.mem_map`. -- However this is a higher priority lemma. -- It seems the side condition `hf` is not applied by `simpNF`. -- https://github.com/leanprover/std4/issues/207 @[to_additive (attr := simp, nolint simpNF)] theorem mem_map_iff_mem {f : M →ₙ* N} (hf : Function.Injective f) {S : Subsemigroup M} {x : M} : f x ∈ S.map f ↔ x ∈ S := hf.mem_set_image @[to_additive] theorem map_le_iff_le_comap {f : M →ₙ* N} {S : Subsemigroup M} {T : Subsemigroup N} : S.map f ≤ T ↔ S ≤ T.comap f := image_subset_iff @[to_additive] theorem gc_map_comap (f : M →ₙ* N) : GaloisConnection (map f) (comap f) := fun _ _ => map_le_iff_le_comap @[to_additive] theorem map_le_of_le_comap {T : Subsemigroup N} {f : M →ₙ* N} : S ≤ T.comap f → S.map f ≤ T := (gc_map_comap f).l_le @[to_additive] theorem le_comap_of_map_le {T : Subsemigroup N} {f : M →ₙ* N} : S.map f ≤ T → S ≤ T.comap f := (gc_map_comap f).le_u @[to_additive] theorem le_comap_map {f : M →ₙ* N} : S ≤ (S.map f).comap f := (gc_map_comap f).le_u_l _ @[to_additive] theorem map_comap_le {S : Subsemigroup N} {f : M →ₙ* N} : (S.comap f).map f ≤ S := (gc_map_comap f).l_u_le _ @[to_additive] theorem monotone_map {f : M →ₙ* N} : Monotone (map f) := (gc_map_comap f).monotone_l @[to_additive] theorem monotone_comap {f : M →ₙ* N} : Monotone (comap f) := (gc_map_comap f).monotone_u @[to_additive (attr := simp)] theorem map_comap_map {f : M →ₙ* N} : ((S.map f).comap f).map f = S.map f := (gc_map_comap f).l_u_l_eq_l _ @[to_additive (attr := simp)] theorem comap_map_comap {S : Subsemigroup N} {f : M →ₙ* N} : ((S.comap f).map f).comap f = S.comap f := (gc_map_comap f).u_l_u_eq_u _ @[to_additive] theorem map_sup (S T : Subsemigroup M) (f : M →ₙ* N) : (S ⊔ T).map f = S.map f ⊔ T.map f := (gc_map_comap f).l_sup @[to_additive] theorem map_iSup {ι : Sort} (f : M →ₙ N) (s : ι → Subsemigroup M) : (iSup s).map f = ⨆ i, (s i).map f := (gc_map_comap f).l_iSup @[to_additive] theorem map_inf (S T : Subsemigroup M) (f : M →ₙ* N) (hf : Function.Injective f) : (S ⊓ T).map f = S.map f ⊓ T.map f := SetLike.coe_injective (Set.image_inter hf) @[to_additive] theorem map_iInf {ι : Sort} [Nonempty ι] (f : M →ₙ N) (hf : Function.Injective f) (s : ι → Subsemigroup M) : (iInf s).map f = ⨅ i, (s i).map f := by apply SetLike.coe_injective simpa using (Set.injOn_of_injective hf).image_iInter_eq (s := SetLike.coe ∘ s) @[to_additive] theorem comap_inf (S T : Subsemigroup N) (f : M →ₙ* N) : (S ⊓ T).comap f = S.comap f ⊓ T.comap f := (gc_map_comap f).u_inf @[to_additive] theorem comap_iInf {ι : Sort} (f : M →ₙ N) (s : ι → Subsemigroup N) : (iInf s).comap f = ⨅ i, (s i).comap f := (gc_map_comap f).u_iInf @[to_additive (attr := simp)] theorem map_bot (f : M →ₙ* N) : (⊥ : Subsemigroup M).map f = ⊥ := (gc_map_comap f).l_bot @[to_additive (attr := simp)] theorem comap_top (f : M →ₙ* N) : (⊤ : Subsemigroup N).comap f = ⊤ := (gc_map_comap f).u_top @[to_additive (attr := simp)] theorem map_id (S : Subsemigroup M) : S.map (MulHom.id M) = S := ext fun _ => ⟨fun ⟨_, h, rfl⟩ => h, fun h => ⟨_, h, rfl⟩⟩ section GaloisCoinsertion variable {ι : Type} {f : M →ₙ N} /-- `map f` and `comap f` form a `GaloisCoinsertion` when `f` is injective. -/ @[to_additive "`map f` and `comap f` form a `GaloisCoinsertion` when `f` is injective."] def gciMapComap (hf : Function.Injective f) : GaloisCoinsertion (map f) (comap f) := (gc_map_comap f).toGaloisCoinsertion fun S x => by simp [mem_comap, mem_map, hf.eq_iff] variable (hf : Function.Injective f) include hf @[to_additive] theorem comap_map_eq_of_injective (S : Subsemigroup M) : (S.map f).comap f = S := (gciMapComap hf).u_l_eq _ @[to_additive] theorem comap_surjective_of_injective : Function.Surjective (comap f) := (gciMapComap hf).u_surjective @[to_additive] theorem map_injective_of_injective : Function.Injective (map f) := (gciMapComap hf).l_injective @[to_additive] theorem comap_inf_map_of_injective (S T : Subsemigroup M) : (S.map f ⊓ T.map f).comap f = S ⊓ T := (gciMapComap hf).u_inf_l _ _ @[to_additive] theorem comap_iInf_map_of_injective (S : ι → Subsemigroup M) : (⨅ i, (S i).map f).comap f = iInf S := (gciMapComap hf).u_iInf_l _ @[to_additive] theorem comap_sup_map_of_injective (S T : Subsemigroup M) : (S.map f ⊔ T.map f).comap f = S ⊔ T := (gciMapComap hf).u_sup_l _ _ @[to_additive] theorem comap_iSup_map_of_injective (S : ι → Subsemigroup M) : (⨆ i, (S i).map f).comap f = iSup S := (gciMapComap hf).u_iSup_l _ @[to_additive] theorem map_le_map_iff_of_injective {S T : Subsemigroup M} : S.map f ≤ T.map f ↔ S ≤ T := (gciMapComap hf).l_le_l_iff @[to_additive] theorem map_strictMono_of_injective : StrictMono (map f) := (gciMapComap hf).strictMono_l end GaloisCoinsertion section GaloisInsertion variable {ι : Type} {f : M →ₙ N} (hf : Function.Surjective f) include hf /-- `map f` and `comap f` form a `GaloisInsertion` when `f` is surjective. -/ @[to_additive "`map f` and `comap f` form a `GaloisInsertion` when `f` is surjective."] def giMapComap : GaloisInsertion (map f) (comap f) := (gc_map_comap f).toGaloisInsertion fun S x h => let ⟨y, hy⟩ := hf x mem_map.2 ⟨y, by simp [hy, h]⟩ @[to_additive] theorem map_comap_eq_of_surjective (S : Subsemigroup N) : (S.comap f).map f = S := (giMapComap hf).l_u_eq _ @[to_additive] theorem map_surjective_of_surjective : Function.Surjective (map f) := (giMapComap hf).l_surjective @[to_additive] theorem comap_injective_of_surjective : Function.Injective (comap f) := (giMapComap hf).u_injective @[to_additive] theorem map_inf_comap_of_surjective (S T : Subsemigroup N) : (S.comap f ⊓ T.comap f).map f = S ⊓ T := (giMapComap hf).l_inf_u _ _ @[to_additive] theorem map_iInf_comap_of_surjective (S : ι → Subsemigroup N) : (⨅ i, (S i).comap f).map f = iInf S := (giMapComap hf).l_iInf_u _ @[to_additive] theorem map_sup_comap_of_surjective (S T : Subsemigroup N) : (S.comap f ⊔ T.comap f).map f = S ⊔ T := (giMapComap hf).l_sup_u _ _ @[to_additive] theorem map_iSup_comap_of_surjective (S : ι → Subsemigroup N) : (⨆ i, (S i).comap f).map f = iSup S := (giMapComap hf).l_iSup_u _ @[to_additive] theorem comap_le_comap_iff_of_surjective {S T : Subsemigroup N} : S.comap f ≤ T.comap f ↔ S ≤ T := (giMapComap hf).u_le_u_iff @[to_additive] theorem comap_strictMono_of_surjective : StrictMono (comap f) := (giMapComap hf).strictMono_u end GaloisInsertion end Subsemigroup namespace Subsemigroup variable [Mul M] [Mul N] [Mul P] (S : Subsemigroup M) /-- The top subsemigroup is isomorphic to the semigroup. -/ @[to_additive (attr := simps) "The top additive subsemigroup is isomorphic to the additive semigroup."] def topEquiv : (⊤ : Subsemigroup M) ≃* M where toFun x := x invFun x := ⟨x, mem_top x⟩ left_inv x := x.eta _ right_inv _ := rfl map_mul' _ _ := rfl @[to_additive (attr := simp)] theorem topEquiv_toMulHom : ((topEquiv : _ ≃* M) : _ →ₙ* M) = MulMemClass.subtype (⊤ : Subsemigroup M) := rfl /-- A subsemigroup is isomorphic to its image under an injective function -/ @[to_additive "An additive subsemigroup is isomorphic to its image under an injective function"] noncomputable def equivMapOfInjective (f : M →ₙ* N) (hf : Function.Injective f) : S ≃* S.map f := { Equiv.Set.image f S hf with map_mul' := fun _ _ => Subtype.ext (map_mul f _ _) } @[to_additive (attr := simp)] theorem coe_equivMapOfInjective_apply (f : M →ₙ* N) (hf : Function.Injective f) (x : S) : (equivMapOfInjective S f hf x : N) = f x := rfl @[to_additive (attr := simp)] theorem closure_closure_coe_preimage {s : Set M} : closure ((Subtype.val : closure s → M) ⁻¹' s) = ⊤ := eq_top_iff.2 fun x _ ↦ Subtype.recOn x fun _ hx' ↦ closure_induction (fun _ h ↦ subset_closure h) (fun _ _ _ _ ↦ mul_mem) hx' /-- Given `Subsemigroup`s `s`, `t` of semigroups `M`, `N` respectively, `s × t` as a subsemigroup of `M × N`. -/ @[to_additive prod "Given `AddSubsemigroup`s `s`, `t` of `AddSemigroup`s `A`, `B` respectively, `s × t` as an `AddSubsemigroup` of `A × B`."] def prod (s : Subsemigroup M) (t : Subsemigroup N) : Subsemigroup (M × N) where carrier := s ×ˢ t mul_mem' hp hq := ⟨s.mul_mem hp.1 hq.1, t.mul_mem hp.2 hq.2⟩ @[to_additive coe_prod] theorem coe_prod (s : Subsemigroup M) (t : Subsemigroup N) : (s.prod t : Set (M × N)) = (s : Set M) ×ˢ (t : Set N) := rfl @[to_additive mem_prod] theorem mem_prod {s : Subsemigroup M} {t : Subsemigroup N} {p : M × N} : p ∈ s.prod t ↔ p.1 ∈ s ∧ p.2 ∈ t := Iff.rfl @[to_additive prod_mono] theorem prod_mono {s₁ s₂ : Subsemigroup M} {t₁ t₂ : Subsemigroup N} (hs : s₁ ≤ s₂) (ht : t₁ ≤ t₂) : s₁.prod t₁ ≤ s₂.prod t₂ := Set.prod_mono hs ht @[to_additive prod_top] theorem prod_top (s : Subsemigroup M) : s.prod (⊤ : Subsemigroup N) = s.comap (MulHom.fst M N) := ext fun x => by simp [mem_prod, MulHom.coe_fst] @[to_additive top_prod] theorem top_prod (s : Subsemigroup N) : (⊤ : Subsemigroup M).prod s = s.comap (MulHom.snd M N) := ext fun x => by simp [mem_prod, MulHom.coe_snd] @[to_additive (attr := simp) top_prod_top] theorem top_prod_top : (⊤ : Subsemigroup M).prod (⊤ : Subsemigroup N) = ⊤ := (top_prod _).trans <\| comap_top _ @[to_additive bot_prod_bot] theorem bot_prod_bot : (⊥ : Subsemigroup M).prod (⊥ : Subsemigroup N) = ⊥ := SetLike.coe_injective <\| by simp [coe_prod] /-- The product of subsemigroups is isomorphic to their product as semigroups. -/ @[to_additive prodEquiv "The product of additive subsemigroups is isomorphic to their product as additive semigroups"] def prodEquiv (s : Subsemigroup M) (t : Subsemigroup N) : s.prod t ≃* s × t := { (Equiv.Set.prod (s : Set M) (t : Set N)) with map_mul' := fun _ _ => rfl } open MulHom @[to_additive] theorem mem_map_equiv {f : M ≃* N} {K : Subsemigroup M} {x : N} : x ∈ K.map (f : M →ₙ* N) ↔ f.symm x ∈ K := @Set.mem_image_equiv _ _ (K : Set M) f.toEquiv x @[to_additive] theorem map_equiv_eq_comap_symm (f : M ≃* N) (K : Subsemigroup M) : K.map (f : M →ₙ* N) = K.comap (f.symm : N →ₙ* M) := SetLike.coe_injective (f.toEquiv.image_eq_preimage K) @[to_additive] theorem comap_equiv_eq_map_symm (f : N ≃* M) (K : Subsemigroup M) : K.comap (f : N →ₙ* M) = K.map (f.symm : M →ₙ* N) := (map_equiv_eq_comap_symm f.symm K).symm @[to_additive (attr := simp)] theorem map_equiv_top (f : M ≃* N) : (⊤ : Subsemigroup M).map (f : M →ₙ* N) = ⊤ := SetLike.coe_injective <\| Set.image_univ.trans f.surjective.range_eq @[to_additive le_prod_iff] theorem le_prod_iff {s : Subsemigroup M} {t : Subsemigroup N} {u : Subsemigroup (M × N)} : u ≤ s.prod t ↔ u.map (fst M N) ≤ s ∧ u.map (snd M N) ≤ t := by constructor · intro h constructor · rintro x ⟨⟨y1, y2⟩, ⟨hy1, rfl⟩⟩ exact (h hy1).1 · rintro x ⟨⟨y1, y2⟩, ⟨hy1, rfl⟩⟩ exact (h hy1).2 · rintro ⟨hH, hK⟩ ⟨x1, x2⟩ h exact ⟨hH ⟨_, h, rfl⟩, hK ⟨_, h, rfl⟩⟩ end Subsemigroup namespace MulHom open Subsemigroup variable [Mul M] [Mul N] [Mul P] (S : Subsemigroup M) /-- The range of a semigroup homomorphism is a subsemigroup. See Note [range copy pattern]. -/ @[to_additive "The range of an `AddHom` is an `AddSubsemigroup`."] def srange (f : M →ₙ* N) : Subsemigroup N := ((⊤ : Subsemigroup M).map f).copy (Set.range f) Set.image_univ.symm @[to_additive (attr := simp)] theorem coe_srange (f : M →ₙ* N) : (f.srange : Set N) = Set.range f := rfl @[to_additive (attr := simp)] theorem mem_srange {f : M →ₙ* N} {y : N} : y ∈ f.srange ↔ ∃ x, f x = y := Iff.rfl @[to_additive] private theorem srange_mk_aux_mul {f : M → N} (hf : ∀ (x y : M), f (x * y) = f x * f y) {x y : N} (hx : x ∈ Set.range f) (hy : y ∈ Set.range f) : x * y ∈ Set.range f := (srange ⟨f, hf⟩).mul_mem hx hy @[to_additive (attr := simp)] theorem srange_mk (f : M → N) (hf) : srange ⟨f, hf⟩ = ⟨Set.range f, srange_mk_aux_mul hf⟩ := rfl @[to_additive] theorem srange_eq_map (f : M →ₙ* N) : f.srange = (⊤ : Subsemigroup M).map f := copy_eq _ @[to_additive] theorem map_srange (g : N →ₙ* P) (f : M →ₙ* N) : f.srange.map g = (g.comp f).srange := by simpa only [srange_eq_map] using (⊤ : Subsemigroup M).map_map g f @[to_additive] theorem srange_eq_top_iff_surjective {N} [Mul N] {f : M →ₙ* N} : f.srange = (⊤ : Subsemigroup N) ↔ Function.Surjective f := SetLike.ext'_iff.trans <\| Iff.trans (by rw [coe_srange, coe_top]) Set.range_eq_univ @[deprecated (since := "2024-11-11")] alias srange_top_iff_surjective := srange_eq_top_iff_surjective /-- The range of a surjective semigroup hom is the whole of the codomain. -/ @[to_additive (attr := simp) "The range of a surjective `AddSemigroup` hom is the whole of the codomain."] theorem srange_eq_top_of_surjective {N} [Mul N] (f : M →ₙ* N) (hf : Function.Surjective f) : f.srange = (⊤ : Subsemigroup N) := srange_eq_top_iff_surjective.2 hf @[deprecated (since := "2024-11-11")] alias srange_top_of_surjective := srange_eq_top_of_surjective @[to_additive] theorem mclosure_preimage_le (f : M →ₙ* N) (s : Set N) : closure (f ⁻¹' s) ≤ (closure s).comap f := closure_le.2 fun _ hx => SetLike.mem_coe.2 <\| mem_comap.2 <\| subset_closure hx /-- The image under a semigroup hom of the subsemigroup generated by a set equals the subsemigroup generated by the image of the set. -/ @[to_additive "The image under an `AddSemigroup` hom of the `AddSubsemigroup` generated by a set equals the `AddSubsemigroup` generated by the image of the set."] theorem map_mclosure (f : M →ₙ* N) (s : Set M) : (closure s).map f = closure (f '' s) := Set.image_preimage.l_comm_of_u_comm (gc_map_comap f) (Subsemigroup.gi N).gc (Subsemigroup.gi M).gc fun _ ↦ rfl /-- Restriction of a semigroup hom to a subsemigroup of the domain. -/ @[to_additive "Restriction of an AddSemigroup hom to an `AddSubsemigroup` of the domain."] def restrict {N : Type} [Mul N] [SetLike σ M] [MulMemClass σ M] (f : M →ₙ N) (S : σ) : S →ₙ* N := f.comp (MulMemClass.subtype S) @[to_additive (attr := simp)] theorem restrict_apply {N : Type} [Mul N] [SetLike σ M] [MulMemClass σ M] (f : M →ₙ N) {S : σ} (x : S) : f.restrict S x = f x := rfl /-- Restriction of a semigroup hom to a subsemigroup of the codomain. -/ @[to_additive (attr := simps) "Restriction of an `AddSemigroup` hom to an `AddSubsemigroup` of the codomain."] def codRestrict [SetLike σ N] [MulMemClass σ N] (f : M →ₙ* N) (S : σ) (h : ∀ x, f x ∈ S) : M →ₙ* S where toFun n := ⟨f n, h n⟩ map_mul' x y := Subtype.eq (map_mul f x y) /-- Restriction of a semigroup hom to its range interpreted as a subsemigroup. -/ @[to_additive "Restriction of an `AddSemigroup` hom to its range interpreted as a subsemigroup."] def srangeRestrict {N} [Mul N] (f : M →ₙ* N) : M →ₙ* f.srange := (f.codRestrict f.srange) fun x => ⟨x, rfl⟩ @[to_additive (attr := simp)] theorem coe_srangeRestrict {N} [Mul N] (f : M →ₙ* N) (x : M) : (f.srangeRestrict x : N) = f x := rfl @[to_additive] theorem srangeRestrict_surjective (f : M →ₙ* N) : Function.Surjective f.srangeRestrict := fun ⟨_, ⟨x, rfl⟩⟩ => ⟨x, rfl⟩ @[to_additive prod_map_comap_prod'] theorem prod_map_comap_prod' {M' : Type} {N' : Type} [Mul M'] [Mul N'] (f : M →ₙ* N) (g : M' →ₙ* N') (S : Subsemigroup N) (S' : Subsemigroup N') : (S.prod S').comap (prodMap f g) = (S.comap f).prod (S'.comap g) := SetLike.coe_injective <\| Set.preimage_prod_map_prod f g _ _ /-- The `MulHom` from the preimage of a subsemigroup to itself. -/ @[to_additive (attr := simps) "The `AddHom` from the preimage of an additive subsemigroup to itself."] def subsemigroupComap (f : M →ₙ* N) (N' : Subsemigroup N) : N'.comap f →ₙ* N' where toFun x := ⟨f x, x.prop⟩ map_mul' x y := Subtype.eq <\| map_mul (M := M) (N := N) f x y /-- The `MulHom` from a subsemigroup to its image. See `MulEquiv.subsemigroupMap` for a variant for `MulEquiv`s. -/ @[to_additive (attr := simps) "the `AddHom` from an additive subsemigroup to its image. See `AddEquiv.addSubsemigroupMap` for a variant for `AddEquiv`s."] def subsemigroupMap (f : M →ₙ* N) (M' : Subsemigroup M) : M' →ₙ* M'.map f where toFun x := ⟨f x, ⟨x, x.prop, rfl⟩⟩ map_mul' x y := Subtype.eq <\| map_mul (M := M) (N := N) f x y @[to_additive] theorem subsemigroupMap_surjective (f : M →ₙ* N) (M' : Subsemigroup M) : Function.Surjective (f.subsemigroupMap M') := by rintro ⟨_, x, hx, rfl⟩ exact ⟨⟨x, hx⟩, rfl⟩ end MulHom namespace Subsemigroup open MulHom variable [Mul M] [Mul N] [Mul P] (S : Subsemigroup M) @[to_additive (attr := simp)] theorem srange_fst [Nonempty N] : (fst M N).srange = ⊤ := (fst M N).srange_eq_top_of_surjective <\| Prod.fst_surjective @[to_additive (attr := simp)] theorem srange_snd [Nonempty M] : (snd M N).srange = ⊤ := (snd M N).srange_eq_top_of_surjective <\| Prod.snd_surjective @[to_additive prod_eq_top_iff] theorem prod_eq_top_iff [Nonempty M] [Nonempty N] {s : Subsemigroup M} {t : Subsemigroup N} : s.prod t = ⊤ ↔ s = ⊤ ∧ t = ⊤ := by simp only [eq_top_iff, le_prod_iff, ← (gc_map_comap _).le_iff_le, ← srange_eq_map, srange_fst, srange_snd] /-- The semigroup hom associated to an inclusion of subsemigroups. -/ @[to_additive "The `AddSemigroup` hom associated to an inclusion of subsemigroups."] def inclusion {S T : Subsemigroup M} (h : S ≤ T) : S →ₙ* T := (MulMemClass.subtype S).codRestrict _ fun x => h x.2 @[to_additive (attr := simp)] theorem range_subtype (s : Subsemigroup M) : (MulMemClass.subtype s).srange = s := SetLike.coe_injective <\| (coe_srange _).trans <\| Subtype.range_coe @[to_additive] theorem eq_top_iff' : S = ⊤ ↔ ∀ x : M, x ∈ S := eq_top_iff.trans ⟨fun h m => h <\| mem_top m, fun h m _ => h m⟩ end Subsemigroup namespace MulEquiv variable [Mul M] [Mul N] {S T : Subsemigroup M} /-- Makes the identity isomorphism from a proof that two subsemigroups of a multiplicative semigroup are equal. -/ @[to_additive "Makes the identity additive isomorphism from a proof two subsemigroups of an additive semigroup are equal."] def subsemigroupCongr (h : S = T) : S ≃* T := { Equiv.setCongr <\| congr_arg _ h with map_mul' := fun _ _ => rfl } -- this name is primed so that the version to `f.range` instead of `f.srange` can be unprimed. /-- A semigroup homomorphism `f : M →ₙ* N` with a left-inverse `g : N → M` defines a multiplicative equivalence between `M` and `f.srange`. This is a bidirectional version of `MulHom.srangeRestrict`. -/ @[to_additive (attr := simps +simpRhs) "An additive semigroup homomorphism `f : M →+ N` with a left-inverse `g : N → M` defines an additive equivalence between `M` and `f.srange`. This is a bidirectional version of `AddHom.srangeRestrict`. "] def ofLeftInverse (f : M →ₙ* N) {g : N → M} (h : Function.LeftInverse g f) : M ≃* f.srange := { f.srangeRestrict with toFun := f.srangeRestrict invFun := g ∘ MulMemClass.subtype f.srange left_inv := h right_inv := fun x => Subtype.ext <\| let ⟨x', hx'⟩ := MulHom.mem_srange.mp x.prop show f (g x) = x by rw [← hx', h x'] } /-- A `MulEquiv` `φ` between two semigroups `M` and `N` induces a `MulEquiv` between a subsemigroup `S ≤ M` and the subsemigroup `φ(S) ≤ N`. See `MulHom.subsemigroupMap` for a variant for `MulHom`s. -/ @[to_additive (attr := simps) "An `AddEquiv` `φ` between two additive semigroups `M` and `N` induces an `AddEquiv` between a subsemigroup `S ≤ M` and the subsemigroup `φ(S) ≤ N`. See `AddHom.addSubsemigroupMap` for a variant for `AddHom`s."] def subsemigroupMap (e : M ≃* N) (S : Subsemigroup M) : S ≃* S.map (e : M →ₙ* N) := { -- we restate this for `simps` to avoid `⇑e.symm.toEquiv x` (e : M →ₙ* N).subsemigroupMap S, (e : M ≃ N).image S with toFun := fun x => ⟨e x, _⟩ invFun := fun x => ⟨e.symm x, _⟩ } end MulEquiv namespace Subsemigroup variable [Mul M] [Mul N] @[to_additive] theorem map_comap_eq (f : M →ₙ* N) (S : Subsemigroup N) : (S.comap f).map f = S ⊓ f.srange := SetLike.coe_injective Set.image_preimage_eq_inter_range @[to_additive] theorem map_comap_eq_self {f : M →ₙ* N} {S : Subsemigroup N} (h : S ≤ f.srange) : (S.comap f).map f = S := by simpa only [inf_of_le_left h] using map_comap_eq f S end Subsemigroup		Mathlib/Algebra/Group/Subsemigroup/Operations.lean	776	777
/- Copyright (c) 2020 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson -/ import Mathlib.Data.Finset.Fold import Mathlib.Algebra.GCDMonoid.Multiset /-! # GCD and LCM operations on finsets ## Main definitions - `Finset.gcd` - the greatest common denominator of a `Finset` of elements of a `GCDMonoid` - `Finset.lcm` - the least common multiple of a `Finset` of elements of a `GCDMonoid` ## Implementation notes Many of the proofs use the lemmas `gcd_def` and `lcm_def`, which relate `Finset.gcd` and `Finset.lcm` to `Multiset.gcd` and `Multiset.lcm`. TODO: simplify with a tactic and `Data.Finset.Lattice` ## Tags finset, gcd -/ variable {ι α β γ : Type} namespace Finset open Multiset variable [CancelCommMonoidWithZero α] [NormalizedGCDMonoid α] /-! ### lcm -/ section lcm /-- Least common multiple of a finite set -/ def lcm (s : Finset β) (f : β → α) : α := s.fold GCDMonoid.lcm 1 f variable {s s₁ s₂ : Finset β} {f : β → α} theorem lcm_def : s.lcm f = (s.1.map f).lcm := rfl @[simp] theorem lcm_empty : (∅ : Finset β).lcm f = 1 := fold_empty @[simp] theorem lcm_dvd_iff {a : α} : s.lcm f ∣ a ↔ ∀ b ∈ s, f b ∣ a := by apply Iff.trans Multiset.lcm_dvd simp only [Multiset.mem_map, and_imp, exists_imp] exact ⟨fun k b hb ↦ k _ _ hb rfl, fun k a' b hb h ↦ h ▸ k _ hb⟩ theorem lcm_dvd {a : α} : (∀ b ∈ s, f b ∣ a) → s.lcm f ∣ a := lcm_dvd_iff.2 theorem dvd_lcm {b : β} (hb : b ∈ s) : f b ∣ s.lcm f := lcm_dvd_iff.1 dvd_rfl _ hb @[simp] theorem lcm_insert [DecidableEq β] {b : β} : (insert b s : Finset β).lcm f = GCDMonoid.lcm (f b) (s.lcm f) := by by_cases h : b ∈ s · rw [insert_eq_of_mem h, (lcm_eq_right_iff (f b) (s.lcm f) (Multiset.normalize_lcm (s.1.map f))).2 (dvd_lcm h)] apply fold_insert h @[simp] theorem lcm_singleton {b : β} : ({b} : Finset β).lcm f = normalize (f b) := Multiset.lcm_singleton @[local simp] -- This will later be provable by other `simp` lemmas. theorem normalize_lcm : normalize (s.lcm f) = s.lcm f := by simp [lcm_def] theorem lcm_union [DecidableEq β] : (s₁ ∪ s₂).lcm f = GCDMonoid.lcm (s₁.lcm f) (s₂.lcm f) := Finset.induction_on s₁ (by rw [empty_union, lcm_empty, lcm_one_left, normalize_lcm]) fun a s _ ih ↦ by rw [insert_union, lcm_insert, lcm_insert, ih, lcm_assoc] theorem lcm_congr {f g : β → α} (hs : s₁ = s₂) (hfg : ∀ a ∈ s₂, f a = g a) : s₁.lcm f = s₂.lcm g := by subst hs exact Finset.fold_congr hfg theorem lcm_mono_fun {g : β → α} (h : ∀ b ∈ s, f b ∣ g b) : s.lcm f ∣ s.lcm g := lcm_dvd fun b hb ↦ (h b hb).trans (dvd_lcm hb) theorem lcm_mono (h : s₁ ⊆ s₂) : s₁.lcm f ∣ s₂.lcm f := lcm_dvd fun _ hb ↦ dvd_lcm (h hb) theorem lcm_image [DecidableEq β] {g : γ → β} (s : Finset γ) : (s.image g).lcm f = s.lcm (f ∘ g) := by classical induction s using Finset.induction <;> simp [] theorem lcm_eq_lcm_image [DecidableEq α] : s.lcm f = (s.image f).lcm id := Eq.symm <\| lcm_image _ theorem lcm_eq_zero_iff [Nontrivial α] : s.lcm f = 0 ↔ 0 ∈ f '' s := by simp only [Multiset.mem_map, lcm_def, Multiset.lcm_eq_zero_iff, Set.mem_image, mem_coe, ← Finset.mem_def] end lcm /-! ### gcd -/ section gcd /-- Greatest common divisor of a finite set -/ def gcd (s : Finset β) (f : β → α) : α := s.fold GCDMonoid.gcd 0 f variable {s s₁ s₂ : Finset β} {f : β → α} theorem gcd_def : s.gcd f = (s.1.map f).gcd := rfl @[simp] theorem gcd_empty : (∅ : Finset β).gcd f = 0 := fold_empty theorem dvd_gcd_iff {a : α} : a ∣ s.gcd f ↔ ∀ b ∈ s, a ∣ f b := by apply Iff.trans Multiset.dvd_gcd simp only [Multiset.mem_map, and_imp, exists_imp] exact ⟨fun k b hb ↦ k _ _ hb rfl, fun k a' b hb h ↦ h ▸ k _ hb⟩ theorem gcd_dvd {b : β} (hb : b ∈ s) : s.gcd f ∣ f b := dvd_gcd_iff.1 dvd_rfl _ hb theorem dvd_gcd {a : α} : (∀ b ∈ s, a ∣ f b) → a ∣ s.gcd f := dvd_gcd_iff.2 @[simp] theorem gcd_insert [DecidableEq β] {b : β} : (insert b s : Finset β).gcd f = GCDMonoid.gcd (f b) (s.gcd f) := by by_cases h : b ∈ s · rw [insert_eq_of_mem h, (gcd_eq_right_iff (f b) (s.gcd f) (Multiset.normalize_gcd (s.1.map f))).2 (gcd_dvd h)] apply fold_insert h @[simp] theorem gcd_singleton {b : β} : ({b} : Finset β).gcd f = normalize (f b) := Multiset.gcd_singleton @[local simp] -- This will later be provable by other `simp` lemmas. theorem normalize_gcd : normalize (s.gcd f) = s.gcd f := by simp [gcd_def] theorem gcd_union [DecidableEq β] : (s₁ ∪ s₂).gcd f = GCDMonoid.gcd (s₁.gcd f) (s₂.gcd f) := Finset.induction_on s₁ (by rw [empty_union, gcd_empty, gcd_zero_left, normalize_gcd]) fun a s _ ih ↦ by rw [insert_union, gcd_insert, gcd_insert, ih, gcd_assoc] theorem gcd_congr {f g : β → α} (hs : s₁ = s₂) (hfg : ∀ a ∈ s₂, f a = g a) : s₁.gcd f = s₂.gcd g := by subst hs exact Finset.fold_congr hfg theorem gcd_mono_fun {g : β → α} (h : ∀ b ∈ s, f b ∣ g b) : s.gcd f ∣ s.gcd g := dvd_gcd fun b hb ↦ (gcd_dvd hb).trans (h b hb) theorem gcd_mono (h : s₁ ⊆ s₂) : s₂.gcd f ∣ s₁.gcd f := dvd_gcd fun _ hb ↦ gcd_dvd (h hb) theorem gcd_image [DecidableEq β] {g : γ → β} (s : Finset γ) : (s.image g).gcd f = s.gcd (f ∘ g) := by classical induction s using Finset.induction <;> simp [] theorem gcd_eq_gcd_image [DecidableEq α] : s.gcd f = (s.image f).gcd id := Eq.symm <\| gcd_image _ theorem gcd_eq_zero_iff : s.gcd f = 0 ↔ ∀ x : β, x ∈ s → f x = 0 := by rw [gcd_def, Multiset.gcd_eq_zero_iff] constructor <;> intro h · intro b bs apply h (f b) simp only [Multiset.mem_map, mem_def.1 bs] use b simp only [mem_def.1 bs, eq_self_iff_true, and_self] · intro a as rw [Multiset.mem_map] at as rcases as with ⟨b, ⟨bs, rfl⟩⟩ apply h b (mem_def.1 bs) theorem gcd_eq_gcd_filter_ne_zero [DecidablePred fun x : β ↦ f x = 0] : s.gcd f = {x ∈ s \| f x ≠ 0}.gcd f := by classical trans ({x ∈ s \| f x = 0} ∪ {x ∈ s \| f x ≠ 0}).gcd f · rw [filter_union_filter_neg_eq] rw [gcd_union] refine Eq.trans (?_ : _ = GCDMonoid.gcd (0 : α) ?_) (?_ : GCDMonoid.gcd (0 : α) _ = _) · exact gcd {x ∈ s \| f x ≠ 0} f · refine congr (congr rfl <\| s.induction_on ?_ ?_) (by simp) · simp · intro a s _ h rw [filter_insert] split_ifs with h1 <;> simp [h, h1] simp only [gcd_zero_left, normalize_gcd] nonrec theorem gcd_mul_left {a : α} : (s.gcd fun x ↦ a f x) = normalize a * s.gcd f := by classical refine s.induction_on ?_ ?_ · simp · intro b t _ h rw [gcd_insert, gcd_insert, h, ← gcd_mul_left] apply ((normalize_associated a).mul_right _).gcd_eq_right	nonrec theorem gcd_mul_right {a : α} : (s.gcd fun x ↦ f x * a) = s.gcd f * normalize a := by classical refine s.induction_on ?_ ?_ · simp · intro b t _ h rw [gcd_insert, gcd_insert, h, ← gcd_mul_right] apply ((normalize_associated a).mul_left _).gcd_eq_right theorem extract_gcd' (f g : β → α) (hs : ∃ x, x ∈ s ∧ f x ≠ 0) (hg : ∀ b ∈ s, f b = s.gcd f * g b) : s.gcd g = 1 := ((@mul_right_eq_self₀ _ _ (s.gcd f) _).1 <\| by conv_lhs => rw [← normalize_gcd, ← gcd_mul_left, ← gcd_congr rfl hg]).resolve_right <\| by	Mathlib/Algebra/GCDMonoid/Finset.lean	212	223
/- Copyright (c) 2021 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.Algebra.Order.Group.Indicator import Mathlib.Analysis.Normed.Affine.AddTorsor import Mathlib.Analysis.NormedSpace.FunctionSeries import Mathlib.Analysis.SpecificLimits.Basic import Mathlib.LinearAlgebra.AffineSpace.Ordered import Mathlib.Topology.ContinuousMap.Algebra import Mathlib.Topology.GDelta.Basic /-! # Urysohn's lemma In this file we prove Urysohn's lemma `exists_continuous_zero_one_of_isClosed`: for any two disjoint closed sets `s` and `t` in a normal topological space `X` there exists a continuous function `f : X → ℝ` such that * `f` equals zero on `s`; * `f` equals one on `t`; * `0 ≤ f x ≤ 1` for all `x`. We also give versions in a regular locally compact space where one assumes that `s` is compact and `t` is closed, in `exists_continuous_zero_one_of_isCompact` and `exists_continuous_one_zero_of_isCompact` (the latter providing additionally a function with compact support). We write a generic proof so that it applies both to normal spaces and to regular locally compact spaces. ## Implementation notes Most paper sources prove Urysohn's lemma using a family of open sets indexed by dyadic rational numbers on `[0, 1]`. There are many technical difficulties with formalizing this proof (e.g., one needs to formalize the "dyadic induction", then prove that the resulting family of open sets is monotone). So, we formalize a slightly different proof. Let `Urysohns.CU` be the type of pairs `(C, U)` of a closed set `C` and an open set `U` such that `C ⊆ U`. Since `X` is a normal topological space, for each `c : CU` there exists an open set `u` such that `c.C ⊆ u ∧ closure u ⊆ c.U`. We define `c.left` and `c.right` to be `(c.C, u)` and `(closure u, c.U)`, respectively. Then we define a family of functions `Urysohns.CU.approx (c : Urysohns.CU) (n : ℕ) : X → ℝ` by recursion on `n`: * `c.approx 0` is the indicator of `c.Uᶜ`; * `c.approx (n + 1) x = (c.left.approx n x + c.right.approx n x) / 2`. For each `x` this is a monotone family of functions that are equal to zero on `c.C` and are equal to one outside of `c.U`. We also have `c.approx n x ∈ [0, 1]` for all `c`, `n`, and `x`. Let `Urysohns.CU.lim c` be the supremum (or equivalently, the limit) of `c.approx n`. Then properties of `Urysohns.CU.approx` immediately imply that * `c.lim x ∈ [0, 1]` for all `x`; * `c.lim` equals zero on `c.C` and equals one outside of `c.U`; * `c.lim x = (c.left.lim x + c.right.lim x) / 2`. In order to prove that `c.lim` is continuous at `x`, we prove by induction on `n : ℕ` that for `y` in a small neighborhood of `x` we have `\|c.lim y - c.lim x\| ≤ (3 / 4) ^ n`. Induction base follows from `c.lim x ∈ [0, 1]`, `c.lim y ∈ [0, 1]`. For the induction step, consider two cases: * `x ∈ c.left.U`; then for `y` in a small neighborhood of `x` we have `y ∈ c.left.U ⊆ c.right.C` (hence `c.right.lim x = c.right.lim y = 0`) and `\|c.left.lim y - c.left.lim x\| ≤ (3 / 4) ^ n`. Then `\|c.lim y - c.lim x\| = \|c.left.lim y - c.left.lim x\| / 2 ≤ (3 / 4) ^ n / 2 < (3 / 4) ^ (n + 1)`. * otherwise, `x ∉ c.left.right.C`; then for `y` in a small neighborhood of `x` we have `y ∉ c.left.right.C ⊇ c.left.left.U` (hence `c.left.left.lim x = c.left.left.lim y = 1`), `\|c.left.right.lim y - c.left.right.lim x\| ≤ (3 / 4) ^ n`, and `\|c.right.lim y - c.right.lim x\| ≤ (3 / 4) ^ n`. Combining these inequalities, the triangle inequality, and the recurrence formula for `c.lim`, we get `\|c.lim x - c.lim y\| ≤ (3 / 4) ^ (n + 1)`. The actual formalization uses `midpoint ℝ x y` instead of `(x + y) / 2` because we have more API lemmas about `midpoint`. ## Tags Urysohn's lemma, normal topological space, locally compact topological space -/ variable {X : Type} [TopologicalSpace X] open Set Filter TopologicalSpace Topology Filter open scoped Pointwise namespace Urysohns /-- An auxiliary type for the proof of Urysohn's lemma: a pair of a closed set `C` and its open neighborhood `U`, together with the assumption that `C` and `U` satisfy the property `P C U`. The latter assumption will make it possible to prove simultaneously both versions of Urysohn's lemma, in normal spaces (with `P` always true) and in locally compact spaces (with `P C U = IsCompact C`). We put also in the structure the assumption that, for any such pair, one may find an intermediate pair in between satisfying `P`, to avoid carrying it around in the argument. -/ structure CU {X : Type} [TopologicalSpace X] (P : Set X → Set X → Prop) where /-- The inner set in the inductive construction towards Urysohn's lemma -/ protected C : Set X /-- The outer set in the inductive construction towards Urysohn's lemma -/ protected U : Set X /-- The proof that `C` and `U` satisfy the property `P C U` -/ protected P_C_U : P C U protected closed_C : IsClosed C protected open_U : IsOpen U protected subset : C ⊆ U /-- The proof that we can divide `CU` pairs in half -/ protected hP : ∀ {c u : Set X}, IsClosed c → P c u → IsOpen u → c ⊆ u → ∃ (v : Set X), IsOpen v ∧ c ⊆ v ∧ closure v ⊆ u ∧ P c v ∧ P (closure v) u namespace CU variable {P : Set X → Set X → Prop} /-- By assumption, for each `c : CU P` there exists an open set `u` such that `c.C ⊆ u` and `closure u ⊆ c.U`. `c.left` is the pair `(c.C, u)`. -/ @[simps C] def left (c : CU P) : CU P where C := c.C U := (c.hP c.closed_C c.P_C_U c.open_U c.subset).choose closed_C := c.closed_C P_C_U := (c.hP c.closed_C c.P_C_U c.open_U c.subset).choose_spec.2.2.2.1 open_U := (c.hP c.closed_C c.P_C_U c.open_U c.subset).choose_spec.1 subset := (c.hP c.closed_C c.P_C_U c.open_U c.subset).choose_spec.2.1 hP := c.hP /-- By assumption, for each `c : CU P` there exists an open set `u` such that `c.C ⊆ u` and `closure u ⊆ c.U`. `c.right` is the pair `(closure u, c.U)`. -/ @[simps U] def right (c : CU P) : CU P where C := closure (c.hP c.closed_C c.P_C_U c.open_U c.subset).choose U := c.U closed_C := isClosed_closure P_C_U := (c.hP c.closed_C c.P_C_U c.open_U c.subset).choose_spec.2.2.2.2 open_U := c.open_U subset := (c.hP c.closed_C c.P_C_U c.open_U c.subset).choose_spec.2.2.1 hP := c.hP theorem left_U_subset_right_C (c : CU P) : c.left.U ⊆ c.right.C := subset_closure theorem left_U_subset (c : CU P) : c.left.U ⊆ c.U := Subset.trans c.left_U_subset_right_C c.right.subset theorem subset_right_C (c : CU P) : c.C ⊆ c.right.C := Subset.trans c.left.subset c.left_U_subset_right_C /-- `n`-th approximation to a continuous function `f : X → ℝ` such that `f = 0` on `c.C` and `f = 1` outside of `c.U`. -/ noncomputable def approx : ℕ → CU P → X → ℝ \| 0, c, x => indicator c.Uᶜ 1 x \| n + 1, c, x => midpoint ℝ (approx n c.left x) (approx n c.right x) theorem approx_of_mem_C (c : CU P) (n : ℕ) {x : X} (hx : x ∈ c.C) : c.approx n x = 0 := by induction n generalizing c with \| zero => exact indicator_of_not_mem (fun (hU : x ∈ c.Uᶜ) => hU <\| c.subset hx) _ \| succ n ihn => simp only [approx] rw [ihn, ihn, midpoint_self] exacts [c.subset_right_C hx, hx] theorem approx_of_nmem_U (c : CU P) (n : ℕ) {x : X} (hx : x ∉ c.U) : c.approx n x = 1 := by induction n generalizing c with \| zero => rw [← mem_compl_iff] at hx exact indicator_of_mem hx _ \| succ n ihn => simp only [approx] rw [ihn, ihn, midpoint_self] exacts [hx, fun hU => hx <\| c.left_U_subset hU] theorem approx_nonneg (c : CU P) (n : ℕ) (x : X) : 0 ≤ c.approx n x := by induction n generalizing c with \| zero => exact indicator_nonneg (fun _ _ => zero_le_one) _ \| succ n ihn => simp only [approx, midpoint_eq_smul_add, invOf_eq_inv] refine mul_nonneg (inv_nonneg.2 zero_le_two) (add_nonneg ?_ ?_) <;> apply ihn theorem approx_le_one (c : CU P) (n : ℕ) (x : X) : c.approx n x ≤ 1 := by induction n generalizing c with \| zero => exact indicator_apply_le' (fun _ => le_rfl) fun _ => zero_le_one \| succ n ihn => simp only [approx, midpoint_eq_smul_add, invOf_eq_inv, smul_eq_mul, ← div_eq_inv_mul] have := add_le_add (ihn (left c)) (ihn (right c)) norm_num at this exact Iff.mpr (div_le_one zero_lt_two) this theorem bddAbove_range_approx (c : CU P) (x : X) : BddAbove (range fun n => c.approx n x) := ⟨1, fun _ ⟨n, hn⟩ => hn ▸ c.approx_le_one n x⟩ theorem approx_le_approx_of_U_sub_C {c₁ c₂ : CU P} (h : c₁.U ⊆ c₂.C) (n₁ n₂ : ℕ) (x : X) : c₂.approx n₂ x ≤ c₁.approx n₁ x := by by_cases hx : x ∈ c₁.U · calc approx n₂ c₂ x = 0 := approx_of_mem_C _ _ (h hx) _ ≤ approx n₁ c₁ x := approx_nonneg _ _ _ · calc approx n₂ c₂ x ≤ 1 := approx_le_one _ _ _ _ = approx n₁ c₁ x := (approx_of_nmem_U _ _ hx).symm theorem approx_mem_Icc_right_left (c : CU P) (n : ℕ) (x : X) : c.approx n x ∈ Icc (c.right.approx n x) (c.left.approx n x) := by induction n generalizing c with \| zero => exact ⟨le_rfl, indicator_le_indicator_of_subset (compl_subset_compl.2 c.left_U_subset) (fun _ => zero_le_one) _⟩ \| succ n ihn => simp only [approx, mem_Icc] refine ⟨midpoint_le_midpoint ?_ (ihn _).1, midpoint_le_midpoint (ihn _).2 ?_⟩ <;> apply approx_le_approx_of_U_sub_C exacts [subset_closure, subset_closure] theorem approx_le_succ (c : CU P) (n : ℕ) (x : X) : c.approx n x ≤ c.approx (n + 1) x := by induction n generalizing c with \| zero => simp only [approx, right_U, right_le_midpoint]	exact (approx_mem_Icc_right_left c 0 x).2 \| succ n ihn => rw [approx, approx] exact midpoint_le_midpoint (ihn _) (ihn _) theorem approx_mono (c : CU P) (x : X) : Monotone fun n => c.approx n x :=	Mathlib/Topology/UrysohnsLemma.lean	220	225
/- Copyright (c) 2018 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau, Yury Kudryashov -/ import Mathlib.Algebra.Algebra.Defs import Mathlib.Algebra.Module.Equiv.Basic import Mathlib.Algebra.Module.Submodule.Ker import Mathlib.Algebra.Module.Submodule.RestrictScalars import Mathlib.Algebra.Module.ULift import Mathlib.Algebra.Ring.CharZero import Mathlib.Algebra.Ring.Subring.Basic import Mathlib.Data.Nat.Cast.Order.Basic import Mathlib.Data.Int.CharZero /-! # Further basic results about `Algebra`. This file could usefully be split further. -/ universe u v w u₁ v₁ open Function namespace Algebra variable {R : Type u} {A : Type w} section Semiring variable [CommSemiring R] variable [Semiring A] [Algebra R A] section PUnit instance _root_.PUnit.algebra : Algebra R PUnit.{v + 1} where algebraMap := { toFun _ := PUnit.unit map_one' := rfl map_mul' _ _ := rfl map_zero' := rfl map_add' _ _ := rfl } commutes' _ _ := rfl smul_def' _ _ := rfl @[simp] theorem algebraMap_pUnit (r : R) : algebraMap R PUnit r = PUnit.unit := rfl end PUnit section ULift instance _root_.ULift.algebra : Algebra R (ULift A) := { ULift.module' with algebraMap := { (ULift.ringEquiv : ULift A ≃+* A).symm.toRingHom.comp (algebraMap R A) with toFun := fun r => ULift.up (algebraMap R A r) } commutes' := fun r x => ULift.down_injective <\| Algebra.commutes r x.down smul_def' := fun r x => ULift.down_injective <\| Algebra.smul_def' r x.down } theorem _root_.ULift.algebraMap_eq (r : R) : algebraMap R (ULift A) r = ULift.up (algebraMap R A r) := rfl @[simp] theorem _root_.ULift.down_algebraMap (r : R) : (algebraMap R (ULift A) r).down = algebraMap R A r := rfl end ULift /-- Algebra over a subsemiring. This builds upon `Subsemiring.module`. -/ instance ofSubsemiring (S : Subsemiring R) : Algebra S A where algebraMap := (algebraMap R A).comp S.subtype smul := (· • ·) commutes' r x := Algebra.commutes (r : R) x smul_def' r x := Algebra.smul_def (r : R) x theorem algebraMap_ofSubsemiring (S : Subsemiring R) : (algebraMap S R : S →+* R) = Subsemiring.subtype S := rfl theorem coe_algebraMap_ofSubsemiring (S : Subsemiring R) : (algebraMap S R : S → R) = Subtype.val := rfl theorem algebraMap_ofSubsemiring_apply (S : Subsemiring R) (x : S) : algebraMap S R x = x := rfl /-- Algebra over a subring. This builds upon `Subring.module`. -/ instance ofSubring {R A : Type} [CommRing R] [Ring A] [Algebra R A] (S : Subring R) : Algebra S A where algebraMap := (algebraMap R A).comp S.subtype smul := (· • ·) commutes' r x := Algebra.commutes (r : R) x smul_def' r x := Algebra.smul_def (r : R) x theorem algebraMap_ofSubring {R : Type} [CommRing R] (S : Subring R) : (algebraMap S R : S →+* R) = Subring.subtype S := rfl theorem coe_algebraMap_ofSubring {R : Type} [CommRing R] (S : Subring R) : (algebraMap S R : S → R) = Subtype.val := rfl theorem algebraMap_ofSubring_apply {R : Type} [CommRing R] (S : Subring R) (x : S) : algebraMap S R x = x := rfl /-- Explicit characterization of the submonoid map in the case of an algebra. `S` is made explicit to help with type inference -/ def algebraMapSubmonoid (S : Type) [Semiring S] [Algebra R S] (M : Submonoid R) : Submonoid S := M.map (algebraMap R S) theorem mem_algebraMapSubmonoid_of_mem {S : Type} [Semiring S] [Algebra R S] {M : Submonoid R} (x : M) : algebraMap R S x ∈ algebraMapSubmonoid S M := Set.mem_image_of_mem (algebraMap R S) x.2 end Semiring section CommSemiring variable [CommSemiring R] theorem mul_sub_algebraMap_commutes [Ring A] [Algebra R A] (x : A) (r : R) : x * (x - algebraMap R A r) = (x - algebraMap R A r) * x := by rw [mul_sub, ← commutes, sub_mul] theorem mul_sub_algebraMap_pow_commutes [Ring A] [Algebra R A] (x : A) (r : R) (n : ℕ) : x * (x - algebraMap R A r) ^ n = (x - algebraMap R A r) ^ n * x := by induction n with \| zero => simp \| succ n ih => rw [pow_succ', ← mul_assoc, mul_sub_algebraMap_commutes, mul_assoc, ih, ← mul_assoc] end CommSemiring section Ring /-- A `Semiring` that is an `Algebra` over a commutative ring carries a natural `Ring` structure. See note [reducible non-instances]. -/	abbrev semiringToRing (R : Type*) [CommRing R] [Semiring A] [Algebra R A] : Ring A := { __ := (inferInstance : Semiring A) __ := Module.addCommMonoidToAddCommGroup R intCast := fun z => algebraMap R A z intCast_ofNat := fun z => by simp only [Int.cast_natCast, map_natCast]	Mathlib/Algebra/Algebra/Basic.lean	141	145
/- Copyright (c) 2018 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Kenny Lau, Johan Commelin, Mario Carneiro, Kevin Buzzard, Amelia Livingston, Yury Kudryashov -/ import Mathlib.Algebra.BigOperators.Group.Multiset.Defs import Mathlib.Algebra.FreeMonoid.Basic import Mathlib.Algebra.Group.Idempotent import Mathlib.Algebra.Group.Nat.Hom import Mathlib.Algebra.Group.Submonoid.MulOpposite import Mathlib.Algebra.Group.Submonoid.Operations import Mathlib.Data.Fintype.EquivFin import Mathlib.Data.Int.Basic /-! # Submonoids: membership criteria In this file we prove various facts about membership in a submonoid: * `pow_mem`, `nsmul_mem`: if `x ∈ S` where `S` is a multiplicative (resp., additive) submonoid and `n` is a natural number, then `x^n` (resp., `n • x`) belongs to `S`; * `mem_iSup_of_directed`, `coe_iSup_of_directed`, `mem_sSup_of_directedOn`, `coe_sSup_of_directedOn`: the supremum of a directed collection of submonoid is their union. * `sup_eq_range`, `mem_sup`: supremum of two submonoids `S`, `T` of a commutative monoid is the set of products; * `closure_singleton_eq`, `mem_closure_singleton`, `mem_closure_pair`: the multiplicative (resp., additive) closure of `{x}` consists of powers (resp., natural multiples) of `x`, and a similar result holds for the closure of `{x, y}`. ## Tags submonoid, submonoids -/ assert_not_exists MonoidWithZero variable {M A B : Type} section Assoc variable [Monoid M] [SetLike B M] [SubmonoidClass B M] {S : B} end Assoc section NonAssoc variable [MulOneClass M] open Set namespace Submonoid -- TODO: this section can be generalized to `[SubmonoidClass B M] [CompleteLattice B]` -- such that `CompleteLattice.LE` coincides with `SetLike.LE` @[to_additive] theorem mem_iSup_of_directed {ι} [hι : Nonempty ι] {S : ι → Submonoid M} (hS : Directed (· ≤ ·) S) {x : M} : (x ∈ ⨆ i, S i) ↔ ∃ i, x ∈ S i := by refine ⟨?_, fun ⟨i, hi⟩ ↦ le_iSup S i hi⟩ suffices x ∈ closure (⋃ i, (S i : Set M)) → ∃ i, x ∈ S i by simpa only [closure_iUnion, closure_eq (S _)] using this refine closure_induction (fun _ ↦ mem_iUnion.1) ?_ ?_ · exact hι.elim fun i ↦ ⟨i, (S i).one_mem⟩ · rintro x y - - ⟨i, hi⟩ ⟨j, hj⟩ rcases hS i j with ⟨k, hki, hkj⟩ exact ⟨k, (S k).mul_mem (hki hi) (hkj hj)⟩ @[to_additive] theorem coe_iSup_of_directed {ι} [Nonempty ι] {S : ι → Submonoid M} (hS : Directed (· ≤ ·) S) : ((⨆ i, S i : Submonoid M) : Set M) = ⋃ i, S i := Set.ext fun x ↦ by simp [mem_iSup_of_directed hS] @[to_additive] theorem mem_sSup_of_directedOn {S : Set (Submonoid M)} (Sne : S.Nonempty) (hS : DirectedOn (· ≤ ·) S) {x : M} : x ∈ sSup S ↔ ∃ s ∈ S, x ∈ s := by haveI : Nonempty S := Sne.to_subtype simp [sSup_eq_iSup', mem_iSup_of_directed hS.directed_val, SetCoe.exists, Subtype.coe_mk] @[to_additive] theorem coe_sSup_of_directedOn {S : Set (Submonoid M)} (Sne : S.Nonempty) (hS : DirectedOn (· ≤ ·) S) : (↑(sSup S) : Set M) = ⋃ s ∈ S, ↑s := Set.ext fun x => by simp [mem_sSup_of_directedOn Sne hS] @[to_additive] theorem mem_sup_left {S T : Submonoid M} : ∀ {x : M}, x ∈ S → x ∈ S ⊔ T := by rw [← SetLike.le_def] exact le_sup_left @[to_additive] theorem mem_sup_right {S T : Submonoid M} : ∀ {x : M}, x ∈ T → x ∈ S ⊔ T := by rw [← SetLike.le_def] exact le_sup_right @[to_additive] theorem mul_mem_sup {S T : Submonoid M} {x y : M} (hx : x ∈ S) (hy : y ∈ T) : x y ∈ S ⊔ T := (S ⊔ T).mul_mem (mem_sup_left hx) (mem_sup_right hy) @[to_additive] theorem mem_iSup_of_mem {ι : Sort} {S : ι → Submonoid M} (i : ι) : ∀ {x : M}, x ∈ S i → x ∈ iSup S := by rw [← SetLike.le_def] exact le_iSup _ _ @[to_additive] theorem mem_sSup_of_mem {S : Set (Submonoid M)} {s : Submonoid M} (hs : s ∈ S) : ∀ {x : M}, x ∈ s → x ∈ sSup S := by rw [← SetLike.le_def] exact le_sSup hs /-- An induction principle for elements of `⨆ i, S i`. If `C` holds for `1` and all elements of `S i` for all `i`, and is preserved under multiplication, then it holds for all elements of the supremum of `S`. -/ @[to_additive (attr := elab_as_elim) " An induction principle for elements of `⨆ i, S i`. If `C` holds for `0` and all elements of `S i` for all `i`, and is preserved under addition, then it holds for all elements of the supremum of `S`. "] theorem iSup_induction {ι : Sort} (S : ι → Submonoid M) {motive : M → Prop} {x : M} (hx : x ∈ ⨆ i, S i) (mem : ∀ (i), ∀ x ∈ S i, motive x) (one : motive 1) (mul : ∀ x y, motive x → motive y → motive (x * y)) : motive x := by rw [iSup_eq_closure] at hx refine closure_induction (fun x hx => ?_) one (fun _ _ _ _ ↦ mul _ _) hx obtain ⟨i, hi⟩ := Set.mem_iUnion.mp hx exact mem _ _ hi /-- A dependent version of `Submonoid.iSup_induction`. -/ @[to_additive (attr := elab_as_elim) "A dependent version of `AddSubmonoid.iSup_induction`. "] theorem iSup_induction' {ι : Sort} (S : ι → Submonoid M) {motive : ∀ x, (x ∈ ⨆ i, S i) → Prop} (mem : ∀ (i), ∀ (x) (hxS : x ∈ S i), motive x (mem_iSup_of_mem i hxS)) (one : motive 1 (one_mem _)) (mul : ∀ x y hx hy, motive x hx → motive y hy → motive (x y) (mul_mem ‹_› ‹_›)) {x : M} (hx : x ∈ ⨆ i, S i) : motive x hx := by refine Exists.elim (?_ : ∃ Hx, motive x Hx) fun (hx : x ∈ ⨆ i, S i) (hc : motive x hx) => hc refine @iSup_induction _ _ ι S (fun m => ∃ hm, motive m hm) _ hx (fun i x hx => ?_) ?_ fun x y => ?_ · exact ⟨_, mem _ _ hx⟩ · exact ⟨_, one⟩ · rintro ⟨_, Cx⟩ ⟨_, Cy⟩ exact ⟨_, mul _ _ _ _ Cx Cy⟩ end Submonoid end NonAssoc namespace FreeMonoid variable {α : Type} open Submonoid @[to_additive] theorem closure_range_of : closure (Set.range <\| @of α) = ⊤ := eq_top_iff.2 fun x _ => FreeMonoid.recOn x (one_mem _) fun _x _xs hxs => mul_mem (subset_closure <\| Set.mem_range_self _) hxs end FreeMonoid namespace Submonoid variable [Monoid M] {a : M} open MonoidHom theorem closure_singleton_eq (x : M) : closure ({x} : Set M) = mrange (powersHom M x) := closure_eq_of_le (Set.singleton_subset_iff.2 ⟨Multiplicative.ofAdd 1, pow_one x⟩) fun _ ⟨_, hn⟩ => hn ▸ pow_mem (subset_closure <\| Set.mem_singleton _) _ /-- The submonoid generated by an element of a monoid equals the set of natural number powers of the element. -/ theorem mem_closure_singleton {x y : M} : y ∈ closure ({x} : Set M) ↔ ∃ n : ℕ, x ^ n = y := by rw [closure_singleton_eq, mem_mrange]; rfl theorem mem_closure_singleton_self {y : M} : y ∈ closure ({y} : Set M) := mem_closure_singleton.2 ⟨1, pow_one y⟩ theorem closure_singleton_one : closure ({1} : Set M) = ⊥ := by simp [eq_bot_iff_forall, mem_closure_singleton] section Submonoid variable {S : Submonoid M} [Fintype S] open Fintype /- curly brackets `{}` are used here instead of instance brackets `[]` because the instance in a goal is often not the same as the one inferred by type class inference. -/ @[to_additive] theorem card_bot {_ : Fintype (⊥ : Submonoid M)} : card (⊥ : Submonoid M) = 1 := card_eq_one_iff.2 ⟨⟨(1 : M), Set.mem_singleton 1⟩, fun ⟨_y, hy⟩ => Subtype.eq <\| mem_bot.1 hy⟩ @[to_additive] theorem eq_bot_of_card_le (h : card S ≤ 1) : S = ⊥ := let _ := card_le_one_iff_subsingleton.mp h eq_bot_of_subsingleton S @[to_additive] theorem eq_bot_of_card_eq (h : card S = 1) : S = ⊥ := S.eq_bot_of_card_le (le_of_eq h) @[to_additive card_le_one_iff_eq_bot] theorem card_le_one_iff_eq_bot : card S ≤ 1 ↔ S = ⊥ := ⟨fun h => (eq_bot_iff_forall _).2 fun x hx => by simpa [Subtype.ext_iff] using card_le_one_iff.1 h ⟨x, hx⟩ 1, fun h => by simp [h]⟩ @[to_additive] lemma eq_bot_iff_card : S = ⊥ ↔ card S = 1 := ⟨by rintro rfl; exact card_bot, eq_bot_of_card_eq⟩ end Submonoid @[to_additive] theorem _root_.FreeMonoid.mrange_lift {α} (f : α → M) : mrange (FreeMonoid.lift f) = closure (Set.range f) := by rw [mrange_eq_map, ← FreeMonoid.closure_range_of, map_mclosure, ← Set.range_comp, FreeMonoid.lift_comp_of] @[to_additive] theorem closure_eq_mrange (s : Set M) : closure s = mrange (FreeMonoid.lift ((↑) : s → M)) := by rw [FreeMonoid.mrange_lift, Subtype.range_coe] @[to_additive] theorem closure_eq_image_prod (s : Set M) : (closure s : Set M) = List.prod '' { l : List M \| ∀ x ∈ l, x ∈ s } := by rw [closure_eq_mrange, coe_mrange, ← Set.range_list_map_coe, ← Set.range_comp] exact congrArg _ (funext <\| FreeMonoid.lift_apply _) @[to_additive] theorem exists_list_of_mem_closure {s : Set M} {x : M} (hx : x ∈ closure s) : ∃ l : List M, (∀ y ∈ l, y ∈ s) ∧ l.prod = x := by rwa [← SetLike.mem_coe, closure_eq_image_prod, Set.mem_image] at hx @[to_additive] theorem exists_multiset_of_mem_closure {M : Type} [CommMonoid M] {s : Set M} {x : M} (hx : x ∈ closure s) : ∃ l : Multiset M, (∀ y ∈ l, y ∈ s) ∧ l.prod = x := by obtain ⟨l, h1, h2⟩ := exists_list_of_mem_closure hx exact ⟨l, h1, (Multiset.prod_coe l).trans h2⟩ @[to_additive (attr := elab_as_elim)] theorem closure_induction_left {s : Set M} {p : (m : M) → m ∈ closure s → Prop} (one : p 1 (one_mem _)) (mul_left : ∀ x (hx : x ∈ s), ∀ (y) hy, p y hy → p (x * y) (mul_mem (subset_closure hx) hy)) {x : M} (h : x ∈ closure s) : p x h := by simp_rw [closure_eq_mrange] at h obtain ⟨l, rfl⟩ := h induction l using FreeMonoid.inductionOn' with \| one => exact one \| mul_of x y ih => simp only [map_mul, FreeMonoid.lift_eval_of] refine mul_left _ x.prop (FreeMonoid.lift Subtype.val y) _ (ih ?_) simp only [closure_eq_mrange, mem_mrange, exists_apply_eq_apply] @[to_additive (attr := elab_as_elim)] theorem induction_of_closure_eq_top_left {s : Set M} {p : M → Prop} (hs : closure s = ⊤) (x : M) (one : p 1) (mul : ∀ x ∈ s, ∀ (y), p y → p (x * y)) : p x := by have : x ∈ closure s := by simp [hs] induction this using closure_induction_left with \| one => exact one \| mul_left x hx y _ ih => exact mul x hx y ih @[to_additive (attr := elab_as_elim)] theorem closure_induction_right {s : Set M} {p : (m : M) → m ∈ closure s → Prop} (one : p 1 (one_mem _)) (mul_right : ∀ x hx, ∀ (y) (hy : y ∈ s), p x hx → p (x * y) (mul_mem hx (subset_closure hy))) {x : M} (h : x ∈ closure s) : p x h := closure_induction_left (s := MulOpposite.unop ⁻¹' s) (p := fun m hm => p m.unop <\| by rwa [← op_closure] at hm) one (fun _x hx _y _ => mul_right _ _ _ hx) (by rwa [← op_closure]) @[to_additive (attr := elab_as_elim)] theorem induction_of_closure_eq_top_right {s : Set M} {p : M → Prop} (hs : closure s = ⊤) (x : M) (H1 : p 1) (Hmul : ∀ (x), ∀ y ∈ s, p x → p (x * y)) : p x := by have : x ∈ closure s := by simp [hs] induction this using closure_induction_right with \| one => exact H1 \| mul_right x _ y hy ih => exact Hmul x y hy ih /-- The submonoid generated by an element. -/ def powers (n : M) : Submonoid M := Submonoid.copy (mrange (powersHom M n)) (Set.range (n ^ · : ℕ → M)) <\| Set.ext fun n => exists_congr fun i => by simp; rfl theorem mem_powers (n : M) : n ∈ powers n := ⟨1, pow_one _⟩ theorem coe_powers (x : M) : ↑(powers x) = Set.range fun n : ℕ => x ^ n := rfl theorem mem_powers_iff (x z : M) : x ∈ powers z ↔ ∃ n : ℕ, z ^ n = x := Iff.rfl noncomputable instance decidableMemPowers : DecidablePred (· ∈ Submonoid.powers a) := Classical.decPred _ -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO the following instance should follow from a more general principle -- See also https://github.com/leanprover-community/mathlib4/issues/2417 noncomputable instance fintypePowers [Fintype M] : Fintype (powers a) := inferInstanceAs <\| Fintype {y // y ∈ powers a} theorem powers_eq_closure (n : M) : powers n = closure {n} := by ext exact mem_closure_singleton.symm lemma powers_le {n : M} {P : Submonoid M} : powers n ≤ P ↔ n ∈ P := by simp [powers_eq_closure] lemma powers_one : powers (1 : M) = ⊥ := bot_unique <\| powers_le.2 <\| one_mem _ theorem _root_.IsIdempotentElem.coe_powers {a : M} (ha : IsIdempotentElem a) : (Submonoid.powers a : Set M) = {1, a} := let S : Submonoid M := { carrier := {1, a}, mul_mem' := by rintro _ _ (rfl\|rfl) (rfl\|rfl) · rw [one_mul]; exact .inl rfl · rw [one_mul]; exact .inr rfl · rw [mul_one]; exact .inr rfl · rw [ha]; exact .inr rfl one_mem' := .inl rfl } suffices Submonoid.powers a = S from congr_arg _ this le_antisymm (Submonoid.powers_le.mpr <\| .inr rfl) (by rintro _ (rfl\|rfl); exacts [one_mem _, Submonoid.mem_powers _]) /-- The submonoid generated by an element is a group if that element has finite order. -/ abbrev groupPowers {x : M} {n : ℕ} (hpos : 0 < n) (hx : x ^ n = 1) : Group (powers x) where inv x := x ^ (n - 1) inv_mul_cancel y := Subtype.ext <\| by obtain ⟨_, k, rfl⟩ := y simp only [coe_one, coe_mul, SubmonoidClass.coe_pow] rw [← pow_succ, Nat.sub_add_cancel hpos, ← pow_mul, mul_comm, pow_mul, hx, one_pow] zpow z x := x ^ z.natMod n zpow_zero' z := by simp only [Int.natMod, Int.zero_emod, Int.toNat_zero, pow_zero] zpow_neg' m x := Subtype.ext <\| by obtain ⟨_, k, rfl⟩ := x simp only [← pow_mul, Int.natMod, SubmonoidClass.coe_pow] rw [Int.negSucc_eq, ← Int.natCast_succ, ← Int.add_mul_emod_self_right (b := (m + 1 : ℕ))] nth_rw 1 [← mul_one ((m + 1 : ℕ) : ℤ)] rw [← sub_eq_neg_add, ← Int.mul_sub, ← Int.natCast_pred_of_pos hpos]; norm_cast simp only [Int.toNat_natCast] rw [mul_comm, pow_mul, ← pow_eq_pow_mod _ hx, mul_comm k, mul_assoc, pow_mul _ (_ % _), ← pow_eq_pow_mod _ hx, pow_mul, pow_mul] zpow_succ' m x := Subtype.ext <\| by obtain ⟨_, k, rfl⟩ := x simp only [← pow_mul, Int.natMod, SubmonoidClass.coe_pow, coe_mul] norm_cast iterate 2 rw [Int.toNat_natCast, mul_comm, pow_mul, ← pow_eq_pow_mod _ hx] rw [← pow_mul _ m, mul_comm, pow_mul, ← pow_succ, ← pow_mul, mul_comm, pow_mul] /-- Exponentiation map from natural numbers to powers. -/ @[simps!] def pow (n : M) (m : ℕ) : powers n := (powersHom M n).mrangeRestrict (Multiplicative.ofAdd m) theorem pow_apply (n : M) (m : ℕ) : Submonoid.pow n m = ⟨n ^ m, m, rfl⟩ := rfl /-- Logarithms from powers to natural numbers. -/ def log [DecidableEq M] {n : M} (p : powers n) : ℕ := Nat.find <\| (mem_powers_iff p.val n).mp p.prop @[simp] theorem pow_log_eq_self [DecidableEq M] {n : M} (p : powers n) : pow n (log p) = p := Subtype.ext <\| Nat.find_spec p.prop theorem pow_right_injective_iff_pow_injective {n : M} : (Function.Injective fun m : ℕ => n ^ m) ↔ Function.Injective (pow n) := Subtype.coe_injective.of_comp_iff (pow n) @[simp] theorem log_pow_eq_self [DecidableEq M] {n : M} (h : Function.Injective fun m : ℕ => n ^ m) (m : ℕ) : log (pow n m) = m := pow_right_injective_iff_pow_injective.mp h <\| pow_log_eq_self _ /-- The exponentiation map is an isomorphism from the additive monoid on natural numbers to powers when it is injective. The inverse is given by the logarithms. -/ @[simps] def powLogEquiv [DecidableEq M] {n : M} (h : Function.Injective fun m : ℕ => n ^ m) : Multiplicative ℕ ≃* powers n where toFun m := pow n m.toAdd invFun m := Multiplicative.ofAdd (log m) left_inv := log_pow_eq_self h right_inv := pow_log_eq_self map_mul' _ _ := by simp only [pow, map_mul, ofAdd_add, toAdd_mul] theorem log_mul [DecidableEq M] {n : M} (h : Function.Injective fun m : ℕ => n ^ m) (x y : powers (n : M)) : log (x * y) = log x + log y := map_mul (powLogEquiv h).symm x y theorem log_pow_int_eq_self {x : ℤ} (h : 1 < x.natAbs) (m : ℕ) : log (pow x m) = m := (powLogEquiv (Int.pow_right_injective h)).symm_apply_apply _ @[simp] theorem map_powers {N : Type} {F : Type} [Monoid N] [FunLike F M N] [MonoidHomClass F M N] (f : F) (m : M) : (powers m).map f = powers (f m) := by simp only [powers_eq_closure, map_mclosure f, Set.image_singleton] end Submonoid @[to_additive] theorem IsScalarTower.of_mclosure_eq_top {N α} [Monoid M] [MulAction M N] [SMul N α] [MulAction M α] {s : Set M} (htop : Submonoid.closure s = ⊤) (hs : ∀ x ∈ s, ∀ (y : N) (z : α), (x • y) • z = x • y • z) : IsScalarTower M N α := by refine ⟨fun x => Submonoid.induction_of_closure_eq_top_left htop x ?_ ?_⟩ · intro y z rw [one_smul, one_smul]	· clear x intro x hx x' hx' y z rw [mul_smul, mul_smul, hs x hx, hx']	Mathlib/Algebra/Group/Submonoid/Membership.lean	407	410
/- Copyright (c) 2015, 2017 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Robert Y. Lewis, Johannes Hölzl, Mario Carneiro, Sébastien Gouëzel -/ import Mathlib.Data.ENNReal.Real import Mathlib.Tactic.Bound.Attribute import Mathlib.Topology.Bornology.Basic import Mathlib.Topology.EMetricSpace.Defs import Mathlib.Topology.UniformSpace.Basic /-! ## Pseudo-metric spaces This file defines pseudo-metric spaces: these differ from metric spaces by not imposing the condition `dist x y = 0 → x = y`. Many definitions and theorems expected on (pseudo-)metric spaces are already introduced on uniform spaces and topological spaces. For example: open and closed sets, compactness, completeness, continuity and uniform continuity. ## Main definitions * `Dist α`: Endows a space `α` with a function `dist a b`. * `PseudoMetricSpace α`: A space endowed with a distance function, which can be zero even if the two elements are non-equal. * `Metric.ball x ε`: The set of all points `y` with `dist y x < ε`. * `Metric.Bounded s`: Whether a subset of a `PseudoMetricSpace` is bounded. * `MetricSpace α`: A `PseudoMetricSpace` with the guarantee `dist x y = 0 → x = y`. Additional useful definitions: * `nndist a b`: `dist` as a function to the non-negative reals. * `Metric.closedBall x ε`: The set of all points `y` with `dist y x ≤ ε`. * `Metric.sphere x ε`: The set of all points `y` with `dist y x = ε`. TODO (anyone): Add "Main results" section. ## Tags pseudo_metric, dist -/ assert_not_exists compactSpace_uniformity open Set Filter TopologicalSpace Bornology open scoped ENNReal NNReal Uniformity Topology universe u v w variable {α : Type u} {β : Type v} {X ι : Type} theorem UniformSpace.ofDist_aux (ε : ℝ) (hε : 0 < ε) : ∃ δ > (0 : ℝ), ∀ x < δ, ∀ y < δ, x + y < ε := ⟨ε / 2, half_pos hε, fun _x hx _y hy => add_halves ε ▸ add_lt_add hx hy⟩ /-- Construct a uniform structure from a distance function and metric space axioms -/ def UniformSpace.ofDist (dist : α → α → ℝ) (dist_self : ∀ x : α, dist x x = 0) (dist_comm : ∀ x y : α, dist x y = dist y x) (dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z) : UniformSpace α := .ofFun dist dist_self dist_comm dist_triangle ofDist_aux /-- Construct a bornology from a distance function and metric space axioms. -/ abbrev Bornology.ofDist {α : Type} (dist : α → α → ℝ) (dist_comm : ∀ x y, dist x y = dist y x) (dist_triangle : ∀ x y z, dist x z ≤ dist x y + dist y z) : Bornology α := Bornology.ofBounded { s : Set α \| ∃ C, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C } ⟨0, fun _ hx _ => hx.elim⟩ (fun _ ⟨c, hc⟩ _ h => ⟨c, fun _ hx _ hy => hc (h hx) (h hy)⟩) (fun s hs t ht => by rcases s.eq_empty_or_nonempty with rfl \| ⟨x, hx⟩ · rwa [empty_union] rcases t.eq_empty_or_nonempty with rfl \| ⟨y, hy⟩ · rwa [union_empty] rsuffices ⟨C, hC⟩ : ∃ C, ∀ z ∈ s ∪ t, dist x z ≤ C · refine ⟨C + C, fun a ha b hb => (dist_triangle a x b).trans ?_⟩ simpa only [dist_comm] using add_le_add (hC _ ha) (hC _ hb) rcases hs with ⟨Cs, hs⟩; rcases ht with ⟨Ct, ht⟩ refine ⟨max Cs (dist x y + Ct), fun z hz => hz.elim (fun hz => (hs hx hz).trans (le_max_left _ _)) (fun hz => (dist_triangle x y z).trans <\| (add_le_add le_rfl (ht hy hz)).trans (le_max_right _ _))⟩) fun z => ⟨dist z z, forall_eq.2 <\| forall_eq.2 le_rfl⟩ /-- The distance function (given an ambient metric space on `α`), which returns a nonnegative real number `dist x y` given `x y : α`. -/ @[ext] class Dist (α : Type) where /-- Distance between two points -/ dist : α → α → ℝ export Dist (dist) -- the uniform structure and the emetric space structure are embedded in the metric space structure -- to avoid instance diamond issues. See Note [forgetful inheritance]. /-- This is an internal lemma used inside the default of `PseudoMetricSpace.edist`. -/ private theorem dist_nonneg' {α} {x y : α} (dist : α → α → ℝ) (dist_self : ∀ x : α, dist x x = 0) (dist_comm : ∀ x y : α, dist x y = dist y x) (dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z) : 0 ≤ dist x y := have : 0 ≤ 2 dist x y := calc 0 = dist x x := (dist_self _).symm _ ≤ dist x y + dist y x := dist_triangle _ _ _ _ = 2 * dist x y := by rw [two_mul, dist_comm] nonneg_of_mul_nonneg_right this two_pos /-- A pseudometric space is a type endowed with a `ℝ`-valued distance `dist` satisfying reflexivity `dist x x = 0`, commutativity `dist x y = dist y x`, and the triangle inequality `dist x z ≤ dist x y + dist y z`. Note that we do not require `dist x y = 0 → x = y`. See metric spaces (`MetricSpace`) for the similar class with that stronger assumption. Any pseudometric space is a topological space and a uniform space (see `TopologicalSpace`, `UniformSpace`), where the topology and uniformity come from the metric. Note that a T1 pseudometric space is just a metric space. We make the uniformity/topology part of the data instead of deriving it from the metric. This eg ensures that we do not get a diamond when doing `[PseudoMetricSpace α] [PseudoMetricSpace β] : TopologicalSpace (α × β)`: The product metric and product topology agree, but not definitionally so. See Note [forgetful inheritance]. -/ class PseudoMetricSpace (α : Type u) : Type u extends Dist α where dist_self : ∀ x : α, dist x x = 0 dist_comm : ∀ x y : α, dist x y = dist y x dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z /-- Extended distance between two points -/ edist : α → α → ℝ≥0∞ := fun x y => ENNReal.ofNNReal ⟨dist x y, dist_nonneg' _ ‹_› ‹_› ‹_›⟩ edist_dist : ∀ x y : α, edist x y = ENNReal.ofReal (dist x y) := by intros x y; exact ENNReal.coe_nnreal_eq _ toUniformSpace : UniformSpace α := .ofDist dist dist_self dist_comm dist_triangle uniformity_dist : 𝓤 α = ⨅ ε > 0, 𝓟 { p : α × α \| dist p.1 p.2 < ε } := by intros; rfl toBornology : Bornology α := Bornology.ofDist dist dist_comm dist_triangle cobounded_sets : (Bornology.cobounded α).sets = { s \| ∃ C : ℝ, ∀ x ∈ sᶜ, ∀ y ∈ sᶜ, dist x y ≤ C } := by intros; rfl /-- Two pseudo metric space structures with the same distance function coincide. -/ @[ext] theorem PseudoMetricSpace.ext {α : Type} {m m' : PseudoMetricSpace α} (h : m.toDist = m'.toDist) : m = m' := by let d := m.toDist obtain ⟨_, _, _, _, hed, _, hU, _, hB⟩ := m let d' := m'.toDist obtain ⟨_, _, _, _, hed', _, hU', _, hB'⟩ := m' obtain rfl : d = d' := h congr · ext x y : 2 rw [hed, hed'] · exact UniformSpace.ext (hU.trans hU'.symm) · ext : 2 rw [← Filter.mem_sets, ← Filter.mem_sets, hB, hB'] variable [PseudoMetricSpace α] attribute [instance] PseudoMetricSpace.toUniformSpace PseudoMetricSpace.toBornology -- see Note [lower instance priority] instance (priority := 200) PseudoMetricSpace.toEDist : EDist α := ⟨PseudoMetricSpace.edist⟩ /-- Construct a pseudo-metric space structure whose underlying topological space structure (definitionally) agrees which a pre-existing topology which is compatible with a given distance function. -/ def PseudoMetricSpace.ofDistTopology {α : Type u} [TopologicalSpace α] (dist : α → α → ℝ) (dist_self : ∀ x : α, dist x x = 0) (dist_comm : ∀ x y : α, dist x y = dist y x) (dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z) (H : ∀ s : Set α, IsOpen s ↔ ∀ x ∈ s, ∃ ε > 0, ∀ y, dist x y < ε → y ∈ s) : PseudoMetricSpace α := { dist := dist dist_self := dist_self dist_comm := dist_comm dist_triangle := dist_triangle toUniformSpace := (UniformSpace.ofDist dist dist_self dist_comm dist_triangle).replaceTopology <\| TopologicalSpace.ext_iff.2 fun s ↦ (H s).trans <\| forall₂_congr fun x _ ↦ ((UniformSpace.hasBasis_ofFun (exists_gt (0 : ℝ)) dist dist_self dist_comm dist_triangle UniformSpace.ofDist_aux).comap (Prod.mk x)).mem_iff.symm uniformity_dist := rfl toBornology := Bornology.ofDist dist dist_comm dist_triangle cobounded_sets := rfl } @[simp] theorem dist_self (x : α) : dist x x = 0 := PseudoMetricSpace.dist_self x theorem dist_comm (x y : α) : dist x y = dist y x := PseudoMetricSpace.dist_comm x y theorem edist_dist (x y : α) : edist x y = ENNReal.ofReal (dist x y) := PseudoMetricSpace.edist_dist x y @[bound] theorem dist_triangle (x y z : α) : dist x z ≤ dist x y + dist y z := PseudoMetricSpace.dist_triangle x y z theorem dist_triangle_left (x y z : α) : dist x y ≤ dist z x + dist z y := by rw [dist_comm z]; apply dist_triangle theorem dist_triangle_right (x y z : α) : dist x y ≤ dist x z + dist y z := by rw [dist_comm y]; apply dist_triangle theorem dist_triangle4 (x y z w : α) : dist x w ≤ dist x y + dist y z + dist z w := calc dist x w ≤ dist x z + dist z w := dist_triangle x z w _ ≤ dist x y + dist y z + dist z w := add_le_add_right (dist_triangle x y z) _ theorem dist_triangle4_left (x₁ y₁ x₂ y₂ : α) : dist x₂ y₂ ≤ dist x₁ y₁ + (dist x₁ x₂ + dist y₁ y₂) := by rw [add_left_comm, dist_comm x₁, ← add_assoc] apply dist_triangle4 theorem dist_triangle4_right (x₁ y₁ x₂ y₂ : α) : dist x₁ y₁ ≤ dist x₁ x₂ + dist y₁ y₂ + dist x₂ y₂ := by rw [add_right_comm, dist_comm y₁] apply dist_triangle4 theorem dist_triangle8 (a b c d e f g h : α) : dist a h ≤ dist a b + dist b c + dist c d + dist d e + dist e f + dist f g + dist g h := by apply le_trans (dist_triangle4 a f g h) apply add_le_add_right (add_le_add_right _ (dist f g)) (dist g h) apply le_trans (dist_triangle4 a d e f) apply add_le_add_right (add_le_add_right _ (dist d e)) (dist e f) exact dist_triangle4 a b c d theorem swap_dist : Function.swap (@dist α _) = dist := by funext x y; exact dist_comm _ _ theorem abs_dist_sub_le (x y z : α) : \|dist x z - dist y z\| ≤ dist x y := abs_sub_le_iff.2 ⟨sub_le_iff_le_add.2 (dist_triangle _ _ _), sub_le_iff_le_add.2 (dist_triangle_left _ _ _)⟩ @[bound] theorem dist_nonneg {x y : α} : 0 ≤ dist x y := dist_nonneg' dist dist_self dist_comm dist_triangle namespace Mathlib.Meta.Positivity open Lean Meta Qq Function /-- Extension for the `positivity` tactic: distances are nonnegative. -/ @[positivity Dist.dist _ _] def evalDist : PositivityExt where eval {u α} _zα _pα e := do match u, α, e with \| 0, ~q(ℝ), ~q(@Dist.dist $β $inst $a $b) => let _inst ← synthInstanceQ q(PseudoMetricSpace $β) assertInstancesCommute pure (.nonnegative q(dist_nonneg)) \| _, _, _ => throwError "not dist" end Mathlib.Meta.Positivity example {x y : α} : 0 ≤ dist x y := by positivity @[simp] theorem abs_dist {a b : α} : \|dist a b\| = dist a b := abs_of_nonneg dist_nonneg /-- A version of `Dist` that takes value in `ℝ≥0`. -/ class NNDist (α : Type) where /-- Nonnegative distance between two points -/ nndist : α → α → ℝ≥0 export NNDist (nndist) -- see Note [lower instance priority] /-- Distance as a nonnegative real number. -/ instance (priority := 100) PseudoMetricSpace.toNNDist : NNDist α := ⟨fun a b => ⟨dist a b, dist_nonneg⟩⟩ /-- Express `dist` in terms of `nndist` -/ theorem dist_nndist (x y : α) : dist x y = nndist x y := rfl @[simp, norm_cast] theorem coe_nndist (x y : α) : ↑(nndist x y) = dist x y := rfl /-- Express `edist` in terms of `nndist` -/ theorem edist_nndist (x y : α) : edist x y = nndist x y := by rw [edist_dist, dist_nndist, ENNReal.ofReal_coe_nnreal] /-- Express `nndist` in terms of `edist` -/ theorem nndist_edist (x y : α) : nndist x y = (edist x y).toNNReal := by simp [edist_nndist] @[simp, norm_cast] theorem coe_nnreal_ennreal_nndist (x y : α) : ↑(nndist x y) = edist x y := (edist_nndist x y).symm @[simp, norm_cast] theorem edist_lt_coe {x y : α} {c : ℝ≥0} : edist x y < c ↔ nndist x y < c := by rw [edist_nndist, ENNReal.coe_lt_coe] @[simp, norm_cast] theorem edist_le_coe {x y : α} {c : ℝ≥0} : edist x y ≤ c ↔ nndist x y ≤ c := by rw [edist_nndist, ENNReal.coe_le_coe] /-- In a pseudometric space, the extended distance is always finite -/ theorem edist_lt_top {α : Type} [PseudoMetricSpace α] (x y : α) : edist x y < ⊤ := (edist_dist x y).symm ▸ ENNReal.ofReal_lt_top /-- In a pseudometric space, the extended distance is always finite -/ theorem edist_ne_top (x y : α) : edist x y ≠ ⊤ := (edist_lt_top x y).ne /-- `nndist x x` vanishes -/ @[simp] theorem nndist_self (a : α) : nndist a a = 0 := NNReal.coe_eq_zero.1 (dist_self a) @[simp, norm_cast] theorem dist_lt_coe {x y : α} {c : ℝ≥0} : dist x y < c ↔ nndist x y < c := Iff.rfl @[simp, norm_cast] theorem dist_le_coe {x y : α} {c : ℝ≥0} : dist x y ≤ c ↔ nndist x y ≤ c := Iff.rfl @[simp] theorem edist_lt_ofReal {x y : α} {r : ℝ} : edist x y < ENNReal.ofReal r ↔ dist x y < r := by rw [edist_dist, ENNReal.ofReal_lt_ofReal_iff_of_nonneg dist_nonneg] @[simp] theorem edist_le_ofReal {x y : α} {r : ℝ} (hr : 0 ≤ r) : edist x y ≤ ENNReal.ofReal r ↔ dist x y ≤ r := by rw [edist_dist, ENNReal.ofReal_le_ofReal_iff hr] /-- Express `nndist` in terms of `dist` -/ theorem nndist_dist (x y : α) : nndist x y = Real.toNNReal (dist x y) := by rw [dist_nndist, Real.toNNReal_coe] theorem nndist_comm (x y : α) : nndist x y = nndist y x := NNReal.eq <\| dist_comm x y /-- Triangle inequality for the nonnegative distance -/ theorem nndist_triangle (x y z : α) : nndist x z ≤ nndist x y + nndist y z := dist_triangle _ _ _ theorem nndist_triangle_left (x y z : α) : nndist x y ≤ nndist z x + nndist z y := dist_triangle_left _ _ _ theorem nndist_triangle_right (x y z : α) : nndist x y ≤ nndist x z + nndist y z := dist_triangle_right _ _ _ /-- Express `dist` in terms of `edist` -/ theorem dist_edist (x y : α) : dist x y = (edist x y).toReal := by rw [edist_dist, ENNReal.toReal_ofReal dist_nonneg] namespace Metric -- instantiate pseudometric space as a topology variable {x y z : α} {δ ε ε₁ ε₂ : ℝ} {s : Set α} /-- `ball x ε` is the set of all points `y` with `dist y x < ε` -/ def ball (x : α) (ε : ℝ) : Set α := { y \| dist y x < ε } @[simp] theorem mem_ball : y ∈ ball x ε ↔ dist y x < ε := Iff.rfl theorem mem_ball' : y ∈ ball x ε ↔ dist x y < ε := by rw [dist_comm, mem_ball] theorem pos_of_mem_ball (hy : y ∈ ball x ε) : 0 < ε := dist_nonneg.trans_lt hy theorem mem_ball_self (h : 0 < ε) : x ∈ ball x ε := by rwa [mem_ball, dist_self] @[simp] theorem nonempty_ball : (ball x ε).Nonempty ↔ 0 < ε := ⟨fun ⟨_x, hx⟩ => pos_of_mem_ball hx, fun h => ⟨x, mem_ball_self h⟩⟩ @[simp] theorem ball_eq_empty : ball x ε = ∅ ↔ ε ≤ 0 := by rw [← not_nonempty_iff_eq_empty, nonempty_ball, not_lt] @[simp] theorem ball_zero : ball x 0 = ∅ := by rw [ball_eq_empty] /-- If a point belongs to an open ball, then there is a strictly smaller radius whose ball also contains it. See also `exists_lt_subset_ball`. -/ theorem exists_lt_mem_ball_of_mem_ball (h : x ∈ ball y ε) : ∃ ε' < ε, x ∈ ball y ε' := by simp only [mem_ball] at h ⊢ exact ⟨(dist x y + ε) / 2, by linarith, by linarith⟩ theorem ball_eq_ball (ε : ℝ) (x : α) : UniformSpace.ball x { p \| dist p.2 p.1 < ε } = Metric.ball x ε := rfl theorem ball_eq_ball' (ε : ℝ) (x : α) : UniformSpace.ball x { p \| dist p.1 p.2 < ε } = Metric.ball x ε := by ext simp [dist_comm, UniformSpace.ball] @[simp] theorem iUnion_ball_nat (x : α) : ⋃ n : ℕ, ball x n = univ := iUnion_eq_univ_iff.2 fun y => exists_nat_gt (dist y x) @[simp] theorem iUnion_ball_nat_succ (x : α) : ⋃ n : ℕ, ball x (n + 1) = univ := iUnion_eq_univ_iff.2 fun y => (exists_nat_gt (dist y x)).imp fun _ h => h.trans (lt_add_one _) /-- `closedBall x ε` is the set of all points `y` with `dist y x ≤ ε` -/ def closedBall (x : α) (ε : ℝ) := { y \| dist y x ≤ ε } @[simp] theorem mem_closedBall : y ∈ closedBall x ε ↔ dist y x ≤ ε := Iff.rfl theorem mem_closedBall' : y ∈ closedBall x ε ↔ dist x y ≤ ε := by rw [dist_comm, mem_closedBall] /-- `sphere x ε` is the set of all points `y` with `dist y x = ε` -/ def sphere (x : α) (ε : ℝ) := { y \| dist y x = ε } @[simp] theorem mem_sphere : y ∈ sphere x ε ↔ dist y x = ε := Iff.rfl theorem mem_sphere' : y ∈ sphere x ε ↔ dist x y = ε := by rw [dist_comm, mem_sphere] theorem ne_of_mem_sphere (h : y ∈ sphere x ε) (hε : ε ≠ 0) : y ≠ x := ne_of_mem_of_not_mem h <\| by simpa using hε.symm theorem nonneg_of_mem_sphere (hy : y ∈ sphere x ε) : 0 ≤ ε := dist_nonneg.trans_eq hy @[simp] theorem sphere_eq_empty_of_neg (hε : ε < 0) : sphere x ε = ∅ := Set.eq_empty_iff_forall_not_mem.mpr fun _y hy => (nonneg_of_mem_sphere hy).not_lt hε theorem sphere_eq_empty_of_subsingleton [Subsingleton α] (hε : ε ≠ 0) : sphere x ε = ∅ := Set.eq_empty_iff_forall_not_mem.mpr fun _ h => ne_of_mem_sphere h hε (Subsingleton.elim _ _) instance sphere_isEmpty_of_subsingleton [Subsingleton α] [NeZero ε] : IsEmpty (sphere x ε) := by rw [sphere_eq_empty_of_subsingleton (NeZero.ne ε)]; infer_instance theorem closedBall_eq_singleton_of_subsingleton [Subsingleton α] (h : 0 ≤ ε) : closedBall x ε = {x} := by ext x' simpa [Subsingleton.allEq x x'] theorem ball_eq_singleton_of_subsingleton [Subsingleton α] (h : 0 < ε) : ball x ε = {x} := by ext x' simpa [Subsingleton.allEq x x'] theorem mem_closedBall_self (h : 0 ≤ ε) : x ∈ closedBall x ε := by rwa [mem_closedBall, dist_self] @[simp] theorem nonempty_closedBall : (closedBall x ε).Nonempty ↔ 0 ≤ ε := ⟨fun ⟨_x, hx⟩ => dist_nonneg.trans hx, fun h => ⟨x, mem_closedBall_self h⟩⟩ @[simp] theorem closedBall_eq_empty : closedBall x ε = ∅ ↔ ε < 0 := by rw [← not_nonempty_iff_eq_empty, nonempty_closedBall, not_le] /-- Closed balls and spheres coincide when the radius is non-positive -/ theorem closedBall_eq_sphere_of_nonpos (hε : ε ≤ 0) : closedBall x ε = sphere x ε := Set.ext fun _ => (hε.trans dist_nonneg).le_iff_eq theorem ball_subset_closedBall : ball x ε ⊆ closedBall x ε := fun _y hy => mem_closedBall.2 (le_of_lt hy) theorem sphere_subset_closedBall : sphere x ε ⊆ closedBall x ε := fun _ => le_of_eq lemma sphere_subset_ball {r R : ℝ} (h : r < R) : sphere x r ⊆ ball x R := fun _x hx ↦ (mem_sphere.1 hx).trans_lt h theorem closedBall_disjoint_ball (h : δ + ε ≤ dist x y) : Disjoint (closedBall x δ) (ball y ε) := Set.disjoint_left.mpr fun _a ha1 ha2 => (h.trans <\| dist_triangle_left _ _ _).not_lt <\| add_lt_add_of_le_of_lt ha1 ha2 theorem ball_disjoint_closedBall (h : δ + ε ≤ dist x y) : Disjoint (ball x δ) (closedBall y ε) := (closedBall_disjoint_ball <\| by rwa [add_comm, dist_comm]).symm theorem ball_disjoint_ball (h : δ + ε ≤ dist x y) : Disjoint (ball x δ) (ball y ε) := (closedBall_disjoint_ball h).mono_left ball_subset_closedBall theorem closedBall_disjoint_closedBall (h : δ + ε < dist x y) : Disjoint (closedBall x δ) (closedBall y ε) := Set.disjoint_left.mpr fun _a ha1 ha2 => h.not_le <\| (dist_triangle_left _ _ _).trans <\| add_le_add ha1 ha2 theorem sphere_disjoint_ball : Disjoint (sphere x ε) (ball x ε) := Set.disjoint_left.mpr fun _y hy₁ hy₂ => absurd hy₁ <\| ne_of_lt hy₂ @[simp] theorem ball_union_sphere : ball x ε ∪ sphere x ε = closedBall x ε := Set.ext fun _y => (@le_iff_lt_or_eq ℝ _ _ _).symm @[simp] theorem sphere_union_ball : sphere x ε ∪ ball x ε = closedBall x ε := by rw [union_comm, ball_union_sphere] @[simp] theorem closedBall_diff_sphere : closedBall x ε \ sphere x ε = ball x ε := by rw [← ball_union_sphere, Set.union_diff_cancel_right sphere_disjoint_ball.symm.le_bot] @[simp] theorem closedBall_diff_ball : closedBall x ε \ ball x ε = sphere x ε := by rw [← ball_union_sphere, Set.union_diff_cancel_left sphere_disjoint_ball.symm.le_bot] theorem mem_ball_comm : x ∈ ball y ε ↔ y ∈ ball x ε := by rw [mem_ball', mem_ball] theorem mem_closedBall_comm : x ∈ closedBall y ε ↔ y ∈ closedBall x ε := by rw [mem_closedBall', mem_closedBall] theorem mem_sphere_comm : x ∈ sphere y ε ↔ y ∈ sphere x ε := by rw [mem_sphere', mem_sphere] @[gcongr] theorem ball_subset_ball (h : ε₁ ≤ ε₂) : ball x ε₁ ⊆ ball x ε₂ := fun _y yx => lt_of_lt_of_le (mem_ball.1 yx) h theorem closedBall_eq_bInter_ball : closedBall x ε = ⋂ δ > ε, ball x δ := by ext y; rw [mem_closedBall, ← forall_lt_iff_le', mem_iInter₂]; rfl theorem ball_subset_ball' (h : ε₁ + dist x y ≤ ε₂) : ball x ε₁ ⊆ ball y ε₂ := fun z hz => calc dist z y ≤ dist z x + dist x y := dist_triangle _ _ _ _ < ε₁ + dist x y := add_lt_add_right (mem_ball.1 hz) _ _ ≤ ε₂ := h @[gcongr] theorem closedBall_subset_closedBall (h : ε₁ ≤ ε₂) : closedBall x ε₁ ⊆ closedBall x ε₂ := fun _y (yx : _ ≤ ε₁) => le_trans yx h theorem closedBall_subset_closedBall' (h : ε₁ + dist x y ≤ ε₂) : closedBall x ε₁ ⊆ closedBall y ε₂ := fun z hz => calc dist z y ≤ dist z x + dist x y := dist_triangle _ _ _ _ ≤ ε₁ + dist x y := add_le_add_right (mem_closedBall.1 hz) _ _ ≤ ε₂ := h theorem closedBall_subset_ball (h : ε₁ < ε₂) : closedBall x ε₁ ⊆ ball x ε₂ := fun y (yh : dist y x ≤ ε₁) => lt_of_le_of_lt yh h theorem closedBall_subset_ball' (h : ε₁ + dist x y < ε₂) : closedBall x ε₁ ⊆ ball y ε₂ := fun z hz => calc dist z y ≤ dist z x + dist x y := dist_triangle _ _ _ _ ≤ ε₁ + dist x y := add_le_add_right (mem_closedBall.1 hz) _ _ < ε₂ := h theorem dist_le_add_of_nonempty_closedBall_inter_closedBall (h : (closedBall x ε₁ ∩ closedBall y ε₂).Nonempty) : dist x y ≤ ε₁ + ε₂ := let ⟨z, hz⟩ := h calc dist x y ≤ dist z x + dist z y := dist_triangle_left _ _ _ _ ≤ ε₁ + ε₂ := add_le_add hz.1 hz.2 theorem dist_lt_add_of_nonempty_closedBall_inter_ball (h : (closedBall x ε₁ ∩ ball y ε₂).Nonempty) : dist x y < ε₁ + ε₂ := let ⟨z, hz⟩ := h calc dist x y ≤ dist z x + dist z y := dist_triangle_left _ _ _ _ < ε₁ + ε₂ := add_lt_add_of_le_of_lt hz.1 hz.2 theorem dist_lt_add_of_nonempty_ball_inter_closedBall (h : (ball x ε₁ ∩ closedBall y ε₂).Nonempty) : dist x y < ε₁ + ε₂ := by rw [inter_comm] at h rw [add_comm, dist_comm] exact dist_lt_add_of_nonempty_closedBall_inter_ball h theorem dist_lt_add_of_nonempty_ball_inter_ball (h : (ball x ε₁ ∩ ball y ε₂).Nonempty) : dist x y < ε₁ + ε₂ := dist_lt_add_of_nonempty_closedBall_inter_ball <\| h.mono (inter_subset_inter ball_subset_closedBall Subset.rfl) @[simp] theorem iUnion_closedBall_nat (x : α) : ⋃ n : ℕ, closedBall x n = univ := iUnion_eq_univ_iff.2 fun y => exists_nat_ge (dist y x) theorem iUnion_inter_closedBall_nat (s : Set α) (x : α) : ⋃ n : ℕ, s ∩ closedBall x n = s := by rw [← inter_iUnion, iUnion_closedBall_nat, inter_univ] theorem ball_subset (h : dist x y ≤ ε₂ - ε₁) : ball x ε₁ ⊆ ball y ε₂ := fun z zx => by rw [← add_sub_cancel ε₁ ε₂] exact lt_of_le_of_lt (dist_triangle z x y) (add_lt_add_of_lt_of_le zx h) theorem ball_half_subset (y) (h : y ∈ ball x (ε / 2)) : ball y (ε / 2) ⊆ ball x ε := ball_subset <\| by rw [sub_self_div_two]; exact le_of_lt h theorem exists_ball_subset_ball (h : y ∈ ball x ε) : ∃ ε' > 0, ball y ε' ⊆ ball x ε := ⟨_, sub_pos.2 h, ball_subset <\| by rw [sub_sub_self]⟩ /-- If a property holds for all points in closed balls of arbitrarily large radii, then it holds for all points. -/ theorem forall_of_forall_mem_closedBall (p : α → Prop) (x : α) (H : ∃ᶠ R : ℝ in atTop, ∀ y ∈ closedBall x R, p y) (y : α) : p y := by obtain ⟨R, hR, h⟩ : ∃ R ≥ dist y x, ∀ z : α, z ∈ closedBall x R → p z := frequently_iff.1 H (Ici_mem_atTop (dist y x)) exact h _ hR /-- If a property holds for all points in balls of arbitrarily large radii, then it holds for all points. -/ theorem forall_of_forall_mem_ball (p : α → Prop) (x : α) (H : ∃ᶠ R : ℝ in atTop, ∀ y ∈ ball x R, p y) (y : α) : p y := by obtain ⟨R, hR, h⟩ : ∃ R > dist y x, ∀ z : α, z ∈ ball x R → p z := frequently_iff.1 H (Ioi_mem_atTop (dist y x)) exact h _ hR theorem isBounded_iff {s : Set α} : IsBounded s ↔ ∃ C : ℝ, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C := by rw [isBounded_def, ← Filter.mem_sets, @PseudoMetricSpace.cobounded_sets α, mem_setOf_eq, compl_compl] theorem isBounded_iff_eventually {s : Set α} : IsBounded s ↔ ∀ᶠ C in atTop, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C := isBounded_iff.trans ⟨fun ⟨C, h⟩ => eventually_atTop.2 ⟨C, fun _C' hC' _x hx _y hy => (h hx hy).trans hC'⟩, Eventually.exists⟩ theorem isBounded_iff_exists_ge {s : Set α} (c : ℝ) : IsBounded s ↔ ∃ C, c ≤ C ∧ ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C := ⟨fun h => ((eventually_ge_atTop c).and (isBounded_iff_eventually.1 h)).exists, fun h => isBounded_iff.2 <\| h.imp fun _ => And.right⟩ theorem isBounded_iff_nndist {s : Set α} : IsBounded s ↔ ∃ C : ℝ≥0, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → nndist x y ≤ C := by simp only [isBounded_iff_exists_ge 0, NNReal.exists, ← NNReal.coe_le_coe, ← dist_nndist, NNReal.coe_mk, exists_prop] theorem toUniformSpace_eq : ‹PseudoMetricSpace α›.toUniformSpace = .ofDist dist dist_self dist_comm dist_triangle := UniformSpace.ext PseudoMetricSpace.uniformity_dist theorem uniformity_basis_dist : (𝓤 α).HasBasis (fun ε : ℝ => 0 < ε) fun ε => { p : α × α \| dist p.1 p.2 < ε } := by rw [toUniformSpace_eq] exact UniformSpace.hasBasis_ofFun (exists_gt _) _ _ _ _ _ /-- Given `f : β → ℝ`, if `f` sends `{i \| p i}` to a set of positive numbers accumulating to zero, then `f i`-neighborhoods of the diagonal form a basis of `𝓤 α`. For specific bases see `uniformity_basis_dist`, `uniformity_basis_dist_inv_nat_succ`, and `uniformity_basis_dist_inv_nat_pos`. -/ protected theorem mk_uniformity_basis {β : Type} {p : β → Prop} {f : β → ℝ} (hf₀ : ∀ i, p i → 0 < f i) (hf : ∀ ⦃ε⦄, 0 < ε → ∃ i, p i ∧ f i ≤ ε) : (𝓤 α).HasBasis p fun i => { p : α × α \| dist p.1 p.2 < f i } := by refine ⟨fun s => uniformity_basis_dist.mem_iff.trans ?_⟩ constructor · rintro ⟨ε, ε₀, hε⟩ rcases hf ε₀ with ⟨i, hi, H⟩ exact ⟨i, hi, fun x (hx : _ < _) => hε <\| lt_of_lt_of_le hx H⟩ · exact fun ⟨i, hi, H⟩ => ⟨f i, hf₀ i hi, H⟩ theorem uniformity_basis_dist_rat : (𝓤 α).HasBasis (fun r : ℚ => 0 < r) fun r => { p : α × α \| dist p.1 p.2 < r } := Metric.mk_uniformity_basis (fun _ => Rat.cast_pos.2) fun _ε hε => let ⟨r, hr0, hrε⟩ := exists_rat_btwn hε ⟨r, Rat.cast_pos.1 hr0, hrε.le⟩ theorem uniformity_basis_dist_inv_nat_succ : (𝓤 α).HasBasis (fun _ => True) fun n : ℕ => { p : α × α \| dist p.1 p.2 < 1 / (↑n + 1) } := Metric.mk_uniformity_basis (fun n _ => div_pos zero_lt_one <\| Nat.cast_add_one_pos n) fun _ε ε0 => (exists_nat_one_div_lt ε0).imp fun _n hn => ⟨trivial, le_of_lt hn⟩ theorem uniformity_basis_dist_inv_nat_pos : (𝓤 α).HasBasis (fun n : ℕ => 0 < n) fun n : ℕ => { p : α × α \| dist p.1 p.2 < 1 / ↑n } := Metric.mk_uniformity_basis (fun _ hn => div_pos zero_lt_one <\| Nat.cast_pos.2 hn) fun _ ε0 => let ⟨n, hn⟩ := exists_nat_one_div_lt ε0 ⟨n + 1, Nat.succ_pos n, mod_cast hn.le⟩ theorem uniformity_basis_dist_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓤 α).HasBasis (fun _ : ℕ => True) fun n : ℕ => { p : α × α \| dist p.1 p.2 < r ^ n } := Metric.mk_uniformity_basis (fun _ _ => pow_pos h0 _) fun _ε ε0 => let ⟨n, hn⟩ := exists_pow_lt_of_lt_one ε0 h1 ⟨n, trivial, hn.le⟩ theorem uniformity_basis_dist_lt {R : ℝ} (hR : 0 < R) : (𝓤 α).HasBasis (fun r : ℝ => 0 < r ∧ r < R) fun r => { p : α × α \| dist p.1 p.2 < r } := Metric.mk_uniformity_basis (fun _ => And.left) fun r hr => ⟨min r (R / 2), ⟨lt_min hr (half_pos hR), min_lt_iff.2 <\| Or.inr (half_lt_self hR)⟩, min_le_left _ _⟩ /-- Given `f : β → ℝ`, if `f` sends `{i \| p i}` to a set of positive numbers accumulating to zero, then closed neighborhoods of the diagonal of sizes `{f i \| p i}` form a basis of `𝓤 α`. Currently we have only one specific basis `uniformity_basis_dist_le` based on this constructor. More can be easily added if needed in the future. -/ protected theorem mk_uniformity_basis_le {β : Type} {p : β → Prop} {f : β → ℝ} (hf₀ : ∀ x, p x → 0 < f x) (hf : ∀ ε, 0 < ε → ∃ x, p x ∧ f x ≤ ε) : (𝓤 α).HasBasis p fun x => { p : α × α \| dist p.1 p.2 ≤ f x } := by refine ⟨fun s => uniformity_basis_dist.mem_iff.trans ?_⟩ constructor · rintro ⟨ε, ε₀, hε⟩ rcases exists_between ε₀ with ⟨ε', hε'⟩ rcases hf ε' hε'.1 with ⟨i, hi, H⟩ exact ⟨i, hi, fun x (hx : _ ≤ _) => hε <\| lt_of_le_of_lt (le_trans hx H) hε'.2⟩ · exact fun ⟨i, hi, H⟩ => ⟨f i, hf₀ i hi, fun x (hx : _ < _) => H (mem_setOf.2 hx.le)⟩ /-- Constant size closed neighborhoods of the diagonal form a basis of the uniformity filter. -/ theorem uniformity_basis_dist_le : (𝓤 α).HasBasis ((0 : ℝ) < ·) fun ε => { p : α × α \| dist p.1 p.2 ≤ ε } := Metric.mk_uniformity_basis_le (fun _ => id) fun ε ε₀ => ⟨ε, ε₀, le_refl ε⟩ theorem uniformity_basis_dist_le_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓤 α).HasBasis (fun _ : ℕ => True) fun n : ℕ => { p : α × α \| dist p.1 p.2 ≤ r ^ n } := Metric.mk_uniformity_basis_le (fun _ _ => pow_pos h0 _) fun _ε ε0 => let ⟨n, hn⟩ := exists_pow_lt_of_lt_one ε0 h1 ⟨n, trivial, hn.le⟩ theorem mem_uniformity_dist {s : Set (α × α)} : s ∈ 𝓤 α ↔ ∃ ε > 0, ∀ ⦃a b : α⦄, dist a b < ε → (a, b) ∈ s := uniformity_basis_dist.mem_uniformity_iff /-- A constant size neighborhood of the diagonal is an entourage. -/ theorem dist_mem_uniformity {ε : ℝ} (ε0 : 0 < ε) : { p : α × α \| dist p.1 p.2 < ε } ∈ 𝓤 α := mem_uniformity_dist.2 ⟨ε, ε0, fun _ _ ↦ id⟩ theorem uniformContinuous_iff [PseudoMetricSpace β] {f : α → β} : UniformContinuous f ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃a b : α⦄, dist a b < δ → dist (f a) (f b) < ε := uniformity_basis_dist.uniformContinuous_iff uniformity_basis_dist theorem uniformContinuousOn_iff [PseudoMetricSpace β] {f : α → β} {s : Set α} : UniformContinuousOn f s ↔ ∀ ε > 0, ∃ δ > 0, ∀ x ∈ s, ∀ y ∈ s, dist x y < δ → dist (f x) (f y) < ε := Metric.uniformity_basis_dist.uniformContinuousOn_iff Metric.uniformity_basis_dist theorem uniformContinuousOn_iff_le [PseudoMetricSpace β] {f : α → β} {s : Set α} : UniformContinuousOn f s ↔ ∀ ε > 0, ∃ δ > 0, ∀ x ∈ s, ∀ y ∈ s, dist x y ≤ δ → dist (f x) (f y) ≤ ε := Metric.uniformity_basis_dist_le.uniformContinuousOn_iff Metric.uniformity_basis_dist_le theorem nhds_basis_ball : (𝓝 x).HasBasis (0 < ·) (ball x) := nhds_basis_uniformity uniformity_basis_dist theorem mem_nhds_iff : s ∈ 𝓝 x ↔ ∃ ε > 0, ball x ε ⊆ s := nhds_basis_ball.mem_iff theorem eventually_nhds_iff {p : α → Prop} : (∀ᶠ y in 𝓝 x, p y) ↔ ∃ ε > 0, ∀ ⦃y⦄, dist y x < ε → p y := mem_nhds_iff theorem eventually_nhds_iff_ball {p : α → Prop} : (∀ᶠ y in 𝓝 x, p y) ↔ ∃ ε > 0, ∀ y ∈ ball x ε, p y := mem_nhds_iff /-- A version of `Filter.eventually_prod_iff` where the first filter consists of neighborhoods in a pseudo-metric space. -/ theorem eventually_nhds_prod_iff {f : Filter ι} {x₀ : α} {p : α × ι → Prop} : (∀ᶠ x in 𝓝 x₀ ×ˢ f, p x) ↔ ∃ ε > (0 : ℝ), ∃ pa : ι → Prop, (∀ᶠ i in f, pa i) ∧ ∀ ⦃x⦄, dist x x₀ < ε → ∀ ⦃i⦄, pa i → p (x, i) := by refine (nhds_basis_ball.prod f.basis_sets).eventually_iff.trans ?_ simp only [Prod.exists, forall_prod_set, id, mem_ball, and_assoc, exists_and_left, and_imp] rfl /-- A version of `Filter.eventually_prod_iff` where the second filter consists of neighborhoods in a pseudo-metric space. -/ theorem eventually_prod_nhds_iff {f : Filter ι} {x₀ : α} {p : ι × α → Prop} : (∀ᶠ x in f ×ˢ 𝓝 x₀, p x) ↔ ∃ pa : ι → Prop, (∀ᶠ i in f, pa i) ∧ ∃ ε > 0, ∀ ⦃i⦄, pa i → ∀ ⦃x⦄, dist x x₀ < ε → p (i, x) := by rw [eventually_swap_iff, Metric.eventually_nhds_prod_iff] constructor <;> · rintro ⟨a1, a2, a3, a4, a5⟩ exact ⟨a3, a4, a1, a2, fun _ b1 b2 b3 => a5 b3 b1⟩ theorem nhds_basis_closedBall : (𝓝 x).HasBasis (fun ε : ℝ => 0 < ε) (closedBall x) := nhds_basis_uniformity uniformity_basis_dist_le theorem nhds_basis_ball_inv_nat_succ : (𝓝 x).HasBasis (fun _ => True) fun n : ℕ => ball x (1 / (↑n + 1)) := nhds_basis_uniformity uniformity_basis_dist_inv_nat_succ theorem nhds_basis_ball_inv_nat_pos : (𝓝 x).HasBasis (fun n => 0 < n) fun n : ℕ => ball x (1 / ↑n) := nhds_basis_uniformity uniformity_basis_dist_inv_nat_pos theorem nhds_basis_ball_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓝 x).HasBasis (fun _ => True) fun n : ℕ => ball x (r ^ n) := nhds_basis_uniformity (uniformity_basis_dist_pow h0 h1) theorem nhds_basis_closedBall_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓝 x).HasBasis (fun _ => True) fun n : ℕ => closedBall x (r ^ n) := nhds_basis_uniformity (uniformity_basis_dist_le_pow h0 h1) theorem isOpen_iff : IsOpen s ↔ ∀ x ∈ s, ∃ ε > 0, ball x ε ⊆ s := by simp only [isOpen_iff_mem_nhds, mem_nhds_iff] @[simp] theorem isOpen_ball : IsOpen (ball x ε) := isOpen_iff.2 fun _ => exists_ball_subset_ball theorem ball_mem_nhds (x : α) {ε : ℝ} (ε0 : 0 < ε) : ball x ε ∈ 𝓝 x := isOpen_ball.mem_nhds (mem_ball_self ε0) theorem closedBall_mem_nhds (x : α) {ε : ℝ} (ε0 : 0 < ε) : closedBall x ε ∈ 𝓝 x := mem_of_superset (ball_mem_nhds x ε0) ball_subset_closedBall theorem closedBall_mem_nhds_of_mem {x c : α} {ε : ℝ} (h : x ∈ ball c ε) : closedBall c ε ∈ 𝓝 x := mem_of_superset (isOpen_ball.mem_nhds h) ball_subset_closedBall theorem nhdsWithin_basis_ball {s : Set α} : (𝓝[s] x).HasBasis (fun ε : ℝ => 0 < ε) fun ε => ball x ε ∩ s := nhdsWithin_hasBasis nhds_basis_ball s theorem mem_nhdsWithin_iff {t : Set α} : s ∈ 𝓝[t] x ↔ ∃ ε > 0, ball x ε ∩ t ⊆ s := nhdsWithin_basis_ball.mem_iff theorem tendsto_nhdsWithin_nhdsWithin [PseudoMetricSpace β] {t : Set β} {f : α → β} {a b} : Tendsto f (𝓝[s] a) (𝓝[t] b) ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, x ∈ s → dist x a < δ → f x ∈ t ∧ dist (f x) b < ε := (nhdsWithin_basis_ball.tendsto_iff nhdsWithin_basis_ball).trans <\| by simp only [inter_comm _ s, inter_comm _ t, mem_inter_iff, and_imp, gt_iff_lt, mem_ball] theorem tendsto_nhdsWithin_nhds [PseudoMetricSpace β] {f : α → β} {a b} : Tendsto f (𝓝[s] a) (𝓝 b) ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, x ∈ s → dist x a < δ → dist (f x) b < ε := by rw [← nhdsWithin_univ b, tendsto_nhdsWithin_nhdsWithin] simp only [mem_univ, true_and] theorem tendsto_nhds_nhds [PseudoMetricSpace β] {f : α → β} {a b} : Tendsto f (𝓝 a) (𝓝 b) ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, dist x a < δ → dist (f x) b < ε := nhds_basis_ball.tendsto_iff nhds_basis_ball theorem continuousAt_iff [PseudoMetricSpace β] {f : α → β} {a : α} : ContinuousAt f a ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, dist x a < δ → dist (f x) (f a) < ε := by rw [ContinuousAt, tendsto_nhds_nhds] theorem continuousWithinAt_iff [PseudoMetricSpace β] {f : α → β} {a : α} {s : Set α} : ContinuousWithinAt f s a ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, x ∈ s → dist x a < δ → dist (f x) (f a) < ε := by rw [ContinuousWithinAt, tendsto_nhdsWithin_nhds] theorem continuousOn_iff [PseudoMetricSpace β] {f : α → β} {s : Set α} : ContinuousOn f s ↔ ∀ b ∈ s, ∀ ε > 0, ∃ δ > 0, ∀ a ∈ s, dist a b < δ → dist (f a) (f b) < ε := by simp [ContinuousOn, continuousWithinAt_iff] theorem continuous_iff [PseudoMetricSpace β] {f : α → β} : Continuous f ↔ ∀ b, ∀ ε > 0, ∃ δ > 0, ∀ a, dist a b < δ → dist (f a) (f b) < ε := continuous_iff_continuousAt.trans <\| forall_congr' fun _ => tendsto_nhds_nhds theorem tendsto_nhds {f : Filter β} {u : β → α} {a : α} : Tendsto u f (𝓝 a) ↔ ∀ ε > 0, ∀ᶠ x in f, dist (u x) a < ε := nhds_basis_ball.tendsto_right_iff theorem continuousAt_iff' [TopologicalSpace β] {f : β → α} {b : β} : ContinuousAt f b ↔ ∀ ε > 0, ∀ᶠ x in 𝓝 b, dist (f x) (f b) < ε := by rw [ContinuousAt, tendsto_nhds] theorem continuousWithinAt_iff' [TopologicalSpace β] {f : β → α} {b : β} {s : Set β} : ContinuousWithinAt f s b ↔ ∀ ε > 0, ∀ᶠ x in 𝓝[s] b, dist (f x) (f b) < ε := by rw [ContinuousWithinAt, tendsto_nhds] theorem continuousOn_iff' [TopologicalSpace β] {f : β → α} {s : Set β} : ContinuousOn f s ↔ ∀ b ∈ s, ∀ ε > 0, ∀ᶠ x in 𝓝[s] b, dist (f x) (f b) < ε := by simp [ContinuousOn, continuousWithinAt_iff'] theorem continuous_iff' [TopologicalSpace β] {f : β → α} : Continuous f ↔ ∀ (a), ∀ ε > 0, ∀ᶠ x in 𝓝 a, dist (f x) (f a) < ε := continuous_iff_continuousAt.trans <\| forall_congr' fun _ => tendsto_nhds theorem tendsto_atTop [Nonempty β] [SemilatticeSup β] {u : β → α} {a : α} : Tendsto u atTop (𝓝 a) ↔ ∀ ε > 0, ∃ N, ∀ n ≥ N, dist (u n) a < ε := (atTop_basis.tendsto_iff nhds_basis_ball).trans <\| by simp only [true_and, mem_ball, mem_Ici] /-- A variant of `tendsto_atTop` that uses `∃ N, ∀ n > N, ...` rather than `∃ N, ∀ n ≥ N, ...` -/ theorem tendsto_atTop' [Nonempty β] [SemilatticeSup β] [NoMaxOrder β] {u : β → α} {a : α} : Tendsto u atTop (𝓝 a) ↔ ∀ ε > 0, ∃ N, ∀ n > N, dist (u n) a < ε := (atTop_basis_Ioi.tendsto_iff nhds_basis_ball).trans <\| by simp only [true_and, gt_iff_lt, mem_Ioi, mem_ball] theorem isOpen_singleton_iff {α : Type} [PseudoMetricSpace α] {x : α} : IsOpen ({x} : Set α) ↔ ∃ ε > 0, ∀ y, dist y x < ε → y = x := by simp [isOpen_iff, subset_singleton_iff, mem_ball] theorem _root_.Dense.exists_dist_lt {s : Set α} (hs : Dense s) (x : α) {ε : ℝ} (hε : 0 < ε) : ∃ y ∈ s, dist x y < ε := by have : (ball x ε).Nonempty := by simp [hε] simpa only [mem_ball'] using hs.exists_mem_open isOpen_ball this nonrec theorem _root_.DenseRange.exists_dist_lt {β : Type*} {f : β → α} (hf : DenseRange f) (x : α) {ε : ℝ} (hε : 0 < ε) : ∃ y, dist x (f y) < ε := exists_range_iff.1 (hf.exists_dist_lt x hε) /-- (Pseudo) metric space has discrete `UniformSpace` structure iff the distances between distinct points are uniformly bounded away from zero. -/ protected lemma uniformSpace_eq_bot : ‹PseudoMetricSpace α›.toUniformSpace = ⊥ ↔ ∃ r : ℝ, 0 < r ∧ Pairwise (r ≤ dist · · : α → α → Prop) := by simp only [uniformity_basis_dist.uniformSpace_eq_bot, mem_setOf_eq, not_lt] end Metric open Metric /-- If the distances between distinct points in a (pseudo) metric space are uniformly bounded away from zero, then the space has discrete topology. -/ lemma DiscreteTopology.of_forall_le_dist {α} [PseudoMetricSpace α] {r : ℝ} (hpos : 0 < r) (hr : Pairwise (r ≤ dist · · : α → α → Prop)) : DiscreteTopology α := ⟨by rw [Metric.uniformSpace_eq_bot.2 ⟨r, hpos, hr⟩, UniformSpace.toTopologicalSpace_bot]⟩ /- Instantiate a pseudometric space as a pseudoemetric space. Before we can state the instance, we need to show that the uniform structure coming from the edistance and the distance coincide. -/ theorem Metric.uniformity_edist_aux {α} (d : α → α → ℝ≥0) : ⨅ ε > (0 : ℝ), 𝓟 { p : α × α \| ↑(d p.1 p.2) < ε } = ⨅ ε > (0 : ℝ≥0∞), 𝓟 { p : α × α \| ↑(d p.1 p.2) < ε } := by simp only [le_antisymm_iff, le_iInf_iff, le_principal_iff] refine ⟨fun ε hε => ?_, fun ε hε => ?_⟩ · rcases ENNReal.lt_iff_exists_nnreal_btwn.1 hε with ⟨ε', ε'0, ε'ε⟩ refine mem_iInf_of_mem (ε' : ℝ) (mem_iInf_of_mem (ENNReal.coe_pos.1 ε'0) ?_) exact fun x hx => lt_trans (ENNReal.coe_lt_coe.2 hx) ε'ε · lift ε to ℝ≥0 using le_of_lt hε refine mem_iInf_of_mem (ε : ℝ≥0∞) (mem_iInf_of_mem (ENNReal.coe_pos.2 hε) ?_) exact fun _ => ENNReal.coe_lt_coe.1 theorem Metric.uniformity_edist : 𝓤 α = ⨅ ε > 0, 𝓟 { p : α × α \| edist p.1 p.2 < ε } := by simp only [PseudoMetricSpace.uniformity_dist, dist_nndist, edist_nndist, Metric.uniformity_edist_aux] -- see Note [lower instance priority] /-- A pseudometric space induces a pseudoemetric space -/ instance (priority := 100) PseudoMetricSpace.toPseudoEMetricSpace : PseudoEMetricSpace α := { ‹PseudoMetricSpace α› with edist_self := by simp [edist_dist] edist_comm := fun _ _ => by simp only [edist_dist, dist_comm] edist_triangle := fun x y z => by simp only [edist_dist, ← ENNReal.ofReal_add, dist_nonneg] rw [ENNReal.ofReal_le_ofReal_iff _] · exact dist_triangle _ _ _ · simpa using add_le_add (dist_nonneg : 0 ≤ dist x y) dist_nonneg uniformity_edist := Metric.uniformity_edist } /-- In a pseudometric space, an open ball of infinite radius is the whole space -/ theorem Metric.eball_top_eq_univ (x : α) : EMetric.ball x ∞ = Set.univ := Set.eq_univ_iff_forall.mpr fun y => edist_lt_top y x /-- Balls defined using the distance or the edistance coincide -/ @[simp] theorem Metric.emetric_ball {x : α} {ε : ℝ} : EMetric.ball x (ENNReal.ofReal ε) = ball x ε := by ext y simp only [EMetric.mem_ball, mem_ball, edist_dist] exact ENNReal.ofReal_lt_ofReal_iff_of_nonneg dist_nonneg /-- Balls defined using the distance or the edistance coincide -/ @[simp] theorem Metric.emetric_ball_nnreal {x : α} {ε : ℝ≥0} : EMetric.ball x ε = ball x ε := by rw [← Metric.emetric_ball] simp /-- Closed balls defined using the distance or the edistance coincide -/ theorem Metric.emetric_closedBall {x : α} {ε : ℝ} (h : 0 ≤ ε) : EMetric.closedBall x (ENNReal.ofReal ε) = closedBall x ε := by ext y; simp [edist_le_ofReal h] /-- Closed balls defined using the distance or the edistance coincide -/ @[simp] theorem Metric.emetric_closedBall_nnreal {x : α} {ε : ℝ≥0} : EMetric.closedBall x ε = closedBall x ε := by rw [← Metric.emetric_closedBall ε.coe_nonneg, ENNReal.ofReal_coe_nnreal] @[simp] theorem Metric.emetric_ball_top (x : α) : EMetric.ball x ⊤ = univ := eq_univ_of_forall fun _ => edist_lt_top _ _ /-- Build a new pseudometric space from an old one where the bundled uniform structure is provably (but typically non-definitionaly) equal to some given uniform structure. See Note [forgetful inheritance]. See Note [reducible non-instances]. -/ abbrev PseudoMetricSpace.replaceUniformity {α} [U : UniformSpace α] (m : PseudoMetricSpace α) (H : 𝓤[U] = 𝓤[PseudoEMetricSpace.toUniformSpace]) : PseudoMetricSpace α := { m with toUniformSpace := U uniformity_dist := H.trans PseudoMetricSpace.uniformity_dist } theorem PseudoMetricSpace.replaceUniformity_eq {α} [U : UniformSpace α] (m : PseudoMetricSpace α) (H : 𝓤[U] = 𝓤[PseudoEMetricSpace.toUniformSpace]) : m.replaceUniformity H = m := by ext rfl -- ensure that the bornology is unchanged when replacing the uniformity. example {α} [U : UniformSpace α] (m : PseudoMetricSpace α) (H : 𝓤[U] = 𝓤[PseudoEMetricSpace.toUniformSpace]) : (PseudoMetricSpace.replaceUniformity m H).toBornology = m.toBornology := by with_reducible_and_instances rfl /-- Build a new pseudo metric space from an old one where the bundled topological structure is provably (but typically non-definitionaly) equal to some given topological structure. See Note [forgetful inheritance]. See Note [reducible non-instances]. -/ abbrev PseudoMetricSpace.replaceTopology {γ} [U : TopologicalSpace γ] (m : PseudoMetricSpace γ) (H : U = m.toUniformSpace.toTopologicalSpace) : PseudoMetricSpace γ := @PseudoMetricSpace.replaceUniformity γ (m.toUniformSpace.replaceTopology H) m rfl theorem PseudoMetricSpace.replaceTopology_eq {γ} [U : TopologicalSpace γ] (m : PseudoMetricSpace γ) (H : U = m.toUniformSpace.toTopologicalSpace) : m.replaceTopology H = m := by ext rfl /-- One gets a pseudometric space from an emetric space if the edistance is everywhere finite, by pushing the edistance to reals. We set it up so that the edist and the uniformity are defeq in the pseudometric space and the pseudoemetric space. In this definition, the distance is given separately, to be able to prescribe some expression which is not defeq to the push-forward of the edistance to reals. See note [reducible non-instances]. -/ abbrev PseudoEMetricSpace.toPseudoMetricSpaceOfDist {α : Type u} [e : PseudoEMetricSpace α] (dist : α → α → ℝ) (edist_ne_top : ∀ x y : α, edist x y ≠ ⊤) (h : ∀ x y, dist x y = ENNReal.toReal (edist x y)) : PseudoMetricSpace α where dist := dist dist_self x := by simp [h] dist_comm x y := by simp [h, edist_comm] dist_triangle x y z := by simp only [h] exact ENNReal.toReal_le_add (edist_triangle _ _ _) (edist_ne_top _ _) (edist_ne_top _ _) edist := edist edist_dist _ _ := by simp only [h, ENNReal.ofReal_toReal (edist_ne_top _ _)] toUniformSpace := e.toUniformSpace uniformity_dist := e.uniformity_edist.trans <\| by simpa only [ENNReal.coe_toNNReal (edist_ne_top _ _), h] using (Metric.uniformity_edist_aux fun x y : α => (edist x y).toNNReal).symm /-- One gets a pseudometric space from an emetric space if the edistance is everywhere finite, by pushing the edistance to reals. We set it up so that the edist and the uniformity are defeq in the pseudometric space and the emetric space. -/ abbrev PseudoEMetricSpace.toPseudoMetricSpace {α : Type u} [PseudoEMetricSpace α] (h : ∀ x y : α, edist x y ≠ ⊤) : PseudoMetricSpace α := PseudoEMetricSpace.toPseudoMetricSpaceOfDist (fun x y => ENNReal.toReal (edist x y)) h fun _ _ => rfl /-- Build a new pseudometric space from an old one where the bundled bornology structure is provably (but typically non-definitionaly) equal to some given bornology structure. See Note [forgetful inheritance]. See Note [reducible non-instances]. -/ abbrev PseudoMetricSpace.replaceBornology {α} [B : Bornology α] (m : PseudoMetricSpace α) (H : ∀ s, @IsBounded _ B s ↔ @IsBounded _ PseudoMetricSpace.toBornology s) : PseudoMetricSpace α := { m with toBornology := B cobounded_sets := Set.ext <\| compl_surjective.forall.2 fun s => (H s).trans <\| by rw [isBounded_iff, mem_setOf_eq, compl_compl] } theorem PseudoMetricSpace.replaceBornology_eq {α} [m : PseudoMetricSpace α] [B : Bornology α] (H : ∀ s, @IsBounded _ B s ↔ @IsBounded _ PseudoMetricSpace.toBornology s) : PseudoMetricSpace.replaceBornology _ H = m := by ext rfl -- ensure that the uniformity is unchanged when replacing the bornology. example {α} [B : Bornology α] (m : PseudoMetricSpace α) (H : ∀ s, @IsBounded _ B s ↔ @IsBounded _ PseudoMetricSpace.toBornology s) : (PseudoMetricSpace.replaceBornology m H).toUniformSpace = m.toUniformSpace := by with_reducible_and_instances rfl section Real /-- Instantiate the reals as a pseudometric space. -/ instance Real.pseudoMetricSpace : PseudoMetricSpace ℝ where dist x y := \|x - y\| dist_self := by simp [abs_zero] dist_comm _ _ := abs_sub_comm _ _ dist_triangle _ _ _ := abs_sub_le _ _ _ theorem Real.dist_eq (x y : ℝ) : dist x y = \|x - y\| := rfl theorem Real.nndist_eq (x y : ℝ) : nndist x y = Real.nnabs (x - y) := rfl theorem Real.nndist_eq' (x y : ℝ) : nndist x y = Real.nnabs (y - x) := nndist_comm _ _ theorem Real.dist_0_eq_abs (x : ℝ) : dist x 0 = \|x\| := by simp [Real.dist_eq] theorem Real.sub_le_dist (x y : ℝ) : x - y ≤ dist x y := by rw [Real.dist_eq, le_abs] exact Or.inl (le_refl _) theorem Real.ball_eq_Ioo (x r : ℝ) : ball x r = Ioo (x - r) (x + r) := Set.ext fun y => by rw [mem_ball, dist_comm, Real.dist_eq, abs_sub_lt_iff, mem_Ioo, ← sub_lt_iff_lt_add', sub_lt_comm] theorem Real.closedBall_eq_Icc {x r : ℝ} : closedBall x r = Icc (x - r) (x + r) := by ext y rw [mem_closedBall, dist_comm, Real.dist_eq, abs_sub_le_iff, mem_Icc, ← sub_le_iff_le_add', sub_le_comm] theorem Real.Ioo_eq_ball (x y : ℝ) : Ioo x y = ball ((x + y) / 2) ((y - x) / 2) := by rw [Real.ball_eq_Ioo, ← sub_div, add_comm, ← sub_add, add_sub_cancel_left, add_self_div_two, ← add_div, add_assoc, add_sub_cancel, add_self_div_two] theorem Real.Icc_eq_closedBall (x y : ℝ) : Icc x y = closedBall ((x + y) / 2) ((y - x) / 2) := by rw [Real.closedBall_eq_Icc, ← sub_div, add_comm, ← sub_add, add_sub_cancel_left, add_self_div_two, ← add_div, add_assoc, add_sub_cancel, add_self_div_two] theorem Metric.uniformity_eq_comap_nhds_zero : 𝓤 α = comap (fun p : α × α => dist p.1 p.2) (𝓝 (0 : ℝ)) := by ext s simp only [mem_uniformity_dist, (nhds_basis_ball.comap _).mem_iff] simp [subset_def, Real.dist_0_eq_abs] theorem tendsto_uniformity_iff_dist_tendsto_zero {f : ι → α × α} {p : Filter ι} : Tendsto f p (𝓤 α) ↔ Tendsto (fun x => dist (f x).1 (f x).2) p (𝓝 0) := by rw [Metric.uniformity_eq_comap_nhds_zero, tendsto_comap_iff, Function.comp_def] theorem Filter.Tendsto.congr_dist {f₁ f₂ : ι → α} {p : Filter ι} {a : α} (h₁ : Tendsto f₁ p (𝓝 a)) (h : Tendsto (fun x => dist (f₁ x) (f₂ x)) p (𝓝 0)) : Tendsto f₂ p (𝓝 a) := h₁.congr_uniformity <\| tendsto_uniformity_iff_dist_tendsto_zero.2 h alias tendsto_of_tendsto_of_dist := Filter.Tendsto.congr_dist theorem tendsto_iff_of_dist {f₁ f₂ : ι → α} {p : Filter ι} {a : α} (h : Tendsto (fun x => dist (f₁ x) (f₂ x)) p (𝓝 0)) : Tendsto f₁ p (𝓝 a) ↔ Tendsto f₂ p (𝓝 a) := Uniform.tendsto_congr <\| tendsto_uniformity_iff_dist_tendsto_zero.2 h end Real theorem PseudoMetricSpace.dist_eq_of_dist_zero (x : α) {y z : α} (h : dist y z = 0) : dist x y = dist x z := dist_comm y x ▸ dist_comm z x ▸ sub_eq_zero.1 (abs_nonpos_iff.1 (h ▸ abs_dist_sub_le y z x)) theorem dist_dist_dist_le_left (x y z : α) : dist (dist x z) (dist y z) ≤ dist x y := abs_dist_sub_le .. theorem dist_dist_dist_le_right (x y z : α) : dist (dist x y) (dist x z) ≤ dist y z := by simpa only [dist_comm x] using dist_dist_dist_le_left y z x theorem dist_dist_dist_le (x y x' y' : α) : dist (dist x y) (dist x' y') ≤ dist x x' + dist y y' := (dist_triangle _ _ _).trans <\| add_le_add (dist_dist_dist_le_left _ _ _) (dist_dist_dist_le_right _ _ _) theorem nhds_comap_dist (a : α) : ((𝓝 (0 : ℝ)).comap (dist · a)) = 𝓝 a := by simp only [@nhds_eq_comap_uniformity α, Metric.uniformity_eq_comap_nhds_zero, comap_comap, Function.comp_def, dist_comm] theorem tendsto_iff_dist_tendsto_zero {f : β → α} {x : Filter β} {a : α} : Tendsto f x (𝓝 a) ↔ Tendsto (fun b => dist (f b) a) x (𝓝 0) := by rw [← nhds_comap_dist a, tendsto_comap_iff, Function.comp_def] namespace Metric variable {x y z : α} {ε ε₁ ε₂ : ℝ} {s : Set α} theorem ball_subset_interior_closedBall : ball x ε ⊆ interior (closedBall x ε) := interior_maximal ball_subset_closedBall isOpen_ball /-- ε-characterization of the closure in pseudometric spaces -/ theorem mem_closure_iff {s : Set α} {a : α} : a ∈ closure s ↔ ∀ ε > 0, ∃ b ∈ s, dist a b < ε := (mem_closure_iff_nhds_basis nhds_basis_ball).trans <\| by simp only [mem_ball, dist_comm] theorem mem_closure_range_iff {e : β → α} {a : α} : a ∈ closure (range e) ↔ ∀ ε > 0, ∃ k : β, dist a (e k) < ε := by simp only [mem_closure_iff, exists_range_iff] theorem mem_closure_range_iff_nat {e : β → α} {a : α} : a ∈ closure (range e) ↔ ∀ n : ℕ, ∃ k : β, dist a (e k) < 1 / ((n : ℝ) + 1) := (mem_closure_iff_nhds_basis nhds_basis_ball_inv_nat_succ).trans <\| by simp only [mem_ball, dist_comm, exists_range_iff, forall_const] theorem mem_of_closed' {s : Set α} (hs : IsClosed s) {a : α} : a ∈ s ↔ ∀ ε > 0, ∃ b ∈ s, dist a b < ε := by simpa only [hs.closure_eq] using @mem_closure_iff _ _ s a theorem dense_iff {s : Set α} : Dense s ↔ ∀ x, ∀ r > 0, (ball x r ∩ s).Nonempty := forall_congr' fun x => by simp only [mem_closure_iff, Set.Nonempty, exists_prop, mem_inter_iff, mem_ball', and_comm] theorem dense_iff_iUnion_ball (s : Set α) : Dense s ↔ ∀ r > 0, ⋃ c ∈ s, ball c r = univ := by simp_rw [eq_univ_iff_forall, mem_iUnion, exists_prop, mem_ball, Dense, mem_closure_iff, forall_comm (α := α)] theorem denseRange_iff {f : β → α} : DenseRange f ↔ ∀ x, ∀ r > 0, ∃ y, dist x (f y) < r := forall_congr' fun x => by simp only [mem_closure_iff, exists_range_iff]	end Metric open Additive Multiplicative	Mathlib/Topology/MetricSpace/Pseudo/Defs.lean	1,158	1,162
/- Copyright (c) 2021 David Wärn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: David Wärn, Antoine Labelle, Rémi Bottinelli -/ import Mathlib.Combinatorics.Quiver.Path import Mathlib.Combinatorics.Quiver.Push /-! ## Symmetric quivers and arrow reversal This file contains constructions related to symmetric quivers: * `Symmetrify V` adds formal inverses to each arrow of `V`. * `HasReverse` is the class of quivers where each arrow has an assigned formal inverse. * `HasInvolutiveReverse` extends `HasReverse` by requiring that the reverse of the reverse is equal to the original arrow. * `Prefunctor.PreserveReverse` is the class of prefunctors mapping reverses to reverses. * `Symmetrify.of`, `Symmetrify.lift`, and the associated lemmas witness the universal property of `Symmetrify`. -/ universe v u w v' namespace Quiver /-- A type synonym for the symmetrized quiver (with an arrow both ways for each original arrow). NB: this does not work for `Prop`-valued quivers. It requires `[Quiver.{v+1} V]`. -/ def Symmetrify (V : Type) := V instance symmetrifyQuiver (V : Type u) [Quiver V] : Quiver (Symmetrify V) := ⟨fun a b : V ↦ (a ⟶ b) ⊕ (b ⟶ a)⟩ variable (U V W : Type) [Quiver.{u + 1} U] [Quiver.{v + 1} V] [Quiver.{w + 1} W] /-- A quiver `HasReverse` if we can reverse an arrow `p` from `a` to `b` to get an arrow `p.reverse` from `b` to `a`. -/ class HasReverse where /-- the map which sends an arrow to its reverse -/ reverse' : ∀ {a b : V}, (a ⟶ b) → (b ⟶ a) /-- Reverse the direction of an arrow. -/ def reverse {V} [Quiver.{v + 1} V] [HasReverse V] {a b : V} : (a ⟶ b) → (b ⟶ a) := HasReverse.reverse' /-- A quiver `HasInvolutiveReverse` if reversing twice is the identity. -/ class HasInvolutiveReverse extends HasReverse V where /-- `reverse` is involutive -/ inv' : ∀ {a b : V} (f : a ⟶ b), reverse (reverse f) = f variable {U V W} @[simp] theorem reverse_reverse [h : HasInvolutiveReverse V] {a b : V} (f : a ⟶ b) : reverse (reverse f) = f := by apply h.inv' @[simp] theorem reverse_inj [h : HasInvolutiveReverse V] {a b : V} (f g : a ⟶ b) : reverse f = reverse g ↔ f = g := by constructor · rintro h simpa using congr_arg Quiver.reverse h · rintro h congr theorem eq_reverse_iff [h : HasInvolutiveReverse V] {a b : V} (f : a ⟶ b) (g : b ⟶ a) : f = reverse g ↔ reverse f = g := by rw [← reverse_inj, reverse_reverse] section MapReverse variable [HasReverse U] [HasReverse V] [HasReverse W] /-- A prefunctor preserving reversal of arrows -/	class _root_.Prefunctor.MapReverse (φ : U ⥤q V) : Prop where /-- The image of a reverse is the reverse of the image. -/ map_reverse' : ∀ {u v : U} (e : u ⟶ v), φ.map (reverse e) = reverse (φ.map e)	Mathlib/Combinatorics/Quiver/Symmetric.lean	75	77
/- Copyright (c) 2019 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison, Justus Springer -/ import Mathlib.Topology.Category.TopCat.OpenNhds import Mathlib.Topology.Sheaves.SheafCondition.UniqueGluing /-! # Stalks For a presheaf `F` on a topological space `X`, valued in some category `C`, the stalk of `F` at the point `x : X` is defined as the colimit of the composition of the inclusion of categories `(OpenNhds x)ᵒᵖ ⥤ (Opens X)ᵒᵖ` and the functor `F : (Opens X)ᵒᵖ ⥤ C`. For an open neighborhood `U` of `x`, we define the map `F.germ x : F.obj (op U) ⟶ F.stalk x` as the canonical morphism into this colimit. Taking stalks is functorial: For every point `x : X` we define a functor `stalkFunctor C x`, sending presheaves on `X` to objects of `C`. Furthermore, for a map `f : X ⟶ Y` between topological spaces, we define `stalkPushforward` as the induced map on the stalks `(f _* ℱ).stalk (f x) ⟶ ℱ.stalk x`. Some lemmas about stalks and germs only hold for certain classes of concrete categories. A basic property of forgetful functors of categories of algebraic structures (like `MonCat`, `CommRingCat`,...) is that they preserve filtered colimits. Since stalks are filtered colimits, this ensures that the stalks of presheaves valued in these categories behave exactly as for `Type`-valued presheaves. For example, in `germ_exist` we prove that in such a category, every element of the stalk is the germ of a section. Furthermore, if we require the forgetful functor to reflect isomorphisms and preserve limits (as is the case for most algebraic structures), we have access to the unique gluing API and can prove further properties. Most notably, in `is_iso_iff_stalk_functor_map_iso`, we prove that in such a category, a morphism of sheaves is an isomorphism if and only if all of its stalk maps are isomorphisms. See also the definition of "algebraic structures" in the stacks project: https://stacks.math.columbia.edu/tag/007L -/ assert_not_exists OrderedCommMonoid noncomputable section universe v u v' u' open CategoryTheory open TopCat open CategoryTheory.Limits open TopologicalSpace Topology open Opposite open scoped AlgebraicGeometry variable {C : Type u} [Category.{v} C] variable [HasColimits.{v} C] variable {X Y Z : TopCat.{v}} namespace TopCat.Presheaf variable (C) in /-- Stalks are functorial with respect to morphisms of presheaves over a fixed `X`. -/ def stalkFunctor (x : X) : X.Presheaf C ⥤ C := (whiskeringLeft _ _ C).obj (OpenNhds.inclusion x).op ⋙ colim /-- The stalk of a presheaf `F` at a point `x` is calculated as the colimit of the functor nbhds x ⥤ opens F.X ⥤ C -/ def stalk (ℱ : X.Presheaf C) (x : X) : C := (stalkFunctor C x).obj ℱ -- -- colimit ((open_nhds.inclusion x).op ⋙ ℱ) @[simp] theorem stalkFunctor_obj (ℱ : X.Presheaf C) (x : X) : (stalkFunctor C x).obj ℱ = ℱ.stalk x := rfl /-- The germ of a section of a presheaf over an open at a point of that open. -/ def germ (F : X.Presheaf C) (U : Opens X) (x : X) (hx : x ∈ U) : F.obj (op U) ⟶ stalk F x := colimit.ι ((OpenNhds.inclusion x).op ⋙ F) (op ⟨U, hx⟩) /-- The germ of a global section of a presheaf at a point. -/ def Γgerm (F : X.Presheaf C) (x : X) : F.obj (op ⊤) ⟶ stalk F x := F.germ ⊤ x True.intro @[reassoc] theorem germ_res (F : X.Presheaf C) {U V : Opens X} (i : U ⟶ V) (x : X) (hx : x ∈ U) : F.map i.op ≫ F.germ U x hx = F.germ V x (i.le hx) := let i' : (⟨U, hx⟩ : OpenNhds x) ⟶ ⟨V, i.le hx⟩ := i colimit.w ((OpenNhds.inclusion x).op ⋙ F) i'.op /-- A variant of `germ_res` with `op V ⟶ op U` so that the LHS is more general and simp fires more easier. -/ @[reassoc (attr := simp)] theorem germ_res' (F : X.Presheaf C) {U V : Opens X} (i : op V ⟶ op U) (x : X) (hx : x ∈ U) : F.map i ≫ F.germ U x hx = F.germ V x (i.unop.le hx) := let i' : (⟨U, hx⟩ : OpenNhds x) ⟶ ⟨V, i.unop.le hx⟩ := i.unop colimit.w ((OpenNhds.inclusion x).op ⋙ F) i'.op @[reassoc] lemma map_germ_eq_Γgerm (F : X.Presheaf C) {U : Opens X} {i : U ⟶ ⊤} (x : X) (hx : x ∈ U) : F.map i.op ≫ F.germ U x hx = F.Γgerm x := germ_res F i x hx variable {FC : C → C → Type} {CC : C → Type} [∀ X Y, FunLike (FC X Y) (CC X) (CC Y)] theorem germ_res_apply (F : X.Presheaf C) {U V : Opens X} (i : U ⟶ V) (x : X) (hx : x ∈ U) [ConcreteCategory C FC] (s) : F.germ U x hx (F.map i.op s) = F.germ V x (i.le hx) s := by rw [← ConcreteCategory.comp_apply, germ_res] theorem germ_res_apply' (F : X.Presheaf C) {U V : Opens X} (i : op V ⟶ op U) (x : X) (hx : x ∈ U) [ConcreteCategory C FC] (s) : F.germ U x hx (F.map i s) = F.germ V x (i.unop.le hx) s := by rw [← ConcreteCategory.comp_apply, germ_res'] lemma Γgerm_res_apply (F : X.Presheaf C) {U : Opens X} {i : U ⟶ ⊤} (x : X) (hx : x ∈ U) [ConcreteCategory C FC] (s) : F.germ U x hx (F.map i.op s) = F.Γgerm x s := F.germ_res_apply i x hx s /-- A morphism from the stalk of `F` at `x` to some object `Y` is completely determined by its composition with the `germ` morphisms. -/ @[ext] theorem stalk_hom_ext (F : X.Presheaf C) {x} {Y : C} {f₁ f₂ : F.stalk x ⟶ Y} (ih : ∀ (U : Opens X) (hxU : x ∈ U), F.germ U x hxU ≫ f₁ = F.germ U x hxU ≫ f₂) : f₁ = f₂ := colimit.hom_ext fun U => by induction U with \| op U => obtain ⟨U, hxU⟩ := U; exact ih U hxU @[reassoc (attr := simp)] theorem stalkFunctor_map_germ {F G : X.Presheaf C} (U : Opens X) (x : X) (hx : x ∈ U) (f : F ⟶ G) : F.germ U x hx ≫ (stalkFunctor C x).map f = f.app (op U) ≫ G.germ U x hx := colimit.ι_map (whiskerLeft (OpenNhds.inclusion x).op f) (op ⟨U, hx⟩) theorem stalkFunctor_map_germ_apply [ConcreteCategory C FC] {F G : X.Presheaf C} (U : Opens X) (x : X) (hx : x ∈ U) (f : F ⟶ G) (s) : (stalkFunctor C x).map f (F.germ U x hx s) = G.germ U x hx (f.app (op U) s) := by rw [← ConcreteCategory.comp_apply, ← stalkFunctor_map_germ, ConcreteCategory.comp_apply] rfl -- a variant of `stalkFunctor_map_germ_apply` that makes simpNF happy. @[simp] theorem stalkFunctor_map_germ_apply' [ConcreteCategory C FC] {F G : X.Presheaf C} (U : Opens X) (x : X) (hx : x ∈ U) (f : F ⟶ G) (s) : DFunLike.coe (F := ToHom (F.stalk x) (G.stalk x)) (ConcreteCategory.hom ((stalkFunctor C x).map f)) (F.germ U x hx s) = G.germ U x hx (f.app (op U) s) := stalkFunctor_map_germ_apply U x hx f s variable (C) /-- For a presheaf `F` on a space `X`, a continuous map `f : X ⟶ Y` induces a morphisms between the stalk of `f _ * F` at `f x` and the stalk of `F` at `x`. -/ def stalkPushforward (f : X ⟶ Y) (F : X.Presheaf C) (x : X) : (f _* F).stalk (f x) ⟶ F.stalk x := by -- This is a hack; Lean doesn't like to elaborate the term written directly. refine ?_ ≫ colimit.pre _ (OpenNhds.map f x).op exact colim.map (whiskerRight (NatTrans.op (OpenNhds.inclusionMapIso f x).inv) F) @[reassoc (attr := simp), elementwise (attr := simp)] theorem stalkPushforward_germ (f : X ⟶ Y) (F : X.Presheaf C) (U : Opens Y) (x : X) (hx : f x ∈ U) : (f _* F).germ U (f x) hx ≫ F.stalkPushforward C f x = F.germ ((Opens.map f).obj U) x hx := by simp [germ, stalkPushforward] -- Here are two other potential solutions, suggested by @fpvandoorn at -- <https://github.com/leanprover-community/mathlib/pull/1018#discussion_r283978240> -- However, I can't get the subsequent two proofs to work with either one. -- def stalkPushforward'' (f : X ⟶ Y) (ℱ : X.Presheaf C) (x : X) : -- (f _* ℱ).stalk (f x) ⟶ ℱ.stalk x := -- colim.map ((Functor.associator _ _ _).inv ≫ -- whiskerRight (NatTrans.op (OpenNhds.inclusionMapIso f x).inv) ℱ) ≫ -- colimit.pre ((OpenNhds.inclusion x).op ⋙ ℱ) (OpenNhds.map f x).op -- def stalkPushforward''' (f : X ⟶ Y) (ℱ : X.Presheaf C) (x : X) : -- (f _* ℱ).stalk (f x) ⟶ ℱ.stalk x := -- (colim.map (whiskerRight (NatTrans.op (OpenNhds.inclusionMapIso f x).inv) ℱ) : -- colim.obj ((OpenNhds.inclusion (f x) ⋙ Opens.map f).op ⋙ ℱ) ⟶ _) ≫ -- colimit.pre ((OpenNhds.inclusion x).op ⋙ ℱ) (OpenNhds.map f x).op namespace stalkPushforward @[simp] theorem id (ℱ : X.Presheaf C) (x : X) : ℱ.stalkPushforward C (𝟙 X) x = (stalkFunctor C x).map (Pushforward.id ℱ).hom := by ext simp only [stalkPushforward, germ, colim_map, ι_colimMap_assoc, whiskerRight_app] erw [CategoryTheory.Functor.map_id] simp [stalkFunctor] @[simp] theorem comp (ℱ : X.Presheaf C) (f : X ⟶ Y) (g : Y ⟶ Z) (x : X) : ℱ.stalkPushforward C (f ≫ g) x = (f _* ℱ).stalkPushforward C g (f x) ≫ ℱ.stalkPushforward C f x := by ext simp [germ, stalkPushforward] theorem stalkPushforward_iso_of_isInducing {f : X ⟶ Y} (hf : IsInducing f) (F : X.Presheaf C) (x : X) : IsIso (F.stalkPushforward _ f x) := by haveI := Functor.initial_of_adjunction (hf.adjunctionNhds x) convert (Functor.Final.colimitIso (OpenNhds.map f x).op ((OpenNhds.inclusion x).op ⋙ F)).isIso_hom refine stalk_hom_ext _ fun U hU ↦ (stalkPushforward_germ _ f F _ x hU).trans ?_ symm exact colimit.ι_pre ((OpenNhds.inclusion x).op ⋙ F) (OpenNhds.map f x).op _ @[deprecated (since := "2024-10-27")] alias stalkPushforward_iso_of_isOpenEmbedding := stalkPushforward_iso_of_isInducing end stalkPushforward section stalkPullback /-- The morphism `ℱ_{f x} ⟶ (f⁻¹ℱ)ₓ` that factors through `(f_f⁻¹ℱ)_{f x}`. -/ def stalkPullbackHom (f : X ⟶ Y) (F : Y.Presheaf C) (x : X) : F.stalk (f x) ⟶ ((pullback C f).obj F).stalk x := (stalkFunctor _ (f x)).map ((pushforwardPullbackAdjunction C f).unit.app F) ≫ stalkPushforward _ _ _ x @[reassoc (attr := simp)] lemma germ_stalkPullbackHom (f : X ⟶ Y) (F : Y.Presheaf C) (x : X) (U : Opens Y) (hU : f x ∈ U) : F.germ U (f x) hU ≫ stalkPullbackHom C f F x = ((pushforwardPullbackAdjunction C f).unit.app F).app _ ≫ ((pullback C f).obj F).germ ((Opens.map f).obj U) x hU := by simp [stalkPullbackHom, germ, stalkFunctor, stalkPushforward] /-- The morphism `(f⁻¹ℱ)(U) ⟶ ℱ_{f(x)}` for some `U ∋ x`. -/ def germToPullbackStalk (f : X ⟶ Y) (F : Y.Presheaf C) (U : Opens X) (x : X) (hx : x ∈ U) : ((pullback C f).obj F).obj (op U) ⟶ F.stalk (f x) := ((Opens.map f).op.isPointwiseLeftKanExtensionLeftKanExtensionUnit F (op U)).desc { pt := F.stalk ((f : X → Y) (x : X)) ι := { app := fun V => F.germ _ (f x) (V.hom.unop.le hx) naturality := fun _ _ i => by simp } } variable {C} in @[ext] lemma pullback_obj_obj_ext {Z : C} {f : X ⟶ Y} {F : Y.Presheaf C} (U : (Opens X)ᵒᵖ) {φ ψ : ((pullback C f).obj F).obj U ⟶ Z} (h : ∀ (V : Opens Y) (hV : U.unop ≤ (Opens.map f).obj V), ((pushforwardPullbackAdjunction C f).unit.app F).app (op V) ≫ ((pullback C f).obj F).map (homOfLE hV).op ≫ φ = ((pushforwardPullbackAdjunction C f).unit.app F).app (op V) ≫ ((pullback C f).obj F).map (homOfLE hV).op ≫ ψ) : φ = ψ := by obtain ⟨U⟩ := U apply ((Opens.map f).op.isPointwiseLeftKanExtensionLeftKanExtensionUnit F _).hom_ext rintro ⟨⟨V⟩, ⟨⟩, ⟨b⟩⟩ simpa [pushforwardPullbackAdjunction, Functor.lanAdjunction_unit] using h V (leOfHom b) @[reassoc (attr := simp)] lemma pushforwardPullbackAdjunction_unit_pullback_map_germToPullbackStalk (f : X ⟶ Y) (F : Y.Presheaf C) (U : Opens X) (x : X) (hx : x ∈ U) (V : Opens Y) (hV : U ≤ (Opens.map f).obj V) : ((pushforwardPullbackAdjunction C f).unit.app F).app (op V) ≫ ((pullback C f).obj F).map (homOfLE hV).op ≫ germToPullbackStalk C f F U x hx = F.germ _ (f x) (hV hx) := by simpa [pushforwardPullbackAdjunction] using ((Opens.map f).op.isPointwiseLeftKanExtensionLeftKanExtensionUnit F (op U)).fac _ (CostructuredArrow.mk (homOfLE hV).op) @[reassoc (attr := simp)] lemma germToPullbackStalk_stalkPullbackHom (f : X ⟶ Y) (F : Y.Presheaf C) (U : Opens X) (x : X) (hx : x ∈ U) : germToPullbackStalk C f F U x hx ≫ stalkPullbackHom C f F x = ((pullback C f).obj F).germ _ x hx := by ext V hV dsimp simp only [pushforwardPullbackAdjunction_unit_pullback_map_germToPullbackStalk_assoc, germ_stalkPullbackHom, germ_res] @[reassoc (attr := simp)] lemma pushforwardPullbackAdjunction_unit_app_app_germToPullbackStalk (f : X ⟶ Y) (F : Y.Presheaf C) (V : (Opens Y)ᵒᵖ) (x : X) (hx : f x ∈ V.unop) : ((pushforwardPullbackAdjunction C f).unit.app F).app V ≫ germToPullbackStalk C f F _ x hx = F.germ _ (f x) hx := by simpa using pushforwardPullbackAdjunction_unit_pullback_map_germToPullbackStalk C f F ((Opens.map f).obj V.unop) x hx V.unop (by rfl) /-- The morphism `(f⁻¹ℱ)ₓ ⟶ ℱ_{f(x)}`. -/ def stalkPullbackInv (f : X ⟶ Y) (F : Y.Presheaf C) (x : X) : ((pullback C f).obj F).stalk x ⟶ F.stalk (f x) := colimit.desc ((OpenNhds.inclusion x).op ⋙ (Presheaf.pullback C f).obj F) { pt := F.stalk (f x) ι := { app := fun U => F.germToPullbackStalk _ f (unop U).1 x (unop U).2 naturality := fun U V i => by dsimp ext W hW dsimp [OpenNhds.inclusion] rw [Category.comp_id, ← Functor.map_comp_assoc, pushforwardPullbackAdjunction_unit_pullback_map_germToPullbackStalk] erw [pushforwardPullbackAdjunction_unit_pullback_map_germToPullbackStalk] } } @[reassoc (attr := simp)] lemma germ_stalkPullbackInv (f : X ⟶ Y) (F : Y.Presheaf C) (x : X) (V : Opens X) (hV : x ∈ V) : ((pullback C f).obj F).germ _ x hV ≫ stalkPullbackInv C f F x = F.germToPullbackStalk _ f V x hV := by apply colimit.ι_desc /-- The isomorphism `ℱ_{f(x)} ≅ (f⁻¹ℱ)ₓ`. -/ def stalkPullbackIso (f : X ⟶ Y) (F : Y.Presheaf C) (x : X) : F.stalk (f x) ≅ ((pullback C f).obj F).stalk x where hom := stalkPullbackHom _ _ _ _ inv := stalkPullbackInv _ _ _ _ hom_inv_id := by ext U hU dsimp rw [germ_stalkPullbackHom_assoc, germ_stalkPullbackInv, Category.comp_id, pushforwardPullbackAdjunction_unit_app_app_germToPullbackStalk] inv_hom_id := by ext V hV dsimp rw [germ_stalkPullbackInv_assoc, Category.comp_id, germToPullbackStalk_stalkPullbackHom] end stalkPullback section stalkSpecializes variable {C} /-- If `x` specializes to `y`, then there is a natural map `F.stalk y ⟶ F.stalk x`. -/ noncomputable def stalkSpecializes (F : X.Presheaf C) {x y : X} (h : x ⤳ y) : F.stalk y ⟶ F.stalk x := by refine colimit.desc _ ⟨_, fun U => ?_, ?_⟩ · exact colimit.ι ((OpenNhds.inclusion x).op ⋙ F) (op ⟨(unop U).1, (specializes_iff_forall_open.mp h _ (unop U).1.2 (unop U).2 :)⟩) · intro U V i dsimp rw [Category.comp_id] let U' : OpenNhds x := ⟨_, (specializes_iff_forall_open.mp h _ (unop U).1.2 (unop U).2 :)⟩ let V' : OpenNhds x := ⟨_, (specializes_iff_forall_open.mp h _ (unop V).1.2 (unop V).2 :)⟩ exact colimit.w ((OpenNhds.inclusion x).op ⋙ F) (show V' ⟶ U' from i.unop).op @[reassoc (attr := simp), elementwise nosimp] theorem germ_stalkSpecializes (F : X.Presheaf C) {U : Opens X} {y : X} (hy : y ∈ U) {x : X} (h : x ⤳ y) : F.germ U y hy ≫ F.stalkSpecializes h = F.germ U x (h.mem_open U.isOpen hy) := colimit.ι_desc _ _ @[simp] theorem stalkSpecializes_refl {C : Type} [Category C] [Limits.HasColimits C] {X : TopCat} (F : X.Presheaf C) (x : X) : F.stalkSpecializes (specializes_refl x) = 𝟙 _ := by ext simp @[reassoc (attr := simp), elementwise (attr := simp)] theorem stalkSpecializes_comp {C : Type} [Category C] [Limits.HasColimits C] {X : TopCat} (F : X.Presheaf C) {x y z : X} (h : x ⤳ y) (h' : y ⤳ z) : F.stalkSpecializes h' ≫ F.stalkSpecializes h = F.stalkSpecializes (h.trans h') := by ext simp @[reassoc (attr := simp), elementwise (attr := simp)] theorem stalkSpecializes_stalkFunctor_map {F G : X.Presheaf C} (f : F ⟶ G) {x y : X} (h : x ⤳ y) : F.stalkSpecializes h ≫ (stalkFunctor C x).map f = (stalkFunctor C y).map f ≫ G.stalkSpecializes h := by change (_ : colimit _ ⟶ _) = (_ : colimit _ ⟶ _) ext; delta stalkFunctor; simpa [stalkSpecializes] using by rfl -- See https://github.com/leanprover-community/batteries/issues/365 for the simpNF issue. -- It seems the side condition `h` is not applied by `simpNF`. @[reassoc, elementwise, simp, nolint simpNF] theorem stalkSpecializes_stalkPushforward (f : X ⟶ Y) (F : X.Presheaf C) {x y : X} (h : x ⤳ y) : (f _ F).stalkSpecializes (f.hom.map_specializes h) ≫ F.stalkPushforward _ f x = F.stalkPushforward _ f y ≫ F.stalkSpecializes h := by change (_ : colimit _ ⟶ _) = (_ : colimit _ ⟶ _) ext; delta stalkPushforward simp only [stalkSpecializes, colimit.ι_desc_assoc, colimit.ι_map_assoc, colimit.ι_pre, Category.assoc, colimit.pre_desc, colimit.ι_desc] rfl /-- The stalks are isomorphic on inseparable points -/ @[simps] def stalkCongr {X : TopCat} {C : Type} [Category C] [HasColimits C] (F : X.Presheaf C) {x y : X} (e : Inseparable x y) : F.stalk x ≅ F.stalk y := ⟨F.stalkSpecializes e.ge, F.stalkSpecializes e.le, by simp, by simp⟩ end stalkSpecializes section Concrete variable {C} {CC : C → Type v} [∀ X Y, FunLike (FC X Y) (CC X) (CC Y)] variable [instCC : ConcreteCategory.{v} C FC] -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: @[ext] attribute only applies to structures or lemmas proving x = y -- @[ext] theorem germ_ext (F : X.Presheaf C) {U V : Opens X} {x : X} {hxU : x ∈ U} {hxV : x ∈ V} (W : Opens X) (hxW : x ∈ W) (iWU : W ⟶ U) (iWV : W ⟶ V) {sU : ToType (F.obj (op U))} {sV : ToType (F.obj (op V))} (ih : F.map iWU.op sU = F.map iWV.op sV) : F.germ _ x hxU sU = F.germ _ x hxV sV := by rw [← F.germ_res iWU x hxW, ← F.germ_res iWV x hxW, ConcreteCategory.comp_apply, ConcreteCategory.comp_apply, ih] variable [PreservesFilteredColimits (forget C)] /-- For presheaves valued in a concrete category whose forgetful functor preserves filtered colimits, every element of the stalk is the germ of a section. -/ theorem germ_exist (F : X.Presheaf C) (x : X) (t : ToType (stalk.{v, u} F x)) : ∃ (U : Opens X) (m : x ∈ U) (s : ToType (F.obj (op U))), F.germ _ x m s = t := by obtain ⟨U, s, e⟩ := Types.jointly_surjective.{v, v} _ (isColimitOfPreserves (forget C) (colimit.isColimit _)) t revert s e induction U with \| op U => ?_ obtain ⟨V, m⟩ := U intro s e exact ⟨V, m, s, e⟩ theorem germ_eq (F : X.Presheaf C) {U V : Opens X} (x : X) (mU : x ∈ U) (mV : x ∈ V) (s : ToType (F.obj (op U))) (t : ToType (F.obj (op V))) (h : F.germ U x mU s = F.germ V x mV t) : ∃ (W : Opens X) (_m : x ∈ W) (iU : W ⟶ U) (iV : W ⟶ V), F.map iU.op s = F.map iV.op t := by obtain ⟨W, iU, iV, e⟩ := (Types.FilteredColimit.isColimit_eq_iff.{v, v} _ (isColimitOfPreserves (forget C) (colimit.isColimit ((OpenNhds.inclusion x).op ⋙ F)))).mp h exact ⟨(unop W).1, (unop W).2, iU.unop, iV.unop, e⟩ theorem stalkFunctor_map_injective_of_app_injective {F G : Presheaf C X} (f : F ⟶ G) (h : ∀ U : Opens X, Function.Injective (f.app (op U))) (x : X) : Function.Injective ((stalkFunctor C x).map f) := fun s t hst => by rcases germ_exist F x s with ⟨U₁, hxU₁, s, rfl⟩ rcases germ_exist F x t with ⟨U₂, hxU₂, t, rfl⟩ rw [stalkFunctor_map_germ_apply, stalkFunctor_map_germ_apply] at hst obtain ⟨W, hxW, iWU₁, iWU₂, heq⟩ := G.germ_eq x hxU₁ hxU₂ _ _ hst rw [← ConcreteCategory.comp_apply, ← ConcreteCategory.comp_apply, ← f.naturality, ← f.naturality, ConcreteCategory.comp_apply, ConcreteCategory.comp_apply] at heq replace heq := h W heq convert congr_arg (F.germ _ x hxW) heq using 1 exacts [(F.germ_res_apply iWU₁ x hxW s).symm, (F.germ_res_apply iWU₂ x hxW t).symm] variable [HasLimits C] [PreservesLimits (forget C)] [(forget C).ReflectsIsomorphisms] /-- Let `F` be a sheaf valued in a concrete category, whose forgetful functor reflects isomorphisms, preserves limits and filtered colimits. Then two sections who agree on every stalk must be equal. -/ theorem section_ext (F : Sheaf C X) (U : Opens X) (s t : ToType (F.1.obj (op U))) (h : ∀ (x : X) (hx : x ∈ U), F.presheaf.germ U x hx s = F.presheaf.germ U x hx t) : s = t := by -- We use `germ_eq` and the axiom of choice, to pick for every point `x` a neighbourhood -- `V x`, such that the restrictions of `s` and `t` to `V x` coincide. choose V m i₁ i₂ heq using fun x : U => F.presheaf.germ_eq x.1 x.2 x.2 s t (h x.1 x.2) -- Since `F` is a sheaf, we can prove the equality locally, if we can show that these -- neighborhoods form a cover of `U`. apply F.eq_of_locally_eq' V U i₁ · intro x hxU simp only [Opens.coe_iSup, Set.mem_iUnion, SetLike.mem_coe] exact ⟨⟨x, hxU⟩, m ⟨x, hxU⟩⟩ · intro x rw [heq, Subsingleton.elim (i₁ x) (i₂ x)] /- Note that the analogous statement for surjectivity is false: Surjectivity on stalks does not imply surjectivity of the components of a sheaf morphism. However it does imply that the morphism is an epi, but this fact is not yet formalized. -/ theorem app_injective_of_stalkFunctor_map_injective {F : Sheaf C X} {G : Presheaf C X} (f : F.1 ⟶ G) (U : Opens X) (h : ∀ x ∈ U, Function.Injective ((stalkFunctor C x).map f)) : Function.Injective (f.app (op U)) := fun s t hst => section_ext F _ _ _ fun x hx => h x hx <\| by rw [stalkFunctor_map_germ_apply, stalkFunctor_map_germ_apply, hst] theorem app_injective_iff_stalkFunctor_map_injective {F : Sheaf C X} {G : Presheaf C X} (f : F.1 ⟶ G) : (∀ x : X, Function.Injective ((stalkFunctor C x).map f)) ↔ ∀ U : Opens X, Function.Injective (f.app (op U)) := ⟨fun h U => app_injective_of_stalkFunctor_map_injective f U fun x _ => h x, stalkFunctor_map_injective_of_app_injective f⟩ instance stalkFunctor_preserves_mono (x : X) : Functor.PreservesMonomorphisms (Sheaf.forget.{v} C X ⋙ stalkFunctor C x) := ⟨@fun _𝓐 _𝓑 f _ => ConcreteCategory.mono_of_injective _ <\| (app_injective_iff_stalkFunctor_map_injective f.1).mpr (fun c => (ConcreteCategory.mono_iff_injective_of_preservesPullback (f.1.app (op c))).mp ((NatTrans.mono_iff_mono_app f.1).mp (CategoryTheory.presheaf_mono_of_mono ..) <\| op c)) x⟩ include instCC in theorem stalk_mono_of_mono {F G : Sheaf C X} (f : F ⟶ G) [Mono f] : ∀ x, Mono <\| (stalkFunctor C x).map f.1 := fun x => Functor.map_mono (Sheaf.forget.{v} C X ⋙ stalkFunctor C x) f include instCC in theorem mono_of_stalk_mono {F G : Sheaf C X} (f : F ⟶ G) [∀ x, Mono <\| (stalkFunctor C x).map f.1] : Mono f := (Sheaf.Hom.mono_iff_presheaf_mono _ _ _).mpr <\| (NatTrans.mono_iff_mono_app _).mpr fun U => (ConcreteCategory.mono_iff_injective_of_preservesPullback _).mpr <\| app_injective_of_stalkFunctor_map_injective f.1 U.unop fun _x _hx => (ConcreteCategory.mono_iff_injective_of_preservesPullback ((stalkFunctor C _).map f.val)).mp <\| inferInstance include instCC in theorem mono_iff_stalk_mono {F G : Sheaf C X} (f : F ⟶ G) : Mono f ↔ ∀ x, Mono ((stalkFunctor C x).map f.1) := ⟨fun _ => stalk_mono_of_mono _, fun _ => mono_of_stalk_mono _⟩ /-- For surjectivity, we are given an arbitrary section `t` and need to find a preimage for it. We claim that it suffices to find preimages locally*. That is, for each `x : U` we construct a neighborhood `V ≤ U` and a section `s : F.obj (op V))` such that `f.app (op V) s` and `t` agree on `V`. -/ theorem app_surjective_of_injective_of_locally_surjective {F G : Sheaf C X} (f : F ⟶ G) (U : Opens X) (hinj : ∀ x ∈ U, Function.Injective ((stalkFunctor C x).map f.1)) (hsurj : ∀ (t x) (_ : x ∈ U), ∃ (V : Opens X) (_ : x ∈ V) (iVU : V ⟶ U) (s : ToType (F.1.obj (op V))), f.1.app (op V) s = G.1.map iVU.op t) : Function.Surjective (f.1.app (op U)) := by conv at hsurj => enter [t] rw [Subtype.forall' (p := (· ∈ U))] intro t -- We use the axiom of choice to pick around each point `x` an open neighborhood `V` and a -- preimage under `f` on `V`. choose V mV iVU sf heq using hsurj t -- These neighborhoods clearly cover all of `U`. have V_cover : U ≤ iSup V := by intro x hxU simp only [Opens.coe_iSup, Set.mem_iUnion, SetLike.mem_coe] exact ⟨⟨x, hxU⟩, mV ⟨x, hxU⟩⟩ suffices IsCompatible F.val V sf by -- Since `F` is a sheaf, we can glue all the local preimages together to get a global preimage. obtain ⟨s, s_spec, -⟩ := F.existsUnique_gluing' V U iVU V_cover sf this · use s apply G.eq_of_locally_eq' V U iVU V_cover intro x rw [← ConcreteCategory.comp_apply, ← f.1.naturality, ConcreteCategory.comp_apply, s_spec, heq] intro x y -- What's left to show here is that the sections `sf` are compatible, i.e. they agree on -- the intersections `V x ⊓ V y`. We prove this by showing that all germs are equal. apply section_ext intro z hz -- Here, we need to use injectivity of the stalk maps. apply hinj z ((iVU x).le ((inf_le_left : V x ⊓ V y ≤ V x) hz)) dsimp only rw [stalkFunctor_map_germ_apply, stalkFunctor_map_germ_apply] simp_rw [← ConcreteCategory.comp_apply, f.1.naturality, ConcreteCategory.comp_apply, heq, ← ConcreteCategory.comp_apply, ← G.1.map_comp] rfl theorem app_surjective_of_stalkFunctor_map_bijective {F G : Sheaf C X} (f : F ⟶ G) (U : Opens X) (h : ∀ x ∈ U, Function.Bijective ((stalkFunctor C x).map f.1)) : Function.Surjective (f.1.app (op U)) := by refine app_surjective_of_injective_of_locally_surjective f U (And.left <\| h · ·) fun t x hx => ?_ -- Now we need to prove our initial claim: That we can find preimages of `t` locally. -- Since `f` is surjective on stalks, we can find a preimage `s₀` of the germ of `t` at `x` obtain ⟨s₀, hs₀⟩ := (h x hx).2 (G.presheaf.germ U x hx t) -- ... and this preimage must come from some section `s₁` defined on some open neighborhood `V₁` obtain ⟨V₁, hxV₁, s₁, hs₁⟩ := F.presheaf.germ_exist x s₀ subst hs₁; rename' hs₀ => hs₁ rw [stalkFunctor_map_germ_apply V₁ x hxV₁ f.1 s₁] at hs₁ -- Now, the germ of `f.app (op V₁) s₁` equals the germ of `t`, hence they must coincide on -- some open neighborhood `V₂`. obtain ⟨V₂, hxV₂, iV₂V₁, iV₂U, heq⟩ := G.presheaf.germ_eq x hxV₁ hx _ _ hs₁ -- The restriction of `s₁` to that neighborhood is our desired local preimage. use V₂, hxV₂, iV₂U, F.1.map iV₂V₁.op s₁ rw [← ConcreteCategory.comp_apply, f.1.naturality, ConcreteCategory.comp_apply, heq] theorem app_bijective_of_stalkFunctor_map_bijective {F G : Sheaf C X} (f : F ⟶ G) (U : Opens X) (h : ∀ x ∈ U, Function.Bijective ((stalkFunctor C x).map f.1)) : Function.Bijective (f.1.app (op U)) := ⟨app_injective_of_stalkFunctor_map_injective f.1 U fun x hx => (h x hx).1, app_surjective_of_stalkFunctor_map_bijective f U h⟩ include instCC in theorem app_isIso_of_stalkFunctor_map_iso {F G : Sheaf C X} (f : F ⟶ G) (U : Opens X) [∀ x : U, IsIso ((stalkFunctor C x.val).map f.1)] : IsIso (f.1.app (op U)) := by -- Since the forgetful functor of `C` reflects isomorphisms, it suffices to see that the -- underlying map between types is an isomorphism, i.e. bijective. suffices IsIso ((forget C).map (f.1.app (op U))) by exact isIso_of_reflects_iso (f.1.app (op U)) (forget C) rw [isIso_iff_bijective] apply app_bijective_of_stalkFunctor_map_bijective intro x hx apply (isIso_iff_bijective _).mp exact Functor.map_isIso (forget C) ((stalkFunctor C (⟨x, hx⟩ : U).1).map f.1) include instCC in -- Making this an instance would cause a loop in typeclass resolution with `Functor.map_isIso` /-- Let `F` and `G` be sheaves valued in a concrete category, whose forgetful functor reflects isomorphisms, preserves limits and filtered colimits. Then if the stalk maps of a morphism `f : F ⟶ G` are all isomorphisms, `f` must be an isomorphism. -/ theorem isIso_of_stalkFunctor_map_iso {F G : Sheaf C X} (f : F ⟶ G) [∀ x : X, IsIso ((stalkFunctor C x).map f.1)] : IsIso f := by -- Since the inclusion functor from sheaves to presheaves is fully faithful, it suffices to -- show that `f`, as a morphism between _presheaves_, is an isomorphism. suffices IsIso ((Sheaf.forget C X).map f) by exact isIso_of_fully_faithful (Sheaf.forget C X) f -- We show that all components of `f` are isomorphisms. suffices ∀ U : (Opens X)ᵒᵖ, IsIso (f.1.app U) by exact @NatIso.isIso_of_isIso_app _ _ _ _ F.1 G.1 f.1 this intro U; induction U apply app_isIso_of_stalkFunctor_map_iso include instCC in /-- Let `F` and `G` be sheaves valued in a concrete category, whose forgetful functor reflects isomorphisms, preserves limits and filtered colimits. Then a morphism `f : F ⟶ G` is an isomorphism if and only if all of its stalk maps are isomorphisms. -/ theorem isIso_iff_stalkFunctor_map_iso {F G : Sheaf C X} (f : F ⟶ G) :	IsIso f ↔ ∀ x : X, IsIso ((stalkFunctor C x).map f.1) := ⟨fun _ x => @Functor.map_isIso _ _ _ _ _ _ (stalkFunctor C x) f.1 ((Sheaf.forget C X).map_isIso f), fun _ => isIso_of_stalkFunctor_map_iso f⟩ end Concrete end TopCat.Presheaf	Mathlib/Topology/Sheaves/Stalks.lean	609	618
/- Copyright (c) 2021 Andrew Yang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.Topology.Gluing import Mathlib.Geometry.RingedSpace.OpenImmersion import Mathlib.Geometry.RingedSpace.LocallyRingedSpace.HasColimits /-! # Gluing Structured spaces Given a family of gluing data of structured spaces (presheafed spaces, sheafed spaces, or locally ringed spaces), we may glue them together. The construction should be "sealed" and considered as a black box, while only using the API provided. ## Main definitions * `AlgebraicGeometry.PresheafedSpace.GlueData`: A structure containing the family of gluing data. * `CategoryTheory.GlueData.glued`: The glued presheafed space. This is defined as the multicoequalizer of `∐ V i j ⇉ ∐ U i`, so that the general colimit API can be used. * `CategoryTheory.GlueData.ι`: The immersion `ι i : U i ⟶ glued` for each `i : J`. ## Main results * `AlgebraicGeometry.PresheafedSpace.GlueData.ιIsOpenImmersion`: The map `ι i : U i ⟶ glued` is an open immersion for each `i : J`. * `AlgebraicGeometry.PresheafedSpace.GlueData.ι_jointly_surjective` : The underlying maps of `ι i : U i ⟶ glued` are jointly surjective. * `AlgebraicGeometry.PresheafedSpace.GlueData.vPullbackConeIsLimit` : `V i j` is the pullback (intersection) of `U i` and `U j` over the glued space. Analogous results are also provided for `SheafedSpace` and `LocallyRingedSpace`. ## Implementation details Almost the whole file is dedicated to showing that `ι i` is an open immersion. The fact that this is an open embedding of topological spaces follows from `Mathlib/Topology/Gluing.lean`, and it remains to construct `Γ(𝒪_{U_i}, U) ⟶ Γ(𝒪_X, ι i '' U)` for each `U ⊆ U i`. Since `Γ(𝒪_X, ι i '' U)` is the limit of `diagram_over_open`, the components of the structure sheafs of the spaces in the gluing diagram, we need to construct a map `ιInvApp_π_app : Γ(𝒪_{U_i}, U) ⟶ Γ(𝒪_V, U_V)` for each `V` in the gluing diagram. We will refer to ![this diagram](https://i.imgur.com/P0phrwr.png) in the following doc strings. The `X` is the glued space, and the dotted arrow is a partial inverse guaranteed by the fact that it is an open immersion. The map `Γ(𝒪_{U_i}, U) ⟶ Γ(𝒪_{U_j}, _)` is given by the composition of the red arrows, and the map `Γ(𝒪_{U_i}, U) ⟶ Γ(𝒪_{V_{jk}}, _)` is given by the composition of the blue arrows. To lift this into a map from `Γ(𝒪_X, ι i '' U)`, we also need to show that these commute with the maps in the diagram (the green arrows), which is just a lengthy diagram-chasing. -/ noncomputable section open TopologicalSpace CategoryTheory Opposite Topology open CategoryTheory.Limits AlgebraicGeometry.PresheafedSpace open AlgebraicGeometry.PresheafedSpace.IsOpenImmersion open CategoryTheory.GlueData namespace AlgebraicGeometry universe v u variable (C : Type u) [Category.{v} C] namespace PresheafedSpace /-- A family of gluing data consists of 1. An index type `J` 2. A presheafed space `U i` for each `i : J`. 3. A presheafed space `V i j` for each `i j : J`. (Note that this is `J × J → PresheafedSpace C` rather than `J → J → PresheafedSpace C` to connect to the limits library easier.) 4. An open immersion `f i j : V i j ⟶ U i` for each `i j : ι`. 5. A transition map `t i j : V i j ⟶ V j i` for each `i j : ι`. such that 6. `f i i` is an isomorphism. 7. `t i i` is the identity. 8. `V i j ×[U i] V i k ⟶ V i j ⟶ V j i` factors through `V j k ×[U j] V j i ⟶ V j i` via some `t' : V i j ×[U i] V i k ⟶ V j k ×[U j] V j i`. 9. `t' i j k ≫ t' j k i ≫ t' k i j = 𝟙 _`. We can then glue the spaces `U i` together by identifying `V i j` with `V j i`, such that the `U i`'s are open subspaces of the glued space. -/ structure GlueData extends CategoryTheory.GlueData (PresheafedSpace.{u, v, v} C) where f_open : ∀ i j, IsOpenImmersion (f i j) attribute [instance] GlueData.f_open namespace GlueData variable {C} variable (D : GlueData.{v, u} C) local notation "𝖣" => D.toGlueData local notation "π₁ " i ", " j ", " k => pullback.fst (D.f i j) (D.f i k) local notation "π₂ " i ", " j ", " k => pullback.snd (D.f i j) (D.f i k) set_option quotPrecheck false local notation "π₁⁻¹ " i ", " j ", " k => (PresheafedSpace.IsOpenImmersion.pullbackFstOfRight (D.f i j) (D.f i k)).invApp set_option quotPrecheck false local notation "π₂⁻¹ " i ", " j ", " k => (PresheafedSpace.IsOpenImmersion.pullbackSndOfLeft (D.f i j) (D.f i k)).invApp /-- The glue data of topological spaces associated to a family of glue data of PresheafedSpaces. -/ abbrev toTopGlueData : TopCat.GlueData := { f_open := fun i j => (D.f_open i j).base_open toGlueData := 𝖣.mapGlueData (forget C) } theorem ι_isOpenEmbedding [HasLimits C] (i : D.J) : IsOpenEmbedding (𝖣.ι i).base := by rw [← show _ = (𝖣.ι i).base from 𝖣.ι_gluedIso_inv (PresheafedSpace.forget _) _, TopCat.coe_comp] exact (TopCat.homeoOfIso (𝖣.gluedIso (PresheafedSpace.forget _)).symm).isOpenEmbedding.comp (D.toTopGlueData.ι_isOpenEmbedding i) theorem pullback_base (i j k : D.J) (S : Set (D.V (i, j)).carrier) : (π₂ i, j, k) '' ((π₁ i, j, k) ⁻¹' S) = D.f i k ⁻¹' (D.f i j '' S) := by have eq₁ : _ = (π₁ i, j, k).base := PreservesPullback.iso_hom_fst (forget C) _ _ have eq₂ : _ = (π₂ i, j, k).base := PreservesPullback.iso_hom_snd (forget C) _ _ rw [← eq₁, ← eq₂, TopCat.coe_comp, Set.image_comp, TopCat.coe_comp, Set.preimage_comp, Set.image_preimage_eq] · simp only [forget_obj, forget_map, TopCat.pullback_snd_image_fst_preimage] rw [← TopCat.epi_iff_surjective] infer_instance /-- The red and the blue arrows in ![this diagram](https://i.imgur.com/0GiBUh6.png) commute. -/ @[simp, reassoc] theorem f_invApp_f_app (i j k : D.J) (U : Opens (D.V (i, j)).carrier) : (D.f_open i j).invApp _ U ≫ (D.f i k).c.app _ = (π₁ i, j, k).c.app (op U) ≫ (π₂⁻¹ i, j, k) (unop _) ≫ (D.V _).presheaf.map (eqToHom (by delta IsOpenImmersion.opensFunctor dsimp only [Functor.op, IsOpenMap.functor, Opens.map, unop_op] congr apply pullback_base)) := by have := PresheafedSpace.congr_app (@pullback.condition _ _ _ _ _ (D.f i j) (D.f i k) _) dsimp only [comp_c_app] at this rw [← cancel_epi (inv ((D.f_open i j).invApp _ U)), IsIso.inv_hom_id_assoc, IsOpenImmersion.inv_invApp] simp_rw [Category.assoc] erw [(π₁ i, j, k).c.naturality_assoc, reassoc_of% this, ← Functor.map_comp_assoc, IsOpenImmersion.inv_naturality_assoc, IsOpenImmersion.app_invApp_assoc, ← (D.V (i, k)).presheaf.map_comp, ← (D.V (i, k)).presheaf.map_comp] -- Porting note: need to provide an explicit argument, otherwise Lean does not know which -- category we are talking about convert (Category.comp_id ((f D.toGlueData i k).c.app _)).symm erw [(D.V (i, k)).presheaf.map_id] rfl /-- We can prove the `eq` along with the lemma. Thus this is bundled together here, and the lemma itself is separated below. -/ theorem snd_invApp_t_app' (i j k : D.J) (U : Opens (pullback (D.f i j) (D.f i k)).carrier) : ∃ eq, (π₂⁻¹ i, j, k) U ≫ (D.t k i).c.app _ ≫ (D.V (k, i)).presheaf.map (eqToHom eq) = (D.t' k i j).c.app _ ≫ (π₁⁻¹ k, j, i) (unop _) := by fconstructor -- Porting note: I don't know what the magic was in Lean3 proof, it just skipped the proof of `eq` · delta IsOpenImmersion.opensFunctor dsimp only [Functor.op, Opens.map, IsOpenMap.functor, unop_op, Opens.coe_mk] congr have := (𝖣.t_fac k i j).symm rw [← IsIso.inv_comp_eq] at this replace this := (congr_arg ((PresheafedSpace.Hom.base ·)) this).symm replace this := congr_arg (TopCat.Hom.hom ·) this replace this := congr_arg (ContinuousMap.toFun ·) this dsimp at this rw [this, Set.image_comp, Set.image_comp, Set.preimage_image_eq] swap · refine Function.HasLeftInverse.injective ⟨(D.t i k).base, fun x => ?_⟩ rw [← ConcreteCategory.comp_apply, ← comp_base, D.t_inv, id_base, ConcreteCategory.id_apply] refine congr_arg (_ '' ·) ?_ refine congr_fun ?_ _ refine Set.image_eq_preimage_of_inverse ?_ ?_ · intro x rw [← ConcreteCategory.comp_apply, ← comp_base, IsIso.inv_hom_id, id_base, ConcreteCategory.id_apply] · intro x rw [← ConcreteCategory.comp_apply, ← comp_base, IsIso.hom_inv_id, id_base, ConcreteCategory.id_apply] · rw [← IsIso.eq_inv_comp, IsOpenImmersion.inv_invApp, Category.assoc, (D.t' k i j).c.naturality_assoc] simp_rw [← Category.assoc] dsimp rw [← comp_c_app, congr_app (D.t_fac k i j), comp_c_app] dsimp simp_rw [Category.assoc] rw [IsOpenImmersion.inv_naturality, IsOpenImmersion.inv_naturality_assoc, IsOpenImmersion.app_inv_app'_assoc] · simp_rw [← (𝖣.V (k, i)).presheaf.map_comp]; rfl rintro x ⟨y, -, eq⟩ replace eq := ConcreteCategory.congr_arg (𝖣.t i k).base eq change ((π₂ i, j, k) ≫ D.t i k).base y = (D.t k i ≫ D.t i k).base x at eq rw [𝖣.t_inv, id_base, TopCat.id_app] at eq subst eq use (inv (D.t' k i j)).base y change (inv (D.t' k i j) ≫ π₁ k, i, j).base y = _ congr 3 rw [IsIso.inv_comp_eq, 𝖣.t_fac_assoc, 𝖣.t_inv, Category.comp_id] /-- The red and the blue arrows in ![this diagram](https://i.imgur.com/q6X1GJ9.png) commute. -/ @[simp, reassoc] theorem snd_invApp_t_app (i j k : D.J) (U : Opens (pullback (D.f i j) (D.f i k)).carrier) : (π₂⁻¹ i, j, k) U ≫ (D.t k i).c.app _ = (D.t' k i j).c.app _ ≫ (π₁⁻¹ k, j, i) (unop _) ≫ (D.V (k, i)).presheaf.map (eqToHom (D.snd_invApp_t_app' i j k U).choose.symm) := by have e := (D.snd_invApp_t_app' i j k U).choose_spec replace e := reassoc_of% e rw [← e] simp [eqToHom_map] variable [HasLimits C] theorem ι_image_preimage_eq (i j : D.J) (U : Opens (D.U i).carrier) : (Opens.map (𝖣.ι j).base).obj ((D.ι_isOpenEmbedding i).isOpenMap.functor.obj U) = (opensFunctor (D.f j i)).obj ((Opens.map (𝖣.t j i).base).obj ((Opens.map (𝖣.f i j).base).obj U)) := by ext1 dsimp only [Opens.map_coe, IsOpenMap.coe_functor_obj] rw [← show _ = (𝖣.ι i).base from 𝖣.ι_gluedIso_inv (PresheafedSpace.forget _) i, ← show _ = (𝖣.ι j).base from 𝖣.ι_gluedIso_inv (PresheafedSpace.forget _) j] -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11224): change `rw` to `erw` on `coe_comp` erw [TopCat.coe_comp, TopCat.coe_comp, TopCat.coe_comp]	rw [Set.image_comp, Set.preimage_comp] erw [Set.preimage_image_eq] · refine Eq.trans (D.toTopGlueData.preimage_image_eq_image' _ _ _) ?_ dsimp rw [Set.image_comp] refine congr_arg (_ '' ·) ?_ rw [Set.eq_preimage_iff_image_eq, ← Set.image_comp] swap · exact CategoryTheory.ConcreteCategory.bijective_of_isIso (C := TopCat) _	Mathlib/Geometry/RingedSpace/PresheafedSpace/Gluing.lean	239	247
/- Copyright (c) 2022 Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies -/ import Mathlib.Order.Filter.Prod /-! # N-ary maps of filter This file defines the binary and ternary maps of filters. This is mostly useful to define pointwise operations on filters. ## Main declarations * `Filter.map₂`: Binary map of filters. ## Notes This file is very similar to `Data.Set.NAry`, `Data.Finset.NAry` and `Data.Option.NAry`. Please keep them in sync. -/ open Function Set open Filter namespace Filter variable {α α' β β' γ γ' δ δ' ε ε' : Type*} {m : α → β → γ} {f f₁ f₂ : Filter α} {g g₁ g₂ : Filter β} {h : Filter γ} {s : Set α} {t : Set β} {u : Set γ} {a : α} {b : β} /-- The image of a binary function `m : α → β → γ` as a function `Filter α → Filter β → Filter γ`. Mathematically this should be thought of as the image of the corresponding function `α × β → γ`. -/ def map₂ (m : α → β → γ) (f : Filter α) (g : Filter β) : Filter γ := ((f ×ˢ g).map (uncurry m)).copy { s \| ∃ u ∈ f, ∃ v ∈ g, image2 m u v ⊆ s } fun _ ↦ by simp only [mem_map, mem_prod_iff, image2_subset_iff, prod_subset_iff]; rfl @[simp 900] theorem mem_map₂_iff : u ∈ map₂ m f g ↔ ∃ s ∈ f, ∃ t ∈ g, image2 m s t ⊆ u := Iff.rfl theorem image2_mem_map₂ (hs : s ∈ f) (ht : t ∈ g) : image2 m s t ∈ map₂ m f g := ⟨_, hs, _, ht, Subset.rfl⟩ theorem map_prod_eq_map₂ (m : α → β → γ) (f : Filter α) (g : Filter β) : Filter.map (fun p : α × β => m p.1 p.2) (f ×ˢ g) = map₂ m f g := by rw [map₂, copy_eq, uncurry_def] theorem map_prod_eq_map₂' (m : α × β → γ) (f : Filter α) (g : Filter β) : Filter.map m (f ×ˢ g) = map₂ (fun a b => m (a, b)) f g := map_prod_eq_map₂ m.curry f g @[simp] theorem map₂_mk_eq_prod (f : Filter α) (g : Filter β) : map₂ Prod.mk f g = f ×ˢ g := by simp only [← map_prod_eq_map₂, map_id'] -- lemma image2_mem_map₂_iff (hm : injective2 m) : image2 m s t ∈ map₂ m f g ↔ s ∈ f ∧ t ∈ g := -- ⟨by { rintro ⟨u, v, hu, hv, h⟩, rw image2_subset_image2_iff hm at h, -- exact ⟨mem_of_superset hu h.1, mem_of_superset hv h.2⟩ }, fun h ↦ image2_mem_map₂ h.1 h.2⟩ @[gcongr] theorem map₂_mono (hf : f₁ ≤ f₂) (hg : g₁ ≤ g₂) : map₂ m f₁ g₁ ≤ map₂ m f₂ g₂ := fun _ ⟨s, hs, t, ht, hst⟩ => ⟨s, hf hs, t, hg ht, hst⟩ @[gcongr] theorem map₂_mono_left (h : g₁ ≤ g₂) : map₂ m f g₁ ≤ map₂ m f g₂ := map₂_mono Subset.rfl h @[gcongr] theorem map₂_mono_right (h : f₁ ≤ f₂) : map₂ m f₁ g ≤ map₂ m f₂ g := map₂_mono h Subset.rfl @[simp] theorem le_map₂_iff {h : Filter γ} : h ≤ map₂ m f g ↔ ∀ ⦃s⦄, s ∈ f → ∀ ⦃t⦄, t ∈ g → image2 m s t ∈ h := ⟨fun H _ hs _ ht => H <\| image2_mem_map₂ hs ht, fun H _ ⟨_, hs, _, ht, hu⟩ => mem_of_superset (H hs ht) hu⟩ @[simp] theorem map₂_eq_bot_iff : map₂ m f g = ⊥ ↔ f = ⊥ ∨ g = ⊥ := by simp [← map_prod_eq_map₂] @[simp] theorem map₂_bot_left : map₂ m ⊥ g = ⊥ := map₂_eq_bot_iff.2 <\| .inl rfl @[simp] theorem map₂_bot_right : map₂ m f ⊥ = ⊥ := map₂_eq_bot_iff.2 <\| .inr rfl @[simp]	theorem map₂_neBot_iff : (map₂ m f g).NeBot ↔ f.NeBot ∧ g.NeBot := by simp [neBot_iff, not_or]	Mathlib/Order/Filter/NAry.lean	91	91
/- Copyright (c) 2015 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura, Jeremy Avigad -/ import Mathlib.Data.Finset.Basic import Mathlib.Data.Finset.Image /-! # Cardinality of a finite set This defines the cardinality of a `Finset` and provides induction principles for finsets. ## Main declarations * `Finset.card`: `#s : ℕ` returns the cardinality of `s : Finset α`. ### Induction principles * `Finset.strongInduction`: Strong induction * `Finset.strongInductionOn` * `Finset.strongDownwardInduction` * `Finset.strongDownwardInductionOn` * `Finset.case_strong_induction_on` * `Finset.Nonempty.strong_induction` -/ assert_not_exists Monoid open Function Multiset Nat variable {α β R : Type} namespace Finset variable {s t : Finset α} {a b : α} /-- `s.card` is the number of elements of `s`, aka its cardinality. The notation `#s` can be accessed in the `Finset` locale. -/ def card (s : Finset α) : ℕ := Multiset.card s.1 @[inherit_doc] scoped prefix:arg "#" => Finset.card theorem card_def (s : Finset α) : #s = Multiset.card s.1 := rfl @[simp] lemma card_val (s : Finset α) : Multiset.card s.1 = #s := rfl @[simp] theorem card_mk {m nodup} : #(⟨m, nodup⟩ : Finset α) = Multiset.card m := rfl @[simp] theorem card_empty : #(∅ : Finset α) = 0 := rfl @[gcongr] theorem card_le_card : s ⊆ t → #s ≤ #t := Multiset.card_le_card ∘ val_le_iff.mpr @[mono] theorem card_mono : Monotone (@card α) := by apply card_le_card @[simp] lemma card_eq_zero : #s = 0 ↔ s = ∅ := Multiset.card_eq_zero.trans val_eq_zero lemma card_ne_zero : #s ≠ 0 ↔ s.Nonempty := card_eq_zero.ne.trans nonempty_iff_ne_empty.symm @[simp] lemma card_pos : 0 < #s ↔ s.Nonempty := Nat.pos_iff_ne_zero.trans card_ne_zero @[simp] lemma one_le_card : 1 ≤ #s ↔ s.Nonempty := card_pos alias ⟨_, Nonempty.card_pos⟩ := card_pos alias ⟨_, Nonempty.card_ne_zero⟩ := card_ne_zero theorem card_ne_zero_of_mem (h : a ∈ s) : #s ≠ 0 := (not_congr card_eq_zero).2 <\| ne_empty_of_mem h @[simp] theorem card_singleton (a : α) : #{a} = 1 := Multiset.card_singleton _ theorem card_singleton_inter [DecidableEq α] : #({a} ∩ s) ≤ 1 := by obtain h \| h := Finset.decidableMem a s · simp [Finset.singleton_inter_of_not_mem h] · simp [Finset.singleton_inter_of_mem h] @[simp] theorem card_cons (h : a ∉ s) : #(s.cons a h) = #s + 1 := Multiset.card_cons _ _ section InsertErase variable [DecidableEq α] @[simp] theorem card_insert_of_not_mem (h : a ∉ s) : #(insert a s) = #s + 1 := by rw [← cons_eq_insert _ _ h, card_cons] theorem card_insert_of_mem (h : a ∈ s) : #(insert a s) = #s := by rw [insert_eq_of_mem h] theorem card_insert_le (a : α) (s : Finset α) : #(insert a s) ≤ #s + 1 := by by_cases h : a ∈ s · rw [insert_eq_of_mem h] exact Nat.le_succ _ · rw [card_insert_of_not_mem h] section variable {a b c d e f : α} theorem card_le_two : #{a, b} ≤ 2 := card_insert_le _ _ theorem card_le_three : #{a, b, c} ≤ 3 := (card_insert_le _ _).trans (Nat.succ_le_succ card_le_two) theorem card_le_four : #{a, b, c, d} ≤ 4 := (card_insert_le _ _).trans (Nat.succ_le_succ card_le_three) theorem card_le_five : #{a, b, c, d, e} ≤ 5 := (card_insert_le _ _).trans (Nat.succ_le_succ card_le_four) theorem card_le_six : #{a, b, c, d, e, f} ≤ 6 := (card_insert_le _ _).trans (Nat.succ_le_succ card_le_five) end /-- If `a ∈ s` is known, see also `Finset.card_insert_of_mem` and `Finset.card_insert_of_not_mem`. -/ theorem card_insert_eq_ite : #(insert a s) = if a ∈ s then #s else #s + 1 := by by_cases h : a ∈ s · rw [card_insert_of_mem h, if_pos h] · rw [card_insert_of_not_mem h, if_neg h] @[simp] theorem card_pair_eq_one_or_two : #{a, b} = 1 ∨ #{a, b} = 2 := by simp [card_insert_eq_ite] tauto @[simp] theorem card_pair (h : a ≠ b) : #{a, b} = 2 := by rw [card_insert_of_not_mem (not_mem_singleton.2 h), card_singleton] /-- $\#(s \setminus \{a\}) = \#s - 1$ if $a \in s$. -/ @[simp] theorem card_erase_of_mem : a ∈ s → #(s.erase a) = #s - 1 := Multiset.card_erase_of_mem @[simp] theorem card_erase_add_one : a ∈ s → #(s.erase a) + 1 = #s := Multiset.card_erase_add_one theorem card_erase_lt_of_mem : a ∈ s → #(s.erase a) < #s := Multiset.card_erase_lt_of_mem theorem card_erase_le : #(s.erase a) ≤ #s := Multiset.card_erase_le theorem pred_card_le_card_erase : #s - 1 ≤ #(s.erase a) := by by_cases h : a ∈ s · exact (card_erase_of_mem h).ge · rw [erase_eq_of_not_mem h] exact Nat.sub_le _ _ /-- If `a ∈ s` is known, see also `Finset.card_erase_of_mem` and `Finset.erase_eq_of_not_mem`. -/ theorem card_erase_eq_ite : #(s.erase a) = if a ∈ s then #s - 1 else #s := Multiset.card_erase_eq_ite end InsertErase @[simp] theorem card_range (n : ℕ) : #(range n) = n := Multiset.card_range n @[simp] theorem card_attach : #s.attach = #s := Multiset.card_attach end Finset open scoped Finset section ToMLListultiset variable [DecidableEq α] (m : Multiset α) (l : List α) theorem Multiset.card_toFinset : #m.toFinset = Multiset.card m.dedup := rfl theorem Multiset.toFinset_card_le : #m.toFinset ≤ Multiset.card m := card_le_card <\| dedup_le _ theorem Multiset.toFinset_card_of_nodup {m : Multiset α} (h : m.Nodup) : #m.toFinset = Multiset.card m := congr_arg card <\| Multiset.dedup_eq_self.mpr h theorem Multiset.dedup_card_eq_card_iff_nodup {m : Multiset α} : card m.dedup = card m ↔ m.Nodup := .trans ⟨fun h ↦ eq_of_le_of_card_le (dedup_le m) h.ge, congr_arg _⟩ dedup_eq_self theorem Multiset.toFinset_card_eq_card_iff_nodup {m : Multiset α} : #m.toFinset = card m ↔ m.Nodup := dedup_card_eq_card_iff_nodup theorem List.card_toFinset : #l.toFinset = l.dedup.length := rfl theorem List.toFinset_card_le : #l.toFinset ≤ l.length := Multiset.toFinset_card_le ⟦l⟧ theorem List.toFinset_card_of_nodup {l : List α} (h : l.Nodup) : #l.toFinset = l.length := Multiset.toFinset_card_of_nodup h end ToMLListultiset namespace Finset variable {s t u : Finset α} {f : α → β} {n : ℕ} @[simp] theorem length_toList (s : Finset α) : s.toList.length = #s := by rw [toList, ← Multiset.coe_card, Multiset.coe_toList, card_def] theorem card_image_le [DecidableEq β] : #(s.image f) ≤ #s := by simpa only [card_map] using (s.1.map f).toFinset_card_le theorem card_image_of_injOn [DecidableEq β] (H : Set.InjOn f s) : #(s.image f) = #s := by simp only [card, image_val_of_injOn H, card_map] theorem injOn_of_card_image_eq [DecidableEq β] (H : #(s.image f) = #s) : Set.InjOn f s := by rw [card_def, card_def, image, toFinset] at H dsimp only at H have : (s.1.map f).dedup = s.1.map f := by refine Multiset.eq_of_le_of_card_le (Multiset.dedup_le _) ?_ simp only [H, Multiset.card_map, le_rfl] rw [Multiset.dedup_eq_self] at this exact inj_on_of_nodup_map this theorem card_image_iff [DecidableEq β] : #(s.image f) = #s ↔ Set.InjOn f s := ⟨injOn_of_card_image_eq, card_image_of_injOn⟩ theorem card_image_of_injective [DecidableEq β] (s : Finset α) (H : Injective f) : #(s.image f) = #s := card_image_of_injOn fun _ _ _ _ h => H h theorem fiber_card_ne_zero_iff_mem_image (s : Finset α) (f : α → β) [DecidableEq β] (y : β) : #(s.filter fun x ↦ f x = y) ≠ 0 ↔ y ∈ s.image f := by rw [← Nat.pos_iff_ne_zero, card_pos, fiber_nonempty_iff_mem_image] lemma card_filter_le_iff (s : Finset α) (P : α → Prop) [DecidablePred P] (n : ℕ) : #(s.filter P) ≤ n ↔ ∀ s' ⊆ s, n < #s' → ∃ a ∈ s', ¬ P a := (s.1.card_filter_le_iff P n).trans ⟨fun H s' hs' h ↦ H s'.1 (by aesop) h, fun H s' hs' h ↦ H ⟨s', nodup_of_le hs' s.2⟩ (fun _ hx ↦ Multiset.subset_of_le hs' hx) h⟩ @[simp] theorem card_map (f : α ↪ β) : #(s.map f) = #s := Multiset.card_map _ _ @[simp] theorem card_subtype (p : α → Prop) [DecidablePred p] (s : Finset α) : #(s.subtype p) = #(s.filter p) := by simp [Finset.subtype] theorem card_filter_le (s : Finset α) (p : α → Prop) [DecidablePred p] : #(s.filter p) ≤ #s := card_le_card <\| filter_subset _ _ theorem eq_of_subset_of_card_le {s t : Finset α} (h : s ⊆ t) (h₂ : #t ≤ #s) : s = t := eq_of_veq <\| Multiset.eq_of_le_of_card_le (val_le_iff.mpr h) h₂ theorem eq_iff_card_le_of_subset (hst : s ⊆ t) : #t ≤ #s ↔ s = t := ⟨eq_of_subset_of_card_le hst, (ge_of_eq <\| congr_arg _ ·)⟩ theorem eq_of_superset_of_card_ge (hst : s ⊆ t) (hts : #t ≤ #s) : t = s := (eq_of_subset_of_card_le hst hts).symm theorem eq_iff_card_ge_of_superset (hst : s ⊆ t) : #t ≤ #s ↔ t = s := (eq_iff_card_le_of_subset hst).trans eq_comm theorem subset_iff_eq_of_card_le (h : #t ≤ #s) : s ⊆ t ↔ s = t := ⟨fun hst => eq_of_subset_of_card_le hst h, Eq.subset'⟩ theorem map_eq_of_subset {f : α ↪ α} (hs : s.map f ⊆ s) : s.map f = s := eq_of_subset_of_card_le hs (card_map _).ge theorem card_filter_eq_iff {p : α → Prop} [DecidablePred p] : #(s.filter p) = #s ↔ ∀ x ∈ s, p x := by rw [(card_filter_le s p).eq_iff_not_lt, not_lt, eq_iff_card_le_of_subset (filter_subset p s), filter_eq_self] alias ⟨filter_card_eq, _⟩ := card_filter_eq_iff theorem card_filter_eq_zero_iff {p : α → Prop} [DecidablePred p] : #(s.filter p) = 0 ↔ ∀ x ∈ s, ¬ p x := by rw [card_eq_zero, filter_eq_empty_iff] nonrec lemma card_lt_card (h : s ⊂ t) : #s < #t := card_lt_card <\| val_lt_iff.2 h lemma card_strictMono : StrictMono (card : Finset α → ℕ) := fun _ _ ↦ card_lt_card theorem card_eq_of_bijective (f : ∀ i, i < n → α) (hf : ∀ a ∈ s, ∃ i, ∃ h : i < n, f i h = a) (hf' : ∀ i (h : i < n), f i h ∈ s) (f_inj : ∀ i j (hi : i < n) (hj : j < n), f i hi = f j hj → i = j) : #s = n := by classical have : s = (range n).attach.image fun i => f i.1 (mem_range.1 i.2) := by ext a suffices _ : a ∈ s ↔ ∃ (i : _) (hi : i ∈ range n), f i (mem_range.1 hi) = a by simpa only [mem_image, mem_attach, true_and, Subtype.exists] constructor · intro ha; obtain ⟨i, hi, rfl⟩ := hf a ha; use i, mem_range.2 hi · rintro ⟨i, hi, rfl⟩; apply hf' calc #s = #((range n).attach.image fun i => f i.1 (mem_range.1 i.2)) := by rw [this] _ = #(range n).attach := ?_ _ = #(range n) := card_attach _ = n := card_range n apply card_image_of_injective intro ⟨i, hi⟩ ⟨j, hj⟩ eq exact Subtype.eq <\| f_inj i j (mem_range.1 hi) (mem_range.1 hj) eq section bij variable {t : Finset β} /-- Reorder a finset. The difference with `Finset.card_bij'` is that the bijection is specified as a surjective injection, rather than by an inverse function. The difference with `Finset.card_nbij` is that the bijection is allowed to use membership of the domain, rather than being a non-dependent function. -/ lemma card_bij (i : ∀ a ∈ s, β) (hi : ∀ a ha, i a ha ∈ t) (i_inj : ∀ a₁ ha₁ a₂ ha₂, i a₁ ha₁ = i a₂ ha₂ → a₁ = a₂) (i_surj : ∀ b ∈ t, ∃ a ha, i a ha = b) : #s = #t := by classical calc #s = #s.attach := card_attach.symm _ = #(s.attach.image fun a ↦ i a.1 a.2) := Eq.symm ?_ _ = #t := ?_ · apply card_image_of_injective intro ⟨_, _⟩ ⟨_, _⟩ h simpa using i_inj _ _ _ _ h · congr 1 ext b constructor <;> intro h · obtain ⟨_, _, rfl⟩ := mem_image.1 h; apply hi · obtain ⟨a, ha, rfl⟩ := i_surj b h; exact mem_image.2 ⟨⟨a, ha⟩, by simp⟩ /-- Reorder a finset. The difference with `Finset.card_bij` is that the bijection is specified with an inverse, rather than as a surjective injection. The difference with `Finset.card_nbij'` is that the bijection and its inverse are allowed to use membership of the domains, rather than being non-dependent functions. -/ lemma card_bij' (i : ∀ a ∈ s, β) (j : ∀ a ∈ t, α) (hi : ∀ a ha, i a ha ∈ t) (hj : ∀ a ha, j a ha ∈ s) (left_inv : ∀ a ha, j (i a ha) (hi a ha) = a) (right_inv : ∀ a ha, i (j a ha) (hj a ha) = a) : #s = #t := by refine card_bij i hi (fun a1 h1 a2 h2 eq ↦ ?_) (fun b hb ↦ ⟨_, hj b hb, right_inv b hb⟩) rw [← left_inv a1 h1, ← left_inv a2 h2] simp only [eq] /-- Reorder a finset. The difference with `Finset.card_nbij'` is that the bijection is specified as a surjective injection, rather than by an inverse function. The difference with `Finset.card_bij` is that the bijection is a non-dependent function, rather than being allowed to use membership of the domain. -/ lemma card_nbij (i : α → β) (hi : ∀ a ∈ s, i a ∈ t) (i_inj : (s : Set α).InjOn i) (i_surj : (s : Set α).SurjOn i t) : #s = #t := card_bij (fun a _ ↦ i a) hi i_inj (by simpa using i_surj) /-- Reorder a finset. The difference with `Finset.card_nbij` is that the bijection is specified with an inverse, rather than as a surjective injection. The difference with `Finset.card_bij'` is that the bijection and its inverse are non-dependent functions, rather than being allowed to use membership of the domains. The difference with `Finset.card_equiv` is that bijectivity is only required to hold on the domains, rather than on the entire types. -/ lemma card_nbij' (i : α → β) (j : β → α) (hi : ∀ a ∈ s, i a ∈ t) (hj : ∀ a ∈ t, j a ∈ s) (left_inv : ∀ a ∈ s, j (i a) = a) (right_inv : ∀ a ∈ t, i (j a) = a) : #s = #t := card_bij' (fun a _ ↦ i a) (fun b _ ↦ j b) hi hj left_inv right_inv /-- Specialization of `Finset.card_nbij'` that automatically fills in most arguments. See `Fintype.card_equiv` for the version where `s` and `t` are `univ`. -/ lemma card_equiv (e : α ≃ β) (hst : ∀ i, i ∈ s ↔ e i ∈ t) : #s = #t := by refine card_nbij' e e.symm ?_ ?_ ?_ ?_ <;> simp [hst] /-- Specialization of `Finset.card_nbij` that automatically fills in most arguments. See `Fintype.card_bijective` for the version where `s` and `t` are `univ`. -/ lemma card_bijective (e : α → β) (he : e.Bijective) (hst : ∀ i, i ∈ s ↔ e i ∈ t) : #s = #t := card_equiv (.ofBijective e he) hst lemma card_le_card_of_injOn (f : α → β) (hf : ∀ a ∈ s, f a ∈ t) (f_inj : (s : Set α).InjOn f) : #s ≤ #t := by classical calc #s = #(s.image f) := (card_image_of_injOn f_inj).symm _ ≤ #t := card_le_card <\| image_subset_iff.2 hf lemma card_le_card_of_injective {f : s → t} (hf : f.Injective) : #s ≤ #t := by rcases s.eq_empty_or_nonempty with rfl \| ⟨a₀, ha₀⟩ · simp · classical let f' : α → β := fun a => f (if ha : a ∈ s then ⟨a, ha⟩ else ⟨a₀, ha₀⟩) apply card_le_card_of_injOn f' · aesop · intro a₁ ha₁ a₂ ha₂ haa rw [mem_coe] at ha₁ ha₂ simp only [f', ha₁, ha₂, ← Subtype.ext_iff] at haa exact Subtype.ext_iff.mp (hf haa) lemma card_le_card_of_surjOn (f : α → β) (hf : Set.SurjOn f s t) : #t ≤ #s := by classical unfold Set.SurjOn at hf; exact (card_le_card (mod_cast hf)).trans card_image_le /-- If there are more pigeons than pigeonholes, then there are two pigeons in the same pigeonhole. -/ theorem exists_ne_map_eq_of_card_lt_of_maps_to {t : Finset β} (hc : #t < #s) {f : α → β} (hf : ∀ a ∈ s, f a ∈ t) : ∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ f x = f y := by classical by_contra! hz refine hc.not_le (card_le_card_of_injOn f hf ?_) intro x hx y hy contrapose exact hz x hx y hy lemma le_card_of_inj_on_range (f : ℕ → α) (hf : ∀ i < n, f i ∈ s) (f_inj : ∀ i < n, ∀ j < n, f i = f j → i = j) : n ≤ #s := calc n = #(range n) := (card_range n).symm _ ≤ #s := card_le_card_of_injOn f (by simpa only [mem_range]) (by simpa) lemma surjOn_of_injOn_of_card_le (f : α → β) (hf : Set.MapsTo f s t) (hinj : Set.InjOn f s) (hst : #t ≤ #s) : Set.SurjOn f s t := by classical suffices s.image f = t by simp [← this, Set.SurjOn] have : s.image f ⊆ t := by aesop (add simp Finset.subset_iff) exact eq_of_subset_of_card_le this (hst.trans_eq (card_image_of_injOn hinj).symm) lemma surj_on_of_inj_on_of_card_le (f : ∀ a ∈ s, β) (hf : ∀ a ha, f a ha ∈ t) (hinj : ∀ a₁ a₂ ha₁ ha₂, f a₁ ha₁ = f a₂ ha₂ → a₁ = a₂) (hst : #t ≤ #s) : ∀ b ∈ t, ∃ a ha, b = f a ha := by let f' : s → β := fun a ↦ f a a.2 have hinj' : Set.InjOn f' s.attach := fun x hx y hy hxy ↦ Subtype.ext (hinj _ _ x.2 y.2 hxy) have hmapsto' : Set.MapsTo f' s.attach t := fun x hx ↦ hf _ _ intro b hb obtain ⟨a, ha, rfl⟩ := surjOn_of_injOn_of_card_le _ hmapsto' hinj' (by rwa [card_attach]) hb exact ⟨a, a.2, rfl⟩ lemma injOn_of_surjOn_of_card_le (f : α → β) (hf : Set.MapsTo f s t) (hsurj : Set.SurjOn f s t) (hst : #s ≤ #t) : Set.InjOn f s := by classical have : s.image f = t := Finset.coe_injective <\| by simp [hsurj.image_eq_of_mapsTo hf] have : #(s.image f) = #t := by rw [this] have : #(s.image f) ≤ #s := card_image_le rw [← card_image_iff] omega theorem inj_on_of_surj_on_of_card_le (f : ∀ a ∈ s, β) (hf : ∀ a ha, f a ha ∈ t) (hsurj : ∀ b ∈ t, ∃ a ha, f a ha = b) (hst : #s ≤ #t) ⦃a₁⦄ (ha₁ : a₁ ∈ s) ⦃a₂⦄ (ha₂ : a₂ ∈ s) (ha₁a₂ : f a₁ ha₁ = f a₂ ha₂) : a₁ = a₂ := by let f' : s → β := fun a ↦ f a a.2 have hsurj' : Set.SurjOn f' s.attach t := fun x hx ↦ by simpa [f'] using hsurj x hx have hinj' := injOn_of_surjOn_of_card_le f' (fun x hx ↦ hf _ _) hsurj' (by simpa) exact congrArg Subtype.val (@hinj' ⟨a₁, ha₁⟩ (by simp) ⟨a₂, ha₂⟩ (by simp) ha₁a₂) end bij @[simp] theorem card_disjUnion (s t : Finset α) (h) : #(s.disjUnion t h) = #s + #t := Multiset.card_add _ _ /-! ### Lattice structure -/ section Lattice variable [DecidableEq α] theorem card_union_add_card_inter (s t : Finset α) : #(s ∪ t) + #(s ∩ t) = #s + #t := Finset.induction_on t (by simp) fun a r har h => by by_cases a ∈ s <;> simp [, ← Nat.add_assoc, Nat.add_right_comm _ 1] theorem card_inter_add_card_union (s t : Finset α) : #(s ∩ t) + #(s ∪ t) = #s + #t := by rw [Nat.add_comm, card_union_add_card_inter] lemma card_union (s t : Finset α) : #(s ∪ t) = #s + #t - #(s ∩ t) := by rw [← card_union_add_card_inter, Nat.add_sub_cancel] lemma card_inter (s t : Finset α) : #(s ∩ t) = #s + #t - #(s ∪ t) := by rw [← card_inter_add_card_union, Nat.add_sub_cancel] theorem card_union_le (s t : Finset α) : #(s ∪ t) ≤ #s + #t := card_union_add_card_inter s t ▸ Nat.le_add_right _ _ lemma card_union_eq_card_add_card : #(s ∪ t) = #s + #t ↔ Disjoint s t := by rw [← card_union_add_card_inter]; simp [disjoint_iff_inter_eq_empty] @[simp] alias ⟨_, card_union_of_disjoint⟩ := card_union_eq_card_add_card theorem card_sdiff (h : s ⊆ t) : #(t \ s) = #t - #s := by suffices #(t \ s) = #(t \ s ∪ s) - #s by rwa [sdiff_union_of_subset h] at this rw [card_union_of_disjoint sdiff_disjoint, Nat.add_sub_cancel_right] theorem card_sdiff_add_card_eq_card {s t : Finset α} (h : s ⊆ t) : #(t \ s) + #s = #t := ((Nat.sub_eq_iff_eq_add (card_le_card h)).mp (card_sdiff h).symm).symm theorem le_card_sdiff (s t : Finset α) : #t - #s ≤ #(t \ s) := calc #t - #s ≤ #t - #(s ∩ t) := Nat.sub_le_sub_left (card_le_card inter_subset_left) _ _ = #(t \ (s ∩ t)) := (card_sdiff inter_subset_right).symm _ ≤ #(t \ s) := by rw [sdiff_inter_self_right t s] theorem card_le_card_sdiff_add_card : #s ≤ #(s \ t) + #t := Nat.sub_le_iff_le_add.1 <\| le_card_sdiff _ _ theorem card_sdiff_add_card (s t : Finset α) : #(s \ t) + #t = #(s ∪ t) := by rw [← card_union_of_disjoint sdiff_disjoint, sdiff_union_self_eq_union] lemma card_sdiff_comm (h : #s = #t) : #(s \ t) = #(t \ s) := Nat.add_right_cancel (m := #t) <\| by simp_rw [card_sdiff_add_card, ← h, card_sdiff_add_card, union_comm] theorem sdiff_nonempty_of_card_lt_card (h : #s < #t) : (t \ s).Nonempty := by rw [nonempty_iff_ne_empty, Ne, sdiff_eq_empty_iff_subset] exact fun h' ↦ h.not_le (card_le_card h') omit [DecidableEq α] in theorem exists_mem_not_mem_of_card_lt_card (h : #s < #t) : ∃ e, e ∈ t ∧ e ∉ s := by classical simpa [Finset.Nonempty] using sdiff_nonempty_of_card_lt_card h @[simp] lemma card_sdiff_add_card_inter (s t : Finset α) : #(s \ t) + #(s ∩ t) = #s := by	rw [← card_union_of_disjoint (disjoint_sdiff_inter _ _), sdiff_union_inter]	Mathlib/Data/Finset/Card.lean	537	538
/- Copyright (c) 2022 Violeta Hernández Palacios. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Violeta Hernández Palacios -/ import Mathlib.Data.Finsupp.Basic import Mathlib.Data.List.AList /-! # Connections between `Finsupp` and `AList` ## Main definitions * `Finsupp.toAList` * `AList.lookupFinsupp`: converts an association list into a finitely supported function via `AList.lookup`, sending absent keys to zero. -/ namespace Finsupp variable {α M : Type*} [Zero M] /-- Produce an association list for the finsupp over its support using choice. -/ @[simps] noncomputable def toAList (f : α →₀ M) : AList fun _x : α => M := ⟨f.graph.toList.map Prod.toSigma, by rw [List.NodupKeys, List.keys, List.map_map, Prod.fst_comp_toSigma, List.nodup_map_iff_inj_on] · rintro ⟨b, m⟩ hb ⟨c, n⟩ hc (rfl : b = c) rw [Finset.mem_toList, Finsupp.mem_graph_iff] at hb hc dsimp at hb hc rw [← hc.1, hb.1] · apply Finset.nodup_toList⟩ @[simp] theorem toAList_keys_toFinset [DecidableEq α] (f : α →₀ M) : f.toAList.keys.toFinset = f.support := by ext	simp [toAList, AList.mem_keys, AList.keys, List.keys] @[simp] theorem mem_toAlist {f : α →₀ M} {x : α} : x ∈ f.toAList ↔ f x ≠ 0 := by	Mathlib/Data/Finsupp/AList.lean	41	44
