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/- Copyright (c) 2020 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel, Johan Commelin -/ import Mathlib.Analysis.Analytic.Basic import Mathlib.Combinatorics.Enumerative.Composition /-! # Composition of analytic functions In this file we prove that the composition of analytic functions is analytic. The argument is the following. Assume `g z = ∑' qₙ (z, ..., z)` and `f y = ∑' pₖ (y, ..., y)`. Then `g (f y) = ∑' qₙ (∑' pₖ (y, ..., y), ..., ∑' pₖ (y, ..., y)) = ∑' qₙ (p_{i₁} (y, ..., y), ..., p_{iₙ} (y, ..., y))`. For each `n` and `i₁, ..., iₙ`, define a `i₁ + ... + iₙ` multilinear function mapping `(y₀, ..., y_{i₁ + ... + iₙ - 1})` to `qₙ (p_{i₁} (y₀, ..., y_{i₁-1}), p_{i₂} (y_{i₁}, ..., y_{i₁ + i₂ - 1}), ..., p_{iₙ} (....)))`. Then `g ∘ f` is obtained by summing all these multilinear functions. To formalize this, we use compositions of an integer `N`, i.e., its decompositions into a sum `i₁ + ... + iₙ` of positive integers. Given such a composition `c` and two formal multilinear series `q` and `p`, let `q.compAlongComposition p c` be the above multilinear function. Then the `N`-th coefficient in the power series expansion of `g ∘ f` is the sum of these terms over all `c : Composition N`. To complete the proof, we need to show that this power series has a positive radius of convergence. This follows from the fact that `Composition N` has cardinality `2^(N-1)` and estimates on the norm of `qₙ` and `pₖ`, which give summability. We also need to show that it indeed converges to `g ∘ f`. For this, we note that the composition of partial sums converges to `g ∘ f`, and that it corresponds to a part of the whole sum, on a subset that increases to the whole space. By summability of the norms, this implies the overall convergence. ## Main results * `q.comp p` is the formal composition of the formal multilinear series `q` and `p`. * `HasFPowerSeriesAt.comp` states that if two functions `g` and `f` admit power series expansions `q` and `p`, then `g ∘ f` admits a power series expansion given by `q.comp p`. * `AnalyticAt.comp` states that the composition of analytic functions is analytic. * `FormalMultilinearSeries.comp_assoc` states that composition is associative on formal multilinear series. ## Implementation details The main technical difficulty is to write down things. In particular, we need to define precisely `q.compAlongComposition p c` and to show that it is indeed a continuous multilinear function. This requires a whole interface built on the class `Composition`. Once this is set, the main difficulty is to reorder the sums, writing the composition of the partial sums as a sum over some subset of `Σ n, Composition n`. We need to check that the reordering is a bijection, running over difficulties due to the dependent nature of the types under consideration, that are controlled thanks to the interface for `Composition`. The associativity of composition on formal multilinear series is a nontrivial result: it does not follow from the associativity of composition of analytic functions, as there is no uniqueness for the formal multilinear series representing a function (and also, it holds even when the radius of convergence of the series is `0`). Instead, we give a direct proof, which amounts to reordering double sums in a careful way. The change of variables is a canonical (combinatorial) bijection `Composition.sigmaEquivSigmaPi` between `(Σ (a : Composition n), Composition a.length)` and `(Σ (c : Composition n), Π (i : Fin c.length), Composition (c.blocksFun i))`, and is described in more details below in the paragraph on associativity. -/ noncomputable section variable {𝕜 : Type} {E F G H : Type} open Filter List open scoped Topology NNReal ENNReal section Topological variable [CommRing 𝕜] [AddCommGroup E] [AddCommGroup F] [AddCommGroup G] variable [Module 𝕜 E] [Module 𝕜 F] [Module 𝕜 G] variable [TopologicalSpace E] [TopologicalSpace F] [TopologicalSpace G] /-! ### Composing formal multilinear series -/ namespace FormalMultilinearSeries variable [IsTopologicalAddGroup E] [ContinuousConstSMul 𝕜 E] variable [IsTopologicalAddGroup F] [ContinuousConstSMul 𝕜 F] variable [IsTopologicalAddGroup G] [ContinuousConstSMul 𝕜 G] /-! In this paragraph, we define the composition of formal multilinear series, by summing over all possible compositions of `n`. -/ /-- Given a formal multilinear series `p`, a composition `c` of `n` and the index `i` of a block of `c`, we may define a function on `Fin n → E` by picking the variables in the `i`-th block of `n`, and applying the corresponding coefficient of `p` to these variables. This function is called `p.applyComposition c v i` for `v : Fin n → E` and `i : Fin c.length`. -/ def applyComposition (p : FormalMultilinearSeries 𝕜 E F) {n : ℕ} (c : Composition n) : (Fin n → E) → Fin c.length → F := fun v i => p (c.blocksFun i) (v ∘ c.embedding i) theorem applyComposition_ones (p : FormalMultilinearSeries 𝕜 E F) (n : ℕ) : p.applyComposition (Composition.ones n) = fun v i => p 1 fun _ => v (Fin.castLE (Composition.length_le _) i) := by funext v i apply p.congr (Composition.ones_blocksFun _ _) intro j hjn hj1 obtain rfl : j = 0 := by omega refine congr_arg v ?_ rw [Fin.ext_iff, Fin.coe_castLE, Composition.ones_embedding, Fin.val_mk] theorem applyComposition_single (p : FormalMultilinearSeries 𝕜 E F) {n : ℕ} (hn : 0 < n) (v : Fin n → E) : p.applyComposition (Composition.single n hn) v = fun _j => p n v := by ext j refine p.congr (by simp) fun i hi1 hi2 => ?_ dsimp congr 1 convert Composition.single_embedding hn ⟨i, hi2⟩ using 1 obtain ⟨j_val, j_property⟩ := j have : j_val = 0 := le_bot_iff.1 (Nat.lt_succ_iff.1 j_property) congr! simp @[simp] theorem removeZero_applyComposition (p : FormalMultilinearSeries 𝕜 E F) {n : ℕ} (c : Composition n) : p.removeZero.applyComposition c = p.applyComposition c := by ext v i simp [applyComposition, zero_lt_one.trans_le (c.one_le_blocksFun i), removeZero_of_pos] /-- Technical lemma stating how `p.applyComposition` commutes with updating variables. This will be the key point to show that functions constructed from `applyComposition` retain multilinearity. -/ theorem applyComposition_update (p : FormalMultilinearSeries 𝕜 E F) {n : ℕ} (c : Composition n) (j : Fin n) (v : Fin n → E) (z : E) : p.applyComposition c (Function.update v j z) = Function.update (p.applyComposition c v) (c.index j) (p (c.blocksFun (c.index j)) (Function.update (v ∘ c.embedding (c.index j)) (c.invEmbedding j) z)) := by ext k by_cases h : k = c.index j · rw [h] let r : Fin (c.blocksFun (c.index j)) → Fin n := c.embedding (c.index j) simp only [Function.update_self] change p (c.blocksFun (c.index j)) (Function.update v j z ∘ r) = _ let j' := c.invEmbedding j suffices B : Function.update v j z ∘ r = Function.update (v ∘ r) j' z by rw [B] suffices C : Function.update v (r j') z ∘ r = Function.update (v ∘ r) j' z by convert C; exact (c.embedding_comp_inv j).symm exact Function.update_comp_eq_of_injective _ (c.embedding _).injective _ _ · simp only [h, Function.update_eq_self, Function.update_of_ne, Ne, not_false_iff] let r : Fin (c.blocksFun k) → Fin n := c.embedding k change p (c.blocksFun k) (Function.update v j z ∘ r) = p (c.blocksFun k) (v ∘ r) suffices B : Function.update v j z ∘ r = v ∘ r by rw [B] apply Function.update_comp_eq_of_not_mem_range rwa [c.mem_range_embedding_iff'] @[simp] theorem compContinuousLinearMap_applyComposition {n : ℕ} (p : FormalMultilinearSeries 𝕜 F G) (f : E →L[𝕜] F) (c : Composition n) (v : Fin n → E) : (p.compContinuousLinearMap f).applyComposition c v = p.applyComposition c (f ∘ v) := by simp (config := {unfoldPartialApp := true}) [applyComposition]; rfl end FormalMultilinearSeries namespace ContinuousMultilinearMap open FormalMultilinearSeries variable [IsTopologicalAddGroup E] [ContinuousConstSMul 𝕜 E] variable [IsTopologicalAddGroup F] [ContinuousConstSMul 𝕜 F] /-- Given a formal multilinear series `p`, a composition `c` of `n` and a continuous multilinear map `f` in `c.length` variables, one may form a continuous multilinear map in `n` variables by applying the right coefficient of `p` to each block of the composition, and then applying `f` to the resulting vector. It is called `f.compAlongComposition p c`. -/ def compAlongComposition {n : ℕ} (p : FormalMultilinearSeries 𝕜 E F) (c : Composition n) (f : F [×c.length]→L[𝕜] G) : E [×n]→L[𝕜] G where toMultilinearMap := MultilinearMap.mk' (fun v ↦ f (p.applyComposition c v)) (fun v i x y ↦ by simp only [applyComposition_update, map_update_add]) (fun v i c x ↦ by simp only [applyComposition_update, map_update_smul]) cont := f.cont.comp <\| continuous_pi fun _ => (coe_continuous _).comp <\| continuous_pi fun _ => continuous_apply _ @[simp] theorem compAlongComposition_apply {n : ℕ} (p : FormalMultilinearSeries 𝕜 E F) (c : Composition n) (f : F [×c.length]→L[𝕜] G) (v : Fin n → E) : (f.compAlongComposition p c) v = f (p.applyComposition c v) := rfl end ContinuousMultilinearMap namespace FormalMultilinearSeries variable [IsTopologicalAddGroup E] [ContinuousConstSMul 𝕜 E] variable [IsTopologicalAddGroup F] [ContinuousConstSMul 𝕜 F] variable [IsTopologicalAddGroup G] [ContinuousConstSMul 𝕜 G] /-- Given two formal multilinear series `q` and `p` and a composition `c` of `n`, one may form a continuous multilinear map in `n` variables by applying the right coefficient of `p` to each block of the composition, and then applying `q c.length` to the resulting vector. It is called `q.compAlongComposition p c`. -/ def compAlongComposition {n : ℕ} (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) (c : Composition n) : (E [×n]→L[𝕜] G) := (q c.length).compAlongComposition p c @[simp] theorem compAlongComposition_apply {n : ℕ} (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) (c : Composition n) (v : Fin n → E) : (q.compAlongComposition p c) v = q c.length (p.applyComposition c v) := rfl /-- Formal composition of two formal multilinear series. The `n`-th coefficient in the composition is defined to be the sum of `q.compAlongComposition p c` over all compositions of `n`. In other words, this term (as a multilinear function applied to `v_0, ..., v_{n-1}`) is `∑'_{k} ∑'_{i₁ + ... + iₖ = n} qₖ (p_{i_1} (...), ..., p_{i_k} (...))`, where one puts all variables `v_0, ..., v_{n-1}` in increasing order in the dots. In general, the composition `q ∘ p` only makes sense when the constant coefficient of `p` vanishes. We give a general formula but which ignores the value of `p 0` instead. -/ protected def comp (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) : FormalMultilinearSeries 𝕜 E G := fun n => ∑ c : Composition n, q.compAlongComposition p c /-- The `0`-th coefficient of `q.comp p` is `q 0`. Since these maps are multilinear maps in zero variables, but on different spaces, we can not state this directly, so we state it when applied to arbitrary vectors (which have to be the zero vector). -/ theorem comp_coeff_zero (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) (v : Fin 0 → E) (v' : Fin 0 → F) : (q.comp p) 0 v = q 0 v' := by let c : Composition 0 := Composition.ones 0 dsimp [FormalMultilinearSeries.comp] have : {c} = (Finset.univ : Finset (Composition 0)) := by apply Finset.eq_of_subset_of_card_le <;> simp [Finset.card_univ, composition_card 0] rw [← this, Finset.sum_singleton, compAlongComposition_apply] symm; congr! -- Porting note: needed the stronger `congr!`! @[simp] theorem comp_coeff_zero' (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) (v : Fin 0 → E) : (q.comp p) 0 v = q 0 fun _i => 0 := q.comp_coeff_zero p v _ /-- The `0`-th coefficient of `q.comp p` is `q 0`. When `p` goes from `E` to `E`, this can be expressed as a direct equality -/ theorem comp_coeff_zero'' (q : FormalMultilinearSeries 𝕜 E F) (p : FormalMultilinearSeries 𝕜 E E) : (q.comp p) 0 = q 0 := by ext v; exact q.comp_coeff_zero p _ _ /-- The first coefficient of a composition of formal multilinear series is the composition of the first coefficients seen as continuous linear maps. -/ theorem comp_coeff_one (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) (v : Fin 1 → E) : (q.comp p) 1 v = q 1 fun _i => p 1 v := by have : {Composition.ones 1} = (Finset.univ : Finset (Composition 1)) := Finset.eq_univ_of_card _ (by simp [composition_card]) simp only [FormalMultilinearSeries.comp, compAlongComposition_apply, ← this, Finset.sum_singleton] refine q.congr (by simp) fun i hi1 hi2 => ?_ simp only [applyComposition_ones] exact p.congr rfl fun j _hj1 hj2 => by congr! -- Porting note: needed the stronger `congr!` /-- Only `0`-th coefficient of `q.comp p` depends on `q 0`. -/ theorem removeZero_comp_of_pos (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) {n : ℕ} (hn : 0 < n) : q.removeZero.comp p n = q.comp p n := by ext v simp only [FormalMultilinearSeries.comp, compAlongComposition, ContinuousMultilinearMap.compAlongComposition_apply, ContinuousMultilinearMap.sum_apply] refine Finset.sum_congr rfl fun c _hc => ?_ rw [removeZero_of_pos _ (c.length_pos_of_pos hn)] @[simp] theorem comp_removeZero (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) : q.comp p.removeZero = q.comp p := by ext n; simp [FormalMultilinearSeries.comp] end FormalMultilinearSeries end Topological variable [NontriviallyNormedField 𝕜] [NormedAddCommGroup E] [NormedSpace 𝕜 E] [NormedAddCommGroup F] [NormedSpace 𝕜 F] [NormedAddCommGroup G] [NormedSpace 𝕜 G] [NormedAddCommGroup H] [NormedSpace 𝕜 H] namespace FormalMultilinearSeries /-- The norm of `f.compAlongComposition p c` is controlled by the product of the norms of the relevant bits of `f` and `p`. -/ theorem compAlongComposition_bound {n : ℕ} (p : FormalMultilinearSeries 𝕜 E F) (c : Composition n) (f : F [×c.length]→L[𝕜] G) (v : Fin n → E) : ‖f.compAlongComposition p c v‖ ≤ (‖f‖ * ∏ i, ‖p (c.blocksFun i)‖) * ∏ i : Fin n, ‖v i‖ := calc ‖f.compAlongComposition p c v‖ = ‖f (p.applyComposition c v)‖ := rfl _ ≤ ‖f‖ * ∏ i, ‖p.applyComposition c v i‖ := ContinuousMultilinearMap.le_opNorm _ _ _ ≤ ‖f‖ * ∏ i, ‖p (c.blocksFun i)‖ * ∏ j : Fin (c.blocksFun i), ‖(v ∘ c.embedding i) j‖ := by apply mul_le_mul_of_nonneg_left _ (norm_nonneg _) refine Finset.prod_le_prod (fun i _hi => norm_nonneg _) fun i _hi => ?_ apply ContinuousMultilinearMap.le_opNorm _ = (‖f‖ * ∏ i, ‖p (c.blocksFun i)‖) * ∏ i, ∏ j : Fin (c.blocksFun i), ‖(v ∘ c.embedding i) j‖ := by rw [Finset.prod_mul_distrib, mul_assoc] _ = (‖f‖ * ∏ i, ‖p (c.blocksFun i)‖) * ∏ i : Fin n, ‖v i‖ := by rw [← c.blocksFinEquiv.prod_comp, ← Finset.univ_sigma_univ, Finset.prod_sigma] congr /-- The norm of `q.compAlongComposition p c` is controlled by the product of the norms of the relevant bits of `q` and `p`. -/ theorem compAlongComposition_norm {n : ℕ} (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) (c : Composition n) : ‖q.compAlongComposition p c‖ ≤ ‖q c.length‖ * ∏ i, ‖p (c.blocksFun i)‖ := ContinuousMultilinearMap.opNorm_le_bound (by positivity) (compAlongComposition_bound _ _ _) theorem compAlongComposition_nnnorm {n : ℕ} (q : FormalMultilinearSeries 𝕜 F G) (p : FormalMultilinearSeries 𝕜 E F) (c : Composition n) : ‖q.compAlongComposition p c‖₊ ≤ ‖q c.length‖₊ * ∏ i, ‖p (c.blocksFun i)‖₊ := by rw [← NNReal.coe_le_coe]; push_cast; exact q.compAlongComposition_norm p c /-! ### The identity formal power series We will now define the identity power series, and show that it is a neutral element for left and right composition. -/ section variable (𝕜 E) /-- The identity formal multilinear series, with all coefficients equal to `0` except for `n = 1` where it is (the continuous multilinear version of) the identity. We allow an arbitrary constant coefficient `x`. -/ def id (x : E) : FormalMultilinearSeries 𝕜 E E \| 0 => ContinuousMultilinearMap.uncurry0 𝕜 _ x \| 1 => (continuousMultilinearCurryFin1 𝕜 E E).symm (ContinuousLinearMap.id 𝕜 E) \| _ => 0 @[simp] theorem id_apply_zero (x : E) (v : Fin 0 → E) : (FormalMultilinearSeries.id 𝕜 E x) 0 v = x := rfl /-- The first coefficient of `id 𝕜 E` is the identity. -/ @[simp] theorem id_apply_one (x : E) (v : Fin 1 → E) : (FormalMultilinearSeries.id 𝕜 E x) 1 v = v 0 := rfl /-- The `n`th coefficient of `id 𝕜 E` is the identity when `n = 1`. We state this in a dependent way, as it will often appear in this form. -/ theorem id_apply_one' (x : E) {n : ℕ} (h : n = 1) (v : Fin n → E) : (id 𝕜 E x) n v = v ⟨0, h.symm ▸ zero_lt_one⟩ := by subst n apply id_apply_one /-- For `n ≠ 1`, the `n`-th coefficient of `id 𝕜 E` is zero, by definition. -/ @[simp] theorem id_apply_of_one_lt (x : E) {n : ℕ} (h : 1 < n) : (FormalMultilinearSeries.id 𝕜 E x) n = 0 := by match n with \| 0 => contradiction \| 1 => contradiction \| n + 2 => rfl end @[simp] theorem comp_id (p : FormalMultilinearSeries 𝕜 E F) (x : E) : p.comp (id 𝕜 E x) = p := by ext1 n dsimp [FormalMultilinearSeries.comp] rw [Finset.sum_eq_single (Composition.ones n)] · show compAlongComposition p (id 𝕜 E x) (Composition.ones n) = p n ext v rw [compAlongComposition_apply] apply p.congr (Composition.ones_length n) intros rw [applyComposition_ones] refine congr_arg v ?_ rw [Fin.ext_iff, Fin.coe_castLE, Fin.val_mk] · show ∀ b : Composition n, b ∈ Finset.univ → b ≠ Composition.ones n → compAlongComposition p (id 𝕜 E x) b = 0 intro b _ hb obtain ⟨k, hk, lt_k⟩ : ∃ (k : ℕ), k ∈ Composition.blocks b ∧ 1 < k := Composition.ne_ones_iff.1 hb obtain ⟨i, hi⟩ : ∃ (i : Fin b.blocks.length), b.blocks[i] = k := List.get_of_mem hk let j : Fin b.length := ⟨i.val, b.blocks_length ▸ i.prop⟩ have A : 1 < b.blocksFun j := by convert lt_k ext v rw [compAlongComposition_apply, ContinuousMultilinearMap.zero_apply] apply ContinuousMultilinearMap.map_coord_zero _ j dsimp [applyComposition] rw [id_apply_of_one_lt _ _ _ A, ContinuousMultilinearMap.zero_apply]	· simp @[simp] theorem id_comp (p : FormalMultilinearSeries 𝕜 E F) (v0 : Fin 0 → E) : (id 𝕜 F (p 0 v0)).comp p = p := by ext1 n obtain rfl \| n_pos := n.eq_zero_or_pos · ext v simp only [comp_coeff_zero', id_apply_zero] congr with i exact i.elim0 · dsimp [FormalMultilinearSeries.comp] rw [Finset.sum_eq_single (Composition.single n n_pos)] · show compAlongComposition (id 𝕜 F (p 0 v0)) p (Composition.single n n_pos) = p n ext v rw [compAlongComposition_apply, id_apply_one' _ _ _ (Composition.single_length n_pos)] dsimp [applyComposition] refine p.congr rfl fun i him hin => congr_arg v <\| ?_ ext; simp · show ∀ b : Composition n, b ∈ Finset.univ → b ≠ Composition.single n n_pos → compAlongComposition (id 𝕜 F (p 0 v0)) p b = 0 intro b _ hb have A : 1 < b.length := by have : b.length ≠ 1 := by simpa [Composition.eq_single_iff_length] using hb have : 0 < b.length := Composition.length_pos_of_pos b n_pos omega ext v rw [compAlongComposition_apply, id_apply_of_one_lt _ _ _ A, ContinuousMultilinearMap.zero_apply, ContinuousMultilinearMap.zero_apply]	Mathlib/Analysis/Analytic/Composition.lean	390	419
/- 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.Logic.Nontrivial.Basic import Mathlib.Order.TypeTags import Mathlib.Data.Option.NAry import Mathlib.Tactic.Contrapose import Mathlib.Tactic.Lift import Mathlib.Data.Option.Basic import Mathlib.Order.Lattice import Mathlib.Order.BoundedOrder.Basic /-! # `WithBot`, `WithTop` Adding a `bot` or a `top` to an order. ## Main declarations * `With<Top/Bot> α`: Equips `Option α` with the order on `α` plus `none` as the top/bottom element. -/ variable {α β γ δ : Type*} namespace WithBot variable {a b : α} instance nontrivial [Nonempty α] : Nontrivial (WithBot α) := Option.nontrivial open Function theorem coe_injective : Injective ((↑) : α → WithBot α) := Option.some_injective _ @[simp, norm_cast] theorem coe_inj : (a : WithBot α) = b ↔ a = b := Option.some_inj protected theorem «forall» {p : WithBot α → Prop} : (∀ x, p x) ↔ p ⊥ ∧ ∀ x : α, p x := Option.forall protected theorem «exists» {p : WithBot α → Prop} : (∃ x, p x) ↔ p ⊥ ∨ ∃ x : α, p x := Option.exists theorem none_eq_bot : (none : WithBot α) = (⊥ : WithBot α) := rfl theorem some_eq_coe (a : α) : (Option.some a : WithBot α) = (↑a : WithBot α) := rfl @[simp] theorem bot_ne_coe : ⊥ ≠ (a : WithBot α) := nofun @[simp] theorem coe_ne_bot : (a : WithBot α) ≠ ⊥ := nofun /-- Specialization of `Option.getD` to values in `WithBot α` that respects API boundaries. -/ def unbotD (d : α) (x : WithBot α) : α := recBotCoe d id x @[deprecated (since := "2025-02-06")] alias unbot' := unbotD @[simp] theorem unbotD_bot {α} (d : α) : unbotD d ⊥ = d := rfl @[deprecated (since := "2025-02-06")] alias unbot'_bot := unbotD_bot @[simp] theorem unbotD_coe {α} (d x : α) : unbotD d x = x := rfl @[deprecated (since := "2025-02-06")] alias unbot'_coe := unbotD_coe theorem coe_eq_coe : (a : WithBot α) = b ↔ a = b := coe_inj theorem unbotD_eq_iff {d y : α} {x : WithBot α} : unbotD d x = y ↔ x = y ∨ x = ⊥ ∧ y = d := by induction x <;> simp [@eq_comm _ d] @[deprecated (since := "2025-02-06")] alias unbot'_eq_iff := unbotD_eq_iff @[simp] theorem unbotD_eq_self_iff {d : α} {x : WithBot α} : unbotD d x = d ↔ x = d ∨ x = ⊥ := by simp [unbotD_eq_iff] @[deprecated (since := "2025-02-06")] alias unbot'_eq_self_iff := unbotD_eq_self_iff theorem unbotD_eq_unbotD_iff {d : α} {x y : WithBot α} : unbotD d x = unbotD d y ↔ x = y ∨ x = d ∧ y = ⊥ ∨ x = ⊥ ∧ y = d := by induction y <;> simp [unbotD_eq_iff, or_comm] @[deprecated (since := "2025-02-06")] alias unbot'_eq_unbot'_iff := unbotD_eq_unbotD_iff /-- Lift a map `f : α → β` to `WithBot α → WithBot β`. Implemented using `Option.map`. -/ def map (f : α → β) : WithBot α → WithBot β := Option.map f @[simp] theorem map_bot (f : α → β) : map f ⊥ = ⊥ := rfl @[simp] theorem map_coe (f : α → β) (a : α) : map f a = f a := rfl @[simp] lemma map_eq_bot_iff {f : α → β} {a : WithBot α} : map f a = ⊥ ↔ a = ⊥ := Option.map_eq_none_iff theorem map_eq_some_iff {f : α → β} {y : β} {v : WithBot α} : WithBot.map f v = .some y ↔ ∃ x, v = .some x ∧ f x = y := Option.map_eq_some_iff theorem some_eq_map_iff {f : α → β} {y : β} {v : WithBot α} : .some y = WithBot.map f v ↔ ∃ x, v = .some x ∧ f x = y := by cases v <;> simp [eq_comm] theorem map_comm {f₁ : α → β} {f₂ : α → γ} {g₁ : β → δ} {g₂ : γ → δ} (h : g₁ ∘ f₁ = g₂ ∘ f₂) (a : α) : map g₁ (map f₁ a) = map g₂ (map f₂ a) := Option.map_comm h _ /-- The image of a binary function `f : α → β → γ` as a function `WithBot α → WithBot β → WithBot γ`. Mathematically this should be thought of as the image of the corresponding function `α × β → γ`. -/ def map₂ : (α → β → γ) → WithBot α → WithBot β → WithBot γ := Option.map₂ lemma map₂_coe_coe (f : α → β → γ) (a : α) (b : β) : map₂ f a b = f a b := rfl @[simp] lemma map₂_bot_left (f : α → β → γ) (b) : map₂ f ⊥ b = ⊥ := rfl @[simp] lemma map₂_bot_right (f : α → β → γ) (a) : map₂ f a ⊥ = ⊥ := by cases a <;> rfl @[simp] lemma map₂_coe_left (f : α → β → γ) (a : α) (b) : map₂ f a b = b.map fun b ↦ f a b := rfl @[simp] lemma map₂_coe_right (f : α → β → γ) (a) (b : β) : map₂ f a b = a.map (f · b) := by cases a <;> rfl @[simp] lemma map₂_eq_bot_iff {f : α → β → γ} {a : WithBot α} {b : WithBot β} : map₂ f a b = ⊥ ↔ a = ⊥ ∨ b = ⊥ := Option.map₂_eq_none_iff lemma ne_bot_iff_exists {x : WithBot α} : x ≠ ⊥ ↔ ∃ a : α, ↑a = x := Option.ne_none_iff_exists lemma eq_bot_iff_forall_ne {x : WithBot α} : x = ⊥ ↔ ∀ a : α, ↑a ≠ x := Option.eq_none_iff_forall_some_ne @[deprecated (since := "2025-03-19")] alias forall_ne_iff_eq_bot := eq_bot_iff_forall_ne /-- Deconstruct a `x : WithBot α` to the underlying value in `α`, given a proof that `x ≠ ⊥`. -/ def unbot : ∀ x : WithBot α, x ≠ ⊥ → α \| (x : α), _ => x @[simp] lemma coe_unbot : ∀ (x : WithBot α) hx, x.unbot hx = x \| (x : α), _ => rfl @[simp] theorem unbot_coe (x : α) (h : (x : WithBot α) ≠ ⊥ := coe_ne_bot) : (x : WithBot α).unbot h = x := rfl instance canLift : CanLift (WithBot α) α (↑) fun r => r ≠ ⊥ where prf x h := ⟨x.unbot h, coe_unbot _ _⟩ instance instTop [Top α] : Top (WithBot α) where top := (⊤ : α) @[simp, norm_cast] lemma coe_top [Top α] : ((⊤ : α) : WithBot α) = ⊤ := rfl @[simp, norm_cast] lemma coe_eq_top [Top α] {a : α} : (a : WithBot α) = ⊤ ↔ a = ⊤ := coe_eq_coe @[simp, norm_cast] lemma top_eq_coe [Top α] {a : α} : ⊤ = (a : WithBot α) ↔ ⊤ = a := coe_eq_coe theorem unbot_eq_iff {a : WithBot α} {b : α} (h : a ≠ ⊥) : a.unbot h = b ↔ a = b := by induction a · simpa using h rfl · simp theorem eq_unbot_iff {a : α} {b : WithBot α} (h : b ≠ ⊥) : a = b.unbot h ↔ a = b := by induction b · simpa using h rfl · simp /-- The equivalence between the non-bottom elements of `WithBot α` and `α`. -/ @[simps] def _root_.Equiv.withBotSubtypeNe : {y : WithBot α // y ≠ ⊥} ≃ α where toFun := fun ⟨x,h⟩ => WithBot.unbot x h invFun x := ⟨x, WithBot.coe_ne_bot⟩ left_inv _ := by simp right_inv _ := by simp section LE variable [LE α] {x y : WithBot α} instance (priority := 10) le : LE (WithBot α) := ⟨fun o₁ o₂ => ∀ a : α, o₁ = ↑a → ∃ b : α, o₂ = ↑b ∧ a ≤ b⟩ lemma le_def : x ≤ y ↔ ∀ a : α, x = ↑a → ∃ b : α, y = ↑b ∧ a ≤ b := .rfl @[simp, norm_cast] lemma coe_le_coe : (a : WithBot α) ≤ b ↔ a ≤ b := by simp [le_def] lemma not_coe_le_bot (a : α) : ¬(a : WithBot α) ≤ ⊥ := by simp [le_def] instance orderBot : OrderBot (WithBot α) where bot_le := by simp [le_def] instance orderTop [OrderTop α] : OrderTop (WithBot α) where le_top x := by cases x <;> simp [le_def] instance instBoundedOrder [OrderTop α] : BoundedOrder (WithBot α) := { WithBot.orderBot, WithBot.orderTop with } /-- There is a general version `le_bot_iff`, but this lemma does not require a `PartialOrder`. -/ @[simp] protected theorem le_bot_iff : ∀ {a : WithBot α}, a ≤ ⊥ ↔ a = ⊥ \| (a : α) => by simp [not_coe_le_bot _] \| ⊥ => by simp theorem coe_le : ∀ {o : Option α}, b ∈ o → ((a : WithBot α) ≤ o ↔ a ≤ b) \| _, rfl => coe_le_coe theorem coe_le_iff : a ≤ x ↔ ∃ b : α, x = b ∧ a ≤ b := by simp [le_def] theorem le_coe_iff : x ≤ b ↔ ∀ a : α, x = ↑a → a ≤ b := by simp [le_def] protected theorem _root_.IsMax.withBot (h : IsMax a) : IsMax (a : WithBot α) := fun x ↦ by cases x <;> simp; simpa using @h _ lemma le_unbot_iff (hy : y ≠ ⊥) : a ≤ unbot y hy ↔ a ≤ y := by lift y to α using id hy; simp lemma unbot_le_iff (hx : x ≠ ⊥) : unbot x hx ≤ b ↔ x ≤ b := by lift x to α using id hx; simp lemma unbotD_le_iff (hx : x = ⊥ → a ≤ b) : x.unbotD a ≤ b ↔ x ≤ b := by cases x <;> simp [hx] @[deprecated (since := "2025-02-06")] alias unbot'_le_iff := unbotD_le_iff end LE section LT variable [LT α] {x y : WithBot α} instance (priority := 10) lt : LT (WithBot α) := ⟨fun o₁ o₂ : WithBot α => ∃ b : α, o₂ = ↑b ∧ ∀ a : α, o₁ = ↑a → a < b⟩ lemma lt_def : x < y ↔ ∃ b : α, y = ↑b ∧ ∀ a : α, x = ↑a → a < b := .rfl @[simp, norm_cast] lemma coe_lt_coe : (a : WithBot α) < b ↔ a < b := by simp [lt_def] @[simp] lemma bot_lt_coe (a : α) : ⊥ < (a : WithBot α) := by simp [lt_def] @[simp] protected lemma not_lt_bot (a : WithBot α) : ¬a < ⊥ := by simp [lt_def] lemma lt_iff_exists_coe : x < y ↔ ∃ b : α, y = b ∧ x < b := by cases y <;> simp lemma lt_coe_iff : x < b ↔ ∀ a : α, x = a → a < b := by simp [lt_def] /-- A version of `bot_lt_iff_ne_bot` for `WithBot` that only requires `LT α`, not `PartialOrder α`. -/ protected lemma bot_lt_iff_ne_bot : ⊥ < x ↔ x ≠ ⊥ := by cases x <;> simp lemma lt_unbot_iff (hy : y ≠ ⊥) : a < unbot y hy ↔ a < y := by lift y to α using id hy; simp lemma unbot_lt_iff (hx : x ≠ ⊥) : unbot x hx < b ↔ x < b := by lift x to α using id hx; simp lemma unbotD_lt_iff (hx : x = ⊥ → a < b) : x.unbotD a < b ↔ x < b := by cases x <;> simp [hx] @[deprecated (since := "2025-02-06")] alias unbot'_lt_iff := unbotD_lt_iff end LT instance preorder [Preorder α] : Preorder (WithBot α) where	lt_iff_le_not_le x y := by cases x <;> cases y <;> simp [lt_iff_le_not_le] le_refl x := by cases x <;> simp [le_def] le_trans x y z := by cases x <;> cases y <;> cases z <;> simp [le_def]; simpa using le_trans	Mathlib/Order/WithBot.lean	272	275
/- 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.Ring.Defs import Mathlib.Order.RelClasses /-! # Euclidean domains This file introduces Euclidean domains and provides the extended Euclidean algorithm. To be precise, a slightly more general version is provided which is sometimes called a transfinite Euclidean domain and differs in the fact that the degree function need not take values in `ℕ` but can take values in any well-ordered set. Transfinite Euclidean domains were introduced by Motzkin and examples which don't satisfy the classical notion were provided independently by Hiblot and Nagata. ## Main definitions * `EuclideanDomain`: Defines Euclidean domain with functions `quotient` and `remainder`. Instances of `Div` and `Mod` are provided, so that one can write `a = b * (a / b) + a % b`. * `gcd`: defines the greatest common divisors of two elements of a Euclidean domain. * `xgcd`: given two elements `a b : R`, `xgcd a b` defines the pair `(x, y)` such that `x * a + y * b = gcd a b`. * `lcm`: defines the lowest common multiple of two elements `a` and `b` of a Euclidean domain as `a * b / (gcd a b)` ## Main statements See `Algebra.EuclideanDomain.Basic` for most of the theorems about Euclidean domains, including Bézout's lemma. See `Algebra.EuclideanDomain.Instances` for the fact that `ℤ` is a Euclidean domain, as is any field. ## Notation `≺` denotes the well founded relation on the Euclidean domain, e.g. in the example of the polynomial ring over a field, `p ≺ q` for polynomials `p` and `q` if and only if the degree of `p` is less than the degree of `q`. ## Implementation details Instead of working with a valuation, `EuclideanDomain` is implemented with the existence of a well founded relation `r` on the integral domain `R`, which in the example of `ℤ` would correspond to setting `i ≺ j` for integers `i` and `j` if the absolute value of `i` is smaller than the absolute value of `j`. ## References * [Th. Motzkin, The Euclidean algorithm][MR32592] * [J.-J. Hiblot, Des anneaux euclidiens dont le plus petit algorithme n'est pas à valeurs finies] [MR399081] * [M. Nagata, On Euclid algorithm][MR541021] ## Tags Euclidean domain, transfinite Euclidean domain, Bézout's lemma -/ universe u /-- A `EuclideanDomain` is a non-trivial commutative ring with a division and a remainder, satisfying `b * (a / b) + a % b = a`. The definition of a Euclidean domain usually includes a valuation function `R → ℕ`. This definition is slightly generalised to include a well founded relation `r` with the property that `r (a % b) b`, instead of a valuation. -/ class EuclideanDomain (R : Type u) extends CommRing R, Nontrivial R where /-- A division function (denoted `/`) on `R`. This satisfies the property `b * (a / b) + a % b = a`, where `%` denotes `remainder`. -/ protected quotient : R → R → R /-- Division by zero should always give zero by convention. -/ protected quotient_zero : ∀ a, quotient a 0 = 0 /-- A remainder function (denoted `%`) on `R`. This satisfies the property `b * (a / b) + a % b = a`, where `/` denotes `quotient`. -/ protected remainder : R → R → R /-- The property that links the quotient and remainder functions. This allows us to compute GCDs and LCMs. -/ protected quotient_mul_add_remainder_eq : ∀ a b, b * quotient a b + remainder a b = a /-- A well-founded relation on `R`, satisfying `r (a % b) b`. This ensures that the GCD algorithm always terminates. -/ protected r : R → R → Prop /-- The relation `r` must be well-founded. This ensures that the GCD algorithm always terminates. -/ r_wellFounded : WellFounded r /-- The relation `r` satisfies `r (a % b) b`. -/ protected remainder_lt : ∀ (a) {b}, b ≠ 0 → r (remainder a b) b /-- An additional constraint on `r`. -/ mul_left_not_lt : ∀ (a) {b}, b ≠ 0 → ¬r (a * b) a namespace EuclideanDomain variable {R : Type u} [EuclideanDomain R] /-- Abbreviated notation for the well-founded relation `r` in a Euclidean domain. -/ local infixl:50 " ≺ " => EuclideanDomain.r local instance wellFoundedRelation : WellFoundedRelation R where rel := EuclideanDomain.r wf := r_wellFounded instance isWellFounded : IsWellFounded R (· ≺ ·) where wf := r_wellFounded -- see Note [lower instance priority] instance (priority := 70) : Div R := ⟨EuclideanDomain.quotient⟩ -- see Note [lower instance priority] instance (priority := 70) : Mod R := ⟨EuclideanDomain.remainder⟩ theorem div_add_mod (a b : R) : b * (a / b) + a % b = a := EuclideanDomain.quotient_mul_add_remainder_eq _ _ theorem mod_add_div (a b : R) : a % b + b * (a / b) = a := (add_comm _ _).trans (div_add_mod _ _) theorem mod_add_div' (m k : R) : m % k + m / k * k = m := by rw [mul_comm] exact mod_add_div _ _ theorem div_add_mod' (m k : R) : m / k * k + m % k = m := by rw [mul_comm] exact div_add_mod _ _ theorem mod_lt : ∀ (a) {b : R}, b ≠ 0 → a % b ≺ b := EuclideanDomain.remainder_lt theorem mul_right_not_lt {a : R} (b) (h : a ≠ 0) : ¬a * b ≺ b := by rw [mul_comm] exact mul_left_not_lt b h @[simp]	theorem mod_zero (a : R) : a % 0 = a := by simpa only [zero_mul, zero_add] using div_add_mod a 0 theorem lt_one (a : R) : a ≺ (1 : R) → a = 0 :=	Mathlib/Algebra/EuclideanDomain/Defs.lean	136	138
/- Copyright (c) 2018 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad -/ import Mathlib.Data.W.Basic /-! # Polynomial functors This file defines polynomial functors and the W-type construction as a polynomial functor. (For the M-type construction, see pfunctor/M.lean.) -/ -- "W", "Idx" universe u v v₁ v₂ v₃ /-- A polynomial functor `P` is given by a type `A` and a family `B` of types over `A`. `P` maps any type `α` to a new type `P α`, which is defined as the sigma type `Σ x, P.B x → α`. An element of `P α` is a pair `⟨a, f⟩`, where `a` is an element of a type `A` and `f : B a → α`. Think of `a` as the shape of the object and `f` as an index to the relevant elements of `α`. -/ @[pp_with_univ] structure PFunctor where /-- The head type -/ A : Type u /-- The child family of types -/ B : A → Type u namespace PFunctor instance : Inhabited PFunctor := ⟨⟨default, default⟩⟩ variable (P : PFunctor.{u}) {α : Type v₁} {β : Type v₂} {γ : Type v₃} /-- Applying `P` to an object of `Type` -/ @[coe] def Obj (α : Type v) := Σ x : P.A, P.B x → α instance : CoeFun PFunctor.{u} (fun _ => Type v → Type (max u v)) where coe := Obj /-- Applying `P` to a morphism of `Type` -/ def map (f : α → β) : P α → P β := fun ⟨a, g⟩ => ⟨a, f ∘ g⟩ instance Obj.inhabited [Inhabited P.A] [Inhabited α] : Inhabited (P α) := ⟨⟨default, default⟩⟩ instance : Functor.{v, max u v} P.Obj where map := @map P /-- We prefer `PFunctor.map` to `Functor.map` because it is universe-polymorphic. -/ @[simp] theorem map_eq_map {α β : Type v} (f : α → β) (x : P α) : f <$> x = P.map f x := rfl @[simp] protected theorem map_eq (f : α → β) (a : P.A) (g : P.B a → α) : P.map f ⟨a, g⟩ = ⟨a, f ∘ g⟩ := rfl @[simp] protected theorem id_map : ∀ x : P α, P.map id x = x := fun ⟨_, _⟩ => rfl @[simp] protected theorem map_map (f : α → β) (g : β → γ) : ∀ x : P α, P.map g (P.map f x) = P.map (g ∘ f) x := fun ⟨_, _⟩ => rfl instance : LawfulFunctor.{v, max u v} P.Obj where map_const := rfl id_map x := P.id_map x comp_map f g x := P.map_map f g x \|>.symm /-- re-export existing definition of W-types and adapt it to a packaged definition of polynomial functor -/ def W := WType P.B /- inhabitants of W types is awkward to encode as an instance assumption because there needs to be a value `a : P.A` such that `P.B a` is empty to yield a finite tree -/ variable {P} /-- root element of a W tree -/ def W.head : W P → P.A \| ⟨a, _f⟩ => a /-- children of the root of a W tree -/ def W.children : ∀ x : W P, P.B (W.head x) → W P \| ⟨_a, f⟩ => f /-- destructor for W-types -/ def W.dest : W P → P (W P) \| ⟨a, f⟩ => ⟨a, f⟩ /-- constructor for W-types -/ def W.mk : P (W P) → W P \| ⟨a, f⟩ => ⟨a, f⟩ @[simp] theorem W.dest_mk (p : P (W P)) : W.dest (W.mk p) = p := by cases p; rfl @[simp] theorem W.mk_dest (p : W P) : W.mk (W.dest p) = p := by cases p; rfl variable (P) /-- `Idx` identifies a location inside the application of a pfunctor. For `F : PFunctor`, `x : F α` and `i : F.Idx`, `i` can designate one part of `x` or is invalid, if `i.1 ≠ x.1` -/ def Idx := Σ x : P.A, P.B x instance Idx.inhabited [Inhabited P.A] [Inhabited (P.B default)] : Inhabited P.Idx := ⟨⟨default, default⟩⟩ variable {P} /-- `x.iget i` takes the component of `x` designated by `i` if any is or returns a default value -/ def Obj.iget [DecidableEq P.A] {α} [Inhabited α] (x : P α) (i : P.Idx) : α := if h : i.1 = x.1 then x.2 (cast (congr_arg _ h) i.2) else default @[simp] theorem fst_map (x : P α) (f : α → β) : (P.map f x).1 = x.1 := by cases x; rfl @[simp] theorem iget_map [DecidableEq P.A] [Inhabited α] [Inhabited β] (x : P α) (f : α → β) (i : P.Idx) (h : i.1 = x.1) : (P.map f x).iget i = f (x.iget i) := by simp only [Obj.iget, fst_map, *, dif_pos, eq_self_iff_true] cases x rfl end PFunctor /- Composition of polynomial functors. -/ namespace PFunctor /-- functor composition for polynomial functors -/ def comp (P₂ P₁ : PFunctor.{u}) : PFunctor.{u} := ⟨Σ a₂ : P₂.1, P₂.2 a₂ → P₁.1, fun a₂a₁ => Σ u : P₂.2 a₂a₁.1, P₁.2 (a₂a₁.2 u)⟩ /-- constructor for composition -/ def comp.mk (P₂ P₁ : PFunctor.{u}) {α : Type} (x : P₂ (P₁ α)) : comp P₂ P₁ α := ⟨⟨x.1, Sigma.fst ∘ x.2⟩, fun a₂a₁ => (x.2 a₂a₁.1).2 a₂a₁.2⟩ /-- destructor for composition -/ def comp.get (P₂ P₁ : PFunctor.{u}) {α : Type} (x : comp P₂ P₁ α) : P₂ (P₁ α) := ⟨x.1.1, fun a₂ => ⟨x.1.2 a₂, fun a₁ => x.2 ⟨a₂, a₁⟩⟩⟩ end PFunctor /- Lifting predicates and relations. -/ namespace PFunctor variable {P : PFunctor.{u}} open Functor theorem liftp_iff {α : Type u} (p : α → Prop) (x : P α) : Liftp p x ↔ ∃ a f, x = ⟨a, f⟩ ∧ ∀ i, p (f i) := by constructor · rintro ⟨y, hy⟩ rcases h : y with ⟨a, f⟩ refine ⟨a, fun i => (f i).val, ?_, fun i => (f i).property⟩ rw [← hy, h, map_eq_map, PFunctor.map_eq] congr rintro ⟨a, f, xeq, pf⟩ use ⟨a, fun i => ⟨f i, pf i⟩⟩ rw [xeq]; rfl theorem liftp_iff' {α : Type u} (p : α → Prop) (a : P.A) (f : P.B a → α) : @Liftp.{u} P.Obj _ α p ⟨a, f⟩ ↔ ∀ i, p (f i) := by simp only [liftp_iff, Sigma.mk.inj_iff]; constructor <;> intro h · rcases h with ⟨a', f', heq, h'⟩ cases heq assumption repeat' first \|constructor\|assumption theorem liftr_iff {α : Type u} (r : α → α → Prop) (x y : P α) : Liftr r x y ↔ ∃ a f₀ f₁, x = ⟨a, f₀⟩ ∧ y = ⟨a, f₁⟩ ∧ ∀ i, r (f₀ i) (f₁ i) := by constructor · rintro ⟨u, xeq, yeq⟩ rcases h : u with ⟨a, f⟩ use a, fun i => (f i).val.fst, fun i => (f i).val.snd constructor · rw [← xeq, h] rfl constructor · rw [← yeq, h] rfl intro i exact (f i).property rintro ⟨a, f₀, f₁, xeq, yeq, h⟩ use ⟨a, fun i => ⟨(f₀ i, f₁ i), h i⟩⟩ constructor · rw [xeq] rfl rw [yeq]; rfl	open Set theorem supp_eq {α : Type u} (a : P.A) (f : P.B a → α) : @supp.{u} P.Obj _ α (⟨a, f⟩ : P α) = f '' univ := by ext x; simp only [supp, image_univ, mem_range, mem_setOf_eq] constructor <;> intro h	Mathlib/Data/PFunctor/Univariate/Basic.lean	211	217
/- Copyright (c) 2022 Markus Himmel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Markus Himmel -/ import Mathlib.CategoryTheory.Limits.Preserves.Shapes.Terminal import Mathlib.CategoryTheory.Limits.Shapes.ZeroMorphisms /-! # Preservation of zero objects and zero morphisms We define the class `PreservesZeroMorphisms` and show basic properties. ## Main results We provide the following results: * Left adjoints and right adjoints preserve zero morphisms; * full functors preserve zero morphisms; * if both categories involved have a zero object, then a functor preserves zero morphisms if and only if it preserves the zero object; * functors which preserve initial or terminal objects preserve zero morphisms. -/ universe v u v₁ v₂ v₃ u₁ u₂ u₃ noncomputable section open CategoryTheory open CategoryTheory.Limits namespace CategoryTheory.Functor variable {C : Type u₁} [Category.{v₁} C] {D : Type u₂} [Category.{v₂} D] {E : Type u₃} [Category.{v₃} E] section ZeroMorphisms variable [HasZeroMorphisms C] [HasZeroMorphisms D] [HasZeroMorphisms E] /-- A functor preserves zero morphisms if it sends zero morphisms to zero morphisms. -/ class PreservesZeroMorphisms (F : C ⥤ D) : Prop where /-- For any pair objects `F (0: X ⟶ Y) = (0 : F X ⟶ F Y)` -/ map_zero : ∀ X Y : C, F.map (0 : X ⟶ Y) = 0 := by aesop @[simp] protected theorem map_zero (F : C ⥤ D) [PreservesZeroMorphisms F] (X Y : C) : F.map (0 : X ⟶ Y) = 0 := PreservesZeroMorphisms.map_zero _ _ lemma map_isZero (F : C ⥤ D) [PreservesZeroMorphisms F] {X : C} (hX : IsZero X) : IsZero (F.obj X) := by simp only [IsZero.iff_id_eq_zero] at hX ⊢ rw [← F.map_id, hX, F.map_zero] theorem zero_of_map_zero (F : C ⥤ D) [PreservesZeroMorphisms F] [Faithful F] {X Y : C} (f : X ⟶ Y) (h : F.map f = 0) : f = 0 := F.map_injective <\| h.trans <\| Eq.symm <\| F.map_zero _ _ theorem map_eq_zero_iff (F : C ⥤ D) [PreservesZeroMorphisms F] [Faithful F] {X Y : C} {f : X ⟶ Y} : F.map f = 0 ↔ f = 0 := ⟨F.zero_of_map_zero _, by rintro rfl exact F.map_zero _ _⟩ instance (priority := 100) preservesZeroMorphisms_of_isLeftAdjoint (F : C ⥤ D) [IsLeftAdjoint F] : PreservesZeroMorphisms F where map_zero X Y := by let adj := Adjunction.ofIsLeftAdjoint F calc F.map (0 : X ⟶ Y) = F.map 0 ≫ F.map (adj.unit.app Y) ≫ adj.counit.app (F.obj Y) := ?_ _ = F.map 0 ≫ F.map ((rightAdjoint F).map (0 : F.obj X ⟶ _)) ≫ adj.counit.app (F.obj Y) := ?_ _ = 0 := ?_ · rw [Adjunction.left_triangle_components] exact (Category.comp_id _).symm · simp only [← Category.assoc, ← F.map_comp, zero_comp] · simp only [Adjunction.counit_naturality, comp_zero] instance (priority := 100) preservesZeroMorphisms_of_isRightAdjoint (G : C ⥤ D) [IsRightAdjoint G] : PreservesZeroMorphisms G where map_zero X Y := by let adj := Adjunction.ofIsRightAdjoint G calc G.map (0 : X ⟶ Y) = adj.unit.app (G.obj X) ≫ G.map (adj.counit.app X) ≫ G.map 0 := ?_ _ = adj.unit.app (G.obj X) ≫ G.map ((leftAdjoint G).map (0 : _ ⟶ G.obj X)) ≫ G.map 0 := ?_ _ = 0 := ?_ · rw [Adjunction.right_triangle_components_assoc] · simp only [← G.map_comp, comp_zero] · simp only [id_obj, comp_obj, Adjunction.unit_naturality_assoc, zero_comp] instance (priority := 100) preservesZeroMorphisms_of_full (F : C ⥤ D) [Full F] : PreservesZeroMorphisms F where map_zero X Y := calc F.map (0 : X ⟶ Y) = F.map (0 ≫ F.preimage (0 : F.obj Y ⟶ F.obj Y)) := by rw [zero_comp] _ = 0 := by rw [F.map_comp, F.map_preimage, comp_zero] instance preservesZeroMorphisms_comp (F : C ⥤ D) (G : D ⥤ E) [F.PreservesZeroMorphisms] [G.PreservesZeroMorphisms] : (F ⋙ G).PreservesZeroMorphisms := ⟨by simp⟩ lemma preservesZeroMorphisms_of_iso {F₁ F₂ : C ⥤ D} [F₁.PreservesZeroMorphisms] (e : F₁ ≅ F₂) : F₂.PreservesZeroMorphisms where map_zero X Y := by simp only [← cancel_epi (e.hom.app X), ← e.hom.naturality, F₁.map_zero, zero_comp, comp_zero] instance preservesZeroMorphisms_evaluation_obj (j : D) : PreservesZeroMorphisms ((evaluation D C).obj j) where instance (F : C ⥤ D ⥤ E) [∀ X, (F.obj X).PreservesZeroMorphisms] :	F.flip.PreservesZeroMorphisms where instance (F : C ⥤ D ⥤ E) [F.PreservesZeroMorphisms] (Y : D) : (F.flip.obj Y).PreservesZeroMorphisms where	Mathlib/CategoryTheory/Limits/Preserves/Shapes/Zero.lean	113	116
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Johannes Hölzl -/ import Mathlib.Algebra.Order.Pi import Mathlib.MeasureTheory.Constructions.BorelSpace.Order /-! # Simple functions A function `f` from a measurable space to any type is called simple, if every preimage `f ⁻¹' {x}` is measurable, and the range is finite. In this file, we define simple functions and establish their basic properties; and we construct a sequence of simple functions approximating an arbitrary Borel measurable function `f : α → ℝ≥0∞`. The theorem `Measurable.ennreal_induction` shows that in order to prove something for an arbitrary measurable function into `ℝ≥0∞`, it is sufficient to show that the property holds for (multiples of) characteristic functions and is closed under addition and supremum of increasing sequences of functions. -/ noncomputable section open Set hiding restrict restrict_apply open Filter ENNReal open Function (support) open Topology NNReal ENNReal MeasureTheory namespace MeasureTheory variable {α β γ δ : Type} /-- A function `f` from a measurable space to any type is called simple*, if every preimage `f ⁻¹' {x}` is measurable, and the range is finite. This structure bundles a function with these properties. -/ structure SimpleFunc.{u, v} (α : Type u) [MeasurableSpace α] (β : Type v) where /-- The underlying function -/ toFun : α → β measurableSet_fiber' : ∀ x, MeasurableSet (toFun ⁻¹' {x}) finite_range' : (Set.range toFun).Finite local infixr:25 " →ₛ " => SimpleFunc namespace SimpleFunc section Measurable variable [MeasurableSpace α] instance instFunLike : FunLike (α →ₛ β) α β where coe := toFun coe_injective' \| ⟨_, _, _⟩, ⟨_, _, _⟩, rfl => rfl theorem coe_injective ⦃f g : α →ₛ β⦄ (H : (f : α → β) = g) : f = g := DFunLike.ext' H @[ext] theorem ext {f g : α →ₛ β} (H : ∀ a, f a = g a) : f = g := DFunLike.ext _ _ H theorem finite_range (f : α →ₛ β) : (Set.range f).Finite := f.finite_range' theorem measurableSet_fiber (f : α →ₛ β) (x : β) : MeasurableSet (f ⁻¹' {x}) := f.measurableSet_fiber' x @[simp] theorem coe_mk (f : α → β) (h h') : ⇑(mk f h h') = f := rfl theorem apply_mk (f : α → β) (h h') (x : α) : SimpleFunc.mk f h h' x = f x := rfl /-- Simple function defined on a finite type. -/ def ofFinite [Finite α] [MeasurableSingletonClass α] (f : α → β) : α →ₛ β where toFun := f measurableSet_fiber' x := (toFinite (f ⁻¹' {x})).measurableSet finite_range' := Set.finite_range f /-- Simple function defined on the empty type. -/ def ofIsEmpty [IsEmpty α] : α →ₛ β := ofFinite isEmptyElim /-- Range of a simple function `α →ₛ β` as a `Finset β`. -/ protected def range (f : α →ₛ β) : Finset β := f.finite_range.toFinset @[simp] theorem mem_range {f : α →ₛ β} {b} : b ∈ f.range ↔ b ∈ range f := Finite.mem_toFinset _ theorem mem_range_self (f : α →ₛ β) (x : α) : f x ∈ f.range := mem_range.2 ⟨x, rfl⟩ @[simp] theorem coe_range (f : α →ₛ β) : (↑f.range : Set β) = Set.range f := f.finite_range.coe_toFinset theorem mem_range_of_measure_ne_zero {f : α →ₛ β} {x : β} {μ : Measure α} (H : μ (f ⁻¹' {x}) ≠ 0) : x ∈ f.range := let ⟨a, ha⟩ := nonempty_of_measure_ne_zero H mem_range.2 ⟨a, ha⟩ theorem forall_mem_range {f : α →ₛ β} {p : β → Prop} : (∀ y ∈ f.range, p y) ↔ ∀ x, p (f x) := by simp only [mem_range, Set.forall_mem_range] theorem exists_range_iff {f : α →ₛ β} {p : β → Prop} : (∃ y ∈ f.range, p y) ↔ ∃ x, p (f x) := by simpa only [mem_range, exists_prop] using Set.exists_range_iff theorem preimage_eq_empty_iff (f : α →ₛ β) (b : β) : f ⁻¹' {b} = ∅ ↔ b ∉ f.range := preimage_singleton_eq_empty.trans <\| not_congr mem_range.symm theorem exists_forall_le [Nonempty β] [Preorder β] [IsDirected β (· ≤ ·)] (f : α →ₛ β) : ∃ C, ∀ x, f x ≤ C := f.range.exists_le.imp fun _ => forall_mem_range.1 /-- Constant function as a `SimpleFunc`. -/ def const (α) {β} [MeasurableSpace α] (b : β) : α →ₛ β := ⟨fun _ => b, fun _ => MeasurableSet.const _, finite_range_const⟩ instance instInhabited [Inhabited β] : Inhabited (α →ₛ β) := ⟨const _ default⟩ theorem const_apply (a : α) (b : β) : (const α b) a = b := rfl @[simp] theorem coe_const (b : β) : ⇑(const α b) = Function.const α b := rfl @[simp] theorem range_const (α) [MeasurableSpace α] [Nonempty α] (b : β) : (const α b).range = {b} := Finset.coe_injective <\| by simp +unfoldPartialApp [Function.const] theorem range_const_subset (α) [MeasurableSpace α] (b : β) : (const α b).range ⊆ {b} := Finset.coe_subset.1 <\| by simp theorem simpleFunc_bot {α} (f : @SimpleFunc α ⊥ β) [Nonempty β] : ∃ c, ∀ x, f x = c := by have hf_meas := @SimpleFunc.measurableSet_fiber α _ ⊥ f simp_rw [MeasurableSpace.measurableSet_bot_iff] at hf_meas exact (exists_eq_const_of_preimage_singleton hf_meas).imp fun c hc ↦ congr_fun hc theorem simpleFunc_bot' {α} [Nonempty β] (f : @SimpleFunc α ⊥ β) : ∃ c, f = @SimpleFunc.const α _ ⊥ c := letI : MeasurableSpace α := ⊥; (simpleFunc_bot f).imp fun _ ↦ ext theorem measurableSet_cut (r : α → β → Prop) (f : α →ₛ β) (h : ∀ b, MeasurableSet { a \| r a b }) : MeasurableSet { a \| r a (f a) } := by have : { a \| r a (f a) } = ⋃ b ∈ range f, { a \| r a b } ∩ f ⁻¹' {b} := by ext a suffices r a (f a) ↔ ∃ i, r a (f i) ∧ f a = f i by simpa exact ⟨fun h => ⟨a, ⟨h, rfl⟩⟩, fun ⟨a', ⟨h', e⟩⟩ => e.symm ▸ h'⟩ rw [this] exact MeasurableSet.biUnion f.finite_range.countable fun b _ => MeasurableSet.inter (h b) (f.measurableSet_fiber _) @[measurability] theorem measurableSet_preimage (f : α →ₛ β) (s) : MeasurableSet (f ⁻¹' s) := measurableSet_cut (fun _ b => b ∈ s) f fun b => MeasurableSet.const (b ∈ s) /-- A simple function is measurable -/ @[measurability, fun_prop] protected theorem measurable [MeasurableSpace β] (f : α →ₛ β) : Measurable f := fun s _ => measurableSet_preimage f s @[measurability] protected theorem aemeasurable [MeasurableSpace β] {μ : Measure α} (f : α →ₛ β) : AEMeasurable f μ := f.measurable.aemeasurable protected theorem sum_measure_preimage_singleton (f : α →ₛ β) {μ : Measure α} (s : Finset β) : (∑ y ∈ s, μ (f ⁻¹' {y})) = μ (f ⁻¹' ↑s) := sum_measure_preimage_singleton _ fun _ _ => f.measurableSet_fiber _ theorem sum_range_measure_preimage_singleton (f : α →ₛ β) (μ : Measure α) : (∑ y ∈ f.range, μ (f ⁻¹' {y})) = μ univ := by rw [f.sum_measure_preimage_singleton, coe_range, preimage_range] open scoped Classical in /-- If-then-else as a `SimpleFunc`. -/ def piecewise (s : Set α) (hs : MeasurableSet s) (f g : α →ₛ β) : α →ₛ β := ⟨s.piecewise f g, fun _ => letI : MeasurableSpace β := ⊤ f.measurable.piecewise hs g.measurable trivial, (f.finite_range.union g.finite_range).subset range_ite_subset⟩ open scoped Classical in @[simp] theorem coe_piecewise {s : Set α} (hs : MeasurableSet s) (f g : α →ₛ β) : ⇑(piecewise s hs f g) = s.piecewise f g := rfl open scoped Classical in theorem piecewise_apply {s : Set α} (hs : MeasurableSet s) (f g : α →ₛ β) (a) : piecewise s hs f g a = if a ∈ s then f a else g a := rfl open scoped Classical in @[simp] theorem piecewise_compl {s : Set α} (hs : MeasurableSet sᶜ) (f g : α →ₛ β) : piecewise sᶜ hs f g = piecewise s hs.of_compl g f := coe_injective <\| by simp [hs] @[simp] theorem piecewise_univ (f g : α →ₛ β) : piecewise univ MeasurableSet.univ f g = f := coe_injective <\| by simp @[simp] theorem piecewise_empty (f g : α →ₛ β) : piecewise ∅ MeasurableSet.empty f g = g := coe_injective <\| by simp open scoped Classical in @[simp] theorem piecewise_same (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) : piecewise s hs f f = f := coe_injective <\| Set.piecewise_same _ _ theorem support_indicator [Zero β] {s : Set α} (hs : MeasurableSet s) (f : α →ₛ β) : Function.support (f.piecewise s hs (SimpleFunc.const α 0)) = s ∩ Function.support f := Set.support_indicator open scoped Classical in theorem range_indicator {s : Set α} (hs : MeasurableSet s) (hs_nonempty : s.Nonempty) (hs_ne_univ : s ≠ univ) (x y : β) : (piecewise s hs (const α x) (const α y)).range = {x, y} := by simp only [← Finset.coe_inj, coe_range, coe_piecewise, range_piecewise, coe_const, Finset.coe_insert, Finset.coe_singleton, hs_nonempty.image_const, (nonempty_compl.2 hs_ne_univ).image_const, singleton_union, Function.const] theorem measurable_bind [MeasurableSpace γ] (f : α →ₛ β) (g : β → α → γ) (hg : ∀ b, Measurable (g b)) : Measurable fun a => g (f a) a := fun s hs => f.measurableSet_cut (fun a b => g b a ∈ s) fun b => hg b hs /-- If `f : α →ₛ β` is a simple function and `g : β → α →ₛ γ` is a family of simple functions, then `f.bind g` binds the first argument of `g` to `f`. In other words, `f.bind g a = g (f a) a`. -/ def bind (f : α →ₛ β) (g : β → α →ₛ γ) : α →ₛ γ :=	⟨fun a => g (f a) a, fun c => f.measurableSet_cut (fun a b => g b a = c) fun b => (g b).measurableSet_preimage {c}, (f.finite_range.biUnion fun b _ => (g b).finite_range).subset <\| by rintro _ ⟨a, rfl⟩; simp⟩	Mathlib/MeasureTheory/Function/SimpleFunc.lean	239	243
/- Copyright (c) 2021 Frédéric Dupuis. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Frédéric Dupuis, Heather Macbeth -/ import Mathlib.Analysis.InnerProductSpace.Dual import Mathlib.Analysis.InnerProductSpace.PiL2 /-! # Adjoint of operators on Hilbert spaces Given an operator `A : E →L[𝕜] F`, where `E` and `F` are Hilbert spaces, its adjoint `adjoint A : F →L[𝕜] E` is the unique operator such that `⟪x, A y⟫ = ⟪adjoint A x, y⟫` for all `x` and `y`. We then use this to put a C⋆-algebra structure on `E →L[𝕜] E` with the adjoint as the star operation. This construction is used to define an adjoint for linear maps (i.e. not continuous) between finite dimensional spaces. ## Main definitions * `ContinuousLinearMap.adjoint : (E →L[𝕜] F) ≃ₗᵢ⋆[𝕜] (F →L[𝕜] E)`: the adjoint of a continuous linear map, bundled as a conjugate-linear isometric equivalence. * `LinearMap.adjoint : (E →ₗ[𝕜] F) ≃ₗ⋆[𝕜] (F →ₗ[𝕜] E)`: the adjoint of a linear map between finite-dimensional spaces, this time only as a conjugate-linear equivalence, since there is no norm defined on these maps. ## Implementation notes * The continuous conjugate-linear version `adjointAux` is only an intermediate definition and is not meant to be used outside this file. ## Tags adjoint -/ noncomputable section open RCLike open scoped ComplexConjugate variable {𝕜 E F G : Type} [RCLike 𝕜] variable [NormedAddCommGroup E] [NormedAddCommGroup F] [NormedAddCommGroup G] variable [InnerProductSpace 𝕜 E] [InnerProductSpace 𝕜 F] [InnerProductSpace 𝕜 G] local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y /-! ### Adjoint operator -/ open InnerProductSpace namespace ContinuousLinearMap variable [CompleteSpace E] [CompleteSpace G] -- Note: made noncomputable to stop excess compilation -- https://github.com/leanprover-community/mathlib4/issues/7103 /-- The adjoint, as a continuous conjugate-linear map. This is only meant as an auxiliary definition for the main definition `adjoint`, where this is bundled as a conjugate-linear isometric equivalence. -/ noncomputable def adjointAux : (E →L[𝕜] F) →L⋆[𝕜] F →L[𝕜] E := (ContinuousLinearMap.compSL _ _ _ _ _ ((toDual 𝕜 E).symm : NormedSpace.Dual 𝕜 E →L⋆[𝕜] E)).comp (toSesqForm : (E →L[𝕜] F) →L[𝕜] F →L⋆[𝕜] NormedSpace.Dual 𝕜 E) @[simp] theorem adjointAux_apply (A : E →L[𝕜] F) (x : F) : adjointAux A x = ((toDual 𝕜 E).symm : NormedSpace.Dual 𝕜 E → E) ((toSesqForm A) x) := rfl theorem adjointAux_inner_left (A : E →L[𝕜] F) (x : E) (y : F) : ⟪adjointAux A y, x⟫ = ⟪y, A x⟫ := by rw [adjointAux_apply, toDual_symm_apply, toSesqForm_apply_coe, coe_comp', innerSL_apply_coe, Function.comp_apply] theorem adjointAux_inner_right (A : E →L[𝕜] F) (x : E) (y : F) : ⟪x, adjointAux A y⟫ = ⟪A x, y⟫ := by rw [← inner_conj_symm, adjointAux_inner_left, inner_conj_symm] variable [CompleteSpace F] theorem adjointAux_adjointAux (A : E →L[𝕜] F) : adjointAux (adjointAux A) = A := by ext v refine ext_inner_left 𝕜 fun w => ?_ rw [adjointAux_inner_right, adjointAux_inner_left] @[simp] theorem adjointAux_norm (A : E →L[𝕜] F) : ‖adjointAux A‖ = ‖A‖ := by refine le_antisymm ?_ ?_ · refine ContinuousLinearMap.opNorm_le_bound _ (norm_nonneg _) fun x => ?_ rw [adjointAux_apply, LinearIsometryEquiv.norm_map] exact toSesqForm_apply_norm_le · nth_rw 1 [← adjointAux_adjointAux A] refine ContinuousLinearMap.opNorm_le_bound _ (norm_nonneg _) fun x => ?_ rw [adjointAux_apply, LinearIsometryEquiv.norm_map] exact toSesqForm_apply_norm_le /-- The adjoint of a bounded operator `A` from a Hilbert space `E` to another Hilbert space `F`, denoted as `A†`. -/ def adjoint : (E →L[𝕜] F) ≃ₗᵢ⋆[𝕜] F →L[𝕜] E := LinearIsometryEquiv.ofSurjective { adjointAux with norm_map' := adjointAux_norm } fun A => ⟨adjointAux A, adjointAux_adjointAux A⟩ @[inherit_doc] scoped[InnerProduct] postfix:1000 "†" => ContinuousLinearMap.adjoint open InnerProduct /-- The fundamental property of the adjoint. -/ theorem adjoint_inner_left (A : E →L[𝕜] F) (x : E) (y : F) : ⟪(A†) y, x⟫ = ⟪y, A x⟫ := adjointAux_inner_left A x y /-- The fundamental property of the adjoint. -/ theorem adjoint_inner_right (A : E →L[𝕜] F) (x : E) (y : F) : ⟪x, (A†) y⟫ = ⟪A x, y⟫ := adjointAux_inner_right A x y /-- The adjoint is involutive. -/ @[simp] theorem adjoint_adjoint (A : E →L[𝕜] F) : A†† = A := adjointAux_adjointAux A /-- The adjoint of the composition of two operators is the composition of the two adjoints in reverse order. -/ @[simp] theorem adjoint_comp (A : F →L[𝕜] G) (B : E →L[𝕜] F) : (A ∘L B)† = B† ∘L A† := by ext v refine ext_inner_left 𝕜 fun w => ?_ simp only [adjoint_inner_right, ContinuousLinearMap.coe_comp', Function.comp_apply] theorem apply_norm_sq_eq_inner_adjoint_left (A : E →L[𝕜] F) (x : E) : ‖A x‖ ^ 2 = re ⟪(A† ∘L A) x, x⟫ := by have h : ⟪(A† ∘L A) x, x⟫ = ⟪A x, A x⟫ := by rw [← adjoint_inner_left]; rfl rw [h, ← inner_self_eq_norm_sq (𝕜 := 𝕜) _] theorem apply_norm_eq_sqrt_inner_adjoint_left (A : E →L[𝕜] F) (x : E) : ‖A x‖ = √(re ⟪(A† ∘L A) x, x⟫) := by rw [← apply_norm_sq_eq_inner_adjoint_left, Real.sqrt_sq (norm_nonneg _)] theorem apply_norm_sq_eq_inner_adjoint_right (A : E →L[𝕜] F) (x : E) : ‖A x‖ ^ 2 = re ⟪x, (A† ∘L A) x⟫ := by have h : ⟪x, (A† ∘L A) x⟫ = ⟪A x, A x⟫ := by rw [← adjoint_inner_right]; rfl rw [h, ← inner_self_eq_norm_sq (𝕜 := 𝕜) _] theorem apply_norm_eq_sqrt_inner_adjoint_right (A : E →L[𝕜] F) (x : E) : ‖A x‖ = √(re ⟪x, (A† ∘L A) x⟫) := by rw [← apply_norm_sq_eq_inner_adjoint_right, Real.sqrt_sq (norm_nonneg _)] /-- The adjoint is unique: a map `A` is the adjoint of `B` iff it satisfies `⟪A x, y⟫ = ⟪x, B y⟫` for all `x` and `y`. -/ theorem eq_adjoint_iff (A : E →L[𝕜] F) (B : F →L[𝕜] E) : A = B† ↔ ∀ x y, ⟪A x, y⟫ = ⟪x, B y⟫ := by refine ⟨fun h x y => by rw [h, adjoint_inner_left], fun h => ?_⟩ ext x exact ext_inner_right 𝕜 fun y => by simp only [adjoint_inner_left, h x y] @[simp] theorem adjoint_id : ContinuousLinearMap.adjoint (ContinuousLinearMap.id 𝕜 E) = ContinuousLinearMap.id 𝕜 E := by refine Eq.symm ?_ rw [eq_adjoint_iff] simp theorem _root_.Submodule.adjoint_subtypeL (U : Submodule 𝕜 E) [CompleteSpace U] : U.subtypeL† = U.orthogonalProjection := by symm rw [eq_adjoint_iff] intro x u rw [U.coe_inner, U.inner_orthogonalProjection_left_eq_right, U.orthogonalProjection_mem_subspace_eq_self] rfl theorem _root_.Submodule.adjoint_orthogonalProjection (U : Submodule 𝕜 E) [CompleteSpace U] : (U.orthogonalProjection : E →L[𝕜] U)† = U.subtypeL := by rw [← U.adjoint_subtypeL, adjoint_adjoint] /-- `E →L[𝕜] E` is a star algebra with the adjoint as the star operation. -/ instance : Star (E →L[𝕜] E) := ⟨adjoint⟩ instance : InvolutiveStar (E →L[𝕜] E) := ⟨adjoint_adjoint⟩ instance : StarMul (E →L[𝕜] E) := ⟨adjoint_comp⟩ instance : StarRing (E →L[𝕜] E) := ⟨LinearIsometryEquiv.map_add adjoint⟩ instance : StarModule 𝕜 (E →L[𝕜] E) := ⟨LinearIsometryEquiv.map_smulₛₗ adjoint⟩ theorem star_eq_adjoint (A : E →L[𝕜] E) : star A = A† := rfl /-- A continuous linear operator is self-adjoint iff it is equal to its adjoint. -/ theorem isSelfAdjoint_iff' {A : E →L[𝕜] E} : IsSelfAdjoint A ↔ ContinuousLinearMap.adjoint A = A := Iff.rfl theorem norm_adjoint_comp_self (A : E →L[𝕜] F) : ‖ContinuousLinearMap.adjoint A ∘L A‖ = ‖A‖ ‖A‖ := by refine le_antisymm ?_ ?_ · calc ‖A† ∘L A‖ ≤ ‖A†‖ * ‖A‖ := opNorm_comp_le _ _ _ = ‖A‖ * ‖A‖ := by rw [LinearIsometryEquiv.norm_map] · rw [← sq, ← Real.sqrt_le_sqrt_iff (norm_nonneg _), Real.sqrt_sq (norm_nonneg _)] refine opNorm_le_bound _ (Real.sqrt_nonneg _) fun x => ?_ have := calc re ⟪(A† ∘L A) x, x⟫ ≤ ‖(A† ∘L A) x‖ * ‖x‖ := re_inner_le_norm _ _ _ ≤ ‖A† ∘L A‖ * ‖x‖ * ‖x‖ := mul_le_mul_of_nonneg_right (le_opNorm _ _) (norm_nonneg _) calc ‖A x‖ = √(re ⟪(A† ∘L A) x, x⟫) := by rw [apply_norm_eq_sqrt_inner_adjoint_left] _ ≤ √(‖A† ∘L A‖ * ‖x‖ * ‖x‖) := Real.sqrt_le_sqrt this _ = √‖A† ∘L A‖ * ‖x‖ := by simp_rw [mul_assoc, Real.sqrt_mul (norm_nonneg _) (‖x‖ * ‖x‖), Real.sqrt_mul_self (norm_nonneg x)] /-- The C⋆-algebra instance when `𝕜 := ℂ` can be found in `Analysis.CStarAlgebra.ContinuousLinearMap`. -/ instance : CStarRing (E →L[𝕜] E) where norm_mul_self_le x := le_of_eq <\| Eq.symm <\| norm_adjoint_comp_self x theorem isAdjointPair_inner (A : E →L[𝕜] F) : LinearMap.IsAdjointPair (sesqFormOfInner : E →ₗ[𝕜] E →ₗ⋆[𝕜] 𝕜) (sesqFormOfInner : F →ₗ[𝕜] F →ₗ⋆[𝕜] 𝕜) A (A†) := by intro x y simp only [sesqFormOfInner_apply_apply, adjoint_inner_left, coe_coe] end ContinuousLinearMap /-! ### Self-adjoint operators -/ namespace IsSelfAdjoint open ContinuousLinearMap variable [CompleteSpace E] [CompleteSpace F] theorem adjoint_eq {A : E →L[𝕜] E} (hA : IsSelfAdjoint A) : ContinuousLinearMap.adjoint A = A := hA /-- Every self-adjoint operator on an inner product space is symmetric. -/ theorem isSymmetric {A : E →L[𝕜] E} (hA : IsSelfAdjoint A) : (A : E →ₗ[𝕜] E).IsSymmetric := by intro x y rw_mod_cast [← A.adjoint_inner_right, hA.adjoint_eq] /-- Conjugating preserves self-adjointness. -/ theorem conj_adjoint {T : E →L[𝕜] E} (hT : IsSelfAdjoint T) (S : E →L[𝕜] F) : IsSelfAdjoint (S ∘L T ∘L ContinuousLinearMap.adjoint S) := by rw [isSelfAdjoint_iff'] at hT ⊢ simp only [hT, adjoint_comp, adjoint_adjoint] exact ContinuousLinearMap.comp_assoc _ _ _ /-- Conjugating preserves self-adjointness. -/ theorem adjoint_conj {T : E →L[𝕜] E} (hT : IsSelfAdjoint T) (S : F →L[𝕜] E) : IsSelfAdjoint (ContinuousLinearMap.adjoint S ∘L T ∘L S) := by rw [isSelfAdjoint_iff'] at hT ⊢ simp only [hT, adjoint_comp, adjoint_adjoint] exact ContinuousLinearMap.comp_assoc _ _ _ theorem _root_.ContinuousLinearMap.isSelfAdjoint_iff_isSymmetric {A : E →L[𝕜] E} : IsSelfAdjoint A ↔ (A : E →ₗ[𝕜] E).IsSymmetric := ⟨fun hA => hA.isSymmetric, fun hA => ext fun x => ext_inner_right 𝕜 fun y => (A.adjoint_inner_left y x).symm ▸ (hA x y).symm⟩ theorem _root_.LinearMap.IsSymmetric.isSelfAdjoint {A : E →L[𝕜] E} (hA : (A : E →ₗ[𝕜] E).IsSymmetric) : IsSelfAdjoint A := by rwa [← ContinuousLinearMap.isSelfAdjoint_iff_isSymmetric] at hA /-- The orthogonal projection is self-adjoint. -/ theorem _root_.orthogonalProjection_isSelfAdjoint (U : Submodule 𝕜 E) [CompleteSpace U] : IsSelfAdjoint (U.subtypeL ∘L U.orthogonalProjection) := U.orthogonalProjection_isSymmetric.isSelfAdjoint theorem conj_orthogonalProjection {T : E →L[𝕜] E} (hT : IsSelfAdjoint T) (U : Submodule 𝕜 E) [CompleteSpace U] : IsSelfAdjoint (U.subtypeL ∘L U.orthogonalProjection ∘L T ∘L U.subtypeL ∘L U.orthogonalProjection) := by rw [← ContinuousLinearMap.comp_assoc] nth_rw 1 [← (orthogonalProjection_isSelfAdjoint U).adjoint_eq] exact hT.adjoint_conj _ end IsSelfAdjoint namespace LinearMap variable [CompleteSpace E] variable {T : E →ₗ[𝕜] E} /-- The Hellinger--Toeplitz theorem: Construct a self-adjoint operator from an everywhere defined symmetric operator. -/ def IsSymmetric.toSelfAdjoint (hT : IsSymmetric T) : selfAdjoint (E →L[𝕜] E) := ⟨⟨T, hT.continuous⟩, ContinuousLinearMap.isSelfAdjoint_iff_isSymmetric.mpr hT⟩ theorem IsSymmetric.coe_toSelfAdjoint (hT : IsSymmetric T) : (hT.toSelfAdjoint : E →ₗ[𝕜] E) = T := rfl theorem IsSymmetric.toSelfAdjoint_apply (hT : IsSymmetric T) {x : E} : (hT.toSelfAdjoint : E → E) x = T x := rfl end LinearMap namespace LinearMap variable [FiniteDimensional 𝕜 E] [FiniteDimensional 𝕜 F] [FiniteDimensional 𝕜 G] /- Porting note: Lean can't use `FiniteDimensional.complete` since it was generalized to topological vector spaces. Use local instances instead. -/ /-- The adjoint of an operator from the finite-dimensional inner product space `E` to the finite-dimensional inner product space `F`. -/ def adjoint : (E →ₗ[𝕜] F) ≃ₗ⋆[𝕜] F →ₗ[𝕜] E := have := FiniteDimensional.complete 𝕜 E have := FiniteDimensional.complete 𝕜 F /- Note: Instead of the two instances above, the following works: ``` have := FiniteDimensional.complete 𝕜 have := FiniteDimensional.complete 𝕜 ``` But removing one of the `have`s makes it fail. The reason is that `E` and `F` don't live in the same universe, so the first `have` can no longer be used for `F` after its universe metavariable has been assigned to that of `E`! -/ ((LinearMap.toContinuousLinearMap : (E →ₗ[𝕜] F) ≃ₗ[𝕜] E →L[𝕜] F).trans ContinuousLinearMap.adjoint.toLinearEquiv).trans LinearMap.toContinuousLinearMap.symm theorem adjoint_toContinuousLinearMap (A : E →ₗ[𝕜] F) : haveI := FiniteDimensional.complete 𝕜 E haveI := FiniteDimensional.complete 𝕜 F LinearMap.toContinuousLinearMap (LinearMap.adjoint A) = ContinuousLinearMap.adjoint (LinearMap.toContinuousLinearMap A) := rfl theorem adjoint_eq_toCLM_adjoint (A : E →ₗ[𝕜] F) : haveI := FiniteDimensional.complete 𝕜 E haveI := FiniteDimensional.complete 𝕜 F LinearMap.adjoint A = ContinuousLinearMap.adjoint (LinearMap.toContinuousLinearMap A) := rfl /-- The fundamental property of the adjoint. -/ theorem adjoint_inner_left (A : E →ₗ[𝕜] F) (x : E) (y : F) : ⟪adjoint A y, x⟫ = ⟪y, A x⟫ := by haveI := FiniteDimensional.complete 𝕜 E haveI := FiniteDimensional.complete 𝕜 F rw [← coe_toContinuousLinearMap A, adjoint_eq_toCLM_adjoint] exact ContinuousLinearMap.adjoint_inner_left _ x y /-- The fundamental property of the adjoint. -/ theorem adjoint_inner_right (A : E →ₗ[𝕜] F) (x : E) (y : F) : ⟪x, adjoint A y⟫ = ⟪A x, y⟫ := by haveI := FiniteDimensional.complete 𝕜 E haveI := FiniteDimensional.complete 𝕜 F rw [← coe_toContinuousLinearMap A, adjoint_eq_toCLM_adjoint] exact ContinuousLinearMap.adjoint_inner_right _ x y /-- The adjoint is involutive. -/ @[simp] theorem adjoint_adjoint (A : E →ₗ[𝕜] F) : LinearMap.adjoint (LinearMap.adjoint A) = A := by ext v refine ext_inner_left 𝕜 fun w => ?_ rw [adjoint_inner_right, adjoint_inner_left] /-- The adjoint of the composition of two operators is the composition of the two adjoints in reverse order. -/ @[simp] theorem adjoint_comp (A : F →ₗ[𝕜] G) (B : E →ₗ[𝕜] F) : LinearMap.adjoint (A ∘ₗ B) = LinearMap.adjoint B ∘ₗ LinearMap.adjoint A := by ext v refine ext_inner_left 𝕜 fun w => ?_ simp only [adjoint_inner_right, LinearMap.coe_comp, Function.comp_apply] /-- The adjoint is unique: a map `A` is the adjoint of `B` iff it satisfies `⟪A x, y⟫ = ⟪x, B y⟫` for all `x` and `y`. -/ theorem eq_adjoint_iff (A : E →ₗ[𝕜] F) (B : F →ₗ[𝕜] E) : A = LinearMap.adjoint B ↔ ∀ x y, ⟪A x, y⟫ = ⟪x, B y⟫ := by refine ⟨fun h x y => by rw [h, adjoint_inner_left], fun h => ?_⟩ ext x exact ext_inner_right 𝕜 fun y => by simp only [adjoint_inner_left, h x y] /-- The adjoint is unique: a map `A` is the adjoint of `B` iff it satisfies `⟪A x, y⟫ = ⟪x, B y⟫` for all basis vectors `x` and `y`. -/ theorem eq_adjoint_iff_basis {ι₁ : Type} {ι₂ : Type} (b₁ : Basis ι₁ 𝕜 E) (b₂ : Basis ι₂ 𝕜 F) (A : E →ₗ[𝕜] F) (B : F →ₗ[𝕜] E) : A = LinearMap.adjoint B ↔ ∀ (i₁ : ι₁) (i₂ : ι₂), ⟪A (b₁ i₁), b₂ i₂⟫ = ⟪b₁ i₁, B (b₂ i₂)⟫ := by refine ⟨fun h x y => by rw [h, adjoint_inner_left], fun h => ?_⟩	refine Basis.ext b₁ fun i₁ => ?_ exact ext_inner_right_basis b₂ fun i₂ => by simp only [adjoint_inner_left, h i₁ i₂] theorem eq_adjoint_iff_basis_left {ι : Type*} (b : Basis ι 𝕜 E) (A : E →ₗ[𝕜] F) (B : F →ₗ[𝕜] E) : A = LinearMap.adjoint B ↔ ∀ i y, ⟪A (b i), y⟫ = ⟪b i, B y⟫ := by	Mathlib/Analysis/InnerProductSpace/Adjoint.lean	389	393
/- Copyright (c) 2022 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn -/ import Mathlib.Analysis.Calculus.ContDiff.Basic import Mathlib.Analysis.Calculus.ParametricIntegral import Mathlib.MeasureTheory.Integral.Prod import Mathlib.MeasureTheory.Function.LocallyIntegrable import Mathlib.MeasureTheory.Group.Integral import Mathlib.MeasureTheory.Group.Prod import Mathlib.MeasureTheory.Integral.IntervalIntegral.Basic /-! # Convolution of functions This file defines the convolution on two functions, i.e. `x ↦ ∫ f(t)g(x - t) ∂t`. In the general case, these functions can be vector-valued, and have an arbitrary (additive) group as domain. We use a continuous bilinear operation `L` on these function values as "multiplication". The domain must be equipped with a Haar measure `μ` (though many individual results have weaker conditions on `μ`). For many applications we can take `L = ContinuousLinearMap.lsmul ℝ ℝ` or `L = ContinuousLinearMap.mul ℝ ℝ`. We also define `ConvolutionExists` and `ConvolutionExistsAt` to state that the convolution is well-defined (everywhere or at a single point). These conditions are needed for pointwise computations (e.g. `ConvolutionExistsAt.distrib_add`), but are generally not strong enough for any local (or global) properties of the convolution. For this we need stronger assumptions on `f` and/or `g`, and generally if we impose stronger conditions on one of the functions, we can impose weaker conditions on the other. We have proven many of the properties of the convolution assuming one of these functions has compact support (in which case the other function only needs to be locally integrable). We still need to prove the properties for other pairs of conditions (e.g. both functions are rapidly decreasing) # Design Decisions We use a bilinear map `L` to "multiply" the two functions in the integrand. This generality has several advantages * This allows us to compute the total derivative of the convolution, in case the functions are multivariate. The total derivative is again a convolution, but where the codomains of the functions can be higher-dimensional. See `HasCompactSupport.hasFDerivAt_convolution_right`. * This allows us to use `@[to_additive]` everywhere (which would not be possible if we would use `mul`/`smul` in the integral, since `@[to_additive]` will incorrectly also try to additivize those definitions). * We need to support the case where at least one of the functions is vector-valued, but if we use `smul` to multiply the functions, that would be an asymmetric definition. # Main Definitions * `MeasureTheory.convolution f g L μ x = (f ⋆[L, μ] g) x = ∫ t, L (f t) (g (x - t)) ∂μ` is the convolution of `f` and `g` w.r.t. the continuous bilinear map `L` and measure `μ`. * `MeasureTheory.ConvolutionExistsAt f g x L μ` states that the convolution `(f ⋆[L, μ] g) x` is well-defined (i.e. the integral exists). * `MeasureTheory.ConvolutionExists f g L μ` states that the convolution `f ⋆[L, μ] g` is well-defined at each point. # Main Results * `HasCompactSupport.hasFDerivAt_convolution_right` and `HasCompactSupport.hasFDerivAt_convolution_left`: we can compute the total derivative of the convolution as a convolution with the total derivative of the right (left) function. * `HasCompactSupport.contDiff_convolution_right` and `HasCompactSupport.contDiff_convolution_left`: the convolution is `𝒞ⁿ` if one of the functions is `𝒞ⁿ` with compact support and the other function in locally integrable. Versions of these statements for functions depending on a parameter are also given. * `MeasureTheory.convolution_tendsto_right`: Given a sequence of nonnegative normalized functions whose support tends to a small neighborhood around `0`, the convolution tends to the right argument. This is specialized to bump functions in `ContDiffBump.convolution_tendsto_right`. # Notation The following notations are localized in the locale `Convolution`: * `f ⋆[L, μ] g` for the convolution. Note: you have to use parentheses to apply the convolution to an argument: `(f ⋆[L, μ] g) x`. * `f ⋆[L] g := f ⋆[L, volume] g` * `f ⋆ g := f ⋆[lsmul ℝ ℝ] g` # To do * Existence and (uniform) continuity of the convolution if one of the maps is in `ℒ^p` and the other in `ℒ^q` with `1 / p + 1 / q = 1`. This might require a generalization of `MeasureTheory.MemLp.smul` where `smul` is generalized to a continuous bilinear map. (see e.g. [Fremlin, Measure Theory (volume 2)][fremlin_vol2], 255K) * The convolution is an `AEStronglyMeasurable` function (see e.g. [Fremlin, Measure Theory (volume 2)][fremlin_vol2], 255I). * Prove properties about the convolution if both functions are rapidly decreasing. * Use `@[to_additive]` everywhere (this likely requires changes in `to_additive`) -/ open Set Function Filter MeasureTheory MeasureTheory.Measure TopologicalSpace open Bornology ContinuousLinearMap Metric Topology open scoped Pointwise NNReal Filter universe u𝕜 uG uE uE' uE'' uF uF' uF'' uP variable {𝕜 : Type u𝕜} {G : Type uG} {E : Type uE} {E' : Type uE'} {E'' : Type uE''} {F : Type uF} {F' : Type uF'} {F'' : Type uF''} {P : Type uP} variable [NormedAddCommGroup E] [NormedAddCommGroup E'] [NormedAddCommGroup E''] [NormedAddCommGroup F] {f f' : G → E} {g g' : G → E'} {x x' : G} {y y' : E} namespace MeasureTheory section NontriviallyNormedField variable [NontriviallyNormedField 𝕜] variable [NormedSpace 𝕜 E] [NormedSpace 𝕜 E'] [NormedSpace 𝕜 E''] [NormedSpace 𝕜 F] variable (L : E →L[𝕜] E' →L[𝕜] F) section NoMeasurability variable [AddGroup G] [TopologicalSpace G] theorem convolution_integrand_bound_right_of_le_of_subset {C : ℝ} (hC : ∀ i, ‖g i‖ ≤ C) {x t : G} {s u : Set G} (hx : x ∈ s) (hu : -tsupport g + s ⊆ u) : ‖L (f t) (g (x - t))‖ ≤ u.indicator (fun t => ‖L‖ * ‖f t‖ * C) t := by -- Porting note: had to add `f := _` refine le_indicator (f := fun t ↦ ‖L (f t) (g (x - t))‖) (fun t _ => ?_) (fun t ht => ?_) t · apply_rules [L.le_of_opNorm₂_le_of_le, le_rfl] · have : x - t ∉ support g := by refine mt (fun hxt => hu ?_) ht refine ⟨_, Set.neg_mem_neg.mpr (subset_closure hxt), _, hx, ?_⟩ simp only [neg_sub, sub_add_cancel] simp only [nmem_support.mp this, (L _).map_zero, norm_zero, le_rfl] theorem _root_.HasCompactSupport.convolution_integrand_bound_right_of_subset (hcg : HasCompactSupport g) (hg : Continuous g) {x t : G} {s u : Set G} (hx : x ∈ s) (hu : -tsupport g + s ⊆ u) : ‖L (f t) (g (x - t))‖ ≤ u.indicator (fun t => ‖L‖ * ‖f t‖ * ⨆ i, ‖g i‖) t := by refine convolution_integrand_bound_right_of_le_of_subset _ (fun i => ?_) hx hu exact le_ciSup (hg.norm.bddAbove_range_of_hasCompactSupport hcg.norm) _ theorem _root_.HasCompactSupport.convolution_integrand_bound_right (hcg : HasCompactSupport g) (hg : Continuous g) {x t : G} {s : Set G} (hx : x ∈ s) : ‖L (f t) (g (x - t))‖ ≤ (-tsupport g + s).indicator (fun t => ‖L‖ * ‖f t‖ * ⨆ i, ‖g i‖) t := hcg.convolution_integrand_bound_right_of_subset L hg hx Subset.rfl theorem _root_.Continuous.convolution_integrand_fst [ContinuousSub G] (hg : Continuous g) (t : G) : Continuous fun x => L (f t) (g (x - t)) := L.continuous₂.comp₂ continuous_const <\| hg.comp <\| continuous_id.sub continuous_const theorem _root_.HasCompactSupport.convolution_integrand_bound_left (hcf : HasCompactSupport f) (hf : Continuous f) {x t : G} {s : Set G} (hx : x ∈ s) : ‖L (f (x - t)) (g t)‖ ≤ (-tsupport f + s).indicator (fun t => (‖L‖ * ⨆ i, ‖f i‖) * ‖g t‖) t := by convert hcf.convolution_integrand_bound_right L.flip hf hx using 1 simp_rw [L.opNorm_flip, mul_right_comm] end NoMeasurability section Measurability variable [MeasurableSpace G] {μ ν : Measure G} /-- The convolution of `f` and `g` exists at `x` when the function `t ↦ L (f t) (g (x - t))` is integrable. There are various conditions on `f` and `g` to prove this. -/ def ConvolutionExistsAt [Sub G] (f : G → E) (g : G → E') (x : G) (L : E →L[𝕜] E' →L[𝕜] F) (μ : Measure G := by volume_tac) : Prop := Integrable (fun t => L (f t) (g (x - t))) μ /-- The convolution of `f` and `g` exists when the function `t ↦ L (f t) (g (x - t))` is integrable for all `x : G`. There are various conditions on `f` and `g` to prove this. -/ def ConvolutionExists [Sub G] (f : G → E) (g : G → E') (L : E →L[𝕜] E' →L[𝕜] F) (μ : Measure G := by volume_tac) : Prop := ∀ x : G, ConvolutionExistsAt f g x L μ section ConvolutionExists variable {L} in theorem ConvolutionExistsAt.integrable [Sub G] {x : G} (h : ConvolutionExistsAt f g x L μ) : Integrable (fun t => L (f t) (g (x - t))) μ := h section Group variable [AddGroup G] theorem AEStronglyMeasurable.convolution_integrand' [MeasurableAdd₂ G] [MeasurableNeg G] (hf : AEStronglyMeasurable f ν) (hg : AEStronglyMeasurable g <\| map (fun p : G × G => p.1 - p.2) (μ.prod ν)) : AEStronglyMeasurable (fun p : G × G => L (f p.2) (g (p.1 - p.2))) (μ.prod ν) := L.aestronglyMeasurable_comp₂ hf.snd <\| hg.comp_measurable measurable_sub section variable [MeasurableAdd G] [MeasurableNeg G] theorem AEStronglyMeasurable.convolution_integrand_snd' (hf : AEStronglyMeasurable f μ) {x : G} (hg : AEStronglyMeasurable g <\| map (fun t => x - t) μ) : AEStronglyMeasurable (fun t => L (f t) (g (x - t))) μ := L.aestronglyMeasurable_comp₂ hf <\| hg.comp_measurable <\| measurable_id.const_sub x theorem AEStronglyMeasurable.convolution_integrand_swap_snd' {x : G} (hf : AEStronglyMeasurable f <\| map (fun t => x - t) μ) (hg : AEStronglyMeasurable g μ) : AEStronglyMeasurable (fun t => L (f (x - t)) (g t)) μ := L.aestronglyMeasurable_comp₂ (hf.comp_measurable <\| measurable_id.const_sub x) hg /-- A sufficient condition to prove that `f ⋆[L, μ] g` exists. We assume that `f` is integrable on a set `s` and `g` is bounded and ae strongly measurable on `x₀ - s` (note that both properties hold if `g` is continuous with compact support). -/ theorem _root_.BddAbove.convolutionExistsAt' {x₀ : G} {s : Set G} (hbg : BddAbove ((fun i => ‖g i‖) '' ((fun t => -t + x₀) ⁻¹' s))) (hs : MeasurableSet s) (h2s : (support fun t => L (f t) (g (x₀ - t))) ⊆ s) (hf : IntegrableOn f s μ) (hmg : AEStronglyMeasurable g <\| map (fun t => x₀ - t) (μ.restrict s)) : ConvolutionExistsAt f g x₀ L μ := by rw [ConvolutionExistsAt] rw [← integrableOn_iff_integrable_of_support_subset h2s] set s' := (fun t => -t + x₀) ⁻¹' s have : ∀ᵐ t : G ∂μ.restrict s, ‖L (f t) (g (x₀ - t))‖ ≤ s.indicator (fun t => ‖L‖ * ‖f t‖ * ⨆ i : s', ‖g i‖) t := by filter_upwards refine le_indicator (fun t ht => ?_) fun t ht => ?_ · apply_rules [L.le_of_opNorm₂_le_of_le, le_rfl] refine (le_ciSup_set hbg <\| mem_preimage.mpr ?_) rwa [neg_sub, sub_add_cancel] · have : t ∉ support fun t => L (f t) (g (x₀ - t)) := mt (fun h => h2s h) ht rw [nmem_support.mp this, norm_zero] refine Integrable.mono' ?_ ?_ this · rw [integrable_indicator_iff hs]; exact ((hf.norm.const_mul _).mul_const _).integrableOn · exact hf.aestronglyMeasurable.convolution_integrand_snd' L hmg /-- If `‖f‖ [μ] ‖g‖` exists, then `f [L, μ] g` exists. -/ theorem ConvolutionExistsAt.of_norm' {x₀ : G} (h : ConvolutionExistsAt (fun x => ‖f x‖) (fun x => ‖g x‖) x₀ (mul ℝ ℝ) μ) (hmf : AEStronglyMeasurable f μ) (hmg : AEStronglyMeasurable g <\| map (fun t => x₀ - t) μ) : ConvolutionExistsAt f g x₀ L μ := by refine (h.const_mul ‖L‖).mono' (hmf.convolution_integrand_snd' L hmg) (Eventually.of_forall fun x => ?_) rw [mul_apply', ← mul_assoc] apply L.le_opNorm₂ @[deprecated (since := "2025-02-07")] alias ConvolutionExistsAt.ofNorm' := ConvolutionExistsAt.of_norm' end section Left variable [MeasurableAdd₂ G] [MeasurableNeg G] [SFinite μ] [IsAddRightInvariant μ] theorem AEStronglyMeasurable.convolution_integrand_snd (hf : AEStronglyMeasurable f μ) (hg : AEStronglyMeasurable g μ) (x : G) : AEStronglyMeasurable (fun t => L (f t) (g (x - t))) μ := hf.convolution_integrand_snd' L <\| hg.mono_ac <\| (quasiMeasurePreserving_sub_left_of_right_invariant μ x).absolutelyContinuous theorem AEStronglyMeasurable.convolution_integrand_swap_snd (hf : AEStronglyMeasurable f μ) (hg : AEStronglyMeasurable g μ) (x : G) : AEStronglyMeasurable (fun t => L (f (x - t)) (g t)) μ := (hf.mono_ac (quasiMeasurePreserving_sub_left_of_right_invariant μ x).absolutelyContinuous).convolution_integrand_swap_snd' L hg /-- If `‖f‖ [μ] ‖g‖` exists, then `f [L, μ] g` exists. -/ theorem ConvolutionExistsAt.of_norm {x₀ : G} (h : ConvolutionExistsAt (fun x => ‖f x‖) (fun x => ‖g x‖) x₀ (mul ℝ ℝ) μ) (hmf : AEStronglyMeasurable f μ) (hmg : AEStronglyMeasurable g μ) : ConvolutionExistsAt f g x₀ L μ := h.of_norm' L hmf <\| hmg.mono_ac (quasiMeasurePreserving_sub_left_of_right_invariant μ x₀).absolutelyContinuous @[deprecated (since := "2025-02-07")] alias ConvolutionExistsAt.ofNorm := ConvolutionExistsAt.of_norm end Left section Right variable [MeasurableAdd₂ G] [MeasurableNeg G] [SFinite μ] [IsAddRightInvariant μ] [SFinite ν] theorem AEStronglyMeasurable.convolution_integrand (hf : AEStronglyMeasurable f ν) (hg : AEStronglyMeasurable g μ) : AEStronglyMeasurable (fun p : G × G => L (f p.2) (g (p.1 - p.2))) (μ.prod ν) := hf.convolution_integrand' L <\| hg.mono_ac (quasiMeasurePreserving_sub_of_right_invariant μ ν).absolutelyContinuous theorem Integrable.convolution_integrand (hf : Integrable f ν) (hg : Integrable g μ) : Integrable (fun p : G × G => L (f p.2) (g (p.1 - p.2))) (μ.prod ν) := by have h_meas : AEStronglyMeasurable (fun p : G × G => L (f p.2) (g (p.1 - p.2))) (μ.prod ν) := hf.aestronglyMeasurable.convolution_integrand L hg.aestronglyMeasurable have h2_meas : AEStronglyMeasurable (fun y : G => ∫ x : G, ‖L (f y) (g (x - y))‖ ∂μ) ν := h_meas.prod_swap.norm.integral_prod_right' simp_rw [integrable_prod_iff' h_meas] refine ⟨Eventually.of_forall fun t => (L (f t)).integrable_comp (hg.comp_sub_right t), ?_⟩ refine Integrable.mono' ?_ h2_meas (Eventually.of_forall fun t => (?_ : _ ≤ ‖L‖ * ‖f t‖ * ∫ x, ‖g (x - t)‖ ∂μ)) · simp only [integral_sub_right_eq_self (‖g ·‖)] exact (hf.norm.const_mul _).mul_const _ · simp_rw [← integral_const_mul] rw [Real.norm_of_nonneg (by positivity)] exact integral_mono_of_nonneg (Eventually.of_forall fun t => norm_nonneg _) ((hg.comp_sub_right t).norm.const_mul _) (Eventually.of_forall fun t => L.le_opNorm₂ _ _) theorem Integrable.ae_convolution_exists (hf : Integrable f ν) (hg : Integrable g μ) : ∀ᵐ x ∂μ, ConvolutionExistsAt f g x L ν := ((integrable_prod_iff <\| hf.aestronglyMeasurable.convolution_integrand L hg.aestronglyMeasurable).mp <\| hf.convolution_integrand L hg).1 end Right variable [TopologicalSpace G] [IsTopologicalAddGroup G] [BorelSpace G] theorem _root_.HasCompactSupport.convolutionExistsAt {x₀ : G} (h : HasCompactSupport fun t => L (f t) (g (x₀ - t))) (hf : LocallyIntegrable f μ) (hg : Continuous g) : ConvolutionExistsAt f g x₀ L μ := by let u := (Homeomorph.neg G).trans (Homeomorph.addRight x₀) let v := (Homeomorph.neg G).trans (Homeomorph.addLeft x₀) apply ((u.isCompact_preimage.mpr h).bddAbove_image hg.norm.continuousOn).convolutionExistsAt' L isClosed_closure.measurableSet subset_closure (hf.integrableOn_isCompact h) have A : AEStronglyMeasurable (g ∘ v) (μ.restrict (tsupport fun t : G => L (f t) (g (x₀ - t)))) := by apply (hg.comp v.continuous).continuousOn.aestronglyMeasurable_of_isCompact h exact (isClosed_tsupport _).measurableSet convert ((v.continuous.measurable.measurePreserving (μ.restrict (tsupport fun t => L (f t) (g (x₀ - t))))).aestronglyMeasurable_comp_iff v.measurableEmbedding).1 A ext x simp only [v, Homeomorph.neg, sub_eq_add_neg, val_toAddUnits_apply, Homeomorph.trans_apply, Equiv.neg_apply, Equiv.toFun_as_coe, Homeomorph.homeomorph_mk_coe, Equiv.coe_fn_mk, Homeomorph.coe_addLeft] theorem _root_.HasCompactSupport.convolutionExists_right (hcg : HasCompactSupport g) (hf : LocallyIntegrable f μ) (hg : Continuous g) : ConvolutionExists f g L μ := by intro x₀ refine HasCompactSupport.convolutionExistsAt L ?_ hf hg refine (hcg.comp_homeomorph (Homeomorph.subLeft x₀)).mono ?_ refine fun t => mt fun ht : g (x₀ - t) = 0 => ?_ simp_rw [ht, (L _).map_zero] theorem _root_.HasCompactSupport.convolutionExists_left_of_continuous_right (hcf : HasCompactSupport f) (hf : LocallyIntegrable f μ) (hg : Continuous g) : ConvolutionExists f g L μ := by intro x₀ refine HasCompactSupport.convolutionExistsAt L ?_ hf hg refine hcf.mono ?_ refine fun t => mt fun ht : f t = 0 => ?_ simp_rw [ht, L.map_zero₂] end Group section CommGroup variable [AddCommGroup G] section MeasurableGroup variable [MeasurableNeg G] [IsAddLeftInvariant μ] /-- A sufficient condition to prove that `f ⋆[L, μ] g` exists. We assume that the integrand has compact support and `g` is bounded on this support (note that both properties hold if `g` is continuous with compact support). We also require that `f` is integrable on the support of the integrand, and that both functions are strongly measurable. This is a variant of `BddAbove.convolutionExistsAt'` in an abelian group with a left-invariant measure. This allows us to state the boundedness and measurability of `g` in a more natural way. -/ theorem _root_.BddAbove.convolutionExistsAt [MeasurableAdd₂ G] [SFinite μ] {x₀ : G} {s : Set G} (hbg : BddAbove ((fun i => ‖g i‖) '' ((fun t => x₀ - t) ⁻¹' s))) (hs : MeasurableSet s) (h2s : (support fun t => L (f t) (g (x₀ - t))) ⊆ s) (hf : IntegrableOn f s μ) (hmg : AEStronglyMeasurable g μ) : ConvolutionExistsAt f g x₀ L μ := by refine BddAbove.convolutionExistsAt' L ?_ hs h2s hf ?_ · simp_rw [← sub_eq_neg_add, hbg] · have : AEStronglyMeasurable g (map (fun t : G => x₀ - t) μ) := hmg.mono_ac (quasiMeasurePreserving_sub_left_of_right_invariant μ x₀).absolutelyContinuous apply this.mono_measure exact map_mono restrict_le_self (measurable_const.sub measurable_id') variable {L} [MeasurableAdd G] [IsNegInvariant μ] theorem convolutionExistsAt_flip : ConvolutionExistsAt g f x L.flip μ ↔ ConvolutionExistsAt f g x L μ := by simp_rw [ConvolutionExistsAt, ← integrable_comp_sub_left (fun t => L (f t) (g (x - t))) x, sub_sub_cancel, flip_apply] theorem ConvolutionExistsAt.integrable_swap (h : ConvolutionExistsAt f g x L μ) : Integrable (fun t => L (f (x - t)) (g t)) μ := by convert h.comp_sub_left x simp_rw [sub_sub_self] theorem convolutionExistsAt_iff_integrable_swap : ConvolutionExistsAt f g x L μ ↔ Integrable (fun t => L (f (x - t)) (g t)) μ := convolutionExistsAt_flip.symm end MeasurableGroup variable [TopologicalSpace G] [IsTopologicalAddGroup G] [BorelSpace G] variable [IsAddLeftInvariant μ] [IsNegInvariant μ] theorem _root_.HasCompactSupport.convolutionExists_left (hcf : HasCompactSupport f) (hf : Continuous f) (hg : LocallyIntegrable g μ) : ConvolutionExists f g L μ := fun x₀ => convolutionExistsAt_flip.mp <\| hcf.convolutionExists_right L.flip hg hf x₀ @[deprecated (since := "2025-02-06")] alias _root_.HasCompactSupport.convolutionExistsLeft := HasCompactSupport.convolutionExists_left theorem _root_.HasCompactSupport.convolutionExists_right_of_continuous_left (hcg : HasCompactSupport g) (hf : Continuous f) (hg : LocallyIntegrable g μ) : ConvolutionExists f g L μ := fun x₀ => convolutionExistsAt_flip.mp <\| hcg.convolutionExists_left_of_continuous_right L.flip hg hf x₀ @[deprecated (since := "2025-02-06")] alias _root_.HasCompactSupport.convolutionExistsRightOfContinuousLeft := HasCompactSupport.convolutionExists_right_of_continuous_left end CommGroup end ConvolutionExists variable [NormedSpace ℝ F] /-- The convolution of two functions `f` and `g` with respect to a continuous bilinear map `L` and measure `μ`. It is defined to be `(f ⋆[L, μ] g) x = ∫ t, L (f t) (g (x - t)) ∂μ`. -/ noncomputable def convolution [Sub G] (f : G → E) (g : G → E') (L : E →L[𝕜] E' →L[𝕜] F) (μ : Measure G := by volume_tac) : G → F := fun x => ∫ t, L (f t) (g (x - t)) ∂μ /-- The convolution of two functions with respect to a bilinear operation `L` and a measure `μ`. -/ scoped[Convolution] notation:67 f " ⋆[" L:67 ", " μ:67 "] " g:66 => convolution f g L μ /-- The convolution of two functions with respect to a bilinear operation `L` and the volume. -/ scoped[Convolution] notation:67 f " ⋆[" L:67 "]" g:66 => convolution f g L MeasureSpace.volume /-- The convolution of two real-valued functions with respect to volume. -/ scoped[Convolution] notation:67 f " ⋆ " g:66 => convolution f g (ContinuousLinearMap.lsmul ℝ ℝ) MeasureSpace.volume open scoped Convolution theorem convolution_def [Sub G] : (f ⋆[L, μ] g) x = ∫ t, L (f t) (g (x - t)) ∂μ := rfl /-- The definition of convolution where the bilinear operator is scalar multiplication. Note: it often helps the elaborator to give the type of the convolution explicitly. -/ theorem convolution_lsmul [Sub G] {f : G → 𝕜} {g : G → F} : (f ⋆[lsmul 𝕜 𝕜, μ] g : G → F) x = ∫ t, f t • g (x - t) ∂μ := rfl /-- The definition of convolution where the bilinear operator is multiplication. -/ theorem convolution_mul [Sub G] [NormedSpace ℝ 𝕜] {f : G → 𝕜} {g : G → 𝕜} : (f ⋆[mul 𝕜 𝕜, μ] g) x = ∫ t, f t * g (x - t) ∂μ := rfl section Group variable {L} [AddGroup G] theorem smul_convolution [SMulCommClass ℝ 𝕜 F] {y : 𝕜} : y • f ⋆[L, μ] g = y • (f ⋆[L, μ] g) := by ext; simp only [Pi.smul_apply, convolution_def, ← integral_smul, L.map_smul₂] theorem convolution_smul [SMulCommClass ℝ 𝕜 F] {y : 𝕜} : f ⋆[L, μ] y • g = y • (f ⋆[L, μ] g) := by ext; simp only [Pi.smul_apply, convolution_def, ← integral_smul, (L _).map_smul] @[simp] theorem zero_convolution : 0 ⋆[L, μ] g = 0 := by ext simp_rw [convolution_def, Pi.zero_apply, L.map_zero₂, integral_zero] @[simp] theorem convolution_zero : f ⋆[L, μ] 0 = 0 := by ext simp_rw [convolution_def, Pi.zero_apply, (L _).map_zero, integral_zero] theorem ConvolutionExistsAt.distrib_add {x : G} (hfg : ConvolutionExistsAt f g x L μ) (hfg' : ConvolutionExistsAt f g' x L μ) : (f ⋆[L, μ] (g + g')) x = (f ⋆[L, μ] g) x + (f ⋆[L, μ] g') x := by simp only [convolution_def, (L _).map_add, Pi.add_apply, integral_add hfg hfg'] theorem ConvolutionExists.distrib_add (hfg : ConvolutionExists f g L μ) (hfg' : ConvolutionExists f g' L μ) : f ⋆[L, μ] (g + g') = f ⋆[L, μ] g + f ⋆[L, μ] g' := by ext x exact (hfg x).distrib_add (hfg' x) theorem ConvolutionExistsAt.add_distrib {x : G} (hfg : ConvolutionExistsAt f g x L μ) (hfg' : ConvolutionExistsAt f' g x L μ) : ((f + f') ⋆[L, μ] g) x = (f ⋆[L, μ] g) x + (f' ⋆[L, μ] g) x := by simp only [convolution_def, L.map_add₂, Pi.add_apply, integral_add hfg hfg'] theorem ConvolutionExists.add_distrib (hfg : ConvolutionExists f g L μ) (hfg' : ConvolutionExists f' g L μ) : (f + f') ⋆[L, μ] g = f ⋆[L, μ] g + f' ⋆[L, μ] g := by ext x exact (hfg x).add_distrib (hfg' x) theorem convolution_mono_right {f g g' : G → ℝ} (hfg : ConvolutionExistsAt f g x (lsmul ℝ ℝ) μ) (hfg' : ConvolutionExistsAt f g' x (lsmul ℝ ℝ) μ) (hf : ∀ x, 0 ≤ f x) (hg : ∀ x, g x ≤ g' x) : (f ⋆[lsmul ℝ ℝ, μ] g) x ≤ (f ⋆[lsmul ℝ ℝ, μ] g') x := by apply integral_mono hfg hfg' simp only [lsmul_apply, Algebra.id.smul_eq_mul] intro t apply mul_le_mul_of_nonneg_left (hg _) (hf _) theorem convolution_mono_right_of_nonneg {f g g' : G → ℝ} (hfg' : ConvolutionExistsAt f g' x (lsmul ℝ ℝ) μ) (hf : ∀ x, 0 ≤ f x) (hg : ∀ x, g x ≤ g' x) (hg' : ∀ x, 0 ≤ g' x) : (f ⋆[lsmul ℝ ℝ, μ] g) x ≤ (f ⋆[lsmul ℝ ℝ, μ] g') x := by by_cases H : ConvolutionExistsAt f g x (lsmul ℝ ℝ) μ · exact convolution_mono_right H hfg' hf hg have : (f ⋆[lsmul ℝ ℝ, μ] g) x = 0 := integral_undef H rw [this] exact integral_nonneg fun y => mul_nonneg (hf y) (hg' (x - y)) variable (L) theorem convolution_congr [MeasurableAdd₂ G] [MeasurableNeg G] [SFinite μ] [IsAddRightInvariant μ] (h1 : f =ᵐ[μ] f') (h2 : g =ᵐ[μ] g') : f ⋆[L, μ] g = f' ⋆[L, μ] g' := by ext x apply integral_congr_ae exact (h1.prodMk <\| h2.comp_tendsto (quasiMeasurePreserving_sub_left_of_right_invariant μ x).tendsto_ae).fun_comp ↿fun x y ↦ L x y theorem support_convolution_subset_swap : support (f ⋆[L, μ] g) ⊆ support g + support f := by intro x h2x by_contra hx apply h2x simp_rw [Set.mem_add, ← exists_and_left, not_exists, not_and_or, nmem_support] at hx rw [convolution_def] convert integral_zero G F using 2 ext t rcases hx (x - t) t with (h \| h \| h) · rw [h, (L _).map_zero] · rw [h, L.map_zero₂] · exact (h <\| sub_add_cancel x t).elim section variable [MeasurableAdd₂ G] [MeasurableNeg G] [SFinite μ] [IsAddRightInvariant μ] theorem Integrable.integrable_convolution (hf : Integrable f μ) (hg : Integrable g μ) : Integrable (f ⋆[L, μ] g) μ := (hf.convolution_integrand L hg).integral_prod_left end variable [TopologicalSpace G] variable [IsTopologicalAddGroup G] protected theorem _root_.HasCompactSupport.convolution [T2Space G] (hcf : HasCompactSupport f) (hcg : HasCompactSupport g) : HasCompactSupport (f ⋆[L, μ] g) := (hcg.isCompact.add hcf).of_isClosed_subset isClosed_closure <\| closure_minimal ((support_convolution_subset_swap L).trans <\| add_subset_add subset_closure subset_closure) (hcg.isCompact.add hcf).isClosed variable [BorelSpace G] [TopologicalSpace P] /-- The convolution `f * g` is continuous if `f` is locally integrable and `g` is continuous and compactly supported. Version where `g` depends on an additional parameter in a subset `s` of a parameter space `P` (and the compact support `k` is independent of the parameter in `s`). -/ theorem continuousOn_convolution_right_with_param {g : P → G → E'} {s : Set P} {k : Set G} (hk : IsCompact k) (hgs : ∀ p, ∀ x, p ∈ s → x ∉ k → g p x = 0) (hf : LocallyIntegrable f μ) (hg : ContinuousOn (↿g) (s ×ˢ univ)) : ContinuousOn (fun q : P × G => (f ⋆[L, μ] g q.1) q.2) (s ×ˢ univ) := by /- First get rid of the case where the space is not locally compact. Then `g` vanishes everywhere and the conclusion is trivial. -/ by_cases H : ∀ p ∈ s, ∀ x, g p x = 0 · apply (continuousOn_const (c := 0)).congr rintro ⟨p, x⟩ ⟨hp, -⟩ apply integral_eq_zero_of_ae (Eventually.of_forall (fun y ↦ ?_)) simp [H p hp _] have : LocallyCompactSpace G := by push_neg at H rcases H with ⟨p, hp, x, hx⟩ have A : support (g p) ⊆ k := support_subset_iff'.2 (fun y hy ↦ hgs p y hp hy) have B : Continuous (g p) := by refine hg.comp_continuous (.prodMk_right _) fun x => ?_ simpa only [prodMk_mem_set_prod_eq, mem_univ, and_true] using hp rcases eq_zero_or_locallyCompactSpace_of_support_subset_isCompact_of_addGroup hk A B with H\|H · simp [H] at hx · exact H /- Since `G` is locally compact, one may thicken `k` a little bit into a larger compact set `(-k) + t`, outside of which all functions that appear in the convolution vanish. Then we can apply a continuity statement for integrals depending on a parameter, with respect to locally integrable functions and compactly supported continuous functions. -/ rintro ⟨q₀, x₀⟩ ⟨hq₀, -⟩ obtain ⟨t, t_comp, ht⟩ : ∃ t, IsCompact t ∧ t ∈ 𝓝 x₀ := exists_compact_mem_nhds x₀ let k' : Set G := (-k) +ᵥ t have k'_comp : IsCompact k' := IsCompact.vadd_set hk.neg t_comp let g' : (P × G) → G → E' := fun p x ↦ g p.1 (p.2 - x) let s' : Set (P × G) := s ×ˢ t have A : ContinuousOn g'.uncurry (s' ×ˢ univ) := by have : g'.uncurry = g.uncurry ∘ (fun w ↦ (w.1.1, w.1.2 - w.2)) := by ext y; rfl rw [this] refine hg.comp (by fun_prop) ?_ simp +contextual [s', MapsTo] have B : ContinuousOn (fun a ↦ ∫ x, L (f x) (g' a x) ∂μ) s' := by apply continuousOn_integral_bilinear_of_locally_integrable_of_compact_support L k'_comp A _ (hf.integrableOn_isCompact k'_comp) rintro ⟨p, x⟩ y ⟨hp, hx⟩ hy apply hgs p _ hp contrapose! hy exact ⟨y - x, by simpa using hy, x, hx, by simp⟩ apply ContinuousWithinAt.mono_of_mem_nhdsWithin (B (q₀, x₀) ⟨hq₀, mem_of_mem_nhds ht⟩) exact mem_nhdsWithin_prod_iff.2 ⟨s, self_mem_nhdsWithin, t, nhdsWithin_le_nhds ht, Subset.rfl⟩ /-- The convolution `f * g` is continuous if `f` is locally integrable and `g` is continuous and compactly supported. Version where `g` depends on an additional parameter in an open subset `s` of a parameter space `P` (and the compact support `k` is independent of the parameter in `s`), given in terms of compositions with an additional continuous map. -/ theorem continuousOn_convolution_right_with_param_comp {s : Set P} {v : P → G} (hv : ContinuousOn v s) {g : P → G → E'} {k : Set G} (hk : IsCompact k) (hgs : ∀ p, ∀ x, p ∈ s → x ∉ k → g p x = 0) (hf : LocallyIntegrable f μ) (hg : ContinuousOn (↿g) (s ×ˢ univ)) : ContinuousOn (fun x => (f ⋆[L, μ] g x) (v x)) s := by apply (continuousOn_convolution_right_with_param L hk hgs hf hg).comp (continuousOn_id.prodMk hv) intro x hx simp only [hx, prodMk_mem_set_prod_eq, mem_univ, and_self_iff, _root_.id] /-- The convolution is continuous if one function is locally integrable and the other has compact support and is continuous. -/ theorem _root_.HasCompactSupport.continuous_convolution_right (hcg : HasCompactSupport g) (hf : LocallyIntegrable f μ) (hg : Continuous g) : Continuous (f ⋆[L, μ] g) := by rw [continuous_iff_continuousOn_univ] let g' : G → G → E' := fun _ q => g q have : ContinuousOn (↿g') (univ ×ˢ univ) := (hg.comp continuous_snd).continuousOn exact continuousOn_convolution_right_with_param_comp L (continuous_iff_continuousOn_univ.1 continuous_id) hcg (fun p x _ hx => image_eq_zero_of_nmem_tsupport hx) hf this /-- The convolution is continuous if one function is integrable and the other is bounded and continuous. -/ theorem _root_.BddAbove.continuous_convolution_right_of_integrable [FirstCountableTopology G] [SecondCountableTopologyEither G E'] (hbg : BddAbove (range fun x => ‖g x‖)) (hf : Integrable f μ) (hg : Continuous g) : Continuous (f ⋆[L, μ] g) := by refine continuous_iff_continuousAt.mpr fun x₀ => ?_ have : ∀ᶠ x in 𝓝 x₀, ∀ᵐ t : G ∂μ, ‖L (f t) (g (x - t))‖ ≤ ‖L‖ * ‖f t‖ * ⨆ i, ‖g i‖ := by filter_upwards with x; filter_upwards with t apply_rules [L.le_of_opNorm₂_le_of_le, le_rfl, le_ciSup hbg (x - t)] refine continuousAt_of_dominated ?_ this ?_ ?_ · exact Eventually.of_forall fun x => hf.aestronglyMeasurable.convolution_integrand_snd' L hg.aestronglyMeasurable · exact (hf.norm.const_mul _).mul_const _ · exact Eventually.of_forall fun t => (L.continuous₂.comp₂ continuous_const <\| hg.comp <\| continuous_id.sub continuous_const).continuousAt end Group section CommGroup variable [AddCommGroup G] theorem support_convolution_subset : support (f ⋆[L, μ] g) ⊆ support f + support g := (support_convolution_subset_swap L).trans (add_comm _ _).subset variable [IsAddLeftInvariant μ] [IsNegInvariant μ] section Measurable variable [MeasurableNeg G] variable [MeasurableAdd G] /-- Commutativity of convolution -/ theorem convolution_flip : g ⋆[L.flip, μ] f = f ⋆[L, μ] g := by ext1 x simp_rw [convolution_def] rw [← integral_sub_left_eq_self _ μ x] simp_rw [sub_sub_self, flip_apply] /-- The symmetric definition of convolution. -/ theorem convolution_eq_swap : (f ⋆[L, μ] g) x = ∫ t, L (f (x - t)) (g t) ∂μ := by rw [← convolution_flip]; rfl /-- The symmetric definition of convolution where the bilinear operator is scalar multiplication. -/ theorem convolution_lsmul_swap {f : G → 𝕜} {g : G → F} : (f ⋆[lsmul 𝕜 𝕜, μ] g : G → F) x = ∫ t, f (x - t) • g t ∂μ := convolution_eq_swap _ /-- The symmetric definition of convolution where the bilinear operator is multiplication. -/ theorem convolution_mul_swap [NormedSpace ℝ 𝕜] {f : G → 𝕜} {g : G → 𝕜} : (f ⋆[mul 𝕜 𝕜, μ] g) x = ∫ t, f (x - t) * g t ∂μ := convolution_eq_swap _ /-- The convolution of two even functions is also even. -/ theorem convolution_neg_of_neg_eq (h1 : ∀ᵐ x ∂μ, f (-x) = f x) (h2 : ∀ᵐ x ∂μ, g (-x) = g x) : (f ⋆[L, μ] g) (-x) = (f ⋆[L, μ] g) x := calc ∫ t : G, (L (f t)) (g (-x - t)) ∂μ = ∫ t : G, (L (f (-t))) (g (x + t)) ∂μ := by apply integral_congr_ae filter_upwards [h1, (eventually_add_left_iff μ x).2 h2] with t ht h't simp_rw [ht, ← h't, neg_add'] _ = ∫ t : G, (L (f t)) (g (x - t)) ∂μ := by rw [← integral_neg_eq_self] simp only [neg_neg, ← sub_eq_add_neg] end Measurable variable [TopologicalSpace G] variable [IsTopologicalAddGroup G] variable [BorelSpace G] theorem _root_.HasCompactSupport.continuous_convolution_left (hcf : HasCompactSupport f) (hf : Continuous f) (hg : LocallyIntegrable g μ) : Continuous (f ⋆[L, μ] g) := by rw [← convolution_flip] exact hcf.continuous_convolution_right L.flip hg hf theorem _root_.BddAbove.continuous_convolution_left_of_integrable [FirstCountableTopology G] [SecondCountableTopologyEither G E] (hbf : BddAbove (range fun x => ‖f x‖)) (hf : Continuous f) (hg : Integrable g μ) : Continuous (f ⋆[L, μ] g) := by rw [← convolution_flip] exact hbf.continuous_convolution_right_of_integrable L.flip hg hf end CommGroup section NormedAddCommGroup variable [SeminormedAddCommGroup G] /-- Compute `(f ⋆ g) x₀` if the support of the `f` is within `Metric.ball 0 R`, and `g` is constant on `Metric.ball x₀ R`. We can simplify the RHS further if we assume `f` is integrable, but also if `L = (•)` or more generally if `L` has an `AntilipschitzWith`-condition. -/ theorem convolution_eq_right' {x₀ : G} {R : ℝ} (hf : support f ⊆ ball (0 : G) R) (hg : ∀ x ∈ ball x₀ R, g x = g x₀) : (f ⋆[L, μ] g) x₀ = ∫ t, L (f t) (g x₀) ∂μ := by have h2 : ∀ t, L (f t) (g (x₀ - t)) = L (f t) (g x₀) := fun t ↦ by by_cases ht : t ∈ support f · have h2t := hf ht rw [mem_ball_zero_iff] at h2t specialize hg (x₀ - t) rw [sub_eq_add_neg, add_mem_ball_iff_norm, norm_neg, ← sub_eq_add_neg] at hg rw [hg h2t] · rw [nmem_support] at ht simp_rw [ht, L.map_zero₂] simp_rw [convolution_def, h2] variable [BorelSpace G] [SecondCountableTopology G] variable [IsAddLeftInvariant μ] [SFinite μ] /-- Approximate `(f ⋆ g) x₀` if the support of the `f` is bounded within a ball, and `g` is near `g x₀` on a ball with the same radius around `x₀`. See `dist_convolution_le` for a special case. We can simplify the second argument of `dist` further if we add some extra type-classes on `E` and `𝕜` or if `L` is scalar multiplication. -/ theorem dist_convolution_le' {x₀ : G} {R ε : ℝ} {z₀ : E'} (hε : 0 ≤ ε) (hif : Integrable f μ) (hf : support f ⊆ ball (0 : G) R) (hmg : AEStronglyMeasurable g μ) (hg : ∀ x ∈ ball x₀ R, dist (g x) z₀ ≤ ε) : dist ((f ⋆[L, μ] g : G → F) x₀) (∫ t, L (f t) z₀ ∂μ) ≤ (‖L‖ * ∫ x, ‖f x‖ ∂μ) * ε := by have hfg : ConvolutionExistsAt f g x₀ L μ := by refine BddAbove.convolutionExistsAt L ?_ Metric.isOpen_ball.measurableSet (Subset.trans ?_ hf) hif.integrableOn hmg swap; · refine fun t => mt fun ht : f t = 0 => ?_; simp_rw [ht, L.map_zero₂] rw [bddAbove_def] refine ⟨‖z₀‖ + ε, ?_⟩ rintro _ ⟨x, hx, rfl⟩ refine norm_le_norm_add_const_of_dist_le (hg x ?_) rwa [mem_ball_iff_norm, norm_sub_rev, ← mem_ball_zero_iff] have h2 : ∀ t, dist (L (f t) (g (x₀ - t))) (L (f t) z₀) ≤ ‖L (f t)‖ * ε := by intro t; by_cases ht : t ∈ support f · have h2t := hf ht rw [mem_ball_zero_iff] at h2t specialize hg (x₀ - t) rw [sub_eq_add_neg, add_mem_ball_iff_norm, norm_neg, ← sub_eq_add_neg] at hg refine ((L (f t)).dist_le_opNorm _ _).trans ?_ exact mul_le_mul_of_nonneg_left (hg h2t) (norm_nonneg _) · rw [nmem_support] at ht simp_rw [ht, L.map_zero₂, L.map_zero, norm_zero, zero_mul, dist_self] rfl simp_rw [convolution_def] simp_rw [dist_eq_norm] at h2 ⊢ rw [← integral_sub hfg.integrable]; swap; · exact (L.flip z₀).integrable_comp hif refine (norm_integral_le_of_norm_le ((L.integrable_comp hif).norm.mul_const ε) (Eventually.of_forall h2)).trans ?_ rw [integral_mul_const] refine mul_le_mul_of_nonneg_right ?_ hε have h3 : ∀ t, ‖L (f t)‖ ≤ ‖L‖ * ‖f t‖ := by intro t exact L.le_opNorm (f t) refine (integral_mono (L.integrable_comp hif).norm (hif.norm.const_mul _) h3).trans_eq ?_ rw [integral_const_mul] variable [NormedSpace ℝ E] [NormedSpace ℝ E'] [CompleteSpace E'] /-- Approximate `f ⋆ g` if the support of the `f` is bounded within a ball, and `g` is near `g x₀` on a ball with the same radius around `x₀`. This is a special case of `dist_convolution_le'` where `L` is `(•)`, `f` has integral 1 and `f` is nonnegative. -/ theorem dist_convolution_le {f : G → ℝ} {x₀ : G} {R ε : ℝ} {z₀ : E'} (hε : 0 ≤ ε) (hf : support f ⊆ ball (0 : G) R) (hnf : ∀ x, 0 ≤ f x) (hintf : ∫ x, f x ∂μ = 1) (hmg : AEStronglyMeasurable g μ) (hg : ∀ x ∈ ball x₀ R, dist (g x) z₀ ≤ ε) : dist ((f ⋆[lsmul ℝ ℝ, μ] g : G → E') x₀) z₀ ≤ ε := by have hif : Integrable f μ := integrable_of_integral_eq_one hintf convert (dist_convolution_le' (lsmul ℝ ℝ) hε hif hf hmg hg).trans _ · simp_rw [lsmul_apply, integral_smul_const, hintf, one_smul] · simp_rw [Real.norm_of_nonneg (hnf _), hintf, mul_one] exact (mul_le_mul_of_nonneg_right opNorm_lsmul_le hε).trans_eq (one_mul ε) /-- `(φ i ⋆ g i) (k i)` tends to `z₀` as `i` tends to some filter `l` if * `φ` is a sequence of nonnegative functions with integral `1` as `i` tends to `l`; * The support of `φ` tends to small neighborhoods around `(0 : G)` as `i` tends to `l`; * `g i` is `mu`-a.e. strongly measurable as `i` tends to `l`; * `g i x` tends to `z₀` as `(i, x)` tends to `l ×ˢ 𝓝 x₀`; * `k i` tends to `x₀`. See also `ContDiffBump.convolution_tendsto_right`. -/ theorem convolution_tendsto_right {ι} {g : ι → G → E'} {l : Filter ι} {x₀ : G} {z₀ : E'} {φ : ι → G → ℝ} {k : ι → G} (hnφ : ∀ᶠ i in l, ∀ x, 0 ≤ φ i x) (hiφ : ∀ᶠ i in l, ∫ x, φ i x ∂μ = 1) -- todo: we could weaken this to "the integral tends to 1" (hφ : Tendsto (fun n => support (φ n)) l (𝓝 0).smallSets) (hmg : ∀ᶠ i in l, AEStronglyMeasurable (g i) μ) (hcg : Tendsto (uncurry g) (l ×ˢ 𝓝 x₀) (𝓝 z₀)) (hk : Tendsto k l (𝓝 x₀)) : Tendsto (fun i : ι => (φ i ⋆[lsmul ℝ ℝ, μ] g i : G → E') (k i)) l (𝓝 z₀) := by simp_rw [tendsto_smallSets_iff] at hφ rw [Metric.tendsto_nhds] at hcg ⊢ simp_rw [Metric.eventually_prod_nhds_iff] at hcg intro ε hε have h2ε : 0 < ε / 3 := div_pos hε (by norm_num) obtain ⟨p, hp, δ, hδ, hgδ⟩ := hcg _ h2ε dsimp only [uncurry] at hgδ have h2k := hk.eventually (ball_mem_nhds x₀ <\| half_pos hδ) have h2φ := hφ (ball (0 : G) _) <\| ball_mem_nhds _ (half_pos hδ) filter_upwards [hp, h2k, h2φ, hnφ, hiφ, hmg] with i hpi hki hφi hnφi hiφi hmgi have hgi : dist (g i (k i)) z₀ < ε / 3 := hgδ hpi (hki.trans <\| half_lt_self hδ) have h1 : ∀ x' ∈ ball (k i) (δ / 2), dist (g i x') (g i (k i)) ≤ ε / 3 + ε / 3 := by intro x' hx' refine (dist_triangle_right _ _ _).trans (add_le_add (hgδ hpi ?_).le hgi.le) exact ((dist_triangle _ _ _).trans_lt (add_lt_add hx'.out hki)).trans_eq (add_halves δ) have := dist_convolution_le (add_pos h2ε h2ε).le hφi hnφi hiφi hmgi h1 refine ((dist_triangle _ _ _).trans_lt (add_lt_add_of_le_of_lt this hgi)).trans_eq ?_ field_simp; ring_nf end NormedAddCommGroup end Measurability end NontriviallyNormedField open scoped Convolution section RCLike variable [RCLike 𝕜] variable [NormedSpace 𝕜 E] variable [NormedSpace 𝕜 E'] variable [NormedSpace 𝕜 E''] variable [NormedSpace ℝ F] [NormedSpace 𝕜 F] variable {n : ℕ∞} variable [MeasurableSpace G] {μ ν : Measure G} variable (L : E →L[𝕜] E' →L[𝕜] F) section Assoc variable [CompleteSpace F] variable [NormedAddCommGroup F'] [NormedSpace ℝ F'] [NormedSpace 𝕜 F'] [CompleteSpace F'] variable [NormedAddCommGroup F''] [NormedSpace ℝ F''] [NormedSpace 𝕜 F''] [CompleteSpace F''] variable {k : G → E''} variable (L₂ : F →L[𝕜] E'' →L[𝕜] F') variable (L₃ : E →L[𝕜] F'' →L[𝕜] F') variable (L₄ : E' →L[𝕜] E'' →L[𝕜] F'') variable [AddGroup G] variable [SFinite μ] [SFinite ν] [IsAddRightInvariant μ] theorem integral_convolution [MeasurableAdd₂ G] [MeasurableNeg G] [NormedSpace ℝ E] [NormedSpace ℝ E'] [CompleteSpace E] [CompleteSpace E'] (hf : Integrable f ν) (hg : Integrable g μ) : ∫ x, (f ⋆[L, ν] g) x ∂μ = L (∫ x, f x ∂ν) (∫ x, g x ∂μ) := by refine (integral_integral_swap (by apply hf.convolution_integrand L hg)).trans ?_ simp_rw [integral_comp_comm _ (hg.comp_sub_right _), integral_sub_right_eq_self] exact (L.flip (∫ x, g x ∂μ)).integral_comp_comm hf variable [MeasurableAdd₂ G] [IsAddRightInvariant ν] [MeasurableNeg G] /-- Convolution is associative. This has a weak but inconvenient integrability condition. See also `MeasureTheory.convolution_assoc`. -/ theorem convolution_assoc' (hL : ∀ (x : E) (y : E') (z : E''), L₂ (L x y) z = L₃ x (L₄ y z)) {x₀ : G} (hfg : ∀ᵐ y ∂μ, ConvolutionExistsAt f g y L ν) (hgk : ∀ᵐ x ∂ν, ConvolutionExistsAt g k x L₄ μ) (hi : Integrable (uncurry fun x y => (L₃ (f y)) ((L₄ (g (x - y))) (k (x₀ - x)))) (μ.prod ν)) : ((f ⋆[L, ν] g) ⋆[L₂, μ] k) x₀ = (f ⋆[L₃, ν] g ⋆[L₄, μ] k) x₀ := calc ((f ⋆[L, ν] g) ⋆[L₂, μ] k) x₀ = ∫ t, L₂ (∫ s, L (f s) (g (t - s)) ∂ν) (k (x₀ - t)) ∂μ := rfl _ = ∫ t, ∫ s, L₂ (L (f s) (g (t - s))) (k (x₀ - t)) ∂ν ∂μ := (integral_congr_ae (hfg.mono fun t ht => ((L₂.flip (k (x₀ - t))).integral_comp_comm ht).symm)) _ = ∫ t, ∫ s, L₃ (f s) (L₄ (g (t - s)) (k (x₀ - t))) ∂ν ∂μ := by simp_rw [hL] _ = ∫ s, ∫ t, L₃ (f s) (L₄ (g (t - s)) (k (x₀ - t))) ∂μ ∂ν := by rw [integral_integral_swap hi] _ = ∫ s, ∫ u, L₃ (f s) (L₄ (g u) (k (x₀ - s - u))) ∂μ ∂ν := by congr; ext t rw [eq_comm, ← integral_sub_right_eq_self _ t] simp_rw [sub_sub_sub_cancel_right] _ = ∫ s, L₃ (f s) (∫ u, L₄ (g u) (k (x₀ - s - u)) ∂μ) ∂ν := by refine integral_congr_ae ?_ refine ((quasiMeasurePreserving_sub_left_of_right_invariant ν x₀).ae hgk).mono fun t ht => ?_ exact (L₃ (f t)).integral_comp_comm ht _ = (f ⋆[L₃, ν] g ⋆[L₄, μ] k) x₀ := rfl /-- Convolution is associative. This requires that * all maps are a.e. strongly measurable w.r.t one of the measures * `f ⋆[L, ν] g` exists almost everywhere * `‖g‖ ⋆[μ] ‖k‖` exists almost everywhere * `‖f‖ ⋆[ν] (‖g‖ ⋆[μ] ‖k‖)` exists at `x₀` -/ theorem convolution_assoc (hL : ∀ (x : E) (y : E') (z : E''), L₂ (L x y) z = L₃ x (L₄ y z)) {x₀ : G} (hf : AEStronglyMeasurable f ν) (hg : AEStronglyMeasurable g μ) (hk : AEStronglyMeasurable k μ) (hfg : ∀ᵐ y ∂μ, ConvolutionExistsAt f g y L ν) (hgk : ∀ᵐ x ∂ν, ConvolutionExistsAt (fun x => ‖g x‖) (fun x => ‖k x‖) x (mul ℝ ℝ) μ) (hfgk : ConvolutionExistsAt (fun x => ‖f x‖) ((fun x => ‖g x‖) ⋆[mul ℝ ℝ, μ] fun x => ‖k x‖) x₀ (mul ℝ ℝ) ν) : ((f ⋆[L, ν] g) ⋆[L₂, μ] k) x₀ = (f ⋆[L₃, ν] g ⋆[L₄, μ] k) x₀ := by refine convolution_assoc' L L₂ L₃ L₄ hL hfg (hgk.mono fun x hx => hx.of_norm L₄ hg hk) ?_ -- the following is similar to `Integrable.convolution_integrand` have h_meas : AEStronglyMeasurable (uncurry fun x y => L₃ (f y) (L₄ (g x) (k (x₀ - y - x)))) (μ.prod ν) := by refine L₃.aestronglyMeasurable_comp₂ hf.snd ?_ refine L₄.aestronglyMeasurable_comp₂ hg.fst ?_ refine (hk.mono_ac ?_).comp_measurable ((measurable_const.sub measurable_snd).sub measurable_fst) refine QuasiMeasurePreserving.absolutelyContinuous ?_ refine QuasiMeasurePreserving.prod_of_left ((measurable_const.sub measurable_snd).sub measurable_fst) (Eventually.of_forall fun y => ?_) dsimp only exact quasiMeasurePreserving_sub_left_of_right_invariant μ _ have h2_meas : AEStronglyMeasurable (fun y => ∫ x, ‖L₃ (f y) (L₄ (g x) (k (x₀ - y - x)))‖ ∂μ) ν := h_meas.prod_swap.norm.integral_prod_right' have h3 : map (fun z : G × G => (z.1 - z.2, z.2)) (μ.prod ν) = μ.prod ν := (measurePreserving_sub_prod μ ν).map_eq suffices Integrable (uncurry fun x y => L₃ (f y) (L₄ (g x) (k (x₀ - y - x)))) (μ.prod ν) by rw [← h3] at this convert this.comp_measurable (measurable_sub.prodMk measurable_snd) ext ⟨x, y⟩ simp +unfoldPartialApp only [uncurry, Function.comp_apply, sub_sub_sub_cancel_right] simp_rw [integrable_prod_iff' h_meas] refine ⟨((quasiMeasurePreserving_sub_left_of_right_invariant ν x₀).ae hgk).mono fun t ht => (L₃ (f t)).integrable_comp <\| ht.of_norm L₄ hg hk, ?_⟩ refine (hfgk.const_mul (‖L₃‖ * ‖L₄‖)).mono' h2_meas (((quasiMeasurePreserving_sub_left_of_right_invariant ν x₀).ae hgk).mono fun t ht => ?_) simp_rw [convolution_def, mul_apply', mul_mul_mul_comm ‖L₃‖ ‖L₄‖, ← integral_const_mul] rw [Real.norm_of_nonneg (by positivity)] refine integral_mono_of_nonneg (Eventually.of_forall fun t => norm_nonneg _) ((ht.const_mul _).const_mul _) (Eventually.of_forall fun s => ?_) simp only [← mul_assoc ‖L₄‖] apply_rules [ContinuousLinearMap.le_of_opNorm₂_le_of_le, le_rfl] end Assoc variable [NormedAddCommGroup G] [BorelSpace G] theorem convolution_precompR_apply {g : G → E'' →L[𝕜] E'} (hf : LocallyIntegrable f μ) (hcg : HasCompactSupport g) (hg : Continuous g) (x₀ : G) (x : E'') : (f ⋆[L.precompR E'', μ] g) x₀ x = (f ⋆[L, μ] fun a => g a x) x₀ := by have := hcg.convolutionExists_right (L.precompR E'' :) hf hg x₀ simp_rw [convolution_def, ContinuousLinearMap.integral_apply this] rfl variable [NormedSpace 𝕜 G] [SFinite μ] [IsAddLeftInvariant μ] /-- Compute the total derivative of `f ⋆ g` if `g` is `C^1` with compact support and `f` is locally integrable. To write down the total derivative as a convolution, we use `ContinuousLinearMap.precompR`. -/ theorem _root_.HasCompactSupport.hasFDerivAt_convolution_right (hcg : HasCompactSupport g) (hf : LocallyIntegrable f μ) (hg : ContDiff 𝕜 1 g) (x₀ : G) : HasFDerivAt (f ⋆[L, μ] g) ((f ⋆[L.precompR G, μ] fderiv 𝕜 g) x₀) x₀ := by rcases hcg.eq_zero_or_finiteDimensional 𝕜 hg.continuous with (rfl \| fin_dim) · have : fderiv 𝕜 (0 : G → E') = 0 := fderiv_const (0 : E') simp only [this, convolution_zero, Pi.zero_apply] exact hasFDerivAt_const (0 : F) x₀ have : ProperSpace G := FiniteDimensional.proper_rclike 𝕜 G set L' := L.precompR G have h1 : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (fun t => L (f t) (g (x - t))) μ := Eventually.of_forall (hf.aestronglyMeasurable.convolution_integrand_snd L hg.continuous.aestronglyMeasurable) have h2 : ∀ x, AEStronglyMeasurable (fun t => L' (f t) (fderiv 𝕜 g (x - t))) μ := hf.aestronglyMeasurable.convolution_integrand_snd L' (hg.continuous_fderiv le_rfl).aestronglyMeasurable have h3 : ∀ x t, HasFDerivAt (fun x => g (x - t)) (fderiv 𝕜 g (x - t)) x := fun x t ↦ by simpa using (hg.differentiable le_rfl).differentiableAt.hasFDerivAt.comp x ((hasFDerivAt_id x).sub (hasFDerivAt_const t x)) let K' := -tsupport (fderiv 𝕜 g) + closedBall x₀ 1 have hK' : IsCompact K' := (hcg.fderiv 𝕜).neg.add (isCompact_closedBall x₀ 1) apply hasFDerivAt_integral_of_dominated_of_fderiv_le zero_lt_one h1 _ (h2 x₀) · filter_upwards with t x hx using (hcg.fderiv 𝕜).convolution_integrand_bound_right L' (hg.continuous_fderiv le_rfl) (ball_subset_closedBall hx) · rw [integrable_indicator_iff hK'.measurableSet] exact ((hf.integrableOn_isCompact hK').norm.const_mul _).mul_const _ · exact Eventually.of_forall fun t x _ => (L _).hasFDerivAt.comp x (h3 x t) · exact hcg.convolutionExists_right L hf hg.continuous x₀ theorem _root_.HasCompactSupport.hasFDerivAt_convolution_left [IsNegInvariant μ] (hcf : HasCompactSupport f) (hf : ContDiff 𝕜 1 f) (hg : LocallyIntegrable g μ) (x₀ : G) : HasFDerivAt (f ⋆[L, μ] g) ((fderiv 𝕜 f ⋆[L.precompL G, μ] g) x₀) x₀ := by simp +singlePass only [← convolution_flip] exact hcf.hasFDerivAt_convolution_right L.flip hg hf x₀ end RCLike section Real /-! The one-variable case -/ variable [RCLike 𝕜] variable [NormedSpace 𝕜 E] variable [NormedSpace 𝕜 E'] variable [NormedSpace ℝ F] [NormedSpace 𝕜 F] variable {f₀ : 𝕜 → E} {g₀ : 𝕜 → E'} variable {n : ℕ∞} variable (L : E →L[𝕜] E' →L[𝕜] F) variable {μ : Measure 𝕜} variable [IsAddLeftInvariant μ] [SFinite μ] theorem _root_.HasCompactSupport.hasDerivAt_convolution_right (hf : LocallyIntegrable f₀ μ) (hcg : HasCompactSupport g₀) (hg : ContDiff 𝕜 1 g₀) (x₀ : 𝕜) : HasDerivAt (f₀ ⋆[L, μ] g₀) ((f₀ ⋆[L, μ] deriv g₀) x₀) x₀ := by convert (hcg.hasFDerivAt_convolution_right L hf hg x₀).hasDerivAt using 1 rw [convolution_precompR_apply L hf (hcg.fderiv 𝕜) (hg.continuous_fderiv le_rfl)] rfl theorem _root_.HasCompactSupport.hasDerivAt_convolution_left [IsNegInvariant μ] (hcf : HasCompactSupport f₀) (hf : ContDiff 𝕜 1 f₀) (hg : LocallyIntegrable g₀ μ) (x₀ : 𝕜) : HasDerivAt (f₀ ⋆[L, μ] g₀) ((deriv f₀ ⋆[L, μ] g₀) x₀) x₀ := by simp +singlePass only [← convolution_flip] exact hcf.hasDerivAt_convolution_right L.flip hg hf x₀ end Real section WithParam variable [RCLike 𝕜] [NormedSpace 𝕜 E] [NormedSpace 𝕜 E'] [NormedSpace 𝕜 E''] [NormedSpace ℝ F] [NormedSpace 𝕜 F] [MeasurableSpace G] [NormedAddCommGroup G] [BorelSpace G] [NormedSpace 𝕜 G] [NormedAddCommGroup P] [NormedSpace 𝕜 P] {μ : Measure G} (L : E →L[𝕜] E' →L[𝕜] F) /-- The derivative of the convolution `f * g` is given by `f * Dg`, when `f` is locally integrable and `g` is `C^1` and compactly supported. Version where `g` depends on an additional parameter in an open subset `s` of a parameter space `P` (and the compact support `k` is independent of the parameter in `s`). -/ theorem hasFDerivAt_convolution_right_with_param {g : P → G → E'} {s : Set P} {k : Set G} (hs : IsOpen s) (hk : IsCompact k) (hgs : ∀ p, ∀ x, p ∈ s → x ∉ k → g p x = 0) (hf : LocallyIntegrable f μ) (hg : ContDiffOn 𝕜 1 (↿g) (s ×ˢ univ)) (q₀ : P × G) (hq₀ : q₀.1 ∈ s) : HasFDerivAt (fun q : P × G => (f ⋆[L, μ] g q.1) q.2) ((f ⋆[L.precompR (P × G), μ] fun x : G => fderiv 𝕜 (↿g) (q₀.1, x)) q₀.2) q₀ := by let g' := fderiv 𝕜 ↿g have A : ∀ p ∈ s, Continuous (g p) := fun p hp ↦ by refine hg.continuousOn.comp_continuous (.prodMk_right _) fun x => ?_ simpa only [prodMk_mem_set_prod_eq, mem_univ, and_true] using hp have A' : ∀ q : P × G, q.1 ∈ s → s ×ˢ univ ∈ 𝓝 q := fun q hq ↦ by apply (hs.prod isOpen_univ).mem_nhds simpa only [mem_prod, mem_univ, and_true] using hq -- The derivative of `g` vanishes away from `k`. have g'_zero : ∀ p x, p ∈ s → x ∉ k → g' (p, x) = 0 := by intro p x hp hx refine (hasFDerivAt_zero_of_eventually_const 0 ?_).fderiv have M2 : kᶜ ∈ 𝓝 x := hk.isClosed.isOpen_compl.mem_nhds hx have M1 : s ∈ 𝓝 p := hs.mem_nhds hp rw [nhds_prod_eq] filter_upwards [prod_mem_prod M1 M2] rintro ⟨p, y⟩ ⟨hp, hy⟩ exact hgs p y hp hy /- We find a small neighborhood of `{q₀.1} × k` on which the derivative is uniformly bounded. This follows from the continuity at all points of the compact set `k`. -/ obtain ⟨ε, C, εpos, h₀ε, hε⟩ : ∃ ε C, 0 < ε ∧ ball q₀.1 ε ⊆ s ∧ ∀ p x, ‖p - q₀.1‖ < ε → ‖g' (p, x)‖ ≤ C := by have A : IsCompact ({q₀.1} ×ˢ k) := isCompact_singleton.prod hk obtain ⟨t, kt, t_open, ht⟩ : ∃ t, {q₀.1} ×ˢ k ⊆ t ∧ IsOpen t ∧ IsBounded (g' '' t) := by have B : ContinuousOn g' (s ×ˢ univ) := hg.continuousOn_fderiv_of_isOpen (hs.prod isOpen_univ) le_rfl apply exists_isOpen_isBounded_image_of_isCompact_of_continuousOn A (hs.prod isOpen_univ) _ B simp only [prod_subset_prod_iff, hq₀, singleton_subset_iff, subset_univ, and_self_iff, true_or] obtain ⟨ε, εpos, hε, h'ε⟩ : ∃ ε : ℝ, 0 < ε ∧ thickening ε ({q₀.fst} ×ˢ k) ⊆ t ∧ ball q₀.1 ε ⊆ s := by obtain ⟨ε, εpos, hε⟩ : ∃ ε : ℝ, 0 < ε ∧ thickening ε (({q₀.fst} : Set P) ×ˢ k) ⊆ t := A.exists_thickening_subset_open t_open kt obtain ⟨δ, δpos, hδ⟩ : ∃ δ : ℝ, 0 < δ ∧ ball q₀.1 δ ⊆ s := Metric.isOpen_iff.1 hs _ hq₀ refine ⟨min ε δ, lt_min εpos δpos, ?_, ?_⟩ · exact Subset.trans (thickening_mono (min_le_left _ _) _) hε · exact Subset.trans (ball_subset_ball (min_le_right _ _)) hδ obtain ⟨C, Cpos, hC⟩ : ∃ C, 0 < C ∧ g' '' t ⊆ closedBall 0 C := ht.subset_closedBall_lt 0 0 refine ⟨ε, C, εpos, h'ε, fun p x hp => ?_⟩ have hps : p ∈ s := h'ε (mem_ball_iff_norm.2 hp) by_cases hx : x ∈ k · have H : (p, x) ∈ t := by apply hε refine mem_thickening_iff.2 ⟨(q₀.1, x), ?_, ?_⟩ · simp only [hx, singleton_prod, mem_image, Prod.mk_inj, eq_self_iff_true, true_and, exists_eq_right] · rw [← dist_eq_norm] at hp	simpa only [Prod.dist_eq, εpos, dist_self, max_lt_iff, and_true] using hp have : g' (p, x) ∈ closedBall (0 : P × G →L[𝕜] E') C := hC (mem_image_of_mem _ H) rwa [mem_closedBall_zero_iff] at this · have : g' (p, x) = 0 := g'_zero _ _ hps hx rw [this]	Mathlib/Analysis/Convolution.lean	1,086	1,090