/- Copyright (c) 2020 Kenji Nakagawa. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenji Nakagawa, Anne Baanen, Filippo A. E. Nuccio -/ import Mathlib.Algebra.Algebra.Subalgebra.Pointwise import Mathlib.Algebra.Polynomial.FieldDivision import Mathlib.RingTheory.Spectrum.Maximal.Localization import Mathlib.RingTheory.ChainOfDivisors import Mathlib.RingTheory.DedekindDomain.Basic import Mathlib.RingTheory.FractionalIdeal.Operations import Mathlib.Algebra.Squarefree.Basic /-! # Dedekind domains and ideals In this file, we show a ring is a Dedekind domain iff all fractional ideals are invertible. Then we prove some results on the unique factorization monoid structure of the ideals. ## Main definitions - `IsDedekindDomainInv` alternatively defines a Dedekind domain as an integral domain where every nonzero fractional ideal is invertible. - `isDedekindDomainInv_iff` shows that this does note depend on the choice of field of fractions. - `IsDedekindDomain.HeightOneSpectrum` defines the type of nonzero prime ideals of `R`. ## Main results: - `isDedekindDomain_iff_isDedekindDomainInv` - `Ideal.uniqueFactorizationMonoid` ## Implementation notes The definitions that involve a field of fractions choose a canonical field of fractions, but are independent of that choice. The `..._iff` lemmas express this independence. Often, definitions assume that Dedekind domains are not fields. We found it more practical to add a `(h : ¬ IsField A)` assumption whenever this is explicitly needed. ## References * [D. Marcus, Number Fields][marcus1977number] * [J.W.S. Cassels, A. Fröhlich, Algebraic Number Theory][cassels1967algebraic] * [J. Neukirch, Algebraic Number Theory][Neukirch1992] ## Tags dedekind domain, dedekind ring -/ variable (R A K : Type) [CommRing R] [CommRing A] [Field K] open scoped nonZeroDivisors Polynomial section Inverse namespace FractionalIdeal variable {R₁ : Type} [CommRing R₁] [IsDomain R₁] [Algebra R₁ K] [IsFractionRing R₁ K] variable {I J : FractionalIdeal R₁⁰ K} noncomputable instance : Inv (FractionalIdeal R₁⁰ K) := ⟨fun I => 1 / I⟩ theorem inv_eq : I⁻¹ = 1 / I := rfl theorem inv_zero' : (0 : FractionalIdeal R₁⁰ K)⁻¹ = 0 := div_zero theorem inv_nonzero {J : FractionalIdeal R₁⁰ K} (h : J ≠ 0) : J⁻¹ = ⟨(1 : FractionalIdeal R₁⁰ K) / J, fractional_div_of_nonzero h⟩ := div_nonzero h theorem coe_inv_of_nonzero {J : FractionalIdeal R₁⁰ K} (h : J ≠ 0) : (↑J⁻¹ : Submodule R₁ K) = IsLocalization.coeSubmodule K ⊤ / (J : Submodule R₁ K) := by simp_rw [inv_nonzero _ h, coe_one, coe_mk, IsLocalization.coeSubmodule_top] variable {K} theorem mem_inv_iff (hI : I ≠ 0) {x : K} : x ∈ I⁻¹ ↔ ∀ y ∈ I, x * y ∈ (1 : FractionalIdeal R₁⁰ K) := mem_div_iff_of_nonzero hI theorem inv_anti_mono (hI : I ≠ 0) (hJ : J ≠ 0) (hIJ : I ≤ J) : J⁻¹ ≤ I⁻¹ := by -- Porting note: in Lean3, introducing `x` would just give `x ∈ J⁻¹ → x ∈ I⁻¹`, but -- in Lean4, it goes all the way down to the subtypes intro x simp only [val_eq_coe, mem_coe, mem_inv_iff hJ, mem_inv_iff hI] exact fun h y hy => h y (hIJ hy) theorem le_self_mul_inv {I : FractionalIdeal R₁⁰ K} (hI : I ≤ (1 : FractionalIdeal R₁⁰ K)) : I ≤ I * I⁻¹ := le_self_mul_one_div hI variable (K) theorem coe_ideal_le_self_mul_inv (I : Ideal R₁) : (I : FractionalIdeal R₁⁰ K) ≤ I * (I : FractionalIdeal R₁⁰ K)⁻¹ := le_self_mul_inv coeIdeal_le_one /-- `I⁻¹` is the inverse of `I` if `I` has an inverse. -/ theorem right_inverse_eq (I J : FractionalIdeal R₁⁰ K) (h : I * J = 1) : J = I⁻¹ := by have hI : I ≠ 0 := ne_zero_of_mul_eq_one I J h suffices h' : I * (1 / I) = 1 from congr_arg Units.inv <\| @Units.ext _ _ (Units.mkOfMulEqOne _ _ h) (Units.mkOfMulEqOne _ _ h') rfl apply le_antisymm · apply mul_le.mpr _ intro x hx y hy rw [mul_comm] exact (mem_div_iff_of_nonzero hI).mp hy x hx rw [← h] apply mul_left_mono I apply (le_div_iff_of_nonzero hI).mpr _ intro y hy x hx rw [mul_comm] exact mul_mem_mul hy hx theorem mul_inv_cancel_iff {I : FractionalIdeal R₁⁰ K} : I * I⁻¹ = 1 ↔ ∃ J, I * J = 1 := ⟨fun h => ⟨I⁻¹, h⟩, fun ⟨J, hJ⟩ => by rwa [← right_inverse_eq K I J hJ]⟩ theorem mul_inv_cancel_iff_isUnit {I : FractionalIdeal R₁⁰ K} : I * I⁻¹ = 1 ↔ IsUnit I := (mul_inv_cancel_iff K).trans isUnit_iff_exists_inv.symm variable {K' : Type} [Field K'] [Algebra R₁ K'] [IsFractionRing R₁ K'] @[simp] protected theorem map_inv (I : FractionalIdeal R₁⁰ K) (h : K ≃ₐ[R₁] K') : I⁻¹.map (h : K →ₐ[R₁] K') = (I.map h)⁻¹ := by rw [inv_eq, FractionalIdeal.map_div, FractionalIdeal.map_one, inv_eq] open Submodule Submodule.IsPrincipal @[simp] theorem spanSingleton_inv (x : K) : (spanSingleton R₁⁰ x)⁻¹ = spanSingleton _ x⁻¹ := one_div_spanSingleton x theorem spanSingleton_div_spanSingleton (x y : K) : spanSingleton R₁⁰ x / spanSingleton R₁⁰ y = spanSingleton R₁⁰ (x / y) := by rw [div_spanSingleton, mul_comm, spanSingleton_mul_spanSingleton, div_eq_mul_inv] theorem spanSingleton_div_self {x : K} (hx : x ≠ 0) : spanSingleton R₁⁰ x / spanSingleton R₁⁰ x = 1 := by rw [spanSingleton_div_spanSingleton, div_self hx, spanSingleton_one] theorem coe_ideal_span_singleton_div_self {x : R₁} (hx : x ≠ 0) : (Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K) / Ideal.span ({x} : Set R₁) = 1 := by rw [coeIdeal_span_singleton, spanSingleton_div_self K <\| (map_ne_zero_iff _ <\| FaithfulSMul.algebraMap_injective R₁ K).mpr hx] theorem spanSingleton_mul_inv {x : K} (hx : x ≠ 0) : spanSingleton R₁⁰ x (spanSingleton R₁⁰ x)⁻¹ = 1 := by rw [spanSingleton_inv, spanSingleton_mul_spanSingleton, mul_inv_cancel₀ hx, spanSingleton_one] theorem coe_ideal_span_singleton_mul_inv {x : R₁} (hx : x ≠ 0) : (Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K) * (Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K)⁻¹ = 1 := by rw [coeIdeal_span_singleton, spanSingleton_mul_inv K <\| (map_ne_zero_iff _ <\| FaithfulSMul.algebraMap_injective R₁ K).mpr hx] theorem spanSingleton_inv_mul {x : K} (hx : x ≠ 0) : (spanSingleton R₁⁰ x)⁻¹ * spanSingleton R₁⁰ x = 1 := by rw [mul_comm, spanSingleton_mul_inv K hx] theorem coe_ideal_span_singleton_inv_mul {x : R₁} (hx : x ≠ 0) : (Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K)⁻¹ * Ideal.span ({x} : Set R₁) = 1 := by rw [mul_comm, coe_ideal_span_singleton_mul_inv K hx] theorem mul_generator_self_inv {R₁ : Type} [CommRing R₁] [Algebra R₁ K] [IsLocalization R₁⁰ K] (I : FractionalIdeal R₁⁰ K) [Submodule.IsPrincipal (I : Submodule R₁ K)] (h : I ≠ 0) : I spanSingleton _ (generator (I : Submodule R₁ K))⁻¹ = 1 := by -- Rewrite only the `I` that appears alone. conv_lhs => congr; rw [eq_spanSingleton_of_principal I] rw [spanSingleton_mul_spanSingleton, mul_inv_cancel₀, spanSingleton_one] intro generator_I_eq_zero apply h rw [eq_spanSingleton_of_principal I, generator_I_eq_zero, spanSingleton_zero] theorem invertible_of_principal (I : FractionalIdeal R₁⁰ K) [Submodule.IsPrincipal (I : Submodule R₁ K)] (h : I ≠ 0) : I * I⁻¹ = 1 := mul_div_self_cancel_iff.mpr ⟨spanSingleton _ (generator (I : Submodule R₁ K))⁻¹, mul_generator_self_inv _ I h⟩ theorem invertible_iff_generator_nonzero (I : FractionalIdeal R₁⁰ K) [Submodule.IsPrincipal (I : Submodule R₁ K)] : I * I⁻¹ = 1 ↔ generator (I : Submodule R₁ K) ≠ 0 := by constructor · intro hI hg apply ne_zero_of_mul_eq_one _ _ hI rw [eq_spanSingleton_of_principal I, hg, spanSingleton_zero] · intro hg apply invertible_of_principal rw [eq_spanSingleton_of_principal I] intro hI have := mem_spanSingleton_self R₁⁰ (generator (I : Submodule R₁ K)) rw [hI, mem_zero_iff] at this contradiction theorem isPrincipal_inv (I : FractionalIdeal R₁⁰ K) [Submodule.IsPrincipal (I : Submodule R₁ K)] (h : I ≠ 0) : Submodule.IsPrincipal I⁻¹.1 := by rw [val_eq_coe, isPrincipal_iff] use (generator (I : Submodule R₁ K))⁻¹ have hI : I * spanSingleton _ (generator (I : Submodule R₁ K))⁻¹ = 1 := mul_generator_self_inv _ I h exact (right_inverse_eq _ I (spanSingleton _ (generator (I : Submodule R₁ K))⁻¹) hI).symm variable {K} lemma den_mem_inv {I : FractionalIdeal R₁⁰ K} (hI : I ≠ ⊥) : (algebraMap R₁ K) (I.den : R₁) ∈ I⁻¹ := by rw [mem_inv_iff hI] intro i hi rw [← Algebra.smul_def (I.den : R₁) i, ← mem_coe, coe_one] suffices Submodule.map (Algebra.linearMap R₁ K) I.num ≤ 1 from this <\| (den_mul_self_eq_num I).symm ▸ smul_mem_pointwise_smul i I.den I.coeToSubmodule hi apply le_trans <\| map_mono (show I.num ≤ 1 by simp only [Ideal.one_eq_top, le_top, bot_eq_zero]) rw [Ideal.one_eq_top, Submodule.map_top, one_eq_range] lemma num_le_mul_inv (I : FractionalIdeal R₁⁰ K) : I.num ≤ I * I⁻¹ := by by_cases hI : I = 0 · rw [hI, num_zero_eq <\| FaithfulSMul.algebraMap_injective R₁ K, zero_mul, zero_eq_bot, coeIdeal_bot] · rw [mul_comm, ← den_mul_self_eq_num'] exact mul_right_mono I <\| spanSingleton_le_iff_mem.2 (den_mem_inv hI) lemma bot_lt_mul_inv {I : FractionalIdeal R₁⁰ K} (hI : I ≠ ⊥) : ⊥ < I * I⁻¹ := lt_of_lt_of_le (coeIdeal_ne_zero.2 (hI ∘ num_eq_zero_iff.1)).bot_lt I.num_le_mul_inv noncomputable instance : InvOneClass (FractionalIdeal R₁⁰ K) := { inv_one := div_one } end FractionalIdeal section IsDedekindDomainInv variable [IsDomain A] /-- A Dedekind domain is an integral domain such that every fractional ideal has an inverse. This is equivalent to `IsDedekindDomain`. In particular we provide a `fractional_ideal.comm_group_with_zero` instance, assuming `IsDedekindDomain A`, which implies `IsDedekindDomainInv`. For integral ideals, `IsDedekindDomain`(`_inv`) implies only `Ideal.cancelCommMonoidWithZero`. -/ def IsDedekindDomainInv : Prop := ∀ I ≠ (⊥ : FractionalIdeal A⁰ (FractionRing A)), I * I⁻¹ = 1 open FractionalIdeal variable {R A K} theorem isDedekindDomainInv_iff [Algebra A K] [IsFractionRing A K] : IsDedekindDomainInv A ↔ ∀ I ≠ (⊥ : FractionalIdeal A⁰ K), I * I⁻¹ = 1 := by let h : FractionalIdeal A⁰ (FractionRing A) ≃+* FractionalIdeal A⁰ K := FractionalIdeal.mapEquiv (FractionRing.algEquiv A K) refine h.toEquiv.forall_congr (fun {x} => ?_) rw [← h.toEquiv.apply_eq_iff_eq] simp [h, IsDedekindDomainInv] theorem FractionalIdeal.adjoinIntegral_eq_one_of_isUnit [Algebra A K] [IsFractionRing A K] (x : K) (hx : IsIntegral A x) (hI : IsUnit (adjoinIntegral A⁰ x hx)) : adjoinIntegral A⁰ x hx = 1 := by set I := adjoinIntegral A⁰ x hx have mul_self : IsIdempotentElem I := by apply coeToSubmodule_injective simp only [coe_mul, adjoinIntegral_coe, I] rw [(Algebra.adjoin A {x}).isIdempotentElem_toSubmodule] convert congr_arg (· * I⁻¹) mul_self <;> simp only [(mul_inv_cancel_iff_isUnit K).mpr hI, mul_assoc, mul_one] namespace IsDedekindDomainInv variable [Algebra A K] [IsFractionRing A K] (h : IsDedekindDomainInv A) include h theorem mul_inv_eq_one {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : I * I⁻¹ = 1 := isDedekindDomainInv_iff.mp h I hI theorem inv_mul_eq_one {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : I⁻¹ * I = 1 := (mul_comm _ _).trans (h.mul_inv_eq_one hI) protected theorem isUnit {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : IsUnit I := isUnit_of_mul_eq_one _ _ (h.mul_inv_eq_one hI) theorem isNoetherianRing : IsNoetherianRing A := by refine isNoetherianRing_iff.mpr ⟨fun I : Ideal A => ?_⟩ by_cases hI : I = ⊥ · rw [hI]; apply Submodule.fg_bot have hI : (I : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr hI exact I.fg_of_isUnit (IsFractionRing.injective A (FractionRing A)) (h.isUnit hI) theorem integrallyClosed : IsIntegrallyClosed A := by -- It suffices to show that for integral `x`, -- `A[x]` (which is a fractional ideal) is in fact equal to `A`. refine (isIntegrallyClosed_iff (FractionRing A)).mpr (fun {x hx} => ?_) rw [← Set.mem_range, ← Algebra.mem_bot, ← Subalgebra.mem_toSubmodule, Algebra.toSubmodule_bot, Submodule.one_eq_span, ← coe_spanSingleton A⁰ (1 : FractionRing A), spanSingleton_one, ← FractionalIdeal.adjoinIntegral_eq_one_of_isUnit x hx (h.isUnit _)] · exact mem_adjoinIntegral_self A⁰ x hx · exact fun h => one_ne_zero (eq_zero_iff.mp h 1 (Algebra.adjoin A {x}).one_mem) open Ring theorem dimensionLEOne : DimensionLEOne A := ⟨by -- We're going to show that `P` is maximal because any (maximal) ideal `M` -- that is strictly larger would be `⊤`. rintro P P_ne hP refine Ideal.isMaximal_def.mpr ⟨hP.ne_top, fun M hM => ?_⟩ -- We may assume `P` and `M` (as fractional ideals) are nonzero. have P'_ne : (P : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr P_ne have M'_ne : (M : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr hM.ne_bot -- In particular, we'll show `M⁻¹ * P ≤ P` suffices (M⁻¹ : FractionalIdeal A⁰ (FractionRing A)) * P ≤ P by rw [eq_top_iff, ← coeIdeal_le_coeIdeal (FractionRing A), coeIdeal_top] calc (1 : FractionalIdeal A⁰ (FractionRing A)) = _ * _ * _ := ?_ _ ≤ _ * _ := mul_right_mono ((P : FractionalIdeal A⁰ (FractionRing A))⁻¹ * M : FractionalIdeal A⁰ (FractionRing A)) this _ = M := ?_ · rw [mul_assoc, ← mul_assoc (P : FractionalIdeal A⁰ (FractionRing A)), h.mul_inv_eq_one P'_ne, one_mul, h.inv_mul_eq_one M'_ne] · rw [← mul_assoc (P : FractionalIdeal A⁰ (FractionRing A)), h.mul_inv_eq_one P'_ne, one_mul] -- Suppose we have `x ∈ M⁻¹ * P`, then in fact `x = algebraMap _ _ y` for some `y`. intro x hx have le_one : (M⁻¹ : FractionalIdeal A⁰ (FractionRing A)) * P ≤ 1 := by rw [← h.inv_mul_eq_one M'_ne] exact mul_left_mono _ ((coeIdeal_le_coeIdeal (FractionRing A)).mpr hM.le) obtain ⟨y, _hy, rfl⟩ := (mem_coeIdeal _).mp (le_one hx) -- Since `M` is strictly greater than `P`, let `z ∈ M \ P`. obtain ⟨z, hzM, hzp⟩ := SetLike.exists_of_lt hM -- We have `z * y ∈ M * (M⁻¹ * P) = P`. have zy_mem := mul_mem_mul (mem_coeIdeal_of_mem A⁰ hzM) hx rw [← RingHom.map_mul, ← mul_assoc, h.mul_inv_eq_one M'_ne, one_mul] at zy_mem obtain ⟨zy, hzy, zy_eq⟩ := (mem_coeIdeal A⁰).mp zy_mem rw [IsFractionRing.injective A (FractionRing A) zy_eq] at hzy -- But `P` is a prime ideal, so `z ∉ P` implies `y ∈ P`, as desired. exact mem_coeIdeal_of_mem A⁰ (Or.resolve_left (hP.mem_or_mem hzy) hzp)⟩ /-- Showing one side of the equivalence between the definitions `IsDedekindDomainInv` and `IsDedekindDomain` of Dedekind domains. -/ theorem isDedekindDomain : IsDedekindDomain A := { h.isNoetherianRing, h.dimensionLEOne, h.integrallyClosed with } end IsDedekindDomainInv end IsDedekindDomainInv variable [Algebra A K] [IsFractionRing A K] variable {A K} theorem one_mem_inv_coe_ideal [IsDomain A] {I : Ideal A} (hI : I ≠ ⊥) : (1 : K) ∈ (I : FractionalIdeal A⁰ K)⁻¹ := by rw [FractionalIdeal.mem_inv_iff (FractionalIdeal.coeIdeal_ne_zero.mpr hI)] intro y hy rw [one_mul] exact FractionalIdeal.coeIdeal_le_one hy /-- Specialization of `exists_primeSpectrum_prod_le_and_ne_bot_of_domain` to Dedekind domains: Let `I : Ideal A` be a nonzero ideal, where `A` is a Dedekind domain that is not a field. Then `exists_primeSpectrum_prod_le_and_ne_bot_of_domain` states we can find a product of prime ideals that is contained within `I`. This lemma extends that result by making the product minimal: let `M` be a maximal ideal that contains `I`, then the product including `M` is contained within `I` and the product excluding `M` is not contained within `I`. -/ theorem exists_multiset_prod_cons_le_and_prod_not_le [IsDedekindDomain A] (hNF : ¬IsField A) {I M : Ideal A} (hI0 : I ≠ ⊥) (hIM : I ≤ M) [hM : M.IsMaximal] : ∃ Z : Multiset (PrimeSpectrum A), (M ::ₘ Z.map PrimeSpectrum.asIdeal).prod ≤ I ∧ ¬Multiset.prod (Z.map PrimeSpectrum.asIdeal) ≤ I := by -- Let `Z` be a minimal set of prime ideals such that their product is contained in `J`. obtain ⟨Z₀, hZ₀⟩ := PrimeSpectrum.exists_primeSpectrum_prod_le_and_ne_bot_of_domain hNF hI0 obtain ⟨Z, ⟨hZI, hprodZ⟩, h_eraseZ⟩ := wellFounded_lt.has_min {Z \| (Z.map PrimeSpectrum.asIdeal).prod ≤ I ∧ (Z.map PrimeSpectrum.asIdeal).prod ≠ ⊥} ⟨Z₀, hZ₀.1, hZ₀.2⟩ obtain ⟨_, hPZ', hPM⟩ := hM.isPrime.multiset_prod_le.mp (hZI.trans hIM) -- Then in fact there is a `P ∈ Z` with `P ≤ M`. obtain ⟨P, hPZ, rfl⟩ := Multiset.mem_map.mp hPZ' classical have := Multiset.map_erase PrimeSpectrum.asIdeal (fun _ _ => PrimeSpectrum.ext) P Z obtain ⟨hP0, hZP0⟩ : P.asIdeal ≠ ⊥ ∧ ((Z.erase P).map PrimeSpectrum.asIdeal).prod ≠ ⊥ := by rwa [Ne, ← Multiset.cons_erase hPZ', Multiset.prod_cons, Ideal.mul_eq_bot, not_or, ← this] at hprodZ -- By maximality of `P` and `M`, we have that `P ≤ M` implies `P = M`. have hPM' := (P.isPrime.isMaximal hP0).eq_of_le hM.ne_top hPM subst hPM' -- By minimality of `Z`, erasing `P` from `Z` is exactly what we need. refine ⟨Z.erase P, ?_, ?_⟩ · convert hZI rw [this, Multiset.cons_erase hPZ'] · refine fun h => h_eraseZ (Z.erase P) ⟨h, ?_⟩ (Multiset.erase_lt.mpr hPZ) exact hZP0 namespace FractionalIdeal open Ideal lemma not_inv_le_one_of_ne_bot [IsDedekindDomain A] {I : Ideal A} (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) : ¬(I⁻¹ : FractionalIdeal A⁰ K) ≤ 1 := by have hNF : ¬IsField A := fun h ↦ letI := h.toField; (eq_bot_or_eq_top I).elim hI0 hI1 wlog hM : I.IsMaximal generalizing I · rcases I.exists_le_maximal hI1 with ⟨M, hmax, hIM⟩ have hMbot : M ≠ ⊥ := (M.bot_lt_of_maximal hNF).ne' refine mt (le_trans <\| inv_anti_mono ?_ ?_ ?_) (this hMbot hmax.ne_top hmax) <;> simpa only [coeIdeal_ne_zero, coeIdeal_le_coeIdeal] have hI0 : ⊥ < I := I.bot_lt_of_maximal hNF obtain ⟨⟨a, haI⟩, ha0⟩ := Submodule.nonzero_mem_of_bot_lt hI0 replace ha0 : a ≠ 0 := Subtype.coe_injective.ne ha0 let J : Ideal A := Ideal.span {a} have hJ0 : J ≠ ⊥ := mt Ideal.span_singleton_eq_bot.mp ha0 have hJI : J ≤ I := I.span_singleton_le_iff_mem.2 haI -- Then we can find a product of prime (hence maximal) ideals contained in `J`, -- such that removing element `M` from the product is not contained in `J`. obtain ⟨Z, hle, hnle⟩ := exists_multiset_prod_cons_le_and_prod_not_le hNF hJ0 hJI -- Choose an element `b` of the product that is not in `J`. obtain ⟨b, hbZ, hbJ⟩ := SetLike.not_le_iff_exists.mp hnle have hnz_fa : algebraMap A K a ≠ 0 := mt ((injective_iff_map_eq_zero _).mp (IsFractionRing.injective A K) a) ha0 -- Then `b a⁻¹ : K` is in `M⁻¹` but not in `1`. refine Set.not_subset.2 ⟨algebraMap A K b * (algebraMap A K a)⁻¹, (mem_inv_iff ?_).mpr ?_, ?_⟩ · exact coeIdeal_ne_zero.mpr hI0.ne' · rintro y₀ hy₀ obtain ⟨y, h_Iy, rfl⟩ := (mem_coeIdeal _).mp hy₀ rw [mul_comm, ← mul_assoc, ← RingHom.map_mul] have h_yb : y * b ∈ J := by apply hle rw [Multiset.prod_cons] exact Submodule.smul_mem_smul h_Iy hbZ rw [Ideal.mem_span_singleton'] at h_yb rcases h_yb with ⟨c, hc⟩ rw [← hc, RingHom.map_mul, mul_assoc, mul_inv_cancel₀ hnz_fa, mul_one] apply coe_mem_one · refine mt (mem_one_iff _).mp ?_ rintro ⟨x', h₂_abs⟩ rw [← div_eq_mul_inv, eq_div_iff_mul_eq hnz_fa, ← RingHom.map_mul] at h₂_abs have := Ideal.mem_span_singleton'.mpr ⟨x', IsFractionRing.injective A K h₂_abs⟩ contradiction theorem exists_not_mem_one_of_ne_bot [IsDedekindDomain A] {I : Ideal A} (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) : ∃ x ∈ (I⁻¹ : FractionalIdeal A⁰ K), x ∉ (1 : FractionalIdeal A⁰ K) := Set.not_subset.1 <\| not_inv_le_one_of_ne_bot hI0 hI1 theorem mul_inv_cancel_of_le_one [h : IsDedekindDomain A] {I : Ideal A} (hI0 : I ≠ ⊥) (hI : (I * (I : FractionalIdeal A⁰ K)⁻¹)⁻¹ ≤ 1) : I * (I : FractionalIdeal A⁰ K)⁻¹ = 1 := by -- We'll show a contradiction with `exists_not_mem_one_of_ne_bot`: -- `J⁻¹ = (I * I⁻¹)⁻¹` cannot have an element `x ∉ 1`, so it must equal `1`. obtain ⟨J, hJ⟩ : ∃ J : Ideal A, (J : FractionalIdeal A⁰ K) = I * (I : FractionalIdeal A⁰ K)⁻¹ := le_one_iff_exists_coeIdeal.mp mul_one_div_le_one by_cases hJ0 : J = ⊥ · subst hJ0 refine absurd ?_ hI0 rw [eq_bot_iff, ← coeIdeal_le_coeIdeal K, hJ] exact coe_ideal_le_self_mul_inv K I by_cases hJ1 : J = ⊤ · rw [← hJ, hJ1, coeIdeal_top] exact (not_inv_le_one_of_ne_bot (K := K) hJ0 hJ1 (hJ ▸ hI)).elim /-- Nonzero integral ideals in a Dedekind domain are invertible. We will use this to show that nonzero fractional ideals are invertible, and finally conclude that fractional ideals in a Dedekind domain form a group with zero. -/ theorem coe_ideal_mul_inv [h : IsDedekindDomain A] (I : Ideal A) (hI0 : I ≠ ⊥) : I * (I : FractionalIdeal A⁰ K)⁻¹ = 1 := by -- We'll show `1 ≤ J⁻¹ = (I * I⁻¹)⁻¹ ≤ 1`. apply mul_inv_cancel_of_le_one hI0 by_cases hJ0 : I * (I : FractionalIdeal A⁰ K)⁻¹ = 0 · rw [hJ0, inv_zero']; exact zero_le _ intro x hx -- In particular, we'll show all `x ∈ J⁻¹` are integral. suffices x ∈ integralClosure A K by rwa [IsIntegrallyClosed.integralClosure_eq_bot, Algebra.mem_bot, Set.mem_range, ← mem_one_iff] at this -- For that, we'll find a subalgebra that is f.g. as a module and contains `x`. -- `A` is a noetherian ring, so we just need to find a subalgebra between `{x}` and `I⁻¹`. rw [mem_integralClosure_iff_mem_fg] have x_mul_mem : ∀ b ∈ (I⁻¹ : FractionalIdeal A⁰ K), x * b ∈ (I⁻¹ : FractionalIdeal A⁰ K) := by intro b hb rw [mem_inv_iff (coeIdeal_ne_zero.mpr hI0)] dsimp only at hx rw [val_eq_coe, mem_coe, mem_inv_iff hJ0] at hx simp only [mul_assoc, mul_comm b] at hx ⊢ intro y hy exact hx _ (mul_mem_mul hy hb) -- It turns out the subalgebra consisting of all `p(x)` for `p : A[X]` works. refine ⟨AlgHom.range (Polynomial.aeval x : A[X] →ₐ[A] K), isNoetherian_submodule.mp (isNoetherian (I : FractionalIdeal A⁰ K)⁻¹) _ fun y hy => ?_, ⟨Polynomial.X, Polynomial.aeval_X x⟩⟩ obtain ⟨p, rfl⟩ := (AlgHom.mem_range _).mp hy rw [Polynomial.aeval_eq_sum_range] refine Submodule.sum_mem _ fun i hi => Submodule.smul_mem _ _ ?_ clear hi induction' i with i ih · rw [pow_zero]; exact one_mem_inv_coe_ideal hI0 · show x ^ i.succ ∈ (I⁻¹ : FractionalIdeal A⁰ K) rw [pow_succ']; exact x_mul_mem _ ih /-- Nonzero fractional ideals in a Dedekind domain are units. This is also available as `_root_.mul_inv_cancel`, using the `Semifield` instance defined below. -/ protected theorem mul_inv_cancel [IsDedekindDomain A] {I : FractionalIdeal A⁰ K} (hne : I ≠ 0) : I * I⁻¹ = 1 := by obtain ⟨a, J, ha, hJ⟩ : ∃ (a : A) (aI : Ideal A), a ≠ 0 ∧ I = spanSingleton A⁰ (algebraMap A K a)⁻¹ * aI := exists_eq_spanSingleton_mul I suffices h₂ : I * (spanSingleton A⁰ (algebraMap _ _ a) * (J : FractionalIdeal A⁰ K)⁻¹) = 1 by rw [mul_inv_cancel_iff] exact ⟨spanSingleton A⁰ (algebraMap _ _ a) * (J : FractionalIdeal A⁰ K)⁻¹, h₂⟩ subst hJ rw [mul_assoc, mul_left_comm (J : FractionalIdeal A⁰ K), coe_ideal_mul_inv, mul_one, spanSingleton_mul_spanSingleton, inv_mul_cancel₀, spanSingleton_one] · exact mt ((injective_iff_map_eq_zero (algebraMap A K)).mp (IsFractionRing.injective A K) _) ha · exact coeIdeal_ne_zero.mp (right_ne_zero_of_mul hne) theorem mul_right_le_iff [IsDedekindDomain A] {J : FractionalIdeal A⁰ K} (hJ : J ≠ 0) : ∀ {I I'}, I * J ≤ I' * J ↔ I ≤ I' := by intro I I' constructor · intro h convert mul_right_mono J⁻¹ h <;> dsimp only <;> rw [mul_assoc, FractionalIdeal.mul_inv_cancel hJ, mul_one] · exact fun h => mul_right_mono J h theorem mul_left_le_iff [IsDedekindDomain A] {J : FractionalIdeal A⁰ K} (hJ : J ≠ 0) {I I'} : J * I ≤ J * I' ↔ I ≤ I' := by convert mul_right_le_iff hJ using 1; simp only [mul_comm] theorem mul_right_strictMono [IsDedekindDomain A] {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : StrictMono (· * I) := strictMono_of_le_iff_le fun _ _ => (mul_right_le_iff hI).symm theorem mul_left_strictMono [IsDedekindDomain A] {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : StrictMono (I * ·) := strictMono_of_le_iff_le fun _ _ => (mul_left_le_iff hI).symm /-- This is also available as `_root_.div_eq_mul_inv`, using the `Semifield` instance defined below. -/ protected theorem div_eq_mul_inv [IsDedekindDomain A] (I J : FractionalIdeal A⁰ K) : I / J = I * J⁻¹ := by by_cases hJ : J = 0 · rw [hJ, div_zero, inv_zero', mul_zero] refine le_antisymm ((mul_right_le_iff hJ).mp ?_) ((le_div_iff_mul_le hJ).mpr ?_) · rw [mul_assoc, mul_comm J⁻¹, FractionalIdeal.mul_inv_cancel hJ, mul_one, mul_le] intro x hx y hy rw [mem_div_iff_of_nonzero hJ] at hx exact hx y hy rw [mul_assoc, mul_comm J⁻¹, FractionalIdeal.mul_inv_cancel hJ, mul_one] end FractionalIdeal /-- `IsDedekindDomain` and `IsDedekindDomainInv` are equivalent ways to express that an integral domain is a Dedekind domain. -/ theorem isDedekindDomain_iff_isDedekindDomainInv [IsDomain A] : IsDedekindDomain A ↔ IsDedekindDomainInv A := ⟨fun _h _I hI => FractionalIdeal.mul_inv_cancel hI, fun h => h.isDedekindDomain⟩ end Inverse section IsDedekindDomain variable {R A} variable [IsDedekindDomain A] [Algebra A K] [IsFractionRing A K] open FractionalIdeal open Ideal noncomputable instance FractionalIdeal.semifield : Semifield (FractionalIdeal A⁰ K) where __ := coeIdeal_injective.nontrivial inv_zero := inv_zero' _ div_eq_mul_inv := FractionalIdeal.div_eq_mul_inv mul_inv_cancel _ := FractionalIdeal.mul_inv_cancel nnqsmul := _ nnqsmul_def := fun _ _ => rfl #adaptation_note /-- 2025-03-29 for lean4#7717 had to add `mul_left_cancel_of_ne_zero` field. TODO(kmill) There is trouble calculating the type of the `IsLeftCancelMulZero` parent. -/ /-- Fractional ideals have cancellative multiplication in a Dedekind domain. Although this instance is a direct consequence of the instance `FractionalIdeal.semifield`, we define this instance to provide a computable alternative. -/ instance FractionalIdeal.cancelCommMonoidWithZero : CancelCommMonoidWithZero (FractionalIdeal A⁰ K) where __ : CommSemiring (FractionalIdeal A⁰ K) := inferInstance mul_left_cancel_of_ne_zero := mul_left_cancel₀ instance Ideal.cancelCommMonoidWithZero : CancelCommMonoidWithZero (Ideal A) := { Function.Injective.cancelCommMonoidWithZero (coeIdealHom A⁰ (FractionRing A)) coeIdeal_injective (RingHom.map_zero _) (RingHom.map_one _) (RingHom.map_mul _) (RingHom.map_pow _) with } -- Porting note: Lean can infer all it needs by itself instance Ideal.isDomain : IsDomain (Ideal A) := { } /-- For ideals in a Dedekind domain, to divide is to contain. -/ theorem Ideal.dvd_iff_le {I J : Ideal A} : I ∣ J ↔ J ≤ I := ⟨Ideal.le_of_dvd, fun h => by by_cases hI : I = ⊥ · have hJ : J = ⊥ := by rwa [hI, ← eq_bot_iff] at h rw [hI, hJ] have hI' : (I : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr hI have : (I : FractionalIdeal A⁰ (FractionRing A))⁻¹ * J ≤ 1 := by rw [← inv_mul_cancel₀ hI'] exact mul_left_mono _ ((coeIdeal_le_coeIdeal _).mpr h) obtain ⟨H, hH⟩ := le_one_iff_exists_coeIdeal.mp this use H refine coeIdeal_injective (show (J : FractionalIdeal A⁰ (FractionRing A)) = ↑(I * H) from ?_) rw [coeIdeal_mul, hH, ← mul_assoc, mul_inv_cancel₀ hI', one_mul]⟩ theorem Ideal.dvdNotUnit_iff_lt {I J : Ideal A} : DvdNotUnit I J ↔ J < I := ⟨fun ⟨hI, H, hunit, hmul⟩ => lt_of_le_of_ne (Ideal.dvd_iff_le.mp ⟨H, hmul⟩) (mt (fun h => have : H = 1 := mul_left_cancel₀ hI (by rw [← hmul, h, mul_one]) show IsUnit H from this.symm ▸ isUnit_one) hunit), fun h => dvdNotUnit_of_dvd_of_not_dvd (Ideal.dvd_iff_le.mpr (le_of_lt h)) (mt Ideal.dvd_iff_le.mp (not_le_of_lt h))⟩ instance : WfDvdMonoid (Ideal A) where wf := by have : WellFoundedGT (Ideal A) := inferInstance convert this.wf ext rw [Ideal.dvdNotUnit_iff_lt] instance Ideal.uniqueFactorizationMonoid : UniqueFactorizationMonoid (Ideal A) := { irreducible_iff_prime := by intro P exact ⟨fun hirr => ⟨hirr.ne_zero, hirr.not_isUnit, fun I J => by have : P.IsMaximal := by refine ⟨⟨mt Ideal.isUnit_iff.mpr hirr.not_isUnit, ?_⟩⟩ intro J hJ obtain ⟨_J_ne, H, hunit, P_eq⟩ := Ideal.dvdNotUnit_iff_lt.mpr hJ exact Ideal.isUnit_iff.mp ((hirr.isUnit_or_isUnit P_eq).resolve_right hunit) rw [Ideal.dvd_iff_le, Ideal.dvd_iff_le, Ideal.dvd_iff_le, SetLike.le_def, SetLike.le_def, SetLike.le_def] contrapose! rintro ⟨⟨x, x_mem, x_not_mem⟩, ⟨y, y_mem, y_not_mem⟩⟩ exact ⟨x * y, Ideal.mul_mem_mul x_mem y_mem, mt this.isPrime.mem_or_mem (not_or_intro x_not_mem y_not_mem)⟩⟩, Prime.irreducible⟩ } instance Ideal.normalizationMonoid : NormalizationMonoid (Ideal A) := .ofUniqueUnits @[simp] theorem Ideal.dvd_span_singleton {I : Ideal A} {x : A} : I ∣ Ideal.span {x} ↔ x ∈ I := Ideal.dvd_iff_le.trans (Ideal.span_le.trans Set.singleton_subset_iff) theorem Ideal.isPrime_of_prime {P : Ideal A} (h : Prime P) : IsPrime P := by refine ⟨?_, fun hxy => ?_⟩ · rintro rfl rw [← Ideal.one_eq_top] at h exact h.not_unit isUnit_one · simp only [← Ideal.dvd_span_singleton, ← Ideal.span_singleton_mul_span_singleton] at hxy ⊢ exact h.dvd_or_dvd hxy theorem Ideal.prime_of_isPrime {P : Ideal A} (hP : P ≠ ⊥) (h : IsPrime P) : Prime P := by refine ⟨hP, mt Ideal.isUnit_iff.mp h.ne_top, fun I J hIJ => ?_⟩ simpa only [Ideal.dvd_iff_le] using h.mul_le.mp (Ideal.le_of_dvd hIJ) /-- In a Dedekind domain, the (nonzero) prime elements of the monoid with zero `Ideal A` are exactly the prime ideals. -/ theorem Ideal.prime_iff_isPrime {P : Ideal A} (hP : P ≠ ⊥) : Prime P ↔ IsPrime P := ⟨Ideal.isPrime_of_prime, Ideal.prime_of_isPrime hP⟩ /-- In a Dedekind domain, the prime ideals are the zero ideal together with the prime elements of the monoid with zero `Ideal A`. -/ theorem Ideal.isPrime_iff_bot_or_prime {P : Ideal A} : IsPrime P ↔ P = ⊥ ∨ Prime P := ⟨fun hp => (eq_or_ne P ⊥).imp_right fun hp0 => Ideal.prime_of_isPrime hp0 hp, fun hp => hp.elim (fun h => h.symm ▸ Ideal.bot_prime) Ideal.isPrime_of_prime⟩ @[simp] theorem Ideal.prime_span_singleton_iff {a : A} : Prime (Ideal.span {a}) ↔ Prime a := by rcases eq_or_ne a 0 with rfl \| ha · rw [Set.singleton_zero, span_zero, ← Ideal.zero_eq_bot, ← not_iff_not] simp only [not_prime_zero, not_false_eq_true] · have ha' : span {a} ≠ ⊥ := by simpa only [ne_eq, span_singleton_eq_bot] using ha rw [Ideal.prime_iff_isPrime ha', Ideal.span_singleton_prime ha] open Submodule.IsPrincipal in theorem Ideal.prime_generator_of_prime {P : Ideal A} (h : Prime P) [P.IsPrincipal] : Prime (generator P) := have : Ideal.IsPrime P := Ideal.isPrime_of_prime h prime_generator_of_isPrime _ h.ne_zero open UniqueFactorizationMonoid in nonrec theorem Ideal.mem_normalizedFactors_iff {p I : Ideal A} (hI : I ≠ ⊥) : p ∈ normalizedFactors I ↔ p.IsPrime ∧ I ≤ p := by rw [← Ideal.dvd_iff_le] by_cases hp : p = 0 · rw [← zero_eq_bot] at hI simp only [hp, zero_not_mem_normalizedFactors, zero_dvd_iff, hI, false_iff, not_and, not_false_eq_true, implies_true] · rwa [mem_normalizedFactors_iff hI, prime_iff_isPrime] theorem Ideal.pow_right_strictAnti (I : Ideal A) (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) : StrictAnti (I ^ · : ℕ → Ideal A) := strictAnti_nat_of_succ_lt fun e => Ideal.dvdNotUnit_iff_lt.mp ⟨pow_ne_zero _ hI0, I, mt isUnit_iff.mp hI1, pow_succ I e⟩ theorem Ideal.pow_lt_self (I : Ideal A) (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) (e : ℕ) (he : 2 ≤ e) : I ^ e < I := by convert I.pow_right_strictAnti hI0 hI1 he dsimp only rw [pow_one] theorem Ideal.exists_mem_pow_not_mem_pow_succ (I : Ideal A) (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) (e : ℕ) : ∃ x ∈ I ^ e, x ∉ I ^ (e + 1) := SetLike.exists_of_lt (I.pow_right_strictAnti hI0 hI1 e.lt_succ_self) open UniqueFactorizationMonoid theorem Ideal.eq_prime_pow_of_succ_lt_of_le {P I : Ideal A} [P_prime : P.IsPrime] (hP : P ≠ ⊥) {i : ℕ} (hlt : P ^ (i + 1) < I) (hle : I ≤ P ^ i) : I = P ^ i := by refine le_antisymm hle ?_ have P_prime' := Ideal.prime_of_isPrime hP P_prime have h1 : I ≠ ⊥ := (lt_of_le_of_lt bot_le hlt).ne' have := pow_ne_zero i hP have h3 := pow_ne_zero (i + 1) hP rw [← Ideal.dvdNotUnit_iff_lt, dvdNotUnit_iff_normalizedFactors_lt_normalizedFactors h1 h3, normalizedFactors_pow, normalizedFactors_irreducible P_prime'.irreducible, Multiset.nsmul_singleton, Multiset.lt_replicate_succ] at hlt rw [← Ideal.dvd_iff_le, dvd_iff_normalizedFactors_le_normalizedFactors, normalizedFactors_pow, normalizedFactors_irreducible P_prime'.irreducible, Multiset.nsmul_singleton] all_goals assumption theorem Ideal.pow_succ_lt_pow {P : Ideal A} [P_prime : P.IsPrime] (hP : P ≠ ⊥) (i : ℕ) : P ^ (i + 1) < P ^ i := lt_of_le_of_ne (Ideal.pow_le_pow_right (Nat.le_succ _)) (mt (pow_inj_of_not_isUnit (mt Ideal.isUnit_iff.mp P_prime.ne_top) hP).mp i.succ_ne_self) theorem Associates.le_singleton_iff (x : A) (n : ℕ) (I : Ideal A) : Associates.mk I ^ n ≤ Associates.mk (Ideal.span {x}) ↔ x ∈ I ^ n := by simp_rw [← Associates.dvd_eq_le, ← Associates.mk_pow, Associates.mk_dvd_mk, Ideal.dvd_span_singleton] variable {K} lemma FractionalIdeal.le_inv_comm {I J : FractionalIdeal A⁰ K} (hI : I ≠ 0) (hJ : J ≠ 0) : I ≤ J⁻¹ ↔ J ≤ I⁻¹ := by rw [inv_eq, inv_eq, le_div_iff_mul_le hI, le_div_iff_mul_le hJ, mul_comm] lemma FractionalIdeal.inv_le_comm {I J : FractionalIdeal A⁰ K} (hI : I ≠ 0) (hJ : J ≠ 0) : I⁻¹ ≤ J ↔ J⁻¹ ≤ I := by simpa using le_inv_comm (A := A) (K := K) (inv_ne_zero hI) (inv_ne_zero hJ) open FractionalIdeal /-- Strengthening of `IsLocalization.exist_integer_multiples`: Let `J ≠ ⊤` be an ideal in a Dedekind domain `A`, and `f ≠ 0` a finite collection of elements of `K = Frac(A)`, then we can multiply the elements of `f` by some `a : K` to find a collection of elements of `A` that is not completely contained in `J`. -/ theorem Ideal.exist_integer_multiples_not_mem {J : Ideal A} (hJ : J ≠ ⊤) {ι : Type*} (s : Finset ι) (f : ι → K) {j} (hjs : j ∈ s) (hjf : f j ≠ 0) :	∃ a : K, (∀ i ∈ s, IsLocalization.IsInteger A (a * f i)) ∧ ∃ i ∈ s, a * f i ∉ (J : FractionalIdeal A⁰ K) := by -- Consider the fractional ideal `I` spanned by the `f`s. let I : FractionalIdeal A⁰ K := spanFinset A s f	Mathlib/RingTheory/DedekindDomain/Ideal.lean	756	760
/- Copyright (c) 2024 Lawrence Wu. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Lawrence Wu -/ import Mathlib.Analysis.Fourier.Inversion import Mathlib.Analysis.MellinTransform /-! # Mellin inversion formula We derive the Mellin inversion formula as a consequence of the Fourier inversion formula. ## Main results - `mellin_inversion`: The inverse Mellin transform of the Mellin transform applied to `x > 0` is x. -/ open Real Complex Set MeasureTheory variable {E : Type*} [NormedAddCommGroup E] [NormedSpace ℂ E] open scoped FourierTransform private theorem rexp_neg_deriv_aux : ∀ x ∈ univ, HasDerivWithinAt (rexp ∘ Neg.neg) (-rexp (-x)) univ x := fun x _ ↦ mul_neg_one (rexp (-x)) ▸ ((Real.hasDerivAt_exp (-x)).comp x (hasDerivAt_neg x)).hasDerivWithinAt	private theorem rexp_neg_image_aux : rexp ∘ Neg.neg '' univ = Ioi 0 := by	Mathlib/Analysis/MellinInversion.lean	28	29
/- Copyright (c) 2021 Riccardo Brasca. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Riccardo Brasca -/ import Mathlib.RingTheory.IntegralClosure.IntegrallyClosed import Mathlib.RingTheory.Trace.Basic import Mathlib.RingTheory.Norm.Basic /-! # Discriminant of a family of vectors Given an `A`-algebra `B` and `b`, an `ι`-indexed family of elements of `B`, we define the discriminant of `b` as the determinant of the matrix whose `(i j)`-th element is the trace of `b i * b j`. ## Main definition * `Algebra.discr A b` : the discriminant of `b : ι → B`. ## Main results * `Algebra.discr_zero_of_not_linearIndependent` : if `b` is not linear independent, then `Algebra.discr A b = 0`. * `Algebra.discr_of_matrix_vecMul` and `Algebra.discr_of_matrix_mulVec` : formulas relating `Algebra.discr A ι b` with `Algebra.discr A (b ᵥ* P.map (algebraMap A B))` and `Algebra.discr A (P.map (algebraMap A B) ᵥ b)`. `Algebra.discr_not_zero_of_basis` : over a field, if `b` is a basis, then `Algebra.discr K b ≠ 0`. * `Algebra.discr_eq_det_embeddingsMatrixReindex_pow_two` : if `L/K` is a field extension and `b : ι → L`, then `discr K b` is the square of the determinant of the matrix whose `(i, j)` coefficient is `σⱼ (b i)`, where `σⱼ : L →ₐ[K] E` is the embedding in an algebraically closed field `E` corresponding to `j : ι` via a bijection `e : ι ≃ (L →ₐ[K] E)`. * `Algebra.discr_powerBasis_eq_prod` : the discriminant of a power basis. * `Algebra.discr_isIntegral` : if `K` and `L` are fields and `IsScalarTower R K L`, if `b : ι → L` satisfies `∀ i, IsIntegral R (b i)`, then `IsIntegral R (discr K b)`. * `Algebra.discr_mul_isIntegral_mem_adjoin` : let `K` be the fraction field of an integrally closed domain `R` and let `L` be a finite separable extension of `K`. Let `B : PowerBasis K L` be such that `IsIntegral R B.gen`. Then for all, `z : L` we have `(discr K B.basis) • z ∈ adjoin R ({B.gen} : Set L)`. ## Implementation details Our definition works for any `A`-algebra `B`, but note that if `B` is not free as an `A`-module, then `trace A B = 0` by definition, so `discr A b = 0` for any `b`. -/ universe u v w z open scoped Matrix open Matrix Module Fintype Polynomial Finset IntermediateField namespace Algebra variable (A : Type u) {B : Type v} (C : Type z) {ι : Type w} [DecidableEq ι] variable [CommRing A] [CommRing B] [Algebra A B] [CommRing C] [Algebra A C] section Discr /-- Given an `A`-algebra `B` and `b`, an `ι`-indexed family of elements of `B`, we define `discr A ι b` as the determinant of `traceMatrix A ι b`. -/ -- Porting note: using `[DecidableEq ι]` instead of `by classical...` did not work in -- mathlib3. noncomputable def discr (A : Type u) {B : Type v} [CommRing A] [CommRing B] [Algebra A B] [Fintype ι] (b : ι → B) := (traceMatrix A b).det theorem discr_def [Fintype ι] (b : ι → B) : discr A b = (traceMatrix A b).det := rfl variable {A C} in /-- Mapping a family of vectors along an `AlgEquiv` preserves the discriminant. -/ theorem discr_eq_discr_of_algEquiv [Fintype ι] (b : ι → B) (f : B ≃ₐ[A] C) : Algebra.discr A b = Algebra.discr A (f ∘ b) := by rw [discr_def]; congr; ext simp_rw [traceMatrix_apply, traceForm_apply, Function.comp, ← map_mul f, trace_eq_of_algEquiv] variable {ι' : Type} [Fintype ι'] [Fintype ι] [DecidableEq ι'] section Basic @[simp] theorem discr_reindex (b : Basis ι A B) (f : ι ≃ ι') : discr A (b ∘ ⇑f.symm) = discr A b := by classical rw [← Basis.coe_reindex, discr_def, traceMatrix_reindex, det_reindex_self, ← discr_def] /-- If `b` is not linear independent, then `Algebra.discr A b = 0`. -/ theorem discr_zero_of_not_linearIndependent [IsDomain A] {b : ι → B} (hli : ¬LinearIndependent A b) : discr A b = 0 := by classical obtain ⟨g, hg, i, hi⟩ := Fintype.not_linearIndependent_iff.1 hli have : (traceMatrix A b) ᵥ g = 0 := by ext i have : ∀ j, (trace A B) (b i * b j) * g j = (trace A B) (g j • b j * b i) := by intro j simp [mul_comm] simp only [mulVec, dotProduct, traceMatrix_apply, Pi.zero_apply, traceForm_apply, fun j => this j, ← map_sum, ← sum_mul, hg, zero_mul, LinearMap.map_zero] by_contra h rw [discr_def] at h simp [Matrix.eq_zero_of_mulVec_eq_zero h this] at hi variable {A} /-- Relation between `Algebra.discr A ι b` and `Algebra.discr A (b ᵥ* P.map (algebraMap A B))`. -/ theorem discr_of_matrix_vecMul (b : ι → B) (P : Matrix ι ι A) : discr A (b ᵥ* P.map (algebraMap A B)) = P.det ^ 2 * discr A b := by rw [discr_def, traceMatrix_of_matrix_vecMul, det_mul, det_mul, det_transpose, mul_comm, ← mul_assoc, discr_def, pow_two] /-- Relation between `Algebra.discr A ι b` and `Algebra.discr A ((P.map (algebraMap A B)) ᵥ b)`. -/ theorem discr_of_matrix_mulVec (b : ι → B) (P : Matrix ι ι A) : discr A (P.map (algebraMap A B) ᵥ b) = P.det ^ 2 * discr A b := by rw [discr_def, traceMatrix_of_matrix_mulVec, det_mul, det_mul, det_transpose, mul_comm, ← mul_assoc, discr_def, pow_two] end Basic section Field variable (K : Type u) {L : Type v} (E : Type z) [Field K] [Field L] [Field E] variable [Algebra K L] [Algebra K E] variable [Module.Finite K L] [IsAlgClosed E] /-- If `b` is a basis of a finite separable field extension `L/K`, then `Algebra.discr K b ≠ 0`. -/ theorem discr_not_zero_of_basis [Algebra.IsSeparable K L] (b : Basis ι K L) : discr K b ≠ 0 := by rw [discr_def, traceMatrix_of_basis, ← LinearMap.BilinForm.nondegenerate_iff_det_ne_zero] exact traceForm_nondegenerate _ _ /-- If `b` is a basis of a finite separable field extension `L/K`, then `Algebra.discr K b` is a unit. -/ theorem discr_isUnit_of_basis [Algebra.IsSeparable K L] (b : Basis ι K L) : IsUnit (discr K b) := IsUnit.mk0 _ (discr_not_zero_of_basis _ _) variable (b : ι → L) (pb : PowerBasis K L) /-- If `L/K` is a field extension and `b : ι → L`, then `discr K b` is the square of the determinant of the matrix whose `(i, j)` coefficient is `σⱼ (b i)`, where `σⱼ : L →ₐ[K] E` is the embedding in an algebraically closed field `E` corresponding to `j : ι` via a bijection `e : ι ≃ (L →ₐ[K] E)`. -/ theorem discr_eq_det_embeddingsMatrixReindex_pow_two [Algebra.IsSeparable K L] (e : ι ≃ (L →ₐ[K] E)) : algebraMap K E (discr K b) = (embeddingsMatrixReindex K E b e).det ^ 2 := by rw [discr_def, RingHom.map_det, RingHom.mapMatrix_apply, traceMatrix_eq_embeddingsMatrixReindex_mul_trans, det_mul, det_transpose, pow_two] /-- The discriminant of a power basis. -/ theorem discr_powerBasis_eq_prod (e : Fin pb.dim ≃ (L →ₐ[K] E)) [Algebra.IsSeparable K L] : algebraMap K E (discr K pb.basis) = ∏ i : Fin pb.dim, ∏ j ∈ Ioi i, (e j pb.gen - e i pb.gen) ^ 2 := by rw [discr_eq_det_embeddingsMatrixReindex_pow_two K E pb.basis e, embeddingsMatrixReindex_eq_vandermonde, det_transpose, det_vandermonde, ← prod_pow] congr; ext i rw [← prod_pow] /-- A variation of `Algebra.discr_powerBasis_eq_prod`. -/ theorem discr_powerBasis_eq_prod' [Algebra.IsSeparable K L] (e : Fin pb.dim ≃ (L →ₐ[K] E)) : algebraMap K E (discr K pb.basis) =	∏ i : Fin pb.dim, ∏ j ∈ Ioi i, -((e j pb.gen - e i pb.gen) * (e i pb.gen - e j pb.gen)) := by rw [discr_powerBasis_eq_prod _ _ _ e] congr; ext i; congr; ext j ring local notation "n" => finrank K L	Mathlib/RingTheory/Discriminant.lean	161	167
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Jeremy Avigad, Yury Kudryashov -/ import Mathlib.Data.Finite.Prod import Mathlib.Data.Fintype.Pi import Mathlib.Data.Set.Finite.Lemmas import Mathlib.Order.ConditionallyCompleteLattice.Basic import Mathlib.Order.Filter.CountablyGenerated import Mathlib.Order.Filter.Ker import Mathlib.Order.Filter.Pi import Mathlib.Order.Filter.Prod import Mathlib.Order.Filter.AtTopBot.Basic /-! # The cofinite filter In this file we define `Filter.cofinite`: the filter of sets with finite complement and prove its basic properties. In particular, we prove that for `ℕ` it is equal to `Filter.atTop`. ## TODO Define filters for other cardinalities of the complement. -/ open Set Function variable {ι α β : Type} {l : Filter α} namespace Filter /-- The cofinite filter is the filter of subsets whose complements are finite. -/ def cofinite : Filter α := comk Set.Finite finite_empty (fun _t ht _s hsub ↦ ht.subset hsub) fun _ h _ ↦ h.union @[simp] theorem mem_cofinite {s : Set α} : s ∈ @cofinite α ↔ sᶜ.Finite := Iff.rfl @[simp] theorem eventually_cofinite {p : α → Prop} : (∀ᶠ x in cofinite, p x) ↔ { x \| ¬p x }.Finite := Iff.rfl theorem hasBasis_cofinite : HasBasis cofinite (fun s : Set α => s.Finite) compl := ⟨fun s => ⟨fun h => ⟨sᶜ, h, (compl_compl s).subset⟩, fun ⟨_t, htf, hts⟩ => htf.subset <\| compl_subset_comm.2 hts⟩⟩ instance cofinite_neBot [Infinite α] : NeBot (@cofinite α) := hasBasis_cofinite.neBot_iff.2 fun hs => hs.infinite_compl.nonempty @[simp] theorem cofinite_eq_bot_iff : @cofinite α = ⊥ ↔ Finite α := by simp [← empty_mem_iff_bot, finite_univ_iff] @[simp] theorem cofinite_eq_bot [Finite α] : @cofinite α = ⊥ := cofinite_eq_bot_iff.2 ‹_› theorem frequently_cofinite_iff_infinite {p : α → Prop} : (∃ᶠ x in cofinite, p x) ↔ Set.Infinite { x \| p x } := by simp only [Filter.Frequently, eventually_cofinite, not_not, Set.Infinite] lemma frequently_cofinite_mem_iff_infinite {s : Set α} : (∃ᶠ x in cofinite, x ∈ s) ↔ s.Infinite := frequently_cofinite_iff_infinite alias ⟨_, _root_.Set.Infinite.frequently_cofinite⟩ := frequently_cofinite_mem_iff_infinite @[simp] lemma cofinite_inf_principal_neBot_iff {s : Set α} : (cofinite ⊓ 𝓟 s).NeBot ↔ s.Infinite := frequently_mem_iff_neBot.symm.trans frequently_cofinite_mem_iff_infinite alias ⟨_, _root_.Set.Infinite.cofinite_inf_principal_neBot⟩ := cofinite_inf_principal_neBot_iff theorem _root_.Set.Finite.compl_mem_cofinite {s : Set α} (hs : s.Finite) : sᶜ ∈ @cofinite α := mem_cofinite.2 <\| (compl_compl s).symm ▸ hs theorem _root_.Set.Finite.eventually_cofinite_nmem {s : Set α} (hs : s.Finite) : ∀ᶠ x in cofinite, x ∉ s := hs.compl_mem_cofinite theorem _root_.Finset.eventually_cofinite_nmem (s : Finset α) : ∀ᶠ x in cofinite, x ∉ s := s.finite_toSet.eventually_cofinite_nmem theorem _root_.Set.infinite_iff_frequently_cofinite {s : Set α} : Set.Infinite s ↔ ∃ᶠ x in cofinite, x ∈ s := frequently_cofinite_iff_infinite.symm theorem eventually_cofinite_ne (x : α) : ∀ᶠ a in cofinite, a ≠ x := (Set.finite_singleton x).eventually_cofinite_nmem theorem le_cofinite_iff_compl_singleton_mem : l ≤ cofinite ↔ ∀ x, {x}ᶜ ∈ l := by refine ⟨fun h x => h (finite_singleton x).compl_mem_cofinite, fun h s (hs : sᶜ.Finite) => ?_⟩ rw [← compl_compl s, ← biUnion_of_singleton sᶜ, compl_iUnion₂, Filter.biInter_mem hs] exact fun x _ => h x theorem le_cofinite_iff_eventually_ne : l ≤ cofinite ↔ ∀ x, ∀ᶠ y in l, y ≠ x := le_cofinite_iff_compl_singleton_mem /-- If `α` is a preorder with no top element, then `atTop ≤ cofinite`. -/ theorem atTop_le_cofinite [Preorder α] [NoTopOrder α] : (atTop : Filter α) ≤ cofinite := le_cofinite_iff_eventually_ne.mpr eventually_ne_atTop /-- If `α` is a preorder with no bottom element, then `atBot ≤ cofinite`. -/ theorem atBot_le_cofinite [Preorder α] [NoBotOrder α] : (atBot : Filter α) ≤ cofinite := le_cofinite_iff_eventually_ne.mpr eventually_ne_atBot theorem comap_cofinite_le (f : α → β) : comap f cofinite ≤ cofinite := le_cofinite_iff_eventually_ne.mpr fun x => mem_comap.2 ⟨{f x}ᶜ, (finite_singleton _).compl_mem_cofinite, fun _ => ne_of_apply_ne f⟩ /-- The coproduct of the cofinite filters on two types is the cofinite filter on their product. -/ theorem coprod_cofinite : (cofinite : Filter α).coprod (cofinite : Filter β) = cofinite := Filter.coext fun s => by simp only [compl_mem_coprod, mem_cofinite, compl_compl, finite_image_fst_and_snd_iff] theorem coprodᵢ_cofinite {α : ι → Type} [Finite ι] : (Filter.coprodᵢ fun i => (cofinite : Filter (α i))) = cofinite := Filter.coext fun s => by simp only [compl_mem_coprodᵢ, mem_cofinite, compl_compl, forall_finite_image_eval_iff] theorem disjoint_cofinite_left : Disjoint cofinite l ↔ ∃ s ∈ l, Set.Finite s := by simp [l.basis_sets.disjoint_iff_right] theorem disjoint_cofinite_right : Disjoint l cofinite ↔ ∃ s ∈ l, Set.Finite s := disjoint_comm.trans disjoint_cofinite_left /-- If `l ≥ Filter.cofinite` is a countably generated filter, then `l.ker` is cocountable. -/ theorem countable_compl_ker [l.IsCountablyGenerated] (h : cofinite ≤ l) : Set.Countable l.kerᶜ := by rcases exists_antitone_basis l with ⟨s, hs⟩ simp only [hs.ker, iInter_true, compl_iInter] exact countable_iUnion fun n ↦ Set.Finite.countable <\| h <\| hs.mem _ /-- If `f` tends to a countably generated filter `l` along `Filter.cofinite`, then for all but countably many elements, `f x ∈ l.ker`. -/ theorem Tendsto.countable_compl_preimage_ker {f : α → β} {l : Filter β} [l.IsCountablyGenerated] (h : Tendsto f cofinite l) : Set.Countable (f ⁻¹' l.ker)ᶜ := by rw [← ker_comap]; exact countable_compl_ker h.le_comap /-- Given a collection of filters `l i : Filter (α i)` and sets `s i ∈ l i`, if all but finitely many of `s i` are the whole space, then their indexed product `Set.pi Set.univ s` belongs to the filter `Filter.pi l`. -/ theorem univ_pi_mem_pi {α : ι → Type*} {s : ∀ i, Set (α i)} {l : ∀ i, Filter (α i)} (h : ∀ i, s i ∈ l i) (hfin : ∀ᶠ i in cofinite, s i = univ) : univ.pi s ∈ pi l := by filter_upwards [pi_mem_pi hfin fun i _ ↦ h i] with a ha i _ if hi : s i = univ then	simp [hi] else exact ha i hi	Mathlib/Order/Filter/Cofinite.lean	150	152
/- Copyright (c) 2020 Anne Baanen. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anne Baanen -/ import Mathlib.LinearAlgebra.Dimension.StrongRankCondition import Mathlib.LinearAlgebra.FreeModule.Basic import Mathlib.LinearAlgebra.Matrix.ToLin /-! # Free modules over PID A free `R`-module `M` is a module with a basis over `R`, equivalently it is an `R`-module linearly equivalent to `ι →₀ R` for some `ι`. This file proves a submodule of a free `R`-module of finite rank is also a free `R`-module of finite rank, if `R` is a principal ideal domain (PID), i.e. we have instances `[IsDomain R] [IsPrincipalIdealRing R]`. We express "free `R`-module of finite rank" as a module `M` which has a basis `b : ι → R`, where `ι` is a `Fintype`. We call the cardinality of `ι` the rank of `M` in this file; it would be equal to `finrank R M` if `R` is a field and `M` is a vector space. ## Main results In this section, `M` is a free and finitely generated `R`-module, and `N` is a submodule of `M`. - `Submodule.inductionOnRank`: if `P` holds for `⊥ : Submodule R M` and if `P N` follows from `P N'` for all `N'` that are of lower rank, then `P` holds on all submodules - `Submodule.exists_basis_of_pid`: if `R` is a PID, then `N : Submodule R M` is free and finitely generated. This is the first part of the structure theorem for modules. - `Submodule.smithNormalForm`: if `R` is a PID, then `M` has a basis `bM` and `N` has a basis `bN` such that `bN i = a i • bM i`. Equivalently, a linear map `f : M →ₗ M` with `range f = N` can be written as a matrix in Smith normal form, a diagonal matrix with the coefficients `a i` along the diagonal. ## Tags free module, finitely generated module, rank, structure theorem -/ universe u v section Ring variable {R : Type u} {M : Type v} [Ring R] [AddCommGroup M] [Module R M] variable {ι : Type} (b : Basis ι R M) open Submodule.IsPrincipal Submodule theorem eq_bot_of_generator_maximal_map_eq_zero (b : Basis ι R M) {N : Submodule R M} {ϕ : M →ₗ[R] R} (hϕ : ∀ ψ : M →ₗ[R] R, ¬N.map ϕ < N.map ψ) [(N.map ϕ).IsPrincipal] (hgen : generator (N.map ϕ) = (0 : R)) : N = ⊥ := by rw [Submodule.eq_bot_iff] intro x hx refine b.ext_elem fun i ↦ ?_ rw [(eq_bot_iff_generator_eq_zero _).mpr hgen] at hϕ rw [LinearEquiv.map_zero, Finsupp.zero_apply] exact (Submodule.eq_bot_iff _).mp (not_bot_lt_iff.1 <\| hϕ (Finsupp.lapply i ∘ₗ ↑b.repr)) _ ⟨x, hx, rfl⟩ theorem eq_bot_of_generator_maximal_submoduleImage_eq_zero {N O : Submodule R M} (b : Basis ι R O) (hNO : N ≤ O) {ϕ : O →ₗ[R] R} (hϕ : ∀ ψ : O →ₗ[R] R, ¬ϕ.submoduleImage N < ψ.submoduleImage N) [(ϕ.submoduleImage N).IsPrincipal] (hgen : generator (ϕ.submoduleImage N) = 0) : N = ⊥ := by rw [Submodule.eq_bot_iff] intro x hx refine (mk_eq_zero _ _).mp (show (⟨x, hNO hx⟩ : O) = 0 from b.ext_elem fun i ↦ ?_) rw [(eq_bot_iff_generator_eq_zero _).mpr hgen] at hϕ rw [LinearEquiv.map_zero, Finsupp.zero_apply] refine (Submodule.eq_bot_iff _).mp (not_bot_lt_iff.1 <\| hϕ (Finsupp.lapply i ∘ₗ ↑b.repr)) _ ?_ exact (LinearMap.mem_submoduleImage_of_le hNO).mpr ⟨x, hx, rfl⟩ end Ring section IsDomain variable {ι : Type} {R : Type} [CommRing R] [IsDomain R] variable {M : Type} [AddCommGroup M] [Module R M] {b : ι → M} open Submodule.IsPrincipal Set Submodule theorem dvd_generator_iff {I : Ideal R} [I.IsPrincipal] {x : R} (hx : x ∈ I) : x ∣ generator I ↔ I = Ideal.span {x} := by conv_rhs => rw [← span_singleton_generator I] rw [Ideal.submodule_span_eq, Ideal.span_singleton_eq_span_singleton, ← dvd_dvd_iff_associated, ← mem_iff_generator_dvd] exact ⟨fun h ↦ ⟨hx, h⟩, fun h ↦ h.2⟩ end IsDomain section PrincipalIdealDomain open Submodule.IsPrincipal Set Submodule variable {ι : Type} {R : Type} [CommRing R] variable {M : Type} [AddCommGroup M] [Module R M] {b : ι → M} section StrongRankCondition variable [IsDomain R] [IsPrincipalIdealRing R] open Submodule.IsPrincipal theorem generator_maximal_submoduleImage_dvd {N O : Submodule R M} (hNO : N ≤ O) {ϕ : O →ₗ[R] R} (hϕ : ∀ ψ : O →ₗ[R] R, ¬ϕ.submoduleImage N < ψ.submoduleImage N) [(ϕ.submoduleImage N).IsPrincipal] (y : M) (yN : y ∈ N) (ϕy_eq : ϕ ⟨y, hNO yN⟩ = generator (ϕ.submoduleImage N)) (ψ : O →ₗ[R] R) : generator (ϕ.submoduleImage N) ∣ ψ ⟨y, hNO yN⟩ := by let a : R := generator (ϕ.submoduleImage N) let d : R := IsPrincipal.generator (Submodule.span R {a, ψ ⟨y, hNO yN⟩}) have d_dvd_left : d ∣ a := (mem_iff_generator_dvd _).mp (subset_span (mem_insert _ _)) have d_dvd_right : d ∣ ψ ⟨y, hNO yN⟩ := (mem_iff_generator_dvd _).mp (subset_span (mem_insert_of_mem _ (mem_singleton _))) refine dvd_trans ?_ d_dvd_right rw [dvd_generator_iff, Ideal.span, ← span_singleton_generator (Submodule.span R {a, ψ ⟨y, hNO yN⟩})] · obtain ⟨r₁, r₂, d_eq⟩ : ∃ r₁ r₂ : R, d = r₁ a + r₂ * ψ ⟨y, hNO yN⟩ := by obtain ⟨r₁, r₂', hr₂', hr₁⟩ := mem_span_insert.mp (IsPrincipal.generator_mem (Submodule.span R {a, ψ ⟨y, hNO yN⟩})) obtain ⟨r₂, rfl⟩ := mem_span_singleton.mp hr₂' exact ⟨r₁, r₂, hr₁⟩ let ψ' : O →ₗ[R] R := r₁ • ϕ + r₂ • ψ have : span R {d} ≤ ψ'.submoduleImage N := by rw [span_le, singleton_subset_iff, SetLike.mem_coe, LinearMap.mem_submoduleImage_of_le hNO] refine ⟨y, yN, ?_⟩ change r₁ * ϕ ⟨y, hNO yN⟩ + r₂ * ψ ⟨y, hNO yN⟩ = d rw [d_eq, ϕy_eq] refine le_antisymm (this.trans (le_of_eq ?_)) (Ideal.span_singleton_le_span_singleton.mpr d_dvd_left) rw [span_singleton_generator] apply (le_trans _ this).eq_of_not_gt (hϕ ψ') rw [← span_singleton_generator (ϕ.submoduleImage N)] exact Ideal.span_singleton_le_span_singleton.mpr d_dvd_left · exact subset_span (mem_insert _ _) /-- The induction hypothesis of `Submodule.basisOfPid` and `Submodule.smithNormalForm`. Basically, it says: let `N ≤ M` be a pair of submodules, then we can find a pair of submodules `N' ≤ M'` of strictly smaller rank, whose basis we can extend to get a basis of `N` and `M`. Moreover, if the basis for `M'` is up to scalars a basis for `N'`, then the basis we find for `M` is up to scalars a basis for `N`. For `basis_of_pid` we only need the first half and can fix `M = ⊤`, for `smith_normal_form` we need the full statement, but must also feed in a basis for `M` using `basis_of_pid` to keep the induction going. -/ theorem Submodule.basis_of_pid_aux [Finite ι] {O : Type} [AddCommGroup O] [Module R O] (M N : Submodule R O) (b'M : Basis ι R M) (N_bot : N ≠ ⊥) (N_le_M : N ≤ M) : ∃ y ∈ M, ∃ a : R, a • y ∈ N ∧ ∃ M' ≤ M, ∃ N' ≤ N, N' ≤ M' ∧ (∀ (c : R) (z : O), z ∈ M' → c • y + z = 0 → c = 0) ∧ (∀ (c : R) (z : O), z ∈ N' → c • a • y + z = 0 → c = 0) ∧ ∀ (n') (bN' : Basis (Fin n') R N'), ∃ bN : Basis (Fin (n' + 1)) R N, ∀ (m') (hn'm' : n' ≤ m') (bM' : Basis (Fin m') R M'), ∃ (hnm : n' + 1 ≤ m' + 1) (bM : Basis (Fin (m' + 1)) R M), ∀ as : Fin n' → R, (∀ i : Fin n', (bN' i : O) = as i • (bM' (Fin.castLE hn'm' i) : O)) → ∃ as' : Fin (n' + 1) → R, ∀ i : Fin (n' + 1), (bN i : O) = as' i • (bM (Fin.castLE hnm i) : O) := by -- Let `ϕ` be a maximal projection of `M` onto `R`, in the sense that there is -- no `ψ` whose image of `N` is larger than `ϕ`'s image of `N`. have : ∃ ϕ : M →ₗ[R] R, ∀ ψ : M →ₗ[R] R, ¬ϕ.submoduleImage N < ψ.submoduleImage N := by obtain ⟨P, P_eq, P_max⟩ := set_has_maximal_iff_noetherian.mpr (inferInstance : IsNoetherian R R) _ (show (Set.range fun ψ : M →ₗ[R] R ↦ ψ.submoduleImage N).Nonempty from ⟨_, Set.mem_range.mpr ⟨0, rfl⟩⟩) obtain ⟨ϕ, rfl⟩ := Set.mem_range.mp P_eq exact ⟨ϕ, fun ψ hψ ↦ P_max _ ⟨_, rfl⟩ hψ⟩ let ϕ := this.choose have ϕ_max := this.choose_spec -- Since `ϕ(N)` is an `R`-submodule of the PID `R`, -- it is principal and generated by some `a`. let a := generator (ϕ.submoduleImage N) have a_mem : a ∈ ϕ.submoduleImage N := generator_mem _ -- If `a` is zero, then the submodule is trivial. So let's assume `a ≠ 0`, `N ≠ ⊥`. by_cases a_zero : a = 0 · have := eq_bot_of_generator_maximal_submoduleImage_eq_zero b'M N_le_M ϕ_max a_zero contradiction -- We claim that `ϕ⁻¹ a = y` can be taken as basis element of `N`. obtain ⟨y, yN, ϕy_eq⟩ := (LinearMap.mem_submoduleImage_of_le N_le_M).mp a_mem have _ϕy_ne_zero : ϕ ⟨y, N_le_M yN⟩ ≠ 0 := fun h ↦ a_zero (ϕy_eq.symm.trans h) -- Write `y` as `a • y'` for some `y'`. have hdvd : ∀ i, a ∣ b'M.coord i ⟨y, N_le_M yN⟩ := fun i ↦ generator_maximal_submoduleImage_dvd N_le_M ϕ_max y yN ϕy_eq (b'M.coord i) choose c hc using hdvd cases nonempty_fintype ι let y' : O := ∑ i, c i • b'M i have y'M : y' ∈ M := M.sum_mem fun i _ ↦ M.smul_mem (c i) (b'M i).2 have mk_y' : (⟨y', y'M⟩ : M) = ∑ i, c i • b'M i := Subtype.ext (show y' = M.subtype _ by simp only [map_sum, map_smul] rfl) have a_smul_y' : a • y' = y := by refine Subtype.mk_eq_mk.mp (show (a • ⟨y', y'M⟩ : M) = ⟨y, N_le_M yN⟩ from ?_) rw [← b'M.sum_repr ⟨y, N_le_M yN⟩, mk_y', Finset.smul_sum] refine Finset.sum_congr rfl fun i _ ↦ ?_ rw [← mul_smul, ← hc] rfl -- We found a `y` and an `a`! refine ⟨y', y'M, a, a_smul_y'.symm ▸ yN, ?_⟩ have ϕy'_eq : ϕ ⟨y', y'M⟩ = 1 := mul_left_cancel₀ a_zero (calc a • ϕ ⟨y', y'M⟩ = ϕ ⟨a • y', _⟩ := (ϕ.map_smul a ⟨y', y'M⟩).symm _ = ϕ ⟨y, N_le_M yN⟩ := by simp only [a_smul_y'] _ = a := ϕy_eq _ = a 1 := (mul_one a).symm ) have ϕy'_ne_zero : ϕ ⟨y', y'M⟩ ≠ 0 := by simpa only [ϕy'_eq] using one_ne_zero -- `M' := ker (ϕ : M → R)` is smaller than `M` and `N' := ker (ϕ : N → R)` is smaller than `N`. let M' : Submodule R O := (LinearMap.ker ϕ).map M.subtype let N' : Submodule R O := (LinearMap.ker (ϕ.comp (inclusion N_le_M))).map N.subtype have M'_le_M : M' ≤ M := M.map_subtype_le (LinearMap.ker ϕ) have N'_le_M' : N' ≤ M' := by intro x hx simp only [N', mem_map, LinearMap.mem_ker] at hx ⊢ obtain ⟨⟨x, xN⟩, hx, rfl⟩ := hx exact ⟨⟨x, N_le_M xN⟩, hx, rfl⟩ have N'_le_N : N' ≤ N := N.map_subtype_le (LinearMap.ker (ϕ.comp (inclusion N_le_M))) -- So fill in those results as well. refine ⟨M', M'_le_M, N', N'_le_N, N'_le_M', ?_⟩ -- Note that `y'` is orthogonal to `M'`. have y'_ortho_M' : ∀ (c : R), ∀ z ∈ M', c • y' + z = 0 → c = 0 := by intro c x xM' hc obtain ⟨⟨x, xM⟩, hx', rfl⟩ := Submodule.mem_map.mp xM' rw [LinearMap.mem_ker] at hx' have hc' : (c • ⟨y', y'M⟩ + ⟨x, xM⟩ : M) = 0 := by exact @Subtype.coe_injective O (· ∈ M) _ _ hc simpa only [LinearMap.map_add, LinearMap.map_zero, LinearMap.map_smul, smul_eq_mul, add_zero, mul_eq_zero, ϕy'_ne_zero, hx', or_false] using congr_arg ϕ hc' -- And `a • y'` is orthogonal to `N'`. have ay'_ortho_N' : ∀ (c : R), ∀ z ∈ N', c • a • y' + z = 0 → c = 0 := by intro c z zN' hc refine (mul_eq_zero.mp (y'_ortho_M' (a * c) z (N'_le_M' zN') ?_)).resolve_left a_zero rw [mul_comm, mul_smul, hc] -- So we can extend a basis for `N'` with `y` refine ⟨y'_ortho_M', ay'_ortho_N', fun n' bN' ↦ ⟨?_, ?_⟩⟩ · refine Basis.mkFinConsOfLE y yN bN' N'_le_N ?_ ?_ · intro c z zN' hc refine ay'_ortho_N' c z zN' ?_ rwa [← a_smul_y'] at hc · intro z zN obtain ⟨b, hb⟩ : _ ∣ ϕ ⟨z, N_le_M zN⟩ := generator_submoduleImage_dvd_of_mem N_le_M ϕ zN refine ⟨-b, Submodule.mem_map.mpr ⟨⟨_, N.sub_mem zN (N.smul_mem b yN)⟩, ?_, ?_⟩⟩ · refine LinearMap.mem_ker.mpr (show ϕ (⟨z, N_le_M zN⟩ - b • ⟨y, N_le_M yN⟩) = 0 from ?_) rw [LinearMap.map_sub, LinearMap.map_smul, hb, ϕy_eq, smul_eq_mul, mul_comm, sub_self] · simp only [sub_eq_add_neg, neg_smul, coe_subtype] -- And extend a basis for `M'` with `y'` intro m' hn'm' bM' refine ⟨Nat.succ_le_succ hn'm', ?_, ?_⟩ · refine Basis.mkFinConsOfLE y' y'M bM' M'_le_M y'_ortho_M' ?_ intro z zM refine ⟨-ϕ ⟨z, zM⟩, ⟨⟨z, zM⟩ - ϕ ⟨z, zM⟩ • ⟨y', y'M⟩, LinearMap.mem_ker.mpr ?_, ?_⟩⟩ · rw [LinearMap.map_sub, LinearMap.map_smul, ϕy'_eq, smul_eq_mul, mul_one, sub_self] · rw [LinearMap.map_sub, LinearMap.map_smul, sub_eq_add_neg, neg_smul] rfl -- It remains to show the extended bases are compatible with each other. intro as h refine ⟨Fin.cons a as, ?_⟩ intro i rw [Basis.coe_mkFinConsOfLE, Basis.coe_mkFinConsOfLE] refine Fin.cases ?_ (fun i ↦ ?_) i · simp only [Fin.cons_zero, Fin.castLE_zero] exact a_smul_y'.symm · rw [Fin.castLE_succ] simp only [Fin.cons_succ, Function.comp_apply, coe_inclusion, map_coe, coe_subtype, h i] /-- A submodule of a free `R`-module of finite rank is also a free `R`-module of finite rank, if `R` is a principal ideal domain. This is a `lemma` to make the induction a bit easier. To actually access the basis, see `Submodule.basisOfPid`. See also the stronger version `Submodule.smithNormalForm`. -/ theorem Submodule.nonempty_basis_of_pid {ι : Type} [Finite ι] (b : Basis ι R M) (N : Submodule R M) : ∃ n : ℕ, Nonempty (Basis (Fin n) R N) := by haveI := Classical.decEq M cases nonempty_fintype ι induction N using inductionOnRank b with \| ih N ih => let b' := (b.reindex (Fintype.equivFin ι)).map (LinearEquiv.ofTop _ rfl).symm by_cases N_bot : N = ⊥ · subst N_bot exact ⟨0, ⟨Basis.empty _⟩⟩ obtain ⟨y, -, a, hay, M', -, N', N'_le_N, -, -, ay_ortho, h'⟩ := Submodule.basis_of_pid_aux ⊤ N b' N_bot le_top obtain ⟨n', ⟨bN'⟩⟩ := ih N' N'_le_N _ hay ay_ortho obtain ⟨bN, _hbN⟩ := h' n' bN' exact ⟨n' + 1, ⟨bN⟩⟩ /-- A submodule of a free `R`-module of finite rank is also a free `R`-module of finite rank, if `R` is a principal ideal domain. See also the stronger version `Submodule.smithNormalForm`. -/ noncomputable def Submodule.basisOfPid {ι : Type} [Finite ι] (b : Basis ι R M) (N : Submodule R M) : Σn : ℕ, Basis (Fin n) R N := ⟨_, (N.nonempty_basis_of_pid b).choose_spec.some⟩ theorem Submodule.basisOfPid_bot {ι : Type} [Finite ι] (b : Basis ι R M) : Submodule.basisOfPid b ⊥ = ⟨0, Basis.empty _⟩ := by obtain ⟨n, b'⟩ := Submodule.basisOfPid b ⊥ let e : Fin n ≃ Fin 0 := b'.indexEquiv (Basis.empty _ : Basis (Fin 0) R (⊥ : Submodule R M)) obtain rfl : n = 0 := by simpa using Fintype.card_eq.mpr ⟨e⟩ exact Sigma.eq rfl (Basis.eq_of_apply_eq <\| finZeroElim) /-- A submodule inside a free `R`-submodule of finite rank is also a free `R`-module of finite rank, if `R` is a principal ideal domain. See also the stronger version `Submodule.smithNormalFormOfLE`. -/ noncomputable def Submodule.basisOfPidOfLE {ι : Type} [Finite ι] {N O : Submodule R M} (hNO : N ≤ O) (b : Basis ι R O) : Σn : ℕ, Basis (Fin n) R N := let ⟨n, bN'⟩ := Submodule.basisOfPid b (N.comap O.subtype) ⟨n, bN'.map (Submodule.comapSubtypeEquivOfLe hNO)⟩ /-- A submodule inside the span of a linear independent family is a free `R`-module of finite rank, if `R` is a principal ideal domain. -/ noncomputable def Submodule.basisOfPidOfLESpan {ι : Type} [Finite ι] {b : ι → M} (hb : LinearIndependent R b) {N : Submodule R M} (le : N ≤ Submodule.span R (Set.range b)) : Σn : ℕ, Basis (Fin n) R N := Submodule.basisOfPidOfLE le (Basis.span hb) /-- A finite type torsion free module over a PID admits a basis. -/ noncomputable def Module.basisOfFiniteTypeTorsionFree [Fintype ι] {s : ι → M} (hs : span R (range s) = ⊤) [NoZeroSMulDivisors R M] : Σn : ℕ, Basis (Fin n) R M := by classical -- We define `N` as the submodule spanned by a maximal linear independent subfamily of `s` have := exists_maximal_linearIndepOn R s let I : Set ι := this.choose obtain ⟨indepI : LinearIndependent R (s ∘ (fun x => x) : I → M), hI : ∀ i ∉ I, ∃ a : R, a ≠ 0 ∧ a • s i ∈ span R (s '' I)⟩ := this.choose_spec let N := span R (range <\| (s ∘ (fun x => x) : I → M)) -- same as `span R (s '' I)` but more convenient let _sI : I → N := fun i ↦ ⟨s i.1, subset_span (mem_range_self i)⟩ -- `s` restricted to `I` is a basis of `N` let sI_basis : Basis I R N := Basis.span indepI -- Our first goal is to build `A ≠ 0` such that `A • M ⊆ N` have exists_a : ∀ i : ι, ∃ a : R, a ≠ 0 ∧ a • s i ∈ N := by intro i by_cases hi : i ∈ I · use 1, zero_ne_one.symm rw [one_smul] exact subset_span (mem_range_self (⟨i, hi⟩ : I)) · simpa [image_eq_range s I] using hI i hi choose a ha ha' using exists_a let A := ∏ i, a i have hA : A ≠ 0 := by rw [Finset.prod_ne_zero_iff] simpa using ha -- `M ≃ A • M` because `M` is torsion free and `A ≠ 0` let φ : M →ₗ[R] M := LinearMap.lsmul R M A have : LinearMap.ker φ = ⊥ := @LinearMap.ker_lsmul R M _ _ _ _ _ hA let ψ := LinearEquiv.ofInjective φ (LinearMap.ker_eq_bot.mp this) have : LinearMap.range φ ≤ N := by -- as announced, `A • M ⊆ N` suffices ∀ i, φ (s i) ∈ N by rw [LinearMap.range_eq_map, ← hs, map_span_le] rintro _ ⟨i, rfl⟩ apply this intro i calc (∏ j ∈ {i}ᶜ, a j) • a i • s i ∈ N := N.smul_mem _ (ha' i) _ = (∏ j, a j) • s i := by rw [Fintype.prod_eq_prod_compl_mul i, mul_smul] -- Since a submodule of a free `R`-module is free, we get that `A • M` is free obtain ⟨n, b : Basis (Fin n) R (LinearMap.range φ)⟩ := Submodule.basisOfPidOfLE this sI_basis -- hence `M` is free. exact ⟨n, b.map ψ.symm⟩ theorem Module.free_of_finite_type_torsion_free [_root_.Finite ι] {s : ι → M} (hs : span R (range s) = ⊤) [NoZeroSMulDivisors R M] : Module.Free R M := by cases nonempty_fintype ι obtain ⟨n, b⟩ : Σn, Basis (Fin n) R M := Module.basisOfFiniteTypeTorsionFree hs exact Module.Free.of_basis b /-- A finite type torsion free module over a PID admits a basis. -/ noncomputable def Module.basisOfFiniteTypeTorsionFree' [Module.Finite R M] [NoZeroSMulDivisors R M] : Σn : ℕ, Basis (Fin n) R M := Module.basisOfFiniteTypeTorsionFree Module.Finite.exists_fin.choose_spec.choose_spec instance Module.free_of_finite_type_torsion_free' [Module.Finite R M] [NoZeroSMulDivisors R M] : Module.Free R M := by obtain ⟨n, b⟩ : Σn, Basis (Fin n) R M := Module.basisOfFiniteTypeTorsionFree' exact Module.Free.of_basis b instance {S : Type} [CommRing S] [Algebra R S] {I : Ideal S} [hI₁ : Module.Finite R I] [hI₂ : NoZeroSMulDivisors R I] : Module.Free R I := by have : Module.Finite R (restrictScalars R I) := hI₁ have : NoZeroSMulDivisors R (restrictScalars R I) := hI₂ change Module.Free R (restrictScalars R I) exact Module.free_of_finite_type_torsion_free' theorem Module.free_iff_noZeroSMulDivisors [Module.Finite R M] : Module.Free R M ↔ NoZeroSMulDivisors R M := ⟨fun _ ↦ inferInstance, fun _ ↦ inferInstance⟩ end StrongRankCondition section SmithNormal /-- A Smith normal form basis for a submodule `N` of a module `M` consists of bases for `M` and `N` such that the inclusion map `N → M` can be written as a (rectangular) matrix with `a` along the diagonal: in Smith normal form. -/ structure Basis.SmithNormalForm (N : Submodule R M) (ι : Type*) (n : ℕ) where /-- The basis of M. -/ bM : Basis ι R M /-- The basis of N. -/ bN : Basis (Fin n) R N /-- The mapping between the vectors of the bases. -/ f : Fin n ↪ ι /-- The (diagonal) entries of the matrix. -/ a : Fin n → R /-- The SNF relation between the vectors of the bases. -/ snf : ∀ i, (bN i : M) = a i • bM (f i) namespace Basis.SmithNormalForm variable {n : ℕ} {N : Submodule R M} (snf : Basis.SmithNormalForm N ι n) (m : N) lemma repr_eq_zero_of_nmem_range {i : ι} (hi : i ∉ Set.range snf.f) : snf.bM.repr m i = 0 := by obtain ⟨m, hm⟩ := m obtain ⟨c, rfl⟩ := snf.bN.mem_submodule_iff.mp hm replace hi : ∀ j, snf.f j ≠ i := by simpa using hi simp [Finsupp.single_apply, hi, snf.snf, map_finsuppSum] lemma le_ker_coord_of_nmem_range {i : ι} (hi : i ∉ Set.range snf.f) : N ≤ LinearMap.ker (snf.bM.coord i) := fun m hm ↦ snf.repr_eq_zero_of_nmem_range ⟨m, hm⟩ hi @[simp] lemma repr_apply_embedding_eq_repr_smul {i : Fin n} : snf.bM.repr m (snf.f i) = snf.bN.repr (snf.a i • m) i := by obtain ⟨m, hm⟩ := m obtain ⟨c, rfl⟩ := snf.bN.mem_submodule_iff.mp hm replace hm : (⟨Finsupp.sum c fun i t ↦ t • (↑(snf.bN i) : M), hm⟩ : N) = Finsupp.sum c fun i t ↦ t • ⟨snf.bN i, (snf.bN i).2⟩ := by ext; change _ = N.subtype _; simp [map_finsuppSum] classical simp_rw [hm, map_smul, map_finsuppSum, map_smul, Subtype.coe_eta, repr_self, Finsupp.smul_single, smul_eq_mul, mul_one, Finsupp.sum_single, Finsupp.smul_apply, snf.snf, map_smul, repr_self, Finsupp.smul_single, smul_eq_mul, mul_one, Finsupp.sum_apply, Finsupp.single_apply, EmbeddingLike.apply_eq_iff_eq, Finsupp.sum_ite_eq', Finsupp.mem_support_iff, ite_not, mul_comm, ite_eq_right_iff] exact fun a ↦ (mul_eq_zero_of_right _ a).symm @[simp] lemma repr_comp_embedding_eq_smul : snf.bM.repr m ∘ snf.f = snf.a • (snf.bN.repr m : Fin n → R) := by ext i simp [Pi.smul_apply (snf.a i)] @[simp] lemma coord_apply_embedding_eq_smul_coord {i : Fin n} : snf.bM.coord (snf.f i) ∘ₗ N.subtype = snf.a i • snf.bN.coord i := by ext m simp [Pi.smul_apply (snf.a i)] /-- Given a Smith-normal-form pair of bases for `N ⊆ M`, and a linear endomorphism `f` of `M` that preserves `N`, the diagonal of the matrix of the restriction `f` to `N` does not depend on	which of the two bases for `N` is used. -/ @[simp] lemma toMatrix_restrict_eq_toMatrix [Fintype ι] [DecidableEq ι] (f : M →ₗ[R] M) (hf : ∀ x, f x ∈ N) (hf' : ∀ x ∈ N, f x ∈ N := fun x _ ↦ hf x) {i : Fin n} :	Mathlib/LinearAlgebra/FreeModule/PID.lean	469	472
/- Copyright (c) 2018 Louis Carlin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Louis Carlin, Mario Carneiro -/ import Mathlib.Algebra.EuclideanDomain.Defs import Mathlib.Algebra.Ring.Divisibility.Basic import Mathlib.Algebra.Ring.Regular import Mathlib.Algebra.GroupWithZero.Divisibility import Mathlib.Algebra.Ring.Basic /-! # Lemmas about Euclidean domains ## Main statements * `gcd_eq_gcd_ab`: states Bézout's lemma for Euclidean domains. -/ universe u namespace EuclideanDomain variable {R : Type u} variable [EuclideanDomain R] /-- The well founded relation in a Euclidean Domain satisfying `a % b ≺ b` for `b ≠ 0` -/ local infixl:50 " ≺ " => EuclideanDomain.r -- See note [lower instance priority] instance (priority := 100) toMulDivCancelClass : MulDivCancelClass R where mul_div_cancel a b hb := by refine (eq_of_sub_eq_zero ?_).symm by_contra h have := mul_right_not_lt b h rw [sub_mul, mul_comm (_ / _), sub_eq_iff_eq_add'.2 (div_add_mod (a * b) b).symm] at this exact this (mod_lt _ hb) theorem mod_eq_sub_mul_div {R : Type} [EuclideanDomain R] (a b : R) : a % b = a - b (a / b) := calc a % b = b * (a / b) + a % b - b * (a / b) := (add_sub_cancel_left _ _).symm _ = a - b * (a / b) := by rw [div_add_mod] theorem val_dvd_le : ∀ a b : R, b ∣ a → a ≠ 0 → ¬a ≺ b \| _, b, ⟨d, rfl⟩, ha => mul_left_not_lt b (mt (by rintro rfl; exact mul_zero _) ha) @[simp] theorem mod_eq_zero {a b : R} : a % b = 0 ↔ b ∣ a := ⟨fun h => by rw [← div_add_mod a b, h, add_zero] exact dvd_mul_right _ _, fun ⟨c, e⟩ => by rw [e, ← add_left_cancel_iff, div_add_mod, add_zero] haveI := Classical.dec by_cases b0 : b = 0 · simp only [b0, zero_mul] · rw [mul_div_cancel_left₀ _ b0]⟩ @[simp] theorem mod_self (a : R) : a % a = 0 := mod_eq_zero.2 dvd_rfl theorem dvd_mod_iff {a b c : R} (h : c ∣ b) : c ∣ a % b ↔ c ∣ a := by rw [← dvd_add_right (h.mul_right _), div_add_mod] @[simp] theorem mod_one (a : R) : a % 1 = 0 := mod_eq_zero.2 (one_dvd _) @[simp] theorem zero_mod (b : R) : 0 % b = 0 := mod_eq_zero.2 (dvd_zero _) @[simp] theorem zero_div {a : R} : 0 / a = 0 := by_cases (fun a0 : a = 0 => a0.symm ▸ div_zero 0) fun a0 => by simpa only [zero_mul] using mul_div_cancel_right₀ 0 a0 @[simp] theorem div_self {a : R} (a0 : a ≠ 0) : a / a = 1 := by simpa only [one_mul] using mul_div_cancel_right₀ 1 a0 theorem eq_div_of_mul_eq_left {a b c : R} (hb : b ≠ 0) (h : a * b = c) : a = c / b := by rw [← h, mul_div_cancel_right₀ _ hb] theorem eq_div_of_mul_eq_right {a b c : R} (ha : a ≠ 0) (h : a * b = c) : b = c / a := by rw [← h, mul_div_cancel_left₀ _ ha] theorem mul_div_assoc (x : R) {y z : R} (h : z ∣ y) : x * y / z = x * (y / z) := by by_cases hz : z = 0 · subst hz rw [div_zero, div_zero, mul_zero] rcases h with ⟨p, rfl⟩ rw [mul_div_cancel_left₀ _ hz, mul_left_comm, mul_div_cancel_left₀ _ hz] protected theorem mul_div_cancel' {a b : R} (hb : b ≠ 0) (hab : b ∣ a) : b * (a / b) = a := by rw [← mul_div_assoc _ hab, mul_div_cancel_left₀ _ hb] -- This generalizes `Int.div_one`, see note [simp-normal form] @[simp] theorem div_one (p : R) : p / 1 = p := (EuclideanDomain.eq_div_of_mul_eq_left (one_ne_zero' R) (mul_one p)).symm theorem div_dvd_of_dvd {p q : R} (hpq : q ∣ p) : p / q ∣ p := by by_cases hq : q = 0 · rw [hq, zero_dvd_iff] at hpq rw [hpq] exact dvd_zero _ use q rw [mul_comm, ← EuclideanDomain.mul_div_assoc _ hpq, mul_comm, mul_div_cancel_right₀ _ hq] theorem dvd_div_of_mul_dvd {a b c : R} (h : a * b ∣ c) : b ∣ c / a := by rcases eq_or_ne a 0 with (rfl \| ha) · simp only [div_zero, dvd_zero] rcases h with ⟨d, rfl⟩ refine ⟨d, ?_⟩ rw [mul_assoc, mul_div_cancel_left₀ _ ha] section GCD variable [DecidableEq R] @[simp] theorem gcd_zero_right (a : R) : gcd a 0 = a := by rw [gcd] split_ifs with h <;> simp only [h, zero_mod, gcd_zero_left] theorem gcd_val (a b : R) : gcd a b = gcd (b % a) a := by rw [gcd] split_ifs with h <;> [simp only [h, mod_zero, gcd_zero_right]; rfl] theorem gcd_dvd (a b : R) : gcd a b ∣ a ∧ gcd a b ∣ b := GCD.induction a b (fun b => by rw [gcd_zero_left] exact ⟨dvd_zero _, dvd_rfl⟩) fun a b _ ⟨IH₁, IH₂⟩ => by rw [gcd_val] exact ⟨IH₂, (dvd_mod_iff IH₂).1 IH₁⟩ theorem gcd_dvd_left (a b : R) : gcd a b ∣ a := (gcd_dvd a b).left theorem gcd_dvd_right (a b : R) : gcd a b ∣ b :=	(gcd_dvd a b).right protected theorem gcd_eq_zero_iff {a b : R} : gcd a b = 0 ↔ a = 0 ∧ b = 0 := ⟨fun h => by simpa [h] using gcd_dvd a b, by rintro ⟨rfl, rfl⟩ exact gcd_zero_right _⟩ theorem dvd_gcd {a b c : R} : c ∣ a → c ∣ b → c ∣ gcd a b :=	Mathlib/Algebra/EuclideanDomain/Basic.lean	146	153
/- Copyright (c) 2019 Amelia Livingston. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Amelia Livingston, Bryan Gin-ge Chen -/ import Mathlib.Logic.Relation import Mathlib.Order.CompleteLattice.Basic import Mathlib.Order.GaloisConnection.Defs /-! # Equivalence relations This file defines the complete lattice of equivalence relations on a type, results about the inductively defined equivalence closure of a binary relation, and the analogues of some isomorphism theorems for quotients of arbitrary types. ## Implementation notes The complete lattice instance for equivalence relations could have been defined by lifting the Galois insertion of equivalence relations on α into binary relations on α, and then using `CompleteLattice.copy` to define a complete lattice instance with more appropriate definitional equalities (a similar example is `Filter.CompleteLattice` in `Mathlib/Order/Filter/Basic.lean`). This does not save space, however, and is less clear. Partitions are not defined as a separate structure here; users are encouraged to reason about them using the existing `Setoid` and its infrastructure. ## Tags setoid, equivalence, iseqv, relation, equivalence relation -/ attribute [refl, simp] Setoid.refl attribute [symm] Setoid.symm attribute [trans] Setoid.trans variable {α : Type} {β : Type} namespace Setoid attribute [ext] ext /-- Two equivalence relations are equal iff their underlying binary operations are equal. -/ theorem eq_iff_rel_eq {r₁ r₂ : Setoid α} : r₁ = r₂ ↔ ⇑r₁ = ⇑r₂ := ⟨fun h => h ▸ rfl, fun h => Setoid.ext fun _ _ => h ▸ Iff.rfl⟩ /-- Defining `≤` for equivalence relations. -/ instance : LE (Setoid α) := ⟨fun r s => ∀ ⦃x y⦄, r x y → s x y⟩ theorem le_def {r s : Setoid α} : r ≤ s ↔ ∀ {x y}, r x y → s x y := Iff.rfl @[refl] theorem refl' (r : Setoid α) (x) : r x x := r.iseqv.refl x @[symm] theorem symm' (r : Setoid α) : ∀ {x y}, r x y → r y x := r.iseqv.symm @[trans] theorem trans' (r : Setoid α) : ∀ {x y z}, r x y → r y z → r x z := r.iseqv.trans theorem comm' (s : Setoid α) {x y} : s x y ↔ s y x := ⟨s.symm', s.symm'⟩ open scoped Function -- required for scoped `on` notation /-- The kernel of a function is an equivalence relation. -/ def ker (f : α → β) : Setoid α := ⟨(· = ·) on f, eq_equivalence.comap f⟩ /-- The kernel of the quotient map induced by an equivalence relation r equals r. -/ @[simp] theorem ker_mk_eq (r : Setoid α) : ker (@Quotient.mk'' _ r) = r := ext fun _ _ => Quotient.eq theorem ker_apply_mk_out {f : α → β} (a : α) : f (⟦a⟧ : Quotient (Setoid.ker f)).out = f a := @Quotient.mk_out _ (Setoid.ker f) a theorem ker_def {f : α → β} {x y : α} : ker f x y ↔ f x = f y := Iff.rfl /-- Given types `α`, `β`, the product of two equivalence relations `r` on `α` and `s` on `β`: `(x₁, x₂), (y₁, y₂) ∈ α × β` are related by `r.prod s` iff `x₁` is related to `y₁` by `r` and `x₂` is related to `y₂` by `s`. -/ protected def prod (r : Setoid α) (s : Setoid β) : Setoid (α × β) where r x y := r x.1 y.1 ∧ s x.2 y.2 iseqv := ⟨fun x => ⟨r.refl' x.1, s.refl' x.2⟩, fun h => ⟨r.symm' h.1, s.symm' h.2⟩, fun h₁ h₂ => ⟨r.trans' h₁.1 h₂.1, s.trans' h₁.2 h₂.2⟩⟩ lemma prod_apply {r : Setoid α} {s : Setoid β} {x₁ x₂ : α} {y₁ y₂ : β} : @Setoid.r _ (r.prod s) (x₁, y₁) (x₂, y₂) ↔ (@Setoid.r _ r x₁ x₂ ∧ @Setoid.r _ s y₁ y₂) := Iff.rfl lemma piSetoid_apply {ι : Sort} {α : ι → Sort} {r : ∀ i, Setoid (α i)} {x y : ∀ i, α i} : @Setoid.r _ (@piSetoid _ _ r) x y ↔ ∀ i, @Setoid.r _ (r i) (x i) (y i) := Iff.rfl /-- A bijection between the product of two quotients and the quotient by the product of the equivalence relations. -/ @[simps] def prodQuotientEquiv (r : Setoid α) (s : Setoid β) : Quotient r × Quotient s ≃ Quotient (r.prod s) where toFun \| (x, y) => Quotient.map₂ Prod.mk (fun _ _ hx _ _ hy ↦ ⟨hx, hy⟩) x y invFun q := Quotient.liftOn' q (fun xy ↦ (Quotient.mk'' xy.1, Quotient.mk'' xy.2)) fun x y hxy ↦ Prod.ext (by simpa using hxy.1) (by simpa using hxy.2) left_inv q := by rcases q with ⟨qa, qb⟩ exact Quotient.inductionOn₂' qa qb fun _ _ ↦ rfl right_inv q := by simp only refine Quotient.inductionOn' q fun _ ↦ rfl /-- A bijection between an indexed product of quotients and the quotient by the product of the equivalence relations. -/ @[simps] noncomputable def piQuotientEquiv {ι : Sort} {α : ι → Sort} (r : ∀ i, Setoid (α i)) : (∀ i, Quotient (r i)) ≃ Quotient (@piSetoid _ _ r) where toFun x := Quotient.mk'' fun i ↦ (x i).out invFun q := Quotient.liftOn' q (fun x i ↦ Quotient.mk'' (x i)) fun x y hxy ↦ by ext i simpa using hxy i left_inv q := by ext i simp right_inv q := by refine Quotient.inductionOn' q fun _ ↦ ?_ simp only [Quotient.liftOn'_mk'', Quotient.eq''] intro i change Setoid.r _ _ rw [← Quotient.eq''] simp /-- The infimum of two equivalence relations. -/ instance : Min (Setoid α) := ⟨fun r s => ⟨fun x y => r x y ∧ s x y, ⟨fun x => ⟨r.refl' x, s.refl' x⟩, fun h => ⟨r.symm' h.1, s.symm' h.2⟩, fun h1 h2 => ⟨r.trans' h1.1 h2.1, s.trans' h1.2 h2.2⟩⟩⟩⟩ /-- The infimum of 2 equivalence relations r and s is the same relation as the infimum of the underlying binary operations. -/ theorem inf_def {r s : Setoid α} : ⇑(r ⊓ s) = ⇑r ⊓ ⇑s := rfl theorem inf_iff_and {r s : Setoid α} {x y} : (r ⊓ s) x y ↔ r x y ∧ s x y := Iff.rfl /-- The infimum of a set of equivalence relations. -/ instance : InfSet (Setoid α) := ⟨fun S => { r := fun x y => ∀ r ∈ S, r x y	iseqv := ⟨fun x r _ => r.refl' x, fun h r hr => r.symm' <\| h r hr, fun h1 h2 r hr => r.trans' (h1 r hr) <\| h2 r hr⟩ }⟩ /-- The underlying binary operation of the infimum of a set of equivalence relations	Mathlib/Data/Setoid/Basic.lean	155	158
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Floris van Doorn, Violeta Hernández Palacios -/ import Mathlib.Algebra.GroupWithZero.Divisibility import Mathlib.Data.Nat.SuccPred import Mathlib.Order.SuccPred.InitialSeg import Mathlib.SetTheory.Ordinal.Basic /-! # Ordinal arithmetic Ordinals have an addition (corresponding to disjoint union) that turns them into an additive monoid, and a multiplication (corresponding to the lexicographic order on the product) that turns them into a monoid. One can also define correspondingly a subtraction, a division, a successor function, a power function and a logarithm function. We also define limit ordinals and prove the basic induction principle on ordinals separating successor ordinals and limit ordinals, in `limitRecOn`. ## Main definitions and results * `o₁ + o₂` is the order on the disjoint union of `o₁` and `o₂` obtained by declaring that every element of `o₁` is smaller than every element of `o₂`. * `o₁ - o₂` is the unique ordinal `o` such that `o₂ + o = o₁`, when `o₂ ≤ o₁`. * `o₁ * o₂` is the lexicographic order on `o₂ × o₁`. * `o₁ / o₂` is the ordinal `o` such that `o₁ = o₂ * o + o'` with `o' < o₂`. We also define the divisibility predicate, and a modulo operation. * `Order.succ o = o + 1` is the successor of `o`. * `pred o` if the predecessor of `o`. If `o` is not a successor, we set `pred o = o`. We discuss the properties of casts of natural numbers of and of `ω` with respect to these operations. Some properties of the operations are also used to discuss general tools on ordinals: * `IsLimit o`: an ordinal is a limit ordinal if it is neither `0` nor a successor. * `limitRecOn` is the main induction principle of ordinals: if one can prove a property by induction at successor ordinals and at limit ordinals, then it holds for all ordinals. * `IsNormal`: a function `f : Ordinal → Ordinal` satisfies `IsNormal` if it is strictly increasing and order-continuous, i.e., the image `f o` of a limit ordinal `o` is the sup of `f a` for `a < o`. Various other basic arithmetic results are given in `Principal.lean` instead. -/ assert_not_exists Field Module noncomputable section open Function Cardinal Set Equiv Order open scoped Ordinal universe u v w namespace Ordinal variable {α β γ : Type} {r : α → α → Prop} {s : β → β → Prop} {t : γ → γ → Prop} /-! ### Further properties of addition on ordinals -/ @[simp] theorem lift_add (a b : Ordinal.{v}) : lift.{u} (a + b) = lift.{u} a + lift.{u} b := Quotient.inductionOn₂ a b fun ⟨_α, _r, _⟩ ⟨_β, _s, _⟩ => Quotient.sound ⟨(RelIso.preimage Equiv.ulift _).trans (RelIso.sumLexCongr (RelIso.preimage Equiv.ulift _) (RelIso.preimage Equiv.ulift _)).symm⟩ @[simp] theorem lift_succ (a : Ordinal.{v}) : lift.{u} (succ a) = succ (lift.{u} a) := by rw [← add_one_eq_succ, lift_add, lift_one] rfl instance instAddLeftReflectLE : AddLeftReflectLE Ordinal.{u} where elim c a b := by refine inductionOn₃ a b c fun α r _ β s _ γ t _ ⟨f⟩ ↦ ?_ have H₁ a : f (Sum.inl a) = Sum.inl a := by simpa using ((InitialSeg.leAdd t r).trans f).eq (InitialSeg.leAdd t s) a have H₂ a : ∃ b, f (Sum.inr a) = Sum.inr b := by generalize hx : f (Sum.inr a) = x obtain x \| x := x · rw [← H₁, f.inj] at hx contradiction · exact ⟨x, rfl⟩ choose g hg using H₂ refine (RelEmbedding.ofMonotone g fun _ _ h ↦ ?_).ordinal_type_le rwa [← @Sum.lex_inr_inr _ t _ s, ← hg, ← hg, f.map_rel_iff, Sum.lex_inr_inr] instance : IsLeftCancelAdd Ordinal where add_left_cancel a b c h := by simpa only [le_antisymm_iff, add_le_add_iff_left] using h @[deprecated add_left_cancel_iff (since := "2024-12-11")] protected theorem add_left_cancel (a) {b c : Ordinal} : a + b = a + c ↔ b = c := add_left_cancel_iff private theorem add_lt_add_iff_left' (a) {b c : Ordinal} : a + b < a + c ↔ b < c := by rw [← not_le, ← not_le, add_le_add_iff_left] instance instAddLeftStrictMono : AddLeftStrictMono Ordinal.{u} := ⟨fun a _b _c ↦ (add_lt_add_iff_left' a).2⟩ instance instAddLeftReflectLT : AddLeftReflectLT Ordinal.{u} := ⟨fun a _b _c ↦ (add_lt_add_iff_left' a).1⟩ instance instAddRightReflectLT : AddRightReflectLT Ordinal.{u} := ⟨fun _a _b _c ↦ lt_imp_lt_of_le_imp_le fun h => add_le_add_right h _⟩ theorem add_le_add_iff_right {a b : Ordinal} : ∀ n : ℕ, a + n ≤ b + n ↔ a ≤ b \| 0 => by simp \| n + 1 => by simp only [natCast_succ, add_succ, add_succ, succ_le_succ_iff, add_le_add_iff_right] theorem add_right_cancel {a b : Ordinal} (n : ℕ) : a + n = b + n ↔ a = b := by simp only [le_antisymm_iff, add_le_add_iff_right] theorem add_eq_zero_iff {a b : Ordinal} : a + b = 0 ↔ a = 0 ∧ b = 0 := inductionOn₂ a b fun α r _ β s _ => by simp_rw [← type_sum_lex, type_eq_zero_iff_isEmpty] exact isEmpty_sum theorem left_eq_zero_of_add_eq_zero {a b : Ordinal} (h : a + b = 0) : a = 0 := (add_eq_zero_iff.1 h).1 theorem right_eq_zero_of_add_eq_zero {a b : Ordinal} (h : a + b = 0) : b = 0 := (add_eq_zero_iff.1 h).2 /-! ### The predecessor of an ordinal -/ open Classical in /-- The ordinal predecessor of `o` is `o'` if `o = succ o'`, and `o` otherwise. -/ def pred (o : Ordinal) : Ordinal := if h : ∃ a, o = succ a then Classical.choose h else o @[simp] theorem pred_succ (o) : pred (succ o) = o := by have h : ∃ a, succ o = succ a := ⟨_, rfl⟩ simpa only [pred, dif_pos h] using (succ_injective <\| Classical.choose_spec h).symm theorem pred_le_self (o) : pred o ≤ o := by classical exact if h : ∃ a, o = succ a then by let ⟨a, e⟩ := h rw [e, pred_succ]; exact le_succ a else by rw [pred, dif_neg h] theorem pred_eq_iff_not_succ {o} : pred o = o ↔ ¬∃ a, o = succ a := ⟨fun e ⟨a, e'⟩ => by rw [e', pred_succ] at e; exact (lt_succ a).ne e, fun h => dif_neg h⟩ theorem pred_eq_iff_not_succ' {o} : pred o = o ↔ ∀ a, o ≠ succ a := by simpa using pred_eq_iff_not_succ theorem pred_lt_iff_is_succ {o} : pred o < o ↔ ∃ a, o = succ a := Iff.trans (by simp only [le_antisymm_iff, pred_le_self, true_and, not_le]) (iff_not_comm.1 pred_eq_iff_not_succ).symm @[simp] theorem pred_zero : pred 0 = 0 := pred_eq_iff_not_succ'.2 fun a => (succ_ne_zero a).symm theorem succ_pred_iff_is_succ {o} : succ (pred o) = o ↔ ∃ a, o = succ a := ⟨fun e => ⟨_, e.symm⟩, fun ⟨a, e⟩ => by simp only [e, pred_succ]⟩ theorem succ_lt_of_not_succ {o b : Ordinal} (h : ¬∃ a, o = succ a) : succ b < o ↔ b < o := ⟨(lt_succ b).trans, fun l => lt_of_le_of_ne (succ_le_of_lt l) fun e => h ⟨_, e.symm⟩⟩ theorem lt_pred {a b} : a < pred b ↔ succ a < b := by classical exact if h : ∃ a, b = succ a then by let ⟨c, e⟩ := h rw [e, pred_succ, succ_lt_succ_iff] else by simp only [pred, dif_neg h, succ_lt_of_not_succ h] theorem pred_le {a b} : pred a ≤ b ↔ a ≤ succ b := le_iff_le_iff_lt_iff_lt.2 lt_pred @[simp] theorem lift_is_succ {o : Ordinal.{v}} : (∃ a, lift.{u} o = succ a) ↔ ∃ a, o = succ a := ⟨fun ⟨a, h⟩ => let ⟨b, e⟩ := mem_range_lift_of_le <\| show a ≤ lift.{u} o from le_of_lt <\| h.symm ▸ lt_succ a ⟨b, (lift_inj.{u,v}).1 <\| by rw [h, ← e, lift_succ]⟩, fun ⟨a, h⟩ => ⟨lift.{u} a, by simp only [h, lift_succ]⟩⟩ @[simp] theorem lift_pred (o : Ordinal.{v}) : lift.{u} (pred o) = pred (lift.{u} o) := by classical exact if h : ∃ a, o = succ a then by obtain ⟨a, e⟩ := h; simp only [e, pred_succ, lift_succ] else by rw [pred_eq_iff_not_succ.2 h, pred_eq_iff_not_succ.2 (mt lift_is_succ.1 h)] /-! ### Limit ordinals -/ /-- A limit ordinal is an ordinal which is not zero and not a successor. TODO: deprecate this in favor of `Order.IsSuccLimit`. -/ def IsLimit (o : Ordinal) : Prop := IsSuccLimit o theorem isLimit_iff {o} : IsLimit o ↔ o ≠ 0 ∧ IsSuccPrelimit o := by simp [IsLimit, IsSuccLimit] theorem IsLimit.isSuccPrelimit {o} (h : IsLimit o) : IsSuccPrelimit o := IsSuccLimit.isSuccPrelimit h theorem IsLimit.succ_lt {o a : Ordinal} (h : IsLimit o) : a < o → succ a < o := IsSuccLimit.succ_lt h theorem isSuccPrelimit_zero : IsSuccPrelimit (0 : Ordinal) := isSuccPrelimit_bot theorem not_zero_isLimit : ¬IsLimit 0 := not_isSuccLimit_bot theorem not_succ_isLimit (o) : ¬IsLimit (succ o) := not_isSuccLimit_succ o theorem not_succ_of_isLimit {o} (h : IsLimit o) : ¬∃ a, o = succ a \| ⟨a, e⟩ => not_succ_isLimit a (e ▸ h) theorem succ_lt_of_isLimit {o a : Ordinal} (h : IsLimit o) : succ a < o ↔ a < o := IsSuccLimit.succ_lt_iff h theorem le_succ_of_isLimit {o} (h : IsLimit o) {a} : o ≤ succ a ↔ o ≤ a := le_iff_le_iff_lt_iff_lt.2 <\| succ_lt_of_isLimit h theorem limit_le {o} (h : IsLimit o) {a} : o ≤ a ↔ ∀ x < o, x ≤ a := ⟨fun h _x l => l.le.trans h, fun H => (le_succ_of_isLimit h).1 <\| le_of_not_lt fun hn => not_lt_of_le (H _ hn) (lt_succ a)⟩ theorem lt_limit {o} (h : IsLimit o) {a} : a < o ↔ ∃ x < o, a < x := by -- Porting note: `bex_def` is required. simpa only [not_forall₂, not_le, bex_def] using not_congr (@limit_le _ h a) @[simp] theorem lift_isLimit (o : Ordinal.{v}) : IsLimit (lift.{u,v} o) ↔ IsLimit o := liftInitialSeg.isSuccLimit_apply_iff theorem IsLimit.pos {o : Ordinal} (h : IsLimit o) : 0 < o := IsSuccLimit.bot_lt h theorem IsLimit.ne_zero {o : Ordinal} (h : IsLimit o) : o ≠ 0 := h.pos.ne' theorem IsLimit.one_lt {o : Ordinal} (h : IsLimit o) : 1 < o := by simpa only [succ_zero] using h.succ_lt h.pos theorem IsLimit.nat_lt {o : Ordinal} (h : IsLimit o) : ∀ n : ℕ, (n : Ordinal) < o \| 0 => h.pos \| n + 1 => h.succ_lt (IsLimit.nat_lt h n) theorem zero_or_succ_or_limit (o : Ordinal) : o = 0 ∨ (∃ a, o = succ a) ∨ IsLimit o := by simpa [eq_comm] using isMin_or_mem_range_succ_or_isSuccLimit o theorem isLimit_of_not_succ_of_ne_zero {o : Ordinal} (h : ¬∃ a, o = succ a) (h' : o ≠ 0) : IsLimit o := ((zero_or_succ_or_limit o).resolve_left h').resolve_left h -- TODO: this is an iff with `IsSuccPrelimit` theorem IsLimit.sSup_Iio {o : Ordinal} (h : IsLimit o) : sSup (Iio o) = o := by apply (csSup_le' (fun a ha ↦ le_of_lt ha)).antisymm apply le_of_forall_lt intro a ha exact (lt_succ a).trans_le (le_csSup bddAbove_Iio (h.succ_lt ha)) theorem IsLimit.iSup_Iio {o : Ordinal} (h : IsLimit o) : ⨆ a : Iio o, a.1 = o := by rw [← sSup_eq_iSup', h.sSup_Iio] /-- Main induction principle of ordinals: if one can prove a property by induction at successor ordinals and at limit ordinals, then it holds for all ordinals. -/ @[elab_as_elim] def limitRecOn {motive : Ordinal → Sort} (o : Ordinal) (zero : motive 0) (succ : ∀ o, motive o → motive (succ o)) (isLimit : ∀ o, IsLimit o → (∀ o' < o, motive o') → motive o) : motive o := by refine SuccOrder.limitRecOn o (fun a ha ↦ ?_) (fun a _ ↦ succ a) isLimit convert zero simpa using ha @[simp] theorem limitRecOn_zero {motive} (H₁ H₂ H₃) : @limitRecOn motive 0 H₁ H₂ H₃ = H₁ := SuccOrder.limitRecOn_isMin _ _ _ isMin_bot @[simp] theorem limitRecOn_succ {motive} (o H₁ H₂ H₃) : @limitRecOn motive (succ o) H₁ H₂ H₃ = H₂ o (@limitRecOn motive o H₁ H₂ H₃) := SuccOrder.limitRecOn_succ .. @[simp] theorem limitRecOn_limit {motive} (o H₁ H₂ H₃ h) : @limitRecOn motive o H₁ H₂ H₃ = H₃ o h fun x _h => @limitRecOn motive x H₁ H₂ H₃ := SuccOrder.limitRecOn_of_isSuccLimit .. /-- Bounded recursion on ordinals. Similar to `limitRecOn`, with the assumption `o < l` added to all cases. The final term's domain is the ordinals below `l`. -/ @[elab_as_elim] def boundedLimitRecOn {l : Ordinal} (lLim : l.IsLimit) {motive : Iio l → Sort*} (o : Iio l) (zero : motive ⟨0, lLim.pos⟩) (succ : (o : Iio l) → motive o → motive ⟨succ o, lLim.succ_lt o.2⟩) (isLimit : (o : Iio l) → IsLimit o → (Π o' < o, motive o') → motive o) : motive o := limitRecOn (motive := fun p ↦ (h : p < l) → motive ⟨p, h⟩) o.1 (fun _ ↦ zero) (fun o ih h ↦ succ ⟨o, _⟩ <\| ih <\| (lt_succ o).trans h) (fun _o ho ih _ ↦ isLimit _ ho fun _o' h ↦ ih _ h _) o.2 @[simp] theorem boundedLimitRec_zero {l} (lLim : l.IsLimit) {motive} (H₁ H₂ H₃) : @boundedLimitRecOn l lLim motive ⟨0, lLim.pos⟩ H₁ H₂ H₃ = H₁ := by rw [boundedLimitRecOn, limitRecOn_zero] @[simp] theorem boundedLimitRec_succ {l} (lLim : l.IsLimit) {motive} (o H₁ H₂ H₃) : @boundedLimitRecOn l lLim motive ⟨succ o.1, lLim.succ_lt o.2⟩ H₁ H₂ H₃ = H₂ o (@boundedLimitRecOn l lLim motive o H₁ H₂ H₃) := by rw [boundedLimitRecOn, limitRecOn_succ] rfl theorem boundedLimitRec_limit {l} (lLim : l.IsLimit) {motive} (o H₁ H₂ H₃ oLim) : @boundedLimitRecOn l lLim motive o H₁ H₂ H₃ = H₃ o oLim (fun x _ ↦ @boundedLimitRecOn l lLim motive x H₁ H₂ H₃) := by rw [boundedLimitRecOn, limitRecOn_limit] rfl instance orderTopToTypeSucc (o : Ordinal) : OrderTop (succ o).toType := @OrderTop.mk _ _ (Top.mk _) le_enum_succ theorem enum_succ_eq_top {o : Ordinal} : enum (α := (succ o).toType) (· < ·) ⟨o, type_toType _ ▸ lt_succ o⟩ = ⊤ := rfl theorem has_succ_of_type_succ_lt {α} {r : α → α → Prop} [wo : IsWellOrder α r] (h : ∀ a < type r, succ a < type r) (x : α) : ∃ y, r x y := by use enum r ⟨succ (typein r x), h _ (typein_lt_type r x)⟩ convert enum_lt_enum.mpr _ · rw [enum_typein] · rw [Subtype.mk_lt_mk, lt_succ_iff] theorem toType_noMax_of_succ_lt {o : Ordinal} (ho : ∀ a < o, succ a < o) : NoMaxOrder o.toType := ⟨has_succ_of_type_succ_lt (type_toType _ ▸ ho)⟩ theorem bounded_singleton {r : α → α → Prop} [IsWellOrder α r] (hr : (type r).IsLimit) (x) : Bounded r {x} := by refine ⟨enum r ⟨succ (typein r x), hr.succ_lt (typein_lt_type r x)⟩, ?_⟩ intro b hb rw [mem_singleton_iff.1 hb] nth_rw 1 [← enum_typein r x] rw [@enum_lt_enum _ r, Subtype.mk_lt_mk] apply lt_succ @[simp] theorem typein_ordinal (o : Ordinal.{u}) : @typein Ordinal (· < ·) _ o = Ordinal.lift.{u + 1} o := by refine Quotient.inductionOn o ?_ rintro ⟨α, r, wo⟩; apply Quotient.sound	constructor; refine ((RelIso.preimage Equiv.ulift r).trans (enum r).symm).symm theorem mk_Iio_ordinal (o : Ordinal.{u}) : #(Iio o) = Cardinal.lift.{u + 1} o.card := by rw [lift_card, ← typein_ordinal]	Mathlib/SetTheory/Ordinal/Arithmetic.lean	352	356
/- Copyright (c) 2022 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison -/ import Mathlib.CategoryTheory.Limits.Shapes.ZeroMorphisms import Mathlib.CategoryTheory.Limits.Constructions.BinaryProducts /-! # Limits involving zero objects Binary products and coproducts with a zero object always exist, and pullbacks/pushouts over a zero object are products/coproducts. -/ noncomputable section open CategoryTheory variable {C : Type*} [Category C] namespace CategoryTheory.Limits variable [HasZeroObject C] [HasZeroMorphisms C] open ZeroObject /-- The limit cone for the product with a zero object. -/ def binaryFanZeroLeft (X : C) : BinaryFan (0 : C) X := BinaryFan.mk 0 (𝟙 X) /-- The limit cone for the product with a zero object is limiting. -/ def binaryFanZeroLeftIsLimit (X : C) : IsLimit (binaryFanZeroLeft X) := BinaryFan.isLimitMk (fun s => BinaryFan.snd s) (by aesop_cat) (by simp) (fun s m _ h₂ => by simpa using h₂) instance hasBinaryProduct_zero_left (X : C) : HasBinaryProduct (0 : C) X := HasLimit.mk ⟨_, binaryFanZeroLeftIsLimit X⟩ /-- A zero object is a left unit for categorical product. -/ def zeroProdIso (X : C) : (0 : C) ⨯ X ≅ X := limit.isoLimitCone ⟨_, binaryFanZeroLeftIsLimit X⟩ @[simp] theorem zeroProdIso_hom (X : C) : (zeroProdIso X).hom = prod.snd := rfl @[simp] theorem zeroProdIso_inv_snd (X : C) : (zeroProdIso X).inv ≫ prod.snd = 𝟙 X := by dsimp [zeroProdIso, binaryFanZeroLeft] simp /-- The limit cone for the product with a zero object. -/ def binaryFanZeroRight (X : C) : BinaryFan X (0 : C) := BinaryFan.mk (𝟙 X) 0 /-- The limit cone for the product with a zero object is limiting. -/ def binaryFanZeroRightIsLimit (X : C) : IsLimit (binaryFanZeroRight X) := BinaryFan.isLimitMk (fun s => BinaryFan.fst s) (by simp) (by aesop_cat) (fun s m h₁ _ => by simpa using h₁) instance hasBinaryProduct_zero_right (X : C) : HasBinaryProduct X (0 : C) := HasLimit.mk ⟨_, binaryFanZeroRightIsLimit X⟩ /-- A zero object is a right unit for categorical product. -/ def prodZeroIso (X : C) : X ⨯ (0 : C) ≅ X := limit.isoLimitCone ⟨_, binaryFanZeroRightIsLimit X⟩ @[simp] theorem prodZeroIso_hom (X : C) : (prodZeroIso X).hom = prod.fst := rfl @[simp] theorem prodZeroIso_iso_inv_snd (X : C) : (prodZeroIso X).inv ≫ prod.fst = 𝟙 X := by dsimp [prodZeroIso, binaryFanZeroRight] simp /-- The colimit cocone for the coproduct with a zero object. -/ def binaryCofanZeroLeft (X : C) : BinaryCofan (0 : C) X := BinaryCofan.mk 0 (𝟙 X) /-- The colimit cocone for the coproduct with a zero object is colimiting. -/ def binaryCofanZeroLeftIsColimit (X : C) : IsColimit (binaryCofanZeroLeft X) := BinaryCofan.isColimitMk (fun s => BinaryCofan.inr s) (by aesop_cat) (by simp) (fun s m _ h₂ => by simpa using h₂) instance hasBinaryCoproduct_zero_left (X : C) : HasBinaryCoproduct (0 : C) X := HasColimit.mk ⟨_, binaryCofanZeroLeftIsColimit X⟩ /-- A zero object is a left unit for categorical coproduct. -/ def zeroCoprodIso (X : C) : (0 : C) ⨿ X ≅ X := colimit.isoColimitCocone ⟨_, binaryCofanZeroLeftIsColimit X⟩ @[simp] theorem inr_zeroCoprodIso_hom (X : C) : coprod.inr ≫ (zeroCoprodIso X).hom = 𝟙 X := by dsimp [zeroCoprodIso, binaryCofanZeroLeft] simp @[simp] theorem zeroCoprodIso_inv (X : C) : (zeroCoprodIso X).inv = coprod.inr := rfl /-- The colimit cocone for the coproduct with a zero object. -/ def binaryCofanZeroRight (X : C) : BinaryCofan X (0 : C) := BinaryCofan.mk (𝟙 X) 0 /-- The colimit cocone for the coproduct with a zero object is colimiting. -/ def binaryCofanZeroRightIsColimit (X : C) : IsColimit (binaryCofanZeroRight X) := BinaryCofan.isColimitMk (fun s => BinaryCofan.inl s) (by simp) (by aesop_cat) (fun s m h₁ _ => by simpa using h₁) instance hasBinaryCoproduct_zero_right (X : C) : HasBinaryCoproduct X (0 : C) := HasColimit.mk ⟨_, binaryCofanZeroRightIsColimit X⟩ /-- A zero object is a right unit for categorical coproduct. -/ def coprodZeroIso (X : C) : X ⨿ (0 : C) ≅ X := colimit.isoColimitCocone ⟨_, binaryCofanZeroRightIsColimit X⟩ @[simp] theorem inr_coprodZeroIso_hom (X : C) : coprod.inl ≫ (coprodZeroIso X).hom = 𝟙 X := by dsimp [coprodZeroIso, binaryCofanZeroRight] simp @[simp] theorem coprodZeroIso_inv (X : C) : (coprodZeroIso X).inv = coprod.inl := rfl instance hasPullback_over_zero (X Y : C) [HasBinaryProduct X Y] : HasPullback (0 : X ⟶ 0) (0 : Y ⟶ 0) := HasLimit.mk ⟨_, isPullbackOfIsTerminalIsProduct _ _ _ _ HasZeroObject.zeroIsTerminal (prodIsProd X Y)⟩ /-- The pullback over the zero object is the product. -/ def pullbackZeroZeroIso (X Y : C) [HasBinaryProduct X Y] : pullback (0 : X ⟶ 0) (0 : Y ⟶ 0) ≅ X ⨯ Y := limit.isoLimitCone ⟨_, isPullbackOfIsTerminalIsProduct _ _ _ _ HasZeroObject.zeroIsTerminal (prodIsProd X Y)⟩ @[simp] theorem pullbackZeroZeroIso_inv_fst (X Y : C) [HasBinaryProduct X Y] : (pullbackZeroZeroIso X Y).inv ≫ pullback.fst 0 0 = prod.fst := by dsimp [pullbackZeroZeroIso] simp	@[simp] theorem pullbackZeroZeroIso_inv_snd (X Y : C) [HasBinaryProduct X Y] : (pullbackZeroZeroIso X Y).inv ≫ pullback.snd 0 0 = prod.snd := by	Mathlib/CategoryTheory/Limits/Constructions/ZeroObjects.lean	146	148
/- Copyright (c) 2024 Christian Merten. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Christian Merten -/ import Mathlib.CategoryTheory.Limits.Opposites import Mathlib.CategoryTheory.Limits.Preserves.Limits import Mathlib.CategoryTheory.Limits.Yoneda /-! # Ind- and pro- (co)yoneda lemmas We define limit versions of the yoneda and coyoneda lemmas. ## Main results Notation: categories `C`, `I` and functors `D : Iᵒᵖ ⥤ C`, `F : C ⥤ Type`. - `colimitCoyonedaHomIsoLimit`: pro-coyoneda lemma: homorphisms from colimit of coyoneda of diagram `D` to `F` is limit of `F` evaluated at `D`. - `colimitCoyonedaHomIsoLimit'`: a variant of `colimitCoyonedaHomIsoLimit` for a covariant diagram. -/ universe u₁ u₂ v₁ v₂ namespace CategoryTheory namespace Limits open Opposite variable {C : Type u₁} [Category.{u₂} C] {I : Type v₁} [Category.{v₂} I] section HomCocontinuousCovariant variable (F : I ⥤ C) [HasColimit F] /-- Hom is functorially cocontinuous: coyoneda of a colimit is the limit over coyoneda of the diagram. -/ noncomputable def coyonedaOpColimitIsoLimitCoyoneda : coyoneda.obj (op <\| colimit F) ≅ limit (F.op ⋙ coyoneda) := coyoneda.mapIso (limitOpIsoOpColimit F).symm ≪≫ (preservesLimitIso coyoneda F.op) @[reassoc (attr := simp)] lemma coyonedaOpColimitIsoLimitCoyoneda_hom_comp_π (i : I) : (coyonedaOpColimitIsoLimitCoyoneda F).hom ≫ limit.π (F.op.comp coyoneda) ⟨i⟩	= coyoneda.map (colimit.ι F i).op := by simp only [coyonedaOpColimitIsoLimitCoyoneda, Functor.mapIso_symm, Iso.trans_hom, Iso.symm_hom, Functor.mapIso_inv, Category.assoc, preservesLimitIso_hom_π, ← Functor.map_comp, limitOpIsoOpColimit_inv_comp_π]	Mathlib/CategoryTheory/Limits/IndYoneda.lean	50	53
/- Copyright (c) 2024 Jeremy Tan. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Tan -/ import Mathlib.Analysis.Complex.Basic import Mathlib.Analysis.SpecificLimits.Normed import Mathlib.Tactic.Peel import Mathlib.Tactic.Positivity /-! # Abel's limit theorem If a real or complex power series for a function has radius of convergence 1 and the series is only known to converge conditionally at 1, Abel's limit theorem gives the value at 1 as the limit of the function at 1 from the left. "Left" for complex numbers means within a fixed cone opening to the left with angle less than `π`. ## Main theorems * `Complex.tendsto_tsum_powerSeries_nhdsWithin_stolzCone`: Abel's limit theorem for complex power series. * `Real.tendsto_tsum_powerSeries_nhdsWithin_lt`: Abel's limit theorem for real power series. ## References * https://planetmath.org/proofofabelslimittheorem * https://en.wikipedia.org/wiki/Abel%27s_theorem -/ open Filter Finset open scoped Topology namespace Complex section StolzSet open Real /-- The Stolz set for a given `M`, roughly teardrop-shaped with the tip at 1 but tending to the open unit disc as `M` tends to infinity. -/ def stolzSet (M : ℝ) : Set ℂ := {z \| ‖z‖ < 1 ∧ ‖1 - z‖ < M * (1 - ‖z‖)} /-- The cone to the left of `1` with angle `2θ` such that `tan θ = s`. -/ def stolzCone (s : ℝ) : Set ℂ := {z \| \|z.im\| < s * (1 - z.re)} theorem stolzSet_empty {M : ℝ} (hM : M ≤ 1) : stolzSet M = ∅ := by ext z rw [stolzSet, Set.mem_setOf, Set.mem_empty_iff_false, iff_false, not_and, not_lt, ← sub_pos] intro zn calc _ ≤ 1 * (1 - ‖z‖) := mul_le_mul_of_nonneg_right hM zn.le _ = ‖(1 : ℂ)‖ - ‖z‖ := by rw [one_mul, norm_one] _ ≤ _ := norm_sub_norm_le _ _ theorem nhdsWithin_lt_le_nhdsWithin_stolzSet {M : ℝ} (hM : 1 < M) : (𝓝[<] 1).map ofReal ≤ 𝓝[stolzSet M] 1 := by rw [← tendsto_id'] refine tendsto_map' <\| tendsto_nhdsWithin_of_tendsto_nhds_of_eventually_within ofReal (tendsto_nhdsWithin_of_tendsto_nhds <\| ofRealCLM.continuous.tendsto' 1 1 rfl) ?_ simp only [eventually_iff, mem_nhdsWithin] refine ⟨Set.Ioo 0 2, isOpen_Ioo, by norm_num, fun x hx ↦ ?_⟩ simp only [Set.mem_inter_iff, Set.mem_Ioo, Set.mem_Iio] at hx simp only [Set.mem_setOf_eq, stolzSet, ← ofReal_one, ← ofReal_sub, norm_real, norm_of_nonneg hx.1.1.le, norm_of_nonneg <\| (sub_pos.mpr hx.2).le] exact ⟨hx.2, lt_mul_left (sub_pos.mpr hx.2) hM⟩ -- An ugly technical lemma private lemma stolzCone_subset_stolzSet_aux' (s : ℝ) : ∃ M ε, 0 < M ∧ 0 < ε ∧ ∀ x y, 0 < x → x < ε → \|y\| < s * x → sqrt (x ^ 2 + y ^ 2) < M * (1 - sqrt ((1 - x) ^ 2 + y ^ 2)) := by refine ⟨2 * sqrt (1 + s ^ 2) + 1, 1 / (1 + s ^ 2), by positivity, by positivity, fun x y hx₀ hx₁ hy ↦ ?_⟩ have H : sqrt ((1 - x) ^ 2 + y ^ 2) ≤ 1 - x / 2 := by calc sqrt ((1 - x) ^ 2 + y ^ 2) _ ≤ sqrt ((1 - x) ^ 2 + (s * x) ^ 2) := sqrt_le_sqrt <\| by rw [← sq_abs y]; gcongr _ = sqrt (1 - 2 * x + (1 + s ^ 2) * x * x) := by congr 1; ring _ ≤ sqrt (1 - 2 * x + (1 + s ^ 2) * (1 / (1 + s ^ 2)) * x) := sqrt_le_sqrt <\| by gcongr _ = sqrt (1 - x) := by congr 1; field_simp; ring _ ≤ 1 - x / 2 := by simp_rw [sub_eq_add_neg, ← neg_div] refine sqrt_one_add_le <\| neg_le_neg_iff.mpr (hx₁.trans_le ?_).le rw [div_le_one (by positivity)] exact le_add_of_nonneg_right <\| sq_nonneg s calc sqrt (x ^ 2 + y ^ 2) _ ≤ sqrt (x ^ 2 + (s * x) ^ 2) := sqrt_le_sqrt <\| by rw [← sq_abs y]; gcongr _ = sqrt ((1 + s ^ 2) * x ^ 2) := by congr; ring _ = sqrt (1 + s ^ 2) * x := by rw [sqrt_mul' _ (sq_nonneg x), sqrt_sq hx₀.le] _ = 2 * sqrt (1 + s ^ 2) * (x / 2) := by ring _ < (2 * sqrt (1 + s ^ 2) + 1) * (x / 2) := by gcongr; exact lt_add_one _ _ ≤ _ := by gcongr; exact le_sub_comm.mpr H lemma stolzCone_subset_stolzSet_aux {s : ℝ} (hs : 0 < s) :	∃ M ε, 0 < M ∧ 0 < ε ∧ {z : ℂ \| 1 - ε < z.re} ∩ stolzCone s ⊆ stolzSet M := by peel stolzCone_subset_stolzSet_aux' s with M ε hM hε H rintro z ⟨hzl, hzr⟩ rw [Set.mem_setOf_eq, sub_lt_comm, ← one_re, ← sub_re] at hzl rw [stolzCone, Set.mem_setOf_eq, ← one_re, ← sub_re] at hzr replace H := H (1 - z).re z.im ((mul_pos_iff_of_pos_left hs).mp <\| (abs_nonneg z.im).trans_lt hzr) hzl hzr have h : z.im ^ 2 = (1 - z).im ^ 2 := by simp only [sub_im, one_im, zero_sub, even_two, neg_sq] rw [h, ← norm_eq_sqrt_sq_add_sq, ← h, sub_re, one_re, sub_sub_cancel, ← norm_eq_sqrt_sq_add_sq] at H exact ⟨sub_pos.mp <\| (mul_pos_iff_of_pos_left hM).mp <\| (norm_nonneg _).trans_lt H, H⟩	Mathlib/Analysis/Complex/AbelLimit.lean	96	108
/- Copyright (c) 2024 David Kurniadi Angdinata. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: David Kurniadi Angdinata -/ import Mathlib.Data.Nat.EvenOddRec import Mathlib.Tactic.Linarith import Mathlib.Tactic.LinearCombination /-! # Elliptic divisibility sequences This file defines the type of an elliptic divisibility sequence (EDS) and a few examples. ## Mathematical background Let `R` be a commutative ring. An elliptic sequence is a sequence `W : ℤ → R` satisfying `W(m + n)W(m - n)W(r)² = W(m + r)W(m - r)W(n)² - W(n + r)W(n - r)W(m)²` for any `m, n, r ∈ ℤ`. A divisibility sequence is a sequence `W : ℤ → R` satisfying `W(m) ∣ W(n)` for any `m, n ∈ ℤ` such that `m ∣ n`. An elliptic divisibility sequence is simply a divisibility sequence that is elliptic. Some examples of EDSs include * the identity sequence, * certain terms of Lucas sequences, and * division polynomials of elliptic curves. ## Main definitions * `IsEllSequence`: a sequence indexed by integers is an elliptic sequence. * `IsDivSequence`: a sequence indexed by integers is a divisibility sequence. * `IsEllDivSequence`: a sequence indexed by integers is an EDS. * `preNormEDS'`: the auxiliary sequence for a normalised EDS indexed by `ℕ`. * `preNormEDS`: the auxiliary sequence for a normalised EDS indexed by `ℤ`. * `normEDS`: the canonical example of a normalised EDS indexed by `ℤ`. ## Main statements * TODO: prove that `normEDS` satisfies `IsEllDivSequence`. * TODO: prove that a normalised sequence satisfying `IsEllDivSequence` can be given by `normEDS`. ## Implementation notes The normalised EDS `normEDS b c d n` is defined in terms of the auxiliary sequence `preNormEDS (b ^ 4) c d n`, which are equal when `n` is odd, and which differ by a factor of `b` when `n` is even. This coincides with the definition in the references since both agree for `normEDS b c d 2` and for `normEDS b c d 4`, and the correct factors of `b` are removed in `normEDS b c d (2 * (m + 2) + 1)` and in `normEDS b c d (2 * (m + 3))`. One reason is to avoid the necessity for ring division by `b` in the inductive definition of `normEDS b c d (2 * (m + 3))`. The idea is that, it can be shown that `normEDS b c d (2 * (m + 3))` always contains a factor of `b`, so it is possible to remove a factor of `b` a posteriori, but stating this lemma requires first defining `normEDS b c d (2 * (m + 3))`, which requires having this factor of `b` a priori. Another reason is to allow the definition of univariate `n`-division polynomials of elliptic curves, omitting a factor of the bivariate `2`-division polynomial. ## References M Ward, Memoir on Elliptic Divisibility Sequences ## Tags elliptic, divisibility, sequence -/ universe u v variable {R : Type u} [CommRing R] section IsEllDivSequence variable (W : ℤ → R) /-- The proposition that a sequence indexed by integers is an elliptic sequence. -/ def IsEllSequence : Prop := ∀ m n r : ℤ, W (m + n) * W (m - n) * W r ^ 2 = W (m + r) * W (m - r) * W n ^ 2 - W (n + r) * W (n - r) * W m ^ 2 /-- The proposition that a sequence indexed by integers is a divisibility sequence. -/ def IsDivSequence : Prop := ∀ m n : ℕ, m ∣ n → W m ∣ W n /-- The proposition that a sequence indexed by integers is an EDS. -/ def IsEllDivSequence : Prop := IsEllSequence W ∧ IsDivSequence W lemma isEllSequence_id : IsEllSequence id := fun _ _ _ => by simp only [id_eq]; ring1 lemma isDivSequence_id : IsDivSequence id := fun _ _ => Int.ofNat_dvd.mpr /-- The identity sequence is an EDS. -/ theorem isEllDivSequence_id : IsEllDivSequence id := ⟨isEllSequence_id, isDivSequence_id⟩ variable {W} lemma IsEllSequence.smul (h : IsEllSequence W) (x : R) : IsEllSequence (x • W) := fun m n r => by linear_combination (norm := (simp only [Pi.smul_apply, smul_eq_mul]; ring1)) x ^ 4 * h m n r lemma IsDivSequence.smul (h : IsDivSequence W) (x : R) : IsDivSequence (x • W) := fun m n r => mul_dvd_mul_left x <\| h m n r lemma IsEllDivSequence.smul (h : IsEllDivSequence W) (x : R) : IsEllDivSequence (x • W) := ⟨h.left.smul x, h.right.smul x⟩ end IsEllDivSequence /-- Strong recursion principle for a normalised EDS: if we have * `P 0`, `P 1`, `P 2`, `P 3`, and `P 4`, * for all `m : ℕ` we can prove `P (2 * (m + 3))` from `P k` for all `k < 2 * (m + 3)`, and * for all `m : ℕ` we can prove `P (2 * (m + 2) + 1)` from `P k` for all `k < 2 * (m + 2) + 1`, then we have `P n` for all `n : ℕ`. -/ @[elab_as_elim] noncomputable def normEDSRec' {P : ℕ → Sort u} (zero : P 0) (one : P 1) (two : P 2) (three : P 3) (four : P 4) (even : ∀ m : ℕ, (∀ k < 2 * (m + 3), P k) → P (2 * (m + 3))) (odd : ∀ m : ℕ, (∀ k < 2 * (m + 2) + 1, P k) → P (2 * (m + 2) + 1)) (n : ℕ) : P n := n.evenOddStrongRec (by rintro (_ \| _ \| _ \| _) h; exacts [zero, two, four, even _ h]) (by rintro (_ \| _ \| _) h; exacts [one, three, odd _ h]) /-- Recursion principle for a normalised EDS: if we have * `P 0`, `P 1`, `P 2`, `P 3`, and `P 4`, * for all `m : ℕ` we can prove `P (2 * (m + 3))` from `P (m + 1)`, `P (m + 2)`, `P (m + 3)`, `P (m + 4)`, and `P (m + 5)`, and * for all `m : ℕ` we can prove `P (2 * (m + 2) + 1)` from `P (m + 1)`, `P (m + 2)`, `P (m + 3)`, and `P (m + 4)`,	then we have `P n` for all `n : ℕ`. -/ @[elab_as_elim] noncomputable def normEDSRec {P : ℕ → Sort u}	Mathlib/NumberTheory/EllipticDivisibilitySequence.lean	129	131
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.Polynomial.Reverse import Mathlib.Algebra.Regular.SMul /-! # Theory of monic polynomials We give several tools for proving that polynomials are monic, e.g. `Monic.mul`, `Monic.map`, `Monic.pow`. -/ noncomputable section open Finset open Polynomial namespace Polynomial universe u v y variable {R : Type u} {S : Type v} {a b : R} {m n : ℕ} {ι : Type y} section Semiring variable [Semiring R] {p q r : R[X]} theorem monic_zero_iff_subsingleton : Monic (0 : R[X]) ↔ Subsingleton R := subsingleton_iff_zero_eq_one theorem not_monic_zero_iff : ¬Monic (0 : R[X]) ↔ (0 : R) ≠ 1 := (monic_zero_iff_subsingleton.trans subsingleton_iff_zero_eq_one.symm).not theorem monic_zero_iff_subsingleton' : Monic (0 : R[X]) ↔ (∀ f g : R[X], f = g) ∧ ∀ a b : R, a = b := Polynomial.monic_zero_iff_subsingleton.trans ⟨by intro simp [eq_iff_true_of_subsingleton], fun h => subsingleton_iff.mpr h.2⟩ theorem Monic.as_sum (hp : p.Monic) : p = X ^ p.natDegree + ∑ i ∈ range p.natDegree, C (p.coeff i) * X ^ i := by conv_lhs => rw [p.as_sum_range_C_mul_X_pow, sum_range_succ_comm] suffices C (p.coeff p.natDegree) = 1 by rw [this, one_mul] exact congr_arg C hp theorem ne_zero_of_ne_zero_of_monic (hp : p ≠ 0) (hq : Monic q) : q ≠ 0 := by rintro rfl rw [Monic.def, leadingCoeff_zero] at hq rw [← mul_one p, ← C_1, ← hq, C_0, mul_zero] at hp exact hp rfl theorem Monic.map [Semiring S] (f : R →+* S) (hp : Monic p) : Monic (p.map f) := by unfold Monic nontriviality have : f p.leadingCoeff ≠ 0 := by rw [show _ = _ from hp, f.map_one] exact one_ne_zero rw [Polynomial.leadingCoeff, coeff_map] suffices p.coeff (p.map f).natDegree = 1 by simp [this] rwa [natDegree_eq_of_degree_eq (degree_map_eq_of_leadingCoeff_ne_zero f this)] theorem monic_C_mul_of_mul_leadingCoeff_eq_one {b : R} (hp : b * p.leadingCoeff = 1) : Monic (C b * p) := by unfold Monic nontriviality rw [leadingCoeff_mul' _] <;> simp [leadingCoeff_C b, hp] theorem monic_mul_C_of_leadingCoeff_mul_eq_one {b : R} (hp : p.leadingCoeff * b = 1) : Monic (p * C b) := by unfold Monic nontriviality rw [leadingCoeff_mul' _] <;> simp [leadingCoeff_C b, hp] theorem monic_of_degree_le (n : ℕ) (H1 : degree p ≤ n) (H2 : coeff p n = 1) : Monic p := Decidable.byCases (fun H : degree p < n => eq_of_zero_eq_one (H2 ▸ (coeff_eq_zero_of_degree_lt H).symm) _ _) fun H : ¬degree p < n => by rwa [Monic, Polynomial.leadingCoeff, natDegree, (lt_or_eq_of_le H1).resolve_left H] theorem monic_X_pow_add {n : ℕ} (H : degree p < n) : Monic (X ^ n + p) := monic_of_degree_le n (le_trans (degree_add_le _ _) (max_le (degree_X_pow_le _) (le_of_lt H))) (by rw [coeff_add, coeff_X_pow, if_pos rfl, coeff_eq_zero_of_degree_lt H, add_zero]) variable (a) in theorem monic_X_pow_add_C {n : ℕ} (h : n ≠ 0) : (X ^ n + C a).Monic := monic_X_pow_add <\| (lt_of_le_of_lt degree_C_le (by simp only [Nat.cast_pos, Nat.pos_iff_ne_zero, ne_eq, h, not_false_eq_true])) theorem monic_X_add_C (x : R) : Monic (X + C x) := pow_one (X : R[X]) ▸ monic_X_pow_add_C x one_ne_zero theorem Monic.mul (hp : Monic p) (hq : Monic q) : Monic (p * q) := letI := Classical.decEq R if h0 : (0 : R) = 1 then haveI := subsingleton_of_zero_eq_one h0 Subsingleton.elim _ _ else by have : p.leadingCoeff * q.leadingCoeff ≠ 0 := by simp [Monic.def.1 hp, Monic.def.1 hq, Ne.symm h0] rw [Monic.def, leadingCoeff_mul' this, Monic.def.1 hp, Monic.def.1 hq, one_mul] theorem Monic.pow (hp : Monic p) : ∀ n : ℕ, Monic (p ^ n) \| 0 => monic_one \| n + 1 => by rw [pow_succ] exact (Monic.pow hp n).mul hp theorem Monic.add_of_left (hp : Monic p) (hpq : degree q < degree p) : Monic (p + q) := by rwa [Monic, add_comm, leadingCoeff_add_of_degree_lt hpq] theorem Monic.add_of_right (hq : Monic q) (hpq : degree p < degree q) : Monic (p + q) := by rwa [Monic, leadingCoeff_add_of_degree_lt hpq] theorem Monic.of_mul_monic_left (hp : p.Monic) (hpq : (p * q).Monic) : q.Monic := by contrapose! hpq rw [Monic.def] at hpq ⊢ rwa [leadingCoeff_monic_mul hp] theorem Monic.of_mul_monic_right (hq : q.Monic) (hpq : (p * q).Monic) : p.Monic := by contrapose! hpq rw [Monic.def] at hpq ⊢ rwa [leadingCoeff_mul_monic hq] namespace Monic lemma comp (hp : p.Monic) (hq : q.Monic) (h : q.natDegree ≠ 0) : (p.comp q).Monic := by nontriviality R have : (p.comp q).natDegree = p.natDegree * q.natDegree := natDegree_comp_eq_of_mul_ne_zero <\| by simp [hp.leadingCoeff, hq.leadingCoeff] rw [Monic.def, Polynomial.leadingCoeff, this, coeff_comp_degree_mul_degree h, hp.leadingCoeff, hq.leadingCoeff, one_pow, mul_one] lemma comp_X_add_C (hp : p.Monic) (r : R) : (p.comp (X + C r)).Monic := by nontriviality R refine hp.comp (monic_X_add_C _) fun ha ↦ ?_ rw [natDegree_X_add_C] at ha exact one_ne_zero ha @[simp] theorem natDegree_eq_zero_iff_eq_one (hp : p.Monic) : p.natDegree = 0 ↔ p = 1 := by constructor <;> intro h swap · rw [h] exact natDegree_one have : p = C (p.coeff 0) := by rw [← Polynomial.degree_le_zero_iff] rwa [Polynomial.natDegree_eq_zero_iff_degree_le_zero] at h rw [this] rw [← h, ← Polynomial.leadingCoeff, Monic.def.1 hp, C_1] @[simp] theorem degree_le_zero_iff_eq_one (hp : p.Monic) : p.degree ≤ 0 ↔ p = 1 := by rw [← hp.natDegree_eq_zero_iff_eq_one, natDegree_eq_zero_iff_degree_le_zero] theorem natDegree_mul (hp : p.Monic) (hq : q.Monic) : (p * q).natDegree = p.natDegree + q.natDegree := by nontriviality R apply natDegree_mul' simp [hp.leadingCoeff, hq.leadingCoeff] theorem degree_mul_comm (hp : p.Monic) (q : R[X]) : (p * q).degree = (q * p).degree := by by_cases h : q = 0 · simp [h] rw [degree_mul', hp.degree_mul] · exact add_comm _ _ · rwa [hp.leadingCoeff, one_mul, leadingCoeff_ne_zero] nonrec theorem natDegree_mul' (hp : p.Monic) (hq : q ≠ 0) : (p * q).natDegree = p.natDegree + q.natDegree := by rw [natDegree_mul'] simpa [hp.leadingCoeff, leadingCoeff_ne_zero] theorem natDegree_mul_comm (hp : p.Monic) (q : R[X]) : (p * q).natDegree = (q * p).natDegree := by by_cases h : q = 0 · simp [h] rw [hp.natDegree_mul' h, Polynomial.natDegree_mul', add_comm] simpa [hp.leadingCoeff, leadingCoeff_ne_zero] theorem not_dvd_of_natDegree_lt (hp : Monic p) (h0 : q ≠ 0) (hl : natDegree q < natDegree p) : ¬p ∣ q := by rintro ⟨r, rfl⟩ rw [hp.natDegree_mul' <\| right_ne_zero_of_mul h0] at hl exact hl.not_le (Nat.le_add_right _ _) theorem not_dvd_of_degree_lt (hp : Monic p) (h0 : q ≠ 0) (hl : degree q < degree p) : ¬p ∣ q := Monic.not_dvd_of_natDegree_lt hp h0 <\| natDegree_lt_natDegree h0 hl theorem nextCoeff_mul (hp : Monic p) (hq : Monic q) : nextCoeff (p * q) = nextCoeff p + nextCoeff q := by nontriviality simp only [← coeff_one_reverse] rw [reverse_mul] <;> simp [hp.leadingCoeff, hq.leadingCoeff, mul_coeff_one, add_comm] theorem nextCoeff_pow (hp : p.Monic) (n : ℕ) : (p ^ n).nextCoeff = n • p.nextCoeff := by induction n with \| zero => rw [pow_zero, zero_smul, ← map_one (f := C), nextCoeff_C_eq_zero] \| succ n ih => rw [pow_succ, (hp.pow n).nextCoeff_mul hp, ih, succ_nsmul] theorem eq_one_of_map_eq_one {S : Type} [Semiring S] [Nontrivial S] (f : R →+ S) (hp : p.Monic) (map_eq : p.map f = 1) : p = 1 := by nontriviality R have hdeg : p.degree = 0 := by rw [← degree_map_eq_of_leadingCoeff_ne_zero f _, map_eq, degree_one] · rw [hp.leadingCoeff, f.map_one] exact one_ne_zero have hndeg : p.natDegree = 0 := WithBot.coe_eq_coe.mp ((degree_eq_natDegree hp.ne_zero).symm.trans hdeg) convert eq_C_of_degree_eq_zero hdeg rw [← hndeg, ← Polynomial.leadingCoeff, hp.leadingCoeff, C.map_one] theorem natDegree_pow (hp : p.Monic) (n : ℕ) : (p ^ n).natDegree = n * p.natDegree := by induction n with \| zero => simp \| succ n hn => rw [pow_succ, (hp.pow n).natDegree_mul hp, hn, Nat.succ_mul, add_comm] end Monic @[simp] theorem natDegree_pow_X_add_C [Nontrivial R] (n : ℕ) (r : R) : ((X + C r) ^ n).natDegree = n := by rw [(monic_X_add_C r).natDegree_pow, natDegree_X_add_C, mul_one] theorem Monic.eq_one_of_isUnit (hm : Monic p) (hpu : IsUnit p) : p = 1 := by nontriviality R obtain ⟨q, h⟩ := hpu.exists_right_inv have := hm.natDegree_mul' (right_ne_zero_of_mul_eq_one h) rw [h, natDegree_one, eq_comm, add_eq_zero] at this exact hm.natDegree_eq_zero_iff_eq_one.mp this.1 theorem Monic.isUnit_iff (hm : p.Monic) : IsUnit p ↔ p = 1 := ⟨hm.eq_one_of_isUnit, fun h => h.symm ▸ isUnit_one⟩ theorem eq_of_monic_of_associated (hp : p.Monic) (hq : q.Monic) (hpq : Associated p q) : p = q := by obtain ⟨u, rfl⟩ := hpq rw [(hp.of_mul_monic_left hq).eq_one_of_isUnit u.isUnit, mul_one] end Semiring section CommSemiring variable [CommSemiring R] {p : R[X]} theorem monic_multiset_prod_of_monic (t : Multiset ι) (f : ι → R[X]) (ht : ∀ i ∈ t, Monic (f i)) : Monic (t.map f).prod := by revert ht refine t.induction_on ?_ ?_; · simp intro a t ih ht rw [Multiset.map_cons, Multiset.prod_cons] exact (ht _ (Multiset.mem_cons_self _ _)).mul (ih fun _ hi => ht _ (Multiset.mem_cons_of_mem hi)) theorem monic_prod_of_monic (s : Finset ι) (f : ι → R[X]) (hs : ∀ i ∈ s, Monic (f i)) : Monic (∏ i ∈ s, f i) := monic_multiset_prod_of_monic s.1 f hs theorem monic_finprod_of_monic (α : Type) (f : α → R[X]) (hf : ∀ i ∈ Function.mulSupport f, Monic (f i)) : Monic (finprod f) := by classical rw [finprod_def] split_ifs · exact monic_prod_of_monic _ _ fun a ha => hf a ((Set.Finite.mem_toFinset _).mp ha) · exact monic_one theorem Monic.nextCoeff_multiset_prod (t : Multiset ι) (f : ι → R[X]) (h : ∀ i ∈ t, Monic (f i)) : nextCoeff (t.map f).prod = (t.map fun i => nextCoeff (f i)).sum := by revert h refine Multiset.induction_on t ?_ fun a t ih ht => ?_ · simp only [Multiset.not_mem_zero, forall_prop_of_true, forall_prop_of_false, Multiset.map_zero, Multiset.prod_zero, Multiset.sum_zero, not_false_iff, forall_true_iff] rw [← C_1] rw [nextCoeff_C_eq_zero] · rw [Multiset.map_cons, Multiset.prod_cons, Multiset.map_cons, Multiset.sum_cons, Monic.nextCoeff_mul, ih] exacts [fun i hi => ht i (Multiset.mem_cons_of_mem hi), ht a (Multiset.mem_cons_self _ _), monic_multiset_prod_of_monic _ _ fun b bs => ht _ (Multiset.mem_cons_of_mem bs)] theorem Monic.nextCoeff_prod (s : Finset ι) (f : ι → R[X]) (h : ∀ i ∈ s, Monic (f i)) : nextCoeff (∏ i ∈ s, f i) = ∑ i ∈ s, nextCoeff (f i) := Monic.nextCoeff_multiset_prod s.1 f h variable [NoZeroDivisors R] {p q : R[X]} lemma irreducible_of_monic (hp : p.Monic) (hp1 : p ≠ 1) : Irreducible p ↔ ∀ f g : R[X], f.Monic → g.Monic → f g = p → f = 1 ∨ g = 1 := by refine ⟨fun h f g hf hg hp => (h.2 hp.symm).imp hf.eq_one_of_isUnit hg.eq_one_of_isUnit, fun h => ⟨hp1 ∘ hp.eq_one_of_isUnit, fun f g hfg => (h (g * C f.leadingCoeff) (f * C g.leadingCoeff) ?_ ?_ ?_).symm.imp (isUnit_of_mul_eq_one f _) (isUnit_of_mul_eq_one g _)⟩⟩ · rwa [Monic, leadingCoeff_mul, leadingCoeff_C, ← leadingCoeff_mul, mul_comm, ← hfg, ← Monic] · rwa [Monic, leadingCoeff_mul, leadingCoeff_C, ← leadingCoeff_mul, ← hfg, ← Monic] · rw [mul_mul_mul_comm, ← C_mul, ← leadingCoeff_mul, ← hfg, hp.leadingCoeff, C_1, mul_one, mul_comm, ← hfg] lemma Monic.irreducible_iff_natDegree (hp : p.Monic) : Irreducible p ↔ p ≠ 1 ∧ ∀ f g : R[X], f.Monic → g.Monic → f * g = p → f.natDegree = 0 ∨ g.natDegree = 0 := by by_cases hp1 : p = 1; · simp [hp1] rw [irreducible_of_monic hp hp1, and_iff_right hp1] refine forall₄_congr fun a b ha hb => ?_ rw [ha.natDegree_eq_zero_iff_eq_one, hb.natDegree_eq_zero_iff_eq_one] lemma Monic.irreducible_iff_natDegree' (hp : p.Monic) : Irreducible p ↔ p ≠ 1 ∧ ∀ f g : R[X], f.Monic → g.Monic → f * g = p → g.natDegree ∉ Ioc 0 (p.natDegree / 2) := by simp_rw [hp.irreducible_iff_natDegree, mem_Ioc, Nat.le_div_iff_mul_le zero_lt_two, mul_two] apply and_congr_right' constructor <;> intro h f g hf hg he <;> subst he · rw [hf.natDegree_mul hg, add_le_add_iff_right] exact fun ha => (h f g hf hg rfl).elim (ha.1.trans_le ha.2).ne' ha.1.ne'	· simp_rw [hf.natDegree_mul hg, pos_iff_ne_zero] at h contrapose! h obtain hl \| hl := le_total f.natDegree g.natDegree · exact ⟨g, f, hg, hf, mul_comm g f, h.1, add_le_add_left hl _⟩ · exact ⟨f, g, hf, hg, rfl, h.2, add_le_add_right hl _⟩	Mathlib/Algebra/Polynomial/Monic.lean	318	322
/- Copyright (c) 2024 Jeremy Tan. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Tan -/ import Mathlib.Combinatorics.SimpleGraph.Clique import Mathlib.Order.Partition.Equipartition /-! # Turán's theorem In this file we prove Turán's theorem, the first important result of extremal graph theory, which states that the `r + 1`-cliquefree graph on `n` vertices with the most edges is the complete `r`-partite graph with part sizes as equal as possible (`turanGraph n r`). The forward direction of the proof performs "Zykov symmetrisation", which first shows constructively that non-adjacency is an equivalence relation in a maximal graph, so it must be complete multipartite with the parts being the equivalence classes. Then basic manipulations show that the graph is isomorphic to the Turán graph for the given parameters. For the reverse direction we first show that a Turán-maximal graph exists, then transfer the property through `turanGraph n r` using the isomorphism provided by the forward direction. ## Main declarations * `SimpleGraph.IsTuranMaximal`: `G.IsTuranMaximal r` means that `G` has the most number of edges for its number of vertices while still being `r + 1`-cliquefree. * `SimpleGraph.turanGraph n r`: The canonical `r + 1`-cliquefree Turán graph on `n` vertices. * `SimpleGraph.IsTuranMaximal.finpartition`: The result of Zykov symmetrisation, a finpartition of the vertices such that two vertices are in the same part iff they are non-adjacent. * `SimpleGraph.IsTuranMaximal.nonempty_iso_turanGraph`: The forward direction, an isomorphism between `G` satisfying `G.IsTuranMaximal r` and `turanGraph n r`. * `isTuranMaximal_of_iso`: the reverse direction, `G.IsTuranMaximal r` given the isomorphism. * `isTuranMaximal_iff_nonempty_iso_turanGraph`: Turán's theorem in full. ## References * https://en.wikipedia.org/wiki/Turán%27s_theorem -/ open Finset namespace SimpleGraph variable {V : Type*} [Fintype V] {G : SimpleGraph V} [DecidableRel G.Adj] {n r : ℕ} variable (G) in /-- An `r + 1`-cliquefree graph is `r`-Turán-maximal if any other `r + 1`-cliquefree graph on the same vertex set has the same or fewer number of edges. -/ def IsTuranMaximal (r : ℕ) : Prop := G.CliqueFree (r + 1) ∧ ∀ (H : SimpleGraph V) [DecidableRel H.Adj], H.CliqueFree (r + 1) → #H.edgeFinset ≤ #G.edgeFinset section Defs variable {H : SimpleGraph V} lemma IsTuranMaximal.le_iff_eq (hG : G.IsTuranMaximal r) (hH : H.CliqueFree (r + 1)) : G ≤ H ↔ G = H := by classical exact ⟨fun hGH ↦ edgeFinset_inj.1 <\| eq_of_subset_of_card_le (edgeFinset_subset_edgeFinset.2 hGH) (hG.2 _ hH), le_of_eq⟩ /-- The canonical `r + 1`-cliquefree Turán graph on `n` vertices. -/ def turanGraph (n r : ℕ) : SimpleGraph (Fin n) where Adj v w := v % r ≠ w % r instance turanGraph.instDecidableRelAdj : DecidableRel (turanGraph n r).Adj := by dsimp only [turanGraph]; infer_instance @[simp] lemma turanGraph_zero : turanGraph n 0 = ⊤ := by ext a b; simp_rw [turanGraph, top_adj, Nat.mod_zero, not_iff_not, Fin.val_inj] @[simp]	theorem turanGraph_eq_top : turanGraph n r = ⊤ ↔ r = 0 ∨ n ≤ r := by simp_rw [SimpleGraph.ext_iff, funext_iff, turanGraph, top_adj, eq_iff_iff, not_iff_not] refine ⟨fun h ↦ ?_, ?_⟩ · contrapose! h use ⟨0, (Nat.pos_of_ne_zero h.1).trans h.2⟩, ⟨r, h.2⟩ simp [h.1.symm] · rintro (rfl \| h) a b · simp [Fin.val_inj] · rw [Nat.mod_eq_of_lt (a.2.trans_le h), Nat.mod_eq_of_lt (b.2.trans_le h), Fin.val_inj]	Mathlib/Combinatorics/SimpleGraph/Turan.lean	74	82
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Aaron Anderson, Yakov Pechersky -/ import Mathlib.Data.Fintype.Card import Mathlib.Algebra.Group.Commute.Basic import Mathlib.Algebra.Group.End import Mathlib.Data.Finset.NoncommProd /-! # support of a permutation ## Main definitions In the following, `f g : Equiv.Perm α`. * `Equiv.Perm.Disjoint`: two permutations `f` and `g` are `Disjoint` if every element is fixed either by `f`, or by `g`. Equivalently, `f` and `g` are `Disjoint` iff their `support` are disjoint. * `Equiv.Perm.IsSwap`: `f = swap x y` for `x ≠ y`. * `Equiv.Perm.support`: the elements `x : α` that are not fixed by `f`. Assume `α` is a Fintype: * `Equiv.Perm.fixed_point_card_lt_of_ne_one f` says that `f` has strictly less than `Fintype.card α - 1` fixed points, unless `f = 1`. (Equivalently, `f.support` has at least 2 elements.) -/ open Equiv Finset Function namespace Equiv.Perm variable {α : Type} section Disjoint /-- Two permutations `f` and `g` are `Disjoint` if their supports are disjoint, i.e., every element is fixed either by `f`, or by `g`. -/ def Disjoint (f g : Perm α) := ∀ x, f x = x ∨ g x = x variable {f g h : Perm α} @[symm] theorem Disjoint.symm : Disjoint f g → Disjoint g f := by simp only [Disjoint, or_comm, imp_self] theorem Disjoint.symmetric : Symmetric (@Disjoint α) := fun _ _ => Disjoint.symm instance : IsSymm (Perm α) Disjoint := ⟨Disjoint.symmetric⟩ theorem disjoint_comm : Disjoint f g ↔ Disjoint g f := ⟨Disjoint.symm, Disjoint.symm⟩ theorem Disjoint.commute (h : Disjoint f g) : Commute f g := Equiv.ext fun x => (h x).elim (fun hf => (h (g x)).elim (fun hg => by simp [mul_apply, hf, hg]) fun hg => by simp [mul_apply, hf, g.injective hg]) fun hg => (h (f x)).elim (fun hf => by simp [mul_apply, f.injective hf, hg]) fun hf => by simp [mul_apply, hf, hg] @[simp] theorem disjoint_one_left (f : Perm α) : Disjoint 1 f := fun _ => Or.inl rfl @[simp] theorem disjoint_one_right (f : Perm α) : Disjoint f 1 := fun _ => Or.inr rfl theorem disjoint_iff_eq_or_eq : Disjoint f g ↔ ∀ x : α, f x = x ∨ g x = x := Iff.rfl @[simp] theorem disjoint_refl_iff : Disjoint f f ↔ f = 1 := by refine ⟨fun h => ?_, fun h => h.symm ▸ disjoint_one_left 1⟩ ext x rcases h x with hx \| hx <;> simp [hx] theorem Disjoint.inv_left (h : Disjoint f g) : Disjoint f⁻¹ g := by intro x rw [inv_eq_iff_eq, eq_comm] exact h x theorem Disjoint.inv_right (h : Disjoint f g) : Disjoint f g⁻¹ := h.symm.inv_left.symm @[simp] theorem disjoint_inv_left_iff : Disjoint f⁻¹ g ↔ Disjoint f g := by refine ⟨fun h => ?_, Disjoint.inv_left⟩ convert h.inv_left @[simp] theorem disjoint_inv_right_iff : Disjoint f g⁻¹ ↔ Disjoint f g := by rw [disjoint_comm, disjoint_inv_left_iff, disjoint_comm] theorem Disjoint.mul_left (H1 : Disjoint f h) (H2 : Disjoint g h) : Disjoint (f g) h := fun x => by cases H1 x <;> cases H2 x <;> simp [] theorem Disjoint.mul_right (H1 : Disjoint f g) (H2 : Disjoint f h) : Disjoint f (g h) := by rw [disjoint_comm] exact H1.symm.mul_left H2.symm -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: make it `@[simp]` theorem disjoint_conj (h : Perm α) : Disjoint (h * f * h⁻¹) (h * g * h⁻¹) ↔ Disjoint f g := (h⁻¹).forall_congr fun {_} ↦ by simp only [mul_apply, eq_inv_iff_eq] theorem Disjoint.conj (H : Disjoint f g) (h : Perm α) : Disjoint (h * f * h⁻¹) (h * g * h⁻¹) := (disjoint_conj h).2 H theorem disjoint_prod_right (l : List (Perm α)) (h : ∀ g ∈ l, Disjoint f g) : Disjoint f l.prod := by induction' l with g l ih · exact disjoint_one_right _ · rw [List.prod_cons] exact (h _ List.mem_cons_self).mul_right (ih fun g hg => h g (List.mem_cons_of_mem _ hg)) theorem disjoint_noncommProd_right {ι : Type} {k : ι → Perm α} {s : Finset ι} (hs : Set.Pairwise s fun i j ↦ Commute (k i) (k j)) (hg : ∀ i ∈ s, g.Disjoint (k i)) : Disjoint g (s.noncommProd k (hs)) := noncommProd_induction s k hs g.Disjoint (fun _ _ ↦ Disjoint.mul_right) (disjoint_one_right g) hg open scoped List in theorem disjoint_prod_perm {l₁ l₂ : List (Perm α)} (hl : l₁.Pairwise Disjoint) (hp : l₁ ~ l₂) : l₁.prod = l₂.prod := hp.prod_eq' <\| hl.imp Disjoint.commute theorem nodup_of_pairwise_disjoint {l : List (Perm α)} (h1 : (1 : Perm α) ∉ l) (h2 : l.Pairwise Disjoint) : l.Nodup := by refine List.Pairwise.imp_of_mem ?_ h2 intro τ σ h_mem _ h_disjoint _ subst τ suffices (σ : Perm α) = 1 by rw [this] at h_mem exact h1 h_mem exact ext fun a => or_self_iff.mp (h_disjoint a) theorem pow_apply_eq_self_of_apply_eq_self {x : α} (hfx : f x = x) : ∀ n : ℕ, (f ^ n) x = x \| 0 => rfl \| n + 1 => by rw [pow_succ, mul_apply, hfx, pow_apply_eq_self_of_apply_eq_self hfx n] theorem zpow_apply_eq_self_of_apply_eq_self {x : α} (hfx : f x = x) : ∀ n : ℤ, (f ^ n) x = x \| (n : ℕ) => pow_apply_eq_self_of_apply_eq_self hfx n \| Int.negSucc n => by rw [zpow_negSucc, inv_eq_iff_eq, pow_apply_eq_self_of_apply_eq_self hfx] theorem pow_apply_eq_of_apply_apply_eq_self {x : α} (hffx : f (f x) = x) : ∀ n : ℕ, (f ^ n) x = x ∨ (f ^ n) x = f x \| 0 => Or.inl rfl \| n + 1 => (pow_apply_eq_of_apply_apply_eq_self hffx n).elim (fun h => Or.inr (by rw [pow_succ', mul_apply, h])) fun h => Or.inl (by rw [pow_succ', mul_apply, h, hffx]) theorem zpow_apply_eq_of_apply_apply_eq_self {x : α} (hffx : f (f x) = x) : ∀ i : ℤ, (f ^ i) x = x ∨ (f ^ i) x = f x \| (n : ℕ) => pow_apply_eq_of_apply_apply_eq_self hffx n \| Int.negSucc n => by rw [zpow_negSucc, inv_eq_iff_eq, ← f.injective.eq_iff, ← mul_apply, ← pow_succ', eq_comm, inv_eq_iff_eq, ← mul_apply, ← pow_succ, @eq_comm _ x, or_comm] exact pow_apply_eq_of_apply_apply_eq_self hffx _ theorem Disjoint.mul_apply_eq_iff {σ τ : Perm α} (hστ : Disjoint σ τ) {a : α} : (σ τ) a = a ↔ σ a = a ∧ τ a = a := by refine ⟨fun h => ?_, fun h => by rw [mul_apply, h.2, h.1]⟩ rcases hστ a with hσ \| hτ · exact ⟨hσ, σ.injective (h.trans hσ.symm)⟩ · exact ⟨(congr_arg σ hτ).symm.trans h, hτ⟩ theorem Disjoint.mul_eq_one_iff {σ τ : Perm α} (hστ : Disjoint σ τ) : σ * τ = 1 ↔ σ = 1 ∧ τ = 1 := by simp_rw [Perm.ext_iff, one_apply, hστ.mul_apply_eq_iff, forall_and] theorem Disjoint.zpow_disjoint_zpow {σ τ : Perm α} (hστ : Disjoint σ τ) (m n : ℤ) : Disjoint (σ ^ m) (τ ^ n) := fun x => Or.imp (fun h => zpow_apply_eq_self_of_apply_eq_self h m) (fun h => zpow_apply_eq_self_of_apply_eq_self h n) (hστ x) theorem Disjoint.pow_disjoint_pow {σ τ : Perm α} (hστ : Disjoint σ τ) (m n : ℕ) : Disjoint (σ ^ m) (τ ^ n) := hστ.zpow_disjoint_zpow m n end Disjoint section IsSwap variable [DecidableEq α] /-- `f.IsSwap` indicates that the permutation `f` is a transposition of two elements. -/ def IsSwap (f : Perm α) : Prop := ∃ x y, x ≠ y ∧ f = swap x y @[simp] theorem ofSubtype_swap_eq {p : α → Prop} [DecidablePred p] (x y : Subtype p) : ofSubtype (Equiv.swap x y) = Equiv.swap ↑x ↑y := Equiv.ext fun z => by by_cases hz : p z · rw [swap_apply_def, ofSubtype_apply_of_mem _ hz] split_ifs with hzx hzy · simp_rw [hzx, Subtype.coe_eta, swap_apply_left] · simp_rw [hzy, Subtype.coe_eta, swap_apply_right] · rw [swap_apply_of_ne_of_ne] <;> simp [Subtype.ext_iff, ] · rw [ofSubtype_apply_of_not_mem _ hz, swap_apply_of_ne_of_ne] · intro h apply hz rw [h] exact Subtype.prop x intro h apply hz rw [h] exact Subtype.prop y theorem IsSwap.of_subtype_isSwap {p : α → Prop} [DecidablePred p] {f : Perm (Subtype p)} (h : f.IsSwap) : (ofSubtype f).IsSwap := let ⟨⟨x, hx⟩, ⟨y, hy⟩, hxy⟩ := h ⟨x, y, by simp only [Ne, Subtype.ext_iff] at hxy exact hxy.1, by rw [hxy.2, ofSubtype_swap_eq]⟩ theorem ne_and_ne_of_swap_mul_apply_ne_self {f : Perm α} {x y : α} (hy : (swap x (f x) f) y ≠ y) : f y ≠ y ∧ y ≠ x := by simp only [swap_apply_def, mul_apply, f.injective.eq_iff] at * by_cases h : f y = x · constructor <;> intro <;> simp_all only [if_true, eq_self_iff_true, not_true, Ne] · split_ifs at hy with h <;> try { simp [] at } end IsSwap section support section Set variable (p q : Perm α) theorem set_support_inv_eq : { x \| p⁻¹ x ≠ x } = { x \| p x ≠ x } := by ext x simp only [Set.mem_setOf_eq, Ne] rw [inv_def, symm_apply_eq, eq_comm] theorem set_support_apply_mem {p : Perm α} {a : α} : p a ∈ { x \| p x ≠ x } ↔ a ∈ { x \| p x ≠ x } := by simp theorem set_support_zpow_subset (n : ℤ) : { x \| (p ^ n) x ≠ x } ⊆ { x \| p x ≠ x } := by intro x simp only [Set.mem_setOf_eq, Ne] intro hx H simp [zpow_apply_eq_self_of_apply_eq_self H] at hx theorem set_support_mul_subset : { x \| (p * q) x ≠ x } ⊆ { x \| p x ≠ x } ∪ { x \| q x ≠ x } := by intro x simp only [Perm.coe_mul, Function.comp_apply, Ne, Set.mem_union, Set.mem_setOf_eq] by_cases hq : q x = x <;> simp [hq] end Set @[simp] theorem apply_pow_apply_eq_iff (f : Perm α) (n : ℕ) {x : α} : f ((f ^ n) x) = (f ^ n) x ↔ f x = x := by rw [← mul_apply, Commute.self_pow f, mul_apply, apply_eq_iff_eq] @[simp] theorem apply_zpow_apply_eq_iff (f : Perm α) (n : ℤ) {x : α} : f ((f ^ n) x) = (f ^ n) x ↔ f x = x := by rw [← mul_apply, Commute.self_zpow f, mul_apply, apply_eq_iff_eq] variable [DecidableEq α] [Fintype α] {f g : Perm α} /-- The `Finset` of nonfixed points of a permutation. -/ def support (f : Perm α) : Finset α := {x \| f x ≠ x} @[simp] theorem mem_support {x : α} : x ∈ f.support ↔ f x ≠ x := by rw [support, mem_filter, and_iff_right (mem_univ x)] theorem not_mem_support {x : α} : x ∉ f.support ↔ f x = x := by simp theorem coe_support_eq_set_support (f : Perm α) : (f.support : Set α) = { x \| f x ≠ x } := by ext simp @[simp] theorem support_eq_empty_iff {σ : Perm α} : σ.support = ∅ ↔ σ = 1 := by simp_rw [Finset.ext_iff, mem_support, Finset.not_mem_empty, iff_false, not_not, Equiv.Perm.ext_iff, one_apply] @[simp] theorem support_one : (1 : Perm α).support = ∅ := by rw [support_eq_empty_iff] @[simp] theorem support_refl : support (Equiv.refl α) = ∅ := support_one theorem support_congr (h : f.support ⊆ g.support) (h' : ∀ x ∈ g.support, f x = g x) : f = g := by ext x by_cases hx : x ∈ g.support · exact h' x hx · rw [not_mem_support.mp hx, ← not_mem_support] exact fun H => hx (h H) /-- If g and c commute, then g stabilizes the support of c -/ theorem mem_support_iff_of_commute {g c : Perm α} (hgc : Commute g c) (x : α) : x ∈ c.support ↔ g x ∈ c.support := by simp only [mem_support, not_iff_not, ← mul_apply] rw [← hgc, mul_apply, Equiv.apply_eq_iff_eq] theorem support_mul_le (f g : Perm α) : (f * g).support ≤ f.support ⊔ g.support := fun x => by simp only [sup_eq_union] rw [mem_union, mem_support, mem_support, mem_support, mul_apply, ← not_and_or, not_imp_not] rintro ⟨hf, hg⟩ rw [hg, hf] theorem exists_mem_support_of_mem_support_prod {l : List (Perm α)} {x : α} (hx : x ∈ l.prod.support) : ∃ f : Perm α, f ∈ l ∧ x ∈ f.support := by contrapose! hx simp_rw [mem_support, not_not] at hx ⊢ induction' l with f l ih · rfl · rw [List.prod_cons, mul_apply, ih, hx] · simp only [List.find?, List.mem_cons, true_or] intros f' hf' refine hx f' ?_ simp only [List.find?, List.mem_cons] exact Or.inr hf' theorem support_pow_le (σ : Perm α) (n : ℕ) : (σ ^ n).support ≤ σ.support := fun _ h1 => mem_support.mpr fun h2 => mem_support.mp h1 (pow_apply_eq_self_of_apply_eq_self h2 n) @[simp] theorem support_inv (σ : Perm α) : support σ⁻¹ = σ.support := by simp_rw [Finset.ext_iff, mem_support, not_iff_not, inv_eq_iff_eq.trans eq_comm, imp_true_iff] theorem apply_mem_support {x : α} : f x ∈ f.support ↔ x ∈ f.support := by rw [mem_support, mem_support, Ne, Ne, apply_eq_iff_eq] /-- The support of a permutation is invariant -/ theorem isInvariant_of_support_le {c : Perm α} {s : Finset α} (hcs : c.support ≤ s) (x : α) : x ∈ s ↔ c x ∈ s := by by_cases hx' : x ∈ c.support · simp only [hcs hx', true_iff, hcs (apply_mem_support.mpr hx')] · rw [not_mem_support.mp hx'] /-- A permutation c is the extension of a restriction of g to s iff its support is contained in s and its restriction is that of g -/ lemma ofSubtype_eq_iff {g c : Equiv.Perm α} {s : Finset α} (hg : ∀ x, x ∈ s ↔ g x ∈ s) : ofSubtype (g.subtypePerm hg) = c ↔ c.support ≤ s ∧ ∀ (hc' : ∀ x, x ∈ s ↔ c x ∈ s), c.subtypePerm hc' = g.subtypePerm hg := by simp only [Equiv.ext_iff, subtypePerm_apply, Subtype.mk.injEq, Subtype.forall] constructor · intro h constructor · intro a ha by_contra ha' rw [mem_support, ← h a, ofSubtype_apply_of_not_mem (p := (· ∈ s)) _ ha'] at ha exact ha rfl · intro _ a ha rw [← h a, ofSubtype_apply_of_mem (p := (· ∈ s)) _ ha, subtypePerm_apply] · rintro ⟨hc, h⟩ a specialize h (isInvariant_of_support_le hc) by_cases ha : a ∈ s · rw [h a ha, ofSubtype_apply_of_mem (p := (· ∈ s)) _ ha, subtypePerm_apply] · rw [ofSubtype_apply_of_not_mem (p := (· ∈ s)) _ ha, eq_comm, ← not_mem_support] exact Finset.not_mem_mono hc ha theorem support_ofSubtype {p : α → Prop} [DecidablePred p] (u : Perm (Subtype p)) : (ofSubtype u).support = u.support.map (Function.Embedding.subtype p) := by ext x simp only [mem_support, ne_eq, Finset.mem_map, Function.Embedding.coe_subtype, Subtype.exists, exists_and_right, exists_eq_right, not_iff_comm, not_exists, not_not] by_cases hx : p x · simp only [forall_prop_of_true hx, ofSubtype_apply_of_mem u hx, ← Subtype.coe_inj] · simp only [forall_prop_of_false hx, true_iff, ofSubtype_apply_of_not_mem u hx] theorem mem_support_of_mem_noncommProd_support {α β : Type} [DecidableEq β] [Fintype β] {s : Finset α} {f : α → Perm β} {comm : (s : Set α).Pairwise (Commute on f)} {x : β} (hx : x ∈ (s.noncommProd f comm).support) : ∃ a ∈ s, x ∈ (f a).support := by contrapose! hx classical revert hx comm s apply Finset.induction · simp · intro a s ha ih comm hs rw [Finset.noncommProd_insert_of_not_mem s a f comm ha] apply mt (Finset.mem_of_subset (support_mul_le _ _)) rw [Finset.sup_eq_union, Finset.not_mem_union] exact ⟨hs a (s.mem_insert_self a), ih (fun a ha ↦ hs a (Finset.mem_insert_of_mem ha))⟩ theorem pow_apply_mem_support {n : ℕ} {x : α} : (f ^ n) x ∈ f.support ↔ x ∈ f.support := by simp only [mem_support, ne_eq, apply_pow_apply_eq_iff] theorem zpow_apply_mem_support {n : ℤ} {x : α} : (f ^ n) x ∈ f.support ↔ x ∈ f.support := by simp only [mem_support, ne_eq, apply_zpow_apply_eq_iff] theorem pow_eq_on_of_mem_support (h : ∀ x ∈ f.support ∩ g.support, f x = g x) (k : ℕ) : ∀ x ∈ f.support ∩ g.support, (f ^ k) x = (g ^ k) x := by induction' k with k hk · simp · intro x hx rw [pow_succ, mul_apply, pow_succ, mul_apply, h _ hx, hk] rwa [mem_inter, apply_mem_support, ← h _ hx, apply_mem_support, ← mem_inter] theorem disjoint_iff_disjoint_support : Disjoint f g ↔ _root_.Disjoint f.support g.support := by simp [disjoint_iff_eq_or_eq, disjoint_iff, disjoint_iff, Finset.ext_iff, not_and_or, imp_iff_not_or] theorem Disjoint.disjoint_support (h : Disjoint f g) : _root_.Disjoint f.support g.support := disjoint_iff_disjoint_support.1 h theorem Disjoint.support_mul (h : Disjoint f g) : (f g).support = f.support ∪ g.support := by refine le_antisymm (support_mul_le _ _) fun a => ?_ rw [mem_union, mem_support, mem_support, mem_support, mul_apply, ← not_and_or, not_imp_not] exact (h a).elim (fun hf h => ⟨hf, f.apply_eq_iff_eq.mp (h.trans hf.symm)⟩) fun hg h => ⟨(congr_arg f hg).symm.trans h, hg⟩ theorem support_prod_of_pairwise_disjoint (l : List (Perm α)) (h : l.Pairwise Disjoint) : l.prod.support = (l.map support).foldr (· ⊔ ·) ⊥ := by induction' l with hd tl hl · simp · rw [List.pairwise_cons] at h have : Disjoint hd tl.prod := disjoint_prod_right _ h.left simp [this.support_mul, hl h.right] theorem support_noncommProd {ι : Type} {k : ι → Perm α} {s : Finset ι} (hs : Set.Pairwise s fun i j ↦ Disjoint (k i) (k j)) : (s.noncommProd k (hs.imp (fun _ _ ↦ Perm.Disjoint.commute))).support = s.biUnion fun i ↦ (k i).support := by classical induction s using Finset.induction_on with \| empty => simp \| insert i s hi hrec => have hs' : (s : Set ι).Pairwise fun i j ↦ Disjoint (k i) (k j) := hs.mono (by simp only [Finset.coe_insert, Set.subset_insert]) rw [Finset.noncommProd_insert_of_not_mem _ _ _ _ hi, Finset.biUnion_insert] rw [Equiv.Perm.Disjoint.support_mul, hrec hs'] apply disjoint_noncommProd_right intro j hj apply hs _ _ (ne_of_mem_of_not_mem hj hi).symm <;> simp only [Finset.coe_insert, Set.mem_insert_iff, Finset.mem_coe, hj, or_true, true_or] theorem support_prod_le (l : List (Perm α)) : l.prod.support ≤ (l.map support).foldr (· ⊔ ·) ⊥ := by induction' l with hd tl hl · simp · rw [List.prod_cons, List.map_cons, List.foldr_cons] refine (support_mul_le hd tl.prod).trans ?_ exact sup_le_sup le_rfl hl theorem support_zpow_le (σ : Perm α) (n : ℤ) : (σ ^ n).support ≤ σ.support := fun _ h1 => mem_support.mpr fun h2 => mem_support.mp h1 (zpow_apply_eq_self_of_apply_eq_self h2 n) @[simp] theorem support_swap {x y : α} (h : x ≠ y) : support (swap x y) = {x, y} := by ext z by_cases hx : z = x any_goals simpa [hx] using h.symm by_cases hy : z = y · simpa [swap_apply_of_ne_of_ne, hx, hy] using h · simp [swap_apply_of_ne_of_ne, hx, hy] theorem support_swap_iff (x y : α) : support (swap x y) = {x, y} ↔ x ≠ y := by refine ⟨fun h => ?_, fun h => support_swap h⟩ rintro rfl simp [Finset.ext_iff] at h theorem support_swap_mul_swap {x y z : α} (h : List.Nodup [x, y, z]) : support (swap x y swap y z) = {x, y, z} := by simp only [List.not_mem_nil, and_true, List.mem_cons, not_false_iff, List.nodup_cons, List.mem_singleton, and_self_iff, List.nodup_nil] at h push_neg at h apply le_antisymm · convert support_mul_le (swap x y) (swap y z) using 1 rw [support_swap h.left.left, support_swap h.right.left] simp [Finset.ext_iff] · intro simp only [mem_insert, mem_singleton] rintro (rfl \| rfl \| rfl \| _) <;> simp [swap_apply_of_ne_of_ne, h.left.left, h.left.left.symm, h.left.right.symm, h.left.right.left.symm, h.right.left.symm] theorem support_swap_mul_ge_support_diff (f : Perm α) (x y : α) : f.support \ {x, y} ≤ (swap x y * f).support := by intro simp only [and_imp, Perm.coe_mul, Function.comp_apply, Ne, mem_support, mem_insert, mem_sdiff, mem_singleton] push_neg rintro ha ⟨hx, hy⟩ H rw [swap_apply_eq_iff, swap_apply_of_ne_of_ne hx hy] at H exact ha H theorem support_swap_mul_eq (f : Perm α) (x : α) (h : f (f x) ≠ x) : (swap x (f x) * f).support = f.support \ {x} := by by_cases hx : f x = x · simp [hx, sdiff_singleton_eq_erase, not_mem_support.mpr hx, erase_eq_of_not_mem] ext z by_cases hzx : z = x · simp [hzx] by_cases hzf : z = f x · simp [hzf, hx, h, swap_apply_of_ne_of_ne] by_cases hzfx : f z = x · simp [Ne.symm hzx, hzx, Ne.symm hzf, hzfx] · simp [Ne.symm hzx, hzx, Ne.symm hzf, hzfx, f.injective.ne hzx, swap_apply_of_ne_of_ne] theorem mem_support_swap_mul_imp_mem_support_ne {x y : α} (hy : y ∈ support (swap x (f x) * f)) : y ∈ support f ∧ y ≠ x := by simp only [mem_support, swap_apply_def, mul_apply, f.injective.eq_iff] at * by_cases h : f y = x · constructor <;> intro <;> simp_all only [if_true, eq_self_iff_true, not_true, Ne] · split_ifs at hy with heq · subst heq; exact ⟨h, hy⟩ · exact ⟨hy, heq⟩ theorem Disjoint.mem_imp (h : Disjoint f g) {x : α} (hx : x ∈ f.support) : x ∉ g.support := disjoint_left.mp h.disjoint_support hx theorem eq_on_support_mem_disjoint {l : List (Perm α)} (h : f ∈ l) (hl : l.Pairwise Disjoint) : ∀ x ∈ f.support, f x = l.prod x := by induction' l with hd tl IH · simp at h · intro x hx rw [List.pairwise_cons] at hl rw [List.mem_cons] at h rcases h with (rfl \| h) · rw [List.prod_cons, mul_apply, not_mem_support.mp ((disjoint_prod_right tl hl.left).mem_imp hx)] · rw [List.prod_cons, mul_apply, ← IH h hl.right _ hx, eq_comm, ← not_mem_support] refine (hl.left _ h).symm.mem_imp ?_ simpa using hx theorem Disjoint.mono {x y : Perm α} (h : Disjoint f g) (hf : x.support ≤ f.support) (hg : y.support ≤ g.support) : Disjoint x y := by rw [disjoint_iff_disjoint_support] at h ⊢ exact h.mono hf hg theorem support_le_prod_of_mem {l : List (Perm α)} (h : f ∈ l) (hl : l.Pairwise Disjoint) : f.support ≤ l.prod.support := by intro x hx rwa [mem_support, ← eq_on_support_mem_disjoint h hl _ hx, ← mem_support] section ExtendDomain variable {β : Type} [DecidableEq β] [Fintype β] {p : β → Prop} [DecidablePred p] @[simp] theorem support_extend_domain (f : α ≃ Subtype p) {g : Perm α} : support (g.extendDomain f) = g.support.map f.asEmbedding := by ext b simp only [exists_prop, Function.Embedding.coeFn_mk, toEmbedding_apply, mem_map, Ne, Function.Embedding.trans_apply, mem_support] by_cases pb : p b · rw [extendDomain_apply_subtype _ _ pb] constructor · rintro h refine ⟨f.symm ⟨b, pb⟩, ?_, by simp⟩ contrapose! h simp [h] · rintro ⟨a, ha, hb⟩ contrapose! ha obtain rfl : a = f.symm ⟨b, pb⟩ := by rw [eq_symm_apply] exact Subtype.coe_injective hb rw [eq_symm_apply] exact Subtype.coe_injective ha · rw [extendDomain_apply_not_subtype _ _ pb] simp only [not_exists, false_iff, not_and, eq_self_iff_true, not_true] rintro a _ rfl exact pb (Subtype.prop _) theorem card_support_extend_domain (f : α ≃ Subtype p) {g : Perm α} : #(g.extendDomain f).support = #g.support := by simp end ExtendDomain section Card theorem card_support_eq_zero {f : Perm α} : #f.support = 0 ↔ f = 1 := by rw [Finset.card_eq_zero, support_eq_empty_iff] theorem one_lt_card_support_of_ne_one {f : Perm α} (h : f ≠ 1) : 1 < #f.support := by simp_rw [one_lt_card_iff, mem_support, ← not_or] contrapose! h ext a specialize h (f a) a rwa [apply_eq_iff_eq, or_self_iff, or_self_iff] at h theorem card_support_ne_one (f : Perm α) : #f.support ≠ 1 := by by_cases h : f = 1 · exact ne_of_eq_of_ne (card_support_eq_zero.mpr h) zero_ne_one · exact ne_of_gt (one_lt_card_support_of_ne_one h) @[simp] theorem card_support_le_one {f : Perm α} : #f.support ≤ 1 ↔ f = 1 := by rw [le_iff_lt_or_eq, Nat.lt_succ_iff, Nat.le_zero, card_support_eq_zero, or_iff_not_imp_right, imp_iff_right f.card_support_ne_one] theorem two_le_card_support_of_ne_one {f : Perm α} (h : f ≠ 1) : 2 ≤ #f.support := one_lt_card_support_of_ne_one h theorem card_support_swap_mul {f : Perm α} {x : α} (hx : f x ≠ x) : #(swap x (f x) f).support < #f.support := Finset.card_lt_card ⟨fun _ hz => (mem_support_swap_mul_imp_mem_support_ne hz).left, fun h => absurd (h (mem_support.2 hx)) (mt mem_support.1 (by simp))⟩ theorem card_support_swap {x y : α} (hxy : x ≠ y) : #(swap x y).support = 2 := show #(swap x y).support = #⟨x ::ₘ y ::ₘ 0, by simp [hxy]⟩ from congr_arg card <\| by simp [support_swap hxy, , Finset.ext_iff] @[simp] theorem card_support_eq_two {f : Perm α} : #f.support = 2 ↔ IsSwap f := by constructor <;> intro h · obtain ⟨x, t, hmem, hins, ht⟩ := card_eq_succ.1 h obtain ⟨y, rfl⟩ := card_eq_one.1 ht rw [mem_singleton] at hmem refine ⟨x, y, hmem, ?_⟩ ext a have key : ∀ b, f b ≠ b ↔ _ := fun b => by rw [← mem_support, ← hins, mem_insert, mem_singleton] by_cases ha : f a = a · have ha' := not_or.mp (mt (key a).mpr (not_not.mpr ha)) rw [ha, swap_apply_of_ne_of_ne ha'.1 ha'.2] · have ha' := (key (f a)).mp (mt f.apply_eq_iff_eq.mp ha) obtain rfl \| rfl := (key a).mp ha · rw [Or.resolve_left ha' ha, swap_apply_left] · rw [Or.resolve_right ha' ha, swap_apply_right] · obtain ⟨x, y, hxy, rfl⟩ := h exact card_support_swap hxy theorem Disjoint.card_support_mul (h : Disjoint f g) : #(f g).support = #f.support + #g.support := by rw [← Finset.card_union_of_disjoint] · congr ext simp [h.support_mul] · simpa using h.disjoint_support theorem card_support_prod_list_of_pairwise_disjoint {l : List (Perm α)} (h : l.Pairwise Disjoint) : #l.prod.support = (l.map (card ∘ support)).sum := by induction' l with a t ih · exact card_support_eq_zero.mpr rfl · obtain ⟨ha, ht⟩ := List.pairwise_cons.1 h rw [List.prod_cons, List.map_cons, List.sum_cons, ← ih ht] exact (disjoint_prod_right _ ha).card_support_mul end Card end support @[simp] theorem support_subtype_perm [DecidableEq α] {s : Finset α} (f : Perm α) (h) : (f.subtypePerm h : Perm s).support = ({x \| f x ≠ x} : Finset s) := by ext; simp [Subtype.ext_iff] end Equiv.Perm section FixedPoints namespace Equiv.Perm /-! ### Fixed points -/ variable {α : Type} theorem fixed_point_card_lt_of_ne_one [DecidableEq α] [Fintype α] {σ : Perm α} (h : σ ≠ 1) : #{x \| σ x = x} < Fintype.card α - 1 := by rw [Nat.lt_sub_iff_add_lt, ← Nat.lt_sub_iff_add_lt', ← Finset.card_compl, Finset.compl_filter] exact one_lt_card_support_of_ne_one h end Equiv.Perm end FixedPoints section Conjugation namespace Equiv.Perm variable {α : Type} [Fintype α] [DecidableEq α] {σ τ : Perm α} @[simp] theorem support_conj : (σ * τ * σ⁻¹).support = τ.support.map σ.toEmbedding := by ext simp only [mem_map_equiv, Perm.coe_mul, Function.comp_apply, Ne, Perm.mem_support, Equiv.eq_symm_apply, inv_def] theorem card_support_conj : #(σ * τ * σ⁻¹).support = #τ.support := by simp end Equiv.Perm	end Conjugation	Mathlib/GroupTheory/Perm/Support.lean	695	695
/- Copyright (c) 2021 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel -/ import Mathlib.MeasureTheory.Covering.VitaliFamily import Mathlib.MeasureTheory.Function.AEMeasurableOrder import Mathlib.MeasureTheory.Integral.Average import Mathlib.MeasureTheory.Measure.Decomposition.Lebesgue import Mathlib.MeasureTheory.Measure.Regular /-! # Differentiation of measures On a second countable metric space with a measure `μ`, consider a Vitali family (i.e., for each `x` one has a family of sets shrinking to `x`, with a good behavior with respect to covering theorems). Consider also another measure `ρ`. Then, for almost every `x`, the ratio `ρ a / μ a` converges when `a` shrinks to `x` along the Vitali family, towards the Radon-Nikodym derivative of `ρ` with respect to `μ`. This is the main theorem on differentiation of measures. This theorem is proved in this file, under the name `VitaliFamily.ae_tendsto_rnDeriv`. Note that, almost surely, `μ a` is eventually positive and finite (see `VitaliFamily.ae_eventually_measure_pos` and `VitaliFamily.eventually_measure_lt_top`), so the ratio really makes sense. For concrete applications, one needs concrete instances of Vitali families, as provided for instance by `Besicovitch.vitaliFamily` (for balls) or by `Vitali.vitaliFamily` (for doubling measures). Specific applications to Lebesgue density points and the Lebesgue differentiation theorem are also derived: * `VitaliFamily.ae_tendsto_measure_inter_div` states that, for almost every point `x ∈ s`, then `μ (s ∩ a) / μ a` tends to `1` as `a` shrinks to `x` along a Vitali family. * `VitaliFamily.ae_tendsto_average_norm_sub` states that, for almost every point `x`, then the average of `y ↦ ‖f y - f x‖` on `a` tends to `0` as `a` shrinks to `x` along a Vitali family. ## Sketch of proof Let `v` be a Vitali family for `μ`. Assume for simplicity that `ρ` is absolutely continuous with respect to `μ`, as the case of a singular measure is easier. It is easy to see that a set `s` on which `liminf ρ a / μ a < q` satisfies `ρ s ≤ q * μ s`, by using a disjoint subcovering provided by the definition of Vitali families. Similarly for the limsup. It follows that a set on which `ρ a / μ a` oscillates has measure `0`, and therefore that `ρ a / μ a` converges almost surely (`VitaliFamily.ae_tendsto_div`). Moreover, on a set where the limit is close to a constant `c`, one gets `ρ s ∼ c μ s`, using again a covering lemma as above. It follows that `ρ` is equal to `μ.withDensity (v.limRatio ρ x)`, where `v.limRatio ρ x` is the limit of `ρ a / μ a` at `x` (which is well defined almost everywhere). By uniqueness of the Radon-Nikodym derivative, one gets `v.limRatio ρ x = ρ.rnDeriv μ x` almost everywhere, completing the proof. There is a difficulty in this sketch: this argument works well when `v.limRatio ρ` is measurable, but there is no guarantee that this is the case, especially if one doesn't make further assumptions on the Vitali family. We use an indirect argument to show that `v.limRatio ρ` is always almost everywhere measurable, again based on the disjoint subcovering argument (see `VitaliFamily.exists_measurable_supersets_limRatio`), and then proceed as sketched above but replacing `v.limRatio ρ` by a measurable version called `v.limRatioMeas ρ`. ## Counterexample The standing assumption in this file is that spaces are second countable. Without this assumption, measures may be zero locally but nonzero globally, which is not compatible with differentiation theory (which deduces global information from local one). Here is an example displaying this behavior. Define a measure `μ` by `μ s = 0` if `s` is covered by countably many balls of radius `1`, and `μ s = ∞` otherwise. This is indeed a countably additive measure, which is moreover locally finite and doubling at small scales. It vanishes on every ball of radius `1`, so all the quantities in differentiation theory (defined as ratios of measures as the radius tends to zero) make no sense. However, the measure is not globally zero if the space is big enough. ## References * [Herbert Federer, Geometric Measure Theory, Chapter 2.9][Federer1996] -/ open MeasureTheory Metric Set Filter TopologicalSpace MeasureTheory.Measure open scoped Filter ENNReal MeasureTheory NNReal Topology variable {α : Type} [PseudoMetricSpace α] {m0 : MeasurableSpace α} {μ : Measure α} (v : VitaliFamily μ) {E : Type} [NormedAddCommGroup E] namespace VitaliFamily /-- The limit along a Vitali family of `ρ a / μ a` where it makes sense, and garbage otherwise. Do not use this definition: it is only a temporary device to show that this ratio tends almost everywhere to the Radon-Nikodym derivative. -/ noncomputable def limRatio (ρ : Measure α) (x : α) : ℝ≥0∞ := limUnder (v.filterAt x) fun a => ρ a / μ a /-- For almost every point `x`, sufficiently small sets in a Vitali family around `x` have positive measure. (This is a nontrivial result, following from the covering property of Vitali families). -/ theorem ae_eventually_measure_pos [SecondCountableTopology α] : ∀ᵐ x ∂μ, ∀ᶠ a in v.filterAt x, 0 < μ a := by set s := {x \| ¬∀ᶠ a in v.filterAt x, 0 < μ a} with hs simp -zeta only [not_lt, not_eventually, nonpos_iff_eq_zero] at hs change μ s = 0 let f : α → Set (Set α) := fun _ => {a \| μ a = 0} have h : v.FineSubfamilyOn f s := by intro x hx ε εpos rw [hs] at hx simp only [frequently_filterAt_iff, exists_prop, gt_iff_lt, mem_setOf_eq] at hx rcases hx ε εpos with ⟨a, a_sets, ax, μa⟩ exact ⟨a, ⟨a_sets, μa⟩, ax⟩ refine le_antisymm ?_ bot_le calc μ s ≤ ∑' x : h.index, μ (h.covering x) := h.measure_le_tsum _ = ∑' x : h.index, 0 := by congr; ext1 x; exact h.covering_mem x.2 _ = 0 := by simp only [tsum_zero, add_zero] /-- For every point `x`, sufficiently small sets in a Vitali family around `x` have finite measure. (This is a trivial result, following from the fact that the measure is locally finite). -/ theorem eventually_measure_lt_top [IsLocallyFiniteMeasure μ] (x : α) : ∀ᶠ a in v.filterAt x, μ a < ∞ := (μ.finiteAt_nhds x).eventually.filter_mono inf_le_left /-- If two measures `ρ` and `ν` have, at every point of a set `s`, arbitrarily small sets in a Vitali family satisfying `ρ a ≤ ν a`, then `ρ s ≤ ν s` if `ρ ≪ μ`. -/ theorem measure_le_of_frequently_le [SecondCountableTopology α] [BorelSpace α] {ρ : Measure α} (ν : Measure α) [IsLocallyFiniteMeasure ν] (hρ : ρ ≪ μ) (s : Set α) (hs : ∀ x ∈ s, ∃ᶠ a in v.filterAt x, ρ a ≤ ν a) : ρ s ≤ ν s := by -- this follows from a covering argument using the sets satisfying `ρ a ≤ ν a`. apply ENNReal.le_of_forall_pos_le_add fun ε εpos _ => ?_ obtain ⟨U, sU, U_open, νU⟩ : ∃ (U : Set α), s ⊆ U ∧ IsOpen U ∧ ν U ≤ ν s + ε := exists_isOpen_le_add s ν (ENNReal.coe_pos.2 εpos).ne' let f : α → Set (Set α) := fun _ => {a \| ρ a ≤ ν a ∧ a ⊆ U} have h : v.FineSubfamilyOn f s := by apply v.fineSubfamilyOn_of_frequently f s fun x hx => ?_ have := (hs x hx).and_eventually ((v.eventually_filterAt_mem_setsAt x).and (v.eventually_filterAt_subset_of_nhds (U_open.mem_nhds (sU hx)))) apply Frequently.mono this rintro a ⟨ρa, _, aU⟩ exact ⟨ρa, aU⟩ haveI : Encodable h.index := h.index_countable.toEncodable calc ρ s ≤ ∑' x : h.index, ρ (h.covering x) := h.measure_le_tsum_of_absolutelyContinuous hρ _ ≤ ∑' x : h.index, ν (h.covering x) := ENNReal.tsum_le_tsum fun x => (h.covering_mem x.2).1 _ = ν (⋃ x : h.index, h.covering x) := by rw [measure_iUnion h.covering_disjoint_subtype fun i => h.measurableSet_u i.2] _ ≤ ν U := (measure_mono (iUnion_subset fun i => (h.covering_mem i.2).2)) _ ≤ ν s + ε := νU theorem eventually_filterAt_integrableOn (x : α) {f : α → E} (hf : LocallyIntegrable f μ) : ∀ᶠ a in v.filterAt x, IntegrableOn f a μ := by rcases hf x with ⟨w, w_nhds, hw⟩ filter_upwards [v.eventually_filterAt_subset_of_nhds w_nhds] with a ha exact hw.mono_set ha section variable [SecondCountableTopology α] [BorelSpace α] [IsLocallyFiniteMeasure μ] {ρ : Measure α} [IsLocallyFiniteMeasure ρ] /-- If a measure `ρ` is singular with respect to `μ`, then for `μ` almost every `x`, the ratio `ρ a / μ a` tends to zero when `a` shrinks to `x` along the Vitali family. This makes sense as `μ a` is eventually positive by `ae_eventually_measure_pos`. -/ theorem ae_eventually_measure_zero_of_singular (hρ : ρ ⟂ₘ μ) : ∀ᵐ x ∂μ, Tendsto (fun a => ρ a / μ a) (v.filterAt x) (𝓝 0) := by have A : ∀ ε > (0 : ℝ≥0), ∀ᵐ x ∂μ, ∀ᶠ a in v.filterAt x, ρ a < ε * μ a := by intro ε εpos set s := {x \| ¬∀ᶠ a in v.filterAt x, ρ a < ε * μ a} with hs change μ s = 0 obtain ⟨o, _, ρo, μo⟩ : ∃ o : Set α, MeasurableSet o ∧ ρ o = 0 ∧ μ oᶜ = 0 := hρ apply le_antisymm _ bot_le calc μ s ≤ μ (s ∩ o ∪ oᶜ) := by conv_lhs => rw [← inter_union_compl s o] gcongr apply inter_subset_right _ ≤ μ (s ∩ o) + μ oᶜ := measure_union_le _ _ _ = μ (s ∩ o) := by rw [μo, add_zero] _ = (ε : ℝ≥0∞)⁻¹ * (ε • μ) (s ∩ o) := by simp only [coe_nnreal_smul_apply, ← mul_assoc, mul_comm _ (ε : ℝ≥0∞)] rw [ENNReal.mul_inv_cancel (ENNReal.coe_pos.2 εpos).ne' ENNReal.coe_ne_top, one_mul] _ ≤ (ε : ℝ≥0∞)⁻¹ * ρ (s ∩ o) := by gcongr refine v.measure_le_of_frequently_le ρ smul_absolutelyContinuous _ ?_ intro x hx rw [hs] at hx simp only [mem_inter_iff, not_lt, not_eventually, mem_setOf_eq] at hx exact hx.1 _ ≤ (ε : ℝ≥0∞)⁻¹ * ρ o := by gcongr; apply inter_subset_right _ = 0 := by rw [ρo, mul_zero] obtain ⟨u, _, u_pos, u_lim⟩ : ∃ u : ℕ → ℝ≥0, StrictAnti u ∧ (∀ n : ℕ, 0 < u n) ∧ Tendsto u atTop (𝓝 0) := exists_seq_strictAnti_tendsto (0 : ℝ≥0) have B : ∀ᵐ x ∂μ, ∀ n, ∀ᶠ a in v.filterAt x, ρ a < u n * μ a := ae_all_iff.2 fun n => A (u n) (u_pos n) filter_upwards [B, v.ae_eventually_measure_pos] intro x hx h'x refine tendsto_order.2 ⟨fun z hz => (ENNReal.not_lt_zero hz).elim, fun z hz => ?_⟩ obtain ⟨w, w_pos, w_lt⟩ : ∃ w : ℝ≥0, (0 : ℝ≥0∞) < w ∧ (w : ℝ≥0∞) < z := ENNReal.lt_iff_exists_nnreal_btwn.1 hz obtain ⟨n, hn⟩ : ∃ n, u n < w := ((tendsto_order.1 u_lim).2 w (ENNReal.coe_pos.1 w_pos)).exists filter_upwards [hx n, h'x, v.eventually_measure_lt_top x] intro a ha μa_pos μa_lt_top rw [ENNReal.div_lt_iff (Or.inl μa_pos.ne') (Or.inl μa_lt_top.ne)] exact ha.trans_le (mul_le_mul_right' ((ENNReal.coe_le_coe.2 hn.le).trans w_lt.le) _) section AbsolutelyContinuous variable (hρ : ρ ≪ μ) include hρ /-- A set of points `s` satisfying both `ρ a ≤ c * μ a` and `ρ a ≥ d * μ a` at arbitrarily small sets in a Vitali family has measure `0` if `c < d`. Indeed, the first inequality should imply that `ρ s ≤ c * μ s`, and the second one that `ρ s ≥ d * μ s`, a contradiction if `0 < μ s`. -/ theorem null_of_frequently_le_of_frequently_ge {c d : ℝ≥0} (hcd : c < d) (s : Set α) (hc : ∀ x ∈ s, ∃ᶠ a in v.filterAt x, ρ a ≤ c * μ a) (hd : ∀ x ∈ s, ∃ᶠ a in v.filterAt x, (d : ℝ≥0∞) * μ a ≤ ρ a) : μ s = 0 := by apply measure_null_of_locally_null s fun x _ => ?_ obtain ⟨o, xo, o_open, μo⟩ : ∃ o : Set α, x ∈ o ∧ IsOpen o ∧ μ o < ∞ := Measure.exists_isOpen_measure_lt_top μ x refine ⟨s ∩ o, inter_mem_nhdsWithin _ (o_open.mem_nhds xo), ?_⟩ let s' := s ∩ o by_contra h apply lt_irrefl (ρ s') calc ρ s' ≤ c * μ s' := v.measure_le_of_frequently_le (c • μ) hρ s' fun x hx => hc x hx.1 _ < d * μ s' := by apply (ENNReal.mul_lt_mul_right h _).2 (ENNReal.coe_lt_coe.2 hcd) exact (lt_of_le_of_lt (measure_mono inter_subset_right) μo).ne _ ≤ ρ s' := v.measure_le_of_frequently_le ρ smul_absolutelyContinuous s' fun x hx ↦ hd x hx.1 /-- If `ρ` is absolutely continuous with respect to `μ`, then for almost every `x`, the ratio `ρ a / μ a` converges as `a` shrinks to `x` along a Vitali family for `μ`. -/ theorem ae_tendsto_div : ∀ᵐ x ∂μ, ∃ c, Tendsto (fun a => ρ a / μ a) (v.filterAt x) (𝓝 c) := by obtain ⟨w, w_count, w_dense, _, w_top⟩ : ∃ w : Set ℝ≥0∞, w.Countable ∧ Dense w ∧ 0 ∉ w ∧ ∞ ∉ w := ENNReal.exists_countable_dense_no_zero_top have I : ∀ x ∈ w, x ≠ ∞ := fun x xs hx => w_top (hx ▸ xs) have A : ∀ c ∈ w, ∀ d ∈ w, c < d → ∀ᵐ x ∂μ, ¬((∃ᶠ a in v.filterAt x, ρ a / μ a < c) ∧ ∃ᶠ a in v.filterAt x, d < ρ a / μ a) := by intro c hc d hd hcd lift c to ℝ≥0 using I c hc lift d to ℝ≥0 using I d hd apply v.null_of_frequently_le_of_frequently_ge hρ (ENNReal.coe_lt_coe.1 hcd) · simp only [and_imp, exists_prop, not_frequently, not_and, not_lt, not_le, not_eventually, mem_setOf_eq, mem_compl_iff, not_forall] intro x h1x _ apply h1x.mono fun a ha => ?_ refine (ENNReal.div_le_iff_le_mul ?_ (Or.inr (bot_le.trans_lt ha).ne')).1 ha.le simp only [ENNReal.coe_ne_top, Ne, or_true, not_false_iff] · simp only [and_imp, exists_prop, not_frequently, not_and, not_lt, not_le, not_eventually, mem_setOf_eq, mem_compl_iff, not_forall] intro x _ h2x apply h2x.mono fun a ha => ?_ exact ENNReal.mul_le_of_le_div ha.le have B : ∀ᵐ x ∂μ, ∀ c ∈ w, ∀ d ∈ w, c < d → ¬((∃ᶠ a in v.filterAt x, ρ a / μ a < c) ∧ ∃ᶠ a in v.filterAt x, d < ρ a / μ a) := by #adaptation_note /-- 2024-04-23 The next two lines were previously just `simpa only [ae_ball_iff w_count, ae_all_iff]` -/ rw [ae_ball_iff w_count]; intro x hx; rw [ae_ball_iff w_count]; revert x simpa only [ae_all_iff] filter_upwards [B] intro x hx exact tendsto_of_no_upcrossings w_dense hx theorem ae_tendsto_limRatio : ∀ᵐ x ∂μ, Tendsto (fun a => ρ a / μ a) (v.filterAt x) (𝓝 (v.limRatio ρ x)) := by filter_upwards [v.ae_tendsto_div hρ] intro x hx exact tendsto_nhds_limUnder hx /-- Given two thresholds `p < q`, the sets `{x \| v.limRatio ρ x < p}` and `{x \| q < v.limRatio ρ x}` are obviously disjoint. The key to proving that `v.limRatio ρ` is almost everywhere measurable is to show that these sets have measurable supersets which are also disjoint, up to zero measure. This is the content of this lemma. -/ theorem exists_measurable_supersets_limRatio {p q : ℝ≥0} (hpq : p < q) : ∃ a b, MeasurableSet a ∧ MeasurableSet b ∧ {x \| v.limRatio ρ x < p} ⊆ a ∧ {x \| (q : ℝ≥0∞) < v.limRatio ρ x} ⊆ b ∧ μ (a ∩ b) = 0 := by /- Here is a rough sketch, assuming that the measure is finite and the limit is well defined everywhere. Let `u := {x \| v.limRatio ρ x < p}` and `w := {x \| q < v.limRatio ρ x}`. They have measurable supersets `u'` and `w'` of the same measure. We will show that these satisfy the conclusion of the theorem, i.e., `μ (u' ∩ w') = 0`. For this, note that `ρ (u' ∩ w') = ρ (u ∩ w')` (as `w'` is measurable, see `measure_toMeasurable_add_inter_left`). The latter set is included in the set where the limit of the ratios is `< p`, and therefore its measure is `≤ p * μ (u ∩ w')`. Using the same trick in the other direction gives that this is `p * μ (u' ∩ w')`. We have shown that `ρ (u' ∩ w') ≤ p * μ (u' ∩ w')`. Arguing in the same way but using the `w` part gives `q * μ (u' ∩ w') ≤ ρ (u' ∩ w')`. If `μ (u' ∩ w')` were nonzero, this would be a contradiction as `p < q`. For the rigorous proof, we need to work on a part of the space where the measure is finite (provided by `spanningSets (ρ + μ)`) and to restrict to the set where the limit is well defined (called `s` below, of full measure). Otherwise, the argument goes through. -/ let s := {x \| ∃ c, Tendsto (fun a => ρ a / μ a) (v.filterAt x) (𝓝 c)} let o : ℕ → Set α := spanningSets (ρ + μ) let u n := s ∩ {x \| v.limRatio ρ x < p} ∩ o n let w n := s ∩ {x \| (q : ℝ≥0∞) < v.limRatio ρ x} ∩ o n -- the supersets are obtained by restricting to the set `s` where the limit is well defined, to -- a finite measure part `o n`, taking a measurable superset here, and then taking the union over -- `n`. refine ⟨toMeasurable μ sᶜ ∪ ⋃ n, toMeasurable (ρ + μ) (u n), toMeasurable μ sᶜ ∪ ⋃ n, toMeasurable (ρ + μ) (w n), ?_, ?_, ?_, ?_, ?_⟩ -- check that these sets are measurable supersets as required · exact (measurableSet_toMeasurable _ _).union (MeasurableSet.iUnion fun n => measurableSet_toMeasurable _ _) · exact (measurableSet_toMeasurable _ _).union (MeasurableSet.iUnion fun n => measurableSet_toMeasurable _ _) · intro x hx by_cases h : x ∈ s · refine Or.inr (mem_iUnion.2 ⟨spanningSetsIndex (ρ + μ) x, ?_⟩) exact subset_toMeasurable _ _ ⟨⟨h, hx⟩, mem_spanningSetsIndex _ _⟩ · exact Or.inl (subset_toMeasurable μ sᶜ h) · intro x hx by_cases h : x ∈ s · refine Or.inr (mem_iUnion.2 ⟨spanningSetsIndex (ρ + μ) x, ?_⟩) exact subset_toMeasurable _ _ ⟨⟨h, hx⟩, mem_spanningSetsIndex _ _⟩ · exact Or.inl (subset_toMeasurable μ sᶜ h) -- it remains to check the nontrivial part that these sets have zero measure intersection. -- it suffices to do it for fixed `m` and `n`, as one is taking countable unions. suffices H : ∀ m n : ℕ, μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) = 0 by have A : (toMeasurable μ sᶜ ∪ ⋃ n, toMeasurable (ρ + μ) (u n)) ∩ (toMeasurable μ sᶜ ∪ ⋃ n, toMeasurable (ρ + μ) (w n)) ⊆ toMeasurable μ sᶜ ∪ ⋃ (m) (n), toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n) := by simp only [inter_union_distrib_left, union_inter_distrib_right, true_and, subset_union_left, union_subset_iff, inter_self] refine ⟨?_, ?_, ?_⟩ · exact inter_subset_right.trans subset_union_left · exact inter_subset_left.trans subset_union_left · simp_rw [iUnion_inter, inter_iUnion]; exact subset_union_right refine le_antisymm ((measure_mono A).trans ?_) bot_le calc μ (toMeasurable μ sᶜ ∪ ⋃ (m) (n), toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) ≤ μ (toMeasurable μ sᶜ) + μ (⋃ (m) (n), toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := measure_union_le _ _ _ = μ (⋃ (m) (n), toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := by have : μ sᶜ = 0 := v.ae_tendsto_div hρ; rw [measure_toMeasurable, this, zero_add] _ ≤ ∑' (m) (n), μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := ((measure_iUnion_le _).trans (ENNReal.tsum_le_tsum fun m => measure_iUnion_le _)) _ = 0 := by simp only [H, tsum_zero] -- now starts the nontrivial part of the argument. We fix `m` and `n`, and show that the -- measurable supersets of `u m` and `w n` have zero measure intersection by using the lemmas -- `measure_toMeasurable_add_inter_left` (to reduce to `u m` or `w n` instead of the measurable -- superset) and `measure_le_of_frequently_le` to compare their measures for `ρ` and `μ`. intro m n have I : (ρ + μ) (u m) ≠ ∞ := by apply (lt_of_le_of_lt (measure_mono _) (measure_spanningSets_lt_top (ρ + μ) m)).ne exact inter_subset_right have J : (ρ + μ) (w n) ≠ ∞ := by apply (lt_of_le_of_lt (measure_mono _) (measure_spanningSets_lt_top (ρ + μ) n)).ne exact inter_subset_right have A : ρ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) ≤ p * μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := calc ρ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) = ρ (u m ∩ toMeasurable (ρ + μ) (w n)) := measure_toMeasurable_add_inter_left (measurableSet_toMeasurable _ _) I _ ≤ (p • μ) (u m ∩ toMeasurable (ρ + μ) (w n)) := by refine v.measure_le_of_frequently_le (p • μ) hρ _ fun x hx => ?_ have L : Tendsto (fun a : Set α => ρ a / μ a) (v.filterAt x) (𝓝 (v.limRatio ρ x)) := tendsto_nhds_limUnder hx.1.1.1 have I : ∀ᶠ b : Set α in v.filterAt x, ρ b / μ b < p := (tendsto_order.1 L).2 _ hx.1.1.2 apply I.frequently.mono fun a ha => ?_ rw [coe_nnreal_smul_apply] refine (ENNReal.div_le_iff_le_mul ?_ (Or.inr (bot_le.trans_lt ha).ne')).1 ha.le simp only [ENNReal.coe_ne_top, Ne, or_true, not_false_iff] _ = p * μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := by simp only [coe_nnreal_smul_apply, measure_toMeasurable_add_inter_right (measurableSet_toMeasurable _ _) I] have B : (q : ℝ≥0∞) * μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) ≤ ρ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := calc (q : ℝ≥0∞) * μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) = (q : ℝ≥0∞) * μ (toMeasurable (ρ + μ) (u m) ∩ w n) := by conv_rhs => rw [inter_comm] rw [inter_comm, measure_toMeasurable_add_inter_right (measurableSet_toMeasurable _ _) J] _ ≤ ρ (toMeasurable (ρ + μ) (u m) ∩ w n) := by rw [← coe_nnreal_smul_apply] refine v.measure_le_of_frequently_le _ (.smul_left .rfl _) _ ?_ intro x hx have L : Tendsto (fun a : Set α => ρ a / μ a) (v.filterAt x) (𝓝 (v.limRatio ρ x)) := tendsto_nhds_limUnder hx.2.1.1 have I : ∀ᶠ b : Set α in v.filterAt x, (q : ℝ≥0∞) < ρ b / μ b := (tendsto_order.1 L).1 _ hx.2.1.2 apply I.frequently.mono fun a ha => ?_ rw [coe_nnreal_smul_apply] exact ENNReal.mul_le_of_le_div ha.le _ = ρ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := by conv_rhs => rw [inter_comm] rw [inter_comm] exact (measure_toMeasurable_add_inter_left (measurableSet_toMeasurable _ _) J).symm by_contra h apply lt_irrefl (ρ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n))) calc ρ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) ≤ p * μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := A _ < q * μ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := by gcongr suffices H : (ρ + μ) (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) ≠ ∞ by simp only [not_or, ENNReal.add_eq_top, Pi.add_apply, Ne, coe_add] at H exact H.2 apply (lt_of_le_of_lt (measure_mono inter_subset_left) _).ne rw [measure_toMeasurable] apply lt_of_le_of_lt (measure_mono _) (measure_spanningSets_lt_top (ρ + μ) m) exact inter_subset_right _ ≤ ρ (toMeasurable (ρ + μ) (u m) ∩ toMeasurable (ρ + μ) (w n)) := B theorem aemeasurable_limRatio : AEMeasurable (v.limRatio ρ) μ := by apply ENNReal.aemeasurable_of_exist_almost_disjoint_supersets _ _ fun p q hpq => ?_ exact v.exists_measurable_supersets_limRatio hρ hpq /-- A measurable version of `v.limRatio ρ`. Do not use this definition: it is only a temporary device to show that `v.limRatio` is almost everywhere equal to the Radon-Nikodym derivative. -/ noncomputable def limRatioMeas : α → ℝ≥0∞ := (v.aemeasurable_limRatio hρ).mk _ theorem limRatioMeas_measurable : Measurable (v.limRatioMeas hρ) := AEMeasurable.measurable_mk _ theorem ae_tendsto_limRatioMeas : ∀ᵐ x ∂μ, Tendsto (fun a => ρ a / μ a) (v.filterAt x) (𝓝 (v.limRatioMeas hρ x)) := by filter_upwards [v.ae_tendsto_limRatio hρ, AEMeasurable.ae_eq_mk (v.aemeasurable_limRatio hρ)] intro x hx h'x rwa [h'x] at hx /-- If, for all `x` in a set `s`, one has frequently `ρ a / μ a < p`, then `ρ s ≤ p * μ s`, as proved in `measure_le_of_frequently_le`. Since `ρ a / μ a` tends almost everywhere to `v.limRatioMeas hρ x`, the same property holds for sets `s` on which `v.limRatioMeas hρ < p`. -/ theorem measure_le_mul_of_subset_limRatioMeas_lt {p : ℝ≥0} {s : Set α} (h : s ⊆ {x \| v.limRatioMeas hρ x < p}) : ρ s ≤ p * μ s := by let t := {x : α \| Tendsto (fun a => ρ a / μ a) (v.filterAt x) (𝓝 (v.limRatioMeas hρ x))} have A : μ tᶜ = 0 := v.ae_tendsto_limRatioMeas hρ suffices H : ρ (s ∩ t) ≤ (p • μ) (s ∩ t) by calc ρ s = ρ (s ∩ t ∪ s ∩ tᶜ) := by rw [inter_union_compl] _ ≤ ρ (s ∩ t) + ρ (s ∩ tᶜ) := measure_union_le _ _ _ ≤ (p • μ) (s ∩ t) + ρ tᶜ := by gcongr; apply inter_subset_right _ ≤ p * μ (s ∩ t) := by simp [(hρ A)] _ ≤ p * μ s := by gcongr; apply inter_subset_left refine v.measure_le_of_frequently_le (p • μ) hρ _ fun x hx => ?_ have I : ∀ᶠ b : Set α in v.filterAt x, ρ b / μ b < p := (tendsto_order.1 hx.2).2 _ (h hx.1) apply I.frequently.mono fun a ha => ?_ rw [coe_nnreal_smul_apply] refine (ENNReal.div_le_iff_le_mul ?_ (Or.inr (bot_le.trans_lt ha).ne')).1 ha.le simp only [ENNReal.coe_ne_top, Ne, or_true, not_false_iff] /-- If, for all `x` in a set `s`, one has frequently `q < ρ a / μ a`, then `q * μ s ≤ ρ s`, as proved in `measure_le_of_frequently_le`. Since `ρ a / μ a` tends almost everywhere to `v.limRatioMeas hρ x`, the same property holds for sets `s` on which `q < v.limRatioMeas hρ`. -/ theorem mul_measure_le_of_subset_lt_limRatioMeas {q : ℝ≥0} {s : Set α} (h : s ⊆ {x \| (q : ℝ≥0∞) < v.limRatioMeas hρ x}) : (q : ℝ≥0∞) * μ s ≤ ρ s := by let t := {x : α \| Tendsto (fun a => ρ a / μ a) (v.filterAt x) (𝓝 (v.limRatioMeas hρ x))} have A : μ tᶜ = 0 := v.ae_tendsto_limRatioMeas hρ suffices H : (q • μ) (s ∩ t) ≤ ρ (s ∩ t) by calc (q • μ) s = (q • μ) (s ∩ t ∪ s ∩ tᶜ) := by rw [inter_union_compl] _ ≤ (q • μ) (s ∩ t) + (q • μ) (s ∩ tᶜ) := measure_union_le _ _ _ ≤ ρ (s ∩ t) + (q • μ) tᶜ := by gcongr; apply inter_subset_right _ = ρ (s ∩ t) := by simp [A] _ ≤ ρ s := by gcongr; apply inter_subset_left refine v.measure_le_of_frequently_le _ (.smul_left .rfl _) _ ?_ intro x hx have I : ∀ᶠ a in v.filterAt x, (q : ℝ≥0∞) < ρ a / μ a := (tendsto_order.1 hx.2).1 _ (h hx.1) apply I.frequently.mono fun a ha => ?_ rw [coe_nnreal_smul_apply] exact ENNReal.mul_le_of_le_div ha.le /-- The points with `v.limRatioMeas hρ x = ∞` have measure `0` for `μ`. -/ theorem measure_limRatioMeas_top : μ {x \| v.limRatioMeas hρ x = ∞} = 0 := by refine measure_null_of_locally_null _ fun x _ => ?_ obtain ⟨o, xo, o_open, μo⟩ : ∃ o : Set α, x ∈ o ∧ IsOpen o ∧ ρ o < ∞ := Measure.exists_isOpen_measure_lt_top ρ x let s := {x : α \| v.limRatioMeas hρ x = ∞} ∩ o refine ⟨s, inter_mem_nhdsWithin _ (o_open.mem_nhds xo), le_antisymm ?_ bot_le⟩ have ρs : ρ s ≠ ∞ := ((measure_mono inter_subset_right).trans_lt μo).ne have A : ∀ q : ℝ≥0, 1 ≤ q → μ s ≤ (q : ℝ≥0∞)⁻¹ * ρ s := by intro q hq rw [mul_comm, ← div_eq_mul_inv, ENNReal.le_div_iff_mul_le _ (Or.inr ρs), mul_comm] · apply v.mul_measure_le_of_subset_lt_limRatioMeas hρ intro y hy have : v.limRatioMeas hρ y = ∞ := hy.1 simp only [this, ENNReal.coe_lt_top, mem_setOf_eq] · simp only [(zero_lt_one.trans_le hq).ne', true_or, ENNReal.coe_eq_zero, Ne, not_false_iff] have B : Tendsto (fun q : ℝ≥0 => (q : ℝ≥0∞)⁻¹ * ρ s) atTop (𝓝 (∞⁻¹ * ρ s)) := by apply ENNReal.Tendsto.mul_const _ (Or.inr ρs) exact ENNReal.tendsto_inv_iff.2 (ENNReal.tendsto_coe_nhds_top.2 tendsto_id) simp only [zero_mul, ENNReal.inv_top] at B apply ge_of_tendsto B exact eventually_atTop.2 ⟨1, A⟩ /-- The points with `v.limRatioMeas hρ x = 0` have measure `0` for `ρ`. -/ theorem measure_limRatioMeas_zero : ρ {x \| v.limRatioMeas hρ x = 0} = 0 := by refine measure_null_of_locally_null _ fun x _ => ?_ obtain ⟨o, xo, o_open, μo⟩ : ∃ o : Set α, x ∈ o ∧ IsOpen o ∧ μ o < ∞ := Measure.exists_isOpen_measure_lt_top μ x let s := {x : α \| v.limRatioMeas hρ x = 0} ∩ o refine ⟨s, inter_mem_nhdsWithin _ (o_open.mem_nhds xo), le_antisymm ?_ bot_le⟩ have μs : μ s ≠ ∞ := ((measure_mono inter_subset_right).trans_lt μo).ne have A : ∀ q : ℝ≥0, 0 < q → ρ s ≤ q * μ s := by intro q hq apply v.measure_le_mul_of_subset_limRatioMeas_lt hρ intro y hy have : v.limRatioMeas hρ y = 0 := hy.1 simp only [this, mem_setOf_eq, hq, ENNReal.coe_pos] have B : Tendsto (fun q : ℝ≥0 => (q : ℝ≥0∞) * μ s) (𝓝[>] (0 : ℝ≥0)) (𝓝 ((0 : ℝ≥0) * μ s)) := by apply ENNReal.Tendsto.mul_const _ (Or.inr μs) rw [ENNReal.tendsto_coe] exact nhdsWithin_le_nhds simp only [zero_mul, ENNReal.coe_zero] at B apply ge_of_tendsto B filter_upwards [self_mem_nhdsWithin] using A /-- As an intermediate step to show that `μ.withDensity (v.limRatioMeas hρ) = ρ`, we show here that `μ.withDensity (v.limRatioMeas hρ) ≤ t^2 ρ` for any `t > 1`. -/ theorem withDensity_le_mul {s : Set α} (hs : MeasurableSet s) {t : ℝ≥0} (ht : 1 < t) : μ.withDensity (v.limRatioMeas hρ) s ≤ (t : ℝ≥0∞) ^ 2 * ρ s := by /- We cut `s` into the sets where `v.limRatioMeas hρ = 0`, where `v.limRatioMeas hρ = ∞`, and where `v.limRatioMeas hρ ∈ [t^n, t^(n+1))` for `n : ℤ`. The first and second have measure `0`. For the latter, since `v.limRatioMeas hρ` fluctuates by at most `t` on this slice, we can use `measure_le_mul_of_subset_limRatioMeas_lt` and `mul_measure_le_of_subset_lt_limRatioMeas` to show that the two measures are comparable up to `t` (in fact `t^2` for technical reasons of strict inequalities). -/ have t_ne_zero' : t ≠ 0 := (zero_lt_one.trans ht).ne' have t_ne_zero : (t : ℝ≥0∞) ≠ 0 := by simpa only [ENNReal.coe_eq_zero, Ne] using t_ne_zero' let ν := μ.withDensity (v.limRatioMeas hρ) let f := v.limRatioMeas hρ have f_meas : Measurable f := v.limRatioMeas_measurable hρ -- Note(kmill): smul elaborator when used for CoeFun fails to get CoeFun instance to trigger -- unless you use the `(... :)` notation. Another fix is using `(2 : Nat)`, so this appears -- to be an unpleasant interaction with default instances. have A : ν (s ∩ f ⁻¹' {0}) ≤ ((t : ℝ≥0∞) ^ 2 • ρ :) (s ∩ f ⁻¹' {0}) := by apply le_trans _ (zero_le _) have M : MeasurableSet (s ∩ f ⁻¹' {0}) := hs.inter (f_meas (measurableSet_singleton _)) simp only [f, ν, nonpos_iff_eq_zero, M, withDensity_apply, lintegral_eq_zero_iff f_meas] apply (ae_restrict_iff' M).2 exact Eventually.of_forall fun x hx => hx.2 have B : ν (s ∩ f ⁻¹' {∞}) ≤ ((t : ℝ≥0∞) ^ 2 • ρ :) (s ∩ f ⁻¹' {∞}) := by apply le_trans (le_of_eq _) (zero_le _) apply withDensity_absolutelyContinuous μ _ rw [← nonpos_iff_eq_zero] exact (measure_mono inter_subset_right).trans (v.measure_limRatioMeas_top hρ).le have C : ∀ n : ℤ, ν (s ∩ f ⁻¹' Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1))) ≤ ((t : ℝ≥0∞) ^ 2 • ρ :) (s ∩ f ⁻¹' Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1))) := by intro n let I := Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1)) have M : MeasurableSet (s ∩ f ⁻¹' I) := hs.inter (f_meas measurableSet_Ico) simp only [ν, I, M, withDensity_apply, coe_nnreal_smul_apply] calc (∫⁻ x in s ∩ f ⁻¹' I, f x ∂μ) ≤ ∫⁻ _ in s ∩ f ⁻¹' I, (t : ℝ≥0∞) ^ (n + 1) ∂μ := lintegral_mono_ae ((ae_restrict_iff' M).2 (Eventually.of_forall fun x hx => hx.2.2.le)) _ = (t : ℝ≥0∞) ^ (n + 1) * μ (s ∩ f ⁻¹' I) := by simp only [lintegral_const, MeasurableSet.univ, Measure.restrict_apply, univ_inter] _ = (t : ℝ≥0∞) ^ (2 : ℤ) * ((t : ℝ≥0∞) ^ (n - 1) * μ (s ∩ f ⁻¹' I)) := by rw [← mul_assoc, ← ENNReal.zpow_add t_ne_zero ENNReal.coe_ne_top] congr 2 abel _ ≤ (t : ℝ≥0∞) ^ (2 : ℤ) * ρ (s ∩ f ⁻¹' I) := by gcongr rw [← ENNReal.coe_zpow (zero_lt_one.trans ht).ne'] apply v.mul_measure_le_of_subset_lt_limRatioMeas hρ intro x hx apply lt_of_lt_of_le _ hx.2.1 rw [← ENNReal.coe_zpow (zero_lt_one.trans ht).ne', ENNReal.coe_lt_coe, sub_eq_add_neg, zpow_add₀ t_ne_zero'] conv_rhs => rw [← mul_one (t ^ n)] gcongr rw [zpow_neg_one] exact inv_lt_one_of_one_lt₀ ht calc ν s = ν (s ∩ f ⁻¹' {0}) + ν (s ∩ f ⁻¹' {∞}) + ∑' n : ℤ, ν (s ∩ f ⁻¹' Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1))) := measure_eq_measure_preimage_add_measure_tsum_Ico_zpow ν f_meas hs ht _ ≤ ((t : ℝ≥0∞) ^ 2 • ρ :) (s ∩ f ⁻¹' {0}) + ((t : ℝ≥0∞) ^ 2 • ρ :) (s ∩ f ⁻¹' {∞}) + ∑' n : ℤ, ((t : ℝ≥0∞) ^ 2 • ρ :) (s ∩ f ⁻¹' Ico (t ^ n) (t ^ (n + 1))) := (add_le_add (add_le_add A B) (ENNReal.tsum_le_tsum C)) _ = ((t : ℝ≥0∞) ^ 2 • ρ :) s := (measure_eq_measure_preimage_add_measure_tsum_Ico_zpow ((t : ℝ≥0∞) ^ 2 • ρ) f_meas hs ht).symm /-- As an intermediate step to show that `μ.withDensity (v.limRatioMeas hρ) = ρ`, we show here that `ρ ≤ t μ.withDensity (v.limRatioMeas hρ)` for any `t > 1`. -/ theorem le_mul_withDensity {s : Set α} (hs : MeasurableSet s) {t : ℝ≥0} (ht : 1 < t) : ρ s ≤ t * μ.withDensity (v.limRatioMeas hρ) s := by /- We cut `s` into the sets where `v.limRatioMeas hρ = 0`, where `v.limRatioMeas hρ = ∞`, and where `v.limRatioMeas hρ ∈ [t^n, t^(n+1))` for `n : ℤ`. The first and second have measure `0`. For the latter, since `v.limRatioMeas hρ` fluctuates by at most `t` on this slice, we can use `measure_le_mul_of_subset_limRatioMeas_lt` and `mul_measure_le_of_subset_lt_limRatioMeas` to show that the two measures are comparable up to `t`. -/ have t_ne_zero' : t ≠ 0 := (zero_lt_one.trans ht).ne' have t_ne_zero : (t : ℝ≥0∞) ≠ 0 := by simpa only [ENNReal.coe_eq_zero, Ne] using t_ne_zero' let ν := μ.withDensity (v.limRatioMeas hρ) let f := v.limRatioMeas hρ have f_meas : Measurable f := v.limRatioMeas_measurable hρ have A : ρ (s ∩ f ⁻¹' {0}) ≤ (t • ν) (s ∩ f ⁻¹' {0}) := by refine le_trans (measure_mono inter_subset_right) (le_trans (le_of_eq ?_) (zero_le _)) exact v.measure_limRatioMeas_zero hρ	have B : ρ (s ∩ f ⁻¹' {∞}) ≤ (t • ν) (s ∩ f ⁻¹' {∞}) := by apply le_trans (le_of_eq _) (zero_le _) apply hρ rw [← nonpos_iff_eq_zero] exact (measure_mono inter_subset_right).trans (v.measure_limRatioMeas_top hρ).le have C : ∀ n : ℤ, ρ (s ∩ f ⁻¹' Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1))) ≤ (t • ν) (s ∩ f ⁻¹' Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1))) := by intro n let I := Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1)) have M : MeasurableSet (s ∩ f ⁻¹' I) := hs.inter (f_meas measurableSet_Ico) simp only [ν, I, M, withDensity_apply, coe_nnreal_smul_apply] calc ρ (s ∩ f ⁻¹' I) ≤ (t : ℝ≥0∞) ^ (n + 1) * μ (s ∩ f ⁻¹' I) := by rw [← ENNReal.coe_zpow t_ne_zero'] apply v.measure_le_mul_of_subset_limRatioMeas_lt hρ intro x hx apply hx.2.2.trans_le (le_of_eq _) rw [ENNReal.coe_zpow t_ne_zero'] _ = ∫⁻ _ in s ∩ f ⁻¹' I, (t : ℝ≥0∞) ^ (n + 1) ∂μ := by simp only [lintegral_const, MeasurableSet.univ, Measure.restrict_apply, univ_inter] _ ≤ ∫⁻ x in s ∩ f ⁻¹' I, t * f x ∂μ := by apply lintegral_mono_ae ((ae_restrict_iff' M).2 (Eventually.of_forall fun x hx => ?_)) rw [add_comm, ENNReal.zpow_add t_ne_zero ENNReal.coe_ne_top, zpow_one] exact mul_le_mul_left' hx.2.1 _ _ = t * ∫⁻ x in s ∩ f ⁻¹' I, f x ∂μ := lintegral_const_mul _ f_meas calc ρ s = ρ (s ∩ f ⁻¹' {0}) + ρ (s ∩ f ⁻¹' {∞}) + ∑' n : ℤ, ρ (s ∩ f ⁻¹' Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1))) := measure_eq_measure_preimage_add_measure_tsum_Ico_zpow ρ f_meas hs ht _ ≤ (t • ν) (s ∩ f ⁻¹' {0}) + (t • ν) (s ∩ f ⁻¹' {∞}) + ∑' n : ℤ, (t • ν) (s ∩ f ⁻¹' Ico ((t : ℝ≥0∞) ^ n) ((t : ℝ≥0∞) ^ (n + 1))) := (add_le_add (add_le_add A B) (ENNReal.tsum_le_tsum C)) _ = (t • ν) s := (measure_eq_measure_preimage_add_measure_tsum_Ico_zpow (t • ν) f_meas hs ht).symm theorem withDensity_limRatioMeas_eq : μ.withDensity (v.limRatioMeas hρ) = ρ := by ext1 s hs refine le_antisymm ?_ ?_ · have : Tendsto (fun t : ℝ≥0 => ((t : ℝ≥0∞) ^ 2 * ρ s : ℝ≥0∞)) (𝓝[>] 1) (𝓝 ((1 : ℝ≥0∞) ^ 2 * ρ s)) := by refine ENNReal.Tendsto.mul ?_ ?_ tendsto_const_nhds ?_ · exact ENNReal.Tendsto.pow (ENNReal.tendsto_coe.2 nhdsWithin_le_nhds) · simp only [one_pow, ENNReal.coe_one, true_or, Ne, not_false_iff, one_ne_zero] · simp only [one_pow, ENNReal.coe_one, Ne, or_true, ENNReal.one_ne_top, not_false_iff] simp only [one_pow, one_mul, ENNReal.coe_one] at this refine ge_of_tendsto this ?_ filter_upwards [self_mem_nhdsWithin] with _ ht exact v.withDensity_le_mul hρ hs ht · have :	Mathlib/MeasureTheory/Covering/Differentiation.lean	604	656
/- Copyright (c) 2017 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison -/ import Mathlib.CategoryTheory.EqToHom import Mathlib.CategoryTheory.Products.Basic /-! # Curry and uncurry, as functors. We define `curry : ((C × D) ⥤ E) ⥤ (C ⥤ (D ⥤ E))` and `uncurry : (C ⥤ (D ⥤ E)) ⥤ ((C × D) ⥤ E)`, and verify that they provide an equivalence of categories `currying : (C ⥤ (D ⥤ E)) ≌ ((C × D) ⥤ E)`. -/ namespace CategoryTheory universe v₁ v₂ v₃ v₄ v₅ u₁ u₂ u₃ u₄ u₅ variable {B : Type u₁} [Category.{v₁} B] {C : Type u₂} [Category.{v₂} C] {D : Type u₃} [Category.{v₃} D] {E : Type u₄} [Category.{v₄} E] {H : Type u₅} [Category.{v₅} H] /-- The uncurrying functor, taking a functor `C ⥤ (D ⥤ E)` and producing a functor `(C × D) ⥤ E`. -/ @[simps] def uncurry : (C ⥤ D ⥤ E) ⥤ C × D ⥤ E where obj F := { obj := fun X => (F.obj X.1).obj X.2 map := fun {X} {Y} f => (F.map f.1).app X.2 ≫ (F.obj Y.1).map f.2 map_comp := fun f g => by simp only [prod_comp_fst, prod_comp_snd, Functor.map_comp, NatTrans.comp_app, Category.assoc] slice_lhs 2 3 => rw [← NatTrans.naturality] rw [Category.assoc] } map T := { app := fun X => (T.app X.1).app X.2 naturality := fun X Y f => by simp only [prod_comp_fst, prod_comp_snd, Category.comp_id, Category.assoc, Functor.map_id, Functor.map_comp, NatTrans.id_app, NatTrans.comp_app] slice_lhs 2 3 => rw [NatTrans.naturality] slice_lhs 1 2 => rw [← NatTrans.comp_app, NatTrans.naturality, NatTrans.comp_app] rw [Category.assoc] } /-- The object level part of the currying functor. (See `curry` for the functorial version.) -/ def curryObj (F : C × D ⥤ E) : C ⥤ D ⥤ E where obj X := { obj := fun Y => F.obj (X, Y) map := fun g => F.map (𝟙 X, g) map_id := fun Y => by simp only [F.map_id]; rw [← prod_id]; exact F.map_id ⟨X,Y⟩ map_comp := fun f g => by simp [← F.map_comp]} map f := { app := fun Y => F.map (f, 𝟙 Y) naturality := fun {Y} {Y'} g => by simp [← F.map_comp] } map_id := fun X => by ext Y; exact F.map_id _ map_comp := fun f g => by ext Y; dsimp; simp [← F.map_comp] /-- The currying functor, taking a functor `(C × D) ⥤ E` and producing a functor `C ⥤ (D ⥤ E)`. -/ @[simps! obj_obj_obj obj_obj_map obj_map_app map_app_app] def curry : (C × D ⥤ E) ⥤ C ⥤ D ⥤ E where obj F := curryObj F map T := { app := fun X => { app := fun Y => T.app (X, Y) naturality := fun Y Y' g => by dsimp [curryObj] rw [NatTrans.naturality] } naturality := fun X X' f => by ext; dsimp [curryObj] rw [NatTrans.naturality] } -- create projection simp lemmas even though this isn't a `{ .. }`. /-- The equivalence of functor categories given by currying/uncurrying. -/ @[simps!] def currying : C ⥤ D ⥤ E ≌ C × D ⥤ E where functor := uncurry inverse := curry unitIso := NatIso.ofComponents (fun _ ↦ NatIso.ofComponents (fun _ ↦ NatIso.ofComponents (fun _ ↦ Iso.refl _))) counitIso := NatIso.ofComponents (fun F ↦ NatIso.ofComponents (fun _ ↦ Iso.refl _) (by rintro ⟨X₁, X₂⟩ ⟨Y₁, Y₂⟩ ⟨f₁, f₂⟩ dsimp at f₁ f₂ ⊢ simp only [← F.map_comp, prod_comp, Category.comp_id, Category.id_comp])) /-- The functor `uncurry : (C ⥤ D ⥤ E) ⥤ C × D ⥤ E` is fully faithful. -/ def fullyFaithfulUncurry : (uncurry : (C ⥤ D ⥤ E) ⥤ C × D ⥤ E).FullyFaithful := currying.fullyFaithfulFunctor instance : (uncurry : (C ⥤ D ⥤ E) ⥤ C × D ⥤ E).Full := fullyFaithfulUncurry.full instance : (uncurry : (C ⥤ D ⥤ E) ⥤ C × D ⥤ E).Faithful := fullyFaithfulUncurry.faithful /-- Given functors `F₁ : C ⥤ D`, `F₂ : C' ⥤ D'` and `G : D × D' ⥤ E`, this is the isomorphism between `curry.obj ((F₁.prod F₂).comp G)` and `F₁ ⋙ curry.obj G ⋙ (whiskeringLeft C' D' E).obj F₂` in the category `C ⥤ C' ⥤ E`. -/ @[simps!] def curryObjProdComp {C' D' : Type*} [Category C'] [Category D'] (F₁ : C ⥤ D) (F₂ : C' ⥤ D') (G : D × D' ⥤ E) : curry.obj ((F₁.prod F₂).comp G) ≅ F₁ ⋙ curry.obj G ⋙ (whiskeringLeft C' D' E).obj F₂ := NatIso.ofComponents (fun X₁ ↦ NatIso.ofComponents (fun X₂ ↦ Iso.refl _)) /-- `F.flip` is isomorphic to uncurrying `F`, swapping the variables, and currying. -/ @[simps!] def flipIsoCurrySwapUncurry (F : C ⥤ D ⥤ E) : F.flip ≅ curry.obj (Prod.swap _ _ ⋙ uncurry.obj F) := NatIso.ofComponents fun d => NatIso.ofComponents fun _ => Iso.refl _ /-- The uncurrying of `F.flip` is isomorphic to swapping the factors followed by the uncurrying of `F`. -/ @[simps!] def uncurryObjFlip (F : C ⥤ D ⥤ E) : uncurry.obj F.flip ≅ Prod.swap _ _ ⋙ uncurry.obj F := NatIso.ofComponents fun _ => Iso.refl _ variable (B C D E) /-- A version of `CategoryTheory.whiskeringRight` for bifunctors, obtained by uncurrying,	applying `whiskeringRight` and currying back -/ @[simps!]	Mathlib/CategoryTheory/Functor/Currying.lean	125	127
/- Copyright (c) 2020 Kyle Miller. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kyle Miller -/ import Mathlib.Algebra.Group.Action.Pi import Mathlib.Data.Finset.Prod import Mathlib.Data.SetLike.Basic import Mathlib.Data.Sym.Basic import Mathlib.Data.Sym.Sym2.Init /-! # The symmetric square This file defines the symmetric square, which is `α × α` modulo swapping. This is also known as the type of unordered pairs. More generally, the symmetric square is the second symmetric power (see `Data.Sym.Basic`). The equivalence is `Sym2.equivSym`. From the point of view that an unordered pair is equivalent to a multiset of cardinality two (see `Sym2.equivMultiset`), there is a `Mem` instance `Sym2.Mem`, which is a `Prop`-valued membership test. Given `h : a ∈ z` for `z : Sym2 α`, then `Mem.other h` is the other element of the pair, defined using `Classical.choice`. If `α` has decidable equality, then `h.other'` computably gives the other element. The universal property of `Sym2` is provided as `Sym2.lift`, which states that functions from `Sym2 α` are equivalent to symmetric two-argument functions from `α`. Recall that an undirected graph (allowing self loops, but no multiple edges) is equivalent to a symmetric relation on the vertex type `α`. Given a symmetric relation on `α`, the corresponding edge set is constructed by `Sym2.fromRel` which is a special case of `Sym2.lift`. ## Notation The element `Sym2.mk (a, b)` can be written as `s(a, b)` for short. ## Tags symmetric square, unordered pairs, symmetric powers -/ assert_not_exists MonoidWithZero open List (Vector) open Finset Function Sym universe u variable {α β γ : Type} namespace Sym2 /-- This is the relation capturing the notion of pairs equivalent up to permutations. -/ @[aesop (rule_sets := [Sym2]) [safe [constructors, cases], norm]] inductive Rel (α : Type u) : α × α → α × α → Prop \| refl (x y : α) : Rel _ (x, y) (x, y) \| swap (x y : α) : Rel _ (x, y) (y, x) attribute [refl] Rel.refl @[symm] theorem Rel.symm {x y : α × α} : Rel α x y → Rel α y x := by aesop (rule_sets := [Sym2]) @[trans] theorem Rel.trans {x y z : α × α} (a : Rel α x y) (b : Rel α y z) : Rel α x z := by aesop (rule_sets := [Sym2]) theorem Rel.is_equivalence : Equivalence (Rel α) := { refl := fun (x, y) ↦ Rel.refl x y, symm := Rel.symm, trans := Rel.trans } /-- One can use `attribute [local instance] Sym2.Rel.setoid` to temporarily make `Quotient` functionality work for `α × α`. -/ def Rel.setoid (α : Type u) : Setoid (α × α) := ⟨Rel α, Rel.is_equivalence⟩ @[simp] theorem rel_iff' {p q : α × α} : Rel α p q ↔ p = q ∨ p = q.swap := by aesop (rule_sets := [Sym2]) theorem rel_iff {x y z w : α} : Rel α (x, y) (z, w) ↔ x = z ∧ y = w ∨ x = w ∧ y = z := by simp end Sym2 /-- `Sym2 α` is the symmetric square of `α`, which, in other words, is the type of unordered pairs. It is equivalent in a natural way to multisets of cardinality 2 (see `Sym2.equivMultiset`). -/ abbrev Sym2 (α : Type u) := Quot (Sym2.Rel α) /-- Constructor for `Sym2`. This is the quotient map `α × α → Sym2 α`. -/ protected abbrev Sym2.mk {α : Type} (p : α × α) : Sym2 α := Quot.mk (Sym2.Rel α) p /-- `s(x, y)` is an unordered pair, which is to say a pair modulo the action of the symmetric group. It is equal to `Sym2.mk (x, y)`. -/ notation3 "s(" x ", " y ")" => Sym2.mk (x, y) namespace Sym2 protected theorem sound {p p' : α × α} (h : Sym2.Rel α p p') : Sym2.mk p = Sym2.mk p' := Quot.sound h protected theorem exact {p p' : α × α} (h : Sym2.mk p = Sym2.mk p') : Sym2.Rel α p p' := Quotient.exact (s := Sym2.Rel.setoid α) h @[simp] protected theorem eq {p p' : α × α} : Sym2.mk p = Sym2.mk p' ↔ Sym2.Rel α p p' := Quotient.eq' (s₁ := Sym2.Rel.setoid α) @[elab_as_elim, cases_eliminator, induction_eliminator] protected theorem ind {f : Sym2 α → Prop} (h : ∀ x y, f s(x, y)) : ∀ i, f i := Quot.ind <\| Prod.rec <\| h @[elab_as_elim] protected theorem inductionOn {f : Sym2 α → Prop} (i : Sym2 α) (hf : ∀ x y, f s(x, y)) : f i := i.ind hf @[elab_as_elim] protected theorem inductionOn₂ {f : Sym2 α → Sym2 β → Prop} (i : Sym2 α) (j : Sym2 β) (hf : ∀ a₁ a₂ b₁ b₂, f s(a₁, a₂) s(b₁, b₂)) : f i j := Quot.induction_on₂ i j <\| by intro ⟨a₁, a₂⟩ ⟨b₁, b₂⟩ exact hf _ _ _ _ /-- Dependent recursion principal for `Sym2`. See `Quot.rec`. -/ @[elab_as_elim] protected def rec {motive : Sym2 α → Sort} (f : (p : α × α) → motive (Sym2.mk p)) (h : (p q : α × α) → (h : Sym2.Rel α p q) → Eq.ndrec (f p) (Sym2.sound h) = f q) (z : Sym2 α) : motive z := Quot.rec f h z /-- Dependent recursion principal for `Sym2` when the target is a `Subsingleton` type. See `Quot.recOnSubsingleton`. -/ @[elab_as_elim] protected abbrev recOnSubsingleton {motive : Sym2 α → Sort} [(p : α × α) → Subsingleton (motive (Sym2.mk p))] (z : Sym2 α) (f : (p : α × α) → motive (Sym2.mk p)) : motive z := Quot.recOnSubsingleton z f protected theorem «exists» {α : Sort _} {f : Sym2 α → Prop} : (∃ x : Sym2 α, f x) ↔ ∃ x y, f s(x, y) := Quot.mk_surjective.exists.trans Prod.exists protected theorem «forall» {α : Sort _} {f : Sym2 α → Prop} : (∀ x : Sym2 α, f x) ↔ ∀ x y, f s(x, y) := Quot.mk_surjective.forall.trans Prod.forall theorem eq_swap {a b : α} : s(a, b) = s(b, a) := Quot.sound (Rel.swap _ _) @[simp] theorem mk_prod_swap_eq {p : α × α} : Sym2.mk p.swap = Sym2.mk p := by cases p exact eq_swap theorem congr_right {a b c : α} : s(a, b) = s(a, c) ↔ b = c := by simp +contextual theorem congr_left {a b c : α} : s(b, a) = s(c, a) ↔ b = c := by simp +contextual theorem eq_iff {x y z w : α} : s(x, y) = s(z, w) ↔ x = z ∧ y = w ∨ x = w ∧ y = z := by simp theorem mk_eq_mk_iff {p q : α × α} : Sym2.mk p = Sym2.mk q ↔ p = q ∨ p = q.swap := by cases p cases q simp only [eq_iff, Prod.mk_inj, Prod.swap_prod_mk] /-- The universal property of `Sym2`; symmetric functions of two arguments are equivalent to functions from `Sym2`. Note that when `β` is `Prop`, it can sometimes be more convenient to use `Sym2.fromRel` instead. -/ def lift : { f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁ } ≃ (Sym2 α → β) where toFun f := Quot.lift (uncurry ↑f) <\| by rintro _ _ ⟨⟩ exacts [rfl, f.prop _ _] invFun F := ⟨curry (F ∘ Sym2.mk), fun _ _ => congr_arg F eq_swap⟩ left_inv _ := Subtype.ext rfl right_inv _ := funext <\| Sym2.ind fun _ _ => rfl @[simp] theorem lift_mk (f : { f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁ }) (a₁ a₂ : α) : lift f s(a₁, a₂) = (f : α → α → β) a₁ a₂ := rfl @[simp] theorem coe_lift_symm_apply (F : Sym2 α → β) (a₁ a₂ : α) : (lift.symm F : α → α → β) a₁ a₂ = F s(a₁, a₂) := rfl /-- A two-argument version of `Sym2.lift`. -/ def lift₂ : { f : α → α → β → β → γ // ∀ a₁ a₂ b₁ b₂, f a₁ a₂ b₁ b₂ = f a₂ a₁ b₁ b₂ ∧ f a₁ a₂ b₁ b₂ = f a₁ a₂ b₂ b₁ } ≃ (Sym2 α → Sym2 β → γ) where toFun f := Quotient.lift₂ (s₁ := Sym2.Rel.setoid α) (s₂ := Sym2.Rel.setoid β) (fun (a : α × α) (b : β × β) => f.1 a.1 a.2 b.1 b.2) (by rintro _ _ _ _ ⟨⟩ ⟨⟩ exacts [rfl, (f.2 _ _ _ _).2, (f.2 _ _ _ _).1, (f.2 _ _ _ _).1.trans (f.2 _ _ _ _).2]) invFun F := ⟨fun a₁ a₂ b₁ b₂ => F s(a₁, a₂) s(b₁, b₂), fun a₁ a₂ b₁ b₂ => by constructor exacts [congr_arg₂ F eq_swap rfl, congr_arg₂ F rfl eq_swap]⟩ left_inv _ := Subtype.ext rfl right_inv _ := funext₂ fun a b => Sym2.inductionOn₂ a b fun _ _ _ _ => rfl @[simp] theorem lift₂_mk (f : { f : α → α → β → β → γ // ∀ a₁ a₂ b₁ b₂, f a₁ a₂ b₁ b₂ = f a₂ a₁ b₁ b₂ ∧ f a₁ a₂ b₁ b₂ = f a₁ a₂ b₂ b₁ }) (a₁ a₂ : α) (b₁ b₂ : β) : lift₂ f s(a₁, a₂) s(b₁, b₂) = (f : α → α → β → β → γ) a₁ a₂ b₁ b₂ := rfl @[simp] theorem coe_lift₂_symm_apply (F : Sym2 α → Sym2 β → γ) (a₁ a₂ : α) (b₁ b₂ : β) : (lift₂.symm F : α → α → β → β → γ) a₁ a₂ b₁ b₂ = F s(a₁, a₂) s(b₁, b₂) := rfl /-- The functor `Sym2` is functorial, and this function constructs the induced maps. -/ def map (f : α → β) : Sym2 α → Sym2 β := Quot.map (Prod.map f f) (by intro _ _ h; cases h <;> constructor) @[simp] theorem map_id : map (@id α) = id := by ext ⟨⟨x, y⟩⟩ rfl theorem map_comp {g : β → γ} {f : α → β} : Sym2.map (g ∘ f) = Sym2.map g ∘ Sym2.map f := by ext ⟨⟨x, y⟩⟩ rfl theorem map_map {g : β → γ} {f : α → β} (x : Sym2 α) : map g (map f x) = map (g ∘ f) x := by induction x; aesop @[simp] theorem map_pair_eq (f : α → β) (x y : α) : map f s(x, y) = s(f x, f y) := rfl theorem map.injective {f : α → β} (hinj : Injective f) : Injective (map f) := by intro z z' refine Sym2.inductionOn₂ z z' (fun x y x' y' => ?_) simp [hinj.eq_iff] /-- `mk a` as an embedding. This is the symmetric version of `Function.Embedding.sectL`. -/ @[simps] def mkEmbedding (a : α) : α ↪ Sym2 α where toFun b := s(a, b) inj' b₁ b₁ h := by simp only [Sym2.eq, Sym2.rel_iff', Prod.mk.injEq, true_and, Prod.swap_prod_mk] at h obtain rfl \| ⟨rfl, rfl⟩ := h <;> rfl /-- `Sym2.map` as an embedding. -/ @[simps] def _root_.Function.Embedding.sym2Map (f : α ↪ β) : Sym2 α ↪ Sym2 β where toFun := map f inj' := map.injective f.injective lemma lift_comp_map {g : γ → α} (f : {f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁}) : lift f ∘ map g = lift ⟨fun (c₁ c₂ : γ) => f.val (g c₁) (g c₂), fun _ _ => f.prop _ _⟩ := lift.symm_apply_eq.mp rfl lemma lift_map_apply {g : γ → α} (f : {f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁}) (p : Sym2 γ) : lift f (map g p) = lift ⟨fun (c₁ c₂ : γ) => f.val (g c₁) (g c₂), fun _ _ => f.prop _ _⟩ p := by conv_rhs => rw [← lift_comp_map, comp_apply] section Membership /-! ### Membership and set coercion -/ /-- This is a predicate that determines whether a given term is a member of a term of the symmetric square. From this point of view, the symmetric square is the subtype of cardinality-two multisets on `α`. -/ protected def Mem (x : α) (z : Sym2 α) : Prop := ∃ y : α, z = s(x, y) @[aesop norm (rule_sets := [Sym2])] theorem mem_iff' {a b c : α} : Sym2.Mem a s(b, c) ↔ a = b ∨ a = c := { mp := by rintro ⟨_, h⟩ rw [eq_iff] at h aesop mpr := by rintro (rfl \| rfl) · exact ⟨_, rfl⟩ rw [eq_swap] exact ⟨_, rfl⟩ } instance : SetLike (Sym2 α) α where coe z := { x \| z.Mem x } coe_injective' z z' h := by simp only [Set.ext_iff, Set.mem_setOf_eq] at h obtain ⟨x, y⟩ := z obtain ⟨x', y'⟩ := z' have hx := h x; have hy := h y; have hx' := h x'; have hy' := h y' simp only [mem_iff', eq_self_iff_true] at hx hy hx' hy' aesop @[simp] theorem mem_iff_mem {x : α} {z : Sym2 α} : Sym2.Mem x z ↔ x ∈ z := Iff.rfl theorem mem_iff_exists {x : α} {z : Sym2 α} : x ∈ z ↔ ∃ y : α, z = s(x, y) := Iff.rfl @[ext] theorem ext {p q : Sym2 α} (h : ∀ x, x ∈ p ↔ x ∈ q) : p = q := SetLike.ext h theorem mem_mk_left (x y : α) : x ∈ s(x, y) := ⟨y, rfl⟩ theorem mem_mk_right (x y : α) : y ∈ s(x, y) := eq_swap ▸ mem_mk_left y x @[simp, aesop norm (rule_sets := [Sym2])] theorem mem_iff {a b c : α} : a ∈ s(b, c) ↔ a = b ∨ a = c := mem_iff' theorem out_fst_mem (e : Sym2 α) : e.out.1 ∈ e := ⟨e.out.2, by rw [Sym2.mk, e.out_eq]⟩ theorem out_snd_mem (e : Sym2 α) : e.out.2 ∈ e := ⟨e.out.1, by rw [eq_swap, Sym2.mk, e.out_eq]⟩ theorem ball {p : α → Prop} {a b : α} : (∀ c ∈ s(a, b), p c) ↔ p a ∧ p b := by refine ⟨fun h => ⟨h _ <\| mem_mk_left _ _, h _ <\| mem_mk_right _ _⟩, fun h c hc => ?_⟩ obtain rfl \| rfl := Sym2.mem_iff.1 hc · exact h.1 · exact h.2 /-- Given an element of the unordered pair, give the other element using `Classical.choose`. See also `Mem.other'` for the computable version. -/ noncomputable def Mem.other {a : α} {z : Sym2 α} (h : a ∈ z) : α := Classical.choose h @[simp] theorem other_spec {a : α} {z : Sym2 α} (h : a ∈ z) : s(a, Mem.other h) = z := by erw [← Classical.choose_spec h] theorem other_mem {a : α} {z : Sym2 α} (h : a ∈ z) : Mem.other h ∈ z := by convert mem_mk_right a <\| Mem.other h rw [other_spec h] theorem mem_and_mem_iff {x y : α} {z : Sym2 α} (hne : x ≠ y) : x ∈ z ∧ y ∈ z ↔ z = s(x, y) := by constructor · cases z rw [mem_iff, mem_iff] aesop · rintro rfl simp theorem eq_of_ne_mem {x y : α} {z z' : Sym2 α} (h : x ≠ y) (h1 : x ∈ z) (h2 : y ∈ z) (h3 : x ∈ z') (h4 : y ∈ z') : z = z' := ((mem_and_mem_iff h).mp ⟨h1, h2⟩).trans ((mem_and_mem_iff h).mp ⟨h3, h4⟩).symm instance Mem.decidable [DecidableEq α] (x : α) (z : Sym2 α) : Decidable (x ∈ z) := z.recOnSubsingleton fun ⟨_, _⟩ => decidable_of_iff' _ mem_iff end Membership @[simp] theorem mem_map {f : α → β} {b : β} {z : Sym2 α} : b ∈ Sym2.map f z ↔ ∃ a, a ∈ z ∧ f a = b := by cases z simp only [map_pair_eq, mem_iff, exists_eq_or_imp, exists_eq_left] aesop @[congr] theorem map_congr {f g : α → β} {s : Sym2 α} (h : ∀ x ∈ s, f x = g x) : map f s = map g s := by	ext y simp only [mem_map] constructor <;> · rintro ⟨w, hw, rfl⟩ exact ⟨w, hw, by simp [hw, h]⟩ /-- Note: `Sym2.map_id` will not simplify `Sym2.map id z` due to `Sym2.map_congr`. -/	Mathlib/Data/Sym/Sym2.lean	386	392