/- Copyright (c) 2016 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Leonardo de Moura, Mario Carneiro, Johannes Hölzl -/ import Mathlib.Algebra.Order.Monoid.Unbundled.WithTop import Mathlib.Algebra.Order.Monoid.Canonical.Defs /-! # Adjoining top/bottom elements to ordered monoids. -/ universe u variable {α : Type u} open Function namespace WithTop instance isOrderedAddMonoid [AddCommMonoid α] [PartialOrder α] [IsOrderedAddMonoid α] : IsOrderedAddMonoid (WithTop α) where add_le_add_left _ _ := add_le_add_left instance canonicallyOrderedAdd [Add α] [Preorder α] [CanonicallyOrderedAdd α] : CanonicallyOrderedAdd (WithTop α) := { WithTop.existsAddOfLE with le_self_add := fun a b => match a, b with \| ⊤, ⊤ => le_rfl \| (a : α), ⊤ => le_top \| (a : α), (b : α) => WithTop.coe_le_coe.2 le_self_add \| ⊤, (b : α) => le_rfl } end WithTop namespace WithBot instance isOrderedAddMonoid [AddCommMonoid α] [PartialOrder α] [IsOrderedAddMonoid α] : IsOrderedAddMonoid (WithBot α) := { add_le_add_left := fun _ _ h c => add_le_add_left h c } protected theorem le_self_add [Add α] [LE α] [CanonicallyOrderedAdd α] {x : WithBot α} (hx : x ≠ ⊥) (y : WithBot α) : y ≤ y + x := by induction x · simp at hx induction y · simp · rw [← WithBot.coe_add, WithBot.coe_le_coe] exact le_self_add protected theorem le_add_self [AddCommMagma α] [LE α] [CanonicallyOrderedAdd α] {x : WithBot α} (hx : x ≠ ⊥) (y : WithBot α) : y ≤ x + y := by induction x · simp at hx induction y · simp · rw [← WithBot.coe_add, WithBot.coe_le_coe] exact le_add_self end WithBot		Mathlib/Algebra/Order/Monoid/WithTop.lean	164	170
/- Copyright (c) 2021 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson -/ import Mathlib.Data.SetLike.Basic import Mathlib.ModelTheory.Semantics /-! # Definable Sets This file defines what it means for a set over a first-order structure to be definable. ## Main Definitions - `Set.Definable` is defined so that `A.Definable L s` indicates that the set `s` of a finite cartesian power of `M` is definable with parameters in `A`. - `Set.Definable₁` is defined so that `A.Definable₁ L s` indicates that `(s : Set M)` is definable with parameters in `A`. - `Set.Definable₂` is defined so that `A.Definable₂ L s` indicates that `(s : Set (M × M))` is definable with parameters in `A`. - A `FirstOrder.Language.DefinableSet` is defined so that `L.DefinableSet A α` is the boolean algebra of subsets of `α → M` defined by formulas with parameters in `A`. ## Main Results - `L.DefinableSet A α` forms a `BooleanAlgebra` - `Set.Definable.image_comp` shows that definability is closed under projections in finite dimensions. -/ universe u v w u₁ namespace Set variable {M : Type w} (A : Set M) (L : FirstOrder.Language.{u, v}) [L.Structure M] open FirstOrder FirstOrder.Language FirstOrder.Language.Structure variable {α : Type u₁} {β : Type} /-- A subset of a finite Cartesian product of a structure is definable over a set `A` when membership in the set is given by a first-order formula with parameters from `A`. -/ def Definable (s : Set (α → M)) : Prop := ∃ φ : L[[A]].Formula α, s = setOf φ.Realize variable {L} {A} {B : Set M} {s : Set (α → M)} theorem Definable.map_expansion {L' : FirstOrder.Language} [L'.Structure M] (h : A.Definable L s) (φ : L →ᴸ L') [φ.IsExpansionOn M] : A.Definable L' s := by obtain ⟨ψ, rfl⟩ := h refine ⟨(φ.addConstants A).onFormula ψ, ?_⟩ ext x simp only [mem_setOf_eq, LHom.realize_onFormula] theorem definable_iff_exists_formula_sum : A.Definable L s ↔ ∃ φ : L.Formula (A ⊕ α), s = {v \| φ.Realize (Sum.elim (↑) v)} := by rw [Definable, Equiv.exists_congr_left (BoundedFormula.constantsVarsEquiv)] refine exists_congr (fun φ => iff_iff_eq.2 (congr_arg (s = ·) ?_)) ext simp only [BoundedFormula.constantsVarsEquiv, constantsOn, BoundedFormula.mapTermRelEquiv_symm_apply, mem_setOf_eq, Formula.Realize] refine BoundedFormula.realize_mapTermRel_id ?_ (fun _ _ _ => rfl) intros simp only [Term.constantsVarsEquivLeft_symm_apply, Term.realize_varsToConstants, coe_con, Term.realize_relabel] congr ext a rcases a with (_ \| _) \| _ <;> rfl theorem empty_definable_iff : (∅ : Set M).Definable L s ↔ ∃ φ : L.Formula α, s = setOf φ.Realize := by rw [Definable, Equiv.exists_congr_left (LEquiv.addEmptyConstants L (∅ : Set M)).onFormula] simp theorem definable_iff_empty_definable_with_params : A.Definable L s ↔ (∅ : Set M).Definable (L[[A]]) s := empty_definable_iff.symm theorem Definable.mono (hAs : A.Definable L s) (hAB : A ⊆ B) : B.Definable L s := by rw [definable_iff_empty_definable_with_params] at exact hAs.map_expansion (L.lhomWithConstantsMap (Set.inclusion hAB)) @[simp] theorem definable_empty : A.Definable L (∅ : Set (α → M)) := ⟨⊥, by ext simp⟩ @[simp] theorem definable_univ : A.Definable L (univ : Set (α → M)) := ⟨⊤, by ext simp⟩ @[simp] theorem Definable.inter {f g : Set (α → M)} (hf : A.Definable L f) (hg : A.Definable L g) : A.Definable L (f ∩ g) := by rcases hf with ⟨φ, rfl⟩ rcases hg with ⟨θ, rfl⟩ refine ⟨φ ⊓ θ, ?_⟩ ext simp @[simp] theorem Definable.union {f g : Set (α → M)} (hf : A.Definable L f) (hg : A.Definable L g) : A.Definable L (f ∪ g) := by rcases hf with ⟨φ, hφ⟩ rcases hg with ⟨θ, hθ⟩ refine ⟨φ ⊔ θ, ?_⟩ ext rw [hφ, hθ, mem_setOf_eq, Formula.realize_sup, mem_union, mem_setOf_eq, mem_setOf_eq] theorem definable_finset_inf {ι : Type} {f : ι → Set (α → M)} (hf : ∀ i, A.Definable L (f i)) (s : Finset ι) : A.Definable L (s.inf f) := by classical refine Finset.induction definable_univ (fun i s _ h => ?_) s rw [Finset.inf_insert] exact (hf i).inter h theorem definable_finset_sup {ι : Type} {f : ι → Set (α → M)} (hf : ∀ i, A.Definable L (f i)) (s : Finset ι) : A.Definable L (s.sup f) := by classical refine Finset.induction definable_empty (fun i s _ h => ?_) s rw [Finset.sup_insert] exact (hf i).union h theorem definable_finset_biInter {ι : Type} {f : ι → Set (α → M)} (hf : ∀ i, A.Definable L (f i)) (s : Finset ι) : A.Definable L (⋂ i ∈ s, f i) := by rw [← Finset.inf_set_eq_iInter] exact definable_finset_inf hf s theorem definable_finset_biUnion {ι : Type} {f : ι → Set (α → M)} (hf : ∀ i, A.Definable L (f i)) (s : Finset ι) : A.Definable L (⋃ i ∈ s, f i) := by rw [← Finset.sup_set_eq_biUnion] exact definable_finset_sup hf s @[simp] theorem Definable.compl {s : Set (α → M)} (hf : A.Definable L s) : A.Definable L sᶜ := by rcases hf with ⟨φ, hφ⟩ refine ⟨φ.not, ?_⟩ ext v rw [hφ, compl_setOf, mem_setOf, mem_setOf, Formula.realize_not] @[simp] theorem Definable.sdiff {s t : Set (α → M)} (hs : A.Definable L s) (ht : A.Definable L t) : A.Definable L (s \ t) := hs.inter ht.compl @[simp] lemma Definable.himp {s t : Set (α → M)} (hs : A.Definable L s) (ht : A.Definable L t) : A.Definable L (s ⇨ t) := by rw [himp_eq]; exact ht.union hs.compl theorem Definable.preimage_comp (f : α → β) {s : Set (α → M)} (h : A.Definable L s) : A.Definable L ((fun g : β → M => g ∘ f) ⁻¹' s) := by obtain ⟨φ, rfl⟩ := h refine ⟨φ.relabel f, ?_⟩ ext simp only [Set.preimage_setOf_eq, mem_setOf_eq, Formula.realize_relabel] theorem Definable.image_comp_equiv {s : Set (β → M)} (h : A.Definable L s) (f : α ≃ β) : A.Definable L ((fun g : β → M => g ∘ f) '' s) := by refine (congr rfl ?_).mp (h.preimage_comp f.symm) rw [image_eq_preimage_of_inverse] · intro i ext b simp only [Function.comp_apply, Equiv.apply_symm_apply] · intro i ext a simp theorem definable_iff_finitely_definable : A.Definable L s ↔ ∃ (A0 : Finset M), (A0 : Set M) ⊆ A ∧ (A0 : Set M).Definable L s := by classical constructor · simp only [definable_iff_exists_formula_sum] rintro ⟨φ, rfl⟩ let A0 := (φ.freeVarFinset.toLeft).image Subtype.val refine ⟨A0, by simp [A0], (φ.restrictFreeVar <\| fun x => Sum.casesOn x.1 (fun x hx => Sum.inl ⟨x, by simp [A0, hx]⟩) (fun x _ => Sum.inr x) x.2), ?_⟩ ext simp only [Formula.Realize, mem_setOf_eq, Finset.coe_sort_coe] exact iff_comm.1 <\| BoundedFormula.realize_restrictFreeVar _ (by simp) · rintro ⟨A0, hA0, hd⟩ exact Definable.mono hd hA0 /-- This lemma is only intended as a helper for `Definable.image_comp`. -/ theorem Definable.image_comp_sumInl_fin (m : ℕ) {s : Set (Sum α (Fin m) → M)} (h : A.Definable L s) : A.Definable L ((fun g : Sum α (Fin m) → M => g ∘ Sum.inl) '' s) := by obtain ⟨φ, rfl⟩ := h refine ⟨(BoundedFormula.relabel id φ).exs, ?_⟩ ext x simp only [Set.mem_image, mem_setOf_eq, BoundedFormula.realize_exs, BoundedFormula.realize_relabel, Function.comp_id, Fin.castAdd_zero, Fin.cast_refl] constructor · rintro ⟨y, hy, rfl⟩ exact ⟨y ∘ Sum.inr, (congr (congr rfl (Sum.elim_comp_inl_inr y).symm) (funext finZeroElim)).mp hy⟩ · rintro ⟨y, hy⟩ exact ⟨Sum.elim x y, (congr rfl (funext finZeroElim)).mp hy, Sum.elim_comp_inl _ _⟩ @[deprecated (since := "2025-02-21")] alias Definable.image_comp_sum_inl_fin := Definable.image_comp_sumInl_fin /-- Shows that definability is closed under finite projections. -/ theorem Definable.image_comp_embedding {s : Set (β → M)} (h : A.Definable L s) (f : α ↪ β) [Finite β] : A.Definable L ((fun g : β → M => g ∘ f) '' s) := by classical cases nonempty_fintype β refine (congr rfl (ext fun x => ?_)).mp (((h.image_comp_equiv (Equiv.Set.sumCompl (range f))).image_comp_equiv (Equiv.sumCongr (Equiv.ofInjective f f.injective) (Fintype.equivFin (↥(range f)ᶜ)).symm)).image_comp_sumInl_fin _) simp only [mem_preimage, mem_image, exists_exists_and_eq_and] refine exists_congr fun y => and_congr_right fun _ => Eq.congr_left (funext fun a => ?_) simp /-- Shows that definability is closed under finite projections. -/ theorem Definable.image_comp {s : Set (β → M)} (h : A.Definable L s) (f : α → β) [Finite α] [Finite β] : A.Definable L ((fun g : β → M => g ∘ f) '' s) := by classical cases nonempty_fintype α cases nonempty_fintype β have h := (((h.image_comp_equiv (Equiv.Set.sumCompl (range f))).image_comp_equiv (Equiv.sumCongr (_root_.Equiv.refl _) (Fintype.equivFin _).symm)).image_comp_sumInl_fin _).preimage_comp (rangeSplitting f) have h' : A.Definable L { x : α → M \| ∀ a, x a = x (rangeSplitting f (rangeFactorization f a)) } := by have h' : ∀ a, A.Definable L { x : α → M \| x a = x (rangeSplitting f (rangeFactorization f a)) } := by refine fun a => ⟨(var a).equal (var (rangeSplitting f (rangeFactorization f a))), ext ?_⟩ simp refine (congr rfl (ext ?_)).mp (definable_finset_biInter h' Finset.univ) simp refine (congr rfl (ext fun x => ?_)).mp (h.inter h') simp only [Equiv.coe_trans, mem_inter_iff, mem_preimage, mem_image, exists_exists_and_eq_and, mem_setOf_eq] constructor	· rintro ⟨⟨y, ys, hy⟩, hx⟩ refine ⟨y, ys, ?_⟩ ext a rw [hx a, ← Function.comp_apply (f := x), ← hy] simp · rintro ⟨y, ys, rfl⟩ refine ⟨⟨y, ys, ?_⟩, fun a => ?_⟩ · ext simp [Set.apply_rangeSplitting f] · rw [Function.comp_apply, Function.comp_apply, apply_rangeSplitting f, rangeFactorization_coe] variable (L A) /-- A 1-dimensional version of `Definable`, for `Set M`. -/ def Definable₁ (s : Set M) : Prop := A.Definable L { x : Fin 1 → M \| x 0 ∈ s } /-- A 2-dimensional version of `Definable`, for `Set (M × M)`. -/ def Definable₂ (s : Set (M × M)) : Prop := A.Definable L { x : Fin 2 → M \| (x 0, x 1) ∈ s } end Set namespace FirstOrder namespace Language open Set variable (L : FirstOrder.Language.{u, v}) {M : Type w} [L.Structure M] (A : Set M) (α : Type u₁) /-- Definable sets are subsets of finite Cartesian products of a structure such that membership is given by a first-order formula. -/	Mathlib/ModelTheory/Definability.lean	246	279
/- 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] convert Real.sInf_empty exact eq_empty_iff_forall_not_mem.2 fun r hr => hr.2.elim (ne_of_gt hr.1) hx @[simp] theorem gauge_empty : gauge (∅ : Set E) = 0 := by ext simp only [gauge_def', Real.sInf_empty, mem_empty_iff_false, Pi.zero_apply, sep_false] theorem gauge_of_subset_zero (h : s ⊆ 0) : gauge s = 0 := by obtain rfl \| rfl := subset_singleton_iff_eq.1 h exacts [gauge_empty, gauge_zero'] /-- The gauge is always nonnegative. -/ theorem gauge_nonneg (x : E) : 0 ≤ gauge s x := Real.sInf_nonneg fun _ hx => hx.1.le theorem gauge_neg (symmetric : ∀ x ∈ s, -x ∈ s) (x : E) : gauge s (-x) = gauge s x := by have : ∀ x, -x ∈ s ↔ x ∈ s := fun x => ⟨fun h => by simpa using symmetric _ h, symmetric x⟩ simp_rw [gauge_def', smul_neg, this] theorem gauge_neg_set_neg (x : E) : gauge (-s) (-x) = gauge s x := by simp_rw [gauge_def', smul_neg, neg_mem_neg] theorem gauge_neg_set_eq_gauge_neg (x : E) : gauge (-s) x = gauge s (-x) := by rw [← gauge_neg_set_neg, neg_neg] theorem gauge_le_of_mem (ha : 0 ≤ a) (hx : x ∈ a • s) : gauge s x ≤ a := by obtain rfl \| ha' := ha.eq_or_lt · rw [mem_singleton_iff.1 (zero_smul_set_subset _ hx), gauge_zero] · exact csInf_le gauge_set_bddBelow ⟨ha', hx⟩ theorem gauge_le_eq (hs₁ : Convex ℝ s) (hs₀ : (0 : E) ∈ s) (hs₂ : Absorbent ℝ s) (ha : 0 ≤ a) : { x \| gauge s x ≤ a } = ⋂ (r : ℝ) (_ : a < r), r • s := by ext x simp_rw [Set.mem_iInter, Set.mem_setOf_eq] refine ⟨fun h r hr => ?_, fun h => le_of_forall_pos_lt_add fun ε hε => ?_⟩ · have hr' := ha.trans_lt hr rw [mem_smul_set_iff_inv_smul_mem₀ hr'.ne'] obtain ⟨δ, δ_pos, hδr, hδ⟩ := exists_lt_of_gauge_lt hs₂ (h.trans_lt hr) suffices (r⁻¹ δ) • δ⁻¹ • x ∈ s by rwa [smul_smul, mul_inv_cancel_right₀ δ_pos.ne'] at this rw [mem_smul_set_iff_inv_smul_mem₀ δ_pos.ne'] at hδ refine hs₁.smul_mem_of_zero_mem hs₀ hδ ⟨by positivity, ?_⟩ rw [inv_mul_le_iff₀ hr', mul_one] exact hδr.le · have hε' := (lt_add_iff_pos_right a).2 (half_pos hε) exact (gauge_le_of_mem (ha.trans hε'.le) <\| h _ hε').trans_lt (add_lt_add_left (half_lt_self hε) _) theorem gauge_lt_eq' (absorbs : Absorbent ℝ s) (a : ℝ) : { x \| gauge s x < a } = ⋃ (r : ℝ) (_ : 0 < r) (_ : r < a), r • s := by ext simp_rw [mem_setOf, mem_iUnion, exists_prop] exact ⟨exists_lt_of_gauge_lt absorbs, fun ⟨r, hr₀, hr₁, hx⟩ => (gauge_le_of_mem hr₀.le hx).trans_lt hr₁⟩ theorem gauge_lt_eq (absorbs : Absorbent ℝ s) (a : ℝ) : { x \| gauge s x < a } = ⋃ r ∈ Set.Ioo 0 (a : ℝ), r • s := by ext simp_rw [mem_setOf, mem_iUnion, exists_prop, mem_Ioo, and_assoc] exact ⟨exists_lt_of_gauge_lt absorbs, fun ⟨r, hr₀, hr₁, hx⟩ => (gauge_le_of_mem hr₀.le hx).trans_lt hr₁⟩ theorem mem_openSegment_of_gauge_lt_one (absorbs : Absorbent ℝ s) (hgauge : gauge s x < 1) : ∃ y ∈ s, x ∈ openSegment ℝ 0 y := by rcases exists_lt_of_gauge_lt absorbs hgauge with ⟨r, hr₀, hr₁, y, hy, rfl⟩ refine ⟨y, hy, 1 - r, r, ?_⟩ simp [] theorem gauge_lt_one_subset_self (hs : Convex ℝ s) (h₀ : (0 : E) ∈ s) (absorbs : Absorbent ℝ s) : { x \| gauge s x < 1 } ⊆ s := fun _x hx ↦ let ⟨_y, hys, hx⟩ := mem_openSegment_of_gauge_lt_one absorbs hx hs.openSegment_subset h₀ hys hx theorem gauge_le_one_of_mem {x : E} (hx : x ∈ s) : gauge s x ≤ 1 := gauge_le_of_mem zero_le_one <\| by rwa [one_smul] /-- Gauge is subadditive. -/ theorem gauge_add_le (hs : Convex ℝ s) (absorbs : Absorbent ℝ s) (x y : E) : gauge s (x + y) ≤ gauge s x + gauge s y := by refine le_of_forall_pos_lt_add fun ε hε => ?_ obtain ⟨a, ha, ha', x, hx, rfl⟩ := exists_lt_of_gauge_lt absorbs (lt_add_of_pos_right (gauge s x) (half_pos hε)) obtain ⟨b, hb, hb', y, hy, rfl⟩ := exists_lt_of_gauge_lt absorbs (lt_add_of_pos_right (gauge s y) (half_pos hε)) calc gauge s (a • x + b • y) ≤ a + b := gauge_le_of_mem (by positivity) <\| by rw [hs.add_smul ha.le hb.le] exact add_mem_add (smul_mem_smul_set hx) (smul_mem_smul_set hy) _ < gauge s (a • x) + gauge s (b • y) + ε := by linarith theorem self_subset_gauge_le_one : s ⊆ { x \| gauge s x ≤ 1 } := fun _ => gauge_le_one_of_mem theorem Convex.gauge_le (hs : Convex ℝ s) (h₀ : (0 : E) ∈ s) (absorbs : Absorbent ℝ s) (a : ℝ) : Convex ℝ { x \| gauge s x ≤ a } := by by_cases ha : 0 ≤ a · rw [gauge_le_eq hs h₀ absorbs ha] exact convex_iInter fun i => convex_iInter fun _ => hs.smul _ · convert convex_empty (𝕜 := ℝ) exact eq_empty_iff_forall_not_mem.2 fun x hx => ha <\| (gauge_nonneg _).trans hx theorem Balanced.starConvex (hs : Balanced ℝ s) : StarConvex ℝ 0 s := starConvex_zero_iff.2 fun _ hx a ha₀ ha₁ => hs _ (by rwa [Real.norm_of_nonneg ha₀]) (smul_mem_smul_set hx) theorem le_gauge_of_not_mem (hs₀ : StarConvex ℝ 0 s) (hs₂ : Absorbs ℝ s {x}) (hx : x ∉ a • s) : a ≤ gauge s x := by rw [starConvex_zero_iff] at hs₀ obtain ⟨r, hr, h⟩ := hs₂.exists_pos refine le_csInf ⟨r, hr, singleton_subset_iff.1 <\| h _ (Real.norm_of_nonneg hr.le).ge⟩ ?_ rintro b ⟨hb, x, hx', rfl⟩ refine not_lt.1 fun hba => hx ?_ have ha := hb.trans hba refine ⟨(a⁻¹ b) • x, hs₀ hx' (by positivity) ?_, ?_⟩ · rw [← div_eq_inv_mul] exact div_le_one_of_le₀ hba.le ha.le · dsimp only rw [← mul_smul, mul_inv_cancel_left₀ ha.ne'] theorem one_le_gauge_of_not_mem (hs₁ : StarConvex ℝ 0 s) (hs₂ : Absorbs ℝ s {x}) (hx : x ∉ s) : 1 ≤ gauge s x := le_gauge_of_not_mem hs₁ hs₂ <\| by rwa [one_smul] section LinearOrderedField variable {α : Type} [Field α] [LinearOrder α] [IsStrictOrderedRing α] [MulActionWithZero α ℝ] [OrderedSMul α ℝ] theorem gauge_smul_of_nonneg [MulActionWithZero α E] [IsScalarTower α ℝ (Set E)] {s : Set E} {a : α} (ha : 0 ≤ a) (x : E) : gauge s (a • x) = a • gauge s x := by obtain rfl \| ha' := ha.eq_or_lt · rw [zero_smul, gauge_zero, zero_smul] rw [gauge_def', gauge_def', ← Real.sInf_smul_of_nonneg ha] congr 1 ext r simp_rw [Set.mem_smul_set, Set.mem_sep_iff] constructor · rintro ⟨hr, hx⟩ simp_rw [mem_Ioi] at hr ⊢ rw [← mem_smul_set_iff_inv_smul_mem₀ hr.ne'] at hx have := smul_pos (inv_pos.2 ha') hr refine ⟨a⁻¹ • r, ⟨this, ?_⟩, smul_inv_smul₀ ha'.ne' _⟩ rwa [← mem_smul_set_iff_inv_smul_mem₀ this.ne', smul_assoc, mem_smul_set_iff_inv_smul_mem₀ (inv_ne_zero ha'.ne'), inv_inv] · rintro ⟨r, ⟨hr, hx⟩, rfl⟩ rw [mem_Ioi] at hr ⊢ rw [← mem_smul_set_iff_inv_smul_mem₀ hr.ne'] at hx have := smul_pos ha' hr refine ⟨this, ?_⟩ rw [← mem_smul_set_iff_inv_smul_mem₀ this.ne', smul_assoc] exact smul_mem_smul_set hx theorem gauge_smul_left_of_nonneg [MulActionWithZero α E] [SMulCommClass α ℝ ℝ] [IsScalarTower α ℝ ℝ] [IsScalarTower α ℝ E] {s : Set E} {a : α} (ha : 0 ≤ a) : gauge (a • s) = a⁻¹ • gauge s := by obtain rfl \| ha' := ha.eq_or_lt · rw [inv_zero, zero_smul, gauge_of_subset_zero (zero_smul_set_subset _)] ext x rw [gauge_def', Pi.smul_apply, gauge_def', ← Real.sInf_smul_of_nonneg (inv_nonneg.2 ha)] congr 1 ext r simp_rw [Set.mem_smul_set, Set.mem_sep_iff] constructor · rintro ⟨hr, y, hy, h⟩ simp_rw [mem_Ioi] at hr ⊢ refine ⟨a • r, ⟨smul_pos ha' hr, ?_⟩, inv_smul_smul₀ ha'.ne' _⟩ rwa [smul_inv₀, smul_assoc, ← h, inv_smul_smul₀ ha'.ne'] · rintro ⟨r, ⟨hr, hx⟩, rfl⟩ rw [mem_Ioi] at hr ⊢ refine ⟨smul_pos (inv_pos.2 ha') hr, r⁻¹ • x, hx, ?_⟩ rw [smul_inv₀, smul_assoc, inv_inv] theorem gauge_smul_left [Module α E] [SMulCommClass α ℝ ℝ] [IsScalarTower α ℝ ℝ] [IsScalarTower α ℝ E] {s : Set E} (symmetric : ∀ x ∈ s, -x ∈ s) (a : α) : gauge (a • s) = \|a\|⁻¹ • gauge s := by rw [← gauge_smul_left_of_nonneg (abs_nonneg a)] obtain h \| h := abs_choice a · rw [h] · rw [h, Set.neg_smul_set, ← Set.smul_set_neg] -- Porting note: was congr apply congr_arg apply congr_arg ext y refine ⟨symmetric _, fun hy => ?_⟩ rw [← neg_neg y] exact symmetric _ hy end LinearOrderedField section RCLike variable [RCLike 𝕜] [Module 𝕜 E] [IsScalarTower ℝ 𝕜 E] theorem gauge_norm_smul (hs : Balanced 𝕜 s) (r : 𝕜) (x : E) : gauge s (‖r‖ • x) = gauge s (r • x) := by unfold gauge congr with θ rw [@RCLike.real_smul_eq_coe_smul 𝕜] refine and_congr_right fun hθ => (hs.smul _).smul_mem_iff ?_ rw [RCLike.norm_ofReal, abs_norm] /-- If `s` is balanced, then the Minkowski functional is ℂ-homogeneous. -/ theorem gauge_smul (hs : Balanced 𝕜 s) (r : 𝕜) (x : E) : gauge s (r • x) = ‖r‖ gauge s x := by rw [← smul_eq_mul, ← gauge_smul_of_nonneg (norm_nonneg r), gauge_norm_smul hs] end RCLike open Filter section TopologicalSpace variable [TopologicalSpace E] theorem comap_gauge_nhds_zero_le (ha : Absorbent ℝ s) (hb : Bornology.IsVonNBounded ℝ s) : comap (gauge s) (𝓝 0) ≤ 𝓝 0 := fun u hu ↦ by rcases (hb hu).exists_pos with ⟨r, hr₀, hr⟩ filter_upwards [preimage_mem_comap (gt_mem_nhds (inv_pos.2 hr₀))] with x (hx : gauge s x < r⁻¹) rcases exists_lt_of_gauge_lt ha hx with ⟨c, hc₀, hcr, y, hy, rfl⟩ have hrc := (lt_inv_comm₀ hr₀ hc₀).2 hcr rcases hr c⁻¹ (hrc.le.trans (le_abs_self _)) hy with ⟨z, hz, rfl⟩ simpa only [smul_inv_smul₀ hc₀.ne'] variable [T1Space E] theorem gauge_eq_zero (hs : Absorbent ℝ s) (hb : Bornology.IsVonNBounded ℝ s) : gauge s x = 0 ↔ x = 0 := by refine ⟨fun h₀ ↦ by_contra fun (hne : x ≠ 0) ↦ ?_, fun h ↦ h.symm ▸ gauge_zero⟩ have : {x}ᶜ ∈ comap (gauge s) (𝓝 0) := comap_gauge_nhds_zero_le hs hb (isOpen_compl_singleton.mem_nhds hne.symm) rcases ((nhds_basis_zero_abs_lt _).comap _).mem_iff.1 this with ⟨r, hr₀, hr⟩ exact hr (by simpa [h₀]) rfl theorem gauge_pos (hs : Absorbent ℝ s) (hb : Bornology.IsVonNBounded ℝ s) : 0 < gauge s x ↔ x ≠ 0 := by simp only [(gauge_nonneg _).gt_iff_ne, Ne, gauge_eq_zero hs hb] end TopologicalSpace section ContinuousSMul variable [TopologicalSpace E] [ContinuousSMul ℝ E] open Filter in theorem interior_subset_gauge_lt_one (s : Set E) : interior s ⊆ { x \| gauge s x < 1 } := by intro x hx have H₁ : Tendsto (fun r : ℝ ↦ r⁻¹ • x) (𝓝[<] 1) (𝓝 ((1 : ℝ)⁻¹ • x)) := ((tendsto_id.inv₀ one_ne_zero).smul tendsto_const_nhds).mono_left inf_le_left rw [inv_one, one_smul] at H₁ have H₂ : ∀ᶠ r in 𝓝[<] (1 : ℝ), x ∈ r • s ∧ 0 < r ∧ r < 1 := by filter_upwards [H₁ (mem_interior_iff_mem_nhds.1 hx), Ioo_mem_nhdsLT one_pos] with r h₁ h₂ exact ⟨(mem_smul_set_iff_inv_smul_mem₀ h₂.1.ne' _ _).2 h₁, h₂⟩ rcases H₂.exists with ⟨r, hxr, hr₀, hr₁⟩ exact (gauge_le_of_mem hr₀.le hxr).trans_lt hr₁ theorem gauge_lt_one_eq_self_of_isOpen (hs₁ : Convex ℝ s) (hs₀ : (0 : E) ∈ s) (hs₂ : IsOpen s) : { x \| gauge s x < 1 } = s := by refine (gauge_lt_one_subset_self hs₁ ‹_› <\| absorbent_nhds_zero <\| hs₂.mem_nhds hs₀).antisymm ?_ convert interior_subset_gauge_lt_one s exact hs₂.interior_eq.symm theorem gauge_lt_one_of_mem_of_isOpen (hs₂ : IsOpen s) {x : E} (hx : x ∈ s) : gauge s x < 1 := interior_subset_gauge_lt_one s <\| by rwa [hs₂.interior_eq] theorem gauge_lt_of_mem_smul (x : E) (ε : ℝ) (hε : 0 < ε) (hs₂ : IsOpen s) (hx : x ∈ ε • s) : gauge s x < ε := by have : ε⁻¹ • x ∈ s := by rwa [← mem_smul_set_iff_inv_smul_mem₀ hε.ne'] have h_gauge_lt := gauge_lt_one_of_mem_of_isOpen hs₂ this rwa [gauge_smul_of_nonneg (inv_nonneg.2 hε.le), smul_eq_mul, inv_mul_lt_iff₀ hε, mul_one] at h_gauge_lt theorem mem_closure_of_gauge_le_one (hc : Convex ℝ s) (hs₀ : 0 ∈ s) (ha : Absorbent ℝ s) (h : gauge s x ≤ 1) : x ∈ closure s := by have : ∀ᶠ r : ℝ in 𝓝[<] 1, r • x ∈ s := by filter_upwards [Ico_mem_nhdsLT one_pos] with r ⟨hr₀, hr₁⟩ apply gauge_lt_one_subset_self hc hs₀ ha rw [mem_setOf_eq, gauge_smul_of_nonneg hr₀] exact mul_lt_one_of_nonneg_of_lt_one_left hr₀ hr₁ h refine mem_closure_of_tendsto ?_ this exact Filter.Tendsto.mono_left (Continuous.tendsto' (by fun_prop) _ _ (one_smul _ _)) inf_le_left theorem mem_frontier_of_gauge_eq_one (hc : Convex ℝ s) (hs₀ : 0 ∈ s) (ha : Absorbent ℝ s) (h : gauge s x = 1) : x ∈ frontier s := ⟨mem_closure_of_gauge_le_one hc hs₀ ha h.le, fun h' ↦ (interior_subset_gauge_lt_one s h').out.ne h⟩ theorem tendsto_gauge_nhds_zero_nhdsGE (hs : s ∈ 𝓝 0) : Tendsto (gauge s) (𝓝 0) (𝓝[≥] 0) := by refine nhdsGE_basis_Icc.tendsto_right_iff.2 fun ε hε ↦ ?_ rw [← set_smul_mem_nhds_zero_iff hε.ne'] at hs filter_upwards [hs] with x hx exact ⟨gauge_nonneg _, gauge_le_of_mem hε.le hx⟩ @[deprecated (since := "2025-03-02")] alias tendsto_gauge_nhds_zero' := tendsto_gauge_nhds_zero_nhdsGE theorem tendsto_gauge_nhds_zero (hs : s ∈ 𝓝 0) : Tendsto (gauge s) (𝓝 0) (𝓝 0) := (tendsto_gauge_nhds_zero_nhdsGE hs).mono_right inf_le_left /-- If `s` is a neighborhood of the origin, then `gauge s` is continuous at the origin. See also `continuousAt_gauge`. -/ theorem continuousAt_gauge_zero (hs : s ∈ 𝓝 0) : ContinuousAt (gauge s) 0 := by rw [ContinuousAt, gauge_zero] exact tendsto_gauge_nhds_zero hs theorem comap_gauge_nhds_zero (hb : Bornology.IsVonNBounded ℝ s) (h₀ : s ∈ 𝓝 0) : comap (gauge s) (𝓝 0) = 𝓝 0 := (comap_gauge_nhds_zero_le (absorbent_nhds_zero h₀) hb).antisymm (tendsto_gauge_nhds_zero h₀).le_comap end ContinuousSMul section TopologicalVectorSpace open Filter variable [TopologicalSpace E] [IsTopologicalAddGroup E] [ContinuousSMul ℝ E] /-- If `s` is a convex neighborhood of the origin in a topological real vector space, then `gauge s` is continuous. If the ambient space is a normed space, then `gauge s` is Lipschitz continuous, see `Convex.lipschitz_gauge`. -/ theorem continuousAt_gauge (hc : Convex ℝ s) (hs₀ : s ∈ 𝓝 0) : ContinuousAt (gauge s) x := by have ha : Absorbent ℝ s := absorbent_nhds_zero hs₀ refine (nhds_basis_Icc_pos _).tendsto_right_iff.2 fun ε hε₀ ↦ ?_ rw [← map_add_left_nhds_zero, eventually_map] have : ε • s ∩ -(ε • s) ∈ 𝓝 0 := inter_mem ((set_smul_mem_nhds_zero_iff hε₀.ne').2 hs₀)	(neg_mem_nhds_zero _ ((set_smul_mem_nhds_zero_iff hε₀.ne').2 hs₀)) filter_upwards [this] with y hy constructor · rw [sub_le_iff_le_add] calc	Mathlib/Analysis/Convex/Gauge.lean	428	432
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Johannes Hölzl -/ import Mathlib.MeasureTheory.Integral.Lebesgue.Basic import Mathlib.MeasureTheory.Integral.Lebesgue.Countable import Mathlib.MeasureTheory.Integral.Lebesgue.MeasurePreserving import Mathlib.MeasureTheory.Integral.Lebesgue.Norm deprecated_module (since := "2025-04-13")		Mathlib/MeasureTheory/Integral/Lebesgue.lean	802	804
/- 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.Differentiation /-! # Besicovitch covering theorems The topological Besicovitch covering theorem ensures that, in a nice metric space, there exists a number `N` such that, from any family of balls with bounded radii, one can extract `N` families, each made of disjoint balls, covering together all the centers of the initial family. By "nice metric space", we mean a technical property stated as follows: there exists no satellite configuration of `N + 1` points (with a given parameter `τ > 1`). Such a configuration is a family of `N + 1` balls, where the first `N` balls all intersect the last one, but none of them contains the center of another one and their radii are controlled. This property is for instance satisfied by finite-dimensional real vector spaces. In this file, we prove the topological Besicovitch covering theorem, in `Besicovitch.exist_disjoint_covering_families`. The measurable Besicovitch theorem ensures that, in the same class of metric spaces, if at every point one considers a class of balls of arbitrarily small radii, called admissible balls, then one can cover almost all the space by a family of disjoint admissible balls. It is deduced from the topological Besicovitch theorem, and proved in `Besicovitch.exists_disjoint_closedBall_covering_ae`. This implies that balls of small radius form a Vitali family in such spaces. Therefore, theorems on differentiation of measures hold as a consequence of general results. We restate them in this context to make them more easily usable. ## Main definitions and results * `SatelliteConfig α N τ` is the type of all satellite configurations of `N + 1` points in the metric space `α`, with parameter `τ`. * `HasBesicovitchCovering` is a class recording that there exist `N` and `τ > 1` such that there is no satellite configuration of `N + 1` points with parameter `τ`. * `exist_disjoint_covering_families` is the topological Besicovitch covering theorem: from any family of balls one can extract finitely many disjoint subfamilies covering the same set. * `exists_disjoint_closedBall_covering` is the measurable Besicovitch covering theorem: from any family of balls with arbitrarily small radii at every point, one can extract countably many disjoint balls covering almost all the space. While the value of `N` is relevant for the precise statement of the topological Besicovitch theorem, it becomes irrelevant for the measurable one. Therefore, this statement is expressed using the `Prop`-valued typeclass `HasBesicovitchCovering`. We also restate the following specialized versions of general theorems on differentiation of measures: * `Besicovitch.ae_tendsto_rnDeriv` ensures that `ρ (closedBall x r) / μ (closedBall x r)` tends almost surely to the Radon-Nikodym derivative of `ρ` with respect to `μ` at `x`. * `Besicovitch.ae_tendsto_measure_inter_div` states that almost every point in an arbitrary set `s` is a Lebesgue density point, i.e., `μ (s ∩ closedBall x r) / μ (closedBall x r)` tends to `1` as `r` tends to `0`. A stronger version for measurable sets is given in `Besicovitch.ae_tendsto_measure_inter_div_of_measurableSet`. ## Implementation #### Sketch of proof of the topological Besicovitch theorem: We choose balls in a greedy way. First choose a ball with maximal radius (or rather, since there is no guarantee the maximal radius is realized, a ball with radius within a factor `τ` of the supremum). Then, remove all balls whose center is covered by the first ball, and choose among the remaining ones a ball with radius close to maximum. Go on forever until there is no available center (this is a transfinite induction in general). Then define inductively a coloring of the balls. A ball will be of color `i` if it intersects already chosen balls of color `0`, ..., `i - 1`, but none of color `i`. In this way, balls of the same color form a disjoint family, and the space is covered by the families of the different colors. The nontrivial part is to show that at most `N` colors are used. If one needs `N + 1` colors, consider the first time this happens. Then the corresponding ball intersects `N` balls of the different colors. Moreover, the inductive construction ensures that the radii of all the balls are controlled: they form a satellite configuration with `N + 1` balls (essentially by definition of satellite configurations). Since we assume that there are no such configurations, this is a contradiction. #### Sketch of proof of the measurable Besicovitch theorem: From the topological Besicovitch theorem, one can find a disjoint countable family of balls covering a proportion `> 1 / (N + 1)` of the space. Taking a large enough finite subset of these balls, one gets the same property for finitely many balls. Their union is closed. Therefore, any point in the complement has around it an admissible ball not intersecting these finitely many balls. Applying again the topological Besicovitch theorem, one extracts from these a disjoint countable subfamily covering a proportion `> 1 / (N + 1)` of the remaining points, and then even a disjoint finite subfamily. Then one goes on again and again, covering at each step a positive proportion of the remaining points, while remaining disjoint from the already chosen balls. The union of all these balls is the desired almost everywhere covering. -/ noncomputable section universe u open Metric Set Filter Fin MeasureTheory TopologicalSpace open scoped Topology ENNReal MeasureTheory NNReal /-! ### Satellite configurations -/ /-- A satellite configuration is a configuration of `N+1` points that shows up in the inductive construction for the Besicovitch covering theorem. It depends on some parameter `τ ≥ 1`. This is a family of balls (indexed by `i : Fin N.succ`, with center `c i` and radius `r i`) such that the last ball intersects all the other balls (condition `inter`), and given any two balls there is an order between them, ensuring that the first ball does not contain the center of the other one, and the radius of the second ball can not be larger than the radius of the first ball (up to a factor `τ`). This order corresponds to the order of choice in the inductive construction: otherwise, the second ball would have been chosen before. This is the condition `h`. Finally, the last ball is chosen after all the other ones, meaning that `h` can be strengthened by keeping only one side of the alternative in `hlast`. -/ structure Besicovitch.SatelliteConfig (α : Type) [MetricSpace α] (N : ℕ) (τ : ℝ) where /-- Centers of the balls -/ c : Fin N.succ → α /-- Radii of the balls -/ r : Fin N.succ → ℝ rpos : ∀ i, 0 < r i h : Pairwise fun i j => r i ≤ dist (c i) (c j) ∧ r j ≤ τ r i ∨ r j ≤ dist (c j) (c i) ∧ r i ≤ τ * r j hlast : ∀ i < last N, r i ≤ dist (c i) (c (last N)) ∧ r (last N) ≤ τ * r i inter : ∀ i < last N, dist (c i) (c (last N)) ≤ r i + r (last N) namespace Mathlib.Meta.Positivity open Lean Meta Qq /-- Extension for the `positivity` tactic: `Besicovitch.SatelliteConfig.r`. -/ @[positivity Besicovitch.SatelliteConfig.r _ _] def evalBesicovitchSatelliteConfigR : PositivityExt where eval {u α} _zα _pα e := do match u, α, e with \| 0, ~q(ℝ), ~q(@Besicovitch.SatelliteConfig.r $β $inst $N $τ $self $i) => assertInstancesCommute return .positive q(Besicovitch.SatelliteConfig.rpos $self $i) \| _, _, _ => throwError "not Besicovitch.SatelliteConfig.r" end Mathlib.Meta.Positivity /-- A metric space has the Besicovitch covering property if there exist `N` and `τ > 1` such that there are no satellite configuration of parameter `τ` with `N+1` points. This is the condition that guarantees that the measurable Besicovitch covering theorem holds. It is satisfied by finite-dimensional real vector spaces. -/ class HasBesicovitchCovering (α : Type) [MetricSpace α] : Prop where no_satelliteConfig : ∃ (N : ℕ) (τ : ℝ), 1 < τ ∧ IsEmpty (Besicovitch.SatelliteConfig α N τ) /-- There is always a satellite configuration with a single point. -/ instance Besicovitch.SatelliteConfig.instInhabited {α : Type} {τ : ℝ} [Inhabited α] [MetricSpace α] : Inhabited (Besicovitch.SatelliteConfig α 0 τ) := ⟨{ c := default r := fun _ => 1 rpos := fun _ => zero_lt_one h := fun i j hij => (hij (Subsingleton.elim (α := Fin 1) i j)).elim hlast := fun i hi => by rw [Subsingleton.elim (α := Fin 1) i (last 0)] at hi; exact (lt_irrefl _ hi).elim inter := fun i hi => by rw [Subsingleton.elim (α := Fin 1) i (last 0)] at hi; exact (lt_irrefl _ hi).elim }⟩ namespace Besicovitch namespace SatelliteConfig variable {α : Type} [MetricSpace α] {N : ℕ} {τ : ℝ} (a : SatelliteConfig α N τ) theorem inter' (i : Fin N.succ) : dist (a.c i) (a.c (last N)) ≤ a.r i + a.r (last N) := by rcases lt_or_le i (last N) with (H \| H) · exact a.inter i H · have I : i = last N := top_le_iff.1 H have := (a.rpos (last N)).le simp only [I, add_nonneg this this, dist_self] theorem hlast' (i : Fin N.succ) (h : 1 ≤ τ) : a.r (last N) ≤ τ a.r i := by rcases lt_or_le i (last N) with (H \| H) · exact (a.hlast i H).2 · have : i = last N := top_le_iff.1 H rw [this] exact le_mul_of_one_le_left (a.rpos _).le h end SatelliteConfig /-! ### Extracting disjoint subfamilies from a ball covering -/ /-- A ball package is a family of balls in a metric space with positive bounded radii. -/ structure BallPackage (β : Type) (α : Type) where /-- Centers of the balls -/ c : β → α /-- Radii of the balls -/	r : β → ℝ rpos : ∀ b, 0 < r b /-- Bound on the radii of the balls -/ r_bound : ℝ r_le : ∀ b, r b ≤ r_bound	Mathlib/MeasureTheory/Covering/Besicovitch.lean	195	200
/- Copyright (c) 2024 Violeta Hernández Palacios. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Violeta Hernández Palacios -/ import Mathlib.SetTheory.Cardinal.Arithmetic import Mathlib.SetTheory.Ordinal.Principal /-! # Ordinal arithmetic with cardinals This file collects results about the cardinality of different ordinal operations. -/ universe u v open Cardinal Ordinal Set /-! ### Cardinal operations with ordinal indices -/ namespace Cardinal /-- Bounds the cardinal of an ordinal-indexed union of sets. -/ lemma mk_iUnion_Ordinal_lift_le_of_le {β : Type v} {o : Ordinal.{u}} {c : Cardinal.{v}} (ho : lift.{v} o.card ≤ lift.{u} c) (hc : ℵ₀ ≤ c) (A : Ordinal → Set β) (hA : ∀ j < o, #(A j) ≤ c) : #(⋃ j < o, A j) ≤ c := by simp_rw [← mem_Iio, biUnion_eq_iUnion, iUnion, iSup, ← o.enumIsoToType.symm.surjective.range_comp] rw [← lift_le.{u}] apply ((mk_iUnion_le_lift _).trans _).trans_eq (mul_eq_self (aleph0_le_lift.2 hc)) rw [mk_toType] refine mul_le_mul' ho (ciSup_le' ?_) intro i simpa using hA _ (o.enumIsoToType.symm i).2 lemma mk_iUnion_Ordinal_le_of_le {β : Type} {o : Ordinal} {c : Cardinal} (ho : o.card ≤ c) (hc : ℵ₀ ≤ c) (A : Ordinal → Set β) (hA : ∀ j < o, #(A j) ≤ c) : #(⋃ j < o, A j) ≤ c := by apply mk_iUnion_Ordinal_lift_le_of_le _ hc A hA rwa [Cardinal.lift_le] end Cardinal @[deprecated mk_iUnion_Ordinal_le_of_le (since := "2024-11-02")] alias Ordinal.Cardinal.mk_iUnion_Ordinal_le_of_le := mk_iUnion_Ordinal_le_of_le /-! ### Cardinality of ordinals -/ namespace Ordinal theorem lift_card_iSup_le_sum_card {ι : Type u} [Small.{v} ι] (f : ι → Ordinal.{v}) : Cardinal.lift.{u} (⨆ i, f i).card ≤ Cardinal.sum fun i ↦ (f i).card := by simp_rw [← mk_toType] rw [← mk_sigma, ← Cardinal.lift_id'.{v} #(Σ _, _), ← Cardinal.lift_umax.{v, u}] apply lift_mk_le_lift_mk_of_surjective (f := enumIsoToType _ ∘ (⟨(enumIsoToType _).symm ·.2, (mem_Iio.mp ((enumIsoToType _).symm _).2).trans_le (Ordinal.le_iSup _ _)⟩)) rw [EquivLike.comp_surjective] rintro ⟨x, hx⟩ obtain ⟨i, hi⟩ := Ordinal.lt_iSup_iff.mp hx exact ⟨⟨i, enumIsoToType _ ⟨x, hi⟩⟩, by simp⟩ theorem card_iSup_le_sum_card {ι : Type u} (f : ι → Ordinal.{max u v}) : (⨆ i, f i).card ≤ Cardinal.sum (fun i ↦ (f i).card) := by have := lift_card_iSup_le_sum_card f rwa [Cardinal.lift_id'] at this theorem card_iSup_Iio_le_sum_card {o : Ordinal.{u}} (f : Iio o → Ordinal.{max u v}) : (⨆ a : Iio o, f a).card ≤ Cardinal.sum fun i ↦ (f ((enumIsoToType o).symm i)).card := by apply le_of_eq_of_le (congr_arg _ _).symm (card_iSup_le_sum_card _) simpa using (enumIsoToType o).symm.iSup_comp (g := fun x ↦ f x) theorem card_iSup_Iio_le_card_mul_iSup {o : Ordinal.{u}} (f : Iio o → Ordinal.{max u v}) : (⨆ a : Iio o, f a).card ≤ Cardinal.lift.{v} o.card ⨆ a : Iio o, (f a).card := by apply (card_iSup_Iio_le_sum_card f).trans convert ← sum_le_iSup_lift _ · exact mk_toType o · exact (enumIsoToType o).symm.iSup_comp (g := fun x ↦ (f x).card) theorem card_opow_le_of_omega0_le_left {a : Ordinal} (ha : ω ≤ a) (b : Ordinal) : (a ^ b).card ≤ max a.card b.card := by refine limitRecOn b ?_ ?_ ?_ · simpa using one_lt_omega0.le.trans ha · intro b IH rw [opow_succ, card_mul, card_succ, Cardinal.mul_eq_max_of_aleph0_le_right, max_comm] · apply (max_le_max_left _ IH).trans rw [← max_assoc, max_self] exact max_le_max_left _ le_self_add · rw [ne_eq, card_eq_zero, opow_eq_zero] rintro ⟨rfl, -⟩ cases omega0_pos.not_le ha · rwa [aleph0_le_card] · intro b hb IH rw [(isNormal_opow (one_lt_omega0.trans_le ha)).apply_of_isLimit hb] apply (card_iSup_Iio_le_card_mul_iSup _).trans rw [Cardinal.lift_id, Cardinal.mul_eq_max_of_aleph0_le_right, max_comm] · apply max_le _ (le_max_right _ _) apply ciSup_le' intro c exact (IH c.1 c.2).trans (max_le_max_left _ (card_le_card c.2.le)) · simpa using hb.pos.ne' · refine le_ciSup_of_le ?_ ⟨1, one_lt_omega0.trans_le <\| omega0_le_of_isLimit hb⟩ ?_ · exact Cardinal.bddAbove_of_small _ · simpa theorem card_opow_le_of_omega0_le_right (a : Ordinal) {b : Ordinal} (hb : ω ≤ b) : (a ^ b).card ≤ max a.card b.card := by obtain ⟨n, rfl⟩ \| ha := eq_nat_or_omega0_le a · apply (card_le_card <\| opow_le_opow_left b (nat_lt_omega0 n).le).trans apply (card_opow_le_of_omega0_le_left le_rfl _).trans simp [hb] · exact card_opow_le_of_omega0_le_left ha b theorem card_opow_le (a b : Ordinal) : (a ^ b).card ≤ max ℵ₀ (max a.card b.card) := by obtain ⟨n, rfl⟩ \| ha := eq_nat_or_omega0_le a · obtain ⟨m, rfl⟩ \| hb := eq_nat_or_omega0_le b · rw [← natCast_opow, card_nat] exact le_max_of_le_left (nat_lt_aleph0 _).le · exact (card_opow_le_of_omega0_le_right _ hb).trans (le_max_right _ _) · exact (card_opow_le_of_omega0_le_left ha _).trans (le_max_right _ _) theorem card_opow_eq_of_omega0_le_left {a b : Ordinal} (ha : ω ≤ a) (hb : 0 < b) : (a ^ b).card = max a.card b.card := by apply (card_opow_le_of_omega0_le_left ha b).antisymm (max_le _ _) <;> apply card_le_card · exact left_le_opow a hb · exact right_le_opow b (one_lt_omega0.trans_le ha) theorem card_opow_eq_of_omega0_le_right {a b : Ordinal} (ha : 1 < a) (hb : ω ≤ b) : (a ^ b).card = max a.card b.card := by apply (card_opow_le_of_omega0_le_right a hb).antisymm (max_le _ _) <;> apply card_le_card · exact left_le_opow a (omega0_pos.trans_le hb) · exact right_le_opow b ha theorem card_omega0_opow {a : Ordinal} (h : a ≠ 0) : card (ω ^ a) = max ℵ₀ a.card := by rw [card_opow_eq_of_omega0_le_left le_rfl h.bot_lt, card_omega0] theorem card_opow_omega0 {a : Ordinal} (h : 1 < a) : card (a ^ ω) = max ℵ₀ a.card := by rw [card_opow_eq_of_omega0_le_right h le_rfl, card_omega0, max_comm] theorem principal_opow_omega (o : Ordinal) : Principal (· ^ ·) (ω_ o) := by obtain rfl \| ho := Ordinal.eq_zero_or_pos o · rw [omega_zero] exact principal_opow_omega0 · intro a b ha hb rw [lt_omega_iff_card_lt] at ha hb ⊢ apply (card_opow_le a b).trans_lt (max_lt _ (max_lt ha hb)) rwa [← aleph_zero, aleph_lt_aleph] theorem IsInitial.principal_opow {o : Ordinal} (h : IsInitial o) (ho : ω ≤ o) : Principal (· ^ ·) o := by obtain ⟨a, rfl⟩ := mem_range_omega_iff.2 ⟨ho, h⟩ exact principal_opow_omega a theorem principal_opow_ord {c : Cardinal} (hc : ℵ₀ ≤ c) : Principal (· ^ ·) c.ord := by apply (isInitial_ord c).principal_opow rwa [omega0_le_ord] /-! ### Initial ordinals are principal -/ theorem principal_add_ord {c : Cardinal} (hc : ℵ₀ ≤ c) : Principal (· + ·) c.ord := by intro a b ha hb rw [lt_ord, card_add] at * exact add_lt_of_lt hc ha hb theorem IsInitial.principal_add {o : Ordinal} (h : IsInitial o) (ho : ω ≤ o) : Principal (· + ·) o := by rw [← h.ord_card] apply principal_add_ord rwa [aleph0_le_card] theorem principal_add_omega (o : Ordinal) : Principal (· + ·) (ω_ o) := (isInitial_omega o).principal_add (omega0_le_omega o) theorem principal_mul_ord {c : Cardinal} (hc : ℵ₀ ≤ c) : Principal (· * ·) c.ord := by intro a b ha hb rw [lt_ord, card_mul] at * exact mul_lt_of_lt hc ha hb theorem IsInitial.principal_mul {o : Ordinal} (h : IsInitial o) (ho : ω ≤ o) : Principal (· * ·) o := by rw [← h.ord_card] apply principal_mul_ord rwa [aleph0_le_card] theorem principal_mul_omega (o : Ordinal) : Principal (· * ·) (ω_ o) := (isInitial_omega o).principal_mul (omega0_le_omega o) @[deprecated principal_add_omega (since := "2024-11-08")] theorem _root_.Cardinal.principal_add_aleph (o : Ordinal) : Principal (· + ·) (ℵ_ o).ord := principal_add_ord <\| aleph0_le_aleph o end Ordinal		Mathlib/SetTheory/Cardinal/Ordinal.lean	885	887
/- 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.Additive import Mathlib.Algebra.Homology.ShortComplex.Exact import Mathlib.Algebra.Homology.ShortComplex.Preadditive import Mathlib.Tactic.Linarith /-! # The short complexes attached to homological complexes In this file, we define a functor `shortComplexFunctor C c i : HomologicalComplex C c ⥤ ShortComplex C`. By definition, the image of a homological complex `K` by this functor is the short complex `K.X (c.prev i) ⟶ K.X i ⟶ K.X (c.next i)`. The homology `K.homology i` of a homological complex `K` in degree `i` is defined as the homology of the short complex `(shortComplexFunctor C c i).obj K`, which can be abbreviated as `K.sc i`. -/ open CategoryTheory Category Limits namespace HomologicalComplex variable (C : Type) [Category C] [HasZeroMorphisms C] {ι : Type} (c : ComplexShape ι) /-- The functor `HomologicalComplex C c ⥤ ShortComplex C` which sends a homological complex `K` to the short complex `K.X i ⟶ K.X j ⟶ K.X k` for arbitrary indices `i`, `j` and `k`. -/ @[simps] def shortComplexFunctor' (i j k : ι) : HomologicalComplex C c ⥤ ShortComplex C where obj K := ShortComplex.mk (K.d i j) (K.d j k) (K.d_comp_d i j k) map f := { τ₁ := f.f i τ₂ := f.f j τ₃ := f.f k } /-- The functor `HomologicalComplex C c ⥤ ShortComplex C` which sends a homological complex `K` to the short complex `K.X (c.prev i) ⟶ K.X i ⟶ K.X (c.next i)`. -/ @[simps!] noncomputable def shortComplexFunctor (i : ι) := shortComplexFunctor' C c (c.prev i) i (c.next i) /-- The natural isomorphism `shortComplexFunctor C c j ≅ shortComplexFunctor' C c i j k` when `c.prev j = i` and `c.next j = k`. -/ @[simps!] noncomputable def natIsoSc' (i j k : ι) (hi : c.prev j = i) (hk : c.next j = k) : shortComplexFunctor C c j ≅ shortComplexFunctor' C c i j k := NatIso.ofComponents (fun K => ShortComplex.isoMk (K.XIsoOfEq hi) (Iso.refl _) (K.XIsoOfEq hk) (by simp) (by simp)) (by aesop_cat) variable {C c} variable (K L M : HomologicalComplex C c) (φ : K ⟶ L) (ψ : L ⟶ M) (i j k : ι) /-- The short complex `K.X i ⟶ K.X j ⟶ K.X k` for arbitrary indices `i`, `j` and `k`. -/ abbrev sc' := (shortComplexFunctor' C c i j k).obj K /-- The short complex `K.X (c.prev i) ⟶ K.X i ⟶ K.X (c.next i)`. -/ noncomputable abbrev sc := (shortComplexFunctor C c i).obj K /-- The canonical isomorphism `K.sc j ≅ K.sc' i j k` when `c.prev j = i` and `c.next j = k`. -/ noncomputable abbrev isoSc' (hi : c.prev j = i) (hk : c.next j = k) : K.sc j ≅ K.sc' i j k := (natIsoSc' C c i j k hi hk).app K /-- A homological complex `K` has homology in degree `i` if the associated short complex `K.sc i` has. -/ abbrev HasHomology := (K.sc i).HasHomology section variable [K.HasHomology i] /-- The homology in degree `i` of a homological complex. -/ noncomputable def homology := (K.sc i).homology /-- The cycles in degree `i` of a homological complex. -/ noncomputable def cycles := (K.sc i).cycles /-- The inclusion of the cycles of a homological complex. -/ noncomputable def iCycles : K.cycles i ⟶ K.X i := (K.sc i).iCycles /-- The homology class map from cycles to the homology of a homological complex. -/ noncomputable def homologyπ : K.cycles i ⟶ K.homology i := (K.sc i).homologyπ variable {i} /-- The morphism to `K.cycles i` that is induced by a "cycle", i.e. a morphism to `K.X i` whose postcomposition with the differential is zero. -/ noncomputable def liftCycles {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j) (hk : k ≫ K.d i j = 0) : A ⟶ K.cycles i := (K.sc i).liftCycles k (by subst hj; exact hk) /-- The morphism to `K.cycles i` that is induced by a "cycle", i.e. a morphism to `K.X i` whose postcomposition with the differential is zero. -/ noncomputable abbrev liftCycles' {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.Rel i j) (hk : k ≫ K.d i j = 0) : A ⟶ K.cycles i := K.liftCycles k j (c.next_eq' hj) hk @[reassoc (attr := simp)] lemma liftCycles_i {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j) (hk : k ≫ K.d i j = 0) : K.liftCycles k j hj hk ≫ K.iCycles i = k := by dsimp [liftCycles, iCycles] simp variable (i) /-- The map `K.X i ⟶ K.cycles j` induced by the differential `K.d i j`. -/ noncomputable def toCycles [K.HasHomology j] : K.X i ⟶ K.cycles j := K.liftCycles (K.d i j) (c.next j) rfl (K.d_comp_d _ _ _) @[reassoc (attr := simp)] lemma iCycles_d : K.iCycles i ≫ K.d i j = 0 := by by_cases hij : c.Rel i j · obtain rfl := c.next_eq' hij exact (K.sc i).iCycles_g · rw [K.shape _ _ hij, comp_zero] /-- `K.cycles i` is the kernel of `K.d i j` when `c.next i = j`. -/ noncomputable def cyclesIsKernel (hj : c.next i = j) : IsLimit (KernelFork.ofι (K.iCycles i) (K.iCycles_d i j)) := by obtain rfl := hj exact (K.sc i).cyclesIsKernel end @[reassoc (attr := simp)] lemma toCycles_i [K.HasHomology j] : K.toCycles i j ≫ K.iCycles j = K.d i j := liftCycles_i _ _ _ _ _ section variable [K.HasHomology i] instance : Mono (K.iCycles i) := by dsimp only [iCycles] infer_instance instance : Epi (K.homologyπ i) := by dsimp only [homologyπ] infer_instance end @[reassoc (attr := simp)] lemma d_toCycles [K.HasHomology k] : K.d i j ≫ K.toCycles j k = 0 := by simp only [← cancel_mono (K.iCycles k), assoc, toCycles_i, d_comp_d, zero_comp] variable {i j} in lemma toCycles_eq_zero [K.HasHomology j] (hij : ¬ c.Rel i j) : K.toCycles i j = 0 := by rw [← cancel_mono (K.iCycles j), toCycles_i, zero_comp, K.shape _ _ hij] variable {i} section variable [K.HasHomology i] @[reassoc] lemma comp_liftCycles {A' A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j) (hk : k ≫ K.d i j = 0) (α : A' ⟶ A) : α ≫ K.liftCycles k j hj hk = K.liftCycles (α ≫ k) j hj (by rw [assoc, hk, comp_zero]) := by simp only [← cancel_mono (K.iCycles i), assoc, liftCycles_i] @[reassoc] lemma liftCycles_homologyπ_eq_zero_of_boundary {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j) {i' : ι} (x : A ⟶ K.X i') (hx : k = x ≫ K.d i' i) : K.liftCycles k j hj (by rw [hx, assoc, K.d_comp_d, comp_zero]) ≫ K.homologyπ i = 0 := by by_cases h : c.Rel i' i · obtain rfl := c.prev_eq' h exact (K.sc i).liftCycles_homologyπ_eq_zero_of_boundary _ x hx · have : liftCycles K k j hj (by rw [hx, assoc, K.d_comp_d, comp_zero]) = 0 := by rw [K.shape _ _ h, comp_zero] at hx rw [← cancel_mono (K.iCycles i), zero_comp, liftCycles_i, hx] rw [this, zero_comp] end variable (i) @[reassoc (attr := simp)] lemma toCycles_comp_homologyπ [K.HasHomology j] : K.toCycles i j ≫ K.homologyπ j = 0 := K.liftCycles_homologyπ_eq_zero_of_boundary (K.d i j) (c.next j) rfl (𝟙 _) (by simp) /-- `K.homology j` is the cokernel of `K.toCycles i j : K.X i ⟶ K.cycles j` when `c.prev j = i`. -/ noncomputable def homologyIsCokernel (hi : c.prev j = i) [K.HasHomology j] : IsColimit (CokernelCofork.ofπ (K.homologyπ j) (K.toCycles_comp_homologyπ i j)) := by subst hi exact (K.sc j).homologyIsCokernel section variable [K.HasHomology i] /-- The opcycles in degree `i` of a homological complex. -/ noncomputable def opcycles := (K.sc i).opcycles /-- The projection to the opcycles of a homological complex. -/ noncomputable def pOpcycles : K.X i ⟶ K.opcycles i := (K.sc i).pOpcycles /-- The inclusion map of the homology of a homological complex into its opcycles. -/ noncomputable def homologyι : K.homology i ⟶ K.opcycles i := (K.sc i).homologyι variable {i} /-- The morphism from `K.opcycles i` that is induced by an "opcycle", i.e. a morphism from `K.X i` whose precomposition with the differential is zero. -/ noncomputable def descOpcycles {A : C} (k : K.X i ⟶ A) (j : ι) (hj : c.prev i = j) (hk : K.d j i ≫ k = 0) : K.opcycles i ⟶ A := (K.sc i).descOpcycles k (by subst hj; exact hk) /-- The morphism from `K.opcycles i` that is induced by an "opcycle", i.e. a morphism from `K.X i` whose precomposition with the differential is zero. -/ noncomputable abbrev descOpcycles' {A : C} (k : K.X i ⟶ A) (j : ι) (hj : c.Rel j i) (hk : K.d j i ≫ k = 0) : K.opcycles i ⟶ A := K.descOpcycles k j (c.prev_eq' hj) hk @[reassoc (attr := simp)] lemma p_descOpcycles {A : C} (k : K.X i ⟶ A) (j : ι) (hj : c.prev i = j) (hk : K.d j i ≫ k = 0) : K.pOpcycles i ≫ K.descOpcycles k j hj hk = k := by dsimp [descOpcycles, pOpcycles] simp variable (i) /-- The map `K.opcycles i ⟶ K.X j` induced by the differential `K.d i j`. -/ noncomputable def fromOpcycles : K.opcycles i ⟶ K.X j := K.descOpcycles (K.d i j) (c.prev i) rfl (K.d_comp_d _ _ _) @[reassoc (attr := simp)] lemma d_pOpcycles [K.HasHomology j] : K.d i j ≫ K.pOpcycles j = 0 := by by_cases hij : c.Rel i j · obtain rfl := c.prev_eq' hij exact (K.sc j).f_pOpcycles · rw [K.shape _ _ hij, zero_comp] /-- `K.opcycles j` is the cokernel of `K.d i j` when `c.prev j = i`. -/ noncomputable def opcyclesIsCokernel (hi : c.prev j = i) [K.HasHomology j] : IsColimit (CokernelCofork.ofπ (K.pOpcycles j) (K.d_pOpcycles i j)) := by obtain rfl := hi exact (K.sc j).opcyclesIsCokernel @[reassoc (attr := simp)] lemma p_fromOpcycles : K.pOpcycles i ≫ K.fromOpcycles i j = K.d i j := p_descOpcycles _ _ _ _ _ instance : Epi (K.pOpcycles i) := by dsimp only [pOpcycles] infer_instance instance : Mono (K.homologyι i) := by dsimp only [homologyι] infer_instance @[reassoc (attr := simp)] lemma fromOpcycles_d : K.fromOpcycles i j ≫ K.d j k = 0 := by simp only [← cancel_epi (K.pOpcycles i), p_fromOpcycles_assoc, d_comp_d, comp_zero] variable {i j} in lemma fromOpcycles_eq_zero (hij : ¬ c.Rel i j) : K.fromOpcycles i j = 0 := by rw [← cancel_epi (K.pOpcycles i), p_fromOpcycles, comp_zero, K.shape _ _ hij] variable {i} @[reassoc] lemma descOpcycles_comp {A A' : C} (k : K.X i ⟶ A) (j : ι) (hj : c.prev i = j) (hk : K.d j i ≫ k = 0) (α : A ⟶ A') : K.descOpcycles k j hj hk ≫ α = K.descOpcycles (k ≫ α) j hj (by rw [reassoc_of% hk, zero_comp]) := by simp only [← cancel_epi (K.pOpcycles i), p_descOpcycles_assoc, p_descOpcycles] @[reassoc] lemma homologyι_descOpcycles_eq_zero_of_boundary {A : C} (k : K.X i ⟶ A) (j : ι) (hj : c.prev i = j) {i' : ι} (x : K.X i' ⟶ A) (hx : k = K.d i i' ≫ x) : K.homologyι i ≫ K.descOpcycles k j hj (by rw [hx, K.d_comp_d_assoc, zero_comp]) = 0 := by by_cases h : c.Rel i i' · obtain rfl := c.next_eq' h exact (K.sc i).homologyι_descOpcycles_eq_zero_of_boundary _ x hx · have : K.descOpcycles k j hj (by rw [hx, K.d_comp_d_assoc, zero_comp]) = 0 := by rw [K.shape _ _ h, zero_comp] at hx rw [← cancel_epi (K.pOpcycles i), comp_zero, p_descOpcycles, hx] rw [this, comp_zero] variable (i) @[reassoc (attr := simp)] lemma homologyι_comp_fromOpcycles : K.homologyι i ≫ K.fromOpcycles i j = 0 := K.homologyι_descOpcycles_eq_zero_of_boundary (K.d i j) _ rfl (𝟙 _) (by simp) /-- `K.homology i` is the kernel of `K.fromOpcycles i j : K.opcycles i ⟶ K.X j` when `c.next i = j`. -/ noncomputable def homologyIsKernel (hi : c.next i = j) : IsLimit (KernelFork.ofι (K.homologyι i) (K.homologyι_comp_fromOpcycles i j)) := by subst hi exact (K.sc i).homologyIsKernel variable {K L M} variable [L.HasHomology i] [M.HasHomology i] /-- The map `K.homology i ⟶ L.homology i` induced by a morphism in `HomologicalComplex`. -/ noncomputable def homologyMap : K.homology i ⟶ L.homology i := ShortComplex.homologyMap ((shortComplexFunctor C c i).map φ) /-- The map `K.cycles i ⟶ L.cycles i` induced by a morphism in `HomologicalComplex`. -/ noncomputable def cyclesMap : K.cycles i ⟶ L.cycles i := ShortComplex.cyclesMap ((shortComplexFunctor C c i).map φ) /-- The map `K.opcycles i ⟶ L.opcycles i` induced by a morphism in `HomologicalComplex`. -/ noncomputable def opcyclesMap : K.opcycles i ⟶ L.opcycles i := ShortComplex.opcyclesMap ((shortComplexFunctor C c i).map φ) @[reassoc (attr := simp)] lemma cyclesMap_i : cyclesMap φ i ≫ L.iCycles i = K.iCycles i ≫ φ.f i := ShortComplex.cyclesMap_i _ @[reassoc (attr := simp)] lemma p_opcyclesMap : K.pOpcycles i ≫ opcyclesMap φ i = φ.f i ≫ L.pOpcycles i := ShortComplex.p_opcyclesMap _ instance [Mono (φ.f i)] : Mono (cyclesMap φ i) := mono_of_mono_fac (cyclesMap_i φ i) instance [Epi (φ.f i)] : Epi (opcyclesMap φ i) := epi_of_epi_fac (p_opcyclesMap φ i) variable (K) @[simp] lemma homologyMap_id : homologyMap (𝟙 K) i = 𝟙 _ := ShortComplex.homologyMap_id _ @[simp] lemma cyclesMap_id : cyclesMap (𝟙 K) i = 𝟙 _ := ShortComplex.cyclesMap_id _ @[simp] lemma opcyclesMap_id : opcyclesMap (𝟙 K) i = 𝟙 _ := ShortComplex.opcyclesMap_id _ variable {K} @[reassoc] lemma homologyMap_comp : homologyMap (φ ≫ ψ) i = homologyMap φ i ≫ homologyMap ψ i := by dsimp [homologyMap] rw [Functor.map_comp, ShortComplex.homologyMap_comp] @[reassoc] lemma cyclesMap_comp : cyclesMap (φ ≫ ψ) i = cyclesMap φ i ≫ cyclesMap ψ i := by dsimp [cyclesMap] rw [Functor.map_comp, ShortComplex.cyclesMap_comp] @[reassoc] lemma opcyclesMap_comp : opcyclesMap (φ ≫ ψ) i = opcyclesMap φ i ≫ opcyclesMap ψ i := by dsimp [opcyclesMap] rw [Functor.map_comp, ShortComplex.opcyclesMap_comp] variable (K L) @[simp] lemma homologyMap_zero : homologyMap (0 : K ⟶ L) i = 0 := ShortComplex.homologyMap_zero _ _ @[simp] lemma cyclesMap_zero : cyclesMap (0 : K ⟶ L) i = 0 := ShortComplex.cyclesMap_zero _ _ @[simp] lemma opcyclesMap_zero : opcyclesMap (0 : K ⟶ L) i = 0 := ShortComplex.opcyclesMap_zero _ _ variable {K L} @[reassoc (attr := simp)] lemma homologyπ_naturality : K.homologyπ i ≫ homologyMap φ i = cyclesMap φ i ≫ L.homologyπ i := ShortComplex.homologyπ_naturality _ @[reassoc (attr := simp)] lemma homologyι_naturality : homologyMap φ i ≫ L.homologyι i = K.homologyι i ≫ opcyclesMap φ i := ShortComplex.homologyι_naturality _ @[reassoc (attr := simp)] lemma homology_π_ι : K.homologyπ i ≫ K.homologyι i = K.iCycles i ≫ K.pOpcycles i := (K.sc i).homology_π_ι variable {i} @[reassoc (attr := simp)] lemma opcyclesMap_comp_descOpcycles {A : C} (k : L.X i ⟶ A) (j : ι) (hj : c.prev i = j) (hk : L.d j i ≫ k = 0) (φ : K ⟶ L) : opcyclesMap φ i ≫ L.descOpcycles k j hj hk = K.descOpcycles (φ.f i ≫ k) j hj (by rw [← φ.comm_assoc, hk, comp_zero]) := by simp only [← cancel_epi (K.pOpcycles i), p_opcyclesMap_assoc, p_descOpcycles] @[reassoc (attr := simp)] lemma liftCycles_comp_cyclesMap {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j) (hk : k ≫ K.d i j = 0) (φ : K ⟶ L) : K.liftCycles k j hj hk ≫ cyclesMap φ i = L.liftCycles (k ≫ φ.f i) j hj (by rw [assoc, φ.comm, reassoc_of% hk, zero_comp]) := by simp only [← cancel_mono (L.iCycles i), assoc, cyclesMap_i, liftCycles_i_assoc, liftCycles_i] section variable (C c i) attribute [local simp] homologyMap_comp cyclesMap_comp opcyclesMap_comp /-- The `i`th homology functor `HomologicalComplex C c ⥤ C`. -/ @[simps] noncomputable def homologyFunctor [CategoryWithHomology C] : HomologicalComplex C c ⥤ C where obj K := K.homology i map f := homologyMap f i /-- The homology functor to graded objects. -/ @[simps] noncomputable def gradedHomologyFunctor [CategoryWithHomology C] : HomologicalComplex C c ⥤ GradedObject ι C where obj K i := K.homology i map f i := homologyMap f i /-- The `i`th cycles functor `HomologicalComplex C c ⥤ C`. -/ @[simps] noncomputable def cyclesFunctor [CategoryWithHomology C] : HomologicalComplex C c ⥤ C where obj K := K.cycles i map f := cyclesMap f i /-- The `i`th opcycles functor `HomologicalComplex C c ⥤ C`. -/ @[simps] noncomputable def opcyclesFunctor [CategoryWithHomology C] : HomologicalComplex C c ⥤ C where obj K := K.opcycles i map f := opcyclesMap f i /-- The natural transformation `K.homologyπ i : K.cycles i ⟶ K.homology i` for all `K : HomologicalComplex C c`. -/ @[simps] noncomputable def natTransHomologyπ [CategoryWithHomology C] : cyclesFunctor C c i ⟶ homologyFunctor C c i where app K := K.homologyπ i /-- The natural transformation `K.homologyι i : K.homology i ⟶ K.opcycles i` for all `K : HomologicalComplex C c`. -/ @[simps] noncomputable def natTransHomologyι [CategoryWithHomology C] : homologyFunctor C c i ⟶ opcyclesFunctor C c i where app K := K.homologyι i /-- The natural isomorphism `K.homology i ≅ (K.sc i).homology` for all homological complexes `K`. -/ @[simps!] noncomputable def homologyFunctorIso [CategoryWithHomology C] : homologyFunctor C c i ≅ shortComplexFunctor C c i ⋙ ShortComplex.homologyFunctor C := Iso.refl _ /-- The natural isomorphism `K.homology j ≅ (K.sc' i j k).homology` for all homological complexes `K` when `c.prev j = i` and `c.next j = k`. -/ noncomputable def homologyFunctorIso' [CategoryWithHomology C] (hi : c.prev j = i) (hk : c.next j = k) : homologyFunctor C c j ≅ shortComplexFunctor' C c i j k ⋙ ShortComplex.homologyFunctor C := homologyFunctorIso C c j ≪≫ isoWhiskerRight (natIsoSc' C c i j k hi hk) _ instance [CategoryWithHomology C] : (homologyFunctor C c i).PreservesZeroMorphisms where instance [CategoryWithHomology C] : (opcyclesFunctor C c i).PreservesZeroMorphisms where instance [CategoryWithHomology C] : (cyclesFunctor C c i).PreservesZeroMorphisms where end end section variable (hj : c.next i = j) (h : K.d i j = 0) [K.HasHomology i] include hj h lemma isIso_iCycles : IsIso (K.iCycles i) := by subst hj exact ShortComplex.isIso_iCycles _ h /-- The canonical isomorphism `K.cycles i ≅ K.X i` when the differential from `i` is zero. -/ @[simps! hom] noncomputable def iCyclesIso : K.cycles i ≅ K.X i := have := K.isIso_iCycles i j hj h asIso (K.iCycles i) @[reassoc (attr := simp)] lemma iCyclesIso_hom_inv_id : K.iCycles i ≫ (K.iCyclesIso i j hj h).inv = 𝟙 _ := (K.iCyclesIso i j hj h).hom_inv_id @[reassoc (attr := simp)] lemma iCyclesIso_inv_hom_id : (K.iCyclesIso i j hj h).inv ≫ K.iCycles i = 𝟙 _ := (K.iCyclesIso i j hj h).inv_hom_id lemma isIso_homologyι : IsIso (K.homologyι i) := ShortComplex.isIso_homologyι _ (by aesop_cat) /-- The canonical isomorphism `K.homology i ≅ K.opcycles i` when the differential from `i` is zero. -/ @[simps! hom] noncomputable def isoHomologyι : K.homology i ≅ K.opcycles i := have := K.isIso_homologyι i j hj h asIso (K.homologyι i) @[reassoc (attr := simp)] lemma isoHomologyι_hom_inv_id : K.homologyι i ≫ (K.isoHomologyι i j hj h).inv = 𝟙 _ := (K.isoHomologyι i j hj h).hom_inv_id @[reassoc (attr := simp)] lemma isoHomologyι_inv_hom_id : (K.isoHomologyι i j hj h).inv ≫ K.homologyι i = 𝟙 _ := (K.isoHomologyι i j hj h).inv_hom_id end section variable (hi : c.prev j = i) (h : K.d i j = 0) [K.HasHomology j] include hi h lemma isIso_pOpcycles : IsIso (K.pOpcycles j) := by obtain rfl := hi exact ShortComplex.isIso_pOpcycles _ h /-- The canonical isomorphism `K.X j ≅ K.opCycles j` when the differential to `j` is zero. -/ @[simps! hom] noncomputable def pOpcyclesIso : K.X j ≅ K.opcycles j := have := K.isIso_pOpcycles i j hi h asIso (K.pOpcycles j) @[reassoc (attr := simp)] lemma pOpcyclesIso_hom_inv_id : K.pOpcycles j ≫ (K.pOpcyclesIso i j hi h).inv = 𝟙 _ := (K.pOpcyclesIso i j hi h).hom_inv_id @[reassoc (attr := simp)] lemma pOpcyclesIso_inv_hom_id : (K.pOpcyclesIso i j hi h).inv ≫ K.pOpcycles j = 𝟙 _ := (K.pOpcyclesIso i j hi h).inv_hom_id lemma isIso_homologyπ : IsIso (K.homologyπ j) := ShortComplex.isIso_homologyπ _ (by aesop_cat) /-- The canonical isomorphism `K.cycles j ≅ K.homology j` when the differential to `j` is zero. -/ @[simps! hom] noncomputable def isoHomologyπ : K.cycles j ≅ K.homology j := have := K.isIso_homologyπ i j hi h asIso (K.homologyπ j) @[reassoc (attr := simp)] lemma isoHomologyπ_hom_inv_id : K.homologyπ j ≫ (K.isoHomologyπ i j hi h).inv = 𝟙 _ := (K.isoHomologyπ i j hi h).hom_inv_id @[reassoc (attr := simp)] lemma isoHomologyπ_inv_hom_id : (K.isoHomologyπ i j hi h).inv ≫ K.homologyπ j = 𝟙 _ := (K.isoHomologyπ i j hi h).inv_hom_id end section variable {K L} lemma epi_homologyMap_of_epi_of_not_rel (φ : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i] [Epi (φ.f i)] (hi : ∀ j, ¬ c.Rel i j) : Epi (homologyMap φ i) := ((MorphismProperty.epimorphisms C).arrow_mk_iso_iff (Arrow.isoMk (K.isoHomologyι i _ rfl (shape _ _ _ (by tauto))) (L.isoHomologyι i _ rfl (shape _ _ _ (by tauto))))).2 (MorphismProperty.epimorphisms.infer_property (opcyclesMap φ i)) lemma mono_homologyMap_of_mono_of_not_rel (φ : K ⟶ L) (j : ι) [K.HasHomology j] [L.HasHomology j] [Mono (φ.f j)] (hj : ∀ i, ¬ c.Rel i j) : Mono (homologyMap φ j) := ((MorphismProperty.monomorphisms C).arrow_mk_iso_iff (Arrow.isoMk (K.isoHomologyπ _ j rfl (shape _ _ _ (by tauto))) (L.isoHomologyπ _ j rfl (shape _ _ _ (by tauto))))).1 (MorphismProperty.monomorphisms.infer_property (cyclesMap φ j)) end /-- A homological complex `K` is exact at `i` if the short complex `K.sc i` is exact. -/ def ExactAt := (K.sc i).Exact lemma exactAt_iff : K.ExactAt i ↔ (K.sc i).Exact := by rfl variable {K i} in lemma ExactAt.of_iso (hK : K.ExactAt i) {L : HomologicalComplex C c} (e : K ≅ L) : L.ExactAt i := by rw [exactAt_iff] at hK ⊢ exact ShortComplex.exact_of_iso ((shortComplexFunctor C c i).mapIso e) hK lemma exactAt_iff' (hi : c.prev j = i) (hk : c.next j = k) : K.ExactAt j ↔ (K.sc' i j k).Exact := ShortComplex.exact_iff_of_iso (K.isoSc' i j k hi hk) lemma exactAt_iff_isZero_homology [K.HasHomology i] : K.ExactAt i ↔ IsZero (K.homology i) := by dsimp [homology] rw [exactAt_iff, ShortComplex.exact_iff_isZero_homology] variable {K i} in lemma ExactAt.isZero_homology [K.HasHomology i] (h : K.ExactAt i) : IsZero (K.homology i) := by rwa [← exactAt_iff_isZero_homology] /-- A homological complex `K` is acyclic if it is exact at `i` for any `i`. -/ def Acyclic := ∀ i, K.ExactAt i lemma acyclic_iff : K.Acyclic ↔ ∀ i, K.ExactAt i := by rfl lemma acyclic_of_isZero (hK : IsZero K) : K.Acyclic := by rw [acyclic_iff] intro i apply ShortComplex.exact_of_isZero_X₂ exact (eval _ _ i).map_isZero hK end HomologicalComplex namespace ChainComplex variable {C : Type} [Category C] [HasZeroMorphisms C] (K L : ChainComplex C ℕ) (φ : K ⟶ L) [K.HasHomology 0] instance isIso_homologyι₀ : IsIso (K.homologyι 0) := K.isIso_homologyι 0 _ rfl (by simp) /-- The canonical isomorphism `K.homology 0 ≅ K.opcycles 0` for a chain complex `K` indexed by `ℕ`. -/ noncomputable abbrev isoHomologyι₀ : K.homology 0 ≅ K.opcycles 0 := K.isoHomologyι 0 _ rfl (by simp) variable {K L} @[reassoc (attr := simp)] lemma isoHomologyι₀_inv_naturality [L.HasHomology 0] : K.isoHomologyι₀.inv ≫ HomologicalComplex.homologyMap φ 0 = HomologicalComplex.opcyclesMap φ 0 ≫ L.isoHomologyι₀.inv := by simp only [assoc, ← cancel_mono (L.homologyι 0), HomologicalComplex.homologyι_naturality, HomologicalComplex.isoHomologyι_inv_hom_id_assoc, HomologicalComplex.isoHomologyι_inv_hom_id, comp_id] end ChainComplex namespace CochainComplex variable {C : Type} [Category C] [HasZeroMorphisms C] (K L : CochainComplex C ℕ) (φ : K ⟶ L) [K.HasHomology 0] instance isIso_homologyπ₀ : IsIso (K.homologyπ 0) := K.isIso_homologyπ _ 0 rfl (by simp) /-- The canonical isomorphism `K.cycles 0 ≅ K.homology 0` for a cochain complex `K` indexed by `ℕ`. -/ noncomputable abbrev isoHomologyπ₀ : K.cycles 0 ≅ K.homology 0 := K.isoHomologyπ _ 0 rfl (by simp) variable {K L} @[reassoc (attr := simp)] lemma isoHomologyπ₀_inv_naturality [L.HasHomology 0] : HomologicalComplex.homologyMap φ 0 ≫ L.isoHomologyπ₀.inv = K.isoHomologyπ₀.inv ≫ HomologicalComplex.cyclesMap φ 0 := by simp only [← cancel_epi (K.homologyπ 0), HomologicalComplex.homologyπ_naturality_assoc, HomologicalComplex.isoHomologyπ_hom_inv_id, comp_id, HomologicalComplex.isoHomologyπ_hom_inv_id_assoc] end CochainComplex namespace HomologicalComplex variable {C ι : Type} [Category C] [Preadditive C] {c : ComplexShape ι} {K L : HomologicalComplex C c} {f g : K ⟶ L} variable (φ ψ : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i] @[simp] lemma homologyMap_neg : homologyMap (-φ) i = -homologyMap φ i := by dsimp [homologyMap] rw [← ShortComplex.homologyMap_neg] rfl @[simp] lemma homologyMap_add : homologyMap (φ + ψ) i = homologyMap φ i + homologyMap ψ i := by dsimp [homologyMap] rw [← ShortComplex.homologyMap_add] rfl @[simp] lemma homologyMap_sub : homologyMap (φ - ψ) i = homologyMap φ i - homologyMap ψ i := by dsimp [homologyMap] rw [← ShortComplex.homologyMap_sub] rfl instance [CategoryWithHomology C] : (homologyFunctor C c i).Additive where end HomologicalComplex namespace CochainComplex variable {C : Type} [Category C] [Abelian C] lemma isIso_liftCycles_iff (K : CochainComplex C ℕ) {X : C} (φ : X ⟶ K.X 0) [K.HasHomology 0] (hφ : φ ≫ K.d 0 1 = 0) : IsIso (K.liftCycles φ 1 (by simp) hφ) ↔ (ShortComplex.mk _ _ hφ).Exact ∧ Mono φ := by suffices ∀ (i : ℕ) (hx : (ComplexShape.up ℕ).next 0 = i) (hφ : φ ≫ K.d 0 i = 0), IsIso (K.liftCycles φ i hx hφ) ↔ (ShortComplex.mk _ _ hφ).Exact ∧ Mono φ from this 1 (by simp) hφ rintro _ rfl hφ let α : ShortComplex.mk (0 : X ⟶ X) (0 : X ⟶ X) (by simp) ⟶ K.sc 0 := { τ₁ := 0 τ₂ := φ τ₃ := 0 } exact (ShortComplex.quasiIso_iff_isIso_liftCycles α rfl rfl (by simp)).symm.trans (ShortComplex.quasiIso_iff_of_zeros α rfl rfl (by simp)) end CochainComplex namespace ChainComplex variable {C : Type} [Category C] [Abelian C] lemma isIso_descOpcycles_iff (K : ChainComplex C ℕ) {X : C} (φ : K.X 0 ⟶ X) [K.HasHomology 0] (hφ : K.d 1 0 ≫ φ = 0) : IsIso (K.descOpcycles φ 1 (by simp) hφ) ↔ (ShortComplex.mk _ _ hφ).Exact ∧ Epi φ := by suffices ∀ (i : ℕ) (hx : (ComplexShape.down ℕ).prev 0 = i) (hφ : K.d i 0 ≫ φ = 0), IsIso (K.descOpcycles φ i hx hφ) ↔ (ShortComplex.mk _ _ hφ).Exact ∧ Epi φ from this 1 (by simp) hφ rintro _ rfl hφ let α : K.sc 0 ⟶ ShortComplex.mk (0 : X ⟶ X) (0 : X ⟶ X) (by simp) := { τ₁ := 0 τ₂ := φ τ₃ := 0 } exact (ShortComplex.quasiIso_iff_isIso_descOpcycles α (by simp) rfl rfl).symm.trans (ShortComplex.quasiIso_iff_of_zeros' α (by simp) rfl rfl) end ChainComplex namespace HomologicalComplex variable {C : Type} [Category C] [HasZeroMorphisms C] {ι : Type*} {c : ComplexShape ι} (K : HomologicalComplex C c) (i j k : ι) (hi : c.prev j = i) (hk : c.next j = k) [K.HasHomology j] [(K.sc' i j k).HasHomology] /-- The cycles of a homological complex in degree `j` can be computed by specifying a choice of `c.prev j` and `c.next j`. -/ noncomputable def cyclesIsoSc' : K.cycles j ≅ (K.sc' i j k).cycles := ShortComplex.cyclesMapIso (K.isoSc' i j k hi hk) @[reassoc (attr := simp)] lemma cyclesIsoSc'_hom_iCycles : (K.cyclesIsoSc' i j k hi hk).hom ≫ (K.sc' i j k).iCycles = K.iCycles j := by dsimp [cyclesIsoSc'] simp only [ShortComplex.cyclesMap_i, shortComplexFunctor_obj_X₂, shortComplexFunctor'_obj_X₂, natIsoSc'_hom_app_τ₂, comp_id] rfl @[reassoc (attr := simp)] lemma cyclesIsoSc'_inv_iCycles : (K.cyclesIsoSc' i j k hi hk).inv ≫ K.iCycles j = (K.sc' i j k).iCycles := by dsimp [cyclesIsoSc'] erw [ShortComplex.cyclesMap_i] apply comp_id @[reassoc (attr := simp)] lemma toCycles_cyclesIsoSc'_hom : K.toCycles i j ≫ (K.cyclesIsoSc' i j k hi hk).hom = (K.sc' i j k).toCycles := by	simp only [← cancel_mono (K.sc' i j k).iCycles, assoc, cyclesIsoSc'_hom_iCycles, toCycles_i, ShortComplex.toCycles_i, shortComplexFunctor'_obj_f] /-- The homology of a homological complex in degree `j` can be computed by specifying a choice of `c.prev j` and `c.next j`. -/	Mathlib/Algebra/Homology/ShortComplex/HomologicalComplex.lean	792	796
/- 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	1,465	1,467
/- Copyright (c) 2019 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Sébastien Gouëzel, Yury Kudryashov -/ import Mathlib.Analysis.Analytic.Constructions import Mathlib.Analysis.Calculus.FDeriv.Analytic import Mathlib.Analysis.Calculus.FDeriv.Bilinear /-! # Multiplicative operations on derivatives For detailed documentation of the Fréchet derivative, see the module docstring of `Mathlib/Analysis/Calculus/FDeriv/Basic.lean`. This file contains the usual formulas (and existence assertions) for the derivative of * multiplication of a function by a scalar function * product of finitely many scalar functions * taking the pointwise multiplicative inverse (i.e. `Inv.inv` or `Ring.inverse`) of a function -/ open Asymptotics ContinuousLinearMap Topology section variable {𝕜 : Type} [NontriviallyNormedField 𝕜] variable {E : Type} [NormedAddCommGroup E] [NormedSpace 𝕜 E] variable {F : Type} [NormedAddCommGroup F] [NormedSpace 𝕜 F] variable {G : Type} [NormedAddCommGroup G] [NormedSpace 𝕜 G] variable {f : E → F} variable {f' : E →L[𝕜] F} variable {x : E} variable {s : Set E} section CLMCompApply /-! ### Derivative of the pointwise composition/application of continuous linear maps -/ variable {H : Type} [NormedAddCommGroup H] [NormedSpace 𝕜 H] {c : E → G →L[𝕜] H} {c' : E →L[𝕜] G →L[𝕜] H} {d : E → F →L[𝕜] G} {d' : E →L[𝕜] F →L[𝕜] G} {u : E → G} {u' : E →L[𝕜] G} #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 split proof term into steps to solve unification issues. -/ @[fun_prop] theorem HasStrictFDerivAt.clm_comp (hc : HasStrictFDerivAt c c' x) (hd : HasStrictFDerivAt d d' x) : HasStrictFDerivAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') x := by have := isBoundedBilinearMap_comp.hasStrictFDerivAt (c x, d x) have := this.comp x (hc.prodMk hd) exact this #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.clm_comp (hc : HasFDerivWithinAt c c' s x) (hd : HasFDerivWithinAt d d' s x) : HasFDerivWithinAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') s x := by exact (isBoundedBilinearMap_comp.hasFDerivAt (c x, d x) :).comp_hasFDerivWithinAt x (hc.prodMk hd) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.clm_comp (hc : HasFDerivAt c c' x) (hd : HasFDerivAt d d' x) : HasFDerivAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') x := by exact (isBoundedBilinearMap_comp.hasFDerivAt (c x, d x) :).comp x <\| hc.prodMk hd @[fun_prop] theorem DifferentiableWithinAt.clm_comp (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : DifferentiableWithinAt 𝕜 (fun y => (c y).comp (d y)) s x := (hc.hasFDerivWithinAt.clm_comp hd.hasFDerivWithinAt).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.clm_comp (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : DifferentiableAt 𝕜 (fun y => (c y).comp (d y)) x := (hc.hasFDerivAt.clm_comp hd.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.clm_comp (hc : DifferentiableOn 𝕜 c s) (hd : DifferentiableOn 𝕜 d s) : DifferentiableOn 𝕜 (fun y => (c y).comp (d y)) s := fun x hx => (hc x hx).clm_comp (hd x hx) @[fun_prop] theorem Differentiable.clm_comp (hc : Differentiable 𝕜 c) (hd : Differentiable 𝕜 d) : Differentiable 𝕜 fun y => (c y).comp (d y) := fun x => (hc x).clm_comp (hd x) theorem fderivWithin_clm_comp (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : fderivWithin 𝕜 (fun y => (c y).comp (d y)) s x = (compL 𝕜 F G H (c x)).comp (fderivWithin 𝕜 d s x) + ((compL 𝕜 F G H).flip (d x)).comp (fderivWithin 𝕜 c s x) := (hc.hasFDerivWithinAt.clm_comp hd.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_clm_comp (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : fderiv 𝕜 (fun y => (c y).comp (d y)) x = (compL 𝕜 F G H (c x)).comp (fderiv 𝕜 d x) + ((compL 𝕜 F G H).flip (d x)).comp (fderiv 𝕜 c x) := (hc.hasFDerivAt.clm_comp hd.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.clm_apply (hc : HasStrictFDerivAt c c' x) (hu : HasStrictFDerivAt u u' x) : HasStrictFDerivAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) x := (isBoundedBilinearMap_apply.hasStrictFDerivAt (c x, u x)).comp x (hc.prodMk hu) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.clm_apply (hc : HasFDerivWithinAt c c' s x) (hu : HasFDerivWithinAt u u' s x) : HasFDerivWithinAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) s x := by exact (isBoundedBilinearMap_apply.hasFDerivAt (c x, u x) :).comp_hasFDerivWithinAt x (hc.prodMk hu) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.clm_apply (hc : HasFDerivAt c c' x) (hu : HasFDerivAt u u' x) : HasFDerivAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) x := by exact (isBoundedBilinearMap_apply.hasFDerivAt (c x, u x) :).comp x (hc.prodMk hu) @[fun_prop] theorem DifferentiableWithinAt.clm_apply (hc : DifferentiableWithinAt 𝕜 c s x) (hu : DifferentiableWithinAt 𝕜 u s x) : DifferentiableWithinAt 𝕜 (fun y => (c y) (u y)) s x := (hc.hasFDerivWithinAt.clm_apply hu.hasFDerivWithinAt).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.clm_apply (hc : DifferentiableAt 𝕜 c x) (hu : DifferentiableAt 𝕜 u x) : DifferentiableAt 𝕜 (fun y => (c y) (u y)) x := (hc.hasFDerivAt.clm_apply hu.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.clm_apply (hc : DifferentiableOn 𝕜 c s) (hu : DifferentiableOn 𝕜 u s) : DifferentiableOn 𝕜 (fun y => (c y) (u y)) s := fun x hx => (hc x hx).clm_apply (hu x hx) @[fun_prop] theorem Differentiable.clm_apply (hc : Differentiable 𝕜 c) (hu : Differentiable 𝕜 u) : Differentiable 𝕜 fun y => (c y) (u y) := fun x => (hc x).clm_apply (hu x) theorem fderivWithin_clm_apply (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hu : DifferentiableWithinAt 𝕜 u s x) : fderivWithin 𝕜 (fun y => (c y) (u y)) s x = (c x).comp (fderivWithin 𝕜 u s x) + (fderivWithin 𝕜 c s x).flip (u x) := (hc.hasFDerivWithinAt.clm_apply hu.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_clm_apply (hc : DifferentiableAt 𝕜 c x) (hu : DifferentiableAt 𝕜 u x) : fderiv 𝕜 (fun y => (c y) (u y)) x = (c x).comp (fderiv 𝕜 u x) + (fderiv 𝕜 c x).flip (u x) := (hc.hasFDerivAt.clm_apply hu.hasFDerivAt).fderiv end CLMCompApply section ContinuousMultilinearApplyConst /-! ### Derivative of the application of continuous multilinear maps to a constant -/ variable {ι : Type} [Fintype ι] {M : ι → Type} [∀ i, NormedAddCommGroup (M i)] [∀ i, NormedSpace 𝕜 (M i)] {H : Type} [NormedAddCommGroup H] [NormedSpace 𝕜 H] {c : E → ContinuousMultilinearMap 𝕜 M H} {c' : E →L[𝕜] ContinuousMultilinearMap 𝕜 M H} @[fun_prop] theorem HasStrictFDerivAt.continuousMultilinear_apply_const (hc : HasStrictFDerivAt c c' x) (u : ∀ i, M i) : HasStrictFDerivAt (fun y ↦ (c y) u) (c'.flipMultilinear u) x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasStrictFDerivAt.comp x hc @[fun_prop] theorem HasFDerivWithinAt.continuousMultilinear_apply_const (hc : HasFDerivWithinAt c c' s x) (u : ∀ i, M i) : HasFDerivWithinAt (fun y ↦ (c y) u) (c'.flipMultilinear u) s x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasFDerivAt.comp_hasFDerivWithinAt x hc @[fun_prop] theorem HasFDerivAt.continuousMultilinear_apply_const (hc : HasFDerivAt c c' x) (u : ∀ i, M i) : HasFDerivAt (fun y ↦ (c y) u) (c'.flipMultilinear u) x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasFDerivAt.comp x hc @[fun_prop] theorem DifferentiableWithinAt.continuousMultilinear_apply_const (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) : DifferentiableWithinAt 𝕜 (fun y ↦ (c y) u) s x := (hc.hasFDerivWithinAt.continuousMultilinear_apply_const u).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.continuousMultilinear_apply_const (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) : DifferentiableAt 𝕜 (fun y ↦ (c y) u) x := (hc.hasFDerivAt.continuousMultilinear_apply_const u).differentiableAt @[fun_prop] theorem DifferentiableOn.continuousMultilinear_apply_const (hc : DifferentiableOn 𝕜 c s) (u : ∀ i, M i) : DifferentiableOn 𝕜 (fun y ↦ (c y) u) s := fun x hx ↦ (hc x hx).continuousMultilinear_apply_const u @[fun_prop] theorem Differentiable.continuousMultilinear_apply_const (hc : Differentiable 𝕜 c) (u : ∀ i, M i) : Differentiable 𝕜 fun y ↦ (c y) u := fun x ↦ (hc x).continuousMultilinear_apply_const u theorem fderivWithin_continuousMultilinear_apply_const (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) : fderivWithin 𝕜 (fun y ↦ (c y) u) s x = ((fderivWithin 𝕜 c s x).flipMultilinear u) := (hc.hasFDerivWithinAt.continuousMultilinear_apply_const u).fderivWithin hxs theorem fderiv_continuousMultilinear_apply_const (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) : (fderiv 𝕜 (fun y ↦ (c y) u) x) = (fderiv 𝕜 c x).flipMultilinear u := (hc.hasFDerivAt.continuousMultilinear_apply_const u).fderiv /-- Application of a `ContinuousMultilinearMap` to a constant commutes with `fderivWithin`. -/ theorem fderivWithin_continuousMultilinear_apply_const_apply (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) (m : E) : (fderivWithin 𝕜 (fun y ↦ (c y) u) s x) m = (fderivWithin 𝕜 c s x) m u := by simp [fderivWithin_continuousMultilinear_apply_const hxs hc] /-- Application of a `ContinuousMultilinearMap` to a constant commutes with `fderiv`. -/ theorem fderiv_continuousMultilinear_apply_const_apply (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) (m : E) : (fderiv 𝕜 (fun y ↦ (c y) u) x) m = (fderiv 𝕜 c x) m u := by simp [fderiv_continuousMultilinear_apply_const hc] end ContinuousMultilinearApplyConst section SMul /-! ### Derivative of the product of a scalar-valued function and a vector-valued function If `c` is a differentiable scalar-valued function and `f` is a differentiable vector-valued function, then `fun x ↦ c x • f x` is differentiable as well. Lemmas in this section works for function `c` taking values in the base field, as well as in a normed algebra over the base field: e.g., they work for `c : E → ℂ` and `f : E → F` provided that `F` is a complex normed vector space. -/ variable {𝕜' : Type} [NontriviallyNormedField 𝕜'] [NormedAlgebra 𝕜 𝕜'] [NormedSpace 𝕜' F] [IsScalarTower 𝕜 𝕜' F] variable {c : E → 𝕜'} {c' : E →L[𝕜] 𝕜'} @[fun_prop] theorem HasStrictFDerivAt.smul (hc : HasStrictFDerivAt c c' x) (hf : HasStrictFDerivAt f f' x) : HasStrictFDerivAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) x := (isBoundedBilinearMap_smul.hasStrictFDerivAt (c x, f x)).comp x <\| hc.prodMk hf #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.smul (hc : HasFDerivWithinAt c c' s x) (hf : HasFDerivWithinAt f f' s x) : HasFDerivWithinAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) s x := by exact (isBoundedBilinearMap_smul.hasFDerivAt (𝕜 := 𝕜) (c x, f x) :).comp_hasFDerivWithinAt x <\| hc.prodMk hf #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.smul (hc : HasFDerivAt c c' x) (hf : HasFDerivAt f f' x) : HasFDerivAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) x := by exact (isBoundedBilinearMap_smul.hasFDerivAt (𝕜 := 𝕜) (c x, f x) :).comp x <\| hc.prodMk hf @[fun_prop] theorem DifferentiableWithinAt.smul (hc : DifferentiableWithinAt 𝕜 c s x) (hf : DifferentiableWithinAt 𝕜 f s x) : DifferentiableWithinAt 𝕜 (fun y => c y • f y) s x := (hc.hasFDerivWithinAt.smul hf.hasFDerivWithinAt).differentiableWithinAt @[simp, fun_prop] theorem DifferentiableAt.smul (hc : DifferentiableAt 𝕜 c x) (hf : DifferentiableAt 𝕜 f x) : DifferentiableAt 𝕜 (fun y => c y • f y) x := (hc.hasFDerivAt.smul hf.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.smul (hc : DifferentiableOn 𝕜 c s) (hf : DifferentiableOn 𝕜 f s) : DifferentiableOn 𝕜 (fun y => c y • f y) s := fun x hx => (hc x hx).smul (hf x hx) @[simp, fun_prop] theorem Differentiable.smul (hc : Differentiable 𝕜 c) (hf : Differentiable 𝕜 f) : Differentiable 𝕜 fun y => c y • f y := fun x => (hc x).smul (hf x) theorem fderivWithin_smul (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hf : DifferentiableWithinAt 𝕜 f s x) : fderivWithin 𝕜 (fun y => c y • f y) s x = c x • fderivWithin 𝕜 f s x + (fderivWithin 𝕜 c s x).smulRight (f x) := (hc.hasFDerivWithinAt.smul hf.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_smul (hc : DifferentiableAt 𝕜 c x) (hf : DifferentiableAt 𝕜 f x) : fderiv 𝕜 (fun y => c y • f y) x = c x • fderiv 𝕜 f x + (fderiv 𝕜 c x).smulRight (f x) := (hc.hasFDerivAt.smul hf.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.smul_const (hc : HasStrictFDerivAt c c' x) (f : F) : HasStrictFDerivAt (fun y => c y • f) (c'.smulRight f) x := by simpa only [smul_zero, zero_add] using hc.smul (hasStrictFDerivAt_const f x) @[fun_prop] theorem HasFDerivWithinAt.smul_const (hc : HasFDerivWithinAt c c' s x) (f : F) : HasFDerivWithinAt (fun y => c y • f) (c'.smulRight f) s x := by simpa only [smul_zero, zero_add] using hc.smul (hasFDerivWithinAt_const f x s) @[fun_prop] theorem HasFDerivAt.smul_const (hc : HasFDerivAt c c' x) (f : F) : HasFDerivAt (fun y => c y • f) (c'.smulRight f) x := by simpa only [smul_zero, zero_add] using hc.smul (hasFDerivAt_const f x) @[fun_prop] theorem DifferentiableWithinAt.smul_const (hc : DifferentiableWithinAt 𝕜 c s x) (f : F) : DifferentiableWithinAt 𝕜 (fun y => c y • f) s x := (hc.hasFDerivWithinAt.smul_const f).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.smul_const (hc : DifferentiableAt 𝕜 c x) (f : F) : DifferentiableAt 𝕜 (fun y => c y • f) x := (hc.hasFDerivAt.smul_const f).differentiableAt @[fun_prop] theorem DifferentiableOn.smul_const (hc : DifferentiableOn 𝕜 c s) (f : F) : DifferentiableOn 𝕜 (fun y => c y • f) s := fun x hx => (hc x hx).smul_const f @[fun_prop] theorem Differentiable.smul_const (hc : Differentiable 𝕜 c) (f : F) : Differentiable 𝕜 fun y => c y • f := fun x => (hc x).smul_const f theorem fderivWithin_smul_const (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (f : F) : fderivWithin 𝕜 (fun y => c y • f) s x = (fderivWithin 𝕜 c s x).smulRight f := (hc.hasFDerivWithinAt.smul_const f).fderivWithin hxs theorem fderiv_smul_const (hc : DifferentiableAt 𝕜 c x) (f : F) : fderiv 𝕜 (fun y => c y • f) x = (fderiv 𝕜 c x).smulRight f := (hc.hasFDerivAt.smul_const f).fderiv end SMul section Mul /-! ### Derivative of the product of two functions -/ variable {𝔸 𝔸' : Type} [NormedRing 𝔸] [NormedCommRing 𝔸'] [NormedAlgebra 𝕜 𝔸] [NormedAlgebra 𝕜 𝔸'] {a b : E → 𝔸} {a' b' : E →L[𝕜] 𝔸} {c d : E → 𝔸'} {c' d' : E →L[𝕜] 𝔸'} @[fun_prop] theorem HasStrictFDerivAt.mul' {x : E} (ha : HasStrictFDerivAt a a' x) (hb : HasStrictFDerivAt b b' x) : HasStrictFDerivAt (fun y => a y * b y) (a x • b' + a'.smulRight (b x)) x := ((ContinuousLinearMap.mul 𝕜 𝔸).isBoundedBilinearMap.hasStrictFDerivAt (a x, b x)).comp x (ha.prodMk hb) @[fun_prop] theorem HasStrictFDerivAt.mul (hc : HasStrictFDerivAt c c' x) (hd : HasStrictFDerivAt d d' x) : HasStrictFDerivAt (fun y => c y * d y) (c x • d' + d x • c') x := by convert hc.mul' hd ext z apply mul_comm #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.mul' (ha : HasFDerivWithinAt a a' s x) (hb : HasFDerivWithinAt b b' s x) : HasFDerivWithinAt (fun y => a y * b y) (a x • b' + a'.smulRight (b x)) s x := by exact ((ContinuousLinearMap.mul 𝕜 𝔸).isBoundedBilinearMap.hasFDerivAt (a x, b x)).comp_hasFDerivWithinAt x (ha.prodMk hb) @[fun_prop] theorem HasFDerivWithinAt.mul (hc : HasFDerivWithinAt c c' s x) (hd : HasFDerivWithinAt d d' s x) : HasFDerivWithinAt (fun y => c y * d y) (c x • d' + d x • c') s x := by convert hc.mul' hd ext z apply mul_comm #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.mul' (ha : HasFDerivAt a a' x) (hb : HasFDerivAt b b' x) : HasFDerivAt (fun y => a y * b y) (a x • b' + a'.smulRight (b x)) x := by exact ((ContinuousLinearMap.mul 𝕜 𝔸).isBoundedBilinearMap.hasFDerivAt (a x, b x)).comp x (ha.prodMk hb) @[fun_prop] theorem HasFDerivAt.mul (hc : HasFDerivAt c c' x) (hd : HasFDerivAt d d' x) : HasFDerivAt (fun y => c y * d y) (c x • d' + d x • c') x := by convert hc.mul' hd ext z apply mul_comm @[fun_prop] theorem DifferentiableWithinAt.mul (ha : DifferentiableWithinAt 𝕜 a s x) (hb : DifferentiableWithinAt 𝕜 b s x) : DifferentiableWithinAt 𝕜 (fun y => a y * b y) s x := (ha.hasFDerivWithinAt.mul' hb.hasFDerivWithinAt).differentiableWithinAt @[simp, fun_prop] theorem DifferentiableAt.mul (ha : DifferentiableAt 𝕜 a x) (hb : DifferentiableAt 𝕜 b x) : DifferentiableAt 𝕜 (fun y => a y * b y) x := (ha.hasFDerivAt.mul' hb.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.mul (ha : DifferentiableOn 𝕜 a s) (hb : DifferentiableOn 𝕜 b s) : DifferentiableOn 𝕜 (fun y => a y * b y) s := fun x hx => (ha x hx).mul (hb x hx) @[simp, fun_prop] theorem Differentiable.mul (ha : Differentiable 𝕜 a) (hb : Differentiable 𝕜 b) : Differentiable 𝕜 fun y => a y * b y := fun x => (ha x).mul (hb x) @[fun_prop] theorem DifferentiableWithinAt.pow (ha : DifferentiableWithinAt 𝕜 a s x) : ∀ n : ℕ, DifferentiableWithinAt 𝕜 (fun x => a x ^ n) s x \| 0 => by simp only [pow_zero, differentiableWithinAt_const] \| n + 1 => by simp only [pow_succ', DifferentiableWithinAt.pow ha n, ha.mul] @[simp, fun_prop] theorem DifferentiableAt.pow (ha : DifferentiableAt 𝕜 a x) (n : ℕ) : DifferentiableAt 𝕜 (fun x => a x ^ n) x := differentiableWithinAt_univ.mp <\| ha.differentiableWithinAt.pow n @[fun_prop] theorem DifferentiableOn.pow (ha : DifferentiableOn 𝕜 a s) (n : ℕ) : DifferentiableOn 𝕜 (fun x => a x ^ n) s := fun x h => (ha x h).pow n @[simp, fun_prop] theorem Differentiable.pow (ha : Differentiable 𝕜 a) (n : ℕ) : Differentiable 𝕜 fun x => a x ^ n := fun x => (ha x).pow n theorem fderivWithin_mul' (hxs : UniqueDiffWithinAt 𝕜 s x) (ha : DifferentiableWithinAt 𝕜 a s x) (hb : DifferentiableWithinAt 𝕜 b s x) : fderivWithin 𝕜 (fun y => a y * b y) s x = a x • fderivWithin 𝕜 b s x + (fderivWithin 𝕜 a s x).smulRight (b x) := (ha.hasFDerivWithinAt.mul' hb.hasFDerivWithinAt).fderivWithin hxs theorem fderivWithin_mul (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : fderivWithin 𝕜 (fun y => c y * d y) s x = c x • fderivWithin 𝕜 d s x + d x • fderivWithin 𝕜 c s x := (hc.hasFDerivWithinAt.mul hd.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_mul' (ha : DifferentiableAt 𝕜 a x) (hb : DifferentiableAt 𝕜 b x) : fderiv 𝕜 (fun y => a y * b y) x = a x • fderiv 𝕜 b x + (fderiv 𝕜 a x).smulRight (b x) := (ha.hasFDerivAt.mul' hb.hasFDerivAt).fderiv theorem fderiv_mul (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : fderiv 𝕜 (fun y => c y * d y) x = c x • fderiv 𝕜 d x + d x • fderiv 𝕜 c x := (hc.hasFDerivAt.mul hd.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.mul_const' (ha : HasStrictFDerivAt a a' x) (b : 𝔸) : HasStrictFDerivAt (fun y => a y * b) (a'.smulRight b) x := ((ContinuousLinearMap.mul 𝕜 𝔸).flip b).hasStrictFDerivAt.comp x ha @[fun_prop] theorem HasStrictFDerivAt.mul_const (hc : HasStrictFDerivAt c c' x) (d : 𝔸') : HasStrictFDerivAt (fun y => c y * d) (d • c') x := by convert hc.mul_const' d ext z apply mul_comm @[fun_prop] theorem HasFDerivWithinAt.mul_const' (ha : HasFDerivWithinAt a a' s x) (b : 𝔸) : HasFDerivWithinAt (fun y => a y * b) (a'.smulRight b) s x := ((ContinuousLinearMap.mul 𝕜 𝔸).flip b).hasFDerivAt.comp_hasFDerivWithinAt x ha @[fun_prop] theorem HasFDerivWithinAt.mul_const (hc : HasFDerivWithinAt c c' s x) (d : 𝔸') : HasFDerivWithinAt (fun y => c y * d) (d • c') s x := by convert hc.mul_const' d ext z apply mul_comm @[fun_prop] theorem HasFDerivAt.mul_const' (ha : HasFDerivAt a a' x) (b : 𝔸) : HasFDerivAt (fun y => a y * b) (a'.smulRight b) x := ((ContinuousLinearMap.mul 𝕜 𝔸).flip b).hasFDerivAt.comp x ha @[fun_prop] theorem HasFDerivAt.mul_const (hc : HasFDerivAt c c' x) (d : 𝔸') : HasFDerivAt (fun y => c y * d) (d • c') x := by convert hc.mul_const' d ext z apply mul_comm @[fun_prop] theorem DifferentiableWithinAt.mul_const (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : DifferentiableWithinAt 𝕜 (fun y => a y * b) s x := (ha.hasFDerivWithinAt.mul_const' b).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.mul_const (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : DifferentiableAt 𝕜 (fun y => a y * b) x := (ha.hasFDerivAt.mul_const' b).differentiableAt @[fun_prop] theorem DifferentiableOn.mul_const (ha : DifferentiableOn 𝕜 a s) (b : 𝔸) : DifferentiableOn 𝕜 (fun y => a y * b) s := fun x hx => (ha x hx).mul_const b @[fun_prop] theorem Differentiable.mul_const (ha : Differentiable 𝕜 a) (b : 𝔸) : Differentiable 𝕜 fun y => a y * b := fun x => (ha x).mul_const b theorem fderivWithin_mul_const' (hxs : UniqueDiffWithinAt 𝕜 s x) (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : fderivWithin 𝕜 (fun y => a y * b) s x = (fderivWithin 𝕜 a s x).smulRight b := (ha.hasFDerivWithinAt.mul_const' b).fderivWithin hxs theorem fderivWithin_mul_const (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (d : 𝔸') : fderivWithin 𝕜 (fun y => c y * d) s x = d • fderivWithin 𝕜 c s x := (hc.hasFDerivWithinAt.mul_const d).fderivWithin hxs theorem fderiv_mul_const' (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : fderiv 𝕜 (fun y => a y * b) x = (fderiv 𝕜 a x).smulRight b := (ha.hasFDerivAt.mul_const' b).fderiv theorem fderiv_mul_const (hc : DifferentiableAt 𝕜 c x) (d : 𝔸') : fderiv 𝕜 (fun y => c y * d) x = d • fderiv 𝕜 c x := (hc.hasFDerivAt.mul_const d).fderiv @[fun_prop] theorem HasStrictFDerivAt.const_mul (ha : HasStrictFDerivAt a a' x) (b : 𝔸) : HasStrictFDerivAt (fun y => b * a y) (b • a') x := ((ContinuousLinearMap.mul 𝕜 𝔸) b).hasStrictFDerivAt.comp x ha @[fun_prop] theorem HasFDerivWithinAt.const_mul (ha : HasFDerivWithinAt a a' s x) (b : 𝔸) : HasFDerivWithinAt (fun y => b * a y) (b • a') s x := ((ContinuousLinearMap.mul 𝕜 𝔸) b).hasFDerivAt.comp_hasFDerivWithinAt x ha @[fun_prop] theorem HasFDerivAt.const_mul (ha : HasFDerivAt a a' x) (b : 𝔸) : HasFDerivAt (fun y => b * a y) (b • a') x := ((ContinuousLinearMap.mul 𝕜 𝔸) b).hasFDerivAt.comp x ha @[fun_prop] theorem DifferentiableWithinAt.const_mul (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : DifferentiableWithinAt 𝕜 (fun y => b * a y) s x := (ha.hasFDerivWithinAt.const_mul b).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.const_mul (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : DifferentiableAt 𝕜 (fun y => b * a y) x := (ha.hasFDerivAt.const_mul b).differentiableAt @[fun_prop] theorem DifferentiableOn.const_mul (ha : DifferentiableOn 𝕜 a s) (b : 𝔸) : DifferentiableOn 𝕜 (fun y => b * a y) s := fun x hx => (ha x hx).const_mul b @[fun_prop] theorem Differentiable.const_mul (ha : Differentiable 𝕜 a) (b : 𝔸) : Differentiable 𝕜 fun y => b * a y := fun x => (ha x).const_mul b theorem fderivWithin_const_mul (hxs : UniqueDiffWithinAt 𝕜 s x) (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : fderivWithin 𝕜 (fun y => b * a y) s x = b • fderivWithin 𝕜 a s x := (ha.hasFDerivWithinAt.const_mul b).fderivWithin hxs theorem fderiv_const_mul (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : fderiv 𝕜 (fun y => b * a y) x = b • fderiv 𝕜 a x := (ha.hasFDerivAt.const_mul b).fderiv end Mul section Prod /-! ### Derivative of a finite product of functions -/ variable {ι : Type} {𝔸 𝔸' : Type} [NormedRing 𝔸] [NormedCommRing 𝔸'] [NormedAlgebra 𝕜 𝔸] [NormedAlgebra 𝕜 𝔸'] {u : Finset ι} {f : ι → E → 𝔸} {f' : ι → E →L[𝕜] 𝔸} {g : ι → E → 𝔸'} {g' : ι → E →L[𝕜] 𝔸'} @[fun_prop] theorem hasStrictFDerivAt_list_prod' [Fintype ι] {l : List ι} {x : ι → 𝔸} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.map x).prod) (∑ i : Fin l.length, ((l.take i).map x).prod • smulRight (proj l[i]) ((l.drop (.succ i)).map x).prod) x := by induction l with \| nil => simp [hasStrictFDerivAt_const] \| cons a l IH => simp only [List.map_cons, List.prod_cons, ← proj_apply (R := 𝕜) (φ := fun _ : ι ↦ 𝔸) a] exact .congr_fderiv (.mul' (ContinuousLinearMap.hasStrictFDerivAt _) IH) (by ext; simp [Fin.sum_univ_succ, Finset.mul_sum, mul_assoc, add_comm]) @[fun_prop] theorem hasStrictFDerivAt_list_prod_finRange' {n : ℕ} {x : Fin n → 𝔸} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ ((List.finRange n).map x).prod) (∑ i : Fin n, (((List.finRange n).take i).map x).prod • smulRight (proj i) (((List.finRange n).drop (.succ i)).map x).prod) x := hasStrictFDerivAt_list_prod'.congr_fderiv <\| Finset.sum_equiv (finCongr List.length_finRange) (by simp) (by simp [Fin.forall_iff]) @[fun_prop] theorem hasStrictFDerivAt_list_prod_attach' {l : List ι} {x : {i // i ∈ l} → 𝔸} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.attach.map x).prod) (∑ i : Fin l.length, ((l.attach.take i).map x).prod • smulRight (proj l.attach[i.cast List.length_attach.symm]) ((l.attach.drop (.succ i)).map x).prod) x := by classical exact hasStrictFDerivAt_list_prod'.congr_fderiv <\| Eq.symm <\| Finset.sum_equiv (finCongr List.length_attach.symm) (by simp) (by simp) @[fun_prop] theorem hasFDerivAt_list_prod' [Fintype ι] {l : List ι} {x : ι → 𝔸'} : HasFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.map x).prod) (∑ i : Fin l.length, ((l.take i).map x).prod • smulRight (proj l[i]) ((l.drop (.succ i)).map x).prod) x := hasStrictFDerivAt_list_prod'.hasFDerivAt @[fun_prop] theorem hasFDerivAt_list_prod_finRange' {n : ℕ} {x : Fin n → 𝔸} : HasFDerivAt (𝕜 := 𝕜) (fun x ↦ ((List.finRange n).map x).prod) (∑ i : Fin n, (((List.finRange n).take i).map x).prod • smulRight (proj i) (((List.finRange n).drop (.succ i)).map x).prod) x := (hasStrictFDerivAt_list_prod_finRange').hasFDerivAt @[fun_prop] theorem hasFDerivAt_list_prod_attach' {l : List ι} {x : {i // i ∈ l} → 𝔸} : HasFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.attach.map x).prod) (∑ i : Fin l.length, ((l.attach.take i).map x).prod • smulRight (proj l.attach[i.cast List.length_attach.symm]) ((l.attach.drop (.succ i)).map x).prod) x := by classical exact hasStrictFDerivAt_list_prod_attach'.hasFDerivAt /-- Auxiliary lemma for `hasStrictFDerivAt_multiset_prod`. For `NormedCommRing 𝔸'`, can rewrite as `Multiset` using `Multiset.prod_coe`. -/ @[fun_prop] theorem hasStrictFDerivAt_list_prod [DecidableEq ι] [Fintype ι] {l : List ι} {x : ι → 𝔸'} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.map x).prod) (l.map fun i ↦ ((l.erase i).map x).prod • proj i).sum x := by refine hasStrictFDerivAt_list_prod'.congr_fderiv ?_	conv_rhs => arg 1; arg 2; rw [← List.finRange_map_get l] simp only [List.map_map, ← List.sum_toFinset _ (List.nodup_finRange _), List.toFinset_finRange, Function.comp_def, ((List.erase_getElem _).map _).prod_eq, List.eraseIdx_eq_take_drop_succ, List.map_append, List.prod_append, List.get_eq_getElem, Fin.getElem_fin, Nat.succ_eq_add_one] exact Finset.sum_congr rfl fun i _ ↦ by ext; simp only [smul_apply, smulRight_apply, smul_eq_mul]; ring @[fun_prop] theorem hasStrictFDerivAt_multiset_prod [DecidableEq ι] [Fintype ι] {u : Multiset ι} {x : ι → 𝔸'} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (u.map x).prod)	Mathlib/Analysis/Calculus/FDeriv/Mul.lean	629	638