/- Copyright (c) 2022 Andrew Yang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.Algebra.Polynomial.Module.Basic import Mathlib.RingTheory.Finiteness.Nakayama import Mathlib.RingTheory.LocalRing.MaximalIdeal.Basic import Mathlib.RingTheory.ReesAlgebra /-! # `I`-filtrations of modules This file contains the definitions and basic results around (stable) `I`-filtrations of modules. ## Main results - `Ideal.Filtration`: An `I`-filtration on the module `M` is a sequence of decreasing submodules `N i` such that `∀ i, I • (N i) ≤ N (i + 1)`. Note that we do not require the filtration to start from `⊤`. - `Ideal.Filtration.Stable`: An `I`-filtration is stable if `I • (N i) = N (i + 1)` for large enough `i`. - `Ideal.Filtration.submodule`: The associated module `⨁ Nᵢ` of a filtration, implemented as a submodule of `M[X]`. - `Ideal.Filtration.submodule_fg_iff_stable`: If `F.N i` are all finitely generated, then `F.Stable` iff `F.submodule.FG`. - `Ideal.Filtration.Stable.of_le`: In a finite module over a noetherian ring, if `F' ≤ F`, then `F.Stable → F'.Stable`. - `Ideal.exists_pow_inf_eq_pow_smul`: Artin-Rees lemma. given `N ≤ M`, there exists a `k` such that `IⁿM ⊓ N = Iⁿ⁻ᵏ(IᵏM ⊓ N)` for all `n ≥ k`. - `Ideal.iInf_pow_eq_bot_of_isLocalRing`: Krull's intersection theorem (`⨅ i, I ^ i = ⊥`) for noetherian local rings. - `Ideal.iInf_pow_eq_bot_of_isDomain`: Krull's intersection theorem (`⨅ i, I ^ i = ⊥`) for noetherian domains. -/ variable {R M : Type} [CommRing R] [AddCommGroup M] [Module R M] (I : Ideal R) open Polynomial open scoped Polynomial /-- An `I`-filtration on the module `M` is a sequence of decreasing submodules `N i` such that `I • (N i) ≤ N (i + 1)`. Note that we do not require the filtration to start from `⊤`. -/ @[ext] structure Ideal.Filtration (M : Type) [AddCommGroup M] [Module R M] where N : ℕ → Submodule R M mono : ∀ i, N (i + 1) ≤ N i smul_le : ∀ i, I • N i ≤ N (i + 1) variable (F F' : I.Filtration M) {I} namespace Ideal.Filtration theorem pow_smul_le (i j : ℕ) : I ^ i • F.N j ≤ F.N (i + j) := by induction' i with _ ih · simp · rw [pow_succ', mul_smul, add_assoc, add_comm 1, ← add_assoc] exact (smul_mono_right _ ih).trans (F.smul_le _) theorem pow_smul_le_pow_smul (i j k : ℕ) : I ^ (i + k) • F.N j ≤ I ^ k • F.N (i + j) := by rw [add_comm, pow_add, mul_smul] exact smul_mono_right _ (F.pow_smul_le i j)	protected theorem antitone : Antitone F.N := antitone_nat_of_succ_le F.mono /-- The trivial `I`-filtration of `N`. -/ @[simps]	Mathlib/RingTheory/Filtration.lean	67	71
/- Copyright (c) 2015 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura, Mario Carneiro -/ import Mathlib.Data.Sum.Basic import Mathlib.Logic.Equiv.Option import Mathlib.Logic.Equiv.Sum import Mathlib.Logic.Function.Conjugate import Mathlib.Tactic.CC import Mathlib.Tactic.Lift /-! # Equivalence between types In this file we continue the work on equivalences begun in `Mathlib/Logic/Equiv/Defs.lean`, defining a lot of equivalences between various types and operations on these equivalences. More definitions of this kind can be found in other files. E.g., `Mathlib/Algebra/Equiv/TransferInstance.lean` does it for many algebraic type classes like `Group`, `Module`, etc. ## Tags equivalence, congruence, bijective map -/ universe u v w z open Function -- Unless required to be `Type`, all variables in this file are `Sort` variable {α α₁ α₂ β β₁ β₂ γ δ : Sort} namespace Equiv /-- The product over `Option α` of `β a` is the binary product of the product over `α` of `β (some α)` and `β none` -/ @[simps] def piOptionEquivProd {α} {β : Option α → Type} : (∀ a : Option α, β a) ≃ β none × ∀ a : α, β (some a) where toFun f := (f none, fun a => f (some a)) invFun x a := Option.casesOn a x.fst x.snd left_inv f := funext fun a => by cases a <;> rfl right_inv x := by simp section subtypeCongr /-- Combines an `Equiv` between two subtypes with an `Equiv` between their complements to form a permutation. -/ def subtypeCongr {α} {p q : α → Prop} [DecidablePred p] [DecidablePred q] (e : { x // p x } ≃ { x // q x }) (f : { x // ¬p x } ≃ { x // ¬q x }) : Perm α := (sumCompl p).symm.trans ((sumCongr e f).trans (sumCompl q)) variable {ε : Type} {p : ε → Prop} [DecidablePred p] variable (ep ep' : Perm { a // p a }) (en en' : Perm { a // ¬p a }) /-- Combining permutations on `ε` that permute only inside or outside the subtype split induced by `p : ε → Prop` constructs a permutation on `ε`. -/ def Perm.subtypeCongr : Equiv.Perm ε := permCongr (sumCompl p) (sumCongr ep en) theorem Perm.subtypeCongr.apply (a : ε) : ep.subtypeCongr en a = if h : p a then (ep ⟨a, h⟩ : ε) else en ⟨a, h⟩ := by by_cases h : p a <;> simp [Perm.subtypeCongr, h] @[simp] theorem Perm.subtypeCongr.left_apply {a : ε} (h : p a) : ep.subtypeCongr en a = ep ⟨a, h⟩ := by simp [Perm.subtypeCongr.apply, h] @[simp] theorem Perm.subtypeCongr.left_apply_subtype (a : { a // p a }) : ep.subtypeCongr en a = ep a := Perm.subtypeCongr.left_apply ep en a.property @[simp] theorem Perm.subtypeCongr.right_apply {a : ε} (h : ¬p a) : ep.subtypeCongr en a = en ⟨a, h⟩ := by simp [Perm.subtypeCongr.apply, h] @[simp] theorem Perm.subtypeCongr.right_apply_subtype (a : { a // ¬p a }) : ep.subtypeCongr en a = en a := Perm.subtypeCongr.right_apply ep en a.property @[simp] theorem Perm.subtypeCongr.refl : Perm.subtypeCongr (Equiv.refl { a // p a }) (Equiv.refl { a // ¬p a }) = Equiv.refl ε := by ext x by_cases h : p x <;> simp [h] @[simp] theorem Perm.subtypeCongr.symm : (ep.subtypeCongr en).symm = Perm.subtypeCongr ep.symm en.symm := by ext x by_cases h : p x · have : p (ep.symm ⟨x, h⟩) := Subtype.property _ simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this] · have : ¬p (en.symm ⟨x, h⟩) := Subtype.property (en.symm _) simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this] @[simp] theorem Perm.subtypeCongr.trans : (ep.subtypeCongr en).trans (ep'.subtypeCongr en') = Perm.subtypeCongr (ep.trans ep') (en.trans en') := by ext x by_cases h : p x · have : p (ep ⟨x, h⟩) := Subtype.property _ simp [Perm.subtypeCongr.apply, h, this] · have : ¬p (en ⟨x, h⟩) := Subtype.property (en _) simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this] end subtypeCongr section subtypePreimage variable (p : α → Prop) [DecidablePred p] (x₀ : { a // p a } → β) /-- For a fixed function `x₀ : {a // p a} → β` defined on a subtype of `α`, the subtype of functions `x : α → β` that agree with `x₀` on the subtype `{a // p a}` is naturally equivalent to the type of functions `{a // ¬ p a} → β`. -/ @[simps] def subtypePreimage : { x : α → β // x ∘ Subtype.val = x₀ } ≃ ({ a // ¬p a } → β) where toFun (x : { x : α → β // x ∘ Subtype.val = x₀ }) a := (x : α → β) a invFun x := ⟨fun a => if h : p a then x₀ ⟨a, h⟩ else x ⟨a, h⟩, funext fun ⟨_, h⟩ => dif_pos h⟩ left_inv := fun ⟨x, hx⟩ => Subtype.val_injective <\| funext fun a => by dsimp only split_ifs · rw [← hx]; rfl · rfl right_inv x := funext fun ⟨a, h⟩ => show dite (p a) _ _ = _ by dsimp only rw [dif_neg h] theorem subtypePreimage_symm_apply_coe_pos (x : { a // ¬p a } → β) (a : α) (h : p a) : ((subtypePreimage p x₀).symm x : α → β) a = x₀ ⟨a, h⟩ := dif_pos h theorem subtypePreimage_symm_apply_coe_neg (x : { a // ¬p a } → β) (a : α) (h : ¬p a) : ((subtypePreimage p x₀).symm x : α → β) a = x ⟨a, h⟩ := dif_neg h end subtypePreimage section /-- A family of equivalences `∀ a, β₁ a ≃ β₂ a` generates an equivalence between `∀ a, β₁ a` and `∀ a, β₂ a`. -/ @[simps] def piCongrRight {β₁ β₂ : α → Sort} (F : ∀ a, β₁ a ≃ β₂ a) : (∀ a, β₁ a) ≃ (∀ a, β₂ a) := ⟨Pi.map fun a ↦ F a, Pi.map fun a ↦ (F a).symm, fun H => funext <\| by simp, fun H => funext <\| by simp⟩ /-- Given `φ : α → β → Sort`, we have an equivalence between `∀ a b, φ a b` and `∀ b a, φ a b`. This is `Function.swap` as an `Equiv`. -/ @[simps apply] def piComm (φ : α → β → Sort) : (∀ a b, φ a b) ≃ ∀ b a, φ a b := ⟨swap, swap, fun _ => rfl, fun _ => rfl⟩ @[simp] theorem piComm_symm {φ : α → β → Sort} : (piComm φ).symm = (piComm <\| swap φ) := rfl /-- Dependent `curry` equivalence: the type of dependent functions on `Σ i, β i` is equivalent to the type of dependent functions of two arguments (i.e., functions to the space of functions). This is `Sigma.curry` and `Sigma.uncurry` together as an equiv. -/ def piCurry {α} {β : α → Type} (γ : ∀ a, β a → Type) : (∀ x : Σ i, β i, γ x.1 x.2) ≃ ∀ a b, γ a b where toFun := Sigma.curry invFun := Sigma.uncurry left_inv := Sigma.uncurry_curry right_inv := Sigma.curry_uncurry -- `simps` overapplies these but `simps -fullyApplied` under-applies them @[simp] theorem piCurry_apply {α} {β : α → Type} (γ : ∀ a, β a → Type) (f : ∀ x : Σ i, β i, γ x.1 x.2) : piCurry γ f = Sigma.curry f := rfl @[simp] theorem piCurry_symm_apply {α} {β : α → Type} (γ : ∀ a, β a → Type) (f : ∀ a b, γ a b) : (piCurry γ).symm f = Sigma.uncurry f := rfl end section prodCongr variable {α₁ α₂ β₁ β₂ : Type} (e : α₁ → β₁ ≃ β₂) -- See also `Equiv.ofPreimageEquiv`. /-- A family of equivalences between fibers gives an equivalence between domains. -/ @[simps!] def ofFiberEquiv {α β γ} {f : α → γ} {g : β → γ} (e : ∀ c, { a // f a = c } ≃ { b // g b = c }) : α ≃ β := (sigmaFiberEquiv f).symm.trans <\| (Equiv.sigmaCongrRight e).trans (sigmaFiberEquiv g) theorem ofFiberEquiv_map {α β γ} {f : α → γ} {g : β → γ} (e : ∀ c, { a // f a = c } ≃ { b // g b = c }) (a : α) : g (ofFiberEquiv e a) = f a := (_ : { b // g b = _ }).property end prodCongr section open Sum /-- An equivalence that separates out the 0th fiber of `(Σ (n : ℕ), f n)`. -/ def sigmaNatSucc (f : ℕ → Type u) : (Σ n, f n) ≃ f 0 ⊕ Σ n, f (n + 1) := ⟨fun x => @Sigma.casesOn ℕ f (fun _ => f 0 ⊕ Σ n, f (n + 1)) x fun n => @Nat.casesOn (fun i => f i → f 0 ⊕ Σ n : ℕ, f (n + 1)) n (fun x : f 0 => Sum.inl x) fun (n : ℕ) (x : f n.succ) => Sum.inr ⟨n, x⟩, Sum.elim (Sigma.mk 0) (Sigma.map Nat.succ fun _ => id), by rintro ⟨n \| n, x⟩ <;> rfl, by rintro (x \| ⟨n, x⟩) <;> rfl⟩ end section open Sum Nat /-- The set of natural numbers is equivalent to `ℕ ⊕ PUnit`. -/ def natEquivNatSumPUnit : ℕ ≃ ℕ ⊕ PUnit where toFun n := Nat.casesOn n (inr PUnit.unit) inl invFun := Sum.elim Nat.succ fun _ => 0 left_inv n := by cases n <;> rfl right_inv := by rintro (_ \| _) <;> rfl /-- `ℕ ⊕ PUnit` is equivalent to `ℕ`. -/ def natSumPUnitEquivNat : ℕ ⊕ PUnit ≃ ℕ := natEquivNatSumPUnit.symm /-- The type of integer numbers is equivalent to `ℕ ⊕ ℕ`. -/ def intEquivNatSumNat : ℤ ≃ ℕ ⊕ ℕ where toFun z := Int.casesOn z inl inr invFun := Sum.elim Int.ofNat Int.negSucc left_inv := by rintro (m \| n) <;> rfl right_inv := by rintro (m \| n) <;> rfl end /-- If `α` is equivalent to `β`, then `Unique α` is equivalent to `Unique β`. -/ def uniqueCongr (e : α ≃ β) : Unique α ≃ Unique β where toFun h := @Equiv.unique _ _ h e.symm invFun h := @Equiv.unique _ _ h e left_inv _ := Subsingleton.elim _ _ right_inv _ := Subsingleton.elim _ _ /-- If `α` is equivalent to `β`, then `IsEmpty α` is equivalent to `IsEmpty β`. -/ theorem isEmpty_congr (e : α ≃ β) : IsEmpty α ↔ IsEmpty β := ⟨fun h => @Function.isEmpty _ _ h e.symm, fun h => @Function.isEmpty _ _ h e⟩ protected theorem isEmpty (e : α ≃ β) [IsEmpty β] : IsEmpty α := e.isEmpty_congr.mpr ‹_› section open Subtype /-- If `α` is equivalent to `β` and the predicates `p : α → Prop` and `q : β → Prop` are equivalent at corresponding points, then `{a // p a}` is equivalent to `{b // q b}`. For the statement where `α = β`, that is, `e : perm α`, see `Perm.subtypePerm`. -/ @[simps apply] def subtypeEquiv {p : α → Prop} {q : β → Prop} (e : α ≃ β) (h : ∀ a, p a ↔ q (e a)) : { a : α // p a } ≃ { b : β // q b } where toFun a := ⟨e a, (h _).mp a.property⟩ invFun b := ⟨e.symm b, (h _).mpr ((e.apply_symm_apply b).symm ▸ b.property)⟩ left_inv a := Subtype.ext <\| by simp right_inv b := Subtype.ext <\| by simp lemma coe_subtypeEquiv_eq_map {X Y} {p : X → Prop} {q : Y → Prop} (e : X ≃ Y) (h : ∀ x, p x ↔ q (e x)) : ⇑(e.subtypeEquiv h) = Subtype.map e (h · \|>.mp) := rfl @[simp] theorem subtypeEquiv_refl {p : α → Prop} (h : ∀ a, p a ↔ p (Equiv.refl _ a) := fun _ => Iff.rfl) : (Equiv.refl α).subtypeEquiv h = Equiv.refl { a : α // p a } := by ext rfl -- We use `as_aux_lemma` here to avoid creating large proof terms when using `simp` @[simp] theorem subtypeEquiv_symm {p : α → Prop} {q : β → Prop} (e : α ≃ β) (h : ∀ a : α, p a ↔ q (e a)) : (e.subtypeEquiv h).symm = e.symm.subtypeEquiv (by as_aux_lemma => intro a convert (h <\| e.symm a).symm exact (e.apply_symm_apply a).symm) := rfl @[simp] theorem subtypeEquiv_trans {p : α → Prop} {q : β → Prop} {r : γ → Prop} (e : α ≃ β) (f : β ≃ γ) (h : ∀ a : α, p a ↔ q (e a)) (h' : ∀ b : β, q b ↔ r (f b)) : (e.subtypeEquiv h).trans (f.subtypeEquiv h') = (e.trans f).subtypeEquiv (by as_aux_lemma => exact fun a => (h a).trans (h' <\| e a)) := rfl /-- If two predicates `p` and `q` are pointwise equivalent, then `{x // p x}` is equivalent to `{x // q x}`. -/ @[simps!] def subtypeEquivRight {p q : α → Prop} (e : ∀ x, p x ↔ q x) : { x // p x } ≃ { x // q x } := subtypeEquiv (Equiv.refl _) e lemma subtypeEquivRight_apply {p q : α → Prop} (e : ∀ x, p x ↔ q x) (z : { x // p x }) : subtypeEquivRight e z = ⟨z, (e z.1).mp z.2⟩ := rfl lemma subtypeEquivRight_symm_apply {p q : α → Prop} (e : ∀ x, p x ↔ q x) (z : { x // q x }) : (subtypeEquivRight e).symm z = ⟨z, (e z.1).mpr z.2⟩ := rfl /-- If `α ≃ β`, then for any predicate `p : β → Prop` the subtype `{a // p (e a)}` is equivalent to the subtype `{b // p b}`. -/ def subtypeEquivOfSubtype {p : β → Prop} (e : α ≃ β) : { a : α // p (e a) } ≃ { b : β // p b } := subtypeEquiv e <\| by simp /-- If `α ≃ β`, then for any predicate `p : α → Prop` the subtype `{a // p a}` is equivalent to the subtype `{b // p (e.symm b)}`. This version is used by `equiv_rw`. -/ def subtypeEquivOfSubtype' {p : α → Prop} (e : α ≃ β) : { a : α // p a } ≃ { b : β // p (e.symm b) } := e.symm.subtypeEquivOfSubtype.symm /-- If two predicates are equal, then the corresponding subtypes are equivalent. -/ def subtypeEquivProp {p q : α → Prop} (h : p = q) : Subtype p ≃ Subtype q := subtypeEquiv (Equiv.refl α) fun _ => h ▸ Iff.rfl /-- A subtype of a subtype is equivalent to the subtype of elements satisfying both predicates. This version allows the “inner” predicate to depend on `h : p a`. -/ @[simps] def subtypeSubtypeEquivSubtypeExists (p : α → Prop) (q : Subtype p → Prop) : Subtype q ≃ { a : α // ∃ h : p a, q ⟨a, h⟩ } := ⟨fun a => ⟨a.1, a.1.2, by rcases a with ⟨⟨a, hap⟩, haq⟩ exact haq⟩, fun a => ⟨⟨a, a.2.fst⟩, a.2.snd⟩, fun ⟨⟨_, _⟩, _⟩ => rfl, fun ⟨_, _, _⟩ => rfl⟩ /-- A subtype of a subtype is equivalent to the subtype of elements satisfying both predicates. -/ @[simps!] def subtypeSubtypeEquivSubtypeInter {α : Type u} (p q : α → Prop) : { x : Subtype p // q x.1 } ≃ Subtype fun x => p x ∧ q x := (subtypeSubtypeEquivSubtypeExists p _).trans <\| subtypeEquivRight fun x => @exists_prop (q x) (p x) /-- If the outer subtype has more restrictive predicate than the inner one, then we can drop the latter. -/ @[simps!] def subtypeSubtypeEquivSubtype {α} {p q : α → Prop} (h : ∀ {x}, q x → p x) : { x : Subtype p // q x.1 } ≃ Subtype q := (subtypeSubtypeEquivSubtypeInter p _).trans <\| subtypeEquivRight fun _ => and_iff_right_of_imp h /-- If a proposition holds for all elements, then the subtype is equivalent to the original type. -/ @[simps apply symm_apply] def subtypeUnivEquiv {α} {p : α → Prop} (h : ∀ x, p x) : Subtype p ≃ α := ⟨fun x => x, fun x => ⟨x, h x⟩, fun _ => Subtype.eq rfl, fun _ => rfl⟩ /-- A subtype of a sigma-type is a sigma-type over a subtype. -/ def subtypeSigmaEquiv {α} (p : α → Type v) (q : α → Prop) : { y : Sigma p // q y.1 } ≃ Σ x : Subtype q, p x.1 := ⟨fun x => ⟨⟨x.1.1, x.2⟩, x.1.2⟩, fun x => ⟨⟨x.1.1, x.2⟩, x.1.2⟩, fun _ => rfl, fun _ => rfl⟩ /-- A sigma type over a subtype is equivalent to the sigma set over the original type, if the fiber is empty outside of the subset -/ def sigmaSubtypeEquivOfSubset {α} (p : α → Type v) (q : α → Prop) (h : ∀ x, p x → q x) : (Σ x : Subtype q, p x) ≃ Σ x : α, p x := (subtypeSigmaEquiv p q).symm.trans <\| subtypeUnivEquiv fun x => h x.1 x.2 /-- If a predicate `p : β → Prop` is true on the range of a map `f : α → β`, then `Σ y : {y // p y}, {x // f x = y}` is equivalent to `α`. -/ def sigmaSubtypeFiberEquiv {α β : Type} (f : α → β) (p : β → Prop) (h : ∀ x, p (f x)) : (Σ y : Subtype p, { x : α // f x = y }) ≃ α := calc _ ≃ Σy : β, { x : α // f x = y } := sigmaSubtypeEquivOfSubset _ p fun _ ⟨x, h'⟩ => h' ▸ h x _ ≃ α := sigmaFiberEquiv f /-- If for each `x` we have `p x ↔ q (f x)`, then `Σ y : {y // q y}, f ⁻¹' {y}` is equivalent to `{x // p x}`. -/ def sigmaSubtypeFiberEquivSubtype {α β : Type} (f : α → β) {p : α → Prop} {q : β → Prop} (h : ∀ x, p x ↔ q (f x)) : (Σ y : Subtype q, { x : α // f x = y }) ≃ Subtype p := calc (Σy : Subtype q, { x : α // f x = y }) ≃ Σy : Subtype q, { x : Subtype p // Subtype.mk (f x) ((h x).1 x.2) = y } := by { apply sigmaCongrRight intro y apply Equiv.symm refine (subtypeSubtypeEquivSubtypeExists _ _).trans (subtypeEquivRight ?_) intro x exact ⟨fun ⟨hp, h'⟩ => congr_arg Subtype.val h', fun h' => ⟨(h x).2 (h'.symm ▸ y.2), Subtype.eq h'⟩⟩ } _ ≃ Subtype p := sigmaFiberEquiv fun x : Subtype p => (⟨f x, (h x).1 x.property⟩ : Subtype q) /-- A sigma type over an `Option` is equivalent to the sigma set over the original type, if the fiber is empty at none. -/ def sigmaOptionEquivOfSome {α} (p : Option α → Type v) (h : p none → False) : (Σ x : Option α, p x) ≃ Σ x : α, p (some x) := haveI h' : ∀ x, p x → x.isSome := by intro x cases x · intro n exfalso exact h n · intro _ exact rfl (sigmaSubtypeEquivOfSubset _ _ h').symm.trans (sigmaCongrLeft' (optionIsSomeEquiv α)) /-- The `Pi`-type `∀ i, π i` is equivalent to the type of sections `f : ι → Σ i, π i` of the `Sigma` type such that for all `i` we have `(f i).fst = i`. -/ def piEquivSubtypeSigma (ι) (π : ι → Type) : (∀ i, π i) ≃ { f : ι → Σ i, π i // ∀ i, (f i).1 = i } where toFun := fun f => ⟨fun i => ⟨i, f i⟩, fun _ => rfl⟩ invFun := fun f i => by rw [← f.2 i]; exact (f.1 i).2 left_inv := fun _ => funext fun _ => rfl right_inv := fun ⟨f, hf⟩ => Subtype.eq <\| funext fun i => Sigma.eq (hf i).symm <\| eq_of_heq <\| rec_heq_of_heq _ <\| by simp /-- The type of functions `f : ∀ a, β a` such that for all `a` we have `p a (f a)` is equivalent to the type of functions `∀ a, {b : β a // p a b}`. -/ def subtypePiEquivPi {β : α → Sort v} {p : ∀ a, β a → Prop} : { f : ∀ a, β a // ∀ a, p a (f a) } ≃ ∀ a, { b : β a // p a b } where toFun := fun f a => ⟨f.1 a, f.2 a⟩ invFun := fun f => ⟨fun a => (f a).1, fun a => (f a).2⟩ left_inv := by rintro ⟨f, h⟩ rfl right_inv := by rintro f funext a exact Subtype.ext_val rfl end section subtypeEquivCodomain variable {X Y : Sort} [DecidableEq X] {x : X} /-- The type of all functions `X → Y` with prescribed values for all `x' ≠ x` is equivalent to the codomain `Y`. -/ def subtypeEquivCodomain (f : { x' // x' ≠ x } → Y) : { g : X → Y // g ∘ (↑) = f } ≃ Y := (subtypePreimage _ f).trans <\| @funUnique { x' // ¬x' ≠ x } _ <\| show Unique { x' // ¬x' ≠ x } from @Equiv.unique _ _ (show Unique { x' // x' = x } from { default := ⟨x, rfl⟩, uniq := fun ⟨_, h⟩ => Subtype.val_injective h }) (subtypeEquivRight fun _ => not_not) @[simp] theorem coe_subtypeEquivCodomain (f : { x' // x' ≠ x } → Y) : (subtypeEquivCodomain f : _ → Y) = fun g : { g : X → Y // g ∘ (↑) = f } => (g : X → Y) x := rfl @[simp] theorem subtypeEquivCodomain_apply (f : { x' // x' ≠ x } → Y) (g) : subtypeEquivCodomain f g = (g : X → Y) x := rfl theorem coe_subtypeEquivCodomain_symm (f : { x' // x' ≠ x } → Y) : ((subtypeEquivCodomain f).symm : Y → _) = fun y => ⟨fun x' => if h : x' ≠ x then f ⟨x', h⟩ else y, by funext x' simp only [ne_eq, dite_not, comp_apply, Subtype.coe_eta, dite_eq_ite, ite_eq_right_iff] intro w exfalso exact x'.property w⟩ := rfl @[simp] theorem subtypeEquivCodomain_symm_apply (f : { x' // x' ≠ x } → Y) (y : Y) (x' : X) : ((subtypeEquivCodomain f).symm y : X → Y) x' = if h : x' ≠ x then f ⟨x', h⟩ else y := rfl theorem subtypeEquivCodomain_symm_apply_eq (f : { x' // x' ≠ x } → Y) (y : Y) : ((subtypeEquivCodomain f).symm y : X → Y) x = y := dif_neg (not_not.mpr rfl) theorem subtypeEquivCodomain_symm_apply_ne (f : { x' // x' ≠ x } → Y) (y : Y) (x' : X) (h : x' ≠ x) : ((subtypeEquivCodomain f).symm y : X → Y) x' = f ⟨x', h⟩ := dif_pos h end subtypeEquivCodomain instance : CanLift (α → β) (α ≃ β) (↑) Bijective where prf f hf := ⟨ofBijective f hf, rfl⟩ section variable {α' β' : Type} (e : Perm α') {p : β' → Prop} [DecidablePred p] (f : α' ≃ Subtype p) /-- Extend the domain of `e : Equiv.Perm α` to one that is over `β` via `f : α → Subtype p`, where `p : β → Prop`, permuting only the `b : β` that satisfy `p b`. This can be used to extend the domain across a function `f : α → β`, keeping everything outside of `Set.range f` fixed. For this use-case `Equiv` given by `f` can be constructed by `Equiv.of_leftInverse'` or `Equiv.of_leftInverse` when there is a known inverse, or `Equiv.ofInjective` in the general case. -/ def Perm.extendDomain : Perm β' := (permCongr f e).subtypeCongr (Equiv.refl _) @[simp] theorem Perm.extendDomain_apply_image (a : α') : e.extendDomain f (f a) = f (e a) := by simp [Perm.extendDomain] theorem Perm.extendDomain_apply_subtype {b : β'} (h : p b) : e.extendDomain f b = f (e (f.symm ⟨b, h⟩)) := by simp [Perm.extendDomain, h] theorem Perm.extendDomain_apply_not_subtype {b : β'} (h : ¬p b) : e.extendDomain f b = b := by simp [Perm.extendDomain, h] @[simp] theorem Perm.extendDomain_refl : Perm.extendDomain (Equiv.refl _) f = Equiv.refl _ := by simp [Perm.extendDomain] @[simp] theorem Perm.extendDomain_symm : (e.extendDomain f).symm = Perm.extendDomain e.symm f := rfl theorem Perm.extendDomain_trans (e e' : Perm α') : (e.extendDomain f).trans (e'.extendDomain f) = Perm.extendDomain (e.trans e') f := by simp [Perm.extendDomain, permCongr_trans] end /-- Subtype of the quotient is equivalent to the quotient of the subtype. Let `α` be a setoid with equivalence relation `~`. Let `p₂` be a predicate on the quotient type `α/~`, and `p₁` be the lift of this predicate to `α`: `p₁ a ↔ p₂ ⟦a⟧`. Let `~₂` be the restriction of `~` to `{x // p₁ x}`. Then `{x // p₂ x}` is equivalent to the quotient of `{x // p₁ x}` by `~₂`. -/ def subtypeQuotientEquivQuotientSubtype (p₁ : α → Prop) {s₁ : Setoid α} {s₂ : Setoid (Subtype p₁)} (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧) (h : ∀ x y : Subtype p₁, s₂.r x y ↔ s₁.r x y) : {x // p₂ x} ≃ Quotient s₂ where toFun a := Quotient.hrecOn a.1 (fun a h => ⟦⟨a, (hp₂ _).2 h⟩⟧) (fun a b hab => hfunext (by rw [Quotient.sound hab]) fun _ _ _ => heq_of_eq (Quotient.sound ((h _ _).2 hab))) a.2 invFun a := Quotient.liftOn a (fun a => (⟨⟦a.1⟧, (hp₂ _).1 a.2⟩ : { x // p₂ x })) fun _ _ hab => Subtype.ext_val (Quotient.sound ((h _ _).1 hab)) left_inv := by exact fun ⟨a, ha⟩ => Quotient.inductionOn a (fun b hb => rfl) ha right_inv a := by exact Quotient.inductionOn a fun ⟨a, ha⟩ => rfl @[simp] theorem subtypeQuotientEquivQuotientSubtype_mk (p₁ : α → Prop) [s₁ : Setoid α] [s₂ : Setoid (Subtype p₁)] (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧) (h : ∀ x y : Subtype p₁, s₂ x y ↔ (x : α) ≈ y) (x hx) : subtypeQuotientEquivQuotientSubtype p₁ p₂ hp₂ h ⟨⟦x⟧, hx⟩ = ⟦⟨x, (hp₂ _).2 hx⟩⟧ := rfl @[simp] theorem subtypeQuotientEquivQuotientSubtype_symm_mk (p₁ : α → Prop) [s₁ : Setoid α] [s₂ : Setoid (Subtype p₁)] (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧) (h : ∀ x y : Subtype p₁, s₂ x y ↔ (x : α) ≈ y) (x) : (subtypeQuotientEquivQuotientSubtype p₁ p₂ hp₂ h).symm ⟦x⟧ = ⟨⟦x⟧, (hp₂ _).1 x.property⟩ := rfl section Swap variable [DecidableEq α] /-- A helper function for `Equiv.swap`. -/ def swapCore (a b r : α) : α := if r = a then b else if r = b then a else r theorem swapCore_self (r a : α) : swapCore a a r = r := by unfold swapCore split_ifs <;> simp [] theorem swapCore_swapCore (r a b : α) : swapCore a b (swapCore a b r) = r := by unfold swapCore; split_ifs <;> cc theorem swapCore_comm (r a b : α) : swapCore a b r = swapCore b a r := by unfold swapCore; split_ifs <;> cc /-- `swap a b` is the permutation that swaps `a` and `b` and leaves other values as is. -/ def swap (a b : α) : Perm α := ⟨swapCore a b, swapCore a b, fun r => swapCore_swapCore r a b, fun r => swapCore_swapCore r a b⟩ @[simp] theorem swap_self (a : α) : swap a a = Equiv.refl _ := ext fun r => swapCore_self r a theorem swap_comm (a b : α) : swap a b = swap b a := ext fun r => swapCore_comm r _ _ theorem swap_apply_def (a b x : α) : swap a b x = if x = a then b else if x = b then a else x := rfl @[simp] theorem swap_apply_left (a b : α) : swap a b a = b := if_pos rfl @[simp] theorem swap_apply_right (a b : α) : swap a b b = a := by by_cases h : b = a <;> simp [swap_apply_def, h] theorem swap_apply_of_ne_of_ne {a b x : α} : x ≠ a → x ≠ b → swap a b x = x := by simp +contextual [swap_apply_def] theorem eq_or_eq_of_swap_apply_ne_self {a b x : α} (h : swap a b x ≠ x) : x = a ∨ x = b := by contrapose! h exact swap_apply_of_ne_of_ne h.1 h.2 @[simp] theorem swap_swap (a b : α) : (swap a b).trans (swap a b) = Equiv.refl _ := ext fun _ => swapCore_swapCore _ _ _ @[simp] theorem symm_swap (a b : α) : (swap a b).symm = swap a b := rfl @[simp] theorem swap_eq_refl_iff {x y : α} : swap x y = Equiv.refl _ ↔ x = y := by refine ⟨fun h => (Equiv.refl _).injective ?_, fun h => h ▸ swap_self _⟩ rw [← h, swap_apply_left, h, refl_apply] theorem swap_comp_apply {a b x : α} (π : Perm α) : π.trans (swap a b) x = if π x = a then b else if π x = b then a else π x := by cases π rfl theorem swap_eq_update (i j : α) : (Equiv.swap i j : α → α) = update (update id j i) i j := funext fun x => by rw [update_apply _ i j, update_apply _ j i, Equiv.swap_apply_def, id] theorem comp_swap_eq_update (i j : α) (f : α → β) : f ∘ Equiv.swap i j = update (update f j (f i)) i (f j) := by rw [swap_eq_update, comp_update, comp_update, comp_id] @[simp] theorem symm_trans_swap_trans [DecidableEq β] (a b : α) (e : α ≃ β) : (e.symm.trans (swap a b)).trans e = swap (e a) (e b) := Equiv.ext fun x => by have : ∀ a, e.symm x = a ↔ x = e a := fun a => by rw [@eq_comm _ (e.symm x)] constructor <;> intros <;> simp_all simp only [trans_apply, swap_apply_def, this] split_ifs <;> simp @[simp] theorem trans_swap_trans_symm [DecidableEq β] (a b : β) (e : α ≃ β) : (e.trans (swap a b)).trans e.symm = swap (e.symm a) (e.symm b) := symm_trans_swap_trans a b e.symm @[simp] theorem swap_apply_self (i j a : α) : swap i j (swap i j a) = a := by rw [← Equiv.trans_apply, Equiv.swap_swap, Equiv.refl_apply] /-- A function is invariant to a swap if it is equal at both elements -/ theorem apply_swap_eq_self {v : α → β} {i j : α} (hv : v i = v j) (k : α) : v (swap i j k) = v k := by by_cases hi : k = i · rw [hi, swap_apply_left, hv] by_cases hj : k = j · rw [hj, swap_apply_right, hv] rw [swap_apply_of_ne_of_ne hi hj] theorem swap_apply_eq_iff {x y z w : α} : swap x y z = w ↔ z = swap x y w := by rw [apply_eq_iff_eq_symm_apply, symm_swap] theorem swap_apply_ne_self_iff {a b x : α} : swap a b x ≠ x ↔ a ≠ b ∧ (x = a ∨ x = b) := by by_cases hab : a = b · simp [hab] by_cases hax : x = a · simp [hax, eq_comm] by_cases hbx : x = b · simp [hbx] simp [hab, hax, hbx, swap_apply_of_ne_of_ne] namespace Perm @[simp] theorem sumCongr_swap_refl {α β : Sort _} [DecidableEq α] [DecidableEq β] (i j : α) : Equiv.Perm.sumCongr (Equiv.swap i j) (Equiv.refl β) = Equiv.swap (Sum.inl i) (Sum.inl j) := by ext x cases x · simp only [Equiv.sumCongr_apply, Sum.map, coe_refl, comp_id, Sum.elim_inl, comp_apply, swap_apply_def, Sum.inl.injEq] split_ifs <;> rfl · simp [Sum.map, swap_apply_of_ne_of_ne] @[simp] theorem sumCongr_refl_swap {α β : Sort _} [DecidableEq α] [DecidableEq β] (i j : β) : Equiv.Perm.sumCongr (Equiv.refl α) (Equiv.swap i j) = Equiv.swap (Sum.inr i) (Sum.inr j) := by ext x cases x · simp [Sum.map, swap_apply_of_ne_of_ne] · simp only [Equiv.sumCongr_apply, Sum.map, coe_refl, comp_id, Sum.elim_inr, comp_apply, swap_apply_def, Sum.inr.injEq] split_ifs <;> rfl end Perm /-- Augment an equivalence with a prescribed mapping `f a = b` -/ def setValue (f : α ≃ β) (a : α) (b : β) : α ≃ β := (swap a (f.symm b)).trans f @[simp] theorem setValue_eq (f : α ≃ β) (a : α) (b : β) : setValue f a b a = b := by simp [setValue, swap_apply_left] end Swap end Equiv namespace Function.Involutive /-- Convert an involutive function `f` to a permutation with `toFun = invFun = f`. -/ def toPerm (f : α → α) (h : Involutive f) : Equiv.Perm α := ⟨f, f, h.leftInverse, h.rightInverse⟩ @[simp] theorem coe_toPerm {f : α → α} (h : Involutive f) : (h.toPerm f : α → α) = f := rfl @[simp] theorem toPerm_symm {f : α → α} (h : Involutive f) : (h.toPerm f).symm = h.toPerm f := rfl theorem toPerm_involutive {f : α → α} (h : Involutive f) : Involutive (h.toPerm f) := h theorem symm_eq_self_of_involutive (f : Equiv.Perm α) (h : Involutive f) : f.symm = f := DFunLike.coe_injective (h.leftInverse_iff.mp f.left_inv) end Function.Involutive theorem PLift.eq_up_iff_down_eq {x : PLift α} {y : α} : x = PLift.up y ↔ x.down = y := Equiv.plift.eq_symm_apply theorem Function.Injective.map_swap [DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y z : α) : f (Equiv.swap x y z) = Equiv.swap (f x) (f y) (f z) := by conv_rhs => rw [Equiv.swap_apply_def] split_ifs with h₁ h₂ · rw [hf h₁, Equiv.swap_apply_left] · rw [hf h₂, Equiv.swap_apply_right] · rw [Equiv.swap_apply_of_ne_of_ne (mt (congr_arg f) h₁) (mt (congr_arg f) h₂)] namespace Equiv section /-- Transport dependent functions through an equivalence of the base space. -/ @[simps apply, simps -isSimp symm_apply] def piCongrLeft' (P : α → Sort) (e : α ≃ β) : (∀ a, P a) ≃ ∀ b, P (e.symm b) where toFun f x := f (e.symm x) invFun f x := (e.symm_apply_apply x).ndrec (f (e x)) left_inv f := funext fun x => (by rintro _ rfl; rfl : ∀ {y} (h : y = x), h.ndrec (f y) = f x) (e.symm_apply_apply x) right_inv f := funext fun x => (by rintro _ rfl; rfl : ∀ {y} (h : y = x), (congr_arg e.symm h).ndrec (f y) = f x) (e.apply_symm_apply x) /-- Note: the "obvious" statement `(piCongrLeft' P e).symm g a = g (e a)` doesn't typecheck: the LHS would have type `P a` while the RHS would have type `P (e.symm (e a))`. For that reason, we have to explicitly substitute along `e.symm (e a) = a` in the statement of this lemma. -/ add_decl_doc Equiv.piCongrLeft'_symm_apply /-- This lemma is impractical to state in the dependent case. -/ @[simp] theorem piCongrLeft'_symm (P : Sort) (e : α ≃ β) : (piCongrLeft' (fun _ => P) e).symm = piCongrLeft' _ e.symm := by ext; simp [piCongrLeft'] /-- Note: the "obvious" statement `(piCongrLeft' P e).symm g a = g (e a)` doesn't typecheck: the LHS would have type `P a` while the RHS would have type `P (e.symm (e a))`. This lemma is a way around it in the case where `a` is of the form `e.symm b`, so we can use `g b` instead of `g (e (e.symm b))`. -/ @[simp] lemma piCongrLeft'_symm_apply_apply (P : α → Sort) (e : α ≃ β) (g : ∀ b, P (e.symm b)) (b : β) : (piCongrLeft' P e).symm g (e.symm b) = g b := by rw [piCongrLeft'_symm_apply, ← heq_iff_eq, rec_heq_iff_heq] exact congr_arg_heq _ (e.apply_symm_apply _) end section variable (P : β → Sort w) (e : α ≃ β) /-- Transporting dependent functions through an equivalence of the base, expressed as a "simplification". -/ def piCongrLeft : (∀ a, P (e a)) ≃ ∀ b, P b := (piCongrLeft' P e.symm).symm /-- Note: the "obvious" statement `(piCongrLeft P e) f b = f (e.symm b)` doesn't typecheck: the LHS would have type `P b` while the RHS would have type `P (e (e.symm b))`. For that reason, we have to explicitly substitute along `e (e.symm b) = b` in the statement of this lemma. -/ @[simp] lemma piCongrLeft_apply (f : ∀ a, P (e a)) (b : β) : (piCongrLeft P e) f b = e.apply_symm_apply b ▸ f (e.symm b) := rfl @[simp] lemma piCongrLeft_symm_apply (g : ∀ b, P b) (a : α) : (piCongrLeft P e).symm g a = g (e a) := piCongrLeft'_apply P e.symm g a /-- Note: the "obvious" statement `(piCongrLeft P e) f b = f (e.symm b)` doesn't typecheck: the LHS would have type `P b` while the RHS would have type `P (e (e.symm b))`. This lemma is a way around it in the case where `b` is of the form `e a`, so we can use `f a` instead of `f (e.symm (e a))`. -/ lemma piCongrLeft_apply_apply (f : ∀ a, P (e a)) (a : α) : (piCongrLeft P e) f (e a) = f a := piCongrLeft'_symm_apply_apply P e.symm f a open Sum lemma piCongrLeft_apply_eq_cast {P : β → Sort v} {e : α ≃ β} (f : (a : α) → P (e a)) (b : β) : piCongrLeft P e f b = cast (congr_arg P (e.apply_symm_apply b)) (f (e.symm b)) := Eq.rec_eq_cast _ _ theorem piCongrLeft_sumInl {ι ι' ι''} (π : ι'' → Type) (e : ι ⊕ ι' ≃ ι'') (f : ∀ i, π (e (inl i))) (g : ∀ i, π (e (inr i))) (i : ι) : piCongrLeft π e (sumPiEquivProdPi (fun x => π (e x)) \|>.symm (f, g)) (e (inl i)) = f i := by simp_rw [piCongrLeft_apply_eq_cast, sumPiEquivProdPi_symm_apply, sum_rec_congr _ _ _ (e.symm_apply_apply (inl i)), cast_cast, cast_eq] theorem piCongrLeft_sumInr {ι ι' ι''} (π : ι'' → Type) (e : ι ⊕ ι' ≃ ι'') (f : ∀ i, π (e (inl i))) (g : ∀ i, π (e (inr i))) (j : ι') : piCongrLeft π e (sumPiEquivProdPi (fun x => π (e x)) \|>.symm (f, g)) (e (inr j)) = g j := by simp_rw [piCongrLeft_apply_eq_cast, sumPiEquivProdPi_symm_apply, sum_rec_congr _ _ _ (e.symm_apply_apply (inr j)), cast_cast, cast_eq] @[deprecated (since := "2025-02-21")] alias piCongrLeft_sum_inl := piCongrLeft_sumInl @[deprecated (since := "2025-02-21")] alias piCongrLeft_sum_inr := piCongrLeft_sumInr end section variable {W : α → Sort w} {Z : β → Sort z} (h₁ : α ≃ β) (h₂ : ∀ a : α, W a ≃ Z (h₁ a)) /-- Transport dependent functions through an equivalence of the base spaces and a family of equivalences of the matching fibers. -/ def piCongr : (∀ a, W a) ≃ ∀ b, Z b := (Equiv.piCongrRight h₂).trans (Equiv.piCongrLeft _ h₁) @[simp] theorem coe_piCongr_symm : ((h₁.piCongr h₂).symm : (∀ b, Z b) → ∀ a, W a) = fun f a => (h₂ a).symm (f (h₁ a)) := rfl theorem piCongr_symm_apply (f : ∀ b, Z b) : (h₁.piCongr h₂).symm f = fun a => (h₂ a).symm (f (h₁ a)) := rfl @[simp] theorem piCongr_apply_apply (f : ∀ a, W a) (a : α) : h₁.piCongr h₂ f (h₁ a) = h₂ a (f a) := by simp only [piCongr, piCongrRight, trans_apply, coe_fn_mk, piCongrLeft_apply_apply, Pi.map_apply] end section variable {W : α → Sort w} {Z : β → Sort z} (h₁ : α ≃ β) (h₂ : ∀ b : β, W (h₁.symm b) ≃ Z b) /-- Transport dependent functions through an equivalence of the base spaces and a family of equivalences of the matching fibres. -/ def piCongr' : (∀ a, W a) ≃ ∀ b, Z b := (piCongr h₁.symm fun b => (h₂ b).symm).symm @[simp] theorem coe_piCongr' : (h₁.piCongr' h₂ : (∀ a, W a) → ∀ b, Z b) = fun f b => h₂ b <\| f <\| h₁.symm b := rfl theorem piCongr'_apply (f : ∀ a, W a) : h₁.piCongr' h₂ f = fun b => h₂ b <\| f <\| h₁.symm b := rfl @[simp] theorem piCongr'_symm_apply_symm_apply (f : ∀ b, Z b) (b : β) : (h₁.piCongr' h₂).symm f (h₁.symm b) = (h₂ b).symm (f b) := by simp [piCongr', piCongr_apply_apply] end /-- Transport dependent functions through an equality of sets. -/ @[simps!] def piCongrSet {α} {W : α → Sort w} {s t : Set α} (h : s = t) : (∀ i : {i // i ∈ s}, W i) ≃ (∀ i : {i // i ∈ t}, W i) where toFun f i := f ⟨i, h ▸ i.2⟩ invFun f i := f ⟨i, h.symm ▸ i.2⟩ left_inv f := rfl right_inv f := rfl section BinaryOp variable {α₁ β₁ : Type} (e : α₁ ≃ β₁) (f : α₁ → α₁ → α₁) theorem semiconj_conj (f : α₁ → α₁) : Semiconj e f (e.conj f) := fun x => by simp theorem semiconj₂_conj : Semiconj₂ e f (e.arrowCongr e.conj f) := fun x y => by simp [arrowCongr] instance [Std.Associative f] : Std.Associative (e.arrowCongr (e.arrowCongr e) f) := (e.semiconj₂_conj f).isAssociative_right e.surjective instance [Std.IdempotentOp f] : Std.IdempotentOp (e.arrowCongr (e.arrowCongr e) f) := (e.semiconj₂_conj f).isIdempotent_right e.surjective end BinaryOp section ULift @[simp] theorem ulift_symm_down {α} (x : α) : (Equiv.ulift.{u, v}.symm x).down = x := rfl end ULift end Equiv theorem Function.Injective.swap_apply [DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y z : α) : Equiv.swap (f x) (f y) (f z) = f (Equiv.swap x y z) := by by_cases hx : z = x · simp [hx] by_cases hy : z = y · simp [hy] rw [Equiv.swap_apply_of_ne_of_ne hx hy, Equiv.swap_apply_of_ne_of_ne (hf.ne hx) (hf.ne hy)] theorem Function.Injective.swap_comp [DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y : α) : Equiv.swap (f x) (f y) ∘ f = f ∘ Equiv.swap x y := funext fun _ => hf.swap_apply _ _ _ /-- To give an equivalence between two subsingleton types, it is sufficient to give any two functions between them. -/ def equivOfSubsingletonOfSubsingleton [Subsingleton α] [Subsingleton β] (f : α → β) (g : β → α) : α ≃ β where toFun := f invFun := g left_inv _ := Subsingleton.elim _ _ right_inv _ := Subsingleton.elim _ _ /-- A nonempty subsingleton type is (noncomputably) equivalent to `PUnit`. -/ noncomputable def Equiv.punitOfNonemptyOfSubsingleton [h : Nonempty α] [Subsingleton α] : α ≃ PUnit := equivOfSubsingletonOfSubsingleton (fun _ => PUnit.unit) fun _ => h.some /-- `Unique (Unique α)` is equivalent to `Unique α`. -/ def uniqueUniqueEquiv : Unique (Unique α) ≃ Unique α := equivOfSubsingletonOfSubsingleton (fun h => h.default) fun h => { default := h, uniq := fun _ => Subsingleton.elim _ _ } /-- If `Unique β`, then `Unique α` is equivalent to `α ≃ β`. -/ def uniqueEquivEquivUnique (α : Sort u) (β : Sort v) [Unique β] : Unique α ≃ (α ≃ β) := equivOfSubsingletonOfSubsingleton (fun _ => Equiv.ofUnique _ _) Equiv.unique namespace Function variable {α' : Sort} theorem update_comp_equiv [DecidableEq α'] [DecidableEq α] (f : α → β) (g : α' ≃ α) (a : α) (v : β) : update f a v ∘ g = update (f ∘ g) (g.symm a) v := by rw [← update_comp_eq_of_injective _ g.injective, g.apply_symm_apply] theorem update_apply_equiv_apply [DecidableEq α'] [DecidableEq α] (f : α → β) (g : α' ≃ α) (a : α) (v : β) (a' : α') : update f a v (g a') = update (f ∘ g) (g.symm a) v a' := congr_fun (update_comp_equiv f g a v) a' theorem piCongrLeft'_update [DecidableEq α] [DecidableEq β] (P : α → Sort) (e : α ≃ β) (f : ∀ a, P a) (b : β) (x : P (e.symm b)) : e.piCongrLeft' P (update f (e.symm b) x) = update (e.piCongrLeft' P f) b x := by ext b' rcases eq_or_ne b' b with (rfl \| h) <;> simp_all theorem piCongrLeft'_symm_update [DecidableEq α] [DecidableEq β] (P : α → Sort*) (e : α ≃ β) (f : ∀ b, P (e.symm b)) (b : β) (x : P (e.symm b)) : (e.piCongrLeft' P).symm (update f b x) = update ((e.piCongrLeft' P).symm f) (e.symm b) x := by simp [(e.piCongrLeft' P).symm_apply_eq, piCongrLeft'_update] end Function		Mathlib/Logic/Equiv/Basic.lean	1,847	1,848
/- Copyright (c) 2024 Mitchell Lee. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mitchell Lee, Junyan Xu -/ import Mathlib.LinearAlgebra.TensorProduct.RightExactness import Mathlib.LinearAlgebra.TensorProduct.Finiteness import Mathlib.LinearAlgebra.DirectSum.Finsupp /-! # Vanishing of elements in a tensor product of two modules Let $M$ and $N$ be modules over a commutative ring $R$. Recall that every element of $M \otimes N$ can be written as a finite sum $\sum_{i} m_i \otimes n_i$ of pure tensors (`TensorProduct.exists_finset`). We would like to determine under what circumstances such an expression vanishes. Let us say that an expression $\sum_{i \in \iota} m_i \otimes n_i$ in $M \otimes N$ vanishes trivially (`TensorProduct.VanishesTrivially`) if there exist a finite index type $\kappa$ = `Fin k`, elements $(y_j)_{j \in \kappa}$ of $N$, and elements $(a_{ij})_{i \in \iota, j \in \kappa}$ of $R$ such that for all $i$, $$n_i = \sum_j a_{ij} y_j$$ and for all $j$, $$\sum_i a_{ij} m_i = 0.$$ (The terminology "trivial" comes from [Stacks 00HK](https://stacks.math.columbia.edu/tag/00HK).) It is not difficult to show (`TensorProduct.sum_tmul_eq_zero_of_vanishesTrivially`) that if $\sum_i m_i \otimes n_i$ vanishes trivially, then it vanishes; that is, $\sum_i m_i \otimes n_i = 0$. The equational criterion for vanishing (`TensorProduct.vanishesTrivially_iff_sum_tmul_eq_zero`), which appears as [A. Altman and S. Kleiman, A term of commutative algebra (Lemma 8.16)][altman2021term], states that if the elements $m_i$ generate the module $M$, then $\sum_i m_i \otimes n_i = 0$ if and only if the expression $\sum_i m_i \otimes n_i$ vanishes trivially. We also prove the following generalization (`TensorProduct.vanishesTrivially_iff_sum_tmul_eq_zero_of_rTensor_injective`). If the submodule $M' \subseteq M$ generated by the $m_i$ satisfies the property that the induced map $M' \otimes N \to M \otimes N$ is injective, then $\sum_i m_i \otimes n_i = 0$ if and only if the expression $\sum_i m_i \otimes n_i$ vanishes trivially. (In the case that $M = R$, this yields the equational criterion for flatness `Module.Flat.iff_forall_isTrivialRelation`.) Conversely (`TensorProduct.rTensor_injective_of_forall_vanishesTrivially`), suppose that for every equation $\sum_i m_i \otimes n_i = 0$, the expression $\sum_i m_i \otimes n_i$ vanishes trivially. Then the induced map $M' \otimes N \to M \otimes N$ is injective for every submodule $M' \subseteq M$. ## References * [A. Altman and S. Kleiman, A term of commutative algebra (Lemma 8.16)][altman2021term] ## TODO * Prove the same theorems with $M$ and $N$ swapped. -/ variable (R : Type) [CommRing R] variable {M : Type} [AddCommGroup M] [Module R M] variable {N : Type} [AddCommGroup N] [Module R N] open DirectSum LinearMap Function Submodule Finsupp namespace TensorProduct variable {ι : Type} [Fintype ι] {m : ι → M} {n : ι → N} variable (m n) in /-- An expression $\sum_i m_i \otimes n_i$ in $M \otimes N$ vanishes trivially if there exist a finite index type $\kappa$ = `Fin k`, elements $(y_j)_{j \in \kappa}$ of $N$, and elements $(a_{ij})_{i \in \iota, j \in \kappa}$ of $R$ such that for all $i$, $$n_i = \sum_j a_{ij} y_j$$ and for all $j$, $$\sum_i a_{ij} m_i = 0.$$ Note that this condition is not symmetric in $M$ and $N$. (The terminology "trivial" comes from [Stacks 00HK](https://stacks.math.columbia.edu/tag/00HK).) -/ abbrev VanishesTrivially : Prop := ∃ (k : ℕ) (a : ι → Fin k → R) (y : Fin k → N), (∀ i, n i = ∑ j, a i j • y j) ∧ ∀ j, ∑ i, a i j • m i = 0 variable {R} theorem VanishesTrivially.of_fintype {κ} [Fintype κ] (a : ι → κ → R) (y : κ → N) (hay : ∀ i, n i = ∑ j, a i j • y j) (ham : ∀ j, ∑ i, a i j • m i = 0) : VanishesTrivially R m n := have e := (Fintype.equivFin κ).symm ⟨Fintype.card κ, (a · ∘ e), y ∘ e, by simpa only [← e.sum_comp] using hay, by rwa [← e.forall_congr_right] at ham⟩ theorem _root_.Equiv.vanishesTrivially_comp {κ} [Fintype κ] (e : κ ≃ ι) : VanishesTrivially R (m ∘ e) (n ∘ e) ↔ VanishesTrivially R m n := by simp [VanishesTrivially, ← e.forall_congr_right, ← (e.arrowCongr (.refl _)).exists_congr_right, ← e.sum_comp] variable (R) /-- Equational criterion for vanishing [A. Altman and S. Kleiman, A term of commutative algebra (Lemma 8.16)][altman2021term], backward direction. If the expression $\sum_i m_i \otimes n_i$ vanishes trivially, then it vanishes. That is, $\sum_i m_i \otimes n_i = 0$. -/ theorem sum_tmul_eq_zero_of_vanishesTrivially (hmn : VanishesTrivially R m n) : ∑ i, m i ⊗ₜ n i = (0 : M ⊗[R] N) := by obtain ⟨k, a, y, h₁, h₂⟩ := hmn simp_rw [h₁, tmul_sum, tmul_smul] rw [Finset.sum_comm] simp_rw [← tmul_smul, ← smul_tmul, ← sum_tmul, h₂, zero_tmul, Finset.sum_const_zero] /-- Equational criterion for vanishing [A. Altman and S. Kleiman, A term of commutative algebra (Lemma 8.16)][altman2021term], forward direction. Assume that the $m_i$ generate $M$. If the expression $\sum_i m_i \otimes n_i$ vanishes, then it vanishes trivially. -/ theorem vanishesTrivially_of_sum_tmul_eq_zero (hm : Submodule.span R (Set.range m) = ⊤) (hmn : ∑ i, m i ⊗ₜ n i = (0 : M ⊗[R] N)) : VanishesTrivially R m n := by -- Define a map $G \colon R^\iota \to M$ whose matrix entries are the $m_i$. It is surjective. set G : (ι →₀ R) →ₗ[R] M := Finsupp.linearCombination R m with hG have G_basis_eq (i : ι) : G (Finsupp.single i 1) = m i := by simp [hG, toModule_lof] have G_surjective : Surjective G := by apply LinearMap.range_eq_top.mp apply top_le_iff.mp rw [← hm] apply Submodule.span_le.mpr rintro _ ⟨i, rfl⟩ use Finsupp.single i 1, G_basis_eq i /- Consider the element $\sum_i e_i \otimes n_i$ of $R^\iota \otimes N$. It is in the kernel of $R^\iota \otimes N \to M \otimes N$. -/ set en : (ι →₀ R) ⊗[R] N := ∑ i, Finsupp.single i 1 ⊗ₜ n i with hen have en_mem_ker : en ∈ ker (rTensor N G) := by simp [hen, G_basis_eq, hmn] -- We have an exact sequence $\ker G \to R^\iota \to M \to 0$. have exact_ker_subtype : Exact (ker G).subtype G := G.exact_subtype_ker_map -- Tensor the exact sequence with $N$. have exact_rTensor_ker_subtype : Exact (rTensor N (ker G).subtype) (rTensor N G) := rTensor_exact (M := ↥(ker G)) N exact_ker_subtype G_surjective /- We conclude that $\sum_i e_i \otimes n_i$ is in the range of $\ker G \otimes N \to R^\iota \otimes N$. -/ have en_mem_range : en ∈ range (rTensor N (ker G).subtype) := exact_rTensor_ker_subtype.linearMap_ker_eq ▸ en_mem_ker /- There is an element of in $\ker G \otimes N$ that maps to $\sum_i e_i \otimes n_i$. Write it as a finite sum of pure tensors. -/ obtain ⟨kn, hkn⟩ := en_mem_range obtain ⟨ma, rfl : kn = ∑ kj ∈ ma, kj.1 ⊗ₜ[R] kj.2⟩ := exists_finset kn /- Let $\sum_j k_j \otimes y_j$ be the sum obtained in the previous step. In order to show that $\sum_i m_i \otimes n_i$ vanishes trivially, it suffices to prove that there exist $(a_{ij})_{i, j}$ such that for all $i$, $$n_i = \sum_j a_{ij} y_j$$ and for all $j$, $$\sum_i a_{ij} m_i = 0.$$ For this, take $a_{ij}$ to be the coefficient of $e_i$ in $k_j$. -/ refine .of_fintype (κ := ma) (fun i ⟨⟨kj, _⟩, _⟩ ↦ (kj : ι →₀ R) i) (fun ⟨⟨_, yj⟩, _⟩ ↦ yj) ?_ ?_ · intro i classical apply_fun finsuppScalarLeft R N ι at hkn apply_fun (· i) at hkn symm at hkn simp only [map_sum, finsuppScalarLeft_apply_tmul, zero_smul, Finsupp.single_zero, Finsupp.sum_single_index, one_smul, Finsupp.finset_sum_apply, Finsupp.single_apply, Finset.sum_ite_eq', Finset.mem_univ, ↓reduceIte, rTensor_tmul, coe_subtype, Finsupp.sum_apply, Finsupp.sum_ite_eq', Finsupp.mem_support_iff, ne_eq, ite_not, en] at hkn simp only [Finset.univ_eq_attach, Finset.sum_attach ma (fun x ↦ (x.1 : ι →₀ R) i • x.2)] convert hkn using 2 with x _ split · next h'x => rw [h'x, zero_smul] · rfl · rintro ⟨⟨⟨k, hk⟩, _⟩, _⟩ simpa only [hG, linearCombination_apply, zero_smul, implies_true, Finsupp.sum_fintype] using mem_ker.mp hk /-- Equational criterion for vanishing [A. Altman and S. Kleiman, A term of commutative algebra (Lemma 8.16)][altman2021term]. Assume that the $m_i$ generate $M$. Then the expression $\sum_i m_i \otimes n_i$ vanishes trivially if and only if it vanishes. -/ theorem vanishesTrivially_iff_sum_tmul_eq_zero (hm : Submodule.span R (Set.range m) = ⊤) : VanishesTrivially R m n ↔ ∑ i, m i ⊗ₜ n i = (0 : M ⊗[R] N) := ⟨sum_tmul_eq_zero_of_vanishesTrivially R, vanishesTrivially_of_sum_tmul_eq_zero R hm⟩ /-- Equational criterion for vanishing [A. Altman and S. Kleiman, A term of commutative algebra (Lemma 8.16)][altman2021term], forward direction, generalization. Assume that the submodule $M' \subseteq M$ generated by the $m_i$ satisfies the property that the map $M' \otimes N \to M \otimes N$ is injective. If the expression $\sum_i m_i \otimes n_i$ vanishes, then it vanishes trivially. -/ theorem vanishesTrivially_of_sum_tmul_eq_zero_of_rTensor_injective (hm : Injective (rTensor N (span R (Set.range m)).subtype)) (hmn : ∑ i, m i ⊗ₜ n i = (0 : M ⊗[R] N)) : VanishesTrivially R m n := by -- Restrict `m` on the codomain to $M'$, then apply `vanishesTrivially_of_sum_tmul_eq_zero`. have mem_M' i : m i ∈ span R (Set.range m) := subset_span ⟨i, rfl⟩ set m' : ι → span R (Set.range m) := Subtype.coind m mem_M' with m'_eq have hm' : span R (Set.range m') = ⊤ := by apply map_injective_of_injective (injective_subtype (span R (Set.range m))) rw [Submodule.map_span, Submodule.map_top, range_subtype, coe_subtype, ← Set.range_comp] rfl have hm'n : ∑ i, m' i ⊗ₜ n i = (0 : span R (Set.range m) ⊗[R] N) := by apply hm simp only [m'_eq, map_sum, rTensor_tmul, coe_subtype, Subtype.coind_coe, map_zero, hmn] have : VanishesTrivially R m' n := vanishesTrivially_of_sum_tmul_eq_zero R hm' hm'n unfold VanishesTrivially at this ⊢ convert this with κ _ a y j convert (injective_iff_map_eq_zero' _).mp (injective_subtype (span R (Set.range m))) _ simp [m'_eq] /-- Equational criterion for vanishing [A. Altman and S. Kleiman, A term of commutative algebra (Lemma 8.16)][altman2021term], generalization. Assume that the submodule $M' \subseteq M$ generated by the $m_i$ satisfies the	property that the map $M' \otimes N \to M \otimes N$ is injective. Then the expression $\sum_i m_i \otimes n_i$ vanishes trivially if and only if it vanishes. -/ theorem vanishesTrivially_iff_sum_tmul_eq_zero_of_rTensor_injective (hm : Injective (rTensor N (span R (Set.range m)).subtype)) : VanishesTrivially R m n ↔ ∑ i, m i ⊗ₜ n i = (0 : M ⊗[R] N) := ⟨sum_tmul_eq_zero_of_vanishesTrivially R, vanishesTrivially_of_sum_tmul_eq_zero_of_rTensor_injective R hm⟩ /-- Converse of `TensorProduct.vanishesTrivially_of_sum_tmul_eq_zero_of_rTensor_injective`. Assume that every expression $\sum_i m_i \otimes n_i$ which vanishes also vanishes trivially. Then, for every submodule $M' \subseteq M$, the map $M' \otimes N \to M \otimes N$ is injective. -/ theorem rTensor_injective_of_forall_vanishesTrivially (hMN : ∀ {l : ℕ} {m : Fin l → M} {n : Fin l → N}, ∑ i, m i ⊗ₜ n i = (0 : M ⊗[R] N) → VanishesTrivially R m n) (M' : Submodule R M) : Injective (rTensor N M'.subtype) := by	Mathlib/LinearAlgebra/TensorProduct/Vanishing.lean	211	226
/- Copyright (c) 2018 Simon Hudon. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Simon Hudon -/ import Mathlib.Control.Applicative import Mathlib.Control.Traversable.Basic import Mathlib.Data.List.Forall2 import Mathlib.Data.Set.Functor /-! # LawfulTraversable instances This file provides instances of `LawfulTraversable` for types from the core library: `Option`, `List` and `Sum`. -/ universe u v section Option open Functor variable {F G : Type u → Type u} variable [Applicative F] [Applicative G] variable [LawfulApplicative G] theorem Option.id_traverse {α} (x : Option α) : Option.traverse (pure : α → Id α) x = x := by cases x <;> rfl theorem Option.comp_traverse {α β γ} (f : β → F γ) (g : α → G β) (x : Option α) : Option.traverse (Comp.mk ∘ (f <$> ·) ∘ g) x = Comp.mk (Option.traverse f <$> Option.traverse g x) := by cases x <;> (simp! [functor_norm] <;> rfl) theorem Option.traverse_eq_map_id {α β} (f : α → β) (x : Option α) : Option.traverse ((pure : _ → Id _) ∘ f) x = (pure : _ → Id _) (f <$> x) := by cases x <;> rfl variable (η : ApplicativeTransformation F G) theorem Option.naturality [LawfulApplicative F] {α β} (f : α → F β) (x : Option α) : η (Option.traverse f x) = Option.traverse (@η _ ∘ f) x := by -- Porting note: added `ApplicativeTransformation` theorems rcases x with - \| x <;> simp! [, functor_norm, ApplicativeTransformation.preserves_map, ApplicativeTransformation.preserves_seq, ApplicativeTransformation.preserves_pure] end Option instance : LawfulTraversable Option := { show LawfulMonad Option from inferInstance with id_traverse := Option.id_traverse comp_traverse := Option.comp_traverse traverse_eq_map_id := Option.traverse_eq_map_id naturality := fun η _ _ f x => Option.naturality η f x } namespace List variable {F G : Type u → Type u} variable [Applicative F] [Applicative G] section variable [LawfulApplicative G] open Applicative Functor List protected theorem id_traverse {α} (xs : List α) : List.traverse (pure : α → Id α) xs = xs := by induction xs <;> simp! [, List.traverse, functor_norm]; rfl protected theorem comp_traverse {α β γ} (f : β → F γ) (g : α → G β) (x : List α) : List.traverse (Comp.mk ∘ (f <$> ·) ∘ g) x = Comp.mk (List.traverse f <$> List.traverse g x) := by	induction x <;> simp! [*, functor_norm] <;> rfl	Mathlib/Control/Traversable/Instances.lean	74	75
/- Copyright (c) 2018 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau -/ import Mathlib.Algebra.Group.Subgroup.Ker import Mathlib.Algebra.BigOperators.Group.List.Basic /-! # Free groups This file defines free groups over a type. Furthermore, it is shown that the free group construction is an instance of a monad. For the result that `FreeGroup` is the left adjoint to the forgetful functor from groups to types, see `Mathlib/Algebra/Category/Grp/Adjunctions.lean`. ## Main definitions * `FreeGroup`/`FreeAddGroup`: the free group (resp. free additive group) associated to a type `α` defined as the words over `a : α × Bool` modulo the relation `a * x * x⁻¹ * b = a * b`. * `FreeGroup.mk`/`FreeAddGroup.mk`: the canonical quotient map `List (α × Bool) → FreeGroup α`. * `FreeGroup.of`/`FreeAddGroup.of`: the canonical injection `α → FreeGroup α`. * `FreeGroup.lift f`/`FreeAddGroup.lift`: the canonical group homomorphism `FreeGroup α →* G` given a group `G` and a function `f : α → G`. ## Main statements * `FreeGroup.Red.church_rosser`/`FreeAddGroup.Red.church_rosser`: The Church-Rosser theorem for word reduction (also known as Newman's diamond lemma). * `FreeGroup.freeGroupUnitEquivInt`: The free group over the one-point type is isomorphic to the integers. * The free group construction is an instance of a monad. ## Implementation details First we introduce the one step reduction relation `FreeGroup.Red.Step`: `w * x * x⁻¹ * v ~> w * v`, its reflexive transitive closure `FreeGroup.Red.trans` and prove that its join is an equivalence relation. Then we introduce `FreeGroup α` as a quotient over `FreeGroup.Red.Step`. For the additive version we introduce the same relation under a different name so that we can distinguish the quotient types more easily. ## Tags free group, Newman's diamond lemma, Church-Rosser theorem -/ open Relation open scoped List universe u v w variable {α : Type u} attribute [local simp] List.append_eq_has_append -- Porting note: to_additive.map_namespace is not supported yet -- worked around it by putting a few extra manual mappings (but not too many all in all) -- run_cmd to_additive.map_namespace `FreeGroup `FreeAddGroup /-- Reduction step for the additive free group relation: `w + x + (-x) + v ~> w + v` -/ inductive FreeAddGroup.Red.Step : List (α × Bool) → List (α × Bool) → Prop \| not {L₁ L₂ x b} : FreeAddGroup.Red.Step (L₁ ++ (x, b) :: (x, not b) :: L₂) (L₁ ++ L₂) attribute [simp] FreeAddGroup.Red.Step.not /-- Reduction step for the multiplicative free group relation: `w * x * x⁻¹ * v ~> w * v` -/ @[to_additive FreeAddGroup.Red.Step] inductive FreeGroup.Red.Step : List (α × Bool) → List (α × Bool) → Prop \| not {L₁ L₂ x b} : FreeGroup.Red.Step (L₁ ++ (x, b) :: (x, not b) :: L₂) (L₁ ++ L₂) attribute [simp] FreeGroup.Red.Step.not namespace FreeGroup variable {L L₁ L₂ L₃ L₄ : List (α × Bool)} /-- Reflexive-transitive closure of `Red.Step` -/ @[to_additive FreeAddGroup.Red "Reflexive-transitive closure of `Red.Step`"] def Red : List (α × Bool) → List (α × Bool) → Prop := ReflTransGen Red.Step @[to_additive (attr := refl)] theorem Red.refl : Red L L := ReflTransGen.refl @[to_additive (attr := trans)] theorem Red.trans : Red L₁ L₂ → Red L₂ L₃ → Red L₁ L₃ := ReflTransGen.trans namespace Red /-- Predicate asserting that the word `w₁` can be reduced to `w₂` in one step, i.e. there are words `w₃ w₄` and letter `x` such that `w₁ = w₃xx⁻¹w₄` and `w₂ = w₃w₄` -/ @[to_additive "Predicate asserting that the word `w₁` can be reduced to `w₂` in one step, i.e. there are words `w₃ w₄` and letter `x` such that `w₁ = w₃ + x + (-x) + w₄` and `w₂ = w₃w₄`"] theorem Step.length : ∀ {L₁ L₂ : List (α × Bool)}, Step L₁ L₂ → L₂.length + 2 = L₁.length \| _, _, @Red.Step.not _ L1 L2 x b => by rw [List.length_append, List.length_append]; rfl @[to_additive (attr := simp)] theorem Step.not_rev {x b} : Step (L₁ ++ (x, !b) :: (x, b) :: L₂) (L₁ ++ L₂) := by cases b <;> exact Step.not @[to_additive (attr := simp)] theorem Step.cons_not {x b} : Red.Step ((x, b) :: (x, !b) :: L) L := @Step.not _ [] _ _ _ @[to_additive (attr := simp)] theorem Step.cons_not_rev {x b} : Red.Step ((x, !b) :: (x, b) :: L) L := @Red.Step.not_rev _ [] _ _ _ @[to_additive] theorem Step.append_left : ∀ {L₁ L₂ L₃ : List (α × Bool)}, Step L₂ L₃ → Step (L₁ ++ L₂) (L₁ ++ L₃) \| _, _, _, Red.Step.not => by rw [← List.append_assoc, ← List.append_assoc]; constructor @[to_additive] theorem Step.cons {x} (H : Red.Step L₁ L₂) : Red.Step (x :: L₁) (x :: L₂) := @Step.append_left _ [x] _ _ H @[to_additive] theorem Step.append_right : ∀ {L₁ L₂ L₃ : List (α × Bool)}, Step L₁ L₂ → Step (L₁ ++ L₃) (L₂ ++ L₃) \| _, _, _, Red.Step.not => by simp @[to_additive] theorem not_step_nil : ¬Step [] L := by generalize h' : [] = L' intro h rcases h with - \| ⟨L₁, L₂⟩ simp [List.nil_eq_append_iff] at h' @[to_additive] theorem Step.cons_left_iff {a : α} {b : Bool} : Step ((a, b) :: L₁) L₂ ↔ (∃ L, Step L₁ L ∧ L₂ = (a, b) :: L) ∨ L₁ = (a, ! b) :: L₂ := by constructor · generalize hL : ((a, b) :: L₁ : List _) = L rintro @⟨_ \| ⟨p, s'⟩, e, a', b'⟩ <;> simp_all · rintro (⟨L, h, rfl⟩ \| rfl) · exact Step.cons h · exact Step.cons_not @[to_additive] theorem not_step_singleton : ∀ {p : α × Bool}, ¬Step [p] L \| (a, b) => by simp [Step.cons_left_iff, not_step_nil] @[to_additive] theorem Step.cons_cons_iff : ∀ {p : α × Bool}, Step (p :: L₁) (p :: L₂) ↔ Step L₁ L₂ := by simp +contextual [Step.cons_left_iff, iff_def, or_imp] @[to_additive] theorem Step.append_left_iff : ∀ L, Step (L ++ L₁) (L ++ L₂) ↔ Step L₁ L₂ \| [] => by simp \| p :: l => by simp [Step.append_left_iff l, Step.cons_cons_iff] @[to_additive] theorem Step.diamond_aux : ∀ {L₁ L₂ L₃ L₄ : List (α × Bool)} {x1 b1 x2 b2}, L₁ ++ (x1, b1) :: (x1, !b1) :: L₂ = L₃ ++ (x2, b2) :: (x2, !b2) :: L₄ → L₁ ++ L₂ = L₃ ++ L₄ ∨ ∃ L₅, Red.Step (L₁ ++ L₂) L₅ ∧ Red.Step (L₃ ++ L₄) L₅ \| [], _, [], _, _, _, _, _, H => by injections; subst_vars; simp \| [], _, [(x3, b3)], _, _, _, _, _, H => by injections; subst_vars; simp \| [(x3, b3)], _, [], _, _, _, _, _, H => by injections; subst_vars; simp \| [], _, (x3, b3) :: (x4, b4) :: tl, _, _, _, _, _, H => by injections; subst_vars; right; exact ⟨_, Red.Step.not, Red.Step.cons_not⟩ \| (x3, b3) :: (x4, b4) :: tl, _, [], _, _, _, _, _, H => by injections; subst_vars; right; simpa using ⟨_, Red.Step.cons_not, Red.Step.not⟩ \| (x3, b3) :: tl, _, (x4, b4) :: tl2, _, _, _, _, _, H => let ⟨H1, H2⟩ := List.cons.inj H match Step.diamond_aux H2 with \| Or.inl H3 => Or.inl <\| by simp [H1, H3] \| Or.inr ⟨L₅, H3, H4⟩ => Or.inr ⟨_, Step.cons H3, by simpa [H1] using Step.cons H4⟩ @[to_additive] theorem Step.diamond : ∀ {L₁ L₂ L₃ L₄ : List (α × Bool)}, Red.Step L₁ L₃ → Red.Step L₂ L₄ → L₁ = L₂ → L₃ = L₄ ∨ ∃ L₅, Red.Step L₃ L₅ ∧ Red.Step L₄ L₅ \| _, _, _, _, Red.Step.not, Red.Step.not, H => Step.diamond_aux H @[to_additive] theorem Step.to_red : Step L₁ L₂ → Red L₁ L₂ := ReflTransGen.single /-- Church-Rosser theorem for word reduction: If `w1 w2 w3` are words such that `w1` reduces to `w2` and `w3` respectively, then there is a word `w4` such that `w2` and `w3` reduce to `w4` respectively. This is also known as Newman's diamond lemma. -/ @[to_additive "Church-Rosser theorem for word reduction: If `w1 w2 w3` are words such that `w1` reduces to `w2` and `w3` respectively, then there is a word `w4` such that `w2` and `w3` reduce to `w4` respectively. This is also known as Newman's diamond lemma."] theorem church_rosser : Red L₁ L₂ → Red L₁ L₃ → Join Red L₂ L₃ := Relation.church_rosser fun _ b c hab hac => match b, c, Red.Step.diamond hab hac rfl with \| b, _, Or.inl rfl => ⟨b, by rfl, by rfl⟩ \| _, _, Or.inr ⟨d, hbd, hcd⟩ => ⟨d, ReflGen.single hbd, hcd.to_red⟩ @[to_additive] theorem cons_cons {p} : Red L₁ L₂ → Red (p :: L₁) (p :: L₂) := ReflTransGen.lift (List.cons p) fun _ _ => Step.cons @[to_additive] theorem cons_cons_iff (p) : Red (p :: L₁) (p :: L₂) ↔ Red L₁ L₂ := Iff.intro (by generalize eq₁ : (p :: L₁ : List _) = LL₁ generalize eq₂ : (p :: L₂ : List _) = LL₂ intro h induction h using Relation.ReflTransGen.head_induction_on generalizing L₁ L₂ with \| refl => subst_vars cases eq₂ constructor \| head h₁₂ h ih => subst_vars obtain ⟨a, b⟩ := p rw [Step.cons_left_iff] at h₁₂ rcases h₁₂ with (⟨L, h₁₂, rfl⟩ \| rfl) · exact (ih rfl rfl).head h₁₂ · exact (cons_cons h).tail Step.cons_not_rev) cons_cons @[to_additive] theorem append_append_left_iff : ∀ L, Red (L ++ L₁) (L ++ L₂) ↔ Red L₁ L₂ \| [] => Iff.rfl \| p :: L => by simp [append_append_left_iff L, cons_cons_iff] @[to_additive] theorem append_append (h₁ : Red L₁ L₃) (h₂ : Red L₂ L₄) : Red (L₁ ++ L₂) (L₃ ++ L₄) := (h₁.lift (fun L => L ++ L₂) fun _ _ => Step.append_right).trans ((append_append_left_iff _).2 h₂) @[to_additive] theorem to_append_iff : Red L (L₁ ++ L₂) ↔ ∃ L₃ L₄, L = L₃ ++ L₄ ∧ Red L₃ L₁ ∧ Red L₄ L₂ := Iff.intro (by generalize eq : L₁ ++ L₂ = L₁₂ intro h induction h generalizing L₁ L₂ with \| refl => exact ⟨_, _, eq.symm, by rfl, by rfl⟩ \| tail hLL' h ih => obtain @⟨s, e, a, b⟩ := h rcases List.append_eq_append_iff.1 eq with (⟨s', rfl, rfl⟩ \| ⟨e', rfl, rfl⟩) · have : L₁ ++ (s' ++ (a, b) :: (a, not b) :: e) = L₁ ++ s' ++ (a, b) :: (a, not b) :: e := by simp rcases ih this with ⟨w₁, w₂, rfl, h₁, h₂⟩ exact ⟨w₁, w₂, rfl, h₁, h₂.tail Step.not⟩ · have : s ++ (a, b) :: (a, not b) :: e' ++ L₂ = s ++ (a, b) :: (a, not b) :: (e' ++ L₂) := by simp rcases ih this with ⟨w₁, w₂, rfl, h₁, h₂⟩ exact ⟨w₁, w₂, rfl, h₁.tail Step.not, h₂⟩) fun ⟨_, _, Eq, h₃, h₄⟩ => Eq.symm ▸ append_append h₃ h₄ /-- The empty word `[]` only reduces to itself. -/ @[to_additive "The empty word `[]` only reduces to itself."] theorem nil_iff : Red [] L ↔ L = [] := reflTransGen_iff_eq fun _ => Red.not_step_nil /-- A letter only reduces to itself. -/ @[to_additive "A letter only reduces to itself."] theorem singleton_iff {x} : Red [x] L₁ ↔ L₁ = [x] := reflTransGen_iff_eq fun _ => not_step_singleton /-- If `x` is a letter and `w` is a word such that `xw` reduces to the empty word, then `w` reduces to `x⁻¹` -/ @[to_additive "If `x` is a letter and `w` is a word such that `x + w` reduces to the empty word, then `w` reduces to `-x`."] theorem cons_nil_iff_singleton {x b} : Red ((x, b) :: L) [] ↔ Red L [(x, not b)] := Iff.intro (fun h => by have h₁ : Red ((x, not b) :: (x, b) :: L) [(x, not b)] := cons_cons h have h₂ : Red ((x, not b) :: (x, b) :: L) L := ReflTransGen.single Step.cons_not_rev let ⟨L', h₁, h₂⟩ := church_rosser h₁ h₂ rw [singleton_iff] at h₁ subst L' assumption) fun h => (cons_cons h).tail Step.cons_not @[to_additive] theorem red_iff_irreducible {x1 b1 x2 b2} (h : (x1, b1) ≠ (x2, b2)) : Red [(x1, !b1), (x2, b2)] L ↔ L = [(x1, !b1), (x2, b2)] := by apply reflTransGen_iff_eq generalize eq : [(x1, not b1), (x2, b2)] = L' intro L h' cases h' simp only [List.cons_eq_append_iff, List.cons.injEq, Prod.mk.injEq, and_false, List.nil_eq_append_iff, exists_const, or_self, or_false, List.cons_ne_nil] at eq rcases eq with ⟨rfl, ⟨rfl, rfl⟩, ⟨rfl, rfl⟩, rfl⟩ simp at h /-- If `x` and `y` are distinct letters and `w₁ w₂` are words such that `xw₁` reduces to `yw₂`, then `w₁` reduces to `x⁻¹yw₂`. -/ @[to_additive "If `x` and `y` are distinct letters and `w₁ w₂` are words such that `x + w₁` reduces to `y + w₂`, then `w₁` reduces to `-x + y + w₂`."] theorem inv_of_red_of_ne {x1 b1 x2 b2} (H1 : (x1, b1) ≠ (x2, b2)) (H2 : Red ((x1, b1) :: L₁) ((x2, b2) :: L₂)) : Red L₁ ((x1, not b1) :: (x2, b2) :: L₂) := by have : Red ((x1, b1) :: L₁) ([(x2, b2)] ++ L₂) := H2 rcases to_append_iff.1 this with ⟨_ \| ⟨p, L₃⟩, L₄, eq, h₁, h₂⟩ · simp [nil_iff] at h₁ · cases eq show Red (L₃ ++ L₄) ([(x1, not b1), (x2, b2)] ++ L₂) apply append_append _ h₂ have h₁ : Red ((x1, not b1) :: (x1, b1) :: L₃) [(x1, not b1), (x2, b2)] := cons_cons h₁ have h₂ : Red ((x1, not b1) :: (x1, b1) :: L₃) L₃ := Step.cons_not_rev.to_red rcases church_rosser h₁ h₂ with ⟨L', h₁, h₂⟩ rw [red_iff_irreducible H1] at h₁ rwa [h₁] at h₂ open List -- for <+ notation @[to_additive] theorem Step.sublist (H : Red.Step L₁ L₂) : L₂ <+ L₁ := by cases H; simp /-- If `w₁ w₂` are words such that `w₁` reduces to `w₂`, then `w₂` is a sublist of `w₁`. -/ @[to_additive "If `w₁ w₂` are words such that `w₁` reduces to `w₂`, then `w₂` is a sublist of `w₁`."] protected theorem sublist : Red L₁ L₂ → L₂ <+ L₁ := @reflTransGen_of_transitive_reflexive _ (fun a b => b <+ a) _ _ _ (fun l => List.Sublist.refl l) (fun _a _b _c hab hbc => List.Sublist.trans hbc hab) (fun _ _ => Red.Step.sublist) @[to_additive] theorem length_le (h : Red L₁ L₂) : L₂.length ≤ L₁.length := h.sublist.length_le	@[to_additive] theorem sizeof_of_step : ∀ {L₁ L₂ : List (α × Bool)}, Step L₁ L₂ → sizeOf L₂ < sizeOf L₁ \| _, _, @Step.not _ L1 L2 x b => by induction L1 with \| nil => dsimp omega \| cons hd tl ih => dsimp	Mathlib/GroupTheory/FreeGroup/Basic.lean	328	337
/- Copyright (c) 2023 Andrew Yang, Patrick Lutz. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.RingTheory.RootsOfUnity.PrimitiveRoots import Mathlib.FieldTheory.Galois.Basic import Mathlib.FieldTheory.KummerPolynomial import Mathlib.LinearAlgebra.Eigenspace.Minpoly import Mathlib.RingTheory.Norm.Basic /-! # Kummer Extensions ## Main result - `isCyclic_tfae`: Suppose `L/K` is a finite extension of dimension `n`, and `K` contains all `n`-th roots of unity. Then `L/K` is cyclic iff `L` is a splitting field of some irreducible polynomial of the form `Xⁿ - a : K[X]` iff `L = K[α]` for some `αⁿ ∈ K`. - `autEquivRootsOfUnity`: Given an instance `IsSplittingField K L (X ^ n - C a)` (perhaps via `isSplittingField_X_pow_sub_C_of_root_adjoin_eq_top`), then the galois group is isomorphic to `rootsOfUnity n K`, by sending `σ ↦ σ α / α` for `α ^ n = a`, and the inverse is given by `μ ↦ (α ↦ μ • α)`. - `autEquivZmod`: Furthermore, given an explicit choice `ζ` of a primitive `n`-th root of unity, the galois group is then isomorphic to `Multiplicative (ZMod n)` whose inverse is given by `i ↦ (α ↦ ζⁱ • α)`. ## Other results Criteria for `X ^ n - C a` to be irreducible is given: - `X_pow_sub_C_irreducible_iff_of_prime_pow`: For `n = p ^ k` an odd prime power, `X ^ n - C a` is irreducible iff `a` is not a `p`-power. - `X_pow_sub_C_irreducible_iff_forall_prime_of_odd`: For `n` odd, `X ^ n - C a` is irreducible iff `a` is not a `p`-power for all prime `p ∣ n`. - `X_pow_sub_C_irreducible_iff_of_odd`: For `n` odd, `X ^ n - C a` is irreducible iff `a` is not a `d`-power for `d ∣ n` and `d ≠ 1`. TODO: criteria for even `n`. See [serge_lang_algebra] VI,§9. TODO: relate Kummer extensions of degree 2 with the class `Algebra.IsQuadraticExtension`. -/ universe u variable {K : Type u} [Field K] open Polynomial IntermediateField AdjoinRoot section Splits theorem X_pow_sub_C_splits_of_isPrimitiveRoot {n : ℕ} {ζ : K} (hζ : IsPrimitiveRoot ζ n) {α a : K} (e : α ^ n = a) : (X ^ n - C a).Splits (RingHom.id _) := by cases n.eq_zero_or_pos with \| inl hn => rw [hn, pow_zero, ← C.map_one, ← map_sub] exact splits_C _ _ \| inr hn => rw [splits_iff_card_roots, ← nthRoots, hζ.card_nthRoots, natDegree_X_pow_sub_C, if_pos ⟨α, e⟩]	-- make this private, as we only use it to prove a strictly more general version private theorem X_pow_sub_C_eq_prod' {n : ℕ} {ζ : K} (hζ : IsPrimitiveRoot ζ n) {α a : K} (hn : 0 < n) (e : α ^ n = a) : (X ^ n - C a) = ∏ i ∈ Finset.range n, (X - C (ζ ^ i * α)) := by rw [eq_prod_roots_of_monic_of_splits_id (monic_X_pow_sub_C _ (Nat.pos_iff_ne_zero.mp hn)) (X_pow_sub_C_splits_of_isPrimitiveRoot hζ e), ← nthRoots, hζ.nthRoots_eq e, Multiset.map_map] rfl lemma X_pow_sub_C_eq_prod {R : Type*} [CommRing R] [IsDomain R]	Mathlib/FieldTheory/KummerExtension.lean	63	72
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Abhimanyu Pallavi Sudhir -/ import Mathlib.Algebra.CharP.Defs import Mathlib.Algebra.Order.CauSeq.BigOperators import Mathlib.Algebra.Order.Star.Basic import Mathlib.Data.Complex.BigOperators import Mathlib.Data.Complex.Norm import Mathlib.Data.Nat.Choose.Sum /-! # Exponential Function This file contains the definitions of the real and complex exponential function. ## Main definitions * `Complex.exp`: The complex exponential function, defined via its Taylor series * `Real.exp`: The real exponential function, defined as the real part of the complex exponential -/ open CauSeq Finset IsAbsoluteValue open scoped ComplexConjugate namespace Complex theorem isCauSeq_norm_exp (z : ℂ) : IsCauSeq abs fun n => ∑ m ∈ range n, ‖z ^ m / m.factorial‖ := let ⟨n, hn⟩ := exists_nat_gt ‖z‖ have hn0 : (0 : ℝ) < n := lt_of_le_of_lt (norm_nonneg _) hn IsCauSeq.series_ratio_test n (‖z‖ / n) (div_nonneg (norm_nonneg _) (le_of_lt hn0)) (by rwa [div_lt_iff₀ hn0, one_mul]) fun m hm => by rw [abs_norm, abs_norm, Nat.factorial_succ, pow_succ', mul_comm m.succ, Nat.cast_mul, ← div_div, mul_div_assoc, mul_div_right_comm, Complex.norm_mul, Complex.norm_div, norm_natCast] gcongr exact le_trans hm (Nat.le_succ _) @[deprecated (since := "2025-02-16")] alias isCauSeq_abs_exp := isCauSeq_norm_exp noncomputable section theorem isCauSeq_exp (z : ℂ) : IsCauSeq (‖·‖) fun n => ∑ m ∈ range n, z ^ m / m.factorial := (isCauSeq_norm_exp z).of_abv /-- The Cauchy sequence consisting of partial sums of the Taylor series of the complex exponential function -/ @[pp_nodot] def exp' (z : ℂ) : CauSeq ℂ (‖·‖) := ⟨fun n => ∑ m ∈ range n, z ^ m / m.factorial, isCauSeq_exp z⟩ /-- The complex exponential function, defined via its Taylor series -/ @[pp_nodot] def exp (z : ℂ) : ℂ := CauSeq.lim (exp' z) /-- scoped notation for the complex exponential function -/ scoped notation "cexp" => Complex.exp end end Complex namespace Real open Complex noncomputable section /-- The real exponential function, defined as the real part of the complex exponential -/ @[pp_nodot] nonrec def exp (x : ℝ) : ℝ := (exp x).re /-- scoped notation for the real exponential function -/ scoped notation "rexp" => Real.exp end end Real namespace Complex variable (x y : ℂ) @[simp] theorem exp_zero : exp 0 = 1 := by rw [exp] refine lim_eq_of_equiv_const fun ε ε0 => ⟨1, fun j hj => ?_⟩ convert (config := .unfoldSameFun) ε0 -- ε0 : ε > 0 but goal is _ < ε rcases j with - \| j · exact absurd hj (not_le_of_gt zero_lt_one) · dsimp [exp'] induction' j with j ih · dsimp [exp']; simp [show Nat.succ 0 = 1 from rfl] · rw [← ih (by simp [Nat.succ_le_succ])] simp only [sum_range_succ, pow_succ] simp theorem exp_add : exp (x + y) = exp x * exp y := by have hj : ∀ j : ℕ, (∑ m ∈ range j, (x + y) ^ m / m.factorial) = ∑ i ∈ range j, ∑ k ∈ range (i + 1), x ^ k / k.factorial * (y ^ (i - k) / (i - k).factorial) := by intro j refine Finset.sum_congr rfl fun m _ => ?_ rw [add_pow, div_eq_mul_inv, sum_mul] refine Finset.sum_congr rfl fun I hi => ?_ have h₁ : (m.choose I : ℂ) ≠ 0 := Nat.cast_ne_zero.2 (pos_iff_ne_zero.1 (Nat.choose_pos (Nat.le_of_lt_succ (mem_range.1 hi)))) have h₂ := Nat.choose_mul_factorial_mul_factorial (Nat.le_of_lt_succ <\| Finset.mem_range.1 hi) rw [← h₂, Nat.cast_mul, Nat.cast_mul, mul_inv, mul_inv] simp only [mul_left_comm (m.choose I : ℂ), mul_assoc, mul_left_comm (m.choose I : ℂ)⁻¹, mul_comm (m.choose I : ℂ)] rw [inv_mul_cancel₀ h₁] simp [div_eq_mul_inv, mul_comm, mul_assoc, mul_left_comm] simp_rw [exp, exp', lim_mul_lim] apply (lim_eq_lim_of_equiv _).symm simp only [hj] exact cauchy_product (isCauSeq_norm_exp x) (isCauSeq_exp y) /-- the exponential function as a monoid hom from `Multiplicative ℂ` to `ℂ` -/ @[simps] noncomputable def expMonoidHom : MonoidHom (Multiplicative ℂ) ℂ := { toFun := fun z => exp z.toAdd, map_one' := by simp, map_mul' := by simp [exp_add] } theorem exp_list_sum (l : List ℂ) : exp l.sum = (l.map exp).prod := map_list_prod (M := Multiplicative ℂ) expMonoidHom l theorem exp_multiset_sum (s : Multiset ℂ) : exp s.sum = (s.map exp).prod := @MonoidHom.map_multiset_prod (Multiplicative ℂ) ℂ _ _ expMonoidHom s theorem exp_sum {α : Type} (s : Finset α) (f : α → ℂ) : exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) := map_prod (β := Multiplicative ℂ) expMonoidHom f s lemma exp_nsmul (x : ℂ) (n : ℕ) : exp (n • x) = exp x ^ n := @MonoidHom.map_pow (Multiplicative ℂ) ℂ _ _ expMonoidHom _ _ theorem exp_nat_mul (x : ℂ) : ∀ n : ℕ, exp (n x) = exp x ^ n \| 0 => by rw [Nat.cast_zero, zero_mul, exp_zero, pow_zero] \| Nat.succ n => by rw [pow_succ, Nat.cast_add_one, add_mul, exp_add, ← exp_nat_mul _ n, one_mul] @[simp] theorem exp_ne_zero : exp x ≠ 0 := fun h => zero_ne_one (α := ℂ) <\| by rw [← exp_zero, ← add_neg_cancel x, exp_add, h]; simp theorem exp_neg : exp (-x) = (exp x)⁻¹ := by rw [← mul_right_inj' (exp_ne_zero x), ← exp_add]; simp [mul_inv_cancel₀ (exp_ne_zero x)] theorem exp_sub : exp (x - y) = exp x / exp y := by simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv] theorem exp_int_mul (z : ℂ) (n : ℤ) : Complex.exp (n * z) = Complex.exp z ^ n := by cases n · simp [exp_nat_mul] · simp [exp_add, add_mul, pow_add, exp_neg, exp_nat_mul] @[simp] theorem exp_conj : exp (conj x) = conj (exp x) := by dsimp [exp] rw [← lim_conj] refine congr_arg CauSeq.lim (CauSeq.ext fun _ => ?_) dsimp [exp', Function.comp_def, cauSeqConj] rw [map_sum (starRingEnd _)] refine sum_congr rfl fun n _ => ?_ rw [map_div₀, map_pow, ← ofReal_natCast, conj_ofReal] @[simp] theorem ofReal_exp_ofReal_re (x : ℝ) : ((exp x).re : ℂ) = exp x := conj_eq_iff_re.1 <\| by rw [← exp_conj, conj_ofReal] @[simp, norm_cast] theorem ofReal_exp (x : ℝ) : (Real.exp x : ℂ) = exp x := ofReal_exp_ofReal_re _ @[simp] theorem exp_ofReal_im (x : ℝ) : (exp x).im = 0 := by rw [← ofReal_exp_ofReal_re, ofReal_im] theorem exp_ofReal_re (x : ℝ) : (exp x).re = Real.exp x := rfl end Complex namespace Real open Complex variable (x y : ℝ) @[simp] theorem exp_zero : exp 0 = 1 := by simp [Real.exp] nonrec theorem exp_add : exp (x + y) = exp x * exp y := by simp [exp_add, exp] /-- the exponential function as a monoid hom from `Multiplicative ℝ` to `ℝ` -/ @[simps] noncomputable def expMonoidHom : MonoidHom (Multiplicative ℝ) ℝ := { toFun := fun x => exp x.toAdd, map_one' := by simp, map_mul' := by simp [exp_add] } theorem exp_list_sum (l : List ℝ) : exp l.sum = (l.map exp).prod := map_list_prod (M := Multiplicative ℝ) expMonoidHom l theorem exp_multiset_sum (s : Multiset ℝ) : exp s.sum = (s.map exp).prod := @MonoidHom.map_multiset_prod (Multiplicative ℝ) ℝ _ _ expMonoidHom s theorem exp_sum {α : Type} (s : Finset α) (f : α → ℝ) : exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) := map_prod (β := Multiplicative ℝ) expMonoidHom f s lemma exp_nsmul (x : ℝ) (n : ℕ) : exp (n • x) = exp x ^ n := @MonoidHom.map_pow (Multiplicative ℝ) ℝ _ _ expMonoidHom _ _ nonrec theorem exp_nat_mul (x : ℝ) (n : ℕ) : exp (n x) = exp x ^ n := ofReal_injective (by simp [exp_nat_mul]) @[simp] nonrec theorem exp_ne_zero : exp x ≠ 0 := fun h => exp_ne_zero x <\| by rw [exp, ← ofReal_inj] at h; simp_all nonrec theorem exp_neg : exp (-x) = (exp x)⁻¹ := ofReal_injective <\| by simp [exp_neg] theorem exp_sub : exp (x - y) = exp x / exp y := by simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv] open IsAbsoluteValue Nat theorem sum_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) (n : ℕ) : ∑ i ∈ range n, x ^ i / i ! ≤ exp x := calc ∑ i ∈ range n, x ^ i / i ! ≤ lim (⟨_, isCauSeq_re (exp' x)⟩ : CauSeq ℝ abs) := by refine le_lim (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp only [exp', const_apply, re_sum] norm_cast refine sum_le_sum_of_subset_of_nonneg (range_mono hj) fun _ _ _ ↦ ?_ positivity _ = exp x := by rw [exp, Complex.exp, ← cauSeqRe, lim_re] lemma pow_div_factorial_le_exp (hx : 0 ≤ x) (n : ℕ) : x ^ n / n ! ≤ exp x := calc x ^ n / n ! ≤ ∑ k ∈ range (n + 1), x ^ k / k ! := single_le_sum (f := fun k ↦ x ^ k / k !) (fun k _ ↦ by positivity) (self_mem_range_succ n) _ ≤ exp x := sum_le_exp_of_nonneg hx _ theorem quadratic_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : 1 + x + x ^ 2 / 2 ≤ exp x := calc 1 + x + x ^ 2 / 2 = ∑ i ∈ range 3, x ^ i / i ! := by simp only [sum_range_succ, range_one, sum_singleton, _root_.pow_zero, factorial, cast_one, ne_eq, one_ne_zero, not_false_eq_true, div_self, pow_one, mul_one, div_one, Nat.mul_one, cast_succ, add_right_inj] ring_nf _ ≤ exp x := sum_le_exp_of_nonneg hx 3 private theorem add_one_lt_exp_of_pos {x : ℝ} (hx : 0 < x) : x + 1 < exp x := (by nlinarith : x + 1 < 1 + x + x ^ 2 / 2).trans_le (quadratic_le_exp_of_nonneg hx.le) private theorem add_one_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : x + 1 ≤ exp x := by rcases eq_or_lt_of_le hx with (rfl \| h) · simp exact (add_one_lt_exp_of_pos h).le theorem one_le_exp {x : ℝ} (hx : 0 ≤ x) : 1 ≤ exp x := by linarith [add_one_le_exp_of_nonneg hx] @[bound] theorem exp_pos (x : ℝ) : 0 < exp x := (le_total 0 x).elim (lt_of_lt_of_le zero_lt_one ∘ one_le_exp) fun h => by rw [← neg_neg x, Real.exp_neg] exact inv_pos.2 (lt_of_lt_of_le zero_lt_one (one_le_exp (neg_nonneg.2 h))) @[bound] lemma exp_nonneg (x : ℝ) : 0 ≤ exp x := x.exp_pos.le @[simp] theorem abs_exp (x : ℝ) : \|exp x\| = exp x := abs_of_pos (exp_pos _) lemma exp_abs_le (x : ℝ) : exp \|x\| ≤ exp x + exp (-x) := by cases le_total x 0 <;> simp [abs_of_nonpos, abs_of_nonneg, exp_nonneg, ] @[mono] theorem exp_strictMono : StrictMono exp := fun x y h => by rw [← sub_add_cancel y x, Real.exp_add] exact (lt_mul_iff_one_lt_left (exp_pos _)).2 (lt_of_lt_of_le (by linarith) (add_one_le_exp_of_nonneg (by linarith))) @[gcongr] theorem exp_lt_exp_of_lt {x y : ℝ} (h : x < y) : exp x < exp y := exp_strictMono h @[mono] theorem exp_monotone : Monotone exp := exp_strictMono.monotone @[gcongr, bound] theorem exp_le_exp_of_le {x y : ℝ} (h : x ≤ y) : exp x ≤ exp y := exp_monotone h @[simp] theorem exp_lt_exp {x y : ℝ} : exp x < exp y ↔ x < y := exp_strictMono.lt_iff_lt @[simp] theorem exp_le_exp {x y : ℝ} : exp x ≤ exp y ↔ x ≤ y := exp_strictMono.le_iff_le theorem exp_injective : Function.Injective exp := exp_strictMono.injective @[simp] theorem exp_eq_exp {x y : ℝ} : exp x = exp y ↔ x = y := exp_injective.eq_iff @[simp] theorem exp_eq_one_iff : exp x = 1 ↔ x = 0 := exp_injective.eq_iff' exp_zero @[simp] theorem one_lt_exp_iff {x : ℝ} : 1 < exp x ↔ 0 < x := by rw [← exp_zero, exp_lt_exp] @[bound] private alias ⟨_, Bound.one_lt_exp_of_pos⟩ := one_lt_exp_iff @[simp] theorem exp_lt_one_iff {x : ℝ} : exp x < 1 ↔ x < 0 := by rw [← exp_zero, exp_lt_exp] @[simp] theorem exp_le_one_iff {x : ℝ} : exp x ≤ 1 ↔ x ≤ 0 := exp_zero ▸ exp_le_exp @[simp] theorem one_le_exp_iff {x : ℝ} : 1 ≤ exp x ↔ 0 ≤ x := exp_zero ▸ exp_le_exp end Real namespace Complex theorem sum_div_factorial_le {α : Type} [Field α] [LinearOrder α] [IsStrictOrderedRing α] (n j : ℕ) (hn : 0 < n) : (∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) ≤ n.succ / (n.factorial * n) := calc (∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) = ∑ m ∈ range (j - n), (1 / ((m + n).factorial : α)) := by refine sum_nbij' (· - n) (· + n) ?_ ?_ ?_ ?_ ?_ <;> simp +contextual [lt_tsub_iff_right, tsub_add_cancel_of_le] _ ≤ ∑ m ∈ range (j - n), ((n.factorial : α) * (n.succ : α) ^ m)⁻¹ := by simp_rw [one_div] gcongr rw [← Nat.cast_pow, ← Nat.cast_mul, Nat.cast_le, add_comm] exact Nat.factorial_mul_pow_le_factorial _ = (n.factorial : α)⁻¹ * ∑ m ∈ range (j - n), (n.succ : α)⁻¹ ^ m := by simp [mul_inv, ← mul_sum, ← sum_mul, mul_comm, inv_pow] _ = ((n.succ : α) - n.succ * (n.succ : α)⁻¹ ^ (j - n)) / (n.factorial * n) := by have h₁ : (n.succ : α) ≠ 1 := @Nat.cast_one α _ ▸ mt Nat.cast_inj.1 (mt Nat.succ.inj (pos_iff_ne_zero.1 hn)) have h₂ : (n.succ : α) ≠ 0 := by positivity have h₃ : (n.factorial * n : α) ≠ 0 := by positivity have h₄ : (n.succ - 1 : α) = n := by simp rw [geom_sum_inv h₁ h₂, eq_div_iff_mul_eq h₃, mul_comm _ (n.factorial * n : α), ← mul_assoc (n.factorial⁻¹ : α), ← mul_inv_rev, h₄, ← mul_assoc (n.factorial * n : α), mul_comm (n : α) n.factorial, mul_inv_cancel₀ h₃, one_mul, mul_comm] _ ≤ n.succ / (n.factorial * n : α) := by gcongr; apply sub_le_self; positivity theorem exp_bound {x : ℂ} (hx : ‖x‖ ≤ 1) {n : ℕ} (hn : 0 < n) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹) := by rw [← lim_const (abv := norm) (∑ m ∈ range n, _), exp, sub_eq_add_neg, ← lim_neg, lim_add, ← lim_norm] refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹) rw [sum_range_sub_sum_range hj] calc ‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖ = ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by refine congr_arg norm (sum_congr rfl fun m hm => ?_) rw [mem_filter, mem_range] at hm rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2] _ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ := IsAbsoluteValue.abv_sum norm .. _ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (1 / m.factorial) := by simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast] gcongr rw [Complex.norm_pow] exact pow_le_one₀ (norm_nonneg _) hx _ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (1 / m.factorial : ℝ) := by simp [abs_mul, abv_pow abs, abs_div, ← mul_sum] _ ≤ ‖x‖ ^ n * (n.succ * (n.factorial * n : ℝ)⁻¹) := by gcongr exact sum_div_factorial_le _ _ hn theorem exp_bound' {x : ℂ} {n : ℕ} (hx : ‖x‖ / n.succ ≤ 1 / 2) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n / n.factorial * 2 := by rw [← lim_const (abv := norm) (∑ m ∈ range n, _), exp, sub_eq_add_neg, ← lim_neg, lim_add, ← lim_norm] refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n / n.factorial * 2 let k := j - n have hj : j = n + k := (add_tsub_cancel_of_le hj).symm rw [hj, sum_range_add_sub_sum_range] calc ‖∑ i ∈ range k, x ^ (n + i) / ((n + i).factorial : ℂ)‖ ≤ ∑ i ∈ range k, ‖x ^ (n + i) / ((n + i).factorial : ℂ)‖ := IsAbsoluteValue.abv_sum _ _ _ _ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / (n + i).factorial := by simp [norm_natCast, Complex.norm_pow] _ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / ((n.factorial : ℝ) * (n.succ : ℝ) ^ i) := ?_ _ = ∑ i ∈ range k, ‖x‖ ^ n / n.factorial * (‖x‖ ^ i / (n.succ : ℝ) ^ i) := ?_ _ ≤ ‖x‖ ^ n / ↑n.factorial * 2 := ?_ · gcongr exact mod_cast Nat.factorial_mul_pow_le_factorial · refine Finset.sum_congr rfl fun _ _ => ?_ simp only [pow_add, div_eq_inv_mul, mul_inv, mul_left_comm, mul_assoc] · rw [← mul_sum] gcongr simp_rw [← div_pow] rw [geom_sum_eq, div_le_iff_of_neg] · trans (-1 : ℝ) · linarith · simp only [neg_le_sub_iff_le_add, div_pow, Nat.cast_succ, le_add_iff_nonneg_left] positivity · linarith · linarith theorem norm_exp_sub_one_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1‖ ≤ 2 * ‖x‖ := calc ‖exp x - 1‖ = ‖exp x - ∑ m ∈ range 1, x ^ m / m.factorial‖ := by simp [sum_range_succ] _ ≤ ‖x‖ ^ 1 * ((Nat.succ 1 : ℝ) * ((Nat.factorial 1) * (1 : ℕ) : ℝ)⁻¹) := (exp_bound hx (by decide)) _ = 2 * ‖x‖ := by simp [two_mul, mul_two, mul_add, mul_comm, add_mul, Nat.factorial] theorem norm_exp_sub_one_sub_id_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1 - x‖ ≤ ‖x‖ ^ 2 := calc ‖exp x - 1 - x‖ = ‖exp x - ∑ m ∈ range 2, x ^ m / m.factorial‖ := by simp [sub_eq_add_neg, sum_range_succ_comm, add_assoc, Nat.factorial] _ ≤ ‖x‖ ^ 2 * ((Nat.succ 2 : ℝ) * (Nat.factorial 2 * (2 : ℕ) : ℝ)⁻¹) := (exp_bound hx (by decide)) _ ≤ ‖x‖ ^ 2 * 1 := by gcongr; norm_num [Nat.factorial] _ = ‖x‖ ^ 2 := by rw [mul_one] lemma norm_exp_sub_sum_le_exp_norm_sub_sum (x : ℂ) (n : ℕ) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg, ← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm] refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] calc ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ _ ≤ (∑ m ∈ range j, ‖x‖ ^ m / m.factorial) - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by rw [sum_range_sub_sum_range hj, sum_range_sub_sum_range hj] refine (IsAbsoluteValue.abv_sum norm ..).trans_eq ?_ congr with i simp [Complex.norm_pow] _ ≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by gcongr exact Real.sum_le_exp_of_nonneg (norm_nonneg _) _ lemma norm_exp_le_exp_norm (x : ℂ) : ‖exp x‖ ≤ Real.exp ‖x‖ := by convert norm_exp_sub_sum_le_exp_norm_sub_sum x 0 using 1 <;> simp lemma norm_exp_sub_sum_le_norm_mul_exp (x : ℂ) (n : ℕ) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg, ← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm] refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ _ rw [sum_range_sub_sum_range hj] calc ‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖ = ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by refine congr_arg norm (sum_congr rfl fun m hm => ?_) rw [mem_filter, mem_range] at hm rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2] _ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ := IsAbsoluteValue.abv_sum norm .. _ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (‖x‖ ^ (m - n) / (m - n).factorial) := by simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast] gcongr with i hi · rw [Complex.norm_pow] · simp _ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (‖x‖ ^ (m - n) / (m - n).factorial) := by rw [← mul_sum] _ = ‖x‖ ^ n * ∑ m ∈ range (j - n), (‖x‖ ^ m / m.factorial) := by congr 1 refine (sum_bij (fun m hm ↦ m + n) ?_ ?_ ?_ ?_).symm · intro a ha simp only [mem_filter, mem_range, le_add_iff_nonneg_left, zero_le, and_true] simp only [mem_range] at ha rwa [← lt_tsub_iff_right] · intro a ha b hb hab simpa using hab · intro b hb simp only [mem_range, exists_prop] simp only [mem_filter, mem_range] at hb refine ⟨b - n, ?_, ?_⟩ · rw [tsub_lt_tsub_iff_right hb.2] exact hb.1 · rw [tsub_add_cancel_of_le hb.2] · simp _ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by gcongr refine Real.sum_le_exp_of_nonneg ?_ _ exact norm_nonneg _ @[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_le := norm_exp_sub_one_le @[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_sub_id_le := norm_exp_sub_one_sub_id_le @[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_exp_abs_sub_sum := norm_exp_sub_sum_le_exp_norm_sub_sum @[deprecated (since := "2025-02-16")] alias abs_exp_le_exp_abs := norm_exp_le_exp_norm @[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_abs_mul_exp := norm_exp_sub_sum_le_norm_mul_exp end Complex namespace Real open Complex Finset nonrec theorem exp_bound {x : ℝ} (hx : \|x\| ≤ 1) {n : ℕ} (hn : 0 < n) : \|exp x - ∑ m ∈ range n, x ^ m / m.factorial\| ≤ \|x\| ^ n * (n.succ / (n.factorial * n)) := by have hxc : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx convert exp_bound hxc hn using 2 <;> norm_cast theorem exp_bound' {x : ℝ} (h1 : 0 ≤ x) (h2 : x ≤ 1) {n : ℕ} (hn : 0 < n) : Real.exp x ≤ (∑ m ∈ Finset.range n, x ^ m / m.factorial) + x ^ n * (n + 1) / (n.factorial * n) := by have h3 : \|x\| = x := by simpa have h4 : \|x\| ≤ 1 := by rwa [h3] have h' := Real.exp_bound h4 hn rw [h3] at h' have h'' := (abs_sub_le_iff.1 h').1 have t := sub_le_iff_le_add'.1 h'' simpa [mul_div_assoc] using t theorem abs_exp_sub_one_le {x : ℝ} (hx : \|x\| ≤ 1) : \|exp x - 1\| ≤ 2 * \|x\| := by have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx exact_mod_cast Complex.norm_exp_sub_one_le (x := x) this theorem abs_exp_sub_one_sub_id_le {x : ℝ} (hx : \|x\| ≤ 1) : \|exp x - 1 - x\| ≤ x ^ 2 := by rw [← sq_abs] have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx exact_mod_cast Complex.norm_exp_sub_one_sub_id_le this /-- A finite initial segment of the exponential series, followed by an arbitrary tail. For fixed `n` this is just a linear map wrt `r`, and each map is a simple linear function of the previous (see `expNear_succ`), with `expNear n x r ⟶ exp x` as `n ⟶ ∞`, for any `r`. -/ noncomputable def expNear (n : ℕ) (x r : ℝ) : ℝ := (∑ m ∈ range n, x ^ m / m.factorial) + x ^ n / n.factorial * r @[simp] theorem expNear_zero (x r) : expNear 0 x r = r := by simp [expNear] @[simp] theorem expNear_succ (n x r) : expNear (n + 1) x r = expNear n x (1 + x / (n + 1) * r) := by simp [expNear, range_succ, mul_add, add_left_comm, add_assoc, pow_succ, div_eq_mul_inv, mul_inv, Nat.factorial] ac_rfl theorem expNear_sub (n x r₁ r₂) : expNear n x r₁ - expNear n x r₂ = x ^ n / n.factorial * (r₁ - r₂) := by simp [expNear, mul_sub] theorem exp_approx_end (n m : ℕ) (x : ℝ) (e₁ : n + 1 = m) (h : \|x\| ≤ 1) : \|exp x - expNear m x 0\| ≤ \|x\| ^ m / m.factorial * ((m + 1) / m) := by simp only [expNear, mul_zero, add_zero] convert exp_bound (n := m) h ?_ using 1 · field_simp [mul_comm] · omega theorem exp_approx_succ {n} {x a₁ b₁ : ℝ} (m : ℕ) (e₁ : n + 1 = m) (a₂ b₂ : ℝ) (e : \|1 + x / m * a₂ - a₁\| ≤ b₁ - \|x\| / m * b₂) (h : \|exp x - expNear m x a₂\| ≤ \|x\| ^ m / m.factorial * b₂) : \|exp x - expNear n x a₁\| ≤ \|x\| ^ n / n.factorial * b₁ := by refine (abs_sub_le _ _ _).trans ((add_le_add_right h _).trans ?_) subst e₁; rw [expNear_succ, expNear_sub, abs_mul] convert mul_le_mul_of_nonneg_left (a := \|x\| ^ n / ↑(Nat.factorial n)) (le_sub_iff_add_le'.1 e) ?_ using 1 · simp [mul_add, pow_succ', div_eq_mul_inv, abs_mul, abs_inv, ← pow_abs, mul_inv, Nat.factorial] ac_rfl · simp [div_nonneg, abs_nonneg] theorem exp_approx_end' {n} {x a b : ℝ} (m : ℕ) (e₁ : n + 1 = m) (rm : ℝ) (er : ↑m = rm) (h : \|x\| ≤ 1) (e : \|1 - a\| ≤ b - \|x\| / rm * ((rm + 1) / rm)) : \|exp x - expNear n x a\| ≤ \|x\| ^ n / n.factorial * b := by subst er exact exp_approx_succ _ e₁ _ _ (by simpa using e) (exp_approx_end _ _ _ e₁ h) theorem exp_1_approx_succ_eq {n} {a₁ b₁ : ℝ} {m : ℕ} (en : n + 1 = m) {rm : ℝ} (er : ↑m = rm) (h : \|exp 1 - expNear m 1 ((a₁ - 1) * rm)\| ≤ \|1\| ^ m / m.factorial * (b₁ * rm)) : \|exp 1 - expNear n 1 a₁\| ≤ \|1\| ^ n / n.factorial * b₁ := by subst er refine exp_approx_succ _ en _ _ ?_ h field_simp [show (m : ℝ) ≠ 0 by norm_cast; omega] theorem exp_approx_start (x a b : ℝ) (h : \|exp x - expNear 0 x a\| ≤ \|x\| ^ 0 / Nat.factorial 0 * b) : \|exp x - a\| ≤ b := by simpa using h theorem exp_bound_div_one_sub_of_interval' {x : ℝ} (h1 : 0 < x) (h2 : x < 1) : Real.exp x < 1 / (1 - x) := by have H : 0 < 1 - (1 + x + x ^ 2) * (1 - x) := calc 0 < x ^ 3 := by positivity _ = 1 - (1 + x + x ^ 2) * (1 - x) := by ring calc exp x ≤ _ := exp_bound' h1.le h2.le zero_lt_three _ ≤ 1 + x + x ^ 2 := by -- Porting note: was `norm_num [Finset.sum] <;> nlinarith` -- This proof should be restored after the norm_num plugin for big operators is ported. -- (It may also need the positivity extensions in https://github.com/leanprover-community/mathlib4/pull/3907.) rw [show 3 = 1 + 1 + 1 from rfl] repeat rw [Finset.sum_range_succ] norm_num [Nat.factorial] nlinarith _ < 1 / (1 - x) := by rw [lt_div_iff₀] <;> nlinarith theorem exp_bound_div_one_sub_of_interval {x : ℝ} (h1 : 0 ≤ x) (h2 : x < 1) : Real.exp x ≤ 1 / (1 - x) := by rcases eq_or_lt_of_le h1 with (rfl \| h1) · simp · exact (exp_bound_div_one_sub_of_interval' h1 h2).le theorem add_one_lt_exp {x : ℝ} (hx : x ≠ 0) : x + 1 < Real.exp x := by obtain hx \| hx := hx.symm.lt_or_lt · exact add_one_lt_exp_of_pos hx obtain h' \| h' := le_or_lt 1 (-x) · linarith [x.exp_pos] have hx' : 0 < x + 1 := by linarith simpa [add_comm, exp_neg, inv_lt_inv₀ (exp_pos _) hx'] using exp_bound_div_one_sub_of_interval' (neg_pos.2 hx) h' theorem add_one_le_exp (x : ℝ) : x + 1 ≤ Real.exp x := by obtain rfl \| hx := eq_or_ne x 0 · simp · exact (add_one_lt_exp hx).le lemma one_sub_lt_exp_neg {x : ℝ} (hx : x ≠ 0) : 1 - x < exp (-x) := (sub_eq_neg_add _ _).trans_lt <\| add_one_lt_exp <\| neg_ne_zero.2 hx lemma one_sub_le_exp_neg (x : ℝ) : 1 - x ≤ exp (-x) := (sub_eq_neg_add _ _).trans_le <\| add_one_le_exp _ theorem one_sub_div_pow_le_exp_neg {n : ℕ} {t : ℝ} (ht' : t ≤ n) : (1 - t / n) ^ n ≤ exp (-t) := by rcases eq_or_ne n 0 with (rfl \| hn) · simp rwa [Nat.cast_zero] at ht' calc (1 - t / n) ^ n ≤ rexp (-(t / n)) ^ n := by gcongr · exact sub_nonneg.2 <\| div_le_one_of_le₀ ht' n.cast_nonneg · exact one_sub_le_exp_neg _ _ = rexp (-t) := by rw [← Real.exp_nat_mul, mul_neg, mul_comm, div_mul_cancel₀]; positivity lemma le_inv_mul_exp (x : ℝ) {c : ℝ} (hc : 0 < c) : x ≤ c⁻¹ * exp (c * x) := by rw [le_inv_mul_iff₀ hc] calc c * x _ ≤ c * x + 1 := le_add_of_nonneg_right zero_le_one _ ≤ _ := Real.add_one_le_exp (c * x) end Real namespace Mathlib.Meta.Positivity open Lean.Meta Qq /-- Extension for the `positivity` tactic: `Real.exp` is always positive. -/ @[positivity Real.exp _] def evalExp : PositivityExt where eval {u α} _ _ e := do match u, α, e with \| 0, ~q(ℝ), ~q(Real.exp $a) => assertInstancesCommute pure (.positive q(Real.exp_pos $a)) \| _, _, _ => throwError "not Real.exp" end Mathlib.Meta.Positivity namespace Complex @[simp] theorem norm_exp_ofReal (x : ℝ) : ‖exp x‖ = Real.exp x := by rw [← ofReal_exp] exact Complex.norm_of_nonneg (le_of_lt (Real.exp_pos _)) @[deprecated (since := "2025-02-16")] alias abs_exp_ofReal := norm_exp_ofReal end Complex		Mathlib/Data/Complex/Exponential.lean	1,047	1,047
/- Copyright (c) 2019 Amelia Livingston. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Amelia Livingston -/ import Mathlib.Algebra.BigOperators.Group.Multiset.Basic import Mathlib.Algebra.BigOperators.Group.List.Lemmas import Mathlib.GroupTheory.Congruence.Defs import Mathlib.Algebra.BigOperators.Group.Finset.Defs /-! # Interactions between `∑, ∏` and `(Add)Con` -/ namespace Con /-- Multiplicative congruence relations preserve product indexed by a list. -/ @[to_additive "Additive congruence relations preserve sum indexed by a list."] protected theorem list_prod {ι M : Type*} [MulOneClass M] (c : Con M) {l : List ι} {f g : ι → M} (h : ∀ x ∈ l, c (f x) (g x)) :	c (l.map f).prod (l.map g).prod := by induction l with \| nil => simpa only [List.map_nil, List.prod_nil] using c.refl 1 \| cons x xs ih => rw [List.map_cons, List.map_cons, List.prod_cons, List.prod_cons] exact c.mul (h _ <\| .head _) <\| ih fun k hk ↦ h _ (.tail _ hk) /-- Multiplicative congruence relations preserve product indexed by a multiset. -/	Mathlib/GroupTheory/Congruence/BigOperators.lean	23	31
/- Copyright (c) 2024 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin -/ import Mathlib.Algebra.MvPolynomial.Monad import Mathlib.LinearAlgebra.Charpoly.ToMatrix import Mathlib.LinearAlgebra.FreeModule.StrongRankCondition import Mathlib.LinearAlgebra.Matrix.Charpoly.Univ import Mathlib.RingTheory.TensorProduct.Finite import Mathlib.RingTheory.TensorProduct.Free /-! # Characteristic polynomials of linear families of endomorphisms The coefficients of the characteristic polynomials of a linear family of endomorphisms are homogeneous polynomials in the parameters. This result is used in Lie theory to establish the existence of regular elements and Cartan subalgebras, and ultimately a well-defined notion of rank for Lie algebras. In this file we prove this result about characteristic polynomials. Let `L` and `M` be modules over a nontrivial commutative ring `R`, and let `φ : L →ₗ[R] Module.End R M` be a linear map. Let `b` be a basis of `L`, indexed by `ι`. Then we define a multivariate polynomial with variables indexed by `ι` that evaluates on elements `x` of `L` to the characteristic polynomial of `φ x`. ## Main declarations * `Matrix.toMvPolynomial M i`: the family of multivariate polynomials that evaluates on `c : n → R` to the dot product of the `i`-th row of `M` with `c`. `Matrix.toMvPolynomial M i` is the sum of the monomials `C (M i j) * X j`. * `LinearMap.toMvPolynomial b₁ b₂ f`: a version of `Matrix.toMvPolynomial` for linear maps `f` with respect to bases `b₁` and `b₂` of the domain and codomain. * `LinearMap.polyCharpoly`: the multivariate polynomial that evaluates on elements `x` of `L` to the characteristic polynomial of `φ x`. * `LinearMap.polyCharpoly_map_eq_charpoly`: the evaluation of `polyCharpoly` on elements `x` of `L` is the characteristic polynomial of `φ x`. * `LinearMap.polyCharpoly_coeff_isHomogeneous`: the coefficients of `polyCharpoly` are homogeneous polynomials in the parameters. * `LinearMap.nilRank`: the smallest index at which `polyCharpoly` has a non-zero coefficient, which is independent of the choice of basis for `L`. * `LinearMap.IsNilRegular`: an element `x` of `L` is nil-regular with respect to `φ` if the `n`-th coefficient of the characteristic polynomial of `φ x` is non-zero, where `n` denotes the nil-rank of `φ`. ## Implementation details We show that `LinearMap.polyCharpoly` does not depend on the choice of basis of the target module. This is done via `LinearMap.polyCharpoly_eq_polyCharpolyAux` and `LinearMap.polyCharpolyAux_basisIndep`. The latter is proven by considering the base change of the `R`-linear map `φ : L →ₗ[R] End R M` to the multivariate polynomial ring `MvPolynomial ι R`, and showing that `polyCharpolyAux φ` is equal to the characteristic polynomial of this base change. The proof concludes because characteristic polynomials are independent of the chosen basis. ## References * [barnes1967]: "On Cartan subalgebras of Lie algebras" by D.W. Barnes. -/ open scoped Matrix namespace Matrix variable {m n o R S : Type} variable [Fintype n] [Fintype o] [CommSemiring R] [CommSemiring S] open MvPolynomial /-- Let `M` be an `(m × n)`-matrix over `R`. Then `Matrix.toMvPolynomial M` is the family (indexed by `i : m`) of multivariate polynomials in `n` variables over `R` that evaluates on `c : n → R` to the dot product of the `i`-th row of `M` with `c`: `Matrix.toMvPolynomial M i` is the sum of the monomials `C (M i j) X j`. -/ noncomputable def toMvPolynomial (M : Matrix m n R) (i : m) : MvPolynomial n R := ∑ j, monomial (.single j 1) (M i j)	lemma toMvPolynomial_eval_eq_apply (M : Matrix m n R) (i : m) (c : n → R) : eval c (M.toMvPolynomial i) = (M *ᵥ c) i := by simp only [toMvPolynomial, map_sum, eval_monomial, pow_zero, Finsupp.prod_single_index, pow_one,	Mathlib/Algebra/Module/LinearMap/Polynomial.lean	82	85
/- Copyright (c) 2021 Damiano Testa. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Damiano Testa -/ import Mathlib.Algebra.Group.Basic import Mathlib.Order.Basic import Mathlib.Order.Monotone.Defs /-! # Covariants and contravariants This file contains general lemmas and instances to work with the interactions between a relation and an action on a Type. The intended application is the splitting of the ordering from the algebraic assumptions on the operations in the `Ordered[...]` hierarchy. The strategy is to introduce two more flexible typeclasses, `CovariantClass` and `ContravariantClass`: * `CovariantClass` models the implication `a ≤ b → c * a ≤ c * b` (multiplication is monotone), * `ContravariantClass` models the implication `a * b < a * c → b < c`. Since `Co(ntra)variantClass` takes as input the operation (typically `(+)` or `()`) and the order relation (typically `(≤)` or `(<)`), these are the only two typeclasses that I have used. The general approach is to formulate the lemma that you are interested in and prove it, with the `Ordered[...]` typeclass of your liking. After that, you convert the single typeclass, say `[OrderedCancelMonoid M]`, into three typeclasses, e.g. `[CancelMonoid M] [PartialOrder M] [CovariantClass M M (Function.swap ()) (≤)]` and have a go at seeing if the proof still works! Note that it is possible to combine several `Co(ntra)variantClass` assumptions together. Indeed, the usual ordered typeclasses arise from assuming the pair `[CovariantClass M M () (≤)] [ContravariantClass M M () (<)]` on top of order/algebraic assumptions. A formal remark is that normally `CovariantClass` uses the `(≤)`-relation, while `ContravariantClass` uses the `(<)`-relation. This need not be the case in general, but seems to be the most common usage. In the opposite direction, the implication ```lean [Semigroup α] [PartialOrder α] [ContravariantClass α α () (≤)] → LeftCancelSemigroup α ``` holds -- note the `Contra` assumption on the `(≤)`-relation. # Formalization notes We stick to the convention of using `Function.swap ()` (or `Function.swap (+)`), for the typeclass assumptions, since `Function.swap` is slightly better behaved than `flip`. However, sometimes as a non-typeclass assumption, we prefer `flip ()` (or `flip (+)`), as it is easier to use. -/ -- TODO: convert `ExistsMulOfLE`, `ExistsAddOfLE`? -- TODO: relationship with `Con/AddCon` -- TODO: include equivalence of `LeftCancelSemigroup` with -- `Semigroup PartialOrder ContravariantClass α α () (≤)`? -- TODO : use ⇒, as per Eric's suggestion? See -- https://leanprover.zulipchat.com/#narrow/stream/116395-maths/topic/ordered.20stuff/near/236148738 -- for a discussion. open Function section Variants variable {M N : Type} (μ : M → N → N) (r : N → N → Prop) variable (M N) /-- `Covariant` is useful to formulate succinctly statements about the interactions between an action of a Type on another one and a relation on the acted-upon Type. See the `CovariantClass` doc-string for its meaning. -/ def Covariant : Prop := ∀ (m) {n₁ n₂}, r n₁ n₂ → r (μ m n₁) (μ m n₂) /-- `Contravariant` is useful to formulate succinctly statements about the interactions between an action of a Type on another one and a relation on the acted-upon Type. See the `ContravariantClass` doc-string for its meaning. -/ def Contravariant : Prop := ∀ (m) {n₁ n₂}, r (μ m n₁) (μ m n₂) → r n₁ n₂ /-- Given an action `μ` of a Type `M` on a Type `N` and a relation `r` on `N`, informally, the `CovariantClass` says that "the action `μ` preserves the relation `r`." More precisely, the `CovariantClass` is a class taking two Types `M N`, together with an "action" `μ : M → N → N` and a relation `r : N → N → Prop`. Its unique field `elim` is the assertion that for all `m ∈ M` and all elements `n₁, n₂ ∈ N`, if the relation `r` holds for the pair `(n₁, n₂)`, then, the relation `r` also holds for the pair `(μ m n₁, μ m n₂)`, obtained from `(n₁, n₂)` by acting upon it by `m`. If `m : M` and `h : r n₁ n₂`, then `CovariantClass.elim m h : r (μ m n₁) (μ m n₂)`. -/ class CovariantClass : Prop where /-- For all `m ∈ M` and all elements `n₁, n₂ ∈ N`, if the relation `r` holds for the pair `(n₁, n₂)`, then, the relation `r` also holds for the pair `(μ m n₁, μ m n₂)` -/ protected elim : Covariant M N μ r /-- Given an action `μ` of a Type `M` on a Type `N` and a relation `r` on `N`, informally, the `ContravariantClass` says that "if the result of the action `μ` on a pair satisfies the relation `r`, then the initial pair satisfied the relation `r`." More precisely, the `ContravariantClass` is a class taking two Types `M N`, together with an "action" `μ : M → N → N` and a relation `r : N → N → Prop`. Its unique field `elim` is the assertion that for all `m ∈ M` and all elements `n₁, n₂ ∈ N`, if the relation `r` holds for the pair `(μ m n₁, μ m n₂)` obtained from `(n₁, n₂)` by acting upon it by `m`, then, the relation `r` also holds for the pair `(n₁, n₂)`. If `m : M` and `h : r (μ m n₁) (μ m n₂)`, then `ContravariantClass.elim m h : r n₁ n₂`. -/ class ContravariantClass : Prop where /-- For all `m ∈ M` and all elements `n₁, n₂ ∈ N`, if the relation `r` holds for the pair `(μ m n₁, μ m n₂)` obtained from `(n₁, n₂)` by acting upon it by `m`, then, the relation `r` also holds for the pair `(n₁, n₂)`. -/ protected elim : Contravariant M N μ r /-- Typeclass for monotonicity of multiplication on the left, namely `b₁ ≤ b₂ → a b₁ ≤ a * b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCommMonoid`. -/ abbrev MulLeftMono [Mul M] [LE M] : Prop := CovariantClass M M (· * ·) (· ≤ ·) /-- Typeclass for monotonicity of multiplication on the right, namely `a₁ ≤ a₂ → a₁ * b ≤ a₂ * b`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCommMonoid`. -/ abbrev MulRightMono [Mul M] [LE M] : Prop := CovariantClass M M (swap (· * ·)) (· ≤ ·) /-- Typeclass for monotonicity of addition on the left, namely `b₁ ≤ b₂ → a + b₁ ≤ a + b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedAddCommMonoid`. -/ abbrev AddLeftMono [Add M] [LE M] : Prop := CovariantClass M M (· + ·) (· ≤ ·) /-- Typeclass for monotonicity of addition on the right, namely `a₁ ≤ a₂ → a₁ + b ≤ a₂ + b`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedAddCommMonoid`. -/ abbrev AddRightMono [Add M] [LE M] : Prop := CovariantClass M M (swap (· + ·)) (· ≤ ·) attribute [to_additive existing] MulLeftMono MulRightMono /-- Typeclass for monotonicity of multiplication on the left, namely `b₁ < b₂ → a * b₁ < a * b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCommGroup`. -/ abbrev MulLeftStrictMono [Mul M] [LT M] : Prop := CovariantClass M M (· * ·) (· < ·) /-- Typeclass for monotonicity of multiplication on the right, namely `a₁ < a₂ → a₁ * b < a₂ * b`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCommGroup`. -/ abbrev MulRightStrictMono [Mul M] [LT M] : Prop := CovariantClass M M (swap (· * ·)) (· < ·) /-- Typeclass for monotonicity of addition on the left, namely `b₁ < b₂ → a + b₁ < a + b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedAddCommGroup`. -/ abbrev AddLeftStrictMono [Add M] [LT M] : Prop := CovariantClass M M (· + ·) (· < ·) /-- Typeclass for monotonicity of addition on the right, namely `a₁ < a₂ → a₁ + b < a₂ + b`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedAddCommGroup`. -/ abbrev AddRightStrictMono [Add M] [LT M] : Prop := CovariantClass M M (swap (· + ·)) (· < ·) attribute [to_additive existing] MulLeftStrictMono MulRightStrictMono /-- Typeclass for strict reverse monotonicity of multiplication on the left, namely `a * b₁ < a * b₂ → b₁ < b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCommGroup`. -/ abbrev MulLeftReflectLT [Mul M] [LT M] : Prop := ContravariantClass M M (· * ·) (· < ·) /-- Typeclass for strict reverse monotonicity of multiplication on the right, namely `a₁ * b < a₂ * b → a₁ < a₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCommGroup`. -/ abbrev MulRightReflectLT [Mul M] [LT M] : Prop := ContravariantClass M M (swap (· * ·)) (· < ·) /-- Typeclass for strict reverse monotonicity of addition on the left, namely `a + b₁ < a + b₂ → b₁ < b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedAddCommGroup`. -/ abbrev AddLeftReflectLT [Add M] [LT M] : Prop := ContravariantClass M M (· + ·) (· < ·) /-- Typeclass for strict reverse monotonicity of addition on the right, namely `a₁ * b < a₂ * b → a₁ < a₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedAddCommGroup`. -/ abbrev AddRightReflectLT [Add M] [LT M] : Prop := ContravariantClass M M (swap (· + ·)) (· < ·) attribute [to_additive existing] MulLeftReflectLT MulRightReflectLT /-- Typeclass for reverse monotonicity of multiplication on the left, namely `a * b₁ ≤ a * b₂ → b₁ ≤ b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCancelCommMonoid`. -/ abbrev MulLeftReflectLE [Mul M] [LE M] : Prop := ContravariantClass M M (· * ·) (· ≤ ·) /-- Typeclass for reverse monotonicity of multiplication on the right, namely `a₁ * b ≤ a₂ * b → a₁ ≤ a₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCancelCommMonoid`. -/ abbrev MulRightReflectLE [Mul M] [LE M] : Prop := ContravariantClass M M (swap (· * ·)) (· ≤ ·) /-- Typeclass for reverse monotonicity of addition on the left, namely `a + b₁ ≤ a + b₂ → b₁ ≤ b₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCancelAddCommMonoid`. -/ abbrev AddLeftReflectLE [Add M] [LE M] : Prop := ContravariantClass M M (· + ·) (· ≤ ·) /-- Typeclass for reverse monotonicity of addition on the right, namely `a₁ + b ≤ a₂ + b → a₁ ≤ a₂`. You should usually not use this very granular typeclass directly, but rather a typeclass like `OrderedCancelAddCommMonoid`. -/ abbrev AddRightReflectLE [Add M] [LE M] : Prop := ContravariantClass M M (swap (· + ·)) (· ≤ ·) attribute [to_additive existing] MulLeftReflectLE MulRightReflectLE theorem rel_iff_cov [CovariantClass M N μ r] [ContravariantClass M N μ r] (m : M) {a b : N} : r (μ m a) (μ m b) ↔ r a b := ⟨ContravariantClass.elim _, CovariantClass.elim _⟩ section flip variable {M N μ r} theorem Covariant.flip (h : Covariant M N μ r) : Covariant M N μ (flip r) := fun a _ _ ↦ h a theorem Contravariant.flip (h : Contravariant M N μ r) : Contravariant M N μ (flip r) := fun a _ _ ↦ h a end flip section Covariant variable {M N μ r} [CovariantClass M N μ r] theorem act_rel_act_of_rel (m : M) {a b : N} (ab : r a b) : r (μ m a) (μ m b) := CovariantClass.elim _ ab @[to_additive] theorem Group.covariant_iff_contravariant [Group N] :	Covariant N N (· * ·) r ↔ Contravariant N N (· * ·) r := by refine ⟨fun h a b c bc ↦ ?_, fun h a b c bc ↦ ?_⟩ · rw [← inv_mul_cancel_left a b, ← inv_mul_cancel_left a c] exact h a⁻¹ bc · rw [← inv_mul_cancel_left a b, ← inv_mul_cancel_left a c] at bc exact h a⁻¹ bc	Mathlib/Algebra/Order/Monoid/Unbundled/Defs.lean	281	286
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.Polynomial.Eval.Degree import Mathlib.Algebra.Prime.Lemmas /-! # Theory of degrees of polynomials Some of the main results include - `natDegree_comp_le` : The degree of the composition is at most the product of degrees -/ noncomputable section open Polynomial open Finsupp Finset namespace Polynomial universe u v w variable {R : Type u} {S : Type v} {ι : Type w} {a b : R} {m n : ℕ} section Semiring variable [Semiring R] {p q r : R[X]} section Degree theorem natDegree_comp_le : natDegree (p.comp q) ≤ natDegree p * natDegree q := letI := Classical.decEq R if h0 : p.comp q = 0 then by rw [h0, natDegree_zero]; exact Nat.zero_le _ else WithBot.coe_le_coe.1 <\| calc ↑(natDegree (p.comp q)) = degree (p.comp q) := (degree_eq_natDegree h0).symm _ = _ := congr_arg degree comp_eq_sum_left _ ≤ _ := degree_sum_le _ _ _ ≤ _ := Finset.sup_le fun n hn => calc degree (C (coeff p n) * q ^ n) ≤ degree (C (coeff p n)) + degree (q ^ n) := degree_mul_le _ _ _ ≤ natDegree (C (coeff p n)) + n • degree q := (add_le_add degree_le_natDegree (degree_pow_le _ _)) _ ≤ natDegree (C (coeff p n)) + n • ↑(natDegree q) := (add_le_add_left (nsmul_le_nsmul_right (@degree_le_natDegree _ _ q) n) _) _ = (n * natDegree q : ℕ) := by rw [natDegree_C, Nat.cast_zero, zero_add, nsmul_eq_mul] simp _ ≤ (natDegree p * natDegree q : ℕ) := WithBot.coe_le_coe.2 <\| mul_le_mul_of_nonneg_right (le_natDegree_of_ne_zero (mem_support_iff.1 hn)) (Nat.zero_le _) theorem natDegree_comp_eq_of_mul_ne_zero (h : p.leadingCoeff * q.leadingCoeff ^ p.natDegree ≠ 0) : natDegree (p.comp q) = natDegree p * natDegree q := by by_cases hq : natDegree q = 0 · exact le_antisymm natDegree_comp_le (by simp [hq]) apply natDegree_eq_of_le_of_coeff_ne_zero natDegree_comp_le rwa [coeff_comp_degree_mul_degree hq] theorem degree_pos_of_root {p : R[X]} (hp : p ≠ 0) (h : IsRoot p a) : 0 < degree p := lt_of_not_ge fun hlt => by have := eq_C_of_degree_le_zero hlt rw [IsRoot, this, eval_C] at h simp only [h, RingHom.map_zero] at this exact hp this theorem natDegree_le_iff_coeff_eq_zero : p.natDegree ≤ n ↔ ∀ N : ℕ, n < N → p.coeff N = 0 := by simp_rw [natDegree_le_iff_degree_le, degree_le_iff_coeff_zero, Nat.cast_lt] theorem natDegree_add_le_iff_left {n : ℕ} (p q : R[X]) (qn : q.natDegree ≤ n) : (p + q).natDegree ≤ n ↔ p.natDegree ≤ n := by refine ⟨fun h => ?_, fun h => natDegree_add_le_of_degree_le h qn⟩ refine natDegree_le_iff_coeff_eq_zero.mpr fun m hm => ?_ convert natDegree_le_iff_coeff_eq_zero.mp h m hm using 1 rw [coeff_add, natDegree_le_iff_coeff_eq_zero.mp qn _ hm, add_zero] theorem natDegree_add_le_iff_right {n : ℕ} (p q : R[X]) (pn : p.natDegree ≤ n) : (p + q).natDegree ≤ n ↔ q.natDegree ≤ n := by rw [add_comm] exact natDegree_add_le_iff_left _ _ pn -- TODO: Do we really want the following two lemmas? They are straightforward consequences of a -- more atomic lemma theorem natDegree_C_mul_le (a : R) (f : R[X]) : (C a * f).natDegree ≤ f.natDegree := by simpa using natDegree_mul_le (p := C a) theorem natDegree_mul_C_le (f : R[X]) (a : R) : (f * C a).natDegree ≤ f.natDegree := by simpa using natDegree_mul_le (q := C a) theorem eq_natDegree_of_le_mem_support (pn : p.natDegree ≤ n) (ns : n ∈ p.support) : p.natDegree = n := le_antisymm pn (le_natDegree_of_mem_supp _ ns) theorem natDegree_C_mul_eq_of_mul_eq_one {ai : R} (au : ai * a = 1) : (C a * p).natDegree = p.natDegree := le_antisymm (natDegree_C_mul_le a p) (calc p.natDegree = (1 * p).natDegree := by nth_rw 1 [← one_mul p] _ = (C ai * (C a * p)).natDegree := by rw [← C_1, ← au, RingHom.map_mul, ← mul_assoc] _ ≤ (C a * p).natDegree := natDegree_C_mul_le ai (C a * p)) theorem natDegree_mul_C_eq_of_mul_eq_one {ai : R} (au : a * ai = 1) : (p * C a).natDegree = p.natDegree := le_antisymm (natDegree_mul_C_le p a) (calc p.natDegree = (p * 1).natDegree := by nth_rw 1 [← mul_one p] _ = (p * C a * C ai).natDegree := by rw [← C_1, ← au, RingHom.map_mul, ← mul_assoc] _ ≤ (p * C a).natDegree := natDegree_mul_C_le (p * C a) ai) /-- Although not explicitly stated, the assumptions of lemma `natDegree_mul_C_eq_of_mul_ne_zero` force the polynomial `p` to be non-zero, via `p.leadingCoeff ≠ 0`. -/ theorem natDegree_mul_C_eq_of_mul_ne_zero (h : p.leadingCoeff * a ≠ 0) : (p * C a).natDegree = p.natDegree := by refine eq_natDegree_of_le_mem_support (natDegree_mul_C_le p a) ?_ refine mem_support_iff.mpr ?_ rwa [coeff_mul_C] /-- Although not explicitly stated, the assumptions of lemma `natDegree_C_mul_of_mul_ne_zero` force the polynomial `p` to be non-zero, via `p.leadingCoeff ≠ 0`. -/ theorem natDegree_C_mul_of_mul_ne_zero (h : a * p.leadingCoeff ≠ 0) : (C a * p).natDegree = p.natDegree := by refine eq_natDegree_of_le_mem_support (natDegree_C_mul_le a p) ?_ refine mem_support_iff.mpr ?_ rwa [coeff_C_mul] @[deprecated (since := "2025-01-03")] alias natDegree_C_mul_eq_of_mul_ne_zero := natDegree_C_mul_of_mul_ne_zero lemma degree_C_mul_of_mul_ne_zero (h : a * p.leadingCoeff ≠ 0) : (C a * p).degree = p.degree := by rw [degree_mul' (by simpa)]; simp [left_ne_zero_of_mul h] theorem natDegree_add_coeff_mul (f g : R[X]) : (f * g).coeff (f.natDegree + g.natDegree) = f.coeff f.natDegree * g.coeff g.natDegree := by simp only [coeff_natDegree, coeff_mul_degree_add_degree] theorem natDegree_lt_coeff_mul (h : p.natDegree + q.natDegree < m + n) : (p * q).coeff (m + n) = 0 := coeff_eq_zero_of_natDegree_lt (natDegree_mul_le.trans_lt h) theorem coeff_mul_of_natDegree_le (pm : p.natDegree ≤ m) (qn : q.natDegree ≤ n) : (p * q).coeff (m + n) = p.coeff m * q.coeff n := by simp_rw [← Polynomial.toFinsupp_apply, toFinsupp_mul] refine AddMonoidAlgebra.apply_add_of_supDegree_le ?_ Function.injective_id ?_ ?_ · simp · rwa [supDegree_eq_natDegree, id_eq] · rwa [supDegree_eq_natDegree, id_eq] theorem coeff_pow_of_natDegree_le (pn : p.natDegree ≤ n) : (p ^ m).coeff (m * n) = p.coeff n ^ m := by induction' m with m hm · simp · rw [pow_succ, pow_succ, ← hm, Nat.succ_mul, coeff_mul_of_natDegree_le _ pn] refine natDegree_pow_le.trans (le_trans ?_ (le_refl _)) exact mul_le_mul_of_nonneg_left pn m.zero_le theorem coeff_pow_eq_ite_of_natDegree_le_of_le {o : ℕ} (pn : natDegree p ≤ n) (mno : m * n ≤ o) : coeff (p ^ m) o = if o = m * n then (coeff p n) ^ m else 0 := by rcases eq_or_ne o (m * n) with rfl \| h · simpa only [ite_true] using coeff_pow_of_natDegree_le pn · simpa only [h, ite_false] using coeff_eq_zero_of_natDegree_lt <\| lt_of_le_of_lt (natDegree_pow_le_of_le m pn) (lt_of_le_of_ne mno h.symm) theorem coeff_add_eq_left_of_lt (qn : q.natDegree < n) : (p + q).coeff n = p.coeff n := (coeff_add _ _ _).trans <\| (congr_arg _ <\| coeff_eq_zero_of_natDegree_lt <\| qn).trans <\| add_zero _ theorem coeff_add_eq_right_of_lt (pn : p.natDegree < n) : (p + q).coeff n = q.coeff n := by rw [add_comm] exact coeff_add_eq_left_of_lt pn open scoped Function -- required for scoped `on` notation theorem degree_sum_eq_of_disjoint (f : S → R[X]) (s : Finset S) (h : Set.Pairwise { i \| i ∈ s ∧ f i ≠ 0 } (Ne on degree ∘ f)) : degree (s.sum f) = s.sup fun i => degree (f i) := by classical induction' s using Finset.induction_on with x s hx IH · simp · simp only [hx, Finset.sum_insert, not_false_iff, Finset.sup_insert] specialize IH (h.mono fun _ => by simp +contextual) rcases lt_trichotomy (degree (f x)) (degree (s.sum f)) with (H \| H \| H) · rw [← IH, sup_eq_right.mpr H.le, degree_add_eq_right_of_degree_lt H] · rcases s.eq_empty_or_nonempty with (rfl \| hs) · simp obtain ⟨y, hy, hy'⟩ := Finset.exists_mem_eq_sup s hs fun i => degree (f i) rw [IH, hy'] at H by_cases hx0 : f x = 0 · simp [hx0, IH] have hy0 : f y ≠ 0 := by contrapose! H simpa [H, degree_eq_bot] using hx0 refine absurd H (h ?_ ?_ fun H => hx ?_) · simp [hx0] · simp [hy, hy0] · exact H.symm ▸ hy · rw [← IH, sup_eq_left.mpr H.le, degree_add_eq_left_of_degree_lt H] theorem natDegree_sum_eq_of_disjoint (f : S → R[X]) (s : Finset S) (h : Set.Pairwise { i \| i ∈ s ∧ f i ≠ 0 } (Ne on natDegree ∘ f)) : natDegree (s.sum f) = s.sup fun i => natDegree (f i) := by by_cases H : ∃ x ∈ s, f x ≠ 0 · obtain ⟨x, hx, hx'⟩ := H have hs : s.Nonempty := ⟨x, hx⟩ refine natDegree_eq_of_degree_eq_some ?_ rw [degree_sum_eq_of_disjoint] · rw [← Finset.sup'_eq_sup hs, ← Finset.sup'_eq_sup hs, Nat.cast_withBot, Finset.coe_sup' hs, ← Finset.sup'_eq_sup hs] refine le_antisymm ?_ ?_ · rw [Finset.sup'_le_iff] intro b hb by_cases hb' : f b = 0 · simpa [hb'] using hs rw [degree_eq_natDegree hb', Nat.cast_withBot] exact Finset.le_sup' (fun i : S => (natDegree (f i) : WithBot ℕ)) hb · rw [Finset.sup'_le_iff] intro b hb simp only [Finset.le_sup'_iff, exists_prop, Function.comp_apply] by_cases hb' : f b = 0 · refine ⟨x, hx, ?_⟩ contrapose! hx' simpa [← Nat.cast_withBot, hb', degree_eq_bot] using hx' exact ⟨b, hb, (degree_eq_natDegree hb').ge⟩ · exact h.imp fun x y hxy hxy' => hxy (natDegree_eq_of_degree_eq hxy') · push_neg at H rw [Finset.sum_eq_zero H, natDegree_zero, eq_comm, show 0 = ⊥ from rfl, Finset.sup_eq_bot_iff] intro x hx simp [H x hx] variable [Semiring S] theorem natDegree_pos_of_eval₂_root {p : R[X]} (hp : p ≠ 0) (f : R →+* S) {z : S} (hz : eval₂ f z p = 0) (inj : ∀ x : R, f x = 0 → x = 0) : 0 < natDegree p := lt_of_not_ge fun hlt => by have A : p = C (p.coeff 0) := eq_C_of_natDegree_le_zero hlt rw [A, eval₂_C] at hz simp only [inj (p.coeff 0) hz, RingHom.map_zero] at A exact hp A theorem degree_pos_of_eval₂_root {p : R[X]} (hp : p ≠ 0) (f : R →+* S) {z : S} (hz : eval₂ f z p = 0) (inj : ∀ x : R, f x = 0 → x = 0) : 0 < degree p := natDegree_pos_iff_degree_pos.mp (natDegree_pos_of_eval₂_root hp f hz inj) @[simp] theorem coe_lt_degree {p : R[X]} {n : ℕ} : (n : WithBot ℕ) < degree p ↔ n < natDegree p := by by_cases h : p = 0 · simp [h] simp [degree_eq_natDegree h, Nat.cast_lt] @[simp] theorem degree_map_eq_iff {f : R →+* S} {p : Polynomial R} : degree (map f p) = degree p ↔ f (leadingCoeff p) ≠ 0 ∨ p = 0 := by rcases eq_or_ne p 0 with h\|h · simp [h] simp only [h, or_false] refine ⟨fun h2 ↦ ?_, degree_map_eq_of_leadingCoeff_ne_zero f⟩ have h3 : natDegree (map f p) = natDegree p := by simp_rw [natDegree, h2] have h4 : map f p ≠ 0 := by rwa [ne_eq, ← degree_eq_bot, h2, degree_eq_bot] rwa [← coeff_natDegree, ← coeff_map, ← h3, coeff_natDegree, ne_eq, leadingCoeff_eq_zero] @[simp] theorem natDegree_map_eq_iff {f : R →+* S} {p : Polynomial R} : natDegree (map f p) = natDegree p ↔ f (p.leadingCoeff) ≠ 0 ∨ natDegree p = 0 := by rcases eq_or_ne (natDegree p) 0 with h\|h · simp_rw [h, ne_eq, or_true, iff_true, ← Nat.le_zero, ← h, natDegree_map_le] have h2 : p ≠ 0 := by rintro rfl; simp at h simp_all [natDegree, WithBot.unbotD_eq_unbotD_iff] theorem natDegree_pos_of_nextCoeff_ne_zero (h : p.nextCoeff ≠ 0) : 0 < p.natDegree := by rw [nextCoeff] at h by_cases hpz : p.natDegree = 0 · simp_all only [ne_eq, zero_le, ite_true, not_true_eq_false] · apply Nat.zero_lt_of_ne_zero hpz end Degree end Semiring section Ring variable [Ring R] {p q : R[X]} theorem natDegree_sub : (p - q).natDegree = (q - p).natDegree := by rw [← natDegree_neg, neg_sub] theorem natDegree_sub_le_iff_left (qn : q.natDegree ≤ n) : (p - q).natDegree ≤ n ↔ p.natDegree ≤ n := by rw [← natDegree_neg] at qn rw [sub_eq_add_neg, natDegree_add_le_iff_left _ _ qn] theorem natDegree_sub_le_iff_right (pn : p.natDegree ≤ n) : (p - q).natDegree ≤ n ↔ q.natDegree ≤ n := by rwa [natDegree_sub, natDegree_sub_le_iff_left] theorem coeff_sub_eq_left_of_lt (dg : q.natDegree < n) : (p - q).coeff n = p.coeff n := by rw [← natDegree_neg] at dg rw [sub_eq_add_neg, coeff_add_eq_left_of_lt dg] theorem coeff_sub_eq_neg_right_of_lt (df : p.natDegree < n) : (p - q).coeff n = -q.coeff n := by rwa [sub_eq_add_neg, coeff_add_eq_right_of_lt, coeff_neg] end Ring section NoZeroDivisors variable [Semiring R] {p q : R[X]} {a : R} @[simp] lemma nextCoeff_C_mul_X_add_C (ha : a ≠ 0) (c : R) : nextCoeff (C a * X + C c) = c := by rw [nextCoeff_of_natDegree_pos] <;> simp [ha] lemma natDegree_eq_one : p.natDegree = 1 ↔ ∃ a ≠ 0, ∃ b, C a * X + C b = p := by refine ⟨fun hp ↦ ⟨p.coeff 1, fun h ↦ ?_, p.coeff 0, ?_⟩, ?_⟩ · rw [← hp, coeff_natDegree, leadingCoeff_eq_zero] at h aesop · ext n obtain _ \| _ \| n := n · simp · simp · simp only [coeff_add, coeff_mul_X, coeff_C_succ, add_zero] rw [coeff_eq_zero_of_natDegree_lt] simp [hp] · rintro ⟨a, ha, b, rfl⟩ simp [ha] variable [NoZeroDivisors R] theorem degree_mul_C (a0 : a ≠ 0) : (p * C a).degree = p.degree := by rw [degree_mul, degree_C a0, add_zero] theorem degree_C_mul (a0 : a ≠ 0) : (C a * p).degree = p.degree := by rw [degree_mul, degree_C a0, zero_add] theorem natDegree_mul_C (a0 : a ≠ 0) : (p * C a).natDegree = p.natDegree := by simp only [natDegree, degree_mul_C a0] theorem natDegree_C_mul (a0 : a ≠ 0) : (C a * p).natDegree = p.natDegree := by simp only [natDegree, degree_C_mul a0] theorem natDegree_comp : natDegree (p.comp q) = natDegree p * natDegree q := by by_cases q0 : q.natDegree = 0 · rw [degree_le_zero_iff.mp (natDegree_eq_zero_iff_degree_le_zero.mp q0), comp_C, natDegree_C, natDegree_C, mul_zero] · by_cases p0 : p = 0 · simp only [p0, zero_comp, natDegree_zero, zero_mul] · simp only [Ne, mul_eq_zero, leadingCoeff_eq_zero, p0, natDegree_comp_eq_of_mul_ne_zero, ne_zero_of_natDegree_gt (Nat.pos_of_ne_zero q0), not_false_eq_true, pow_ne_zero, or_self] @[simp] theorem natDegree_iterate_comp (k : ℕ) : (p.comp^[k] q).natDegree = p.natDegree ^ k * q.natDegree := by induction k with \| zero => simp \| succ k IH => rw [Function.iterate_succ_apply', natDegree_comp, IH, pow_succ', mul_assoc] theorem leadingCoeff_comp (hq : natDegree q ≠ 0) : leadingCoeff (p.comp q) = leadingCoeff p * leadingCoeff q ^ natDegree p := by rw [← coeff_comp_degree_mul_degree hq, ← natDegree_comp, coeff_natDegree] end NoZeroDivisors @[simp] lemma comp_neg_X_leadingCoeff_eq [Ring R] (p : R[X]) : (p.comp (-X)).leadingCoeff = (-1) ^ p.natDegree * p.leadingCoeff := by nontriviality R by_cases h : p = 0 · simp [h] rw [Polynomial.leadingCoeff, natDegree_comp_eq_of_mul_ne_zero, coeff_comp_degree_mul_degree] <;> simp [((Commute.neg_one_left _).pow_left _).eq, h] lemma comp_eq_zero_iff [Semiring R] [NoZeroDivisors R] {p q : R[X]} : p.comp q = 0 ↔ p = 0 ∨ p.eval (q.coeff 0) = 0 ∧ q = C (q.coeff 0) := by refine ⟨fun h ↦ ?_, Or.rec (fun h ↦ by simp [h]) fun h ↦ by rw [h.2, comp_C, h.1, C_0]⟩ have key : p.natDegree = 0 ∨ q.natDegree = 0 := by rw [← mul_eq_zero, ← natDegree_comp, h, natDegree_zero] obtain key \| key := Or.imp eq_C_of_natDegree_eq_zero eq_C_of_natDegree_eq_zero key · rw [key, C_comp] at h exact Or.inl (key.trans h) · rw [key, comp_C, C_eq_zero] at h exact Or.inr ⟨h, key⟩ section DivisionRing variable {K : Type} [DivisionRing K] /-! Useful lemmas for the "monicization" of a nonzero polynomial `p`. -/ @[simp] theorem irreducible_mul_leadingCoeff_inv {p : K[X]} : Irreducible (p C (leadingCoeff p)⁻¹) ↔ Irreducible p := by by_cases hp0 : p = 0 · simp [hp0] exact irreducible_mul_isUnit (isUnit_C.mpr (IsUnit.mk0 _ (inv_ne_zero (leadingCoeff_ne_zero.mpr hp0)))) @[simp] lemma dvd_mul_leadingCoeff_inv {p q : K[X]} (hp0 : p ≠ 0) : q ∣ p * C (leadingCoeff p)⁻¹ ↔ q ∣ p := IsUnit.dvd_mul_right <\| isUnit_C.mpr <\| IsUnit.mk0 _ <\| inv_ne_zero <\| leadingCoeff_ne_zero.mpr hp0 theorem monic_mul_leadingCoeff_inv {p : K[X]} (h : p ≠ 0) : Monic (p * C (leadingCoeff p)⁻¹) := by rw [Monic, leadingCoeff_mul, leadingCoeff_C, mul_inv_cancel₀ (show leadingCoeff p ≠ 0 from mt leadingCoeff_eq_zero.1 h)] -- `simp` normal form of `degree_mul_leadingCoeff_inv` @[simp] lemma degree_leadingCoeff_inv {p : K[X]} (hp0 : p ≠ 0) : degree (C (leadingCoeff p)⁻¹) = 0 := degree_C (inv_ne_zero <\| leadingCoeff_ne_zero.mpr hp0) theorem degree_mul_leadingCoeff_inv (p : K[X]) {q : K[X]} (h : q ≠ 0) : degree (p * C (leadingCoeff q)⁻¹) = degree p := by have h₁ : (leadingCoeff q)⁻¹ ≠ 0 := inv_ne_zero (mt leadingCoeff_eq_zero.1 h) rw [degree_mul_C h₁] theorem natDegree_mul_leadingCoeff_inv (p : K[X]) {q : K[X]} (h : q ≠ 0) : natDegree (p * C (leadingCoeff q)⁻¹) = natDegree p := natDegree_eq_of_degree_eq (degree_mul_leadingCoeff_inv _ h) theorem degree_mul_leadingCoeff_self_inv (p : K[X]) : degree (p * C (leadingCoeff p)⁻¹) = degree p := by by_cases hp : p = 0 · simp [hp] exact degree_mul_leadingCoeff_inv _ hp theorem natDegree_mul_leadingCoeff_self_inv (p : K[X]) : natDegree (p * C (leadingCoeff p)⁻¹) = natDegree p := natDegree_eq_of_degree_eq (degree_mul_leadingCoeff_self_inv _) -- `simp` normal form of `degree_mul_leadingCoeff_self_inv` @[simp] lemma degree_add_degree_leadingCoeff_inv (p : K[X]) : degree p + degree (C (leadingCoeff p)⁻¹) = degree p := by rw [← degree_mul, degree_mul_leadingCoeff_self_inv] end DivisionRing end Polynomial		Mathlib/Algebra/Polynomial/Degree/Lemmas.lean	469	471
/- Copyright (c) 2019 Simon Hudon. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Simon Hudon -/ import Mathlib.Data.Fintype.Basic import Mathlib.Data.Fintype.EquivFin import Mathlib.Data.List.ProdSigma import Mathlib.Data.List.Pi /-! Type class for finitely enumerable types. The property is stronger than `Fintype` in that it assigns each element a rank in a finite enumeration. -/ universe u v open Finset /-- `FinEnum α` means that `α` is finite and can be enumerated in some order, i.e. `α` has an explicit bijection with `Fin n` for some n. -/ class FinEnum (α : Sort) where /-- `FinEnum.card` is the cardinality of the `FinEnum` -/ card : ℕ /-- `FinEnum.Equiv` states that type `α` is in bijection with `Fin card`, the size of the `FinEnum` -/ equiv : α ≃ Fin card [decEq : DecidableEq α] attribute [instance 100] FinEnum.decEq namespace FinEnum variable {α : Type u} {β : α → Type v} /-- transport a `FinEnum` instance across an equivalence -/ def ofEquiv (α) {β} [FinEnum α] (h : β ≃ α) : FinEnum β where card := card α equiv := h.trans (equiv) decEq := (h.trans (equiv)).decidableEq /-- create a `FinEnum` instance from an exhaustive list without duplicates -/ def ofNodupList [DecidableEq α] (xs : List α) (h : ∀ x : α, x ∈ xs) (h' : List.Nodup xs) : FinEnum α where card := xs.length equiv := ⟨fun x => ⟨xs.idxOf x, by rw [List.idxOf_lt_length_iff]; apply h⟩, xs.get, fun x => by simp, fun i => by ext; simp [List.idxOf_getElem h']⟩ /-- create a `FinEnum` instance from an exhaustive list; duplicates are removed -/ def ofList [DecidableEq α] (xs : List α) (h : ∀ x : α, x ∈ xs) : FinEnum α := ofNodupList xs.dedup (by simp []) (List.nodup_dedup _) /-- create an exhaustive list of the values of a given type -/ def toList (α) [FinEnum α] : List α := (List.finRange (card α)).map (equiv).symm open Function @[simp] theorem mem_toList [FinEnum α] (x : α) : x ∈ toList α := by simp [toList]; exists equiv x; simp @[simp] theorem nodup_toList [FinEnum α] : List.Nodup (toList α) := by simp [toList]; apply List.Nodup.map <;> [apply Equiv.injective; apply List.nodup_finRange] /-- create a `FinEnum` instance using a surjection -/ def ofSurjective {β} (f : β → α) [DecidableEq α] [FinEnum β] (h : Surjective f) : FinEnum α := ofList ((toList β).map f) (by intro; simpa using h _) /-- create a `FinEnum` instance using an injection -/ noncomputable def ofInjective {α β} (f : α → β) [DecidableEq α] [FinEnum β] (h : Injective f) : FinEnum α := ofList ((toList β).filterMap (partialInv f)) (by intro x simp only [mem_toList, true_and, List.mem_filterMap] use f x simp only [h, Function.partialInv_left]) instance _root_.ULift.instFinEnum [FinEnum α] : FinEnum (ULift α) := ⟨card α, Equiv.ulift.trans equiv⟩ @[simp] theorem card_ulift [FinEnum (ULift α)] [FinEnum α] : card (ULift α) = card α := Fin.equiv_iff_eq.mp ⟨equiv.symm.trans Equiv.ulift \|>.trans equiv⟩ section ULift variable [FinEnum α] (a : α) (a' : ULift α) (i : Fin (card α)) @[simp] lemma equiv_up : equiv (ULift.up a) = equiv a := rfl @[simp] lemma equiv_down : equiv a'.down = equiv a' := rfl @[simp] lemma up_equiv_symm : ULift.up (equiv.symm i) = (equiv (α := ULift α)).symm i := rfl @[simp] lemma down_equiv_symm : ((equiv (α := ULift α)).symm i).down = equiv.symm i := rfl end ULift instance pempty : FinEnum PEmpty := ofList [] fun x => PEmpty.elim x instance empty : FinEnum Empty := ofList [] fun x => Empty.elim x instance punit : FinEnum PUnit := ofList [PUnit.unit] fun x => by cases x; simp instance prod {β} [FinEnum α] [FinEnum β] : FinEnum (α × β) := ofList (toList α ×ˢ toList β) fun x => by cases x; simp instance sum {β} [FinEnum α] [FinEnum β] : FinEnum (α ⊕ β) := ofList ((toList α).map Sum.inl ++ (toList β).map Sum.inr) fun x => by cases x <;> simp instance fin {n} : FinEnum (Fin n) := ofList (List.finRange _) (by simp) @[simp] theorem card_fin {n} [FinEnum (Fin n)] : card (Fin n) = n := Fin.equiv_iff_eq.mp ⟨equiv.symm⟩ instance Quotient.enum [FinEnum α] (s : Setoid α) [DecidableRel ((· ≈ ·) : α → α → Prop)] : FinEnum (Quotient s) := FinEnum.ofSurjective Quotient.mk'' fun x => Quotient.inductionOn x fun x => ⟨x, rfl⟩ /-- enumerate all finite sets of a given type -/ def Finset.enum [DecidableEq α] : List α → List (Finset α) \| [] => [∅] \| x :: xs => do let r ← Finset.enum xs [r, insert x r] @[simp] theorem Finset.mem_enum [DecidableEq α] (s : Finset α) (xs : List α) : s ∈ Finset.enum xs ↔ ∀ x ∈ s, x ∈ xs := by induction xs generalizing s with \| nil => simp [enum, eq_empty_iff_forall_not_mem] \| cons x xs ih => simp only [enum, List.bind_eq_flatMap, List.mem_flatMap, List.mem_cons, List.mem_singleton, List.not_mem_nil, or_false, ih] refine ⟨by aesop, fun hs => ⟨s.erase x, ?_⟩⟩ simp only [or_iff_not_imp_left] at hs simp +contextual [eq_comm (a := s), or_iff_not_imp_left, hs] instance Finset.finEnum [FinEnum α] : FinEnum (Finset α) := ofList (Finset.enum (toList α)) (by intro; simp) instance Subtype.finEnum [FinEnum α] (p : α → Prop) [DecidablePred p] : FinEnum { x // p x } := ofList ((toList α).filterMap fun x => if h : p x then some ⟨_, h⟩ else none) (by rintro ⟨x, h⟩; simpa) instance (β : α → Type v) [FinEnum α] [∀ a, FinEnum (β a)] : FinEnum (Sigma β) := ofList ((toList α).flatMap fun a => (toList (β a)).map <\| Sigma.mk a) (by intro x; cases x; simp) instance PSigma.finEnum [FinEnum α] [∀ a, FinEnum (β a)] : FinEnum (Σ'a, β a) := FinEnum.ofEquiv _ (Equiv.psigmaEquivSigma _) instance PSigma.finEnumPropLeft {α : Prop} {β : α → Type v} [∀ a, FinEnum (β a)] [Decidable α] : FinEnum (Σ'a, β a) := if h : α then ofList ((toList (β h)).map <\| PSigma.mk h) fun ⟨a, Ba⟩ => by simp else ofList [] fun ⟨a, _⟩ => (h a).elim instance PSigma.finEnumPropRight {β : α → Prop} [FinEnum α] [∀ a, Decidable (β a)] : FinEnum (Σ'a, β a) := FinEnum.ofEquiv { a // β a } ⟨fun ⟨x, y⟩ => ⟨x, y⟩, fun ⟨x, y⟩ => ⟨x, y⟩, fun ⟨_, _⟩ => rfl, fun ⟨_, _⟩ => rfl⟩ instance PSigma.finEnumPropProp {α : Prop} {β : α → Prop} [Decidable α] [∀ a, Decidable (β a)] : FinEnum (Σ'a, β a) := if h : ∃ a, β a then ofList [⟨h.fst, h.snd⟩] (by rintro ⟨⟩; simp) else ofList [] fun a => (h ⟨a.fst, a.snd⟩).elim instance [DecidableEq α] (xs : List α) : FinEnum { x : α // x ∈ xs } := ofList xs.attach (by simp) instance (priority := 100) [FinEnum α] : Fintype α where elems := univ.map (equiv).symm.toEmbedding complete := by intros; simp /-- The enumeration merely adds an ordering, leaving the cardinality as is. -/ theorem card_eq_fintypeCard {α : Type u} [FinEnum α] [Fintype α] : card α = Fintype.card α := Fintype.truncEquivFin α \|>.inductionOn (fun h ↦ Fin.equiv_iff_eq.mp ⟨equiv.symm.trans h⟩) /-- Any two enumerations of the same type have the same length. -/ theorem card_unique {α : Type u} (e₁ e₂ : FinEnum α) : e₁.card = e₂.card := calc _ _ = _ := @card_eq_fintypeCard _ e₁ inferInstance _ = _ := Fintype.card_congr' rfl _ = _ := @card_eq_fintypeCard _ e₂ inferInstance \|>.symm /-- A type indexable by `Fin 0` is empty and vice versa. -/ theorem card_eq_zero_iff {α : Type u} [FinEnum α] : card α = 0 ↔ IsEmpty α := Eq.congr_left card_eq_fintypeCard \|>.trans Fintype.card_eq_zero_iff /-- Any enumeration of an empty type has length 0. -/ theorem card_eq_zero {α : Type u} [FinEnum α] [IsEmpty α] : card α = 0 := card_eq_zero_iff.mpr ‹_› /-- A type indexable by `Fin n` with positive `n` is inhabited and vice versa. -/ theorem card_pos_iff {α : Type u} [FinEnum α] : 0 < card α ↔ Nonempty α := card_eq_fintypeCard (α := α) ▸ Fintype.card_pos_iff /-- Any non-empty enumeration has more than one element. -/ lemma card_pos {α : Type} [FinEnum α] [Nonempty α] : 0 < card α := card_pos_iff.mpr ‹_› /-- No non-empty enumeration has 0 elements. -/ lemma card_ne_zero {α : Type} [FinEnum α] [Nonempty α] : card α ≠ 0 := card_pos.ne' /-- Any enumeration of a type with unique inhabitant has length 1. -/ theorem card_eq_one (α : Type u) [FinEnum α] [Unique α] : card α = 1 := card_eq_fintypeCard.trans <\| Fintype.card_eq_one_iff_nonempty_unique.mpr ⟨‹_›⟩ instance [IsEmpty α] : Unique (FinEnum α) where default := ⟨0, Equiv.equivOfIsEmpty α (Fin 0)⟩ uniq e := by show FinEnum.mk e.1 e.2 = _ congr 1 · exact card_eq_zero · refine heq_of_cast_eq ?_ (Subsingleton.allEq _ _) exact congrArg (α ≃ Fin ·) <\| card_eq_zero · funext x exact ‹IsEmpty α›.elim x /-- An empty type has a trivial enumeration. Not registered as an instance, to make sure that there aren't two definitionally differing instances around. -/ def ofIsEmpty [IsEmpty α] : FinEnum α := default instance [Unique α] : Unique (FinEnum α) where default := ⟨1, Equiv.ofUnique α (Fin 1)⟩ uniq e := by show FinEnum.mk e.1 e.2 = _ congr 1 · exact card_eq_one α · refine heq_of_cast_eq ?_ (Subsingleton.allEq _ _) exact congrArg (α ≃ Fin ·) <\| card_eq_one α · funext x y cases decEq x y <;> cases decidableEq_of_subsingleton x y <;> first \| rfl \| contradiction /-- A type with unique inhabitant has a trivial enumeration. Not registered as an instance, to make sure that there aren't two definitionally differing instances around. -/ def ofUnique [Unique α] : FinEnum α := default end FinEnum namespace List	variable {α : Type} [FinEnum α] {β : α → Type} [∀ a, FinEnum (β a)] open FinEnum	Mathlib/Data/FinEnum.lean	248	249
/- Copyright (c) 2015, 2017 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Robert Y. Lewis, Johannes Hölzl, Mario Carneiro, Sébastien Gouëzel -/ import Mathlib.Data.ENNReal.Real import Mathlib.Tactic.Bound.Attribute import Mathlib.Topology.Bornology.Basic import Mathlib.Topology.EMetricSpace.Defs import Mathlib.Topology.UniformSpace.Basic /-! ## Pseudo-metric spaces This file defines pseudo-metric spaces: these differ from metric spaces by not imposing the condition `dist x y = 0 → x = y`. Many definitions and theorems expected on (pseudo-)metric spaces are already introduced on uniform spaces and topological spaces. For example: open and closed sets, compactness, completeness, continuity and uniform continuity. ## Main definitions * `Dist α`: Endows a space `α` with a function `dist a b`. * `PseudoMetricSpace α`: A space endowed with a distance function, which can be zero even if the two elements are non-equal. * `Metric.ball x ε`: The set of all points `y` with `dist y x < ε`. * `Metric.Bounded s`: Whether a subset of a `PseudoMetricSpace` is bounded. * `MetricSpace α`: A `PseudoMetricSpace` with the guarantee `dist x y = 0 → x = y`. Additional useful definitions: * `nndist a b`: `dist` as a function to the non-negative reals. * `Metric.closedBall x ε`: The set of all points `y` with `dist y x ≤ ε`. * `Metric.sphere x ε`: The set of all points `y` with `dist y x = ε`. TODO (anyone): Add "Main results" section. ## Tags pseudo_metric, dist -/ assert_not_exists compactSpace_uniformity open Set Filter TopologicalSpace Bornology open scoped ENNReal NNReal Uniformity Topology universe u v w variable {α : Type u} {β : Type v} {X ι : Type} theorem UniformSpace.ofDist_aux (ε : ℝ) (hε : 0 < ε) : ∃ δ > (0 : ℝ), ∀ x < δ, ∀ y < δ, x + y < ε := ⟨ε / 2, half_pos hε, fun _x hx _y hy => add_halves ε ▸ add_lt_add hx hy⟩ /-- Construct a uniform structure from a distance function and metric space axioms -/ def UniformSpace.ofDist (dist : α → α → ℝ) (dist_self : ∀ x : α, dist x x = 0) (dist_comm : ∀ x y : α, dist x y = dist y x) (dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z) : UniformSpace α := .ofFun dist dist_self dist_comm dist_triangle ofDist_aux /-- Construct a bornology from a distance function and metric space axioms. -/ abbrev Bornology.ofDist {α : Type} (dist : α → α → ℝ) (dist_comm : ∀ x y, dist x y = dist y x) (dist_triangle : ∀ x y z, dist x z ≤ dist x y + dist y z) : Bornology α := Bornology.ofBounded { s : Set α \| ∃ C, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C } ⟨0, fun _ hx _ => hx.elim⟩ (fun _ ⟨c, hc⟩ _ h => ⟨c, fun _ hx _ hy => hc (h hx) (h hy)⟩) (fun s hs t ht => by rcases s.eq_empty_or_nonempty with rfl \| ⟨x, hx⟩ · rwa [empty_union] rcases t.eq_empty_or_nonempty with rfl \| ⟨y, hy⟩ · rwa [union_empty] rsuffices ⟨C, hC⟩ : ∃ C, ∀ z ∈ s ∪ t, dist x z ≤ C · refine ⟨C + C, fun a ha b hb => (dist_triangle a x b).trans ?_⟩ simpa only [dist_comm] using add_le_add (hC _ ha) (hC _ hb) rcases hs with ⟨Cs, hs⟩; rcases ht with ⟨Ct, ht⟩ refine ⟨max Cs (dist x y + Ct), fun z hz => hz.elim (fun hz => (hs hx hz).trans (le_max_left _ _)) (fun hz => (dist_triangle x y z).trans <\| (add_le_add le_rfl (ht hy hz)).trans (le_max_right _ _))⟩) fun z => ⟨dist z z, forall_eq.2 <\| forall_eq.2 le_rfl⟩ /-- The distance function (given an ambient metric space on `α`), which returns a nonnegative real number `dist x y` given `x y : α`. -/ @[ext] class Dist (α : Type) where /-- Distance between two points -/ dist : α → α → ℝ export Dist (dist) -- the uniform structure and the emetric space structure are embedded in the metric space structure -- to avoid instance diamond issues. See Note [forgetful inheritance]. /-- This is an internal lemma used inside the default of `PseudoMetricSpace.edist`. -/ private theorem dist_nonneg' {α} {x y : α} (dist : α → α → ℝ) (dist_self : ∀ x : α, dist x x = 0) (dist_comm : ∀ x y : α, dist x y = dist y x) (dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z) : 0 ≤ dist x y := have : 0 ≤ 2 dist x y := calc 0 = dist x x := (dist_self _).symm _ ≤ dist x y + dist y x := dist_triangle _ _ _ _ = 2 * dist x y := by rw [two_mul, dist_comm] nonneg_of_mul_nonneg_right this two_pos /-- A pseudometric space is a type endowed with a `ℝ`-valued distance `dist` satisfying reflexivity `dist x x = 0`, commutativity `dist x y = dist y x`, and the triangle inequality `dist x z ≤ dist x y + dist y z`. Note that we do not require `dist x y = 0 → x = y`. See metric spaces (`MetricSpace`) for the similar class with that stronger assumption. Any pseudometric space is a topological space and a uniform space (see `TopologicalSpace`, `UniformSpace`), where the topology and uniformity come from the metric. Note that a T1 pseudometric space is just a metric space. We make the uniformity/topology part of the data instead of deriving it from the metric. This eg ensures that we do not get a diamond when doing `[PseudoMetricSpace α] [PseudoMetricSpace β] : TopologicalSpace (α × β)`: The product metric and product topology agree, but not definitionally so. See Note [forgetful inheritance]. -/ class PseudoMetricSpace (α : Type u) : Type u extends Dist α where dist_self : ∀ x : α, dist x x = 0 dist_comm : ∀ x y : α, dist x y = dist y x dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z /-- Extended distance between two points -/ edist : α → α → ℝ≥0∞ := fun x y => ENNReal.ofNNReal ⟨dist x y, dist_nonneg' _ ‹_› ‹_› ‹_›⟩ edist_dist : ∀ x y : α, edist x y = ENNReal.ofReal (dist x y) := by intros x y; exact ENNReal.coe_nnreal_eq _ toUniformSpace : UniformSpace α := .ofDist dist dist_self dist_comm dist_triangle uniformity_dist : 𝓤 α = ⨅ ε > 0, 𝓟 { p : α × α \| dist p.1 p.2 < ε } := by intros; rfl toBornology : Bornology α := Bornology.ofDist dist dist_comm dist_triangle cobounded_sets : (Bornology.cobounded α).sets = { s \| ∃ C : ℝ, ∀ x ∈ sᶜ, ∀ y ∈ sᶜ, dist x y ≤ C } := by intros; rfl /-- Two pseudo metric space structures with the same distance function coincide. -/ @[ext] theorem PseudoMetricSpace.ext {α : Type} {m m' : PseudoMetricSpace α} (h : m.toDist = m'.toDist) : m = m' := by let d := m.toDist obtain ⟨_, _, _, _, hed, _, hU, _, hB⟩ := m let d' := m'.toDist obtain ⟨_, _, _, _, hed', _, hU', _, hB'⟩ := m' obtain rfl : d = d' := h congr · ext x y : 2 rw [hed, hed'] · exact UniformSpace.ext (hU.trans hU'.symm) · ext : 2 rw [← Filter.mem_sets, ← Filter.mem_sets, hB, hB'] variable [PseudoMetricSpace α] attribute [instance] PseudoMetricSpace.toUniformSpace PseudoMetricSpace.toBornology -- see Note [lower instance priority] instance (priority := 200) PseudoMetricSpace.toEDist : EDist α := ⟨PseudoMetricSpace.edist⟩ /-- Construct a pseudo-metric space structure whose underlying topological space structure (definitionally) agrees which a pre-existing topology which is compatible with a given distance function. -/ def PseudoMetricSpace.ofDistTopology {α : Type u} [TopologicalSpace α] (dist : α → α → ℝ) (dist_self : ∀ x : α, dist x x = 0) (dist_comm : ∀ x y : α, dist x y = dist y x) (dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z) (H : ∀ s : Set α, IsOpen s ↔ ∀ x ∈ s, ∃ ε > 0, ∀ y, dist x y < ε → y ∈ s) : PseudoMetricSpace α := { dist := dist dist_self := dist_self dist_comm := dist_comm dist_triangle := dist_triangle toUniformSpace := (UniformSpace.ofDist dist dist_self dist_comm dist_triangle).replaceTopology <\| TopologicalSpace.ext_iff.2 fun s ↦ (H s).trans <\| forall₂_congr fun x _ ↦ ((UniformSpace.hasBasis_ofFun (exists_gt (0 : ℝ)) dist dist_self dist_comm dist_triangle UniformSpace.ofDist_aux).comap (Prod.mk x)).mem_iff.symm uniformity_dist := rfl toBornology := Bornology.ofDist dist dist_comm dist_triangle cobounded_sets := rfl } @[simp] theorem dist_self (x : α) : dist x x = 0 := PseudoMetricSpace.dist_self x theorem dist_comm (x y : α) : dist x y = dist y x := PseudoMetricSpace.dist_comm x y theorem edist_dist (x y : α) : edist x y = ENNReal.ofReal (dist x y) := PseudoMetricSpace.edist_dist x y @[bound] theorem dist_triangle (x y z : α) : dist x z ≤ dist x y + dist y z := PseudoMetricSpace.dist_triangle x y z theorem dist_triangle_left (x y z : α) : dist x y ≤ dist z x + dist z y := by rw [dist_comm z]; apply dist_triangle theorem dist_triangle_right (x y z : α) : dist x y ≤ dist x z + dist y z := by rw [dist_comm y]; apply dist_triangle theorem dist_triangle4 (x y z w : α) : dist x w ≤ dist x y + dist y z + dist z w := calc dist x w ≤ dist x z + dist z w := dist_triangle x z w _ ≤ dist x y + dist y z + dist z w := add_le_add_right (dist_triangle x y z) _ theorem dist_triangle4_left (x₁ y₁ x₂ y₂ : α) : dist x₂ y₂ ≤ dist x₁ y₁ + (dist x₁ x₂ + dist y₁ y₂) := by rw [add_left_comm, dist_comm x₁, ← add_assoc] apply dist_triangle4 theorem dist_triangle4_right (x₁ y₁ x₂ y₂ : α) : dist x₁ y₁ ≤ dist x₁ x₂ + dist y₁ y₂ + dist x₂ y₂ := by rw [add_right_comm, dist_comm y₁] apply dist_triangle4 theorem dist_triangle8 (a b c d e f g h : α) : dist a h ≤ dist a b + dist b c + dist c d + dist d e + dist e f + dist f g + dist g h := by apply le_trans (dist_triangle4 a f g h) apply add_le_add_right (add_le_add_right _ (dist f g)) (dist g h) apply le_trans (dist_triangle4 a d e f) apply add_le_add_right (add_le_add_right _ (dist d e)) (dist e f) exact dist_triangle4 a b c d theorem swap_dist : Function.swap (@dist α _) = dist := by funext x y; exact dist_comm _ _ theorem abs_dist_sub_le (x y z : α) : \|dist x z - dist y z\| ≤ dist x y := abs_sub_le_iff.2 ⟨sub_le_iff_le_add.2 (dist_triangle _ _ _), sub_le_iff_le_add.2 (dist_triangle_left _ _ _)⟩ @[bound] theorem dist_nonneg {x y : α} : 0 ≤ dist x y := dist_nonneg' dist dist_self dist_comm dist_triangle namespace Mathlib.Meta.Positivity open Lean Meta Qq Function /-- Extension for the `positivity` tactic: distances are nonnegative. -/ @[positivity Dist.dist _ _] def evalDist : PositivityExt where eval {u α} _zα _pα e := do match u, α, e with \| 0, ~q(ℝ), ~q(@Dist.dist $β $inst $a $b) => let _inst ← synthInstanceQ q(PseudoMetricSpace $β) assertInstancesCommute pure (.nonnegative q(dist_nonneg)) \| _, _, _ => throwError "not dist" end Mathlib.Meta.Positivity example {x y : α} : 0 ≤ dist x y := by positivity @[simp] theorem abs_dist {a b : α} : \|dist a b\| = dist a b := abs_of_nonneg dist_nonneg /-- A version of `Dist` that takes value in `ℝ≥0`. -/ class NNDist (α : Type) where /-- Nonnegative distance between two points -/ nndist : α → α → ℝ≥0 export NNDist (nndist) -- see Note [lower instance priority] /-- Distance as a nonnegative real number. -/ instance (priority := 100) PseudoMetricSpace.toNNDist : NNDist α := ⟨fun a b => ⟨dist a b, dist_nonneg⟩⟩ /-- Express `dist` in terms of `nndist` -/ theorem dist_nndist (x y : α) : dist x y = nndist x y := rfl @[simp, norm_cast] theorem coe_nndist (x y : α) : ↑(nndist x y) = dist x y := rfl /-- Express `edist` in terms of `nndist` -/ theorem edist_nndist (x y : α) : edist x y = nndist x y := by rw [edist_dist, dist_nndist, ENNReal.ofReal_coe_nnreal] /-- Express `nndist` in terms of `edist` -/ theorem nndist_edist (x y : α) : nndist x y = (edist x y).toNNReal := by simp [edist_nndist] @[simp, norm_cast] theorem coe_nnreal_ennreal_nndist (x y : α) : ↑(nndist x y) = edist x y := (edist_nndist x y).symm @[simp, norm_cast] theorem edist_lt_coe {x y : α} {c : ℝ≥0} : edist x y < c ↔ nndist x y < c := by rw [edist_nndist, ENNReal.coe_lt_coe] @[simp, norm_cast] theorem edist_le_coe {x y : α} {c : ℝ≥0} : edist x y ≤ c ↔ nndist x y ≤ c := by rw [edist_nndist, ENNReal.coe_le_coe] /-- In a pseudometric space, the extended distance is always finite -/ theorem edist_lt_top {α : Type} [PseudoMetricSpace α] (x y : α) : edist x y < ⊤ := (edist_dist x y).symm ▸ ENNReal.ofReal_lt_top /-- In a pseudometric space, the extended distance is always finite -/ theorem edist_ne_top (x y : α) : edist x y ≠ ⊤ := (edist_lt_top x y).ne /-- `nndist x x` vanishes -/ @[simp] theorem nndist_self (a : α) : nndist a a = 0 := NNReal.coe_eq_zero.1 (dist_self a) @[simp, norm_cast] theorem dist_lt_coe {x y : α} {c : ℝ≥0} : dist x y < c ↔ nndist x y < c := Iff.rfl @[simp, norm_cast] theorem dist_le_coe {x y : α} {c : ℝ≥0} : dist x y ≤ c ↔ nndist x y ≤ c := Iff.rfl @[simp] theorem edist_lt_ofReal {x y : α} {r : ℝ} : edist x y < ENNReal.ofReal r ↔ dist x y < r := by rw [edist_dist, ENNReal.ofReal_lt_ofReal_iff_of_nonneg dist_nonneg] @[simp] theorem edist_le_ofReal {x y : α} {r : ℝ} (hr : 0 ≤ r) : edist x y ≤ ENNReal.ofReal r ↔ dist x y ≤ r := by rw [edist_dist, ENNReal.ofReal_le_ofReal_iff hr] /-- Express `nndist` in terms of `dist` -/ theorem nndist_dist (x y : α) : nndist x y = Real.toNNReal (dist x y) := by rw [dist_nndist, Real.toNNReal_coe] theorem nndist_comm (x y : α) : nndist x y = nndist y x := NNReal.eq <\| dist_comm x y /-- Triangle inequality for the nonnegative distance -/ theorem nndist_triangle (x y z : α) : nndist x z ≤ nndist x y + nndist y z := dist_triangle _ _ _ theorem nndist_triangle_left (x y z : α) : nndist x y ≤ nndist z x + nndist z y := dist_triangle_left _ _ _ theorem nndist_triangle_right (x y z : α) : nndist x y ≤ nndist x z + nndist y z := dist_triangle_right _ _ _ /-- Express `dist` in terms of `edist` -/ theorem dist_edist (x y : α) : dist x y = (edist x y).toReal := by rw [edist_dist, ENNReal.toReal_ofReal dist_nonneg] namespace Metric -- instantiate pseudometric space as a topology variable {x y z : α} {δ ε ε₁ ε₂ : ℝ} {s : Set α} /-- `ball x ε` is the set of all points `y` with `dist y x < ε` -/ def ball (x : α) (ε : ℝ) : Set α := { y \| dist y x < ε } @[simp] theorem mem_ball : y ∈ ball x ε ↔ dist y x < ε := Iff.rfl theorem mem_ball' : y ∈ ball x ε ↔ dist x y < ε := by rw [dist_comm, mem_ball] theorem pos_of_mem_ball (hy : y ∈ ball x ε) : 0 < ε := dist_nonneg.trans_lt hy theorem mem_ball_self (h : 0 < ε) : x ∈ ball x ε := by rwa [mem_ball, dist_self] @[simp] theorem nonempty_ball : (ball x ε).Nonempty ↔ 0 < ε := ⟨fun ⟨_x, hx⟩ => pos_of_mem_ball hx, fun h => ⟨x, mem_ball_self h⟩⟩ @[simp] theorem ball_eq_empty : ball x ε = ∅ ↔ ε ≤ 0 := by rw [← not_nonempty_iff_eq_empty, nonempty_ball, not_lt] @[simp] theorem ball_zero : ball x 0 = ∅ := by rw [ball_eq_empty] /-- If a point belongs to an open ball, then there is a strictly smaller radius whose ball also contains it. See also `exists_lt_subset_ball`. -/ theorem exists_lt_mem_ball_of_mem_ball (h : x ∈ ball y ε) : ∃ ε' < ε, x ∈ ball y ε' := by simp only [mem_ball] at h ⊢ exact ⟨(dist x y + ε) / 2, by linarith, by linarith⟩ theorem ball_eq_ball (ε : ℝ) (x : α) : UniformSpace.ball x { p \| dist p.2 p.1 < ε } = Metric.ball x ε := rfl theorem ball_eq_ball' (ε : ℝ) (x : α) : UniformSpace.ball x { p \| dist p.1 p.2 < ε } = Metric.ball x ε := by ext simp [dist_comm, UniformSpace.ball] @[simp] theorem iUnion_ball_nat (x : α) : ⋃ n : ℕ, ball x n = univ := iUnion_eq_univ_iff.2 fun y => exists_nat_gt (dist y x) @[simp] theorem iUnion_ball_nat_succ (x : α) : ⋃ n : ℕ, ball x (n + 1) = univ := iUnion_eq_univ_iff.2 fun y => (exists_nat_gt (dist y x)).imp fun _ h => h.trans (lt_add_one _) /-- `closedBall x ε` is the set of all points `y` with `dist y x ≤ ε` -/ def closedBall (x : α) (ε : ℝ) := { y \| dist y x ≤ ε } @[simp] theorem mem_closedBall : y ∈ closedBall x ε ↔ dist y x ≤ ε := Iff.rfl theorem mem_closedBall' : y ∈ closedBall x ε ↔ dist x y ≤ ε := by rw [dist_comm, mem_closedBall] /-- `sphere x ε` is the set of all points `y` with `dist y x = ε` -/ def sphere (x : α) (ε : ℝ) := { y \| dist y x = ε } @[simp] theorem mem_sphere : y ∈ sphere x ε ↔ dist y x = ε := Iff.rfl theorem mem_sphere' : y ∈ sphere x ε ↔ dist x y = ε := by rw [dist_comm, mem_sphere] theorem ne_of_mem_sphere (h : y ∈ sphere x ε) (hε : ε ≠ 0) : y ≠ x := ne_of_mem_of_not_mem h <\| by simpa using hε.symm theorem nonneg_of_mem_sphere (hy : y ∈ sphere x ε) : 0 ≤ ε := dist_nonneg.trans_eq hy @[simp] theorem sphere_eq_empty_of_neg (hε : ε < 0) : sphere x ε = ∅ := Set.eq_empty_iff_forall_not_mem.mpr fun _y hy => (nonneg_of_mem_sphere hy).not_lt hε theorem sphere_eq_empty_of_subsingleton [Subsingleton α] (hε : ε ≠ 0) : sphere x ε = ∅ := Set.eq_empty_iff_forall_not_mem.mpr fun _ h => ne_of_mem_sphere h hε (Subsingleton.elim _ _) instance sphere_isEmpty_of_subsingleton [Subsingleton α] [NeZero ε] : IsEmpty (sphere x ε) := by rw [sphere_eq_empty_of_subsingleton (NeZero.ne ε)]; infer_instance theorem closedBall_eq_singleton_of_subsingleton [Subsingleton α] (h : 0 ≤ ε) : closedBall x ε = {x} := by ext x' simpa [Subsingleton.allEq x x'] theorem ball_eq_singleton_of_subsingleton [Subsingleton α] (h : 0 < ε) : ball x ε = {x} := by ext x' simpa [Subsingleton.allEq x x'] theorem mem_closedBall_self (h : 0 ≤ ε) : x ∈ closedBall x ε := by rwa [mem_closedBall, dist_self] @[simp] theorem nonempty_closedBall : (closedBall x ε).Nonempty ↔ 0 ≤ ε := ⟨fun ⟨_x, hx⟩ => dist_nonneg.trans hx, fun h => ⟨x, mem_closedBall_self h⟩⟩ @[simp] theorem closedBall_eq_empty : closedBall x ε = ∅ ↔ ε < 0 := by rw [← not_nonempty_iff_eq_empty, nonempty_closedBall, not_le] /-- Closed balls and spheres coincide when the radius is non-positive -/ theorem closedBall_eq_sphere_of_nonpos (hε : ε ≤ 0) : closedBall x ε = sphere x ε := Set.ext fun _ => (hε.trans dist_nonneg).le_iff_eq theorem ball_subset_closedBall : ball x ε ⊆ closedBall x ε := fun _y hy => mem_closedBall.2 (le_of_lt hy) theorem sphere_subset_closedBall : sphere x ε ⊆ closedBall x ε := fun _ => le_of_eq lemma sphere_subset_ball {r R : ℝ} (h : r < R) : sphere x r ⊆ ball x R := fun _x hx ↦ (mem_sphere.1 hx).trans_lt h theorem closedBall_disjoint_ball (h : δ + ε ≤ dist x y) : Disjoint (closedBall x δ) (ball y ε) := Set.disjoint_left.mpr fun _a ha1 ha2 => (h.trans <\| dist_triangle_left _ _ _).not_lt <\| add_lt_add_of_le_of_lt ha1 ha2 theorem ball_disjoint_closedBall (h : δ + ε ≤ dist x y) : Disjoint (ball x δ) (closedBall y ε) := (closedBall_disjoint_ball <\| by rwa [add_comm, dist_comm]).symm theorem ball_disjoint_ball (h : δ + ε ≤ dist x y) : Disjoint (ball x δ) (ball y ε) := (closedBall_disjoint_ball h).mono_left ball_subset_closedBall theorem closedBall_disjoint_closedBall (h : δ + ε < dist x y) : Disjoint (closedBall x δ) (closedBall y ε) := Set.disjoint_left.mpr fun _a ha1 ha2 => h.not_le <\| (dist_triangle_left _ _ _).trans <\| add_le_add ha1 ha2 theorem sphere_disjoint_ball : Disjoint (sphere x ε) (ball x ε) := Set.disjoint_left.mpr fun _y hy₁ hy₂ => absurd hy₁ <\| ne_of_lt hy₂ @[simp] theorem ball_union_sphere : ball x ε ∪ sphere x ε = closedBall x ε := Set.ext fun _y => (@le_iff_lt_or_eq ℝ _ _ _).symm @[simp] theorem sphere_union_ball : sphere x ε ∪ ball x ε = closedBall x ε := by rw [union_comm, ball_union_sphere] @[simp] theorem closedBall_diff_sphere : closedBall x ε \ sphere x ε = ball x ε := by rw [← ball_union_sphere, Set.union_diff_cancel_right sphere_disjoint_ball.symm.le_bot] @[simp] theorem closedBall_diff_ball : closedBall x ε \ ball x ε = sphere x ε := by rw [← ball_union_sphere, Set.union_diff_cancel_left sphere_disjoint_ball.symm.le_bot] theorem mem_ball_comm : x ∈ ball y ε ↔ y ∈ ball x ε := by rw [mem_ball', mem_ball] theorem mem_closedBall_comm : x ∈ closedBall y ε ↔ y ∈ closedBall x ε := by rw [mem_closedBall', mem_closedBall] theorem mem_sphere_comm : x ∈ sphere y ε ↔ y ∈ sphere x ε := by rw [mem_sphere', mem_sphere] @[gcongr] theorem ball_subset_ball (h : ε₁ ≤ ε₂) : ball x ε₁ ⊆ ball x ε₂ := fun _y yx => lt_of_lt_of_le (mem_ball.1 yx) h theorem closedBall_eq_bInter_ball : closedBall x ε = ⋂ δ > ε, ball x δ := by ext y; rw [mem_closedBall, ← forall_lt_iff_le', mem_iInter₂]; rfl theorem ball_subset_ball' (h : ε₁ + dist x y ≤ ε₂) : ball x ε₁ ⊆ ball y ε₂ := fun z hz => calc dist z y ≤ dist z x + dist x y := dist_triangle _ _ _ _ < ε₁ + dist x y := add_lt_add_right (mem_ball.1 hz) _ _ ≤ ε₂ := h @[gcongr] theorem closedBall_subset_closedBall (h : ε₁ ≤ ε₂) : closedBall x ε₁ ⊆ closedBall x ε₂ := fun _y (yx : _ ≤ ε₁) => le_trans yx h theorem closedBall_subset_closedBall' (h : ε₁ + dist x y ≤ ε₂) : closedBall x ε₁ ⊆ closedBall y ε₂ := fun z hz => calc dist z y ≤ dist z x + dist x y := dist_triangle _ _ _ _ ≤ ε₁ + dist x y := add_le_add_right (mem_closedBall.1 hz) _ _ ≤ ε₂ := h theorem closedBall_subset_ball (h : ε₁ < ε₂) : closedBall x ε₁ ⊆ ball x ε₂ := fun y (yh : dist y x ≤ ε₁) => lt_of_le_of_lt yh h theorem closedBall_subset_ball' (h : ε₁ + dist x y < ε₂) : closedBall x ε₁ ⊆ ball y ε₂ := fun z hz => calc dist z y ≤ dist z x + dist x y := dist_triangle _ _ _ _ ≤ ε₁ + dist x y := add_le_add_right (mem_closedBall.1 hz) _ _ < ε₂ := h theorem dist_le_add_of_nonempty_closedBall_inter_closedBall (h : (closedBall x ε₁ ∩ closedBall y ε₂).Nonempty) : dist x y ≤ ε₁ + ε₂ := let ⟨z, hz⟩ := h calc dist x y ≤ dist z x + dist z y := dist_triangle_left _ _ _ _ ≤ ε₁ + ε₂ := add_le_add hz.1 hz.2 theorem dist_lt_add_of_nonempty_closedBall_inter_ball (h : (closedBall x ε₁ ∩ ball y ε₂).Nonempty) : dist x y < ε₁ + ε₂ := let ⟨z, hz⟩ := h calc dist x y ≤ dist z x + dist z y := dist_triangle_left _ _ _ _ < ε₁ + ε₂ := add_lt_add_of_le_of_lt hz.1 hz.2 theorem dist_lt_add_of_nonempty_ball_inter_closedBall (h : (ball x ε₁ ∩ closedBall y ε₂).Nonempty) : dist x y < ε₁ + ε₂ := by rw [inter_comm] at h rw [add_comm, dist_comm] exact dist_lt_add_of_nonempty_closedBall_inter_ball h theorem dist_lt_add_of_nonempty_ball_inter_ball (h : (ball x ε₁ ∩ ball y ε₂).Nonempty) : dist x y < ε₁ + ε₂ := dist_lt_add_of_nonempty_closedBall_inter_ball <\| h.mono (inter_subset_inter ball_subset_closedBall Subset.rfl) @[simp] theorem iUnion_closedBall_nat (x : α) : ⋃ n : ℕ, closedBall x n = univ := iUnion_eq_univ_iff.2 fun y => exists_nat_ge (dist y x) theorem iUnion_inter_closedBall_nat (s : Set α) (x : α) : ⋃ n : ℕ, s ∩ closedBall x n = s := by rw [← inter_iUnion, iUnion_closedBall_nat, inter_univ] theorem ball_subset (h : dist x y ≤ ε₂ - ε₁) : ball x ε₁ ⊆ ball y ε₂ := fun z zx => by rw [← add_sub_cancel ε₁ ε₂] exact lt_of_le_of_lt (dist_triangle z x y) (add_lt_add_of_lt_of_le zx h) theorem ball_half_subset (y) (h : y ∈ ball x (ε / 2)) : ball y (ε / 2) ⊆ ball x ε := ball_subset <\| by rw [sub_self_div_two]; exact le_of_lt h theorem exists_ball_subset_ball (h : y ∈ ball x ε) : ∃ ε' > 0, ball y ε' ⊆ ball x ε := ⟨_, sub_pos.2 h, ball_subset <\| by rw [sub_sub_self]⟩ /-- If a property holds for all points in closed balls of arbitrarily large radii, then it holds for all points. -/ theorem forall_of_forall_mem_closedBall (p : α → Prop) (x : α) (H : ∃ᶠ R : ℝ in atTop, ∀ y ∈ closedBall x R, p y) (y : α) : p y := by obtain ⟨R, hR, h⟩ : ∃ R ≥ dist y x, ∀ z : α, z ∈ closedBall x R → p z := frequently_iff.1 H (Ici_mem_atTop (dist y x)) exact h _ hR /-- If a property holds for all points in balls of arbitrarily large radii, then it holds for all points. -/ theorem forall_of_forall_mem_ball (p : α → Prop) (x : α) (H : ∃ᶠ R : ℝ in atTop, ∀ y ∈ ball x R, p y) (y : α) : p y := by obtain ⟨R, hR, h⟩ : ∃ R > dist y x, ∀ z : α, z ∈ ball x R → p z := frequently_iff.1 H (Ioi_mem_atTop (dist y x)) exact h _ hR theorem isBounded_iff {s : Set α} : IsBounded s ↔ ∃ C : ℝ, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C := by rw [isBounded_def, ← Filter.mem_sets, @PseudoMetricSpace.cobounded_sets α, mem_setOf_eq, compl_compl] theorem isBounded_iff_eventually {s : Set α} : IsBounded s ↔ ∀ᶠ C in atTop, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C := isBounded_iff.trans ⟨fun ⟨C, h⟩ => eventually_atTop.2 ⟨C, fun _C' hC' _x hx _y hy => (h hx hy).trans hC'⟩, Eventually.exists⟩ theorem isBounded_iff_exists_ge {s : Set α} (c : ℝ) : IsBounded s ↔ ∃ C, c ≤ C ∧ ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → dist x y ≤ C := ⟨fun h => ((eventually_ge_atTop c).and (isBounded_iff_eventually.1 h)).exists, fun h => isBounded_iff.2 <\| h.imp fun _ => And.right⟩ theorem isBounded_iff_nndist {s : Set α} : IsBounded s ↔ ∃ C : ℝ≥0, ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → nndist x y ≤ C := by simp only [isBounded_iff_exists_ge 0, NNReal.exists, ← NNReal.coe_le_coe, ← dist_nndist, NNReal.coe_mk, exists_prop] theorem toUniformSpace_eq : ‹PseudoMetricSpace α›.toUniformSpace = .ofDist dist dist_self dist_comm dist_triangle := UniformSpace.ext PseudoMetricSpace.uniformity_dist theorem uniformity_basis_dist : (𝓤 α).HasBasis (fun ε : ℝ => 0 < ε) fun ε => { p : α × α \| dist p.1 p.2 < ε } := by rw [toUniformSpace_eq] exact UniformSpace.hasBasis_ofFun (exists_gt _) _ _ _ _ _ /-- Given `f : β → ℝ`, if `f` sends `{i \| p i}` to a set of positive numbers accumulating to zero, then `f i`-neighborhoods of the diagonal form a basis of `𝓤 α`. For specific bases see `uniformity_basis_dist`, `uniformity_basis_dist_inv_nat_succ`, and `uniformity_basis_dist_inv_nat_pos`. -/ protected theorem mk_uniformity_basis {β : Type} {p : β → Prop} {f : β → ℝ} (hf₀ : ∀ i, p i → 0 < f i) (hf : ∀ ⦃ε⦄, 0 < ε → ∃ i, p i ∧ f i ≤ ε) : (𝓤 α).HasBasis p fun i => { p : α × α \| dist p.1 p.2 < f i } := by refine ⟨fun s => uniformity_basis_dist.mem_iff.trans ?_⟩ constructor · rintro ⟨ε, ε₀, hε⟩ rcases hf ε₀ with ⟨i, hi, H⟩ exact ⟨i, hi, fun x (hx : _ < _) => hε <\| lt_of_lt_of_le hx H⟩ · exact fun ⟨i, hi, H⟩ => ⟨f i, hf₀ i hi, H⟩ theorem uniformity_basis_dist_rat : (𝓤 α).HasBasis (fun r : ℚ => 0 < r) fun r => { p : α × α \| dist p.1 p.2 < r } := Metric.mk_uniformity_basis (fun _ => Rat.cast_pos.2) fun _ε hε => let ⟨r, hr0, hrε⟩ := exists_rat_btwn hε ⟨r, Rat.cast_pos.1 hr0, hrε.le⟩ theorem uniformity_basis_dist_inv_nat_succ : (𝓤 α).HasBasis (fun _ => True) fun n : ℕ => { p : α × α \| dist p.1 p.2 < 1 / (↑n + 1) } := Metric.mk_uniformity_basis (fun n _ => div_pos zero_lt_one <\| Nat.cast_add_one_pos n) fun _ε ε0 => (exists_nat_one_div_lt ε0).imp fun _n hn => ⟨trivial, le_of_lt hn⟩ theorem uniformity_basis_dist_inv_nat_pos : (𝓤 α).HasBasis (fun n : ℕ => 0 < n) fun n : ℕ => { p : α × α \| dist p.1 p.2 < 1 / ↑n } := Metric.mk_uniformity_basis (fun _ hn => div_pos zero_lt_one <\| Nat.cast_pos.2 hn) fun _ ε0 => let ⟨n, hn⟩ := exists_nat_one_div_lt ε0 ⟨n + 1, Nat.succ_pos n, mod_cast hn.le⟩ theorem uniformity_basis_dist_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓤 α).HasBasis (fun _ : ℕ => True) fun n : ℕ => { p : α × α \| dist p.1 p.2 < r ^ n } := Metric.mk_uniformity_basis (fun _ _ => pow_pos h0 _) fun _ε ε0 => let ⟨n, hn⟩ := exists_pow_lt_of_lt_one ε0 h1 ⟨n, trivial, hn.le⟩ theorem uniformity_basis_dist_lt {R : ℝ} (hR : 0 < R) : (𝓤 α).HasBasis (fun r : ℝ => 0 < r ∧ r < R) fun r => { p : α × α \| dist p.1 p.2 < r } := Metric.mk_uniformity_basis (fun _ => And.left) fun r hr => ⟨min r (R / 2), ⟨lt_min hr (half_pos hR), min_lt_iff.2 <\| Or.inr (half_lt_self hR)⟩, min_le_left _ _⟩ /-- Given `f : β → ℝ`, if `f` sends `{i \| p i}` to a set of positive numbers accumulating to zero, then closed neighborhoods of the diagonal of sizes `{f i \| p i}` form a basis of `𝓤 α`. Currently we have only one specific basis `uniformity_basis_dist_le` based on this constructor. More can be easily added if needed in the future. -/ protected theorem mk_uniformity_basis_le {β : Type} {p : β → Prop} {f : β → ℝ} (hf₀ : ∀ x, p x → 0 < f x) (hf : ∀ ε, 0 < ε → ∃ x, p x ∧ f x ≤ ε) : (𝓤 α).HasBasis p fun x => { p : α × α \| dist p.1 p.2 ≤ f x } := by refine ⟨fun s => uniformity_basis_dist.mem_iff.trans ?_⟩ constructor · rintro ⟨ε, ε₀, hε⟩ rcases exists_between ε₀ with ⟨ε', hε'⟩ rcases hf ε' hε'.1 with ⟨i, hi, H⟩ exact ⟨i, hi, fun x (hx : _ ≤ _) => hε <\| lt_of_le_of_lt (le_trans hx H) hε'.2⟩ · exact fun ⟨i, hi, H⟩ => ⟨f i, hf₀ i hi, fun x (hx : _ < _) => H (mem_setOf.2 hx.le)⟩ /-- Constant size closed neighborhoods of the diagonal form a basis of the uniformity filter. -/ theorem uniformity_basis_dist_le : (𝓤 α).HasBasis ((0 : ℝ) < ·) fun ε => { p : α × α \| dist p.1 p.2 ≤ ε } := Metric.mk_uniformity_basis_le (fun _ => id) fun ε ε₀ => ⟨ε, ε₀, le_refl ε⟩ theorem uniformity_basis_dist_le_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓤 α).HasBasis (fun _ : ℕ => True) fun n : ℕ => { p : α × α \| dist p.1 p.2 ≤ r ^ n } := Metric.mk_uniformity_basis_le (fun _ _ => pow_pos h0 _) fun _ε ε0 => let ⟨n, hn⟩ := exists_pow_lt_of_lt_one ε0 h1 ⟨n, trivial, hn.le⟩ theorem mem_uniformity_dist {s : Set (α × α)} : s ∈ 𝓤 α ↔ ∃ ε > 0, ∀ ⦃a b : α⦄, dist a b < ε → (a, b) ∈ s := uniformity_basis_dist.mem_uniformity_iff /-- A constant size neighborhood of the diagonal is an entourage. -/ theorem dist_mem_uniformity {ε : ℝ} (ε0 : 0 < ε) : { p : α × α \| dist p.1 p.2 < ε } ∈ 𝓤 α := mem_uniformity_dist.2 ⟨ε, ε0, fun _ _ ↦ id⟩ theorem uniformContinuous_iff [PseudoMetricSpace β] {f : α → β} : UniformContinuous f ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃a b : α⦄, dist a b < δ → dist (f a) (f b) < ε := uniformity_basis_dist.uniformContinuous_iff uniformity_basis_dist theorem uniformContinuousOn_iff [PseudoMetricSpace β] {f : α → β} {s : Set α} : UniformContinuousOn f s ↔ ∀ ε > 0, ∃ δ > 0, ∀ x ∈ s, ∀ y ∈ s, dist x y < δ → dist (f x) (f y) < ε := Metric.uniformity_basis_dist.uniformContinuousOn_iff Metric.uniformity_basis_dist theorem uniformContinuousOn_iff_le [PseudoMetricSpace β] {f : α → β} {s : Set α} : UniformContinuousOn f s ↔ ∀ ε > 0, ∃ δ > 0, ∀ x ∈ s, ∀ y ∈ s, dist x y ≤ δ → dist (f x) (f y) ≤ ε := Metric.uniformity_basis_dist_le.uniformContinuousOn_iff Metric.uniformity_basis_dist_le theorem nhds_basis_ball : (𝓝 x).HasBasis (0 < ·) (ball x) := nhds_basis_uniformity uniformity_basis_dist theorem mem_nhds_iff : s ∈ 𝓝 x ↔ ∃ ε > 0, ball x ε ⊆ s := nhds_basis_ball.mem_iff theorem eventually_nhds_iff {p : α → Prop} : (∀ᶠ y in 𝓝 x, p y) ↔ ∃ ε > 0, ∀ ⦃y⦄, dist y x < ε → p y := mem_nhds_iff theorem eventually_nhds_iff_ball {p : α → Prop} : (∀ᶠ y in 𝓝 x, p y) ↔ ∃ ε > 0, ∀ y ∈ ball x ε, p y := mem_nhds_iff /-- A version of `Filter.eventually_prod_iff` where the first filter consists of neighborhoods in a pseudo-metric space. -/ theorem eventually_nhds_prod_iff {f : Filter ι} {x₀ : α} {p : α × ι → Prop} : (∀ᶠ x in 𝓝 x₀ ×ˢ f, p x) ↔ ∃ ε > (0 : ℝ), ∃ pa : ι → Prop, (∀ᶠ i in f, pa i) ∧ ∀ ⦃x⦄, dist x x₀ < ε → ∀ ⦃i⦄, pa i → p (x, i) := by refine (nhds_basis_ball.prod f.basis_sets).eventually_iff.trans ?_ simp only [Prod.exists, forall_prod_set, id, mem_ball, and_assoc, exists_and_left, and_imp] rfl /-- A version of `Filter.eventually_prod_iff` where the second filter consists of neighborhoods in a pseudo-metric space. -/ theorem eventually_prod_nhds_iff {f : Filter ι} {x₀ : α} {p : ι × α → Prop} : (∀ᶠ x in f ×ˢ 𝓝 x₀, p x) ↔ ∃ pa : ι → Prop, (∀ᶠ i in f, pa i) ∧ ∃ ε > 0, ∀ ⦃i⦄, pa i → ∀ ⦃x⦄, dist x x₀ < ε → p (i, x) := by rw [eventually_swap_iff, Metric.eventually_nhds_prod_iff] constructor <;> · rintro ⟨a1, a2, a3, a4, a5⟩ exact ⟨a3, a4, a1, a2, fun _ b1 b2 b3 => a5 b3 b1⟩ theorem nhds_basis_closedBall : (𝓝 x).HasBasis (fun ε : ℝ => 0 < ε) (closedBall x) := nhds_basis_uniformity uniformity_basis_dist_le theorem nhds_basis_ball_inv_nat_succ : (𝓝 x).HasBasis (fun _ => True) fun n : ℕ => ball x (1 / (↑n + 1)) := nhds_basis_uniformity uniformity_basis_dist_inv_nat_succ theorem nhds_basis_ball_inv_nat_pos : (𝓝 x).HasBasis (fun n => 0 < n) fun n : ℕ => ball x (1 / ↑n) := nhds_basis_uniformity uniformity_basis_dist_inv_nat_pos theorem nhds_basis_ball_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓝 x).HasBasis (fun _ => True) fun n : ℕ => ball x (r ^ n) := nhds_basis_uniformity (uniformity_basis_dist_pow h0 h1) theorem nhds_basis_closedBall_pow {r : ℝ} (h0 : 0 < r) (h1 : r < 1) : (𝓝 x).HasBasis (fun _ => True) fun n : ℕ => closedBall x (r ^ n) := nhds_basis_uniformity (uniformity_basis_dist_le_pow h0 h1) theorem isOpen_iff : IsOpen s ↔ ∀ x ∈ s, ∃ ε > 0, ball x ε ⊆ s := by simp only [isOpen_iff_mem_nhds, mem_nhds_iff] @[simp] theorem isOpen_ball : IsOpen (ball x ε) := isOpen_iff.2 fun _ => exists_ball_subset_ball theorem ball_mem_nhds (x : α) {ε : ℝ} (ε0 : 0 < ε) : ball x ε ∈ 𝓝 x := isOpen_ball.mem_nhds (mem_ball_self ε0) theorem closedBall_mem_nhds (x : α) {ε : ℝ} (ε0 : 0 < ε) : closedBall x ε ∈ 𝓝 x := mem_of_superset (ball_mem_nhds x ε0) ball_subset_closedBall theorem closedBall_mem_nhds_of_mem {x c : α} {ε : ℝ} (h : x ∈ ball c ε) : closedBall c ε ∈ 𝓝 x := mem_of_superset (isOpen_ball.mem_nhds h) ball_subset_closedBall theorem nhdsWithin_basis_ball {s : Set α} : (𝓝[s] x).HasBasis (fun ε : ℝ => 0 < ε) fun ε => ball x ε ∩ s := nhdsWithin_hasBasis nhds_basis_ball s theorem mem_nhdsWithin_iff {t : Set α} : s ∈ 𝓝[t] x ↔ ∃ ε > 0, ball x ε ∩ t ⊆ s := nhdsWithin_basis_ball.mem_iff theorem tendsto_nhdsWithin_nhdsWithin [PseudoMetricSpace β] {t : Set β} {f : α → β} {a b} : Tendsto f (𝓝[s] a) (𝓝[t] b) ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, x ∈ s → dist x a < δ → f x ∈ t ∧ dist (f x) b < ε := (nhdsWithin_basis_ball.tendsto_iff nhdsWithin_basis_ball).trans <\| by simp only [inter_comm _ s, inter_comm _ t, mem_inter_iff, and_imp, gt_iff_lt, mem_ball] theorem tendsto_nhdsWithin_nhds [PseudoMetricSpace β] {f : α → β} {a b} : Tendsto f (𝓝[s] a) (𝓝 b) ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, x ∈ s → dist x a < δ → dist (f x) b < ε := by rw [← nhdsWithin_univ b, tendsto_nhdsWithin_nhdsWithin] simp only [mem_univ, true_and] theorem tendsto_nhds_nhds [PseudoMetricSpace β] {f : α → β} {a b} : Tendsto f (𝓝 a) (𝓝 b) ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, dist x a < δ → dist (f x) b < ε := nhds_basis_ball.tendsto_iff nhds_basis_ball theorem continuousAt_iff [PseudoMetricSpace β] {f : α → β} {a : α} : ContinuousAt f a ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, dist x a < δ → dist (f x) (f a) < ε := by rw [ContinuousAt, tendsto_nhds_nhds] theorem continuousWithinAt_iff [PseudoMetricSpace β] {f : α → β} {a : α} {s : Set α} : ContinuousWithinAt f s a ↔ ∀ ε > 0, ∃ δ > 0, ∀ ⦃x : α⦄, x ∈ s → dist x a < δ → dist (f x) (f a) < ε := by rw [ContinuousWithinAt, tendsto_nhdsWithin_nhds] theorem continuousOn_iff [PseudoMetricSpace β] {f : α → β} {s : Set α} : ContinuousOn f s ↔ ∀ b ∈ s, ∀ ε > 0, ∃ δ > 0, ∀ a ∈ s, dist a b < δ → dist (f a) (f b) < ε := by simp [ContinuousOn, continuousWithinAt_iff] theorem continuous_iff [PseudoMetricSpace β] {f : α → β} : Continuous f ↔ ∀ b, ∀ ε > 0, ∃ δ > 0, ∀ a, dist a b < δ → dist (f a) (f b) < ε := continuous_iff_continuousAt.trans <\| forall_congr' fun _ => tendsto_nhds_nhds theorem tendsto_nhds {f : Filter β} {u : β → α} {a : α} : Tendsto u f (𝓝 a) ↔ ∀ ε > 0, ∀ᶠ x in f, dist (u x) a < ε := nhds_basis_ball.tendsto_right_iff theorem continuousAt_iff' [TopologicalSpace β] {f : β → α} {b : β} : ContinuousAt f b ↔ ∀ ε > 0, ∀ᶠ x in 𝓝 b, dist (f x) (f b) < ε := by rw [ContinuousAt, tendsto_nhds] theorem continuousWithinAt_iff' [TopologicalSpace β] {f : β → α} {b : β} {s : Set β} : ContinuousWithinAt f s b ↔ ∀ ε > 0, ∀ᶠ x in 𝓝[s] b, dist (f x) (f b) < ε := by rw [ContinuousWithinAt, tendsto_nhds] theorem continuousOn_iff' [TopologicalSpace β] {f : β → α} {s : Set β} : ContinuousOn f s ↔ ∀ b ∈ s, ∀ ε > 0, ∀ᶠ x in 𝓝[s] b, dist (f x) (f b) < ε := by simp [ContinuousOn, continuousWithinAt_iff'] theorem continuous_iff' [TopologicalSpace β] {f : β → α} : Continuous f ↔ ∀ (a), ∀ ε > 0, ∀ᶠ x in 𝓝 a, dist (f x) (f a) < ε := continuous_iff_continuousAt.trans <\| forall_congr' fun _ => tendsto_nhds theorem tendsto_atTop [Nonempty β] [SemilatticeSup β] {u : β → α} {a : α} : Tendsto u atTop (𝓝 a) ↔ ∀ ε > 0, ∃ N, ∀ n ≥ N, dist (u n) a < ε := (atTop_basis.tendsto_iff nhds_basis_ball).trans <\| by simp only [true_and, mem_ball, mem_Ici] /-- A variant of `tendsto_atTop` that uses `∃ N, ∀ n > N, ...` rather than `∃ N, ∀ n ≥ N, ...` -/ theorem tendsto_atTop' [Nonempty β] [SemilatticeSup β] [NoMaxOrder β] {u : β → α} {a : α} : Tendsto u atTop (𝓝 a) ↔ ∀ ε > 0, ∃ N, ∀ n > N, dist (u n) a < ε := (atTop_basis_Ioi.tendsto_iff nhds_basis_ball).trans <\| by simp only [true_and, gt_iff_lt, mem_Ioi, mem_ball] theorem isOpen_singleton_iff {α : Type} [PseudoMetricSpace α] {x : α} : IsOpen ({x} : Set α) ↔ ∃ ε > 0, ∀ y, dist y x < ε → y = x := by simp [isOpen_iff, subset_singleton_iff, mem_ball] theorem _root_.Dense.exists_dist_lt {s : Set α} (hs : Dense s) (x : α) {ε : ℝ} (hε : 0 < ε) : ∃ y ∈ s, dist x y < ε := by have : (ball x ε).Nonempty := by simp [hε] simpa only [mem_ball'] using hs.exists_mem_open isOpen_ball this nonrec theorem _root_.DenseRange.exists_dist_lt {β : Type*} {f : β → α} (hf : DenseRange f) (x : α) {ε : ℝ} (hε : 0 < ε) : ∃ y, dist x (f y) < ε := exists_range_iff.1 (hf.exists_dist_lt x hε) /-- (Pseudo) metric space has discrete `UniformSpace` structure iff the distances between distinct points are uniformly bounded away from zero. -/ protected lemma uniformSpace_eq_bot : ‹PseudoMetricSpace α›.toUniformSpace = ⊥ ↔ ∃ r : ℝ, 0 < r ∧ Pairwise (r ≤ dist · · : α → α → Prop) := by simp only [uniformity_basis_dist.uniformSpace_eq_bot, mem_setOf_eq, not_lt] end Metric open Metric /-- If the distances between distinct points in a (pseudo) metric space are uniformly bounded away from zero, then the space has discrete topology. -/ lemma DiscreteTopology.of_forall_le_dist {α} [PseudoMetricSpace α] {r : ℝ} (hpos : 0 < r) (hr : Pairwise (r ≤ dist · · : α → α → Prop)) : DiscreteTopology α := ⟨by rw [Metric.uniformSpace_eq_bot.2 ⟨r, hpos, hr⟩, UniformSpace.toTopologicalSpace_bot]⟩ /- Instantiate a pseudometric space as a pseudoemetric space. Before we can state the instance, we need to show that the uniform structure coming from the edistance and the distance coincide. -/ theorem Metric.uniformity_edist_aux {α} (d : α → α → ℝ≥0) : ⨅ ε > (0 : ℝ), 𝓟 { p : α × α \| ↑(d p.1 p.2) < ε } = ⨅ ε > (0 : ℝ≥0∞), 𝓟 { p : α × α \| ↑(d p.1 p.2) < ε } := by simp only [le_antisymm_iff, le_iInf_iff, le_principal_iff] refine ⟨fun ε hε => ?_, fun ε hε => ?_⟩ · rcases ENNReal.lt_iff_exists_nnreal_btwn.1 hε with ⟨ε', ε'0, ε'ε⟩ refine mem_iInf_of_mem (ε' : ℝ) (mem_iInf_of_mem (ENNReal.coe_pos.1 ε'0) ?_) exact fun x hx => lt_trans (ENNReal.coe_lt_coe.2 hx) ε'ε · lift ε to ℝ≥0 using le_of_lt hε refine mem_iInf_of_mem (ε : ℝ≥0∞) (mem_iInf_of_mem (ENNReal.coe_pos.2 hε) ?_) exact fun _ => ENNReal.coe_lt_coe.1 theorem Metric.uniformity_edist : 𝓤 α = ⨅ ε > 0, 𝓟 { p : α × α \| edist p.1 p.2 < ε } := by simp only [PseudoMetricSpace.uniformity_dist, dist_nndist, edist_nndist, Metric.uniformity_edist_aux] -- see Note [lower instance priority] /-- A pseudometric space induces a pseudoemetric space -/ instance (priority := 100) PseudoMetricSpace.toPseudoEMetricSpace : PseudoEMetricSpace α := { ‹PseudoMetricSpace α› with edist_self := by simp [edist_dist] edist_comm := fun _ _ => by simp only [edist_dist, dist_comm] edist_triangle := fun x y z => by simp only [edist_dist, ← ENNReal.ofReal_add, dist_nonneg] rw [ENNReal.ofReal_le_ofReal_iff _] · exact dist_triangle _ _ _ · simpa using add_le_add (dist_nonneg : 0 ≤ dist x y) dist_nonneg uniformity_edist := Metric.uniformity_edist } /-- In a pseudometric space, an open ball of infinite radius is the whole space -/ theorem Metric.eball_top_eq_univ (x : α) : EMetric.ball x ∞ = Set.univ := Set.eq_univ_iff_forall.mpr fun y => edist_lt_top y x /-- Balls defined using the distance or the edistance coincide -/ @[simp] theorem Metric.emetric_ball {x : α} {ε : ℝ} : EMetric.ball x (ENNReal.ofReal ε) = ball x ε := by ext y simp only [EMetric.mem_ball, mem_ball, edist_dist] exact ENNReal.ofReal_lt_ofReal_iff_of_nonneg dist_nonneg /-- Balls defined using the distance or the edistance coincide -/ @[simp] theorem Metric.emetric_ball_nnreal {x : α} {ε : ℝ≥0} : EMetric.ball x ε = ball x ε := by rw [← Metric.emetric_ball] simp /-- Closed balls defined using the distance or the edistance coincide -/ theorem Metric.emetric_closedBall {x : α} {ε : ℝ} (h : 0 ≤ ε) : EMetric.closedBall x (ENNReal.ofReal ε) = closedBall x ε := by ext y; simp [edist_le_ofReal h] /-- Closed balls defined using the distance or the edistance coincide -/ @[simp] theorem Metric.emetric_closedBall_nnreal {x : α} {ε : ℝ≥0} : EMetric.closedBall x ε = closedBall x ε := by rw [← Metric.emetric_closedBall ε.coe_nonneg, ENNReal.ofReal_coe_nnreal] @[simp] theorem Metric.emetric_ball_top (x : α) : EMetric.ball x ⊤ = univ := eq_univ_of_forall fun _ => edist_lt_top _ _ /-- Build a new pseudometric space from an old one where the bundled uniform structure is provably (but typically non-definitionaly) equal to some given uniform structure. See Note [forgetful inheritance]. See Note [reducible non-instances]. -/ abbrev PseudoMetricSpace.replaceUniformity {α} [U : UniformSpace α] (m : PseudoMetricSpace α) (H : 𝓤[U] = 𝓤[PseudoEMetricSpace.toUniformSpace]) : PseudoMetricSpace α := { m with toUniformSpace := U uniformity_dist := H.trans PseudoMetricSpace.uniformity_dist } theorem PseudoMetricSpace.replaceUniformity_eq {α} [U : UniformSpace α] (m : PseudoMetricSpace α) (H : 𝓤[U] = 𝓤[PseudoEMetricSpace.toUniformSpace]) : m.replaceUniformity H = m := by ext rfl -- ensure that the bornology is unchanged when replacing the uniformity. example {α} [U : UniformSpace α] (m : PseudoMetricSpace α) (H : 𝓤[U] = 𝓤[PseudoEMetricSpace.toUniformSpace]) : (PseudoMetricSpace.replaceUniformity m H).toBornology = m.toBornology := by with_reducible_and_instances rfl /-- Build a new pseudo metric space from an old one where the bundled topological structure is provably (but typically non-definitionaly) equal to some given topological structure. See Note [forgetful inheritance]. See Note [reducible non-instances]. -/ abbrev PseudoMetricSpace.replaceTopology {γ} [U : TopologicalSpace γ] (m : PseudoMetricSpace γ) (H : U = m.toUniformSpace.toTopologicalSpace) : PseudoMetricSpace γ := @PseudoMetricSpace.replaceUniformity γ (m.toUniformSpace.replaceTopology H) m rfl theorem PseudoMetricSpace.replaceTopology_eq {γ} [U : TopologicalSpace γ] (m : PseudoMetricSpace γ) (H : U = m.toUniformSpace.toTopologicalSpace) : m.replaceTopology H = m := by ext rfl /-- One gets a pseudometric space from an emetric space if the edistance is everywhere finite, by pushing the edistance to reals. We set it up so that the edist and the uniformity are defeq in the pseudometric space and the pseudoemetric space. In this definition, the distance is given separately, to be able to prescribe some expression which is not defeq to the push-forward of the edistance to reals. See note [reducible non-instances]. -/ abbrev PseudoEMetricSpace.toPseudoMetricSpaceOfDist {α : Type u} [e : PseudoEMetricSpace α] (dist : α → α → ℝ) (edist_ne_top : ∀ x y : α, edist x y ≠ ⊤) (h : ∀ x y, dist x y = ENNReal.toReal (edist x y)) : PseudoMetricSpace α where dist := dist dist_self x := by simp [h] dist_comm x y := by simp [h, edist_comm] dist_triangle x y z := by simp only [h] exact ENNReal.toReal_le_add (edist_triangle _ _ _) (edist_ne_top _ _) (edist_ne_top _ _) edist := edist edist_dist _ _ := by simp only [h, ENNReal.ofReal_toReal (edist_ne_top _ _)] toUniformSpace := e.toUniformSpace uniformity_dist := e.uniformity_edist.trans <\| by simpa only [ENNReal.coe_toNNReal (edist_ne_top _ _), h] using (Metric.uniformity_edist_aux fun x y : α => (edist x y).toNNReal).symm /-- One gets a pseudometric space from an emetric space if the edistance is everywhere finite, by pushing the edistance to reals. We set it up so that the edist and the uniformity are defeq in the pseudometric space and the emetric space. -/ abbrev PseudoEMetricSpace.toPseudoMetricSpace {α : Type u} [PseudoEMetricSpace α] (h : ∀ x y : α, edist x y ≠ ⊤) : PseudoMetricSpace α := PseudoEMetricSpace.toPseudoMetricSpaceOfDist (fun x y => ENNReal.toReal (edist x y)) h fun _ _ => rfl /-- Build a new pseudometric space from an old one where the bundled bornology structure is provably (but typically non-definitionaly) equal to some given bornology structure. See Note [forgetful inheritance]. See Note [reducible non-instances]. -/ abbrev PseudoMetricSpace.replaceBornology {α} [B : Bornology α] (m : PseudoMetricSpace α) (H : ∀ s, @IsBounded _ B s ↔ @IsBounded _ PseudoMetricSpace.toBornology s) : PseudoMetricSpace α := { m with toBornology := B cobounded_sets := Set.ext <\| compl_surjective.forall.2 fun s => (H s).trans <\| by rw [isBounded_iff, mem_setOf_eq, compl_compl] } theorem PseudoMetricSpace.replaceBornology_eq {α} [m : PseudoMetricSpace α] [B : Bornology α] (H : ∀ s, @IsBounded _ B s ↔ @IsBounded _ PseudoMetricSpace.toBornology s) : PseudoMetricSpace.replaceBornology _ H = m := by ext rfl -- ensure that the uniformity is unchanged when replacing the bornology. example {α} [B : Bornology α] (m : PseudoMetricSpace α) (H : ∀ s, @IsBounded _ B s ↔ @IsBounded _ PseudoMetricSpace.toBornology s) : (PseudoMetricSpace.replaceBornology m H).toUniformSpace = m.toUniformSpace := by with_reducible_and_instances rfl section Real /-- Instantiate the reals as a pseudometric space. -/ instance Real.pseudoMetricSpace : PseudoMetricSpace ℝ where dist x y := \|x - y\| dist_self := by simp [abs_zero] dist_comm _ _ := abs_sub_comm _ _ dist_triangle _ _ _ := abs_sub_le _ _ _ theorem Real.dist_eq (x y : ℝ) : dist x y = \|x - y\| := rfl theorem Real.nndist_eq (x y : ℝ) : nndist x y = Real.nnabs (x - y) := rfl theorem Real.nndist_eq' (x y : ℝ) : nndist x y = Real.nnabs (y - x) := nndist_comm _ _ theorem Real.dist_0_eq_abs (x : ℝ) : dist x 0 = \|x\| := by simp [Real.dist_eq] theorem Real.sub_le_dist (x y : ℝ) : x - y ≤ dist x y := by rw [Real.dist_eq, le_abs] exact Or.inl (le_refl _) theorem Real.ball_eq_Ioo (x r : ℝ) : ball x r = Ioo (x - r) (x + r) := Set.ext fun y => by rw [mem_ball, dist_comm, Real.dist_eq, abs_sub_lt_iff, mem_Ioo, ← sub_lt_iff_lt_add', sub_lt_comm] theorem Real.closedBall_eq_Icc {x r : ℝ} : closedBall x r = Icc (x - r) (x + r) := by ext y rw [mem_closedBall, dist_comm, Real.dist_eq, abs_sub_le_iff, mem_Icc, ← sub_le_iff_le_add', sub_le_comm] theorem Real.Ioo_eq_ball (x y : ℝ) : Ioo x y = ball ((x + y) / 2) ((y - x) / 2) := by rw [Real.ball_eq_Ioo, ← sub_div, add_comm, ← sub_add, add_sub_cancel_left, add_self_div_two, ← add_div, add_assoc, add_sub_cancel, add_self_div_two] theorem Real.Icc_eq_closedBall (x y : ℝ) : Icc x y = closedBall ((x + y) / 2) ((y - x) / 2) := by rw [Real.closedBall_eq_Icc, ← sub_div, add_comm, ← sub_add, add_sub_cancel_left, add_self_div_two, ← add_div, add_assoc, add_sub_cancel, add_self_div_two] theorem Metric.uniformity_eq_comap_nhds_zero : 𝓤 α = comap (fun p : α × α => dist p.1 p.2) (𝓝 (0 : ℝ)) := by ext s simp only [mem_uniformity_dist, (nhds_basis_ball.comap _).mem_iff] simp [subset_def, Real.dist_0_eq_abs] theorem tendsto_uniformity_iff_dist_tendsto_zero {f : ι → α × α} {p : Filter ι} : Tendsto f p (𝓤 α) ↔ Tendsto (fun x => dist (f x).1 (f x).2) p (𝓝 0) := by rw [Metric.uniformity_eq_comap_nhds_zero, tendsto_comap_iff, Function.comp_def] theorem Filter.Tendsto.congr_dist {f₁ f₂ : ι → α} {p : Filter ι} {a : α} (h₁ : Tendsto f₁ p (𝓝 a)) (h : Tendsto (fun x => dist (f₁ x) (f₂ x)) p (𝓝 0)) : Tendsto f₂ p (𝓝 a) := h₁.congr_uniformity <\| tendsto_uniformity_iff_dist_tendsto_zero.2 h alias tendsto_of_tendsto_of_dist := Filter.Tendsto.congr_dist theorem tendsto_iff_of_dist {f₁ f₂ : ι → α} {p : Filter ι} {a : α} (h : Tendsto (fun x => dist (f₁ x) (f₂ x)) p (𝓝 0)) : Tendsto f₁ p (𝓝 a) ↔ Tendsto f₂ p (𝓝 a) := Uniform.tendsto_congr <\| tendsto_uniformity_iff_dist_tendsto_zero.2 h end Real theorem PseudoMetricSpace.dist_eq_of_dist_zero (x : α) {y z : α} (h : dist y z = 0) : dist x y = dist x z := dist_comm y x ▸ dist_comm z x ▸ sub_eq_zero.1 (abs_nonpos_iff.1 (h ▸ abs_dist_sub_le y z x)) theorem dist_dist_dist_le_left (x y z : α) : dist (dist x z) (dist y z) ≤ dist x y := abs_dist_sub_le .. theorem dist_dist_dist_le_right (x y z : α) : dist (dist x y) (dist x z) ≤ dist y z := by simpa only [dist_comm x] using dist_dist_dist_le_left y z x theorem dist_dist_dist_le (x y x' y' : α) : dist (dist x y) (dist x' y') ≤ dist x x' + dist y y' := (dist_triangle _ _ _).trans <\| add_le_add (dist_dist_dist_le_left _ _ _) (dist_dist_dist_le_right _ _ _) theorem nhds_comap_dist (a : α) : ((𝓝 (0 : ℝ)).comap (dist · a)) = 𝓝 a := by simp only [@nhds_eq_comap_uniformity α, Metric.uniformity_eq_comap_nhds_zero, comap_comap, Function.comp_def, dist_comm] theorem tendsto_iff_dist_tendsto_zero {f : β → α} {x : Filter β} {a : α} : Tendsto f x (𝓝 a) ↔ Tendsto (fun b => dist (f b) a) x (𝓝 0) := by rw [← nhds_comap_dist a, tendsto_comap_iff, Function.comp_def] namespace Metric variable {x y z : α} {ε ε₁ ε₂ : ℝ} {s : Set α} theorem ball_subset_interior_closedBall : ball x ε ⊆ interior (closedBall x ε) := interior_maximal ball_subset_closedBall isOpen_ball /-- ε-characterization of the closure in pseudometric spaces -/ theorem mem_closure_iff {s : Set α} {a : α} : a ∈ closure s ↔ ∀ ε > 0, ∃ b ∈ s, dist a b < ε := (mem_closure_iff_nhds_basis nhds_basis_ball).trans <\| by simp only [mem_ball, dist_comm] theorem mem_closure_range_iff {e : β → α} {a : α} : a ∈ closure (range e) ↔ ∀ ε > 0, ∃ k : β, dist a (e k) < ε := by simp only [mem_closure_iff, exists_range_iff] theorem mem_closure_range_iff_nat {e : β → α} {a : α} : a ∈ closure (range e) ↔ ∀ n : ℕ, ∃ k : β, dist a (e k) < 1 / ((n : ℝ) + 1) := (mem_closure_iff_nhds_basis nhds_basis_ball_inv_nat_succ).trans <\| by simp only [mem_ball, dist_comm, exists_range_iff, forall_const] theorem mem_of_closed' {s : Set α} (hs : IsClosed s) {a : α} : a ∈ s ↔ ∀ ε > 0, ∃ b ∈ s, dist a b < ε := by simpa only [hs.closure_eq] using @mem_closure_iff _ _ s a theorem dense_iff {s : Set α} : Dense s ↔ ∀ x, ∀ r > 0, (ball x r ∩ s).Nonempty := forall_congr' fun x => by simp only [mem_closure_iff, Set.Nonempty, exists_prop, mem_inter_iff, mem_ball', and_comm] theorem dense_iff_iUnion_ball (s : Set α) : Dense s ↔ ∀ r > 0, ⋃ c ∈ s, ball c r = univ := by simp_rw [eq_univ_iff_forall, mem_iUnion, exists_prop, mem_ball, Dense, mem_closure_iff, forall_comm (α := α)] theorem denseRange_iff {f : β → α} : DenseRange f ↔ ∀ x, ∀ r > 0, ∃ y, dist x (f y) < r := forall_congr' fun x => by simp only [mem_closure_iff, exists_range_iff] end Metric open Additive Multiplicative instance : PseudoMetricSpace (Additive α) := ‹_› instance : PseudoMetricSpace (Multiplicative α) := ‹_› section variable [PseudoMetricSpace X] @[simp] theorem nndist_ofMul (a b : X) : nndist (ofMul a) (ofMul b) = nndist a b := rfl @[simp] theorem nndist_ofAdd (a b : X) : nndist (ofAdd a) (ofAdd b) = nndist a b := rfl @[simp] theorem nndist_toMul (a b : Additive X) : nndist a.toMul b.toMul = nndist a b := rfl @[simp] theorem nndist_toAdd (a b : Multiplicative X) : nndist a.toAdd b.toAdd = nndist a b := rfl end open OrderDual instance : PseudoMetricSpace αᵒᵈ := ‹_› section variable [PseudoMetricSpace X] @[simp] theorem nndist_toDual (a b : X) : nndist (toDual a) (toDual b) = nndist a b := rfl @[simp] theorem nndist_ofDual (a b : Xᵒᵈ) : nndist (ofDual a) (ofDual b) = nndist a b := rfl end		Mathlib/Topology/MetricSpace/Pseudo/Defs.lean	1,254	1,257