/- Copyright (c) 2018 Patrick Massot. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Patrick Massot, Johannes Hölzl, Yaël Dillies -/ import Mathlib.Analysis.Normed.Group.Continuity import Mathlib.Topology.Algebra.IsUniformGroup.Basic import Mathlib.Topology.MetricSpace.Algebra import Mathlib.Topology.MetricSpace.IsometricSMul /-! # Normed groups are uniform groups This file proves lipschitzness of normed group operations and shows that normed groups are uniform groups. -/ variable {𝓕 E F : Type} open Filter Function Metric Bornology open scoped ENNReal NNReal Uniformity Pointwise Topology section SeminormedGroup variable [SeminormedGroup E] [SeminormedGroup F] {s : Set E} {a b : E} {r : ℝ} @[to_additive] instance NormedGroup.to_isIsometricSMul_right : IsIsometricSMul Eᵐᵒᵖ E := ⟨fun a => Isometry.of_dist_eq fun b c => by simp [dist_eq_norm_div]⟩ @[to_additive] theorem Isometry.norm_map_of_map_one {f : E → F} (hi : Isometry f) (h₁ : f 1 = 1) (x : E) : ‖f x‖ = ‖x‖ := by rw [← dist_one_right, ← h₁, hi.dist_eq, dist_one_right] @[to_additive (attr := simp)] theorem dist_mul_self_right (a b : E) : dist b (a b) = ‖a‖ := by rw [← dist_one_left, ← dist_mul_right 1 a b, one_mul] @[to_additive (attr := simp)] theorem dist_mul_self_left (a b : E) : dist (a * b) b = ‖a‖ := by rw [dist_comm, dist_mul_self_right] @[to_additive (attr := simp)] theorem dist_div_eq_dist_mul_left (a b c : E) : dist (a / b) c = dist a (c * b) := by rw [← dist_mul_right _ _ b, div_mul_cancel] @[to_additive (attr := simp)] theorem dist_div_eq_dist_mul_right (a b c : E) : dist a (b / c) = dist (a * c) b := by rw [← dist_mul_right _ _ c, div_mul_cancel] open Finset variable [FunLike 𝓕 E F] /-- A homomorphism `f` of seminormed groups is Lipschitz, if there exists a constant `C` such that for all `x`, one has `‖f x‖ ≤ C * ‖x‖`. The analogous condition for a linear map of (semi)normed spaces is in `Mathlib/Analysis/NormedSpace/OperatorNorm.lean`. -/ @[to_additive "A homomorphism `f` of seminormed groups is Lipschitz, if there exists a constant `C` such that for all `x`, one has `‖f x‖ ≤ C * ‖x‖`. The analogous condition for a linear map of (semi)normed spaces is in `Mathlib/Analysis/NormedSpace/OperatorNorm.lean`."] theorem MonoidHomClass.lipschitz_of_bound [MonoidHomClass 𝓕 E F] (f : 𝓕) (C : ℝ) (h : ∀ x, ‖f x‖ ≤ C * ‖x‖) : LipschitzWith (Real.toNNReal C) f := LipschitzWith.of_dist_le' fun x y => by simpa only [dist_eq_norm_div, map_div] using h (x / y) @[to_additive] theorem lipschitzOnWith_iff_norm_div_le {f : E → F} {C : ℝ≥0} : LipschitzOnWith C f s ↔ ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → ‖f x / f y‖ ≤ C * ‖x / y‖ := by simp only [lipschitzOnWith_iff_dist_le_mul, dist_eq_norm_div] alias ⟨LipschitzOnWith.norm_div_le, _⟩ := lipschitzOnWith_iff_norm_div_le attribute [to_additive] LipschitzOnWith.norm_div_le @[to_additive] theorem LipschitzOnWith.norm_div_le_of_le {f : E → F} {C : ℝ≥0} (h : LipschitzOnWith C f s) (ha : a ∈ s) (hb : b ∈ s) (hr : ‖a / b‖ ≤ r) : ‖f a / f b‖ ≤ C * r := (h.norm_div_le ha hb).trans <\| by gcongr @[to_additive] theorem lipschitzWith_iff_norm_div_le {f : E → F} {C : ℝ≥0} : LipschitzWith C f ↔ ∀ x y, ‖f x / f y‖ ≤ C * ‖x / y‖ := by simp only [lipschitzWith_iff_dist_le_mul, dist_eq_norm_div] alias ⟨LipschitzWith.norm_div_le, _⟩ := lipschitzWith_iff_norm_div_le attribute [to_additive] LipschitzWith.norm_div_le @[to_additive] theorem LipschitzWith.norm_div_le_of_le {f : E → F} {C : ℝ≥0} (h : LipschitzWith C f) (hr : ‖a / b‖ ≤ r) : ‖f a / f b‖ ≤ C * r := (h.norm_div_le _ _).trans <\| by gcongr /-- A homomorphism `f` of seminormed groups is continuous, if there exists a constant `C` such that for all `x`, one has `‖f x‖ ≤ C * ‖x‖`. -/ @[to_additive "A homomorphism `f` of seminormed groups is continuous, if there exists a constant `C` such that for all `x`, one has `‖f x‖ ≤ C * ‖x‖`"] theorem MonoidHomClass.continuous_of_bound [MonoidHomClass 𝓕 E F] (f : 𝓕) (C : ℝ) (h : ∀ x, ‖f x‖ ≤ C * ‖x‖) : Continuous f := (MonoidHomClass.lipschitz_of_bound f C h).continuous @[to_additive] theorem MonoidHomClass.uniformContinuous_of_bound [MonoidHomClass 𝓕 E F] (f : 𝓕) (C : ℝ) (h : ∀ x, ‖f x‖ ≤ C * ‖x‖) : UniformContinuous f := (MonoidHomClass.lipschitz_of_bound f C h).uniformContinuous @[to_additive] theorem MonoidHomClass.isometry_iff_norm [MonoidHomClass 𝓕 E F] (f : 𝓕) : Isometry f ↔ ∀ x, ‖f x‖ = ‖x‖ := by simp only [isometry_iff_dist_eq, dist_eq_norm_div, ← map_div] refine ⟨fun h x => ?_, fun h x y => h _⟩ simpa using h x 1 alias ⟨_, MonoidHomClass.isometry_of_norm⟩ := MonoidHomClass.isometry_iff_norm attribute [to_additive] MonoidHomClass.isometry_of_norm section NNNorm @[to_additive] theorem MonoidHomClass.lipschitz_of_bound_nnnorm [MonoidHomClass 𝓕 E F] (f : 𝓕) (C : ℝ≥0) (h : ∀ x, ‖f x‖₊ ≤ C * ‖x‖₊) : LipschitzWith C f := @Real.toNNReal_coe C ▸ MonoidHomClass.lipschitz_of_bound f C h @[to_additive] theorem MonoidHomClass.antilipschitz_of_bound [MonoidHomClass 𝓕 E F] (f : 𝓕) {K : ℝ≥0} (h : ∀ x, ‖x‖ ≤ K * ‖f x‖) : AntilipschitzWith K f := AntilipschitzWith.of_le_mul_dist fun x y => by simpa only [dist_eq_norm_div, map_div] using h (x / y) @[to_additive LipschitzWith.norm_le_mul] theorem LipschitzWith.norm_le_mul' {f : E → F} {K : ℝ≥0} (h : LipschitzWith K f) (hf : f 1 = 1) (x) : ‖f x‖ ≤ K * ‖x‖ := by simpa only [dist_one_right, hf] using h.dist_le_mul x 1 @[to_additive LipschitzWith.nnorm_le_mul] theorem LipschitzWith.nnorm_le_mul' {f : E → F} {K : ℝ≥0} (h : LipschitzWith K f) (hf : f 1 = 1) (x) : ‖f x‖₊ ≤ K * ‖x‖₊ := h.norm_le_mul' hf x @[to_additive AntilipschitzWith.le_mul_norm] theorem AntilipschitzWith.le_mul_norm' {f : E → F} {K : ℝ≥0} (h : AntilipschitzWith K f) (hf : f 1 = 1) (x) : ‖x‖ ≤ K * ‖f x‖ := by simpa only [dist_one_right, hf] using h.le_mul_dist x 1 @[to_additive AntilipschitzWith.le_mul_nnnorm] theorem AntilipschitzWith.le_mul_nnnorm' {f : E → F} {K : ℝ≥0} (h : AntilipschitzWith K f) (hf : f 1 = 1) (x) : ‖x‖₊ ≤ K * ‖f x‖₊ := h.le_mul_norm' hf x @[to_additive] theorem OneHomClass.bound_of_antilipschitz [OneHomClass 𝓕 E F] (f : 𝓕) {K : ℝ≥0} (h : AntilipschitzWith K f) (x) : ‖x‖ ≤ K * ‖f x‖ := h.le_mul_nnnorm' (map_one f) x @[to_additive] theorem Isometry.nnnorm_map_of_map_one {f : E → F} (hi : Isometry f) (h₁ : f 1 = 1) (x : E) : ‖f x‖₊ = ‖x‖₊ := Subtype.ext <\| hi.norm_map_of_map_one h₁ x end NNNorm @[to_additive lipschitzWith_one_norm] theorem lipschitzWith_one_norm' : LipschitzWith 1 (norm : E → ℝ) := by simpa using LipschitzWith.dist_right (1 : E) @[to_additive lipschitzWith_one_nnnorm] theorem lipschitzWith_one_nnnorm' : LipschitzWith 1 (NNNorm.nnnorm : E → ℝ≥0) := lipschitzWith_one_norm' @[to_additive uniformContinuous_norm] theorem uniformContinuous_norm' : UniformContinuous (norm : E → ℝ) := lipschitzWith_one_norm'.uniformContinuous @[to_additive uniformContinuous_nnnorm] theorem uniformContinuous_nnnorm' : UniformContinuous fun a : E => ‖a‖₊ := uniformContinuous_norm'.subtype_mk _ end SeminormedGroup section SeminormedCommGroup variable [SeminormedCommGroup E] [SeminormedCommGroup F] {a₁ a₂ b₁ b₂ : E} {r₁ r₂ : ℝ} @[to_additive] instance NormedGroup.to_isIsometricSMul_left : IsIsometricSMul E E := ⟨fun a => Isometry.of_dist_eq fun b c => by simp [dist_eq_norm_div]⟩ @[to_additive (attr := simp)] theorem dist_self_mul_right (a b : E) : dist a (a * b) = ‖b‖ := by rw [← dist_one_left, ← dist_mul_left a 1 b, mul_one] @[to_additive (attr := simp)] theorem dist_self_mul_left (a b : E) : dist (a * b) a = ‖b‖ := by rw [dist_comm, dist_self_mul_right] @[to_additive (attr := simp 1001)] -- Increase priority because `simp` can prove this theorem dist_self_div_right (a b : E) : dist a (a / b) = ‖b‖ := by rw [div_eq_mul_inv, dist_self_mul_right, norm_inv'] @[to_additive (attr := simp 1001)] -- Increase priority because `simp` can prove this theorem dist_self_div_left (a b : E) : dist (a / b) a = ‖b‖ := by rw [dist_comm, dist_self_div_right] @[to_additive] theorem dist_mul_mul_le (a₁ a₂ b₁ b₂ : E) : dist (a₁ * a₂) (b₁ * b₂) ≤ dist a₁ b₁ + dist a₂ b₂ := by simpa only [dist_mul_left, dist_mul_right] using dist_triangle (a₁ * a₂) (b₁ * a₂) (b₁ * b₂) @[to_additive] theorem dist_mul_mul_le_of_le (h₁ : dist a₁ b₁ ≤ r₁) (h₂ : dist a₂ b₂ ≤ r₂) : dist (a₁ * a₂) (b₁ * b₂) ≤ r₁ + r₂ := (dist_mul_mul_le a₁ a₂ b₁ b₂).trans <\| add_le_add h₁ h₂ @[to_additive] theorem dist_div_div_le (a₁ a₂ b₁ b₂ : E) : dist (a₁ / a₂) (b₁ / b₂) ≤ dist a₁ b₁ + dist a₂ b₂ := by simpa only [div_eq_mul_inv, dist_inv_inv] using dist_mul_mul_le a₁ a₂⁻¹ b₁ b₂⁻¹ @[to_additive] theorem dist_div_div_le_of_le (h₁ : dist a₁ b₁ ≤ r₁) (h₂ : dist a₂ b₂ ≤ r₂) : dist (a₁ / a₂) (b₁ / b₂) ≤ r₁ + r₂ := (dist_div_div_le a₁ a₂ b₁ b₂).trans <\| add_le_add h₁ h₂ @[to_additive] theorem abs_dist_sub_le_dist_mul_mul (a₁ a₂ b₁ b₂ : E) : \|dist a₁ b₁ - dist a₂ b₂\| ≤ dist (a₁ * a₂) (b₁ * b₂) := by simpa only [dist_mul_left, dist_mul_right, dist_comm b₂] using abs_dist_sub_le (a₁ * a₂) (b₁ * b₂) (b₁ * a₂) open Finset @[to_additive] theorem nndist_mul_mul_le (a₁ a₂ b₁ b₂ : E) : nndist (a₁ * a₂) (b₁ * b₂) ≤ nndist a₁ b₁ + nndist a₂ b₂ := NNReal.coe_le_coe.1 <\| dist_mul_mul_le a₁ a₂ b₁ b₂ @[to_additive] theorem edist_mul_mul_le (a₁ a₂ b₁ b₂ : E) : edist (a₁ * a₂) (b₁ * b₂) ≤ edist a₁ b₁ + edist a₂ b₂ := by simp only [edist_nndist] norm_cast apply nndist_mul_mul_le section PseudoEMetricSpace variable {α E : Type*} [SeminormedCommGroup E] [PseudoEMetricSpace α] {K Kf Kg : ℝ≥0} {f g : α → E} {s : Set α}	@[to_additive (attr := simp)] lemma lipschitzWith_inv_iff : LipschitzWith K f⁻¹ ↔ LipschitzWith K f := by simp [LipschitzWith]	Mathlib/Analysis/Normed/Group/Uniform.lean	244	245
/- 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.Algebra.BigOperators.NatAntidiagonal import Mathlib.Topology.Algebra.InfiniteSum.Constructions import Mathlib.Topology.Algebra.Ring.Basic /-! # Infinite sum in a ring This file provides lemmas about the interaction between infinite sums and multiplication. ## Main results * `tsum_mul_tsum_eq_tsum_sum_antidiagonal`: Cauchy product formula -/ open Filter Finset Function variable {ι κ α : Type} section NonUnitalNonAssocSemiring variable [NonUnitalNonAssocSemiring α] [TopologicalSpace α] [IsTopologicalSemiring α] {f : ι → α} {a₁ : α} theorem HasSum.mul_left (a₂) (h : HasSum f a₁) : HasSum (fun i ↦ a₂ f i) (a₂ * a₁) := by simpa only using h.map (AddMonoidHom.mulLeft a₂) (continuous_const.mul continuous_id) theorem HasSum.mul_right (a₂) (hf : HasSum f a₁) : HasSum (fun i ↦ f i * a₂) (a₁ * a₂) := by simpa only using hf.map (AddMonoidHom.mulRight a₂) (continuous_id.mul continuous_const) theorem Summable.mul_left (a) (hf : Summable f) : Summable fun i ↦ a * f i := (hf.hasSum.mul_left _).summable theorem Summable.mul_right (a) (hf : Summable f) : Summable fun i ↦ f i * a := (hf.hasSum.mul_right _).summable section tsum variable [T2Space α] protected theorem Summable.tsum_mul_left (a) (hf : Summable f) : ∑' i, a * f i = a * ∑' i, f i := (hf.hasSum.mul_left _).tsum_eq protected theorem Summable.tsum_mul_right (a) (hf : Summable f) : ∑' i, f i * a = (∑' i, f i) * a := (hf.hasSum.mul_right _).tsum_eq theorem Commute.tsum_right (a) (h : ∀ i, Commute a (f i)) : Commute a (∑' i, f i) := by classical by_cases hf : Summable f · exact (hf.tsum_mul_left a).symm.trans ((congr_arg _ <\| funext h).trans (hf.tsum_mul_right a)) · exact (tsum_eq_zero_of_not_summable hf).symm ▸ Commute.zero_right _ theorem Commute.tsum_left (a) (h : ∀ i, Commute (f i) a) : Commute (∑' i, f i) a := (Commute.tsum_right _ fun i ↦ (h i).symm).symm end tsum end NonUnitalNonAssocSemiring section DivisionSemiring variable [DivisionSemiring α] [TopologicalSpace α] [IsTopologicalSemiring α] {f : ι → α} {a a₁ a₂ : α} theorem HasSum.div_const (h : HasSum f a) (b : α) : HasSum (fun i ↦ f i / b) (a / b) := by simp only [div_eq_mul_inv, h.mul_right b⁻¹] theorem Summable.div_const (h : Summable f) (b : α) : Summable fun i ↦ f i / b := (h.hasSum.div_const _).summable theorem hasSum_mul_left_iff (h : a₂ ≠ 0) : HasSum (fun i ↦ a₂ * f i) (a₂ * a₁) ↔ HasSum f a₁ := ⟨fun H ↦ by simpa only [inv_mul_cancel_left₀ h] using H.mul_left a₂⁻¹, HasSum.mul_left _⟩ theorem hasSum_mul_right_iff (h : a₂ ≠ 0) : HasSum (fun i ↦ f i * a₂) (a₁ * a₂) ↔ HasSum f a₁ := ⟨fun H ↦ by simpa only [mul_inv_cancel_right₀ h] using H.mul_right a₂⁻¹, HasSum.mul_right _⟩ theorem hasSum_div_const_iff (h : a₂ ≠ 0) : HasSum (fun i ↦ f i / a₂) (a₁ / a₂) ↔ HasSum f a₁ := by simpa only [div_eq_mul_inv] using hasSum_mul_right_iff (inv_ne_zero h) theorem summable_mul_left_iff (h : a ≠ 0) : (Summable fun i ↦ a * f i) ↔ Summable f := ⟨fun H ↦ by simpa only [inv_mul_cancel_left₀ h] using H.mul_left a⁻¹, fun H ↦ H.mul_left _⟩ theorem summable_mul_right_iff (h : a ≠ 0) : (Summable fun i ↦ f i * a) ↔ Summable f := ⟨fun H ↦ by simpa only [mul_inv_cancel_right₀ h] using H.mul_right a⁻¹, fun H ↦ H.mul_right _⟩ theorem summable_div_const_iff (h : a ≠ 0) : (Summable fun i ↦ f i / a) ↔ Summable f := by simpa only [div_eq_mul_inv] using summable_mul_right_iff (inv_ne_zero h) theorem tsum_mul_left [T2Space α] : ∑' x, a * f x = a * ∑' x, f x := by classical exact if hf : Summable f then hf.tsum_mul_left a else if ha : a = 0 then by simp [ha] else by rw [tsum_eq_zero_of_not_summable hf, tsum_eq_zero_of_not_summable (mt (summable_mul_left_iff ha).mp hf), mul_zero] theorem tsum_mul_right [T2Space α] : ∑' x, f x * a = (∑' x, f x) * a := by classical exact if hf : Summable f then hf.tsum_mul_right a else if ha : a = 0 then by simp [ha] else by rw [tsum_eq_zero_of_not_summable hf,	tsum_eq_zero_of_not_summable (mt (summable_mul_right_iff ha).mp hf), zero_mul]	Mathlib/Topology/Algebra/InfiniteSum/Ring.lean	105	106
/- Copyright (c) 2021 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison, Antoine Chambert-Loir, María Inés de Frutos-Fernández -/ import Mathlib.Algebra.Algebra.Subalgebra.Lattice import Mathlib.Algebra.Algebra.Tower import Mathlib.Topology.Algebra.Module.LinearMap /-! # Topological (sub)algebras A topological algebra over a topological semiring `R` is a topological semiring with a compatible continuous scalar multiplication by elements of `R`. We reuse typeclass `ContinuousSMul` for topological algebras. ## Results The topological closure of a subalgebra is still a subalgebra, which as an algebra is a topological algebra. In this file we define continuous algebra homomorphisms, as algebra homomorphisms between topological (semi-)rings which are continuous. The set of continuous algebra homomorphisms between the topological `R`-algebras `A` and `B` is denoted by `A →A[R] B`. TODO: add continuous algebra isomorphisms. -/ assert_not_exists Basis open Algebra Set TopologicalSpace Topology universe u v w section TopologicalAlgebra variable (R : Type) (A : Type u) variable [CommSemiring R] [Semiring A] [Algebra R A] variable [TopologicalSpace R] [TopologicalSpace A] @[continuity, fun_prop] theorem continuous_algebraMap [ContinuousSMul R A] : Continuous (algebraMap R A) := by rw [algebraMap_eq_smul_one'] exact continuous_id.smul continuous_const theorem continuous_algebraMap_iff_smul [ContinuousMul A] : Continuous (algebraMap R A) ↔ Continuous fun p : R × A => p.1 • p.2 := by refine ⟨fun h => ?_, fun h => have : ContinuousSMul R A := ⟨h⟩; continuous_algebraMap _ _⟩ simp only [Algebra.smul_def] exact (h.comp continuous_fst).mul continuous_snd theorem continuousSMul_of_algebraMap [ContinuousMul A] (h : Continuous (algebraMap R A)) : ContinuousSMul R A := ⟨(continuous_algebraMap_iff_smul R A).1 h⟩ instance Subalgebra.continuousSMul (S : Subalgebra R A) (X) [TopologicalSpace X] [MulAction A X] [ContinuousSMul A X] : ContinuousSMul S X := Subsemiring.continuousSMul S.toSubsemiring X section variable [ContinuousSMul R A] /-- The inclusion of the base ring in a topological algebra as a continuous linear map. -/ @[simps] def algebraMapCLM : R →L[R] A := { Algebra.linearMap R A with toFun := algebraMap R A cont := continuous_algebraMap R A } theorem algebraMapCLM_coe : ⇑(algebraMapCLM R A) = algebraMap R A := rfl theorem algebraMapCLM_toLinearMap : (algebraMapCLM R A).toLinearMap = Algebra.linearMap R A := rfl end /-- If `R` is a discrete topological ring, then any topological ring `S` which is an `R`-algebra is also a topological `R`-algebra. NB: This could be an instance but the signature makes it very expensive in search. See https://github.com/leanprover-community/mathlib4/pull/15339 for the regressions caused by making this an instance. -/ theorem DiscreteTopology.instContinuousSMul [IsTopologicalSemiring A] [DiscreteTopology R] : ContinuousSMul R A := continuousSMul_of_algebraMap _ _ continuous_of_discreteTopology end TopologicalAlgebra section TopologicalAlgebra section variable (R : Type) [CommSemiring R] (A : Type) [Semiring A] /-- Continuous algebra homomorphisms between algebras. We only put the type classes that are necessary for the definition, although in applications `M` and `B` will be topological algebras over the topological ring `R`. -/ structure ContinuousAlgHom (R : Type) [CommSemiring R] (A : Type) [Semiring A] [TopologicalSpace A] (B : Type) [Semiring B] [TopologicalSpace B] [Algebra R A] [Algebra R B] extends A →ₐ[R] B where -- TODO: replace with `fun_prop` when that is stable cont : Continuous toFun := by continuity @[inherit_doc] notation:25 A " →A[" R "] " B => ContinuousAlgHom R A B namespace ContinuousAlgHom section Semiring variable {R} {A} variable [TopologicalSpace A] variable {B : Type*} [Semiring B] [TopologicalSpace B] [Algebra R A] [Algebra R B] instance : FunLike (A →A[R] B) A B where coe f := f.toAlgHom coe_injective' f g h := by cases f; cases g simp only [mk.injEq] exact AlgHom.ext (congrFun h) instance : AlgHomClass (A →A[R] B) R A B where map_mul f x y := map_mul f.toAlgHom x y map_one f := map_one f.toAlgHom map_add f := map_add f.toAlgHom map_zero f := map_zero f.toAlgHom	commutes f r := f.toAlgHom.commutes r @[simp] theorem toAlgHom_eq_coe (f : A →A[R] B) : f.toAlgHom = f := rfl @[simp, norm_cast] theorem coe_inj {f g : A →A[R] B} : (f : A →ₐ[R] B) = g ↔ f = g := by cases f; cases g; simp only [mk.injEq]; exact Eq.congr_right rfl	Mathlib/Topology/Algebra/Algebra.lean	130	137
/- 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	Mathlib/Data/Complex/Exponential.lean	665	665
/- Copyright (c) 2021 Alena Gusakov, Bhavik Mehta, Kyle Miller. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Alena Gusakov, Bhavik Mehta, Kyle Miller -/ import Mathlib.Data.Fintype.Basic import Mathlib.Data.Fintype.Powerset import Mathlib.Data.Set.Finite.Basic /-! # Hall's Marriage Theorem for finite index types This module proves the basic form of Hall's theorem. In contrast to the theorem described in `Combinatorics.Hall.Basic`, this version requires that the indexed family `t : ι → Finset α` have `ι` be finite. The `Combinatorics.Hall.Basic` module applies a compactness argument to this version to remove the `Finite` constraint on `ι`. The modules are split like this since the generalized statement depends on the topology and category theory libraries, but the finite case in this module has few dependencies. A description of this formalization is in [Gusakov2021]. ## Main statements * `Finset.all_card_le_biUnion_card_iff_existsInjective'` is Hall's theorem with a finite index set. This is elsewhere generalized to `Finset.all_card_le_biUnion_card_iff_existsInjective`. ## Tags Hall's Marriage Theorem, indexed families -/ open Finset universe u v namespace HallMarriageTheorem variable {ι : Type u} {α : Type v} [DecidableEq α] {t : ι → Finset α} section Fintype variable [Fintype ι] theorem hall_cond_of_erase {x : ι} (a : α) (ha : ∀ s : Finset ι, s.Nonempty → s ≠ univ → #s < #(s.biUnion t)) (s' : Finset { x' : ι \| x' ≠ x }) : #s' ≤ #(s'.biUnion fun x' => (t x').erase a) := by haveI := Classical.decEq ι specialize ha (s'.image fun z => z.1) rw [image_nonempty, Finset.card_image_of_injective s' Subtype.coe_injective] at ha by_cases he : s'.Nonempty · have ha' : #s' < #(s'.biUnion fun x => t x) := by convert ha he fun h => by simpa [← h] using mem_univ x using 2 ext x simp only [mem_image, mem_biUnion, exists_prop, SetCoe.exists, exists_and_right, exists_eq_right, Subtype.coe_mk] rw [← erase_biUnion] by_cases hb : a ∈ s'.biUnion fun x => t x · rw [card_erase_of_mem hb] exact Nat.le_sub_one_of_lt ha' · rw [erase_eq_of_not_mem hb] exact Nat.le_of_lt ha' · rw [nonempty_iff_ne_empty, not_not] at he subst s' simp /-- First case of the inductive step: assuming that `∀ (s : Finset ι), s.Nonempty → s ≠ univ → #s < #(s.biUnion t)` and that the statement of Hall's Marriage Theorem is true for all `ι'` of cardinality ≤ `n`, then it is true for `ι` of cardinality `n + 1`. -/ theorem hall_hard_inductive_step_A {n : ℕ} (hn : Fintype.card ι = n + 1) (ht : ∀ s : Finset ι, #s ≤ #(s.biUnion t))	(ih : ∀ {ι' : Type u} [Fintype ι'] (t' : ι' → Finset α), Fintype.card ι' ≤ n → (∀ s' : Finset ι', #s' ≤ #(s'.biUnion t')) → ∃ f : ι' → α, Function.Injective f ∧ ∀ x, f x ∈ t' x) (ha : ∀ s : Finset ι, s.Nonempty → s ≠ univ → #s < #(s.biUnion t)) : ∃ f : ι → α, Function.Injective f ∧ ∀ x, f x ∈ t x := by haveI : Nonempty ι := Fintype.card_pos_iff.mp (hn.symm ▸ Nat.succ_pos _) haveI := Classical.decEq ι -- Choose an arbitrary element `x : ι` and `y : t x`. let x := Classical.arbitrary ι have tx_ne : (t x).Nonempty := by rw [← Finset.card_pos] calc 0 < 1 := Nat.one_pos _ ≤ #(.biUnion {x} t) := ht {x} _ = (t x).card := by rw [Finset.singleton_biUnion] choose y hy using tx_ne -- Restrict to everything except `x` and `y`. let ι' := { x' : ι \| x' ≠ x } let t' : ι' → Finset α := fun x' => (t x').erase y have card_ι' : Fintype.card ι' = n := calc Fintype.card ι' = Fintype.card ι - 1 := Set.card_ne_eq _ _ = n := by rw [hn, Nat.add_succ_sub_one, add_zero] rcases ih t' card_ι'.le (hall_cond_of_erase y ha) with ⟨f', hfinj, hfr⟩ -- Extend the resulting function. refine ⟨fun z => if h : z = x then y else f' ⟨z, h⟩, ?_, ?_⟩ · rintro z₁ z₂ have key : ∀ {x}, y ≠ f' x := by intro x h simpa [t', ← h] using hfr x by_cases h₁ : z₁ = x <;> by_cases h₂ : z₂ = x <;> simp [h₁, h₂, hfinj.eq_iff, key, key.symm] · intro z simp only [ne_eq, Set.mem_setOf_eq] split_ifs with hz · rwa [hz] · specialize hfr ⟨z, hz⟩ rw [mem_erase] at hfr exact hfr.2	Mathlib/Combinatorics/Hall/Finite.lean	78	121
/- Copyright (c) 2020 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison -/ import Mathlib.CategoryTheory.Monoidal.Discrete import Mathlib.CategoryTheory.Monoidal.NaturalTransformation import Mathlib.CategoryTheory.Monoidal.Opposite import Mathlib.Tactic.CategoryTheory.Monoidal.Basic import Mathlib.CategoryTheory.CommSq /-! # Braided and symmetric monoidal categories The basic definitions of braided monoidal categories, and symmetric monoidal categories, as well as braided functors. ## Implementation note We make `BraidedCategory` another typeclass, but then have `SymmetricCategory` extend this. The rationale is that we are not carrying any additional data, just requiring a property. ## Future work * Construct the Drinfeld center of a monoidal category as a braided monoidal category. * Say something about pseudo-natural transformations. ## References * [Pavel Etingof, Shlomo Gelaki, Dmitri Nikshych, Victor Ostrik, Tensor categories][egno15] -/ universe v v₁ v₂ v₃ u u₁ u₂ u₃ namespace CategoryTheory open Category MonoidalCategory Functor.LaxMonoidal Functor.OplaxMonoidal Functor.Monoidal /-- A braided monoidal category is a monoidal category equipped with a braiding isomorphism `β_ X Y : X ⊗ Y ≅ Y ⊗ X` which is natural in both arguments, and also satisfies the two hexagon identities. -/ class BraidedCategory (C : Type u) [Category.{v} C] [MonoidalCategory.{v} C] where /-- The braiding natural isomorphism. -/ braiding : ∀ X Y : C, X ⊗ Y ≅ Y ⊗ X braiding_naturality_right : ∀ (X : C) {Y Z : C} (f : Y ⟶ Z), X ◁ f ≫ (braiding X Z).hom = (braiding X Y).hom ≫ f ▷ X := by aesop_cat braiding_naturality_left : ∀ {X Y : C} (f : X ⟶ Y) (Z : C), f ▷ Z ≫ (braiding Y Z).hom = (braiding X Z).hom ≫ Z ◁ f := by aesop_cat /-- The first hexagon identity. -/ hexagon_forward : ∀ X Y Z : C, (α_ X Y Z).hom ≫ (braiding X (Y ⊗ Z)).hom ≫ (α_ Y Z X).hom = ((braiding X Y).hom ▷ Z) ≫ (α_ Y X Z).hom ≫ (Y ◁ (braiding X Z).hom) := by aesop_cat /-- The second hexagon identity. -/ hexagon_reverse : ∀ X Y Z : C, (α_ X Y Z).inv ≫ (braiding (X ⊗ Y) Z).hom ≫ (α_ Z X Y).inv = (X ◁ (braiding Y Z).hom) ≫ (α_ X Z Y).inv ≫ ((braiding X Z).hom ▷ Y) := by aesop_cat attribute [reassoc (attr := simp)] BraidedCategory.braiding_naturality_left BraidedCategory.braiding_naturality_right attribute [reassoc] BraidedCategory.hexagon_forward BraidedCategory.hexagon_reverse open BraidedCategory @[inherit_doc] notation "β_" => BraidedCategory.braiding namespace BraidedCategory variable {C : Type u} [Category.{v} C] [MonoidalCategory.{v} C] [BraidedCategory.{v} C] @[simp, reassoc] theorem braiding_tensor_left (X Y Z : C) : (β_ (X ⊗ Y) Z).hom = (α_ X Y Z).hom ≫ X ◁ (β_ Y Z).hom ≫ (α_ X Z Y).inv ≫ (β_ X Z).hom ▷ Y ≫ (α_ Z X Y).hom := by apply (cancel_epi (α_ X Y Z).inv).1 apply (cancel_mono (α_ Z X Y).inv).1 simp [hexagon_reverse] @[simp, reassoc] theorem braiding_tensor_right (X Y Z : C) : (β_ X (Y ⊗ Z)).hom = (α_ X Y Z).inv ≫ (β_ X Y).hom ▷ Z ≫ (α_ Y X Z).hom ≫ Y ◁ (β_ X Z).hom ≫ (α_ Y Z X).inv := by apply (cancel_epi (α_ X Y Z).hom).1 apply (cancel_mono (α_ Y Z X).hom).1 simp [hexagon_forward] @[simp, reassoc] theorem braiding_inv_tensor_left (X Y Z : C) : (β_ (X ⊗ Y) Z).inv = (α_ Z X Y).inv ≫ (β_ X Z).inv ▷ Y ≫ (α_ X Z Y).hom ≫ X ◁ (β_ Y Z).inv ≫ (α_ X Y Z).inv := eq_of_inv_eq_inv (by simp) @[simp, reassoc] theorem braiding_inv_tensor_right (X Y Z : C) : (β_ X (Y ⊗ Z)).inv = (α_ Y Z X).hom ≫ Y ◁ (β_ X Z).inv ≫ (α_ Y X Z).inv ≫ (β_ X Y).inv ▷ Z ≫ (α_ X Y Z).hom := eq_of_inv_eq_inv (by simp) @[reassoc (attr := simp)] theorem braiding_naturality {X X' Y Y' : C} (f : X ⟶ Y) (g : X' ⟶ Y') : (f ⊗ g) ≫ (braiding Y Y').hom = (braiding X X').hom ≫ (g ⊗ f) := by rw [tensorHom_def' f g, tensorHom_def g f] simp_rw [Category.assoc, braiding_naturality_left, braiding_naturality_right_assoc] @[reassoc (attr := simp)] theorem braiding_inv_naturality_right (X : C) {Y Z : C} (f : Y ⟶ Z) : X ◁ f ≫ (β_ Z X).inv = (β_ Y X).inv ≫ f ▷ X := CommSq.w <\| .vert_inv <\| .mk <\| braiding_naturality_left f X @[reassoc (attr := simp)] theorem braiding_inv_naturality_left {X Y : C} (f : X ⟶ Y) (Z : C) : f ▷ Z ≫ (β_ Z Y).inv = (β_ Z X).inv ≫ Z ◁ f := CommSq.w <\| .vert_inv <\| .mk <\| braiding_naturality_right Z f @[reassoc (attr := simp)] theorem braiding_inv_naturality {X X' Y Y' : C} (f : X ⟶ Y) (g : X' ⟶ Y') : (f ⊗ g) ≫ (β_ Y' Y).inv = (β_ X' X).inv ≫ (g ⊗ f) := CommSq.w <\| .vert_inv <\| .mk <\| braiding_naturality g f /-- In a braided monoidal category, the functors `tensorLeft X` and `tensorRight X` are isomorphic. -/ @[simps] def tensorLeftIsoTensorRight (X : C) : tensorLeft X ≅ tensorRight X where hom := { app Y := (β_ X Y).hom } inv := { app Y := (β_ X Y).inv } @[reassoc] theorem yang_baxter (X Y Z : C) : (α_ X Y Z).inv ≫ (β_ X Y).hom ▷ Z ≫ (α_ Y X Z).hom ≫ Y ◁ (β_ X Z).hom ≫ (α_ Y Z X).inv ≫ (β_ Y Z).hom ▷ X ≫ (α_ Z Y X).hom = X ◁ (β_ Y Z).hom ≫ (α_ X Z Y).inv ≫ (β_ X Z).hom ▷ Y ≫ (α_ Z X Y).hom ≫ Z ◁ (β_ X Y).hom := by rw [← braiding_tensor_right_assoc X Y Z, ← cancel_mono (α_ Z Y X).inv] repeat rw [assoc] rw [Iso.hom_inv_id, comp_id, ← braiding_naturality_right, braiding_tensor_right]	theorem yang_baxter' (X Y Z : C) : (β_ X Y).hom ▷ Z ⊗≫ Y ◁ (β_ X Z).hom ⊗≫ (β_ Y Z).hom ▷ X = 𝟙 _ ⊗≫ (X ◁ (β_ Y Z).hom ⊗≫ (β_ X Z).hom ▷ Y ⊗≫ Z ◁ (β_ X Y).hom) ⊗≫ 𝟙 _ := by rw [← cancel_epi (α_ X Y Z).inv, ← cancel_mono (α_ Z Y X).hom] convert yang_baxter X Y Z using 1	Mathlib/CategoryTheory/Monoidal/Braided/Basic.lean	155	160
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Kevin Kappelmann -/ import Mathlib.Algebra.Order.Floor.Defs import Mathlib.Algebra.Order.Floor.Ring import Mathlib.Algebra.Order.Floor.Semiring deprecated_module (since := "2025-04-13")		Mathlib/Algebra/Order/Floor.lean	1,203	1,204
/- Copyright (c) 2022 Robert Y. Lewis. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Robert Y. Lewis, Heather Macbeth -/ import Mathlib.Algebra.MvPolynomial.Supported import Mathlib.RingTheory.WittVector.Truncated /-! # Leading terms of Witt vector multiplication The goal of this file is to study the leading terms of the formula for the `n+1`st coefficient of a product of Witt vectors `x` and `y` over a ring of characteristic `p`. We aim to isolate the `n+1`st coefficients of `x` and `y`, and express the rest of the product in terms of a function of the lower coefficients. For most of this file we work with terms of type `MvPolynomial (Fin 2 × ℕ) ℤ`. We will eventually evaluate them in `k`, but first we must take care of a calculation that needs to happen in characteristic 0. ## Main declarations * `WittVector.nth_mul_coeff`: expresses the coefficient of a product of Witt vectors in terms of the previous coefficients of the multiplicands. -/ noncomputable section namespace WittVector variable (p : ℕ) [hp : Fact p.Prime] variable {k : Type} [CommRing k] local notation "𝕎" => WittVector p -- Porting note: new notation local notation "𝕄" => MvPolynomial (Fin 2 × ℕ) ℤ open Finset MvPolynomial /-- ``` (∑ i ∈ range n, (y.coeff i)^(p^(n-i)) p^i.val) * (∑ i ∈ range n, (y.coeff i)^(p^(n-i)) * p^i.val) ``` -/ def wittPolyProd (n : ℕ) : 𝕄 := rename (Prod.mk (0 : Fin 2)) (wittPolynomial p ℤ n) * rename (Prod.mk (1 : Fin 2)) (wittPolynomial p ℤ n) theorem wittPolyProd_vars (n : ℕ) : (wittPolyProd p n).vars ⊆ univ ×ˢ range (n + 1) := by rw [wittPolyProd] apply Subset.trans (vars_mul _ _) refine union_subset ?_ ?_ <;> · refine Subset.trans (vars_rename _ _) ?_ simp [wittPolynomial_vars, image_subset_iff] /-- The "remainder term" of `WittVector.wittPolyProd`. See `mul_polyOfInterest_aux2`. -/ def wittPolyProdRemainder (n : ℕ) : 𝕄 := ∑ i ∈ range n, (p : 𝕄) ^ i * wittMul p i ^ p ^ (n - i) theorem wittPolyProdRemainder_vars (n : ℕ) : (wittPolyProdRemainder p n).vars ⊆ univ ×ˢ range n := by rw [wittPolyProdRemainder] refine Subset.trans (vars_sum_subset _ _) ?_ rw [biUnion_subset] intro x hx apply Subset.trans (vars_mul _ _) refine union_subset ?_ ?_ · apply Subset.trans (vars_pow _ _) have : (p : 𝕄) = C (p : ℤ) := by simp only [Int.cast_natCast, eq_intCast] rw [this, vars_C] apply empty_subset · apply Subset.trans (vars_pow _ _) apply Subset.trans (wittMul_vars _ _) apply product_subset_product (Subset.refl _) simp only [mem_range, range_subset] at hx ⊢ exact hx /-- `remainder p n` represents the remainder term from `mul_polyOfInterest_aux3`. `wittPolyProd p (n+1)` will have variables up to `n+1`, but `remainder` will only have variables up to `n`. -/ def remainder (n : ℕ) : 𝕄 := (∑ x ∈ range (n + 1), (rename (Prod.mk 0)) ((monomial (Finsupp.single x (p ^ (n + 1 - x)))) ((p : ℤ) ^ x))) * ∑ x ∈ range (n + 1), (rename (Prod.mk 1)) ((monomial (Finsupp.single x (p ^ (n + 1 - x)))) ((p : ℤ) ^ x)) theorem remainder_vars (n : ℕ) : (remainder p n).vars ⊆ univ ×ˢ range (n + 1) := by rw [remainder] apply Subset.trans (vars_mul _ _) refine union_subset ?_ ?_ <;> · refine Subset.trans (vars_sum_subset _ _) ?_ rw [biUnion_subset] intro x hx rw [rename_monomial, vars_monomial, Finsupp.mapDomain_single] · apply Subset.trans Finsupp.support_single_subset simpa using mem_range.mp hx · apply pow_ne_zero exact mod_cast hp.out.ne_zero /-- This is the polynomial whose degree we want to get a handle on. -/ def polyOfInterest (n : ℕ) : 𝕄 := wittMul p (n + 1) + (p : 𝕄) ^ (n + 1) * X (0, n + 1) * X (1, n + 1) - X (0, n + 1) * rename (Prod.mk (1 : Fin 2)) (wittPolynomial p ℤ (n + 1)) - X (1, n + 1) * rename (Prod.mk (0 : Fin 2)) (wittPolynomial p ℤ (n + 1)) theorem mul_polyOfInterest_aux1 (n : ℕ) : ∑ i ∈ range (n + 1), (p : 𝕄) ^ i * wittMul p i ^ p ^ (n - i) = wittPolyProd p n := by simp only [wittPolyProd] convert wittStructureInt_prop p (X (0 : Fin 2) * X 1) n using 1 · simp only [wittPolynomial, wittMul] rw [map_sum] congr 1 with i congr 1 have hsupp : (Finsupp.single i (p ^ (n - i))).support = {i} := by rw [Finsupp.support_eq_singleton] simp only [and_true, Finsupp.single_eq_same, eq_self_iff_true, Ne] exact pow_ne_zero _ hp.out.ne_zero simp only [bind₁_monomial, hsupp, Int.cast_natCast, prod_singleton, eq_intCast, Finsupp.single_eq_same, C_pow, mul_eq_mul_left_iff, eq_self_iff_true, Int.cast_pow] · simp only [map_mul, bind₁_X_right] theorem mul_polyOfInterest_aux2 (n : ℕ) : (p : 𝕄) ^ n * wittMul p n + wittPolyProdRemainder p n = wittPolyProd p n := by convert mul_polyOfInterest_aux1 p n rw [sum_range_succ, add_comm, Nat.sub_self, pow_zero, pow_one] rfl -- We redeclare `p` here to locally discard the unneeded `p.Prime` hypothesis. theorem mul_polyOfInterest_aux3 (p n : ℕ) : wittPolyProd p (n + 1) = -((p : 𝕄) ^ (n + 1) * X (0, n + 1)) * ((p : 𝕄) ^ (n + 1) * X (1, n + 1)) + (p : 𝕄) ^ (n + 1) * X (0, n + 1) * rename (Prod.mk (1 : Fin 2)) (wittPolynomial p ℤ (n + 1)) + (p : 𝕄) ^ (n + 1) * X (1, n + 1) * rename (Prod.mk (0 : Fin 2)) (wittPolynomial p ℤ (n + 1)) + remainder p n := by -- a useful auxiliary fact have mvpz : (p : 𝕄) ^ (n + 1) = MvPolynomial.C ((p : ℤ) ^ (n + 1)) := by norm_cast -- Porting note: the original proof applies `sum_range_succ` through a non-`conv` rewrite, -- but this does not work in Lean 4; the whole proof also times out very badly. The proof has been -- nearly totally rewritten here and now finishes quite fast. rw [wittPolyProd, wittPolynomial, map_sum, map_sum] conv_lhs => arg 1 rw [sum_range_succ, ← C_mul_X_pow_eq_monomial, tsub_self, pow_zero, pow_one, map_mul, rename_C, rename_X, ← mvpz] conv_lhs => arg 2 rw [sum_range_succ, ← C_mul_X_pow_eq_monomial, tsub_self, pow_zero, pow_one, map_mul, rename_C, rename_X, ← mvpz] conv_rhs => enter [1, 1, 2, 2] rw [sum_range_succ, ← C_mul_X_pow_eq_monomial, tsub_self, pow_zero, pow_one, map_mul, rename_C, rename_X, ← mvpz] conv_rhs => enter [1, 2, 2] rw [sum_range_succ, ← C_mul_X_pow_eq_monomial, tsub_self, pow_zero, pow_one, map_mul, rename_C, rename_X, ← mvpz] simp only [add_mul, mul_add] rw [add_comm _ (remainder p n)] simp only [add_assoc] apply congrArg (Add.add _) ring theorem mul_polyOfInterest_aux4 (n : ℕ) : (p : 𝕄) ^ (n + 1) * wittMul p (n + 1) = -((p : 𝕄) ^ (n + 1) * X (0, n + 1)) * ((p : 𝕄) ^ (n + 1) * X (1, n + 1)) + (p : 𝕄) ^ (n + 1) * X (0, n + 1) * rename (Prod.mk (1 : Fin 2)) (wittPolynomial p ℤ (n + 1)) + (p : 𝕄) ^ (n + 1) * X (1, n + 1) * rename (Prod.mk (0 : Fin 2)) (wittPolynomial p ℤ (n + 1)) + (remainder p n - wittPolyProdRemainder p (n + 1)) := by rw [← add_sub_assoc, eq_sub_iff_add_eq, mul_polyOfInterest_aux2] exact mul_polyOfInterest_aux3 _ _ theorem mul_polyOfInterest_aux5 (n : ℕ) : (p : 𝕄) ^ (n + 1) * polyOfInterest p n = remainder p n - wittPolyProdRemainder p (n + 1) := by simp only [polyOfInterest, mul_sub, mul_add, sub_eq_iff_eq_add']	rw [mul_polyOfInterest_aux4 p n] ring theorem mul_polyOfInterest_vars (n : ℕ) : ((p : 𝕄) ^ (n + 1) * polyOfInterest p n).vars ⊆ univ ×ˢ range (n + 1) := by rw [mul_polyOfInterest_aux5] apply Subset.trans (vars_sub_subset _) refine union_subset ?_ ?_	Mathlib/RingTheory/WittVector/MulCoeff.lean	179	186
/- Copyright (c) 2024 David Loeffler. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: David Loeffler -/ import Mathlib.NumberTheory.LSeries.AbstractFuncEq import Mathlib.NumberTheory.ModularForms.JacobiTheta.Bounds import Mathlib.NumberTheory.LSeries.MellinEqDirichlet import Mathlib.NumberTheory.LSeries.Basic /-! # Odd Hurwitz zeta functions In this file we study the functions on `ℂ` which are the analytic continuation of the following series (convergent for `1 < re s`), where `a ∈ ℝ` is a parameter: `hurwitzZetaOdd a s = 1 / 2 * ∑' n : ℤ, sgn (n + a) / \|n + a\| ^ s` and `sinZeta a s = ∑' n : ℕ, sin (2 * π * a * n) / n ^ s`. The term for `n = -a` in the first sum is understood as 0 if `a` is an integer, as is the term for `n = 0` in the second sum (for all `a`). Note that these functions are differentiable everywhere, unlike their even counterparts which have poles. Of course, we cannot define these functions by the above formulae (since existence of the analytic continuation is not at all obvious); we in fact construct them as Mellin transforms of various versions of the Jacobi theta function. ## Main definitions and theorems * `completedHurwitzZetaOdd`: the completed Hurwitz zeta function * `completedSinZeta`: the completed cosine zeta function * `differentiable_completedHurwitzZetaOdd` and `differentiable_completedSinZeta`: differentiability on `ℂ` * `completedHurwitzZetaOdd_one_sub`: the functional equation `completedHurwitzZetaOdd a (1 - s) = completedSinZeta a s` * `hasSum_int_hurwitzZetaOdd` and `hasSum_nat_sinZeta`: relation between the zeta functions and corresponding Dirichlet series for `1 < re s` -/ noncomputable section open Complex hiding abs_of_nonneg open CharZero Filter Topology Asymptotics Real Set MeasureTheory open scoped ComplexConjugate namespace HurwitzZeta section kernel_defs /-! ## Definitions and elementary properties of kernels -/ /-- Variant of `jacobiTheta₂'` which we introduce to simplify some formulae. -/ def jacobiTheta₂'' (z τ : ℂ) : ℂ := cexp (π * I * z ^ 2 * τ) * (jacobiTheta₂' (z * τ) τ / (2 * π * I) + z * jacobiTheta₂ (z * τ) τ) lemma jacobiTheta₂''_conj (z τ : ℂ) : conj (jacobiTheta₂'' z τ) = jacobiTheta₂'' (conj z) (-conj τ) := by simp [jacobiTheta₂'', jacobiTheta₂'_conj, jacobiTheta₂_conj, ← exp_conj, map_ofNat, div_neg, neg_div, jacobiTheta₂'_neg_left] /-- Restatement of `jacobiTheta₂'_add_left'`: the function `jacobiTheta₂''` is 1-periodic in `z`. -/ lemma jacobiTheta₂''_add_left (z τ : ℂ) : jacobiTheta₂'' (z + 1) τ = jacobiTheta₂'' z τ := by simp only [jacobiTheta₂'', add_mul z 1, one_mul, jacobiTheta₂'_add_left', jacobiTheta₂_add_left'] generalize jacobiTheta₂ (z * τ) τ = J generalize jacobiTheta₂' (z * τ) τ = J' -- clear denominator simp_rw [div_add' _ _ _ two_pi_I_ne_zero, ← mul_div_assoc] refine congr_arg (· / (2 * π * I)) ?_ -- get all exponential terms to left rw [mul_left_comm _ (cexp _), ← mul_add, mul_assoc (cexp _), ← mul_add, ← mul_assoc (cexp _), ← Complex.exp_add] congrm (cexp ?_ * ?_) <;> ring lemma jacobiTheta₂''_neg_left (z τ : ℂ) : jacobiTheta₂'' (-z) τ = -jacobiTheta₂'' z τ := by simp [jacobiTheta₂'', jacobiTheta₂'_neg_left, neg_div, -neg_add_rev, ← neg_add] lemma jacobiTheta₂'_functional_equation' (z τ : ℂ) : jacobiTheta₂' z τ = (-2 * π) / (-I * τ) ^ (3 / 2 : ℂ) * jacobiTheta₂'' z (-1 / τ) := by rcases eq_or_ne τ 0 with rfl \| hτ · rw [jacobiTheta₂'_undef _ (by simp), mul_zero, zero_cpow (by norm_num), div_zero, zero_mul] have aux1 : (-2 * π : ℂ) / (2 * π * I) = I := by rw [div_eq_iff two_pi_I_ne_zero, mul_comm I, mul_assoc _ I I, I_mul_I, neg_mul, mul_neg, mul_one] rw [jacobiTheta₂'_functional_equation, ← mul_one_div _ τ, mul_right_comm _ (cexp _), (by rw [cpow_one, ← div_div, div_self (neg_ne_zero.mpr I_ne_zero)] : 1 / τ = -I / (-I * τ) ^ (1 : ℂ)), div_mul_div_comm, ← cpow_add _ _ (mul_ne_zero (neg_ne_zero.mpr I_ne_zero) hτ), ← div_mul_eq_mul_div, (by norm_num : (1 / 2 + 1 : ℂ) = 3 / 2), mul_assoc (1 / _), mul_assoc (1 / _), ← mul_one_div (-2 * π : ℂ), mul_comm _ (1 / _), mul_assoc (1 / _)] congr 1 rw [jacobiTheta₂'', div_add' _ _ _ two_pi_I_ne_zero, ← mul_div_assoc, ← mul_div_assoc, ← div_mul_eq_mul_div (-2 * π : ℂ), mul_assoc, aux1, mul_div z (-1), mul_neg_one, neg_div τ z, jacobiTheta₂_neg_left, jacobiTheta₂'_neg_left, neg_mul, ← mul_neg, ← mul_neg, mul_div, mul_neg_one, neg_div, neg_mul, neg_mul, neg_div] congr 2 rw [neg_sub, ← sub_eq_neg_add, mul_comm _ (_ * I), ← mul_assoc] /-- Odd Hurwitz zeta kernel (function whose Mellin transform will be the odd part of the completed Hurwitz zeta function). See `oddKernel_def` for the defining formula, and `hasSum_int_oddKernel` for an expression as a sum over `ℤ`. -/ @[irreducible] def oddKernel (a : UnitAddCircle) (x : ℝ) : ℝ := (show Function.Periodic (fun a : ℝ ↦ re (jacobiTheta₂'' a (I * x))) 1 by intro a; simp [jacobiTheta₂''_add_left]).lift a lemma oddKernel_def (a x : ℝ) : ↑(oddKernel a x) = jacobiTheta₂'' a (I * x) := by simp [oddKernel, ← conj_eq_iff_re, jacobiTheta₂''_conj] lemma oddKernel_def' (a x : ℝ) : ↑(oddKernel ↑a x) = cexp (-π * a ^ 2 * x) * (jacobiTheta₂' (a * I * x) (I * x) / (2 * π * I) + a * jacobiTheta₂ (a * I * x) (I * x)) := by rw [oddKernel_def, jacobiTheta₂'', ← mul_assoc ↑a I x, (by ring : ↑π * I * ↑a ^ 2 * (I * ↑x) = I ^ 2 * ↑π * ↑a ^ 2 * x), I_sq, neg_one_mul] lemma oddKernel_undef (a : UnitAddCircle) {x : ℝ} (hx : x ≤ 0) : oddKernel a x = 0 := by induction a using QuotientAddGroup.induction_on with \| H a' => rw [← ofReal_eq_zero, oddKernel_def', jacobiTheta₂_undef, jacobiTheta₂'_undef, zero_div, zero_add, mul_zero, mul_zero] <;> simpa /-- Auxiliary function appearing in the functional equation for the odd Hurwitz zeta kernel, equal to `∑ (n : ℕ), 2 * n * sin (2 * π * n * a) * exp (-π * n ^ 2 * x)`. See `hasSum_nat_sinKernel` for the defining sum. -/ @[irreducible] def sinKernel (a : UnitAddCircle) (x : ℝ) : ℝ := (show Function.Periodic (fun ξ : ℝ ↦ re (jacobiTheta₂' ξ (I * x) / (-2 * π))) 1 by intro ξ; simp [jacobiTheta₂'_add_left]).lift a lemma sinKernel_def (a x : ℝ) : ↑(sinKernel ↑a x) = jacobiTheta₂' a (I * x) / (-2 * π) := by simp [sinKernel, re_eq_add_conj, jacobiTheta₂'_conj, map_ofNat] lemma sinKernel_undef (a : UnitAddCircle) {x : ℝ} (hx : x ≤ 0) : sinKernel a x = 0 := by induction a using QuotientAddGroup.induction_on with \| H a => rw [← ofReal_eq_zero, sinKernel_def, jacobiTheta₂'_undef _ (by simpa), zero_div] lemma oddKernel_neg (a : UnitAddCircle) (x : ℝ) : oddKernel (-a) x = -oddKernel a x := by induction a using QuotientAddGroup.induction_on with \| H a => simp [← ofReal_inj, ← QuotientAddGroup.mk_neg, oddKernel_def, jacobiTheta₂''_neg_left] @[simp] lemma oddKernel_zero (x : ℝ) : oddKernel 0 x = 0 := by simpa using oddKernel_neg 0 x lemma sinKernel_neg (a : UnitAddCircle) (x : ℝ) : sinKernel (-a) x = -sinKernel a x := by induction a using QuotientAddGroup.induction_on with \| H a => simp [← ofReal_inj, ← QuotientAddGroup.mk_neg, sinKernel_def, jacobiTheta₂'_neg_left, neg_div] @[simp] lemma sinKernel_zero (x : ℝ) : sinKernel 0 x = 0 := by simpa using sinKernel_neg 0 x /-- The odd kernel is continuous on `Ioi 0`. -/ lemma continuousOn_oddKernel (a : UnitAddCircle) : ContinuousOn (oddKernel a) (Ioi 0) := by induction a using QuotientAddGroup.induction_on with \| H a => suffices ContinuousOn (fun x ↦ (oddKernel a x : ℂ)) (Ioi 0) from (continuous_re.comp_continuousOn this).congr fun a _ ↦ (ofReal_re _).symm simp_rw [oddKernel_def' a] refine fun x hx ↦ ((Continuous.continuousAt ?_).mul ?_).continuousWithinAt · fun_prop · have hf : Continuous fun u : ℝ ↦ (a * I * u, I * u) := by fun_prop apply ContinuousAt.add · exact ((continuousAt_jacobiTheta₂' (a * I * x) (by rwa [I_mul_im, ofReal_re])).comp (f := fun u : ℝ ↦ (a * I * u, I * u)) hf.continuousAt).div_const _ · exact continuousAt_const.mul <\| (continuousAt_jacobiTheta₂ (a * I * x) (by rwa [I_mul_im, ofReal_re])).comp (f := fun u : ℝ ↦ (a * I * u, I * u)) hf.continuousAt lemma continuousOn_sinKernel (a : UnitAddCircle) : ContinuousOn (sinKernel a) (Ioi 0) := by induction a using QuotientAddGroup.induction_on with \| H a => suffices ContinuousOn (fun x ↦ (sinKernel a x : ℂ)) (Ioi 0) from (continuous_re.comp_continuousOn this).congr fun a _ ↦ (ofReal_re _).symm simp_rw [sinKernel_def] apply (continuousOn_of_forall_continuousAt (fun x hx ↦ ?_)).div_const have h := continuousAt_jacobiTheta₂' a (by rwa [I_mul_im, ofReal_re]) fun_prop lemma oddKernel_functional_equation (a : UnitAddCircle) (x : ℝ) : oddKernel a x = 1 / x ^ (3 / 2 : ℝ) * sinKernel a (1 / x) := by -- first reduce to `0 < x` rcases le_or_lt x 0 with hx \| hx · rw [oddKernel_undef _ hx, sinKernel_undef _ (one_div_nonpos.mpr hx), mul_zero] induction a using QuotientAddGroup.induction_on with \| H a => have h1 : -1 / (I * ↑(1 / x)) = I * x := by rw [one_div, ofReal_inv, mul_comm, ← div_div, div_inv_eq_mul, div_eq_mul_inv, inv_I, mul_neg, neg_one_mul, neg_mul, neg_neg, mul_comm] have h2 : (-I * (I * ↑(1 / x))) = 1 / x := by rw [← mul_assoc, neg_mul, I_mul_I, neg_neg, one_mul, ofReal_div, ofReal_one] have h3 : (x : ℂ) ^ (3 / 2 : ℂ) ≠ 0 := by simp only [Ne, cpow_eq_zero_iff, ofReal_eq_zero, hx.ne', false_and, not_false_eq_true] have h4 : arg x ≠ π := by rw [arg_ofReal_of_nonneg hx.le]; exact pi_ne_zero.symm rw [← ofReal_inj, oddKernel_def, ofReal_mul, sinKernel_def, jacobiTheta₂'_functional_equation', h1, h2] generalize jacobiTheta₂'' a (I * ↑x) = J rw [one_div (x : ℂ), inv_cpow _ _ h4, div_inv_eq_mul, one_div, ofReal_inv, ofReal_cpow hx.le, ofReal_div, ofReal_ofNat, ofReal_ofNat, ← mul_div_assoc _ _ (-2 * π : ℂ), eq_div_iff <\| mul_ne_zero (neg_ne_zero.mpr two_ne_zero) (ofReal_ne_zero.mpr pi_ne_zero), ← div_eq_inv_mul, eq_div_iff h3, mul_comm J _, mul_right_comm] end kernel_defs section sum_formulas /-! ## Formulae for the kernels as sums -/ lemma hasSum_int_oddKernel (a : ℝ) {x : ℝ} (hx : 0 < x) : HasSum (fun n : ℤ ↦ (n + a) * rexp (-π * (n + a) ^ 2 * x)) (oddKernel ↑a x) := by rw [← hasSum_ofReal, oddKernel_def' a x] have h1 := hasSum_jacobiTheta₂_term (a * I * x) (by rwa [I_mul_im, ofReal_re]) have h2 := hasSum_jacobiTheta₂'_term (a * I * x) (by rwa [I_mul_im, ofReal_re]) refine (((h2.div_const (2 * π * I)).add (h1.mul_left ↑a)).mul_left (cexp (-π * a ^ 2 * x))).congr_fun (fun n ↦ ?_) rw [jacobiTheta₂'_term, mul_assoc (2 * π * I), mul_div_cancel_left₀ _ two_pi_I_ne_zero, ← add_mul, mul_left_comm, jacobiTheta₂_term, ← Complex.exp_add] push_cast simp only [← mul_assoc, ← add_mul] congrm _ * cexp (?_ * x) simp only [mul_right_comm _ I, add_mul, mul_assoc _ I, I_mul_I] ring_nf lemma hasSum_int_sinKernel (a : ℝ) {t : ℝ} (ht : 0 < t) : HasSum (fun n : ℤ ↦ -I * n * cexp (2 * π * I * a * n) * rexp (-π * n ^ 2 * t)) ↑(sinKernel a t) := by have h : -2 * (π : ℂ) ≠ (0 : ℂ) := by simp only [neg_mul, ne_eq, neg_eq_zero, mul_eq_zero, OfNat.ofNat_ne_zero, ofReal_eq_zero, pi_ne_zero, or_self, not_false_eq_true] rw [sinKernel_def] refine ((hasSum_jacobiTheta₂'_term a (by rwa [I_mul_im, ofReal_re])).div_const _).congr_fun fun n ↦ ?_ rw [jacobiTheta₂'_term, jacobiTheta₂_term, ofReal_exp, mul_assoc (-I * n), ← Complex.exp_add, eq_div_iff h, ofReal_mul, ofReal_mul, ofReal_pow, ofReal_neg, ofReal_intCast, mul_comm _ (-2 * π : ℂ), ← mul_assoc] congrm ?_ * cexp (?_ + ?_) · simp [mul_assoc] · exact mul_right_comm (2 * π * I) a n · simp [← mul_assoc, mul_comm _ I] lemma hasSum_nat_sinKernel (a : ℝ) {t : ℝ} (ht : 0 < t) : HasSum (fun n : ℕ ↦ 2 * n * Real.sin (2 * π * a * n) * rexp (-π * n ^ 2 * t)) (sinKernel ↑a t) := by rw [← hasSum_ofReal] have := (hasSum_int_sinKernel a ht).nat_add_neg simp only [Int.cast_zero, sq (0 : ℂ), zero_mul, mul_zero, add_zero] at this refine this.congr_fun fun n ↦ ?_ simp_rw [Int.cast_neg, neg_sq, mul_neg, ofReal_mul, Int.cast_natCast, ofReal_natCast, ofReal_ofNat, ← add_mul, ofReal_sin, Complex.sin] push_cast congr 1 rw [← mul_div_assoc, ← div_mul_eq_mul_div, ← div_mul_eq_mul_div, div_self two_ne_zero, one_mul, neg_mul, neg_mul, neg_neg, mul_comm _ I, ← mul_assoc, mul_comm _ I, neg_mul, ← sub_eq_neg_add, mul_sub] congr 3 <;> ring end sum_formulas section asymp /-! ## Asymptotics of the kernels as `t → ∞` -/ /-- The function `oddKernel a` has exponential decay at `+∞`, for any `a`. -/ lemma isBigO_atTop_oddKernel (a : UnitAddCircle) : ∃ p, 0 < p ∧ IsBigO atTop (oddKernel a) (fun x ↦ Real.exp (-p * x)) := by induction a using QuotientAddGroup.induction_on with \| H b => obtain ⟨p, hp, hp'⟩ := HurwitzKernelBounds.isBigO_atTop_F_int_one b refine ⟨p, hp, (Eventually.isBigO ?_).trans hp'⟩ filter_upwards [eventually_gt_atTop 0] with t ht simpa [← (hasSum_int_oddKernel b ht).tsum_eq, HurwitzKernelBounds.F_int, HurwitzKernelBounds.f_int, abs_of_nonneg (exp_pos _).le] using norm_tsum_le_tsum_norm (hasSum_int_oddKernel b ht).summable.norm /-- The function `sinKernel a` has exponential decay at `+∞`, for any `a`. -/ lemma isBigO_atTop_sinKernel (a : UnitAddCircle) : ∃ p, 0 < p ∧ IsBigO atTop (sinKernel a) (fun x ↦ Real.exp (-p * x)) := by induction a using QuotientAddGroup.induction_on with \| H a => obtain ⟨p, hp, hp'⟩ := HurwitzKernelBounds.isBigO_atTop_F_nat_one (le_refl 0) refine ⟨p, hp, (Eventually.isBigO ?_).trans (hp'.const_mul_left 2)⟩ filter_upwards [eventually_gt_atTop 0] with t ht rw [HurwitzKernelBounds.F_nat, ← (hasSum_nat_sinKernel a ht).tsum_eq] apply tsum_of_norm_bounded (g := fun n ↦ 2 * HurwitzKernelBounds.f_nat 1 0 t n) · exact (HurwitzKernelBounds.summable_f_nat 1 0 ht).hasSum.mul_left _ · intro n rw [norm_mul, norm_mul, norm_mul, norm_two, mul_assoc, mul_assoc, mul_le_mul_iff_of_pos_left two_pos, HurwitzKernelBounds.f_nat, pow_one, add_zero, norm_of_nonneg (exp_pos _).le, Real.norm_eq_abs, Nat.abs_cast, ← mul_assoc, mul_le_mul_iff_of_pos_right (exp_pos _)] exact mul_le_of_le_one_right (Nat.cast_nonneg _) (abs_sin_le_one _) end asymp section FEPair /-! ## Construction of an FE-pair -/ /-- A `StrongFEPair` structure with `f = oddKernel a` and `g = sinKernel a`. -/ @[simps] def hurwitzOddFEPair (a : UnitAddCircle) : StrongFEPair ℂ where f := ofReal ∘ oddKernel a g := ofReal ∘ sinKernel a hf_int := (continuous_ofReal.comp_continuousOn (continuousOn_oddKernel a)).locallyIntegrableOn measurableSet_Ioi hg_int := (continuous_ofReal.comp_continuousOn (continuousOn_sinKernel a)).locallyIntegrableOn measurableSet_Ioi k := 3 / 2 hk := by norm_num ε := 1 hε := one_ne_zero f₀ := 0 hf₀ := rfl g₀ := 0 hg₀ := rfl hf_top r := by let ⟨v, hv, hv'⟩ := isBigO_atTop_oddKernel a rw [← isBigO_norm_left] at hv' ⊢ simpa using hv'.trans (isLittleO_exp_neg_mul_rpow_atTop hv _).isBigO hg_top r := by let ⟨v, hv, hv'⟩ := isBigO_atTop_sinKernel a rw [← isBigO_norm_left] at hv' ⊢ simpa using hv'.trans (isLittleO_exp_neg_mul_rpow_atTop hv _).isBigO h_feq x hx := by simp [← ofReal_mul, oddKernel_functional_equation a, inv_rpow (le_of_lt hx)] end FEPair /-! ## Definition of the completed odd Hurwitz zeta function -/ /-- The entire function of `s` which agrees with `1 / 2 * Gamma ((s + 1) / 2) * π ^ (-(s + 1) / 2) * ∑' (n : ℤ), sgn (n + a) / \|n + a\| ^ s` for `1 < re s`. -/ def completedHurwitzZetaOdd (a : UnitAddCircle) (s : ℂ) : ℂ := ((hurwitzOddFEPair a).Λ ((s + 1) / 2)) / 2 lemma differentiable_completedHurwitzZetaOdd (a : UnitAddCircle) : Differentiable ℂ (completedHurwitzZetaOdd a) := ((hurwitzOddFEPair a).differentiable_Λ.comp ((differentiable_id.add_const 1).div_const 2)).div_const 2 /-- The entire function of `s` which agrees with ` Gamma ((s + 1) / 2) * π ^ (-(s + 1) / 2) * ∑' (n : ℕ), sin (2 * π * a * n) / n ^ s` for `1 < re s`. -/ def completedSinZeta (a : UnitAddCircle) (s : ℂ) : ℂ := ((hurwitzOddFEPair a).symm.Λ ((s + 1) / 2)) / 2 lemma differentiable_completedSinZeta (a : UnitAddCircle) : Differentiable ℂ (completedSinZeta a) := ((hurwitzOddFEPair a).symm.differentiable_Λ.comp ((differentiable_id.add_const 1).div_const 2)).div_const 2 /-! ## Parity and functional equations -/ lemma completedHurwitzZetaOdd_neg (a : UnitAddCircle) (s : ℂ) : completedHurwitzZetaOdd (-a) s = -completedHurwitzZetaOdd a s := by simp [completedHurwitzZetaOdd, StrongFEPair.Λ, hurwitzOddFEPair, mellin, oddKernel_neg, integral_neg, neg_div] lemma completedSinZeta_neg (a : UnitAddCircle) (s : ℂ) : completedSinZeta (-a) s = -completedSinZeta a s := by simp [completedSinZeta, StrongFEPair.Λ, mellin, StrongFEPair.symm, WeakFEPair.symm, hurwitzOddFEPair, sinKernel_neg, integral_neg, neg_div]	/-- Functional equation for the odd Hurwitz zeta function. -/ theorem completedHurwitzZetaOdd_one_sub (a : UnitAddCircle) (s : ℂ) : completedHurwitzZetaOdd a (1 - s) = completedSinZeta a s := by rw [completedHurwitzZetaOdd, completedSinZeta,	Mathlib/NumberTheory/LSeries/HurwitzZetaOdd.lean	366	370
/- Copyright (c) 2016 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Leonardo de Moura -/ import Mathlib.Tactic.Attr.Register import Mathlib.Tactic.Basic import Batteries.Logic import Batteries.Tactic.Trans import Batteries.Util.LibraryNote import Mathlib.Data.Nat.Notation import Mathlib.Data.Int.Notation /-! # Basic logic properties This file is one of the earliest imports in mathlib. ## Implementation notes Theorems that require decidability hypotheses are in the namespace `Decidable`. Classical versions are in the namespace `Classical`. -/ open Function section Miscellany -- attribute [refl] HEq.refl -- FIXME This is still rejected after https://github.com/leanprover-community/mathlib4/pull/857 attribute [trans] Iff.trans HEq.trans heq_of_eq_of_heq attribute [simp] cast_heq /-- An identity function with its main argument implicit. This will be printed as `hidden` even if it is applied to a large term, so it can be used for elision, as done in the `elide` and `unelide` tactics. -/ abbrev hidden {α : Sort} {a : α} := a variable {α : Sort} instance (priority := 10) decidableEq_of_subsingleton [Subsingleton α] : DecidableEq α := fun a b ↦ isTrue (Subsingleton.elim a b) instance [Subsingleton α] (p : α → Prop) : Subsingleton (Subtype p) := ⟨fun ⟨x, _⟩ ⟨y, _⟩ ↦ by cases Subsingleton.elim x y; rfl⟩ theorem congr_heq {α β γ : Sort _} {f : α → γ} {g : β → γ} {x : α} {y : β} (h₁ : HEq f g) (h₂ : HEq x y) : f x = g y := by cases h₂; cases h₁; rfl theorem congr_arg_heq {β : α → Sort} (f : ∀ a, β a) : ∀ {a₁ a₂ : α}, a₁ = a₂ → HEq (f a₁) (f a₂) \| _, _, rfl => HEq.rfl @[simp] theorem eq_iff_eq_cancel_left {b c : α} : (∀ {a}, a = b ↔ a = c) ↔ b = c := ⟨fun h ↦ by rw [← h], fun h a ↦ by rw [h]⟩ @[simp] theorem eq_iff_eq_cancel_right {a b : α} : (∀ {c}, a = c ↔ b = c) ↔ a = b := ⟨fun h ↦ by rw [h], fun h a ↦ by rw [h]⟩ lemma ne_and_eq_iff_right {a b c : α} (h : b ≠ c) : a ≠ b ∧ a = c ↔ a = c := and_iff_right_of_imp (fun h2 => h2.symm ▸ h.symm) /-- Wrapper for adding elementary propositions to the type class systems. Warning: this can easily be abused. See the rest of this docstring for details. Certain propositions should not be treated as a class globally, but sometimes it is very convenient to be able to use the type class system in specific circumstances. For example, `ZMod p` is a field if and only if `p` is a prime number. In order to be able to find this field instance automatically by type class search, we have to turn `p.prime` into an instance implicit assumption. On the other hand, making `Nat.prime` a class would require a major refactoring of the library, and it is questionable whether making `Nat.prime` a class is desirable at all. The compromise is to add the assumption `[Fact p.prime]` to `ZMod.field`. In particular, this class is not intended for turning the type class system into an automated theorem prover for first order logic. -/ class Fact (p : Prop) : Prop where /-- `Fact.out` contains the unwrapped witness for the fact represented by the instance of `Fact p`. -/ out : p library_note "fact non-instances"/-- In most cases, we should not have global instances of `Fact`; typeclass search only reads the head symbol and then tries any instances, which means that adding any such instance will cause slowdowns everywhere. We instead make them as lemmata and make them local instances as required. -/ theorem Fact.elim {p : Prop} (h : Fact p) : p := h.1 theorem fact_iff {p : Prop} : Fact p ↔ p := ⟨fun h ↦ h.1, fun h ↦ ⟨h⟩⟩ instance {p : Prop} [Decidable p] : Decidable (Fact p) := decidable_of_iff _ fact_iff.symm /-- Swaps two pairs of arguments to a function. -/ abbrev Function.swap₂ {ι₁ ι₂ : Sort} {κ₁ : ι₁ → Sort} {κ₂ : ι₂ → Sort} {φ : ∀ i₁, κ₁ i₁ → ∀ i₂, κ₂ i₂ → Sort} (f : ∀ i₁ j₁ i₂ j₂, φ i₁ j₁ i₂ j₂) (i₂ j₂ i₁ j₁) : φ i₁ j₁ i₂ j₂ := f i₁ j₁ i₂ j₂ end Miscellany open Function /-! ### Declarations about propositional connectives -/ section Propositional /-! ### Declarations about `implies` -/ alias Iff.imp := imp_congr -- This is a duplicate of `Classical.imp_iff_right_iff`. Deprecate? theorem imp_iff_right_iff {a b : Prop} : (a → b ↔ b) ↔ a ∨ b := open scoped Classical in Decidable.imp_iff_right_iff -- This is a duplicate of `Classical.and_or_imp`. Deprecate? theorem and_or_imp {a b c : Prop} : a ∧ b ∨ (a → c) ↔ a → b ∨ c := open scoped Classical in Decidable.and_or_imp /-- Provide modus tollens (`mt`) as dot notation for implications. -/ protected theorem Function.mt {a b : Prop} : (a → b) → ¬b → ¬a := mt /-! ### Declarations about `not` -/ alias dec_em := Decidable.em theorem dec_em' (p : Prop) [Decidable p] : ¬p ∨ p := (dec_em p).symm alias em := Classical.em theorem em' (p : Prop) : ¬p ∨ p := (em p).symm theorem or_not {p : Prop} : p ∨ ¬p := em _ theorem Decidable.eq_or_ne {α : Sort} (x y : α) [Decidable (x = y)] : x = y ∨ x ≠ y := dec_em <\| x = y theorem Decidable.ne_or_eq {α : Sort} (x y : α) [Decidable (x = y)] : x ≠ y ∨ x = y := dec_em' <\| x = y theorem eq_or_ne {α : Sort} (x y : α) : x = y ∨ x ≠ y := em <\| x = y theorem ne_or_eq {α : Sort} (x y : α) : x ≠ y ∨ x = y := em' <\| x = y theorem by_contradiction {p : Prop} : (¬p → False) → p := open scoped Classical in Decidable.byContradiction theorem by_cases {p q : Prop} (hpq : p → q) (hnpq : ¬p → q) : q := open scoped Classical in if hp : p then hpq hp else hnpq hp alias by_contra := by_contradiction library_note "decidable namespace"/-- In most of mathlib, we use the law of excluded middle (LEM) and the axiom of choice (AC) freely. The `Decidable` namespace contains versions of lemmas from the root namespace that explicitly attempt to avoid the axiom of choice, usually by adding decidability assumptions on the inputs. You can check if a lemma uses the axiom of choice by using `#print axioms foo` and seeing if `Classical.choice` appears in the list. -/ library_note "decidable arguments"/-- As mathlib is primarily classical, if the type signature of a `def` or `lemma` does not require any `Decidable` instances to state, it is preferable not to introduce any `Decidable` instances that are needed in the proof as arguments, but rather to use the `classical` tactic as needed. In the other direction, when `Decidable` instances do appear in the type signature, it is better to use explicitly introduced ones rather than allowing Lean to automatically infer classical ones, as these may cause instance mismatch errors later. -/ export Classical (not_not) attribute [simp] not_not variable {a b : Prop} theorem of_not_not {a : Prop} : ¬¬a → a := by_contra theorem not_ne_iff {α : Sort} {a b : α} : ¬a ≠ b ↔ a = b := not_not theorem of_not_imp : ¬(a → b) → a := open scoped Classical in Decidable.of_not_imp alias Not.decidable_imp_symm := Decidable.not_imp_symm theorem Not.imp_symm : (¬a → b) → ¬b → a := open scoped Classical in Not.decidable_imp_symm theorem not_imp_comm : ¬a → b ↔ ¬b → a := open scoped Classical in Decidable.not_imp_comm @[simp] theorem not_imp_self : ¬a → a ↔ a := open scoped Classical in Decidable.not_imp_self theorem Imp.swap {a b : Sort} {c : Prop} : a → b → c ↔ b → a → c := ⟨fun h x y ↦ h y x, fun h x y ↦ h y x⟩ alias Iff.not := not_congr theorem Iff.not_left (h : a ↔ ¬b) : ¬a ↔ b := h.not.trans not_not theorem Iff.not_right (h : ¬a ↔ b) : a ↔ ¬b := not_not.symm.trans h.not protected lemma Iff.ne {α β : Sort} {a b : α} {c d : β} : (a = b ↔ c = d) → (a ≠ b ↔ c ≠ d) := Iff.not lemma Iff.ne_left {α β : Sort} {a b : α} {c d : β} : (a = b ↔ c ≠ d) → (a ≠ b ↔ c = d) := Iff.not_left lemma Iff.ne_right {α β : Sort} {a b : α} {c d : β} : (a ≠ b ↔ c = d) → (a = b ↔ c ≠ d) := Iff.not_right /-! ### Declarations about `Xor'` -/ /-- `Xor' a b` is the exclusive-or of propositions. -/ def Xor' (a b : Prop) := (a ∧ ¬b) ∨ (b ∧ ¬a) instance [Decidable a] [Decidable b] : Decidable (Xor' a b) := inferInstanceAs (Decidable (Or ..)) @[simp] theorem xor_true : Xor' True = Not := by simp +unfoldPartialApp [Xor'] @[simp] theorem xor_false : Xor' False = id := by ext; simp [Xor'] theorem xor_comm (a b : Prop) : Xor' a b = Xor' b a := by simp [Xor', and_comm, or_comm] instance : Std.Commutative Xor' := ⟨xor_comm⟩ @[simp] theorem xor_self (a : Prop) : Xor' a a = False := by simp [Xor'] @[simp] theorem xor_not_left : Xor' (¬a) b ↔ (a ↔ b) := by by_cases a <;> simp [] @[simp] theorem xor_not_right : Xor' a (¬b) ↔ (a ↔ b) := by by_cases a <;> simp [] theorem xor_not_not : Xor' (¬a) (¬b) ↔ Xor' a b := by simp [Xor', or_comm, and_comm] protected theorem Xor'.or (h : Xor' a b) : a ∨ b := h.imp And.left And.left /-! ### Declarations about `and` -/ alias Iff.and := and_congr alias ⟨And.rotate, _⟩ := and_rotate theorem and_symm_right {α : Sort} (a b : α) (p : Prop) : p ∧ a = b ↔ p ∧ b = a := by simp [eq_comm] theorem and_symm_left {α : Sort} (a b : α) (p : Prop) : a = b ∧ p ↔ b = a ∧ p := by simp [eq_comm] /-! ### Declarations about `or` -/ alias Iff.or := or_congr alias ⟨Or.rotate, _⟩ := or_rotate theorem Or.elim3 {c d : Prop} (h : a ∨ b ∨ c) (ha : a → d) (hb : b → d) (hc : c → d) : d := Or.elim h ha fun h₂ ↦ Or.elim h₂ hb hc theorem Or.imp3 {d e c f : Prop} (had : a → d) (hbe : b → e) (hcf : c → f) : a ∨ b ∨ c → d ∨ e ∨ f := Or.imp had <\| Or.imp hbe hcf export Classical (or_iff_not_imp_left or_iff_not_imp_right) theorem not_or_of_imp : (a → b) → ¬a ∨ b := open scoped Classical in Decidable.not_or_of_imp -- See Note [decidable namespace] protected theorem Decidable.or_not_of_imp [Decidable a] (h : a → b) : b ∨ ¬a := dite _ (Or.inl ∘ h) Or.inr theorem or_not_of_imp : (a → b) → b ∨ ¬a := open scoped Classical in Decidable.or_not_of_imp theorem imp_iff_not_or : a → b ↔ ¬a ∨ b := open scoped Classical in Decidable.imp_iff_not_or theorem imp_iff_or_not {b a : Prop} : b → a ↔ a ∨ ¬b := open scoped Classical in Decidable.imp_iff_or_not theorem not_imp_not : ¬a → ¬b ↔ b → a := open scoped Classical in Decidable.not_imp_not theorem imp_and_neg_imp_iff (p q : Prop) : (p → q) ∧ (¬p → q) ↔ q := by simp /-- Provide the reverse of modus tollens (`mt`) as dot notation for implications. -/ protected theorem Function.mtr : (¬a → ¬b) → b → a := not_imp_not.mp theorem or_congr_left' {c a b : Prop} (h : ¬c → (a ↔ b)) : a ∨ c ↔ b ∨ c := open scoped Classical in Decidable.or_congr_left' h theorem or_congr_right' {c : Prop} (h : ¬a → (b ↔ c)) : a ∨ b ↔ a ∨ c := open scoped Classical in Decidable.or_congr_right' h /-! ### Declarations about distributivity -/ /-! Declarations about `iff` -/ alias Iff.iff := iff_congr -- @[simp] -- FIXME simp ignores proof rewrites theorem iff_mpr_iff_true_intro {P : Prop} (h : P) : Iff.mpr (iff_true_intro h) True.intro = h := rfl theorem imp_or {a b c : Prop} : a → b ∨ c ↔ (a → b) ∨ (a → c) := open scoped Classical in Decidable.imp_or theorem imp_or' {a : Sort} {b c : Prop} : a → b ∨ c ↔ (a → b) ∨ (a → c) := open scoped Classical in Decidable.imp_or' theorem not_imp : ¬(a → b) ↔ a ∧ ¬b := open scoped Classical in Decidable.not_imp_iff_and_not theorem peirce (a b : Prop) : ((a → b) → a) → a := open scoped Classical in Decidable.peirce _ _ theorem not_iff_not : (¬a ↔ ¬b) ↔ (a ↔ b) := open scoped Classical in Decidable.not_iff_not theorem not_iff_comm : (¬a ↔ b) ↔ (¬b ↔ a) := open scoped Classical in Decidable.not_iff_comm theorem not_iff : ¬(a ↔ b) ↔ (¬a ↔ b) := open scoped Classical in Decidable.not_iff theorem iff_not_comm : (a ↔ ¬b) ↔ (b ↔ ¬a) := open scoped Classical in Decidable.iff_not_comm theorem iff_iff_and_or_not_and_not : (a ↔ b) ↔ a ∧ b ∨ ¬a ∧ ¬b := open scoped Classical in Decidable.iff_iff_and_or_not_and_not theorem iff_iff_not_or_and_or_not : (a ↔ b) ↔ (¬a ∨ b) ∧ (a ∨ ¬b) := open scoped Classical in Decidable.iff_iff_not_or_and_or_not theorem not_and_not_right : ¬(a ∧ ¬b) ↔ a → b := open scoped Classical in Decidable.not_and_not_right /-! ### De Morgan's laws -/ /-- One of de Morgan's laws: the negation of a conjunction is logically equivalent to the disjunction of the negations. -/ theorem not_and_or : ¬(a ∧ b) ↔ ¬a ∨ ¬b := open scoped Classical in Decidable.not_and_iff_not_or_not theorem or_iff_not_and_not : a ∨ b ↔ ¬(¬a ∧ ¬b) := open scoped Classical in Decidable.or_iff_not_not_and_not theorem and_iff_not_or_not : a ∧ b ↔ ¬(¬a ∨ ¬b) := open scoped Classical in Decidable.and_iff_not_not_or_not @[simp] theorem not_xor (P Q : Prop) : ¬Xor' P Q ↔ (P ↔ Q) := by simp only [not_and, Xor', not_or, not_not, ← iff_iff_implies_and_implies] theorem xor_iff_not_iff (P Q : Prop) : Xor' P Q ↔ ¬ (P ↔ Q) := (not_xor P Q).not_right theorem xor_iff_iff_not : Xor' a b ↔ (a ↔ ¬b) := by simp only [← @xor_not_right a, not_not] theorem xor_iff_not_iff' : Xor' a b ↔ (¬a ↔ b) := by simp only [← @xor_not_left _ b, not_not] theorem xor_iff_or_and_not_and (a b : Prop) : Xor' a b ↔ (a ∨ b) ∧ (¬ (a ∧ b)) := by rw [Xor', or_and_right, not_and_or, and_or_left, and_not_self_iff, false_or, and_or_left, and_not_self_iff, or_false] end Propositional /-! ### Membership -/ alias Membership.mem.ne_of_not_mem := ne_of_mem_of_not_mem alias Membership.mem.ne_of_not_mem' := ne_of_mem_of_not_mem' section Membership variable {α β : Type} [Membership α β] {p : Prop} [Decidable p] theorem mem_dite {a : α} {s : p → β} {t : ¬p → β} : (a ∈ if h : p then s h else t h) ↔ (∀ h, a ∈ s h) ∧ (∀ h, a ∈ t h) := by by_cases h : p <;> simp [h] theorem dite_mem {a : p → α} {b : ¬p → α} {s : β} : (if h : p then a h else b h) ∈ s ↔ (∀ h, a h ∈ s) ∧ (∀ h, b h ∈ s) := by by_cases h : p <;> simp [h] theorem mem_ite {a : α} {s t : β} : (a ∈ if p then s else t) ↔ (p → a ∈ s) ∧ (¬p → a ∈ t) := mem_dite theorem ite_mem {a b : α} {s : β} : (if p then a else b) ∈ s ↔ (p → a ∈ s) ∧ (¬p → b ∈ s) := dite_mem end Membership /-! ### Declarations about equality -/ section Equality -- todo: change name theorem forall_cond_comm {α} {s : α → Prop} {p : α → α → Prop} : (∀ a, s a → ∀ b, s b → p a b) ↔ ∀ a b, s a → s b → p a b := ⟨fun h a b ha hb ↦ h a ha b hb, fun h a ha b hb ↦ h a b ha hb⟩ theorem forall_mem_comm {α β} [Membership α β] {s : β} {p : α → α → Prop} : (∀ a (_ : a ∈ s) b (_ : b ∈ s), p a b) ↔ ∀ a b, a ∈ s → b ∈ s → p a b := forall_cond_comm lemma ne_of_eq_of_ne {α : Sort} {a b c : α} (h₁ : a = b) (h₂ : b ≠ c) : a ≠ c := h₁.symm ▸ h₂ lemma ne_of_ne_of_eq {α : Sort} {a b c : α} (h₁ : a ≠ b) (h₂ : b = c) : a ≠ c := h₂ ▸ h₁ alias Eq.trans_ne := ne_of_eq_of_ne alias Ne.trans_eq := ne_of_ne_of_eq theorem eq_equivalence {α : Sort} : Equivalence (@Eq α) := ⟨Eq.refl, @Eq.symm _, @Eq.trans _⟩ -- These were migrated to Batteries but the `@[simp]` attributes were (mysteriously?) removed. attribute [simp] eq_mp_eq_cast eq_mpr_eq_cast -- @[simp] -- FIXME simp ignores proof rewrites theorem congr_refl_left {α β : Sort} (f : α → β) {a b : α} (h : a = b) : congr (Eq.refl f) h = congr_arg f h := rfl -- @[simp] -- FIXME simp ignores proof rewrites theorem congr_refl_right {α β : Sort} {f g : α → β} (h : f = g) (a : α) : congr h (Eq.refl a) = congr_fun h a := rfl -- @[simp] -- FIXME simp ignores proof rewrites theorem congr_arg_refl {α β : Sort} (f : α → β) (a : α) : congr_arg f (Eq.refl a) = Eq.refl (f a) := rfl -- @[simp] -- FIXME simp ignores proof rewrites theorem congr_fun_rfl {α β : Sort} (f : α → β) (a : α) : congr_fun (Eq.refl f) a = Eq.refl (f a) := rfl -- @[simp] -- FIXME simp ignores proof rewrites theorem congr_fun_congr_arg {α β γ : Sort} (f : α → β → γ) {a a' : α} (p : a = a') (b : β) : congr_fun (congr_arg f p) b = congr_arg (fun a ↦ f a b) p := rfl theorem Eq.rec_eq_cast {α : Sort _} {P : α → Sort _} {x y : α} (h : x = y) (z : P x) : h ▸ z = cast (congr_arg P h) z := by induction h; rfl theorem eqRec_heq' {α : Sort} {a' : α} {motive : (a : α) → a' = a → Sort} (p : motive a' (rfl : a' = a')) {a : α} (t : a' = a) : HEq (@Eq.rec α a' motive p a t) p := by subst t; rfl theorem rec_heq_of_heq {α β : Sort _} {a b : α} {C : α → Sort} {x : C a} {y : β} (e : a = b) (h : HEq x y) : HEq (e ▸ x) y := by subst e; exact h theorem rec_heq_iff_heq {α β : Sort _} {a b : α} {C : α → Sort} {x : C a} {y : β} {e : a = b} : HEq (e ▸ x) y ↔ HEq x y := by subst e; rfl theorem heq_rec_iff_heq {α β : Sort _} {a b : α} {C : α → Sort} {x : β} {y : C a} {e : a = b} : HEq x (e ▸ y) ↔ HEq x y := by subst e; rfl @[simp] theorem cast_heq_iff_heq {α β γ : Sort _} (e : α = β) (a : α) (c : γ) : HEq (cast e a) c ↔ HEq a c := by subst e; rfl @[simp] theorem heq_cast_iff_heq {α β γ : Sort _} (e : β = γ) (a : α) (b : β) : HEq a (cast e b) ↔ HEq a b := by subst e; rfl universe u variable {α β : Sort u} {e : β = α} {a : α} {b : β} lemma heq_of_eq_cast (e : β = α) : a = cast e b → HEq a b := by rintro rfl; simp lemma eq_cast_iff_heq : a = cast e b ↔ HEq a b := ⟨heq_of_eq_cast _, fun h ↦ by cases h; rfl⟩ end Equality /-! ### Declarations about quantifiers -/ section Quantifiers section Dependent variable {α : Sort} {β : α → Sort} {γ : ∀ a, β a → Sort} theorem forall₂_imp {p q : ∀ a, β a → Prop} (h : ∀ a b, p a b → q a b) : (∀ a b, p a b) → ∀ a b, q a b := forall_imp fun i ↦ forall_imp <\| h i theorem forall₃_imp {p q : ∀ a b, γ a b → Prop} (h : ∀ a b c, p a b c → q a b c) : (∀ a b c, p a b c) → ∀ a b c, q a b c := forall_imp fun a ↦ forall₂_imp <\| h a theorem Exists₂.imp {p q : ∀ a, β a → Prop} (h : ∀ a b, p a b → q a b) : (∃ a b, p a b) → ∃ a b, q a b := Exists.imp fun a ↦ Exists.imp <\| h a theorem Exists₃.imp {p q : ∀ a b, γ a b → Prop} (h : ∀ a b c, p a b c → q a b c) : (∃ a b c, p a b c) → ∃ a b c, q a b c := Exists.imp fun a ↦ Exists₂.imp <\| h a end Dependent variable {α β : Sort} {p : α → Prop} theorem forall_swap {p : α → β → Prop} : (∀ x y, p x y) ↔ ∀ y x, p x y := ⟨fun f x y ↦ f y x, fun f x y ↦ f y x⟩ theorem forall₂_swap {ι₁ ι₂ : Sort} {κ₁ : ι₁ → Sort} {κ₂ : ι₂ → Sort} {p : ∀ i₁, κ₁ i₁ → ∀ i₂, κ₂ i₂ → Prop} : (∀ i₁ j₁ i₂ j₂, p i₁ j₁ i₂ j₂) ↔ ∀ i₂ j₂ i₁ j₁, p i₁ j₁ i₂ j₂ := ⟨swap₂, swap₂⟩ /-- We intentionally restrict the type of `α` in this lemma so that this is a safer to use in simp than `forall_swap`. -/ theorem imp_forall_iff {α : Type} {p : Prop} {q : α → Prop} : (p → ∀ x, q x) ↔ ∀ x, p → q x := forall_swap lemma imp_forall_iff_forall (A : Prop) (B : A → Prop) : (A → ∀ h : A, B h) ↔ ∀ h : A, B h := by by_cases h : A <;> simp [h] theorem exists_swap {p : α → β → Prop} : (∃ x y, p x y) ↔ ∃ y x, p x y := ⟨fun ⟨x, y, h⟩ ↦ ⟨y, x, h⟩, fun ⟨y, x, h⟩ ↦ ⟨x, y, h⟩⟩ theorem exists_and_exists_comm {P : α → Prop} {Q : β → Prop} : (∃ a, P a) ∧ (∃ b, Q b) ↔ ∃ a b, P a ∧ Q b := ⟨fun ⟨⟨a, ha⟩, ⟨b, hb⟩⟩ ↦ ⟨a, b, ⟨ha, hb⟩⟩, fun ⟨a, b, ⟨ha, hb⟩⟩ ↦ ⟨⟨a, ha⟩, ⟨b, hb⟩⟩⟩ export Classical (not_forall) theorem not_forall_not : (¬∀ x, ¬p x) ↔ ∃ x, p x := open scoped Classical in Decidable.not_forall_not export Classical (not_exists_not) lemma forall_or_exists_not (P : α → Prop) : (∀ a, P a) ∨ ∃ a, ¬ P a := by rw [← not_forall]; exact em _ lemma exists_or_forall_not (P : α → Prop) : (∃ a, P a) ∨ ∀ a, ¬ P a := by rw [← not_exists]; exact em _ theorem forall_imp_iff_exists_imp {α : Sort} {p : α → Prop} {b : Prop} [ha : Nonempty α] : (∀ x, p x) → b ↔ ∃ x, p x → b := by classical let ⟨a⟩ := ha refine ⟨fun h ↦ not_forall_not.1 fun h' ↦ ?_, fun ⟨x, hx⟩ h ↦ hx (h x)⟩ exact if hb : b then h' a fun _ ↦ hb else hb <\| h fun x ↦ (_root_.not_imp.1 (h' x)).1 @[mfld_simps] theorem forall_true_iff : (α → True) ↔ True := imp_true_iff _ -- Unfortunately this causes simp to loop sometimes, so we -- add the 2 and 3 cases as simp lemmas instead theorem forall_true_iff' (h : ∀ a, p a ↔ True) : (∀ a, p a) ↔ True := iff_true_intro fun _ ↦ of_iff_true (h _) -- This is not marked `@[simp]` because `implies_true : (α → True) = True` works theorem forall₂_true_iff {β : α → Sort} : (∀ a, β a → True) ↔ True := by simp -- This is not marked `@[simp]` because `implies_true : (α → True) = True` works theorem forall₃_true_iff {β : α → Sort} {γ : ∀ a, β a → Sort} : (∀ (a) (b : β a), γ a b → True) ↔ True := by simp theorem Decidable.and_forall_ne [DecidableEq α] (a : α) {p : α → Prop} : (p a ∧ ∀ b, b ≠ a → p b) ↔ ∀ b, p b := by simp only [← @forall_eq _ p a, ← forall_and, ← or_imp, Decidable.em, forall_const] theorem and_forall_ne (a : α) : (p a ∧ ∀ b, b ≠ a → p b) ↔ ∀ b, p b := open scoped Classical in Decidable.and_forall_ne a theorem Ne.ne_or_ne {x y : α} (z : α) (h : x ≠ y) : x ≠ z ∨ y ≠ z := not_and_or.1 <\| mt (and_imp.2 (· ▸ ·)) h.symm @[simp] theorem exists_apply_eq_apply' (f : α → β) (a' : α) : ∃ a, f a' = f a := ⟨a', rfl⟩ @[simp] lemma exists_apply_eq_apply2 {α β γ} {f : α → β → γ} {a : α} {b : β} : ∃ x y, f x y = f a b := ⟨a, b, rfl⟩ @[simp] lemma exists_apply_eq_apply2' {α β γ} {f : α → β → γ} {a : α} {b : β} : ∃ x y, f a b = f x y := ⟨a, b, rfl⟩ @[simp] lemma exists_apply_eq_apply3 {α β γ δ} {f : α → β → γ → δ} {a : α} {b : β} {c : γ} : ∃ x y z, f x y z = f a b c := ⟨a, b, c, rfl⟩ @[simp] lemma exists_apply_eq_apply3' {α β γ δ} {f : α → β → γ → δ} {a : α} {b : β} {c : γ} : ∃ x y z, f a b c = f x y z := ⟨a, b, c, rfl⟩ /-- The constant function witnesses that there exists a function sending a given term to a given term. This is sometimes useful in `simp` to discharge side conditions. -/ theorem exists_apply_eq (a : α) (b : β) : ∃ f : α → β, f a = b := ⟨fun _ ↦ b, rfl⟩ @[simp] theorem exists_exists_and_eq_and {f : α → β} {p : α → Prop} {q : β → Prop} : (∃ b, (∃ a, p a ∧ f a = b) ∧ q b) ↔ ∃ a, p a ∧ q (f a) := ⟨fun ⟨_, ⟨a, ha, hab⟩, hb⟩ ↦ ⟨a, ha, hab.symm ▸ hb⟩, fun ⟨a, hp, hq⟩ ↦ ⟨f a, ⟨a, hp, rfl⟩, hq⟩⟩ @[simp] theorem exists_exists_eq_and {f : α → β} {p : β → Prop} : (∃ b, (∃ a, f a = b) ∧ p b) ↔ ∃ a, p (f a) := ⟨fun ⟨_, ⟨a, ha⟩, hb⟩ ↦ ⟨a, ha.symm ▸ hb⟩, fun ⟨a, ha⟩ ↦ ⟨f a, ⟨a, rfl⟩, ha⟩⟩ @[simp] theorem exists_exists_and_exists_and_eq_and {α β γ : Type} {f : α → β → γ} {p : α → Prop} {q : β → Prop} {r : γ → Prop} : (∃ c, (∃ a, p a ∧ ∃ b, q b ∧ f a b = c) ∧ r c) ↔ ∃ a, p a ∧ ∃ b, q b ∧ r (f a b) := ⟨fun ⟨_, ⟨a, ha, b, hb, hab⟩, hc⟩ ↦ ⟨a, ha, b, hb, hab.symm ▸ hc⟩, fun ⟨a, ha, b, hb, hab⟩ ↦ ⟨f a b, ⟨a, ha, b, hb, rfl⟩, hab⟩⟩ @[simp] theorem exists_exists_exists_and_eq {α β γ : Type} {f : α → β → γ} {p : γ → Prop} : (∃ c, (∃ a, ∃ b, f a b = c) ∧ p c) ↔ ∃ a, ∃ b, p (f a b) := ⟨fun ⟨_, ⟨a, b, hab⟩, hc⟩ ↦ ⟨a, b, hab.symm ▸ hc⟩, fun ⟨a, b, hab⟩ ↦ ⟨f a b, ⟨a, b, rfl⟩, hab⟩⟩ theorem forall_apply_eq_imp_iff' {f : α → β} {p : β → Prop} : (∀ a b, f a = b → p b) ↔ ∀ a, p (f a) := by simp theorem forall_eq_apply_imp_iff' {f : α → β} {p : β → Prop} : (∀ a b, b = f a → p b) ↔ ∀ a, p (f a) := by simp theorem exists₂_comm {ι₁ ι₂ : Sort} {κ₁ : ι₁ → Sort} {κ₂ : ι₂ → Sort} {p : ∀ i₁, κ₁ i₁ → ∀ i₂, κ₂ i₂ → Prop} : (∃ i₁ j₁ i₂ j₂, p i₁ j₁ i₂ j₂) ↔ ∃ i₂ j₂ i₁ j₁, p i₁ j₁ i₂ j₂ := by simp only [@exists_comm (κ₁ _), @exists_comm ι₁] theorem And.exists {p q : Prop} {f : p ∧ q → Prop} : (∃ h, f h) ↔ ∃ hp hq, f ⟨hp, hq⟩ := ⟨fun ⟨h, H⟩ ↦ ⟨h.1, h.2, H⟩, fun ⟨hp, hq, H⟩ ↦ ⟨⟨hp, hq⟩, H⟩⟩ theorem forall_or_of_or_forall {α : Sort} {p : α → Prop} {b : Prop} (h : b ∨ ∀ x, p x) (x : α) : b ∨ p x := h.imp_right fun h₂ ↦ h₂ x -- See Note [decidable namespace] protected theorem Decidable.forall_or_left {q : Prop} {p : α → Prop} [Decidable q] : (∀ x, q ∨ p x) ↔ q ∨ ∀ x, p x := ⟨fun h ↦ if hq : q then Or.inl hq else Or.inr fun x ↦ (h x).resolve_left hq, forall_or_of_or_forall⟩ theorem forall_or_left {q} {p : α → Prop} : (∀ x, q ∨ p x) ↔ q ∨ ∀ x, p x := open scoped Classical in Decidable.forall_or_left -- See Note [decidable namespace] protected theorem Decidable.forall_or_right {q} {p : α → Prop} [Decidable q] : (∀ x, p x ∨ q) ↔ (∀ x, p x) ∨ q := by simp [or_comm, Decidable.forall_or_left] theorem forall_or_right {q} {p : α → Prop} : (∀ x, p x ∨ q) ↔ (∀ x, p x) ∨ q := open scoped Classical in Decidable.forall_or_right theorem Exists.fst {b : Prop} {p : b → Prop} : Exists p → b \| ⟨h, _⟩ => h theorem Exists.snd {b : Prop} {p : b → Prop} : ∀ h : Exists p, p h.fst \| ⟨_, h⟩ => h theorem Prop.exists_iff {p : Prop → Prop} : (∃ h, p h) ↔ p False ∨ p True := ⟨fun ⟨h₁, h₂⟩ ↦ by_cases (fun H : h₁ ↦ .inr <\| by simpa only [H] using h₂) (fun H ↦ .inl <\| by simpa only [H] using h₂), fun h ↦ h.elim (.intro _) (.intro _)⟩ theorem Prop.forall_iff {p : Prop → Prop} : (∀ h, p h) ↔ p False ∧ p True := ⟨fun H ↦ ⟨H _, H _⟩, fun ⟨h₁, h₂⟩ h ↦ by by_cases H : h <;> simpa only [H]⟩ theorem exists_iff_of_forall {p : Prop} {q : p → Prop} (h : ∀ h, q h) : (∃ h, q h) ↔ p := ⟨Exists.fst, fun H ↦ ⟨H, h H⟩⟩ theorem exists_prop_of_false {p : Prop} {q : p → Prop} : ¬p → ¬∃ h' : p, q h' := mt Exists.fst /- See `IsEmpty.exists_iff` for the `False` version of `exists_true_left`. -/ theorem forall_prop_congr {p p' : Prop} {q q' : p → Prop} (hq : ∀ h, q h ↔ q' h) (hp : p ↔ p') : (∀ h, q h) ↔ ∀ h : p', q' (hp.2 h) := ⟨fun h1 h2 ↦ (hq _).1 (h1 (hp.2 h2)), fun h1 h2 ↦ (hq _).2 (h1 (hp.1 h2))⟩ theorem forall_prop_congr' {p p' : Prop} {q q' : p → Prop} (hq : ∀ h, q h ↔ q' h) (hp : p ↔ p') : (∀ h, q h) = ∀ h : p', q' (hp.2 h) := propext (forall_prop_congr hq hp) lemma imp_congr_eq {a b c d : Prop} (h₁ : a = c) (h₂ : b = d) : (a → b) = (c → d) := propext (imp_congr h₁.to_iff h₂.to_iff) lemma imp_congr_ctx_eq {a b c d : Prop} (h₁ : a = c) (h₂ : c → b = d) : (a → b) = (c → d) := propext (imp_congr_ctx h₁.to_iff fun hc ↦ (h₂ hc).to_iff) lemma eq_true_intro {a : Prop} (h : a) : a = True := propext (iff_true_intro h) lemma eq_false_intro {a : Prop} (h : ¬a) : a = False := propext (iff_false_intro h) -- FIXME: `alias` creates `def Iff.eq := propext` instead of `lemma Iff.eq := propext` @[nolint defLemma] alias Iff.eq := propext lemma iff_eq_eq {a b : Prop} : (a ↔ b) = (a = b) := propext ⟨propext, Eq.to_iff⟩ -- They were not used in Lean 3 and there are already lemmas with those names in Lean 4 /-- See `IsEmpty.forall_iff` for the `False` version. -/ @[simp] theorem forall_true_left (p : True → Prop) : (∀ x, p x) ↔ p True.intro := forall_prop_of_true _ end Quantifiers /-! ### Classical lemmas -/ namespace Classical -- use shortened names to avoid conflict when classical namespace is open. /-- Any prop `p` is decidable classically. A shorthand for `Classical.propDecidable`. -/ noncomputable def dec (p : Prop) : Decidable p := by infer_instance variable {α : Sort} /-- Any predicate `p` is decidable classically. -/ noncomputable def decPred (p : α → Prop) : DecidablePred p := by infer_instance /-- Any relation `p` is decidable classically. -/ noncomputable def decRel (p : α → α → Prop) : DecidableRel p := by infer_instance /-- Any type `α` has decidable equality classically. -/ noncomputable def decEq (α : Sort) : DecidableEq α := by infer_instance /-- Construct a function from a default value `H0`, and a function to use if there exists a value satisfying the predicate. -/ noncomputable def existsCases {α C : Sort} {p : α → Prop} (H0 : C) (H : ∀ a, p a → C) : C := if h : ∃ a, p a then H (Classical.choose h) (Classical.choose_spec h) else H0 theorem some_spec₂ {α : Sort} {p : α → Prop} {h : ∃ a, p a} (q : α → Prop) (hpq : ∀ a, p a → q a) : q (choose h) := hpq _ <\| choose_spec _ /-- A version of `byContradiction` that uses types instead of propositions. -/ protected noncomputable def byContradiction' {α : Sort} (H : ¬(α → False)) : α := Classical.choice <\| (peirce _ False) fun h ↦ (H fun a ↦ h ⟨a⟩).elim /-- `Classical.byContradiction'` is equivalent to lean's axiom `Classical.choice`. -/ def choice_of_byContradiction' {α : Sort} (contra : ¬(α → False) → α) : Nonempty α → α := fun H ↦ contra H.elim @[simp] lemma choose_eq (a : α) : @Exists.choose _ (· = a) ⟨a, rfl⟩ = a := @choose_spec _ (· = a) _ @[simp] lemma choose_eq' (a : α) : @Exists.choose _ (a = ·) ⟨a, rfl⟩ = a := (@choose_spec _ (a = ·) _).symm alias axiom_of_choice := axiomOfChoice -- TODO: remove? rename in core? alias by_cases := byCases -- TODO: remove? rename in core? alias by_contradiction := byContradiction -- TODO: remove? rename in core? -- The remaining theorems in this section were ported from Lean 3, -- but are currently unused in Mathlib, so have been deprecated. -- If any are being used downstream, please remove the deprecation. alias prop_complete := propComplete -- TODO: remove? rename in core? end Classical /-- This function has the same type as `Exists.recOn`, and can be used to case on an equality, but `Exists.recOn` can only eliminate into Prop, while this version eliminates into any universe using the axiom of choice. -/ noncomputable def Exists.classicalRecOn {α : Sort} {p : α → Prop} (h : ∃ a, p a) {C : Sort} (H : ∀ a, p a → C) : C := H (Classical.choose h) (Classical.choose_spec h) /-! ### Declarations about bounded quantifiers -/ section BoundedQuantifiers variable {α : Sort} {r p q : α → Prop} {P Q : ∀ x, p x → Prop} theorem bex_def : (∃ (x : _) (_ : p x), q x) ↔ ∃ x, p x ∧ q x := ⟨fun ⟨x, px, qx⟩ ↦ ⟨x, px, qx⟩, fun ⟨x, px, qx⟩ ↦ ⟨x, px, qx⟩⟩ theorem BEx.elim {b : Prop} : (∃ x h, P x h) → (∀ a h, P a h → b) → b \| ⟨a, h₁, h₂⟩, h' => h' a h₁ h₂ theorem BEx.intro (a : α) (h₁ : p a) (h₂ : P a h₁) : ∃ (x : _) (h : p x), P x h := ⟨a, h₁, h₂⟩ theorem BAll.imp_right (H : ∀ x h, P x h → Q x h) (h₁ : ∀ x h, P x h) (x h) : Q x h := H _ _ <\| h₁ _ _ theorem BEx.imp_right (H : ∀ x h, P x h → Q x h) : (∃ x h, P x h) → ∃ x h, Q x h \| ⟨_, _, h'⟩ => ⟨_, _, H _ _ h'⟩ theorem BAll.imp_left (H : ∀ x, p x → q x) (h₁ : ∀ x, q x → r x) (x) (h : p x) : r x := h₁ _ <\| H _ h theorem BEx.imp_left (H : ∀ x, p x → q x) : (∃ (x : _) (_ : p x), r x) → ∃ (x : _) (_ : q x), r x \| ⟨x, hp, hr⟩ => ⟨x, H _ hp, hr⟩ theorem exists_mem_of_exists (H : ∀ x, p x) : (∃ x, q x) → ∃ (x : _) (_ : p x), q x \| ⟨x, hq⟩ => ⟨x, H x, hq⟩ theorem exists_of_exists_mem : (∃ (x : _) (_ : p x), q x) → ∃ x, q x \| ⟨x, _, hq⟩ => ⟨x, hq⟩ theorem not_exists_mem : (¬∃ x h, P x h) ↔ ∀ x h, ¬P x h := exists₂_imp theorem not_forall₂_of_exists₂_not : (∃ x h, ¬P x h) → ¬∀ x h, P x h \| ⟨x, h, hp⟩, al => hp <\| al x h -- See Note [decidable namespace] protected theorem Decidable.not_forall₂ [Decidable (∃ x h, ¬P x h)] [∀ x h, Decidable (P x h)] : (¬∀ x h, P x h) ↔ ∃ x h, ¬P x h := ⟨Not.decidable_imp_symm fun nx x h ↦ nx.decidable_imp_symm fun h' ↦ ⟨x, h, h'⟩, not_forall₂_of_exists₂_not⟩ theorem not_forall₂ : (¬∀ x h, P x h) ↔ ∃ x h, ¬P x h := open scoped Classical in Decidable.not_forall₂ theorem forall₂_and : (∀ x h, P x h ∧ Q x h) ↔ (∀ x h, P x h) ∧ ∀ x h, Q x h := Iff.trans (forall_congr' fun _ ↦ forall_and) forall_and theorem forall_and_left [Nonempty α] (q : Prop) (p : α → Prop) : (∀ x, q ∧ p x) ↔ (q ∧ ∀ x, p x) := by rw [forall_and, forall_const] theorem forall_and_right [Nonempty α] (p : α → Prop) (q : Prop) : (∀ x, p x ∧ q) ↔ (∀ x, p x) ∧ q := by rw [forall_and, forall_const] theorem exists_mem_or : (∃ x h, P x h ∨ Q x h) ↔ (∃ x h, P x h) ∨ ∃ x h, Q x h := Iff.trans (exists_congr fun _ ↦ exists_or) exists_or theorem forall₂_or_left : (∀ x, p x ∨ q x → r x) ↔ (∀ x, p x → r x) ∧ ∀ x, q x → r x := Iff.trans (forall_congr' fun _ ↦ or_imp) forall_and theorem exists_mem_or_left : (∃ (x : _) (_ : p x ∨ q x), r x) ↔ (∃ (x : _) (_ : p x), r x) ∨ ∃ (x : _) (_ : q x), r x := by simp only [exists_prop] exact Iff.trans (exists_congr fun x ↦ or_and_right) exists_or end BoundedQuantifiers section ite variable {α : Sort} {σ : α → Sort} {P Q R : Prop} [Decidable P] {a b c : α} {A : P → α} {B : ¬P → α} theorem dite_eq_iff : dite P A B = c ↔ (∃ h, A h = c) ∨ ∃ h, B h = c := by by_cases P <;> simp [*, exists_prop_of_true, exists_prop_of_false] theorem ite_eq_iff : ite P a b = c ↔ P ∧ a = c ∨ ¬P ∧ b = c := dite_eq_iff.trans <\| by rw [exists_prop, exists_prop] theorem eq_ite_iff : a = ite P b c ↔ P ∧ a = b ∨ ¬P ∧ a = c := eq_comm.trans <\| ite_eq_iff.trans <\| (Iff.rfl.and eq_comm).or (Iff.rfl.and eq_comm)	theorem dite_eq_iff' : dite P A B = c ↔ (∀ h, A h = c) ∧ ∀ h, B h = c := ⟨fun he ↦ ⟨fun h ↦ (dif_pos h).symm.trans he, fun h ↦ (dif_neg h).symm.trans he⟩, fun he ↦	Mathlib/Logic/Basic.lean	828	829
/- Copyright (c) 2024 Joël Riou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joël Riou -/ import Mathlib.Algebra.Homology.ShortComplex.Exact import Mathlib.CategoryTheory.Shift.ShiftSequence import Mathlib.CategoryTheory.Triangulated.Functor import Mathlib.CategoryTheory.Triangulated.Subcategory import Mathlib.Algebra.Homology.ExactSequence /-! # Homological functors In this file, given a functor `F : C ⥤ A` from a pretriangulated category to an abelian category, we define the type class `F.IsHomological`, which is the property that `F` sends distinguished triangles in `C` to exact sequences in `A`. If `F` has been endowed with `[F.ShiftSequence ℤ]`, then we may think of the functor `F` as a `H^0`, and then the `H^n` functors are the functors `F.shift n : C ⥤ A`: we have isomorphisms `(F.shift n).obj X ≅ F.obj (X⟦n⟧)`, but through the choice of this "shift sequence", the user may provide functors with better definitional properties. Given a triangle `T` in `C`, we define a connecting homomorphism `F.homologySequenceδ T n₀ n₁ h : (F.shift n₀).obj T.obj₃ ⟶ (F.shift n₁).obj T.obj₁` under the assumption `h : n₀ + 1 = n₁`. When `T` is distinguished, this connecting homomorphism is part of a long exact sequence `... ⟶ (F.shift n₀).obj T.obj₁ ⟶ (F.shift n₀).obj T.obj₂ ⟶ (F.shift n₀).obj T.obj₃ ⟶ ...` The exactness of this long exact sequence is given by three lemmas `F.homologySequence_exact₁`, `F.homologySequence_exact₂` and `F.homologySequence_exact₃`. If `F` is a homological functor, we define the strictly full triangulated subcategory `F.homologicalKernel`: it consists of objects `X : C` such that for all `n : ℤ`, `(F.shift n).obj X` (or `F.obj (X⟦n⟧)`) is zero. We show that a morphism `f` in `C` belongs to `F.homologicalKernel.W` (i.e. the cone of `f` is in this kernel) iff `(F.shift n).map f` is an isomorphism for all `n : ℤ`. Note: depending on the sources, homological functors are sometimes called cohomological functors, while certain authors use "cohomological functors" for "contravariant" functors (i.e. functors `Cᵒᵖ ⥤ A`). ## TODO * The long exact sequence in homology attached to an homological functor. ## References * [Jean-Louis Verdier, Des catégories dérivées des catégories abéliennes][verdier1996] -/ namespace CategoryTheory open Category Limits Pretriangulated ZeroObject Preadditive variable {C D A : Type*} [Category C] [HasShift C ℤ] [Category D] [HasZeroObject D] [HasShift D ℤ] [Preadditive D] [∀ (n : ℤ), (CategoryTheory.shiftFunctor D n).Additive] [Pretriangulated D] [Category A] namespace Functor variable (F : C ⥤ A) section Pretriangulated variable [HasZeroObject C] [Preadditive C] [∀ (n : ℤ), (CategoryTheory.shiftFunctor C n).Additive] [Pretriangulated C] [Abelian A] /-- A functor from a pretriangulated category to an abelian category is an homological functor if it sends distinguished triangles to exact sequences. -/ class IsHomological : Prop extends F.PreservesZeroMorphisms where exact (T : Triangle C) (hT : T ∈ distTriang C) : ((shortComplexOfDistTriangle T hT).map F).Exact lemma map_distinguished_exact [F.IsHomological] (T : Triangle C) (hT : T ∈ distTriang C) : ((shortComplexOfDistTriangle T hT).map F).Exact := IsHomological.exact _ hT instance (L : C ⥤ D) (F : D ⥤ A) [L.CommShift ℤ] [L.IsTriangulated] [F.IsHomological] : (L ⋙ F).IsHomological where exact T hT := F.map_distinguished_exact _ (L.map_distinguished T hT) lemma IsHomological.mk' [F.PreservesZeroMorphisms] (hF : ∀ (T : Pretriangulated.Triangle C) (hT : T ∈ distTriang C), ∃ (T' : Pretriangulated.Triangle C) (e : T ≅ T'), ((shortComplexOfDistTriangle T' (isomorphic_distinguished _ hT _ e.symm)).map F).Exact) : F.IsHomological where exact T hT := by obtain ⟨T', e, h'⟩ := hF T hT exact (ShortComplex.exact_iff_of_iso (F.mapShortComplex.mapIso ((shortComplexOfDistTriangleIsoOfIso e hT)))).2 h' lemma IsHomological.of_iso {F₁ F₂ : C ⥤ A} [F₁.IsHomological] (e : F₁ ≅ F₂) : F₂.IsHomological := have := preservesZeroMorphisms_of_iso e ⟨fun T hT => ShortComplex.exact_of_iso (ShortComplex.mapNatIso _ e) (F₁.map_distinguished_exact T hT)⟩ /-- The kernel of a homological functor `F : C ⥤ A` is the strictly full triangulated subcategory consisting of objects `X` such that for all `n : ℤ`, `F.obj (X⟦n⟧)` is zero. -/ def homologicalKernel [F.IsHomological] : Triangulated.Subcategory C := Triangulated.Subcategory.mk' (fun X => ∀ (n : ℤ), IsZero (F.obj (X⟦n⟧))) (fun n => by rw [IsZero.iff_id_eq_zero, ← F.map_id, ← Functor.map_id, id_zero, Functor.map_zero, Functor.map_zero]) (fun X a hX b => IsZero.of_iso (hX (a + b)) (F.mapIso ((shiftFunctorAdd C a b).app X).symm)) (fun T hT h₁ h₃ n => (F.map_distinguished_exact _ (Triangle.shift_distinguished T hT n)).isZero_of_both_zeros (IsZero.eq_of_src (h₁ n) _ _) (IsZero.eq_of_tgt (h₃ n) _ _)) instance [F.IsHomological] : F.homologicalKernel.P.IsClosedUnderIsomorphisms := by dsimp only [homologicalKernel] infer_instance lemma mem_homologicalKernel_iff [F.IsHomological] [F.ShiftSequence ℤ] (X : C) : F.homologicalKernel.P X ↔ ∀ (n : ℤ), IsZero ((F.shift n).obj X) := by simp only [← fun (n : ℤ) => Iso.isZero_iff ((F.isoShift n).app X)] rfl noncomputable instance (priority := 100) [F.IsHomological] : PreservesLimitsOfShape (Discrete WalkingPair) F := by suffices ∀ (X₁ X₂ : C), PreservesLimit (pair X₁ X₂) F from ⟨fun {X} => preservesLimit_of_iso_diagram F (diagramIsoPair X).symm⟩ intro X₁ X₂ have : HasBinaryBiproduct (F.obj X₁) (F.obj X₂) := HasBinaryBiproducts.has_binary_biproduct _ _ have : Mono (F.biprodComparison X₁ X₂) := by rw [mono_iff_cancel_zero] intro Z f hf let S := (ShortComplex.mk _ _ (biprod.inl_snd (X := X₁) (Y := X₂))).map F have : Mono S.f := by dsimp [S]; infer_instance have ex : S.Exact := F.map_distinguished_exact _ (binaryBiproductTriangle_distinguished X₁ X₂) obtain ⟨g, rfl⟩ := ex.lift' f (by simpa using hf =≫ biprod.snd) dsimp [S] at hf ⊢ replace hf := hf =≫ biprod.fst simp only [assoc, biprodComparison_fst, zero_comp, ← F.map_comp, biprod.inl_fst, F.map_id, comp_id] at hf rw [hf, zero_comp] have : PreservesBinaryBiproduct X₁ X₂ F := preservesBinaryBiproduct_of_mono_biprodComparison _ apply Limits.preservesBinaryProduct_of_preservesBinaryBiproduct instance (priority := 100) [F.IsHomological] : F.Additive := F.additive_of_preserves_binary_products lemma isHomological_of_localization (L : C ⥤ D) [L.CommShift ℤ] [L.IsTriangulated] [L.mapArrow.EssSurj] (F : D ⥤ A) (G : C ⥤ A) (e : L ⋙ F ≅ G) [G.IsHomological] : F.IsHomological := by have : F.PreservesZeroMorphisms := preservesZeroMorphisms_of_map_zero_object (F.mapIso L.mapZeroObject.symm ≪≫ e.app _ ≪≫ G.mapZeroObject) have : (L ⋙ F).IsHomological := IsHomological.of_iso e.symm refine IsHomological.mk' _ (fun T hT => ?_) rw [L.distTriang_iff] at hT obtain ⟨T₀, e, hT₀⟩ := hT exact ⟨L.mapTriangle.obj T₀, e, (L ⋙ F).map_distinguished_exact _ hT₀⟩ end Pretriangulated section /-- The connecting homomorphism in the long exact sequence attached to an homological functor and a distinguished triangle. -/ noncomputable def homologySequenceδ [F.ShiftSequence ℤ] (T : Triangle C) (n₀ n₁ : ℤ) (h : n₀ + 1 = n₁) : (F.shift n₀).obj T.obj₃ ⟶ (F.shift n₁).obj T.obj₁ := F.shiftMap T.mor₃ n₀ n₁ (by rw [add_comm 1, h]) variable {T T'} @[reassoc] lemma homologySequenceδ_naturality [F.ShiftSequence ℤ] (T T' : Triangle C) (φ : T ⟶ T') (n₀ n₁ : ℤ) (h : n₀ + 1 = n₁) : (F.shift n₀).map φ.hom₃ ≫ F.homologySequenceδ T' n₀ n₁ h = F.homologySequenceδ T n₀ n₁ h ≫ (F.shift n₁).map φ.hom₁ := by dsimp only [homologySequenceδ] rw [← shiftMap_comp', ← φ.comm₃, shiftMap_comp] variable (T) variable [HasZeroObject C] [Preadditive C] [∀ (n : ℤ), (CategoryTheory.shiftFunctor C n).Additive] [Pretriangulated C] [Abelian A] [F.IsHomological] variable [F.ShiftSequence ℤ] (T T' : Triangle C) (hT : T ∈ distTriang C) (hT' : T' ∈ distTriang C) (φ : T ⟶ T') (n₀ n₁ : ℤ) (h : n₀ + 1 = n₁) section include hT @[reassoc] lemma comp_homologySequenceδ : (F.shift n₀).map T.mor₂ ≫ F.homologySequenceδ T n₀ n₁ h = 0 := by dsimp only [homologySequenceδ] rw [← F.shiftMap_comp', comp_distTriang_mor_zero₂₃ _ hT, shiftMap_zero] @[reassoc] lemma homologySequenceδ_comp : F.homologySequenceδ T n₀ n₁ h ≫ (F.shift n₁).map T.mor₁ = 0 := by dsimp only [homologySequenceδ] rw [← F.shiftMap_comp, comp_distTriang_mor_zero₃₁ _ hT, shiftMap_zero] @[reassoc] lemma homologySequence_comp : (F.shift n₀).map T.mor₁ ≫ (F.shift n₀).map T.mor₂ = 0 := by rw [← Functor.map_comp, comp_distTriang_mor_zero₁₂ _ hT, Functor.map_zero] attribute [local simp] smul_smul lemma homologySequence_exact₂ : (ShortComplex.mk _ _ (F.homologySequence_comp T hT n₀)).Exact := by refine ShortComplex.exact_of_iso ?_ (F.map_distinguished_exact _ (Triangle.shift_distinguished _ hT n₀)) exact ShortComplex.isoMk ((F.isoShift n₀).app _) (n₀.negOnePow • ((F.isoShift n₀).app _)) ((F.isoShift n₀).app _) (by dsimp; simp) (by dsimp; simp) lemma homologySequence_exact₃ : (ShortComplex.mk _ _ (F.comp_homologySequenceδ T hT _ _ h)).Exact := by refine ShortComplex.exact_of_iso ?_ (F.homologySequence_exact₂ _ (rot_of_distTriang _ hT) n₀) exact ShortComplex.isoMk (Iso.refl _) (Iso.refl _) ((F.shiftIso 1 n₀ n₁ (by omega)).app _) (by simp) (by simp [homologySequenceδ, shiftMap]) lemma homologySequence_exact₁ : (ShortComplex.mk _ _ (F.homologySequenceδ_comp T hT _ _ h)).Exact := by refine ShortComplex.exact_of_iso ?_ (F.homologySequence_exact₂ _ (inv_rot_of_distTriang _ hT) n₁) refine ShortComplex.isoMk (-((F.shiftIso (-1) n₁ n₀ (by omega)).app _)) (Iso.refl _) (Iso.refl _) ?_ (by simp) dsimp simp only [homologySequenceδ, neg_comp, map_neg, comp_id, F.shiftIso_hom_app_comp_shiftMap_of_add_eq_zero T.mor₃ (-1) (neg_add_cancel 1) n₀ n₁ (by omega)] lemma homologySequence_epi_shift_map_mor₁_iff : Epi ((F.shift n₀).map T.mor₁) ↔ (F.shift n₀).map T.mor₂ = 0 := (F.homologySequence_exact₂ T hT n₀).epi_f_iff lemma homologySequence_mono_shift_map_mor₁_iff : Mono ((F.shift n₁).map T.mor₁) ↔ F.homologySequenceδ T n₀ n₁ h = 0 :=	(F.homologySequence_exact₁ T hT n₀ n₁ h).mono_g_iff lemma homologySequence_epi_shift_map_mor₂_iff : Epi ((F.shift n₀).map T.mor₂) ↔ F.homologySequenceδ T n₀ n₁ h = 0 := (F.homologySequence_exact₃ T hT n₀ n₁ h).epi_f_iff lemma homologySequence_mono_shift_map_mor₂_iff : Mono ((F.shift n₀).map T.mor₂) ↔ (F.shift n₀).map T.mor₁ = 0 := (F.homologySequence_exact₂ T hT n₀).mono_g_iff end lemma mem_homologicalKernel_W_iff {X Y : C} (f : X ⟶ Y) : F.homologicalKernel.W f ↔ ∀ (n : ℤ), IsIso ((F.shift n).map f) := by obtain ⟨Z, g, h, hT⟩ := distinguished_cocone_triangle f apply (F.homologicalKernel.mem_W_iff_of_distinguished _ hT).trans have h₁ := fun n => (F.homologySequence_exact₃ _ hT n _ rfl).isZero_X₂_iff have h₂ := fun n => F.homologySequence_mono_shift_map_mor₁_iff _ hT n _ rfl	Mathlib/CategoryTheory/Triangulated/HomologicalFunctor.lean	235	251
/- Copyright (c) 2020 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.Algebra.Group.Basic import Mathlib.Algebra.Group.Pi.Basic import Mathlib.Algebra.Notation.Prod import Mathlib.Data.Set.Image /-! # Support of a function In this file we define `Function.support f = {x \| f x ≠ 0}` and prove its basic properties. We also define `Function.mulSupport f = {x \| f x ≠ 1}`. -/ assert_not_exists CompleteLattice MonoidWithZero open Set namespace Function variable {α β A B M M' N P G : Type} section One variable [One M] [One N] [One P] /-- `mulSupport` of a function is the set of points `x` such that `f x ≠ 1`. -/ @[to_additive "`support` of a function is the set of points `x` such that `f x ≠ 0`."] def mulSupport (f : α → M) : Set α := {x \| f x ≠ 1} @[to_additive] theorem mulSupport_eq_preimage (f : α → M) : mulSupport f = f ⁻¹' {1}ᶜ := rfl @[to_additive] theorem nmem_mulSupport {f : α → M} {x : α} : x ∉ mulSupport f ↔ f x = 1 := not_not @[to_additive] theorem compl_mulSupport {f : α → M} : (mulSupport f)ᶜ = { x \| f x = 1 } := ext fun _ => nmem_mulSupport @[to_additive (attr := simp)] theorem mem_mulSupport {f : α → M} {x : α} : x ∈ mulSupport f ↔ f x ≠ 1 := Iff.rfl @[to_additive (attr := simp)] theorem mulSupport_subset_iff {f : α → M} {s : Set α} : mulSupport f ⊆ s ↔ ∀ x, f x ≠ 1 → x ∈ s := Iff.rfl @[to_additive] theorem mulSupport_subset_iff' {f : α → M} {s : Set α} : mulSupport f ⊆ s ↔ ∀ x ∉ s, f x = 1 := forall_congr' fun _ => not_imp_comm @[to_additive] theorem mulSupport_eq_iff {f : α → M} {s : Set α} : mulSupport f = s ↔ (∀ x, x ∈ s → f x ≠ 1) ∧ ∀ x, x ∉ s → f x = 1 := by simp +contextual only [Set.ext_iff, mem_mulSupport, ne_eq, iff_def, not_imp_comm, and_comm, forall_and] @[to_additive] theorem ext_iff_mulSupport {f g : α → M} : f = g ↔ f.mulSupport = g.mulSupport ∧ ∀ x ∈ f.mulSupport, f x = g x := ⟨fun h ↦ h ▸ ⟨rfl, fun _ _ ↦ rfl⟩, fun ⟨h₁, h₂⟩ ↦ funext fun x ↦ by if hx : x ∈ f.mulSupport then exact h₂ x hx else rw [nmem_mulSupport.1 hx, nmem_mulSupport.1 (mt (Set.ext_iff.1 h₁ x).2 hx)]⟩ @[to_additive] theorem mulSupport_update_of_ne_one [DecidableEq α] (f : α → M) (x : α) {y : M} (hy : y ≠ 1) : mulSupport (update f x y) = insert x (mulSupport f) := by ext a; rcases eq_or_ne a x with rfl \| hne <;> simp [] @[to_additive] theorem mulSupport_update_one [DecidableEq α] (f : α → M) (x : α) : mulSupport (update f x 1) = mulSupport f \ {x} := by ext a; rcases eq_or_ne a x with rfl \| hne <;> simp [] @[to_additive] theorem mulSupport_update_eq_ite [DecidableEq α] [DecidableEq M] (f : α → M) (x : α) (y : M) : mulSupport (update f x y) = if y = 1 then mulSupport f \ {x} else insert x (mulSupport f) := by rcases eq_or_ne y 1 with rfl \| hy <;> simp [mulSupport_update_one, mulSupport_update_of_ne_one, ] @[to_additive] theorem mulSupport_extend_one_subset {f : α → M'} {g : α → N} : mulSupport (f.extend g 1) ⊆ f '' mulSupport g := mulSupport_subset_iff'.mpr fun x hfg ↦ by by_cases hf : ∃ a, f a = x · rw [extend, dif_pos hf, ← nmem_mulSupport] rw [← Classical.choose_spec hf] at hfg exact fun hg ↦ hfg ⟨_, hg, rfl⟩ · rw [extend_apply' _ _ _ hf]; rfl @[to_additive] theorem mulSupport_extend_one {f : α → M'} {g : α → N} (hf : f.Injective) :	mulSupport (f.extend g 1) = f '' mulSupport g := mulSupport_extend_one_subset.antisymm <\| by rintro _ ⟨x, hx, rfl⟩; rwa [mem_mulSupport, hf.extend_apply]	Mathlib/Algebra/Group/Support.lean	98	100
/- 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.FieldTheory.Finiteness import Mathlib.LinearAlgebra.AffineSpace.Basis import Mathlib.LinearAlgebra.FiniteDimensional.Lemmas /-! # Finite-dimensional subspaces of affine spaces. This file provides a few results relating to finite-dimensional subspaces of affine spaces. ## Main definitions * `Collinear` defines collinear sets of points as those that span a subspace of dimension at most 1. -/ noncomputable section open Affine open scoped Finset section AffineSpace' variable (k : Type) {V : Type} {P : Type} variable {ι : Type} open AffineSubspace Module variable [DivisionRing k] [AddCommGroup V] [Module k V] [AffineSpace V P] /-- The `vectorSpan` of a finite set is finite-dimensional. -/ theorem finiteDimensional_vectorSpan_of_finite {s : Set P} (h : Set.Finite s) : FiniteDimensional k (vectorSpan k s) := .span_of_finite k <\| h.vsub h /-- The vector span of a singleton is finite-dimensional. -/ instance finiteDimensional_vectorSpan_singleton (p : P) : FiniteDimensional k (vectorSpan k {p}) := finiteDimensional_vectorSpan_of_finite _ (Set.finite_singleton p) /-- The `vectorSpan` of a family indexed by a `Fintype` is finite-dimensional. -/ instance finiteDimensional_vectorSpan_range [Finite ι] (p : ι → P) : FiniteDimensional k (vectorSpan k (Set.range p)) := finiteDimensional_vectorSpan_of_finite k (Set.finite_range _) /-- The `vectorSpan` of a subset of a family indexed by a `Fintype` is finite-dimensional. -/ instance finiteDimensional_vectorSpan_image_of_finite [Finite ι] (p : ι → P) (s : Set ι) : FiniteDimensional k (vectorSpan k (p '' s)) := finiteDimensional_vectorSpan_of_finite k (Set.toFinite _) /-- The direction of the affine span of a finite set is finite-dimensional. -/ theorem finiteDimensional_direction_affineSpan_of_finite {s : Set P} (h : Set.Finite s) : FiniteDimensional k (affineSpan k s).direction := (direction_affineSpan k s).symm ▸ finiteDimensional_vectorSpan_of_finite k h /-- The direction of the affine span of a singleton is finite-dimensional. -/ instance finiteDimensional_direction_affineSpan_singleton (p : P) : FiniteDimensional k (affineSpan k {p}).direction := by rw [direction_affineSpan] infer_instance /-- The direction of the affine span of a family indexed by a `Fintype` is finite-dimensional. -/ instance finiteDimensional_direction_affineSpan_range [Finite ι] (p : ι → P) : FiniteDimensional k (affineSpan k (Set.range p)).direction := finiteDimensional_direction_affineSpan_of_finite k (Set.finite_range _) /-- The direction of the affine span of a subset of a family indexed by a `Fintype` is finite-dimensional. -/ instance finiteDimensional_direction_affineSpan_image_of_finite [Finite ι] (p : ι → P) (s : Set ι) : FiniteDimensional k (affineSpan k (p '' s)).direction := finiteDimensional_direction_affineSpan_of_finite k (Set.toFinite _) /-- An affine-independent family of points in a finite-dimensional affine space is finite. -/ theorem finite_of_fin_dim_affineIndependent [FiniteDimensional k V] {p : ι → P} (hi : AffineIndependent k p) : Finite ι := by nontriviality ι; inhabit ι rw [affineIndependent_iff_linearIndependent_vsub k p default] at hi letI : IsNoetherian k V := IsNoetherian.iff_fg.2 inferInstance exact (Set.finite_singleton default).finite_of_compl (Set.finite_coe_iff.1 hi.finite_of_isNoetherian) /-- An affine-independent subset of a finite-dimensional affine space is finite. -/ theorem finite_set_of_fin_dim_affineIndependent [FiniteDimensional k V] {s : Set ι} {f : s → P} (hi : AffineIndependent k f) : s.Finite := @Set.toFinite _ s (finite_of_fin_dim_affineIndependent k hi) variable {k} /-- The `vectorSpan` of a finite subset of an affinely independent family has dimension one less than its cardinality. -/ theorem AffineIndependent.finrank_vectorSpan_image_finset [DecidableEq P] {p : ι → P} (hi : AffineIndependent k p) {s : Finset ι} {n : ℕ} (hc : #s = n + 1) : finrank k (vectorSpan k (s.image p : Set P)) = n := by classical have hi' := hi.range.mono (Set.image_subset_range p ↑s) have hc' : #(s.image p) = n + 1 := by rwa [s.card_image_of_injective hi.injective] have hn : (s.image p).Nonempty := by simp [hc', ← Finset.card_pos] rcases hn with ⟨p₁, hp₁⟩ have hp₁' : p₁ ∈ p '' s := by simpa using hp₁ rw [affineIndependent_set_iff_linearIndependent_vsub k hp₁', ← Finset.coe_singleton, ← Finset.coe_image, ← Finset.coe_sdiff, Finset.sdiff_singleton_eq_erase, ← Finset.coe_image] at hi' have hc : #(((s.image p).erase p₁).image (· -ᵥ p₁)) = n := by rw [Finset.card_image_of_injective _ (vsub_left_injective _), Finset.card_erase_of_mem hp₁] exact Nat.pred_eq_of_eq_succ hc' rwa [vectorSpan_eq_span_vsub_finset_right_ne k hp₁, finrank_span_finset_eq_card, hc] /-- The `vectorSpan` of a finite affinely independent family has dimension one less than its cardinality. -/ theorem AffineIndependent.finrank_vectorSpan [Fintype ι] {p : ι → P} (hi : AffineIndependent k p) {n : ℕ} (hc : Fintype.card ι = n + 1) : finrank k (vectorSpan k (Set.range p)) = n := by classical rw [← Finset.card_univ] at hc rw [← Set.image_univ, ← Finset.coe_univ, ← Finset.coe_image] exact hi.finrank_vectorSpan_image_finset hc /-- The `vectorSpan` of a finite affinely independent family has dimension one less than its cardinality. -/ lemma AffineIndependent.finrank_vectorSpan_add_one [Fintype ι] [Nonempty ι] {p : ι → P} (hi : AffineIndependent k p) : finrank k (vectorSpan k (Set.range p)) + 1 = Fintype.card ι := by rw [hi.finrank_vectorSpan (tsub_add_cancel_of_le _).symm, tsub_add_cancel_of_le] <;> exact Fintype.card_pos /-- The `vectorSpan` of a finite affinely independent family whose cardinality is one more than that of the finite-dimensional space is `⊤`. -/ theorem AffineIndependent.vectorSpan_eq_top_of_card_eq_finrank_add_one [FiniteDimensional k V] [Fintype ι] {p : ι → P} (hi : AffineIndependent k p) (hc : Fintype.card ι = finrank k V + 1) : vectorSpan k (Set.range p) = ⊤ := Submodule.eq_top_of_finrank_eq <\| hi.finrank_vectorSpan hc variable (k) /-- The `vectorSpan` of `n + 1` points in an indexed family has dimension at most `n`. -/ theorem finrank_vectorSpan_image_finset_le [DecidableEq P] (p : ι → P) (s : Finset ι) {n : ℕ} (hc : #s = n + 1) : finrank k (vectorSpan k (s.image p : Set P)) ≤ n := by classical have hn : (s.image p).Nonempty := by rw [Finset.image_nonempty, ← Finset.card_pos, hc] apply Nat.succ_pos rcases hn with ⟨p₁, hp₁⟩ rw [vectorSpan_eq_span_vsub_finset_right_ne k hp₁] refine le_trans (finrank_span_finset_le_card (((s.image p).erase p₁).image fun p => p -ᵥ p₁)) ?_ rw [Finset.card_image_of_injective _ (vsub_left_injective p₁), Finset.card_erase_of_mem hp₁, tsub_le_iff_right, ← hc] apply Finset.card_image_le /-- The `vectorSpan` of an indexed family of `n + 1` points has dimension at most `n`. -/ theorem finrank_vectorSpan_range_le [Fintype ι] (p : ι → P) {n : ℕ} (hc : Fintype.card ι = n + 1) : finrank k (vectorSpan k (Set.range p)) ≤ n := by classical rw [← Set.image_univ, ← Finset.coe_univ, ← Finset.coe_image] rw [← Finset.card_univ] at hc exact finrank_vectorSpan_image_finset_le _ _ _ hc /-- The `vectorSpan` of an indexed family of `n + 1` points has dimension at most `n`. -/ lemma finrank_vectorSpan_range_add_one_le [Fintype ι] [Nonempty ι] (p : ι → P) : finrank k (vectorSpan k (Set.range p)) + 1 ≤ Fintype.card ι := (le_tsub_iff_right <\| Nat.succ_le_iff.2 Fintype.card_pos).1 <\| finrank_vectorSpan_range_le _ _ (tsub_add_cancel_of_le <\| Nat.succ_le_iff.2 Fintype.card_pos).symm /-- `n + 1` points are affinely independent if and only if their `vectorSpan` has dimension `n`. -/ theorem affineIndependent_iff_finrank_vectorSpan_eq [Fintype ι] (p : ι → P) {n : ℕ} (hc : Fintype.card ι = n + 1) : AffineIndependent k p ↔ finrank k (vectorSpan k (Set.range p)) = n := by classical have hn : Nonempty ι := by simp [← Fintype.card_pos_iff, hc] obtain ⟨i₁⟩ := hn rw [affineIndependent_iff_linearIndependent_vsub _ _ i₁, linearIndependent_iff_card_eq_finrank_span, eq_comm, vectorSpan_range_eq_span_range_vsub_right_ne k p i₁, Set.finrank] rw [← Finset.card_univ] at hc rw [Fintype.subtype_card] simp [Finset.filter_ne', Finset.card_erase_of_mem, hc] /-- `n + 1` points are affinely independent if and only if their `vectorSpan` has dimension at least `n`. -/ theorem affineIndependent_iff_le_finrank_vectorSpan [Fintype ι] (p : ι → P) {n : ℕ} (hc : Fintype.card ι = n + 1) : AffineIndependent k p ↔ n ≤ finrank k (vectorSpan k (Set.range p)) := by rw [affineIndependent_iff_finrank_vectorSpan_eq k p hc] constructor · rintro rfl rfl · exact fun hle => le_antisymm (finrank_vectorSpan_range_le k p hc) hle /-- `n + 2` points are affinely independent if and only if their `vectorSpan` does not have dimension at most `n`. -/ theorem affineIndependent_iff_not_finrank_vectorSpan_le [Fintype ι] (p : ι → P) {n : ℕ} (hc : Fintype.card ι = n + 2) : AffineIndependent k p ↔ ¬finrank k (vectorSpan k (Set.range p)) ≤ n := by rw [affineIndependent_iff_le_finrank_vectorSpan k p hc, ← Nat.lt_iff_add_one_le, lt_iff_not_ge] /-- `n + 2` points have a `vectorSpan` with dimension at most `n` if and only if they are not affinely independent. -/ theorem finrank_vectorSpan_le_iff_not_affineIndependent [Fintype ι] (p : ι → P) {n : ℕ} (hc : Fintype.card ι = n + 2) : finrank k (vectorSpan k (Set.range p)) ≤ n ↔ ¬AffineIndependent k p := (not_iff_comm.1 (affineIndependent_iff_not_finrank_vectorSpan_le k p hc).symm).symm variable {k} lemma AffineIndependent.card_le_finrank_succ [Fintype ι] {p : ι → P} (hp : AffineIndependent k p) : Fintype.card ι ≤ Module.finrank k (vectorSpan k (Set.range p)) + 1 := by cases isEmpty_or_nonempty ι · simp [Fintype.card_eq_zero] rw [← tsub_le_iff_right] exact (affineIndependent_iff_le_finrank_vectorSpan _ _ (tsub_add_cancel_of_le <\| Nat.one_le_iff_ne_zero.2 Fintype.card_ne_zero).symm).1 hp open Finset in /-- If an affine independent finset is contained in the affine span of another finset, then its cardinality is at most the cardinality of that finset. -/ lemma AffineIndependent.card_le_card_of_subset_affineSpan {s t : Finset V} (hs : AffineIndependent k ((↑) : s → V)) (hst : (s : Set V) ⊆ affineSpan k (t : Set V)) : #s ≤ #t := by obtain rfl \| hs' := s.eq_empty_or_nonempty · simp obtain rfl \| ht' := t.eq_empty_or_nonempty · simpa [Set.subset_empty_iff] using hst have := hs'.to_subtype have := ht'.to_set.to_subtype have direction_le := AffineSubspace.direction_le (affineSpan_mono k hst) rw [AffineSubspace.affineSpan_coe, direction_affineSpan, direction_affineSpan, ← @Subtype.range_coe _ (s : Set V), ← @Subtype.range_coe _ (t : Set V)] at direction_le have finrank_le := add_le_add_right (Submodule.finrank_mono direction_le) 1 -- We use `erw` to elide the difference between `↥s` and `↥(s : Set V)}` erw [hs.finrank_vectorSpan_add_one] at finrank_le simpa using finrank_le.trans <\| finrank_vectorSpan_range_add_one_le _ _ open Finset in /-- If the affine span of an affine independent finset is strictly contained in the affine span of another finset, then its cardinality is strictly less than the cardinality of that finset. -/ lemma AffineIndependent.card_lt_card_of_affineSpan_lt_affineSpan {s t : Finset V} (hs : AffineIndependent k ((↑) : s → V)) (hst : affineSpan k (s : Set V) < affineSpan k (t : Set V)) : #s < #t := by obtain rfl \| hs' := s.eq_empty_or_nonempty · simpa [card_pos] using hst obtain rfl \| ht' := t.eq_empty_or_nonempty · simp [Set.subset_empty_iff] at hst have := hs'.to_subtype have := ht'.to_set.to_subtype have dir_lt := AffineSubspace.direction_lt_of_nonempty (k := k) hst <\| hs'.to_set.affineSpan k rw [direction_affineSpan, direction_affineSpan, ← @Subtype.range_coe _ (s : Set V), ← @Subtype.range_coe _ (t : Set V)] at dir_lt have finrank_lt := add_lt_add_right (Submodule.finrank_lt_finrank_of_lt dir_lt) 1 -- We use `erw` to elide the difference between `↥s` and `↥(s : Set V)}` erw [hs.finrank_vectorSpan_add_one] at finrank_lt simpa using finrank_lt.trans_le <\| finrank_vectorSpan_range_add_one_le _ _ /-- If the `vectorSpan` of a finite subset of an affinely independent family lies in a submodule with dimension one less than its cardinality, it equals that submodule. -/ theorem AffineIndependent.vectorSpan_image_finset_eq_of_le_of_card_eq_finrank_add_one [DecidableEq P] {p : ι → P} (hi : AffineIndependent k p) {s : Finset ι} {sm : Submodule k V} [FiniteDimensional k sm] (hle : vectorSpan k (s.image p : Set P) ≤ sm) (hc : #s = finrank k sm + 1) : vectorSpan k (s.image p : Set P) = sm := Submodule.eq_of_le_of_finrank_eq hle <\| hi.finrank_vectorSpan_image_finset hc /-- If the `vectorSpan` of a finite affinely independent family lies in a submodule with dimension one less than its cardinality, it equals that submodule. -/ theorem AffineIndependent.vectorSpan_eq_of_le_of_card_eq_finrank_add_one [Fintype ι] {p : ι → P} (hi : AffineIndependent k p) {sm : Submodule k V} [FiniteDimensional k sm] (hle : vectorSpan k (Set.range p) ≤ sm) (hc : Fintype.card ι = finrank k sm + 1) : vectorSpan k (Set.range p) = sm := Submodule.eq_of_le_of_finrank_eq hle <\| hi.finrank_vectorSpan hc /-- If the `affineSpan` of a finite subset of an affinely independent family lies in an affine subspace whose direction has dimension one less than its cardinality, it equals that subspace. -/ theorem AffineIndependent.affineSpan_image_finset_eq_of_le_of_card_eq_finrank_add_one [DecidableEq P] {p : ι → P} (hi : AffineIndependent k p) {s : Finset ι} {sp : AffineSubspace k P} [FiniteDimensional k sp.direction] (hle : affineSpan k (s.image p : Set P) ≤ sp) (hc : #s = finrank k sp.direction + 1) : affineSpan k (s.image p : Set P) = sp := by have hn : s.Nonempty := by rw [← Finset.card_pos, hc] apply Nat.succ_pos refine eq_of_direction_eq_of_nonempty_of_le ?_ ((hn.image p).to_set.affineSpan k) hle have hd := direction_le hle rw [direction_affineSpan] at hd ⊢ exact hi.vectorSpan_image_finset_eq_of_le_of_card_eq_finrank_add_one hd hc /-- If the `affineSpan` of a finite affinely independent family lies in an affine subspace whose direction has dimension one less than its cardinality, it equals that subspace. -/ theorem AffineIndependent.affineSpan_eq_of_le_of_card_eq_finrank_add_one [Fintype ι] {p : ι → P} (hi : AffineIndependent k p) {sp : AffineSubspace k P} [FiniteDimensional k sp.direction] (hle : affineSpan k (Set.range p) ≤ sp) (hc : Fintype.card ι = finrank k sp.direction + 1) : affineSpan k (Set.range p) = sp := by classical rw [← Finset.card_univ] at hc rw [← Set.image_univ, ← Finset.coe_univ, ← Finset.coe_image] at hle ⊢ exact hi.affineSpan_image_finset_eq_of_le_of_card_eq_finrank_add_one hle hc /-- The `affineSpan` of a finite affinely independent family is `⊤` iff the family's cardinality is one more than that of the finite-dimensional space. -/ theorem AffineIndependent.affineSpan_eq_top_iff_card_eq_finrank_add_one [FiniteDimensional k V] [Fintype ι] {p : ι → P} (hi : AffineIndependent k p) : affineSpan k (Set.range p) = ⊤ ↔ Fintype.card ι = finrank k V + 1 := by constructor · intro h_tot let n := Fintype.card ι - 1 have hn : Fintype.card ι = n + 1 := (Nat.succ_pred_eq_of_pos (card_pos_of_affineSpan_eq_top k V P h_tot)).symm rw [hn, ← finrank_top, ← (vectorSpan_eq_top_of_affineSpan_eq_top k V P) h_tot, ← hi.finrank_vectorSpan hn] · intro hc rw [← finrank_top, ← direction_top k V P] at hc exact hi.affineSpan_eq_of_le_of_card_eq_finrank_add_one le_top hc theorem Affine.Simplex.span_eq_top [FiniteDimensional k V] {n : ℕ} (T : Affine.Simplex k V n) (hrank : finrank k V = n) : affineSpan k (Set.range T.points) = ⊤ := by rw [AffineIndependent.affineSpan_eq_top_iff_card_eq_finrank_add_one T.independent, Fintype.card_fin, hrank] /-- The `vectorSpan` of adding a point to a finite-dimensional subspace is finite-dimensional. -/ instance finiteDimensional_vectorSpan_insert (s : AffineSubspace k P) [FiniteDimensional k s.direction] (p : P) : FiniteDimensional k (vectorSpan k (insert p (s : Set P))) := by rw [← direction_affineSpan, ← affineSpan_insert_affineSpan] rcases (s : Set P).eq_empty_or_nonempty with (hs \| ⟨p₀, hp₀⟩) · rw [coe_eq_bot_iff] at hs rw [hs, bot_coe, span_empty, bot_coe, direction_affineSpan] convert finiteDimensional_bot k V <;> simp · rw [affineSpan_coe, direction_affineSpan_insert hp₀] infer_instance /-- The direction of the affine span of adding a point to a finite-dimensional subspace is finite-dimensional. -/ instance finiteDimensional_direction_affineSpan_insert (s : AffineSubspace k P) [FiniteDimensional k s.direction] (p : P) : FiniteDimensional k (affineSpan k (insert p (s : Set P))).direction := (direction_affineSpan k (insert p (s : Set P))).symm ▸ finiteDimensional_vectorSpan_insert s p variable (k) /-- The `vectorSpan` of adding a point to a set with a finite-dimensional `vectorSpan` is finite-dimensional. -/ instance finiteDimensional_vectorSpan_insert_set (s : Set P) [FiniteDimensional k (vectorSpan k s)] (p : P) : FiniteDimensional k (vectorSpan k (insert p s)) := by haveI : FiniteDimensional k (affineSpan k s).direction := (direction_affineSpan k s).symm ▸ inferInstance rw [← direction_affineSpan, ← affineSpan_insert_affineSpan, direction_affineSpan] exact finiteDimensional_vectorSpan_insert (affineSpan k s) p /-- A set of points is collinear if their `vectorSpan` has dimension at most `1`. -/ def Collinear (s : Set P) : Prop := Module.rank k (vectorSpan k s) ≤ 1 /-- The definition of `Collinear`. -/ theorem collinear_iff_rank_le_one (s : Set P) : Collinear k s ↔ Module.rank k (vectorSpan k s) ≤ 1 := Iff.rfl variable {k} /-- A set of points, whose `vectorSpan` is finite-dimensional, is collinear if and only if their `vectorSpan` has dimension at most `1`. -/ theorem collinear_iff_finrank_le_one {s : Set P} [FiniteDimensional k (vectorSpan k s)] : Collinear k s ↔ finrank k (vectorSpan k s) ≤ 1 := by have h := collinear_iff_rank_le_one k s rw [← finrank_eq_rank] at h exact mod_cast h alias ⟨Collinear.finrank_le_one, _⟩ := collinear_iff_finrank_le_one /-- A subset of a collinear set is collinear. -/ theorem Collinear.subset {s₁ s₂ : Set P} (hs : s₁ ⊆ s₂) (h : Collinear k s₂) : Collinear k s₁ := (Submodule.rank_mono (vectorSpan_mono k hs)).trans h /-- The `vectorSpan` of collinear points is finite-dimensional. -/ theorem Collinear.finiteDimensional_vectorSpan {s : Set P} (h : Collinear k s) : FiniteDimensional k (vectorSpan k s) := IsNoetherian.iff_fg.1 (IsNoetherian.iff_rank_lt_aleph0.2 (lt_of_le_of_lt h Cardinal.one_lt_aleph0)) /-- The direction of the affine span of collinear points is finite-dimensional. -/ theorem Collinear.finiteDimensional_direction_affineSpan {s : Set P} (h : Collinear k s) : FiniteDimensional k (affineSpan k s).direction := (direction_affineSpan k s).symm ▸ h.finiteDimensional_vectorSpan variable (k P) /-- The empty set is collinear. -/ theorem collinear_empty : Collinear k (∅ : Set P) := by rw [collinear_iff_rank_le_one, vectorSpan_empty] simp variable {P} /-- A single point is collinear. -/ theorem collinear_singleton (p : P) : Collinear k ({p} : Set P) := by rw [collinear_iff_rank_le_one, vectorSpan_singleton] simp variable {k} /-- Given a point `p₀` in a set of points, that set is collinear if and only if the points can all be expressed as multiples of the same vector, added to `p₀`. -/ theorem collinear_iff_of_mem {s : Set P} {p₀ : P} (h : p₀ ∈ s) : Collinear k s ↔ ∃ v : V, ∀ p ∈ s, ∃ r : k, p = r • v +ᵥ p₀ := by simp_rw [collinear_iff_rank_le_one, rank_submodule_le_one_iff', Submodule.le_span_singleton_iff] constructor · rintro ⟨v₀, hv⟩ use v₀ intro p hp obtain ⟨r, hr⟩ := hv (p -ᵥ p₀) (vsub_mem_vectorSpan k hp h) use r rw [eq_vadd_iff_vsub_eq] exact hr.symm · rintro ⟨v, hp₀v⟩ use v intro w hw have hs : vectorSpan k s ≤ k ∙ v := by rw [vectorSpan_eq_span_vsub_set_right k h, Submodule.span_le, Set.subset_def] intro x hx rw [SetLike.mem_coe, Submodule.mem_span_singleton] rw [Set.mem_image] at hx rcases hx with ⟨p, hp, rfl⟩ rcases hp₀v p hp with ⟨r, rfl⟩ use r simp have hw' := SetLike.le_def.1 hs hw rwa [Submodule.mem_span_singleton] at hw' /-- A set of points is collinear if and only if they can all be expressed as multiples of the same vector, added to the same base point. -/ theorem collinear_iff_exists_forall_eq_smul_vadd (s : Set P) : Collinear k s ↔ ∃ (p₀ : P) (v : V), ∀ p ∈ s, ∃ r : k, p = r • v +ᵥ p₀ := by rcases Set.eq_empty_or_nonempty s with (rfl \| ⟨⟨p₁, hp₁⟩⟩) · simp [collinear_empty] · rw [collinear_iff_of_mem hp₁] constructor · exact fun h => ⟨p₁, h⟩ · rintro ⟨p, v, hv⟩ use v intro p₂ hp₂ rcases hv p₂ hp₂ with ⟨r, rfl⟩ rcases hv p₁ hp₁ with ⟨r₁, rfl⟩ use r - r₁ simp [vadd_vadd, ← add_smul] variable (k) in /-- Two points are collinear. -/ theorem collinear_pair (p₁ p₂ : P) : Collinear k ({p₁, p₂} : Set P) := by rw [collinear_iff_exists_forall_eq_smul_vadd] use p₁, p₂ -ᵥ p₁ intro p hp rw [Set.mem_insert_iff, Set.mem_singleton_iff] at hp rcases hp with hp \| hp · use 0 simp [hp] · use 1	simp [hp] /-- Three points are affinely independent if and only if they are not collinear. -/ theorem affineIndependent_iff_not_collinear {p : Fin 3 → P} : AffineIndependent k p ↔ ¬Collinear k (Set.range p) := by rw [collinear_iff_finrank_le_one, affineIndependent_iff_not_finrank_vectorSpan_le k p (Fintype.card_fin 3)] /-- Three points are collinear if and only if they are not affinely independent. -/ theorem collinear_iff_not_affineIndependent {p : Fin 3 → P} : Collinear k (Set.range p) ↔ ¬AffineIndependent k p := by rw [collinear_iff_finrank_le_one,	Mathlib/LinearAlgebra/AffineSpace/FiniteDimensional.lean	474	487
/- Copyright (c) 2020 Alena Gusakov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Alena Gusakov, Arthur Paulino, Kyle Miller, Pim Otte -/ import Mathlib.Combinatorics.SimpleGraph.Clique import Mathlib.Combinatorics.SimpleGraph.Connectivity.Subgraph import Mathlib.Combinatorics.SimpleGraph.Connectivity.WalkCounting import Mathlib.Combinatorics.SimpleGraph.DegreeSum import Mathlib.Combinatorics.SimpleGraph.Operations import Mathlib.Data.Fintype.Order import Mathlib.Data.Set.Card.Arithmetic import Mathlib.Data.Set.Functor /-! # Matchings A matching for a simple graph is a set of disjoint pairs of adjacent vertices, and the set of all the vertices in a matching is called its support (and sometimes the vertices in the support are said to be saturated by the matching). A perfect matching is a matching whose support contains every vertex of the graph. In this module, we represent a matching as a subgraph whose vertices are each incident to at most one edge, and the edges of the subgraph represent the paired vertices. ## Main definitions * `SimpleGraph.Subgraph.IsMatching`: `M.IsMatching` means that `M` is a matching of its underlying graph. * `SimpleGraph.Subgraph.IsPerfectMatching` defines when a subgraph `M` of a simple graph is a perfect matching, denoted `M.IsPerfectMatching`. * `SimpleGraph.IsMatchingFree` means that a graph `G` has no perfect matchings. * `SimpleGraph.IsCycles` means that a graph consists of cycles (including cycles of length 0, also known as isolated vertices) * `SimpleGraph.IsAlternating` means that edges in a graph `G` are alternatingly included and not included in some other graph `G'` ## TODO * Define an `other` function and prove useful results about it (https://leanprover.zulipchat.com/#narrow/stream/252551-graph-theory/topic/matchings/near/266205863) * Provide a bicoloring for matchings (https://leanprover.zulipchat.com/#narrow/stream/252551-graph-theory/topic/matchings/near/265495120) * Tutte's Theorem * Hall's Marriage Theorem (see `Mathlib.Combinatorics.Hall.Basic`) -/ assert_not_exists Field TwoSidedIdeal open Function namespace SimpleGraph variable {V W : Type} {G G' : SimpleGraph V} {M M' : Subgraph G} {u v w : V} namespace Subgraph /-- The subgraph `M` of `G` is a matching if every vertex of `M` is incident to exactly one edge in `M`. We say that the vertices in `M.support` are matched* or saturated. -/ def IsMatching (M : Subgraph G) : Prop := ∀ ⦃v⦄, v ∈ M.verts → ∃! w, M.Adj v w /-- Given a vertex, returns the unique edge of the matching it is incident to. -/ noncomputable def IsMatching.toEdge (h : M.IsMatching) (v : M.verts) : M.edgeSet := ⟨s(v, (h v.property).choose), (h v.property).choose_spec.1⟩ theorem IsMatching.toEdge_eq_of_adj (h : M.IsMatching) (hv : v ∈ M.verts) (hvw : M.Adj v w) : h.toEdge ⟨v, hv⟩ = ⟨s(v, w), hvw⟩ := by simp only [IsMatching.toEdge, Subtype.mk_eq_mk] congr exact ((h (M.edge_vert hvw)).choose_spec.2 w hvw).symm theorem IsMatching.toEdge.surjective (h : M.IsMatching) : Surjective h.toEdge := by rintro ⟨⟨x, y⟩, he⟩ exact ⟨⟨x, M.edge_vert he⟩, h.toEdge_eq_of_adj _ he⟩ theorem IsMatching.toEdge_eq_toEdge_of_adj (h : M.IsMatching) (hv : v ∈ M.verts) (hw : w ∈ M.verts) (ha : M.Adj v w) : h.toEdge ⟨v, hv⟩ = h.toEdge ⟨w, hw⟩ := by rw [h.toEdge_eq_of_adj hv ha, h.toEdge_eq_of_adj hw (M.symm ha), Subtype.mk_eq_mk, Sym2.eq_swap] lemma IsMatching.map_ofLE (h : M.IsMatching) (hGG' : G ≤ G') : (M.map (Hom.ofLE hGG')).IsMatching := by intro _ hv obtain ⟨_, hv, hv'⟩ := Set.mem_image _ _ _ \|>.mp hv obtain ⟨w, hw⟩ := h hv use w simpa using hv' ▸ hw lemma IsMatching.eq_of_adj_left (hM : M.IsMatching) (huv : M.Adj u v) (huw : M.Adj u w) : v = w := (hM <\| M.edge_vert huv).unique huv huw lemma IsMatching.eq_of_adj_right (hM : M.IsMatching) (huw : M.Adj u w) (hvw : M.Adj v w) : u = v := hM.eq_of_adj_left huw.symm hvw.symm	lemma IsMatching.not_adj_left_of_ne (hM : M.IsMatching) (hvw : v ≠ w) (huv : M.Adj u v) : ¬M.Adj u w := fun huw ↦ hvw <\| hM.eq_of_adj_left huv huw lemma IsMatching.not_adj_right_of_ne (hM : M.IsMatching) (huv : u ≠ v) (huw : M.Adj u w) : ¬M.Adj v w := fun hvw ↦ huv <\| hM.eq_of_adj_right huw hvw lemma IsMatching.sup (hM : M.IsMatching) (hM' : M'.IsMatching) (hd : Disjoint M.support M'.support) : (M ⊔ M').IsMatching := by intro v hv have aux {N N' : Subgraph G} (hN : N.IsMatching) (hd : Disjoint N.support N'.support) (hmN: v ∈ N.verts) : ∃! w, (N ⊔ N').Adj v w := by	Mathlib/Combinatorics/SimpleGraph/Matching.lean	101	111
/- Copyright (c) 2019 Jean Lo. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jean Lo, Yaël Dillies, Moritz Doll -/ import Mathlib.Algebra.Order.Pi import Mathlib.Analysis.Convex.Function import Mathlib.Analysis.LocallyConvex.Basic import Mathlib.Data.Real.Pointwise /-! # Seminorms This file defines seminorms. A seminorm is a function to the reals which is positive-semidefinite, absolutely homogeneous, and subadditive. They are closely related to convex sets, and a topological vector space is locally convex if and only if its topology is induced by a family of seminorms. ## Main declarations For a module over a normed ring: * `Seminorm`: A function to the reals that is positive-semidefinite, absolutely homogeneous, and subadditive. * `normSeminorm 𝕜 E`: The norm on `E` as a seminorm. ## References * [H. H. Schaefer, Topological Vector Spaces][schaefer1966] ## Tags seminorm, locally convex, LCTVS -/ assert_not_exists balancedCore open NormedField Set Filter open scoped NNReal Pointwise Topology Uniformity variable {R R' 𝕜 𝕜₂ 𝕜₃ 𝕝 E E₂ E₃ F ι : Type} /-- A seminorm on a module over a normed ring is a function to the reals that is positive semidefinite, positive homogeneous, and subadditive. -/ structure Seminorm (𝕜 : Type) (E : Type) [SeminormedRing 𝕜] [AddGroup E] [SMul 𝕜 E] extends AddGroupSeminorm E where /-- The seminorm of a scalar multiplication is the product of the absolute value of the scalar and the original seminorm. -/ smul' : ∀ (a : 𝕜) (x : E), toFun (a • x) = ‖a‖ toFun x attribute [nolint docBlame] Seminorm.toAddGroupSeminorm /-- `SeminormClass F 𝕜 E` states that `F` is a type of seminorms on the `𝕜`-module `E`. You should extend this class when you extend `Seminorm`. -/ class SeminormClass (F : Type) (𝕜 E : outParam Type) [SeminormedRing 𝕜] [AddGroup E] [SMul 𝕜 E] [FunLike F E ℝ] : Prop extends AddGroupSeminormClass F E ℝ where /-- The seminorm of a scalar multiplication is the product of the absolute value of the scalar and the original seminorm. -/ map_smul_eq_mul (f : F) (a : 𝕜) (x : E) : f (a • x) = ‖a‖ * f x export SeminormClass (map_smul_eq_mul) section Of /-- Alternative constructor for a `Seminorm` on an `AddCommGroup E` that is a module over a `SeminormedRing 𝕜`. -/ def Seminorm.of [SeminormedRing 𝕜] [AddCommGroup E] [Module 𝕜 E] (f : E → ℝ) (add_le : ∀ x y : E, f (x + y) ≤ f x + f y) (smul : ∀ (a : 𝕜) (x : E), f (a • x) = ‖a‖ * f x) : Seminorm 𝕜 E where toFun := f map_zero' := by rw [← zero_smul 𝕜 (0 : E), smul, norm_zero, zero_mul] add_le' := add_le smul' := smul neg' x := by rw [← neg_one_smul 𝕜, smul, norm_neg, ← smul, one_smul] /-- Alternative constructor for a `Seminorm` over a normed field `𝕜` that only assumes `f 0 = 0` and an inequality for the scalar multiplication. -/ def Seminorm.ofSMulLE [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] (f : E → ℝ) (map_zero : f 0 = 0) (add_le : ∀ x y, f (x + y) ≤ f x + f y) (smul_le : ∀ (r : 𝕜) (x), f (r • x) ≤ ‖r‖ * f x) : Seminorm 𝕜 E := Seminorm.of f add_le fun r x => by refine le_antisymm (smul_le r x) ?_ by_cases h : r = 0 · simp [h, map_zero] rw [← mul_le_mul_left (inv_pos.mpr (norm_pos_iff.mpr h))] rw [inv_mul_cancel_left₀ (norm_ne_zero_iff.mpr h)] specialize smul_le r⁻¹ (r • x) rw [norm_inv] at smul_le convert smul_le simp [h] end Of namespace Seminorm section SeminormedRing variable [SeminormedRing 𝕜] section AddGroup variable [AddGroup E] section SMul variable [SMul 𝕜 E] instance instFunLike : FunLike (Seminorm 𝕜 E) E ℝ where coe f := f.toFun coe_injective' f g h := by rcases f with ⟨⟨_⟩⟩ rcases g with ⟨⟨_⟩⟩ congr instance instSeminormClass : SeminormClass (Seminorm 𝕜 E) 𝕜 E where map_zero f := f.map_zero' map_add_le_add f := f.add_le' map_neg_eq_map f := f.neg' map_smul_eq_mul f := f.smul' @[ext] theorem ext {p q : Seminorm 𝕜 E} (h : ∀ x, (p : E → ℝ) x = q x) : p = q := DFunLike.ext p q h instance instZero : Zero (Seminorm 𝕜 E) := ⟨{ AddGroupSeminorm.instZeroAddGroupSeminorm.zero with smul' := fun _ _ => (mul_zero _).symm }⟩ @[simp] theorem coe_zero : ⇑(0 : Seminorm 𝕜 E) = 0 := rfl @[simp] theorem zero_apply (x : E) : (0 : Seminorm 𝕜 E) x = 0 := rfl instance : Inhabited (Seminorm 𝕜 E) := ⟨0⟩ variable (p : Seminorm 𝕜 E) (x : E) (r : ℝ) /-- Any action on `ℝ` which factors through `ℝ≥0` applies to a seminorm. -/ instance instSMul [SMul R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] : SMul R (Seminorm 𝕜 E) where smul r p := { r • p.toAddGroupSeminorm with toFun := fun x => r • p x smul' := fun _ _ => by simp only [← smul_one_smul ℝ≥0 r (_ : ℝ), NNReal.smul_def, smul_eq_mul] rw [map_smul_eq_mul, mul_left_comm] } instance [SMul R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] [SMul R' ℝ] [SMul R' ℝ≥0] [IsScalarTower R' ℝ≥0 ℝ] [SMul R R'] [IsScalarTower R R' ℝ] : IsScalarTower R R' (Seminorm 𝕜 E) where smul_assoc r a p := ext fun x => smul_assoc r a (p x) theorem coe_smul [SMul R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] (r : R) (p : Seminorm 𝕜 E) : ⇑(r • p) = r • ⇑p := rfl @[simp] theorem smul_apply [SMul R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] (r : R) (p : Seminorm 𝕜 E) (x : E) : (r • p) x = r • p x := rfl instance instAdd : Add (Seminorm 𝕜 E) where add p q := { p.toAddGroupSeminorm + q.toAddGroupSeminorm with toFun := fun x => p x + q x smul' := fun a x => by simp only [map_smul_eq_mul, map_smul_eq_mul, mul_add] } theorem coe_add (p q : Seminorm 𝕜 E) : ⇑(p + q) = p + q := rfl @[simp] theorem add_apply (p q : Seminorm 𝕜 E) (x : E) : (p + q) x = p x + q x := rfl instance instAddMonoid : AddMonoid (Seminorm 𝕜 E) := DFunLike.coe_injective.addMonoid _ rfl coe_add fun _ _ => by rfl instance instAddCommMonoid : AddCommMonoid (Seminorm 𝕜 E) := DFunLike.coe_injective.addCommMonoid _ rfl coe_add fun _ _ => by rfl instance instPartialOrder : PartialOrder (Seminorm 𝕜 E) := PartialOrder.lift _ DFunLike.coe_injective instance instIsOrderedCancelAddMonoid : IsOrderedCancelAddMonoid (Seminorm 𝕜 E) := DFunLike.coe_injective.isOrderedCancelAddMonoid _ rfl coe_add fun _ _ => rfl instance instMulAction [Monoid R] [MulAction R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] : MulAction R (Seminorm 𝕜 E) := DFunLike.coe_injective.mulAction _ (by intros; rfl) variable (𝕜 E) /-- `coeFn` as an `AddMonoidHom`. Helper definition for showing that `Seminorm 𝕜 E` is a module. -/ @[simps] def coeFnAddMonoidHom : AddMonoidHom (Seminorm 𝕜 E) (E → ℝ) where toFun := (↑) map_zero' := coe_zero map_add' := coe_add theorem coeFnAddMonoidHom_injective : Function.Injective (coeFnAddMonoidHom 𝕜 E) := show @Function.Injective (Seminorm 𝕜 E) (E → ℝ) (↑) from DFunLike.coe_injective variable {𝕜 E} instance instDistribMulAction [Monoid R] [DistribMulAction R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] : DistribMulAction R (Seminorm 𝕜 E) := (coeFnAddMonoidHom_injective 𝕜 E).distribMulAction _ (by intros; rfl) instance instModule [Semiring R] [Module R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] : Module R (Seminorm 𝕜 E) := (coeFnAddMonoidHom_injective 𝕜 E).module R _ (by intros; rfl) instance instSup : Max (Seminorm 𝕜 E) where max p q := { p.toAddGroupSeminorm ⊔ q.toAddGroupSeminorm with toFun := p ⊔ q smul' := fun x v => (congr_arg₂ max (map_smul_eq_mul p x v) (map_smul_eq_mul q x v)).trans <\| (mul_max_of_nonneg _ _ <\| norm_nonneg x).symm } @[simp] theorem coe_sup (p q : Seminorm 𝕜 E) : ⇑(p ⊔ q) = (p : E → ℝ) ⊔ (q : E → ℝ) := rfl theorem sup_apply (p q : Seminorm 𝕜 E) (x : E) : (p ⊔ q) x = p x ⊔ q x := rfl theorem smul_sup [SMul R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] (r : R) (p q : Seminorm 𝕜 E) : r • (p ⊔ q) = r • p ⊔ r • q := have real.smul_max : ∀ x y : ℝ, r • max x y = max (r • x) (r • y) := fun x y => by simpa only [← smul_eq_mul, ← NNReal.smul_def, smul_one_smul ℝ≥0 r (_ : ℝ)] using mul_max_of_nonneg x y (r • (1 : ℝ≥0) : ℝ≥0).coe_nonneg ext fun _ => real.smul_max _ _ @[simp, norm_cast] theorem coe_le_coe {p q : Seminorm 𝕜 E} : (p : E → ℝ) ≤ q ↔ p ≤ q := Iff.rfl @[simp, norm_cast] theorem coe_lt_coe {p q : Seminorm 𝕜 E} : (p : E → ℝ) < q ↔ p < q := Iff.rfl theorem le_def {p q : Seminorm 𝕜 E} : p ≤ q ↔ ∀ x, p x ≤ q x := Iff.rfl theorem lt_def {p q : Seminorm 𝕜 E} : p < q ↔ p ≤ q ∧ ∃ x, p x < q x := @Pi.lt_def _ _ _ p q instance instSemilatticeSup : SemilatticeSup (Seminorm 𝕜 E) := Function.Injective.semilatticeSup _ DFunLike.coe_injective coe_sup end SMul end AddGroup section Module variable [SeminormedRing 𝕜₂] [SeminormedRing 𝕜₃] variable {σ₁₂ : 𝕜 →+* 𝕜₂} [RingHomIsometric σ₁₂] variable {σ₂₃ : 𝕜₂ →+* 𝕜₃} [RingHomIsometric σ₂₃] variable {σ₁₃ : 𝕜 →+* 𝕜₃} [RingHomIsometric σ₁₃] variable [AddCommGroup E] [AddCommGroup E₂] [AddCommGroup E₃] variable [Module 𝕜 E] [Module 𝕜₂ E₂] [Module 𝕜₃ E₃] variable [SMul R ℝ] [SMul R ℝ≥0] [IsScalarTower R ℝ≥0 ℝ] /-- Composition of a seminorm with a linear map is a seminorm. -/ def comp (p : Seminorm 𝕜₂ E₂) (f : E →ₛₗ[σ₁₂] E₂) : Seminorm 𝕜 E := { p.toAddGroupSeminorm.comp f.toAddMonoidHom with toFun := fun x => p (f x) -- Porting note: the `simp only` below used to be part of the `rw`. -- I'm not sure why this change was needed, and am worried by it! -- Note: https://github.com/leanprover-community/mathlib4/pull/8386 had to change `map_smulₛₗ` to `map_smulₛₗ _` smul' := fun _ _ => by simp only [map_smulₛₗ _]; rw [map_smul_eq_mul, RingHomIsometric.is_iso] } theorem coe_comp (p : Seminorm 𝕜₂ E₂) (f : E →ₛₗ[σ₁₂] E₂) : ⇑(p.comp f) = p ∘ f := rfl @[simp] theorem comp_apply (p : Seminorm 𝕜₂ E₂) (f : E →ₛₗ[σ₁₂] E₂) (x : E) : (p.comp f) x = p (f x) := rfl @[simp] theorem comp_id (p : Seminorm 𝕜 E) : p.comp LinearMap.id = p := ext fun _ => rfl @[simp] theorem comp_zero (p : Seminorm 𝕜₂ E₂) : p.comp (0 : E →ₛₗ[σ₁₂] E₂) = 0 := ext fun _ => map_zero p @[simp] theorem zero_comp (f : E →ₛₗ[σ₁₂] E₂) : (0 : Seminorm 𝕜₂ E₂).comp f = 0 := ext fun _ => rfl theorem comp_comp [RingHomCompTriple σ₁₂ σ₂₃ σ₁₃] (p : Seminorm 𝕜₃ E₃) (g : E₂ →ₛₗ[σ₂₃] E₃) (f : E →ₛₗ[σ₁₂] E₂) : p.comp (g.comp f) = (p.comp g).comp f := ext fun _ => rfl theorem add_comp (p q : Seminorm 𝕜₂ E₂) (f : E →ₛₗ[σ₁₂] E₂) : (p + q).comp f = p.comp f + q.comp f := ext fun _ => rfl theorem comp_add_le (p : Seminorm 𝕜₂ E₂) (f g : E →ₛₗ[σ₁₂] E₂) : p.comp (f + g) ≤ p.comp f + p.comp g := fun _ => map_add_le_add p _ _ theorem smul_comp (p : Seminorm 𝕜₂ E₂) (f : E →ₛₗ[σ₁₂] E₂) (c : R) : (c • p).comp f = c • p.comp f := ext fun _ => rfl theorem comp_mono {p q : Seminorm 𝕜₂ E₂} (f : E →ₛₗ[σ₁₂] E₂) (hp : p ≤ q) : p.comp f ≤ q.comp f := fun _ => hp _ /-- The composition as an `AddMonoidHom`. -/ @[simps] def pullback (f : E →ₛₗ[σ₁₂] E₂) : Seminorm 𝕜₂ E₂ →+ Seminorm 𝕜 E where toFun := fun p => p.comp f map_zero' := zero_comp f map_add' := fun p q => add_comp p q f instance instOrderBot : OrderBot (Seminorm 𝕜 E) where bot := 0 bot_le := apply_nonneg @[simp] theorem coe_bot : ⇑(⊥ : Seminorm 𝕜 E) = 0 := rfl theorem bot_eq_zero : (⊥ : Seminorm 𝕜 E) = 0 := rfl theorem smul_le_smul {p q : Seminorm 𝕜 E} {a b : ℝ≥0} (hpq : p ≤ q) (hab : a ≤ b) : a • p ≤ b • q := by simp_rw [le_def] intro x exact mul_le_mul hab (hpq x) (apply_nonneg p x) (NNReal.coe_nonneg b) theorem finset_sup_apply (p : ι → Seminorm 𝕜 E) (s : Finset ι) (x : E) : s.sup p x = ↑(s.sup fun i => ⟨p i x, apply_nonneg (p i) x⟩ : ℝ≥0) := by induction' s using Finset.cons_induction_on with a s ha ih · rw [Finset.sup_empty, Finset.sup_empty, coe_bot, _root_.bot_eq_zero, Pi.zero_apply] norm_cast · rw [Finset.sup_cons, Finset.sup_cons, coe_sup, Pi.sup_apply, NNReal.coe_max, NNReal.coe_mk, ih] theorem exists_apply_eq_finset_sup (p : ι → Seminorm 𝕜 E) {s : Finset ι} (hs : s.Nonempty) (x : E) : ∃ i ∈ s, s.sup p x = p i x := by rcases Finset.exists_mem_eq_sup s hs (fun i ↦ (⟨p i x, apply_nonneg _ _⟩ : ℝ≥0)) with ⟨i, hi, hix⟩ rw [finset_sup_apply] exact ⟨i, hi, congr_arg _ hix⟩ theorem zero_or_exists_apply_eq_finset_sup (p : ι → Seminorm 𝕜 E) (s : Finset ι) (x : E) : s.sup p x = 0 ∨ ∃ i ∈ s, s.sup p x = p i x := by rcases Finset.eq_empty_or_nonempty s with (rfl\|hs) · left; rfl · right; exact exists_apply_eq_finset_sup p hs x theorem finset_sup_smul (p : ι → Seminorm 𝕜 E) (s : Finset ι) (C : ℝ≥0) : s.sup (C • p) = C • s.sup p := by ext x rw [smul_apply, finset_sup_apply, finset_sup_apply] symm exact congr_arg ((↑) : ℝ≥0 → ℝ) (NNReal.mul_finset_sup C s (fun i ↦ ⟨p i x, apply_nonneg _ _⟩)) theorem finset_sup_le_sum (p : ι → Seminorm 𝕜 E) (s : Finset ι) : s.sup p ≤ ∑ i ∈ s, p i := by classical refine Finset.sup_le_iff.mpr ?_ intro i hi rw [Finset.sum_eq_sum_diff_singleton_add hi, le_add_iff_nonneg_left] exact bot_le theorem finset_sup_apply_le {p : ι → Seminorm 𝕜 E} {s : Finset ι} {x : E} {a : ℝ} (ha : 0 ≤ a) (h : ∀ i, i ∈ s → p i x ≤ a) : s.sup p x ≤ a := by lift a to ℝ≥0 using ha rw [finset_sup_apply, NNReal.coe_le_coe] exact Finset.sup_le h theorem le_finset_sup_apply {p : ι → Seminorm 𝕜 E} {s : Finset ι} {x : E} {i : ι} (hi : i ∈ s) : p i x ≤ s.sup p x := (Finset.le_sup hi : p i ≤ s.sup p) x theorem finset_sup_apply_lt {p : ι → Seminorm 𝕜 E} {s : Finset ι} {x : E} {a : ℝ} (ha : 0 < a) (h : ∀ i, i ∈ s → p i x < a) : s.sup p x < a := by lift a to ℝ≥0 using ha.le rw [finset_sup_apply, NNReal.coe_lt_coe, Finset.sup_lt_iff] · exact h · exact NNReal.coe_pos.mpr ha theorem norm_sub_map_le_sub (p : Seminorm 𝕜 E) (x y : E) : ‖p x - p y‖ ≤ p (x - y) := abs_sub_map_le_sub p x y end Module end SeminormedRing section SeminormedCommRing variable [SeminormedRing 𝕜] [SeminormedCommRing 𝕜₂] variable {σ₁₂ : 𝕜 →+* 𝕜₂} [RingHomIsometric σ₁₂] variable [AddCommGroup E] [AddCommGroup E₂] [Module 𝕜 E] [Module 𝕜₂ E₂] theorem comp_smul (p : Seminorm 𝕜₂ E₂) (f : E →ₛₗ[σ₁₂] E₂) (c : 𝕜₂) : p.comp (c • f) = ‖c‖₊ • p.comp f := ext fun _ => by rw [comp_apply, smul_apply, LinearMap.smul_apply, map_smul_eq_mul, NNReal.smul_def, coe_nnnorm, smul_eq_mul, comp_apply] theorem comp_smul_apply (p : Seminorm 𝕜₂ E₂) (f : E →ₛₗ[σ₁₂] E₂) (c : 𝕜₂) (x : E) : p.comp (c • f) x = ‖c‖ * p (f x) := map_smul_eq_mul p _ _ end SeminormedCommRing section NormedField	variable [NormedField 𝕜] [AddCommGroup E] [Module 𝕜 E] {p q : Seminorm 𝕜 E} {x : E} /-- Auxiliary lemma to show that the infimum of seminorms is well-defined. -/ theorem bddBelow_range_add : BddBelow (range fun u => p u + q (x - u)) := ⟨0, by	Mathlib/Analysis/Seminorm.lean	418	422
/- Copyright (c) 2024 Jz Pan. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jz Pan -/ import Mathlib.FieldTheory.PurelyInseparable.Basic import Mathlib.FieldTheory.PerfectClosure /-! # `IsPerfectClosure` predicate This file contains `IsPerfectClosure` which asserts that `L` is a perfect closure of `K` under a ring homomorphism `i : K →+* L`, as well as its basic properties. ## Main definitions - `pNilradical`: given a natural number `p`, the `p`-nilradical of a ring is defined to be the nilradical if `p > 1` (`pNilradical_eq_nilradical`), and defined to be the zero ideal if `p ≤ 1` (`pNilradical_eq_bot'`). Equivalently, it is the ideal consisting of elements `x` such that `x ^ p ^ n = 0` for some `n` (`mem_pNilradical`). - `IsPRadical`: a ring homomorphism `i : K →+* L` of characteristic `p` rings is called `p`-radical, if or any element `x` of `L` there is `n : ℕ` such that `x ^ (p ^ n)` is contained in `K`, and the kernel of `i` is contained in the `p`-nilradical of `K`. A generalization of purely inseparable extension for fields. - `IsPerfectClosure`: if `i : K →+* L` is `p`-radical ring homomorphism, then it makes `L` a perfect closure of `K`, if `L` is perfect. Our definition makes it synonymous to `IsPRadical` if `PerfectRing L p` is present. A caveat is that you need to write `[PerfectRing L p] [IsPerfectClosure i p]`. This is similar to `PerfectRing` which has `ExpChar` as a prerequisite. - `PerfectRing.lift`: if a `p`-radical ring homomorphism `K →+* L` is given, `M` is a perfect ring, then any ring homomorphism `K →+* M` can be lifted to `L →+* M`. This is similar to `IsAlgClosed.lift` and `IsSepClosed.lift`. - `PerfectRing.liftEquiv`: `K →+* M` is one-to-one correspondence to `L →+* M`, given by `PerfectRing.lift`. This is a generalization to `PerfectClosure.lift`. - `IsPerfectClosure.equiv`: perfect closures of a ring are isomorphic. ## Main results - `IsPRadical.trans`: composition of `p`-radical ring homomorphisms is also `p`-radical. - `PerfectClosure.isPRadical`: the absolute perfect closure `PerfectClosure` is a `p`-radical extension over the base ring, in particular, it is a perfect closure of the base ring. - `IsPRadical.isPurelyInseparable`, `IsPurelyInseparable.isPRadical`: `p`-radical and purely inseparable are equivalent for fields. - The (relative) perfect closure `perfectClosure` is a perfect closure (inferred from `IsPurelyInseparable.isPRadical` automatically by Lean). ## Tags perfect ring, perfect closure, purely inseparable -/ open Module Polynomial IntermediateField Field noncomputable section /-- Given a natural number `p`, the `p`-nilradical of a ring is defined to be the nilradical if `p > 1` (`pNilradical_eq_nilradical`), and defined to be the zero ideal if `p ≤ 1` (`pNilradical_eq_bot'`). Equivalently, it is the ideal consisting of elements `x` such that `x ^ p ^ n = 0` for some `n` (`mem_pNilradical`). -/ def pNilradical (R : Type) [CommSemiring R] (p : ℕ) : Ideal R := if 1 < p then nilradical R else ⊥ theorem pNilradical_le_nilradical {R : Type} [CommSemiring R] {p : ℕ} : pNilradical R p ≤ nilradical R := by by_cases hp : 1 < p · rw [pNilradical, if_pos hp] simp_rw [pNilradical, if_neg hp, bot_le] theorem pNilradical_eq_nilradical {R : Type} [CommSemiring R] {p : ℕ} (hp : 1 < p) : pNilradical R p = nilradical R := by rw [pNilradical, if_pos hp] theorem pNilradical_eq_bot {R : Type} [CommSemiring R] {p : ℕ} (hp : ¬ 1 < p) : pNilradical R p = ⊥ := by rw [pNilradical, if_neg hp] theorem pNilradical_eq_bot' {R : Type} [CommSemiring R] {p : ℕ} (hp : p ≤ 1) : pNilradical R p = ⊥ := pNilradical_eq_bot (not_lt.2 hp) theorem pNilradical_prime {R : Type} [CommSemiring R] {p : ℕ} (hp : p.Prime) : pNilradical R p = nilradical R := pNilradical_eq_nilradical hp.one_lt theorem pNilradical_one {R : Type} [CommSemiring R] : pNilradical R 1 = ⊥ := pNilradical_eq_bot' rfl.le theorem mem_pNilradical {R : Type} [CommSemiring R] {p : ℕ} {x : R} : x ∈ pNilradical R p ↔ ∃ n : ℕ, x ^ p ^ n = 0 := by by_cases hp : 1 < p · rw [pNilradical_eq_nilradical hp] refine ⟨fun ⟨n, h⟩ ↦ ⟨n, ?_⟩, fun ⟨n, h⟩ ↦ ⟨p ^ n, h⟩⟩ rw [← Nat.sub_add_cancel ((n.lt_pow_self hp).le), pow_add, h, mul_zero] rw [pNilradical_eq_bot hp, Ideal.mem_bot] refine ⟨fun h ↦ ⟨0, by rw [pow_zero, pow_one, h]⟩, fun ⟨n, h⟩ ↦ ?_⟩ rcases Nat.le_one_iff_eq_zero_or_eq_one.1 (not_lt.1 hp) with hp \| hp · by_cases hn : n = 0 · rwa [hn, pow_zero, pow_one] at h rw [hp, zero_pow hn, pow_zero] at h subsingleton [subsingleton_of_zero_eq_one h.symm] rwa [hp, one_pow, pow_one] at h theorem sub_mem_pNilradical_iff_pow_expChar_pow_eq {R : Type} [CommRing R] {p : ℕ} [ExpChar R p] {x y : R} : x - y ∈ pNilradical R p ↔ ∃ n : ℕ, x ^ p ^ n = y ^ p ^ n := by simp_rw [mem_pNilradical, sub_pow_expChar_pow, sub_eq_zero] theorem pow_expChar_pow_inj_of_pNilradical_eq_bot (R : Type) [CommRing R] (p : ℕ) [ExpChar R p] (h : pNilradical R p = ⊥) (n : ℕ) : Function.Injective fun x : R ↦ x ^ p ^ n := fun _ _ H ↦ sub_eq_zero.1 <\| Ideal.mem_bot.1 <\| h ▸ sub_mem_pNilradical_iff_pow_expChar_pow_eq.2 ⟨n, H⟩ theorem pNilradical_eq_bot_of_frobenius_inj (R : Type) [CommSemiring R] (p : ℕ) [ExpChar R p] (h : Function.Injective (frobenius R p)) : pNilradical R p = ⊥ := bot_unique fun x ↦ by rw [mem_pNilradical, Ideal.mem_bot] exact fun ⟨n, _⟩ ↦ h.iterate n (by rwa [← coe_iterateFrobenius, map_zero]) theorem PerfectRing.pNilradical_eq_bot (R : Type) [CommSemiring R] (p : ℕ) [ExpChar R p] [PerfectRing R p] : pNilradical R p = ⊥ := pNilradical_eq_bot_of_frobenius_inj R p (injective_frobenius R p) section IsPerfectClosure variable {K L M N : Type} section CommSemiring variable [CommSemiring K] [CommSemiring L] [CommSemiring M] (i : K →+ L) (j : K →+* M) (f : L →+* M) (p : ℕ) /-- If `i : K →+* L` is a ring homomorphism of characteristic `p` rings, then it is called `p`-radical if the following conditions are satisfied: - For any element `x` of `L` there is `n : ℕ` such that `x ^ (p ^ n)` is contained in `K`. - The kernel of `i` is contained in the `p`-nilradical of `K`. It is a generalization of purely inseparable extension for fields. -/ @[mk_iff] class IsPRadical : Prop where pow_mem' : ∀ x : L, ∃ (n : ℕ) (y : K), i y = x ^ p ^ n ker_le' : RingHom.ker i ≤ pNilradical K p theorem IsPRadical.pow_mem [IsPRadical i p] (x : L) : ∃ (n : ℕ) (y : K), i y = x ^ p ^ n := pow_mem' x theorem IsPRadical.ker_le [IsPRadical i p] : RingHom.ker i ≤ pNilradical K p := ker_le' theorem IsPRadical.comap_pNilradical [IsPRadical i p] : (pNilradical L p).comap i = pNilradical K p := by refine le_antisymm (fun x h ↦ mem_pNilradical.2 ?_) (fun x h ↦ ?_) · obtain ⟨n, h⟩ := mem_pNilradical.1 <\| Ideal.mem_comap.1 h obtain ⟨m, h⟩ := mem_pNilradical.1 <\| ker_le i p ((map_pow i x _).symm ▸ h) exact ⟨n + m, by rwa [pow_add, pow_mul]⟩ simp only [Ideal.mem_comap, mem_pNilradical] at h ⊢ obtain ⟨n, h⟩ := h exact ⟨n, by simpa only [map_pow, map_zero] using congr(i $h)⟩ variable (K) in instance IsPRadical.of_id : IsPRadical (RingHom.id K) p where pow_mem' x := ⟨0, x, by simp⟩ ker_le' x h := by convert Ideal.zero_mem _ /-- Composition of `p`-radical ring homomorphisms is also `p`-radical. -/ theorem IsPRadical.trans [IsPRadical i p] [IsPRadical f p] : IsPRadical (f.comp i) p where pow_mem' x := by obtain ⟨n, y, hy⟩ := pow_mem f p x obtain ⟨m, z, hz⟩ := pow_mem i p y exact ⟨n + m, z, by rw [RingHom.comp_apply, hz, map_pow, hy, pow_add, pow_mul]⟩ ker_le' x h := by rw [RingHom.mem_ker, RingHom.comp_apply, ← RingHom.mem_ker] at h simpa only [← Ideal.mem_comap, comap_pNilradical] using ker_le f p h /-- If `i : K →+* L` is a `p`-radical ring homomorphism, then it makes `L` a perfect closure of `K`, if `L` is perfect. In this case the kernel of `i` is equal to the `p`-nilradical of `K` (see `IsPerfectClosure.ker_eq`). Our definition makes it synonymous to `IsPRadical` if `PerfectRing L p` is present. A caveat is that you need to write `[PerfectRing L p] [IsPerfectClosure i p]`. This is similar to `PerfectRing` which has `ExpChar` as a prerequisite. -/ @[nolint unusedArguments] abbrev IsPerfectClosure [ExpChar L p] [PerfectRing L p] := IsPRadical i p /-- If `i : K →+* L` is a ring homomorphism of exponential characteristic `p` rings, such that `L` is perfect, then the `p`-nilradical of `K` is contained in the kernel of `i`. -/ theorem RingHom.pNilradical_le_ker_of_perfectRing [ExpChar L p] [PerfectRing L p] : pNilradical K p ≤ RingHom.ker i := fun x h ↦ by obtain ⟨n, h⟩ := mem_pNilradical.1 h replace h := congr((iterateFrobeniusEquiv L p n).symm (i $h)) rwa [map_pow, ← iterateFrobenius_def, ← iterateFrobeniusEquiv_apply, RingEquiv.symm_apply_apply, map_zero, map_zero] at h variable [ExpChar L p] in theorem IsPerfectClosure.ker_eq [PerfectRing L p] [IsPerfectClosure i p] : RingHom.ker i = pNilradical K p := IsPRadical.ker_le'.antisymm (i.pNilradical_le_ker_of_perfectRing p) namespace PerfectRing /- NOTE: To define `PerfectRing.lift_aux`, only the `IsPRadical.pow_mem` is required, but not `IsPRadical.ker_le`. But in order to use typeclass, here we require the whole `IsPRadical`. -/ variable [ExpChar M p] [PerfectRing M p] [IsPRadical i p] theorem lift_aux (x : L) : ∃ y : ℕ × K, i y.2 = x ^ p ^ y.1 := by obtain ⟨n, y, h⟩ := IsPRadical.pow_mem i p x exact ⟨(n, y), h⟩	/-- If `i : K →+* L` and `j : K →+* M` are ring homomorphisms of characteristic `p` rings, such that `i` is `p`-radical (in fact only the `IsPRadical.pow_mem` is required) and `M` is a perfect ring,	Mathlib/FieldTheory/IsPerfectClosure.lean	214	216
/- 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 -/ import Mathlib.Algebra.Order.Ring.WithTop import Mathlib.Algebra.Order.Sub.WithTop import Mathlib.Data.NNReal.Defs import Mathlib.Order.Interval.Set.WithBotTop /-! # Extended non-negative reals We define `ENNReal = ℝ≥0∞ := WithTop ℝ≥0` to be the type of extended nonnegative real numbers, i.e., the interval `[0, +∞]`. This type is used as the codomain of a `MeasureTheory.Measure`, and of the extended distance `edist` in an `EMetricSpace`. In this file we set up many of the instances on `ℝ≥0∞`, and provide relationships between `ℝ≥0∞` and `ℝ≥0`, and between `ℝ≥0∞` and `ℝ`. In particular, we provide a coercion from `ℝ≥0` to `ℝ≥0∞` as well as functions `ENNReal.toNNReal`, `ENNReal.ofReal` and `ENNReal.toReal`, all of which take the value zero wherever they cannot be the identity. Also included is the relationship between `ℝ≥0∞` and `ℕ`. The interaction of these functions, especially `ENNReal.ofReal` and `ENNReal.toReal`, with the algebraic and lattice structure can be found in `Data.ENNReal.Real`. This file proves many of the order properties of `ℝ≥0∞`, with the exception of the ways those relate to the algebraic structure, which are included in `Data.ENNReal.Operations`. This file also defines inversion and division: this includes `Inv` and `Div` instances on `ℝ≥0∞` making it into a `DivInvOneMonoid`. As a consequence of being a `DivInvOneMonoid`, `ℝ≥0∞` inherits a power operation with integer exponent: this and other properties is shown in `Data.ENNReal.Inv`. ## Main definitions * `ℝ≥0∞`: the extended nonnegative real numbers `[0, ∞]`; defined as `WithTop ℝ≥0`; it is equipped with the following structures: - coercion from `ℝ≥0` defined in the natural way; - the natural structure of a complete dense linear order: `↑p ≤ ↑q ↔ p ≤ q` and `∀ a, a ≤ ∞`; - `a + b` is defined so that `↑p + ↑q = ↑(p + q)` for `(p q : ℝ≥0)` and `a + ∞ = ∞ + a = ∞`; - `a * b` is defined so that `↑p * ↑q = ↑(p * q)` for `(p q : ℝ≥0)`, `0 * ∞ = ∞ * 0 = 0`, and `a * ∞ = ∞ * a = ∞` for `a ≠ 0`; - `a - b` is defined as the minimal `d` such that `a ≤ d + b`; this way we have `↑p - ↑q = ↑(p - q)`, `∞ - ↑p = ∞`, `↑p - ∞ = ∞ - ∞ = 0`; note that there is no negation, only subtraction; The addition and multiplication defined this way together with `0 = ↑0` and `1 = ↑1` turn `ℝ≥0∞` into a canonically ordered commutative semiring of characteristic zero. - `a⁻¹` is defined as `Inf {b \| 1 ≤ a * b}`. This way we have `(↑p)⁻¹ = ↑(p⁻¹)` for `p : ℝ≥0`, `p ≠ 0`, `0⁻¹ = ∞`, and `∞⁻¹ = 0`. - `a / b` is defined as `a * b⁻¹`. This inversion and division include `Inv` and `Div` instances on `ℝ≥0∞`, making it into a `DivInvOneMonoid`. Further properties of these are shown in `Data.ENNReal.Inv`. * Coercions to/from other types: - coercion `ℝ≥0 → ℝ≥0∞` is defined as `Coe`, so one can use `(p : ℝ≥0)` in a context that expects `a : ℝ≥0∞`, and Lean will apply `coe` automatically; - `ENNReal.toNNReal` sends `↑p` to `p` and `∞` to `0`; - `ENNReal.toReal := coe ∘ ENNReal.toNNReal` sends `↑p`, `p : ℝ≥0` to `(↑p : ℝ)` and `∞` to `0`; - `ENNReal.ofReal := coe ∘ Real.toNNReal` sends `x : ℝ` to `↑⟨max x 0, _⟩` - `ENNReal.neTopEquivNNReal` is an equivalence between `{a : ℝ≥0∞ // a ≠ 0}` and `ℝ≥0`. ## Implementation notes We define a `CanLift ℝ≥0∞ ℝ≥0` instance, so one of the ways to prove theorems about an `ℝ≥0∞` number `a` is to consider the cases `a = ∞` and `a ≠ ∞`, and use the tactic `lift a to ℝ≥0 using ha` in the second case. This instance is even more useful if one already has `ha : a ≠ ∞` in the context, or if we have `(f : α → ℝ≥0∞) (hf : ∀ x, f x ≠ ∞)`. ## Notations * `ℝ≥0∞`: the type of the extended nonnegative real numbers; * `ℝ≥0`: the type of nonnegative real numbers `[0, ∞)`; defined in `Data.Real.NNReal`; * `∞`: a localized notation in `ENNReal` for `⊤ : ℝ≥0∞`. -/ assert_not_exists Finset open Function Set NNReal variable {α : Type} /-- The extended nonnegative real numbers. This is usually denoted [0, ∞], and is relevant as the codomain of a measure. -/ def ENNReal := WithTop ℝ≥0 deriving Zero, Top, AddCommMonoidWithOne, SemilatticeSup, DistribLattice, Nontrivial @[inherit_doc] scoped[ENNReal] notation "ℝ≥0∞" => ENNReal /-- Notation for infinity as an `ENNReal` number. -/ scoped[ENNReal] notation "∞" => (⊤ : ENNReal) namespace ENNReal instance : OrderBot ℝ≥0∞ := inferInstanceAs (OrderBot (WithTop ℝ≥0)) instance : OrderTop ℝ≥0∞ := inferInstanceAs (OrderTop (WithTop ℝ≥0)) instance : BoundedOrder ℝ≥0∞ := inferInstanceAs (BoundedOrder (WithTop ℝ≥0)) instance : CharZero ℝ≥0∞ := inferInstanceAs (CharZero (WithTop ℝ≥0)) instance : Min ℝ≥0∞ := SemilatticeInf.toMin instance : Max ℝ≥0∞ := SemilatticeSup.toMax noncomputable instance : CommSemiring ℝ≥0∞ := inferInstanceAs (CommSemiring (WithTop ℝ≥0)) instance : PartialOrder ℝ≥0∞ := inferInstanceAs (PartialOrder (WithTop ℝ≥0)) instance : IsOrderedRing ℝ≥0∞ := inferInstanceAs (IsOrderedRing (WithTop ℝ≥0)) instance : CanonicallyOrderedAdd ℝ≥0∞ := inferInstanceAs (CanonicallyOrderedAdd (WithTop ℝ≥0)) instance : NoZeroDivisors ℝ≥0∞ := inferInstanceAs (NoZeroDivisors (WithTop ℝ≥0)) noncomputable instance : CompleteLinearOrder ℝ≥0∞ := inferInstanceAs (CompleteLinearOrder (WithTop ℝ≥0)) instance : DenselyOrdered ℝ≥0∞ := inferInstanceAs (DenselyOrdered (WithTop ℝ≥0)) instance : AddCommMonoid ℝ≥0∞ := inferInstanceAs (AddCommMonoid (WithTop ℝ≥0)) noncomputable instance : LinearOrder ℝ≥0∞ := inferInstanceAs (LinearOrder (WithTop ℝ≥0)) instance : IsOrderedAddMonoid ℝ≥0∞ := inferInstanceAs (IsOrderedAddMonoid (WithTop ℝ≥0)) instance instSub : Sub ℝ≥0∞ := inferInstanceAs (Sub (WithTop ℝ≥0)) instance : OrderedSub ℝ≥0∞ := inferInstanceAs (OrderedSub (WithTop ℝ≥0)) noncomputable instance : LinearOrderedAddCommMonoidWithTop ℝ≥0∞ := inferInstanceAs (LinearOrderedAddCommMonoidWithTop (WithTop ℝ≥0)) -- RFC: redefine using pattern matching? noncomputable instance : Inv ℝ≥0∞ := ⟨fun a => sInf { b \| 1 ≤ a b }⟩ noncomputable instance : DivInvMonoid ℝ≥0∞ where variable {a b c d : ℝ≥0∞} {r p q : ℝ≥0} -- TODO: add a `WithTop` instance and use it here noncomputable instance : LinearOrderedCommMonoidWithZero ℝ≥0∞ := { inferInstanceAs (LinearOrderedAddCommMonoidWithTop ℝ≥0∞), inferInstanceAs (CommSemiring ℝ≥0∞) with bot_le _ := bot_le mul_le_mul_left := fun _ _ => mul_le_mul_left' zero_le_one := zero_le 1 } instance : Unique (AddUnits ℝ≥0∞) where default := 0 uniq a := AddUnits.ext <\| le_zero_iff.1 <\| by rw [← a.add_neg]; exact le_self_add instance : Inhabited ℝ≥0∞ := ⟨0⟩ /-- Coercion from `ℝ≥0` to `ℝ≥0∞`. -/ @[coe, match_pattern] def ofNNReal : ℝ≥0 → ℝ≥0∞ := WithTop.some instance : Coe ℝ≥0 ℝ≥0∞ := ⟨ofNNReal⟩ /-- A version of `WithTop.recTopCoe` that uses `ENNReal.ofNNReal`. -/ @[elab_as_elim, induction_eliminator, cases_eliminator] def recTopCoe {C : ℝ≥0∞ → Sort} (top : C ∞) (coe : ∀ x : ℝ≥0, C x) (x : ℝ≥0∞) : C x := WithTop.recTopCoe top coe x instance canLift : CanLift ℝ≥0∞ ℝ≥0 ofNNReal (· ≠ ∞) := WithTop.canLift @[simp] theorem none_eq_top : (none : ℝ≥0∞) = ∞ := rfl @[simp] theorem some_eq_coe (a : ℝ≥0) : (Option.some a : ℝ≥0∞) = (↑a : ℝ≥0∞) := rfl @[simp] theorem some_eq_coe' (a : ℝ≥0) : (WithTop.some a : ℝ≥0∞) = (↑a : ℝ≥0∞) := rfl lemma coe_injective : Injective ((↑) : ℝ≥0 → ℝ≥0∞) := WithTop.coe_injective @[simp, norm_cast] lemma coe_inj : (p : ℝ≥0∞) = q ↔ p = q := coe_injective.eq_iff lemma coe_ne_coe : (p : ℝ≥0∞) ≠ q ↔ p ≠ q := coe_inj.not theorem range_coe' : range ofNNReal = Iio ∞ := WithTop.range_coe theorem range_coe : range ofNNReal = {∞}ᶜ := (isCompl_range_some_none ℝ≥0).symm.compl_eq.symm instance : NNRatCast ℝ≥0∞ where nnratCast r := ofNNReal r @[norm_cast] theorem coe_nnratCast (q : ℚ≥0) : ↑(q : ℝ≥0) = (q : ℝ≥0∞) := rfl /-- `toNNReal x` returns `x` if it is real, otherwise 0. -/ protected def toNNReal : ℝ≥0∞ → ℝ≥0 := WithTop.untopD 0 /-- `toReal x` returns `x` if it is real, `0` otherwise. -/ protected def toReal (a : ℝ≥0∞) : Real := a.toNNReal /-- `ofReal x` returns `x` if it is nonnegative, `0` otherwise. -/ protected def ofReal (r : Real) : ℝ≥0∞ := r.toNNReal @[simp, norm_cast] lemma toNNReal_coe (r : ℝ≥0) : (r : ℝ≥0∞).toNNReal = r := rfl @[simp] theorem coe_toNNReal : ∀ {a : ℝ≥0∞}, a ≠ ∞ → ↑a.toNNReal = a \| ofNNReal _, _ => rfl \| ⊤, h => (h rfl).elim @[simp] theorem coe_comp_toNNReal_comp {ι : Type} {f : ι → ℝ≥0∞} (hf : ∀ x, f x ≠ ∞) : (fun (x : ℝ≥0) => (x : ℝ≥0∞)) ∘ ENNReal.toNNReal ∘ f = f := by ext x simp [coe_toNNReal (hf x)] @[simp] theorem ofReal_toReal {a : ℝ≥0∞} (h : a ≠ ∞) : ENNReal.ofReal a.toReal = a := by simp [ENNReal.toReal, ENNReal.ofReal, h] @[simp] theorem toReal_ofReal {r : ℝ} (h : 0 ≤ r) : (ENNReal.ofReal r).toReal = r := max_eq_left h theorem toReal_ofReal' {r : ℝ} : (ENNReal.ofReal r).toReal = max r 0 := rfl theorem coe_toNNReal_le_self : ∀ {a : ℝ≥0∞}, ↑a.toNNReal ≤ a \| ofNNReal r => by rw [toNNReal_coe] \| ⊤ => le_top theorem coe_nnreal_eq (r : ℝ≥0) : (r : ℝ≥0∞) = ENNReal.ofReal r := by rw [ENNReal.ofReal, Real.toNNReal_coe] theorem ofReal_eq_coe_nnreal {x : ℝ} (h : 0 ≤ x) : ENNReal.ofReal x = ofNNReal ⟨x, h⟩ := (coe_nnreal_eq ⟨x, h⟩).symm theorem ofNNReal_toNNReal (x : ℝ) : (Real.toNNReal x : ℝ≥0∞) = ENNReal.ofReal x := rfl @[simp] theorem ofReal_coe_nnreal : ENNReal.ofReal p = p := (coe_nnreal_eq p).symm @[simp, norm_cast] theorem coe_zero : ↑(0 : ℝ≥0) = (0 : ℝ≥0∞) := rfl @[simp, norm_cast] theorem coe_one : ↑(1 : ℝ≥0) = (1 : ℝ≥0∞) := rfl @[simp] theorem toReal_nonneg {a : ℝ≥0∞} : 0 ≤ a.toReal := a.toNNReal.2 @[norm_cast] theorem coe_toNNReal_eq_toReal (z : ℝ≥0∞) : (z.toNNReal : ℝ) = z.toReal := rfl @[simp] theorem toNNReal_toReal_eq (z : ℝ≥0∞) : z.toReal.toNNReal = z.toNNReal := by ext; simp [coe_toNNReal_eq_toReal] @[simp] theorem toNNReal_top : ∞.toNNReal = 0 := rfl @[deprecated (since := "2025-03-20")] alias top_toNNReal := toNNReal_top @[simp] theorem toReal_top : ∞.toReal = 0 := rfl @[deprecated (since := "2025-03-20")] alias top_toReal := toReal_top @[simp] theorem toReal_one : (1 : ℝ≥0∞).toReal = 1 := rfl		Mathlib/Data/ENNReal/Basic.lean	271	271
/- 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.Logic.Basic import Mathlib.Tactic.Convert import Mathlib.Tactic.SplitIfs import Mathlib.Tactic.Tauto /-! # More basic logic properties A few more logic lemmas. These are in their own file, rather than `Logic.Basic`, because it is convenient to be able to use the `tauto` or `split_ifs` tactics. ## Implementation notes We spell those lemmas out with `dite` and `ite` rather than the `if then else` notation because this would result in less delta-reduced statements. -/ theorem iff_assoc {a b c : Prop} : ((a ↔ b) ↔ c) ↔ (a ↔ (b ↔ c)) := by tauto	theorem iff_left_comm {a b c : Prop} : (a ↔ (b ↔ c)) ↔ (b ↔ (a ↔ c)) := by tauto	Mathlib/Logic/Lemmas.lean	22	22
/- Copyright (c) 2019 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Sébastien Gouëzel, Yury Kudryashov -/ import Mathlib.Analysis.Analytic.Constructions import Mathlib.Analysis.Calculus.FDeriv.Analytic import Mathlib.Analysis.Calculus.FDeriv.Bilinear /-! # Multiplicative operations on derivatives For detailed documentation of the Fréchet derivative, see the module docstring of `Mathlib/Analysis/Calculus/FDeriv/Basic.lean`. This file contains the usual formulas (and existence assertions) for the derivative of * multiplication of a function by a scalar function * product of finitely many scalar functions * taking the pointwise multiplicative inverse (i.e. `Inv.inv` or `Ring.inverse`) of a function -/ open Asymptotics ContinuousLinearMap Topology section variable {𝕜 : Type} [NontriviallyNormedField 𝕜] variable {E : Type} [NormedAddCommGroup E] [NormedSpace 𝕜 E] variable {F : Type} [NormedAddCommGroup F] [NormedSpace 𝕜 F] variable {G : Type} [NormedAddCommGroup G] [NormedSpace 𝕜 G] variable {f : E → F} variable {f' : E →L[𝕜] F} variable {x : E} variable {s : Set E} section CLMCompApply /-! ### Derivative of the pointwise composition/application of continuous linear maps -/ variable {H : Type} [NormedAddCommGroup H] [NormedSpace 𝕜 H] {c : E → G →L[𝕜] H} {c' : E →L[𝕜] G →L[𝕜] H} {d : E → F →L[𝕜] G} {d' : E →L[𝕜] F →L[𝕜] G} {u : E → G} {u' : E →L[𝕜] G} #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 split proof term into steps to solve unification issues. -/ @[fun_prop] theorem HasStrictFDerivAt.clm_comp (hc : HasStrictFDerivAt c c' x) (hd : HasStrictFDerivAt d d' x) : HasStrictFDerivAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') x := by have := isBoundedBilinearMap_comp.hasStrictFDerivAt (c x, d x) have := this.comp x (hc.prodMk hd) exact this #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.clm_comp (hc : HasFDerivWithinAt c c' s x) (hd : HasFDerivWithinAt d d' s x) : HasFDerivWithinAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') s x := by exact (isBoundedBilinearMap_comp.hasFDerivAt (c x, d x) :).comp_hasFDerivWithinAt x (hc.prodMk hd) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.clm_comp (hc : HasFDerivAt c c' x) (hd : HasFDerivAt d d' x) : HasFDerivAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') x := by exact (isBoundedBilinearMap_comp.hasFDerivAt (c x, d x) :).comp x <\| hc.prodMk hd @[fun_prop] theorem DifferentiableWithinAt.clm_comp (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : DifferentiableWithinAt 𝕜 (fun y => (c y).comp (d y)) s x := (hc.hasFDerivWithinAt.clm_comp hd.hasFDerivWithinAt).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.clm_comp (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : DifferentiableAt 𝕜 (fun y => (c y).comp (d y)) x := (hc.hasFDerivAt.clm_comp hd.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.clm_comp (hc : DifferentiableOn 𝕜 c s) (hd : DifferentiableOn 𝕜 d s) : DifferentiableOn 𝕜 (fun y => (c y).comp (d y)) s := fun x hx => (hc x hx).clm_comp (hd x hx) @[fun_prop] theorem Differentiable.clm_comp (hc : Differentiable 𝕜 c) (hd : Differentiable 𝕜 d) : Differentiable 𝕜 fun y => (c y).comp (d y) := fun x => (hc x).clm_comp (hd x) theorem fderivWithin_clm_comp (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : fderivWithin 𝕜 (fun y => (c y).comp (d y)) s x = (compL 𝕜 F G H (c x)).comp (fderivWithin 𝕜 d s x) + ((compL 𝕜 F G H).flip (d x)).comp (fderivWithin 𝕜 c s x) := (hc.hasFDerivWithinAt.clm_comp hd.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_clm_comp (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : fderiv 𝕜 (fun y => (c y).comp (d y)) x = (compL 𝕜 F G H (c x)).comp (fderiv 𝕜 d x) + ((compL 𝕜 F G H).flip (d x)).comp (fderiv 𝕜 c x) := (hc.hasFDerivAt.clm_comp hd.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.clm_apply (hc : HasStrictFDerivAt c c' x) (hu : HasStrictFDerivAt u u' x) : HasStrictFDerivAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) x := (isBoundedBilinearMap_apply.hasStrictFDerivAt (c x, u x)).comp x (hc.prodMk hu) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.clm_apply (hc : HasFDerivWithinAt c c' s x) (hu : HasFDerivWithinAt u u' s x) : HasFDerivWithinAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) s x := by exact (isBoundedBilinearMap_apply.hasFDerivAt (c x, u x) :).comp_hasFDerivWithinAt x (hc.prodMk hu) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.clm_apply (hc : HasFDerivAt c c' x) (hu : HasFDerivAt u u' x) : HasFDerivAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) x := by exact (isBoundedBilinearMap_apply.hasFDerivAt (c x, u x) :).comp x (hc.prodMk hu) @[fun_prop] theorem DifferentiableWithinAt.clm_apply (hc : DifferentiableWithinAt 𝕜 c s x) (hu : DifferentiableWithinAt 𝕜 u s x) : DifferentiableWithinAt 𝕜 (fun y => (c y) (u y)) s x := (hc.hasFDerivWithinAt.clm_apply hu.hasFDerivWithinAt).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.clm_apply (hc : DifferentiableAt 𝕜 c x) (hu : DifferentiableAt 𝕜 u x) : DifferentiableAt 𝕜 (fun y => (c y) (u y)) x := (hc.hasFDerivAt.clm_apply hu.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.clm_apply (hc : DifferentiableOn 𝕜 c s) (hu : DifferentiableOn 𝕜 u s) : DifferentiableOn 𝕜 (fun y => (c y) (u y)) s := fun x hx => (hc x hx).clm_apply (hu x hx) @[fun_prop] theorem Differentiable.clm_apply (hc : Differentiable 𝕜 c) (hu : Differentiable 𝕜 u) : Differentiable 𝕜 fun y => (c y) (u y) := fun x => (hc x).clm_apply (hu x) theorem fderivWithin_clm_apply (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hu : DifferentiableWithinAt 𝕜 u s x) : fderivWithin 𝕜 (fun y => (c y) (u y)) s x = (c x).comp (fderivWithin 𝕜 u s x) + (fderivWithin 𝕜 c s x).flip (u x) := (hc.hasFDerivWithinAt.clm_apply hu.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_clm_apply (hc : DifferentiableAt 𝕜 c x) (hu : DifferentiableAt 𝕜 u x) : fderiv 𝕜 (fun y => (c y) (u y)) x = (c x).comp (fderiv 𝕜 u x) + (fderiv 𝕜 c x).flip (u x) := (hc.hasFDerivAt.clm_apply hu.hasFDerivAt).fderiv end CLMCompApply section ContinuousMultilinearApplyConst /-! ### Derivative of the application of continuous multilinear maps to a constant -/ variable {ι : Type} [Fintype ι] {M : ι → Type} [∀ i, NormedAddCommGroup (M i)] [∀ i, NormedSpace 𝕜 (M i)] {H : Type} [NormedAddCommGroup H] [NormedSpace 𝕜 H] {c : E → ContinuousMultilinearMap 𝕜 M H} {c' : E →L[𝕜] ContinuousMultilinearMap 𝕜 M H} @[fun_prop] theorem HasStrictFDerivAt.continuousMultilinear_apply_const (hc : HasStrictFDerivAt c c' x) (u : ∀ i, M i) : HasStrictFDerivAt (fun y ↦ (c y) u) (c'.flipMultilinear u) x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasStrictFDerivAt.comp x hc @[fun_prop] theorem HasFDerivWithinAt.continuousMultilinear_apply_const (hc : HasFDerivWithinAt c c' s x) (u : ∀ i, M i) : HasFDerivWithinAt (fun y ↦ (c y) u) (c'.flipMultilinear u) s x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasFDerivAt.comp_hasFDerivWithinAt x hc @[fun_prop] theorem HasFDerivAt.continuousMultilinear_apply_const (hc : HasFDerivAt c c' x) (u : ∀ i, M i) : HasFDerivAt (fun y ↦ (c y) u) (c'.flipMultilinear u) x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasFDerivAt.comp x hc @[fun_prop] theorem DifferentiableWithinAt.continuousMultilinear_apply_const (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) : DifferentiableWithinAt 𝕜 (fun y ↦ (c y) u) s x := (hc.hasFDerivWithinAt.continuousMultilinear_apply_const u).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.continuousMultilinear_apply_const (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) : DifferentiableAt 𝕜 (fun y ↦ (c y) u) x := (hc.hasFDerivAt.continuousMultilinear_apply_const u).differentiableAt @[fun_prop] theorem DifferentiableOn.continuousMultilinear_apply_const (hc : DifferentiableOn 𝕜 c s) (u : ∀ i, M i) : DifferentiableOn 𝕜 (fun y ↦ (c y) u) s := fun x hx ↦ (hc x hx).continuousMultilinear_apply_const u @[fun_prop] theorem Differentiable.continuousMultilinear_apply_const (hc : Differentiable 𝕜 c) (u : ∀ i, M i) : Differentiable 𝕜 fun y ↦ (c y) u := fun x ↦ (hc x).continuousMultilinear_apply_const u theorem fderivWithin_continuousMultilinear_apply_const (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) : fderivWithin 𝕜 (fun y ↦ (c y) u) s x = ((fderivWithin 𝕜 c s x).flipMultilinear u) := (hc.hasFDerivWithinAt.continuousMultilinear_apply_const u).fderivWithin hxs theorem fderiv_continuousMultilinear_apply_const (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) : (fderiv 𝕜 (fun y ↦ (c y) u) x) = (fderiv 𝕜 c x).flipMultilinear u := (hc.hasFDerivAt.continuousMultilinear_apply_const u).fderiv /-- Application of a `ContinuousMultilinearMap` to a constant commutes with `fderivWithin`. -/ theorem fderivWithin_continuousMultilinear_apply_const_apply (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) (m : E) : (fderivWithin 𝕜 (fun y ↦ (c y) u) s x) m = (fderivWithin 𝕜 c s x) m u := by simp [fderivWithin_continuousMultilinear_apply_const hxs hc] /-- Application of a `ContinuousMultilinearMap` to a constant commutes with `fderiv`. -/ theorem fderiv_continuousMultilinear_apply_const_apply (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) (m : E) : (fderiv 𝕜 (fun y ↦ (c y) u) x) m = (fderiv 𝕜 c x) m u := by simp [fderiv_continuousMultilinear_apply_const hc] end ContinuousMultilinearApplyConst section SMul /-! ### Derivative of the product of a scalar-valued function and a vector-valued function If `c` is a differentiable scalar-valued function and `f` is a differentiable vector-valued function, then `fun x ↦ c x • f x` is differentiable as well. Lemmas in this section works for function `c` taking values in the base field, as well as in a normed algebra over the base field: e.g., they work for `c : E → ℂ` and `f : E → F` provided that `F` is a complex normed vector space. -/ variable {𝕜' : Type} [NontriviallyNormedField 𝕜'] [NormedAlgebra 𝕜 𝕜'] [NormedSpace 𝕜' F] [IsScalarTower 𝕜 𝕜' F] variable {c : E → 𝕜'} {c' : E →L[𝕜] 𝕜'} @[fun_prop] theorem HasStrictFDerivAt.smul (hc : HasStrictFDerivAt c c' x) (hf : HasStrictFDerivAt f f' x) : HasStrictFDerivAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) x := (isBoundedBilinearMap_smul.hasStrictFDerivAt (c x, f x)).comp x <\| hc.prodMk hf #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.smul (hc : HasFDerivWithinAt c c' s x) (hf : HasFDerivWithinAt f f' s x) : HasFDerivWithinAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) s x := by exact (isBoundedBilinearMap_smul.hasFDerivAt (𝕜 := 𝕜) (c x, f x) :).comp_hasFDerivWithinAt x <\| hc.prodMk hf #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.smul (hc : HasFDerivAt c c' x) (hf : HasFDerivAt f f' x) : HasFDerivAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) x := by exact (isBoundedBilinearMap_smul.hasFDerivAt (𝕜 := 𝕜) (c x, f x) :).comp x <\| hc.prodMk hf @[fun_prop] theorem DifferentiableWithinAt.smul (hc : DifferentiableWithinAt 𝕜 c s x) (hf : DifferentiableWithinAt 𝕜 f s x) : DifferentiableWithinAt 𝕜 (fun y => c y • f y) s x := (hc.hasFDerivWithinAt.smul hf.hasFDerivWithinAt).differentiableWithinAt @[simp, fun_prop] theorem DifferentiableAt.smul (hc : DifferentiableAt 𝕜 c x) (hf : DifferentiableAt 𝕜 f x) : DifferentiableAt 𝕜 (fun y => c y • f y) x := (hc.hasFDerivAt.smul hf.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.smul (hc : DifferentiableOn 𝕜 c s) (hf : DifferentiableOn 𝕜 f s) : DifferentiableOn 𝕜 (fun y => c y • f y) s := fun x hx => (hc x hx).smul (hf x hx) @[simp, fun_prop] theorem Differentiable.smul (hc : Differentiable 𝕜 c) (hf : Differentiable 𝕜 f) : Differentiable 𝕜 fun y => c y • f y := fun x => (hc x).smul (hf x) theorem fderivWithin_smul (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hf : DifferentiableWithinAt 𝕜 f s x) : fderivWithin 𝕜 (fun y => c y • f y) s x = c x • fderivWithin 𝕜 f s x + (fderivWithin 𝕜 c s x).smulRight (f x) := (hc.hasFDerivWithinAt.smul hf.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_smul (hc : DifferentiableAt 𝕜 c x) (hf : DifferentiableAt 𝕜 f x) : fderiv 𝕜 (fun y => c y • f y) x = c x • fderiv 𝕜 f x + (fderiv 𝕜 c x).smulRight (f x) := (hc.hasFDerivAt.smul hf.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.smul_const (hc : HasStrictFDerivAt c c' x) (f : F) : HasStrictFDerivAt (fun y => c y • f) (c'.smulRight f) x := by simpa only [smul_zero, zero_add] using hc.smul (hasStrictFDerivAt_const f x) @[fun_prop] theorem HasFDerivWithinAt.smul_const (hc : HasFDerivWithinAt c c' s x) (f : F) : HasFDerivWithinAt (fun y => c y • f) (c'.smulRight f) s x := by simpa only [smul_zero, zero_add] using hc.smul (hasFDerivWithinAt_const f x s) @[fun_prop] theorem HasFDerivAt.smul_const (hc : HasFDerivAt c c' x) (f : F) : HasFDerivAt (fun y => c y • f) (c'.smulRight f) x := by simpa only [smul_zero, zero_add] using hc.smul (hasFDerivAt_const f x) @[fun_prop] theorem DifferentiableWithinAt.smul_const (hc : DifferentiableWithinAt 𝕜 c s x) (f : F) : DifferentiableWithinAt 𝕜 (fun y => c y • f) s x := (hc.hasFDerivWithinAt.smul_const f).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.smul_const (hc : DifferentiableAt 𝕜 c x) (f : F) : DifferentiableAt 𝕜 (fun y => c y • f) x := (hc.hasFDerivAt.smul_const f).differentiableAt @[fun_prop] theorem DifferentiableOn.smul_const (hc : DifferentiableOn 𝕜 c s) (f : F) : DifferentiableOn 𝕜 (fun y => c y • f) s := fun x hx => (hc x hx).smul_const f @[fun_prop] theorem Differentiable.smul_const (hc : Differentiable 𝕜 c) (f : F) : Differentiable 𝕜 fun y => c y • f := fun x => (hc x).smul_const f theorem fderivWithin_smul_const (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (f : F) : fderivWithin 𝕜 (fun y => c y • f) s x = (fderivWithin 𝕜 c s x).smulRight f := (hc.hasFDerivWithinAt.smul_const f).fderivWithin hxs theorem fderiv_smul_const (hc : DifferentiableAt 𝕜 c x) (f : F) : fderiv 𝕜 (fun y => c y • f) x = (fderiv 𝕜 c x).smulRight f := (hc.hasFDerivAt.smul_const f).fderiv end SMul section Mul /-! ### Derivative of the product of two functions -/ variable {𝔸 𝔸' : Type} [NormedRing 𝔸] [NormedCommRing 𝔸'] [NormedAlgebra 𝕜 𝔸] [NormedAlgebra 𝕜 𝔸'] {a b : E → 𝔸} {a' b' : E →L[𝕜] 𝔸} {c d : E → 𝔸'} {c' d' : E →L[𝕜] 𝔸'} @[fun_prop] theorem HasStrictFDerivAt.mul' {x : E} (ha : HasStrictFDerivAt a a' x) (hb : HasStrictFDerivAt b b' x) : HasStrictFDerivAt (fun y => a y * b y) (a x • b' + a'.smulRight (b x)) x := ((ContinuousLinearMap.mul 𝕜 𝔸).isBoundedBilinearMap.hasStrictFDerivAt (a x, b x)).comp x (ha.prodMk hb) @[fun_prop] theorem HasStrictFDerivAt.mul (hc : HasStrictFDerivAt c c' x) (hd : HasStrictFDerivAt d d' x) : HasStrictFDerivAt (fun y => c y * d y) (c x • d' + d x • c') x := by convert hc.mul' hd ext z apply mul_comm #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.mul' (ha : HasFDerivWithinAt a a' s x) (hb : HasFDerivWithinAt b b' s x) : HasFDerivWithinAt (fun y => a y * b y) (a x • b' + a'.smulRight (b x)) s x := by exact ((ContinuousLinearMap.mul 𝕜 𝔸).isBoundedBilinearMap.hasFDerivAt (a x, b x)).comp_hasFDerivWithinAt x (ha.prodMk hb) @[fun_prop] theorem HasFDerivWithinAt.mul (hc : HasFDerivWithinAt c c' s x) (hd : HasFDerivWithinAt d d' s x) : HasFDerivWithinAt (fun y => c y * d y) (c x • d' + d x • c') s x := by convert hc.mul' hd ext z apply mul_comm #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.mul' (ha : HasFDerivAt a a' x) (hb : HasFDerivAt b b' x) : HasFDerivAt (fun y => a y * b y) (a x • b' + a'.smulRight (b x)) x := by exact ((ContinuousLinearMap.mul 𝕜 𝔸).isBoundedBilinearMap.hasFDerivAt (a x, b x)).comp x (ha.prodMk hb) @[fun_prop] theorem HasFDerivAt.mul (hc : HasFDerivAt c c' x) (hd : HasFDerivAt d d' x) : HasFDerivAt (fun y => c y * d y) (c x • d' + d x • c') x := by convert hc.mul' hd ext z apply mul_comm @[fun_prop] theorem DifferentiableWithinAt.mul (ha : DifferentiableWithinAt 𝕜 a s x) (hb : DifferentiableWithinAt 𝕜 b s x) : DifferentiableWithinAt 𝕜 (fun y => a y * b y) s x := (ha.hasFDerivWithinAt.mul' hb.hasFDerivWithinAt).differentiableWithinAt @[simp, fun_prop] theorem DifferentiableAt.mul (ha : DifferentiableAt 𝕜 a x) (hb : DifferentiableAt 𝕜 b x) : DifferentiableAt 𝕜 (fun y => a y * b y) x := (ha.hasFDerivAt.mul' hb.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.mul (ha : DifferentiableOn 𝕜 a s) (hb : DifferentiableOn 𝕜 b s) : DifferentiableOn 𝕜 (fun y => a y * b y) s := fun x hx => (ha x hx).mul (hb x hx) @[simp, fun_prop] theorem Differentiable.mul (ha : Differentiable 𝕜 a) (hb : Differentiable 𝕜 b) : Differentiable 𝕜 fun y => a y * b y := fun x => (ha x).mul (hb x) @[fun_prop] theorem DifferentiableWithinAt.pow (ha : DifferentiableWithinAt 𝕜 a s x) : ∀ n : ℕ, DifferentiableWithinAt 𝕜 (fun x => a x ^ n) s x \| 0 => by simp only [pow_zero, differentiableWithinAt_const] \| n + 1 => by simp only [pow_succ', DifferentiableWithinAt.pow ha n, ha.mul] @[simp, fun_prop] theorem DifferentiableAt.pow (ha : DifferentiableAt 𝕜 a x) (n : ℕ) : DifferentiableAt 𝕜 (fun x => a x ^ n) x := differentiableWithinAt_univ.mp <\| ha.differentiableWithinAt.pow n @[fun_prop] theorem DifferentiableOn.pow (ha : DifferentiableOn 𝕜 a s) (n : ℕ) : DifferentiableOn 𝕜 (fun x => a x ^ n) s := fun x h => (ha x h).pow n @[simp, fun_prop] theorem Differentiable.pow (ha : Differentiable 𝕜 a) (n : ℕ) : Differentiable 𝕜 fun x => a x ^ n := fun x => (ha x).pow n theorem fderivWithin_mul' (hxs : UniqueDiffWithinAt 𝕜 s x) (ha : DifferentiableWithinAt 𝕜 a s x) (hb : DifferentiableWithinAt 𝕜 b s x) : fderivWithin 𝕜 (fun y => a y * b y) s x = a x • fderivWithin 𝕜 b s x + (fderivWithin 𝕜 a s x).smulRight (b x) := (ha.hasFDerivWithinAt.mul' hb.hasFDerivWithinAt).fderivWithin hxs theorem fderivWithin_mul (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : fderivWithin 𝕜 (fun y => c y * d y) s x = c x • fderivWithin 𝕜 d s x + d x • fderivWithin 𝕜 c s x := (hc.hasFDerivWithinAt.mul hd.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_mul' (ha : DifferentiableAt 𝕜 a x) (hb : DifferentiableAt 𝕜 b x) : fderiv 𝕜 (fun y => a y * b y) x = a x • fderiv 𝕜 b x + (fderiv 𝕜 a x).smulRight (b x) := (ha.hasFDerivAt.mul' hb.hasFDerivAt).fderiv theorem fderiv_mul (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : fderiv 𝕜 (fun y => c y * d y) x = c x • fderiv 𝕜 d x + d x • fderiv 𝕜 c x := (hc.hasFDerivAt.mul hd.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.mul_const' (ha : HasStrictFDerivAt a a' x) (b : 𝔸) : HasStrictFDerivAt (fun y => a y * b) (a'.smulRight b) x := ((ContinuousLinearMap.mul 𝕜 𝔸).flip b).hasStrictFDerivAt.comp x ha @[fun_prop] theorem HasStrictFDerivAt.mul_const (hc : HasStrictFDerivAt c c' x) (d : 𝔸') : HasStrictFDerivAt (fun y => c y * d) (d • c') x := by convert hc.mul_const' d ext z apply mul_comm @[fun_prop] theorem HasFDerivWithinAt.mul_const' (ha : HasFDerivWithinAt a a' s x) (b : 𝔸) : HasFDerivWithinAt (fun y => a y * b) (a'.smulRight b) s x := ((ContinuousLinearMap.mul 𝕜 𝔸).flip b).hasFDerivAt.comp_hasFDerivWithinAt x ha @[fun_prop] theorem HasFDerivWithinAt.mul_const (hc : HasFDerivWithinAt c c' s x) (d : 𝔸') : HasFDerivWithinAt (fun y => c y * d) (d • c') s x := by convert hc.mul_const' d ext z apply mul_comm @[fun_prop] theorem HasFDerivAt.mul_const' (ha : HasFDerivAt a a' x) (b : 𝔸) : HasFDerivAt (fun y => a y * b) (a'.smulRight b) x := ((ContinuousLinearMap.mul 𝕜 𝔸).flip b).hasFDerivAt.comp x ha @[fun_prop] theorem HasFDerivAt.mul_const (hc : HasFDerivAt c c' x) (d : 𝔸') : HasFDerivAt (fun y => c y * d) (d • c') x := by convert hc.mul_const' d ext z apply mul_comm @[fun_prop] theorem DifferentiableWithinAt.mul_const (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : DifferentiableWithinAt 𝕜 (fun y => a y * b) s x := (ha.hasFDerivWithinAt.mul_const' b).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.mul_const (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : DifferentiableAt 𝕜 (fun y => a y * b) x := (ha.hasFDerivAt.mul_const' b).differentiableAt @[fun_prop] theorem DifferentiableOn.mul_const (ha : DifferentiableOn 𝕜 a s) (b : 𝔸) : DifferentiableOn 𝕜 (fun y => a y * b) s := fun x hx => (ha x hx).mul_const b @[fun_prop] theorem Differentiable.mul_const (ha : Differentiable 𝕜 a) (b : 𝔸) : Differentiable 𝕜 fun y => a y * b := fun x => (ha x).mul_const b theorem fderivWithin_mul_const' (hxs : UniqueDiffWithinAt 𝕜 s x) (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : fderivWithin 𝕜 (fun y => a y * b) s x = (fderivWithin 𝕜 a s x).smulRight b := (ha.hasFDerivWithinAt.mul_const' b).fderivWithin hxs theorem fderivWithin_mul_const (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (d : 𝔸') : fderivWithin 𝕜 (fun y => c y * d) s x = d • fderivWithin 𝕜 c s x := (hc.hasFDerivWithinAt.mul_const d).fderivWithin hxs theorem fderiv_mul_const' (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : fderiv 𝕜 (fun y => a y * b) x = (fderiv 𝕜 a x).smulRight b := (ha.hasFDerivAt.mul_const' b).fderiv theorem fderiv_mul_const (hc : DifferentiableAt 𝕜 c x) (d : 𝔸') : fderiv 𝕜 (fun y => c y * d) x = d • fderiv 𝕜 c x := (hc.hasFDerivAt.mul_const d).fderiv @[fun_prop] theorem HasStrictFDerivAt.const_mul (ha : HasStrictFDerivAt a a' x) (b : 𝔸) : HasStrictFDerivAt (fun y => b * a y) (b • a') x := ((ContinuousLinearMap.mul 𝕜 𝔸) b).hasStrictFDerivAt.comp x ha @[fun_prop] theorem HasFDerivWithinAt.const_mul (ha : HasFDerivWithinAt a a' s x) (b : 𝔸) : HasFDerivWithinAt (fun y => b * a y) (b • a') s x := ((ContinuousLinearMap.mul 𝕜 𝔸) b).hasFDerivAt.comp_hasFDerivWithinAt x ha @[fun_prop] theorem HasFDerivAt.const_mul (ha : HasFDerivAt a a' x) (b : 𝔸) : HasFDerivAt (fun y => b * a y) (b • a') x := ((ContinuousLinearMap.mul 𝕜 𝔸) b).hasFDerivAt.comp x ha @[fun_prop] theorem DifferentiableWithinAt.const_mul (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : DifferentiableWithinAt 𝕜 (fun y => b * a y) s x := (ha.hasFDerivWithinAt.const_mul b).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.const_mul (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : DifferentiableAt 𝕜 (fun y => b * a y) x := (ha.hasFDerivAt.const_mul b).differentiableAt @[fun_prop] theorem DifferentiableOn.const_mul (ha : DifferentiableOn 𝕜 a s) (b : 𝔸) : DifferentiableOn 𝕜 (fun y => b * a y) s := fun x hx => (ha x hx).const_mul b @[fun_prop] theorem Differentiable.const_mul (ha : Differentiable 𝕜 a) (b : 𝔸) : Differentiable 𝕜 fun y => b * a y := fun x => (ha x).const_mul b theorem fderivWithin_const_mul (hxs : UniqueDiffWithinAt 𝕜 s x) (ha : DifferentiableWithinAt 𝕜 a s x) (b : 𝔸) : fderivWithin 𝕜 (fun y => b * a y) s x = b • fderivWithin 𝕜 a s x := (ha.hasFDerivWithinAt.const_mul b).fderivWithin hxs theorem fderiv_const_mul (ha : DifferentiableAt 𝕜 a x) (b : 𝔸) : fderiv 𝕜 (fun y => b * a y) x = b • fderiv 𝕜 a x := (ha.hasFDerivAt.const_mul b).fderiv end Mul section Prod /-! ### Derivative of a finite product of functions -/ variable {ι : Type} {𝔸 𝔸' : Type} [NormedRing 𝔸] [NormedCommRing 𝔸'] [NormedAlgebra 𝕜 𝔸] [NormedAlgebra 𝕜 𝔸'] {u : Finset ι} {f : ι → E → 𝔸} {f' : ι → E →L[𝕜] 𝔸} {g : ι → E → 𝔸'} {g' : ι → E →L[𝕜] 𝔸'} @[fun_prop] theorem hasStrictFDerivAt_list_prod' [Fintype ι] {l : List ι} {x : ι → 𝔸} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.map x).prod) (∑ i : Fin l.length, ((l.take i).map x).prod • smulRight (proj l[i]) ((l.drop (.succ i)).map x).prod) x := by induction l with \| nil => simp [hasStrictFDerivAt_const] \| cons a l IH => simp only [List.map_cons, List.prod_cons, ← proj_apply (R := 𝕜) (φ := fun _ : ι ↦ 𝔸) a] exact .congr_fderiv (.mul' (ContinuousLinearMap.hasStrictFDerivAt _) IH) (by ext; simp [Fin.sum_univ_succ, Finset.mul_sum, mul_assoc, add_comm]) @[fun_prop] theorem hasStrictFDerivAt_list_prod_finRange' {n : ℕ} {x : Fin n → 𝔸} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ ((List.finRange n).map x).prod) (∑ i : Fin n, (((List.finRange n).take i).map x).prod • smulRight (proj i) (((List.finRange n).drop (.succ i)).map x).prod) x := hasStrictFDerivAt_list_prod'.congr_fderiv <\| Finset.sum_equiv (finCongr List.length_finRange) (by simp) (by simp [Fin.forall_iff]) @[fun_prop] theorem hasStrictFDerivAt_list_prod_attach' {l : List ι} {x : {i // i ∈ l} → 𝔸} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.attach.map x).prod) (∑ i : Fin l.length, ((l.attach.take i).map x).prod • smulRight (proj l.attach[i.cast List.length_attach.symm]) ((l.attach.drop (.succ i)).map x).prod) x := by classical exact hasStrictFDerivAt_list_prod'.congr_fderiv <\| Eq.symm <\| Finset.sum_equiv (finCongr List.length_attach.symm) (by simp) (by simp) @[fun_prop] theorem hasFDerivAt_list_prod' [Fintype ι] {l : List ι} {x : ι → 𝔸'} : HasFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.map x).prod) (∑ i : Fin l.length, ((l.take i).map x).prod • smulRight (proj l[i]) ((l.drop (.succ i)).map x).prod) x := hasStrictFDerivAt_list_prod'.hasFDerivAt @[fun_prop] theorem hasFDerivAt_list_prod_finRange' {n : ℕ} {x : Fin n → 𝔸} : HasFDerivAt (𝕜 := 𝕜) (fun x ↦ ((List.finRange n).map x).prod) (∑ i : Fin n, (((List.finRange n).take i).map x).prod • smulRight (proj i) (((List.finRange n).drop (.succ i)).map x).prod) x := (hasStrictFDerivAt_list_prod_finRange').hasFDerivAt @[fun_prop] theorem hasFDerivAt_list_prod_attach' {l : List ι} {x : {i // i ∈ l} → 𝔸} : HasFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.attach.map x).prod) (∑ i : Fin l.length, ((l.attach.take i).map x).prod • smulRight (proj l.attach[i.cast List.length_attach.symm]) ((l.attach.drop (.succ i)).map x).prod) x := by classical exact hasStrictFDerivAt_list_prod_attach'.hasFDerivAt /-- Auxiliary lemma for `hasStrictFDerivAt_multiset_prod`. For `NormedCommRing 𝔸'`, can rewrite as `Multiset` using `Multiset.prod_coe`. -/ @[fun_prop] theorem hasStrictFDerivAt_list_prod [DecidableEq ι] [Fintype ι] {l : List ι} {x : ι → 𝔸'} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (l.map x).prod) (l.map fun i ↦ ((l.erase i).map x).prod • proj i).sum x := by refine hasStrictFDerivAt_list_prod'.congr_fderiv ?_ conv_rhs => arg 1; arg 2; rw [← List.finRange_map_get l] simp only [List.map_map, ← List.sum_toFinset _ (List.nodup_finRange _), List.toFinset_finRange, Function.comp_def, ((List.erase_getElem _).map _).prod_eq, List.eraseIdx_eq_take_drop_succ, List.map_append, List.prod_append, List.get_eq_getElem, Fin.getElem_fin, Nat.succ_eq_add_one] exact Finset.sum_congr rfl fun i _ ↦ by ext; simp only [smul_apply, smulRight_apply, smul_eq_mul]; ring @[fun_prop] theorem hasStrictFDerivAt_multiset_prod [DecidableEq ι] [Fintype ι] {u : Multiset ι} {x : ι → 𝔸'} : HasStrictFDerivAt (𝕜 := 𝕜) (fun x ↦ (u.map x).prod) (u.map (fun i ↦ ((u.erase i).map x).prod • proj i)).sum x := u.inductionOn fun l ↦ by simpa using hasStrictFDerivAt_list_prod @[fun_prop] theorem hasFDerivAt_multiset_prod [DecidableEq ι] [Fintype ι] {u : Multiset ι} {x : ι → 𝔸'} : HasFDerivAt (𝕜 := 𝕜) (fun x ↦ (u.map x).prod) (Multiset.sum (u.map (fun i ↦ ((u.erase i).map x).prod • proj i))) x := hasStrictFDerivAt_multiset_prod.hasFDerivAt theorem hasStrictFDerivAt_finset_prod [DecidableEq ι] [Fintype ι] {x : ι → 𝔸'} : HasStrictFDerivAt (𝕜 := 𝕜) (∏ i ∈ u, · i) (∑ i ∈ u, (∏ j ∈ u.erase i, x j) • proj i) x := by simp only [Finset.sum_eq_multiset_sum, Finset.prod_eq_multiset_prod] exact hasStrictFDerivAt_multiset_prod theorem hasFDerivAt_finset_prod [DecidableEq ι] [Fintype ι] {x : ι → 𝔸'} : HasFDerivAt (𝕜 := 𝕜) (∏ i ∈ u, · i) (∑ i ∈ u, (∏ j ∈ u.erase i, x j) • proj i) x := hasStrictFDerivAt_finset_prod.hasFDerivAt section Comp @[fun_prop] theorem HasStrictFDerivAt.list_prod' {l : List ι} {x : E} (h : ∀ i ∈ l, HasStrictFDerivAt (f i ·) (f' i) x) : HasStrictFDerivAt (fun x ↦ (l.map (f · x)).prod) (∑ i : Fin l.length, ((l.take i).map (f · x)).prod • smulRight (f' l[i]) ((l.drop (.succ i)).map (f · x)).prod) x := by simp_rw [Fin.getElem_fin, ← l.get_eq_getElem, ← List.finRange_map_get l, List.map_map] -- After #19108, we have to be optimistic with `:)`s; otherwise Lean decides it need to find -- `NormedAddCommGroup (List 𝔸)` which is nonsense. refine .congr_fderiv (hasStrictFDerivAt_list_prod_finRange'.comp x (hasStrictFDerivAt_pi.mpr fun i ↦ h (l.get i) (List.getElem_mem ..)) :) ?_ ext m simp_rw [List.map_take, List.map_drop, List.map_map, comp_apply, sum_apply, smul_apply, smulRight_apply, proj_apply, pi_apply, Function.comp_def] /-- Unlike `HasFDerivAt.finset_prod`, supports non-commutative multiply and duplicate elements. -/ @[fun_prop] theorem HasFDerivAt.list_prod' {l : List ι} {x : E} (h : ∀ i ∈ l, HasFDerivAt (f i ·) (f' i) x) : HasFDerivAt (fun x ↦ (l.map (f · x)).prod) (∑ i : Fin l.length, ((l.take i).map (f · x)).prod • smulRight (f' l[i]) ((l.drop (.succ i)).map (f · x)).prod) x := by simp_rw [Fin.getElem_fin, ← l.get_eq_getElem, ← List.finRange_map_get l, List.map_map] refine .congr_fderiv (hasFDerivAt_list_prod_finRange'.comp x (hasFDerivAt_pi.mpr fun i ↦ h (l.get i) (l.get_mem i)) :) ?_ ext m simp_rw [List.map_take, List.map_drop, List.map_map, comp_apply, sum_apply, smul_apply, smulRight_apply, proj_apply, pi_apply, Function.comp_def] @[fun_prop] theorem HasFDerivWithinAt.list_prod' {l : List ι} {x : E} (h : ∀ i ∈ l, HasFDerivWithinAt (f i ·) (f' i) s x) : HasFDerivWithinAt (fun x ↦ (l.map (f · x)).prod) (∑ i : Fin l.length, ((l.take i).map (f · x)).prod • smulRight (f' l[i]) ((l.drop (.succ i)).map (f · x)).prod) s x := by simp_rw [Fin.getElem_fin, ← l.get_eq_getElem, ← List.finRange_map_get l, List.map_map] refine .congr_fderiv (hasFDerivAt_list_prod_finRange'.comp_hasFDerivWithinAt x (hasFDerivWithinAt_pi.mpr fun i ↦ h (l.get i) (l.get_mem i)) :) ?_ ext m simp_rw [List.map_take, List.map_drop, List.map_map, comp_apply, sum_apply, smul_apply, smulRight_apply, proj_apply, pi_apply, Function.comp_def] theorem fderiv_list_prod' {l : List ι} {x : E} (h : ∀ i ∈ l, DifferentiableAt 𝕜 (f i ·) x) : fderiv 𝕜 (fun x ↦ (l.map (f · x)).prod) x = ∑ i : Fin l.length, ((l.take i).map (f · x)).prod • smulRight (fderiv 𝕜 (fun x ↦ f l[i] x) x) ((l.drop (.succ i)).map (f · x)).prod := (HasFDerivAt.list_prod' fun i hi ↦ (h i hi).hasFDerivAt).fderiv theorem fderivWithin_list_prod' {l : List ι} {x : E} (hxs : UniqueDiffWithinAt 𝕜 s x) (h : ∀ i ∈ l, DifferentiableWithinAt 𝕜 (f i ·) s x) : fderivWithin 𝕜 (fun x ↦ (l.map (f · x)).prod) s x = ∑ i : Fin l.length, ((l.take i).map (f · x)).prod • smulRight (fderivWithin 𝕜 (fun x ↦ f l[i] x) s x) ((l.drop (.succ i)).map (f · x)).prod := (HasFDerivWithinAt.list_prod' fun i hi ↦ (h i hi).hasFDerivWithinAt).fderivWithin hxs @[fun_prop] theorem HasStrictFDerivAt.multiset_prod [DecidableEq ι] {u : Multiset ι} {x : E} (h : ∀ i ∈ u, HasStrictFDerivAt (g i ·) (g' i) x) : HasStrictFDerivAt (fun x ↦ (u.map (g · x)).prod) (u.map fun i ↦ ((u.erase i).map (g · x)).prod • g' i).sum x := by simp only [← Multiset.attach_map_val u, Multiset.map_map] exact .congr_fderiv (hasStrictFDerivAt_multiset_prod.comp x <\| hasStrictFDerivAt_pi.mpr fun i ↦ h (Subtype.val i) i.prop :) (by ext; simp [Finset.sum_multiset_map_count, u.erase_attach_map (g · x)]) /-- Unlike `HasFDerivAt.finset_prod`, supports duplicate elements. -/ @[fun_prop] theorem HasFDerivAt.multiset_prod [DecidableEq ι] {u : Multiset ι} {x : E} (h : ∀ i ∈ u, HasFDerivAt (g i ·) (g' i) x) : HasFDerivAt (fun x ↦ (u.map (g · x)).prod) (u.map fun i ↦ ((u.erase i).map (g · x)).prod • g' i).sum x := by simp only [← Multiset.attach_map_val u, Multiset.map_map] exact .congr_fderiv (hasFDerivAt_multiset_prod.comp x <\| hasFDerivAt_pi.mpr fun i ↦ h (Subtype.val i) i.prop :) (by ext; simp [Finset.sum_multiset_map_count, u.erase_attach_map (g · x)]) @[fun_prop] theorem HasFDerivWithinAt.multiset_prod [DecidableEq ι] {u : Multiset ι} {x : E} (h : ∀ i ∈ u, HasFDerivWithinAt (g i ·) (g' i) s x) : HasFDerivWithinAt (fun x ↦ (u.map (g · x)).prod) (u.map fun i ↦ ((u.erase i).map (g · x)).prod • g' i).sum s x := by simp only [← Multiset.attach_map_val u, Multiset.map_map] exact .congr_fderiv (hasFDerivAt_multiset_prod.comp_hasFDerivWithinAt x <\| hasFDerivWithinAt_pi.mpr fun i ↦ h (Subtype.val i) i.prop :) (by ext; simp [Finset.sum_multiset_map_count, u.erase_attach_map (g · x)]) theorem fderiv_multiset_prod [DecidableEq ι] {u : Multiset ι} {x : E} (h : ∀ i ∈ u, DifferentiableAt 𝕜 (g i ·) x) : fderiv 𝕜 (fun x ↦ (u.map (g · x)).prod) x = (u.map fun i ↦ ((u.erase i).map (g · x)).prod • fderiv 𝕜 (g i) x).sum := (HasFDerivAt.multiset_prod fun i hi ↦ (h i hi).hasFDerivAt).fderiv theorem fderivWithin_multiset_prod [DecidableEq ι] {u : Multiset ι} {x : E} (hxs : UniqueDiffWithinAt 𝕜 s x) (h : ∀ i ∈ u, DifferentiableWithinAt 𝕜 (g i ·) s x) : fderivWithin 𝕜 (fun x ↦ (u.map (g · x)).prod) s x = (u.map fun i ↦ ((u.erase i).map (g · x)).prod • fderivWithin 𝕜 (g i) s x).sum := (HasFDerivWithinAt.multiset_prod fun i hi ↦ (h i hi).hasFDerivWithinAt).fderivWithin hxs theorem HasStrictFDerivAt.finset_prod [DecidableEq ι] {x : E} (hg : ∀ i ∈ u, HasStrictFDerivAt (g i) (g' i) x) : HasStrictFDerivAt (∏ i ∈ u, g i ·) (∑ i ∈ u, (∏ j ∈ u.erase i, g j x) • g' i) x := by simpa [← Finset.prod_attach u] using .congr_fderiv (hasStrictFDerivAt_finset_prod.comp x <\| hasStrictFDerivAt_pi.mpr fun i ↦ hg i i.prop) (by ext; simp [Finset.prod_erase_attach (g · x), ← u.sum_attach]) theorem HasFDerivAt.finset_prod [DecidableEq ι] {x : E} (hg : ∀ i ∈ u, HasFDerivAt (g i) (g' i) x) : HasFDerivAt (∏ i ∈ u, g i ·) (∑ i ∈ u, (∏ j ∈ u.erase i, g j x) • g' i) x := by simpa [← Finset.prod_attach u] using .congr_fderiv (hasFDerivAt_finset_prod.comp x <\| hasFDerivAt_pi.mpr fun i ↦ hg (Subtype.val i) i.prop :) (by ext; simp [Finset.prod_erase_attach (g · x), ← u.sum_attach]) theorem HasFDerivWithinAt.finset_prod [DecidableEq ι] {x : E} (hg : ∀ i ∈ u, HasFDerivWithinAt (g i) (g' i) s x) : HasFDerivWithinAt (∏ i ∈ u, g i ·) (∑ i ∈ u, (∏ j ∈ u.erase i, g j x) • g' i) s x := by simpa [← Finset.prod_attach u] using .congr_fderiv (hasFDerivAt_finset_prod.comp_hasFDerivWithinAt x <\| hasFDerivWithinAt_pi.mpr fun i ↦ hg (Subtype.val i) i.prop :) (by ext; simp [Finset.prod_erase_attach (g · x), ← u.sum_attach]) theorem fderiv_finset_prod [DecidableEq ι] {x : E} (hg : ∀ i ∈ u, DifferentiableAt 𝕜 (g i) x) : fderiv 𝕜 (∏ i ∈ u, g i ·) x = ∑ i ∈ u, (∏ j ∈ u.erase i, (g j x)) • fderiv 𝕜 (g i) x := (HasFDerivAt.finset_prod fun i hi ↦ (hg i hi).hasFDerivAt).fderiv theorem fderivWithin_finset_prod [DecidableEq ι] {x : E} (hxs : UniqueDiffWithinAt 𝕜 s x) (hg : ∀ i ∈ u, DifferentiableWithinAt 𝕜 (g i) s x) : fderivWithin 𝕜 (∏ i ∈ u, g i ·) s x = ∑ i ∈ u, (∏ j ∈ u.erase i, (g j x)) • fderivWithin 𝕜 (g i) s x := (HasFDerivWithinAt.finset_prod fun i hi ↦ (hg i hi).hasFDerivWithinAt).fderivWithin hxs end Comp end Prod section AlgebraInverse variable {R : Type} [NormedRing R] [HasSummableGeomSeries R] [NormedAlgebra 𝕜 R] open NormedRing ContinuousLinearMap Ring /-- At an invertible element `x` of a normed algebra `R`, the Fréchet derivative of the inversion operation is the linear map `fun t ↦ - x⁻¹ t * x⁻¹`. TODO (low prio): prove a version without assumption `[HasSummableGeomSeries R]` but within the set of units. -/ @[fun_prop] theorem hasFDerivAt_ringInverse (x : Rˣ) : HasFDerivAt Ring.inverse (-mulLeftRight 𝕜 R ↑x⁻¹ ↑x⁻¹) x := have : (fun t : R => Ring.inverse (↑x + t) - ↑x⁻¹ + ↑x⁻¹ * t * ↑x⁻¹) =o[𝓝 0] id := (inverse_add_norm_diff_second_order x).trans_isLittleO (isLittleO_norm_pow_id one_lt_two) by simpa [hasFDerivAt_iff_isLittleO_nhds_zero] using this @[deprecated (since := "2025-04-22")] alias hasFDerivAt_ring_inverse := hasFDerivAt_ringInverse @[fun_prop] theorem differentiableAt_inverse {x : R} (hx : IsUnit x) : DifferentiableAt 𝕜 (@Ring.inverse R _) x := let ⟨u, hu⟩ := hx; hu ▸ (hasFDerivAt_ringInverse u).differentiableAt @[fun_prop] theorem differentiableWithinAt_inverse {x : R} (hx : IsUnit x) (s : Set R) :	DifferentiableWithinAt 𝕜 (@Ring.inverse R _) s x := (differentiableAt_inverse hx).differentiableWithinAt @[fun_prop] theorem differentiableOn_inverse : DifferentiableOn 𝕜 (@Ring.inverse R _) {x \| IsUnit x} := fun _x hx => differentiableWithinAt_inverse hx _	Mathlib/Analysis/Calculus/FDeriv/Mul.lean	827	832
/- 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.CharP.Defs import Mathlib.Algebra.GeomSum import Mathlib.Algebra.MvPolynomial.CommRing import Mathlib.Algebra.MvPolynomial.Equiv import Mathlib.Algebra.Polynomial.BigOperators import Mathlib.RingTheory.Noetherian.Basic /-! # Ring-theoretic supplement of Algebra.Polynomial. ## Main results * `MvPolynomial.isDomain`: If a ring is an integral domain, then so is its polynomial ring over finitely many variables. * `Polynomial.isNoetherianRing`: Hilbert basis theorem, that if a ring is noetherian then so is its polynomial ring. -/ noncomputable section open Polynomial open Finset universe u v w variable {R : Type u} {S : Type} namespace Polynomial section Semiring variable [Semiring R] instance instCharP (p : ℕ) [h : CharP R p] : CharP R[X] p := let ⟨h⟩ := h ⟨fun n => by rw [← map_natCast C, ← C_0, C_inj, h]⟩ instance instExpChar (p : ℕ) [h : ExpChar R p] : ExpChar R[X] p := by cases h; exacts [ExpChar.zero, ExpChar.prime ‹_›] variable (R) /-- The `R`-submodule of `R[X]` consisting of polynomials of degree ≤ `n`. -/ def degreeLE (n : WithBot ℕ) : Submodule R R[X] := ⨅ k : ℕ, ⨅ _ : ↑k > n, LinearMap.ker (lcoeff R k) /-- The `R`-submodule of `R[X]` consisting of polynomials of degree < `n`. -/ def degreeLT (n : ℕ) : Submodule R R[X] := ⨅ k : ℕ, ⨅ (_ : k ≥ n), LinearMap.ker (lcoeff R k) variable {R} theorem mem_degreeLE {n : WithBot ℕ} {f : R[X]} : f ∈ degreeLE R n ↔ degree f ≤ n := by simp only [degreeLE, Submodule.mem_iInf, degree_le_iff_coeff_zero, LinearMap.mem_ker]; rfl @[mono] theorem degreeLE_mono {m n : WithBot ℕ} (H : m ≤ n) : degreeLE R m ≤ degreeLE R n := fun _ hf => mem_degreeLE.2 (le_trans (mem_degreeLE.1 hf) H) theorem degreeLE_eq_span_X_pow [DecidableEq R] {n : ℕ} : degreeLE R n = Submodule.span R ↑((Finset.range (n + 1)).image fun n => (X : R[X]) ^ n) := by apply le_antisymm · intro p hp replace hp := mem_degreeLE.1 hp rw [← Polynomial.sum_monomial_eq p, Polynomial.sum] refine Submodule.sum_mem _ fun k hk => ?_ have := WithBot.coe_le_coe.1 (Finset.sup_le_iff.1 hp k hk) rw [← C_mul_X_pow_eq_monomial, C_mul'] refine Submodule.smul_mem _ _ (Submodule.subset_span <\| Finset.mem_coe.2 <\| Finset.mem_image.2 ⟨_, Finset.mem_range.2 (Nat.lt_succ_of_le this), rfl⟩) rw [Submodule.span_le, Finset.coe_image, Set.image_subset_iff] intro k hk apply mem_degreeLE.2 exact (degree_X_pow_le _).trans (WithBot.coe_le_coe.2 <\| Nat.le_of_lt_succ <\| Finset.mem_range.1 hk) theorem mem_degreeLT {n : ℕ} {f : R[X]} : f ∈ degreeLT R n ↔ degree f < n := by rw [degreeLT, Submodule.mem_iInf] conv_lhs => intro i; rw [Submodule.mem_iInf] rw [degree, Finset.max_eq_sup_coe] rw [Finset.sup_lt_iff ?_] rotate_left · apply WithBot.bot_lt_coe conv_rhs => simp only [mem_support_iff] intro b rw [Nat.cast_withBot, WithBot.coe_lt_coe, lt_iff_not_le, Ne, not_imp_not] rfl @[mono] theorem degreeLT_mono {m n : ℕ} (H : m ≤ n) : degreeLT R m ≤ degreeLT R n := fun _ hf => mem_degreeLT.2 (lt_of_lt_of_le (mem_degreeLT.1 hf) <\| WithBot.coe_le_coe.2 H) theorem degreeLT_eq_span_X_pow [DecidableEq R] {n : ℕ} : degreeLT R n = Submodule.span R ↑((Finset.range n).image fun n => X ^ n : Finset R[X]) := by apply le_antisymm · intro p hp replace hp := mem_degreeLT.1 hp rw [← Polynomial.sum_monomial_eq p, Polynomial.sum] refine Submodule.sum_mem _ fun k hk => ?_ have := WithBot.coe_lt_coe.1 ((Finset.sup_lt_iff <\| WithBot.bot_lt_coe n).1 hp k hk) rw [← C_mul_X_pow_eq_monomial, C_mul'] refine Submodule.smul_mem _ _ (Submodule.subset_span <\| Finset.mem_coe.2 <\| Finset.mem_image.2 ⟨_, Finset.mem_range.2 this, rfl⟩) rw [Submodule.span_le, Finset.coe_image, Set.image_subset_iff] intro k hk apply mem_degreeLT.2 exact lt_of_le_of_lt (degree_X_pow_le _) (WithBot.coe_lt_coe.2 <\| Finset.mem_range.1 hk) /-- The first `n` coefficients on `degreeLT n` form a linear equivalence with `Fin n → R`. -/ def degreeLTEquiv (R) [Semiring R] (n : ℕ) : degreeLT R n ≃ₗ[R] Fin n → R where toFun p n := (↑p : R[X]).coeff n invFun f := ⟨∑ i : Fin n, monomial i (f i), (degreeLT R n).sum_mem fun i _ => mem_degreeLT.mpr (lt_of_le_of_lt (degree_monomial_le i (f i)) (WithBot.coe_lt_coe.mpr i.is_lt))⟩ map_add' p q := by ext dsimp rw [coeff_add] map_smul' x p := by ext dsimp rw [coeff_smul] rfl left_inv := by rintro ⟨p, hp⟩ ext1 simp only [Submodule.coe_mk] by_cases hp0 : p = 0 · subst hp0 simp only [coeff_zero, LinearMap.map_zero, Finset.sum_const_zero] rw [mem_degreeLT, degree_eq_natDegree hp0, Nat.cast_lt] at hp conv_rhs => rw [p.as_sum_range' n hp, ← Fin.sum_univ_eq_sum_range] right_inv f := by ext i simp only [finset_sum_coeff, Submodule.coe_mk] rw [Finset.sum_eq_single i, coeff_monomial, if_pos rfl] · rintro j - hji rw [coeff_monomial, if_neg] rwa [← Fin.ext_iff] · intro h exact (h (Finset.mem_univ _)).elim theorem degreeLTEquiv_eq_zero_iff_eq_zero {n : ℕ} {p : R[X]} (hp : p ∈ degreeLT R n) : degreeLTEquiv _ _ ⟨p, hp⟩ = 0 ↔ p = 0 := by simp theorem eval_eq_sum_degreeLTEquiv {n : ℕ} {p : R[X]} (hp : p ∈ degreeLT R n) (x : R) : p.eval x = ∑ i, degreeLTEquiv _ _ ⟨p, hp⟩ i x ^ (i : ℕ) := by simp_rw [eval_eq_sum] exact (sum_fin _ (by simp_rw [zero_mul, forall_const]) (mem_degreeLT.mp hp)).symm theorem degreeLT_succ_eq_degreeLE {n : ℕ} : degreeLT R (n + 1) = degreeLE R n := by ext x by_cases x_zero : x = 0 · simp_rw [x_zero, Submodule.zero_mem] · rw [mem_degreeLT, mem_degreeLE, ← natDegree_lt_iff_degree_lt (by rwa [ne_eq]), ← natDegree_le_iff_degree_le, Nat.lt_succ] /-- The equivalence between monic polynomials of degree `n` and polynomials of degree less than `n`, formed by adding a term `X ^ n`. -/ def monicEquivDegreeLT [Nontrivial R] (n : ℕ) : { p : R[X] // p.Monic ∧ p.natDegree = n } ≃ degreeLT R n where toFun p := ⟨p.1.eraseLead, by rcases p with ⟨p, hp, rfl⟩ simp only [mem_degreeLT] refine lt_of_lt_of_le ?_ degree_le_natDegree exact degree_eraseLead_lt (ne_zero_of_ne_zero_of_monic one_ne_zero hp)⟩ invFun := fun p => ⟨X^n + p.1, monic_X_pow_add (mem_degreeLT.1 p.2), by rw [natDegree_add_eq_left_of_degree_lt] · simp · simp [mem_degreeLT.1 p.2]⟩ left_inv := by rintro ⟨p, hp, rfl⟩ ext1 simp only conv_rhs => rw [← eraseLead_add_C_mul_X_pow p] simp [Monic.def.1 hp, add_comm] right_inv := by rintro ⟨p, hp⟩ ext1 simp only rw [eraseLead_add_of_degree_lt_left] · simp · simp [mem_degreeLT.1 hp] /-- For every polynomial `p` in the span of a set `s : Set R[X]`, there exists a polynomial of `p' ∈ s` with higher degree. See also `Polynomial.exists_degree_le_of_mem_span_of_finite`. -/ theorem exists_degree_le_of_mem_span {s : Set R[X]} {p : R[X]} (hs : s.Nonempty) (hp : p ∈ Submodule.span R s) : ∃ p' ∈ s, degree p ≤ degree p' := by by_contra! h by_cases hp_zero : p = 0 · rw [hp_zero, degree_zero] at h rcases hs with ⟨x, hx⟩ exact not_lt_bot (h x hx) · have : p ∈ degreeLT R (natDegree p) := by refine (Submodule.span_le.mpr fun p' p'_mem => ?_) hp rw [SetLike.mem_coe, mem_degreeLT, Nat.cast_withBot] exact lt_of_lt_of_le (h p' p'_mem) degree_le_natDegree rwa [mem_degreeLT, Nat.cast_withBot, degree_eq_natDegree hp_zero, Nat.cast_withBot, lt_self_iff_false] at this /-- A stronger version of `Polynomial.exists_degree_le_of_mem_span` under the assumption that the set `s : R[X]` is finite. There exists a polynomial `p' ∈ s` whose degree dominates the degree of every element of `p ∈ span R s`. -/ theorem exists_degree_le_of_mem_span_of_finite {s : Set R[X]} (s_fin : s.Finite) (hs : s.Nonempty) : ∃ p' ∈ s, ∀ (p : R[X]), p ∈ Submodule.span R s → degree p ≤ degree p' := by rcases Set.Finite.exists_maximal_wrt degree s s_fin hs with ⟨a, has, hmax⟩ refine ⟨a, has, fun p hp => ?_⟩ rcases exists_degree_le_of_mem_span hs hp with ⟨p', hp'⟩ by_cases h : degree a ≤ degree p' · rw [← hmax p' hp'.left h] at hp'; exact hp'.right · exact le_trans hp'.right (not_le.mp h).le /-- The span of every finite set of polynomials is contained in a `degreeLE n` for some `n`. -/ theorem span_le_degreeLE_of_finite {s : Set R[X]} (s_fin : s.Finite) : ∃ n : ℕ, Submodule.span R s ≤ degreeLE R n := by by_cases s_emp : s.Nonempty · rcases exists_degree_le_of_mem_span_of_finite s_fin s_emp with ⟨p', _, hp'max⟩ exact ⟨natDegree p', fun p hp => mem_degreeLE.mpr ((hp'max _ hp).trans degree_le_natDegree)⟩ · rw [Set.not_nonempty_iff_eq_empty] at s_emp rw [s_emp, Submodule.span_empty] exact ⟨0, bot_le⟩ /-- The span of every finite set of polynomials is contained in a `degreeLT n` for some `n`. -/ theorem span_of_finite_le_degreeLT {s : Set R[X]} (s_fin : s.Finite) : ∃ n : ℕ, Submodule.span R s ≤ degreeLT R n := by rcases span_le_degreeLE_of_finite s_fin with ⟨n, _⟩ exact ⟨n + 1, by rwa [degreeLT_succ_eq_degreeLE]⟩ /-- If `R` is a nontrivial ring, the polynomials `R[X]` are not finite as an `R`-module. When `R` is a field, this is equivalent to `R[X]` being an infinite-dimensional vector space over `R`. -/ theorem not_finite [Nontrivial R] : ¬ Module.Finite R R[X] := by rw [Module.finite_def, Submodule.fg_def] push_neg intro s hs contra rcases span_le_degreeLE_of_finite hs with ⟨n,hn⟩ have : ((X : R[X]) ^ (n + 1)) ∈ Polynomial.degreeLE R ↑n := by rw [contra] at hn exact hn Submodule.mem_top rw [mem_degreeLE, degree_X_pow, Nat.cast_le, add_le_iff_nonpos_right, nonpos_iff_eq_zero] at this exact one_ne_zero this theorem geom_sum_X_comp_X_add_one_eq_sum (n : ℕ) : (∑ i ∈ range n, (X : R[X]) ^ i).comp (X + 1) = (Finset.range n).sum fun i : ℕ => (n.choose (i + 1) : R[X]) * X ^ i := by ext i trans (n.choose (i + 1) : R); swap · simp only [finset_sum_coeff, ← C_eq_natCast, coeff_C_mul_X_pow] rw [Finset.sum_eq_single i, if_pos rfl] · simp +contextual only [@eq_comm _ i, if_false, eq_self_iff_true, imp_true_iff] · simp +contextual only [Nat.lt_add_one_iff, Nat.choose_eq_zero_of_lt, Nat.cast_zero, Finset.mem_range, not_lt, eq_self_iff_true, if_true, imp_true_iff] induction' n with n ih generalizing i · dsimp; simp only [zero_comp, coeff_zero, Nat.cast_zero] · simp only [geom_sum_succ', ih, add_comp, X_pow_comp, coeff_add, Nat.choose_succ_succ, Nat.cast_add, coeff_X_add_one_pow] theorem Monic.geom_sum {P : R[X]} (hP : P.Monic) (hdeg : 0 < P.natDegree) {n : ℕ} (hn : n ≠ 0) : (∑ i ∈ range n, P ^ i).Monic := by nontriviality R obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero hn rw [geom_sum_succ'] refine (hP.pow _).add_of_left ?_ refine lt_of_le_of_lt (degree_sum_le _ _) ?_ rw [Finset.sup_lt_iff] · simp only [Finset.mem_range, degree_eq_natDegree (hP.pow _).ne_zero] simp only [Nat.cast_lt, hP.natDegree_pow] intro k exact nsmul_lt_nsmul_left hdeg · rw [bot_lt_iff_ne_bot, Ne, degree_eq_bot] exact (hP.pow _).ne_zero theorem Monic.geom_sum' {P : R[X]} (hP : P.Monic) (hdeg : 0 < P.degree) {n : ℕ} (hn : n ≠ 0) : (∑ i ∈ range n, P ^ i).Monic := hP.geom_sum (natDegree_pos_iff_degree_pos.2 hdeg) hn theorem monic_geom_sum_X {n : ℕ} (hn : n ≠ 0) : (∑ i ∈ range n, (X : R[X]) ^ i).Monic := by nontriviality R apply monic_X.geom_sum _ hn simp only [natDegree_X, zero_lt_one] end Semiring section Ring variable [Ring R] /-- Given a polynomial, return the polynomial whose coefficients are in the ring closure of the original coefficients. -/ def restriction (p : R[X]) : Polynomial (Subring.closure (↑p.coeffs : Set R)) := ∑ i ∈ p.support, monomial i (⟨p.coeff i, letI := Classical.decEq R if H : p.coeff i = 0 then H.symm ▸ (Subring.closure _).zero_mem else Subring.subset_closure (p.coeff_mem_coeffs _ H)⟩ : Subring.closure (↑p.coeffs : Set R)) @[simp] theorem coeff_restriction {p : R[X]} {n : ℕ} : ↑(coeff (restriction p) n) = coeff p n := by classical simp only [restriction, coeff_monomial, finset_sum_coeff, mem_support_iff, Finset.sum_ite_eq', Ne, ite_not] split_ifs with h · rw [h] rfl · rfl theorem coeff_restriction' {p : R[X]} {n : ℕ} : (coeff (restriction p) n).1 = coeff p n := by simp @[simp] theorem support_restriction (p : R[X]) : support (restriction p) = support p := by ext i simp only [mem_support_iff, not_iff_not, Ne] conv_rhs => rw [← coeff_restriction] exact ⟨fun H => by rw [H, ZeroMemClass.coe_zero], fun H => Subtype.coe_injective H⟩ @[simp] theorem map_restriction {R : Type u} [CommRing R] (p : R[X]) : p.restriction.map (algebraMap _ _) = p := ext fun n => by rw [coeff_map, Algebra.algebraMap_ofSubring_apply, coeff_restriction] @[simp] theorem degree_restriction {p : R[X]} : (restriction p).degree = p.degree := by simp [degree] @[simp] theorem natDegree_restriction {p : R[X]} : (restriction p).natDegree = p.natDegree := by simp [natDegree] @[simp] theorem monic_restriction {p : R[X]} : Monic (restriction p) ↔ Monic p := by simp only [Monic, leadingCoeff, natDegree_restriction] rw [← @coeff_restriction _ _ p] exact ⟨fun H => by rw [H, OneMemClass.coe_one], fun H => Subtype.coe_injective H⟩ @[simp] theorem restriction_zero : restriction (0 : R[X]) = 0 := by simp only [restriction, Finset.sum_empty, support_zero] @[simp] theorem restriction_one : restriction (1 : R[X]) = 1 := ext fun i => Subtype.eq <\| by rw [coeff_restriction', coeff_one, coeff_one]; split_ifs <;> rfl variable [Semiring S] {f : R →+* S} {x : S} theorem eval₂_restriction {p : R[X]} : eval₂ f x p = eval₂ (f.comp (Subring.subtype (Subring.closure (p.coeffs : Set R)))) x p.restriction := by simp only [eval₂_eq_sum, sum, support_restriction, ← @coeff_restriction _ _ p, RingHom.comp_apply, Subring.coe_subtype] section ToSubring variable (p : R[X]) (T : Subring R) /-- Given a polynomial `p` and a subring `T` that contains the coefficients of `p`, return the corresponding polynomial whose coefficients are in `T`. -/ def toSubring (hp : (↑p.coeffs : Set R) ⊆ T) : T[X] := ∑ i ∈ p.support, monomial i (⟨p.coeff i, letI := Classical.decEq R if H : p.coeff i = 0 then H.symm ▸ T.zero_mem else hp (p.coeff_mem_coeffs _ H)⟩ : T) variable (hp : (↑p.coeffs : Set R) ⊆ T) @[simp] theorem coeff_toSubring {n : ℕ} : ↑(coeff (toSubring p T hp) n) = coeff p n := by classical simp only [toSubring, coeff_monomial, finset_sum_coeff, mem_support_iff, Finset.sum_ite_eq', Ne, ite_not] split_ifs with h · rw [h] rfl · rfl theorem coeff_toSubring' {n : ℕ} : (coeff (toSubring p T hp) n).1 = coeff p n := by simp @[simp] theorem support_toSubring : support (toSubring p T hp) = support p := by ext i simp only [mem_support_iff, not_iff_not, Ne] conv_rhs => rw [← coeff_toSubring p T hp] exact ⟨fun H => by rw [H, ZeroMemClass.coe_zero], fun H => Subtype.coe_injective H⟩ @[simp] theorem degree_toSubring : (toSubring p T hp).degree = p.degree := by simp [degree] @[simp] theorem natDegree_toSubring : (toSubring p T hp).natDegree = p.natDegree := by simp [natDegree] @[simp] theorem monic_toSubring : Monic (toSubring p T hp) ↔ Monic p := by simp_rw [Monic, leadingCoeff, natDegree_toSubring, ← coeff_toSubring p T hp] exact ⟨fun H => by rw [H, OneMemClass.coe_one], fun H => Subtype.coe_injective H⟩ @[simp] theorem toSubring_zero : toSubring (0 : R[X]) T (by simp [coeffs]) = 0 := by ext i simp @[simp] theorem toSubring_one : toSubring (1 : R[X]) T (Set.Subset.trans coeffs_one <\| Finset.singleton_subset_set_iff.2 T.one_mem) = 1 := ext fun i => Subtype.eq <\| by rw [coeff_toSubring', coeff_one, coeff_one, apply_ite Subtype.val, ZeroMemClass.coe_zero, OneMemClass.coe_one] @[simp] theorem map_toSubring : (p.toSubring T hp).map (Subring.subtype T) = p := by ext n simp [coeff_map] end ToSubring variable (T : Subring R) /-- Given a polynomial whose coefficients are in some subring, return the corresponding polynomial whose coefficients are in the ambient ring. -/ def ofSubring (p : T[X]) : R[X] := ∑ i ∈ p.support, monomial i (p.coeff i : R) theorem coeff_ofSubring (p : T[X]) (n : ℕ) : coeff (ofSubring T p) n = (coeff p n : T) := by simp only [ofSubring, coeff_monomial, finset_sum_coeff, mem_support_iff, Finset.sum_ite_eq', ite_eq_right_iff, Ne, ite_not, Classical.not_not, ite_eq_left_iff] intro h rw [h, ZeroMemClass.coe_zero] @[simp] theorem coeffs_ofSubring {p : T[X]} : (↑(p.ofSubring T).coeffs : Set R) ⊆ T := by classical intro i hi simp only [coeffs, Set.mem_image, mem_support_iff, Ne, Finset.mem_coe, (Finset.coe_image)] at hi rcases hi with ⟨n, _, h'n⟩ rw [← h'n, coeff_ofSubring] exact Subtype.mem (coeff p n : T) end Ring end Polynomial namespace Ideal open Polynomial section Semiring variable [Semiring R] /-- Transport an ideal of `R[X]` to an `R`-submodule of `R[X]`. -/ def ofPolynomial (I : Ideal R[X]) : Submodule R R[X] where carrier := I.carrier zero_mem' := I.zero_mem add_mem' := I.add_mem smul_mem' c x H := by rw [← C_mul'] exact I.mul_mem_left _ H variable {I : Ideal R[X]} theorem mem_ofPolynomial (x) : x ∈ I.ofPolynomial ↔ x ∈ I := Iff.rfl variable (I) /-- Given an ideal `I` of `R[X]`, make the `R`-submodule of `I` consisting of polynomials of degree ≤ `n`. -/ def degreeLE (n : WithBot ℕ) : Submodule R R[X] := Polynomial.degreeLE R n ⊓ I.ofPolynomial /-- Given an ideal `I` of `R[X]`, make the ideal in `R` of leading coefficients of polynomials in `I` with degree ≤ `n`. -/ def leadingCoeffNth (n : ℕ) : Ideal R := (I.degreeLE n).map <\| lcoeff R n /-- Given an ideal `I` in `R[X]`, make the ideal in `R` of the leading coefficients in `I`. -/ def leadingCoeff : Ideal R := ⨆ n : ℕ, I.leadingCoeffNth n end Semiring section CommSemiring variable [CommSemiring R] [Semiring S] /-- If every coefficient of a polynomial is in an ideal `I`, then so is the polynomial itself -/ theorem polynomial_mem_ideal_of_coeff_mem_ideal (I : Ideal R[X]) (p : R[X]) (hp : ∀ n : ℕ, p.coeff n ∈ I.comap (C : R →+* R[X])) : p ∈ I := sum_C_mul_X_pow_eq p ▸ Submodule.sum_mem I fun n _ => I.mul_mem_right _ (hp n) /-- The push-forward of an ideal `I` of `R` to `R[X]` via inclusion is exactly the set of polynomials whose coefficients are in `I` -/ theorem mem_map_C_iff {I : Ideal R} {f : R[X]} : f ∈ (Ideal.map (C : R →+* R[X]) I : Ideal R[X]) ↔ ∀ n : ℕ, f.coeff n ∈ I := by constructor · intro hf refine Submodule.span_induction ?_ ?_ ?_ ?_ hf · intro f hf n obtain ⟨x, hx⟩ := (Set.mem_image _ _ _).mp hf rw [← hx.right, coeff_C] by_cases h : n = 0 · simpa [h] using hx.left · simp [h] · simp · exact fun f g _ _ hf hg n => by simp [I.add_mem (hf n) (hg n)] · refine fun f g _ hg n => ?_ rw [smul_eq_mul, coeff_mul] exact I.sum_mem fun c _ => I.mul_mem_left (f.coeff c.fst) (hg c.snd) · intro hf rw [← sum_monomial_eq f] refine (I.map C : Ideal R[X]).sum_mem fun n _ => ?_ simp only [← C_mul_X_pow_eq_monomial, ne_eq] rw [mul_comm] exact (I.map C : Ideal R[X]).mul_mem_left _ (mem_map_of_mem _ (hf n)) theorem _root_.Polynomial.ker_mapRingHom (f : R →+* S) : RingHom.ker (Polynomial.mapRingHom f) = (RingHom.ker f).map (C : R →+* R[X]) := by ext simp only [RingHom.mem_ker, coe_mapRingHom] rw [mem_map_C_iff, Polynomial.ext_iff] simp [RingHom.mem_ker] variable (I : Ideal R[X]) theorem mem_leadingCoeffNth (n : ℕ) (x) : x ∈ I.leadingCoeffNth n ↔ ∃ p ∈ I, degree p ≤ n ∧ p.leadingCoeff = x := by simp only [leadingCoeffNth, degreeLE, Submodule.mem_map, lcoeff_apply, Submodule.mem_inf, mem_degreeLE] constructor · rintro ⟨p, ⟨hpdeg, hpI⟩, rfl⟩ rcases lt_or_eq_of_le hpdeg with hpdeg \| hpdeg · refine ⟨0, I.zero_mem, bot_le, ?_⟩ rw [leadingCoeff_zero, eq_comm] exact coeff_eq_zero_of_degree_lt hpdeg · refine ⟨p, hpI, le_of_eq hpdeg, ?_⟩ rw [Polynomial.leadingCoeff, natDegree, hpdeg, Nat.cast_withBot, WithBot.unbotD_coe] · rintro ⟨p, hpI, hpdeg, rfl⟩ have : natDegree p + (n - natDegree p) = n := add_tsub_cancel_of_le (natDegree_le_of_degree_le hpdeg) refine ⟨p * X ^ (n - natDegree p), ⟨?_, I.mul_mem_right _ hpI⟩, ?_⟩ · apply le_trans (degree_mul_le _ _) _ apply le_trans (add_le_add degree_le_natDegree (degree_X_pow_le _)) _ rw [← Nat.cast_add, this] · rw [Polynomial.leadingCoeff, ← coeff_mul_X_pow p (n - natDegree p), this] theorem mem_leadingCoeffNth_zero (x) : x ∈ I.leadingCoeffNth 0 ↔ C x ∈ I := (mem_leadingCoeffNth _ _ _).trans ⟨fun ⟨p, hpI, hpdeg, hpx⟩ => by rwa [← hpx, Polynomial.leadingCoeff, Nat.eq_zero_of_le_zero (natDegree_le_of_degree_le hpdeg), ← eq_C_of_degree_le_zero hpdeg], fun hx => ⟨C x, hx, degree_C_le, leadingCoeff_C x⟩⟩ theorem leadingCoeffNth_mono {m n : ℕ} (H : m ≤ n) : I.leadingCoeffNth m ≤ I.leadingCoeffNth n := by intro r hr simp only [SetLike.mem_coe, mem_leadingCoeffNth] at hr ⊢ rcases hr with ⟨p, hpI, hpdeg, rfl⟩ refine ⟨p * X ^ (n - m), I.mul_mem_right _ hpI, ?_, leadingCoeff_mul_X_pow⟩ refine le_trans (degree_mul_le _ _) ?_ refine le_trans (add_le_add hpdeg (degree_X_pow_le _)) ?_ rw [← Nat.cast_add, add_tsub_cancel_of_le H] theorem mem_leadingCoeff (x) : x ∈ I.leadingCoeff ↔ ∃ p ∈ I, Polynomial.leadingCoeff p = x := by rw [leadingCoeff, Submodule.mem_iSup_of_directed] · simp only [mem_leadingCoeffNth] constructor · rintro ⟨i, p, hpI, _, rfl⟩ exact ⟨p, hpI, rfl⟩ rintro ⟨p, hpI, rfl⟩ exact ⟨natDegree p, p, hpI, degree_le_natDegree, rfl⟩ intro i j exact ⟨i + j, I.leadingCoeffNth_mono (Nat.le_add_right _ _), I.leadingCoeffNth_mono (Nat.le_add_left _ _)⟩ /-- If `I` is an ideal, and `pᵢ` is a finite family of polynomials each satisfying `∀ k, (pᵢ)ₖ ∈ Iⁿⁱ⁻ᵏ` for some `nᵢ`, then `p = ∏ pᵢ` also satisfies `∀ k, pₖ ∈ Iⁿ⁻ᵏ` with `n = ∑ nᵢ`. -/ theorem _root_.Polynomial.coeff_prod_mem_ideal_pow_tsub {ι : Type} (s : Finset ι) (f : ι → R[X]) (I : Ideal R) (n : ι → ℕ) (h : ∀ i ∈ s, ∀ (k), (f i).coeff k ∈ I ^ (n i - k)) (k : ℕ) : (s.prod f).coeff k ∈ I ^ (s.sum n - k) := by classical induction' s using Finset.induction with a s ha hs generalizing k · rw [sum_empty, prod_empty, coeff_one, zero_tsub, pow_zero, Ideal.one_eq_top] exact Submodule.mem_top · rw [sum_insert ha, prod_insert ha, coeff_mul] apply sum_mem rintro ⟨i, j⟩ e obtain rfl : i + j = k := mem_antidiagonal.mp e apply Ideal.pow_le_pow_right add_tsub_add_le_tsub_add_tsub rw [pow_add] exact Ideal.mul_mem_mul (h _ (Finset.mem_insert.mpr <\| Or.inl rfl) _) (hs (fun i hi k => h _ (Finset.mem_insert.mpr <\| Or.inr hi) _) j) end CommSemiring section Ring variable [Ring R] /-- `R[X]` is never a field for any ring `R`. -/ theorem polynomial_not_isField : ¬IsField R[X] := by nontriviality R intro hR obtain ⟨p, hp⟩ := hR.mul_inv_cancel X_ne_zero have hp0 : p ≠ 0 := right_ne_zero_of_mul_eq_one hp have := degree_lt_degree_mul_X hp0 rw [← X_mul, congr_arg degree hp, degree_one, Nat.WithBot.lt_zero_iff, degree_eq_bot] at this exact hp0 this /-- The only constant in a maximal ideal over a field is `0`. -/ theorem eq_zero_of_constant_mem_of_maximal (hR : IsField R) (I : Ideal R[X]) [hI : I.IsMaximal] (x : R) (hx : C x ∈ I) : x = 0 := by refine Classical.by_contradiction fun hx0 => hI.ne_top ((eq_top_iff_one I).2 ?_) obtain ⟨y, hy⟩ := hR.mul_inv_cancel hx0 convert I.mul_mem_left (C y) hx rw [← C.map_mul, hR.mul_comm y x, hy, RingHom.map_one] end Ring section CommRing variable [CommRing R] /-- If `P` is a prime ideal of `R`, then `P.R[x]` is a prime ideal of `R[x]`. -/ theorem isPrime_map_C_iff_isPrime (P : Ideal R) : IsPrime (map (C : R →+ R[X]) P : Ideal R[X]) ↔ IsPrime P := by -- Note: the following proof avoids quotient rings -- It can be golfed substantially by using something like -- `(Quotient.isDomain_iff_prime (map C P : Ideal R[X]))` constructor · intro H have := comap_isPrime C (map C P) convert this using 1 ext x simp only [mem_comap, mem_map_C_iff] constructor · rintro h (- \| n) · rwa [coeff_C_zero] · simp only [coeff_C_ne_zero (Nat.succ_ne_zero _), Submodule.zero_mem] · intro h simpa only [coeff_C_zero] using h 0 · intro h constructor · rw [Ne, eq_top_iff_one, mem_map_C_iff, not_forall] use 0 rw [coeff_one_zero, ← eq_top_iff_one] exact h.1 · intro f g simp only [mem_map_C_iff] contrapose! rintro ⟨hf, hg⟩ classical let m := Nat.find hf let n := Nat.find hg refine ⟨m + n, ?