/- Copyright (c) 2014 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Andrew Zipperer, Haitao Zhang, Minchao Wu, Yury Kudryashov -/ import Mathlib.Data.Set.Prod import Mathlib.Data.Set.Restrict /-! # Functions over sets This file contains basic results on the following predicates of functions and sets: * `Set.EqOn f₁ f₂ s` : functions `f₁` and `f₂` are equal at every point of `s`; * `Set.MapsTo f s t` : `f` sends every point of `s` to a point of `t`; * `Set.InjOn f s` : restriction of `f` to `s` is injective; * `Set.SurjOn f s t` : every point in `s` has a preimage in `s`; * `Set.BijOn f s t` : `f` is a bijection between `s` and `t`; * `Set.LeftInvOn f' f s` : for every `x ∈ s` we have `f' (f x) = x`; * `Set.RightInvOn f' f t` : for every `y ∈ t` we have `f (f' y) = y`; * `Set.InvOn f' f s t` : `f'` is a two-side inverse of `f` on `s` and `t`, i.e. we have `Set.LeftInvOn f' f s` and `Set.RightInvOn f' f t`. -/ variable {α β γ δ : Type} {ι : Sort} {π : α → Type} open Equiv Equiv.Perm Function namespace Set /-! ### Equality on a set -/ section equality variable {s s₁ s₂ : Set α} {f₁ f₂ f₃ : α → β} {g : β → γ} {a : α} /-- This lemma exists for use by `aesop` as a forward rule. -/ @[aesop safe forward] lemma EqOn.eq_of_mem (h : s.EqOn f₁ f₂) (ha : a ∈ s) : f₁ a = f₂ a := h ha @[simp] theorem eqOn_empty (f₁ f₂ : α → β) : EqOn f₁ f₂ ∅ := fun _ => False.elim @[simp] theorem eqOn_singleton : Set.EqOn f₁ f₂ {a} ↔ f₁ a = f₂ a := by simp [Set.EqOn] @[simp] theorem eqOn_univ (f₁ f₂ : α → β) : EqOn f₁ f₂ univ ↔ f₁ = f₂ := by simp [EqOn, funext_iff] @[symm] theorem EqOn.symm (h : EqOn f₁ f₂ s) : EqOn f₂ f₁ s := fun _ hx => (h hx).symm theorem eqOn_comm : EqOn f₁ f₂ s ↔ EqOn f₂ f₁ s := ⟨EqOn.symm, EqOn.symm⟩ -- This can not be tagged as `@[refl]` with the current argument order. -- See note below at `EqOn.trans`. theorem eqOn_refl (f : α → β) (s : Set α) : EqOn f f s := fun _ _ => rfl -- Note: this was formerly tagged with `@[trans]`, and although the `trans` attribute accepted it -- the `trans` tactic could not use it. -- An update to the trans tactic coming in https://github.com/leanprover-community/mathlib4/pull/7014 will reject this attribute. -- It can be restored by changing the argument order from `EqOn f₁ f₂ s` to `EqOn s f₁ f₂`. -- This change will be made separately: [zulip](https://leanprover.zulipchat.com/#narrow/stream/287929-mathlib4/topic/Reordering.20arguments.20of.20.60Set.2EEqOn.60/near/390467581). theorem EqOn.trans (h₁ : EqOn f₁ f₂ s) (h₂ : EqOn f₂ f₃ s) : EqOn f₁ f₃ s := fun _ hx => (h₁ hx).trans (h₂ hx) theorem EqOn.image_eq (heq : EqOn f₁ f₂ s) : f₁ '' s = f₂ '' s := image_congr heq /-- Variant of `EqOn.image_eq`, for one function being the identity. -/ theorem EqOn.image_eq_self {f : α → α} (h : Set.EqOn f id s) : f '' s = s := by rw [h.image_eq, image_id] theorem EqOn.inter_preimage_eq (heq : EqOn f₁ f₂ s) (t : Set β) : s ∩ f₁ ⁻¹' t = s ∩ f₂ ⁻¹' t := ext fun x => and_congr_right_iff.2 fun hx => by rw [mem_preimage, mem_preimage, heq hx] theorem EqOn.mono (hs : s₁ ⊆ s₂) (hf : EqOn f₁ f₂ s₂) : EqOn f₁ f₂ s₁ := fun _ hx => hf (hs hx) @[simp] theorem eqOn_union : EqOn f₁ f₂ (s₁ ∪ s₂) ↔ EqOn f₁ f₂ s₁ ∧ EqOn f₁ f₂ s₂ := forall₂_or_left theorem EqOn.union (h₁ : EqOn f₁ f₂ s₁) (h₂ : EqOn f₁ f₂ s₂) : EqOn f₁ f₂ (s₁ ∪ s₂) := eqOn_union.2 ⟨h₁, h₂⟩ theorem EqOn.comp_left (h : s.EqOn f₁ f₂) : s.EqOn (g ∘ f₁) (g ∘ f₂) := fun _ ha => congr_arg _ <\| h ha @[simp] theorem eqOn_range {ι : Sort} {f : ι → α} {g₁ g₂ : α → β} : EqOn g₁ g₂ (range f) ↔ g₁ ∘ f = g₂ ∘ f := forall_mem_range.trans <\| funext_iff.symm alias ⟨EqOn.comp_eq, _⟩ := eqOn_range end equality variable {s s₁ s₂ : Set α} {t t₁ t₂ : Set β} {p : Set γ} {f f₁ f₂ : α → β} {g g₁ g₂ : β → γ} {f' f₁' f₂' : β → α} {g' : γ → β} {a : α} {b : β} section MapsTo theorem mapsTo' : MapsTo f s t ↔ f '' s ⊆ t := image_subset_iff.symm theorem mapsTo_prodMap_diagonal : MapsTo (Prod.map f f) (diagonal α) (diagonal β) := diagonal_subset_iff.2 fun _ => rfl @[deprecated (since := "2025-04-18")] alias mapsTo_prod_map_diagonal := mapsTo_prodMap_diagonal theorem MapsTo.subset_preimage (hf : MapsTo f s t) : s ⊆ f ⁻¹' t := hf theorem mapsTo_iff_subset_preimage : MapsTo f s t ↔ s ⊆ f ⁻¹' t := Iff.rfl @[simp] theorem mapsTo_singleton {x : α} : MapsTo f {x} t ↔ f x ∈ t := singleton_subset_iff theorem mapsTo_empty (f : α → β) (t : Set β) : MapsTo f ∅ t := empty_subset _ @[simp] theorem mapsTo_empty_iff : MapsTo f s ∅ ↔ s = ∅ := by simp [mapsTo', subset_empty_iff] /-- If `f` maps `s` to `t` and `s` is non-empty, `t` is non-empty. -/ theorem MapsTo.nonempty (h : MapsTo f s t) (hs : s.Nonempty) : t.Nonempty := (hs.image f).mono (mapsTo'.mp h) theorem MapsTo.image_subset (h : MapsTo f s t) : f '' s ⊆ t := mapsTo'.1 h theorem MapsTo.congr (h₁ : MapsTo f₁ s t) (h : EqOn f₁ f₂ s) : MapsTo f₂ s t := fun _ hx => h hx ▸ h₁ hx theorem EqOn.comp_right (hg : t.EqOn g₁ g₂) (hf : s.MapsTo f t) : s.EqOn (g₁ ∘ f) (g₂ ∘ f) := fun _ ha => hg <\| hf ha theorem EqOn.mapsTo_iff (H : EqOn f₁ f₂ s) : MapsTo f₁ s t ↔ MapsTo f₂ s t := ⟨fun h => h.congr H, fun h => h.congr H.symm⟩ theorem MapsTo.comp (h₁ : MapsTo g t p) (h₂ : MapsTo f s t) : MapsTo (g ∘ f) s p := fun _ h => h₁ (h₂ h) theorem mapsTo_id (s : Set α) : MapsTo id s s := fun _ => id theorem MapsTo.iterate {f : α → α} {s : Set α} (h : MapsTo f s s) : ∀ n, MapsTo f^[n] s s \| 0 => fun _ => id \| n + 1 => (MapsTo.iterate h n).comp h theorem MapsTo.iterate_restrict {f : α → α} {s : Set α} (h : MapsTo f s s) (n : ℕ) : (h.restrict f s s)^[n] = (h.iterate n).restrict _ _ _ := by funext x rw [Subtype.ext_iff, MapsTo.val_restrict_apply] induction n generalizing x with \| zero => rfl \| succ n ihn => simp [Nat.iterate, ihn] lemma mapsTo_of_subsingleton' [Subsingleton β] (f : α → β) (h : s.Nonempty → t.Nonempty) : MapsTo f s t := fun a ha ↦ Subsingleton.mem_iff_nonempty.2 <\| h ⟨a, ha⟩ lemma mapsTo_of_subsingleton [Subsingleton α] (f : α → α) (s : Set α) : MapsTo f s s := mapsTo_of_subsingleton' _ id theorem MapsTo.mono (hf : MapsTo f s₁ t₁) (hs : s₂ ⊆ s₁) (ht : t₁ ⊆ t₂) : MapsTo f s₂ t₂ := fun _ hx => ht (hf <\| hs hx) theorem MapsTo.mono_left (hf : MapsTo f s₁ t) (hs : s₂ ⊆ s₁) : MapsTo f s₂ t := fun _ hx => hf (hs hx) theorem MapsTo.mono_right (hf : MapsTo f s t₁) (ht : t₁ ⊆ t₂) : MapsTo f s t₂ := fun _ hx => ht (hf hx) theorem MapsTo.union_union (h₁ : MapsTo f s₁ t₁) (h₂ : MapsTo f s₂ t₂) : MapsTo f (s₁ ∪ s₂) (t₁ ∪ t₂) := fun _ hx => hx.elim (fun hx => Or.inl <\| h₁ hx) fun hx => Or.inr <\| h₂ hx theorem MapsTo.union (h₁ : MapsTo f s₁ t) (h₂ : MapsTo f s₂ t) : MapsTo f (s₁ ∪ s₂) t := union_self t ▸ h₁.union_union h₂ @[simp] theorem mapsTo_union : MapsTo f (s₁ ∪ s₂) t ↔ MapsTo f s₁ t ∧ MapsTo f s₂ t := ⟨fun h => ⟨h.mono subset_union_left (Subset.refl t), h.mono subset_union_right (Subset.refl t)⟩, fun h => h.1.union h.2⟩ theorem MapsTo.inter (h₁ : MapsTo f s t₁) (h₂ : MapsTo f s t₂) : MapsTo f s (t₁ ∩ t₂) := fun _ hx => ⟨h₁ hx, h₂ hx⟩ lemma MapsTo.insert (h : MapsTo f s t) (x : α) : MapsTo f (insert x s) (insert (f x) t) := by simpa [← singleton_union] using h.mono_right subset_union_right theorem MapsTo.inter_inter (h₁ : MapsTo f s₁ t₁) (h₂ : MapsTo f s₂ t₂) : MapsTo f (s₁ ∩ s₂) (t₁ ∩ t₂) := fun _ hx => ⟨h₁ hx.1, h₂ hx.2⟩ @[simp] theorem mapsTo_inter : MapsTo f s (t₁ ∩ t₂) ↔ MapsTo f s t₁ ∧ MapsTo f s t₂ := ⟨fun h => ⟨h.mono (Subset.refl s) inter_subset_left, h.mono (Subset.refl s) inter_subset_right⟩, fun h => h.1.inter h.2⟩ theorem mapsTo_univ (f : α → β) (s : Set α) : MapsTo f s univ := fun _ _ => trivial theorem mapsTo_range (f : α → β) (s : Set α) : MapsTo f s (range f) := (mapsTo_image f s).mono (Subset.refl s) (image_subset_range _ _) @[simp] theorem mapsTo_image_iff {f : α → β} {g : γ → α} {s : Set γ} {t : Set β} : MapsTo f (g '' s) t ↔ MapsTo (f ∘ g) s t := ⟨fun h c hc => h ⟨c, hc, rfl⟩, fun h _ ⟨_, hc⟩ => hc.2 ▸ h hc.1⟩ lemma MapsTo.comp_left (g : β → γ) (hf : MapsTo f s t) : MapsTo (g ∘ f) s (g '' t) := fun x hx ↦ ⟨f x, hf hx, rfl⟩ lemma MapsTo.comp_right {s : Set β} {t : Set γ} (hg : MapsTo g s t) (f : α → β) : MapsTo (g ∘ f) (f ⁻¹' s) t := fun _ hx ↦ hg hx @[simp] lemma mapsTo_univ_iff : MapsTo f univ t ↔ ∀ x, f x ∈ t := ⟨fun h _ => h (mem_univ _), fun h x _ => h x⟩ @[simp] lemma mapsTo_range_iff {g : ι → α} : MapsTo f (range g) t ↔ ∀ i, f (g i) ∈ t := forall_mem_range theorem MapsTo.mem_iff (h : MapsTo f s t) (hc : MapsTo f sᶜ tᶜ) {x} : f x ∈ t ↔ x ∈ s := ⟨fun ht => by_contra fun hs => hc hs ht, fun hx => h hx⟩ end MapsTo /-! ### Injectivity on a set -/ section injOn theorem Subsingleton.injOn (hs : s.Subsingleton) (f : α → β) : InjOn f s := fun _ hx _ hy _ => hs hx hy @[simp] theorem injOn_empty (f : α → β) : InjOn f ∅ := subsingleton_empty.injOn f @[simp] theorem injOn_singleton (f : α → β) (a : α) : InjOn f {a} := subsingleton_singleton.injOn f @[simp] lemma injOn_pair {b : α} : InjOn f {a, b} ↔ f a = f b → a = b := by unfold InjOn; aesop theorem InjOn.eq_iff {x y} (h : InjOn f s) (hx : x ∈ s) (hy : y ∈ s) : f x = f y ↔ x = y := ⟨h hx hy, fun h => h ▸ rfl⟩ theorem InjOn.ne_iff {x y} (h : InjOn f s) (hx : x ∈ s) (hy : y ∈ s) : f x ≠ f y ↔ x ≠ y := (h.eq_iff hx hy).not alias ⟨_, InjOn.ne⟩ := InjOn.ne_iff theorem InjOn.congr (h₁ : InjOn f₁ s) (h : EqOn f₁ f₂ s) : InjOn f₂ s := fun _ hx _ hy => h hx ▸ h hy ▸ h₁ hx hy theorem EqOn.injOn_iff (H : EqOn f₁ f₂ s) : InjOn f₁ s ↔ InjOn f₂ s := ⟨fun h => h.congr H, fun h => h.congr H.symm⟩ theorem InjOn.mono (h : s₁ ⊆ s₂) (ht : InjOn f s₂) : InjOn f s₁ := fun _ hx _ hy H => ht (h hx) (h hy) H theorem injOn_union (h : Disjoint s₁ s₂) : InjOn f (s₁ ∪ s₂) ↔ InjOn f s₁ ∧ InjOn f s₂ ∧ ∀ x ∈ s₁, ∀ y ∈ s₂, f x ≠ f y := by refine ⟨fun H => ⟨H.mono subset_union_left, H.mono subset_union_right, ?_⟩, ?_⟩ · intro x hx y hy hxy obtain rfl : x = y := H (Or.inl hx) (Or.inr hy) hxy exact h.le_bot ⟨hx, hy⟩ · rintro ⟨h₁, h₂, h₁₂⟩ rintro x (hx \| hx) y (hy \| hy) hxy exacts [h₁ hx hy hxy, (h₁₂ _ hx _ hy hxy).elim, (h₁₂ _ hy _ hx hxy.symm).elim, h₂ hx hy hxy] theorem injOn_insert {f : α → β} {s : Set α} {a : α} (has : a ∉ s) : Set.InjOn f (insert a s) ↔ Set.InjOn f s ∧ f a ∉ f '' s := by rw [← union_singleton, injOn_union (disjoint_singleton_right.2 has)] simp theorem injective_iff_injOn_univ : Injective f ↔ InjOn f univ := ⟨fun h _ _ _ _ hxy => h hxy, fun h _ _ heq => h trivial trivial heq⟩ theorem injOn_of_injective (h : Injective f) {s : Set α} : InjOn f s := fun _ _ _ _ hxy => h hxy alias _root_.Function.Injective.injOn := injOn_of_injective -- A specialization of `injOn_of_injective` for `Subtype.val`. theorem injOn_subtype_val {s : Set { x // p x }} : Set.InjOn Subtype.val s := Subtype.coe_injective.injOn lemma injOn_id (s : Set α) : InjOn id s := injective_id.injOn theorem InjOn.comp (hg : InjOn g t) (hf : InjOn f s) (h : MapsTo f s t) : InjOn (g ∘ f) s := fun _ hx _ hy heq => hf hx hy <\| hg (h hx) (h hy) heq lemma InjOn.of_comp (h : InjOn (g ∘ f) s) : InjOn f s := fun _ hx _ hy heq ↦ h hx hy (by simp [heq]) lemma InjOn.image_of_comp (h : InjOn (g ∘ f) s) : InjOn g (f '' s) := forall_mem_image.2 fun _x hx ↦ forall_mem_image.2 fun _y hy heq ↦ congr_arg f <\| h hx hy heq lemma InjOn.comp_iff (hf : InjOn f s) : InjOn (g ∘ f) s ↔ InjOn g (f '' s) := ⟨image_of_comp, fun h ↦ InjOn.comp h hf <\| mapsTo_image f s⟩ lemma InjOn.iterate {f : α → α} {s : Set α} (h : InjOn f s) (hf : MapsTo f s s) : ∀ n, InjOn f^[n] s \| 0 => injOn_id _ \| (n + 1) => (h.iterate hf n).comp h hf lemma injOn_of_subsingleton [Subsingleton α] (f : α → β) (s : Set α) : InjOn f s := (injective_of_subsingleton _).injOn theorem _root_.Function.Injective.injOn_range (h : Injective (g ∘ f)) : InjOn g (range f) := by rintro _ ⟨x, rfl⟩ _ ⟨y, rfl⟩ H exact congr_arg f (h H) theorem _root_.Set.InjOn.injective_iff (s : Set β) (h : InjOn g s) (hs : range f ⊆ s) : Injective (g ∘ f) ↔ Injective f := ⟨(·.of_comp), fun h _ ↦ by aesop⟩ theorem exists_injOn_iff_injective [Nonempty β] : (∃ f : α → β, InjOn f s) ↔ ∃ f : s → β, Injective f := ⟨fun ⟨_, hf⟩ => ⟨_, hf.injective⟩, fun ⟨f, hf⟩ => by lift f to α → β using trivial exact ⟨f, injOn_iff_injective.2 hf⟩⟩ theorem injOn_preimage {B : Set (Set β)} (hB : B ⊆ 𝒫 range f) : InjOn (preimage f) B := fun _ hs _ ht hst => (preimage_eq_preimage' (hB hs) (hB ht)).1 hst theorem InjOn.mem_of_mem_image {x} (hf : InjOn f s) (hs : s₁ ⊆ s) (h : x ∈ s) (h₁ : f x ∈ f '' s₁) : x ∈ s₁ := let ⟨_, h', Eq⟩ := h₁ hf (hs h') h Eq ▸ h' theorem InjOn.mem_image_iff {x} (hf : InjOn f s) (hs : s₁ ⊆ s) (hx : x ∈ s) : f x ∈ f '' s₁ ↔ x ∈ s₁ := ⟨hf.mem_of_mem_image hs hx, mem_image_of_mem f⟩ theorem InjOn.preimage_image_inter (hf : InjOn f s) (hs : s₁ ⊆ s) : f ⁻¹' (f '' s₁) ∩ s = s₁ := ext fun _ => ⟨fun ⟨h₁, h₂⟩ => hf.mem_of_mem_image hs h₂ h₁, fun h => ⟨mem_image_of_mem _ h, hs h⟩⟩ theorem EqOn.cancel_left (h : s.EqOn (g ∘ f₁) (g ∘ f₂)) (hg : t.InjOn g) (hf₁ : s.MapsTo f₁ t) (hf₂ : s.MapsTo f₂ t) : s.EqOn f₁ f₂ := fun _ ha => hg (hf₁ ha) (hf₂ ha) (h ha) theorem InjOn.cancel_left (hg : t.InjOn g) (hf₁ : s.MapsTo f₁ t) (hf₂ : s.MapsTo f₂ t) : s.EqOn (g ∘ f₁) (g ∘ f₂) ↔ s.EqOn f₁ f₂ := ⟨fun h => h.cancel_left hg hf₁ hf₂, EqOn.comp_left⟩ lemma InjOn.image_inter {s t u : Set α} (hf : u.InjOn f) (hs : s ⊆ u) (ht : t ⊆ u) : f '' (s ∩ t) = f '' s ∩ f '' t := by apply Subset.antisymm (image_inter_subset _ _ _) intro x ⟨⟨y, ys, hy⟩, ⟨z, zt, hz⟩⟩ have : y = z := by apply hf (hs ys) (ht zt) rwa [← hz] at hy rw [← this] at zt exact ⟨y, ⟨ys, zt⟩, hy⟩ lemma InjOn.image (h : s.InjOn f) : s.powerset.InjOn (image f) := fun s₁ hs₁ s₂ hs₂ h' ↦ by rw [← h.preimage_image_inter hs₁, h', h.preimage_image_inter hs₂] theorem InjOn.image_eq_image_iff (h : s.InjOn f) (h₁ : s₁ ⊆ s) (h₂ : s₂ ⊆ s) : f '' s₁ = f '' s₂ ↔ s₁ = s₂ := h.image.eq_iff h₁ h₂ lemma InjOn.image_subset_image_iff (h : s.InjOn f) (h₁ : s₁ ⊆ s) (h₂ : s₂ ⊆ s) : f '' s₁ ⊆ f '' s₂ ↔ s₁ ⊆ s₂ := by refine ⟨fun h' ↦ ?_, image_subset _⟩ rw [← h.preimage_image_inter h₁, ← h.preimage_image_inter h₂] exact inter_subset_inter_left _ (preimage_mono h') lemma InjOn.image_ssubset_image_iff (h : s.InjOn f) (h₁ : s₁ ⊆ s) (h₂ : s₂ ⊆ s) : f '' s₁ ⊂ f '' s₂ ↔ s₁ ⊂ s₂ := by simp_rw [ssubset_def, h.image_subset_image_iff h₁ h₂, h.image_subset_image_iff h₂ h₁] -- TODO: can this move to a better place? theorem _root_.Disjoint.image {s t u : Set α} {f : α → β} (h : Disjoint s t) (hf : u.InjOn f) (hs : s ⊆ u) (ht : t ⊆ u) : Disjoint (f '' s) (f '' t) := by rw [disjoint_iff_inter_eq_empty] at h ⊢ rw [← hf.image_inter hs ht, h, image_empty] lemma InjOn.image_diff {t : Set α} (h : s.InjOn f) : f '' (s \ t) = f '' s \ f '' (s ∩ t) := by refine subset_antisymm (subset_diff.2 ⟨image_subset f diff_subset, ?_⟩) (diff_subset_iff.2 (by rw [← image_union, inter_union_diff])) exact Disjoint.image disjoint_sdiff_inter h diff_subset inter_subset_left lemma InjOn.image_diff_subset {f : α → β} {t : Set α} (h : InjOn f s) (hst : t ⊆ s) : f '' (s \ t) = f '' s \ f '' t := by rw [h.image_diff, inter_eq_self_of_subset_right hst] alias image_diff_of_injOn := InjOn.image_diff_subset theorem InjOn.imageFactorization_injective (h : InjOn f s) : Injective (s.imageFactorization f) := fun ⟨x, hx⟩ ⟨y, hy⟩ h' ↦ by simpa [imageFactorization, h.eq_iff hx hy] using h' @[simp] theorem imageFactorization_injective_iff : Injective (s.imageFactorization f) ↔ InjOn f s := ⟨fun h x hx y hy _ ↦ by simpa using @h ⟨x, hx⟩ ⟨y, hy⟩ (by simpa [imageFactorization]), InjOn.imageFactorization_injective⟩ end injOn section graphOn variable {x : α × β} lemma graphOn_univ_inj {g : α → β} : univ.graphOn f = univ.graphOn g ↔ f = g := by simp lemma graphOn_univ_injective : Injective (univ.graphOn : (α → β) → Set (α × β)) := fun _f _g ↦ graphOn_univ_inj.1 lemma exists_eq_graphOn_image_fst [Nonempty β] {s : Set (α × β)} : (∃ f : α → β, s = graphOn f (Prod.fst '' s)) ↔ InjOn Prod.fst s := by refine ⟨?_, fun h ↦ ?_⟩ · rintro ⟨f, hf⟩ rw [hf] exact InjOn.image_of_comp <\| injOn_id _ · have : ∀ x ∈ Prod.fst '' s, ∃ y, (x, y) ∈ s := forall_mem_image.2 fun (x, y) h ↦ ⟨y, h⟩ choose! f hf using this rw [forall_mem_image] at hf use f rw [graphOn, image_image, EqOn.image_eq_self] exact fun x hx ↦ h (hf hx) hx rfl lemma exists_eq_graphOn [Nonempty β] {s : Set (α × β)} : (∃ f t, s = graphOn f t) ↔ InjOn Prod.fst s := .trans ⟨fun ⟨f, t, hs⟩ ↦ ⟨f, by rw [hs, image_fst_graphOn]⟩, fun ⟨f, hf⟩ ↦ ⟨f, _, hf⟩⟩ exists_eq_graphOn_image_fst end graphOn /-! ### Surjectivity on a set -/ section surjOn theorem SurjOn.subset_range (h : SurjOn f s t) : t ⊆ range f := Subset.trans h <\| image_subset_range f s theorem surjOn_iff_exists_map_subtype : SurjOn f s t ↔ ∃ (t' : Set β) (g : s → t'), t ⊆ t' ∧ Surjective g ∧ ∀ x : s, f x = g x := ⟨fun h => ⟨_, (mapsTo_image f s).restrict f s _, h, surjective_mapsTo_image_restrict _ _, fun _ => rfl⟩, fun ⟨t', g, htt', hg, hfg⟩ y hy => let ⟨x, hx⟩ := hg ⟨y, htt' hy⟩ ⟨x, x.2, by rw [hfg, hx, Subtype.coe_mk]⟩⟩ theorem surjOn_empty (f : α → β) (s : Set α) : SurjOn f s ∅ := empty_subset _ @[simp] theorem surjOn_empty_iff : SurjOn f ∅ t ↔ t = ∅ := by simp [SurjOn, subset_empty_iff] @[simp] lemma surjOn_singleton : SurjOn f s {b} ↔ b ∈ f '' s := singleton_subset_iff theorem surjOn_image (f : α → β) (s : Set α) : SurjOn f s (f '' s) := Subset.rfl theorem SurjOn.comap_nonempty (h : SurjOn f s t) (ht : t.Nonempty) : s.Nonempty := (ht.mono h).of_image theorem SurjOn.congr (h : SurjOn f₁ s t) (H : EqOn f₁ f₂ s) : SurjOn f₂ s t := by rwa [SurjOn, ← H.image_eq] theorem EqOn.surjOn_iff (h : EqOn f₁ f₂ s) : SurjOn f₁ s t ↔ SurjOn f₂ s t := ⟨fun H => H.congr h, fun H => H.congr h.symm⟩ theorem SurjOn.mono (hs : s₁ ⊆ s₂) (ht : t₁ ⊆ t₂) (hf : SurjOn f s₁ t₂) : SurjOn f s₂ t₁ := Subset.trans ht <\| Subset.trans hf <\| image_subset _ hs theorem SurjOn.union (h₁ : SurjOn f s t₁) (h₂ : SurjOn f s t₂) : SurjOn f s (t₁ ∪ t₂) := fun _ hx => hx.elim (fun hx => h₁ hx) fun hx => h₂ hx theorem SurjOn.union_union (h₁ : SurjOn f s₁ t₁) (h₂ : SurjOn f s₂ t₂) : SurjOn f (s₁ ∪ s₂) (t₁ ∪ t₂) := (h₁.mono subset_union_left (Subset.refl _)).union (h₂.mono subset_union_right (Subset.refl _)) theorem SurjOn.inter_inter (h₁ : SurjOn f s₁ t₁) (h₂ : SurjOn f s₂ t₂) (h : InjOn f (s₁ ∪ s₂)) : SurjOn f (s₁ ∩ s₂) (t₁ ∩ t₂) := by intro y hy rcases h₁ hy.1 with ⟨x₁, hx₁, rfl⟩ rcases h₂ hy.2 with ⟨x₂, hx₂, heq⟩ obtain rfl : x₁ = x₂ := h (Or.inl hx₁) (Or.inr hx₂) heq.symm exact mem_image_of_mem f ⟨hx₁, hx₂⟩ theorem SurjOn.inter (h₁ : SurjOn f s₁ t) (h₂ : SurjOn f s₂ t) (h : InjOn f (s₁ ∪ s₂)) : SurjOn f (s₁ ∩ s₂) t := inter_self t ▸ h₁.inter_inter h₂ h lemma surjOn_id (s : Set α) : SurjOn id s s := by simp [SurjOn] theorem SurjOn.comp (hg : SurjOn g t p) (hf : SurjOn f s t) : SurjOn (g ∘ f) s p := Subset.trans hg <\| Subset.trans (image_subset g hf) <\| image_comp g f s ▸ Subset.refl _ lemma SurjOn.of_comp (h : SurjOn (g ∘ f) s p) (hr : MapsTo f s t) : SurjOn g t p := by intro z hz obtain ⟨x, hx, rfl⟩ := h hz exact ⟨f x, hr hx, rfl⟩ lemma surjOn_comp_iff : SurjOn (g ∘ f) s p ↔ SurjOn g (f '' s) p := ⟨fun h ↦ h.of_comp <\| mapsTo_image f s, fun h ↦ h.comp <\| surjOn_image _ _⟩ lemma SurjOn.iterate {f : α → α} {s : Set α} (h : SurjOn f s s) : ∀ n, SurjOn f^[n] s s \| 0 => surjOn_id _ \| (n + 1) => (h.iterate n).comp h lemma SurjOn.comp_left (hf : SurjOn f s t) (g : β → γ) : SurjOn (g ∘ f) s (g '' t) := by rw [SurjOn, image_comp g f]; exact image_subset _ hf lemma SurjOn.comp_right {s : Set β} {t : Set γ} (hf : Surjective f) (hg : SurjOn g s t) : SurjOn (g ∘ f) (f ⁻¹' s) t := by rwa [SurjOn, image_comp g f, image_preimage_eq _ hf] lemma surjOn_of_subsingleton' [Subsingleton β] (f : α → β) (h : t.Nonempty → s.Nonempty) : SurjOn f s t := fun _ ha ↦ Subsingleton.mem_iff_nonempty.2 <\| (h ⟨_, ha⟩).image _ lemma surjOn_of_subsingleton [Subsingleton α] (f : α → α) (s : Set α) : SurjOn f s s := surjOn_of_subsingleton' _ id theorem surjective_iff_surjOn_univ : Surjective f ↔ SurjOn f univ univ := by simp [Surjective, SurjOn, subset_def] theorem SurjOn.image_eq_of_mapsTo (h₁ : SurjOn f s t) (h₂ : MapsTo f s t) : f '' s = t := eq_of_subset_of_subset h₂.image_subset h₁ theorem image_eq_iff_surjOn_mapsTo : f '' s = t ↔ s.SurjOn f t ∧ s.MapsTo f t := by refine ⟨?_, fun h => h.1.image_eq_of_mapsTo h.2⟩ rintro rfl exact ⟨s.surjOn_image f, s.mapsTo_image f⟩ lemma SurjOn.image_preimage (h : Set.SurjOn f s t) (ht : t₁ ⊆ t) : f '' (f ⁻¹' t₁) = t₁ := image_preimage_eq_iff.2 fun _ hx ↦ mem_range_of_mem_image f s <\| h <\| ht hx theorem SurjOn.mapsTo_compl (h : SurjOn f s t) (h' : Injective f) : MapsTo f sᶜ tᶜ := fun _ hs ht => let ⟨_, hx', HEq⟩ := h ht hs <\| h' HEq ▸ hx' theorem MapsTo.surjOn_compl (h : MapsTo f s t) (h' : Surjective f) : SurjOn f sᶜ tᶜ := h'.forall.2 fun _ ht => (mem_image_of_mem _) fun hs => ht (h hs) theorem EqOn.cancel_right (hf : s.EqOn (g₁ ∘ f) (g₂ ∘ f)) (hf' : s.SurjOn f t) : t.EqOn g₁ g₂ := by intro b hb obtain ⟨a, ha, rfl⟩ := hf' hb exact hf ha theorem SurjOn.cancel_right (hf : s.SurjOn f t) (hf' : s.MapsTo f t) : s.EqOn (g₁ ∘ f) (g₂ ∘ f) ↔ t.EqOn g₁ g₂ := ⟨fun h => h.cancel_right hf, fun h => h.comp_right hf'⟩ theorem eqOn_comp_right_iff : s.EqOn (g₁ ∘ f) (g₂ ∘ f) ↔ (f '' s).EqOn g₁ g₂ := (s.surjOn_image f).cancel_right <\| s.mapsTo_image f theorem SurjOn.forall {p : β → Prop} (hf : s.SurjOn f t) (hf' : s.MapsTo f t) : (∀ y ∈ t, p y) ↔ (∀ x ∈ s, p (f x)) := ⟨fun H x hx ↦ H (f x) (hf' hx), fun H _y hy ↦ let ⟨x, hx, hxy⟩ := hf hy; hxy ▸ H x hx⟩ end surjOn /-! ### Bijectivity -/ section bijOn theorem BijOn.mapsTo (h : BijOn f s t) : MapsTo f s t := h.left theorem BijOn.injOn (h : BijOn f s t) : InjOn f s := h.right.left theorem BijOn.surjOn (h : BijOn f s t) : SurjOn f s t := h.right.right theorem BijOn.mk (h₁ : MapsTo f s t) (h₂ : InjOn f s) (h₃ : SurjOn f s t) : BijOn f s t := ⟨h₁, h₂, h₃⟩ theorem bijOn_empty (f : α → β) : BijOn f ∅ ∅ := ⟨mapsTo_empty f ∅, injOn_empty f, surjOn_empty f ∅⟩ @[simp] theorem bijOn_empty_iff_left : BijOn f s ∅ ↔ s = ∅ := ⟨fun h ↦ by simpa using h.mapsTo, by rintro rfl; exact bijOn_empty f⟩ @[simp] theorem bijOn_empty_iff_right : BijOn f ∅ t ↔ t = ∅ := ⟨fun h ↦ by simpa using h.surjOn, by rintro rfl; exact bijOn_empty f⟩ @[simp] lemma bijOn_singleton : BijOn f {a} {b} ↔ f a = b := by simp [BijOn, eq_comm] theorem BijOn.inter_mapsTo (h₁ : BijOn f s₁ t₁) (h₂ : MapsTo f s₂ t₂) (h₃ : s₁ ∩ f ⁻¹' t₂ ⊆ s₂) : BijOn f (s₁ ∩ s₂) (t₁ ∩ t₂) := ⟨h₁.mapsTo.inter_inter h₂, h₁.injOn.mono inter_subset_left, fun _ hy => let ⟨x, hx, hxy⟩ := h₁.surjOn hy.1 ⟨x, ⟨hx, h₃ ⟨hx, hxy.symm.subst hy.2⟩⟩, hxy⟩⟩ theorem MapsTo.inter_bijOn (h₁ : MapsTo f s₁ t₁) (h₂ : BijOn f s₂ t₂) (h₃ : s₂ ∩ f ⁻¹' t₁ ⊆ s₁) : BijOn f (s₁ ∩ s₂) (t₁ ∩ t₂) := inter_comm s₂ s₁ ▸ inter_comm t₂ t₁ ▸ h₂.inter_mapsTo h₁ h₃ theorem BijOn.inter (h₁ : BijOn f s₁ t₁) (h₂ : BijOn f s₂ t₂) (h : InjOn f (s₁ ∪ s₂)) : BijOn f (s₁ ∩ s₂) (t₁ ∩ t₂) := ⟨h₁.mapsTo.inter_inter h₂.mapsTo, h₁.injOn.mono inter_subset_left, h₁.surjOn.inter_inter h₂.surjOn h⟩ theorem BijOn.union (h₁ : BijOn f s₁ t₁) (h₂ : BijOn f s₂ t₂) (h : InjOn f (s₁ ∪ s₂)) : BijOn f (s₁ ∪ s₂) (t₁ ∪ t₂) := ⟨h₁.mapsTo.union_union h₂.mapsTo, h, h₁.surjOn.union_union h₂.surjOn⟩ theorem BijOn.subset_range (h : BijOn f s t) : t ⊆ range f := h.surjOn.subset_range theorem InjOn.bijOn_image (h : InjOn f s) : BijOn f s (f '' s) := BijOn.mk (mapsTo_image f s) h (Subset.refl _) theorem BijOn.congr (h₁ : BijOn f₁ s t) (h : EqOn f₁ f₂ s) : BijOn f₂ s t := BijOn.mk (h₁.mapsTo.congr h) (h₁.injOn.congr h) (h₁.surjOn.congr h) theorem EqOn.bijOn_iff (H : EqOn f₁ f₂ s) : BijOn f₁ s t ↔ BijOn f₂ s t := ⟨fun h => h.congr H, fun h => h.congr H.symm⟩ theorem BijOn.image_eq (h : BijOn f s t) : f '' s = t := h.surjOn.image_eq_of_mapsTo h.mapsTo lemma BijOn.forall {p : β → Prop} (hf : BijOn f s t) : (∀ b ∈ t, p b) ↔ ∀ a ∈ s, p (f a) where mp h _ ha := h _ <\| hf.mapsTo ha mpr h b hb := by obtain ⟨a, ha, rfl⟩ := hf.surjOn hb; exact h _ ha lemma BijOn.exists {p : β → Prop} (hf : BijOn f s t) : (∃ b ∈ t, p b) ↔ ∃ a ∈ s, p (f a) where mp := by rintro ⟨b, hb, h⟩; obtain ⟨a, ha, rfl⟩ := hf.surjOn hb; exact ⟨a, ha, h⟩ mpr := by rintro ⟨a, ha, h⟩; exact ⟨f a, hf.mapsTo ha, h⟩ lemma _root_.Equiv.image_eq_iff_bijOn (e : α ≃ β) : e '' s = t ↔ BijOn e s t := ⟨fun h ↦ ⟨(mapsTo_image e s).mono_right h.subset, e.injective.injOn, h ▸ surjOn_image e s⟩, BijOn.image_eq⟩ lemma bijOn_id (s : Set α) : BijOn id s s := ⟨s.mapsTo_id, s.injOn_id, s.surjOn_id⟩ theorem BijOn.comp (hg : BijOn g t p) (hf : BijOn f s t) : BijOn (g ∘ f) s p := BijOn.mk (hg.mapsTo.comp hf.mapsTo) (hg.injOn.comp hf.injOn hf.mapsTo) (hg.surjOn.comp hf.surjOn) /-- If `f : α → β` and `g : β → γ` and if `f` is injective on `s`, then `f ∘ g` is a bijection on `s` iff `g` is a bijection on `f '' s`. -/ theorem bijOn_comp_iff (hf : InjOn f s) : BijOn (g ∘ f) s p ↔ BijOn g (f '' s) p := by simp only [BijOn, InjOn.comp_iff, surjOn_comp_iff, mapsTo_image_iff, hf] /-- If we have a commutative square ``` α --f--> β \| \| p₁ p₂ \| \| \/ \/ γ --g--> δ ``` and `f` induces a bijection from `s : Set α` to `t : Set β`, then `g` induces a bijection from the image of `s` to the image of `t`, as long as `g` is is injective on the image of `s`. -/ theorem bijOn_image_image {p₁ : α → γ} {p₂ : β → δ} {g : γ → δ} (comm : ∀ a, p₂ (f a) = g (p₁ a)) (hbij : BijOn f s t) (hinj: InjOn g (p₁ '' s)) : BijOn g (p₁ '' s) (p₂ '' t) := by obtain ⟨h1, h2, h3⟩ := hbij refine ⟨?_, hinj, ?_⟩ · rintro _ ⟨a, ha, rfl⟩ exact ⟨f a, h1 ha, by rw [comm a]⟩ · rintro _ ⟨b, hb, rfl⟩ obtain ⟨a, ha, rfl⟩ := h3 hb rw [← image_comp, comm] exact ⟨a, ha, rfl⟩ lemma BijOn.iterate {f : α → α} {s : Set α} (h : BijOn f s s) : ∀ n, BijOn f^[n] s s \| 0 => s.bijOn_id \| (n + 1) => (h.iterate n).comp h lemma bijOn_of_subsingleton' [Subsingleton α] [Subsingleton β] (f : α → β) (h : s.Nonempty ↔ t.Nonempty) : BijOn f s t := ⟨mapsTo_of_subsingleton' _ h.1, injOn_of_subsingleton _ _, surjOn_of_subsingleton' _ h.2⟩ lemma bijOn_of_subsingleton [Subsingleton α] (f : α → α) (s : Set α) : BijOn f s s := bijOn_of_subsingleton' _ Iff.rfl theorem BijOn.bijective (h : BijOn f s t) : Bijective (h.mapsTo.restrict f s t) := ⟨fun x y h' => Subtype.ext <\| h.injOn x.2 y.2 <\| Subtype.ext_iff.1 h', fun ⟨_, hy⟩ => let ⟨x, hx, hxy⟩ := h.surjOn hy ⟨⟨x, hx⟩, Subtype.eq hxy⟩⟩ theorem bijective_iff_bijOn_univ : Bijective f ↔ BijOn f univ univ := Iff.intro (fun h => let ⟨inj, surj⟩ := h ⟨mapsTo_univ f _, inj.injOn, Iff.mp surjective_iff_surjOn_univ surj⟩) fun h => let ⟨_map, inj, surj⟩ := h ⟨Iff.mpr injective_iff_injOn_univ inj, Iff.mpr surjective_iff_surjOn_univ surj⟩ alias ⟨_root_.Function.Bijective.bijOn_univ, _⟩ := bijective_iff_bijOn_univ theorem BijOn.compl (hst : BijOn f s t) (hf : Bijective f) : BijOn f sᶜ tᶜ := ⟨hst.surjOn.mapsTo_compl hf.1, hf.1.injOn, hst.mapsTo.surjOn_compl hf.2⟩ theorem BijOn.subset_right {r : Set β} (hf : BijOn f s t) (hrt : r ⊆ t) : BijOn f (s ∩ f ⁻¹' r) r := by refine ⟨inter_subset_right, hf.injOn.mono inter_subset_left, fun x hx ↦ ?_⟩ obtain ⟨y, hy, rfl⟩ := hf.surjOn (hrt hx) exact ⟨y, ⟨hy, hx⟩, rfl⟩ theorem BijOn.subset_left {r : Set α} (hf : BijOn f s t) (hrs : r ⊆ s) : BijOn f r (f '' r) := (hf.injOn.mono hrs).bijOn_image theorem BijOn.insert_iff (ha : a ∉ s) (hfa : f a ∉ t) : BijOn f (insert a s) (insert (f a) t) ↔ BijOn f s t where mp h := by have := congrArg (· \ {f a}) (image_insert_eq ▸ h.image_eq) simp only [mem_singleton_iff, insert_diff_of_mem] at this rw [diff_singleton_eq_self hfa, diff_singleton_eq_self] at this · exact ⟨by simp [← this, mapsTo'], h.injOn.mono (subset_insert ..), by simp [← this, surjOn_image]⟩ simp only [mem_image, not_exists, not_and] intro x hx rw [h.injOn.eq_iff (by simp [hx]) (by simp)] exact ha ∘ (· ▸ hx) mpr h := by repeat rw [insert_eq] refine (bijOn_singleton.mpr rfl).union h ?_ simp only [singleton_union, injOn_insert fun x ↦ (hfa (h.mapsTo x)), h.injOn, mem_image, not_exists, not_and, true_and] exact fun _ hx h₂ ↦ hfa (h₂ ▸ h.mapsTo hx) theorem BijOn.insert (h₁ : BijOn f s t) (h₂ : f a ∉ t) : BijOn f (insert a s) (insert (f a) t) := (insert_iff (h₂ <\| h₁.mapsTo ·) h₂).mpr h₁ theorem BijOn.sdiff_singleton (h₁ : BijOn f s t) (h₂ : a ∈ s) : BijOn f (s \ {a}) (t \ {f a}) := by convert h₁.subset_left diff_subset simp [h₁.injOn.image_diff, h₁.image_eq, h₂, inter_eq_self_of_subset_right] end bijOn /-! ### left inverse -/ namespace LeftInvOn theorem eqOn (h : LeftInvOn f' f s) : EqOn (f' ∘ f) id s := h theorem eq (h : LeftInvOn f' f s) {x} (hx : x ∈ s) : f' (f x) = x := h hx theorem congr_left (h₁ : LeftInvOn f₁' f s) {t : Set β} (h₁' : MapsTo f s t) (heq : EqOn f₁' f₂' t) : LeftInvOn f₂' f s := fun _ hx => heq (h₁' hx) ▸ h₁ hx theorem congr_right (h₁ : LeftInvOn f₁' f₁ s) (heq : EqOn f₁ f₂ s) : LeftInvOn f₁' f₂ s := fun _ hx => heq hx ▸ h₁ hx theorem injOn (h : LeftInvOn f₁' f s) : InjOn f s := fun x₁ h₁ x₂ h₂ heq => calc x₁ = f₁' (f x₁) := Eq.symm <\| h h₁ _ = f₁' (f x₂) := congr_arg f₁' heq _ = x₂ := h h₂ theorem surjOn (h : LeftInvOn f' f s) (hf : MapsTo f s t) : SurjOn f' t s := fun x hx => ⟨f x, hf hx, h hx⟩ theorem mapsTo (h : LeftInvOn f' f s) (hf : SurjOn f s t) : MapsTo f' t s := fun y hy => by let ⟨x, hs, hx⟩ := hf hy rwa [← hx, h hs] lemma _root_.Set.leftInvOn_id (s : Set α) : LeftInvOn id id s := fun _ _ ↦ rfl theorem comp (hf' : LeftInvOn f' f s) (hg' : LeftInvOn g' g t) (hf : MapsTo f s t) : LeftInvOn (f' ∘ g') (g ∘ f) s := fun x h => calc (f' ∘ g') ((g ∘ f) x) = f' (f x) := congr_arg f' (hg' (hf h)) _ = x := hf' h theorem mono (hf : LeftInvOn f' f s) (ht : s₁ ⊆ s) : LeftInvOn f' f s₁ := fun _ hx => hf (ht hx) theorem image_inter' (hf : LeftInvOn f' f s) : f '' (s₁ ∩ s) = f' ⁻¹' s₁ ∩ f '' s := by apply Subset.antisymm · rintro _ ⟨x, ⟨h₁, h⟩, rfl⟩ exact ⟨by rwa [mem_preimage, hf h], mem_image_of_mem _ h⟩ · rintro _ ⟨h₁, ⟨x, h, rfl⟩⟩ exact mem_image_of_mem _ ⟨by rwa [← hf h], h⟩ theorem image_inter (hf : LeftInvOn f' f s) : f '' (s₁ ∩ s) = f' ⁻¹' (s₁ ∩ s) ∩ f '' s := by rw [hf.image_inter'] refine Subset.antisymm ?_ (inter_subset_inter_left _ (preimage_mono inter_subset_left)) rintro _ ⟨h₁, x, hx, rfl⟩; exact ⟨⟨h₁, by rwa [hf hx]⟩, mem_image_of_mem _ hx⟩ theorem image_image (hf : LeftInvOn f' f s) : f' '' (f '' s) = s := by rw [Set.image_image, image_congr hf, image_id'] theorem image_image' (hf : LeftInvOn f' f s) (hs : s₁ ⊆ s) : f' '' (f '' s₁) = s₁ := (hf.mono hs).image_image end LeftInvOn /-! ### Right inverse -/ section RightInvOn namespace RightInvOn theorem eqOn (h : RightInvOn f' f t) : EqOn (f ∘ f') id t := h theorem eq (h : RightInvOn f' f t) {y} (hy : y ∈ t) : f (f' y) = y := h hy theorem _root_.Set.LeftInvOn.rightInvOn_image (h : LeftInvOn f' f s) : RightInvOn f' f (f '' s) := fun _y ⟨_x, hx, heq⟩ => heq ▸ (congr_arg f <\| h.eq hx) theorem congr_left (h₁ : RightInvOn f₁' f t) (heq : EqOn f₁' f₂' t) : RightInvOn f₂' f t := h₁.congr_right heq theorem congr_right (h₁ : RightInvOn f' f₁ t) (hg : MapsTo f' t s) (heq : EqOn f₁ f₂ s) : RightInvOn f' f₂ t := LeftInvOn.congr_left h₁ hg heq theorem surjOn (hf : RightInvOn f' f t) (hf' : MapsTo f' t s) : SurjOn f s t := LeftInvOn.surjOn hf hf' theorem mapsTo (h : RightInvOn f' f t) (hf : SurjOn f' t s) : MapsTo f s t := LeftInvOn.mapsTo h hf lemma _root_.Set.rightInvOn_id (s : Set α) : RightInvOn id id s := fun _ _ ↦ rfl theorem comp (hf : RightInvOn f' f t) (hg : RightInvOn g' g p) (g'pt : MapsTo g' p t) : RightInvOn (f' ∘ g') (g ∘ f) p := LeftInvOn.comp hg hf g'pt theorem mono (hf : RightInvOn f' f t) (ht : t₁ ⊆ t) : RightInvOn f' f t₁ := LeftInvOn.mono hf ht end RightInvOn theorem InjOn.rightInvOn_of_leftInvOn (hf : InjOn f s) (hf' : LeftInvOn f f' t) (h₁ : MapsTo f s t) (h₂ : MapsTo f' t s) : RightInvOn f f' s := fun _ h => hf (h₂ <\| h₁ h) h (hf' (h₁ h)) theorem eqOn_of_leftInvOn_of_rightInvOn (h₁ : LeftInvOn f₁' f s) (h₂ : RightInvOn f₂' f t) (h : MapsTo f₂' t s) : EqOn f₁' f₂' t := fun y hy => calc f₁' y = (f₁' ∘ f ∘ f₂') y := congr_arg f₁' (h₂ hy).symm _ = f₂' y := h₁ (h hy) theorem SurjOn.leftInvOn_of_rightInvOn (hf : SurjOn f s t) (hf' : RightInvOn f f' s) : LeftInvOn f f' t := fun y hy => by let ⟨x, hx, heq⟩ := hf hy rw [← heq, hf' hx] end RightInvOn /-! ### Two-side inverses -/ namespace InvOn lemma _root_.Set.invOn_id (s : Set α) : InvOn id id s s := ⟨s.leftInvOn_id, s.rightInvOn_id⟩ lemma comp (hf : InvOn f' f s t) (hg : InvOn g' g t p) (fst : MapsTo f s t) (g'pt : MapsTo g' p t) : InvOn (f' ∘ g') (g ∘ f) s p := ⟨hf.1.comp hg.1 fst, hf.2.comp hg.2 g'pt⟩ @[symm] theorem symm (h : InvOn f' f s t) : InvOn f f' t s := ⟨h.right, h.left⟩ theorem mono (h : InvOn f' f s t) (hs : s₁ ⊆ s) (ht : t₁ ⊆ t) : InvOn f' f s₁ t₁ := ⟨h.1.mono hs, h.2.mono ht⟩ /-- If functions `f'` and `f` are inverse on `s` and `t`, `f` maps `s` into `t`, and `f'` maps `t` into `s`, then `f` is a bijection between `s` and `t`. The `mapsTo` arguments can be deduced from `surjOn` statements using `LeftInvOn.mapsTo` and `RightInvOn.mapsTo`. -/ theorem bijOn (h : InvOn f' f s t) (hf : MapsTo f s t) (hf' : MapsTo f' t s) : BijOn f s t := ⟨hf, h.left.injOn, h.right.surjOn hf'⟩ end InvOn end Set /-! ### `invFunOn` is a left/right inverse -/ namespace Function variable {s : Set α} {f : α → β} {a : α} {b : β} /-- Construct the inverse for a function `f` on domain `s`. This function is a right inverse of `f` on `f '' s`. For a computable version, see `Function.Embedding.invOfMemRange`. -/ noncomputable def invFunOn [Nonempty α] (f : α → β) (s : Set α) (b : β) : α := open scoped Classical in if h : ∃ a, a ∈ s ∧ f a = b then Classical.choose h else Classical.choice ‹Nonempty α› variable [Nonempty α] theorem invFunOn_pos (h : ∃ a ∈ s, f a = b) : invFunOn f s b ∈ s ∧ f (invFunOn f s b) = b := by rw [invFunOn, dif_pos h] exact Classical.choose_spec h theorem invFunOn_mem (h : ∃ a ∈ s, f a = b) : invFunOn f s b ∈ s := (invFunOn_pos h).left theorem invFunOn_eq (h : ∃ a ∈ s, f a = b) : f (invFunOn f s b) = b := (invFunOn_pos h).right theorem invFunOn_neg (h : ¬∃ a ∈ s, f a = b) : invFunOn f s b = Classical.choice ‹Nonempty α› := by rw [invFunOn, dif_neg h] @[simp] theorem invFunOn_apply_mem (h : a ∈ s) : invFunOn f s (f a) ∈ s := invFunOn_mem ⟨a, h, rfl⟩ theorem invFunOn_apply_eq (h : a ∈ s) : f (invFunOn f s (f a)) = f a := invFunOn_eq ⟨a, h, rfl⟩ end Function open Function namespace Set variable {s s₁ s₂ : Set α} {t : Set β} {f : α → β} theorem InjOn.leftInvOn_invFunOn [Nonempty α] (h : InjOn f s) : LeftInvOn (invFunOn f s) f s := fun _a ha => h (invFunOn_apply_mem ha) ha (invFunOn_apply_eq ha) theorem InjOn.invFunOn_image [Nonempty α] (h : InjOn f s₂) (ht : s₁ ⊆ s₂) : invFunOn f s₂ '' (f '' s₁) = s₁ := h.leftInvOn_invFunOn.image_image' ht theorem _root_.Function.leftInvOn_invFunOn_of_subset_image_image [Nonempty α] (h : s ⊆ (invFunOn f s) '' (f '' s)) : LeftInvOn (invFunOn f s) f s := fun x hx ↦ by obtain ⟨-, ⟨x, hx', rfl⟩, rfl⟩ := h hx rw [invFunOn_apply_eq (f := f) hx'] theorem injOn_iff_invFunOn_image_image_eq_self [Nonempty α] : InjOn f s ↔ (invFunOn f s) '' (f '' s) = s := ⟨fun h ↦ h.invFunOn_image Subset.rfl, fun h ↦ (Function.leftInvOn_invFunOn_of_subset_image_image h.symm.subset).injOn⟩ theorem _root_.Function.invFunOn_injOn_image [Nonempty α] (f : α → β) (s : Set α) : Set.InjOn (invFunOn f s) (f '' s) := by rintro _ ⟨x, hx, rfl⟩ _ ⟨x', hx', rfl⟩ he rw [← invFunOn_apply_eq (f := f) hx, he, invFunOn_apply_eq (f := f) hx'] theorem _root_.Function.invFunOn_image_image_subset [Nonempty α] (f : α → β) (s : Set α) : (invFunOn f s) '' (f '' s) ⊆ s := by rintro _ ⟨_, ⟨x,hx,rfl⟩, rfl⟩; exact invFunOn_apply_mem hx theorem SurjOn.rightInvOn_invFunOn [Nonempty α] (h : SurjOn f s t) : RightInvOn (invFunOn f s) f t := fun _y hy => invFunOn_eq <\| h hy theorem BijOn.invOn_invFunOn [Nonempty α] (h : BijOn f s t) : InvOn (invFunOn f s) f s t := ⟨h.injOn.leftInvOn_invFunOn, h.surjOn.rightInvOn_invFunOn⟩ theorem SurjOn.invOn_invFunOn [Nonempty α] (h : SurjOn f s t) : InvOn (invFunOn f s) f (invFunOn f s '' t) t := by refine ⟨?_, h.rightInvOn_invFunOn⟩ rintro _ ⟨y, hy, rfl⟩ rw [h.rightInvOn_invFunOn hy] theorem SurjOn.mapsTo_invFunOn [Nonempty α] (h : SurjOn f s t) : MapsTo (invFunOn f s) t s := fun _y hy => mem_preimage.2 <\| invFunOn_mem <\| h hy /-- This lemma is a special case of `rightInvOn_invFunOn.image_image'`; it may make more sense to use the other lemma directly in an application. -/ theorem SurjOn.image_invFunOn_image_of_subset [Nonempty α] {r : Set β} (hf : SurjOn f s t) (hrt : r ⊆ t) : f '' (f.invFunOn s '' r) = r := hf.rightInvOn_invFunOn.image_image' hrt /-- This lemma is a special case of `rightInvOn_invFunOn.image_image`; it may make more sense to use the other lemma directly in an application. -/ theorem SurjOn.image_invFunOn_image [Nonempty α] (hf : SurjOn f s t) : f '' (f.invFunOn s '' t) = t := hf.rightInvOn_invFunOn.image_image theorem SurjOn.bijOn_subset [Nonempty α] (h : SurjOn f s t) : BijOn f (invFunOn f s '' t) t := by refine h.invOn_invFunOn.bijOn ?_ (mapsTo_image _ _) rintro _ ⟨y, hy, rfl⟩ rwa [h.rightInvOn_invFunOn hy] theorem surjOn_iff_exists_bijOn_subset : SurjOn f s t ↔ ∃ s' ⊆ s, BijOn f s' t := by constructor · rcases eq_empty_or_nonempty t with (rfl \| ht) · exact fun _ => ⟨∅, empty_subset _, bijOn_empty f⟩ · intro h haveI : Nonempty α := ⟨Classical.choose (h.comap_nonempty ht)⟩ exact ⟨_, h.mapsTo_invFunOn.image_subset, h.bijOn_subset⟩ · rintro ⟨s', hs', hfs'⟩ exact hfs'.surjOn.mono hs' (Subset.refl _) alias ⟨SurjOn.exists_bijOn_subset, _⟩ := Set.surjOn_iff_exists_bijOn_subset variable (f s) lemma exists_subset_bijOn : ∃ s' ⊆ s, BijOn f s' (f '' s) := surjOn_iff_exists_bijOn_subset.mp (surjOn_image f s) lemma exists_image_eq_and_injOn : ∃ u, f '' u = f '' s ∧ InjOn f u := let ⟨u, _, hfu⟩ := exists_subset_bijOn s f ⟨u, hfu.image_eq, hfu.injOn⟩ variable {f s} lemma exists_image_eq_injOn_of_subset_range (ht : t ⊆ range f) : ∃ s, f '' s = t ∧ InjOn f s := image_preimage_eq_of_subset ht ▸ exists_image_eq_and_injOn _ _ /-- If `f` maps `s` bijectively to `t` and a set `t'` is contained in the image of some `s₁ ⊇ s`, then `s₁` has a subset containing `s` that `f` maps bijectively to `t'`. -/ theorem BijOn.exists_extend_of_subset {t' : Set β} (h : BijOn f s t) (hss₁ : s ⊆ s₁) (htt' : t ⊆ t') (ht' : SurjOn f s₁ t') : ∃ s', s ⊆ s' ∧ s' ⊆ s₁ ∧ Set.BijOn f s' t' := by obtain ⟨r, hrss, hbij⟩ := exists_subset_bijOn ((s₁ ∩ f ⁻¹' t') \ f ⁻¹' t) f rw [image_diff_preimage, image_inter_preimage] at hbij refine ⟨s ∪ r, subset_union_left, ?_, ?_, ?_, fun y hyt' ↦ ?_⟩ · exact union_subset hss₁ <\| hrss.trans <\| diff_subset.trans inter_subset_left · rw [mapsTo', image_union, hbij.image_eq, h.image_eq, union_subset_iff] exact ⟨htt', diff_subset.trans inter_subset_right⟩ · rw [injOn_union, and_iff_right h.injOn, and_iff_right hbij.injOn] · refine fun x hxs y hyr hxy ↦ (hrss hyr).2 ?_ rw [← h.image_eq] exact ⟨x, hxs, hxy⟩ exact (subset_diff.1 hrss).2.symm.mono_left h.mapsTo rw [image_union, h.image_eq, hbij.image_eq, union_diff_self] exact .inr ⟨ht' hyt', hyt'⟩ /-- If `f` maps `s` bijectively to `t`, and `t'` is a superset of `t` contained in the range of `f`, then `f` maps some superset of `s` bijectively to `t'`. -/ theorem BijOn.exists_extend {t' : Set β} (h : BijOn f s t) (htt' : t ⊆ t') (ht' : t' ⊆ range f) : ∃ s', s ⊆ s' ∧ BijOn f s' t' := by simpa using h.exists_extend_of_subset (subset_univ s) htt' (by simpa [SurjOn]) theorem InjOn.exists_subset_injOn_subset_range_eq {r : Set α} (hinj : InjOn f r) (hrs : r ⊆ s) : ∃ u : Set α, r ⊆ u ∧ u ⊆ s ∧ f '' u = f '' s ∧ InjOn f u := by obtain ⟨u, hru, hus, h⟩ := hinj.bijOn_image.exists_extend_of_subset hrs (image_subset f hrs) Subset.rfl exact ⟨u, hru, hus, h.image_eq, h.injOn⟩ theorem preimage_invFun_of_mem [n : Nonempty α] {f : α → β} (hf : Injective f) {s : Set α} (h : Classical.choice n ∈ s) : invFun f ⁻¹' s = f '' s ∪ (range f)ᶜ := by ext x rcases em (x ∈ range f) with (⟨a, rfl⟩ \| hx) · simp only [mem_preimage, mem_union, mem_compl_iff, mem_range_self, not_true, or_false, leftInverse_invFun hf _, hf.mem_set_image] · simp only [mem_preimage, invFun_neg hx, h, hx, mem_union, mem_compl_iff, not_false_iff, or_true] theorem preimage_invFun_of_not_mem [n : Nonempty α] {f : α → β} (hf : Injective f) {s : Set α} (h : Classical.choice n ∉ s) : invFun f ⁻¹' s = f '' s := by ext x rcases em (x ∈ range f) with (⟨a, rfl⟩ \| hx) · rw [mem_preimage, leftInverse_invFun hf, hf.mem_set_image] · have : x ∉ f '' s := fun h' => hx (image_subset_range _ _ h') simp only [mem_preimage, invFun_neg hx, h, this] lemma BijOn.symm {g : β → α} (h : InvOn f g t s) (hf : BijOn f s t) : BijOn g t s := ⟨h.2.mapsTo hf.surjOn, h.1.injOn, h.2.surjOn hf.mapsTo⟩ lemma bijOn_comm {g : β → α} (h : InvOn f g t s) : BijOn f s t ↔ BijOn g t s := ⟨BijOn.symm h, BijOn.symm h.symm⟩ end Set namespace Function open Set variable {fa : α → α} {fb : β → β} {f : α → β} {g : β → γ} {s t : Set α} theorem Injective.comp_injOn (hg : Injective g) (hf : s.InjOn f) : s.InjOn (g ∘ f) := hg.injOn.comp hf (mapsTo_univ _ _) theorem Surjective.surjOn (hf : Surjective f) (s : Set β) : SurjOn f univ s := (surjective_iff_surjOn_univ.1 hf).mono (Subset.refl _) (subset_univ _) theorem LeftInverse.leftInvOn {g : β → α} (h : LeftInverse f g) (s : Set β) : LeftInvOn f g s := fun x _ => h x theorem RightInverse.rightInvOn {g : β → α} (h : RightInverse f g) (s : Set α) : RightInvOn f g s := fun x _ => h x theorem LeftInverse.rightInvOn_range {g : β → α} (h : LeftInverse f g) : RightInvOn f g (range g) := forall_mem_range.2 fun i => congr_arg g (h i) namespace Semiconj theorem mapsTo_image (h : Semiconj f fa fb) (ha : MapsTo fa s t) : MapsTo fb (f '' s) (f '' t) := fun _y ⟨x, hx, hy⟩ => hy ▸ ⟨fa x, ha hx, h x⟩ theorem mapsTo_image_right {t : Set β} (h : Semiconj f fa fb) (hst : MapsTo f s t) : MapsTo f (fa '' s) (fb '' t) := mapsTo_image_iff.2 fun x hx ↦ ⟨f x, hst hx, (h x).symm⟩ theorem mapsTo_range (h : Semiconj f fa fb) : MapsTo fb (range f) (range f) := fun _y ⟨x, hy⟩ => hy ▸ ⟨fa x, h x⟩ theorem surjOn_image (h : Semiconj f fa fb) (ha : SurjOn fa s t) : SurjOn fb (f '' s) (f '' t) := by rintro y ⟨x, hxt, rfl⟩ rcases ha hxt with ⟨x, hxs, rfl⟩ rw [h x] exact mem_image_of_mem _ (mem_image_of_mem _ hxs) theorem surjOn_range (h : Semiconj f fa fb) (ha : Surjective fa) : SurjOn fb (range f) (range f) := by rw [← image_univ] exact h.surjOn_image (ha.surjOn univ) theorem injOn_image (h : Semiconj f fa fb) (ha : InjOn fa s) (hf : InjOn f (fa '' s)) : InjOn fb (f '' s) := by rintro _ ⟨x, hx, rfl⟩ _ ⟨y, hy, rfl⟩ H simp only [← h.eq] at H exact congr_arg f (ha hx hy <\| hf (mem_image_of_mem fa hx) (mem_image_of_mem fa hy) H) theorem injOn_range (h : Semiconj f fa fb) (ha : Injective fa) (hf : InjOn f (range fa)) : InjOn fb (range f) := by rw [← image_univ] at * exact h.injOn_image ha.injOn hf theorem bijOn_image (h : Semiconj f fa fb) (ha : BijOn fa s t) (hf : InjOn f t) : BijOn fb (f '' s) (f '' t) := ⟨h.mapsTo_image ha.mapsTo, h.injOn_image ha.injOn (ha.image_eq.symm ▸ hf), h.surjOn_image ha.surjOn⟩ theorem bijOn_range (h : Semiconj f fa fb) (ha : Bijective fa) (hf : Injective f) : BijOn fb (range f) (range f) := by rw [← image_univ] exact h.bijOn_image (bijective_iff_bijOn_univ.1 ha) hf.injOn theorem mapsTo_preimage (h : Semiconj f fa fb) {s t : Set β} (hb : MapsTo fb s t) : MapsTo fa (f ⁻¹' s) (f ⁻¹' t) := fun x hx => by simp only [mem_preimage, h x, hb hx] theorem injOn_preimage (h : Semiconj f fa fb) {s : Set β} (hb : InjOn fb s) (hf : InjOn f (f ⁻¹' s)) : InjOn fa (f ⁻¹' s) := by intro x hx y hy H have := congr_arg f H rw [h.eq, h.eq] at this exact hf hx hy (hb hx hy this) end Semiconj theorem update_comp_eq_of_not_mem_range' {α : Sort} {β : Type} {γ : β → Sort} [DecidableEq β] (g : ∀ b, γ b) {f : α → β} {i : β} (a : γ i) (h : i ∉ Set.range f) : (fun j => update g i a (f j)) = fun j => g (f j) := (update_comp_eq_of_forall_ne' _ _) fun x hx => h ⟨x, hx⟩ /-- Non-dependent version of `Function.update_comp_eq_of_not_mem_range'` -/ theorem update_comp_eq_of_not_mem_range {α : Sort} {β : Type} {γ : Sort} [DecidableEq β] (g : β → γ) {f : α → β} {i : β} (a : γ) (h : i ∉ Set.range f) : update g i a ∘ f = g ∘ f := update_comp_eq_of_not_mem_range' g a h theorem insert_injOn (s : Set α) : sᶜ.InjOn fun a => insert a s := fun _a ha _ _ => (insert_inj ha).1 lemma apply_eq_of_range_eq_singleton {f : α → β} {b : β} (h : range f = {b}) (a : α) : f a = b := by simpa only [h, mem_singleton_iff] using mem_range_self (f := f) a end Function /-! ### Equivalences, permutations -/ namespace Set variable {p : β → Prop} [DecidablePred p] {f : α ≃ Subtype p} {g g₁ g₂ : Perm α} {s t : Set α} protected lemma MapsTo.extendDomain (h : MapsTo g s t) : MapsTo (g.extendDomain f) ((↑) ∘ f '' s) ((↑) ∘ f '' t) := by rintro _ ⟨a, ha, rfl⟩; exact ⟨_, h ha, by simp_rw [Function.comp_apply, extendDomain_apply_image]⟩ protected lemma SurjOn.extendDomain (h : SurjOn g s t) : SurjOn (g.extendDomain f) ((↑) ∘ f '' s) ((↑) ∘ f '' t) := by rintro _ ⟨a, ha, rfl⟩ obtain ⟨b, hb, rfl⟩ := h ha exact ⟨_, ⟨_, hb, rfl⟩, by simp_rw [Function.comp_apply, extendDomain_apply_image]⟩ protected lemma BijOn.extendDomain (h : BijOn g s t) : BijOn (g.extendDomain f) ((↑) ∘ f '' s) ((↑) ∘ f '' t) := ⟨h.mapsTo.extendDomain, (g.extendDomain f).injective.injOn, h.surjOn.extendDomain⟩ protected lemma LeftInvOn.extendDomain (h : LeftInvOn g₁ g₂ s) : LeftInvOn (g₁.extendDomain f) (g₂.extendDomain f) ((↑) ∘ f '' s) := by rintro _ ⟨a, ha, rfl⟩; simp_rw [Function.comp_apply, extendDomain_apply_image, h ha] protected lemma RightInvOn.extendDomain (h : RightInvOn g₁ g₂ t) : RightInvOn (g₁.extendDomain f) (g₂.extendDomain f) ((↑) ∘ f '' t) := by rintro _ ⟨a, ha, rfl⟩; simp_rw [Function.comp_apply, extendDomain_apply_image, h ha] protected lemma InvOn.extendDomain (h : InvOn g₁ g₂ s t) : InvOn (g₁.extendDomain f) (g₂.extendDomain f) ((↑) ∘ f '' s) ((↑) ∘ f '' t) := ⟨h.1.extendDomain, h.2.extendDomain⟩ end Set namespace Set variable {α₁ α₂ β₁ β₂ : Type} {s₁ : Set α₁} {s₂ : Set α₂} {t₁ : Set β₁} {t₂ : Set β₂} {f₁ : α₁ → β₁} {f₂ : α₂ → β₂} {g₁ : β₁ → α₁} {g₂ : β₂ → α₂} lemma InjOn.prodMap (h₁ : s₁.InjOn f₁) (h₂ : s₂.InjOn f₂) : (s₁ ×ˢ s₂).InjOn fun x ↦ (f₁ x.1, f₂ x.2) := fun x hx y hy ↦ by simp_rw [Prod.ext_iff]; exact And.imp (h₁ hx.1 hy.1) (h₂ hx.2 hy.2) lemma SurjOn.prodMap (h₁ : SurjOn f₁ s₁ t₁) (h₂ : SurjOn f₂ s₂ t₂) : SurjOn (fun x ↦ (f₁ x.1, f₂ x.2)) (s₁ ×ˢ s₂) (t₁ ×ˢ t₂) := by rintro x hx obtain ⟨a₁, ha₁, hx₁⟩ := h₁ hx.1 obtain ⟨a₂, ha₂, hx₂⟩ := h₂ hx.2 exact ⟨(a₁, a₂), ⟨ha₁, ha₂⟩, Prod.ext hx₁ hx₂⟩ lemma MapsTo.prodMap (h₁ : MapsTo f₁ s₁ t₁) (h₂ : MapsTo f₂ s₂ t₂) : MapsTo (fun x ↦ (f₁ x.1, f₂ x.2)) (s₁ ×ˢ s₂) (t₁ ×ˢ t₂) := fun _x hx ↦ ⟨h₁ hx.1, h₂ hx.2⟩ lemma BijOn.prodMap (h₁ : BijOn f₁ s₁ t₁) (h₂ : BijOn f₂ s₂ t₂) : BijOn (fun x ↦ (f₁ x.1, f₂ x.2)) (s₁ ×ˢ s₂) (t₁ ×ˢ t₂) := ⟨h₁.mapsTo.prodMap h₂.mapsTo, h₁.injOn.prodMap h₂.injOn, h₁.surjOn.prodMap h₂.surjOn⟩ lemma LeftInvOn.prodMap (h₁ : LeftInvOn g₁ f₁ s₁) (h₂ : LeftInvOn g₂ f₂ s₂) : LeftInvOn (fun x ↦ (g₁ x.1, g₂ x.2)) (fun x ↦ (f₁ x.1, f₂ x.2)) (s₁ ×ˢ s₂) := fun _x hx ↦ Prod.ext (h₁ hx.1) (h₂ hx.2) lemma RightInvOn.prodMap (h₁ : RightInvOn g₁ f₁ t₁) (h₂ : RightInvOn g₂ f₂ t₂) : RightInvOn (fun x ↦ (g₁ x.1, g₂ x.2)) (fun x ↦ (f₁ x.1, f₂ x.2)) (t₁ ×ˢ t₂) := fun _x hx ↦ Prod.ext (h₁ hx.1) (h₂ hx.2) lemma InvOn.prodMap (h₁ : InvOn g₁ f₁ s₁ t₁) (h₂ : InvOn g₂ f₂ s₂ t₂) : InvOn (fun x ↦ (g₁ x.1, g₂ x.2)) (fun x ↦ (f₁ x.1, f₂ x.2)) (s₁ ×ˢ s₂) (t₁ ×ˢ t₂) := ⟨h₁.1.prodMap h₂.1, h₁.2.prodMap h₂.2⟩ end Set namespace Equiv open Set variable (e : α ≃ β) {s : Set α} {t : Set β} lemma bijOn' (h₁ : MapsTo e s t) (h₂ : MapsTo e.symm t s) : BijOn e s t := ⟨h₁, e.injective.injOn, fun b hb ↦ ⟨e.symm b, h₂ hb, apply_symm_apply _ _⟩⟩ protected lemma bijOn (h : ∀ a, e a ∈ t ↔ a ∈ s) : BijOn e s t := e.bijOn' (fun _ ↦ (h _).2) fun b hb ↦ (h _).1 <\| by rwa [apply_symm_apply] lemma invOn : InvOn e e.symm t s := ⟨e.rightInverse_symm.leftInvOn _, e.leftInverse_symm.leftInvOn _⟩ lemma bijOn_image : BijOn e s (e '' s) := e.injective.injOn.bijOn_image lemma bijOn_symm_image : BijOn e.symm (e '' s) s := e.bijOn_image.symm e.invOn variable {e} @[simp] lemma bijOn_symm : BijOn e.symm t s ↔ BijOn e s t := bijOn_comm e.symm.invOn alias ⟨_root_.Set.BijOn.of_equiv_symm, _root_.Set.BijOn.equiv_symm⟩ := bijOn_symm variable [DecidableEq α] {a b : α} lemma bijOn_swap (ha : a ∈ s) (hb : b ∈ s) : BijOn (swap a b) s s := (swap a b).bijOn fun x ↦ by obtain rfl \| hxa := eq_or_ne x a <;> obtain rfl \| hxb := eq_or_ne x b <;> simp [, swap_apply_of_ne_of_ne] end Equiv		Mathlib/Data/Set/Function.lean	2,035	2,039
/- Copyright (c) 2019 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Yaël Dillies -/ import Mathlib.Algebra.Module.BigOperators import Mathlib.GroupTheory.Perm.Basic import Mathlib.GroupTheory.Perm.Finite import Mathlib.GroupTheory.Perm.List import Mathlib.GroupTheory.Perm.Sign /-! # Cycles of a permutation This file starts the theory of cycles in permutations. ## Main definitions In the following, `f : Equiv.Perm β`. * `Equiv.Perm.SameCycle`: `f.SameCycle x y` when `x` and `y` are in the same cycle of `f`. * `Equiv.Perm.IsCycle`: `f` is a cycle if any two nonfixed points of `f` are related by repeated applications of `f`, and `f` is not the identity. * `Equiv.Perm.IsCycleOn`: `f` is a cycle on a set `s` when any two points of `s` are related by repeated applications of `f`. ## Notes `Equiv.Perm.IsCycle` and `Equiv.Perm.IsCycleOn` are different in three ways: * `IsCycle` is about the entire type while `IsCycleOn` is restricted to a set. * `IsCycle` forbids the identity while `IsCycleOn` allows it (if `s` is a subsingleton). * `IsCycleOn` forbids fixed points on `s` (if `s` is nontrivial), while `IsCycle` allows them. -/ open Equiv Function Finset variable {ι α β : Type} namespace Equiv.Perm /-! ### `SameCycle` -/ section SameCycle variable {f g : Perm α} {p : α → Prop} {x y z : α} /-- The equivalence relation indicating that two points are in the same cycle of a permutation. -/ def SameCycle (f : Perm α) (x y : α) : Prop := ∃ i : ℤ, (f ^ i) x = y @[refl] theorem SameCycle.refl (f : Perm α) (x : α) : SameCycle f x x := ⟨0, rfl⟩ theorem SameCycle.rfl : SameCycle f x x := SameCycle.refl _ _ protected theorem _root_.Eq.sameCycle (h : x = y) (f : Perm α) : f.SameCycle x y := by rw [h] @[symm] theorem SameCycle.symm : SameCycle f x y → SameCycle f y x := fun ⟨i, hi⟩ => ⟨-i, by rw [zpow_neg, ← hi, inv_apply_self]⟩ theorem sameCycle_comm : SameCycle f x y ↔ SameCycle f y x := ⟨SameCycle.symm, SameCycle.symm⟩ @[trans] theorem SameCycle.trans : SameCycle f x y → SameCycle f y z → SameCycle f x z := fun ⟨i, hi⟩ ⟨j, hj⟩ => ⟨j + i, by rw [zpow_add, mul_apply, hi, hj]⟩ variable (f) in theorem SameCycle.equivalence : Equivalence (SameCycle f) := ⟨SameCycle.refl f, SameCycle.symm, SameCycle.trans⟩ /-- The setoid defined by the `SameCycle` relation. -/ def SameCycle.setoid (f : Perm α) : Setoid α where r := f.SameCycle iseqv := SameCycle.equivalence f @[simp] theorem sameCycle_one : SameCycle 1 x y ↔ x = y := by simp [SameCycle] @[simp] theorem sameCycle_inv : SameCycle f⁻¹ x y ↔ SameCycle f x y := (Equiv.neg _).exists_congr_left.trans <\| by simp [SameCycle] alias ⟨SameCycle.of_inv, SameCycle.inv⟩ := sameCycle_inv @[simp] theorem sameCycle_conj : SameCycle (g f * g⁻¹) x y ↔ SameCycle f (g⁻¹ x) (g⁻¹ y) := exists_congr fun i => by simp [conj_zpow, eq_inv_iff_eq] theorem SameCycle.conj : SameCycle f x y → SameCycle (g * f * g⁻¹) (g x) (g y) := by simp [sameCycle_conj] theorem SameCycle.apply_eq_self_iff : SameCycle f x y → (f x = x ↔ f y = y) := fun ⟨i, hi⟩ => by rw [← hi, ← mul_apply, ← zpow_one_add, add_comm, zpow_add_one, mul_apply, (f ^ i).injective.eq_iff] theorem SameCycle.eq_of_left (h : SameCycle f x y) (hx : IsFixedPt f x) : x = y := let ⟨_, hn⟩ := h (hx.perm_zpow _).eq.symm.trans hn theorem SameCycle.eq_of_right (h : SameCycle f x y) (hy : IsFixedPt f y) : x = y := h.eq_of_left <\| h.apply_eq_self_iff.2 hy @[simp] theorem sameCycle_apply_left : SameCycle f (f x) y ↔ SameCycle f x y := (Equiv.addRight 1).exists_congr_left.trans <\| by simp [zpow_sub, SameCycle, Int.add_neg_one, Function.comp] @[simp] theorem sameCycle_apply_right : SameCycle f x (f y) ↔ SameCycle f x y := by rw [sameCycle_comm, sameCycle_apply_left, sameCycle_comm] @[simp] theorem sameCycle_inv_apply_left : SameCycle f (f⁻¹ x) y ↔ SameCycle f x y := by rw [← sameCycle_apply_left, apply_inv_self] @[simp] theorem sameCycle_inv_apply_right : SameCycle f x (f⁻¹ y) ↔ SameCycle f x y := by rw [← sameCycle_apply_right, apply_inv_self] @[simp] theorem sameCycle_zpow_left {n : ℤ} : SameCycle f ((f ^ n) x) y ↔ SameCycle f x y := (Equiv.addRight (n : ℤ)).exists_congr_left.trans <\| by simp [SameCycle, zpow_add] @[simp] theorem sameCycle_zpow_right {n : ℤ} : SameCycle f x ((f ^ n) y) ↔ SameCycle f x y := by rw [sameCycle_comm, sameCycle_zpow_left, sameCycle_comm] @[simp] theorem sameCycle_pow_left {n : ℕ} : SameCycle f ((f ^ n) x) y ↔ SameCycle f x y := by rw [← zpow_natCast, sameCycle_zpow_left] @[simp] theorem sameCycle_pow_right {n : ℕ} : SameCycle f x ((f ^ n) y) ↔ SameCycle f x y := by rw [← zpow_natCast, sameCycle_zpow_right] alias ⟨SameCycle.of_apply_left, SameCycle.apply_left⟩ := sameCycle_apply_left alias ⟨SameCycle.of_apply_right, SameCycle.apply_right⟩ := sameCycle_apply_right alias ⟨SameCycle.of_inv_apply_left, SameCycle.inv_apply_left⟩ := sameCycle_inv_apply_left alias ⟨SameCycle.of_inv_apply_right, SameCycle.inv_apply_right⟩ := sameCycle_inv_apply_right alias ⟨SameCycle.of_pow_left, SameCycle.pow_left⟩ := sameCycle_pow_left alias ⟨SameCycle.of_pow_right, SameCycle.pow_right⟩ := sameCycle_pow_right alias ⟨SameCycle.of_zpow_left, SameCycle.zpow_left⟩ := sameCycle_zpow_left alias ⟨SameCycle.of_zpow_right, SameCycle.zpow_right⟩ := sameCycle_zpow_right theorem SameCycle.of_pow {n : ℕ} : SameCycle (f ^ n) x y → SameCycle f x y := fun ⟨m, h⟩ => ⟨n * m, by simp [zpow_mul, h]⟩ theorem SameCycle.of_zpow {n : ℤ} : SameCycle (f ^ n) x y → SameCycle f x y := fun ⟨m, h⟩ => ⟨n * m, by simp [zpow_mul, h]⟩ @[simp] theorem sameCycle_subtypePerm {h} {x y : { x // p x }} : (f.subtypePerm h).SameCycle x y ↔ f.SameCycle x y := exists_congr fun n => by simp [Subtype.ext_iff] alias ⟨_, SameCycle.subtypePerm⟩ := sameCycle_subtypePerm @[simp] theorem sameCycle_extendDomain {p : β → Prop} [DecidablePred p] {f : α ≃ Subtype p} : SameCycle (g.extendDomain f) (f x) (f y) ↔ g.SameCycle x y := exists_congr fun n => by rw [← extendDomain_zpow, extendDomain_apply_image, Subtype.coe_inj, f.injective.eq_iff] alias ⟨_, SameCycle.extendDomain⟩ := sameCycle_extendDomain theorem SameCycle.exists_pow_eq' [Finite α] : SameCycle f x y → ∃ i < orderOf f, (f ^ i) x = y := by rintro ⟨k, rfl⟩ use (k % orderOf f).natAbs have h₀ := Int.natCast_pos.mpr (orderOf_pos f) have h₁ := Int.emod_nonneg k h₀.ne' rw [← zpow_natCast, Int.natAbs_of_nonneg h₁, zpow_mod_orderOf] refine ⟨?_, by rfl⟩ rw [← Int.ofNat_lt, Int.natAbs_of_nonneg h₁] exact Int.emod_lt_of_pos _ h₀ theorem SameCycle.exists_pow_eq'' [Finite α] (h : SameCycle f x y) : ∃ i : ℕ, 0 < i ∧ i ≤ orderOf f ∧ (f ^ i) x = y := by obtain ⟨_ \| i, hi, rfl⟩ := h.exists_pow_eq' · refine ⟨orderOf f, orderOf_pos f, le_rfl, ?_⟩ rw [pow_orderOf_eq_one, pow_zero] · exact ⟨i.succ, i.zero_lt_succ, hi.le, by rfl⟩ theorem SameCycle.exists_fin_pow_eq [Finite α] (h : SameCycle f x y) : ∃ i : Fin (orderOf f), (f ^ (i : ℕ)) x = y := by obtain ⟨i, hi, hx⟩ := SameCycle.exists_pow_eq' h exact ⟨⟨i, hi⟩, hx⟩ theorem SameCycle.exists_nat_pow_eq [Finite α] (h : SameCycle f x y) : ∃ i : ℕ, (f ^ i) x = y := by obtain ⟨i, _, hi⟩ := h.exists_pow_eq' exact ⟨i, hi⟩ instance (f : Perm α) [DecidableRel (SameCycle f)] : DecidableRel (SameCycle f⁻¹) := fun x y => decidable_of_iff (f.SameCycle x y) (sameCycle_inv).symm instance (priority := 100) [DecidableEq α] : DecidableRel (SameCycle (1 : Perm α)) := fun x y => decidable_of_iff (x = y) sameCycle_one.symm end SameCycle /-! ### `IsCycle` -/ section IsCycle variable {f g : Perm α} {x y : α} /-- A cycle is a non identity permutation where any two nonfixed points of the permutation are related by repeated application of the permutation. -/ def IsCycle (f : Perm α) : Prop := ∃ x, f x ≠ x ∧ ∀ ⦃y⦄, f y ≠ y → SameCycle f x y theorem IsCycle.ne_one (h : IsCycle f) : f ≠ 1 := fun hf => by simp [hf, IsCycle] at h @[simp] theorem not_isCycle_one : ¬(1 : Perm α).IsCycle := fun H => H.ne_one rfl protected theorem IsCycle.sameCycle (hf : IsCycle f) (hx : f x ≠ x) (hy : f y ≠ y) : SameCycle f x y := let ⟨g, hg⟩ := hf let ⟨a, ha⟩ := hg.2 hx	let ⟨b, hb⟩ := hg.2 hy ⟨b - a, by rw [← ha, ← mul_apply, ← zpow_add, sub_add_cancel, hb]⟩ theorem IsCycle.exists_zpow_eq : IsCycle f → f x ≠ x → f y ≠ y → ∃ i : ℤ, (f ^ i) x = y := IsCycle.sameCycle theorem IsCycle.inv (hf : IsCycle f) : IsCycle f⁻¹ :=	Mathlib/GroupTheory/Perm/Cycle/Basic.lean	237	243
/- Copyright (c) 2017 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Algebra.Ring.Associated import Mathlib.Algebra.Star.Unitary import Mathlib.RingTheory.PrincipalIdealDomain import Mathlib.Tactic.Ring import Mathlib.Algebra.EuclideanDomain.Int /-! # ℤ[√d] The ring of integers adjoined with a square root of `d : ℤ`. After defining the norm, we show that it is a linearly ordered commutative ring, as well as an integral domain. We provide the universal property, that ring homomorphisms `ℤ√d →+* R` correspond to choices of square roots of `d` in `R`. -/ /-- The ring of integers adjoined with a square root of `d`. These have the form `a + b √d` where `a b : ℤ`. The components are called `re` and `im` by analogy to the negative `d` case. -/ @[ext] structure Zsqrtd (d : ℤ) where /-- Component of the integer not multiplied by `√d` -/ re : ℤ /-- Component of the integer multiplied by `√d` -/ im : ℤ deriving DecidableEq @[inherit_doc] prefix:100 "ℤ√" => Zsqrtd namespace Zsqrtd section variable {d : ℤ} /-- Convert an integer to a `ℤ√d` -/ def ofInt (n : ℤ) : ℤ√d := ⟨n, 0⟩ theorem ofInt_re (n : ℤ) : (ofInt n : ℤ√d).re = n := rfl theorem ofInt_im (n : ℤ) : (ofInt n : ℤ√d).im = 0 := rfl /-- The zero of the ring -/ instance : Zero (ℤ√d) := ⟨ofInt 0⟩ @[simp] theorem zero_re : (0 : ℤ√d).re = 0 := rfl @[simp] theorem zero_im : (0 : ℤ√d).im = 0 := rfl instance : Inhabited (ℤ√d) := ⟨0⟩ /-- The one of the ring -/ instance : One (ℤ√d) := ⟨ofInt 1⟩ @[simp] theorem one_re : (1 : ℤ√d).re = 1 := rfl @[simp] theorem one_im : (1 : ℤ√d).im = 0 := rfl /-- The representative of `√d` in the ring -/ def sqrtd : ℤ√d := ⟨0, 1⟩ @[simp] theorem sqrtd_re : (sqrtd : ℤ√d).re = 0 := rfl @[simp] theorem sqrtd_im : (sqrtd : ℤ√d).im = 1 := rfl /-- Addition of elements of `ℤ√d` -/ instance : Add (ℤ√d) := ⟨fun z w => ⟨z.1 + w.1, z.2 + w.2⟩⟩ @[simp] theorem add_def (x y x' y' : ℤ) : (⟨x, y⟩ + ⟨x', y'⟩ : ℤ√d) = ⟨x + x', y + y'⟩ := rfl @[simp] theorem add_re (z w : ℤ√d) : (z + w).re = z.re + w.re := rfl @[simp] theorem add_im (z w : ℤ√d) : (z + w).im = z.im + w.im := rfl /-- Negation in `ℤ√d` -/ instance : Neg (ℤ√d) := ⟨fun z => ⟨-z.1, -z.2⟩⟩ @[simp] theorem neg_re (z : ℤ√d) : (-z).re = -z.re := rfl @[simp] theorem neg_im (z : ℤ√d) : (-z).im = -z.im := rfl /-- Multiplication in `ℤ√d` -/ instance : Mul (ℤ√d) := ⟨fun z w => ⟨z.1 * w.1 + d * z.2 * w.2, z.1 * w.2 + z.2 * w.1⟩⟩ @[simp] theorem mul_re (z w : ℤ√d) : (z * w).re = z.re * w.re + d * z.im * w.im := rfl @[simp] theorem mul_im (z w : ℤ√d) : (z * w).im = z.re * w.im + z.im * w.re := rfl instance addCommGroup : AddCommGroup (ℤ√d) := by refine { add := (· + ·) zero := (0 : ℤ√d) sub := fun a b => a + -b neg := Neg.neg nsmul := @nsmulRec (ℤ√d) ⟨0⟩ ⟨(· + ·)⟩ zsmul := @zsmulRec (ℤ√d) ⟨0⟩ ⟨(· + ·)⟩ ⟨Neg.neg⟩ (@nsmulRec (ℤ√d) ⟨0⟩ ⟨(· + ·)⟩) add_assoc := ?_ zero_add := ?_ add_zero := ?_ neg_add_cancel := ?_ add_comm := ?_ } <;> intros <;> ext <;> simp [add_comm, add_left_comm] @[simp] theorem sub_re (z w : ℤ√d) : (z - w).re = z.re - w.re := rfl @[simp] theorem sub_im (z w : ℤ√d) : (z - w).im = z.im - w.im := rfl instance addGroupWithOne : AddGroupWithOne (ℤ√d) := { Zsqrtd.addCommGroup with natCast := fun n => ofInt n intCast := ofInt one := 1 } instance commRing : CommRing (ℤ√d) := by refine { Zsqrtd.addGroupWithOne with mul := (· * ·) npow := @npowRec (ℤ√d) ⟨1⟩ ⟨(· * ·)⟩, add_comm := ?_ left_distrib := ?_ right_distrib := ?_ zero_mul := ?_ mul_zero := ?_ mul_assoc := ?_ one_mul := ?_ mul_one := ?_ mul_comm := ?_ } <;> intros <;> ext <;> simp <;> ring instance : AddMonoid (ℤ√d) := by infer_instance instance : Monoid (ℤ√d) := by infer_instance instance : CommMonoid (ℤ√d) := by infer_instance instance : CommSemigroup (ℤ√d) := by infer_instance instance : Semigroup (ℤ√d) := by infer_instance instance : AddCommSemigroup (ℤ√d) := by infer_instance instance : AddSemigroup (ℤ√d) := by infer_instance instance : CommSemiring (ℤ√d) := by infer_instance instance : Semiring (ℤ√d) := by infer_instance instance : Ring (ℤ√d) := by infer_instance instance : Distrib (ℤ√d) := by infer_instance /-- Conjugation in `ℤ√d`. The conjugate of `a + b √d` is `a - b √d`. -/ instance : Star (ℤ√d) where star z := ⟨z.1, -z.2⟩ @[simp] theorem star_mk (x y : ℤ) : star (⟨x, y⟩ : ℤ√d) = ⟨x, -y⟩ := rfl @[simp] theorem star_re (z : ℤ√d) : (star z).re = z.re := rfl @[simp] theorem star_im (z : ℤ√d) : (star z).im = -z.im := rfl instance : StarRing (ℤ√d) where star_involutive _ := Zsqrtd.ext rfl (neg_neg _) star_mul a b := by ext <;> simp <;> ring star_add _ _ := Zsqrtd.ext rfl (neg_add _ _) -- Porting note: proof was `by decide` instance nontrivial : Nontrivial (ℤ√d) := ⟨⟨0, 1, Zsqrtd.ext_iff.not.mpr (by simp)⟩⟩ @[simp] theorem natCast_re (n : ℕ) : (n : ℤ√d).re = n := rfl @[simp] theorem ofNat_re (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℤ√d).re = n := rfl @[simp] theorem natCast_im (n : ℕ) : (n : ℤ√d).im = 0 := rfl @[simp] theorem ofNat_im (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℤ√d).im = 0 := rfl theorem natCast_val (n : ℕ) : (n : ℤ√d) = ⟨n, 0⟩ := rfl @[simp] theorem intCast_re (n : ℤ) : (n : ℤ√d).re = n := by cases n <;> rfl @[simp] theorem intCast_im (n : ℤ) : (n : ℤ√d).im = 0 := by cases n <;> rfl theorem intCast_val (n : ℤ) : (n : ℤ√d) = ⟨n, 0⟩ := by ext <;> simp instance : CharZero (ℤ√d) where cast_injective m n := by simp [Zsqrtd.ext_iff] @[simp] theorem ofInt_eq_intCast (n : ℤ) : (ofInt n : ℤ√d) = n := by ext <;> simp [ofInt_re, ofInt_im] @[simp] theorem nsmul_val (n : ℕ) (x y : ℤ) : (n : ℤ√d) * ⟨x, y⟩ = ⟨n * x, n * y⟩ := by ext <;> simp @[simp] theorem smul_val (n x y : ℤ) : (n : ℤ√d) * ⟨x, y⟩ = ⟨n * x, n * y⟩ := by ext <;> simp theorem smul_re (a : ℤ) (b : ℤ√d) : (↑a * b).re = a * b.re := by simp theorem smul_im (a : ℤ) (b : ℤ√d) : (↑a * b).im = a * b.im := by simp @[simp] theorem muld_val (x y : ℤ) : sqrtd (d := d) * ⟨x, y⟩ = ⟨d * y, x⟩ := by ext <;> simp @[simp] theorem dmuld : sqrtd (d := d) * sqrtd (d := d) = d := by ext <;> simp @[simp] theorem smuld_val (n x y : ℤ) : sqrtd * (n : ℤ√d) * ⟨x, y⟩ = ⟨d * n * y, n * x⟩ := by ext <;> simp theorem decompose {x y : ℤ} : (⟨x, y⟩ : ℤ√d) = x + sqrtd (d := d) * y := by ext <;> simp theorem mul_star {x y : ℤ} : (⟨x, y⟩ * star ⟨x, y⟩ : ℤ√d) = x * x - d * y * y := by ext <;> simp [sub_eq_add_neg, mul_comm] theorem intCast_dvd (z : ℤ) (a : ℤ√d) : ↑z ∣ a ↔ z ∣ a.re ∧ z ∣ a.im := by constructor · rintro ⟨x, rfl⟩ simp only [add_zero, intCast_re, zero_mul, mul_im, dvd_mul_right, and_self_iff, mul_re, mul_zero, intCast_im] · rintro ⟨⟨r, hr⟩, ⟨i, hi⟩⟩ use ⟨r, i⟩ rw [smul_val, Zsqrtd.ext_iff] exact ⟨hr, hi⟩ @[simp, norm_cast] theorem intCast_dvd_intCast (a b : ℤ) : (a : ℤ√d) ∣ b ↔ a ∣ b := by rw [intCast_dvd] constructor · rintro ⟨hre, -⟩ rwa [intCast_re] at hre · rw [intCast_re, intCast_im] exact fun hc => ⟨hc, dvd_zero a⟩ protected theorem eq_of_smul_eq_smul_left {a : ℤ} {b c : ℤ√d} (ha : a ≠ 0) (h : ↑a * b = a * c) : b = c := by rw [Zsqrtd.ext_iff] at h ⊢ apply And.imp _ _ h <;> simpa only [smul_re, smul_im] using mul_left_cancel₀ ha section Gcd theorem gcd_eq_zero_iff (a : ℤ√d) : Int.gcd a.re a.im = 0 ↔ a = 0 := by simp only [Int.gcd_eq_zero_iff, Zsqrtd.ext_iff, eq_self_iff_true, zero_im, zero_re] theorem gcd_pos_iff (a : ℤ√d) : 0 < Int.gcd a.re a.im ↔ a ≠ 0 := pos_iff_ne_zero.trans <\| not_congr a.gcd_eq_zero_iff theorem isCoprime_of_dvd_isCoprime {a b : ℤ√d} (hcoprime : IsCoprime a.re a.im) (hdvd : b ∣ a) : IsCoprime b.re b.im := by apply isCoprime_of_dvd · rintro ⟨hre, him⟩ obtain rfl : b = 0 := Zsqrtd.ext hre him rw [zero_dvd_iff] at hdvd simp [hdvd, zero_im, zero_re, not_isCoprime_zero_zero] at hcoprime · rintro z hz - hzdvdu hzdvdv apply hz obtain ⟨ha, hb⟩ : z ∣ a.re ∧ z ∣ a.im := by rw [← intCast_dvd] apply dvd_trans _ hdvd rw [intCast_dvd] exact ⟨hzdvdu, hzdvdv⟩ exact hcoprime.isUnit_of_dvd' ha hb @[deprecated (since := "2025-01-23")] alias coprime_of_dvd_coprime := isCoprime_of_dvd_isCoprime theorem exists_coprime_of_gcd_pos {a : ℤ√d} (hgcd : 0 < Int.gcd a.re a.im) : ∃ b : ℤ√d, a = ((Int.gcd a.re a.im : ℤ) : ℤ√d) * b ∧ IsCoprime b.re b.im := by obtain ⟨re, im, H1, Hre, Him⟩ := Int.exists_gcd_one hgcd rw [mul_comm] at Hre Him refine ⟨⟨re, im⟩, ?_, ?_⟩ · rw [smul_val, ← Hre, ← Him] · rw [Int.isCoprime_iff_gcd_eq_one, H1] end Gcd /-- Read `SqLe a c b d` as `a √c ≤ b √d` -/ def SqLe (a c b d : ℕ) : Prop := c * a * a ≤ d * b * b theorem sqLe_of_le {c d x y z w : ℕ} (xz : z ≤ x) (yw : y ≤ w) (xy : SqLe x c y d) : SqLe z c w d := le_trans (mul_le_mul (Nat.mul_le_mul_left _ xz) xz (Nat.zero_le _) (Nat.zero_le _)) <\| le_trans xy (mul_le_mul (Nat.mul_le_mul_left _ yw) yw (Nat.zero_le _) (Nat.zero_le _)) theorem sqLe_add_mixed {c d x y z w : ℕ} (xy : SqLe x c y d) (zw : SqLe z c w d) : c * (x * z) ≤ d * (y * w) := Nat.mul_self_le_mul_self_iff.1 <\| by simpa [mul_comm, mul_left_comm] using mul_le_mul xy zw (Nat.zero_le _) (Nat.zero_le _) theorem sqLe_add {c d x y z w : ℕ} (xy : SqLe x c y d) (zw : SqLe z c w d) : SqLe (x + z) c (y + w) d := by have xz := sqLe_add_mixed xy zw simp? [SqLe, mul_assoc] at xy zw says simp only [SqLe, mul_assoc] at xy zw simp [SqLe, mul_add, mul_comm, mul_left_comm, add_le_add, ] theorem sqLe_cancel {c d x y z w : ℕ} (zw : SqLe y d x c) (h : SqLe (x + z) c (y + w) d) : SqLe z c w d := by apply le_of_not_gt intro l refine not_le_of_gt ?_ h simp only [SqLe, mul_add, mul_comm, mul_left_comm, add_assoc, gt_iff_lt] have hm := sqLe_add_mixed zw (le_of_lt l) simp only [SqLe, mul_assoc, gt_iff_lt] at l zw exact lt_of_le_of_lt (add_le_add_right zw _) (add_lt_add_left (add_lt_add_of_le_of_lt hm (add_lt_add_of_le_of_lt hm l)) _) theorem sqLe_smul {c d x y : ℕ} (n : ℕ) (xy : SqLe x c y d) : SqLe (n x) c (n * y) d := by simpa [SqLe, mul_left_comm, mul_assoc] using Nat.mul_le_mul_left (n * n) xy theorem sqLe_mul {d x y z w : ℕ} : (SqLe x 1 y d → SqLe z 1 w d → SqLe (x * w + y * z) d (x * z + d * y * w) 1) ∧ (SqLe x 1 y d → SqLe w d z 1 → SqLe (x * z + d * y * w) 1 (x * w + y * z) d) ∧ (SqLe y d x 1 → SqLe z 1 w d → SqLe (x * z + d * y * w) 1 (x * w + y * z) d) ∧ (SqLe y d x 1 → SqLe w d z 1 → SqLe (x * w + y * z) d (x * z + d * y * w) 1) := by refine ⟨?_, ?_, ?_, ?_⟩ <;> · intro xy zw have := Int.mul_nonneg (sub_nonneg_of_le (Int.ofNat_le_ofNat_of_le xy)) (sub_nonneg_of_le (Int.ofNat_le_ofNat_of_le zw)) refine Int.le_of_ofNat_le_ofNat (le_of_sub_nonneg ?_) convert this using 1 simp only [one_mul, Int.natCast_add, Int.natCast_mul] ring open Int in /-- "Generalized" `nonneg`. `nonnegg c d x y` means `a √c + b √d ≥ 0`; we are interested in the case `c = 1` but this is more symmetric -/ def Nonnegg (c d : ℕ) : ℤ → ℤ → Prop \| (a : ℕ), (b : ℕ) => True \| (a : ℕ), -[b+1] => SqLe (b + 1) c a d \| -[a+1], (b : ℕ) => SqLe (a + 1) d b c \| -[_+1], -[_+1] => False theorem nonnegg_comm {c d : ℕ} {x y : ℤ} : Nonnegg c d x y = Nonnegg d c y x := by cases x <;> cases y <;> rfl theorem nonnegg_neg_pos {c d} : ∀ {a b : ℕ}, Nonnegg c d (-a) b ↔ SqLe a d b c \| 0, b => ⟨by simp [SqLe, Nat.zero_le], fun _ => trivial⟩ \| a + 1, b => by rfl theorem nonnegg_pos_neg {c d} {a b : ℕ} : Nonnegg c d a (-b) ↔ SqLe b c a d := by rw [nonnegg_comm]; exact nonnegg_neg_pos open Int in theorem nonnegg_cases_right {c d} {a : ℕ} : ∀ {b : ℤ}, (∀ x : ℕ, b = -x → SqLe x c a d) → Nonnegg c d a b \| (b : Nat), _ => trivial \| -[b+1], h => h (b + 1) rfl theorem nonnegg_cases_left {c d} {b : ℕ} {a : ℤ} (h : ∀ x : ℕ, a = -x → SqLe x d b c) : Nonnegg c d a b := cast nonnegg_comm (nonnegg_cases_right h) section Norm /-- The norm of an element of `ℤ[√d]`. -/ def norm (n : ℤ√d) : ℤ := n.re * n.re - d * n.im * n.im theorem norm_def (n : ℤ√d) : n.norm = n.re * n.re - d * n.im * n.im := rfl @[simp] theorem norm_zero : norm (0 : ℤ√d) = 0 := by simp [norm] @[simp] theorem norm_one : norm (1 : ℤ√d) = 1 := by simp [norm] @[simp] theorem norm_intCast (n : ℤ) : norm (n : ℤ√d) = n * n := by simp [norm] @[simp] theorem norm_natCast (n : ℕ) : norm (n : ℤ√d) = n * n := norm_intCast n @[simp] theorem norm_mul (n m : ℤ√d) : norm (n * m) = norm n * norm m := by simp only [norm, mul_im, mul_re] ring /-- `norm` as a `MonoidHom`. -/ def normMonoidHom : ℤ√d →* ℤ where toFun := norm map_mul' := norm_mul map_one' := norm_one theorem norm_eq_mul_conj (n : ℤ√d) : (norm n : ℤ√d) = n * star n := by ext <;> simp [norm, star, mul_comm, sub_eq_add_neg] @[simp] theorem norm_neg (x : ℤ√d) : (-x).norm = x.norm := (Int.cast_inj (α := ℤ√d)).1 <\| by simp [norm_eq_mul_conj] @[simp] theorem norm_conj (x : ℤ√d) : (star x).norm = x.norm := (Int.cast_inj (α := ℤ√d)).1 <\| by simp [norm_eq_mul_conj, mul_comm] theorem norm_nonneg (hd : d ≤ 0) (n : ℤ√d) : 0 ≤ n.norm := add_nonneg (mul_self_nonneg _) (by rw [mul_assoc, neg_mul_eq_neg_mul] exact mul_nonneg (neg_nonneg.2 hd) (mul_self_nonneg _)) theorem norm_eq_one_iff {x : ℤ√d} : x.norm.natAbs = 1 ↔ IsUnit x := ⟨fun h => isUnit_iff_dvd_one.2 <\| (le_total 0 (norm x)).casesOn (fun hx => ⟨star x, by rwa [← Int.natCast_inj, Int.natAbs_of_nonneg hx, ← @Int.cast_inj (ℤ√d) _ _, norm_eq_mul_conj, eq_comm] at h⟩) fun hx => ⟨-star x, by rwa [← Int.natCast_inj, Int.ofNat_natAbs_of_nonpos hx, ← @Int.cast_inj (ℤ√d) _ _, Int.cast_neg, norm_eq_mul_conj, neg_mul_eq_mul_neg, eq_comm] at h⟩, fun h => by let ⟨y, hy⟩ := isUnit_iff_dvd_one.1 h have := congr_arg (Int.natAbs ∘ norm) hy rw [Function.comp_apply, Function.comp_apply, norm_mul, Int.natAbs_mul, norm_one, Int.natAbs_one, eq_comm, mul_eq_one] at this exact this.1⟩ theorem isUnit_iff_norm_isUnit {d : ℤ} (z : ℤ√d) : IsUnit z ↔ IsUnit z.norm := by rw [Int.isUnit_iff_natAbs_eq, norm_eq_one_iff] theorem norm_eq_one_iff' {d : ℤ} (hd : d ≤ 0) (z : ℤ√d) : z.norm = 1 ↔ IsUnit z := by rw [← norm_eq_one_iff, ← Int.natCast_inj, Int.natAbs_of_nonneg (norm_nonneg hd z), Int.ofNat_one] theorem norm_eq_zero_iff {d : ℤ} (hd : d < 0) (z : ℤ√d) : z.norm = 0 ↔ z = 0 := by constructor · intro h rw [norm_def, sub_eq_add_neg, mul_assoc] at h have left := mul_self_nonneg z.re have right := neg_nonneg.mpr (mul_nonpos_of_nonpos_of_nonneg hd.le (mul_self_nonneg z.im)) obtain ⟨ha, hb⟩ := (add_eq_zero_iff_of_nonneg left right).mp h ext <;> apply eq_zero_of_mul_self_eq_zero · exact ha · rw [neg_eq_zero, mul_eq_zero] at hb exact hb.resolve_left hd.ne · rintro rfl exact norm_zero theorem norm_eq_of_associated {d : ℤ} (hd : d ≤ 0) {x y : ℤ√d} (h : Associated x y) : x.norm = y.norm := by obtain ⟨u, rfl⟩ := h rw [norm_mul, (norm_eq_one_iff' hd _).mpr u.isUnit, mul_one] end Norm end section variable {d : ℕ} /-- Nonnegativity of an element of `ℤ√d`. -/ def Nonneg : ℤ√d → Prop \| ⟨a, b⟩ => Nonnegg d 1 a b instance : LE (ℤ√d) := ⟨fun a b => Nonneg (b - a)⟩ instance : LT (ℤ√d) := ⟨fun a b => ¬b ≤ a⟩ instance decidableNonnegg (c d a b) : Decidable (Nonnegg c d a b) := by cases a <;> cases b <;> unfold Nonnegg SqLe <;> infer_instance instance decidableNonneg : ∀ a : ℤ√d, Decidable (Nonneg a) \| ⟨_, _⟩ => Zsqrtd.decidableNonnegg _ _ _ _ instance decidableLE : DecidableLE (ℤ√d) := fun _ _ => decidableNonneg _ open Int in theorem nonneg_cases : ∀ {a : ℤ√d}, Nonneg a → ∃ x y : ℕ, a = ⟨x, y⟩ ∨ a = ⟨x, -y⟩ ∨ a = ⟨-x, y⟩ \| ⟨(x : ℕ), (y : ℕ)⟩, _ => ⟨x, y, Or.inl rfl⟩ \| ⟨(x : ℕ), -[y+1]⟩, _ => ⟨x, y + 1, Or.inr <\| Or.inl rfl⟩ \| ⟨-[x+1], (y : ℕ)⟩, _ => ⟨x + 1, y, Or.inr <\| Or.inr rfl⟩ \| ⟨-[_+1], -[_+1]⟩, h => False.elim h open Int in theorem nonneg_add_lem {x y z w : ℕ} (xy : Nonneg (⟨x, -y⟩ : ℤ√d)) (zw : Nonneg (⟨-z, w⟩ : ℤ√d)) : Nonneg (⟨x, -y⟩ + ⟨-z, w⟩ : ℤ√d) := by have : Nonneg ⟨Int.subNatNat x z, Int.subNatNat w y⟩ := Int.subNatNat_elim x z (fun m n i => SqLe y d m 1 → SqLe n 1 w d → Nonneg ⟨i, Int.subNatNat w y⟩) (fun j k => Int.subNatNat_elim w y (fun m n i => SqLe n d (k + j) 1 → SqLe k 1 m d → Nonneg ⟨Int.ofNat j, i⟩) (fun _ _ _ _ => trivial) fun m n xy zw => sqLe_cancel zw xy) (fun j k => Int.subNatNat_elim w y (fun m n i => SqLe n d k 1 → SqLe (k + j + 1) 1 m d → Nonneg ⟨-[j+1], i⟩) (fun m n xy zw => sqLe_cancel xy zw) fun m n xy zw => let t := Nat.le_trans zw (sqLe_of_le (Nat.le_add_right n (m + 1)) le_rfl xy) have : k + j + 1 ≤ k := Nat.mul_self_le_mul_self_iff.1 (by simpa [one_mul] using t) absurd this (not_le_of_gt <\| Nat.succ_le_succ <\| Nat.le_add_right _ _)) (nonnegg_pos_neg.1 xy) (nonnegg_neg_pos.1 zw) rw [add_def, neg_add_eq_sub] rwa [Int.subNatNat_eq_coe, Int.subNatNat_eq_coe] at this theorem Nonneg.add {a b : ℤ√d} (ha : Nonneg a) (hb : Nonneg b) : Nonneg (a + b) := by rcases nonneg_cases ha with ⟨x, y, rfl \| rfl \| rfl⟩ <;> rcases nonneg_cases hb with ⟨z, w, rfl \| rfl \| rfl⟩ · trivial · refine nonnegg_cases_right fun i h => sqLe_of_le ?_ ?_ (nonnegg_pos_neg.1 hb) · dsimp only at h exact Int.ofNat_le.1 (le_of_neg_le_neg (Int.le.intro y (by simp [add_comm, ]))) · apply Nat.le_add_left · refine nonnegg_cases_left fun i h => sqLe_of_le ?_ ?_ (nonnegg_neg_pos.1 hb) · dsimp only at h exact Int.ofNat_le.1 (le_of_neg_le_neg (Int.le.intro x (by simp [add_comm, ]))) · apply Nat.le_add_left · refine nonnegg_cases_right fun i h => sqLe_of_le ?_ ?_ (nonnegg_pos_neg.1 ha) · dsimp only at h exact Int.ofNat_le.1 (le_of_neg_le_neg (Int.le.intro w (by simp []))) · apply Nat.le_add_right · have : Nonneg ⟨_, _⟩ := nonnegg_pos_neg.2 (sqLe_add (nonnegg_pos_neg.1 ha) (nonnegg_pos_neg.1 hb)) rw [Nat.cast_add, Nat.cast_add, neg_add] at this rwa [add_def] · exact nonneg_add_lem ha hb · refine nonnegg_cases_left fun i h => sqLe_of_le ?_ ?_ (nonnegg_neg_pos.1 ha) · dsimp only at h exact Int.ofNat_le.1 (le_of_neg_le_neg (Int.le.intro _ h)) · apply Nat.le_add_right · dsimp rw [add_comm, add_comm (y : ℤ)] exact nonneg_add_lem hb ha · have : Nonneg ⟨_, _⟩ := nonnegg_neg_pos.2 (sqLe_add (nonnegg_neg_pos.1 ha) (nonnegg_neg_pos.1 hb)) rw [Nat.cast_add, Nat.cast_add, neg_add] at this rwa [add_def] theorem nonneg_iff_zero_le {a : ℤ√d} : Nonneg a ↔ 0 ≤ a := show _ ↔ Nonneg _ by simp theorem le_of_le_le {x y z w : ℤ} (xz : x ≤ z) (yw : y ≤ w) : (⟨x, y⟩ : ℤ√d) ≤ ⟨z, w⟩ := show Nonneg ⟨z - x, w - y⟩ from match z - x, w - y, Int.le.dest_sub xz, Int.le.dest_sub yw with \| _, _, ⟨_, rfl⟩, ⟨_, rfl⟩ => trivial open Int in protected theorem nonneg_total : ∀ a : ℤ√d, Nonneg a ∨ Nonneg (-a) \| ⟨(x : ℕ), (y : ℕ)⟩ => Or.inl trivial \| ⟨-[_+1], -[_+1]⟩ => Or.inr trivial \| ⟨0, -[_+1]⟩ => Or.inr trivial \| ⟨-[_+1], 0⟩ => Or.inr trivial \| ⟨(_ + 1 : ℕ), -[_+1]⟩ => Nat.le_total _ _ \| ⟨-[_+1], (_ + 1 : ℕ)⟩ => Nat.le_total _ _ protected theorem le_total (a b : ℤ√d) : a ≤ b ∨ b ≤ a := by have t := (b - a).nonneg_total rwa [neg_sub] at t instance preorder : Preorder (ℤ√d) where le := (· ≤ ·) le_refl a := show Nonneg (a - a) by simp only [sub_self]; trivial le_trans a b c hab hbc := by simpa [sub_add_sub_cancel'] using hab.add hbc lt := (· < ·) lt_iff_le_not_le _ _ := (and_iff_right_of_imp (Zsqrtd.le_total _ _).resolve_left).symm open Int in theorem le_arch (a : ℤ√d) : ∃ n : ℕ, a ≤ n := by obtain ⟨x, y, (h : a ≤ ⟨x, y⟩)⟩ : ∃ x y : ℕ, Nonneg (⟨x, y⟩ + -a) := match -a with \| ⟨Int.ofNat x, Int.ofNat y⟩ => ⟨0, 0, by trivial⟩ \| ⟨Int.ofNat x, -[y+1]⟩ => ⟨0, y + 1, by simp [add_def, Int.negSucc_eq, add_assoc]; trivial⟩ \| ⟨-[x+1], Int.ofNat y⟩ => ⟨x + 1, 0, by simp [Int.negSucc_eq, add_assoc]; trivial⟩ \| ⟨-[x+1], -[y+1]⟩ => ⟨x + 1, y + 1, by simp [Int.negSucc_eq, add_assoc]; trivial⟩ refine ⟨x + d y, h.trans ?_⟩ change Nonneg ⟨↑x + d * y - ↑x, 0 - ↑y⟩ rcases y with - \| y · simp trivial have h : ∀ y, SqLe y d (d * y) 1 := fun y => by simpa [SqLe, mul_comm, mul_left_comm] using Nat.mul_le_mul_right (y * y) (Nat.le_mul_self d) rw [show (x : ℤ) + d * Nat.succ y - x = d * Nat.succ y by simp] exact h (y + 1) protected theorem add_le_add_left (a b : ℤ√d) (ab : a ≤ b) (c : ℤ√d) : c + a ≤ c + b := show Nonneg _ by rw [add_sub_add_left_eq_sub]; exact ab protected theorem le_of_add_le_add_left (a b c : ℤ√d) (h : c + a ≤ c + b) : a ≤ b := by simpa using Zsqrtd.add_le_add_left _ _ h (-c) protected theorem add_lt_add_left (a b : ℤ√d) (h : a < b) (c) : c + a < c + b := fun h' => h (Zsqrtd.le_of_add_le_add_left _ _ _ h') theorem nonneg_smul {a : ℤ√d} {n : ℕ} (ha : Nonneg a) : Nonneg ((n : ℤ√d) * a) := by rw [← Int.cast_natCast n] exact match a, nonneg_cases ha, ha with \| _, ⟨x, y, Or.inl rfl⟩, _ => by rw [smul_val]; trivial \| _, ⟨x, y, Or.inr <\| Or.inl rfl⟩, ha => by rw [smul_val]; simpa using nonnegg_pos_neg.2 (sqLe_smul n <\| nonnegg_pos_neg.1 ha) \| _, ⟨x, y, Or.inr <\| Or.inr rfl⟩, ha => by rw [smul_val]; simpa using nonnegg_neg_pos.2 (sqLe_smul n <\| nonnegg_neg_pos.1 ha) theorem nonneg_muld {a : ℤ√d} (ha : Nonneg a) : Nonneg (sqrtd * a) := match a, nonneg_cases ha, ha with \| _, ⟨_, _, Or.inl rfl⟩, _ => trivial \| _, ⟨x, y, Or.inr <\| Or.inl rfl⟩, ha => by simp only [muld_val, mul_neg] apply nonnegg_neg_pos.2 simpa [SqLe, mul_comm, mul_left_comm] using Nat.mul_le_mul_left d (nonnegg_pos_neg.1 ha) \| _, ⟨x, y, Or.inr <\| Or.inr rfl⟩, ha => by simp only [muld_val] apply nonnegg_pos_neg.2 simpa [SqLe, mul_comm, mul_left_comm] using Nat.mul_le_mul_left d (nonnegg_neg_pos.1 ha) theorem nonneg_mul_lem {x y : ℕ} {a : ℤ√d} (ha : Nonneg a) : Nonneg (⟨x, y⟩ * a) := by have : (⟨x, y⟩ * a : ℤ√d) = (x : ℤ√d) * a + sqrtd * ((y : ℤ√d) * a) := by rw [decompose, right_distrib, mul_assoc, Int.cast_natCast, Int.cast_natCast] rw [this] exact (nonneg_smul ha).add (nonneg_muld <\| nonneg_smul ha) theorem nonneg_mul {a b : ℤ√d} (ha : Nonneg a) (hb : Nonneg b) : Nonneg (a * b) := match a, b, nonneg_cases ha, nonneg_cases hb, ha, hb with \| _, _, ⟨_, _, Or.inl rfl⟩, ⟨_, _, Or.inl rfl⟩, _, _ => trivial \| _, _, ⟨x, y, Or.inl rfl⟩, ⟨z, w, Or.inr <\| Or.inr rfl⟩, _, hb => nonneg_mul_lem hb \| _, _, ⟨x, y, Or.inl rfl⟩, ⟨z, w, Or.inr <\| Or.inl rfl⟩, _, hb => nonneg_mul_lem hb \| _, _, ⟨x, y, Or.inr <\| Or.inr rfl⟩, ⟨z, w, Or.inl rfl⟩, ha, _ => by rw [mul_comm]; exact nonneg_mul_lem ha \| _, _, ⟨x, y, Or.inr <\| Or.inl rfl⟩, ⟨z, w, Or.inl rfl⟩, ha, _ => by rw [mul_comm]; exact nonneg_mul_lem ha \| _, _, ⟨x, y, Or.inr <\| Or.inr rfl⟩, ⟨z, w, Or.inr <\| Or.inr rfl⟩, ha, hb => by rw [calc (⟨-x, y⟩ * ⟨-z, w⟩ : ℤ√d) = ⟨_, _⟩ := rfl _ = ⟨x * z + d * y * w, -(x * w + y * z)⟩ := by simp [add_comm] ] exact nonnegg_pos_neg.2 (sqLe_mul.left (nonnegg_neg_pos.1 ha) (nonnegg_neg_pos.1 hb)) \| _, _, ⟨x, y, Or.inr <\| Or.inr rfl⟩, ⟨z, w, Or.inr <\| Or.inl rfl⟩, ha, hb => by rw [calc (⟨-x, y⟩ * ⟨z, -w⟩ : ℤ√d) = ⟨_, _⟩ := rfl _ = ⟨-(x * z + d * y * w), x * w + y * z⟩ := by simp [add_comm] ] exact nonnegg_neg_pos.2 (sqLe_mul.right.left (nonnegg_neg_pos.1 ha) (nonnegg_pos_neg.1 hb)) \| _, _, ⟨x, y, Or.inr <\| Or.inl rfl⟩, ⟨z, w, Or.inr <\| Or.inr rfl⟩, ha, hb => by rw [calc (⟨x, -y⟩ * ⟨-z, w⟩ : ℤ√d) = ⟨_, _⟩ := rfl _ = ⟨-(x * z + d * y * w), x * w + y * z⟩ := by simp [add_comm] ] exact nonnegg_neg_pos.2 (sqLe_mul.right.right.left (nonnegg_pos_neg.1 ha) (nonnegg_neg_pos.1 hb)) \| _, _, ⟨x, y, Or.inr <\| Or.inl rfl⟩, ⟨z, w, Or.inr <\| Or.inl rfl⟩, ha, hb => by rw [calc (⟨x, -y⟩ * ⟨z, -w⟩ : ℤ√d) = ⟨_, _⟩ := rfl _ = ⟨x * z + d * y * w, -(x * w + y * z)⟩ := by simp [add_comm] ] exact nonnegg_pos_neg.2 (sqLe_mul.right.right.right (nonnegg_pos_neg.1 ha) (nonnegg_pos_neg.1 hb)) protected theorem mul_nonneg (a b : ℤ√d) : 0 ≤ a → 0 ≤ b → 0 ≤ a * b := by simp_rw [← nonneg_iff_zero_le] exact nonneg_mul theorem not_sqLe_succ (c d y) (h : 0 < c) : ¬SqLe (y + 1) c 0 d := not_le_of_gt <\| mul_pos (mul_pos h <\| Nat.succ_pos _) <\| Nat.succ_pos _ -- Porting note: renamed field and added theorem to make `x` explicit /-- A nonsquare is a natural number that is not equal to the square of an integer. This is implemented as a typeclass because it's a necessary condition for much of the Pell equation theory. -/ class Nonsquare (x : ℕ) : Prop where ns' : ∀ n : ℕ, x ≠ n * n theorem Nonsquare.ns (x : ℕ) [Nonsquare x] : ∀ n : ℕ, x ≠ n * n := ns' variable [dnsq : Nonsquare d] theorem d_pos : 0 < d := lt_of_le_of_ne (Nat.zero_le _) <\| Ne.symm <\| Nonsquare.ns d 0 theorem divides_sq_eq_zero {x y} (h : x * x = d * y * y) : x = 0 ∧ y = 0 := let g := x.gcd y Or.elim g.eq_zero_or_pos (fun H => ⟨Nat.eq_zero_of_gcd_eq_zero_left H, Nat.eq_zero_of_gcd_eq_zero_right H⟩) fun gpos => False.elim <\| by	let ⟨m, n, co, (hx : x = m * g), (hy : y = n * g)⟩ := Nat.exists_coprime _ _ rw [hx, hy] at h have : m * m = d * (n * n) := by refine mul_left_cancel₀ (mul_pos gpos gpos).ne' ?_ -- Porting note: was `simpa [mul_comm, mul_left_comm] using h` calc g * g * (m * m) _ = m * g * (m * g) := by ring _ = d * (n * g) * (n * g) := h _ = g * g * (d * (n * n)) := by ring have co2 := let co1 := co.mul_right co co1.mul co1 exact Nonsquare.ns d m (Nat.dvd_antisymm (by rw [this]; apply dvd_mul_right) <\|	Mathlib/NumberTheory/Zsqrtd/Basic.lean	752	767
/- Copyright (c) 2022 Michael Stoll. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Michael Stoll -/ import Mathlib.Algebra.Ring.Regular import Mathlib.Algebra.Equiv.TransferInstance import Mathlib.Algebra.BigOperators.Pi import Mathlib.Algebra.BigOperators.Ring.Finset /-! # Characters from additive to multiplicative monoids Let `A` be an additive monoid, and `M` a multiplicative one. An additive character of `A` with values in `M` is simply a map `A → M` which intertwines the addition operation on `A` with the multiplicative operation on `M`. We define these objects, using the namespace `AddChar`, and show that if `A` is a commutative group under addition, then the additive characters are also a group (written multiplicatively). Note that we do not need `M` to be a group here. We also include some constructions specific to the case when `A = R` is a ring; then we define `mulShift ψ r`, where `ψ : AddChar R M` and `r : R`, to be the character defined by `x ↦ ψ (r * x)`. For more refined results of a number-theoretic nature (primitive characters, Gauss sums, etc) see `Mathlib.NumberTheory.LegendreSymbol.AddCharacter`. # Implementation notes Due to their role as the dual of an additive group, additive characters must themselves be an additive group. This contrasts to their pointwise operations which make them a multiplicative group. We simply define both the additive and multiplicative group structures and prove them equal. For more information on this design decision, see the following zulip thread: https://leanprover.zulipchat.com/#narrow/stream/116395-maths/topic/Additive.20characters ## Tags additive character -/ /-! ### Definitions related to and results on additive characters -/ open Function Multiplicative open Finset hiding card open Fintype (card) section AddCharDef -- The domain of our additive characters variable (A : Type) [AddMonoid A] -- The target variable (M : Type) [Monoid M] /-- `AddChar A M` is the type of maps `A → M`, for `A` an additive monoid and `M` a multiplicative monoid, which intertwine addition in `A` with multiplication in `M`. We only put the typeclasses needed for the definition, although in practice we are usually interested in much more specific cases (e.g. when `A` is a group and `M` a commutative ring). -/ structure AddChar where /-- The underlying function. Do not use this function directly. Instead use the coercion coming from the `FunLike` instance. -/ toFun : A → M /-- The function maps `0` to `1`. Do not use this directly. Instead use `AddChar.map_zero_eq_one`. -/ map_zero_eq_one' : toFun 0 = 1 /-- The function maps addition in `A` to multiplication in `M`. Do not use this directly. Instead use `AddChar.map_add_eq_mul`. -/ map_add_eq_mul' : ∀ a b : A, toFun (a + b) = toFun a * toFun b end AddCharDef namespace AddChar section Basic -- results which don't require commutativity or inverses variable {A B M N : Type} [AddMonoid A] [AddMonoid B] [Monoid M] [Monoid N] {ψ : AddChar A M} /-- Define coercion to a function. -/ instance instFunLike : FunLike (AddChar A M) A M where coe := AddChar.toFun coe_injective' φ ψ h := by cases φ; cases ψ; congr @[ext] lemma ext (f g : AddChar A M) (h : ∀ x : A, f x = g x) : f = g := DFunLike.ext f g h @[simp] lemma coe_mk (f : A → M) (map_zero_eq_one' : f 0 = 1) (map_add_eq_mul' : ∀ a b : A, f (a + b) = f a f b) : AddChar.mk f map_zero_eq_one' map_add_eq_mul' = f := by rfl /-- An additive character maps `0` to `1`. -/ @[simp] lemma map_zero_eq_one (ψ : AddChar A M) : ψ 0 = 1 := ψ.map_zero_eq_one' /-- An additive character maps sums to products. -/ lemma map_add_eq_mul (ψ : AddChar A M) (x y : A) : ψ (x + y) = ψ x * ψ y := ψ.map_add_eq_mul' x y /-- Interpret an additive character as a monoid homomorphism. -/ def toMonoidHom (φ : AddChar A M) : Multiplicative A →* M where toFun := φ.toFun map_one' := φ.map_zero_eq_one' map_mul' := φ.map_add_eq_mul' -- this instance was a bad idea and conflicted with `instFunLike` above @[simp] lemma toMonoidHom_apply (ψ : AddChar A M) (a : Multiplicative A) : ψ.toMonoidHom a = ψ a.toAdd := rfl /-- An additive character maps multiples by natural numbers to powers. -/ lemma map_nsmul_eq_pow (ψ : AddChar A M) (n : ℕ) (x : A) : ψ (n • x) = ψ x ^ n := ψ.toMonoidHom.map_pow x n /-- Additive characters `A → M` are the same thing as monoid homomorphisms from `Multiplicative A` to `M`. -/ def toMonoidHomEquiv : AddChar A M ≃ (Multiplicative A →* M) where toFun φ := φ.toMonoidHom invFun f := { toFun := f.toFun map_zero_eq_one' := f.map_one' map_add_eq_mul' := f.map_mul' } left_inv _ := rfl right_inv _ := rfl @[simp, norm_cast] lemma coe_toMonoidHomEquiv (ψ : AddChar A M) : ⇑(toMonoidHomEquiv ψ) = ψ ∘ Multiplicative.toAdd := rfl @[simp, norm_cast] lemma coe_toMonoidHomEquiv_symm (ψ : Multiplicative A →* M) : ⇑(toMonoidHomEquiv.symm ψ) = ψ ∘ Multiplicative.ofAdd := rfl @[simp] lemma toMonoidHomEquiv_apply (ψ : AddChar A M) (a : Multiplicative A) : toMonoidHomEquiv ψ a = ψ a.toAdd := rfl @[simp] lemma toMonoidHomEquiv_symm_apply (ψ : Multiplicative A →* M) (a : A) : toMonoidHomEquiv.symm ψ a = ψ (Multiplicative.ofAdd a) := rfl /-- Interpret an additive character as a monoid homomorphism. -/ def toAddMonoidHom (φ : AddChar A M) : A →+ Additive M where toFun := φ.toFun map_zero' := φ.map_zero_eq_one' map_add' := φ.map_add_eq_mul' @[simp] lemma coe_toAddMonoidHom (ψ : AddChar A M) : ⇑ψ.toAddMonoidHom = Additive.ofMul ∘ ψ := rfl @[simp] lemma toAddMonoidHom_apply (ψ : AddChar A M) (a : A) : ψ.toAddMonoidHom a = Additive.ofMul (ψ a) := rfl /-- Additive characters `A → M` are the same thing as additive homomorphisms from `A` to `Additive M`. -/ def toAddMonoidHomEquiv : AddChar A M ≃ (A →+ Additive M) where toFun φ := φ.toAddMonoidHom invFun f := { toFun := f.toFun map_zero_eq_one' := f.map_zero' map_add_eq_mul' := f.map_add' } left_inv _ := rfl right_inv _ := rfl @[simp, norm_cast] lemma coe_toAddMonoidHomEquiv (ψ : AddChar A M) : ⇑(toAddMonoidHomEquiv ψ) = Additive.ofMul ∘ ψ := rfl @[simp, norm_cast] lemma coe_toAddMonoidHomEquiv_symm (ψ : A →+ Additive M) : ⇑(toAddMonoidHomEquiv.symm ψ) = Additive.toMul ∘ ψ := rfl @[simp] lemma toAddMonoidHomEquiv_apply (ψ : AddChar A M) (a : A) : toAddMonoidHomEquiv ψ a = Additive.ofMul (ψ a) := rfl @[simp] lemma toAddMonoidHomEquiv_symm_apply (ψ : A →+ Additive M) (a : A) : toAddMonoidHomEquiv.symm ψ a = (ψ a).toMul := rfl /-- The trivial additive character (sending everything to `1`). -/ instance instOne : One (AddChar A M) := toMonoidHomEquiv.one /-- The trivial additive character (sending everything to `1`). -/ instance instZero : Zero (AddChar A M) := ⟨1⟩ @[simp, norm_cast] lemma coe_one : ⇑(1 : AddChar A M) = 1 := rfl @[simp, norm_cast] lemma coe_zero : ⇑(0 : AddChar A M) = 1 := rfl @[simp] lemma one_apply (a : A) : (1 : AddChar A M) a = 1 := rfl @[simp] lemma zero_apply (a : A) : (0 : AddChar A M) a = 1 := rfl lemma one_eq_zero : (1 : AddChar A M) = (0 : AddChar A M) := rfl @[simp, norm_cast] lemma coe_eq_one : ⇑ψ = 1 ↔ ψ = 0 := by rw [← coe_zero, DFunLike.coe_fn_eq] @[simp] lemma toMonoidHomEquiv_zero : toMonoidHomEquiv (0 : AddChar A M) = 1 := rfl @[simp] lemma toMonoidHomEquiv_symm_one : toMonoidHomEquiv.symm (1 : Multiplicative A →* M) = 0 := rfl @[simp] lemma toAddMonoidHomEquiv_zero : toAddMonoidHomEquiv (0 : AddChar A M) = 0 := rfl @[simp] lemma toAddMonoidHomEquiv_symm_zero : toAddMonoidHomEquiv.symm (0 : A →+ Additive M) = 0 := rfl instance instInhabited : Inhabited (AddChar A M) := ⟨1⟩ /-- Composing a `MonoidHom` with an `AddChar` yields another `AddChar`. -/ def _root_.MonoidHom.compAddChar {N : Type} [Monoid N] (f : M → N) (φ : AddChar A M) : AddChar A N := toMonoidHomEquiv.symm (f.comp φ.toMonoidHom) @[simp, norm_cast] lemma _root_.MonoidHom.coe_compAddChar {N : Type} [Monoid N] (f : M → N) (φ : AddChar A M) : f.compAddChar φ = f ∘ φ := rfl @[simp, norm_cast] lemma _root_.MonoidHom.compAddChar_apply (f : M →* N) (φ : AddChar A M) : f.compAddChar φ = f ∘ φ := rfl lemma _root_.MonoidHom.compAddChar_injective_left (ψ : AddChar A M) (hψ : Surjective ψ) : Injective fun f : M →* N ↦ f.compAddChar ψ := by rintro f g h; rw [DFunLike.ext'_iff] at h ⊢; exact hψ.injective_comp_right h lemma _root_.MonoidHom.compAddChar_injective_right (f : M →* N) (hf : Injective f) : Injective fun ψ : AddChar B M ↦ f.compAddChar ψ := by rintro ψ χ h; rw [DFunLike.ext'_iff] at h ⊢; exact hf.comp_left h /-- Composing an `AddChar` with an `AddMonoidHom` yields another `AddChar`. -/ def compAddMonoidHom (φ : AddChar B M) (f : A →+ B) : AddChar A M := toAddMonoidHomEquiv.symm (φ.toAddMonoidHom.comp f) @[simp, norm_cast] lemma coe_compAddMonoidHom (φ : AddChar B M) (f : A →+ B) : φ.compAddMonoidHom f = φ ∘ f := rfl @[simp] lemma compAddMonoidHom_apply (ψ : AddChar B M) (f : A →+ B) (a : A) : ψ.compAddMonoidHom f a = ψ (f a) := rfl lemma compAddMonoidHom_injective_left (f : A →+ B) (hf : Surjective f) : Injective fun ψ : AddChar B M ↦ ψ.compAddMonoidHom f := by rintro ψ χ h; rw [DFunLike.ext'_iff] at h ⊢; exact hf.injective_comp_right h lemma compAddMonoidHom_injective_right (ψ : AddChar B M) (hψ : Injective ψ) : Injective fun f : A →+ B ↦ ψ.compAddMonoidHom f := by rintro f g h rw [DFunLike.ext'_iff] at h ⊢; exact hψ.comp_left h lemma eq_one_iff : ψ = 1 ↔ ∀ x, ψ x = 1 := DFunLike.ext_iff lemma eq_zero_iff : ψ = 0 ↔ ∀ x, ψ x = 1 := DFunLike.ext_iff lemma ne_one_iff : ψ ≠ 1 ↔ ∃ x, ψ x ≠ 1 := DFunLike.ne_iff lemma ne_zero_iff : ψ ≠ 0 ↔ ∃ x, ψ x ≠ 1 := DFunLike.ne_iff noncomputable instance : DecidableEq (AddChar A M) := Classical.decEq _ end Basic section toCommMonoid variable {ι A M : Type} [AddMonoid A] [CommMonoid M] /-- When `M` is commutative, `AddChar A M` is a commutative monoid. -/ instance instCommMonoid : CommMonoid (AddChar A M) := toMonoidHomEquiv.commMonoid /-- When `M` is commutative, `AddChar A M` is an additive commutative monoid. -/ instance instAddCommMonoid : AddCommMonoid (AddChar A M) := Additive.addCommMonoid @[simp, norm_cast] lemma coe_mul (ψ χ : AddChar A M) : ⇑(ψ χ) = ψ * χ := rfl @[simp, norm_cast] lemma coe_add (ψ χ : AddChar A M) : ⇑(ψ + χ) = ψ * χ := rfl @[simp, norm_cast] lemma coe_pow (ψ : AddChar A M) (n : ℕ) : ⇑(ψ ^ n) = ψ ^ n := rfl @[simp, norm_cast] lemma coe_nsmul (n : ℕ) (ψ : AddChar A M) : ⇑(n • ψ) = ψ ^ n := rfl @[simp, norm_cast] lemma coe_prod (s : Finset ι) (ψ : ι → AddChar A M) : ∏ i ∈ s, ψ i = ∏ i ∈ s, ⇑(ψ i) := by induction s using Finset.cons_induction <;> simp [] @[simp, norm_cast] lemma coe_sum (s : Finset ι) (ψ : ι → AddChar A M) : ∑ i ∈ s, ψ i = ∏ i ∈ s, ⇑(ψ i) := by induction s using Finset.cons_induction <;> simp [] @[simp] lemma mul_apply (ψ φ : AddChar A M) (a : A) : (ψ * φ) a = ψ a * φ a := rfl @[simp] lemma add_apply (ψ φ : AddChar A M) (a : A) : (ψ + φ) a = ψ a * φ a := rfl @[simp] lemma pow_apply (ψ : AddChar A M) (n : ℕ) (a : A) : (ψ ^ n) a = (ψ a) ^ n := rfl @[simp] lemma nsmul_apply (ψ : AddChar A M) (n : ℕ) (a : A) : (n • ψ) a = (ψ a) ^ n := rfl lemma prod_apply (s : Finset ι) (ψ : ι → AddChar A M) (a : A) : (∏ i ∈ s, ψ i) a = ∏ i ∈ s, ψ i a := by rw [coe_prod, Finset.prod_apply] lemma sum_apply (s : Finset ι) (ψ : ι → AddChar A M) (a : A) : (∑ i ∈ s, ψ i) a = ∏ i ∈ s, ψ i a := by rw [coe_sum, Finset.prod_apply] lemma mul_eq_add (ψ χ : AddChar A M) : ψ * χ = ψ + χ := rfl lemma pow_eq_nsmul (ψ : AddChar A M) (n : ℕ) : ψ ^ n = n • ψ := rfl lemma prod_eq_sum (s : Finset ι) (ψ : ι → AddChar A M) : ∏ i ∈ s, ψ i = ∑ i ∈ s, ψ i := rfl @[simp] lemma toMonoidHomEquiv_add (ψ φ : AddChar A M) : toMonoidHomEquiv (ψ + φ) = toMonoidHomEquiv ψ * toMonoidHomEquiv φ := rfl @[simp] lemma toMonoidHomEquiv_symm_mul (ψ φ : Multiplicative A →* M) : toMonoidHomEquiv.symm (ψ * φ) = toMonoidHomEquiv.symm ψ + toMonoidHomEquiv.symm φ := rfl /-- The natural equivalence to `(Multiplicative A →* M)` is a monoid isomorphism. -/ def toMonoidHomMulEquiv : AddChar A M ≃* (Multiplicative A →* M) := { toMonoidHomEquiv with map_mul' := fun φ ψ ↦ by rfl } /-- Additive characters `A → M` are the same thing as additive homomorphisms from `A` to `Additive M`. -/ def toAddMonoidAddEquiv : Additive (AddChar A M) ≃+ (A →+ Additive M) := { toAddMonoidHomEquiv with map_add' := fun φ ψ ↦ by rfl } /-- The double dual embedding. -/ def doubleDualEmb : A →+ AddChar (AddChar A M) M where toFun a := { toFun := fun ψ ↦ ψ a	map_zero_eq_one' := by simp map_add_eq_mul' := by simp } map_zero' := by ext; simp map_add' _ _ := by ext; simp [map_add_eq_mul]	Mathlib/Algebra/Group/AddChar.lean	310	313
/- Copyright (c) 2022 Yaël Dillies, Bhavik Mehta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies, Bhavik Mehta -/ import Mathlib.Algebra.Order.Field.Basic import Mathlib.Combinatorics.SimpleGraph.Basic import Mathlib.Data.Rat.Cast.Order import Mathlib.Order.Partition.Finpartition import Mathlib.Tactic.GCongr import Mathlib.Tactic.NormNum import Mathlib.Tactic.Positivity import Mathlib.Tactic.Ring /-! # Edge density This file defines the number and density of edges of a relation/graph. ## Main declarations Between two finsets of vertices, * `Rel.interedges`: Finset of edges of a relation. * `Rel.edgeDensity`: Edge density of a relation. * `SimpleGraph.interedges`: Finset of edges of a graph. * `SimpleGraph.edgeDensity`: Edge density of a graph. -/ open Finset variable {𝕜 ι κ α β : Type} /-! ### Density of a relation -/ namespace Rel section Asymmetric variable [Field 𝕜] [LinearOrder 𝕜] [IsStrictOrderedRing 𝕜] (r : α → β → Prop) [∀ a, DecidablePred (r a)] {s s₁ s₂ : Finset α} {t t₁ t₂ : Finset β} {a : α} {b : β} {δ : 𝕜} /-- Finset of edges of a relation between two finsets of vertices. -/ def interedges (s : Finset α) (t : Finset β) : Finset (α × β) := {e ∈ s ×ˢ t \| r e.1 e.2} /-- Edge density of a relation between two finsets of vertices. -/ def edgeDensity (s : Finset α) (t : Finset β) : ℚ := #(interedges r s t) / (#s #t) variable {r} theorem mem_interedges_iff {x : α × β} : x ∈ interedges r s t ↔ x.1 ∈ s ∧ x.2 ∈ t ∧ r x.1 x.2 := by rw [interedges, mem_filter, Finset.mem_product, and_assoc] theorem mk_mem_interedges_iff : (a, b) ∈ interedges r s t ↔ a ∈ s ∧ b ∈ t ∧ r a b := mem_interedges_iff	@[simp]	Mathlib/Combinatorics/SimpleGraph/Density.lean	57	58
/- Copyright (c) 2023 Alex Keizer. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Alex Keizer -/ import Mathlib.Data.Vector.Basic import Mathlib.Data.Vector.Snoc /-! This file establishes a set of normalization lemmas for `map`/`mapAccumr` operations on vectors -/ variable {α β γ ζ σ σ₁ σ₂ φ : Type*} {n : ℕ} {s : σ} {s₁ : σ₁} {s₂ : σ₂} namespace List namespace Vector /-! ## Fold nested `mapAccumr`s into one -/ section Fold section Unary variable (xs : Vector α n) (f₁ : β → σ₁ → σ₁ × γ) (f₂ : α → σ₂ → σ₂ × β) @[simp] theorem mapAccumr_mapAccumr : mapAccumr f₁ (mapAccumr f₂ xs s₂).snd s₁ = let m := (mapAccumr (fun x s => let r₂ := f₂ x s.snd let r₁ := f₁ r₂.snd s.fst ((r₁.fst, r₂.fst), r₁.snd) ) xs (s₁, s₂)) (m.fst.fst, m.snd) := by induction xs using Vector.revInductionOn generalizing s₁ s₂ <;> simp_all @[simp] theorem mapAccumr_map {s : σ₁} (f₂ : α → β) : (mapAccumr f₁ (map f₂ xs) s) = (mapAccumr (fun x s => f₁ (f₂ x) s) xs s) := by induction xs using Vector.revInductionOn generalizing s <;> simp_all @[simp] theorem map_mapAccumr {s : σ₂} (f₁ : β → γ) : (map f₁ (mapAccumr f₂ xs s).snd) = (mapAccumr (fun x s => let r := (f₂ x s); (r.fst, f₁ r.snd) ) xs s).snd := by induction xs using Vector.revInductionOn generalizing s <;> simp_all @[simp] theorem map_map (f₁ : β → γ) (f₂ : α → β) : map f₁ (map f₂ xs) = map (fun x => f₁ <\| f₂ x) xs := by induction xs <;> simp_all theorem map_pmap {p : α → Prop} (f₁ : β → γ) (f₂ : (a : α) → p a → β) (H : ∀ x ∈ xs.toList, p x): map f₁ (pmap f₂ xs H) = pmap (fun x hx => f₁ <\| f₂ x hx) xs H := by induction xs <;> simp_all theorem pmap_map {p : β → Prop} (f₁ : (b : β) → p b → γ) (f₂ : α → β) (H : ∀ x ∈ (xs.map f₂).toList, p x): pmap f₁ (map f₂ xs) H = pmap (fun x hx => f₁ (f₂ x) hx) xs (by simpa using H) := by induction xs <;> simp_all end Unary section Binary variable (xs : Vector α n) (ys : Vector β n) @[simp] theorem mapAccumr₂_mapAccumr_left (f₁ : γ → β → σ₁ → σ₁ × ζ) (f₂ : α → σ₂ → σ₂ × γ) : (mapAccumr₂ f₁ (mapAccumr f₂ xs s₂).snd ys s₁) = let m := (mapAccumr₂ (fun x y s => let r₂ := f₂ x s.snd let r₁ := f₁ r₂.snd y s.fst ((r₁.fst, r₂.fst), r₁.snd) ) xs ys (s₁, s₂)) (m.fst.fst, m.snd) := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ <;> simp_all @[simp] theorem map₂_map_left (f₁ : γ → β → ζ) (f₂ : α → γ) : map₂ f₁ (map f₂ xs) ys = map₂ (fun x y => f₁ (f₂ x) y) xs ys := by induction xs, ys using Vector.revInductionOn₂ <;> simp_all @[simp] theorem mapAccumr₂_mapAccumr_right (f₁ : α → γ → σ₁ → σ₁ × ζ) (f₂ : β → σ₂ → σ₂ × γ) : (mapAccumr₂ f₁ xs (mapAccumr f₂ ys s₂).snd s₁) = let m := (mapAccumr₂ (fun x y s => let r₂ := f₂ y s.snd let r₁ := f₁ x r₂.snd s.fst ((r₁.fst, r₂.fst), r₁.snd) ) xs ys (s₁, s₂)) (m.fst.fst, m.snd) := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ <;> simp_all @[simp] theorem map₂_map_right (f₁ : α → γ → ζ) (f₂ : β → γ) : map₂ f₁ xs (map f₂ ys) = map₂ (fun x y => f₁ x (f₂ y)) xs ys := by induction xs, ys using Vector.revInductionOn₂ <;> simp_all @[simp] theorem mapAccumr_mapAccumr₂ (f₁ : γ → σ₁ → σ₁ × ζ) (f₂ : α → β → σ₂ → σ₂ × γ) : (mapAccumr f₁ (mapAccumr₂ f₂ xs ys s₂).snd s₁) = let m := mapAccumr₂ (fun x y s => let r₂ := f₂ x y s.snd let r₁ := f₁ r₂.snd s.fst ((r₁.fst, r₂.fst), r₁.snd) ) xs ys (s₁, s₂) (m.fst.fst, m.snd) := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ <;> simp_all @[simp] theorem map_map₂ (f₁ : γ → ζ) (f₂ : α → β → γ) : map f₁ (map₂ f₂ xs ys) = map₂ (fun x y => f₁ <\| f₂ x y) xs ys := by induction xs, ys using Vector.revInductionOn₂ <;> simp_all @[simp] theorem mapAccumr₂_mapAccumr₂_left_left (f₁ : γ → α → σ₁ → σ₁ × φ) (f₂ : α → β → σ₂ → σ₂ × γ) : (mapAccumr₂ f₁ (mapAccumr₂ f₂ xs ys s₂).snd xs s₁) = let m := mapAccumr₂ (fun x y (s₁, s₂) => let r₂ := f₂ x y s₂ let r₁ := f₁ r₂.snd x s₁ ((r₁.fst, r₂.fst), r₁.snd) ) xs ys (s₁, s₂) (m.fst.fst, m.snd) := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ <;> simp_all @[simp] theorem mapAccumr₂_mapAccumr₂_left_right (f₁ : γ → β → σ₁ → σ₁ × φ) (f₂ : α → β → σ₂ → σ₂ × γ) : (mapAccumr₂ f₁ (mapAccumr₂ f₂ xs ys s₂).snd ys s₁) = let m := mapAccumr₂ (fun x y (s₁, s₂) => let r₂ := f₂ x y s₂ let r₁ := f₁ r₂.snd y s₁ ((r₁.fst, r₂.fst), r₁.snd) ) xs ys (s₁, s₂) (m.fst.fst, m.snd) := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ <;> simp_all @[simp] theorem mapAccumr₂_mapAccumr₂_right_left (f₁ : α → γ → σ₁ → σ₁ × φ) (f₂ : α → β → σ₂ → σ₂ × γ) : (mapAccumr₂ f₁ xs (mapAccumr₂ f₂ xs ys s₂).snd s₁) = let m := mapAccumr₂ (fun x y (s₁, s₂) => let r₂ := f₂ x y s₂ let r₁ := f₁ x r₂.snd s₁ ((r₁.fst, r₂.fst), r₁.snd) ) xs ys (s₁, s₂) (m.fst.fst, m.snd) := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ <;> simp_all @[simp] theorem mapAccumr₂_mapAccumr₂_right_right (f₁ : β → γ → σ₁ → σ₁ × φ) (f₂ : α → β → σ₂ → σ₂ × γ) : (mapAccumr₂ f₁ ys (mapAccumr₂ f₂ xs ys s₂).snd s₁) = let m := mapAccumr₂ (fun x y (s₁, s₂) => let r₂ := f₂ x y s₂ let r₁ := f₁ y r₂.snd s₁ ((r₁.fst, r₂.fst), r₁.snd) ) xs ys (s₁, s₂) (m.fst.fst, m.snd) := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ <;> simp_all end Binary end Fold /-! ## Bisimulations We can prove two applications of `mapAccumr` equal by providing a bisimulation relation that relates the initial states. That is, by providing a relation `R : σ₁ → σ₁ → Prop` such that `R s₁ s₂` implies that `R` also relates any pair of states reachable by applying `f₁` to `s₁` and `f₂` to `s₂`, with any possible input values. -/ section Bisim variable {xs : Vector α n} theorem mapAccumr_bisim {f₁ : α → σ₁ → σ₁ × β} {f₂ : α → σ₂ → σ₂ × β} {s₁ : σ₁} {s₂ : σ₂} (R : σ₁ → σ₂ → Prop) (h₀ : R s₁ s₂) (hR : ∀ {s q} a, R s q → R (f₁ a s).1 (f₂ a q).1 ∧ (f₁ a s).2 = (f₂ a q).2) : R (mapAccumr f₁ xs s₁).fst (mapAccumr f₂ xs s₂).fst ∧ (mapAccumr f₁ xs s₁).snd = (mapAccumr f₂ xs s₂).snd := by induction xs using Vector.revInductionOn generalizing s₁ s₂ next => exact ⟨h₀, rfl⟩ next xs x ih => rcases (hR x h₀) with ⟨hR, _⟩ simp only [mapAccumr_snoc, ih hR, true_and] congr 1 theorem mapAccumr_bisim_tail {f₁ : α → σ₁ → σ₁ × β} {f₂ : α → σ₂ → σ₂ × β} {s₁ : σ₁} {s₂ : σ₂} (h : ∃ R : σ₁ → σ₂ → Prop, R s₁ s₂ ∧ ∀ {s q} a, R s q → R (f₁ a s).1 (f₂ a q).1 ∧ (f₁ a s).2 = (f₂ a q).2) : (mapAccumr f₁ xs s₁).snd = (mapAccumr f₂ xs s₂).snd := by rcases h with ⟨R, h₀, hR⟩ exact (mapAccumr_bisim R h₀ hR).2 theorem mapAccumr₂_bisim {ys : Vector β n} {f₁ : α → β → σ₁ → σ₁ × γ} {f₂ : α → β → σ₂ → σ₂ × γ} {s₁ : σ₁} {s₂ : σ₂} (R : σ₁ → σ₂ → Prop) (h₀ : R s₁ s₂) (hR : ∀ {s q} a b, R s q → R (f₁ a b s).1 (f₂ a b q).1 ∧ (f₁ a b s).2 = (f₂ a b q).2) : R (mapAccumr₂ f₁ xs ys s₁).1 (mapAccumr₂ f₂ xs ys s₂).1 ∧ (mapAccumr₂ f₁ xs ys s₁).2 = (mapAccumr₂ f₂ xs ys s₂).2 := by induction xs, ys using Vector.revInductionOn₂ generalizing s₁ s₂ next => exact ⟨h₀, rfl⟩ next xs ys x y ih => rcases (hR x y h₀) with ⟨hR, _⟩ simp only [mapAccumr₂_snoc, ih hR, true_and] congr 1 theorem mapAccumr₂_bisim_tail {ys : Vector β n} {f₁ : α → β → σ₁ → σ₁ × γ} {f₂ : α → β → σ₂ → σ₂ × γ} {s₁ : σ₁} {s₂ : σ₂} (h : ∃ R : σ₁ → σ₂ → Prop, R s₁ s₂ ∧ ∀ {s q} a b, R s q → R (f₁ a b s).1 (f₂ a b q).1 ∧ (f₁ a b s).2 = (f₂ a b q).2) : (mapAccumr₂ f₁ xs ys s₁).2 = (mapAccumr₂ f₂ xs ys s₂).2 := by rcases h with ⟨R, h₀, hR⟩ exact (mapAccumr₂_bisim R h₀ hR).2 end Bisim /-! ## Redundant state optimization The following section are collection of rewrites to simplify, or even get rid, redundant accumulation state -/ section RedundantState variable {xs : Vector α n} {ys : Vector β n} protected theorem map_eq_mapAccumr {f : α → β} : map f xs = (mapAccumr (fun x (_ : Unit) ↦ ((), f x)) xs ()).snd := by induction xs using Vector.revInductionOn <;> simp_all /-- If there is a set of states that is closed under `f`, and such that `f` produces that same output for all states in this set, then the state is not actually needed. Hence, then we can rewrite `mapAccumr` into just `map`. -/ theorem mapAccumr_eq_map {f : α → σ → σ × β} {s₀ : σ} (S : Set σ) (h₀ : s₀ ∈ S) (closure : ∀ a s, s ∈ S → (f a s).1 ∈ S) (out : ∀ a s s', s ∈ S → s' ∈ S → (f a s).2 = (f a s').2) : (mapAccumr f xs s₀).snd = map (f · s₀ \|>.snd) xs := by rw [Vector.map_eq_mapAccumr] apply mapAccumr_bisim_tail use fun s _ => s ∈ S, h₀ exact @fun s _q a h => ⟨closure a s h, out a s s₀ h h₀⟩ protected theorem map₂_eq_mapAccumr₂ {f : α → β → γ} :	map₂ f xs ys = (mapAccumr₂ (fun x y (_ : Unit) ↦ ((), f x y)) xs ys ()).snd := by induction xs, ys using Vector.revInductionOn₂ <;> simp_all /-- If there is a set of states that is closed under `f`, and such that `f` produces that same output for all states in this set, then the state is not actually needed. Hence, then we can rewrite `mapAccumr₂` into just `map₂`. -/	Mathlib/Data/Vector/MapLemmas.lean	252	259
/- Copyright (c) 2019 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau -/ import Mathlib.Algebra.Algebra.Bilinear import Mathlib.Algebra.Algebra.Opposite import Mathlib.Algebra.Group.Pointwise.Finset.Basic import Mathlib.Algebra.Group.Pointwise.Set.BigOperators import Mathlib.Algebra.Module.Submodule.Pointwise import Mathlib.Algebra.Ring.NonZeroDivisors import Mathlib.Algebra.Ring.Submonoid.Pointwise import Mathlib.Data.Set.Semiring import Mathlib.GroupTheory.GroupAction.SubMulAction.Pointwise /-! # Multiplication and division of submodules of an algebra. An interface for multiplication and division of sub-R-modules of an R-algebra A is developed. ## Main definitions Let `R` be a commutative ring (or semiring) and let `A` be an `R`-algebra. * `1 : Submodule R A` : the R-submodule R of the R-algebra A * `Mul (Submodule R A)` : multiplication of two sub-R-modules M and N of A is defined to be the smallest submodule containing all the products `m * n`. * `Div (Submodule R A)` : `I / J` is defined to be the submodule consisting of all `a : A` such that `a • J ⊆ I` It is proved that `Submodule R A` is a semiring, and also an algebra over `Set A`. Additionally, in the `Pointwise` locale we promote `Submodule.pointwiseDistribMulAction` to a `MulSemiringAction` as `Submodule.pointwiseMulSemiringAction`. When `R` is not necessarily commutative, and `A` is merely a `R`-module with a ring structure such that `IsScalarTower R A A` holds (equivalent to the data of a ring homomorphism `R →+* A` by `ringHomEquivModuleIsScalarTower`), we can still define `1 : Submodule R A` and `Mul (Submodule R A)`, but `1` is only a left identity, not necessarily a right one. ## Tags multiplication of submodules, division of submodules, submodule semiring -/ universe uι u v open Algebra Set MulOpposite open Pointwise namespace SubMulAction variable {R : Type u} {A : Type v} [CommSemiring R] [Semiring A] [Algebra R A] theorem algebraMap_mem (r : R) : algebraMap R A r ∈ (1 : SubMulAction R A) := ⟨r, (algebraMap_eq_smul_one r).symm⟩ theorem mem_one' {x : A} : x ∈ (1 : SubMulAction R A) ↔ ∃ y, algebraMap R A y = x := exists_congr fun r => by rw [algebraMap_eq_smul_one] end SubMulAction namespace Submodule section Module variable {R : Type u} [Semiring R] {A : Type v} [Semiring A] [Module R A] -- TODO: Why is this in a file about `Algebra`? -- TODO: potentially change this back to `LinearMap.range (Algebra.linearMap R A)` -- once a version of `Algebra` without the `commutes'` field is introduced. -- See issue https://github.com/leanprover-community/mathlib4/issues/18110. /-- `1 : Submodule R A` is the submodule `R ∙ 1` of `A`. -/ instance one : One (Submodule R A) := ⟨LinearMap.range (LinearMap.toSpanSingleton R A 1)⟩ theorem one_eq_span : (1 : Submodule R A) = R ∙ 1 := (LinearMap.span_singleton_eq_range _ _ _).symm theorem le_one_toAddSubmonoid : 1 ≤ (1 : Submodule R A).toAddSubmonoid := by rintro x ⟨n, rfl⟩ exact ⟨n, show (n : R) • (1 : A) = n by rw [Nat.cast_smul_eq_nsmul, nsmul_one]⟩ @[simp] theorem toSubMulAction_one : (1 : Submodule R A).toSubMulAction = 1 := SetLike.ext fun _ ↦ by rw [one_eq_span, SubMulAction.mem_one]; exact mem_span_singleton theorem one_eq_span_one_set : (1 : Submodule R A) = span R 1 := one_eq_span @[simp] theorem one_le {P : Submodule R A} : (1 : Submodule R A) ≤ P ↔ (1 : A) ∈ P := by simp [one_eq_span] variable {M : Type} [AddCommMonoid M] [Module R M] [Module A M] [IsScalarTower R A M] instance : SMul (Submodule R A) (Submodule R M) where smul A' M' := { __ := A'.toAddSubmonoid • M'.toAddSubmonoid smul_mem' := fun r m hm ↦ AddSubmonoid.smul_induction_on hm (fun a ha m hm ↦ by rw [← smul_assoc]; exact AddSubmonoid.smul_mem_smul (A'.smul_mem r ha) hm) fun m₁ m₂ h₁ h₂ ↦ by rw [smul_add]; exact (A'.1 • M'.1).add_mem h₁ h₂ } section variable {I J : Submodule R A} {N P : Submodule R M} theorem smul_toAddSubmonoid : (I • N).toAddSubmonoid = I.toAddSubmonoid • N.toAddSubmonoid := rfl theorem smul_mem_smul {r} {n} (hr : r ∈ I) (hn : n ∈ N) : r • n ∈ I • N := AddSubmonoid.smul_mem_smul hr hn theorem smul_le : I • N ≤ P ↔ ∀ r ∈ I, ∀ n ∈ N, r • n ∈ P := AddSubmonoid.smul_le @[simp, norm_cast] lemma coe_set_smul : (I : Set A) • N = I • N := set_smul_eq_of_le _ _ _ (fun _ _ hr hx ↦ smul_mem_smul hr hx) (smul_le.mpr fun _ hr _ hx ↦ mem_set_smul_of_mem_mem hr hx) @[elab_as_elim] theorem smul_induction_on {p : M → Prop} {x} (H : x ∈ I • N) (smul : ∀ r ∈ I, ∀ n ∈ N, p (r • n)) (add : ∀ x y, p x → p y → p (x + y)) : p x := AddSubmonoid.smul_induction_on H smul add /-- Dependent version of `Submodule.smul_induction_on`. -/ @[elab_as_elim] theorem smul_induction_on' {x : M} (hx : x ∈ I • N) {p : ∀ x, x ∈ I • N → Prop} (smul : ∀ (r : A) (hr : r ∈ I) (n : M) (hn : n ∈ N), p (r • n) (smul_mem_smul hr hn)) (add : ∀ x hx y hy, p x hx → p y hy → p (x + y) (add_mem ‹_› ‹_›)) : p x hx := by refine Exists.elim ?_ fun (h : x ∈ I • N) (H : p x h) ↦ H exact smul_induction_on hx (fun a ha x hx ↦ ⟨_, smul _ ha _ hx⟩) fun x y ⟨_, hx⟩ ⟨_, hy⟩ ↦ ⟨_, add _ _ _ _ hx hy⟩ theorem smul_mono (hij : I ≤ J) (hnp : N ≤ P) : I • N ≤ J • P := AddSubmonoid.smul_le_smul hij hnp theorem smul_mono_left (h : I ≤ J) : I • N ≤ J • N := smul_mono h le_rfl instance : CovariantClass (Submodule R A) (Submodule R M) HSMul.hSMul LE.le := ⟨fun _ _ => smul_mono le_rfl⟩ variable (I J N P) @[simp] theorem smul_bot : I • (⊥ : Submodule R M) = ⊥ := toAddSubmonoid_injective <\| AddSubmonoid.addSubmonoid_smul_bot _ @[simp] theorem bot_smul : (⊥ : Submodule R A) • N = ⊥ := le_bot_iff.mp <\| smul_le.mpr <\| by rintro _ rfl _ _; rw [zero_smul]; exact zero_mem _ theorem smul_sup : I • (N ⊔ P) = I • N ⊔ I • P := toAddSubmonoid_injective <\| by simp only [smul_toAddSubmonoid, sup_toAddSubmonoid, AddSubmonoid.addSubmonoid_smul_sup] theorem sup_smul : (I ⊔ J) • N = I • N ⊔ J • N := le_antisymm (smul_le.mpr fun mn hmn p hp ↦ by obtain ⟨m, hm, n, hn, rfl⟩ := mem_sup.mp hmn rw [add_smul]; exact add_mem_sup (smul_mem_smul hm hp) <\| smul_mem_smul hn hp) (sup_le (smul_mono_left le_sup_left) <\| smul_mono_left le_sup_right) protected theorem smul_assoc {B} [Semiring B] [Module R B] [Module A B] [Module B M] [IsScalarTower R A B] [IsScalarTower R B M] [IsScalarTower A B M] (I : Submodule R A) (J : Submodule R B) (N : Submodule R M) : (I • J) • N = I • J • N := le_antisymm (smul_le.2 fun _ hrsij t htn ↦ smul_induction_on hrsij (fun r hr s hs ↦ smul_assoc r s t ▸ smul_mem_smul hr (smul_mem_smul hs htn)) fun x y ↦ (add_smul x y t).symm ▸ add_mem) (smul_le.2 fun r hr _ hsn ↦ smul_induction_on hsn (fun j hj n hn ↦ (smul_assoc r j n).symm ▸ smul_mem_smul (smul_mem_smul hr hj) hn) fun m₁ m₂ ↦ (smul_add r m₁ m₂) ▸ add_mem) theorem smul_iSup {ι : Sort} {I : Submodule R A} {t : ι → Submodule R M} : I • (⨆ i, t i)= ⨆ i, I • t i := toAddSubmonoid_injective <\| by simp only [smul_toAddSubmonoid, iSup_toAddSubmonoid, AddSubmonoid.smul_iSup] theorem iSup_smul {ι : Sort} {t : ι → Submodule R A} {N : Submodule R M} : (⨆ i, t i) • N = ⨆ i, t i • N := le_antisymm (smul_le.mpr fun t ht s hs ↦ iSup_induction _ (motive := (· • s ∈ _)) ht (fun i t ht ↦ mem_iSup_of_mem i <\| smul_mem_smul ht hs) (by simp_rw [zero_smul]; apply zero_mem) fun x y ↦ by simp_rw [add_smul]; apply add_mem) (iSup_le fun i ↦ Submodule.smul_mono_left <\| le_iSup _ i) protected theorem one_smul : (1 : Submodule R A) • N = N := by refine le_antisymm (smul_le.mpr fun r hr m hm ↦ ?_) fun m hm ↦ ?_ · obtain ⟨r, rfl⟩ := hr rw [LinearMap.toSpanSingleton_apply, smul_one_smul]; exact N.smul_mem r hm · rw [← one_smul A m]; exact smul_mem_smul (one_le.mp le_rfl) hm theorem smul_subset_smul : (↑I : Set A) • (↑N : Set M) ⊆ (↑(I • N) : Set M) := AddSubmonoid.smul_subset_smul end variable [IsScalarTower R A A] /-- Multiplication of sub-R-modules of an R-module A that is also a semiring. The submodule `M N` consists of finite sums of elements `m * n` for `m ∈ M` and `n ∈ N`. -/ instance mul : Mul (Submodule R A) where mul := (· • ·) variable (S T : Set A) {M N P Q : Submodule R A} {m n : A} theorem mul_mem_mul (hm : m ∈ M) (hn : n ∈ N) : m * n ∈ M * N := smul_mem_smul hm hn theorem mul_le : M * N ≤ P ↔ ∀ m ∈ M, ∀ n ∈ N, m * n ∈ P := smul_le theorem mul_toAddSubmonoid (M N : Submodule R A) : (M * N).toAddSubmonoid = M.toAddSubmonoid * N.toAddSubmonoid := rfl @[elab_as_elim] protected theorem mul_induction_on {C : A → Prop} {r : A} (hr : r ∈ M * N) (hm : ∀ m ∈ M, ∀ n ∈ N, C (m * n)) (ha : ∀ x y, C x → C y → C (x + y)) : C r := smul_induction_on hr hm ha /-- A dependent version of `mul_induction_on`. -/ @[elab_as_elim] protected theorem mul_induction_on' {C : ∀ r, r ∈ M * N → Prop} (mem_mul_mem : ∀ m (hm : m ∈ M) n (hn : n ∈ N), C (m * n) (mul_mem_mul hm hn)) (add : ∀ x hx y hy, C x hx → C y hy → C (x + y) (add_mem hx hy)) {r : A} (hr : r ∈ M * N) : C r hr := smul_induction_on' hr mem_mul_mem add variable (M) @[simp] theorem mul_bot : M * ⊥ = ⊥ := smul_bot _ @[simp] theorem bot_mul : ⊥ * M = ⊥ := bot_smul _ protected theorem one_mul : (1 : Submodule R A) * M = M := Submodule.one_smul _ variable {M} @[mono] theorem mul_le_mul (hmp : M ≤ P) (hnq : N ≤ Q) : M * N ≤ P * Q := smul_mono hmp hnq theorem mul_le_mul_left (h : M ≤ N) : M * P ≤ N * P := smul_mono_left h theorem mul_le_mul_right (h : N ≤ P) : M * N ≤ M * P := smul_mono_right _ h theorem mul_comm_of_commute (h : ∀ m ∈ M, ∀ n ∈ N, Commute m n) : M * N = N * M := toAddSubmonoid_injective <\| AddSubmonoid.mul_comm_of_commute h variable (M N P) theorem mul_sup : M * (N ⊔ P) = M * N ⊔ M * P := smul_sup _ _ _ theorem sup_mul : (M ⊔ N) * P = M * P ⊔ N * P := sup_smul _ _ _ theorem mul_subset_mul : (↑M : Set A) * (↑N : Set A) ⊆ (↑(M * N) : Set A) := smul_subset_smul _ _ lemma restrictScalars_mul {A B C} [Semiring A] [Semiring B] [Semiring C] [SMul A B] [Module A C] [Module B C] [IsScalarTower A C C] [IsScalarTower B C C] [IsScalarTower A B C] {I J : Submodule B C} : (I * J).restrictScalars A = I.restrictScalars A * J.restrictScalars A := rfl variable {ι : Sort uι} theorem iSup_mul (s : ι → Submodule R A) (t : Submodule R A) : (⨆ i, s i) * t = ⨆ i, s i * t := iSup_smul theorem mul_iSup (t : Submodule R A) (s : ι → Submodule R A) : (t * ⨆ i, s i) = ⨆ i, t * s i := smul_iSup /-- Sub-`R`-modules of an `R`-module form an idempotent semiring. -/ instance : NonUnitalSemiring (Submodule R A) where __ := toAddSubmonoid_injective.semigroup _ mul_toAddSubmonoid zero_mul := bot_mul mul_zero := mul_bot left_distrib := mul_sup right_distrib := sup_mul instance : Pow (Submodule R A) ℕ where pow s n := npowRec n s theorem pow_eq_npowRec {n : ℕ} : M ^ n = npowRec n M := rfl protected theorem pow_zero : M ^ 0 = 1 := rfl protected theorem pow_succ {n : ℕ} : M ^ (n + 1) = M ^ n * M := rfl protected theorem pow_add {m n : ℕ} (h : n ≠ 0) : M ^ (m + n) = M ^ m * M ^ n := npowRec_add m n h _ M.one_mul protected theorem pow_one : M ^ 1 = M := by rw [Submodule.pow_succ, Submodule.pow_zero, Submodule.one_mul] /-- `Submodule.pow_succ` with the right hand side commuted. -/ protected theorem pow_succ' {n : ℕ} (h : n ≠ 0) : M ^ (n + 1) = M * M ^ n := by rw [add_comm, M.pow_add h, Submodule.pow_one] theorem pow_toAddSubmonoid {n : ℕ} (h : n ≠ 0) : (M ^ n).toAddSubmonoid = M.toAddSubmonoid ^ n := by induction n with \| zero => exact (h rfl).elim \| succ n ih => rw [Submodule.pow_succ, pow_succ, mul_toAddSubmonoid] cases n with \| zero => rw [Submodule.pow_zero, pow_zero, one_mul, ← mul_toAddSubmonoid, Submodule.one_mul] \| succ n => rw [ih n.succ_ne_zero] theorem le_pow_toAddSubmonoid {n : ℕ} : M.toAddSubmonoid ^ n ≤ (M ^ n).toAddSubmonoid := by obtain rfl \| hn := Decidable.eq_or_ne n 0 · rw [Submodule.pow_zero, pow_zero] exact le_one_toAddSubmonoid · exact (pow_toAddSubmonoid M hn).ge theorem pow_subset_pow {n : ℕ} : (↑M : Set A) ^ n ⊆ ↑(M ^ n : Submodule R A) := trans AddSubmonoid.pow_subset_pow (le_pow_toAddSubmonoid M) theorem pow_mem_pow {x : A} (hx : x ∈ M) (n : ℕ) : x ^ n ∈ M ^ n := pow_subset_pow _ <\| Set.pow_mem_pow hx lemma restrictScalars_pow {A B C : Type} [Semiring A] [Semiring B] [Semiring C] [SMul A B] [Module A C] [Module B C] [IsScalarTower A C C] [IsScalarTower B C C] [IsScalarTower A B C] {I : Submodule B C} : ∀ {n : ℕ}, (hn : n ≠ 0) → (I ^ n).restrictScalars A = I.restrictScalars A ^ n \| 1, _ => by simp [Submodule.pow_one] \| n + 2, _ => by simp [Submodule.pow_succ (n := n + 1), restrictScalars_mul, restrictScalars_pow n.succ_ne_zero] end Module variable {ι : Sort uι} variable {R : Type u} [CommSemiring R] section AlgebraSemiring variable {A : Type v} [Semiring A] [Algebra R A] variable (S T : Set A) {M N P Q : Submodule R A} {m n : A} theorem one_eq_range : (1 : Submodule R A) = LinearMap.range (Algebra.linearMap R A) := by rw [one_eq_span, LinearMap.span_singleton_eq_range, LinearMap.toSpanSingleton_eq_algebra_linearMap] theorem algebraMap_mem (r : R) : algebraMap R A r ∈ (1 : Submodule R A) := by simp [one_eq_range] @[simp] theorem mem_one {x : A} : x ∈ (1 : Submodule R A) ↔ ∃ y, algebraMap R A y = x := by simp [one_eq_range] protected theorem map_one {A'} [Semiring A'] [Algebra R A'] (f : A →ₐ[R] A') : map f.toLinearMap (1 : Submodule R A) = 1 := by ext simp @[simp] theorem map_op_one : map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) (1 : Submodule R A) = 1 := by ext x induction x simp @[simp] theorem comap_op_one : comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) (1 : Submodule R Aᵐᵒᵖ) = 1 := by ext simp @[simp] theorem map_unop_one : map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) (1 : Submodule R Aᵐᵒᵖ) = 1 := by rw [← comap_equiv_eq_map_symm, comap_op_one] @[simp] theorem comap_unop_one : comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) (1 : Submodule R A) = 1 := by rw [← map_equiv_eq_comap_symm, map_op_one] theorem mul_eq_map₂ : M N = map₂ (LinearMap.mul R A) M N := le_antisymm (mul_le.mpr fun _m hm _n ↦ apply_mem_map₂ _ hm) (map₂_le.mpr fun _m hm _n ↦ mul_mem_mul hm) variable (R M N) theorem span_mul_span : span R S * span R T = span R (S * T) := by rw [mul_eq_map₂]; apply map₂_span_span lemma mul_def : M * N = span R (M * N : Set A) := by simp [← span_mul_span] variable {R} (P Q) protected theorem mul_one : M * 1 = M := by conv_lhs => rw [one_eq_span, ← span_eq M] rw [span_mul_span] simp protected theorem map_mul {A'} [Semiring A'] [Algebra R A'] (f : A →ₐ[R] A') : map f.toLinearMap (M * N) = map f.toLinearMap M * map f.toLinearMap N := calc map f.toLinearMap (M * N) = ⨆ i : M, (N.map (LinearMap.mul R A i)).map f.toLinearMap := by rw [mul_eq_map₂]; apply map_iSup _ = map f.toLinearMap M * map f.toLinearMap N := by rw [mul_eq_map₂] apply congr_arg sSup ext S constructor <;> rintro ⟨y, hy⟩ · use ⟨f y, mem_map.mpr ⟨y.1, y.2, rfl⟩⟩ refine Eq.trans ?_ hy ext simp · obtain ⟨y', hy', fy_eq⟩ := mem_map.mp y.2 use ⟨y', hy'⟩ refine Eq.trans ?_ hy rw [f.toLinearMap_apply] at fy_eq ext simp [fy_eq] theorem map_op_mul : map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) (M * N) = map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) N * map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) M := by apply le_antisymm · simp_rw [map_le_iff_le_comap] refine mul_le.2 fun m hm n hn => ?_ rw [mem_comap, map_equiv_eq_comap_symm, map_equiv_eq_comap_symm] show op n * op m ∈ _ exact mul_mem_mul hn hm · refine mul_le.2 (MulOpposite.rec' fun m hm => MulOpposite.rec' fun n hn => ?_) rw [Submodule.mem_map_equiv] at hm hn ⊢ exact mul_mem_mul hn hm theorem comap_unop_mul : comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) (M * N) = comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) N * comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) M := by simp_rw [← map_equiv_eq_comap_symm, map_op_mul] theorem map_unop_mul (M N : Submodule R Aᵐᵒᵖ) : map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) (M * N) = map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) N * map (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ).symm : Aᵐᵒᵖ →ₗ[R] A) M := have : Function.Injective (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) := LinearEquiv.injective _ map_injective_of_injective this <\| by rw [← map_comp, map_op_mul, ← map_comp, ← map_comp, LinearEquiv.comp_coe, LinearEquiv.symm_trans_self, LinearEquiv.refl_toLinearMap, map_id, map_id, map_id] theorem comap_op_mul (M N : Submodule R Aᵐᵒᵖ) : comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) (M * N) = comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) N * comap (↑(opLinearEquiv R : A ≃ₗ[R] Aᵐᵒᵖ) : A →ₗ[R] Aᵐᵒᵖ) M := by simp_rw [comap_equiv_eq_map_symm, map_unop_mul] section variable {α : Type*} [Monoid α] [DistribMulAction α A] [SMulCommClass α R A]	instance [IsScalarTower α A A] : IsScalarTower α (Submodule R A) (Submodule R A) where smul_assoc a S T := by rw [← S.span_eq, ← T.span_eq, smul_span, smul_eq_mul, smul_eq_mul, span_mul_span, span_mul_span, smul_span, smul_mul_assoc] instance [SMulCommClass α A A] : SMulCommClass α (Submodule R A) (Submodule R A) where smul_comm a S T := by rw [← S.span_eq, ← T.span_eq, smul_span, smul_eq_mul, smul_eq_mul, span_mul_span, span_mul_span, smul_span, mul_smul_comm] instance [SMulCommClass A α A] : SMulCommClass (Submodule R A) α (Submodule R A) := have := SMulCommClass.symm A α A; .symm .. end section open Pointwise	Mathlib/Algebra/Algebra/Operations.lean	471	488
/- Copyright (c) 2023 Michael Stoll. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Michael Geißer, Michael Stoll -/ import Mathlib.Data.ZMod.Basic import Mathlib.NumberTheory.DiophantineApproximation.Basic import Mathlib.NumberTheory.Zsqrtd.Basic import Mathlib.Tactic.Qify /-! # Pell's Equation Pell's Equation is the equation $x^2 - d y^2 = 1$, where $d$ is a positive integer that is not a square, and one is interested in solutions in integers $x$ and $y$. In this file, we aim at providing all of the essential theory of Pell's Equation for general $d$ (as opposed to the contents of `NumberTheory.PellMatiyasevic`, which is specific to the case $d = a^2 - 1$ for some $a > 1$). We begin by defining a type `Pell.Solution₁ d` for solutions of the equation, show that it has a natural structure as an abelian group, and prove some basic properties. We then prove the following Theorem. Let $d$ be a positive integer that is not a square. Then the equation $x^2 - d y^2 = 1$ has a nontrivial (i.e., with $y \ne 0$) solution in integers. See `Pell.exists_of_not_isSquare` and `Pell.Solution₁.exists_nontrivial_of_not_isSquare`. We then define the fundamental solution to be the solution with smallest $x$ among all solutions satisfying $x > 1$ and $y > 0$. We show that every solution is a power (in the sense of the group structure mentioned above) of the fundamental solution up to a (common) sign, see `Pell.IsFundamental.eq_zpow_or_neg_zpow`, and that a (positive) solution has this property if and only if it is fundamental, see `Pell.pos_generator_iff_fundamental`. ## References * [K. Ireland, M. Rosen, A classical introduction to modern number theory (Section 17.5)][IrelandRosen1990] ## Tags Pell's equation ## TODO * Extend to `x ^ 2 - d * y ^ 2 = -1` and further generalizations. * Connect solutions to the continued fraction expansion of `√d`. -/ namespace Pell /-! ### Group structure of the solution set We define a structure of a commutative multiplicative group with distributive negation on the set of all solutions to the Pell equation `x^2 - dy^2 = 1`. The type of such solutions is `Pell.Solution₁ d`. It corresponds to a pair of integers `x` and `y` and a proof that `(x, y)` is indeed a solution. The multiplication is given by `(x, y) (x', y') = (xy' + dyy', xy' + yx')`. This is obtained by mapping `(x, y)` to `x + y√d` and multiplying the results. In fact, we define `Pell.Solution₁ d` to be `↥(unitary (ℤ√d))` and transport the "commutative group with distributive negation" structure from `↥(unitary (ℤ√d))`. We then set up an API for `Pell.Solution₁ d`. -/ open CharZero Zsqrtd /-- An element of `ℤ√d` has norm one (i.e., `a.re^2 - da.im^2 = 1`) if and only if it is contained in the submonoid of unitary elements. TODO: merge this result with `Pell.isPell_iff_mem_unitary`. -/ theorem is_pell_solution_iff_mem_unitary {d : ℤ} {a : ℤ√d} : a.re ^ 2 - d a.im ^ 2 = 1 ↔ a ∈ unitary (ℤ√d) := by rw [← norm_eq_one_iff_mem_unitary, norm_def, sq, sq, ← mul_assoc] -- We use `solution₁ d` to allow for a more general structure `solution d m` that -- encodes solutions to `x^2 - dy^2 = m` to be added later. /-- `Pell.Solution₁ d` is the type of solutions to the Pell equation `x^2 - dy^2 = 1`. We define this in terms of elements of `ℤ√d` of norm one. -/ def Solution₁ (d : ℤ) : Type := ↥(unitary (ℤ√d)) namespace Solution₁ variable {d : ℤ} instance instCommGroup : CommGroup (Solution₁ d) := inferInstanceAs (CommGroup (unitary (ℤ√d))) instance instHasDistribNeg : HasDistribNeg (Solution₁ d) := inferInstanceAs (HasDistribNeg (unitary (ℤ√d))) instance instInhabited : Inhabited (Solution₁ d) := inferInstanceAs (Inhabited (unitary (ℤ√d))) instance : Coe (Solution₁ d) (ℤ√d) where coe := Subtype.val /-- The `x` component of a solution to the Pell equation `x^2 - dy^2 = 1` -/ protected def x (a : Solution₁ d) : ℤ := (a : ℤ√d).re /-- The `y` component of a solution to the Pell equation `x^2 - dy^2 = 1` -/ protected def y (a : Solution₁ d) : ℤ := (a : ℤ√d).im /-- The proof that `a` is a solution to the Pell equation `x^2 - dy^2 = 1` -/ theorem prop (a : Solution₁ d) : a.x ^ 2 - d a.y ^ 2 = 1 := is_pell_solution_iff_mem_unitary.mpr a.property /-- An alternative form of the equation, suitable for rewriting `x^2`. -/ theorem prop_x (a : Solution₁ d) : a.x ^ 2 = 1 + d * a.y ^ 2 := by rw [← a.prop]; ring /-- An alternative form of the equation, suitable for rewriting `d * y^2`. -/ theorem prop_y (a : Solution₁ d) : d * a.y ^ 2 = a.x ^ 2 - 1 := by rw [← a.prop]; ring /-- Two solutions are equal if their `x` and `y` components are equal. -/ @[ext] theorem ext {a b : Solution₁ d} (hx : a.x = b.x) (hy : a.y = b.y) : a = b := Subtype.ext <\| Zsqrtd.ext hx hy /-- Construct a solution from `x`, `y` and a proof that the equation is satisfied. -/ def mk (x y : ℤ) (prop : x ^ 2 - d * y ^ 2 = 1) : Solution₁ d where val := ⟨x, y⟩ property := is_pell_solution_iff_mem_unitary.mp prop @[simp] theorem x_mk (x y : ℤ) (prop : x ^ 2 - d * y ^ 2 = 1) : (mk x y prop).x = x := rfl @[simp] theorem y_mk (x y : ℤ) (prop : x ^ 2 - d * y ^ 2 = 1) : (mk x y prop).y = y := rfl @[simp] theorem coe_mk (x y : ℤ) (prop : x ^ 2 - d * y ^ 2 = 1) : (↑(mk x y prop) : ℤ√d) = ⟨x, y⟩ := Zsqrtd.ext (x_mk x y prop) (y_mk x y prop) @[simp] theorem x_one : (1 : Solution₁ d).x = 1 := rfl @[simp] theorem y_one : (1 : Solution₁ d).y = 0 := rfl @[simp] theorem x_mul (a b : Solution₁ d) : (a * b).x = a.x * b.x + d * (a.y * b.y) := by rw [← mul_assoc] rfl @[simp] theorem y_mul (a b : Solution₁ d) : (a * b).y = a.x * b.y + a.y * b.x := rfl @[simp] theorem x_inv (a : Solution₁ d) : a⁻¹.x = a.x := rfl @[simp] theorem y_inv (a : Solution₁ d) : a⁻¹.y = -a.y := rfl @[simp] theorem x_neg (a : Solution₁ d) : (-a).x = -a.x := rfl @[simp] theorem y_neg (a : Solution₁ d) : (-a).y = -a.y := rfl /-- When `d` is negative, then `x` or `y` must be zero in a solution. -/ theorem eq_zero_of_d_neg (h₀ : d < 0) (a : Solution₁ d) : a.x = 0 ∨ a.y = 0 := by have h := a.prop contrapose! h have h1 := sq_pos_of_ne_zero h.1 have h2 := sq_pos_of_ne_zero h.2 nlinarith /-- A solution has `x ≠ 0`. -/ theorem x_ne_zero (h₀ : 0 ≤ d) (a : Solution₁ d) : a.x ≠ 0 := by intro hx have h : 0 ≤ d * a.y ^ 2 := mul_nonneg h₀ (sq_nonneg _) rw [a.prop_y, hx, sq, zero_mul, zero_sub] at h exact not_le.mpr (neg_one_lt_zero : (-1 : ℤ) < 0) h /-- A solution with `x > 1` must have `y ≠ 0`. -/ theorem y_ne_zero_of_one_lt_x {a : Solution₁ d} (ha : 1 < a.x) : a.y ≠ 0 := by intro hy have prop := a.prop rw [hy, sq (0 : ℤ), zero_mul, mul_zero, sub_zero] at prop exact lt_irrefl _ (((one_lt_sq_iff₀ <\| zero_le_one.trans ha.le).mpr ha).trans_eq prop) /-- If a solution has `x > 1`, then `d` is positive. -/ theorem d_pos_of_one_lt_x {a : Solution₁ d} (ha : 1 < a.x) : 0 < d := by refine pos_of_mul_pos_left ?_ (sq_nonneg a.y) rw [a.prop_y, sub_pos] exact one_lt_pow₀ ha two_ne_zero /-- If a solution has `x > 1`, then `d` is not a square. -/ theorem d_nonsquare_of_one_lt_x {a : Solution₁ d} (ha : 1 < a.x) : ¬IsSquare d := by have hp := a.prop rintro ⟨b, rfl⟩ simp_rw [← sq, ← mul_pow, sq_sub_sq, Int.mul_eq_one_iff_eq_one_or_neg_one] at hp omega /-- A solution with `x = 1` is trivial. -/ theorem eq_one_of_x_eq_one (h₀ : d ≠ 0) {a : Solution₁ d} (ha : a.x = 1) : a = 1 := by have prop := a.prop_y rw [ha, one_pow, sub_self, mul_eq_zero, or_iff_right h₀, sq_eq_zero_iff] at prop exact ext ha prop /-- A solution is `1` or `-1` if and only if `y = 0`. -/ theorem eq_one_or_neg_one_iff_y_eq_zero {a : Solution₁ d} : a = 1 ∨ a = -1 ↔ a.y = 0 := by refine ⟨fun H => H.elim (fun h => by simp [h]) fun h => by simp [h], fun H => ?_⟩ have prop := a.prop rw [H, sq (0 : ℤ), mul_zero, mul_zero, sub_zero, sq_eq_one_iff] at prop exact prop.imp (fun h => ext h H) fun h => ext h H /-- The set of solutions with `x > 0` is closed under multiplication. -/ theorem x_mul_pos {a b : Solution₁ d} (ha : 0 < a.x) (hb : 0 < b.x) : 0 < (a * b).x := by simp only [x_mul] refine neg_lt_iff_pos_add'.mp (abs_lt.mp ?_).1 rw [← abs_of_pos ha, ← abs_of_pos hb, ← abs_mul, ← sq_lt_sq, mul_pow a.x, a.prop_x, b.prop_x, ← sub_pos] ring_nf rcases le_or_lt 0 d with h \| h · positivity · rw [(eq_zero_of_d_neg h a).resolve_left ha.ne', (eq_zero_of_d_neg h b).resolve_left hb.ne'] simp /-- The set of solutions with `x` and `y` positive is closed under multiplication. -/ theorem y_mul_pos {a b : Solution₁ d} (hax : 0 < a.x) (hay : 0 < a.y) (hbx : 0 < b.x) (hby : 0 < b.y) : 0 < (a * b).y := by simp only [y_mul] positivity /-- If `(x, y)` is a solution with `x` positive, then all its powers with natural exponents have positive `x`. -/ theorem x_pow_pos {a : Solution₁ d} (hax : 0 < a.x) (n : ℕ) : 0 < (a ^ n).x := by induction n with \| zero => simp only [pow_zero, x_one, zero_lt_one] \| succ n ih => rw [pow_succ]; exact x_mul_pos ih hax /-- If `(x, y)` is a solution with `x` and `y` positive, then all its powers with positive natural exponents have positive `y`. -/ theorem y_pow_succ_pos {a : Solution₁ d} (hax : 0 < a.x) (hay : 0 < a.y) (n : ℕ) : 0 < (a ^ n.succ).y := by induction n with \| zero => simp only [pow_one, hay] \| succ n ih => rw [pow_succ']; exact y_mul_pos hax hay (x_pow_pos hax _) ih /-- If `(x, y)` is a solution with `x` and `y` positive, then all its powers with positive exponents have positive `y`. -/ theorem y_zpow_pos {a : Solution₁ d} (hax : 0 < a.x) (hay : 0 < a.y) {n : ℤ} (hn : 0 < n) : 0 < (a ^ n).y := by lift n to ℕ using hn.le norm_cast at hn ⊢ rw [← Nat.succ_pred_eq_of_pos hn] exact y_pow_succ_pos hax hay _ /-- If `(x, y)` is a solution with `x` positive, then all its powers have positive `x`. -/ theorem x_zpow_pos {a : Solution₁ d} (hax : 0 < a.x) (n : ℤ) : 0 < (a ^ n).x := by cases n with \| ofNat n => rw [Int.ofNat_eq_coe, zpow_natCast] exact x_pow_pos hax n \| negSucc n => rw [zpow_negSucc] exact x_pow_pos hax (n + 1) /-- If `(x, y)` is a solution with `x` and `y` positive, then the `y` component of any power has the same sign as the exponent. -/ theorem sign_y_zpow_eq_sign_of_x_pos_of_y_pos {a : Solution₁ d} (hax : 0 < a.x) (hay : 0 < a.y) (n : ℤ) : (a ^ n).y.sign = n.sign := by rcases n with ((_ \| n) \| n) · rfl · rw [Int.ofNat_eq_coe, zpow_natCast] exact Int.sign_eq_one_of_pos (y_pow_succ_pos hax hay n) · rw [zpow_negSucc] exact Int.sign_eq_neg_one_of_neg (neg_neg_of_pos (y_pow_succ_pos hax hay n)) /-- If `a` is any solution, then one of `a`, `a⁻¹`, `-a`, `-a⁻¹` has positive `x` and nonnegative `y`. -/ theorem exists_pos_variant (h₀ : 0 < d) (a : Solution₁ d) : ∃ b : Solution₁ d, 0 < b.x ∧ 0 ≤ b.y ∧ a ∈ ({b, b⁻¹, -b, -b⁻¹} : Set (Solution₁ d)) := by refine (lt_or_gt_of_ne (a.x_ne_zero h₀.le)).elim ((le_total 0 a.y).elim (fun hy hx => ⟨-a⁻¹, ?_, ?_, ?_⟩) fun hy hx => ⟨-a, ?_, ?_, ?_⟩) ((le_total 0 a.y).elim (fun hy hx => ⟨a, hx, hy, ?_⟩) fun hy hx => ⟨a⁻¹, hx, ?_, ?_⟩) <;> simp only [neg_neg, inv_inv, neg_inv, Set.mem_insert_iff, Set.mem_singleton_iff, true_or, eq_self_iff_true, x_neg, x_inv, y_neg, y_inv, neg_pos, neg_nonneg, or_true] <;> assumption end Solution₁ section Existence /-! ### Existence of nontrivial solutions -/ variable {d : ℤ} open Set Real /-- If `d` is a positive integer that is not a square, then there is a nontrivial solution to the Pell equation `x^2 - dy^2 = 1`. -/ theorem exists_of_not_isSquare (h₀ : 0 < d) (hd : ¬IsSquare d) : ∃ x y : ℤ, x ^ 2 - d y ^ 2 = 1 ∧ y ≠ 0 := by let ξ : ℝ := √d have hξ : Irrational ξ := by refine irrational_nrt_of_notint_nrt 2 d (sq_sqrt <\| Int.cast_nonneg.mpr h₀.le) ?_ two_pos rintro ⟨x, hx⟩ refine hd ⟨x, @Int.cast_injective ℝ _ _ d (x * x) ?_⟩ rw [← sq_sqrt <\| Int.cast_nonneg.mpr h₀.le, Int.cast_mul, ← hx, sq] obtain ⟨M, hM₁⟩ := exists_int_gt (2 * \|ξ\| + 1) have hM : {q : ℚ \| \|q.1 ^ 2 - d * (q.2 : ℤ) ^ 2\| < M}.Infinite := by refine Infinite.mono (fun q h => ?_) (infinite_rat_abs_sub_lt_one_div_den_sq_of_irrational hξ) have h0 : 0 < (q.2 : ℝ) ^ 2 := pow_pos (Nat.cast_pos.mpr q.pos) 2 have h1 : (q.num : ℝ) / (q.den : ℝ) = q := mod_cast q.num_div_den rw [mem_setOf, abs_sub_comm, ← @Int.cast_lt ℝ, ← div_lt_div_iff_of_pos_right (abs_pos_of_pos h0)] push_cast rw [← abs_div, abs_sq, sub_div, mul_div_cancel_right₀ _ h0.ne', ← div_pow, h1, ← sq_sqrt (Int.cast_pos.mpr h₀).le, sq_sub_sq, abs_mul, ← mul_one_div] refine mul_lt_mul'' (((abs_add ξ q).trans ?_).trans_lt hM₁) h (abs_nonneg _) (abs_nonneg _) rw [two_mul, add_assoc, add_le_add_iff_left, ← sub_le_iff_le_add'] rw [mem_setOf, abs_sub_comm] at h refine (abs_sub_abs_le_abs_sub (q : ℝ) ξ).trans (h.le.trans ?_) rw [div_le_one h0, one_le_sq_iff_one_le_abs, Nat.abs_cast, Nat.one_le_cast] exact q.pos obtain ⟨m, hm⟩ : ∃ m : ℤ, {q : ℚ \| q.1 ^ 2 - d * (q.den : ℤ) ^ 2 = m}.Infinite := by contrapose! hM simp only [not_infinite] at hM ⊢ refine (congr_arg _ (ext fun x => ?_)).mp (Finite.biUnion (finite_Ioo (-M) M) fun m _ => hM m) simp only [abs_lt, mem_setOf, mem_Ioo, mem_iUnion, exists_prop, exists_eq_right'] have hm₀ : m ≠ 0 := by rintro rfl obtain ⟨q, hq⟩ := hm.nonempty rw [mem_setOf, sub_eq_zero, mul_comm] at hq obtain ⟨a, ha⟩ := (Int.pow_dvd_pow_iff two_ne_zero).mp ⟨d, hq⟩ rw [ha, mul_pow, mul_right_inj' (pow_pos (Int.natCast_pos.mpr q.pos) 2).ne'] at hq exact hd ⟨a, sq a ▸ hq.symm⟩ haveI := neZero_iff.mpr (Int.natAbs_ne_zero.mpr hm₀) let f : ℚ → ZMod m.natAbs × ZMod m.natAbs := fun q => (q.num, q.den) obtain ⟨q₁, h₁ : q₁.num ^ 2 - d * (q₁.den : ℤ) ^ 2 = m, q₂, h₂ : q₂.num ^ 2 - d * (q₂.den : ℤ) ^ 2 = m, hne, hqf⟩ := hm.exists_ne_map_eq_of_mapsTo (mapsTo_univ f _) finite_univ obtain ⟨hq1 : (q₁.num : ZMod m.natAbs) = q₂.num, hq2 : (q₁.den : ZMod m.natAbs) = q₂.den⟩ := Prod.ext_iff.mp hqf have hd₁ : m ∣ q₁.num * q₂.num - d * (q₁.den * q₂.den) := by rw [← Int.natAbs_dvd, ← ZMod.intCast_zmod_eq_zero_iff_dvd] push_cast rw [hq1, hq2, ← sq, ← sq] norm_cast rw [ZMod.intCast_zmod_eq_zero_iff_dvd, Int.natAbs_dvd, Nat.cast_pow, ← h₂] have hd₂ : m ∣ q₁.num * q₂.den - q₂.num * q₁.den := by rw [← Int.natAbs_dvd, ← ZMod.intCast_eq_intCast_iff_dvd_sub] push_cast rw [hq1, hq2] replace hm₀ : (m : ℚ) ≠ 0 := Int.cast_ne_zero.mpr hm₀ refine ⟨(q₁.num * q₂.num - d * (q₁.den * q₂.den)) / m, (q₁.num * q₂.den - q₂.num * q₁.den) / m, ?_, ?_⟩ · qify [hd₁, hd₂] field_simp [hm₀] norm_cast conv_rhs => rw [sq] congr · rw [← h₁] · rw [← h₂] push_cast ring · qify [hd₂] refine div_ne_zero_iff.mpr ⟨?_, hm₀⟩ exact mod_cast mt sub_eq_zero.mp (mt Rat.eq_iff_mul_eq_mul.mpr hne) /-- If `d` is a positive integer, then there is a nontrivial solution to the Pell equation `x^2 - dy^2 = 1` if and only if `d` is not a square. -/ theorem exists_iff_not_isSquare (h₀ : 0 < d) : (∃ x y : ℤ, x ^ 2 - d y ^ 2 = 1 ∧ y ≠ 0) ↔ ¬IsSquare d := by refine ⟨?_, exists_of_not_isSquare h₀⟩ rintro ⟨x, y, hxy, hy⟩ ⟨a, rfl⟩ rw [← sq, ← mul_pow, sq_sub_sq] at hxy simpa [hy, mul_self_pos.mp h₀, sub_eq_add_neg, eq_neg_self_iff] using Int.eq_of_mul_eq_one hxy namespace Solution₁ /-- If `d` is a positive integer that is not a square, then there exists a nontrivial solution to the Pell equation `x^2 - dy^2 = 1`. -/ theorem exists_nontrivial_of_not_isSquare (h₀ : 0 < d) (hd : ¬IsSquare d) : ∃ a : Solution₁ d, a ≠ 1 ∧ a ≠ -1 := by obtain ⟨x, y, prop, hy⟩ := exists_of_not_isSquare h₀ hd refine ⟨mk x y prop, fun H => ?_, fun H => ?_⟩ <;> apply_fun Solution₁.y at H <;> simp [hy] at H /-- If `d` is a positive integer that is not a square, then there exists a solution to the Pell equation `x^2 - dy^2 = 1` with `x > 1` and `y > 0`. -/ theorem exists_pos_of_not_isSquare (h₀ : 0 < d) (hd : ¬IsSquare d) : ∃ a : Solution₁ d, 1 < a.x ∧ 0 < a.y := by obtain ⟨x, y, h, hy⟩ := exists_of_not_isSquare h₀ hd refine ⟨mk \|x\| \|y\| (by rwa [sq_abs, sq_abs]), ?_, abs_pos.mpr hy⟩ rw [x_mk, ← one_lt_sq_iff_one_lt_abs, eq_add_of_sub_eq h, lt_add_iff_pos_right] exact mul_pos h₀ (sq_pos_of_ne_zero hy) end Solution₁ end Existence /-! ### Fundamental solutions We define the notion of a fundamental solution of Pell's equation and show that it exists and is unique (when `d` is positive and non-square) and generates the group of solutions up to sign. -/ variable {d : ℤ} /-- We define a solution to be fundamental if it has `x > 1` and `y > 0` and its `x` is the smallest possible among solutions with `x > 1`. -/ def IsFundamental (a : Solution₁ d) : Prop := 1 < a.x ∧ 0 < a.y ∧ ∀ {b : Solution₁ d}, 1 < b.x → a.x ≤ b.x namespace IsFundamental open Solution₁ /-- A fundamental solution has positive `x`. -/ theorem x_pos {a : Solution₁ d} (h : IsFundamental a) : 0 < a.x := zero_lt_one.trans h.1 /-- If a fundamental solution exists, then `d` must be positive. -/ theorem d_pos {a : Solution₁ d} (h : IsFundamental a) : 0 < d := d_pos_of_one_lt_x h.1 /-- If a fundamental solution exists, then `d` must be a non-square. -/ theorem d_nonsquare {a : Solution₁ d} (h : IsFundamental a) : ¬IsSquare d := d_nonsquare_of_one_lt_x h.1 /-- If there is a fundamental solution, it is unique. -/ theorem subsingleton {a b : Solution₁ d} (ha : IsFundamental a) (hb : IsFundamental b) : a = b := by have hx := le_antisymm (ha.2.2 hb.1) (hb.2.2 ha.1) refine Solution₁.ext hx ?_ have : d * a.y ^ 2 = d * b.y ^ 2 := by rw [a.prop_y, b.prop_y, hx] exact (sq_eq_sq₀ ha.2.1.le hb.2.1.le).mp (Int.eq_of_mul_eq_mul_left ha.d_pos.ne' this) /-- If `d` is positive and not a square, then a fundamental solution exists. -/ theorem exists_of_not_isSquare (h₀ : 0 < d) (hd : ¬IsSquare d) : ∃ a : Solution₁ d, IsFundamental a := by obtain ⟨a, ha₁, ha₂⟩ := exists_pos_of_not_isSquare h₀ hd -- convert to `x : ℕ` to be able to use `Nat.find` have P : ∃ x' : ℕ, 1 < x' ∧ ∃ y' : ℤ, 0 < y' ∧ (x' : ℤ) ^ 2 - d * y' ^ 2 = 1 := by have hax := a.prop lift a.x to ℕ using by positivity with ax norm_cast at ha₁ exact ⟨ax, ha₁, a.y, ha₂, hax⟩ classical -- to avoid having to show that the predicate is decidable let x₁ := Nat.find P obtain ⟨hx, y₁, hy₀, hy₁⟩ := Nat.find_spec P refine ⟨mk x₁ y₁ hy₁, by rw [x_mk]; exact mod_cast hx, hy₀, fun {b} hb => ?_⟩ rw [x_mk] have hb' := (Int.toNat_of_nonneg <\| zero_le_one.trans hb.le).symm have hb'' := hb rw [hb'] at hb ⊢ norm_cast at hb ⊢ refine Nat.find_min' P ⟨hb, \|b.y\|, abs_pos.mpr <\| y_ne_zero_of_one_lt_x hb'', ?_⟩ rw [← hb', sq_abs] exact b.prop /-- The map sending an integer `n` to the `y`-coordinate of `a^n` for a fundamental solution `a` is stritcly increasing. -/ theorem y_strictMono {a : Solution₁ d} (h : IsFundamental a) : StrictMono fun n : ℤ => (a ^ n).y := by have H : ∀ n : ℤ, 0 ≤ n → (a ^ n).y < (a ^ (n + 1)).y := by intro n hn rw [← sub_pos, zpow_add, zpow_one, y_mul, add_sub_assoc] rw [show (a ^ n).y * a.x - (a ^ n).y = (a ^ n).y * (a.x - 1) by ring] refine add_pos_of_pos_of_nonneg (mul_pos (x_zpow_pos h.x_pos _) h.2.1) (mul_nonneg ?_ (by rw [sub_nonneg]; exact h.1.le)) rcases hn.eq_or_lt with (rfl \| hn) · simp only [zpow_zero, y_one, le_refl] · exact (y_zpow_pos h.x_pos h.2.1 hn).le refine strictMono_int_of_lt_succ fun n => ?_ rcases le_or_lt 0 n with hn \| hn · exact H n hn · let m : ℤ := -n - 1 have hm : n = -m - 1 := by simp only [m, neg_sub, sub_neg_eq_add, add_tsub_cancel_left] rw [hm, sub_add_cancel, ← neg_add', zpow_neg, zpow_neg, y_inv, y_inv, neg_lt_neg_iff] exact H _ (by omega) /-- If `a` is a fundamental solution, then `(a^m).y < (a^n).y` if and only if `m < n`. -/ theorem zpow_y_lt_iff_lt {a : Solution₁ d} (h : IsFundamental a) (m n : ℤ) : (a ^ m).y < (a ^ n).y ↔ m < n := by refine ⟨fun H => ?_, fun H => h.y_strictMono H⟩ contrapose! H exact h.y_strictMono.monotone H /-- The `n`th power of a fundamental solution is trivial if and only if `n = 0`. -/ theorem zpow_eq_one_iff {a : Solution₁ d} (h : IsFundamental a) (n : ℤ) : a ^ n = 1 ↔ n = 0 := by rw [← zpow_zero a] exact ⟨fun H => h.y_strictMono.injective (congr_arg Solution₁.y H), fun H => H ▸ rfl⟩ /-- A power of a fundamental solution is never equal to the negative of a power of this fundamental solution. -/ theorem zpow_ne_neg_zpow {a : Solution₁ d} (h : IsFundamental a) {n n' : ℤ} : a ^ n ≠ -a ^ n' := by intro hf apply_fun Solution₁.x at hf have H := x_zpow_pos h.x_pos n rw [hf, x_neg, lt_neg, neg_zero] at H exact lt_irrefl _ ((x_zpow_pos h.x_pos n').trans H) /-- The `x`-coordinate of a fundamental solution is a lower bound for the `x`-coordinate of any positive solution. -/ theorem x_le_x {a₁ : Solution₁ d} (h : IsFundamental a₁) {a : Solution₁ d} (hax : 1 < a.x) : a₁.x ≤ a.x := h.2.2 hax /-- The `y`-coordinate of a fundamental solution is a lower bound for the `y`-coordinate of any positive solution. -/ theorem y_le_y {a₁ : Solution₁ d} (h : IsFundamental a₁) {a : Solution₁ d} (hax : 1 < a.x) (hay : 0 < a.y) : a₁.y ≤ a.y := by have H : d * (a₁.y ^ 2 - a.y ^ 2) = a₁.x ^ 2 - a.x ^ 2 := by rw [a.prop_x, a₁.prop_x]; ring rw [← abs_of_pos hay, ← abs_of_pos h.2.1, ← sq_le_sq, ← mul_le_mul_left h.d_pos, ← sub_nonpos, ← mul_sub, H, sub_nonpos, sq_le_sq, abs_of_pos (zero_lt_one.trans h.1), abs_of_pos (zero_lt_one.trans hax)] exact h.x_le_x hax -- helper lemma for the next three results theorem x_mul_y_le_y_mul_x {a₁ : Solution₁ d} (h : IsFundamental a₁) {a : Solution₁ d} (hax : 1 < a.x) (hay : 0 < a.y) : a.x * a₁.y ≤ a.y * a₁.x := by rw [← abs_of_pos <\| zero_lt_one.trans hax, ← abs_of_pos hay, ← abs_of_pos h.x_pos, ← abs_of_pos h.2.1, ← abs_mul, ← abs_mul, ← sq_le_sq, mul_pow, mul_pow, a.prop_x, a₁.prop_x, ← sub_nonneg] ring_nf rw [sub_nonneg, sq_le_sq, abs_of_pos hay, abs_of_pos h.2.1] exact h.y_le_y hax hay /-- If we multiply a positive solution with the inverse of a fundamental solution, the `y`-coordinate remains nonnegative. -/ theorem mul_inv_y_nonneg {a₁ : Solution₁ d} (h : IsFundamental a₁) {a : Solution₁ d} (hax : 1 < a.x) (hay : 0 < a.y) : 0 ≤ (a * a₁⁻¹).y := by simpa only [y_inv, mul_neg, y_mul, le_neg_add_iff_add_le, add_zero] using h.x_mul_y_le_y_mul_x hax hay /-- If we multiply a positive solution with the inverse of a fundamental solution, the `x`-coordinate stays positive. -/ theorem mul_inv_x_pos {a₁ : Solution₁ d} (h : IsFundamental a₁) {a : Solution₁ d} (hax : 1 < a.x) (hay : 0 < a.y) : 0 < (a * a₁⁻¹).x := by simp only [x_mul, x_inv, y_inv, mul_neg, lt_add_neg_iff_add_lt, zero_add] refine (mul_lt_mul_left <\| zero_lt_one.trans hax).mp ?_ rw [(by ring : a.x * (d * (a.y * a₁.y)) = d * a.y * (a.x * a₁.y))] refine ((mul_le_mul_left <\| mul_pos h.d_pos hay).mpr <\| x_mul_y_le_y_mul_x h hax hay).trans_lt ?_ rw [← mul_assoc, mul_assoc d, ← sq, a.prop_y, ← sub_pos] ring_nf exact zero_lt_one.trans h.1 /-- If we multiply a positive solution with the inverse of a fundamental solution,	the `x`-coordinate decreases. -/ theorem mul_inv_x_lt_x {a₁ : Solution₁ d} (h : IsFundamental a₁) {a : Solution₁ d} (hax : 1 < a.x) (hay : 0 < a.y) : (a * a₁⁻¹).x < a.x := by	Mathlib/NumberTheory/Pell.lean	572	574
/- Copyright (c) 2019 Gabriel Ebner. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Gabriel Ebner, Sébastien Gouëzel, Yury Kudryashov, Yuyang Zhao -/ import Mathlib.Analysis.Calculus.Deriv.Basic import Mathlib.Analysis.Calculus.FDeriv.Comp import Mathlib.Analysis.Calculus.FDeriv.RestrictScalars /-! # One-dimensional derivatives of compositions of functions In this file we prove the chain rule for the following cases: * `HasDerivAt.comp` etc: `f : 𝕜' → 𝕜'` composed with `g : 𝕜 → 𝕜'`; * `HasDerivAt.scomp` etc: `f : 𝕜' → E` composed with `g : 𝕜 → 𝕜'`; * `HasFDerivAt.comp_hasDerivAt` etc: `f : E → F` composed with `g : 𝕜 → E`; Here `𝕜` is the base normed field, `E` and `F` are normed spaces over `𝕜` and `𝕜'` is an algebra over `𝕜` (e.g., `𝕜'=𝕜` or `𝕜=ℝ`, `𝕜'=ℂ`). We also give versions with the `of_eq` suffix, which require an equality proof instead of definitional equality of the different points used in the composition. These versions are often more flexible to use. For a more detailed overview of one-dimensional derivatives in mathlib, see the module docstring of `analysis/calculus/deriv/basic`. ## Keywords derivative, chain rule -/ universe u v w open scoped Topology Filter ENNReal open Filter Asymptotics Set open ContinuousLinearMap (smulRight smulRight_one_eq_iff) variable {𝕜 : Type u} [NontriviallyNormedField 𝕜] variable {F : Type v} [NormedAddCommGroup F] [NormedSpace 𝕜 F] variable {E : Type w} [NormedAddCommGroup E] [NormedSpace 𝕜 E] variable {f : 𝕜 → F} variable {f' : F} variable {x : 𝕜} variable {s : Set 𝕜} variable {L : Filter 𝕜} section Composition /-! ### Derivative of the composition of a vector function and a scalar function We use `scomp` in lemmas on composition of vector valued and scalar valued functions, and `comp` in lemmas on composition of scalar valued functions, in analogy for `smul` and `mul` (and also because the `comp` version with the shorter name will show up much more often in applications). The formula for the derivative involves `smul` in `scomp` lemmas, which can be reduced to usual multiplication in `comp` lemmas. -/ /- For composition lemmas, we put x explicit to help the elaborator, as otherwise Lean tends to get confused since there are too many possibilities for composition -/ variable {𝕜' : Type} [NontriviallyNormedField 𝕜'] [NormedAlgebra 𝕜 𝕜'] [NormedSpace 𝕜' F] [IsScalarTower 𝕜 𝕜' F] {s' t' : Set 𝕜'} {h : 𝕜 → 𝕜'} {h₂ : 𝕜' → 𝕜'} {h' h₂' : 𝕜'} {g₁ : 𝕜' → F} {g₁' : F} {L' : Filter 𝕜'} {y : 𝕜'} (x) theorem HasDerivAtFilter.scomp (hg : HasDerivAtFilter g₁ g₁' (h x) L') (hh : HasDerivAtFilter h h' x L) (hL : Tendsto h L L') : HasDerivAtFilter (g₁ ∘ h) (h' • g₁') x L := by simpa using ((hg.restrictScalars 𝕜).comp x hh hL).hasDerivAtFilter theorem HasDerivAtFilter.scomp_of_eq (hg : HasDerivAtFilter g₁ g₁' y L') (hh : HasDerivAtFilter h h' x L) (hy : y = h x) (hL : Tendsto h L L') : HasDerivAtFilter (g₁ ∘ h) (h' • g₁') x L := by rw [hy] at hg; exact hg.scomp x hh hL theorem HasDerivWithinAt.scomp_hasDerivAt (hg : HasDerivWithinAt g₁ g₁' s' (h x)) (hh : HasDerivAt h h' x) (hs : ∀ x, h x ∈ s') : HasDerivAt (g₁ ∘ h) (h' • g₁') x := hg.scomp x hh <\| tendsto_inf.2 ⟨hh.continuousAt, tendsto_principal.2 <\| Eventually.of_forall hs⟩ theorem HasDerivWithinAt.scomp_hasDerivAt_of_eq (hg : HasDerivWithinAt g₁ g₁' s' y) (hh : HasDerivAt h h' x) (hs : ∀ x, h x ∈ s') (hy : y = h x) : HasDerivAt (g₁ ∘ h) (h' • g₁') x := by rw [hy] at hg; exact hg.scomp_hasDerivAt x hh hs nonrec theorem HasDerivWithinAt.scomp (hg : HasDerivWithinAt g₁ g₁' t' (h x)) (hh : HasDerivWithinAt h h' s x) (hst : MapsTo h s t') : HasDerivWithinAt (g₁ ∘ h) (h' • g₁') s x := hg.scomp x hh <\| hh.continuousWithinAt.tendsto_nhdsWithin hst theorem HasDerivWithinAt.scomp_of_eq (hg : HasDerivWithinAt g₁ g₁' t' y) (hh : HasDerivWithinAt h h' s x) (hst : MapsTo h s t') (hy : y = h x) : HasDerivWithinAt (g₁ ∘ h) (h' • g₁') s x := by rw [hy] at hg; exact hg.scomp x hh hst /-- The chain rule. -/ nonrec theorem HasDerivAt.scomp (hg : HasDerivAt g₁ g₁' (h x)) (hh : HasDerivAt h h' x) : HasDerivAt (g₁ ∘ h) (h' • g₁') x := hg.scomp x hh hh.continuousAt /-- The chain rule. -/ theorem HasDerivAt.scomp_of_eq (hg : HasDerivAt g₁ g₁' y) (hh : HasDerivAt h h' x) (hy : y = h x) : HasDerivAt (g₁ ∘ h) (h' • g₁') x := by rw [hy] at hg; exact hg.scomp x hh theorem HasStrictDerivAt.scomp (hg : HasStrictDerivAt g₁ g₁' (h x)) (hh : HasStrictDerivAt h h' x) : HasStrictDerivAt (g₁ ∘ h) (h' • g₁') x := by simpa using ((hg.restrictScalars 𝕜).comp x hh).hasStrictDerivAt theorem HasStrictDerivAt.scomp_of_eq (hg : HasStrictDerivAt g₁ g₁' y) (hh : HasStrictDerivAt h h' x) (hy : y = h x) : HasStrictDerivAt (g₁ ∘ h) (h' • g₁') x := by rw [hy] at hg; exact hg.scomp x hh theorem HasDerivAt.scomp_hasDerivWithinAt (hg : HasDerivAt g₁ g₁' (h x)) (hh : HasDerivWithinAt h h' s x) : HasDerivWithinAt (g₁ ∘ h) (h' • g₁') s x := HasDerivWithinAt.scomp x hg.hasDerivWithinAt hh (mapsTo_univ _ _) theorem HasDerivAt.scomp_hasDerivWithinAt_of_eq (hg : HasDerivAt g₁ g₁' y) (hh : HasDerivWithinAt h h' s x) (hy : y = h x) : HasDerivWithinAt (g₁ ∘ h) (h' • g₁') s x := by rw [hy] at hg; exact hg.scomp_hasDerivWithinAt x hh theorem derivWithin.scomp (hg : DifferentiableWithinAt 𝕜' g₁ t' (h x)) (hh : DifferentiableWithinAt 𝕜 h s x) (hs : MapsTo h s t') : derivWithin (g₁ ∘ h) s x = derivWithin h s x • derivWithin g₁ t' (h x) := by by_cases hsx : UniqueDiffWithinAt 𝕜 s x · exact (HasDerivWithinAt.scomp x hg.hasDerivWithinAt hh.hasDerivWithinAt hs).derivWithin hsx · simp [derivWithin_zero_of_not_uniqueDiffWithinAt hsx] theorem derivWithin.scomp_of_eq (hg : DifferentiableWithinAt 𝕜' g₁ t' y) (hh : DifferentiableWithinAt 𝕜 h s x) (hs : MapsTo h s t') (hy : y = h x) : derivWithin (g₁ ∘ h) s x = derivWithin h s x • derivWithin g₁ t' (h x) := by rw [hy] at hg; exact derivWithin.scomp x hg hh hs theorem deriv.scomp (hg : DifferentiableAt 𝕜' g₁ (h x)) (hh : DifferentiableAt 𝕜 h x) : deriv (g₁ ∘ h) x = deriv h x • deriv g₁ (h x) := (HasDerivAt.scomp x hg.hasDerivAt hh.hasDerivAt).deriv theorem deriv.scomp_of_eq (hg : DifferentiableAt 𝕜' g₁ y) (hh : DifferentiableAt 𝕜 h x) (hy : y = h x) : deriv (g₁ ∘ h) x = deriv h x • deriv g₁ (h x) := by rw [hy] at hg; exact deriv.scomp x hg hh /-! ### Derivative of the composition of a scalar and vector functions -/ theorem HasDerivAtFilter.comp_hasFDerivAtFilter {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} (x) {L'' : Filter E} (hh₂ : HasDerivAtFilter h₂ h₂' (f x) L') (hf : HasFDerivAtFilter f f' x L'') (hL : Tendsto f L'' L') : HasFDerivAtFilter (h₂ ∘ f) (h₂' • f') x L'' := by convert (hh₂.restrictScalars 𝕜).comp x hf hL ext x simp [mul_comm] theorem HasDerivAtFilter.comp_hasFDerivAtFilter_of_eq {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} (x) {L'' : Filter E} (hh₂ : HasDerivAtFilter h₂ h₂' y L') (hf : HasFDerivAtFilter f f' x L'') (hL : Tendsto f L'' L') (hy : y = f x) : HasFDerivAtFilter (h₂ ∘ f) (h₂' • f') x L'' := by rw [hy] at hh₂; exact hh₂.comp_hasFDerivAtFilter x hf hL theorem HasStrictDerivAt.comp_hasStrictFDerivAt {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} (x) (hh : HasStrictDerivAt h₂ h₂' (f x)) (hf : HasStrictFDerivAt f f' x) : HasStrictFDerivAt (h₂ ∘ f) (h₂' • f') x := by rw [HasStrictDerivAt] at hh convert (hh.restrictScalars 𝕜).comp x hf ext x simp [mul_comm] theorem HasStrictDerivAt.comp_hasStrictFDerivAt_of_eq {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} (x) (hh : HasStrictDerivAt h₂ h₂' y) (hf : HasStrictFDerivAt f f' x) (hy : y = f x) : HasStrictFDerivAt (h₂ ∘ f) (h₂' • f') x := by rw [hy] at hh; exact hh.comp_hasStrictFDerivAt x hf theorem HasDerivAt.comp_hasFDerivAt {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} (x) (hh : HasDerivAt h₂ h₂' (f x)) (hf : HasFDerivAt f f' x) : HasFDerivAt (h₂ ∘ f) (h₂' • f') x := hh.comp_hasFDerivAtFilter x hf hf.continuousAt theorem HasDerivAt.comp_hasFDerivAt_of_eq {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} (x) (hh : HasDerivAt h₂ h₂' y) (hf : HasFDerivAt f f' x) (hy : y = f x) : HasFDerivAt (h₂ ∘ f) (h₂' • f') x := by rw [hy] at hh; exact hh.comp_hasFDerivAt x hf theorem HasDerivAt.comp_hasFDerivWithinAt {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} {s} (x) (hh : HasDerivAt h₂ h₂' (f x)) (hf : HasFDerivWithinAt f f' s x) : HasFDerivWithinAt (h₂ ∘ f) (h₂' • f') s x := hh.comp_hasFDerivAtFilter x hf hf.continuousWithinAt theorem HasDerivAt.comp_hasFDerivWithinAt_of_eq {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} {s} (x) (hh : HasDerivAt h₂ h₂' y) (hf : HasFDerivWithinAt f f' s x) (hy : y = f x) : HasFDerivWithinAt (h₂ ∘ f) (h₂' • f') s x := by rw [hy] at hh; exact hh.comp_hasFDerivWithinAt x hf theorem HasDerivWithinAt.comp_hasFDerivWithinAt {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} {s t} (x) (hh : HasDerivWithinAt h₂ h₂' t (f x)) (hf : HasFDerivWithinAt f f' s x) (hst : MapsTo f s t) : HasFDerivWithinAt (h₂ ∘ f) (h₂' • f') s x := hh.comp_hasFDerivAtFilter x hf <\| hf.continuousWithinAt.tendsto_nhdsWithin hst theorem HasDerivWithinAt.comp_hasFDerivWithinAt_of_eq {f : E → 𝕜'} {f' : E →L[𝕜] 𝕜'} {s t} (x) (hh : HasDerivWithinAt h₂ h₂' t y) (hf : HasFDerivWithinAt f f' s x) (hst : MapsTo f s t) (hy : y = f x) : HasFDerivWithinAt (h₂ ∘ f) (h₂' • f') s x := by rw [hy] at hh; exact hh.comp_hasFDerivWithinAt x hf hst /-! ### Derivative of the composition of two scalar functions -/ theorem HasDerivAtFilter.comp (hh₂ : HasDerivAtFilter h₂ h₂' (h x) L') (hh : HasDerivAtFilter h h' x L) (hL : Tendsto h L L') : HasDerivAtFilter (h₂ ∘ h) (h₂' h') x L := by rw [mul_comm] exact hh₂.scomp x hh hL theorem HasDerivAtFilter.comp_of_eq (hh₂ : HasDerivAtFilter h₂ h₂' y L') (hh : HasDerivAtFilter h h' x L) (hL : Tendsto h L L') (hy : y = h x) : HasDerivAtFilter (h₂ ∘ h) (h₂' * h') x L := by rw [hy] at hh₂; exact hh₂.comp x hh hL theorem HasDerivWithinAt.comp (hh₂ : HasDerivWithinAt h₂ h₂' s' (h x)) (hh : HasDerivWithinAt h h' s x) (hst : MapsTo h s s') : HasDerivWithinAt (h₂ ∘ h) (h₂' * h') s x := by rw [mul_comm] exact hh₂.scomp x hh hst theorem HasDerivWithinAt.comp_of_eq (hh₂ : HasDerivWithinAt h₂ h₂' s' y) (hh : HasDerivWithinAt h h' s x) (hst : MapsTo h s s') (hy : y = h x) : HasDerivWithinAt (h₂ ∘ h) (h₂' * h') s x := by rw [hy] at hh₂; exact hh₂.comp x hh hst /-- The chain rule. Note that the function `h₂` is a function on an algebra. If you are looking for the chain rule with `h₂` taking values in a vector space, use `HasDerivAt.scomp`. -/ nonrec theorem HasDerivAt.comp (hh₂ : HasDerivAt h₂ h₂' (h x)) (hh : HasDerivAt h h' x) : HasDerivAt (h₂ ∘ h) (h₂' * h') x := hh₂.comp x hh hh.continuousAt /-- The chain rule. Note that the function `h₂` is a function on an algebra. If you are looking for the chain rule with `h₂` taking values in a vector space, use `HasDerivAt.scomp_of_eq`. -/ theorem HasDerivAt.comp_of_eq (hh₂ : HasDerivAt h₂ h₂' y) (hh : HasDerivAt h h' x) (hy : y = h x) : HasDerivAt (h₂ ∘ h) (h₂' * h') x := by rw [hy] at hh₂; exact hh₂.comp x hh theorem HasStrictDerivAt.comp (hh₂ : HasStrictDerivAt h₂ h₂' (h x)) (hh : HasStrictDerivAt h h' x) : HasStrictDerivAt (h₂ ∘ h) (h₂' * h') x := by rw [mul_comm] exact hh₂.scomp x hh theorem HasStrictDerivAt.comp_of_eq (hh₂ : HasStrictDerivAt h₂ h₂' y) (hh : HasStrictDerivAt h h' x) (hy : y = h x) : HasStrictDerivAt (h₂ ∘ h) (h₂' * h') x := by rw [hy] at hh₂; exact hh₂.comp x hh theorem HasDerivAt.comp_hasDerivWithinAt (hh₂ : HasDerivAt h₂ h₂' (h x)) (hh : HasDerivWithinAt h h' s x) : HasDerivWithinAt (h₂ ∘ h) (h₂' * h') s x := hh₂.hasDerivWithinAt.comp x hh (mapsTo_univ _ _) theorem HasDerivAt.comp_hasDerivWithinAt_of_eq (hh₂ : HasDerivAt h₂ h₂' y) (hh : HasDerivWithinAt h h' s x) (hy : y = h x) : HasDerivWithinAt (h₂ ∘ h) (h₂' * h') s x := by rw [hy] at hh₂; exact hh₂.comp_hasDerivWithinAt x hh theorem derivWithin_comp (hh₂ : DifferentiableWithinAt 𝕜' h₂ s' (h x)) (hh : DifferentiableWithinAt 𝕜 h s x) (hs : MapsTo h s s') : derivWithin (h₂ ∘ h) s x = derivWithin h₂ s' (h x) * derivWithin h s x := by by_cases hsx : UniqueDiffWithinAt 𝕜 s x · exact (hh₂.hasDerivWithinAt.comp x hh.hasDerivWithinAt hs).derivWithin hsx · simp [derivWithin_zero_of_not_uniqueDiffWithinAt hsx] @[deprecated (since := "2024-10-31")] alias derivWithin.comp := derivWithin_comp theorem derivWithin_comp_of_eq (hh₂ : DifferentiableWithinAt 𝕜' h₂ s' y) (hh : DifferentiableWithinAt 𝕜 h s x) (hs : MapsTo h s s') (hy : h x = y) : derivWithin (h₂ ∘ h) s x = derivWithin h₂ s' (h x) * derivWithin h s x := by subst hy; exact derivWithin_comp x hh₂ hh hs @[deprecated (since := "2024-10-31")] alias derivWithin.comp_of_eq := derivWithin_comp_of_eq theorem deriv_comp (hh₂ : DifferentiableAt 𝕜' h₂ (h x)) (hh : DifferentiableAt 𝕜 h x) : deriv (h₂ ∘ h) x = deriv h₂ (h x) * deriv h x := (hh₂.hasDerivAt.comp x hh.hasDerivAt).deriv @[deprecated (since := "2024-10-31")] alias deriv.comp := deriv_comp theorem deriv_comp_of_eq (hh₂ : DifferentiableAt 𝕜' h₂ y) (hh : DifferentiableAt 𝕜 h x) (hy : h x = y) : deriv (h₂ ∘ h) x = deriv h₂ (h x) * deriv h x := by subst hy; exact deriv_comp x hh₂ hh @[deprecated (since := "2024-10-31")] alias deriv.comp_of_eq := deriv_comp_of_eq protected nonrec theorem HasDerivAtFilter.iterate {f : 𝕜 → 𝕜} {f' : 𝕜} (hf : HasDerivAtFilter f f' x L) (hL : Tendsto f L L) (hx : f x = x) (n : ℕ) : HasDerivAtFilter f^[n] (f' ^ n) x L := by have := hf.iterate hL hx n rwa [ContinuousLinearMap.smulRight_one_pow] at this protected nonrec theorem HasDerivAt.iterate {f : 𝕜 → 𝕜} {f' : 𝕜} (hf : HasDerivAt f f' x) (hx : f x = x) (n : ℕ) : HasDerivAt f^[n] (f' ^ n) x := hf.iterate _ (have := hf.tendsto_nhds le_rfl; by rwa [hx] at this) hx n protected theorem HasDerivWithinAt.iterate {f : 𝕜 → 𝕜} {f' : 𝕜} (hf : HasDerivWithinAt f f' s x) (hx : f x = x) (hs : MapsTo f s s) (n : ℕ) : HasDerivWithinAt f^[n] (f' ^ n) s x := by have := HasFDerivWithinAt.iterate hf hx hs n rwa [ContinuousLinearMap.smulRight_one_pow] at this protected nonrec theorem HasStrictDerivAt.iterate {f : 𝕜 → 𝕜} {f' : 𝕜} (hf : HasStrictDerivAt f f' x) (hx : f x = x) (n : ℕ) : HasStrictDerivAt f^[n] (f' ^ n) x := by have := hf.iterate hx n rwa [ContinuousLinearMap.smulRight_one_pow] at this end Composition section CompositionVector /-! ### Derivative of the composition of a function between vector spaces and a function on `𝕜` -/ open ContinuousLinearMap variable {l : F → E} {l' : F →L[𝕜] E} {y : F} variable (x) /-- The composition `l ∘ f` where `l : F → E` and `f : 𝕜 → F`, has a derivative within a set equal to the Fréchet derivative of `l` applied to the derivative of `f`. -/ theorem HasFDerivWithinAt.comp_hasDerivWithinAt {t : Set F} (hl : HasFDerivWithinAt l l' t (f x)) (hf : HasDerivWithinAt f f' s x) (hst : MapsTo f s t) : HasDerivWithinAt (l ∘ f) (l' f') s x := by simpa only [one_apply, one_smul, smulRight_apply, coe_comp', (· ∘ ·)] using (hl.comp x hf.hasFDerivWithinAt hst).hasDerivWithinAt /-- The composition `l ∘ f` where `l : F → E` and `f : 𝕜 → F`, has a derivative within a set equal to the Fréchet derivative of `l` applied to the derivative of `f`. -/ theorem HasFDerivWithinAt.comp_hasDerivWithinAt_of_eq {t : Set F} (hl : HasFDerivWithinAt l l' t y) (hf : HasDerivWithinAt f f' s x) (hst : MapsTo f s t) (hy : y = f x) : HasDerivWithinAt (l ∘ f) (l' f') s x := by rw [hy] at hl; exact hl.comp_hasDerivWithinAt x hf hst theorem HasFDerivAt.comp_hasDerivWithinAt (hl : HasFDerivAt l l' (f x)) (hf : HasDerivWithinAt f f' s x) : HasDerivWithinAt (l ∘ f) (l' f') s x := hl.hasFDerivWithinAt.comp_hasDerivWithinAt x hf (mapsTo_univ _ _) theorem HasFDerivAt.comp_hasDerivWithinAt_of_eq (hl : HasFDerivAt l l' y) (hf : HasDerivWithinAt f f' s x) (hy : y = f x) : HasDerivWithinAt (l ∘ f) (l' f') s x := by rw [hy] at hl; exact hl.comp_hasDerivWithinAt x hf /-- The composition `l ∘ f` where `l : F → E` and `f : 𝕜 → F`, has a derivative equal to the Fréchet derivative of `l` applied to the derivative of `f`. -/ theorem HasFDerivAt.comp_hasDerivAt (hl : HasFDerivAt l l' (f x)) (hf : HasDerivAt f f' x) : HasDerivAt (l ∘ f) (l' f') x := hasDerivWithinAt_univ.mp <\| hl.comp_hasDerivWithinAt x hf.hasDerivWithinAt /-- The composition `l ∘ f` where `l : F → E` and `f : 𝕜 → F`, has a derivative equal to the Fréchet derivative of `l` applied to the derivative of `f`. -/ theorem HasFDerivAt.comp_hasDerivAt_of_eq (hl : HasFDerivAt l l' y) (hf : HasDerivAt f f' x) (hy : y = f x) : HasDerivAt (l ∘ f) (l' f') x := by rw [hy] at hl; exact hl.comp_hasDerivAt x hf	theorem HasStrictFDerivAt.comp_hasStrictDerivAt (hl : HasStrictFDerivAt l l' (f x)) (hf : HasStrictDerivAt f f' x) : HasStrictDerivAt (l ∘ f) (l' f') x := by simpa only [one_apply, one_smul, smulRight_apply, coe_comp', (· ∘ ·)] using	Mathlib/Analysis/Calculus/Deriv/Comp.lean	368	371
/- Copyright (c) 2019 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau -/ import Mathlib.Algebra.Algebra.Bilinear import Mathlib.Algebra.Algebra.Opposite import Mathlib.Algebra.Group.Pointwise.Finset.Basic import Mathlib.Algebra.Group.Pointwise.Set.BigOperators import Mathlib.Algebra.Module.Submodule.Pointwise import Mathlib.Algebra.Ring.NonZeroDivisors import Mathlib.Algebra.Ring.Submonoid.Pointwise import Mathlib.Data.Set.Semiring import Mathlib.GroupTheory.GroupAction.SubMulAction.Pointwise /-! # Multiplication and division of submodules of an algebra. An interface for multiplication and division of sub-R-modules of an R-algebra A is developed. ## Main definitions Let `R` be a commutative ring (or semiring) and let `A` be an `R`-algebra. * `1 : Submodule R A` : the R-submodule R of the R-algebra A * `Mul (Submodule R A)` : multiplication of two sub-R-modules M and N of A is defined to be the smallest submodule containing all the products `m * n`. * `Div (Submodule R A)` : `I / J` is defined to be the submodule consisting of all `a : A` such that `a • J ⊆ I` It is proved that `Submodule R A` is a semiring, and also an algebra over `Set A`. Additionally, in the `Pointwise` locale we promote `Submodule.pointwiseDistribMulAction` to a `MulSemiringAction` as `Submodule.pointwiseMulSemiringAction`. When `R` is not necessarily commutative, and `A` is merely a `R`-module with a ring structure such that `IsScalarTower R A A` holds (equivalent to the data of a ring homomorphism `R →+* A` by `ringHomEquivModuleIsScalarTower`), we can still define `1 : Submodule R A` and `Mul (Submodule R A)`, but `1` is only a left identity, not necessarily a right one. ## Tags multiplication of submodules, division of submodules, submodule semiring -/ universe uι u v open Algebra Set MulOpposite open Pointwise namespace SubMulAction variable {R : Type u} {A : Type v} [CommSemiring R] [Semiring A] [Algebra R A] theorem algebraMap_mem (r : R) : algebraMap R A r ∈ (1 : SubMulAction R A) := ⟨r, (algebraMap_eq_smul_one r).symm⟩ theorem mem_one' {x : A} : x ∈ (1 : SubMulAction R A) ↔ ∃ y, algebraMap R A y = x := exists_congr fun r => by rw [algebraMap_eq_smul_one] end SubMulAction namespace Submodule section Module variable {R : Type u} [Semiring R] {A : Type v} [Semiring A] [Module R A] -- TODO: Why is this in a file about `Algebra`? -- TODO: potentially change this back to `LinearMap.range (Algebra.linearMap R A)` -- once a version of `Algebra` without the `commutes'` field is introduced. -- See issue https://github.com/leanprover-community/mathlib4/issues/18110. /-- `1 : Submodule R A` is the submodule `R ∙ 1` of `A`. -/ instance one : One (Submodule R A) := ⟨LinearMap.range (LinearMap.toSpanSingleton R A 1)⟩ theorem one_eq_span : (1 : Submodule R A) = R ∙ 1 := (LinearMap.span_singleton_eq_range _ _ _).symm theorem le_one_toAddSubmonoid : 1 ≤ (1 : Submodule R A).toAddSubmonoid := by rintro x ⟨n, rfl⟩ exact ⟨n, show (n : R) • (1 : A) = n by rw [Nat.cast_smul_eq_nsmul, nsmul_one]⟩ @[simp] theorem toSubMulAction_one : (1 : Submodule R A).toSubMulAction = 1 := SetLike.ext fun _ ↦ by rw [one_eq_span, SubMulAction.mem_one]; exact mem_span_singleton theorem one_eq_span_one_set : (1 : Submodule R A) = span R 1 := one_eq_span @[simp] theorem one_le {P : Submodule R A} : (1 : Submodule R A) ≤ P ↔ (1 : A) ∈ P := by simp [one_eq_span] variable {M : Type*} [AddCommMonoid M] [Module R M] [Module A M] [IsScalarTower R A M] instance : SMul (Submodule R A) (Submodule R M) where smul A' M' := { __ := A'.toAddSubmonoid • M'.toAddSubmonoid smul_mem' := fun r m hm ↦ AddSubmonoid.smul_induction_on hm (fun a ha m hm ↦ by rw [← smul_assoc]; exact AddSubmonoid.smul_mem_smul (A'.smul_mem r ha) hm) fun m₁ m₂ h₁ h₂ ↦ by rw [smul_add]; exact (A'.1 • M'.1).add_mem h₁ h₂ } section variable {I J : Submodule R A} {N P : Submodule R M} theorem smul_toAddSubmonoid : (I • N).toAddSubmonoid = I.toAddSubmonoid • N.toAddSubmonoid := rfl theorem smul_mem_smul {r} {n} (hr : r ∈ I) (hn : n ∈ N) : r • n ∈ I • N := AddSubmonoid.smul_mem_smul hr hn theorem smul_le : I • N ≤ P ↔ ∀ r ∈ I, ∀ n ∈ N, r • n ∈ P := AddSubmonoid.smul_le @[simp, norm_cast] lemma coe_set_smul : (I : Set A) • N = I • N := set_smul_eq_of_le _ _ _ (fun _ _ hr hx ↦ smul_mem_smul hr hx) (smul_le.mpr fun _ hr _ hx ↦ mem_set_smul_of_mem_mem hr hx) @[elab_as_elim] theorem smul_induction_on {p : M → Prop} {x} (H : x ∈ I • N) (smul : ∀ r ∈ I, ∀ n ∈ N, p (r • n)) (add : ∀ x y, p x → p y → p (x + y)) : p x := AddSubmonoid.smul_induction_on H smul add /-- Dependent version of `Submodule.smul_induction_on`. -/ @[elab_as_elim] theorem smul_induction_on' {x : M} (hx : x ∈ I • N) {p : ∀ x, x ∈ I • N → Prop} (smul : ∀ (r : A) (hr : r ∈ I) (n : M) (hn : n ∈ N), p (r • n) (smul_mem_smul hr hn)) (add : ∀ x hx y hy, p x hx → p y hy → p (x + y) (add_mem ‹_› ‹_›)) : p x hx := by refine Exists.elim ?_ fun (h : x ∈ I • N) (H : p x h) ↦ H exact smul_induction_on hx (fun a ha x hx ↦ ⟨_, smul _ ha _ hx⟩) fun x y ⟨_, hx⟩ ⟨_, hy⟩ ↦ ⟨_, add _ _ _ _ hx hy⟩ theorem smul_mono (hij : I ≤ J) (hnp : N ≤ P) : I • N ≤ J • P := AddSubmonoid.smul_le_smul hij hnp theorem smul_mono_left (h : I ≤ J) : I • N ≤ J • N := smul_mono h le_rfl instance : CovariantClass (Submodule R A) (Submodule R M) HSMul.hSMul LE.le := ⟨fun _ _ => smul_mono le_rfl⟩ variable (I J N P)	@[simp] theorem smul_bot : I • (⊥ : Submodule R M) = ⊥ :=	Mathlib/Algebra/Algebra/Operations.lean	149	151
/- Copyright (c) 2021 Kalle Kytölä. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kalle Kytölä -/ import Mathlib.MeasureTheory.Integral.Bochner.ContinuousLinearMap import Mathlib.MeasureTheory.Measure.HasOuterApproxClosed import Mathlib.MeasureTheory.Measure.Prod import Mathlib.Topology.Algebra.Module.WeakDual /-! # Finite measures This file defines the type of finite measures on a given measurable space. When the underlying space has a topology and the measurable space structure (sigma algebra) is finer than the Borel sigma algebra, then the type of finite measures is equipped with the topology of weak convergence of measures. The topology of weak convergence is the coarsest topology w.r.t. which for every bounded continuous `ℝ≥0`-valued function `f`, the integration of `f` against the measure is continuous. ## Main definitions The main definitions are * `MeasureTheory.FiniteMeasure Ω`: The type of finite measures on `Ω` with the topology of weak convergence of measures. * `MeasureTheory.FiniteMeasure.toWeakDualBCNN : FiniteMeasure Ω → (WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0))`: Interpret a finite measure as a continuous linear functional on the space of bounded continuous nonnegative functions on `Ω`. This is used for the definition of the topology of weak convergence. * `MeasureTheory.FiniteMeasure.map`: The push-forward `f* μ` of a finite measure `μ` on `Ω` along a measurable function `f : Ω → Ω'`. * `MeasureTheory.FiniteMeasure.mapCLM`: The push-forward along a given continuous `f : Ω → Ω'` as a continuous linear map `f* : FiniteMeasure Ω →L[ℝ≥0] FiniteMeasure Ω'`. ## Main results * Finite measures `μ` on `Ω` give rise to continuous linear functionals on the space of bounded continuous nonnegative functions on `Ω` via integration: `MeasureTheory.FiniteMeasure.toWeakDualBCNN : FiniteMeasure Ω → (WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0))` * `MeasureTheory.FiniteMeasure.tendsto_iff_forall_integral_tendsto`: Convergence of finite measures is characterized by the convergence of integrals of all bounded continuous functions. This shows that the chosen definition of topology coincides with the common textbook definition of weak convergence of measures. A similar characterization by the convergence of integrals (in the `MeasureTheory.lintegral` sense) of all bounded continuous nonnegative functions is `MeasureTheory.FiniteMeasure.tendsto_iff_forall_lintegral_tendsto`. * `MeasureTheory.FiniteMeasure.continuous_map`: For a continuous function `f : Ω → Ω'`, the push-forward of finite measures `f* : FiniteMeasure Ω → FiniteMeasure Ω'` is continuous. * `MeasureTheory.FiniteMeasure.t2Space`: The topology of weak convergence of finite Borel measures is Hausdorff on spaces where indicators of closed sets have continuous decreasing approximating sequences (in particular on any pseudo-metrizable spaces). ## Implementation notes The topology of weak convergence of finite Borel measures is defined using a mapping from `MeasureTheory.FiniteMeasure Ω` to `WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0)`, inheriting the topology from the latter. The implementation of `MeasureTheory.FiniteMeasure Ω` and is directly as a subtype of `MeasureTheory.Measure Ω`, and the coercion to a function is the composition `ENNReal.toNNReal` and the coercion to function of `MeasureTheory.Measure Ω`. Another alternative would have been to use a bijection with `MeasureTheory.VectorMeasure Ω ℝ≥0` as an intermediate step. Some considerations: * Potential advantages of using the `NNReal`-valued vector measure alternative: * The coercion to function would avoid need to compose with `ENNReal.toNNReal`, the `NNReal`-valued API could be more directly available. * Potential drawbacks of the vector measure alternative: * The coercion to function would lose monotonicity, as non-measurable sets would be defined to have measure 0. * No integration theory directly. E.g., the topology definition requires `MeasureTheory.lintegral` w.r.t. a coercion to `MeasureTheory.Measure Ω` in any case. ## References * [Billingsley, Convergence of probability measures][billingsley1999] ## Tags weak convergence of measures, finite measure -/ noncomputable section open BoundedContinuousFunction Filter MeasureTheory Set Topology open scoped ENNReal NNReal namespace MeasureTheory namespace FiniteMeasure section FiniteMeasure /-! ### Finite measures In this section we define the `Type` of `MeasureTheory.FiniteMeasure Ω`, when `Ω` is a measurable space. Finite measures on `Ω` are a module over `ℝ≥0`. If `Ω` is moreover a topological space and the sigma algebra on `Ω` is finer than the Borel sigma algebra (i.e. `[OpensMeasurableSpace Ω]`), then `MeasureTheory.FiniteMeasure Ω` is equipped with the topology of weak convergence of measures. This is implemented by defining a pairing of finite measures `μ` on `Ω` with continuous bounded nonnegative functions `f : Ω →ᵇ ℝ≥0` via integration, and using the associated weak topology (essentially the weak-star topology on the dual of `Ω →ᵇ ℝ≥0`). -/ variable {Ω : Type} [MeasurableSpace Ω] /-- Finite measures are defined as the subtype of measures that have the property of being finite measures (i.e., their total mass is finite). -/ def _root_.MeasureTheory.FiniteMeasure (Ω : Type) [MeasurableSpace Ω] : Type _ := { μ : Measure Ω // IsFiniteMeasure μ } /-- Coercion from `MeasureTheory.FiniteMeasure Ω` to `MeasureTheory.Measure Ω`. -/ @[coe] def toMeasure : FiniteMeasure Ω → Measure Ω := Subtype.val /-- A finite measure can be interpreted as a measure. -/ instance instCoe : Coe (FiniteMeasure Ω) (MeasureTheory.Measure Ω) := { coe := toMeasure } instance isFiniteMeasure (μ : FiniteMeasure Ω) : IsFiniteMeasure (μ : Measure Ω) := μ.prop @[simp] theorem val_eq_toMeasure (ν : FiniteMeasure Ω) : ν.val = (ν : Measure Ω) := rfl theorem toMeasure_injective : Function.Injective ((↑) : FiniteMeasure Ω → Measure Ω) := Subtype.coe_injective instance instFunLike : FunLike (FiniteMeasure Ω) (Set Ω) ℝ≥0 where coe μ s := ((μ : Measure Ω) s).toNNReal coe_injective' μ ν h := toMeasure_injective <\| Measure.ext fun s _ ↦ by simpa [ENNReal.toNNReal_eq_toNNReal_iff, measure_ne_top] using congr_fun h s lemma coeFn_def (μ : FiniteMeasure Ω) : μ = fun s ↦ ((μ : Measure Ω) s).toNNReal := rfl lemma coeFn_mk (μ : Measure Ω) (hμ) : DFunLike.coe (F := FiniteMeasure Ω) ⟨μ, hμ⟩ = fun s ↦ (μ s).toNNReal := rfl @[simp, norm_cast] lemma mk_apply (μ : Measure Ω) (hμ) (s : Set Ω) : DFunLike.coe (F := FiniteMeasure Ω) ⟨μ, hμ⟩ s = (μ s).toNNReal := rfl @[simp] theorem ennreal_coeFn_eq_coeFn_toMeasure (ν : FiniteMeasure Ω) (s : Set Ω) : (ν s : ℝ≥0∞) = (ν : Measure Ω) s := ENNReal.coe_toNNReal (measure_lt_top (↑ν) s).ne @[simp] theorem null_iff_toMeasure_null (ν : FiniteMeasure Ω) (s : Set Ω) : ν s = 0 ↔ (ν : Measure Ω) s = 0 := ⟨fun h ↦ by rw [← ennreal_coeFn_eq_coeFn_toMeasure, h, ENNReal.coe_zero], fun h ↦ congrArg ENNReal.toNNReal h⟩ theorem apply_mono (μ : FiniteMeasure Ω) {s₁ s₂ : Set Ω} (h : s₁ ⊆ s₂) : μ s₁ ≤ μ s₂ := ENNReal.toNNReal_mono (measure_ne_top _ s₂) ((μ : Measure Ω).mono h) /-- Continuity from below: the measure of the union of a sequence of (not necessarily measurable) sets is the limit of the measures of the partial unions. -/ protected lemma tendsto_measure_iUnion_accumulate {ι : Type} [Preorder ι] [IsCountablyGenerated (atTop : Filter ι)] {μ : FiniteMeasure Ω} {f : ι → Set Ω} : Tendsto (fun i ↦ μ (Accumulate f i)) atTop (𝓝 (μ (⋃ i, f i))) := by simpa [← ennreal_coeFn_eq_coeFn_toMeasure] using tendsto_measure_iUnion_accumulate (μ := μ.toMeasure) (ι := ι) /-- The (total) mass of a finite measure `μ` is `μ univ`, i.e., the cast to `NNReal` of `(μ : measure Ω) univ`. -/ def mass (μ : FiniteMeasure Ω) : ℝ≥0 := μ univ @[simp] theorem apply_le_mass (μ : FiniteMeasure Ω) (s : Set Ω) : μ s ≤ μ.mass := by simpa using apply_mono μ (subset_univ s) @[simp] theorem ennreal_mass {μ : FiniteMeasure Ω} : (μ.mass : ℝ≥0∞) = (μ : Measure Ω) univ := ennreal_coeFn_eq_coeFn_toMeasure μ Set.univ instance instZero : Zero (FiniteMeasure Ω) where zero := ⟨0, MeasureTheory.isFiniteMeasureZero⟩ @[simp, norm_cast] lemma coeFn_zero : ⇑(0 : FiniteMeasure Ω) = 0 := rfl @[simp] theorem zero_mass : (0 : FiniteMeasure Ω).mass = 0 := rfl @[simp] theorem mass_zero_iff (μ : FiniteMeasure Ω) : μ.mass = 0 ↔ μ = 0 := by refine ⟨fun μ_mass => ?_, fun hμ => by simp only [hμ, zero_mass]⟩ apply toMeasure_injective apply Measure.measure_univ_eq_zero.mp rwa [← ennreal_mass, ENNReal.coe_eq_zero] theorem mass_nonzero_iff (μ : FiniteMeasure Ω) : μ.mass ≠ 0 ↔ μ ≠ 0 := not_iff_not.mpr <\| FiniteMeasure.mass_zero_iff μ @[ext] theorem eq_of_forall_toMeasure_apply_eq (μ ν : FiniteMeasure Ω) (h : ∀ s : Set Ω, MeasurableSet s → (μ : Measure Ω) s = (ν : Measure Ω) s) : μ = ν := by apply Subtype.ext ext1 s s_mble exact h s s_mble theorem eq_of_forall_apply_eq (μ ν : FiniteMeasure Ω) (h : ∀ s : Set Ω, MeasurableSet s → μ s = ν s) : μ = ν := by ext1 s s_mble simpa [ennreal_coeFn_eq_coeFn_toMeasure] using congr_arg ((↑) : ℝ≥0 → ℝ≥0∞) (h s s_mble) instance instInhabited : Inhabited (FiniteMeasure Ω) := ⟨0⟩ instance instAdd : Add (FiniteMeasure Ω) where add μ ν := ⟨μ + ν, MeasureTheory.isFiniteMeasureAdd⟩ variable {R : Type} [SMul R ℝ≥0] [SMul R ℝ≥0∞] [IsScalarTower R ℝ≥0 ℝ≥0∞] [IsScalarTower R ℝ≥0∞ ℝ≥0∞] instance instSMul : SMul R (FiniteMeasure Ω) where smul (c : R) μ := ⟨c • (μ : Measure Ω), MeasureTheory.isFiniteMeasureSMulOfNNRealTower⟩ @[simp, norm_cast] theorem toMeasure_zero : ((↑) : FiniteMeasure Ω → Measure Ω) 0 = 0 := rfl @[norm_cast] theorem toMeasure_add (μ ν : FiniteMeasure Ω) : ↑(μ + ν) = (↑μ + ↑ν : Measure Ω) := rfl @[simp, norm_cast] theorem toMeasure_smul (c : R) (μ : FiniteMeasure Ω) : ↑(c • μ) = c • (μ : Measure Ω) := rfl @[simp, norm_cast] theorem coeFn_add (μ ν : FiniteMeasure Ω) : (⇑(μ + ν) : Set Ω → ℝ≥0) = (⇑μ + ⇑ν : Set Ω → ℝ≥0) := by funext simp only [Pi.add_apply, ← ENNReal.coe_inj, ne_eq, ennreal_coeFn_eq_coeFn_toMeasure, ENNReal.coe_add] norm_cast @[simp, norm_cast] theorem coeFn_smul [IsScalarTower R ℝ≥0 ℝ≥0] (c : R) (μ : FiniteMeasure Ω) : (⇑(c • μ) : Set Ω → ℝ≥0) = c • (⇑μ : Set Ω → ℝ≥0) := by funext; simp [← ENNReal.coe_inj, ENNReal.coe_smul] instance instAddCommMonoid : AddCommMonoid (FiniteMeasure Ω) := toMeasure_injective.addCommMonoid _ toMeasure_zero toMeasure_add fun _ _ ↦ toMeasure_smul _ _ /-- Coercion is an `AddMonoidHom`. -/ @[simps] def toMeasureAddMonoidHom : FiniteMeasure Ω →+ Measure Ω where toFun := (↑) map_zero' := toMeasure_zero map_add' := toMeasure_add instance {Ω : Type} [MeasurableSpace Ω] : Module ℝ≥0 (FiniteMeasure Ω) := Function.Injective.module _ toMeasureAddMonoidHom toMeasure_injective toMeasure_smul @[simp] theorem smul_apply [IsScalarTower R ℝ≥0 ℝ≥0] (c : R) (μ : FiniteMeasure Ω) (s : Set Ω) : (c • μ) s = c • μ s := by rw [coeFn_smul, Pi.smul_apply] /-- Restrict a finite measure μ to a set A. -/ def restrict (μ : FiniteMeasure Ω) (A : Set Ω) : FiniteMeasure Ω where val := (μ : Measure Ω).restrict A property := MeasureTheory.isFiniteMeasureRestrict (μ : Measure Ω) A theorem restrict_measure_eq (μ : FiniteMeasure Ω) (A : Set Ω) : (μ.restrict A : Measure Ω) = (μ : Measure Ω).restrict A := rfl theorem restrict_apply_measure (μ : FiniteMeasure Ω) (A : Set Ω) {s : Set Ω} (s_mble : MeasurableSet s) : (μ.restrict A : Measure Ω) s = (μ : Measure Ω) (s ∩ A) := Measure.restrict_apply s_mble theorem restrict_apply (μ : FiniteMeasure Ω) (A : Set Ω) {s : Set Ω} (s_mble : MeasurableSet s) : (μ.restrict A) s = μ (s ∩ A) := by apply congr_arg ENNReal.toNNReal exact Measure.restrict_apply s_mble theorem restrict_mass (μ : FiniteMeasure Ω) (A : Set Ω) : (μ.restrict A).mass = μ A := by simp only [mass, restrict_apply μ A MeasurableSet.univ, univ_inter] theorem restrict_eq_zero_iff (μ : FiniteMeasure Ω) (A : Set Ω) : μ.restrict A = 0 ↔ μ A = 0 := by rw [← mass_zero_iff, restrict_mass] theorem restrict_nonzero_iff (μ : FiniteMeasure Ω) (A : Set Ω) : μ.restrict A ≠ 0 ↔ μ A ≠ 0 := by rw [← mass_nonzero_iff, restrict_mass] /-- The type of finite measures is a measurable space when equipped with the Giry monad. -/ instance : MeasurableSpace (FiniteMeasure Ω) := Subtype.instMeasurableSpace /-- The set of all finite measures is a measurable set in the Giry monad. -/ lemma measurableSet_isFiniteMeasure : MeasurableSet { μ : Measure Ω \| IsFiniteMeasure μ } := by suffices { μ : Measure Ω \| IsFiniteMeasure μ } = (fun μ => μ univ) ⁻¹' (Set.Ico 0 ∞) by rw [this] exact Measure.measurable_coe MeasurableSet.univ measurableSet_Ico ext μ simp only [mem_setOf_eq, mem_iUnion, mem_preimage, mem_Ico, zero_le, true_and, exists_const] exact isFiniteMeasure_iff μ /-- The monoidal product is a measurabule function from the product of finite measures over `α` and `β` into the type of finite measures over `α × β`. -/ theorem measurable_prod {α β : Type} [MeasurableSpace α] [MeasurableSpace β] : Measurable (fun (μ : FiniteMeasure α × FiniteMeasure β) ↦ μ.1.toMeasure.prod μ.2.toMeasure) := by have Heval {u v} (Hu : MeasurableSet u) (Hv : MeasurableSet v): Measurable fun a : (FiniteMeasure α × FiniteMeasure β) ↦ a.1.toMeasure u * a.2.toMeasure v := Measurable.mul ((Measure.measurable_coe Hu).comp (measurable_subtype_coe.comp measurable_fst)) ((Measure.measurable_coe Hv).comp (measurable_subtype_coe.comp measurable_snd)) apply Measurable.measure_of_isPiSystem generateFrom_prod.symm isPiSystem_prod _ · simp_rw [← Set.univ_prod_univ, Measure.prod_prod, Heval MeasurableSet.univ MeasurableSet.univ] simp only [mem_image2, mem_setOf_eq, forall_exists_index, and_imp] intros _ _ Hu _ Hv Heq simp_rw [← Heq, Measure.prod_prod, Heval Hu Hv] variable [TopologicalSpace Ω] /-- Two finite Borel measures are equal if the integrals of all non-negative bounded continuous functions with respect to both agree. -/ theorem ext_of_forall_lintegral_eq [HasOuterApproxClosed Ω] [BorelSpace Ω] {μ ν : FiniteMeasure Ω} (h : ∀ (f : Ω →ᵇ ℝ≥0), ∫⁻ x, f x ∂μ = ∫⁻ x, f x ∂ν) : μ = ν := by apply Subtype.ext change (μ : Measure Ω) = (ν : Measure Ω) exact ext_of_forall_lintegral_eq_of_IsFiniteMeasure h /-- Two finite Borel measures are equal if the integrals of all bounded continuous functions with respect to both agree. -/ theorem ext_of_forall_integral_eq [HasOuterApproxClosed Ω] [BorelSpace Ω] {μ ν : FiniteMeasure Ω} (h : ∀ (f : Ω →ᵇ ℝ), ∫ x, f x ∂μ = ∫ x, f x ∂ν) : μ = ν := by apply ext_of_forall_lintegral_eq intro f apply (ENNReal.toReal_eq_toReal_iff' (lintegral_lt_top_of_nnreal μ f).ne (lintegral_lt_top_of_nnreal ν f).ne).mp rw [toReal_lintegral_coe_eq_integral f μ, toReal_lintegral_coe_eq_integral f ν] exact h ⟨⟨fun x => (f x).toReal, Continuous.comp' NNReal.continuous_coe f.continuous⟩, f.map_bounded'⟩ /-- The pairing of a finite (Borel) measure `μ` with a nonnegative bounded continuous function is obtained by (Lebesgue) integrating the (test) function against the measure. This is `MeasureTheory.FiniteMeasure.testAgainstNN`. -/ def testAgainstNN (μ : FiniteMeasure Ω) (f : Ω →ᵇ ℝ≥0) : ℝ≥0 := (∫⁻ ω, f ω ∂(μ : Measure Ω)).toNNReal @[simp] theorem testAgainstNN_coe_eq {μ : FiniteMeasure Ω} {f : Ω →ᵇ ℝ≥0} : (μ.testAgainstNN f : ℝ≥0∞) = ∫⁻ ω, f ω ∂(μ : Measure Ω) := ENNReal.coe_toNNReal (f.lintegral_lt_top_of_nnreal _).ne theorem testAgainstNN_const (μ : FiniteMeasure Ω) (c : ℝ≥0) : μ.testAgainstNN (BoundedContinuousFunction.const Ω c) = c * μ.mass := by simp [← ENNReal.coe_inj] theorem testAgainstNN_mono (μ : FiniteMeasure Ω) {f g : Ω →ᵇ ℝ≥0} (f_le_g : (f : Ω → ℝ≥0) ≤ g) : μ.testAgainstNN f ≤ μ.testAgainstNN g := by simp only [← ENNReal.coe_le_coe, testAgainstNN_coe_eq] gcongr apply f_le_g @[simp] theorem testAgainstNN_zero (μ : FiniteMeasure Ω) : μ.testAgainstNN 0 = 0 := by simpa only [zero_mul] using μ.testAgainstNN_const 0 @[simp] theorem testAgainstNN_one (μ : FiniteMeasure Ω) : μ.testAgainstNN 1 = μ.mass := by simp only [testAgainstNN, coe_one, Pi.one_apply, ENNReal.coe_one, lintegral_one]	rfl @[simp]	Mathlib/MeasureTheory/Measure/FiniteMeasure.lean	363	365