_⟩ rw [coeff_mul, ← Finset.insert_erase ((Finset.mem_antidiagonal (a := (m,n))).mpr rfl), Finset.sum_insert (Finset.not_mem_erase _ _), (P.add_mem_iff_left _).not] · apply mt h.2 rw [not_or] exact ⟨Nat.find_spec hf, Nat.find_spec hg⟩ apply P.sum_mem rintro ⟨i, j⟩ hij rw [Finset.mem_erase, Finset.mem_antidiagonal] at hij simp only [Ne, Prod.mk_inj, not_and_or] at hij obtain hi \| hj : i < m ∨ j < n := by omega · rw [mul_comm] apply P.mul_mem_left exact Classical.not_not.1 (Nat.find_min hf hi) · apply P.mul_mem_left exact Classical.not_not.1 (Nat.find_min hg hj) /-- If `P` is a prime ideal of `R`, then `P.R[x]` is a prime ideal of `R[x]`. -/ theorem isPrime_map_C_of_isPrime {P : Ideal R} (H : IsPrime P) : IsPrime (map (C : R →+* R[X]) P : Ideal R[X]) := (isPrime_map_C_iff_isPrime P).mpr H theorem is_fg_degreeLE [IsNoetherianRing R] (I : Ideal R[X]) (n : ℕ) : Submodule.FG (I.degreeLE n) := letI := Classical.decEq R isNoetherian_submodule_left.1 (isNoetherian_of_fg_of_noetherian _ ⟨_, degreeLE_eq_span_X_pow.symm⟩) _ end CommRing end Ideal section Ideal open Submodule Set variable [Semiring R] {f : R[X]} {I : Ideal R[X]} /-- If the coefficients of a polynomial belong to an ideal, then that ideal contains the ideal spanned by the coefficients of the polynomial. -/ theorem span_le_of_C_coeff_mem (cf : ∀ i : ℕ, C (f.coeff i) ∈ I) : Ideal.span { g \| ∃ i, g = C (f.coeff i) } ≤ I := by simp only [@eq_comm _ _ (C _)] exact (Ideal.span_le.trans range_subset_iff).mpr cf theorem mem_span_C_coeff : f ∈ Ideal.span { g : R[X] \| ∃ i : ℕ, g = C (coeff f i) } := by let p := Ideal.span { g : R[X] \| ∃ i : ℕ, g = C (coeff f i) } nth_rw 2 [(sum_C_mul_X_pow_eq f).symm] refine Submodule.sum_mem _ fun n _hn => ?_ dsimp have : C (coeff f n) ∈ p := by apply subset_span rw [mem_setOf_eq] use n have : monomial n (1 : R) • C (coeff f n) ∈ p := p.smul_mem _ this convert this using 1 simp only [monomial_mul_C, one_mul, smul_eq_mul] rw [← C_mul_X_pow_eq_monomial] theorem exists_C_coeff_not_mem : f ∉ I → ∃ i : ℕ, C (coeff f i) ∉ I := Not.imp_symm fun cf => span_le_of_C_coeff_mem (not_exists_not.mp cf) mem_span_C_coeff end Ideal variable {σ : Type v} {M : Type w} variable [CommRing R] [CommRing S] [AddCommGroup M] [Module R M] section Prime variable (σ) {r : R} namespace Polynomial theorem prime_C_iff : Prime (C r) ↔ Prime r := ⟨comap_prime C (evalRingHom (0 : R)) fun _ => eval_C, fun hr => by have := hr.1 rw [← Ideal.span_singleton_prime] at hr ⊢ · rw [← Set.image_singleton, ← Ideal.map_span] apply Ideal.isPrime_map_C_of_isPrime hr · intro h; apply (this (C_eq_zero.mp h)) · assumption⟩ end Polynomial namespace MvPolynomial private theorem prime_C_iff_of_fintype {R : Type u} (σ : Type v) {r : R} [CommRing R] [Fintype σ] : Prime (C r : MvPolynomial σ R) ↔ Prime r := by rw [← MulEquiv.prime_iff (renameEquiv R (Fintype.equivFin σ))] convert_to Prime (C r) ↔ _ · congr! simp only [renameEquiv_apply, algHom_C, algebraMap_eq] · induction' Fintype.card σ with d hd · exact MulEquiv.prime_iff (isEmptyAlgEquiv R (Fin 0)).symm (p := r) · convert MulEquiv.prime_iff (finSuccEquiv R d).symm (p := Polynomial.C (C r)) · simp [← finSuccEquiv_comp_C_eq_C] · simp [← hd, Polynomial.prime_C_iff] theorem prime_C_iff : Prime (C r : MvPolynomial σ R) ↔ Prime r := ⟨comap_prime C constantCoeff (constantCoeff_C _), fun hr => ⟨fun h => hr.1 <\| by rw [← C_inj, h] simp, fun h => hr.2.1 <\| by rw [← constantCoeff_C _ r] exact h.map _, fun a b hd => by obtain ⟨s, a', b', rfl, rfl⟩ := exists_finset_rename₂ a b rw [← algebraMap_eq] at hd have : algebraMap R _ r ∣ a' * b' := by convert killCompl Subtype.coe_injective \|>.toRingHom.map_dvd hd <;> simp rw [← rename_C ((↑) : s → σ)] let f := (rename (R := R) ((↑) : s → σ)).toRingHom exact (((prime_C_iff_of_fintype s).2 hr).2.2 a' b' this).imp f.map_dvd f.map_dvd⟩⟩ variable {σ} theorem prime_rename_iff (s : Set σ) {p : MvPolynomial s R} : Prime (rename ((↑) : s → σ) p) ↔ Prime (p : MvPolynomial s R) := by classical symm let eqv := (sumAlgEquiv R (↥sᶜ) s).symm.trans (renameEquiv R <\| (Equiv.sumComm (↥sᶜ) s).trans <\| Equiv.Set.sumCompl s) have : (rename (↑)).toRingHom = eqv.toAlgHom.toRingHom.comp C := by apply ringHom_ext · intro simp only [eqv, AlgHom.toRingHom_eq_coe, RingHom.coe_coe, rename_C, AlgEquiv.toAlgHom_eq_coe, AlgEquiv.toAlgHom_toRingHom, RingHom.coe_comp, AlgEquiv.coe_trans, Function.comp_apply, MvPolynomial.sumAlgEquiv_symm_apply, iterToSum_C_C, renameEquiv_apply, Equiv.coe_trans, Equiv.sumComm_apply] · intro simp only [eqv, AlgHom.toRingHom_eq_coe, RingHom.coe_coe, rename_X, AlgEquiv.toAlgHom_eq_coe, AlgEquiv.toAlgHom_toRingHom, RingHom.coe_comp, AlgEquiv.coe_trans, Function.comp_apply, MvPolynomial.sumAlgEquiv_symm_apply, iterToSum_C_X, renameEquiv_apply, Equiv.coe_trans, Equiv.sumComm_apply, Sum.swap_inr, Equiv.Set.sumCompl_apply_inl] apply_fun (· p) at this simp only [AlgHom.toRingHom_eq_coe, RingHom.coe_coe, AlgEquiv.toAlgHom_eq_coe, AlgEquiv.toAlgHom_toRingHom, RingHom.coe_comp, Function.comp_apply] at this rw [this, MulEquiv.prime_iff, prime_C_iff] end MvPolynomial end Prime /-- Hilbert basis theorem: a polynomial ring over a Noetherian ring is a Noetherian ring. -/ protected theorem Polynomial.isNoetherianRing [inst : IsNoetherianRing R] : IsNoetherianRing R[X] := isNoetherianRing_iff.2 ⟨fun I : Ideal R[X] => let M := inst.wf.min (Set.range I.leadingCoeffNth) ⟨_, ⟨0, rfl⟩⟩ have hm : M ∈ Set.range I.leadingCoeffNth := WellFounded.min_mem _ _ _ let ⟨N, HN⟩ := hm let ⟨s, hs⟩ := I.is_fg_degreeLE N have hm2 : ∀ k, I.leadingCoeffNth k ≤ M := fun k => Or.casesOn (le_or_lt k N) (fun h => HN ▸ I.leadingCoeffNth_mono h) fun h _ hx => Classical.by_contradiction fun hxm => haveI : IsNoetherian R R := inst have : ¬M < I.leadingCoeffNth k := by refine WellFounded.not_lt_min inst.wf _ _ ?_; exact ⟨k, rfl⟩ this ⟨HN ▸ I.leadingCoeffNth_mono (le_of_lt h), fun H => hxm (H hx)⟩ have hs2 : ∀ {x}, x ∈ I.degreeLE N → x ∈ Ideal.span (↑s : Set R[X]) := hs ▸ fun hx => Submodule.span_induction (hx := hx) (fun _ hx => Ideal.subset_span hx) (Ideal.zero_mem _) (fun _ _ _ _ => Ideal.add_mem _) fun c f _ hf => f.C_mul' c ▸ Ideal.mul_mem_left _ _ hf ⟨s, le_antisymm (Ideal.span_le.2 fun x hx => have : x ∈ I.degreeLE N := hs ▸ Submodule.subset_span hx this.2) <\| by have : Submodule.span R[X] ↑s = Ideal.span ↑s := rfl rw [this] intro p hp generalize hn : p.natDegree = k induction' k using Nat.strong_induction_on with k ih generalizing p rcases le_or_lt k N with h \| h · subst k refine hs2 ⟨Polynomial.mem_degreeLE.2 (le_trans Polynomial.degree_le_natDegree <\| WithBot.coe_le_coe.2 h), hp⟩ · have hp0 : p ≠ 0 := by rintro rfl cases hn exact Nat.not_lt_zero _ h have : (0 : R) ≠ 1 := by intro h apply hp0 ext i refine (mul_one _).symm.trans ?_ rw [← h, mul_zero] rfl haveI : Nontrivial R := ⟨⟨0, 1, this⟩⟩ have : p.leadingCoeff ∈ I.leadingCoeffNth N := by rw [HN] exact hm2 k ((I.mem_leadingCoeffNth _ _).2 ⟨_, hp, hn ▸ Polynomial.degree_le_natDegree, rfl⟩) rw [I.mem_leadingCoeffNth] at this rcases this with ⟨q, hq, hdq, hlqp⟩ have hq0 : q ≠ 0 := by intro H rw [← Polynomial.leadingCoeff_eq_zero] at H rw [hlqp, Polynomial.leadingCoeff_eq_zero] at H exact hp0 H have h1 : p.degree = (q * Polynomial.X ^ (k - q.natDegree)).degree := by rw [Polynomial.degree_mul', Polynomial.degree_X_pow] · rw [Polynomial.degree_eq_natDegree hp0, Polynomial.degree_eq_natDegree hq0] rw [← Nat.cast_add, add_tsub_cancel_of_le, hn] · refine le_trans (Polynomial.natDegree_le_of_degree_le hdq) (le_of_lt h) rw [Polynomial.leadingCoeff_X_pow, mul_one] exact mt Polynomial.leadingCoeff_eq_zero.1 hq0 have h2 : p.leadingCoeff = (q * Polynomial.X ^ (k - q.natDegree)).leadingCoeff := by rw [← hlqp, Polynomial.leadingCoeff_mul_X_pow] have := Polynomial.degree_sub_lt h1 hp0 h2 rw [Polynomial.degree_eq_natDegree hp0] at this rw [← sub_add_cancel p (q * Polynomial.X ^ (k - q.natDegree))] convert (Ideal.span ↑s).add_mem _ ((Ideal.span (s : Set R[X])).mul_mem_right _ _) · by_cases hpq : p - q * Polynomial.X ^ (k - q.natDegree) = 0 · rw [hpq] exact Ideal.zero_mem _ refine ih _ ?_ (I.sub_mem hp (I.mul_mem_right _ hq)) rfl rwa [Polynomial.degree_eq_natDegree hpq, Nat.cast_lt, hn] at this exact hs2 ⟨Polynomial.mem_degreeLE.2 hdq, hq⟩⟩⟩ attribute [instance] Polynomial.isNoetherianRing namespace Polynomial theorem linearIndependent_powers_iff_aeval (f : M →ₗ[R] M) (v : M) : (LinearIndependent R fun n : ℕ => (f ^ n) v) ↔ ∀ p : R[X], aeval f p v = 0 → p = 0 := by rw [linearIndependent_iff] simp only [Finsupp.linearCombination_apply, aeval_endomorphism, forall_iff_forall_finsupp, Sum, support, coeff, ofFinsupp_eq_zero] exact Iff.rfl theorem disjoint_ker_aeval_of_isCoprime (f : M →ₗ[R] M) {p q : R[X]} (hpq : IsCoprime p q) : Disjoint (LinearMap.ker (aeval f p)) (LinearMap.ker (aeval f q)) := by rw [disjoint_iff_inf_le] intro v hv rcases hpq with ⟨p', q', hpq'⟩ simpa [LinearMap.mem_ker.1 (Submodule.mem_inf.1 hv).1, LinearMap.mem_ker.1 (Submodule.mem_inf.1 hv).2] using congr_arg (fun p : R[X] => aeval f p v) hpq'.symm @[deprecated (since := "2025-01-23")] alias disjoint_ker_aeval_of_coprime := disjoint_ker_aeval_of_isCoprime theorem sup_aeval_range_eq_top_of_isCoprime (f : M →ₗ[R] M) {p q : R[X]} (hpq : IsCoprime p q) : LinearMap.range (aeval f p) ⊔ LinearMap.range (aeval f q) = ⊤ := by rw [eq_top_iff] intro v _ rw [Submodule.mem_sup] rcases hpq with ⟨p', q', hpq'⟩ use aeval f (p * p') v use LinearMap.mem_range.2 ⟨aeval f p' v, by simp only [Module.End.mul_apply, aeval_mul]⟩ use aeval f (q * q') v use LinearMap.mem_range.2 ⟨aeval f q' v, by simp only [Module.End.mul_apply, aeval_mul]⟩ simpa only [mul_comm p p', mul_comm q q', aeval_one, aeval_add] using congr_arg (fun p : R[X] => aeval f p v) hpq' @[deprecated (since := "2025-01-23")] alias sup_aeval_range_eq_top_of_coprime := sup_aeval_range_eq_top_of_isCoprime theorem sup_ker_aeval_le_ker_aeval_mul {f : M →ₗ[R] M} {p q : R[X]} : LinearMap.ker (aeval f p) ⊔ LinearMap.ker (aeval f q) ≤ LinearMap.ker (aeval f (p * q)) := by intro v hv rcases Submodule.mem_sup.1 hv with ⟨x, hx, y, hy, hxy⟩ have h_eval_x : aeval f (p * q) x = 0 := by rw [mul_comm, aeval_mul, Module.End.mul_apply, LinearMap.mem_ker.1 hx, LinearMap.map_zero] have h_eval_y : aeval f (p * q) y = 0 := by rw [aeval_mul, Module.End.mul_apply, LinearMap.mem_ker.1 hy, LinearMap.map_zero] rw [LinearMap.mem_ker, ← hxy, LinearMap.map_add, h_eval_x, h_eval_y, add_zero] theorem sup_ker_aeval_eq_ker_aeval_mul_of_coprime (f : M →ₗ[R] M) {p q : R[X]} (hpq : IsCoprime p q) : LinearMap.ker (aeval f p) ⊔ LinearMap.ker (aeval f q) = LinearMap.ker (aeval f (p * q)) := by apply le_antisymm sup_ker_aeval_le_ker_aeval_mul intro v hv rw [Submodule.mem_sup] rcases hpq with ⟨p', q', hpq'⟩ have h_eval₂_qpp' := calc aeval f (q * (p * p')) v = aeval f (p' * (p * q)) v := by rw [mul_comm, mul_assoc, mul_comm, mul_assoc, mul_comm q p] _ = 0 := by rw [aeval_mul, Module.End.mul_apply, LinearMap.mem_ker.1 hv, LinearMap.map_zero] have h_eval₂_pqq' := calc aeval f (p * (q * q')) v = aeval f (q' * (p * q)) v := by rw [← mul_assoc, mul_comm] _ = 0 := by rw [aeval_mul, Module.End.mul_apply, LinearMap.mem_ker.1 hv, LinearMap.map_zero] rw [aeval_mul] at h_eval₂_qpp' h_eval₂_pqq' refine ⟨aeval f (q * q') v, LinearMap.mem_ker.1 h_eval₂_pqq', aeval f (p * p') v, LinearMap.mem_ker.1 h_eval₂_qpp', ?_⟩ rw [add_comm, mul_comm p p', mul_comm q q'] simpa only [map_add, map_mul, aeval_one] using congr_arg (fun p : R[X] => aeval f p v) hpq' end Polynomial namespace MvPolynomial lemma aeval_natDegree_le {R : Type} [CommSemiring R] {m n : ℕ} (F : MvPolynomial σ R) (hF : F.totalDegree ≤ m) (f : σ → Polynomial R) (hf : ∀ i, (f i).natDegree ≤ n) : (MvPolynomial.aeval f F).natDegree ≤ m n := by rw [MvPolynomial.aeval_def, MvPolynomial.eval₂] apply (Polynomial.natDegree_sum_le _ _).trans apply Finset.sup_le intro d hd simp_rw [Function.comp_apply, ← C_eq_algebraMap] apply (Polynomial.natDegree_C_mul_le _ _).trans apply (Polynomial.natDegree_prod_le _ _).trans have : ∑ i ∈ d.support, (d i) * n ≤ m * n := by rw [← Finset.sum_mul] apply mul_le_mul' (.trans _ hF) le_rfl rw [MvPolynomial.totalDegree] exact Finset.le_sup_of_le hd le_rfl apply (Finset.sum_le_sum _).trans this rintro i - apply Polynomial.natDegree_pow_le.trans exact mul_le_mul' le_rfl (hf i) theorem isNoetherianRing_fin_0 [IsNoetherianRing R] : IsNoetherianRing (MvPolynomial (Fin 0) R) := by apply isNoetherianRing_of_ringEquiv R symm; apply MvPolynomial.isEmptyRingEquiv R (Fin 0) theorem isNoetherianRing_fin [IsNoetherianRing R] : ∀ {n : ℕ}, IsNoetherianRing (MvPolynomial (Fin n) R) \| 0 => isNoetherianRing_fin_0 \| n + 1 => @isNoetherianRing_of_ringEquiv (Polynomial (MvPolynomial (Fin n) R)) _ _ _ (MvPolynomial.finSuccEquiv _ n).toRingEquiv.symm (@Polynomial.isNoetherianRing (MvPolynomial (Fin n) R) _ isNoetherianRing_fin) /-- The multivariate polynomial ring in finitely many variables over a noetherian ring is itself a noetherian ring. -/ instance isNoetherianRing [Finite σ] [IsNoetherianRing R] : IsNoetherianRing (MvPolynomial σ R) := by cases nonempty_fintype σ exact @isNoetherianRing_of_ringEquiv (MvPolynomial (Fin (Fintype.card σ)) R) _ _ _ (renameEquiv R (Fintype.equivFin σ).symm).toRingEquiv isNoetherianRing_fin /-- Auxiliary lemma: Multivariate polynomials over an integral domain with variables indexed by `Fin n` form an integral domain. This fact is proven inductively, and then used to prove the general case without any finiteness hypotheses. See `MvPolynomial.noZeroDivisors` for the general case. -/ theorem noZeroDivisors_fin (R : Type u) [CommSemiring R] [NoZeroDivisors R] : ∀ n : ℕ, NoZeroDivisors (MvPolynomial (Fin n) R) \| 0 => (MvPolynomial.isEmptyAlgEquiv R _).injective.noZeroDivisors _ (map_zero _) (map_mul _) \| n + 1 => haveI := noZeroDivisors_fin R n (MvPolynomial.finSuccEquiv R n).injective.noZeroDivisors _ (map_zero _) (map_mul _) /-- Auxiliary definition: Multivariate polynomials in finitely many variables over an integral domain form an integral domain. This fact is proven by transport of structure from the `MvPolynomial.noZeroDivisors_fin`, and then used to prove the general case without finiteness hypotheses. See `MvPolynomial.noZeroDivisors` for the general case. -/ theorem noZeroDivisors_of_finite (R : Type u) (σ : Type v) [CommSemiring R] [Finite σ] [NoZeroDivisors R] : NoZeroDivisors (MvPolynomial σ R) := by cases nonempty_fintype σ haveI := noZeroDivisors_fin R (Fintype.card σ) exact (renameEquiv R (Fintype.equivFin σ)).injective.noZeroDivisors _ (map_zero _) (map_mul _) instance {R : Type u} [CommSemiring R] [NoZeroDivisors R] {σ : Type v} : NoZeroDivisors (MvPolynomial σ R) where eq_zero_or_eq_zero_of_mul_eq_zero {p q} h := by obtain ⟨s, p, q, rfl, rfl⟩ := exists_finset_rename₂ p q let _nzd := MvPolynomial.noZeroDivisors_of_finite R s have : p * q = 0 := by apply rename_injective _ Subtype.val_injective simpa using h rw [mul_eq_zero] at this apply this.imp <;> rintro rfl <;> simp /-- The multivariate polynomial ring over an integral domain is an integral domain. -/ instance isDomain {R : Type u} {σ : Type v} [CommRing R] [IsDomain R] : IsDomain (MvPolynomial σ R) := by apply @NoZeroDivisors.to_isDomain (MvPolynomial σ R) _ ?_ _ apply AddMonoidAlgebra.nontrivial -- instance {R : Type u} {σ : Type v} [CommRing R] [IsDomain R] : -- IsDomain (MvPolynomial σ R)[X] := inferInstance theorem map_mvPolynomial_eq_eval₂ {S : Type} [CommSemiring S] [Finite σ] (ϕ : MvPolynomial σ R →+ S) (p : MvPolynomial σ R) : ϕ p = MvPolynomial.eval₂ (ϕ.comp MvPolynomial.C) (fun s => ϕ (MvPolynomial.X s)) p := by cases nonempty_fintype σ refine Trans.trans (congr_arg ϕ (MvPolynomial.as_sum p)) ?_ rw [MvPolynomial.eval₂_eq', map_sum ϕ] congr ext simp only [monomial_eq, ϕ.map_pow, map_prod ϕ, ϕ.comp_apply, ϕ.map_mul, Finsupp.prod_pow] /-- If every coefficient of a polynomial is in an ideal `I`, then so is the polynomial itself, multivariate version. -/ theorem mem_ideal_of_coeff_mem_ideal (I : Ideal (MvPolynomial σ R)) (p : MvPolynomial σ R) (hcoe : ∀ m : σ →₀ ℕ, p.coeff m ∈ I.comap (C : R →+* MvPolynomial σ R)) : p ∈ I := by rw [as_sum p] suffices ∀ m ∈ p.support, monomial m (MvPolynomial.coeff m p) ∈ I by exact Submodule.sum_mem I this intro m _ rw [← mul_one (coeff m p), ← C_mul_monomial] suffices C (coeff m p) ∈ I by exact I.mul_mem_right (monomial m 1) this simpa [Ideal.mem_comap] using hcoe m /-- The push-forward of an ideal `I` of `R` to `MvPolynomial σ R` via inclusion is exactly the set of polynomials whose coefficients are in `I` -/ theorem mem_map_C_iff {I : Ideal R} {f : MvPolynomial σ R} : f ∈ (Ideal.map (C : R →+* MvPolynomial σ R) I : Ideal (MvPolynomial σ R)) ↔ ∀ m : σ →₀ ℕ, f.coeff m ∈ I := by classical constructor · intro hf refine Submodule.span_induction ?_ ?_ ?_ ?_ hf · intro f hf n obtain ⟨x, hx⟩ := (Set.mem_image _ _ _).mp hf rw [← hx.right, coeff_C] by_cases h : n = 0 · simpa [h] using hx.left · simp [Ne.symm h] · simp · exact fun f g _ _ hf hg n => by simp [I.add_mem (hf n) (hg n)] · refine fun f g _ hg n => ?_ rw [smul_eq_mul, coeff_mul] exact I.sum_mem fun c _ => I.mul_mem_left (f.coeff c.fst) (hg c.snd) · intro hf rw [as_sum f] suffices ∀ m ∈ f.support, monomial m (coeff m f) ∈ (Ideal.map C I : Ideal (MvPolynomial σ R)) by exact Submodule.sum_mem _ this intro m _ rw [← mul_one (coeff m f), ← C_mul_monomial] suffices C (coeff m f) ∈ (Ideal.map C I : Ideal (MvPolynomial σ R)) by exact Ideal.mul_mem_right _ _ this apply Ideal.mem_map_of_mem _ exact hf m theorem ker_map (f : R →+* S) : RingHom.ker (map f : MvPolynomial σ R →+* MvPolynomial σ S) = Ideal.map (C : R →+* MvPolynomial σ R) (RingHom.ker f) := by ext rw [MvPolynomial.mem_map_C_iff, RingHom.mem_ker, MvPolynomial.ext_iff] simp_rw [coeff_map, coeff_zero, RingHom.mem_ker] lemma ker_mapAlgHom {S₁ S₂ σ : Type} [CommRing S₁] [CommRing S₂] [Algebra R S₁] [Algebra R S₂] (f : S₁ →ₐ[R] S₂) : RingHom.ker (MvPolynomial.mapAlgHom (σ := σ) f) = Ideal.map MvPolynomial.C (RingHom.ker f) := MvPolynomial.ker_map (f.toRingHom : S₁ →+ S₂) end MvPolynomial		Mathlib/RingTheory/Polynomial/Basic.lean	1,191	1,195
/- Copyright (c) 2020 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.Algebra.Star.SelfAdjoint import Mathlib.LinearAlgebra.Dimension.StrongRankCondition import Mathlib.LinearAlgebra.FreeModule.Finite.Basic /-! # Quaternions In this file we define quaternions `ℍ[R]` over a commutative ring `R`, and define some algebraic structures on `ℍ[R]`. ## Main definitions * `QuaternionAlgebra R a b c`, `ℍ[R, a, b, c]` : [Bourbaki, Algebra I][bourbaki1989] with coefficients `a`, `b`, `c` (Many other references such as Wikipedia assume $\operatorname{char} R ≠ 2$ therefore one can complete the square and WLOG assume $b = 0$.) * `Quaternion R`, `ℍ[R]` : the space of quaternions, a.k.a. `QuaternionAlgebra R (-1) (0) (-1)`; * `Quaternion.normSq` : square of the norm of a quaternion; We also define the following algebraic structures on `ℍ[R]`: * `Ring ℍ[R, a, b, c]`, `StarRing ℍ[R, a, b, c]`, and `Algebra R ℍ[R, a, b, c]` : for any commutative ring `R`; * `Ring ℍ[R]`, `StarRing ℍ[R]`, and `Algebra R ℍ[R]` : for any commutative ring `R`; * `IsDomain ℍ[R]` : for a linear ordered commutative ring `R`; * `DivisionRing ℍ[R]` : for a linear ordered field `R`. ## Notation The following notation is available with `open Quaternion` or `open scoped Quaternion`. * `ℍ[R, c₁, c₂, c₃]` : `QuaternionAlgebra R c₁ c₂ c₃` * `ℍ[R, c₁, c₂]` : `QuaternionAlgebra R c₁ 0 c₂` * `ℍ[R]` : quaternions over `R`. ## Implementation notes We define quaternions over any ring `R`, not just `ℝ` to be able to deal with, e.g., integer or rational quaternions without using real numbers. In particular, all definitions in this file are computable. ## Tags quaternion -/ /-- Quaternion algebra over a type with fixed coefficients where $i^2 = a + bi$ and $j^2 = c$, denoted as `ℍ[R,a,b]`. Implemented as a structure with four fields: `re`, `imI`, `imJ`, and `imK`. -/ @[ext] structure QuaternionAlgebra (R : Type) (a b c : R) where /-- Real part of a quaternion. -/ re : R /-- First imaginary part (i) of a quaternion. -/ imI : R /-- Second imaginary part (j) of a quaternion. -/ imJ : R /-- Third imaginary part (k) of a quaternion. -/ imK : R @[inherit_doc] scoped[Quaternion] notation "ℍ[" R "," a "," b "," c "]" => QuaternionAlgebra R a b c @[inherit_doc] scoped[Quaternion] notation "ℍ[" R "," a "," b "]" => QuaternionAlgebra R a 0 b namespace QuaternionAlgebra open Quaternion /-- The equivalence between a quaternion algebra over `R` and `R × R × R × R`. -/ @[simps] def equivProd {R : Type} (c₁ c₂ c₃ : R) : ℍ[R,c₁,c₂,c₃] ≃ R × R × R × R where toFun a := ⟨a.1, a.2, a.3, a.4⟩ invFun a := ⟨a.1, a.2.1, a.2.2.1, a.2.2.2⟩ left_inv _ := rfl right_inv _ := rfl /-- The equivalence between a quaternion algebra over `R` and `Fin 4 → R`. -/ @[simps symm_apply] def equivTuple {R : Type} (c₁ c₂ c₃ : R) : ℍ[R,c₁,c₂,c₃] ≃ (Fin 4 → R) where toFun a := ![a.1, a.2, a.3, a.4] invFun a := ⟨a 0, a 1, a 2, a 3⟩ left_inv _ := rfl right_inv f := by ext ⟨_, _ \| _ \| _ \| _ \| _ \| ⟨⟩⟩ <;> rfl @[simp] theorem equivTuple_apply {R : Type} (c₁ c₂ c₃ : R) (x : ℍ[R,c₁,c₂,c₃]) : equivTuple c₁ c₂ c₃ x = ![x.re, x.imI, x.imJ, x.imK] := rfl @[simp] theorem mk.eta {R : Type} {c₁ c₂ c₃} (a : ℍ[R,c₁,c₂,c₃]) : mk a.1 a.2 a.3 a.4 = a := rfl variable {S T R : Type} {c₁ c₂ c₃ : R} (r x y : R) (a b : ℍ[R,c₁,c₂,c₃]) instance [Subsingleton R] : Subsingleton ℍ[R, c₁, c₂, c₃] := (equivTuple c₁ c₂ c₃).subsingleton instance [Nontrivial R] : Nontrivial ℍ[R, c₁, c₂, c₃] := (equivTuple c₁ c₂ c₃).surjective.nontrivial section Zero variable [Zero R] /-- The imaginary part of a quaternion. Note that unless `c₂ = 0`, this definition is not particularly well-behaved; for instance, `QuaternionAlgebra.star_im` only says that the star of an imaginary quaternion is imaginary under this condition. -/ def im (x : ℍ[R,c₁,c₂,c₃]) : ℍ[R,c₁,c₂,c₃] := ⟨0, x.imI, x.imJ, x.imK⟩ @[simp] theorem im_re : a.im.re = 0 := rfl @[simp] theorem im_imI : a.im.imI = a.imI := rfl @[simp] theorem im_imJ : a.im.imJ = a.imJ := rfl @[simp] theorem im_imK : a.im.imK = a.imK := rfl @[simp] theorem im_idem : a.im.im = a.im := rfl /-- Coercion `R → ℍ[R,c₁,c₂,c₃]`. -/ @[coe] def coe (x : R) : ℍ[R,c₁,c₂,c₃] := ⟨x, 0, 0, 0⟩ instance : CoeTC R ℍ[R,c₁,c₂,c₃] := ⟨coe⟩ @[simp, norm_cast] theorem coe_re : (x : ℍ[R,c₁,c₂,c₃]).re = x := rfl @[simp, norm_cast] theorem coe_imI : (x : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[simp, norm_cast] theorem coe_imJ : (x : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[simp, norm_cast] theorem coe_imK : (x : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl theorem coe_injective : Function.Injective (coe : R → ℍ[R,c₁,c₂,c₃]) := fun _ _ h => congr_arg re h @[simp] theorem coe_inj {x y : R} : (x : ℍ[R,c₁,c₂,c₃]) = y ↔ x = y := coe_injective.eq_iff -- Porting note: removed `simps`, added simp lemmas manually. -- Should adjust `simps` to name properly, i.e. as `zero_re` rather than `instZero_zero_re`. instance : Zero ℍ[R,c₁,c₂,c₃] := ⟨⟨0, 0, 0, 0⟩⟩ @[scoped simp] theorem zero_re : (0 : ℍ[R,c₁,c₂,c₃]).re = 0 := rfl @[scoped simp] theorem zero_imI : (0 : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[scoped simp] theorem zero_imJ : (0 : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[scoped simp] theorem zero_imK : (0 : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[scoped simp] theorem zero_im : (0 : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp, norm_cast] theorem coe_zero : ((0 : R) : ℍ[R,c₁,c₂,c₃]) = 0 := rfl instance : Inhabited ℍ[R,c₁,c₂,c₃] := ⟨0⟩ section One variable [One R] -- Porting note: removed `simps`, added simp lemmas manually. Should adjust `simps` to name properly instance : One ℍ[R,c₁,c₂,c₃] := ⟨⟨1, 0, 0, 0⟩⟩ @[scoped simp] theorem one_re : (1 : ℍ[R,c₁,c₂,c₃]).re = 1 := rfl @[scoped simp] theorem one_imI : (1 : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[scoped simp] theorem one_imJ : (1 : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[scoped simp] theorem one_imK : (1 : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[scoped simp] theorem one_im : (1 : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp, norm_cast] theorem coe_one : ((1 : R) : ℍ[R,c₁,c₂,c₃]) = 1 := rfl end One end Zero section Add variable [Add R] -- Porting note: removed `simps`, added simp lemmas manually. Should adjust `simps` to name properly instance : Add ℍ[R,c₁,c₂,c₃] := ⟨fun a b => ⟨a.1 + b.1, a.2 + b.2, a.3 + b.3, a.4 + b.4⟩⟩ @[simp] theorem add_re : (a + b).re = a.re + b.re := rfl @[simp] theorem add_imI : (a + b).imI = a.imI + b.imI := rfl @[simp] theorem add_imJ : (a + b).imJ = a.imJ + b.imJ := rfl @[simp] theorem add_imK : (a + b).imK = a.imK + b.imK := rfl @[simp] theorem mk_add_mk (a₁ a₂ a₃ a₄ b₁ b₂ b₃ b₄ : R) : (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) + mk b₁ b₂ b₃ b₄ = mk (a₁ + b₁) (a₂ + b₂) (a₃ + b₃) (a₄ + b₄) := rfl end Add section AddZeroClass variable [AddZeroClass R] @[simp] theorem add_im : (a + b).im = a.im + b.im := QuaternionAlgebra.ext (zero_add _).symm rfl rfl rfl @[simp, norm_cast] theorem coe_add : ((x + y : R) : ℍ[R,c₁,c₂,c₃]) = x + y := by ext <;> simp end AddZeroClass section Neg variable [Neg R] -- Porting note: removed `simps`, added simp lemmas manually. Should adjust `simps` to name properly instance : Neg ℍ[R,c₁,c₂,c₃] := ⟨fun a => ⟨-a.1, -a.2, -a.3, -a.4⟩⟩ @[simp] theorem neg_re : (-a).re = -a.re := rfl @[simp] theorem neg_imI : (-a).imI = -a.imI := rfl @[simp] theorem neg_imJ : (-a).imJ = -a.imJ := rfl @[simp] theorem neg_imK : (-a).imK = -a.imK := rfl @[simp] theorem neg_mk (a₁ a₂ a₃ a₄ : R) : -(mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) = ⟨-a₁, -a₂, -a₃, -a₄⟩ := rfl end Neg section AddGroup variable [AddGroup R] @[simp] theorem neg_im : (-a).im = -a.im := QuaternionAlgebra.ext neg_zero.symm rfl rfl rfl @[simp, norm_cast] theorem coe_neg : ((-x : R) : ℍ[R,c₁,c₂,c₃]) = -x := by ext <;> simp instance : Sub ℍ[R,c₁,c₂,c₃] := ⟨fun a b => ⟨a.1 - b.1, a.2 - b.2, a.3 - b.3, a.4 - b.4⟩⟩ @[simp] theorem sub_re : (a - b).re = a.re - b.re := rfl @[simp] theorem sub_imI : (a - b).imI = a.imI - b.imI := rfl @[simp] theorem sub_imJ : (a - b).imJ = a.imJ - b.imJ := rfl @[simp] theorem sub_imK : (a - b).imK = a.imK - b.imK := rfl @[simp] theorem sub_im : (a - b).im = a.im - b.im := QuaternionAlgebra.ext (sub_zero _).symm rfl rfl rfl @[simp] theorem mk_sub_mk (a₁ a₂ a₃ a₄ b₁ b₂ b₃ b₄ : R) : (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) - mk b₁ b₂ b₃ b₄ = mk (a₁ - b₁) (a₂ - b₂) (a₃ - b₃) (a₄ - b₄) := rfl @[simp, norm_cast] theorem coe_im : (x : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp] theorem re_add_im : ↑a.re + a.im = a := QuaternionAlgebra.ext (add_zero _) (zero_add _) (zero_add _) (zero_add _) @[simp] theorem sub_self_im : a - a.im = a.re := QuaternionAlgebra.ext (sub_zero _) (sub_self _) (sub_self _) (sub_self _) @[simp] theorem sub_self_re : a - a.re = a.im := QuaternionAlgebra.ext (sub_self _) (sub_zero _) (sub_zero _) (sub_zero _) end AddGroup section Ring variable [Ring R] /-- Multiplication is given by * `1 * x = x * 1 = x`; * `i * i = c₁ + c₂ * i`; * `j * j = c₃`; * `i * j = k`, `j * i = c₂ * j - k`; * `k * k = - c₁ * c₃`; * `i * k = c₁ * j + c₂ * k`, `k * i = -c₁ * j`; * `j * k = c₂ * c₃ - c₃ * i`, `k * j = c₃ * i`. -/ instance : Mul ℍ[R,c₁,c₂,c₃] := ⟨fun a b => ⟨a.1 * b.1 + c₁ * a.2 * b.2 + c₃ * a.3 * b.3 + c₂ * c₃ * a.3 * b.4 - c₁ * c₃ * a.4 * b.4, a.1 * b.2 + a.2 * b.1 + c₂ * a.2 * b.2 - c₃ * a.3 * b.4 + c₃ * a.4 * b.3, a.1 * b.3 + c₁ * a.2 * b.4 + a.3 * b.1 + c₂ * a.3 * b.2 - c₁ * a.4 * b.2, a.1 * b.4 + a.2 * b.3 + c₂ * a.2 * b.4 - a.3 * b.2 + a.4 * b.1⟩⟩ @[simp] theorem mul_re : (a * b).re = a.1 * b.1 + c₁ * a.2 * b.2 + c₃ * a.3 * b.3 + c₂ * c₃ * a.3 * b.4 - c₁ * c₃ * a.4 * b.4 := rfl @[simp] theorem mul_imI : (a * b).imI = a.1 * b.2 + a.2 * b.1 + c₂ * a.2 * b.2 - c₃ * a.3 * b.4 + c₃ * a.4 * b.3 := rfl @[simp] theorem mul_imJ : (a * b).imJ = a.1 * b.3 + c₁ * a.2 * b.4 + a.3 * b.1 + c₂ * a.3 * b.2 - c₁ * a.4 * b.2 := rfl @[simp] theorem mul_imK : (a * b).imK = a.1 * b.4 + a.2 * b.3 + c₂ * a.2 * b.4 - a.3 * b.2 + a.4 * b.1 := rfl @[simp] theorem mk_mul_mk (a₁ a₂ a₃ a₄ b₁ b₂ b₃ b₄ : R) : (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) * mk b₁ b₂ b₃ b₄ = mk (a₁ * b₁ + c₁ * a₂ * b₂ + c₃ * a₃ * b₃ + c₂ * c₃ * a₃ * b₄ - c₁ * c₃ * a₄ * b₄) (a₁ * b₂ + a₂ * b₁ + c₂ * a₂ * b₂ - c₃ * a₃ * b₄ + c₃ * a₄ * b₃) (a₁ * b₃ + c₁ * a₂ * b₄ + a₃ * b₁ + c₂ * a₃ * b₂ - c₁ * a₄ * b₂) (a₁ * b₄ + a₂ * b₃ + c₂ * a₂ * b₄ - a₃ * b₂ + a₄ * b₁) := rfl end Ring section SMul variable [SMul S R] [SMul T R] (s : S) instance : SMul S ℍ[R,c₁,c₂,c₃] where smul s a := ⟨s • a.1, s • a.2, s • a.3, s • a.4⟩ instance [SMul S T] [IsScalarTower S T R] : IsScalarTower S T ℍ[R,c₁,c₂,c₃] where smul_assoc s t x := by ext <;> exact smul_assoc _ _ _ instance [SMulCommClass S T R] : SMulCommClass S T ℍ[R,c₁,c₂,c₃] where smul_comm s t x := by ext <;> exact smul_comm _ _ _ @[simp] theorem smul_re : (s • a).re = s • a.re := rfl @[simp] theorem smul_imI : (s • a).imI = s • a.imI := rfl @[simp] theorem smul_imJ : (s • a).imJ = s • a.imJ := rfl @[simp] theorem smul_imK : (s • a).imK = s • a.imK := rfl @[simp] theorem smul_im {S} [CommRing R] [SMulZeroClass S R] (s : S) : (s • a).im = s • a.im := QuaternionAlgebra.ext (smul_zero s).symm rfl rfl rfl @[simp] theorem smul_mk (re im_i im_j im_k : R) : s • (⟨re, im_i, im_j, im_k⟩ : ℍ[R,c₁,c₂,c₃]) = ⟨s • re, s • im_i, s • im_j, s • im_k⟩ := rfl end SMul @[simp, norm_cast] theorem coe_smul [Zero R] [SMulZeroClass S R] (s : S) (r : R) : (↑(s • r) : ℍ[R,c₁,c₂,c₃]) = s • (r : ℍ[R,c₁,c₂,c₃]) := QuaternionAlgebra.ext rfl (smul_zero _).symm (smul_zero _).symm (smul_zero _).symm instance [AddCommGroup R] : AddCommGroup ℍ[R,c₁,c₂,c₃] := (equivProd c₁ c₂ c₃).injective.addCommGroup _ rfl (fun _ _ ↦ rfl) (fun _ ↦ rfl) (fun _ _ ↦ rfl) (fun _ _ ↦ rfl) (fun _ _ ↦ rfl) section AddCommGroupWithOne variable [AddCommGroupWithOne R] instance : AddCommGroupWithOne ℍ[R,c₁,c₂,c₃] where natCast n := ((n : R) : ℍ[R,c₁,c₂,c₃]) natCast_zero := by simp natCast_succ := by simp intCast n := ((n : R) : ℍ[R,c₁,c₂,c₃]) intCast_ofNat _ := congr_arg coe (Int.cast_natCast _) intCast_negSucc n := by change coe _ = -coe _ rw [Int.cast_negSucc, coe_neg] @[simp, norm_cast] theorem natCast_re (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).re = n := rfl @[simp, norm_cast] theorem natCast_imI (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[simp, norm_cast] theorem natCast_imJ (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[simp, norm_cast] theorem natCast_imK (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[simp, norm_cast] theorem natCast_im (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[norm_cast] theorem coe_natCast (n : ℕ) : ↑(n : R) = (n : ℍ[R,c₁,c₂,c₃]) := rfl @[simp, norm_cast] theorem intCast_re (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).re = z := rfl @[scoped simp] theorem ofNat_re (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).re = ofNat(n) := rfl @[scoped simp] theorem ofNat_imI (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[scoped simp] theorem ofNat_imJ (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[scoped simp] theorem ofNat_imK (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[scoped simp] theorem ofNat_im (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp, norm_cast] theorem intCast_imI (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[simp, norm_cast] theorem intCast_imJ (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[simp, norm_cast] theorem intCast_imK (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[simp, norm_cast] theorem intCast_im (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[norm_cast] theorem coe_intCast (z : ℤ) : ↑(z : R) = (z : ℍ[R,c₁,c₂,c₃]) := rfl end AddCommGroupWithOne -- For the remainder of the file we assume `CommRing R`. variable [CommRing R] instance instRing : Ring ℍ[R,c₁,c₂,c₃] where __ := inferInstanceAs (AddCommGroupWithOne ℍ[R,c₁,c₂,c₃]) left_distrib _ _ _ := by ext <;> simp <;> ring right_distrib _ _ _ := by ext <;> simp <;> ring zero_mul _ := by ext <;> simp mul_zero _ := by ext <;> simp mul_assoc _ _ _ := by ext <;> simp <;> ring one_mul _ := by ext <;> simp mul_one _ := by ext <;> simp @[norm_cast, simp] theorem coe_mul : ((x * y : R) : ℍ[R,c₁,c₂,c₃]) = x * y := by ext <;> simp @[norm_cast, simp] lemma coe_ofNat {n : ℕ} [n.AtLeastTwo]: ((ofNat(n) : R) : ℍ[R,c₁,c₂,c₃]) = (ofNat(n) : ℍ[R,c₁,c₂,c₃]) := by rfl -- TODO: add weaker `MulAction`, `DistribMulAction`, and `Module` instances (and repeat them -- for `ℍ[R]`) instance [CommSemiring S] [Algebra S R] : Algebra S ℍ[R,c₁,c₂,c₃] where smul := (· • ·) algebraMap := { toFun s := coe (algebraMap S R s) map_one' := by simp only [map_one, coe_one] map_zero' := by simp only [map_zero, coe_zero] map_mul' x y := by simp only [map_mul, coe_mul] map_add' x y := by simp only [map_add, coe_add] } smul_def' s x := by ext <;> simp [Algebra.smul_def] commutes' s x := by ext <;> simp [Algebra.commutes] theorem algebraMap_eq (r : R) : algebraMap R ℍ[R,c₁,c₂,c₃] r = ⟨r, 0, 0, 0⟩ := rfl theorem algebraMap_injective : (algebraMap R ℍ[R,c₁,c₂,c₃] : _ → _).Injective := fun _ _ ↦ by simp [algebraMap_eq] instance [NoZeroDivisors R] : NoZeroSMulDivisors R ℍ[R,c₁,c₂,c₃] := ⟨by rintro t ⟨a, b, c, d⟩ h rw [or_iff_not_imp_left] intro ht simpa [QuaternionAlgebra.ext_iff, ht] using h⟩ section variable (c₁ c₂ c₃) /-- `QuaternionAlgebra.re` as a `LinearMap` -/ @[simps] def reₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := re map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.imI` as a `LinearMap` -/ @[simps] def imIₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := imI map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.imJ` as a `LinearMap` -/ @[simps] def imJₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := imJ map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.imK` as a `LinearMap` -/ @[simps] def imKₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := imK map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.equivTuple` as a linear equivalence. -/ def linearEquivTuple : ℍ[R,c₁,c₂,c₃] ≃ₗ[R] Fin 4 → R := LinearEquiv.symm -- proofs are not `rfl` in the forward direction { (equivTuple c₁ c₂ c₃).symm with toFun := (equivTuple c₁ c₂ c₃).symm invFun := equivTuple c₁ c₂ c₃ map_add' := fun _ _ => rfl map_smul' := fun _ _ => rfl } @[simp] theorem coe_linearEquivTuple : ⇑(linearEquivTuple c₁ c₂ c₃) = equivTuple c₁ c₂ c₃ := rfl @[simp] theorem coe_linearEquivTuple_symm : ⇑(linearEquivTuple c₁ c₂ c₃).symm = (equivTuple c₁ c₂ c₃).symm := rfl /-- `ℍ[R, c₁, c₂, c₃]` has a basis over `R` given by `1`, `i`, `j`, and `k`. -/ noncomputable def basisOneIJK : Basis (Fin 4) R ℍ[R,c₁,c₂,c₃] := .ofEquivFun <\| linearEquivTuple c₁ c₂ c₃ @[simp] theorem coe_basisOneIJK_repr (q : ℍ[R,c₁,c₂,c₃]) : ((basisOneIJK c₁ c₂ c₃).repr q) = ![q.re, q.imI, q.imJ, q.imK] := rfl instance : Module.Finite R ℍ[R,c₁,c₂,c₃] := .of_basis (basisOneIJK c₁ c₂ c₃) instance : Module.Free R ℍ[R,c₁,c₂,c₃] := .of_basis (basisOneIJK c₁ c₂ c₃) theorem rank_eq_four [StrongRankCondition R] : Module.rank R ℍ[R,c₁,c₂,c₃] = 4 := by rw [rank_eq_card_basis (basisOneIJK c₁ c₂ c₃), Fintype.card_fin] norm_num theorem finrank_eq_four [StrongRankCondition R] : Module.finrank R ℍ[R,c₁,c₂,c₃] = 4 := by rw [Module.finrank, rank_eq_four, Cardinal.toNat_ofNat] /-- There is a natural equivalence when swapping the first and third coefficients of a quaternion algebra if `c₂` is 0. -/ @[simps] def swapEquiv : ℍ[R,c₁,0,c₃] ≃ₐ[R] ℍ[R,c₃,0,c₁] where toFun t := ⟨t.1, t.3, t.2, -t.4⟩ invFun t := ⟨t.1, t.3, t.2, -t.4⟩ left_inv _ := by simp right_inv _ := by simp map_mul' _ _ := by ext <;> simp <;> ring map_add' _ _ := by ext <;> simp [add_comm] commutes' _ := by simp [algebraMap_eq] end @[norm_cast, simp] theorem coe_sub : ((x - y : R) : ℍ[R,c₁,c₂,c₃]) = x - y := (algebraMap R ℍ[R,c₁,c₂,c₃]).map_sub x y @[norm_cast, simp] theorem coe_pow (n : ℕ) : (↑(x ^ n) : ℍ[R,c₁,c₂,c₃]) = (x : ℍ[R,c₁,c₂,c₃]) ^ n := (algebraMap R ℍ[R,c₁,c₂,c₃]).map_pow x n theorem coe_commutes : ↑r * a = a * r := Algebra.commutes r a theorem coe_commute : Commute (↑r) a := coe_commutes r a theorem coe_mul_eq_smul : ↑r * a = r • a := (Algebra.smul_def r a).symm theorem mul_coe_eq_smul : a * r = r • a := by rw [← coe_commutes, coe_mul_eq_smul] @[norm_cast, simp] theorem coe_algebraMap : ⇑(algebraMap R ℍ[R,c₁,c₂,c₃]) = coe := rfl theorem smul_coe : x • (y : ℍ[R,c₁,c₂,c₃]) = ↑(x * y) := by rw [coe_mul, coe_mul_eq_smul] /-- Quaternion conjugate. -/ instance instStarQuaternionAlgebra : Star ℍ[R,c₁,c₂,c₃] where star a := ⟨a.1 + c₂ * a.2, -a.2, -a.3, -a.4⟩ @[simp] theorem re_star : (star a).re = a.re + c₂ * a.imI := rfl @[simp] theorem imI_star : (star a).imI = -a.imI := rfl @[simp] theorem imJ_star : (star a).imJ = -a.imJ := rfl @[simp] theorem imK_star : (star a).imK = -a.imK := rfl @[simp] theorem im_star : (star a).im = -a.im := QuaternionAlgebra.ext neg_zero.symm rfl rfl rfl @[simp] theorem star_mk (a₁ a₂ a₃ a₄ : R) : star (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) = ⟨a₁ + c₂ * a₂, -a₂, -a₃, -a₄⟩ := rfl instance instStarRing : StarRing ℍ[R,c₁,c₂,c₃] where star_involutive x := by simp [Star.star] star_add a b := by ext <;> simp [add_comm] ; ring star_mul a b := by ext <;> simp <;> ring theorem self_add_star' : a + star a = ↑(2 * a.re + c₂ * a.imI) := by ext <;> simp [two_mul]; ring theorem self_add_star : a + star a = 2 * a.re + c₂ * a.imI := by simp [self_add_star'] theorem star_add_self' : star a + a = ↑(2 * a.re + c₂ * a.imI) := by rw [add_comm, self_add_star'] theorem star_add_self : star a + a = 2 * a.re + c₂ * a.imI := by rw [add_comm, self_add_star] theorem star_eq_two_re_sub : star a = ↑(2 * a.re + c₂ * a.imI) - a := eq_sub_iff_add_eq.2 a.star_add_self' lemma comm (r : R) (x : ℍ[R, c₁, c₂, c₃]) : r * x = x * r := by ext <;> simp [mul_comm] instance : IsStarNormal a := ⟨by rw [commute_iff_eq, a.star_eq_two_re_sub]; ext <;> simp <;> ring⟩ @[simp, norm_cast] theorem star_coe : star (x : ℍ[R,c₁,c₂,c₃]) = x := by ext <;> simp @[simp] theorem star_im : star a.im = -a.im + c₂ * a.imI := by ext <;> simp @[simp] theorem star_smul [Monoid S] [DistribMulAction S R] [SMulCommClass S R R] (s : S) (a : ℍ[R,c₁,c₂,c₃]) : star (s • a) = s • star a := QuaternionAlgebra.ext (by simp [mul_smul_comm]) (smul_neg _ _).symm (smul_neg _ _).symm (smul_neg _ _).symm /-- A version of `star_smul` for the special case when `c₂ = 0`, without `SMulCommClass S R R`. -/ theorem star_smul' [Monoid S] [DistribMulAction S R] (s : S) (a : ℍ[R,c₁,0,c₃]) : star (s • a) = s • star a := QuaternionAlgebra.ext (by simp) (smul_neg _ _).symm (smul_neg _ _).symm (smul_neg _ _).symm theorem eq_re_of_eq_coe {a : ℍ[R,c₁,c₂,c₃]} {x : R} (h : a = x) : a = a.re := by rw [h, coe_re] theorem eq_re_iff_mem_range_coe {a : ℍ[R,c₁,c₂,c₃]} : a = a.re ↔ a ∈ Set.range (coe : R → ℍ[R,c₁,c₂,c₃]) := ⟨fun h => ⟨a.re, h.symm⟩, fun ⟨_, h⟩ => eq_re_of_eq_coe h.symm⟩ section CharZero variable [NoZeroDivisors R] [CharZero R] @[simp] theorem star_eq_self {c₁ c₂ : R} {a : ℍ[R,c₁,c₂,c₃]} : star a = a ↔ a = a.re := by simp_all [QuaternionAlgebra.ext_iff, neg_eq_iff_add_eq_zero, add_self_eq_zero] theorem star_eq_neg {c₁ : R} {a : ℍ[R,c₁,0,c₃]} : star a = -a ↔ a.re = 0 := by simp [QuaternionAlgebra.ext_iff, eq_neg_iff_add_eq_zero] end CharZero -- Can't use `rw ← star_eq_self` in the proof without additional assumptions theorem star_mul_eq_coe : star a * a = (star a * a).re := by ext <;> simp <;> ring theorem mul_star_eq_coe : a * star a = (a * star a).re := by rw [← star_comm_self'] exact a.star_mul_eq_coe open MulOpposite /-- Quaternion conjugate as an `AlgEquiv` to the opposite ring. -/ def starAe : ℍ[R,c₁,c₂,c₃] ≃ₐ[R] ℍ[R,c₁,c₂,c₃]ᵐᵒᵖ := { starAddEquiv.trans opAddEquiv with toFun := op ∘ star invFun := star ∘ unop map_mul' := fun x y => by simp commutes' := fun r => by simp } @[simp] theorem coe_starAe : ⇑(starAe : ℍ[R,c₁,c₂,c₃] ≃ₐ[R] _) = op ∘ star := rfl end QuaternionAlgebra /-- Space of quaternions over a type, denoted as `ℍ[R]`. Implemented as a structure with four fields: `re`, `im_i`, `im_j`, and `im_k`. -/ def Quaternion (R : Type) [Zero R] [One R] [Neg R] := QuaternionAlgebra R (-1) (0) (-1) @[inherit_doc] scoped[Quaternion] notation "ℍ[" R "]" => Quaternion R open Quaternion /-- The equivalence between the quaternions over `R` and `R × R × R × R`. -/ @[simps!] def Quaternion.equivProd (R : Type) [Zero R] [One R] [Neg R] : ℍ[R] ≃ R × R × R × R := QuaternionAlgebra.equivProd _ _ _ /-- The equivalence between the quaternions over `R` and `Fin 4 → R`. -/ @[simps! symm_apply] def Quaternion.equivTuple (R : Type) [Zero R] [One R] [Neg R] : ℍ[R] ≃ (Fin 4 → R) := QuaternionAlgebra.equivTuple _ _ _ @[simp] theorem Quaternion.equivTuple_apply (R : Type) [Zero R] [One R] [Neg R] (x : ℍ[R]) : Quaternion.equivTuple R x = ![x.re, x.imI, x.imJ, x.imK] := rfl instance {R : Type} [Zero R] [One R] [Neg R] [Subsingleton R] : Subsingleton ℍ[R] := inferInstanceAs (Subsingleton <\| ℍ[R, -1, 0, -1]) instance {R : Type} [Zero R] [One R] [Neg R] [Nontrivial R] : Nontrivial ℍ[R] := inferInstanceAs (Nontrivial <\| ℍ[R, -1, 0, -1]) namespace Quaternion variable {S T R : Type} [CommRing R] (r x y : R) (a b : ℍ[R]) /-- Coercion `R → ℍ[R]`. -/ @[coe] def coe : R → ℍ[R] := QuaternionAlgebra.coe instance : CoeTC R ℍ[R] := ⟨coe⟩ instance instRing : Ring ℍ[R] := QuaternionAlgebra.instRing instance : Inhabited ℍ[R] := inferInstanceAs <\| Inhabited ℍ[R,-1, 0, -1] instance [SMul S R] : SMul S ℍ[R] := inferInstanceAs <\| SMul S ℍ[R,-1, 0, -1] instance [SMul S T] [SMul S R] [SMul T R] [IsScalarTower S T R] : IsScalarTower S T ℍ[R] := inferInstanceAs <\| IsScalarTower S T ℍ[R,-1,0,-1] instance [SMul S R] [SMul T R] [SMulCommClass S T R] : SMulCommClass S T ℍ[R] := inferInstanceAs <\| SMulCommClass S T ℍ[R,-1,0,-1] protected instance algebra [CommSemiring S] [Algebra S R] : Algebra S ℍ[R] := inferInstanceAs <\| Algebra S ℍ[R,-1,0,-1] instance : Star ℍ[R] := QuaternionAlgebra.instStarQuaternionAlgebra instance : StarRing ℍ[R] := QuaternionAlgebra.instStarRing instance : IsStarNormal a := inferInstanceAs <\| IsStarNormal (R := ℍ[R,-1,0,-1]) a @[ext] theorem ext : a.re = b.re → a.imI = b.imI → a.imJ = b.imJ → a.imK = b.imK → a = b := QuaternionAlgebra.ext /-- The imaginary part of a quaternion. -/ nonrec def im (x : ℍ[R]) : ℍ[R] := x.im @[simp] theorem im_re : a.im.re = 0 := rfl @[simp] theorem im_imI : a.im.imI = a.imI := rfl @[simp] theorem im_imJ : a.im.imJ = a.imJ := rfl @[simp] theorem im_imK : a.im.imK = a.imK := rfl @[simp] theorem im_idem : a.im.im = a.im := rfl @[simp] nonrec theorem re_add_im : ↑a.re + a.im = a := a.re_add_im @[simp] nonrec theorem sub_self_im : a - a.im = a.re := a.sub_self_im @[simp] nonrec theorem sub_self_re : a - ↑a.re = a.im := a.sub_self_re @[simp, norm_cast] theorem coe_re : (x : ℍ[R]).re = x := rfl @[simp, norm_cast] theorem coe_imI : (x : ℍ[R]).imI = 0 := rfl @[simp, norm_cast] theorem coe_imJ : (x : ℍ[R]).imJ = 0 := rfl @[simp, norm_cast] theorem coe_imK : (x : ℍ[R]).imK = 0 := rfl @[simp, norm_cast] theorem coe_im : (x : ℍ[R]).im = 0 := rfl @[scoped simp] theorem zero_re : (0 : ℍ[R]).re = 0 := rfl @[scoped simp] theorem zero_imI : (0 : ℍ[R]).imI = 0 := rfl @[scoped simp] theorem zero_imJ : (0 : ℍ[R]).imJ = 0 := rfl @[scoped simp] theorem zero_imK : (0 : ℍ[R]).imK = 0 := rfl @[scoped simp] theorem zero_im : (0 : ℍ[R]).im = 0 := rfl @[simp, norm_cast] theorem coe_zero : ((0 : R) : ℍ[R]) = 0 := rfl @[scoped simp] theorem one_re : (1 : ℍ[R]).re = 1 := rfl @[scoped simp] theorem one_imI : (1 : ℍ[R]).imI = 0 := rfl @[scoped simp] theorem one_imJ : (1 : ℍ[R]).imJ = 0 := rfl @[scoped simp] theorem one_imK : (1 : ℍ[R]).imK = 0 := rfl @[scoped simp] theorem one_im : (1 : ℍ[R]).im = 0 := rfl @[simp, norm_cast] theorem coe_one : ((1 : R) : ℍ[R]) = 1 := rfl @[simp] theorem add_re : (a + b).re = a.re + b.re := rfl @[simp] theorem add_imI : (a + b).imI = a.imI + b.imI := rfl @[simp] theorem add_imJ : (a + b).imJ = a.imJ + b.imJ := rfl @[simp] theorem add_imK : (a + b).imK = a.imK + b.imK := rfl @[simp] nonrec theorem add_im : (a + b).im = a.im + b.im := a.add_im b @[simp, norm_cast] theorem coe_add : ((x + y : R) : ℍ[R]) = x + y := QuaternionAlgebra.coe_add x y @[simp] theorem neg_re : (-a).re = -a.re := rfl @[simp] theorem neg_imI : (-a).imI = -a.imI := rfl @[simp] theorem neg_imJ : (-a).imJ = -a.imJ := rfl @[simp] theorem neg_imK : (-a).imK = -a.imK := rfl @[simp] nonrec theorem neg_im : (-a).im = -a.im := a.neg_im @[simp, norm_cast] theorem coe_neg : ((-x : R) : ℍ[R]) = -x := QuaternionAlgebra.coe_neg x @[simp] theorem sub_re : (a - b).re = a.re - b.re := rfl @[simp] theorem sub_imI : (a - b).imI = a.imI - b.imI := rfl @[simp] theorem sub_imJ : (a - b).imJ = a.imJ - b.imJ := rfl @[simp] theorem sub_imK : (a - b).imK = a.imK - b.imK := rfl @[simp] nonrec theorem sub_im : (a - b).im = a.im - b.im := a.sub_im b @[simp, norm_cast] theorem coe_sub : ((x - y : R) : ℍ[R]) = x - y := QuaternionAlgebra.coe_sub x y @[simp] theorem mul_re : (a b).re = a.re * b.re - a.imI * b.imI - a.imJ * b.imJ - a.imK * b.imK := (QuaternionAlgebra.mul_re a b).trans <\| by simp [one_mul, neg_mul, sub_eq_add_neg, neg_neg] @[simp] theorem mul_imI : (a * b).imI = a.re * b.imI + a.imI * b.re + a.imJ * b.imK - a.imK * b.imJ := (QuaternionAlgebra.mul_imI a b).trans <\| by ring @[simp] theorem mul_imJ : (a * b).imJ = a.re * b.imJ - a.imI * b.imK + a.imJ * b.re + a.imK * b.imI := (QuaternionAlgebra.mul_imJ a b).trans <\| by ring @[simp] theorem mul_imK : (a * b).imK = a.re * b.imK + a.imI * b.imJ - a.imJ * b.imI + a.imK * b.re := (QuaternionAlgebra.mul_imK a b).trans <\| by ring @[simp, norm_cast] theorem coe_mul : ((x * y : R) : ℍ[R]) = x * y := QuaternionAlgebra.coe_mul x y @[norm_cast, simp] theorem coe_pow (n : ℕ) : (↑(x ^ n) : ℍ[R]) = (x : ℍ[R]) ^ n := QuaternionAlgebra.coe_pow x n @[simp, norm_cast] theorem natCast_re (n : ℕ) : (n : ℍ[R]).re = n := rfl @[simp, norm_cast] theorem natCast_imI (n : ℕ) : (n : ℍ[R]).imI = 0 := rfl @[simp, norm_cast] theorem natCast_imJ (n : ℕ) : (n : ℍ[R]).imJ = 0 := rfl @[simp, norm_cast] theorem natCast_imK (n : ℕ) : (n : ℍ[R]).imK = 0 := rfl @[simp, norm_cast] theorem natCast_im (n : ℕ) : (n : ℍ[R]).im = 0 := rfl @[norm_cast] theorem coe_natCast (n : ℕ) : ↑(n : R) = (n : ℍ[R]) := rfl @[simp, norm_cast] theorem intCast_re (z : ℤ) : (z : ℍ[R]).re = z := rfl @[simp, norm_cast] theorem intCast_imI (z : ℤ) : (z : ℍ[R]).imI = 0 := rfl @[simp, norm_cast] theorem intCast_imJ (z : ℤ) : (z : ℍ[R]).imJ = 0 := rfl @[simp, norm_cast] theorem intCast_imK (z : ℤ) : (z : ℍ[R]).imK = 0 := rfl @[simp, norm_cast] theorem intCast_im (z : ℤ) : (z : ℍ[R]).im = 0 := rfl @[norm_cast] theorem coe_intCast (z : ℤ) : ↑(z : R) = (z : ℍ[R]) := rfl theorem coe_injective : Function.Injective (coe : R → ℍ[R]) := QuaternionAlgebra.coe_injective @[simp] theorem coe_inj {x y : R} : (x : ℍ[R]) = y ↔ x = y := coe_injective.eq_iff @[simp] theorem smul_re [SMul S R] (s : S) : (s • a).re = s • a.re := rfl @[simp] theorem smul_imI [SMul S R] (s : S) : (s • a).imI = s • a.imI := rfl @[simp] theorem smul_imJ [SMul S R] (s : S) : (s • a).imJ = s • a.imJ := rfl @[simp] theorem smul_imK [SMul S R] (s : S) : (s • a).imK = s • a.imK := rfl @[simp] nonrec theorem smul_im [SMulZeroClass S R] (s : S) : (s • a).im = s • a.im := a.smul_im s @[simp, norm_cast] theorem coe_smul [SMulZeroClass S R] (s : S) (r : R) : (↑(s • r) : ℍ[R]) = s • (r : ℍ[R]) := QuaternionAlgebra.coe_smul _ _ theorem coe_commutes : ↑r * a = a * r := QuaternionAlgebra.coe_commutes r a theorem coe_commute : Commute (↑r) a := QuaternionAlgebra.coe_commute r a theorem coe_mul_eq_smul : ↑r * a = r • a := QuaternionAlgebra.coe_mul_eq_smul r a theorem mul_coe_eq_smul : a * r = r • a := QuaternionAlgebra.mul_coe_eq_smul r a @[simp] theorem algebraMap_def : ⇑(algebraMap R ℍ[R]) = coe := rfl theorem algebraMap_injective : (algebraMap R ℍ[R] : _ → _).Injective := QuaternionAlgebra.algebraMap_injective theorem smul_coe : x • (y : ℍ[R]) = ↑(x * y) := QuaternionAlgebra.smul_coe x y instance : Module.Finite R ℍ[R] := inferInstanceAs <\| Module.Finite R ℍ[R,-1,0,-1] instance : Module.Free R ℍ[R] := inferInstanceAs <\| Module.Free R ℍ[R,-1,0,-1] theorem rank_eq_four [StrongRankCondition R] : Module.rank R ℍ[R] = 4 := QuaternionAlgebra.rank_eq_four _ _ _ theorem finrank_eq_four [StrongRankCondition R] : Module.finrank R ℍ[R] = 4 := QuaternionAlgebra.finrank_eq_four _ _ _ @[simp] theorem star_re : (star a).re = a.re := by rw [QuaternionAlgebra.re_star, zero_mul, add_zero] @[simp] theorem star_imI : (star a).imI = -a.imI := rfl @[simp] theorem star_imJ : (star a).imJ = -a.imJ := rfl @[simp] theorem star_imK : (star a).imK = -a.imK := rfl @[simp] theorem star_im : (star a).im = -a.im := a.im_star nonrec theorem self_add_star' : a + star a = ↑(2 * a.re) := by simp [a.self_add_star', Quaternion.coe] nonrec theorem self_add_star : a + star a = 2 * a.re := by simp [a.self_add_star, Quaternion.coe] nonrec theorem star_add_self' : star a + a = ↑(2 * a.re) := by simp [a.star_add_self', Quaternion.coe] nonrec theorem star_add_self : star a + a = 2 * a.re := by simp [a.star_add_self, Quaternion.coe] nonrec theorem star_eq_two_re_sub : star a = ↑(2 * a.re) - a := by simp [a.star_eq_two_re_sub, Quaternion.coe] @[simp, norm_cast] theorem star_coe : star (x : ℍ[R]) = x := QuaternionAlgebra.star_coe x @[simp] theorem im_star : star a.im = -a.im := by ext <;> simp @[simp] theorem star_smul [Monoid S] [DistribMulAction S R] (s : S) (a : ℍ[R]) : star (s • a) = s • star a := QuaternionAlgebra.star_smul' s a theorem eq_re_of_eq_coe {a : ℍ[R]} {x : R} (h : a = x) : a = a.re := QuaternionAlgebra.eq_re_of_eq_coe h theorem eq_re_iff_mem_range_coe {a : ℍ[R]} : a = a.re ↔ a ∈ Set.range (coe : R → ℍ[R]) := QuaternionAlgebra.eq_re_iff_mem_range_coe section CharZero variable [NoZeroDivisors R] [CharZero R] @[simp] theorem star_eq_self {a : ℍ[R]} : star a = a ↔ a = a.re := QuaternionAlgebra.star_eq_self @[simp] theorem star_eq_neg {a : ℍ[R]} : star a = -a ↔ a.re = 0 := QuaternionAlgebra.star_eq_neg end CharZero nonrec theorem star_mul_eq_coe : star a * a = (star a * a).re := a.star_mul_eq_coe nonrec theorem mul_star_eq_coe : a * star a = (a * star a).re := a.mul_star_eq_coe open MulOpposite /-- Quaternion conjugate as an `AlgEquiv` to the opposite ring. -/ def starAe : ℍ[R] ≃ₐ[R] ℍ[R]ᵐᵒᵖ := QuaternionAlgebra.starAe @[simp] theorem coe_starAe : ⇑(starAe : ℍ[R] ≃ₐ[R] ℍ[R]ᵐᵒᵖ) = op ∘ star := rfl /-- Square of the norm. -/ def normSq : ℍ[R] →₀ R where toFun a := (a star a).re map_zero' := by simp only [star_zero, zero_mul, zero_re] map_one' := by simp only [star_one, one_mul, one_re] map_mul' x y := coe_injective <\| by conv_lhs => rw [← mul_star_eq_coe, star_mul, mul_assoc, ← mul_assoc y, y.mul_star_eq_coe, coe_commutes, ← mul_assoc, x.mul_star_eq_coe, ← coe_mul] theorem normSq_def : normSq a = (a * star a).re := rfl theorem normSq_def' : normSq a = a.1 ^ 2 + a.2 ^ 2 + a.3 ^ 2 + a.4 ^ 2 := by simp only [normSq_def, sq, mul_neg, sub_neg_eq_add, mul_re, star_re, star_imI, star_imJ, star_imK] theorem normSq_coe : normSq (x : ℍ[R]) = x ^ 2 := by rw [normSq_def, star_coe, ← coe_mul, coe_re, sq] @[simp] theorem normSq_star : normSq (star a) = normSq a := by simp [normSq_def'] @[norm_cast] theorem normSq_natCast (n : ℕ) : normSq (n : ℍ[R]) = (n : R) ^ 2 := by rw [← coe_natCast, normSq_coe] @[norm_cast] theorem normSq_intCast (z : ℤ) : normSq (z : ℍ[R]) = (z : R) ^ 2 := by rw [← coe_intCast, normSq_coe] @[simp] theorem normSq_neg : normSq (-a) = normSq a := by simp only [normSq_def, star_neg, neg_mul_neg] theorem self_mul_star : a * star a = normSq a := by rw [mul_star_eq_coe, normSq_def] theorem star_mul_self : star a * a = normSq a := by rw [star_comm_self, self_mul_star] theorem im_sq : a.im ^ 2 = -normSq a.im := by simp_rw [sq, ← star_mul_self, im_star, neg_mul, neg_neg] theorem coe_normSq_add : normSq (a + b) = normSq a + a * star b + b * star a + normSq b := by simp only [star_add, ← self_mul_star, mul_add, add_mul, add_assoc, add_left_comm] theorem normSq_smul (r : R) (q : ℍ[R]) : normSq (r • q) = r ^ 2 * normSq q := by simp only [normSq_def', smul_re, smul_imI, smul_imJ, smul_imK, mul_pow, mul_add, smul_eq_mul] theorem normSq_add (a b : ℍ[R]) : normSq (a + b) = normSq a + normSq b + 2 * (a * star b).re := calc normSq (a + b) = normSq a + (a * star b).re + ((b * star a).re + normSq b) := by simp_rw [normSq_def, star_add, add_mul, mul_add, add_re] _ = normSq a + normSq b + ((a * star b).re + (b * star a).re) := by abel _ = normSq a + normSq b + 2 * (a * star b).re := by rw [← add_re, ← star_mul_star a b, self_add_star', coe_re] end Quaternion namespace Quaternion variable {R : Type} section LinearOrderedCommRing variable [CommRing R] [LinearOrder R] [IsStrictOrderedRing R] {a : ℍ[R]} @[simp] theorem normSq_eq_zero : normSq a = 0 ↔ a = 0 := by refine ⟨fun h => ?_, fun h => h.symm ▸ normSq.map_zero⟩ rw [normSq_def', add_eq_zero_iff_of_nonneg, add_eq_zero_iff_of_nonneg, add_eq_zero_iff_of_nonneg] at h · exact ext a 0 (pow_eq_zero h.1.1.1) (pow_eq_zero h.1.1.2) (pow_eq_zero h.1.2) (pow_eq_zero h.2) all_goals apply_rules [sq_nonneg, add_nonneg] theorem normSq_ne_zero : normSq a ≠ 0 ↔ a ≠ 0 := normSq_eq_zero.not @[simp] theorem normSq_nonneg : 0 ≤ normSq a := by rw [normSq_def'] apply_rules [sq_nonneg, add_nonneg] @[simp] theorem normSq_le_zero : normSq a ≤ 0 ↔ a = 0 := normSq_nonneg.le_iff_eq.trans normSq_eq_zero instance instNontrivial : Nontrivial ℍ[R] where exists_pair_ne := ⟨0, 1, mt (congr_arg QuaternionAlgebra.re) zero_ne_one⟩ instance : NoZeroDivisors ℍ[R] where eq_zero_or_eq_zero_of_mul_eq_zero {a b} hab := have : normSq a normSq b = 0 := by rwa [← map_mul, normSq_eq_zero] (eq_zero_or_eq_zero_of_mul_eq_zero this).imp normSq_eq_zero.1 normSq_eq_zero.1 instance : IsDomain ℍ[R] := NoZeroDivisors.to_isDomain _ theorem sq_eq_normSq : a ^ 2 = normSq a ↔ a = a.re := by rw [← star_eq_self, ← star_mul_self, sq, mul_eq_mul_right_iff, eq_comm] exact or_iff_left_of_imp fun ha ↦ ha.symm ▸ star_zero _ theorem sq_eq_neg_normSq : a ^ 2 = -normSq a ↔ a.re = 0 := by simp_rw [← star_eq_neg] obtain rfl \| hq0 := eq_or_ne a 0 · simp · rw [← star_mul_self, ← mul_neg, ← neg_sq, sq, mul_left_inj' (neg_ne_zero.mpr hq0), eq_comm] end LinearOrderedCommRing section Field variable [Field R] (a b : ℍ[R]) instance instNNRatCast : NNRatCast ℍ[R] where nnratCast q := (q : R) instance instRatCast : RatCast ℍ[R] where ratCast q := (q : R) @[simp, norm_cast] lemma re_nnratCast (q : ℚ≥0) : (q : ℍ[R]).re = q := rfl @[simp, norm_cast] lemma im_nnratCast (q : ℚ≥0) : (q : ℍ[R]).im = 0 := rfl @[simp, norm_cast] lemma imI_nnratCast (q : ℚ≥0) : (q : ℍ[R]).imI = 0 := rfl @[simp, norm_cast] lemma imJ_nnratCast (q : ℚ≥0) : (q : ℍ[R]).imJ = 0 := rfl @[simp, norm_cast] lemma imK_nnratCast (q : ℚ≥0) : (q : ℍ[R]).imK = 0 := rfl @[simp, norm_cast] lemma ratCast_re (q : ℚ) : (q : ℍ[R]).re = q := rfl @[simp, norm_cast] lemma ratCast_im (q : ℚ) : (q : ℍ[R]).im = 0 := rfl @[simp, norm_cast] lemma ratCast_imI (q : ℚ) : (q : ℍ[R]).imI = 0 := rfl @[simp, norm_cast] lemma ratCast_imJ (q : ℚ) : (q : ℍ[R]).imJ = 0 := rfl @[simp, norm_cast] lemma ratCast_imK (q : ℚ) : (q : ℍ[R]).imK = 0 := rfl @[norm_cast] lemma coe_nnratCast (q : ℚ≥0) : ↑(q : R) = (q : ℍ[R]) := rfl @[norm_cast] lemma coe_ratCast (q : ℚ) : ↑(q : R) = (q : ℍ[R]) := rfl variable [LinearOrder R] [IsStrictOrderedRing R] (a b : ℍ[R]) @[simps -isSimp] instance instInv : Inv ℍ[R] := ⟨fun a => (normSq a)⁻¹ • star a⟩ instance instGroupWithZero : GroupWithZero ℍ[R] := { Quaternion.instNontrivial with inv := Inv.inv inv_zero := by rw [instInv_inv, star_zero, smul_zero] mul_inv_cancel := fun a ha => by rw [instInv_inv, Algebra.mul_smul_comm (normSq a)⁻¹ a (star a), self_mul_star, smul_coe, inv_mul_cancel₀ (normSq_ne_zero.2 ha), coe_one] } @[norm_cast, simp] theorem coe_inv (x : R) : ((x⁻¹ : R) : ℍ[R]) = (↑x)⁻¹ := map_inv₀ (algebraMap R ℍ[R]) _ @[norm_cast, simp] theorem coe_div (x y : R) : ((x / y : R) : ℍ[R]) = x / y := map_div₀ (algebraMap R ℍ[R]) x y @[norm_cast, simp] theorem coe_zpow (x : R) (z : ℤ) : ((x ^ z : R) : ℍ[R]) = (x : ℍ[R]) ^ z := map_zpow₀ (algebraMap R ℍ[R]) x z instance instDivisionRing : DivisionRing ℍ[R] where __ := Quaternion.instRing __ := Quaternion.instGroupWithZero nnqsmul := (· • ·) qsmul := (· • ·) nnratCast_def _ := by rw [← coe_nnratCast, NNRat.cast_def, coe_div, coe_natCast, coe_natCast] ratCast_def _ := by rw [← coe_ratCast, Rat.cast_def, coe_div, coe_intCast, coe_natCast] nnqsmul_def _ _ := by rw [← coe_nnratCast, coe_mul_eq_smul]; ext <;> exact NNRat.smul_def .. qsmul_def _ _ := by rw [← coe_ratCast, coe_mul_eq_smul]; ext <;> exact Rat.smul_def .. theorem normSq_inv : normSq a⁻¹ = (normSq a)⁻¹ := map_inv₀ normSq _ theorem normSq_div : normSq (a / b) = normSq a / normSq b := map_div₀ normSq a b theorem normSq_zpow (z : ℤ) : normSq (a ^ z) = normSq a ^ z := map_zpow₀ normSq a z @[norm_cast] theorem normSq_ratCast (q : ℚ) : normSq (q : ℍ[R]) = (q : ℍ[R]) ^ 2 := by rw [← coe_ratCast, normSq_coe, coe_pow] end Field end Quaternion namespace Cardinal open Quaternion section QuaternionAlgebra variable {R : Type} (c₁ c₂ c₃ : R) private theorem pow_four [Infinite R] : #R ^ 4 = #R := power_nat_eq (aleph0_le_mk R) <\| by decide /-- The cardinality of a quaternion algebra, as a type. -/ theorem mk_quaternionAlgebra : #(ℍ[R,c₁,c₂,c₃]) = #R ^ 4 := by rw [mk_congr (QuaternionAlgebra.equivProd c₁ c₂ c₃)] simp only [mk_prod, lift_id] ring @[simp] theorem mk_quaternionAlgebra_of_infinite [Infinite R] : #(ℍ[R,c₁,c₂,c₃]) = #R := by rw [mk_quaternionAlgebra, pow_four] /-- The cardinality of a quaternion algebra, as a set. -/ theorem mk_univ_quaternionAlgebra : #(Set.univ : Set ℍ[R,c₁,c₂,c₃]) = #R ^ 4 := by rw [mk_univ, mk_quaternionAlgebra] theorem mk_univ_quaternionAlgebra_of_infinite [Infinite R] : #(Set.univ : Set ℍ[R,c₁,c₂,c₃]) = #R := by rw [mk_univ_quaternionAlgebra, pow_four] /-- Show the quaternion ⟨w, x, y, z⟩ as a string "{ re := w, imI := x, imJ := y, imK := z }". For the typical case of quaternions over ℝ, each component will show as a Cauchy sequence due to the way Real numbers are represented. -/ instance [Repr R] {a b c : R} : Repr ℍ[R, a, b, c] where reprPrec q _ := s!"\{ re := {repr q.re}, imI := {repr q.imI}, imJ := {repr q.imJ}, imK := {repr q.imK} }" end QuaternionAlgebra section Quaternion variable (R : Type) [Zero R] [One R] [Neg R] /-- The cardinality of the quaternions, as a type. -/ @[simp] theorem mk_quaternion : #(ℍ[R]) = #R ^ 4 := mk_quaternionAlgebra _ _ _ theorem mk_quaternion_of_infinite [Infinite R] : #(ℍ[R]) = #R := mk_quaternionAlgebra_of_infinite _ _ _ /-- The cardinality of the quaternions, as a set. -/ theorem mk_univ_quaternion : #(Set.univ : Set ℍ[R]) = #R ^ 4 := mk_univ_quaternionAlgebra _ _ _ theorem mk_univ_quaternion_of_infinite [Infinite R] : #(Set.univ : Set ℍ[R]) = #R := mk_univ_quaternionAlgebra_of_infinite _ _ _ end Quaternion end Cardinal		Mathlib/Algebra/Quaternion.lean	1,326	1,327
/- 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, Jean Lo, Calle Sönne, Sébastien Gouëzel, Rémy Degenne, David Loeffler -/ import Mathlib.Analysis.SpecialFunctions.Pow.Complex import Qq /-! # Power function on `ℝ` We construct the power functions `x ^ y`, where `x` and `y` are real numbers. -/ noncomputable section open Real ComplexConjugate Finset Set /- ## Definitions -/ namespace Real variable {x y z : ℝ} /-- The real power function `x ^ y`, defined as the real part of the complex power function. For `x > 0`, it is equal to `exp (y log x)`. For `x = 0`, one sets `0 ^ 0=1` and `0 ^ y=0` for `y ≠ 0`. For `x < 0`, the definition is somewhat arbitrary as it depends on the choice of a complex determination of the logarithm. With our conventions, it is equal to `exp (y log x) cos (π y)`. -/ noncomputable def rpow (x y : ℝ) := ((x : ℂ) ^ (y : ℂ)).re noncomputable instance : Pow ℝ ℝ := ⟨rpow⟩ @[simp] theorem rpow_eq_pow (x y : ℝ) : rpow x y = x ^ y := rfl theorem rpow_def (x y : ℝ) : x ^ y = ((x : ℂ) ^ (y : ℂ)).re := rfl theorem rpow_def_of_nonneg {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : x ^ y = if x = 0 then if y = 0 then 1 else 0 else exp (log x * y) := by simp only [rpow_def, Complex.cpow_def]; split_ifs <;> simp_all [(Complex.ofReal_log hx).symm, -Complex.ofReal_mul, (Complex.ofReal_mul _ _).symm, Complex.exp_ofReal_re, Complex.ofReal_eq_zero] theorem rpow_def_of_pos {x : ℝ} (hx : 0 < x) (y : ℝ) : x ^ y = exp (log x * y) := by rw [rpow_def_of_nonneg (le_of_lt hx), if_neg (ne_of_gt hx)] theorem exp_mul (x y : ℝ) : exp (x * y) = exp x ^ y := by rw [rpow_def_of_pos (exp_pos _), log_exp] @[simp, norm_cast] theorem rpow_intCast (x : ℝ) (n : ℤ) : x ^ (n : ℝ) = x ^ n := by simp only [rpow_def, ← Complex.ofReal_zpow, Complex.cpow_intCast, Complex.ofReal_intCast, Complex.ofReal_re] @[simp, norm_cast] theorem rpow_natCast (x : ℝ) (n : ℕ) : x ^ (n : ℝ) = x ^ n := by simpa using rpow_intCast x n @[simp] theorem exp_one_rpow (x : ℝ) : exp 1 ^ x = exp x := by rw [← exp_mul, one_mul] @[simp] lemma exp_one_pow (n : ℕ) : exp 1 ^ n = exp n := by rw [← rpow_natCast, exp_one_rpow] theorem rpow_eq_zero_iff_of_nonneg (hx : 0 ≤ x) : x ^ y = 0 ↔ x = 0 ∧ y ≠ 0 := by simp only [rpow_def_of_nonneg hx] split_ifs <;> simp [, exp_ne_zero] @[simp] lemma rpow_eq_zero (hx : 0 ≤ x) (hy : y ≠ 0) : x ^ y = 0 ↔ x = 0 := by simp [rpow_eq_zero_iff_of_nonneg, ] @[simp] lemma rpow_ne_zero (hx : 0 ≤ x) (hy : y ≠ 0) : x ^ y ≠ 0 ↔ x ≠ 0 := Real.rpow_eq_zero hx hy \|>.not open Real theorem rpow_def_of_neg {x : ℝ} (hx : x < 0) (y : ℝ) : x ^ y = exp (log x * y) * cos (y * π) := by rw [rpow_def, Complex.cpow_def, if_neg] · have : Complex.log x * y = ↑(log (-x) * y) + ↑(y * π) * Complex.I := by simp only [Complex.log, Complex.norm_real, norm_eq_abs, abs_of_neg hx, log_neg_eq_log, Complex.arg_ofReal_of_neg hx, Complex.ofReal_mul] ring rw [this, Complex.exp_add_mul_I, ← Complex.ofReal_exp, ← Complex.ofReal_cos, ← Complex.ofReal_sin, mul_add, ← Complex.ofReal_mul, ← mul_assoc, ← Complex.ofReal_mul, Complex.add_re, Complex.ofReal_re, Complex.mul_re, Complex.I_re, Complex.ofReal_im, Real.log_neg_eq_log] ring · rw [Complex.ofReal_eq_zero] exact ne_of_lt hx theorem rpow_def_of_nonpos {x : ℝ} (hx : x ≤ 0) (y : ℝ) : x ^ y = if x = 0 then if y = 0 then 1 else 0 else exp (log x * y) * cos (y * π) := by split_ifs with h <;> simp [rpow_def, ]; exact rpow_def_of_neg (lt_of_le_of_ne hx h) _ @[bound] theorem rpow_pos_of_pos {x : ℝ} (hx : 0 < x) (y : ℝ) : 0 < x ^ y := by rw [rpow_def_of_pos hx]; apply exp_pos @[simp] theorem rpow_zero (x : ℝ) : x ^ (0 : ℝ) = 1 := by simp [rpow_def] theorem rpow_zero_pos (x : ℝ) : 0 < x ^ (0 : ℝ) := by simp @[simp] theorem zero_rpow {x : ℝ} (h : x ≠ 0) : (0 : ℝ) ^ x = 0 := by simp [rpow_def, ] theorem zero_rpow_eq_iff {x : ℝ} {a : ℝ} : 0 ^ x = a ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by constructor · intro hyp simp only [rpow_def, Complex.ofReal_zero] at hyp by_cases h : x = 0 · subst h simp only [Complex.one_re, Complex.ofReal_zero, Complex.cpow_zero] at hyp exact Or.inr ⟨rfl, hyp.symm⟩ · rw [Complex.zero_cpow (Complex.ofReal_ne_zero.mpr h)] at hyp exact Or.inl ⟨h, hyp.symm⟩ · rintro (⟨h, rfl⟩ \| ⟨rfl, rfl⟩) · exact zero_rpow h · exact rpow_zero _ theorem eq_zero_rpow_iff {x : ℝ} {a : ℝ} : a = 0 ^ x ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by rw [← zero_rpow_eq_iff, eq_comm] @[simp] theorem rpow_one (x : ℝ) : x ^ (1 : ℝ) = x := by simp [rpow_def] @[simp] theorem one_rpow (x : ℝ) : (1 : ℝ) ^ x = 1 := by simp [rpow_def] theorem zero_rpow_le_one (x : ℝ) : (0 : ℝ) ^ x ≤ 1 := by by_cases h : x = 0 <;> simp [h, zero_le_one] theorem zero_rpow_nonneg (x : ℝ) : 0 ≤ (0 : ℝ) ^ x := by by_cases h : x = 0 <;> simp [h, zero_le_one] @[bound] theorem rpow_nonneg {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : 0 ≤ x ^ y := by rw [rpow_def_of_nonneg hx]; split_ifs <;> simp only [zero_le_one, le_refl, le_of_lt (exp_pos _)] theorem abs_rpow_of_nonneg {x y : ℝ} (hx_nonneg : 0 ≤ x) : \|x ^ y\| = \|x\| ^ y := by have h_rpow_nonneg : 0 ≤ x ^ y := Real.rpow_nonneg hx_nonneg _ rw [abs_eq_self.mpr hx_nonneg, abs_eq_self.mpr h_rpow_nonneg] @[bound] theorem abs_rpow_le_abs_rpow (x y : ℝ) : \|x ^ y\| ≤ \|x\| ^ y := by rcases le_or_lt 0 x with hx \| hx · rw [abs_rpow_of_nonneg hx] · rw [abs_of_neg hx, rpow_def_of_neg hx, rpow_def_of_pos (neg_pos.2 hx), log_neg_eq_log, abs_mul, abs_of_pos (exp_pos _)] exact mul_le_of_le_one_right (exp_pos _).le (abs_cos_le_one _) theorem abs_rpow_le_exp_log_mul (x y : ℝ) : \|x ^ y\| ≤ exp (log x * y) := by refine (abs_rpow_le_abs_rpow x y).trans ?_ by_cases hx : x = 0 · by_cases hy : y = 0 <;> simp [hx, hy, zero_le_one] · rw [rpow_def_of_pos (abs_pos.2 hx), log_abs] lemma rpow_inv_log (hx₀ : 0 < x) (hx₁ : x ≠ 1) : x ^ (log x)⁻¹ = exp 1 := by rw [rpow_def_of_pos hx₀, mul_inv_cancel₀] exact log_ne_zero.2 ⟨hx₀.ne', hx₁, (hx₀.trans' <\| by norm_num).ne'⟩ /-- See `Real.rpow_inv_log` for the equality when `x ≠ 1` is strictly positive. -/ lemma rpow_inv_log_le_exp_one : x ^ (log x)⁻¹ ≤ exp 1 := by calc _ ≤ \|x ^ (log x)⁻¹\| := le_abs_self _ _ ≤ \|x\| ^ (log x)⁻¹ := abs_rpow_le_abs_rpow .. rw [← log_abs] obtain hx \| hx := (abs_nonneg x).eq_or_gt · simp [hx] · rw [rpow_def_of_pos hx] gcongr exact mul_inv_le_one theorem norm_rpow_of_nonneg {x y : ℝ} (hx_nonneg : 0 ≤ x) : ‖x ^ y‖ = ‖x‖ ^ y := by simp_rw [Real.norm_eq_abs] exact abs_rpow_of_nonneg hx_nonneg variable {w x y z : ℝ} theorem rpow_add (hx : 0 < x) (y z : ℝ) : x ^ (y + z) = x ^ y * x ^ z := by simp only [rpow_def_of_pos hx, mul_add, exp_add] theorem rpow_add' (hx : 0 ≤ x) (h : y + z ≠ 0) : x ^ (y + z) = x ^ y * x ^ z := by rcases hx.eq_or_lt with (rfl \| pos) · rw [zero_rpow h, zero_eq_mul] have : y ≠ 0 ∨ z ≠ 0 := not_and_or.1 fun ⟨hy, hz⟩ => h <\| hy.symm ▸ hz.symm ▸ zero_add 0 exact this.imp zero_rpow zero_rpow · exact rpow_add pos _ _ /-- Variant of `Real.rpow_add'` that avoids having to prove `y + z = w` twice. -/ lemma rpow_of_add_eq (hx : 0 ≤ x) (hw : w ≠ 0) (h : y + z = w) : x ^ w = x ^ y * x ^ z := by rw [← h, rpow_add' hx]; rwa [h] theorem rpow_add_of_nonneg (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 ≤ z) : x ^ (y + z) = x ^ y * x ^ z := by rcases hy.eq_or_lt with (rfl \| hy) · rw [zero_add, rpow_zero, one_mul] exact rpow_add' hx (ne_of_gt <\| add_pos_of_pos_of_nonneg hy hz)	/-- For `0 ≤ x`, the only problematic case in the equality `x ^ y * x ^ z = x ^ (y + z)` is for	Mathlib/Analysis/SpecialFunctions/Pow/Real.lean	201	202
/- 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.Algebra.Order.Group.OrderIso import Mathlib.SetTheory.Game.Ordinal import Mathlib.SetTheory.Ordinal.NaturalOps /-! # Birthdays of games There are two related but distinct notions of a birthday within combinatorial game theory. One is the birthday of a pre-game, which represents the "step" at which it is constructed. We define it recursively as the least ordinal larger than the birthdays of its left and right options. On the other hand, the birthday of a game is the smallest birthday among all pre-games that quotient to it. The birthday of a pre-game can be understood as representing the depth of its game tree. On the other hand, the birthday of a game more closely matches Conway's original description. The lemma `SetTheory.Game.birthday_eq_pGameBirthday` links both definitions together. # Main declarations - `SetTheory.PGame.birthday`: The birthday of a pre-game. - `SetTheory.Game.birthday`: The birthday of a game. # Todo - Characterize the birthdays of other basic arithmetical operations. -/ universe u open Ordinal namespace SetTheory open scoped NaturalOps PGame namespace PGame /-- The birthday of a pre-game is inductively defined as the least strict upper bound of the birthdays of its left and right games. It may be thought as the "step" in which a certain game is constructed. -/ noncomputable def birthday : PGame.{u} → Ordinal.{u} \| ⟨_, _, xL, xR⟩ => max (lsub.{u, u} fun i => birthday (xL i)) (lsub.{u, u} fun i => birthday (xR i)) theorem birthday_def (x : PGame) : birthday x = max (lsub.{u, u} fun i => birthday (x.moveLeft i)) (lsub.{u, u} fun i => birthday (x.moveRight i)) := by cases x; rw [birthday]; rfl theorem birthday_moveLeft_lt {x : PGame} (i : x.LeftMoves) : (x.moveLeft i).birthday < x.birthday := by cases x; rw [birthday]; exact lt_max_of_lt_left (lt_lsub _ i) theorem birthday_moveRight_lt {x : PGame} (i : x.RightMoves) : (x.moveRight i).birthday < x.birthday := by cases x; rw [birthday]; exact lt_max_of_lt_right (lt_lsub _ i) theorem lt_birthday_iff {x : PGame} {o : Ordinal} :	o < x.birthday ↔ (∃ i : x.LeftMoves, o ≤ (x.moveLeft i).birthday) ∨ ∃ i : x.RightMoves, o ≤ (x.moveRight i).birthday := by constructor · rw [birthday_def] intro h rcases lt_max_iff.1 h with h' \| h' · left rwa [lt_lsub_iff] at h' · right rwa [lt_lsub_iff] at h' · rintro (⟨i, hi⟩ \| ⟨i, hi⟩) · exact hi.trans_lt (birthday_moveLeft_lt i) · exact hi.trans_lt (birthday_moveRight_lt i)	Mathlib/SetTheory/Game/Birthday.lean	64	78
/- Copyright (c) 2014 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Leonardo de Moura, Floris van Doorn, Yury Kudryashov, Neil Strickland -/ import Mathlib.Algebra.Group.Defs import Mathlib.Algebra.GroupWithZero.Defs import Mathlib.Data.Int.Cast.Defs import Mathlib.Tactic.Spread import Mathlib.Util.AssertExists import Mathlib.Tactic.StacksAttribute /-! # Semirings and rings This file defines semirings, rings and domains. This is analogous to `Algebra.Group.Defs` and `Algebra.Group.Basic`, the difference being that the former is about `+` and `` separately, while the present file is about their interaction. ## Main definitions `Distrib`: Typeclass for distributivity of multiplication over addition. * `HasDistribNeg`: Typeclass for commutativity of negation and multiplication. This is useful when dealing with multiplicative submonoids which are closed under negation without being closed under addition, for example `Units`. * `(NonUnital)(NonAssoc)(Semi)Ring`: Typeclasses for possibly non-unital or non-associative rings and semirings. Some combinations are not defined yet because they haven't found use. For Lie Rings, there is a type synonym `CommutatorRing` defined in `Mathlib/Algebra/Algebra/NonUnitalHom.lean` turning the bracket into a multiplication so that the instance `instNonUnitalNonAssocSemiringCommutatorRing` can be defined. ## Tags `Semiring`, `CommSemiring`, `Ring`, `CommRing`, domain, `IsDomain`, nonzero, units -/ /-! Previously an import dependency on `Mathlib.Algebra.Group.Basic` had crept in. In general, the `.Defs` files in the basic algebraic hierarchy should only depend on earlier `.Defs` files, without importing `.Basic` theory development. These `assert_not_exists` statements guard against this returning. -/ assert_not_exists DivisionMonoid.toDivInvOneMonoid mul_rotate universe u v variable {α : Type u} {R : Type v} open Function /-! ### `Distrib` class -/ /-- A typeclass stating that multiplication is left and right distributive over addition. -/ class Distrib (R : Type) extends Mul R, Add R where /-- Multiplication is left distributive over addition -/ protected left_distrib : ∀ a b c : R, a (b + c) = a * b + a * c /-- Multiplication is right distributive over addition -/ protected right_distrib : ∀ a b c : R, (a + b) * c = a * c + b * c /-- A typeclass stating that multiplication is left distributive over addition. -/ class LeftDistribClass (R : Type) [Mul R] [Add R] : Prop where /-- Multiplication is left distributive over addition -/ protected left_distrib : ∀ a b c : R, a (b + c) = a * b + a * c /-- A typeclass stating that multiplication is right distributive over addition. -/ class RightDistribClass (R : Type) [Mul R] [Add R] : Prop where /-- Multiplication is right distributive over addition -/ protected right_distrib : ∀ a b c : R, (a + b) c = a * c + b * c -- see Note [lower instance priority] instance (priority := 100) Distrib.leftDistribClass (R : Type) [Distrib R] : LeftDistribClass R := ⟨Distrib.left_distrib⟩ -- see Note [lower instance priority] instance (priority := 100) Distrib.rightDistribClass (R : Type) [Distrib R] : RightDistribClass R := ⟨Distrib.right_distrib⟩ theorem left_distrib [Mul R] [Add R] [LeftDistribClass R] (a b c : R) : a * (b + c) = a * b + a * c := LeftDistribClass.left_distrib a b c alias mul_add := left_distrib theorem right_distrib [Mul R] [Add R] [RightDistribClass R] (a b c : R) : (a + b) * c = a * c + b * c := RightDistribClass.right_distrib a b c alias add_mul := right_distrib theorem distrib_three_right [Mul R] [Add R] [RightDistribClass R] (a b c d : R) : (a + b + c) * d = a * d + b * d + c * d := by simp [right_distrib] /-! ### Classes of semirings and rings We make sure that the canonical path from `NonAssocSemiring` to `Ring` passes through `Semiring`, as this is a path which is followed all the time in linear algebra where the defining semilinear map `σ : R →+* S` depends on the `NonAssocSemiring` structure of `R` and `S` while the module definition depends on the `Semiring` structure. It is not currently possible to adjust priorities by hand (see https://github.com/leanprover/lean4/issues/2115). Instead, the last declared instance is used, so we make sure that `Semiring` is declared after `NonAssocRing`, so that `Semiring -> NonAssocSemiring` is tried before `NonAssocRing -> NonAssocSemiring`. TODO: clean this once https://github.com/leanprover/lean4/issues/2115 is fixed -/ /-- A not-necessarily-unital, not-necessarily-associative semiring. See `CommutatorRing` and the documentation thereof in case you need a `NonUnitalNonAssocSemiring` instance on a Lie ring or a Lie algebra. -/ class NonUnitalNonAssocSemiring (α : Type u) extends AddCommMonoid α, Distrib α, MulZeroClass α /-- An associative but not-necessarily unital semiring. -/ class NonUnitalSemiring (α : Type u) extends NonUnitalNonAssocSemiring α, SemigroupWithZero α /-- A unital but not-necessarily-associative semiring. -/ class NonAssocSemiring (α : Type u) extends NonUnitalNonAssocSemiring α, MulZeroOneClass α, AddCommMonoidWithOne α /-- A not-necessarily-unital, not-necessarily-associative ring. -/ class NonUnitalNonAssocRing (α : Type u) extends AddCommGroup α, NonUnitalNonAssocSemiring α /-- An associative but not-necessarily unital ring. -/ class NonUnitalRing (α : Type) extends NonUnitalNonAssocRing α, NonUnitalSemiring α /-- A unital but not-necessarily-associative ring. -/ class NonAssocRing (α : Type) extends NonUnitalNonAssocRing α, NonAssocSemiring α, AddCommGroupWithOne α /-- A `Semiring` is a type with addition, multiplication, a `0` and a `1` where addition is commutative and associative, multiplication is associative and left and right distributive over addition, and `0` and `1` are additive and multiplicative identities. -/ class Semiring (α : Type u) extends NonUnitalSemiring α, NonAssocSemiring α, MonoidWithZero α /-- A `Ring` is a `Semiring` with negation making it an additive group. -/ class Ring (R : Type u) extends Semiring R, AddCommGroup R, AddGroupWithOne R /-! ### Semirings -/ section DistribMulOneClass variable [Add α] [MulOneClass α] theorem add_one_mul [RightDistribClass α] (a b : α) : (a + 1) * b = a * b + b := by rw [add_mul, one_mul] theorem mul_add_one [LeftDistribClass α] (a b : α) : a * (b + 1) = a * b + a := by rw [mul_add, mul_one] theorem one_add_mul [RightDistribClass α] (a b : α) : (1 + a) * b = b + a * b := by rw [add_mul, one_mul] theorem mul_one_add [LeftDistribClass α] (a b : α) : a * (1 + b) = a + a * b := by rw [mul_add, mul_one] end DistribMulOneClass section NonAssocSemiring	variable [NonAssocSemiring α]	Mathlib/Algebra/Ring/Defs.lean	168	169
/- Copyright (c) 2020 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers, Manuel Candales -/ import Mathlib.Analysis.Convex.Between import Mathlib.Analysis.Normed.Group.AddTorsor import Mathlib.Geometry.Euclidean.Angle.Unoriented.Basic import Mathlib.Analysis.Normed.Affine.Isometry /-! # Angles between points This file defines unoriented angles in Euclidean affine spaces. ## Main definitions * `EuclideanGeometry.angle`, with notation `∠`, is the undirected angle determined by three points. ## TODO Prove the triangle inequality for the angle. -/ noncomputable section open Real RealInnerProductSpace namespace EuclideanGeometry open InnerProductGeometry variable {V P : Type} [NormedAddCommGroup V] [InnerProductSpace ℝ V] [MetricSpace P] [NormedAddTorsor V P] {p p₀ : P} /-- The undirected angle at `p₂` between the line segments to `p₁` and `p₃`. If either of those points equals `p₂`, this is π/2. Use `open scoped EuclideanGeometry` to access the `∠ p₁ p₂ p₃` notation. -/ nonrec def angle (p₁ p₂ p₃ : P) : ℝ := angle (p₁ -ᵥ p₂ : V) (p₃ -ᵥ p₂) @[inherit_doc] scoped notation "∠" => EuclideanGeometry.angle theorem continuousAt_angle {x : P × P × P} (hx12 : x.1 ≠ x.2.1) (hx32 : x.2.2 ≠ x.2.1) : ContinuousAt (fun y : P × P × P => ∠ y.1 y.2.1 y.2.2) x := by let f : P × P × P → V × V := fun y => (y.1 -ᵥ y.2.1, y.2.2 -ᵥ y.2.1) have hf1 : (f x).1 ≠ 0 := by simp [f, hx12] have hf2 : (f x).2 ≠ 0 := by simp [f, hx32] exact (InnerProductGeometry.continuousAt_angle hf1 hf2).comp (by fun_prop) @[simp] theorem _root_.AffineIsometry.angle_map {V₂ P₂ : Type} [NormedAddCommGroup V₂] [InnerProductSpace ℝ V₂] [MetricSpace P₂] [NormedAddTorsor V₂ P₂] (f : P →ᵃⁱ[ℝ] P₂) (p₁ p₂ p₃ : P) : ∠ (f p₁) (f p₂) (f p₃) = ∠ p₁ p₂ p₃ := by simp_rw [angle, ← AffineIsometry.map_vsub, LinearIsometry.angle_map] @[simp, norm_cast] theorem _root_.AffineSubspace.angle_coe {s : AffineSubspace ℝ P} (p₁ p₂ p₃ : s) : haveI : Nonempty s := ⟨p₁⟩ ∠ (p₁ : P) (p₂ : P) (p₃ : P) = ∠ p₁ p₂ p₃ := haveI : Nonempty s := ⟨p₁⟩ s.subtypeₐᵢ.angle_map p₁ p₂ p₃ /-- Angles are translation invariant -/ @[simp] theorem angle_const_vadd (v : V) (p₁ p₂ p₃ : P) : ∠ (v +ᵥ p₁) (v +ᵥ p₂) (v +ᵥ p₃) = ∠ p₁ p₂ p₃ := (AffineIsometryEquiv.constVAdd ℝ P v).toAffineIsometry.angle_map _ _ _ /-- Angles are translation invariant -/ @[simp] theorem angle_vadd_const (v₁ v₂ v₃ : V) (p : P) : ∠ (v₁ +ᵥ p) (v₂ +ᵥ p) (v₃ +ᵥ p) = ∠ v₁ v₂ v₃ := (AffineIsometryEquiv.vaddConst ℝ p).toAffineIsometry.angle_map _ _ _ /-- Angles are translation invariant -/ @[simp] theorem angle_const_vsub (p p₁ p₂ p₃ : P) : ∠ (p -ᵥ p₁) (p -ᵥ p₂) (p -ᵥ p₃) = ∠ p₁ p₂ p₃ := (AffineIsometryEquiv.constVSub ℝ p).toAffineIsometry.angle_map _ _ _ /-- Angles are translation invariant -/ @[simp] theorem angle_vsub_const (p₁ p₂ p₃ p : P) : ∠ (p₁ -ᵥ p) (p₂ -ᵥ p) (p₃ -ᵥ p) = ∠ p₁ p₂ p₃ := (AffineIsometryEquiv.vaddConst ℝ p).symm.toAffineIsometry.angle_map _ _ _ /-- Angles in a vector space are translation invariant -/ @[simp] theorem angle_add_const (v₁ v₂ v₃ : V) (v : V) : ∠ (v₁ + v) (v₂ + v) (v₃ + v) = ∠ v₁ v₂ v₃ := angle_vadd_const _ _ _ _ /-- Angles in a vector space are translation invariant -/ @[simp] theorem angle_const_add (v : V) (v₁ v₂ v₃ : V) : ∠ (v + v₁) (v + v₂) (v + v₃) = ∠ v₁ v₂ v₃ := angle_const_vadd _ _ _ _ /-- Angles in a vector space are translation invariant -/ @[simp] theorem angle_sub_const (v₁ v₂ v₃ : V) (v : V) : ∠ (v₁ - v) (v₂ - v) (v₃ - v) = ∠ v₁ v₂ v₃ := by simpa only [vsub_eq_sub] using angle_vsub_const v₁ v₂ v₃ v /-- Angles in a vector space are invariant to inversion -/ @[simp] theorem angle_const_sub (v : V) (v₁ v₂ v₃ : V) : ∠ (v - v₁) (v - v₂) (v - v₃) = ∠ v₁ v₂ v₃ := by simpa only [vsub_eq_sub] using angle_const_vsub v v₁ v₂ v₃ /-- Angles in a vector space are invariant to inversion -/ @[simp] theorem angle_neg (v₁ v₂ v₃ : V) : ∠ (-v₁) (-v₂) (-v₃) = ∠ v₁ v₂ v₃ := by simpa only [zero_sub] using angle_const_sub 0 v₁ v₂ v₃ /-- The angle at a point does not depend on the order of the other two points. -/ nonrec theorem angle_comm (p₁ p₂ p₃ : P) : ∠ p₁ p₂ p₃ = ∠ p₃ p₂ p₁ := angle_comm _ _ /-- The angle at a point is nonnegative. -/ nonrec theorem angle_nonneg (p₁ p₂ p₃ : P) : 0 ≤ ∠ p₁ p₂ p₃ := angle_nonneg _ _ /-- The angle at a point is at most π. -/ nonrec theorem angle_le_pi (p₁ p₂ p₃ : P) : ∠ p₁ p₂ p₃ ≤ π := angle_le_pi _ _ /-- The angle ∠AAB at a point is always `π / 2`. -/ @[simp] lemma angle_self_left (p₀ p : P) : ∠ p₀ p₀ p = π / 2 := by unfold angle rw [vsub_self] exact angle_zero_left _ /-- The angle ∠ABB at a point is always `π / 2`. -/ @[simp] lemma angle_self_right (p₀ p : P) : ∠ p p₀ p₀ = π / 2 := by rw [angle_comm, angle_self_left] /-- The angle ∠ABA at a point is `0`, unless `A = B`. -/ theorem angle_self_of_ne (h : p ≠ p₀) : ∠ p p₀ p = 0 := angle_self <\| vsub_ne_zero.2 h /-- If the angle ∠ABC at a point is π, the angle ∠BAC is 0. -/ theorem angle_eq_zero_of_angle_eq_pi_left {p₁ p₂ p₃ : P} (h : ∠ p₁ p₂ p₃ = π) : ∠ p₂ p₁ p₃ = 0 := by unfold angle at h rw [angle_eq_pi_iff] at h rcases h with ⟨hp₁p₂, ⟨r, ⟨hr, hpr⟩⟩⟩ unfold angle rw [angle_eq_zero_iff] rw [← neg_vsub_eq_vsub_rev, neg_ne_zero] at hp₁p₂ use hp₁p₂, -r + 1, add_pos (neg_pos_of_neg hr) zero_lt_one rw [add_smul, ← neg_vsub_eq_vsub_rev p₁ p₂, smul_neg] simp [← hpr] /-- If the angle ∠ABC at a point is π, the angle ∠BCA is 0. -/ theorem angle_eq_zero_of_angle_eq_pi_right {p₁ p₂ p₃ : P} (h : ∠ p₁ p₂ p₃ = π) : ∠ p₂ p₃ p₁ = 0 := by rw [angle_comm] at h exact angle_eq_zero_of_angle_eq_pi_left h /-- If ∠BCD = π, then ∠ABC = ∠ABD. -/ theorem angle_eq_angle_of_angle_eq_pi (p₁ : P) {p₂ p₃ p₄ : P} (h : ∠ p₂ p₃ p₄ = π) : ∠ p₁ p₂ p₃ = ∠ p₁ p₂ p₄ := by unfold angle at * rcases angle_eq_pi_iff.1 h with ⟨_, ⟨r, ⟨hr, hpr⟩⟩⟩ rw [eq_comm] convert angle_smul_right_of_pos (p₁ -ᵥ p₂) (p₃ -ᵥ p₂) (add_pos (neg_pos_of_neg hr) zero_lt_one) rw [add_smul, ← neg_vsub_eq_vsub_rev p₂ p₃, smul_neg, neg_smul, ← hpr] simp /-- If ∠BCD = π, then ∠ACB + ∠ACD = π. -/ nonrec theorem angle_add_angle_eq_pi_of_angle_eq_pi (p₁ : P) {p₂ p₃ p₄ : P} (h : ∠ p₂ p₃ p₄ = π) : ∠ p₁ p₃ p₂ + ∠ p₁ p₃ p₄ = π := by unfold angle at h rw [angle_comm p₁ p₃ p₂, angle_comm p₁ p₃ p₄] unfold angle exact angle_add_angle_eq_pi_of_angle_eq_pi _ h /-- Vertical Angles Theorem: angles opposite each other, formed by two intersecting straight lines, are equal. -/ theorem angle_eq_angle_of_angle_eq_pi_of_angle_eq_pi {p₁ p₂ p₃ p₄ p₅ : P} (hapc : ∠ p₁ p₅ p₃ = π) (hbpd : ∠ p₂ p₅ p₄ = π) : ∠ p₁ p₅ p₂ = ∠ p₃ p₅ p₄ := by linarith [angle_add_angle_eq_pi_of_angle_eq_pi p₁ hbpd, angle_comm p₄ p₅ p₁, angle_add_angle_eq_pi_of_angle_eq_pi p₄ hapc, angle_comm p₄ p₅ p₃] /-- If ∠ABC = π then dist A B ≠ 0. -/ theorem left_dist_ne_zero_of_angle_eq_pi {p₁ p₂ p₃ : P} (h : ∠ p₁ p₂ p₃ = π) : dist p₁ p₂ ≠ 0 := by by_contra heq rw [dist_eq_zero] at heq rw [heq, angle_self_left] at h exact Real.pi_ne_zero (by linarith) /-- If ∠ABC = π then dist C B ≠ 0. -/ theorem right_dist_ne_zero_of_angle_eq_pi {p₁ p₂ p₃ : P} (h : ∠ p₁ p₂ p₃ = π) : dist p₃ p₂ ≠ 0 := left_dist_ne_zero_of_angle_eq_pi <\| (angle_comm _ _ _).trans h /-- If ∠ABC = π, then (dist A C) = (dist A B) + (dist B C). -/ theorem dist_eq_add_dist_of_angle_eq_pi {p₁ p₂ p₃ : P} (h : ∠ p₁ p₂ p₃ = π) : dist p₁ p₃ = dist p₁ p₂ + dist p₃ p₂ := by rw [dist_eq_norm_vsub V, dist_eq_norm_vsub V, dist_eq_norm_vsub V, ← vsub_sub_vsub_cancel_right] exact norm_sub_eq_add_norm_of_angle_eq_pi h /-- If A ≠ B and C ≠ B then ∠ABC = π if and only if (dist A C) = (dist A B) + (dist B C). -/ theorem dist_eq_add_dist_iff_angle_eq_pi {p₁ p₂ p₃ : P} (hp₁p₂ : p₁ ≠ p₂) (hp₃p₂ : p₃ ≠ p₂) : dist p₁ p₃ = dist p₁ p₂ + dist p₃ p₂ ↔ ∠ p₁ p₂ p₃ = π := by rw [dist_eq_norm_vsub V, dist_eq_norm_vsub V, dist_eq_norm_vsub V, ← vsub_sub_vsub_cancel_right] exact norm_sub_eq_add_norm_iff_angle_eq_pi (fun he => hp₁p₂ (vsub_eq_zero_iff_eq.1 he)) fun he => hp₃p₂ (vsub_eq_zero_iff_eq.1 he) /-- If ∠ABC = 0, then (dist A C) = abs ((dist A B) - (dist B C)). -/ theorem dist_eq_abs_sub_dist_of_angle_eq_zero {p₁ p₂ p₃ : P} (h : ∠ p₁ p₂ p₃ = 0) : dist p₁ p₃ = \|dist p₁ p₂ - dist p₃ p₂\| := by rw [dist_eq_norm_vsub V, dist_eq_norm_vsub V, dist_eq_norm_vsub V, ← vsub_sub_vsub_cancel_right] exact norm_sub_eq_abs_sub_norm_of_angle_eq_zero h /-- If A ≠ B and C ≠ B then ∠ABC = 0 if and only if (dist A C) = abs ((dist A B) - (dist B C)). -/ theorem dist_eq_abs_sub_dist_iff_angle_eq_zero {p₁ p₂ p₃ : P} (hp₁p₂ : p₁ ≠ p₂) (hp₃p₂ : p₃ ≠ p₂) : dist p₁ p₃ = \|dist p₁ p₂ - dist p₃ p₂\| ↔ ∠ p₁ p₂ p₃ = 0 := by rw [dist_eq_norm_vsub V, dist_eq_norm_vsub V, dist_eq_norm_vsub V, ← vsub_sub_vsub_cancel_right] exact norm_sub_eq_abs_sub_norm_iff_angle_eq_zero (fun he => hp₁p₂ (vsub_eq_zero_iff_eq.1 he)) fun he => hp₃p₂ (vsub_eq_zero_iff_eq.1 he) /-- If M is the midpoint of the segment AB, then ∠AMB = π. -/ theorem angle_midpoint_eq_pi (p₁ p₂ : P) (hp₁p₂ : p₁ ≠ p₂) : ∠ p₁ (midpoint ℝ p₁ p₂) p₂ = π := by simp only [angle, left_vsub_midpoint, invOf_eq_inv, right_vsub_midpoint, inv_pos, zero_lt_two, angle_smul_right_of_pos, angle_smul_left_of_pos] rw [← neg_vsub_eq_vsub_rev p₁ p₂] apply angle_self_neg_of_nonzero	simpa only [ne_eq, vsub_eq_zero_iff_eq] /-- If M is the midpoint of the segment AB and C is the same distance from A as it is from B then ∠CMA = π / 2. -/	Mathlib/Geometry/Euclidean/Angle/Unoriented/Affine.lean	226	229
/- Copyright (c) 2022 Adam Topaz. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Adam Topaz, Junyan Xu -/ import Mathlib.RingTheory.Localization.LocalizationLocalization /-! # Localizations of domains as subalgebras of the fraction field. Given a domain `A` with fraction field `K`, and a submonoid `S` of `A` which does not contain zero, this file constructs the localization of `A` at `S` as a subalgebra of the field `K` over `A`. -/ namespace Localization open nonZeroDivisors variable {A : Type} (K : Type) [CommRing A] (S : Submonoid A) (hS : S ≤ A⁰) section CommRing variable [CommRing K] [Algebra A K] [IsFractionRing A K] theorem map_isUnit_of_le (hS : S ≤ A⁰) (s : S) : IsUnit (algebraMap A K s) := by apply IsLocalization.map_units K (⟨s.1, hS s.2⟩ : A⁰)	/-- The canonical map from a localization of `A` at `S` to the fraction ring	Mathlib/RingTheory/Localization/AsSubring.lean	31	32
/- Copyright (c) 2023 Oliver Nash. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Oliver Nash -/ import Mathlib.Algebra.Lie.Weights.Basic import Mathlib.LinearAlgebra.Trace import Mathlib.LinearAlgebra.FreeModule.PID /-! # Lie modules with linear weights Given a Lie module `M` over a nilpotent Lie algebra `L` with coefficients in `R`, one frequently studies `M` via its weights. These are functions `χ : L → R` whose corresponding weight space `LieModule.genWeightSpace M χ`, is non-trivial. If `L` is Abelian or if `R` has characteristic zero (and `M` is finite-dimensional) then such `χ` are necessarily `R`-linear. However in general non-linear weights do exist. For example if we take: * `R`: the field with two elements (or indeed any perfect field of characteristic two), * `L`: `sl₂` (this is nilpotent in characteristic two), * `M`: the natural two-dimensional representation of `L`, then there is a single weight and it is non-linear. (See remark following Proposition 9 of chapter VII, §1.3 in [N. Bourbaki, Chapters 7--9](bourbaki1975b).) We thus introduce a typeclass `LieModule.LinearWeights` to encode the fact that a Lie module does have linear weights and provide typeclass instances in the two important cases that `L` is Abelian or `R` has characteristic zero. ## Main definitions * `LieModule.LinearWeights`: a typeclass encoding the fact that a given Lie module has linear weights, and furthermore that the weights vanish on the derived ideal. * `LieModule.instLinearWeightsOfCharZero`: a typeclass instance encoding the fact that for an Abelian Lie algebra, the weights of any Lie module are linear. * `LieModule.instLinearWeightsOfIsLieAbelian`: a typeclass instance encoding the fact that in characteristic zero, the weights of any finite-dimensional Lie module are linear. * `LieModule.exists_forall_lie_eq_smul`: existence of simultaneous eigenvectors from existence of simultaneous generalized eigenvectors for Noetherian Lie modules with linear weights. -/ open Set variable (k R L M : Type*) [CommRing R] [LieRing L] [LieAlgebra R L] [AddCommGroup M] [Module R M] [LieRingModule L M] [LieModule R L M] namespace LieModule /-- A typeclass encoding the fact that a given Lie module has linear weights, vanishing on the derived ideal. -/ class LinearWeights [LieRing.IsNilpotent L] : Prop where map_add : ∀ χ : L → R, genWeightSpace M χ ≠ ⊥ → ∀ x y, χ (x + y) = χ x + χ y map_smul : ∀ χ : L → R, genWeightSpace M χ ≠ ⊥ → ∀ (t : R) x, χ (t • x) = t • χ x map_lie : ∀ χ : L → R, genWeightSpace M χ ≠ ⊥ → ∀ x y : L, χ ⁅x, y⁆ = 0 namespace Weight variable [LieRing.IsNilpotent L] [LinearWeights R L M] (χ : Weight R L M) /-- A weight of a Lie module, bundled as a linear map. -/ @[simps] def toLinear : L →ₗ[R] R where toFun := χ map_add' := LinearWeights.map_add χ χ.genWeightSpace_ne_bot map_smul' := LinearWeights.map_smul χ χ.genWeightSpace_ne_bot instance instCoeLinearMap : CoeOut (Weight R L M) (L →ₗ[R] R) where coe := Weight.toLinear R L M instance instLinearMapClass : LinearMapClass (Weight R L M) R L R where map_add χ := LinearWeights.map_add χ χ.genWeightSpace_ne_bot map_smulₛₗ χ := LinearWeights.map_smul χ χ.genWeightSpace_ne_bot variable {R L M χ} @[simp] lemma apply_lie (x y : L) : χ ⁅x, y⁆ = 0 := LinearWeights.map_lie χ χ.genWeightSpace_ne_bot x y @[simp] lemma coe_coe : (↑(χ : L →ₗ[R] R) : L → R) = (χ : L → R) := rfl @[simp] lemma coe_toLinear_eq_zero_iff : (χ : L →ₗ[R] R) = 0 ↔ χ.IsZero :=	⟨fun h ↦ funext fun x ↦ LinearMap.congr_fun h x, fun h ↦ by ext; simp [h.eq]⟩	Mathlib/Algebra/Lie/Weights/Linear.lean	84	85
/- Copyright (c) 2021 Kexing Ying. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kexing Ying -/ import Mathlib.MeasureTheory.VectorMeasure.Basic import Mathlib.Analysis.Complex.Basic /-! # Complex measure This file defines a complex measure to be a vector measure with codomain `ℂ`. Then we prove some elementary results about complex measures. In particular, we prove that a complex measure is always in the form `s + it` where `s` and `t` are signed measures. ## Main definitions * `MeasureTheory.ComplexMeasure.re`: obtains a signed measure `s` from a complex measure `c` such that `s i = (c i).re` for all measurable sets `i`. * `MeasureTheory.ComplexMeasure.im`: obtains a signed measure `s` from a complex measure `c` such that `s i = (c i).im` for all measurable sets `i`. * `MeasureTheory.SignedMeasure.toComplexMeasure`: given two signed measures `s` and `t`, `s.to_complex_measure t` provides a complex measure of the form `s + it`. * `MeasureTheory.ComplexMeasure.equivSignedMeasure`: is the equivalence between the complex measures and the type of the product of the signed measures with itself. ## Tags Complex measure -/ noncomputable section open scoped MeasureTheory ENNReal NNReal variable {α : Type} {m : MeasurableSpace α} namespace MeasureTheory open VectorMeasure /-- A `ComplexMeasure` is a `ℂ`-vector measure. -/ abbrev ComplexMeasure (α : Type) [MeasurableSpace α] := VectorMeasure α ℂ namespace ComplexMeasure /-- The real part of a complex measure is a signed measure. -/ @[simps! apply] def re : ComplexMeasure α →ₗ[ℝ] SignedMeasure α := mapRangeₗ Complex.reCLM Complex.continuous_re /-- The imaginary part of a complex measure is a signed measure. -/ @[simps! apply] def im : ComplexMeasure α →ₗ[ℝ] SignedMeasure α := mapRangeₗ Complex.imCLM Complex.continuous_im /-- Given `s` and `t` signed measures, `s + it` is a complex measure -/ @[simps!] def _root_.MeasureTheory.SignedMeasure.toComplexMeasure (s t : SignedMeasure α) : ComplexMeasure α where measureOf' i := ⟨s i, t i⟩ empty' := by rw [s.empty, t.empty]; rfl not_measurable' i hi := by rw [s.not_measurable hi, t.not_measurable hi]; rfl m_iUnion' _ hf hfdisj := (Complex.hasSum_iff _ _).2 ⟨s.m_iUnion hf hfdisj, t.m_iUnion hf hfdisj⟩ theorem _root_.MeasureTheory.SignedMeasure.toComplexMeasure_apply {s t : SignedMeasure α} {i : Set α} : s.toComplexMeasure t i = ⟨s i, t i⟩ := rfl theorem toComplexMeasure_to_signedMeasure (c : ComplexMeasure α) : SignedMeasure.toComplexMeasure (ComplexMeasure.re c) (ComplexMeasure.im c) = c := rfl theorem _root_.MeasureTheory.SignedMeasure.re_toComplexMeasure (s t : SignedMeasure α) : ComplexMeasure.re (SignedMeasure.toComplexMeasure s t) = s := rfl theorem _root_.MeasureTheory.SignedMeasure.im_toComplexMeasure (s t : SignedMeasure α) : ComplexMeasure.im (SignedMeasure.toComplexMeasure s t) = t := rfl /-- The complex measures form an equivalence to the type of pairs of signed measures. -/ @[simps] def equivSignedMeasure : ComplexMeasure α ≃ SignedMeasure α × SignedMeasure α where toFun c := ⟨ComplexMeasure.re c, ComplexMeasure.im c⟩ invFun := fun ⟨s, t⟩ => s.toComplexMeasure t left_inv c := c.toComplexMeasure_to_signedMeasure right_inv := fun ⟨s, t⟩ => Prod.ext (s.re_toComplexMeasure t) (s.im_toComplexMeasure t) section variable {R : Type*} [Semiring R] [Module R ℝ] variable [ContinuousConstSMul R ℝ] [ContinuousConstSMul R ℂ] /-- The complex measures form a linear isomorphism to the type of pairs of signed measures. -/ @[simps] def equivSignedMeasureₗ : ComplexMeasure α ≃ₗ[R] SignedMeasure α × SignedMeasure α := { equivSignedMeasure with map_add' := fun c d => by rfl map_smul' := by intro r c dsimp ext · simp [Complex.smul_re] · simp [Complex.smul_im] } end theorem absolutelyContinuous_ennreal_iff (c : ComplexMeasure α) (μ : VectorMeasure α ℝ≥0∞) : c ≪ᵥ μ ↔ ComplexMeasure.re c ≪ᵥ μ ∧ ComplexMeasure.im c ≪ᵥ μ := by constructor <;> intro h · constructor <;> · intro i hi; simp [h hi] · intro i hi rw [← Complex.re_add_im (c i), (_ : (c i).re = 0), (_ : (c i).im = 0)] exacts [by simp, h.2 hi, h.1 hi] end ComplexMeasure	end MeasureTheory	Mathlib/MeasureTheory/Measure/Complex.lean	116	122
/- Copyright (c) 2022 Rémi Bottinelli. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémi Bottinelli, Junyan Xu -/ import Mathlib.Algebra.Group.Subgroup.Defs import Mathlib.CategoryTheory.Groupoid.VertexGroup import Mathlib.CategoryTheory.Groupoid.Basic import Mathlib.CategoryTheory.Groupoid import Mathlib.Data.Set.Lattice /-! # Subgroupoid This file defines subgroupoids as `structure`s containing the subsets of arrows and their stability under composition and inversion. Also defined are: * containment of subgroupoids is a complete lattice; * images and preimages of subgroupoids under a functor; * the notion of normality of subgroupoids and its stability under intersection and preimage; * compatibility of the above with `CategoryTheory.Groupoid.vertexGroup`. ## Main definitions Given a type `C` with associated `groupoid C` instance. * `CategoryTheory.Subgroupoid C` is the type of subgroupoids of `C` * `CategoryTheory.Subgroupoid.IsNormal` is the property that the subgroupoid is stable under conjugation by arbitrary arrows, _and_ that all identity arrows are contained in the subgroupoid. * `CategoryTheory.Subgroupoid.comap` is the "preimage" map of subgroupoids along a functor. * `CategoryTheory.Subgroupoid.map` is the "image" map of subgroupoids along a functor _injective on objects_. * `CategoryTheory.Subgroupoid.vertexSubgroup` is the subgroup of the vertex group at a given vertex `v`, assuming `v` is contained in the `CategoryTheory.Subgroupoid` (meaning, by definition, that the arrow `𝟙 v` is contained in the subgroupoid). ## Implementation details The structure of this file is copied from/inspired by `Mathlib/GroupTheory/Subgroup/Basic.lean` and `Mathlib/Combinatorics/SimpleGraph/Subgraph.lean`. ## TODO * Equivalent inductive characterization of generated (normal) subgroupoids. * Characterization of normal subgroupoids as kernels. * Prove that `CategoryTheory.Subgroupoid.full` and `CategoryTheory.Subgroupoid.disconnect` preserve intersections (and `CategoryTheory.Subgroupoid.disconnect` also unions) ## Tags category theory, groupoid, subgroupoid -/ namespace CategoryTheory open Set Groupoid universe u v variable {C : Type u} [Groupoid C] /-- A sugroupoid of `C` consists of a choice of arrows for each pair of vertices, closed under composition and inverses. -/ @[ext] structure Subgroupoid (C : Type u) [Groupoid C] where /-- The arrow choice for each pair of vertices -/ arrows : ∀ c d : C, Set (c ⟶ d) protected inv : ∀ {c d} {p : c ⟶ d}, p ∈ arrows c d → Groupoid.inv p ∈ arrows d c protected mul : ∀ {c d e} {p}, p ∈ arrows c d → ∀ {q}, q ∈ arrows d e → p ≫ q ∈ arrows c e namespace Subgroupoid variable (S : Subgroupoid C) theorem inv_mem_iff {c d : C} (f : c ⟶ d) : Groupoid.inv f ∈ S.arrows d c ↔ f ∈ S.arrows c d := by constructor · intro h simpa only [inv_eq_inv, IsIso.inv_inv] using S.inv h · apply S.inv theorem mul_mem_cancel_left {c d e : C} {f : c ⟶ d} {g : d ⟶ e} (hf : f ∈ S.arrows c d) : f ≫ g ∈ S.arrows c e ↔ g ∈ S.arrows d e := by constructor · rintro h suffices Groupoid.inv f ≫ f ≫ g ∈ S.arrows d e by simpa only [inv_eq_inv, IsIso.inv_hom_id_assoc] using this apply S.mul (S.inv hf) h · apply S.mul hf theorem mul_mem_cancel_right {c d e : C} {f : c ⟶ d} {g : d ⟶ e} (hg : g ∈ S.arrows d e) : f ≫ g ∈ S.arrows c e ↔ f ∈ S.arrows c d := by constructor · rintro h suffices (f ≫ g) ≫ Groupoid.inv g ∈ S.arrows c d by simpa only [inv_eq_inv, IsIso.hom_inv_id, Category.comp_id, Category.assoc] using this apply S.mul h (S.inv hg) · exact fun hf => S.mul hf hg /-- The vertices of `C` on which `S` has non-trivial isotropy -/ def objs : Set C := {c : C \| (S.arrows c c).Nonempty} theorem mem_objs_of_src {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : c ∈ S.objs := ⟨f ≫ Groupoid.inv f, S.mul h (S.inv h)⟩ theorem mem_objs_of_tgt {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : d ∈ S.objs := ⟨Groupoid.inv f ≫ f, S.mul (S.inv h) h⟩ theorem id_mem_of_nonempty_isotropy (c : C) : c ∈ objs S → 𝟙 c ∈ S.arrows c c := by rintro ⟨γ, hγ⟩ convert S.mul hγ (S.inv hγ) simp only [inv_eq_inv, IsIso.hom_inv_id] theorem id_mem_of_src {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : 𝟙 c ∈ S.arrows c c := id_mem_of_nonempty_isotropy S c (mem_objs_of_src S h) theorem id_mem_of_tgt {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : 𝟙 d ∈ S.arrows d d := id_mem_of_nonempty_isotropy S d (mem_objs_of_tgt S h) /-- A subgroupoid seen as a quiver on vertex set `C` -/ def asWideQuiver : Quiver C := ⟨fun c d => Subtype <\| S.arrows c d⟩ /-- The coercion of a subgroupoid as a groupoid -/ @[simps comp_coe, simps -isSimp inv_coe] instance coe : Groupoid S.objs where Hom a b := S.arrows a.val b.val id a := ⟨𝟙 a.val, id_mem_of_nonempty_isotropy S a.val a.prop⟩ comp p q := ⟨p.val ≫ q.val, S.mul p.prop q.prop⟩ inv p := ⟨Groupoid.inv p.val, S.inv p.prop⟩ @[simp] theorem coe_inv_coe' {c d : S.objs} (p : c ⟶ d) : (CategoryTheory.inv p).val = CategoryTheory.inv p.val := by simp only [← inv_eq_inv, coe_inv_coe] /-- The embedding of the coerced subgroupoid to its parent -/ def hom : S.objs ⥤ C where obj c := c.val map f := f.val map_id _ := rfl map_comp _ _ := rfl theorem hom.inj_on_objects : Function.Injective (hom S).obj := by rintro ⟨c, hc⟩ ⟨d, hd⟩ hcd simp only [Subtype.mk_eq_mk]; exact hcd theorem hom.faithful : ∀ c d, Function.Injective fun f : c ⟶ d => (hom S).map f := by rintro ⟨c, hc⟩ ⟨d, hd⟩ ⟨f, hf⟩ ⟨g, hg⟩ hfg; exact Subtype.eq hfg /-- The subgroup of the vertex group at `c` given by the subgroupoid -/ def vertexSubgroup {c : C} (hc : c ∈ S.objs) : Subgroup (c ⟶ c) where carrier := S.arrows c c mul_mem' hf hg := S.mul hf hg one_mem' := id_mem_of_nonempty_isotropy _ _ hc inv_mem' hf := S.inv hf /-- The set of all arrows of a subgroupoid, as a set in `Σ c d : C, c ⟶ d`. -/ @[coe] def toSet (S : Subgroupoid C) : Set (Σ c d : C, c ⟶ d) := {F \| F.2.2 ∈ S.arrows F.1 F.2.1} instance : SetLike (Subgroupoid C) (Σ c d : C, c ⟶ d) where coe := toSet coe_injective' := fun ⟨S, _, _⟩ ⟨T, _, _⟩ h => by ext c d f; apply Set.ext_iff.1 h ⟨c, d, f⟩ theorem mem_iff (S : Subgroupoid C) (F : Σ c d, c ⟶ d) : F ∈ S ↔ F.2.2 ∈ S.arrows F.1 F.2.1 := Iff.rfl theorem le_iff (S T : Subgroupoid C) : S ≤ T ↔ ∀ {c d}, S.arrows c d ⊆ T.arrows c d := by rw [SetLike.le_def, Sigma.forall]; exact forall_congr' fun c => Sigma.forall instance : Top (Subgroupoid C) := ⟨{ arrows := fun _ _ => Set.univ mul := by intros; trivial inv := by intros; trivial }⟩ theorem mem_top {c d : C} (f : c ⟶ d) : f ∈ (⊤ : Subgroupoid C).arrows c d := trivial theorem mem_top_objs (c : C) : c ∈ (⊤ : Subgroupoid C).objs := by dsimp [Top.top, objs] simp only [univ_nonempty] instance : Bot (Subgroupoid C) := ⟨{ arrows := fun _ _ => ∅ mul := False.elim inv := False.elim }⟩ instance : Inhabited (Subgroupoid C) := ⟨⊤⟩ instance : Min (Subgroupoid C) := ⟨fun S T => { arrows := fun c d => S.arrows c d ∩ T.arrows c d inv := fun hp ↦ ⟨S.inv hp.1, T.inv hp.2⟩ mul := fun hp _ hq ↦ ⟨S.mul hp.1 hq.1, T.mul hp.2 hq.2⟩ }⟩ instance : InfSet (Subgroupoid C) := ⟨fun s => { arrows := fun c d => ⋂ S ∈ s, Subgroupoid.arrows S c d inv := fun hp ↦ by rw [mem_iInter₂] at hp ⊢; exact fun S hS => S.inv (hp S hS) mul := fun hp _ hq ↦ by rw [mem_iInter₂] at hp hq ⊢ exact fun S hS => S.mul (hp S hS) (hq S hS) }⟩ theorem mem_sInf_arrows {s : Set (Subgroupoid C)} {c d : C} {p : c ⟶ d} : p ∈ (sInf s).arrows c d ↔ ∀ S ∈ s, p ∈ S.arrows c d := mem_iInter₂ theorem mem_sInf {s : Set (Subgroupoid C)} {p : Σ c d : C, c ⟶ d} : p ∈ sInf s ↔ ∀ S ∈ s, p ∈ S := mem_sInf_arrows instance : CompleteLattice (Subgroupoid C) := { completeLatticeOfInf (Subgroupoid C) (by refine fun s => ⟨fun S Ss F => ?_, fun T Tl F fT => ?_⟩ <;> simp only [mem_sInf] exacts [fun hp => hp S Ss, fun S Ss => Tl Ss fT]) with bot := ⊥ bot_le := fun _ => empty_subset _ top := ⊤ le_top := fun _ => subset_univ _ inf := (· ⊓ ·) le_inf := fun _ _ _ RS RT _ pR => ⟨RS pR, RT pR⟩ inf_le_left := fun _ _ _ => And.left inf_le_right := fun _ _ _ => And.right } theorem le_objs {S T : Subgroupoid C} (h : S ≤ T) : S.objs ⊆ T.objs := fun s ⟨γ, hγ⟩ => ⟨γ, @h ⟨s, s, γ⟩ hγ⟩ /-- The functor associated to the embedding of subgroupoids -/ def inclusion {S T : Subgroupoid C} (h : S ≤ T) : S.objs ⥤ T.objs where obj s := ⟨s.val, le_objs h s.prop⟩ map f := ⟨f.val, @h ⟨_, _, f.val⟩ f.prop⟩ map_id _ := rfl map_comp _ _ := rfl theorem inclusion_inj_on_objects {S T : Subgroupoid C} (h : S ≤ T) : Function.Injective (inclusion h).obj := fun ⟨s, hs⟩ ⟨t, ht⟩ => by simpa only [inclusion, Subtype.mk_eq_mk] using id theorem inclusion_faithful {S T : Subgroupoid C} (h : S ≤ T) (s t : S.objs) : Function.Injective fun f : s ⟶ t => (inclusion h).map f := fun ⟨f, hf⟩ ⟨g, hg⟩ => by -- Porting note: was `...; simpa only [Subtype.mk_eq_mk] using id` dsimp only [inclusion]; rw [Subtype.mk_eq_mk, Subtype.mk_eq_mk]; exact id theorem inclusion_refl {S : Subgroupoid C} : inclusion (le_refl S) = 𝟭 S.objs := Functor.hext (fun _ => rfl) fun _ _ _ => HEq.refl _ theorem inclusion_trans {R S T : Subgroupoid C} (k : R ≤ S) (h : S ≤ T) : inclusion (k.trans h) = inclusion k ⋙ inclusion h := rfl theorem inclusion_comp_embedding {S T : Subgroupoid C} (h : S ≤ T) : inclusion h ⋙ T.hom = S.hom := rfl /-- The family of arrows of the discrete groupoid -/ inductive Discrete.Arrows : ∀ c d : C, (c ⟶ d) → Prop \| id (c : C) : Discrete.Arrows c c (𝟙 c) /-- The only arrows of the discrete groupoid are the identity arrows. -/ def discrete : Subgroupoid C where arrows c d := {p \| Discrete.Arrows c d p} inv := by rintro _ _ _ ⟨⟩; simp only [inv_eq_inv, IsIso.inv_id]; constructor mul := by rintro _ _ _ _ ⟨⟩ _ ⟨⟩; rw [Category.comp_id]; constructor theorem mem_discrete_iff {c d : C} (f : c ⟶ d) : f ∈ discrete.arrows c d ↔ ∃ h : c = d, f = eqToHom h := ⟨by rintro ⟨⟩; exact ⟨rfl, rfl⟩, by rintro ⟨rfl, rfl⟩; constructor⟩ /-- A subgroupoid is wide if its carrier set is all of `C`. -/ structure IsWide : Prop where wide : ∀ c, 𝟙 c ∈ S.arrows c c theorem isWide_iff_objs_eq_univ : S.IsWide ↔ S.objs = Set.univ := by constructor · rintro h ext x; constructor <;> simp only [top_eq_univ, mem_univ, imp_true_iff, forall_true_left] apply mem_objs_of_src S (h.wide x) · rintro h refine ⟨fun c => ?_⟩ obtain ⟨γ, γS⟩ := (le_of_eq h.symm : ⊤ ⊆ S.objs) (Set.mem_univ c) exact id_mem_of_src S γS theorem IsWide.id_mem {S : Subgroupoid C} (Sw : S.IsWide) (c : C) : 𝟙 c ∈ S.arrows c c := Sw.wide c theorem IsWide.eqToHom_mem {S : Subgroupoid C} (Sw : S.IsWide) {c d : C} (h : c = d) : eqToHom h ∈ S.arrows c d := by cases h; simp only [eqToHom_refl]; apply Sw.id_mem c /-- A subgroupoid is normal if it is wide and satisfies the expected stability under conjugacy. -/ structure IsNormal : Prop extends IsWide S where conj : ∀ {c d} (p : c ⟶ d) {γ : c ⟶ c}, γ ∈ S.arrows c c → Groupoid.inv p ≫ γ ≫ p ∈ S.arrows d d theorem IsNormal.conj' {S : Subgroupoid C} (Sn : IsNormal S) : ∀ {c d} (p : d ⟶ c) {γ : c ⟶ c}, γ ∈ S.arrows c c → p ≫ γ ≫ Groupoid.inv p ∈ S.arrows d d := fun p γ hs => by convert Sn.conj (Groupoid.inv p) hs; simp theorem IsNormal.conjugation_bij (Sn : IsNormal S) {c d} (p : c ⟶ d) : Set.BijOn (fun γ : c ⟶ c => Groupoid.inv p ≫ γ ≫ p) (S.arrows c c) (S.arrows d d) := by refine ⟨fun γ γS => Sn.conj p γS, fun γ₁ _ γ₂ _ h => ?_, fun δ δS => ⟨p ≫ δ ≫ Groupoid.inv p, Sn.conj' p δS, ?_⟩⟩ · simpa only [inv_eq_inv, Category.assoc, IsIso.hom_inv_id, Category.comp_id, IsIso.hom_inv_id_assoc] using p ≫= h =≫ inv p · simp only [inv_eq_inv, Category.assoc, IsIso.inv_hom_id, Category.comp_id, IsIso.inv_hom_id_assoc] theorem top_isNormal : IsNormal (⊤ : Subgroupoid C) := { wide := fun _ => trivial conj := fun _ _ _ => trivial } theorem sInf_isNormal (s : Set <\| Subgroupoid C) (sn : ∀ S ∈ s, IsNormal S) : IsNormal (sInf s) := { wide := by simp_rw [sInf, mem_iInter₂]; exact fun c S Ss => (sn S Ss).wide c conj := by simp_rw [sInf, mem_iInter₂]; exact fun p γ hγ S Ss => (sn S Ss).conj p (hγ S Ss) } theorem discrete_isNormal : (@discrete C _).IsNormal := { wide := fun c => by constructor conj := fun f γ hγ => by cases hγ simp only [inv_eq_inv, Category.id_comp, IsIso.inv_hom_id]; constructor } theorem IsNormal.vertexSubgroup (Sn : IsNormal S) (c : C) (cS : c ∈ S.objs) : (S.vertexSubgroup cS).Normal where conj_mem x hx y := by rw [mul_assoc]; exact Sn.conj' y hx section GeneratedSubgroupoid -- TODO: proof that generated is just "words in X" and generatedNormal is similarly variable (X : ∀ c d : C, Set (c ⟶ d)) /-- The subgropoid generated by the set of arrows `X` -/ def generated : Subgroupoid C := sInf {S : Subgroupoid C \| ∀ c d, X c d ⊆ S.arrows c d} theorem subset_generated (c d : C) : X c d ⊆ (generated X).arrows c d := by dsimp only [generated, sInf] simp only [subset_iInter₂_iff] exact fun S hS f fS => hS _ _ fS /-- The normal sugroupoid generated by the set of arrows `X` -/ def generatedNormal : Subgroupoid C := sInf {S : Subgroupoid C \| (∀ c d, X c d ⊆ S.arrows c d) ∧ S.IsNormal} theorem generated_le_generatedNormal : generated X ≤ generatedNormal X := by apply @sInf_le_sInf (Subgroupoid C) _ exact fun S ⟨h, _⟩ => h theorem generatedNormal_isNormal : (generatedNormal X).IsNormal := sInf_isNormal _ fun _ h => h.right theorem IsNormal.generatedNormal_le {S : Subgroupoid C} (Sn : S.IsNormal) : generatedNormal X ≤ S ↔ ∀ c d, X c d ⊆ S.arrows c d := by constructor · rintro h c d have h' := generated_le_generatedNormal X rw [le_iff] at h h' exact ((subset_generated X c d).trans (@h' c d)).trans (@h c d) · rintro h apply @sInf_le (Subgroupoid C) _ exact ⟨h, Sn⟩ end GeneratedSubgroupoid section Hom variable {D : Type} [Groupoid D] (φ : C ⥤ D) /-- A functor between groupoid defines a map of subgroupoids in the reverse direction by taking preimages. -/ def comap (S : Subgroupoid D) : Subgroupoid C where arrows c d := {f : c ⟶ d \| φ.map f ∈ S.arrows (φ.obj c) (φ.obj d)} inv hp := by rw [mem_setOf, inv_eq_inv, φ.map_inv, ← inv_eq_inv]; exact S.inv hp mul := by intros simp only [mem_setOf, Functor.map_comp] apply S.mul <;> assumption theorem comap_mono (S T : Subgroupoid D) : S ≤ T → comap φ S ≤ comap φ T := fun ST _ => @ST ⟨_, _, _⟩ theorem isNormal_comap {S : Subgroupoid D} (Sn : IsNormal S) : IsNormal (comap φ S) where wide c := by rw [comap, mem_setOf, Functor.map_id]; apply Sn.wide conj f γ hγ := by simp_rw [inv_eq_inv f, comap, mem_setOf, Functor.map_comp, Functor.map_inv, ← inv_eq_inv] exact Sn.conj _ hγ @[simp] theorem comap_comp {E : Type} [Groupoid E] (ψ : D ⥤ E) : comap (φ ⋙ ψ) = comap φ ∘ comap ψ := rfl /-- The kernel of a functor between subgroupoid is the preimage. -/ def ker : Subgroupoid C := comap φ discrete theorem mem_ker_iff {c d : C} (f : c ⟶ d) : f ∈ (ker φ).arrows c d ↔ ∃ h : φ.obj c = φ.obj d, φ.map f = eqToHom h := mem_discrete_iff (φ.map f) theorem ker_isNormal : (ker φ).IsNormal := isNormal_comap φ discrete_isNormal @[simp] theorem ker_comp {E : Type*} [Groupoid E] (ψ : D ⥤ E) : ker (φ ⋙ ψ) = comap φ (ker ψ) := rfl /-- The family of arrows of the image of a subgroupoid under a functor injective on objects -/ inductive Map.Arrows (hφ : Function.Injective φ.obj) (S : Subgroupoid C) : ∀ c d : D, (c ⟶ d) → Prop \| im {c d : C} (f : c ⟶ d) (hf : f ∈ S.arrows c d) : Map.Arrows hφ S (φ.obj c) (φ.obj d) (φ.map f) theorem Map.arrows_iff (hφ : Function.Injective φ.obj) (S : Subgroupoid C) {c d : D} (f : c ⟶ d) : Map.Arrows φ hφ S c d f ↔ ∃ (a b : C) (g : a ⟶ b) (ha : φ.obj a = c) (hb : φ.obj b = d) (_hg : g ∈ S.arrows a b), f = eqToHom ha.symm ≫ φ.map g ≫ eqToHom hb := by constructor · rintro ⟨g, hg⟩; exact ⟨_, _, g, rfl, rfl, hg, eq_conj_eqToHom _⟩ · rintro ⟨a, b, g, rfl, rfl, hg, rfl⟩; rw [← eq_conj_eqToHom]; constructor; exact hg /-- The "forward" image of a subgroupoid under a functor injective on objects -/ def map (hφ : Function.Injective φ.obj) (S : Subgroupoid C) : Subgroupoid D where arrows c d := {x \| Map.Arrows φ hφ S c d x} inv := by rintro _ _ _ ⟨⟩ rw [inv_eq_inv, ← Functor.map_inv, ← inv_eq_inv] constructor; apply S.inv; assumption mul := by rintro _ _ _ _ ⟨f, hf⟩ q hq obtain ⟨c₃, c₄, g, he, rfl, hg, gq⟩ := (Map.arrows_iff φ hφ S q).mp hq cases hφ he; rw [gq, ← eq_conj_eqToHom, ← φ.map_comp] constructor; exact S.mul hf hg theorem mem_map_iff (hφ : Function.Injective φ.obj) (S : Subgroupoid C) {c d : D} (f : c ⟶ d) : f ∈ (map φ hφ S).arrows c d ↔ ∃ (a b : C) (g : a ⟶ b) (ha : φ.obj a = c) (hb : φ.obj b = d) (_hg : g ∈ S.arrows a b), f = eqToHom ha.symm ≫ φ.map g ≫ eqToHom hb := Map.arrows_iff φ hφ S f theorem galoisConnection_map_comap (hφ : Function.Injective φ.obj) : GaloisConnection (map φ hφ) (comap φ) := by rintro S T; simp_rw [le_iff]; constructor · exact fun h c d f fS => h (Map.Arrows.im f fS) · rintro h _ _ g ⟨a, gφS⟩ exact h gφS theorem map_mono (hφ : Function.Injective φ.obj) (S T : Subgroupoid C) : S ≤ T → map φ hφ S ≤ map φ hφ T := fun h => (galoisConnection_map_comap φ hφ).monotone_l h theorem le_comap_map (hφ : Function.Injective φ.obj) (S : Subgroupoid C) : S ≤ comap φ (map φ hφ S) := (galoisConnection_map_comap φ hφ).le_u_l S theorem map_comap_le (hφ : Function.Injective φ.obj) (T : Subgroupoid D) : map φ hφ (comap φ T) ≤ T := (galoisConnection_map_comap φ hφ).l_u_le T theorem map_le_iff_le_comap (hφ : Function.Injective φ.obj) (S : Subgroupoid C) (T : Subgroupoid D) : map φ hφ S ≤ T ↔ S ≤ comap φ T := (galoisConnection_map_comap φ hφ).le_iff_le theorem mem_map_objs_iff (hφ : Function.Injective φ.obj) (d : D) : d ∈ (map φ hφ S).objs ↔ ∃ c ∈ S.objs, φ.obj c = d := by dsimp [objs, map] constructor · rintro ⟨f, hf⟩ change Map.Arrows φ hφ S d d f at hf; rw [Map.arrows_iff] at hf obtain ⟨c, d, g, ec, ed, eg, gS, eg⟩ := hf exact ⟨c, ⟨mem_objs_of_src S eg, ec⟩⟩ · rintro ⟨c, ⟨γ, γS⟩, rfl⟩ exact ⟨φ.map γ, ⟨γ, γS⟩⟩ @[simp] theorem map_objs_eq (hφ : Function.Injective φ.obj) : (map φ hφ S).objs = φ.obj '' S.objs := by ext x; convert mem_map_objs_iff S φ hφ x /-- The image of a functor injective on objects -/ def im (hφ : Function.Injective φ.obj) := map φ hφ ⊤ theorem mem_im_iff (hφ : Function.Injective φ.obj) {c d : D} (f : c ⟶ d) : f ∈ (im φ hφ).arrows c d ↔ ∃ (a b : C) (g : a ⟶ b) (ha : φ.obj a = c) (hb : φ.obj b = d), f = eqToHom ha.symm ≫ φ.map g ≫ eqToHom hb := by convert Map.arrows_iff φ hφ ⊤ f; simp only [Top.top, mem_univ, exists_true_left] theorem mem_im_objs_iff (hφ : Function.Injective φ.obj) (d : D) : d ∈ (im φ hφ).objs ↔ ∃ c : C, φ.obj c = d := by simp only [im, mem_map_objs_iff, mem_top_objs, true_and] theorem obj_surjective_of_im_eq_top (hφ : Function.Injective φ.obj) (hφ' : im φ hφ = ⊤) : Function.Surjective φ.obj := by rintro d rw [← mem_im_objs_iff, hφ'] apply mem_top_objs theorem isNormal_map (hφ : Function.Injective φ.obj) (hφ' : im φ hφ = ⊤) (Sn : S.IsNormal) : (map φ hφ S).IsNormal := { wide := fun d => by obtain ⟨c, rfl⟩ := obj_surjective_of_im_eq_top φ hφ hφ' d change Map.Arrows φ hφ S _ _ (𝟙 _); rw [← Functor.map_id] constructor; exact Sn.wide c conj := fun {d d'} g δ hδ => by rw [mem_map_iff] at hδ obtain ⟨c, c', γ, cd, cd', γS, hγ⟩ := hδ; subst_vars; cases hφ cd' have : d' ∈ (im φ hφ).objs := by rw [hφ']; apply mem_top_objs rw [mem_im_objs_iff] at this obtain ⟨c', rfl⟩ := this have : g ∈ (im φ hφ).arrows (φ.obj c) (φ.obj c') := by rw [hφ']; trivial rw [mem_im_iff] at this obtain ⟨b, b', f, hb, hb', _, hf⟩ := this; cases hφ hb; cases hφ hb' change Map.Arrows φ hφ S (φ.obj c') (φ.obj c') _ simp only [eqToHom_refl, Category.comp_id, Category.id_comp, inv_eq_inv] suffices Map.Arrows φ hφ S (φ.obj c') (φ.obj c') (φ.map <\| Groupoid.inv f ≫ γ ≫ f) by simp only [inv_eq_inv, Functor.map_comp, Functor.map_inv] at this; exact this constructor; apply Sn.conj f γS } end Hom section Thin /-- A subgroupoid is thin (`CategoryTheory.Subgroupoid.IsThin`) if it has at most one arrow between any two vertices. -/ abbrev IsThin := Quiver.IsThin S.objs nonrec theorem isThin_iff : S.IsThin ↔ ∀ c : S.objs, Subsingleton (S.arrows c c) := isThin_iff _ end Thin section Disconnected /-- A subgroupoid `IsTotallyDisconnected` if it has only isotropy arrows. -/ nonrec abbrev IsTotallyDisconnected := IsTotallyDisconnected S.objs theorem isTotallyDisconnected_iff : S.IsTotallyDisconnected ↔ ∀ c d, (S.arrows c d).Nonempty → c = d := by constructor · rintro h c d ⟨f, fS⟩ exact congr_arg Subtype.val <\| h ⟨c, mem_objs_of_src S fS⟩ ⟨d, mem_objs_of_tgt S fS⟩ ⟨f, fS⟩ · rintro h ⟨c, hc⟩ ⟨d, hd⟩ ⟨f, fS⟩ simp only [Subtype.mk_eq_mk] exact h c d ⟨f, fS⟩ /-- The isotropy subgroupoid of `S` -/ def disconnect : Subgroupoid C where arrows c d := {f \| c = d ∧ f ∈ S.arrows c d} inv := by rintro _ _ _ ⟨rfl, h⟩; exact ⟨rfl, S.inv h⟩ mul := by rintro _ _ _ _ ⟨rfl, h⟩ _ ⟨rfl, h'⟩; exact ⟨rfl, S.mul h h'⟩ theorem disconnect_le : S.disconnect ≤ S := by rw [le_iff]; rintro _ _ _ ⟨⟩; assumption theorem disconnect_normal (Sn : S.IsNormal) : S.disconnect.IsNormal := { wide := fun c => ⟨rfl, Sn.wide c⟩ conj := fun _ _ ⟨_, h'⟩ => ⟨rfl, Sn.conj _ h'⟩ } @[simp] theorem mem_disconnect_objs_iff {c : C} : c ∈ S.disconnect.objs ↔ c ∈ S.objs := ⟨fun ⟨γ, _, γS⟩ => ⟨γ, γS⟩, fun ⟨γ, γS⟩ => ⟨γ, rfl, γS⟩⟩ theorem disconnect_objs : S.disconnect.objs = S.objs := Set.ext fun _ ↦ mem_disconnect_objs_iff _ theorem disconnect_isTotallyDisconnected : S.disconnect.IsTotallyDisconnected := by rw [isTotallyDisconnected_iff]; exact fun c d ⟨_, h, _⟩ => h end Disconnected section Full variable (D : Set C) /-- The full subgroupoid on a set `D : Set C` -/ def full : Subgroupoid C where arrows c d := {_f \| c ∈ D ∧ d ∈ D} inv := by rintro _ _ _ ⟨⟩; constructor <;> assumption mul := by rintro _ _ _ _ ⟨⟩ _ ⟨⟩; constructor <;> assumption theorem full_objs : (full D).objs = D := Set.ext fun _ => ⟨fun ⟨_, h, _⟩ => h, fun h => ⟨𝟙 _, h, h⟩⟩ @[simp] theorem mem_full_iff {c d : C} {f : c ⟶ d} : f ∈ (full D).arrows c d ↔ c ∈ D ∧ d ∈ D := Iff.rfl @[simp] theorem mem_full_objs_iff {c : C} : c ∈ (full D).objs ↔ c ∈ D := by rw [full_objs] @[simp] theorem full_empty : full ∅ = (⊥ : Subgroupoid C) := by ext simp only [Bot.bot, mem_full_iff, mem_empty_iff_false, and_self_iff] @[simp] theorem full_univ : full Set.univ = (⊤ : Subgroupoid C) := by ext simp only [mem_full_iff, mem_univ, and_self, mem_top] theorem full_mono {D E : Set C} (h : D ≤ E) : full D ≤ full E := by rw [le_iff] rintro c d f simp only [mem_full_iff] exact fun ⟨hc, hd⟩ => ⟨h hc, h hd⟩ -- Porting note: using `.1` instead of `↑` theorem full_arrow_eq_iff {c d : (full D).objs} {f g : c ⟶ d} : f = g ↔ (f.1 : c.val ⟶ d.val) = g.1 := Subtype.ext_iff end Full end Subgroupoid end CategoryTheory		Mathlib/CategoryTheory/Groupoid/Subgroupoid.lean	650	651