/- Copyright (c) 2018 Rohan Mitta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rohan Mitta, Kevin Buzzard, Alistair Tucker, Johannes Hölzl, Yury Kudryashov, Winston Yin -/ import Mathlib.Algebra.Group.End import Mathlib.Topology.EMetricSpace.Diam /-! # Lipschitz continuous functions A map `f : α → β` between two (extended) metric spaces is called Lipschitz continuous with constant `K ≥ 0` if for all `x, y` we have `edist (f x) (f y) ≤ K * edist x y`. For a metric space, the latter inequality is equivalent to `dist (f x) (f y) ≤ K * dist x y`. There is also a version asserting this inequality only for `x` and `y` in some set `s`. Finally, `f : α → β` is called locally Lipschitz continuous if each `x : α` has a neighbourhood on which `f` is Lipschitz continuous (with some constant). In this file we provide various ways to prove that various combinations of Lipschitz continuous functions are Lipschitz continuous. We also prove that Lipschitz continuous functions are uniformly continuous, and that locally Lipschitz functions are continuous. ## Main definitions and lemmas * `LipschitzWith K f`: states that `f` is Lipschitz with constant `K : ℝ≥0` * `LipschitzOnWith K f s`: states that `f` is Lipschitz with constant `K : ℝ≥0` on a set `s` * `LipschitzWith.uniformContinuous`: a Lipschitz function is uniformly continuous * `LipschitzOnWith.uniformContinuousOn`: a function which is Lipschitz on a set `s` is uniformly continuous on `s`. * `LocallyLipschitz f`: states that `f` is locally Lipschitz * `LocallyLipschitzOn f s`: states that `f` is locally Lipschitz on `s`. * `LocallyLipschitz.continuous`: a locally Lipschitz function is continuous. ## Implementation notes The parameter `K` has type `ℝ≥0`. This way we avoid conjunction in the definition and have coercions both to `ℝ` and `ℝ≥0∞`. Constructors whose names end with `'` take `K : ℝ` as an argument, and return `LipschitzWith (Real.toNNReal K) f`. -/ universe u v w x open Filter Function Set Topology NNReal ENNReal Bornology variable {α : Type u} {β : Type v} {γ : Type w} {ι : Type x} section PseudoEMetricSpace variable [PseudoEMetricSpace α] [PseudoEMetricSpace β] {K : ℝ≥0} {s t : Set α} {f : α → β} /-- A function `f` is Lipschitz continuous with constant `K ≥ 0` if for all `x, y` we have `dist (f x) (f y) ≤ K * dist x y`. -/ def LipschitzWith (K : ℝ≥0) (f : α → β) := ∀ x y, edist (f x) (f y) ≤ K * edist x y /-- A function `f` is Lipschitz continuous with constant `K ≥ 0` on `s` if for all `x, y` in `s` we have `dist (f x) (f y) ≤ K * dist x y`. -/ def LipschitzOnWith (K : ℝ≥0) (f : α → β) (s : Set α) := ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → edist (f x) (f y) ≤ K * edist x y /-- `f : α → β` is called locally Lipschitz continuous iff every point `x` has a neighbourhood on which `f` is Lipschitz. -/ def LocallyLipschitz (f : α → β) : Prop := ∀ x, ∃ K, ∃ t ∈ 𝓝 x, LipschitzOnWith K f t /-- `f : α → β` is called locally Lipschitz continuous on `s` iff every point `x` of `s` has a neighbourhood within `s` on which `f` is Lipschitz. -/ def LocallyLipschitzOn (s : Set α) (f : α → β) : Prop := ∀ ⦃x⦄, x ∈ s → ∃ K, ∃ t ∈ 𝓝[s] x, LipschitzOnWith K f t /-- Every function is Lipschitz on the empty set (with any Lipschitz constant). -/ @[simp] theorem lipschitzOnWith_empty (K : ℝ≥0) (f : α → β) : LipschitzOnWith K f ∅ := fun _ => False.elim @[simp] lemma locallyLipschitzOn_empty (f : α → β) : LocallyLipschitzOn ∅ f := fun _ ↦ False.elim /-- Being Lipschitz on a set is monotone w.r.t. that set. -/ theorem LipschitzOnWith.mono (hf : LipschitzOnWith K f t) (h : s ⊆ t) : LipschitzOnWith K f s := fun _x x_in _y y_in => hf (h x_in) (h y_in) lemma LocallyLipschitzOn.mono (hf : LocallyLipschitzOn t f) (h : s ⊆ t) : LocallyLipschitzOn s f := fun x hx ↦ by obtain ⟨K, u, hu, hfu⟩ := hf (h hx); exact ⟨K, u, nhdsWithin_mono _ h hu, hfu⟩ /-- `f` is Lipschitz iff it is Lipschitz on the entire space. -/ @[simp] lemma lipschitzOnWith_univ : LipschitzOnWith K f univ ↔ LipschitzWith K f := by simp [LipschitzOnWith, LipschitzWith] @[simp] lemma locallyLipschitzOn_univ : LocallyLipschitzOn univ f ↔ LocallyLipschitz f := by simp [LocallyLipschitzOn, LocallyLipschitz] protected lemma LocallyLipschitz.locallyLipschitzOn (h : LocallyLipschitz f) : LocallyLipschitzOn s f := (locallyLipschitzOn_univ.2 h).mono s.subset_univ theorem lipschitzOnWith_iff_restrict : LipschitzOnWith K f s ↔ LipschitzWith K (s.restrict f) := by simp [LipschitzOnWith, LipschitzWith] lemma lipschitzOnWith_restrict {t : Set s} : LipschitzOnWith K (s.restrict f) t ↔ LipschitzOnWith K f (s ∩ Subtype.val '' t) := by simp [LipschitzOnWith, LipschitzWith] lemma locallyLipschitzOn_iff_restrict : LocallyLipschitzOn s f ↔ LocallyLipschitz (s.restrict f) := by simp only [LocallyLipschitzOn, LocallyLipschitz, SetCoe.forall', restrict_apply, Subtype.edist_mk_mk, ← lipschitzOnWith_iff_restrict, lipschitzOnWith_restrict, nhds_subtype_eq_comap_nhdsWithin, mem_comap] congr! with x K constructor · rintro ⟨t, ht, hft⟩ exact ⟨_, ⟨t, ht, Subset.rfl⟩, hft.mono <\| inter_subset_right.trans <\| image_preimage_subset ..⟩ · rintro ⟨t, ⟨u, hu, hut⟩, hft⟩ exact ⟨s ∩ u, Filter.inter_mem self_mem_nhdsWithin hu, hft.mono fun x hx ↦ ⟨hx.1, ⟨x, hx.1⟩, hut hx.2, rfl⟩⟩ alias ⟨LipschitzOnWith.to_restrict, _⟩ := lipschitzOnWith_iff_restrict alias ⟨LocallyLipschitzOn.restrict, _⟩ := locallyLipschitzOn_iff_restrict lemma Set.MapsTo.lipschitzOnWith_iff_restrict {t : Set β} (h : MapsTo f s t) : LipschitzOnWith K f s ↔ LipschitzWith K (h.restrict f s t) := _root_.lipschitzOnWith_iff_restrict alias ⟨LipschitzOnWith.to_restrict_mapsTo, _⟩ := Set.MapsTo.lipschitzOnWith_iff_restrict end PseudoEMetricSpace namespace LipschitzWith open EMetric variable [PseudoEMetricSpace α] [PseudoEMetricSpace β] [PseudoEMetricSpace γ] variable {K : ℝ≥0} {f : α → β} {x y : α} {r : ℝ≥0∞} {s : Set α} protected theorem lipschitzOnWith (h : LipschitzWith K f) : LipschitzOnWith K f s := fun x _ y _ => h x y theorem edist_le_mul (h : LipschitzWith K f) (x y : α) : edist (f x) (f y) ≤ K * edist x y := h x y theorem edist_le_mul_of_le (h : LipschitzWith K f) (hr : edist x y ≤ r) : edist (f x) (f y) ≤ K * r := (h x y).trans <\| mul_left_mono hr theorem edist_lt_mul_of_lt (h : LipschitzWith K f) (hK : K ≠ 0) (hr : edist x y < r) : edist (f x) (f y) < K * r := (h x y).trans_lt <\| (ENNReal.mul_lt_mul_left (ENNReal.coe_ne_zero.2 hK) ENNReal.coe_ne_top).2 hr theorem mapsTo_emetric_closedBall (h : LipschitzWith K f) (x : α) (r : ℝ≥0∞) : MapsTo f (closedBall x r) (closedBall (f x) (K * r)) := fun _y hy => h.edist_le_mul_of_le hy theorem mapsTo_emetric_ball (h : LipschitzWith K f) (hK : K ≠ 0) (x : α) (r : ℝ≥0∞) : MapsTo f (ball x r) (ball (f x) (K * r)) := fun _y hy => h.edist_lt_mul_of_lt hK hy theorem edist_lt_top (hf : LipschitzWith K f) {x y : α} (h : edist x y ≠ ⊤) : edist (f x) (f y) < ⊤ := (hf x y).trans_lt <\| ENNReal.mul_lt_top ENNReal.coe_lt_top h.lt_top theorem mul_edist_le (h : LipschitzWith K f) (x y : α) : (K⁻¹ : ℝ≥0∞) * edist (f x) (f y) ≤ edist x y := by rw [mul_comm, ← div_eq_mul_inv] exact ENNReal.div_le_of_le_mul' (h x y) protected theorem of_edist_le (h : ∀ x y, edist (f x) (f y) ≤ edist x y) : LipschitzWith 1 f := fun x y => by simp only [ENNReal.coe_one, one_mul, h] protected theorem weaken (hf : LipschitzWith K f) {K' : ℝ≥0} (h : K ≤ K') : LipschitzWith K' f := fun x y => le_trans (hf x y) <\| mul_right_mono (ENNReal.coe_le_coe.2 h) theorem ediam_image_le (hf : LipschitzWith K f) (s : Set α) : EMetric.diam (f '' s) ≤ K * EMetric.diam s := by apply EMetric.diam_le rintro _ ⟨x, hx, rfl⟩ _ ⟨y, hy, rfl⟩ exact hf.edist_le_mul_of_le (EMetric.edist_le_diam_of_mem hx hy) theorem edist_lt_of_edist_lt_div (hf : LipschitzWith K f) {x y : α} {d : ℝ≥0∞} (h : edist x y < d / K) : edist (f x) (f y) < d := calc edist (f x) (f y) ≤ K * edist x y := hf x y _ < d := ENNReal.mul_lt_of_lt_div' h /-- A Lipschitz function is uniformly continuous. -/ protected theorem uniformContinuous (hf : LipschitzWith K f) : UniformContinuous f := EMetric.uniformContinuous_iff.2 fun ε εpos => ⟨ε / K, ENNReal.div_pos_iff.2 ⟨ne_of_gt εpos, ENNReal.coe_ne_top⟩, hf.edist_lt_of_edist_lt_div⟩ /-- A Lipschitz function is continuous. -/ protected theorem continuous (hf : LipschitzWith K f) : Continuous f := hf.uniformContinuous.continuous /-- Constant functions are Lipschitz (with any constant). -/ protected theorem const (b : β) : LipschitzWith 0 fun _ : α => b := fun x y => by simp only [edist_self, zero_le] protected theorem const' (b : β) {K : ℝ≥0} : LipschitzWith K fun _ : α => b := fun x y => by simp only [edist_self, zero_le] /-- The identity is 1-Lipschitz. -/ protected theorem id : LipschitzWith 1 (@id α) := LipschitzWith.of_edist_le fun _ _ => le_rfl /-- The inclusion of a subset is 1-Lipschitz. -/ protected theorem subtype_val (s : Set α) : LipschitzWith 1 (Subtype.val : s → α) := LipschitzWith.of_edist_le fun _ _ => le_rfl theorem subtype_mk (hf : LipschitzWith K f) {p : β → Prop} (hp : ∀ x, p (f x)) : LipschitzWith K (fun x => ⟨f x, hp x⟩ : α → { y // p y }) := hf protected theorem eval {α : ι → Type u} [∀ i, PseudoEMetricSpace (α i)] [Fintype ι] (i : ι) : LipschitzWith 1 (Function.eval i : (∀ i, α i) → α i) := LipschitzWith.of_edist_le fun f g => by convert edist_le_pi_edist f g i /-- The restriction of a `K`-Lipschitz function is `K`-Lipschitz. -/ protected theorem restrict (hf : LipschitzWith K f) (s : Set α) : LipschitzWith K (s.restrict f) := fun x y => hf x y /-- The composition of Lipschitz functions is Lipschitz. -/ protected theorem comp {Kf Kg : ℝ≥0} {f : β → γ} {g : α → β} (hf : LipschitzWith Kf f) (hg : LipschitzWith Kg g) : LipschitzWith (Kf * Kg) (f ∘ g) := fun x y => calc edist (f (g x)) (f (g y)) ≤ Kf * edist (g x) (g y) := hf _ _ _ ≤ Kf * (Kg * edist x y) := mul_left_mono (hg _ _) _ = (Kf * Kg : ℝ≥0) * edist x y := by rw [← mul_assoc, ENNReal.coe_mul] theorem comp_lipschitzOnWith {Kf Kg : ℝ≥0} {f : β → γ} {g : α → β} {s : Set α} (hf : LipschitzWith Kf f) (hg : LipschitzOnWith Kg g s) : LipschitzOnWith (Kf * Kg) (f ∘ g) s := lipschitzOnWith_iff_restrict.mpr <\| hf.comp hg.to_restrict protected theorem prod_fst : LipschitzWith 1 (@Prod.fst α β) := LipschitzWith.of_edist_le fun _ _ => le_max_left _ _ protected theorem prod_snd : LipschitzWith 1 (@Prod.snd α β) := LipschitzWith.of_edist_le fun _ _ => le_max_right _ _ /-- If `f` and `g` are Lipschitz functions, so is the induced map `f × g` to the product type. -/ protected theorem prodMk {f : α → β} {Kf : ℝ≥0} (hf : LipschitzWith Kf f) {g : α → γ} {Kg : ℝ≥0} (hg : LipschitzWith Kg g) : LipschitzWith (max Kf Kg) fun x => (f x, g x) := by intro x y rw [ENNReal.coe_mono.map_max, Prod.edist_eq, max_mul] exact max_le_max (hf x y) (hg x y)	@[deprecated (since := "2025-03-10")] protected alias prod := LipschitzWith.prodMk protected theorem prodMk_left (a : α) : LipschitzWith 1 (Prod.mk a : β → α × β) := by	Mathlib/Topology/EMetricSpace/Lipschitz.lean	237	241
/- Copyright (c) 2022 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Patrick Massot, Yury Kudryashov, Kevin H. Wilson, Heather Macbeth -/ import Mathlib.Order.Filter.Tendsto /-! # Product and coproduct filters In this file we define `Filter.prod f g` (notation: `f ×ˢ g`) and `Filter.coprod f g`. The product of two filters is the largest filter `l` such that `Filter.Tendsto Prod.fst l f` and `Filter.Tendsto Prod.snd l g`. ## Implementation details The product filter cannot be defined using the monad structure on filters. For example: ```lean F := do {x ← seq, y ← top, return (x, y)} G := do {y ← top, x ← seq, return (x, y)} ``` hence: ```lean s ∈ F ↔ ∃ n, [n..∞] × univ ⊆ s s ∈ G ↔ ∀ i:ℕ, ∃ n, [n..∞] × {i} ⊆ s ``` Now `⋃ i, [i..∞] × {i}` is in `G` but not in `F`. As product filter we want to have `F` as result. ## Notations * `f ×ˢ g` : `Filter.prod f g`, localized in `Filter`. -/ open Set open Filter namespace Filter variable {α β γ δ : Type} {ι : Sort} section Prod variable {s : Set α} {t : Set β} {f : Filter α} {g : Filter β} theorem prod_mem_prod (hs : s ∈ f) (ht : t ∈ g) : s ×ˢ t ∈ f ×ˢ g := inter_mem_inf (preimage_mem_comap hs) (preimage_mem_comap ht) theorem mem_prod_iff {s : Set (α × β)} {f : Filter α} {g : Filter β} : s ∈ f ×ˢ g ↔ ∃ t₁ ∈ f, ∃ t₂ ∈ g, t₁ ×ˢ t₂ ⊆ s := by constructor · rintro ⟨t₁, ⟨s₁, hs₁, hts₁⟩, t₂, ⟨s₂, hs₂, hts₂⟩, rfl⟩ exact ⟨s₁, hs₁, s₂, hs₂, fun p ⟨h, h'⟩ => ⟨hts₁ h, hts₂ h'⟩⟩ · rintro ⟨t₁, ht₁, t₂, ht₂, h⟩ exact mem_inf_of_inter (preimage_mem_comap ht₁) (preimage_mem_comap ht₂) h @[simp] theorem compl_diagonal_mem_prod {l₁ l₂ : Filter α} : (diagonal α)ᶜ ∈ l₁ ×ˢ l₂ ↔ Disjoint l₁ l₂ := by simp only [mem_prod_iff, Filter.disjoint_iff, prod_subset_compl_diagonal_iff_disjoint] @[simp] theorem prod_mem_prod_iff [f.NeBot] [g.NeBot] : s ×ˢ t ∈ f ×ˢ g ↔ s ∈ f ∧ t ∈ g := ⟨fun h => let ⟨_s', hs', _t', ht', H⟩ := mem_prod_iff.1 h (prod_subset_prod_iff.1 H).elim (fun ⟨hs's, ht't⟩ => ⟨mem_of_superset hs' hs's, mem_of_superset ht' ht't⟩) fun h => h.elim (fun hs'e => absurd hs'e (nonempty_of_mem hs').ne_empty) fun ht'e => absurd ht'e (nonempty_of_mem ht').ne_empty, fun h => prod_mem_prod h.1 h.2⟩ theorem mem_prod_principal {s : Set (α × β)} : s ∈ f ×ˢ 𝓟 t ↔ { a \| ∀ b ∈ t, (a, b) ∈ s } ∈ f := by rw [← @exists_mem_subset_iff _ f, mem_prod_iff] refine exists_congr fun u => Iff.rfl.and ⟨?_, fun h => ⟨t, mem_principal_self t, ?_⟩⟩ · rintro ⟨v, v_in, hv⟩ a a_in b b_in exact hv (mk_mem_prod a_in <\| v_in b_in) · rintro ⟨x, y⟩ ⟨hx, hy⟩ exact h hx y hy theorem mem_prod_top {s : Set (α × β)} : s ∈ f ×ˢ (⊤ : Filter β) ↔ { a \| ∀ b, (a, b) ∈ s } ∈ f := by rw [← principal_univ, mem_prod_principal] simp only [mem_univ, forall_true_left] theorem eventually_prod_principal_iff {p : α × β → Prop} {s : Set β} : (∀ᶠ x : α × β in f ×ˢ 𝓟 s, p x) ↔ ∀ᶠ x : α in f, ∀ y : β, y ∈ s → p (x, y) := by rw [eventually_iff, eventually_iff, mem_prod_principal] simp only [mem_setOf_eq] theorem comap_prod (f : α → β × γ) (b : Filter β) (c : Filter γ) : comap f (b ×ˢ c) = comap (Prod.fst ∘ f) b ⊓ comap (Prod.snd ∘ f) c := by rw [prod_eq_inf, comap_inf, Filter.comap_comap, Filter.comap_comap] theorem comap_prodMap_prod (f : α → β) (g : γ → δ) (lb : Filter β) (ld : Filter δ) : comap (Prod.map f g) (lb ×ˢ ld) = comap f lb ×ˢ comap g ld := by simp [prod_eq_inf, comap_comap, Function.comp_def] theorem prod_top : f ×ˢ (⊤ : Filter β) = f.comap Prod.fst := by rw [prod_eq_inf, comap_top, inf_top_eq] theorem top_prod : (⊤ : Filter α) ×ˢ g = g.comap Prod.snd := by rw [prod_eq_inf, comap_top, top_inf_eq] theorem sup_prod (f₁ f₂ : Filter α) (g : Filter β) : (f₁ ⊔ f₂) ×ˢ g = (f₁ ×ˢ g) ⊔ (f₂ ×ˢ g) := by simp only [prod_eq_inf, comap_sup, inf_sup_right] theorem prod_sup (f : Filter α) (g₁ g₂ : Filter β) : f ×ˢ (g₁ ⊔ g₂) = (f ×ˢ g₁) ⊔ (f ×ˢ g₂) := by simp only [prod_eq_inf, comap_sup, inf_sup_left] theorem eventually_prod_iff {p : α × β → Prop} : (∀ᶠ x in f ×ˢ g, p x) ↔ ∃ pa : α → Prop, (∀ᶠ x in f, pa x) ∧ ∃ pb : β → Prop, (∀ᶠ y in g, pb y) ∧ ∀ {x}, pa x → ∀ {y}, pb y → p (x, y) := by simpa only [Set.prod_subset_iff] using @mem_prod_iff α β p f g theorem tendsto_fst : Tendsto Prod.fst (f ×ˢ g) f := tendsto_inf_left tendsto_comap theorem tendsto_snd : Tendsto Prod.snd (f ×ˢ g) g := tendsto_inf_right tendsto_comap /-- If a function tends to a product `g ×ˢ h` of filters, then its first component tends to `g`. See also `Filter.Tendsto.fst_nhds` for the special case of converging to a point in a product of two topological spaces. -/ theorem Tendsto.fst {h : Filter γ} {m : α → β × γ} (H : Tendsto m f (g ×ˢ h)) : Tendsto (fun a ↦ (m a).1) f g := tendsto_fst.comp H /-- If a function tends to a product `g ×ˢ h` of filters, then its second component tends to `h`. See also `Filter.Tendsto.snd_nhds` for the special case of converging to a point in a product of two topological spaces. -/ theorem Tendsto.snd {h : Filter γ} {m : α → β × γ} (H : Tendsto m f (g ×ˢ h)) : Tendsto (fun a ↦ (m a).2) f h := tendsto_snd.comp H theorem Tendsto.prodMk {h : Filter γ} {m₁ : α → β} {m₂ : α → γ} (h₁ : Tendsto m₁ f g) (h₂ : Tendsto m₂ f h) : Tendsto (fun x => (m₁ x, m₂ x)) f (g ×ˢ h) := tendsto_inf.2 ⟨tendsto_comap_iff.2 h₁, tendsto_comap_iff.2 h₂⟩ @[deprecated (since := "2025-03-10")] alias Tendsto.prod_mk := Tendsto.prodMk theorem tendsto_prod_swap : Tendsto (Prod.swap : α × β → β × α) (f ×ˢ g) (g ×ˢ f) := tendsto_snd.prodMk tendsto_fst theorem Eventually.prod_inl {la : Filter α} {p : α → Prop} (h : ∀ᶠ x in la, p x) (lb : Filter β) : ∀ᶠ x in la ×ˢ lb, p (x : α × β).1 := tendsto_fst.eventually h theorem Eventually.prod_inr {lb : Filter β} {p : β → Prop} (h : ∀ᶠ x in lb, p x) (la : Filter α) : ∀ᶠ x in la ×ˢ lb, p (x : α × β).2 := tendsto_snd.eventually h theorem Eventually.prod_mk {la : Filter α} {pa : α → Prop} (ha : ∀ᶠ x in la, pa x) {lb : Filter β} {pb : β → Prop} (hb : ∀ᶠ y in lb, pb y) : ∀ᶠ p in la ×ˢ lb, pa (p : α × β).1 ∧ pb p.2 := (ha.prod_inl lb).and (hb.prod_inr la) theorem EventuallyEq.prodMap {δ} {la : Filter α} {fa ga : α → γ} (ha : fa =ᶠ[la] ga) {lb : Filter β} {fb gb : β → δ} (hb : fb =ᶠ[lb] gb) : Prod.map fa fb =ᶠ[la ×ˢ lb] Prod.map ga gb := (Eventually.prod_mk ha hb).mono fun _ h => Prod.ext h.1 h.2 @[deprecated (since := "2025-03-10")] alias EventuallyEq.prod_map := EventuallyEq.prodMap theorem EventuallyLE.prodMap {δ} [LE γ] [LE δ] {la : Filter α} {fa ga : α → γ} (ha : fa ≤ᶠ[la] ga) {lb : Filter β} {fb gb : β → δ} (hb : fb ≤ᶠ[lb] gb) : Prod.map fa fb ≤ᶠ[la ×ˢ lb] Prod.map ga gb := Eventually.prod_mk ha hb @[deprecated (since := "2025-03-10")] alias EventuallyLE.prod_map := EventuallyLE.prodMap theorem Eventually.curry {la : Filter α} {lb : Filter β} {p : α × β → Prop} (h : ∀ᶠ x in la ×ˢ lb, p x) : ∀ᶠ x in la, ∀ᶠ y in lb, p (x, y) := by rcases eventually_prod_iff.1 h with ⟨pa, ha, pb, hb, h⟩ exact ha.mono fun a ha => hb.mono fun b hb => h ha hb protected lemma Frequently.uncurry {la : Filter α} {lb : Filter β} {p : α → β → Prop} (h : ∃ᶠ x in la, ∃ᶠ y in lb, p x y) : ∃ᶠ xy in la ×ˢ lb, p xy.1 xy.2 := mt (fun h ↦ by simpa only [not_frequently] using h.curry) h lemma Frequently.of_curry {la : Filter α} {lb : Filter β} {p : α × β → Prop} (h : ∃ᶠ x in la, ∃ᶠ y in lb, p (x, y)) : ∃ᶠ xy in la ×ˢ lb, p xy := h.uncurry /-- A fact that is eventually true about all pairs `l ×ˢ l` is eventually true about all diagonal pairs `(i, i)` -/ theorem Eventually.diag_of_prod {p : α × α → Prop} (h : ∀ᶠ i in f ×ˢ f, p i) : ∀ᶠ i in f, p (i, i) := by obtain ⟨t, ht, s, hs, hst⟩ := eventually_prod_iff.1 h apply (ht.and hs).mono fun x hx => hst hx.1 hx.2 theorem Eventually.diag_of_prod_left {f : Filter α} {g : Filter γ} {p : (α × α) × γ → Prop} : (∀ᶠ x in (f ×ˢ f) ×ˢ g, p x) → ∀ᶠ x : α × γ in f ×ˢ g, p ((x.1, x.1), x.2) := by intro h obtain ⟨t, ht, s, hs, hst⟩ := eventually_prod_iff.1 h exact (ht.diag_of_prod.prod_mk hs).mono fun x hx => by simp only [hst hx.1 hx.2] theorem Eventually.diag_of_prod_right {f : Filter α} {g : Filter γ} {p : α × γ × γ → Prop} : (∀ᶠ x in f ×ˢ (g ×ˢ g), p x) → ∀ᶠ x : α × γ in f ×ˢ g, p (x.1, x.2, x.2) := by intro h obtain ⟨t, ht, s, hs, hst⟩ := eventually_prod_iff.1 h exact (ht.prod_mk hs.diag_of_prod).mono fun x hx => by simp only [hst hx.1 hx.2] theorem tendsto_diag : Tendsto (fun i => (i, i)) f (f ×ˢ f) := tendsto_iff_eventually.mpr fun _ hpr => hpr.diag_of_prod theorem prod_iInf_left [Nonempty ι] {f : ι → Filter α} {g : Filter β} : (⨅ i, f i) ×ˢ g = ⨅ i, f i ×ˢ g := by simp only [prod_eq_inf, comap_iInf, iInf_inf] theorem prod_iInf_right [Nonempty ι] {f : Filter α} {g : ι → Filter β} : (f ×ˢ ⨅ i, g i) = ⨅ i, f ×ˢ g i := by simp only [prod_eq_inf, comap_iInf, inf_iInf] @[mono, gcongr] theorem prod_mono {f₁ f₂ : Filter α} {g₁ g₂ : Filter β} (hf : f₁ ≤ f₂) (hg : g₁ ≤ g₂) : f₁ ×ˢ g₁ ≤ f₂ ×ˢ g₂ := inf_le_inf (comap_mono hf) (comap_mono hg) @[gcongr] theorem prod_mono_left (g : Filter β) {f₁ f₂ : Filter α} (hf : f₁ ≤ f₂) : f₁ ×ˢ g ≤ f₂ ×ˢ g := Filter.prod_mono hf rfl.le @[gcongr] theorem prod_mono_right (f : Filter α) {g₁ g₂ : Filter β} (hf : g₁ ≤ g₂) : f ×ˢ g₁ ≤ f ×ˢ g₂ := Filter.prod_mono rfl.le hf theorem prod_comap_comap_eq.{u, v, w, x} {α₁ : Type u} {α₂ : Type v} {β₁ : Type w} {β₂ : Type x} {f₁ : Filter α₁} {f₂ : Filter α₂} {m₁ : β₁ → α₁} {m₂ : β₂ → α₂} : comap m₁ f₁ ×ˢ comap m₂ f₂ = comap (fun p : β₁ × β₂ => (m₁ p.1, m₂ p.2)) (f₁ ×ˢ f₂) := by simp only [prod_eq_inf, comap_comap, comap_inf, Function.comp_def] theorem prod_comm' : f ×ˢ g = comap Prod.swap (g ×ˢ f) := by simp only [prod_eq_inf, comap_comap, Function.comp_def, inf_comm, Prod.swap, comap_inf] theorem prod_comm : f ×ˢ g = map (fun p : β × α => (p.2, p.1)) (g ×ˢ f) := by rw [prod_comm', ← map_swap_eq_comap_swap] rfl theorem mem_prod_iff_left {s : Set (α × β)} : s ∈ f ×ˢ g ↔ ∃ t ∈ f, ∀ᶠ y in g, ∀ x ∈ t, (x, y) ∈ s := by simp only [mem_prod_iff, prod_subset_iff] refine exists_congr fun _ => Iff.rfl.and <\| Iff.trans ?_ exists_mem_subset_iff exact exists_congr fun _ => Iff.rfl.and forall₂_swap theorem mem_prod_iff_right {s : Set (α × β)} : s ∈ f ×ˢ g ↔ ∃ t ∈ g, ∀ᶠ x in f, ∀ y ∈ t, (x, y) ∈ s := by rw [prod_comm, mem_map, mem_prod_iff_left]; rfl @[simp] theorem map_fst_prod (f : Filter α) (g : Filter β) [NeBot g] : map Prod.fst (f ×ˢ g) = f := by ext s simp only [mem_map, mem_prod_iff_left, mem_preimage, eventually_const, ← subset_def, exists_mem_subset_iff] @[simp] theorem map_snd_prod (f : Filter α) (g : Filter β) [NeBot f] : map Prod.snd (f ×ˢ g) = g := by rw [prod_comm, map_map]; apply map_fst_prod @[simp] theorem prod_le_prod {f₁ f₂ : Filter α} {g₁ g₂ : Filter β} [NeBot f₁] [NeBot g₁] : f₁ ×ˢ g₁ ≤ f₂ ×ˢ g₂ ↔ f₁ ≤ f₂ ∧ g₁ ≤ g₂ := ⟨fun h => ⟨map_fst_prod f₁ g₁ ▸ tendsto_fst.mono_left h, map_snd_prod f₁ g₁ ▸ tendsto_snd.mono_left h⟩, fun h => prod_mono h.1 h.2⟩ @[simp] theorem prod_inj {f₁ f₂ : Filter α} {g₁ g₂ : Filter β} [NeBot f₁] [NeBot g₁] : f₁ ×ˢ g₁ = f₂ ×ˢ g₂ ↔ f₁ = f₂ ∧ g₁ = g₂ := by refine ⟨fun h => ?_, fun h => h.1 ▸ h.2 ▸ rfl⟩ have hle : f₁ ≤ f₂ ∧ g₁ ≤ g₂ := prod_le_prod.1 h.le haveI := neBot_of_le hle.1; haveI := neBot_of_le hle.2 exact ⟨hle.1.antisymm <\| (prod_le_prod.1 h.ge).1, hle.2.antisymm <\| (prod_le_prod.1 h.ge).2⟩ theorem eventually_swap_iff {p : α × β → Prop} : (∀ᶠ x : α × β in f ×ˢ g, p x) ↔ ∀ᶠ y : β × α in g ×ˢ f, p y.swap := by rw [prod_comm]; rfl theorem prod_assoc (f : Filter α) (g : Filter β) (h : Filter γ) : map (Equiv.prodAssoc α β γ) ((f ×ˢ g) ×ˢ h) = f ×ˢ (g ×ˢ h) := by simp_rw [← comap_equiv_symm, prod_eq_inf, comap_inf, comap_comap, inf_assoc, Function.comp_def, Equiv.prodAssoc_symm_apply] theorem prod_assoc_symm (f : Filter α) (g : Filter β) (h : Filter γ) : map (Equiv.prodAssoc α β γ).symm (f ×ˢ (g ×ˢ h)) = (f ×ˢ g) ×ˢ h := by simp_rw [map_equiv_symm, prod_eq_inf, comap_inf, comap_comap, inf_assoc, Function.comp_def, Equiv.prodAssoc_apply] theorem tendsto_prodAssoc {h : Filter γ} : Tendsto (Equiv.prodAssoc α β γ) ((f ×ˢ g) ×ˢ h) (f ×ˢ (g ×ˢ h)) := (prod_assoc f g h).le theorem tendsto_prodAssoc_symm {h : Filter γ} : Tendsto (Equiv.prodAssoc α β γ).symm (f ×ˢ (g ×ˢ h)) ((f ×ˢ g) ×ˢ h) := (prod_assoc_symm f g h).le /-- A useful lemma when dealing with uniformities. -/ theorem map_swap4_prod {h : Filter γ} {k : Filter δ} : map (fun p : (α × β) × γ × δ => ((p.1.1, p.2.1), (p.1.2, p.2.2))) ((f ×ˢ g) ×ˢ (h ×ˢ k)) = (f ×ˢ h) ×ˢ (g ×ˢ k) := by simp_rw [map_swap4_eq_comap, prod_eq_inf, comap_inf, comap_comap]; ac_rfl theorem tendsto_swap4_prod {h : Filter γ} {k : Filter δ} : Tendsto (fun p : (α × β) × γ × δ => ((p.1.1, p.2.1), (p.1.2, p.2.2))) ((f ×ˢ g) ×ˢ (h ×ˢ k)) ((f ×ˢ h) ×ˢ (g ×ˢ k)) := map_swap4_prod.le theorem prod_map_map_eq.{u, v, w, x} {α₁ : Type u} {α₂ : Type v} {β₁ : Type w} {β₂ : Type x} {f₁ : Filter α₁} {f₂ : Filter α₂} {m₁ : α₁ → β₁} {m₂ : α₂ → β₂} : map m₁ f₁ ×ˢ map m₂ f₂ = map (fun p : α₁ × α₂ => (m₁ p.1, m₂ p.2)) (f₁ ×ˢ f₂) := le_antisymm (fun s hs => let ⟨s₁, hs₁, s₂, hs₂, h⟩ := mem_prod_iff.mp hs mem_of_superset (prod_mem_prod (image_mem_map hs₁) (image_mem_map hs₂)) <\| by rwa [prod_image_image_eq, image_subset_iff]) ((tendsto_map.comp tendsto_fst).prodMk (tendsto_map.comp tendsto_snd)) theorem prod_map_map_eq' {α₁ : Type} {α₂ : Type} {β₁ : Type} {β₂ : Type} (f : α₁ → α₂) (g : β₁ → β₂) (F : Filter α₁) (G : Filter β₁) : map f F ×ˢ map g G = map (Prod.map f g) (F ×ˢ G) := prod_map_map_eq theorem prod_map_left (f : α → β) (F : Filter α) (G : Filter γ) : map f F ×ˢ G = map (Prod.map f id) (F ×ˢ G) := by rw [← prod_map_map_eq', map_id] theorem prod_map_right (f : β → γ) (F : Filter α) (G : Filter β) : F ×ˢ map f G = map (Prod.map id f) (F ×ˢ G) := by rw [← prod_map_map_eq', map_id] theorem le_prod_map_fst_snd {f : Filter (α × β)} : f ≤ map Prod.fst f ×ˢ map Prod.snd f := le_inf le_comap_map le_comap_map theorem Tendsto.prodMap {δ : Type*} {f : α → γ} {g : β → δ} {a : Filter α} {b : Filter β} {c : Filter γ} {d : Filter δ} (hf : Tendsto f a c) (hg : Tendsto g b d) : Tendsto (Prod.map f g) (a ×ˢ b) (c ×ˢ d) := by rw [Tendsto, Prod.map_def, ← prod_map_map_eq] exact Filter.prod_mono hf hg @[deprecated (since := "2025-03-10")] alias Tendsto.prod_map := Tendsto.prodMap protected theorem map_prod (m : α × β → γ) (f : Filter α) (g : Filter β) : map m (f ×ˢ g) = (f.map fun a b => m (a, b)).seq g := by simp only [Filter.ext_iff, mem_map, mem_prod_iff, mem_map_seq_iff, exists_and_left] intro s constructor · exact fun ⟨t, ht, s, hs, h⟩ => ⟨s, hs, t, ht, fun x hx y hy => @h ⟨x, y⟩ ⟨hx, hy⟩⟩ · exact fun ⟨s, hs, t, ht, h⟩ => ⟨t, ht, s, hs, fun ⟨x, y⟩ ⟨hx, hy⟩ => h x hx y hy⟩ theorem prod_eq : f ×ˢ g = (f.map Prod.mk).seq g := f.map_prod id g theorem prod_inf_prod {f₁ f₂ : Filter α} {g₁ g₂ : Filter β} : (f₁ ×ˢ g₁) ⊓ (f₂ ×ˢ g₂) = (f₁ ⊓ f₂) ×ˢ (g₁ ⊓ g₂) := by simp only [prod_eq_inf, comap_inf, inf_comm, inf_assoc, inf_left_comm] theorem inf_prod {f₁ f₂ : Filter α} : (f₁ ⊓ f₂) ×ˢ g = (f₁ ×ˢ g) ⊓ (f₂ ×ˢ g) := by rw [prod_inf_prod, inf_idem] theorem prod_inf {g₁ g₂ : Filter β} : f ×ˢ (g₁ ⊓ g₂) = (f ×ˢ g₁) ⊓ (f ×ˢ g₂) := by rw [prod_inf_prod, inf_idem] @[simp] theorem prod_principal_principal {s : Set α} {t : Set β} : 𝓟 s ×ˢ 𝓟 t = 𝓟 (s ×ˢ t) := by simp only [prod_eq_inf, comap_principal, principal_eq_iff_eq, comap_principal, inf_principal]; rfl @[simp] theorem pure_prod {a : α} {f : Filter β} : pure a ×ˢ f = map (Prod.mk a) f := by rw [prod_eq, map_pure, pure_seq_eq_map] theorem map_pure_prod (f : α → β → γ) (a : α) (B : Filter β) : map (Function.uncurry f) (pure a ×ˢ B) = map (f a) B := by rw [Filter.pure_prod]; rfl @[simp] theorem prod_pure {b : β} : f ×ˢ pure b = map (fun a => (a, b)) f := by rw [prod_eq, seq_pure, map_map]; rfl theorem prod_pure_pure {a : α} {b : β} : (pure a : Filter α) ×ˢ (pure b : Filter β) = pure (a, b) := by simp @[simp] theorem prod_eq_bot : f ×ˢ g = ⊥ ↔ f = ⊥ ∨ g = ⊥ := by simp_rw [← empty_mem_iff_bot, mem_prod_iff, subset_empty_iff, prod_eq_empty_iff, ← exists_prop, Subtype.exists', exists_or, exists_const, Subtype.exists, exists_prop, exists_eq_right] @[simp] theorem prod_bot : f ×ˢ (⊥ : Filter β) = ⊥ := prod_eq_bot.2 <\| Or.inr rfl @[simp] theorem bot_prod : (⊥ : Filter α) ×ˢ g = ⊥ := prod_eq_bot.2 <\| Or.inl rfl theorem prod_neBot : NeBot (f ×ˢ g) ↔ NeBot f ∧ NeBot g := by simp only [neBot_iff, Ne, prod_eq_bot, not_or] protected theorem NeBot.prod (hf : NeBot f) (hg : NeBot g) : NeBot (f ×ˢ g) := prod_neBot.2 ⟨hf, hg⟩ instance prod.instNeBot [hf : NeBot f] [hg : NeBot g] : NeBot (f ×ˢ g) := hf.prod hg @[simp] lemma disjoint_prod {f' : Filter α} {g' : Filter β} : Disjoint (f ×ˢ g) (f' ×ˢ g') ↔ Disjoint f f' ∨ Disjoint g g' := by simp only [disjoint_iff, prod_inf_prod, prod_eq_bot] /-- `p ∧ q` occurs frequently along the product of two filters iff both `p` and `q` occur frequently along the corresponding filters. -/ theorem frequently_prod_and {p : α → Prop} {q : β → Prop} : (∃ᶠ x in f ×ˢ g, p x.1 ∧ q x.2) ↔ (∃ᶠ a in f, p a) ∧ ∃ᶠ b in g, q b := by simp only [frequently_iff_neBot, ← prod_neBot, ← prod_inf_prod, prod_principal_principal] rfl theorem tendsto_prod_iff {f : α × β → γ} {x : Filter α} {y : Filter β} {z : Filter γ} : Tendsto f (x ×ˢ y) z ↔ ∀ W ∈ z, ∃ U ∈ x, ∃ V ∈ y, ∀ x y, x ∈ U → y ∈ V → f (x, y) ∈ W := by simp only [tendsto_def, mem_prod_iff, prod_sub_preimage_iff, exists_prop] theorem tendsto_prod_iff' {g' : Filter γ} {s : α → β × γ} : Tendsto s f (g ×ˢ g') ↔ Tendsto (fun n => (s n).1) f g ∧ Tendsto (fun n => (s n).2) f g' := by simp only [prod_eq_inf, tendsto_inf, tendsto_comap_iff, Function.comp_def] theorem le_prod {f : Filter (α × β)} {g : Filter α} {g' : Filter β} : (f ≤ g ×ˢ g') ↔ Tendsto Prod.fst f g ∧ Tendsto Prod.snd f g' := tendsto_prod_iff' end Prod /-! ### Coproducts of filters -/ section Coprod variable {f : Filter α} {g : Filter β} theorem coprod_eq_prod_top_sup_top_prod (f : Filter α) (g : Filter β) : Filter.coprod f g = f ×ˢ ⊤ ⊔ ⊤ ×ˢ g := by rw [prod_top, top_prod] rfl theorem mem_coprod_iff {s : Set (α × β)} {f : Filter α} {g : Filter β} : s ∈ f.coprod g ↔ (∃ t₁ ∈ f, Prod.fst ⁻¹' t₁ ⊆ s) ∧ ∃ t₂ ∈ g, Prod.snd ⁻¹' t₂ ⊆ s := by simp [Filter.coprod] @[simp] theorem bot_coprod (l : Filter β) : (⊥ : Filter α).coprod l = comap Prod.snd l := by simp [Filter.coprod] @[simp] theorem coprod_bot (l : Filter α) : l.coprod (⊥ : Filter β) = comap Prod.fst l := by simp [Filter.coprod]	theorem bot_coprod_bot : (⊥ : Filter α).coprod (⊥ : Filter β) = ⊥ := by simp	Mathlib/Order/Filter/Prod.lean	452	453
/- Copyright (c) 2024 Raghuram Sundararajan. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Raghuram Sundararajan -/ import Mathlib.Algebra.Ring.Defs import Mathlib.Algebra.Group.Ext /-! # Extensionality lemmas for rings and similar structures In this file we prove extensionality lemmas for the ring-like structures defined in `Mathlib/Algebra/Ring/Defs.lean`, ranging from `NonUnitalNonAssocSemiring` to `CommRing`. These extensionality lemmas take the form of asserting that two algebraic structures on a type are equal whenever the addition and multiplication defined by them are both the same. ## Implementation details We follow `Mathlib/Algebra/Group/Ext.lean` in using the term `(letI := i; HMul.hMul : R → R → R)` to refer to the multiplication specified by a typeclass instance `i` on a type `R` (and similarly for addition). We abbreviate these using some local notations. Since `Mathlib/Algebra/Group/Ext.lean` proved several injectivity lemmas, we do so as well — even if sometimes we don't need them to prove extensionality. ## Tags semiring, ring, extensionality -/ local macro:max "local_hAdd[" type:term ", " inst:term "]" : term => `(term\| (letI := $inst; HAdd.hAdd : $type → $type → $type)) local macro:max "local_hMul[" type:term ", " inst:term "]" : term => `(term\| (letI := $inst; HMul.hMul : $type → $type → $type)) universe u variable {R : Type u} /-! ### Distrib -/ namespace Distrib @[ext] theorem ext ⦃inst₁ inst₂ : Distrib R⦄ (h_add : local_hAdd[R, inst₁] = local_hAdd[R, inst₂]) (h_mul : local_hMul[R, inst₁] = local_hMul[R, inst₂]) : inst₁ = inst₂ := by -- Split into `add` and `mul` functions and properties. rcases inst₁ with @⟨⟨⟩, ⟨⟩⟩ rcases inst₂ with @⟨⟨⟩, ⟨⟩⟩ -- Prove equality of parts using function extensionality. congr	end Distrib /-! ### NonUnitalNonAssocSemiring -/ namespace NonUnitalNonAssocSemiring	Mathlib/Algebra/Ring/Ext.lean	52	56
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Floris van Doorn -/ import Mathlib.Data.Countable.Small import Mathlib.Data.Fintype.BigOperators import Mathlib.Data.Fintype.Powerset import Mathlib.Data.Nat.Cast.Order.Basic import Mathlib.Data.Set.Countable import Mathlib.Logic.Equiv.Fin.Basic import Mathlib.Logic.Small.Set import Mathlib.Logic.UnivLE import Mathlib.SetTheory.Cardinal.Order /-! # Basic results on cardinal numbers We provide a collection of basic results on cardinal numbers, in particular focussing on finite/countable/small types and sets. ## Main definitions * `Cardinal.powerlt a b` or `a ^< b` is defined as the supremum of `a ^ c` for `c < b`. ## References * <https://en.wikipedia.org/wiki/Cardinal_number> ## Tags cardinal number, cardinal arithmetic, cardinal exponentiation, aleph, Cantor's theorem, König's theorem, Konig's theorem -/ assert_not_exists Field open List (Vector) open Function Order Set noncomputable section universe u v w v' w' variable {α β : Type u} namespace Cardinal /-! ### Lifting cardinals to a higher universe -/ @[simp] lemma mk_preimage_down {s : Set α} : #(ULift.down.{v} ⁻¹' s) = lift.{v} (#s) := by rw [← mk_uLift, Cardinal.eq] constructor let f : ULift.down ⁻¹' s → ULift s := fun x ↦ ULift.up (restrictPreimage s ULift.down x) have : Function.Bijective f := ULift.up_bijective.comp (restrictPreimage_bijective _ (ULift.down_bijective)) exact Equiv.ofBijective f this -- `simp` can't figure out universe levels: normal form is `lift_mk_shrink'`. theorem lift_mk_shrink (α : Type u) [Small.{v} α] : Cardinal.lift.{max u w} #(Shrink.{v} α) = Cardinal.lift.{max v w} #α := lift_mk_eq.2 ⟨(equivShrink α).symm⟩ @[simp] theorem lift_mk_shrink' (α : Type u) [Small.{v} α] : Cardinal.lift.{u} #(Shrink.{v} α) = Cardinal.lift.{v} #α := lift_mk_shrink.{u, v, 0} α @[simp] theorem lift_mk_shrink'' (α : Type max u v) [Small.{v} α] : Cardinal.lift.{u} #(Shrink.{v} α) = #α := by rw [← lift_umax, lift_mk_shrink.{max u v, v, 0} α, ← lift_umax, lift_id] theorem prod_eq_of_fintype {α : Type u} [h : Fintype α] (f : α → Cardinal.{v}) : prod f = Cardinal.lift.{u} (∏ i, f i) := by revert f refine Fintype.induction_empty_option ?_ ?_ ?_ α (h_fintype := h) · intro α β hβ e h f letI := Fintype.ofEquiv β e.symm rw [← e.prod_comp f, ← h] exact mk_congr (e.piCongrLeft _).symm · intro f rw [Fintype.univ_pempty, Finset.prod_empty, lift_one, Cardinal.prod, mk_eq_one] · intro α hα h f rw [Cardinal.prod, mk_congr Equiv.piOptionEquivProd, mk_prod, lift_umax.{v, u}, mk_out, ← Cardinal.prod, lift_prod, Fintype.prod_option, lift_mul, ← h fun a => f (some a)] simp only [lift_id] /-! ### Basic cardinals -/ theorem le_one_iff_subsingleton {α : Type u} : #α ≤ 1 ↔ Subsingleton α := ⟨fun ⟨f⟩ => ⟨fun _ _ => f.injective (Subsingleton.elim _ _)⟩, fun ⟨h⟩ => ⟨fun _ => ULift.up 0, fun _ _ _ => h _ _⟩⟩ @[simp] theorem mk_le_one_iff_set_subsingleton {s : Set α} : #s ≤ 1 ↔ s.Subsingleton := le_one_iff_subsingleton.trans s.subsingleton_coe alias ⟨_, _root_.Set.Subsingleton.cardinalMk_le_one⟩ := mk_le_one_iff_set_subsingleton @[deprecated (since := "2024-11-10")] alias _root_.Set.Subsingleton.cardinal_mk_le_one := Set.Subsingleton.cardinalMk_le_one private theorem cast_succ (n : ℕ) : ((n + 1 : ℕ) : Cardinal.{u}) = n + 1 := by change #(ULift.{u} _) = #(ULift.{u} _) + 1 rw [← mk_option] simp /-! ### Order properties -/ theorem one_lt_iff_nontrivial {α : Type u} : 1 < #α ↔ Nontrivial α := by rw [← not_le, le_one_iff_subsingleton, ← not_nontrivial_iff_subsingleton, Classical.not_not] lemma sInf_eq_zero_iff {s : Set Cardinal} : sInf s = 0 ↔ s = ∅ ∨ ∃ a ∈ s, a = 0 := by refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩ · rcases s.eq_empty_or_nonempty with rfl \| hne · exact Or.inl rfl · exact Or.inr ⟨sInf s, csInf_mem hne, h⟩ · rcases h with rfl \| ⟨a, ha, rfl⟩ · exact Cardinal.sInf_empty · exact eq_bot_iff.2 (csInf_le' ha) lemma iInf_eq_zero_iff {ι : Sort} {f : ι → Cardinal} : (⨅ i, f i) = 0 ↔ IsEmpty ι ∨ ∃ i, f i = 0 := by simp [iInf, sInf_eq_zero_iff] /-- A variant of `ciSup_of_empty` but with `0` on the RHS for convenience -/ protected theorem iSup_of_empty {ι} (f : ι → Cardinal) [IsEmpty ι] : iSup f = 0 := ciSup_of_empty f @[simp] theorem lift_sInf (s : Set Cardinal) : lift.{u, v} (sInf s) = sInf (lift.{u, v} '' s) := by rcases eq_empty_or_nonempty s with (rfl \| hs) · simp · exact lift_monotone.map_csInf hs @[simp] theorem lift_iInf {ι} (f : ι → Cardinal) : lift.{u, v} (iInf f) = ⨅ i, lift.{u, v} (f i) := by unfold iInf convert lift_sInf (range f) simp_rw [← comp_apply (f := lift), range_comp] end Cardinal /-! ### Small sets of cardinals -/ namespace Cardinal instance small_Iic (a : Cardinal.{u}) : Small.{u} (Iic a) := by rw [← mk_out a] apply @small_of_surjective (Set a.out) (Iic #a.out) _ fun x => ⟨#x, mk_set_le x⟩ rintro ⟨x, hx⟩ simpa using le_mk_iff_exists_set.1 hx instance small_Iio (a : Cardinal.{u}) : Small.{u} (Iio a) := small_subset Iio_subset_Iic_self instance small_Icc (a b : Cardinal.{u}) : Small.{u} (Icc a b) := small_subset Icc_subset_Iic_self instance small_Ico (a b : Cardinal.{u}) : Small.{u} (Ico a b) := small_subset Ico_subset_Iio_self instance small_Ioc (a b : Cardinal.{u}) : Small.{u} (Ioc a b) := small_subset Ioc_subset_Iic_self instance small_Ioo (a b : Cardinal.{u}) : Small.{u} (Ioo a b) := small_subset Ioo_subset_Iio_self /-- A set of cardinals is bounded above iff it's small, i.e. it corresponds to a usual ZFC set. -/ theorem bddAbove_iff_small {s : Set Cardinal.{u}} : BddAbove s ↔ Small.{u} s := ⟨fun ⟨a, ha⟩ => @small_subset _ (Iic a) s (fun _ h => ha h) _, by rintro ⟨ι, ⟨e⟩⟩ use sum.{u, u} fun x ↦ e.symm x intro a ha simpa using le_sum (fun x ↦ e.symm x) (e ⟨a, ha⟩)⟩ theorem bddAbove_of_small (s : Set Cardinal.{u}) [h : Small.{u} s] : BddAbove s := bddAbove_iff_small.2 h theorem bddAbove_range {ι : Type} [Small.{u} ι] (f : ι → Cardinal.{u}) : BddAbove (Set.range f) := bddAbove_of_small _ theorem bddAbove_image (f : Cardinal.{u} → Cardinal.{max u v}) {s : Set Cardinal.{u}} (hs : BddAbove s) : BddAbove (f '' s) := by rw [bddAbove_iff_small] at hs ⊢ exact small_lift _ theorem bddAbove_range_comp {ι : Type u} {f : ι → Cardinal.{v}} (hf : BddAbove (range f)) (g : Cardinal.{v} → Cardinal.{max v w}) : BddAbove (range (g ∘ f)) := by rw [range_comp] exact bddAbove_image g hf /-- The type of cardinals in universe `u` is not `Small.{u}`. This is a version of the Burali-Forti paradox. -/ theorem _root_.not_small_cardinal : ¬ Small.{u} Cardinal.{max u v} := by intro h have := small_lift.{_, v} Cardinal.{max u v} rw [← small_univ_iff, ← bddAbove_iff_small] at this exact not_bddAbove_univ this instance uncountable : Uncountable Cardinal.{u} := Uncountable.of_not_small not_small_cardinal.{u} /-! ### Bounds on suprema -/ theorem sum_le_iSup_lift {ι : Type u} (f : ι → Cardinal.{max u v}) : sum f ≤ Cardinal.lift #ι * iSup f := by rw [← (iSup f).lift_id, ← lift_umax, lift_umax.{max u v, u}, ← sum_const] exact sum_le_sum _ _ (le_ciSup <\| bddAbove_of_small _) theorem sum_le_iSup {ι : Type u} (f : ι → Cardinal.{u}) : sum f ≤ #ι * iSup f := by rw [← lift_id #ι] exact sum_le_iSup_lift f /-- The lift of a supremum is the supremum of the lifts. -/ theorem lift_sSup {s : Set Cardinal} (hs : BddAbove s) : lift.{u} (sSup s) = sSup (lift.{u} '' s) := by apply ((le_csSup_iff' (bddAbove_image.{_,u} _ hs)).2 fun c hc => _).antisymm (csSup_le' _) · intro c hc by_contra h obtain ⟨d, rfl⟩ := Cardinal.mem_range_lift_of_le (not_le.1 h).le simp_rw [lift_le] at h hc rw [csSup_le_iff' hs] at h exact h fun a ha => lift_le.1 <\| hc (mem_image_of_mem _ ha) · rintro i ⟨j, hj, rfl⟩ exact lift_le.2 (le_csSup hs hj) /-- The lift of a supremum is the supremum of the lifts. -/ theorem lift_iSup {ι : Type v} {f : ι → Cardinal.{w}} (hf : BddAbove (range f)) : lift.{u} (iSup f) = ⨆ i, lift.{u} (f i) := by rw [iSup, iSup, lift_sSup hf, ← range_comp] simp [Function.comp_def] /-- To prove that the lift of a supremum is bounded by some cardinal `t`, it suffices to show that the lift of each cardinal is bounded by `t`. -/ theorem lift_iSup_le {ι : Type v} {f : ι → Cardinal.{w}} {t : Cardinal} (hf : BddAbove (range f)) (w : ∀ i, lift.{u} (f i) ≤ t) : lift.{u} (iSup f) ≤ t := by rw [lift_iSup hf] exact ciSup_le' w @[simp] theorem lift_iSup_le_iff {ι : Type v} {f : ι → Cardinal.{w}} (hf : BddAbove (range f)) {t : Cardinal} : lift.{u} (iSup f) ≤ t ↔ ∀ i, lift.{u} (f i) ≤ t := by rw [lift_iSup hf] exact ciSup_le_iff' (bddAbove_range_comp.{_,_,u} hf _) /-- To prove an inequality between the lifts to a common universe of two different supremums, it suffices to show that the lift of each cardinal from the smaller supremum if bounded by the lift of some cardinal from the larger supremum. -/ theorem lift_iSup_le_lift_iSup {ι : Type v} {ι' : Type v'} {f : ι → Cardinal.{w}} {f' : ι' → Cardinal.{w'}} (hf : BddAbove (range f)) (hf' : BddAbove (range f')) {g : ι → ι'} (h : ∀ i, lift.{w'} (f i) ≤ lift.{w} (f' (g i))) : lift.{w'} (iSup f) ≤ lift.{w} (iSup f') := by rw [lift_iSup hf, lift_iSup hf'] exact ciSup_mono' (bddAbove_range_comp.{_,_,w} hf' _) fun i => ⟨_, h i⟩ /-- A variant of `lift_iSup_le_lift_iSup` with universes specialized via `w = v` and `w' = v'`. This is sometimes necessary to avoid universe unification issues. -/ theorem lift_iSup_le_lift_iSup' {ι : Type v} {ι' : Type v'} {f : ι → Cardinal.{v}} {f' : ι' → Cardinal.{v'}} (hf : BddAbove (range f)) (hf' : BddAbove (range f')) (g : ι → ι') (h : ∀ i, lift.{v'} (f i) ≤ lift.{v} (f' (g i))) : lift.{v'} (iSup f) ≤ lift.{v} (iSup f') := lift_iSup_le_lift_iSup hf hf' h /-! ### Properties about the cast from `ℕ` -/ theorem mk_finset_of_fintype [Fintype α] : #(Finset α) = 2 ^ Fintype.card α := by simp [Pow.pow] @[norm_cast] theorem nat_succ (n : ℕ) : (n.succ : Cardinal) = succ ↑n := by rw [Nat.cast_succ] refine (add_one_le_succ _).antisymm (succ_le_of_lt ?_) rw [← Nat.cast_succ] exact Nat.cast_lt.2 (Nat.lt_succ_self _) lemma succ_natCast (n : ℕ) : Order.succ (n : Cardinal) = n + 1 := by rw [← Cardinal.nat_succ] norm_cast lemma natCast_add_one_le_iff {n : ℕ} {c : Cardinal} : n + 1 ≤ c ↔ n < c := by rw [← Order.succ_le_iff, Cardinal.succ_natCast] lemma two_le_iff_one_lt {c : Cardinal} : 2 ≤ c ↔ 1 < c := by convert natCast_add_one_le_iff norm_cast @[simp] theorem succ_zero : succ (0 : Cardinal) = 1 := by norm_cast -- This works generally to prove inequalities between numeric cardinals. theorem one_lt_two : (1 : Cardinal) < 2 := by norm_cast theorem exists_finset_le_card (α : Type) (n : ℕ) (h : n ≤ #α) : ∃ s : Finset α, n ≤ s.card := by obtain hα\|hα := finite_or_infinite α · let hα := Fintype.ofFinite α use Finset.univ simpa only [mk_fintype, Nat.cast_le] using h · obtain ⟨s, hs⟩ := Infinite.exists_subset_card_eq α n exact ⟨s, hs.ge⟩ theorem card_le_of {α : Type u} {n : ℕ} (H : ∀ s : Finset α, s.card ≤ n) : #α ≤ n := by contrapose! H apply exists_finset_le_card α (n+1) simpa only [nat_succ, succ_le_iff] using H theorem cantor' (a) {b : Cardinal} (hb : 1 < b) : a < b ^ a := by rw [← succ_le_iff, (by norm_cast : succ (1 : Cardinal) = 2)] at hb exact (cantor a).trans_le (power_le_power_right hb) theorem one_le_iff_pos {c : Cardinal} : 1 ≤ c ↔ 0 < c := by rw [← succ_zero, succ_le_iff] theorem one_le_iff_ne_zero {c : Cardinal} : 1 ≤ c ↔ c ≠ 0 := by rw [one_le_iff_pos, pos_iff_ne_zero] @[simp] theorem lt_one_iff_zero {c : Cardinal} : c < 1 ↔ c = 0 := by simpa using lt_succ_bot_iff (a := c) /-! ### Properties about `aleph0` -/ theorem nat_lt_aleph0 (n : ℕ) : (n : Cardinal.{u}) < ℵ₀ := succ_le_iff.1 (by rw [← nat_succ, ← lift_mk_fin, aleph0, lift_mk_le.{u}] exact ⟨⟨(↑), fun a b => Fin.ext⟩⟩) @[simp] theorem one_lt_aleph0 : 1 < ℵ₀ := by simpa using nat_lt_aleph0 1 @[simp] theorem one_le_aleph0 : 1 ≤ ℵ₀ := one_lt_aleph0.le theorem lt_aleph0 {c : Cardinal} : c < ℵ₀ ↔ ∃ n : ℕ, c = n := ⟨fun h => by rcases lt_lift_iff.1 h with ⟨c, h', rfl⟩ rcases le_mk_iff_exists_set.1 h'.1 with ⟨S, rfl⟩ suffices S.Finite by lift S to Finset ℕ using this simp contrapose! h' haveI := Infinite.to_subtype h' exact ⟨Infinite.natEmbedding S⟩, fun ⟨_, e⟩ => e.symm ▸ nat_lt_aleph0 _⟩ lemma succ_eq_of_lt_aleph0 {c : Cardinal} (h : c < ℵ₀) : Order.succ c = c + 1 := by obtain ⟨n, hn⟩ := Cardinal.lt_aleph0.mp h rw [hn, succ_natCast] theorem aleph0_le {c : Cardinal} : ℵ₀ ≤ c ↔ ∀ n : ℕ, ↑n ≤ c := ⟨fun h _ => (nat_lt_aleph0 _).le.trans h, fun h => le_of_not_lt fun hn => by rcases lt_aleph0.1 hn with ⟨n, rfl⟩ exact (Nat.lt_succ_self _).not_le (Nat.cast_le.1 (h (n + 1)))⟩ theorem isSuccPrelimit_aleph0 : IsSuccPrelimit ℵ₀ := isSuccPrelimit_of_succ_lt fun a ha => by rcases lt_aleph0.1 ha with ⟨n, rfl⟩ rw [← nat_succ] apply nat_lt_aleph0 theorem isSuccLimit_aleph0 : IsSuccLimit ℵ₀ := by rw [Cardinal.isSuccLimit_iff] exact ⟨aleph0_ne_zero, isSuccPrelimit_aleph0⟩ lemma not_isSuccLimit_natCast : (n : ℕ) → ¬ IsSuccLimit (n : Cardinal.{u}) \| 0, e => e.1 isMin_bot \| Nat.succ n, e => Order.not_isSuccPrelimit_succ _ (nat_succ n ▸ e.2) theorem not_isSuccLimit_of_lt_aleph0 {c : Cardinal} (h : c < ℵ₀) : ¬ IsSuccLimit c := by obtain ⟨n, rfl⟩ := lt_aleph0.1 h exact not_isSuccLimit_natCast n theorem aleph0_le_of_isSuccLimit {c : Cardinal} (h : IsSuccLimit c) : ℵ₀ ≤ c := by contrapose! h exact not_isSuccLimit_of_lt_aleph0 h theorem isStrongLimit_aleph0 : IsStrongLimit ℵ₀ := by refine ⟨aleph0_ne_zero, fun x hx ↦ ?_⟩ obtain ⟨n, rfl⟩ := lt_aleph0.1 hx exact_mod_cast nat_lt_aleph0 _ theorem IsStrongLimit.aleph0_le {c} (H : IsStrongLimit c) : ℵ₀ ≤ c := aleph0_le_of_isSuccLimit H.isSuccLimit lemma exists_eq_natCast_of_iSup_eq {ι : Type u} [Nonempty ι] (f : ι → Cardinal.{v}) (hf : BddAbove (range f)) (n : ℕ) (h : ⨆ i, f i = n) : ∃ i, f i = n := exists_eq_of_iSup_eq_of_not_isSuccLimit.{u, v} f hf (not_isSuccLimit_natCast n) h @[simp] theorem range_natCast : range ((↑) : ℕ → Cardinal) = Iio ℵ₀ := ext fun x => by simp only [mem_Iio, mem_range, eq_comm, lt_aleph0] theorem mk_eq_nat_iff {α : Type u} {n : ℕ} : #α = n ↔ Nonempty (α ≃ Fin n) := by rw [← lift_mk_fin, ← lift_uzero #α, lift_mk_eq'] theorem lt_aleph0_iff_finite {α : Type u} : #α < ℵ₀ ↔ Finite α := by simp only [lt_aleph0, mk_eq_nat_iff, finite_iff_exists_equiv_fin] theorem lt_aleph0_iff_fintype {α : Type u} : #α < ℵ₀ ↔ Nonempty (Fintype α) := lt_aleph0_iff_finite.trans (finite_iff_nonempty_fintype _) theorem lt_aleph0_of_finite (α : Type u) [Finite α] : #α < ℵ₀ := lt_aleph0_iff_finite.2 ‹_› theorem lt_aleph0_iff_set_finite {S : Set α} : #S < ℵ₀ ↔ S.Finite := lt_aleph0_iff_finite.trans finite_coe_iff alias ⟨_, _root_.Set.Finite.lt_aleph0⟩ := lt_aleph0_iff_set_finite @[simp] theorem lt_aleph0_iff_subtype_finite {p : α → Prop} : #{ x // p x } < ℵ₀ ↔ { x \| p x }.Finite := lt_aleph0_iff_set_finite theorem mk_le_aleph0_iff : #α ≤ ℵ₀ ↔ Countable α := by rw [countable_iff_nonempty_embedding, aleph0, ← lift_uzero #α, lift_mk_le'] @[simp] theorem mk_le_aleph0 [Countable α] : #α ≤ ℵ₀ := mk_le_aleph0_iff.mpr ‹_› theorem le_aleph0_iff_set_countable {s : Set α} : #s ≤ ℵ₀ ↔ s.Countable := mk_le_aleph0_iff alias ⟨_, _root_.Set.Countable.le_aleph0⟩ := le_aleph0_iff_set_countable @[simp] theorem le_aleph0_iff_subtype_countable {p : α → Prop} : #{ x // p x } ≤ ℵ₀ ↔ { x \| p x }.Countable := le_aleph0_iff_set_countable theorem aleph0_lt_mk_iff : ℵ₀ < #α ↔ Uncountable α := by rw [← not_le, ← not_countable_iff, not_iff_not, mk_le_aleph0_iff] @[simp] theorem aleph0_lt_mk [Uncountable α] : ℵ₀ < #α := aleph0_lt_mk_iff.mpr ‹_› instance canLiftCardinalNat : CanLift Cardinal ℕ (↑) fun x => x < ℵ₀ := ⟨fun _ hx => let ⟨n, hn⟩ := lt_aleph0.mp hx ⟨n, hn.symm⟩⟩ theorem add_lt_aleph0 {a b : Cardinal} (ha : a < ℵ₀) (hb : b < ℵ₀) : a + b < ℵ₀ := match a, b, lt_aleph0.1 ha, lt_aleph0.1 hb with \| _, _, ⟨m, rfl⟩, ⟨n, rfl⟩ => by rw [← Nat.cast_add]; apply nat_lt_aleph0 theorem add_lt_aleph0_iff {a b : Cardinal} : a + b < ℵ₀ ↔ a < ℵ₀ ∧ b < ℵ₀ := ⟨fun h => ⟨(self_le_add_right _ _).trans_lt h, (self_le_add_left _ _).trans_lt h⟩, fun ⟨h1, h2⟩ => add_lt_aleph0 h1 h2⟩ theorem aleph0_le_add_iff {a b : Cardinal} : ℵ₀ ≤ a + b ↔ ℵ₀ ≤ a ∨ ℵ₀ ≤ b := by simp only [← not_lt, add_lt_aleph0_iff, not_and_or] /-- See also `Cardinal.nsmul_lt_aleph0_iff_of_ne_zero` if you already have `n ≠ 0`. -/ theorem nsmul_lt_aleph0_iff {n : ℕ} {a : Cardinal} : n • a < ℵ₀ ↔ n = 0 ∨ a < ℵ₀ := by cases n with \| zero => simpa using nat_lt_aleph0 0 \| succ n => simp only [Nat.succ_ne_zero, false_or] induction' n with n ih · simp rw [succ_nsmul, add_lt_aleph0_iff, ih, and_self_iff] /-- See also `Cardinal.nsmul_lt_aleph0_iff` for a hypothesis-free version. -/ theorem nsmul_lt_aleph0_iff_of_ne_zero {n : ℕ} {a : Cardinal} (h : n ≠ 0) : n • a < ℵ₀ ↔ a < ℵ₀ := nsmul_lt_aleph0_iff.trans <\| or_iff_right h theorem mul_lt_aleph0 {a b : Cardinal} (ha : a < ℵ₀) (hb : b < ℵ₀) : a b < ℵ₀ := match a, b, lt_aleph0.1 ha, lt_aleph0.1 hb with \| _, _, ⟨m, rfl⟩, ⟨n, rfl⟩ => by rw [← Nat.cast_mul]; apply nat_lt_aleph0 theorem mul_lt_aleph0_iff {a b : Cardinal} : a * b < ℵ₀ ↔ a = 0 ∨ b = 0 ∨ a < ℵ₀ ∧ b < ℵ₀ := by refine ⟨fun h => ?_, ?_⟩ · by_cases ha : a = 0 · exact Or.inl ha right by_cases hb : b = 0 · exact Or.inl hb right rw [← Ne, ← one_le_iff_ne_zero] at ha hb constructor · rw [← mul_one a] exact (mul_le_mul' le_rfl hb).trans_lt h · rw [← one_mul b] exact (mul_le_mul' ha le_rfl).trans_lt h rintro (rfl \| rfl \| ⟨ha, hb⟩) <;> simp only [, mul_lt_aleph0, aleph0_pos, zero_mul, mul_zero] /-- See also `Cardinal.aleph0_le_mul_iff`. -/ theorem aleph0_le_mul_iff {a b : Cardinal} : ℵ₀ ≤ a b ↔ a ≠ 0 ∧ b ≠ 0 ∧ (ℵ₀ ≤ a ∨ ℵ₀ ≤ b) := by let h := (@mul_lt_aleph0_iff a b).not rwa [not_lt, not_or, not_or, not_and_or, not_lt, not_lt] at h /-- See also `Cardinal.aleph0_le_mul_iff'`. -/ theorem aleph0_le_mul_iff' {a b : Cardinal.{u}} : ℵ₀ ≤ a * b ↔ a ≠ 0 ∧ ℵ₀ ≤ b ∨ ℵ₀ ≤ a ∧ b ≠ 0 := by have : ∀ {a : Cardinal.{u}}, ℵ₀ ≤ a → a ≠ 0 := fun a => ne_bot_of_le_ne_bot aleph0_ne_zero a simp only [aleph0_le_mul_iff, and_or_left, and_iff_right_of_imp this, @and_left_comm (a ≠ 0)] simp only [and_comm, or_comm] theorem mul_lt_aleph0_iff_of_ne_zero {a b : Cardinal} (ha : a ≠ 0) (hb : b ≠ 0) : a * b < ℵ₀ ↔ a < ℵ₀ ∧ b < ℵ₀ := by simp [mul_lt_aleph0_iff, ha, hb] theorem power_lt_aleph0 {a b : Cardinal} (ha : a < ℵ₀) (hb : b < ℵ₀) : a ^ b < ℵ₀ := match a, b, lt_aleph0.1 ha, lt_aleph0.1 hb with \| _, _, ⟨m, rfl⟩, ⟨n, rfl⟩ => by rw [power_natCast, ← Nat.cast_pow]; apply nat_lt_aleph0 theorem eq_one_iff_unique {α : Type} : #α = 1 ↔ Subsingleton α ∧ Nonempty α := calc #α = 1 ↔ #α ≤ 1 ∧ 1 ≤ #α := le_antisymm_iff _ ↔ Subsingleton α ∧ Nonempty α := le_one_iff_subsingleton.and (one_le_iff_ne_zero.trans mk_ne_zero_iff) theorem infinite_iff {α : Type u} : Infinite α ↔ ℵ₀ ≤ #α := by rw [← not_lt, lt_aleph0_iff_finite, not_finite_iff_infinite] lemma aleph0_le_mk_iff : ℵ₀ ≤ #α ↔ Infinite α := infinite_iff.symm lemma mk_lt_aleph0_iff : #α < ℵ₀ ↔ Finite α := by simp [← not_le, aleph0_le_mk_iff] @[simp] lemma mk_lt_aleph0 [Finite α] : #α < ℵ₀ := mk_lt_aleph0_iff.2 ‹_› @[simp] theorem aleph0_le_mk (α : Type u) [Infinite α] : ℵ₀ ≤ #α := infinite_iff.1 ‹_› @[simp] theorem mk_eq_aleph0 (α : Type) [Countable α] [Infinite α] : #α = ℵ₀ := mk_le_aleph0.antisymm <\| aleph0_le_mk _ theorem denumerable_iff {α : Type u} : Nonempty (Denumerable α) ↔ #α = ℵ₀ := ⟨fun ⟨h⟩ => mk_congr ((@Denumerable.eqv α h).trans Equiv.ulift.symm), fun h => by obtain ⟨f⟩ := Quotient.exact h exact ⟨Denumerable.mk' <\| f.trans Equiv.ulift⟩⟩ theorem mk_denumerable (α : Type u) [Denumerable α] : #α = ℵ₀ := denumerable_iff.1 ⟨‹_›⟩ theorem _root_.Set.countable_infinite_iff_nonempty_denumerable {α : Type} {s : Set α} : s.Countable ∧ s.Infinite ↔ Nonempty (Denumerable s) := by rw [nonempty_denumerable_iff, ← Set.infinite_coe_iff, countable_coe_iff] @[simp] theorem aleph0_add_aleph0 : ℵ₀ + ℵ₀ = ℵ₀ := mk_denumerable _ theorem aleph0_mul_aleph0 : ℵ₀ ℵ₀ = ℵ₀ := mk_denumerable _ @[simp] theorem nat_mul_aleph0 {n : ℕ} (hn : n ≠ 0) : ↑n * ℵ₀ = ℵ₀ := le_antisymm (lift_mk_fin n ▸ mk_le_aleph0) <\| le_mul_of_one_le_left (zero_le _) <\| by rwa [← Nat.cast_one, Nat.cast_le, Nat.one_le_iff_ne_zero] @[simp] theorem aleph0_mul_nat {n : ℕ} (hn : n ≠ 0) : ℵ₀ * n = ℵ₀ := by rw [mul_comm, nat_mul_aleph0 hn] @[simp] theorem ofNat_mul_aleph0 {n : ℕ} [Nat.AtLeastTwo n] : ofNat(n) * ℵ₀ = ℵ₀ := nat_mul_aleph0 (NeZero.ne n) @[simp] theorem aleph0_mul_ofNat {n : ℕ} [Nat.AtLeastTwo n] : ℵ₀ * ofNat(n) = ℵ₀ := aleph0_mul_nat (NeZero.ne n) @[simp] theorem add_le_aleph0 {c₁ c₂ : Cardinal} : c₁ + c₂ ≤ ℵ₀ ↔ c₁ ≤ ℵ₀ ∧ c₂ ≤ ℵ₀ := ⟨fun h => ⟨le_self_add.trans h, le_add_self.trans h⟩, fun h => aleph0_add_aleph0 ▸ add_le_add h.1 h.2⟩ @[simp] theorem aleph0_add_nat (n : ℕ) : ℵ₀ + n = ℵ₀ := (add_le_aleph0.2 ⟨le_rfl, (nat_lt_aleph0 n).le⟩).antisymm le_self_add @[simp] theorem nat_add_aleph0 (n : ℕ) : ↑n + ℵ₀ = ℵ₀ := by rw [add_comm, aleph0_add_nat] @[simp] theorem ofNat_add_aleph0 {n : ℕ} [Nat.AtLeastTwo n] : ofNat(n) + ℵ₀ = ℵ₀ := nat_add_aleph0 n @[simp] theorem aleph0_add_ofNat {n : ℕ} [Nat.AtLeastTwo n] : ℵ₀ + ofNat(n) = ℵ₀ := aleph0_add_nat n theorem exists_nat_eq_of_le_nat {c : Cardinal} {n : ℕ} (h : c ≤ n) : ∃ m, m ≤ n ∧ c = m := by lift c to ℕ using h.trans_lt (nat_lt_aleph0 _) exact ⟨c, mod_cast h, rfl⟩ theorem mk_int : #ℤ = ℵ₀ := mk_denumerable ℤ theorem mk_pnat : #ℕ+ = ℵ₀ := mk_denumerable ℕ+ @[deprecated (since := "2025-04-27")] alias mk_pNat := mk_pnat /-! ### Cardinalities of basic sets and types -/ @[simp] theorem mk_additive : #(Additive α) = #α := rfl @[simp] theorem mk_multiplicative : #(Multiplicative α) = #α := rfl @[to_additive (attr := simp)] theorem mk_mulOpposite : #(MulOpposite α) = #α := mk_congr MulOpposite.opEquiv.symm theorem mk_singleton {α : Type u} (x : α) : #({x} : Set α) = 1 := mk_eq_one _ @[simp] theorem mk_vector (α : Type u) (n : ℕ) : #(List.Vector α n) = #α ^ n := (mk_congr (Equiv.vectorEquivFin α n)).trans <\| by simp theorem mk_list_eq_sum_pow (α : Type u) : #(List α) = sum fun n : ℕ => #α ^ n := calc #(List α) = #(Σn, List.Vector α n) := mk_congr (Equiv.sigmaFiberEquiv List.length).symm _ = sum fun n : ℕ => #α ^ n := by simp theorem mk_quot_le {α : Type u} {r : α → α → Prop} : #(Quot r) ≤ #α := mk_le_of_surjective Quot.exists_rep theorem mk_quotient_le {α : Type u} {s : Setoid α} : #(Quotient s) ≤ #α := mk_quot_le theorem mk_subtype_le_of_subset {α : Type u} {p q : α → Prop} (h : ∀ ⦃x⦄, p x → q x) : #(Subtype p) ≤ #(Subtype q) := ⟨Embedding.subtypeMap (Embedding.refl α) h⟩ theorem mk_emptyCollection (α : Type u) : #(∅ : Set α) = 0 := mk_eq_zero _ theorem mk_emptyCollection_iff {α : Type u} {s : Set α} : #s = 0 ↔ s = ∅ := by constructor · intro h rw [mk_eq_zero_iff] at h exact eq_empty_iff_forall_not_mem.2 fun x hx => h.elim' ⟨x, hx⟩ · rintro rfl exact mk_emptyCollection _ @[simp] theorem mk_univ {α : Type u} : #(@univ α) = #α := mk_congr (Equiv.Set.univ α) @[simp] lemma mk_setProd {α β : Type u} (s : Set α) (t : Set β) : #(s ×ˢ t) = #s * #t := by rw [mul_def, mk_congr (Equiv.Set.prod ..)] theorem mk_image_le {α β : Type u} {f : α → β} {s : Set α} : #(f '' s) ≤ #s := mk_le_of_surjective surjective_onto_image lemma mk_image2_le {α β γ : Type u} {f : α → β → γ} {s : Set α} {t : Set β} : #(image2 f s t) ≤ #s * #t := by rw [← image_uncurry_prod, ← mk_setProd] exact mk_image_le theorem mk_image_le_lift {α : Type u} {β : Type v} {f : α → β} {s : Set α} : lift.{u} #(f '' s) ≤ lift.{v} #s := lift_mk_le.{0}.mpr ⟨Embedding.ofSurjective _ surjective_onto_image⟩ theorem mk_range_le {α β : Type u} {f : α → β} : #(range f) ≤ #α := mk_le_of_surjective surjective_onto_range theorem mk_range_le_lift {α : Type u} {β : Type v} {f : α → β} : lift.{u} #(range f) ≤ lift.{v} #α := lift_mk_le.{0}.mpr ⟨Embedding.ofSurjective _ surjective_onto_range⟩ theorem mk_range_eq (f : α → β) (h : Injective f) : #(range f) = #α := mk_congr (Equiv.ofInjective f h).symm theorem mk_range_eq_lift {α : Type u} {β : Type v} {f : α → β} (hf : Injective f) : lift.{max u w} #(range f) = lift.{max v w} #α := lift_mk_eq.{v,u,w}.mpr ⟨(Equiv.ofInjective f hf).symm⟩ theorem mk_range_eq_of_injective {α : Type u} {β : Type v} {f : α → β} (hf : Injective f) : lift.{u} #(range f) = lift.{v} #α := lift_mk_eq'.mpr ⟨(Equiv.ofInjective f hf).symm⟩ lemma lift_mk_le_lift_mk_of_injective {α : Type u} {β : Type v} {f : α → β} (hf : Injective f) : Cardinal.lift.{v} (#α) ≤ Cardinal.lift.{u} (#β) := by rw [← Cardinal.mk_range_eq_of_injective hf] exact Cardinal.lift_le.2 (Cardinal.mk_set_le _) lemma lift_mk_le_lift_mk_of_surjective {α : Type u} {β : Type v} {f : α → β} (hf : Surjective f) : Cardinal.lift.{u} (#β) ≤ Cardinal.lift.{v} (#α) := lift_mk_le_lift_mk_of_injective (injective_surjInv hf) theorem mk_image_eq_of_injOn {α β : Type u} (f : α → β) (s : Set α) (h : InjOn f s) : #(f '' s) = #s := mk_congr (Equiv.Set.imageOfInjOn f s h).symm theorem mk_image_eq_of_injOn_lift {α : Type u} {β : Type v} (f : α → β) (s : Set α) (h : InjOn f s) : lift.{u} #(f '' s) = lift.{v} #s := lift_mk_eq.{v, u, 0}.mpr ⟨(Equiv.Set.imageOfInjOn f s h).symm⟩ theorem mk_image_eq {α β : Type u} {f : α → β} {s : Set α} (hf : Injective f) : #(f '' s) = #s := mk_image_eq_of_injOn _ _ hf.injOn theorem mk_image_eq_lift {α : Type u} {β : Type v} (f : α → β) (s : Set α) (h : Injective f) : lift.{u} #(f '' s) = lift.{v} #s := mk_image_eq_of_injOn_lift _ _ h.injOn @[simp] theorem mk_image_embedding_lift {β : Type v} (f : α ↪ β) (s : Set α) : lift.{u} #(f '' s) = lift.{v} #s := mk_image_eq_lift _ _ f.injective @[simp] theorem mk_image_embedding (f : α ↪ β) (s : Set α) : #(f '' s) = #s := by simpa using mk_image_embedding_lift f s theorem mk_iUnion_le_sum_mk {α ι : Type u} {f : ι → Set α} : #(⋃ i, f i) ≤ sum fun i => #(f i) := calc #(⋃ i, f i) ≤ #(Σi, f i) := mk_le_of_surjective (Set.sigmaToiUnion_surjective f) _ = sum fun i => #(f i) := mk_sigma _ theorem mk_iUnion_le_sum_mk_lift {α : Type u} {ι : Type v} {f : ι → Set α} : lift.{v} #(⋃ i, f i) ≤ sum fun i => #(f i) := calc lift.{v} #(⋃ i, f i) ≤ #(Σi, f i) := mk_le_of_surjective <\| ULift.up_surjective.comp (Set.sigmaToiUnion_surjective f) _ = sum fun i => #(f i) := mk_sigma _ theorem mk_iUnion_eq_sum_mk {α ι : Type u} {f : ι → Set α} (h : Pairwise (Disjoint on f)) : #(⋃ i, f i) = sum fun i => #(f i) := calc #(⋃ i, f i) = #(Σi, f i) := mk_congr (Set.unionEqSigmaOfDisjoint h) _ = sum fun i => #(f i) := mk_sigma _ theorem mk_iUnion_eq_sum_mk_lift {α : Type u} {ι : Type v} {f : ι → Set α} (h : Pairwise (Disjoint on f)) : lift.{v} #(⋃ i, f i) = sum fun i => #(f i) := calc lift.{v} #(⋃ i, f i) = #(Σi, f i) := mk_congr <\| .trans Equiv.ulift (Set.unionEqSigmaOfDisjoint h) _ = sum fun i => #(f i) := mk_sigma _ theorem mk_iUnion_le {α ι : Type u} (f : ι → Set α) : #(⋃ i, f i) ≤ #ι * ⨆ i, #(f i) := mk_iUnion_le_sum_mk.trans (sum_le_iSup _) theorem mk_iUnion_le_lift {α : Type u} {ι : Type v} (f : ι → Set α) : lift.{v} #(⋃ i, f i) ≤ lift.{u} #ι * ⨆ i, lift.{v} #(f i) := by refine mk_iUnion_le_sum_mk_lift.trans <\| Eq.trans_le ?_ (sum_le_iSup_lift _) rw [← lift_sum, lift_id'.{_,u}] theorem mk_sUnion_le {α : Type u} (A : Set (Set α)) : #(⋃₀ A) ≤ #A * ⨆ s : A, #s := by rw [sUnion_eq_iUnion] apply mk_iUnion_le theorem mk_biUnion_le {ι α : Type u} (A : ι → Set α) (s : Set ι) : #(⋃ x ∈ s, A x) ≤ #s * ⨆ x : s, #(A x.1) := by rw [biUnion_eq_iUnion] apply mk_iUnion_le theorem mk_biUnion_le_lift {α : Type u} {ι : Type v} (A : ι → Set α) (s : Set ι) : lift.{v} #(⋃ x ∈ s, A x) ≤ lift.{u} #s * ⨆ x : s, lift.{v} #(A x.1) := by rw [biUnion_eq_iUnion] apply mk_iUnion_le_lift theorem finset_card_lt_aleph0 (s : Finset α) : #(↑s : Set α) < ℵ₀ := lt_aleph0_of_finite _ theorem mk_set_eq_nat_iff_finset {α} {s : Set α} {n : ℕ} : #s = n ↔ ∃ t : Finset α, (t : Set α) = s ∧ t.card = n := by constructor · intro h lift s to Finset α using lt_aleph0_iff_set_finite.1 (h.symm ▸ nat_lt_aleph0 n) simpa using h · rintro ⟨t, rfl, rfl⟩ exact mk_coe_finset theorem mk_eq_nat_iff_finset {n : ℕ} : #α = n ↔ ∃ t : Finset α, (t : Set α) = univ ∧ t.card = n := by rw [← mk_univ, mk_set_eq_nat_iff_finset] theorem mk_eq_nat_iff_fintype {n : ℕ} : #α = n ↔ ∃ h : Fintype α, @Fintype.card α h = n := by rw [mk_eq_nat_iff_finset] constructor · rintro ⟨t, ht, hn⟩ exact ⟨⟨t, eq_univ_iff_forall.1 ht⟩, hn⟩ · rintro ⟨⟨t, ht⟩, hn⟩ exact ⟨t, eq_univ_iff_forall.2 ht, hn⟩ theorem mk_union_add_mk_inter {α : Type u} {S T : Set α} : #(S ∪ T : Set α) + #(S ∩ T : Set α) = #S + #T := by classical exact Quot.sound ⟨Equiv.Set.unionSumInter S T⟩ /-- The cardinality of a union is at most the sum of the cardinalities of the two sets. -/ theorem mk_union_le {α : Type u} (S T : Set α) : #(S ∪ T : Set α) ≤ #S + #T := @mk_union_add_mk_inter α S T ▸ self_le_add_right #(S ∪ T : Set α) #(S ∩ T : Set α) theorem mk_union_of_disjoint {α : Type u} {S T : Set α} (H : Disjoint S T) : #(S ∪ T : Set α) = #S + #T := by classical exact Quot.sound ⟨Equiv.Set.union H⟩ theorem mk_insert {α : Type u} {s : Set α} {a : α} (h : a ∉ s) : #(insert a s : Set α) = #s + 1 := by rw [← union_singleton, mk_union_of_disjoint, mk_singleton] simpa theorem mk_insert_le {α : Type u} {s : Set α} {a : α} : #(insert a s : Set α) ≤ #s + 1 := by by_cases h : a ∈ s · simp only [insert_eq_of_mem h, self_le_add_right] · rw [mk_insert h] theorem mk_sum_compl {α} (s : Set α) : #s + #(sᶜ : Set α) = #α := by classical exact mk_congr (Equiv.Set.sumCompl s) theorem mk_le_mk_of_subset {α} {s t : Set α} (h : s ⊆ t) : #s ≤ #t := ⟨Set.embeddingOfSubset s t h⟩ theorem mk_le_iff_forall_finset_subset_card_le {α : Type u} {n : ℕ} {t : Set α} : #t ≤ n ↔ ∀ s : Finset α, (s : Set α) ⊆ t → s.card ≤ n := by refine ⟨fun H s hs ↦ by simpa using (mk_le_mk_of_subset hs).trans H, fun H ↦ ?_⟩ apply card_le_of (fun s ↦ ?_) classical let u : Finset α := s.image Subtype.val have : u.card = s.card := Finset.card_image_of_injOn Subtype.coe_injective.injOn rw [← this] apply H simp only [u, Finset.coe_image, image_subset_iff, Subtype.coe_preimage_self, subset_univ] theorem mk_subtype_mono {p q : α → Prop} (h : ∀ x, p x → q x) : #{ x // p x } ≤ #{ x // q x } := ⟨embeddingOfSubset _ _ h⟩ theorem le_mk_diff_add_mk (S T : Set α) : #S ≤ #(S \ T : Set α) + #T := (mk_le_mk_of_subset <\| subset_diff_union _ _).trans <\| mk_union_le _ _ theorem mk_diff_add_mk {S T : Set α} (h : T ⊆ S) : #(S \ T : Set α) + #T = #S := by refine (mk_union_of_disjoint <\| ?_).symm.trans <\| by rw [diff_union_of_subset h] exact disjoint_sdiff_self_left theorem mk_union_le_aleph0 {α} {P Q : Set α} : #(P ∪ Q : Set α) ≤ ℵ₀ ↔ #P ≤ ℵ₀ ∧ #Q ≤ ℵ₀ := by simp only [le_aleph0_iff_subtype_countable, mem_union, setOf_mem_eq, Set.union_def, ← countable_union] theorem mk_sep (s : Set α) (t : α → Prop) : #({ x ∈ s \| t x } : Set α) = #{ x : s \| t x.1 } := mk_congr (Equiv.Set.sep s t) theorem mk_preimage_of_injective_lift {α : Type u} {β : Type v} (f : α → β) (s : Set β) (h : Injective f) : lift.{v} #(f ⁻¹' s) ≤ lift.{u} #s := by rw [lift_mk_le.{0}] -- Porting note: Needed to insert `mem_preimage.mp` below use Subtype.coind (fun x => f x.1) fun x => mem_preimage.mp x.2 apply Subtype.coind_injective; exact h.comp Subtype.val_injective theorem mk_preimage_of_subset_range_lift {α : Type u} {β : Type v} (f : α → β) (s : Set β) (h : s ⊆ range f) : lift.{u} #s ≤ lift.{v} #(f ⁻¹' s) := by rw [← image_preimage_eq_iff] at h nth_rewrite 1 [← h] apply mk_image_le_lift theorem mk_preimage_of_injective_of_subset_range_lift {β : Type v} (f : α → β) (s : Set β) (h : Injective f) (h2 : s ⊆ range f) : lift.{v} #(f ⁻¹' s) = lift.{u} #s := le_antisymm (mk_preimage_of_injective_lift f s h) (mk_preimage_of_subset_range_lift f s h2) theorem mk_preimage_of_injective_of_subset_range (f : α → β) (s : Set β) (h : Injective f) (h2 : s ⊆ range f) : #(f ⁻¹' s) = #s := by convert mk_preimage_of_injective_of_subset_range_lift.{u, u} f s h h2 using 1 <;> rw [lift_id] @[simp] theorem mk_preimage_equiv_lift {β : Type v} (f : α ≃ β) (s : Set β) : lift.{v} #(f ⁻¹' s) = lift.{u} #s := by apply mk_preimage_of_injective_of_subset_range_lift _ _ f.injective rw [f.range_eq_univ] exact fun _ _ ↦ ⟨⟩ @[simp] theorem mk_preimage_equiv (f : α ≃ β) (s : Set β) : #(f ⁻¹' s) = #s := by simpa using mk_preimage_equiv_lift f s theorem mk_preimage_of_injective (f : α → β) (s : Set β) (h : Injective f) : #(f ⁻¹' s) ≤ #s := by rw [← lift_id #(↑(f ⁻¹' s)), ← lift_id #(↑s)] exact mk_preimage_of_injective_lift f s h theorem mk_preimage_of_subset_range (f : α → β) (s : Set β) (h : s ⊆ range f) : #s ≤ #(f ⁻¹' s) := by rw [← lift_id #(↑(f ⁻¹' s)), ← lift_id #(↑s)] exact mk_preimage_of_subset_range_lift f s h theorem mk_subset_ge_of_subset_image_lift {α : Type u} {β : Type v} (f : α → β) {s : Set α} {t : Set β} (h : t ⊆ f '' s) : lift.{u} #t ≤ lift.{v} #({ x ∈ s \| f x ∈ t } : Set α) := by rw [image_eq_range] at h convert mk_preimage_of_subset_range_lift _ _ h using 1 rw [mk_sep] rfl theorem mk_subset_ge_of_subset_image (f : α → β) {s : Set α} {t : Set β} (h : t ⊆ f '' s) : #t ≤ #({ x ∈ s \| f x ∈ t } : Set α) := by rw [image_eq_range] at h convert mk_preimage_of_subset_range _ _ h using 1 rw [mk_sep] rfl theorem le_mk_iff_exists_subset {c : Cardinal} {α : Type u} {s : Set α} : c ≤ #s ↔ ∃ p : Set α, p ⊆ s ∧ #p = c := by rw [le_mk_iff_exists_set, ← Subtype.exists_set_subtype] apply exists_congr; intro t; rw [mk_image_eq]; apply Subtype.val_injective @[simp] theorem mk_range_inl {α : Type u} {β : Type v} : #(range (@Sum.inl α β)) = lift.{v} #α := by rw [← lift_id'.{u, v} #_, (Equiv.Set.rangeInl α β).lift_cardinal_eq, lift_umax.{u, v}] @[simp] theorem mk_range_inr {α : Type u} {β : Type v} : #(range (@Sum.inr α β)) = lift.{u} #β := by rw [← lift_id'.{v, u} #_, (Equiv.Set.rangeInr α β).lift_cardinal_eq, lift_umax.{v, u}] theorem two_le_iff : (2 : Cardinal) ≤ #α ↔ ∃ x y : α, x ≠ y := by rw [← Nat.cast_two, nat_succ, succ_le_iff, Nat.cast_one, one_lt_iff_nontrivial, nontrivial_iff] theorem two_le_iff' (x : α) : (2 : Cardinal) ≤ #α ↔ ∃ y : α, y ≠ x := by rw [two_le_iff, ← nontrivial_iff, nontrivial_iff_exists_ne x] theorem mk_eq_two_iff : #α = 2 ↔ ∃ x y : α, x ≠ y ∧ ({x, y} : Set α) = univ := by classical simp only [← @Nat.cast_two Cardinal, mk_eq_nat_iff_finset, Finset.card_eq_two] constructor · rintro ⟨t, ht, x, y, hne, rfl⟩ exact ⟨x, y, hne, by simpa using ht⟩ · rintro ⟨x, y, hne, h⟩ exact ⟨{x, y}, by simpa using h, x, y, hne, rfl⟩ theorem mk_eq_two_iff' (x : α) : #α = 2 ↔ ∃! y, y ≠ x := by rw [mk_eq_two_iff]; constructor · rintro ⟨a, b, hne, h⟩ simp only [eq_univ_iff_forall, mem_insert_iff, mem_singleton_iff] at h rcases h x with (rfl \| rfl) exacts [⟨b, hne.symm, fun z => (h z).resolve_left⟩, ⟨a, hne, fun z => (h z).resolve_right⟩] · rintro ⟨y, hne, hy⟩ exact ⟨x, y, hne.symm, eq_univ_of_forall fun z => or_iff_not_imp_left.2 (hy z)⟩ theorem exists_not_mem_of_length_lt {α : Type} (l : List α) (h : ↑l.length < #α) : ∃ z : α, z ∉ l := by classical contrapose! h calc #α = #(Set.univ : Set α) := mk_univ.symm _ ≤ #l.toFinset := mk_le_mk_of_subset fun x _ => List.mem_toFinset.mpr (h x) _ = l.toFinset.card := Cardinal.mk_coe_finset _ ≤ l.length := Nat.cast_le.mpr (List.toFinset_card_le l) theorem three_le {α : Type} (h : 3 ≤ #α) (x : α) (y : α) : ∃ z : α, z ≠ x ∧ z ≠ y := by have : ↑(3 : ℕ) ≤ #α := by simpa using h have : ↑(2 : ℕ) < #α := by rwa [← succ_le_iff, ← Cardinal.nat_succ] have := exists_not_mem_of_length_lt [x, y] this simpa [not_or] using this /-! ### `powerlt` operation -/ /-- The function `a ^< b`, defined as the supremum of `a ^ c` for `c < b`. -/ def powerlt (a b : Cardinal.{u}) : Cardinal.{u} := ⨆ c : Iio b, a ^ (c : Cardinal) @[inherit_doc] infixl:80 " ^< " => powerlt theorem le_powerlt {b c : Cardinal.{u}} (a) (h : c < b) : (a^c) ≤ a ^< b := by refine le_ciSup (f := fun y : Iio b => a ^ (y : Cardinal)) ?_ ⟨c, h⟩ rw [← image_eq_range] exact bddAbove_image.{u, u} _ bddAbove_Iio theorem powerlt_le {a b c : Cardinal.{u}} : a ^< b ≤ c ↔ ∀ x < b, a ^ x ≤ c := by rw [powerlt, ciSup_le_iff'] · simp · rw [← image_eq_range] exact bddAbove_image.{u, u} _ bddAbove_Iio theorem powerlt_le_powerlt_left {a b c : Cardinal} (h : b ≤ c) : a ^< b ≤ a ^< c := powerlt_le.2 fun _ hx => le_powerlt a <\| hx.trans_le h theorem powerlt_mono_left (a) : Monotone fun c => a ^< c := fun _ _ => powerlt_le_powerlt_left theorem powerlt_succ {a b : Cardinal} (h : a ≠ 0) : a ^< succ b = a ^ b := (powerlt_le.2 fun _ h' => power_le_power_left h <\| le_of_lt_succ h').antisymm <\| le_powerlt a (lt_succ b) theorem powerlt_min {a b c : Cardinal} : a ^< min b c = min (a ^< b) (a ^< c) := (powerlt_mono_left a).map_min theorem powerlt_max {a b c : Cardinal} : a ^< max b c = max (a ^< b) (a ^< c) := (powerlt_mono_left a).map_max theorem zero_powerlt {a : Cardinal} (h : a ≠ 0) : 0 ^< a = 1 := by apply (powerlt_le.2 fun c _ => zero_power_le _).antisymm rw [← power_zero] exact le_powerlt 0 (pos_iff_ne_zero.2 h) @[simp] theorem powerlt_zero {a : Cardinal} : a ^< 0 = 0 := by convert Cardinal.iSup_of_empty _ exact Subtype.isEmpty_of_false fun x => mem_Iio.not.mpr (Cardinal.zero_le x).not_lt end Cardinal		Mathlib/SetTheory/Cardinal/Basic.lean	1,762	1,764
/- Copyright (c) 2017 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Algebra.Group.Basic import Mathlib.Algebra.Group.Nat.Defs import Mathlib.Data.Nat.Basic /-! # Partial predecessor and partial subtraction on the natural numbers The usual definition of natural number subtraction (`Nat.sub`) returns 0 as a "garbage value" for `a - b` when `a < b`. Similarly, `Nat.pred 0` is defined to be `0`. The functions in this file wrap the result in an `Option` type instead: ## Main definitions - `Nat.ppred`: a partial predecessor operation - `Nat.psub`: a partial subtraction operation -/ namespace Nat /-- Partial predecessor operation. Returns `ppred n = some m` if `n = m + 1`, otherwise `none`. -/ def ppred : ℕ → Option ℕ \| 0 => none \| n + 1 => some n @[simp] theorem ppred_zero : ppred 0 = none := rfl @[simp] theorem ppred_succ {n : ℕ} : ppred (succ n) = some n := rfl /-- Partial subtraction operation. Returns `psub m n = some k` if `m = n + k`, otherwise `none`. -/ def psub (m : ℕ) : ℕ → Option ℕ \| 0 => some m \| n + 1 => psub m n >>= ppred @[simp] theorem psub_zero {m : ℕ} : psub m 0 = some m := rfl @[simp] theorem psub_succ {m n : ℕ} : psub m (succ n) = psub m n >>= ppred := rfl theorem pred_eq_ppred (n : ℕ) : pred n = (ppred n).getD 0 := by cases n <;> rfl theorem sub_eq_psub (m : ℕ) : ∀ n, m - n = (psub m n).getD 0 \| 0 => rfl	\| n + 1 => (pred_eq_ppred (m - n)).trans <\| by rw [sub_eq_psub m n, psub]; cases psub m n <;> rfl	Mathlib/Data/Nat/PSub.lean	54	54
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Sébastien Gouëzel, Yury Kudryashov -/ import Mathlib.Dynamics.Ergodic.MeasurePreserving import Mathlib.LinearAlgebra.Determinant import Mathlib.LinearAlgebra.Matrix.Diagonal import Mathlib.LinearAlgebra.Matrix.Transvection import Mathlib.MeasureTheory.Group.LIntegral import Mathlib.MeasureTheory.Integral.Marginal import Mathlib.MeasureTheory.Measure.Stieltjes import Mathlib.MeasureTheory.Measure.Haar.OfBasis /-! # Lebesgue measure on the real line and on `ℝⁿ` We show that the Lebesgue measure on the real line (constructed as a particular case of additive Haar measure on inner product spaces) coincides with the Stieltjes measure associated to the function `x ↦ x`. We deduce properties of this measure on `ℝ`, and then of the product Lebesgue measure on `ℝⁿ`. In particular, we prove that they are translation invariant. We show that, on `ℝⁿ`, a linear map acts on Lebesgue measure by rescaling it through the absolute value of its determinant, in `Real.map_linearMap_volume_pi_eq_smul_volume_pi`. More properties of the Lebesgue measure are deduced from this in `Mathlib/MeasureTheory/Measure/Lebesgue/EqHaar.lean`, where they are proved more generally for any additive Haar measure on a finite-dimensional real vector space. -/ assert_not_exists MeasureTheory.integral noncomputable section open Set Filter MeasureTheory MeasureTheory.Measure TopologicalSpace open ENNReal (ofReal) open scoped ENNReal NNReal Topology /-! ### Definition of the Lebesgue measure and lengths of intervals -/ namespace Real variable {ι : Type} [Fintype ι] /-- The volume on the real line (as a particular case of the volume on a finite-dimensional inner product space) coincides with the Stieltjes measure coming from the identity function. -/ theorem volume_eq_stieltjes_id : (volume : Measure ℝ) = StieltjesFunction.id.measure := by haveI : IsAddLeftInvariant StieltjesFunction.id.measure := ⟨fun a => Eq.symm <\| Real.measure_ext_Ioo_rat fun p q => by simp only [Measure.map_apply (measurable_const_add a) measurableSet_Ioo, sub_sub_sub_cancel_right, StieltjesFunction.measure_Ioo, StieltjesFunction.id_leftLim, StieltjesFunction.id_apply, id, preimage_const_add_Ioo]⟩ have A : StieltjesFunction.id.measure (stdOrthonormalBasis ℝ ℝ).toBasis.parallelepiped = 1 := by change StieltjesFunction.id.measure (parallelepiped (stdOrthonormalBasis ℝ ℝ)) = 1 rcases parallelepiped_orthonormalBasis_one_dim (stdOrthonormalBasis ℝ ℝ) with (H \| H) <;> simp only [H, StieltjesFunction.measure_Icc, StieltjesFunction.id_apply, id, tsub_zero, StieltjesFunction.id_leftLim, sub_neg_eq_add, zero_add, ENNReal.ofReal_one] conv_rhs => rw [addHaarMeasure_unique StieltjesFunction.id.measure (stdOrthonormalBasis ℝ ℝ).toBasis.parallelepiped, A] simp only [volume, Basis.addHaar, one_smul] theorem volume_val (s) : volume s = StieltjesFunction.id.measure s := by simp [volume_eq_stieltjes_id] @[simp] theorem volume_Ico {a b : ℝ} : volume (Ico a b) = ofReal (b - a) := by simp [volume_val] @[simp] theorem volume_real_Ico {a b : ℝ} : volume.real (Ico a b) = max (b - a) 0 := by simp [measureReal_def, ENNReal.toReal_ofReal'] theorem volume_real_Ico_of_le {a b : ℝ} (hab : a ≤ b) : volume.real (Ico a b) = b - a := by simp [hab] @[simp] theorem volume_Icc {a b : ℝ} : volume (Icc a b) = ofReal (b - a) := by simp [volume_val] @[simp] theorem volume_real_Icc {a b : ℝ} : volume.real (Icc a b) = max (b - a) 0 := by simp [measureReal_def, ENNReal.toReal_ofReal'] theorem volume_real_Icc_of_le {a b : ℝ} (hab : a ≤ b) : volume.real (Icc a b) = b - a := by simp [hab] @[simp] theorem volume_Ioo {a b : ℝ} : volume (Ioo a b) = ofReal (b - a) := by simp [volume_val] @[simp] theorem volume_real_Ioo {a b : ℝ} : volume.real (Ioo a b) = max (b - a) 0 := by simp [measureReal_def, ENNReal.toReal_ofReal'] theorem volume_real_Ioo_of_le {a b : ℝ} (hab : a ≤ b) : volume.real (Ioo a b) = b - a := by simp [hab] @[simp] theorem volume_Ioc {a b : ℝ} : volume (Ioc a b) = ofReal (b - a) := by simp [volume_val] @[simp] theorem volume_real_Ioc {a b : ℝ} : volume.real (Ioc a b) = max (b - a) 0 := by simp [measureReal_def, ENNReal.toReal_ofReal'] theorem volume_real_Ioc_of_le {a b : ℝ} (hab : a ≤ b) : volume.real (Ioc a b) = b - a := by simp [hab] theorem volume_singleton {a : ℝ} : volume ({a} : Set ℝ) = 0 := by simp [volume_val] theorem volume_univ : volume (univ : Set ℝ) = ∞ := ENNReal.eq_top_of_forall_nnreal_le fun r => calc (r : ℝ≥0∞) = volume (Icc (0 : ℝ) r) := by simp _ ≤ volume univ := measure_mono (subset_univ _) @[simp] theorem volume_ball (a r : ℝ) : volume (Metric.ball a r) = ofReal (2 r) := by rw [ball_eq_Ioo, volume_Ioo, ← sub_add, add_sub_cancel_left, two_mul] @[simp] theorem volume_real_ball {a r : ℝ} (hr : 0 ≤ r) : volume.real (Metric.ball a r) = 2 * r := by simp [measureReal_def, hr] @[simp] theorem volume_closedBall (a r : ℝ) : volume (Metric.closedBall a r) = ofReal (2 * r) := by rw [closedBall_eq_Icc, volume_Icc, ← sub_add, add_sub_cancel_left, two_mul] @[simp] theorem volume_real_closedBall {a r : ℝ} (hr : 0 ≤ r) : volume.real (Metric.closedBall a r) = 2 * r := by simp [measureReal_def, hr] @[simp] theorem volume_emetric_ball (a : ℝ) (r : ℝ≥0∞) : volume (EMetric.ball a r) = 2 * r := by rcases eq_or_ne r ∞ with (rfl \| hr) · rw [Metric.emetric_ball_top, volume_univ, two_mul, _root_.top_add] · lift r to ℝ≥0 using hr rw [Metric.emetric_ball_nnreal, volume_ball, two_mul, ← NNReal.coe_add, ENNReal.ofReal_coe_nnreal, ENNReal.coe_add, two_mul] @[simp] theorem volume_emetric_closedBall (a : ℝ) (r : ℝ≥0∞) : volume (EMetric.closedBall a r) = 2 * r := by rcases eq_or_ne r ∞ with (rfl \| hr) · rw [EMetric.closedBall_top, volume_univ, two_mul, _root_.top_add] · lift r to ℝ≥0 using hr rw [Metric.emetric_closedBall_nnreal, volume_closedBall, two_mul, ← NNReal.coe_add, ENNReal.ofReal_coe_nnreal, ENNReal.coe_add, two_mul] instance noAtoms_volume : NoAtoms (volume : Measure ℝ) := ⟨fun _ => volume_singleton⟩ @[simp] theorem volume_interval {a b : ℝ} : volume (uIcc a b) = ofReal \|b - a\| := by rw [← Icc_min_max, volume_Icc, max_sub_min_eq_abs] @[simp] theorem volume_real_interval {a b : ℝ} : volume.real (uIcc a b) = \|b - a\| := by simp [measureReal_def] @[simp] theorem volume_Ioi {a : ℝ} : volume (Ioi a) = ∞ := top_unique <\| le_of_tendsto' ENNReal.tendsto_nat_nhds_top fun n => calc (n : ℝ≥0∞) = volume (Ioo a (a + n)) := by simp _ ≤ volume (Ioi a) := measure_mono Ioo_subset_Ioi_self @[simp] theorem volume_Ici {a : ℝ} : volume (Ici a) = ∞ := by rw [← measure_congr Ioi_ae_eq_Ici]; simp @[simp] theorem volume_Iio {a : ℝ} : volume (Iio a) = ∞ := top_unique <\| le_of_tendsto' ENNReal.tendsto_nat_nhds_top fun n => calc (n : ℝ≥0∞) = volume (Ioo (a - n) a) := by simp _ ≤ volume (Iio a) := measure_mono Ioo_subset_Iio_self @[simp] theorem volume_Iic {a : ℝ} : volume (Iic a) = ∞ := by rw [← measure_congr Iio_ae_eq_Iic]; simp instance locallyFinite_volume : IsLocallyFiniteMeasure (volume : Measure ℝ) := ⟨fun x => ⟨Ioo (x - 1) (x + 1), IsOpen.mem_nhds isOpen_Ioo ⟨sub_lt_self _ zero_lt_one, lt_add_of_pos_right _ zero_lt_one⟩, by simp only [Real.volume_Ioo, ENNReal.ofReal_lt_top]⟩⟩ instance isFiniteMeasure_restrict_Icc (x y : ℝ) : IsFiniteMeasure (volume.restrict (Icc x y)) := ⟨by simp⟩ instance isFiniteMeasure_restrict_Ico (x y : ℝ) : IsFiniteMeasure (volume.restrict (Ico x y)) := ⟨by simp⟩ instance isFiniteMeasure_restrict_Ioc (x y : ℝ) : IsFiniteMeasure (volume.restrict (Ioc x y)) := ⟨by simp⟩ instance isFiniteMeasure_restrict_Ioo (x y : ℝ) : IsFiniteMeasure (volume.restrict (Ioo x y)) := ⟨by simp⟩ theorem volume_le_diam (s : Set ℝ) : volume s ≤ EMetric.diam s := by by_cases hs : Bornology.IsBounded s · rw [Real.ediam_eq hs, ← volume_Icc] exact volume.mono hs.subset_Icc_sInf_sSup · rw [Metric.ediam_of_unbounded hs]; exact le_top theorem _root_.Filter.Eventually.volume_pos_of_nhds_real {p : ℝ → Prop} {a : ℝ} (h : ∀ᶠ x in 𝓝 a, p x) : (0 : ℝ≥0∞) < volume { x \| p x } := by rcases h.exists_Ioo_subset with ⟨l, u, hx, hs⟩ refine lt_of_lt_of_le ?_ (measure_mono hs) simpa [-mem_Ioo] using hx.1.trans hx.2 /-! ### Volume of a box in `ℝⁿ` -/ theorem volume_Icc_pi {a b : ι → ℝ} : volume (Icc a b) = ∏ i, ENNReal.ofReal (b i - a i) := by rw [← pi_univ_Icc, volume_pi_pi] simp only [Real.volume_Icc] @[simp] theorem volume_Icc_pi_toReal {a b : ι → ℝ} (h : a ≤ b) : (volume (Icc a b)).toReal = ∏ i, (b i - a i) := by simp only [volume_Icc_pi, ENNReal.toReal_prod, ENNReal.toReal_ofReal (sub_nonneg.2 (h _))] theorem volume_pi_Ioo {a b : ι → ℝ} : volume (pi univ fun i => Ioo (a i) (b i)) = ∏ i, ENNReal.ofReal (b i - a i) := (measure_congr Measure.univ_pi_Ioo_ae_eq_Icc).trans volume_Icc_pi @[simp] theorem volume_pi_Ioo_toReal {a b : ι → ℝ} (h : a ≤ b) : (volume (pi univ fun i => Ioo (a i) (b i))).toReal = ∏ i, (b i - a i) := by simp only [volume_pi_Ioo, ENNReal.toReal_prod, ENNReal.toReal_ofReal (sub_nonneg.2 (h _))] theorem volume_pi_Ioc {a b : ι → ℝ} : volume (pi univ fun i => Ioc (a i) (b i)) = ∏ i, ENNReal.ofReal (b i - a i) := (measure_congr Measure.univ_pi_Ioc_ae_eq_Icc).trans volume_Icc_pi @[simp] theorem volume_pi_Ioc_toReal {a b : ι → ℝ} (h : a ≤ b) : (volume (pi univ fun i => Ioc (a i) (b i))).toReal = ∏ i, (b i - a i) := by simp only [volume_pi_Ioc, ENNReal.toReal_prod, ENNReal.toReal_ofReal (sub_nonneg.2 (h _))] theorem volume_pi_Ico {a b : ι → ℝ} : volume (pi univ fun i => Ico (a i) (b i)) = ∏ i, ENNReal.ofReal (b i - a i) := (measure_congr Measure.univ_pi_Ico_ae_eq_Icc).trans volume_Icc_pi @[simp] theorem volume_pi_Ico_toReal {a b : ι → ℝ} (h : a ≤ b) : (volume (pi univ fun i => Ico (a i) (b i))).toReal = ∏ i, (b i - a i) := by simp only [volume_pi_Ico, ENNReal.toReal_prod, ENNReal.toReal_ofReal (sub_nonneg.2 (h _))] @[simp] nonrec theorem volume_pi_ball (a : ι → ℝ) {r : ℝ} (hr : 0 < r) : volume (Metric.ball a r) = ENNReal.ofReal ((2 * r) ^ Fintype.card ι) := by simp only [MeasureTheory.volume_pi_ball a hr, volume_ball, Finset.prod_const] exact (ENNReal.ofReal_pow (mul_nonneg zero_le_two hr.le) _).symm @[simp] nonrec theorem volume_pi_closedBall (a : ι → ℝ) {r : ℝ} (hr : 0 ≤ r) : volume (Metric.closedBall a r) = ENNReal.ofReal ((2 * r) ^ Fintype.card ι) := by simp only [MeasureTheory.volume_pi_closedBall a hr, volume_closedBall, Finset.prod_const] exact (ENNReal.ofReal_pow (mul_nonneg zero_le_two hr) _).symm theorem volume_pi_le_prod_diam (s : Set (ι → ℝ)) : volume s ≤ ∏ i : ι, EMetric.diam (Function.eval i '' s) := calc volume s ≤ volume (pi univ fun i => closure (Function.eval i '' s)) := volume.mono <\| Subset.trans (subset_pi_eval_image univ s) <\| pi_mono fun _ _ => subset_closure _ = ∏ i, volume (closure <\| Function.eval i '' s) := volume_pi_pi _ _ ≤ ∏ i : ι, EMetric.diam (Function.eval i '' s) := Finset.prod_le_prod' fun _ _ => (volume_le_diam _).trans_eq (EMetric.diam_closure _) theorem volume_pi_le_diam_pow (s : Set (ι → ℝ)) : volume s ≤ EMetric.diam s ^ Fintype.card ι := calc volume s ≤ ∏ i : ι, EMetric.diam (Function.eval i '' s) := volume_pi_le_prod_diam s _ ≤ ∏ _i : ι, (1 : ℝ≥0) * EMetric.diam s := (Finset.prod_le_prod' fun i _ => (LipschitzWith.eval i).ediam_image_le s) _ = EMetric.diam s ^ Fintype.card ι := by simp only [ENNReal.coe_one, one_mul, Finset.prod_const, Fintype.card] /-! ### Images of the Lebesgue measure under multiplication in ℝ -/ theorem smul_map_volume_mul_left {a : ℝ} (h : a ≠ 0) : ENNReal.ofReal \|a\| • Measure.map (a * ·) volume = volume := by refine (Real.measure_ext_Ioo_rat fun p q => ?_).symm rcases lt_or_gt_of_ne h with h \| h · simp only [Real.volume_Ioo, Measure.smul_apply, ← ENNReal.ofReal_mul (le_of_lt <\| neg_pos.2 h), Measure.map_apply (measurable_const_mul a) measurableSet_Ioo, neg_sub_neg, neg_mul, preimage_const_mul_Ioo_of_neg _ _ h, abs_of_neg h, mul_sub, smul_eq_mul, mul_div_cancel₀ _ (ne_of_lt h)] · simp only [Real.volume_Ioo, Measure.smul_apply, ← ENNReal.ofReal_mul (le_of_lt h), Measure.map_apply (measurable_const_mul a) measurableSet_Ioo, preimage_const_mul_Ioo _ _ h, abs_of_pos h, mul_sub, mul_div_cancel₀ _ (ne_of_gt h), smul_eq_mul] theorem map_volume_mul_left {a : ℝ} (h : a ≠ 0) : Measure.map (a * ·) volume = ENNReal.ofReal \|a⁻¹\| • volume := by conv_rhs => rw [← Real.smul_map_volume_mul_left h, smul_smul, ← ENNReal.ofReal_mul (abs_nonneg _), ← abs_mul, inv_mul_cancel₀ h, abs_one, ENNReal.ofReal_one, one_smul] @[simp] theorem volume_preimage_mul_left {a : ℝ} (h : a ≠ 0) (s : Set ℝ) : volume ((a * ·) ⁻¹' s) = ENNReal.ofReal (abs a⁻¹) * volume s := calc volume ((a * ·) ⁻¹' s) = Measure.map (a * ·) volume s := ((Homeomorph.mulLeft₀ a h).toMeasurableEquiv.map_apply s).symm _ = ENNReal.ofReal (abs a⁻¹) * volume s := by rw [map_volume_mul_left h]; rfl theorem smul_map_volume_mul_right {a : ℝ} (h : a ≠ 0) : ENNReal.ofReal \|a\| • Measure.map (· * a) volume = volume := by simpa only [mul_comm] using Real.smul_map_volume_mul_left h theorem map_volume_mul_right {a : ℝ} (h : a ≠ 0) : Measure.map (· * a) volume = ENNReal.ofReal \|a⁻¹\| • volume := by simpa only [mul_comm] using Real.map_volume_mul_left h @[simp] theorem volume_preimage_mul_right {a : ℝ} (h : a ≠ 0) (s : Set ℝ) : volume ((· * a) ⁻¹' s) = ENNReal.ofReal (abs a⁻¹) * volume s := calc volume ((· * a) ⁻¹' s) = Measure.map (· * a) volume s := ((Homeomorph.mulRight₀ a h).toMeasurableEquiv.map_apply s).symm _ = ENNReal.ofReal (abs a⁻¹) * volume s := by rw [map_volume_mul_right h]; rfl /-! ### Images of the Lebesgue measure under translation/linear maps in ℝⁿ -/ open Matrix /-- A diagonal matrix rescales Lebesgue according to its determinant. This is a special case of `Real.map_matrix_volume_pi_eq_smul_volume_pi`, that one should use instead (and whose proof uses this particular case). -/ theorem smul_map_diagonal_volume_pi [DecidableEq ι] {D : ι → ℝ} (h : det (diagonal D) ≠ 0) : ENNReal.ofReal (abs (det (diagonal D))) • Measure.map (toLin' (diagonal D)) volume = volume := by refine (Measure.pi_eq fun s hs => ?_).symm simp only [det_diagonal, Measure.coe_smul, Algebra.id.smul_eq_mul, Pi.smul_apply] rw [Measure.map_apply _ (MeasurableSet.univ_pi hs)] swap; · exact Continuous.measurable (LinearMap.continuous_on_pi _) have : (Matrix.toLin' (diagonal D) ⁻¹' Set.pi Set.univ fun i : ι => s i) = Set.pi Set.univ fun i : ι => (D i * ·) ⁻¹' s i := by ext f simp only [LinearMap.coe_proj, Algebra.id.smul_eq_mul, LinearMap.smul_apply, mem_univ_pi, mem_preimage, LinearMap.pi_apply, diagonal_toLin'] have B : ∀ i, ofReal (abs (D i)) * volume ((D i * ·) ⁻¹' s i) = volume (s i) := by intro i have A : D i ≠ 0 := by simp only [det_diagonal, Ne] at h exact Finset.prod_ne_zero_iff.1 h i (Finset.mem_univ i) rw [volume_preimage_mul_left A, ← mul_assoc, ← ENNReal.ofReal_mul (abs_nonneg _), ← abs_mul, mul_inv_cancel₀ A, abs_one, ENNReal.ofReal_one, one_mul] rw [this, volume_pi_pi, Finset.abs_prod, ENNReal.ofReal_prod_of_nonneg fun i _ => abs_nonneg (D i), ← Finset.prod_mul_distrib] simp only [B] /-- A transvection preserves Lebesgue measure. -/ theorem volume_preserving_transvectionStruct [DecidableEq ι] (t : TransvectionStruct ι ℝ) : MeasurePreserving (toLin' t.toMatrix) := by /- We use `lmarginal` to conveniently use Fubini's theorem. Along the coordinate where there is a shearing, it acts like a translation, and therefore preserves Lebesgue. -/ have ht : Measurable (toLin' t.toMatrix) := (toLin' t.toMatrix).continuous_of_finiteDimensional.measurable refine ⟨ht, ?_⟩ refine (pi_eq fun s hs ↦ ?_).symm have h2s : MeasurableSet (univ.pi s) := .pi countable_univ fun i _ ↦ hs i simp_rw [← pi_pi, ← lintegral_indicator_one h2s] rw [lintegral_map (measurable_one.indicator h2s) ht, volume_pi] refine lintegral_eq_of_lmarginal_eq {t.i} ((measurable_one.indicator h2s).comp ht) (measurable_one.indicator h2s) ?_ simp_rw [lmarginal_singleton] ext x cases t with \| mk t_i t_j t_hij t_c => simp [transvection, mulVec_stdBasisMatrix, t_hij.symm, ← Function.update_add, lintegral_add_right_eq_self fun xᵢ ↦ indicator (univ.pi s) 1 (Function.update x t_i xᵢ)] /-- Any invertible matrix rescales Lebesgue measure through the absolute value of its determinant. -/ theorem map_matrix_volume_pi_eq_smul_volume_pi [DecidableEq ι] {M : Matrix ι ι ℝ} (hM : det M ≠ 0) : Measure.map (toLin' M) volume = ENNReal.ofReal (abs (det M)⁻¹) • volume := by -- This follows from the cases we have already proved, of diagonal matrices and transvections, -- as these matrices generate all invertible matrices. apply diagonal_transvection_induction_of_det_ne_zero _ M hM · intro D hD conv_rhs => rw [← smul_map_diagonal_volume_pi hD] rw [smul_smul, ← ENNReal.ofReal_mul (abs_nonneg _), ← abs_mul, inv_mul_cancel₀ hD, abs_one, ENNReal.ofReal_one, one_smul] · intro t simp_rw [Matrix.TransvectionStruct.det, _root_.inv_one, abs_one, ENNReal.ofReal_one, one_smul, (volume_preserving_transvectionStruct _).map_eq] · intro A B _ _ IHA IHB rw [toLin'_mul, det_mul, LinearMap.coe_comp, ← Measure.map_map, IHB, Measure.map_smul, IHA, smul_smul, ← ENNReal.ofReal_mul (abs_nonneg _), ← abs_mul, mul_comm, mul_inv] · apply Continuous.measurable apply LinearMap.continuous_on_pi · apply Continuous.measurable apply LinearMap.continuous_on_pi /-- Any invertible linear map rescales Lebesgue measure through the absolute value of its determinant. -/ theorem map_linearMap_volume_pi_eq_smul_volume_pi {f : (ι → ℝ) →ₗ[ℝ] ι → ℝ} (hf : LinearMap.det f ≠ 0) : Measure.map f volume = ENNReal.ofReal (abs (LinearMap.det f)⁻¹) • volume := by classical -- this is deduced from the matrix case let M := LinearMap.toMatrix' f have A : LinearMap.det f = det M := by simp only [M, LinearMap.det_toMatrix'] have B : f = toLin' M := by simp only [M, toLin'_toMatrix'] rw [A, B] apply map_matrix_volume_pi_eq_smul_volume_pi	rwa [A] at hf end Real section regionBetween variable {α : Type*} /-- The region between two real-valued functions on an arbitrary set. -/ def regionBetween (f g : α → ℝ) (s : Set α) : Set (α × ℝ) := { p : α × ℝ \| p.1 ∈ s ∧ p.2 ∈ Ioo (f p.1) (g p.1) }	Mathlib/MeasureTheory/Measure/Lebesgue/Basic.lean	425	435
/- Copyright (c) 2020 Jannis Limperg. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jannis Limperg -/ import Mathlib.Data.List.Induction /-! # Lemmas about List.Idx functions. Some specification lemmas for `List.mapIdx`, `List.mapIdxM`, `List.foldlIdx` and `List.foldrIdx`. As of 2025-01-29, these are not used anywhere in Mathlib. Moreover, with `List.enum` and `List.enumFrom` being replaced by `List.zipIdx` in Lean's `nightly-2025-01-29` release, they now use deprecated functions and theorems. Rather than updating this unused material, we are deprecating it. Anyone wanting to restore this material is welcome to do so, but will need to update uses of `List.enum` and `List.enumFrom` to use `List.zipIdx` instead. However, note that this material will later be implemented in the Lean standard library. -/ assert_not_exists MonoidWithZero universe u v open Function namespace List variable {α : Type u} {β : Type v} section MapIdx @[deprecated reverseRecOn (since := "2025-01-28")] theorem list_reverse_induction (p : List α → Prop) (base : p []) (ind : ∀ (l : List α) (e : α), p l → p (l ++ [e])) : (∀ (l : List α), p l) := fun l => l.reverseRecOn base ind theorem mapIdx_append_one : ∀ {f : ℕ → α → β} {l : List α} {e : α}, mapIdx f (l ++ [e]) = mapIdx f l ++ [f l.length e] := mapIdx_concat set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29"), local simp] theorem map_enumFrom_eq_zipWith : ∀ (l : List α) (n : ℕ) (f : ℕ → α → β), map (uncurry f) (enumFrom n l) = zipWith (fun i ↦ f (i + n)) (range (length l)) l := by intro l generalize e : l.length = len revert l induction' len with len ih <;> intros l e n f · have : l = [] := by cases l · rfl · contradiction rw [this]; rfl · rcases l with - \| ⟨head, tail⟩ · contradiction · simp only [enumFrom_cons, map_cons, range_succ_eq_map, zipWith_cons_cons, Nat.zero_add, zipWith_map_left, true_and] rw [ih] · suffices (fun i ↦ f (i + (n + 1))) = ((fun i ↦ f (i + n)) ∘ Nat.succ) by rw [this] rfl funext n' a simp only [comp, Nat.add_assoc, Nat.add_comm, Nat.add_succ] simp only [length_cons, Nat.succ.injEq] at e; exact e set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem get_mapIdx (l : List α) (f : ℕ → α → β) (i : ℕ) (h : i < l.length) (h' : i < (l.mapIdx f).length := h.trans_le length_mapIdx.ge) : (l.mapIdx f).get ⟨i, h'⟩ = f i (l.get ⟨i, h⟩) := by simp [mapIdx_eq_zipIdx_map, enum_eq_zip_range] theorem mapIdx_eq_ofFn (l : List α) (f : ℕ → α → β) : l.mapIdx f = ofFn fun i : Fin l.length ↦ f (i : ℕ) (l.get i) := by induction l generalizing f with \| nil => simp \| cons _ _ IH => simp [IH] end MapIdx section FoldrIdx -- Porting note: Changed argument order of `foldrIdxSpec` to align better with `foldrIdx`. set_option linter.deprecated false in /-- Specification of `foldrIdx`. -/ @[deprecated "Deprecated without replacement." (since := "2025-01-29")] def foldrIdxSpec (f : ℕ → α → β → β) (b : β) (as : List α) (start : ℕ) : β := foldr (uncurry f) b <\| enumFrom start as set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldrIdxSpec_cons (f : ℕ → α → β → β) (b a as start) : foldrIdxSpec f b (a :: as) start = f start a (foldrIdxSpec f b as (start + 1)) := rfl set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldrIdx_eq_foldrIdxSpec (f : ℕ → α → β → β) (b as start) : foldrIdx f b as start = foldrIdxSpec f b as start := by induction as generalizing start · rfl · simp only [foldrIdx, foldrIdxSpec_cons, ] set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldrIdx_eq_foldr_enum (f : ℕ → α → β → β) (b : β) (as : List α) : foldrIdx f b as = foldr (uncurry f) b (enum as) := by simp only [foldrIdx, foldrIdxSpec, foldrIdx_eq_foldrIdxSpec, enum] end FoldrIdx set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem indexesValues_eq_filter_enum (p : α → Prop) [DecidablePred p] (as : List α) : indexesValues p as = filter (p ∘ Prod.snd) (enum as) := by simp +unfoldPartialApp [indexesValues, foldrIdx_eq_foldr_enum, uncurry, filter_eq_foldr, cond_eq_if] set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem findIdxs_eq_map_indexesValues (p : α → Prop) [DecidablePred p] (as : List α) : findIdxs p as = map Prod.fst (indexesValues p as) := by simp +unfoldPartialApp only [indexesValues_eq_filter_enum, map_filter_eq_foldr, findIdxs, uncurry, foldrIdx_eq_foldr_enum, decide_eq_true_eq, comp_apply, Bool.cond_decide] section FoldlIdx -- Porting note: Changed argument order of `foldlIdxSpec` to align better with `foldlIdx`. set_option linter.deprecated false in /-- Specification of `foldlIdx`. -/ @[deprecated "Deprecated without replacement." (since := "2025-01-29")] def foldlIdxSpec (f : ℕ → α → β → α) (a : α) (bs : List β) (start : ℕ) : α := foldl (fun a p ↦ f p.fst a p.snd) a <\| enumFrom start bs set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldlIdxSpec_cons (f : ℕ → α → β → α) (a b bs start) : foldlIdxSpec f a (b :: bs) start = foldlIdxSpec f (f start a b) bs (start + 1) := rfl set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldlIdx_eq_foldlIdxSpec (f : ℕ → α → β → α) (a bs start) : foldlIdx f a bs start = foldlIdxSpec f a bs start := by induction bs generalizing start a · rfl · simp [foldlIdxSpec, ] set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldlIdx_eq_foldl_enum (f : ℕ → α → β → α) (a : α) (bs : List β) : foldlIdx f a bs = foldl (fun a p ↦ f p.fst a p.snd) a (enum bs) := by simp only [foldlIdx, foldlIdxSpec, foldlIdx_eq_foldlIdxSpec, enum] end FoldlIdx section FoldIdxM -- Porting note: `foldrM_eq_foldr` now depends on `[LawfulMonad m]` variable {m : Type u → Type v} [Monad m] set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldrIdxM_eq_foldrM_enum {β} (f : ℕ → α → β → m β) (b : β) (as : List α) [LawfulMonad m] : foldrIdxM f b as = foldrM (uncurry f) b (enum as) := by simp +unfoldPartialApp only [foldrIdxM, foldrM_eq_foldr, foldrIdx_eq_foldr_enum, uncurry] set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem foldlIdxM_eq_foldlM_enum [LawfulMonad m] {β} (f : ℕ → β → α → m β) (b : β) (as : List α) : foldlIdxM f b as = List.foldlM (fun b p ↦ f p.fst b p.snd) b (enum as) := by rw [foldlIdxM, foldlM_eq_foldl, foldlIdx_eq_foldl_enum] end FoldIdxM section MapIdxM -- Porting note: `[Applicative m]` replaced by `[Monad m] [LawfulMonad m]` variable {m : Type u → Type v} [Monad m] set_option linter.deprecated false in /-- Specification of `mapIdxMAux`. -/ @[deprecated "Deprecated without replacement." (since := "2025-01-29")] def mapIdxMAuxSpec {β} (f : ℕ → α → m β) (start : ℕ) (as : List α) : m (List β) := List.traverse (uncurry f) <\| enumFrom start as -- Note: `traverse` the class method would require a less universe-polymorphic -- `m : Type u → Type u`. set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem mapIdxMAuxSpec_cons {β} (f : ℕ → α → m β) (start : ℕ) (a : α) (as : List α) : mapIdxMAuxSpec f start (a :: as) = cons <$> f start a <> mapIdxMAuxSpec f (start + 1) as := rfl set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem mapIdxMGo_eq_mapIdxMAuxSpec [LawfulMonad m] {β} (f : ℕ → α → m β) (arr : Array β) (as : List α) : mapIdxM.go f as arr = (arr.toList ++ ·) <$> mapIdxMAuxSpec f arr.size as := by generalize e : as.length = len revert as arr induction' len with len ih <;> intro arr as h · have : as = [] := by cases as · rfl · contradiction simp only [this, mapIdxM.go, mapIdxMAuxSpec, enumFrom_nil, List.traverse, map_pure, append_nil] · match as with \| nil => contradiction \| cons head tail => simp only [length_cons, Nat.succ.injEq] at h simp only [mapIdxM.go, mapIdxMAuxSpec_cons, map_eq_pure_bind, seq_eq_bind_map, LawfulMonad.bind_assoc, pure_bind] congr conv => { lhs; intro x; rw [ih _ _ h]; } funext x simp only [Array.push_toList, append_assoc, singleton_append, Array.size_push, map_eq_pure_bind] set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-01-29")] theorem mapIdxM_eq_mmap_enum [LawfulMonad m] {β} (f : ℕ → α → m β) (as : List α) : as.mapIdxM f = List.traverse (uncurry f) (enum as) := by simp only [mapIdxM, mapIdxMGo_eq_mapIdxMAuxSpec, Array.toList_toArray, nil_append, mapIdxMAuxSpec, Array.size_toArray, length_nil, id_map', enum] end MapIdxM section MapIdxM' -- Porting note: `[Applicative m] [LawfulApplicative m]` replaced by [Monad m] [LawfulMonad m] variable {m : Type u → Type v} [Monad m] [LawfulMonad m] theorem mapIdxMAux'_eq_mapIdxMGo {α} (f : ℕ → α → m PUnit) (as : List α) (arr : Array PUnit) : mapIdxMAux' f arr.size as = mapIdxM.go f as arr > pure PUnit.unit := by revert arr induction' as with head tail ih <;> intro arr · simp only [mapIdxMAux', mapIdxM.go, seqRight_eq, map_pure, seq_pure] · simp only [mapIdxMAux', seqRight_eq, map_eq_pure_bind, seq_eq_bind, bind_pure_unit, LawfulMonad.bind_assoc, pure_bind, mapIdxM.go, seq_pure] generalize (f (Array.size arr) head) = head have : (arr.push ⟨⟩).size = arr.size + 1 := Array.size_push _ rw [← this, ih] simp only [seqRight_eq, map_eq_pure_bind, seq_pure, LawfulMonad.bind_assoc, pure_bind] theorem mapIdxM'_eq_mapIdxM {α} (f : ℕ → α → m PUnit) (as : List α) : mapIdxM' f as = mapIdxM f as > pure PUnit.unit := mapIdxMAux'_eq_mapIdxMGo f as #[] end MapIdxM' end List		Mathlib/Data/List/Indexes.lean	279	282
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Computability.Tape import Mathlib.Data.Fintype.Option import Mathlib.Data.Fintype.Prod import Mathlib.Data.Fintype.Pi import Mathlib.Data.PFun import Mathlib.Computability.PostTuringMachine /-! # Turing machines The files `PostTuringMachine.lean` and `TuringMachine.lean` define a sequence of simple machine languages, starting with Turing machines and working up to more complex languages based on Wang B-machines. `PostTuringMachine.lean` covers the TM0 model and TM1 model; `TuringMachine.lean` adds the TM2 model. ## Naming conventions Each model of computation in this file shares a naming convention for the elements of a model of computation. These are the parameters for the language: * `Γ` is the alphabet on the tape. * `Λ` is the set of labels, or internal machine states. * `σ` is the type of internal memory, not on the tape. This does not exist in the TM0 model, and later models achieve this by mixing it into `Λ`. * `K` is used in the TM2 model, which has multiple stacks, and denotes the number of such stacks. All of these variables denote "essentially finite" types, but for technical reasons it is convenient to allow them to be infinite anyway. When using an infinite type, we will be interested to prove that only finitely many values of the type are ever interacted with. Given these parameters, there are a few common structures for the model that arise: * `Stmt` is the set of all actions that can be performed in one step. For the TM0 model this set is finite, and for later models it is an infinite inductive type representing "possible program texts". * `Cfg` is the set of instantaneous configurations, that is, the state of the machine together with its environment. * `Machine` is the set of all machines in the model. Usually this is approximately a function `Λ → Stmt`, although different models have different ways of halting and other actions. * `step : Cfg → Option Cfg` is the function that describes how the state evolves over one step. If `step c = none`, then `c` is a terminal state, and the result of the computation is read off from `c`. Because of the type of `step`, these models are all deterministic by construction. * `init : Input → Cfg` sets up the initial state. The type `Input` depends on the model; in most cases it is `List Γ`. * `eval : Machine → Input → Part Output`, given a machine `M` and input `i`, starts from `init i`, runs `step` until it reaches an output, and then applies a function `Cfg → Output` to the final state to obtain the result. The type `Output` depends on the model. * `Supports : Machine → Finset Λ → Prop` asserts that a machine `M` starts in `S : Finset Λ`, and can only ever jump to other states inside `S`. This implies that the behavior of `M` on any input cannot depend on its values outside `S`. We use this to allow `Λ` to be an infinite set when convenient, and prove that only finitely many of these states are actually accessible. This formalizes "essentially finite" mentioned above. -/ assert_not_exists MonoidWithZero open List (Vector) open Relation open Nat (iterate) open Function (update iterate_succ iterate_succ_apply iterate_succ' iterate_succ_apply' iterate_zero_apply) namespace Turing /-! ## The TM2 model The TM2 model removes the tape entirely from the TM1 model, replacing it with an arbitrary (finite) collection of stacks, each with elements of different types (the alphabet of stack `k : K` is `Γ k`). The statements are: * `push k (f : σ → Γ k) q` puts `f a` on the `k`-th stack, then does `q`. * `pop k (f : σ → Option (Γ k) → σ) q` changes the state to `f a (S k).head`, where `S k` is the value of the `k`-th stack, and removes this element from the stack, then does `q`. * `peek k (f : σ → Option (Γ k) → σ) q` changes the state to `f a (S k).head`, where `S k` is the value of the `k`-th stack, then does `q`. * `load (f : σ → σ) q` reads nothing but applies `f` to the internal state, then does `q`. * `branch (f : σ → Bool) qtrue qfalse` does `qtrue` or `qfalse` according to `f a`. * `goto (f : σ → Λ)` jumps to label `f a`. * `halt` halts on the next step. The configuration is a tuple `(l, var, stk)` where `l : Option Λ` is the current label to run or `none` for the halting state, `var : σ` is the (finite) internal state, and `stk : ∀ k, List (Γ k)` is the collection of stacks. (Note that unlike the `TM0` and `TM1` models, these are not `ListBlank`s, they have definite ends that can be detected by the `pop` command.) Given a designated stack `k` and a value `L : List (Γ k)`, the initial configuration has all the stacks empty except the designated "input" stack; in `eval` this designated stack also functions as the output stack. -/ namespace TM2 variable {K : Type} -- Index type of stacks variable (Γ : K → Type) -- Type of stack elements variable (Λ : Type) -- Type of function labels variable (σ : Type) -- Type of variable settings /-- The TM2 model removes the tape entirely from the TM1 model, replacing it with an arbitrary (finite) collection of stacks. The operation `push` puts an element on one of the stacks, and `pop` removes an element from a stack (and modifying the internal state based on the result). `peek` modifies the internal state but does not remove an element. -/ inductive Stmt \| push : ∀ k, (σ → Γ k) → Stmt → Stmt \| peek : ∀ k, (σ → Option (Γ k) → σ) → Stmt → Stmt \| pop : ∀ k, (σ → Option (Γ k) → σ) → Stmt → Stmt \| load : (σ → σ) → Stmt → Stmt \| branch : (σ → Bool) → Stmt → Stmt → Stmt \| goto : (σ → Λ) → Stmt \| halt : Stmt open Stmt instance Stmt.inhabited : Inhabited (Stmt Γ Λ σ) := ⟨halt⟩ /-- A configuration in the TM2 model is a label (or `none` for the halt state), the state of local variables, and the stacks. (Note that the stacks are not `ListBlank`s, they have a definite size.) -/ structure Cfg where /-- The current label to run (or `none` for the halting state) -/ l : Option Λ /-- The internal state -/ var : σ /-- The (finite) collection of internal stacks -/ stk : ∀ k, List (Γ k) instance Cfg.inhabited [Inhabited σ] : Inhabited (Cfg Γ Λ σ) := ⟨⟨default, default, default⟩⟩ variable {Γ Λ σ} section variable [DecidableEq K] /-- The step function for the TM2 model. -/ def stepAux : Stmt Γ Λ σ → σ → (∀ k, List (Γ k)) → Cfg Γ Λ σ \| push k f q, v, S => stepAux q v (update S k (f v :: S k)) \| peek k f q, v, S => stepAux q (f v (S k).head?) S \| pop k f q, v, S => stepAux q (f v (S k).head?) (update S k (S k).tail) \| load a q, v, S => stepAux q (a v) S \| branch f q₁ q₂, v, S => cond (f v) (stepAux q₁ v S) (stepAux q₂ v S) \| goto f, v, S => ⟨some (f v), v, S⟩ \| halt, v, S => ⟨none, v, S⟩ /-- The step function for the TM2 model. -/ def step (M : Λ → Stmt Γ Λ σ) : Cfg Γ Λ σ → Option (Cfg Γ Λ σ) \| ⟨none, _, _⟩ => none \| ⟨some l, v, S⟩ => some (stepAux (M l) v S) attribute [simp] stepAux.eq_1 stepAux.eq_2 stepAux.eq_3 stepAux.eq_4 stepAux.eq_5 stepAux.eq_6 stepAux.eq_7 step.eq_1 step.eq_2 /-- The (reflexive) reachability relation for the TM2 model. -/ def Reaches (M : Λ → Stmt Γ Λ σ) : Cfg Γ Λ σ → Cfg Γ Λ σ → Prop := ReflTransGen fun a b ↦ b ∈ step M a end /-- Given a set `S` of states, `SupportsStmt S q` means that `q` only jumps to states in `S`. -/ def SupportsStmt (S : Finset Λ) : Stmt Γ Λ σ → Prop \| push _ _ q => SupportsStmt S q \| peek _ _ q => SupportsStmt S q \| pop _ _ q => SupportsStmt S q \| load _ q => SupportsStmt S q \| branch _ q₁ q₂ => SupportsStmt S q₁ ∧ SupportsStmt S q₂ \| goto l => ∀ v, l v ∈ S \| halt => True section open scoped Classical in /-- The set of subtree statements in a statement. -/ noncomputable def stmts₁ : Stmt Γ Λ σ → Finset (Stmt Γ Λ σ) \| Q@(push _ _ q) => insert Q (stmts₁ q) \| Q@(peek _ _ q) => insert Q (stmts₁ q) \| Q@(pop _ _ q) => insert Q (stmts₁ q) \| Q@(load _ q) => insert Q (stmts₁ q) \| Q@(branch _ q₁ q₂) => insert Q (stmts₁ q₁ ∪ stmts₁ q₂) \| Q@(goto _) => {Q} \| Q@halt => {Q} theorem stmts₁_self {q : Stmt Γ Λ σ} : q ∈ stmts₁ q := by cases q <;> simp only [Finset.mem_insert_self, Finset.mem_singleton_self, stmts₁] theorem stmts₁_trans {q₁ q₂ : Stmt Γ Λ σ} : q₁ ∈ stmts₁ q₂ → stmts₁ q₁ ⊆ stmts₁ q₂ := by classical intro h₁₂ q₀ h₀₁ induction q₂ with ( simp only [stmts₁] at h₁₂ ⊢ simp only [Finset.mem_insert, Finset.mem_singleton, Finset.mem_union] at h₁₂) \| branch f q₁ q₂ IH₁ IH₂ => rcases h₁₂ with (rfl \| h₁₂ \| h₁₂) · unfold stmts₁ at h₀₁ exact h₀₁ · exact Finset.mem_insert_of_mem (Finset.mem_union_left _ (IH₁ h₁₂)) · exact Finset.mem_insert_of_mem (Finset.mem_union_right _ (IH₂ h₁₂)) \| goto l => subst h₁₂; exact h₀₁ \| halt => subst h₁₂; exact h₀₁ \| load _ q IH \| _ _ _ q IH => rcases h₁₂ with (rfl \| h₁₂) · unfold stmts₁ at h₀₁ exact h₀₁ · exact Finset.mem_insert_of_mem (IH h₁₂) theorem stmts₁_supportsStmt_mono {S : Finset Λ} {q₁ q₂ : Stmt Γ Λ σ} (h : q₁ ∈ stmts₁ q₂) (hs : SupportsStmt S q₂) : SupportsStmt S q₁ := by induction q₂ with simp only [stmts₁, SupportsStmt, Finset.mem_insert, Finset.mem_union, Finset.mem_singleton] at h hs \| branch f q₁ q₂ IH₁ IH₂ => rcases h with (rfl \| h \| h); exacts [hs, IH₁ h hs.1, IH₂ h hs.2] \| goto l => subst h; exact hs \| halt => subst h; trivial \| load _ _ IH \| _ _ _ _ IH => rcases h with (rfl \| h) <;> [exact hs; exact IH h hs] open scoped Classical in /-- The set of statements accessible from initial set `S` of labels. -/ noncomputable def stmts (M : Λ → Stmt Γ Λ σ) (S : Finset Λ) : Finset (Option (Stmt Γ Λ σ)) := Finset.insertNone (S.biUnion fun q ↦ stmts₁ (M q)) theorem stmts_trans {M : Λ → Stmt Γ Λ σ} {S : Finset Λ} {q₁ q₂ : Stmt Γ Λ σ} (h₁ : q₁ ∈ stmts₁ q₂) : some q₂ ∈ stmts M S → some q₁ ∈ stmts M S := by simp only [stmts, Finset.mem_insertNone, Finset.mem_biUnion, Option.mem_def, Option.some.injEq, forall_eq', exists_imp, and_imp] exact fun l ls h₂ ↦ ⟨_, ls, stmts₁_trans h₂ h₁⟩ end variable [Inhabited Λ] /-- Given a TM2 machine `M` and a set `S` of states, `Supports M S` means that all states in `S` jump only to other states in `S`. -/ def Supports (M : Λ → Stmt Γ Λ σ) (S : Finset Λ) := default ∈ S ∧ ∀ q ∈ S, SupportsStmt S (M q) theorem stmts_supportsStmt {M : Λ → Stmt Γ Λ σ} {S : Finset Λ} {q : Stmt Γ Λ σ} (ss : Supports M S) : some q ∈ stmts M S → SupportsStmt S q := by simp only [stmts, Finset.mem_insertNone, Finset.mem_biUnion, Option.mem_def, Option.some.injEq, forall_eq', exists_imp, and_imp] exact fun l ls h ↦ stmts₁_supportsStmt_mono h (ss.2 _ ls) variable [DecidableEq K] theorem step_supports (M : Λ → Stmt Γ Λ σ) {S : Finset Λ} (ss : Supports M S) : ∀ {c c' : Cfg Γ Λ σ}, c' ∈ step M c → c.l ∈ Finset.insertNone S → c'.l ∈ Finset.insertNone S \| ⟨some l₁, v, T⟩, c', h₁, h₂ => by replace h₂ := ss.2 _ (Finset.some_mem_insertNone.1 h₂) simp only [step, Option.mem_def, Option.some.injEq] at h₁; subst c' revert h₂; induction M l₁ generalizing v T with intro hs \| branch p q₁' q₂' IH₁ IH₂ => unfold stepAux; cases p v · exact IH₂ _ _ hs.2 · exact IH₁ _ _ hs.1 \| goto => exact Finset.some_mem_insertNone.2 (hs _) \| halt => apply Multiset.mem_cons_self \| load _ _ IH \| _ _ _ _ IH => exact IH _ _ hs variable [Inhabited σ] /-- The initial state of the TM2 model. The input is provided on a designated stack. -/ def init (k : K) (L : List (Γ k)) : Cfg Γ Λ σ := ⟨some default, default, update (fun _ ↦ []) k L⟩ /-- Evaluates a TM2 program to completion, with the output on the same stack as the input. -/ def eval (M : Λ → Stmt Γ Λ σ) (k : K) (L : List (Γ k)) : Part (List (Γ k)) := (Turing.eval (step M) (init k L)).map fun c ↦ c.stk k end TM2 /-! ## TM2 emulator in TM1 To prove that TM2 computable functions are TM1 computable, we need to reduce each TM2 program to a TM1 program. So suppose a TM2 program is given. This program has to maintain a whole collection of stacks, but we have only one tape, so we must "multiplex" them all together. Pictorially, if stack 1 contains `[a, b]` and stack 2 contains `[c, d, e, f]` then the tape looks like this: ``` bottom: ... \| _ \| T \| _ \| _ \| _ \| _ \| ... stack 1: ... \| _ \| b \| a \| _ \| _ \| _ \| ... stack 2: ... \| _ \| f \| e \| d \| c \| _ \| ... ``` where a tape element is a vertical slice through the diagram. Here the alphabet is `Γ' := Bool × ∀ k, Option (Γ k)`, where: * `bottom : Bool` is marked only in one place, the initial position of the TM, and represents the tail of all stacks. It is never modified. * `stk k : Option (Γ k)` is the value of the `k`-th stack, if in range, otherwise `none` (which is the blank value). Note that the head of the stack is at the far end; this is so that push and pop don't have to do any shifting. In "resting" position, the TM is sitting at the position marked `bottom`. For non-stack actions, it operates in place, but for the stack actions `push`, `peek`, and `pop`, it must shuttle to the end of the appropriate stack, make its changes, and then return to the bottom. So the states are: * `normal (l : Λ)`: waiting at `bottom` to execute function `l` * `go k (s : StAct k) (q : Stmt₂)`: travelling to the right to get to the end of stack `k` in order to perform stack action `s`, and later continue with executing `q` * `ret (q : Stmt₂)`: travelling to the left after having performed a stack action, and executing `q` once we arrive Because of the shuttling, emulation overhead is `O(n)`, where `n` is the current maximum of the length of all stacks. Therefore a program that takes `k` steps to run in TM2 takes `O((m+k)k)` steps to run when emulated in TM1, where `m` is the length of the input. -/ namespace TM2to1 -- A displaced lemma proved in unnecessary generality theorem stk_nth_val {K : Type} {Γ : K → Type} {L : ListBlank (∀ k, Option (Γ k))} {k S} (n) (hL : ListBlank.map (proj k) L = ListBlank.mk (List.map some S).reverse) : L.nth n k = S.reverse[n]? := by rw [← proj_map_nth, hL, ← List.map_reverse, ListBlank.nth_mk, List.getI_eq_iget_getElem?, List.getElem?_map] cases S.reverse[n]? <;> rfl variable (K : Type) variable (Γ : K → Type) variable {Λ σ : Type*} /-- The alphabet of the TM2 simulator on TM1 is a marker for the stack bottom, plus a vector of stack elements for each stack, or none if the stack does not extend this far. -/ def Γ' := Bool × ∀ k, Option (Γ k) variable {K Γ} instance Γ'.inhabited : Inhabited (Γ' K Γ) := ⟨⟨false, fun _ ↦ none⟩⟩ instance Γ'.fintype [DecidableEq K] [Fintype K] [∀ k, Fintype (Γ k)] : Fintype (Γ' K Γ) := instFintypeProd _ _ /-- The bottom marker is fixed throughout the calculation, so we use the `addBottom` function to express the program state in terms of a tape with only the stacks themselves. -/ def addBottom (L : ListBlank (∀ k, Option (Γ k))) : ListBlank (Γ' K Γ) := ListBlank.cons (true, L.head) (L.tail.map ⟨Prod.mk false, rfl⟩) theorem addBottom_map (L : ListBlank (∀ k, Option (Γ k))) : (addBottom L).map ⟨Prod.snd, by rfl⟩ = L := by simp only [addBottom, ListBlank.map_cons] convert ListBlank.cons_head_tail L generalize ListBlank.tail L = L' refine L'.induction_on fun l ↦ ?_; simp theorem addBottom_modifyNth (f : (∀ k, Option (Γ k)) → ∀ k, Option (Γ k)) (L : ListBlank (∀ k, Option (Γ k))) (n : ℕ) : (addBottom L).modifyNth (fun a ↦ (a.1, f a.2)) n = addBottom (L.modifyNth f n) := by cases n <;> simp only [addBottom, ListBlank.head_cons, ListBlank.modifyNth, ListBlank.tail_cons] congr; symm; apply ListBlank.map_modifyNth; intro; rfl theorem addBottom_nth_snd (L : ListBlank (∀ k, Option (Γ k))) (n : ℕ) : ((addBottom L).nth n).2 = L.nth n := by conv => rhs; rw [← addBottom_map L, ListBlank.nth_map] theorem addBottom_nth_succ_fst (L : ListBlank (∀ k, Option (Γ k))) (n : ℕ) : ((addBottom L).nth (n + 1)).1 = false := by rw [ListBlank.nth_succ, addBottom, ListBlank.tail_cons, ListBlank.nth_map] theorem addBottom_head_fst (L : ListBlank (∀ k, Option (Γ k))) : (addBottom L).head.1 = true := by rw [addBottom, ListBlank.head_cons] variable (K Γ σ) in /-- A stack action is a command that interacts with the top of a stack. Our default position is at the bottom of all the stacks, so we have to hold on to this action while going to the end to modify the stack. -/ inductive StAct (k : K) \| push : (σ → Γ k) → StAct k \| peek : (σ → Option (Γ k) → σ) → StAct k \| pop : (σ → Option (Γ k) → σ) → StAct k instance StAct.inhabited {k : K} : Inhabited (StAct K Γ σ k) := ⟨StAct.peek fun s _ ↦ s⟩ section open StAct /-- The TM2 statement corresponding to a stack action. -/ def stRun {k : K} : StAct K Γ σ k → TM2.Stmt Γ Λ σ → TM2.Stmt Γ Λ σ \| push f => TM2.Stmt.push k f \| peek f => TM2.Stmt.peek k f \| pop f => TM2.Stmt.pop k f /-- The effect of a stack action on the local variables, given the value of the stack. -/ def stVar {k : K} (v : σ) (l : List (Γ k)) : StAct K Γ σ k → σ \| push _ => v \| peek f => f v l.head? \| pop f => f v l.head? /-- The effect of a stack action on the stack. -/ def stWrite {k : K} (v : σ) (l : List (Γ k)) : StAct K Γ σ k → List (Γ k) \| push f => f v :: l \| peek _ => l \| pop _ => l.tail /-- We have partitioned the TM2 statements into "stack actions", which require going to the end of the stack, and all other actions, which do not. This is a modified recursor which lumps the stack actions into one. -/ @[elab_as_elim] def stmtStRec.{l} {motive : TM2.Stmt Γ Λ σ → Sort l} (run : ∀ (k) (s : StAct K Γ σ k) (q) (_ : motive q), motive (stRun s q)) (load : ∀ (a q) (_ : motive q), motive (TM2.Stmt.load a q)) (branch : ∀ (p q₁ q₂) (_ : motive q₁) (_ : motive q₂), motive (TM2.Stmt.branch p q₁ q₂)) (goto : ∀ l, motive (TM2.Stmt.goto l)) (halt : motive TM2.Stmt.halt) : ∀ n, motive n \| TM2.Stmt.push _ f q => run _ (push f) _ (stmtStRec run load branch goto halt q) \| TM2.Stmt.peek _ f q => run _ (peek f) _ (stmtStRec run load branch goto halt q) \| TM2.Stmt.pop _ f q => run _ (pop f) _ (stmtStRec run load branch goto halt q) \| TM2.Stmt.load _ q => load _ _ (stmtStRec run load branch goto halt q) \| TM2.Stmt.branch _ q₁ q₂ => branch _ _ _ (stmtStRec run load branch goto halt q₁) (stmtStRec run load branch goto halt q₂) \| TM2.Stmt.goto _ => goto _ \| TM2.Stmt.halt => halt theorem supports_run (S : Finset Λ) {k : K} (s : StAct K Γ σ k) (q : TM2.Stmt Γ Λ σ) : TM2.SupportsStmt S (stRun s q) ↔ TM2.SupportsStmt S q := by cases s <;> rfl end variable (K Γ Λ σ) /-- The machine states of the TM2 emulator. We can either be in a normal state when waiting for the next TM2 action, or we can be in the "go" and "return" states to go to the top of the stack and return to the bottom, respectively. -/ inductive Λ' \| normal : Λ → Λ' \| go (k : K) : StAct K Γ σ k → TM2.Stmt Γ Λ σ → Λ' \| ret : TM2.Stmt Γ Λ σ → Λ' variable {K Γ Λ σ} open Λ' instance Λ'.inhabited [Inhabited Λ] : Inhabited (Λ' K Γ Λ σ) := ⟨normal default⟩ open TM1.Stmt section variable [DecidableEq K] /-- The program corresponding to state transitions at the end of a stack. Here we start out just after the top of the stack, and should end just after the new top of the stack. -/ def trStAct {k : K} (q : TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ) : StAct K Γ σ k → TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ \| StAct.push f => (write fun a s ↦ (a.1, update a.2 k <\| some <\| f s)) <\| move Dir.right q \| StAct.peek f => move Dir.left <\| (load fun a s ↦ f s (a.2 k)) <\| move Dir.right q \| StAct.pop f => branch (fun a _ ↦ a.1) (load (fun _ s ↦ f s none) q) (move Dir.left <\| (load fun a s ↦ f s (a.2 k)) <\| write (fun a _ ↦ (a.1, update a.2 k none)) q) /-- The initial state for the TM2 emulator, given an initial TM2 state. All stacks start out empty except for the input stack, and the stack bottom mark is set at the head. -/ def trInit (k : K) (L : List (Γ k)) : List (Γ' K Γ) := let L' : List (Γ' K Γ) := L.reverse.map fun a ↦ (false, update (fun _ ↦ none) k (some a)) (true, L'.headI.2) :: L'.tail theorem step_run {k : K} (q : TM2.Stmt Γ Λ σ) (v : σ) (S : ∀ k, List (Γ k)) : ∀ s : StAct K Γ σ k, TM2.stepAux (stRun s q) v S = TM2.stepAux q (stVar v (S k) s) (update S k (stWrite v (S k) s)) \| StAct.push _ => rfl \| StAct.peek f => by unfold stWrite; rw [Function.update_eq_self]; rfl \| StAct.pop _ => rfl end /-- The translation of TM2 statements to TM1 statements. regular actions have direct equivalents, but stack actions are deferred by going to the corresponding `go` state, so that we can find the appropriate stack top. -/ def trNormal : TM2.Stmt Γ Λ σ → TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ \| TM2.Stmt.push k f q => goto fun _ _ ↦ go k (StAct.push f) q \| TM2.Stmt.peek k f q => goto fun _ _ ↦ go k (StAct.peek f) q \| TM2.Stmt.pop k f q => goto fun _ _ ↦ go k (StAct.pop f) q \| TM2.Stmt.load a q => load (fun _ ↦ a) (trNormal q) \| TM2.Stmt.branch f q₁ q₂ => branch (fun _ ↦ f) (trNormal q₁) (trNormal q₂) \| TM2.Stmt.goto l => goto fun _ s ↦ normal (l s) \| TM2.Stmt.halt => halt theorem trNormal_run {k : K} (s : StAct K Γ σ k) (q : TM2.Stmt Γ Λ σ) : trNormal (stRun s q) = goto fun _ _ ↦ go k s q := by cases s <;> rfl section open scoped Classical in /-- The set of machine states accessible from an initial TM2 statement. -/ noncomputable def trStmts₁ : TM2.Stmt Γ Λ σ → Finset (Λ' K Γ Λ σ) \| TM2.Stmt.push k f q => {go k (StAct.push f) q, ret q} ∪ trStmts₁ q \| TM2.Stmt.peek k f q => {go k (StAct.peek f) q, ret q} ∪ trStmts₁ q \| TM2.Stmt.pop k f q => {go k (StAct.pop f) q, ret q} ∪ trStmts₁ q \| TM2.Stmt.load _ q => trStmts₁ q \| TM2.Stmt.branch _ q₁ q₂ => trStmts₁ q₁ ∪ trStmts₁ q₂ \| _ => ∅ theorem trStmts₁_run {k : K} {s : StAct K Γ σ k} {q : TM2.Stmt Γ Λ σ} : open scoped Classical in trStmts₁ (stRun s q) = {go k s q, ret q} ∪ trStmts₁ q := by cases s <;> simp only [trStmts₁, stRun] theorem tr_respects_aux₂ [DecidableEq K] {k : K} {q : TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ} {v : σ} {S : ∀ k, List (Γ k)} {L : ListBlank (∀ k, Option (Γ k))} (hL : ∀ k, L.map (proj k) = ListBlank.mk ((S k).map some).reverse) (o : StAct K Γ σ k) : let v' := stVar v (S k) o let Sk' := stWrite v (S k) o let S' := update S k Sk' ∃ L' : ListBlank (∀ k, Option (Γ k)), (∀ k, L'.map (proj k) = ListBlank.mk ((S' k).map some).reverse) ∧ TM1.stepAux (trStAct q o) v ((Tape.move Dir.right)^[(S k).length] (Tape.mk' ∅ (addBottom L))) = TM1.stepAux q v' ((Tape.move Dir.right)^[(S' k).length] (Tape.mk' ∅ (addBottom L'))) := by simp only [Function.update_self]; cases o with simp only [stWrite, stVar, trStAct, TM1.stepAux] \| push f => have := Tape.write_move_right_n fun a : Γ' K Γ ↦ (a.1, update a.2 k (some (f v))) refine ⟨_, fun k' ↦ ?_, by -- Porting note: `rw [...]` to `erw [...]; rfl`. -- https://github.com/leanprover-community/mathlib4/issues/5164 rw [Tape.move_right_n_head, List.length, Tape.mk'_nth_nat, this] erw [addBottom_modifyNth fun a ↦ update a k (some (f v))] rw [Nat.add_one, iterate_succ'] rfl⟩ refine ListBlank.ext fun i ↦ ?_ rw [ListBlank.nth_map, ListBlank.nth_modifyNth, proj, PointedMap.mk_val] by_cases h' : k' = k · subst k' split_ifs with h <;> simp only [List.reverse_cons, Function.update_self, ListBlank.nth_mk, List.map] · rw [List.getI_eq_getElem _, List.getElem_append_right] <;> simp only [List.length_append, List.length_reverse, List.length_map, ← h, Nat.sub_self, List.length_singleton, List.getElem_singleton, le_refl, Nat.lt_succ_self] rw [← proj_map_nth, hL, ListBlank.nth_mk] rcases lt_or_gt_of_ne h with h \| h · rw [List.getI_append] simpa only [List.length_map, List.length_reverse] using h · rw [gt_iff_lt] at h rw [List.getI_eq_default, List.getI_eq_default] <;> simp only [Nat.add_one_le_iff, h, List.length, le_of_lt, List.length_reverse, List.length_append, List.length_map] · split_ifs <;> rw [Function.update_of_ne h', ← proj_map_nth, hL] rw [Function.update_of_ne h'] \| peek f => rw [Function.update_eq_self] use L, hL; rw [Tape.move_left_right]; congr cases e : S k; · rfl rw [List.length_cons, iterate_succ', Function.comp, Tape.move_right_left, Tape.move_right_n_head, Tape.mk'_nth_nat, addBottom_nth_snd, stk_nth_val _ (hL k), e, List.reverse_cons, ← List.length_reverse, List.getElem?_concat_length] rfl \| pop f => rcases e : S k with - \| ⟨hd, tl⟩ · simp only [Tape.mk'_head, ListBlank.head_cons, Tape.move_left_mk', List.length, Tape.write_mk', List.head?, iterate_zero_apply, List.tail_nil] rw [← e, Function.update_eq_self] exact ⟨L, hL, by rw [addBottom_head_fst, cond]⟩ · refine ⟨_, fun k' ↦ ?_, by erw [List.length_cons, Tape.move_right_n_head, Tape.mk'_nth_nat, addBottom_nth_succ_fst, cond_false, iterate_succ', Function.comp, Tape.move_right_left, Tape.move_right_n_head, Tape.mk'_nth_nat, Tape.write_move_right_n fun a : Γ' K Γ ↦ (a.1, update a.2 k none), addBottom_modifyNth fun a ↦ update a k none, addBottom_nth_snd, stk_nth_val _ (hL k), e, show (List.cons hd tl).reverse[tl.length]? = some hd by rw [List.reverse_cons, ← List.length_reverse, List.getElem?_concat_length], List.head?, List.tail]⟩ refine ListBlank.ext fun i ↦ ?_ rw [ListBlank.nth_map, ListBlank.nth_modifyNth, proj, PointedMap.mk_val] by_cases h' : k' = k · subst k' split_ifs with h <;> simp only [Function.update_self, ListBlank.nth_mk, List.tail] · rw [List.getI_eq_default] · rfl rw [h, List.length_reverse, List.length_map] rw [← proj_map_nth, hL, ListBlank.nth_mk, e, List.map, List.reverse_cons] rcases lt_or_gt_of_ne h with h \| h · rw [List.getI_append] simpa only [List.length_map, List.length_reverse] using h · rw [gt_iff_lt] at h rw [List.getI_eq_default, List.getI_eq_default] <;> simp only [Nat.add_one_le_iff, h, List.length, le_of_lt, List.length_reverse, List.length_append, List.length_map] · split_ifs <;> rw [Function.update_of_ne h', ← proj_map_nth, hL] rw [Function.update_of_ne h'] end variable [DecidableEq K] variable (M : Λ → TM2.Stmt Γ Λ σ) /-- The TM2 emulator machine states written as a TM1 program. This handles the `go` and `ret` states, which shuttle to and from a stack top. -/ def tr : Λ' K Γ Λ σ → TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ \| normal q => trNormal (M q) \| go k s q => branch (fun a _ ↦ (a.2 k).isNone) (trStAct (goto fun _ _ ↦ ret q) s) (move Dir.right <\| goto fun _ _ ↦ go k s q) \| ret q => branch (fun a _ ↦ a.1) (trNormal q) (move Dir.left <\| goto fun _ _ ↦ ret q) /-- The relation between TM2 configurations and TM1 configurations of the TM2 emulator. -/ inductive TrCfg : TM2.Cfg Γ Λ σ → TM1.Cfg (Γ' K Γ) (Λ' K Γ Λ σ) σ → Prop \| mk {q : Option Λ} {v : σ} {S : ∀ k, List (Γ k)} (L : ListBlank (∀ k, Option (Γ k))) : (∀ k, L.map (proj k) = ListBlank.mk ((S k).map some).reverse) → TrCfg ⟨q, v, S⟩ ⟨q.map normal, v, Tape.mk' ∅ (addBottom L)⟩ theorem tr_respects_aux₁ {k} (o q v) {S : List (Γ k)} {L : ListBlank (∀ k, Option (Γ k))} (hL : L.map (proj k) = ListBlank.mk (S.map some).reverse) (n) (H : n ≤ S.length) : Reaches₀ (TM1.step (tr M)) ⟨some (go k o q), v, Tape.mk' ∅ (addBottom L)⟩ ⟨some (go k o q), v, (Tape.move Dir.right)^[n] (Tape.mk' ∅ (addBottom L))⟩ := by induction' n with n IH; · rfl apply (IH (le_of_lt H)).tail rw [iterate_succ_apply'] simp only [TM1.step, TM1.stepAux, tr, Tape.mk'_nth_nat, Tape.move_right_n_head, addBottom_nth_snd, Option.mem_def] rw [stk_nth_val _ hL, List.getElem?_eq_getElem] · rfl · rwa [List.length_reverse] theorem tr_respects_aux₃ {q v} {L : ListBlank (∀ k, Option (Γ k))} (n) : Reaches₀ (TM1.step (tr M)) ⟨some (ret q), v, (Tape.move Dir.right)^[n] (Tape.mk' ∅ (addBottom L))⟩ ⟨some (ret q), v, Tape.mk' ∅ (addBottom L)⟩ := by induction' n with n IH; · rfl refine Reaches₀.head ?_ IH simp only [Option.mem_def, TM1.step] rw [Option.some_inj, tr, TM1.stepAux, Tape.move_right_n_head, Tape.mk'_nth_nat, addBottom_nth_succ_fst, TM1.stepAux, iterate_succ', Function.comp_apply, Tape.move_right_left] rfl theorem tr_respects_aux {q v T k} {S : ∀ k, List (Γ k)} (hT : ∀ k, ListBlank.map (proj k) T = ListBlank.mk ((S k).map some).reverse) (o : StAct K Γ σ k) (IH : ∀ {v : σ} {S : ∀ k : K, List (Γ k)} {T : ListBlank (∀ k, Option (Γ k))}, (∀ k, ListBlank.map (proj k) T = ListBlank.mk ((S k).map some).reverse) → ∃ b, TrCfg (TM2.stepAux q v S) b ∧ Reaches (TM1.step (tr M)) (TM1.stepAux (trNormal q) v (Tape.mk' ∅ (addBottom T))) b) : ∃ b, TrCfg (TM2.stepAux (stRun o q) v S) b ∧ Reaches (TM1.step (tr M)) (TM1.stepAux (trNormal (stRun o q)) v (Tape.mk' ∅ (addBottom T))) b := by simp only [trNormal_run, step_run] have hgo := tr_respects_aux₁ M o q v (hT k) _ le_rfl obtain ⟨T', hT', hrun⟩ := tr_respects_aux₂ (Λ := Λ) hT o have := hgo.tail' rfl rw [tr, TM1.stepAux, Tape.move_right_n_head, Tape.mk'_nth_nat, addBottom_nth_snd, stk_nth_val _ (hT k), List.getElem?_eq_none (le_of_eq List.length_reverse), Option.isNone, cond, hrun, TM1.stepAux] at this obtain ⟨c, gc, rc⟩ := IH hT' refine ⟨c, gc, (this.to₀.trans (tr_respects_aux₃ M _) c (TransGen.head' rfl ?_)).to_reflTransGen⟩ rw [tr, TM1.stepAux, Tape.mk'_head, addBottom_head_fst] exact rc attribute [local simp] Respects TM2.step TM2.stepAux trNormal theorem tr_respects : Respects (TM2.step M) (TM1.step (tr M)) TrCfg := by -- Porting note (https://github.com/leanprover-community/mathlib4/issues/12129): additional beta reduction needed intro c₁ c₂ h obtain @⟨- \| l, v, S, L, hT⟩ := h; · constructor rsuffices ⟨b, c, r⟩ : ∃ b, _ ∧ Reaches (TM1.step (tr M)) _ _ · exact ⟨b, c, TransGen.head' rfl r⟩ simp only [tr] generalize M l = N induction N using stmtStRec generalizing v S L hT with \| run k s q IH => exact tr_respects_aux M hT s @IH \| load a _ IH => exact IH _ hT \| branch p q₁ q₂ IH₁ IH₂ => unfold TM2.stepAux trNormal TM1.stepAux beta_reduce cases p v <;> [exact IH₂ _ hT; exact IH₁ _ hT] \| goto => exact ⟨_, ⟨_, hT⟩, ReflTransGen.refl⟩ \| halt => exact ⟨_, ⟨_, hT⟩, ReflTransGen.refl⟩ section variable [Inhabited Λ] [Inhabited σ] theorem trCfg_init (k) (L : List (Γ k)) : TrCfg (TM2.init k L) (TM1.init (trInit k L) : TM1.Cfg (Γ' K Γ) (Λ' K Γ Λ σ) σ) := by rw [(_ : TM1.init _ = _)] · refine ⟨ListBlank.mk (L.reverse.map fun a ↦ update default k (some a)), fun k' ↦ ?_⟩ refine ListBlank.ext fun i ↦ ?_ rw [ListBlank.map_mk, ListBlank.nth_mk, List.getI_eq_iget_getElem?, List.map_map] have : ((proj k').f ∘ fun a => update (β := fun k => Option (Γ k)) default k (some a)) = fun a => (proj k').f (update (β := fun k => Option (Γ k)) default k (some a)) := rfl rw [this, List.getElem?_map, proj, PointedMap.mk_val] simp only [] by_cases h : k' = k · subst k' simp only [Function.update_self] rw [ListBlank.nth_mk, List.getI_eq_iget_getElem?, ← List.map_reverse, List.getElem?_map] · simp only [Function.update_of_ne h] rw [ListBlank.nth_mk, List.getI_eq_iget_getElem?, List.map, List.reverse_nil] cases L.reverse[i]? <;> rfl · rw [trInit, TM1.init] congr <;> cases L.reverse <;> try rfl simp only [List.map_map, List.tail_cons, List.map] rfl theorem tr_eval_dom (k) (L : List (Γ k)) : (TM1.eval (tr M) (trInit k L)).Dom ↔ (TM2.eval M k L).Dom := Turing.tr_eval_dom (tr_respects M) (trCfg_init k L) theorem tr_eval (k) (L : List (Γ k)) {L₁ L₂} (H₁ : L₁ ∈ TM1.eval (tr M) (trInit k L)) (H₂ : L₂ ∈ TM2.eval M k L) : ∃ (S : ∀ k, List (Γ k)) (L' : ListBlank (∀ k, Option (Γ k))), addBottom L' = L₁ ∧ (∀ k, L'.map (proj k) = ListBlank.mk ((S k).map some).reverse) ∧ S k = L₂ := by obtain ⟨c₁, h₁, rfl⟩ := (Part.mem_map_iff _).1 H₁ obtain ⟨c₂, h₂, rfl⟩ := (Part.mem_map_iff _).1 H₂ obtain ⟨_, ⟨L', hT⟩, h₃⟩ := Turing.tr_eval (tr_respects M) (trCfg_init k L) h₂ cases Part.mem_unique h₁ h₃ exact ⟨_, L', by simp only [Tape.mk'_right₀], hT, rfl⟩ end section variable [Inhabited Λ] open scoped Classical in /-- The support of a set of TM2 states in the TM2 emulator. -/ noncomputable def trSupp (S : Finset Λ) : Finset (Λ' K Γ Λ σ) := S.biUnion fun l ↦ insert (normal l) (trStmts₁ (M l)) open scoped Classical in theorem tr_supports {S} (ss : TM2.Supports M S) : TM1.Supports (tr M) (trSupp M S) := ⟨Finset.mem_biUnion.2 ⟨_, ss.1, Finset.mem_insert.2 <\| Or.inl rfl⟩, fun l' h ↦ by suffices ∀ (q) (_ : TM2.SupportsStmt S q) (_ : ∀ x ∈ trStmts₁ q, x ∈ trSupp M S), TM1.SupportsStmt (trSupp M S) (trNormal q) ∧ ∀ l' ∈ trStmts₁ q, TM1.SupportsStmt (trSupp M S) (tr M l') by rcases Finset.mem_biUnion.1 h with ⟨l, lS, h⟩ have := this _ (ss.2 l lS) fun x hx ↦ Finset.mem_biUnion.2 ⟨_, lS, Finset.mem_insert_of_mem hx⟩ rcases Finset.mem_insert.1 h with (rfl \| h) <;> [exact this.1; exact this.2 _ h] clear h l' refine stmtStRec ?_ ?_ ?_ ?_ ?_ · intro _ s _ IH ss' sub -- stack op rw [TM2to1.supports_run] at ss' simp only [TM2to1.trStmts₁_run, Finset.mem_union, Finset.mem_insert, Finset.mem_singleton] at sub have hgo := sub _ (Or.inl <\| Or.inl rfl) have hret := sub _ (Or.inl <\| Or.inr rfl) obtain ⟨IH₁, IH₂⟩ := IH ss' fun x hx ↦ sub x <\| Or.inr hx refine ⟨by simp only [trNormal_run, TM1.SupportsStmt]; intros; exact hgo, fun l h ↦ ?_⟩ rw [trStmts₁_run] at h simp only [TM2to1.trStmts₁_run, Finset.mem_union, Finset.mem_insert, Finset.mem_singleton] at h rcases h with (⟨rfl \| rfl⟩ \| h) · cases s · exact ⟨fun _ _ ↦ hret, fun _ _ ↦ hgo⟩ · exact ⟨fun _ _ ↦ hret, fun _ _ ↦ hgo⟩ · exact ⟨⟨fun _ _ ↦ hret, fun _ _ ↦ hret⟩, fun _ _ ↦ hgo⟩ · unfold TM1.SupportsStmt TM2to1.tr exact ⟨IH₁, fun _ _ ↦ hret⟩ · exact IH₂ _ h · intro _ _ IH ss' sub -- load unfold TM2to1.trStmts₁ at sub ⊢ exact IH ss' sub · intro _ _ _ IH₁ IH₂ ss' sub -- branch unfold TM2to1.trStmts₁ at sub obtain ⟨IH₁₁, IH₁₂⟩ := IH₁ ss'.1 fun x hx ↦ sub x <\| Finset.mem_union_left _ hx obtain ⟨IH₂₁, IH₂₂⟩ := IH₂ ss'.2 fun x hx ↦ sub x <\| Finset.mem_union_right _ hx refine ⟨⟨IH₁₁, IH₂₁⟩, fun l h ↦ ?_⟩ rw [trStmts₁] at h rcases Finset.mem_union.1 h with (h \| h) <;> [exact IH₁₂ _ h; exact IH₂₂ _ h] · intro _ ss' _ -- goto simp only [trStmts₁, Finset.not_mem_empty]; refine ⟨?_, fun _ ↦ False.elim⟩ exact fun _ v ↦ Finset.mem_biUnion.2 ⟨_, ss' v, Finset.mem_insert_self _ _⟩ · intro _ _ -- halt simp only [trStmts₁, Finset.not_mem_empty] exact ⟨trivial, fun _ ↦ False.elim⟩⟩ end end TM2to1 end Turing		Mathlib/Computability/TuringMachine.lean	1,125	1,129
/- Copyright (c) 2021 Kexing Ying. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kexing Ying, Rémy Degenne -/ import Mathlib.Probability.Process.Adapted import Mathlib.MeasureTheory.Constructions.BorelSpace.Order /-! # Stopping times, stopped processes and stopped values Definition and properties of stopping times. ## Main definitions * `MeasureTheory.IsStoppingTime`: a stopping time with respect to some filtration `f` is a function `τ` such that for all `i`, the preimage of `{j \| j ≤ i}` along `τ` is `f i`-measurable * `MeasureTheory.IsStoppingTime.measurableSpace`: the σ-algebra associated with a stopping time ## Main results * `ProgMeasurable.stoppedProcess`: the stopped process of a progressively measurable process is progressively measurable. * `memLp_stoppedProcess`: if a process belongs to `ℒp` at every time in `ℕ`, then its stopped process belongs to `ℒp` as well. ## Tags stopping time, stochastic process -/ open Filter Order TopologicalSpace open scoped MeasureTheory NNReal ENNReal Topology namespace MeasureTheory variable {Ω β ι : Type*} {m : MeasurableSpace Ω} /-! ### Stopping times -/ /-- A stopping time with respect to some filtration `f` is a function `τ` such that for all `i`, the preimage of `{j \| j ≤ i}` along `τ` is measurable with respect to `f i`. Intuitively, the stopping time `τ` describes some stopping rule such that at time `i`, we may determine it with the information we have at time `i`. -/ def IsStoppingTime [Preorder ι] (f : Filtration ι m) (τ : Ω → ι) := ∀ i : ι, MeasurableSet[f i] <\| {ω \| τ ω ≤ i} theorem isStoppingTime_const [Preorder ι] (f : Filtration ι m) (i : ι) : IsStoppingTime f fun _ => i := fun j => by simp only [MeasurableSet.const] section MeasurableSet section Preorder variable [Preorder ι] {f : Filtration ι m} {τ : Ω → ι} protected theorem IsStoppingTime.measurableSet_le (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| τ ω ≤ i} := hτ i theorem IsStoppingTime.measurableSet_lt_of_pred [PredOrder ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| τ ω < i} := by by_cases hi_min : IsMin i · suffices {ω : Ω \| τ ω < i} = ∅ by rw [this]; exact @MeasurableSet.empty _ (f i) ext1 ω simp only [Set.mem_setOf_eq, Set.mem_empty_iff_false, iff_false] rw [isMin_iff_forall_not_lt] at hi_min exact hi_min (τ ω) have : {ω : Ω \| τ ω < i} = τ ⁻¹' Set.Iic (pred i) := by ext; simp [Iic_pred_of_not_isMin hi_min] rw [this] exact f.mono (pred_le i) _ (hτ.measurableSet_le <\| pred i) end Preorder section CountableStoppingTime namespace IsStoppingTime variable [PartialOrder ι] {τ : Ω → ι} {f : Filtration ι m} protected theorem measurableSet_eq_of_countable_range (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[f i] {ω \| τ ω = i} := by have : {ω \| τ ω = i} = {ω \| τ ω ≤ i} \ ⋃ (j ∈ Set.range τ) (_ : j < i), {ω \| τ ω ≤ j} := by ext1 a simp only [Set.mem_setOf_eq, Set.mem_range, Set.iUnion_exists, Set.iUnion_iUnion_eq', Set.mem_diff, Set.mem_iUnion, exists_prop, not_exists, not_and, not_le] constructor <;> intro h · simp only [h, lt_iff_le_not_le, le_refl, and_imp, imp_self, imp_true_iff, and_self_iff] · exact h.1.eq_or_lt.resolve_right fun h_lt => h.2 a h_lt le_rfl rw [this] refine (hτ.measurableSet_le i).diff ?_ refine MeasurableSet.biUnion h_countable fun j _ => ?_ classical rw [Set.iUnion_eq_if] split_ifs with hji · exact f.mono hji.le _ (hτ.measurableSet_le j) · exact @MeasurableSet.empty _ (f i) protected theorem measurableSet_eq_of_countable [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| τ ω = i} := hτ.measurableSet_eq_of_countable_range (Set.to_countable _) i protected theorem measurableSet_lt_of_countable_range (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[f i] {ω \| τ ω < i} := by have : {ω \| τ ω < i} = {ω \| τ ω ≤ i} \ {ω \| τ ω = i} := by ext1 ω; simp [lt_iff_le_and_ne] rw [this] exact (hτ.measurableSet_le i).diff (hτ.measurableSet_eq_of_countable_range h_countable i) protected theorem measurableSet_lt_of_countable [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| τ ω < i} := hτ.measurableSet_lt_of_countable_range (Set.to_countable _) i protected theorem measurableSet_ge_of_countable_range {ι} [LinearOrder ι] {τ : Ω → ι} {f : Filtration ι m} (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[f i] {ω \| i ≤ τ ω} := by have : {ω \| i ≤ τ ω} = {ω \| τ ω < i}ᶜ := by ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_compl_iff, not_lt] rw [this] exact (hτ.measurableSet_lt_of_countable_range h_countable i).compl protected theorem measurableSet_ge_of_countable {ι} [LinearOrder ι] {τ : Ω → ι} {f : Filtration ι m} [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| i ≤ τ ω} := hτ.measurableSet_ge_of_countable_range (Set.to_countable _) i end IsStoppingTime end CountableStoppingTime section LinearOrder variable [LinearOrder ι] {f : Filtration ι m} {τ : Ω → ι} theorem IsStoppingTime.measurableSet_gt (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| i < τ ω} := by have : {ω \| i < τ ω} = {ω \| τ ω ≤ i}ᶜ := by ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_compl_iff, not_le] rw [this] exact (hτ.measurableSet_le i).compl section TopologicalSpace variable [TopologicalSpace ι] [OrderTopology ι] [FirstCountableTopology ι] /-- Auxiliary lemma for `MeasureTheory.IsStoppingTime.measurableSet_lt`. -/ theorem IsStoppingTime.measurableSet_lt_of_isLUB (hτ : IsStoppingTime f τ) (i : ι) (h_lub : IsLUB (Set.Iio i) i) : MeasurableSet[f i] {ω \| τ ω < i} := by by_cases hi_min : IsMin i · suffices {ω \| τ ω < i} = ∅ by rw [this]; exact @MeasurableSet.empty _ (f i) ext1 ω simp only [Set.mem_setOf_eq, Set.mem_empty_iff_false, iff_false] exact isMin_iff_forall_not_lt.mp hi_min (τ ω) obtain ⟨seq, -, -, h_tendsto, h_bound⟩ : ∃ seq : ℕ → ι, Monotone seq ∧ (∀ j, seq j ≤ i) ∧ Tendsto seq atTop (𝓝 i) ∧ ∀ j, seq j < i := h_lub.exists_seq_monotone_tendsto (not_isMin_iff.mp hi_min) have h_Ioi_eq_Union : Set.Iio i = ⋃ j, {k \| k ≤ seq j} := by ext1 k simp only [Set.mem_Iio, Set.mem_iUnion, Set.mem_setOf_eq] refine ⟨fun hk_lt_i => ?_, fun h_exists_k_le_seq => ?_⟩ · rw [tendsto_atTop'] at h_tendsto have h_nhds : Set.Ici k ∈ 𝓝 i := mem_nhds_iff.mpr ⟨Set.Ioi k, Set.Ioi_subset_Ici le_rfl, isOpen_Ioi, hk_lt_i⟩ obtain ⟨a, ha⟩ : ∃ a : ℕ, ∀ b : ℕ, b ≥ a → k ≤ seq b := h_tendsto (Set.Ici k) h_nhds exact ⟨a, ha a le_rfl⟩ · obtain ⟨j, hk_seq_j⟩ := h_exists_k_le_seq exact hk_seq_j.trans_lt (h_bound j) have h_lt_eq_preimage : {ω \| τ ω < i} = τ ⁻¹' Set.Iio i := by ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_preimage, Set.mem_Iio] rw [h_lt_eq_preimage, h_Ioi_eq_Union] simp only [Set.preimage_iUnion, Set.preimage_setOf_eq] exact MeasurableSet.iUnion fun n => f.mono (h_bound n).le _ (hτ.measurableSet_le (seq n)) theorem IsStoppingTime.measurableSet_lt (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| τ ω < i} := by obtain ⟨i', hi'_lub⟩ : ∃ i', IsLUB (Set.Iio i) i' := exists_lub_Iio i rcases lub_Iio_eq_self_or_Iio_eq_Iic i hi'_lub with hi'_eq_i \| h_Iio_eq_Iic · rw [← hi'_eq_i] at hi'_lub ⊢ exact hτ.measurableSet_lt_of_isLUB i' hi'_lub · have h_lt_eq_preimage : {ω : Ω \| τ ω < i} = τ ⁻¹' Set.Iio i := rfl rw [h_lt_eq_preimage, h_Iio_eq_Iic] exact f.mono (lub_Iio_le i hi'_lub) _ (hτ.measurableSet_le i') theorem IsStoppingTime.measurableSet_ge (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| i ≤ τ ω} := by have : {ω \| i ≤ τ ω} = {ω \| τ ω < i}ᶜ := by ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_compl_iff, not_lt] rw [this] exact (hτ.measurableSet_lt i).compl theorem IsStoppingTime.measurableSet_eq (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω \| τ ω = i} := by have : {ω \| τ ω = i} = {ω \| τ ω ≤ i} ∩ {ω \| τ ω ≥ i} := by ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_inter_iff, le_antisymm_iff] rw [this] exact (hτ.measurableSet_le i).inter (hτ.measurableSet_ge i) theorem IsStoppingTime.measurableSet_eq_le (hτ : IsStoppingTime f τ) {i j : ι} (hle : i ≤ j) : MeasurableSet[f j] {ω \| τ ω = i} := f.mono hle _ <\| hτ.measurableSet_eq i theorem IsStoppingTime.measurableSet_lt_le (hτ : IsStoppingTime f τ) {i j : ι} (hle : i ≤ j) : MeasurableSet[f j] {ω \| τ ω < i} := f.mono hle _ <\| hτ.measurableSet_lt i end TopologicalSpace end LinearOrder section Countable theorem isStoppingTime_of_measurableSet_eq [Preorder ι] [Countable ι] {f : Filtration ι m} {τ : Ω → ι} (hτ : ∀ i, MeasurableSet[f i] {ω \| τ ω = i}) : IsStoppingTime f τ := by intro i rw [show {ω \| τ ω ≤ i} = ⋃ k ≤ i, {ω \| τ ω = k} by ext; simp] refine MeasurableSet.biUnion (Set.to_countable _) fun k hk => ?_ exact f.mono hk _ (hτ k) end Countable end MeasurableSet namespace IsStoppingTime protected theorem max [LinearOrder ι] {f : Filtration ι m} {τ π : Ω → ι} (hτ : IsStoppingTime f τ) (hπ : IsStoppingTime f π) : IsStoppingTime f fun ω => max (τ ω) (π ω) := by intro i simp_rw [max_le_iff, Set.setOf_and] exact (hτ i).inter (hπ i) protected theorem max_const [LinearOrder ι] {f : Filtration ι m} {τ : Ω → ι} (hτ : IsStoppingTime f τ) (i : ι) : IsStoppingTime f fun ω => max (τ ω) i := hτ.max (isStoppingTime_const f i) protected theorem min [LinearOrder ι] {f : Filtration ι m} {τ π : Ω → ι} (hτ : IsStoppingTime f τ) (hπ : IsStoppingTime f π) : IsStoppingTime f fun ω => min (τ ω) (π ω) := by intro i simp_rw [min_le_iff, Set.setOf_or] exact (hτ i).union (hπ i) protected theorem min_const [LinearOrder ι] {f : Filtration ι m} {τ : Ω → ι} (hτ : IsStoppingTime f τ) (i : ι) : IsStoppingTime f fun ω => min (τ ω) i := hτ.min (isStoppingTime_const f i) theorem add_const [AddGroup ι] [Preorder ι] [AddRightMono ι] [AddLeftMono ι] {f : Filtration ι m} {τ : Ω → ι} (hτ : IsStoppingTime f τ) {i : ι} (hi : 0 ≤ i) : IsStoppingTime f fun ω => τ ω + i := by intro j simp_rw [← le_sub_iff_add_le] exact f.mono (sub_le_self j hi) _ (hτ (j - i)) theorem add_const_nat {f : Filtration ℕ m} {τ : Ω → ℕ} (hτ : IsStoppingTime f τ) {i : ℕ} : IsStoppingTime f fun ω => τ ω + i := by refine isStoppingTime_of_measurableSet_eq fun j => ?_ by_cases hij : i ≤ j · simp_rw [eq_comm, ← Nat.sub_eq_iff_eq_add hij, eq_comm] exact f.mono (j.sub_le i) _ (hτ.measurableSet_eq (j - i)) · rw [not_le] at hij convert @MeasurableSet.empty _ (f.1 j) ext ω simp only [Set.mem_empty_iff_false, iff_false, Set.mem_setOf] omega -- generalize to certain countable type? theorem add {f : Filtration ℕ m} {τ π : Ω → ℕ} (hτ : IsStoppingTime f τ) (hπ : IsStoppingTime f π) : IsStoppingTime f (τ + π) := by intro i rw [(_ : {ω \| (τ + π) ω ≤ i} = ⋃ k ≤ i, {ω \| π ω = k} ∩ {ω \| τ ω + k ≤ i})] · exact MeasurableSet.iUnion fun k => MeasurableSet.iUnion fun hk => (hπ.measurableSet_eq_le hk).inter (hτ.add_const_nat i) ext ω simp only [Pi.add_apply, Set.mem_setOf_eq, Set.mem_iUnion, Set.mem_inter_iff, exists_prop] refine ⟨fun h => ⟨π ω, by omega, rfl, h⟩, ?_⟩ rintro ⟨j, hj, rfl, h⟩ assumption section Preorder variable [Preorder ι] {f : Filtration ι m} {τ π : Ω → ι} /-- The associated σ-algebra with a stopping time. -/ protected def measurableSpace (hτ : IsStoppingTime f τ) : MeasurableSpace Ω where MeasurableSet' s := ∀ i : ι, MeasurableSet[f i] (s ∩ {ω \| τ ω ≤ i}) measurableSet_empty i := (Set.empty_inter {ω \| τ ω ≤ i}).symm ▸ @MeasurableSet.empty _ (f i) measurableSet_compl s hs i := by rw [(_ : sᶜ ∩ {ω \| τ ω ≤ i} = (sᶜ ∪ {ω \| τ ω ≤ i}ᶜ) ∩ {ω \| τ ω ≤ i})] · refine MeasurableSet.inter ?_ ?_ · rw [← Set.compl_inter] exact (hs i).compl · exact hτ i · rw [Set.union_inter_distrib_right] simp only [Set.compl_inter_self, Set.union_empty] measurableSet_iUnion s hs i := by rw [forall_swap] at hs rw [Set.iUnion_inter] exact MeasurableSet.iUnion (hs i) protected theorem measurableSet (hτ : IsStoppingTime f τ) (s : Set Ω) : MeasurableSet[hτ.measurableSpace] s ↔ ∀ i : ι, MeasurableSet[f i] (s ∩ {ω \| τ ω ≤ i}) := Iff.rfl theorem measurableSpace_mono (hτ : IsStoppingTime f τ) (hπ : IsStoppingTime f π) (hle : τ ≤ π) : hτ.measurableSpace ≤ hπ.measurableSpace := by intro s hs i rw [(_ : s ∩ {ω \| π ω ≤ i} = s ∩ {ω \| τ ω ≤ i} ∩ {ω \| π ω ≤ i})] · exact (hs i).inter (hπ i) · ext simp only [Set.mem_inter_iff, iff_self_and, and_congr_left_iff, Set.mem_setOf_eq] intro hle' _ exact le_trans (hle _) hle' theorem measurableSpace_le_of_countable [Countable ι] (hτ : IsStoppingTime f τ) : hτ.measurableSpace ≤ m := by intro s hs change ∀ i, MeasurableSet[f i] (s ∩ {ω \| τ ω ≤ i}) at hs rw [(_ : s = ⋃ i, s ∩ {ω \| τ ω ≤ i})] · exact MeasurableSet.iUnion fun i => f.le i _ (hs i) · ext ω; constructor <;> rw [Set.mem_iUnion] · exact fun hx => ⟨τ ω, hx, le_rfl⟩ · rintro ⟨_, hx, _⟩ exact hx theorem measurableSpace_le [IsCountablyGenerated (atTop : Filter ι)] [IsDirected ι (· ≤ ·)] (hτ : IsStoppingTime f τ) : hτ.measurableSpace ≤ m := by intro s hs cases isEmpty_or_nonempty ι · haveI : IsEmpty Ω := ⟨fun ω => IsEmpty.false (τ ω)⟩ apply Subsingleton.measurableSet · change ∀ i, MeasurableSet[f i] (s ∩ {ω \| τ ω ≤ i}) at hs obtain ⟨seq : ℕ → ι, h_seq_tendsto⟩ := (atTop : Filter ι).exists_seq_tendsto rw [(_ : s = ⋃ n, s ∩ {ω \| τ ω ≤ seq n})] · exact MeasurableSet.iUnion fun i => f.le (seq i) _ (hs (seq i)) · ext ω; constructor <;> rw [Set.mem_iUnion] · intro hx suffices ∃ i, τ ω ≤ seq i from ⟨this.choose, hx, this.choose_spec⟩ rw [tendsto_atTop] at h_seq_tendsto exact (h_seq_tendsto (τ ω)).exists · rintro ⟨_, hx, _⟩ exact hx @[deprecated (since := "2024-12-25")] alias measurableSpace_le' := measurableSpace_le example {f : Filtration ℕ m} {τ : Ω → ℕ} (hτ : IsStoppingTime f τ) : hτ.measurableSpace ≤ m := hτ.measurableSpace_le example {f : Filtration ℝ m} {τ : Ω → ℝ} (hτ : IsStoppingTime f τ) : hτ.measurableSpace ≤ m := hτ.measurableSpace_le @[simp] theorem measurableSpace_const (f : Filtration ι m) (i : ι) : (isStoppingTime_const f i).measurableSpace = f i := by ext1 s change MeasurableSet[(isStoppingTime_const f i).measurableSpace] s ↔ MeasurableSet[f i] s rw [IsStoppingTime.measurableSet] constructor <;> intro h · specialize h i simpa only [le_refl, Set.setOf_true, Set.inter_univ] using h · intro j by_cases hij : i ≤ j · simp only [hij, Set.setOf_true, Set.inter_univ] exact f.mono hij _ h · simp only [hij, Set.setOf_false, Set.inter_empty, @MeasurableSet.empty _ (f.1 j)] theorem measurableSet_inter_eq_iff (hτ : IsStoppingTime f τ) (s : Set Ω) (i : ι) : MeasurableSet[hτ.measurableSpace] (s ∩ {ω \| τ ω = i}) ↔ MeasurableSet[f i] (s ∩ {ω \| τ ω = i}) := by have : ∀ j, {ω : Ω \| τ ω = i} ∩ {ω : Ω \| τ ω ≤ j} = {ω : Ω \| τ ω = i} ∩ {_ω \| i ≤ j} := by intro j ext1 ω simp only [Set.mem_inter_iff, Set.mem_setOf_eq, and_congr_right_iff] intro hxi rw [hxi] constructor <;> intro h · specialize h i simpa only [Set.inter_assoc, this, le_refl, Set.setOf_true, Set.inter_univ] using h · intro j rw [Set.inter_assoc, this] by_cases hij : i ≤ j · simp only [hij, Set.setOf_true, Set.inter_univ] exact f.mono hij _ h · simp [hij] theorem measurableSpace_le_of_le_const (hτ : IsStoppingTime f τ) {i : ι} (hτ_le : ∀ ω, τ ω ≤ i) : hτ.measurableSpace ≤ f i := (measurableSpace_mono hτ _ hτ_le).trans (measurableSpace_const _ _).le theorem measurableSpace_le_of_le (hτ : IsStoppingTime f τ) {n : ι} (hτ_le : ∀ ω, τ ω ≤ n) : hτ.measurableSpace ≤ m := (hτ.measurableSpace_le_of_le_const hτ_le).trans (f.le n) theorem le_measurableSpace_of_const_le (hτ : IsStoppingTime f τ) {i : ι} (hτ_le : ∀ ω, i ≤ τ ω) : f i ≤ hτ.measurableSpace := (measurableSpace_const _ _).symm.le.trans (measurableSpace_mono _ hτ hτ_le) end Preorder instance sigmaFinite_stopping_time {ι} [SemilatticeSup ι] [OrderBot ι] [(Filter.atTop : Filter ι).IsCountablyGenerated] {μ : Measure Ω} {f : Filtration ι m} {τ : Ω → ι} [SigmaFiniteFiltration μ f] (hτ : IsStoppingTime f τ) : SigmaFinite (μ.trim hτ.measurableSpace_le) := by refine @sigmaFiniteTrim_mono _ _ ?_ _ _ _ ?_ ?_ · exact f ⊥ · exact hτ.le_measurableSpace_of_const_le fun _ => bot_le · infer_instance instance sigmaFinite_stopping_time_of_le {ι} [SemilatticeSup ι] [OrderBot ι] {μ : Measure Ω} {f : Filtration ι m} {τ : Ω → ι} [SigmaFiniteFiltration μ f] (hτ : IsStoppingTime f τ) {n : ι} (hτ_le : ∀ ω, τ ω ≤ n) : SigmaFinite (μ.trim (hτ.measurableSpace_le_of_le hτ_le)) := by refine @sigmaFiniteTrim_mono _ _ ?_ _ _ _ ?_ ?_ · exact f ⊥ · exact hτ.le_measurableSpace_of_const_le fun _ => bot_le · infer_instance section LinearOrder variable [LinearOrder ι] {f : Filtration ι m} {τ π : Ω → ι} protected theorem measurableSet_le' (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| τ ω ≤ i} := by intro j have : {ω : Ω \| τ ω ≤ i} ∩ {ω : Ω \| τ ω ≤ j} = {ω : Ω \| τ ω ≤ min i j} := by ext1 ω; simp only [Set.mem_inter_iff, Set.mem_setOf_eq, le_min_iff] rw [this] exact f.mono (min_le_right i j) _ (hτ _) protected theorem measurableSet_gt' (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| i < τ ω} := by have : {ω : Ω \| i < τ ω} = {ω : Ω \| τ ω ≤ i}ᶜ := by ext1 ω; simp rw [this] exact (hτ.measurableSet_le' i).compl protected theorem measurableSet_eq' [TopologicalSpace ι] [OrderTopology ι] [FirstCountableTopology ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| τ ω = i} := by rw [← Set.univ_inter {ω \| τ ω = i}, measurableSet_inter_eq_iff, Set.univ_inter] exact hτ.measurableSet_eq i protected theorem measurableSet_ge' [TopologicalSpace ι] [OrderTopology ι] [FirstCountableTopology ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| i ≤ τ ω} := by have : {ω \| i ≤ τ ω} = {ω \| τ ω = i} ∪ {ω \| i < τ ω} := by ext1 ω simp only [le_iff_lt_or_eq, Set.mem_setOf_eq, Set.mem_union] rw [@eq_comm _ i, or_comm] rw [this] exact (hτ.measurableSet_eq' i).union (hτ.measurableSet_gt' i) protected theorem measurableSet_lt' [TopologicalSpace ι] [OrderTopology ι] [FirstCountableTopology ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| τ ω < i} := by have : {ω \| τ ω < i} = {ω \| τ ω ≤ i} \ {ω \| τ ω = i} := by ext1 ω simp only [lt_iff_le_and_ne, Set.mem_setOf_eq, Set.mem_diff] rw [this] exact (hτ.measurableSet_le' i).diff (hτ.measurableSet_eq' i) section Countable protected theorem measurableSet_eq_of_countable_range' (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| τ ω = i} := by rw [← Set.univ_inter {ω \| τ ω = i}, measurableSet_inter_eq_iff, Set.univ_inter] exact hτ.measurableSet_eq_of_countable_range h_countable i protected theorem measurableSet_eq_of_countable' [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| τ ω = i} := hτ.measurableSet_eq_of_countable_range' (Set.to_countable _) i protected theorem measurableSet_ge_of_countable_range' (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| i ≤ τ ω} := by have : {ω \| i ≤ τ ω} = {ω \| τ ω = i} ∪ {ω \| i < τ ω} := by ext1 ω simp only [le_iff_lt_or_eq, Set.mem_setOf_eq, Set.mem_union] rw [@eq_comm _ i, or_comm] rw [this] exact (hτ.measurableSet_eq_of_countable_range' h_countable i).union (hτ.measurableSet_gt' i) protected theorem measurableSet_ge_of_countable' [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| i ≤ τ ω} := hτ.measurableSet_ge_of_countable_range' (Set.to_countable _) i protected theorem measurableSet_lt_of_countable_range' (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| τ ω < i} := by have : {ω \| τ ω < i} = {ω \| τ ω ≤ i} \ {ω \| τ ω = i} := by ext1 ω simp only [lt_iff_le_and_ne, Set.mem_setOf_eq, Set.mem_diff] rw [this] exact (hτ.measurableSet_le' i).diff (hτ.measurableSet_eq_of_countable_range' h_countable i) protected theorem measurableSet_lt_of_countable' [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[hτ.measurableSpace] {ω \| τ ω < i} := hτ.measurableSet_lt_of_countable_range' (Set.to_countable _) i protected theorem measurableSpace_le_of_countable_range (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) : hτ.measurableSpace ≤ m := by intro s hs change ∀ i, MeasurableSet[f i] (s ∩ {ω \| τ ω ≤ i}) at hs rw [(_ : s = ⋃ i ∈ Set.range τ, s ∩ {ω \| τ ω ≤ i})] · exact MeasurableSet.biUnion h_countable fun i _ => f.le i _ (hs i) · ext ω constructor <;> rw [Set.mem_iUnion] · exact fun hx => ⟨τ ω, by simpa using hx⟩ · rintro ⟨i, hx⟩ simp only [Set.mem_range, Set.iUnion_exists, Set.mem_iUnion, Set.mem_inter_iff, Set.mem_setOf_eq, exists_prop, exists_and_right] at hx exact hx.2.1	end Countable protected theorem measurable [TopologicalSpace ι] [MeasurableSpace ι] [BorelSpace ι] [OrderTopology ι] [SecondCountableTopology ι] (hτ : IsStoppingTime f τ) : Measurable[hτ.measurableSpace] τ :=	Mathlib/Probability/Process/Stopping.lean	514	518
/- Copyright (c) 2019 Johannes Hölzl, Zhouhang Zhou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Zhouhang Zhou -/ import Mathlib.Dynamics.Ergodic.MeasurePreserving import Mathlib.MeasureTheory.Function.StronglyMeasurable.AEStronglyMeasurable import Mathlib.MeasureTheory.Integral.Lebesgue.Add import Mathlib.Order.Filter.Germ.Basic import Mathlib.Topology.ContinuousMap.Algebra /-! # Almost everywhere equal functions We build a space of equivalence classes of functions, where two functions are treated as identical if they are almost everywhere equal. We form the set of equivalence classes under the relation of being almost everywhere equal, which is sometimes known as the `L⁰` space. To use this space as a basis for the `L^p` spaces and for the Bochner integral, we consider equivalence classes of strongly measurable functions (or, equivalently, of almost everywhere strongly measurable functions.) See `L1Space.lean` for `L¹` space. ## Notation * `α →ₘ[μ] β` is the type of `L⁰` space, where `α` is a measurable space, `β` is a topological space, and `μ` is a measure on `α`. `f : α →ₘ β` is a "function" in `L⁰`. In comments, `[f]` is also used to denote an `L⁰` function. `ₘ` can be typed as `\_m`. Sometimes it is shown as a box if font is missing. ## Main statements * The linear structure of `L⁰` : Addition and scalar multiplication are defined on `L⁰` in the natural way, i.e., `[f] + [g] := [f + g]`, `c • [f] := [c • f]`. So defined, `α →ₘ β` inherits the linear structure of `β`. For example, if `β` is a module, then `α →ₘ β` is a module over the same ring. See `mk_add_mk`, `neg_mk`, `mk_sub_mk`, `smul_mk`, `add_toFun`, `neg_toFun`, `sub_toFun`, `smul_toFun` * The order structure of `L⁰` : `≤` can be defined in a similar way: `[f] ≤ [g]` if `f a ≤ g a` for almost all `a` in domain. And `α →ₘ β` inherits the preorder and partial order of `β`. TODO: Define `sup` and `inf` on `L⁰` so that it forms a lattice. It seems that `β` must be a linear order, since otherwise `f ⊔ g` may not be a measurable function. ## Implementation notes * `f.toFun` : To find a representative of `f : α →ₘ β`, use the coercion `(f : α → β)`, which is implemented as `f.toFun`. For each operation `op` in `L⁰`, there is a lemma called `coe_fn_op`, characterizing, say, `(f op g : α → β)`. * `ae_eq_fun.mk` : To constructs an `L⁰` function `α →ₘ β` from an almost everywhere strongly measurable function `f : α → β`, use `ae_eq_fun.mk` * `comp` : Use `comp g f` to get `[g ∘ f]` from `g : β → γ` and `[f] : α →ₘ γ` when `g` is continuous. Use `comp_measurable` if `g` is only measurable (this requires the target space to be second countable). * `comp₂` : Use `comp₂ g f₁ f₂` to get `[fun a ↦ g (f₁ a) (f₂ a)]`. For example, `[f + g]` is `comp₂ (+)` ## Tags function space, almost everywhere equal, `L⁰`, ae_eq_fun -/ -- Guard against import creep assert_not_exists InnerProductSpace noncomputable section open Topology Set Filter TopologicalSpace ENNReal EMetric MeasureTheory Function variable {α β γ δ : Type} [MeasurableSpace α] {μ ν : Measure α} namespace MeasureTheory section MeasurableSpace variable [TopologicalSpace β] variable (β) /-- The equivalence relation of being almost everywhere equal for almost everywhere strongly measurable functions. -/ def Measure.aeEqSetoid (μ : Measure α) : Setoid { f : α → β // AEStronglyMeasurable f μ } := ⟨fun f g => (f : α → β) =ᵐ[μ] g, fun {f} => ae_eq_refl f.val, fun {_ _} => ae_eq_symm, fun {_ _ _} => ae_eq_trans⟩ variable (α) /-- The space of equivalence classes of almost everywhere strongly measurable functions, where two strongly measurable functions are equivalent if they agree almost everywhere, i.e., they differ on a set of measure `0`. -/ def AEEqFun (μ : Measure α) : Type _ := Quotient (μ.aeEqSetoid β) variable {α β} @[inherit_doc MeasureTheory.AEEqFun] notation:25 α " →ₘ[" μ "] " β => AEEqFun α β μ end MeasurableSpace variable [TopologicalSpace δ] namespace AEEqFun section variable [TopologicalSpace β] /-- Construct the equivalence class `[f]` of an almost everywhere measurable function `f`, based on the equivalence relation of being almost everywhere equal. -/ def mk {β : Type} [TopologicalSpace β] (f : α → β) (hf : AEStronglyMeasurable f μ) : α →ₘ[μ] β := Quotient.mk'' ⟨f, hf⟩ open scoped Classical in /-- Coercion from a space of equivalence classes of almost everywhere strongly measurable functions to functions. We ensure that if `f` has a constant representative, then we choose that one. -/ @[coe] def cast (f : α →ₘ[μ] β) : α → β := if h : ∃ (b : β), f = mk (const α b) aestronglyMeasurable_const then const α <\| Classical.choose h else AEStronglyMeasurable.mk _ (Quotient.out f : { f : α → β // AEStronglyMeasurable f μ }).2 /-- A measurable representative of an `AEEqFun` [f] -/ instance instCoeFun : CoeFun (α →ₘ[μ] β) fun _ => α → β := ⟨cast⟩ protected theorem stronglyMeasurable (f : α →ₘ[μ] β) : StronglyMeasurable f := by simp only [cast] split_ifs with h · exact stronglyMeasurable_const · apply AEStronglyMeasurable.stronglyMeasurable_mk protected theorem aestronglyMeasurable (f : α →ₘ[μ] β) : AEStronglyMeasurable f μ := f.stronglyMeasurable.aestronglyMeasurable protected theorem measurable [PseudoMetrizableSpace β] [MeasurableSpace β] [BorelSpace β] (f : α →ₘ[μ] β) : Measurable f := f.stronglyMeasurable.measurable protected theorem aemeasurable [PseudoMetrizableSpace β] [MeasurableSpace β] [BorelSpace β] (f : α →ₘ[μ] β) : AEMeasurable f μ := f.measurable.aemeasurable @[simp] theorem quot_mk_eq_mk (f : α → β) (hf) : (Quot.mk (@Setoid.r _ <\| μ.aeEqSetoid β) ⟨f, hf⟩ : α →ₘ[μ] β) = mk f hf := rfl @[simp] theorem mk_eq_mk {f g : α → β} {hf hg} : (mk f hf : α →ₘ[μ] β) = mk g hg ↔ f =ᵐ[μ] g := Quotient.eq'' @[simp] theorem mk_coeFn (f : α →ₘ[μ] β) : mk f f.aestronglyMeasurable = f := by conv_lhs => simp only [cast] split_ifs with h · exact Classical.choose_spec h \|>.symm conv_rhs => rw [← Quotient.out_eq' f] rw [← mk, mk_eq_mk] exact (AEStronglyMeasurable.ae_eq_mk _).symm @[ext] theorem ext {f g : α →ₘ[μ] β} (h : f =ᵐ[μ] g) : f = g := by rwa [← f.mk_coeFn, ← g.mk_coeFn, mk_eq_mk] theorem coeFn_mk (f : α → β) (hf) : (mk f hf : α →ₘ[μ] β) =ᵐ[μ] f := by rw [← mk_eq_mk, mk_coeFn] @[elab_as_elim] theorem induction_on (f : α →ₘ[μ] β) {p : (α →ₘ[μ] β) → Prop} (H : ∀ f hf, p (mk f hf)) : p f := Quotient.inductionOn' f <\| Subtype.forall.2 H @[elab_as_elim] theorem induction_on₂ {α' β' : Type} [MeasurableSpace α'] [TopologicalSpace β'] {μ' : Measure α'} (f : α →ₘ[μ] β) (f' : α' →ₘ[μ'] β') {p : (α →ₘ[μ] β) → (α' →ₘ[μ'] β') → Prop} (H : ∀ f hf f' hf', p (mk f hf) (mk f' hf')) : p f f' := induction_on f fun f hf => induction_on f' <\| H f hf @[elab_as_elim] theorem induction_on₃ {α' β' : Type} [MeasurableSpace α'] [TopologicalSpace β'] {μ' : Measure α'} {α'' β'' : Type} [MeasurableSpace α''] [TopologicalSpace β''] {μ'' : Measure α''} (f : α →ₘ[μ] β) (f' : α' →ₘ[μ'] β') (f'' : α'' →ₘ[μ''] β'') {p : (α →ₘ[μ] β) → (α' →ₘ[μ'] β') → (α'' →ₘ[μ''] β'') → Prop} (H : ∀ f hf f' hf' f'' hf'', p (mk f hf) (mk f' hf') (mk f'' hf'')) : p f f' f'' := induction_on f fun f hf => induction_on₂ f' f'' <\| H f hf end /-! ### Composition of an a.e. equal function with a (quasi) measure preserving function -/ section compQuasiMeasurePreserving variable [TopologicalSpace γ] [MeasurableSpace β] {ν : MeasureTheory.Measure β} {f : α → β} open MeasureTheory.Measure (QuasiMeasurePreserving) /-- Composition of an almost everywhere equal function and a quasi measure preserving function. See also `AEEqFun.compMeasurePreserving`. -/ def compQuasiMeasurePreserving (g : β →ₘ[ν] γ) (f : α → β) (hf : QuasiMeasurePreserving f μ ν) : α →ₘ[μ] γ := Quotient.liftOn' g (fun g ↦ mk (g ∘ f) <\| g.2.comp_quasiMeasurePreserving hf) fun _ _ h ↦ mk_eq_mk.2 <\| h.comp_tendsto hf.tendsto_ae @[simp] theorem compQuasiMeasurePreserving_mk {g : β → γ} (hg : AEStronglyMeasurable g ν) (hf : QuasiMeasurePreserving f μ ν) : (mk g hg).compQuasiMeasurePreserving f hf = mk (g ∘ f) (hg.comp_quasiMeasurePreserving hf) := rfl theorem compQuasiMeasurePreserving_eq_mk (g : β →ₘ[ν] γ) (hf : QuasiMeasurePreserving f μ ν) : g.compQuasiMeasurePreserving f hf = mk (g ∘ f) (g.aestronglyMeasurable.comp_quasiMeasurePreserving hf) := by rw [← compQuasiMeasurePreserving_mk g.aestronglyMeasurable hf, mk_coeFn] theorem coeFn_compQuasiMeasurePreserving (g : β →ₘ[ν] γ) (hf : QuasiMeasurePreserving f μ ν) : g.compQuasiMeasurePreserving f hf =ᵐ[μ] g ∘ f := by rw [compQuasiMeasurePreserving_eq_mk] apply coeFn_mk end compQuasiMeasurePreserving section compMeasurePreserving variable [TopologicalSpace γ] [MeasurableSpace β] {ν : MeasureTheory.Measure β} {f : α → β} {g : β → γ} /-- Composition of an almost everywhere equal function and a quasi measure preserving function. This is an important special case of `AEEqFun.compQuasiMeasurePreserving`. We use a separate definition so that lemmas that need `f` to be measure preserving can be `@[simp]` lemmas. -/ def compMeasurePreserving (g : β →ₘ[ν] γ) (f : α → β) (hf : MeasurePreserving f μ ν) : α →ₘ[μ] γ := g.compQuasiMeasurePreserving f hf.quasiMeasurePreserving @[simp] theorem compMeasurePreserving_mk (hg : AEStronglyMeasurable g ν) (hf : MeasurePreserving f μ ν) : (mk g hg).compMeasurePreserving f hf = mk (g ∘ f) (hg.comp_quasiMeasurePreserving hf.quasiMeasurePreserving) := rfl theorem compMeasurePreserving_eq_mk (g : β →ₘ[ν] γ) (hf : MeasurePreserving f μ ν) : g.compMeasurePreserving f hf = mk (g ∘ f) (g.aestronglyMeasurable.comp_quasiMeasurePreserving hf.quasiMeasurePreserving) := g.compQuasiMeasurePreserving_eq_mk _ theorem coeFn_compMeasurePreserving (g : β →ₘ[ν] γ) (hf : MeasurePreserving f μ ν) : g.compMeasurePreserving f hf =ᵐ[μ] g ∘ f := g.coeFn_compQuasiMeasurePreserving _ end compMeasurePreserving variable [TopologicalSpace β] [TopologicalSpace γ] /-- Given a continuous function `g : β → γ`, and an almost everywhere equal function `[f] : α →ₘ β`, return the equivalence class of `g ∘ f`, i.e., the almost everywhere equal function `[g ∘ f] : α →ₘ γ`. -/ def comp (g : β → γ) (hg : Continuous g) (f : α →ₘ[μ] β) : α →ₘ[μ] γ := Quotient.liftOn' f (fun f => mk (g ∘ (f : α → β)) (hg.comp_aestronglyMeasurable f.2)) fun _ _ H => mk_eq_mk.2 <\| H.fun_comp g @[simp] theorem comp_mk (g : β → γ) (hg : Continuous g) (f : α → β) (hf) : comp g hg (mk f hf : α →ₘ[μ] β) = mk (g ∘ f) (hg.comp_aestronglyMeasurable hf) := rfl theorem comp_eq_mk (g : β → γ) (hg : Continuous g) (f : α →ₘ[μ] β) : comp g hg f = mk (g ∘ f) (hg.comp_aestronglyMeasurable f.aestronglyMeasurable) := by rw [← comp_mk g hg f f.aestronglyMeasurable, mk_coeFn] theorem coeFn_comp (g : β → γ) (hg : Continuous g) (f : α →ₘ[μ] β) : comp g hg f =ᵐ[μ] g ∘ f := by rw [comp_eq_mk] apply coeFn_mk theorem comp_compQuasiMeasurePreserving {β : Type} [MeasurableSpace β] {ν} (g : γ → δ) (hg : Continuous g) (f : β →ₘ[ν] γ) {φ : α → β} (hφ : Measure.QuasiMeasurePreserving φ μ ν) : (comp g hg f).compQuasiMeasurePreserving φ hφ = comp g hg (f.compQuasiMeasurePreserving φ hφ) := by rcases f; rfl section CompMeasurable variable [MeasurableSpace β] [PseudoMetrizableSpace β] [BorelSpace β] [MeasurableSpace γ] [PseudoMetrizableSpace γ] [OpensMeasurableSpace γ] [SecondCountableTopology γ] /-- Given a measurable function `g : β → γ`, and an almost everywhere equal function `[f] : α →ₘ β`, return the equivalence class of `g ∘ f`, i.e., the almost everywhere equal function `[g ∘ f] : α →ₘ γ`. This requires that `γ` has a second countable topology. -/ def compMeasurable (g : β → γ) (hg : Measurable g) (f : α →ₘ[μ] β) : α →ₘ[μ] γ := Quotient.liftOn' f (fun f' => mk (g ∘ (f' : α → β)) (hg.comp_aemeasurable f'.2.aemeasurable).aestronglyMeasurable) fun _ _ H => mk_eq_mk.2 <\| H.fun_comp g @[simp] theorem compMeasurable_mk (g : β → γ) (hg : Measurable g) (f : α → β) (hf : AEStronglyMeasurable f μ) : compMeasurable g hg (mk f hf : α →ₘ[μ] β) = mk (g ∘ f) (hg.comp_aemeasurable hf.aemeasurable).aestronglyMeasurable := rfl theorem compMeasurable_eq_mk (g : β → γ) (hg : Measurable g) (f : α →ₘ[μ] β) : compMeasurable g hg f = mk (g ∘ f) (hg.comp_aemeasurable f.aemeasurable).aestronglyMeasurable := by rw [← compMeasurable_mk g hg f f.aestronglyMeasurable, mk_coeFn] theorem coeFn_compMeasurable (g : β → γ) (hg : Measurable g) (f : α →ₘ[μ] β) : compMeasurable g hg f =ᵐ[μ] g ∘ f := by rw [compMeasurable_eq_mk] apply coeFn_mk end CompMeasurable /-- The class of `x ↦ (f x, g x)`. -/ def pair (f : α →ₘ[μ] β) (g : α →ₘ[μ] γ) : α →ₘ[μ] β × γ := Quotient.liftOn₂' f g (fun f g => mk (fun x => (f.1 x, g.1 x)) (f.2.prodMk g.2)) fun _f _g _f' _g' Hf Hg => mk_eq_mk.2 <\| Hf.prodMk Hg @[simp] theorem pair_mk_mk (f : α → β) (hf) (g : α → γ) (hg) : (mk f hf : α →ₘ[μ] β).pair (mk g hg) = mk (fun x => (f x, g x)) (hf.prodMk hg) := rfl theorem pair_eq_mk (f : α →ₘ[μ] β) (g : α →ₘ[μ] γ) : f.pair g = mk (fun x => (f x, g x)) (f.aestronglyMeasurable.prodMk g.aestronglyMeasurable) := by simp only [← pair_mk_mk, mk_coeFn, f.aestronglyMeasurable, g.aestronglyMeasurable] theorem coeFn_pair (f : α →ₘ[μ] β) (g : α →ₘ[μ] γ) : f.pair g =ᵐ[μ] fun x => (f x, g x) := by rw [pair_eq_mk] apply coeFn_mk /-- Given a continuous function `g : β → γ → δ`, and almost everywhere equal functions `[f₁] : α →ₘ β` and `[f₂] : α →ₘ γ`, return the equivalence class of the function `fun a => g (f₁ a) (f₂ a)`, i.e., the almost everywhere equal function `[fun a => g (f₁ a) (f₂ a)] : α →ₘ γ` -/ def comp₂ (g : β → γ → δ) (hg : Continuous (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : α →ₘ[μ] δ := comp _ hg (f₁.pair f₂) @[simp] theorem comp₂_mk_mk (g : β → γ → δ) (hg : Continuous (uncurry g)) (f₁ : α → β) (f₂ : α → γ) (hf₁ hf₂) : comp₂ g hg (mk f₁ hf₁ : α →ₘ[μ] β) (mk f₂ hf₂) = mk (fun a => g (f₁ a) (f₂ a)) (hg.comp_aestronglyMeasurable (hf₁.prodMk hf₂)) := rfl theorem comp₂_eq_pair (g : β → γ → δ) (hg : Continuous (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : comp₂ g hg f₁ f₂ = comp _ hg (f₁.pair f₂) := rfl theorem comp₂_eq_mk (g : β → γ → δ) (hg : Continuous (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : comp₂ g hg f₁ f₂ = mk (fun a => g (f₁ a) (f₂ a)) (hg.comp_aestronglyMeasurable (f₁.aestronglyMeasurable.prodMk f₂.aestronglyMeasurable)) := by rw [comp₂_eq_pair, pair_eq_mk, comp_mk]; rfl theorem coeFn_comp₂ (g : β → γ → δ) (hg : Continuous (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : comp₂ g hg f₁ f₂ =ᵐ[μ] fun a => g (f₁ a) (f₂ a) := by rw [comp₂_eq_mk] apply coeFn_mk section variable [MeasurableSpace β] [PseudoMetrizableSpace β] [BorelSpace β] [MeasurableSpace γ] [PseudoMetrizableSpace γ] [BorelSpace γ] [SecondCountableTopologyEither β γ] [MeasurableSpace δ] [PseudoMetrizableSpace δ] [OpensMeasurableSpace δ] [SecondCountableTopology δ] /-- Given a measurable function `g : β → γ → δ`, and almost everywhere equal functions `[f₁] : α →ₘ β` and `[f₂] : α →ₘ γ`, return the equivalence class of the function `fun a => g (f₁ a) (f₂ a)`, i.e., the almost everywhere equal function `[fun a => g (f₁ a) (f₂ a)] : α →ₘ γ`. This requires `δ` to have second-countable topology. -/ def comp₂Measurable (g : β → γ → δ) (hg : Measurable (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : α →ₘ[μ] δ := compMeasurable _ hg (f₁.pair f₂) @[simp] theorem comp₂Measurable_mk_mk (g : β → γ → δ) (hg : Measurable (uncurry g)) (f₁ : α → β) (f₂ : α → γ) (hf₁ hf₂) : comp₂Measurable g hg (mk f₁ hf₁ : α →ₘ[μ] β) (mk f₂ hf₂) = mk (fun a => g (f₁ a) (f₂ a)) (hg.comp_aemeasurable (hf₁.aemeasurable.prodMk hf₂.aemeasurable)).aestronglyMeasurable := rfl theorem comp₂Measurable_eq_pair (g : β → γ → δ) (hg : Measurable (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : comp₂Measurable g hg f₁ f₂ = compMeasurable _ hg (f₁.pair f₂) := rfl theorem comp₂Measurable_eq_mk (g : β → γ → δ) (hg : Measurable (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : comp₂Measurable g hg f₁ f₂ = mk (fun a => g (f₁ a) (f₂ a)) (hg.comp_aemeasurable (f₁.aemeasurable.prodMk f₂.aemeasurable)).aestronglyMeasurable := by rw [comp₂Measurable_eq_pair, pair_eq_mk, compMeasurable_mk]; rfl theorem coeFn_comp₂Measurable (g : β → γ → δ) (hg : Measurable (uncurry g)) (f₁ : α →ₘ[μ] β) (f₂ : α →ₘ[μ] γ) : comp₂Measurable g hg f₁ f₂ =ᵐ[μ] fun a => g (f₁ a) (f₂ a) := by rw [comp₂Measurable_eq_mk] apply coeFn_mk end /-- Interpret `f : α →ₘ[μ] β` as a germ at `ae μ` forgetting that `f` is almost everywhere strongly measurable. -/ def toGerm (f : α →ₘ[μ] β) : Germ (ae μ) β := Quotient.liftOn' f (fun f => ((f : α → β) : Germ (ae μ) β)) fun _ _ H => Germ.coe_eq.2 H @[simp] theorem mk_toGerm (f : α → β) (hf) : (mk f hf : α →ₘ[μ] β).toGerm = f := rfl theorem toGerm_eq (f : α →ₘ[μ] β) : f.toGerm = (f : α → β) := by rw [← mk_toGerm, mk_coeFn] theorem toGerm_injective : Injective (toGerm : (α →ₘ[μ] β) → Germ (ae μ) β) := fun f g H => ext <\| Germ.coe_eq.1 <\| by rwa [← toGerm_eq, ← toGerm_eq] @[simp] theorem compQuasiMeasurePreserving_toGerm {β : Type*} [MeasurableSpace β] {f : α → β} {ν} (g : β →ₘ[ν] γ) (hf : Measure.QuasiMeasurePreserving f μ ν) : (g.compQuasiMeasurePreserving f hf).toGerm = g.toGerm.compTendsto f hf.tendsto_ae := by rcases g; rfl	@[simp] theorem compMeasurePreserving_toGerm {β : Type*} [MeasurableSpace β] {f : α → β} {ν} (g : β →ₘ[ν] γ) (hf : MeasurePreserving f μ ν) :	Mathlib/MeasureTheory/Function/AEEqFun.lean	428	431
/- Copyright (c) 2020 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers -/ import Mathlib.Analysis.SpecialFunctions.Trigonometric.Arctan import Mathlib.Geometry.Euclidean.Angle.Unoriented.Affine /-! # Right-angled triangles This file proves basic geometrical results about distances and angles in (possibly degenerate) right-angled triangles in real inner product spaces and Euclidean affine spaces. ## Implementation notes Results in this file are generally given in a form with only those non-degeneracy conditions needed for the particular result, rather than requiring affine independence of the points of a triangle unnecessarily. ## References * https://en.wikipedia.org/wiki/Pythagorean_theorem -/ noncomputable section open scoped EuclideanGeometry open scoped Real open scoped RealInnerProductSpace namespace InnerProductGeometry variable {V : Type} [NormedAddCommGroup V] [InnerProductSpace ℝ V] /-- Pythagorean theorem, if-and-only-if vector angle form. -/ theorem norm_add_sq_eq_norm_sq_add_norm_sq_iff_angle_eq_pi_div_two (x y : V) : ‖x + y‖ ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ angle x y = π / 2 := by rw [norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero] exact inner_eq_zero_iff_angle_eq_pi_div_two x y /-- Pythagorean theorem, vector angle form. -/ theorem norm_add_sq_eq_norm_sq_add_norm_sq' (x y : V) (h : angle x y = π / 2) : ‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ := (norm_add_sq_eq_norm_sq_add_norm_sq_iff_angle_eq_pi_div_two x y).2 h /-- Pythagorean theorem, subtracting vectors, if-and-only-if vector angle form. -/ theorem norm_sub_sq_eq_norm_sq_add_norm_sq_iff_angle_eq_pi_div_two (x y : V) : ‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ angle x y = π / 2 := by rw [norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero] exact inner_eq_zero_iff_angle_eq_pi_div_two x y /-- Pythagorean theorem, subtracting vectors, vector angle form. -/ theorem norm_sub_sq_eq_norm_sq_add_norm_sq' (x y : V) (h : angle x y = π / 2) : ‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ := (norm_sub_sq_eq_norm_sq_add_norm_sq_iff_angle_eq_pi_div_two x y).2 h /-- An angle in a right-angled triangle expressed using `arccos`. -/ theorem angle_add_eq_arccos_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) : angle x (x + y) = Real.arccos (‖x‖ / ‖x + y‖) := by rw [angle, inner_add_right, h, add_zero, real_inner_self_eq_norm_mul_norm] by_cases hx : ‖x‖ = 0; · simp [hx] rw [div_mul_eq_div_div, mul_self_div_self] /-- An angle in a right-angled triangle expressed using `arcsin`. -/ theorem angle_add_eq_arcsin_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) (h0 : x ≠ 0 ∨ y ≠ 0) : angle x (x + y) = Real.arcsin (‖y‖ / ‖x + y‖) := by have hxy : ‖x + y‖ ^ 2 ≠ 0 := by rw [pow_two, norm_add_sq_eq_norm_sq_add_norm_sq_real h, ne_comm] refine ne_of_lt ?_ rcases h0 with (h0 \| h0) · exact Left.add_pos_of_pos_of_nonneg (mul_self_pos.2 (norm_ne_zero_iff.2 h0)) (mul_self_nonneg _) · exact Left.add_pos_of_nonneg_of_pos (mul_self_nonneg _) (mul_self_pos.2 (norm_ne_zero_iff.2 h0)) rw [angle_add_eq_arccos_of_inner_eq_zero h, Real.arccos_eq_arcsin (div_nonneg (norm_nonneg _) (norm_nonneg _)), div_pow, one_sub_div hxy] nth_rw 1 [pow_two] rw [norm_add_sq_eq_norm_sq_add_norm_sq_real h, pow_two, add_sub_cancel_left, ← pow_two, ← div_pow, Real.sqrt_sq (div_nonneg (norm_nonneg _) (norm_nonneg _))] /-- An angle in a right-angled triangle expressed using `arctan`. -/ theorem angle_add_eq_arctan_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) (h0 : x ≠ 0) : angle x (x + y) = Real.arctan (‖y‖ / ‖x‖) := by rw [angle_add_eq_arcsin_of_inner_eq_zero h (Or.inl h0), Real.arctan_eq_arcsin, ← div_mul_eq_div_div, norm_add_eq_sqrt_iff_real_inner_eq_zero.2 h] nth_rw 3 [← Real.sqrt_sq (norm_nonneg x)] rw_mod_cast [← Real.sqrt_mul (sq_nonneg _), div_pow, pow_two, pow_two, mul_add, mul_one, mul_div, mul_comm (‖x‖ * ‖x‖), ← mul_div, div_self (mul_self_pos.2 (norm_ne_zero_iff.2 h0)).ne', mul_one] /-- An angle in a non-degenerate right-angled triangle is positive. -/ theorem angle_add_pos_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) (h0 : x = 0 ∨ y ≠ 0) : 0 < angle x (x + y) := by rw [angle_add_eq_arccos_of_inner_eq_zero h, Real.arccos_pos, norm_add_eq_sqrt_iff_real_inner_eq_zero.2 h] by_cases hx : x = 0; · simp [hx] rw [div_lt_one (Real.sqrt_pos.2 (Left.add_pos_of_pos_of_nonneg (mul_self_pos.2 (norm_ne_zero_iff.2 hx)) (mul_self_nonneg _))), Real.lt_sqrt (norm_nonneg _), pow_two] simpa [hx] using h0 /-- An angle in a right-angled triangle is at most `π / 2`. -/ theorem angle_add_le_pi_div_two_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) : angle x (x + y) ≤ π / 2 := by rw [angle_add_eq_arccos_of_inner_eq_zero h, Real.arccos_le_pi_div_two] exact div_nonneg (norm_nonneg _) (norm_nonneg _) /-- An angle in a non-degenerate right-angled triangle is less than `π / 2`. -/ theorem angle_add_lt_pi_div_two_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) (h0 : x ≠ 0) : angle x (x + y) < π / 2 := by rw [angle_add_eq_arccos_of_inner_eq_zero h, Real.arccos_lt_pi_div_two, norm_add_eq_sqrt_iff_real_inner_eq_zero.2 h] exact div_pos (norm_pos_iff.2 h0) (Real.sqrt_pos.2 (Left.add_pos_of_pos_of_nonneg (mul_self_pos.2 (norm_ne_zero_iff.2 h0)) (mul_self_nonneg _))) /-- The cosine of an angle in a right-angled triangle as a ratio of sides. -/ theorem cos_angle_add_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) : Real.cos (angle x (x + y)) = ‖x‖ / ‖x + y‖ := by rw [angle_add_eq_arccos_of_inner_eq_zero h, Real.cos_arccos (le_trans (by norm_num) (div_nonneg (norm_nonneg _) (norm_nonneg _))) (div_le_one_of_le₀ _ (norm_nonneg _))] rw [mul_self_le_mul_self_iff (norm_nonneg _) (norm_nonneg _), norm_add_sq_eq_norm_sq_add_norm_sq_real h] exact le_add_of_nonneg_right (mul_self_nonneg _) /-- The sine of an angle in a right-angled triangle as a ratio of sides. -/ theorem sin_angle_add_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) (h0 : x ≠ 0 ∨ y ≠ 0) : Real.sin (angle x (x + y)) = ‖y‖ / ‖x + y‖ := by rw [angle_add_eq_arcsin_of_inner_eq_zero h h0, Real.sin_arcsin (le_trans (by norm_num) (div_nonneg (norm_nonneg _) (norm_nonneg _))) (div_le_one_of_le₀ _ (norm_nonneg _))] rw [mul_self_le_mul_self_iff (norm_nonneg _) (norm_nonneg _), norm_add_sq_eq_norm_sq_add_norm_sq_real h] exact le_add_of_nonneg_left (mul_self_nonneg _) /-- The tangent of an angle in a right-angled triangle as a ratio of sides. -/ theorem tan_angle_add_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) : Real.tan (angle x (x + y)) = ‖y‖ / ‖x‖ := by by_cases h0 : x = 0; · simp [h0] rw [angle_add_eq_arctan_of_inner_eq_zero h h0, Real.tan_arctan] /-- The cosine of an angle in a right-angled triangle multiplied by the hypotenuse equals the adjacent side. -/ theorem cos_angle_add_mul_norm_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) : Real.cos (angle x (x + y)) * ‖x + y‖ = ‖x‖ := by rw [cos_angle_add_of_inner_eq_zero h] by_cases hxy : ‖x + y‖ = 0 · have h' := norm_add_sq_eq_norm_sq_add_norm_sq_real h rw [hxy, zero_mul, eq_comm, add_eq_zero_iff_of_nonneg (mul_self_nonneg ‖x‖) (mul_self_nonneg ‖y‖), mul_self_eq_zero] at h' simp [h'.1] · exact div_mul_cancel₀ _ hxy /-- The sine of an angle in a right-angled triangle multiplied by the hypotenuse equals the opposite side. -/ theorem sin_angle_add_mul_norm_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) : Real.sin (angle x (x + y)) * ‖x + y‖ = ‖y‖ := by by_cases h0 : x = 0 ∧ y = 0; · simp [h0] rw [not_and_or] at h0 rw [sin_angle_add_of_inner_eq_zero h h0, div_mul_cancel₀] rw [← mul_self_ne_zero, norm_add_sq_eq_norm_sq_add_norm_sq_real h] refine (ne_of_lt ?_).symm rcases h0 with (h0 \| h0) · exact Left.add_pos_of_pos_of_nonneg (mul_self_pos.2 (norm_ne_zero_iff.2 h0)) (mul_self_nonneg _) · exact Left.add_pos_of_nonneg_of_pos (mul_self_nonneg _) (mul_self_pos.2 (norm_ne_zero_iff.2 h0)) /-- The tangent of an angle in a right-angled triangle multiplied by the adjacent side equals the opposite side. -/ theorem tan_angle_add_mul_norm_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) (h0 : x ≠ 0 ∨ y = 0) : Real.tan (angle x (x + y)) * ‖x‖ = ‖y‖ := by rw [tan_angle_add_of_inner_eq_zero h]	rcases h0 with (h0 \| h0) <;> simp [h0] /-- A side of a right-angled triangle divided by the cosine of the adjacent angle equals the hypotenuse. -/ theorem norm_div_cos_angle_add_of_inner_eq_zero {x y : V} (h : ⟪x, y⟫ = 0) (h0 : x ≠ 0 ∨ y = 0) : ‖x‖ / Real.cos (angle x (x + y)) = ‖x + y‖ := by rw [cos_angle_add_of_inner_eq_zero h] rcases h0 with (h0 \| h0) · rw [div_div_eq_mul_div, mul_comm, div_eq_mul_inv, mul_inv_cancel_right₀ (norm_ne_zero_iff.2 h0)] · simp [h0]	Mathlib/Geometry/Euclidean/Angle/Unoriented/RightAngle.lean	175	184
/- Copyright (c) 2014 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Mario Carneiro -/ import Mathlib.Data.Subtype import Mathlib.Order.Defs.LinearOrder import Mathlib.Order.Notation import Mathlib.Tactic.GCongr.Core import Mathlib.Tactic.Spread import Mathlib.Tactic.Convert import Mathlib.Tactic.Inhabit import Mathlib.Tactic.SimpRw /-! # Basic definitions about `≤` and `<` This file proves basic results about orders, provides extensive dot notation, defines useful order classes and allows to transfer order instances. ## Type synonyms * `OrderDual α` : A type synonym reversing the meaning of all inequalities, with notation `αᵒᵈ`. * `AsLinearOrder α`: A type synonym to promote `PartialOrder α` to `LinearOrder α` using `IsTotal α (≤)`. ### Transferring orders - `Order.Preimage`, `Preorder.lift`: Transfers a (pre)order on `β` to an order on `α` using a function `f : α → β`. - `PartialOrder.lift`, `LinearOrder.lift`: Transfers a partial (resp., linear) order on `β` to a partial (resp., linear) order on `α` using an injective function `f`. ### Extra class * `DenselyOrdered`: An order with no gap, i.e. for any two elements `a < b` there exists `c` such that `a < c < b`. ## Notes `≤` and `<` are highly favored over `≥` and `>` in mathlib. The reason is that we can formulate all lemmas using `≤`/`<`, and `rw` has trouble unifying `≤` and `≥`. Hence choosing one direction spares us useless duplication. This is enforced by a linter. See Note [nolint_ge] for more infos. Dot notation is particularly useful on `≤` (`LE.le`) and `<` (`LT.lt`). To that end, we provide many aliases to dot notation-less lemmas. For example, `le_trans` is aliased with `LE.le.trans` and can be used to construct `hab.trans hbc : a ≤ c` when `hab : a ≤ b`, `hbc : b ≤ c`, `lt_of_le_of_lt` is aliased as `LE.le.trans_lt` and can be used to construct `hab.trans hbc : a < c` when `hab : a ≤ b`, `hbc : b < c`. ## TODO - expand module docs - automatic construction of dual definitions / theorems ## Tags preorder, order, partial order, poset, linear order, chain -/ open Function variable {ι α β : Type} {π : ι → Type} /-! ### Bare relations -/ attribute [ext] LE protected lemma LE.le.ge [LE α] {x y : α} (h : x ≤ y) : y ≥ x := h protected lemma GE.ge.le [LE α] {x y : α} (h : x ≥ y) : y ≤ x := h protected lemma LT.lt.gt [LT α] {x y : α} (h : x < y) : y > x := h protected lemma GT.gt.lt [LT α] {x y : α} (h : x > y) : y < x := h /-- Given a relation `R` on `β` and a function `f : α → β`, the preimage relation on `α` is defined by `x ≤ y ↔ f x ≤ f y`. It is the unique relation on `α` making `f` a `RelEmbedding` (assuming `f` is injective). -/ @[simp] def Order.Preimage (f : α → β) (s : β → β → Prop) (x y : α) : Prop := s (f x) (f y) @[inherit_doc] infixl:80 " ⁻¹'o " => Order.Preimage /-- The preimage of a decidable order is decidable. -/ instance Order.Preimage.decidable (f : α → β) (s : β → β → Prop) [H : DecidableRel s] : DecidableRel (f ⁻¹'o s) := fun _ _ ↦ H _ _ /-! ### Preorders -/ section Preorder variable [Preorder α] {a b c d : α} theorem le_trans' : b ≤ c → a ≤ b → a ≤ c := flip le_trans theorem lt_trans' : b < c → a < b → a < c := flip lt_trans theorem lt_of_le_of_lt' : b ≤ c → a < b → a < c := flip lt_of_lt_of_le theorem lt_of_lt_of_le' : b < c → a ≤ b → a < c := flip lt_of_le_of_lt theorem le_of_le_of_eq' : b ≤ c → a = b → a ≤ c := flip le_of_eq_of_le theorem le_of_eq_of_le' : b = c → a ≤ b → a ≤ c := flip le_of_le_of_eq theorem lt_of_lt_of_eq' : b < c → a = b → a < c := flip lt_of_eq_of_lt theorem lt_of_eq_of_lt' : b = c → a < b → a < c := flip lt_of_lt_of_eq theorem not_lt_iff_not_le_or_ge : ¬a < b ↔ ¬a ≤ b ∨ b ≤ a := by rw [lt_iff_le_not_le, Classical.not_and_iff_not_or_not, Classical.not_not] -- Unnecessary brackets are here for readability lemma not_lt_iff_le_imp_le : ¬ a < b ↔ (a ≤ b → b ≤ a) := by simp [not_lt_iff_not_le_or_ge, or_iff_not_imp_left] /-- If `x = y` then `y ≤ x`. Note: this lemma uses `y ≤ x` instead of `x ≥ y`, because `le` is used almost exclusively in mathlib. -/ lemma ge_of_eq (h : a = b) : b ≤ a := le_of_eq h.symm @[simp] lemma lt_self_iff_false (x : α) : x < x ↔ False := ⟨lt_irrefl x, False.elim⟩ alias LE.le.trans := le_trans alias LE.le.trans' := le_trans' alias LT.lt.trans := lt_trans alias LT.lt.trans' := lt_trans' alias LE.le.trans_lt := lt_of_le_of_lt alias LE.le.trans_lt' := lt_of_le_of_lt' alias LT.lt.trans_le := lt_of_lt_of_le alias LT.lt.trans_le' := lt_of_lt_of_le' alias LE.le.trans_eq := le_of_le_of_eq alias LE.le.trans_eq' := le_of_le_of_eq' alias LT.lt.trans_eq := lt_of_lt_of_eq alias LT.lt.trans_eq' := lt_of_lt_of_eq' alias Eq.trans_le := le_of_eq_of_le alias Eq.trans_ge := le_of_eq_of_le' alias Eq.trans_lt := lt_of_eq_of_lt alias Eq.trans_gt := lt_of_eq_of_lt' alias LE.le.lt_of_not_le := lt_of_le_not_le alias LE.le.lt_or_eq_dec := Decidable.lt_or_eq_of_le alias LT.lt.le := le_of_lt alias LT.lt.ne := ne_of_lt alias Eq.le := le_of_eq @[inherit_doc ge_of_eq] alias Eq.ge := ge_of_eq alias LT.lt.asymm := lt_asymm alias LT.lt.not_lt := lt_asymm theorem ne_of_not_le (h : ¬a ≤ b) : a ≠ b := fun hab ↦ h (le_of_eq hab) protected lemma Eq.not_lt (hab : a = b) : ¬a < b := fun h' ↦ h'.ne hab protected lemma Eq.not_gt (hab : a = b) : ¬b < a := hab.symm.not_lt @[simp] lemma le_of_subsingleton [Subsingleton α] : a ≤ b := (Subsingleton.elim a b).le -- Making this a @[simp] lemma causes confluence problems downstream. lemma not_lt_of_subsingleton [Subsingleton α] : ¬a < b := (Subsingleton.elim a b).not_lt namespace LT.lt protected theorem false : a < a → False := lt_irrefl a theorem ne' (h : a < b) : b ≠ a := h.ne.symm end LT.lt theorem le_of_forall_le (H : ∀ c, c ≤ a → c ≤ b) : a ≤ b := H _ le_rfl theorem le_of_forall_ge (H : ∀ c, a ≤ c → b ≤ c) : b ≤ a := H _ le_rfl @[deprecated (since := "2025-01-30")] alias le_of_forall_le' := le_of_forall_ge theorem forall_le_iff_le : (∀ ⦃c⦄, c ≤ a → c ≤ b) ↔ a ≤ b := ⟨le_of_forall_le, fun h _ hca ↦ le_trans hca h⟩ theorem forall_le_iff_ge : (∀ ⦃c⦄, a ≤ c → b ≤ c) ↔ b ≤ a := ⟨le_of_forall_ge, fun h _ hca ↦ le_trans h hca⟩ /-- monotonicity of `≤` with respect to `→` -/ theorem le_implies_le_of_le_of_le (hca : c ≤ a) (hbd : b ≤ d) : a ≤ b → c ≤ d := fun hab ↦ (hca.trans hab).trans hbd end Preorder /-! ### Partial order -/ section PartialOrder variable [PartialOrder α] {a b : α} theorem ge_antisymm : a ≤ b → b ≤ a → b = a := flip le_antisymm theorem lt_of_le_of_ne' : a ≤ b → b ≠ a → a < b := fun h₁ h₂ ↦ lt_of_le_of_ne h₁ h₂.symm theorem Ne.lt_of_le : a ≠ b → a ≤ b → a < b := flip lt_of_le_of_ne theorem Ne.lt_of_le' : b ≠ a → a ≤ b → a < b := flip lt_of_le_of_ne' alias LE.le.antisymm := le_antisymm alias LE.le.antisymm' := ge_antisymm alias LE.le.lt_of_ne := lt_of_le_of_ne alias LE.le.lt_of_ne' := lt_of_le_of_ne' alias LE.le.lt_or_eq := lt_or_eq_of_le -- Unnecessary brackets are here for readability lemma le_imp_eq_iff_le_imp_le : (a ≤ b → b = a) ↔ (a ≤ b → b ≤ a) where mp h hab := (h hab).le mpr h hab := (h hab).antisymm hab -- Unnecessary brackets are here for readability lemma ge_imp_eq_iff_le_imp_le : (a ≤ b → a = b) ↔ (a ≤ b → b ≤ a) where mp h hab := (h hab).ge mpr h hab := hab.antisymm (h hab) namespace LE.le theorem lt_iff_ne (h : a ≤ b) : a < b ↔ a ≠ b := ⟨fun h ↦ h.ne, h.lt_of_ne⟩ theorem gt_iff_ne (h : a ≤ b) : a < b ↔ b ≠ a := ⟨fun h ↦ h.ne.symm, h.lt_of_ne'⟩ theorem not_lt_iff_eq (h : a ≤ b) : ¬a < b ↔ a = b := h.lt_iff_ne.not_left theorem not_gt_iff_eq (h : a ≤ b) : ¬a < b ↔ b = a := h.gt_iff_ne.not_left theorem le_iff_eq (h : a ≤ b) : b ≤ a ↔ b = a := ⟨fun h' ↦ h'.antisymm h, Eq.le⟩ theorem ge_iff_eq (h : a ≤ b) : b ≤ a ↔ a = b := ⟨h.antisymm, Eq.ge⟩ end LE.le -- See Note [decidable namespace] protected theorem Decidable.le_iff_eq_or_lt [DecidableLE α] : a ≤ b ↔ a = b ∨ a < b := Decidable.le_iff_lt_or_eq.trans or_comm theorem le_iff_eq_or_lt : a ≤ b ↔ a = b ∨ a < b := le_iff_lt_or_eq.trans or_comm theorem lt_iff_le_and_ne : a < b ↔ a ≤ b ∧ a ≠ b := ⟨fun h ↦ ⟨le_of_lt h, ne_of_lt h⟩, fun ⟨h1, h2⟩ ↦ h1.lt_of_ne h2⟩ lemma eq_iff_not_lt_of_le (hab : a ≤ b) : a = b ↔ ¬ a < b := by simp [hab, lt_iff_le_and_ne] alias LE.le.eq_iff_not_lt := eq_iff_not_lt_of_le -- See Note [decidable namespace] protected theorem Decidable.eq_iff_le_not_lt [DecidableLE α] : a = b ↔ a ≤ b ∧ ¬a < b := ⟨fun h ↦ ⟨h.le, h ▸ lt_irrefl _⟩, fun ⟨h₁, h₂⟩ ↦ h₁.antisymm <\| Decidable.byContradiction fun h₃ ↦ h₂ (h₁.lt_of_not_le h₃)⟩ theorem eq_iff_le_not_lt : a = b ↔ a ≤ b ∧ ¬a < b := haveI := Classical.dec Decidable.eq_iff_le_not_lt theorem eq_or_lt_of_le (h : a ≤ b) : a = b ∨ a < b := h.lt_or_eq.symm theorem eq_or_gt_of_le (h : a ≤ b) : b = a ∨ a < b := h.lt_or_eq.symm.imp Eq.symm id theorem gt_or_eq_of_le (h : a ≤ b) : a < b ∨ b = a := (eq_or_gt_of_le h).symm alias LE.le.eq_or_lt_dec := Decidable.eq_or_lt_of_le alias LE.le.eq_or_lt := eq_or_lt_of_le alias LE.le.eq_or_gt := eq_or_gt_of_le alias LE.le.gt_or_eq := gt_or_eq_of_le theorem eq_of_le_of_not_lt (hab : a ≤ b) (hba : ¬a < b) : a = b := hab.eq_or_lt.resolve_right hba theorem eq_of_ge_of_not_gt (hab : a ≤ b) (hba : ¬a < b) : b = a := (eq_of_le_of_not_lt hab hba).symm alias LE.le.eq_of_not_lt := eq_of_le_of_not_lt alias LE.le.eq_of_not_gt := eq_of_ge_of_not_gt theorem Ne.le_iff_lt (h : a ≠ b) : a ≤ b ↔ a < b := ⟨fun h' ↦ lt_of_le_of_ne h' h, fun h ↦ h.le⟩ theorem Ne.not_le_or_not_le (h : a ≠ b) : ¬a ≤ b ∨ ¬b ≤ a := not_and_or.1 <\| le_antisymm_iff.not.1 h -- See Note [decidable namespace] protected theorem Decidable.ne_iff_lt_iff_le [DecidableEq α] : (a ≠ b ↔ a < b) ↔ a ≤ b := ⟨fun h ↦ Decidable.byCases le_of_eq (le_of_lt ∘ h.mp), fun h ↦ ⟨lt_of_le_of_ne h, ne_of_lt⟩⟩ @[simp] theorem ne_iff_lt_iff_le : (a ≠ b ↔ a < b) ↔ a ≤ b := haveI := Classical.dec Decidable.ne_iff_lt_iff_le lemma eq_of_forall_le_iff (H : ∀ c, c ≤ a ↔ c ≤ b) : a = b := ((H _).1 le_rfl).antisymm ((H _).2 le_rfl) lemma eq_of_forall_ge_iff (H : ∀ c, a ≤ c ↔ b ≤ c) : a = b := ((H _).2 le_rfl).antisymm ((H _).1 le_rfl) /-- To prove commutativity of a binary operation `○`, we only to check `a ○ b ≤ b ○ a` for all `a`, `b`. -/ lemma commutative_of_le {f : β → β → α} (comm : ∀ a b, f a b ≤ f b a) : ∀ a b, f a b = f b a := fun _ _ ↦ (comm _ _).antisymm <\| comm _ _ /-- To prove associativity of a commutative binary operation `○`, we only to check `(a ○ b) ○ c ≤ a ○ (b ○ c)` for all `a`, `b`, `c`. -/ lemma associative_of_commutative_of_le {f : α → α → α} (comm : Std.Commutative f) (assoc : ∀ a b c, f (f a b) c ≤ f a (f b c)) : Std.Associative f where assoc a b c := le_antisymm (assoc _ _ _) <\| by rw [comm.comm, comm.comm b, comm.comm _ c, comm.comm a] exact assoc .. end PartialOrder section LinearOrder variable [LinearOrder α] {a b : α} namespace LE.le lemma lt_or_le (h : a ≤ b) (c : α) : a < c ∨ c ≤ b := (lt_or_ge a c).imp id h.trans' lemma le_or_lt (h : a ≤ b) (c : α) : a ≤ c ∨ c < b := (le_or_gt a c).imp id h.trans_lt' lemma le_or_le (h : a ≤ b) (c : α) : a ≤ c ∨ c ≤ b := (h.lt_or_le c).imp le_of_lt id end LE.le namespace LT.lt lemma lt_or_lt (h : a < b) (c : α) : a < c ∨ c < b := (le_or_gt b c).imp h.trans_le id end LT.lt -- Variant of `min_def` with the branches reversed. theorem min_def' (a b : α) : min a b = if b ≤ a then b else a := by rw [min_def] rcases lt_trichotomy a b with (lt \| eq \| gt) · rw [if_pos lt.le, if_neg (not_le.mpr lt)] · rw [if_pos eq.le, if_pos eq.ge, eq] · rw [if_neg (not_le.mpr gt.gt), if_pos gt.le] -- Variant of `min_def` with the branches reversed. -- This is sometimes useful as it used to be the default. theorem max_def' (a b : α) : max a b = if b ≤ a then a else b := by rw [max_def] rcases lt_trichotomy a b with (lt \| eq \| gt) · rw [if_pos lt.le, if_neg (not_le.mpr lt)] · rw [if_pos eq.le, if_pos eq.ge, eq] · rw [if_neg (not_le.mpr gt.gt), if_pos gt.le] theorem lt_of_not_le (h : ¬b ≤ a) : a < b := ((le_total _ _).resolve_right h).lt_of_not_le h theorem lt_iff_not_le : a < b ↔ ¬b ≤ a := ⟨not_le_of_lt, lt_of_not_le⟩ theorem Ne.lt_or_lt (h : a ≠ b) : a < b ∨ b < a := lt_or_gt_of_ne h /-- A version of `ne_iff_lt_or_gt` with LHS and RHS reversed. -/ @[simp] theorem lt_or_lt_iff_ne : a < b ∨ b < a ↔ a ≠ b := ne_iff_lt_or_gt.symm theorem not_lt_iff_eq_or_lt : ¬a < b ↔ a = b ∨ b < a := not_lt.trans <\| Decidable.le_iff_eq_or_lt.trans <\| or_congr eq_comm Iff.rfl theorem exists_ge_of_linear (a b : α) : ∃ c, a ≤ c ∧ b ≤ c := match le_total a b with \| Or.inl h => ⟨_, h, le_rfl⟩ \| Or.inr h => ⟨_, le_rfl, h⟩ lemma exists_forall_ge_and {p q : α → Prop} : (∃ i, ∀ j ≥ i, p j) → (∃ i, ∀ j ≥ i, q j) → ∃ i, ∀ j ≥ i, p j ∧ q j \| ⟨a, ha⟩, ⟨b, hb⟩ => let ⟨c, hac, hbc⟩ := exists_ge_of_linear a b ⟨c, fun _d hcd ↦ ⟨ha _ <\| hac.trans hcd, hb _ <\| hbc.trans hcd⟩⟩ theorem le_of_forall_lt (H : ∀ c, c < a → c < b) : a ≤ b := le_of_not_lt fun h ↦ lt_irrefl _ (H _ h) theorem forall_lt_iff_le : (∀ ⦃c⦄, c < a → c < b) ↔ a ≤ b := ⟨le_of_forall_lt, fun h _ hca ↦ lt_of_lt_of_le hca h⟩ theorem le_of_forall_lt' (H : ∀ c, a < c → b < c) : b ≤ a := le_of_not_lt fun h ↦ lt_irrefl _ (H _ h) theorem forall_lt_iff_le' : (∀ ⦃c⦄, a < c → b < c) ↔ b ≤ a := ⟨le_of_forall_lt', fun h _ hac ↦ lt_of_le_of_lt h hac⟩ theorem eq_of_forall_lt_iff (h : ∀ c, c < a ↔ c < b) : a = b := (le_of_forall_lt fun _ ↦ (h _).1).antisymm <\| le_of_forall_lt fun _ ↦ (h _).2 theorem eq_of_forall_gt_iff (h : ∀ c, a < c ↔ b < c) : a = b := (le_of_forall_lt' fun _ ↦ (h _).2).antisymm <\| le_of_forall_lt' fun _ ↦ (h _).1 section ltByCases variable {P : Sort} {x y : α} @[simp] lemma ltByCases_lt (h : x < y) {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} : ltByCases x y h₁ h₂ h₃ = h₁ h := dif_pos h @[simp] lemma ltByCases_gt (h : y < x) {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} : ltByCases x y h₁ h₂ h₃ = h₃ h := (dif_neg h.not_lt).trans (dif_pos h) @[simp] lemma ltByCases_eq (h : x = y) {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} : ltByCases x y h₁ h₂ h₃ = h₂ h := (dif_neg h.not_lt).trans (dif_neg h.not_gt) lemma ltByCases_not_lt (h : ¬ x < y) {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} (p : ¬ y < x → x = y := fun h' => (le_antisymm (le_of_not_gt h') (le_of_not_gt h))) : ltByCases x y h₁ h₂ h₃ = if h' : y < x then h₃ h' else h₂ (p h') := dif_neg h lemma ltByCases_not_gt (h : ¬ y < x) {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} (p : ¬ x < y → x = y := fun h' => (le_antisymm (le_of_not_gt h) (le_of_not_gt h'))) : ltByCases x y h₁ h₂ h₃ = if h' : x < y then h₁ h' else h₂ (p h') := dite_congr rfl (fun _ => rfl) (fun _ => dif_neg h) lemma ltByCases_ne (h : x ≠ y) {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} (p : ¬ x < y → y < x := fun h' => h.lt_or_lt.resolve_left h') : ltByCases x y h₁ h₂ h₃ = if h' : x < y then h₁ h' else h₃ (p h') := dite_congr rfl (fun _ => rfl) (fun _ => dif_pos _) lemma ltByCases_comm {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} (p : y = x → x = y := fun h' => h'.symm) : ltByCases x y h₁ h₂ h₃ = ltByCases y x h₃ (h₂ ∘ p) h₁ := by refine ltByCases x y (fun h => ?_) (fun h => ?_) (fun h => ?_) · rw [ltByCases_lt h, ltByCases_gt h] · rw [ltByCases_eq h, ltByCases_eq h.symm, comp_apply] · rw [ltByCases_lt h, ltByCases_gt h] lemma eq_iff_eq_of_lt_iff_lt_of_gt_iff_gt {x' y' : α} (ltc : (x < y) ↔ (x' < y')) (gtc : (y < x) ↔ (y' < x')) : x = y ↔ x' = y' := by simp_rw [eq_iff_le_not_lt, ← not_lt, ltc, gtc] lemma ltByCases_rec {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} (p : P) (hlt : (h : x < y) → h₁ h = p) (heq : (h : x = y) → h₂ h = p) (hgt : (h : y < x) → h₃ h = p) : ltByCases x y h₁ h₂ h₃ = p := ltByCases x y (fun h => ltByCases_lt h ▸ hlt h) (fun h => ltByCases_eq h ▸ heq h) (fun h => ltByCases_gt h ▸ hgt h) lemma ltByCases_eq_iff {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} {p : P} : ltByCases x y h₁ h₂ h₃ = p ↔ (∃ h, h₁ h = p) ∨ (∃ h, h₂ h = p) ∨ (∃ h, h₃ h = p) := by refine ltByCases x y (fun h => ?_) (fun h => ?_) (fun h => ?_) · simp only [ltByCases_lt, exists_prop_of_true, h, h.not_lt, not_false_eq_true, exists_prop_of_false, or_false, h.ne] · simp only [h, lt_self_iff_false, ltByCases_eq, not_false_eq_true, exists_prop_of_false, exists_prop_of_true, or_false, false_or] · simp only [ltByCases_gt, exists_prop_of_true, h, h.not_lt, not_false_eq_true, exists_prop_of_false, false_or, h.ne'] lemma ltByCases_congr {x' y' : α} {h₁ : x < y → P} {h₂ : x = y → P} {h₃ : y < x → P} {h₁' : x' < y' → P} {h₂' : x' = y' → P} {h₃' : y' < x' → P} (ltc : (x < y) ↔ (x' < y')) (gtc : (y < x) ↔ (y' < x')) (hh'₁ : ∀ (h : x' < y'), h₁ (ltc.mpr h) = h₁' h) (hh'₂ : ∀ (h : x' = y'), h₂ ((eq_iff_eq_of_lt_iff_lt_of_gt_iff_gt ltc gtc).mpr h) = h₂' h) (hh'₃ : ∀ (h : y' < x'), h₃ (gtc.mpr h) = h₃' h) : ltByCases x y h₁ h₂ h₃ = ltByCases x' y' h₁' h₂' h₃' := by refine ltByCases_rec _ (fun h => ?_) (fun h => ?_) (fun h => ?_) · rw [ltByCases_lt (ltc.mp h), hh'₁] · rw [eq_iff_eq_of_lt_iff_lt_of_gt_iff_gt ltc gtc] at h rw [ltByCases_eq h, hh'₂] · rw [ltByCases_gt (gtc.mp h), hh'₃] /-- Perform a case-split on the ordering of `x` and `y` in a decidable linear order, non-dependently. -/ abbrev ltTrichotomy (x y : α) (p q r : P) := ltByCases x y (fun _ => p) (fun _ => q) (fun _ => r) variable {p q r s : P} @[simp] lemma ltTrichotomy_lt (h : x < y) : ltTrichotomy x y p q r = p := ltByCases_lt h @[simp] lemma ltTrichotomy_gt (h : y < x) : ltTrichotomy x y p q r = r := ltByCases_gt h @[simp] lemma ltTrichotomy_eq (h : x = y) : ltTrichotomy x y p q r = q := ltByCases_eq h lemma ltTrichotomy_not_lt (h : ¬ x < y) : ltTrichotomy x y p q r = if y < x then r else q := ltByCases_not_lt h lemma ltTrichotomy_not_gt (h : ¬ y < x) : ltTrichotomy x y p q r = if x < y then p else q := ltByCases_not_gt h lemma ltTrichotomy_ne (h : x ≠ y) : ltTrichotomy x y p q r = if x < y then p else r := ltByCases_ne h lemma ltTrichotomy_comm : ltTrichotomy x y p q r = ltTrichotomy y x r q p := ltByCases_comm lemma ltTrichotomy_self {p : P} : ltTrichotomy x y p p p = p := ltByCases_rec p (fun _ => rfl) (fun _ => rfl) (fun _ => rfl) lemma ltTrichotomy_eq_iff : ltTrichotomy x y p q r = s ↔ (x < y ∧ p = s) ∨ (x = y ∧ q = s) ∨ (y < x ∧ r = s) := by refine ltByCases x y (fun h => ?_) (fun h => ?_) (fun h => ?_) · simp only [ltTrichotomy_lt, false_and, true_and, or_false, h, h.not_lt, h.ne] · simp only [ltTrichotomy_eq, false_and, true_and, or_false, false_or, h, lt_irrefl] · simp only [ltTrichotomy_gt, false_and, true_and, false_or, h, h.not_lt, h.ne'] lemma ltTrichotomy_congr {x' y' : α} {p' q' r' : P} (ltc : (x < y) ↔ (x' < y')) (gtc : (y < x) ↔ (y' < x')) (hh'₁ : x' < y' → p = p') (hh'₂ : x' = y' → q = q') (hh'₃ : y' < x' → r = r') : ltTrichotomy x y p q r = ltTrichotomy x' y' p' q' r' := ltByCases_congr ltc gtc hh'₁ hh'₂ hh'₃ end ltByCases /-! #### `min`/`max` recursors -/ section MinMaxRec variable {p : α → Prop} lemma min_rec (ha : a ≤ b → p a) (hb : b ≤ a → p b) : p (min a b) := by obtain hab \| hba := le_total a b <;> simp [min_eq_left, min_eq_right, ] lemma max_rec (ha : b ≤ a → p a) (hb : a ≤ b → p b) : p (max a b) := by obtain hab \| hba := le_total a b <;> simp [max_eq_left, max_eq_right, ] lemma min_rec' (p : α → Prop) (ha : p a) (hb : p b) : p (min a b) := min_rec (fun _ ↦ ha) fun _ ↦ hb lemma max_rec' (p : α → Prop) (ha : p a) (hb : p b) : p (max a b) := max_rec (fun _ ↦ ha) fun _ ↦ hb lemma min_def_lt (a b : α) : min a b = if a < b then a else b := by rw [min_comm, min_def, ← ite_not]; simp only [not_le] lemma max_def_lt (a b : α) : max a b = if a < b then b else a := by rw [max_comm, max_def, ← ite_not]; simp only [not_le] end MinMaxRec end LinearOrder /-! ### Implications -/ lemma lt_imp_lt_of_le_imp_le {β} [LinearOrder α] [Preorder β] {a b : α} {c d : β} (H : a ≤ b → c ≤ d) (h : d < c) : b < a := lt_of_not_le fun h' ↦ (H h').not_lt h lemma le_imp_le_iff_lt_imp_lt {β} [LinearOrder α] [LinearOrder β] {a b : α} {c d : β} : a ≤ b → c ≤ d ↔ d < c → b < a := ⟨lt_imp_lt_of_le_imp_le, le_imp_le_of_lt_imp_lt⟩ lemma lt_iff_lt_of_le_iff_le' {β} [Preorder α] [Preorder β] {a b : α} {c d : β} (H : a ≤ b ↔ c ≤ d) (H' : b ≤ a ↔ d ≤ c) : b < a ↔ d < c := lt_iff_le_not_le.trans <\| (and_congr H' (not_congr H)).trans lt_iff_le_not_le.symm lemma lt_iff_lt_of_le_iff_le {β} [LinearOrder α] [LinearOrder β] {a b : α} {c d : β} (H : a ≤ b ↔ c ≤ d) : b < a ↔ d < c := not_le.symm.trans <\| (not_congr H).trans <\| not_le lemma le_iff_le_iff_lt_iff_lt {β} [LinearOrder α] [LinearOrder β] {a b : α} {c d : β} : (a ≤ b ↔ c ≤ d) ↔ (b < a ↔ d < c) := ⟨lt_iff_lt_of_le_iff_le, fun H ↦ not_lt.symm.trans <\| (not_congr H).trans <\| not_lt⟩ /-- A symmetric relation implies two values are equal, when it implies they're less-equal. -/ lemma rel_imp_eq_of_rel_imp_le [PartialOrder β] (r : α → α → Prop) [IsSymm α r] {f : α → β} (h : ∀ a b, r a b → f a ≤ f b) {a b : α} : r a b → f a = f b := fun hab ↦ le_antisymm (h a b hab) (h b a <\| symm hab) /-! ### Extensionality lemmas -/ @[ext] lemma Preorder.toLE_injective : Function.Injective (@Preorder.toLE α) := fun \| { lt := A_lt, lt_iff_le_not_le := A_iff, .. }, { lt := B_lt, lt_iff_le_not_le := B_iff, .. } => by rintro ⟨⟩ have : A_lt = B_lt := by funext a b rw [A_iff, B_iff] cases this congr @[ext] lemma PartialOrder.toPreorder_injective : Function.Injective (@PartialOrder.toPreorder α) := by rintro ⟨⟩ ⟨⟩ ⟨⟩; congr @[ext] lemma LinearOrder.toPartialOrder_injective : Function.Injective (@LinearOrder.toPartialOrder α) := fun \| { le := A_le, lt := A_lt, toDecidableLE := A_decidableLE, toDecidableEq := A_decidableEq, toDecidableLT := A_decidableLT min := A_min, max := A_max, min_def := A_min_def, max_def := A_max_def, compare := A_compare, compare_eq_compareOfLessAndEq := A_compare_canonical, .. }, { le := B_le, lt := B_lt, toDecidableLE := B_decidableLE, toDecidableEq := B_decidableEq, toDecidableLT := B_decidableLT min := B_min, max := B_max, min_def := B_min_def, max_def := B_max_def, compare := B_compare, compare_eq_compareOfLessAndEq := B_compare_canonical, .. } => by rintro ⟨⟩ obtain rfl : A_decidableLE = B_decidableLE := Subsingleton.elim _ _ obtain rfl : A_decidableEq = B_decidableEq := Subsingleton.elim _ _ obtain rfl : A_decidableLT = B_decidableLT := Subsingleton.elim _ _ have : A_min = B_min := by funext a b exact (A_min_def _ _).trans (B_min_def _ _).symm cases this have : A_max = B_max := by funext a b exact (A_max_def _ _).trans (B_max_def _ _).symm cases this have : A_compare = B_compare := by funext a b exact (A_compare_canonical _ _).trans (B_compare_canonical _ _).symm congr lemma Preorder.ext {A B : Preorder α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) : A = B := by ext x y; exact H x y lemma PartialOrder.ext {A B : PartialOrder α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) : A = B := by ext x y; exact H x y lemma PartialOrder.ext_lt {A B : PartialOrder α} (H : ∀ x y : α, (haveI := A; x < y) ↔ x < y) : A = B := by ext x y; rw [le_iff_lt_or_eq, @le_iff_lt_or_eq _ A, H] lemma LinearOrder.ext {A B : LinearOrder α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) : A = B := by ext x y; exact H x y lemma LinearOrder.ext_lt {A B : LinearOrder α} (H : ∀ x y : α, (haveI := A; x < y) ↔ x < y) : A = B := LinearOrder.toPartialOrder_injective (PartialOrder.ext_lt H) /-! ### Order dual -/ /-- Type synonym to equip a type with the dual order: `≤` means `≥` and `<` means `>`. `αᵒᵈ` is notation for `OrderDual α`. -/ def OrderDual (α : Type) : Type _ := α @[inherit_doc] notation:max α "ᵒᵈ" => OrderDual α namespace OrderDual instance (α : Type) [h : Nonempty α] : Nonempty αᵒᵈ := h instance (α : Type) [h : Subsingleton α] : Subsingleton αᵒᵈ := h instance (α : Type) [LE α] : LE αᵒᵈ := ⟨fun x y : α ↦ y ≤ x⟩ instance (α : Type) [LT α] : LT αᵒᵈ := ⟨fun x y : α ↦ y < x⟩ instance instOrd (α : Type) [Ord α] : Ord αᵒᵈ where compare := fun (a b : α) ↦ compare b a instance instSup (α : Type) [Min α] : Max αᵒᵈ := ⟨((· ⊓ ·) : α → α → α)⟩ instance instInf (α : Type) [Max α] : Min αᵒᵈ := ⟨((· ⊔ ·) : α → α → α)⟩ instance instPreorder (α : Type) [Preorder α] : Preorder αᵒᵈ where le_refl := fun _ ↦ le_refl _ le_trans := fun _ _ _ hab hbc ↦ hbc.trans hab lt_iff_le_not_le := fun _ _ ↦ lt_iff_le_not_le instance instPartialOrder (α : Type) [PartialOrder α] : PartialOrder αᵒᵈ where __ := inferInstanceAs (Preorder αᵒᵈ) le_antisymm := fun a b hab hba ↦ @le_antisymm α _ a b hba hab instance instLinearOrder (α : Type) [LinearOrder α] : LinearOrder αᵒᵈ where __ := inferInstanceAs (PartialOrder αᵒᵈ) __ := inferInstanceAs (Ord αᵒᵈ) le_total := fun a b : α ↦ le_total b a max := fun a b ↦ (min a b : α) min := fun a b ↦ (max a b : α) min_def := fun a b ↦ show (max .. : α) = _ by rw [max_comm, max_def]; rfl max_def := fun a b ↦ show (min .. : α) = _ by rw [min_comm, min_def]; rfl toDecidableLE := (inferInstance : DecidableRel (fun a b : α ↦ b ≤ a)) toDecidableLT := (inferInstance : DecidableRel (fun a b : α ↦ b < a)) toDecidableEq := (inferInstance : DecidableEq α) compare_eq_compareOfLessAndEq a b := by simp only [compare, LinearOrder.compare_eq_compareOfLessAndEq, compareOfLessAndEq, eq_comm] rfl /-- The opposite linear order to a given linear order -/ def _root_.LinearOrder.swap (α : Type) (_ : LinearOrder α) : LinearOrder α := inferInstanceAs <\| LinearOrder (OrderDual α) instance : ∀ [Inhabited α], Inhabited αᵒᵈ := fun [x : Inhabited α] => x theorem Ord.dual_dual (α : Type) [H : Ord α] : OrderDual.instOrd αᵒᵈ = H := rfl theorem Preorder.dual_dual (α : Type) [H : Preorder α] : OrderDual.instPreorder αᵒᵈ = H := rfl theorem instPartialOrder.dual_dual (α : Type) [H : PartialOrder α] : OrderDual.instPartialOrder αᵒᵈ = H := rfl theorem instLinearOrder.dual_dual (α : Type) [H : LinearOrder α] : OrderDual.instLinearOrder αᵒᵈ = H := rfl end OrderDual /-! ### `HasCompl` -/ instance Prop.hasCompl : HasCompl Prop := ⟨Not⟩ instance Pi.hasCompl [∀ i, HasCompl (π i)] : HasCompl (∀ i, π i) := ⟨fun x i ↦ (x i)ᶜ⟩ theorem Pi.compl_def [∀ i, HasCompl (π i)] (x : ∀ i, π i) : xᶜ = fun i ↦ (x i)ᶜ := rfl @[simp] theorem Pi.compl_apply [∀ i, HasCompl (π i)] (x : ∀ i, π i) (i : ι) : xᶜ i = (x i)ᶜ := rfl instance IsIrrefl.compl (r) [IsIrrefl α r] : IsRefl α rᶜ := ⟨@irrefl α r _⟩ instance IsRefl.compl (r) [IsRefl α r] : IsIrrefl α rᶜ := ⟨fun a ↦ not_not_intro (refl a)⟩ theorem compl_lt [LinearOrder α] : (· < · : α → α → _)ᶜ = (· ≥ ·) := by ext; simp [compl] theorem compl_le [LinearOrder α] : (· ≤ · : α → α → _)ᶜ = (· > ·) := by ext; simp [compl] theorem compl_gt [LinearOrder α] : (· > · : α → α → _)ᶜ = (· ≤ ·) := by ext; simp [compl] theorem compl_ge [LinearOrder α] : (· ≥ · : α → α → _)ᶜ = (· < ·) := by ext; simp [compl] instance Ne.instIsEquiv_compl : IsEquiv α (· ≠ ·)ᶜ := by convert eq_isEquiv α simp [compl] /-! ### Order instances on the function space -/ instance Pi.hasLe [∀ i, LE (π i)] : LE (∀ i, π i) where le x y := ∀ i, x i ≤ y i theorem Pi.le_def [∀ i, LE (π i)] {x y : ∀ i, π i} : x ≤ y ↔ ∀ i, x i ≤ y i := Iff.rfl instance Pi.preorder [∀ i, Preorder (π i)] : Preorder (∀ i, π i) where __ := inferInstanceAs (LE (∀ i, π i)) le_refl := fun a i ↦ le_refl (a i) le_trans := fun _ _ _ h₁ h₂ i ↦ le_trans (h₁ i) (h₂ i) theorem Pi.lt_def [∀ i, Preorder (π i)] {x y : ∀ i, π i} : x < y ↔ x ≤ y ∧ ∃ i, x i < y i := by simp +contextual [lt_iff_le_not_le, Pi.le_def] instance Pi.partialOrder [∀ i, PartialOrder (π i)] : PartialOrder (∀ i, π i) where __ := Pi.preorder le_antisymm := fun _ _ h1 h2 ↦ funext fun b ↦ (h1 b).antisymm (h2 b) namespace Sum variable {α₁ α₂ : Type} [LE β] @[simp] lemma elim_le_elim_iff {u₁ v₁ : α₁ → β} {u₂ v₂ : α₂ → β} : Sum.elim u₁ u₂ ≤ Sum.elim v₁ v₂ ↔ u₁ ≤ v₁ ∧ u₂ ≤ v₂ := Sum.forall lemma const_le_elim_iff {b : β} {v₁ : α₁ → β} {v₂ : α₂ → β} : Function.const _ b ≤ Sum.elim v₁ v₂ ↔ Function.const _ b ≤ v₁ ∧ Function.const _ b ≤ v₂ := elim_const_const b ▸ elim_le_elim_iff .. lemma elim_le_const_iff {b : β} {u₁ : α₁ → β} {u₂ : α₂ → β} : Sum.elim u₁ u₂ ≤ Function.const _ b ↔ u₁ ≤ Function.const _ b ∧ u₂ ≤ Function.const _ b := elim_const_const b ▸ elim_le_elim_iff .. end Sum section Pi /-- A function `a` is strongly less than a function `b` if `a i < b i` for all `i`. -/ def StrongLT [∀ i, LT (π i)] (a b : ∀ i, π i) : Prop := ∀ i, a i < b i @[inherit_doc] local infixl:50 " ≺ " => StrongLT variable [∀ i, Preorder (π i)] {a b c : ∀ i, π i} theorem le_of_strongLT (h : a ≺ b) : a ≤ b := fun _ ↦ (h _).le theorem lt_of_strongLT [Nonempty ι] (h : a ≺ b) : a < b := by inhabit ι exact Pi.lt_def.2 ⟨le_of_strongLT h, default, h _⟩ theorem strongLT_of_strongLT_of_le (hab : a ≺ b) (hbc : b ≤ c) : a ≺ c := fun _ ↦ (hab _).trans_le <\| hbc _ theorem strongLT_of_le_of_strongLT (hab : a ≤ b) (hbc : b ≺ c) : a ≺ c := fun _ ↦ (hab _).trans_lt <\| hbc _ alias StrongLT.le := le_of_strongLT alias StrongLT.lt := lt_of_strongLT alias StrongLT.trans_le := strongLT_of_strongLT_of_le alias LE.le.trans_strongLT := strongLT_of_le_of_strongLT end Pi section Function variable [DecidableEq ι] [∀ i, Preorder (π i)] {x y : ∀ i, π i} {i : ι} {a b : π i} theorem le_update_iff : x ≤ Function.update y i a ↔ x i ≤ a ∧ ∀ (j) (_ : j ≠ i), x j ≤ y j := Function.forall_update_iff _ fun j z ↦ x j ≤ z theorem update_le_iff : Function.update x i a ≤ y ↔ a ≤ y i ∧ ∀ (j) (_ : j ≠ i), x j ≤ y j := Function.forall_update_iff _ fun j z ↦ z ≤ y j theorem update_le_update_iff : Function.update x i a ≤ Function.update y i b ↔ a ≤ b ∧ ∀ (j) (_ : j ≠ i), x j ≤ y j := by simp +contextual [update_le_iff] @[simp] theorem update_le_update_iff' : update x i a ≤ update x i b ↔ a ≤ b := by simp [update_le_update_iff] @[simp] theorem update_lt_update_iff : update x i a < update x i b ↔ a < b := lt_iff_lt_of_le_iff_le' update_le_update_iff' update_le_update_iff' @[simp] theorem le_update_self_iff : x ≤ update x i a ↔ x i ≤ a := by simp [le_update_iff] @[simp] theorem update_le_self_iff : update x i a ≤ x ↔ a ≤ x i := by simp [update_le_iff] @[simp] theorem lt_update_self_iff : x < update x i a ↔ x i < a := by simp [lt_iff_le_not_le] @[simp] theorem update_lt_self_iff : update x i a < x ↔ a < x i := by simp [lt_iff_le_not_le] end Function instance Pi.sdiff [∀ i, SDiff (π i)] : SDiff (∀ i, π i) := ⟨fun x y i ↦ x i \ y i⟩ theorem Pi.sdiff_def [∀ i, SDiff (π i)] (x y : ∀ i, π i) : x \ y = fun i ↦ x i \ y i := rfl @[simp] theorem Pi.sdiff_apply [∀ i, SDiff (π i)] (x y : ∀ i, π i) (i : ι) : (x \ y) i = x i \ y i := rfl namespace Function variable [Preorder α] [Nonempty β] {a b : α} @[simp] theorem const_le_const : const β a ≤ const β b ↔ a ≤ b := by simp [Pi.le_def] @[simp] theorem const_lt_const : const β a < const β b ↔ a < b := by simpa [Pi.lt_def] using le_of_lt end Function /-! ### Lifts of order instances -/ /-- Transfer a `Preorder` on `β` to a `Preorder` on `α` using a function `f : α → β`. See note [reducible non-instances]. -/ abbrev Preorder.lift [Preorder β] (f : α → β) : Preorder α where le x y := f x ≤ f y le_refl _ := le_rfl le_trans _ _ _ := _root_.le_trans lt x y := f x < f y lt_iff_le_not_le _ _ := _root_.lt_iff_le_not_le /-- Transfer a `PartialOrder` on `β` to a `PartialOrder` on `α` using an injective function `f : α → β`. See note [reducible non-instances]. -/ abbrev PartialOrder.lift [PartialOrder β] (f : α → β) (inj : Injective f) : PartialOrder α := { Preorder.lift f with le_antisymm := fun _ _ h₁ h₂ ↦ inj (h₁.antisymm h₂) } theorem compare_of_injective_eq_compareOfLessAndEq (a b : α) [LinearOrder β] [DecidableEq α] (f : α → β) (inj : Injective f) [Decidable (LT.lt (self := PartialOrder.lift f inj \|>.toLT) a b)] : compare (f a) (f b) = @compareOfLessAndEq _ a b (PartialOrder.lift f inj \|>.toLT) _ _ := by have h := LinearOrder.compare_eq_compareOfLessAndEq (f a) (f b) simp only [h, compareOfLessAndEq] split_ifs <;> try (first \| rfl \| contradiction) · have : ¬ f a = f b := by rename_i h; exact inj.ne h contradiction · have : f a = f b := by rename_i h; exact congrArg f h contradiction /-- Transfer a `LinearOrder` on `β` to a `LinearOrder` on `α` using an injective function `f : α → β`. This version takes `[Max α]` and `[Min α]` as arguments, then uses them for `max` and `min` fields. See `LinearOrder.lift'` for a version that autogenerates `min` and `max` fields, and `LinearOrder.liftWithOrd` for one that does not auto-generate `compare` fields. See note [reducible non-instances]. -/ abbrev LinearOrder.lift [LinearOrder β] [Max α] [Min α] (f : α → β) (inj : Injective f) (hsup : ∀ x y, f (x ⊔ y) = max (f x) (f y)) (hinf : ∀ x y, f (x ⊓ y) = min (f x) (f y)) : LinearOrder α := letI instOrdα : Ord α := ⟨fun a b ↦ compare (f a) (f b)⟩ letI decidableLE := fun x y ↦ (inferInstance : Decidable (f x ≤ f y)) letI decidableLT := fun x y ↦ (inferInstance : Decidable (f x < f y)) letI decidableEq := fun x y ↦ decidable_of_iff (f x = f y) inj.eq_iff { PartialOrder.lift f inj, instOrdα with le_total := fun x y ↦ le_total (f x) (f y) toDecidableLE := decidableLE toDecidableLT := decidableLT toDecidableEq := decidableEq min := (· ⊓ ·) max := (· ⊔ ·) min_def := by intros x y apply inj rw [apply_ite f] exact (hinf _ _).trans (min_def _ _) max_def := by intros x y apply inj rw [apply_ite f] exact (hsup _ _).trans (max_def _ _) compare_eq_compareOfLessAndEq := fun a b ↦ compare_of_injective_eq_compareOfLessAndEq a b f inj } /-- Transfer a `LinearOrder` on `β` to a `LinearOrder` on `α` using an injective function `f : α → β`. This version autogenerates `min` and `max` fields. See `LinearOrder.lift` for a version that takes `[Max α]` and `[Min α]`, then uses them as `max` and `min`. See `LinearOrder.liftWithOrd'` for a version which does not auto-generate `compare` fields. See note [reducible non-instances]. -/ abbrev LinearOrder.lift' [LinearOrder β] (f : α → β) (inj : Injective f) : LinearOrder α := @LinearOrder.lift α β _ ⟨fun x y ↦ if f x ≤ f y then y else x⟩ ⟨fun x y ↦ if f x ≤ f y then x else y⟩ f inj (fun _ _ ↦ (apply_ite f _ _ _).trans (max_def _ _).symm) fun _ _ ↦ (apply_ite f _ _ _).trans (min_def _ _).symm /-- Transfer a `LinearOrder` on `β` to a `LinearOrder` on `α` using an injective function `f : α → β`. This version takes `[Max α]` and `[Min α]` as arguments, then uses them for `max` and `min` fields. It also takes `[Ord α]` as an argument and uses them for `compare` fields. See `LinearOrder.lift` for a version that autogenerates `compare` fields, and `LinearOrder.liftWithOrd'` for one that auto-generates `min` and `max` fields. fields. See note [reducible non-instances]. -/ abbrev LinearOrder.liftWithOrd [LinearOrder β] [Max α] [Min α] [Ord α] (f : α → β) (inj : Injective f) (hsup : ∀ x y, f (x ⊔ y) = max (f x) (f y)) (hinf : ∀ x y, f (x ⊓ y) = min (f x) (f y)) (compare_f : ∀ a b : α, compare a b = compare (f a) (f b)) : LinearOrder α := letI decidableLE := fun x y ↦ (inferInstance : Decidable (f x ≤ f y)) letI decidableLT := fun x y ↦ (inferInstance : Decidable (f x < f y)) letI decidableEq := fun x y ↦ decidable_of_iff (f x = f y) inj.eq_iff { PartialOrder.lift f inj with le_total := fun x y ↦ le_total (f x) (f y) toDecidableLE := decidableLE toDecidableLT := decidableLT toDecidableEq := decidableEq min := (· ⊓ ·) max := (· ⊔ ·) min_def := by intros x y apply inj rw [apply_ite f] exact (hinf _ _).trans (min_def _ _) max_def := by intros x y apply inj rw [apply_ite f] exact (hsup _ _).trans (max_def _ _) compare_eq_compareOfLessAndEq := fun a b ↦ (compare_f a b).trans <\| compare_of_injective_eq_compareOfLessAndEq a b f inj } /-- Transfer a `LinearOrder` on `β` to a `LinearOrder` on `α` using an injective function `f : α → β`. This version auto-generates `min` and `max` fields. It also takes `[Ord α]` as an argument and uses them for `compare` fields. See `LinearOrder.lift` for a version that autogenerates `compare` fields, and `LinearOrder.liftWithOrd` for one that doesn't auto-generate `min` and `max` fields. fields. See note [reducible non-instances]. -/ abbrev LinearOrder.liftWithOrd' [LinearOrder β] [Ord α] (f : α → β) (inj : Injective f) (compare_f : ∀ a b : α, compare a b = compare (f a) (f b)) : LinearOrder α := @LinearOrder.liftWithOrd α β _ ⟨fun x y ↦ if f x ≤ f y then y else x⟩ ⟨fun x y ↦ if f x ≤ f y then x else y⟩ _ f inj (fun _ _ ↦ (apply_ite f _ _ _).trans (max_def _ _).symm) (fun _ _ ↦ (apply_ite f _ _ _).trans (min_def _ _).symm) compare_f /-! ### Subtype of an order -/ namespace Subtype instance le [LE α] {p : α → Prop} : LE (Subtype p) := ⟨fun x y ↦ (x : α) ≤ y⟩ instance lt [LT α] {p : α → Prop} : LT (Subtype p) := ⟨fun x y ↦ (x : α) < y⟩ @[simp] theorem mk_le_mk [LE α] {p : α → Prop} {x y : α} {hx : p x} {hy : p y} : (⟨x, hx⟩ : Subtype p) ≤ ⟨y, hy⟩ ↔ x ≤ y := Iff.rfl @[simp] theorem mk_lt_mk [LT α] {p : α → Prop} {x y : α} {hx : p x} {hy : p y} : (⟨x, hx⟩ : Subtype p) < ⟨y, hy⟩ ↔ x < y := Iff.rfl @[simp, norm_cast] theorem coe_le_coe [LE α] {p : α → Prop} {x y : Subtype p} : (x : α) ≤ y ↔ x ≤ y := Iff.rfl @[gcongr] alias ⟨_, GCongr.coe_le_coe⟩ := coe_le_coe @[simp, norm_cast] theorem coe_lt_coe [LT α] {p : α → Prop} {x y : Subtype p} : (x : α) < y ↔ x < y := Iff.rfl @[gcongr] alias ⟨_, GCongr.coe_lt_coe⟩ := coe_lt_coe instance preorder [Preorder α] (p : α → Prop) : Preorder (Subtype p) := Preorder.lift (fun (a : Subtype p) ↦ (a : α)) instance partialOrder [PartialOrder α] (p : α → Prop) : PartialOrder (Subtype p) := PartialOrder.lift (fun (a : Subtype p) ↦ (a : α)) Subtype.coe_injective instance decidableLE [Preorder α] [h : DecidableLE α] {p : α → Prop} : DecidableLE (Subtype p) := fun a b ↦ h a b instance decidableLT [Preorder α] [h : DecidableLT α] {p : α → Prop} : DecidableLT (Subtype p) := fun a b ↦ h a b /-- A subtype of a linear order is a linear order. We explicitly give the proofs of decidable equality and decidable order in order to ensure the decidability instances are all definitionally equal. -/ instance instLinearOrder [LinearOrder α] (p : α → Prop) : LinearOrder (Subtype p) := @LinearOrder.lift (Subtype p) _ _ ⟨fun x y ↦ ⟨max x y, max_rec' _ x.2 y.2⟩⟩ ⟨fun x y ↦ ⟨min x y, min_rec' _ x.2 y.2⟩⟩ (fun (a : Subtype p) ↦ (a : α)) Subtype.coe_injective (fun _ _ ↦ rfl) fun _ _ ↦ rfl end Subtype /-! ### Pointwise order on `α × β` The lexicographic order is defined in `Data.Prod.Lex`, and the instances are available via the type synonym `α ×ₗ β = α × β`. -/ namespace Prod section LE variable [LE α] [LE β] {x y : α × β} {a a₁ a₂ : α} {b b₁ b₂ : β} instance : LE (α × β) where le p q := p.1 ≤ q.1 ∧ p.2 ≤ q.2 instance instDecidableLE [Decidable (x.1 ≤ y.1)] [Decidable (x.2 ≤ y.2)] : Decidable (x ≤ y) := inferInstanceAs (Decidable (x.1 ≤ y.1 ∧ x.2 ≤ y.2)) lemma le_def : x ≤ y ↔ x.1 ≤ y.1 ∧ x.2 ≤ y.2 := .rfl @[simp] lemma mk_le_mk : (a₁, b₁) ≤ (a₂, b₂) ↔ a₁ ≤ a₂ ∧ b₁ ≤ b₂ := .rfl @[simp] lemma swap_le_swap : x.swap ≤ y.swap ↔ x ≤ y := and_comm @[simp] lemma swap_le_mk : x.swap ≤ (b, a) ↔ x ≤ (a, b) := and_comm @[simp] lemma mk_le_swap : (b, a) ≤ x.swap ↔ (a, b) ≤ x := and_comm end LE section Preorder	variable [Preorder α] [Preorder β] {a a₁ a₂ : α} {b b₁ b₂ : β} {x y : α × β}	Mathlib/Order/Basic.lean	1,076	1,078
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Patrick Massot -/ import Mathlib.Algebra.Group.TypeTags.Basic import Mathlib.Data.Fin.VecNotation import Mathlib.Data.Finset.Piecewise import Mathlib.Order.Filter.Cofinite import Mathlib.Order.Filter.Curry import Mathlib.Topology.Constructions.SumProd import Mathlib.Topology.NhdsSet /-! # Constructions of new topological spaces from old ones This file constructs pi types, subtypes and quotients of topological spaces and sets up their basic theory, such as criteria for maps into or out of these constructions to be continuous; descriptions of the open sets, neighborhood filters, and generators of these constructions; and their behavior with respect to embeddings and other specific classes of maps. ## Implementation note The constructed topologies are defined using induced and coinduced topologies along with the complete lattice structure on topologies. Their universal properties (for example, a map `X → Y × Z` is continuous if and only if both projections `X → Y`, `X → Z` are) follow easily using order-theoretic descriptions of continuity. With more work we can also extract descriptions of the open sets, neighborhood filters and so on. ## Tags product, subspace, quotient space -/ noncomputable section open Topology TopologicalSpace Set Filter Function open scoped Set.Notation universe u v u' v' variable {X : Type u} {Y : Type v} {Z W ε ζ : Type} section Constructions instance {r : X → X → Prop} [t : TopologicalSpace X] : TopologicalSpace (Quot r) := coinduced (Quot.mk r) t instance instTopologicalSpaceQuotient {s : Setoid X} [t : TopologicalSpace X] : TopologicalSpace (Quotient s) := coinduced Quotient.mk' t instance instTopologicalSpaceSigma {ι : Type} {X : ι → Type v} [t₂ : ∀ i, TopologicalSpace (X i)] : TopologicalSpace (Sigma X) := ⨆ i, coinduced (Sigma.mk i) (t₂ i) instance Pi.topologicalSpace {ι : Type} {Y : ι → Type v} [t₂ : (i : ι) → TopologicalSpace (Y i)] : TopologicalSpace ((i : ι) → Y i) := ⨅ i, induced (fun f => f i) (t₂ i) instance ULift.topologicalSpace [t : TopologicalSpace X] : TopologicalSpace (ULift.{v, u} X) := t.induced ULift.down /-! ### `Additive`, `Multiplicative` The topology on those type synonyms is inherited without change. -/ section variable [TopologicalSpace X] open Additive Multiplicative instance : TopologicalSpace (Additive X) := ‹TopologicalSpace X› instance : TopologicalSpace (Multiplicative X) := ‹TopologicalSpace X› instance [DiscreteTopology X] : DiscreteTopology (Additive X) := ‹DiscreteTopology X› instance [DiscreteTopology X] : DiscreteTopology (Multiplicative X) := ‹DiscreteTopology X› theorem continuous_ofMul : Continuous (ofMul : X → Additive X) := continuous_id theorem continuous_toMul : Continuous (toMul : Additive X → X) := continuous_id theorem continuous_ofAdd : Continuous (ofAdd : X → Multiplicative X) := continuous_id theorem continuous_toAdd : Continuous (toAdd : Multiplicative X → X) := continuous_id theorem isOpenMap_ofMul : IsOpenMap (ofMul : X → Additive X) := IsOpenMap.id theorem isOpenMap_toMul : IsOpenMap (toMul : Additive X → X) := IsOpenMap.id theorem isOpenMap_ofAdd : IsOpenMap (ofAdd : X → Multiplicative X) := IsOpenMap.id theorem isOpenMap_toAdd : IsOpenMap (toAdd : Multiplicative X → X) := IsOpenMap.id theorem isClosedMap_ofMul : IsClosedMap (ofMul : X → Additive X) := IsClosedMap.id theorem isClosedMap_toMul : IsClosedMap (toMul : Additive X → X) := IsClosedMap.id theorem isClosedMap_ofAdd : IsClosedMap (ofAdd : X → Multiplicative X) := IsClosedMap.id theorem isClosedMap_toAdd : IsClosedMap (toAdd : Multiplicative X → X) := IsClosedMap.id theorem nhds_ofMul (x : X) : 𝓝 (ofMul x) = map ofMul (𝓝 x) := rfl theorem nhds_ofAdd (x : X) : 𝓝 (ofAdd x) = map ofAdd (𝓝 x) := rfl theorem nhds_toMul (x : Additive X) : 𝓝 x.toMul = map toMul (𝓝 x) := rfl theorem nhds_toAdd (x : Multiplicative X) : 𝓝 x.toAdd = map toAdd (𝓝 x) := rfl end /-! ### Order dual The topology on this type synonym is inherited without change. -/ section variable [TopologicalSpace X] open OrderDual instance OrderDual.instTopologicalSpace : TopologicalSpace Xᵒᵈ := ‹_› instance OrderDual.instDiscreteTopology [DiscreteTopology X] : DiscreteTopology Xᵒᵈ := ‹_› theorem continuous_toDual : Continuous (toDual : X → Xᵒᵈ) := continuous_id theorem continuous_ofDual : Continuous (ofDual : Xᵒᵈ → X) := continuous_id theorem isOpenMap_toDual : IsOpenMap (toDual : X → Xᵒᵈ) := IsOpenMap.id theorem isOpenMap_ofDual : IsOpenMap (ofDual : Xᵒᵈ → X) := IsOpenMap.id theorem isClosedMap_toDual : IsClosedMap (toDual : X → Xᵒᵈ) := IsClosedMap.id theorem isClosedMap_ofDual : IsClosedMap (ofDual : Xᵒᵈ → X) := IsClosedMap.id theorem nhds_toDual (x : X) : 𝓝 (toDual x) = map toDual (𝓝 x) := rfl theorem nhds_ofDual (x : X) : 𝓝 (ofDual x) = map ofDual (𝓝 x) := rfl variable [Preorder X] {x : X} instance OrderDual.instNeBotNhdsWithinIoi [(𝓝[<] x).NeBot] : (𝓝[>] toDual x).NeBot := ‹_› instance OrderDual.instNeBotNhdsWithinIio [(𝓝[>] x).NeBot] : (𝓝[<] toDual x).NeBot := ‹_› end theorem Quotient.preimage_mem_nhds [TopologicalSpace X] [s : Setoid X] {V : Set <\| Quotient s} {x : X} (hs : V ∈ 𝓝 (Quotient.mk' x)) : Quotient.mk' ⁻¹' V ∈ 𝓝 x := preimage_nhds_coinduced hs /-- The image of a dense set under `Quotient.mk'` is a dense set. -/ theorem Dense.quotient [Setoid X] [TopologicalSpace X] {s : Set X} (H : Dense s) : Dense (Quotient.mk' '' s) := Quotient.mk''_surjective.denseRange.dense_image continuous_coinduced_rng H /-- The composition of `Quotient.mk'` and a function with dense range has dense range. -/ theorem DenseRange.quotient [Setoid X] [TopologicalSpace X] {f : Y → X} (hf : DenseRange f) : DenseRange (Quotient.mk' ∘ f) := Quotient.mk''_surjective.denseRange.comp hf continuous_coinduced_rng theorem continuous_map_of_le {α : Type} [TopologicalSpace α] {s t : Setoid α} (h : s ≤ t) : Continuous (Setoid.map_of_le h) := continuous_coinduced_rng theorem continuous_map_sInf {α : Type} [TopologicalSpace α] {S : Set (Setoid α)} {s : Setoid α} (h : s ∈ S) : Continuous (Setoid.map_sInf h) := continuous_coinduced_rng instance {p : X → Prop} [TopologicalSpace X] [DiscreteTopology X] : DiscreteTopology (Subtype p) := ⟨bot_unique fun s _ => ⟨(↑) '' s, isOpen_discrete _, preimage_image_eq _ Subtype.val_injective⟩⟩ instance Sum.discreteTopology [TopologicalSpace X] [TopologicalSpace Y] [h : DiscreteTopology X] [hY : DiscreteTopology Y] : DiscreteTopology (X ⊕ Y) := ⟨sup_eq_bot_iff.2 <\| by simp [h.eq_bot, hY.eq_bot]⟩ instance Sigma.discreteTopology {ι : Type} {Y : ι → Type v} [∀ i, TopologicalSpace (Y i)] [h : ∀ i, DiscreteTopology (Y i)] : DiscreteTopology (Sigma Y) := ⟨iSup_eq_bot.2 fun _ => by simp only [(h _).eq_bot, coinduced_bot]⟩ @[simp] lemma comap_nhdsWithin_range {α β} [TopologicalSpace β] (f : α → β) (y : β) : comap f (𝓝[range f] y) = comap f (𝓝 y) := comap_inf_principal_range section Top variable [TopologicalSpace X] /- The 𝓝 filter and the subspace topology. -/ theorem mem_nhds_subtype (s : Set X) (x : { x // x ∈ s }) (t : Set { x // x ∈ s }) : t ∈ 𝓝 x ↔ ∃ u ∈ 𝓝 (x : X), Subtype.val ⁻¹' u ⊆ t := mem_nhds_induced _ x t theorem nhds_subtype (s : Set X) (x : { x // x ∈ s }) : 𝓝 x = comap (↑) (𝓝 (x : X)) := nhds_induced _ x lemma nhds_subtype_eq_comap_nhdsWithin (s : Set X) (x : { x // x ∈ s }) : 𝓝 x = comap (↑) (𝓝[s] (x : X)) := by rw [nhds_subtype, ← comap_nhdsWithin_range, Subtype.range_val] theorem nhdsWithin_subtype_eq_bot_iff {s t : Set X} {x : s} : 𝓝[((↑) : s → X) ⁻¹' t] x = ⊥ ↔ 𝓝[t] (x : X) ⊓ 𝓟 s = ⊥ := by rw [inf_principal_eq_bot_iff_comap, nhdsWithin, nhdsWithin, comap_inf, comap_principal, nhds_induced] theorem nhds_ne_subtype_eq_bot_iff {S : Set X} {x : S} : 𝓝[≠] x = ⊥ ↔ 𝓝[≠] (x : X) ⊓ 𝓟 S = ⊥ := by rw [← nhdsWithin_subtype_eq_bot_iff, preimage_compl, ← image_singleton, Subtype.coe_injective.preimage_image] theorem nhds_ne_subtype_neBot_iff {S : Set X} {x : S} : (𝓝[≠] x).NeBot ↔ (𝓝[≠] (x : X) ⊓ 𝓟 S).NeBot := by rw [neBot_iff, neBot_iff, not_iff_not, nhds_ne_subtype_eq_bot_iff] theorem discreteTopology_subtype_iff {S : Set X} : DiscreteTopology S ↔ ∀ x ∈ S, 𝓝[≠] x ⊓ 𝓟 S = ⊥ := by simp_rw [discreteTopology_iff_nhds_ne, SetCoe.forall', nhds_ne_subtype_eq_bot_iff] end Top /-- A type synonym equipped with the topology whose open sets are the empty set and the sets with finite complements. -/ def CofiniteTopology (X : Type) := X namespace CofiniteTopology /-- The identity equivalence between `` and `CofiniteTopology `. -/ def of : X ≃ CofiniteTopology X := Equiv.refl X instance [Inhabited X] : Inhabited (CofiniteTopology X) where default := of default instance : TopologicalSpace (CofiniteTopology X) where IsOpen s := s.Nonempty → Set.Finite sᶜ isOpen_univ := by simp isOpen_inter s t := by rintro hs ht ⟨x, hxs, hxt⟩ rw [compl_inter] exact (hs ⟨x, hxs⟩).union (ht ⟨x, hxt⟩) isOpen_sUnion := by rintro s h ⟨x, t, hts, hzt⟩ rw [compl_sUnion] exact Finite.sInter (mem_image_of_mem _ hts) (h t hts ⟨x, hzt⟩) theorem isOpen_iff {s : Set (CofiniteTopology X)} : IsOpen s ↔ s.Nonempty → sᶜ.Finite := Iff.rfl theorem isOpen_iff' {s : Set (CofiniteTopology X)} : IsOpen s ↔ s = ∅ ∨ sᶜ.Finite := by simp only [isOpen_iff, nonempty_iff_ne_empty, or_iff_not_imp_left] theorem isClosed_iff {s : Set (CofiniteTopology X)} : IsClosed s ↔ s = univ ∨ s.Finite := by simp only [← isOpen_compl_iff, isOpen_iff', compl_compl, compl_empty_iff] theorem nhds_eq (x : CofiniteTopology X) : 𝓝 x = pure x ⊔ cofinite := by ext U rw [mem_nhds_iff] constructor · rintro ⟨V, hVU, V_op, haV⟩ exact mem_sup.mpr ⟨hVU haV, mem_of_superset (V_op ⟨_, haV⟩) hVU⟩ · rintro ⟨hU : x ∈ U, hU' : Uᶜ.Finite⟩ exact ⟨U, Subset.rfl, fun _ => hU', hU⟩ theorem mem_nhds_iff {x : CofiniteTopology X} {s : Set (CofiniteTopology X)} : s ∈ 𝓝 x ↔ x ∈ s ∧ sᶜ.Finite := by simp [nhds_eq] end CofiniteTopology end Constructions section Prod variable [TopologicalSpace X] [TopologicalSpace Y] theorem MapClusterPt.curry_prodMap {α β : Type} {f : α → X} {g : β → Y} {la : Filter α} {lb : Filter β} {x : X} {y : Y} (hf : MapClusterPt x la f) (hg : MapClusterPt y lb g) : MapClusterPt (x, y) (la.curry lb) (.map f g) := by rw [mapClusterPt_iff_frequently] at hf hg rw [((𝓝 x).basis_sets.prod_nhds (𝓝 y).basis_sets).mapClusterPt_iff_frequently] rintro ⟨s, t⟩ ⟨hs, ht⟩ rw [frequently_curry_iff] exact (hf s hs).mono fun x hx ↦ (hg t ht).mono fun y hy ↦ ⟨hx, hy⟩ theorem MapClusterPt.prodMap {α β : Type} {f : α → X} {g : β → Y} {la : Filter α} {lb : Filter β} {x : X} {y : Y} (hf : MapClusterPt x la f) (hg : MapClusterPt y lb g) : MapClusterPt (x, y) (la ×ˢ lb) (.map f g) := (hf.curry_prodMap hg).mono <\| map_mono curry_le_prod end Prod section Bool lemma continuous_bool_rng [TopologicalSpace X] {f : X → Bool} (b : Bool) : Continuous f ↔ IsClopen (f ⁻¹' {b}) := by rw [continuous_discrete_rng, Bool.forall_bool' b, IsClopen, ← isOpen_compl_iff, ← preimage_compl, Bool.compl_singleton, and_comm] end Bool section Subtype variable [TopologicalSpace X] [TopologicalSpace Y] {p : X → Prop} lemma Topology.IsInducing.subtypeVal {t : Set Y} : IsInducing ((↑) : t → Y) := ⟨rfl⟩ @[deprecated (since := "2024-10-28")] alias inducing_subtype_val := IsInducing.subtypeVal lemma Topology.IsInducing.of_codRestrict {f : X → Y} {t : Set Y} (ht : ∀ x, f x ∈ t) (h : IsInducing (t.codRestrict f ht)) : IsInducing f := subtypeVal.comp h @[deprecated (since := "2024-10-28")] alias Inducing.of_codRestrict := IsInducing.of_codRestrict lemma Topology.IsEmbedding.subtypeVal : IsEmbedding ((↑) : Subtype p → X) := ⟨.subtypeVal, Subtype.coe_injective⟩ @[deprecated (since := "2024-10-26")] alias embedding_subtype_val := IsEmbedding.subtypeVal theorem Topology.IsClosedEmbedding.subtypeVal (h : IsClosed {a \| p a}) : IsClosedEmbedding ((↑) : Subtype p → X) := ⟨.subtypeVal, by rwa [Subtype.range_coe_subtype]⟩ @[continuity, fun_prop] theorem continuous_subtype_val : Continuous (@Subtype.val X p) := continuous_induced_dom theorem Continuous.subtype_val {f : Y → Subtype p} (hf : Continuous f) : Continuous fun x => (f x : X) := continuous_subtype_val.comp hf theorem IsOpen.isOpenEmbedding_subtypeVal {s : Set X} (hs : IsOpen s) : IsOpenEmbedding ((↑) : s → X) := ⟨.subtypeVal, (@Subtype.range_coe _ s).symm ▸ hs⟩ theorem IsOpen.isOpenMap_subtype_val {s : Set X} (hs : IsOpen s) : IsOpenMap ((↑) : s → X) := hs.isOpenEmbedding_subtypeVal.isOpenMap theorem IsOpenMap.restrict {f : X → Y} (hf : IsOpenMap f) {s : Set X} (hs : IsOpen s) : IsOpenMap (s.restrict f) := hf.comp hs.isOpenMap_subtype_val lemma IsClosed.isClosedEmbedding_subtypeVal {s : Set X} (hs : IsClosed s) : IsClosedEmbedding ((↑) : s → X) := .subtypeVal hs theorem IsClosed.isClosedMap_subtype_val {s : Set X} (hs : IsClosed s) : IsClosedMap ((↑) : s → X) := hs.isClosedEmbedding_subtypeVal.isClosedMap @[continuity, fun_prop] theorem Continuous.subtype_mk {f : Y → X} (h : Continuous f) (hp : ∀ x, p (f x)) : Continuous fun x => (⟨f x, hp x⟩ : Subtype p) := continuous_induced_rng.2 h theorem Continuous.subtype_map {f : X → Y} (h : Continuous f) {q : Y → Prop} (hpq : ∀ x, p x → q (f x)) : Continuous (Subtype.map f hpq) := (h.comp continuous_subtype_val).subtype_mk _ theorem continuous_inclusion {s t : Set X} (h : s ⊆ t) : Continuous (inclusion h) := continuous_id.subtype_map h theorem continuousAt_subtype_val {p : X → Prop} {x : Subtype p} : ContinuousAt ((↑) : Subtype p → X) x := continuous_subtype_val.continuousAt theorem Subtype.dense_iff {s : Set X} {t : Set s} : Dense t ↔ s ⊆ closure ((↑) '' t) := by rw [IsInducing.subtypeVal.dense_iff, SetCoe.forall] rfl theorem map_nhds_subtype_val {s : Set X} (x : s) : map ((↑) : s → X) (𝓝 x) = 𝓝[s] ↑x := by rw [IsInducing.subtypeVal.map_nhds_eq, Subtype.range_val] theorem map_nhds_subtype_coe_eq_nhds {x : X} (hx : p x) (h : ∀ᶠ x in 𝓝 x, p x) : map ((↑) : Subtype p → X) (𝓝 ⟨x, hx⟩) = 𝓝 x := map_nhds_induced_of_mem <\| by rw [Subtype.range_val]; exact h theorem nhds_subtype_eq_comap {x : X} {h : p x} : 𝓝 (⟨x, h⟩ : Subtype p) = comap (↑) (𝓝 x) := nhds_induced _ _ theorem tendsto_subtype_rng {Y : Type} {p : X → Prop} {l : Filter Y} {f : Y → Subtype p} : ∀ {x : Subtype p}, Tendsto f l (𝓝 x) ↔ Tendsto (fun x => (f x : X)) l (𝓝 (x : X)) \| ⟨a, ha⟩ => by rw [nhds_subtype_eq_comap, tendsto_comap_iff]; rfl theorem closure_subtype {x : { a // p a }} {s : Set { a // p a }} : x ∈ closure s ↔ (x : X) ∈ closure (((↑) : _ → X) '' s) := closure_induced @[simp] theorem continuousAt_codRestrict_iff {f : X → Y} {t : Set Y} (h1 : ∀ x, f x ∈ t) {x : X} : ContinuousAt (codRestrict f t h1) x ↔ ContinuousAt f x := IsInducing.subtypeVal.continuousAt_iff alias ⟨_, ContinuousAt.codRestrict⟩ := continuousAt_codRestrict_iff theorem ContinuousAt.restrict {f : X → Y} {s : Set X} {t : Set Y} (h1 : MapsTo f s t) {x : s} (h2 : ContinuousAt f x) : ContinuousAt (h1.restrict f s t) x := (h2.comp continuousAt_subtype_val).codRestrict _ theorem ContinuousAt.restrictPreimage {f : X → Y} {s : Set Y} {x : f ⁻¹' s} (h : ContinuousAt f x) : ContinuousAt (s.restrictPreimage f) x := h.restrict _ @[continuity, fun_prop] theorem Continuous.codRestrict {f : X → Y} {s : Set Y} (hf : Continuous f) (hs : ∀ a, f a ∈ s) : Continuous (s.codRestrict f hs) := hf.subtype_mk hs @[continuity, fun_prop] theorem Continuous.restrict {f : X → Y} {s : Set X} {t : Set Y} (h1 : MapsTo f s t) (h2 : Continuous f) : Continuous (h1.restrict f s t) := (h2.comp continuous_subtype_val).codRestrict _ @[continuity, fun_prop] theorem Continuous.restrictPreimage {f : X → Y} {s : Set Y} (h : Continuous f) : Continuous (s.restrictPreimage f) := h.restrict _ lemma Topology.IsEmbedding.restrict {f : X → Y} (hf : IsEmbedding f) {s : Set X} {t : Set Y} (H : s.MapsTo f t) : IsEmbedding H.restrict := .of_comp (hf.continuous.restrict H) continuous_subtype_val (hf.comp .subtypeVal) lemma Topology.IsOpenEmbedding.restrict {f : X → Y} (hf : IsOpenEmbedding f) {s : Set X} {t : Set Y} (H : s.MapsTo f t) (hs : IsOpen s) : IsOpenEmbedding H.restrict := ⟨hf.isEmbedding.restrict H, (by rw [MapsTo.range_restrict] exact continuous_subtype_val.1 _ (hf.isOpenMap _ hs))⟩ theorem Topology.IsInducing.codRestrict {e : X → Y} (he : IsInducing e) {s : Set Y} (hs : ∀ x, e x ∈ s) : IsInducing (codRestrict e s hs) := he.of_comp (he.continuous.codRestrict hs) continuous_subtype_val @[deprecated (since := "2024-10-28")] alias Inducing.codRestrict := IsInducing.codRestrict protected lemma Topology.IsEmbedding.codRestrict {e : X → Y} (he : IsEmbedding e) (s : Set Y) (hs : ∀ x, e x ∈ s) : IsEmbedding (codRestrict e s hs) := he.of_comp (he.continuous.codRestrict hs) continuous_subtype_val @[deprecated (since := "2024-10-26")] alias Embedding.codRestrict := IsEmbedding.codRestrict variable {s t : Set X} protected lemma Topology.IsEmbedding.inclusion (h : s ⊆ t) : IsEmbedding (inclusion h) := IsEmbedding.subtypeVal.codRestrict _ _ protected lemma Topology.IsOpenEmbedding.inclusion (hst : s ⊆ t) (hs : IsOpen (t ↓∩ s)) : IsOpenEmbedding (inclusion hst) where toIsEmbedding := .inclusion _ isOpen_range := by rwa [range_inclusion] protected lemma Topology.IsClosedEmbedding.inclusion (hst : s ⊆ t) (hs : IsClosed (t ↓∩ s)) : IsClosedEmbedding (inclusion hst) where toIsEmbedding := .inclusion _ isClosed_range := by rwa [range_inclusion] @[deprecated (since := "2024-10-26")] alias embedding_inclusion := IsEmbedding.inclusion /-- Let `s, t ⊆ X` be two subsets of a topological space `X`. If `t ⊆ s` and the topology induced by `X`on `s` is discrete, then also the topology induces on `t` is discrete. -/ theorem DiscreteTopology.of_subset {X : Type} [TopologicalSpace X] {s t : Set X} (_ : DiscreteTopology s) (ts : t ⊆ s) : DiscreteTopology t := (IsEmbedding.inclusion ts).discreteTopology /-- Let `s` be a discrete subset of a topological space. Then the preimage of `s` by a continuous injective map is also discrete. -/ theorem DiscreteTopology.preimage_of_continuous_injective {X Y : Type} [TopologicalSpace X] [TopologicalSpace Y] (s : Set Y) [DiscreteTopology s] {f : X → Y} (hc : Continuous f) (hinj : Function.Injective f) : DiscreteTopology (f ⁻¹' s) := DiscreteTopology.of_continuous_injective (β := s) (Continuous.restrict (by exact fun _ x ↦ x) hc) ((MapsTo.restrict_inj _).mpr hinj.injOn) /-- If `f : X → Y` is a quotient map, then its restriction to the preimage of an open set is a quotient map too. -/ theorem Topology.IsQuotientMap.restrictPreimage_isOpen {f : X → Y} (hf : IsQuotientMap f) {s : Set Y} (hs : IsOpen s) : IsQuotientMap (s.restrictPreimage f) := by refine isQuotientMap_iff.2 ⟨hf.surjective.restrictPreimage _, fun U ↦ ?_⟩ rw [hs.isOpenEmbedding_subtypeVal.isOpen_iff_image_isOpen, ← hf.isOpen_preimage, (hs.preimage hf.continuous).isOpenEmbedding_subtypeVal.isOpen_iff_image_isOpen, image_val_preimage_restrictPreimage] @[deprecated (since := "2024-10-22")] alias QuotientMap.restrictPreimage_isOpen := IsQuotientMap.restrictPreimage_isOpen open scoped Set.Notation in lemma isClosed_preimage_val {s t : Set X} : IsClosed (s ↓∩ t) ↔ s ∩ closure (s ∩ t) ⊆ t := by rw [← closure_eq_iff_isClosed, IsEmbedding.subtypeVal.closure_eq_preimage_closure_image, ← Subtype.val_injective.image_injective.eq_iff, Subtype.image_preimage_coe, Subtype.image_preimage_coe, subset_antisymm_iff, and_iff_left, Set.subset_inter_iff, and_iff_right] exacts [Set.inter_subset_left, Set.subset_inter Set.inter_subset_left subset_closure] theorem frontier_inter_open_inter {s t : Set X} (ht : IsOpen t) : frontier (s ∩ t) ∩ t = frontier s ∩ t := by simp only [Set.inter_comm _ t, ← Subtype.preimage_coe_eq_preimage_coe_iff, ht.isOpenMap_subtype_val.preimage_frontier_eq_frontier_preimage continuous_subtype_val, Subtype.preimage_coe_self_inter] section SetNotation open scoped Set.Notation lemma IsOpen.preimage_val {s t : Set X} (ht : IsOpen t) : IsOpen (s ↓∩ t) := ht.preimage continuous_subtype_val lemma IsClosed.preimage_val {s t : Set X} (ht : IsClosed t) : IsClosed (s ↓∩ t) := ht.preimage continuous_subtype_val @[simp] lemma IsOpen.inter_preimage_val_iff {s t : Set X} (hs : IsOpen s) : IsOpen (s ↓∩ t) ↔ IsOpen (s ∩ t) := ⟨fun h ↦ by simpa using hs.isOpenMap_subtype_val _ h, fun h ↦ (Subtype.preimage_coe_self_inter _ _).symm ▸ h.preimage_val⟩ @[simp] lemma IsClosed.inter_preimage_val_iff {s t : Set X} (hs : IsClosed s) : IsClosed (s ↓∩ t) ↔ IsClosed (s ∩ t) := ⟨fun h ↦ by simpa using hs.isClosedMap_subtype_val _ h, fun h ↦ (Subtype.preimage_coe_self_inter _ _).symm ▸ h.preimage_val⟩ end SetNotation end Subtype section Quotient variable [TopologicalSpace X] [TopologicalSpace Y] variable {r : X → X → Prop} {s : Setoid X} theorem isQuotientMap_quot_mk : IsQuotientMap (@Quot.mk X r) := ⟨Quot.exists_rep, rfl⟩ @[deprecated (since := "2024-10-22")] alias quotientMap_quot_mk := isQuotientMap_quot_mk @[continuity, fun_prop] theorem continuous_quot_mk : Continuous (@Quot.mk X r) := continuous_coinduced_rng @[continuity, fun_prop] theorem continuous_quot_lift {f : X → Y} (hr : ∀ a b, r a b → f a = f b) (h : Continuous f) : Continuous (Quot.lift f hr : Quot r → Y) := continuous_coinduced_dom.2 h theorem isQuotientMap_quotient_mk' : IsQuotientMap (@Quotient.mk' X s) := isQuotientMap_quot_mk @[deprecated (since := "2024-10-22")] alias quotientMap_quotient_mk' := isQuotientMap_quotient_mk' theorem continuous_quotient_mk' : Continuous (@Quotient.mk' X s) := continuous_coinduced_rng theorem Continuous.quotient_lift {f : X → Y} (h : Continuous f) (hs : ∀ a b, a ≈ b → f a = f b) : Continuous (Quotient.lift f hs : Quotient s → Y) := continuous_coinduced_dom.2 h theorem Continuous.quotient_liftOn' {f : X → Y} (h : Continuous f) (hs : ∀ a b, s a b → f a = f b) : Continuous (fun x => Quotient.liftOn' x f hs : Quotient s → Y) := h.quotient_lift hs open scoped Relator in @[continuity, fun_prop] theorem Continuous.quotient_map' {t : Setoid Y} {f : X → Y} (hf : Continuous f) (H : (s.r ⇒ t.r) f f) : Continuous (Quotient.map' f H) := (continuous_quotient_mk'.comp hf).quotient_lift _ end Quotient section Pi variable {ι : Type} {π : ι → Type} {κ : Type} [TopologicalSpace X] [T : ∀ i, TopologicalSpace (π i)] {f : X → ∀ i : ι, π i} theorem continuous_pi_iff : Continuous f ↔ ∀ i, Continuous fun a => f a i := by simp only [continuous_iInf_rng, continuous_induced_rng, comp_def] @[continuity, fun_prop] theorem continuous_pi (h : ∀ i, Continuous fun a => f a i) : Continuous f := continuous_pi_iff.2 h @[continuity, fun_prop] theorem continuous_apply (i : ι) : Continuous fun p : ∀ i, π i => p i := continuous_iInf_dom continuous_induced_dom @[continuity] theorem continuous_apply_apply {ρ : κ → ι → Type} [∀ j i, TopologicalSpace (ρ j i)] (j : κ) (i : ι) : Continuous fun p : ∀ j, ∀ i, ρ j i => p j i := (continuous_apply i).comp (continuous_apply j) theorem continuousAt_apply (i : ι) (x : ∀ i, π i) : ContinuousAt (fun p : ∀ i, π i => p i) x := (continuous_apply i).continuousAt theorem Filter.Tendsto.apply_nhds {l : Filter Y} {f : Y → ∀ i, π i} {x : ∀ i, π i} (h : Tendsto f l (𝓝 x)) (i : ι) : Tendsto (fun a => f a i) l (𝓝 <\| x i) := (continuousAt_apply i _).tendsto.comp h @[fun_prop] protected theorem Continuous.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} (hf : ∀ i, Continuous (f i)) : Continuous (Pi.map f) := continuous_pi fun i ↦ (hf i).comp (continuous_apply i) theorem nhds_pi {a : ∀ i, π i} : 𝓝 a = pi fun i => 𝓝 (a i) := by simp only [nhds_iInf, nhds_induced, Filter.pi] protected theorem IsOpenMap.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} (hfo : ∀ i, IsOpenMap (f i)) (hsurj : ∀ᶠ i in cofinite, Surjective (f i)) : IsOpenMap (Pi.map f) := by refine IsOpenMap.of_nhds_le fun x ↦ ?_ rw [nhds_pi, nhds_pi, map_piMap_pi hsurj] exact Filter.pi_mono fun i ↦ (hfo i).nhds_le _ protected theorem IsOpenQuotientMap.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} (hf : ∀ i, IsOpenQuotientMap (f i)) : IsOpenQuotientMap (Pi.map f) := ⟨.piMap fun i ↦ (hf i).1, .piMap fun i ↦ (hf i).2, .piMap (fun i ↦ (hf i).3) <\| .of_forall fun i ↦ (hf i).1⟩ theorem tendsto_pi_nhds {f : Y → ∀ i, π i} {g : ∀ i, π i} {u : Filter Y} : Tendsto f u (𝓝 g) ↔ ∀ x, Tendsto (fun i => f i x) u (𝓝 (g x)) := by rw [nhds_pi, Filter.tendsto_pi] theorem continuousAt_pi {f : X → ∀ i, π i} {x : X} : ContinuousAt f x ↔ ∀ i, ContinuousAt (fun y => f y i) x := tendsto_pi_nhds @[fun_prop] theorem continuousAt_pi' {f : X → ∀ i, π i} {x : X} (hf : ∀ i, ContinuousAt (fun y => f y i) x) : ContinuousAt f x := continuousAt_pi.2 hf @[fun_prop] protected theorem ContinuousAt.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} {x : ∀ i, π i} (hf : ∀ i, ContinuousAt (f i) (x i)) : ContinuousAt (Pi.map f) x := continuousAt_pi.2 fun i ↦ (hf i).comp (continuousAt_apply i x) theorem Pi.continuous_precomp' {ι' : Type} (φ : ι' → ι) : Continuous (fun (f : (∀ i, π i)) (j : ι') ↦ f (φ j)) := continuous_pi fun j ↦ continuous_apply (φ j) theorem Pi.continuous_precomp {ι' : Type} (φ : ι' → ι) : Continuous (· ∘ φ : (ι → X) → (ι' → X)) := Pi.continuous_precomp' φ theorem Pi.continuous_postcomp' {X : ι → Type} [∀ i, TopologicalSpace (X i)] {g : ∀ i, π i → X i} (hg : ∀ i, Continuous (g i)) : Continuous (fun (f : (∀ i, π i)) (i : ι) ↦ g i (f i)) := continuous_pi fun i ↦ (hg i).comp <\| continuous_apply i theorem Pi.continuous_postcomp [TopologicalSpace Y] {g : X → Y} (hg : Continuous g) : Continuous (g ∘ · : (ι → X) → (ι → Y)) := Pi.continuous_postcomp' fun _ ↦ hg lemma Pi.induced_precomp' {ι' : Type} (φ : ι' → ι) : induced (fun (f : (∀ i, π i)) (j : ι') ↦ f (φ j)) Pi.topologicalSpace = ⨅ i', induced (eval (φ i')) (T (φ i')) := by simp [Pi.topologicalSpace, induced_iInf, induced_compose, comp_def] lemma Pi.induced_precomp [TopologicalSpace Y] {ι' : Type} (φ : ι' → ι) : induced (· ∘ φ) Pi.topologicalSpace = ⨅ i', induced (eval (φ i')) ‹TopologicalSpace Y› := induced_precomp' φ @[continuity, fun_prop] lemma Pi.continuous_restrict (S : Set ι) : Continuous (S.restrict : (∀ i : ι, π i) → (∀ i : S, π i)) := Pi.continuous_precomp' ((↑) : S → ι) @[continuity, fun_prop] lemma Pi.continuous_restrict₂ {s t : Set ι} (hst : s ⊆ t) : Continuous (restrict₂ (π := π) hst) := continuous_pi fun _ ↦ continuous_apply _ @[continuity, fun_prop] theorem Finset.continuous_restrict (s : Finset ι) : Continuous (s.restrict (π := π)) := continuous_pi fun _ ↦ continuous_apply _ @[continuity, fun_prop] theorem Finset.continuous_restrict₂ {s t : Finset ι} (hst : s ⊆ t) : Continuous (Finset.restrict₂ (π := π) hst) := continuous_pi fun _ ↦ continuous_apply _ variable [TopologicalSpace Z] @[continuity, fun_prop] theorem Pi.continuous_restrict_apply (s : Set X) {f : X → Z} (hf : Continuous f) : Continuous (s.restrict f) := hf.comp continuous_subtype_val @[continuity, fun_prop] theorem Pi.continuous_restrict₂_apply {s t : Set X} (hst : s ⊆ t) {f : t → Z} (hf : Continuous f) : Continuous (restrict₂ (π := fun _ ↦ Z) hst f) := hf.comp (continuous_inclusion hst) @[continuity, fun_prop] theorem Finset.continuous_restrict_apply (s : Finset X) {f : X → Z} (hf : Continuous f) : Continuous (s.restrict f) := hf.comp continuous_subtype_val @[continuity, fun_prop] theorem Finset.continuous_restrict₂_apply {s t : Finset X} (hst : s ⊆ t) {f : t → Z} (hf : Continuous f) : Continuous (restrict₂ (π := fun _ ↦ Z) hst f) := hf.comp (continuous_inclusion hst) lemma Pi.induced_restrict (S : Set ι) : induced (S.restrict) Pi.topologicalSpace = ⨅ i ∈ S, induced (eval i) (T i) := by simp +unfoldPartialApp [← iInf_subtype'', ← induced_precomp' ((↑) : S → ι), restrict] lemma Pi.induced_restrict_sUnion (𝔖 : Set (Set ι)) : induced (⋃₀ 𝔖).restrict (Pi.topologicalSpace (Y := fun i : (⋃₀ 𝔖) ↦ π i)) = ⨅ S ∈ 𝔖, induced S.restrict Pi.topologicalSpace := by simp_rw [Pi.induced_restrict, iInf_sUnion] theorem Filter.Tendsto.update [DecidableEq ι] {l : Filter Y} {f : Y → ∀ i, π i} {x : ∀ i, π i} (hf : Tendsto f l (𝓝 x)) (i : ι) {g : Y → π i} {xi : π i} (hg : Tendsto g l (𝓝 xi)) : Tendsto (fun a => update (f a) i (g a)) l (𝓝 <\| update x i xi) := tendsto_pi_nhds.2 fun j => by rcases eq_or_ne j i with (rfl \| hj) <;> simp [, hf.apply_nhds] theorem ContinuousAt.update [DecidableEq ι] {x : X} (hf : ContinuousAt f x) (i : ι) {g : X → π i} (hg : ContinuousAt g x) : ContinuousAt (fun a => update (f a) i (g a)) x := hf.tendsto.update i hg theorem Continuous.update [DecidableEq ι] (hf : Continuous f) (i : ι) {g : X → π i} (hg : Continuous g) : Continuous fun a => update (f a) i (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.update i hg.continuousAt /-- `Function.update f i x` is continuous in `(f, x)`. -/ @[continuity, fun_prop] theorem continuous_update [DecidableEq ι] (i : ι) : Continuous fun f : (∀ j, π j) × π i => update f.1 i f.2 := continuous_fst.update i continuous_snd /-- `Pi.mulSingle i x` is continuous in `x`. -/ @[to_additive (attr := continuity) "`Pi.single i x` is continuous in `x`."] theorem continuous_mulSingle [∀ i, One (π i)] [DecidableEq ι] (i : ι) : Continuous fun x => (Pi.mulSingle i x : ∀ i, π i) := continuous_const.update _ continuous_id section Fin variable {n : ℕ} {π : Fin (n + 1) → Type} [∀ i, TopologicalSpace (π i)] theorem Filter.Tendsto.finCons {f : Y → π 0} {g : Y → ∀ j : Fin n, π j.succ} {l : Filter Y} {x : π 0} {y : ∀ j, π (Fin.succ j)} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => Fin.cons (f a) (g a)) l (𝓝 <\| Fin.cons x y) := tendsto_pi_nhds.2 fun j => Fin.cases (by simpa) (by simpa using tendsto_pi_nhds.1 hg) j theorem ContinuousAt.finCons {f : X → π 0} {g : X → ∀ j : Fin n, π (Fin.succ j)} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => Fin.cons (f a) (g a)) x := hf.tendsto.finCons hg theorem Continuous.finCons {f : X → π 0} {g : X → ∀ j : Fin n, π (Fin.succ j)} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => Fin.cons (f a) (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.finCons hg.continuousAt theorem Filter.Tendsto.matrixVecCons {f : Y → Z} {g : Y → Fin n → Z} {l : Filter Y} {x : Z} {y : Fin n → Z} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => Matrix.vecCons (f a) (g a)) l (𝓝 <\| Matrix.vecCons x y) := hf.finCons hg theorem ContinuousAt.matrixVecCons {f : X → Z} {g : X → Fin n → Z} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => Matrix.vecCons (f a) (g a)) x := hf.finCons hg theorem Continuous.matrixVecCons {f : X → Z} {g : X → Fin n → Z} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => Matrix.vecCons (f a) (g a) := hf.finCons hg theorem Filter.Tendsto.finSnoc {f : Y → ∀ j : Fin n, π j.castSucc} {g : Y → π (Fin.last _)} {l : Filter Y} {x : ∀ j, π (Fin.castSucc j)} {y : π (Fin.last _)} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => Fin.snoc (f a) (g a)) l (𝓝 <\| Fin.snoc x y) := tendsto_pi_nhds.2 fun j => Fin.lastCases (by simpa) (by simpa using tendsto_pi_nhds.1 hf) j theorem ContinuousAt.finSnoc {f : X → ∀ j : Fin n, π j.castSucc} {g : X → π (Fin.last _)} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => Fin.snoc (f a) (g a)) x := hf.tendsto.finSnoc hg theorem Continuous.finSnoc {f : X → ∀ j : Fin n, π j.castSucc} {g : X → π (Fin.last _)} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => Fin.snoc (f a) (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.finSnoc hg.continuousAt theorem Filter.Tendsto.finInsertNth (i : Fin (n + 1)) {f : Y → π i} {g : Y → ∀ j : Fin n, π (i.succAbove j)} {l : Filter Y} {x : π i} {y : ∀ j, π (i.succAbove j)} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => i.insertNth (f a) (g a)) l (𝓝 <\| i.insertNth x y) := tendsto_pi_nhds.2 fun j => Fin.succAboveCases i (by simpa) (by simpa using tendsto_pi_nhds.1 hg) j @[deprecated (since := "2025-01-02")] alias Filter.Tendsto.fin_insertNth := Filter.Tendsto.finInsertNth theorem ContinuousAt.finInsertNth (i : Fin (n + 1)) {f : X → π i} {g : X → ∀ j : Fin n, π (i.succAbove j)} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => i.insertNth (f a) (g a)) x := hf.tendsto.finInsertNth i hg @[deprecated (since := "2025-01-02")] alias ContinuousAt.fin_insertNth := ContinuousAt.finInsertNth theorem Continuous.finInsertNth (i : Fin (n + 1)) {f : X → π i} {g : X → ∀ j : Fin n, π (i.succAbove j)} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => i.insertNth (f a) (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.finInsertNth i hg.continuousAt @[deprecated (since := "2025-01-02")] alias Continuous.fin_insertNth := Continuous.finInsertNth theorem Filter.Tendsto.finInit {f : Y → ∀ j : Fin (n + 1), π j} {l : Filter Y} {x : ∀ j, π j} (hg : Tendsto f l (𝓝 x)) : Tendsto (fun a ↦ Fin.init (f a)) l (𝓝 <\| Fin.init x) := tendsto_pi_nhds.2 fun j ↦ apply_nhds hg j.castSucc @[fun_prop] theorem ContinuousAt.finInit {f : X → ∀ j : Fin (n + 1), π j} {x : X} (hf : ContinuousAt f x) : ContinuousAt (fun a ↦ Fin.init (f a)) x := hf.tendsto.finInit @[fun_prop] theorem Continuous.finInit {f : X → ∀ j : Fin (n + 1), π j} (hf : Continuous f) : Continuous fun a ↦ Fin.init (f a) := continuous_iff_continuousAt.2 fun _ ↦ hf.continuousAt.finInit theorem Filter.Tendsto.finTail {f : Y → ∀ j : Fin (n + 1), π j} {l : Filter Y} {x : ∀ j, π j} (hg : Tendsto f l (𝓝 x)) : Tendsto (fun a ↦ Fin.tail (f a)) l (𝓝 <\| Fin.tail x) := tendsto_pi_nhds.2 fun j ↦ apply_nhds hg j.succ @[fun_prop] theorem ContinuousAt.finTail {f : X → ∀ j : Fin (n + 1), π j} {x : X} (hf : ContinuousAt f x) : ContinuousAt (fun a ↦ Fin.tail (f a)) x := hf.tendsto.finTail @[fun_prop] theorem Continuous.finTail {f : X → ∀ j : Fin (n + 1), π j} (hf : Continuous f) : Continuous fun a ↦ Fin.tail (f a) := continuous_iff_continuousAt.2 fun _ ↦ hf.continuousAt.finTail end Fin theorem isOpen_set_pi {i : Set ι} {s : ∀ a, Set (π a)} (hi : i.Finite) (hs : ∀ a ∈ i, IsOpen (s a)) : IsOpen (pi i s) := by rw [pi_def]; exact hi.isOpen_biInter fun a ha => (hs _ ha).preimage (continuous_apply _) theorem isOpen_pi_iff {s : Set (∀ a, π a)} : IsOpen s ↔ ∀ f, f ∈ s → ∃ (I : Finset ι) (u : ∀ a, Set (π a)), (∀ a, a ∈ I → IsOpen (u a) ∧ f a ∈ u a) ∧ (I : Set ι).pi u ⊆ s := by rw [isOpen_iff_nhds] simp_rw [le_principal_iff, nhds_pi, Filter.mem_pi', mem_nhds_iff] refine forall₂_congr fun a _ => ⟨?_, ?_⟩ · rintro ⟨I, t, ⟨h1, h2⟩⟩ refine ⟨I, fun a => eval a '' (I : Set ι).pi fun a => (h1 a).choose, fun i hi => ?_, ?_⟩ · simp_rw [eval_image_pi (Finset.mem_coe.mpr hi) (pi_nonempty_iff.mpr fun i => ⟨_, fun _ => (h1 i).choose_spec.2.2⟩)] exact (h1 i).choose_spec.2 · exact Subset.trans (pi_mono fun i hi => (eval_image_pi_subset hi).trans (h1 i).choose_spec.1) h2 · rintro ⟨I, t, ⟨h1, h2⟩⟩ classical refine ⟨I, fun a => ite (a ∈ I) (t a) univ, fun i => ?_, ?_⟩ · by_cases hi : i ∈ I · use t i simp_rw [if_pos hi] exact ⟨Subset.rfl, (h1 i) hi⟩ · use univ simp_rw [if_neg hi] exact ⟨Subset.rfl, isOpen_univ, mem_univ _⟩ · rw [← univ_pi_ite] simp only [← ite_and, ← Finset.mem_coe, and_self_iff, univ_pi_ite, h2] theorem isOpen_pi_iff' [Finite ι] {s : Set (∀ a, π a)} : IsOpen s ↔ ∀ f, f ∈ s → ∃ u : ∀ a, Set (π a), (∀ a, IsOpen (u a) ∧ f a ∈ u a) ∧ univ.pi u ⊆ s := by cases nonempty_fintype ι rw [isOpen_iff_nhds] simp_rw [le_principal_iff, nhds_pi, Filter.mem_pi', mem_nhds_iff] refine forall₂_congr fun a _ => ⟨?_, ?_⟩ · rintro ⟨I, t, ⟨h1, h2⟩⟩ refine ⟨fun i => (h1 i).choose, ⟨fun i => (h1 i).choose_spec.2, (pi_mono fun i _ => (h1 i).choose_spec.1).trans (Subset.trans ?_ h2)⟩⟩ rw [← pi_inter_compl (I : Set ι)] exact inter_subset_left · exact fun ⟨u, ⟨h1, _⟩⟩ => ⟨Finset.univ, u, ⟨fun i => ⟨u i, ⟨rfl.subset, h1 i⟩⟩, by rwa [Finset.coe_univ]⟩⟩ theorem isClosed_set_pi {i : Set ι} {s : ∀ a, Set (π a)} (hs : ∀ a ∈ i, IsClosed (s a)) : IsClosed (pi i s) := by rw [pi_def]; exact isClosed_biInter fun a ha => (hs _ ha).preimage (continuous_apply _) theorem mem_nhds_of_pi_mem_nhds {I : Set ι} {s : ∀ i, Set (π i)} (a : ∀ i, π i) (hs : I.pi s ∈ 𝓝 a) {i : ι} (hi : i ∈ I) : s i ∈ 𝓝 (a i) := by rw [nhds_pi] at hs; exact mem_of_pi_mem_pi hs hi theorem set_pi_mem_nhds {i : Set ι} {s : ∀ a, Set (π a)} {x : ∀ a, π a} (hi : i.Finite) (hs : ∀ a ∈ i, s a ∈ 𝓝 (x a)) : pi i s ∈ 𝓝 x := by rw [pi_def, biInter_mem hi] exact fun a ha => (continuous_apply a).continuousAt (hs a ha) theorem set_pi_mem_nhds_iff {I : Set ι} (hI : I.Finite) {s : ∀ i, Set (π i)} (a : ∀ i, π i) : I.pi s ∈ 𝓝 a ↔ ∀ i : ι, i ∈ I → s i ∈ 𝓝 (a i) := by rw [nhds_pi, pi_mem_pi_iff hI] theorem interior_pi_set {I : Set ι} (hI : I.Finite) {s : ∀ i, Set (π i)} : interior (pi I s) = I.pi fun i => interior (s i) := by ext a simp only [Set.mem_pi, mem_interior_iff_mem_nhds, set_pi_mem_nhds_iff hI] theorem exists_finset_piecewise_mem_of_mem_nhds [DecidableEq ι] {s : Set (∀ a, π a)} {x : ∀ a, π a} (hs : s ∈ 𝓝 x) (y : ∀ a, π a) : ∃ I : Finset ι, I.piecewise x y ∈ s := by simp only [nhds_pi, Filter.mem_pi'] at hs rcases hs with ⟨I, t, htx, hts⟩ refine ⟨I, hts fun i hi => ?_⟩ simpa [Finset.mem_coe.1 hi] using mem_of_mem_nhds (htx i) theorem pi_generateFrom_eq {π : ι → Type} {g : ∀ a, Set (Set (π a))} : (@Pi.topologicalSpace ι π fun a => generateFrom (g a)) = generateFrom { t \| ∃ (s : ∀ a, Set (π a)) (i : Finset ι), (∀ a ∈ i, s a ∈ g a) ∧ t = pi (↑i) s } := by refine le_antisymm ?_ ?_ · apply le_generateFrom rintro _ ⟨s, i, hi, rfl⟩ letI := fun a => generateFrom (g a) exact isOpen_set_pi i.finite_toSet (fun a ha => GenerateOpen.basic _ (hi a ha)) · classical refine le_iInf fun i => coinduced_le_iff_le_induced.1 <\| le_generateFrom fun s hs => ?_ refine GenerateOpen.basic _ ⟨update (fun i => univ) i s, {i}, ?_⟩ simp [hs] theorem pi_eq_generateFrom : Pi.topologicalSpace = generateFrom { g \| ∃ (s : ∀ a, Set (π a)) (i : Finset ι), (∀ a ∈ i, IsOpen (s a)) ∧ g = pi (↑i) s } := calc Pi.topologicalSpace _ = @Pi.topologicalSpace ι π fun _ => generateFrom { s \| IsOpen s } := by simp only [generateFrom_setOf_isOpen] _ = _ := pi_generateFrom_eq theorem pi_generateFrom_eq_finite {π : ι → Type} {g : ∀ a, Set (Set (π a))} [Finite ι] (hg : ∀ a, ⋃₀ g a = univ) : (@Pi.topologicalSpace ι π fun a => generateFrom (g a)) = generateFrom { t \| ∃ s : ∀ a, Set (π a), (∀ a, s a ∈ g a) ∧ t = pi univ s } := by cases nonempty_fintype ι rw [pi_generateFrom_eq] refine le_antisymm (generateFrom_anti ?_) (le_generateFrom ?_) · exact fun s ⟨t, ht, Eq⟩ => ⟨t, Finset.univ, by simp [ht, Eq]⟩ · rintro s ⟨t, i, ht, rfl⟩ letI := generateFrom { t \| ∃ s : ∀ a, Set (π a), (∀ a, s a ∈ g a) ∧ t = pi univ s } refine isOpen_iff_forall_mem_open.2 fun f hf => ?_ choose c hcg hfc using fun a => sUnion_eq_univ_iff.1 (hg a) (f a) refine ⟨pi i t ∩ pi ((↑i)ᶜ : Set ι) c, inter_subset_left, ?_, ⟨hf, fun a _ => hfc a⟩⟩ classical rw [← univ_pi_piecewise] refine GenerateOpen.basic _ ⟨_, fun a => ?_, rfl⟩ by_cases a ∈ i <;> simp [] theorem induced_to_pi {X : Type} (f : X → ∀ i, π i) : induced f Pi.topologicalSpace = ⨅ i, induced (f · i) inferInstance := by simp_rw [Pi.topologicalSpace, induced_iInf, induced_compose, Function.comp_def] /-- Suppose `π i` is a family of topological spaces indexed by `i : ι`, and `X` is a type endowed with a family of maps `f i : X → π i` for every `i : ι`, hence inducing a map `g : X → Π i, π i`. This lemma shows that infimum of the topologies on `X` induced by the `f i` as `i : ι` varies is simply the topology on `X` induced by `g : X → Π i, π i` where `Π i, π i` is endowed with the usual product topology. -/ theorem inducing_iInf_to_pi {X : Type} (f : ∀ i, X → π i) : @IsInducing X (∀ i, π i) (⨅ i, induced (f i) inferInstance) _ fun x i => f i x := letI := ⨅ i, induced (f i) inferInstance; ⟨(induced_to_pi _).symm⟩ variable [Finite ι] [∀ i, DiscreteTopology (π i)] /-- A finite product of discrete spaces is discrete. -/ instance Pi.discreteTopology : DiscreteTopology (∀ i, π i) := singletons_open_iff_discrete.mp fun x => by rw [← univ_pi_singleton] exact isOpen_set_pi finite_univ fun i _ => (isOpen_discrete {x i}) end Pi section Sigma variable {ι κ : Type} {σ : ι → Type} {τ : κ → Type*} [∀ i, TopologicalSpace (σ i)] [∀ k, TopologicalSpace (τ k)] [TopologicalSpace X] @[continuity, fun_prop] theorem continuous_sigmaMk {i : ι} : Continuous (@Sigma.mk ι σ i) := continuous_iSup_rng continuous_coinduced_rng theorem isOpen_sigma_iff {s : Set (Sigma σ)} : IsOpen s ↔ ∀ i, IsOpen (Sigma.mk i ⁻¹' s) := by rw [isOpen_iSup_iff] rfl theorem isClosed_sigma_iff {s : Set (Sigma σ)} : IsClosed s ↔ ∀ i, IsClosed (Sigma.mk i ⁻¹' s) := by simp only [← isOpen_compl_iff, isOpen_sigma_iff, preimage_compl] theorem isOpenMap_sigmaMk {i : ι} : IsOpenMap (@Sigma.mk ι σ i) := by intro s hs rw [isOpen_sigma_iff] intro j rcases eq_or_ne j i with (rfl \| hne) · rwa [preimage_image_eq _ sigma_mk_injective] · rw [preimage_image_sigmaMk_of_ne hne] exact isOpen_empty theorem isOpen_range_sigmaMk {i : ι} : IsOpen (range (@Sigma.mk ι σ i)) := isOpenMap_sigmaMk.isOpen_range theorem isClosedMap_sigmaMk {i : ι} : IsClosedMap (@Sigma.mk ι σ i) := by intro s hs rw [isClosed_sigma_iff] intro j rcases eq_or_ne j i with (rfl \| hne) · rwa [preimage_image_eq _ sigma_mk_injective] · rw [preimage_image_sigmaMk_of_ne hne] exact isClosed_empty theorem isClosed_range_sigmaMk {i : ι} : IsClosed (range (@Sigma.mk ι σ i)) := isClosedMap_sigmaMk.isClosed_range lemma Topology.IsOpenEmbedding.sigmaMk {i : ι} : IsOpenEmbedding (@Sigma.mk ι σ i) := .of_continuous_injective_isOpenMap continuous_sigmaMk sigma_mk_injective isOpenMap_sigmaMk @[deprecated (since := "2024-10-30")] alias isOpenEmbedding_sigmaMk := IsOpenEmbedding.sigmaMk lemma Topology.IsClosedEmbedding.sigmaMk {i : ι} : IsClosedEmbedding (@Sigma.mk ι σ i) := .of_continuous_injective_isClosedMap continuous_sigmaMk sigma_mk_injective isClosedMap_sigmaMk @[deprecated (since := "2024-10-30")] alias isClosedEmbedding_sigmaMk := IsClosedEmbedding.sigmaMk lemma Topology.IsEmbedding.sigmaMk {i : ι} : IsEmbedding (@Sigma.mk ι σ i) := IsClosedEmbedding.sigmaMk.1 @[deprecated (since := "2024-10-26")] alias embedding_sigmaMk := IsEmbedding.sigmaMk theorem Sigma.nhds_mk (i : ι) (x : σ i) : 𝓝 (⟨i, x⟩ : Sigma σ) = Filter.map (Sigma.mk i) (𝓝 x) := (IsOpenEmbedding.sigmaMk.map_nhds_eq x).symm theorem Sigma.nhds_eq (x : Sigma σ) : 𝓝 x = Filter.map (Sigma.mk x.1) (𝓝 x.2) := by cases x apply Sigma.nhds_mk theorem comap_sigmaMk_nhds (i : ι) (x : σ i) : comap (Sigma.mk i) (𝓝 ⟨i, x⟩) = 𝓝 x := (IsEmbedding.sigmaMk.nhds_eq_comap _).symm theorem isOpen_sigma_fst_preimage (s : Set ι) : IsOpen (Sigma.fst ⁻¹' s : Set (Σ a, σ a)) := by rw [← biUnion_of_singleton s, preimage_iUnion₂] simp only [← range_sigmaMk] exact isOpen_biUnion fun _ _ => isOpen_range_sigmaMk /-- A map out of a sum type is continuous iff its restriction to each summand is. -/ @[simp] theorem continuous_sigma_iff {f : Sigma σ → X} : Continuous f ↔ ∀ i, Continuous fun a => f ⟨i, a⟩ := by delta instTopologicalSpaceSigma rw [continuous_iSup_dom] exact forall_congr' fun _ => continuous_coinduced_dom /-- A map out of a sum type is continuous if its restriction to each summand is. -/ @[continuity, fun_prop] theorem continuous_sigma {f : Sigma σ → X} (hf : ∀ i, Continuous fun a => f ⟨i, a⟩) : Continuous f := continuous_sigma_iff.2 hf /-- A map defined on a sigma type (a.k.a. the disjoint union of an indexed family of topological spaces) is inducing iff its restriction to each component is inducing and each the image of each component under `f` can be separated from the images of all other components by an open set. -/ theorem inducing_sigma {f : Sigma σ → X} : IsInducing f ↔ (∀ i, IsInducing (f ∘ Sigma.mk i)) ∧ (∀ i, ∃ U, IsOpen U ∧ ∀ x, f x ∈ U ↔ x.1 = i) := by refine ⟨fun h ↦ ⟨fun i ↦ h.comp IsEmbedding.sigmaMk.1, fun i ↦ ?_⟩, ?_⟩ · rcases h.isOpen_iff.1 (isOpen_range_sigmaMk (i := i)) with ⟨U, hUo, hU⟩ refine ⟨U, hUo, ?_⟩ simpa [Set.ext_iff] using hU · refine fun ⟨h₁, h₂⟩ ↦ isInducing_iff_nhds.2 fun ⟨i, x⟩ ↦ ?_ rw [Sigma.nhds_mk, (h₁ i).nhds_eq_comap, comp_apply, ← comap_comap, map_comap_of_mem] rcases h₂ i with ⟨U, hUo, hU⟩ filter_upwards [preimage_mem_comap <\| hUo.mem_nhds <\| (hU _).2 rfl] with y hy simpa [hU] using hy @[simp 1100] theorem continuous_sigma_map {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} : Continuous (Sigma.map f₁ f₂) ↔ ∀ i, Continuous (f₂ i) := continuous_sigma_iff.trans <\| by simp only [Sigma.map, IsEmbedding.sigmaMk.continuous_iff, comp_def] @[continuity, fun_prop] theorem Continuous.sigma_map {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (hf : ∀ i, Continuous (f₂ i)) : Continuous (Sigma.map f₁ f₂) := continuous_sigma_map.2 hf theorem isOpenMap_sigma {f : Sigma σ → X} : IsOpenMap f ↔ ∀ i, IsOpenMap fun a => f ⟨i, a⟩ := by simp only [isOpenMap_iff_nhds_le, Sigma.forall, Sigma.nhds_eq, map_map, comp_def] theorem isOpenMap_sigma_map {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} : IsOpenMap (Sigma.map f₁ f₂) ↔ ∀ i, IsOpenMap (f₂ i) := isOpenMap_sigma.trans <\| forall_congr' fun i => (@IsOpenEmbedding.sigmaMk _ _ _ (f₁ i)).isOpenMap_iff.symm lemma Topology.isInducing_sigmaMap {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (h₁ : Injective f₁) : IsInducing (Sigma.map f₁ f₂) ↔ ∀ i, IsInducing (f₂ i) := by simp only [isInducing_iff_nhds, Sigma.forall, Sigma.nhds_mk, Sigma.map_mk, ← map_sigma_mk_comap h₁, map_inj sigma_mk_injective] @[deprecated (since := "2024-10-28")] alias inducing_sigma_map := isInducing_sigmaMap lemma Topology.isEmbedding_sigmaMap {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (h : Injective f₁) : IsEmbedding (Sigma.map f₁ f₂) ↔ ∀ i, IsEmbedding (f₂ i) := by simp only [isEmbedding_iff, Injective.sigma_map, isInducing_sigmaMap h, forall_and, h.sigma_map_iff] @[deprecated (since := "2024-10-26")] alias embedding_sigma_map := isEmbedding_sigmaMap lemma Topology.isOpenEmbedding_sigmaMap {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (h : Injective f₁) : IsOpenEmbedding (Sigma.map f₁ f₂) ↔ ∀ i, IsOpenEmbedding (f₂ i) := by simp only [isOpenEmbedding_iff_isEmbedding_isOpenMap, isOpenMap_sigma_map, isEmbedding_sigmaMap h, forall_and] @[deprecated (since := "2024-10-30")] alias isOpenEmbedding_sigma_map := isOpenEmbedding_sigmaMap end Sigma section ULift theorem ULift.isOpen_iff [TopologicalSpace X] {s : Set (ULift.{v} X)} : IsOpen s ↔ IsOpen (ULift.up ⁻¹' s) := by rw [ULift.topologicalSpace, ← Equiv.ulift_apply, ← Equiv.ulift.coinduced_symm, ← isOpen_coinduced] theorem ULift.isClosed_iff [TopologicalSpace X] {s : Set (ULift.{v} X)} : IsClosed s ↔ IsClosed (ULift.up ⁻¹' s) := by rw [← isOpen_compl_iff, ← isOpen_compl_iff, isOpen_iff, preimage_compl] @[continuity, fun_prop] theorem continuous_uliftDown [TopologicalSpace X] : Continuous (ULift.down : ULift.{v, u} X → X) := continuous_induced_dom @[continuity, fun_prop] theorem continuous_uliftUp [TopologicalSpace X] : Continuous (ULift.up : X → ULift.{v, u} X) := continuous_induced_rng.2 continuous_id @[deprecated (since := "2025-02-10")] alias continuous_uLift_down := continuous_uliftDown @[deprecated (since := "2025-02-10")] alias continuous_uLift_up := continuous_uliftUp @[continuity, fun_prop] theorem continuous_uliftMap [TopologicalSpace X] [TopologicalSpace Y] (f : X → Y) (hf : Continuous f) : Continuous (ULift.map f : ULift.{u'} X → ULift.{v'} Y) := by change Continuous (ULift.up ∘ f ∘ ULift.down) fun_prop lemma Topology.IsEmbedding.uliftDown [TopologicalSpace X] : IsEmbedding (ULift.down : ULift.{v, u} X → X) := ⟨⟨rfl⟩, ULift.down_injective⟩ @[deprecated (since := "2024-10-26")] alias embedding_uLift_down := IsEmbedding.uliftDown lemma Topology.IsClosedEmbedding.uliftDown [TopologicalSpace X] : IsClosedEmbedding (ULift.down : ULift.{v, u} X → X) := ⟨.uliftDown, by simp only [ULift.down_surjective.range_eq, isClosed_univ]⟩ @[deprecated (since := "2024-10-30")] alias ULift.isClosedEmbedding_down := IsClosedEmbedding.uliftDown instance [TopologicalSpace X] [DiscreteTopology X] : DiscreteTopology (ULift X) := IsEmbedding.uliftDown.discreteTopology end ULift section Monad variable [TopologicalSpace X] {s : Set X} {t : Set s} theorem IsOpen.trans (ht : IsOpen t) (hs : IsOpen s) : IsOpen (t : Set X) := by rcases isOpen_induced_iff.mp ht with ⟨s', hs', rfl⟩ rw [Subtype.image_preimage_coe] exact hs.inter hs' theorem IsClosed.trans (ht : IsClosed t) (hs : IsClosed s) : IsClosed (t : Set X) := by rcases isClosed_induced_iff.mp ht with ⟨s', hs', rfl⟩ rw [Subtype.image_preimage_coe] exact hs.inter hs' end Monad section NhdsSet variable [TopologicalSpace X] [TopologicalSpace Y] {s : Set X} {t : Set Y} /-- The product of a neighborhood of `s` and a neighborhood of `t` is a neighborhood of `s ×ˢ t`, formulated in terms of a filter inequality. -/ theorem nhdsSet_prod_le (s : Set X) (t : Set Y) : 𝓝ˢ (s ×ˢ t) ≤ 𝓝ˢ s ×ˢ 𝓝ˢ t := ((hasBasis_nhdsSet _).prod (hasBasis_nhdsSet _)).ge_iff.2 fun (_u, _v) ⟨⟨huo, hsu⟩, hvo, htv⟩ ↦ (huo.prod hvo).mem_nhdsSet.2 <\| prod_mono hsu htv theorem Filter.eventually_nhdsSet_prod_iff {p : X × Y → Prop} : (∀ᶠ q in 𝓝ˢ (s ×ˢ t), p q) ↔ ∀ x ∈ s, ∀ y ∈ t, ∃ px : X → Prop, (∀ᶠ x' in 𝓝 x, px x') ∧ ∃ py : Y → Prop, (∀ᶠ y' in 𝓝 y, py y') ∧ ∀ {x : X}, px x → ∀ {y : Y}, py y → p (x, y) := by simp_rw [eventually_nhdsSet_iff_forall, forall_prod_set, nhds_prod_eq, eventually_prod_iff] theorem Filter.Eventually.prod_nhdsSet {p : X × Y → Prop} {px : X → Prop} {py : Y → Prop} (hp : ∀ {x : X}, px x → ∀ {y : Y}, py y → p (x, y)) (hs : ∀ᶠ x in 𝓝ˢ s, px x) (ht : ∀ᶠ y in 𝓝ˢ t, py y) : ∀ᶠ q in 𝓝ˢ (s ×ˢ t), p q := nhdsSet_prod_le _ _ (mem_of_superset (prod_mem_prod hs ht) fun _ ⟨hx, hy⟩ ↦ hp hx hy) end NhdsSet		Mathlib/Topology/Constructions.lean	1,286	1,287
/- Copyright (c) 2022 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers -/ import Mathlib.Algebra.CharP.Invertible import Mathlib.Algebra.Order.Interval.Set.Group import Mathlib.Analysis.Convex.Basic import Mathlib.Analysis.Convex.Segment import Mathlib.LinearAlgebra.AffineSpace.FiniteDimensional import Mathlib.Tactic.FieldSimp /-! # Betweenness in affine spaces This file defines notions of a point in an affine space being between two given points. ## Main definitions * `affineSegment R x y`: The segment of points weakly between `x` and `y`. * `Wbtw R x y z`: The point `y` is weakly between `x` and `z`. * `Sbtw R x y z`: The point `y` is strictly between `x` and `z`. -/ variable (R : Type) {V V' P P' : Type} open AffineEquiv AffineMap section OrderedRing /-- The segment of points weakly between `x` and `y`. When convexity is refactored to support abstract affine combination spaces, this will no longer need to be a separate definition from `segment`. However, lemmas involving `+ᵥ` or `-ᵥ` will still be relevant after such a refactoring, as distinct from versions involving `+` or `-` in a module. -/ def affineSegment [Ring R] [PartialOrder R] [AddCommGroup V] [Module R V] [AddTorsor V P] (x y : P) := lineMap x y '' Set.Icc (0 : R) 1 variable [Ring R] [PartialOrder R] [AddCommGroup V] [Module R V] [AddTorsor V P] variable [AddCommGroup V'] [Module R V'] [AddTorsor V' P'] variable {R} in @[simp] theorem affineSegment_image (f : P →ᵃ[R] P') (x y : P) : f '' affineSegment R x y = affineSegment R (f x) (f y) := by rw [affineSegment, affineSegment, Set.image_image, ← comp_lineMap] rfl @[simp] theorem affineSegment_const_vadd_image (x y : P) (v : V) : (v +ᵥ ·) '' affineSegment R x y = affineSegment R (v +ᵥ x) (v +ᵥ y) := affineSegment_image (AffineEquiv.constVAdd R P v : P →ᵃ[R] P) x y @[simp] theorem affineSegment_vadd_const_image (x y : V) (p : P) : (· +ᵥ p) '' affineSegment R x y = affineSegment R (x +ᵥ p) (y +ᵥ p) := affineSegment_image (AffineEquiv.vaddConst R p : V →ᵃ[R] P) x y @[simp] theorem affineSegment_const_vsub_image (x y p : P) : (p -ᵥ ·) '' affineSegment R x y = affineSegment R (p -ᵥ x) (p -ᵥ y) := affineSegment_image (AffineEquiv.constVSub R p : P →ᵃ[R] V) x y @[simp] theorem affineSegment_vsub_const_image (x y p : P) : (· -ᵥ p) '' affineSegment R x y = affineSegment R (x -ᵥ p) (y -ᵥ p) := affineSegment_image ((AffineEquiv.vaddConst R p).symm : P →ᵃ[R] V) x y variable {R} @[simp] theorem mem_const_vadd_affineSegment {x y z : P} (v : V) : v +ᵥ z ∈ affineSegment R (v +ᵥ x) (v +ᵥ y) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_const_vadd_image, (AddAction.injective v).mem_set_image] @[simp] theorem mem_vadd_const_affineSegment {x y z : V} (p : P) : z +ᵥ p ∈ affineSegment R (x +ᵥ p) (y +ᵥ p) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_vadd_const_image, (vadd_right_injective p).mem_set_image] @[simp] theorem mem_const_vsub_affineSegment {x y z : P} (p : P) : p -ᵥ z ∈ affineSegment R (p -ᵥ x) (p -ᵥ y) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_const_vsub_image, (vsub_right_injective p).mem_set_image] @[simp] theorem mem_vsub_const_affineSegment {x y z : P} (p : P) : z -ᵥ p ∈ affineSegment R (x -ᵥ p) (y -ᵥ p) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_vsub_const_image, (vsub_left_injective p).mem_set_image] variable (R) section OrderedRing variable [IsOrderedRing R] theorem affineSegment_eq_segment (x y : V) : affineSegment R x y = segment R x y := by rw [segment_eq_image_lineMap, affineSegment] theorem affineSegment_comm (x y : P) : affineSegment R x y = affineSegment R y x := by refine Set.ext fun z => ?_ constructor <;> · rintro ⟨t, ht, hxy⟩ refine ⟨1 - t, ?_, ?_⟩ · rwa [Set.sub_mem_Icc_iff_right, sub_self, sub_zero] · rwa [lineMap_apply_one_sub] theorem left_mem_affineSegment (x y : P) : x ∈ affineSegment R x y := ⟨0, Set.left_mem_Icc.2 zero_le_one, lineMap_apply_zero _ _⟩ theorem right_mem_affineSegment (x y : P) : y ∈ affineSegment R x y := ⟨1, Set.right_mem_Icc.2 zero_le_one, lineMap_apply_one _ _⟩ @[simp] theorem affineSegment_same (x : P) : affineSegment R x x = {x} := by simp_rw [affineSegment, lineMap_same, AffineMap.coe_const, Function.const, (Set.nonempty_Icc.mpr zero_le_one).image_const] end OrderedRing /-- The point `y` is weakly between `x` and `z`. -/ def Wbtw (x y z : P) : Prop := y ∈ affineSegment R x z /-- The point `y` is strictly between `x` and `z`. -/ def Sbtw (x y z : P) : Prop := Wbtw R x y z ∧ y ≠ x ∧ y ≠ z variable {R} section OrderedRing variable [IsOrderedRing R] lemma mem_segment_iff_wbtw {x y z : V} : y ∈ segment R x z ↔ Wbtw R x y z := by rw [Wbtw, affineSegment_eq_segment] alias ⟨_, Wbtw.mem_segment⟩ := mem_segment_iff_wbtw lemma Convex.mem_of_wbtw {p₀ p₁ p₂ : V} {s : Set V} (hs : Convex R s) (h₀₁₂ : Wbtw R p₀ p₁ p₂) (h₀ : p₀ ∈ s) (h₂ : p₂ ∈ s) : p₁ ∈ s := hs.segment_subset h₀ h₂ h₀₁₂.mem_segment theorem wbtw_comm {x y z : P} : Wbtw R x y z ↔ Wbtw R z y x := by rw [Wbtw, Wbtw, affineSegment_comm] alias ⟨Wbtw.symm, _⟩ := wbtw_comm theorem sbtw_comm {x y z : P} : Sbtw R x y z ↔ Sbtw R z y x := by rw [Sbtw, Sbtw, wbtw_comm, ← and_assoc, ← and_assoc, and_right_comm] alias ⟨Sbtw.symm, _⟩ := sbtw_comm end OrderedRing lemma AffineSubspace.mem_of_wbtw {s : AffineSubspace R P} {x y z : P} (hxyz : Wbtw R x y z) (hx : x ∈ s) (hz : z ∈ s) : y ∈ s := by obtain ⟨ε, -, rfl⟩ := hxyz; exact lineMap_mem _ hx hz theorem Wbtw.map {x y z : P} (h : Wbtw R x y z) (f : P →ᵃ[R] P') : Wbtw R (f x) (f y) (f z) := by rw [Wbtw, ← affineSegment_image] exact Set.mem_image_of_mem _ h theorem Function.Injective.wbtw_map_iff {x y z : P} {f : P →ᵃ[R] P'} (hf : Function.Injective f) : Wbtw R (f x) (f y) (f z) ↔ Wbtw R x y z := by refine ⟨fun h => ?_, fun h => h.map _⟩ rwa [Wbtw, ← affineSegment_image, hf.mem_set_image] at h theorem Function.Injective.sbtw_map_iff {x y z : P} {f : P →ᵃ[R] P'} (hf : Function.Injective f) : Sbtw R (f x) (f y) (f z) ↔ Sbtw R x y z := by simp_rw [Sbtw, hf.wbtw_map_iff, hf.ne_iff] @[simp] theorem AffineEquiv.wbtw_map_iff {x y z : P} (f : P ≃ᵃ[R] P') : Wbtw R (f x) (f y) (f z) ↔ Wbtw R x y z := by have : Function.Injective f.toAffineMap := f.injective -- `refine` or `exact` are very slow, `apply` is fast. Please check before golfing. apply this.wbtw_map_iff @[simp] theorem AffineEquiv.sbtw_map_iff {x y z : P} (f : P ≃ᵃ[R] P') : Sbtw R (f x) (f y) (f z) ↔ Sbtw R x y z := by have : Function.Injective f.toAffineMap := f.injective -- `refine` or `exact` are very slow, `apply` is fast. Please check before golfing. apply this.sbtw_map_iff @[simp] theorem wbtw_const_vadd_iff {x y z : P} (v : V) : Wbtw R (v +ᵥ x) (v +ᵥ y) (v +ᵥ z) ↔ Wbtw R x y z := mem_const_vadd_affineSegment _ @[simp] theorem wbtw_vadd_const_iff {x y z : V} (p : P) : Wbtw R (x +ᵥ p) (y +ᵥ p) (z +ᵥ p) ↔ Wbtw R x y z := mem_vadd_const_affineSegment _ @[simp] theorem wbtw_const_vsub_iff {x y z : P} (p : P) : Wbtw R (p -ᵥ x) (p -ᵥ y) (p -ᵥ z) ↔ Wbtw R x y z := mem_const_vsub_affineSegment _ @[simp] theorem wbtw_vsub_const_iff {x y z : P} (p : P) : Wbtw R (x -ᵥ p) (y -ᵥ p) (z -ᵥ p) ↔ Wbtw R x y z := mem_vsub_const_affineSegment _ @[simp] theorem sbtw_const_vadd_iff {x y z : P} (v : V) : Sbtw R (v +ᵥ x) (v +ᵥ y) (v +ᵥ z) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_const_vadd_iff, (AddAction.injective v).ne_iff, (AddAction.injective v).ne_iff] @[simp] theorem sbtw_vadd_const_iff {x y z : V} (p : P) : Sbtw R (x +ᵥ p) (y +ᵥ p) (z +ᵥ p) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_vadd_const_iff, (vadd_right_injective p).ne_iff, (vadd_right_injective p).ne_iff] @[simp] theorem sbtw_const_vsub_iff {x y z : P} (p : P) : Sbtw R (p -ᵥ x) (p -ᵥ y) (p -ᵥ z) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_const_vsub_iff, (vsub_right_injective p).ne_iff, (vsub_right_injective p).ne_iff] @[simp] theorem sbtw_vsub_const_iff {x y z : P} (p : P) : Sbtw R (x -ᵥ p) (y -ᵥ p) (z -ᵥ p) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_vsub_const_iff, (vsub_left_injective p).ne_iff, (vsub_left_injective p).ne_iff] theorem Sbtw.wbtw {x y z : P} (h : Sbtw R x y z) : Wbtw R x y z := h.1 theorem Sbtw.ne_left {x y z : P} (h : Sbtw R x y z) : y ≠ x := h.2.1 theorem Sbtw.left_ne {x y z : P} (h : Sbtw R x y z) : x ≠ y := h.2.1.symm theorem Sbtw.ne_right {x y z : P} (h : Sbtw R x y z) : y ≠ z := h.2.2 theorem Sbtw.right_ne {x y z : P} (h : Sbtw R x y z) : z ≠ y := h.2.2.symm theorem Sbtw.mem_image_Ioo {x y z : P} (h : Sbtw R x y z) : y ∈ lineMap x z '' Set.Ioo (0 : R) 1 := by rcases h with ⟨⟨t, ht, rfl⟩, hyx, hyz⟩ rcases Set.eq_endpoints_or_mem_Ioo_of_mem_Icc ht with (rfl \| rfl \| ho) · exfalso exact hyx (lineMap_apply_zero _ _) · exfalso exact hyz (lineMap_apply_one _ _) · exact ⟨t, ho, rfl⟩ theorem Wbtw.mem_affineSpan {x y z : P} (h : Wbtw R x y z) : y ∈ line[R, x, z] := by rcases h with ⟨r, ⟨-, rfl⟩⟩ exact lineMap_mem_affineSpan_pair _ _ _ variable (R) section OrderedRing variable [IsOrderedRing R] @[simp] theorem wbtw_self_left (x y : P) : Wbtw R x x y := left_mem_affineSegment _ _ _ @[simp] theorem wbtw_self_right (x y : P) : Wbtw R x y y := right_mem_affineSegment _ _ _ @[simp] theorem wbtw_self_iff {x y : P} : Wbtw R x y x ↔ y = x := by refine ⟨fun h => ?_, fun h => ?_⟩ · simpa [Wbtw, affineSegment] using h · rw [h] exact wbtw_self_left R x x end OrderedRing @[simp] theorem not_sbtw_self_left (x y : P) : ¬Sbtw R x x y := fun h => h.ne_left rfl @[simp] theorem not_sbtw_self_right (x y : P) : ¬Sbtw R x y y := fun h => h.ne_right rfl variable {R} variable [IsOrderedRing R] theorem Wbtw.left_ne_right_of_ne_left {x y z : P} (h : Wbtw R x y z) (hne : y ≠ x) : x ≠ z := by rintro rfl rw [wbtw_self_iff] at h exact hne h theorem Wbtw.left_ne_right_of_ne_right {x y z : P} (h : Wbtw R x y z) (hne : y ≠ z) : x ≠ z := by rintro rfl rw [wbtw_self_iff] at h exact hne h theorem Sbtw.left_ne_right {x y z : P} (h : Sbtw R x y z) : x ≠ z := h.wbtw.left_ne_right_of_ne_left h.2.1 theorem sbtw_iff_mem_image_Ioo_and_ne [NoZeroSMulDivisors R V] {x y z : P} : Sbtw R x y z ↔ y ∈ lineMap x z '' Set.Ioo (0 : R) 1 ∧ x ≠ z := by refine ⟨fun h => ⟨h.mem_image_Ioo, h.left_ne_right⟩, fun h => ?_⟩ rcases h with ⟨⟨t, ht, rfl⟩, hxz⟩ refine ⟨⟨t, Set.mem_Icc_of_Ioo ht, rfl⟩, ?_⟩ rw [lineMap_apply, ← @vsub_ne_zero V, ← @vsub_ne_zero V _ _ _ _ z, vadd_vsub_assoc, vsub_self, vadd_vsub_assoc, ← neg_vsub_eq_vsub_rev z x, ← @neg_one_smul R, ← add_smul, ← sub_eq_add_neg] simp [smul_ne_zero, sub_eq_zero, ht.1.ne.symm, ht.2.ne, hxz.symm] variable (R) @[simp] theorem not_sbtw_self (x y : P) : ¬Sbtw R x y x := fun h => h.left_ne_right rfl theorem wbtw_swap_left_iff [NoZeroSMulDivisors R V] {x y : P} (z : P) : Wbtw R x y z ∧ Wbtw R y x z ↔ x = y := by constructor · rintro ⟨hxyz, hyxz⟩ rcases hxyz with ⟨ty, hty, rfl⟩ rcases hyxz with ⟨tx, htx, hx⟩ rw [lineMap_apply, lineMap_apply, ← add_vadd] at hx rw [← @vsub_eq_zero_iff_eq V, vadd_vsub, vsub_vadd_eq_vsub_sub, smul_sub, smul_smul, ← sub_smul, ← add_smul, smul_eq_zero] at hx rcases hx with (h \| h) · nth_rw 1 [← mul_one tx] at h rw [← mul_sub, add_eq_zero_iff_neg_eq] at h have h' : ty = 0 := by refine le_antisymm ?_ hty.1 rw [← h, Left.neg_nonpos_iff] exact mul_nonneg htx.1 (sub_nonneg.2 hty.2) simp [h'] · rw [vsub_eq_zero_iff_eq] at h rw [h, lineMap_same_apply] · rintro rfl exact ⟨wbtw_self_left _ _ _, wbtw_self_left _ _ _⟩ theorem wbtw_swap_right_iff [NoZeroSMulDivisors R V] (x : P) {y z : P} : Wbtw R x y z ∧ Wbtw R x z y ↔ y = z := by rw [wbtw_comm, wbtw_comm (z := y), eq_comm] exact wbtw_swap_left_iff R x theorem wbtw_rotate_iff [NoZeroSMulDivisors R V] (x : P) {y z : P} : Wbtw R x y z ∧ Wbtw R z x y ↔ x = y := by rw [wbtw_comm, wbtw_swap_right_iff, eq_comm] variable {R} theorem Wbtw.swap_left_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) : Wbtw R y x z ↔ x = y := by rw [← wbtw_swap_left_iff R z, and_iff_right h] theorem Wbtw.swap_right_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) : Wbtw R x z y ↔ y = z := by rw [← wbtw_swap_right_iff R x, and_iff_right h] theorem Wbtw.rotate_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) : Wbtw R z x y ↔ x = y := by rw [← wbtw_rotate_iff R x, and_iff_right h] theorem Sbtw.not_swap_left [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) : ¬Wbtw R y x z := fun hs => h.left_ne (h.wbtw.swap_left_iff.1 hs) theorem Sbtw.not_swap_right [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) : ¬Wbtw R x z y := fun hs => h.ne_right (h.wbtw.swap_right_iff.1 hs) theorem Sbtw.not_rotate [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) : ¬Wbtw R z x y := fun hs => h.left_ne (h.wbtw.rotate_iff.1 hs) @[simp] theorem wbtw_lineMap_iff [NoZeroSMulDivisors R V] {x y : P} {r : R} : Wbtw R x (lineMap x y r) y ↔ x = y ∨ r ∈ Set.Icc (0 : R) 1 := by by_cases hxy : x = y · rw [hxy, lineMap_same_apply] simp rw [or_iff_right hxy, Wbtw, affineSegment, (lineMap_injective R hxy).mem_set_image] @[simp] theorem sbtw_lineMap_iff [NoZeroSMulDivisors R V] {x y : P} {r : R} : Sbtw R x (lineMap x y r) y ↔ x ≠ y ∧ r ∈ Set.Ioo (0 : R) 1 := by rw [sbtw_iff_mem_image_Ioo_and_ne, and_comm, and_congr_right] intro hxy rw [(lineMap_injective R hxy).mem_set_image] @[simp] theorem wbtw_mul_sub_add_iff [NoZeroDivisors R] {x y r : R} : Wbtw R x (r * (y - x) + x) y ↔ x = y ∨ r ∈ Set.Icc (0 : R) 1 := wbtw_lineMap_iff @[simp] theorem sbtw_mul_sub_add_iff [NoZeroDivisors R] {x y r : R} : Sbtw R x (r * (y - x) + x) y ↔ x ≠ y ∧ r ∈ Set.Ioo (0 : R) 1 := sbtw_lineMap_iff omit [IsOrderedRing R] in @[simp] theorem wbtw_zero_one_iff {x : R} : Wbtw R 0 x 1 ↔ x ∈ Set.Icc (0 : R) 1 := by rw [Wbtw, affineSegment, Set.mem_image] simp_rw [lineMap_apply_ring] simp @[simp] theorem wbtw_one_zero_iff {x : R} : Wbtw R 1 x 0 ↔ x ∈ Set.Icc (0 : R) 1 := by rw [wbtw_comm, wbtw_zero_one_iff] omit [IsOrderedRing R] in @[simp] theorem sbtw_zero_one_iff {x : R} : Sbtw R 0 x 1 ↔ x ∈ Set.Ioo (0 : R) 1 := by rw [Sbtw, wbtw_zero_one_iff, Set.mem_Icc, Set.mem_Ioo] exact ⟨fun h => ⟨h.1.1.lt_of_ne (Ne.symm h.2.1), h.1.2.lt_of_ne h.2.2⟩, fun h => ⟨⟨h.1.le, h.2.le⟩, h.1.ne', h.2.ne⟩⟩ @[simp] theorem sbtw_one_zero_iff {x : R} : Sbtw R 1 x 0 ↔ x ∈ Set.Ioo (0 : R) 1 := by rw [sbtw_comm, sbtw_zero_one_iff] theorem Wbtw.trans_left {w x y z : P} (h₁ : Wbtw R w y z) (h₂ : Wbtw R w x y) : Wbtw R w x z := by rcases h₁ with ⟨t₁, ht₁, rfl⟩ rcases h₂ with ⟨t₂, ht₂, rfl⟩ refine ⟨t₂ * t₁, ⟨mul_nonneg ht₂.1 ht₁.1, mul_le_one₀ ht₂.2 ht₁.1 ht₁.2⟩, ?_⟩ rw [lineMap_apply, lineMap_apply, lineMap_vsub_left, smul_smul] theorem Wbtw.trans_right {w x y z : P} (h₁ : Wbtw R w x z) (h₂ : Wbtw R x y z) : Wbtw R w y z := by rw [wbtw_comm] at * exact h₁.trans_left h₂ theorem Wbtw.trans_sbtw_left [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w y z) (h₂ : Sbtw R w x y) : Sbtw R w x z := by refine ⟨h₁.trans_left h₂.wbtw, h₂.ne_left, ?_⟩ rintro rfl exact h₂.right_ne ((wbtw_swap_right_iff R w).1 ⟨h₁, h₂.wbtw⟩) theorem Wbtw.trans_sbtw_right [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w x z) (h₂ : Sbtw R x y z) : Sbtw R w y z := by rw [wbtw_comm] at * rw [sbtw_comm] at * exact h₁.trans_sbtw_left h₂ theorem Sbtw.trans_left [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w y z) (h₂ : Sbtw R w x y) : Sbtw R w x z := h₁.wbtw.trans_sbtw_left h₂ theorem Sbtw.trans_right [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w x z) (h₂ : Sbtw R x y z) : Sbtw R w y z := h₁.wbtw.trans_sbtw_right h₂ theorem Wbtw.trans_left_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w y z) (h₂ : Wbtw R w x y) (h : y ≠ z) : x ≠ z := by rintro rfl exact h (h₁.swap_right_iff.1 h₂) theorem Wbtw.trans_right_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w x z) (h₂ : Wbtw R x y z) (h : w ≠ x) : w ≠ y := by rintro rfl exact h (h₁.swap_left_iff.1 h₂) theorem Sbtw.trans_wbtw_left_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w y z) (h₂ : Wbtw R w x y) : x ≠ z := h₁.wbtw.trans_left_ne h₂ h₁.ne_right theorem Sbtw.trans_wbtw_right_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w x z) (h₂ : Wbtw R x y z) : w ≠ y := h₁.wbtw.trans_right_ne h₂ h₁.left_ne theorem Sbtw.affineCombination_of_mem_affineSpan_pair [NoZeroDivisors R] [NoZeroSMulDivisors R V] {ι : Type*} {p : ι → P} (ha : AffineIndependent R p) {w w₁ w₂ : ι → R} {s : Finset ι} (hw : ∑ i ∈ s, w i = 1) (hw₁ : ∑ i ∈ s, w₁ i = 1) (hw₂ : ∑ i ∈ s, w₂ i = 1) (h : s.affineCombination R p w ∈ line[R, s.affineCombination R p w₁, s.affineCombination R p w₂]) {i : ι} (his : i ∈ s) (hs : Sbtw R (w₁ i) (w i) (w₂ i)) : Sbtw R (s.affineCombination R p w₁) (s.affineCombination R p w) (s.affineCombination R p w₂) := by rw [affineCombination_mem_affineSpan_pair ha hw hw₁ hw₂] at h rcases h with ⟨r, hr⟩ rw [hr i his, sbtw_mul_sub_add_iff] at hs change ∀ i ∈ s, w i = (r • (w₂ - w₁) + w₁) i at hr rw [s.affineCombination_congr hr fun _ _ => rfl] rw [← s.weightedVSub_vadd_affineCombination, s.weightedVSub_const_smul, ← s.affineCombination_vsub, ← lineMap_apply, sbtw_lineMap_iff, and_iff_left hs.2, ← @vsub_ne_zero V, s.affineCombination_vsub] intro hz have hw₁w₂ : (∑ i ∈ s, (w₁ - w₂) i) = 0 := by simp_rw [Pi.sub_apply, Finset.sum_sub_distrib, hw₁, hw₂, sub_self] refine hs.1 ?_ have ha' := ha s (w₁ - w₂) hw₁w₂ hz i his rwa [Pi.sub_apply, sub_eq_zero] at ha' end OrderedRing section StrictOrderedCommRing variable [CommRing R] [PartialOrder R] [IsStrictOrderedRing R] [AddCommGroup V] [Module R V] [AddTorsor V P] variable {R}	theorem Wbtw.sameRay_vsub {x y z : P} (h : Wbtw R x y z) : SameRay R (y -ᵥ x) (z -ᵥ y) := by rcases h with ⟨t, ⟨ht0, ht1⟩, rfl⟩ simp_rw [lineMap_apply] rcases ht0.lt_or_eq with (ht0' \| rfl); swap; · simp	Mathlib/Analysis/Convex/Between.lean	498	501
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl -/ import Mathlib.Data.Bool.Basic import Mathlib.Order.Monotone.Basic import Mathlib.Order.ULift import Mathlib.Tactic.GCongr.CoreAttrs /-! # (Semi-)lattices Semilattices are partially ordered sets with join (least upper bound, or `sup`) or meet (greatest lower bound, or `inf`) operations. Lattices are posets that are both join-semilattices and meet-semilattices. Distributive lattices are lattices which satisfy any of four equivalent distributivity properties, of `sup` over `inf`, on the left or on the right. ## Main declarations * `SemilatticeSup`: a type class for join semilattices * `SemilatticeSup.mk'`: an alternative constructor for `SemilatticeSup` via proofs that `⊔` is commutative, associative and idempotent. * `SemilatticeInf`: a type class for meet semilattices * `SemilatticeSup.mk'`: an alternative constructor for `SemilatticeInf` via proofs that `⊓` is commutative, associative and idempotent. * `Lattice`: a type class for lattices * `Lattice.mk'`: an alternative constructor for `Lattice` via proofs that `⊔` and `⊓` are commutative, associative and satisfy a pair of "absorption laws". * `DistribLattice`: a type class for distributive lattices. ## Notations * `a ⊔ b`: the supremum or join of `a` and `b` * `a ⊓ b`: the infimum or meet of `a` and `b` ## TODO * (Semi-)lattice homomorphisms * Alternative constructors for distributive lattices from the other distributive properties ## Tags semilattice, lattice -/ /-- See if the term is `a ⊂ b` and the goal is `a ⊆ b`. -/ @[gcongr_forward] def exactSubsetOfSSubset : Mathlib.Tactic.GCongr.ForwardExt where eval h goal := do goal.assignIfDefEq (← Lean.Meta.mkAppM ``subset_of_ssubset #[h]) universe u v w variable {α : Type u} {β : Type v} /-! ### Join-semilattices -/ -- TODO: automatic construction of dual definitions / theorems /-- A `SemilatticeSup` is a join-semilattice, that is, a partial order with a join (a.k.a. lub / least upper bound, sup / supremum) operation `⊔` which is the least element larger than both factors. -/ class SemilatticeSup (α : Type u) extends PartialOrder α where /-- The binary supremum, used to derive `Max α` -/ sup : α → α → α /-- The supremum is an upper bound on the first argument -/ protected le_sup_left : ∀ a b : α, a ≤ sup a b /-- The supremum is an upper bound on the second argument -/ protected le_sup_right : ∀ a b : α, b ≤ sup a b /-- The supremum is the least upper bound -/ protected sup_le : ∀ a b c : α, a ≤ c → b ≤ c → sup a b ≤ c instance SemilatticeSup.toMax [SemilatticeSup α] : Max α where max a b := SemilatticeSup.sup a b /-- A type with a commutative, associative and idempotent binary `sup` operation has the structure of a join-semilattice. The partial order is defined so that `a ≤ b` unfolds to `a ⊔ b = b`; cf. `sup_eq_right`. -/ def SemilatticeSup.mk' {α : Type} [Max α] (sup_comm : ∀ a b : α, a ⊔ b = b ⊔ a) (sup_assoc : ∀ a b c : α, a ⊔ b ⊔ c = a ⊔ (b ⊔ c)) (sup_idem : ∀ a : α, a ⊔ a = a) : SemilatticeSup α where sup := (· ⊔ ·) le a b := a ⊔ b = b le_refl := sup_idem le_trans a b c hab hbc := by rw [← hbc, ← sup_assoc, hab] le_antisymm a b hab hba := by rwa [← hba, sup_comm] le_sup_left a b := by rw [← sup_assoc, sup_idem] le_sup_right a b := by rw [sup_comm, sup_assoc, sup_idem] sup_le a b c hac hbc := by rwa [sup_assoc, hbc] section SemilatticeSup variable [SemilatticeSup α] {a b c d : α} @[simp] theorem le_sup_left : a ≤ a ⊔ b := SemilatticeSup.le_sup_left a b @[simp] theorem le_sup_right : b ≤ a ⊔ b := SemilatticeSup.le_sup_right a b theorem le_sup_of_le_left (h : c ≤ a) : c ≤ a ⊔ b := le_trans h le_sup_left theorem le_sup_of_le_right (h : c ≤ b) : c ≤ a ⊔ b := le_trans h le_sup_right theorem lt_sup_of_lt_left (h : c < a) : c < a ⊔ b := h.trans_le le_sup_left theorem lt_sup_of_lt_right (h : c < b) : c < a ⊔ b := h.trans_le le_sup_right theorem sup_le : a ≤ c → b ≤ c → a ⊔ b ≤ c := SemilatticeSup.sup_le a b c @[simp] theorem sup_le_iff : a ⊔ b ≤ c ↔ a ≤ c ∧ b ≤ c := ⟨fun h : a ⊔ b ≤ c => ⟨le_trans le_sup_left h, le_trans le_sup_right h⟩, fun ⟨h₁, h₂⟩ => sup_le h₁ h₂⟩ @[simp] theorem sup_eq_left : a ⊔ b = a ↔ b ≤ a := le_antisymm_iff.trans <\| by simp [le_rfl] @[simp] theorem sup_eq_right : a ⊔ b = b ↔ a ≤ b := le_antisymm_iff.trans <\| by simp [le_rfl] @[simp] theorem left_eq_sup : a = a ⊔ b ↔ b ≤ a := eq_comm.trans sup_eq_left @[simp] theorem right_eq_sup : b = a ⊔ b ↔ a ≤ b := eq_comm.trans sup_eq_right alias ⟨_, sup_of_le_left⟩ := sup_eq_left alias ⟨le_of_sup_eq, sup_of_le_right⟩ := sup_eq_right attribute [simp] sup_of_le_left sup_of_le_right @[simp] theorem left_lt_sup : a < a ⊔ b ↔ ¬b ≤ a := le_sup_left.lt_iff_ne.trans <\| not_congr left_eq_sup @[simp] theorem right_lt_sup : b < a ⊔ b ↔ ¬a ≤ b := le_sup_right.lt_iff_ne.trans <\| not_congr right_eq_sup theorem left_or_right_lt_sup (h : a ≠ b) : a < a ⊔ b ∨ b < a ⊔ b := h.not_le_or_not_le.symm.imp left_lt_sup.2 right_lt_sup.2 theorem le_iff_exists_sup : a ≤ b ↔ ∃ c, b = a ⊔ c := by constructor · intro h exact ⟨b, (sup_eq_right.mpr h).symm⟩ · rintro ⟨c, rfl : _ = _ ⊔ _⟩ exact le_sup_left @[gcongr] theorem sup_le_sup (h₁ : a ≤ b) (h₂ : c ≤ d) : a ⊔ c ≤ b ⊔ d := sup_le (le_sup_of_le_left h₁) (le_sup_of_le_right h₂) @[gcongr] theorem sup_le_sup_left (h₁ : a ≤ b) (c) : c ⊔ a ≤ c ⊔ b := sup_le_sup le_rfl h₁ @[gcongr] theorem sup_le_sup_right (h₁ : a ≤ b) (c) : a ⊔ c ≤ b ⊔ c := sup_le_sup h₁ le_rfl theorem sup_idem (a : α) : a ⊔ a = a := by simp instance : Std.IdempotentOp (α := α) (· ⊔ ·) := ⟨sup_idem⟩ theorem sup_comm (a b : α) : a ⊔ b = b ⊔ a := by apply le_antisymm <;> simp instance : Std.Commutative (α := α) (· ⊔ ·) := ⟨sup_comm⟩ theorem sup_assoc (a b c : α) : a ⊔ b ⊔ c = a ⊔ (b ⊔ c) := eq_of_forall_ge_iff fun x => by simp only [sup_le_iff]; rw [and_assoc] instance : Std.Associative (α := α) (· ⊔ ·) := ⟨sup_assoc⟩ theorem sup_left_right_swap (a b c : α) : a ⊔ b ⊔ c = c ⊔ b ⊔ a := by rw [sup_comm, sup_comm a, sup_assoc] theorem sup_left_idem (a b : α) : a ⊔ (a ⊔ b) = a ⊔ b := by simp theorem sup_right_idem (a b : α) : a ⊔ b ⊔ b = a ⊔ b := by simp theorem sup_left_comm (a b c : α) : a ⊔ (b ⊔ c) = b ⊔ (a ⊔ c) := by rw [← sup_assoc, ← sup_assoc, @sup_comm α _ a] theorem sup_right_comm (a b c : α) : a ⊔ b ⊔ c = a ⊔ c ⊔ b := by rw [sup_assoc, sup_assoc, sup_comm b] theorem sup_sup_sup_comm (a b c d : α) : a ⊔ b ⊔ (c ⊔ d) = a ⊔ c ⊔ (b ⊔ d) := by rw [sup_assoc, sup_left_comm b, ← sup_assoc] theorem sup_sup_distrib_left (a b c : α) : a ⊔ (b ⊔ c) = a ⊔ b ⊔ (a ⊔ c) := by rw [sup_sup_sup_comm, sup_idem] theorem sup_sup_distrib_right (a b c : α) : a ⊔ b ⊔ c = a ⊔ c ⊔ (b ⊔ c) := by rw [sup_sup_sup_comm, sup_idem] theorem sup_congr_left (hb : b ≤ a ⊔ c) (hc : c ≤ a ⊔ b) : a ⊔ b = a ⊔ c := (sup_le le_sup_left hb).antisymm <\| sup_le le_sup_left hc theorem sup_congr_right (ha : a ≤ b ⊔ c) (hb : b ≤ a ⊔ c) : a ⊔ c = b ⊔ c := (sup_le ha le_sup_right).antisymm <\| sup_le hb le_sup_right theorem sup_eq_sup_iff_left : a ⊔ b = a ⊔ c ↔ b ≤ a ⊔ c ∧ c ≤ a ⊔ b := ⟨fun h => ⟨h ▸ le_sup_right, h.symm ▸ le_sup_right⟩, fun h => sup_congr_left h.1 h.2⟩ theorem sup_eq_sup_iff_right : a ⊔ c = b ⊔ c ↔ a ≤ b ⊔ c ∧ b ≤ a ⊔ c := ⟨fun h => ⟨h ▸ le_sup_left, h.symm ▸ le_sup_left⟩, fun h => sup_congr_right h.1 h.2⟩ theorem Ne.lt_sup_or_lt_sup (hab : a ≠ b) : a < a ⊔ b ∨ b < a ⊔ b := hab.symm.not_le_or_not_le.imp left_lt_sup.2 right_lt_sup.2 /-- If `f` is monotone, `g` is antitone, and `f ≤ g`, then for all `a`, `b` we have `f a ≤ g b`. -/ theorem Monotone.forall_le_of_antitone {β : Type} [Preorder β] {f g : α → β} (hf : Monotone f) (hg : Antitone g) (h : f ≤ g) (m n : α) : f m ≤ g n := calc f m ≤ f (m ⊔ n) := hf le_sup_left _ ≤ g (m ⊔ n) := h _ _ ≤ g n := hg le_sup_right theorem SemilatticeSup.ext_sup {α} {A B : SemilatticeSup α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) (x y : α) : (haveI := A; x ⊔ y) = x ⊔ y := eq_of_forall_ge_iff fun c => by simp only [sup_le_iff]; rw [← H, @sup_le_iff α A, H, H] theorem SemilatticeSup.ext {α} {A B : SemilatticeSup α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) : A = B := by cases A cases B cases PartialOrder.ext H congr ext; apply SemilatticeSup.ext_sup H theorem ite_le_sup (s s' : α) (P : Prop) [Decidable P] : ite P s s' ≤ s ⊔ s' := if h : P then (if_pos h).trans_le le_sup_left else (if_neg h).trans_le le_sup_right end SemilatticeSup /-! ### Meet-semilattices -/ /-- A `SemilatticeInf` is a meet-semilattice, that is, a partial order with a meet (a.k.a. glb / greatest lower bound, inf / infimum) operation `⊓` which is the greatest element smaller than both factors. -/ class SemilatticeInf (α : Type u) extends PartialOrder α where /-- The binary infimum, used to derive `Min α` -/ inf : α → α → α /-- The infimum is a lower bound on the first argument -/ protected inf_le_left : ∀ a b : α, inf a b ≤ a /-- The infimum is a lower bound on the second argument -/ protected inf_le_right : ∀ a b : α, inf a b ≤ b /-- The infimum is the greatest lower bound -/ protected le_inf : ∀ a b c : α, a ≤ b → a ≤ c → a ≤ inf b c instance SemilatticeInf.toMin [SemilatticeInf α] : Min α where min a b := SemilatticeInf.inf a b instance OrderDual.instSemilatticeSup (α) [SemilatticeInf α] : SemilatticeSup αᵒᵈ where sup := @SemilatticeInf.inf α _ le_sup_left := @SemilatticeInf.inf_le_left α _ le_sup_right := @SemilatticeInf.inf_le_right α _ sup_le := fun _ _ _ hca hcb => @SemilatticeInf.le_inf α _ _ _ _ hca hcb instance OrderDual.instSemilatticeInf (α) [SemilatticeSup α] : SemilatticeInf αᵒᵈ where inf := @SemilatticeSup.sup α _ inf_le_left := @le_sup_left α _ inf_le_right := @le_sup_right α _ le_inf := fun _ _ _ hca hcb => @sup_le α _ _ _ _ hca hcb theorem SemilatticeSup.dual_dual (α : Type) [H : SemilatticeSup α] : OrderDual.instSemilatticeSup αᵒᵈ = H := SemilatticeSup.ext fun _ _ => Iff.rfl section SemilatticeInf variable [SemilatticeInf α] {a b c d : α} @[simp] theorem inf_le_left : a ⊓ b ≤ a := SemilatticeInf.inf_le_left a b @[simp] theorem inf_le_right : a ⊓ b ≤ b := SemilatticeInf.inf_le_right a b theorem le_inf : a ≤ b → a ≤ c → a ≤ b ⊓ c := SemilatticeInf.le_inf a b c theorem inf_le_of_left_le (h : a ≤ c) : a ⊓ b ≤ c := le_trans inf_le_left h theorem inf_le_of_right_le (h : b ≤ c) : a ⊓ b ≤ c := le_trans inf_le_right h theorem inf_lt_of_left_lt (h : a < c) : a ⊓ b < c := lt_of_le_of_lt inf_le_left h theorem inf_lt_of_right_lt (h : b < c) : a ⊓ b < c := lt_of_le_of_lt inf_le_right h @[simp] theorem le_inf_iff : a ≤ b ⊓ c ↔ a ≤ b ∧ a ≤ c := @sup_le_iff αᵒᵈ _ _ _ _ @[simp] theorem inf_eq_left : a ⊓ b = a ↔ a ≤ b := le_antisymm_iff.trans <\| by simp [le_rfl] @[simp] theorem inf_eq_right : a ⊓ b = b ↔ b ≤ a := le_antisymm_iff.trans <\| by simp [le_rfl] @[simp] theorem left_eq_inf : a = a ⊓ b ↔ a ≤ b := eq_comm.trans inf_eq_left @[simp] theorem right_eq_inf : b = a ⊓ b ↔ b ≤ a := eq_comm.trans inf_eq_right alias ⟨le_of_inf_eq, inf_of_le_left⟩ := inf_eq_left alias ⟨_, inf_of_le_right⟩ := inf_eq_right attribute [simp] inf_of_le_left inf_of_le_right @[simp] theorem inf_lt_left : a ⊓ b < a ↔ ¬a ≤ b := @left_lt_sup αᵒᵈ _ _ _ @[simp] theorem inf_lt_right : a ⊓ b < b ↔ ¬b ≤ a := @right_lt_sup αᵒᵈ _ _ _ theorem inf_lt_left_or_right (h : a ≠ b) : a ⊓ b < a ∨ a ⊓ b < b := @left_or_right_lt_sup αᵒᵈ _ _ _ h @[gcongr] theorem inf_le_inf (h₁ : a ≤ b) (h₂ : c ≤ d) : a ⊓ c ≤ b ⊓ d := @sup_le_sup αᵒᵈ _ _ _ _ _ h₁ h₂ @[gcongr] theorem inf_le_inf_right (a : α) {b c : α} (h : b ≤ c) : b ⊓ a ≤ c ⊓ a := inf_le_inf h le_rfl @[gcongr] theorem inf_le_inf_left (a : α) {b c : α} (h : b ≤ c) : a ⊓ b ≤ a ⊓ c := inf_le_inf le_rfl h theorem inf_idem (a : α) : a ⊓ a = a := by simp instance : Std.IdempotentOp (α := α) (· ⊓ ·) := ⟨inf_idem⟩ theorem inf_comm (a b : α) : a ⊓ b = b ⊓ a := @sup_comm αᵒᵈ _ _ _ instance : Std.Commutative (α := α) (· ⊓ ·) := ⟨inf_comm⟩ theorem inf_assoc (a b c : α) : a ⊓ b ⊓ c = a ⊓ (b ⊓ c) := @sup_assoc αᵒᵈ _ _ _ _ instance : Std.Associative (α := α) (· ⊓ ·) := ⟨inf_assoc⟩ theorem inf_left_right_swap (a b c : α) : a ⊓ b ⊓ c = c ⊓ b ⊓ a := @sup_left_right_swap αᵒᵈ _ _ _ _ theorem inf_left_idem (a b : α) : a ⊓ (a ⊓ b) = a ⊓ b := by simp theorem inf_right_idem (a b : α) : a ⊓ b ⊓ b = a ⊓ b := by simp theorem inf_left_comm (a b c : α) : a ⊓ (b ⊓ c) = b ⊓ (a ⊓ c) := @sup_left_comm αᵒᵈ _ a b c theorem inf_right_comm (a b c : α) : a ⊓ b ⊓ c = a ⊓ c ⊓ b := @sup_right_comm αᵒᵈ _ a b c theorem inf_inf_inf_comm (a b c d : α) : a ⊓ b ⊓ (c ⊓ d) = a ⊓ c ⊓ (b ⊓ d) := @sup_sup_sup_comm αᵒᵈ _ _ _ _ _ theorem inf_inf_distrib_left (a b c : α) : a ⊓ (b ⊓ c) = a ⊓ b ⊓ (a ⊓ c) := @sup_sup_distrib_left αᵒᵈ _ _ _ _ theorem inf_inf_distrib_right (a b c : α) : a ⊓ b ⊓ c = a ⊓ c ⊓ (b ⊓ c) := @sup_sup_distrib_right αᵒᵈ _ _ _ _ theorem inf_congr_left (hb : a ⊓ c ≤ b) (hc : a ⊓ b ≤ c) : a ⊓ b = a ⊓ c := @sup_congr_left αᵒᵈ _ _ _ _ hb hc theorem inf_congr_right (h1 : b ⊓ c ≤ a) (h2 : a ⊓ c ≤ b) : a ⊓ c = b ⊓ c := @sup_congr_right αᵒᵈ _ _ _ _ h1 h2 theorem inf_eq_inf_iff_left : a ⊓ b = a ⊓ c ↔ a ⊓ c ≤ b ∧ a ⊓ b ≤ c := @sup_eq_sup_iff_left αᵒᵈ _ _ _ _ theorem inf_eq_inf_iff_right : a ⊓ c = b ⊓ c ↔ b ⊓ c ≤ a ∧ a ⊓ c ≤ b := @sup_eq_sup_iff_right αᵒᵈ _ _ _ _ theorem Ne.inf_lt_or_inf_lt : a ≠ b → a ⊓ b < a ∨ a ⊓ b < b := @Ne.lt_sup_or_lt_sup αᵒᵈ _ _ _ theorem SemilatticeInf.ext_inf {α} {A B : SemilatticeInf α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) (x y : α) : (haveI := A; x ⊓ y) = x ⊓ y := eq_of_forall_le_iff fun c => by simp only [le_inf_iff]; rw [← H, @le_inf_iff α A, H, H] theorem SemilatticeInf.ext {α} {A B : SemilatticeInf α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) : A = B := by cases A cases B cases PartialOrder.ext H congr ext; apply SemilatticeInf.ext_inf H theorem SemilatticeInf.dual_dual (α : Type) [H : SemilatticeInf α] : OrderDual.instSemilatticeInf αᵒᵈ = H := SemilatticeInf.ext fun _ _ => Iff.rfl theorem inf_le_ite (s s' : α) (P : Prop) [Decidable P] : s ⊓ s' ≤ ite P s s' := @ite_le_sup αᵒᵈ _ _ _ _ _ end SemilatticeInf /-- A type with a commutative, associative and idempotent binary `inf` operation has the structure of a meet-semilattice. The partial order is defined so that `a ≤ b` unfolds to `b ⊓ a = a`; cf. `inf_eq_right`. -/ def SemilatticeInf.mk' {α : Type} [Min α] (inf_comm : ∀ a b : α, a ⊓ b = b ⊓ a) (inf_assoc : ∀ a b c : α, a ⊓ b ⊓ c = a ⊓ (b ⊓ c)) (inf_idem : ∀ a : α, a ⊓ a = a) : SemilatticeInf α := by haveI : SemilatticeSup αᵒᵈ := SemilatticeSup.mk' inf_comm inf_assoc inf_idem haveI i := OrderDual.instSemilatticeInf αᵒᵈ exact i /-! ### Lattices -/ /-- A lattice is a join-semilattice which is also a meet-semilattice. -/ class Lattice (α : Type u) extends SemilatticeSup α, SemilatticeInf α instance OrderDual.instLattice (α) [Lattice α] : Lattice αᵒᵈ where /-- The partial orders from `SemilatticeSup_mk'` and `SemilatticeInf_mk'` agree if `sup` and `inf` satisfy the lattice absorption laws `sup_inf_self` (`a ⊔ a ⊓ b = a`) and `inf_sup_self` (`a ⊓ (a ⊔ b) = a`). -/ theorem semilatticeSup_mk'_partialOrder_eq_semilatticeInf_mk'_partialOrder {α : Type} [Max α] [Min α] (sup_comm : ∀ a b : α, a ⊔ b = b ⊔ a) (sup_assoc : ∀ a b c : α, a ⊔ b ⊔ c = a ⊔ (b ⊔ c)) (sup_idem : ∀ a : α, a ⊔ a = a) (inf_comm : ∀ a b : α, a ⊓ b = b ⊓ a) (inf_assoc : ∀ a b c : α, a ⊓ b ⊓ c = a ⊓ (b ⊓ c)) (inf_idem : ∀ a : α, a ⊓ a = a) (sup_inf_self : ∀ a b : α, a ⊔ a ⊓ b = a) (inf_sup_self : ∀ a b : α, a ⊓ (a ⊔ b) = a) : @SemilatticeSup.toPartialOrder _ (SemilatticeSup.mk' sup_comm sup_assoc sup_idem) = @SemilatticeInf.toPartialOrder _ (SemilatticeInf.mk' inf_comm inf_assoc inf_idem) := PartialOrder.ext fun a b => show a ⊔ b = b ↔ b ⊓ a = a from ⟨fun h => by rw [← h, inf_comm, inf_sup_self], fun h => by rw [← h, sup_comm, sup_inf_self]⟩ /-- A type with a pair of commutative and associative binary operations which satisfy two absorption laws relating the two operations has the structure of a lattice. The partial order is defined so that `a ≤ b` unfolds to `a ⊔ b = b`; cf. `sup_eq_right`. -/ def Lattice.mk' {α : Type} [Max α] [Min α] (sup_comm : ∀ a b : α, a ⊔ b = b ⊔ a) (sup_assoc : ∀ a b c : α, a ⊔ b ⊔ c = a ⊔ (b ⊔ c)) (inf_comm : ∀ a b : α, a ⊓ b = b ⊓ a) (inf_assoc : ∀ a b c : α, a ⊓ b ⊓ c = a ⊓ (b ⊓ c)) (sup_inf_self : ∀ a b : α, a ⊔ a ⊓ b = a) (inf_sup_self : ∀ a b : α, a ⊓ (a ⊔ b) = a) : Lattice α := have sup_idem : ∀ b : α, b ⊔ b = b := fun b => calc b ⊔ b = b ⊔ b ⊓ (b ⊔ b) := by rw [inf_sup_self] _ = b := by rw [sup_inf_self] have inf_idem : ∀ b : α, b ⊓ b = b := fun b => calc b ⊓ b = b ⊓ (b ⊔ b ⊓ b) := by rw [sup_inf_self] _ = b := by rw [inf_sup_self] let semilatt_inf_inst := SemilatticeInf.mk' inf_comm inf_assoc inf_idem let semilatt_sup_inst := SemilatticeSup.mk' sup_comm sup_assoc sup_idem have partial_order_eq : @SemilatticeSup.toPartialOrder _ semilatt_sup_inst = @SemilatticeInf.toPartialOrder _ semilatt_inf_inst := semilatticeSup_mk'_partialOrder_eq_semilatticeInf_mk'_partialOrder _ _ _ _ _ _ sup_inf_self inf_sup_self { semilatt_sup_inst, semilatt_inf_inst with inf_le_left := fun a b => by rw [partial_order_eq] apply inf_le_left, inf_le_right := fun a b => by rw [partial_order_eq] apply inf_le_right, le_inf := fun a b c => by rw [partial_order_eq] apply le_inf } section Lattice variable [Lattice α] {a b c : α} theorem inf_le_sup : a ⊓ b ≤ a ⊔ b := inf_le_left.trans le_sup_left theorem sup_le_inf : a ⊔ b ≤ a ⊓ b ↔ a = b := by simp [le_antisymm_iff, and_comm] @[simp] lemma inf_eq_sup : a ⊓ b = a ⊔ b ↔ a = b := by rw [← inf_le_sup.ge_iff_eq, sup_le_inf] @[simp] lemma sup_eq_inf : a ⊔ b = a ⊓ b ↔ a = b := eq_comm.trans inf_eq_sup @[simp] lemma inf_lt_sup : a ⊓ b < a ⊔ b ↔ a ≠ b := by rw [inf_le_sup.lt_iff_ne, Ne, inf_eq_sup] lemma inf_eq_and_sup_eq_iff : a ⊓ b = c ∧ a ⊔ b = c ↔ a = c ∧ b = c := by refine ⟨fun h ↦ ?_, ?_⟩ · obtain rfl := sup_eq_inf.1 (h.2.trans h.1.symm) simpa using h · rintro ⟨rfl, rfl⟩ exact ⟨inf_idem _, sup_idem _⟩ /-! #### Distributivity laws -/ -- TODO: better names? theorem sup_inf_le : a ⊔ b ⊓ c ≤ (a ⊔ b) ⊓ (a ⊔ c) := le_inf (sup_le_sup_left inf_le_left _) (sup_le_sup_left inf_le_right _) theorem le_inf_sup : a ⊓ b ⊔ a ⊓ c ≤ a ⊓ (b ⊔ c) := sup_le (inf_le_inf_left _ le_sup_left) (inf_le_inf_left _ le_sup_right) theorem inf_sup_self : a ⊓ (a ⊔ b) = a := by simp theorem sup_inf_self : a ⊔ a ⊓ b = a := by simp theorem sup_eq_iff_inf_eq : a ⊔ b = b ↔ a ⊓ b = a := by rw [sup_eq_right, ← inf_eq_left] theorem Lattice.ext {α} {A B : Lattice α} (H : ∀ x y : α, (haveI := A; x ≤ y) ↔ x ≤ y) : A = B := by cases A cases B cases SemilatticeSup.ext H cases SemilatticeInf.ext H congr end Lattice /-! ### Distributive lattices -/ /-- A distributive lattice is a lattice that satisfies any of four equivalent distributive properties (of `sup` over `inf` or `inf` over `sup`, on the left or right). The definition here chooses `le_sup_inf`: `(x ⊔ y) ⊓ (x ⊔ z) ≤ x ⊔ (y ⊓ z)`. To prove distributivity from the dual law, use `DistribLattice.of_inf_sup_le`. A classic example of a distributive lattice is the lattice of subsets of a set, and in fact this example is generic in the sense that every distributive lattice is realizable as a sublattice of a powerset lattice. -/ class DistribLattice (α) extends Lattice α where /-- The infimum distributes over the supremum -/ protected le_sup_inf : ∀ x y z : α, (x ⊔ y) ⊓ (x ⊔ z) ≤ x ⊔ y ⊓ z section DistribLattice variable [DistribLattice α] {x y z : α} theorem le_sup_inf : ∀ {x y z : α}, (x ⊔ y) ⊓ (x ⊔ z) ≤ x ⊔ y ⊓ z := fun {x y z} => DistribLattice.le_sup_inf x y z theorem sup_inf_left (a b c : α) : a ⊔ b ⊓ c = (a ⊔ b) ⊓ (a ⊔ c) := le_antisymm sup_inf_le le_sup_inf theorem sup_inf_right (a b c : α) : a ⊓ b ⊔ c = (a ⊔ c) ⊓ (b ⊔ c) := by simp only [sup_inf_left, sup_comm _ c, eq_self_iff_true] theorem inf_sup_left (a b c : α) : a ⊓ (b ⊔ c) = a ⊓ b ⊔ a ⊓ c := calc a ⊓ (b ⊔ c) = a ⊓ (a ⊔ c) ⊓ (b ⊔ c) := by rw [inf_sup_self] _ = a ⊓ (a ⊓ b ⊔ c) := by simp only [inf_assoc, sup_inf_right, eq_self_iff_true] _ = (a ⊔ a ⊓ b) ⊓ (a ⊓ b ⊔ c) := by rw [sup_inf_self] _ = (a ⊓ b ⊔ a) ⊓ (a ⊓ b ⊔ c) := by rw [sup_comm] _ = a ⊓ b ⊔ a ⊓ c := by rw [sup_inf_left] instance OrderDual.instDistribLattice (α : Type) [DistribLattice α] : DistribLattice αᵒᵈ where le_sup_inf _ _ _ := (inf_sup_left _ _ _).le theorem inf_sup_right (a b c : α) : (a ⊔ b) ⊓ c = a ⊓ c ⊔ b ⊓ c := by simp only [inf_sup_left, inf_comm _ c, eq_self_iff_true] theorem le_of_inf_le_sup_le (h₁ : x ⊓ z ≤ y ⊓ z) (h₂ : x ⊔ z ≤ y ⊔ z) : x ≤ y := calc x ≤ y ⊓ z ⊔ x := le_sup_right _ = (y ⊔ x) ⊓ (x ⊔ z) := by rw [sup_inf_right, sup_comm x] _ ≤ (y ⊔ x) ⊓ (y ⊔ z) := inf_le_inf_left _ h₂ _ = y ⊔ x ⊓ z := by rw [← sup_inf_left] _ ≤ y ⊔ y ⊓ z := sup_le_sup_left h₁ _ _ ≤ _ := sup_le (le_refl y) inf_le_left theorem eq_of_inf_eq_sup_eq {a b c : α} (h₁ : b ⊓ a = c ⊓ a) (h₂ : b ⊔ a = c ⊔ a) : b = c := le_antisymm (le_of_inf_le_sup_le (le_of_eq h₁) (le_of_eq h₂)) (le_of_inf_le_sup_le (le_of_eq h₁.symm) (le_of_eq h₂.symm)) end DistribLattice -- See note [reducible non-instances] /-- Prove distributivity of an existing lattice from the dual distributive law. -/ abbrev DistribLattice.ofInfSupLe [Lattice α] (inf_sup_le : ∀ a b c : α, a ⊓ (b ⊔ c) ≤ a ⊓ b ⊔ a ⊓ c) : DistribLattice α where le_sup_inf := (@OrderDual.instDistribLattice αᵒᵈ {inferInstanceAs (Lattice αᵒᵈ) with le_sup_inf := inf_sup_le}).le_sup_inf /-! ### Lattices derived from linear orders -/ -- see Note [lower instance priority] instance (priority := 100) LinearOrder.toLattice {α : Type u} [LinearOrder α] : Lattice α where sup := max inf := min le_sup_left := le_max_left; le_sup_right := le_max_right; sup_le _ _ _ := max_le inf_le_left := min_le_left; inf_le_right := min_le_right; le_inf _ _ _ := le_min section LinearOrder variable [LinearOrder α] {a b c d : α} @[deprecated "is syntactical" (since := "2024-11-13"), nolint synTaut] theorem sup_eq_max : a ⊔ b = max a b := rfl @[deprecated "is syntactical" (since := "2024-11-13"), nolint synTaut] theorem inf_eq_min : a ⊓ b = min a b := rfl theorem sup_ind (a b : α) {p : α → Prop} (ha : p a) (hb : p b) : p (a ⊔ b) := (IsTotal.total a b).elim (fun h : a ≤ b => by rwa [sup_eq_right.2 h]) fun h => by rwa [sup_eq_left.2 h] @[simp] theorem le_sup_iff : a ≤ b ⊔ c ↔ a ≤ b ∨ a ≤ c := by exact ⟨fun h => (le_total c b).imp (fun bc => by rwa [sup_eq_left.2 bc] at h) (fun bc => by rwa [sup_eq_right.2 bc] at h), fun h => h.elim le_sup_of_le_left le_sup_of_le_right⟩ @[simp] theorem lt_sup_iff : a < b ⊔ c ↔ a < b ∨ a < c := by exact ⟨fun h => (le_total c b).imp (fun bc => by rwa [sup_eq_left.2 bc] at h) (fun bc => by rwa [sup_eq_right.2 bc] at h), fun h => h.elim lt_sup_of_lt_left lt_sup_of_lt_right⟩ @[simp] theorem sup_lt_iff : b ⊔ c < a ↔ b < a ∧ c < a := ⟨fun h => ⟨le_sup_left.trans_lt h, le_sup_right.trans_lt h⟩, fun h => sup_ind (p := (· < a)) b c h.1 h.2⟩ theorem inf_ind (a b : α) {p : α → Prop} : p a → p b → p (a ⊓ b) := @sup_ind αᵒᵈ _ _ _ _ @[simp] theorem inf_le_iff : b ⊓ c ≤ a ↔ b ≤ a ∨ c ≤ a := @le_sup_iff αᵒᵈ _ _ _ _ @[simp] theorem inf_lt_iff : b ⊓ c < a ↔ b < a ∨ c < a := @lt_sup_iff αᵒᵈ _ _ _ _ @[simp] theorem lt_inf_iff : a < b ⊓ c ↔ a < b ∧ a < c := @sup_lt_iff αᵒᵈ _ _ _ _ variable (a b c d) theorem max_max_max_comm : max (max a b) (max c d) = max (max a c) (max b d) := sup_sup_sup_comm _ _ _ _ theorem min_min_min_comm : min (min a b) (min c d) = min (min a c) (min b d) := inf_inf_inf_comm _ _ _ _ end LinearOrder theorem sup_eq_maxDefault [SemilatticeSup α] [DecidableLE α] [IsTotal α (· ≤ ·)] : (· ⊔ ·) = (maxDefault : α → α → α) := by ext x y unfold maxDefault split_ifs with h' exacts [sup_of_le_right h', sup_of_le_left <\| (total_of (· ≤ ·) x y).resolve_left h'] theorem inf_eq_minDefault [SemilatticeInf α] [DecidableLE α] [IsTotal α (· ≤ ·)] : (· ⊓ ·) = (minDefault : α → α → α) := by ext x y unfold minDefault split_ifs with h' exacts [inf_of_le_left h', inf_of_le_right <\| (total_of (· ≤ ·) x y).resolve_left h'] /-- A lattice with total order is a linear order. See note [reducible non-instances]. -/ abbrev Lattice.toLinearOrder (α : Type u) [Lattice α] [DecidableEq α] [DecidableLE α] [DecidableLT α] [IsTotal α (· ≤ ·)] : LinearOrder α where toDecidableLE := ‹_› toDecidableEq := ‹_› toDecidableLT := ‹_› le_total := total_of (· ≤ ·) max_def := by exact congr_fun₂ sup_eq_maxDefault min_def := by exact congr_fun₂ inf_eq_minDefault -- see Note [lower instance priority] instance (priority := 100) {α : Type u} [LinearOrder α] : DistribLattice α where le_sup_inf _ b c := match le_total b c with \| Or.inl h => inf_le_of_left_le <\| sup_le_sup_left (le_inf (le_refl b) h) _ \| Or.inr h => inf_le_of_right_le <\| sup_le_sup_left (le_inf h (le_refl c)) _ instance : DistribLattice ℕ := inferInstance instance : Lattice ℤ := inferInstance /-! ### Dual order -/ open OrderDual @[simp] theorem ofDual_inf [Max α] (a b : αᵒᵈ) : ofDual (a ⊓ b) = ofDual a ⊔ ofDual b := rfl @[simp] theorem ofDual_sup [Min α] (a b : αᵒᵈ) : ofDual (a ⊔ b) = ofDual a ⊓ ofDual b := rfl @[simp] theorem toDual_inf [Min α] (a b : α) : toDual (a ⊓ b) = toDual a ⊔ toDual b := rfl @[simp] theorem toDual_sup [Max α] (a b : α) : toDual (a ⊔ b) = toDual a ⊓ toDual b := rfl section LinearOrder variable [LinearOrder α] @[simp] theorem ofDual_min (a b : αᵒᵈ) : ofDual (min a b) = max (ofDual a) (ofDual b) := rfl @[simp] theorem ofDual_max (a b : αᵒᵈ) : ofDual (max a b) = min (ofDual a) (ofDual b) := rfl @[simp] theorem toDual_min (a b : α) : toDual (min a b) = max (toDual a) (toDual b) := rfl @[simp] theorem toDual_max (a b : α) : toDual (max a b) = min (toDual a) (toDual b) := rfl end LinearOrder /-! ### Function lattices -/ namespace Pi variable {ι : Type} {α' : ι → Type} instance [∀ i, Max (α' i)] : Max (∀ i, α' i) := ⟨fun f g i => f i ⊔ g i⟩ @[simp] theorem sup_apply [∀ i, Max (α' i)] (f g : ∀ i, α' i) (i : ι) : (f ⊔ g) i = f i ⊔ g i := rfl theorem sup_def [∀ i, Max (α' i)] (f g : ∀ i, α' i) : f ⊔ g = fun i => f i ⊔ g i := rfl instance [∀ i, Min (α' i)] : Min (∀ i, α' i) := ⟨fun f g i => f i ⊓ g i⟩ @[simp] theorem inf_apply [∀ i, Min (α' i)] (f g : ∀ i, α' i) (i : ι) : (f ⊓ g) i = f i ⊓ g i := rfl theorem inf_def [∀ i, Min (α' i)] (f g : ∀ i, α' i) : f ⊓ g = fun i => f i ⊓ g i := rfl instance instSemilatticeSup [∀ i, SemilatticeSup (α' i)] : SemilatticeSup (∀ i, α' i) where sup x y i := x i ⊔ y i le_sup_left _ _ _ := le_sup_left le_sup_right _ _ _ := le_sup_right sup_le _ _ _ ac bc i := sup_le (ac i) (bc i) instance instSemilatticeInf [∀ i, SemilatticeInf (α' i)] : SemilatticeInf (∀ i, α' i) where inf x y i := x i ⊓ y i inf_le_left _ _ _ := inf_le_left inf_le_right _ _ _ := inf_le_right le_inf _ _ _ ac bc i := le_inf (ac i) (bc i) instance instLattice [∀ i, Lattice (α' i)] : Lattice (∀ i, α' i) where instance instDistribLattice [∀ i, DistribLattice (α' i)] : DistribLattice (∀ i, α' i) where le_sup_inf _ _ _ _ := le_sup_inf end Pi namespace Function variable {ι : Type} {π : ι → Type} [DecidableEq ι] -- Porting note: Dot notation on `Function.update` broke theorem update_sup [∀ i, SemilatticeSup (π i)] (f : ∀ i, π i) (i : ι) (a b : π i) : update f i (a ⊔ b) = update f i a ⊔ update f i b := funext fun j => by obtain rfl \| hji := eq_or_ne j i <;> simp [update_of_ne, ] theorem update_inf [∀ i, SemilatticeInf (π i)] (f : ∀ i, π i) (i : ι) (a b : π i) : update f i (a ⊓ b) = update f i a ⊓ update f i b := funext fun j => by obtain rfl \| hji := eq_or_ne j i <;> simp [update_of_ne, ] end Function /-! ### Monotone functions and lattices -/ namespace Monotone /-- Pointwise supremum of two monotone functions is a monotone function. -/ protected theorem sup [Preorder α] [SemilatticeSup β] {f g : α → β} (hf : Monotone f) (hg : Monotone g) : Monotone (f ⊔ g) := fun _ _ h => sup_le_sup (hf h) (hg h) /-- Pointwise infimum of two monotone functions is a monotone function. -/ protected theorem inf [Preorder α] [SemilatticeInf β] {f g : α → β} (hf : Monotone f) (hg : Monotone g) : Monotone (f ⊓ g) := fun _ _ h => inf_le_inf (hf h) (hg h) /-- Pointwise maximum of two monotone functions is a monotone function. -/ protected theorem max [Preorder α] [LinearOrder β] {f g : α → β} (hf : Monotone f) (hg : Monotone g) : Monotone fun x => max (f x) (g x) := hf.sup hg /-- Pointwise minimum of two monotone functions is a monotone function. -/ protected theorem min [Preorder α] [LinearOrder β] {f g : α → β} (hf : Monotone f) (hg : Monotone g) : Monotone fun x => min (f x) (g x) := hf.inf hg theorem le_map_sup [SemilatticeSup α] [SemilatticeSup β] {f : α → β} (h : Monotone f) (x y : α) : f x ⊔ f y ≤ f (x ⊔ y) := sup_le (h le_sup_left) (h le_sup_right) theorem map_inf_le [SemilatticeInf α] [SemilatticeInf β] {f : α → β} (h : Monotone f) (x y : α) : f (x ⊓ y) ≤ f x ⊓ f y := le_inf (h inf_le_left) (h inf_le_right) theorem of_map_inf_le_left [SemilatticeInf α] [Preorder β] {f : α → β} (h : ∀ x y, f (x ⊓ y) ≤ f x) : Monotone f := by intro x y hxy rw [← inf_eq_right.2 hxy] apply h theorem of_map_inf_le [SemilatticeInf α] [SemilatticeInf β] {f : α → β} (h : ∀ x y, f (x ⊓ y) ≤ f x ⊓ f y) : Monotone f := of_map_inf_le_left fun x y ↦ (h x y).trans inf_le_left theorem of_map_inf [SemilatticeInf α] [SemilatticeInf β] {f : α → β} (h : ∀ x y, f (x ⊓ y) = f x ⊓ f y) : Monotone f := of_map_inf_le fun x y ↦ (h x y).le theorem of_left_le_map_sup [SemilatticeSup α] [Preorder β] {f : α → β} (h : ∀ x y, f x ≤ f (x ⊔ y)) : Monotone f := monotone_dual_iff.1 <\| of_map_inf_le_left h theorem of_le_map_sup [SemilatticeSup α] [SemilatticeSup β] {f : α → β} (h : ∀ x y, f x ⊔ f y ≤ f (x ⊔ y)) : Monotone f := monotone_dual_iff.mp <\| of_map_inf_le h theorem of_map_sup [SemilatticeSup α] [SemilatticeSup β] {f : α → β} (h : ∀ x y, f (x ⊔ y) = f x ⊔ f y) : Monotone f := (@of_map_inf (OrderDual α) (OrderDual β) _ _ _ h).dual variable [LinearOrder α] theorem map_sup [SemilatticeSup β] {f : α → β} (hf : Monotone f) (x y : α) : f (x ⊔ y) = f x ⊔ f y := (IsTotal.total x y).elim (fun h : x ≤ y => by simp only [h, hf h, sup_of_le_right]) fun h => by simp only [h, hf h, sup_of_le_left] theorem map_inf [SemilatticeInf β] {f : α → β} (hf : Monotone f) (x y : α) : f (x ⊓ y) = f x ⊓ f y := hf.dual.map_sup _ _ end Monotone namespace MonotoneOn variable {f : α → β} {s : Set α} {x y : α} /-- Pointwise supremum of two monotone functions is a monotone function. -/ protected theorem sup [Preorder α] [SemilatticeSup β] {f g : α → β} {s : Set α} (hf : MonotoneOn f s) (hg : MonotoneOn g s) : MonotoneOn (f ⊔ g) s := fun _ hx _ hy h => sup_le_sup (hf hx hy h) (hg hx hy h) /-- Pointwise infimum of two monotone functions is a monotone function. -/ protected theorem inf [Preorder α] [SemilatticeInf β] {f g : α → β} {s : Set α} (hf : MonotoneOn f s) (hg : MonotoneOn g s) : MonotoneOn (f ⊓ g) s := (hf.dual.sup hg.dual).dual /-- Pointwise maximum of two monotone functions is a monotone function. -/ protected theorem max [Preorder α] [LinearOrder β] {f g : α → β} {s : Set α} (hf : MonotoneOn f s) (hg : MonotoneOn g s) : MonotoneOn (fun x => max (f x) (g x)) s := hf.sup hg /-- Pointwise minimum of two monotone functions is a monotone function. -/ protected theorem min [Preorder α] [LinearOrder β] {f g : α → β} {s : Set α} (hf : MonotoneOn f s) (hg : MonotoneOn g s) : MonotoneOn (fun x => min (f x) (g x)) s := hf.inf hg theorem of_map_inf [SemilatticeInf α] [SemilatticeInf β] (h : ∀ x ∈ s, ∀ y ∈ s, f (x ⊓ y) = f x ⊓ f y) : MonotoneOn f s := fun x hx y hy hxy => inf_eq_left.1 <\| by rw [← h _ hx _ hy, inf_eq_left.2 hxy] theorem of_map_sup [SemilatticeSup α] [SemilatticeSup β] (h : ∀ x ∈ s, ∀ y ∈ s, f (x ⊔ y) = f x ⊔ f y) : MonotoneOn f s := (@of_map_inf αᵒᵈ βᵒᵈ _ _ _ _ h).dual variable [LinearOrder α] theorem map_sup [SemilatticeSup β] (hf : MonotoneOn f s) (hx : x ∈ s) (hy : y ∈ s) : f (x ⊔ y) = f x ⊔ f y := by cases le_total x y <;> have := hf ?_ ?_ ‹_› <;> first \| assumption \| simp only [, sup_of_le_left, sup_of_le_right] theorem map_inf [SemilatticeInf β] (hf : MonotoneOn f s) (hx : x ∈ s) (hy : y ∈ s) : f (x ⊓ y) = f x ⊓ f y := hf.dual.map_sup hx hy end MonotoneOn namespace Antitone /-- Pointwise supremum of two monotone functions is a monotone function. -/ protected theorem sup [Preorder α] [SemilatticeSup β] {f g : α → β} (hf : Antitone f) (hg : Antitone g) : Antitone (f ⊔ g) := fun _ _ h => sup_le_sup (hf h) (hg h) /-- Pointwise infimum of two monotone functions is a monotone function. -/ protected theorem inf [Preorder α] [SemilatticeInf β] {f g : α → β} (hf : Antitone f) (hg : Antitone g) : Antitone (f ⊓ g) := fun _ _ h => inf_le_inf (hf h) (hg h) /-- Pointwise maximum of two monotone functions is a monotone function. -/ protected theorem max [Preorder α] [LinearOrder β] {f g : α → β} (hf : Antitone f) (hg : Antitone g) : Antitone fun x => max (f x) (g x) := hf.sup hg /-- Pointwise minimum of two monotone functions is a monotone function. -/ protected theorem min [Preorder α] [LinearOrder β] {f g : α → β} (hf : Antitone f) (hg : Antitone g) : Antitone fun x => min (f x) (g x) := hf.inf hg theorem map_sup_le [SemilatticeSup α] [SemilatticeInf β] {f : α → β} (h : Antitone f) (x y : α) : f (x ⊔ y) ≤ f x ⊓ f y := h.dual_right.le_map_sup x y theorem le_map_inf [SemilatticeInf α] [SemilatticeSup β] {f : α → β} (h : Antitone f) (x y : α) : f x ⊔ f y ≤ f (x ⊓ y) := h.dual_right.map_inf_le x y variable [LinearOrder α] theorem map_sup [SemilatticeInf β] {f : α → β} (hf : Antitone f) (x y : α) : f (x ⊔ y) = f x ⊓ f y := hf.dual_right.map_sup x y theorem map_inf [SemilatticeSup β] {f : α → β} (hf : Antitone f) (x y : α) : f (x ⊓ y) = f x ⊔ f y := hf.dual_right.map_inf x y end Antitone namespace AntitoneOn variable {f : α → β} {s : Set α} {x y : α} /-- Pointwise supremum of two antitone functions is an antitone function. -/ protected theorem sup [Preorder α] [SemilatticeSup β] {f g : α → β} {s : Set α} (hf : AntitoneOn f s) (hg : AntitoneOn g s) : AntitoneOn (f ⊔ g) s := fun _ hx _ hy h => sup_le_sup (hf hx hy h) (hg hx hy h) /-- Pointwise infimum of two antitone functions is an antitone function. -/ protected theorem inf [Preorder α] [SemilatticeInf β] {f g : α → β} {s : Set α} (hf : AntitoneOn f s) (hg : AntitoneOn g s) : AntitoneOn (f ⊓ g) s := (hf.dual.sup hg.dual).dual /-- Pointwise maximum of two antitone functions is an antitone function. -/ protected theorem max [Preorder α] [LinearOrder β] {f g : α → β} {s : Set α} (hf : AntitoneOn f s) (hg : AntitoneOn g s) : AntitoneOn (fun x => max (f x) (g x)) s := hf.sup hg /-- Pointwise minimum of two antitone functions is an antitone function. -/ protected theorem min [Preorder α] [LinearOrder β] {f g : α → β} {s : Set α} (hf : AntitoneOn f s) (hg : AntitoneOn g s) : AntitoneOn (fun x => min (f x) (g x)) s := hf.inf hg theorem of_map_inf [SemilatticeInf α] [SemilatticeSup β] (h : ∀ x ∈ s, ∀ y ∈ s, f (x ⊓ y) = f x ⊔ f y) : AntitoneOn f s := fun x hx y hy hxy => sup_eq_left.1 <\| by rw [← h _ hx _ hy, inf_eq_left.2 hxy] theorem of_map_sup [SemilatticeSup α] [SemilatticeInf β] (h : ∀ x ∈ s, ∀ y ∈ s, f (x ⊔ y) = f x ⊓ f y) : AntitoneOn f s := (@of_map_inf αᵒᵈ βᵒᵈ _ _ _ _ h).dual variable [LinearOrder α] theorem map_sup [SemilatticeInf β] (hf : AntitoneOn f s) (hx : x ∈ s) (hy : y ∈ s) : f (x ⊔ y) = f x ⊓ f y := by cases le_total x y <;> have := hf ?_ ?_ ‹_› <;> first \| assumption \| simp only [, sup_of_le_left, sup_of_le_right, inf_of_le_left, inf_of_le_right] theorem map_inf [SemilatticeSup β] (hf : AntitoneOn f s) (hx : x ∈ s) (hy : y ∈ s) : f (x ⊓ y) = f x ⊔ f y := hf.dual.map_sup hx hy end AntitoneOn /-! ### Products of (semi-)lattices -/ namespace Prod variable (α β) instance [Max α] [Max β] : Max (α × β) := ⟨fun p q => ⟨p.1 ⊔ q.1, p.2 ⊔ q.2⟩⟩	instance [Min α] [Min β] : Min (α × β) := ⟨fun p q => ⟨p.1 ⊓ q.1, p.2 ⊓ q.2⟩⟩	Mathlib/Order/Lattice.lean	1,072	1,075
/- Copyright (c) 2022 Moritz Doll. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Moritz Doll, Anatole Dedecker -/ import Mathlib.Analysis.LocallyConvex.Bounded import Mathlib.Analysis.Seminorm import Mathlib.Data.Real.Sqrt import Mathlib.Topology.Algebra.Equicontinuity import Mathlib.Topology.MetricSpace.Equicontinuity import Mathlib.Topology.Algebra.FilterBasis import Mathlib.Topology.Algebra.Module.LocallyConvex /-! # Topology induced by a family of seminorms ## Main definitions * `SeminormFamily.basisSets`: The set of open seminorm balls for a family of seminorms. * `SeminormFamily.moduleFilterBasis`: A module filter basis formed by the open balls. * `Seminorm.IsBounded`: A linear map `f : E →ₗ[𝕜] F` is bounded iff every seminorm in `F` can be bounded by a finite number of seminorms in `E`. ## Main statements * `WithSeminorms.toLocallyConvexSpace`: A space equipped with a family of seminorms is locally convex. * `WithSeminorms.firstCountable`: A space is first countable if it's topology is induced by a countable family of seminorms. ## Continuity of semilinear maps If `E` and `F` are topological vector space with the topology induced by a family of seminorms, then we have a direct method to prove that a linear map is continuous: * `Seminorm.continuous_from_bounded`: A bounded linear map `f : E →ₗ[𝕜] F` is continuous. If the topology of a space `E` is induced by a family of seminorms, then we can characterize von Neumann boundedness in terms of that seminorm family. Together with `LinearMap.continuous_of_locally_bounded` this gives general criterion for continuity. * `WithSeminorms.isVonNBounded_iff_finset_seminorm_bounded` * `WithSeminorms.isVonNBounded_iff_seminorm_bounded` * `WithSeminorms.image_isVonNBounded_iff_finset_seminorm_bounded` * `WithSeminorms.image_isVonNBounded_iff_seminorm_bounded` ## Tags seminorm, locally convex -/ open NormedField Set Seminorm TopologicalSpace Filter List open NNReal Pointwise Topology Uniformity variable {𝕜 𝕜₂ 𝕝 𝕝₂ E F G ι ι' : Type} section FilterBasis variable [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] variable (𝕜 E ι) /-- An abbreviation for indexed families of seminorms. This is mainly to allow for dot-notation. -/ abbrev SeminormFamily := ι → Seminorm 𝕜 E variable {𝕜 E ι} namespace SeminormFamily /-- The sets of a filter basis for the neighborhood filter of 0. -/ def basisSets (p : SeminormFamily 𝕜 E ι) : Set (Set E) := ⋃ (s : Finset ι) (r) (_ : 0 < r), singleton (ball (s.sup p) (0 : E) r) variable (p : SeminormFamily 𝕜 E ι) theorem basisSets_iff {U : Set E} : U ∈ p.basisSets ↔ ∃ (i : Finset ι) (r : ℝ), 0 < r ∧ U = ball (i.sup p) 0 r := by simp only [basisSets, mem_iUnion, exists_prop, mem_singleton_iff] theorem basisSets_mem (i : Finset ι) {r : ℝ} (hr : 0 < r) : (i.sup p).ball 0 r ∈ p.basisSets := (basisSets_iff _).mpr ⟨i, _, hr, rfl⟩ theorem basisSets_singleton_mem (i : ι) {r : ℝ} (hr : 0 < r) : (p i).ball 0 r ∈ p.basisSets := (basisSets_iff _).mpr ⟨{i}, _, hr, by rw [Finset.sup_singleton]⟩ theorem basisSets_nonempty [Nonempty ι] : p.basisSets.Nonempty := by let i := Classical.arbitrary ι refine nonempty_def.mpr ⟨(p i).ball 0 1, ?_⟩ exact p.basisSets_singleton_mem i zero_lt_one theorem basisSets_intersect (U V : Set E) (hU : U ∈ p.basisSets) (hV : V ∈ p.basisSets) : ∃ z ∈ p.basisSets, z ⊆ U ∩ V := by classical rcases p.basisSets_iff.mp hU with ⟨s, r₁, hr₁, hU⟩ rcases p.basisSets_iff.mp hV with ⟨t, r₂, hr₂, hV⟩ use ((s ∪ t).sup p).ball 0 (min r₁ r₂) refine ⟨p.basisSets_mem (s ∪ t) (lt_min_iff.mpr ⟨hr₁, hr₂⟩), ?_⟩ rw [hU, hV, ball_finset_sup_eq_iInter _ _ _ (lt_min_iff.mpr ⟨hr₁, hr₂⟩), ball_finset_sup_eq_iInter _ _ _ hr₁, ball_finset_sup_eq_iInter _ _ _ hr₂] exact Set.subset_inter (Set.iInter₂_mono' fun i hi => ⟨i, Finset.subset_union_left hi, ball_mono <\| min_le_left _ _⟩) (Set.iInter₂_mono' fun i hi => ⟨i, Finset.subset_union_right hi, ball_mono <\| min_le_right _ _⟩) theorem basisSets_zero (U) (hU : U ∈ p.basisSets) : (0 : E) ∈ U := by rcases p.basisSets_iff.mp hU with ⟨ι', r, hr, hU⟩ rw [hU, mem_ball_zero, map_zero] exact hr theorem basisSets_add (U) (hU : U ∈ p.basisSets) : ∃ V ∈ p.basisSets, V + V ⊆ U := by rcases p.basisSets_iff.mp hU with ⟨s, r, hr, hU⟩ use (s.sup p).ball 0 (r / 2) refine ⟨p.basisSets_mem s (div_pos hr zero_lt_two), ?_⟩ refine Set.Subset.trans (ball_add_ball_subset (s.sup p) (r / 2) (r / 2) 0 0) ?_ rw [hU, add_zero, add_halves] theorem basisSets_neg (U) (hU' : U ∈ p.basisSets) : ∃ V ∈ p.basisSets, V ⊆ (fun x : E => -x) ⁻¹' U := by rcases p.basisSets_iff.mp hU' with ⟨s, r, _, hU⟩ rw [hU, neg_preimage, neg_ball (s.sup p), neg_zero] exact ⟨U, hU', Eq.subset hU⟩ /-- The `addGroupFilterBasis` induced by the filter basis `Seminorm.basisSets`. -/ protected def addGroupFilterBasis [Nonempty ι] : AddGroupFilterBasis E := addGroupFilterBasisOfComm p.basisSets p.basisSets_nonempty p.basisSets_intersect p.basisSets_zero p.basisSets_add p.basisSets_neg theorem basisSets_smul_right (v : E) (U : Set E) (hU : U ∈ p.basisSets) : ∀ᶠ x : 𝕜 in 𝓝 0, x • v ∈ U := by rcases p.basisSets_iff.mp hU with ⟨s, r, hr, hU⟩ rw [hU, Filter.eventually_iff] simp_rw [(s.sup p).mem_ball_zero, map_smul_eq_mul] by_cases h : 0 < (s.sup p) v · simp_rw [(lt_div_iff₀ h).symm] rw [← _root_.ball_zero_eq] exact Metric.ball_mem_nhds 0 (div_pos hr h) simp_rw [le_antisymm (not_lt.mp h) (apply_nonneg _ v), mul_zero, hr] exact IsOpen.mem_nhds isOpen_univ (mem_univ 0) variable [Nonempty ι] theorem basisSets_smul (U) (hU : U ∈ p.basisSets) : ∃ V ∈ 𝓝 (0 : 𝕜), ∃ W ∈ p.addGroupFilterBasis.sets, V • W ⊆ U := by rcases p.basisSets_iff.mp hU with ⟨s, r, hr, hU⟩ refine ⟨Metric.ball 0 √r, Metric.ball_mem_nhds 0 (Real.sqrt_pos.mpr hr), ?_⟩ refine ⟨(s.sup p).ball 0 √r, p.basisSets_mem s (Real.sqrt_pos.mpr hr), ?_⟩ refine Set.Subset.trans (ball_smul_ball (s.sup p) √r √r) ?_ rw [hU, Real.mul_self_sqrt (le_of_lt hr)] theorem basisSets_smul_left (x : 𝕜) (U : Set E) (hU : U ∈ p.basisSets) : ∃ V ∈ p.addGroupFilterBasis.sets, V ⊆ (fun y : E => x • y) ⁻¹' U := by rcases p.basisSets_iff.mp hU with ⟨s, r, hr, hU⟩ rw [hU] by_cases h : x ≠ 0 · rw [(s.sup p).smul_ball_preimage 0 r x h, smul_zero] use (s.sup p).ball 0 (r / ‖x‖) exact ⟨p.basisSets_mem s (div_pos hr (norm_pos_iff.mpr h)), Subset.rfl⟩ refine ⟨(s.sup p).ball 0 r, p.basisSets_mem s hr, ?_⟩ simp only [not_ne_iff.mp h, Set.subset_def, mem_ball_zero, hr, mem_univ, map_zero, imp_true_iff, preimage_const_of_mem, zero_smul] /-- The `moduleFilterBasis` induced by the filter basis `Seminorm.basisSets`. -/ protected def moduleFilterBasis : ModuleFilterBasis 𝕜 E where toAddGroupFilterBasis := p.addGroupFilterBasis smul' := p.basisSets_smul _ smul_left' := p.basisSets_smul_left smul_right' := p.basisSets_smul_right theorem filter_eq_iInf (p : SeminormFamily 𝕜 E ι) : p.moduleFilterBasis.toFilterBasis.filter = ⨅ i, (𝓝 0).comap (p i) := by refine le_antisymm (le_iInf fun i => ?_) ?_ · rw [p.moduleFilterBasis.toFilterBasis.hasBasis.le_basis_iff (Metric.nhds_basis_ball.comap _)] intro ε hε refine ⟨(p i).ball 0 ε, ?_, ?_⟩ · rw [← (Finset.sup_singleton : _ = p i)] exact p.basisSets_mem {i} hε · rw [id, (p i).ball_zero_eq_preimage_ball] · rw [p.moduleFilterBasis.toFilterBasis.hasBasis.ge_iff] rintro U (hU : U ∈ p.basisSets) rcases p.basisSets_iff.mp hU with ⟨s, r, hr, rfl⟩ rw [id, Seminorm.ball_finset_sup_eq_iInter _ _ _ hr, s.iInter_mem_sets] exact fun i _ => Filter.mem_iInf_of_mem i ⟨Metric.ball 0 r, Metric.ball_mem_nhds 0 hr, Eq.subset (p i).ball_zero_eq_preimage_ball.symm⟩ /-- If a family of seminorms is continuous, then their basis sets are neighborhoods of zero. -/ lemma basisSets_mem_nhds {𝕜 E ι : Type} [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] [TopologicalSpace E] (p : SeminormFamily 𝕜 E ι) (hp : ∀ i, Continuous (p i)) (U : Set E) (hU : U ∈ p.basisSets) : U ∈ 𝓝 (0 : E) := by obtain ⟨s, r, hr, rfl⟩ := p.basisSets_iff.mp hU clear hU refine Seminorm.ball_mem_nhds ?_ hr classical induction s using Finset.induction_on case empty => simpa using continuous_zero case insert a s _ hs => simp only [Finset.sup_insert, coe_sup] exact Continuous.max (hp a) hs end SeminormFamily end FilterBasis section Bounded namespace Seminorm variable [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] variable [NormedField 𝕜₂] [AddCommGroup F] [Module 𝕜₂ F] variable {σ₁₂ : 𝕜 →+* 𝕜₂} [RingHomIsometric σ₁₂] -- Todo: This should be phrased entirely in terms of the von Neumann bornology. /-- The proposition that a linear map is bounded between spaces with families of seminorms. -/ def IsBounded (p : ι → Seminorm 𝕜 E) (q : ι' → Seminorm 𝕜₂ F) (f : E →ₛₗ[σ₁₂] F) : Prop := ∀ i, ∃ s : Finset ι, ∃ C : ℝ≥0, (q i).comp f ≤ C • s.sup p theorem isBounded_const (ι' : Type) [Nonempty ι'] {p : ι → Seminorm 𝕜 E} {q : Seminorm 𝕜₂ F} (f : E →ₛₗ[σ₁₂] F) : IsBounded p (fun _ : ι' => q) f ↔ ∃ (s : Finset ι) (C : ℝ≥0), q.comp f ≤ C • s.sup p := by simp only [IsBounded, forall_const] theorem const_isBounded (ι : Type) [Nonempty ι] {p : Seminorm 𝕜 E} {q : ι' → Seminorm 𝕜₂ F} (f : E →ₛₗ[σ₁₂] F) : IsBounded (fun _ : ι => p) q f ↔ ∀ i, ∃ C : ℝ≥0, (q i).comp f ≤ C • p := by constructor <;> intro h i · rcases h i with ⟨s, C, h⟩ exact ⟨C, le_trans h (smul_le_smul (Finset.sup_le fun _ _ => le_rfl) le_rfl)⟩ use {Classical.arbitrary ι} simp only [h, Finset.sup_singleton] theorem isBounded_sup {p : ι → Seminorm 𝕜 E} {q : ι' → Seminorm 𝕜₂ F} {f : E →ₛₗ[σ₁₂] F} (hf : IsBounded p q f) (s' : Finset ι') : ∃ (C : ℝ≥0) (s : Finset ι), (s'.sup q).comp f ≤ C • s.sup p := by classical obtain rfl \| _ := s'.eq_empty_or_nonempty · exact ⟨1, ∅, by simp [Seminorm.bot_eq_zero]⟩ choose fₛ fC hf using hf use s'.card • s'.sup fC, Finset.biUnion s' fₛ have hs : ∀ i : ι', i ∈ s' → (q i).comp f ≤ s'.sup fC • (Finset.biUnion s' fₛ).sup p := by intro i hi refine (hf i).trans (smul_le_smul ?_ (Finset.le_sup hi)) exact Finset.sup_mono (Finset.subset_biUnion_of_mem fₛ hi) refine (comp_mono f (finset_sup_le_sum q s')).trans ?_ simp_rw [← pullback_apply, map_sum, pullback_apply] refine (Finset.sum_le_sum hs).trans ?_ rw [Finset.sum_const, smul_assoc] end Seminorm end Bounded section Topology variable [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] [Nonempty ι] /-- The proposition that the topology of `E` is induced by a family of seminorms `p`. -/ structure WithSeminorms (p : SeminormFamily 𝕜 E ι) [topology : TopologicalSpace E] : Prop where topology_eq_withSeminorms : topology = p.moduleFilterBasis.topology theorem WithSeminorms.withSeminorms_eq {p : SeminormFamily 𝕜 E ι} [t : TopologicalSpace E] (hp : WithSeminorms p) : t = p.moduleFilterBasis.topology := hp.1 variable [TopologicalSpace E] variable {p : SeminormFamily 𝕜 E ι} theorem WithSeminorms.topologicalAddGroup (hp : WithSeminorms p) : IsTopologicalAddGroup E := by rw [hp.withSeminorms_eq] exact AddGroupFilterBasis.isTopologicalAddGroup _ theorem WithSeminorms.continuousSMul (hp : WithSeminorms p) : ContinuousSMul 𝕜 E := by rw [hp.withSeminorms_eq] exact ModuleFilterBasis.continuousSMul _ theorem WithSeminorms.hasBasis (hp : WithSeminorms p) : (𝓝 (0 : E)).HasBasis (fun s : Set E => s ∈ p.basisSets) id := by rw [congr_fun (congr_arg (@nhds E) hp.1) 0] exact AddGroupFilterBasis.nhds_zero_hasBasis _ theorem WithSeminorms.hasBasis_zero_ball (hp : WithSeminorms p) : (𝓝 (0 : E)).HasBasis (fun sr : Finset ι × ℝ => 0 < sr.2) fun sr => (sr.1.sup p).ball 0 sr.2 := by refine ⟨fun V => ?_⟩ simp only [hp.hasBasis.mem_iff, SeminormFamily.basisSets_iff, Prod.exists] constructor · rintro ⟨-, ⟨s, r, hr, rfl⟩, hV⟩ exact ⟨s, r, hr, hV⟩ · rintro ⟨s, r, hr, hV⟩ exact ⟨_, ⟨s, r, hr, rfl⟩, hV⟩ theorem WithSeminorms.hasBasis_ball (hp : WithSeminorms p) {x : E} : (𝓝 (x : E)).HasBasis (fun sr : Finset ι × ℝ => 0 < sr.2) fun sr => (sr.1.sup p).ball x sr.2 := by have : IsTopologicalAddGroup E := hp.topologicalAddGroup rw [← map_add_left_nhds_zero] convert hp.hasBasis_zero_ball.map (x + ·) using 1 ext sr : 1 -- Porting note: extra type ascriptions needed on `0` have : (sr.fst.sup p).ball (x +ᵥ (0 : E)) sr.snd = x +ᵥ (sr.fst.sup p).ball 0 sr.snd := Eq.symm (Seminorm.vadd_ball (sr.fst.sup p)) rwa [vadd_eq_add, add_zero] at this /-- The `x`-neighbourhoods of a space whose topology is induced by a family of seminorms are exactly the sets which contain seminorm balls around `x`. -/ theorem WithSeminorms.mem_nhds_iff (hp : WithSeminorms p) (x : E) (U : Set E) : U ∈ 𝓝 x ↔ ∃ s : Finset ι, ∃ r > 0, (s.sup p).ball x r ⊆ U := by rw [hp.hasBasis_ball.mem_iff, Prod.exists] /-- The open sets of a space whose topology is induced by a family of seminorms are exactly the sets which contain seminorm balls around all of their points. -/ theorem WithSeminorms.isOpen_iff_mem_balls (hp : WithSeminorms p) (U : Set E) : IsOpen U ↔ ∀ x ∈ U, ∃ s : Finset ι, ∃ r > 0, (s.sup p).ball x r ⊆ U := by simp_rw [← WithSeminorms.mem_nhds_iff hp _ U, isOpen_iff_mem_nhds] /- Note that through the following lemmas, one also immediately has that separating families of seminorms induce T₂ and T₃ topologies by `IsTopologicalAddGroup.t2Space` and `IsTopologicalAddGroup.t3Space` -/ /-- A separating family of seminorms induces a T₁ topology. -/ theorem WithSeminorms.T1_of_separating (hp : WithSeminorms p) (h : ∀ x, x ≠ 0 → ∃ i, p i x ≠ 0) : T1Space E := by have := hp.topologicalAddGroup refine IsTopologicalAddGroup.t1Space _ ?_ rw [← isOpen_compl_iff, hp.isOpen_iff_mem_balls] rintro x (hx : x ≠ 0) obtain ⟨i, pi_nonzero⟩ := h x hx refine ⟨{i}, p i x, by positivity, subset_compl_singleton_iff.mpr ?_⟩ rw [Finset.sup_singleton, mem_ball, zero_sub, map_neg_eq_map, not_lt] /-- A family of seminorms inducing a T₁ topology is separating. -/ theorem WithSeminorms.separating_of_T1 [T1Space E] (hp : WithSeminorms p) (x : E) (hx : x ≠ 0) : ∃ i, p i x ≠ 0 := by have := ((t1Space_TFAE E).out 0 9).mp (inferInstanceAs <\| T1Space E) by_contra! h refine hx (this ?_) rw [hp.hasBasis_zero_ball.specializes_iff] rintro ⟨s, r⟩ (hr : 0 < r) simp only [ball_finset_sup_eq_iInter _ _ _ hr, mem_iInter₂, mem_ball_zero, h, hr, forall_true_iff] /-- A family of seminorms is separating iff it induces a T₁ topology. -/ theorem WithSeminorms.separating_iff_T1 (hp : WithSeminorms p) : (∀ x, x ≠ 0 → ∃ i, p i x ≠ 0) ↔ T1Space E := by refine ⟨WithSeminorms.T1_of_separating hp, ?_⟩ intro exact WithSeminorms.separating_of_T1 hp end Topology section Tendsto variable [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] [Nonempty ι] [TopologicalSpace E] variable {p : SeminormFamily 𝕜 E ι} /-- Convergence along filters for `WithSeminorms`. Variant with `Finset.sup`. -/ theorem WithSeminorms.tendsto_nhds' (hp : WithSeminorms p) (u : F → E) {f : Filter F} (y₀ : E) : Filter.Tendsto u f (𝓝 y₀) ↔ ∀ (s : Finset ι) (ε), 0 < ε → ∀ᶠ x in f, s.sup p (u x - y₀) < ε := by simp [hp.hasBasis_ball.tendsto_right_iff] /-- Convergence along filters for `WithSeminorms`. -/ theorem WithSeminorms.tendsto_nhds (hp : WithSeminorms p) (u : F → E) {f : Filter F} (y₀ : E) : Filter.Tendsto u f (𝓝 y₀) ↔ ∀ i ε, 0 < ε → ∀ᶠ x in f, p i (u x - y₀) < ε := by rw [hp.tendsto_nhds' u y₀] exact ⟨fun h i => by simpa only [Finset.sup_singleton] using h {i}, fun h s ε hε => (s.eventually_all.2 fun i _ => h i ε hε).mono fun _ => finset_sup_apply_lt hε⟩ variable [SemilatticeSup F] [Nonempty F] /-- Limit `→ ∞` for `WithSeminorms`. -/ theorem WithSeminorms.tendsto_nhds_atTop (hp : WithSeminorms p) (u : F → E) (y₀ : E) : Filter.Tendsto u Filter.atTop (𝓝 y₀) ↔ ∀ i ε, 0 < ε → ∃ x₀, ∀ x, x₀ ≤ x → p i (u x - y₀) < ε := by rw [hp.tendsto_nhds u y₀] exact forall₃_congr fun _ _ _ => Filter.eventually_atTop end Tendsto section IsTopologicalAddGroup variable [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] variable [Nonempty ι] section TopologicalSpace variable [t : TopologicalSpace E] theorem SeminormFamily.withSeminorms_of_nhds [IsTopologicalAddGroup E] (p : SeminormFamily 𝕜 E ι) (h : 𝓝 (0 : E) = p.moduleFilterBasis.toFilterBasis.filter) : WithSeminorms p := by refine ⟨IsTopologicalAddGroup.ext inferInstance p.addGroupFilterBasis.isTopologicalAddGroup ?_⟩	rw [AddGroupFilterBasis.nhds_zero_eq] exact h theorem SeminormFamily.withSeminorms_of_hasBasis [IsTopologicalAddGroup E] (p : SeminormFamily 𝕜 E ι) (h : (𝓝 (0 : E)).HasBasis (fun s : Set E => s ∈ p.basisSets) id) :	Mathlib/Analysis/LocallyConvex/WithSeminorms.lean	398	402
/- Copyright (c) 2024 Frédéric Marbach. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Frédéric Marbach -/ import Mathlib.Algebra.Lie.Derivation.AdjointAction import Mathlib.Algebra.Lie.Killing import Mathlib.LinearAlgebra.BilinearForm.Orthogonal /-! # Derivations of finite dimensional Killing Lie algebras This file establishes that all derivations of finite-dimensional Killing Lie algebras are inner. ## Main statements - `LieDerivation.Killing.ad_mem_orthogonal_of_mem_orthogonal`: if a derivation `D` is in the Killing orthogonal of the range of the adjoint action, then, for any `x : L`, `ad (D x)` is also in this orthogonal. - `LieDerivation.Killing.range_ad_eq_top`: in a finite-dimensional Lie algebra with non-degenerate Killing form, the range of the adjoint action is full, - `LieDerivation.Killing.exists_eq_ad`: in a finite-dimensional Lie algebra with non-degenerate Killing form, any derivation is an inner derivation. -/ namespace LieDerivation.IsKilling section variable (R L : Type*) [Field R] [LieRing L] [LieAlgebra R L] /-- A local notation for the set of (Lie) derivations on `L`. -/ local notation "𝔻" => (LieDerivation R L L) /-- A local notation for the range of `ad`. -/ local notation "𝕀" => (LieHom.range (ad R L)) /-- A local notation for the Killing complement of the ideal range of `ad`. -/ local notation "𝕀ᗮ" => LinearMap.BilinForm.orthogonal (killingForm R 𝔻) 𝕀 lemma killingForm_restrict_range_ad [Module.Finite R L] : (killingForm R 𝔻).restrict 𝕀 = killingForm R 𝕀 := by rw [← (ad_isIdealMorphism R L).eq, ← LieIdeal.killingForm_eq] rfl /-- The orthogonal complement of the inner derivations is a Lie submodule of all derivations. -/ @[simps!] noncomputable def rangeAdOrthogonal : LieSubmodule R L (LieDerivation R L L) where __ := 𝕀ᗮ lie_mem := by intro x D hD have : 𝕀ᗮ = (ad R L).idealRange.killingCompl := by simp [← (ad_isIdealMorphism R L).eq] change D ∈ 𝕀ᗮ at hD change ⁅x, D⁆ ∈ 𝕀ᗮ rw [this] at hD ⊢ rw [← lie_ad] exact lie_mem_right _ _ (ad R L).idealRange.killingCompl _ _ hD variable {R L} /-- If a derivation `D` is in the Killing orthogonal of the range of the adjoint action, then, for any `x : L`, `ad (D x)` is also in this orthogonal. -/ lemma ad_mem_orthogonal_of_mem_orthogonal {D : LieDerivation R L L} (hD : D ∈ 𝕀ᗮ) (x : L) : ad R L (D x) ∈ 𝕀ᗮ := by simp only [ad_apply_lieDerivation, LieHom.range_toSubmodule, neg_mem_iff] exact (rangeAdOrthogonal R L).lie_mem hD variable [Module.Finite R L] lemma ad_mem_ker_killingForm_ad_range_of_mem_orthogonal {D : LieDerivation R L L} (hD : D ∈ 𝕀ᗮ) (x : L) : ad R L (D x) ∈ (LinearMap.ker (killingForm R 𝕀)).map (LieHom.range (ad R L)).subtype := by rw [← killingForm_restrict_range_ad] exact LinearMap.BilinForm.inf_orthogonal_self_le_ker_restrict (LieModule.traceForm_isSymm R 𝔻 𝔻).isRefl ⟨by simp, ad_mem_orthogonal_of_mem_orthogonal hD x⟩ variable (R L) variable [LieAlgebra.IsKilling R L] @[simp] lemma ad_apply_eq_zero_iff (x : L) : ad R L x = 0 ↔ x = 0 := by refine ⟨fun h ↦ ?_, fun h ↦ by simp [h]⟩ rwa [← LieHom.mem_ker, ad_ker_eq_center, LieAlgebra.center_eq_bot, LieSubmodule.mem_bot] at h instance instIsKilling_range_ad : LieAlgebra.IsKilling R 𝕀 := (LieEquiv.ofInjective (ad R L) (injective_ad_of_center_eq_bot <\| by simp)).isKilling /-- The restriction of the Killing form of a finite-dimensional Killing Lie algebra to the range of the adjoint action is nondegenerate. -/ lemma killingForm_restrict_range_ad_nondegenerate : ((killingForm R 𝔻).restrict 𝕀).Nondegenerate := by convert LieAlgebra.IsKilling.killingForm_nondegenerate R 𝕀 exact killingForm_restrict_range_ad R L /-- The range of the adjoint action on a finite-dimensional Killing Lie algebra is full. -/ @[simp] lemma range_ad_eq_top : 𝕀 = ⊤ := by rw [← LieSubalgebra.toSubmodule_inj] apply LinearMap.BilinForm.eq_top_of_restrict_nondegenerate_of_orthogonal_eq_bot (LieModule.traceForm_isSymm R 𝔻 𝔻).isRefl (killingForm_restrict_range_ad_nondegenerate R L)	refine (Submodule.eq_bot_iff _).mpr fun D hD ↦ ext fun x ↦ ?_ simpa using ad_mem_ker_killingForm_ad_range_of_mem_orthogonal hD x variable {R L} in /-- Every derivation of a finite-dimensional Killing Lie algebra is an inner derivation. -/	Mathlib/Algebra/Lie/Derivation/Killing.lean	99	103
/- Copyright (c) 2022 Xavier Roblot. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Alex J. Best, Xavier Roblot -/ import Mathlib.Algebra.Algebra.Hom.Rat import Mathlib.Analysis.Complex.Polynomial.Basic import Mathlib.NumberTheory.NumberField.Norm import Mathlib.RingTheory.RootsOfUnity.PrimitiveRoots import Mathlib.Topology.Instances.Complex /-! # Embeddings of number fields This file defines the embeddings of a number field into an algebraic closed field. ## Main Definitions and Results * `NumberField.Embeddings.range_eval_eq_rootSet_minpoly`: let `x ∈ K` with `K` number field and let `A` be an algebraic closed field of char. 0, then the images of `x` by the embeddings of `K` in `A` are exactly the roots in `A` of the minimal polynomial of `x` over `ℚ`. * `NumberField.Embeddings.pow_eq_one_of_norm_eq_one`: an algebraic integer whose conjugates are all of norm one is a root of unity. * `NumberField.InfinitePlace`: the type of infinite places of a number field `K`. * `NumberField.InfinitePlace.mk_eq_iff`: two complex embeddings define the same infinite place iff they are equal or complex conjugates. * `NumberField.InfinitePlace.prod_eq_abs_norm`: the infinite part of the product formula, that is for `x ∈ K`, we have `Π_w ‖x‖_w = \|norm(x)\|` where the product is over the infinite place `w` and `‖·‖_w` is the normalized absolute value for `w`. ## Tags number field, embeddings, places, infinite places -/ open scoped Finset namespace NumberField.Embeddings section Fintype open Module variable (K : Type) [Field K] [NumberField K] variable (A : Type) [Field A] [CharZero A] /-- There are finitely many embeddings of a number field. -/ noncomputable instance : Fintype (K →+* A) := Fintype.ofEquiv (K →ₐ[ℚ] A) RingHom.equivRatAlgHom.symm variable [IsAlgClosed A] /-- The number of embeddings of a number field is equal to its finrank. -/ theorem card : Fintype.card (K →+* A) = finrank ℚ K := by rw [Fintype.ofEquiv_card RingHom.equivRatAlgHom.symm, AlgHom.card] instance : Nonempty (K →+* A) := by rw [← Fintype.card_pos_iff, NumberField.Embeddings.card K A] exact Module.finrank_pos end Fintype section Roots open Set Polynomial variable (K A : Type) [Field K] [NumberField K] [Field A] [Algebra ℚ A] [IsAlgClosed A] (x : K) /-- Let `A` be an algebraically closed field and let `x ∈ K`, with `K` a number field. The images of `x` by the embeddings of `K` in `A` are exactly the roots in `A` of the minimal polynomial of `x` over `ℚ`. -/ theorem range_eval_eq_rootSet_minpoly : (range fun φ : K →+ A => φ x) = (minpoly ℚ x).rootSet A := by convert (NumberField.isAlgebraic K).range_eval_eq_rootSet_minpoly A x using 1 ext a exact ⟨fun ⟨φ, hφ⟩ => ⟨φ.toRatAlgHom, hφ⟩, fun ⟨φ, hφ⟩ => ⟨φ.toRingHom, hφ⟩⟩ end Roots section Bounded open Module Polynomial Set variable {K : Type} [Field K] [NumberField K] variable {A : Type} [NormedField A] [IsAlgClosed A] [NormedAlgebra ℚ A] theorem coeff_bdd_of_norm_le {B : ℝ} {x : K} (h : ∀ φ : K →+* A, ‖φ x‖ ≤ B) (i : ℕ) : ‖(minpoly ℚ x).coeff i‖ ≤ max B 1 ^ finrank ℚ K * (finrank ℚ K).choose (finrank ℚ K / 2) := by have hx := Algebra.IsSeparable.isIntegral ℚ x rw [← norm_algebraMap' A, ← coeff_map (algebraMap ℚ A)] refine coeff_bdd_of_roots_le _ (minpoly.monic hx) (IsAlgClosed.splits_codomain _) (minpoly.natDegree_le x) (fun z hz => ?_) i classical rw [← Multiset.mem_toFinset] at hz obtain ⟨φ, rfl⟩ := (range_eval_eq_rootSet_minpoly K A x).symm.subset hz exact h φ variable (K A) /-- Let `B` be a real number. The set of algebraic integers in `K` whose conjugates are all smaller in norm than `B` is finite. -/ theorem finite_of_norm_le (B : ℝ) : {x : K \| IsIntegral ℤ x ∧ ∀ φ : K →+* A, ‖φ x‖ ≤ B}.Finite := by classical let C := Nat.ceil (max B 1 ^ finrank ℚ K * (finrank ℚ K).choose (finrank ℚ K / 2)) have := bUnion_roots_finite (algebraMap ℤ K) (finrank ℚ K) (finite_Icc (-C : ℤ) C) refine this.subset fun x hx => ?_; simp_rw [mem_iUnion] have h_map_ℚ_minpoly := minpoly.isIntegrallyClosed_eq_field_fractions' ℚ hx.1 refine ⟨_, ⟨?_, fun i => ?_⟩, mem_rootSet.2 ⟨minpoly.ne_zero hx.1, minpoly.aeval ℤ x⟩⟩ · rw [← (minpoly.monic hx.1).natDegree_map (algebraMap ℤ ℚ), ← h_map_ℚ_minpoly] exact minpoly.natDegree_le x rw [mem_Icc, ← abs_le, ← @Int.cast_le ℝ] refine (Eq.trans_le ?_ <\| coeff_bdd_of_norm_le hx.2 i).trans (Nat.le_ceil _) rw [h_map_ℚ_minpoly, coeff_map, eq_intCast, Int.norm_cast_rat, Int.norm_eq_abs, Int.cast_abs] /-- An algebraic integer whose conjugates are all of norm one is a root of unity. -/ theorem pow_eq_one_of_norm_eq_one {x : K} (hxi : IsIntegral ℤ x) (hx : ∀ φ : K →+* A, ‖φ x‖ = 1) : ∃ (n : ℕ) (_ : 0 < n), x ^ n = 1 := by obtain ⟨a, -, b, -, habne, h⟩ := @Set.Infinite.exists_ne_map_eq_of_mapsTo _ _ _ _ (x ^ · : ℕ → K) Set.infinite_univ (by exact fun a _ => ⟨hxi.pow a, fun φ => by simp [hx φ]⟩) (finite_of_norm_le K A (1 : ℝ)) wlog hlt : b < a · exact this K A hxi hx b a habne.symm h.symm (habne.lt_or_lt.resolve_right hlt) refine ⟨a - b, tsub_pos_of_lt hlt, ?_⟩ rw [← Nat.sub_add_cancel hlt.le, pow_add, mul_left_eq_self₀] at h refine h.resolve_right fun hp => ?_ specialize hx (IsAlgClosed.lift (R := ℚ)).toRingHom rw [pow_eq_zero hp, map_zero, norm_zero] at hx; norm_num at hx end Bounded end NumberField.Embeddings section Place variable {K : Type} [Field K] {A : Type} [NormedDivisionRing A] [Nontrivial A] (φ : K →+* A) /-- An embedding into a normed division ring defines a place of `K` -/ def NumberField.place : AbsoluteValue K ℝ := (IsAbsoluteValue.toAbsoluteValue (norm : A → ℝ)).comp φ.injective @[simp] theorem NumberField.place_apply (x : K) : (NumberField.place φ) x = norm (φ x) := rfl end Place namespace NumberField.ComplexEmbedding open Complex NumberField open scoped ComplexConjugate variable {K : Type} [Field K] {k : Type} [Field k] variable (K) in /-- A (random) lift of the complex embedding `φ : k →+* ℂ` to an extension `K` of `k`. -/ noncomputable def lift [Algebra k K] [Algebra.IsAlgebraic k K] (φ : k →+* ℂ) : K →+* ℂ := by letI := φ.toAlgebra exact (IsAlgClosed.lift (R := k)).toRingHom @[simp] theorem lift_comp_algebraMap [Algebra k K] [Algebra.IsAlgebraic k K] (φ : k →+* ℂ) : (lift K φ).comp (algebraMap k K) = φ := by unfold lift letI := φ.toAlgebra rw [AlgHom.toRingHom_eq_coe, AlgHom.comp_algebraMap_of_tower, RingHom.algebraMap_toAlgebra'] @[simp] theorem lift_algebraMap_apply [Algebra k K] [Algebra.IsAlgebraic k K] (φ : k →+* ℂ) (x : k) : lift K φ (algebraMap k K x) = φ x := RingHom.congr_fun (lift_comp_algebraMap φ) x /-- The conjugate of a complex embedding as a complex embedding. -/ abbrev conjugate (φ : K →+* ℂ) : K →+* ℂ := star φ @[simp] theorem conjugate_coe_eq (φ : K →+* ℂ) (x : K) : (conjugate φ) x = conj (φ x) := rfl theorem place_conjugate (φ : K →+* ℂ) : place (conjugate φ) = place φ := by ext; simp only [place_apply, norm_conj, conjugate_coe_eq] /-- An embedding into `ℂ` is real if it is fixed by complex conjugation. -/ abbrev IsReal (φ : K →+* ℂ) : Prop := IsSelfAdjoint φ theorem isReal_iff {φ : K →+* ℂ} : IsReal φ ↔ conjugate φ = φ := isSelfAdjoint_iff theorem isReal_conjugate_iff {φ : K →+* ℂ} : IsReal (conjugate φ) ↔ IsReal φ := IsSelfAdjoint.star_iff /-- A real embedding as a ring homomorphism from `K` to `ℝ` . -/ def IsReal.embedding {φ : K →+* ℂ} (hφ : IsReal φ) : K →+* ℝ where toFun x := (φ x).re map_one' := by simp only [map_one, one_re] map_mul' := by simp only [Complex.conj_eq_iff_im.mp (RingHom.congr_fun hφ _), map_mul, mul_re, mul_zero, tsub_zero, eq_self_iff_true, forall_const] map_zero' := by simp only [map_zero, zero_re] map_add' := by simp only [map_add, add_re, eq_self_iff_true, forall_const] @[simp] theorem IsReal.coe_embedding_apply {φ : K →+* ℂ} (hφ : IsReal φ) (x : K) : (hφ.embedding x : ℂ) = φ x := by apply Complex.ext · rfl · rw [ofReal_im, eq_comm, ← Complex.conj_eq_iff_im] exact RingHom.congr_fun hφ x lemma IsReal.comp (f : k →+* K) {φ : K →+* ℂ} (hφ : IsReal φ) : IsReal (φ.comp f) := by ext1 x; simpa using RingHom.congr_fun hφ (f x) lemma isReal_comp_iff {f : k ≃+* K} {φ : K →+* ℂ} : IsReal (φ.comp (f : k →+* K)) ↔ IsReal φ := ⟨fun H ↦ by convert H.comp f.symm.toRingHom; ext1; simp, IsReal.comp _⟩ lemma exists_comp_symm_eq_of_comp_eq [Algebra k K] [IsGalois k K] (φ ψ : K →+* ℂ) (h : φ.comp (algebraMap k K) = ψ.comp (algebraMap k K)) : ∃ σ : K ≃ₐ[k] K, φ.comp σ.symm = ψ := by letI := (φ.comp (algebraMap k K)).toAlgebra letI := φ.toAlgebra have : IsScalarTower k K ℂ := IsScalarTower.of_algebraMap_eq' rfl let ψ' : K →ₐ[k] ℂ := { ψ with commutes' := fun r ↦ (RingHom.congr_fun h r).symm } use (AlgHom.restrictNormal' ψ' K).symm ext1 x exact AlgHom.restrictNormal_commutes ψ' K x variable [Algebra k K] (φ : K →+* ℂ) (σ : K ≃ₐ[k] K) /-- `IsConj φ σ` states that `σ : K ≃ₐ[k] K` is the conjugation under the embedding `φ : K →+* ℂ`. -/ def IsConj : Prop := conjugate φ = φ.comp σ variable {φ σ} lemma IsConj.eq (h : IsConj φ σ) (x) : φ (σ x) = star (φ x) := RingHom.congr_fun h.symm x lemma IsConj.ext {σ₁ σ₂ : K ≃ₐ[k] K} (h₁ : IsConj φ σ₁) (h₂ : IsConj φ σ₂) : σ₁ = σ₂ := AlgEquiv.ext fun x ↦ φ.injective ((h₁.eq x).trans (h₂.eq x).symm) lemma IsConj.ext_iff {σ₁ σ₂ : K ≃ₐ[k] K} (h₁ : IsConj φ σ₁) : σ₁ = σ₂ ↔ IsConj φ σ₂ := ⟨fun e ↦ e ▸ h₁, h₁.ext⟩ lemma IsConj.isReal_comp (h : IsConj φ σ) : IsReal (φ.comp (algebraMap k K)) := by ext1 x simp only [conjugate_coe_eq, RingHom.coe_comp, Function.comp_apply, ← h.eq, starRingEnd_apply, AlgEquiv.commutes] lemma isConj_one_iff : IsConj φ (1 : K ≃ₐ[k] K) ↔ IsReal φ := Iff.rfl alias ⟨_, IsReal.isConjGal_one⟩ := ComplexEmbedding.isConj_one_iff lemma IsConj.symm (hσ : IsConj φ σ) : IsConj φ σ.symm := RingHom.ext fun x ↦ by simpa using congr_arg star (hσ.eq (σ.symm x)) lemma isConj_symm : IsConj φ σ.symm ↔ IsConj φ σ := ⟨IsConj.symm, IsConj.symm⟩ end NumberField.ComplexEmbedding section InfinitePlace open NumberField variable {k : Type} [Field k] (K : Type) [Field K] {F : Type} [Field F] /-- An infinite place of a number field `K` is a place associated to a complex embedding. -/ def NumberField.InfinitePlace := { w : AbsoluteValue K ℝ // ∃ φ : K →+ ℂ, place φ = w } instance [NumberField K] : Nonempty (NumberField.InfinitePlace K) := Set.instNonemptyRange _ variable {K} /-- Return the infinite place defined by a complex embedding `φ`. -/ noncomputable def NumberField.InfinitePlace.mk (φ : K →+* ℂ) : NumberField.InfinitePlace K := ⟨place φ, ⟨φ, rfl⟩⟩ namespace NumberField.InfinitePlace open NumberField instance {K : Type} [Field K] : FunLike (InfinitePlace K) K ℝ where coe w x := w.1 x coe_injective' _ _ h := Subtype.eq (AbsoluteValue.ext fun x => congr_fun h x) lemma coe_apply {K : Type} [Field K] (v : InfinitePlace K) (x : K) : v x = v.1 x := rfl @[ext] lemma ext {K : Type} [Field K] (v₁ v₂ : InfinitePlace K) (h : ∀ k, v₁ k = v₂ k) : v₁ = v₂ := Subtype.ext <\| AbsoluteValue.ext h instance : MonoidWithZeroHomClass (InfinitePlace K) K ℝ where map_mul w _ _ := w.1.map_mul _ _ map_one w := w.1.map_one map_zero w := w.1.map_zero instance : NonnegHomClass (InfinitePlace K) K ℝ where apply_nonneg w _ := w.1.nonneg _ @[simp] theorem apply (φ : K →+ ℂ) (x : K) : (mk φ) x = ‖φ x‖ := rfl /-- For an infinite place `w`, return an embedding `φ` such that `w = infinite_place φ` . -/ noncomputable def embedding (w : InfinitePlace K) : K →+* ℂ := w.2.choose @[simp] theorem mk_embedding (w : InfinitePlace K) : mk (embedding w) = w := Subtype.ext w.2.choose_spec @[simp] theorem mk_conjugate_eq (φ : K →+* ℂ) : mk (ComplexEmbedding.conjugate φ) = mk φ := by refine DFunLike.ext _ _ (fun x => ?_) rw [apply, apply, ComplexEmbedding.conjugate_coe_eq, Complex.norm_conj] theorem norm_embedding_eq (w : InfinitePlace K) (x : K) : ‖(embedding w) x‖ = w x := by nth_rewrite 2 [← mk_embedding w] rfl theorem eq_iff_eq (x : K) (r : ℝ) : (∀ w : InfinitePlace K, w x = r) ↔ ∀ φ : K →+* ℂ, ‖φ x‖ = r := ⟨fun hw φ => hw (mk φ), by rintro hφ ⟨w, ⟨φ, rfl⟩⟩; exact hφ φ⟩ theorem le_iff_le (x : K) (r : ℝ) : (∀ w : InfinitePlace K, w x ≤ r) ↔ ∀ φ : K →+* ℂ, ‖φ x‖ ≤ r := ⟨fun hw φ => hw (mk φ), by rintro hφ ⟨w, ⟨φ, rfl⟩⟩; exact hφ φ⟩ theorem pos_iff {w : InfinitePlace K} {x : K} : 0 < w x ↔ x ≠ 0 := AbsoluteValue.pos_iff w.1 @[simp] theorem mk_eq_iff {φ ψ : K →+* ℂ} : mk φ = mk ψ ↔ φ = ψ ∨ ComplexEmbedding.conjugate φ = ψ := by constructor · -- We prove that the map ψ ∘ φ⁻¹ between φ(K) and ℂ is uniform continuous, thus it is either the -- inclusion or the complex conjugation using `Complex.uniformContinuous_ringHom_eq_id_or_conj` intro h₀ obtain ⟨j, hiφ⟩ := (φ.injective).hasLeftInverse let ι := RingEquiv.ofLeftInverse hiφ have hlip : LipschitzWith 1 (RingHom.comp ψ ι.symm.toRingHom) := by change LipschitzWith 1 (ψ ∘ ι.symm) apply LipschitzWith.of_dist_le_mul intro x y rw [NNReal.coe_one, one_mul, NormedField.dist_eq, Function.comp_apply, Function.comp_apply, ← map_sub, ← map_sub] apply le_of_eq suffices ‖φ (ι.symm (x - y))‖ = ‖ψ (ι.symm (x - y))‖ by rw [← this, ← RingEquiv.ofLeftInverse_apply hiφ _, RingEquiv.apply_symm_apply ι _] rfl exact congrFun (congrArg (↑) h₀) _ cases Complex.uniformContinuous_ringHom_eq_id_or_conj φ.fieldRange hlip.uniformContinuous with \| inl h => left; ext1 x conv_rhs => rw [← hiφ x] exact (congrFun h (ι x)).symm \| inr h => right; ext1 x conv_rhs => rw [← hiφ x] exact (congrFun h (ι x)).symm · rintro (⟨h⟩ \| ⟨h⟩) · exact congr_arg mk h · rw [← mk_conjugate_eq] exact congr_arg mk h /-- An infinite place is real if it is defined by a real embedding. -/ def IsReal (w : InfinitePlace K) : Prop := ∃ φ : K →+* ℂ, ComplexEmbedding.IsReal φ ∧ mk φ = w /-- An infinite place is complex if it is defined by a complex (ie. not real) embedding. -/ def IsComplex (w : InfinitePlace K) : Prop := ∃ φ : K →+* ℂ, ¬ComplexEmbedding.IsReal φ ∧ mk φ = w theorem embedding_mk_eq (φ : K →+* ℂ) : embedding (mk φ) = φ ∨ embedding (mk φ) = ComplexEmbedding.conjugate φ := by rw [@eq_comm _ _ φ, @eq_comm _ _ (ComplexEmbedding.conjugate φ), ← mk_eq_iff, mk_embedding] @[simp] theorem embedding_mk_eq_of_isReal {φ : K →+* ℂ} (h : ComplexEmbedding.IsReal φ) : embedding (mk φ) = φ := by have := embedding_mk_eq φ rwa [ComplexEmbedding.isReal_iff.mp h, or_self] at this theorem isReal_iff {w : InfinitePlace K} : IsReal w ↔ ComplexEmbedding.IsReal (embedding w) := by refine ⟨?_, fun h => ⟨embedding w, h, mk_embedding w⟩⟩ rintro ⟨φ, ⟨hφ, rfl⟩⟩ rwa [embedding_mk_eq_of_isReal hφ] theorem isComplex_iff {w : InfinitePlace K} : IsComplex w ↔ ¬ComplexEmbedding.IsReal (embedding w) := by refine ⟨?_, fun h => ⟨embedding w, h, mk_embedding w⟩⟩ rintro ⟨φ, ⟨hφ, rfl⟩⟩ contrapose! hφ cases mk_eq_iff.mp (mk_embedding (mk φ)) with \| inl h => rwa [h] at hφ \| inr h => rwa [← ComplexEmbedding.isReal_conjugate_iff, h] at hφ @[simp] theorem conjugate_embedding_eq_of_isReal {w : InfinitePlace K} (h : IsReal w) : ComplexEmbedding.conjugate (embedding w) = embedding w := ComplexEmbedding.isReal_iff.mpr (isReal_iff.mp h) @[simp] theorem not_isReal_iff_isComplex {w : InfinitePlace K} : ¬IsReal w ↔ IsComplex w := by rw [isComplex_iff, isReal_iff] @[simp] theorem not_isComplex_iff_isReal {w : InfinitePlace K} : ¬IsComplex w ↔ IsReal w := by rw [isComplex_iff, isReal_iff, not_not] theorem isReal_or_isComplex (w : InfinitePlace K) : IsReal w ∨ IsComplex w := by rw [← not_isReal_iff_isComplex]; exact em _ theorem ne_of_isReal_isComplex {w w' : InfinitePlace K} (h : IsReal w) (h' : IsComplex w') : w ≠ w' := fun h_eq ↦ not_isReal_iff_isComplex.mpr h' (h_eq ▸ h) variable (K) in theorem disjoint_isReal_isComplex : Disjoint {(w : InfinitePlace K) \| IsReal w} {(w : InfinitePlace K) \| IsComplex w} := Set.disjoint_iff.2 <\| fun _ hw ↦ not_isReal_iff_isComplex.2 hw.2 hw.1 /-- The real embedding associated to a real infinite place. -/ noncomputable def embedding_of_isReal {w : InfinitePlace K} (hw : IsReal w) : K →+* ℝ := ComplexEmbedding.IsReal.embedding (isReal_iff.mp hw) @[simp] theorem embedding_of_isReal_apply {w : InfinitePlace K} (hw : IsReal w) (x : K) : ((embedding_of_isReal hw) x : ℂ) = (embedding w) x := ComplexEmbedding.IsReal.coe_embedding_apply (isReal_iff.mp hw) x theorem norm_embedding_of_isReal {w : InfinitePlace K} (hw : IsReal w) (x : K) : ‖embedding_of_isReal hw x‖ = w x := by rw [← norm_embedding_eq, ← embedding_of_isReal_apply hw, Complex.norm_real] @[simp] theorem isReal_of_mk_isReal {φ : K →+* ℂ} (h : IsReal (mk φ)) : ComplexEmbedding.IsReal φ := by contrapose! h rw [not_isReal_iff_isComplex] exact ⟨φ, h, rfl⟩ lemma isReal_mk_iff {φ : K →+* ℂ} : IsReal (mk φ) ↔ ComplexEmbedding.IsReal φ := ⟨isReal_of_mk_isReal, fun H ↦ ⟨_, H, rfl⟩⟩ lemma isComplex_mk_iff {φ : K →+* ℂ} : IsComplex (mk φ) ↔ ¬ ComplexEmbedding.IsReal φ := not_isReal_iff_isComplex.symm.trans isReal_mk_iff.not @[simp] theorem not_isReal_of_mk_isComplex {φ : K →+* ℂ} (h : IsComplex (mk φ)) : ¬ ComplexEmbedding.IsReal φ := by rwa [← isComplex_mk_iff] open scoped Classical in /-- The multiplicity of an infinite place, that is the number of distinct complex embeddings that define it, see `card_filter_mk_eq`. -/ noncomputable def mult (w : InfinitePlace K) : ℕ := if (IsReal w) then 1 else 2 @[simp] theorem mult_isReal (w : {w : InfinitePlace K // IsReal w}) : mult w.1 = 1 := by rw [mult, if_pos w.prop] @[simp] theorem mult_isComplex (w : {w : InfinitePlace K // IsComplex w}) : mult w.1 = 2 := by rw [mult, if_neg (not_isReal_iff_isComplex.mpr w.prop)] theorem mult_pos {w : InfinitePlace K} : 0 < mult w := by rw [mult] split_ifs <;> norm_num @[simp] theorem mult_ne_zero {w : InfinitePlace K} : mult w ≠ 0 := ne_of_gt mult_pos theorem mult_coe_ne_zero {w : InfinitePlace K} : (mult w : ℝ) ≠ 0 := Nat.cast_ne_zero.mpr mult_ne_zero theorem one_le_mult {w : InfinitePlace K} : (1 : ℝ) ≤ mult w := by rw [← Nat.cast_one, Nat.cast_le] exact mult_pos open scoped Classical in theorem card_filter_mk_eq [NumberField K] (w : InfinitePlace K) : #{φ \| mk φ = w} = mult w := by conv_lhs => congr; congr; ext rw [← mk_embedding w, mk_eq_iff, ComplexEmbedding.conjugate, star_involutive.eq_iff] simp_rw [Finset.filter_or, Finset.filter_eq' _ (embedding w), Finset.filter_eq' _ (ComplexEmbedding.conjugate (embedding w)), Finset.mem_univ, ite_true, mult] split_ifs with hw · rw [ComplexEmbedding.isReal_iff.mp (isReal_iff.mp hw), Finset.union_idempotent, Finset.card_singleton] · refine Finset.card_pair ?_ rwa [Ne, eq_comm, ← ComplexEmbedding.isReal_iff, ← isReal_iff] open scoped Classical in noncomputable instance NumberField.InfinitePlace.fintype [NumberField K] : Fintype (InfinitePlace K) := Set.fintypeRange _ open scoped Classical in @[to_additive] theorem prod_eq_prod_mul_prod {α : Type} [CommMonoid α] [NumberField K] (f : InfinitePlace K → α) : ∏ w, f w = (∏ w : {w // IsReal w}, f w.1) (∏ w : {w // IsComplex w}, f w.1) := by rw [← Equiv.prod_comp (Equiv.subtypeEquivRight (fun _ ↦ not_isReal_iff_isComplex))] simp [Fintype.prod_subtype_mul_prod_subtype] theorem sum_mult_eq [NumberField K] : ∑ w : InfinitePlace K, mult w = Module.finrank ℚ K := by classical rw [← Embeddings.card K ℂ, Fintype.card, Finset.card_eq_sum_ones, ← Finset.univ.sum_fiberwise (fun φ => InfinitePlace.mk φ)] exact Finset.sum_congr rfl (fun _ _ => by rw [Finset.sum_const, smul_eq_mul, mul_one, card_filter_mk_eq]) /-- The map from real embeddings to real infinite places as an equiv -/ noncomputable def mkReal : { φ : K →+* ℂ // ComplexEmbedding.IsReal φ } ≃ { w : InfinitePlace K // IsReal w } := by refine (Equiv.ofBijective (fun φ => ⟨mk φ, ?_⟩) ⟨fun φ ψ h => ?_, fun w => ?_⟩) · exact ⟨φ, φ.prop, rfl⟩ · rwa [Subtype.mk.injEq, mk_eq_iff, ComplexEmbedding.isReal_iff.mp φ.prop, or_self, ← Subtype.ext_iff] at h · exact ⟨⟨embedding w, isReal_iff.mp w.prop⟩, by simp⟩ /-- The map from nonreal embeddings to complex infinite places -/ noncomputable def mkComplex : { φ : K →+* ℂ // ¬ComplexEmbedding.IsReal φ } → { w : InfinitePlace K // IsComplex w } := Subtype.map mk fun φ hφ => ⟨φ, hφ, rfl⟩ @[simp] theorem mkReal_coe (φ : { φ : K →+* ℂ // ComplexEmbedding.IsReal φ }) : (mkReal φ : InfinitePlace K) = mk (φ : K →+* ℂ) := rfl @[simp] theorem mkComplex_coe (φ : { φ : K →+* ℂ // ¬ComplexEmbedding.IsReal φ }) : (mkComplex φ : InfinitePlace K) = mk (φ : K →+* ℂ) := rfl section NumberField variable [NumberField K] /-- The infinite part of the product formula : for `x ∈ K`, we have `Π_w ‖x‖_w = \|norm(x)\|` where `‖·‖_w` is the normalized absolute value for `w`. -/ theorem prod_eq_abs_norm (x : K) : ∏ w : InfinitePlace K, w x ^ mult w = abs (Algebra.norm ℚ x) := by classical convert (congr_arg (‖·‖) (@Algebra.norm_eq_prod_embeddings ℚ _ _ _ _ ℂ _ _ _ _ _ x)).symm · rw [norm_prod, ← Fintype.prod_equiv RingHom.equivRatAlgHom (fun f => ‖f x‖) (fun φ => ‖φ x‖) fun _ => by simp [RingHom.equivRatAlgHom_apply]] rw [← Finset.prod_fiberwise Finset.univ mk (fun φ => ‖φ x‖)] have (w : InfinitePlace K) (φ) (hφ : φ ∈ ({φ \| mk φ = w} : Finset _)) : ‖φ x‖ = w x := by rw [← (Finset.mem_filter.mp hφ).2, apply] simp_rw [Finset.prod_congr rfl (this _), Finset.prod_const, card_filter_mk_eq] · rw [eq_ratCast, Rat.cast_abs, ← Real.norm_eq_abs, ← Complex.norm_real, Complex.ofReal_ratCast] theorem one_le_of_lt_one {w : InfinitePlace K} {a : (𝓞 K)} (ha : a ≠ 0) (h : ∀ ⦃z⦄, z ≠ w → z a < 1) : 1 ≤ w a := by suffices (1 : ℝ) ≤ \|Algebra.norm ℚ (a : K)\| by contrapose! this rw [← InfinitePlace.prod_eq_abs_norm, ← Finset.prod_const_one] refine Finset.prod_lt_prod_of_nonempty (fun _ _ ↦ ?_) (fun z _ ↦ ?_) Finset.univ_nonempty · exact pow_pos (pos_iff.mpr ((Subalgebra.coe_eq_zero _).not.mpr ha)) _ · refine pow_lt_one₀ (apply_nonneg _ _) ?_ (by rw [mult]; split_ifs <;> norm_num) by_cases hz : z = w · rwa [hz] · exact h hz rw [← Algebra.coe_norm_int, ← Int.cast_one, ← Int.cast_abs, Rat.cast_intCast, Int.cast_le] exact Int.one_le_abs (Algebra.norm_ne_zero_iff.mpr ha) open scoped IntermediateField in theorem _root_.NumberField.is_primitive_element_of_infinitePlace_lt {x : 𝓞 K} {w : InfinitePlace K} (h₁ : x ≠ 0) (h₂ : ∀ ⦃w'⦄, w' ≠ w → w' x < 1) (h₃ : IsReal w ∨ \|(w.embedding x).re\| < 1) : ℚ⟮(x : K)⟯ = ⊤ := by rw [Field.primitive_element_iff_algHom_eq_of_eval ℚ ℂ ?_ _ w.embedding.toRatAlgHom] · intro ψ hψ have h : 1 ≤ w x := one_le_of_lt_one h₁ h₂ have main : w = InfinitePlace.mk ψ.toRingHom := by simp at hψ rw [← norm_embedding_eq, hψ] at h contrapose! h exact h₂ h.symm rw [(mk_embedding w).symm, mk_eq_iff] at main cases h₃ with \| inl hw => rw [conjugate_embedding_eq_of_isReal hw, or_self] at main exact congr_arg RingHom.toRatAlgHom main \| inr hw => refine congr_arg RingHom.toRatAlgHom (main.resolve_right fun h' ↦ hw.not_le ?_) have : (embedding w x).im = 0 := by rw [← Complex.conj_eq_iff_im] have := RingHom.congr_fun h' x simp at this rw [this] exact hψ.symm rwa [← norm_embedding_eq, ← Complex.re_add_im (embedding w x), this, Complex.ofReal_zero, zero_mul, add_zero, Complex.norm_real] at h · exact fun x ↦ IsAlgClosed.splits_codomain (minpoly ℚ x) theorem _root_.NumberField.adjoin_eq_top_of_infinitePlace_lt {x : 𝓞 K} {w : InfinitePlace K} (h₁ : x ≠ 0) (h₂ : ∀ ⦃w'⦄, w' ≠ w → w' x < 1) (h₃ : IsReal w ∨ \|(w.embedding x).re\| < 1) : Algebra.adjoin ℚ {(x : K)} = ⊤ := by rw [← IntermediateField.adjoin_simple_toSubalgebra_of_integral (IsIntegral.of_finite ℚ _)] exact congr_arg IntermediateField.toSubalgebra <\| NumberField.is_primitive_element_of_infinitePlace_lt h₁ h₂ h₃ end NumberField open Fintype Module variable (K) section NumberField variable [NumberField K] open scoped Classical in /-- The number of infinite real places of the number field `K`. -/ noncomputable abbrev nrRealPlaces := card { w : InfinitePlace K // IsReal w } @[deprecated (since := "2024-10-24")] alias NrRealPlaces := nrRealPlaces open scoped Classical in /-- The number of infinite complex places of the number field `K`. -/ noncomputable abbrev nrComplexPlaces := card { w : InfinitePlace K // IsComplex w } @[deprecated (since := "2024-10-24")] alias NrComplexPlaces := nrComplexPlaces open scoped Classical in theorem card_real_embeddings : card { φ : K →+* ℂ // ComplexEmbedding.IsReal φ } = nrRealPlaces K := Fintype.card_congr mkReal theorem card_eq_nrRealPlaces_add_nrComplexPlaces : Fintype.card (InfinitePlace K) = nrRealPlaces K + nrComplexPlaces K := by classical convert Fintype.card_subtype_or_disjoint (IsReal (K := K)) (IsComplex (K := K)) (disjoint_isReal_isComplex K) using 1 exact (Fintype.card_of_subtype _ (fun w ↦ ⟨fun _ ↦ isReal_or_isComplex w, fun _ ↦ by simp⟩)).symm open scoped Classical in theorem card_complex_embeddings : card { φ : K →+* ℂ // ¬ComplexEmbedding.IsReal φ } = 2 * nrComplexPlaces K := by suffices ∀ w : { w : InfinitePlace K // IsComplex w }, #{φ : {φ //¬ ComplexEmbedding.IsReal φ} \| mkComplex φ = w} = 2 by rw [Fintype.card, Finset.card_eq_sum_ones, ← Finset.sum_fiberwise _ (fun φ => mkComplex φ)] simp_rw [Finset.sum_const, this, smul_eq_mul, mul_one, Fintype.card, Finset.card_eq_sum_ones, Finset.mul_sum, Finset.sum_const, smul_eq_mul, mul_one] rintro ⟨w, hw⟩ convert card_filter_mk_eq w · rw [← Fintype.card_subtype, ← Fintype.card_subtype] refine Fintype.card_congr (Equiv.ofBijective ?_ ⟨fun _ _ h => ?_, fun ⟨φ, hφ⟩ => ?_⟩) · exact fun ⟨φ, hφ⟩ => ⟨φ.val, by rwa [Subtype.ext_iff] at hφ⟩ · rwa [Subtype.mk_eq_mk, ← Subtype.ext_iff, ← Subtype.ext_iff] at h · refine ⟨⟨⟨φ, not_isReal_of_mk_isComplex (hφ.symm ▸ hw)⟩, ?_⟩, rfl⟩ rwa [Subtype.ext_iff, mkComplex_coe] · simp_rw [mult, not_isReal_iff_isComplex.mpr hw, ite_false] theorem card_add_two_mul_card_eq_rank : nrRealPlaces K + 2 * nrComplexPlaces K = finrank ℚ K := by classical rw [← card_real_embeddings, ← card_complex_embeddings, Fintype.card_subtype_compl, ← Embeddings.card K ℂ, Nat.add_sub_of_le] exact Fintype.card_subtype_le _ variable {K}	theorem nrComplexPlaces_eq_zero_of_finrank_eq_one (h : finrank ℚ K = 1) : nrComplexPlaces K = 0 := by linarith [card_add_two_mul_card_eq_rank K]	Mathlib/NumberTheory/NumberField/Embeddings.lean	657	659