/- Copyright (c) 2020 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau, Wrenna Robson -/ import Mathlib.Algebra.BigOperators.Group.Finset.Pi import Mathlib.Algebra.Polynomial.FieldDivision import Mathlib.LinearAlgebra.Vandermonde import Mathlib.RingTheory.Polynomial.Basic /-! # Lagrange interpolation ## Main definitions * In everything that follows, `s : Finset ι` is a finite set of indexes, with `v : ι → F` an indexing of the field over some type. We call the image of v on s the interpolation nodes, though strictly unique nodes are only defined when v is injective on s. * `Lagrange.basisDivisor x y`, with `x y : F`. These are the normalised irreducible factors of the Lagrange basis polynomials. They evaluate to `1` at `x` and `0` at `y` when `x` and `y` are distinct. * `Lagrange.basis v i` with `i : ι`: the Lagrange basis polynomial that evaluates to `1` at `v i` and `0` at `v j` for `i ≠ j`. * `Lagrange.interpolate v r` where `r : ι → F` is a function from the fintype to the field: the Lagrange interpolant that evaluates to `r i` at `x i` for all `i : ι`. The `r i` are the _values_ associated with the _nodes_`x i`. -/ open Polynomial section PolynomialDetermination namespace Polynomial variable {R : Type} [CommRing R] [IsDomain R] {f g : R[X]} section Finset open Function Fintype open scoped Finset variable (s : Finset R) theorem eq_zero_of_degree_lt_of_eval_finset_eq_zero (degree_f_lt : f.degree < #s) (eval_f : ∀ x ∈ s, f.eval x = 0) : f = 0 := by rw [← mem_degreeLT] at degree_f_lt simp_rw [eval_eq_sum_degreeLTEquiv degree_f_lt] at eval_f rw [← degreeLTEquiv_eq_zero_iff_eq_zero degree_f_lt] exact Matrix.eq_zero_of_forall_index_sum_mul_pow_eq_zero (Injective.comp (Embedding.subtype _).inj' (equivFinOfCardEq (card_coe _)).symm.injective) fun _ => eval_f _ (Finset.coe_mem _) theorem eq_of_degree_sub_lt_of_eval_finset_eq (degree_fg_lt : (f - g).degree < #s) (eval_fg : ∀ x ∈ s, f.eval x = g.eval x) : f = g := by rw [← sub_eq_zero] refine eq_zero_of_degree_lt_of_eval_finset_eq_zero _ degree_fg_lt ?_ simp_rw [eval_sub, sub_eq_zero] exact eval_fg theorem eq_of_degrees_lt_of_eval_finset_eq (degree_f_lt : f.degree < #s) (degree_g_lt : g.degree < #s) (eval_fg : ∀ x ∈ s, f.eval x = g.eval x) : f = g := by rw [← mem_degreeLT] at degree_f_lt degree_g_lt refine eq_of_degree_sub_lt_of_eval_finset_eq _ ?_ eval_fg rw [← mem_degreeLT]; exact Submodule.sub_mem _ degree_f_lt degree_g_lt /-- Two polynomials, with the same degree and leading coefficient, which have the same evaluation on a set of distinct values with cardinality equal to the degree, are equal. -/ theorem eq_of_degree_le_of_eval_finset_eq (h_deg_le : f.degree ≤ #s) (h_deg_eq : f.degree = g.degree) (hlc : f.leadingCoeff = g.leadingCoeff) (h_eval : ∀ x ∈ s, f.eval x = g.eval x) : f = g := by rcases eq_or_ne f 0 with rfl \| hf · rwa [degree_zero, eq_comm, degree_eq_bot, eq_comm] at h_deg_eq · exact eq_of_degree_sub_lt_of_eval_finset_eq s (lt_of_lt_of_le (degree_sub_lt h_deg_eq hf hlc) h_deg_le) h_eval end Finset section Indexed open Finset variable {ι : Type} {v : ι → R} (s : Finset ι) theorem eq_zero_of_degree_lt_of_eval_index_eq_zero (hvs : Set.InjOn v s) (degree_f_lt : f.degree < #s) (eval_f : ∀ i ∈ s, f.eval (v i) = 0) : f = 0 := by classical rw [← card_image_of_injOn hvs] at degree_f_lt refine eq_zero_of_degree_lt_of_eval_finset_eq_zero _ degree_f_lt ?_ intro x hx rcases mem_image.mp hx with ⟨_, hj, rfl⟩ exact eval_f _ hj theorem eq_of_degree_sub_lt_of_eval_index_eq (hvs : Set.InjOn v s) (degree_fg_lt : (f - g).degree < #s) (eval_fg : ∀ i ∈ s, f.eval (v i) = g.eval (v i)) : f = g := by rw [← sub_eq_zero] refine eq_zero_of_degree_lt_of_eval_index_eq_zero _ hvs degree_fg_lt ?_ simp_rw [eval_sub, sub_eq_zero] exact eval_fg theorem eq_of_degrees_lt_of_eval_index_eq (hvs : Set.InjOn v s) (degree_f_lt : f.degree < #s) (degree_g_lt : g.degree < #s) (eval_fg : ∀ i ∈ s, f.eval (v i) = g.eval (v i)) : f = g := by refine eq_of_degree_sub_lt_of_eval_index_eq _ hvs ?_ eval_fg rw [← mem_degreeLT] at degree_f_lt degree_g_lt ⊢ exact Submodule.sub_mem _ degree_f_lt degree_g_lt theorem eq_of_degree_le_of_eval_index_eq (hvs : Set.InjOn v s) (h_deg_le : f.degree ≤ #s) (h_deg_eq : f.degree = g.degree) (hlc : f.leadingCoeff = g.leadingCoeff) (h_eval : ∀ i ∈ s, f.eval (v i) = g.eval (v i)) : f = g := by rcases eq_or_ne f 0 with rfl \| hf · rwa [degree_zero, eq_comm, degree_eq_bot, eq_comm] at h_deg_eq · exact eq_of_degree_sub_lt_of_eval_index_eq s hvs (lt_of_lt_of_le (degree_sub_lt h_deg_eq hf hlc) h_deg_le) h_eval end Indexed end Polynomial end PolynomialDetermination noncomputable section namespace Lagrange open Polynomial section BasisDivisor variable {F : Type} [Field F] variable {x y : F} /-- `basisDivisor x y` is the unique linear or constant polynomial such that when evaluated at `x` it gives `1` and `y` it gives `0` (where when `x = y` it is identically `0`). Such polynomials are the building blocks for the Lagrange interpolants. -/ def basisDivisor (x y : F) : F[X] := C (x - y)⁻¹ (X - C y) theorem basisDivisor_self : basisDivisor x x = 0 := by simp only [basisDivisor, sub_self, inv_zero, map_zero, zero_mul] theorem basisDivisor_inj (hxy : basisDivisor x y = 0) : x = y := by simp_rw [basisDivisor, mul_eq_zero, X_sub_C_ne_zero, or_false, C_eq_zero, inv_eq_zero, sub_eq_zero] at hxy exact hxy @[simp] theorem basisDivisor_eq_zero_iff : basisDivisor x y = 0 ↔ x = y := ⟨basisDivisor_inj, fun H => H ▸ basisDivisor_self⟩	theorem basisDivisor_ne_zero_iff : basisDivisor x y ≠ 0 ↔ x ≠ y := by rw [Ne, basisDivisor_eq_zero_iff]	Mathlib/LinearAlgebra/Lagrange.lean	157	160
/- Copyright (c) 2018 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Simon Hudon -/ import Mathlib.Data.PFunctor.Multivariate.Basic /-! # Multivariate quotients of polynomial functors. Basic definition of multivariate QPF. QPFs form a compositional framework for defining inductive and coinductive types, their quotients and nesting. The idea is based on building ever larger functors. For instance, we can define a list using a shape functor: ```lean inductive ListShape (a b : Type) \| nil : ListShape \| cons : a -> b -> ListShape ``` This shape can itself be decomposed as a sum of product which are themselves QPFs. It follows that the shape is a QPF and we can take its fixed point and create the list itself: ```lean def List (a : Type) := fix ListShape a -- not the actual notation ``` We can continue and define the quotient on permutation of lists and create the multiset type: ```lean def Multiset (a : Type) := QPF.quot List.perm List a -- not the actual notion ``` And `Multiset` is also a QPF. We can then create a novel data type (for Lean): ```lean inductive Tree (a : Type) \| node : a -> Multiset Tree -> Tree ``` An unordered tree. This is currently not supported by Lean because it nests an inductive type inside of a quotient. We can go further and define unordered, possibly infinite trees: ```lean coinductive Tree' (a : Type) \| node : a -> Multiset Tree' -> Tree' ``` by using the `cofix` construct. Those options can all be mixed and matched because they preserve the properties of QPF. The latter example, `Tree'`, combines fixed point, co-fixed point and quotients. ## Related modules * constructions * Fix * Cofix * Quot * Comp * Sigma / Pi * Prj * Const each proves that some operations on functors preserves the QPF structure -/ set_option linter.style.longLine false in /-! ## Reference [Jeremy Avigad, Mario M. Carneiro and Simon Hudon, Data Types as Quotients of Polynomial Functors][avigad-carneiro-hudon2019] -/ universe u open MvFunctor /-- Multivariate quotients of polynomial functors. -/ class MvQPF {n : ℕ} (F : TypeVec.{u} n → Type) extends MvFunctor F where P : MvPFunctor.{u} n abs : ∀ {α}, P α → F α repr : ∀ {α}, F α → P α abs_repr : ∀ {α} (x : F α), abs (repr x) = x abs_map : ∀ {α β} (f : α ⟹ β) (p : P α), abs (f <$$> p) = f <$$> abs p namespace MvQPF variable {n : ℕ} {F : TypeVec.{u} n → Type} [q : MvQPF F] open MvFunctor (LiftP LiftR) /-! ### Show that every MvQPF is a lawful MvFunctor. -/ protected theorem id_map {α : TypeVec n} (x : F α) : TypeVec.id <$$> x = x := by rw [← abs_repr x, ← abs_map] rfl @[simp] theorem comp_map {α β γ : TypeVec n} (f : α ⟹ β) (g : β ⟹ γ) (x : F α) : (g ⊚ f) <$$> x = g <$$> f <$$> x := by rw [← abs_repr x, ← abs_map, ← abs_map, ← abs_map] rfl instance (priority := 100) lawfulMvFunctor : LawfulMvFunctor F where id_map := @MvQPF.id_map n F _ comp_map := @comp_map n F _ -- Lifting predicates and relations theorem liftP_iff {α : TypeVec n} (p : ∀ ⦃i⦄, α i → Prop) (x : F α) : LiftP p x ↔ ∃ a f, x = abs ⟨a, f⟩ ∧ ∀ i j, p (f i j) := by constructor · rintro ⟨y, hy⟩ rcases h : repr y with ⟨a, f⟩ use a, fun i j => (f i j).val constructor · rw [← hy, ← abs_repr y, h, ← abs_map]; rfl intro i j apply (f i j).property rintro ⟨a, f, h₀, h₁⟩ use abs ⟨a, fun i j => ⟨f i j, h₁ i j⟩⟩ rw [← abs_map, h₀]; rfl theorem liftR_iff {α : TypeVec n} (r : ∀ ⦃i⦄, α i → α i → Prop) (x y : F α) : LiftR r x y ↔ ∃ a f₀ f₁, x = abs ⟨a, f₀⟩ ∧ y = abs ⟨a, f₁⟩ ∧ ∀ i j, r (f₀ i j) (f₁ i j) := by constructor · rintro ⟨u, xeq, yeq⟩ rcases h : repr u with ⟨a, f⟩ use a, fun i j => (f i j).val.fst, fun i j => (f i j).val.snd constructor · rw [← xeq, ← abs_repr u, h, ← abs_map]; rfl constructor · rw [← yeq, ← abs_repr u, h, ← abs_map]; rfl intro i j exact (f i j).property rintro ⟨a, f₀, f₁, xeq, yeq, h⟩ use abs ⟨a, fun i j => ⟨(f₀ i j, f₁ i j), h i j⟩⟩ dsimp; constructor · rw [xeq, ← abs_map]; rfl rw [yeq, ← abs_map]; rfl open Set open MvFunctor (LiftP LiftR) theorem mem_supp {α : TypeVec n} (x : F α) (i) (u : α i) : u ∈ supp x i ↔ ∀ a f, abs ⟨a, f⟩ = x → u ∈ f i '' univ := by rw [supp]; dsimp; constructor · intro h a f haf have : LiftP (fun i u => u ∈ f i '' univ) x := by rw [liftP_iff] refine ⟨a, f, haf.symm, ?_⟩ intro i u exact mem_image_of_mem _ (mem_univ _) exact h this intro h p; rw [liftP_iff] rintro ⟨a, f, xeq, h'⟩ rcases h a f xeq.symm with ⟨i, _, hi⟩ rw [← hi]; apply h' theorem supp_eq {α : TypeVec n} {i} (x : F α) : supp x i = { u \| ∀ a f, abs ⟨a, f⟩ = x → u ∈ f i '' univ } := by ext; apply mem_supp theorem has_good_supp_iff {α : TypeVec n} (x : F α) : (∀ p, LiftP p x ↔ ∀ (i), ∀ u ∈ supp x i, p i u) ↔ ∃ a f, abs ⟨a, f⟩ = x ∧ ∀ i a' f', abs ⟨a', f'⟩ = x → f i '' univ ⊆ f' i '' univ := by constructor · intro h have : LiftP (supp x) x := by rw [h]; introv; exact id rw [liftP_iff] at this rcases this with ⟨a, f, xeq, h'⟩ refine ⟨a, f, xeq.symm, ?_⟩ intro a' f' h'' rintro hu u ⟨j, _h₂, hfi⟩ have hh : u ∈ supp x a' := by rw [← hfi]; apply h' exact (mem_supp x _ u).mp hh _ _ hu rintro ⟨a, f, xeq, h⟩ p; rw [liftP_iff]; constructor · rintro ⟨a', f', xeq', h'⟩ i u usuppx rcases (mem_supp x _ u).mp (@usuppx) a' f' xeq'.symm with ⟨i, _, f'ieq⟩ rw [← f'ieq] apply h' intro h' refine ⟨a, f, xeq.symm, ?_⟩; intro j y apply h'; rw [mem_supp] intro a' f' xeq' apply h _ a' f' xeq' apply mem_image_of_mem _ (mem_univ _) /-- A qpf is said to be uniform if every polynomial functor representing a single value all have the same range. -/ def IsUniform : Prop := ∀ ⦃α : TypeVec n⦄ (a a' : q.P.A) (f : q.P.B a ⟹ α) (f' : q.P.B a' ⟹ α), abs ⟨a, f⟩ = abs ⟨a', f'⟩ → ∀ i, f i '' univ = f' i '' univ /-- does `abs` preserve `liftp`? -/ def LiftPPreservation : Prop := ∀ ⦃α : TypeVec n⦄ (p : ∀ ⦃i⦄, α i → Prop) (x : q.P α), LiftP p (abs x) ↔ LiftP p x /-- does `abs` preserve `supp`? -/ def SuppPreservation : Prop := ∀ ⦃α⦄ (x : q.P α), supp (abs x) = supp x theorem supp_eq_of_isUniform (h : q.IsUniform) {α : TypeVec n} (a : q.P.A) (f : q.P.B a ⟹ α) : ∀ i, supp (abs ⟨a, f⟩) i = f i '' univ := by intro; ext u; rw [mem_supp]; constructor · intro h' apply h' _ _ rfl intro h' a' f' e rw [← h _ _ _ _ e.symm]; apply h' theorem liftP_iff_of_isUniform (h : q.IsUniform) {α : TypeVec n} (x : F α) (p : ∀ i, α i → Prop) : LiftP p x ↔ ∀ (i), ∀ u ∈ supp x i, p i u := by rw [liftP_iff, ← abs_repr x] obtain ⟨a, f⟩ := repr x; constructor · rintro ⟨a', f', abseq, hf⟩ u rw [supp_eq_of_isUniform h, h _ _ _ _ abseq] rintro b ⟨i, _, hi⟩ rw [← hi] apply hf intro h' refine ⟨a, f, rfl, fun _ i => h' _ _ ?_⟩ rw [supp_eq_of_isUniform h] exact ⟨i, mem_univ i, rfl⟩ theorem supp_map (h : q.IsUniform) {α β : TypeVec n} (g : α ⟹ β) (x : F α) (i) : supp (g <$$> x) i = g i '' supp x i := by rw [← abs_repr x]; obtain ⟨a, f⟩ := repr x; rw [← abs_map, MvPFunctor.map_eq] rw [supp_eq_of_isUniform h, supp_eq_of_isUniform h, ← image_comp] rfl theorem suppPreservation_iff_isUniform : q.SuppPreservation ↔ q.IsUniform := by constructor · intro h α a a' f f' h' i rw [← MvPFunctor.supp_eq, ← MvPFunctor.supp_eq, ← h, h', h] · rintro h α ⟨a, f⟩ ext rwa [supp_eq_of_isUniform, MvPFunctor.supp_eq] theorem suppPreservation_iff_liftpPreservation : q.SuppPreservation ↔ q.LiftPPreservation := by constructor <;> intro h · rintro α p ⟨a, f⟩ have h' := h rw [suppPreservation_iff_isUniform] at h' dsimp only [SuppPreservation, supp] at h	simp only [liftP_iff_of_isUniform, supp_eq_of_isUniform, MvPFunctor.liftP_iff', h', image_univ, mem_range, exists_imp] constructor <;> intros <;> subst_vars <;> solve_by_elim · rintro α ⟨a, f⟩ simp only [LiftPPreservation] at h ext simp only [supp, h, mem_setOf_eq]	Mathlib/Data/QPF/Multivariate/Basic.lean	254	260
/- Copyright (c) 2023 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov, Floris van Doorn -/ import Mathlib.Algebra.Group.Indicator import Mathlib.Order.Filter.AtTopBot.Basic import Mathlib.Order.Filter.Subsingleton /-! # Functions that are eventually constant along a filter In this file we define a predicate `Filter.EventuallyConst f l` saying that a function `f : α → β` is eventually equal to a constant along a filter `l`. We also prove some basic properties of these functions. ## Implementation notes A naive definition of `Filter.EventuallyConst f l` is `∃ y, ∀ᶠ x in l, f x = y`. However, this proposition is false for empty `α`, `β`. Instead, we say that `Filter.map f l` is supported on a subsingleton. This allows us to drop `[Nonempty _]` assumptions here and there. -/ open Set variable {α β γ δ : Type} {l : Filter α} {f : α → β} namespace Filter /-- The proposition that a function is eventually constant along a filter on the domain. -/ def EventuallyConst (f : α → β) (l : Filter α) : Prop := (map f l).Subsingleton theorem HasBasis.eventuallyConst_iff {ι : Sort} {p : ι → Prop} {s : ι → Set α} (h : l.HasBasis p s) : EventuallyConst f l ↔ ∃ i, p i ∧ ∀ x ∈ s i, ∀ y ∈ s i, f x = f y := (h.map f).subsingleton_iff.trans <\| by simp only [Set.Subsingleton, forall_mem_image] theorem HasBasis.eventuallyConst_iff' {ι : Sort*} {p : ι → Prop} {s : ι → Set α} {x : ι → α} (h : l.HasBasis p s) (hx : ∀ i, p i → x i ∈ s i) : EventuallyConst f l ↔ ∃ i, p i ∧ ∀ y ∈ s i, f y = f (x i) := h.eventuallyConst_iff.trans <\| exists_congr fun i ↦ and_congr_right fun hi ↦ ⟨fun h ↦ (h · · (x i) (hx i hi)), fun h a ha b hb ↦ h a ha ▸ (h b hb).symm⟩ lemma eventuallyConst_iff_tendsto [Nonempty β] : EventuallyConst f l ↔ ∃ x, Tendsto f l (pure x) := subsingleton_iff_exists_le_pure alias ⟨EventuallyConst.exists_tendsto, _⟩ := eventuallyConst_iff_tendsto theorem EventuallyConst.of_tendsto {x : β} (h : Tendsto f l (pure x)) : EventuallyConst f l := have : Nonempty β := ⟨x⟩; eventuallyConst_iff_tendsto.2 ⟨x, h⟩ theorem eventuallyConst_iff_exists_eventuallyEq [Nonempty β] : EventuallyConst f l ↔ ∃ c, f =ᶠ[l] fun _ ↦ c := subsingleton_iff_exists_singleton_mem alias ⟨EventuallyConst.eventuallyEq_const, _⟩ := eventuallyConst_iff_exists_eventuallyEq	theorem eventuallyConst_pred' {p : α → Prop} : EventuallyConst p l ↔ (p =ᶠ[l] fun _ ↦ False) ∨ (p =ᶠ[l] fun _ ↦ True) := by	Mathlib/Order/Filter/EventuallyConst.lean	57	59
/- Copyright (c) 2022 Yakov Pechersky. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yakov Pechersky, Floris van Doorn -/ import Mathlib.Data.Nat.Find import Mathlib.Data.PNat.Basic /-! # Explicit least witnesses to existentials on positive natural numbers Implemented via calling out to `Nat.find`. -/ namespace PNat variable {p q : ℕ+ → Prop} [DecidablePred p] [DecidablePred q] (h : ∃ n, p n) instance decidablePredExistsNat : DecidablePred fun n' : ℕ => ∃ (n : ℕ+) (_ : n' = n), p n := fun n' => decidable_of_iff' (∃ h : 0 < n', p ⟨n', h⟩) <\| Subtype.exists.trans <\| by simp_rw [mk_coe, @exists_comm (_ < _) (_ = _), exists_prop, exists_eq_left'] /-- The `PNat` version of `Nat.findX` -/ protected def findX : { n // p n ∧ ∀ m : ℕ+, m < n → ¬p m } := by have : ∃ (n' : ℕ) (n : ℕ+) (_ : n' = n), p n := Exists.elim h fun n hn => ⟨n, n, rfl, hn⟩ have n := Nat.findX this refine ⟨⟨n, ?_⟩, ?_, fun m hm pm => ?_⟩ · obtain ⟨n', hn', -⟩ := n.prop.1 rw [hn'] exact n'.prop · obtain ⟨n', hn', pn'⟩ := n.prop.1 simpa [hn', Subtype.coe_eta] using pn' · exact n.prop.2 m hm ⟨m, rfl, pm⟩ /-- If `p` is a (decidable) predicate on `ℕ+` and `hp : ∃ (n : ℕ+), p n` is a proof that there exists some positive natural number satisfying `p`, then `PNat.find hp` is the smallest positive natural number satisfying `p`. Note that `PNat.find` is protected, meaning that you can't just write `find`, even if the `PNat` namespace is open. The API for `PNat.find` is: * `PNat.find_spec` is the proof that `PNat.find hp` satisfies `p`. * `PNat.find_min` is the proof that if `m < PNat.find hp` then `m` does not satisfy `p`. * `PNat.find_min'` is the proof that if `m` does satisfy `p` then `PNat.find hp ≤ m`. -/ protected def find : ℕ+ := PNat.findX h protected theorem find_spec : p (PNat.find h) := (PNat.findX h).prop.left protected theorem find_min : ∀ {m : ℕ+}, m < PNat.find h → ¬p m := @(PNat.findX h).prop.right protected theorem find_min' {m : ℕ+} (hm : p m) : PNat.find h ≤ m := le_of_not_lt fun l => PNat.find_min h l hm variable {n m : ℕ+} theorem find_eq_iff : PNat.find h = m ↔ p m ∧ ∀ n < m, ¬p n := by constructor · rintro rfl exact ⟨PNat.find_spec h, fun _ => PNat.find_min h⟩ · rintro ⟨hm, hlt⟩ exact le_antisymm (PNat.find_min' h hm) (not_lt.1 <\| imp_not_comm.1 (hlt _) <\| PNat.find_spec h) @[simp] theorem find_lt_iff (n : ℕ+) : PNat.find h < n ↔ ∃ m < n, p m := ⟨fun h2 => ⟨PNat.find h, h2, PNat.find_spec h⟩, fun ⟨_, hmn, hm⟩ => (PNat.find_min' h hm).trans_lt hmn⟩ @[simp] theorem find_le_iff (n : ℕ+) : PNat.find h ≤ n ↔ ∃ m ≤ n, p m := by simp only [exists_prop, ← lt_add_one_iff, find_lt_iff] @[simp] theorem le_find_iff (n : ℕ+) : n ≤ PNat.find h ↔ ∀ m < n, ¬p m := by simp only [← not_lt, find_lt_iff, not_exists, not_and] @[simp] theorem lt_find_iff (n : ℕ+) : n < PNat.find h ↔ ∀ m ≤ n, ¬p m := by simp only [← add_one_le_iff, le_find_iff, add_le_add_iff_right] @[simp] theorem find_eq_one : PNat.find h = 1 ↔ p 1 := by simp [find_eq_iff] theorem one_le_find : 1 < PNat.find h ↔ ¬p 1 := by simp theorem find_mono (h : ∀ n, q n → p n) {hp : ∃ n, p n} {hq : ∃ n, q n} : PNat.find hp ≤ PNat.find hq := PNat.find_min' _ (h _ (PNat.find_spec hq)) theorem find_le {h : ∃ n, p n} (hn : p n) : PNat.find h ≤ n := (PNat.find_le_iff _ _).2 ⟨n, le_rfl, hn⟩ theorem find_comp_succ (h : ∃ n, p n) (h₂ : ∃ n, p (n + 1)) (h1 : ¬p 1) : PNat.find h = PNat.find h₂ + 1 := by refine (find_eq_iff _).2 ⟨PNat.find_spec h₂, fun n ↦ ?_⟩ induction n with \| one => simp [h1]	\| succ m _ => intro hm	Mathlib/Data/PNat/Find.lean	105	106
/- 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] theorem zero_testAgainstNN_apply (f : Ω →ᵇ ℝ≥0) : (0 : FiniteMeasure Ω).testAgainstNN f = 0 := by simp only [testAgainstNN, toMeasure_zero, lintegral_zero_measure, ENNReal.toNNReal_zero] theorem zero_testAgainstNN : (0 : FiniteMeasure Ω).testAgainstNN = 0 := by funext simp only [zero_testAgainstNN_apply, Pi.zero_apply] @[simp] theorem smul_testAgainstNN_apply (c : ℝ≥0) (μ : FiniteMeasure Ω) (f : Ω →ᵇ ℝ≥0) : (c • μ).testAgainstNN f = c • μ.testAgainstNN f := by simp only [testAgainstNN, toMeasure_smul, smul_eq_mul, ← ENNReal.smul_toNNReal, ENNReal.smul_def, lintegral_smul_measure] section weak_convergence variable [OpensMeasurableSpace Ω] theorem testAgainstNN_add (μ : FiniteMeasure Ω) (f₁ f₂ : Ω →ᵇ ℝ≥0) : μ.testAgainstNN (f₁ + f₂) = μ.testAgainstNN f₁ + μ.testAgainstNN f₂ := by simp only [← ENNReal.coe_inj, BoundedContinuousFunction.coe_add, ENNReal.coe_add, Pi.add_apply, testAgainstNN_coe_eq] exact lintegral_add_left (BoundedContinuousFunction.measurable_coe_ennreal_comp _) _ theorem testAgainstNN_smul [IsScalarTower R ℝ≥0 ℝ≥0] [PseudoMetricSpace R] [Zero R] [IsBoundedSMul R ℝ≥0] (μ : FiniteMeasure Ω) (c : R) (f : Ω →ᵇ ℝ≥0) : μ.testAgainstNN (c • f) = c • μ.testAgainstNN f := by simp only [← ENNReal.coe_inj, BoundedContinuousFunction.coe_smul, testAgainstNN_coe_eq, ENNReal.coe_smul] simp_rw [← smul_one_smul ℝ≥0∞ c (f _ : ℝ≥0∞), ← smul_one_smul ℝ≥0∞ c (lintegral _ _ : ℝ≥0∞), smul_eq_mul] exact lintegral_const_mul (c • (1 : ℝ≥0∞)) f.measurable_coe_ennreal_comp theorem testAgainstNN_lipschitz_estimate (μ : FiniteMeasure Ω) (f g : Ω →ᵇ ℝ≥0) : μ.testAgainstNN f ≤ μ.testAgainstNN g + nndist f g * μ.mass := by simp only [← μ.testAgainstNN_const (nndist f g), ← testAgainstNN_add, ← ENNReal.coe_le_coe, BoundedContinuousFunction.coe_add, const_apply, ENNReal.coe_add, Pi.add_apply, coe_nnreal_ennreal_nndist, testAgainstNN_coe_eq] apply lintegral_mono have le_dist : ∀ ω, dist (f ω) (g ω) ≤ nndist f g := BoundedContinuousFunction.dist_coe_le_dist intro ω have le' : f ω ≤ g ω + nndist f g := by calc f ω _ ≤ g ω + nndist (f ω) (g ω) := NNReal.le_add_nndist (f ω) (g ω) _ ≤ g ω + nndist f g := (add_le_add_iff_left (g ω)).mpr (le_dist ω) have le : (f ω : ℝ≥0∞) ≤ (g ω : ℝ≥0∞) + nndist f g := by simpa only [← ENNReal.coe_add] using (by exact_mod_cast le') rwa [coe_nnreal_ennreal_nndist] at le theorem testAgainstNN_lipschitz (μ : FiniteMeasure Ω) : LipschitzWith μ.mass fun f : Ω →ᵇ ℝ≥0 ↦ μ.testAgainstNN f := by rw [lipschitzWith_iff_dist_le_mul] intro f₁ f₂ suffices abs (μ.testAgainstNN f₁ - μ.testAgainstNN f₂ : ℝ) ≤ μ.mass * dist f₁ f₂ by rwa [NNReal.dist_eq] apply abs_le.mpr constructor · have key := μ.testAgainstNN_lipschitz_estimate f₂ f₁ rw [mul_comm] at key suffices ↑(μ.testAgainstNN f₂) ≤ ↑(μ.testAgainstNN f₁) + ↑μ.mass * dist f₁ f₂ by linarith simpa [nndist_comm] using NNReal.coe_mono key · have key := μ.testAgainstNN_lipschitz_estimate f₁ f₂ rw [mul_comm] at key suffices ↑(μ.testAgainstNN f₁) ≤ ↑(μ.testAgainstNN f₂) + ↑μ.mass * dist f₁ f₂ by linarith simpa using NNReal.coe_mono key /-- Finite measures yield elements of the `WeakDual` of bounded continuous nonnegative functions via `MeasureTheory.FiniteMeasure.testAgainstNN`, i.e., integration. -/ def toWeakDualBCNN (μ : FiniteMeasure Ω) : WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0) where toFun f := μ.testAgainstNN f map_add' := testAgainstNN_add μ map_smul' := testAgainstNN_smul μ cont := μ.testAgainstNN_lipschitz.continuous @[simp] theorem coe_toWeakDualBCNN (μ : FiniteMeasure Ω) : ⇑μ.toWeakDualBCNN = μ.testAgainstNN := rfl @[simp] theorem toWeakDualBCNN_apply (μ : FiniteMeasure Ω) (f : Ω →ᵇ ℝ≥0) : μ.toWeakDualBCNN f = (∫⁻ x, f x ∂(μ : Measure Ω)).toNNReal := rfl /-- The topology of weak convergence on `MeasureTheory.FiniteMeasure Ω` is inherited (induced) from the weak-* topology on `WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0)` via the function `MeasureTheory.FiniteMeasure.toWeakDualBCNN`. -/ instance instTopologicalSpace : TopologicalSpace (FiniteMeasure Ω) := TopologicalSpace.induced toWeakDualBCNN inferInstance theorem toWeakDualBCNN_continuous : Continuous (@toWeakDualBCNN Ω _ _ _) := continuous_induced_dom /-- Integration of (nonnegative bounded continuous) test functions against finite Borel measures depends continuously on the measure. -/ theorem continuous_testAgainstNN_eval (f : Ω →ᵇ ℝ≥0) : Continuous fun μ : FiniteMeasure Ω ↦ μ.testAgainstNN f := by show Continuous ((fun φ : WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0) ↦ φ f) ∘ toWeakDualBCNN) refine Continuous.comp ?_ (toWeakDualBCNN_continuous (Ω := Ω)) exact WeakBilin.eval_continuous _ _ /-- The total mass of a finite measure depends continuously on the measure. -/ theorem continuous_mass : Continuous fun μ : FiniteMeasure Ω ↦ μ.mass := by simp_rw [← testAgainstNN_one]; exact continuous_testAgainstNN_eval 1 /-- Convergence of finite measures implies the convergence of their total masses. -/ theorem _root_.Filter.Tendsto.mass {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} (h : Tendsto μs F (𝓝 μ)) : Tendsto (fun i ↦ (μs i).mass) F (𝓝 μ.mass) := (continuous_mass.tendsto μ).comp h theorem tendsto_iff_weakDual_tendsto {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} : Tendsto μs F (𝓝 μ) ↔ Tendsto (fun i ↦ (μs i).toWeakDualBCNN) F (𝓝 μ.toWeakDualBCNN) := IsInducing.tendsto_nhds_iff ⟨rfl⟩ theorem tendsto_iff_forall_toWeakDualBCNN_tendsto {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} : Tendsto μs F (𝓝 μ) ↔ ∀ f : Ω →ᵇ ℝ≥0, Tendsto (fun i ↦ (μs i).toWeakDualBCNN f) F (𝓝 (μ.toWeakDualBCNN f)) := by rw [tendsto_iff_weakDual_tendsto, tendsto_iff_forall_eval_tendsto_topDualPairing]; rfl theorem tendsto_iff_forall_testAgainstNN_tendsto {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} : Tendsto μs F (𝓝 μ) ↔ ∀ f : Ω →ᵇ ℝ≥0, Tendsto (fun i ↦ (μs i).testAgainstNN f) F (𝓝 (μ.testAgainstNN f)) := by rw [FiniteMeasure.tendsto_iff_forall_toWeakDualBCNN_tendsto]; rfl /-- If the total masses of finite measures tend to zero, then the measures tend to zero. This formulation concerns the associated functionals on bounded continuous nonnegative test functions. See `MeasureTheory.FiniteMeasure.tendsto_zero_of_tendsto_zero_mass` for a formulation stating the weak convergence of measures. -/ theorem tendsto_zero_testAgainstNN_of_tendsto_zero_mass {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} (mass_lim : Tendsto (fun i ↦ (μs i).mass) F (𝓝 0)) (f : Ω →ᵇ ℝ≥0) : Tendsto (fun i ↦ (μs i).testAgainstNN f) F (𝓝 0) := by apply tendsto_iff_dist_tendsto_zero.mpr have obs := fun i ↦ (μs i).testAgainstNN_lipschitz_estimate f 0 simp_rw [testAgainstNN_zero, zero_add] at obs simp_rw [show ∀ i, dist ((μs i).testAgainstNN f) 0 = (μs i).testAgainstNN f by simp only [dist_nndist, NNReal.nndist_zero_eq_val', eq_self_iff_true, imp_true_iff]] apply squeeze_zero (fun i ↦ NNReal.coe_nonneg _) obs have lim_pair : Tendsto (fun i ↦ (⟨nndist f 0, (μs i).mass⟩ : ℝ × ℝ)) F (𝓝 ⟨nndist f 0, 0⟩) := (Prod.tendsto_iff _ _).mpr ⟨tendsto_const_nhds, (NNReal.continuous_coe.tendsto 0).comp mass_lim⟩ simpa using tendsto_mul.comp lim_pair /-- If the total masses of finite measures tend to zero, then the measures tend to zero. -/ theorem tendsto_zero_of_tendsto_zero_mass {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} (mass_lim : Tendsto (fun i ↦ (μs i).mass) F (𝓝 0)) : Tendsto μs F (𝓝 0) := by rw [tendsto_iff_forall_testAgainstNN_tendsto] intro f convert tendsto_zero_testAgainstNN_of_tendsto_zero_mass mass_lim f rw [zero_testAgainstNN_apply] /-- A characterization of weak convergence in terms of integrals of bounded continuous nonnegative functions. -/ theorem tendsto_iff_forall_lintegral_tendsto {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} : Tendsto μs F (𝓝 μ) ↔ ∀ f : Ω →ᵇ ℝ≥0, Tendsto (fun i ↦ ∫⁻ x, f x ∂(μs i : Measure Ω)) F (𝓝 (∫⁻ x, f x ∂(μ : Measure Ω))) := by rw [tendsto_iff_forall_toWeakDualBCNN_tendsto] simp_rw [toWeakDualBCNN_apply _ _, ← testAgainstNN_coe_eq, ENNReal.tendsto_coe, ENNReal.toNNReal_coe] end weak_convergence -- section section Hausdorff variable [HasOuterApproxClosed Ω] [BorelSpace Ω] open Function /-- The mapping `toWeakDualBCNN` from finite Borel measures to the weak dual of `Ω →ᵇ ℝ≥0` is injective, if in the underlying space `Ω`, indicator functions of closed sets have decreasing approximations by sequences of continuous functions (in particular if `Ω` is pseudometrizable). -/ lemma injective_toWeakDualBCNN : Injective (toWeakDualBCNN : FiniteMeasure Ω → WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0)) := by intro μ ν hμν apply ext_of_forall_lintegral_eq intro f have key := congr_fun (congrArg DFunLike.coe hμν) f apply (ENNReal.toNNReal_eq_toNNReal_iff' ?_ ?_).mp key · exact (lintegral_lt_top_of_nnreal μ f).ne · exact (lintegral_lt_top_of_nnreal ν f).ne variable (Ω) lemma isEmbedding_toWeakDualBCNN : IsEmbedding (toWeakDualBCNN : FiniteMeasure Ω → WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0)) where eq_induced := rfl injective := injective_toWeakDualBCNN @[deprecated (since := "2024-10-26")] alias embedding_toWeakDualBCNN := isEmbedding_toWeakDualBCNN /-- On topological spaces where indicators of closed sets have decreasing approximating sequences of continuous functions (`HasOuterApproxClosed`), the topology of weak convergence of finite Borel measures is Hausdorff (`T2Space`). -/ instance t2Space : T2Space (FiniteMeasure Ω) := (isEmbedding_toWeakDualBCNN Ω).t2Space end Hausdorff -- section end FiniteMeasure -- section section FiniteMeasureBoundedConvergence /-! ### Bounded convergence results for finite measures This section is about bounded convergence theorems for finite measures. -/ variable {Ω : Type} [MeasurableSpace Ω] [TopologicalSpace Ω] [OpensMeasurableSpace Ω] /-- A bounded convergence theorem for a finite measure: If a sequence of bounded continuous non-negative functions are uniformly bounded by a constant and tend pointwise to a limit, then their integrals (`MeasureTheory.lintegral`) against the finite measure tend to the integral of the limit. A related result with more general assumptions is `MeasureTheory.tendsto_lintegral_nn_filter_of_le_const`. -/ theorem tendsto_lintegral_nn_of_le_const (μ : FiniteMeasure Ω) {fs : ℕ → Ω →ᵇ ℝ≥0} {c : ℝ≥0} (fs_le_const : ∀ n ω, fs n ω ≤ c) {f : Ω → ℝ≥0} (fs_lim : ∀ ω, Tendsto (fun n ↦ fs n ω) atTop (𝓝 (f ω))) : Tendsto (fun n ↦ ∫⁻ ω, fs n ω ∂(μ : Measure Ω)) atTop (𝓝 (∫⁻ ω, f ω ∂(μ : Measure Ω))) := tendsto_lintegral_nn_filter_of_le_const μ (.of_forall fun n ↦ .of_forall (fs_le_const n)) (.of_forall fs_lim) /-- A bounded convergence theorem for a finite measure: If bounded continuous non-negative functions are uniformly bounded by a constant and tend to a limit, then their integrals against the finite measure tend to the integral of the limit. This formulation assumes: * the functions tend to a limit along a countably generated filter; * the limit is in the almost everywhere sense; * boundedness holds almost everywhere; * integration is the pairing against non-negative continuous test functions (`MeasureTheory.FiniteMeasure.testAgainstNN`). A related result using `MeasureTheory.lintegral` for integration is `MeasureTheory.FiniteMeasure.tendsto_lintegral_nn_filter_of_le_const`. -/ theorem tendsto_testAgainstNN_filter_of_le_const {ι : Type} {L : Filter ι} [L.IsCountablyGenerated] {μ : FiniteMeasure Ω} {fs : ι → Ω →ᵇ ℝ≥0} {c : ℝ≥0} (fs_le_const : ∀ᶠ i in L, ∀ᵐ ω : Ω ∂(μ : Measure Ω), fs i ω ≤ c) {f : Ω →ᵇ ℝ≥0} (fs_lim : ∀ᵐ ω : Ω ∂(μ : Measure Ω), Tendsto (fun i ↦ fs i ω) L (𝓝 (f ω))) : Tendsto (fun i ↦ μ.testAgainstNN (fs i)) L (𝓝 (μ.testAgainstNN f)) := by apply (ENNReal.tendsto_toNNReal (f.lintegral_lt_top_of_nnreal (μ : Measure Ω)).ne).comp exact tendsto_lintegral_nn_filter_of_le_const (Ω := Ω) μ fs_le_const fs_lim /-- A bounded convergence theorem for a finite measure: If a sequence of bounded continuous non-negative functions are uniformly bounded by a constant and tend pointwise to a limit, then their integrals (`MeasureTheory.FiniteMeasure.testAgainstNN`) against the finite measure tend to the integral of the limit. Related results: `MeasureTheory.FiniteMeasure.tendsto_testAgainstNN_filter_of_le_const`: more general assumptions * `MeasureTheory.FiniteMeasure.tendsto_lintegral_nn_of_le_const`: using `MeasureTheory.lintegral` for integration. -/ theorem tendsto_testAgainstNN_of_le_const {μ : FiniteMeasure Ω} {fs : ℕ → Ω →ᵇ ℝ≥0} {c : ℝ≥0} (fs_le_const : ∀ n ω, fs n ω ≤ c) {f : Ω →ᵇ ℝ≥0} (fs_lim : ∀ ω, Tendsto (fun n ↦ fs n ω) atTop (𝓝 (f ω))) : Tendsto (fun n ↦ μ.testAgainstNN (fs n)) atTop (𝓝 (μ.testAgainstNN f)) := tendsto_testAgainstNN_filter_of_le_const (.of_forall fun n ↦ .of_forall (fs_le_const n)) (.of_forall fs_lim) end FiniteMeasureBoundedConvergence -- section section FiniteMeasureConvergenceByBoundedContinuousFunctions /-! ### Weak convergence of finite measures with bounded continuous real-valued functions In this section we characterize the weak convergence of finite measures by the usual (defining) condition that the integrals of all bounded continuous real-valued functions converge. -/ variable {Ω : Type} [MeasurableSpace Ω] [TopologicalSpace Ω] [OpensMeasurableSpace Ω] theorem tendsto_of_forall_integral_tendsto {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} (h : ∀ f : Ω →ᵇ ℝ, Tendsto (fun i ↦ ∫ x, f x ∂(μs i : Measure Ω)) F (𝓝 (∫ x, f x ∂(μ : Measure Ω)))) : Tendsto μs F (𝓝 μ) := by apply tendsto_iff_forall_lintegral_tendsto.mpr intro f apply (ENNReal.tendsto_toReal_iff (fi := F) (fun i ↦ (f.lintegral_lt_top_of_nnreal (μs i)).ne) (f.lintegral_lt_top_of_nnreal μ).ne).mp have lip : LipschitzWith 1 ((↑) : ℝ≥0 → ℝ) := isometry_subtype_coe.lipschitz set f₀ := BoundedContinuousFunction.comp _ lip f with _def_f₀ have f₀_eq : ⇑f₀ = ((↑) : ℝ≥0 → ℝ) ∘ ⇑f := rfl have f₀_nn : 0 ≤ ⇑f₀ := fun _ ↦ by simp only [f₀_eq, Pi.zero_apply, Function.comp_apply, NNReal.zero_le_coe] have f₀_ae_nn : 0 ≤ᵐ[(μ : Measure Ω)] ⇑f₀ := .of_forall f₀_nn have f₀_ae_nns : ∀ i, 0 ≤ᵐ[(μs i : Measure Ω)] ⇑f₀ := fun i ↦ .of_forall f₀_nn have aux := integral_eq_lintegral_of_nonneg_ae f₀_ae_nn f₀.continuous.measurable.aestronglyMeasurable have auxs := fun i ↦ integral_eq_lintegral_of_nonneg_ae (f₀_ae_nns i) f₀.continuous.measurable.aestronglyMeasurable simp_rw [f₀_eq, Function.comp_apply, ENNReal.ofReal_coe_nnreal] at aux auxs simpa only [← aux, ← auxs] using h f₀ /-- A characterization of weak convergence in terms of integrals of bounded continuous real-valued functions. -/ theorem tendsto_iff_forall_integral_tendsto {γ : Type} {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} : Tendsto μs F (𝓝 μ) ↔ ∀ f : Ω →ᵇ ℝ, Tendsto (fun i ↦ ∫ x, f x ∂(μs i : Measure Ω)) F (𝓝 (∫ x, f x ∂(μ : Measure Ω))) := by refine ⟨?_, tendsto_of_forall_integral_tendsto⟩ rw [tendsto_iff_forall_lintegral_tendsto] intro h f simp_rw [BoundedContinuousFunction.integral_eq_integral_nnrealPart_sub] set f_pos := f.nnrealPart with _def_f_pos set f_neg := (-f).nnrealPart with _def_f_neg have tends_pos := (ENNReal.tendsto_toReal (f_pos.lintegral_lt_top_of_nnreal μ).ne).comp (h f_pos) have tends_neg := (ENNReal.tendsto_toReal (f_neg.lintegral_lt_top_of_nnreal μ).ne).comp (h f_neg) have aux : ∀ g : Ω →ᵇ ℝ≥0, (ENNReal.toReal ∘ fun i : γ ↦ ∫⁻ x : Ω, ↑(g x) ∂(μs i : Measure Ω)) = fun i : γ ↦ (∫⁻ x : Ω, ↑(g x) ∂(μs i : Measure Ω)).toReal := fun _ ↦ rfl simp_rw [aux, BoundedContinuousFunction.toReal_lintegral_coe_eq_integral] at tends_pos tends_neg exact Tendsto.sub tends_pos tends_neg theorem tendsto_iff_forall_integral_rclike_tendsto {γ : Type} (𝕜 : Type*) [RCLike 𝕜] {F : Filter γ} {μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} : Tendsto μs F (𝓝 μ) ↔ ∀ f : Ω →ᵇ 𝕜, Tendsto (fun i ↦ ∫ ω, f ω ∂(μs i : Measure Ω)) F (𝓝 (∫ ω, f ω ∂(μ : Measure Ω))) := by rw [tendsto_iff_forall_integral_tendsto] refine ⟨fun h f ↦ ?_, fun h f ↦ ?_⟩ · rw [← integral_re_add_im (integrable μ f)] simp_rw [← integral_re_add_im (integrable (μs _) f)] refine Tendsto.add ?_ ?_ · exact (RCLike.continuous_ofReal.tendsto _).comp (h (f.comp RCLike.re RCLike.lipschitzWith_re)) · exact (Tendsto.comp (RCLike.continuous_ofReal.tendsto _) (h (f.comp RCLike.im RCLike.lipschitzWith_im))).mul_const _ · specialize h ((RCLike.ofRealAm (K := 𝕜)).compLeftContinuousBounded ℝ RCLike.lipschitzWith_ofReal f) simp only [AlgHom.compLeftContinuousBounded_apply_apply, RCLike.ofRealAm_coe, Complex.coe_algebraMap, integral_ofReal] at h exact tendsto_ofReal_iff'.mp h	lemma continuous_integral_boundedContinuousFunction {α : Type} [TopologicalSpace α] [MeasurableSpace α] [OpensMeasurableSpace α] (f : α →ᵇ ℝ) : Continuous fun μ : FiniteMeasure α ↦ ∫ x, f x ∂μ := by rw [continuous_iff_continuousAt] intro μ exact continuousAt_of_tendsto_nhds (FiniteMeasure.tendsto_iff_forall_integral_tendsto.mp tendsto_id f) end FiniteMeasureConvergenceByBoundedContinuousFunctions -- section section map variable {Ω Ω' : Type} [MeasurableSpace Ω] [MeasurableSpace Ω'] /-- The push-forward of a finite measure by a function between measurable spaces. -/ noncomputable def map (ν : FiniteMeasure Ω) (f : Ω → Ω') : FiniteMeasure Ω' := ⟨(ν : Measure Ω).map f, by constructor by_cases f_aemble : AEMeasurable f ν	Mathlib/MeasureTheory/Measure/FiniteMeasure.lean	711	730
/- 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.Action.End import Mathlib.Algebra.Group.Action.Pointwise.Set.Basic import Mathlib.Algebra.Group.Action.Prod import Mathlib.Algebra.Group.Subgroup.Map import Mathlib.Algebra.Module.Defs import Mathlib.Algebra.NoZeroSMulDivisors.Defs import Mathlib.Data.Finite.Sigma import Mathlib.Data.Set.Finite.Range import Mathlib.Data.Setoid.Basic import Mathlib.GroupTheory.GroupAction.Defs /-! # Basic properties of group actions This file primarily concerns itself with orbits, stabilizers, and other objects defined in terms of actions. Despite this file being called `basic`, low-level helper lemmas for algebraic manipulation of `•` belong elsewhere. ## Main definitions * `MulAction.orbit` * `MulAction.fixedPoints` * `MulAction.fixedBy` * `MulAction.stabilizer` -/ universe u v open Pointwise open Function namespace MulAction variable (M : Type u) [Monoid M] (α : Type v) [MulAction M α] {β : Type} [MulAction M β] section Orbit variable {α M} @[to_additive] lemma fst_mem_orbit_of_mem_orbit {x y : α × β} (h : x ∈ MulAction.orbit M y) : x.1 ∈ MulAction.orbit M y.1 := by rcases h with ⟨g, rfl⟩ exact mem_orbit _ _ @[to_additive] lemma snd_mem_orbit_of_mem_orbit {x y : α × β} (h : x ∈ MulAction.orbit M y) : x.2 ∈ MulAction.orbit M y.2 := by rcases h with ⟨g, rfl⟩ exact mem_orbit _ _ @[to_additive] lemma _root_.Finite.finite_mulAction_orbit [Finite M] (a : α) : Set.Finite (orbit M a) := Set.finite_range _ variable (M) @[to_additive] theorem orbit_eq_univ [IsPretransitive M α] (a : α) : orbit M a = Set.univ := (surjective_smul M a).range_eq end Orbit section FixedPoints variable {M α} @[to_additive (attr := simp)] theorem subsingleton_orbit_iff_mem_fixedPoints {a : α} : (orbit M a).Subsingleton ↔ a ∈ fixedPoints M α := by rw [mem_fixedPoints] constructor · exact fun h m ↦ h (mem_orbit a m) (mem_orbit_self a) · rintro h _ ⟨m, rfl⟩ y ⟨p, rfl⟩ simp only [h] @[to_additive mem_fixedPoints_iff_card_orbit_eq_one] theorem mem_fixedPoints_iff_card_orbit_eq_one {a : α} [Fintype (orbit M a)] : a ∈ fixedPoints M α ↔ Fintype.card (orbit M a) = 1 := by simp only [← subsingleton_orbit_iff_mem_fixedPoints, le_antisymm_iff, Fintype.card_le_one_iff_subsingleton, Nat.add_one_le_iff, Fintype.card_pos_iff, Set.subsingleton_coe, iff_self_and, Set.nonempty_coe_sort, orbit_nonempty, implies_true] @[to_additive instDecidablePredMemSetFixedByAddOfDecidableEq] instance (m : M) [DecidableEq β] : DecidablePred fun b : β => b ∈ MulAction.fixedBy β m := fun b ↦ by simp only [MulAction.mem_fixedBy, Equiv.Perm.smul_def] infer_instance end FixedPoints end MulAction /-- `smul` by a `k : M` over a group is injective, if `k` is not a zero divisor. The general theory of such `k` is elaborated by `IsSMulRegular`. The typeclass that restricts all terms of `M` to have this property is `NoZeroSMulDivisors`. -/ theorem smul_cancel_of_non_zero_divisor {M G : Type} [Monoid M] [AddGroup G] [DistribMulAction M G] (k : M) (h : ∀ x : G, k • x = 0 → x = 0) {a b : G} (h' : k • a = k • b) : a = b := by rw [← sub_eq_zero] refine h _ ?_ rw [smul_sub, h', sub_self] namespace MulAction variable {G α β : Type} [Group G] [MulAction G α] [MulAction G β] @[to_additive] theorem fixedPoints_of_subsingleton [Subsingleton α] : fixedPoints G α = .univ := by apply Set.eq_univ_of_forall simp only [mem_fixedPoints] intro x hx apply Subsingleton.elim .. /-- If a group acts nontrivially, then the type is nontrivial -/ @[to_additive "If a subgroup acts nontrivially, then the type is nontrivial."] theorem nontrivial_of_fixedPoints_ne_univ (h : fixedPoints G α ≠ .univ) : Nontrivial α := (subsingleton_or_nontrivial α).resolve_left fun _ ↦ h fixedPoints_of_subsingleton section Orbit -- TODO: This proof is redoing a special case of `MulAction.IsInvariantBlock.isBlock`. Can we move -- this lemma earlier to golf? @[to_additive (attr := simp)] theorem smul_orbit (g : G) (a : α) : g • orbit G a = orbit G a := (smul_orbit_subset g a).antisymm <\| calc orbit G a = g • g⁻¹ • orbit G a := (smul_inv_smul _ _).symm _ ⊆ g • orbit G a := Set.image_subset _ (smul_orbit_subset _ _) /-- The action of a group on an orbit is transitive. -/ @[to_additive "The action of an additive group on an orbit is transitive."] instance (a : α) : IsPretransitive G (orbit G a) := ⟨by rintro ⟨_, g, rfl⟩ ⟨_, h, rfl⟩ use h g⁻¹ ext1 simp [mul_smul]⟩ @[to_additive] lemma orbitRel_subgroup_le (H : Subgroup G) : orbitRel H α ≤ orbitRel G α := Setoid.le_def.2 mem_orbit_of_mem_orbit_subgroup @[to_additive] lemma orbitRel_subgroupOf (H K : Subgroup G) : orbitRel (H.subgroupOf K) α = orbitRel (H ⊓ K : Subgroup G) α := by rw [← Subgroup.subgroupOf_map_subtype] ext x simp_rw [orbitRel_apply] refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩ · rcases h with ⟨⟨gv, gp⟩, rfl⟩ simp only [Submonoid.mk_smul] refine mem_orbit _ (⟨gv, ?_⟩ : Subgroup.map K.subtype (H.subgroupOf K)) simpa using gp · rcases h with ⟨⟨gv, gp⟩, rfl⟩ simp only [Submonoid.mk_smul] simp only [Subgroup.subgroupOf_map_subtype, Subgroup.mem_inf] at gp refine mem_orbit _ (⟨⟨gv, ?_⟩, ?_⟩ : H.subgroupOf K) · exact gp.2 · simp only [Subgroup.mem_subgroupOf] exact gp.1 variable (G α) /-- An action is pretransitive if and only if the quotient by `MulAction.orbitRel` is a subsingleton. -/ @[to_additive "An additive action is pretransitive if and only if the quotient by `AddAction.orbitRel` is a subsingleton."] theorem pretransitive_iff_subsingleton_quotient : IsPretransitive G α ↔ Subsingleton (orbitRel.Quotient G α) := by refine ⟨fun _ ↦ ⟨fun a b ↦ ?_⟩, fun _ ↦ ⟨fun a b ↦ ?_⟩⟩ · refine Quot.inductionOn a (fun x ↦ ?_) exact Quot.inductionOn b (fun y ↦ Quot.sound <\| exists_smul_eq G y x) · have h : Quotient.mk (orbitRel G α) b = ⟦a⟧ := Subsingleton.elim _ _ exact Quotient.eq''.mp h /-- If `α` is non-empty, an action is pretransitive if and only if the quotient has exactly one element. -/ @[to_additive "If `α` is non-empty, an additive action is pretransitive if and only if the quotient has exactly one element."] theorem pretransitive_iff_unique_quotient_of_nonempty [Nonempty α] : IsPretransitive G α ↔ Nonempty (Unique <\| orbitRel.Quotient G α) := by rw [unique_iff_subsingleton_and_nonempty, pretransitive_iff_subsingleton_quotient, iff_self_and] exact fun _ ↦ (nonempty_quotient_iff _).mpr inferInstance variable {G α} @[to_additive] instance (x : orbitRel.Quotient G α) : IsPretransitive G x.orbit where exists_smul_eq := by induction x using Quotient.inductionOn' rintro ⟨y, yh⟩ ⟨z, zh⟩ rw [orbitRel.Quotient.mem_orbit, Quotient.eq''] at yh zh rcases yh with ⟨g, rfl⟩ rcases zh with ⟨h, rfl⟩ refine ⟨h * g⁻¹, ?_⟩ ext simp [mul_smul] variable (G) (α) local notation "Ω" => orbitRel.Quotient G α @[to_additive] lemma _root_.Finite.of_finite_mulAction_orbitRel_quotient [Finite G] [Finite Ω] : Finite α := by rw [(selfEquivSigmaOrbits' G _).finite_iff] have : ∀ g : Ω, Finite g.orbit := by intro g induction g using Quotient.inductionOn' simpa [Set.finite_coe_iff] using Finite.finite_mulAction_orbit _ exact Finite.instSigma variable (β) @[to_additive] lemma orbitRel_le_fst : orbitRel G (α × β) ≤ (orbitRel G α).comap Prod.fst := Setoid.le_def.2 fst_mem_orbit_of_mem_orbit @[to_additive] lemma orbitRel_le_snd : orbitRel G (α × β) ≤ (orbitRel G β).comap Prod.snd := Setoid.le_def.2 snd_mem_orbit_of_mem_orbit end Orbit section Stabilizer variable (G) variable {G} /-- If the stabilizer of `a` is `S`, then the stabilizer of `g • a` is `gSg⁻¹`. -/ theorem stabilizer_smul_eq_stabilizer_map_conj (g : G) (a : α) : stabilizer G (g • a) = (stabilizer G a).map (MulAut.conj g).toMonoidHom := by ext h rw [mem_stabilizer_iff, ← smul_left_cancel_iff g⁻¹, smul_smul, smul_smul, smul_smul, inv_mul_cancel, one_smul, ← mem_stabilizer_iff, Subgroup.mem_map_equiv, MulAut.conj_symm_apply] /-- A bijection between the stabilizers of two elements in the same orbit. -/ noncomputable def stabilizerEquivStabilizerOfOrbitRel {a b : α} (h : orbitRel G α a b) : stabilizer G a ≃* stabilizer G b := let g : G := Classical.choose h have hg : g • b = a := Classical.choose_spec h have this : stabilizer G a = (stabilizer G b).map (MulAut.conj g).toMonoidHom := by rw [← hg, stabilizer_smul_eq_stabilizer_map_conj] (MulEquiv.subgroupCongr this).trans ((MulAut.conj g).subgroupMap <\| stabilizer G b).symm end Stabilizer end MulAction namespace AddAction variable {G α : Type} [AddGroup G] [AddAction G α] /-- If the stabilizer of `x` is `S`, then the stabilizer of `g +ᵥ x` is `g + S + (-g)`. -/ theorem stabilizer_vadd_eq_stabilizer_map_conj (g : G) (a : α) : stabilizer G (g +ᵥ a) = (stabilizer G a).map (AddAut.conj g).toMul.toAddMonoidHom := by ext h rw [mem_stabilizer_iff, ← vadd_left_cancel_iff (-g), vadd_vadd, vadd_vadd, vadd_vadd, neg_add_cancel, zero_vadd, ← mem_stabilizer_iff, AddSubgroup.mem_map_equiv, AddAut.conj_symm_apply] /-- A bijection between the stabilizers of two elements in the same orbit. -/ noncomputable def stabilizerEquivStabilizerOfOrbitRel {a b : α} (h : orbitRel G α a b) : stabilizer G a ≃+ stabilizer G b := let g : G := Classical.choose h have hg : g +ᵥ b = a := Classical.choose_spec h have this : stabilizer G a = (stabilizer G b).map (AddAut.conj g).toMul.toAddMonoidHom := by rw [← hg, stabilizer_vadd_eq_stabilizer_map_conj] (AddEquiv.addSubgroupCongr this).trans ((AddAut.conj g).addSubgroupMap <\| stabilizer G b).symm end AddAction attribute [to_additive existing] MulAction.stabilizer_smul_eq_stabilizer_map_conj attribute [to_additive existing] MulAction.stabilizerEquivStabilizerOfOrbitRel theorem Equiv.swap_mem_stabilizer {α : Type} [DecidableEq α] {S : Set α} {a b : α} : Equiv.swap a b ∈ MulAction.stabilizer (Equiv.Perm α) S ↔ (a ∈ S ↔ b ∈ S) := by rw [MulAction.mem_stabilizer_iff, Set.ext_iff, ← swap_inv] simp_rw [Set.mem_inv_smul_set_iff, Perm.smul_def, swap_apply_def] exact ⟨fun h ↦ by simpa [Iff.comm] using h a, by intros; split_ifs <;> simp []⟩ namespace MulAction variable {G : Type} [Group G] {α : Type} [MulAction G α] /-- To prove inclusion of a subgroup* in a stabilizer, it is enough to prove inclusions. -/ @[to_additive "To prove inclusion of a subgroup in a stabilizer, it is enough to prove inclusions."] theorem le_stabilizer_iff_smul_le (s : Set α) (H : Subgroup G) : H ≤ stabilizer G s ↔ ∀ g ∈ H, g • s ⊆ s := by constructor · intro hyp g hg apply Eq.subset rw [← mem_stabilizer_iff] exact hyp hg · intro hyp g hg rw [mem_stabilizer_iff] apply subset_antisymm (hyp g hg) intro x hx use g⁻¹ • x constructor · apply hyp g⁻¹ (inv_mem hg) simp only [Set.smul_mem_smul_set_iff, hx] · simp only [smul_inv_smul] end MulAction section variable (R M : Type*) [Ring R] [AddCommGroup M] [Module R M] [NoZeroSMulDivisors R M] variable {M} in lemma Module.stabilizer_units_eq_bot_of_ne_zero {x : M} (hx : x ≠ 0) : MulAction.stabilizer Rˣ x = ⊥ := by rw [eq_bot_iff] intro g (hg : g.val • x = x) ext rw [← sub_eq_zero, ← smul_eq_zero_iff_left hx, Units.val_one, sub_smul, hg, one_smul, sub_self] end		Mathlib/GroupTheory/GroupAction/Basic.lean	728	731
/- 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.Analysis.Calculus.ParametricIntegral import Mathlib.MeasureTheory.Integral.IntervalIntegral.Basic /-! # Derivatives of interval integrals depending on parameters In this file we restate theorems about derivatives of integrals depending on parameters for interval integrals. -/ open TopologicalSpace MeasureTheory Filter Metric open scoped Topology Filter Interval variable {𝕜 : Type} [RCLike 𝕜] {μ : Measure ℝ} {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [NormedSpace 𝕜 E] {H : Type*} [NormedAddCommGroup H] [NormedSpace 𝕜 H] {a b ε : ℝ} {bound : ℝ → ℝ} namespace intervalIntegral /-- Differentiation under integral of `x ↦ ∫ t in a..b, F x t` at a given point `x₀`, assuming `F x₀` is integrable, `x ↦ F x a` is locally Lipschitz on a ball around `x₀` for ae `a` (with a ball radius independent of `a`) with integrable Lipschitz bound, and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ nonrec theorem hasFDerivAt_integral_of_dominated_loc_of_lip {F : H → ℝ → E} {F' : ℝ → H →L[𝕜] E} {x₀ : H} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) (μ.restrict (Ι a b))) (hF_int : IntervalIntegrable (F x₀) μ a b) (hF'_meas : AEStronglyMeasurable F' (μ.restrict (Ι a b))) (h_lip : ∀ᵐ t ∂μ, t ∈ Ι a b → LipschitzOnWith (Real.nnabs <\| bound t) (fun x => F x t) (ball x₀ ε)) (bound_integrable : IntervalIntegrable bound μ a b) (h_diff : ∀ᵐ t ∂μ, t ∈ Ι a b → HasFDerivAt (fun x => F x t) (F' t) x₀) : IntervalIntegrable F' μ a b ∧ HasFDerivAt (fun x => ∫ t in a..b, F x t ∂μ) (∫ t in a..b, F' t ∂μ) x₀ := by rw [← ae_restrict_iff' measurableSet_uIoc] at h_lip h_diff simp only [intervalIntegrable_iff] at hF_int bound_integrable ⊢ simp only [intervalIntegral_eq_integral_uIoc] have := hasFDerivAt_integral_of_dominated_loc_of_lip ε_pos hF_meas hF_int hF'_meas h_lip bound_integrable h_diff exact ⟨this.1, this.2.const_smul _⟩ /-- Differentiation under integral of `x ↦ ∫ F x a` at a given point `x₀`, assuming `F x₀` is integrable, `x ↦ F x a` is differentiable on a ball around `x₀` for ae `a` with derivative norm uniformly bounded by an integrable function (the ball radius is independent of `a`), and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ nonrec theorem hasFDerivAt_integral_of_dominated_of_fderiv_le {F : H → ℝ → E} {F' : H → ℝ → H →L[𝕜] E} {x₀ : H} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) (μ.restrict (Ι a b))) (hF_int : IntervalIntegrable (F x₀) μ a b) (hF'_meas : AEStronglyMeasurable (F' x₀) (μ.restrict (Ι a b))) (h_bound : ∀ᵐ t ∂μ, t ∈ Ι a b → ∀ x ∈ ball x₀ ε, ‖F' x t‖ ≤ bound t) (bound_integrable : IntervalIntegrable bound μ a b) (h_diff : ∀ᵐ t ∂μ, t ∈ Ι a b → ∀ x ∈ ball x₀ ε, HasFDerivAt (fun x => F x t) (F' x t) x) : HasFDerivAt (fun x => ∫ t in a..b, F x t ∂μ) (∫ t in a..b, F' x₀ t ∂μ) x₀ := by rw [← ae_restrict_iff' measurableSet_uIoc] at h_bound h_diff simp only [intervalIntegrable_iff] at hF_int bound_integrable simp only [intervalIntegral_eq_integral_uIoc] exact (hasFDerivAt_integral_of_dominated_of_fderiv_le ε_pos hF_meas hF_int hF'_meas h_bound bound_integrable h_diff).const_smul _ /-- Derivative under integral of `x ↦ ∫ F x a` at a given point `x₀ : 𝕜`, `𝕜 = ℝ` or `𝕜 = ℂ`, assuming `F x₀` is integrable, `x ↦ F x a` is locally Lipschitz on a ball around `x₀` for ae `a` (with ball radius independent of `a`) with integrable Lipschitz bound, and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ nonrec theorem hasDerivAt_integral_of_dominated_loc_of_lip {F : 𝕜 → ℝ → E} {F' : ℝ → E} {x₀ : 𝕜} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) (μ.restrict (Ι a b))) (hF_int : IntervalIntegrable (F x₀) μ a b) (hF'_meas : AEStronglyMeasurable F' (μ.restrict (Ι a b)))	(h_lipsch : ∀ᵐ t ∂μ, t ∈ Ι a b → LipschitzOnWith (Real.nnabs <\| bound t) (fun x => F x t) (ball x₀ ε)) (bound_integrable : IntervalIntegrable (bound : ℝ → ℝ) μ a b) (h_diff : ∀ᵐ t ∂μ, t ∈ Ι a b → HasDerivAt (fun x => F x t) (F' t) x₀) : IntervalIntegrable F' μ a b ∧ HasDerivAt (fun x => ∫ t in a..b, F x t ∂μ) (∫ t in a..b, F' t ∂μ) x₀ := by rw [← ae_restrict_iff' measurableSet_uIoc] at h_lipsch h_diff simp only [intervalIntegrable_iff] at hF_int bound_integrable ⊢ simp only [intervalIntegral_eq_integral_uIoc] have := hasDerivAt_integral_of_dominated_loc_of_lip ε_pos hF_meas hF_int hF'_meas h_lipsch bound_integrable h_diff exact ⟨this.1, this.2.const_smul _⟩ /-- Derivative under integral of `x ↦ ∫ F x a` at a given point `x₀ : 𝕜`, `𝕜 = ℝ` or `𝕜 = ℂ`, assuming `F x₀` is integrable, `x ↦ F x a` is differentiable on an interval around `x₀` for ae `a` (with interval radius independent of `a`) with derivative uniformly bounded by an integrable	Mathlib/Analysis/Calculus/ParametricIntervalIntegral.lean	75	90
/- Copyright (c) 2022 Robert Y. Lewis. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Robert Y. Lewis, Heather Macbeth, Johan Commelin -/ import Mathlib.RingTheory.WittVector.Domain import Mathlib.RingTheory.WittVector.MulCoeff import Mathlib.RingTheory.DiscreteValuationRing.Basic import Mathlib.Tactic.LinearCombination /-! # Witt vectors over a perfect ring This file establishes that Witt vectors over a perfect field are a discrete valuation ring. When `k` is a perfect ring, a nonzero `a : 𝕎 k` can be written as `p^m * b` for some `m : ℕ` and `b : 𝕎 k` with nonzero 0th coefficient. When `k` is also a field, this `b` can be chosen to be a unit of `𝕎 k`. ## Main declarations * `WittVector.exists_eq_pow_p_mul`: the existence of this element `b` over a perfect ring * `WittVector.exists_eq_pow_p_mul'`: the existence of this unit `b` over a perfect field * `WittVector.isDiscreteValuationRing`: `𝕎 k` is a discrete valuation ring if `k` is a perfect field -/ noncomputable section namespace WittVector variable {p : ℕ} [hp : Fact p.Prime] local notation "𝕎" => WittVector p section CommRing variable {k : Type} [CommRing k] [CharP k p] /-- This is the `n+1`st coefficient of our inverse. -/ def succNthValUnits (n : ℕ) (a : Units k) (A : 𝕎 k) (bs : Fin (n + 1) → k) : k := -↑(a⁻¹ ^ p ^ (n + 1)) (A.coeff (n + 1) * ↑(a⁻¹ ^ p ^ (n + 1)) + nthRemainder p n (truncateFun (n + 1) A) bs) /-- Recursively defines the sequence of coefficients for the inverse to a Witt vector whose first entry is a unit. -/ noncomputable def inverseCoeff (a : Units k) (A : 𝕎 k) : ℕ → k \| 0 => ↑a⁻¹ \| n + 1 => succNthValUnits n a A fun i => inverseCoeff a A i.val /-- Upgrade a Witt vector `A` whose first entry `A.coeff 0` is a unit to be, itself, a unit in `𝕎 k`. -/ def mkUnit {a : Units k} {A : 𝕎 k} (hA : A.coeff 0 = a) : Units (𝕎 k) := Units.mkOfMulEqOne A (@WittVector.mk' p _ (inverseCoeff a A)) (by ext n induction' n with n _ · simp [WittVector.mul_coeff_zero, inverseCoeff, hA] let H_coeff := A.coeff (n + 1) * ↑(a⁻¹ ^ p ^ (n + 1)) + nthRemainder p n (truncateFun (n + 1) A) fun i : Fin (n + 1) => inverseCoeff a A i have H := Units.mul_inv (a ^ p ^ (n + 1)) linear_combination (norm := skip) -H_coeff * H have ha : (a : k) ^ p ^ (n + 1) = ↑(a ^ p ^ (n + 1)) := by norm_cast have ha_inv : (↑a⁻¹ : k) ^ p ^ (n + 1) = ↑(a ^ p ^ (n + 1))⁻¹ := by norm_cast simp only [nthRemainder_spec, inverseCoeff, succNthValUnits, hA, one_coeff_eq_of_pos, Nat.succ_pos', ha_inv, ha, inv_pow] ring!) @[simp] theorem coe_mkUnit {a : Units k} {A : 𝕎 k} (hA : A.coeff 0 = a) : (mkUnit hA : 𝕎 k) = A := rfl end CommRing section Field variable {k : Type} [Field k] [CharP k p] theorem isUnit_of_coeff_zero_ne_zero (x : 𝕎 k) (hx : x.coeff 0 ≠ 0) : IsUnit x := by let y : kˣ := Units.mk0 (x.coeff 0) hx have hy : x.coeff 0 = y := rfl exact (mkUnit hy).isUnit variable (p) theorem irreducible : Irreducible (p : 𝕎 k) := by have hp : ¬IsUnit (p : 𝕎 k) := by intro hp simpa only [constantCoeff_apply, coeff_p_zero, not_isUnit_zero] using (constantCoeff : WittVector p k →+ _).isUnit_map hp refine ⟨hp, fun a b hab => ?_⟩ obtain ⟨ha0, hb0⟩ : a ≠ 0 ∧ b ≠ 0 := by	rw [← mul_ne_zero_iff]; intro h; rw [h] at hab; exact p_nonzero p k hab obtain ⟨m, a, ha, rfl⟩ := verschiebung_nonzero ha0 obtain ⟨n, b, hb, rfl⟩ := verschiebung_nonzero hb0 cases m; · exact Or.inl (isUnit_of_coeff_zero_ne_zero a ha) rcases n with - \| n; · exact Or.inr (isUnit_of_coeff_zero_ne_zero b hb) rw [iterate_verschiebung_mul] at hab apply_fun fun x => coeff x 1 at hab simp only [coeff_p_one, Nat.add_succ, add_comm _ n, Function.iterate_succ', Function.comp_apply, verschiebung_coeff_add_one, verschiebung_coeff_zero] at hab exact (one_ne_zero hab).elim end Field section PerfectRing variable {k : Type*} [CommRing k] [CharP k p] [PerfectRing k p]	Mathlib/RingTheory/WittVector/DiscreteValuationRing.lean	96	112
/- Copyright (c) 2020 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel, Yury Kudryashov -/ import Mathlib.Analysis.Calculus.ContDiff.Operations import Mathlib.Analysis.Normed.Module.FiniteDimension /-! # Infinitely smooth "bump" functions A smooth bump function is an infinitely smooth function `f : E → ℝ` supported on a ball that is equal to `1` on a ball of smaller radius. These functions have many uses in real analysis. E.g., - they can be used to construct a smooth partition of unity which is a very useful tool; - they can be used to approximate a continuous function by infinitely smooth functions. There are two classes of spaces where bump functions are guaranteed to exist: inner product spaces and finite dimensional spaces. In this file we define a typeclass `HasContDiffBump` saying that a normed space has a family of smooth bump functions with certain properties. We also define a structure `ContDiffBump` that holds the center and radii of the balls from above. An element `f : ContDiffBump c` can be coerced to a function which is an infinitely smooth function such that - `f` is equal to `1` in `Metric.closedBall c f.rIn`; - `support f = Metric.ball c f.rOut`; - `0 ≤ f x ≤ 1` for all `x`. ## Main Definitions - `ContDiffBump (c : E)`: a structure holding data needed to construct an infinitely smooth bump function. - `ContDiffBumpBase (E : Type)`: a family of infinitely smooth bump functions that can be used to construct coercion of a `ContDiffBump (c : E)` to a function. - `HasContDiffBump (E : Type)`: a typeclass saying that `E` has a `ContDiffBumpBase`. Two instances of this typeclass (for inner product spaces and for finite dimensional spaces) are provided elsewhere. ## Keywords smooth function, smooth bump function -/ noncomputable section open Function Set Filter open scoped Topology Filter ContDiff variable {E X : Type} /-- `f : ContDiffBump c`, where `c` is a point in a normed vector space, is a bundled smooth function such that - `f` is equal to `1` in `Metric.closedBall c f.rIn`; - `support f = Metric.ball c f.rOut`; - `0 ≤ f x ≤ 1` for all `x`. The structure `ContDiffBump` contains the data required to construct the function: real numbers `rIn`, `rOut`, and proofs of `0 < rIn < rOut`. The function itself is available through `CoeFun` when the space is nice enough, i.e., satisfies the `HasContDiffBump` typeclass. -/ structure ContDiffBump (c : E) where /-- real numbers `0 < rIn < rOut` -/ (rIn rOut : ℝ) rIn_pos : 0 < rIn rIn_lt_rOut : rIn < rOut /-- The base function from which one will construct a family of bump functions. One could add more properties if they are useful and satisfied in the examples of inner product spaces and finite dimensional vector spaces, notably derivative norm control in terms of `R - 1`. TODO: do we ever need `f x = 1 ↔ ‖x‖ ≤ 1`? -/ structure ContDiffBumpBase (E : Type) [NormedAddCommGroup E] [NormedSpace ℝ E] where /-- The function underlying this family of bump functions -/ toFun : ℝ → E → ℝ mem_Icc : ∀ (R : ℝ) (x : E), toFun R x ∈ Icc (0 : ℝ) 1 symmetric : ∀ (R : ℝ) (x : E), toFun R (-x) = toFun R x smooth : ContDiffOn ℝ ∞ (uncurry toFun) (Ioi (1 : ℝ) ×ˢ (univ : Set E)) eq_one : ∀ R : ℝ, 1 < R → ∀ x : E, ‖x‖ ≤ 1 → toFun R x = 1 support : ∀ R : ℝ, 1 < R → Function.support (toFun R) = Metric.ball (0 : E) R /-- A class registering that a real vector space admits bump functions. This will be instantiated first for inner product spaces, and then for finite-dimensional normed spaces. We use a specific class instead of `Nonempty (ContDiffBumpBase E)` for performance reasons. -/ class HasContDiffBump (E : Type) [NormedAddCommGroup E] [NormedSpace ℝ E] : Prop where out : Nonempty (ContDiffBumpBase E) /-- In a space with `C^∞` bump functions, register some function that will be used as a basis to construct bump functions of arbitrary size around any point. -/ def someContDiffBumpBase (E : Type) [NormedAddCommGroup E] [NormedSpace ℝ E] [hb : HasContDiffBump E] : ContDiffBumpBase E := Nonempty.some hb.out namespace ContDiffBump theorem rOut_pos {c : E} (f : ContDiffBump c) : 0 < f.rOut := f.rIn_pos.trans f.rIn_lt_rOut theorem one_lt_rOut_div_rIn {c : E} (f : ContDiffBump c) : 1 < f.rOut / f.rIn := by rw [one_lt_div f.rIn_pos] exact f.rIn_lt_rOut instance (c : E) : Inhabited (ContDiffBump c) := ⟨⟨1, 2, zero_lt_one, one_lt_two⟩⟩ variable [NormedAddCommGroup E] [NormedSpace ℝ E] [NormedAddCommGroup X] [NormedSpace ℝ X] [HasContDiffBump E] {c : E} (f : ContDiffBump c) {x : E} {n : ℕ∞} /-- The function defined by `f : ContDiffBump c`. Use automatic coercion to function instead. -/ @[coe] def toFun {c : E} (f : ContDiffBump c) : E → ℝ := (someContDiffBumpBase E).toFun (f.rOut / f.rIn) ∘ fun x ↦ (f.rIn⁻¹ • (x - c)) instance : CoeFun (ContDiffBump c) fun _ => E → ℝ := ⟨toFun⟩ protected theorem apply (x : E) : f x = (someContDiffBumpBase E).toFun (f.rOut / f.rIn) (f.rIn⁻¹ • (x - c)) := rfl protected theorem sub (x : E) : f (c - x) = f (c + x) := by simp [f.apply, ContDiffBumpBase.symmetric] protected theorem neg (f : ContDiffBump (0 : E)) (x : E) : f (-x) = f x := by simp_rw [← zero_sub, f.sub, zero_add] open Metric theorem one_of_mem_closedBall (hx : x ∈ closedBall c f.rIn) : f x = 1 := by apply ContDiffBumpBase.eq_one _ _ f.one_lt_rOut_div_rIn simpa only [norm_smul, Real.norm_eq_abs, abs_inv, abs_of_nonneg f.rIn_pos.le, ← div_eq_inv_mul, div_le_one f.rIn_pos] using mem_closedBall_iff_norm.1 hx theorem nonneg : 0 ≤ f x := (ContDiffBumpBase.mem_Icc (someContDiffBumpBase E) _ _).1 /-- A version of `ContDiffBump.nonneg` with `x` explicit -/ theorem nonneg' (x : E) : 0 ≤ f x := f.nonneg theorem le_one : f x ≤ 1 := (ContDiffBumpBase.mem_Icc (someContDiffBumpBase E) _ _).2 theorem support_eq : Function.support f = Metric.ball c f.rOut := by simp only [toFun, support_comp_eq_preimage, ContDiffBumpBase.support _ _ f.one_lt_rOut_div_rIn] ext x simp only [mem_ball_iff_norm, sub_zero, norm_smul, mem_preimage, Real.norm_eq_abs, abs_inv, abs_of_pos f.rIn_pos, ← div_eq_inv_mul, div_lt_div_iff_of_pos_right f.rIn_pos] theorem tsupport_eq : tsupport f = closedBall c f.rOut := by simp_rw [tsupport, f.support_eq, closure_ball _ f.rOut_pos.ne'] theorem pos_of_mem_ball (hx : x ∈ ball c f.rOut) : 0 < f x := f.nonneg.lt_of_ne' <\| by rwa [← support_eq, mem_support] at hx theorem zero_of_le_dist (hx : f.rOut ≤ dist x c) : f x = 0 := by rwa [← nmem_support, support_eq, mem_ball, not_lt] protected theorem hasCompactSupport [FiniteDimensional ℝ E] : HasCompactSupport f := by simp_rw [HasCompactSupport, f.tsupport_eq, isCompact_closedBall] theorem eventuallyEq_one_of_mem_ball (h : x ∈ ball c f.rIn) : f =ᶠ[𝓝 x] 1 := mem_of_superset (closedBall_mem_nhds_of_mem h) fun _ ↦ f.one_of_mem_closedBall theorem eventuallyEq_one : f =ᶠ[𝓝 c] 1 := f.eventuallyEq_one_of_mem_ball (mem_ball_self f.rIn_pos) /-- `ContDiffBump` is `𝒞ⁿ` in all its arguments. -/ protected theorem _root_.ContDiffWithinAt.contDiffBump {c g : X → E} {s : Set X} {f : ∀ x, ContDiffBump (c x)} {x : X} (hc : ContDiffWithinAt ℝ n c s x) (hr : ContDiffWithinAt ℝ n (fun x => (f x).rIn) s x) (hR : ContDiffWithinAt ℝ n (fun x => (f x).rOut) s x) (hg : ContDiffWithinAt ℝ n g s x) : ContDiffWithinAt ℝ n (fun x => f x (g x)) s x := by change ContDiffWithinAt ℝ n (uncurry (someContDiffBumpBase E).toFun ∘ fun x : X => ((f x).rOut / (f x).rIn, (f x).rIn⁻¹ • (g x - c x))) s x refine (((someContDiffBumpBase E).smooth.contDiffAt ?_).of_le (mod_cast le_top)).comp_contDiffWithinAt x ?_ · exact prod_mem_nhds (Ioi_mem_nhds (f x).one_lt_rOut_div_rIn) univ_mem · exact (hR.div hr (f x).rIn_pos.ne').prodMk ((hr.inv (f x).rIn_pos.ne').smul (hg.sub hc)) /-- `ContDiffBump` is `𝒞ⁿ` in all its arguments. -/ protected nonrec theorem _root_.ContDiffAt.contDiffBump {c g : X → E} {f : ∀ x, ContDiffBump (c x)} {x : X} (hc : ContDiffAt ℝ n c x) (hr : ContDiffAt ℝ n (fun x => (f x).rIn) x) (hR : ContDiffAt ℝ n (fun x => (f x).rOut) x) (hg : ContDiffAt ℝ n g x) : ContDiffAt ℝ n (fun x => f x (g x)) x := hc.contDiffBump hr hR hg theorem _root_.ContDiff.contDiffBump {c g : X → E} {f : ∀ x, ContDiffBump (c x)} (hc : ContDiff ℝ n c) (hr : ContDiff ℝ n fun x => (f x).rIn) (hR : ContDiff ℝ n fun x => (f x).rOut) (hg : ContDiff ℝ n g) : ContDiff ℝ n fun x => f x (g x) := by rw [contDiff_iff_contDiffAt] at * exact fun x => (hc x).contDiffBump (hr x) (hR x) (hg x) protected theorem contDiff : ContDiff ℝ n f := contDiff_const.contDiffBump contDiff_const contDiff_const contDiff_id protected theorem contDiffAt : ContDiffAt ℝ n f x := f.contDiff.contDiffAt	protected theorem contDiffWithinAt {s : Set E} : ContDiffWithinAt ℝ n f s x := f.contDiffAt.contDiffWithinAt protected theorem continuous : Continuous f := contDiff_zero.mp f.contDiff end ContDiffBump	Mathlib/Analysis/Calculus/BumpFunction/Basic.lean	204	214
/- 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.BigOperators.Finprod import Mathlib.Topology.ContinuousMap.Algebra import Mathlib.Topology.Compactness.Paracompact import Mathlib.Topology.ShrinkingLemma import Mathlib.Topology.UrysohnsLemma import Mathlib.Topology.ContinuousMap.Ordered /-! # Continuous partition of unity In this file we define `PartitionOfUnity (ι X : Type) [TopologicalSpace X] (s : Set X := univ)` to be a continuous partition of unity on `s` indexed by `ι`. More precisely, `f : PartitionOfUnity ι X s` is a collection of continuous functions `f i : C(X, ℝ)`, `i : ι`, such that the supports of `f i` form a locally finite family of sets; * each `f i` is nonnegative; * `∑ᶠ i, f i x = 1` for all `x ∈ s`; * `∑ᶠ i, f i x ≤ 1` for all `x : X`. In the case `s = univ` the last assumption follows from the previous one but it is convenient to have this assumption in the case `s ≠ univ`. We also define a bump function covering, `BumpCovering (ι X : Type) [TopologicalSpace X] (s : Set X := univ)`, to be a collection of functions `f i : C(X, ℝ)`, `i : ι`, such that the supports of `f i` form a locally finite family of sets; * each `f i` is nonnegative; * for each `x ∈ s` there exists `i : ι` such that `f i y = 1` in a neighborhood of `x`. The term is motivated by the smooth case. If `f` is a bump function covering indexed by a linearly ordered type, then `g i x = f i x * ∏ᶠ j < i, (1 - f j x)` is a partition of unity, see `BumpCovering.toPartitionOfUnity`. Note that only finitely many terms `1 - f j x` are not equal to one, so this product is well-defined. Note that `g i x = ∏ᶠ j ≤ i, (1 - f j x) - ∏ᶠ j < i, (1 - f j x)`, so most terms in the sum `∑ᶠ i, g i x` cancel, and we get `∑ᶠ i, g i x = 1 - ∏ᶠ i, (1 - f i x)`, and the latter product equals zero because one of `f i x` is equal to one. We say that a partition of unity or a bump function covering `f` is subordinate to a family of sets `U i`, `i : ι`, if the closure of the support of each `f i` is included in `U i`. We use Urysohn's Lemma to prove that a locally finite open covering of a normal topological space admits a subordinate bump function covering (hence, a subordinate partition of unity), see `BumpCovering.exists_isSubordinate_of_locallyFinite`. If `X` is a paracompact space, then any open covering admits a locally finite refinement, hence it admits a subordinate bump function covering and a subordinate partition of unity, see `BumpCovering.exists_isSubordinate`. We also provide two slightly more general versions of these lemmas, `BumpCovering.exists_isSubordinate_of_locallyFinite_of_prop` and `BumpCovering.exists_isSubordinate_of_prop`, to be used later in the construction of a smooth partition of unity. ## Implementation notes Most (if not all) books only define a partition of unity of the whole space. However, quite a few proofs only deal with `f i` such that `tsupport (f i)` meets a specific closed subset, and it is easier to formalize these proofs if we don't have other functions right away. We use `WellOrderingRel j i` instead of `j < i` in the definition of `BumpCovering.toPartitionOfUnity` to avoid a `[LinearOrder ι]` assumption. While `WellOrderingRel j i` is a well order, not only a strict linear order, we never use this property. ## Tags partition of unity, bump function, Urysohn's lemma, normal space, paracompact space -/ universe u v open Function Set Filter Topology noncomputable section /-- A continuous partition of unity on a set `s : Set X` is a collection of continuous functions `f i` such that * the supports of `f i` form a locally finite family of sets, i.e., for every point `x : X` there exists a neighborhood `U ∋ x` such that all but finitely many functions `f i` are zero on `U`; * the functions `f i` are nonnegative; * the sum `∑ᶠ i, f i x` is equal to one for every `x ∈ s` and is less than or equal to one otherwise. If `X` is a normal paracompact space, then `PartitionOfUnity.exists_isSubordinate` guarantees that for every open covering `U : Set (Set X)` of `s` there exists a partition of unity that is subordinate to `U`. -/ structure PartitionOfUnity (ι X : Type) [TopologicalSpace X] (s : Set X := univ) where /-- The collection of continuous functions underlying this partition of unity -/ toFun : ι → C(X, ℝ) /-- the supports of the underlying functions are a locally finite family of sets -/ locallyFinite' : LocallyFinite fun i => support (toFun i) /-- the functions are non-negative -/ nonneg' : 0 ≤ toFun /-- the functions sum up to one on `s` -/ sum_eq_one' : ∀ x ∈ s, ∑ᶠ i, toFun i x = 1 /-- the functions sum up to at most one, globally -/ sum_le_one' : ∀ x, ∑ᶠ i, toFun i x ≤ 1 /-- A `BumpCovering ι X s` is an indexed family of functions `f i`, `i : ι`, such that the supports of `f i` form a locally finite family of sets, i.e., for every point `x : X` there exists a neighborhood `U ∋ x` such that all but finitely many functions `f i` are zero on `U`; * for all `i`, `x` we have `0 ≤ f i x ≤ 1`; * each point `x ∈ s` belongs to the interior of `{x \| f i x = 1}` for some `i`. One of the main use cases for a `BumpCovering` is to define a `PartitionOfUnity`, see `BumpCovering.toPartitionOfUnity`, but some proofs can directly use a `BumpCovering` instead of a `PartitionOfUnity`. If `X` is a normal paracompact space, then `BumpCovering.exists_isSubordinate` guarantees that for every open covering `U : Set (Set X)` of `s` there exists a `BumpCovering` of `s` that is subordinate to `U`. -/ structure BumpCovering (ι X : Type) [TopologicalSpace X] (s : Set X := univ) where /-- The collections of continuous functions underlying this bump covering -/ toFun : ι → C(X, ℝ) /-- the supports of the underlying functions are a locally finite family of sets -/ locallyFinite' : LocallyFinite fun i => support (toFun i) /-- the functions are non-negative -/ nonneg' : 0 ≤ toFun /-- the functions are each at most one -/ le_one' : toFun ≤ 1 /-- Each point `x ∈ s` belongs to the interior of `{x \| f i x = 1}` for some `i`. -/ eventuallyEq_one' : ∀ x ∈ s, ∃ i, toFun i =ᶠ[𝓝 x] 1 variable {ι : Type u} {X : Type v} [TopologicalSpace X] namespace PartitionOfUnity variable {E : Type} [AddCommMonoid E] [SMulWithZero ℝ E] [TopologicalSpace E] [ContinuousSMul ℝ E] {s : Set X} (f : PartitionOfUnity ι X s) instance : FunLike (PartitionOfUnity ι X s) ι C(X, ℝ) where coe := toFun coe_injective' f g h := by cases f; cases g; congr protected theorem locallyFinite : LocallyFinite fun i => support (f i) := f.locallyFinite' theorem locallyFinite_tsupport : LocallyFinite fun i => tsupport (f i) := f.locallyFinite.closure theorem nonneg (i : ι) (x : X) : 0 ≤ f i x := f.nonneg' i x theorem sum_eq_one {x : X} (hx : x ∈ s) : ∑ᶠ i, f i x = 1 := f.sum_eq_one' x hx /-- If `f` is a partition of unity on `s`, then for every `x ∈ s` there exists an index `i` such that `0 < f i x`. -/ theorem exists_pos {x : X} (hx : x ∈ s) : ∃ i, 0 < f i x := by have H := f.sum_eq_one hx contrapose! H simpa only [fun i => (H i).antisymm (f.nonneg i x), finsum_zero] using zero_ne_one theorem sum_le_one (x : X) : ∑ᶠ i, f i x ≤ 1 := f.sum_le_one' x theorem sum_nonneg (x : X) : 0 ≤ ∑ᶠ i, f i x := finsum_nonneg fun i => f.nonneg i x theorem le_one (i : ι) (x : X) : f i x ≤ 1 := (single_le_finsum i (f.locallyFinite.point_finite x) fun j => f.nonneg j x).trans (f.sum_le_one x) section finsupport variable {s : Set X} (ρ : PartitionOfUnity ι X s) (x₀ : X) /-- The support of a partition of unity at a point `x₀` as a `Finset`. This is the set of `i : ι` such that `x₀ ∈ support f i`, i.e. `f i ≠ x₀`. -/ def finsupport : Finset ι := (ρ.locallyFinite.point_finite x₀).toFinset @[simp] theorem mem_finsupport (x₀ : X) {i} : i ∈ ρ.finsupport x₀ ↔ i ∈ support fun i ↦ ρ i x₀ := by simp only [finsupport, mem_support, Finite.mem_toFinset, mem_setOf_eq] @[simp] theorem coe_finsupport (x₀ : X) : (ρ.finsupport x₀ : Set ι) = support fun i ↦ ρ i x₀ := by ext rw [Finset.mem_coe, mem_finsupport] variable {x₀ : X} theorem sum_finsupport (hx₀ : x₀ ∈ s) : ∑ i ∈ ρ.finsupport x₀, ρ i x₀ = 1 := by rw [← ρ.sum_eq_one hx₀, finsum_eq_sum_of_support_subset _ (ρ.coe_finsupport x₀).superset] theorem sum_finsupport' (hx₀ : x₀ ∈ s) {I : Finset ι} (hI : ρ.finsupport x₀ ⊆ I) : ∑ i ∈ I, ρ i x₀ = 1 := by classical rw [← Finset.sum_sdiff hI, ρ.sum_finsupport hx₀] suffices ∑ i ∈ I \ ρ.finsupport x₀, (ρ i) x₀ = ∑ i ∈ I \ ρ.finsupport x₀, 0 by rw [this, add_eq_right, Finset.sum_const_zero] apply Finset.sum_congr rfl rintro x hx simp only [Finset.mem_sdiff, ρ.mem_finsupport, mem_support, Classical.not_not] at hx exact hx.2 theorem sum_finsupport_smul_eq_finsum {M : Type} [AddCommMonoid M] [Module ℝ M] (φ : ι → X → M) : ∑ i ∈ ρ.finsupport x₀, ρ i x₀ • φ i x₀ = ∑ᶠ i, ρ i x₀ • φ i x₀ := by apply (finsum_eq_sum_of_support_subset _ _).symm have : (fun i ↦ (ρ i) x₀ • φ i x₀) = (fun i ↦ (ρ i) x₀) • (fun i ↦ φ i x₀) := funext fun _ => (Pi.smul_apply' _ _ _).symm rw [ρ.coe_finsupport x₀, this, support_smul] exact inter_subset_left end finsupport section fintsupport -- partitions of unity have locally finite `tsupport` variable {s : Set X} (ρ : PartitionOfUnity ι X s) (x₀ : X) /-- The `tsupport`s of a partition of unity are locally finite. -/ theorem finite_tsupport : {i \| x₀ ∈ tsupport (ρ i)}.Finite := by rcases ρ.locallyFinite x₀ with ⟨t, t_in, ht⟩ apply ht.subset rintro i hi simp only [inter_comm] exact mem_closure_iff_nhds.mp hi t t_in /-- The tsupport of a partition of unity at a point `x₀` as a `Finset`. This is the set of `i : ι` such that `x₀ ∈ tsupport f i`. -/ def fintsupport (x₀ : X) : Finset ι := (ρ.finite_tsupport x₀).toFinset theorem mem_fintsupport_iff (i : ι) : i ∈ ρ.fintsupport x₀ ↔ x₀ ∈ tsupport (ρ i) := Finite.mem_toFinset _ theorem eventually_fintsupport_subset : ∀ᶠ y in 𝓝 x₀, ρ.fintsupport y ⊆ ρ.fintsupport x₀ := by apply (ρ.locallyFinite.closure.eventually_subset (fun _ ↦ isClosed_closure) x₀).mono intro y hy z hz rw [PartitionOfUnity.mem_fintsupport_iff] at exact hy hz theorem finsupport_subset_fintsupport : ρ.finsupport x₀ ⊆ ρ.fintsupport x₀ := fun i hi ↦ by rw [ρ.mem_fintsupport_iff] apply subset_closure exact (ρ.mem_finsupport x₀).mp hi theorem eventually_finsupport_subset : ∀ᶠ y in 𝓝 x₀, ρ.finsupport y ⊆ ρ.fintsupport x₀ := (ρ.eventually_fintsupport_subset x₀).mono fun y hy ↦ (ρ.finsupport_subset_fintsupport y).trans hy end fintsupport /-- If `f` is a partition of unity on `s : Set X` and `g : X → E` is continuous at every point of the topological support of some `f i`, then `fun x ↦ f i x • g x` is continuous on the whole space. -/ theorem continuous_smul {g : X → E} {i : ι} (hg : ∀ x ∈ tsupport (f i), ContinuousAt g x) : Continuous fun x => f i x • g x := continuous_of_tsupport fun x hx => ((f i).continuousAt x).smul <\| hg x <\| tsupport_smul_subset_left _ _ hx /-- If `f` is a partition of unity on a set `s : Set X` and `g : ι → X → E` is a family of functions such that each `g i` is continuous at every point of the topological support of `f i`, then the sum `fun x ↦ ∑ᶠ i, f i x • g i x` is continuous on the whole space. -/ theorem continuous_finsum_smul [ContinuousAdd E] {g : ι → X → E} (hg : ∀ (i), ∀ x ∈ tsupport (f i), ContinuousAt (g i) x) : Continuous fun x => ∑ᶠ i, f i x • g i x := (continuous_finsum fun i => f.continuous_smul (hg i)) <\| f.locallyFinite.subset fun _ => support_smul_subset_left _ _ /-- A partition of unity `f i` is subordinate to a family of sets `U i` indexed by the same type if for each `i` the closure of the support of `f i` is a subset of `U i`. -/ def IsSubordinate (U : ι → Set X) : Prop := ∀ i, tsupport (f i) ⊆ U i variable {f} theorem exists_finset_nhd' {s : Set X} (ρ : PartitionOfUnity ι X s) (x₀ : X) : ∃ I : Finset ι, (∀ᶠ x in 𝓝[s] x₀, ∑ i ∈ I, ρ i x = 1) ∧ ∀ᶠ x in 𝓝 x₀, support (ρ · x) ⊆ I := by rcases ρ.locallyFinite.exists_finset_support x₀ with ⟨I, hI⟩ refine ⟨I, eventually_nhdsWithin_iff.mpr (hI.mono fun x hx x_in ↦ ?_), hI⟩ have : ∑ᶠ i : ι, ρ i x = ∑ i ∈ I, ρ i x := finsum_eq_sum_of_support_subset _ hx rwa [eq_comm, ρ.sum_eq_one x_in] at this theorem exists_finset_nhd (ρ : PartitionOfUnity ι X univ) (x₀ : X) : ∃ I : Finset ι, ∀ᶠ x in 𝓝 x₀, ∑ i ∈ I, ρ i x = 1 ∧ support (ρ · x) ⊆ I := by rcases ρ.exists_finset_nhd' x₀ with ⟨I, H⟩ use I rwa [nhdsWithin_univ, ← eventually_and] at H theorem exists_finset_nhd_support_subset {U : ι → Set X} (hso : f.IsSubordinate U) (ho : ∀ i, IsOpen (U i)) (x : X) : ∃ is : Finset ι, ∃ n ∈ 𝓝 x, n ⊆ ⋂ i ∈ is, U i ∧ ∀ z ∈ n, (support (f · z)) ⊆ is := f.locallyFinite.exists_finset_nhd_support_subset hso ho x /-- If `f` is a partition of unity that is subordinate to a family of open sets `U i` and `g : ι → X → E` is a family of functions such that each `g i` is continuous on `U i`, then the sum `fun x ↦ ∑ᶠ i, f i x • g i x` is a continuous function. -/ theorem IsSubordinate.continuous_finsum_smul [ContinuousAdd E] {U : ι → Set X} (ho : ∀ i, IsOpen (U i)) (hf : f.IsSubordinate U) {g : ι → X → E} (hg : ∀ i, ContinuousOn (g i) (U i)) : Continuous fun x => ∑ᶠ i, f i x • g i x := f.continuous_finsum_smul fun i _ hx => (hg i).continuousAt <\| (ho i).mem_nhds <\| hf i hx end PartitionOfUnity namespace BumpCovering variable {s : Set X} (f : BumpCovering ι X s) instance : FunLike (BumpCovering ι X s) ι C(X, ℝ) where coe := toFun coe_injective' f g h := by cases f; cases g; congr @[simp] lemma toFun_eq_coe : f.toFun = f := rfl protected theorem locallyFinite : LocallyFinite fun i => support (f i) := f.locallyFinite' theorem locallyFinite_tsupport : LocallyFinite fun i => tsupport (f i) := f.locallyFinite.closure protected theorem point_finite (x : X) : { i \| f i x ≠ 0 }.Finite := f.locallyFinite.point_finite x theorem nonneg (i : ι) (x : X) : 0 ≤ f i x := f.nonneg' i x theorem le_one (i : ι) (x : X) : f i x ≤ 1 := f.le_one' i x open Classical in /-- A `BumpCovering` that consists of a single function, uniformly equal to one, defined as an example for `Inhabited` instance. -/ protected def single (i : ι) (s : Set X) : BumpCovering ι X s where toFun := Pi.single i 1 locallyFinite' x := by refine ⟨univ, univ_mem, (finite_singleton i).subset ?_⟩ rintro j ⟨x, hx, -⟩ contrapose! hx rw [mem_singleton_iff] at hx simp [hx] nonneg' := le_update_iff.2 ⟨fun _ => zero_le_one, fun _ _ => le_rfl⟩ le_one' := update_le_iff.2 ⟨le_rfl, fun _ _ _ => zero_le_one⟩ eventuallyEq_one' x _ := ⟨i, by rw [Pi.single_eq_same, ContinuousMap.coe_one]⟩ open Classical in @[simp] theorem coe_single (i : ι) (s : Set X) : ⇑(BumpCovering.single i s) = Pi.single i 1 := by rfl instance [Inhabited ι] : Inhabited (BumpCovering ι X s) := ⟨BumpCovering.single default s⟩ /-- A collection of bump functions `f i` is subordinate to a family of sets `U i` indexed by the same type if for each `i` the closure of the support of `f i` is a subset of `U i`. -/ def IsSubordinate (f : BumpCovering ι X s) (U : ι → Set X) : Prop := ∀ i, tsupport (f i) ⊆ U i theorem IsSubordinate.mono {f : BumpCovering ι X s} {U V : ι → Set X} (hU : f.IsSubordinate U) (hV : ∀ i, U i ⊆ V i) : f.IsSubordinate V := fun i => Subset.trans (hU i) (hV i) /-- If `X` is a normal topological space and `U i`, `i : ι`, is a locally finite open covering of a closed set `s`, then there exists a `BumpCovering ι X s` that is subordinate to `U`. If `X` is a paracompact space, then the assumption `hf : LocallyFinite U` can be omitted, see `BumpCovering.exists_isSubordinate`. This version assumes that `p : (X → ℝ) → Prop` is a predicate that satisfies Urysohn's lemma, and provides a `BumpCovering` such that each function of the covering satisfies `p`. -/ theorem exists_isSubordinate_of_locallyFinite_of_prop [NormalSpace X] (p : (X → ℝ) → Prop) (h01 : ∀ s t, IsClosed s → IsClosed t → Disjoint s t → ∃ f : C(X, ℝ), p f ∧ EqOn f 0 s ∧ EqOn f 1 t ∧ ∀ x, f x ∈ Icc (0 : ℝ) 1) (hs : IsClosed s) (U : ι → Set X) (ho : ∀ i, IsOpen (U i)) (hf : LocallyFinite U) (hU : s ⊆ ⋃ i, U i) : ∃ f : BumpCovering ι X s, (∀ i, p (f i)) ∧ f.IsSubordinate U := by rcases exists_subset_iUnion_closure_subset hs ho (fun x _ => hf.point_finite x) hU with ⟨V, hsV, hVo, hVU⟩ have hVU' : ∀ i, V i ⊆ U i := fun i => Subset.trans subset_closure (hVU i) rcases exists_subset_iUnion_closure_subset hs hVo (fun x _ => (hf.subset hVU').point_finite x) hsV with ⟨W, hsW, hWo, hWV⟩ choose f hfp hf0 hf1 hf01 using fun i => h01 _ _ (isClosed_compl_iff.2 <\| hVo i) isClosed_closure (disjoint_right.2 fun x hx => Classical.not_not.2 (hWV i hx)) have hsupp : ∀ i, support (f i) ⊆ V i := fun i => support_subset_iff'.2 (hf0 i) refine ⟨⟨f, hf.subset fun i => Subset.trans (hsupp i) (hVU' i), fun i x => (hf01 i x).1, fun i x => (hf01 i x).2, fun x hx => ?_⟩, hfp, fun i => Subset.trans (closure_mono (hsupp i)) (hVU i)⟩ rcases mem_iUnion.1 (hsW hx) with ⟨i, hi⟩ exact ⟨i, ((hf1 i).mono subset_closure).eventuallyEq_of_mem ((hWo i).mem_nhds hi)⟩ /-- If `X` is a normal topological space and `U i`, `i : ι`, is a locally finite open covering of a closed set `s`, then there exists a `BumpCovering ι X s` that is subordinate to `U`. If `X` is a paracompact space, then the assumption `hf : LocallyFinite U` can be omitted, see `BumpCovering.exists_isSubordinate`. -/ theorem exists_isSubordinate_of_locallyFinite [NormalSpace X] (hs : IsClosed s) (U : ι → Set X) (ho : ∀ i, IsOpen (U i)) (hf : LocallyFinite U) (hU : s ⊆ ⋃ i, U i) : ∃ f : BumpCovering ι X s, f.IsSubordinate U := let ⟨f, _, hfU⟩ := exists_isSubordinate_of_locallyFinite_of_prop (fun _ => True) (fun _ _ hs ht hd => (exists_continuous_zero_one_of_isClosed hs ht hd).imp fun _ hf => ⟨trivial, hf⟩) hs U ho hf hU ⟨f, hfU⟩ /-- If `X` is a paracompact normal topological space and `U` is an open covering of a closed set `s`, then there exists a `BumpCovering ι X s` that is subordinate to `U`. This version assumes that `p : (X → ℝ) → Prop` is a predicate that satisfies Urysohn's lemma, and provides a `BumpCovering` such that each function of the covering satisfies `p`. -/ theorem exists_isSubordinate_of_prop [NormalSpace X] [ParacompactSpace X] (p : (X → ℝ) → Prop) (h01 : ∀ s t, IsClosed s → IsClosed t → Disjoint s t → ∃ f : C(X, ℝ), p f ∧ EqOn f 0 s ∧ EqOn f 1 t ∧ ∀ x, f x ∈ Icc (0 : ℝ) 1) (hs : IsClosed s) (U : ι → Set X) (ho : ∀ i, IsOpen (U i)) (hU : s ⊆ ⋃ i, U i) : ∃ f : BumpCovering ι X s, (∀ i, p (f i)) ∧ f.IsSubordinate U := by rcases precise_refinement_set hs _ ho hU with ⟨V, hVo, hsV, hVf, hVU⟩ rcases exists_isSubordinate_of_locallyFinite_of_prop p h01 hs V hVo hVf hsV with ⟨f, hfp, hf⟩ exact ⟨f, hfp, hf.mono hVU⟩ /-- If `X` is a paracompact normal topological space and `U` is an open covering of a closed set `s`, then there exists a `BumpCovering ι X s` that is subordinate to `U`. -/ theorem exists_isSubordinate [NormalSpace X] [ParacompactSpace X] (hs : IsClosed s) (U : ι → Set X) (ho : ∀ i, IsOpen (U i)) (hU : s ⊆ ⋃ i, U i) : ∃ f : BumpCovering ι X s, f.IsSubordinate U := by rcases precise_refinement_set hs _ ho hU with ⟨V, hVo, hsV, hVf, hVU⟩ rcases exists_isSubordinate_of_locallyFinite hs V hVo hVf hsV with ⟨f, hf⟩ exact ⟨f, hf.mono hVU⟩ /-- If `X` is a locally compact T2 topological space and `U i`, `i : ι`, is a locally finite open covering of a compact set `s`, then there exists a `BumpCovering ι X s` that is subordinate to `U`. If `X` is a paracompact space, then the assumption `hf : LocallyFinite U` can be omitted, see `BumpCovering.exists_isSubordinate`. This version assumes that `p : (X → ℝ) → Prop` is a predicate that satisfies Urysohn's lemma, and provides a `BumpCovering` such that each function of the covering satisfies `p`. -/ theorem exists_isSubordinate_of_locallyFinite_of_prop_t2space [LocallyCompactSpace X] [T2Space X] (p : (X → ℝ) → Prop) (h01 : ∀ s t, IsClosed s → IsCompact t → Disjoint s t → ∃ f : C(X, ℝ), p f ∧ EqOn f 0 s ∧ EqOn f 1 t ∧ ∀ x, f x ∈ Icc (0 : ℝ) 1) (hs : IsCompact s) (U : ι → Set X) (ho : ∀ i, IsOpen (U i)) (hf : LocallyFinite U) (hU : s ⊆ ⋃ i, U i) : ∃ f : BumpCovering ι X s, (∀ i, p (f i)) ∧ f.IsSubordinate U ∧ ∀ i, HasCompactSupport (f i) := by rcases exists_subset_iUnion_closure_subset_t2space hs ho (fun x _ => hf.point_finite x) hU with ⟨V, hsV, hVo, hVU, hcp⟩ have hVU' i : V i ⊆ U i := subset_closure.trans (hVU i) rcases exists_subset_iUnion_closure_subset_t2space hs hVo (fun x _ => (hf.subset hVU').point_finite x) hsV with ⟨W, hsW, hWo, hWV, hWc⟩ choose f hfp hf0 hf1 hf01 using fun i => h01 _ _ (isClosed_compl_iff.2 <\| hVo i) (hWc i) (disjoint_right.2 fun x hx => Classical.not_not.2 (hWV i hx)) have hsupp i : support (f i) ⊆ V i := support_subset_iff'.2 (hf0 i) refine ⟨⟨f, hf.subset fun i => Subset.trans (hsupp i) (hVU' i), fun i x => (hf01 i x).1, fun i x => (hf01 i x).2, fun x hx => ?_⟩, hfp, fun i => Subset.trans (closure_mono (hsupp i)) (hVU i), fun i => IsCompact.of_isClosed_subset (hcp i) isClosed_closure <\| closure_mono (hsupp i)⟩ rcases mem_iUnion.1 (hsW hx) with ⟨i, hi⟩ exact ⟨i, ((hf1 i).mono subset_closure).eventuallyEq_of_mem ((hWo i).mem_nhds hi)⟩ /-- If `X` is a normal topological space and `U i`, `i : ι`, is a locally finite open covering of a closed set `s`, then there exists a `BumpCovering ι X s` that is subordinate to `U`. If `X` is a paracompact space, then the assumption `hf : LocallyFinite U` can be omitted, see `BumpCovering.exists_isSubordinate`. -/ theorem exists_isSubordinate_hasCompactSupport_of_locallyFinite_t2space [LocallyCompactSpace X] [T2Space X] (hs : IsCompact s) (U : ι → Set X) (ho : ∀ i, IsOpen (U i)) (hf : LocallyFinite U) (hU : s ⊆ ⋃ i, U i) : ∃ f : BumpCovering ι X s, f.IsSubordinate U ∧ ∀ i, HasCompactSupport (f i) := by -- need to switch 0 and 1 in `exists_continuous_zero_one_of_isCompact` simpa using exists_isSubordinate_of_locallyFinite_of_prop_t2space (fun _ => True) (fun _ _ ht hs hd => (exists_continuous_zero_one_of_isCompact' hs ht hd.symm).imp fun _ hf => ⟨trivial, hf⟩) hs U ho hf hU /-- Index of a bump function such that `fs i =ᶠ[𝓝 x] 1`. -/ def ind (x : X) (hx : x ∈ s) : ι := (f.eventuallyEq_one' x hx).choose theorem eventuallyEq_one (x : X) (hx : x ∈ s) : f (f.ind x hx) =ᶠ[𝓝 x] 1 := (f.eventuallyEq_one' x hx).choose_spec theorem ind_apply (x : X) (hx : x ∈ s) : f (f.ind x hx) x = 1 := (f.eventuallyEq_one x hx).eq_of_nhds /-- Partition of unity defined by a `BumpCovering`. We use this auxiliary definition to prove some properties of the new family of functions before bundling it into a `PartitionOfUnity`. Do not use this definition, use `BumpCovering.toPartitionOfUnity` instead. The partition of unity is given by the formula `g i x = f i x * ∏ᶠ j < i, (1 - f j x)`. In other words, `g i x = ∏ᶠ j < i, (1 - f j x) - ∏ᶠ j ≤ i, (1 - f j x)`, so `∑ᶠ i, g i x = 1 - ∏ᶠ j, (1 - f j x)`. If `x ∈ s`, then one of `f j x` equals one, hence the product of `1 - f j x` vanishes, and `∑ᶠ i, g i x = 1`.	In order to avoid an assumption `LinearOrder ι`, we use `WellOrderingRel` instead of `(<)`. -/ def toPOUFun (i : ι) (x : X) : ℝ := f i x * ∏ᶠ (j) (_ : WellOrderingRel j i), (1 - f j x) theorem toPOUFun_zero_of_zero {i : ι} {x : X} (h : f i x = 0) : f.toPOUFun i x = 0 := by rw [toPOUFun, h, zero_mul] theorem support_toPOUFun_subset (i : ι) : support (f.toPOUFun i) ⊆ support (f i) := fun _ => mt <\| f.toPOUFun_zero_of_zero open Classical in theorem toPOUFun_eq_mul_prod (i : ι) (x : X) (t : Finset ι) (ht : ∀ j, WellOrderingRel j i → f j x ≠ 0 → j ∈ t) : f.toPOUFun i x = f i x * ∏ j ∈ t with WellOrderingRel j i, (1 - f j x) := by	Mathlib/Topology/PartitionOfUnity.lean	491	505
/- Copyright (c) 2023 Rémi Bottinelli. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémi Bottinelli -/ import Mathlib.Data.Set.Function import Mathlib.Analysis.RCLike.Basic import Mathlib.Topology.EMetricSpace.BoundedVariation /-! # Constant speed This file defines the notion of constant (and unit) speed for a function `f : ℝ → E` with pseudo-emetric structure on `E` with respect to a set `s : Set ℝ` and "speed" `l : ℝ≥0`, and shows that if `f` has locally bounded variation on `s`, it can be obtained (up to distance zero, on `s`), as a composite `φ ∘ (variationOnFromTo f s a)`, where `φ` has unit speed and `a ∈ s`. ## Main definitions * `HasConstantSpeedOnWith f s l`, stating that the speed of `f` on `s` is `l`. * `HasUnitSpeedOn f s`, stating that the speed of `f` on `s` is `1`. * `naturalParameterization f s a : ℝ → E`, the unit speed reparameterization of `f` on `s` relative to `a`. ## Main statements * `unique_unit_speed_on_Icc_zero` proves that if `f` and `f ∘ φ` are both naturally parameterized on closed intervals starting at `0`, then `φ` must be the identity on those intervals. * `edist_naturalParameterization_eq_zero` proves that if `f` has locally bounded variation, then precomposing `naturalParameterization f s a` with `variationOnFromTo f s a` yields a function at distance zero from `f` on `s`. * `has_unit_speed_naturalParameterization` proves that if `f` has locally bounded variation, then `naturalParameterization f s a` has unit speed on `s`. ## Tags arc-length, parameterization -/ open scoped NNReal ENNReal open Set variable {α : Type} [LinearOrder α] {E : Type} [PseudoEMetricSpace E] variable (f : ℝ → E) (s : Set ℝ) (l : ℝ≥0) /-- `f` has constant speed `l` on `s` if the variation of `f` on `s ∩ Icc x y` is equal to `l * (y - x)` for any `x y` in `s`. -/ def HasConstantSpeedOnWith := ∀ ⦃x⦄ (_ : x ∈ s) ⦃y⦄ (_ : y ∈ s), eVariationOn f (s ∩ Icc x y) = ENNReal.ofReal (l * (y - x)) variable {f s l} theorem HasConstantSpeedOnWith.hasLocallyBoundedVariationOn (h : HasConstantSpeedOnWith f s l) : LocallyBoundedVariationOn f s := fun x y hx hy => by simp only [BoundedVariationOn, h hx hy, Ne, ENNReal.ofReal_ne_top, not_false_iff] theorem hasConstantSpeedOnWith_of_subsingleton (f : ℝ → E) {s : Set ℝ} (hs : s.Subsingleton) (l : ℝ≥0) : HasConstantSpeedOnWith f s l := by rintro x hx y hy; cases hs hx hy rw [eVariationOn.subsingleton f (fun y hy z hz => hs hy.1 hz.1 : (s ∩ Icc x x).Subsingleton)] simp only [sub_self, mul_zero, ENNReal.ofReal_zero] theorem hasConstantSpeedOnWith_iff_ordered : HasConstantSpeedOnWith f s l ↔ ∀ ⦃x⦄ (_ : x ∈ s) ⦃y⦄ (_ : y ∈ s), x ≤ y → eVariationOn f (s ∩ Icc x y) = ENNReal.ofReal (l * (y - x)) := by refine ⟨fun h x xs y ys _ => h xs ys, fun h x xs y ys => ?_⟩ rcases le_total x y with (xy \| yx) · exact h xs ys xy · rw [eVariationOn.subsingleton, ENNReal.ofReal_of_nonpos] · exact mul_nonpos_of_nonneg_of_nonpos l.prop (sub_nonpos_of_le yx) · rintro z ⟨zs, xz, zy⟩ w ⟨ws, xw, wy⟩ cases le_antisymm (zy.trans yx) xz cases le_antisymm (wy.trans yx) xw rfl theorem hasConstantSpeedOnWith_iff_variationOnFromTo_eq : HasConstantSpeedOnWith f s l ↔ LocallyBoundedVariationOn f s ∧ ∀ ⦃x⦄ (_ : x ∈ s) ⦃y⦄ (_ : y ∈ s), variationOnFromTo f s x y = l * (y - x) := by constructor · rintro h; refine ⟨h.hasLocallyBoundedVariationOn, fun x xs y ys => ?_⟩	rw [hasConstantSpeedOnWith_iff_ordered] at h rcases le_total x y with (xy \| yx) · rw [variationOnFromTo.eq_of_le f s xy, h xs ys xy] exact ENNReal.toReal_ofReal (mul_nonneg l.prop (sub_nonneg.mpr xy)) · rw [variationOnFromTo.eq_of_ge f s yx, h ys xs yx] have := ENNReal.toReal_ofReal (mul_nonneg l.prop (sub_nonneg.mpr yx)) simp_all only [NNReal.val_eq_coe]; ring · rw [hasConstantSpeedOnWith_iff_ordered] rintro h x xs y ys xy rw [← h.2 xs ys, variationOnFromTo.eq_of_le f s xy, ENNReal.ofReal_toReal (h.1 x y xs ys)] theorem HasConstantSpeedOnWith.union {t : Set ℝ} (hfs : HasConstantSpeedOnWith f s l) (hft : HasConstantSpeedOnWith f t l) {x : ℝ} (hs : IsGreatest s x) (ht : IsLeast t x) : HasConstantSpeedOnWith f (s ∪ t) l := by rw [hasConstantSpeedOnWith_iff_ordered] at hfs hft ⊢	Mathlib/Analysis/ConstantSpeed.lean	85	99
/- Copyright (c) 2020 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin, Robert Y. Lewis -/ import Mathlib.RingTheory.WittVector.StructurePolynomial /-! # Witt vectors In this file we define the type of `p`-typical Witt vectors and ring operations on it. The ring axioms are verified in `Mathlib/RingTheory/WittVector/Basic.lean`. For a fixed commutative ring `R` and prime `p`, a Witt vector `x : 𝕎 R` is an infinite sequence `ℕ → R` of elements of `R`. However, the ring operations `+` and `` are not defined in the obvious component-wise way. Instead, these operations are defined via certain polynomials using the machinery in `Mathlib/RingTheory/WittVector/StructurePolynomial.lean`. The `n`th value of the sum of two Witt vectors can depend on the `0`-th through `n`th values of the summands. This effectively simulates a “carrying” operation. ## Main definitions `WittVector p R`: the type of `p`-typical Witt vectors with coefficients in `R`. * `WittVector.coeff x n`: projects the `n`th value of the Witt vector `x`. ## Notation We use notation `𝕎 R`, entered `\bbW`, for the Witt vectors over `R`. ## References * [Hazewinkel, Witt Vectors][Haze09] * [Commelin and Lewis, Formalizing the Ring of Witt Vectors][CL21] -/ noncomputable section /-- `WittVector p R` is the ring of `p`-typical Witt vectors over the commutative ring `R`, where `p` is a prime number. If `p` is invertible in `R`, this ring is isomorphic to `ℕ → R` (the product of `ℕ` copies of `R`). If `R` is a ring of characteristic `p`, then `WittVector p R` is a ring of characteristic `0`. The canonical example is `WittVector p (ZMod p)`, which is isomorphic to the `p`-adic integers `ℤ_[p]`. -/ structure WittVector (p : ℕ) (R : Type) where mk' :: /-- `x.coeff n` is the `n`th coefficient of the Witt vector `x`. This concept does not have a standard name in the literature. -/ coeff : ℕ → R -- Porting note: added to make the `p` argument explicit /-- Construct a Witt vector `mk p x : 𝕎 R` from a sequence `x` of elements of `R`. -/ def WittVector.mk (p : ℕ) {R : Type} (coeff : ℕ → R) : WittVector p R := mk' coeff variable {p : ℕ} /- We cannot make this `localized` notation, because the `p` on the RHS doesn't occur on the left Hiding the `p` in the notation is very convenient, so we opt for repeating the `local notation` in other files that use Witt vectors. -/ local notation "𝕎" => WittVector p -- type as `\bbW` namespace WittVector variable {R : Type} @[ext] theorem ext {x y : 𝕎 R} (h : ∀ n, x.coeff n = y.coeff n) : x = y := by cases x cases y simp only at h simp [funext_iff, h] variable (p) theorem coeff_mk (x : ℕ → R) : (mk p x).coeff = x := rfl /- These instances are not needed for the rest of the development, but it is interesting to establish early on that `WittVector p` is a lawful functor. -/ instance : Functor (WittVector p) where map f v := mk p (f ∘ v.coeff) mapConst a _ := mk p fun _ => a instance : LawfulFunctor (WittVector p) where map_const := rfl -- Porting note: no longer needs to deconstruct `v` to conclude `{coeff := v.coeff} = v` id_map _ := rfl comp_map _ _ _ := rfl variable [hp : Fact p.Prime] [CommRing R] open MvPolynomial section RingOperations /-- The polynomials used for defining the element `0` of the ring of Witt vectors. -/ def wittZero : ℕ → MvPolynomial (Fin 0 × ℕ) ℤ := wittStructureInt p 0 /-- The polynomials used for defining the element `1` of the ring of Witt vectors. -/ def wittOne : ℕ → MvPolynomial (Fin 0 × ℕ) ℤ := wittStructureInt p 1 /-- The polynomials used for defining the addition of the ring of Witt vectors. -/ def wittAdd : ℕ → MvPolynomial (Fin 2 × ℕ) ℤ := wittStructureInt p (X 0 + X 1) /-- The polynomials used for defining repeated addition of the ring of Witt vectors. -/ def wittNSMul (n : ℕ) : ℕ → MvPolynomial (Fin 1 × ℕ) ℤ := wittStructureInt p (n • X (0 : (Fin 1))) /-- The polynomials used for defining repeated addition of the ring of Witt vectors. -/ def wittZSMul (n : ℤ) : ℕ → MvPolynomial (Fin 1 × ℕ) ℤ := wittStructureInt p (n • X (0 : (Fin 1))) /-- The polynomials used for describing the subtraction of the ring of Witt vectors. -/ def wittSub : ℕ → MvPolynomial (Fin 2 × ℕ) ℤ := wittStructureInt p (X 0 - X 1) /-- The polynomials used for defining the multiplication of the ring of Witt vectors. -/ def wittMul : ℕ → MvPolynomial (Fin 2 × ℕ) ℤ := wittStructureInt p (X 0 X 1) /-- The polynomials used for defining the negation of the ring of Witt vectors. -/ def wittNeg : ℕ → MvPolynomial (Fin 1 × ℕ) ℤ := wittStructureInt p (-X 0) /-- The polynomials used for defining repeated addition of the ring of Witt vectors. -/ def wittPow (n : ℕ) : ℕ → MvPolynomial (Fin 1 × ℕ) ℤ := wittStructureInt p (X 0 ^ n) variable {p} /-- An auxiliary definition used in `WittVector.eval`. Evaluates a polynomial whose variables come from the disjoint union of `k` copies of `ℕ`, with a curried evaluation `x`. This can be defined more generally but we use only a specific instance here. -/ def peval {k : ℕ} (φ : MvPolynomial (Fin k × ℕ) ℤ) (x : Fin k → ℕ → R) : R := aeval (Function.uncurry x) φ /-- Let `φ` be a family of polynomials, indexed by natural numbers, whose variables come from the disjoint union of `k` copies of `ℕ`, and let `xᵢ` be a Witt vector for `0 ≤ i < k`. `eval φ x` evaluates `φ` mapping the variable `X_(i, n)` to the `n`th coefficient of `xᵢ`. Instantiating `φ` with certain polynomials defined in `Mathlib/RingTheory/WittVector/StructurePolynomial.lean` establishes the ring operations on `𝕎 R`. For example, `WittVector.wittAdd` is such a `φ` with `k = 2`; evaluating this at `(x₀, x₁)` gives us the sum of two Witt vectors `x₀ + x₁`. -/ def eval {k : ℕ} (φ : ℕ → MvPolynomial (Fin k × ℕ) ℤ) (x : Fin k → 𝕎 R) : 𝕎 R := mk p fun n => peval (φ n) fun i => (x i).coeff instance : Zero (𝕎 R) := ⟨eval (wittZero p) ![]⟩ instance : Inhabited (𝕎 R) := ⟨0⟩ instance : One (𝕎 R) := ⟨eval (wittOne p) ![]⟩ instance : Add (𝕎 R) := ⟨fun x y => eval (wittAdd p) ![x, y]⟩ instance : Sub (𝕎 R) := ⟨fun x y => eval (wittSub p) ![x, y]⟩ instance hasNatScalar : SMul ℕ (𝕎 R) := ⟨fun n x => eval (wittNSMul p n) ![x]⟩ instance hasIntScalar : SMul ℤ (𝕎 R) := ⟨fun n x => eval (wittZSMul p n) ![x]⟩ instance : Mul (𝕎 R) := ⟨fun x y => eval (wittMul p) ![x, y]⟩ instance : Neg (𝕎 R) := ⟨fun x => eval (wittNeg p) ![x]⟩ instance hasNatPow : Pow (𝕎 R) ℕ := ⟨fun x n => eval (wittPow p n) ![x]⟩ instance : NatCast (𝕎 R) := ⟨Nat.unaryCast⟩ instance : IntCast (𝕎 R) := ⟨Int.castDef⟩ end RingOperations section WittStructureSimplifications @[simp] theorem wittZero_eq_zero (n : ℕ) : wittZero p n = 0 := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [wittZero, wittStructureRat, bind₁, aeval_zero', constantCoeff_xInTermsOfW, map_zero, map_wittStructureInt] @[simp] theorem wittOne_zero_eq_one : wittOne p 0 = 1 := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [wittOne, wittStructureRat, xInTermsOfW_zero, map_one, bind₁_X_right, map_wittStructureInt] @[simp] theorem wittOne_pos_eq_zero (n : ℕ) (hn : 0 < n) : wittOne p n = 0 := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [wittOne, wittStructureRat, RingHom.map_zero, map_one, RingHom.map_one, map_wittStructureInt] induction n using Nat.strong_induction_on with \| h n IH => ?_ rw [xInTermsOfW_eq] simp only [map_mul, map_sub, map_sum, map_pow, bind₁_X_right, bind₁_C_right] rw [sub_mul, one_mul] rw [Finset.sum_eq_single 0] · simp only [invOf_eq_inv, one_mul, inv_pow, tsub_zero, RingHom.map_one, pow_zero] simp only [one_pow, one_mul, xInTermsOfW_zero, sub_self, bind₁_X_right] · intro i hin hi0 rw [Finset.mem_range] at hin rw [IH _ hin (Nat.pos_of_ne_zero hi0), zero_pow (pow_ne_zero _ hp.1.ne_zero), mul_zero] · rw [Finset.mem_range]; intro; contradiction @[simp] theorem wittAdd_zero : wittAdd p 0 = X (0, 0) + X (1, 0) := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [wittAdd, wittStructureRat, map_add, rename_X, xInTermsOfW_zero, map_X, wittPolynomial_zero, bind₁_X_right, map_wittStructureInt] @[simp] theorem wittSub_zero : wittSub p 0 = X (0, 0) - X (1, 0) := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [wittSub, wittStructureRat, map_sub, rename_X, xInTermsOfW_zero, map_X, wittPolynomial_zero, bind₁_X_right, map_wittStructureInt] @[simp] theorem wittMul_zero : wittMul p 0 = X (0, 0) * X (1, 0) := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [wittMul, wittStructureRat, rename_X, xInTermsOfW_zero, map_X, wittPolynomial_zero, map_mul, bind₁_X_right, map_wittStructureInt] @[simp] theorem wittNeg_zero : wittNeg p 0 = -X (0, 0) := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [wittNeg, wittStructureRat, rename_X, xInTermsOfW_zero, map_X, wittPolynomial_zero, map_neg, bind₁_X_right, map_wittStructureInt] @[simp] theorem constantCoeff_wittAdd (n : ℕ) : constantCoeff (wittAdd p n) = 0 := by apply constantCoeff_wittStructureInt p _ _ n simp only [add_zero, RingHom.map_add, constantCoeff_X] @[simp] theorem constantCoeff_wittSub (n : ℕ) : constantCoeff (wittSub p n) = 0 := by apply constantCoeff_wittStructureInt p _ _ n simp only [sub_zero, RingHom.map_sub, constantCoeff_X] @[simp] theorem constantCoeff_wittMul (n : ℕ) : constantCoeff (wittMul p n) = 0 := by apply constantCoeff_wittStructureInt p _ _ n simp only [mul_zero, RingHom.map_mul, constantCoeff_X] @[simp] theorem constantCoeff_wittNeg (n : ℕ) : constantCoeff (wittNeg p n) = 0 := by apply constantCoeff_wittStructureInt p _ _ n simp only [neg_zero, RingHom.map_neg, constantCoeff_X] @[simp] theorem constantCoeff_wittNSMul (m : ℕ) (n : ℕ) : constantCoeff (wittNSMul p m n) = 0 := by apply constantCoeff_wittStructureInt p _ _ n simp only [smul_zero, map_nsmul, constantCoeff_X] @[simp] theorem constantCoeff_wittZSMul (z : ℤ) (n : ℕ) : constantCoeff (wittZSMul p z n) = 0 := by apply constantCoeff_wittStructureInt p _ _ n simp only [smul_zero, map_zsmul, constantCoeff_X] end WittStructureSimplifications section Coeff variable (R) @[simp] theorem zero_coeff (n : ℕ) : (0 : 𝕎 R).coeff n = 0 := show (aeval _ (wittZero p n) : R) = 0 by simp only [wittZero_eq_zero, map_zero] @[simp] theorem one_coeff_zero : (1 : 𝕎 R).coeff 0 = 1 := show (aeval _ (wittOne p 0) : R) = 1 by simp only [wittOne_zero_eq_one, map_one] @[simp] theorem one_coeff_eq_of_pos (n : ℕ) (hn : 0 < n) : coeff (1 : 𝕎 R) n = 0 := show (aeval _ (wittOne p n) : R) = 0 by simp only [hn, wittOne_pos_eq_zero, map_zero] variable {p R} @[simp] theorem v2_coeff {p' R'} (x y : WittVector p' R') (i : Fin 2) : (![x, y] i).coeff = ![x.coeff, y.coeff] i := by fin_cases i <;> simp -- Porting note: the lemmas below needed `coeff_mk` added to the `simp` calls theorem add_coeff (x y : 𝕎 R) (n : ℕ) : (x + y).coeff n = peval (wittAdd p n) ![x.coeff, y.coeff] := by simp [(· + ·), Add.add, eval, coeff_mk] theorem sub_coeff (x y : 𝕎 R) (n : ℕ) : (x - y).coeff n = peval (wittSub p n) ![x.coeff, y.coeff] := by simp [(· - ·), Sub.sub, eval, coeff_mk] theorem mul_coeff (x y : 𝕎 R) (n : ℕ) : (x * y).coeff n = peval (wittMul p n) ![x.coeff, y.coeff] := by simp [(· * ·), Mul.mul, eval, coeff_mk] theorem neg_coeff (x : 𝕎 R) (n : ℕ) : (-x).coeff n = peval (wittNeg p n) ![x.coeff] := by simp [Neg.neg, eval, Matrix.cons_fin_one, coeff_mk] theorem nsmul_coeff (m : ℕ) (x : 𝕎 R) (n : ℕ) : (m • x).coeff n = peval (wittNSMul p m n) ![x.coeff] := by simp [(· • ·), SMul.smul, eval, Matrix.cons_fin_one, coeff_mk] theorem zsmul_coeff (m : ℤ) (x : 𝕎 R) (n : ℕ) : (m • x).coeff n = peval (wittZSMul p m n) ![x.coeff] := by simp [(· • ·), SMul.smul, eval, Matrix.cons_fin_one, coeff_mk] theorem pow_coeff (m : ℕ) (x : 𝕎 R) (n : ℕ) :	(x ^ m).coeff n = peval (wittPow p m n) ![x.coeff] := by simp [(· ^ ·), Pow.pow, eval, Matrix.cons_fin_one, coeff_mk]	Mathlib/RingTheory/WittVector/Defs.lean	333	334