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Yury Kudryashov, Kexing Ying -/ import Mathlib.Topology.Semicontinuous import Mathlib.MeasureTheory.Function.AEMeasurableSequence import Mathlib.MeasureTheory.Order.Lattice import Mathlib.Topology.Order.Lattice import Mathlib.MeasureTheory.Constructions.BorelSpace.Basic /-! # Borel sigma algebras on spaces with orders ## Main statements * `borel_eq_generateFrom_Ixx` (where Ixx is one of {Iio, Ioi, Iic, Ici, Ico, Ioc}): The Borel sigma algebra of a linear order topology is generated by intervals of the given kind. * `Dense.borel_eq_generateFrom_Ico_mem`, `Dense.borel_eq_generateFrom_Ioc_mem`: The Borel sigma algebra of a dense linear order topology is generated by intervals of a given kind, with endpoints from dense subsets. * `ext_of_Ico`, `ext_of_Ioc`: A locally finite Borel measure on a second countable conditionally complete linear order is characterized by the measures of intervals of the given kind. * `ext_of_Iic`, `ext_of_Ici`: A finite Borel measure on a second countable linear order is characterized by the measures of intervals of the given kind. * `UpperSemicontinuous.measurable`, `LowerSemicontinuous.measurable`: Semicontinuous functions are measurable. * `Measurable.iSup`, `Measurable.iInf`, `Measurable.sSup`, `Measurable.sInf`: Countable supremums and infimums of measurable functions to conditionally complete linear orders are measurable. * `Measurable.liminf`, `Measurable.limsup`: Countable liminfs and limsups of measurable functions to conditionally complete linear orders are measurable. -/ open Set Filter MeasureTheory MeasurableSpace TopologicalSpace open scoped Topology NNReal ENNReal MeasureTheory universe u v w x y variable {α β γ δ : Type} {ι : Sort y} {s t u : Set α} section OrderTopology variable (α) variable [TopologicalSpace α] [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] theorem borel_eq_generateFrom_Iio : borel α = .generateFrom (range Iio) := by refine le_antisymm ?_ (generateFrom_le ?_) · rw [borel_eq_generateFrom_of_subbasis (@OrderTopology.topology_eq_generate_intervals α _ _ _)] letI : MeasurableSpace α := MeasurableSpace.generateFrom (range Iio) have H : ∀ a : α, MeasurableSet (Iio a) := fun a => GenerateMeasurable.basic _ ⟨_, rfl⟩ refine generateFrom_le ?_ rintro _ ⟨a, rfl \| rfl⟩ · rcases em (∃ b, a ⋖ b) with ⟨b, hb⟩ \| hcovBy · rw [hb.Ioi_eq, ← compl_Iio] exact (H _).compl · rcases isOpen_biUnion_countable (Ioi a) Ioi fun _ _ ↦ isOpen_Ioi with ⟨t, hat, htc, htU⟩ have : Ioi a = ⋃ b ∈ t, Ici b := by refine Subset.antisymm ?_ <\| iUnion₂_subset fun b hb ↦ Ici_subset_Ioi.2 (hat hb) refine Subset.trans ?_ <\| iUnion₂_mono fun _ _ ↦ Ioi_subset_Ici_self simpa [CovBy, htU, subset_def] using hcovBy simp only [this, ← compl_Iio] exact .biUnion htc <\| fun _ _ ↦ (H _).compl · apply H · rw [forall_mem_range] intro a exact GenerateMeasurable.basic _ isOpen_Iio theorem borel_eq_generateFrom_Ioi : borel α = .generateFrom (range Ioi) := @borel_eq_generateFrom_Iio αᵒᵈ _ (by infer_instance : SecondCountableTopology α) _ _ theorem borel_eq_generateFrom_Iic : borel α = MeasurableSpace.generateFrom (range Iic) := by rw [borel_eq_generateFrom_Ioi] refine le_antisymm ?_ ?_ · refine MeasurableSpace.generateFrom_le fun t ht => ?_ obtain ⟨u, rfl⟩ := ht rw [← compl_Iic] exact (MeasurableSpace.measurableSet_generateFrom (mem_range.mpr ⟨u, rfl⟩)).compl · refine MeasurableSpace.generateFrom_le fun t ht => ?_ obtain ⟨u, rfl⟩ := ht rw [← compl_Ioi] exact (MeasurableSpace.measurableSet_generateFrom (mem_range.mpr ⟨u, rfl⟩)).compl theorem borel_eq_generateFrom_Ici : borel α = MeasurableSpace.generateFrom (range Ici) := @borel_eq_generateFrom_Iic αᵒᵈ _ _ _ _ end OrderTopology section Orders variable [TopologicalSpace α] {mα : MeasurableSpace α} [OpensMeasurableSpace α] variable {mδ : MeasurableSpace δ} section Preorder variable [Preorder α] [OrderClosedTopology α] {a b x : α} {μ : Measure α} @[simp, measurability] theorem measurableSet_Ici : MeasurableSet (Ici a) := isClosed_Ici.measurableSet theorem nullMeasurableSet_Ici : NullMeasurableSet (Ici a) μ := measurableSet_Ici.nullMeasurableSet @[simp, measurability] theorem measurableSet_Iic : MeasurableSet (Iic a) := isClosed_Iic.measurableSet theorem nullMeasurableSet_Iic : NullMeasurableSet (Iic a) μ := measurableSet_Iic.nullMeasurableSet @[simp, measurability] theorem measurableSet_Icc : MeasurableSet (Icc a b) := isClosed_Icc.measurableSet theorem nullMeasurableSet_Icc : NullMeasurableSet (Icc a b) μ := measurableSet_Icc.nullMeasurableSet instance nhdsWithin_Ici_isMeasurablyGenerated : (𝓝[Ici b] a).IsMeasurablyGenerated := measurableSet_Ici.nhdsWithin_isMeasurablyGenerated _ instance nhdsWithin_Iic_isMeasurablyGenerated : (𝓝[Iic b] a).IsMeasurablyGenerated := measurableSet_Iic.nhdsWithin_isMeasurablyGenerated _ instance nhdsWithin_Icc_isMeasurablyGenerated : IsMeasurablyGenerated (𝓝[Icc a b] x) := by rw [← Ici_inter_Iic, nhdsWithin_inter] infer_instance instance atTop_isMeasurablyGenerated : (Filter.atTop : Filter α).IsMeasurablyGenerated := @Filter.iInf_isMeasurablyGenerated _ _ _ _ fun a => (measurableSet_Ici : MeasurableSet (Ici a)).principal_isMeasurablyGenerated instance atBot_isMeasurablyGenerated : (Filter.atBot : Filter α).IsMeasurablyGenerated := @Filter.iInf_isMeasurablyGenerated _ _ _ _ fun a => (measurableSet_Iic : MeasurableSet (Iic a)).principal_isMeasurablyGenerated instance [R1Space α] : IsMeasurablyGenerated (cocompact α) where exists_measurable_subset := by intro _ hs obtain ⟨t, ht, hts⟩ := mem_cocompact.mp hs exact ⟨(closure t)ᶜ, ht.closure.compl_mem_cocompact, isClosed_closure.measurableSet.compl, (compl_subset_compl.2 subset_closure).trans hts⟩ end Preorder section PartialOrder variable [PartialOrder α] [OrderClosedTopology α] [SecondCountableTopology α] {a b : α} @[measurability] theorem measurableSet_le' : MeasurableSet { p : α × α \| p.1 ≤ p.2 } := OrderClosedTopology.isClosed_le'.measurableSet @[measurability] theorem measurableSet_le {f g : δ → α} (hf : Measurable f) (hg : Measurable g) : MeasurableSet { a \| f a ≤ g a } := hf.prodMk hg measurableSet_le' end PartialOrder section LinearOrder variable [LinearOrder α] [OrderClosedTopology α] {a b x : α} {μ : Measure α} -- we open this locale only here to avoid issues with list being treated as intervals above open Interval @[simp, measurability] theorem measurableSet_Iio : MeasurableSet (Iio a) := isOpen_Iio.measurableSet theorem nullMeasurableSet_Iio : NullMeasurableSet (Iio a) μ := measurableSet_Iio.nullMeasurableSet @[simp, measurability] theorem measurableSet_Ioi : MeasurableSet (Ioi a) := isOpen_Ioi.measurableSet theorem nullMeasurableSet_Ioi : NullMeasurableSet (Ioi a) μ := measurableSet_Ioi.nullMeasurableSet @[simp, measurability] theorem measurableSet_Ioo : MeasurableSet (Ioo a b) := isOpen_Ioo.measurableSet theorem nullMeasurableSet_Ioo : NullMeasurableSet (Ioo a b) μ := measurableSet_Ioo.nullMeasurableSet @[simp, measurability] theorem measurableSet_Ioc : MeasurableSet (Ioc a b) := measurableSet_Ioi.inter measurableSet_Iic theorem nullMeasurableSet_Ioc : NullMeasurableSet (Ioc a b) μ := measurableSet_Ioc.nullMeasurableSet @[simp, measurability] theorem measurableSet_Ico : MeasurableSet (Ico a b) := measurableSet_Ici.inter measurableSet_Iio theorem nullMeasurableSet_Ico : NullMeasurableSet (Ico a b) μ := measurableSet_Ico.nullMeasurableSet instance nhdsWithin_Ioi_isMeasurablyGenerated : (𝓝[Ioi b] a).IsMeasurablyGenerated := measurableSet_Ioi.nhdsWithin_isMeasurablyGenerated _ instance nhdsWithin_Iio_isMeasurablyGenerated : (𝓝[Iio b] a).IsMeasurablyGenerated := measurableSet_Iio.nhdsWithin_isMeasurablyGenerated _ instance nhdsWithin_uIcc_isMeasurablyGenerated : IsMeasurablyGenerated (𝓝[[[a, b]]] x) := nhdsWithin_Icc_isMeasurablyGenerated @[measurability] theorem measurableSet_lt' [SecondCountableTopology α] : MeasurableSet { p : α × α \| p.1 < p.2 } := (isOpen_lt continuous_fst continuous_snd).measurableSet @[measurability] theorem measurableSet_lt [SecondCountableTopology α] {f g : δ → α} (hf : Measurable f) (hg : Measurable g) : MeasurableSet { a \| f a < g a } := hf.prodMk hg measurableSet_lt' theorem nullMeasurableSet_lt [SecondCountableTopology α] {μ : Measure δ} {f g : δ → α} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ) : NullMeasurableSet { a \| f a < g a } μ := (hf.prodMk hg).nullMeasurable measurableSet_lt' theorem nullMeasurableSet_lt' [SecondCountableTopology α] {μ : Measure (α × α)} : NullMeasurableSet { p : α × α \| p.1 < p.2 } μ := measurableSet_lt'.nullMeasurableSet theorem nullMeasurableSet_le [SecondCountableTopology α] {μ : Measure δ} {f g : δ → α} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ) : NullMeasurableSet { a \| f a ≤ g a } μ := (hf.prodMk hg).nullMeasurable measurableSet_le' theorem Set.OrdConnected.measurableSet (h : OrdConnected s) : MeasurableSet s := by let u := ⋃ (x ∈ s) (y ∈ s), Ioo x y have huopen : IsOpen u := isOpen_biUnion fun _ _ => isOpen_biUnion fun _ _ => isOpen_Ioo have humeas : MeasurableSet u := huopen.measurableSet have hfinite : (s \ u).Finite := s.finite_diff_iUnion_Ioo have : u ⊆ s := iUnion₂_subset fun x hx => iUnion₂_subset fun y hy => Ioo_subset_Icc_self.trans (h.out hx hy) rw [← union_diff_cancel this] exact humeas.union hfinite.measurableSet theorem IsPreconnected.measurableSet (h : IsPreconnected s) : MeasurableSet s := h.ordConnected.measurableSet theorem generateFrom_Ico_mem_le_borel {α : Type} [TopologicalSpace α] [LinearOrder α] [OrderClosedTopology α] (s t : Set α) : MeasurableSpace.generateFrom { S \| ∃ l ∈ s, ∃ u ∈ t, l < u ∧ Ico l u = S } ≤ borel α := by apply generateFrom_le borelize α rintro _ ⟨a, -, b, -, -, rfl⟩ exact measurableSet_Ico theorem Dense.borel_eq_generateFrom_Ico_mem_aux {α : Type} [TopologicalSpace α] [LinearOrder α] [OrderTopology α] [SecondCountableTopology α] {s : Set α} (hd : Dense s) (hbot : ∀ x, IsBot x → x ∈ s) (hIoo : ∀ x y : α, x < y → Ioo x y = ∅ → y ∈ s) : borel α = .generateFrom { S : Set α \| ∃ l ∈ s, ∃ u ∈ s, l < u ∧ Ico l u = S } := by set S : Set (Set α) := { S \| ∃ l ∈ s, ∃ u ∈ s, l < u ∧ Ico l u = S } refine le_antisymm ?_ (generateFrom_Ico_mem_le_borel _ _) letI : MeasurableSpace α := generateFrom S rw [borel_eq_generateFrom_Iio] refine generateFrom_le (forall_mem_range.2 fun a => ?_) rcases hd.exists_countable_dense_subset_bot_top with ⟨t, hts, hc, htd, htb, -⟩ by_cases ha : ∀ b < a, (Ioo b a).Nonempty · convert_to MeasurableSet (⋃ (l ∈ t) (u ∈ t) (_ : l < u) (_ : u ≤ a), Ico l u) · ext y simp only [mem_iUnion, mem_Iio, mem_Ico] constructor · intro hy rcases htd.exists_le' (fun b hb => htb _ hb (hbot b hb)) y with ⟨l, hlt, hly⟩ rcases htd.exists_mem_open isOpen_Ioo (ha y hy) with ⟨u, hut, hyu, hua⟩ exact ⟨l, hlt, u, hut, hly.trans_lt hyu, hua.le, hly, hyu⟩ · rintro ⟨l, -, u, -, -, hua, -, hyu⟩ exact hyu.trans_le hua · refine MeasurableSet.biUnion hc fun a ha => MeasurableSet.biUnion hc fun b hb => ?_ refine MeasurableSet.iUnion fun hab => MeasurableSet.iUnion fun _ => ?_ exact .basic _ ⟨a, hts ha, b, hts hb, hab, mem_singleton _⟩ · simp only [not_forall, not_nonempty_iff_eq_empty] at ha replace ha : a ∈ s := hIoo ha.choose a ha.choose_spec.fst ha.choose_spec.snd convert_to MeasurableSet (⋃ (l ∈ t) (_ : l < a), Ico l a) · symm simp only [← Ici_inter_Iio, ← iUnion_inter, inter_eq_right, subset_def, mem_iUnion, mem_Ici, mem_Iio] intro x hx rcases htd.exists_le' (fun b hb => htb _ hb (hbot b hb)) x with ⟨z, hzt, hzx⟩ exact ⟨z, hzt, hzx.trans_lt hx, hzx⟩ · refine .biUnion hc fun x hx => MeasurableSet.iUnion fun hlt => ?_ exact .basic _ ⟨x, hts hx, a, ha, hlt, mem_singleton _⟩ theorem Dense.borel_eq_generateFrom_Ico_mem {α : Type} [TopologicalSpace α] [LinearOrder α] [OrderTopology α] [SecondCountableTopology α] [DenselyOrdered α] [NoMinOrder α] {s : Set α} (hd : Dense s) : borel α = .generateFrom { S : Set α \| ∃ l ∈ s, ∃ u ∈ s, l < u ∧ Ico l u = S } := hd.borel_eq_generateFrom_Ico_mem_aux (by simp) fun _ _ hxy H => ((nonempty_Ioo.2 hxy).ne_empty H).elim theorem borel_eq_generateFrom_Ico (α : Type) [TopologicalSpace α] [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] : borel α = .generateFrom { S : Set α \| ∃ (l u : α), l < u ∧ Ico l u = S } := by simpa only [exists_prop, mem_univ, true_and] using (@dense_univ α _).borel_eq_generateFrom_Ico_mem_aux (fun _ _ => mem_univ _) fun _ _ _ _ => mem_univ _ theorem Dense.borel_eq_generateFrom_Ioc_mem_aux {α : Type} [TopologicalSpace α] [LinearOrder α] [OrderTopology α] [SecondCountableTopology α] {s : Set α} (hd : Dense s) (hbot : ∀ x, IsTop x → x ∈ s) (hIoo : ∀ x y : α, x < y → Ioo x y = ∅ → x ∈ s) : borel α = .generateFrom { S : Set α \| ∃ l ∈ s, ∃ u ∈ s, l < u ∧ Ioc l u = S } := by convert hd.orderDual.borel_eq_generateFrom_Ico_mem_aux hbot fun x y hlt he => hIoo y x hlt _ using 2 · ext s constructor <;> rintro ⟨l, hl, u, hu, hlt, rfl⟩ exacts [⟨u, hu, l, hl, hlt, Ico_toDual⟩, ⟨u, hu, l, hl, hlt, Ioc_toDual⟩] · erw [Ioo_toDual] exact he theorem Dense.borel_eq_generateFrom_Ioc_mem {α : Type} [TopologicalSpace α] [LinearOrder α] [OrderTopology α] [SecondCountableTopology α] [DenselyOrdered α] [NoMaxOrder α] {s : Set α} (hd : Dense s) : borel α = .generateFrom { S : Set α \| ∃ l ∈ s, ∃ u ∈ s, l < u ∧ Ioc l u = S } := hd.borel_eq_generateFrom_Ioc_mem_aux (by simp) fun _ _ hxy H => ((nonempty_Ioo.2 hxy).ne_empty H).elim theorem borel_eq_generateFrom_Ioc (α : Type) [TopologicalSpace α] [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] : borel α = .generateFrom { S : Set α \| ∃ l u, l < u ∧ Ioc l u = S } := by simpa only [exists_prop, mem_univ, true_and] using (@dense_univ α _).borel_eq_generateFrom_Ioc_mem_aux (fun _ _ => mem_univ _) fun _ _ _ _ => mem_univ _ namespace MeasureTheory.Measure /-- Two finite measures on a Borel space are equal if they agree on all closed-open intervals. If `α` is a conditionally complete linear order with no top element, `MeasureTheory.Measure.ext_of_Ico` is an extensionality lemma with weaker assumptions on `μ` and `ν`. -/ theorem ext_of_Ico_finite {α : Type} [TopologicalSpace α] {m : MeasurableSpace α} [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] [BorelSpace α] (μ ν : Measure α) [IsFiniteMeasure μ] (hμν : μ univ = ν univ) (h : ∀ ⦃a b⦄, a < b → μ (Ico a b) = ν (Ico a b)) : μ = ν := by refine ext_of_generate_finite _ (BorelSpace.measurable_eq.trans (borel_eq_generateFrom_Ico α)) (isPiSystem_Ico (id : α → α) id) ?_ hμν rintro - ⟨a, b, hlt, rfl⟩ exact h hlt /-- Two finite measures on a Borel space are equal if they agree on all open-closed intervals. If `α` is a conditionally complete linear order with no top element, `MeasureTheory.Measure.ext_of_Ioc` is an extensionality lemma with weaker assumptions on `μ` and `ν`. -/ theorem ext_of_Ioc_finite {α : Type} [TopologicalSpace α] {m : MeasurableSpace α} [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] [BorelSpace α] (μ ν : Measure α) [IsFiniteMeasure μ] (hμν : μ univ = ν univ) (h : ∀ ⦃a b⦄, a < b → μ (Ioc a b) = ν (Ioc a b)) : μ = ν := by refine @ext_of_Ico_finite αᵒᵈ _ _ _ _ _ ‹_› μ ν _ hμν fun a b hab => ?_ erw [Ico_toDual (α := α)] exact h hab /-- Two measures which are finite on closed-open intervals are equal if they agree on all closed-open intervals. -/ theorem ext_of_Ico' {α : Type} [TopologicalSpace α] {m : MeasurableSpace α} [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] [BorelSpace α] [NoMaxOrder α] (μ ν : Measure α) (hμ : ∀ ⦃a b⦄, a < b → μ (Ico a b) ≠ ∞) (h : ∀ ⦃a b⦄, a < b → μ (Ico a b) = ν (Ico a b)) : μ = ν := by rcases exists_countable_dense_bot_top α with ⟨s, hsc, hsd, hsb, _⟩ have : (⋃ (l ∈ s) (u ∈ s) (_ : l < u), {Ico l u} : Set (Set α)).Countable := hsc.biUnion fun l _ => hsc.biUnion fun u _ => countable_iUnion fun _ => countable_singleton _ simp only [← setOf_eq_eq_singleton, ← setOf_exists] at this refine Measure.ext_of_generateFrom_of_cover_subset (BorelSpace.measurable_eq.trans (borel_eq_generateFrom_Ico α)) (isPiSystem_Ico id id) ?_ this ?_ ?_ ?_ · rintro _ ⟨l, -, u, -, h, rfl⟩ exact ⟨l, u, h, rfl⟩ · refine sUnion_eq_univ_iff.2 fun x => ?_ rcases hsd.exists_le' hsb x with ⟨l, hls, hlx⟩ rcases hsd.exists_gt x with ⟨u, hus, hxu⟩ exact ⟨_, ⟨l, hls, u, hus, hlx.trans_lt hxu, rfl⟩, hlx, hxu⟩ · rintro _ ⟨l, -, u, -, hlt, rfl⟩ exact hμ hlt · rintro _ ⟨l, u, hlt, rfl⟩ exact h hlt /-- Two measures which are finite on closed-open intervals are equal if they agree on all open-closed intervals. -/ theorem ext_of_Ioc' {α : Type} [TopologicalSpace α] {m : MeasurableSpace α} [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] [BorelSpace α] [NoMinOrder α] (μ ν : Measure α) (hμ : ∀ ⦃a b⦄, a < b → μ (Ioc a b) ≠ ∞) (h : ∀ ⦃a b⦄, a < b → μ (Ioc a b) = ν (Ioc a b)) : μ = ν := by refine @ext_of_Ico' αᵒᵈ _ _ _ _ _ ‹_› _ μ ν ?_ ?_ <;> intro a b hab <;> erw [Ico_toDual (α := α)] exacts [hμ hab, h hab] /-- Two measures which are finite on closed-open intervals are equal if they agree on all closed-open intervals. -/ theorem ext_of_Ico {α : Type} [TopologicalSpace α] {_m : MeasurableSpace α} [SecondCountableTopology α] [ConditionallyCompleteLinearOrder α] [OrderTopology α] [BorelSpace α] [NoMaxOrder α] (μ ν : Measure α) [IsLocallyFiniteMeasure μ] (h : ∀ ⦃a b⦄, a < b → μ (Ico a b) = ν (Ico a b)) : μ = ν := μ.ext_of_Ico' ν (fun _ _ _ => measure_Ico_lt_top.ne) h /-- Two measures which are finite on closed-open intervals are equal if they agree on all open-closed intervals. -/ theorem ext_of_Ioc {α : Type} [TopologicalSpace α] {_m : MeasurableSpace α} [SecondCountableTopology α] [ConditionallyCompleteLinearOrder α] [OrderTopology α] [BorelSpace α] [NoMinOrder α] (μ ν : Measure α) [IsLocallyFiniteMeasure μ] (h : ∀ ⦃a b⦄, a < b → μ (Ioc a b) = ν (Ioc a b)) : μ = ν := μ.ext_of_Ioc' ν (fun _ _ _ => measure_Ioc_lt_top.ne) h /-- Two finite measures on a Borel space are equal if they agree on all left-infinite right-closed intervals. -/ theorem ext_of_Iic {α : Type} [TopologicalSpace α] {m : MeasurableSpace α} [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] [BorelSpace α] (μ ν : Measure α) [IsFiniteMeasure μ] (h : ∀ a, μ (Iic a) = ν (Iic a)) : μ = ν := by refine ext_of_Ioc_finite μ ν ?_ fun a b hlt => ?_ · rcases exists_countable_dense_bot_top α with ⟨s, hsc, hsd, -, hst⟩ have : DirectedOn (· ≤ ·) s := directedOn_iff_directed.2 (Subtype.mono_coe _).directed_le simp only [← biSup_measure_Iic hsc (hsd.exists_ge' hst) this, h] rw [← Iic_diff_Iic, measure_diff (Iic_subset_Iic.2 hlt.le) nullMeasurableSet_Iic, measure_diff (Iic_subset_Iic.2 hlt.le) nullMeasurableSet_Iic, h a, h b] · rw [← h a] exact measure_ne_top μ _ · exact measure_ne_top μ _ /-- Two finite measures on a Borel space are equal if they agree on all left-closed right-infinite intervals. -/ theorem ext_of_Ici {α : Type} [TopologicalSpace α] {_ : MeasurableSpace α} [SecondCountableTopology α] [LinearOrder α] [OrderTopology α] [BorelSpace α] (μ ν : Measure α) [IsFiniteMeasure μ] (h : ∀ a, μ (Ici a) = ν (Ici a)) : μ = ν := @ext_of_Iic αᵒᵈ _ _ _ _ _ ‹_› _ _ _ h end MeasureTheory.Measure @[measurability] theorem measurableSet_uIcc : MeasurableSet (uIcc a b) := measurableSet_Icc @[measurability] theorem measurableSet_uIoc : MeasurableSet (uIoc a b) := measurableSet_Ioc variable [SecondCountableTopology α] @[measurability, fun_prop] theorem Measurable.max {f g : δ → α} (hf : Measurable f) (hg : Measurable g) : Measurable fun a => max (f a) (g a) := by simpa only [max_def'] using hf.piecewise (measurableSet_le hg hf) hg @[measurability, fun_prop] nonrec theorem AEMeasurable.max {f g : δ → α} {μ : Measure δ} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ) : AEMeasurable (fun a => max (f a) (g a)) μ := ⟨fun a => max (hf.mk f a) (hg.mk g a), hf.measurable_mk.max hg.measurable_mk, EventuallyEq.comp₂ hf.ae_eq_mk _ hg.ae_eq_mk⟩ @[measurability, fun_prop] theorem Measurable.min {f g : δ → α} (hf : Measurable f) (hg : Measurable g) : Measurable fun a => min (f a) (g a) := by simpa only [min_def] using hf.piecewise (measurableSet_le hf hg) hg @[measurability, fun_prop] nonrec theorem AEMeasurable.min {f g : δ → α} {μ : Measure δ} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ) : AEMeasurable (fun a => min (f a) (g a)) μ := ⟨fun a => min (hf.mk f a) (hg.mk g a), hf.measurable_mk.min hg.measurable_mk, EventuallyEq.comp₂ hf.ae_eq_mk _ hg.ae_eq_mk⟩ end LinearOrder section Lattice variable [TopologicalSpace γ] {mγ : MeasurableSpace γ} [BorelSpace γ] instance (priority := 100) ContinuousSup.measurableSup [Max γ] [ContinuousSup γ] : MeasurableSup γ where measurable_const_sup _ := (continuous_const.sup continuous_id).measurable measurable_sup_const _ := (continuous_id.sup continuous_const).measurable instance (priority := 100) ContinuousSup.measurableSup₂ [SecondCountableTopology γ] [Max γ] [ContinuousSup γ] : MeasurableSup₂ γ := ⟨continuous_sup.measurable⟩ instance (priority := 100) ContinuousInf.measurableInf [Min γ] [ContinuousInf γ] : MeasurableInf γ where measurable_const_inf _ := (continuous_const.inf continuous_id).measurable measurable_inf_const _ := (continuous_id.inf continuous_const).measurable instance (priority := 100) ContinuousInf.measurableInf₂ [SecondCountableTopology γ] [Min γ] [ContinuousInf γ] : MeasurableInf₂ γ := ⟨continuous_inf.measurable⟩ end Lattice end Orders section BorelSpace variable [TopologicalSpace α] {mα : MeasurableSpace α} [BorelSpace α] variable [TopologicalSpace β] {mβ : MeasurableSpace β} [BorelSpace β] variable {mδ : MeasurableSpace δ} section LinearOrder variable [LinearOrder α] [OrderTopology α] [SecondCountableTopology α] theorem measurable_of_Iio {f : δ → α} (hf : ∀ x, MeasurableSet (f ⁻¹' Iio x)) : Measurable f := by convert measurable_generateFrom (α := δ) _ · exact BorelSpace.measurable_eq.trans (borel_eq_generateFrom_Iio _) · rintro _ ⟨x, rfl⟩; exact hf x theorem UpperSemicontinuous.measurable [TopologicalSpace δ] [OpensMeasurableSpace δ] {f : δ → α} (hf : UpperSemicontinuous f) : Measurable f := measurable_of_Iio fun y => (hf.isOpen_preimage y).measurableSet theorem measurable_of_Ioi {f : δ → α} (hf : ∀ x, MeasurableSet (f ⁻¹' Ioi x)) : Measurable f := by convert measurable_generateFrom (α := δ) _ · exact BorelSpace.measurable_eq.trans (borel_eq_generateFrom_Ioi _) · rintro _ ⟨x, rfl⟩; exact hf x theorem LowerSemicontinuous.measurable [TopologicalSpace δ] [OpensMeasurableSpace δ] {f : δ → α} (hf : LowerSemicontinuous f) : Measurable f := measurable_of_Ioi fun y => (hf.isOpen_preimage y).measurableSet theorem measurable_of_Iic {f : δ → α} (hf : ∀ x, MeasurableSet (f ⁻¹' Iic x)) : Measurable f := by apply measurable_of_Ioi simp_rw [← compl_Iic, preimage_compl, MeasurableSet.compl_iff] assumption theorem measurable_of_Ici {f : δ → α} (hf : ∀ x, MeasurableSet (f ⁻¹' Ici x)) : Measurable f := by apply measurable_of_Iio simp_rw [← compl_Ici, preimage_compl, MeasurableSet.compl_iff] assumption /-- If a function is the least upper bound of countably many measurable functions, then it is measurable. -/ theorem Measurable.isLUB {ι} [Countable ι] {f : ι → δ → α} {g : δ → α} (hf : ∀ i, Measurable (f i)) (hg : ∀ b, IsLUB { a \| ∃ i, f i b = a } (g b)) : Measurable g := by change ∀ b, IsLUB (range fun i => f i b) (g b) at hg rw [‹BorelSpace α›.measurable_eq, borel_eq_generateFrom_Ioi α] apply measurable_generateFrom rintro _ ⟨a, rfl⟩ simp_rw [Set.preimage, mem_Ioi, lt_isLUB_iff (hg _), exists_range_iff, setOf_exists] exact MeasurableSet.iUnion fun i => hf i (isOpen_lt' _).measurableSet /-- If a function is the least upper bound of countably many measurable functions on a measurable set `s`, and coincides with a measurable function outside of `s`, then it is measurable. -/ theorem Measurable.isLUB_of_mem {ι} [Countable ι] {f : ι → δ → α} {g g' : δ → α} (hf : ∀ i, Measurable (f i)) {s : Set δ} (hs : MeasurableSet s) (hg : ∀ b ∈ s, IsLUB { a \| ∃ i, f i b = a } (g b)) (hg' : EqOn g g' sᶜ) (g'_meas : Measurable g') : Measurable g := by classical rcases isEmpty_or_nonempty ι with hι\|⟨⟨i⟩⟩ · rcases eq_empty_or_nonempty s with rfl\|⟨x, hx⟩ · convert g'_meas rwa [compl_empty, eqOn_univ] at hg' · have A : ∀ b ∈ s, IsBot (g b) := by simpa using hg have B : ∀ b ∈ s, g b = g x := by intro b hb apply le_antisymm (A b hb (g x)) (A x hx (g b)) have : g = s.piecewise (fun _y ↦ g x) g' := by ext b by_cases hb : b ∈ s · simp [hb, B] · simp [hb, hg' hb] rw [this] exact Measurable.piecewise hs measurable_const g'_meas · have : Nonempty ι := ⟨i⟩ let f' : ι → δ → α := fun i ↦ s.piecewise (f i) g' suffices ∀ b, IsLUB { a \| ∃ i, f' i b = a } (g b) from Measurable.isLUB (fun i ↦ Measurable.piecewise hs (hf i) g'_meas) this intro b by_cases hb : b ∈ s · have A : ∀ i, f' i b = f i b := fun i ↦ by simp [f', hb] simpa [A] using hg b hb · have A : ∀ i, f' i b = g' b := fun i ↦ by simp [f', hb] simp [A, hg' hb, isLUB_singleton] theorem AEMeasurable.isLUB {ι} {μ : Measure δ} [Countable ι] {f : ι → δ → α} {g : δ → α} (hf : ∀ i, AEMeasurable (f i) μ) (hg : ∀ᵐ b ∂μ, IsLUB { a \| ∃ i, f i b = a } (g b)) : AEMeasurable g μ := by classical nontriviality α haveI hα : Nonempty α := inferInstance rcases isEmpty_or_nonempty ι with hι \| hι · simp only [IsEmpty.exists_iff, setOf_false, isLUB_empty_iff] at hg exact aemeasurable_const' (hg.mono fun a ha => hg.mono fun b hb => (ha _).antisymm (hb _)) let p : δ → (ι → α) → Prop := fun x f' => IsLUB { a \| ∃ i, f' i = a } (g x) let g_seq := (aeSeqSet hf p).piecewise g fun _ => hα.some have hg_seq : ∀ b, IsLUB { a \| ∃ i, aeSeq hf p i b = a } (g_seq b) := by intro b simp only [g_seq, aeSeq, Set.piecewise] split_ifs with h · have h_set_eq : { a : α \| ∃ i : ι, (hf i).mk (f i) b = a } = { a : α \| ∃ i : ι, f i b = a } := by ext x simp_rw [Set.mem_setOf_eq, aeSeq.mk_eq_fun_of_mem_aeSeqSet hf h] rw [h_set_eq] exact aeSeq.fun_prop_of_mem_aeSeqSet hf h · exact IsGreatest.isLUB ⟨(@exists_const (hα.some = hα.some) ι _).2 rfl, fun x ⟨i, hi⟩ => hi.ge⟩ refine ⟨g_seq, Measurable.isLUB (aeSeq.measurable hf p) hg_seq, ?_⟩ exact (ite_ae_eq_of_measure_compl_zero g (fun _ => hα.some) (aeSeqSet hf p) (aeSeq.measure_compl_aeSeqSet_eq_zero hf hg)).symm /-- If a function is the greatest lower bound of countably many measurable functions, then it is measurable. -/ theorem Measurable.isGLB {ι} [Countable ι] {f : ι → δ → α} {g : δ → α} (hf : ∀ i, Measurable (f i)) (hg : ∀ b, IsGLB { a \| ∃ i, f i b = a } (g b)) : Measurable g := Measurable.isLUB (α := αᵒᵈ) hf hg /-- If a function is the greatest lower bound of countably many measurable functions on a measurable set `s`, and coincides with a measurable function outside of `s`, then it is measurable. -/ theorem Measurable.isGLB_of_mem {ι} [Countable ι] {f : ι → δ → α} {g g' : δ → α} (hf : ∀ i, Measurable (f i)) {s : Set δ} (hs : MeasurableSet s) (hg : ∀ b ∈ s, IsGLB { a \| ∃ i, f i b = a } (g b)) (hg' : EqOn g g' sᶜ) (g'_meas : Measurable g') : Measurable g := Measurable.isLUB_of_mem (α := αᵒᵈ) hf hs hg hg' g'_meas	theorem AEMeasurable.isGLB {ι} {μ : Measure δ} [Countable ι] {f : ι → δ → α} {g : δ → α} (hf : ∀ i, AEMeasurable (f i) μ) (hg : ∀ᵐ b ∂μ, IsGLB { a \| ∃ i, f i b = a } (g b)) : AEMeasurable g μ := AEMeasurable.isLUB (α := αᵒᵈ) hf hg protected theorem Monotone.measurable [LinearOrder β] [OrderClosedTopology β] {f : β → α} (hf : Monotone f) : Measurable f := suffices h : ∀ x, OrdConnected (f ⁻¹' Ioi x) from measurable_of_Ioi fun x => (h x).measurableSet fun _ => ordConnected_def.mpr fun _a ha _ _ _c hc => lt_of_lt_of_le ha (hf hc.1) theorem aemeasurable_restrict_of_monotoneOn [LinearOrder β] [OrderClosedTopology β] {μ : Measure β} {s : Set β} (hs : MeasurableSet s) {f : β → α} (hf : MonotoneOn f s) : AEMeasurable f (μ.restrict s) := have : Monotone (f ∘ (↑) : s → α) := fun ⟨x, hx⟩ ⟨y, hy⟩ => fun (hxy : x ≤ y) => hf hx hy hxy aemeasurable_restrict_of_measurable_subtype hs this.measurable protected theorem Antitone.measurable [LinearOrder β] [OrderClosedTopology β] {f : β → α} (hf : Antitone f) : Measurable f := @Monotone.measurable αᵒᵈ β _ _ ‹_› _ _ _ _ _ ‹_› _ _ _ hf theorem aemeasurable_restrict_of_antitoneOn [LinearOrder β] [OrderClosedTopology β] {μ : Measure β} {s : Set β} (hs : MeasurableSet s) {f : β → α} (hf : AntitoneOn f s) : AEMeasurable f (μ.restrict s) := @aemeasurable_restrict_of_monotoneOn αᵒᵈ β _ _ ‹_› _ _ _ _ _ ‹_› _ _ _ _ hs _ hf	Mathlib/MeasureTheory/Constructions/BorelSpace/Order.lean	623	647
/- Copyright (c) 2022 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers -/ import Mathlib.Algebra.CharP.Invertible import Mathlib.Algebra.Order.Interval.Set.Group import Mathlib.Analysis.Convex.Basic import Mathlib.Analysis.Convex.Segment import Mathlib.LinearAlgebra.AffineSpace.FiniteDimensional import Mathlib.Tactic.FieldSimp /-! # Betweenness in affine spaces This file defines notions of a point in an affine space being between two given points. ## Main definitions * `affineSegment R x y`: The segment of points weakly between `x` and `y`. * `Wbtw R x y z`: The point `y` is weakly between `x` and `z`. * `Sbtw R x y z`: The point `y` is strictly between `x` and `z`. -/ variable (R : Type) {V V' P P' : Type} open AffineEquiv AffineMap section OrderedRing /-- The segment of points weakly between `x` and `y`. When convexity is refactored to support abstract affine combination spaces, this will no longer need to be a separate definition from `segment`. However, lemmas involving `+ᵥ` or `-ᵥ` will still be relevant after such a refactoring, as distinct from versions involving `+` or `-` in a module. -/ def affineSegment [Ring R] [PartialOrder R] [AddCommGroup V] [Module R V] [AddTorsor V P] (x y : P) := lineMap x y '' Set.Icc (0 : R) 1 variable [Ring R] [PartialOrder R] [AddCommGroup V] [Module R V] [AddTorsor V P] variable [AddCommGroup V'] [Module R V'] [AddTorsor V' P'] variable {R} in @[simp] theorem affineSegment_image (f : P →ᵃ[R] P') (x y : P) : f '' affineSegment R x y = affineSegment R (f x) (f y) := by rw [affineSegment, affineSegment, Set.image_image, ← comp_lineMap] rfl @[simp] theorem affineSegment_const_vadd_image (x y : P) (v : V) : (v +ᵥ ·) '' affineSegment R x y = affineSegment R (v +ᵥ x) (v +ᵥ y) := affineSegment_image (AffineEquiv.constVAdd R P v : P →ᵃ[R] P) x y @[simp] theorem affineSegment_vadd_const_image (x y : V) (p : P) : (· +ᵥ p) '' affineSegment R x y = affineSegment R (x +ᵥ p) (y +ᵥ p) := affineSegment_image (AffineEquiv.vaddConst R p : V →ᵃ[R] P) x y @[simp] theorem affineSegment_const_vsub_image (x y p : P) : (p -ᵥ ·) '' affineSegment R x y = affineSegment R (p -ᵥ x) (p -ᵥ y) := affineSegment_image (AffineEquiv.constVSub R p : P →ᵃ[R] V) x y @[simp] theorem affineSegment_vsub_const_image (x y p : P) : (· -ᵥ p) '' affineSegment R x y = affineSegment R (x -ᵥ p) (y -ᵥ p) := affineSegment_image ((AffineEquiv.vaddConst R p).symm : P →ᵃ[R] V) x y variable {R} @[simp] theorem mem_const_vadd_affineSegment {x y z : P} (v : V) : v +ᵥ z ∈ affineSegment R (v +ᵥ x) (v +ᵥ y) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_const_vadd_image, (AddAction.injective v).mem_set_image] @[simp] theorem mem_vadd_const_affineSegment {x y z : V} (p : P) : z +ᵥ p ∈ affineSegment R (x +ᵥ p) (y +ᵥ p) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_vadd_const_image, (vadd_right_injective p).mem_set_image] @[simp] theorem mem_const_vsub_affineSegment {x y z : P} (p : P) : p -ᵥ z ∈ affineSegment R (p -ᵥ x) (p -ᵥ y) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_const_vsub_image, (vsub_right_injective p).mem_set_image] @[simp] theorem mem_vsub_const_affineSegment {x y z : P} (p : P) : z -ᵥ p ∈ affineSegment R (x -ᵥ p) (y -ᵥ p) ↔ z ∈ affineSegment R x y := by rw [← affineSegment_vsub_const_image, (vsub_left_injective p).mem_set_image] variable (R) section OrderedRing variable [IsOrderedRing R] theorem affineSegment_eq_segment (x y : V) : affineSegment R x y = segment R x y := by rw [segment_eq_image_lineMap, affineSegment] theorem affineSegment_comm (x y : P) : affineSegment R x y = affineSegment R y x := by refine Set.ext fun z => ?_ constructor <;> · rintro ⟨t, ht, hxy⟩ refine ⟨1 - t, ?_, ?_⟩ · rwa [Set.sub_mem_Icc_iff_right, sub_self, sub_zero] · rwa [lineMap_apply_one_sub] theorem left_mem_affineSegment (x y : P) : x ∈ affineSegment R x y := ⟨0, Set.left_mem_Icc.2 zero_le_one, lineMap_apply_zero _ _⟩ theorem right_mem_affineSegment (x y : P) : y ∈ affineSegment R x y := ⟨1, Set.right_mem_Icc.2 zero_le_one, lineMap_apply_one _ _⟩ @[simp] theorem affineSegment_same (x : P) : affineSegment R x x = {x} := by simp_rw [affineSegment, lineMap_same, AffineMap.coe_const, Function.const, (Set.nonempty_Icc.mpr zero_le_one).image_const] end OrderedRing /-- The point `y` is weakly between `x` and `z`. -/ def Wbtw (x y z : P) : Prop := y ∈ affineSegment R x z /-- The point `y` is strictly between `x` and `z`. -/ def Sbtw (x y z : P) : Prop := Wbtw R x y z ∧ y ≠ x ∧ y ≠ z variable {R} section OrderedRing variable [IsOrderedRing R] lemma mem_segment_iff_wbtw {x y z : V} : y ∈ segment R x z ↔ Wbtw R x y z := by rw [Wbtw, affineSegment_eq_segment] alias ⟨_, Wbtw.mem_segment⟩ := mem_segment_iff_wbtw lemma Convex.mem_of_wbtw {p₀ p₁ p₂ : V} {s : Set V} (hs : Convex R s) (h₀₁₂ : Wbtw R p₀ p₁ p₂) (h₀ : p₀ ∈ s) (h₂ : p₂ ∈ s) : p₁ ∈ s := hs.segment_subset h₀ h₂ h₀₁₂.mem_segment theorem wbtw_comm {x y z : P} : Wbtw R x y z ↔ Wbtw R z y x := by rw [Wbtw, Wbtw, affineSegment_comm] alias ⟨Wbtw.symm, _⟩ := wbtw_comm theorem sbtw_comm {x y z : P} : Sbtw R x y z ↔ Sbtw R z y x := by rw [Sbtw, Sbtw, wbtw_comm, ← and_assoc, ← and_assoc, and_right_comm] alias ⟨Sbtw.symm, _⟩ := sbtw_comm end OrderedRing lemma AffineSubspace.mem_of_wbtw {s : AffineSubspace R P} {x y z : P} (hxyz : Wbtw R x y z) (hx : x ∈ s) (hz : z ∈ s) : y ∈ s := by obtain ⟨ε, -, rfl⟩ := hxyz; exact lineMap_mem _ hx hz theorem Wbtw.map {x y z : P} (h : Wbtw R x y z) (f : P →ᵃ[R] P') : Wbtw R (f x) (f y) (f z) := by rw [Wbtw, ← affineSegment_image] exact Set.mem_image_of_mem _ h theorem Function.Injective.wbtw_map_iff {x y z : P} {f : P →ᵃ[R] P'} (hf : Function.Injective f) : Wbtw R (f x) (f y) (f z) ↔ Wbtw R x y z := by refine ⟨fun h => ?_, fun h => h.map _⟩ rwa [Wbtw, ← affineSegment_image, hf.mem_set_image] at h theorem Function.Injective.sbtw_map_iff {x y z : P} {f : P →ᵃ[R] P'} (hf : Function.Injective f) : Sbtw R (f x) (f y) (f z) ↔ Sbtw R x y z := by simp_rw [Sbtw, hf.wbtw_map_iff, hf.ne_iff] @[simp] theorem AffineEquiv.wbtw_map_iff {x y z : P} (f : P ≃ᵃ[R] P') : Wbtw R (f x) (f y) (f z) ↔ Wbtw R x y z := by have : Function.Injective f.toAffineMap := f.injective -- `refine` or `exact` are very slow, `apply` is fast. Please check before golfing. apply this.wbtw_map_iff @[simp] theorem AffineEquiv.sbtw_map_iff {x y z : P} (f : P ≃ᵃ[R] P') : Sbtw R (f x) (f y) (f z) ↔ Sbtw R x y z := by have : Function.Injective f.toAffineMap := f.injective -- `refine` or `exact` are very slow, `apply` is fast. Please check before golfing. apply this.sbtw_map_iff @[simp] theorem wbtw_const_vadd_iff {x y z : P} (v : V) : Wbtw R (v +ᵥ x) (v +ᵥ y) (v +ᵥ z) ↔ Wbtw R x y z := mem_const_vadd_affineSegment _ @[simp] theorem wbtw_vadd_const_iff {x y z : V} (p : P) : Wbtw R (x +ᵥ p) (y +ᵥ p) (z +ᵥ p) ↔ Wbtw R x y z := mem_vadd_const_affineSegment _ @[simp] theorem wbtw_const_vsub_iff {x y z : P} (p : P) : Wbtw R (p -ᵥ x) (p -ᵥ y) (p -ᵥ z) ↔ Wbtw R x y z := mem_const_vsub_affineSegment _ @[simp] theorem wbtw_vsub_const_iff {x y z : P} (p : P) : Wbtw R (x -ᵥ p) (y -ᵥ p) (z -ᵥ p) ↔ Wbtw R x y z := mem_vsub_const_affineSegment _ @[simp] theorem sbtw_const_vadd_iff {x y z : P} (v : V) : Sbtw R (v +ᵥ x) (v +ᵥ y) (v +ᵥ z) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_const_vadd_iff, (AddAction.injective v).ne_iff, (AddAction.injective v).ne_iff] @[simp] theorem sbtw_vadd_const_iff {x y z : V} (p : P) : Sbtw R (x +ᵥ p) (y +ᵥ p) (z +ᵥ p) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_vadd_const_iff, (vadd_right_injective p).ne_iff, (vadd_right_injective p).ne_iff] @[simp] theorem sbtw_const_vsub_iff {x y z : P} (p : P) : Sbtw R (p -ᵥ x) (p -ᵥ y) (p -ᵥ z) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_const_vsub_iff, (vsub_right_injective p).ne_iff, (vsub_right_injective p).ne_iff] @[simp] theorem sbtw_vsub_const_iff {x y z : P} (p : P) : Sbtw R (x -ᵥ p) (y -ᵥ p) (z -ᵥ p) ↔ Sbtw R x y z := by rw [Sbtw, Sbtw, wbtw_vsub_const_iff, (vsub_left_injective p).ne_iff, (vsub_left_injective p).ne_iff] theorem Sbtw.wbtw {x y z : P} (h : Sbtw R x y z) : Wbtw R x y z := h.1 theorem Sbtw.ne_left {x y z : P} (h : Sbtw R x y z) : y ≠ x := h.2.1 theorem Sbtw.left_ne {x y z : P} (h : Sbtw R x y z) : x ≠ y := h.2.1.symm theorem Sbtw.ne_right {x y z : P} (h : Sbtw R x y z) : y ≠ z := h.2.2 theorem Sbtw.right_ne {x y z : P} (h : Sbtw R x y z) : z ≠ y := h.2.2.symm theorem Sbtw.mem_image_Ioo {x y z : P} (h : Sbtw R x y z) : y ∈ lineMap x z '' Set.Ioo (0 : R) 1 := by rcases h with ⟨⟨t, ht, rfl⟩, hyx, hyz⟩ rcases Set.eq_endpoints_or_mem_Ioo_of_mem_Icc ht with (rfl \| rfl \| ho) · exfalso exact hyx (lineMap_apply_zero _ _) · exfalso exact hyz (lineMap_apply_one _ _) · exact ⟨t, ho, rfl⟩ theorem Wbtw.mem_affineSpan {x y z : P} (h : Wbtw R x y z) : y ∈ line[R, x, z] := by rcases h with ⟨r, ⟨-, rfl⟩⟩ exact lineMap_mem_affineSpan_pair _ _ _ variable (R) section OrderedRing variable [IsOrderedRing R] @[simp] theorem wbtw_self_left (x y : P) : Wbtw R x x y := left_mem_affineSegment _ _ _ @[simp] theorem wbtw_self_right (x y : P) : Wbtw R x y y := right_mem_affineSegment _ _ _ @[simp] theorem wbtw_self_iff {x y : P} : Wbtw R x y x ↔ y = x := by refine ⟨fun h => ?_, fun h => ?_⟩ · simpa [Wbtw, affineSegment] using h · rw [h] exact wbtw_self_left R x x end OrderedRing @[simp] theorem not_sbtw_self_left (x y : P) : ¬Sbtw R x x y := fun h => h.ne_left rfl @[simp] theorem not_sbtw_self_right (x y : P) : ¬Sbtw R x y y := fun h => h.ne_right rfl variable {R} variable [IsOrderedRing R] theorem Wbtw.left_ne_right_of_ne_left {x y z : P} (h : Wbtw R x y z) (hne : y ≠ x) : x ≠ z := by rintro rfl rw [wbtw_self_iff] at h exact hne h theorem Wbtw.left_ne_right_of_ne_right {x y z : P} (h : Wbtw R x y z) (hne : y ≠ z) : x ≠ z := by rintro rfl rw [wbtw_self_iff] at h exact hne h theorem Sbtw.left_ne_right {x y z : P} (h : Sbtw R x y z) : x ≠ z := h.wbtw.left_ne_right_of_ne_left h.2.1 theorem sbtw_iff_mem_image_Ioo_and_ne [NoZeroSMulDivisors R V] {x y z : P} : Sbtw R x y z ↔ y ∈ lineMap x z '' Set.Ioo (0 : R) 1 ∧ x ≠ z := by refine ⟨fun h => ⟨h.mem_image_Ioo, h.left_ne_right⟩, fun h => ?_⟩ rcases h with ⟨⟨t, ht, rfl⟩, hxz⟩ refine ⟨⟨t, Set.mem_Icc_of_Ioo ht, rfl⟩, ?_⟩ rw [lineMap_apply, ← @vsub_ne_zero V, ← @vsub_ne_zero V _ _ _ _ z, vadd_vsub_assoc, vsub_self, vadd_vsub_assoc, ← neg_vsub_eq_vsub_rev z x, ← @neg_one_smul R, ← add_smul, ← sub_eq_add_neg] simp [smul_ne_zero, sub_eq_zero, ht.1.ne.symm, ht.2.ne, hxz.symm] variable (R) @[simp] theorem not_sbtw_self (x y : P) : ¬Sbtw R x y x := fun h => h.left_ne_right rfl theorem wbtw_swap_left_iff [NoZeroSMulDivisors R V] {x y : P} (z : P) : Wbtw R x y z ∧ Wbtw R y x z ↔ x = y := by constructor · rintro ⟨hxyz, hyxz⟩ rcases hxyz with ⟨ty, hty, rfl⟩ rcases hyxz with ⟨tx, htx, hx⟩ rw [lineMap_apply, lineMap_apply, ← add_vadd] at hx rw [← @vsub_eq_zero_iff_eq V, vadd_vsub, vsub_vadd_eq_vsub_sub, smul_sub, smul_smul, ← sub_smul, ← add_smul, smul_eq_zero] at hx rcases hx with (h \| h) · nth_rw 1 [← mul_one tx] at h rw [← mul_sub, add_eq_zero_iff_neg_eq] at h have h' : ty = 0 := by refine le_antisymm ?_ hty.1 rw [← h, Left.neg_nonpos_iff] exact mul_nonneg htx.1 (sub_nonneg.2 hty.2) simp [h'] · rw [vsub_eq_zero_iff_eq] at h rw [h, lineMap_same_apply] · rintro rfl exact ⟨wbtw_self_left _ _ _, wbtw_self_left _ _ _⟩ theorem wbtw_swap_right_iff [NoZeroSMulDivisors R V] (x : P) {y z : P} : Wbtw R x y z ∧ Wbtw R x z y ↔ y = z := by rw [wbtw_comm, wbtw_comm (z := y), eq_comm] exact wbtw_swap_left_iff R x theorem wbtw_rotate_iff [NoZeroSMulDivisors R V] (x : P) {y z : P} : Wbtw R x y z ∧ Wbtw R z x y ↔ x = y := by rw [wbtw_comm, wbtw_swap_right_iff, eq_comm] variable {R} theorem Wbtw.swap_left_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) : Wbtw R y x z ↔ x = y := by rw [← wbtw_swap_left_iff R z, and_iff_right h] theorem Wbtw.swap_right_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) : Wbtw R x z y ↔ y = z := by rw [← wbtw_swap_right_iff R x, and_iff_right h] theorem Wbtw.rotate_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) : Wbtw R z x y ↔ x = y := by rw [← wbtw_rotate_iff R x, and_iff_right h] theorem Sbtw.not_swap_left [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) : ¬Wbtw R y x z := fun hs => h.left_ne (h.wbtw.swap_left_iff.1 hs) theorem Sbtw.not_swap_right [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) : ¬Wbtw R x z y := fun hs => h.ne_right (h.wbtw.swap_right_iff.1 hs) theorem Sbtw.not_rotate [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) : ¬Wbtw R z x y := fun hs => h.left_ne (h.wbtw.rotate_iff.1 hs) @[simp] theorem wbtw_lineMap_iff [NoZeroSMulDivisors R V] {x y : P} {r : R} : Wbtw R x (lineMap x y r) y ↔ x = y ∨ r ∈ Set.Icc (0 : R) 1 := by by_cases hxy : x = y · rw [hxy, lineMap_same_apply] simp rw [or_iff_right hxy, Wbtw, affineSegment, (lineMap_injective R hxy).mem_set_image] @[simp] theorem sbtw_lineMap_iff [NoZeroSMulDivisors R V] {x y : P} {r : R} : Sbtw R x (lineMap x y r) y ↔ x ≠ y ∧ r ∈ Set.Ioo (0 : R) 1 := by rw [sbtw_iff_mem_image_Ioo_and_ne, and_comm, and_congr_right] intro hxy rw [(lineMap_injective R hxy).mem_set_image] @[simp] theorem wbtw_mul_sub_add_iff [NoZeroDivisors R] {x y r : R} : Wbtw R x (r * (y - x) + x) y ↔ x = y ∨ r ∈ Set.Icc (0 : R) 1 := wbtw_lineMap_iff @[simp] theorem sbtw_mul_sub_add_iff [NoZeroDivisors R] {x y r : R} : Sbtw R x (r * (y - x) + x) y ↔ x ≠ y ∧ r ∈ Set.Ioo (0 : R) 1 := sbtw_lineMap_iff omit [IsOrderedRing R] in @[simp] theorem wbtw_zero_one_iff {x : R} : Wbtw R 0 x 1 ↔ x ∈ Set.Icc (0 : R) 1 := by rw [Wbtw, affineSegment, Set.mem_image] simp_rw [lineMap_apply_ring] simp @[simp] theorem wbtw_one_zero_iff {x : R} : Wbtw R 1 x 0 ↔ x ∈ Set.Icc (0 : R) 1 := by rw [wbtw_comm, wbtw_zero_one_iff] omit [IsOrderedRing R] in @[simp] theorem sbtw_zero_one_iff {x : R} : Sbtw R 0 x 1 ↔ x ∈ Set.Ioo (0 : R) 1 := by rw [Sbtw, wbtw_zero_one_iff, Set.mem_Icc, Set.mem_Ioo] exact ⟨fun h => ⟨h.1.1.lt_of_ne (Ne.symm h.2.1), h.1.2.lt_of_ne h.2.2⟩, fun h => ⟨⟨h.1.le, h.2.le⟩, h.1.ne', h.2.ne⟩⟩ @[simp] theorem sbtw_one_zero_iff {x : R} : Sbtw R 1 x 0 ↔ x ∈ Set.Ioo (0 : R) 1 := by rw [sbtw_comm, sbtw_zero_one_iff] theorem Wbtw.trans_left {w x y z : P} (h₁ : Wbtw R w y z) (h₂ : Wbtw R w x y) : Wbtw R w x z := by rcases h₁ with ⟨t₁, ht₁, rfl⟩ rcases h₂ with ⟨t₂, ht₂, rfl⟩ refine ⟨t₂ * t₁, ⟨mul_nonneg ht₂.1 ht₁.1, mul_le_one₀ ht₂.2 ht₁.1 ht₁.2⟩, ?_⟩ rw [lineMap_apply, lineMap_apply, lineMap_vsub_left, smul_smul] theorem Wbtw.trans_right {w x y z : P} (h₁ : Wbtw R w x z) (h₂ : Wbtw R x y z) : Wbtw R w y z := by rw [wbtw_comm] at * exact h₁.trans_left h₂ theorem Wbtw.trans_sbtw_left [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w y z) (h₂ : Sbtw R w x y) : Sbtw R w x z := by refine ⟨h₁.trans_left h₂.wbtw, h₂.ne_left, ?_⟩ rintro rfl exact h₂.right_ne ((wbtw_swap_right_iff R w).1 ⟨h₁, h₂.wbtw⟩) theorem Wbtw.trans_sbtw_right [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w x z) (h₂ : Sbtw R x y z) : Sbtw R w y z := by rw [wbtw_comm] at * rw [sbtw_comm] at * exact h₁.trans_sbtw_left h₂ theorem Sbtw.trans_left [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w y z) (h₂ : Sbtw R w x y) : Sbtw R w x z := h₁.wbtw.trans_sbtw_left h₂ theorem Sbtw.trans_right [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w x z) (h₂ : Sbtw R x y z) : Sbtw R w y z := h₁.wbtw.trans_sbtw_right h₂ theorem Wbtw.trans_left_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w y z) (h₂ : Wbtw R w x y) (h : y ≠ z) : x ≠ z := by rintro rfl exact h (h₁.swap_right_iff.1 h₂) theorem Wbtw.trans_right_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w x z) (h₂ : Wbtw R x y z) (h : w ≠ x) : w ≠ y := by rintro rfl exact h (h₁.swap_left_iff.1 h₂) theorem Sbtw.trans_wbtw_left_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w y z) (h₂ : Wbtw R w x y) : x ≠ z := h₁.wbtw.trans_left_ne h₂ h₁.ne_right theorem Sbtw.trans_wbtw_right_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w x z) (h₂ : Wbtw R x y z) : w ≠ y := h₁.wbtw.trans_right_ne h₂ h₁.left_ne theorem Sbtw.affineCombination_of_mem_affineSpan_pair [NoZeroDivisors R] [NoZeroSMulDivisors R V] {ι : Type*} {p : ι → P} (ha : AffineIndependent R p) {w w₁ w₂ : ι → R} {s : Finset ι} (hw : ∑ i ∈ s, w i = 1) (hw₁ : ∑ i ∈ s, w₁ i = 1) (hw₂ : ∑ i ∈ s, w₂ i = 1) (h : s.affineCombination R p w ∈ line[R, s.affineCombination R p w₁, s.affineCombination R p w₂]) {i : ι} (his : i ∈ s) (hs : Sbtw R (w₁ i) (w i) (w₂ i)) : Sbtw R (s.affineCombination R p w₁) (s.affineCombination R p w)	(s.affineCombination R p w₂) := by rw [affineCombination_mem_affineSpan_pair ha hw hw₁ hw₂] at h rcases h with ⟨r, hr⟩ rw [hr i his, sbtw_mul_sub_add_iff] at hs change ∀ i ∈ s, w i = (r • (w₂ - w₁) + w₁) i at hr	Mathlib/Analysis/Convex/Between.lean	474	478
/- Copyright (c) 2022 Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies -/ import Mathlib.Order.Filter.Prod /-! # N-ary maps of filter This file defines the binary and ternary maps of filters. This is mostly useful to define pointwise operations on filters. ## Main declarations * `Filter.map₂`: Binary map of filters. ## Notes This file is very similar to `Data.Set.NAry`, `Data.Finset.NAry` and `Data.Option.NAry`. Please keep them in sync. -/ open Function Set open Filter namespace Filter variable {α α' β β' γ γ' δ δ' ε ε' : Type*} {m : α → β → γ} {f f₁ f₂ : Filter α} {g g₁ g₂ : Filter β} {h : Filter γ} {s : Set α} {t : Set β} {u : Set γ} {a : α} {b : β} /-- The image of a binary function `m : α → β → γ` as a function `Filter α → Filter β → Filter γ`. Mathematically this should be thought of as the image of the corresponding function `α × β → γ`. -/ def map₂ (m : α → β → γ) (f : Filter α) (g : Filter β) : Filter γ := ((f ×ˢ g).map (uncurry m)).copy { s \| ∃ u ∈ f, ∃ v ∈ g, image2 m u v ⊆ s } fun _ ↦ by simp only [mem_map, mem_prod_iff, image2_subset_iff, prod_subset_iff]; rfl @[simp 900] theorem mem_map₂_iff : u ∈ map₂ m f g ↔ ∃ s ∈ f, ∃ t ∈ g, image2 m s t ⊆ u := Iff.rfl theorem image2_mem_map₂ (hs : s ∈ f) (ht : t ∈ g) : image2 m s t ∈ map₂ m f g := ⟨_, hs, _, ht, Subset.rfl⟩ theorem map_prod_eq_map₂ (m : α → β → γ) (f : Filter α) (g : Filter β) : Filter.map (fun p : α × β => m p.1 p.2) (f ×ˢ g) = map₂ m f g := by rw [map₂, copy_eq, uncurry_def] theorem map_prod_eq_map₂' (m : α × β → γ) (f : Filter α) (g : Filter β) : Filter.map m (f ×ˢ g) = map₂ (fun a b => m (a, b)) f g := map_prod_eq_map₂ m.curry f g @[simp] theorem map₂_mk_eq_prod (f : Filter α) (g : Filter β) : map₂ Prod.mk f g = f ×ˢ g := by simp only [← map_prod_eq_map₂, map_id'] -- lemma image2_mem_map₂_iff (hm : injective2 m) : image2 m s t ∈ map₂ m f g ↔ s ∈ f ∧ t ∈ g := -- ⟨by { rintro ⟨u, v, hu, hv, h⟩, rw image2_subset_image2_iff hm at h, -- exact ⟨mem_of_superset hu h.1, mem_of_superset hv h.2⟩ }, fun h ↦ image2_mem_map₂ h.1 h.2⟩ @[gcongr] theorem map₂_mono (hf : f₁ ≤ f₂) (hg : g₁ ≤ g₂) : map₂ m f₁ g₁ ≤ map₂ m f₂ g₂ := fun _ ⟨s, hs, t, ht, hst⟩ => ⟨s, hf hs, t, hg ht, hst⟩ @[gcongr] theorem map₂_mono_left (h : g₁ ≤ g₂) : map₂ m f g₁ ≤ map₂ m f g₂ := map₂_mono Subset.rfl h @[gcongr] theorem map₂_mono_right (h : f₁ ≤ f₂) : map₂ m f₁ g ≤ map₂ m f₂ g := map₂_mono h Subset.rfl @[simp] theorem le_map₂_iff {h : Filter γ} : h ≤ map₂ m f g ↔ ∀ ⦃s⦄, s ∈ f → ∀ ⦃t⦄, t ∈ g → image2 m s t ∈ h := ⟨fun H _ hs _ ht => H <\| image2_mem_map₂ hs ht, fun H _ ⟨_, hs, _, ht, hu⟩ => mem_of_superset (H hs ht) hu⟩ @[simp] theorem map₂_eq_bot_iff : map₂ m f g = ⊥ ↔ f = ⊥ ∨ g = ⊥ := by simp [← map_prod_eq_map₂] @[simp] theorem map₂_bot_left : map₂ m ⊥ g = ⊥ := map₂_eq_bot_iff.2 <\| .inl rfl @[simp] theorem map₂_bot_right : map₂ m f ⊥ = ⊥ := map₂_eq_bot_iff.2 <\| .inr rfl @[simp] theorem map₂_neBot_iff : (map₂ m f g).NeBot ↔ f.NeBot ∧ g.NeBot := by simp [neBot_iff, not_or] protected theorem NeBot.map₂ (hf : f.NeBot) (hg : g.NeBot) : (map₂ m f g).NeBot := map₂_neBot_iff.2 ⟨hf, hg⟩ instance map₂.neBot [NeBot f] [NeBot g] : NeBot (map₂ m f g) := .map₂ ‹_› ‹_› theorem NeBot.of_map₂_left (h : (map₂ m f g).NeBot) : f.NeBot := (map₂_neBot_iff.1 h).1 theorem NeBot.of_map₂_right (h : (map₂ m f g).NeBot) : g.NeBot := (map₂_neBot_iff.1 h).2 theorem map₂_sup_left : map₂ m (f₁ ⊔ f₂) g = map₂ m f₁ g ⊔ map₂ m f₂ g := by simp_rw [← map_prod_eq_map₂, sup_prod, map_sup] theorem map₂_sup_right : map₂ m f (g₁ ⊔ g₂) = map₂ m f g₁ ⊔ map₂ m f g₂ := by simp_rw [← map_prod_eq_map₂, prod_sup, map_sup] theorem map₂_inf_subset_left : map₂ m (f₁ ⊓ f₂) g ≤ map₂ m f₁ g ⊓ map₂ m f₂ g := Monotone.map_inf_le (fun _ _ ↦ map₂_mono_right) f₁ f₂ theorem map₂_inf_subset_right : map₂ m f (g₁ ⊓ g₂) ≤ map₂ m f g₁ ⊓ map₂ m f g₂ := Monotone.map_inf_le (fun _ _ ↦ map₂_mono_left) g₁ g₂ @[simp] theorem map₂_pure_left : map₂ m (pure a) g = g.map (m a) := by rw [← map_prod_eq_map₂, pure_prod, map_map]; rfl	@[simp] theorem map₂_pure_right : map₂ m f (pure b) = f.map (m · b) := by	Mathlib/Order/Filter/NAry.lean	120	121
/- Copyright (c) 2023 Joël Riou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joël Riou -/ import Mathlib.Algebra.Homology.Homotopy import Mathlib.Algebra.Ring.NegOnePow import Mathlib.Algebra.Category.Grp.Preadditive import Mathlib.Tactic.Linarith import Mathlib.CategoryTheory.Linear.LinearFunctor /-! The cochain complex of homomorphisms between cochain complexes If `F` and `G` are cochain complexes (indexed by `ℤ`) in a preadditive category, there is a cochain complex of abelian groups whose `0`-cocycles identify to morphisms `F ⟶ G`. Informally, in degree `n`, this complex shall consist of cochains of degree `n` from `F` to `G`, i.e. arbitrary families for morphisms `F.X p ⟶ G.X (p + n)`. This complex shall be denoted `HomComplex F G`. In order to avoid type theoretic issues, a cochain of degree `n : ℤ` (i.e. a term of type of `Cochain F G n`) shall be defined here as the data of a morphism `F.X p ⟶ G.X q` for all triplets `⟨p, q, hpq⟩` where `p` and `q` are integers and `hpq : p + n = q`. If `α : Cochain F G n`, we shall define `α.v p q hpq : F.X p ⟶ G.X q`. We follow the signs conventions appearing in the introduction of [Brian Conrad's book Grothendieck duality and base change][conrad2000]. ## References * [Brian Conrad, Grothendieck duality and base change][conrad2000] -/ assert_not_exists TwoSidedIdeal open CategoryTheory Category Limits Preadditive universe v u variable {C : Type u} [Category.{v} C] [Preadditive C] {R : Type*} [Ring R] [Linear R C] namespace CochainComplex variable {F G K L : CochainComplex C ℤ} (n m : ℤ) namespace HomComplex /-- A term of type `HomComplex.Triplet n` consists of two integers `p` and `q` such that `p + n = q`. (This type is introduced so that the instance `AddCommGroup (Cochain F G n)` defined below can be found automatically.) -/ structure Triplet (n : ℤ) where /-- a first integer -/ p : ℤ /-- a second integer -/ q : ℤ /-- the condition on the two integers -/ hpq : p + n = q variable (F G) /-- A cochain of degree `n : ℤ` between to cochain complexes `F` and `G` consists of a family of morphisms `F.X p ⟶ G.X q` whenever `p + n = q`, i.e. for all triplets in `HomComplex.Triplet n`. -/ def Cochain := ∀ (T : Triplet n), F.X T.p ⟶ G.X T.q instance : AddCommGroup (Cochain F G n) := by dsimp only [Cochain] infer_instance instance : Module R (Cochain F G n) := by dsimp only [Cochain] infer_instance namespace Cochain variable {F G n} /-- A practical constructor for cochains. -/ def mk (v : ∀ (p q : ℤ) (_ : p + n = q), F.X p ⟶ G.X q) : Cochain F G n := fun ⟨p, q, hpq⟩ => v p q hpq /-- The value of a cochain on a triplet `⟨p, q, hpq⟩`. -/ def v (γ : Cochain F G n) (p q : ℤ) (hpq : p + n = q) : F.X p ⟶ G.X q := γ ⟨p, q, hpq⟩ @[simp] lemma mk_v (v : ∀ (p q : ℤ) (_ : p + n = q), F.X p ⟶ G.X q) (p q : ℤ) (hpq : p + n = q) : (Cochain.mk v).v p q hpq = v p q hpq := rfl lemma congr_v {z₁ z₂ : Cochain F G n} (h : z₁ = z₂) (p q : ℤ) (hpq : p + n = q) : z₁.v p q hpq = z₂.v p q hpq := by subst h; rfl @[ext] lemma ext (z₁ z₂ : Cochain F G n) (h : ∀ (p q hpq), z₁.v p q hpq = z₂.v p q hpq) : z₁ = z₂ := by funext ⟨p, q, hpq⟩ apply h @[ext 1100] lemma ext₀ (z₁ z₂ : Cochain F G 0) (h : ∀ (p : ℤ), z₁.v p p (add_zero p) = z₂.v p p (add_zero p)) : z₁ = z₂ := by ext p q hpq obtain rfl : q = p := by rw [← hpq, add_zero] exact h q @[simp] lemma zero_v {n : ℤ} (p q : ℤ) (hpq : p + n = q) : (0 : Cochain F G n).v p q hpq = 0 := rfl @[simp] lemma add_v {n : ℤ} (z₁ z₂ : Cochain F G n) (p q : ℤ) (hpq : p + n = q) : (z₁ + z₂).v p q hpq = z₁.v p q hpq + z₂.v p q hpq := rfl @[simp] lemma sub_v {n : ℤ} (z₁ z₂ : Cochain F G n) (p q : ℤ) (hpq : p + n = q) : (z₁ - z₂).v p q hpq = z₁.v p q hpq - z₂.v p q hpq := rfl @[simp] lemma neg_v {n : ℤ} (z : Cochain F G n) (p q : ℤ) (hpq : p + n = q) : (-z).v p q hpq = - (z.v p q hpq) := rfl @[simp] lemma smul_v {n : ℤ} (k : R) (z : Cochain F G n) (p q : ℤ) (hpq : p + n = q) : (k • z).v p q hpq = k • (z.v p q hpq) := rfl @[simp] lemma units_smul_v {n : ℤ} (k : Rˣ) (z : Cochain F G n) (p q : ℤ) (hpq : p + n = q) : (k • z).v p q hpq = k • (z.v p q hpq) := rfl /-- A cochain of degree `0` from `F` to `G` can be constructed from a family of morphisms `F.X p ⟶ G.X p` for all `p : ℤ`. -/ def ofHoms (ψ : ∀ (p : ℤ), F.X p ⟶ G.X p) : Cochain F G 0 := Cochain.mk (fun p q hpq => ψ p ≫ eqToHom (by rw [← hpq, add_zero])) @[simp] lemma ofHoms_v (ψ : ∀ (p : ℤ), F.X p ⟶ G.X p) (p : ℤ) : (ofHoms ψ).v p p (add_zero p) = ψ p := by simp only [ofHoms, mk_v, eqToHom_refl, comp_id] @[simp] lemma ofHoms_zero : ofHoms (fun p => (0 : F.X p ⟶ G.X p)) = 0 := by aesop_cat @[simp] lemma ofHoms_v_comp_d (ψ : ∀ (p : ℤ), F.X p ⟶ G.X p) (p q q' : ℤ) (hpq : p + 0 = q) : (ofHoms ψ).v p q hpq ≫ G.d q q' = ψ p ≫ G.d p q' := by rw [add_zero] at hpq subst hpq rw [ofHoms_v] @[simp] lemma d_comp_ofHoms_v (ψ : ∀ (p : ℤ), F.X p ⟶ G.X p) (p' p q : ℤ) (hpq : p + 0 = q) : F.d p' p ≫ (ofHoms ψ).v p q hpq = F.d p' q ≫ ψ q := by rw [add_zero] at hpq subst hpq rw [ofHoms_v] /-- The `0`-cochain attached to a morphism of cochain complexes. -/ def ofHom (φ : F ⟶ G) : Cochain F G 0 := ofHoms (fun p => φ.f p) variable (F G) @[simp] lemma ofHom_zero : ofHom (0 : F ⟶ G) = 0 := by simp only [ofHom, HomologicalComplex.zero_f_apply, ofHoms_zero] variable {F G} @[simp] lemma ofHom_v (φ : F ⟶ G) (p : ℤ) : (ofHom φ).v p p (add_zero p) = φ.f p := by simp only [ofHom, ofHoms_v] @[simp] lemma ofHom_v_comp_d (φ : F ⟶ G) (p q q' : ℤ) (hpq : p + 0 = q) : (ofHom φ).v p q hpq ≫ G.d q q' = φ.f p ≫ G.d p q' := by simp only [ofHom, ofHoms_v_comp_d] @[simp] lemma d_comp_ofHom_v (φ : F ⟶ G) (p' p q : ℤ) (hpq : p + 0 = q) : F.d p' p ≫ (ofHom φ).v p q hpq = F.d p' q ≫ φ.f q := by simp only [ofHom, d_comp_ofHoms_v] @[simp] lemma ofHom_add (φ₁ φ₂ : F ⟶ G) : Cochain.ofHom (φ₁ + φ₂) = Cochain.ofHom φ₁ + Cochain.ofHom φ₂ := by aesop_cat @[simp] lemma ofHom_sub (φ₁ φ₂ : F ⟶ G) : Cochain.ofHom (φ₁ - φ₂) = Cochain.ofHom φ₁ - Cochain.ofHom φ₂ := by aesop_cat @[simp] lemma ofHom_neg (φ : F ⟶ G) : Cochain.ofHom (-φ) = -Cochain.ofHom φ := by aesop_cat /-- The cochain of degree `-1` given by an homotopy between two morphism of complexes. -/ def ofHomotopy {φ₁ φ₂ : F ⟶ G} (ho : Homotopy φ₁ φ₂) : Cochain F G (-1) := Cochain.mk (fun p q _ => ho.hom p q) @[simp] lemma ofHomotopy_ofEq {φ₁ φ₂ : F ⟶ G} (h : φ₁ = φ₂) : ofHomotopy (Homotopy.ofEq h) = 0 := rfl @[simp] lemma ofHomotopy_refl (φ : F ⟶ G) : ofHomotopy (Homotopy.refl φ) = 0 := rfl @[reassoc] lemma v_comp_XIsoOfEq_hom (γ : Cochain F G n) (p q q' : ℤ) (hpq : p + n = q) (hq' : q = q') : γ.v p q hpq ≫ (HomologicalComplex.XIsoOfEq G hq').hom = γ.v p q' (by rw [← hq', hpq]) := by subst hq' simp only [HomologicalComplex.XIsoOfEq, eqToIso_refl, Iso.refl_hom, comp_id] @[reassoc] lemma v_comp_XIsoOfEq_inv (γ : Cochain F G n) (p q q' : ℤ) (hpq : p + n = q) (hq' : q' = q) : γ.v p q hpq ≫ (HomologicalComplex.XIsoOfEq G hq').inv = γ.v p q' (by rw [hq', hpq]) := by subst hq' simp only [HomologicalComplex.XIsoOfEq, eqToIso_refl, Iso.refl_inv, comp_id] /-- The composition of cochains. -/ def comp {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : Cochain F K n₁₂ := Cochain.mk (fun p q hpq => z₁.v p (p + n₁) rfl ≫ z₂.v (p + n₁) q (by omega)) /-! If `z₁` is a cochain of degree `n₁` and `z₂` is a cochain of degree `n₂`, and that we have a relation `h : n₁ + n₂ = n₁₂`, then `z₁.comp z₂ h` is a cochain of degree `n₁₂`. The following lemma `comp_v` computes the value of this composition `z₁.comp z₂ h` on a triplet `⟨p₁, p₃, _⟩` (with `p₁ + n₁₂ = p₃`). In order to use this lemma, we need to provide an intermediate integer `p₂` such that `p₁ + n₁ = p₂`. It is advisable to use a `p₂` that has good definitional properties (i.e. `p₁ + n₁` is not always the best choice.) When `z₁` or `z₂` is a `0`-cochain, there is a better choice of `p₂`, and this leads to the two simplification lemmas `comp_zero_cochain_v` and `zero_cochain_comp_v`. -/ lemma comp_v {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) (p₁ p₂ p₃ : ℤ) (h₁ : p₁ + n₁ = p₂) (h₂ : p₂ + n₂ = p₃) : (z₁.comp z₂ h).v p₁ p₃ (by rw [← h₂, ← h₁, ← h, add_assoc]) = z₁.v p₁ p₂ h₁ ≫ z₂.v p₂ p₃ h₂ := by subst h₁; rfl @[simp] lemma comp_zero_cochain_v (z₁ : Cochain F G n) (z₂ : Cochain G K 0) (p q : ℤ) (hpq : p + n = q) : (z₁.comp z₂ (add_zero n)).v p q hpq = z₁.v p q hpq ≫ z₂.v q q (add_zero q) := comp_v z₁ z₂ (add_zero n) p q q hpq (add_zero q) @[simp] lemma zero_cochain_comp_v (z₁ : Cochain F G 0) (z₂ : Cochain G K n) (p q : ℤ) (hpq : p + n = q) : (z₁.comp z₂ (zero_add n)).v p q hpq = z₁.v p p (add_zero p) ≫ z₂.v p q hpq := comp_v z₁ z₂ (zero_add n) p p q (add_zero p) hpq /-- The associativity of the composition of cochains. -/ lemma comp_assoc {n₁ n₂ n₃ n₁₂ n₂₃ n₁₂₃ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (z₃ : Cochain K L n₃) (h₁₂ : n₁ + n₂ = n₁₂) (h₂₃ : n₂ + n₃ = n₂₃) (h₁₂₃ : n₁ + n₂ + n₃ = n₁₂₃) : (z₁.comp z₂ h₁₂).comp z₃ (show n₁₂ + n₃ = n₁₂₃ by rw [← h₁₂, h₁₂₃]) = z₁.comp (z₂.comp z₃ h₂₃) (by rw [← h₂₃, ← h₁₂₃, add_assoc]) := by substs h₁₂ h₂₃ h₁₂₃ ext p q hpq rw [comp_v _ _ rfl p (p + n₁ + n₂) q (add_assoc _ _ _).symm (by omega), comp_v z₁ z₂ rfl p (p + n₁) (p + n₁ + n₂) (by omega) (by omega), comp_v z₁ (z₂.comp z₃ rfl) (add_assoc n₁ n₂ n₃).symm p (p + n₁) q (by omega) (by omega), comp_v z₂ z₃ rfl (p + n₁) (p + n₁ + n₂) q (by omega) (by omega), assoc] /-! The formulation of the associativity of the composition of cochains given by the lemma `comp_assoc` often requires a careful selection of degrees with good definitional properties. In a few cases, like when one of the three cochains is a `0`-cochain, there are better choices, which provides the following simplification lemmas. -/ @[simp] lemma comp_assoc_of_first_is_zero_cochain {n₂ n₃ n₂₃ : ℤ} (z₁ : Cochain F G 0) (z₂ : Cochain G K n₂) (z₃ : Cochain K L n₃) (h₂₃ : n₂ + n₃ = n₂₃) : (z₁.comp z₂ (zero_add n₂)).comp z₃ h₂₃ = z₁.comp (z₂.comp z₃ h₂₃) (zero_add n₂₃) := comp_assoc _ _ _ _ _ (by omega) @[simp] lemma comp_assoc_of_second_is_zero_cochain {n₁ n₃ n₁₃ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K 0) (z₃ : Cochain K L n₃) (h₁₃ : n₁ + n₃ = n₁₃) : (z₁.comp z₂ (add_zero n₁)).comp z₃ h₁₃ = z₁.comp (z₂.comp z₃ (zero_add n₃)) h₁₃ := comp_assoc _ _ _ _ _ (by omega) @[simp] lemma comp_assoc_of_third_is_zero_cochain {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (z₃ : Cochain K L 0) (h₁₂ : n₁ + n₂ = n₁₂) : (z₁.comp z₂ h₁₂).comp z₃ (add_zero n₁₂) = z₁.comp (z₂.comp z₃ (add_zero n₂)) h₁₂ := comp_assoc _ _ _ _ _ (by omega) @[simp] lemma comp_assoc_of_second_degree_eq_neg_third_degree {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K (-n₂)) (z₃ : Cochain K L n₂) (h₁₂ : n₁ + (-n₂) = n₁₂) : (z₁.comp z₂ h₁₂).comp z₃ (show n₁₂ + n₂ = n₁ by rw [← h₁₂, add_assoc, neg_add_cancel, add_zero]) = z₁.comp (z₂.comp z₃ (neg_add_cancel n₂)) (add_zero n₁) := comp_assoc _ _ _ _ _ (by omega) @[simp] protected lemma zero_comp {n₁ n₂ n₁₂ : ℤ} (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : (0 : Cochain F G n₁).comp z₂ h = 0 := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), zero_v, zero_comp] @[simp] protected lemma add_comp {n₁ n₂ n₁₂ : ℤ} (z₁ z₁' : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : (z₁ + z₁').comp z₂ h = z₁.comp z₂ h + z₁'.comp z₂ h := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), add_v, add_comp] @[simp] protected lemma sub_comp {n₁ n₂ n₁₂ : ℤ} (z₁ z₁' : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : (z₁ - z₁').comp z₂ h = z₁.comp z₂ h - z₁'.comp z₂ h := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), sub_v, sub_comp] @[simp] protected lemma neg_comp {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : (-z₁).comp z₂ h = -z₁.comp z₂ h := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), neg_v, neg_comp] @[simp] protected lemma smul_comp {n₁ n₂ n₁₂ : ℤ} (k : R) (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : (k • z₁).comp z₂ h = k • (z₁.comp z₂ h) := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), smul_v, Linear.smul_comp] @[simp] lemma units_smul_comp {n₁ n₂ n₁₂ : ℤ} (k : Rˣ) (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : (k • z₁).comp z₂ h = k • (z₁.comp z₂ h) := by apply Cochain.smul_comp @[simp] protected lemma id_comp {n : ℤ} (z₂ : Cochain F G n) : (Cochain.ofHom (𝟙 F)).comp z₂ (zero_add n) = z₂ := by ext p q hpq simp only [zero_cochain_comp_v, ofHom_v, HomologicalComplex.id_f, id_comp] @[simp] protected lemma comp_zero {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (h : n₁ + n₂ = n₁₂) : z₁.comp (0 : Cochain G K n₂) h = 0 := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), zero_v, comp_zero] @[simp] protected lemma comp_add {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ z₂' : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : z₁.comp (z₂ + z₂') h = z₁.comp z₂ h + z₁.comp z₂' h := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), add_v, comp_add] @[simp] protected lemma comp_sub {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ z₂' : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : z₁.comp (z₂ - z₂') h = z₁.comp z₂ h - z₁.comp z₂' h := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), sub_v, comp_sub] @[simp] protected lemma comp_neg {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) : z₁.comp (-z₂) h = -z₁.comp z₂ h := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), neg_v, comp_neg] @[simp] protected lemma comp_smul {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (k : R) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂ ) : z₁.comp (k • z₂) h = k • (z₁.comp z₂ h) := by ext p q hpq simp only [comp_v _ _ h p _ q rfl (by omega), smul_v, Linear.comp_smul] @[simp] lemma comp_units_smul {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (k : Rˣ) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂ ) : z₁.comp (k • z₂) h = k • (z₁.comp z₂ h) := by apply Cochain.comp_smul @[simp] protected lemma comp_id {n : ℤ} (z₁ : Cochain F G n) : z₁.comp (Cochain.ofHom (𝟙 G)) (add_zero n) = z₁ := by ext p q hpq simp only [comp_zero_cochain_v, ofHom_v, HomologicalComplex.id_f, comp_id] @[simp] lemma ofHoms_comp (φ : ∀ (p : ℤ), F.X p ⟶ G.X p) (ψ : ∀ (p : ℤ), G.X p ⟶ K.X p) : (ofHoms φ).comp (ofHoms ψ) (zero_add 0) = ofHoms (fun p => φ p ≫ ψ p) := by aesop_cat @[simp] lemma ofHom_comp (f : F ⟶ G) (g : G ⟶ K) : ofHom (f ≫ g) = (ofHom f).comp (ofHom g) (zero_add 0) := by simp only [ofHom, HomologicalComplex.comp_f, ofHoms_comp] variable (K) /-- The differential on a cochain complex, as a cochain of degree `1`. -/ def diff : Cochain K K 1 := Cochain.mk (fun p q _ => K.d p q) @[simp] lemma diff_v (p q : ℤ) (hpq : p + 1 = q) : (diff K).v p q hpq = K.d p q := rfl end Cochain variable {F G} /-- The differential on the complex of morphisms between cochain complexes. -/ def δ (z : Cochain F G n) : Cochain F G m := Cochain.mk (fun p q hpq => z.v p (p + n) rfl ≫ G.d (p + n) q + m.negOnePow • F.d p (p + m - n) ≫ z.v (p + m - n) q (by rw [hpq, sub_add_cancel])) /-! Similarly as for the composition of cochains, if `z : Cochain F G n`, we usually need to carefully select intermediate indices with good definitional properties in order to obtain a suitable expansion of the morphisms which constitute `δ n m z : Cochain F G m` (when `n + 1 = m`, otherwise it shall be zero). The basic equational lemma is `δ_v` below. -/ lemma δ_v (hnm : n + 1 = m) (z : Cochain F G n) (p q : ℤ) (hpq : p + m = q) (q₁ q₂ : ℤ) (hq₁ : q₁ = q - 1) (hq₂ : p + 1 = q₂) : (δ n m z).v p q hpq = z.v p q₁ (by rw [hq₁, ← hpq, ← hnm, ← add_assoc, add_sub_cancel_right]) ≫ G.d q₁ q + m.negOnePow • F.d p q₂ ≫ z.v q₂ q (by rw [← hq₂, add_assoc, add_comm 1, hnm, hpq]) := by obtain rfl : q₁ = p + n := by omega obtain rfl : q₂ = p + m - n := by omega rfl lemma δ_shape (hnm : ¬ n + 1 = m) (z : Cochain F G n) : δ n m z = 0 := by ext p q hpq dsimp only [δ] rw [Cochain.mk_v, Cochain.zero_v, F.shape, G.shape, comp_zero, zero_add, zero_comp, smul_zero] all_goals simp only [ComplexShape.up_Rel] exact fun _ => hnm (by omega) variable (F G) (R) /-- The differential on the complex of morphisms between cochain complexes, as a linear map. -/ @[simps!] def δ_hom : Cochain F G n →ₗ[R] Cochain F G m where toFun := δ n m map_add' α β := by by_cases h : n + 1 = m · ext p q hpq dsimp simp only [δ_v n m h _ p q hpq _ _ rfl rfl, Cochain.add_v, add_comp, comp_add, smul_add] abel · simp only [δ_shape _ _ h, add_zero] map_smul' r a := by by_cases h : n + 1 = m · ext p q hpq dsimp simp only [δ_v n m h _ p q hpq _ _ rfl rfl, Cochain.smul_v, Linear.comp_smul, Linear.smul_comp, smul_add, add_right_inj, smul_comm m.negOnePow r] · simp only [δ_shape _ _ h, smul_zero] variable {F G R} @[simp] lemma δ_add (z₁ z₂ : Cochain F G n) : δ n m (z₁ + z₂) = δ n m z₁ + δ n m z₂ := (δ_hom ℤ F G n m).map_add z₁ z₂ @[simp] lemma δ_sub (z₁ z₂ : Cochain F G n) : δ n m (z₁ - z₂) = δ n m z₁ - δ n m z₂ := (δ_hom ℤ F G n m).map_sub z₁ z₂ @[simp] lemma δ_zero : δ n m (0 : Cochain F G n) = 0 := (δ_hom ℤ F G n m).map_zero @[simp] lemma δ_neg (z : Cochain F G n) : δ n m (-z) = - δ n m z := (δ_hom ℤ F G n m).map_neg z @[simp] lemma δ_smul (k : R) (z : Cochain F G n) : δ n m (k • z) = k • δ n m z := (δ_hom R F G n m).map_smul k z @[simp] lemma δ_units_smul (k : Rˣ) (z : Cochain F G n) : δ n m (k • z) = k • δ n m z := δ_smul .. lemma δ_δ (n₀ n₁ n₂ : ℤ) (z : Cochain F G n₀) : δ n₁ n₂ (δ n₀ n₁ z) = 0 := by by_cases h₁₂ : n₁ + 1 = n₂; swap · rw [δ_shape _ _ h₁₂] by_cases h₀₁ : n₀ + 1 = n₁; swap · rw [δ_shape _ _ h₀₁, δ_zero] ext p q hpq dsimp simp only [δ_v n₁ n₂ h₁₂ _ p q hpq _ _ rfl rfl, δ_v n₀ n₁ h₀₁ z p (q-1) (by omega) (q-2) _ (by omega) rfl, δ_v n₀ n₁ h₀₁ z (p+1) q (by omega) _ (p+2) rfl (by omega), ← h₁₂, Int.negOnePow_succ, add_comp, assoc, HomologicalComplex.d_comp_d, comp_zero, zero_add, comp_add, HomologicalComplex.d_comp_d_assoc, zero_comp, smul_zero, add_zero, add_neg_cancel, Units.neg_smul, Linear.units_smul_comp, Linear.comp_units_smul] lemma δ_comp {n₁ n₂ n₁₂ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K n₂) (h : n₁ + n₂ = n₁₂) (m₁ m₂ m₁₂ : ℤ) (h₁₂ : n₁₂ + 1 = m₁₂) (h₁ : n₁ + 1 = m₁) (h₂ : n₂ + 1 = m₂) : δ n₁₂ m₁₂ (z₁.comp z₂ h) = z₁.comp (δ n₂ m₂ z₂) (by rw [← h₁₂, ← h₂, ← h, add_assoc]) + n₂.negOnePow • (δ n₁ m₁ z₁).comp z₂ (by rw [← h₁₂, ← h₁, ← h, add_assoc, add_comm 1, add_assoc]) := by subst h₁₂ h₁ h₂ h ext p q hpq dsimp rw [z₁.comp_v _ (add_assoc n₁ n₂ 1).symm p _ q rfl (by omega), Cochain.comp_v _ _ (show n₁ + 1 + n₂ = n₁ + n₂ + 1 by omega) p (p+n₁+1) q (by omega) (by omega), δ_v (n₁ + n₂) _ rfl (z₁.comp z₂ rfl) p q hpq (p + n₁ + n₂) _ (by omega) rfl, z₁.comp_v z₂ rfl p _ _ rfl rfl, z₁.comp_v z₂ rfl (p+1) (p+n₁+1) q (by omega) (by omega), δ_v n₂ (n₂+1) rfl z₂ (p+n₁) q (by omega) (p+n₁+n₂) _ (by omega) rfl, δ_v n₁ (n₁+1) rfl z₁ p (p+n₁+1) (by omega) (p+n₁) _ (by omega) rfl] simp only [assoc, comp_add, add_comp, Int.negOnePow_succ, Int.negOnePow_add n₁ n₂, Units.neg_smul, comp_neg, neg_comp, smul_neg, smul_smul, Linear.units_smul_comp, mul_comm n₁.negOnePow n₂.negOnePow, Linear.comp_units_smul, smul_add] abel lemma δ_zero_cochain_comp {n₂ : ℤ} (z₁ : Cochain F G 0) (z₂ : Cochain G K n₂) (m₂ : ℤ) (h₂ : n₂ + 1 = m₂) : δ n₂ m₂ (z₁.comp z₂ (zero_add n₂)) = z₁.comp (δ n₂ m₂ z₂) (zero_add m₂) + n₂.negOnePow • ((δ 0 1 z₁).comp z₂ (by rw [add_comm, h₂])) := δ_comp z₁ z₂ (zero_add n₂) 1 m₂ m₂ h₂ (zero_add 1) h₂ lemma δ_comp_zero_cochain {n₁ : ℤ} (z₁ : Cochain F G n₁) (z₂ : Cochain G K 0) (m₁ : ℤ) (h₁ : n₁ + 1 = m₁) : δ n₁ m₁ (z₁.comp z₂ (add_zero n₁)) = z₁.comp (δ 0 1 z₂) h₁ + (δ n₁ m₁ z₁).comp z₂ (add_zero m₁) := by simp only [δ_comp z₁ z₂ (add_zero n₁) m₁ 1 m₁ h₁ h₁ (zero_add 1), one_smul, Int.negOnePow_zero] @[simp] lemma δ_zero_cochain_v (z : Cochain F G 0) (p q : ℤ) (hpq : p + 1 = q) : (δ 0 1 z).v p q hpq = z.v p p (add_zero p) ≫ G.d p q - F.d p q ≫ z.v q q (add_zero q) := by simp only [δ_v 0 1 (zero_add 1) z p q hpq p q (by omega) hpq, zero_add, Int.negOnePow_one, Units.neg_smul, one_smul, sub_eq_add_neg] @[simp] lemma δ_ofHom {p : ℤ} (φ : F ⟶ G) : δ 0 p (Cochain.ofHom φ) = 0 := by by_cases h : p = 1 · subst h ext simp · rw [δ_shape] omega @[simp] lemma δ_ofHomotopy {φ₁ φ₂ : F ⟶ G} (h : Homotopy φ₁ φ₂) : δ (-1) 0 (Cochain.ofHomotopy h) = Cochain.ofHom φ₁ - Cochain.ofHom φ₂ := by ext p have eq := h.comm p rw [dNext_eq h.hom (show (ComplexShape.up ℤ).Rel p (p+1) by simp), prevD_eq h.hom (show (ComplexShape.up ℤ).Rel (p-1) p by simp)] at eq rw [Cochain.ofHomotopy, δ_v (-1) 0 (neg_add_cancel 1) _ p p (add_zero p) (p-1) (p+1) rfl rfl] simp only [Cochain.mk_v, neg_add_cancel, one_smul, Int.negOnePow_zero, Cochain.sub_v, Cochain.ofHom_v, eq] abel lemma δ_neg_one_cochain (z : Cochain F G (-1)) : δ (-1) 0 z = Cochain.ofHom (Homotopy.nullHomotopicMap' (fun i j hij => z.v i j (by dsimp at hij; rw [← hij, add_neg_cancel_right]))) := by ext p rw [δ_v (-1) 0 (neg_add_cancel 1) _ p p (add_zero p) (p-1) (p+1) rfl rfl] simp only [neg_add_cancel, one_smul, Cochain.ofHom_v, Int.negOnePow_zero] rw [Homotopy.nullHomotopicMap'_f (show (ComplexShape.up ℤ).Rel (p-1) p by simp) (show (ComplexShape.up ℤ).Rel p (p+1) by simp)] abel end HomComplex variable (F G) open HomComplex /-- The cochain complex of homomorphisms between two cochain complexes `F` and `G`. In degree `n : ℤ`, it consists of the abelian group `HomComplex.Cochain F G n`. -/ @[simps! X d_hom_apply] def HomComplex : CochainComplex AddCommGrp ℤ where X i := AddCommGrp.of (Cochain F G i) d i j := AddCommGrp.ofHom (δ_hom ℤ F G i j) shape _ _ hij := by ext; simp [δ_shape _ _ hij] d_comp_d' _ _ _ _ _ := by ext; simp [δ_δ] namespace HomComplex /-- The subgroup of cocycles in `Cochain F G n`. -/ def cocycle : AddSubgroup (Cochain F G n) := AddMonoidHom.ker (δ_hom ℤ F G n (n + 1)).toAddMonoidHom /-- The type of `n`-cocycles, as a subtype of `Cochain F G n`. -/ def Cocycle : Type v := cocycle F G n instance : AddCommGroup (Cocycle F G n) := by dsimp only [Cocycle] infer_instance namespace Cocycle variable {F G} lemma mem_iff (hnm : n + 1 = m) (z : Cochain F G n) : z ∈ cocycle F G n ↔ δ n m z = 0 := by subst hnm; rfl variable {n} instance : Coe (Cocycle F G n) (Cochain F G n) where coe x := x.1 @[ext] lemma ext (z₁ z₂ : Cocycle F G n) (h : (z₁ : Cochain F G n) = z₂) : z₁ = z₂ := Subtype.ext h instance : SMul R (Cocycle F G n) where smul r z := ⟨r • z.1, by have hz := z.2 rw [mem_iff n (n + 1) rfl] at hz ⊢ simp only [δ_smul, hz, smul_zero]⟩ variable (F G n) @[simp] lemma coe_zero : (↑(0 : Cocycle F G n) : Cochain F G n) = 0 := by rfl variable {F G n} @[simp] lemma coe_add (z₁ z₂ : Cocycle F G n) : (↑(z₁ + z₂) : Cochain F G n) = (z₁ : Cochain F G n) + (z₂ : Cochain F G n) := rfl @[simp] lemma coe_neg (z : Cocycle F G n) : (↑(-z) : Cochain F G n) = -(z : Cochain F G n) := rfl @[simp] lemma coe_smul (z : Cocycle F G n) (x : R) : (↑(x • z) : Cochain F G n) = x • (z : Cochain F G n) := rfl @[simp] lemma coe_units_smul (z : Cocycle F G n) (x : Rˣ) : (↑(x • z) : Cochain F G n) = x • (z : Cochain F G n) := rfl @[simp] lemma coe_sub (z₁ z₂ : Cocycle F G n) : (↑(z₁ - z₂) : Cochain F G n) = (z₁ : Cochain F G n) - (z₂ : Cochain F G n) := rfl instance : Module R (Cocycle F G n) where one_smul _ := by aesop mul_smul _ _ _ := by ext; dsimp; rw [smul_smul] smul_zero _ := by aesop smul_add _ _ _ := by aesop add_smul _ _ _ := by ext; dsimp; rw [add_smul] zero_smul := by aesop /-- Constructor for `Cocycle F G n`, taking as inputs `z : Cochain F G n`, an integer `m : ℤ` such that `n + 1 = m`, and the relation `δ n m z = 0`. -/ @[simps] def mk (z : Cochain F G n) (m : ℤ) (hnm : n + 1 = m) (h : δ n m z = 0) : Cocycle F G n := ⟨z, by simpa only [mem_iff n m hnm z] using h⟩ @[simp] lemma δ_eq_zero {n : ℤ} (z : Cocycle F G n) (m : ℤ) : δ n m (z : Cochain F G n) = 0 := by by_cases h : n + 1 = m · rw [← mem_iff n m h] exact z.2 · exact δ_shape n m h _ /-- The `0`-cocycle associated to a morphism in `CochainComplex C ℤ`. -/ @[simps!] def ofHom (φ : F ⟶ G) : Cocycle F G 0 := mk (Cochain.ofHom φ) 1 (zero_add 1) (by simp) /-- The morphism in `CochainComplex C ℤ` associated to a `0`-cocycle. -/ @[simps] def homOf (z : Cocycle F G 0) : F ⟶ G where f i := (z : Cochain _ _ _).v i i (add_zero i) comm' := by rintro i j rfl rcases z with ⟨z, hz⟩ dsimp rw [mem_iff 0 1 (zero_add 1)] at hz simpa only [δ_zero_cochain_v, Cochain.zero_v, sub_eq_zero] using Cochain.congr_v hz i (i + 1) rfl @[simp] lemma homOf_ofHom_eq_self (φ : F ⟶ G) : homOf (ofHom φ) = φ := by aesop_cat @[simp] lemma ofHom_homOf_eq_self (z : Cocycle F G 0) : ofHom (homOf z) = z := by aesop_cat @[simp] lemma cochain_ofHom_homOf_eq_coe (z : Cocycle F G 0) : Cochain.ofHom (homOf z) = (z : Cochain F G 0) := by simpa only [Cocycle.ext_iff] using ofHom_homOf_eq_self z variable (F G) /-- The additive equivalence between morphisms in `CochainComplex C ℤ` and `0`-cocycles. -/ @[simps] def equivHom : (F ⟶ G) ≃+ Cocycle F G 0 where toFun := ofHom invFun := homOf left_inv := homOf_ofHom_eq_self right_inv := ofHom_homOf_eq_self map_add' := by aesop_cat variable (K) /-- The `1`-cocycle given by the differential on a cochain complex. -/ @[simps!] def diff : Cocycle K K 1 := Cocycle.mk (Cochain.diff K) 2 rfl (by ext p q hpq simp only [Cochain.zero_v, δ_v 1 2 rfl _ p q hpq _ _ rfl rfl, Cochain.diff_v, HomologicalComplex.d_comp_d, smul_zero, add_zero]) end Cocycle variable {F G} @[simp] lemma δ_comp_zero_cocycle {n : ℤ} (z₁ : Cochain F G n) (z₂ : Cocycle G K 0) (m : ℤ) : δ n m (z₁.comp z₂.1 (add_zero n)) = (δ n m z₁).comp z₂.1 (add_zero m) := by by_cases hnm : n + 1 = m · simp [δ_comp_zero_cochain _ _ _ hnm] · simp [δ_shape _ _ hnm] @[simp] lemma δ_comp_ofHom {n : ℤ} (z₁ : Cochain F G n) (f : G ⟶ K) (m : ℤ) : δ n m (z₁.comp (Cochain.ofHom f) (add_zero n)) = (δ n m z₁).comp (Cochain.ofHom f) (add_zero m) := by rw [← Cocycle.ofHom_coe, δ_comp_zero_cocycle] @[simp]	lemma δ_zero_cocycle_comp {n : ℤ} (z₁ : Cocycle F G 0) (z₂ : Cochain G K n) (m : ℤ) : δ n m (z₁.1.comp z₂ (zero_add n)) = z₁.1.comp (δ n m z₂) (zero_add m) := by by_cases hnm : n + 1 = m · simp [δ_zero_cochain_comp _ _ _ hnm]	Mathlib/Algebra/Homology/HomotopyCategory/HomComplex.lean	724	728
/- Copyright (c) 2021 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel, Yaël Dillies -/ import Mathlib.Analysis.Normed.Group.Pointwise import Mathlib.Analysis.NormedSpace.Real /-! # Properties of pointwise scalar multiplication of sets in normed spaces. We explore the relationships between scalar multiplication of sets in vector spaces, and the norm. Notably, we express arbitrary balls as rescaling of other balls, and we show that the multiplication of bounded sets remain bounded. -/ open Metric Set open Pointwise Topology variable {𝕜 E : Type} section SMulZeroClass variable [SeminormedAddCommGroup 𝕜] [SeminormedAddCommGroup E] variable [SMulZeroClass 𝕜 E] [IsBoundedSMul 𝕜 E] theorem ediam_smul_le (c : 𝕜) (s : Set E) : EMetric.diam (c • s) ≤ ‖c‖₊ • EMetric.diam s := (lipschitzWith_smul c).ediam_image_le s end SMulZeroClass section DivisionRing variable [NormedDivisionRing 𝕜] [SeminormedAddCommGroup E] variable [Module 𝕜 E] [IsBoundedSMul 𝕜 E] theorem ediam_smul₀ (c : 𝕜) (s : Set E) : EMetric.diam (c • s) = ‖c‖₊ • EMetric.diam s := by refine le_antisymm (ediam_smul_le c s) ?_ obtain rfl \| hc := eq_or_ne c 0 · obtain rfl \| hs := s.eq_empty_or_nonempty · simp simp [zero_smul_set hs, ← Set.singleton_zero] · have := (lipschitzWith_smul c⁻¹).ediam_image_le (c • s) rwa [← smul_eq_mul, ← ENNReal.smul_def, Set.image_smul, inv_smul_smul₀ hc s, nnnorm_inv, le_inv_smul_iff_of_pos (nnnorm_pos.2 hc)] at this theorem diam_smul₀ (c : 𝕜) (x : Set E) : diam (c • x) = ‖c‖ diam x := by simp_rw [diam, ediam_smul₀, ENNReal.toReal_smul, NNReal.smul_def, coe_nnnorm, smul_eq_mul] theorem infEdist_smul₀ {c : 𝕜} (hc : c ≠ 0) (s : Set E) (x : E) : EMetric.infEdist (c • x) (c • s) = ‖c‖₊ • EMetric.infEdist x s := by simp_rw [EMetric.infEdist] have : Function.Surjective ((c • ·) : E → E) := Function.RightInverse.surjective (smul_inv_smul₀ hc) trans ⨅ (y) (_ : y ∈ s), ‖c‖₊ • edist x y · refine (this.iInf_congr _ fun y => ?_).symm simp_rw [smul_mem_smul_set_iff₀ hc, edist_smul₀] · have : (‖c‖₊ : ENNReal) ≠ 0 := by simp [hc] simp_rw [ENNReal.smul_def, smul_eq_mul, ENNReal.mul_iInf_of_ne this ENNReal.coe_ne_top] theorem infDist_smul₀ {c : 𝕜} (hc : c ≠ 0) (s : Set E) (x : E) : Metric.infDist (c • x) (c • s) = ‖c‖ * Metric.infDist x s := by simp_rw [Metric.infDist, infEdist_smul₀ hc s, ENNReal.toReal_smul, NNReal.smul_def, coe_nnnorm, smul_eq_mul] end DivisionRing variable [NormedField 𝕜] section SeminormedAddCommGroup variable [SeminormedAddCommGroup E] [NormedSpace 𝕜 E] theorem smul_ball {c : 𝕜} (hc : c ≠ 0) (x : E) (r : ℝ) : c • ball x r = ball (c • x) (‖c‖ * r) := by ext y rw [mem_smul_set_iff_inv_smul_mem₀ hc] conv_lhs => rw [← inv_smul_smul₀ hc x] simp [← div_eq_inv_mul, div_lt_iff₀ (norm_pos_iff.2 hc), mul_comm _ r, dist_smul₀] theorem smul_unitBall {c : 𝕜} (hc : c ≠ 0) : c • ball (0 : E) (1 : ℝ) = ball (0 : E) ‖c‖ := by rw [_root_.smul_ball hc, smul_zero, mul_one] theorem smul_sphere' {c : 𝕜} (hc : c ≠ 0) (x : E) (r : ℝ) : c • sphere x r = sphere (c • x) (‖c‖ * r) := by ext y rw [mem_smul_set_iff_inv_smul_mem₀ hc] conv_lhs => rw [← inv_smul_smul₀ hc x] simp only [mem_sphere, dist_smul₀, norm_inv, ← div_eq_inv_mul, div_eq_iff (norm_pos_iff.2 hc).ne', mul_comm r] theorem smul_closedBall' {c : 𝕜} (hc : c ≠ 0) (x : E) (r : ℝ) : c • closedBall x r = closedBall (c • x) (‖c‖ * r) := by simp only [← ball_union_sphere, Set.smul_set_union, _root_.smul_ball hc, smul_sphere' hc] theorem set_smul_sphere_zero {s : Set 𝕜} (hs : 0 ∉ s) (r : ℝ) : s • sphere (0 : E) r = (‖·‖) ⁻¹' ((‖·‖ * r) '' s) := calc s • sphere (0 : E) r = ⋃ c ∈ s, c • sphere (0 : E) r := iUnion_smul_left_image.symm _ = ⋃ c ∈ s, sphere (0 : E) (‖c‖ * r) := iUnion₂_congr fun c hc ↦ by rw [smul_sphere' (ne_of_mem_of_not_mem hc hs), smul_zero] _ = (‖·‖) ⁻¹' ((‖·‖ * r) '' s) := by ext; simp [eq_comm] /-- Image of a bounded set in a normed space under scalar multiplication by a constant is bounded. See also `Bornology.IsBounded.smul` for a similar lemma about an isometric action. -/ theorem Bornology.IsBounded.smul₀ {s : Set E} (hs : IsBounded s) (c : 𝕜) : IsBounded (c • s) := (lipschitzWith_smul c).isBounded_image hs /-- If `s` is a bounded set, then for small enough `r`, the set `{x} + r • s` is contained in any fixed neighborhood of `x`. -/ theorem eventually_singleton_add_smul_subset {x : E} {s : Set E} (hs : Bornology.IsBounded s) {u : Set E} (hu : u ∈ 𝓝 x) : ∀ᶠ r in 𝓝 (0 : 𝕜), {x} + r • s ⊆ u := by obtain ⟨ε, εpos, hε⟩ : ∃ ε : ℝ, 0 < ε ∧ closedBall x ε ⊆ u := nhds_basis_closedBall.mem_iff.1 hu obtain ⟨R, Rpos, hR⟩ : ∃ R : ℝ, 0 < R ∧ s ⊆ closedBall 0 R := hs.subset_closedBall_lt 0 0 have : Metric.closedBall (0 : 𝕜) (ε / R) ∈ 𝓝 (0 : 𝕜) := closedBall_mem_nhds _ (div_pos εpos Rpos) filter_upwards [this] with r hr simp only [image_add_left, singleton_add] intro y hy obtain ⟨z, zs, hz⟩ : ∃ z : E, z ∈ s ∧ r • z = -x + y := by simpa [mem_smul_set] using hy have I : ‖r • z‖ ≤ ε := calc ‖r • z‖ = ‖r‖ * ‖z‖ := norm_smul _ _	_ ≤ ε / R * R := (mul_le_mul (mem_closedBall_zero_iff.1 hr) (mem_closedBall_zero_iff.1 (hR zs)) (norm_nonneg _) (div_pos εpos Rpos).le) _ = ε := by field_simp have : y = x + r • z := by simp only [hz, add_neg_cancel_left] apply hε simpa only [this, dist_eq_norm, add_sub_cancel_left, mem_closedBall] using I variable [NormedSpace ℝ E] {x y z : E} {δ ε : ℝ} /-- In a real normed space, the image of the unit ball under scalar multiplication by a positive constant `r` is the ball of radius `r`. -/ theorem smul_unitBall_of_pos {r : ℝ} (hr : 0 < r) : r • ball (0 : E) 1 = ball (0 : E) r := by rw [smul_unitBall hr.ne', Real.norm_of_nonneg hr.le] lemma Ioo_smul_sphere_zero {a b r : ℝ} (ha : 0 ≤ a) (hr : 0 < r) : Ioo a b • sphere (0 : E) r = ball 0 (b * r) \ closedBall 0 (a * r) := by have : EqOn (‖·‖) id (Ioo a b) := fun x hx ↦ abs_of_pos (ha.trans_lt hx.1) rw [set_smul_sphere_zero (by simp [ha.not_lt]), ← image_image (· * r), this.image_eq, image_id,	Mathlib/Analysis/NormedSpace/Pointwise.lean	125	143
/- Copyright (c) 2014 Robert Y. Lewis. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Robert Y. Lewis, Leonardo de Moura, Mario Carneiro, Floris van Doorn -/ import Mathlib.Algebra.Field.Basic import Mathlib.Algebra.GroupWithZero.Units.Lemmas import Mathlib.Algebra.Order.Ring.Abs import Mathlib.Order.Bounds.Basic import Mathlib.Order.Bounds.OrderIso import Mathlib.Tactic.Positivity.Core /-! # Lemmas about linear ordered (semi)fields -/ open Function OrderDual variable {ι α β : Type} section LinearOrderedSemifield variable [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {a b c d e : α} {m n : ℤ} /-! ### Relating two divisions. -/ @[deprecated div_le_div_iff_of_pos_right (since := "2024-11-12")] theorem div_le_div_right (hc : 0 < c) : a / c ≤ b / c ↔ a ≤ b := div_le_div_iff_of_pos_right hc @[deprecated div_lt_div_iff_of_pos_right (since := "2024-11-12")] theorem div_lt_div_right (hc : 0 < c) : a / c < b / c ↔ a < b := div_lt_div_iff_of_pos_right hc @[deprecated div_lt_div_iff_of_pos_left (since := "2024-11-13")] theorem div_lt_div_left (ha : 0 < a) (hb : 0 < b) (hc : 0 < c) : a / b < a / c ↔ c < b := div_lt_div_iff_of_pos_left ha hb hc @[deprecated div_le_div_iff_of_pos_left (since := "2024-11-12")] theorem div_le_div_left (ha : 0 < a) (hb : 0 < b) (hc : 0 < c) : a / b ≤ a / c ↔ c ≤ b := div_le_div_iff_of_pos_left ha hb hc @[deprecated div_lt_div_iff₀ (since := "2024-11-12")] theorem div_lt_div_iff (b0 : 0 < b) (d0 : 0 < d) : a / b < c / d ↔ a d < c * b := div_lt_div_iff₀ b0 d0 @[deprecated div_le_div_iff₀ (since := "2024-11-12")] theorem div_le_div_iff (b0 : 0 < b) (d0 : 0 < d) : a / b ≤ c / d ↔ a * d ≤ c * b := div_le_div_iff₀ b0 d0 @[deprecated div_le_div₀ (since := "2024-11-12")] theorem div_le_div (hc : 0 ≤ c) (hac : a ≤ c) (hd : 0 < d) (hbd : d ≤ b) : a / b ≤ c / d := div_le_div₀ hc hac hd hbd @[deprecated div_lt_div₀ (since := "2024-11-12")] theorem div_lt_div (hac : a < c) (hbd : d ≤ b) (c0 : 0 ≤ c) (d0 : 0 < d) : a / b < c / d := div_lt_div₀ hac hbd c0 d0 @[deprecated div_lt_div₀' (since := "2024-11-12")] theorem div_lt_div' (hac : a ≤ c) (hbd : d < b) (c0 : 0 < c) (d0 : 0 < d) : a / b < c / d := div_lt_div₀' hac hbd c0 d0 /-! ### Relating one division and involving `1` -/ @[bound] theorem div_le_self (ha : 0 ≤ a) (hb : 1 ≤ b) : a / b ≤ a := by simpa only [div_one] using div_le_div_of_nonneg_left ha zero_lt_one hb @[bound] theorem div_lt_self (ha : 0 < a) (hb : 1 < b) : a / b < a := by simpa only [div_one] using div_lt_div_of_pos_left ha zero_lt_one hb @[bound] theorem le_div_self (ha : 0 ≤ a) (hb₀ : 0 < b) (hb₁ : b ≤ 1) : a ≤ a / b := by simpa only [div_one] using div_le_div_of_nonneg_left ha hb₀ hb₁ theorem one_le_div (hb : 0 < b) : 1 ≤ a / b ↔ b ≤ a := by rw [le_div_iff₀ hb, one_mul] theorem div_le_one (hb : 0 < b) : a / b ≤ 1 ↔ a ≤ b := by rw [div_le_iff₀ hb, one_mul] theorem one_lt_div (hb : 0 < b) : 1 < a / b ↔ b < a := by rw [lt_div_iff₀ hb, one_mul] theorem div_lt_one (hb : 0 < b) : a / b < 1 ↔ a < b := by rw [div_lt_iff₀ hb, one_mul] theorem one_div_le (ha : 0 < a) (hb : 0 < b) : 1 / a ≤ b ↔ 1 / b ≤ a := by simpa using inv_le_comm₀ ha hb theorem one_div_lt (ha : 0 < a) (hb : 0 < b) : 1 / a < b ↔ 1 / b < a := by simpa using inv_lt_comm₀ ha hb theorem le_one_div (ha : 0 < a) (hb : 0 < b) : a ≤ 1 / b ↔ b ≤ 1 / a := by simpa using le_inv_comm₀ ha hb theorem lt_one_div (ha : 0 < a) (hb : 0 < b) : a < 1 / b ↔ b < 1 / a := by simpa using lt_inv_comm₀ ha hb @[bound] lemma Bound.one_lt_div_of_pos_of_lt (b0 : 0 < b) : b < a → 1 < a / b := (one_lt_div b0).mpr @[bound] lemma Bound.div_lt_one_of_pos_of_lt (b0 : 0 < b) : a < b → a / b < 1 := (div_lt_one b0).mpr /-! ### Relating two divisions, involving `1` -/ theorem one_div_le_one_div_of_le (ha : 0 < a) (h : a ≤ b) : 1 / b ≤ 1 / a := by simpa using inv_anti₀ ha h theorem one_div_lt_one_div_of_lt (ha : 0 < a) (h : a < b) : 1 / b < 1 / a := by rwa [lt_div_iff₀' ha, ← div_eq_mul_one_div, div_lt_one (ha.trans h)] theorem le_of_one_div_le_one_div (ha : 0 < a) (h : 1 / a ≤ 1 / b) : b ≤ a := le_imp_le_of_lt_imp_lt (one_div_lt_one_div_of_lt ha) h theorem lt_of_one_div_lt_one_div (ha : 0 < a) (h : 1 / a < 1 / b) : b < a := lt_imp_lt_of_le_imp_le (one_div_le_one_div_of_le ha) h /-- For the single implications with fewer assumptions, see `one_div_le_one_div_of_le` and `le_of_one_div_le_one_div` -/ theorem one_div_le_one_div (ha : 0 < a) (hb : 0 < b) : 1 / a ≤ 1 / b ↔ b ≤ a := div_le_div_iff_of_pos_left zero_lt_one ha hb /-- For the single implications with fewer assumptions, see `one_div_lt_one_div_of_lt` and `lt_of_one_div_lt_one_div` -/ theorem one_div_lt_one_div (ha : 0 < a) (hb : 0 < b) : 1 / a < 1 / b ↔ b < a := div_lt_div_iff_of_pos_left zero_lt_one ha hb theorem one_lt_one_div (h1 : 0 < a) (h2 : a < 1) : 1 < 1 / a := by rwa [lt_one_div (@zero_lt_one α _ _ _ _ _) h1, one_div_one] theorem one_le_one_div (h1 : 0 < a) (h2 : a ≤ 1) : 1 ≤ 1 / a := by rwa [le_one_div (@zero_lt_one α _ _ _ _ _) h1, one_div_one] /-! ### Results about halving. The equalities also hold in semifields of characteristic `0`. -/ theorem half_pos (h : 0 < a) : 0 < a / 2 := div_pos h zero_lt_two theorem one_half_pos : (0 : α) < 1 / 2 := half_pos zero_lt_one @[simp] theorem half_le_self_iff : a / 2 ≤ a ↔ 0 ≤ a := by rw [div_le_iff₀ (zero_lt_two' α), mul_two, le_add_iff_nonneg_left] @[simp] theorem half_lt_self_iff : a / 2 < a ↔ 0 < a := by rw [div_lt_iff₀ (zero_lt_two' α), mul_two, lt_add_iff_pos_left] alias ⟨_, half_le_self⟩ := half_le_self_iff alias ⟨_, half_lt_self⟩ := half_lt_self_iff alias div_two_lt_of_pos := half_lt_self theorem one_half_lt_one : (1 / 2 : α) < 1 := half_lt_self zero_lt_one theorem two_inv_lt_one : (2⁻¹ : α) < 1 := (one_div _).symm.trans_lt one_half_lt_one theorem left_lt_add_div_two : a < (a + b) / 2 ↔ a < b := by simp [lt_div_iff₀, mul_two] theorem add_div_two_lt_right : (a + b) / 2 < b ↔ a < b := by simp [div_lt_iff₀, mul_two] theorem add_thirds (a : α) : a / 3 + a / 3 + a / 3 = a := by rw [div_add_div_same, div_add_div_same, ← two_mul, ← add_one_mul 2 a, two_add_one_eq_three, mul_div_cancel_left₀ a three_ne_zero] /-! ### Miscellaneous lemmas -/ @[simp] lemma div_pos_iff_of_pos_left (ha : 0 < a) : 0 < a / b ↔ 0 < b := by simp only [div_eq_mul_inv, mul_pos_iff_of_pos_left ha, inv_pos] @[simp] lemma div_pos_iff_of_pos_right (hb : 0 < b) : 0 < a / b ↔ 0 < a := by simp only [div_eq_mul_inv, mul_pos_iff_of_pos_right (inv_pos.2 hb)] theorem mul_le_mul_of_mul_div_le (h : a * (b / c) ≤ d) (hc : 0 < c) : b * a ≤ d * c := by rw [← mul_div_assoc] at h rwa [mul_comm b, ← div_le_iff₀ hc] theorem div_mul_le_div_mul_of_div_le_div (h : a / b ≤ c / d) (he : 0 ≤ e) : a / (b * e) ≤ c / (d * e) := by rw [div_mul_eq_div_mul_one_div, div_mul_eq_div_mul_one_div] exact mul_le_mul_of_nonneg_right h (one_div_nonneg.2 he) theorem exists_pos_mul_lt {a : α} (h : 0 < a) (b : α) : ∃ c : α, 0 < c ∧ b * c < a := by have : 0 < a / max (b + 1) 1 := div_pos h (lt_max_iff.2 (Or.inr zero_lt_one)) refine ⟨a / max (b + 1) 1, this, ?_⟩ rw [← lt_div_iff₀ this, div_div_cancel₀ h.ne'] exact lt_max_iff.2 (Or.inl <\| lt_add_one _) theorem exists_pos_lt_mul {a : α} (h : 0 < a) (b : α) : ∃ c : α, 0 < c ∧ b < c * a := let ⟨c, hc₀, hc⟩ := exists_pos_mul_lt h b; ⟨c⁻¹, inv_pos.2 hc₀, by rwa [← div_eq_inv_mul, lt_div_iff₀ hc₀]⟩ lemma monotone_div_right_of_nonneg (ha : 0 ≤ a) : Monotone (· / a) := fun _b _c hbc ↦ div_le_div_of_nonneg_right hbc ha lemma strictMono_div_right_of_pos (ha : 0 < a) : StrictMono (· / a) := fun _b _c hbc ↦ div_lt_div_of_pos_right hbc ha theorem Monotone.div_const {β : Type} [Preorder β] {f : β → α} (hf : Monotone f) {c : α} (hc : 0 ≤ c) : Monotone fun x => f x / c := (monotone_div_right_of_nonneg hc).comp hf theorem StrictMono.div_const {β : Type} [Preorder β] {f : β → α} (hf : StrictMono f) {c : α} (hc : 0 < c) : StrictMono fun x => f x / c := by simpa only [div_eq_mul_inv] using hf.mul_const (inv_pos.2 hc) -- see Note [lower instance priority] instance (priority := 100) LinearOrderedSemiField.toDenselyOrdered : DenselyOrdered α where dense a₁ a₂ h := ⟨(a₁ + a₂) / 2, calc a₁ = (a₁ + a₁) / 2 := (add_self_div_two a₁).symm _ < (a₁ + a₂) / 2 := div_lt_div_of_pos_right (add_lt_add_left h _) zero_lt_two , calc (a₁ + a₂) / 2 < (a₂ + a₂) / 2 := div_lt_div_of_pos_right (add_lt_add_right h _) zero_lt_two _ = a₂ := add_self_div_two a₂ ⟩ theorem min_div_div_right {c : α} (hc : 0 ≤ c) (a b : α) : min (a / c) (b / c) = min a b / c := (monotone_div_right_of_nonneg hc).map_min.symm theorem max_div_div_right {c : α} (hc : 0 ≤ c) (a b : α) : max (a / c) (b / c) = max a b / c := (monotone_div_right_of_nonneg hc).map_max.symm theorem one_div_strictAntiOn : StrictAntiOn (fun x : α => 1 / x) (Set.Ioi 0) := fun _ x1 _ y1 xy => (one_div_lt_one_div (Set.mem_Ioi.mp y1) (Set.mem_Ioi.mp x1)).mpr xy theorem one_div_pow_le_one_div_pow_of_le (a1 : 1 ≤ a) {m n : ℕ} (mn : m ≤ n) : 1 / a ^ n ≤ 1 / a ^ m := by refine (one_div_le_one_div ?_ ?_).mpr (pow_right_mono₀ a1 mn) <;> exact pow_pos (zero_lt_one.trans_le a1) _ theorem one_div_pow_lt_one_div_pow_of_lt (a1 : 1 < a) {m n : ℕ} (mn : m < n) : 1 / a ^ n < 1 / a ^ m := by refine (one_div_lt_one_div ?_ ?_).2 (pow_lt_pow_right₀ a1 mn) <;> exact pow_pos (zero_lt_one.trans a1) _ theorem one_div_pow_anti (a1 : 1 ≤ a) : Antitone fun n : ℕ => 1 / a ^ n := fun _ _ => one_div_pow_le_one_div_pow_of_le a1 theorem one_div_pow_strictAnti (a1 : 1 < a) : StrictAnti fun n : ℕ => 1 / a ^ n := fun _ _ => one_div_pow_lt_one_div_pow_of_lt a1 theorem inv_strictAntiOn : StrictAntiOn (fun x : α => x⁻¹) (Set.Ioi 0) := fun _ hx _ hy xy => (inv_lt_inv₀ hy hx).2 xy theorem inv_pow_le_inv_pow_of_le (a1 : 1 ≤ a) {m n : ℕ} (mn : m ≤ n) : (a ^ n)⁻¹ ≤ (a ^ m)⁻¹ := by convert one_div_pow_le_one_div_pow_of_le a1 mn using 1 <;> simp theorem inv_pow_lt_inv_pow_of_lt (a1 : 1 < a) {m n : ℕ} (mn : m < n) : (a ^ n)⁻¹ < (a ^ m)⁻¹ := by convert one_div_pow_lt_one_div_pow_of_lt a1 mn using 1 <;> simp theorem inv_pow_anti (a1 : 1 ≤ a) : Antitone fun n : ℕ => (a ^ n)⁻¹ := fun _ _ => inv_pow_le_inv_pow_of_le a1 theorem inv_pow_strictAnti (a1 : 1 < a) : StrictAnti fun n : ℕ => (a ^ n)⁻¹ := fun _ _ => inv_pow_lt_inv_pow_of_lt a1 theorem le_iff_forall_one_lt_le_mul₀ {α : Type} [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {a b : α} (hb : 0 ≤ b) : a ≤ b ↔ ∀ ε, 1 < ε → a ≤ b ε := by refine ⟨fun h _ hε ↦ h.trans <\| le_mul_of_one_le_right hb hε.le, fun h ↦ ?_⟩ obtain rfl\|hb := hb.eq_or_lt · simp_rw [zero_mul] at h exact h 2 one_lt_two refine le_of_forall_gt_imp_ge_of_dense fun x hbx => ?_ convert h (x / b) ((one_lt_div hb).mpr hbx) rw [mul_div_cancel₀ _ hb.ne'] /-! ### Results about `IsGLB` -/ theorem IsGLB.mul_left {s : Set α} (ha : 0 ≤ a) (hs : IsGLB s b) : IsGLB ((fun b => a * b) '' s) (a * b) := by rcases lt_or_eq_of_le ha with (ha \| rfl) · exact (OrderIso.mulLeft₀ _ ha).isGLB_image'.2 hs · simp_rw [zero_mul] rw [hs.nonempty.image_const] exact isGLB_singleton theorem IsGLB.mul_right {s : Set α} (ha : 0 ≤ a) (hs : IsGLB s b) : IsGLB ((fun b => b * a) '' s) (b * a) := by simpa [mul_comm] using hs.mul_left ha end LinearOrderedSemifield section variable [Field α] [LinearOrder α] [IsStrictOrderedRing α] {a b c d : α} {n : ℤ} /-! ### Lemmas about pos, nonneg, nonpos, neg -/ theorem div_pos_iff : 0 < a / b ↔ 0 < a ∧ 0 < b ∨ a < 0 ∧ b < 0 := by simp only [division_def, mul_pos_iff, inv_pos, inv_lt_zero] theorem div_neg_iff : a / b < 0 ↔ 0 < a ∧ b < 0 ∨ a < 0 ∧ 0 < b := by simp [division_def, mul_neg_iff] theorem div_nonneg_iff : 0 ≤ a / b ↔ 0 ≤ a ∧ 0 ≤ b ∨ a ≤ 0 ∧ b ≤ 0 := by simp [division_def, mul_nonneg_iff] theorem div_nonpos_iff : a / b ≤ 0 ↔ 0 ≤ a ∧ b ≤ 0 ∨ a ≤ 0 ∧ 0 ≤ b := by simp [division_def, mul_nonpos_iff] theorem div_nonneg_of_nonpos (ha : a ≤ 0) (hb : b ≤ 0) : 0 ≤ a / b := div_nonneg_iff.2 <\| Or.inr ⟨ha, hb⟩ theorem div_pos_of_neg_of_neg (ha : a < 0) (hb : b < 0) : 0 < a / b := div_pos_iff.2 <\| Or.inr ⟨ha, hb⟩ theorem div_neg_of_neg_of_pos (ha : a < 0) (hb : 0 < b) : a / b < 0 := div_neg_iff.2 <\| Or.inr ⟨ha, hb⟩ theorem div_neg_of_pos_of_neg (ha : 0 < a) (hb : b < 0) : a / b < 0 := div_neg_iff.2 <\| Or.inl ⟨ha, hb⟩ /-! ### Relating one division with another term -/ theorem div_le_iff_of_neg (hc : c < 0) : b / c ≤ a ↔ a * c ≤ b := ⟨fun h => div_mul_cancel₀ b (ne_of_lt hc) ▸ mul_le_mul_of_nonpos_right h hc.le, fun h => calc a = a * c * (1 / c) := mul_mul_div a (ne_of_lt hc) _ ≥ b * (1 / c) := mul_le_mul_of_nonpos_right h (one_div_neg.2 hc).le _ = b / c := (div_eq_mul_one_div b c).symm ⟩ theorem div_le_iff_of_neg' (hc : c < 0) : b / c ≤ a ↔ c * a ≤ b := by rw [mul_comm, div_le_iff_of_neg hc] theorem le_div_iff_of_neg (hc : c < 0) : a ≤ b / c ↔ b ≤ a * c := by rw [← neg_neg c, mul_neg, div_neg, le_neg, div_le_iff₀ (neg_pos.2 hc), neg_mul] theorem le_div_iff_of_neg' (hc : c < 0) : a ≤ b / c ↔ b ≤ c * a := by rw [mul_comm, le_div_iff_of_neg hc] theorem div_lt_iff_of_neg (hc : c < 0) : b / c < a ↔ a * c < b := lt_iff_lt_of_le_iff_le <\| le_div_iff_of_neg hc theorem div_lt_iff_of_neg' (hc : c < 0) : b / c < a ↔ c * a < b := by rw [mul_comm, div_lt_iff_of_neg hc] theorem lt_div_iff_of_neg (hc : c < 0) : a < b / c ↔ b < a * c := lt_iff_lt_of_le_iff_le <\| div_le_iff_of_neg hc theorem lt_div_iff_of_neg' (hc : c < 0) : a < b / c ↔ b < c * a := by rw [mul_comm, lt_div_iff_of_neg hc] theorem div_le_one_of_ge (h : b ≤ a) (hb : b ≤ 0) : a / b ≤ 1 := by simpa only [neg_div_neg_eq] using div_le_one_of_le₀ (neg_le_neg h) (neg_nonneg_of_nonpos hb) /-! ### Bi-implications of inequalities using inversions -/ theorem inv_le_inv_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ ≤ b⁻¹ ↔ b ≤ a := by rw [← one_div, div_le_iff_of_neg ha, ← div_eq_inv_mul, div_le_iff_of_neg hb, one_mul] theorem inv_le_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ ≤ b ↔ b⁻¹ ≤ a := by rw [← inv_le_inv_of_neg hb (inv_lt_zero.2 ha), inv_inv] theorem le_inv_of_neg (ha : a < 0) (hb : b < 0) : a ≤ b⁻¹ ↔ b ≤ a⁻¹ := by rw [← inv_le_inv_of_neg (inv_lt_zero.2 hb) ha, inv_inv] theorem inv_lt_inv_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ < b⁻¹ ↔ b < a := lt_iff_lt_of_le_iff_le (inv_le_inv_of_neg hb ha) theorem inv_lt_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ < b ↔ b⁻¹ < a := lt_iff_lt_of_le_iff_le (le_inv_of_neg hb ha) theorem lt_inv_of_neg (ha : a < 0) (hb : b < 0) : a < b⁻¹ ↔ b < a⁻¹ := lt_iff_lt_of_le_iff_le (inv_le_of_neg hb ha) /-! ### Monotonicity results involving inversion -/ theorem sub_inv_antitoneOn_Ioi : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Ioi c) := antitoneOn_iff_forall_lt.mpr fun _ ha _ hb hab ↦ inv_le_inv₀ (sub_pos.mpr hb) (sub_pos.mpr ha) \|>.mpr <\| sub_le_sub (le_of_lt hab) le_rfl theorem sub_inv_antitoneOn_Iio : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Iio c) := antitoneOn_iff_forall_lt.mpr fun _ ha _ hb hab ↦ inv_le_inv_of_neg (sub_neg.mpr hb) (sub_neg.mpr ha) \|>.mpr <\| sub_le_sub (le_of_lt hab) le_rfl theorem sub_inv_antitoneOn_Icc_right (ha : c < a) : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Icc a b) := by by_cases hab : a ≤ b · exact sub_inv_antitoneOn_Ioi.mono <\| (Set.Icc_subset_Ioi_iff hab).mpr ha · simp [hab, Set.Subsingleton.antitoneOn] theorem sub_inv_antitoneOn_Icc_left (ha : b < c) : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Icc a b) := by by_cases hab : a ≤ b · exact sub_inv_antitoneOn_Iio.mono <\| (Set.Icc_subset_Iio_iff hab).mpr ha · simp [hab, Set.Subsingleton.antitoneOn] theorem inv_antitoneOn_Ioi : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Ioi 0) := by convert sub_inv_antitoneOn_Ioi (α := α) exact (sub_zero _).symm theorem inv_antitoneOn_Iio : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Iio 0) := by convert sub_inv_antitoneOn_Iio (α := α) exact (sub_zero _).symm theorem inv_antitoneOn_Icc_right (ha : 0 < a) : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Icc a b) := by convert sub_inv_antitoneOn_Icc_right ha exact (sub_zero _).symm theorem inv_antitoneOn_Icc_left (hb : b < 0) : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Icc a b) := by convert sub_inv_antitoneOn_Icc_left hb exact (sub_zero _).symm /-! ### Relating two divisions -/ theorem div_le_div_of_nonpos_of_le (hc : c ≤ 0) (h : b ≤ a) : a / c ≤ b / c := by rw [div_eq_mul_one_div a c, div_eq_mul_one_div b c] exact mul_le_mul_of_nonpos_right h (one_div_nonpos.2 hc) theorem div_lt_div_of_neg_of_lt (hc : c < 0) (h : b < a) : a / c < b / c := by rw [div_eq_mul_one_div a c, div_eq_mul_one_div b c] exact mul_lt_mul_of_neg_right h (one_div_neg.2 hc) theorem div_le_div_right_of_neg (hc : c < 0) : a / c ≤ b / c ↔ b ≤ a := ⟨le_imp_le_of_lt_imp_lt <\| div_lt_div_of_neg_of_lt hc, div_le_div_of_nonpos_of_le <\| hc.le⟩ theorem div_lt_div_right_of_neg (hc : c < 0) : a / c < b / c ↔ b < a := lt_iff_lt_of_le_iff_le <\| div_le_div_right_of_neg hc /-! ### Relating one division and involving `1` -/ theorem one_le_div_of_neg (hb : b < 0) : 1 ≤ a / b ↔ a ≤ b := by rw [le_div_iff_of_neg hb, one_mul] theorem div_le_one_of_neg (hb : b < 0) : a / b ≤ 1 ↔ b ≤ a := by rw [div_le_iff_of_neg hb, one_mul] theorem one_lt_div_of_neg (hb : b < 0) : 1 < a / b ↔ a < b := by rw [lt_div_iff_of_neg hb, one_mul] theorem div_lt_one_of_neg (hb : b < 0) : a / b < 1 ↔ b < a := by rw [div_lt_iff_of_neg hb, one_mul] theorem one_div_le_of_neg (ha : a < 0) (hb : b < 0) : 1 / a ≤ b ↔ 1 / b ≤ a := by simpa using inv_le_of_neg ha hb theorem one_div_lt_of_neg (ha : a < 0) (hb : b < 0) : 1 / a < b ↔ 1 / b < a := by simpa using inv_lt_of_neg ha hb theorem le_one_div_of_neg (ha : a < 0) (hb : b < 0) : a ≤ 1 / b ↔ b ≤ 1 / a := by simpa using le_inv_of_neg ha hb theorem lt_one_div_of_neg (ha : a < 0) (hb : b < 0) : a < 1 / b ↔ b < 1 / a := by simpa using lt_inv_of_neg ha hb theorem one_lt_div_iff : 1 < a / b ↔ 0 < b ∧ b < a ∨ b < 0 ∧ a < b := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, one_lt_div_of_neg] · simp [lt_irrefl, zero_le_one] · simp [hb, hb.not_lt, one_lt_div] theorem one_le_div_iff : 1 ≤ a / b ↔ 0 < b ∧ b ≤ a ∨ b < 0 ∧ a ≤ b := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, one_le_div_of_neg] · simp [lt_irrefl, zero_lt_one.not_le, zero_lt_one] · simp [hb, hb.not_lt, one_le_div] theorem div_lt_one_iff : a / b < 1 ↔ 0 < b ∧ a < b ∨ b = 0 ∨ b < 0 ∧ b < a := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, hb.ne, div_lt_one_of_neg] · simp [zero_lt_one] · simp [hb, hb.not_lt, div_lt_one, hb.ne.symm] theorem div_le_one_iff : a / b ≤ 1 ↔ 0 < b ∧ a ≤ b ∨ b = 0 ∨ b < 0 ∧ b ≤ a := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, hb.ne, div_le_one_of_neg] · simp [zero_le_one] · simp [hb, hb.not_lt, div_le_one, hb.ne.symm] /-! ### Relating two divisions, involving `1` -/ theorem one_div_le_one_div_of_neg_of_le (hb : b < 0) (h : a ≤ b) : 1 / b ≤ 1 / a := by rwa [div_le_iff_of_neg' hb, ← div_eq_mul_one_div, div_le_one_of_neg (h.trans_lt hb)] theorem one_div_lt_one_div_of_neg_of_lt (hb : b < 0) (h : a < b) : 1 / b < 1 / a := by rwa [div_lt_iff_of_neg' hb, ← div_eq_mul_one_div, div_lt_one_of_neg (h.trans hb)] theorem le_of_neg_of_one_div_le_one_div (hb : b < 0) (h : 1 / a ≤ 1 / b) : b ≤ a := le_imp_le_of_lt_imp_lt (one_div_lt_one_div_of_neg_of_lt hb) h theorem lt_of_neg_of_one_div_lt_one_div (hb : b < 0) (h : 1 / a < 1 / b) : b < a := lt_imp_lt_of_le_imp_le (one_div_le_one_div_of_neg_of_le hb) h /-- For the single implications with fewer assumptions, see `one_div_lt_one_div_of_neg_of_lt` and `lt_of_one_div_lt_one_div` -/ theorem one_div_le_one_div_of_neg (ha : a < 0) (hb : b < 0) : 1 / a ≤ 1 / b ↔ b ≤ a := by simpa [one_div] using inv_le_inv_of_neg ha hb /-- For the single implications with fewer assumptions, see `one_div_lt_one_div_of_lt` and `lt_of_one_div_lt_one_div` -/ theorem one_div_lt_one_div_of_neg (ha : a < 0) (hb : b < 0) : 1 / a < 1 / b ↔ b < a := lt_iff_lt_of_le_iff_le (one_div_le_one_div_of_neg hb ha) theorem one_div_lt_neg_one (h1 : a < 0) (h2 : -1 < a) : 1 / a < -1 := suffices 1 / a < 1 / -1 by rwa [one_div_neg_one_eq_neg_one] at this one_div_lt_one_div_of_neg_of_lt h1 h2 theorem one_div_le_neg_one (h1 : a < 0) (h2 : -1 ≤ a) : 1 / a ≤ -1 := suffices 1 / a ≤ 1 / -1 by rwa [one_div_neg_one_eq_neg_one] at this one_div_le_one_div_of_neg_of_le h1 h2 /-! ### Results about halving -/ theorem sub_self_div_two (a : α) : a - a / 2 = a / 2 := by suffices a / 2 + a / 2 - a / 2 = a / 2 by rwa [add_halves] at this rw [add_sub_cancel_right] theorem div_two_sub_self (a : α) : a / 2 - a = -(a / 2) := by suffices a / 2 - (a / 2 + a / 2) = -(a / 2) by rwa [add_halves] at this rw [sub_add_eq_sub_sub, sub_self, zero_sub] theorem add_sub_div_two_lt (h : a < b) : a + (b - a) / 2 < b := by rwa [← div_sub_div_same, sub_eq_add_neg, add_comm (b / 2), ← add_assoc, ← sub_eq_add_neg, ← lt_sub_iff_add_lt, sub_self_div_two, sub_self_div_two, div_lt_div_iff_of_pos_right (zero_lt_two' α)] /-- An inequality involving `2`. -/ theorem sub_one_div_inv_le_two (a2 : 2 ≤ a) : (1 - 1 / a)⁻¹ ≤ 2 := by -- Take inverses on both sides to obtain `2⁻¹ ≤ 1 - 1 / a` refine (inv_anti₀ (inv_pos.2 <\| zero_lt_two' α) ?_).trans_eq (inv_inv (2 : α)) -- move `1 / a` to the left and `2⁻¹` to the right. rw [le_sub_iff_add_le, add_comm, ← le_sub_iff_add_le] -- take inverses on both sides and use the assumption `2 ≤ a`. convert (one_div a).le.trans (inv_anti₀ zero_lt_two a2) using 1 -- show `1 - 1 / 2 = 1 / 2`. rw [sub_eq_iff_eq_add, ← two_mul, mul_inv_cancel₀ two_ne_zero] /-! ### Results about `IsLUB` -/ -- TODO: Generalize to `LinearOrderedSemifield` theorem IsLUB.mul_left {s : Set α} (ha : 0 ≤ a) (hs : IsLUB s b) : IsLUB ((fun b => a * b) '' s) (a * b) := by rcases lt_or_eq_of_le ha with (ha \| rfl) · exact (OrderIso.mulLeft₀ _ ha).isLUB_image'.2 hs · simp_rw [zero_mul] rw [hs.nonempty.image_const] exact isLUB_singleton -- TODO: Generalize to `LinearOrderedSemifield` theorem IsLUB.mul_right {s : Set α} (ha : 0 ≤ a) (hs : IsLUB s b) : IsLUB ((fun b => b * a) '' s) (b * a) := by simpa [mul_comm] using hs.mul_left ha /-! ### Miscellaneous lemmas -/ theorem mul_sub_mul_div_mul_neg_iff (hc : c ≠ 0) (hd : d ≠ 0) : (a * d - b * c) / (c * d) < 0 ↔ a / c < b / d := by rw [mul_comm b c, ← div_sub_div _ _ hc hd, sub_lt_zero] theorem mul_sub_mul_div_mul_nonpos_iff (hc : c ≠ 0) (hd : d ≠ 0) : (a * d - b * c) / (c * d) ≤ 0 ↔ a / c ≤ b / d := by rw [mul_comm b c, ← div_sub_div _ _ hc hd, sub_nonpos] alias ⟨div_lt_div_of_mul_sub_mul_div_neg, mul_sub_mul_div_mul_neg⟩ := mul_sub_mul_div_mul_neg_iff alias ⟨div_le_div_of_mul_sub_mul_div_nonpos, mul_sub_mul_div_mul_nonpos⟩ := mul_sub_mul_div_mul_nonpos_iff theorem exists_add_lt_and_pos_of_lt (h : b < a) : ∃ c, b + c < a ∧ 0 < c := ⟨(a - b) / 2, add_sub_div_two_lt h, div_pos (sub_pos_of_lt h) zero_lt_two⟩ theorem le_of_forall_sub_le (h : ∀ ε > 0, b - ε ≤ a) : b ≤ a := by contrapose! h simpa only [@and_comm ((0 : α) < _), lt_sub_iff_add_lt, gt_iff_lt] using exists_add_lt_and_pos_of_lt h private lemma exists_lt_mul_left_of_nonneg {a b c : α} (ha : 0 ≤ a) (hc : 0 ≤ c) (h : c < a * b) : ∃ a' ∈ Set.Ico 0 a, c < a' * b := by have hb : 0 < b := pos_of_mul_pos_right (hc.trans_lt h) ha obtain ⟨a', ha', a_a'⟩ := exists_between ((div_lt_iff₀ hb).2 h) exact ⟨a', ⟨(div_nonneg hc hb.le).trans ha'.le, a_a'⟩, (div_lt_iff₀ hb).1 ha'⟩ private lemma exists_lt_mul_right_of_nonneg {a b c : α} (ha : 0 ≤ a) (hc : 0 ≤ c) (h : c < a * b) : ∃ b' ∈ Set.Ico 0 b, c < a * b' := by have hb : 0 < b := pos_of_mul_pos_right (hc.trans_lt h) ha simp_rw [mul_comm a] at h ⊢ exact exists_lt_mul_left_of_nonneg hb.le hc h private lemma exists_mul_left_lt₀ {a b c : α} (hc : a * b < c) : ∃ a' > a, a' * b < c := by rcases le_or_lt b 0 with hb \| hb · obtain ⟨a', ha'⟩ := exists_gt a exact ⟨a', ha', hc.trans_le' (antitone_mul_right hb ha'.le)⟩ · obtain ⟨a', ha', hc'⟩ := exists_between ((lt_div_iff₀ hb).2 hc) exact ⟨a', ha', (lt_div_iff₀ hb).1 hc'⟩ private lemma exists_mul_right_lt₀ {a b c : α} (hc : a * b < c) : ∃ b' > b, a * b' < c := by simp_rw [mul_comm a] at hc ⊢; exact exists_mul_left_lt₀ hc lemma le_mul_of_forall_lt₀ {a b c : α} (h : ∀ a' > a, ∀ b' > b, c ≤ a' * b') : c ≤ a * b := by refine le_of_forall_gt_imp_ge_of_dense fun d hd ↦ ?_ obtain ⟨a', ha', hd⟩ := exists_mul_left_lt₀ hd obtain ⟨b', hb', hd⟩ := exists_mul_right_lt₀ hd exact (h a' ha' b' hb').trans hd.le lemma mul_le_of_forall_lt_of_nonneg {a b c : α} (ha : 0 ≤ a) (hc : 0 ≤ c) (h : ∀ a' ≥ 0, a' < a → ∀ b' ≥ 0, b' < b → a' * b' ≤ c) : a * b ≤ c := by refine le_of_forall_lt_imp_le_of_dense fun d d_ab ↦ ?_ rcases lt_or_le d 0 with hd \| hd · exact hd.le.trans hc obtain ⟨a', ha', d_ab⟩ := exists_lt_mul_left_of_nonneg ha hd d_ab obtain ⟨b', hb', d_ab⟩ := exists_lt_mul_right_of_nonneg ha'.1 hd d_ab exact d_ab.le.trans (h a' ha'.1 ha'.2 b' hb'.1 hb'.2) theorem mul_self_inj_of_nonneg (a0 : 0 ≤ a) (b0 : 0 ≤ b) : a * a = b * b ↔ a = b := mul_self_eq_mul_self_iff.trans <\| or_iff_left_of_imp fun h => by subst a have : b = 0 := le_antisymm (neg_nonneg.1 a0) b0 rw [this, neg_zero] theorem min_div_div_right_of_nonpos (hc : c ≤ 0) (a b : α) : min (a / c) (b / c) = max a b / c := Eq.symm <\| Antitone.map_max fun _ _ => div_le_div_of_nonpos_of_le hc theorem max_div_div_right_of_nonpos (hc : c ≤ 0) (a b : α) : max (a / c) (b / c) = min a b / c := Eq.symm <\| Antitone.map_min fun _ _ => div_le_div_of_nonpos_of_le hc theorem abs_inv (a : α) : \|a⁻¹\| = \|a\|⁻¹ := map_inv₀ (absHom : α →₀ α) a theorem abs_div (a b : α) : \|a / b\| = \|a\| / \|b\| := map_div₀ (absHom : α →₀ α) a b theorem abs_one_div (a : α) : \|1 / a\| = 1 / \|a\| := by rw [abs_div, abs_one] theorem uniform_continuous_npow_on_bounded (B : α) {ε : α} (hε : 0 < ε) (n : ℕ) : ∃ δ > 0, ∀ q r : α, \|r\| ≤ B → \|q - r\| ≤ δ → \|q ^ n - r ^ n\| < ε := by wlog B_pos : 0 < B generalizing B · have ⟨δ, δ_pos, cont⟩ := this 1 zero_lt_one exact ⟨δ, δ_pos, fun q r hr ↦ cont q r (hr.trans ((le_of_not_lt B_pos).trans zero_le_one))⟩ have pos : 0 < 1 + ↑n * (B + 1) ^ (n - 1) := zero_lt_one.trans_le <\| le_add_of_nonneg_right <\| mul_nonneg n.cast_nonneg <\| (pow_pos (B_pos.trans <\| lt_add_of_pos_right _ zero_lt_one) _).le refine ⟨min 1 (ε / (1 + n * (B + 1) ^ (n - 1))), lt_min zero_lt_one (div_pos hε pos), fun q r hr hqr ↦ (abs_pow_sub_pow_le ..).trans_lt ?_⟩ rw [le_inf_iff, le_div_iff₀ pos, mul_one_add, ← mul_assoc] at hqr obtain h \| h := (abs_nonneg (q - r)).eq_or_lt · simpa only [← h, zero_mul] using hε refine (lt_of_le_of_lt ?_ <\| lt_add_of_pos_left _ h).trans_le hqr.2 refine mul_le_mul_of_nonneg_left (pow_le_pow_left₀ ((abs_nonneg _).trans le_sup_left) ?_ _) (mul_nonneg (abs_nonneg _) n.cast_nonneg) refine max_le ?_ (hr.trans <\| le_add_of_nonneg_right zero_le_one) exact add_sub_cancel r q ▸ (abs_add_le ..).trans (add_le_add hr hqr.1) end namespace Mathlib.Meta.Positivity open Lean Meta Qq Function section LinearOrderedSemifield variable {α : Type*} [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {a b : α} private lemma div_nonneg_of_pos_of_nonneg (ha : 0 < a) (hb : 0 ≤ b) : 0 ≤ a / b := div_nonneg ha.le hb private lemma div_nonneg_of_nonneg_of_pos (ha : 0 ≤ a) (hb : 0 < b) : 0 ≤ a / b := div_nonneg ha hb.le omit [IsStrictOrderedRing α] in private lemma div_ne_zero_of_pos_of_ne_zero (ha : 0 < a) (hb : b ≠ 0) : a / b ≠ 0 := div_ne_zero ha.ne' hb omit [IsStrictOrderedRing α] in private lemma div_ne_zero_of_ne_zero_of_pos (ha : a ≠ 0) (hb : 0 < b) : a / b ≠ 0 := div_ne_zero ha hb.ne' private lemma zpow_zero_pos (a : α) : 0 < a ^ (0 : ℤ) := zero_lt_one.trans_eq (zpow_zero a).symm end LinearOrderedSemifield /-- The `positivity` extension which identifies expressions of the form `a / b`, such that `positivity` successfully recognises both `a` and `b`. -/ @[positivity _ / _] def evalDiv : PositivityExt where eval {u α} zα pα e := do let .app (.app (f : Q($α → $α → $α)) (a : Q($α))) (b : Q($α)) ← withReducible (whnf e) \| throwError "not /" let _e_eq : $e =Q $f $a $b := ⟨⟩ let _a ← synthInstanceQ q(Semifield $α) let _a ← synthInstanceQ q(LinearOrder $α) let _a ← synthInstanceQ q(IsStrictOrderedRing $α) assumeInstancesCommute let ⟨_f_eq⟩ ← withDefault <\| withNewMCtxDepth <\| assertDefEqQ q($f) q(HDiv.hDiv) let ra ← core zα pα a; let rb ← core zα pα b match ra, rb with \| .positive pa, .positive pb => pure (.positive q(div_pos $pa $pb)) \| .positive pa, .nonnegative pb => pure (.nonnegative q(div_nonneg_of_pos_of_nonneg $pa $pb)) \| .nonnegative pa, .positive pb => pure (.nonnegative q(div_nonneg_of_nonneg_of_pos $pa $pb)) \| .nonnegative pa, .nonnegative pb => pure (.nonnegative q(div_nonneg $pa $pb)) \| .positive pa, .nonzero pb => pure (.nonzero q(div_ne_zero_of_pos_of_ne_zero $pa $pb)) \| .nonzero pa, .positive pb => pure (.nonzero q(div_ne_zero_of_ne_zero_of_pos $pa $pb)) \| .nonzero pa, .nonzero pb => pure (.nonzero q(div_ne_zero $pa $pb)) \| _, _ => pure .none /-- The `positivity` extension which identifies expressions of the form `a⁻¹`, such that `positivity` successfully recognises `a`. -/ @[positivity _⁻¹] def evalInv : PositivityExt where eval {u α} zα pα e := do let .app (f : Q($α → $α)) (a : Q($α)) ← withReducible (whnf e) \| throwError "not ⁻¹" let _e_eq : $e =Q $f $a := ⟨⟩ let _a ← synthInstanceQ q(Semifield $α) let _a ← synthInstanceQ q(LinearOrder $α) let _a ← synthInstanceQ q(IsStrictOrderedRing $α) assumeInstancesCommute let ⟨_f_eq⟩ ← withDefault <\| withNewMCtxDepth <\| assertDefEqQ q($f) q(Inv.inv) let ra ← core zα pα a match ra with \| .positive pa => pure (.positive q(inv_pos_of_pos $pa)) \| .nonnegative pa => pure (.nonnegative q(inv_nonneg_of_nonneg $pa)) \| .nonzero pa => pure (.nonzero q(inv_ne_zero $pa)) \| .none => pure .none /-- The `positivity` extension which identifies expressions of the form `a ^ (0:ℤ)`. -/ @[positivity _ ^ (0 : ℤ), Pow.pow _ (0 : ℤ)] def evalPowZeroInt : PositivityExt where eval {u α} _zα _pα e := do let .app (.app _ (a : Q($α))) _ ← withReducible (whnf e) \| throwError "not ^" let _a ← synthInstanceQ q(Semifield $α) let _a ← synthInstanceQ q(LinearOrder $α) let _a ← synthInstanceQ q(IsStrictOrderedRing $α) assumeInstancesCommute let ⟨_a⟩ ← Qq.assertDefEqQ q($e) q($a ^ (0 : ℤ)) pure (.positive q(zpow_zero_pos $a)) end Mathlib.Meta.Positivity		Mathlib/Algebra/Order/Field/Basic.lean	880	881
/- Copyright (c) 2019 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Patrick Massot, Casper Putz, Anne Baanen -/ import Mathlib.Algebra.Order.Star.Basic import Mathlib.Data.Matrix.RowCol /-! # Dot product of two vectors This file contains some results on the map `dotProduct`, which maps two vectors `v w : n → R` to the sum of the entrywise products `v i * w i`. ## Main results * `dotProduct_stdBasis_one`: the dot product of `v` with the `i`th standard basis vector is `v i` * `dotProduct_eq_zero_iff`: if `v`'s dot product with all `w` is zero, then `v` is zero ## Tags matrix -/ variable {m n p R : Type*} section Semiring variable [Semiring R] [Fintype n] theorem dotProduct_eq (v w : n → R) (h : ∀ u, dotProduct v u = dotProduct w u) : v = w := by funext x classical rw [← dotProduct_single_one v x, ← dotProduct_single_one w x, h] @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_eq := dotProduct_eq theorem dotProduct_eq_iff {v w : n → R} : (∀ u, dotProduct v u = dotProduct w u) ↔ v = w := ⟨fun h => dotProduct_eq v w h, fun h _ => h ▸ rfl⟩ @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_eq_iff := dotProduct_eq_iff theorem dotProduct_eq_zero (v : n → R) (h : ∀ w, dotProduct v w = 0) : v = 0 := dotProduct_eq _ _ fun u => (h u).symm ▸ (zero_dotProduct u).symm @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_eq_zero := dotProduct_eq_zero theorem dotProduct_eq_zero_iff {v : n → R} : (∀ w, dotProduct v w = 0) ↔ v = 0 := ⟨fun h => dotProduct_eq_zero v h, fun h w => h.symm ▸ zero_dotProduct w⟩ @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_eq_zero_iff := dotProduct_eq_zero_iff end Semiring section OrderedSemiring variable [Semiring R] [PartialOrder R] [IsOrderedRing R] [Fintype n] lemma dotProduct_nonneg_of_nonneg {v w : n → R} (hv : 0 ≤ v) (hw : 0 ≤ w) : 0 ≤ dotProduct v w := Finset.sum_nonneg (fun i _ => mul_nonneg (hv i) (hw i)) @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_nonneg_of_nonneg := dotProduct_nonneg_of_nonneg lemma dotProduct_le_dotProduct_of_nonneg_right {u v w : n → R} (huv : u ≤ v) (hw : 0 ≤ w) : dotProduct u w ≤ dotProduct v w := Finset.sum_le_sum (fun i _ => mul_le_mul_of_nonneg_right (huv i) (hw i)) @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_le_dotProduct_of_nonneg_right := dotProduct_le_dotProduct_of_nonneg_right lemma dotProduct_le_dotProduct_of_nonneg_left {u v w : n → R} (huv : u ≤ v) (hw : 0 ≤ w) : dotProduct w u ≤ dotProduct w v := Finset.sum_le_sum (fun i _ => mul_le_mul_of_nonneg_left (huv i) (hw i)) @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_le_dotProduct_of_nonneg_left := dotProduct_le_dotProduct_of_nonneg_left end OrderedSemiring section Self variable [Fintype m] [Fintype n] [Fintype p] @[simp] theorem dotProduct_self_eq_zero [Ring R] [LinearOrder R] [IsStrictOrderedRing R] {v : n → R} : dotProduct v v = 0 ↔ v = 0 := (Finset.sum_eq_zero_iff_of_nonneg fun i _ => mul_self_nonneg (v i)).trans <\| by simp [funext_iff] @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_self_eq_zero := dotProduct_self_eq_zero section StarOrderedRing variable [PartialOrder R] [NonUnitalRing R] [StarRing R] [StarOrderedRing R] /-- Note that this applies to `ℂ` via `RCLike.toStarOrderedRing`. -/ @[simp] theorem dotProduct_star_self_nonneg (v : n → R) : 0 ≤ dotProduct (star v) v := Fintype.sum_nonneg fun _ => star_mul_self_nonneg _ @[deprecated (since := "2024-12-12")] protected alias Matrix.dotProduct_star_self_nonneg := dotProduct_star_self_nonneg	/-- Note that this applies to `ℂ` via `RCLike.toStarOrderedRing`. -/ @[simp] theorem dotProduct_self_star_nonneg (v : n → R) : 0 ≤ dotProduct v (star v) :=	Mathlib/LinearAlgebra/Matrix/DotProduct.lean	113	115
/- Copyright (c) 2020 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison, Justus Springer -/ import Mathlib.Geometry.RingedSpace.LocallyRingedSpace import Mathlib.AlgebraicGeometry.StructureSheaf import Mathlib.RingTheory.Localization.LocalizationLocalization import Mathlib.Topology.Sheaves.SheafCondition.Sites import Mathlib.Topology.Sheaves.Functors import Mathlib.Algebra.Module.LocalizedModule.Basic /-! # $Spec$ as a functor to locally ringed spaces. We define the functor $Spec$ from commutative rings to locally ringed spaces. ## Implementation notes We define $Spec$ in three consecutive steps, each with more structure than the last: 1. `Spec.toTop`, valued in the category of topological spaces, 2. `Spec.toSheafedSpace`, valued in the category of sheafed spaces and 3. `Spec.toLocallyRingedSpace`, valued in the category of locally ringed spaces. Additionally, we provide `Spec.toPresheafedSpace` as a composition of `Spec.toSheafedSpace` with a forgetful functor. ## Related results The adjunction `Γ ⊣ Spec` is constructed in `Mathlib/AlgebraicGeometry/GammaSpecAdjunction.lean`. -/ -- Explicit universe annotations were used in this file to improve performance https://github.com/leanprover-community/mathlib4/issues/12737 noncomputable section universe u v namespace AlgebraicGeometry open Opposite open CategoryTheory open StructureSheaf open Spec (structureSheaf) /-- The spectrum of a commutative ring, as a topological space. -/ def Spec.topObj (R : CommRingCat.{u}) : TopCat := TopCat.of (PrimeSpectrum R) @[simp] theorem Spec.topObj_forget {R} : ToType (Spec.topObj R) = PrimeSpectrum R := rfl /-- The induced map of a ring homomorphism on the ring spectra, as a morphism of topological spaces. -/ def Spec.topMap {R S : CommRingCat.{u}} (f : R ⟶ S) : Spec.topObj S ⟶ Spec.topObj R := TopCat.ofHom (PrimeSpectrum.comap f.hom) @[simp] theorem Spec.topMap_id (R : CommRingCat.{u}) : Spec.topMap (𝟙 R) = 𝟙 (Spec.topObj R) := rfl @[simp] theorem Spec.topMap_comp {R S T : CommRingCat.{u}} (f : R ⟶ S) (g : S ⟶ T) : Spec.topMap (f ≫ g) = Spec.topMap g ≫ Spec.topMap f := rfl -- Porting note: `simps!` generate some garbage lemmas, so choose manually, -- if more is needed, add them here /-- The spectrum, as a contravariant functor from commutative rings to topological spaces. -/ @[simps!] def Spec.toTop : CommRingCat.{u}ᵒᵖ ⥤ TopCat where obj R := Spec.topObj (unop R) map {_ _} f := Spec.topMap f.unop /-- The spectrum of a commutative ring, as a `SheafedSpace`. -/ @[simps] def Spec.sheafedSpaceObj (R : CommRingCat.{u}) : SheafedSpace CommRingCat where carrier := Spec.topObj R presheaf := (structureSheaf R).1 IsSheaf := (structureSheaf R).2 /-- The induced map of a ring homomorphism on the ring spectra, as a morphism of sheafed spaces. -/ @[simps base c_app] def Spec.sheafedSpaceMap {R S : CommRingCat.{u}} (f : R ⟶ S) : Spec.sheafedSpaceObj S ⟶ Spec.sheafedSpaceObj R where base := Spec.topMap f c := { app := fun U => CommRingCat.ofHom <\| comap f.hom (unop U) ((TopologicalSpace.Opens.map (Spec.topMap f)).obj (unop U)) fun _ => id naturality := fun {_ _} _ => by ext; rfl } @[simp] theorem Spec.sheafedSpaceMap_id {R : CommRingCat.{u}} : Spec.sheafedSpaceMap (𝟙 R) = 𝟙 (Spec.sheafedSpaceObj R) := AlgebraicGeometry.PresheafedSpace.Hom.ext _ _ (Spec.topMap_id R) <\| by ext dsimp rw [comap_id (by simp)] simp rfl theorem Spec.sheafedSpaceMap_comp {R S T : CommRingCat.{u}} (f : R ⟶ S) (g : S ⟶ T) : Spec.sheafedSpaceMap (f ≫ g) = Spec.sheafedSpaceMap g ≫ Spec.sheafedSpaceMap f := AlgebraicGeometry.PresheafedSpace.Hom.ext _ _ (Spec.topMap_comp f g) <\| by ext -- Porting note: was one liner -- `dsimp, rw category_theory.functor.map_id, rw category.comp_id, erw comap_comp f g, refl` rw [NatTrans.comp_app, sheafedSpaceMap_c_app, whiskerRight_app, eqToHom_refl] erw [(sheafedSpaceObj T).presheaf.map_id] dsimp only [CommRingCat.hom_comp, RingHom.coe_comp, Function.comp_apply] rw [comap_comp] rfl /-- Spec, as a contravariant functor from commutative rings to sheafed spaces. -/ @[simps] def Spec.toSheafedSpace : CommRingCat.{u}ᵒᵖ ⥤ SheafedSpace CommRingCat where obj R := Spec.sheafedSpaceObj (unop R) map f := Spec.sheafedSpaceMap f.unop map_comp f g := by simp [Spec.sheafedSpaceMap_comp] /-- Spec, as a contravariant functor from commutative rings to presheafed spaces. -/ def Spec.toPresheafedSpace : CommRingCat.{u}ᵒᵖ ⥤ PresheafedSpace CommRingCat := Spec.toSheafedSpace ⋙ SheafedSpace.forgetToPresheafedSpace @[simp] theorem Spec.toPresheafedSpace_obj (R : CommRingCat.{u}ᵒᵖ) : Spec.toPresheafedSpace.obj R = (Spec.sheafedSpaceObj (unop R)).toPresheafedSpace := rfl theorem Spec.toPresheafedSpace_obj_op (R : CommRingCat.{u}) : Spec.toPresheafedSpace.obj (op R) = (Spec.sheafedSpaceObj R).toPresheafedSpace := rfl @[simp] theorem Spec.toPresheafedSpace_map (R S : CommRingCat.{u}ᵒᵖ) (f : R ⟶ S) : Spec.toPresheafedSpace.map f = Spec.sheafedSpaceMap f.unop := rfl theorem Spec.toPresheafedSpace_map_op (R S : CommRingCat.{u}) (f : R ⟶ S) : Spec.toPresheafedSpace.map f.op = Spec.sheafedSpaceMap f := rfl theorem Spec.basicOpen_hom_ext {X : RingedSpace.{u}} {R : CommRingCat.{u}} {α β : X ⟶ Spec.sheafedSpaceObj R} (w : α.base = β.base) (h : ∀ r : R, let U := PrimeSpectrum.basicOpen r (toOpen R U ≫ α.c.app (op U)) ≫ X.presheaf.map (eqToHom (by rw [w])) = toOpen R U ≫ β.c.app (op U)) : α = β := by ext : 1 · exact w · apply ((TopCat.Sheaf.pushforward _ β.base).obj X.sheaf).hom_ext _ PrimeSpectrum.isBasis_basic_opens intro r apply (StructureSheaf.to_basicOpen_epi R r).1 simpa using h r -- Porting note: `simps!` generate some garbage lemmas, so choose manually, -- if more is needed, add them here /-- The spectrum of a commutative ring, as a `LocallyRingedSpace`. -/ @[simps! toSheafedSpace presheaf] def Spec.locallyRingedSpaceObj (R : CommRingCat.{u}) : LocallyRingedSpace := { Spec.sheafedSpaceObj R with isLocalRing := fun x => RingEquiv.isLocalRing (A := Localization.AtPrime x.asIdeal) (Iso.commRingCatIsoToRingEquiv <\| stalkIso R x).symm } lemma Spec.locallyRingedSpaceObj_sheaf (R : CommRingCat.{u}) : (Spec.locallyRingedSpaceObj R).sheaf = structureSheaf R := rfl lemma Spec.locallyRingedSpaceObj_sheaf' (R : Type u) [CommRing R] : (Spec.locallyRingedSpaceObj <\| CommRingCat.of R).sheaf = structureSheaf R := rfl lemma Spec.locallyRingedSpaceObj_presheaf_map (R : CommRingCat.{u}) {U V} (i : U ⟶ V) : (Spec.locallyRingedSpaceObj R).presheaf.map i = (structureSheaf R).1.map i := rfl lemma Spec.locallyRingedSpaceObj_presheaf' (R : Type u) [CommRing R] : (Spec.locallyRingedSpaceObj <\| CommRingCat.of R).presheaf = (structureSheaf R).1 := rfl lemma Spec.locallyRingedSpaceObj_presheaf_map' (R : Type u) [CommRing R] {U V} (i : U ⟶ V) : (Spec.locallyRingedSpaceObj <\| CommRingCat.of R).presheaf.map i = (structureSheaf R).1.map i := rfl @[elementwise] theorem stalkMap_toStalk {R S : CommRingCat.{u}} (f : R ⟶ S) (p : PrimeSpectrum S) : toStalk R (PrimeSpectrum.comap f.hom p) ≫ (Spec.sheafedSpaceMap f).stalkMap p = f ≫ toStalk S p := by rw [← toOpen_germ S ⊤ p trivial, ← toOpen_germ R ⊤ (PrimeSpectrum.comap f.hom p) trivial, Category.assoc] erw [PresheafedSpace.stalkMap_germ (Spec.sheafedSpaceMap f) ⊤ p trivial] rw [Spec.sheafedSpaceMap_c_app] erw [toOpen_comp_comap_assoc] rfl /-- Under the isomorphisms `stalkIso`, the map `stalkMap (Spec.sheafedSpaceMap f) p` corresponds to the induced local ring homomorphism `Localization.localRingHom`. -/ @[elementwise] theorem localRingHom_comp_stalkIso {R S : CommRingCat.{u}} (f : R ⟶ S) (p : PrimeSpectrum S) : (stalkIso R (PrimeSpectrum.comap f.hom p)).hom ≫ (CommRingCat.ofHom (Localization.localRingHom (PrimeSpectrum.comap f.hom p).asIdeal p.asIdeal f.hom rfl)) ≫ (stalkIso S p).inv = (Spec.sheafedSpaceMap f).stalkMap p := (stalkIso R (PrimeSpectrum.comap f.hom p)).eq_inv_comp.mp <\| (stalkIso S p).comp_inv_eq.mpr <\| CommRingCat.hom_ext <\| Localization.localRingHom_unique _ _ _ (PrimeSpectrum.comap_asIdeal _ _) fun x => by -- This used to be `rw`, but we need `erw` after https://github.com/leanprover/lean4/pull/2644 and https://github.com/leanprover-community/mathlib4/pull/8386 rw [stalkIso_hom, stalkIso_inv, CommRingCat.comp_apply, CommRingCat.comp_apply, localizationToStalk_of, stalkMap_toStalk_apply f p x] erw [stalkToFiberRingHom_toStalk] rfl /-- Version of `localRingHom_comp_stalkIso_apply` using `CommRingCat.Hom.hom` -/ theorem localRingHom_comp_stalkIso_apply' {R S : CommRingCat.{u}} (f : R ⟶ S) (p : PrimeSpectrum S) (x) : (stalkIso S p).inv ((Localization.localRingHom (PrimeSpectrum.comap f.hom p).asIdeal p.asIdeal f.hom rfl) ((stalkIso R (PrimeSpectrum.comap f.hom p)).hom x)) = (Spec.sheafedSpaceMap f).stalkMap p x := localRingHom_comp_stalkIso_apply _ _ _ /-- The induced map of a ring homomorphism on the prime spectra, as a morphism of locally ringed spaces. -/ @[simps toShHom] def Spec.locallyRingedSpaceMap {R S : CommRingCat.{u}} (f : R ⟶ S) : Spec.locallyRingedSpaceObj S ⟶ Spec.locallyRingedSpaceObj R := LocallyRingedSpace.Hom.mk (Spec.sheafedSpaceMap f) fun p => IsLocalHom.mk fun a ha => by -- Here, we are showing that the map on prime spectra induced by `f` is really a morphism of -- locally ringed spaces, i.e. that the induced map on the stalks is a local ring -- homomorphism. #adaptation_note /-- nightly-2024-04-01 It's this `erw` that is blowing up. The implicit arguments differ significantly. -/ erw [← localRingHom_comp_stalkIso_apply' f p a] at ha have : IsLocalHom (stalkIso (↑S) p).inv.hom := isLocalHom_of_isIso _ replace ha := (isUnit_map_iff (stalkIso S p).inv.hom _).mp ha replace ha := IsLocalHom.map_nonunit ((stalkIso R ((PrimeSpectrum.comap f.hom) p)).hom a) ha convert RingHom.isUnit_map (stalkIso R (PrimeSpectrum.comap f.hom p)).inv.hom ha rw [← CommRingCat.comp_apply, Iso.hom_inv_id, CommRingCat.id_apply] @[simp] theorem Spec.locallyRingedSpaceMap_id (R : CommRingCat.{u}) : Spec.locallyRingedSpaceMap (𝟙 R) = 𝟙 (Spec.locallyRingedSpaceObj R) := LocallyRingedSpace.Hom.ext' <\| by rw [Spec.locallyRingedSpaceMap_toShHom, Spec.sheafedSpaceMap_id]; rfl theorem Spec.locallyRingedSpaceMap_comp {R S T : CommRingCat.{u}} (f : R ⟶ S) (g : S ⟶ T) : Spec.locallyRingedSpaceMap (f ≫ g) = Spec.locallyRingedSpaceMap g ≫ Spec.locallyRingedSpaceMap f := LocallyRingedSpace.Hom.ext' <\| by rw [Spec.locallyRingedSpaceMap_toShHom, Spec.sheafedSpaceMap_comp]; rfl /-- Spec, as a contravariant functor from commutative rings to locally ringed spaces. -/ @[simps] def Spec.toLocallyRingedSpace : CommRingCat.{u}ᵒᵖ ⥤ LocallyRingedSpace where obj R := Spec.locallyRingedSpaceObj (unop R) map f := Spec.locallyRingedSpaceMap f.unop map_id R := by dsimp; rw [Spec.locallyRingedSpaceMap_id] map_comp f g := by dsimp; rw [Spec.locallyRingedSpaceMap_comp] section SpecΓ open AlgebraicGeometry.LocallyRingedSpace /-- The counit morphism `R ⟶ Γ(Spec R)` given by `AlgebraicGeometry.StructureSheaf.toOpen`. -/ def toSpecΓ (R : CommRingCat.{u}) : R ⟶ Γ.obj (op (Spec.toLocallyRingedSpace.obj (op R))) := StructureSheaf.toOpen R ⊤ instance isIso_toSpecΓ (R : CommRingCat.{u}) : IsIso (toSpecΓ R) := by cases R; apply StructureSheaf.isIso_to_global @[reassoc] theorem Spec_Γ_naturality {R S : CommRingCat.{u}} (f : R ⟶ S) : f ≫ toSpecΓ S = toSpecΓ R ≫ Γ.map (Spec.toLocallyRingedSpace.map f.op).op := by -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11041): `ext` failed to pick up one of the three lemmas ext : 2 refine Subtype.ext <\| funext fun x' => ?_; symm apply Localization.localRingHom_to_map /-- The counit (`SpecΓIdentity.inv.op`) of the adjunction `Γ ⊣ Spec` is an isomorphism. -/ @[simps! hom_app inv_app] def LocallyRingedSpace.SpecΓIdentity : Spec.toLocallyRingedSpace.rightOp ⋙ Γ ≅ 𝟭 _ := Iso.symm <\| NatIso.ofComponents.{u,u,u+1,u+1} (fun R => -- Porting note: In Lean3, this `IsIso` is synthesized automatically letI : IsIso (toSpecΓ R) := StructureSheaf.isIso_to_global _ asIso (toSpecΓ R)) fun {X Y} f => by convert Spec_Γ_naturality (R := X) (S := Y) f end SpecΓ /-- The stalk map of `Spec M⁻¹R ⟶ Spec R` is an iso for each `p : Spec M⁻¹R`. -/ theorem Spec_map_localization_isIso (R : CommRingCat.{u}) (M : Submonoid R) (x : PrimeSpectrum (Localization M)) : IsIso ((Spec.toPresheafedSpace.map (CommRingCat.ofHom (algebraMap R (Localization M))).op).stalkMap x) := by dsimp only [Spec.toPresheafedSpace_map, Quiver.Hom.unop_op] rw [← localRingHom_comp_stalkIso] -- Porting note: replaced `apply (config := { instances := false })`. -- See https://github.com/leanprover/lean4/issues/2273 refine IsIso.comp_isIso' inferInstance (IsIso.comp_isIso' ?_ inferInstance) /- I do not know why this is defeq to the goal, but I'm happy to accept that it is. -/ show IsIso (IsLocalization.localizationLocalizationAtPrimeIsoLocalization M x.asIdeal).toRingEquiv.toCommRingCatIso.hom infer_instance namespace StructureSheaf variable {R S : CommRingCat.{u}} (f : R ⟶ S) (p : PrimeSpectrum R) /-- For an algebra `f : R →+* S`, this is the ring homomorphism `S →+* (f∗ 𝒪ₛ)ₚ` for a `p : Spec R`. This is shown to be the localization at `p` in `isLocalizedModule_toPushforwardStalkAlgHom`. -/ def toPushforwardStalk : S ⟶ (Spec.topMap f _* (structureSheaf S).1).stalk p := StructureSheaf.toOpen S ⊤ ≫ @TopCat.Presheaf.germ _ _ _ _ (Spec.topMap f _* (structureSheaf S).1) ⊤ p trivial @[reassoc] theorem toPushforwardStalk_comp : f ≫ StructureSheaf.toPushforwardStalk f p = StructureSheaf.toStalk R p ≫ (TopCat.Presheaf.stalkFunctor _ _).map (Spec.sheafedSpaceMap f).c := by rw [StructureSheaf.toStalk, Category.assoc, TopCat.Presheaf.stalkFunctor_map_germ] exact Spec_Γ_naturality_assoc f _ instance : Algebra R ((Spec.topMap f _* (structureSheaf S).1).stalk p) := (f ≫ StructureSheaf.toPushforwardStalk f p).hom.toAlgebra theorem algebraMap_pushforward_stalk : algebraMap R ((Spec.topMap f _* (structureSheaf S).1).stalk p) = (f ≫ StructureSheaf.toPushforwardStalk f p).hom := rfl variable (R S) variable [Algebra R S] /-- This is the `AlgHom` version of `toPushforwardStalk`, which is the map `S ⟶ (f∗ 𝒪ₛ)ₚ` for some algebra `R ⟶ S` and some `p : Spec R`.	-/ @[simps!] def toPushforwardStalkAlgHom : S →ₐ[R] (Spec.topMap (CommRingCat.ofHom (algebraMap R S)) _* (structureSheaf S).1).stalk p := { (StructureSheaf.toPushforwardStalk (CommRingCat.ofHom (algebraMap R S)) p).hom with commutes' := fun _ => rfl } theorem isLocalizedModule_toPushforwardStalkAlgHom_aux (y) : ∃ x : S × p.asIdeal.primeCompl, x.2 • y = toPushforwardStalkAlgHom R S p x.1 := by obtain ⟨U, hp, s, e⟩ := TopCat.Presheaf.germ_exist _ _ y obtain ⟨_, ⟨r, rfl⟩, hpr : p ∈ PrimeSpectrum.basicOpen r, hrU : PrimeSpectrum.basicOpen r ≤ U⟩ := PrimeSpectrum.isTopologicalBasis_basic_opens.exists_subset_of_mem_open (show p ∈ U from hp) U.2 change PrimeSpectrum.basicOpen r ≤ U at hrU replace e := ((Spec.topMap (CommRingCat.ofHom (algebraMap R S)) _* (structureSheaf S).1).germ_res_apply	Mathlib/AlgebraicGeometry/Spec.lean	359	373
/- Copyright (c) 2020 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Computability.Halting import Mathlib.Computability.TuringMachine import Mathlib.Data.Num.Lemmas import Mathlib.Tactic.DeriveFintype import Mathlib.Computability.TMConfig /-! # Modelling partial recursive functions using Turing machines The files `TMConfig` and `TMToPartrec` define a simplified basis for partial recursive functions, and a `Turing.TM2` model Turing machine for evaluating these functions. This amounts to a constructive proof that every `Partrec` function can be evaluated by a Turing machine. ## Main definitions * `PartrecToTM2.tr`: A TM2 turing machine which can evaluate `code` programs -/ open List (Vector) open Function (update) open Relation namespace Turing /-! ## Simulating sequentialized partial recursive functions in TM2 At this point we have a sequential model of partial recursive functions: the `Cfg` type and `step : Cfg → Option Cfg` function from `TMConfig.lean`. The key feature of this model is that it does a finite amount of computation (in fact, an amount which is statically bounded by the size of the program) between each step, and no individual step can diverge (unlike the compositional semantics, where every sub-part of the computation is potentially divergent). So we can utilize the same techniques as in the other TM simulations in `Computability.TuringMachine` to prove that each step corresponds to a finite number of steps in a lower level model. (We don't prove it here, but in anticipation of the complexity class P, the simulation is actually polynomial-time as well.) The target model is `Turing.TM2`, which has a fixed finite set of stacks, a bit of local storage, with programs selected from a potentially infinite (but finitely accessible) set of program positions, or labels `Λ`, each of which executes a finite sequence of basic stack commands. For this program we will need four stacks, each on an alphabet `Γ'` like so: inductive Γ' \| consₗ \| cons \| bit0 \| bit1 We represent a number as a bit sequence, lists of numbers by putting `cons` after each element, and lists of lists of natural numbers by putting `consₗ` after each list. For example: 0 ~> [] 1 ~> [bit1] 6 ~> [bit0, bit1, bit1] [1, 2] ~> [bit1, cons, bit0, bit1, cons] [[], [1, 2]] ~> [consₗ, bit1, cons, bit0, bit1, cons, consₗ] The four stacks are `main`, `rev`, `aux`, `stack`. In normal mode, `main` contains the input to the current program (a `List ℕ`) and `stack` contains data (a `List (List ℕ)`) associated to the current continuation, and in `ret` mode `main` contains the value that is being passed to the continuation and `stack` contains the data for the continuation. The `rev` and `aux` stacks are usually empty; `rev` is used to store reversed data when e.g. moving a value from one stack to another, while `aux` is used as a temporary for a `main`/`stack` swap that happens during `cons₁` evaluation. The only local store we need is `Option Γ'`, which stores the result of the last pop operation. (Most of our working data are natural numbers, which are too large to fit in the local store.) The continuations from the previous section are data-carrying, containing all the values that have been computed and are awaiting other arguments. In order to have only a finite number of continuations appear in the program so that they can be used in machine states, we separate the data part (anything with type `List ℕ`) from the `Cont` type, producing a `Cont'` type that lacks this information. The data is kept on the `stack` stack. Because we want to have subroutines for e.g. moving an entire stack to another place, we use an infinite inductive type `Λ'` so that we can execute a program and then return to do something else without having to define too many different kinds of intermediate states. (We must nevertheless prove that only finitely many labels are accessible.) The labels are: * `move p k₁ k₂ q`: move elements from stack `k₁` to `k₂` while `p` holds of the value being moved. The last element, that fails `p`, is placed in neither stack but left in the local store. At the end of the operation, `k₂` will have the elements of `k₁` in reverse order. Then do `q`. * `clear p k q`: delete elements from stack `k` until `p` is true. Like `move`, the last element is left in the local storage. Then do `q`. * `copy q`: Move all elements from `rev` to both `main` and `stack` (in reverse order), then do `q`. That is, it takes `(a, b, c, d)` to `(b.reverse ++ a, [], c, b.reverse ++ d)`. * `push k f q`: push `f s`, where `s` is the local store, to stack `k`, then do `q`. This is a duplicate of the `push` instruction that is part of the TM2 model, but by having a subroutine just for this purpose we can build up programs to execute inside a `goto` statement, where we have the flexibility to be general recursive. * `read (f : Option Γ' → Λ')`: go to state `f s` where `s` is the local store. Again this is only here for convenience. * `succ q`: perform a successor operation. Assuming `[n]` is encoded on `main` before, `[n+1]` will be on main after. This implements successor for binary natural numbers. * `pred q₁ q₂`: perform a predecessor operation or `case` statement. If `[]` is encoded on `main` before, then we transition to `q₁` with `[]` on main; if `(0 :: v)` is on `main` before then `v` will be on `main` after and we transition to `q₁`; and if `(n+1 :: v)` is on `main` before then `n :: v` will be on `main` after and we transition to `q₂`. * `ret k`: call continuation `k`. Each continuation has its own interpretation of the data in `stack` and sets up the data for the next continuation. * `ret (cons₁ fs k)`: `v :: KData` on `stack` and `ns` on `main`, and the next step expects `v` on `main` and `ns :: KData` on `stack`. So we have to do a little dance here with six reverse-moves using the `aux` stack to perform a three-point swap, each of which involves two reversals. * `ret (cons₂ k)`: `ns :: KData` is on `stack` and `v` is on `main`, and we have to put `ns.headI :: v` on `main` and `KData` on `stack`. This is done using the `head` subroutine. * `ret (fix f k)`: This stores no data, so we just check if `main` starts with `0` and if so, remove it and call `k`, otherwise `clear` the first value and call `f`. * `ret halt`: the stack is empty, and `main` has the output. Do nothing and halt. In addition to these basic states, we define some additional subroutines that are used in the above: * `push'`, `peek'`, `pop'` are special versions of the builtins that use the local store to supply inputs and outputs. * `unrev`: special case `move false rev main` to move everything from `rev` back to `main`. Used as a cleanup operation in several functions. * `moveExcl p k₁ k₂ q`: same as `move` but pushes the last value read back onto the source stack. * `move₂ p k₁ k₂ q`: double `move`, so that the result comes out in the right order at the target stack. Implemented as `moveExcl p k rev; move false rev k₂`. Assumes that neither `k₁` nor `k₂` is `rev` and `rev` is initially empty. * `head k q`: get the first natural number from stack `k` and reverse-move it to `rev`, then clear the rest of the list at `k` and then `unrev` to reverse-move the head value to `main`. This is used with `k = main` to implement regular `head`, i.e. if `v` is on `main` before then `[v.headI]` will be on `main` after; and also with `k = stack` for the `cons` operation, which has `v` on `main` and `ns :: KData` on `stack`, and results in `KData` on `stack` and `ns.headI :: v` on `main`. * `trNormal` is the main entry point, defining states that perform a given `code` computation. It mostly just dispatches to functions written above. The main theorem of this section is `tr_eval`, which asserts that for each that for each code `c`, the state `init c v` steps to `halt v'` in finitely many steps if and only if `Code.eval c v = some v'`. -/ namespace PartrecToTM2 section open ToPartrec /-- The alphabet for the stacks in the program. `bit0` and `bit1` are used to represent `ℕ` values as lists of binary digits, `cons` is used to separate `List ℕ` values, and `consₗ` is used to separate `List (List ℕ)` values. See the section documentation. -/ inductive Γ' \| consₗ \| cons \| bit0 \| bit1 deriving DecidableEq, Inhabited, Fintype /-- The four stacks used by the program. `main` is used to store the input value in `trNormal` mode and the output value in `Λ'.ret` mode, while `stack` is used to keep all the data for the continuations. `rev` is used to store reversed lists when transferring values between stacks, and `aux` is only used once in `cons₁`. See the section documentation. -/ inductive K' \| main \| rev \| aux \| stack deriving DecidableEq, Inhabited open K' /-- Continuations as in `ToPartrec.Cont` but with the data removed. This is done because we want the set of all continuations in the program to be finite (so that it can ultimately be encoded into the finite state machine of a Turing machine), but a continuation can handle a potentially infinite number of data values during execution. -/ inductive Cont' \| halt \| cons₁ : Code → Cont' → Cont' \| cons₂ : Cont' → Cont' \| comp : Code → Cont' → Cont' \| fix : Code → Cont' → Cont' deriving DecidableEq, Inhabited /-- The set of program positions. We make extensive use of inductive types here to let us describe "subroutines"; for example `clear p k q` is a program that clears stack `k`, then does `q` where `q` is another label. In order to prevent this from resulting in an infinite number of distinct accessible states, we are careful to be non-recursive (although loops are okay). See the section documentation for a description of all the programs. -/ inductive Λ' \| move (p : Γ' → Bool) (k₁ k₂ : K') (q : Λ') \| clear (p : Γ' → Bool) (k : K') (q : Λ') \| copy (q : Λ') \| push (k : K') (s : Option Γ' → Option Γ') (q : Λ') \| read (f : Option Γ' → Λ') \| succ (q : Λ') \| pred (q₁ q₂ : Λ') \| ret (k : Cont') compile_inductive% Code compile_inductive% Cont' compile_inductive% K' compile_inductive% Λ' instance Λ'.instInhabited : Inhabited Λ' := ⟨Λ'.ret Cont'.halt⟩ instance Λ'.instDecidableEq : DecidableEq Λ' := fun a b => by induction a generalizing b <;> cases b <;> first \| apply Decidable.isFalse; rintro ⟨⟨⟩⟩; done \| exact decidable_of_iff' _ (by simp [funext_iff]; rfl) /-- The type of TM2 statements used by this machine. -/ def Stmt' := TM2.Stmt (fun _ : K' => Γ') Λ' (Option Γ') deriving Inhabited /-- The type of TM2 configurations used by this machine. -/ def Cfg' := TM2.Cfg (fun _ : K' => Γ') Λ' (Option Γ') deriving Inhabited open TM2.Stmt /-- A predicate that detects the end of a natural number, either `Γ'.cons` or `Γ'.consₗ` (or implicitly the end of the list), for use in predicate-taking functions like `move` and `clear`. -/ @[simp] def natEnd : Γ' → Bool \| Γ'.consₗ => true \| Γ'.cons => true \| _ => false attribute [nolint simpNF] natEnd.eq_3 /-- Pop a value from the stack and place the result in local store. -/ @[simp] def pop' (k : K') : Stmt' → Stmt' := pop k fun _ v => v /-- Peek a value from the stack and place the result in local store. -/ @[simp] def peek' (k : K') : Stmt' → Stmt' := peek k fun _ v => v /-- Push the value in the local store to the given stack. -/ @[simp] def push' (k : K') : Stmt' → Stmt' := push k fun x => x.iget /-- Move everything from the `rev` stack to the `main` stack (reversed). -/ def unrev := Λ'.move (fun _ => false) rev main /-- Move elements from `k₁` to `k₂` while `p` holds, with the last element being left on `k₁`. -/ def moveExcl (p k₁ k₂ q) := Λ'.move p k₁ k₂ <\| Λ'.push k₁ id q /-- Move elements from `k₁` to `k₂` without reversion, by performing a double move via the `rev` stack. -/ def move₂ (p k₁ k₂ q) := moveExcl p k₁ rev <\| Λ'.move (fun _ => false) rev k₂ q /-- Assuming `trList v` is on the front of stack `k`, remove it, and push `v.headI` onto `main`. See the section documentation. -/ def head (k : K') (q : Λ') : Λ' := Λ'.move natEnd k rev <\| (Λ'.push rev fun _ => some Γ'.cons) <\| Λ'.read fun s => (if s = some Γ'.consₗ then id else Λ'.clear (fun x => x = Γ'.consₗ) k) <\| unrev q /-- The program that evaluates code `c` with continuation `k`. This expects an initial state where `trList v` is on `main`, `trContStack k` is on `stack`, and `aux` and `rev` are empty. See the section documentation for details. -/ @[simp] def trNormal : Code → Cont' → Λ' \| Code.zero', k => (Λ'.push main fun _ => some Γ'.cons) <\| Λ'.ret k \| Code.succ, k => head main <\| Λ'.succ <\| Λ'.ret k \| Code.tail, k => Λ'.clear natEnd main <\| Λ'.ret k \| Code.cons f fs, k => (Λ'.push stack fun _ => some Γ'.consₗ) <\| Λ'.move (fun _ => false) main rev <\| Λ'.copy <\| trNormal f (Cont'.cons₁ fs k) \| Code.comp f g, k => trNormal g (Cont'.comp f k) \| Code.case f g, k => Λ'.pred (trNormal f k) (trNormal g k) \| Code.fix f, k => trNormal f (Cont'.fix f k) /-- The main program. See the section documentation for details. -/ def tr : Λ' → Stmt' \| Λ'.move p k₁ k₂ q => pop' k₁ <\| branch (fun s => s.elim true p) (goto fun _ => q) (push' k₂ <\| goto fun _ => Λ'.move p k₁ k₂ q) \| Λ'.push k f q => branch (fun s => (f s).isSome) ((push k fun s => (f s).iget) <\| goto fun _ => q) (goto fun _ => q) \| Λ'.read q => goto q \| Λ'.clear p k q => pop' k <\| branch (fun s => s.elim true p) (goto fun _ => q) (goto fun _ => Λ'.clear p k q) \| Λ'.copy q => pop' rev <\| branch Option.isSome (push' main <\| push' stack <\| goto fun _ => Λ'.copy q) (goto fun _ => q) \| Λ'.succ q => pop' main <\| branch (fun s => s = some Γ'.bit1) ((push rev fun _ => Γ'.bit0) <\| goto fun _ => Λ'.succ q) <\| branch (fun s => s = some Γ'.cons) ((push main fun _ => Γ'.cons) <\| (push main fun _ => Γ'.bit1) <\| goto fun _ => unrev q) ((push main fun _ => Γ'.bit1) <\| goto fun _ => unrev q) \| Λ'.pred q₁ q₂ => pop' main <\| branch (fun s => s = some Γ'.bit0) ((push rev fun _ => Γ'.bit1) <\| goto fun _ => Λ'.pred q₁ q₂) <\| branch (fun s => natEnd s.iget) (goto fun _ => q₁) (peek' main <\| branch (fun s => natEnd s.iget) (goto fun _ => unrev q₂) ((push rev fun _ => Γ'.bit0) <\| goto fun _ => unrev q₂)) \| Λ'.ret (Cont'.cons₁ fs k) => goto fun _ => move₂ (fun _ => false) main aux <\| move₂ (fun s => s = Γ'.consₗ) stack main <\| move₂ (fun _ => false) aux stack <\| trNormal fs (Cont'.cons₂ k) \| Λ'.ret (Cont'.cons₂ k) => goto fun _ => head stack <\| Λ'.ret k \| Λ'.ret (Cont'.comp f k) => goto fun _ => trNormal f k \| Λ'.ret (Cont'.fix f k) => pop' main <\| goto fun s => cond (natEnd s.iget) (Λ'.ret k) <\| Λ'.clear natEnd main <\| trNormal f (Cont'.fix f k) \| Λ'.ret Cont'.halt => (load fun _ => none) <\| halt @[simp] theorem tr_move (p k₁ k₂ q) : tr (Λ'.move p k₁ k₂ q) = pop' k₁ (branch (fun s => s.elim true p) (goto fun _ => q) (push' k₂ <\| goto fun _ => Λ'.move p k₁ k₂ q)) := rfl @[simp] theorem tr_push (k f q) : tr (Λ'.push k f q) = branch (fun s => (f s).isSome) ((push k fun s => (f s).iget) <\| goto fun _ => q) (goto fun _ => q) := rfl @[simp] theorem tr_read (q) : tr (Λ'.read q) = goto q := rfl @[simp] theorem tr_clear (p k q) : tr (Λ'.clear p k q) = pop' k (branch (fun s => s.elim true p) (goto fun _ => q) (goto fun _ => Λ'.clear p k q)) := rfl @[simp] theorem tr_copy (q) : tr (Λ'.copy q) = pop' rev (branch Option.isSome (push' main <\| push' stack <\| goto fun _ => Λ'.copy q) (goto fun _ => q)) := rfl @[simp] theorem tr_succ (q) : tr (Λ'.succ q) = pop' main (branch (fun s => s = some Γ'.bit1) ((push rev fun _ => Γ'.bit0) <\| goto fun _ => Λ'.succ q) <\| branch (fun s => s = some Γ'.cons) ((push main fun _ => Γ'.cons) <\| (push main fun _ => Γ'.bit1) <\| goto fun _ => unrev q) ((push main fun _ => Γ'.bit1) <\| goto fun _ => unrev q)) := rfl @[simp] theorem tr_pred (q₁ q₂) : tr (Λ'.pred q₁ q₂) = pop' main (branch (fun s => s = some Γ'.bit0) ((push rev fun _ => Γ'.bit1) <\| goto fun _ => Λ'.pred q₁ q₂) <\| branch (fun s => natEnd s.iget) (goto fun _ => q₁) (peek' main <\| branch (fun s => natEnd s.iget) (goto fun _ => unrev q₂) ((push rev fun _ => Γ'.bit0) <\| goto fun _ => unrev q₂))) := rfl @[simp] theorem tr_ret_cons₁ (fs k) : tr (Λ'.ret (Cont'.cons₁ fs k)) = goto fun _ => move₂ (fun _ => false) main aux <\| move₂ (fun s => s = Γ'.consₗ) stack main <\| move₂ (fun _ => false) aux stack <\| trNormal fs (Cont'.cons₂ k) := rfl @[simp] theorem tr_ret_cons₂ (k) : tr (Λ'.ret (Cont'.cons₂ k)) = goto fun _ => head stack <\| Λ'.ret k := rfl @[simp] theorem tr_ret_comp (f k) : tr (Λ'.ret (Cont'.comp f k)) = goto fun _ => trNormal f k := rfl @[simp] theorem tr_ret_fix (f k) : tr (Λ'.ret (Cont'.fix f k)) = pop' main (goto fun s => cond (natEnd s.iget) (Λ'.ret k) <\| Λ'.clear natEnd main <\| trNormal f (Cont'.fix f k)) := rfl @[simp] theorem tr_ret_halt : tr (Λ'.ret Cont'.halt) = (load fun _ => none) halt := rfl /-- Translating a `Cont` continuation to a `Cont'` continuation simply entails dropping all the data. This data is instead encoded in `trContStack` in the configuration. -/ def trCont : Cont → Cont' \| Cont.halt => Cont'.halt \| Cont.cons₁ c _ k => Cont'.cons₁ c (trCont k) \| Cont.cons₂ _ k => Cont'.cons₂ (trCont k) \| Cont.comp c k => Cont'.comp c (trCont k) \| Cont.fix c k => Cont'.fix c (trCont k) /-- We use `PosNum` to define the translation of binary natural numbers. A natural number is represented as a little-endian list of `bit0` and `bit1` elements: 1 = [bit1] 2 = [bit0, bit1] 3 = [bit1, bit1] 4 = [bit0, bit0, bit1] In particular, this representation guarantees no trailing `bit0`'s at the end of the list. -/ def trPosNum : PosNum → List Γ' \| PosNum.one => [Γ'.bit1] \| PosNum.bit0 n => Γ'.bit0 :: trPosNum n \| PosNum.bit1 n => Γ'.bit1 :: trPosNum n /-- We use `Num` to define the translation of binary natural numbers. Positive numbers are translated using `trPosNum`, and `trNum 0 = []`. So there are never any trailing `bit0`'s in a translated `Num`. 0 = [] 1 = [bit1] 2 = [bit0, bit1] 3 = [bit1, bit1] 4 = [bit0, bit0, bit1] -/ def trNum : Num → List Γ' \| Num.zero => [] \| Num.pos n => trPosNum n /-- Because we use binary encoding, we define `trNat` in terms of `trNum`, using `Num`, which are binary natural numbers. (We could also use `Nat.binaryRecOn`, but `Num` and `PosNum` make for easy inductions.) -/ def trNat (n : ℕ) : List Γ' := trNum n @[simp] theorem trNat_zero : trNat 0 = [] := by rw [trNat, Nat.cast_zero]; rfl theorem trNat_default : trNat default = [] := trNat_zero /-- Lists are translated with a `cons` after each encoded number. For example: [] = [] [0] = [cons] [1] = [bit1, cons] [6, 0] = [bit0, bit1, bit1, cons, cons] -/ @[simp] def trList : List ℕ → List Γ' \| [] => [] \| n::ns => trNat n ++ Γ'.cons :: trList ns /-- Lists of lists are translated with a `consₗ` after each encoded list. For example: [] = [] [[]] = [consₗ] [[], []] = [consₗ, consₗ] [[0]] = [cons, consₗ] [[1, 2], [0]] = [bit1, cons, bit0, bit1, cons, consₗ, cons, consₗ] -/ @[simp] def trLList : List (List ℕ) → List Γ' \| [] => [] \| l::ls => trList l ++ Γ'.consₗ :: trLList ls /-- The data part of a continuation is a list of lists, which is encoded on the `stack` stack using `trLList`. -/ @[simp] def contStack : Cont → List (List ℕ) \| Cont.halt => [] \| Cont.cons₁ _ ns k => ns :: contStack k \| Cont.cons₂ ns k => ns :: contStack k \| Cont.comp _ k => contStack k \| Cont.fix _ k => contStack k /-- The data part of a continuation is a list of lists, which is encoded on the `stack` stack using `trLList`. -/ def trContStack (k : Cont) := trLList (contStack k) /-- This is the nondependent eliminator for `K'`, but we use it specifically here in order to represent the stack data as four lists rather than as a function `K' → List Γ'`, because this makes rewrites easier. The theorems `K'.elim_update_main` et. al. show how such a function is updated after an `update` to one of the components. -/ def K'.elim (a b c d : List Γ') : K' → List Γ' \| K'.main => a \| K'.rev => b \| K'.aux => c \| K'.stack => d -- The equation lemma of `elim` simplifies to `match` structures. theorem K'.elim_main (a b c d) : K'.elim a b c d K'.main = a := rfl theorem K'.elim_rev (a b c d) : K'.elim a b c d K'.rev = b := rfl theorem K'.elim_aux (a b c d) : K'.elim a b c d K'.aux = c := rfl theorem K'.elim_stack (a b c d) : K'.elim a b c d K'.stack = d := rfl attribute [simp] K'.elim @[simp] theorem K'.elim_update_main {a b c d a'} : update (K'.elim a b c d) main a' = K'.elim a' b c d := by funext x; cases x <;> rfl @[simp] theorem K'.elim_update_rev {a b c d b'} : update (K'.elim a b c d) rev b' = K'.elim a b' c d := by funext x; cases x <;> rfl @[simp] theorem K'.elim_update_aux {a b c d c'} : update (K'.elim a b c d) aux c' = K'.elim a b c' d := by funext x; cases x <;> rfl @[simp] theorem K'.elim_update_stack {a b c d d'} : update (K'.elim a b c d) stack d' = K'.elim a b c d' := by funext x; cases x <;> rfl /-- The halting state corresponding to a `List ℕ` output value. -/ def halt (v : List ℕ) : Cfg' := ⟨none, none, K'.elim (trList v) [] [] []⟩ /-- The `Cfg` states map to `Cfg'` states almost one to one, except that in normal operation the local store contains an arbitrary garbage value. To make the final theorem cleaner we explicitly clear it in the halt state so that there is exactly one configuration corresponding to output `v`. -/ def TrCfg : Cfg → Cfg' → Prop \| Cfg.ret k v, c' => ∃ s, c' = ⟨some (Λ'.ret (trCont k)), s, K'.elim (trList v) [] [] (trContStack k)⟩ \| Cfg.halt v, c' => c' = halt v /-- This could be a general list definition, but it is also somewhat specialized to this application. `splitAtPred p L` will search `L` for the first element satisfying `p`. If it is found, say `L = l₁ ++ a :: l₂` where `a` satisfies `p` but `l₁` does not, then it returns `(l₁, some a, l₂)`. Otherwise, if there is no such element, it returns `(L, none, [])`. -/ def splitAtPred {α} (p : α → Bool) : List α → List α × Option α × List α \| [] => ([], none, []) \| a :: as => cond (p a) ([], some a, as) <\| let ⟨l₁, o, l₂⟩ := splitAtPred p as ⟨a::l₁, o, l₂⟩ theorem splitAtPred_eq {α} (p : α → Bool) : ∀ L l₁ o l₂, (∀ x ∈ l₁, p x = false) → Option.elim' (L = l₁ ∧ l₂ = []) (fun a => p a = true ∧ L = l₁ ++ a::l₂) o → splitAtPred p L = (l₁, o, l₂) \| [], _, none, _, _, ⟨rfl, rfl⟩ => rfl \| [], l₁, some o, l₂, _, ⟨_, h₃⟩ => by simp at h₃ \| a :: L, l₁, o, l₂, h₁, h₂ => by rw [splitAtPred] have IH := splitAtPred_eq p L rcases o with - \| o · rcases l₁ with - \| ⟨a', l₁⟩ <;> rcases h₂ with ⟨⟨⟩, rfl⟩ rw [h₁ a (List.Mem.head _), cond, IH L none [] _ ⟨rfl, rfl⟩] exact fun x h => h₁ x (List.Mem.tail _ h) · rcases l₁ with - \| ⟨a', l₁⟩ <;> rcases h₂ with ⟨h₂, ⟨⟩⟩ · rw [h₂, cond] rw [h₁ a (List.Mem.head _), cond, IH l₁ (some o) l₂ _ ⟨h₂, _⟩] <;> try rfl exact fun x h => h₁ x (List.Mem.tail _ h) theorem splitAtPred_false {α} (L : List α) : splitAtPred (fun _ => false) L = (L, none, []) := splitAtPred_eq _ _ _ _ _ (fun _ _ => rfl) ⟨rfl, rfl⟩ theorem move_ok {p k₁ k₂ q s L₁ o L₂} {S : K' → List Γ'} (h₁ : k₁ ≠ k₂) (e : splitAtPred p (S k₁) = (L₁, o, L₂)) : Reaches₁ (TM2.step tr) ⟨some (Λ'.move p k₁ k₂ q), s, S⟩ ⟨some q, o, update (update S k₁ L₂) k₂ (L₁.reverseAux (S k₂))⟩ := by induction' L₁ with a L₁ IH generalizing S s · rw [(_ : [].reverseAux _ = _), Function.update_eq_self] swap · rw [Function.update_of_ne h₁.symm, List.reverseAux_nil] refine TransGen.head' rfl ?_ rw [tr]; simp only [pop', TM2.stepAux] revert e; rcases S k₁ with - \| ⟨a, Sk⟩ <;> intro e · cases e rfl simp only [splitAtPred, Option.elim, List.head?, List.tail_cons, Option.iget_some] at e ⊢ revert e; cases p a <;> intro e <;> simp only [cond_false, cond_true, Prod.mk.injEq, true_and, false_and, reduceCtorEq] at e ⊢ simp only [e] rfl · refine TransGen.head rfl ?_ rw [tr]; simp only [pop', Option.elim, TM2.stepAux, push'] rcases e₁ : S k₁ with - \| ⟨a', Sk⟩ <;> rw [e₁, splitAtPred] at e · cases e cases e₂ : p a' <;> simp only [e₂, cond] at e swap · cases e rcases e₃ : splitAtPred p Sk with ⟨_, _, _⟩ rw [e₃] at e cases e simp only [List.head?_cons, e₂, List.tail_cons, ne_eq, cond_false] convert @IH _ (update (update S k₁ Sk) k₂ (a :: S k₂)) _ using 2 <;> simp [Function.update_of_ne, h₁, h₁.symm, e₃, List.reverseAux] simp [Function.update_comm h₁.symm] theorem unrev_ok {q s} {S : K' → List Γ'} : Reaches₁ (TM2.step tr) ⟨some (unrev q), s, S⟩ ⟨some q, none, update (update S rev []) main (List.reverseAux (S rev) (S main))⟩ := move_ok (by decide) <\| splitAtPred_false _ theorem move₂_ok {p k₁ k₂ q s L₁ o L₂} {S : K' → List Γ'} (h₁ : k₁ ≠ rev ∧ k₂ ≠ rev ∧ k₁ ≠ k₂) (h₂ : S rev = []) (e : splitAtPred p (S k₁) = (L₁, o, L₂)) : Reaches₁ (TM2.step tr) ⟨some (move₂ p k₁ k₂ q), s, S⟩ ⟨some q, none, update (update S k₁ (o.elim id List.cons L₂)) k₂ (L₁ ++ S k₂)⟩ := by refine (move_ok h₁.1 e).trans (TransGen.head rfl ?_) simp only [TM2.step, Option.mem_def, TM2.stepAux, id_eq, ne_eq, Option.elim] cases o <;> simp only [Option.elim] <;> rw [tr] <;> simp only [id, TM2.stepAux, Option.isSome, cond_true, cond_false] · convert move_ok h₁.2.1.symm (splitAtPred_false _) using 2 simp only [Function.update_comm h₁.1, Function.update_idem] rw [show update S rev [] = S by rw [← h₂, Function.update_eq_self]] simp only [Function.update_of_ne h₁.2.2.symm, Function.update_of_ne h₁.2.1, Function.update_of_ne h₁.1.symm, List.reverseAux_eq, h₂, Function.update_self, List.append_nil, List.reverse_reverse] · convert move_ok h₁.2.1.symm (splitAtPred_false _) using 2 simp only [h₂, Function.update_comm h₁.1, List.reverseAux_eq, Function.update_self, List.append_nil, Function.update_idem] rw [show update S rev [] = S by rw [← h₂, Function.update_eq_self]] simp only [Function.update_of_ne h₁.1.symm, Function.update_of_ne h₁.2.2.symm, Function.update_of_ne h₁.2.1, Function.update_self, List.reverse_reverse] theorem clear_ok {p k q s L₁ o L₂} {S : K' → List Γ'} (e : splitAtPred p (S k) = (L₁, o, L₂)) : Reaches₁ (TM2.step tr) ⟨some (Λ'.clear p k q), s, S⟩ ⟨some q, o, update S k L₂⟩ := by induction' L₁ with a L₁ IH generalizing S s · refine TransGen.head' rfl ?_ rw [tr]; simp only [pop', TM2.step, Option.mem_def, TM2.stepAux, Option.elim] revert e; rcases S k with - \| ⟨a, Sk⟩ <;> intro e · cases e rfl simp only [splitAtPred, Option.elim, List.head?, List.tail_cons] at e ⊢ revert e; cases p a <;> intro e <;> simp only [cond_false, cond_true, Prod.mk.injEq, true_and, false_and, reduceCtorEq] at e ⊢ rcases e with ⟨e₁, e₂⟩ rw [e₁, e₂] · refine TransGen.head rfl ?_ rw [tr]; simp only [pop', TM2.step, Option.mem_def, TM2.stepAux, Option.elim] rcases e₁ : S k with - \| ⟨a', Sk⟩ <;> rw [e₁, splitAtPred] at e · cases e cases e₂ : p a' <;> simp only [e₂, cond] at e swap · cases e rcases e₃ : splitAtPred p Sk with ⟨_, _, _⟩ rw [e₃] at e cases e simp only [List.head?_cons, e₂, List.tail_cons, cond_false] convert @IH _ (update S k Sk) _ using 2 <;> simp [e₃] theorem copy_ok (q s a b c d) : Reaches₁ (TM2.step tr) ⟨some (Λ'.copy q), s, K'.elim a b c d⟩ ⟨some q, none, K'.elim (List.reverseAux b a) [] c (List.reverseAux b d)⟩ := by induction' b with x b IH generalizing a d s · refine TransGen.single ?_ simp refine TransGen.head rfl ?_ rw [tr] simp only [TM2.step, Option.mem_def, TM2.stepAux, elim_rev, List.head?_cons, Option.isSome_some, List.tail_cons, elim_update_rev, ne_eq, Function.update_of_ne, elim_main, elim_update_main, elim_stack, elim_update_stack, cond_true, List.reverseAux_cons, pop', push'] exact IH _ _ _ theorem trPosNum_natEnd : ∀ (n), ∀ x ∈ trPosNum n, natEnd x = false \| PosNum.one, _, List.Mem.head _ => rfl \| PosNum.bit0 _, _, List.Mem.head _ => rfl \| PosNum.bit0 n, _, List.Mem.tail _ h => trPosNum_natEnd n _ h \| PosNum.bit1 _, _, List.Mem.head _ => rfl \| PosNum.bit1 n, _, List.Mem.tail _ h => trPosNum_natEnd n _ h theorem trNum_natEnd : ∀ (n), ∀ x ∈ trNum n, natEnd x = false \| Num.pos n, x, h => trPosNum_natEnd n x h theorem trNat_natEnd (n) : ∀ x ∈ trNat n, natEnd x = false := trNum_natEnd _ theorem trList_ne_consₗ : ∀ (l), ∀ x ∈ trList l, x ≠ Γ'.consₗ \| a :: l, x, h => by simp only [trList, List.mem_append, List.mem_cons] at h obtain h \| rfl \| h := h · rintro rfl cases trNat_natEnd _ _ h · rintro ⟨⟩ · exact trList_ne_consₗ l _ h theorem head_main_ok {q s L} {c d : List Γ'} : Reaches₁ (TM2.step tr) ⟨some (head main q), s, K'.elim (trList L) [] c d⟩ ⟨some q, none, K'.elim (trList [L.headI]) [] c d⟩ := by let o : Option Γ' := List.casesOn L none fun _ _ => some Γ'.cons refine (move_ok (by decide) (splitAtPred_eq _ _ (trNat L.headI) o (trList L.tail) (trNat_natEnd _) ?_)).trans (TransGen.head rfl (TransGen.head rfl ?_)) · cases L <;> simp [o] rw [tr] simp only [TM2.step, Option.mem_def, TM2.stepAux, elim_update_main, elim_rev, elim_update_rev, Function.update_self, trList] rw [if_neg (show o ≠ some Γ'.consₗ by cases L <;> simp [o])] refine (clear_ok (splitAtPred_eq _ _ _ none [] ?_ ⟨rfl, rfl⟩)).trans ?_ · exact fun x h => Bool.decide_false (trList_ne_consₗ _ _ h) convert unrev_ok using 2; simp [List.reverseAux_eq] theorem head_stack_ok {q s L₁ L₂ L₃} : Reaches₁ (TM2.step tr) ⟨some (head stack q), s, K'.elim (trList L₁) [] [] (trList L₂ ++ Γ'.consₗ :: L₃)⟩ ⟨some q, none, K'.elim (trList (L₂.headI :: L₁)) [] [] L₃⟩ := by rcases L₂ with - \| ⟨a, L₂⟩ · refine TransGen.trans (move_ok (by decide) (splitAtPred_eq _ _ [] (some Γ'.consₗ) L₃ (by rintro _ ⟨⟩) ⟨rfl, rfl⟩)) (TransGen.head rfl (TransGen.head rfl ?_)) rw [tr] simp only [TM2.step, Option.mem_def, TM2.stepAux, ite_true, id_eq, trList, List.nil_append, elim_update_stack, elim_rev, List.reverseAux_nil, elim_update_rev, Function.update_self, List.headI_nil, trNat_default] convert unrev_ok using 2 simp · refine TransGen.trans (move_ok (by decide) (splitAtPred_eq _ _ (trNat a) (some Γ'.cons) (trList L₂ ++ Γ'.consₗ :: L₃) (trNat_natEnd _) ⟨rfl, by simp⟩)) (TransGen.head rfl (TransGen.head rfl ?_)) simp only [TM2.step, Option.mem_def, TM2.stepAux, ite_false, trList, List.append_assoc, List.cons_append, elim_update_stack, elim_rev, elim_update_rev, Function.update_self, List.headI_cons] refine TransGen.trans (clear_ok (splitAtPred_eq _ _ (trList L₂) (some Γ'.consₗ) L₃ (fun x h => Bool.decide_false (trList_ne_consₗ _ _ h)) ⟨rfl, by simp⟩)) ?_ convert unrev_ok using 2 simp [List.reverseAux_eq] theorem succ_ok {q s n} {c d : List Γ'} : Reaches₁ (TM2.step tr) ⟨some (Λ'.succ q), s, K'.elim (trList [n]) [] c d⟩ ⟨some q, none, K'.elim (trList [n.succ]) [] c d⟩ := by simp only [TM2.step, trList, trNat.eq_1, Nat.cast_succ, Num.add_one] rcases (n : Num) with - \| a · refine TransGen.head rfl ?_ simp only [Option.mem_def, TM2.stepAux, elim_main, decide_false, elim_update_main, ne_eq, Function.update_of_ne, elim_rev, elim_update_rev, decide_true, Function.update_self, cond_true, cond_false] convert unrev_ok using 1 simp only [elim_update_rev, elim_rev, elim_main, List.reverseAux_nil, elim_update_main] rfl simp only [trNum, Num.succ, Num.succ'] suffices ∀ l₁, ∃ l₁' l₂' s', List.reverseAux l₁ (trPosNum a.succ) = List.reverseAux l₁' l₂' ∧ Reaches₁ (TM2.step tr) ⟨some q.succ, s, K'.elim (trPosNum a ++ [Γ'.cons]) l₁ c d⟩ ⟨some (unrev q), s', K'.elim (l₂' ++ [Γ'.cons]) l₁' c d⟩ by obtain ⟨l₁', l₂', s', e, h⟩ := this [] simp? [List.reverseAux] at e says simp only [List.reverseAux, List.reverseAux_eq] at e refine h.trans ?_ convert unrev_ok using 2 simp [e, List.reverseAux_eq] induction' a with m IH m _ generalizing s <;> intro l₁ · refine ⟨Γ'.bit0 :: l₁, [Γ'.bit1], some Γ'.cons, rfl, TransGen.head rfl (TransGen.single ?_)⟩ simp [trPosNum] · obtain ⟨l₁', l₂', s', e, h⟩ := IH (Γ'.bit0 :: l₁) refine ⟨l₁', l₂', s', e, TransGen.head ?_ h⟩ simp [PosNum.succ, trPosNum] rfl · refine ⟨l₁, _, some Γ'.bit0, rfl, TransGen.single ?_⟩ simp only [TM2.step]; rw [tr] simp only [TM2.stepAux, pop', elim_main, elim_update_main, ne_eq, Function.update_of_ne, elim_rev, elim_update_rev, Function.update_self, Option.mem_def, Option.some.injEq] rfl theorem pred_ok (q₁ q₂ s v) (c d : List Γ') : ∃ s', Reaches₁ (TM2.step tr) ⟨some (Λ'.pred q₁ q₂), s, K'.elim (trList v) [] c d⟩ (v.headI.rec ⟨some q₁, s', K'.elim (trList v.tail) [] c d⟩ fun n _ => ⟨some q₂, s', K'.elim (trList (n::v.tail)) [] c d⟩) := by rcases v with (_ \| ⟨_ \| n, v⟩) · refine ⟨none, TransGen.single ?_⟩ simp · refine ⟨some Γ'.cons, TransGen.single ?_⟩ simp refine ⟨none, ?_⟩ simp only [TM2.step, trList, trNat.eq_1, trNum, Nat.cast_succ, Num.add_one, Num.succ, List.tail_cons, List.headI_cons] rcases (n : Num) with - \| a · simp only [trPosNum, Num.succ', List.singleton_append, List.nil_append] refine TransGen.head rfl ?_ rw [tr]; simp only [pop', TM2.stepAux, cond_false] convert unrev_ok using 2 simp simp only [Num.succ'] suffices ∀ l₁, ∃ l₁' l₂' s', List.reverseAux l₁ (trPosNum a) = List.reverseAux l₁' l₂' ∧ Reaches₁ (TM2.step tr) ⟨some (q₁.pred q₂), s, K'.elim (trPosNum a.succ ++ Γ'.cons :: trList v) l₁ c d⟩ ⟨some (unrev q₂), s', K'.elim (l₂' ++ Γ'.cons :: trList v) l₁' c d⟩ by obtain ⟨l₁', l₂', s', e, h⟩ := this [] simp only [List.reverseAux] at e refine h.trans ?_ convert unrev_ok using 2 simp [e, List.reverseAux_eq] induction' a with m IH m IH generalizing s <;> intro l₁ · refine ⟨Γ'.bit1::l₁, [], some Γ'.cons, rfl, TransGen.head rfl (TransGen.single ?_)⟩ simp [trPosNum, show PosNum.one.succ = PosNum.one.bit0 from rfl] · obtain ⟨l₁', l₂', s', e, h⟩ := IH (some Γ'.bit0) (Γ'.bit1 :: l₁) refine ⟨l₁', l₂', s', e, TransGen.head ?_ h⟩ simp rfl · obtain ⟨a, l, e, h⟩ : ∃ a l, (trPosNum m = a::l) ∧ natEnd a = false := by cases m <;> refine ⟨_, _, rfl, rfl⟩ refine ⟨Γ'.bit0 :: l₁, _, some a, rfl, TransGen.single ?_⟩ simp [trPosNum, PosNum.succ, e, h, show some Γ'.bit1 ≠ some Γ'.bit0 by decide, Option.iget, -natEnd] rfl theorem trNormal_respects (c k v s) : ∃ b₂, TrCfg (stepNormal c k v) b₂ ∧ Reaches₁ (TM2.step tr) ⟨some (trNormal c (trCont k)), s, K'.elim (trList v) [] [] (trContStack k)⟩ b₂ := by induction c generalizing k v s with \| zero' => refine ⟨_, ⟨s, rfl⟩, TransGen.single ?_⟩; simp \| succ => refine ⟨_, ⟨none, rfl⟩, head_main_ok.trans succ_ok⟩ \| tail => let o : Option Γ' := List.casesOn v none fun _ _ => some Γ'.cons refine ⟨_, ⟨o, rfl⟩, ?_⟩; convert clear_ok _ using 2 · simp; rfl swap refine splitAtPred_eq _ _ (trNat v.headI) _ _ (trNat_natEnd _) ?_ cases v <;> simp [o] \| cons f fs IHf _ => obtain ⟨c, h₁, h₂⟩ := IHf (Cont.cons₁ fs v k) v none refine ⟨c, h₁, TransGen.head rfl <\| (move_ok (by decide) (splitAtPred_false _)).trans ?_⟩ simp only [TM2.step, Option.mem_def, elim_stack, elim_update_stack, elim_update_main, ne_eq, Function.update_of_ne, elim_main, elim_rev, elim_update_rev] refine (copy_ok _ none [] (trList v).reverse _ _).trans ?_ convert h₂ using 2 simp [List.reverseAux_eq, trContStack] \| comp f _ _ IHg => exact IHg (Cont.comp f k) v s \| case f g IHf IHg => rw [stepNormal] simp only obtain ⟨s', h⟩ := pred_ok _ _ s v _ _ revert h; rcases v.headI with - \| n <;> intro h · obtain ⟨c, h₁, h₂⟩ := IHf k _ s' exact ⟨_, h₁, h.trans h₂⟩ · obtain ⟨c, h₁, h₂⟩ := IHg k _ s' exact ⟨_, h₁, h.trans h₂⟩ \| fix f IH => apply IH theorem tr_ret_respects (k v s) : ∃ b₂, TrCfg (stepRet k v) b₂ ∧ Reaches₁ (TM2.step tr) ⟨some (Λ'.ret (trCont k)), s, K'.elim (trList v) [] [] (trContStack k)⟩ b₂ := by induction k generalizing v s with \| halt => exact ⟨_, rfl, TransGen.single rfl⟩ \| cons₁ fs as k _ => obtain ⟨s', h₁, h₂⟩ := trNormal_respects fs (Cont.cons₂ v k) as none refine ⟨s', h₁, TransGen.head rfl ?_⟩; simp refine (move₂_ok (by decide) ?_ (splitAtPred_false _)).trans ?_; · rfl simp only [TM2.step, Option.mem_def, Option.elim, id_eq, elim_update_main, elim_main, elim_aux, List.append_nil, elim_update_aux] refine (move₂_ok (L₁ := ?_) (o := ?_) (L₂ := ?_) (by decide) rfl ?_).trans ?_ pick_goal 4 · exact splitAtPred_eq _ _ _ (some Γ'.consₗ) _ (fun x h => Bool.decide_false (trList_ne_consₗ _ _ h)) ⟨rfl, rfl⟩ refine (move₂_ok (by decide) ?_ (splitAtPred_false _)).trans ?_; · rfl simp only [TM2.step, Option.mem_def, Option.elim, elim_update_stack, elim_main, List.append_nil, elim_update_main, id_eq, elim_update_aux, ne_eq, Function.update_of_ne, elim_aux, elim_stack] exact h₂ \| cons₂ ns k IH => obtain ⟨c, h₁, h₂⟩ := IH (ns.headI :: v) none exact ⟨c, h₁, TransGen.head rfl <\| head_stack_ok.trans h₂⟩ \| comp f k _ => obtain ⟨s', h₁, h₂⟩ := trNormal_respects f k v s exact ⟨_, h₁, TransGen.head rfl h₂⟩ \| fix f k IH => rw [stepRet] have : if v.headI = 0 then natEnd (trList v).head?.iget = true ∧ (trList v).tail = trList v.tail else natEnd (trList v).head?.iget = false ∧ (trList v).tail = (trNat v.headI).tail ++ Γ'.cons :: trList v.tail := by obtain - \| n := v · exact ⟨rfl, rfl⟩ rcases n with - \| n · simp rw [trList, List.headI, trNat, Nat.cast_succ, Num.add_one, Num.succ, List.tail] cases (n : Num).succ' <;> exact ⟨rfl, rfl⟩ by_cases h : v.headI = 0 <;> simp only [h, ite_true, ite_false] at this ⊢ · obtain ⟨c, h₁, h₂⟩ := IH v.tail (trList v).head? refine ⟨c, h₁, TransGen.head rfl ?_⟩ rw [trCont, tr]; simp only [pop', TM2.stepAux, elim_main, this, elim_update_main] exact h₂ · obtain ⟨s', h₁, h₂⟩ := trNormal_respects f (Cont.fix f k) v.tail (some Γ'.cons) refine ⟨_, h₁, TransGen.head rfl <\| TransGen.trans ?_ h₂⟩ rw [trCont, tr]; simp only [pop', TM2.stepAux, elim_main, this.1] convert clear_ok (splitAtPred_eq _ _ (trNat v.headI).tail (some Γ'.cons) _ _ _) using 2 · simp convert rfl · exact fun x h => trNat_natEnd _ _ (List.tail_subset _ h) · exact ⟨rfl, this.2⟩ theorem tr_respects : Respects step (TM2.step tr) TrCfg \| Cfg.ret _ _, _, ⟨_, rfl⟩ => tr_ret_respects _ _ _ \| Cfg.halt _, _, rfl => rfl /-- The initial state, evaluating function `c` on input `v`. -/ def init (c : Code) (v : List ℕ) : Cfg' := ⟨some (trNormal c Cont'.halt), none, K'.elim (trList v) [] [] []⟩ theorem tr_init (c v) : ∃ b, TrCfg (stepNormal c Cont.halt v) b ∧ Reaches₁ (TM2.step tr) (init c v) b := trNormal_respects _ _ _ _ theorem tr_eval (c v) : eval (TM2.step tr) (init c v) = halt <$> Code.eval c v := by obtain ⟨i, h₁, h₂⟩ := tr_init c v refine Part.ext fun x => ?_ rw [reaches_eval h₂.to_reflTransGen]; simp only [Part.map_eq_map, Part.mem_map_iff] refine ⟨fun h => ?_, ?_⟩ · obtain ⟨c, hc₁, hc₂⟩ := tr_eval_rev tr_respects h₁ h simp [stepNormal_eval] at hc₂ obtain ⟨v', hv, rfl⟩ := hc₂ exact ⟨_, hv, hc₁.symm⟩ · rintro ⟨v', hv, rfl⟩ have := Turing.tr_eval (b₁ := Cfg.halt v') tr_respects h₁ simp only [stepNormal_eval, Part.map_eq_map, Part.mem_map_iff, Cfg.halt.injEq, exists_eq_right] at this obtain ⟨_, ⟨⟩, h⟩ := this hv exact h /-- The set of machine states reachable via downward label jumps, discounting jumps via `ret`. -/ def trStmts₁ : Λ' → Finset Λ' \| Q@(Λ'.move _ _ _ q) => insert Q <\| trStmts₁ q \| Q@(Λ'.push _ _ q) => insert Q <\| trStmts₁ q \| Q@(Λ'.read q) => insert Q <\| Finset.univ.biUnion fun s => trStmts₁ (q s) \| Q@(Λ'.clear _ _ q) => insert Q <\| trStmts₁ q \| Q@(Λ'.copy q) => insert Q <\| trStmts₁ q \| Q@(Λ'.succ q) => insert Q <\| insert (unrev q) <\| trStmts₁ q \| Q@(Λ'.pred q₁ q₂) => insert Q <\| trStmts₁ q₁ ∪ insert (unrev q₂) (trStmts₁ q₂) \| Q@(Λ'.ret _) => {Q} theorem trStmts₁_trans {q q'} : q' ∈ trStmts₁ q → trStmts₁ q' ⊆ trStmts₁ q := by induction q with \| move _ _ _ q q_ih => _ \| clear _ _ q q_ih => _ \| copy q q_ih => _ \| push _ _ q q_ih => _ \| read q q_ih => _ \| succ q q_ih => _ \| pred q₁ q₂ q₁_ih q₂_ih => _ \| ret => _ <;> all_goals simp +contextual only [trStmts₁, Finset.mem_insert, Finset.mem_union, or_imp, Finset.mem_singleton, Finset.Subset.refl, imp_true_iff, true_and] repeat exact fun h => Finset.Subset.trans (q_ih h) (Finset.subset_insert _ _) · simp intro s h x h' simp only [Finset.mem_biUnion, Finset.mem_univ, true_and, Finset.mem_insert] exact Or.inr ⟨_, q_ih s h h'⟩ · constructor · rintro rfl apply Finset.subset_insert · intro h x h' simp only [Finset.mem_insert] exact Or.inr (Or.inr <\| q_ih h h') · refine ⟨fun h x h' => ?_, fun _ x h' => ?_, fun h x h' => ?_⟩ <;> simp · exact Or.inr (Or.inr <\| Or.inl <\| q₁_ih h h') · rcases Finset.mem_insert.1 h' with h' \| h' <;> simp [h', unrev] · exact Or.inr (Or.inr <\| Or.inr <\| q₂_ih h h') theorem trStmts₁_self (q) : q ∈ trStmts₁ q := by induction q <;> · first \|apply Finset.mem_singleton_self\|apply Finset.mem_insert_self /-- The (finite!) set of machine states visited during the course of evaluation of `c`, including the state `ret k` but not any states after that (that is, the states visited while evaluating `k`). -/ def codeSupp' : Code → Cont' → Finset Λ' \| c@Code.zero', k => trStmts₁ (trNormal c k) \| c@Code.succ, k => trStmts₁ (trNormal c k) \| c@Code.tail, k => trStmts₁ (trNormal c k) \| c@(Code.cons f fs), k => trStmts₁ (trNormal c k) ∪ (codeSupp' f (Cont'.cons₁ fs k) ∪ (trStmts₁ (move₂ (fun _ => false) main aux <\| move₂ (fun s => s = Γ'.consₗ) stack main <\| move₂ (fun _ => false) aux stack <\| trNormal fs (Cont'.cons₂ k)) ∪ (codeSupp' fs (Cont'.cons₂ k) ∪ trStmts₁ (head stack <\| Λ'.ret k)))) \| c@(Code.comp f g), k => trStmts₁ (trNormal c k) ∪ (codeSupp' g (Cont'.comp f k) ∪ (trStmts₁ (trNormal f k) ∪ codeSupp' f k)) \| c@(Code.case f g), k => trStmts₁ (trNormal c k) ∪ (codeSupp' f k ∪ codeSupp' g k) \| c@(Code.fix f), k => trStmts₁ (trNormal c k) ∪ (codeSupp' f (Cont'.fix f k) ∪ (trStmts₁ (Λ'.clear natEnd main <\| trNormal f (Cont'.fix f k)) ∪ {Λ'.ret k})) @[simp] theorem codeSupp'_self (c k) : trStmts₁ (trNormal c k) ⊆ codeSupp' c k := by cases c <;> first \| rfl \| exact Finset.union_subset_left (fun _ a ↦ a) /-- The (finite!) set of machine states visited during the course of evaluation of a continuation `k`, not including the initial state `ret k`. -/ def contSupp : Cont' → Finset Λ' \| Cont'.cons₁ fs k => trStmts₁ (move₂ (fun _ => false) main aux <\| move₂ (fun s => s = Γ'.consₗ) stack main <\| move₂ (fun _ => false) aux stack <\| trNormal fs (Cont'.cons₂ k)) ∪ (codeSupp' fs (Cont'.cons₂ k) ∪ (trStmts₁ (head stack <\| Λ'.ret k) ∪ contSupp k)) \| Cont'.cons₂ k => trStmts₁ (head stack <\| Λ'.ret k) ∪ contSupp k \| Cont'.comp f k => codeSupp' f k ∪ contSupp k \| Cont'.fix f k => codeSupp' (Code.fix f) k ∪ contSupp k \| Cont'.halt => ∅ /-- The (finite!) set of machine states visited during the course of evaluation of `c` in continuation `k`. This is actually closed under forward simulation (see `tr_supports`), and the existence of this set means that the machine constructed in this section is in fact a proper Turing machine, with a finite set of states. -/ def codeSupp (c : Code) (k : Cont') : Finset Λ' := codeSupp' c k ∪ contSupp k @[simp] theorem codeSupp_self (c k) : trStmts₁ (trNormal c k) ⊆ codeSupp c k := Finset.Subset.trans (codeSupp'_self _ _) (Finset.union_subset_left fun _ a ↦ a) @[simp] theorem codeSupp_zero (k) : codeSupp Code.zero' k = trStmts₁ (trNormal Code.zero' k) ∪ contSupp k := rfl @[simp] theorem codeSupp_succ (k) : codeSupp Code.succ k = trStmts₁ (trNormal Code.succ k) ∪ contSupp k := rfl @[simp] theorem codeSupp_tail (k) : codeSupp Code.tail k = trStmts₁ (trNormal Code.tail k) ∪ contSupp k := rfl @[simp] theorem codeSupp_cons (f fs k) : codeSupp (Code.cons f fs) k = trStmts₁ (trNormal (Code.cons f fs) k) ∪ codeSupp f (Cont'.cons₁ fs k) := by simp [codeSupp, codeSupp', contSupp, Finset.union_assoc] @[simp] theorem codeSupp_comp (f g k) : codeSupp (Code.comp f g) k = trStmts₁ (trNormal (Code.comp f g) k) ∪ codeSupp g (Cont'.comp f k) := by simp only [codeSupp, codeSupp', trNormal, Finset.union_assoc, contSupp] rw [← Finset.union_assoc _ _ (contSupp k), Finset.union_eq_right.2 (codeSupp'_self _ _)] @[simp] theorem codeSupp_case (f g k) : codeSupp (Code.case f g) k = trStmts₁ (trNormal (Code.case f g) k) ∪ (codeSupp f k ∪ codeSupp g k) := by simp [codeSupp, codeSupp', contSupp, Finset.union_assoc, Finset.union_left_comm] @[simp] theorem codeSupp_fix (f k) : codeSupp (Code.fix f) k = trStmts₁ (trNormal (Code.fix f) k) ∪ codeSupp f (Cont'.fix f k) := by simp [codeSupp, codeSupp', contSupp, Finset.union_assoc, Finset.union_left_comm, Finset.union_left_idem] @[simp] theorem contSupp_cons₁ (fs k) : contSupp (Cont'.cons₁ fs k) = trStmts₁ (move₂ (fun _ => false) main aux <\| move₂ (fun s => s = Γ'.consₗ) stack main <\| move₂ (fun _ => false) aux stack <\| trNormal fs (Cont'.cons₂ k)) ∪ codeSupp fs (Cont'.cons₂ k) := by simp [codeSupp, codeSupp', contSupp, Finset.union_assoc] @[simp] theorem contSupp_cons₂ (k) : contSupp (Cont'.cons₂ k) = trStmts₁ (head stack <\| Λ'.ret k) ∪ contSupp k := rfl @[simp] theorem contSupp_comp (f k) : contSupp (Cont'.comp f k) = codeSupp f k := rfl theorem contSupp_fix (f k) : contSupp (Cont'.fix f k) = codeSupp f (Cont'.fix f k) := by simp +contextual [codeSupp, codeSupp', contSupp, Finset.union_assoc, Finset.subset_iff] @[simp] theorem contSupp_halt : contSupp Cont'.halt = ∅ := rfl /-- The statement `Λ'.Supports S q` means that `contSupp k ⊆ S` for any `ret k` reachable from `q`. (This is a technical condition used in the proof that the machine is supported.) -/ def Λ'.Supports (S : Finset Λ') : Λ' → Prop \| Λ'.move _ _ _ q => Λ'.Supports S q \| Λ'.push _ _ q => Λ'.Supports S q \| Λ'.read q => ∀ s, Λ'.Supports S (q s) \| Λ'.clear _ _ q => Λ'.Supports S q \| Λ'.copy q => Λ'.Supports S q \| Λ'.succ q => Λ'.Supports S q \| Λ'.pred q₁ q₂ => Λ'.Supports S q₁ ∧ Λ'.Supports S q₂ \| Λ'.ret k => contSupp k ⊆ S /-- A shorthand for the predicate that we are proving in the main theorems `trStmts₁_supports`, `codeSupp'_supports`, `contSupp_supports`, `codeSupp_supports`. The set `S` is fixed throughout the proof, and denotes the full set of states in the machine, while `K` is a subset that we are currently proving a property about. The predicate asserts that every state in `K` is closed in `S` under forward simulation, i.e. stepping forward through evaluation starting from any state in `K` stays entirely within `S`. -/ def Supports (K S : Finset Λ') := ∀ q ∈ K, TM2.SupportsStmt S (tr q) theorem supports_insert {K S q} : Supports (insert q K) S ↔ TM2.SupportsStmt S (tr q) ∧ Supports K S := by simp [Supports] theorem supports_singleton {S q} : Supports {q} S ↔ TM2.SupportsStmt S (tr q) := by simp [Supports] theorem supports_union {K₁ K₂ S} : Supports (K₁ ∪ K₂) S ↔ Supports K₁ S ∧ Supports K₂ S := by simp [Supports, or_imp, forall_and] theorem supports_biUnion {K : Option Γ' → Finset Λ'} {S} : Supports (Finset.univ.biUnion K) S ↔ ∀ a, Supports (K a) S := by simpa [Supports] using forall_swap theorem head_supports {S k q} (H : (q : Λ').Supports S) : (head k q).Supports S := fun _ => by dsimp only; split_ifs <;> exact H theorem ret_supports {S k} (H₁ : contSupp k ⊆ S) : TM2.SupportsStmt S (tr (Λ'.ret k)) := by have W := fun {q} => trStmts₁_self q cases k with \| halt => trivial \| cons₁ => rw [contSupp_cons₁, Finset.union_subset_iff] at H₁; exact fun _ => H₁.1 W \| cons₂ => rw [contSupp_cons₂, Finset.union_subset_iff] at H₁; exact fun _ => H₁.1 W \| comp => rw [contSupp_comp] at H₁; exact fun _ => H₁ (codeSupp_self _ _ W) \| fix => rw [contSupp_fix] at H₁ have L := @Finset.mem_union_left; have R := @Finset.mem_union_right intro s; dsimp only; cases natEnd s.iget · refine H₁ (R _ <\| L _ <\| R _ <\| R _ <\| L _ W) · exact H₁ (R _ <\| L _ <\| R _ <\| R _ <\| R _ <\| Finset.mem_singleton_self _) theorem trStmts₁_supports {S q} (H₁ : (q : Λ').Supports S) (HS₁ : trStmts₁ q ⊆ S) : Supports (trStmts₁ q) S := by have W := fun {q} => trStmts₁_self q induction q with \| move _ _ _ q q_ih => _ \| clear _ _ q q_ih => _ \| copy q q_ih => _ \| push _ _ q q_ih => _ \| read q q_ih => _ \| succ q q_ih => _ \| pred q₁ q₂ q₁_ih q₂_ih => _ \| ret => _ <;> simp [trStmts₁, -Finset.singleton_subset_iff] at HS₁ ⊢ any_goals obtain ⟨h₁, h₂⟩ := Finset.insert_subset_iff.1 HS₁ first \| have h₃ := h₂ W \| try simp [Finset.subset_iff] at h₂ · exact supports_insert.2 ⟨⟨fun _ => h₃, fun _ => h₁⟩, q_ih H₁ h₂⟩ -- move · exact supports_insert.2 ⟨⟨fun _ => h₃, fun _ => h₁⟩, q_ih H₁ h₂⟩ -- clear · exact supports_insert.2 ⟨⟨fun _ => h₁, fun _ => h₃⟩, q_ih H₁ h₂⟩ -- copy · exact supports_insert.2 ⟨⟨fun _ => h₃, fun _ => h₃⟩, q_ih H₁ h₂⟩ -- push · refine supports_insert.2 ⟨fun _ => h₂ _ W, ?_⟩ -- read exact supports_biUnion.2 fun _ => q_ih _ (H₁ _) fun _ h => h₂ _ h · refine supports_insert.2 ⟨⟨fun _ => h₁, fun _ => h₂.1, fun _ => h₂.1⟩, ?_⟩ -- succ exact supports_insert.2 ⟨⟨fun _ => h₂.2 _ W, fun _ => h₂.1⟩, q_ih H₁ h₂.2⟩ · refine -- pred supports_insert.2 ⟨⟨fun _ => h₁, fun _ => h₂.2 _ (Or.inl W), fun _ => h₂.1, fun _ => h₂.1⟩, ?_⟩ refine supports_insert.2 ⟨⟨fun _ => h₂.2 _ (Or.inr W), fun _ => h₂.1⟩, ?_⟩ refine supports_union.2 ⟨?_, ?_⟩ · exact q₁_ih H₁.1 fun _ h => h₂.2 _ (Or.inl h) · exact q₂_ih H₁.2 fun _ h => h₂.2 _ (Or.inr h) · exact supports_singleton.2 (ret_supports H₁) -- ret theorem trStmts₁_supports' {S q K} (H₁ : (q : Λ').Supports S) (H₂ : trStmts₁ q ∪ K ⊆ S) (H₃ : K ⊆ S → Supports K S) : Supports (trStmts₁ q ∪ K) S := by simp only [Finset.union_subset_iff] at H₂ exact supports_union.2 ⟨trStmts₁_supports H₁ H₂.1, H₃ H₂.2⟩ theorem trNormal_supports {S c k} (Hk : codeSupp c k ⊆ S) : (trNormal c k).Supports S := by induction c generalizing k with simp [Λ'.Supports, head] \| zero' => exact Finset.union_subset_right Hk \| succ => intro; split_ifs <;> exact Finset.union_subset_right Hk \| tail => exact Finset.union_subset_right Hk \| cons f fs IHf _ => apply IHf rw [codeSupp_cons] at Hk exact Finset.union_subset_right Hk \| comp f g _ IHg => apply IHg; rw [codeSupp_comp] at Hk; exact Finset.union_subset_right Hk \| case f g IHf IHg => simp only [codeSupp_case, Finset.union_subset_iff] at Hk exact ⟨IHf Hk.2.1, IHg Hk.2.2⟩ \| fix f IHf => apply IHf; rw [codeSupp_fix] at Hk; exact Finset.union_subset_right Hk theorem codeSupp'_supports {S c k} (H : codeSupp c k ⊆ S) : Supports (codeSupp' c k) S := by induction c generalizing k with \| cons f fs IHf IHfs => have H' := H; simp only [codeSupp_cons, Finset.union_subset_iff] at H' refine trStmts₁_supports' (trNormal_supports H) (Finset.union_subset_left H) fun h => ?_ refine supports_union.2 ⟨IHf H'.2, ?_⟩ refine trStmts₁_supports' (trNormal_supports ?_) (Finset.union_subset_right h) fun h => ?_ · simp only [codeSupp, Finset.union_subset_iff, contSupp] at h H ⊢ exact ⟨h.2.2.1, h.2.2.2, H.2⟩ refine supports_union.2 ⟨IHfs ?_, ?_⟩ · rw [codeSupp, contSupp_cons₁] at H' exact Finset.union_subset_right (Finset.union_subset_right H'.2) exact trStmts₁_supports (head_supports <\| Finset.union_subset_right H) (Finset.union_subset_right h) \| comp f g IHf IHg => have H' := H; rw [codeSupp_comp] at H'; have H' := Finset.union_subset_right H' refine trStmts₁_supports' (trNormal_supports H) (Finset.union_subset_left H) fun h => ?_ refine supports_union.2 ⟨IHg H', ?_⟩ refine trStmts₁_supports' (trNormal_supports ?_) (Finset.union_subset_right h) fun _ => ?_ · simp only [codeSupp', codeSupp, Finset.union_subset_iff, contSupp] at h H ⊢ exact ⟨h.2.2, H.2⟩ exact IHf (Finset.union_subset_right H') \| case f g IHf IHg => have H' := H; simp only [codeSupp_case, Finset.union_subset_iff] at H' refine trStmts₁_supports' (trNormal_supports H) (Finset.union_subset_left H) fun _ => ?_ exact supports_union.2 ⟨IHf H'.2.1, IHg H'.2.2⟩ \| fix f IHf => have H' := H; simp only [codeSupp_fix, Finset.union_subset_iff] at H' refine trStmts₁_supports' (trNormal_supports H) (Finset.union_subset_left H) fun h => ?_ refine supports_union.2 ⟨IHf H'.2, ?_⟩ refine trStmts₁_supports' (trNormal_supports ?_) (Finset.union_subset_right h) fun _ => ?_ · simp only [codeSupp', codeSupp, Finset.union_subset_iff, contSupp, trStmts₁, Finset.insert_subset_iff] at h H ⊢ exact ⟨h.1, ⟨H.1.1, h⟩, H.2⟩ exact supports_singleton.2 (ret_supports <\| Finset.union_subset_right H) \| _ => exact trStmts₁_supports (trNormal_supports H) (Finset.Subset.trans (codeSupp_self _ _) H) theorem contSupp_supports {S k} (H : contSupp k ⊆ S) : Supports (contSupp k) S := by induction k with \| halt => simp [contSupp_halt, Supports] \| cons₁ f k IH => have H₁ := H; rw [contSupp_cons₁] at H₁; have H₂ := Finset.union_subset_right H₁ refine trStmts₁_supports' (trNormal_supports H₂) H₁ fun h => ?_ refine supports_union.2 ⟨codeSupp'_supports H₂, ?_⟩ simp only [codeSupp, contSupp_cons₂, Finset.union_subset_iff] at H₂ exact trStmts₁_supports' (head_supports H₂.2.2) (Finset.union_subset_right h) IH \| cons₂ k IH => have H' := H; rw [contSupp_cons₂] at H' exact trStmts₁_supports' (head_supports <\| Finset.union_subset_right H') H' IH \| comp f k IH => have H' := H; rw [contSupp_comp] at H'; have H₂ := Finset.union_subset_right H' exact supports_union.2 ⟨codeSupp'_supports H', IH H₂⟩ \| fix f k IH => rw [contSupp] at H exact supports_union.2 ⟨codeSupp'_supports H, IH (Finset.union_subset_right H)⟩ theorem codeSupp_supports {S c k} (H : codeSupp c k ⊆ S) : Supports (codeSupp c k) S := supports_union.2 ⟨codeSupp'_supports H, contSupp_supports (Finset.union_subset_right H)⟩ /-- The set `codeSupp c k` is a finite set that witnesses the effective finiteness of the `tr` Turing machine. Starting from the initial state `trNormal c k`, forward simulation uses only states in `codeSupp c k`, so this is a finite state machine. Even though the underlying type of state labels `Λ'` is infinite, for a given partial recursive function `c` and continuation `k`, only finitely many states are accessed, corresponding roughly to subterms of `c`. -/ theorem tr_supports (c k) : @TM2.Supports _ _ _ _ ⟨trNormal c k⟩ tr (codeSupp c k) := ⟨codeSupp_self _ _ (trStmts₁_self _), fun _ => codeSupp_supports (Finset.Subset.refl _) _⟩ end end PartrecToTM2 end Turing		Mathlib/Computability/TMToPartrec.lean	1,459	1,473