/- Copyright (c) 2020 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers, Manuel Candales -/ import Mathlib.Analysis.InnerProductSpace.Subspace import Mathlib.Analysis.SpecialFunctions.Trigonometric.Inverse /-! # Angles between vectors This file defines unoriented angles in real inner product spaces. ## Main definitions * `InnerProductGeometry.angle` is the undirected angle between two vectors. ## TODO Prove the triangle inequality for the angle. -/ assert_not_exists HasFDerivAt ConformalAt noncomputable section open Real Set open Real open RealInnerProductSpace namespace InnerProductGeometry variable {V : Type} [NormedAddCommGroup V] [InnerProductSpace ℝ V] {x y : V} /-- The undirected angle between two vectors. If either vector is 0, this is π/2. See `Orientation.oangle` for the corresponding oriented angle definition. -/ def angle (x y : V) : ℝ := Real.arccos (⟪x, y⟫ / (‖x‖ ‖y‖)) theorem continuousAt_angle {x : V × V} (hx1 : x.1 ≠ 0) (hx2 : x.2 ≠ 0) : ContinuousAt (fun y : V × V => angle y.1 y.2) x := by unfold angle fun_prop (disch := simp []) theorem angle_smul_smul {c : ℝ} (hc : c ≠ 0) (x y : V) : angle (c • x) (c • y) = angle x y := by have : c c ≠ 0 := mul_ne_zero hc hc rw [angle, angle, real_inner_smul_left, inner_smul_right, norm_smul, norm_smul, Real.norm_eq_abs, mul_mul_mul_comm _ ‖x‖, abs_mul_abs_self, ← mul_assoc c c, mul_div_mul_left _ _ this] @[simp] theorem _root_.LinearIsometry.angle_map {E F : Type} [NormedAddCommGroup E] [NormedAddCommGroup F] [InnerProductSpace ℝ E] [InnerProductSpace ℝ F] (f : E →ₗᵢ[ℝ] F) (u v : E) : angle (f u) (f v) = angle u v := by rw [angle, angle, f.inner_map_map, f.norm_map, f.norm_map] @[simp, norm_cast] theorem _root_.Submodule.angle_coe {s : Submodule ℝ V} (x y : s) : angle (x : V) (y : V) = angle x y := s.subtypeₗᵢ.angle_map x y /-- The cosine of the angle between two vectors. -/ theorem cos_angle (x y : V) : Real.cos (angle x y) = ⟪x, y⟫ / (‖x‖ ‖y‖) := Real.cos_arccos (abs_le.mp (abs_real_inner_div_norm_mul_norm_le_one x y)).1 (abs_le.mp (abs_real_inner_div_norm_mul_norm_le_one x y)).2 /-- The angle between two vectors does not depend on their order. -/ theorem angle_comm (x y : V) : angle x y = angle y x := by unfold angle rw [real_inner_comm, mul_comm] /-- The angle between the negation of two vectors. -/ @[simp] theorem angle_neg_neg (x y : V) : angle (-x) (-y) = angle x y := by unfold angle rw [inner_neg_neg, norm_neg, norm_neg] /-- The angle between two vectors is nonnegative. -/ theorem angle_nonneg (x y : V) : 0 ≤ angle x y := Real.arccos_nonneg _ /-- The angle between two vectors is at most π. -/ theorem angle_le_pi (x y : V) : angle x y ≤ π := Real.arccos_le_pi _ /-- The sine of the angle between two vectors is nonnegative. -/ theorem sin_angle_nonneg (x y : V) : 0 ≤ sin (angle x y) := sin_nonneg_of_nonneg_of_le_pi (angle_nonneg x y) (angle_le_pi x y) /-- The angle between a vector and the negation of another vector. -/ theorem angle_neg_right (x y : V) : angle x (-y) = π - angle x y := by unfold angle rw [← Real.arccos_neg, norm_neg, inner_neg_right, neg_div] /-- The angle between the negation of a vector and another vector. -/ theorem angle_neg_left (x y : V) : angle (-x) y = π - angle x y := by rw [← angle_neg_neg, neg_neg, angle_neg_right] proof_wanted angle_triangle (x y z : V) : angle x z ≤ angle x y + angle y z /-- The angle between the zero vector and a vector. -/ @[simp] theorem angle_zero_left (x : V) : angle 0 x = π / 2 := by unfold angle rw [inner_zero_left, zero_div, Real.arccos_zero] /-- The angle between a vector and the zero vector. -/ @[simp] theorem angle_zero_right (x : V) : angle x 0 = π / 2 := by unfold angle rw [inner_zero_right, zero_div, Real.arccos_zero] /-- The angle between a nonzero vector and itself. -/ @[simp] theorem angle_self {x : V} (hx : x ≠ 0) : angle x x = 0 := by unfold angle rw [← real_inner_self_eq_norm_mul_norm, div_self (inner_self_ne_zero.2 hx : ⟪x, x⟫ ≠ 0), Real.arccos_one] /-- The angle between a nonzero vector and its negation. -/ @[simp] theorem angle_self_neg_of_nonzero {x : V} (hx : x ≠ 0) : angle x (-x) = π := by rw [angle_neg_right, angle_self hx, sub_zero] /-- The angle between the negation of a nonzero vector and that vector. -/ @[simp] theorem angle_neg_self_of_nonzero {x : V} (hx : x ≠ 0) : angle (-x) x = π := by rw [angle_comm, angle_self_neg_of_nonzero hx] /-- The angle between a vector and a positive multiple of a vector. -/ @[simp] theorem angle_smul_right_of_pos (x y : V) {r : ℝ} (hr : 0 < r) : angle x (r • y) = angle x y := by unfold angle rw [inner_smul_right, norm_smul, Real.norm_eq_abs, abs_of_nonneg (le_of_lt hr), ← mul_assoc, mul_comm _ r, mul_assoc, mul_div_mul_left _ _ (ne_of_gt hr)] /-- The angle between a positive multiple of a vector and a vector. -/ @[simp] theorem angle_smul_left_of_pos (x y : V) {r : ℝ} (hr : 0 < r) : angle (r • x) y = angle x y := by rw [angle_comm, angle_smul_right_of_pos y x hr, angle_comm] /-- The angle between a vector and a negative multiple of a vector. -/ @[simp] theorem angle_smul_right_of_neg (x y : V) {r : ℝ} (hr : r < 0) : angle x (r • y) = angle x (-y) := by rw [← neg_neg r, neg_smul, angle_neg_right, angle_smul_right_of_pos x y (neg_pos_of_neg hr), angle_neg_right] /-- The angle between a negative multiple of a vector and a vector. -/ @[simp] theorem angle_smul_left_of_neg (x y : V) {r : ℝ} (hr : r < 0) : angle (r • x) y = angle (-x) y := by rw [angle_comm, angle_smul_right_of_neg y x hr, angle_comm] /-- The cosine of the angle between two vectors, multiplied by the product of their norms. -/ theorem cos_angle_mul_norm_mul_norm (x y : V) : Real.cos (angle x y) * (‖x‖ * ‖y‖) = ⟪x, y⟫ := by rw [cos_angle, div_mul_cancel_of_imp] simp +contextual [or_imp] /-- The sine of the angle between two vectors, multiplied by the product of their norms. -/ theorem sin_angle_mul_norm_mul_norm (x y : V) : Real.sin (angle x y) * (‖x‖ * ‖y‖) = √(⟪x, x⟫ * ⟪y, y⟫ - ⟪x, y⟫ * ⟪x, y⟫) := by unfold angle rw [Real.sin_arccos, ← Real.sqrt_mul_self (mul_nonneg (norm_nonneg x) (norm_nonneg y)), ← Real.sqrt_mul' _ (mul_self_nonneg _), sq, Real.sqrt_mul_self (mul_nonneg (norm_nonneg x) (norm_nonneg y)), real_inner_self_eq_norm_mul_norm, real_inner_self_eq_norm_mul_norm] by_cases h : ‖x‖ * ‖y‖ = 0 · rw [show ‖x‖ * ‖x‖ * (‖y‖ * ‖y‖) = ‖x‖ * ‖y‖ * (‖x‖ * ‖y‖) by ring, h, mul_zero, mul_zero, zero_sub] rcases eq_zero_or_eq_zero_of_mul_eq_zero h with hx \| hy · rw [norm_eq_zero] at hx rw [hx, inner_zero_left, zero_mul, neg_zero] · rw [norm_eq_zero] at hy rw [hy, inner_zero_right, zero_mul, neg_zero] · -- takes 600ms; squeezing the "equivalent" simp call yields an invalid result field_simp [h] ring_nf /-- The angle between two vectors is zero if and only if they are nonzero and one is a positive multiple of the other. -/ theorem angle_eq_zero_iff {x y : V} : angle x y = 0 ↔ x ≠ 0 ∧ ∃ r : ℝ, 0 < r ∧ y = r • x := by rw [angle, ← real_inner_div_norm_mul_norm_eq_one_iff, Real.arccos_eq_zero, LE.le.le_iff_eq, eq_comm] exact (abs_le.mp (abs_real_inner_div_norm_mul_norm_le_one x y)).2 /-- The angle between two vectors is π if and only if they are nonzero and one is a negative multiple of the other. -/ theorem angle_eq_pi_iff {x y : V} : angle x y = π ↔ x ≠ 0 ∧ ∃ r : ℝ, r < 0 ∧ y = r • x := by rw [angle, ← real_inner_div_norm_mul_norm_eq_neg_one_iff, Real.arccos_eq_pi, LE.le.le_iff_eq] exact (abs_le.mp (abs_real_inner_div_norm_mul_norm_le_one x y)).1 /-- If the angle between two vectors is π, the angles between those vectors and a third vector add to π. -/ theorem angle_add_angle_eq_pi_of_angle_eq_pi {x y : V} (z : V) (h : angle x y = π) : angle x z + angle y z = π := by rcases angle_eq_pi_iff.1 h with ⟨_, ⟨r, ⟨hr, rfl⟩⟩⟩ rw [angle_smul_left_of_neg x z hr, angle_neg_left, add_sub_cancel] /-- Two vectors have inner product 0 if and only if the angle between them is π/2. -/ theorem inner_eq_zero_iff_angle_eq_pi_div_two (x y : V) : ⟪x, y⟫ = 0 ↔ angle x y = π / 2 := Iff.symm <\| by simp +contextual [angle, or_imp] /-- If the angle between two vectors is π, the inner product equals the negative product of the norms. -/ theorem inner_eq_neg_mul_norm_of_angle_eq_pi {x y : V} (h : angle x y = π) : ⟪x, y⟫ = -(‖x‖ * ‖y‖) := by simp [← cos_angle_mul_norm_mul_norm, h] /-- If the angle between two vectors is 0, the inner product equals the product of the norms. -/ theorem inner_eq_mul_norm_of_angle_eq_zero {x y : V} (h : angle x y = 0) : ⟪x, y⟫ = ‖x‖ * ‖y‖ := by simp [← cos_angle_mul_norm_mul_norm, h] /-- The inner product of two non-zero vectors equals the negative product of their norms if and only if the angle between the two vectors is π. -/ theorem inner_eq_neg_mul_norm_iff_angle_eq_pi {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) : ⟪x, y⟫ = -(‖x‖ * ‖y‖) ↔ angle x y = π := by refine ⟨fun h => ?_, inner_eq_neg_mul_norm_of_angle_eq_pi⟩ have h₁ : ‖x‖ * ‖y‖ ≠ 0 := (mul_pos (norm_pos_iff.mpr hx) (norm_pos_iff.mpr hy)).ne' rw [angle, h, neg_div, div_self h₁, Real.arccos_neg_one] /-- The inner product of two non-zero vectors equals the product of their norms if and only if the angle between the two vectors is 0. -/ theorem inner_eq_mul_norm_iff_angle_eq_zero {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) : ⟪x, y⟫ = ‖x‖ * ‖y‖ ↔ angle x y = 0 := by refine ⟨fun h => ?_, inner_eq_mul_norm_of_angle_eq_zero⟩ have h₁ : ‖x‖ * ‖y‖ ≠ 0 := (mul_pos (norm_pos_iff.mpr hx) (norm_pos_iff.mpr hy)).ne' rw [angle, h, div_self h₁, Real.arccos_one] /-- If the angle between two vectors is π, the norm of their difference equals the sum of their norms. -/ theorem norm_sub_eq_add_norm_of_angle_eq_pi {x y : V} (h : angle x y = π) : ‖x - y‖ = ‖x‖ + ‖y‖ := by	rw [← sq_eq_sq₀ (norm_nonneg (x - y)) (add_nonneg (norm_nonneg x) (norm_nonneg y)), norm_sub_pow_two_real, inner_eq_neg_mul_norm_of_angle_eq_pi h] ring	Mathlib/Geometry/Euclidean/Angle/Unoriented/Basic.lean	240	242
/- Copyright (c) 2017 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Data.Nat.Find import Mathlib.Data.Stream.Init import Mathlib.Tactic.Common /-! # Coinductive formalization of unbounded computations. This file provides a `Computation` type where `Computation α` is the type of unbounded computations returning `α`. -/ open Function universe u v w /- coinductive Computation (α : Type u) : Type u \| pure : α → Computation α \| think : Computation α → Computation α -/ /-- `Computation α` is the type of unbounded computations returning `α`. An element of `Computation α` is an infinite sequence of `Option α` such that if `f n = some a` for some `n` then it is constantly `some a` after that. -/ def Computation (α : Type u) : Type u := { f : Stream' (Option α) // ∀ ⦃n a⦄, f n = some a → f (n + 1) = some a } namespace Computation variable {α : Type u} {β : Type v} {γ : Type w} -- constructors /-- `pure a` is the computation that immediately terminates with result `a`. -/ def pure (a : α) : Computation α := ⟨Stream'.const (some a), fun _ _ => id⟩ instance : CoeTC α (Computation α) := ⟨pure⟩ -- note [use has_coe_t] /-- `think c` is the computation that delays for one "tick" and then performs computation `c`. -/ def think (c : Computation α) : Computation α := ⟨Stream'.cons none c.1, fun n a h => by rcases n with - \| n · contradiction · exact c.2 h⟩ /-- `thinkN c n` is the computation that delays for `n` ticks and then performs computation `c`. -/ def thinkN (c : Computation α) : ℕ → Computation α \| 0 => c \| n + 1 => think (thinkN c n) -- check for immediate result /-- `head c` is the first step of computation, either `some a` if `c = pure a` or `none` if `c = think c'`. -/ def head (c : Computation α) : Option α := c.1.head -- one step of computation /-- `tail c` is the remainder of computation, either `c` if `c = pure a` or `c'` if `c = think c'`. -/ def tail (c : Computation α) : Computation α := ⟨c.1.tail, fun _ _ h => c.2 h⟩ /-- `empty α` is the computation that never returns, an infinite sequence of `think`s. -/ def empty (α) : Computation α := ⟨Stream'.const none, fun _ _ => id⟩ instance : Inhabited (Computation α) := ⟨empty _⟩ /-- `runFor c n` evaluates `c` for `n` steps and returns the result, or `none` if it did not terminate after `n` steps. -/ def runFor : Computation α → ℕ → Option α := Subtype.val /-- `destruct c` is the destructor for `Computation α` as a coinductive type. It returns `inl a` if `c = pure a` and `inr c'` if `c = think c'`. -/ def destruct (c : Computation α) : α ⊕ (Computation α) := match c.1 0 with \| none => Sum.inr (tail c) \| some a => Sum.inl a /-- `run c` is an unsound meta function that runs `c` to completion, possibly resulting in an infinite loop in the VM. -/ unsafe def run : Computation α → α \| c => match destruct c with \| Sum.inl a => a \| Sum.inr ca => run ca theorem destruct_eq_pure {s : Computation α} {a : α} : destruct s = Sum.inl a → s = pure a := by dsimp [destruct] induction' f0 : s.1 0 with _ <;> intro h · contradiction · apply Subtype.eq funext n induction' n with n IH · injection h with h' rwa [h'] at f0 · exact s.2 IH theorem destruct_eq_think {s : Computation α} {s'} : destruct s = Sum.inr s' → s = think s' := by dsimp [destruct] induction' f0 : s.1 0 with a' <;> intro h · injection h with h' rw [← h'] obtain ⟨f, al⟩ := s apply Subtype.eq dsimp [think, tail] rw [← f0] exact (Stream'.eta f).symm · contradiction @[simp] theorem destruct_pure (a : α) : destruct (pure a) = Sum.inl a := rfl @[simp] theorem destruct_think : ∀ s : Computation α, destruct (think s) = Sum.inr s \| ⟨_, _⟩ => rfl @[simp] theorem destruct_empty : destruct (empty α) = Sum.inr (empty α) := rfl @[simp] theorem head_pure (a : α) : head (pure a) = some a := rfl @[simp] theorem head_think (s : Computation α) : head (think s) = none := rfl @[simp] theorem head_empty : head (empty α) = none := rfl @[simp] theorem tail_pure (a : α) : tail (pure a) = pure a := rfl @[simp] theorem tail_think (s : Computation α) : tail (think s) = s := by obtain ⟨f, al⟩ := s; apply Subtype.eq; dsimp [tail, think] @[simp] theorem tail_empty : tail (empty α) = empty α := rfl theorem think_empty : empty α = think (empty α) := destruct_eq_think destruct_empty /-- Recursion principle for computations, compare with `List.recOn`. -/ def recOn {C : Computation α → Sort v} (s : Computation α) (h1 : ∀ a, C (pure a)) (h2 : ∀ s, C (think s)) : C s := match H : destruct s with \| Sum.inl v => by rw [destruct_eq_pure H] apply h1 \| Sum.inr v => match v with \| ⟨a, s'⟩ => by rw [destruct_eq_think H] apply h2 /-- Corecursor constructor for `corec` -/ def Corec.f (f : β → α ⊕ β) : α ⊕ β → Option α × (α ⊕ β) \| Sum.inl a => (some a, Sum.inl a) \| Sum.inr b => (match f b with \| Sum.inl a => some a \| Sum.inr _ => none, f b) /-- `corec f b` is the corecursor for `Computation α` as a coinductive type. If `f b = inl a` then `corec f b = pure a`, and if `f b = inl b'` then `corec f b = think (corec f b')`. -/ def corec (f : β → α ⊕ β) (b : β) : Computation α := by refine ⟨Stream'.corec' (Corec.f f) (Sum.inr b), fun n a' h => ?_⟩ rw [Stream'.corec'_eq] change Stream'.corec' (Corec.f f) (Corec.f f (Sum.inr b)).2 n = some a' revert h; generalize Sum.inr b = o; revert o induction' n with n IH <;> intro o · change (Corec.f f o).1 = some a' → (Corec.f f (Corec.f f o).2).1 = some a' rcases o with _ \| b <;> intro h · exact h unfold Corec.f at *; split <;> simp_all · rw [Stream'.corec'_eq (Corec.f f) (Corec.f f o).2, Stream'.corec'_eq (Corec.f f) o] exact IH (Corec.f f o).2 /-- left map of `⊕` -/ def lmap (f : α → β) : α ⊕ γ → β ⊕ γ \| Sum.inl a => Sum.inl (f a) \| Sum.inr b => Sum.inr b /-- right map of `⊕` -/ def rmap (f : β → γ) : α ⊕ β → α ⊕ γ \| Sum.inl a => Sum.inl a \| Sum.inr b => Sum.inr (f b) attribute [simp] lmap rmap @[simp] theorem corec_eq (f : β → α ⊕ β) (b : β) : destruct (corec f b) = rmap (corec f) (f b) := by dsimp [corec, destruct] rw [show Stream'.corec' (Corec.f f) (Sum.inr b) 0 = Sum.rec Option.some (fun _ ↦ none) (f b) by dsimp [Corec.f, Stream'.corec', Stream'.corec, Stream'.map, Stream'.get, Stream'.iterate] match (f b) with \| Sum.inl x => rfl \| Sum.inr x => rfl ] induction' h : f b with a b'; · rfl dsimp [Corec.f, destruct] apply congr_arg; apply Subtype.eq dsimp [corec, tail] rw [Stream'.corec'_eq, Stream'.tail_cons] dsimp [Corec.f]; rw [h] section Bisim variable (R : Computation α → Computation α → Prop) /-- bisimilarity relation -/ local infixl:50 " ~ " => R /-- Bisimilarity over a sum of `Computation`s -/ def BisimO : α ⊕ (Computation α) → α ⊕ (Computation α) → Prop \| Sum.inl a, Sum.inl a' => a = a' \| Sum.inr s, Sum.inr s' => R s s' \| _, _ => False attribute [simp] BisimO attribute [nolint simpNF] BisimO.eq_3 /-- Attribute expressing bisimilarity over two `Computation`s -/ def IsBisimulation := ∀ ⦃s₁ s₂⦄, s₁ ~ s₂ → BisimO R (destruct s₁) (destruct s₂) -- If two computations are bisimilar, then they are equal theorem eq_of_bisim (bisim : IsBisimulation R) {s₁ s₂} (r : s₁ ~ s₂) : s₁ = s₂ := by apply Subtype.eq apply Stream'.eq_of_bisim fun x y => ∃ s s' : Computation α, s.1 = x ∧ s'.1 = y ∧ R s s' · dsimp [Stream'.IsBisimulation] intro t₁ t₂ e match t₁, t₂, e with \| _, _, ⟨s, s', rfl, rfl, r⟩ => suffices head s = head s' ∧ R (tail s) (tail s') from And.imp id (fun r => ⟨tail s, tail s', by cases s; rfl, by cases s'; rfl, r⟩) this have h := bisim r; revert r h apply recOn s _ _ <;> intro r' <;> apply recOn s' _ _ <;> intro a' r h · constructor <;> dsimp at h · rw [h] · rw [h] at r rw [tail_pure, tail_pure,h] assumption · rw [destruct_pure, destruct_think] at h exact False.elim h · rw [destruct_pure, destruct_think] at h exact False.elim h · simp_all · exact ⟨s₁, s₂, rfl, rfl, r⟩ end Bisim -- It's more of a stretch to use ∈ for this relation, but it -- asserts that the computation limits to the given value. /-- Assertion that a `Computation` limits to a given value -/ protected def Mem (s : Computation α) (a : α) := some a ∈ s.1 instance : Membership α (Computation α) := ⟨Computation.Mem⟩ theorem le_stable (s : Computation α) {a m n} (h : m ≤ n) : s.1 m = some a → s.1 n = some a := by obtain ⟨f, al⟩ := s induction' h with n _ IH exacts [id, fun h2 => al (IH h2)] theorem mem_unique {s : Computation α} {a b : α} : a ∈ s → b ∈ s → a = b \| ⟨m, ha⟩, ⟨n, hb⟩ => by injection (le_stable s (le_max_left m n) ha.symm).symm.trans (le_stable s (le_max_right m n) hb.symm) theorem Mem.left_unique : Relator.LeftUnique ((· ∈ ·) : α → Computation α → Prop) := fun _ _ _ => mem_unique /-- `Terminates s` asserts that the computation `s` eventually terminates with some value. -/ class Terminates (s : Computation α) : Prop where /-- assertion that there is some term `a` such that the `Computation` terminates -/ term : ∃ a, a ∈ s theorem terminates_iff (s : Computation α) : Terminates s ↔ ∃ a, a ∈ s := ⟨fun h => h.1, Terminates.mk⟩ theorem terminates_of_mem {s : Computation α} {a : α} (h : a ∈ s) : Terminates s := ⟨⟨a, h⟩⟩ theorem terminates_def (s : Computation α) : Terminates s ↔ ∃ n, (s.1 n).isSome := ⟨fun ⟨⟨a, n, h⟩⟩ => ⟨n, by dsimp [Stream'.get] at h rw [← h] exact rfl⟩, fun ⟨n, h⟩ => ⟨⟨Option.get _ h, n, (Option.eq_some_of_isSome h).symm⟩⟩⟩ theorem ret_mem (a : α) : a ∈ pure a := Exists.intro 0 rfl theorem eq_of_pure_mem {a a' : α} (h : a' ∈ pure a) : a' = a := mem_unique h (ret_mem _) @[simp] theorem mem_pure_iff (a b : α) : a ∈ pure b ↔ a = b := ⟨eq_of_pure_mem, fun h => h ▸ ret_mem _⟩ instance ret_terminates (a : α) : Terminates (pure a) := terminates_of_mem (ret_mem _) theorem think_mem {s : Computation α} {a} : a ∈ s → a ∈ think s \| ⟨n, h⟩ => ⟨n + 1, h⟩ instance think_terminates (s : Computation α) : ∀ [Terminates s], Terminates (think s) \| ⟨⟨a, n, h⟩⟩ => ⟨⟨a, n + 1, h⟩⟩ theorem of_think_mem {s : Computation α} {a} : a ∈ think s → a ∈ s \| ⟨n, h⟩ => by rcases n with - \| n' · contradiction · exact ⟨n', h⟩ theorem of_think_terminates {s : Computation α} : Terminates (think s) → Terminates s \| ⟨⟨a, h⟩⟩ => ⟨⟨a, of_think_mem h⟩⟩ theorem not_mem_empty (a : α) : a ∉ empty α := fun ⟨n, h⟩ => by contradiction theorem not_terminates_empty : ¬Terminates (empty α) := fun ⟨⟨a, h⟩⟩ => not_mem_empty a h theorem eq_empty_of_not_terminates {s} (H : ¬Terminates s) : s = empty α := by apply Subtype.eq; funext n induction' h : s.val n with _; · rfl refine absurd ?_ H; exact ⟨⟨_, _, h.symm⟩⟩ theorem thinkN_mem {s : Computation α} {a} : ∀ n, a ∈ thinkN s n ↔ a ∈ s \| 0 => Iff.rfl \| n + 1 => Iff.trans ⟨of_think_mem, think_mem⟩ (thinkN_mem n) instance thinkN_terminates (s : Computation α) : ∀ [Terminates s] (n), Terminates (thinkN s n) \| ⟨⟨a, h⟩⟩, n => ⟨⟨a, (thinkN_mem n).2 h⟩⟩ theorem of_thinkN_terminates (s : Computation α) (n) : Terminates (thinkN s n) → Terminates s \| ⟨⟨a, h⟩⟩ => ⟨⟨a, (thinkN_mem _).1 h⟩⟩ /-- `Promises s a`, or `s ~> a`, asserts that although the computation `s` may not terminate, if it does, then the result is `a`. -/ def Promises (s : Computation α) (a : α) : Prop := ∀ ⦃a'⦄, a' ∈ s → a = a' /-- `Promises s a`, or `s ~> a`, asserts that although the computation `s` may not terminate, if it does, then the result is `a`. -/ scoped infixl:50 " ~> " => Promises theorem mem_promises {s : Computation α} {a : α} : a ∈ s → s ~> a := fun h _ => mem_unique h theorem empty_promises (a : α) : empty α ~> a := fun _ h => absurd h (not_mem_empty _) section get variable (s : Computation α) [h : Terminates s] /-- `length s` gets the number of steps of a terminating computation -/ def length : ℕ := Nat.find ((terminates_def _).1 h) /-- `get s` returns the result of a terminating computation -/ def get : α := Option.get _ (Nat.find_spec <\| (terminates_def _).1 h) theorem get_mem : get s ∈ s := Exists.intro (length s) (Option.eq_some_of_isSome _).symm theorem get_eq_of_mem {a} : a ∈ s → get s = a := mem_unique (get_mem _) theorem mem_of_get_eq {a} : get s = a → a ∈ s := by intro h; rw [← h]; apply get_mem @[simp] theorem get_think : get (think s) = get s := get_eq_of_mem _ <\| let ⟨n, h⟩ := get_mem s ⟨n + 1, h⟩ @[simp] theorem get_thinkN (n) : get (thinkN s n) = get s := get_eq_of_mem _ <\| (thinkN_mem _).2 (get_mem _) theorem get_promises : s ~> get s := fun _ => get_eq_of_mem _ theorem mem_of_promises {a} (p : s ~> a) : a ∈ s := by obtain ⟨h⟩ := h obtain ⟨a', h⟩ := h rw [p h] exact h theorem get_eq_of_promises {a} : s ~> a → get s = a := get_eq_of_mem _ ∘ mem_of_promises _ end get /-- `Results s a n` completely characterizes a terminating computation: it asserts that `s` terminates after exactly `n` steps, with result `a`. -/ def Results (s : Computation α) (a : α) (n : ℕ) := ∃ h : a ∈ s, @length _ s (terminates_of_mem h) = n theorem results_of_terminates (s : Computation α) [_T : Terminates s] : Results s (get s) (length s) := ⟨get_mem _, rfl⟩ theorem results_of_terminates' (s : Computation α) [T : Terminates s] {a} (h : a ∈ s) : Results s a (length s) := by rw [← get_eq_of_mem _ h]; apply results_of_terminates theorem Results.mem {s : Computation α} {a n} : Results s a n → a ∈ s \| ⟨m, _⟩ => m theorem Results.terminates {s : Computation α} {a n} (h : Results s a n) : Terminates s := terminates_of_mem h.mem theorem Results.length {s : Computation α} {a n} [_T : Terminates s] : Results s a n → length s = n \| ⟨_, h⟩ => h theorem Results.val_unique {s : Computation α} {a b m n} (h1 : Results s a m) (h2 : Results s b n) : a = b := mem_unique h1.mem h2.mem theorem Results.len_unique {s : Computation α} {a b m n} (h1 : Results s a m) (h2 : Results s b n) : m = n := by haveI := h1.terminates; haveI := h2.terminates; rw [← h1.length, h2.length] theorem exists_results_of_mem {s : Computation α} {a} (h : a ∈ s) : ∃ n, Results s a n := haveI := terminates_of_mem h ⟨_, results_of_terminates' s h⟩ @[simp] theorem get_pure (a : α) : get (pure a) = a := get_eq_of_mem _ ⟨0, rfl⟩ @[simp] theorem length_pure (a : α) : length (pure a) = 0 := let h := Computation.ret_terminates a Nat.eq_zero_of_le_zero <\| Nat.find_min' ((terminates_def (pure a)).1 h) rfl theorem results_pure (a : α) : Results (pure a) a 0 := ⟨ret_mem a, length_pure _⟩ @[simp] theorem length_think (s : Computation α) [h : Terminates s] : length (think s) = length s + 1 := by apply le_antisymm · exact Nat.find_min' _ (Nat.find_spec ((terminates_def _).1 h)) · have : (Option.isSome ((think s).val (length (think s))) : Prop) := Nat.find_spec ((terminates_def _).1 s.think_terminates) revert this; rcases length (think s) with - \| n <;> intro this · simp [think, Stream'.cons] at this · apply Nat.succ_le_succ apply Nat.find_min' apply this theorem results_think {s : Computation α} {a n} (h : Results s a n) : Results (think s) a (n + 1) := haveI := h.terminates ⟨think_mem h.mem, by rw [length_think, h.length]⟩ theorem of_results_think {s : Computation α} {a n} (h : Results (think s) a n) : ∃ m, Results s a m ∧ n = m + 1 := by haveI := of_think_terminates h.terminates have := results_of_terminates' _ (of_think_mem h.mem) exact ⟨_, this, Results.len_unique h (results_think this)⟩ @[simp] theorem results_think_iff {s : Computation α} {a n} : Results (think s) a (n + 1) ↔ Results s a n := ⟨fun h => by let ⟨n', r, e⟩ := of_results_think h injection e with h'; rwa [h'], results_think⟩ theorem results_thinkN {s : Computation α} {a m} : ∀ n, Results s a m → Results (thinkN s n) a (m + n) \| 0, h => h \| n + 1, h => results_think (results_thinkN n h) theorem results_thinkN_pure (a : α) (n) : Results (thinkN (pure a) n) a n := by have := results_thinkN n (results_pure a); rwa [Nat.zero_add] at this @[simp] theorem length_thinkN (s : Computation α) [_h : Terminates s] (n) : length (thinkN s n) = length s + n := (results_thinkN n (results_of_terminates _)).length theorem eq_thinkN {s : Computation α} {a n} (h : Results s a n) : s = thinkN (pure a) n := by revert s induction n with \| zero => _ \| succ n IH => _ <;> (intro s; apply recOn s (fun a' => _) fun s => _) <;> intro a h · rw [← eq_of_pure_mem h.mem] rfl · obtain ⟨n, h⟩ := of_results_think h cases h contradiction · have := h.len_unique (results_pure _) contradiction · rw [IH (results_think_iff.1 h)] rfl theorem eq_thinkN' (s : Computation α) [_h : Terminates s] : s = thinkN (pure (get s)) (length s) := eq_thinkN (results_of_terminates _) /-- Recursor based on membership -/ def memRecOn {C : Computation α → Sort v} {a s} (M : a ∈ s) (h1 : C (pure a)) (h2 : ∀ s, C s → C (think s)) : C s := by haveI T := terminates_of_mem M rw [eq_thinkN' s, get_eq_of_mem s M] generalize length s = n induction' n with n IH; exacts [h1, h2 _ IH] /-- Recursor based on assertion of `Terminates` -/ def terminatesRecOn {C : Computation α → Sort v} (s) [Terminates s] (h1 : ∀ a, C (pure a)) (h2 : ∀ s, C s → C (think s)) : C s := memRecOn (get_mem s) (h1 _) h2 /-- Map a function on the result of a computation. -/ def map (f : α → β) : Computation α → Computation β \| ⟨s, al⟩ => ⟨s.map fun o => Option.casesOn o none (some ∘ f), fun n b => by dsimp [Stream'.map, Stream'.get] induction' e : s n with a <;> intro h · contradiction · rw [al e]; exact h⟩ /-- bind over a `Sum` of `Computation` -/ def Bind.g : β ⊕ Computation β → β ⊕ (Computation α ⊕ Computation β) \| Sum.inl b => Sum.inl b \| Sum.inr cb' => Sum.inr <\| Sum.inr cb' /-- bind over a function mapping `α` to a `Computation` -/ def Bind.f (f : α → Computation β) : Computation α ⊕ Computation β → β ⊕ (Computation α ⊕ Computation β) \| Sum.inl ca => match destruct ca with \| Sum.inl a => Bind.g <\| destruct (f a) \| Sum.inr ca' => Sum.inr <\| Sum.inl ca' \| Sum.inr cb => Bind.g <\| destruct cb /-- Compose two computations into a monadic `bind` operation. -/ def bind (c : Computation α) (f : α → Computation β) : Computation β := corec (Bind.f f) (Sum.inl c) instance : Bind Computation := ⟨@bind⟩ theorem has_bind_eq_bind {β} (c : Computation α) (f : α → Computation β) : c >>= f = bind c f := rfl /-- Flatten a computation of computations into a single computation. -/ def join (c : Computation (Computation α)) : Computation α := c >>= id @[simp] theorem map_pure (f : α → β) (a) : map f (pure a) = pure (f a) := rfl @[simp] theorem map_think (f : α → β) : ∀ s, map f (think s) = think (map f s) \| ⟨s, al⟩ => by apply Subtype.eq; dsimp [think, map]; rw [Stream'.map_cons] @[simp] theorem destruct_map (f : α → β) (s) : destruct (map f s) = lmap f (rmap (map f) (destruct s)) := by apply s.recOn <;> intro <;> simp @[simp] theorem map_id : ∀ s : Computation α, map id s = s \| ⟨f, al⟩ => by apply Subtype.eq; simp only [map, comp_apply, id_eq] have e : @Option.rec α (fun _ => Option α) none some = id := by ext ⟨⟩ <;> rfl have h : ((fun x : Option α => x) = id) := rfl simp [e, h, Stream'.map_id] theorem map_comp (f : α → β) (g : β → γ) : ∀ s : Computation α, map (g ∘ f) s = map g (map f s) \| ⟨s, al⟩ => by apply Subtype.eq; dsimp [map] apply congr_arg fun f : _ → Option γ => Stream'.map f s ext ⟨⟩ <;> rfl @[simp] theorem ret_bind (a) (f : α → Computation β) : bind (pure a) f = f a := by apply eq_of_bisim fun c₁ c₂ => c₁ = bind (pure a) f ∧ c₂ = f a ∨ c₁ = corec (Bind.f f) (Sum.inr c₂) · intro c₁ c₂ h match c₁, c₂, h with \| _, _, Or.inl ⟨rfl, rfl⟩ => simp only [BisimO, bind, Bind.f, corec_eq, rmap, destruct_pure] rcases destruct (f a) with b \| cb <;> simp [Bind.g] \| _, c, Or.inr rfl => simp only [BisimO, Bind.f, corec_eq, rmap] rcases destruct c with b \| cb <;> simp [Bind.g] · simp @[simp] theorem think_bind (c) (f : α → Computation β) : bind (think c) f = think (bind c f) := destruct_eq_think <\| by simp [bind, Bind.f] @[simp] theorem bind_pure (f : α → β) (s) : bind s (pure ∘ f) = map f s := by apply eq_of_bisim fun c₁ c₂ => c₁ = c₂ ∨ ∃ s, c₁ = bind s (pure ∘ f) ∧ c₂ = map f s · intro c₁ c₂ h match c₁, c₂, h with \| _, c₂, Or.inl (Eq.refl _) => rcases destruct c₂ with b \| cb <;> simp \| _, _, Or.inr ⟨s, rfl, rfl⟩ => apply recOn s <;> intro s · simp · simpa using Or.inr ⟨s, rfl, rfl⟩ · exact Or.inr ⟨s, rfl, rfl⟩ @[simp] theorem bind_pure' (s : Computation α) : bind s pure = s := by simpa using bind_pure id s @[simp] theorem bind_assoc (s : Computation α) (f : α → Computation β) (g : β → Computation γ) : bind (bind s f) g = bind s fun x : α => bind (f x) g := by apply eq_of_bisim fun c₁ c₂ => c₁ = c₂ ∨ ∃ s, c₁ = bind (bind s f) g ∧ c₂ = bind s fun x : α => bind (f x) g · intro c₁ c₂ h match c₁, c₂, h with \| _, c₂, Or.inl (Eq.refl _) => rcases destruct c₂ with b \| cb <;> simp \| _, _, Or.inr ⟨s, rfl, rfl⟩ => apply recOn s <;> intro s · simp only [BisimO, ret_bind]; generalize f s = fs apply recOn fs <;> intro t <;> simp · rcases destruct (g t) with b \| cb <;> simp · simpa [BisimO] using Or.inr ⟨s, rfl, rfl⟩ · exact Or.inr ⟨s, rfl, rfl⟩ theorem results_bind {s : Computation α} {f : α → Computation β} {a b m n} (h1 : Results s a m) (h2 : Results (f a) b n) : Results (bind s f) b (n + m) := by have := h1.mem; revert m apply memRecOn this _ fun s IH => _ · intro _ h1 rw [ret_bind] rw [h1.len_unique (results_pure _)] exact h2 · intro _ h3 _ h1 rw [think_bind] obtain ⟨m', h⟩ := of_results_think h1 obtain ⟨h1, e⟩ := h rw [e] exact results_think (h3 h1) theorem mem_bind {s : Computation α} {f : α → Computation β} {a b} (h1 : a ∈ s) (h2 : b ∈ f a) : b ∈ bind s f := let ⟨_, h1⟩ := exists_results_of_mem h1 let ⟨_, h2⟩ := exists_results_of_mem h2 (results_bind h1 h2).mem instance terminates_bind (s : Computation α) (f : α → Computation β) [Terminates s] [Terminates (f (get s))] : Terminates (bind s f) := terminates_of_mem (mem_bind (get_mem s) (get_mem (f (get s)))) @[simp] theorem get_bind (s : Computation α) (f : α → Computation β) [Terminates s] [Terminates (f (get s))] : get (bind s f) = get (f (get s)) := get_eq_of_mem _ (mem_bind (get_mem s) (get_mem (f (get s)))) @[simp] theorem length_bind (s : Computation α) (f : α → Computation β) [_T1 : Terminates s] [_T2 : Terminates (f (get s))] : length (bind s f) = length (f (get s)) + length s := (results_of_terminates _).len_unique <\| results_bind (results_of_terminates _) (results_of_terminates _) theorem of_results_bind {s : Computation α} {f : α → Computation β} {b k} : Results (bind s f) b k → ∃ a m n, Results s a m ∧ Results (f a) b n ∧ k = n + m := by induction k generalizing s with \| zero => _ \| succ n IH => _ <;> apply recOn s (fun a => _) fun s' => _ <;> intro e h · simp only [ret_bind] at h exact ⟨e, _, _, results_pure _, h, rfl⟩ · have := congr_arg head (eq_thinkN h) contradiction · simp only [ret_bind] at h exact ⟨e, _, n + 1, results_pure _, h, rfl⟩ · simp only [think_bind, results_think_iff] at h let ⟨a, m, n', h1, h2, e'⟩ := IH h rw [e'] exact ⟨a, m.succ, n', results_think h1, h2, rfl⟩ theorem exists_of_mem_bind {s : Computation α} {f : α → Computation β} {b} (h : b ∈ bind s f) : ∃ a ∈ s, b ∈ f a := let ⟨_, h⟩ := exists_results_of_mem h let ⟨a, _, _, h1, h2, _⟩ := of_results_bind h ⟨a, h1.mem, h2.mem⟩ theorem bind_promises {s : Computation α} {f : α → Computation β} {a b} (h1 : s ~> a) (h2 : f a ~> b) : bind s f ~> b := fun b' bB => by rcases exists_of_mem_bind bB with ⟨a', a's, ba'⟩ rw [← h1 a's] at ba'; exact h2 ba' instance monad : Monad Computation where map := @map pure := @pure bind := @bind instance : LawfulMonad Computation := LawfulMonad.mk' (id_map := @map_id) (bind_pure_comp := @bind_pure) (pure_bind := @ret_bind) (bind_assoc := @bind_assoc) theorem has_map_eq_map {β} (f : α → β) (c : Computation α) : f <$> c = map f c := rfl @[simp] theorem pure_def (a) : (return a : Computation α) = pure a := rfl @[simp] theorem map_pure' {α β} : ∀ (f : α → β) (a), f <$> pure a = pure (f a) := map_pure @[simp] theorem map_think' {α β} : ∀ (f : α → β) (s), f <$> think s = think (f <$> s) := map_think theorem mem_map (f : α → β) {a} {s : Computation α} (m : a ∈ s) : f a ∈ map f s := by rw [← bind_pure]; apply mem_bind m; apply ret_mem theorem exists_of_mem_map {f : α → β} {b : β} {s : Computation α} (h : b ∈ map f s) : ∃ a, a ∈ s ∧ f a = b := by rw [← bind_pure] at h let ⟨a, as, fb⟩ := exists_of_mem_bind h exact ⟨a, as, mem_unique (ret_mem _) fb⟩ instance terminates_map (f : α → β) (s : Computation α) [Terminates s] : Terminates (map f s) := by rw [← bind_pure]; exact terminates_of_mem (mem_bind (get_mem s) (get_mem (α := β) (f (get s)))) theorem terminates_map_iff (f : α → β) (s : Computation α) : Terminates (map f s) ↔ Terminates s := ⟨fun ⟨⟨_, h⟩⟩ => let ⟨_, h1, _⟩ := exists_of_mem_map h ⟨⟨_, h1⟩⟩, @Computation.terminates_map _ _ _ _⟩ -- Parallel computation /-- `c₁ <\|> c₂` calculates `c₁` and `c₂` simultaneously, returning the first one that gives a result. -/ def orElse (c₁ : Computation α) (c₂ : Unit → Computation α) : Computation α := @Computation.corec α (Computation α × Computation α) (fun ⟨c₁, c₂⟩ => match destruct c₁ with \| Sum.inl a => Sum.inl a \| Sum.inr c₁' => match destruct c₂ with \| Sum.inl a => Sum.inl a \| Sum.inr c₂' => Sum.inr (c₁', c₂')) (c₁, c₂ ()) instance instAlternativeComputation : Alternative Computation := { Computation.monad with orElse := @orElse failure := @empty } @[simp] theorem ret_orElse (a : α) (c₂ : Computation α) : (pure a <\|> c₂) = pure a := destruct_eq_pure <\| by unfold_projs simp [orElse] @[simp] theorem orElse_pure (c₁ : Computation α) (a : α) : (think c₁ <\|> pure a) = pure a := destruct_eq_pure <\| by unfold_projs simp [orElse] @[simp] theorem orElse_think (c₁ c₂ : Computation α) : (think c₁ <\|> think c₂) = think (c₁ <\|> c₂) := destruct_eq_think <\| by unfold_projs simp [orElse] @[simp] theorem empty_orElse (c) : (empty α <\|> c) = c := by apply eq_of_bisim (fun c₁ c₂ => (empty α <\|> c₂) = c₁) _ rfl intro s' s h; rw [← h] apply recOn s <;> intro s <;> rw [think_empty] <;> simp rw [← think_empty] @[simp] theorem orElse_empty (c : Computation α) : (c <\|> empty α) = c := by apply eq_of_bisim (fun c₁ c₂ => (c₂ <\|> empty α) = c₁) _ rfl intro s' s h; rw [← h] apply recOn s <;> intro s <;> rw [think_empty] <;> simp rw [← think_empty] /-- `c₁ ~ c₂` asserts that `c₁` and `c₂` either both terminate with the same result, or both loop forever. -/ def Equiv (c₁ c₂ : Computation α) : Prop := ∀ a, a ∈ c₁ ↔ a ∈ c₂ /-- equivalence relation for computations -/ scoped infixl:50 " ~ " => Equiv @[refl] theorem Equiv.refl (s : Computation α) : s ~ s := fun _ => Iff.rfl @[symm] theorem Equiv.symm {s t : Computation α} : s ~ t → t ~ s := fun h a => (h a).symm @[trans] theorem Equiv.trans {s t u : Computation α} : s ~ t → t ~ u → s ~ u := fun h1 h2 a => (h1 a).trans (h2 a) theorem Equiv.equivalence : Equivalence (@Equiv α) := ⟨@Equiv.refl _, @Equiv.symm _, @Equiv.trans _⟩ theorem equiv_of_mem {s t : Computation α} {a} (h1 : a ∈ s) (h2 : a ∈ t) : s ~ t := fun a' => ⟨fun ma => by rw [mem_unique ma h1]; exact h2, fun ma => by rw [mem_unique ma h2]; exact h1⟩ theorem terminates_congr {c₁ c₂ : Computation α} (h : c₁ ~ c₂) : Terminates c₁ ↔ Terminates c₂ := by simp only [terminates_iff, exists_congr h] theorem promises_congr {c₁ c₂ : Computation α} (h : c₁ ~ c₂) (a) : c₁ ~> a ↔ c₂ ~> a := forall_congr' fun a' => imp_congr (h a') Iff.rfl theorem get_equiv {c₁ c₂ : Computation α} (h : c₁ ~ c₂) [Terminates c₁] [Terminates c₂] : get c₁ = get c₂ := get_eq_of_mem _ <\| (h _).2 <\| get_mem _ theorem think_equiv (s : Computation α) : think s ~ s := fun _ => ⟨of_think_mem, think_mem⟩ theorem thinkN_equiv (s : Computation α) (n) : thinkN s n ~ s := fun _ => thinkN_mem n theorem bind_congr {s1 s2 : Computation α} {f1 f2 : α → Computation β} (h1 : s1 ~ s2) (h2 : ∀ a, f1 a ~ f2 a) : bind s1 f1 ~ bind s2 f2 := fun b => ⟨fun h => let ⟨a, ha, hb⟩ := exists_of_mem_bind h mem_bind ((h1 a).1 ha) ((h2 a b).1 hb), fun h => let ⟨a, ha, hb⟩ := exists_of_mem_bind h mem_bind ((h1 a).2 ha) ((h2 a b).2 hb)⟩ theorem equiv_pure_of_mem {s : Computation α} {a} (h : a ∈ s) : s ~ pure a := equiv_of_mem h (ret_mem _) /-- `LiftRel R ca cb` is a generalization of `Equiv` to relations other than equality. It asserts that if `ca` terminates with `a`, then `cb` terminates with some `b` such that `R a b`, and if `cb` terminates with `b` then `ca` terminates with some `a` such that `R a b`. -/ def LiftRel (R : α → β → Prop) (ca : Computation α) (cb : Computation β) : Prop := (∀ {a}, a ∈ ca → ∃ b, b ∈ cb ∧ R a b) ∧ ∀ {b}, b ∈ cb → ∃ a, a ∈ ca ∧ R a b theorem LiftRel.swap (R : α → β → Prop) (ca : Computation α) (cb : Computation β) : LiftRel (swap R) cb ca ↔ LiftRel R ca cb := @and_comm _ _ theorem lift_eq_iff_equiv (c₁ c₂ : Computation α) : LiftRel (· = ·) c₁ c₂ ↔ c₁ ~ c₂ := ⟨fun ⟨h1, h2⟩ a => ⟨fun a1 => by let ⟨b, b2, ab⟩ := h1 a1; rwa [ab], fun a2 => by let ⟨b, b1, ab⟩ := h2 a2; rwa [← ab]⟩, fun e => ⟨fun {a} a1 => ⟨a, (e _).1 a1, rfl⟩, fun {a} a2 => ⟨a, (e _).2 a2, rfl⟩⟩⟩ theorem LiftRel.refl (R : α → α → Prop) (H : Reflexive R) : Reflexive (LiftRel R) := fun _ => ⟨fun {a} as => ⟨a, as, H a⟩, fun {b} bs => ⟨b, bs, H b⟩⟩ theorem LiftRel.symm (R : α → α → Prop) (H : Symmetric R) : Symmetric (LiftRel R) := fun _ _ ⟨l, r⟩ => ⟨fun {_} a2 => let ⟨b, b1, ab⟩ := r a2 ⟨b, b1, H ab⟩, fun {_} a1 => let ⟨b, b2, ab⟩ := l a1 ⟨b, b2, H ab⟩⟩ theorem LiftRel.trans (R : α → α → Prop) (H : Transitive R) : Transitive (LiftRel R) := fun _ _ _ ⟨l1, r1⟩ ⟨l2, r2⟩ => ⟨fun {_} a1 => let ⟨_, b2, ab⟩ := l1 a1 let ⟨c, c3, bc⟩ := l2 b2 ⟨c, c3, H ab bc⟩, fun {_} c3 => let ⟨_, b2, bc⟩ := r2 c3 let ⟨a, a1, ab⟩ := r1 b2 ⟨a, a1, H ab bc⟩⟩ theorem LiftRel.equiv (R : α → α → Prop) : Equivalence R → Equivalence (LiftRel R) \| ⟨refl, symm, trans⟩ => ⟨LiftRel.refl R refl, @LiftRel.symm _ R @symm, @LiftRel.trans _ R @trans⟩ theorem LiftRel.imp {R S : α → β → Prop} (H : ∀ {a b}, R a b → S a b) (s t) : LiftRel R s t → LiftRel S s t \| ⟨l, r⟩ => ⟨fun {_} as => let ⟨b, bt, ab⟩ := l as ⟨b, bt, H ab⟩, fun {_} bt => let ⟨a, as, ab⟩ := r bt ⟨a, as, H ab⟩⟩ theorem terminates_of_liftRel {R : α → β → Prop} {s t} : LiftRel R s t → (Terminates s ↔ Terminates t) \| ⟨l, r⟩ => ⟨fun ⟨⟨_, as⟩⟩ => let ⟨b, bt, _⟩ := l as ⟨⟨b, bt⟩⟩, fun ⟨⟨_, bt⟩⟩ => let ⟨a, as, _⟩ := r bt ⟨⟨a, as⟩⟩⟩ theorem rel_of_liftRel {R : α → β → Prop} {ca cb} : LiftRel R ca cb → ∀ {a b}, a ∈ ca → b ∈ cb → R a b \| ⟨l, _⟩, a, b, ma, mb => by let ⟨b', mb', ab'⟩ := l ma rw [mem_unique mb mb']; exact ab' theorem liftRel_of_mem {R : α → β → Prop} {a b ca cb} (ma : a ∈ ca) (mb : b ∈ cb) (ab : R a b) : LiftRel R ca cb := ⟨fun {a'} ma' => by rw [mem_unique ma' ma]; exact ⟨b, mb, ab⟩, fun {b'} mb' => by rw [mem_unique mb' mb]; exact ⟨a, ma, ab⟩⟩ theorem exists_of_liftRel_left {R : α → β → Prop} {ca cb} (H : LiftRel R ca cb) {a} (h : a ∈ ca) : ∃ b, b ∈ cb ∧ R a b := H.left h theorem exists_of_liftRel_right {R : α → β → Prop} {ca cb} (H : LiftRel R ca cb) {b} (h : b ∈ cb) : ∃ a, a ∈ ca ∧ R a b := H.right h theorem liftRel_def {R : α → β → Prop} {ca cb} : LiftRel R ca cb ↔ (Terminates ca ↔ Terminates cb) ∧ ∀ {a b}, a ∈ ca → b ∈ cb → R a b := ⟨fun h => ⟨terminates_of_liftRel h, fun {a b} ma mb => by let ⟨b', mb', ab⟩ := h.left ma rwa [mem_unique mb mb']⟩, fun ⟨l, r⟩ => ⟨fun {_} ma => let ⟨⟨b, mb⟩⟩ := l.1 ⟨⟨_, ma⟩⟩ ⟨b, mb, r ma mb⟩, fun {_} mb => let ⟨⟨a, ma⟩⟩ := l.2 ⟨⟨_, mb⟩⟩ ⟨a, ma, r ma mb⟩⟩⟩ theorem liftRel_bind {δ} (R : α → β → Prop) (S : γ → δ → Prop) {s1 : Computation α} {s2 : Computation β} {f1 : α → Computation γ} {f2 : β → Computation δ} (h1 : LiftRel R s1 s2) (h2 : ∀ {a b}, R a b → LiftRel S (f1 a) (f2 b)) : LiftRel S (bind s1 f1) (bind s2 f2) := let ⟨l1, r1⟩ := h1 ⟨fun {_} cB => let ⟨_, a1, c₁⟩ := exists_of_mem_bind cB let ⟨_, b2, ab⟩ := l1 a1 let ⟨l2, _⟩ := h2 ab let ⟨_, d2, cd⟩ := l2 c₁ ⟨_, mem_bind b2 d2, cd⟩, fun {_} dB => let ⟨_, b1, d1⟩ := exists_of_mem_bind dB let ⟨_, a2, ab⟩ := r1 b1 let ⟨_, r2⟩ := h2 ab let ⟨_, c₂, cd⟩ := r2 d1 ⟨_, mem_bind a2 c₂, cd⟩⟩ @[simp] theorem liftRel_pure_left (R : α → β → Prop) (a : α) (cb : Computation β) : LiftRel R (pure a) cb ↔ ∃ b, b ∈ cb ∧ R a b := ⟨fun ⟨l, _⟩ => l (ret_mem _), fun ⟨b, mb, ab⟩ => ⟨fun {a'} ma' => by rw [eq_of_pure_mem ma']; exact ⟨b, mb, ab⟩, fun {b'} mb' => ⟨_, ret_mem _, by rw [mem_unique mb' mb]; exact ab⟩⟩⟩ @[simp] theorem liftRel_pure_right (R : α → β → Prop) (ca : Computation α) (b : β) : LiftRel R ca (pure b) ↔ ∃ a, a ∈ ca ∧ R a b := by rw [LiftRel.swap, liftRel_pure_left] theorem liftRel_pure (R : α → β → Prop) (a : α) (b : β) : LiftRel R (pure a) (pure b) ↔ R a b := by simp @[simp] theorem liftRel_think_left (R : α → β → Prop) (ca : Computation α) (cb : Computation β) : LiftRel R (think ca) cb ↔ LiftRel R ca cb := and_congr (forall_congr' fun _ => imp_congr ⟨of_think_mem, think_mem⟩ Iff.rfl) (forall_congr' fun _ => imp_congr Iff.rfl <\| exists_congr fun _ => and_congr ⟨of_think_mem, think_mem⟩ Iff.rfl) @[simp] theorem liftRel_think_right (R : α → β → Prop) (ca : Computation α) (cb : Computation β) : LiftRel R ca (think cb) ↔ LiftRel R ca cb := by rw [← LiftRel.swap R, ← LiftRel.swap R]; apply liftRel_think_left theorem liftRel_mem_cases {R : α → β → Prop} {ca cb} (Ha : ∀ a ∈ ca, LiftRel R ca cb) (Hb : ∀ b ∈ cb, LiftRel R ca cb) : LiftRel R ca cb := ⟨fun {_} ma => (Ha _ ma).left ma, fun {_} mb => (Hb _ mb).right mb⟩ theorem liftRel_congr {R : α → β → Prop} {ca ca' : Computation α} {cb cb' : Computation β} (ha : ca ~ ca') (hb : cb ~ cb') : LiftRel R ca cb ↔ LiftRel R ca' cb' := and_congr (forall_congr' fun _ => imp_congr (ha _) <\| exists_congr fun _ => and_congr (hb _) Iff.rfl) (forall_congr' fun _ => imp_congr (hb _) <\| exists_congr fun _ => and_congr (ha _) Iff.rfl) theorem liftRel_map {δ} (R : α → β → Prop) (S : γ → δ → Prop) {s1 : Computation α} {s2 : Computation β} {f1 : α → γ} {f2 : β → δ} (h1 : LiftRel R s1 s2) (h2 : ∀ {a b}, R a b → S (f1 a) (f2 b)) : LiftRel S (map f1 s1) (map f2 s2) := by rw [← bind_pure, ← bind_pure]; apply liftRel_bind _ _ h1; simpa theorem map_congr {s1 s2 : Computation α} {f : α → β} (h1 : s1 ~ s2) : map f s1 ~ map f s2 := by rw [← lift_eq_iff_equiv] exact liftRel_map Eq _ ((lift_eq_iff_equiv _ _).2 h1) fun {a} b => congr_arg _ /-- Alternate definition of `LiftRel` over relations between `Computation`s -/ def LiftRelAux (R : α → β → Prop) (C : Computation α → Computation β → Prop) : α ⊕ (Computation α) → β ⊕ (Computation β) → Prop \| Sum.inl a, Sum.inl b => R a b \| Sum.inl a, Sum.inr cb => ∃ b, b ∈ cb ∧ R a b \| Sum.inr ca, Sum.inl b => ∃ a, a ∈ ca ∧ R a b \| Sum.inr ca, Sum.inr cb => C ca cb variable {R : α → β → Prop} {C : Computation α → Computation β → Prop} @[simp] lemma liftRelAux_inl_inl {a : α} {b : β} : LiftRelAux R C (Sum.inl a) (Sum.inl b) = R a b := rfl @[simp] lemma liftRelAux_inl_inr {a : α} {cb} : LiftRelAux R C (Sum.inl a) (Sum.inr cb) = ∃ b, b ∈ cb ∧ R a b := rfl @[simp] lemma liftRelAux_inr_inl {b : β} {ca} : LiftRelAux R C (Sum.inr ca) (Sum.inl b) = ∃ a, a ∈ ca ∧ R a b := rfl @[simp] lemma liftRelAux_inr_inr {ca cb} : LiftRelAux R C (Sum.inr ca) (Sum.inr cb) = C ca cb := rfl @[simp] theorem LiftRelAux.ret_left (R : α → β → Prop) (C : Computation α → Computation β → Prop) (a cb) : LiftRelAux R C (Sum.inl a) (destruct cb) ↔ ∃ b, b ∈ cb ∧ R a b := by apply cb.recOn (fun b => _) fun cb => _ · intro b exact ⟨fun h => ⟨_, ret_mem _, h⟩, fun ⟨b', mb, h⟩ => by rw [mem_unique (ret_mem _) mb]; exact h⟩ · intro rw [destruct_think] exact ⟨fun ⟨b, h, r⟩ => ⟨b, think_mem h, r⟩, fun ⟨b, h, r⟩ => ⟨b, of_think_mem h, r⟩⟩ theorem LiftRelAux.swap (R : α → β → Prop) (C) (a b) : LiftRelAux (swap R) (swap C) b a = LiftRelAux R C a b := by rcases a with a \| ca <;> rcases b with b \| cb <;> simp only [LiftRelAux] @[simp] theorem LiftRelAux.ret_right (R : α → β → Prop) (C : Computation α → Computation β → Prop) (b ca) : LiftRelAux R C (destruct ca) (Sum.inl b) ↔ ∃ a, a ∈ ca ∧ R a b := by rw [← LiftRelAux.swap, LiftRelAux.ret_left] theorem LiftRelRec.lem {R : α → β → Prop} (C : Computation α → Computation β → Prop) (H : ∀ {ca cb}, C ca cb → LiftRelAux R C (destruct ca) (destruct cb)) (ca cb) (Hc : C ca cb) (a) (ha : a ∈ ca) : LiftRel R ca cb := by revert cb refine memRecOn (C := (fun ca ↦ ∀ (cb : Computation β), C ca cb → LiftRel R ca cb)) ha ?_ (fun ca' IH => ?_) <;> intro cb Hc <;> have h := H Hc · simp only [destruct_pure, LiftRelAux.ret_left] at h simp [h]	· simp only [liftRel_think_left] revert h apply cb.recOn (fun b => _) fun cb' => _ <;> intros _ h	Mathlib/Data/Seq/Computation.lean	1,067	1,069
/- Copyright (c) 2017 Robert Y. Lewis. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Robert Y. Lewis, Keeley Hoek -/ import Mathlib.Algebra.NeZero import Mathlib.Data.Int.DivMod import Mathlib.Logic.Embedding.Basic import Mathlib.Logic.Equiv.Set import Mathlib.Tactic.Common import Mathlib.Tactic.Attr.Register /-! # The finite type with `n` elements `Fin n` is the type whose elements are natural numbers smaller than `n`. This file expands on the development in the core library. ## Main definitions ### Induction principles * `finZeroElim` : Elimination principle for the empty set `Fin 0`, generalizes `Fin.elim0`. Further definitions and eliminators can be found in `Init.Data.Fin.Lemmas` ### Embeddings and isomorphisms * `Fin.valEmbedding` : coercion to natural numbers as an `Embedding`; * `Fin.succEmb` : `Fin.succ` as an `Embedding`; * `Fin.castLEEmb h` : `Fin.castLE` as an `Embedding`, embed `Fin n` into `Fin m`, `h : n ≤ m`; * `finCongr` : `Fin.cast` as an `Equiv`, equivalence between `Fin n` and `Fin m` when `n = m`; * `Fin.castAddEmb m` : `Fin.castAdd` as an `Embedding`, embed `Fin n` into `Fin (n+m)`; * `Fin.castSuccEmb` : `Fin.castSucc` as an `Embedding`, embed `Fin n` into `Fin (n+1)`; * `Fin.addNatEmb m i` : `Fin.addNat` as an `Embedding`, add `m` on `i` on the right, generalizes `Fin.succ`; * `Fin.natAddEmb n i` : `Fin.natAdd` as an `Embedding`, adds `n` on `i` on the left; ### Other casts * `Fin.divNat i` : divides `i : Fin (m * n)` by `n`; * `Fin.modNat i` : takes the mod of `i : Fin (m * n)` by `n`; -/ assert_not_exists Monoid Finset open Fin Nat Function attribute [simp] Fin.succ_ne_zero Fin.castSucc_lt_last /-- Elimination principle for the empty set `Fin 0`, dependent version. -/ def finZeroElim {α : Fin 0 → Sort} (x : Fin 0) : α x := x.elim0 namespace Fin @[simp] theorem mk_eq_one {n a : Nat} {ha : a < n + 2} : (⟨a, ha⟩ : Fin (n + 2)) = 1 ↔ a = 1 := mk.inj_iff @[simp] theorem one_eq_mk {n a : Nat} {ha : a < n + 2} : 1 = (⟨a, ha⟩ : Fin (n + 2)) ↔ a = 1 := by simp [eq_comm] instance {n : ℕ} : CanLift ℕ (Fin n) Fin.val (· < n) where prf k hk := ⟨⟨k, hk⟩, rfl⟩ /-- A dependent variant of `Fin.elim0`. -/ def rec0 {α : Fin 0 → Sort} (i : Fin 0) : α i := absurd i.2 (Nat.not_lt_zero _) variable {n m : ℕ} --variable {a b : Fin n} -- this really breaks stuff theorem val_injective : Function.Injective (@Fin.val n) := @Fin.eq_of_val_eq n /-- If you actually have an element of `Fin n`, then the `n` is always positive -/ lemma size_positive : Fin n → 0 < n := Fin.pos lemma size_positive' [Nonempty (Fin n)] : 0 < n := ‹Nonempty (Fin n)›.elim Fin.pos protected theorem prop (a : Fin n) : a.val < n := a.2 lemma lt_last_iff_ne_last {a : Fin (n + 1)} : a < last n ↔ a ≠ last n := by simp [Fin.lt_iff_le_and_ne, le_last] lemma ne_zero_of_lt {a b : Fin (n + 1)} (hab : a < b) : b ≠ 0 := Fin.ne_of_gt <\| Fin.lt_of_le_of_lt a.zero_le hab lemma ne_last_of_lt {a b : Fin (n + 1)} (hab : a < b) : a ≠ last n := Fin.ne_of_lt <\| Fin.lt_of_lt_of_le hab b.le_last /-- Equivalence between `Fin n` and `{ i // i < n }`. -/ @[simps apply symm_apply] def equivSubtype : Fin n ≃ { i // i < n } where toFun a := ⟨a.1, a.2⟩ invFun a := ⟨a.1, a.2⟩ left_inv := fun ⟨_, _⟩ => rfl right_inv := fun ⟨_, _⟩ => rfl section coe /-! ### coercions and constructions -/ theorem val_eq_val (a b : Fin n) : (a : ℕ) = b ↔ a = b := Fin.ext_iff.symm theorem ne_iff_vne (a b : Fin n) : a ≠ b ↔ a.1 ≠ b.1 := Fin.ext_iff.not theorem mk_eq_mk {a h a' h'} : @mk n a h = @mk n a' h' ↔ a = a' := Fin.ext_iff -- syntactic tautologies now /-- Assume `k = l`. If two functions defined on `Fin k` and `Fin l` are equal on each element, then they coincide (in the heq sense). -/ protected theorem heq_fun_iff {α : Sort} {k l : ℕ} (h : k = l) {f : Fin k → α} {g : Fin l → α} : HEq f g ↔ ∀ i : Fin k, f i = g ⟨(i : ℕ), h ▸ i.2⟩ := by subst h simp [funext_iff] /-- Assume `k = l` and `k' = l'`. If two functions `Fin k → Fin k' → α` and `Fin l → Fin l' → α` are equal on each pair, then they coincide (in the heq sense). -/ protected theorem heq_fun₂_iff {α : Sort} {k l k' l' : ℕ} (h : k = l) (h' : k' = l') {f : Fin k → Fin k' → α} {g : Fin l → Fin l' → α} : HEq f g ↔ ∀ (i : Fin k) (j : Fin k'), f i j = g ⟨(i : ℕ), h ▸ i.2⟩ ⟨(j : ℕ), h' ▸ j.2⟩ := by subst h subst h' simp [funext_iff] /-- Two elements of `Fin k` and `Fin l` are heq iff their values in `ℕ` coincide. This requires `k = l`. For the left implication without this assumption, see `val_eq_val_of_heq`. -/ protected theorem heq_ext_iff {k l : ℕ} (h : k = l) {i : Fin k} {j : Fin l} : HEq i j ↔ (i : ℕ) = (j : ℕ) := by subst h simp [val_eq_val] end coe section Order /-! ### order -/ theorem le_iff_val_le_val {a b : Fin n} : a ≤ b ↔ (a : ℕ) ≤ b := Iff.rfl /-- `a < b` as natural numbers if and only if `a < b` in `Fin n`. -/ @[norm_cast, simp] theorem val_fin_lt {n : ℕ} {a b : Fin n} : (a : ℕ) < (b : ℕ) ↔ a < b := Iff.rfl /-- `a ≤ b` as natural numbers if and only if `a ≤ b` in `Fin n`. -/ @[norm_cast, simp] theorem val_fin_le {n : ℕ} {a b : Fin n} : (a : ℕ) ≤ (b : ℕ) ↔ a ≤ b := Iff.rfl theorem min_val {a : Fin n} : min (a : ℕ) n = a := by simp theorem max_val {a : Fin n} : max (a : ℕ) n = n := by simp /-- The inclusion map `Fin n → ℕ` is an embedding. -/ @[simps -fullyApplied apply] def valEmbedding : Fin n ↪ ℕ := ⟨val, val_injective⟩ @[simp] theorem equivSubtype_symm_trans_valEmbedding : equivSubtype.symm.toEmbedding.trans valEmbedding = Embedding.subtype (· < n) := rfl /-- Use the ordering on `Fin n` for checking recursive definitions. For example, the following definition is not accepted by the termination checker, unless we declare the `WellFoundedRelation` instance: ```lean def factorial {n : ℕ} : Fin n → ℕ \| ⟨0, _⟩ := 1 \| ⟨i + 1, hi⟩ := (i + 1) * factorial ⟨i, i.lt_succ_self.trans hi⟩ ``` -/ instance {n : ℕ} : WellFoundedRelation (Fin n) := measure (val : Fin n → ℕ) @[deprecated (since := "2025-02-24")] alias val_zero' := val_zero /-- `Fin.mk_zero` in `Lean` only applies in `Fin (n + 1)`. This one instead uses a `NeZero n` typeclass hypothesis. -/ @[simp] theorem mk_zero' (n : ℕ) [NeZero n] : (⟨0, pos_of_neZero n⟩ : Fin n) = 0 := rfl /-- The `Fin.zero_le` in `Lean` only applies in `Fin (n+1)`. This one instead uses a `NeZero n` typeclass hypothesis. -/ @[simp] protected theorem zero_le' [NeZero n] (a : Fin n) : 0 ≤ a := Nat.zero_le a.val @[simp, norm_cast] theorem val_eq_zero_iff [NeZero n] {a : Fin n} : a.val = 0 ↔ a = 0 := by rw [Fin.ext_iff, val_zero] theorem val_ne_zero_iff [NeZero n] {a : Fin n} : a.val ≠ 0 ↔ a ≠ 0 := val_eq_zero_iff.not @[simp, norm_cast] theorem val_pos_iff [NeZero n] {a : Fin n} : 0 < a.val ↔ 0 < a := by rw [← val_fin_lt, val_zero] /-- The `Fin.pos_iff_ne_zero` in `Lean` only applies in `Fin (n+1)`. This one instead uses a `NeZero n` typeclass hypothesis. -/ theorem pos_iff_ne_zero' [NeZero n] (a : Fin n) : 0 < a ↔ a ≠ 0 := by rw [← val_pos_iff, Nat.pos_iff_ne_zero, val_ne_zero_iff] @[simp] lemma cast_eq_self (a : Fin n) : a.cast rfl = a := rfl @[simp] theorem cast_eq_zero {k l : ℕ} [NeZero k] [NeZero l] (h : k = l) (x : Fin k) : Fin.cast h x = 0 ↔ x = 0 := by simp [← val_eq_zero_iff] lemma cast_injective {k l : ℕ} (h : k = l) : Injective (Fin.cast h) := fun a b hab ↦ by simpa [← val_eq_val] using hab theorem last_pos' [NeZero n] : 0 < last n := n.pos_of_neZero theorem one_lt_last [NeZero n] : 1 < last (n + 1) := by rw [lt_iff_val_lt_val, val_one, val_last, Nat.lt_add_left_iff_pos, Nat.pos_iff_ne_zero] exact NeZero.ne n end Order /-! ### Coercions to `ℤ` and the `fin_omega` tactic. -/ open Int theorem coe_int_sub_eq_ite {n : Nat} (u v : Fin n) : ((u - v : Fin n) : Int) = if v ≤ u then (u - v : Int) else (u - v : Int) + n := by rw [Fin.sub_def] split · rw [natCast_emod, Int.emod_eq_sub_self_emod, Int.emod_eq_of_lt] <;> omega · rw [natCast_emod, Int.emod_eq_of_lt] <;> omega theorem coe_int_sub_eq_mod {n : Nat} (u v : Fin n) : ((u - v : Fin n) : Int) = ((u : Int) - (v : Int)) % n := by rw [coe_int_sub_eq_ite] split · rw [Int.emod_eq_of_lt] <;> omega · rw [Int.emod_eq_add_self_emod, Int.emod_eq_of_lt] <;> omega theorem coe_int_add_eq_ite {n : Nat} (u v : Fin n) : ((u + v : Fin n) : Int) = if (u + v : ℕ) < n then (u + v : Int) else (u + v : Int) - n := by rw [Fin.add_def] split · rw [natCast_emod, Int.emod_eq_of_lt] <;> omega · rw [natCast_emod, Int.emod_eq_sub_self_emod, Int.emod_eq_of_lt] <;> omega theorem coe_int_add_eq_mod {n : Nat} (u v : Fin n) : ((u + v : Fin n) : Int) = ((u : Int) + (v : Int)) % n := by rw [coe_int_add_eq_ite] split · rw [Int.emod_eq_of_lt] <;> omega · rw [Int.emod_eq_sub_self_emod, Int.emod_eq_of_lt] <;> omega -- Write `a + b` as `if (a + b : ℕ) < n then (a + b : ℤ) else (a + b : ℤ) - n` and -- similarly `a - b` as `if (b : ℕ) ≤ a then (a - b : ℤ) else (a - b : ℤ) + n`. attribute [fin_omega] coe_int_sub_eq_ite coe_int_add_eq_ite -- Rewrite inequalities in `Fin` to inequalities in `ℕ` attribute [fin_omega] Fin.lt_iff_val_lt_val Fin.le_iff_val_le_val -- Rewrite `1 : Fin (n + 2)` to `1 : ℤ` attribute [fin_omega] val_one /-- Preprocessor for `omega` to handle inequalities in `Fin`. Note that this involves a lot of case splitting, so may be slow. -/ -- Further adjustment to the simp set can probably make this more powerful. -- Please experiment and PR updates! macro "fin_omega" : tactic => `(tactic\| { try simp only [fin_omega, ← Int.ofNat_lt, ← Int.ofNat_le] at * omega }) section Add /-! ### addition, numerals, and coercion from Nat -/ @[simp] theorem val_one' (n : ℕ) [NeZero n] : ((1 : Fin n) : ℕ) = 1 % n := rfl @[deprecated val_one' (since := "2025-03-10")] theorem val_one'' {n : ℕ} : ((1 : Fin (n + 1)) : ℕ) = 1 % (n + 1) := rfl instance nontrivial {n : ℕ} : Nontrivial (Fin (n + 2)) where exists_pair_ne := ⟨0, 1, (ne_iff_vne 0 1).mpr (by simp [val_one, val_zero])⟩ theorem nontrivial_iff_two_le : Nontrivial (Fin n) ↔ 2 ≤ n := by rcases n with (_ \| _ \| n) <;> simp [Fin.nontrivial, not_nontrivial, Nat.succ_le_iff] section Monoid instance inhabitedFinOneAdd (n : ℕ) : Inhabited (Fin (1 + n)) := haveI : NeZero (1 + n) := by rw [Nat.add_comm]; infer_instance inferInstance @[simp] theorem default_eq_zero (n : ℕ) [NeZero n] : (default : Fin n) = 0 := rfl instance instNatCast [NeZero n] : NatCast (Fin n) where natCast i := Fin.ofNat' n i lemma natCast_def [NeZero n] (a : ℕ) : (a : Fin n) = ⟨a % n, mod_lt _ n.pos_of_neZero⟩ := rfl end Monoid theorem val_add_eq_ite {n : ℕ} (a b : Fin n) : (↑(a + b) : ℕ) = if n ≤ a + b then a + b - n else a + b := by rw [Fin.val_add, Nat.add_mod_eq_ite, Nat.mod_eq_of_lt (show ↑a < n from a.2), Nat.mod_eq_of_lt (show ↑b < n from b.2)] theorem val_add_eq_of_add_lt {n : ℕ} {a b : Fin n} (huv : a.val + b.val < n) : (a + b).val = a.val + b.val := by rw [val_add] simp [Nat.mod_eq_of_lt huv] lemma intCast_val_sub_eq_sub_add_ite {n : ℕ} (a b : Fin n) : ((a - b).val : ℤ) = a.val - b.val + if b ≤ a then 0 else n := by split <;> fin_omega lemma one_le_of_ne_zero {n : ℕ} [NeZero n] {k : Fin n} (hk : k ≠ 0) : 1 ≤ k := by obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero (NeZero.ne n) cases n with \| zero => simp only [Nat.reduceAdd, Fin.isValue, Fin.zero_le] \| succ n => rwa [Fin.le_iff_val_le_val, Fin.val_one, Nat.one_le_iff_ne_zero, val_ne_zero_iff] lemma val_sub_one_of_ne_zero [NeZero n] {i : Fin n} (hi : i ≠ 0) : (i - 1).val = i - 1 := by obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero (NeZero.ne n) rw [Fin.sub_val_of_le (one_le_of_ne_zero hi), Fin.val_one', Nat.mod_eq_of_lt (Nat.succ_le_iff.mpr (nontrivial_iff_two_le.mp <\| nontrivial_of_ne i 0 hi))] section OfNatCoe @[simp] theorem ofNat'_eq_cast (n : ℕ) [NeZero n] (a : ℕ) : Fin.ofNat' n a = a := rfl @[simp] lemma val_natCast (a n : ℕ) [NeZero n] : (a : Fin n).val = a % n := rfl /-- Converting an in-range number to `Fin (n + 1)` produces a result whose value is the original number. -/ theorem val_cast_of_lt {n : ℕ} [NeZero n] {a : ℕ} (h : a < n) : (a : Fin n).val = a := Nat.mod_eq_of_lt h /-- If `n` is non-zero, converting the value of a `Fin n` to `Fin n` results in the same value. -/ @[simp, norm_cast] theorem cast_val_eq_self {n : ℕ} [NeZero n] (a : Fin n) : (a.val : Fin n) = a := Fin.ext <\| val_cast_of_lt a.isLt -- This is a special case of `CharP.cast_eq_zero` that doesn't require typeclass search @[simp high] lemma natCast_self (n : ℕ) [NeZero n] : (n : Fin n) = 0 := by ext; simp @[simp] lemma natCast_eq_zero {a n : ℕ} [NeZero n] : (a : Fin n) = 0 ↔ n ∣ a := by simp [Fin.ext_iff, Nat.dvd_iff_mod_eq_zero] @[simp]	theorem natCast_eq_last (n) : (n : Fin (n + 1)) = Fin.last n := by ext; simp	Mathlib/Data/Fin/Basic.lean	386	387
/- Copyright (c) 2023 Anne Baanen. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anne Baanen -/ import Mathlib.Data.ZMod.Basic import Mathlib.RingTheory.Polynomial.Basic import Mathlib.Tactic.NormNum.DivMod import Mathlib.Tactic.NormNum.PowMod import Mathlib.Tactic.ReduceModChar.Ext /-! # `reduce_mod_char` tactic Define the `reduce_mod_char` tactic, which traverses expressions looking for numerals `n`, such that the type of `n` is a ring of (positive) characteristic `p`, and reduces these numerals modulo `p`, to lie between `0` and `p`. ## Implementation The main entry point is `ReduceModChar.derive`, which uses `simp` to traverse expressions and calls `matchAndNorm` on each subexpression. The type of each subexpression is matched syntactically to determine if it is a ring with positive characteristic in `typeToCharP`. Using syntactic matching should be faster than trying to infer a `CharP` instance on each subexpression. The actual reduction happens in `normIntNumeral`. This is written to be compatible with `norm_num` so it can serve as a drop-in replacement for some `norm_num`-based routines (specifically, the intended use is as an option for the `ring` tactic). In addition to the main functionality, we call `normNeg` and `normNegCoeffMul` to replace negation with multiplication by `p - 1`, and simp lemmas tagged `@[reduce_mod_char]` to clean up the resulting expression: e.g. `1 * X + 0` becomes `X`. -/ open Lean Meta Simp open Lean.Elab open Tactic open Qq namespace Tactic namespace ReduceModChar open Mathlib.Meta.NormNum variable {u : Level} lemma CharP.isInt_of_mod {e' r : ℤ} {α : Type*} [Ring α] {n n' : ℕ} (inst : CharP α n) {e : α} (he : IsInt e e') (hn : IsNat n n') (h₂ : IsInt (e' % n') r) : IsInt e r := ⟨by rw [he.out, CharP.intCast_eq_intCast_mod α n, show n = n' from hn.out, h₂.out, Int.cast_id]⟩ lemma CharP.isNat_pow {α} [Semiring α] : ∀ {f : α → ℕ → α} {a : α} {a' b b' c n n' : ℕ},	CharP α n → f = HPow.hPow → IsNat a a' → IsNat b b' → IsNat n n' → Nat.mod (Nat.pow a' b') n' = c → IsNat (f a b) c \| _, _, a, _, b, _, _, n, _, rfl, ⟨h⟩, ⟨rfl⟩, ⟨rfl⟩, rfl => ⟨by	Mathlib/Tactic/ReduceModChar.lean	53	55
/- Copyright (c) 2014 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.Logic.Basic import Mathlib.Logic.Function.Defs import Mathlib.Order.Defs.LinearOrder /-! # Booleans This file proves various trivial lemmas about booleans and their relation to decidable propositions. ## Tags bool, boolean, Bool, De Morgan -/ namespace Bool section /-! This section contains lemmas about booleans which were present in core Lean 3. The remainder of this file contains lemmas about booleans from mathlib 3. -/ theorem true_eq_false_eq_False : ¬true = false := by decide theorem false_eq_true_eq_False : ¬false = true := by decide theorem eq_false_eq_not_eq_true (b : Bool) : (¬b = true) = (b = false) := by simp theorem eq_true_eq_not_eq_false (b : Bool) : (¬b = false) = (b = true) := by simp theorem eq_false_of_not_eq_true {b : Bool} : ¬b = true → b = false := Eq.mp (eq_false_eq_not_eq_true b) theorem eq_true_of_not_eq_false {b : Bool} : ¬b = false → b = true := Eq.mp (eq_true_eq_not_eq_false b) theorem and_eq_true_eq_eq_true_and_eq_true (a b : Bool) : ((a && b) = true) = (a = true ∧ b = true) := by simp theorem or_eq_true_eq_eq_true_or_eq_true (a b : Bool) : ((a \|\| b) = true) = (a = true ∨ b = true) := by simp theorem not_eq_true_eq_eq_false (a : Bool) : (not a = true) = (a = false) := by cases a <;> simp #adaptation_note /-- nightly-2024-03-05 this is no longer a simp lemma, as the LHS simplifies. -/ theorem and_eq_false_eq_eq_false_or_eq_false (a b : Bool) : ((a && b) = false) = (a = false ∨ b = false) := by cases a <;> cases b <;> simp theorem or_eq_false_eq_eq_false_and_eq_false (a b : Bool) : ((a \|\| b) = false) = (a = false ∧ b = false) := by cases a <;> cases b <;> simp theorem not_eq_false_eq_eq_true (a : Bool) : (not a = false) = (a = true) := by cases a <;> simp theorem coe_false : ↑false = False := by simp theorem coe_true : ↑true = True := by simp theorem coe_sort_false : (false : Prop) = False := by simp theorem coe_sort_true : (true : Prop) = True := by simp theorem decide_iff (p : Prop) [d : Decidable p] : decide p = true ↔ p := by simp theorem decide_true {p : Prop} [Decidable p] : p → decide p := (decide_iff p).2 theorem of_decide_true {p : Prop} [Decidable p] : decide p → p := (decide_iff p).1 theorem bool_iff_false {b : Bool} : ¬b ↔ b = false := by cases b <;> decide theorem bool_eq_false {b : Bool} : ¬b → b = false := bool_iff_false.1 theorem decide_false_iff (p : Prop) {_ : Decidable p} : decide p = false ↔ ¬p := bool_iff_false.symm.trans (not_congr (decide_iff _)) theorem decide_false {p : Prop} [Decidable p] : ¬p → decide p = false := (decide_false_iff p).2 theorem of_decide_false {p : Prop} [Decidable p] : decide p = false → ¬p := (decide_false_iff p).1 theorem decide_congr {p q : Prop} [Decidable p] [Decidable q] (h : p ↔ q) : decide p = decide q := decide_eq_decide.mpr h theorem coe_xor_iff (a b : Bool) : xor a b ↔ Xor' (a = true) (b = true) := by cases a <;> cases b <;> decide end theorem dichotomy (b : Bool) : b = false ∨ b = true := by cases b <;> simp theorem not_ne_id : not ≠ id := fun h ↦ false_ne_true <\| congrFun h true theorem or_inl {a b : Bool} (H : a) : a \|\| b := by simp [H] theorem or_inr {a b : Bool} (H : b) : a \|\| b := by cases a <;> simp [H] theorem and_elim_left : ∀ {a b : Bool}, a && b → a := by decide theorem and_intro : ∀ {a b : Bool}, a → b → a && b := by decide theorem and_elim_right : ∀ {a b : Bool}, a && b → b := by decide lemma eq_not_iff : ∀ {a b : Bool}, a = !b ↔ a ≠ b := by decide lemma not_eq_iff : ∀ {a b : Bool}, !a = b ↔ a ≠ b := by decide theorem ne_not {a b : Bool} : a ≠ !b ↔ a = b := not_eq_not lemma not_ne_self : ∀ b : Bool, (!b) ≠ b := by decide lemma self_ne_not : ∀ b : Bool, b ≠ !b := by decide lemma eq_or_eq_not : ∀ a b, a = b ∨ a = !b := by decide -- TODO naming issue: these two `not` are different. theorem not_iff_not : ∀ {b : Bool}, !b ↔ ¬b := by simp theorem eq_true_of_not_eq_false' {a : Bool} : !a = false → a = true := by cases a <;> decide theorem eq_false_of_not_eq_true' {a : Bool} : !a = true → a = false := by cases a <;> decide theorem bne_eq_xor : bne = xor := by funext a b; revert a b; decide attribute [simp] xor_assoc theorem xor_iff_ne : ∀ {x y : Bool}, xor x y = true ↔ x ≠ y := by decide /-! ### De Morgan's laws for booleans -/ instance linearOrder : LinearOrder Bool where	le_refl := by decide	Mathlib/Data/Bool/Basic.lean	147	147
/- Copyright (c) 2019 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl -/ import Mathlib.Algebra.CharP.Defs import Mathlib.Algebra.MvPolynomial.Degrees import Mathlib.Data.DFinsupp.Small import Mathlib.Data.Fintype.Pi import Mathlib.LinearAlgebra.Finsupp.VectorSpace import Mathlib.LinearAlgebra.FreeModule.Finite.Basic /-! # Multivariate polynomials over commutative rings This file contains basic facts about multivariate polynomials over commutative rings, for example that the monomials form a basis. ## Main definitions * `restrictTotalDegree σ R m`: the subspace of multivariate polynomials indexed by `σ` over the commutative ring `R` of total degree at most `m`. * `restrictDegree σ R m`: the subspace of multivariate polynomials indexed by `σ` over the commutative ring `R` such that the degree in each individual variable is at most `m`. ## Main statements * The multivariate polynomial ring over a commutative semiring of characteristic `p` has characteristic `p`, and similarly for `CharZero`. * `basisMonomials`: shows that the monomials form a basis of the vector space of multivariate polynomials. ## TODO Generalise to noncommutative (semi)rings -/ noncomputable section open Set LinearMap Submodule universe u v variable (σ : Type u) (R : Type v) [CommSemiring R] (p m : ℕ) namespace MvPolynomial instance {σ : Type} {R : Type} [CommSemiring R] [Small.{u} R] [Small.{u} σ] : Small.{u} (MvPolynomial σ R) := inferInstanceAs (Small.{u} ((σ →₀ ℕ) →₀ R)) section CharP instance [CharP R p] : CharP (MvPolynomial σ R) p where cast_eq_zero_iff n := by rw [← C_eq_coe_nat, ← C_0, C_inj, CharP.cast_eq_zero_iff R p] end CharP section CharZero instance [CharZero R] : CharZero (MvPolynomial σ R) where cast_injective x y hxy := by rwa [← C_eq_coe_nat, ← C_eq_coe_nat, C_inj, Nat.cast_inj] at hxy end CharZero section Homomorphism theorem mapRange_eq_map {R S : Type} [CommSemiring R] [CommSemiring S] (p : MvPolynomial σ R) (f : R →+ S) : Finsupp.mapRange f f.map_zero p = map f p := by rw [p.as_sum, Finsupp.mapRange_finset_sum, map_sum (map f)] refine Finset.sum_congr rfl fun n _ => ?_ rw [map_monomial, ← single_eq_monomial, Finsupp.mapRange_single, single_eq_monomial] end Homomorphism section Degree variable {σ} /-- The submodule of polynomials that are sum of monomials in the set `s`. -/ def restrictSupport (s : Set (σ →₀ ℕ)) : Submodule R (MvPolynomial σ R) := Finsupp.supported _ _ s /-- `restrictSupport R s` has a canonical `R`-basis indexed by `s`. -/ def basisRestrictSupport (s : Set (σ →₀ ℕ)) : Basis s R (restrictSupport R s) where repr := Finsupp.supportedEquivFinsupp s theorem restrictSupport_mono {s t : Set (σ →₀ ℕ)} (h : s ⊆ t) : restrictSupport R s ≤ restrictSupport R t := Finsupp.supported_mono h variable (σ) /-- The submodule of polynomials of total degree less than or equal to `m`. -/ def restrictTotalDegree (m : ℕ) : Submodule R (MvPolynomial σ R) := restrictSupport R { n \| (n.sum fun _ e => e) ≤ m } /-- The submodule of polynomials such that the degree with respect to each individual variable is less than or equal to `m`. -/ def restrictDegree (m : ℕ) : Submodule R (MvPolynomial σ R) := restrictSupport R { n \| ∀ i, n i ≤ m } variable {R} theorem mem_restrictTotalDegree (p : MvPolynomial σ R) : p ∈ restrictTotalDegree σ R m ↔ p.totalDegree ≤ m := by rw [totalDegree, Finset.sup_le_iff] rfl theorem mem_restrictDegree (p : MvPolynomial σ R) (n : ℕ) : p ∈ restrictDegree σ R n ↔ ∀ s ∈ p.support, ∀ i, (s : σ →₀ ℕ) i ≤ n := by rw [restrictDegree, restrictSupport, Finsupp.mem_supported] rfl theorem mem_restrictDegree_iff_sup [DecidableEq σ] (p : MvPolynomial σ R) (n : ℕ) : p ∈ restrictDegree σ R n ↔ ∀ i, p.degrees.count i ≤ n := by simp only [mem_restrictDegree, degrees_def, Multiset.count_finset_sup, Finsupp.count_toMultiset,	Finset.sup_le_iff] exact ⟨fun h n s hs => h s hs n, fun h s hs n => h n s hs⟩ variable (R)	Mathlib/RingTheory/MvPolynomial/Basic.lean	119	123
/- 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)] theorem Finite.encard_eq_coe_toFinset_card (h : s.Finite) : s.encard = h.toFinset.card := by have := h.fintype rw [encard, ENat.card_eq_coe_fintype_card, toFinite_toFinset, toFinset_card] theorem encard_eq_coe_toFinset_card (s : Set α) [Fintype s] : encard s = s.toFinset.card := by have h := toFinite s rw [h.encard_eq_coe_toFinset_card, toFinite_toFinset] @[simp] theorem toENat_cardinalMk (s : Set α) : (Cardinal.mk s).toENat = s.encard := rfl theorem toENat_cardinalMk_subtype (P : α → Prop) : (Cardinal.mk {x // P x}).toENat = {x \| P x}.encard := rfl @[simp] theorem coe_fintypeCard (s : Set α) [Fintype s] : Fintype.card s = s.encard := by simp [encard_eq_coe_toFinset_card] @[simp, norm_cast] theorem encard_coe_eq_coe_finsetCard (s : Finset α) : encard (s : Set α) = s.card := by rw [Finite.encard_eq_coe_toFinset_card (Finset.finite_toSet s)]; simp @[simp] theorem Infinite.encard_eq {s : Set α} (h : s.Infinite) : s.encard = ⊤ := by have := h.to_subtype rw [encard, ENat.card_eq_top_of_infinite] @[simp] theorem encard_eq_zero : s.encard = 0 ↔ s = ∅ := by rw [encard, ENat.card_eq_zero_iff_empty, isEmpty_subtype, eq_empty_iff_forall_not_mem] @[simp] theorem encard_empty : (∅ : Set α).encard = 0 := by rw [encard_eq_zero] theorem nonempty_of_encard_ne_zero (h : s.encard ≠ 0) : s.Nonempty := by rwa [nonempty_iff_ne_empty, Ne, ← encard_eq_zero] theorem encard_ne_zero : s.encard ≠ 0 ↔ s.Nonempty := by rw [ne_eq, encard_eq_zero, nonempty_iff_ne_empty] @[simp] theorem encard_pos : 0 < s.encard ↔ s.Nonempty := by rw [pos_iff_ne_zero, encard_ne_zero] protected alias ⟨_, Nonempty.encard_pos⟩ := encard_pos @[simp] theorem encard_singleton (e : α) : ({e} : Set α).encard = 1 := by rw [encard, ENat.card_eq_coe_fintype_card, Fintype.card_ofSubsingleton, Nat.cast_one] theorem encard_union_eq (h : Disjoint s t) : (s ∪ t).encard = s.encard + t.encard := by classical simp [encard, ENat.card_congr (Equiv.Set.union h)] theorem encard_insert_of_not_mem {a : α} (has : a ∉ s) : (insert a s).encard = s.encard + 1 := by rw [← union_singleton, encard_union_eq (by simpa), encard_singleton] theorem Finite.encard_lt_top (h : s.Finite) : s.encard < ⊤ := by induction s, h using Set.Finite.induction_on with \| empty => simp \| insert hat _ ht' => rw [encard_insert_of_not_mem hat] exact lt_tsub_iff_right.1 ht' theorem Finite.encard_eq_coe (h : s.Finite) : s.encard = ENat.toNat s.encard := (ENat.coe_toNat h.encard_lt_top.ne).symm theorem Finite.exists_encard_eq_coe (h : s.Finite) : ∃ (n : ℕ), s.encard = n := ⟨_, h.encard_eq_coe⟩ @[simp] theorem encard_lt_top_iff : s.encard < ⊤ ↔ s.Finite := ⟨fun h ↦ by_contra fun h' ↦ h.ne (Infinite.encard_eq h'), Finite.encard_lt_top⟩ @[simp] theorem encard_eq_top_iff : s.encard = ⊤ ↔ s.Infinite := by rw [← not_iff_not, ← Ne, ← lt_top_iff_ne_top, encard_lt_top_iff, not_infinite] alias ⟨_, encard_eq_top⟩ := encard_eq_top_iff theorem encard_ne_top_iff : s.encard ≠ ⊤ ↔ s.Finite := by simp theorem finite_of_encard_le_coe {k : ℕ} (h : s.encard ≤ k) : s.Finite := by rw [← encard_lt_top_iff]; exact h.trans_lt (WithTop.coe_lt_top _) theorem finite_of_encard_eq_coe {k : ℕ} (h : s.encard = k) : s.Finite := finite_of_encard_le_coe h.le theorem encard_le_coe_iff {k : ℕ} : s.encard ≤ k ↔ s.Finite ∧ ∃ (n₀ : ℕ), s.encard = n₀ ∧ n₀ ≤ k := ⟨fun h ↦ ⟨finite_of_encard_le_coe h, by rwa [ENat.le_coe_iff] at h⟩, fun ⟨_,⟨n₀,hs, hle⟩⟩ ↦ by rwa [hs, Nat.cast_le]⟩ @[simp] theorem encard_prod : (s ×ˢ t).encard = s.encard * t.encard := by simp [Set.encard, ENat.card_congr (Equiv.Set.prod ..)] section Lattice theorem encard_le_encard (h : s ⊆ t) : s.encard ≤ t.encard := by rw [← union_diff_cancel h, encard_union_eq disjoint_sdiff_right]; exact le_self_add @[deprecated (since := "2025-01-05")] alias encard_le_card := encard_le_encard theorem encard_mono {α : Type} : Monotone (encard : Set α → ℕ∞) := fun _ _ ↦ encard_le_encard theorem encard_diff_add_encard_of_subset (h : s ⊆ t) : (t \ s).encard + s.encard = t.encard := by rw [← encard_union_eq disjoint_sdiff_left, diff_union_self, union_eq_self_of_subset_right h] @[simp] theorem one_le_encard_iff_nonempty : 1 ≤ s.encard ↔ s.Nonempty := by rw [nonempty_iff_ne_empty, Ne, ← encard_eq_zero, ENat.one_le_iff_ne_zero] theorem encard_diff_add_encard_inter (s t : Set α) : (s \ t).encard + (s ∩ t).encard = s.encard := by rw [← encard_union_eq (disjoint_of_subset_right inter_subset_right disjoint_sdiff_left), diff_union_inter] theorem encard_union_add_encard_inter (s t : Set α) : (s ∪ t).encard + (s ∩ t).encard = s.encard + t.encard := by rw [← diff_union_self, encard_union_eq disjoint_sdiff_left, add_right_comm, encard_diff_add_encard_inter] theorem encard_eq_encard_iff_encard_diff_eq_encard_diff (h : (s ∩ t).Finite) : s.encard = t.encard ↔ (s \ t).encard = (t \ s).encard := by rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_right_inj h.encard_lt_top.ne] theorem encard_le_encard_iff_encard_diff_le_encard_diff (h : (s ∩ t).Finite) : s.encard ≤ t.encard ↔ (s \ t).encard ≤ (t \ s).encard := by rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_le_add_iff_right h.encard_lt_top.ne] theorem encard_lt_encard_iff_encard_diff_lt_encard_diff (h : (s ∩ t).Finite) : s.encard < t.encard ↔ (s \ t).encard < (t \ s).encard := by rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_lt_add_iff_right h.encard_lt_top.ne] theorem encard_union_le (s t : Set α) : (s ∪ t).encard ≤ s.encard + t.encard := by rw [← encard_union_add_encard_inter]; exact le_self_add theorem finite_iff_finite_of_encard_eq_encard (h : s.encard = t.encard) : s.Finite ↔ t.Finite := by rw [← encard_lt_top_iff, ← encard_lt_top_iff, h] theorem infinite_iff_infinite_of_encard_eq_encard (h : s.encard = t.encard) : s.Infinite ↔ t.Infinite := by rw [← encard_eq_top_iff, h, encard_eq_top_iff] theorem Finite.finite_of_encard_le {s : Set α} {t : Set β} (hs : s.Finite) (h : t.encard ≤ s.encard) : t.Finite := encard_lt_top_iff.1 (h.trans_lt hs.encard_lt_top) lemma Finite.eq_of_subset_of_encard_le' (ht : t.Finite) (hst : s ⊆ t) (hts : t.encard ≤ s.encard) : s = t := by rw [← zero_add (a := encard s), ← encard_diff_add_encard_of_subset hst] at hts have hdiff := WithTop.le_of_add_le_add_right (ht.subset hst).encard_lt_top.ne hts rw [nonpos_iff_eq_zero, encard_eq_zero, diff_eq_empty] at hdiff exact hst.antisymm hdiff theorem Finite.eq_of_subset_of_encard_le (hs : s.Finite) (hst : s ⊆ t) (hts : t.encard ≤ s.encard) : s = t := (hs.finite_of_encard_le hts).eq_of_subset_of_encard_le' hst hts theorem Finite.encard_lt_encard (hs : s.Finite) (h : s ⊂ t) : s.encard < t.encard := (encard_mono h.subset).lt_of_ne fun he ↦ h.ne (hs.eq_of_subset_of_encard_le h.subset he.symm.le) theorem encard_strictMono [Finite α] : StrictMono (encard : Set α → ℕ∞) := fun _ _ h ↦ (toFinite _).encard_lt_encard h theorem encard_diff_add_encard (s t : Set α) : (s \ t).encard + t.encard = (s ∪ t).encard := by rw [← encard_union_eq disjoint_sdiff_left, diff_union_self] theorem encard_le_encard_diff_add_encard (s t : Set α) : s.encard ≤ (s \ t).encard + t.encard := (encard_mono subset_union_left).trans_eq (encard_diff_add_encard _ _).symm theorem tsub_encard_le_encard_diff (s t : Set α) : s.encard - t.encard ≤ (s \ t).encard := by rw [tsub_le_iff_left, add_comm]; apply encard_le_encard_diff_add_encard theorem encard_add_encard_compl (s : Set α) : s.encard + sᶜ.encard = (univ : Set α).encard := by rw [← encard_union_eq disjoint_compl_right, union_compl_self] end Lattice section InsertErase variable {a b : α} theorem encard_insert_le (s : Set α) (x : α) : (insert x s).encard ≤ s.encard + 1 := by rw [← union_singleton, ← encard_singleton x]; apply encard_union_le theorem encard_singleton_inter (s : Set α) (x : α) : ({x} ∩ s).encard ≤ 1 := by rw [← encard_singleton x]; exact encard_le_encard inter_subset_left theorem encard_diff_singleton_add_one (h : a ∈ s) : (s \ {a}).encard + 1 = s.encard := by rw [← encard_insert_of_not_mem (fun h ↦ h.2 rfl), insert_diff_singleton, insert_eq_of_mem h] theorem encard_diff_singleton_of_mem (h : a ∈ s) : (s \ {a}).encard = s.encard - 1 := by rw [← encard_diff_singleton_add_one h, ← WithTop.add_right_inj WithTop.one_ne_top, tsub_add_cancel_of_le (self_le_add_left _ _)] theorem encard_tsub_one_le_encard_diff_singleton (s : Set α) (x : α) : s.encard - 1 ≤ (s \ {x}).encard := by rw [← encard_singleton x]; apply tsub_encard_le_encard_diff theorem encard_exchange (ha : a ∉ s) (hb : b ∈ s) : (insert a (s \ {b})).encard = s.encard := by rw [encard_insert_of_not_mem, encard_diff_singleton_add_one hb] simp_all only [not_true, mem_diff, mem_singleton_iff, false_and, not_false_eq_true] theorem encard_exchange' (ha : a ∉ s) (hb : b ∈ s) : (insert a s \ {b}).encard = s.encard := by rw [← insert_diff_singleton_comm (by rintro rfl; exact ha hb), encard_exchange ha hb] theorem encard_eq_add_one_iff {k : ℕ∞} : s.encard = k + 1 ↔ (∃ a t, ¬a ∈ t ∧ insert a t = s ∧ t.encard = k) := by refine ⟨fun h ↦ ?_, ?_⟩ · obtain ⟨a, ha⟩ := nonempty_of_encard_ne_zero (s := s) (by simp [h]) refine ⟨a, s \ {a}, fun h ↦ h.2 rfl, by rwa [insert_diff_singleton, insert_eq_of_mem], ?_⟩ rw [← WithTop.add_right_inj WithTop.one_ne_top, ← h, encard_diff_singleton_add_one ha] rintro ⟨a, t, h, rfl, rfl⟩ rw [encard_insert_of_not_mem h] /-- Every set is either empty, infinite, or can have its `encard` reduced by a removal. Intended for well-founded induction on the value of `encard`. -/ theorem eq_empty_or_encard_eq_top_or_encard_diff_singleton_lt (s : Set α) : s = ∅ ∨ s.encard = ⊤ ∨ ∃ a ∈ s, (s \ {a}).encard < s.encard := by refine s.eq_empty_or_nonempty.elim Or.inl (Or.inr ∘ fun ⟨a,ha⟩ ↦ (s.finite_or_infinite.elim (fun hfin ↦ Or.inr ⟨a, ha, ?_⟩) (Or.inl ∘ Infinite.encard_eq))) rw [← encard_diff_singleton_add_one ha]; nth_rw 1 [← add_zero (encard _)] exact WithTop.add_lt_add_left hfin.diff.encard_lt_top.ne zero_lt_one end InsertErase section SmallSets theorem encard_pair {x y : α} (hne : x ≠ y) : ({x, y} : Set α).encard = 2 := by rw [encard_insert_of_not_mem (by simpa), ← one_add_one_eq_two, WithTop.add_right_inj WithTop.one_ne_top, encard_singleton] theorem encard_eq_one : s.encard = 1 ↔ ∃ x, s = {x} := by refine ⟨fun h ↦ ?_, fun ⟨x, hx⟩ ↦ by rw [hx, encard_singleton]⟩ obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp) exact ⟨x, ((finite_singleton x).eq_of_subset_of_encard_le (by simpa) (by simp [h])).symm⟩ theorem encard_le_one_iff_eq : s.encard ≤ 1 ↔ s = ∅ ∨ ∃ x, s = {x} := by rw [le_iff_lt_or_eq, lt_iff_not_le, ENat.one_le_iff_ne_zero, not_not, encard_eq_zero, encard_eq_one] theorem encard_le_one_iff : s.encard ≤ 1 ↔ ∀ a b, a ∈ s → b ∈ s → a = b := by rw [encard_le_one_iff_eq, or_iff_not_imp_left, ← Ne, ← nonempty_iff_ne_empty] refine ⟨fun h a b has hbs ↦ ?_, fun h ⟨x, hx⟩ ↦ ⟨x, ((singleton_subset_iff.2 hx).antisymm' (fun y hy ↦ h _ _ hy hx))⟩⟩ obtain ⟨x, rfl⟩ := h ⟨_, has⟩ rw [(has : a = x), (hbs : b = x)] theorem encard_le_one_iff_subsingleton : s.encard ≤ 1 ↔ s.Subsingleton := by rw [encard_le_one_iff, Set.Subsingleton] tauto theorem one_lt_encard_iff_nontrivial : 1 < s.encard ↔ s.Nontrivial := by rw [← not_iff_not, not_lt, Set.not_nontrivial_iff, ← encard_le_one_iff_subsingleton] theorem one_lt_encard_iff : 1 < s.encard ↔ ∃ a b, a ∈ s ∧ b ∈ s ∧ a ≠ b := by rw [← not_iff_not, not_exists, not_lt, encard_le_one_iff]; aesop theorem exists_ne_of_one_lt_encard (h : 1 < s.encard) (a : α) : ∃ b ∈ s, b ≠ a := by by_contra! h' obtain ⟨b, b', hb, hb', hne⟩ := one_lt_encard_iff.1 h apply hne rw [h' b hb, h' b' hb'] theorem encard_eq_two : s.encard = 2 ↔ ∃ x y, x ≠ y ∧ s = {x, y} := by refine ⟨fun h ↦ ?_, fun ⟨x, y, hne, hs⟩ ↦ by rw [hs, encard_pair hne]⟩ obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp) rw [← insert_eq_of_mem hx, ← insert_diff_singleton, encard_insert_of_not_mem (fun h ↦ h.2 rfl), ← one_add_one_eq_two, WithTop.add_right_inj (WithTop.one_ne_top), encard_eq_one] at h obtain ⟨y, h⟩ := h refine ⟨x, y, by rintro rfl; exact (h.symm.subset rfl).2 rfl, ?_⟩ rw [← h, insert_diff_singleton, insert_eq_of_mem hx] theorem encard_eq_three {α : Type u_1} {s : Set α} : encard s = 3 ↔ ∃ x y z, x ≠ y ∧ x ≠ z ∧ y ≠ z ∧ s = {x, y, z} := by refine ⟨fun h ↦ ?_, fun ⟨x, y, z, hxy, hyz, hxz, hs⟩ ↦ ?_⟩ · obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp) rw [← insert_eq_of_mem hx, ← insert_diff_singleton, encard_insert_of_not_mem (fun h ↦ h.2 rfl), (by exact rfl : (3 : ℕ∞) = 2 + 1), WithTop.add_right_inj WithTop.one_ne_top, encard_eq_two] at h obtain ⟨y, z, hne, hs⟩ := h refine ⟨x, y, z, ?_, ?_, hne, ?_⟩ · rintro rfl; exact (hs.symm.subset (Or.inl rfl)).2 rfl · rintro rfl; exact (hs.symm.subset (Or.inr rfl)).2 rfl rw [← hs, insert_diff_singleton, insert_eq_of_mem hx] rw [hs, encard_insert_of_not_mem, encard_insert_of_not_mem, encard_singleton] <;> aesop theorem Nat.encard_range (k : ℕ) : {i \| i < k}.encard = k := by convert encard_coe_eq_coe_finsetCard (Finset.range k) using 1 · rw [Finset.coe_range, Iio_def] rw [Finset.card_range] end SmallSets theorem Finite.eq_insert_of_subset_of_encard_eq_succ (hs : s.Finite) (h : s ⊆ t) (hst : t.encard = s.encard + 1) : ∃ a, t = insert a s := by rw [← encard_diff_add_encard_of_subset h, add_comm, WithTop.add_left_inj hs.encard_lt_top.ne, encard_eq_one] at hst obtain ⟨x, hx⟩ := hst; use x; rw [← diff_union_of_subset h, hx, singleton_union] theorem exists_subset_encard_eq {k : ℕ∞} (hk : k ≤ s.encard) : ∃ t, t ⊆ s ∧ t.encard = k := by revert hk refine ENat.nat_induction k (fun _ ↦ ⟨∅, empty_subset _, by simp⟩) (fun n IH hle ↦ ?_) ?_ · obtain ⟨t₀, ht₀s, ht₀⟩ := IH (le_trans (by simp) hle) simp only [Nat.cast_succ] at have hne : t₀ ≠ s := by rintro rfl; rw [ht₀, ← Nat.cast_one, ← Nat.cast_add, Nat.cast_le] at hle; simp at hle obtain ⟨x, hx⟩ := exists_of_ssubset (ht₀s.ssubset_of_ne hne) exact ⟨insert x t₀, insert_subset hx.1 ht₀s, by rw [encard_insert_of_not_mem hx.2, ht₀]⟩ simp only [top_le_iff, encard_eq_top_iff] exact fun _ hi ↦ ⟨s, Subset.rfl, hi⟩ theorem exists_superset_subset_encard_eq {k : ℕ∞} (hst : s ⊆ t) (hsk : s.encard ≤ k) (hkt : k ≤ t.encard) : ∃ r, s ⊆ r ∧ r ⊆ t ∧ r.encard = k := by obtain (hs \| hs) := eq_or_ne s.encard ⊤ · rw [hs, top_le_iff] at hsk; subst hsk; exact ⟨s, Subset.rfl, hst, hs⟩ obtain ⟨k, rfl⟩ := exists_add_of_le hsk obtain ⟨k', hk'⟩ := exists_add_of_le hkt have hk : k ≤ encard (t \ s) := by rw [← encard_diff_add_encard_of_subset hst, add_comm] at hkt exact WithTop.le_of_add_le_add_right hs hkt obtain ⟨r', hr', rfl⟩ := exists_subset_encard_eq hk refine ⟨s ∪ r', subset_union_left, union_subset hst (hr'.trans diff_subset), ?_⟩ rw [encard_union_eq (disjoint_of_subset_right hr' disjoint_sdiff_right)] section Function variable {s : Set α} {t : Set β} {f : α → β} theorem InjOn.encard_image (h : InjOn f s) : (f '' s).encard = s.encard := by rw [encard, ENat.card_image_of_injOn h, encard] theorem encard_congr (e : s ≃ t) : s.encard = t.encard := by rw [← encard_univ_coe, ← encard_univ_coe t, encard_univ, encard_univ, ENat.card_congr e] theorem _root_.Function.Injective.encard_image (hf : f.Injective) (s : Set α) : (f '' s).encard = s.encard := hf.injOn.encard_image theorem _root_.Function.Embedding.encard_le (e : s ↪ t) : s.encard ≤ t.encard := by rw [← encard_univ_coe, ← e.injective.encard_image, ← Subtype.coe_injective.encard_image] exact encard_mono (by simp) theorem encard_image_le (f : α → β) (s : Set α) : (f '' s).encard ≤ s.encard := by obtain (h \| h) := isEmpty_or_nonempty α · rw [s.eq_empty_of_isEmpty]; simp rw [← (f.invFunOn_injOn_image s).encard_image] apply encard_le_encard exact f.invFunOn_image_image_subset s theorem Finite.injOn_of_encard_image_eq (hs : s.Finite) (h : (f '' s).encard = s.encard) : InjOn f s := by obtain (h' \| hne) := isEmpty_or_nonempty α · rw [s.eq_empty_of_isEmpty]; simp rw [← (f.invFunOn_injOn_image s).encard_image] at h rw [injOn_iff_invFunOn_image_image_eq_self] exact hs.eq_of_subset_of_encard_le' (f.invFunOn_image_image_subset s) h.symm.le theorem encard_preimage_of_injective_subset_range (hf : f.Injective) (ht : t ⊆ range f) : (f ⁻¹' t).encard = t.encard := by rw [← hf.encard_image, image_preimage_eq_inter_range, inter_eq_self_of_subset_left ht] lemma encard_preimage_of_bijective (hf : f.Bijective) (t : Set β) : (f ⁻¹' t).encard = t.encard := encard_preimage_of_injective_subset_range hf.injective (by simp [hf.surjective.range_eq]) theorem encard_le_encard_of_injOn (hf : MapsTo f s t) (f_inj : InjOn f s) : s.encard ≤ t.encard := by rw [← f_inj.encard_image]; apply encard_le_encard; rintro _ ⟨x, hx, rfl⟩; exact hf hx theorem Finite.exists_injOn_of_encard_le [Nonempty β] {s : Set α} {t : Set β} (hs : s.Finite) (hle : s.encard ≤ t.encard) : ∃ (f : α → β), s ⊆ f ⁻¹' t ∧ InjOn f s := by classical obtain (rfl \| h \| ⟨a, has, -⟩) := s.eq_empty_or_encard_eq_top_or_encard_diff_singleton_lt · simp · exact (encard_ne_top_iff.mpr hs h).elim obtain ⟨b, hbt⟩ := encard_pos.1 ((encard_pos.2 ⟨_, has⟩).trans_le hle) have hle' : (s \ {a}).encard ≤ (t \ {b}).encard := by rwa [← WithTop.add_le_add_iff_right WithTop.one_ne_top, encard_diff_singleton_add_one has, encard_diff_singleton_add_one hbt] obtain ⟨f₀, hf₀s, hinj⟩ := exists_injOn_of_encard_le hs.diff hle' simp only [preimage_diff, subset_def, mem_diff, mem_singleton_iff, mem_preimage, and_imp] at hf₀s use Function.update f₀ a b rw [← insert_eq_of_mem has, ← insert_diff_singleton, injOn_insert (fun h ↦ h.2 rfl)] simp only [mem_diff, mem_singleton_iff, not_true, and_false, insert_diff_singleton, subset_def, mem_insert_iff, mem_preimage, ne_eq, Function.update_apply, forall_eq_or_imp, ite_true, and_imp, mem_image, ite_eq_left_iff, not_exists, not_and, not_forall, exists_prop, and_iff_right hbt] refine ⟨?_, ?_, fun x hxs hxa ↦ ⟨hxa, (hf₀s x hxs hxa).2⟩⟩ · rintro x hx; split_ifs with h · assumption · exact (hf₀s x hx h).1 exact InjOn.congr hinj (fun x ⟨_, hxa⟩ ↦ by rwa [Function.update_of_ne]) termination_by encard s theorem Finite.exists_bijOn_of_encard_eq [Nonempty β] (hs : s.Finite) (h : s.encard = t.encard) : ∃ (f : α → β), BijOn f s t := by obtain ⟨f, hf, hinj⟩ := hs.exists_injOn_of_encard_le h.le; use f convert hinj.bijOn_image rw [(hs.image f).eq_of_subset_of_encard_le (image_subset_iff.mpr hf) (h.symm.trans hinj.encard_image.symm).le] end Function section ncard open Nat /-- A tactic (for use in default params) that applies `Set.toFinite` to synthesize a `Set.Finite` term. -/ syntax "toFinite_tac" : tactic macro_rules \| `(tactic\| toFinite_tac) => `(tactic\| apply Set.toFinite) /-- A tactic useful for transferring proofs for `encard` to their corresponding `card` statements -/ syntax "to_encard_tac" : tactic macro_rules \| `(tactic\| to_encard_tac) => `(tactic\| simp only [← Nat.cast_le (α := ℕ∞), ← Nat.cast_inj (R := ℕ∞), Nat.cast_add, Nat.cast_one]) /-- The cardinality of `s : Set α` . Has the junk value `0` if `s` is infinite -/ noncomputable def ncard (s : Set α) : ℕ := ENat.toNat s.encard theorem ncard_def (s : Set α) : s.ncard = ENat.toNat s.encard := rfl theorem Finite.cast_ncard_eq (hs : s.Finite) : s.ncard = s.encard := by rwa [ncard, ENat.coe_toNat_eq_self, ne_eq, encard_eq_top_iff, Set.Infinite, not_not] lemma ncard_le_encard (s : Set α) : s.ncard ≤ s.encard := ENat.coe_toNat_le_self _ theorem Nat.card_coe_set_eq (s : Set α) : Nat.card s = s.ncard := by obtain (h \| h) := s.finite_or_infinite · have := h.fintype rw [ncard, h.encard_eq_coe_toFinset_card, Nat.card_eq_fintype_card, toFinite_toFinset, toFinset_card, ENat.toNat_coe] have := infinite_coe_iff.2 h rw [ncard, h.encard_eq, Nat.card_eq_zero_of_infinite, ENat.toNat_top] theorem ncard_eq_toFinset_card (s : Set α) (hs : s.Finite := by toFinite_tac) : s.ncard = hs.toFinset.card := by rw [← Nat.card_coe_set_eq, @Nat.card_eq_fintype_card _ hs.fintype, @Finite.card_toFinset _ _ hs.fintype hs] theorem ncard_eq_toFinset_card' (s : Set α) [Fintype s] : s.ncard = s.toFinset.card := by simp [← Nat.card_coe_set_eq, Nat.card_eq_fintype_card] lemma cast_ncard {s : Set α} (hs : s.Finite) : (s.ncard : Cardinal) = Cardinal.mk s := @Nat.cast_card _ hs theorem encard_le_coe_iff_finite_ncard_le {k : ℕ} : s.encard ≤ k ↔ s.Finite ∧ s.ncard ≤ k := by rw [encard_le_coe_iff, and_congr_right_iff] exact fun hfin ↦ ⟨fun ⟨n₀, hn₀, hle⟩ ↦ by rwa [ncard_def, hn₀, ENat.toNat_coe], fun h ↦ ⟨s.ncard, by rw [hfin.cast_ncard_eq], h⟩⟩ theorem Infinite.ncard (hs : s.Infinite) : s.ncard = 0 := by rw [← Nat.card_coe_set_eq, @Nat.card_eq_zero_of_infinite _ hs.to_subtype] @[gcongr] theorem ncard_le_ncard (hst : s ⊆ t) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ t.ncard := by rw [← Nat.cast_le (α := ℕ∞), ht.cast_ncard_eq, (ht.subset hst).cast_ncard_eq] exact encard_mono hst theorem ncard_mono [Finite α] : @Monotone (Set α) _ _ _ ncard := fun _ _ ↦ ncard_le_ncard @[simp] theorem ncard_eq_zero (hs : s.Finite := by toFinite_tac) : s.ncard = 0 ↔ s = ∅ := by rw [← Nat.cast_inj (R := ℕ∞), hs.cast_ncard_eq, Nat.cast_zero, encard_eq_zero] @[simp, norm_cast] theorem ncard_coe_Finset (s : Finset α) : (s : Set α).ncard = s.card := by rw [ncard_eq_toFinset_card _, Finset.finite_toSet_toFinset] theorem ncard_univ (α : Type) : (univ : Set α).ncard = Nat.card α := by rcases finite_or_infinite α with h \| h · have hft := Fintype.ofFinite α rw [ncard_eq_toFinset_card, Finite.toFinset_univ, Finset.card_univ, Nat.card_eq_fintype_card] rw [Nat.card_eq_zero_of_infinite, Infinite.ncard] exact infinite_univ @[simp] theorem ncard_empty (α : Type) : (∅ : Set α).ncard = 0 := by rw [ncard_eq_zero] theorem ncard_pos (hs : s.Finite := by toFinite_tac) : 0 < s.ncard ↔ s.Nonempty := by rw [pos_iff_ne_zero, Ne, ncard_eq_zero hs, nonempty_iff_ne_empty] protected alias ⟨_, Nonempty.ncard_pos⟩ := ncard_pos theorem ncard_ne_zero_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : s.ncard ≠ 0 := ((ncard_pos hs).mpr ⟨a, h⟩).ne.symm theorem finite_of_ncard_ne_zero (hs : s.ncard ≠ 0) : s.Finite := s.finite_or_infinite.elim id fun h ↦ (hs h.ncard).elim theorem finite_of_ncard_pos (hs : 0 < s.ncard) : s.Finite := finite_of_ncard_ne_zero hs.ne.symm theorem nonempty_of_ncard_ne_zero (hs : s.ncard ≠ 0) : s.Nonempty := by rw [nonempty_iff_ne_empty]; rintro rfl; simp at hs @[simp] theorem ncard_singleton (a : α) : ({a} : Set α).ncard = 1 := by simp [ncard] theorem ncard_singleton_inter (a : α) (s : Set α) : ({a} ∩ s).ncard ≤ 1 := by rw [← Nat.cast_le (α := ℕ∞), (toFinite _).cast_ncard_eq, Nat.cast_one] apply encard_singleton_inter @[simp] theorem ncard_prod : (s ×ˢ t).ncard = s.ncard * t.ncard := by simp [ncard, ENat.toNat_mul] @[simp] theorem ncard_powerset (s : Set α) (hs : s.Finite := by toFinite_tac) : (𝒫 s).ncard = 2 ^ s.ncard := by have h := Cardinal.mk_powerset s rw [← cast_ncard hs.powerset, ← cast_ncard hs] at h norm_cast at h section InsertErase @[simp] theorem ncard_insert_of_not_mem {a : α} (h : a ∉ s) (hs : s.Finite := by toFinite_tac) : (insert a s).ncard = s.ncard + 1 := by rw [← Nat.cast_inj (R := ℕ∞), (hs.insert a).cast_ncard_eq, Nat.cast_add, Nat.cast_one, hs.cast_ncard_eq, encard_insert_of_not_mem h] theorem ncard_insert_of_mem {a : α} (h : a ∈ s) : ncard (insert a s) = s.ncard := by rw [insert_eq_of_mem h] theorem ncard_insert_le (a : α) (s : Set α) : (insert a s).ncard ≤ s.ncard + 1 := by obtain hs \| hs := s.finite_or_infinite · to_encard_tac; rw [hs.cast_ncard_eq, (hs.insert _).cast_ncard_eq]; apply encard_insert_le rw [(hs.mono (subset_insert a s)).ncard] exact Nat.zero_le _ theorem ncard_insert_eq_ite {a : α} [Decidable (a ∈ s)] (hs : s.Finite := by toFinite_tac) : ncard (insert a s) = if a ∈ s then s.ncard else s.ncard + 1 := by by_cases h : a ∈ s · rw [ncard_insert_of_mem h, if_pos h] · rw [ncard_insert_of_not_mem h hs, if_neg h] theorem ncard_le_ncard_insert (a : α) (s : Set α) : s.ncard ≤ (insert a s).ncard := by classical refine s.finite_or_infinite.elim (fun h ↦ ?_) (fun h ↦ by (rw [h.ncard]; exact Nat.zero_le _)) rw [ncard_insert_eq_ite h]; split_ifs <;> simp @[simp] theorem ncard_pair {a b : α} (h : a ≠ b) : ({a, b} : Set α).ncard = 2 := by rw [ncard_insert_of_not_mem, ncard_singleton]; simpa @[simp] theorem ncard_diff_singleton_add_one {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : (s \ {a}).ncard + 1 = s.ncard := by to_encard_tac; rw [hs.cast_ncard_eq, hs.diff.cast_ncard_eq, encard_diff_singleton_add_one h] @[simp] theorem ncard_diff_singleton_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : (s \ {a}).ncard = s.ncard - 1 := eq_tsub_of_add_eq (ncard_diff_singleton_add_one h hs) theorem ncard_diff_singleton_lt_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : (s \ {a}).ncard < s.ncard := by rw [← ncard_diff_singleton_add_one h hs]; apply lt_add_one theorem ncard_diff_singleton_le (s : Set α) (a : α) : (s \ {a}).ncard ≤ s.ncard := by obtain hs \| hs := s.finite_or_infinite · apply ncard_le_ncard diff_subset hs convert zero_le (α := ℕ) _ exact (hs.diff (by simp : Set.Finite {a})).ncard theorem pred_ncard_le_ncard_diff_singleton (s : Set α) (a : α) : s.ncard - 1 ≤ (s \ {a}).ncard := by rcases s.finite_or_infinite with hs \| hs · by_cases h : a ∈ s · rw [ncard_diff_singleton_of_mem h hs] rw [diff_singleton_eq_self h] apply Nat.pred_le convert Nat.zero_le _ rw [hs.ncard] theorem ncard_exchange {a b : α} (ha : a ∉ s) (hb : b ∈ s) : (insert a (s \ {b})).ncard = s.ncard := congr_arg ENat.toNat <\| encard_exchange ha hb theorem ncard_exchange' {a b : α} (ha : a ∉ s) (hb : b ∈ s) : (insert a s \ {b}).ncard = s.ncard := by rw [← ncard_exchange ha hb, ← singleton_union, ← singleton_union, union_diff_distrib, @diff_singleton_eq_self _ b {a} fun h ↦ ha (by rwa [← mem_singleton_iff.mp h])] lemma odd_card_insert_iff {a : α} (ha : a ∉ s) (hs : s.Finite := by toFinite_tac) : Odd (insert a s).ncard ↔ Even s.ncard := by rw [ncard_insert_of_not_mem ha hs, Nat.odd_add] simp only [Nat.odd_add, ← Nat.not_even_iff_odd, Nat.not_even_one, iff_false, Decidable.not_not] lemma even_card_insert_iff {a : α} (ha : a ∉ s) (hs : s.Finite := by toFinite_tac) : Even (insert a s).ncard ↔ Odd s.ncard := by rw [ncard_insert_of_not_mem ha hs, Nat.even_add_one, Nat.not_even_iff_odd] end InsertErase variable {f : α → β} theorem ncard_image_le (hs : s.Finite := by toFinite_tac) : (f '' s).ncard ≤ s.ncard := by to_encard_tac; rw [hs.cast_ncard_eq, (hs.image _).cast_ncard_eq]; apply encard_image_le theorem ncard_image_of_injOn (H : Set.InjOn f s) : (f '' s).ncard = s.ncard := congr_arg ENat.toNat <\| H.encard_image theorem injOn_of_ncard_image_eq (h : (f '' s).ncard = s.ncard) (hs : s.Finite := by toFinite_tac) : Set.InjOn f s := by rw [← Nat.cast_inj (R := ℕ∞), hs.cast_ncard_eq, (hs.image _).cast_ncard_eq] at h exact hs.injOn_of_encard_image_eq h theorem ncard_image_iff (hs : s.Finite := by toFinite_tac) : (f '' s).ncard = s.ncard ↔ Set.InjOn f s := ⟨fun h ↦ injOn_of_ncard_image_eq h hs, ncard_image_of_injOn⟩ theorem ncard_image_of_injective (s : Set α) (H : f.Injective) : (f '' s).ncard = s.ncard := ncard_image_of_injOn fun _ _ _ _ h ↦ H h theorem ncard_preimage_of_injective_subset_range {s : Set β} (H : f.Injective) (hs : s ⊆ Set.range f) : (f ⁻¹' s).ncard = s.ncard := by rw [← ncard_image_of_injective _ H, image_preimage_eq_iff.mpr hs] theorem fiber_ncard_ne_zero_iff_mem_image {y : β} (hs : s.Finite := by toFinite_tac) : { x ∈ s \| f x = y }.ncard ≠ 0 ↔ y ∈ f '' s := by refine ⟨nonempty_of_ncard_ne_zero, ?_⟩ rintro ⟨z, hz, rfl⟩ exact @ncard_ne_zero_of_mem _ ({ x ∈ s \| f x = f z }) z (mem_sep hz rfl) (hs.subset (sep_subset _ _)) @[simp] theorem ncard_map (f : α ↪ β) : (f '' s).ncard = s.ncard := ncard_image_of_injective _ f.inj' @[simp] theorem ncard_subtype (P : α → Prop) (s : Set α) : { x : Subtype P \| (x : α) ∈ s }.ncard = (s ∩ setOf P).ncard := by convert (ncard_image_of_injective _ (@Subtype.coe_injective _ P)).symm ext x simp [← and_assoc, exists_eq_right] theorem ncard_inter_le_ncard_left (s t : Set α) (hs : s.Finite := by toFinite_tac) : (s ∩ t).ncard ≤ s.ncard := ncard_le_ncard inter_subset_left hs theorem ncard_inter_le_ncard_right (s t : Set α) (ht : t.Finite := by toFinite_tac) : (s ∩ t).ncard ≤ t.ncard := ncard_le_ncard inter_subset_right ht theorem eq_of_subset_of_ncard_le (h : s ⊆ t) (h' : t.ncard ≤ s.ncard) (ht : t.Finite := by toFinite_tac) : s = t := ht.eq_of_subset_of_encard_le' h (by rwa [← Nat.cast_le (α := ℕ∞), ht.cast_ncard_eq, (ht.subset h).cast_ncard_eq] at h') theorem subset_iff_eq_of_ncard_le (h : t.ncard ≤ s.ncard) (ht : t.Finite := by toFinite_tac) : s ⊆ t ↔ s = t := ⟨fun hst ↦ eq_of_subset_of_ncard_le hst h ht, Eq.subset'⟩ theorem map_eq_of_subset {f : α ↪ α} (h : f '' s ⊆ s) (hs : s.Finite := by toFinite_tac) : f '' s = s := eq_of_subset_of_ncard_le h (ncard_map _).ge hs theorem sep_of_ncard_eq {a : α} {P : α → Prop} (h : { x ∈ s \| P x }.ncard = s.ncard) (ha : a ∈ s) (hs : s.Finite := by toFinite_tac) : P a := sep_eq_self_iff_mem_true.mp (eq_of_subset_of_ncard_le (by simp) h.symm.le hs) _ ha theorem ncard_lt_ncard (h : s ⊂ t) (ht : t.Finite := by toFinite_tac) : s.ncard < t.ncard := by rw [← Nat.cast_lt (α := ℕ∞), ht.cast_ncard_eq, (ht.subset h.subset).cast_ncard_eq] exact (ht.subset h.subset).encard_lt_encard h theorem ncard_strictMono [Finite α] : @StrictMono (Set α) _ _ _ ncard := fun _ _ h ↦ ncard_lt_ncard h theorem ncard_eq_of_bijective {n : ℕ} (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.ncard = n := by let f' : Fin n → α := fun i ↦ f i.val i.is_lt suffices himage : s = f' '' Set.univ by rw [← Fintype.card_fin n, ← Nat.card_eq_fintype_card, ← Set.ncard_univ, himage] exact ncard_image_of_injOn <\| fun i _hi j _hj h ↦ Fin.ext <\| f_inj i.val j.val i.is_lt j.is_lt h ext x simp only [image_univ, mem_range] refine ⟨fun hx ↦ ?_, fun ⟨⟨i, hi⟩, hx⟩ ↦ hx ▸ hf' i hi⟩ obtain ⟨i, hi, rfl⟩ := hf x hx use ⟨i, hi⟩ theorem ncard_congr {t : Set β} (f : ∀ a ∈ s, β) (h₁ : ∀ a ha, f a ha ∈ t) (h₂ : ∀ a b ha hb, f a ha = f b hb → a = b) (h₃ : ∀ b ∈ t, ∃ a ha, f a ha = b) : s.ncard = t.ncard := by set f' : s → t := fun x ↦ ⟨f x.1 x.2, h₁ _ _⟩ have hbij : f'.Bijective := by constructor · rintro ⟨x, hx⟩ ⟨y, hy⟩ hxy simp only [f', Subtype.mk.injEq] at hxy ⊢ exact h₂ _ _ hx hy hxy rintro ⟨y, hy⟩ obtain ⟨a, ha, rfl⟩ := h₃ y hy simp only [Subtype.mk.injEq, Subtype.exists] exact ⟨_, ha, rfl⟩ simp_rw [← Nat.card_coe_set_eq] exact Nat.card_congr (Equiv.ofBijective f' hbij) theorem ncard_le_ncard_of_injOn {t : Set β} (f : α → β) (hf : ∀ a ∈ s, f a ∈ t) (f_inj : InjOn f s) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ t.ncard := by have hle := encard_le_encard_of_injOn hf f_inj to_encard_tac; rwa [ht.cast_ncard_eq, (ht.finite_of_encard_le hle).cast_ncard_eq] theorem exists_ne_map_eq_of_ncard_lt_of_maps_to {t : Set β} (hc : t.ncard < s.ncard) {f : α → β} (hf : ∀ a ∈ s, f a ∈ t) (ht : t.Finite := by toFinite_tac) : ∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ f x = f y := by by_contra h' simp only [Ne, exists_prop, not_exists, not_and, not_imp_not] at h' exact (ncard_le_ncard_of_injOn f hf h' ht).not_lt hc theorem le_ncard_of_inj_on_range {n : ℕ} (f : ℕ → α) (hf : ∀ i < n, f i ∈ s) (f_inj : ∀ i < n, ∀ j < n, f i = f j → i = j) (hs : s.Finite := by toFinite_tac) : n ≤ s.ncard := by rw [ncard_eq_toFinset_card _ hs] apply Finset.le_card_of_inj_on_range <;> simpa theorem surj_on_of_inj_on_of_ncard_le {t : Set β} (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.ncard ≤ s.ncard) (ht : t.Finite := by toFinite_tac) : ∀ b ∈ t, ∃ a ha, b = f a ha := by intro b hb set f' : s → t := fun x ↦ ⟨f x.1 x.2, hf _ _⟩ have finj : f'.Injective := by rintro ⟨x, hx⟩ ⟨y, hy⟩ hxy simp only [f', Subtype.mk.injEq] at hxy ⊢ apply hinj _ _ hx hy hxy have hft := ht.fintype have hft' := Fintype.ofInjective f' finj set f'' : ∀ a, a ∈ s.toFinset → β := fun a h ↦ f a (by simpa using h) convert @Finset.surj_on_of_inj_on_of_card_le _ _ _ t.toFinset f'' _ _ _ _ (by simpa) using 1 · simp [f''] · simp [f'', hf] · intros a₁ a₂ ha₁ ha₂ h rw [mem_toFinset] at ha₁ ha₂ exact hinj _ _ ha₁ ha₂ h rwa [← ncard_eq_toFinset_card', ← ncard_eq_toFinset_card'] theorem inj_on_of_surj_on_of_ncard_le {t : Set β} (f : ∀ a ∈ s, β) (hf : ∀ a ha, f a ha ∈ t) (hsurj : ∀ b ∈ t, ∃ a ha, f a ha = b) (hst : s.ncard ≤ t.ncard) ⦃a₁⦄ (ha₁ : a₁ ∈ s) ⦃a₂⦄ (ha₂ : a₂ ∈ s) (ha₁a₂ : f a₁ ha₁ = f a₂ ha₂) (hs : s.Finite := by toFinite_tac) : a₁ = a₂ := by classical set f' : s → t := fun x ↦ ⟨f x.1 x.2, hf _ _⟩ have hsurj : f'.Surjective := by rintro ⟨y, hy⟩ obtain ⟨a, ha, rfl⟩ := hsurj y hy simp only [Subtype.mk.injEq, Subtype.exists] exact ⟨_, ha, rfl⟩ haveI := hs.fintype haveI := Fintype.ofSurjective _ hsurj set f'' : ∀ a, a ∈ s.toFinset → β := fun a h ↦ f a (by simpa using h) exact @Finset.inj_on_of_surj_on_of_card_le _ _ _ t.toFinset f'' (fun a ha ↦ by { rw [mem_toFinset] at ha ⊢; exact hf a ha }) (by simpa) (by { rwa [← ncard_eq_toFinset_card', ← ncard_eq_toFinset_card'] }) a₁ (by simpa) a₂ (by simpa) (by simpa) @[simp] theorem ncard_coe {α : Type} (s : Set α) : Set.ncard (Set.univ : Set (Set.Elem s)) = s.ncard := Set.ncard_congr (fun a ha ↦ ↑a) (fun a ha ↦ a.prop) (by simp) (by simp) @[simp] lemma ncard_graphOn (s : Set α) (f : α → β) : (s.graphOn f).ncard = s.ncard := by rw [← ncard_image_of_injOn fst_injOn_graph, image_fst_graphOn] section Lattice theorem ncard_union_add_ncard_inter (s t : Set α) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s ∪ t).ncard + (s ∩ t).ncard = s.ncard + t.ncard := by to_encard_tac; rw [hs.cast_ncard_eq, ht.cast_ncard_eq, (hs.union ht).cast_ncard_eq, (hs.subset inter_subset_left).cast_ncard_eq, encard_union_add_encard_inter] theorem ncard_inter_add_ncard_union (s t : Set α) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s ∩ t).ncard + (s ∪ t).ncard = s.ncard + t.ncard := by rw [add_comm, ncard_union_add_ncard_inter _ _ hs ht] theorem ncard_union_le (s t : Set α) : (s ∪ t).ncard ≤ s.ncard + t.ncard := by obtain (h \| h) := (s ∪ t).finite_or_infinite · to_encard_tac rw [h.cast_ncard_eq, (h.subset subset_union_left).cast_ncard_eq, (h.subset subset_union_right).cast_ncard_eq] apply encard_union_le rw [h.ncard] apply zero_le theorem ncard_union_eq (h : Disjoint s t) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s ∪ t).ncard = s.ncard + t.ncard := by to_encard_tac rw [hs.cast_ncard_eq, ht.cast_ncard_eq, (hs.union ht).cast_ncard_eq, encard_union_eq h] theorem ncard_diff_add_ncard_of_subset (h : s ⊆ t) (ht : t.Finite := by toFinite_tac) : (t \ s).ncard + s.ncard = t.ncard := by to_encard_tac rw [ht.cast_ncard_eq, (ht.subset h).cast_ncard_eq, ht.diff.cast_ncard_eq, encard_diff_add_encard_of_subset h] theorem ncard_diff (hst : s ⊆ t) (hs : s.Finite := by toFinite_tac) : (t \ s).ncard = t.ncard - s.ncard := by obtain ht \| ht := t.finite_or_infinite · rw [← ncard_diff_add_ncard_of_subset hst ht, add_tsub_cancel_right] · rw [ht.ncard, Nat.zero_sub, (ht.diff hs).ncard] lemma cast_ncard_sdiff {R : Type} [AddGroupWithOne R] (hst : s ⊆ t) (ht : t.Finite) : ((t \ s).ncard : R) = t.ncard - s.ncard := by rw [ncard_diff hst (ht.subset hst), Nat.cast_sub (ncard_le_ncard hst ht)] theorem ncard_le_ncard_diff_add_ncard (s t : Set α) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ (s \ t).ncard + t.ncard := by rcases s.finite_or_infinite with hs \| hs · to_encard_tac rw [ht.cast_ncard_eq, hs.cast_ncard_eq, hs.diff.cast_ncard_eq] apply encard_le_encard_diff_add_encard convert Nat.zero_le _ rw [hs.ncard] theorem le_ncard_diff (s t : Set α) (hs : s.Finite := by toFinite_tac) : t.ncard - s.ncard ≤ (t \ s).ncard := tsub_le_iff_left.mpr (by rw [add_comm]; apply ncard_le_ncard_diff_add_ncard _ _ hs) theorem ncard_diff_add_ncard (s t : Set α) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s \ t).ncard + t.ncard = (s ∪ t).ncard := by rw [← ncard_union_eq disjoint_sdiff_left hs.diff ht, diff_union_self] theorem diff_nonempty_of_ncard_lt_ncard (h : s.ncard < t.ncard) (hs : s.Finite := by toFinite_tac) : (t \ s).Nonempty := by rw [Set.nonempty_iff_ne_empty, Ne, diff_eq_empty] exact fun h' ↦ h.not_le (ncard_le_ncard h' hs) theorem exists_mem_not_mem_of_ncard_lt_ncard (h : s.ncard < t.ncard) (hs : s.Finite := by toFinite_tac) : ∃ e, e ∈ t ∧ e ∉ s := diff_nonempty_of_ncard_lt_ncard h hs @[simp] theorem ncard_inter_add_ncard_diff_eq_ncard (s t : Set α) (hs : s.Finite := by toFinite_tac) : (s ∩ t).ncard + (s \ t).ncard = s.ncard := by rw [← ncard_union_eq (disjoint_of_subset_left inter_subset_right disjoint_sdiff_right) (hs.inter_of_left _) hs.diff, union_comm, diff_union_inter] theorem ncard_eq_ncard_iff_ncard_diff_eq_ncard_diff (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : s.ncard = t.ncard ↔ (s \ t).ncard = (t \ s).ncard := by rw [← ncard_inter_add_ncard_diff_eq_ncard s t hs, ← ncard_inter_add_ncard_diff_eq_ncard t s ht, inter_comm, add_right_inj] theorem ncard_le_ncard_iff_ncard_diff_le_ncard_diff (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ t.ncard ↔ (s \ t).ncard ≤ (t \ s).ncard := by rw [← ncard_inter_add_ncard_diff_eq_ncard s t hs, ← ncard_inter_add_ncard_diff_eq_ncard t s ht, inter_comm, add_le_add_iff_left] theorem ncard_lt_ncard_iff_ncard_diff_lt_ncard_diff (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : s.ncard < t.ncard ↔ (s \ t).ncard < (t \ s).ncard := by rw [← ncard_inter_add_ncard_diff_eq_ncard s t hs, ← ncard_inter_add_ncard_diff_eq_ncard t s ht, inter_comm, add_lt_add_iff_left] theorem ncard_add_ncard_compl (s : Set α) (hs : s.Finite := by toFinite_tac) (hsc : sᶜ.Finite := by toFinite_tac) : s.ncard + sᶜ.ncard = Nat.card α := by rw [← ncard_univ, ← ncard_union_eq (@disjoint_compl_right _ _ s) hs hsc, union_compl_self] theorem eq_univ_iff_ncard [Finite α] (s : Set α) : s = univ ↔ ncard s = Nat.card α := by rw [← compl_empty_iff, ← ncard_eq_zero, ← ncard_add_ncard_compl s, left_eq_add] lemma even_ncard_compl_iff [Finite α] (heven : Even (Nat.card α)) (s : Set α) : Even sᶜ.ncard ↔ Even s.ncard := by simp [compl_eq_univ_diff, ncard_diff (subset_univ _ : s ⊆ Set.univ), Nat.even_sub (ncard_le_ncard (subset_univ _ : s ⊆ Set.univ)), (ncard_univ _).symm ▸ heven] lemma odd_ncard_compl_iff [Finite α] (heven : Even (Nat.card α)) (s : Set α) : Odd sᶜ.ncard ↔ Odd s.ncard := by rw [← Nat.not_even_iff_odd, even_ncard_compl_iff heven, Nat.not_even_iff_odd] end Lattice /-- Given a subset `s` of a set `t`, of sizes at most and at least `n` respectively, there exists a set `u` of size `n` which is both a superset of `s` and a subset of `t`. -/ lemma exists_subsuperset_card_eq {n : ℕ} (hst : s ⊆ t) (hsn : s.ncard ≤ n) (hnt : n ≤ t.ncard) : ∃ u, s ⊆ u ∧ u ⊆ t ∧ u.ncard = n := by obtain ht \| ht := t.infinite_or_finite · rw [ht.ncard, Nat.le_zero, ← ht.ncard] at hnt exact ⟨t, hst, Subset.rfl, hnt.symm⟩ lift s to Finset α using ht.subset hst lift t to Finset α using ht obtain ⟨u, hsu, hut, hu⟩ := Finset.exists_subsuperset_card_eq (mod_cast hst) (by simpa using hsn) (mod_cast hnt) exact ⟨u, mod_cast hsu, mod_cast hut, mod_cast hu⟩ /-- We can shrink a set to any smaller size. -/ lemma exists_subset_card_eq {n : ℕ} (hns : n ≤ s.ncard) : ∃ t ⊆ s, t.ncard = n := by simpa using exists_subsuperset_card_eq s.empty_subset (by simp) hns theorem Infinite.exists_subset_ncard_eq {s : Set α} (hs : s.Infinite) (k : ℕ) : ∃ t, t ⊆ s ∧ t.Finite ∧ t.ncard = k := by have := hs.to_subtype obtain ⟨t', -, rfl⟩ := @Infinite.exists_subset_card_eq s univ infinite_univ k refine ⟨Subtype.val '' (t' : Set s), by simp, Finite.image _ (by simp), ?_⟩ rw [ncard_image_of_injective _ Subtype.coe_injective] simp theorem Infinite.exists_superset_ncard_eq {s t : Set α} (ht : t.Infinite) (hst : s ⊆ t)	(hs : s.Finite) {k : ℕ} (hsk : s.ncard ≤ k) : ∃ s', s ⊆ s' ∧ s' ⊆ t ∧ s'.ncard = k := by obtain ⟨s₁, hs₁, hs₁fin, hs₁card⟩ := (ht.diff hs).exists_subset_ncard_eq (k - s.ncard) refine ⟨s ∪ s₁, subset_union_left, union_subset hst (hs₁.trans diff_subset), ?_⟩ rwa [ncard_union_eq (disjoint_of_subset_right hs₁ disjoint_sdiff_right) hs hs₁fin, hs₁card, add_tsub_cancel_of_le] theorem exists_subset_or_subset_of_two_mul_lt_ncard {n : ℕ} (hst : 2 * n < (s ∪ t).ncard) :	Mathlib/Data/Set/Card.lean	977	983