/- Copyright (c) 2015 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura, Mario Carneiro -/ import Mathlib.Data.Sum.Basic import Mathlib.Logic.Equiv.Option import Mathlib.Logic.Equiv.Sum import Mathlib.Logic.Function.Conjugate import Mathlib.Tactic.CC import Mathlib.Tactic.Lift /-! # Equivalence between types In this file we continue the work on equivalences begun in `Mathlib/Logic/Equiv/Defs.lean`, defining a lot of equivalences between various types and operations on these equivalences. More definitions of this kind can be found in other files. E.g., `Mathlib/Algebra/Equiv/TransferInstance.lean` does it for many algebraic type classes like `Group`, `Module`, etc. ## Tags equivalence, congruence, bijective map -/ universe u v w z open Function -- Unless required to be `Type`, all variables in this file are `Sort` variable {α α₁ α₂ β β₁ β₂ γ δ : Sort} namespace Equiv /-- The product over `Option α` of `β a` is the binary product of the product over `α` of `β (some α)` and `β none` -/ @[simps] def piOptionEquivProd {α} {β : Option α → Type} : (∀ a : Option α, β a) ≃ β none × ∀ a : α, β (some a) where toFun f := (f none, fun a => f (some a)) invFun x a := Option.casesOn a x.fst x.snd left_inv f := funext fun a => by cases a <;> rfl right_inv x := by simp section subtypeCongr /-- Combines an `Equiv` between two subtypes with an `Equiv` between their complements to form a permutation. -/ def subtypeCongr {α} {p q : α → Prop} [DecidablePred p] [DecidablePred q] (e : { x // p x } ≃ { x // q x }) (f : { x // ¬p x } ≃ { x // ¬q x }) : Perm α := (sumCompl p).symm.trans ((sumCongr e f).trans (sumCompl q)) variable {ε : Type} {p : ε → Prop} [DecidablePred p] variable (ep ep' : Perm { a // p a }) (en en' : Perm { a // ¬p a }) /-- Combining permutations on `ε` that permute only inside or outside the subtype split induced by `p : ε → Prop` constructs a permutation on `ε`. -/ def Perm.subtypeCongr : Equiv.Perm ε := permCongr (sumCompl p) (sumCongr ep en) theorem Perm.subtypeCongr.apply (a : ε) : ep.subtypeCongr en a = if h : p a then (ep ⟨a, h⟩ : ε) else en ⟨a, h⟩ := by by_cases h : p a <;> simp [Perm.subtypeCongr, h] @[simp] theorem Perm.subtypeCongr.left_apply {a : ε} (h : p a) : ep.subtypeCongr en a = ep ⟨a, h⟩ := by simp [Perm.subtypeCongr.apply, h] @[simp] theorem Perm.subtypeCongr.left_apply_subtype (a : { a // p a }) : ep.subtypeCongr en a = ep a := Perm.subtypeCongr.left_apply ep en a.property @[simp] theorem Perm.subtypeCongr.right_apply {a : ε} (h : ¬p a) : ep.subtypeCongr en a = en ⟨a, h⟩ := by simp [Perm.subtypeCongr.apply, h] @[simp] theorem Perm.subtypeCongr.right_apply_subtype (a : { a // ¬p a }) : ep.subtypeCongr en a = en a := Perm.subtypeCongr.right_apply ep en a.property @[simp] theorem Perm.subtypeCongr.refl : Perm.subtypeCongr (Equiv.refl { a // p a }) (Equiv.refl { a // ¬p a }) = Equiv.refl ε := by ext x by_cases h : p x <;> simp [h] @[simp] theorem Perm.subtypeCongr.symm : (ep.subtypeCongr en).symm = Perm.subtypeCongr ep.symm en.symm := by ext x by_cases h : p x · have : p (ep.symm ⟨x, h⟩) := Subtype.property _ simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this] · have : ¬p (en.symm ⟨x, h⟩) := Subtype.property (en.symm _) simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this] @[simp] theorem Perm.subtypeCongr.trans : (ep.subtypeCongr en).trans (ep'.subtypeCongr en') = Perm.subtypeCongr (ep.trans ep') (en.trans en') := by ext x by_cases h : p x · have : p (ep ⟨x, h⟩) := Subtype.property _ simp [Perm.subtypeCongr.apply, h, this] · have : ¬p (en ⟨x, h⟩) := Subtype.property (en _) simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this] end subtypeCongr section subtypePreimage variable (p : α → Prop) [DecidablePred p] (x₀ : { a // p a } → β) /-- For a fixed function `x₀ : {a // p a} → β` defined on a subtype of `α`, the subtype of functions `x : α → β` that agree with `x₀` on the subtype `{a // p a}` is naturally equivalent to the type of functions `{a // ¬ p a} → β`. -/ @[simps] def subtypePreimage : { x : α → β // x ∘ Subtype.val = x₀ } ≃ ({ a // ¬p a } → β) where toFun (x : { x : α → β // x ∘ Subtype.val = x₀ }) a := (x : α → β) a invFun x := ⟨fun a => if h : p a then x₀ ⟨a, h⟩ else x ⟨a, h⟩, funext fun ⟨_, h⟩ => dif_pos h⟩ left_inv := fun ⟨x, hx⟩ => Subtype.val_injective <\| funext fun a => by dsimp only split_ifs · rw [← hx]; rfl · rfl right_inv x := funext fun ⟨a, h⟩ => show dite (p a) _ _ = _ by dsimp only rw [dif_neg h] theorem subtypePreimage_symm_apply_coe_pos (x : { a // ¬p a } → β) (a : α) (h : p a) : ((subtypePreimage p x₀).symm x : α → β) a = x₀ ⟨a, h⟩ := dif_pos h theorem subtypePreimage_symm_apply_coe_neg (x : { a // ¬p a } → β) (a : α) (h : ¬p a) : ((subtypePreimage p x₀).symm x : α → β) a = x ⟨a, h⟩ := dif_neg h end subtypePreimage section /-- A family of equivalences `∀ a, β₁ a ≃ β₂ a` generates an equivalence between `∀ a, β₁ a` and `∀ a, β₂ a`. -/ @[simps] def piCongrRight {β₁ β₂ : α → Sort} (F : ∀ a, β₁ a ≃ β₂ a) : (∀ a, β₁ a) ≃ (∀ a, β₂ a) := ⟨Pi.map fun a ↦ F a, Pi.map fun a ↦ (F a).symm, fun H => funext <\| by simp, fun H => funext <\| by simp⟩ /-- Given `φ : α → β → Sort`, we have an equivalence between `∀ a b, φ a b` and `∀ b a, φ a b`. This is `Function.swap` as an `Equiv`. -/ @[simps apply] def piComm (φ : α → β → Sort) : (∀ a b, φ a b) ≃ ∀ b a, φ a b := ⟨swap, swap, fun _ => rfl, fun _ => rfl⟩ @[simp] theorem piComm_symm {φ : α → β → Sort} : (piComm φ).symm = (piComm <\| swap φ) := rfl /-- Dependent `curry` equivalence: the type of dependent functions on `Σ i, β i` is equivalent to the type of dependent functions of two arguments (i.e., functions to the space of functions). This is `Sigma.curry` and `Sigma.uncurry` together as an equiv. -/ def piCurry {α} {β : α → Type} (γ : ∀ a, β a → Type) : (∀ x : Σ i, β i, γ x.1 x.2) ≃ ∀ a b, γ a b where toFun := Sigma.curry invFun := Sigma.uncurry left_inv := Sigma.uncurry_curry right_inv := Sigma.curry_uncurry -- `simps` overapplies these but `simps -fullyApplied` under-applies them @[simp] theorem piCurry_apply {α} {β : α → Type} (γ : ∀ a, β a → Type) (f : ∀ x : Σ i, β i, γ x.1 x.2) : piCurry γ f = Sigma.curry f := rfl @[simp] theorem piCurry_symm_apply {α} {β : α → Type} (γ : ∀ a, β a → Type) (f : ∀ a b, γ a b) : (piCurry γ).symm f = Sigma.uncurry f := rfl end section prodCongr variable {α₁ α₂ β₁ β₂ : Type} (e : α₁ → β₁ ≃ β₂) -- See also `Equiv.ofPreimageEquiv`. /-- A family of equivalences between fibers gives an equivalence between domains. -/ @[simps!] def ofFiberEquiv {α β γ} {f : α → γ} {g : β → γ} (e : ∀ c, { a // f a = c } ≃ { b // g b = c }) : α ≃ β := (sigmaFiberEquiv f).symm.trans <\| (Equiv.sigmaCongrRight e).trans (sigmaFiberEquiv g) theorem ofFiberEquiv_map {α β γ} {f : α → γ} {g : β → γ} (e : ∀ c, { a // f a = c } ≃ { b // g b = c }) (a : α) : g (ofFiberEquiv e a) = f a := (_ : { b // g b = _ }).property end prodCongr section open Sum /-- An equivalence that separates out the 0th fiber of `(Σ (n : ℕ), f n)`. -/ def sigmaNatSucc (f : ℕ → Type u) : (Σ n, f n) ≃ f 0 ⊕ Σ n, f (n + 1) := ⟨fun x => @Sigma.casesOn ℕ f (fun _ => f 0 ⊕ Σ n, f (n + 1)) x fun n => @Nat.casesOn (fun i => f i → f 0 ⊕ Σ n : ℕ, f (n + 1)) n (fun x : f 0 => Sum.inl x) fun (n : ℕ) (x : f n.succ) => Sum.inr ⟨n, x⟩, Sum.elim (Sigma.mk 0) (Sigma.map Nat.succ fun _ => id), by rintro ⟨n \| n, x⟩ <;> rfl, by rintro (x \| ⟨n, x⟩) <;> rfl⟩ end section open Sum Nat /-- The set of natural numbers is equivalent to `ℕ ⊕ PUnit`. -/ def natEquivNatSumPUnit : ℕ ≃ ℕ ⊕ PUnit where toFun n := Nat.casesOn n (inr PUnit.unit) inl invFun := Sum.elim Nat.succ fun _ => 0 left_inv n := by cases n <;> rfl right_inv := by rintro (_ \| _) <;> rfl /-- `ℕ ⊕ PUnit` is equivalent to `ℕ`. -/ def natSumPUnitEquivNat : ℕ ⊕ PUnit ≃ ℕ := natEquivNatSumPUnit.symm /-- The type of integer numbers is equivalent to `ℕ ⊕ ℕ`. -/ def intEquivNatSumNat : ℤ ≃ ℕ ⊕ ℕ where toFun z := Int.casesOn z inl inr invFun := Sum.elim Int.ofNat Int.negSucc left_inv := by rintro (m \| n) <;> rfl right_inv := by rintro (m \| n) <;> rfl end /-- If `α` is equivalent to `β`, then `Unique α` is equivalent to `Unique β`. -/ def uniqueCongr (e : α ≃ β) : Unique α ≃ Unique β where toFun h := @Equiv.unique _ _ h e.symm invFun h := @Equiv.unique _ _ h e left_inv _ := Subsingleton.elim _ _ right_inv _ := Subsingleton.elim _ _ /-- If `α` is equivalent to `β`, then `IsEmpty α` is equivalent to `IsEmpty β`. -/ theorem isEmpty_congr (e : α ≃ β) : IsEmpty α ↔ IsEmpty β := ⟨fun h => @Function.isEmpty _ _ h e.symm, fun h => @Function.isEmpty _ _ h e⟩ protected theorem isEmpty (e : α ≃ β) [IsEmpty β] : IsEmpty α := e.isEmpty_congr.mpr ‹_› section open Subtype /-- If `α` is equivalent to `β` and the predicates `p : α → Prop` and `q : β → Prop` are equivalent at corresponding points, then `{a // p a}` is equivalent to `{b // q b}`. For the statement where `α = β`, that is, `e : perm α`, see `Perm.subtypePerm`. -/ @[simps apply] def subtypeEquiv {p : α → Prop} {q : β → Prop} (e : α ≃ β) (h : ∀ a, p a ↔ q (e a)) : { a : α // p a } ≃ { b : β // q b } where toFun a := ⟨e a, (h _).mp a.property⟩ invFun b := ⟨e.symm b, (h _).mpr ((e.apply_symm_apply b).symm ▸ b.property)⟩ left_inv a := Subtype.ext <\| by simp right_inv b := Subtype.ext <\| by simp lemma coe_subtypeEquiv_eq_map {X Y} {p : X → Prop} {q : Y → Prop} (e : X ≃ Y) (h : ∀ x, p x ↔ q (e x)) : ⇑(e.subtypeEquiv h) = Subtype.map e (h · \|>.mp) := rfl @[simp] theorem subtypeEquiv_refl {p : α → Prop} (h : ∀ a, p a ↔ p (Equiv.refl _ a) := fun _ => Iff.rfl) : (Equiv.refl α).subtypeEquiv h = Equiv.refl { a : α // p a } := by ext rfl -- We use `as_aux_lemma` here to avoid creating large proof terms when using `simp` @[simp] theorem subtypeEquiv_symm {p : α → Prop} {q : β → Prop} (e : α ≃ β) (h : ∀ a : α, p a ↔ q (e a)) : (e.subtypeEquiv h).symm = e.symm.subtypeEquiv (by as_aux_lemma => intro a convert (h <\| e.symm a).symm exact (e.apply_symm_apply a).symm) := rfl @[simp] theorem subtypeEquiv_trans {p : α → Prop} {q : β → Prop} {r : γ → Prop} (e : α ≃ β) (f : β ≃ γ) (h : ∀ a : α, p a ↔ q (e a)) (h' : ∀ b : β, q b ↔ r (f b)) : (e.subtypeEquiv h).trans (f.subtypeEquiv h') = (e.trans f).subtypeEquiv (by as_aux_lemma => exact fun a => (h a).trans (h' <\| e a)) := rfl /-- If two predicates `p` and `q` are pointwise equivalent, then `{x // p x}` is equivalent to `{x // q x}`. -/ @[simps!] def subtypeEquivRight {p q : α → Prop} (e : ∀ x, p x ↔ q x) : { x // p x } ≃ { x // q x } := subtypeEquiv (Equiv.refl _) e lemma subtypeEquivRight_apply {p q : α → Prop} (e : ∀ x, p x ↔ q x) (z : { x // p x }) : subtypeEquivRight e z = ⟨z, (e z.1).mp z.2⟩ := rfl lemma subtypeEquivRight_symm_apply {p q : α → Prop} (e : ∀ x, p x ↔ q x) (z : { x // q x }) : (subtypeEquivRight e).symm z = ⟨z, (e z.1).mpr z.2⟩ := rfl /-- If `α ≃ β`, then for any predicate `p : β → Prop` the subtype `{a // p (e a)}` is equivalent to the subtype `{b // p b}`. -/ def subtypeEquivOfSubtype {p : β → Prop} (e : α ≃ β) : { a : α // p (e a) } ≃ { b : β // p b } := subtypeEquiv e <\| by simp /-- If `α ≃ β`, then for any predicate `p : α → Prop` the subtype `{a // p a}` is equivalent to the subtype `{b // p (e.symm b)}`. This version is used by `equiv_rw`. -/ def subtypeEquivOfSubtype' {p : α → Prop} (e : α ≃ β) : { a : α // p a } ≃ { b : β // p (e.symm b) } := e.symm.subtypeEquivOfSubtype.symm /-- If two predicates are equal, then the corresponding subtypes are equivalent. -/ def subtypeEquivProp {p q : α → Prop} (h : p = q) : Subtype p ≃ Subtype q := subtypeEquiv (Equiv.refl α) fun _ => h ▸ Iff.rfl /-- A subtype of a subtype is equivalent to the subtype of elements satisfying both predicates. This version allows the “inner” predicate to depend on `h : p a`. -/ @[simps] def subtypeSubtypeEquivSubtypeExists (p : α → Prop) (q : Subtype p → Prop) : Subtype q ≃ { a : α // ∃ h : p a, q ⟨a, h⟩ } := ⟨fun a => ⟨a.1, a.1.2, by rcases a with ⟨⟨a, hap⟩, haq⟩ exact haq⟩, fun a => ⟨⟨a, a.2.fst⟩, a.2.snd⟩, fun ⟨⟨_, _⟩, _⟩ => rfl, fun ⟨_, _, _⟩ => rfl⟩ /-- A subtype of a subtype is equivalent to the subtype of elements satisfying both predicates. -/ @[simps!] def subtypeSubtypeEquivSubtypeInter {α : Type u} (p q : α → Prop) : { x : Subtype p // q x.1 } ≃ Subtype fun x => p x ∧ q x := (subtypeSubtypeEquivSubtypeExists p _).trans <\| subtypeEquivRight fun x => @exists_prop (q x) (p x) /-- If the outer subtype has more restrictive predicate than the inner one, then we can drop the latter. -/ @[simps!] def subtypeSubtypeEquivSubtype {α} {p q : α → Prop} (h : ∀ {x}, q x → p x) : { x : Subtype p // q x.1 } ≃ Subtype q := (subtypeSubtypeEquivSubtypeInter p _).trans <\| subtypeEquivRight fun _ => and_iff_right_of_imp h /-- If a proposition holds for all elements, then the subtype is equivalent to the original type. -/ @[simps apply symm_apply] def subtypeUnivEquiv {α} {p : α → Prop} (h : ∀ x, p x) : Subtype p ≃ α := ⟨fun x => x, fun x => ⟨x, h x⟩, fun _ => Subtype.eq rfl, fun _ => rfl⟩ /-- A subtype of a sigma-type is a sigma-type over a subtype. -/ def subtypeSigmaEquiv {α} (p : α → Type v) (q : α → Prop) : { y : Sigma p // q y.1 } ≃ Σ x : Subtype q, p x.1 := ⟨fun x => ⟨⟨x.1.1, x.2⟩, x.1.2⟩, fun x => ⟨⟨x.1.1, x.2⟩, x.1.2⟩, fun _ => rfl, fun _ => rfl⟩ /-- A sigma type over a subtype is equivalent to the sigma set over the original type, if the fiber is empty outside of the subset -/ def sigmaSubtypeEquivOfSubset {α} (p : α → Type v) (q : α → Prop) (h : ∀ x, p x → q x) : (Σ x : Subtype q, p x) ≃ Σ x : α, p x := (subtypeSigmaEquiv p q).symm.trans <\| subtypeUnivEquiv fun x => h x.1 x.2 /-- If a predicate `p : β → Prop` is true on the range of a map `f : α → β`, then `Σ y : {y // p y}, {x // f x = y}` is equivalent to `α`. -/ def sigmaSubtypeFiberEquiv {α β : Type} (f : α → β) (p : β → Prop) (h : ∀ x, p (f x)) : (Σ y : Subtype p, { x : α // f x = y }) ≃ α := calc _ ≃ Σy : β, { x : α // f x = y } := sigmaSubtypeEquivOfSubset _ p fun _ ⟨x, h'⟩ => h' ▸ h x _ ≃ α := sigmaFiberEquiv f /-- If for each `x` we have `p x ↔ q (f x)`, then `Σ y : {y // q y}, f ⁻¹' {y}` is equivalent to `{x // p x}`. -/ def sigmaSubtypeFiberEquivSubtype {α β : Type} (f : α → β) {p : α → Prop} {q : β → Prop} (h : ∀ x, p x ↔ q (f x)) : (Σ y : Subtype q, { x : α // f x = y }) ≃ Subtype p := calc (Σy : Subtype q, { x : α // f x = y }) ≃ Σy : Subtype q, { x : Subtype p // Subtype.mk (f x) ((h x).1 x.2) = y } := by { apply sigmaCongrRight intro y apply Equiv.symm refine (subtypeSubtypeEquivSubtypeExists _ _).trans (subtypeEquivRight ?_) intro x exact ⟨fun ⟨hp, h'⟩ => congr_arg Subtype.val h', fun h' => ⟨(h x).2 (h'.symm ▸ y.2), Subtype.eq h'⟩⟩ } _ ≃ Subtype p := sigmaFiberEquiv fun x : Subtype p => (⟨f x, (h x).1 x.property⟩ : Subtype q) /-- A sigma type over an `Option` is equivalent to the sigma set over the original type, if the fiber is empty at none. -/ def sigmaOptionEquivOfSome {α} (p : Option α → Type v) (h : p none → False) : (Σ x : Option α, p x) ≃ Σ x : α, p (some x) := haveI h' : ∀ x, p x → x.isSome := by intro x cases x · intro n exfalso exact h n · intro _ exact rfl (sigmaSubtypeEquivOfSubset _ _ h').symm.trans (sigmaCongrLeft' (optionIsSomeEquiv α)) /-- The `Pi`-type `∀ i, π i` is equivalent to the type of sections `f : ι → Σ i, π i` of the `Sigma` type such that for all `i` we have `(f i).fst = i`. -/ def piEquivSubtypeSigma (ι) (π : ι → Type) : (∀ i, π i) ≃ { f : ι → Σ i, π i // ∀ i, (f i).1 = i } where toFun := fun f => ⟨fun i => ⟨i, f i⟩, fun _ => rfl⟩ invFun := fun f i => by rw [← f.2 i]; exact (f.1 i).2 left_inv := fun _ => funext fun _ => rfl right_inv := fun ⟨f, hf⟩ => Subtype.eq <\| funext fun i => Sigma.eq (hf i).symm <\| eq_of_heq <\| rec_heq_of_heq _ <\| by simp /-- The type of functions `f : ∀ a, β a` such that for all `a` we have `p a (f a)` is equivalent to the type of functions `∀ a, {b : β a // p a b}`. -/ def subtypePiEquivPi {β : α → Sort v} {p : ∀ a, β a → Prop} : { f : ∀ a, β a // ∀ a, p a (f a) } ≃ ∀ a, { b : β a // p a b } where toFun := fun f a => ⟨f.1 a, f.2 a⟩ invFun := fun f => ⟨fun a => (f a).1, fun a => (f a).2⟩ left_inv := by rintro ⟨f, h⟩ rfl right_inv := by rintro f funext a exact Subtype.ext_val rfl end section subtypeEquivCodomain variable {X Y : Sort} [DecidableEq X] {x : X} /-- The type of all functions `X → Y` with prescribed values for all `x' ≠ x` is equivalent to the codomain `Y`. -/ def subtypeEquivCodomain (f : { x' // x' ≠ x } → Y) : { g : X → Y // g ∘ (↑) = f } ≃ Y := (subtypePreimage _ f).trans <\| @funUnique { x' // ¬x' ≠ x } _ <\| show Unique { x' // ¬x' ≠ x } from @Equiv.unique _ _ (show Unique { x' // x' = x } from { default := ⟨x, rfl⟩, uniq := fun ⟨_, h⟩ => Subtype.val_injective h }) (subtypeEquivRight fun _ => not_not) @[simp] theorem coe_subtypeEquivCodomain (f : { x' // x' ≠ x } → Y) : (subtypeEquivCodomain f : _ → Y) = fun g : { g : X → Y // g ∘ (↑) = f } => (g : X → Y) x := rfl @[simp] theorem subtypeEquivCodomain_apply (f : { x' // x' ≠ x } → Y) (g) : subtypeEquivCodomain f g = (g : X → Y) x := rfl theorem coe_subtypeEquivCodomain_symm (f : { x' // x' ≠ x } → Y) : ((subtypeEquivCodomain f).symm : Y → _) = fun y => ⟨fun x' => if h : x' ≠ x then f ⟨x', h⟩ else y, by funext x' simp only [ne_eq, dite_not, comp_apply, Subtype.coe_eta, dite_eq_ite, ite_eq_right_iff] intro w exfalso exact x'.property w⟩ := rfl @[simp] theorem subtypeEquivCodomain_symm_apply (f : { x' // x' ≠ x } → Y) (y : Y) (x' : X) : ((subtypeEquivCodomain f).symm y : X → Y) x' = if h : x' ≠ x then f ⟨x', h⟩ else y := rfl theorem subtypeEquivCodomain_symm_apply_eq (f : { x' // x' ≠ x } → Y) (y : Y) : ((subtypeEquivCodomain f).symm y : X → Y) x = y := dif_neg (not_not.mpr rfl) theorem subtypeEquivCodomain_symm_apply_ne (f : { x' // x' ≠ x } → Y) (y : Y) (x' : X) (h : x' ≠ x) : ((subtypeEquivCodomain f).symm y : X → Y) x' = f ⟨x', h⟩ := dif_pos h end subtypeEquivCodomain instance : CanLift (α → β) (α ≃ β) (↑) Bijective where prf f hf := ⟨ofBijective f hf, rfl⟩ section variable {α' β' : Type} (e : Perm α') {p : β' → Prop} [DecidablePred p] (f : α' ≃ Subtype p) /-- Extend the domain of `e : Equiv.Perm α` to one that is over `β` via `f : α → Subtype p`, where `p : β → Prop`, permuting only the `b : β` that satisfy `p b`. This can be used to extend the domain across a function `f : α → β`, keeping everything outside of `Set.range f` fixed. For this use-case `Equiv` given by `f` can be constructed by `Equiv.of_leftInverse'` or `Equiv.of_leftInverse` when there is a known inverse, or `Equiv.ofInjective` in the general case. -/ def Perm.extendDomain : Perm β' := (permCongr f e).subtypeCongr (Equiv.refl _) @[simp] theorem Perm.extendDomain_apply_image (a : α') : e.extendDomain f (f a) = f (e a) := by simp [Perm.extendDomain] theorem Perm.extendDomain_apply_subtype {b : β'} (h : p b) : e.extendDomain f b = f (e (f.symm ⟨b, h⟩)) := by simp [Perm.extendDomain, h] theorem Perm.extendDomain_apply_not_subtype {b : β'} (h : ¬p b) : e.extendDomain f b = b := by simp [Perm.extendDomain, h] @[simp] theorem Perm.extendDomain_refl : Perm.extendDomain (Equiv.refl _) f = Equiv.refl _ := by simp [Perm.extendDomain] @[simp] theorem Perm.extendDomain_symm : (e.extendDomain f).symm = Perm.extendDomain e.symm f := rfl theorem Perm.extendDomain_trans (e e' : Perm α') : (e.extendDomain f).trans (e'.extendDomain f) = Perm.extendDomain (e.trans e') f := by simp [Perm.extendDomain, permCongr_trans] end /-- Subtype of the quotient is equivalent to the quotient of the subtype. Let `α` be a setoid with equivalence relation `~`. Let `p₂` be a predicate on the quotient type `α/~`, and `p₁` be the lift of this predicate to `α`: `p₁ a ↔ p₂ ⟦a⟧`. Let `~₂` be the restriction of `~` to `{x // p₁ x}`. Then `{x // p₂ x}` is equivalent to the quotient of `{x // p₁ x}` by `~₂`. -/ def subtypeQuotientEquivQuotientSubtype (p₁ : α → Prop) {s₁ : Setoid α} {s₂ : Setoid (Subtype p₁)} (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧) (h : ∀ x y : Subtype p₁, s₂.r x y ↔ s₁.r x y) : {x // p₂ x} ≃ Quotient s₂ where toFun a := Quotient.hrecOn a.1 (fun a h => ⟦⟨a, (hp₂ _).2 h⟩⟧) (fun a b hab => hfunext (by rw [Quotient.sound hab]) fun _ _ _ => heq_of_eq (Quotient.sound ((h _ _).2 hab))) a.2 invFun a := Quotient.liftOn a (fun a => (⟨⟦a.1⟧, (hp₂ _).1 a.2⟩ : { x // p₂ x })) fun _ _ hab => Subtype.ext_val (Quotient.sound ((h _ _).1 hab)) left_inv := by exact fun ⟨a, ha⟩ => Quotient.inductionOn a (fun b hb => rfl) ha right_inv a := by exact Quotient.inductionOn a fun ⟨a, ha⟩ => rfl @[simp] theorem subtypeQuotientEquivQuotientSubtype_mk (p₁ : α → Prop) [s₁ : Setoid α] [s₂ : Setoid (Subtype p₁)] (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧) (h : ∀ x y : Subtype p₁, s₂ x y ↔ (x : α) ≈ y) (x hx) : subtypeQuotientEquivQuotientSubtype p₁ p₂ hp₂ h ⟨⟦x⟧, hx⟩ = ⟦⟨x, (hp₂ _).2 hx⟩⟧ := rfl @[simp] theorem subtypeQuotientEquivQuotientSubtype_symm_mk (p₁ : α → Prop) [s₁ : Setoid α] [s₂ : Setoid (Subtype p₁)] (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧) (h : ∀ x y : Subtype p₁, s₂ x y ↔ (x : α) ≈ y) (x) : (subtypeQuotientEquivQuotientSubtype p₁ p₂ hp₂ h).symm ⟦x⟧ = ⟨⟦x⟧, (hp₂ _).1 x.property⟩ := rfl section Swap variable [DecidableEq α] /-- A helper function for `Equiv.swap`. -/ def swapCore (a b r : α) : α := if r = a then b else if r = b then a else r theorem swapCore_self (r a : α) : swapCore a a r = r := by unfold swapCore split_ifs <;> simp [] theorem swapCore_swapCore (r a b : α) : swapCore a b (swapCore a b r) = r := by unfold swapCore; split_ifs <;> cc theorem swapCore_comm (r a b : α) : swapCore a b r = swapCore b a r := by unfold swapCore; split_ifs <;> cc /-- `swap a b` is the permutation that swaps `a` and `b` and leaves other values as is. -/ def swap (a b : α) : Perm α := ⟨swapCore a b, swapCore a b, fun r => swapCore_swapCore r a b, fun r => swapCore_swapCore r a b⟩ @[simp] theorem swap_self (a : α) : swap a a = Equiv.refl _ := ext fun r => swapCore_self r a theorem swap_comm (a b : α) : swap a b = swap b a := ext fun r => swapCore_comm r _ _ theorem swap_apply_def (a b x : α) : swap a b x = if x = a then b else if x = b then a else x := rfl @[simp] theorem swap_apply_left (a b : α) : swap a b a = b := if_pos rfl @[simp] theorem swap_apply_right (a b : α) : swap a b b = a := by by_cases h : b = a <;> simp [swap_apply_def, h] theorem swap_apply_of_ne_of_ne {a b x : α} : x ≠ a → x ≠ b → swap a b x = x := by simp +contextual [swap_apply_def] theorem eq_or_eq_of_swap_apply_ne_self {a b x : α} (h : swap a b x ≠ x) : x = a ∨ x = b := by contrapose! h exact swap_apply_of_ne_of_ne h.1 h.2 @[simp] theorem swap_swap (a b : α) : (swap a b).trans (swap a b) = Equiv.refl _ := ext fun _ => swapCore_swapCore _ _ _ @[simp] theorem symm_swap (a b : α) : (swap a b).symm = swap a b := rfl @[simp] theorem swap_eq_refl_iff {x y : α} : swap x y = Equiv.refl _ ↔ x = y := by refine ⟨fun h => (Equiv.refl _).injective ?_, fun h => h ▸ swap_self _⟩ rw [← h, swap_apply_left, h, refl_apply] theorem swap_comp_apply {a b x : α} (π : Perm α) : π.trans (swap a b) x = if π x = a then b else if π x = b then a else π x := by cases π rfl theorem swap_eq_update (i j : α) : (Equiv.swap i j : α → α) = update (update id j i) i j := funext fun x => by rw [update_apply _ i j, update_apply _ j i, Equiv.swap_apply_def, id] theorem comp_swap_eq_update (i j : α) (f : α → β) : f ∘ Equiv.swap i j = update (update f j (f i)) i (f j) := by rw [swap_eq_update, comp_update, comp_update, comp_id] @[simp] theorem symm_trans_swap_trans [DecidableEq β] (a b : α) (e : α ≃ β) : (e.symm.trans (swap a b)).trans e = swap (e a) (e b) := Equiv.ext fun x => by have : ∀ a, e.symm x = a ↔ x = e a := fun a => by rw [@eq_comm _ (e.symm x)] constructor <;> intros <;> simp_all simp only [trans_apply, swap_apply_def, this] split_ifs <;> simp @[simp] theorem trans_swap_trans_symm [DecidableEq β] (a b : β) (e : α ≃ β) : (e.trans (swap a b)).trans e.symm = swap (e.symm a) (e.symm b) := symm_trans_swap_trans a b e.symm @[simp] theorem swap_apply_self (i j a : α) : swap i j (swap i j a) = a := by rw [← Equiv.trans_apply, Equiv.swap_swap, Equiv.refl_apply] /-- A function is invariant to a swap if it is equal at both elements -/ theorem apply_swap_eq_self {v : α → β} {i j : α} (hv : v i = v j) (k : α) : v (swap i j k) = v k := by by_cases hi : k = i · rw [hi, swap_apply_left, hv] by_cases hj : k = j · rw [hj, swap_apply_right, hv] rw [swap_apply_of_ne_of_ne hi hj] theorem swap_apply_eq_iff {x y z w : α} : swap x y z = w ↔ z = swap x y w := by rw [apply_eq_iff_eq_symm_apply, symm_swap] theorem swap_apply_ne_self_iff {a b x : α} : swap a b x ≠ x ↔ a ≠ b ∧ (x = a ∨ x = b) := by by_cases hab : a = b · simp [hab] by_cases hax : x = a · simp [hax, eq_comm] by_cases hbx : x = b · simp [hbx] simp [hab, hax, hbx, swap_apply_of_ne_of_ne] namespace Perm @[simp] theorem sumCongr_swap_refl {α β : Sort _} [DecidableEq α] [DecidableEq β] (i j : α) : Equiv.Perm.sumCongr (Equiv.swap i j) (Equiv.refl β) = Equiv.swap (Sum.inl i) (Sum.inl j) := by ext x cases x · simp only [Equiv.sumCongr_apply, Sum.map, coe_refl, comp_id, Sum.elim_inl, comp_apply, swap_apply_def, Sum.inl.injEq] split_ifs <;> rfl · simp [Sum.map, swap_apply_of_ne_of_ne] @[simp] theorem sumCongr_refl_swap {α β : Sort _} [DecidableEq α] [DecidableEq β] (i j : β) : Equiv.Perm.sumCongr (Equiv.refl α) (Equiv.swap i j) = Equiv.swap (Sum.inr i) (Sum.inr j) := by ext x cases x · simp [Sum.map, swap_apply_of_ne_of_ne] · simp only [Equiv.sumCongr_apply, Sum.map, coe_refl, comp_id, Sum.elim_inr, comp_apply, swap_apply_def, Sum.inr.injEq] split_ifs <;> rfl end Perm /-- Augment an equivalence with a prescribed mapping `f a = b` -/ def setValue (f : α ≃ β) (a : α) (b : β) : α ≃ β := (swap a (f.symm b)).trans f @[simp] theorem setValue_eq (f : α ≃ β) (a : α) (b : β) : setValue f a b a = b := by simp [setValue, swap_apply_left] end Swap end Equiv namespace Function.Involutive /-- Convert an involutive function `f` to a permutation with `toFun = invFun = f`. -/ def toPerm (f : α → α) (h : Involutive f) : Equiv.Perm α := ⟨f, f, h.leftInverse, h.rightInverse⟩ @[simp] theorem coe_toPerm {f : α → α} (h : Involutive f) : (h.toPerm f : α → α) = f := rfl @[simp] theorem toPerm_symm {f : α → α} (h : Involutive f) : (h.toPerm f).symm = h.toPerm f := rfl theorem toPerm_involutive {f : α → α} (h : Involutive f) : Involutive (h.toPerm f) := h theorem symm_eq_self_of_involutive (f : Equiv.Perm α) (h : Involutive f) : f.symm = f := DFunLike.coe_injective (h.leftInverse_iff.mp f.left_inv) end Function.Involutive theorem PLift.eq_up_iff_down_eq {x : PLift α} {y : α} : x = PLift.up y ↔ x.down = y := Equiv.plift.eq_symm_apply theorem Function.Injective.map_swap [DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y z : α) : f (Equiv.swap x y z) = Equiv.swap (f x) (f y) (f z) := by conv_rhs => rw [Equiv.swap_apply_def] split_ifs with h₁ h₂ · rw [hf h₁, Equiv.swap_apply_left] · rw [hf h₂, Equiv.swap_apply_right] · rw [Equiv.swap_apply_of_ne_of_ne (mt (congr_arg f) h₁) (mt (congr_arg f) h₂)] namespace Equiv section /-- Transport dependent functions through an equivalence of the base space. -/ @[simps apply, simps -isSimp symm_apply] def piCongrLeft' (P : α → Sort) (e : α ≃ β) : (∀ a, P a) ≃ ∀ b, P (e.symm b) where toFun f x := f (e.symm x) invFun f x := (e.symm_apply_apply x).ndrec (f (e x)) left_inv f := funext fun x => (by rintro _ rfl; rfl : ∀ {y} (h : y = x), h.ndrec (f y) = f x) (e.symm_apply_apply x) right_inv f := funext fun x => (by rintro _ rfl; rfl : ∀ {y} (h : y = x), (congr_arg e.symm h).ndrec (f y) = f x) (e.apply_symm_apply x) /-- Note: the "obvious" statement `(piCongrLeft' P e).symm g a = g (e a)` doesn't typecheck: the LHS would have type `P a` while the RHS would have type `P (e.symm (e a))`. For that reason, we have to explicitly substitute along `e.symm (e a) = a` in the statement of this lemma. -/ add_decl_doc Equiv.piCongrLeft'_symm_apply /-- This lemma is impractical to state in the dependent case. -/ @[simp] theorem piCongrLeft'_symm (P : Sort) (e : α ≃ β) : (piCongrLeft' (fun _ => P) e).symm = piCongrLeft' _ e.symm := by ext; simp [piCongrLeft'] /-- Note: the "obvious" statement `(piCongrLeft' P e).symm g a = g (e a)` doesn't typecheck: the LHS would have type `P a` while the RHS would have type `P (e.symm (e a))`. This lemma is a way around it in the case where `a` is of the form `e.symm b`, so we can use `g b` instead of `g (e (e.symm b))`. -/ @[simp] lemma piCongrLeft'_symm_apply_apply (P : α → Sort) (e : α ≃ β) (g : ∀ b, P (e.symm b)) (b : β) : (piCongrLeft' P e).symm g (e.symm b) = g b := by rw [piCongrLeft'_symm_apply, ← heq_iff_eq, rec_heq_iff_heq] exact congr_arg_heq _ (e.apply_symm_apply _) end section variable (P : β → Sort w) (e : α ≃ β) /-- Transporting dependent functions through an equivalence of the base, expressed as a "simplification". -/ def piCongrLeft : (∀ a, P (e a)) ≃ ∀ b, P b := (piCongrLeft' P e.symm).symm /-- Note: the "obvious" statement `(piCongrLeft P e) f b = f (e.symm b)` doesn't typecheck: the LHS would have type `P b` while the RHS would have type `P (e (e.symm b))`. For that reason, we have to explicitly substitute along `e (e.symm b) = b` in the statement of this lemma. -/ @[simp] lemma piCongrLeft_apply (f : ∀ a, P (e a)) (b : β) : (piCongrLeft P e) f b = e.apply_symm_apply b ▸ f (e.symm b) := rfl @[simp] lemma piCongrLeft_symm_apply (g : ∀ b, P b) (a : α) : (piCongrLeft P e).symm g a = g (e a) := piCongrLeft'_apply P e.symm g a /-- Note: the "obvious" statement `(piCongrLeft P e) f b = f (e.symm b)` doesn't typecheck: the LHS would have type `P b` while the RHS would have type `P (e (e.symm b))`. This lemma is a way around it in the case where `b` is of the form `e a`, so we can use `f a` instead of `f (e.symm (e a))`. -/ lemma piCongrLeft_apply_apply (f : ∀ a, P (e a)) (a : α) : (piCongrLeft P e) f (e a) = f a := piCongrLeft'_symm_apply_apply P e.symm f a open Sum lemma piCongrLeft_apply_eq_cast {P : β → Sort v} {e : α ≃ β} (f : (a : α) → P (e a)) (b : β) : piCongrLeft P e f b = cast (congr_arg P (e.apply_symm_apply b)) (f (e.symm b)) := Eq.rec_eq_cast _ _ theorem piCongrLeft_sumInl {ι ι' ι''} (π : ι'' → Type) (e : ι ⊕ ι' ≃ ι'') (f : ∀ i, π (e (inl i))) (g : ∀ i, π (e (inr i))) (i : ι) : piCongrLeft π e (sumPiEquivProdPi (fun x => π (e x)) \|>.symm (f, g)) (e (inl i)) = f i := by simp_rw [piCongrLeft_apply_eq_cast, sumPiEquivProdPi_symm_apply, sum_rec_congr _ _ _ (e.symm_apply_apply (inl i)), cast_cast, cast_eq] theorem piCongrLeft_sumInr {ι ι' ι''} (π : ι'' → Type) (e : ι ⊕ ι' ≃ ι'') (f : ∀ i, π (e (inl i))) (g : ∀ i, π (e (inr i))) (j : ι') : piCongrLeft π e (sumPiEquivProdPi (fun x => π (e x)) \|>.symm (f, g)) (e (inr j)) = g j := by simp_rw [piCongrLeft_apply_eq_cast, sumPiEquivProdPi_symm_apply, sum_rec_congr _ _ _ (e.symm_apply_apply (inr j)), cast_cast, cast_eq] @[deprecated (since := "2025-02-21")] alias piCongrLeft_sum_inl := piCongrLeft_sumInl @[deprecated (since := "2025-02-21")] alias piCongrLeft_sum_inr := piCongrLeft_sumInr end section variable {W : α → Sort w} {Z : β → Sort z} (h₁ : α ≃ β) (h₂ : ∀ a : α, W a ≃ Z (h₁ a)) /-- Transport dependent functions through an equivalence of the base spaces and a family of equivalences of the matching fibers. -/ def piCongr : (∀ a, W a) ≃ ∀ b, Z b := (Equiv.piCongrRight h₂).trans (Equiv.piCongrLeft _ h₁) @[simp] theorem coe_piCongr_symm : ((h₁.piCongr h₂).symm : (∀ b, Z b) → ∀ a, W a) = fun f a => (h₂ a).symm (f (h₁ a)) := rfl theorem piCongr_symm_apply (f : ∀ b, Z b) : (h₁.piCongr h₂).symm f = fun a => (h₂ a).symm (f (h₁ a)) := rfl @[simp] theorem piCongr_apply_apply (f : ∀ a, W a) (a : α) : h₁.piCongr h₂ f (h₁ a) = h₂ a (f a) := by simp only [piCongr, piCongrRight, trans_apply, coe_fn_mk, piCongrLeft_apply_apply, Pi.map_apply] end section variable {W : α → Sort w} {Z : β → Sort z} (h₁ : α ≃ β) (h₂ : ∀ b : β, W (h₁.symm b) ≃ Z b) /-- Transport dependent functions through an equivalence of the base spaces and a family of equivalences of the matching fibres. -/ def piCongr' : (∀ a, W a) ≃ ∀ b, Z b := (piCongr h₁.symm fun b => (h₂ b).symm).symm @[simp] theorem coe_piCongr' : (h₁.piCongr' h₂ : (∀ a, W a) → ∀ b, Z b) = fun f b => h₂ b <\| f <\| h₁.symm b := rfl theorem piCongr'_apply (f : ∀ a, W a) : h₁.piCongr' h₂ f = fun b => h₂ b <\| f <\| h₁.symm b := rfl @[simp] theorem piCongr'_symm_apply_symm_apply (f : ∀ b, Z b) (b : β) : (h₁.piCongr' h₂).symm f (h₁.symm b) = (h₂ b).symm (f b) := by simp [piCongr', piCongr_apply_apply] end /-- Transport dependent functions through an equality of sets. -/ @[simps!] def piCongrSet {α} {W : α → Sort w} {s t : Set α} (h : s = t) : (∀ i : {i // i ∈ s}, W i) ≃ (∀ i : {i // i ∈ t}, W i) where toFun f i := f ⟨i, h ▸ i.2⟩ invFun f i := f ⟨i, h.symm ▸ i.2⟩ left_inv f := rfl right_inv f := rfl section BinaryOp variable {α₁ β₁ : Type} (e : α₁ ≃ β₁) (f : α₁ → α₁ → α₁) theorem semiconj_conj (f : α₁ → α₁) : Semiconj e f (e.conj f) := fun x => by simp theorem semiconj₂_conj : Semiconj₂ e f (e.arrowCongr e.conj f) := fun x y => by simp [arrowCongr] instance [Std.Associative f] : Std.Associative (e.arrowCongr (e.arrowCongr e) f) := (e.semiconj₂_conj f).isAssociative_right e.surjective instance [Std.IdempotentOp f] : Std.IdempotentOp (e.arrowCongr (e.arrowCongr e) f) := (e.semiconj₂_conj f).isIdempotent_right e.surjective end BinaryOp section ULift @[simp] theorem ulift_symm_down {α} (x : α) : (Equiv.ulift.{u, v}.symm x).down = x := rfl end ULift end Equiv theorem Function.Injective.swap_apply [DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y z : α) : Equiv.swap (f x) (f y) (f z) = f (Equiv.swap x y z) := by by_cases hx : z = x · simp [hx] by_cases hy : z = y · simp [hy] rw [Equiv.swap_apply_of_ne_of_ne hx hy, Equiv.swap_apply_of_ne_of_ne (hf.ne hx) (hf.ne hy)] theorem Function.Injective.swap_comp [DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y : α) : Equiv.swap (f x) (f y) ∘ f = f ∘ Equiv.swap x y := funext fun _ => hf.swap_apply _ _ _ /-- To give an equivalence between two subsingleton types, it is sufficient to give any two functions between them. -/ def equivOfSubsingletonOfSubsingleton [Subsingleton α] [Subsingleton β] (f : α → β) (g : β → α) : α ≃ β where toFun := f invFun := g left_inv _ := Subsingleton.elim _ _ right_inv _ := Subsingleton.elim _ _ /-- A nonempty subsingleton type is (noncomputably) equivalent to `PUnit`. -/ noncomputable def Equiv.punitOfNonemptyOfSubsingleton [h : Nonempty α] [Subsingleton α] : α ≃ PUnit := equivOfSubsingletonOfSubsingleton (fun _ => PUnit.unit) fun _ => h.some /-- `Unique (Unique α)` is equivalent to `Unique α`. -/ def uniqueUniqueEquiv : Unique (Unique α) ≃ Unique α := equivOfSubsingletonOfSubsingleton (fun h => h.default) fun h => { default := h, uniq := fun _ => Subsingleton.elim _ _ } /-- If `Unique β`, then `Unique α` is equivalent to `α ≃ β`. -/ def uniqueEquivEquivUnique (α : Sort u) (β : Sort v) [Unique β] : Unique α ≃ (α ≃ β) := equivOfSubsingletonOfSubsingleton (fun _ => Equiv.ofUnique _ _) Equiv.unique namespace Function variable {α' : Sort} theorem update_comp_equiv [DecidableEq α'] [DecidableEq α] (f : α → β) (g : α' ≃ α) (a : α) (v : β) : update f a v ∘ g = update (f ∘ g) (g.symm a) v := by rw [← update_comp_eq_of_injective _ g.injective, g.apply_symm_apply] theorem update_apply_equiv_apply [DecidableEq α'] [DecidableEq α] (f : α → β) (g : α' ≃ α) (a : α) (v : β) (a' : α') : update f a v (g a') = update (f ∘ g) (g.symm a) v a' := congr_fun (update_comp_equiv f g a v) a' theorem piCongrLeft'_update [DecidableEq α] [DecidableEq β] (P : α → Sort) (e : α ≃ β) (f : ∀ a, P a) (b : β) (x : P (e.symm b)) : e.piCongrLeft' P (update f (e.symm b) x) = update (e.piCongrLeft' P f) b x := by ext b' rcases eq_or_ne b' b with (rfl \| h) <;> simp_all theorem piCongrLeft'_symm_update [DecidableEq α] [DecidableEq β] (P : α → Sort*) (e : α ≃ β) (f : ∀ b, P (e.symm b)) (b : β) (x : P (e.symm b)) : (e.piCongrLeft' P).symm (update f b x) = update ((e.piCongrLeft' P).symm f) (e.symm b) x := by simp [(e.piCongrLeft' P).symm_apply_eq, piCongrLeft'_update] end Function		Mathlib/Logic/Equiv/Basic.lean	1,744	1,751
/- Copyright (c) 2019 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel -/ import Mathlib.Analysis.Analytic.Within import Mathlib.Analysis.Calculus.FDeriv.Analytic import Mathlib.Analysis.Calculus.ContDiff.FTaylorSeries /-! # Higher differentiability A function is `C^1` on a domain if it is differentiable there, and its derivative is continuous. By induction, it is `C^n` if it is `C^{n-1}` and its (n-1)-th derivative is `C^1` there or, equivalently, if it is `C^1` and its derivative is `C^{n-1}`. It is `C^∞` if it is `C^n` for all n. Finally, it is `C^ω` if it is analytic (as well as all its derivative, which is automatic if the space is complete). We formalize these notions with predicates `ContDiffWithinAt`, `ContDiffAt`, `ContDiffOn` and `ContDiff` saying that the function is `C^n` within a set at a point, at a point, on a set and on the whole space respectively. To avoid the issue of choice when choosing a derivative in sets where the derivative is not necessarily unique, `ContDiffOn` is not defined directly in terms of the regularity of the specific choice `iteratedFDerivWithin 𝕜 n f s` inside `s`, but in terms of the existence of a nice sequence of derivatives, expressed with a predicate `HasFTaylorSeriesUpToOn` defined in the file `FTaylorSeries`. We prove basic properties of these notions. ## Main definitions and results Let `f : E → F` be a map between normed vector spaces over a nontrivially normed field `𝕜`. * `ContDiff 𝕜 n f`: expresses that `f` is `C^n`, i.e., it admits a Taylor series up to rank `n`. * `ContDiffOn 𝕜 n f s`: expresses that `f` is `C^n` in `s`. * `ContDiffAt 𝕜 n f x`: expresses that `f` is `C^n` around `x`. * `ContDiffWithinAt 𝕜 n f s x`: expresses that `f` is `C^n` around `x` within the set `s`. In sets of unique differentiability, `ContDiffOn 𝕜 n f s` can be expressed in terms of the properties of `iteratedFDerivWithin 𝕜 m f s` for `m ≤ n`. In the whole space, `ContDiff 𝕜 n f` can be expressed in terms of the properties of `iteratedFDeriv 𝕜 m f` for `m ≤ n`. ## Implementation notes The definitions in this file are designed to work on any field `𝕜`. They are sometimes slightly more complicated than the naive definitions one would guess from the intuition over the real or complex numbers, but they are designed to circumvent the lack of gluing properties and partitions of unity in general. In the usual situations, they coincide with the usual definitions. ### Definition of `C^n` functions in domains One could define `C^n` functions in a domain `s` by fixing an arbitrary choice of derivatives (this is what we do with `iteratedFDerivWithin`) and requiring that all these derivatives up to `n` are continuous. If the derivative is not unique, this could lead to strange behavior like two `C^n` functions `f` and `g` on `s` whose sum is not `C^n`. A better definition is thus to say that a function is `C^n` inside `s` if it admits a sequence of derivatives up to `n` inside `s`. This definition still has the problem that a function which is locally `C^n` would not need to be `C^n`, as different choices of sequences of derivatives around different points might possibly not be glued together to give a globally defined sequence of derivatives. (Note that this issue can not happen over reals, thanks to partition of unity, but the behavior over a general field is not so clear, and we want a definition for general fields). Also, there are locality problems for the order parameter: one could image a function which, for each `n`, has a nice sequence of derivatives up to order `n`, but they do not coincide for varying `n` and can therefore not be glued to give rise to an infinite sequence of derivatives. This would give a function which is `C^n` for all `n`, but not `C^∞`. We solve this issue by putting locality conditions in space and order in our definition of `ContDiffWithinAt` and `ContDiffOn`. The resulting definition is slightly more complicated to work with (in fact not so much), but it gives rise to completely satisfactory theorems. For instance, with this definition, a real function which is `C^m` (but not better) on `(-1/m, 1/m)` for each natural `m` is by definition `C^∞` at `0`. There is another issue with the definition of `ContDiffWithinAt 𝕜 n f s x`. We can require the existence and good behavior of derivatives up to order `n` on a neighborhood of `x` within `s`. However, this does not imply continuity or differentiability within `s` of the function at `x` when `x` does not belong to `s`. Therefore, we require such existence and good behavior on a neighborhood of `x` within `s ∪ {x}` (which appears as `insert x s` in this file). ## Notations We use the notation `E [×n]→L[𝕜] F` for the space of continuous multilinear maps on `E^n` with values in `F`. This is the space in which the `n`-th derivative of a function from `E` to `F` lives. In this file, we denote `(⊤ : ℕ∞) : WithTop ℕ∞` with `∞`, and `⊤ : WithTop ℕ∞` with `ω`. To avoid ambiguities with the two tops, the theorems name use either `infty` or `omega`. These notations are scoped in `ContDiff`. ## Tags derivative, differentiability, higher derivative, `C^n`, multilinear, Taylor series, formal series -/ noncomputable section open Set Fin Filter Function open scoped NNReal Topology ContDiff universe u uE uF uG uX variable {𝕜 : Type u} [NontriviallyNormedField 𝕜] {E : Type uE} [NormedAddCommGroup E] [NormedSpace 𝕜 E] {F : Type uF} [NormedAddCommGroup F] [NormedSpace 𝕜 F] {G : Type uG} [NormedAddCommGroup G] [NormedSpace 𝕜 G] {X : Type uX} [NormedAddCommGroup X] [NormedSpace 𝕜 X] {s s₁ t u : Set E} {f f₁ : E → F} {g : F → G} {x x₀ : E} {c : F} {m n : WithTop ℕ∞} {p : E → FormalMultilinearSeries 𝕜 E F} /-! ### Smooth functions within a set around a point -/ variable (𝕜) in /-- A function is continuously differentiable up to order `n` within a set `s` at a point `x` if it admits continuous derivatives up to order `n` in a neighborhood of `x` in `s ∪ {x}`. For `n = ∞`, we only require that this holds up to any finite order (where the neighborhood may depend on the finite order we consider). For `n = ω`, we require the function to be analytic within `s` at `x`. The precise definition we give (all the derivatives should be analytic) is more involved to work around issues when the space is not complete, but it is equivalent when the space is complete. For instance, a real function which is `C^m` on `(-1/m, 1/m)` for each natural `m`, but not better, is `C^∞` at `0` within `univ`. -/ def ContDiffWithinAt (n : WithTop ℕ∞) (f : E → F) (s : Set E) (x : E) : Prop := match n with \| ω => ∃ u ∈ 𝓝[insert x s] x, ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn ω f p u ∧ ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u \| (n : ℕ∞) => ∀ m : ℕ, m ≤ n → ∃ u ∈ 𝓝[insert x s] x, ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn m f p u lemma HasFTaylorSeriesUpToOn.analyticOn (hf : HasFTaylorSeriesUpToOn ω f p s) (h : AnalyticOn 𝕜 (fun x ↦ p x 0) s) : AnalyticOn 𝕜 f s := by have : AnalyticOn 𝕜 (fun x ↦ (continuousMultilinearCurryFin0 𝕜 E F) (p x 0)) s := (LinearIsometryEquiv.analyticOnNhd _ _ ).comp_analyticOn h (Set.mapsTo_univ _ _) exact this.congr (fun y hy ↦ (hf.zero_eq _ hy).symm) lemma ContDiffWithinAt.analyticOn (h : ContDiffWithinAt 𝕜 ω f s x) : ∃ u ∈ 𝓝[insert x s] x, AnalyticOn 𝕜 f u := by obtain ⟨u, hu, p, hp, h'p⟩ := h exact ⟨u, hu, hp.analyticOn (h'p 0)⟩ lemma ContDiffWithinAt.analyticWithinAt (h : ContDiffWithinAt 𝕜 ω f s x) : AnalyticWithinAt 𝕜 f s x := by obtain ⟨u, hu, hf⟩ := h.analyticOn have xu : x ∈ u := mem_of_mem_nhdsWithin (by simp) hu exact (hf x xu).mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert _ _) hu) theorem contDiffWithinAt_omega_iff_analyticWithinAt [CompleteSpace F] : ContDiffWithinAt 𝕜 ω f s x ↔ AnalyticWithinAt 𝕜 f s x := by refine ⟨fun h ↦ h.analyticWithinAt, fun h ↦ ?_⟩ obtain ⟨u, hu, p, hp, h'p⟩ := h.exists_hasFTaylorSeriesUpToOn ω exact ⟨u, hu, p, hp.of_le le_top, fun i ↦ h'p i⟩ theorem contDiffWithinAt_nat {n : ℕ} : ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x, ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u := ⟨fun H => H n le_rfl, fun ⟨u, hu, p, hp⟩ _m hm => ⟨u, hu, p, hp.of_le (mod_cast hm)⟩⟩ /-- When `n` is either a natural number or `ω`, one can characterize the property of being `C^n` as the existence of a neighborhood on which there is a Taylor series up to order `n`, requiring in addition that its terms are analytic in the `ω` case. -/ lemma contDiffWithinAt_iff_of_ne_infty (hn : n ≠ ∞) : ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x, ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u ∧ (n = ω → ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u) := by match n with \| ω => simp [ContDiffWithinAt] \| ∞ => simp at hn \| (n : ℕ) => simp [contDiffWithinAt_nat] theorem ContDiffWithinAt.of_le (h : ContDiffWithinAt 𝕜 n f s x) (hmn : m ≤ n) : ContDiffWithinAt 𝕜 m f s x := by match n with \| ω => match m with \| ω => exact h \| (m : ℕ∞) => intro k _ obtain ⟨u, hu, p, hp, -⟩ := h exact ⟨u, hu, p, hp.of_le le_top⟩ \| (n : ℕ∞) => match m with \| ω => simp at hmn \| (m : ℕ∞) => exact fun k hk ↦ h k (le_trans hk (mod_cast hmn)) /-- In a complete space, a function which is analytic within a set at a point is also `C^ω` there. Note that the same statement for `AnalyticOn` does not require completeness, see `AnalyticOn.contDiffOn`. -/ theorem AnalyticWithinAt.contDiffWithinAt [CompleteSpace F] (h : AnalyticWithinAt 𝕜 f s x) : ContDiffWithinAt 𝕜 n f s x := (contDiffWithinAt_omega_iff_analyticWithinAt.2 h).of_le le_top theorem contDiffWithinAt_iff_forall_nat_le {n : ℕ∞} : ContDiffWithinAt 𝕜 n f s x ↔ ∀ m : ℕ, ↑m ≤ n → ContDiffWithinAt 𝕜 m f s x := ⟨fun H _ hm => H.of_le (mod_cast hm), fun H m hm => H m hm _ le_rfl⟩ theorem contDiffWithinAt_infty : ContDiffWithinAt 𝕜 ∞ f s x ↔ ∀ n : ℕ, ContDiffWithinAt 𝕜 n f s x := contDiffWithinAt_iff_forall_nat_le.trans <\| by simp only [forall_prop_of_true, le_top] @[deprecated (since := "2024-11-25")] alias contDiffWithinAt_top := contDiffWithinAt_infty theorem ContDiffWithinAt.continuousWithinAt (h : ContDiffWithinAt 𝕜 n f s x) : ContinuousWithinAt f s x := by have := h.of_le (zero_le _) simp only [ContDiffWithinAt, nonpos_iff_eq_zero, Nat.cast_eq_zero, mem_pure, forall_eq, CharP.cast_eq_zero] at this rcases this with ⟨u, hu, p, H⟩ rw [mem_nhdsWithin_insert] at hu exact (H.continuousOn.continuousWithinAt hu.1).mono_of_mem_nhdsWithin hu.2 theorem ContDiffWithinAt.congr_of_eventuallyEq (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x := by match n with \| ω => obtain ⟨u, hu, p, H, H'⟩ := h exact ⟨{x ∈ u \| f₁ x = f x}, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p, (H.mono (sep_subset _ _)).congr fun _ ↦ And.right, fun i ↦ (H' i).mono (sep_subset _ _)⟩ \| (n : ℕ∞) => intro m hm let ⟨u, hu, p, H⟩ := h m hm exact ⟨{ x ∈ u \| f₁ x = f x }, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p, (H.mono (sep_subset _ _)).congr fun _ ↦ And.right⟩ theorem Filter.EventuallyEq.congr_contDiffWithinAt (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x := ⟨fun H ↦ H.congr_of_eventuallyEq h₁.symm hx.symm, fun H ↦ H.congr_of_eventuallyEq h₁ hx⟩ theorem ContDiffWithinAt.congr_of_eventuallyEq_insert (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) : ContDiffWithinAt 𝕜 n f₁ s x := h.congr_of_eventuallyEq (nhdsWithin_mono x (subset_insert x s) h₁) (mem_of_mem_nhdsWithin (mem_insert x s) h₁ :) theorem Filter.EventuallyEq.congr_contDiffWithinAt_of_insert (h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) : ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x := ⟨fun H ↦ H.congr_of_eventuallyEq_insert h₁.symm, fun H ↦ H.congr_of_eventuallyEq_insert h₁⟩ theorem ContDiffWithinAt.congr_of_eventuallyEq_of_mem (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : x ∈ s) : ContDiffWithinAt 𝕜 n f₁ s x := h.congr_of_eventuallyEq h₁ <\| h₁.self_of_nhdsWithin hx theorem Filter.EventuallyEq.congr_contDiffWithinAt_of_mem (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : x ∈ s): ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x := ⟨fun H ↦ H.congr_of_eventuallyEq_of_mem h₁.symm hx, fun H ↦ H.congr_of_eventuallyEq_of_mem h₁ hx⟩ theorem ContDiffWithinAt.congr (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x := h.congr_of_eventuallyEq (Filter.eventuallyEq_of_mem self_mem_nhdsWithin h₁) hx theorem contDiffWithinAt_congr (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x := ⟨fun h' ↦ h'.congr (fun x hx ↦ (h₁ x hx).symm) hx.symm, fun h' ↦ h'.congr h₁ hx⟩ theorem ContDiffWithinAt.congr_of_mem (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : x ∈ s) : ContDiffWithinAt 𝕜 n f₁ s x := h.congr h₁ (h₁ _ hx) theorem contDiffWithinAt_congr_of_mem (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : x ∈ s) : ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x := contDiffWithinAt_congr h₁ (h₁ x hx) theorem ContDiffWithinAt.congr_of_insert (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : ∀ y ∈ insert x s, f₁ y = f y) : ContDiffWithinAt 𝕜 n f₁ s x := h.congr (fun y hy ↦ h₁ y (mem_insert_of_mem _ hy)) (h₁ x (mem_insert _ _)) theorem contDiffWithinAt_congr_of_insert (h₁ : ∀ y ∈ insert x s, f₁ y = f y) : ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x := contDiffWithinAt_congr (fun y hy ↦ h₁ y (mem_insert_of_mem _ hy)) (h₁ x (mem_insert _ _)) theorem ContDiffWithinAt.mono_of_mem_nhdsWithin (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E} (hst : s ∈ 𝓝[t] x) : ContDiffWithinAt 𝕜 n f t x := by match n with \| ω => obtain ⟨u, hu, p, H, H'⟩ := h exact ⟨u, nhdsWithin_le_of_mem (insert_mem_nhdsWithin_insert hst) hu, p, H, H'⟩ \| (n : ℕ∞) => intro m hm rcases h m hm with ⟨u, hu, p, H⟩ exact ⟨u, nhdsWithin_le_of_mem (insert_mem_nhdsWithin_insert hst) hu, p, H⟩ @[deprecated (since := "2024-10-30")] alias ContDiffWithinAt.mono_of_mem := ContDiffWithinAt.mono_of_mem_nhdsWithin theorem ContDiffWithinAt.mono (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E} (hst : t ⊆ s) : ContDiffWithinAt 𝕜 n f t x := h.mono_of_mem_nhdsWithin <\| Filter.mem_of_superset self_mem_nhdsWithin hst theorem ContDiffWithinAt.congr_mono (h : ContDiffWithinAt 𝕜 n f s x) (h' : EqOn f₁ f s₁) (h₁ : s₁ ⊆ s) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s₁ x := (h.mono h₁).congr h' hx theorem ContDiffWithinAt.congr_set (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E} (hst : s =ᶠ[𝓝 x] t) : ContDiffWithinAt 𝕜 n f t x := by rw [← nhdsWithin_eq_iff_eventuallyEq] at hst apply h.mono_of_mem_nhdsWithin <\| hst ▸ self_mem_nhdsWithin @[deprecated (since := "2024-10-23")] alias ContDiffWithinAt.congr_nhds := ContDiffWithinAt.congr_set theorem contDiffWithinAt_congr_set {t : Set E} (hst : s =ᶠ[𝓝 x] t) : ContDiffWithinAt 𝕜 n f s x ↔ ContDiffWithinAt 𝕜 n f t x := ⟨fun h => h.congr_set hst, fun h => h.congr_set hst.symm⟩ @[deprecated (since := "2024-10-23")] alias contDiffWithinAt_congr_nhds := contDiffWithinAt_congr_set theorem contDiffWithinAt_inter' (h : t ∈ 𝓝[s] x) : ContDiffWithinAt 𝕜 n f (s ∩ t) x ↔ ContDiffWithinAt 𝕜 n f s x := contDiffWithinAt_congr_set (mem_nhdsWithin_iff_eventuallyEq.1 h).symm theorem contDiffWithinAt_inter (h : t ∈ 𝓝 x) : ContDiffWithinAt 𝕜 n f (s ∩ t) x ↔ ContDiffWithinAt 𝕜 n f s x := contDiffWithinAt_inter' (mem_nhdsWithin_of_mem_nhds h) theorem contDiffWithinAt_insert_self : ContDiffWithinAt 𝕜 n f (insert x s) x ↔ ContDiffWithinAt 𝕜 n f s x := by match n with \| ω => simp [ContDiffWithinAt] \| (n : ℕ∞) => simp_rw [ContDiffWithinAt, insert_idem] theorem contDiffWithinAt_insert {y : E} : ContDiffWithinAt 𝕜 n f (insert y s) x ↔ ContDiffWithinAt 𝕜 n f s x := by rcases eq_or_ne x y with (rfl \| hx) · exact contDiffWithinAt_insert_self refine ⟨fun h ↦ h.mono (subset_insert _ _), fun h ↦ ?_⟩ apply h.mono_of_mem_nhdsWithin simp [nhdsWithin_insert_of_ne hx, self_mem_nhdsWithin] alias ⟨ContDiffWithinAt.of_insert, ContDiffWithinAt.insert'⟩ := contDiffWithinAt_insert protected theorem ContDiffWithinAt.insert (h : ContDiffWithinAt 𝕜 n f s x) : ContDiffWithinAt 𝕜 n f (insert x s) x := h.insert' theorem contDiffWithinAt_diff_singleton {y : E} : ContDiffWithinAt 𝕜 n f (s \ {y}) x ↔ ContDiffWithinAt 𝕜 n f s x := by rw [← contDiffWithinAt_insert, insert_diff_singleton, contDiffWithinAt_insert] /-- If a function is `C^n` within a set at a point, with `n ≥ 1`, then it is differentiable within this set at this point. -/ theorem ContDiffWithinAt.differentiableWithinAt' (h : ContDiffWithinAt 𝕜 n f s x) (hn : 1 ≤ n) : DifferentiableWithinAt 𝕜 f (insert x s) x := by rcases contDiffWithinAt_nat.1 (h.of_le hn) with ⟨u, hu, p, H⟩ rcases mem_nhdsWithin.1 hu with ⟨t, t_open, xt, tu⟩ rw [inter_comm] at tu exact (differentiableWithinAt_inter (IsOpen.mem_nhds t_open xt)).1 <\| ((H.mono tu).differentiableOn le_rfl) x ⟨mem_insert x s, xt⟩ theorem ContDiffWithinAt.differentiableWithinAt (h : ContDiffWithinAt 𝕜 n f s x) (hn : 1 ≤ n) : DifferentiableWithinAt 𝕜 f s x := (h.differentiableWithinAt' hn).mono (subset_insert x s) /-- A function is `C^(n + 1)` on a domain iff locally, it has a derivative which is `C^n` (and moreover the function is analytic when `n = ω`). -/ theorem contDiffWithinAt_succ_iff_hasFDerivWithinAt (hn : n ≠ ∞) : ContDiffWithinAt 𝕜 (n + 1) f s x ↔ ∃ u ∈ 𝓝[insert x s] x, (n = ω → AnalyticOn 𝕜 f u) ∧ ∃ f' : E → E →L[𝕜] F, (∀ x ∈ u, HasFDerivWithinAt f (f' x) u x) ∧ ContDiffWithinAt 𝕜 n f' u x := by have h'n : n + 1 ≠ ∞ := by simpa using hn constructor · intro h rcases (contDiffWithinAt_iff_of_ne_infty h'n).1 h with ⟨u, hu, p, Hp, H'p⟩ refine ⟨u, hu, ?_, fun y => (continuousMultilinearCurryFin1 𝕜 E F) (p y 1), fun y hy => Hp.hasFDerivWithinAt le_add_self hy, ?_⟩ · rintro rfl exact Hp.analyticOn (H'p rfl 0) apply (contDiffWithinAt_iff_of_ne_infty hn).2 refine ⟨u, ?_, fun y : E => (p y).shift, ?_⟩ · convert @self_mem_nhdsWithin _ _ x u have : x ∈ insert x s := by simp exact insert_eq_of_mem (mem_of_mem_nhdsWithin this hu) · rw [hasFTaylorSeriesUpToOn_succ_iff_right] at Hp refine ⟨Hp.2.2, ?_⟩ rintro rfl i change AnalyticOn 𝕜 (fun x ↦ (continuousMultilinearCurryRightEquiv' 𝕜 i E F) (p x (i + 1))) u apply (LinearIsometryEquiv.analyticOnNhd _ _).comp_analyticOn ?_ (Set.mapsTo_univ _ _) exact H'p rfl _ · rintro ⟨u, hu, hf, f', f'_eq_deriv, Hf'⟩ rw [contDiffWithinAt_iff_of_ne_infty h'n] rcases (contDiffWithinAt_iff_of_ne_infty hn).1 Hf' with ⟨v, hv, p', Hp', p'_an⟩ refine ⟨v ∩ u, ?_, fun x => (p' x).unshift (f x), ?_, ?_⟩ · apply Filter.inter_mem _ hu apply nhdsWithin_le_of_mem hu exact nhdsWithin_mono _ (subset_insert x u) hv · rw [hasFTaylorSeriesUpToOn_succ_iff_right] refine ⟨fun y _ => rfl, fun y hy => ?_, ?_⟩ · change HasFDerivWithinAt (fun z => (continuousMultilinearCurryFin0 𝕜 E F).symm (f z)) (FormalMultilinearSeries.unshift (p' y) (f y) 1).curryLeft (v ∩ u) y rw [← Function.comp_def _ f, LinearIsometryEquiv.comp_hasFDerivWithinAt_iff'] convert (f'_eq_deriv y hy.2).mono inter_subset_right rw [← Hp'.zero_eq y hy.1] ext z change ((p' y 0) (init (@cons 0 (fun _ => E) z 0))) (@cons 0 (fun _ => E) z 0 (last 0)) = ((p' y 0) 0) z congr norm_num [eq_iff_true_of_subsingleton] · convert (Hp'.mono inter_subset_left).congr fun x hx => Hp'.zero_eq x hx.1 using 1 · ext x y change p' x 0 (init (@snoc 0 (fun _ : Fin 1 => E) 0 y)) y = p' x 0 0 y rw [init_snoc] · ext x k v y change p' x k (init (@snoc k (fun _ : Fin k.succ => E) v y)) (@snoc k (fun _ : Fin k.succ => E) v y (last k)) = p' x k v y rw [snoc_last, init_snoc] · intro h i simp only [WithTop.add_eq_top, WithTop.one_ne_top, or_false] at h match i with \| 0 => simp only [FormalMultilinearSeries.unshift] apply AnalyticOnNhd.comp_analyticOn _ ((hf h).mono inter_subset_right) (Set.mapsTo_univ _ _) exact LinearIsometryEquiv.analyticOnNhd _ _ \| i + 1 => simp only [FormalMultilinearSeries.unshift, Nat.succ_eq_add_one] apply AnalyticOnNhd.comp_analyticOn _ ((p'_an h i).mono inter_subset_left) (Set.mapsTo_univ _ _) exact LinearIsometryEquiv.analyticOnNhd _ _ /-- A version of `contDiffWithinAt_succ_iff_hasFDerivWithinAt` where all derivatives are taken within the same set. -/ theorem contDiffWithinAt_succ_iff_hasFDerivWithinAt' (hn : n ≠ ∞) : ContDiffWithinAt 𝕜 (n + 1) f s x ↔ ∃ u ∈ 𝓝[insert x s] x, u ⊆ insert x s ∧ (n = ω → AnalyticOn 𝕜 f u) ∧ ∃ f' : E → E →L[𝕜] F, (∀ x ∈ u, HasFDerivWithinAt f (f' x) s x) ∧ ContDiffWithinAt 𝕜 n f' s x := by refine ⟨fun hf => ?_, ?_⟩ · obtain ⟨u, hu, f_an, f', huf', hf'⟩ := (contDiffWithinAt_succ_iff_hasFDerivWithinAt hn).mp hf obtain ⟨w, hw, hxw, hwu⟩ := mem_nhdsWithin.mp hu rw [inter_comm] at hwu refine ⟨insert x s ∩ w, inter_mem_nhdsWithin _ (hw.mem_nhds hxw), inter_subset_left, ?_, f', fun y hy => ?_, ?_⟩ · intro h apply (f_an h).mono hwu · refine ((huf' y <\| hwu hy).mono hwu).mono_of_mem_nhdsWithin ?_ refine mem_of_superset ?_ (inter_subset_inter_left _ (subset_insert _ _)) exact inter_mem_nhdsWithin _ (hw.mem_nhds hy.2) · exact hf'.mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert _ _) hu) · rw [← contDiffWithinAt_insert, contDiffWithinAt_succ_iff_hasFDerivWithinAt hn, insert_eq_of_mem (mem_insert _ _)] rintro ⟨u, hu, hus, f_an, f', huf', hf'⟩ exact ⟨u, hu, f_an, f', fun y hy => (huf' y hy).insert'.mono hus, hf'.insert.mono hus⟩ /-! ### Smooth functions within a set -/ variable (𝕜) in /-- A function is continuously differentiable up to `n` on `s` if, for any point `x` in `s`, it admits continuous derivatives up to order `n` on a neighborhood of `x` in `s`. For `n = ∞`, we only require that this holds up to any finite order (where the neighborhood may depend on the finite order we consider). -/ def ContDiffOn (n : WithTop ℕ∞) (f : E → F) (s : Set E) : Prop := ∀ x ∈ s, ContDiffWithinAt 𝕜 n f s x theorem HasFTaylorSeriesUpToOn.contDiffOn {n : ℕ∞} {f' : E → FormalMultilinearSeries 𝕜 E F} (hf : HasFTaylorSeriesUpToOn n f f' s) : ContDiffOn 𝕜 n f s := by intro x hx m hm use s simp only [Set.insert_eq_of_mem hx, self_mem_nhdsWithin, true_and] exact ⟨f', hf.of_le (mod_cast hm)⟩ theorem ContDiffOn.contDiffWithinAt (h : ContDiffOn 𝕜 n f s) (hx : x ∈ s) : ContDiffWithinAt 𝕜 n f s x := h x hx theorem ContDiffOn.of_le (h : ContDiffOn 𝕜 n f s) (hmn : m ≤ n) : ContDiffOn 𝕜 m f s := fun x hx => (h x hx).of_le hmn theorem ContDiffWithinAt.contDiffOn' (hm : m ≤ n) (h' : m = ∞ → n = ω) (h : ContDiffWithinAt 𝕜 n f s x) : ∃ u, IsOpen u ∧ x ∈ u ∧ ContDiffOn 𝕜 m f (insert x s ∩ u) := by rcases eq_or_ne n ω with rfl \| hn · obtain ⟨t, ht, p, hp, h'p⟩ := h rcases mem_nhdsWithin.1 ht with ⟨u, huo, hxu, hut⟩ rw [inter_comm] at hut refine ⟨u, huo, hxu, ?_⟩ suffices ContDiffOn 𝕜 ω f (insert x s ∩ u) from this.of_le le_top intro y hy refine ⟨insert x s ∩ u, ?_, p, hp.mono hut, fun i ↦ (h'p i).mono hut⟩ simp only [insert_eq_of_mem, hy, self_mem_nhdsWithin] · match m with \| ω => simp [hn] at hm \| ∞ => exact (hn (h' rfl)).elim \| (m : ℕ) => rcases contDiffWithinAt_nat.1 (h.of_le hm) with ⟨t, ht, p, hp⟩ rcases mem_nhdsWithin.1 ht with ⟨u, huo, hxu, hut⟩ rw [inter_comm] at hut exact ⟨u, huo, hxu, (hp.mono hut).contDiffOn⟩ theorem ContDiffWithinAt.contDiffOn (hm : m ≤ n) (h' : m = ∞ → n = ω) (h : ContDiffWithinAt 𝕜 n f s x) : ∃ u ∈ 𝓝[insert x s] x, u ⊆ insert x s ∧ ContDiffOn 𝕜 m f u := by obtain ⟨_u, uo, xu, h⟩ := h.contDiffOn' hm h' exact ⟨_, inter_mem_nhdsWithin _ (uo.mem_nhds xu), inter_subset_left, h⟩ theorem ContDiffOn.analyticOn (h : ContDiffOn 𝕜 ω f s) : AnalyticOn 𝕜 f s := fun x hx ↦ (h x hx).analyticWithinAt /-- A function is `C^n` within a set at a point, for `n : ℕ`, if and only if it is `C^n` on a neighborhood of this point. -/ theorem contDiffWithinAt_iff_contDiffOn_nhds (hn : n ≠ ∞) : ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x, ContDiffOn 𝕜 n f u := by refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩ · rcases h.contDiffOn le_rfl (by simp [hn]) with ⟨u, hu, h'u⟩ exact ⟨u, hu, h'u.2⟩ · rcases h with ⟨u, u_mem, hu⟩ have : x ∈ u := mem_of_mem_nhdsWithin (mem_insert x s) u_mem exact (hu x this).mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert x s) u_mem) protected theorem ContDiffWithinAt.eventually (h : ContDiffWithinAt 𝕜 n f s x) (hn : n ≠ ∞) : ∀ᶠ y in 𝓝[insert x s] x, ContDiffWithinAt 𝕜 n f s y := by rcases h.contDiffOn le_rfl (by simp [hn]) with ⟨u, hu, _, hd⟩ have : ∀ᶠ y : E in 𝓝[insert x s] x, u ∈ 𝓝[insert x s] y ∧ y ∈ u := (eventually_eventually_nhdsWithin.2 hu).and hu refine this.mono fun y hy => (hd y hy.2).mono_of_mem_nhdsWithin ?_ exact nhdsWithin_mono y (subset_insert _ _) hy.1 theorem ContDiffOn.of_succ (h : ContDiffOn 𝕜 (n + 1) f s) : ContDiffOn 𝕜 n f s := h.of_le le_self_add theorem ContDiffOn.one_of_succ (h : ContDiffOn 𝕜 (n + 1) f s) : ContDiffOn 𝕜 1 f s := h.of_le le_add_self theorem contDiffOn_iff_forall_nat_le {n : ℕ∞} : ContDiffOn 𝕜 n f s ↔ ∀ m : ℕ, ↑m ≤ n → ContDiffOn 𝕜 m f s := ⟨fun H _ hm => H.of_le (mod_cast hm), fun H x hx m hm => H m hm x hx m le_rfl⟩ theorem contDiffOn_infty : ContDiffOn 𝕜 ∞ f s ↔ ∀ n : ℕ, ContDiffOn 𝕜 n f s := contDiffOn_iff_forall_nat_le.trans <\| by simp only [le_top, forall_prop_of_true] @[deprecated (since := "2024-11-27")] alias contDiffOn_top := contDiffOn_infty @[deprecated (since := "2024-11-27")] alias contDiffOn_infty_iff_contDiffOn_omega := contDiffOn_infty theorem contDiffOn_all_iff_nat : (∀ (n : ℕ∞), ContDiffOn 𝕜 n f s) ↔ ∀ n : ℕ, ContDiffOn 𝕜 n f s := by refine ⟨fun H n => H n, ?_⟩ rintro H (_ \| n) exacts [contDiffOn_infty.2 H, H n] theorem ContDiffOn.continuousOn (h : ContDiffOn 𝕜 n f s) : ContinuousOn f s := fun x hx => (h x hx).continuousWithinAt theorem ContDiffOn.congr (h : ContDiffOn 𝕜 n f s) (h₁ : ∀ x ∈ s, f₁ x = f x) : ContDiffOn 𝕜 n f₁ s := fun x hx => (h x hx).congr h₁ (h₁ x hx) theorem contDiffOn_congr (h₁ : ∀ x ∈ s, f₁ x = f x) : ContDiffOn 𝕜 n f₁ s ↔ ContDiffOn 𝕜 n f s := ⟨fun H => H.congr fun x hx => (h₁ x hx).symm, fun H => H.congr h₁⟩ theorem ContDiffOn.mono (h : ContDiffOn 𝕜 n f s) {t : Set E} (hst : t ⊆ s) : ContDiffOn 𝕜 n f t := fun x hx => (h x (hst hx)).mono hst theorem ContDiffOn.congr_mono (hf : ContDiffOn 𝕜 n f s) (h₁ : ∀ x ∈ s₁, f₁ x = f x) (hs : s₁ ⊆ s) : ContDiffOn 𝕜 n f₁ s₁ := (hf.mono hs).congr h₁ /-- If a function is `C^n` on a set with `n ≥ 1`, then it is differentiable there. -/ theorem ContDiffOn.differentiableOn (h : ContDiffOn 𝕜 n f s) (hn : 1 ≤ n) : DifferentiableOn 𝕜 f s := fun x hx => (h x hx).differentiableWithinAt hn /-- If a function is `C^n` around each point in a set, then it is `C^n` on the set. -/ theorem contDiffOn_of_locally_contDiffOn (h : ∀ x ∈ s, ∃ u, IsOpen u ∧ x ∈ u ∧ ContDiffOn 𝕜 n f (s ∩ u)) : ContDiffOn 𝕜 n f s := by intro x xs rcases h x xs with ⟨u, u_open, xu, hu⟩ apply (contDiffWithinAt_inter _).1 (hu x ⟨xs, xu⟩) exact IsOpen.mem_nhds u_open xu /-- A function is `C^(n + 1)` on a domain iff locally, it has a derivative which is `C^n`. -/ theorem contDiffOn_succ_iff_hasFDerivWithinAt (hn : n ≠ ∞) : ContDiffOn 𝕜 (n + 1) f s ↔ ∀ x ∈ s, ∃ u ∈ 𝓝[insert x s] x, (n = ω → AnalyticOn 𝕜 f u) ∧ ∃ f' : E → E →L[𝕜] F, (∀ x ∈ u, HasFDerivWithinAt f (f' x) u x) ∧ ContDiffOn 𝕜 n f' u := by constructor · intro h x hx rcases (contDiffWithinAt_succ_iff_hasFDerivWithinAt hn).1 (h x hx) with ⟨u, hu, f_an, f', hf', Hf'⟩ rcases Hf'.contDiffOn le_rfl (by simp [hn]) with ⟨v, vu, v'u, hv⟩ rw [insert_eq_of_mem hx] at hu ⊢ have xu : x ∈ u := mem_of_mem_nhdsWithin hx hu rw [insert_eq_of_mem xu] at vu v'u exact ⟨v, nhdsWithin_le_of_mem hu vu, fun h ↦ (f_an h).mono v'u, f', fun y hy ↦ (hf' y (v'u hy)).mono v'u, hv⟩ · intro h x hx rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt hn] rcases h x hx with ⟨u, u_nhbd, f_an, f', hu, hf'⟩ have : x ∈ u := mem_of_mem_nhdsWithin (mem_insert _ _) u_nhbd exact ⟨u, u_nhbd, f_an, f', hu, hf' x this⟩ /-! ### Iterated derivative within a set -/ @[simp] theorem contDiffOn_zero : ContDiffOn 𝕜 0 f s ↔ ContinuousOn f s := by refine ⟨fun H => H.continuousOn, fun H => fun x hx m hm ↦ ?_⟩ have : (m : WithTop ℕ∞) = 0 := le_antisymm (mod_cast hm) bot_le rw [this] refine ⟨insert x s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_⟩ rw [hasFTaylorSeriesUpToOn_zero_iff] exact ⟨by rwa [insert_eq_of_mem hx], fun x _ => by simp [ftaylorSeriesWithin]⟩ theorem contDiffWithinAt_zero (hx : x ∈ s) : ContDiffWithinAt 𝕜 0 f s x ↔ ∃ u ∈ 𝓝[s] x, ContinuousOn f (s ∩ u) := by constructor · intro h obtain ⟨u, H, p, hp⟩ := h 0 le_rfl refine ⟨u, ?_, ?_⟩ · simpa [hx] using H · simp only [Nat.cast_zero, hasFTaylorSeriesUpToOn_zero_iff] at hp exact hp.1.mono inter_subset_right · rintro ⟨u, H, hu⟩ rw [← contDiffWithinAt_inter' H] have h' : x ∈ s ∩ u := ⟨hx, mem_of_mem_nhdsWithin hx H⟩ exact (contDiffOn_zero.mpr hu).contDiffWithinAt h' /-- When a function is `C^n` in a set `s` of unique differentiability, it admits `ftaylorSeriesWithin 𝕜 f s` as a Taylor series up to order `n` in `s`. -/ protected theorem ContDiffOn.ftaylorSeriesWithin (h : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s) : HasFTaylorSeriesUpToOn n f (ftaylorSeriesWithin 𝕜 f s) s := by constructor · intro x _ simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply, iteratedFDerivWithin_zero_apply] · intro m hm x hx have : (m + 1 : ℕ) ≤ n := ENat.add_one_natCast_le_withTop_of_lt hm rcases (h x hx).of_le this _ le_rfl with ⟨u, hu, p, Hp⟩ rw [insert_eq_of_mem hx] at hu rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩ rw [inter_comm] at ho have : p x m.succ = ftaylorSeriesWithin 𝕜 f s x m.succ := by change p x m.succ = iteratedFDerivWithin 𝕜 m.succ f s x rw [← iteratedFDerivWithin_inter_open o_open xo] exact (Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl (hs.inter o_open) ⟨hx, xo⟩ rw [← this, ← hasFDerivWithinAt_inter (IsOpen.mem_nhds o_open xo)] have A : ∀ y ∈ s ∩ o, p y m = ftaylorSeriesWithin 𝕜 f s y m := by rintro y ⟨hy, yo⟩ change p y m = iteratedFDerivWithin 𝕜 m f s y rw [← iteratedFDerivWithin_inter_open o_open yo] exact (Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn (mod_cast Nat.le_succ m) (hs.inter o_open) ⟨hy, yo⟩ exact ((Hp.mono ho).fderivWithin m (mod_cast lt_add_one m) x ⟨hx, xo⟩).congr (fun y hy => (A y hy).symm) (A x ⟨hx, xo⟩).symm · intro m hm apply continuousOn_of_locally_continuousOn intro x hx rcases (h x hx).of_le hm _ le_rfl with ⟨u, hu, p, Hp⟩ rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩ rw [insert_eq_of_mem hx] at ho rw [inter_comm] at ho refine ⟨o, o_open, xo, ?_⟩ have A : ∀ y ∈ s ∩ o, p y m = ftaylorSeriesWithin 𝕜 f s y m := by rintro y ⟨hy, yo⟩ change p y m = iteratedFDerivWithin 𝕜 m f s y rw [← iteratedFDerivWithin_inter_open o_open yo] exact (Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl (hs.inter o_open) ⟨hy, yo⟩ exact ((Hp.mono ho).cont m le_rfl).congr fun y hy => (A y hy).symm theorem iteratedFDerivWithin_subset {n : ℕ} (st : s ⊆ t) (hs : UniqueDiffOn 𝕜 s) (ht : UniqueDiffOn 𝕜 t) (h : ContDiffOn 𝕜 n f t) (hx : x ∈ s) : iteratedFDerivWithin 𝕜 n f s x = iteratedFDerivWithin 𝕜 n f t x := (((h.ftaylorSeriesWithin ht).mono st).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl hs hx).symm theorem ContDiffWithinAt.eventually_hasFTaylorSeriesUpToOn {f : E → F} {s : Set E} {a : E} (h : ContDiffWithinAt 𝕜 n f s a) (hs : UniqueDiffOn 𝕜 s) (ha : a ∈ s) {m : ℕ} (hm : m ≤ n) : ∀ᶠ t in (𝓝[s] a).smallSets, HasFTaylorSeriesUpToOn m f (ftaylorSeriesWithin 𝕜 f s) t := by rcases h.contDiffOn' hm (by simp) with ⟨U, hUo, haU, hfU⟩ have : ∀ᶠ t in (𝓝[s] a).smallSets, t ⊆ s ∩ U := by rw [eventually_smallSets_subset] exact inter_mem_nhdsWithin _ <\| hUo.mem_nhds haU refine this.mono fun t ht ↦ .mono ?_ ht rw [insert_eq_of_mem ha] at hfU refine (hfU.ftaylorSeriesWithin (hs.inter hUo)).congr_series fun k hk x hx ↦ ?_ exact iteratedFDerivWithin_inter_open hUo hx.2 /-- On a set with unique differentiability, an analytic function is automatically `C^ω`, as its successive derivatives are also analytic. This does not require completeness of the space. See also `AnalyticOn.contDiffOn_of_completeSpace`. -/ theorem AnalyticOn.contDiffOn (h : AnalyticOn 𝕜 f s) (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 n f s := by suffices ContDiffOn 𝕜 ω f s from this.of_le le_top rcases h.exists_hasFTaylorSeriesUpToOn hs with ⟨p, hp⟩ intro x hx refine ⟨s, ?_, p, hp⟩ rw [insert_eq_of_mem hx] exact self_mem_nhdsWithin /-- On a set with unique differentiability, an analytic function is automatically `C^ω`, as its successive derivatives are also analytic. This does not require completeness of the space. See also `AnalyticOnNhd.contDiffOn_of_completeSpace`. -/ theorem AnalyticOnNhd.contDiffOn (h : AnalyticOnNhd 𝕜 f s) (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 n f s := h.analyticOn.contDiffOn hs /-- An analytic function is automatically `C^ω` in a complete space -/ theorem AnalyticOn.contDiffOn_of_completeSpace [CompleteSpace F] (h : AnalyticOn 𝕜 f s) : ContDiffOn 𝕜 n f s := fun x hx ↦ (h x hx).contDiffWithinAt /-- An analytic function is automatically `C^ω` in a complete space -/ theorem AnalyticOnNhd.contDiffOn_of_completeSpace [CompleteSpace F] (h : AnalyticOnNhd 𝕜 f s) : ContDiffOn 𝕜 n f s := h.analyticOn.contDiffOn_of_completeSpace theorem contDiffOn_of_continuousOn_differentiableOn {n : ℕ∞} (Hcont : ∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s) (Hdiff : ∀ m : ℕ, m < n → DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s) : ContDiffOn 𝕜 n f s := by intro x hx m hm rw [insert_eq_of_mem hx] refine ⟨s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_⟩ constructor · intro y _ simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply, iteratedFDerivWithin_zero_apply] · intro k hk y hy convert (Hdiff k (lt_of_lt_of_le (mod_cast hk) (mod_cast hm)) y hy).hasFDerivWithinAt · intro k hk exact Hcont k (le_trans (mod_cast hk) (mod_cast hm)) theorem contDiffOn_of_differentiableOn {n : ℕ∞} (h : ∀ m : ℕ, m ≤ n → DifferentiableOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s) : ContDiffOn 𝕜 n f s := contDiffOn_of_continuousOn_differentiableOn (fun m hm => (h m hm).continuousOn) fun m hm => h m (le_of_lt hm) theorem contDiffOn_of_analyticOn_iteratedFDerivWithin (h : ∀ m, AnalyticOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s) : ContDiffOn 𝕜 n f s := by suffices ContDiffOn 𝕜 ω f s from this.of_le le_top intro x hx refine ⟨insert x s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_, ?_⟩ · rw [insert_eq_of_mem hx] constructor · intro y _ simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply, iteratedFDerivWithin_zero_apply] · intro k _ y hy exact ((h k).differentiableOn y hy).hasFDerivWithinAt · intro k _ exact (h k).continuousOn · intro i rw [insert_eq_of_mem hx] exact h i theorem contDiffOn_omega_iff_analyticOn (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 ω f s ↔ AnalyticOn 𝕜 f s := ⟨fun h m ↦ h.analyticOn m, fun h ↦ h.contDiffOn hs⟩ theorem ContDiffOn.continuousOn_iteratedFDerivWithin {m : ℕ} (h : ContDiffOn 𝕜 n f s) (hmn : m ≤ n) (hs : UniqueDiffOn 𝕜 s) : ContinuousOn (iteratedFDerivWithin 𝕜 m f s) s := ((h.of_le hmn).ftaylorSeriesWithin hs).cont m le_rfl theorem ContDiffOn.differentiableOn_iteratedFDerivWithin {m : ℕ} (h : ContDiffOn 𝕜 n f s) (hmn : m < n) (hs : UniqueDiffOn 𝕜 s) : DifferentiableOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s := by intro x hx have : (m + 1 : ℕ) ≤ n := ENat.add_one_natCast_le_withTop_of_lt hmn apply (((h.of_le this).ftaylorSeriesWithin hs).fderivWithin m ?_ x hx).differentiableWithinAt exact_mod_cast lt_add_one m theorem ContDiffWithinAt.differentiableWithinAt_iteratedFDerivWithin {m : ℕ} (h : ContDiffWithinAt 𝕜 n f s x) (hmn : m < n) (hs : UniqueDiffOn 𝕜 (insert x s)) : DifferentiableWithinAt 𝕜 (iteratedFDerivWithin 𝕜 m f s) s x := by have : (m + 1 : WithTop ℕ∞) ≠ ∞ := Ne.symm (ne_of_beq_false rfl) rcases h.contDiffOn' (ENat.add_one_natCast_le_withTop_of_lt hmn) (by simp [this]) with ⟨u, uo, xu, hu⟩ set t := insert x s ∩ u have A : t =ᶠ[𝓝[≠] x] s := by simp only [set_eventuallyEq_iff_inf_principal, ← nhdsWithin_inter'] rw [← inter_assoc, nhdsWithin_inter_of_mem', ← diff_eq_compl_inter, insert_diff_of_mem, diff_eq_compl_inter] exacts [rfl, mem_nhdsWithin_of_mem_nhds (uo.mem_nhds xu)] have B : iteratedFDerivWithin 𝕜 m f s =ᶠ[𝓝 x] iteratedFDerivWithin 𝕜 m f t := iteratedFDerivWithin_eventually_congr_set' _ A.symm _ have C : DifferentiableWithinAt 𝕜 (iteratedFDerivWithin 𝕜 m f t) t x := hu.differentiableOn_iteratedFDerivWithin (Nat.cast_lt.2 m.lt_succ_self) (hs.inter uo) x ⟨mem_insert _ _, xu⟩ rw [differentiableWithinAt_congr_set' _ A] at C exact C.congr_of_eventuallyEq (B.filter_mono inf_le_left) B.self_of_nhds theorem contDiffOn_iff_continuousOn_differentiableOn {n : ℕ∞} (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 n f s ↔ (∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s) ∧ ∀ m : ℕ, m < n → DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s := ⟨fun h => ⟨fun _m hm => h.continuousOn_iteratedFDerivWithin (mod_cast hm) hs, fun _m hm => h.differentiableOn_iteratedFDerivWithin (mod_cast hm) hs⟩, fun h => contDiffOn_of_continuousOn_differentiableOn h.1 h.2⟩ theorem contDiffOn_nat_iff_continuousOn_differentiableOn {n : ℕ} (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 n f s ↔ (∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s) ∧ ∀ m : ℕ, m < n → DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s := by rw [← WithTop.coe_natCast, contDiffOn_iff_continuousOn_differentiableOn hs] simp theorem contDiffOn_succ_of_fderivWithin (hf : DifferentiableOn 𝕜 f s) (h' : n = ω → AnalyticOn 𝕜 f s) (h : ContDiffOn 𝕜 n (fun y => fderivWithin 𝕜 f s y) s) : ContDiffOn 𝕜 (n + 1) f s := by rcases eq_or_ne n ∞ with rfl \| hn · rw [ENat.coe_top_add_one, contDiffOn_infty] intro m x hx apply ContDiffWithinAt.of_le _ (show (m : WithTop ℕ∞) ≤ m + 1 from le_self_add) rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt (by simp), insert_eq_of_mem hx] exact ⟨s, self_mem_nhdsWithin, (by simp), fderivWithin 𝕜 f s, fun y hy => (hf y hy).hasFDerivWithinAt, (h x hx).of_le (mod_cast le_top)⟩ · intro x hx rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt hn, insert_eq_of_mem hx] exact ⟨s, self_mem_nhdsWithin, h', fderivWithin 𝕜 f s, fun y hy => (hf y hy).hasFDerivWithinAt, h x hx⟩ theorem contDiffOn_of_analyticOn_of_fderivWithin (hf : AnalyticOn 𝕜 f s) (h : ContDiffOn 𝕜 ω (fun y ↦ fderivWithin 𝕜 f s y) s) : ContDiffOn 𝕜 n f s := by suffices ContDiffOn 𝕜 (ω + 1) f s from this.of_le le_top exact contDiffOn_succ_of_fderivWithin hf.differentiableOn (fun _ ↦ hf) h /-- A function is `C^(n + 1)` on a domain with unique derivatives if and only if it is differentiable there, and its derivative (expressed with `fderivWithin`) is `C^n`. -/ theorem contDiffOn_succ_iff_fderivWithin (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 (n + 1) f s ↔ DifferentiableOn 𝕜 f s ∧ (n = ω → AnalyticOn 𝕜 f s) ∧ ContDiffOn 𝕜 n (fderivWithin 𝕜 f s) s := by refine ⟨fun H => ?_, fun h => contDiffOn_succ_of_fderivWithin h.1 h.2.1 h.2.2⟩ refine ⟨H.differentiableOn le_add_self, ?_, fun x hx => ?_⟩ · rintro rfl exact H.analyticOn have A (m : ℕ) (hm : m ≤ n) : ContDiffWithinAt 𝕜 m (fun y => fderivWithin 𝕜 f s y) s x := by rcases (contDiffWithinAt_succ_iff_hasFDerivWithinAt (n := m) (ne_of_beq_false rfl)).1 (H.of_le (add_le_add_right hm 1) x hx) with ⟨u, hu, -, f', hff', hf'⟩ rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩ rw [inter_comm, insert_eq_of_mem hx] at ho have := hf'.mono ho rw [contDiffWithinAt_inter' (mem_nhdsWithin_of_mem_nhds (IsOpen.mem_nhds o_open xo))] at this apply this.congr_of_eventuallyEq_of_mem _ hx have : o ∩ s ∈ 𝓝[s] x := mem_nhdsWithin.2 ⟨o, o_open, xo, Subset.refl _⟩ rw [inter_comm] at this refine Filter.eventuallyEq_of_mem this fun y hy => ?_ have A : fderivWithin 𝕜 f (s ∩ o) y = f' y := ((hff' y (ho hy)).mono ho).fderivWithin (hs.inter o_open y hy) rwa [fderivWithin_inter (o_open.mem_nhds hy.2)] at A match n with \| ω => exact (H.analyticOn.fderivWithin hs).contDiffOn hs (n := ω) x hx \| ∞ => exact contDiffWithinAt_infty.2 (fun m ↦ A m (mod_cast le_top)) \| (n : ℕ) => exact A n le_rfl theorem contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 (n + 1) f s ↔ (n = ω → AnalyticOn 𝕜 f s) ∧ ∃ f' : E → E →L[𝕜] F, ContDiffOn 𝕜 n f' s ∧ ∀ x, x ∈ s → HasFDerivWithinAt f (f' x) s x := by rw [contDiffOn_succ_iff_fderivWithin hs] refine ⟨fun h => ⟨h.2.1, fderivWithin 𝕜 f s, h.2.2, fun x hx => (h.1 x hx).hasFDerivWithinAt⟩, fun ⟨f_an, h⟩ => ?_⟩ rcases h with ⟨f', h1, h2⟩ refine ⟨fun x hx => (h2 x hx).differentiableWithinAt, f_an, fun x hx => ?_⟩ exact (h1 x hx).congr_of_mem (fun y hy => (h2 y hy).fderivWithin (hs y hy)) hx @[deprecated (since := "2024-11-27")] alias contDiffOn_succ_iff_hasFDerivWithin := contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn theorem contDiffOn_infty_iff_fderivWithin (hs : UniqueDiffOn 𝕜 s) : ContDiffOn 𝕜 ∞ f s ↔ DifferentiableOn 𝕜 f s ∧ ContDiffOn 𝕜 ∞ (fderivWithin 𝕜 f s) s := by rw [← ENat.coe_top_add_one, contDiffOn_succ_iff_fderivWithin hs] simp @[deprecated (since := "2024-11-27")] alias contDiffOn_top_iff_fderivWithin := contDiffOn_infty_iff_fderivWithin /-- A function is `C^(n + 1)` on an open domain if and only if it is differentiable there, and its derivative (expressed with `fderiv`) is `C^n`. -/ theorem contDiffOn_succ_iff_fderiv_of_isOpen (hs : IsOpen s) : ContDiffOn 𝕜 (n + 1) f s ↔ DifferentiableOn 𝕜 f s ∧ (n = ω → AnalyticOn 𝕜 f s) ∧ ContDiffOn 𝕜 n (fderiv 𝕜 f) s := by rw [contDiffOn_succ_iff_fderivWithin hs.uniqueDiffOn, contDiffOn_congr fun x hx ↦ fderivWithin_of_isOpen hs hx] theorem contDiffOn_infty_iff_fderiv_of_isOpen (hs : IsOpen s) : ContDiffOn 𝕜 ∞ f s ↔ DifferentiableOn 𝕜 f s ∧ ContDiffOn 𝕜 ∞ (fderiv 𝕜 f) s := by rw [← ENat.coe_top_add_one, contDiffOn_succ_iff_fderiv_of_isOpen hs] simp @[deprecated (since := "2024-11-27")] alias contDiffOn_top_iff_fderiv_of_isOpen := contDiffOn_infty_iff_fderiv_of_isOpen protected theorem ContDiffOn.fderivWithin (hf : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s) (hmn : m + 1 ≤ n) : ContDiffOn 𝕜 m (fderivWithin 𝕜 f s) s := ((contDiffOn_succ_iff_fderivWithin hs).1 (hf.of_le hmn)).2.2 theorem ContDiffOn.fderiv_of_isOpen (hf : ContDiffOn 𝕜 n f s) (hs : IsOpen s) (hmn : m + 1 ≤ n) : ContDiffOn 𝕜 m (fderiv 𝕜 f) s := (hf.fderivWithin hs.uniqueDiffOn hmn).congr fun _ hx => (fderivWithin_of_isOpen hs hx).symm theorem ContDiffOn.continuousOn_fderivWithin (h : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s) (hn : 1 ≤ n) : ContinuousOn (fderivWithin 𝕜 f s) s := ((contDiffOn_succ_iff_fderivWithin hs).1 (h.of_le (show 0 + (1 : WithTop ℕ∞) ≤ n from hn))).2.2.continuousOn theorem ContDiffOn.continuousOn_fderiv_of_isOpen (h : ContDiffOn 𝕜 n f s) (hs : IsOpen s) (hn : 1 ≤ n) : ContinuousOn (fderiv 𝕜 f) s := ((contDiffOn_succ_iff_fderiv_of_isOpen hs).1 (h.of_le (show 0 + (1 : WithTop ℕ∞) ≤ n from hn))).2.2.continuousOn /-! ### Smooth functions at a point -/ variable (𝕜) in /-- A function is continuously differentiable up to `n` at a point `x` if, for any integer `k ≤ n`, there is a neighborhood of `x` where `f` admits derivatives up to order `n`, which are continuous. -/ def ContDiffAt (n : WithTop ℕ∞) (f : E → F) (x : E) : Prop := ContDiffWithinAt 𝕜 n f univ x theorem contDiffWithinAt_univ : ContDiffWithinAt 𝕜 n f univ x ↔ ContDiffAt 𝕜 n f x := Iff.rfl theorem contDiffAt_infty : ContDiffAt 𝕜 ∞ f x ↔ ∀ n : ℕ, ContDiffAt 𝕜 n f x := by simp [← contDiffWithinAt_univ, contDiffWithinAt_infty] @[deprecated (since := "2024-11-27")] alias contDiffAt_top := contDiffAt_infty theorem ContDiffAt.contDiffWithinAt (h : ContDiffAt 𝕜 n f x) : ContDiffWithinAt 𝕜 n f s x := h.mono (subset_univ _) theorem ContDiffWithinAt.contDiffAt (h : ContDiffWithinAt 𝕜 n f s x) (hx : s ∈ 𝓝 x) : ContDiffAt 𝕜 n f x := by rwa [ContDiffAt, ← contDiffWithinAt_inter hx, univ_inter] theorem contDiffWithinAt_iff_contDiffAt (h : s ∈ 𝓝 x) : ContDiffWithinAt 𝕜 n f s x ↔ ContDiffAt 𝕜 n f x := by rw [← univ_inter s, contDiffWithinAt_inter h, contDiffWithinAt_univ] theorem IsOpen.contDiffOn_iff (hs : IsOpen s) : ContDiffOn 𝕜 n f s ↔ ∀ ⦃a⦄, a ∈ s → ContDiffAt 𝕜 n f a := forall₂_congr fun _ => contDiffWithinAt_iff_contDiffAt ∘ hs.mem_nhds theorem ContDiffOn.contDiffAt (h : ContDiffOn 𝕜 n f s) (hx : s ∈ 𝓝 x) : ContDiffAt 𝕜 n f x := (h _ (mem_of_mem_nhds hx)).contDiffAt hx theorem ContDiffAt.congr_of_eventuallyEq (h : ContDiffAt 𝕜 n f x) (hg : f₁ =ᶠ[𝓝 x] f) : ContDiffAt 𝕜 n f₁ x := h.congr_of_eventuallyEq_of_mem (by rwa [nhdsWithin_univ]) (mem_univ x) theorem ContDiffAt.of_le (h : ContDiffAt 𝕜 n f x) (hmn : m ≤ n) : ContDiffAt 𝕜 m f x := ContDiffWithinAt.of_le h hmn theorem ContDiffAt.continuousAt (h : ContDiffAt 𝕜 n f x) : ContinuousAt f x := by simpa [continuousWithinAt_univ] using h.continuousWithinAt theorem ContDiffAt.analyticAt (h : ContDiffAt 𝕜 ω f x) : AnalyticAt 𝕜 f x := by rw [← contDiffWithinAt_univ] at h rw [← analyticWithinAt_univ] exact h.analyticWithinAt /-- In a complete space, a function which is analytic at a point is also `C^ω` there. Note that the same statement for `AnalyticOn` does not require completeness, see `AnalyticOn.contDiffOn`. -/ theorem AnalyticAt.contDiffAt [CompleteSpace F] (h : AnalyticAt 𝕜 f x) : ContDiffAt 𝕜 n f x := by rw [← contDiffWithinAt_univ] rw [← analyticWithinAt_univ] at h exact h.contDiffWithinAt @[simp] theorem contDiffWithinAt_compl_self : ContDiffWithinAt 𝕜 n f {x}ᶜ x ↔ ContDiffAt 𝕜 n f x := by rw [compl_eq_univ_diff, contDiffWithinAt_diff_singleton, contDiffWithinAt_univ] /-- If a function is `C^n` with `n ≥ 1` at a point, then it is differentiable there. -/ theorem ContDiffAt.differentiableAt (h : ContDiffAt 𝕜 n f x) (hn : 1 ≤ n) : DifferentiableAt 𝕜 f x := by simpa [hn, differentiableWithinAt_univ] using h.differentiableWithinAt nonrec lemma ContDiffAt.contDiffOn (h : ContDiffAt 𝕜 n f x) (hm : m ≤ n) (h' : m = ∞ → n = ω): ∃ u ∈ 𝓝 x, ContDiffOn 𝕜 m f u := by simpa [nhdsWithin_univ] using h.contDiffOn hm h' /-- A function is `C^(n + 1)` at a point iff locally, it has a derivative which is `C^n`. -/ theorem contDiffAt_succ_iff_hasFDerivAt {n : ℕ} : ContDiffAt 𝕜 (n + 1) f x ↔ ∃ f' : E → E →L[𝕜] F, (∃ u ∈ 𝓝 x, ∀ x ∈ u, HasFDerivAt f (f' x) x) ∧ ContDiffAt 𝕜 n f' x := by rw [← contDiffWithinAt_univ, contDiffWithinAt_succ_iff_hasFDerivWithinAt (by simp)] simp only [nhdsWithin_univ, exists_prop, mem_univ, insert_eq_of_mem] constructor · rintro ⟨u, H, -, f', h_fderiv, h_cont_diff⟩ rcases mem_nhds_iff.mp H with ⟨t, htu, ht, hxt⟩ refine ⟨f', ⟨t, ?_⟩, h_cont_diff.contDiffAt H⟩ refine ⟨mem_nhds_iff.mpr ⟨t, Subset.rfl, ht, hxt⟩, ?_⟩ intro y hyt refine (h_fderiv y (htu hyt)).hasFDerivAt ?_ exact mem_nhds_iff.mpr ⟨t, htu, ht, hyt⟩ · rintro ⟨f', ⟨u, H, h_fderiv⟩, h_cont_diff⟩ refine ⟨u, H, by simp, f', fun x hxu ↦ ?_, h_cont_diff.contDiffWithinAt⟩ exact (h_fderiv x hxu).hasFDerivWithinAt protected theorem ContDiffAt.eventually (h : ContDiffAt 𝕜 n f x) (h' : n ≠ ∞) : ∀ᶠ y in 𝓝 x, ContDiffAt 𝕜 n f y := by simpa [nhdsWithin_univ] using ContDiffWithinAt.eventually h h' theorem iteratedFDerivWithin_eq_iteratedFDeriv {n : ℕ} (hs : UniqueDiffOn 𝕜 s) (h : ContDiffAt 𝕜 n f x) (hx : x ∈ s) : iteratedFDerivWithin 𝕜 n f s x = iteratedFDeriv 𝕜 n f x := by rw [← iteratedFDerivWithin_univ] rcases h.contDiffOn' le_rfl (by simp) with ⟨u, u_open, xu, hu⟩ rw [← iteratedFDerivWithin_inter_open u_open xu, ← iteratedFDerivWithin_inter_open u_open xu (s := univ)] apply iteratedFDerivWithin_subset · exact inter_subset_inter_left _ (subset_univ _) · exact hs.inter u_open · apply uniqueDiffOn_univ.inter u_open · simpa using hu · exact ⟨hx, xu⟩ /-! ### Smooth functions -/ variable (𝕜) in /-- A function is continuously differentiable up to `n` if it admits derivatives up to order `n`, which are continuous. Contrary to the case of definitions in domains (where derivatives might not be unique) we do not need to localize the definition in space or time. -/ def ContDiff (n : WithTop ℕ∞) (f : E → F) : Prop := match n with \| ω => ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpTo ⊤ f p ∧ ∀ i, AnalyticOnNhd 𝕜 (fun x ↦ p x i) univ \| (n : ℕ∞) => ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpTo n f p /-- If `f` has a Taylor series up to `n`, then it is `C^n`. -/ theorem HasFTaylorSeriesUpTo.contDiff {n : ℕ∞} {f' : E → FormalMultilinearSeries 𝕜 E F} (hf : HasFTaylorSeriesUpTo n f f') : ContDiff 𝕜 n f := ⟨f', hf⟩ theorem contDiffOn_univ : ContDiffOn 𝕜 n f univ ↔ ContDiff 𝕜 n f := by match n with \| ω => constructor · intro H use ftaylorSeriesWithin 𝕜 f univ rw [← hasFTaylorSeriesUpToOn_univ_iff] refine ⟨H.ftaylorSeriesWithin uniqueDiffOn_univ, fun i ↦ ?_⟩ rw [← analyticOn_univ] exact H.analyticOn.iteratedFDerivWithin uniqueDiffOn_univ _ · rintro ⟨p, hp, h'p⟩ x _ exact ⟨univ, Filter.univ_sets _, p, (hp.hasFTaylorSeriesUpToOn univ).of_le le_top, fun i ↦ (h'p i).analyticOn⟩ \| (n : ℕ∞) => constructor · intro H use ftaylorSeriesWithin 𝕜 f univ rw [← hasFTaylorSeriesUpToOn_univ_iff] exact H.ftaylorSeriesWithin uniqueDiffOn_univ · rintro ⟨p, hp⟩ x _ m hm exact ⟨univ, Filter.univ_sets _, p, (hp.hasFTaylorSeriesUpToOn univ).of_le (mod_cast hm)⟩ theorem contDiff_iff_contDiffAt : ContDiff 𝕜 n f ↔ ∀ x, ContDiffAt 𝕜 n f x := by simp [← contDiffOn_univ, ContDiffOn, ContDiffAt] theorem ContDiff.contDiffAt (h : ContDiff 𝕜 n f) : ContDiffAt 𝕜 n f x := contDiff_iff_contDiffAt.1 h x theorem ContDiff.contDiffWithinAt (h : ContDiff 𝕜 n f) : ContDiffWithinAt 𝕜 n f s x := h.contDiffAt.contDiffWithinAt theorem contDiff_infty : ContDiff 𝕜 ∞ f ↔ ∀ n : ℕ, ContDiff 𝕜 n f := by simp [contDiffOn_univ.symm, contDiffOn_infty] @[deprecated (since := "2024-11-25")] alias contDiff_top := contDiff_infty @[deprecated (since := "2024-11-25")] alias contDiff_infty_iff_contDiff_omega := contDiff_infty theorem contDiff_all_iff_nat : (∀ n : ℕ∞, ContDiff 𝕜 n f) ↔ ∀ n : ℕ, ContDiff 𝕜 n f := by simp only [← contDiffOn_univ, contDiffOn_all_iff_nat] theorem ContDiff.contDiffOn (h : ContDiff 𝕜 n f) : ContDiffOn 𝕜 n f s := (contDiffOn_univ.2 h).mono (subset_univ _) @[simp] theorem contDiff_zero : ContDiff 𝕜 0 f ↔ Continuous f := by rw [← contDiffOn_univ, continuous_iff_continuousOn_univ] exact contDiffOn_zero theorem contDiffAt_zero : ContDiffAt 𝕜 0 f x ↔ ∃ u ∈ 𝓝 x, ContinuousOn f u := by rw [← contDiffWithinAt_univ]; simp [contDiffWithinAt_zero, nhdsWithin_univ] theorem contDiffAt_one_iff : ContDiffAt 𝕜 1 f x ↔ ∃ f' : E → E →L[𝕜] F, ∃ u ∈ 𝓝 x, ContinuousOn f' u ∧ ∀ x ∈ u, HasFDerivAt f (f' x) x := by rw [show (1 : WithTop ℕ∞) = (0 : ℕ) + 1 from rfl] simp_rw [contDiffAt_succ_iff_hasFDerivAt, show ((0 : ℕ) : WithTop ℕ∞) = 0 from rfl, contDiffAt_zero, exists_mem_and_iff antitone_bforall antitone_continuousOn, and_comm] theorem ContDiff.of_le (h : ContDiff 𝕜 n f) (hmn : m ≤ n) : ContDiff 𝕜 m f := contDiffOn_univ.1 <\| (contDiffOn_univ.2 h).of_le hmn theorem ContDiff.of_succ (h : ContDiff 𝕜 (n + 1) f) : ContDiff 𝕜 n f := h.of_le le_self_add theorem ContDiff.one_of_succ (h : ContDiff 𝕜 (n + 1) f) : ContDiff 𝕜 1 f := by apply h.of_le le_add_self theorem ContDiff.continuous (h : ContDiff 𝕜 n f) : Continuous f := contDiff_zero.1 (h.of_le bot_le) /-- If a function is `C^n` with `n ≥ 1`, then it is differentiable. -/ theorem ContDiff.differentiable (h : ContDiff 𝕜 n f) (hn : 1 ≤ n) : Differentiable 𝕜 f := differentiableOn_univ.1 <\| (contDiffOn_univ.2 h).differentiableOn hn theorem contDiff_iff_forall_nat_le {n : ℕ∞} : ContDiff 𝕜 n f ↔ ∀ m : ℕ, ↑m ≤ n → ContDiff 𝕜 m f := by simp_rw [← contDiffOn_univ]; exact contDiffOn_iff_forall_nat_le /-- A function is `C^(n+1)` iff it has a `C^n` derivative. -/ theorem contDiff_succ_iff_hasFDerivAt {n : ℕ} : ContDiff 𝕜 (n + 1) f ↔ ∃ f' : E → E →L[𝕜] F, ContDiff 𝕜 n f' ∧ ∀ x, HasFDerivAt f (f' x) x := by simp only [← contDiffOn_univ, ← hasFDerivWithinAt_univ, Set.mem_univ, forall_true_left, contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn uniqueDiffOn_univ, WithTop.natCast_ne_top, analyticOn_univ, false_implies, true_and] theorem contDiff_one_iff_hasFDerivAt : ContDiff 𝕜 1 f ↔ ∃ f' : E → E →L[𝕜] F, Continuous f' ∧ ∀ x, HasFDerivAt f (f' x) x := by convert contDiff_succ_iff_hasFDerivAt using 4; simp theorem AnalyticOn.contDiff (hf : AnalyticOn 𝕜 f univ) : ContDiff 𝕜 n f := by rw [← contDiffOn_univ] exact hf.contDiffOn (n := n) uniqueDiffOn_univ theorem AnalyticOnNhd.contDiff (hf : AnalyticOnNhd 𝕜 f univ) : ContDiff 𝕜 n f := hf.analyticOn.contDiff theorem ContDiff.analyticOnNhd (h : ContDiff 𝕜 ω f) : AnalyticOnNhd 𝕜 f s := by rw [← contDiffOn_univ] at h have := h.analyticOn rw [analyticOn_univ] at this exact this.mono (subset_univ _) theorem contDiff_omega_iff_analyticOnNhd : ContDiff 𝕜 ω f ↔ AnalyticOnNhd 𝕜 f univ := ⟨fun h ↦ h.analyticOnNhd, fun h ↦ h.contDiff⟩ /-! ### Iterated derivative -/ /-- When a function is `C^n`, it admits `ftaylorSeries 𝕜 f` as a Taylor series up to order `n` in `s`. -/ theorem ContDiff.ftaylorSeries (hf : ContDiff 𝕜 n f) : HasFTaylorSeriesUpTo n f (ftaylorSeries 𝕜 f) := by simp only [← contDiffOn_univ, ← hasFTaylorSeriesUpToOn_univ_iff, ← ftaylorSeriesWithin_univ] at hf ⊢ exact ContDiffOn.ftaylorSeriesWithin hf uniqueDiffOn_univ /-- For `n : ℕ∞`, a function is `C^n` iff it admits `ftaylorSeries 𝕜 f` as a Taylor series up to order `n`. -/ theorem contDiff_iff_ftaylorSeries {n : ℕ∞} : ContDiff 𝕜 n f ↔ HasFTaylorSeriesUpTo n f (ftaylorSeries 𝕜 f) := by constructor · rw [← contDiffOn_univ, ← hasFTaylorSeriesUpToOn_univ_iff, ← ftaylorSeriesWithin_univ] exact fun h ↦ ContDiffOn.ftaylorSeriesWithin h uniqueDiffOn_univ · exact fun h ↦ ⟨ftaylorSeries 𝕜 f, h⟩ theorem contDiff_iff_continuous_differentiable {n : ℕ∞} : ContDiff 𝕜 n f ↔ (∀ m : ℕ, m ≤ n → Continuous fun x => iteratedFDeriv 𝕜 m f x) ∧ ∀ m : ℕ, m < n → Differentiable 𝕜 fun x => iteratedFDeriv 𝕜 m f x := by simp [contDiffOn_univ.symm, continuous_iff_continuousOn_univ, differentiableOn_univ.symm, iteratedFDerivWithin_univ, contDiffOn_iff_continuousOn_differentiableOn uniqueDiffOn_univ] theorem contDiff_nat_iff_continuous_differentiable {n : ℕ} : ContDiff 𝕜 n f ↔ (∀ m : ℕ, m ≤ n → Continuous fun x => iteratedFDeriv 𝕜 m f x) ∧ ∀ m : ℕ, m < n → Differentiable 𝕜 fun x => iteratedFDeriv 𝕜 m f x := by rw [← WithTop.coe_natCast, contDiff_iff_continuous_differentiable] simp /-- If `f` is `C^n` then its `m`-times iterated derivative is continuous for `m ≤ n`. -/ theorem ContDiff.continuous_iteratedFDeriv {m : ℕ} (hm : m ≤ n) (hf : ContDiff 𝕜 n f) : Continuous fun x => iteratedFDeriv 𝕜 m f x := (contDiff_iff_continuous_differentiable.mp (hf.of_le hm)).1 m le_rfl /-- If `f` is `C^n` then its `m`-times iterated derivative is differentiable for `m < n`. -/ theorem ContDiff.differentiable_iteratedFDeriv {m : ℕ} (hm : m < n) (hf : ContDiff 𝕜 n f) : Differentiable 𝕜 fun x => iteratedFDeriv 𝕜 m f x := (contDiff_iff_continuous_differentiable.mp (hf.of_le (ENat.add_one_natCast_le_withTop_of_lt hm))).2 m (mod_cast lt_add_one m) theorem contDiff_of_differentiable_iteratedFDeriv {n : ℕ∞} (h : ∀ m : ℕ, m ≤ n → Differentiable 𝕜 (iteratedFDeriv 𝕜 m f)) : ContDiff 𝕜 n f := contDiff_iff_continuous_differentiable.2 ⟨fun m hm => (h m hm).continuous, fun m hm => h m (le_of_lt hm)⟩ /-- A function is `C^(n + 1)` if and only if it is differentiable, and its derivative (formulated in terms of `fderiv`) is `C^n`. -/ theorem contDiff_succ_iff_fderiv : ContDiff 𝕜 (n + 1) f ↔ Differentiable 𝕜 f ∧ (n = ω → AnalyticOnNhd 𝕜 f univ) ∧ ContDiff 𝕜 n (fderiv 𝕜 f) := by simp only [← contDiffOn_univ, ← differentiableOn_univ, ← fderivWithin_univ, contDiffOn_succ_iff_fderivWithin uniqueDiffOn_univ, analyticOn_univ] theorem contDiff_one_iff_fderiv : ContDiff 𝕜 1 f ↔ Differentiable 𝕜 f ∧ Continuous (fderiv 𝕜 f) := by rw [← zero_add 1, contDiff_succ_iff_fderiv] simp theorem contDiff_infty_iff_fderiv : ContDiff 𝕜 ∞ f ↔ Differentiable 𝕜 f ∧ ContDiff 𝕜 ∞ (fderiv 𝕜 f) := by rw [← ENat.coe_top_add_one, contDiff_succ_iff_fderiv] simp @[deprecated (since := "2024-11-27")] alias contDiff_top_iff_fderiv := contDiff_infty_iff_fderiv theorem ContDiff.continuous_fderiv (h : ContDiff 𝕜 n f) (hn : 1 ≤ n) : Continuous (fderiv 𝕜 f) := (contDiff_one_iff_fderiv.1 (h.of_le hn)).2 /-- If a function is at least `C^1`, its bundled derivative (mapping `(x, v)` to `Df(x) v`) is continuous. -/ theorem ContDiff.continuous_fderiv_apply (h : ContDiff 𝕜 n f) (hn : 1 ≤ n) : Continuous fun p : E × E => (fderiv 𝕜 f p.1 : E → F) p.2 := have A : Continuous fun q : (E →L[𝕜] F) × E => q.1 q.2 := isBoundedBilinearMap_apply.continuous have B : Continuous fun p : E × E => (fderiv 𝕜 f p.1, p.2) := ((h.continuous_fderiv hn).comp continuous_fst).prodMk continuous_snd A.comp B		Mathlib/Analysis/Calculus/ContDiff/Defs.lean	1,540	1,542
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro -/ import Mathlib.Data.Finset.Pi import Mathlib.Data.Finset.Sigma import Mathlib.Data.Finset.Sum import Mathlib.Data.Set.Finite.Basic /-! # Preimage of a `Finset` under an injective map. -/ assert_not_exists Finset.sum open Set Function universe u v w x variable {α : Type u} {β : Type v} {ι : Sort w} {γ : Type x} namespace Finset section Preimage /-- Preimage of `s : Finset β` under a map `f` injective on `f ⁻¹' s` as a `Finset`. -/ noncomputable def preimage (s : Finset β) (f : α → β) (hf : Set.InjOn f (f ⁻¹' ↑s)) : Finset α := (s.finite_toSet.preimage hf).toFinset @[simp] theorem mem_preimage {f : α → β} {s : Finset β} {hf : Set.InjOn f (f ⁻¹' ↑s)} {x : α} : x ∈ preimage s f hf ↔ f x ∈ s := Set.Finite.mem_toFinset _ @[simp, norm_cast] theorem coe_preimage {f : α → β} (s : Finset β) (hf : Set.InjOn f (f ⁻¹' ↑s)) : (↑(preimage s f hf) : Set α) = f ⁻¹' ↑s := Set.Finite.coe_toFinset _ @[simp] theorem preimage_empty {f : α → β} : preimage ∅ f (by simp [InjOn]) = ∅ := Finset.coe_injective (by simp) @[simp] theorem preimage_univ {f : α → β} [Fintype α] [Fintype β] (hf) : preimage univ f hf = univ := Finset.coe_injective (by simp) @[simp] theorem preimage_inter [DecidableEq α] [DecidableEq β] {f : α → β} {s t : Finset β} (hs : Set.InjOn f (f ⁻¹' ↑s)) (ht : Set.InjOn f (f ⁻¹' ↑t)) : (preimage (s ∩ t) f fun _ hx₁ _ hx₂ => hs (mem_of_mem_inter_left hx₁) (mem_of_mem_inter_left hx₂)) =	preimage s f hs ∩ preimage t f ht := Finset.coe_injective (by simp) @[simp] theorem preimage_union [DecidableEq α] [DecidableEq β] {f : α → β} {s t : Finset β} (hst) : preimage (s ∪ t) f hst =	Mathlib/Data/Finset/Preimage.lean	54	59
/- Copyright (c) 2022 Kexing Ying. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kexing Ying -/ import Mathlib.Order.Interval.Set.Monotone import Mathlib.Probability.Process.HittingTime import Mathlib.Probability.Martingale.Basic import Mathlib.Tactic.AdaptationNote /-! # Doob's upcrossing estimate Given a discrete real-valued submartingale $(f_n)_{n \in \mathbb{N}}$, denoting by $U_N(a, b)$ the number of times $f_n$ crossed from below $a$ to above $b$ before time $N$, Doob's upcrossing estimate (also known as Doob's inequality) states that $$(b - a) \mathbb{E}[U_N(a, b)] \le \mathbb{E}[(f_N - a)^+].$$ Doob's upcrossing estimate is an important inequality and is central in proving the martingale convergence theorems. ## Main definitions * `MeasureTheory.upperCrossingTime a b f N n`: is the stopping time corresponding to `f` crossing above `b` the `n`-th time before time `N` (if this does not occur then the value is taken to be `N`). * `MeasureTheory.lowerCrossingTime a b f N n`: is the stopping time corresponding to `f` crossing below `a` the `n`-th time before time `N` (if this does not occur then the value is taken to be `N`). * `MeasureTheory.upcrossingStrat a b f N`: is the predictable process which is 1 if `n` is between a consecutive pair of lower and upper crossings and is 0 otherwise. Intuitively one might think of the `upcrossingStrat` as the strategy of buying 1 share whenever the process crosses below `a` for the first time after selling and selling 1 share whenever the process crosses above `b` for the first time after buying. * `MeasureTheory.upcrossingsBefore a b f N`: is the number of times `f` crosses from below `a` to above `b` before time `N`. * `MeasureTheory.upcrossings a b f`: is the number of times `f` crosses from below `a` to above `b`. This takes value in `ℝ≥0∞` and so is allowed to be `∞`. ## Main results * `MeasureTheory.Adapted.isStoppingTime_upperCrossingTime`: `upperCrossingTime` is a stopping time whenever the process it is associated to is adapted. * `MeasureTheory.Adapted.isStoppingTime_lowerCrossingTime`: `lowerCrossingTime` is a stopping time whenever the process it is associated to is adapted. * `MeasureTheory.Submartingale.mul_integral_upcrossingsBefore_le_integral_pos_part`: Doob's upcrossing estimate. * `MeasureTheory.Submartingale.mul_lintegral_upcrossings_le_lintegral_pos_part`: the inequality obtained by taking the supremum on both sides of Doob's upcrossing estimate. ### References We mostly follow the proof from [Kallenberg, Foundations of modern probability][kallenberg2021] -/ open TopologicalSpace Filter open scoped NNReal ENNReal MeasureTheory ProbabilityTheory Topology namespace MeasureTheory variable {Ω ι : Type*} {m0 : MeasurableSpace Ω} {μ : Measure Ω} /-! ## Proof outline In this section, we will denote by $U_N(a, b)$ the number of upcrossings of $(f_n)$ from below $a$ to above $b$ before time $N$. To define $U_N(a, b)$, we will construct two stopping times corresponding to when $(f_n)$ crosses below $a$ and above $b$. Namely, we define $$ \sigma_n := \inf \{n \ge \tau_n \mid f_n \le a\} \wedge N; $$ $$ \tau_{n + 1} := \inf \{n \ge \sigma_n \mid f_n \ge b\} \wedge N. $$ These are `lowerCrossingTime` and `upperCrossingTime` in our formalization which are defined using `MeasureTheory.hitting` allowing us to specify a starting and ending time. Then, we may simply define $U_N(a, b) := \sup \{n \mid \tau_n < N\}$. Fixing $a < b \in \mathbb{R}$, we will first prove the theorem in the special case that $0 \le f_0$ and $a \le f_N$. In particular, we will show $$ (b - a) \mathbb{E}[U_N(a, b)] \le \mathbb{E}[f_N]. $$ This is `MeasureTheory.integral_mul_upcrossingsBefore_le_integral` in our formalization. To prove this, we use the fact that given a non-negative, bounded, predictable process $(C_n)$ (i.e. $(C_{n + 1})$ is adapted), $(C \bullet f)_n := \sum_{k \le n} C_{k + 1}(f_{k + 1} - f_k)$ is a submartingale if $(f_n)$ is. Define $C_n := \sum_{k \le n} \mathbf{1}_{[\sigma_k, \tau_{k + 1})}(n)$. It is easy to see that $(1 - C_n)$ is non-negative, bounded and predictable, and hence, given a submartingale $(f_n)$, $(1 - C) \bullet f$ is also a submartingale. Thus, by the submartingale property, $0 \le \mathbb{E}[((1 - C) \bullet f)_0] \le \mathbb{E}[((1 - C) \bullet f)_N]$ implying $$ \mathbb{E}[(C \bullet f)_N] \le \mathbb{E}[(1 \bullet f)_N] = \mathbb{E}[f_N] - \mathbb{E}[f_0]. $$ Furthermore, \begin{align} (C \bullet f)_N & = \sum_{n \le N} \sum_{k \le N} \mathbf{1}_{[\sigma_k, \tau_{k + 1})}(n)(f_{n + 1} - f_n)\\ & = \sum_{k \le N} \sum_{n \le N} \mathbf{1}_{[\sigma_k, \tau_{k + 1})}(n)(f_{n + 1} - f_n)\\ & = \sum_{k \le N} (f_{\sigma_k + 1} - f_{\sigma_k} + f_{\sigma_k + 2} - f_{\sigma_k + 1} + \cdots + f_{\tau_{k + 1}} - f_{\tau_{k + 1} - 1})\\ & = \sum_{k \le N} (f_{\tau_{k + 1}} - f_{\sigma_k}) \ge \sum_{k < U_N(a, b)} (b - a) = (b - a) U_N(a, b) \end{align} where the inequality follows since for all $k < U_N(a, b)$, $f_{\tau_{k + 1}} - f_{\sigma_k} \ge b - a$ while for all $k > U_N(a, b)$, $f_{\tau_{k + 1}} = f_{\sigma_k} = f_N$ and $f_{\tau_{U_N(a, b) + 1}} - f_{\sigma_{U_N(a, b)}} = f_N - a \ge 0$. Hence, we have $$ (b - a) \mathbb{E}[U_N(a, b)] \le \mathbb{E}[(C \bullet f)_N] \le \mathbb{E}[f_N] - \mathbb{E}[f_0] \le \mathbb{E}[f_N], $$ as required. To obtain the general case, we simply apply the above to $((f_n - a)^+)_n$. -/ /-- `lowerCrossingTimeAux a f c N` is the first time `f` reached below `a` after time `c` before time `N`. -/ noncomputable def lowerCrossingTimeAux [Preorder ι] [InfSet ι] (a : ℝ) (f : ι → Ω → ℝ) (c N : ι) : Ω → ι := hitting f (Set.Iic a) c N /-- `upperCrossingTime a b f N n` is the first time before time `N`, `f` reaches above `b` after `f` reached below `a` for the `n - 1`-th time. -/ noncomputable def upperCrossingTime [Preorder ι] [OrderBot ι] [InfSet ι] (a b : ℝ) (f : ι → Ω → ℝ) (N : ι) : ℕ → Ω → ι \| 0 => ⊥ \| n + 1 => fun ω => hitting f (Set.Ici b) (lowerCrossingTimeAux a f (upperCrossingTime a b f N n ω) N ω) N ω /-- `lowerCrossingTime a b f N n` is the first time before time `N`, `f` reaches below `a` after `f` reached above `b` for the `n`-th time. -/ noncomputable def lowerCrossingTime [Preorder ι] [OrderBot ι] [InfSet ι] (a b : ℝ) (f : ι → Ω → ℝ) (N : ι) (n : ℕ) : Ω → ι := fun ω => hitting f (Set.Iic a) (upperCrossingTime a b f N n ω) N ω section variable [Preorder ι] [OrderBot ι] [InfSet ι] variable {a b : ℝ} {f : ι → Ω → ℝ} {N : ι} {n : ℕ} {ω : Ω} @[simp] theorem upperCrossingTime_zero : upperCrossingTime a b f N 0 = ⊥ := rfl @[simp] theorem lowerCrossingTime_zero : lowerCrossingTime a b f N 0 = hitting f (Set.Iic a) ⊥ N := rfl theorem upperCrossingTime_succ : upperCrossingTime a b f N (n + 1) ω = hitting f (Set.Ici b) (lowerCrossingTimeAux a f (upperCrossingTime a b f N n ω) N ω) N ω := by rw [upperCrossingTime] theorem upperCrossingTime_succ_eq (ω : Ω) : upperCrossingTime a b f N (n + 1) ω = hitting f (Set.Ici b) (lowerCrossingTime a b f N n ω) N ω := by simp only [upperCrossingTime_succ] rfl end section ConditionallyCompleteLinearOrderBot variable [ConditionallyCompleteLinearOrderBot ι] variable {a b : ℝ} {f : ι → Ω → ℝ} {N : ι} {n m : ℕ} {ω : Ω} theorem upperCrossingTime_le : upperCrossingTime a b f N n ω ≤ N := by cases n · simp only [upperCrossingTime_zero, Pi.bot_apply, bot_le] · simp only [upperCrossingTime_succ, hitting_le] @[simp] theorem upperCrossingTime_zero' : upperCrossingTime a b f ⊥ n ω = ⊥ := eq_bot_iff.2 upperCrossingTime_le theorem lowerCrossingTime_le : lowerCrossingTime a b f N n ω ≤ N := by simp only [lowerCrossingTime, hitting_le ω] theorem upperCrossingTime_le_lowerCrossingTime : upperCrossingTime a b f N n ω ≤ lowerCrossingTime a b f N n ω := by simp only [lowerCrossingTime, le_hitting upperCrossingTime_le ω] theorem lowerCrossingTime_le_upperCrossingTime_succ : lowerCrossingTime a b f N n ω ≤ upperCrossingTime a b f N (n + 1) ω := by rw [upperCrossingTime_succ] exact le_hitting lowerCrossingTime_le ω theorem lowerCrossingTime_mono (hnm : n ≤ m) : lowerCrossingTime a b f N n ω ≤ lowerCrossingTime a b f N m ω := by suffices Monotone fun n => lowerCrossingTime a b f N n ω by exact this hnm exact monotone_nat_of_le_succ fun n => le_trans lowerCrossingTime_le_upperCrossingTime_succ upperCrossingTime_le_lowerCrossingTime theorem upperCrossingTime_mono (hnm : n ≤ m) : upperCrossingTime a b f N n ω ≤ upperCrossingTime a b f N m ω := by suffices Monotone fun n => upperCrossingTime a b f N n ω by exact this hnm exact monotone_nat_of_le_succ fun n => le_trans upperCrossingTime_le_lowerCrossingTime lowerCrossingTime_le_upperCrossingTime_succ end ConditionallyCompleteLinearOrderBot	variable {a b : ℝ} {f : ℕ → Ω → ℝ} {N : ℕ} {n m : ℕ} {ω : Ω} theorem stoppedValue_lowerCrossingTime (h : lowerCrossingTime a b f N n ω ≠ N) : stoppedValue f (lowerCrossingTime a b f N n) ω ≤ a := by obtain ⟨j, hj₁, hj₂⟩ := (hitting_le_iff_of_lt _ (lt_of_le_of_ne lowerCrossingTime_le h)).1 le_rfl	Mathlib/Probability/Martingale/Upcrossing.lean	212	216
/- Copyright (c) 2022 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers, Heather Macbeth -/ import Mathlib.Analysis.SpecialFunctions.Complex.Circle import Mathlib.Geometry.Euclidean.Angle.Oriented.Basic /-! # Rotations by oriented angles. This file defines rotations by oriented angles in real inner product spaces. ## Main definitions * `Orientation.rotation` is the rotation by an oriented angle with respect to an orientation. -/ noncomputable section open Module Complex open scoped Real RealInnerProductSpace ComplexConjugate namespace Orientation attribute [local instance] Complex.finrank_real_complex_fact variable {V V' : Type} variable [NormedAddCommGroup V] [NormedAddCommGroup V'] variable [InnerProductSpace ℝ V] [InnerProductSpace ℝ V'] variable [Fact (finrank ℝ V = 2)] [Fact (finrank ℝ V' = 2)] (o : Orientation ℝ V (Fin 2)) local notation "J" => o.rightAngleRotation /-- Auxiliary construction to build a rotation by the oriented angle `θ`. -/ def rotationAux (θ : Real.Angle) : V →ₗᵢ[ℝ] V := LinearMap.isometryOfInner (Real.Angle.cos θ • LinearMap.id + Real.Angle.sin θ • (LinearIsometryEquiv.toLinearEquiv J).toLinearMap) (by intro x y simp only [RCLike.conj_to_real, id, LinearMap.smul_apply, LinearMap.add_apply, LinearMap.id_coe, LinearEquiv.coe_coe, LinearIsometryEquiv.coe_toLinearEquiv, Orientation.areaForm_rightAngleRotation_left, Orientation.inner_rightAngleRotation_left, Orientation.inner_rightAngleRotation_right, inner_add_left, inner_smul_left, inner_add_right, inner_smul_right] linear_combination inner (𝕜 := ℝ) x y θ.cos_sq_add_sin_sq) @[simp] theorem rotationAux_apply (θ : Real.Angle) (x : V) : o.rotationAux θ x = Real.Angle.cos θ • x + Real.Angle.sin θ • J x := rfl /-- A rotation by the oriented angle `θ`. -/ def rotation (θ : Real.Angle) : V ≃ₗᵢ[ℝ] V := LinearIsometryEquiv.ofLinearIsometry (o.rotationAux θ) (Real.Angle.cos θ • LinearMap.id - Real.Angle.sin θ • (LinearIsometryEquiv.toLinearEquiv J).toLinearMap) (by ext x convert congr_arg (fun t : ℝ => t • x) θ.cos_sq_add_sin_sq using 1 · simp only [o.rightAngleRotation_rightAngleRotation, o.rotationAux_apply, Function.comp_apply, id, LinearEquiv.coe_coe, LinearIsometry.coe_toLinearMap, LinearIsometryEquiv.coe_toLinearEquiv, map_smul, map_sub, LinearMap.coe_comp, LinearMap.id_coe, LinearMap.smul_apply, LinearMap.sub_apply] module · simp) (by ext x convert congr_arg (fun t : ℝ => t • x) θ.cos_sq_add_sin_sq using 1 · simp only [o.rightAngleRotation_rightAngleRotation, o.rotationAux_apply, Function.comp_apply, id, LinearEquiv.coe_coe, LinearIsometry.coe_toLinearMap, LinearIsometryEquiv.coe_toLinearEquiv, map_add, map_smul, LinearMap.coe_comp, LinearMap.id_coe, LinearMap.smul_apply, LinearMap.sub_apply] module · simp) theorem rotation_apply (θ : Real.Angle) (x : V) : o.rotation θ x = Real.Angle.cos θ • x + Real.Angle.sin θ • J x := rfl theorem rotation_symm_apply (θ : Real.Angle) (x : V) : (o.rotation θ).symm x = Real.Angle.cos θ • x - Real.Angle.sin θ • J x := rfl theorem rotation_eq_matrix_toLin (θ : Real.Angle) {x : V} (hx : x ≠ 0) : (o.rotation θ).toLinearMap = Matrix.toLin (o.basisRightAngleRotation x hx) (o.basisRightAngleRotation x hx) !![θ.cos, -θ.sin; θ.sin, θ.cos] := by apply (o.basisRightAngleRotation x hx).ext intro i fin_cases i · rw [Matrix.toLin_self] simp [rotation_apply, Fin.sum_univ_succ] · rw [Matrix.toLin_self] simp [rotation_apply, Fin.sum_univ_succ, add_comm] /-- The determinant of `rotation` (as a linear map) is equal to `1`. -/ @[simp] theorem det_rotation (θ : Real.Angle) : LinearMap.det (o.rotation θ).toLinearMap = 1 := by haveI : Nontrivial V := nontrivial_of_finrank_eq_succ (@Fact.out (finrank ℝ V = 2) _) obtain ⟨x, hx⟩ : ∃ x, x ≠ (0 : V) := exists_ne (0 : V) rw [o.rotation_eq_matrix_toLin θ hx] simpa [sq] using θ.cos_sq_add_sin_sq /-- The determinant of `rotation` (as a linear equiv) is equal to `1`. -/ @[simp] theorem linearEquiv_det_rotation (θ : Real.Angle) : LinearEquiv.det (o.rotation θ).toLinearEquiv = 1 := Units.ext <\| by -- Porting note: Lean can't see through `LinearEquiv.coe_det` and needed the rewrite -- in mathlib3 this was just `units.ext <\| o.det_rotation θ` simpa only [LinearEquiv.coe_det, Units.val_one] using o.det_rotation θ /-- The inverse of `rotation` is rotation by the negation of the angle. -/ @[simp] theorem rotation_symm (θ : Real.Angle) : (o.rotation θ).symm = o.rotation (-θ) := by ext; simp [o.rotation_apply, o.rotation_symm_apply, sub_eq_add_neg] /-- Rotation by 0 is the identity. -/ @[simp] theorem rotation_zero : o.rotation 0 = LinearIsometryEquiv.refl ℝ V := by ext; simp [rotation] /-- Rotation by π is negation. -/ @[simp] theorem rotation_pi : o.rotation π = LinearIsometryEquiv.neg ℝ := by ext x simp [rotation] /-- Rotation by π is negation. -/ theorem rotation_pi_apply (x : V) : o.rotation π x = -x := by simp /-- Rotation by π / 2 is the "right-angle-rotation" map `J`. -/ theorem rotation_pi_div_two : o.rotation (π / 2 : ℝ) = J := by ext x simp [rotation] /-- Rotating twice is equivalent to rotating by the sum of the angles. -/ @[simp] theorem rotation_rotation (θ₁ θ₂ : Real.Angle) (x : V) : o.rotation θ₁ (o.rotation θ₂ x) = o.rotation (θ₁ + θ₂) x := by simp only [o.rotation_apply, Real.Angle.cos_add, Real.Angle.sin_add, LinearIsometryEquiv.map_add, LinearIsometryEquiv.trans_apply, map_smul, rightAngleRotation_rightAngleRotation] module /-- Rotating twice is equivalent to rotating by the sum of the angles. -/ @[simp] theorem rotation_trans (θ₁ θ₂ : Real.Angle) : (o.rotation θ₁).trans (o.rotation θ₂) = o.rotation (θ₂ + θ₁) := LinearIsometryEquiv.ext fun _ => by rw [← rotation_rotation, LinearIsometryEquiv.trans_apply] /-- Rotating the first of two vectors by `θ` scales their Kahler form by `cos θ - sin θ * I`. -/ @[simp] theorem kahler_rotation_left (x y : V) (θ : Real.Angle) : o.kahler (o.rotation θ x) y = conj (θ.toCircle : ℂ) * o.kahler x y := by -- Porting note: this needed the `Complex.conj_ofReal` instead of `RCLike.conj_ofReal`; -- I believe this is because the respective coercions are no longer defeq, and -- `Real.Angle.coe_toCircle` uses the `Complex` version. simp only [o.rotation_apply, map_add, map_mul, LinearMap.map_smulₛₗ, RingHom.id_apply, LinearMap.add_apply, LinearMap.smul_apply, real_smul, kahler_rightAngleRotation_left, Real.Angle.coe_toCircle, Complex.conj_ofReal, conj_I] ring /-- Negating a rotation is equivalent to rotation by π plus the angle. -/ theorem neg_rotation (θ : Real.Angle) (x : V) : -o.rotation θ x = o.rotation (π + θ) x := by rw [← o.rotation_pi_apply, rotation_rotation] /-- Negating a rotation by -π / 2 is equivalent to rotation by π / 2. -/ @[simp] theorem neg_rotation_neg_pi_div_two (x : V) : -o.rotation (-π / 2 : ℝ) x = o.rotation (π / 2 : ℝ) x := by rw [neg_rotation, ← Real.Angle.coe_add, neg_div, ← sub_eq_add_neg, sub_half] /-- Negating a rotation by π / 2 is equivalent to rotation by -π / 2. -/ theorem neg_rotation_pi_div_two (x : V) : -o.rotation (π / 2 : ℝ) x = o.rotation (-π / 2 : ℝ) x := (neg_eq_iff_eq_neg.mp <\| o.neg_rotation_neg_pi_div_two _).symm /-- Rotating the first of two vectors by `θ` scales their Kahler form by `cos (-θ) + sin (-θ) * I`. -/ theorem kahler_rotation_left' (x y : V) (θ : Real.Angle) : o.kahler (o.rotation θ x) y = (-θ).toCircle * o.kahler x y := by simp only [Real.Angle.toCircle_neg, Circle.coe_inv_eq_conj, kahler_rotation_left] /-- Rotating the second of two vectors by `θ` scales their Kahler form by `cos θ + sin θ * I`. -/ @[simp] theorem kahler_rotation_right (x y : V) (θ : Real.Angle) : o.kahler x (o.rotation θ y) = θ.toCircle * o.kahler x y := by simp only [o.rotation_apply, map_add, LinearMap.map_smulₛₗ, RingHom.id_apply, real_smul, kahler_rightAngleRotation_right, Real.Angle.coe_toCircle] ring /-- Rotating the first vector by `θ` subtracts `θ` from the angle between two vectors. -/ @[simp] theorem oangle_rotation_left {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) (θ : Real.Angle) : o.oangle (o.rotation θ x) y = o.oangle x y - θ := by simp only [oangle, o.kahler_rotation_left'] rw [Complex.arg_mul_coe_angle, Real.Angle.arg_toCircle] · abel · exact Circle.coe_ne_zero _ · exact o.kahler_ne_zero hx hy /-- Rotating the second vector by `θ` adds `θ` to the angle between two vectors. -/ @[simp] theorem oangle_rotation_right {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) (θ : Real.Angle) : o.oangle x (o.rotation θ y) = o.oangle x y + θ := by simp only [oangle, o.kahler_rotation_right] rw [Complex.arg_mul_coe_angle, Real.Angle.arg_toCircle] · abel · exact Circle.coe_ne_zero _ · exact o.kahler_ne_zero hx hy /-- The rotation of a vector by `θ` has an angle of `-θ` from that vector. -/ @[simp] theorem oangle_rotation_self_left {x : V} (hx : x ≠ 0) (θ : Real.Angle) : o.oangle (o.rotation θ x) x = -θ := by simp [hx] /-- A vector has an angle of `θ` from the rotation of that vector by `θ`. -/ @[simp] theorem oangle_rotation_self_right {x : V} (hx : x ≠ 0) (θ : Real.Angle) : o.oangle x (o.rotation θ x) = θ := by simp [hx] /-- Rotating the first vector by the angle between the two vectors results in an angle of 0. -/	@[simp] theorem oangle_rotation_oangle_left (x y : V) : o.oangle (o.rotation (o.oangle x y) x) y = 0 := by by_cases hx : x = 0 · simp [hx] · by_cases hy : y = 0 · simp [hy] · simp [hx, hy]	Mathlib/Geometry/Euclidean/Angle/Oriented/Rotation.lean	226	232
/- Copyright (c) 2023 Kalle Kytölä. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kalle Kytölä -/ import Mathlib.MeasureTheory.Measure.ProbabilityMeasure import Mathlib.MeasureTheory.Measure.Prod /-! # Products of finite measures and probability measures This file introduces binary products of finite measures and probability measures. The constructions are obtained from special cases of products of general measures. Taking products nevertheless has specific properties in the cases of finite measures and probability measures, notably the fact that the product measures depend continuously on their factors in the topology of weak convergence when the underlying space is metrizable and separable. ## Main definitions * `MeasureTheory.FiniteMeasure.prod`: The product of two finite measures. * `MeasureTheory.ProbabilityMeasure.prod`: The product of two probability measures. ## TODO * Add continuous dependence of the product measures on the factors. -/ open MeasureTheory Topology Metric Filter Set ENNReal NNReal open scoped Topology ENNReal NNReal BoundedContinuousFunction namespace MeasureTheory section FiniteMeasure_product namespace FiniteMeasure variable {α : Type} [MeasurableSpace α] {β : Type} [MeasurableSpace β] /-- The binary product of finite measures. -/ noncomputable def prod (μ : FiniteMeasure α) (ν : FiniteMeasure β) : FiniteMeasure (α × β) := ⟨μ.toMeasure.prod ν.toMeasure, inferInstance⟩ variable (μ : FiniteMeasure α) (ν : FiniteMeasure β) @[simp] lemma toMeasure_prod : (μ.prod ν).toMeasure = μ.toMeasure.prod ν.toMeasure := rfl lemma prod_apply (s : Set (α × β)) (s_mble : MeasurableSet s) : μ.prod ν s = ENNReal.toNNReal (∫⁻ x, ν.toMeasure (Prod.mk x ⁻¹' s) ∂μ) := by simp [coeFn_def, Measure.prod_apply s_mble] lemma prod_apply_symm (s : Set (α × β)) (s_mble : MeasurableSet s) : μ.prod ν s = ENNReal.toNNReal (∫⁻ y, μ.toMeasure ((fun x ↦ ⟨x, y⟩) ⁻¹' s) ∂ν) := by simp [coeFn_def, Measure.prod_apply_symm s_mble] lemma prod_prod (s : Set α) (t : Set β) : μ.prod ν (s ×ˢ t) = μ s * ν t := by simp [coeFn_def] @[simp] lemma mass_prod : (μ.prod ν).mass = μ.mass * ν.mass := by simp only [coeFn_def, mass, univ_prod_univ.symm, toMeasure_prod] rw [← ENNReal.toNNReal_mul] exact congr_arg ENNReal.toNNReal (Measure.prod_prod univ univ)	@[simp] lemma zero_prod : (0 : FiniteMeasure α).prod ν = 0 := by rw [← mass_zero_iff, mass_prod, zero_mass, zero_mul]	Mathlib/MeasureTheory/Measure/FiniteMeasureProd.lean	64	65
/- Copyright (c) 2021 Yaël Dillies, Bhavik Mehta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies, Bhavik Mehta -/ import Mathlib.Analysis.Convex.Topology import Mathlib.Analysis.NormedSpace.Pointwise import Mathlib.Analysis.Seminorm import Mathlib.Analysis.LocallyConvex.Bounded import Mathlib.Analysis.RCLike.Basic /-! # The Minkowski functional This file defines the Minkowski functional, aka gauge. The Minkowski functional of a set `s` is the function which associates each point to how much you need to scale `s` for `x` to be inside it. When `s` is symmetric, convex and absorbent, its gauge is a seminorm. Reciprocally, any seminorm arises as the gauge of some set, namely its unit ball. This induces the equivalence of seminorms and locally convex topological vector spaces. ## Main declarations For a real vector space, * `gauge`: Aka Minkowski functional. `gauge s x` is the least (actually, an infimum) `r` such that `x ∈ r • s`. * `gaugeSeminorm`: The Minkowski functional as a seminorm, when `s` is symmetric, convex and absorbent. ## References * [H. H. Schaefer, Topological Vector Spaces][schaefer1966] ## Tags Minkowski functional, gauge -/ open NormedField Set open scoped Pointwise Topology NNReal noncomputable section variable {𝕜 E : Type*} section AddCommGroup variable [AddCommGroup E] [Module ℝ E] /-- The Minkowski functional. Given a set `s` in a real vector space, `gauge s` is the functional which sends `x : E` to the smallest `r : ℝ` such that `x` is in `s` scaled by `r`. -/ def gauge (s : Set E) (x : E) : ℝ := sInf { r : ℝ \| 0 < r ∧ x ∈ r • s } variable {s t : Set E} {x : E} {a : ℝ} theorem gauge_def : gauge s x = sInf ({ r ∈ Set.Ioi (0 : ℝ) \| x ∈ r • s }) := rfl /-- An alternative definition of the gauge using scalar multiplication on the element rather than on the set. -/ theorem gauge_def' : gauge s x = sInf {r ∈ Set.Ioi (0 : ℝ) \| r⁻¹ • x ∈ s} := by congrm sInf {r \| ?_} exact and_congr_right fun hr => mem_smul_set_iff_inv_smul_mem₀ hr.ne' _ _ private theorem gauge_set_bddBelow : BddBelow { r : ℝ \| 0 < r ∧ x ∈ r • s } := ⟨0, fun _ hr => hr.1.le⟩ /-- If the given subset is `Absorbent` then the set we take an infimum over in `gauge` is nonempty, which is useful for proving many properties about the gauge. -/ theorem Absorbent.gauge_set_nonempty (absorbs : Absorbent ℝ s) : { r : ℝ \| 0 < r ∧ x ∈ r • s }.Nonempty := let ⟨r, hr₁, hr₂⟩ := (absorbs x).exists_pos ⟨r, hr₁, hr₂ r (Real.norm_of_nonneg hr₁.le).ge rfl⟩ theorem gauge_mono (hs : Absorbent ℝ s) (h : s ⊆ t) : gauge t ≤ gauge s := fun _ => csInf_le_csInf gauge_set_bddBelow hs.gauge_set_nonempty fun _ hr => ⟨hr.1, smul_set_mono h hr.2⟩ theorem exists_lt_of_gauge_lt (absorbs : Absorbent ℝ s) (h : gauge s x < a) : ∃ b, 0 < b ∧ b < a ∧ x ∈ b • s := by obtain ⟨b, ⟨hb, hx⟩, hba⟩ := exists_lt_of_csInf_lt absorbs.gauge_set_nonempty h exact ⟨b, hb, hba, hx⟩ /-- The gauge evaluated at `0` is always zero (mathematically this requires `0` to be in the set `s` but, the real infimum of the empty set in Lean being defined as `0`, it holds unconditionally). -/ @[simp] theorem gauge_zero : gauge s 0 = 0 := by rw [gauge_def'] by_cases h : (0 : E) ∈ s · simp only [smul_zero, sep_true, h, csInf_Ioi] · simp only [smul_zero, sep_false, h, Real.sInf_empty] @[simp] theorem gauge_zero' : gauge (0 : Set E) = 0 := by	ext x rw [gauge_def'] obtain rfl \| hx := eq_or_ne x 0 · simp only [csInf_Ioi, mem_zero, Pi.zero_apply, eq_self_iff_true, sep_true, smul_zero] · simp only [mem_zero, Pi.zero_apply, inv_eq_zero, smul_eq_zero]	Mathlib/Analysis/Convex/Gauge.lean	95	99
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.MonoidAlgebra.Degree import Mathlib.Algebra.Order.Ring.WithTop import Mathlib.Algebra.Polynomial.Basic import Mathlib.Data.Nat.Cast.WithTop import Mathlib.Data.Nat.SuccPred import Mathlib.Order.SuccPred.WithBot /-! # Degree of univariate polynomials ## Main definitions * `Polynomial.degree`: the degree of a polynomial, where `0` has degree `⊥` * `Polynomial.natDegree`: the degree of a polynomial, where `0` has degree `0` * `Polynomial.leadingCoeff`: the leading coefficient of a polynomial * `Polynomial.Monic`: a polynomial is monic if its leading coefficient is 0 * `Polynomial.nextCoeff`: the next coefficient after the leading coefficient ## Main results * `Polynomial.degree_eq_natDegree`: the degree and natDegree coincide for nonzero polynomials -/ noncomputable section open Finsupp Finset open Polynomial namespace Polynomial universe u v variable {R : Type u} {S : Type v} {a b c d : R} {n m : ℕ} section Semiring variable [Semiring R] {p q r : R[X]} /-- `degree p` is the degree of the polynomial `p`, i.e. the largest `X`-exponent in `p`. `degree p = some n` when `p ≠ 0` and `n` is the highest power of `X` that appears in `p`, otherwise `degree 0 = ⊥`. -/ def degree (p : R[X]) : WithBot ℕ := p.support.max /-- `natDegree p` forces `degree p` to ℕ, by defining `natDegree 0 = 0`. -/ def natDegree (p : R[X]) : ℕ := (degree p).unbotD 0 /-- `leadingCoeff p` gives the coefficient of the highest power of `X` in `p`. -/ def leadingCoeff (p : R[X]) : R := coeff p (natDegree p) /-- a polynomial is `Monic` if its leading coefficient is 1 -/ def Monic (p : R[X]) := leadingCoeff p = (1 : R) theorem Monic.def : Monic p ↔ leadingCoeff p = 1 := Iff.rfl instance Monic.decidable [DecidableEq R] : Decidable (Monic p) := by unfold Monic; infer_instance @[simp] theorem Monic.leadingCoeff {p : R[X]} (hp : p.Monic) : leadingCoeff p = 1 := hp theorem Monic.coeff_natDegree {p : R[X]} (hp : p.Monic) : p.coeff p.natDegree = 1 := hp @[simp] theorem degree_zero : degree (0 : R[X]) = ⊥ := rfl @[simp] theorem natDegree_zero : natDegree (0 : R[X]) = 0 := rfl @[simp] theorem coeff_natDegree : coeff p (natDegree p) = leadingCoeff p := rfl @[simp] theorem degree_eq_bot : degree p = ⊥ ↔ p = 0 := ⟨fun h => support_eq_empty.1 (Finset.max_eq_bot.1 h), fun h => h.symm ▸ rfl⟩ theorem degree_ne_bot : degree p ≠ ⊥ ↔ p ≠ 0 := degree_eq_bot.not theorem degree_eq_natDegree (hp : p ≠ 0) : degree p = (natDegree p : WithBot ℕ) := by let ⟨n, hn⟩ := not_forall.1 (mt Option.eq_none_iff_forall_not_mem.2 (mt degree_eq_bot.1 hp)) have hn : degree p = some n := Classical.not_not.1 hn rw [natDegree, hn]; rfl theorem degree_eq_iff_natDegree_eq {p : R[X]} {n : ℕ} (hp : p ≠ 0) : p.degree = n ↔ p.natDegree = n := by rw [degree_eq_natDegree hp]; exact WithBot.coe_eq_coe theorem degree_eq_iff_natDegree_eq_of_pos {p : R[X]} {n : ℕ} (hn : 0 < n) : p.degree = n ↔ p.natDegree = n := by obtain rfl\|h := eq_or_ne p 0 · simp [hn.ne] · exact degree_eq_iff_natDegree_eq h theorem natDegree_eq_of_degree_eq_some {p : R[X]} {n : ℕ} (h : degree p = n) : natDegree p = n := by rw [natDegree, h, Nat.cast_withBot, WithBot.unbotD_coe] theorem degree_ne_of_natDegree_ne {n : ℕ} : p.natDegree ≠ n → degree p ≠ n := mt natDegree_eq_of_degree_eq_some @[simp] theorem degree_le_natDegree : degree p ≤ natDegree p := WithBot.giUnbotDBot.gc.le_u_l _ theorem natDegree_eq_of_degree_eq [Semiring S] {q : S[X]} (h : degree p = degree q) : natDegree p = natDegree q := by unfold natDegree; rw [h] theorem le_degree_of_ne_zero (h : coeff p n ≠ 0) : (n : WithBot ℕ) ≤ degree p := by rw [Nat.cast_withBot] exact Finset.le_sup (mem_support_iff.2 h) theorem degree_mono [Semiring S] {f : R[X]} {g : S[X]} (h : f.support ⊆ g.support) : f.degree ≤ g.degree := Finset.sup_mono h theorem degree_le_degree (h : coeff q (natDegree p) ≠ 0) : degree p ≤ degree q := by by_cases hp : p = 0 · rw [hp, degree_zero] exact bot_le · rw [degree_eq_natDegree hp] exact le_degree_of_ne_zero h theorem natDegree_le_iff_degree_le {n : ℕ} : natDegree p ≤ n ↔ degree p ≤ n := WithBot.unbotD_le_iff (fun _ ↦ bot_le) theorem natDegree_lt_iff_degree_lt (hp : p ≠ 0) : p.natDegree < n ↔ p.degree < ↑n := WithBot.unbotD_lt_iff (absurd · (degree_eq_bot.not.mpr hp)) alias ⟨degree_le_of_natDegree_le, natDegree_le_of_degree_le⟩ := natDegree_le_iff_degree_le theorem natDegree_le_natDegree [Semiring S] {q : S[X]} (hpq : p.degree ≤ q.degree) : p.natDegree ≤ q.natDegree := WithBot.giUnbotDBot.gc.monotone_l hpq @[simp] theorem degree_C (ha : a ≠ 0) : degree (C a) = (0 : WithBot ℕ) := by rw [degree, ← monomial_zero_left, support_monomial 0 ha, max_eq_sup_coe, sup_singleton, WithBot.coe_zero] theorem degree_C_le : degree (C a) ≤ 0 := by by_cases h : a = 0 · rw [h, C_0] exact bot_le · rw [degree_C h] theorem degree_C_lt : degree (C a) < 1 := degree_C_le.trans_lt <\| WithBot.coe_lt_coe.mpr zero_lt_one theorem degree_one_le : degree (1 : R[X]) ≤ (0 : WithBot ℕ) := by rw [← C_1]; exact degree_C_le @[simp] theorem natDegree_C (a : R) : natDegree (C a) = 0 := by by_cases ha : a = 0 · have : C a = 0 := by rw [ha, C_0] rw [natDegree, degree_eq_bot.2 this, WithBot.unbotD_bot] · rw [natDegree, degree_C ha, WithBot.unbotD_zero] @[simp] theorem natDegree_one : natDegree (1 : R[X]) = 0 := natDegree_C 1 @[simp] theorem natDegree_natCast (n : ℕ) : natDegree (n : R[X]) = 0 := by simp only [← C_eq_natCast, natDegree_C] @[simp] theorem natDegree_ofNat (n : ℕ) [Nat.AtLeastTwo n] : natDegree (ofNat(n) : R[X]) = 0 := natDegree_natCast _ theorem degree_natCast_le (n : ℕ) : degree (n : R[X]) ≤ 0 := degree_le_of_natDegree_le (by simp) @[simp] theorem degree_monomial (n : ℕ) (ha : a ≠ 0) : degree (monomial n a) = n := by rw [degree, support_monomial n ha, max_singleton, Nat.cast_withBot] @[simp] theorem degree_C_mul_X_pow (n : ℕ) (ha : a ≠ 0) : degree (C a * X ^ n) = n := by rw [C_mul_X_pow_eq_monomial, degree_monomial n ha] theorem degree_C_mul_X (ha : a ≠ 0) : degree (C a * X) = 1 := by simpa only [pow_one] using degree_C_mul_X_pow 1 ha theorem degree_monomial_le (n : ℕ) (a : R) : degree (monomial n a) ≤ n := letI := Classical.decEq R if h : a = 0 then by rw [h, (monomial n).map_zero, degree_zero]; exact bot_le else le_of_eq (degree_monomial n h) theorem degree_C_mul_X_pow_le (n : ℕ) (a : R) : degree (C a * X ^ n) ≤ n := by rw [C_mul_X_pow_eq_monomial] apply degree_monomial_le theorem degree_C_mul_X_le (a : R) : degree (C a * X) ≤ 1 := by simpa only [pow_one] using degree_C_mul_X_pow_le 1 a @[simp] theorem natDegree_C_mul_X_pow (n : ℕ) (a : R) (ha : a ≠ 0) : natDegree (C a * X ^ n) = n := natDegree_eq_of_degree_eq_some (degree_C_mul_X_pow n ha) @[simp] theorem natDegree_C_mul_X (a : R) (ha : a ≠ 0) : natDegree (C a * X) = 1 := by simpa only [pow_one] using natDegree_C_mul_X_pow 1 a ha @[simp] theorem natDegree_monomial [DecidableEq R] (i : ℕ) (r : R) : natDegree (monomial i r) = if r = 0 then 0 else i := by split_ifs with hr · simp [hr] · rw [← C_mul_X_pow_eq_monomial, natDegree_C_mul_X_pow i r hr] theorem natDegree_monomial_le (a : R) {m : ℕ} : (monomial m a).natDegree ≤ m := by classical rw [Polynomial.natDegree_monomial] split_ifs exacts [Nat.zero_le _, le_rfl] theorem natDegree_monomial_eq (i : ℕ) {r : R} (r0 : r ≠ 0) : (monomial i r).natDegree = i := letI := Classical.decEq R Eq.trans (natDegree_monomial _ _) (if_neg r0) theorem coeff_ne_zero_of_eq_degree (hn : degree p = n) : coeff p n ≠ 0 := fun h => mem_support_iff.mp (mem_of_max hn) h theorem degree_X_pow_le (n : ℕ) : degree (X ^ n : R[X]) ≤ n := by simpa only [C_1, one_mul] using degree_C_mul_X_pow_le n (1 : R) theorem degree_X_le : degree (X : R[X]) ≤ 1 := degree_monomial_le _ _ theorem natDegree_X_le : (X : R[X]).natDegree ≤ 1 := natDegree_le_of_degree_le degree_X_le theorem withBotSucc_degree_eq_natDegree_add_one (h : p ≠ 0) : p.degree.succ = p.natDegree + 1 := by rw [degree_eq_natDegree h] exact WithBot.succ_coe p.natDegree end Semiring section NonzeroSemiring variable [Semiring R] [Nontrivial R] {p q : R[X]} @[simp] theorem degree_one : degree (1 : R[X]) = (0 : WithBot ℕ) := degree_C one_ne_zero @[simp] theorem degree_X : degree (X : R[X]) = 1 := degree_monomial _ one_ne_zero @[simp] theorem natDegree_X : (X : R[X]).natDegree = 1 := natDegree_eq_of_degree_eq_some degree_X end NonzeroSemiring section Ring variable [Ring R] @[simp] theorem degree_neg (p : R[X]) : degree (-p) = degree p := by unfold degree; rw [support_neg] theorem degree_neg_le_of_le {a : WithBot ℕ} {p : R[X]} (hp : degree p ≤ a) : degree (-p) ≤ a := p.degree_neg.le.trans hp @[simp] theorem natDegree_neg (p : R[X]) : natDegree (-p) = natDegree p := by simp [natDegree] theorem natDegree_neg_le_of_le {p : R[X]} (hp : natDegree p ≤ m) : natDegree (-p) ≤ m := (natDegree_neg p).le.trans hp @[simp] theorem natDegree_intCast (n : ℤ) : natDegree (n : R[X]) = 0 := by rw [← C_eq_intCast, natDegree_C] theorem degree_intCast_le (n : ℤ) : degree (n : R[X]) ≤ 0 := degree_le_of_natDegree_le (by simp) @[simp] theorem leadingCoeff_neg (p : R[X]) : (-p).leadingCoeff = -p.leadingCoeff := by rw [leadingCoeff, leadingCoeff, natDegree_neg, coeff_neg] end Ring section Semiring variable [Semiring R] {p : R[X]} /-- The second-highest coefficient, or 0 for constants -/ def nextCoeff (p : R[X]) : R := if p.natDegree = 0 then 0 else p.coeff (p.natDegree - 1) lemma nextCoeff_eq_zero : p.nextCoeff = 0 ↔ p.natDegree = 0 ∨ 0 < p.natDegree ∧ p.coeff (p.natDegree - 1) = 0 := by simp [nextCoeff, or_iff_not_imp_left, pos_iff_ne_zero]; aesop lemma nextCoeff_ne_zero : p.nextCoeff ≠ 0 ↔ p.natDegree ≠ 0 ∧ p.coeff (p.natDegree - 1) ≠ 0 := by simp [nextCoeff] @[simp] theorem nextCoeff_C_eq_zero (c : R) : nextCoeff (C c) = 0 := by rw [nextCoeff] simp theorem nextCoeff_of_natDegree_pos (hp : 0 < p.natDegree) : nextCoeff p = p.coeff (p.natDegree - 1) := by rw [nextCoeff, if_neg] contrapose! hp simpa variable {p q : R[X]} {ι : Type} theorem degree_add_le (p q : R[X]) : degree (p + q) ≤ max (degree p) (degree q) := by simpa only [degree, ← support_toFinsupp, toFinsupp_add] using AddMonoidAlgebra.sup_support_add_le _ _ _ theorem degree_add_le_of_degree_le {p q : R[X]} {n : ℕ} (hp : degree p ≤ n) (hq : degree q ≤ n) : degree (p + q) ≤ n := (degree_add_le p q).trans <\| max_le hp hq theorem degree_add_le_of_le {a b : WithBot ℕ} (hp : degree p ≤ a) (hq : degree q ≤ b) : degree (p + q) ≤ max a b := (p.degree_add_le q).trans <\| max_le_max ‹_› ‹_› theorem natDegree_add_le (p q : R[X]) : natDegree (p + q) ≤ max (natDegree p) (natDegree q) := by rcases le_max_iff.1 (degree_add_le p q) with h \| h <;> simp [natDegree_le_natDegree h] theorem natDegree_add_le_of_degree_le {p q : R[X]} {n : ℕ} (hp : natDegree p ≤ n) (hq : natDegree q ≤ n) : natDegree (p + q) ≤ n := (natDegree_add_le p q).trans <\| max_le hp hq theorem natDegree_add_le_of_le (hp : natDegree p ≤ m) (hq : natDegree q ≤ n) : natDegree (p + q) ≤ max m n := (p.natDegree_add_le q).trans <\| max_le_max ‹_› ‹_› @[simp] theorem leadingCoeff_zero : leadingCoeff (0 : R[X]) = 0 := rfl @[simp] theorem leadingCoeff_eq_zero : leadingCoeff p = 0 ↔ p = 0 := ⟨fun h => Classical.by_contradiction fun hp => mt mem_support_iff.1 (Classical.not_not.2 h) (mem_of_max (degree_eq_natDegree hp)), fun h => h.symm ▸ leadingCoeff_zero⟩ theorem leadingCoeff_ne_zero : leadingCoeff p ≠ 0 ↔ p ≠ 0 := by rw [Ne, leadingCoeff_eq_zero] theorem leadingCoeff_eq_zero_iff_deg_eq_bot : leadingCoeff p = 0 ↔ degree p = ⊥ := by rw [leadingCoeff_eq_zero, degree_eq_bot] theorem natDegree_C_mul_X_pow_le (a : R) (n : ℕ) : natDegree (C a X ^ n) ≤ n := natDegree_le_iff_degree_le.2 <\| degree_C_mul_X_pow_le _ _ theorem degree_erase_le (p : R[X]) (n : ℕ) : degree (p.erase n) ≤ degree p := by rcases p with ⟨p⟩ simp only [erase_def, degree, coeff, support] apply sup_mono rw [Finsupp.support_erase] apply Finset.erase_subset theorem degree_erase_lt (hp : p ≠ 0) : degree (p.erase (natDegree p)) < degree p := by apply lt_of_le_of_ne (degree_erase_le _ _) rw [degree_eq_natDegree hp, degree, support_erase] exact fun h => not_mem_erase _ _ (mem_of_max h) theorem degree_update_le (p : R[X]) (n : ℕ) (a : R) : degree (p.update n a) ≤ max (degree p) n := by classical rw [degree, support_update] split_ifs · exact (Finset.max_mono (erase_subset _ _)).trans (le_max_left _ _) · rw [max_insert, max_comm] exact le_rfl theorem degree_sum_le (s : Finset ι) (f : ι → R[X]) : degree (∑ i ∈ s, f i) ≤ s.sup fun b => degree (f b) := Finset.cons_induction_on s (by simp only [sum_empty, sup_empty, degree_zero, le_refl]) fun a s has ih => calc degree (∑ i ∈ cons a s has, f i) ≤ max (degree (f a)) (degree (∑ i ∈ s, f i)) := by rw [Finset.sum_cons]; exact degree_add_le _ _ _ ≤ _ := by rw [sup_cons]; exact max_le_max le_rfl ih theorem degree_mul_le (p q : R[X]) : degree (p * q) ≤ degree p + degree q := by simpa only [degree, ← support_toFinsupp, toFinsupp_mul] using AddMonoidAlgebra.sup_support_mul_le (WithBot.coe_add _ _).le _ _ theorem degree_mul_le_of_le {a b : WithBot ℕ} (hp : degree p ≤ a) (hq : degree q ≤ b) : degree (p * q) ≤ a + b := (p.degree_mul_le _).trans <\| add_le_add ‹_› ‹_› theorem degree_pow_le (p : R[X]) : ∀ n : ℕ, degree (p ^ n) ≤ n • degree p \| 0 => by rw [pow_zero, zero_nsmul]; exact degree_one_le \| n + 1 => calc degree (p ^ (n + 1)) ≤ degree (p ^ n) + degree p := by rw [pow_succ]; exact degree_mul_le _ _ _ ≤ _ := by rw [succ_nsmul]; exact add_le_add_right (degree_pow_le _ _) _ theorem degree_pow_le_of_le {a : WithBot ℕ} (b : ℕ) (hp : degree p ≤ a) : degree (p ^ b) ≤ b * a := by induction b with \| zero => simp [degree_one_le] \| succ n hn => rw [Nat.cast_succ, add_mul, one_mul, pow_succ] exact degree_mul_le_of_le hn hp @[simp] theorem leadingCoeff_monomial (a : R) (n : ℕ) : leadingCoeff (monomial n a) = a := by classical by_cases ha : a = 0 · simp only [ha, (monomial n).map_zero, leadingCoeff_zero] · rw [leadingCoeff, natDegree_monomial, if_neg ha, coeff_monomial] simp theorem leadingCoeff_C_mul_X_pow (a : R) (n : ℕ) : leadingCoeff (C a * X ^ n) = a := by rw [C_mul_X_pow_eq_monomial, leadingCoeff_monomial] theorem leadingCoeff_C_mul_X (a : R) : leadingCoeff (C a * X) = a := by simpa only [pow_one] using leadingCoeff_C_mul_X_pow a 1 @[simp] theorem leadingCoeff_C (a : R) : leadingCoeff (C a) = a := leadingCoeff_monomial a 0 theorem leadingCoeff_X_pow (n : ℕ) : leadingCoeff ((X : R[X]) ^ n) = 1 := by simpa only [C_1, one_mul] using leadingCoeff_C_mul_X_pow (1 : R) n theorem leadingCoeff_X : leadingCoeff (X : R[X]) = 1 := by simpa only [pow_one] using @leadingCoeff_X_pow R _ 1 @[simp] theorem monic_X_pow (n : ℕ) : Monic (X ^ n : R[X]) := leadingCoeff_X_pow n @[simp] theorem monic_X : Monic (X : R[X]) := leadingCoeff_X theorem leadingCoeff_one : leadingCoeff (1 : R[X]) = 1 := leadingCoeff_C 1 @[simp] theorem monic_one : Monic (1 : R[X]) := leadingCoeff_C _ theorem Monic.ne_zero {R : Type} [Semiring R] [Nontrivial R] {p : R[X]} (hp : p.Monic) : p ≠ 0 := by rintro rfl simp [Monic] at hp theorem Monic.ne_zero_of_ne (h : (0 : R) ≠ 1) {p : R[X]} (hp : p.Monic) : p ≠ 0 := by nontriviality R exact hp.ne_zero theorem Monic.ne_zero_of_polynomial_ne {r} (hp : Monic p) (hne : q ≠ r) : p ≠ 0 := haveI := Nontrivial.of_polynomial_ne hne hp.ne_zero theorem natDegree_mul_le {p q : R[X]} : natDegree (p q) ≤ natDegree p + natDegree q := by apply natDegree_le_of_degree_le apply le_trans (degree_mul_le p q) rw [Nat.cast_add] apply add_le_add <;> apply degree_le_natDegree theorem natDegree_mul_le_of_le (hp : natDegree p ≤ m) (hg : natDegree q ≤ n) : natDegree (p * q) ≤ m + n := natDegree_mul_le.trans <\| add_le_add ‹_› ‹_› theorem natDegree_pow_le {p : R[X]} {n : ℕ} : (p ^ n).natDegree ≤ n * p.natDegree := by induction n with \| zero => simp \| succ i hi => rw [pow_succ, Nat.succ_mul] apply le_trans natDegree_mul_le (add_le_add_right hi _) theorem natDegree_pow_le_of_le (n : ℕ) (hp : natDegree p ≤ m) : natDegree (p ^ n) ≤ n * m := natDegree_pow_le.trans (Nat.mul_le_mul le_rfl ‹_›) theorem natDegree_eq_zero_iff_degree_le_zero : p.natDegree = 0 ↔ p.degree ≤ 0 := by rw [← nonpos_iff_eq_zero, natDegree_le_iff_degree_le, Nat.cast_zero] theorem degree_zero_le : degree (0 : R[X]) ≤ 0 := natDegree_eq_zero_iff_degree_le_zero.mp rfl theorem degree_le_iff_coeff_zero (f : R[X]) (n : WithBot ℕ) : degree f ≤ n ↔ ∀ m : ℕ, n < m → coeff f m = 0 := by simp only [degree, Finset.max, Finset.sup_le_iff, mem_support_iff, Ne, ← not_le, not_imp_comm, Nat.cast_withBot] theorem degree_lt_iff_coeff_zero (f : R[X]) (n : ℕ) : degree f < n ↔ ∀ m : ℕ, n ≤ m → coeff f m = 0 := by simp only [degree, Finset.sup_lt_iff (WithBot.bot_lt_coe n), mem_support_iff, WithBot.coe_lt_coe, ← @not_le ℕ, max_eq_sup_coe, Nat.cast_withBot, Ne, not_imp_not] theorem natDegree_pos_iff_degree_pos : 0 < natDegree p ↔ 0 < degree p := lt_iff_lt_of_le_iff_le natDegree_le_iff_degree_le end Semiring section NontrivialSemiring variable [Semiring R] [Nontrivial R] {p q : R[X]} (n : ℕ) @[simp] theorem degree_X_pow : degree ((X : R[X]) ^ n) = n := by rw [X_pow_eq_monomial, degree_monomial _ (one_ne_zero' R)] @[simp] theorem natDegree_X_pow : natDegree ((X : R[X]) ^ n) = n := natDegree_eq_of_degree_eq_some (degree_X_pow n) end NontrivialSemiring section Ring variable [Ring R] {p q : R[X]} theorem degree_sub_le (p q : R[X]) : degree (p - q) ≤ max (degree p) (degree q) := by simpa only [degree_neg q] using degree_add_le p (-q) theorem degree_sub_le_of_le {a b : WithBot ℕ} (hp : degree p ≤ a) (hq : degree q ≤ b) : degree (p - q) ≤ max a b := (p.degree_sub_le q).trans <\| max_le_max ‹_› ‹_› theorem natDegree_sub_le (p q : R[X]) : natDegree (p - q) ≤ max (natDegree p) (natDegree q) := by simpa only [← natDegree_neg q] using natDegree_add_le p (-q) theorem natDegree_sub_le_of_le (hp : natDegree p ≤ m) (hq : natDegree q ≤ n) : natDegree (p - q) ≤ max m n := (p.natDegree_sub_le q).trans <\| max_le_max ‹_› ‹_› theorem degree_sub_lt (hd : degree p = degree q) (hp0 : p ≠ 0) (hlc : leadingCoeff p = leadingCoeff q) : degree (p - q) < degree p := have hp : monomial (natDegree p) (leadingCoeff p) + p.erase (natDegree p) = p := monomial_add_erase _ _ have hq : monomial (natDegree q) (leadingCoeff q) + q.erase (natDegree q) = q := monomial_add_erase _ _ have hd' : natDegree p = natDegree q := by unfold natDegree; rw [hd] have hq0 : q ≠ 0 := mt degree_eq_bot.2 (hd ▸ mt degree_eq_bot.1 hp0) calc degree (p - q) = degree (erase (natDegree q) p + -erase (natDegree q) q) := by conv => lhs rw [← hp, ← hq, hlc, hd', add_sub_add_left_eq_sub, sub_eq_add_neg] _ ≤ max (degree (erase (natDegree q) p)) (degree (erase (natDegree q) q)) := (degree_neg (erase (natDegree q) q) ▸ degree_add_le _ _) _ < degree p := max_lt_iff.2 ⟨hd' ▸ degree_erase_lt hp0, hd.symm ▸ degree_erase_lt hq0⟩ theorem degree_X_sub_C_le (r : R) : (X - C r).degree ≤ 1 := (degree_sub_le _ _).trans (max_le degree_X_le (degree_C_le.trans zero_le_one)) theorem natDegree_X_sub_C_le (r : R) : (X - C r).natDegree ≤ 1 := natDegree_le_iff_degree_le.2 <\| degree_X_sub_C_le r end Ring end Polynomial		Mathlib/Algebra/Polynomial/Degree/Definitions.lean	597	601
/- Copyright (c) 2021 Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies -/ import Mathlib.Data.Finset.Preimage import Mathlib.Data.Finset.Prod import Mathlib.Order.Hom.WithTopBot import Mathlib.Order.Interval.Set.UnorderedInterval /-! # Locally finite orders This file defines locally finite orders. A locally finite order is an order for which all bounded intervals are finite. This allows to make sense of `Icc`/`Ico`/`Ioc`/`Ioo` as lists, multisets, or finsets. Further, if the order is bounded above (resp. below), then we can also make sense of the "unbounded" intervals `Ici`/`Ioi` (resp. `Iic`/`Iio`). Many theorems about these intervals can be found in `Mathlib.Order.Interval.Finset.Basic`. ## Examples Naturally occurring locally finite orders are `ℕ`, `ℤ`, `ℕ+`, `Fin n`, `α × β` the product of two locally finite orders, `α →₀ β` the finitely supported functions to a locally finite order `β`... ## Main declarations In a `LocallyFiniteOrder`, * `Finset.Icc`: Closed-closed interval as a finset. * `Finset.Ico`: Closed-open interval as a finset. * `Finset.Ioc`: Open-closed interval as a finset. * `Finset.Ioo`: Open-open interval as a finset. * `Finset.uIcc`: Unordered closed interval as a finset. In a `LocallyFiniteOrderTop`, * `Finset.Ici`: Closed-infinite interval as a finset. * `Finset.Ioi`: Open-infinite interval as a finset. In a `LocallyFiniteOrderBot`, * `Finset.Iic`: Infinite-open interval as a finset. * `Finset.Iio`: Infinite-closed interval as a finset. ## Instances A `LocallyFiniteOrder` instance can be built * for a subtype of a locally finite order. See `Subtype.locallyFiniteOrder`. * for the product of two locally finite orders. See `Prod.locallyFiniteOrder`. * for any fintype (but not as an instance). See `Fintype.toLocallyFiniteOrder`. * from a definition of `Finset.Icc` alone. See `LocallyFiniteOrder.ofIcc`. * by pulling back `LocallyFiniteOrder β` through an order embedding `f : α →o β`. See `OrderEmbedding.locallyFiniteOrder`. Instances for concrete types are proved in their respective files: * `ℕ` is in `Order.Interval.Finset.Nat` * `ℤ` is in `Data.Int.Interval` * `ℕ+` is in `Data.PNat.Interval` * `Fin n` is in `Order.Interval.Finset.Fin` * `Finset α` is in `Data.Finset.Interval` * `Σ i, α i` is in `Data.Sigma.Interval` Along, you will find lemmas about the cardinality of those finite intervals. ## TODO Provide the `LocallyFiniteOrder` instance for `α ×ₗ β` where `LocallyFiniteOrder α` and `Fintype β`. Provide the `LocallyFiniteOrder` instance for `α →₀ β` where `β` is locally finite. Provide the `LocallyFiniteOrder` instance for `Π₀ i, β i` where all the `β i` are locally finite. From `LinearOrder α`, `NoMaxOrder α`, `LocallyFiniteOrder α`, we can also define an order isomorphism `α ≃ ℕ` or `α ≃ ℤ`, depending on whether we have `OrderBot α` or `NoMinOrder α` and `Nonempty α`. When `OrderBot α`, we can match `a : α` to `#(Iio a)`. We can provide `SuccOrder α` from `LinearOrder α` and `LocallyFiniteOrder α` using ```lean lemma exists_min_greater [LinearOrder α] [LocallyFiniteOrder α] {x ub : α} (hx : x < ub) : ∃ lub, x < lub ∧ ∀ y, x < y → lub ≤ y := by -- very non golfed have h : (Finset.Ioc x ub).Nonempty := ⟨ub, Finset.mem_Ioc.2 ⟨hx, le_rfl⟩⟩ use Finset.min' (Finset.Ioc x ub) h constructor · exact (Finset.mem_Ioc.mp <\| Finset.min'_mem _ h).1 rintro y hxy obtain hy \| hy := le_total y ub · refine Finset.min'_le (Ioc x ub) y ?_ simp [] at · exact (Finset.min'_le _ _ (Finset.mem_Ioc.2 ⟨hx, le_rfl⟩)).trans hy ``` Note that the converse is not true. Consider `{-2^z \| z : ℤ} ∪ {2^z \| z : ℤ}`. Any element has a successor (and actually a predecessor as well), so it is a `SuccOrder`, but it's not locally finite as `Icc (-1) 1` is infinite. -/ open Finset Function /-- This is a mixin class describing a locally finite order, that is, is an order where bounded intervals are finite. When you don't care too much about definitional equality, you can use `LocallyFiniteOrder.ofIcc` or `LocallyFiniteOrder.ofFiniteIcc` to build a locally finite order from just `Finset.Icc`. -/ class LocallyFiniteOrder (α : Type) [Preorder α] where /-- Left-closed right-closed interval -/ finsetIcc : α → α → Finset α /-- Left-closed right-open interval -/ finsetIco : α → α → Finset α /-- Left-open right-closed interval -/ finsetIoc : α → α → Finset α /-- Left-open right-open interval -/ finsetIoo : α → α → Finset α /-- `x ∈ finsetIcc a b ↔ a ≤ x ∧ x ≤ b` -/ finset_mem_Icc : ∀ a b x : α, x ∈ finsetIcc a b ↔ a ≤ x ∧ x ≤ b /-- `x ∈ finsetIco a b ↔ a ≤ x ∧ x < b` -/ finset_mem_Ico : ∀ a b x : α, x ∈ finsetIco a b ↔ a ≤ x ∧ x < b /-- `x ∈ finsetIoc a b ↔ a < x ∧ x ≤ b` -/ finset_mem_Ioc : ∀ a b x : α, x ∈ finsetIoc a b ↔ a < x ∧ x ≤ b /-- `x ∈ finsetIoo a b ↔ a < x ∧ x < b` -/ finset_mem_Ioo : ∀ a b x : α, x ∈ finsetIoo a b ↔ a < x ∧ x < b /-- This mixin class describes an order where all intervals bounded below are finite. This is slightly weaker than `LocallyFiniteOrder` + `OrderTop` as it allows empty types. -/ class LocallyFiniteOrderTop (α : Type) [Preorder α] where /-- Left-open right-infinite interval -/ finsetIoi : α → Finset α /-- Left-closed right-infinite interval -/ finsetIci : α → Finset α /-- `x ∈ finsetIci a ↔ a ≤ x` -/ finset_mem_Ici : ∀ a x : α, x ∈ finsetIci a ↔ a ≤ x /-- `x ∈ finsetIoi a ↔ a < x` -/ finset_mem_Ioi : ∀ a x : α, x ∈ finsetIoi a ↔ a < x /-- This mixin class describes an order where all intervals bounded above are finite. This is slightly weaker than `LocallyFiniteOrder` + `OrderBot` as it allows empty types. -/ class LocallyFiniteOrderBot (α : Type) [Preorder α] where /-- Left-infinite right-open interval -/ finsetIio : α → Finset α /-- Left-infinite right-closed interval -/ finsetIic : α → Finset α /-- `x ∈ finsetIic a ↔ x ≤ a` -/ finset_mem_Iic : ∀ a x : α, x ∈ finsetIic a ↔ x ≤ a /-- `x ∈ finsetIio a ↔ x < a` -/ finset_mem_Iio : ∀ a x : α, x ∈ finsetIio a ↔ x < a /-- A constructor from a definition of `Finset.Icc` alone, the other ones being derived by removing the ends. As opposed to `LocallyFiniteOrder.ofIcc`, this one requires `DecidableLE` but only `Preorder`. -/ def LocallyFiniteOrder.ofIcc' (α : Type) [Preorder α] [DecidableLE α] (finsetIcc : α → α → Finset α) (mem_Icc : ∀ a b x, x ∈ finsetIcc a b ↔ a ≤ x ∧ x ≤ b) : LocallyFiniteOrder α where finsetIcc := finsetIcc finsetIco a b := {x ∈ finsetIcc a b \| ¬b ≤ x} finsetIoc a b := {x ∈ finsetIcc a b \| ¬x ≤ a} finsetIoo a b := {x ∈ finsetIcc a b \| ¬x ≤ a ∧ ¬b ≤ x} finset_mem_Icc := mem_Icc finset_mem_Ico a b x := by rw [Finset.mem_filter, mem_Icc, and_assoc, lt_iff_le_not_le] finset_mem_Ioc a b x := by rw [Finset.mem_filter, mem_Icc, and_right_comm, lt_iff_le_not_le] finset_mem_Ioo a b x := by rw [Finset.mem_filter, mem_Icc, and_and_and_comm, lt_iff_le_not_le, lt_iff_le_not_le] /-- A constructor from a definition of `Finset.Icc` alone, the other ones being derived by removing the ends. As opposed to `LocallyFiniteOrder.ofIcc'`, this one requires `PartialOrder` but only `DecidableEq`. -/ def LocallyFiniteOrder.ofIcc (α : Type) [PartialOrder α] [DecidableEq α] (finsetIcc : α → α → Finset α) (mem_Icc : ∀ a b x, x ∈ finsetIcc a b ↔ a ≤ x ∧ x ≤ b) : LocallyFiniteOrder α where finsetIcc := finsetIcc finsetIco a b := {x ∈ finsetIcc a b \| x ≠ b} finsetIoc a b := {x ∈ finsetIcc a b \| a ≠ x} finsetIoo a b := {x ∈ finsetIcc a b \| a ≠ x ∧ x ≠ b} finset_mem_Icc := mem_Icc finset_mem_Ico a b x := by rw [Finset.mem_filter, mem_Icc, and_assoc, lt_iff_le_and_ne] finset_mem_Ioc a b x := by rw [Finset.mem_filter, mem_Icc, and_right_comm, lt_iff_le_and_ne] finset_mem_Ioo a b x := by rw [Finset.mem_filter, mem_Icc, and_and_and_comm, lt_iff_le_and_ne, lt_iff_le_and_ne] /-- A constructor from a definition of `Finset.Ici` alone, the other ones being derived by removing the ends. As opposed to `LocallyFiniteOrderTop.ofIci`, this one requires `DecidableLE` but only `Preorder`. -/ def LocallyFiniteOrderTop.ofIci' (α : Type) [Preorder α] [DecidableLE α] (finsetIci : α → Finset α) (mem_Ici : ∀ a x, x ∈ finsetIci a ↔ a ≤ x) : LocallyFiniteOrderTop α where finsetIci := finsetIci finsetIoi a := {x ∈ finsetIci a \| ¬x ≤ a} finset_mem_Ici := mem_Ici finset_mem_Ioi a x := by rw [mem_filter, mem_Ici, lt_iff_le_not_le] /-- A constructor from a definition of `Finset.Ici` alone, the other ones being derived by removing the ends. As opposed to `LocallyFiniteOrderTop.ofIci'`, this one requires `PartialOrder` but only `DecidableEq`. -/ def LocallyFiniteOrderTop.ofIci (α : Type) [PartialOrder α] [DecidableEq α] (finsetIci : α → Finset α) (mem_Ici : ∀ a x, x ∈ finsetIci a ↔ a ≤ x) : LocallyFiniteOrderTop α where finsetIci := finsetIci finsetIoi a := {x ∈ finsetIci a \| a ≠ x} finset_mem_Ici := mem_Ici finset_mem_Ioi a x := by rw [mem_filter, mem_Ici, lt_iff_le_and_ne] /-- A constructor from a definition of `Finset.Iic` alone, the other ones being derived by removing the ends. As opposed to `LocallyFiniteOrderBot.ofIic`, this one requires `DecidableLE` but only `Preorder`. -/ def LocallyFiniteOrderBot.ofIic' (α : Type) [Preorder α] [DecidableLE α] (finsetIic : α → Finset α) (mem_Iic : ∀ a x, x ∈ finsetIic a ↔ x ≤ a) : LocallyFiniteOrderBot α where finsetIic := finsetIic finsetIio a := {x ∈ finsetIic a \| ¬a ≤ x} finset_mem_Iic := mem_Iic finset_mem_Iio a x := by rw [mem_filter, mem_Iic, lt_iff_le_not_le] /-- A constructor from a definition of `Finset.Iic` alone, the other ones being derived by removing the ends. As opposed to `LocallyFiniteOrderBot.ofIic'`, this one requires `PartialOrder` but only `DecidableEq`. -/ def LocallyFiniteOrderBot.ofIic (α : Type) [PartialOrder α] [DecidableEq α] (finsetIic : α → Finset α) (mem_Iic : ∀ a x, x ∈ finsetIic a ↔ x ≤ a) : LocallyFiniteOrderBot α where finsetIic := finsetIic finsetIio a := {x ∈ finsetIic a \| x ≠ a} finset_mem_Iic := mem_Iic finset_mem_Iio a x := by rw [mem_filter, mem_Iic, lt_iff_le_and_ne] variable {α β : Type} -- See note [reducible non-instances] /-- An empty type is locally finite. This is not an instance as it would not be defeq to more specific instances. -/ protected abbrev IsEmpty.toLocallyFiniteOrder [Preorder α] [IsEmpty α] : LocallyFiniteOrder α where finsetIcc := isEmptyElim finsetIco := isEmptyElim finsetIoc := isEmptyElim finsetIoo := isEmptyElim finset_mem_Icc := isEmptyElim finset_mem_Ico := isEmptyElim finset_mem_Ioc := isEmptyElim finset_mem_Ioo := isEmptyElim -- See note [reducible non-instances] /-- An empty type is locally finite. This is not an instance as it would not be defeq to more specific instances. -/ protected abbrev IsEmpty.toLocallyFiniteOrderTop [Preorder α] [IsEmpty α] : LocallyFiniteOrderTop α where finsetIci := isEmptyElim finsetIoi := isEmptyElim finset_mem_Ici := isEmptyElim finset_mem_Ioi := isEmptyElim -- See note [reducible non-instances] /-- An empty type is locally finite. This is not an instance as it would not be defeq to more specific instances. -/ protected abbrev IsEmpty.toLocallyFiniteOrderBot [Preorder α] [IsEmpty α] : LocallyFiniteOrderBot α where finsetIic := isEmptyElim finsetIio := isEmptyElim finset_mem_Iic := isEmptyElim finset_mem_Iio := isEmptyElim /-! ### Intervals as finsets -/ namespace Finset section Preorder variable [Preorder α] section LocallyFiniteOrder variable [LocallyFiniteOrder α] {a b x : α} /-- The finset $[a, b]$ of elements `x` such that `a ≤ x` and `x ≤ b`. Basically `Set.Icc a b` as a finset. -/ def Icc (a b : α) : Finset α := LocallyFiniteOrder.finsetIcc a b /-- The finset $[a, b)$ of elements `x` such that `a ≤ x` and `x < b`. Basically `Set.Ico a b` as a finset. -/ def Ico (a b : α) : Finset α := LocallyFiniteOrder.finsetIco a b /-- The finset $(a, b]$ of elements `x` such that `a < x` and `x ≤ b`. Basically `Set.Ioc a b` as a finset. -/ def Ioc (a b : α) : Finset α := LocallyFiniteOrder.finsetIoc a b /-- The finset $(a, b)$ of elements `x` such that `a < x` and `x < b`. Basically `Set.Ioo a b` as a finset. -/ def Ioo (a b : α) : Finset α := LocallyFiniteOrder.finsetIoo a b @[simp] theorem mem_Icc : x ∈ Icc a b ↔ a ≤ x ∧ x ≤ b := LocallyFiniteOrder.finset_mem_Icc a b x @[simp] theorem mem_Ico : x ∈ Ico a b ↔ a ≤ x ∧ x < b := LocallyFiniteOrder.finset_mem_Ico a b x @[simp] theorem mem_Ioc : x ∈ Ioc a b ↔ a < x ∧ x ≤ b := LocallyFiniteOrder.finset_mem_Ioc a b x @[simp] theorem mem_Ioo : x ∈ Ioo a b ↔ a < x ∧ x < b := LocallyFiniteOrder.finset_mem_Ioo a b x @[simp, norm_cast] theorem coe_Icc (a b : α) : (Icc a b : Set α) = Set.Icc a b := Set.ext fun _ => mem_Icc @[simp, norm_cast] theorem coe_Ico (a b : α) : (Ico a b : Set α) = Set.Ico a b := Set.ext fun _ => mem_Ico @[simp, norm_cast] theorem coe_Ioc (a b : α) : (Ioc a b : Set α) = Set.Ioc a b := Set.ext fun _ => mem_Ioc @[simp, norm_cast] theorem coe_Ioo (a b : α) : (Ioo a b : Set α) = Set.Ioo a b := Set.ext fun _ => mem_Ioo @[simp] theorem _root_.Fintype.card_Icc (a b : α) [Fintype (Set.Icc a b)] : Fintype.card (Set.Icc a b) = #(Icc a b) := Fintype.card_of_finset' _ fun _ ↦ by simp @[simp] theorem _root_.Fintype.card_Ico (a b : α) [Fintype (Set.Ico a b)] : Fintype.card (Set.Ico a b) = #(Ico a b) := Fintype.card_of_finset' _ fun _ ↦ by simp @[simp] theorem _root_.Fintype.card_Ioc (a b : α) [Fintype (Set.Ioc a b)] : Fintype.card (Set.Ioc a b) = #(Ioc a b) := Fintype.card_of_finset' _ fun _ ↦ by simp @[simp] theorem _root_.Fintype.card_Ioo (a b : α) [Fintype (Set.Ioo a b)] : Fintype.card (Set.Ioo a b) = #(Ioo a b) := Fintype.card_of_finset' _ fun _ ↦ by simp end LocallyFiniteOrder section LocallyFiniteOrderTop variable [LocallyFiniteOrderTop α] {a x : α} /-- The finset $[a, ∞)$ of elements `x` such that `a ≤ x`. Basically `Set.Ici a` as a finset. -/ def Ici (a : α) : Finset α := LocallyFiniteOrderTop.finsetIci a /-- The finset $(a, ∞)$ of elements `x` such that `a < x`. Basically `Set.Ioi a` as a finset. -/ def Ioi (a : α) : Finset α := LocallyFiniteOrderTop.finsetIoi a @[simp] theorem mem_Ici : x ∈ Ici a ↔ a ≤ x := LocallyFiniteOrderTop.finset_mem_Ici _ _ @[simp] theorem mem_Ioi : x ∈ Ioi a ↔ a < x := LocallyFiniteOrderTop.finset_mem_Ioi _ _ @[simp, norm_cast] theorem coe_Ici (a : α) : (Ici a : Set α) = Set.Ici a := Set.ext fun _ => mem_Ici @[simp, norm_cast] theorem coe_Ioi (a : α) : (Ioi a : Set α) = Set.Ioi a := Set.ext fun _ => mem_Ioi @[simp] theorem _root_.Fintype.card_Ici (a : α) [Fintype (Set.Ici a)] : Fintype.card (Set.Ici a) = #(Ici a) := Fintype.card_of_finset' _ fun _ ↦ by simp @[simp] theorem _root_.Fintype.card_Ioi (a : α) [Fintype (Set.Ioi a)] : Fintype.card (Set.Ioi a) = #(Ioi a) := Fintype.card_of_finset' _ fun _ ↦ by simp end LocallyFiniteOrderTop section LocallyFiniteOrderBot variable [LocallyFiniteOrderBot α] {a x : α} /-- The finset $(-∞, b]$ of elements `x` such that `x ≤ b`. Basically `Set.Iic b` as a finset. -/ def Iic (b : α) : Finset α := LocallyFiniteOrderBot.finsetIic b /-- The finset $(-∞, b)$ of elements `x` such that `x < b`. Basically `Set.Iio b` as a finset. -/ def Iio (b : α) : Finset α := LocallyFiniteOrderBot.finsetIio b @[simp] theorem mem_Iic : x ∈ Iic a ↔ x ≤ a := LocallyFiniteOrderBot.finset_mem_Iic _ _ @[simp] theorem mem_Iio : x ∈ Iio a ↔ x < a := LocallyFiniteOrderBot.finset_mem_Iio _ _ @[simp, norm_cast] theorem coe_Iic (a : α) : (Iic a : Set α) = Set.Iic a := Set.ext fun _ => mem_Iic @[simp, norm_cast] theorem coe_Iio (a : α) : (Iio a : Set α) = Set.Iio a := Set.ext fun _ => mem_Iio @[simp] theorem _root_.Fintype.card_Iic (a : α) [Fintype (Set.Iic a)] : Fintype.card (Set.Iic a) = #(Iic a) := Fintype.card_of_finset' _ fun _ ↦ by simp @[simp] theorem _root_.Fintype.card_Iio (a : α) [Fintype (Set.Iio a)] : Fintype.card (Set.Iio a) = #(Iio a) := Fintype.card_of_finset' _ fun _ ↦ by simp end LocallyFiniteOrderBot section OrderTop variable [LocallyFiniteOrder α] [OrderTop α] {a x : α} -- See note [lower priority instance] instance (priority := 100) _root_.LocallyFiniteOrder.toLocallyFiniteOrderTop : LocallyFiniteOrderTop α where finsetIci b := Icc b ⊤ finsetIoi b := Ioc b ⊤ finset_mem_Ici a x := by rw [mem_Icc, and_iff_left le_top] finset_mem_Ioi a x := by rw [mem_Ioc, and_iff_left le_top] theorem Ici_eq_Icc (a : α) : Ici a = Icc a ⊤ := rfl theorem Ioi_eq_Ioc (a : α) : Ioi a = Ioc a ⊤ := rfl end OrderTop section OrderBot variable [OrderBot α] [LocallyFiniteOrder α] {b x : α} -- See note [lower priority instance] instance (priority := 100) LocallyFiniteOrder.toLocallyFiniteOrderBot : LocallyFiniteOrderBot α where finsetIic := Icc ⊥ finsetIio := Ico ⊥ finset_mem_Iic a x := by rw [mem_Icc, and_iff_right bot_le] finset_mem_Iio a x := by rw [mem_Ico, and_iff_right bot_le] theorem Iic_eq_Icc : Iic = Icc (⊥ : α) := rfl theorem Iio_eq_Ico : Iio = Ico (⊥ : α) := rfl end OrderBot end Preorder section Lattice variable [Lattice α] [LocallyFiniteOrder α] {a b x : α} /-- `Finset.uIcc a b` is the set of elements lying between `a` and `b`, with `a` and `b` included. Note that we define it more generally in a lattice as `Finset.Icc (a ⊓ b) (a ⊔ b)`. In a product type, `Finset.uIcc` corresponds to the bounding box of the two elements. -/ def uIcc (a b : α) : Finset α := Icc (a ⊓ b) (a ⊔ b) @[inherit_doc] scoped[FinsetInterval] notation "[[" a ", " b "]]" => Finset.uIcc a b @[simp] theorem mem_uIcc : x ∈ uIcc a b ↔ a ⊓ b ≤ x ∧ x ≤ a ⊔ b := mem_Icc @[simp, norm_cast] theorem coe_uIcc (a b : α) : (Finset.uIcc a b : Set α) = Set.uIcc a b := coe_Icc _ _ @[simp] theorem _root_.Fintype.card_uIcc (a b : α) [Fintype (Set.uIcc a b)] : Fintype.card (Set.uIcc a b) = #(uIcc a b) := Fintype.card_of_finset' _ fun _ ↦ by simp [Set.uIcc] end Lattice end Finset namespace Mathlib.Meta open Lean Elab Term Meta Batteries.ExtendedBinder /-- Elaborate set builder notation for `Finset`. * `{x ≤ a \| p x}` is elaborated as `Finset.filter (fun x ↦ p x) (Finset.Iic a)` if the expected type is `Finset ?α`. * `{x ≥ a \| p x}` is elaborated as `Finset.filter (fun x ↦ p x) (Finset.Ici a)` if the expected type is `Finset ?α`. * `{x < a \| p x}` is elaborated as `Finset.filter (fun x ↦ p x) (Finset.Iio a)` if the expected type is `Finset ?α`. * `{x > a \| p x}` is elaborated as `Finset.filter (fun x ↦ p x) (Finset.Ioi a)` if the expected type is `Finset ?α`. See also * `Data.Set.Defs` for the `Set` builder notation elaborator that this elaborator partly overrides. * `Data.Finset.Basic` for the `Finset` builder notation elaborator partly overriding this one for syntax of the form `{x ∈ s \| p x}`. * `Data.Fintype.Basic` for the `Finset` builder notation elaborator handling syntax of the form `{x \| p x}`, `{x : α \| p x}`, `{x ∉ s \| p x}`, `{x ≠ a \| p x}`. TODO: Write a delaborator -/ @[term_elab setBuilder] def elabFinsetBuilderIxx : TermElab \| `({ $x:ident ≤ $a \| $p }), expectedType? => do -- If the expected type is not known to be `Finset ?α`, give up. unless ← knownToBeFinsetNotSet expectedType? do throwUnsupportedSyntax elabTerm (← `(Finset.filter (fun $x:ident ↦ $p) (Finset.Iic $a))) expectedType? \| `({ $x:ident ≥ $a \| $p }), expectedType? => do -- If the expected type is not known to be `Finset ?α`, give up. unless ← knownToBeFinsetNotSet expectedType? do throwUnsupportedSyntax elabTerm (← `(Finset.filter (fun $x:ident ↦ $p) (Finset.Ici $a))) expectedType? \| `({ $x:ident < $a \| $p }), expectedType? => do -- If the expected type is not known to be `Finset ?α`, give up. unless ← knownToBeFinsetNotSet expectedType? do throwUnsupportedSyntax elabTerm (← `(Finset.filter (fun $x:ident ↦ $p) (Finset.Iio $a))) expectedType? \| `({ $x:ident > $a \| $p }), expectedType? => do -- If the expected type is not known to be `Finset ?α`, give up. unless ← knownToBeFinsetNotSet expectedType? do throwUnsupportedSyntax elabTerm (← `(Finset.filter (fun $x:ident ↦ $p) (Finset.Ioi $a))) expectedType? \| _, _ => throwUnsupportedSyntax end Mathlib.Meta /-! ### Finiteness of `Set` intervals -/ namespace Set section Preorder variable [Preorder α] [LocallyFiniteOrder α] (a b : α) instance instFintypeIcc : Fintype (Icc a b) := .ofFinset (Finset.Icc a b) fun _ => Finset.mem_Icc instance instFintypeIco : Fintype (Ico a b) := .ofFinset (Finset.Ico a b) fun _ => Finset.mem_Ico instance instFintypeIoc : Fintype (Ioc a b) := .ofFinset (Finset.Ioc a b) fun _ => Finset.mem_Ioc instance instFintypeIoo : Fintype (Ioo a b) := .ofFinset (Finset.Ioo a b) fun _ => Finset.mem_Ioo theorem finite_Icc : (Icc a b).Finite := (Icc a b).toFinite theorem finite_Ico : (Ico a b).Finite := (Ico a b).toFinite theorem finite_Ioc : (Ioc a b).Finite := (Ioc a b).toFinite theorem finite_Ioo : (Ioo a b).Finite := (Ioo a b).toFinite end Preorder section OrderTop variable [Preorder α] [LocallyFiniteOrderTop α] (a : α) instance instFintypeIci : Fintype (Ici a) := .ofFinset (Finset.Ici a) fun _ => Finset.mem_Ici instance instFintypeIoi : Fintype (Ioi a) := .ofFinset (Finset.Ioi a) fun _ => Finset.mem_Ioi theorem finite_Ici : (Ici a).Finite := (Ici a).toFinite theorem finite_Ioi : (Ioi a).Finite := (Ioi a).toFinite end OrderTop section OrderBot variable [Preorder α] [LocallyFiniteOrderBot α] (b : α) instance instFintypeIic : Fintype (Iic b) := .ofFinset (Finset.Iic b) fun _ => Finset.mem_Iic instance instFintypeIio : Fintype (Iio b) := .ofFinset (Finset.Iio b) fun _ => Finset.mem_Iio theorem finite_Iic : (Iic b).Finite := (Iic b).toFinite theorem finite_Iio : (Iio b).Finite := (Iio b).toFinite end OrderBot section Lattice variable [Lattice α] [LocallyFiniteOrder α] (a b : α) instance fintypeUIcc : Fintype (uIcc a b) := Fintype.ofFinset (Finset.uIcc a b) fun _ => Finset.mem_uIcc @[simp] theorem finite_interval : (uIcc a b).Finite := (uIcc _ _).toFinite end Lattice end Set /-! ### Instances -/ open Finset section Preorder variable [Preorder α] [Preorder β] /-- A noncomputable constructor from the finiteness of all closed intervals. -/ noncomputable def LocallyFiniteOrder.ofFiniteIcc (h : ∀ a b : α, (Set.Icc a b).Finite) : LocallyFiniteOrder α := @LocallyFiniteOrder.ofIcc' α _ (Classical.decRel _) (fun a b => (h a b).toFinset) fun a b x => by rw [Set.Finite.mem_toFinset, Set.mem_Icc] /-- A fintype is a locally finite order. This is not an instance as it would not be defeq to better instances such as `Fin.locallyFiniteOrder`. -/ abbrev Fintype.toLocallyFiniteOrder [Fintype α] [DecidableLT α] [DecidableLE α] : LocallyFiniteOrder α where finsetIcc a b := (Set.Icc a b).toFinset finsetIco a b := (Set.Ico a b).toFinset finsetIoc a b := (Set.Ioc a b).toFinset finsetIoo a b := (Set.Ioo a b).toFinset finset_mem_Icc a b x := by simp only [Set.mem_toFinset, Set.mem_Icc] finset_mem_Ico a b x := by simp only [Set.mem_toFinset, Set.mem_Ico] finset_mem_Ioc a b x := by simp only [Set.mem_toFinset, Set.mem_Ioc] finset_mem_Ioo a b x := by simp only [Set.mem_toFinset, Set.mem_Ioo] instance : Subsingleton (LocallyFiniteOrder α) := Subsingleton.intro fun h₀ h₁ => by obtain ⟨h₀_finset_Icc, h₀_finset_Ico, h₀_finset_Ioc, h₀_finset_Ioo, h₀_finset_mem_Icc, h₀_finset_mem_Ico, h₀_finset_mem_Ioc, h₀_finset_mem_Ioo⟩ := h₀ obtain ⟨h₁_finset_Icc, h₁_finset_Ico, h₁_finset_Ioc, h₁_finset_Ioo, h₁_finset_mem_Icc, h₁_finset_mem_Ico, h₁_finset_mem_Ioc, h₁_finset_mem_Ioo⟩ := h₁ have hIcc : h₀_finset_Icc = h₁_finset_Icc := by ext a b x rw [h₀_finset_mem_Icc, h₁_finset_mem_Icc] have hIco : h₀_finset_Ico = h₁_finset_Ico := by ext a b x rw [h₀_finset_mem_Ico, h₁_finset_mem_Ico] have hIoc : h₀_finset_Ioc = h₁_finset_Ioc := by ext a b x rw [h₀_finset_mem_Ioc, h₁_finset_mem_Ioc] have hIoo : h₀_finset_Ioo = h₁_finset_Ioo := by ext a b x rw [h₀_finset_mem_Ioo, h₁_finset_mem_Ioo] simp_rw [hIcc, hIco, hIoc, hIoo] instance : Subsingleton (LocallyFiniteOrderTop α) := Subsingleton.intro fun h₀ h₁ => by obtain ⟨h₀_finset_Ioi, h₀_finset_Ici, h₀_finset_mem_Ici, h₀_finset_mem_Ioi⟩ := h₀ obtain ⟨h₁_finset_Ioi, h₁_finset_Ici, h₁_finset_mem_Ici, h₁_finset_mem_Ioi⟩ := h₁ have hIci : h₀_finset_Ici = h₁_finset_Ici := by ext a b rw [h₀_finset_mem_Ici, h₁_finset_mem_Ici] have hIoi : h₀_finset_Ioi = h₁_finset_Ioi := by ext a b rw [h₀_finset_mem_Ioi, h₁_finset_mem_Ioi] simp_rw [hIci, hIoi] instance : Subsingleton (LocallyFiniteOrderBot α) := Subsingleton.intro fun h₀ h₁ => by obtain ⟨h₀_finset_Iio, h₀_finset_Iic, h₀_finset_mem_Iic, h₀_finset_mem_Iio⟩ := h₀ obtain ⟨h₁_finset_Iio, h₁_finset_Iic, h₁_finset_mem_Iic, h₁_finset_mem_Iio⟩ := h₁ have hIic : h₀_finset_Iic = h₁_finset_Iic := by ext a b rw [h₀_finset_mem_Iic, h₁_finset_mem_Iic] have hIio : h₀_finset_Iio = h₁_finset_Iio := by ext a b rw [h₀_finset_mem_Iio, h₁_finset_mem_Iio] simp_rw [hIic, hIio] -- Should this be called `LocallyFiniteOrder.lift`? /-- Given an order embedding `α ↪o β`, pulls back the `LocallyFiniteOrder` on `β` to `α`. -/ protected noncomputable def OrderEmbedding.locallyFiniteOrder [LocallyFiniteOrder β] (f : α ↪o β) : LocallyFiniteOrder α where finsetIcc a b := (Icc (f a) (f b)).preimage f f.toEmbedding.injective.injOn finsetIco a b := (Ico (f a) (f b)).preimage f f.toEmbedding.injective.injOn finsetIoc a b := (Ioc (f a) (f b)).preimage f f.toEmbedding.injective.injOn finsetIoo a b := (Ioo (f a) (f b)).preimage f f.toEmbedding.injective.injOn finset_mem_Icc a b x := by rw [mem_preimage, mem_Icc, f.le_iff_le, f.le_iff_le] finset_mem_Ico a b x := by rw [mem_preimage, mem_Ico, f.le_iff_le, f.lt_iff_lt] finset_mem_Ioc a b x := by rw [mem_preimage, mem_Ioc, f.lt_iff_lt, f.le_iff_le] finset_mem_Ioo a b x := by rw [mem_preimage, mem_Ioo, f.lt_iff_lt, f.lt_iff_lt] /-! ### `OrderDual` -/ open OrderDual section LocallyFiniteOrder variable [LocallyFiniteOrder α] (a b : α) /-- Note we define `Icc (toDual a) (toDual b)` as `Icc α _ _ b a` (which has type `Finset α` not `Finset αᵒᵈ`!) instead of `(Icc b a).map toDual.toEmbedding` as this means the following is defeq: ``` lemma this : (Icc (toDual (toDual a)) (toDual (toDual b)) :) = (Icc a b :) := rfl ``` -/ instance OrderDual.instLocallyFiniteOrder : LocallyFiniteOrder αᵒᵈ where finsetIcc a b := @Icc α _ _ (ofDual b) (ofDual a) finsetIco a b := @Ioc α _ _ (ofDual b) (ofDual a) finsetIoc a b := @Ico α _ _ (ofDual b) (ofDual a) finsetIoo a b := @Ioo α _ _ (ofDual b) (ofDual a) finset_mem_Icc _ _ _ := (mem_Icc (α := α)).trans and_comm finset_mem_Ico _ _ _ := (mem_Ioc (α := α)).trans and_comm finset_mem_Ioc _ _ _ := (mem_Ico (α := α)).trans and_comm finset_mem_Ioo _ _ _ := (mem_Ioo (α := α)).trans and_comm lemma Finset.Icc_orderDual_def (a b : αᵒᵈ) : Icc a b = (Icc (ofDual b) (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Finset.Ico_orderDual_def (a b : αᵒᵈ) : Ico a b = (Ioc (ofDual b) (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Finset.Ioc_orderDual_def (a b : αᵒᵈ) : Ioc a b = (Ico (ofDual b) (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Finset.Ioo_orderDual_def (a b : αᵒᵈ) : Ioo a b = (Ioo (ofDual b) (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Finset.Icc_toDual : Icc (toDual a) (toDual b) = (Icc b a).map toDual.toEmbedding := map_refl.symm lemma Finset.Ico_toDual : Ico (toDual a) (toDual b) = (Ioc b a).map toDual.toEmbedding := map_refl.symm lemma Finset.Ioc_toDual : Ioc (toDual a) (toDual b) = (Ico b a).map toDual.toEmbedding := map_refl.symm lemma Finset.Ioo_toDual : Ioo (toDual a) (toDual b) = (Ioo b a).map toDual.toEmbedding := map_refl.symm lemma Finset.Icc_ofDual (a b : αᵒᵈ) : Icc (ofDual a) (ofDual b) = (Icc b a).map ofDual.toEmbedding := map_refl.symm lemma Finset.Ico_ofDual (a b : αᵒᵈ) : Ico (ofDual a) (ofDual b) = (Ioc b a).map ofDual.toEmbedding := map_refl.symm lemma Finset.Ioc_ofDual (a b : αᵒᵈ) : Ioc (ofDual a) (ofDual b) = (Ico b a).map ofDual.toEmbedding := map_refl.symm lemma Finset.Ioo_ofDual (a b : αᵒᵈ) : Ioo (ofDual a) (ofDual b) = (Ioo b a).map ofDual.toEmbedding := map_refl.symm end LocallyFiniteOrder section LocallyFiniteOrderTop variable [LocallyFiniteOrderTop α] /-- Note we define `Iic (toDual a)` as `Ici a` (which has type `Finset α` not `Finset αᵒᵈ`!) instead of `(Ici a).map toDual.toEmbedding` as this means the following is defeq: ``` lemma this : (Iic (toDual (toDual a)) :) = (Iic a :) := rfl ``` -/ instance OrderDual.instLocallyFiniteOrderBot : LocallyFiniteOrderBot αᵒᵈ where finsetIic a := @Ici α _ _ (ofDual a) finsetIio a := @Ioi α _ _ (ofDual a) finset_mem_Iic _ _ := mem_Ici (α := α) finset_mem_Iio _ _ := mem_Ioi (α := α) lemma Iic_orderDual_def (a : αᵒᵈ) : Iic a = (Ici (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Iio_orderDual_def (a : αᵒᵈ) : Iio a = (Ioi (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Finset.Iic_toDual (a : α) : Iic (toDual a) = (Ici a).map toDual.toEmbedding := map_refl.symm lemma Finset.Iio_toDual (a : α) : Iio (toDual a) = (Ioi a).map toDual.toEmbedding := map_refl.symm lemma Finset.Ici_ofDual (a : αᵒᵈ) : Ici (ofDual a) = (Iic a).map ofDual.toEmbedding := map_refl.symm lemma Finset.Ioi_ofDual (a : αᵒᵈ) : Ioi (ofDual a) = (Iio a).map ofDual.toEmbedding := map_refl.symm end LocallyFiniteOrderTop section LocallyFiniteOrderTop variable [LocallyFiniteOrderBot α] /-- Note we define `Ici (toDual a)` as `Iic a` (which has type `Finset α` not `Finset αᵒᵈ`!) instead of `(Iic a).map toDual.toEmbedding` as this means the following is defeq: ``` lemma this : (Ici (toDual (toDual a)) :) = (Ici a :) := rfl ``` -/ instance OrderDual.instLocallyFiniteOrderTop : LocallyFiniteOrderTop αᵒᵈ where finsetIci a := @Iic α _ _ (ofDual a) finsetIoi a := @Iio α _ _ (ofDual a) finset_mem_Ici _ _ := mem_Iic (α := α) finset_mem_Ioi _ _ := mem_Iio (α := α) lemma Ici_orderDual_def (a : αᵒᵈ) : Ici a = (Iic (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Ioi_orderDual_def (a : αᵒᵈ) : Ioi a = (Iio (ofDual a)).map toDual.toEmbedding := map_refl.symm lemma Finset.Ici_toDual (a : α) : Ici (toDual a) = (Iic a).map toDual.toEmbedding := map_refl.symm lemma Finset.Ioi_toDual (a : α) : Ioi (toDual a) = (Iio a).map toDual.toEmbedding := map_refl.symm lemma Finset.Iic_ofDual (a : αᵒᵈ) : Iic (ofDual a) = (Ici a).map ofDual.toEmbedding := map_refl.symm lemma Finset.Iio_ofDual (a : αᵒᵈ) : Iio (ofDual a) = (Ioi a).map ofDual.toEmbedding := map_refl.symm end LocallyFiniteOrderTop /-! ### `Prod` -/ section LocallyFiniteOrder variable [LocallyFiniteOrder α] [LocallyFiniteOrder β] [DecidableLE (α × β)] instance Prod.instLocallyFiniteOrder : LocallyFiniteOrder (α × β) := LocallyFiniteOrder.ofIcc' (α × β) (fun x y ↦ Icc x.1 y.1 ×ˢ Icc x.2 y.2) fun a b x => by rw [mem_product, mem_Icc, mem_Icc, and_and_and_comm, le_def, le_def] lemma Finset.Icc_prod_def (x y : α × β) : Icc x y = Icc x.1 y.1 ×ˢ Icc x.2 y.2 := rfl lemma Finset.Icc_product_Icc (a₁ a₂ : α) (b₁ b₂ : β) : Icc a₁ a₂ ×ˢ Icc b₁ b₂ = Icc (a₁, b₁) (a₂, b₂) := rfl lemma Finset.card_Icc_prod (x y : α × β) : #(Icc x y) = #(Icc x.1 y.1) * #(Icc x.2 y.2) := card_product .. end LocallyFiniteOrder section LocallyFiniteOrderTop variable [LocallyFiniteOrderTop α] [LocallyFiniteOrderTop β] [DecidableLE (α × β)] instance Prod.instLocallyFiniteOrderTop : LocallyFiniteOrderTop (α × β) := LocallyFiniteOrderTop.ofIci' (α × β) (fun x => Ici x.1 ×ˢ Ici x.2) fun a x => by rw [mem_product, mem_Ici, mem_Ici, le_def] lemma Finset.Ici_prod_def (x : α × β) : Ici x = Ici x.1 ×ˢ Ici x.2 := rfl lemma Finset.Ici_product_Ici (a : α) (b : β) : Ici a ×ˢ Ici b = Ici (a, b) := rfl lemma Finset.card_Ici_prod (x : α × β) : #(Ici x) = #(Ici x.1) * #(Ici x.2) := card_product _ _ end LocallyFiniteOrderTop section LocallyFiniteOrderBot variable [LocallyFiniteOrderBot α] [LocallyFiniteOrderBot β] [DecidableLE (α × β)] instance Prod.instLocallyFiniteOrderBot : LocallyFiniteOrderBot (α × β) := LocallyFiniteOrderBot.ofIic' (α × β) (fun x ↦ Iic x.1 ×ˢ Iic x.2) fun a x ↦ by rw [mem_product, mem_Iic, mem_Iic, le_def] lemma Finset.Iic_prod_def (x : α × β) : Iic x = Iic x.1 ×ˢ Iic x.2 := rfl lemma Finset.Iic_product_Iic (a : α) (b : β) : Iic a ×ˢ Iic b = Iic (a, b) := rfl lemma Finset.card_Iic_prod (x : α × β) : #(Iic x) = #(Iic x.1) * #(Iic x.2) := card_product .. end LocallyFiniteOrderBot end Preorder section Lattice variable [Lattice α] [Lattice β] [LocallyFiniteOrder α] [LocallyFiniteOrder β] [DecidableLE (α × β)] lemma Finset.uIcc_prod_def (x y : α × β) : uIcc x y = uIcc x.1 y.1 ×ˢ uIcc x.2 y.2 := rfl lemma Finset.uIcc_product_uIcc (a₁ a₂ : α) (b₁ b₂ : β) : uIcc a₁ a₂ ×ˢ uIcc b₁ b₂ = uIcc (a₁, b₁) (a₂, b₂) := rfl lemma Finset.card_uIcc_prod (x y : α × β) : #(uIcc x y) = #(uIcc x.1 y.1) * #(uIcc x.2 y.2) := card_product .. end Lattice /-! #### `WithTop`, `WithBot` Adding a `⊤` to a locally finite `OrderTop` keeps it locally finite. Adding a `⊥` to a locally finite `OrderBot` keeps it locally finite. -/ namespace WithTop /-- Given a finset on `α`, lift it to being a finset on `WithTop α` using `WithTop.some` and then insert `⊤`. -/ def insertTop : Finset α ↪o Finset (WithTop α) := OrderEmbedding.ofMapLEIff (fun s => cons ⊤ (s.map Embedding.coeWithTop) <\| by simp) (fun s t => by rw [le_iff_subset, cons_subset_cons, map_subset_map, le_iff_subset]) @[simp] theorem some_mem_insertTop {s : Finset α} {a : α} : ↑a ∈ insertTop s ↔ a ∈ s := by simp [insertTop] @[simp] theorem top_mem_insertTop {s : Finset α} : ⊤ ∈ insertTop s := by simp [insertTop] variable (α) [PartialOrder α] [OrderTop α] [LocallyFiniteOrder α] instance locallyFiniteOrder : LocallyFiniteOrder (WithTop α) where finsetIcc a b := match a, b with \| ⊤, ⊤ => {⊤} \| ⊤, (b : α) => ∅ \| (a : α), ⊤ => insertTop (Ici a) \| (a : α), (b : α) => (Icc a b).map Embedding.coeWithTop finsetIco a b := match a, b with \| ⊤, _ => ∅ \| (a : α), ⊤ => (Ici a).map Embedding.coeWithTop \| (a : α), (b : α) => (Ico a b).map Embedding.coeWithTop finsetIoc a b := match a, b with \| ⊤, _ => ∅ \| (a : α), ⊤ => insertTop (Ioi a) \| (a : α), (b : α) => (Ioc a b).map Embedding.coeWithTop finsetIoo a b := match a, b with \| ⊤, _ => ∅ \| (a : α), ⊤ => (Ioi a).map Embedding.coeWithTop \| (a : α), (b : α) => (Ioo a b).map Embedding.coeWithTop finset_mem_Icc a b x := by cases a <;> cases b <;> cases x <;> simp finset_mem_Ico a b x := by cases a <;> cases b <;> cases x <;> simp finset_mem_Ioc a b x := by cases a <;> cases b <;> cases x <;> simp finset_mem_Ioo a b x := by cases a <;> cases b <;> cases x <;> simp variable (a b : α) theorem Icc_coe_top : Icc (a : WithTop α) ⊤ = insertNone (Ici a) := rfl theorem Icc_coe_coe : Icc (a : WithTop α) b = (Icc a b).map Embedding.some := rfl theorem Ico_coe_top : Ico (a : WithTop α) ⊤ = (Ici a).map Embedding.some := rfl theorem Ico_coe_coe : Ico (a : WithTop α) b = (Ico a b).map Embedding.some := rfl theorem Ioc_coe_top : Ioc (a : WithTop α) ⊤ = insertNone (Ioi a) := rfl theorem Ioc_coe_coe : Ioc (a : WithTop α) b = (Ioc a b).map Embedding.some := rfl theorem Ioo_coe_top : Ioo (a : WithTop α) ⊤ = (Ioi a).map Embedding.some := rfl theorem Ioo_coe_coe : Ioo (a : WithTop α) b = (Ioo a b).map Embedding.some := rfl end WithTop namespace WithBot /-- Given a finset on `α`, lift it to being a finset on `WithBot α` using `WithBot.some` and then insert `⊥`. -/ def insertBot : Finset α ↪o Finset (WithBot α) := OrderEmbedding.ofMapLEIff (fun s => cons ⊥ (s.map Embedding.coeWithBot) <\| by simp) (fun s t => by rw [le_iff_subset, cons_subset_cons, map_subset_map, le_iff_subset]) @[simp] theorem some_mem_insertBot {s : Finset α} {a : α} : ↑a ∈ insertBot s ↔ a ∈ s := by simp [insertBot] @[simp] theorem bot_mem_insertBot {s : Finset α} : ⊥ ∈ insertBot s := by simp [insertBot] variable (α) [PartialOrder α] [OrderBot α] [LocallyFiniteOrder α] instance instLocallyFiniteOrder : LocallyFiniteOrder (WithBot α) := OrderDual.instLocallyFiniteOrder (α := WithTop αᵒᵈ) variable (a b : α) theorem Icc_bot_coe : Icc (⊥ : WithBot α) b = insertNone (Iic b) := rfl theorem Icc_coe_coe : Icc (a : WithBot α) b = (Icc a b).map Embedding.some := rfl theorem Ico_bot_coe : Ico (⊥ : WithBot α) b = insertNone (Iio b) := rfl theorem Ico_coe_coe : Ico (a : WithBot α) b = (Ico a b).map Embedding.some := rfl theorem Ioc_bot_coe : Ioc (⊥ : WithBot α) b = (Iic b).map Embedding.some := rfl theorem Ioc_coe_coe : Ioc (a : WithBot α) b = (Ioc a b).map Embedding.some := rfl theorem Ioo_bot_coe : Ioo (⊥ : WithBot α) b = (Iio b).map Embedding.some := rfl theorem Ioo_coe_coe : Ioo (a : WithBot α) b = (Ioo a b).map Embedding.some := rfl end WithBot namespace OrderIso variable [Preorder α] [Preorder β] /-! #### Transfer locally finite orders across order isomorphisms -/ -- See note [reducible non-instances] /-- Transfer `LocallyFiniteOrder` across an `OrderIso`. -/ abbrev locallyFiniteOrder [LocallyFiniteOrder β] (f : α ≃o β) : LocallyFiniteOrder α where finsetIcc a b := (Icc (f a) (f b)).map f.symm.toEquiv.toEmbedding finsetIco a b := (Ico (f a) (f b)).map f.symm.toEquiv.toEmbedding finsetIoc a b := (Ioc (f a) (f b)).map f.symm.toEquiv.toEmbedding finsetIoo a b := (Ioo (f a) (f b)).map f.symm.toEquiv.toEmbedding finset_mem_Icc := by simp finset_mem_Ico := by simp finset_mem_Ioc := by simp finset_mem_Ioo := by simp -- See note [reducible non-instances] /-- Transfer `LocallyFiniteOrderTop` across an `OrderIso`. -/ abbrev locallyFiniteOrderTop [LocallyFiniteOrderTop β] (f : α ≃o β) : LocallyFiniteOrderTop α where finsetIci a := (Ici (f a)).map f.symm.toEquiv.toEmbedding finsetIoi a := (Ioi (f a)).map f.symm.toEquiv.toEmbedding finset_mem_Ici := by simp finset_mem_Ioi := by simp -- See note [reducible non-instances] /-- Transfer `LocallyFiniteOrderBot` across an `OrderIso`. -/ abbrev locallyFiniteOrderBot [LocallyFiniteOrderBot β] (f : α ≃o β) : LocallyFiniteOrderBot α where finsetIic a := (Iic (f a)).map f.symm.toEquiv.toEmbedding finsetIio a := (Iio (f a)).map f.symm.toEquiv.toEmbedding finset_mem_Iic := by simp finset_mem_Iio := by simp end OrderIso /-! #### Subtype of a locally finite order -/ variable [Preorder α] (p : α → Prop) [DecidablePred p] instance Subtype.instLocallyFiniteOrder [LocallyFiniteOrder α] : LocallyFiniteOrder (Subtype p) where finsetIcc a b := (Icc (a : α) b).subtype p finsetIco a b := (Ico (a : α) b).subtype p finsetIoc a b := (Ioc (a : α) b).subtype p finsetIoo a b := (Ioo (a : α) b).subtype p finset_mem_Icc a b x := by simp_rw [Finset.mem_subtype, mem_Icc, Subtype.coe_le_coe] finset_mem_Ico a b x := by simp_rw [Finset.mem_subtype, mem_Ico, Subtype.coe_le_coe, Subtype.coe_lt_coe] finset_mem_Ioc a b x := by simp_rw [Finset.mem_subtype, mem_Ioc, Subtype.coe_le_coe, Subtype.coe_lt_coe] finset_mem_Ioo a b x := by simp_rw [Finset.mem_subtype, mem_Ioo, Subtype.coe_lt_coe] instance Subtype.instLocallyFiniteOrderTop [LocallyFiniteOrderTop α] : LocallyFiniteOrderTop (Subtype p) where finsetIci a := (Ici (a : α)).subtype p finsetIoi a := (Ioi (a : α)).subtype p finset_mem_Ici a x := by simp_rw [Finset.mem_subtype, mem_Ici, Subtype.coe_le_coe] finset_mem_Ioi a x := by simp_rw [Finset.mem_subtype, mem_Ioi, Subtype.coe_lt_coe] instance Subtype.instLocallyFiniteOrderBot [LocallyFiniteOrderBot α] : LocallyFiniteOrderBot (Subtype p) where finsetIic a := (Iic (a : α)).subtype p finsetIio a := (Iio (a : α)).subtype p finset_mem_Iic a x := by simp_rw [Finset.mem_subtype, mem_Iic, Subtype.coe_le_coe] finset_mem_Iio a x := by simp_rw [Finset.mem_subtype, mem_Iio, Subtype.coe_lt_coe] namespace Finset section LocallyFiniteOrder variable [LocallyFiniteOrder α] (a b : Subtype p) theorem subtype_Icc_eq : Icc a b = (Icc (a : α) b).subtype p := rfl theorem subtype_Ico_eq : Ico a b = (Ico (a : α) b).subtype p := rfl theorem subtype_Ioc_eq : Ioc a b = (Ioc (a : α) b).subtype p := rfl theorem subtype_Ioo_eq : Ioo a b = (Ioo (a : α) b).subtype p := rfl theorem map_subtype_embedding_Icc (hp : ∀ ⦃a b x⦄, a ≤ x → x ≤ b → p a → p b → p x): (Icc a b).map (Embedding.subtype p) = (Icc a b : Finset α) := by rw [subtype_Icc_eq] refine Finset.subtype_map_of_mem fun x hx => ?_ rw [mem_Icc] at hx exact hp hx.1 hx.2 a.prop b.prop theorem map_subtype_embedding_Ico (hp : ∀ ⦃a b x⦄, a ≤ x → x ≤ b → p a → p b → p x): (Ico a b).map (Embedding.subtype p) = (Ico a b : Finset α) := by rw [subtype_Ico_eq] refine Finset.subtype_map_of_mem fun x hx => ?_ rw [mem_Ico] at hx exact hp hx.1 hx.2.le a.prop b.prop theorem map_subtype_embedding_Ioc (hp : ∀ ⦃a b x⦄, a ≤ x → x ≤ b → p a → p b → p x): (Ioc a b).map (Embedding.subtype p) = (Ioc a b : Finset α) := by rw [subtype_Ioc_eq] refine Finset.subtype_map_of_mem fun x hx => ?_ rw [mem_Ioc] at hx exact hp hx.1.le hx.2 a.prop b.prop theorem map_subtype_embedding_Ioo (hp : ∀ ⦃a b x⦄, a ≤ x → x ≤ b → p a → p b → p x): (Ioo a b).map (Embedding.subtype p) = (Ioo a b : Finset α) := by rw [subtype_Ioo_eq] refine Finset.subtype_map_of_mem fun x hx => ?_ rw [mem_Ioo] at hx exact hp hx.1.le hx.2.le a.prop b.prop end LocallyFiniteOrder section LocallyFiniteOrderTop variable [LocallyFiniteOrderTop α] (a : Subtype p) theorem subtype_Ici_eq : Ici a = (Ici (a : α)).subtype p := rfl theorem subtype_Ioi_eq : Ioi a = (Ioi (a : α)).subtype p := rfl theorem map_subtype_embedding_Ici (hp : ∀ ⦃a x⦄, a ≤ x → p a → p x) : (Ici a).map (Embedding.subtype p) = (Ici a : Finset α) := by rw [subtype_Ici_eq] exact Finset.subtype_map_of_mem fun x hx => hp (mem_Ici.1 hx) a.prop theorem map_subtype_embedding_Ioi (hp : ∀ ⦃a x⦄, a ≤ x → p a → p x) : (Ioi a).map (Embedding.subtype p) = (Ioi a : Finset α) := by rw [subtype_Ioi_eq] exact Finset.subtype_map_of_mem fun x hx => hp (mem_Ioi.1 hx).le a.prop end LocallyFiniteOrderTop section LocallyFiniteOrderBot variable [LocallyFiniteOrderBot α] (a : Subtype p) theorem subtype_Iic_eq : Iic a = (Iic (a : α)).subtype p := rfl theorem subtype_Iio_eq : Iio a = (Iio (a : α)).subtype p := rfl theorem map_subtype_embedding_Iic (hp : ∀ ⦃a x⦄, x ≤ a → p a → p x) : (Iic a).map (Embedding.subtype p) = (Iic a : Finset α) := by rw [subtype_Iic_eq] exact Finset.subtype_map_of_mem fun x hx => hp (mem_Iic.1 hx) a.prop theorem map_subtype_embedding_Iio (hp : ∀ ⦃a x⦄, x ≤ a → p a → p x) : (Iio a).map (Embedding.subtype p) = (Iio a : Finset α) := by rw [subtype_Iio_eq] exact Finset.subtype_map_of_mem fun x hx => hp (mem_Iio.1 hx).le a.prop end LocallyFiniteOrderBot end Finset section Finite variable {α : Type} {s : Set α} theorem BddBelow.finite_of_bddAbove [Preorder α] [LocallyFiniteOrder α] {s : Set α} (h₀ : BddBelow s) (h₁ : BddAbove s) : s.Finite := let ⟨a, ha⟩ := h₀ let ⟨b, hb⟩ := h₁ (Set.finite_Icc a b).subset fun _x hx ↦ ⟨ha hx, hb hx⟩ theorem Set.finite_iff_bddAbove [SemilatticeSup α] [LocallyFiniteOrder α] [OrderBot α] : s.Finite ↔ BddAbove s := ⟨fun h ↦ ⟨h.toFinset.sup id, fun _ hx ↦ Finset.le_sup (f := id) ((Finite.mem_toFinset h).mpr hx)⟩, fun ⟨m, hm⟩ ↦ (Set.finite_Icc ⊥ m).subset (fun _ hx ↦ ⟨bot_le, hm hx⟩)⟩ theorem Set.finite_iff_bddBelow [SemilatticeInf α] [LocallyFiniteOrder α] [OrderTop α] : s.Finite ↔ BddBelow s := finite_iff_bddAbove (α := αᵒᵈ) theorem Set.finite_iff_bddBelow_bddAbove [Nonempty α] [Lattice α] [LocallyFiniteOrder α] : s.Finite ↔ BddBelow s ∧ BddAbove s := by obtain (rfl \| hs) := s.eq_empty_or_nonempty · simp only [Set.finite_empty, bddBelow_empty, bddAbove_empty, and_self] exact ⟨fun h ↦ ⟨⟨h.toFinset.inf' ((Finite.toFinset_nonempty h).mpr hs) id, fun x hx ↦ Finset.inf'_le id ((Finite.mem_toFinset h).mpr hx)⟩, ⟨h.toFinset.sup' ((Finite.toFinset_nonempty h).mpr hs) id, fun x hx ↦ Finset.le_sup' id ((Finite.mem_toFinset h).mpr hx)⟩⟩, fun ⟨h₀, h₁⟩ ↦ BddBelow.finite_of_bddAbove h₀ h₁⟩ end Finite /-! We make the instances below low priority so when alternative constructions are available they are preferred. -/ variable {y : α} instance (priority := low) [Preorder α] [DecidableLE α] [LocallyFiniteOrder α] : LocallyFiniteOrderTop { x : α // x ≤ y } where finsetIoi a := Finset.Ioc a ⟨y, by rfl⟩ finsetIci a := Finset.Icc a ⟨y, by rfl⟩ finset_mem_Ici a b := by simp only [Finset.mem_Icc, and_iff_left_iff_imp] exact fun _ => b.property finset_mem_Ioi a b := by simp only [Finset.mem_Ioc, and_iff_left_iff_imp] exact fun _ => b.property instance (priority := low) [Preorder α] [DecidableLT α] [LocallyFiniteOrder α] : LocallyFiniteOrderTop { x : α // x < y } where finsetIoi a := (Finset.Ioo ↑a y).subtype _ finsetIci a := (Finset.Ico ↑a y).subtype _ finset_mem_Ici a b := by simp only [Finset.mem_subtype, Finset.mem_Ico, Subtype.coe_le_coe, and_iff_left_iff_imp] exact fun _ => b.property finset_mem_Ioi a b := by simp only [Finset.mem_subtype, Finset.mem_Ioo, Subtype.coe_lt_coe, and_iff_left_iff_imp] exact fun _ => b.property instance (priority := low) [Preorder α] [DecidableLE α] [LocallyFiniteOrder α] : LocallyFiniteOrderBot { x : α // y ≤ x } where finsetIio a := Finset.Ico ⟨y, by rfl⟩ a finsetIic a := Finset.Icc ⟨y, by rfl⟩ a finset_mem_Iic a b := by simp only [Finset.mem_Icc, and_iff_right_iff_imp] exact fun _ => b.property finset_mem_Iio a b := by simp only [Finset.mem_Ico, and_iff_right_iff_imp] exact fun _ => b.property instance (priority := low) [Preorder α] [DecidableLT α] [LocallyFiniteOrder α] : LocallyFiniteOrderBot { x : α // y < x } where finsetIio a := (Finset.Ioo y ↑a).subtype _ finsetIic a := (Finset.Ioc y ↑a).subtype _ finset_mem_Iic a b := by simp only [Finset.mem_subtype, Finset.mem_Ioc, Subtype.coe_le_coe, and_iff_right_iff_imp] exact fun _ => b.property finset_mem_Iio a b := by simp only [Finset.mem_subtype, Finset.mem_Ioo, Subtype.coe_lt_coe, and_iff_right_iff_imp] exact fun _ => b.property instance [Preorder α] [LocallyFiniteOrderBot α] : Finite { x : α // x ≤ y } := by simpa only [coe_Iic] using (Finset.Iic y).finite_toSet instance [Preorder α] [LocallyFiniteOrderBot α] : Finite { x : α // x < y } := by simpa only [coe_Iio] using (Finset.Iio y).finite_toSet instance [Preorder α] [LocallyFiniteOrderTop α] : Finite { x : α // y ≤ x } := by simpa only [coe_Ici] using (Finset.Ici y).finite_toSet instance [Preorder α] [LocallyFiniteOrderTop α] : Finite { x : α // y < x } := by simpa only [coe_Ioi] using (Finset.Ioi y).finite_toSet namespace Set variable {α : Type} [Preorder α] section LocallyFiniteOrder variable [LocallyFiniteOrder α] @[simp] lemma toFinset_Icc (a b : α) [Fintype (Icc a b)] : (Icc a b).toFinset = Finset.Icc a b := by ext; simp @[simp] lemma toFinset_Ico (a b : α) [Fintype (Ico a b)] : (Ico a b).toFinset = Finset.Ico a b := by ext; simp @[simp] lemma toFinset_Ioc (a b : α) [Fintype (Ioc a b)] : (Ioc a b).toFinset = Finset.Ioc a b := by ext; simp @[simp] lemma toFinset_Ioo (a b : α) [Fintype (Ioo a b)] : (Ioo a b).toFinset = Finset.Ioo a b := by ext; simp end LocallyFiniteOrder section LocallyFiniteOrderTop variable [LocallyFiniteOrderTop α] @[simp] lemma toFinset_Ici (a : α) [Fintype (Ici a)] : (Ici a).toFinset = Finset.Ici a := by ext; simp @[simp] lemma toFinset_Ioi (a : α) [Fintype (Ioi a)] : (Ioi a).toFinset = Finset.Ioi a := by ext; simp end LocallyFiniteOrderTop section LocallyFiniteOrderBot variable [LocallyFiniteOrderBot α] @[simp] lemma toFinset_Iic (a : α) [Fintype (Iic a)] : (Iic a).toFinset = Finset.Iic a := by ext; simp @[simp] lemma toFinset_Iio (a : α) [Fintype (Iio a)] : (Iio a).toFinset = Finset.Iio a := by ext; simp end LocallyFiniteOrderBot end Set /-- A `LocallyFiniteOrder` can be transferred across an order isomorphism. -/ -- See note [reducible non instances] abbrev LocallyFiniteOrder.ofOrderIsoClass {F M N : Type*} [Preorder M] [Preorder N] [EquivLike F M N] [OrderIsoClass F M N] (f : F) [LocallyFiniteOrder N] : LocallyFiniteOrder M where finsetIcc x y := (finsetIcc (f x) (f y)).map ⟨EquivLike.inv f, (EquivLike.right_inv f).injective⟩ finsetIco x y := (finsetIco (f x) (f y)).map ⟨EquivLike.inv f, (EquivLike.right_inv f).injective⟩	finsetIoc x y := (finsetIoc (f x) (f y)).map ⟨EquivLike.inv f, (EquivLike.right_inv f).injective⟩ finsetIoo x y := (finsetIoo (f x) (f y)).map ⟨EquivLike.inv f, (EquivLike.right_inv f).injective⟩	Mathlib/Order/Interval/Finset/Defs.lean	1,336	1,337

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