/- Copyright (c) 2020 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn, Sébastien Gouëzel -/ import Mathlib.MeasureTheory.Measure.Haar.InnerProductSpace import Mathlib.MeasureTheory.Measure.Lebesgue.EqHaar import Mathlib.MeasureTheory.Integral.Bochner.Set /-! # Basic properties of Haar measures on real vector spaces -/ noncomputable section open Function Filter Inv MeasureTheory.Measure Module Set TopologicalSpace open scoped NNReal ENNReal Pointwise Topology namespace MeasureTheory namespace Measure /- The instance `MeasureTheory.Measure.IsAddHaarMeasure.noAtoms` applies in particular to show that an additive Haar measure on a nontrivial finite-dimensional real vector space has no atom. -/ example {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [Nontrivial E] [FiniteDimensional ℝ E] [MeasurableSpace E] [BorelSpace E] (μ : Measure E) [IsAddHaarMeasure μ] : NoAtoms μ := by infer_instance section LinearEquiv variable {𝕜 G H : Type} [MeasurableSpace G] [MeasurableSpace H] [NontriviallyNormedField 𝕜] [TopologicalSpace G] [TopologicalSpace H] [AddCommGroup G] [AddCommGroup H] [IsTopologicalAddGroup G] [IsTopologicalAddGroup H] [Module 𝕜 G] [Module 𝕜 H] (μ : Measure G) [IsAddHaarMeasure μ] [BorelSpace G] [BorelSpace H] [CompleteSpace 𝕜] [T2Space G] [FiniteDimensional 𝕜 G] [ContinuousSMul 𝕜 G] [ContinuousSMul 𝕜 H] [T2Space H] instance MapLinearEquiv.isAddHaarMeasure (e : G ≃ₗ[𝕜] H) : IsAddHaarMeasure (μ.map e) := e.toContinuousLinearEquiv.isAddHaarMeasure_map _ end LinearEquiv section SeminormedGroup variable {G H : Type} [MeasurableSpace G] [Group G] [TopologicalSpace G] [IsTopologicalGroup G] [BorelSpace G] [LocallyCompactSpace G] [MeasurableSpace H] [SeminormedGroup H] [OpensMeasurableSpace H] -- TODO: This could be streamlined by proving that inner regular measures always exist open Metric Bornology in @[to_additive] lemma _root_.MonoidHom.exists_nhds_isBounded (f : G → H) (hf : Measurable f) (x : G) : ∃ s ∈ 𝓝 x, IsBounded (f '' s) := by let K : PositiveCompacts G := Classical.arbitrary _ obtain ⟨n, hn⟩ : ∃ n : ℕ, 0 < haar (interior K ∩ f ⁻¹' ball 1 n) := by by_contra! simp_rw [nonpos_iff_eq_zero, ← measure_iUnion_null_iff, ← inter_iUnion, ← preimage_iUnion, iUnion_ball_nat, preimage_univ, inter_univ] at this exact this.not_gt <\| isOpen_interior.measure_pos _ K.interior_nonempty rw [← one_mul x, ← op_smul_eq_mul] refine ⟨_, smul_mem_nhds_smul _ <\| div_mem_nhds_one_of_haar_pos_ne_top haar _ (isOpen_interior.measurableSet.inter <\| hf measurableSet_ball) hn <\| mt (measure_mono_top <\| inter_subset_left.trans interior_subset) K.isCompact.measure_ne_top, ?_⟩ have : Bornology.IsBounded (f '' (interior K ∩ f ⁻¹' ball 1 n)) := isBounded_ball.subset <\| (image_mono inter_subset_right).trans <\| image_preimage_subset _ _ rw [image_op_smul_distrib, image_div] exact (this.div this).smul _ end SeminormedGroup /-- A Borel-measurable group hom from a locally compact normed group to a real normed space is continuous. -/ lemma AddMonoidHom.continuous_of_measurable {G H : Type} [SeminormedAddCommGroup G] [MeasurableSpace G] [BorelSpace G] [LocallyCompactSpace G] [SeminormedAddCommGroup H] [MeasurableSpace H] [OpensMeasurableSpace H] [NormedSpace ℝ H] (f : G →+ H) (hf : Measurable f) : Continuous f := let ⟨_s, hs, hbdd⟩ := f.exists_nhds_isBounded hf 0; f.continuous_of_isBounded_nhds_zero hs hbdd variable {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [MeasurableSpace E] [BorelSpace E] [FiniteDimensional ℝ E] (μ : Measure E) [IsAddHaarMeasure μ] {F : Type} [NormedAddCommGroup F] [NormedSpace ℝ F] /-- The integral of `f (R • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/ theorem integral_comp_smul (f : E → F) (R : ℝ) : ∫ x, f (R • x) ∂μ = \|(R ^ finrank ℝ E)⁻¹\| • ∫ x, f x ∂μ := by by_cases hF : CompleteSpace F; swap · simp [integral, hF] rcases eq_or_ne R 0 with (rfl \| hR) · simp only [zero_smul, integral_const] rcases Nat.eq_zero_or_pos (finrank ℝ E) with (hE \| hE) · have : Subsingleton E := finrank_zero_iff.1 hE have : f = fun _ => f 0 := by ext x; rw [Subsingleton.elim x 0] conv_rhs => rw [this] simp only [hE, pow_zero, inv_one, abs_one, one_smul, integral_const] · have : Nontrivial E := finrank_pos_iff.1 hE simp [zero_pow hE.ne', measure_univ_of_isAddLeftInvariant, measureReal_def] · calc (∫ x, f (R • x) ∂μ) = ∫ y, f y ∂Measure.map (fun x => R • x) μ := (integral_map_equiv (Homeomorph.smul (isUnit_iff_ne_zero.2 hR).unit).toMeasurableEquiv f).symm _ = \|(R ^ finrank ℝ E)⁻¹\| • ∫ x, f x ∂μ := by simp only [map_addHaar_smul μ hR, integral_smul_measure, ENNReal.toReal_ofReal, abs_nonneg] /-- The integral of `f (R • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/ theorem integral_comp_smul_of_nonneg (f : E → F) (R : ℝ) {hR : 0 ≤ R} : ∫ x, f (R • x) ∂μ = (R ^ finrank ℝ E)⁻¹ • ∫ x, f x ∂μ := by rw [integral_comp_smul μ f R, abs_of_nonneg (inv_nonneg.2 (pow_nonneg hR _))] /-- The integral of `f (R⁻¹ • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/ theorem integral_comp_inv_smul (f : E → F) (R : ℝ) : ∫ x, f (R⁻¹ • x) ∂μ = \|R ^ finrank ℝ E\| • ∫ x, f x ∂μ := by rw [integral_comp_smul μ f R⁻¹, inv_pow, inv_inv] /-- The integral of `f (R⁻¹ • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/ theorem integral_comp_inv_smul_of_nonneg (f : E → F) {R : ℝ} (hR : 0 ≤ R) : ∫ x, f (R⁻¹ • x) ∂μ = R ^ finrank ℝ E • ∫ x, f x ∂μ := by rw [integral_comp_inv_smul μ f R, abs_of_nonneg (pow_nonneg hR _)] theorem setIntegral_comp_smul (f : E → F) {R : ℝ} (s : Set E) (hR : R ≠ 0) : ∫ x in s, f (R • x) ∂μ = \|(R ^ finrank ℝ E)⁻¹\| • ∫ x in R • s, f x ∂μ := by let e : E ≃ᵐ E := (Homeomorph.smul (Units.mk0 R hR)).toMeasurableEquiv calc ∫ x in s, f (R • x) ∂μ = ∫ x in e ⁻¹' (e.symm ⁻¹' s), f (e x) ∂μ := by simp [← preimage_comp]; rfl _ = ∫ y in e.symm ⁻¹' s, f y ∂map (fun x ↦ R • x) μ := (setIntegral_map_equiv _ _ _).symm _ = \|(R ^ finrank ℝ E)⁻¹\| • ∫ y in e.symm ⁻¹' s, f y ∂μ := by simp [map_addHaar_smul μ hR, integral_smul_measure, ENNReal.toReal_ofReal, abs_nonneg] _ = \|(R ^ finrank ℝ E)⁻¹\| • ∫ x in R • s, f x ∂μ := by congr ext y rw [mem_smul_set_iff_inv_smul_mem₀ hR] rfl theorem setIntegral_comp_smul_of_pos (f : E → F) {R : ℝ} (s : Set E) (hR : 0 < R) : ∫ x in s, f (R • x) ∂μ = (R ^ finrank ℝ E)⁻¹ • ∫ x in R • s, f x ∂μ := by rw [setIntegral_comp_smul μ f s hR.ne', abs_of_nonneg (inv_nonneg.2 (pow_nonneg hR.le _))] theorem integral_comp_mul_left (g : ℝ → F) (a : ℝ) : (∫ x : ℝ, g (a x)) = \|a⁻¹\| • ∫ y : ℝ, g y := by simp_rw [← smul_eq_mul, Measure.integral_comp_smul, Module.finrank_self, pow_one] theorem integral_comp_inv_mul_left (g : ℝ → F) (a : ℝ) : (∫ x : ℝ, g (a⁻¹ * x)) = \|a\| • ∫ y : ℝ, g y := by simp_rw [← smul_eq_mul, Measure.integral_comp_inv_smul, Module.finrank_self, pow_one] theorem integral_comp_mul_right (g : ℝ → F) (a : ℝ) : (∫ x : ℝ, g (x * a)) = \|a⁻¹\| • ∫ y : ℝ, g y := by simpa only [mul_comm] using integral_comp_mul_left g a theorem integral_comp_inv_mul_right (g : ℝ → F) (a : ℝ) : (∫ x : ℝ, g (x * a⁻¹)) = \|a\| • ∫ y : ℝ, g y := by simpa only [mul_comm] using integral_comp_inv_mul_left g a theorem integral_comp_div (g : ℝ → F) (a : ℝ) : (∫ x : ℝ, g (x / a)) = \|a\| • ∫ y : ℝ, g y := integral_comp_inv_mul_right g a end Measure variable {F : Type} [NormedAddCommGroup F] theorem integrable_comp_smul_iff {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [MeasurableSpace E] [BorelSpace E] [FiniteDimensional ℝ E] (μ : Measure E) [IsAddHaarMeasure μ] (f : E → F) {R : ℝ} (hR : R ≠ 0) : Integrable (fun x => f (R • x)) μ ↔ Integrable f μ := by -- reduce to one-way implication suffices ∀ {g : E → F} (_ : Integrable g μ) {S : ℝ} (_ : S ≠ 0), Integrable (fun x => g (S • x)) μ by refine ⟨fun hf => ?_, fun hf => this hf hR⟩ convert this hf (inv_ne_zero hR) rw [← mul_smul, mul_inv_cancel₀ hR, one_smul] -- now prove intro g hg S hS let t := ((Homeomorph.smul (isUnit_iff_ne_zero.2 hS).unit).toMeasurableEquiv : E ≃ᵐ E) refine (integrable_map_equiv t g).mp (?_ : Integrable g (map (S • ·) μ)) rwa [map_addHaar_smul μ hS, integrable_smul_measure _ ENNReal.ofReal_ne_top] simpa only [Ne, ENNReal.ofReal_eq_zero, not_le, abs_pos] using inv_ne_zero (pow_ne_zero _ hS) theorem Integrable.comp_smul {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [MeasurableSpace E] [BorelSpace E] [FiniteDimensional ℝ E] {μ : Measure E} [IsAddHaarMeasure μ] {f : E → F} (hf : Integrable f μ) {R : ℝ} (hR : R ≠ 0) : Integrable (fun x => f (R • x)) μ := (integrable_comp_smul_iff μ f hR).2 hf theorem integrable_comp_mul_left_iff (g : ℝ → F) {R : ℝ} (hR : R ≠ 0) : (Integrable fun x => g (R x)) ↔ Integrable g := by simpa only [smul_eq_mul] using integrable_comp_smul_iff volume g hR theorem Integrable.comp_mul_left' {g : ℝ → F} (hg : Integrable g) {R : ℝ} (hR : R ≠ 0) :	Integrable fun x => g (R * x) := (integrable_comp_mul_left_iff g hR).2 hg	Mathlib/MeasureTheory/Measure/Haar/NormedSpace.lean	196	198
/- 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]	Mathlib/Algebra/Algebra/Operations.lean	61	62
/- Copyright (c) 2022 Tian Chen. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Tian Chen, Mantas Bakšys -/ import Mathlib.Algebra.GeomSum import Mathlib.Algebra.Order.Ring.Basic import Mathlib.Algebra.Ring.Int.Parity import Mathlib.Data.Nat.Choose.Sum import Mathlib.Data.Nat.Prime.Int import Mathlib.NumberTheory.Padics.PadicVal.Defs import Mathlib.RingTheory.Ideal.Quotient.Defs import Mathlib.RingTheory.Ideal.Span /-! # Multiplicity in Number Theory This file contains results in number theory relating to multiplicity. ## Main statements * `multiplicity.Int.pow_sub_pow` is the lifting the exponent lemma for odd primes. We also prove several variations of the lemma. ## References * [Wikipedia, Lifting-the-exponent lemma] (https://en.wikipedia.org/wiki/Lifting-the-exponent_lemma) -/ open Ideal Ideal.Quotient Finset variable {R : Type} {n : ℕ} section CommRing variable [CommRing R] {a b x y : R} theorem dvd_geom_sum₂_iff_of_dvd_sub {x y p : R} (h : p ∣ x - y) : (p ∣ ∑ i ∈ range n, x ^ i y ^ (n - 1 - i)) ↔ p ∣ n * y ^ (n - 1) := by rw [← mem_span_singleton, ← Ideal.Quotient.eq] at h simp only [← mem_span_singleton, ← eq_zero_iff_mem, RingHom.map_geom_sum₂, h, geom_sum₂_self, map_mul, map_pow, map_natCast] theorem dvd_geom_sum₂_iff_of_dvd_sub' {x y p : R} (h : p ∣ x - y) : (p ∣ ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) ↔ p ∣ n * x ^ (n - 1) := by rw [geom_sum₂_comm, dvd_geom_sum₂_iff_of_dvd_sub]; simpa using h.neg_right theorem dvd_geom_sum₂_self {x y : R} (h : ↑n ∣ x - y) : ↑n ∣ ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) := (dvd_geom_sum₂_iff_of_dvd_sub h).mpr (dvd_mul_right _ _) theorem sq_dvd_add_pow_sub_sub (p x : R) (n : ℕ) : p ^ 2 ∣ (x + p) ^ n - x ^ (n - 1) * p * n - x ^ n := by	rcases n with - \| n · simp only [pow_zero, Nat.cast_zero, sub_zero, sub_self, dvd_zero, mul_zero] · simp only [Nat.succ_sub_succ_eq_sub, tsub_zero, Nat.cast_succ, add_pow, Finset.sum_range_succ, Nat.choose_self, Nat.succ_sub _, tsub_self, pow_one, Nat.choose_succ_self_right, pow_zero, mul_one, Nat.cast_zero, zero_add, Nat.succ_eq_add_one, add_tsub_cancel_left] suffices p ^ 2 ∣ ∑ i ∈ range n, x ^ i * p ^ (n + 1 - i) * ↑((n + 1).choose i) by convert this; abel apply Finset.dvd_sum intro y hy calc p ^ 2 ∣ p ^ (n + 1 - y) := pow_dvd_pow p (le_tsub_of_add_le_left (by linarith [Finset.mem_range.mp hy])) _ ∣ x ^ y * p ^ (n + 1 - y) * ↑((n + 1).choose y) := dvd_mul_of_dvd_left (dvd_mul_left _ _) _ theorem not_dvd_geom_sum₂ {p : R} (hp : Prime p) (hxy : p ∣ x - y) (hx : ¬p ∣ x) (hn : ¬p ∣ n) :	Mathlib/NumberTheory/Multiplicity.lean	56	71
/- Copyright (c) 2020 Jean Lo. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jean Lo -/ import Mathlib.Logic.Function.Iterate import Mathlib.Topology.Algebra.Monoid import Mathlib.Topology.Algebra.Group.Defs /-! # Flows and invariant sets This file defines a flow on a topological space `α` by a topological monoid `τ` as a continuous monoid-action of `τ` on `α`. Anticipating the cases where `τ` is one of `ℕ`, `ℤ`, `ℝ⁺`, or `ℝ`, we use additive notation for the monoids, though the definition does not require commutativity. A subset `s` of `α` is invariant under a family of maps `ϕₜ : α → α` if `ϕₜ s ⊆ s` for all `t`. In many cases `ϕ` will be a flow on `α`. For the cases where `ϕ` is a flow by an ordered (additive, commutative) monoid, we additionally define forward invariance, where `t` ranges over those elements which are nonnegative. Additionally, we define such constructions as the restriction of a flow onto an invariant subset, and the time-reversal of a flow by a group. -/ open Set Function Filter /-! ### Invariant sets -/ section Invariant variable {τ : Type} {α : Type} /-- A set `s ⊆ α` is invariant under `ϕ : τ → α → α` if `ϕ t s ⊆ s` for all `t` in `τ`. -/ def IsInvariant (ϕ : τ → α → α) (s : Set α) : Prop := ∀ t, MapsTo (ϕ t) s s variable (ϕ : τ → α → α) (s : Set α) theorem isInvariant_iff_image : IsInvariant ϕ s ↔ ∀ t, ϕ t '' s ⊆ s := by simp_rw [IsInvariant, mapsTo'] /-- A set `s ⊆ α` is forward-invariant under `ϕ : τ → α → α` if `ϕ t s ⊆ s` for all `t ≥ 0`. -/ def IsFwInvariant [Preorder τ] [Zero τ] (ϕ : τ → α → α) (s : Set α) : Prop := ∀ ⦃t⦄, 0 ≤ t → MapsTo (ϕ t) s s theorem IsInvariant.isFwInvariant [Preorder τ] [Zero τ] {ϕ : τ → α → α} {s : Set α} (h : IsInvariant ϕ s) : IsFwInvariant ϕ s := fun t _ht => h t /-- If `τ` is a `CanonicallyOrderedAdd` monoid (e.g., `ℕ` or `ℝ≥0`), then the notions `IsFwInvariant` and `IsInvariant` are equivalent. -/ theorem IsFwInvariant.isInvariant [AddMonoid τ] [PartialOrder τ] [CanonicallyOrderedAdd τ] {ϕ : τ → α → α} {s : Set α} (h : IsFwInvariant ϕ s) : IsInvariant ϕ s := fun t => h (zero_le t) /-- If `τ` is a `CanonicallyOrderedAdd` monoid (e.g., `ℕ` or `ℝ≥0`), then the notions `IsFwInvariant` and `IsInvariant` are equivalent. -/ theorem isFwInvariant_iff_isInvariant [AddMonoid τ] [PartialOrder τ] [CanonicallyOrderedAdd τ] {ϕ : τ → α → α} {s : Set α} : IsFwInvariant ϕ s ↔ IsInvariant ϕ s := ⟨IsFwInvariant.isInvariant, IsInvariant.isFwInvariant⟩ end Invariant /-! ### Flows -/ /-- A flow on a topological space `α` by an additive topological monoid `τ` is a continuous monoid action of `τ` on `α`. -/ structure Flow (τ : Type) [TopologicalSpace τ] [AddMonoid τ] [ContinuousAdd τ] (α : Type) [TopologicalSpace α] where /-- The map `τ → α → α` underlying a flow of `τ` on `α`. -/ toFun : τ → α → α cont' : Continuous (uncurry toFun) map_add' : ∀ t₁ t₂ x, toFun (t₁ + t₂) x = toFun t₁ (toFun t₂ x) map_zero' : ∀ x, toFun 0 x = x namespace Flow variable {τ : Type} [AddMonoid τ] [TopologicalSpace τ] [ContinuousAdd τ] {α : Type} [TopologicalSpace α] (ϕ : Flow τ α) instance : Inhabited (Flow τ α) := ⟨{ toFun := fun _ x => x cont' := continuous_snd map_add' := fun _ _ _ => rfl map_zero' := fun _ => rfl }⟩ instance : CoeFun (Flow τ α) fun _ => τ → α → α := ⟨Flow.toFun⟩ @[ext] theorem ext : ∀ {ϕ₁ ϕ₂ : Flow τ α}, (∀ t x, ϕ₁ t x = ϕ₂ t x) → ϕ₁ = ϕ₂ \| ⟨f₁, _, _, _⟩, ⟨f₂, _, _, _⟩, h => by congr funext exact h _ _ @[continuity, fun_prop]	protected theorem continuous {β : Type*} [TopologicalSpace β] {t : β → τ} (ht : Continuous t) {f : β → α} (hf : Continuous f) : Continuous fun x => ϕ (t x) (f x) := ϕ.cont'.comp (ht.prodMk hf) alias _root_.Continuous.flow := Flow.continuous	Mathlib/Dynamics/Flow.lean	108	112
/- 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.Data.Ordmap.Invariants /-! # Verification of `Ordnode` This file uses the invariants defined in `Mathlib.Data.Ordmap.Invariants` to construct `Ordset α`, a wrapper around `Ordnode α` which includes the correctness invariant of the type. It exposes parallel operations like `insert` as functions on `Ordset` that do the same thing but bundle the correctness proofs. The advantage is that it is possible to, for example, prove that the result of `find` on `insert` will actually find the element, while `Ordnode` cannot guarantee this if the input tree did not satisfy the type invariants. ## Main definitions * `Ordnode.Valid`: The validity predicate for an `Ordnode` subtree. * `Ordset α`: A well formed set of values of type `α`. ## Implementation notes Because the `Ordnode` file was ported from Haskell, the correctness invariants of some of the functions have not been spelled out, and some theorems like `Ordnode.Valid'.balanceL_aux` show very intricate assumptions on the sizes, which may need to be revised if it turns out some operations violate these assumptions, because there is a decent amount of slop in the actual data structure invariants, so the theorem will go through with multiple choices of assumption. -/ variable {α : Type} namespace Ordnode section Valid variable [Preorder α] /-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are correct, the tree is balanced, and the elements of the tree are organized according to the ordering. This version of `Valid` also puts all elements in the tree in the interval `(lo, hi)`. -/ structure Valid' (lo : WithBot α) (t : Ordnode α) (hi : WithTop α) : Prop where ord : t.Bounded lo hi sz : t.Sized bal : t.Balanced /-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are correct, the tree is balanced, and the elements of the tree are organized according to the ordering. -/ def Valid (t : Ordnode α) : Prop := Valid' ⊥ t ⊤ theorem Valid'.mono_left {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' y t o) : Valid' x t o := ⟨h.1.mono_left xy, h.2, h.3⟩ theorem Valid'.mono_right {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' o t x) : Valid' o t y := ⟨h.1.mono_right xy, h.2, h.3⟩ theorem Valid'.trans_left {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (h : Bounded t₁ o₁ x) (H : Valid' x t₂ o₂) : Valid' o₁ t₂ o₂ := ⟨h.trans_left H.1, H.2, H.3⟩ theorem Valid'.trans_right {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t₁ x) (h : Bounded t₂ x o₂) : Valid' o₁ t₁ o₂ := ⟨H.1.trans_right h, H.2, H.3⟩ theorem Valid'.of_lt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil o₁ x) (h₂ : All (· < x) t) : Valid' o₁ t x := ⟨H.1.of_lt h₁ h₂, H.2, H.3⟩ theorem Valid'.of_gt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil x o₂) (h₂ : All (· > x) t) : Valid' x t o₂ := ⟨H.1.of_gt h₁ h₂, H.2, H.3⟩ theorem Valid'.valid {t o₁ o₂} (h : @Valid' α _ o₁ t o₂) : Valid t := ⟨h.1.weak, h.2, h.3⟩ theorem valid'_nil {o₁ o₂} (h : Bounded nil o₁ o₂) : Valid' o₁ (@nil α) o₂ := ⟨h, ⟨⟩, ⟨⟩⟩ theorem valid_nil : Valid (@nil α) := valid'_nil ⟨⟩ theorem Valid'.node {s l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : BalancedSz (size l) (size r)) (hs : s = size l + size r + 1) : Valid' o₁ (@node α s l x r) o₂ := ⟨⟨hl.1, hr.1⟩, ⟨hs, hl.2, hr.2⟩, ⟨H, hl.3, hr.3⟩⟩ theorem Valid'.dual : ∀ {t : Ordnode α} {o₁ o₂}, Valid' o₁ t o₂ → @Valid' αᵒᵈ _ o₂ (dual t) o₁ \| .nil, _, _, h => valid'_nil h.1.dual \| .node _ l _ r, _, _, ⟨⟨ol, Or⟩, ⟨rfl, sl, sr⟩, ⟨b, bl, br⟩⟩ => let ⟨ol', sl', bl'⟩ := Valid'.dual ⟨ol, sl, bl⟩ let ⟨or', sr', br'⟩ := Valid'.dual ⟨Or, sr, br⟩ ⟨⟨or', ol'⟩, ⟨by simp [size_dual, add_comm], sr', sl'⟩, ⟨by rw [size_dual, size_dual]; exact b.symm, br', bl'⟩⟩ theorem Valid'.dual_iff {t : Ordnode α} {o₁ o₂} : Valid' o₁ t o₂ ↔ @Valid' αᵒᵈ _ o₂ (.dual t) o₁ := ⟨Valid'.dual, fun h => by have := Valid'.dual h; rwa [dual_dual, OrderDual.Preorder.dual_dual] at this⟩ theorem Valid.dual {t : Ordnode α} : Valid t → @Valid αᵒᵈ _ (.dual t) := Valid'.dual theorem Valid.dual_iff {t : Ordnode α} : Valid t ↔ @Valid αᵒᵈ _ (.dual t) := Valid'.dual_iff theorem Valid'.left {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' o₁ l x := ⟨H.1.1, H.2.2.1, H.3.2.1⟩ theorem Valid'.right {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' x r o₂ := ⟨H.1.2, H.2.2.2, H.3.2.2⟩ nonrec theorem Valid.left {s l x r} (H : Valid (@node α s l x r)) : Valid l := H.left.valid nonrec theorem Valid.right {s l x r} (H : Valid (@node α s l x r)) : Valid r := H.right.valid theorem Valid.size_eq {s l x r} (H : Valid (@node α s l x r)) : size (@node α s l x r) = size l + size r + 1 := H.2.1 theorem Valid'.node' {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : BalancedSz (size l) (size r)) : Valid' o₁ (@node' α l x r) o₂ := hl.node hr H rfl theorem valid'_singleton {x : α} {o₁ o₂} (h₁ : Bounded nil o₁ x) (h₂ : Bounded nil x o₂) : Valid' o₁ (singleton x : Ordnode α) o₂ := (valid'_nil h₁).node (valid'_nil h₂) (Or.inl zero_le_one) rfl theorem valid_singleton {x : α} : Valid (singleton x : Ordnode α) := valid'_singleton ⟨⟩ ⟨⟩ theorem Valid'.node3L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m)) (H2 : BalancedSz (size l + size m + 1) (size r)) : Valid' o₁ (@node3L α l x m y r) o₂ := (hl.node' hm H1).node' hr H2 theorem Valid'.node3R {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m + size r + 1)) (H2 : BalancedSz (size m) (size r)) : Valid' o₁ (@node3R α l x m y r) o₂ := hl.node' (hm.node' hr H2) H1 theorem Valid'.node4L_lemma₁ {a b c d : ℕ} (lr₂ : 3 (b + c + 1 + d) ≤ 16 * a + 9) (mr₂ : b + c + 1 ≤ 3 * d) (mm₁ : b ≤ 3 * c) : b < 3 * a + 1 := by omega theorem Valid'.node4L_lemma₂ {b c d : ℕ} (mr₂ : b + c + 1 ≤ 3 * d) : c ≤ 3 * d := by omega theorem Valid'.node4L_lemma₃ {b c d : ℕ} (mr₁ : 2 * d ≤ b + c + 1) (mm₁ : b ≤ 3 * c) : d ≤ 3 * c := by omega theorem Valid'.node4L_lemma₄ {a b c d : ℕ} (lr₁ : 3 * a ≤ b + c + 1 + d) (mr₂ : b + c + 1 ≤ 3 * d) (mm₁ : b ≤ 3 * c) : a + b + 1 ≤ 3 * (c + d + 1) := by omega theorem Valid'.node4L_lemma₅ {a b c d : ℕ} (lr₂ : 3 * (b + c + 1 + d) ≤ 16 * a + 9) (mr₁ : 2 * d ≤ b + c + 1) (mm₂ : c ≤ 3 * b) : c + d + 1 ≤ 3 * (a + b + 1) := by omega theorem Valid'.node4L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' (↑y) r o₂) (Hm : 0 < size m) (H : size l = 0 ∧ size m = 1 ∧ size r ≤ 1 ∨ 0 < size l ∧ ratio * size r ≤ size m ∧ delta * size l ≤ size m + size r ∧ 3 * (size m + size r) ≤ 16 * size l + 9 ∧ size m ≤ delta * size r) : Valid' o₁ (@node4L α l x m y r) o₂ := by obtain - \| ⟨s, ml, z, mr⟩ := m; · cases Hm suffices BalancedSz (size l) (size ml) ∧ BalancedSz (size mr) (size r) ∧ BalancedSz (size l + size ml + 1) (size mr + size r + 1) from Valid'.node' (hl.node' hm.left this.1) (hm.right.node' hr this.2.1) this.2.2 rcases H with (⟨l0, m1, r0⟩ \| ⟨l0, mr₁, lr₁, lr₂, mr₂⟩) · rw [hm.2.size_eq, Nat.succ_inj, add_eq_zero] at m1 rw [l0, m1.1, m1.2]; revert r0; rcases size r with (_ \| _ \| _) <;> [decide; decide; (intro r0; unfold BalancedSz delta; omega)] · rcases Nat.eq_zero_or_pos (size r) with r0 \| r0 · rw [r0] at mr₂; cases not_le_of_lt Hm mr₂ rw [hm.2.size_eq] at lr₁ lr₂ mr₁ mr₂ by_cases mm : size ml + size mr ≤ 1 · have r1 := le_antisymm ((mul_le_mul_left (by decide)).1 (le_trans mr₁ (Nat.succ_le_succ mm) : _ ≤ ratio * 1)) r0 rw [r1, add_assoc] at lr₁ have l1 := le_antisymm ((mul_le_mul_left (by decide)).1 (le_trans lr₁ (add_le_add_right mm 2) : _ ≤ delta * 1)) l0 rw [l1, r1] revert mm; cases size ml <;> cases size mr <;> intro mm · decide · rw [zero_add] at mm; rcases mm with (_ \| ⟨⟨⟩⟩) decide · rcases mm with (_ \| ⟨⟨⟩⟩); decide	· rw [Nat.succ_add] at mm; rcases mm with (_ \| ⟨⟨⟩⟩) rcases hm.3.1.resolve_left mm with ⟨mm₁, mm₂⟩ rcases Nat.eq_zero_or_pos (size ml) with ml0 \| ml0 · rw [ml0, mul_zero, Nat.le_zero] at mm₂ rw [ml0, mm₂] at mm; cases mm (by decide) have : 2 * size l ≤ size ml + size mr + 1 := by have := Nat.mul_le_mul_left ratio lr₁ rw [mul_left_comm, mul_add] at this have := le_trans this (add_le_add_left mr₁ _) rw [← Nat.succ_mul] at this exact (mul_le_mul_left (by decide)).1 this	Mathlib/Data/Ordmap/Ordset.lean	200	210
/- Copyright (c) 2022 Martin Zinkevich. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Martin Zinkevich -/ import Mathlib.MeasureTheory.Measure.Typeclasses.Finite /-! # Subtraction of measures In this file we define `μ - ν` to be the least measure `τ` such that `μ ≤ τ + ν`. It is the equivalent of `(μ - ν) ⊔ 0` if `μ` and `ν` were signed measures. Compare with `ENNReal.instSub`. Specifically, note that if you have `α = {1,2}`, and `μ {1} = 2`, `μ {2} = 0`, and `ν {2} = 2`, `ν {1} = 0`, then `(μ - ν) {1, 2} = 2`. However, if `μ ≤ ν`, and `ν univ ≠ ∞`, then `(μ - ν) + ν = μ`. -/ open Set namespace MeasureTheory namespace Measure /-- The measure `μ - ν` is defined to be the least measure `τ` such that `μ ≤ τ + ν`. It is the equivalent of `(μ - ν) ⊔ 0` if `μ` and `ν` were signed measures. Compare with `ENNReal.instSub`. Specifically, note that if you have `α = {1,2}`, and `μ {1} = 2`, `μ {2} = 0`, and `ν {2} = 2`, `ν {1} = 0`, then `(μ - ν) {1, 2} = 2`. However, if `μ ≤ ν`, and `ν univ ≠ ∞`, then `(μ - ν) + ν = μ`. -/ noncomputable instance instSub {α : Type} [MeasurableSpace α] : Sub (Measure α) := ⟨fun μ ν => sInf { τ \| μ ≤ τ + ν }⟩ variable {α : Type} {m : MeasurableSpace α} {μ ν : Measure α} {s : Set α} theorem sub_def : μ - ν = sInf { d \| μ ≤ d + ν } := rfl theorem sub_le_of_le_add {d} (h : μ ≤ d + ν) : μ - ν ≤ d := sInf_le h theorem sub_eq_zero_of_le (h : μ ≤ ν) : μ - ν = 0 := nonpos_iff_eq_zero'.1 <\| sub_le_of_le_add <\| by rwa [zero_add] theorem sub_le : μ - ν ≤ μ := sub_le_of_le_add <\| Measure.le_add_right le_rfl @[simp] theorem sub_top : μ - ⊤ = 0 := sub_eq_zero_of_le le_top @[simp] theorem zero_sub : 0 - μ = 0 := sub_eq_zero_of_le μ.zero_le @[simp] theorem sub_self : μ - μ = 0 := sub_eq_zero_of_le le_rfl /-- This application lemma only works in special circumstances. Given knowledge of when `μ ≤ ν` and `ν ≤ μ`, a more general application lemma can be written. -/ theorem sub_apply [IsFiniteMeasure ν] (h₁ : MeasurableSet s) (h₂ : ν ≤ μ) : (μ - ν) s = μ s - ν s := by -- We begin by defining `measure_sub`, which will be equal to `(μ - ν)`. let measure_sub : Measure α := MeasureTheory.Measure.ofMeasurable (fun (t : Set α) (_ : MeasurableSet t) => μ t - ν t) (by simp) (fun g h_meas h_disj ↦ by simp only [measure_iUnion h_disj h_meas] rw [ENNReal.tsum_sub _ (h₂ <\| g ·)] rw [← measure_iUnion h_disj h_meas] apply measure_ne_top) -- Now, we demonstrate `μ - ν = measure_sub`, and apply it. have h_measure_sub_add : ν + measure_sub = μ := by ext1 t h_t_measurable_set simp only [Pi.add_apply, coe_add] rw [MeasureTheory.Measure.ofMeasurable_apply _ h_t_measurable_set, add_comm, tsub_add_cancel_of_le (h₂ t)] have h_measure_sub_eq : μ - ν = measure_sub := by rw [MeasureTheory.Measure.sub_def] apply le_antisymm · apply sInf_le simp [le_refl, add_comm, h_measure_sub_add] apply le_sInf intro d h_d rw [← h_measure_sub_add, mem_setOf_eq, add_comm d] at h_d apply Measure.le_of_add_le_add_left h_d rw [h_measure_sub_eq] apply Measure.ofMeasurable_apply _ h₁ theorem sub_add_cancel_of_le [IsFiniteMeasure ν] (h₁ : ν ≤ μ) : μ - ν + ν = μ := by ext1 s h_s_meas rw [add_apply, sub_apply h_s_meas h₁, tsub_add_cancel_of_le (h₁ s)] @[simp] protected lemma add_sub_cancel [IsFiniteMeasure ν] : μ + ν - ν = μ := by ext1 s hs rw [sub_apply hs (Measure.le_add_left (le_refl _)), add_apply, ENNReal.add_sub_cancel_right (measure_ne_top ν s)] theorem restrict_sub_eq_restrict_sub_restrict (h_meas_s : MeasurableSet s) :	(μ - ν).restrict s = μ.restrict s - ν.restrict s := by repeat rw [sub_def] have h_nonempty : { d \| μ ≤ d + ν }.Nonempty := ⟨μ, Measure.le_add_right le_rfl⟩	Mathlib/MeasureTheory/Measure/Sub.lean	100	102
/- Copyright (c) 2018 Michael Jendrusch. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Michael Jendrusch, Kim Morrison, Bhavik Mehta, Jakob von Raumer -/ import Mathlib.CategoryTheory.EqToHom import Mathlib.CategoryTheory.Functor.Trifunctor import Mathlib.CategoryTheory.Products.Basic /-! # Monoidal categories A monoidal category is a category equipped with a tensor product, unitors, and an associator. In the definition, we provide the tensor product as a pair of functions * `tensorObj : C → C → C` * `tensorHom : (X₁ ⟶ Y₁) → (X₂ ⟶ Y₂) → ((X₁ ⊗ X₂) ⟶ (Y₁ ⊗ Y₂))` and allow use of the overloaded notation `⊗` for both. The unitors and associator are provided componentwise. The tensor product can be expressed as a functor via `tensor : C × C ⥤ C`. The unitors and associator are gathered together as natural isomorphisms in `leftUnitor_nat_iso`, `rightUnitor_nat_iso` and `associator_nat_iso`. Some consequences of the definition are proved in other files after proving the coherence theorem, e.g. `(λ_ (𝟙_ C)).hom = (ρ_ (𝟙_ C)).hom` in `CategoryTheory.Monoidal.CoherenceLemmas`. ## Implementation notes In the definition of monoidal categories, we also provide the whiskering operators: * `whiskerLeft (X : C) {Y₁ Y₂ : C} (f : Y₁ ⟶ Y₂) : X ⊗ Y₁ ⟶ X ⊗ Y₂`, denoted by `X ◁ f`, * `whiskerRight {X₁ X₂ : C} (f : X₁ ⟶ X₂) (Y : C) : X₁ ⊗ Y ⟶ X₂ ⊗ Y`, denoted by `f ▷ Y`. These are products of an object and a morphism (the terminology "whiskering" is borrowed from 2-category theory). The tensor product of morphisms `tensorHom` can be defined in terms of the whiskerings. There are two possible such definitions, which are related by the exchange property of the whiskerings. These two definitions are accessed by `tensorHom_def` and `tensorHom_def'`. By default, `tensorHom` is defined so that `tensorHom_def` holds definitionally. If you want to provide `tensorHom` and define `whiskerLeft` and `whiskerRight` in terms of it, you can use the alternative constructor `CategoryTheory.MonoidalCategory.ofTensorHom`. The whiskerings are useful when considering simp-normal forms of morphisms in monoidal categories. ### Simp-normal form for morphisms Rewriting involving associators and unitors could be very complicated. We try to ease this complexity by putting carefully chosen simp lemmas that rewrite any morphisms into the simp-normal form defined below. Rewriting into simp-normal form is especially useful in preprocessing performed by the `coherence` tactic. The simp-normal form of morphisms is defined to be an expression that has the minimal number of parentheses. More precisely, 1. it is a composition of morphisms like `f₁ ≫ f₂ ≫ f₃ ≫ f₄ ≫ f₅` such that each `fᵢ` is either a structural morphisms (morphisms made up only of identities, associators, unitors) or non-structural morphisms, and 2. each non-structural morphism in the composition is of the form `X₁ ◁ X₂ ◁ X₃ ◁ f ▷ X₄ ▷ X₅`, where each `Xᵢ` is a object that is not the identity or a tensor and `f` is a non-structural morphisms that is not the identity or a composite. Note that `X₁ ◁ X₂ ◁ X₃ ◁ f ▷ X₄ ▷ X₅` is actually `X₁ ◁ (X₂ ◁ (X₃ ◁ ((f ▷ X₄) ▷ X₅)))`. Currently, the simp lemmas don't rewrite `𝟙 X ⊗ f` and `f ⊗ 𝟙 Y` into `X ◁ f` and `f ▷ Y`, respectively, since it requires a huge refactoring. We hope to add these simp lemmas soon. ## References * Tensor categories, Etingof, Gelaki, Nikshych, Ostrik, http://www-math.mit.edu/~etingof/egnobookfinal.pdf * <https://stacks.math.columbia.edu/tag/0FFK>. -/ universe v u open CategoryTheory.Category open CategoryTheory.Iso namespace CategoryTheory /-- Auxiliary structure to carry only the data fields of (and provide notation for) `MonoidalCategory`. -/ class MonoidalCategoryStruct (C : Type u) [𝒞 : Category.{v} C] where /-- curried tensor product of objects -/ tensorObj : C → C → C /-- left whiskering for morphisms -/ whiskerLeft (X : C) {Y₁ Y₂ : C} (f : Y₁ ⟶ Y₂) : tensorObj X Y₁ ⟶ tensorObj X Y₂ /-- right whiskering for morphisms -/ whiskerRight {X₁ X₂ : C} (f : X₁ ⟶ X₂) (Y : C) : tensorObj X₁ Y ⟶ tensorObj X₂ Y /-- Tensor product of identity maps is the identity: `(𝟙 X₁ ⊗ 𝟙 X₂) = 𝟙 (X₁ ⊗ X₂)` -/ -- By default, it is defined in terms of whiskerings. tensorHom {X₁ Y₁ X₂ Y₂ : C} (f : X₁ ⟶ Y₁) (g : X₂ ⟶ Y₂) : (tensorObj X₁ X₂ ⟶ tensorObj Y₁ Y₂) := whiskerRight f X₂ ≫ whiskerLeft Y₁ g /-- The tensor unity in the monoidal structure `𝟙_ C` -/ tensorUnit (C) : C /-- The associator isomorphism `(X ⊗ Y) ⊗ Z ≃ X ⊗ (Y ⊗ Z)` -/ associator : ∀ X Y Z : C, tensorObj (tensorObj X Y) Z ≅ tensorObj X (tensorObj Y Z) /-- The left unitor: `𝟙_ C ⊗ X ≃ X` -/ leftUnitor : ∀ X : C, tensorObj tensorUnit X ≅ X /-- The right unitor: `X ⊗ 𝟙_ C ≃ X` -/ rightUnitor : ∀ X : C, tensorObj X tensorUnit ≅ X namespace MonoidalCategory export MonoidalCategoryStruct (tensorObj whiskerLeft whiskerRight tensorHom tensorUnit associator leftUnitor rightUnitor) end MonoidalCategory namespace MonoidalCategory /-- Notation for `tensorObj`, the tensor product of objects in a monoidal category -/ scoped infixr:70 " ⊗ " => MonoidalCategoryStruct.tensorObj /-- Notation for the `whiskerLeft` operator of monoidal categories -/ scoped infixr:81 " ◁ " => MonoidalCategoryStruct.whiskerLeft /-- Notation for the `whiskerRight` operator of monoidal categories -/ scoped infixl:81 " ▷ " => MonoidalCategoryStruct.whiskerRight /-- Notation for `tensorHom`, the tensor product of morphisms in a monoidal category -/ scoped infixr:70 " ⊗ " => MonoidalCategoryStruct.tensorHom /-- Notation for `tensorUnit`, the two-sided identity of `⊗` -/ scoped notation "𝟙_ " C:arg => MonoidalCategoryStruct.tensorUnit C /-- Notation for the monoidal `associator`: `(X ⊗ Y) ⊗ Z ≃ X ⊗ (Y ⊗ Z)` -/ scoped notation "α_" => MonoidalCategoryStruct.associator /-- Notation for the `leftUnitor`: `𝟙_C ⊗ X ≃ X` -/ scoped notation "λ_" => MonoidalCategoryStruct.leftUnitor /-- Notation for the `rightUnitor`: `X ⊗ 𝟙_C ≃ X` -/ scoped notation "ρ_" => MonoidalCategoryStruct.rightUnitor /-- The property that the pentagon relation is satisfied by four objects in a category equipped with a `MonoidalCategoryStruct`. -/ def Pentagon {C : Type u} [Category.{v} C] [MonoidalCategoryStruct C] (Y₁ Y₂ Y₃ Y₄ : C) : Prop := (α_ Y₁ Y₂ Y₃).hom ▷ Y₄ ≫ (α_ Y₁ (Y₂ ⊗ Y₃) Y₄).hom ≫ Y₁ ◁ (α_ Y₂ Y₃ Y₄).hom = (α_ (Y₁ ⊗ Y₂) Y₃ Y₄).hom ≫ (α_ Y₁ Y₂ (Y₃ ⊗ Y₄)).hom end MonoidalCategory open MonoidalCategory /-- In a monoidal category, we can take the tensor product of objects, `X ⊗ Y` and of morphisms `f ⊗ g`. Tensor product does not need to be strictly associative on objects, but there is a specified associator, `α_ X Y Z : (X ⊗ Y) ⊗ Z ≅ X ⊗ (Y ⊗ Z)`. There is a tensor unit `𝟙_ C`, with specified left and right unitor isomorphisms `λ_ X : 𝟙_ C ⊗ X ≅ X` and `ρ_ X : X ⊗ 𝟙_ C ≅ X`. These associators and unitors satisfy the pentagon and triangle equations. -/ @[stacks 0FFK] -- Porting note: The Mathport did not translate the temporary notation class MonoidalCategory (C : Type u) [𝒞 : Category.{v} C] extends MonoidalCategoryStruct C where tensorHom_def {X₁ Y₁ X₂ Y₂ : C} (f : X₁ ⟶ Y₁) (g : X₂ ⟶ Y₂) : f ⊗ g = (f ▷ X₂) ≫ (Y₁ ◁ g) := by aesop_cat /-- Tensor product of identity maps is the identity: `(𝟙 X₁ ⊗ 𝟙 X₂) = 𝟙 (X₁ ⊗ X₂)` -/ tensor_id : ∀ X₁ X₂ : C, 𝟙 X₁ ⊗ 𝟙 X₂ = 𝟙 (X₁ ⊗ X₂) := by aesop_cat /-- Tensor product of compositions is composition of tensor products: `(f₁ ≫ g₁) ⊗ (f₂ ≫ g₂) = (f₁ ⊗ f₂) ≫ (g₁ ⊗ g₂)` -/ tensor_comp : ∀ {X₁ Y₁ Z₁ X₂ Y₂ Z₂ : C} (f₁ : X₁ ⟶ Y₁) (f₂ : X₂ ⟶ Y₂) (g₁ : Y₁ ⟶ Z₁) (g₂ : Y₂ ⟶ Z₂), (f₁ ≫ g₁) ⊗ (f₂ ≫ g₂) = (f₁ ⊗ f₂) ≫ (g₁ ⊗ g₂) := by aesop_cat whiskerLeft_id : ∀ (X Y : C), X ◁ 𝟙 Y = 𝟙 (X ⊗ Y) := by aesop_cat id_whiskerRight : ∀ (X Y : C), 𝟙 X ▷ Y = 𝟙 (X ⊗ Y) := by aesop_cat /-- Naturality of the associator isomorphism: `(f₁ ⊗ f₂) ⊗ f₃ ≃ f₁ ⊗ (f₂ ⊗ f₃)` -/ associator_naturality : ∀ {X₁ X₂ X₃ Y₁ Y₂ Y₃ : C} (f₁ : X₁ ⟶ Y₁) (f₂ : X₂ ⟶ Y₂) (f₃ : X₃ ⟶ Y₃), ((f₁ ⊗ f₂) ⊗ f₃) ≫ (α_ Y₁ Y₂ Y₃).hom = (α_ X₁ X₂ X₃).hom ≫ (f₁ ⊗ (f₂ ⊗ f₃)) := by aesop_cat /-- Naturality of the left unitor, commutativity of `𝟙_ C ⊗ X ⟶ 𝟙_ C ⊗ Y ⟶ Y` and `𝟙_ C ⊗ X ⟶ X ⟶ Y` -/ leftUnitor_naturality : ∀ {X Y : C} (f : X ⟶ Y), 𝟙_ _ ◁ f ≫ (λ_ Y).hom = (λ_ X).hom ≫ f := by aesop_cat /-- Naturality of the right unitor: commutativity of `X ⊗ 𝟙_ C ⟶ Y ⊗ 𝟙_ C ⟶ Y` and `X ⊗ 𝟙_ C ⟶ X ⟶ Y` -/ rightUnitor_naturality : ∀ {X Y : C} (f : X ⟶ Y), f ▷ 𝟙_ _ ≫ (ρ_ Y).hom = (ρ_ X).hom ≫ f := by aesop_cat /-- The pentagon identity relating the isomorphism between `X ⊗ (Y ⊗ (Z ⊗ W))` and `((X ⊗ Y) ⊗ Z) ⊗ W` -/ pentagon : ∀ W X Y Z : C, (α_ W X Y).hom ▷ Z ≫ (α_ W (X ⊗ Y) Z).hom ≫ W ◁ (α_ X Y Z).hom = (α_ (W ⊗ X) Y Z).hom ≫ (α_ W X (Y ⊗ Z)).hom := by aesop_cat /-- The identity relating the isomorphisms between `X ⊗ (𝟙_ C ⊗ Y)`, `(X ⊗ 𝟙_ C) ⊗ Y` and `X ⊗ Y` -/ triangle : ∀ X Y : C, (α_ X (𝟙_ _) Y).hom ≫ X ◁ (λ_ Y).hom = (ρ_ X).hom ▷ Y := by aesop_cat attribute [reassoc] MonoidalCategory.tensorHom_def attribute [reassoc, simp] MonoidalCategory.whiskerLeft_id attribute [reassoc, simp] MonoidalCategory.id_whiskerRight attribute [reassoc] MonoidalCategory.tensor_comp attribute [simp] MonoidalCategory.tensor_comp attribute [reassoc] MonoidalCategory.associator_naturality attribute [reassoc] MonoidalCategory.leftUnitor_naturality attribute [reassoc] MonoidalCategory.rightUnitor_naturality attribute [reassoc (attr := simp)] MonoidalCategory.pentagon attribute [reassoc (attr := simp)] MonoidalCategory.triangle namespace MonoidalCategory variable {C : Type u} [𝒞 : Category.{v} C] [MonoidalCategory C] @[simp] theorem id_tensorHom (X : C) {Y₁ Y₂ : C} (f : Y₁ ⟶ Y₂) : 𝟙 X ⊗ f = X ◁ f := by simp [tensorHom_def] @[simp] theorem tensorHom_id {X₁ X₂ : C} (f : X₁ ⟶ X₂) (Y : C) : f ⊗ 𝟙 Y = f ▷ Y := by simp [tensorHom_def] @[reassoc, simp] theorem whiskerLeft_comp (W : C) {X Y Z : C} (f : X ⟶ Y) (g : Y ⟶ Z) : W ◁ (f ≫ g) = W ◁ f ≫ W ◁ g := by simp only [← id_tensorHom, ← tensor_comp, comp_id] @[reassoc, simp] theorem id_whiskerLeft {X Y : C} (f : X ⟶ Y) : 𝟙_ C ◁ f = (λ_ X).hom ≫ f ≫ (λ_ Y).inv := by rw [← assoc, ← leftUnitor_naturality]; simp [id_tensorHom] @[reassoc, simp] theorem tensor_whiskerLeft (X Y : C) {Z Z' : C} (f : Z ⟶ Z') : (X ⊗ Y) ◁ f = (α_ X Y Z).hom ≫ X ◁ Y ◁ f ≫ (α_ X Y Z').inv := by simp only [← id_tensorHom, ← tensorHom_id] rw [← assoc, ← associator_naturality] simp @[reassoc, simp] theorem comp_whiskerRight {W X Y : C} (f : W ⟶ X) (g : X ⟶ Y) (Z : C) : (f ≫ g) ▷ Z = f ▷ Z ≫ g ▷ Z := by simp only [← tensorHom_id, ← tensor_comp, id_comp] @[reassoc, simp] theorem whiskerRight_id {X Y : C} (f : X ⟶ Y) : f ▷ 𝟙_ C = (ρ_ X).hom ≫ f ≫ (ρ_ Y).inv := by rw [← assoc, ← rightUnitor_naturality]; simp [tensorHom_id] @[reassoc, simp] theorem whiskerRight_tensor {X X' : C} (f : X ⟶ X') (Y Z : C) : f ▷ (Y ⊗ Z) = (α_ X Y Z).inv ≫ f ▷ Y ▷ Z ≫ (α_ X' Y Z).hom := by simp only [← id_tensorHom, ← tensorHom_id] rw [associator_naturality] simp [tensor_id] @[reassoc, simp] theorem whisker_assoc (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) : (X ◁ f) ▷ Z = (α_ X Y Z).hom ≫ X ◁ f ▷ Z ≫ (α_ X Y' Z).inv := by simp only [← id_tensorHom, ← tensorHom_id] rw [← assoc, ← associator_naturality] simp @[reassoc] theorem whisker_exchange {W X Y Z : C} (f : W ⟶ X) (g : Y ⟶ Z) : W ◁ g ≫ f ▷ Z = f ▷ Y ≫ X ◁ g := by simp only [← id_tensorHom, ← tensorHom_id, ← tensor_comp, id_comp, comp_id] @[reassoc] theorem tensorHom_def' {X₁ Y₁ X₂ Y₂ : C} (f : X₁ ⟶ Y₁) (g : X₂ ⟶ Y₂) : f ⊗ g = X₁ ◁ g ≫ f ▷ Y₂ := whisker_exchange f g ▸ tensorHom_def f g @[reassoc (attr := simp)] theorem whiskerLeft_hom_inv (X : C) {Y Z : C} (f : Y ≅ Z) : X ◁ f.hom ≫ X ◁ f.inv = 𝟙 (X ⊗ Y) := by rw [← whiskerLeft_comp, hom_inv_id, whiskerLeft_id] @[reassoc (attr := simp)] theorem hom_inv_whiskerRight {X Y : C} (f : X ≅ Y) (Z : C) : f.hom ▷ Z ≫ f.inv ▷ Z = 𝟙 (X ⊗ Z) := by rw [← comp_whiskerRight, hom_inv_id, id_whiskerRight] @[reassoc (attr := simp)] theorem whiskerLeft_inv_hom (X : C) {Y Z : C} (f : Y ≅ Z) : X ◁ f.inv ≫ X ◁ f.hom = 𝟙 (X ⊗ Z) := by rw [← whiskerLeft_comp, inv_hom_id, whiskerLeft_id] @[reassoc (attr := simp)] theorem inv_hom_whiskerRight {X Y : C} (f : X ≅ Y) (Z : C) : f.inv ▷ Z ≫ f.hom ▷ Z = 𝟙 (Y ⊗ Z) := by rw [← comp_whiskerRight, inv_hom_id, id_whiskerRight] @[reassoc (attr := simp)] theorem whiskerLeft_hom_inv' (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] : X ◁ f ≫ X ◁ inv f = 𝟙 (X ⊗ Y) := by rw [← whiskerLeft_comp, IsIso.hom_inv_id, whiskerLeft_id] @[reassoc (attr := simp)] theorem hom_inv_whiskerRight' {X Y : C} (f : X ⟶ Y) [IsIso f] (Z : C) : f ▷ Z ≫ inv f ▷ Z = 𝟙 (X ⊗ Z) := by rw [← comp_whiskerRight, IsIso.hom_inv_id, id_whiskerRight] @[reassoc (attr := simp)] theorem whiskerLeft_inv_hom' (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] : X ◁ inv f ≫ X ◁ f = 𝟙 (X ⊗ Z) := by rw [← whiskerLeft_comp, IsIso.inv_hom_id, whiskerLeft_id] @[reassoc (attr := simp)] theorem inv_hom_whiskerRight' {X Y : C} (f : X ⟶ Y) [IsIso f] (Z : C) : inv f ▷ Z ≫ f ▷ Z = 𝟙 (Y ⊗ Z) := by rw [← comp_whiskerRight, IsIso.inv_hom_id, id_whiskerRight] /-- The left whiskering of an isomorphism is an isomorphism. -/ @[simps] def whiskerLeftIso (X : C) {Y Z : C} (f : Y ≅ Z) : X ⊗ Y ≅ X ⊗ Z where hom := X ◁ f.hom inv := X ◁ f.inv instance whiskerLeft_isIso (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] : IsIso (X ◁ f) := (whiskerLeftIso X (asIso f)).isIso_hom @[simp] theorem inv_whiskerLeft (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] : inv (X ◁ f) = X ◁ inv f := by aesop_cat @[simp] lemma whiskerLeftIso_refl (W X : C) : whiskerLeftIso W (Iso.refl X) = Iso.refl (W ⊗ X) := Iso.ext (whiskerLeft_id W X) @[simp] lemma whiskerLeftIso_trans (W : C) {X Y Z : C} (f : X ≅ Y) (g : Y ≅ Z) : whiskerLeftIso W (f ≪≫ g) = whiskerLeftIso W f ≪≫ whiskerLeftIso W g := Iso.ext (whiskerLeft_comp W f.hom g.hom) @[simp] lemma whiskerLeftIso_symm (W : C) {X Y : C} (f : X ≅ Y) : (whiskerLeftIso W f).symm = whiskerLeftIso W f.symm := rfl /-- The right whiskering of an isomorphism is an isomorphism. -/ @[simps!] def whiskerRightIso {X Y : C} (f : X ≅ Y) (Z : C) : X ⊗ Z ≅ Y ⊗ Z where hom := f.hom ▷ Z inv := f.inv ▷ Z instance whiskerRight_isIso {X Y : C} (f : X ⟶ Y) (Z : C) [IsIso f] : IsIso (f ▷ Z) := (whiskerRightIso (asIso f) Z).isIso_hom @[simp] theorem inv_whiskerRight {X Y : C} (f : X ⟶ Y) (Z : C) [IsIso f] : inv (f ▷ Z) = inv f ▷ Z := by aesop_cat @[simp] lemma whiskerRightIso_refl (X W : C) : whiskerRightIso (Iso.refl X) W = Iso.refl (X ⊗ W) := Iso.ext (id_whiskerRight X W) @[simp] lemma whiskerRightIso_trans {X Y Z : C} (f : X ≅ Y) (g : Y ≅ Z) (W : C) : whiskerRightIso (f ≪≫ g) W = whiskerRightIso f W ≪≫ whiskerRightIso g W := Iso.ext (comp_whiskerRight f.hom g.hom W) @[simp] lemma whiskerRightIso_symm {X Y : C} (f : X ≅ Y) (W : C) : (whiskerRightIso f W).symm = whiskerRightIso f.symm W := rfl /-- The tensor product of two isomorphisms is an isomorphism. -/ @[simps] def tensorIso {X Y X' Y' : C} (f : X ≅ Y) (g : X' ≅ Y') : X ⊗ X' ≅ Y ⊗ Y' where hom := f.hom ⊗ g.hom inv := f.inv ⊗ g.inv hom_inv_id := by rw [← tensor_comp, Iso.hom_inv_id, Iso.hom_inv_id, ← tensor_id] inv_hom_id := by rw [← tensor_comp, Iso.inv_hom_id, Iso.inv_hom_id, ← tensor_id] /-- Notation for `tensorIso`, the tensor product of isomorphisms -/ scoped infixr:70 " ⊗ " => tensorIso theorem tensorIso_def {X Y X' Y' : C} (f : X ≅ Y) (g : X' ≅ Y') : f ⊗ g = whiskerRightIso f X' ≪≫ whiskerLeftIso Y g := Iso.ext (tensorHom_def f.hom g.hom) theorem tensorIso_def' {X Y X' Y' : C} (f : X ≅ Y) (g : X' ≅ Y') : f ⊗ g = whiskerLeftIso X g ≪≫ whiskerRightIso f Y' := Iso.ext (tensorHom_def' f.hom g.hom) instance tensor_isIso {W X Y Z : C} (f : W ⟶ X) [IsIso f] (g : Y ⟶ Z) [IsIso g] : IsIso (f ⊗ g) := (asIso f ⊗ asIso g).isIso_hom @[simp] theorem inv_tensor {W X Y Z : C} (f : W ⟶ X) [IsIso f] (g : Y ⟶ Z) [IsIso g] : inv (f ⊗ g) = inv f ⊗ inv g := by simp [tensorHom_def ,whisker_exchange] variable {W X Y Z : C} theorem whiskerLeft_dite {P : Prop} [Decidable P] (X : C) {Y Z : C} (f : P → (Y ⟶ Z)) (f' : ¬P → (Y ⟶ Z)) : X ◁ (if h : P then f h else f' h) = if h : P then X ◁ f h else X ◁ f' h := by split_ifs <;> rfl theorem dite_whiskerRight {P : Prop} [Decidable P] {X Y : C} (f : P → (X ⟶ Y)) (f' : ¬P → (X ⟶ Y)) (Z : C) : (if h : P then f h else f' h) ▷ Z = if h : P then f h ▷ Z else f' h ▷ Z := by split_ifs <;> rfl theorem tensor_dite {P : Prop} [Decidable P] {W X Y Z : C} (f : W ⟶ X) (g : P → (Y ⟶ Z)) (g' : ¬P → (Y ⟶ Z)) : (f ⊗ if h : P then g h else g' h) = if h : P then f ⊗ g h else f ⊗ g' h := by split_ifs <;> rfl theorem dite_tensor {P : Prop} [Decidable P] {W X Y Z : C} (f : W ⟶ X) (g : P → (Y ⟶ Z)) (g' : ¬P → (Y ⟶ Z)) : (if h : P then g h else g' h) ⊗ f = if h : P then g h ⊗ f else g' h ⊗ f := by split_ifs <;> rfl @[simp] theorem whiskerLeft_eqToHom (X : C) {Y Z : C} (f : Y = Z) : X ◁ eqToHom f = eqToHom (congr_arg₂ tensorObj rfl f) := by cases f simp only [whiskerLeft_id, eqToHom_refl] @[simp] theorem eqToHom_whiskerRight {X Y : C} (f : X = Y) (Z : C) : eqToHom f ▷ Z = eqToHom (congr_arg₂ tensorObj f rfl) := by cases f simp only [id_whiskerRight, eqToHom_refl] @[reassoc] theorem associator_naturality_left {X X' : C} (f : X ⟶ X') (Y Z : C) : f ▷ Y ▷ Z ≫ (α_ X' Y Z).hom = (α_ X Y Z).hom ≫ f ▷ (Y ⊗ Z) := by simp @[reassoc] theorem associator_inv_naturality_left {X X' : C} (f : X ⟶ X') (Y Z : C) : f ▷ (Y ⊗ Z) ≫ (α_ X' Y Z).inv = (α_ X Y Z).inv ≫ f ▷ Y ▷ Z := by simp @[reassoc] theorem whiskerRight_tensor_symm {X X' : C} (f : X ⟶ X') (Y Z : C) : f ▷ Y ▷ Z = (α_ X Y Z).hom ≫ f ▷ (Y ⊗ Z) ≫ (α_ X' Y Z).inv := by simp @[reassoc] theorem associator_naturality_middle (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) : (X ◁ f) ▷ Z ≫ (α_ X Y' Z).hom = (α_ X Y Z).hom ≫ X ◁ f ▷ Z := by simp @[reassoc] theorem associator_inv_naturality_middle (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) : X ◁ f ▷ Z ≫ (α_ X Y' Z).inv = (α_ X Y Z).inv ≫ (X ◁ f) ▷ Z := by simp @[reassoc] theorem whisker_assoc_symm (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) : X ◁ f ▷ Z = (α_ X Y Z).inv ≫ (X ◁ f) ▷ Z ≫ (α_ X Y' Z).hom := by simp @[reassoc] theorem associator_naturality_right (X Y : C) {Z Z' : C} (f : Z ⟶ Z') : (X ⊗ Y) ◁ f ≫ (α_ X Y Z').hom = (α_ X Y Z).hom ≫ X ◁ Y ◁ f := by simp @[reassoc] theorem associator_inv_naturality_right (X Y : C) {Z Z' : C} (f : Z ⟶ Z') : X ◁ Y ◁ f ≫ (α_ X Y Z').inv = (α_ X Y Z).inv ≫ (X ⊗ Y) ◁ f := by simp @[reassoc] theorem tensor_whiskerLeft_symm (X Y : C) {Z Z' : C} (f : Z ⟶ Z') : X ◁ Y ◁ f = (α_ X Y Z).inv ≫ (X ⊗ Y) ◁ f ≫ (α_ X Y Z').hom := by simp @[reassoc] theorem leftUnitor_inv_naturality {X Y : C} (f : X ⟶ Y) : f ≫ (λ_ Y).inv = (λ_ X).inv ≫ _ ◁ f := by simp @[reassoc] theorem id_whiskerLeft_symm {X X' : C} (f : X ⟶ X') : f = (λ_ X).inv ≫ 𝟙_ C ◁ f ≫ (λ_ X').hom := by simp only [id_whiskerLeft, assoc, inv_hom_id, comp_id, inv_hom_id_assoc] @[reassoc] theorem rightUnitor_inv_naturality {X X' : C} (f : X ⟶ X') : f ≫ (ρ_ X').inv = (ρ_ X).inv ≫ f ▷ _ := by simp @[reassoc] theorem whiskerRight_id_symm {X Y : C} (f : X ⟶ Y) : f = (ρ_ X).inv ≫ f ▷ 𝟙_ C ≫ (ρ_ Y).hom := by simp theorem whiskerLeft_iff {X Y : C} (f g : X ⟶ Y) : 𝟙_ C ◁ f = 𝟙_ C ◁ g ↔ f = g := by simp theorem whiskerRight_iff {X Y : C} (f g : X ⟶ Y) : f ▷ 𝟙_ C = g ▷ 𝟙_ C ↔ f = g := by simp /-! The lemmas in the next section are true by coherence, but we prove them directly as they are used in proving the coherence theorem. -/ section @[reassoc (attr := simp)] theorem pentagon_inv : W ◁ (α_ X Y Z).inv ≫ (α_ W (X ⊗ Y) Z).inv ≫ (α_ W X Y).inv ▷ Z = (α_ W X (Y ⊗ Z)).inv ≫ (α_ (W ⊗ X) Y Z).inv := eq_of_inv_eq_inv (by simp) @[reassoc (attr := simp)] theorem pentagon_inv_inv_hom_hom_inv : (α_ W (X ⊗ Y) Z).inv ≫ (α_ W X Y).inv ▷ Z ≫ (α_ (W ⊗ X) Y Z).hom = W ◁ (α_ X Y Z).hom ≫ (α_ W X (Y ⊗ Z)).inv := by rw [← cancel_epi (W ◁ (α_ X Y Z).inv), ← cancel_mono (α_ (W ⊗ X) Y Z).inv] simp @[reassoc (attr := simp)] theorem pentagon_inv_hom_hom_hom_inv : (α_ (W ⊗ X) Y Z).inv ≫ (α_ W X Y).hom ▷ Z ≫ (α_ W (X ⊗ Y) Z).hom = (α_ W X (Y ⊗ Z)).hom ≫ W ◁ (α_ X Y Z).inv := eq_of_inv_eq_inv (by simp) @[reassoc (attr := simp)] theorem pentagon_hom_inv_inv_inv_inv : W ◁ (α_ X Y Z).hom ≫ (α_ W X (Y ⊗ Z)).inv ≫ (α_ (W ⊗ X) Y Z).inv = (α_ W (X ⊗ Y) Z).inv ≫ (α_ W X Y).inv ▷ Z := by simp [← cancel_epi (W ◁ (α_ X Y Z).inv)] @[reassoc (attr := simp)] theorem pentagon_hom_hom_inv_hom_hom : (α_ (W ⊗ X) Y Z).hom ≫ (α_ W X (Y ⊗ Z)).hom ≫ W ◁ (α_ X Y Z).inv = (α_ W X Y).hom ▷ Z ≫ (α_ W (X ⊗ Y) Z).hom := eq_of_inv_eq_inv (by simp) @[reassoc (attr := simp)] theorem pentagon_hom_inv_inv_inv_hom : (α_ W X (Y ⊗ Z)).hom ≫ W ◁ (α_ X Y Z).inv ≫ (α_ W (X ⊗ Y) Z).inv = (α_ (W ⊗ X) Y Z).inv ≫ (α_ W X Y).hom ▷ Z := by rw [← cancel_epi (α_ W X (Y ⊗ Z)).inv, ← cancel_mono ((α_ W X Y).inv ▷ Z)] simp @[reassoc (attr := simp)] theorem pentagon_hom_hom_inv_inv_hom : (α_ W (X ⊗ Y) Z).hom ≫ W ◁ (α_ X Y Z).hom ≫ (α_ W X (Y ⊗ Z)).inv = (α_ W X Y).inv ▷ Z ≫ (α_ (W ⊗ X) Y Z).hom := eq_of_inv_eq_inv (by simp) @[reassoc (attr := simp)] theorem pentagon_inv_hom_hom_hom_hom : (α_ W X Y).inv ▷ Z ≫ (α_ (W ⊗ X) Y Z).hom ≫ (α_ W X (Y ⊗ Z)).hom = (α_ W (X ⊗ Y) Z).hom ≫ W ◁ (α_ X Y Z).hom := by simp [← cancel_epi ((α_ W X Y).hom ▷ Z)] @[reassoc (attr := simp)] theorem pentagon_inv_inv_hom_inv_inv : (α_ W X (Y ⊗ Z)).inv ≫ (α_ (W ⊗ X) Y Z).inv ≫ (α_ W X Y).hom ▷ Z = W ◁ (α_ X Y Z).inv ≫ (α_ W (X ⊗ Y) Z).inv := eq_of_inv_eq_inv (by simp) @[reassoc (attr := simp)] theorem triangle_assoc_comp_right (X Y : C) : (α_ X (𝟙_ C) Y).inv ≫ ((ρ_ X).hom ▷ Y) = X ◁ (λ_ Y).hom := by rw [← triangle, Iso.inv_hom_id_assoc] @[reassoc (attr := simp)] theorem triangle_assoc_comp_right_inv (X Y : C) : (ρ_ X).inv ▷ Y ≫ (α_ X (𝟙_ C) Y).hom = X ◁ (λ_ Y).inv := by simp [← cancel_mono (X ◁ (λ_ Y).hom)] @[reassoc (attr := simp)] theorem triangle_assoc_comp_left_inv (X Y : C) : (X ◁ (λ_ Y).inv) ≫ (α_ X (𝟙_ C) Y).inv = (ρ_ X).inv ▷ Y := by simp [← cancel_mono ((ρ_ X).hom ▷ Y)] /-- We state it as a simp lemma, which is regarded as an involved version of `id_whiskerRight X Y : 𝟙 X ▷ Y = 𝟙 (X ⊗ Y)`. -/ @[reassoc, simp] theorem leftUnitor_whiskerRight (X Y : C) : (λ_ X).hom ▷ Y = (α_ (𝟙_ C) X Y).hom ≫ (λ_ (X ⊗ Y)).hom := by rw [← whiskerLeft_iff, whiskerLeft_comp, ← cancel_epi (α_ _ _ _).hom, ← cancel_epi ((α_ _ _ _).hom ▷ _), pentagon_assoc, triangle, ← associator_naturality_middle, ← comp_whiskerRight_assoc, triangle, associator_naturality_left] @[reassoc, simp] theorem leftUnitor_inv_whiskerRight (X Y : C) : (λ_ X).inv ▷ Y = (λ_ (X ⊗ Y)).inv ≫ (α_ (𝟙_ C) X Y).inv := eq_of_inv_eq_inv (by simp) @[reassoc, simp] theorem whiskerLeft_rightUnitor (X Y : C) :	X ◁ (ρ_ Y).hom = (α_ X Y (𝟙_ C)).inv ≫ (ρ_ (X ⊗ Y)).hom := by rw [← whiskerRight_iff, comp_whiskerRight, ← cancel_epi (α_ _ _ _).inv, ← cancel_epi (X ◁ (α_ _ _ _).inv), pentagon_inv_assoc, triangle_assoc_comp_right, ←	Mathlib/CategoryTheory/Monoidal/Category.lean	586	588
/- 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.NumberTheory.Cyclotomic.PrimitiveRoots import Mathlib.FieldTheory.Finite.Trace import Mathlib.Algebra.Group.AddChar import Mathlib.Data.ZMod.Units import Mathlib.Analysis.Complex.Polynomial.Basic /-! # Additive characters of finite rings and fields This file collects some results on additive characters whose domain is (the additive group of) a finite ring or field. ## Main definitions and results We define an additive character `ψ` to be primitive if `mulShift ψ a` is trivial only when `a = 0`. We show that when `ψ` is primitive, then the map `a ↦ mulShift ψ a` is injective (`AddChar.to_mulShift_inj_of_isPrimitive`) and that `ψ` is primitive when `R` is a field and `ψ` is nontrivial (`AddChar.IsNontrivial.isPrimitive`). We also show that there are primitive additive characters on `R` (with suitable target `R'`) when `R` is a field or `R = ZMod n` (`AddChar.primitiveCharFiniteField` and `AddChar.primitiveZModChar`). Finally, we show that the sum of all character values is zero when the character is nontrivial (and the target is a domain); see `AddChar.sum_eq_zero_of_isNontrivial`. ## Tags additive character -/ universe u v namespace AddChar section Additive -- The domain and target of our additive characters. Now we restrict to a ring in the domain. variable {R : Type u} [CommRing R] {R' : Type v} [CommMonoid R'] /-- The values of an additive character on a ring of positive characteristic are roots of unity. -/ lemma val_mem_rootsOfUnity (φ : AddChar R R') (a : R) (h : 0 < ringChar R) : (φ.val_isUnit a).unit ∈ rootsOfUnity (ringChar R).toPNat' R' := by simp only [mem_rootsOfUnity', IsUnit.unit_spec, Nat.toPNat'_coe, h, ↓reduceIte, ← map_nsmul_eq_pow, nsmul_eq_mul, CharP.cast_eq_zero, zero_mul, map_zero_eq_one] /-- An additive character is primitive iff all its multiplicative shifts by nonzero elements are nontrivial. -/ def IsPrimitive (ψ : AddChar R R') : Prop := ∀ ⦃a : R⦄, a ≠ 0 → mulShift ψ a ≠ 1 /-- The composition of a primitive additive character with an injective mooid homomorphism is also primitive. -/ lemma IsPrimitive.compMulHom_of_isPrimitive {R'' : Type} [CommMonoid R''] {φ : AddChar R R'} {f : R' → R''} (hφ : φ.IsPrimitive) (hf : Function.Injective f) : (f.compAddChar φ).IsPrimitive := fun a ha ↦ by simpa [DFunLike.ext_iff] using (MonoidHom.compAddChar_injective_right f hf).ne (hφ ha) /-- The map associating to `a : R` the multiplicative shift of `ψ` by `a` is injective when `ψ` is primitive. -/ theorem to_mulShift_inj_of_isPrimitive {ψ : AddChar R R'} (hψ : IsPrimitive ψ) : Function.Injective ψ.mulShift := by intro a b h apply_fun fun x => x * mulShift ψ (-b) at h simp only [mulShift_mul, mulShift_zero, add_neg_cancel, mulShift_apply] at h simpa [← sub_eq_add_neg, sub_eq_zero] using (hψ · h) -- `AddCommGroup.equiv_direct_sum_zmod_of_fintype` -- gives the structure theorem for finite abelian groups. -- This could be used to show that the map above is a bijection. -- We leave this for a later occasion. /-- When `R` is a field `F`, then a nontrivial additive character is primitive -/ theorem IsPrimitive.of_ne_one {F : Type u} [Field F] {ψ : AddChar F R'} (hψ : ψ ≠ 1) : IsPrimitive ψ := fun a ha h ↦ hψ <\| by simpa [mulShift_mulShift, ha] using congr_arg (mulShift · a⁻¹) h /-- If `r` is not a unit, then `e.mulShift r` is not primitive. -/ lemma not_isPrimitive_mulShift [Finite R] (e : AddChar R R') {r : R} (hr : ¬ IsUnit r) : ¬ IsPrimitive (e.mulShift r) := by simp only [IsPrimitive, not_forall] simp only [isUnit_iff_mem_nonZeroDivisors_of_finite, mem_nonZeroDivisors_iff, not_forall] at hr	rcases hr with ⟨x, h, h'⟩ exact ⟨x, h', by simp only [mulShift_mulShift, mul_comm r, h, mulShift_zero, not_ne_iff]⟩ /-- Definition for a primitive additive character on a finite ring `R` into a cyclotomic extension of a field `R'`. It records which cyclotomic extension it is, the character, and the fact that the character is primitive. -/ structure PrimitiveAddChar (R : Type u) [CommRing R] (R' : Type v) [Field R'] where	Mathlib/NumberTheory/LegendreSymbol/AddCharacter.lean	89	95
/- Copyright (c) 2019 Calle Sönne. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Calle Sönne -/ import Mathlib.Analysis.SpecialFunctions.Trigonometric.Basic import Mathlib.Analysis.Normed.Group.AddCircle import Mathlib.Algebra.CharZero.Quotient import Mathlib.Topology.Instances.Sign /-! # The type of angles In this file we define `Real.Angle` to be the quotient group `ℝ/2πℤ` and prove a few simple lemmas about trigonometric functions and angles. -/ open Real noncomputable section namespace Real /-- The type of angles -/ def Angle : Type := AddCircle (2 * π) -- The `NormedAddCommGroup, Inhabited` instances should be constructed by a deriving handler. -- https://github.com/leanprover-community/mathlib4/issues/380 namespace Angle instance : NormedAddCommGroup Angle := inferInstanceAs (NormedAddCommGroup (AddCircle (2 * π))) instance : Inhabited Angle := inferInstanceAs (Inhabited (AddCircle (2 * π))) /-- The canonical map from `ℝ` to the quotient `Angle`. -/ @[coe] protected def coe (r : ℝ) : Angle := QuotientAddGroup.mk r instance : Coe ℝ Angle := ⟨Angle.coe⟩ instance : CircularOrder Real.Angle := QuotientAddGroup.circularOrder (hp' := ⟨by norm_num [pi_pos]⟩) @[continuity] theorem continuous_coe : Continuous ((↑) : ℝ → Angle) := continuous_quotient_mk' /-- Coercion `ℝ → Angle` as an additive homomorphism. -/ def coeHom : ℝ →+ Angle := QuotientAddGroup.mk' _ @[simp] theorem coe_coeHom : (coeHom : ℝ → Angle) = ((↑) : ℝ → Angle) := rfl /-- An induction principle to deduce results for `Angle` from those for `ℝ`, used with `induction θ using Real.Angle.induction_on`. -/ @[elab_as_elim] protected theorem induction_on {p : Angle → Prop} (θ : Angle) (h : ∀ x : ℝ, p x) : p θ := Quotient.inductionOn' θ h @[simp] theorem coe_zero : ↑(0 : ℝ) = (0 : Angle) := rfl @[simp] theorem coe_add (x y : ℝ) : ↑(x + y : ℝ) = (↑x + ↑y : Angle) := rfl @[simp] theorem coe_neg (x : ℝ) : ↑(-x : ℝ) = -(↑x : Angle) := rfl @[simp] theorem coe_sub (x y : ℝ) : ↑(x - y : ℝ) = (↑x - ↑y : Angle) := rfl theorem coe_nsmul (n : ℕ) (x : ℝ) : ↑(n • x : ℝ) = n • (↑x : Angle) := rfl theorem coe_zsmul (z : ℤ) (x : ℝ) : ↑(z • x : ℝ) = z • (↑x : Angle) := rfl theorem coe_eq_zero_iff {x : ℝ} : (x : Angle) = 0 ↔ ∃ n : ℤ, n • (2 * π) = x := AddCircle.coe_eq_zero_iff (2 * π) @[simp, norm_cast] theorem natCast_mul_eq_nsmul (x : ℝ) (n : ℕ) : ↑((n : ℝ) * x) = n • (↑x : Angle) := by simpa only [nsmul_eq_mul] using coeHom.map_nsmul x n @[simp, norm_cast] theorem intCast_mul_eq_zsmul (x : ℝ) (n : ℤ) : ↑((n : ℝ) * x : ℝ) = n • (↑x : Angle) := by simpa only [zsmul_eq_mul] using coeHom.map_zsmul x n theorem angle_eq_iff_two_pi_dvd_sub {ψ θ : ℝ} : (θ : Angle) = ψ ↔ ∃ k : ℤ, θ - ψ = 2 * π * k := by simp only [QuotientAddGroup.eq, AddSubgroup.zmultiples_eq_closure, AddSubgroup.mem_closure_singleton, zsmul_eq_mul', (sub_eq_neg_add _ _).symm, eq_comm] rw [Angle.coe, Angle.coe, QuotientAddGroup.eq] simp only [AddSubgroup.zmultiples_eq_closure, AddSubgroup.mem_closure_singleton, zsmul_eq_mul', (sub_eq_neg_add _ _).symm, eq_comm] @[simp] theorem coe_two_pi : ↑(2 * π : ℝ) = (0 : Angle) := angle_eq_iff_two_pi_dvd_sub.2 ⟨1, by rw [sub_zero, Int.cast_one, mul_one]⟩ @[simp] theorem neg_coe_pi : -(π : Angle) = π := by rw [← coe_neg, angle_eq_iff_two_pi_dvd_sub] use -1 simp [two_mul, sub_eq_add_neg] @[simp] theorem two_nsmul_coe_div_two (θ : ℝ) : (2 : ℕ) • (↑(θ / 2) : Angle) = θ := by rw [← coe_nsmul, two_nsmul, add_halves] @[simp] theorem two_zsmul_coe_div_two (θ : ℝ) : (2 : ℤ) • (↑(θ / 2) : Angle) = θ := by rw [← coe_zsmul, two_zsmul, add_halves] theorem two_nsmul_neg_pi_div_two : (2 : ℕ) • (↑(-π / 2) : Angle) = π := by rw [two_nsmul_coe_div_two, coe_neg, neg_coe_pi] theorem two_zsmul_neg_pi_div_two : (2 : ℤ) • (↑(-π / 2) : Angle) = π := by rw [two_zsmul, ← two_nsmul, two_nsmul_neg_pi_div_two] theorem sub_coe_pi_eq_add_coe_pi (θ : Angle) : θ - π = θ + π := by rw [sub_eq_add_neg, neg_coe_pi] @[simp] theorem two_nsmul_coe_pi : (2 : ℕ) • (π : Angle) = 0 := by simp [← natCast_mul_eq_nsmul] @[simp] theorem two_zsmul_coe_pi : (2 : ℤ) • (π : Angle) = 0 := by simp [← intCast_mul_eq_zsmul] @[simp] theorem coe_pi_add_coe_pi : (π : Real.Angle) + π = 0 := by rw [← two_nsmul, two_nsmul_coe_pi] theorem zsmul_eq_iff {ψ θ : Angle} {z : ℤ} (hz : z ≠ 0) : z • ψ = z • θ ↔ ∃ k : Fin z.natAbs, ψ = θ + (k : ℕ) • (2 * π / z : ℝ) := QuotientAddGroup.zmultiples_zsmul_eq_zsmul_iff hz theorem nsmul_eq_iff {ψ θ : Angle} {n : ℕ} (hz : n ≠ 0) : n • ψ = n • θ ↔ ∃ k : Fin n, ψ = θ + (k : ℕ) • (2 * π / n : ℝ) := QuotientAddGroup.zmultiples_nsmul_eq_nsmul_iff hz theorem two_zsmul_eq_iff {ψ θ : Angle} : (2 : ℤ) • ψ = (2 : ℤ) • θ ↔ ψ = θ ∨ ψ = θ + ↑π := by have : Int.natAbs 2 = 2 := rfl rw [zsmul_eq_iff two_ne_zero, this, Fin.exists_fin_two, Fin.val_zero, Fin.val_one, zero_smul, add_zero, one_smul, Int.cast_two, mul_div_cancel_left₀ (_ : ℝ) two_ne_zero] theorem two_nsmul_eq_iff {ψ θ : Angle} : (2 : ℕ) • ψ = (2 : ℕ) • θ ↔ ψ = θ ∨ ψ = θ + ↑π := by simp_rw [← natCast_zsmul, Nat.cast_ofNat, two_zsmul_eq_iff] theorem two_nsmul_eq_zero_iff {θ : Angle} : (2 : ℕ) • θ = 0 ↔ θ = 0 ∨ θ = π := by convert two_nsmul_eq_iff <;> simp theorem two_nsmul_ne_zero_iff {θ : Angle} : (2 : ℕ) • θ ≠ 0 ↔ θ ≠ 0 ∧ θ ≠ π := by rw [← not_or, ← two_nsmul_eq_zero_iff] theorem two_zsmul_eq_zero_iff {θ : Angle} : (2 : ℤ) • θ = 0 ↔ θ = 0 ∨ θ = π := by simp_rw [two_zsmul, ← two_nsmul, two_nsmul_eq_zero_iff] theorem two_zsmul_ne_zero_iff {θ : Angle} : (2 : ℤ) • θ ≠ 0 ↔ θ ≠ 0 ∧ θ ≠ π := by rw [← not_or, ← two_zsmul_eq_zero_iff] theorem eq_neg_self_iff {θ : Angle} : θ = -θ ↔ θ = 0 ∨ θ = π := by rw [← add_eq_zero_iff_eq_neg, ← two_nsmul, two_nsmul_eq_zero_iff] theorem ne_neg_self_iff {θ : Angle} : θ ≠ -θ ↔ θ ≠ 0 ∧ θ ≠ π := by rw [← not_or, ← eq_neg_self_iff.not] theorem neg_eq_self_iff {θ : Angle} : -θ = θ ↔ θ = 0 ∨ θ = π := by rw [eq_comm, eq_neg_self_iff] theorem neg_ne_self_iff {θ : Angle} : -θ ≠ θ ↔ θ ≠ 0 ∧ θ ≠ π := by rw [← not_or, ← neg_eq_self_iff.not] theorem two_nsmul_eq_pi_iff {θ : Angle} : (2 : ℕ) • θ = π ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by have h : (π : Angle) = ((2 : ℕ) • (π / 2 : ℝ):) := by rw [two_nsmul, add_halves] nth_rw 1 [h] rw [coe_nsmul, two_nsmul_eq_iff] -- Porting note: `congr` didn't simplify the goal of iff of `Or`s convert Iff.rfl rw [add_comm, ← coe_add, ← sub_eq_zero, ← coe_sub, neg_div, ← neg_sub, sub_neg_eq_add, add_assoc, add_halves, ← two_mul, coe_neg, coe_two_pi, neg_zero] theorem two_zsmul_eq_pi_iff {θ : Angle} : (2 : ℤ) • θ = π ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by rw [two_zsmul, ← two_nsmul, two_nsmul_eq_pi_iff] theorem cos_eq_iff_coe_eq_or_eq_neg {θ ψ : ℝ} : cos θ = cos ψ ↔ (θ : Angle) = ψ ∨ (θ : Angle) = -ψ := by constructor · intro Hcos rw [← sub_eq_zero, cos_sub_cos, mul_eq_zero, mul_eq_zero, neg_eq_zero, eq_false (two_ne_zero' ℝ), false_or, sin_eq_zero_iff, sin_eq_zero_iff] at Hcos rcases Hcos with (⟨n, hn⟩ \| ⟨n, hn⟩) · right rw [eq_div_iff_mul_eq (two_ne_zero' ℝ), ← sub_eq_iff_eq_add] at hn rw [← hn, coe_sub, eq_neg_iff_add_eq_zero, sub_add_cancel, mul_assoc, intCast_mul_eq_zsmul, mul_comm, coe_two_pi, zsmul_zero] · left rw [eq_div_iff_mul_eq (two_ne_zero' ℝ), eq_sub_iff_add_eq] at hn rw [← hn, coe_add, mul_assoc, intCast_mul_eq_zsmul, mul_comm, coe_two_pi, zsmul_zero, zero_add] · rw [angle_eq_iff_two_pi_dvd_sub, ← coe_neg, angle_eq_iff_two_pi_dvd_sub] rintro (⟨k, H⟩ \| ⟨k, H⟩) · rw [← sub_eq_zero, cos_sub_cos, H, mul_assoc 2 π k, mul_div_cancel_left₀ _ (two_ne_zero' ℝ), mul_comm π _, sin_int_mul_pi, mul_zero] rw [← sub_eq_zero, cos_sub_cos, ← sub_neg_eq_add, H, mul_assoc 2 π k, mul_div_cancel_left₀ _ (two_ne_zero' ℝ), mul_comm π _, sin_int_mul_pi, mul_zero, zero_mul] theorem sin_eq_iff_coe_eq_or_add_eq_pi {θ ψ : ℝ} : sin θ = sin ψ ↔ (θ : Angle) = ψ ∨ (θ : Angle) + ψ = π := by constructor · intro Hsin rw [← cos_pi_div_two_sub, ← cos_pi_div_two_sub] at Hsin rcases cos_eq_iff_coe_eq_or_eq_neg.mp Hsin with h \| h · left rw [coe_sub, coe_sub] at h exact sub_right_inj.1 h right rw [coe_sub, coe_sub, eq_neg_iff_add_eq_zero, add_sub, sub_add_eq_add_sub, ← coe_add, add_halves, sub_sub, sub_eq_zero] at h exact h.symm · rw [angle_eq_iff_two_pi_dvd_sub, ← eq_sub_iff_add_eq, ← coe_sub, angle_eq_iff_two_pi_dvd_sub] rintro (⟨k, H⟩ \| ⟨k, H⟩) · rw [← sub_eq_zero, sin_sub_sin, H, mul_assoc 2 π k, mul_div_cancel_left₀ _ (two_ne_zero' ℝ), mul_comm π _, sin_int_mul_pi, mul_zero, zero_mul] have H' : θ + ψ = 2 * k * π + π := by rwa [← sub_add, sub_add_eq_add_sub, sub_eq_iff_eq_add, mul_assoc, mul_comm π _, ← mul_assoc] at H rw [← sub_eq_zero, sin_sub_sin, H', add_div, mul_assoc 2 _ π, mul_div_cancel_left₀ _ (two_ne_zero' ℝ), cos_add_pi_div_two, sin_int_mul_pi, neg_zero, mul_zero] theorem cos_sin_inj {θ ψ : ℝ} (Hcos : cos θ = cos ψ) (Hsin : sin θ = sin ψ) : (θ : Angle) = ψ := by rcases cos_eq_iff_coe_eq_or_eq_neg.mp Hcos with hc \| hc; · exact hc rcases sin_eq_iff_coe_eq_or_add_eq_pi.mp Hsin with hs \| hs; · exact hs rw [eq_neg_iff_add_eq_zero, hs] at hc obtain ⟨n, hn⟩ : ∃ n, n • _ = _ := QuotientAddGroup.leftRel_apply.mp (Quotient.exact' hc) rw [← neg_one_mul, add_zero, ← sub_eq_zero, zsmul_eq_mul, ← mul_assoc, ← sub_mul, mul_eq_zero, eq_false (ne_of_gt pi_pos), or_false, sub_neg_eq_add, ← Int.cast_zero, ← Int.cast_one, ← Int.cast_ofNat, ← Int.cast_mul, ← Int.cast_add, Int.cast_inj] at hn have : (n * 2 + 1) % (2 : ℤ) = 0 % (2 : ℤ) := congr_arg (· % (2 : ℤ)) hn rw [add_comm, Int.add_mul_emod_self_right] at this exact absurd this one_ne_zero /-- The sine of a `Real.Angle`. -/ def sin (θ : Angle) : ℝ := sin_periodic.lift θ @[simp] theorem sin_coe (x : ℝ) : sin (x : Angle) = Real.sin x := rfl @[continuity] theorem continuous_sin : Continuous sin := Real.continuous_sin.quotient_liftOn' _ /-- The cosine of a `Real.Angle`. -/ def cos (θ : Angle) : ℝ := cos_periodic.lift θ @[simp] theorem cos_coe (x : ℝ) : cos (x : Angle) = Real.cos x := rfl @[continuity] theorem continuous_cos : Continuous cos := Real.continuous_cos.quotient_liftOn' _ theorem cos_eq_real_cos_iff_eq_or_eq_neg {θ : Angle} {ψ : ℝ} : cos θ = Real.cos ψ ↔ θ = ψ ∨ θ = -ψ := by induction θ using Real.Angle.induction_on exact cos_eq_iff_coe_eq_or_eq_neg theorem cos_eq_iff_eq_or_eq_neg {θ ψ : Angle} : cos θ = cos ψ ↔ θ = ψ ∨ θ = -ψ := by induction ψ using Real.Angle.induction_on exact cos_eq_real_cos_iff_eq_or_eq_neg theorem sin_eq_real_sin_iff_eq_or_add_eq_pi {θ : Angle} {ψ : ℝ} : sin θ = Real.sin ψ ↔ θ = ψ ∨ θ + ψ = π := by induction θ using Real.Angle.induction_on exact sin_eq_iff_coe_eq_or_add_eq_pi theorem sin_eq_iff_eq_or_add_eq_pi {θ ψ : Angle} : sin θ = sin ψ ↔ θ = ψ ∨ θ + ψ = π := by induction ψ using Real.Angle.induction_on exact sin_eq_real_sin_iff_eq_or_add_eq_pi @[simp] theorem sin_zero : sin (0 : Angle) = 0 := by rw [← coe_zero, sin_coe, Real.sin_zero] theorem sin_coe_pi : sin (π : Angle) = 0 := by rw [sin_coe, Real.sin_pi] theorem sin_eq_zero_iff {θ : Angle} : sin θ = 0 ↔ θ = 0 ∨ θ = π := by nth_rw 1 [← sin_zero] rw [sin_eq_iff_eq_or_add_eq_pi] simp theorem sin_ne_zero_iff {θ : Angle} : sin θ ≠ 0 ↔ θ ≠ 0 ∧ θ ≠ π := by rw [← not_or, ← sin_eq_zero_iff] @[simp] theorem sin_neg (θ : Angle) : sin (-θ) = -sin θ := by induction θ using Real.Angle.induction_on exact Real.sin_neg _ theorem sin_antiperiodic : Function.Antiperiodic sin (π : Angle) := by intro θ induction θ using Real.Angle.induction_on exact Real.sin_antiperiodic _ @[simp] theorem sin_add_pi (θ : Angle) : sin (θ + π) = -sin θ := sin_antiperiodic θ @[simp] theorem sin_sub_pi (θ : Angle) : sin (θ - π) = -sin θ := sin_antiperiodic.sub_eq θ @[simp] theorem cos_zero : cos (0 : Angle) = 1 := by rw [← coe_zero, cos_coe, Real.cos_zero] theorem cos_coe_pi : cos (π : Angle) = -1 := by rw [cos_coe, Real.cos_pi] @[simp] theorem cos_neg (θ : Angle) : cos (-θ) = cos θ := by induction θ using Real.Angle.induction_on exact Real.cos_neg _ theorem cos_antiperiodic : Function.Antiperiodic cos (π : Angle) := by intro θ induction θ using Real.Angle.induction_on exact Real.cos_antiperiodic _ @[simp] theorem cos_add_pi (θ : Angle) : cos (θ + π) = -cos θ := cos_antiperiodic θ @[simp] theorem cos_sub_pi (θ : Angle) : cos (θ - π) = -cos θ := cos_antiperiodic.sub_eq θ theorem cos_eq_zero_iff {θ : Angle} : cos θ = 0 ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by rw [← cos_pi_div_two, ← cos_coe, cos_eq_iff_eq_or_eq_neg, ← coe_neg, ← neg_div] theorem sin_add (θ₁ θ₂ : Real.Angle) : sin (θ₁ + θ₂) = sin θ₁ * cos θ₂ + cos θ₁ * sin θ₂ := by induction θ₁ using Real.Angle.induction_on induction θ₂ using Real.Angle.induction_on exact Real.sin_add _ _ theorem cos_add (θ₁ θ₂ : Real.Angle) : cos (θ₁ + θ₂) = cos θ₁ * cos θ₂ - sin θ₁ * sin θ₂ := by induction θ₂ using Real.Angle.induction_on induction θ₁ using Real.Angle.induction_on exact Real.cos_add _ _ @[simp] theorem cos_sq_add_sin_sq (θ : Real.Angle) : cos θ ^ 2 + sin θ ^ 2 = 1 := by induction θ using Real.Angle.induction_on exact Real.cos_sq_add_sin_sq _ theorem sin_add_pi_div_two (θ : Angle) : sin (θ + ↑(π / 2)) = cos θ := by induction θ using Real.Angle.induction_on exact Real.sin_add_pi_div_two _ theorem sin_sub_pi_div_two (θ : Angle) : sin (θ - ↑(π / 2)) = -cos θ := by induction θ using Real.Angle.induction_on exact Real.sin_sub_pi_div_two _ theorem sin_pi_div_two_sub (θ : Angle) : sin (↑(π / 2) - θ) = cos θ := by induction θ using Real.Angle.induction_on exact Real.sin_pi_div_two_sub _ theorem cos_add_pi_div_two (θ : Angle) : cos (θ + ↑(π / 2)) = -sin θ := by induction θ using Real.Angle.induction_on exact Real.cos_add_pi_div_two _ theorem cos_sub_pi_div_two (θ : Angle) : cos (θ - ↑(π / 2)) = sin θ := by induction θ using Real.Angle.induction_on exact Real.cos_sub_pi_div_two _ theorem cos_pi_div_two_sub (θ : Angle) : cos (↑(π / 2) - θ) = sin θ := by induction θ using Real.Angle.induction_on exact Real.cos_pi_div_two_sub _ theorem abs_sin_eq_of_two_nsmul_eq {θ ψ : Angle} (h : (2 : ℕ) • θ = (2 : ℕ) • ψ) : \|sin θ\| = \|sin ψ\| := by rw [two_nsmul_eq_iff] at h rcases h with (rfl \| rfl) · rfl · rw [sin_add_pi, abs_neg] theorem abs_sin_eq_of_two_zsmul_eq {θ ψ : Angle} (h : (2 : ℤ) • θ = (2 : ℤ) • ψ) : \|sin θ\| = \|sin ψ\| := by simp_rw [two_zsmul, ← two_nsmul] at h exact abs_sin_eq_of_two_nsmul_eq h theorem abs_cos_eq_of_two_nsmul_eq {θ ψ : Angle} (h : (2 : ℕ) • θ = (2 : ℕ) • ψ) : \|cos θ\| = \|cos ψ\| := by rw [two_nsmul_eq_iff] at h rcases h with (rfl \| rfl) · rfl · rw [cos_add_pi, abs_neg] theorem abs_cos_eq_of_two_zsmul_eq {θ ψ : Angle} (h : (2 : ℤ) • θ = (2 : ℤ) • ψ) : \|cos θ\| = \|cos ψ\| := by simp_rw [two_zsmul, ← two_nsmul] at h exact abs_cos_eq_of_two_nsmul_eq h @[simp] theorem coe_toIcoMod (θ ψ : ℝ) : ↑(toIcoMod two_pi_pos ψ θ) = (θ : Angle) := by rw [angle_eq_iff_two_pi_dvd_sub] refine ⟨-toIcoDiv two_pi_pos ψ θ, ?_⟩ rw [toIcoMod_sub_self, zsmul_eq_mul, mul_comm] @[simp] theorem coe_toIocMod (θ ψ : ℝ) : ↑(toIocMod two_pi_pos ψ θ) = (θ : Angle) := by rw [angle_eq_iff_two_pi_dvd_sub] refine ⟨-toIocDiv two_pi_pos ψ θ, ?_⟩ rw [toIocMod_sub_self, zsmul_eq_mul, mul_comm] /-- Convert a `Real.Angle` to a real number in the interval `Ioc (-π) π`. -/ def toReal (θ : Angle) : ℝ := (toIocMod_periodic two_pi_pos (-π)).lift θ theorem toReal_coe (θ : ℝ) : (θ : Angle).toReal = toIocMod two_pi_pos (-π) θ := rfl theorem toReal_coe_eq_self_iff {θ : ℝ} : (θ : Angle).toReal = θ ↔ -π < θ ∧ θ ≤ π := by rw [toReal_coe, toIocMod_eq_self two_pi_pos] ring_nf rfl theorem toReal_coe_eq_self_iff_mem_Ioc {θ : ℝ} : (θ : Angle).toReal = θ ↔ θ ∈ Set.Ioc (-π) π := by rw [toReal_coe_eq_self_iff, ← Set.mem_Ioc] theorem toReal_injective : Function.Injective toReal := by intro θ ψ h induction θ using Real.Angle.induction_on induction ψ using Real.Angle.induction_on simpa [toReal_coe, toIocMod_eq_toIocMod, zsmul_eq_mul, mul_comm _ (2 * π), ← angle_eq_iff_two_pi_dvd_sub, eq_comm] using h @[simp] theorem toReal_inj {θ ψ : Angle} : θ.toReal = ψ.toReal ↔ θ = ψ := toReal_injective.eq_iff @[simp] theorem coe_toReal (θ : Angle) : (θ.toReal : Angle) = θ := by induction θ using Real.Angle.induction_on exact coe_toIocMod _ _ theorem neg_pi_lt_toReal (θ : Angle) : -π < θ.toReal := by induction θ using Real.Angle.induction_on exact left_lt_toIocMod _ _ _ theorem toReal_le_pi (θ : Angle) : θ.toReal ≤ π := by induction θ using Real.Angle.induction_on convert toIocMod_le_right two_pi_pos _ _ ring theorem abs_toReal_le_pi (θ : Angle) : \|θ.toReal\| ≤ π := abs_le.2 ⟨(neg_pi_lt_toReal _).le, toReal_le_pi _⟩ theorem toReal_mem_Ioc (θ : Angle) : θ.toReal ∈ Set.Ioc (-π) π := ⟨neg_pi_lt_toReal _, toReal_le_pi _⟩ @[simp] theorem toIocMod_toReal (θ : Angle) : toIocMod two_pi_pos (-π) θ.toReal = θ.toReal := by induction θ using Real.Angle.induction_on rw [toReal_coe] exact toIocMod_toIocMod _ _ _ _ @[simp] theorem toReal_zero : (0 : Angle).toReal = 0 := by rw [← coe_zero, toReal_coe_eq_self_iff] exact ⟨Left.neg_neg_iff.2 Real.pi_pos, Real.pi_pos.le⟩ @[simp] theorem toReal_eq_zero_iff {θ : Angle} : θ.toReal = 0 ↔ θ = 0 := by nth_rw 1 [← toReal_zero] exact toReal_inj @[simp] theorem toReal_pi : (π : Angle).toReal = π := by rw [toReal_coe_eq_self_iff] exact ⟨Left.neg_lt_self Real.pi_pos, le_refl _⟩ @[simp] theorem toReal_eq_pi_iff {θ : Angle} : θ.toReal = π ↔ θ = π := by rw [← toReal_inj, toReal_pi] theorem pi_ne_zero : (π : Angle) ≠ 0 := by rw [← toReal_injective.ne_iff, toReal_pi, toReal_zero] exact Real.pi_ne_zero @[simp] theorem toReal_pi_div_two : ((π / 2 : ℝ) : Angle).toReal = π / 2 := toReal_coe_eq_self_iff.2 <\| by constructor <;> linarith [pi_pos] @[simp] theorem toReal_eq_pi_div_two_iff {θ : Angle} : θ.toReal = π / 2 ↔ θ = (π / 2 : ℝ) := by rw [← toReal_inj, toReal_pi_div_two] @[simp] theorem toReal_neg_pi_div_two : ((-π / 2 : ℝ) : Angle).toReal = -π / 2 := toReal_coe_eq_self_iff.2 <\| by constructor <;> linarith [pi_pos] @[simp] theorem toReal_eq_neg_pi_div_two_iff {θ : Angle} : θ.toReal = -π / 2 ↔ θ = (-π / 2 : ℝ) := by rw [← toReal_inj, toReal_neg_pi_div_two] theorem pi_div_two_ne_zero : ((π / 2 : ℝ) : Angle) ≠ 0 := by rw [← toReal_injective.ne_iff, toReal_pi_div_two, toReal_zero] exact div_ne_zero Real.pi_ne_zero two_ne_zero theorem neg_pi_div_two_ne_zero : ((-π / 2 : ℝ) : Angle) ≠ 0 := by rw [← toReal_injective.ne_iff, toReal_neg_pi_div_two, toReal_zero] exact div_ne_zero (neg_ne_zero.2 Real.pi_ne_zero) two_ne_zero theorem abs_toReal_coe_eq_self_iff {θ : ℝ} : \|(θ : Angle).toReal\| = θ ↔ 0 ≤ θ ∧ θ ≤ π := ⟨fun h => h ▸ ⟨abs_nonneg _, abs_toReal_le_pi _⟩, fun h => (toReal_coe_eq_self_iff.2 ⟨(Left.neg_neg_iff.2 Real.pi_pos).trans_le h.1, h.2⟩).symm ▸ abs_eq_self.2 h.1⟩ theorem abs_toReal_neg_coe_eq_self_iff {θ : ℝ} : \|(-θ : Angle).toReal\| = θ ↔ 0 ≤ θ ∧ θ ≤ π := by refine ⟨fun h => h ▸ ⟨abs_nonneg _, abs_toReal_le_pi _⟩, fun h => ?_⟩ by_cases hnegpi : θ = π; · simp [hnegpi, Real.pi_pos.le] rw [← coe_neg, toReal_coe_eq_self_iff.2 ⟨neg_lt_neg (lt_of_le_of_ne h.2 hnegpi), (neg_nonpos.2 h.1).trans Real.pi_pos.le⟩, abs_neg, abs_eq_self.2 h.1] theorem abs_toReal_eq_pi_div_two_iff {θ : Angle} : \|θ.toReal\| = π / 2 ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by rw [abs_eq (div_nonneg Real.pi_pos.le two_pos.le), ← neg_div, toReal_eq_pi_div_two_iff, toReal_eq_neg_pi_div_two_iff] theorem nsmul_toReal_eq_mul {n : ℕ} (h : n ≠ 0) {θ : Angle} : (n • θ).toReal = n * θ.toReal ↔ θ.toReal ∈ Set.Ioc (-π / n) (π / n) := by nth_rw 1 [← coe_toReal θ] have h' : 0 < (n : ℝ) := mod_cast Nat.pos_of_ne_zero h rw [← coe_nsmul, nsmul_eq_mul, toReal_coe_eq_self_iff, Set.mem_Ioc, div_lt_iff₀' h', le_div_iff₀' h'] theorem two_nsmul_toReal_eq_two_mul {θ : Angle} : ((2 : ℕ) • θ).toReal = 2 * θ.toReal ↔ θ.toReal ∈ Set.Ioc (-π / 2) (π / 2) := mod_cast nsmul_toReal_eq_mul two_ne_zero theorem two_zsmul_toReal_eq_two_mul {θ : Angle} : ((2 : ℤ) • θ).toReal = 2 * θ.toReal ↔ θ.toReal ∈ Set.Ioc (-π / 2) (π / 2) := by rw [two_zsmul, ← two_nsmul, two_nsmul_toReal_eq_two_mul] theorem toReal_coe_eq_self_sub_two_mul_int_mul_pi_iff {θ : ℝ} {k : ℤ} : (θ : Angle).toReal = θ - 2 * k * π ↔ θ ∈ Set.Ioc ((2 * k - 1 : ℝ) * π) ((2 * k + 1) * π) := by rw [← sub_zero (θ : Angle), ← zsmul_zero k, ← coe_two_pi, ← coe_zsmul, ← coe_sub, zsmul_eq_mul, ← mul_assoc, mul_comm (k : ℝ), toReal_coe_eq_self_iff, Set.mem_Ioc] exact ⟨fun h => ⟨by linarith, by linarith⟩, fun h => ⟨by linarith, by linarith⟩⟩ theorem toReal_coe_eq_self_sub_two_pi_iff {θ : ℝ} : (θ : Angle).toReal = θ - 2 * π ↔ θ ∈ Set.Ioc π (3 * π) := by convert @toReal_coe_eq_self_sub_two_mul_int_mul_pi_iff θ 1 <;> norm_num theorem toReal_coe_eq_self_add_two_pi_iff {θ : ℝ} : (θ : Angle).toReal = θ + 2 * π ↔ θ ∈ Set.Ioc (-3 * π) (-π) := by convert @toReal_coe_eq_self_sub_two_mul_int_mul_pi_iff θ (-1) using 2 <;> norm_num theorem two_nsmul_toReal_eq_two_mul_sub_two_pi {θ : Angle} : ((2 : ℕ) • θ).toReal = 2 * θ.toReal - 2 * π ↔ π / 2 < θ.toReal := by nth_rw 1 [← coe_toReal θ] rw [← coe_nsmul, two_nsmul, ← two_mul, toReal_coe_eq_self_sub_two_pi_iff, Set.mem_Ioc] exact ⟨fun h => by linarith, fun h => ⟨(div_lt_iff₀' (zero_lt_two' ℝ)).1 h, by linarith [pi_pos, toReal_le_pi θ]⟩⟩ theorem two_zsmul_toReal_eq_two_mul_sub_two_pi {θ : Angle} : ((2 : ℤ) • θ).toReal = 2 * θ.toReal - 2 * π ↔ π / 2 < θ.toReal := by rw [two_zsmul, ← two_nsmul, two_nsmul_toReal_eq_two_mul_sub_two_pi] theorem two_nsmul_toReal_eq_two_mul_add_two_pi {θ : Angle} : ((2 : ℕ) • θ).toReal = 2 * θ.toReal + 2 * π ↔ θ.toReal ≤ -π / 2 := by nth_rw 1 [← coe_toReal θ] rw [← coe_nsmul, two_nsmul, ← two_mul, toReal_coe_eq_self_add_two_pi_iff, Set.mem_Ioc] refine ⟨fun h => by linarith, fun h => ⟨by linarith [pi_pos, neg_pi_lt_toReal θ], (le_div_iff₀' (zero_lt_two' ℝ)).1 h⟩⟩ theorem two_zsmul_toReal_eq_two_mul_add_two_pi {θ : Angle} : ((2 : ℤ) • θ).toReal = 2 * θ.toReal + 2 * π ↔ θ.toReal ≤ -π / 2 := by rw [two_zsmul, ← two_nsmul, two_nsmul_toReal_eq_two_mul_add_two_pi] @[simp] theorem sin_toReal (θ : Angle) : Real.sin θ.toReal = sin θ := by conv_rhs => rw [← coe_toReal θ, sin_coe] @[simp] theorem cos_toReal (θ : Angle) : Real.cos θ.toReal = cos θ := by conv_rhs => rw [← coe_toReal θ, cos_coe] theorem cos_nonneg_iff_abs_toReal_le_pi_div_two {θ : Angle} : 0 ≤ cos θ ↔ \|θ.toReal\| ≤ π / 2 := by nth_rw 1 [← coe_toReal θ] rw [abs_le, cos_coe] refine ⟨fun h => ?_, cos_nonneg_of_mem_Icc⟩ by_contra hn rw [not_and_or, not_le, not_le] at hn refine (not_lt.2 h) ?_ rcases hn with (hn \| hn) · rw [← Real.cos_neg] refine cos_neg_of_pi_div_two_lt_of_lt (by linarith) ?_ linarith [neg_pi_lt_toReal θ] · refine cos_neg_of_pi_div_two_lt_of_lt hn ?_ linarith [toReal_le_pi θ] theorem cos_pos_iff_abs_toReal_lt_pi_div_two {θ : Angle} : 0 < cos θ ↔ \|θ.toReal\| < π / 2 := by rw [lt_iff_le_and_ne, lt_iff_le_and_ne, cos_nonneg_iff_abs_toReal_le_pi_div_two, ← and_congr_right] rintro - rw [Ne, Ne, not_iff_not, @eq_comm ℝ 0, abs_toReal_eq_pi_div_two_iff, cos_eq_zero_iff] theorem cos_neg_iff_pi_div_two_lt_abs_toReal {θ : Angle} : cos θ < 0 ↔ π / 2 < \|θ.toReal\| := by rw [← not_le, ← not_le, not_iff_not, cos_nonneg_iff_abs_toReal_le_pi_div_two] theorem abs_cos_eq_abs_sin_of_two_nsmul_add_two_nsmul_eq_pi {θ ψ : Angle} (h : (2 : ℕ) • θ + (2 : ℕ) • ψ = π) : \|cos θ\| = \|sin ψ\| := by rw [← eq_sub_iff_add_eq, ← two_nsmul_coe_div_two, ← nsmul_sub, two_nsmul_eq_iff] at h rcases h with (rfl \| rfl) <;> simp [cos_pi_div_two_sub] theorem abs_cos_eq_abs_sin_of_two_zsmul_add_two_zsmul_eq_pi {θ ψ : Angle} (h : (2 : ℤ) • θ + (2 : ℤ) • ψ = π) : \|cos θ\| = \|sin ψ\| := by simp_rw [two_zsmul, ← two_nsmul] at h exact abs_cos_eq_abs_sin_of_two_nsmul_add_two_nsmul_eq_pi h /-- The tangent of a `Real.Angle`. -/ def tan (θ : Angle) : ℝ := sin θ / cos θ theorem tan_eq_sin_div_cos (θ : Angle) : tan θ = sin θ / cos θ := rfl @[simp] theorem tan_coe (x : ℝ) : tan (x : Angle) = Real.tan x := by rw [tan, sin_coe, cos_coe, Real.tan_eq_sin_div_cos] @[simp] theorem tan_zero : tan (0 : Angle) = 0 := by rw [← coe_zero, tan_coe, Real.tan_zero] theorem tan_coe_pi : tan (π : Angle) = 0 := by rw [tan_coe, Real.tan_pi] theorem tan_periodic : Function.Periodic tan (π : Angle) := by intro θ induction θ using Real.Angle.induction_on rw [← coe_add, tan_coe, tan_coe] exact Real.tan_periodic _ @[simp] theorem tan_add_pi (θ : Angle) : tan (θ + π) = tan θ := tan_periodic θ @[simp] theorem tan_sub_pi (θ : Angle) : tan (θ - π) = tan θ := tan_periodic.sub_eq θ @[simp] theorem tan_toReal (θ : Angle) : Real.tan θ.toReal = tan θ := by conv_rhs => rw [← coe_toReal θ, tan_coe] theorem tan_eq_of_two_nsmul_eq {θ ψ : Angle} (h : (2 : ℕ) • θ = (2 : ℕ) • ψ) : tan θ = tan ψ := by rw [two_nsmul_eq_iff] at h rcases h with (rfl \| rfl) · rfl · exact tan_add_pi _ theorem tan_eq_of_two_zsmul_eq {θ ψ : Angle} (h : (2 : ℤ) • θ = (2 : ℤ) • ψ) : tan θ = tan ψ := by simp_rw [two_zsmul, ← two_nsmul] at h exact tan_eq_of_two_nsmul_eq h theorem tan_eq_inv_of_two_nsmul_add_two_nsmul_eq_pi {θ ψ : Angle} (h : (2 : ℕ) • θ + (2 : ℕ) • ψ = π) : tan ψ = (tan θ)⁻¹ := by induction θ using Real.Angle.induction_on induction ψ using Real.Angle.induction_on rw [← smul_add, ← coe_add, ← coe_nsmul, two_nsmul, ← two_mul, angle_eq_iff_two_pi_dvd_sub] at h rcases h with ⟨k, h⟩ rw [sub_eq_iff_eq_add, ← mul_inv_cancel_left₀ two_ne_zero π, mul_assoc, ← mul_add, mul_right_inj' (two_ne_zero' ℝ), ← eq_sub_iff_add_eq', mul_inv_cancel_left₀ two_ne_zero π, inv_mul_eq_div, mul_comm] at h rw [tan_coe, tan_coe, ← tan_pi_div_two_sub, h, add_sub_assoc, add_comm] exact Real.tan_periodic.int_mul _ _ theorem tan_eq_inv_of_two_zsmul_add_two_zsmul_eq_pi {θ ψ : Angle} (h : (2 : ℤ) • θ + (2 : ℤ) • ψ = π) : tan ψ = (tan θ)⁻¹ := by simp_rw [two_zsmul, ← two_nsmul] at h exact tan_eq_inv_of_two_nsmul_add_two_nsmul_eq_pi h /-- The sign of a `Real.Angle` is `0` if the angle is `0` or `π`, `1` if the angle is strictly between `0` and `π` and `-1` is the angle is strictly between `-π` and `0`. It is defined as the sign of the sine of the angle. -/ def sign (θ : Angle) : SignType := SignType.sign (sin θ) @[simp] theorem sign_zero : (0 : Angle).sign = 0 := by rw [sign, sin_zero, _root_.sign_zero] @[simp] theorem sign_coe_pi : (π : Angle).sign = 0 := by rw [sign, sin_coe_pi, _root_.sign_zero] @[simp] theorem sign_neg (θ : Angle) : (-θ).sign = -θ.sign := by simp_rw [sign, sin_neg, Left.sign_neg] theorem sign_antiperiodic : Function.Antiperiodic sign (π : Angle) := fun θ => by rw [sign, sign, sin_add_pi, Left.sign_neg] @[simp] theorem sign_add_pi (θ : Angle) : (θ + π).sign = -θ.sign := sign_antiperiodic θ @[simp] theorem sign_pi_add (θ : Angle) : ((π : Angle) + θ).sign = -θ.sign := by rw [add_comm, sign_add_pi] @[simp] theorem sign_sub_pi (θ : Angle) : (θ - π).sign = -θ.sign := sign_antiperiodic.sub_eq θ @[simp] theorem sign_pi_sub (θ : Angle) : ((π : Angle) - θ).sign = θ.sign := by simp [sign_antiperiodic.sub_eq'] theorem sign_eq_zero_iff {θ : Angle} : θ.sign = 0 ↔ θ = 0 ∨ θ = π := by rw [sign, _root_.sign_eq_zero_iff, sin_eq_zero_iff] theorem sign_ne_zero_iff {θ : Angle} : θ.sign ≠ 0 ↔ θ ≠ 0 ∧ θ ≠ π := by rw [← not_or, ← sign_eq_zero_iff] theorem toReal_neg_iff_sign_neg {θ : Angle} : θ.toReal < 0 ↔ θ.sign = -1 := by rw [sign, ← sin_toReal, sign_eq_neg_one_iff] rcases lt_trichotomy θ.toReal 0 with (h \| h \| h) · exact ⟨fun _ => Real.sin_neg_of_neg_of_neg_pi_lt h (neg_pi_lt_toReal θ), fun _ => h⟩ · simp [h] · exact ⟨fun hn => False.elim (h.asymm hn), fun hn => False.elim (hn.not_le (sin_nonneg_of_nonneg_of_le_pi h.le (toReal_le_pi θ)))⟩ theorem toReal_nonneg_iff_sign_nonneg {θ : Angle} : 0 ≤ θ.toReal ↔ 0 ≤ θ.sign := by rcases lt_trichotomy θ.toReal 0 with (h \| h \| h) · refine ⟨fun hn => False.elim (h.not_le hn), fun hn => ?_⟩ rw [toReal_neg_iff_sign_neg.1 h] at hn exact False.elim (hn.not_lt (by decide)) · simp [h, sign, ← sin_toReal] · refine ⟨fun _ => ?_, fun _ => h.le⟩ rw [sign, ← sin_toReal, sign_nonneg_iff] exact sin_nonneg_of_nonneg_of_le_pi h.le (toReal_le_pi θ) @[simp] theorem sign_toReal {θ : Angle} (h : θ ≠ π) : SignType.sign θ.toReal = θ.sign := by rcases lt_trichotomy θ.toReal 0 with (ht \| ht \| ht) · simp [ht, toReal_neg_iff_sign_neg.1 ht] · simp [sign, ht, ← sin_toReal] · rw [sign, ← sin_toReal, sign_pos ht, sign_pos (sin_pos_of_pos_of_lt_pi ht ((toReal_le_pi θ).lt_of_ne (toReal_eq_pi_iff.not.2 h)))] theorem coe_abs_toReal_of_sign_nonneg {θ : Angle} (h : 0 ≤ θ.sign) : ↑\|θ.toReal\| = θ := by rw [abs_eq_self.2 (toReal_nonneg_iff_sign_nonneg.2 h), coe_toReal] theorem neg_coe_abs_toReal_of_sign_nonpos {θ : Angle} (h : θ.sign ≤ 0) : -↑\|θ.toReal\| = θ := by rw [SignType.nonpos_iff] at h rcases h with (h \| h) · rw [abs_of_neg (toReal_neg_iff_sign_neg.2 h), coe_neg, neg_neg, coe_toReal] · rw [sign_eq_zero_iff] at h rcases h with (rfl \| rfl) <;> simp [abs_of_pos Real.pi_pos] theorem eq_iff_sign_eq_and_abs_toReal_eq {θ ψ : Angle} : θ = ψ ↔ θ.sign = ψ.sign ∧ \|θ.toReal\| = \|ψ.toReal\| := by refine ⟨?_, fun h => ?_⟩ · rintro rfl exact ⟨rfl, rfl⟩ rcases h with ⟨hs, hr⟩ rw [abs_eq_abs] at hr rcases hr with (hr \| hr) · exact toReal_injective hr · by_cases h : θ = π · rw [h, toReal_pi, ← neg_eq_iff_eq_neg] at hr exact False.elim ((neg_pi_lt_toReal ψ).ne hr) · by_cases h' : ψ = π · rw [h', toReal_pi] at hr exact False.elim ((neg_pi_lt_toReal θ).ne hr.symm) · rw [← sign_toReal h, ← sign_toReal h', hr, Left.sign_neg, SignType.neg_eq_self_iff, _root_.sign_eq_zero_iff, toReal_eq_zero_iff] at hs rw [hs, toReal_zero, neg_zero, toReal_eq_zero_iff] at hr rw [hr, hs] theorem eq_iff_abs_toReal_eq_of_sign_eq {θ ψ : Angle} (h : θ.sign = ψ.sign) : θ = ψ ↔ \|θ.toReal\| = \|ψ.toReal\| := by simpa [h] using @eq_iff_sign_eq_and_abs_toReal_eq θ ψ @[simp] theorem sign_coe_pi_div_two : (↑(π / 2) : Angle).sign = 1 := by rw [sign, sin_coe, sin_pi_div_two, sign_one] @[simp] theorem sign_coe_neg_pi_div_two : (↑(-π / 2) : Angle).sign = -1 := by rw [sign, sin_coe, neg_div, Real.sin_neg, sin_pi_div_two, Left.sign_neg, sign_one] theorem sign_coe_nonneg_of_nonneg_of_le_pi {θ : ℝ} (h0 : 0 ≤ θ) (hpi : θ ≤ π) : 0 ≤ (θ : Angle).sign := by rw [sign, sign_nonneg_iff] exact sin_nonneg_of_nonneg_of_le_pi h0 hpi theorem sign_neg_coe_nonpos_of_nonneg_of_le_pi {θ : ℝ} (h0 : 0 ≤ θ) (hpi : θ ≤ π) : (-θ : Angle).sign ≤ 0 := by rw [sign, sign_nonpos_iff, sin_neg, Left.neg_nonpos_iff] exact sin_nonneg_of_nonneg_of_le_pi h0 hpi theorem sign_two_nsmul_eq_sign_iff {θ : Angle} : ((2 : ℕ) • θ).sign = θ.sign ↔ θ = π ∨ \|θ.toReal\| < π / 2 := by by_cases hpi : θ = π; · simp [hpi] rw [or_iff_right hpi] refine ⟨fun h => ?_, fun h => ?_⟩ · by_contra hle	rw [not_lt, le_abs, le_neg] at hle have hpi' : θ.toReal ≠ π := by simpa using hpi rcases hle with (hle \| hle) <;> rcases hle.eq_or_lt with (heq \| hlt)	Mathlib/Analysis/SpecialFunctions/Trigonometric/Angle.lean	825	827
/- Copyright (c) 2023 Oliver Nash. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Emilie Uthaiwat, Oliver Nash -/ import Mathlib.Algebra.Polynomial.AlgebraMap import Mathlib.Algebra.Polynomial.Div import Mathlib.Algebra.Polynomial.Identities import Mathlib.RingTheory.Ideal.Quotient.Operations import Mathlib.RingTheory.Nilpotent.Basic import Mathlib.RingTheory.Nilpotent.Lemmas import Mathlib.RingTheory.Polynomial.Tower /-! # Nilpotency in polynomial rings. This file is a place for results related to nilpotency in (single-variable) polynomial rings. ## Main results: * `Polynomial.isNilpotent_iff` * `Polynomial.isUnit_iff_coeff_isUnit_isNilpotent` -/ namespace Polynomial variable {R : Type} {r : R} section Semiring variable [Semiring R] {P : R[X]} lemma isNilpotent_C_mul_pow_X_of_isNilpotent (n : ℕ) (hnil : IsNilpotent r) : IsNilpotent ((C r) X ^ n) := by refine Commute.isNilpotent_mul_left (commute_X_pow _ _).symm ?_ obtain ⟨m, hm⟩ := hnil refine ⟨m, ?_⟩ rw [← C_pow, hm, C_0] lemma isNilpotent_pow_X_mul_C_of_isNilpotent (n : ℕ) (hnil : IsNilpotent r) : IsNilpotent (X ^ n * (C r)) := by rw [commute_X_pow] exact isNilpotent_C_mul_pow_X_of_isNilpotent n hnil @[simp] lemma isNilpotent_monomial_iff {n : ℕ} : IsNilpotent (monomial (R := R) n r) ↔ IsNilpotent r := exists_congr fun k ↦ by simp @[simp] lemma isNilpotent_C_iff : IsNilpotent (C r) ↔ IsNilpotent r := exists_congr fun k ↦ by simpa only [← C_pow] using C_eq_zero @[simp] lemma isNilpotent_X_mul_iff : IsNilpotent (X * P) ↔ IsNilpotent P := by refine ⟨fun h ↦ ?_, ?_⟩ · rwa [Commute.isNilpotent_mul_right_iff (commute_X P) (by simp)] at h · rintro ⟨k, hk⟩ exact ⟨k, by simp [(commute_X P).mul_pow, hk]⟩	@[simp] lemma isNilpotent_mul_X_iff : IsNilpotent (P * X) ↔ IsNilpotent P := by rw [← commute_X P] exact isNilpotent_X_mul_iff	Mathlib/RingTheory/Polynomial/Nilpotent.lean	60	63
/- Copyright (c) 2018 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Floris van Doorn, Gabriel Ebner, Yury Kudryashov -/ import Mathlib.Data.Set.Accumulate import Mathlib.Order.ConditionallyCompleteLattice.Finset import Mathlib.Order.Interval.Finset.Nat /-! # Conditionally complete linear order structure on `ℕ` In this file we * define a `ConditionallyCompleteLinearOrderBot` structure on `ℕ`; * prove a few lemmas about `iSup`/`iInf`/`Set.iUnion`/`Set.iInter` and natural numbers. -/ assert_not_exists MonoidWithZero open Set namespace Nat open scoped Classical in noncomputable instance : InfSet ℕ := ⟨fun s ↦ if h : ∃ n, n ∈ s then @Nat.find (fun n ↦ n ∈ s) _ h else 0⟩ open scoped Classical in noncomputable instance : SupSet ℕ := ⟨fun s ↦ if h : ∃ n, ∀ a ∈ s, a ≤ n then @Nat.find (fun n ↦ ∀ a ∈ s, a ≤ n) _ h else 0⟩ open scoped Classical in theorem sInf_def {s : Set ℕ} (h : s.Nonempty) : sInf s = @Nat.find (fun n ↦ n ∈ s) _ h := dif_pos _ open scoped Classical in theorem sSup_def {s : Set ℕ} (h : ∃ n, ∀ a ∈ s, a ≤ n) : sSup s = @Nat.find (fun n ↦ ∀ a ∈ s, a ≤ n) _ h := dif_pos _ theorem _root_.Set.Infinite.Nat.sSup_eq_zero {s : Set ℕ} (h : s.Infinite) : sSup s = 0 := dif_neg fun ⟨n, hn⟩ ↦ let ⟨k, hks, hk⟩ := h.exists_gt n (hn k hks).not_lt hk @[simp] theorem sInf_eq_zero {s : Set ℕ} : sInf s = 0 ↔ 0 ∈ s ∨ s = ∅ := by cases eq_empty_or_nonempty s with \| inl h => subst h simp only [or_true, eq_self_iff_true, iInf, InfSet.sInf, mem_empty_iff_false, exists_false, dif_neg, not_false_iff] \| inr h => simp only [h.ne_empty, or_false, Nat.sInf_def, h, Nat.find_eq_zero] @[simp] theorem sInf_empty : sInf ∅ = 0 := by rw [sInf_eq_zero] right	rfl @[simp] theorem iInf_of_empty {ι : Sort*} [IsEmpty ι] (f : ι → ℕ) : iInf f = 0 := by	Mathlib/Data/Nat/Lattice.lean	59	62
/- Copyright (c) 2022 Matej Penciak. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Matej Penciak, Moritz Doll, Fabien Clery -/ import Mathlib.LinearAlgebra.Matrix.NonsingularInverse /-! # The Symplectic Group This file defines the symplectic group and proves elementary properties. ## Main Definitions * `Matrix.J`: the canonical `2n × 2n` skew-symmetric matrix * `symplecticGroup`: the group of symplectic matrices ## TODO * Every symplectic matrix has determinant 1. * For `n = 1` the symplectic group coincides with the special linear group. -/ open Matrix variable {l R : Type} namespace Matrix variable (l) [DecidableEq l] (R) [CommRing R] section JMatrixLemmas /-- The matrix defining the canonical skew-symmetric bilinear form. -/ def J : Matrix (l ⊕ l) (l ⊕ l) R := Matrix.fromBlocks 0 (-1) 1 0 @[simp] theorem J_transpose : (J l R)ᵀ = -J l R := by rw [J, fromBlocks_transpose, ← neg_one_smul R (fromBlocks _ _ _ _ : Matrix (l ⊕ l) (l ⊕ l) R), fromBlocks_smul, Matrix.transpose_zero, Matrix.transpose_one, transpose_neg] simp [fromBlocks] variable [Fintype l] theorem J_squared : J l R J l R = -1 := by rw [J, fromBlocks_multiply] simp only [Matrix.zero_mul, Matrix.neg_mul, zero_add, neg_zero, Matrix.one_mul, add_zero] rw [← neg_zero, ← Matrix.fromBlocks_neg, ← fromBlocks_one] theorem J_inv : (J l R)⁻¹ = -J l R := by refine Matrix.inv_eq_right_inv ?_ rw [Matrix.mul_neg, J_squared] exact neg_neg 1 theorem J_det_mul_J_det : det (J l R) * det (J l R) = 1 := by rw [← det_mul, J_squared, ← one_smul R (-1 : Matrix _ _ R), smul_neg, ← neg_smul, det_smul, Fintype.card_sum, det_one, mul_one] apply Even.neg_one_pow exact Even.add_self _ theorem isUnit_det_J : IsUnit (det (J l R)) := isUnit_iff_exists_inv.mpr ⟨det (J l R), J_det_mul_J_det _ _⟩ end JMatrixLemmas variable [Fintype l] /-- The group of symplectic matrices over a ring `R`. -/ def symplecticGroup : Submonoid (Matrix (l ⊕ l) (l ⊕ l) R) where carrier := { A \| A * J l R * Aᵀ = J l R } mul_mem' {a b} ha hb := by simp only [Set.mem_setOf_eq, transpose_mul] at * rw [← Matrix.mul_assoc, a.mul_assoc, a.mul_assoc, hb] exact ha one_mem' := by simp end Matrix namespace SymplecticGroup variable [DecidableEq l] [Fintype l] [CommRing R] open Matrix theorem mem_iff {A : Matrix (l ⊕ l) (l ⊕ l) R} : A ∈ symplecticGroup l R ↔ A * J l R * Aᵀ = J l R := by simp [symplecticGroup] instance coeMatrix : Coe (symplecticGroup l R) (Matrix (l ⊕ l) (l ⊕ l) R) := ⟨Subtype.val⟩ section SymplecticJ variable (l) (R) theorem J_mem : J l R ∈ symplecticGroup l R := by rw [mem_iff, J, fromBlocks_multiply, fromBlocks_transpose, fromBlocks_multiply] simp /-- The canonical skew-symmetric matrix as an element in the symplectic group. -/ def symJ : symplecticGroup l R := ⟨J l R, J_mem l R⟩ variable {l} {R} @[simp] theorem coe_J : ↑(symJ l R) = J l R := rfl end SymplecticJ variable {A : Matrix (l ⊕ l) (l ⊕ l) R} theorem neg_mem (h : A ∈ symplecticGroup l R) : -A ∈ symplecticGroup l R := by rw [mem_iff] at h ⊢ simp [h] theorem symplectic_det (hA : A ∈ symplecticGroup l R) : IsUnit <\| det A := by rw [isUnit_iff_exists_inv] use A.det refine (isUnit_det_J l R).mul_left_cancel ?_ rw [mul_one] rw [mem_iff] at hA apply_fun det at hA simp only [det_mul, det_transpose] at hA rw [mul_comm A.det, mul_assoc] at hA exact hA theorem transpose_mem (hA : A ∈ symplecticGroup l R) : Aᵀ ∈ symplecticGroup l R := by rw [mem_iff] at hA ⊢ rw [transpose_transpose] have huA := symplectic_det hA have huAT : IsUnit Aᵀ.det := by rw [Matrix.det_transpose] exact huA calc Aᵀ * J l R * A = (-Aᵀ) * (J l R)⁻¹ * A := by rw [J_inv] simp _ = (-Aᵀ) * (A * J l R * Aᵀ)⁻¹ * A := by rw [hA] _ = -(Aᵀ * (Aᵀ⁻¹ * (J l R)⁻¹)) * A⁻¹ * A := by simp only [Matrix.mul_inv_rev, Matrix.mul_assoc, Matrix.neg_mul] _ = -(J l R)⁻¹ := by rw [mul_nonsing_inv_cancel_left _ _ huAT, nonsing_inv_mul_cancel_right _ _ huA] _ = J l R := by simp [J_inv] @[simp] theorem transpose_mem_iff : Aᵀ ∈ symplecticGroup l R ↔ A ∈ symplecticGroup l R := ⟨fun hA => by simpa using transpose_mem hA, transpose_mem⟩ theorem mem_iff' : A ∈ symplecticGroup l R ↔ Aᵀ * J l R * A = J l R := by rw [← transpose_mem_iff, mem_iff, transpose_transpose] instance hasInv : Inv (symplecticGroup l R) where inv A := ⟨(-J l R) * (A : Matrix (l ⊕ l) (l ⊕ l) R)ᵀ * J l R, mul_mem (mul_mem (neg_mem <\| J_mem _ _) <\| transpose_mem A.2) <\| J_mem _ _⟩ theorem coe_inv (A : symplecticGroup l R) : (↑A⁻¹ : Matrix _ _ _) = (-J l R) * (↑A)ᵀ * J l R := rfl theorem inv_left_mul_aux (hA : A ∈ symplecticGroup l R) : -(J l R * Aᵀ * J l R * A) = 1 := calc -(J l R * Aᵀ * J l R * A) = (-J l R) * (Aᵀ * J l R * A) := by simp only [Matrix.mul_assoc, Matrix.neg_mul] _ = (-J l R) * J l R := by rw [mem_iff'] at hA rw [hA] _ = (-1 : R) • (J l R * J l R) := by simp only [Matrix.neg_mul, neg_smul, one_smul] _ = (-1 : R) • (-1 : Matrix _ _ _) := by rw [J_squared] _ = 1 := by simp only [neg_smul_neg, one_smul] theorem coe_inv' (A : symplecticGroup l R) : (↑A⁻¹ : Matrix (l ⊕ l) (l ⊕ l) R) = (↑A)⁻¹ := by refine (coe_inv A).trans (inv_eq_left_inv ?_).symm simp [inv_left_mul_aux, coe_inv] theorem inv_eq_symplectic_inv (A : Matrix (l ⊕ l) (l ⊕ l) R) (hA : A ∈ symplecticGroup l R) : A⁻¹ = (-J l R) * Aᵀ * J l R := inv_eq_left_inv (by simp only [Matrix.neg_mul, inv_left_mul_aux hA]) instance : Group (symplecticGroup l R) := { SymplecticGroup.hasInv, Submonoid.toMonoid _ with inv_mul_cancel := fun A => by apply Subtype.ext simp only [Submonoid.coe_one, Submonoid.coe_mul, Matrix.neg_mul, coe_inv] exact inv_left_mul_aux A.2 } end SymplecticGroup		Mathlib/LinearAlgebra/SymplecticGroup.lean	206	208
/- 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.Data.FunLike.Basic import Mathlib.Logic.Embedding.Basic import Mathlib.Order.RelClasses /-! # Relation homomorphisms, embeddings, isomorphisms This file defines relation homomorphisms, embeddings, isomorphisms and order embeddings and isomorphisms. ## Main declarations * `RelHom`: Relation homomorphism. A `RelHom r s` is a function `f : α → β` such that `r a b → s (f a) (f b)`. * `RelEmbedding`: Relation embedding. A `RelEmbedding r s` is an embedding `f : α ↪ β` such that `r a b ↔ s (f a) (f b)`. * `RelIso`: Relation isomorphism. A `RelIso r s` is an equivalence `f : α ≃ β` such that `r a b ↔ s (f a) (f b)`. * `sumLexCongr`, `prodLexCongr`: Creates a relation homomorphism between two `Sum.Lex` or two `Prod.Lex` from relation homomorphisms between their arguments. ## Notation * `→r`: `RelHom` * `↪r`: `RelEmbedding` * `≃r`: `RelIso` -/ open Function universe u v w variable {α β γ δ : Type} {r : α → α → Prop} {s : β → β → Prop} {t : γ → γ → Prop} {u : δ → δ → Prop} /-- A relation homomorphism with respect to a given pair of relations `r` and `s` is a function `f : α → β` such that `r a b → s (f a) (f b)`. -/ structure RelHom {α β : Type} (r : α → α → Prop) (s : β → β → Prop) where /-- The underlying function of a `RelHom` -/ toFun : α → β /-- A `RelHom` sends related elements to related elements -/ map_rel' : ∀ {a b}, r a b → s (toFun a) (toFun b) /-- A relation homomorphism with respect to a given pair of relations `r` and `s` is a function `f : α → β` such that `r a b → s (f a) (f b)`. -/ infixl:25 " →r " => RelHom section /-- `RelHomClass F r s` asserts that `F` is a type of functions such that all `f : F` satisfy `r a b → s (f a) (f b)`. The relations `r` and `s` are `outParam`s since figuring them out from a goal is a higher-order matching problem that Lean usually can't do unaided. -/ class RelHomClass (F : Type) {α β : outParam Type} (r : outParam <\| α → α → Prop) (s : outParam <\| β → β → Prop) [FunLike F α β] : Prop where /-- A `RelHomClass` sends related elements to related elements -/ map_rel : ∀ (f : F) {a b}, r a b → s (f a) (f b) export RelHomClass (map_rel) end namespace RelHomClass variable {F : Type} [FunLike F α β] protected theorem isIrrefl [RelHomClass F r s] (f : F) : ∀ [IsIrrefl β s], IsIrrefl α r \| ⟨H⟩ => ⟨fun _ h => H _ (map_rel f h)⟩ protected theorem isAsymm [RelHomClass F r s] (f : F) : ∀ [IsAsymm β s], IsAsymm α r \| ⟨H⟩ => ⟨fun _ _ h₁ h₂ => H _ _ (map_rel f h₁) (map_rel f h₂)⟩ protected theorem acc [RelHomClass F r s] (f : F) (a : α) : Acc s (f a) → Acc r a := by generalize h : f a = b intro ac induction ac generalizing a with \| intro _ H IH => ?_ subst h exact ⟨_, fun a' h => IH (f a') (map_rel f h) _ rfl⟩ protected theorem wellFounded [RelHomClass F r s] (f : F) : WellFounded s → WellFounded r \| ⟨H⟩ => ⟨fun _ => RelHomClass.acc f _ (H _)⟩ protected theorem isWellFounded [RelHomClass F r s] (f : F) [IsWellFounded β s] : IsWellFounded α r := ⟨RelHomClass.wellFounded f IsWellFounded.wf⟩ end RelHomClass namespace RelHom instance : FunLike (r →r s) α β where coe o := o.toFun coe_injective' f g h := by cases f cases g congr instance : RelHomClass (r →r s) r s where map_rel := map_rel' initialize_simps_projections RelHom (toFun → apply) protected theorem map_rel (f : r →r s) {a b} : r a b → s (f a) (f b) := f.map_rel' @[simp] theorem coe_fn_toFun (f : r →r s) : f.toFun = (f : α → β) := rfl /-- The map `coe_fn : (r →r s) → (α → β)` is injective. -/ theorem coe_fn_injective : Injective fun (f : r →r s) => (f : α → β) := DFunLike.coe_injective @[ext] theorem ext ⦃f g : r →r s⦄ (h : ∀ x, f x = g x) : f = g := DFunLike.ext f g h /-- Identity map is a relation homomorphism. -/ @[refl, simps] protected def id (r : α → α → Prop) : r →r r := ⟨fun x => x, fun x => x⟩ /-- Composition of two relation homomorphisms is a relation homomorphism. -/ @[simps] protected def comp (g : s →r t) (f : r →r s) : r →r t := ⟨fun x => g (f x), fun h => g.2 (f.2 h)⟩ /-- A relation homomorphism is also a relation homomorphism between dual relations. -/ protected def swap (f : r →r s) : swap r →r swap s := ⟨f, f.map_rel⟩ /-- A function is a relation homomorphism from the preimage relation of `s` to `s`. -/ def preimage (f : α → β) (s : β → β → Prop) : f ⁻¹'o s →r s := ⟨f, id⟩ end RelHom /-- An increasing function is injective -/ theorem injective_of_increasing (r : α → α → Prop) (s : β → β → Prop) [IsTrichotomous α r] [IsIrrefl β s] (f : α → β) (hf : ∀ {x y}, r x y → s (f x) (f y)) : Injective f := by intro x y hxy rcases trichotomous_of r x y with (h \| h \| h) · have := hf h rw [hxy] at this exfalso exact irrefl_of s (f y) this · exact h · have := hf h rw [hxy] at this exfalso exact irrefl_of s (f y) this /-- An increasing function is injective -/ theorem RelHom.injective_of_increasing [IsTrichotomous α r] [IsIrrefl β s] (f : r →r s) : Injective f := _root_.injective_of_increasing r s f f.map_rel theorem Function.Surjective.wellFounded_iff {f : α → β} (hf : Surjective f) (o : ∀ {a b}, r a b ↔ s (f a) (f b)) : WellFounded r ↔ WellFounded s := Iff.intro (RelHomClass.wellFounded (⟨surjInv hf, fun h => by simpa only [o, surjInv_eq hf] using h⟩ : s →r r)) (RelHomClass.wellFounded (⟨f, o.1⟩ : r →r s)) /-- A relation embedding with respect to a given pair of relations `r` and `s` is an embedding `f : α ↪ β` such that `r a b ↔ s (f a) (f b)`. -/ structure RelEmbedding {α β : Type} (r : α → α → Prop) (s : β → β → Prop) extends α ↪ β where /-- Elements are related iff they are related after apply a `RelEmbedding` -/ map_rel_iff' : ∀ {a b}, s (toEmbedding a) (toEmbedding b) ↔ r a b /-- A relation embedding with respect to a given pair of relations `r` and `s` is an embedding `f : α ↪ β` such that `r a b ↔ s (f a) (f b)`. -/ infixl:25 " ↪r " => RelEmbedding /-- The induced relation on a subtype is an embedding under the natural inclusion. -/ def Subtype.relEmbedding {X : Type} (r : X → X → Prop) (p : X → Prop) : (Subtype.val : Subtype p → X) ⁻¹'o r ↪r r := ⟨Embedding.subtype p, Iff.rfl⟩ theorem preimage_equivalence {α β} (f : α → β) {s : β → β → Prop} (hs : Equivalence s) : Equivalence (f ⁻¹'o s) := ⟨fun _ => hs.1 _, fun h => hs.2 h, fun h₁ h₂ => hs.3 h₁ h₂⟩ namespace RelEmbedding /-- A relation embedding is also a relation homomorphism -/ def toRelHom (f : r ↪r s) : r →r s where toFun := f.toEmbedding.toFun map_rel' := (map_rel_iff' f).mpr instance : Coe (r ↪r s) (r →r s) := ⟨toRelHom⟩ -- TODO: define and instantiate a `RelEmbeddingClass` when `EmbeddingLike` is defined instance : FunLike (r ↪r s) α β where coe x := x.toFun coe_injective' f g h := by rcases f with ⟨⟨⟩⟩ rcases g with ⟨⟨⟩⟩ congr -- TODO: define and instantiate a `RelEmbeddingClass` when `EmbeddingLike` is defined instance : RelHomClass (r ↪r s) r s where map_rel f _ _ := Iff.mpr (map_rel_iff' f) initialize_simps_projections RelEmbedding (toFun → apply) instance : EmbeddingLike (r ↪r s) α β where injective' f := f.inj' @[simp] theorem coe_toEmbedding {f : r ↪r s} : ((f : r ↪r s).toEmbedding : α → β) = f := rfl @[simp] theorem coe_toRelHom {f : r ↪r s} : ((f : r ↪r s).toRelHom : α → β) = f := rfl theorem toEmbedding_injective : Injective (toEmbedding : r ↪r s → (α ↪ β)) := by rintro ⟨f, -⟩ ⟨g, -⟩; simp @[simp] theorem toEmbedding_inj {f g : r ↪r s} : f.toEmbedding = g.toEmbedding ↔ f = g := toEmbedding_injective.eq_iff theorem injective (f : r ↪r s) : Injective f := f.inj' theorem inj (f : r ↪r s) {a b} : f a = f b ↔ a = b := f.injective.eq_iff theorem map_rel_iff (f : r ↪r s) {a b} : s (f a) (f b) ↔ r a b := f.map_rel_iff' @[simp] theorem coe_mk {f} {h} : ⇑(⟨f, h⟩ : r ↪r s) = f := rfl /-- The map `coe_fn : (r ↪r s) → (α → β)` is injective. -/ theorem coe_fn_injective : Injective fun f : r ↪r s => (f : α → β) := DFunLike.coe_injective @[ext] theorem ext ⦃f g : r ↪r s⦄ (h : ∀ x, f x = g x) : f = g := DFunLike.ext _ _ h /-- Identity map is a relation embedding. -/ @[refl, simps!] protected def refl (r : α → α → Prop) : r ↪r r := ⟨Embedding.refl _, Iff.rfl⟩ /-- Composition of two relation embeddings is a relation embedding. -/ protected def trans (f : r ↪r s) (g : s ↪r t) : r ↪r t := ⟨f.1.trans g.1, by simp [f.map_rel_iff, g.map_rel_iff]⟩ instance (r : α → α → Prop) : Inhabited (r ↪r r) := ⟨RelEmbedding.refl _⟩ theorem trans_apply (f : r ↪r s) (g : s ↪r t) (a : α) : (f.trans g) a = g (f a) := rfl @[simp] theorem coe_trans (f : r ↪r s) (g : s ↪r t) : (f.trans g) = g ∘ f := rfl /-- A relation embedding is also a relation embedding between dual relations. -/ protected def swap (f : r ↪r s) : swap r ↪r swap s := ⟨f.toEmbedding, f.map_rel_iff⟩ /-- If `f` is injective, then it is a relation embedding from the preimage relation of `s` to `s`. -/ def preimage (f : α ↪ β) (s : β → β → Prop) : f ⁻¹'o s ↪r s := ⟨f, Iff.rfl⟩ theorem eq_preimage (f : r ↪r s) : r = f ⁻¹'o s := by ext a b exact f.map_rel_iff.symm protected theorem isIrrefl (f : r ↪r s) [IsIrrefl β s] : IsIrrefl α r := ⟨fun a => mt f.map_rel_iff.2 (irrefl (f a))⟩ protected theorem isRefl (f : r ↪r s) [IsRefl β s] : IsRefl α r := ⟨fun _ => f.map_rel_iff.1 <\| refl _⟩ protected theorem isSymm (f : r ↪r s) [IsSymm β s] : IsSymm α r := ⟨fun _ _ => imp_imp_imp f.map_rel_iff.2 f.map_rel_iff.1 symm⟩ protected theorem isAsymm (f : r ↪r s) [IsAsymm β s] : IsAsymm α r := ⟨fun _ _ h₁ h₂ => asymm (f.map_rel_iff.2 h₁) (f.map_rel_iff.2 h₂)⟩ protected theorem isAntisymm : ∀ (_ : r ↪r s) [IsAntisymm β s], IsAntisymm α r \| ⟨f, o⟩, ⟨H⟩ => ⟨fun _ _ h₁ h₂ => f.inj' (H _ _ (o.2 h₁) (o.2 h₂))⟩ protected theorem isTrans : ∀ (_ : r ↪r s) [IsTrans β s], IsTrans α r \| ⟨_, o⟩, ⟨H⟩ => ⟨fun _ _ _ h₁ h₂ => o.1 (H _ _ _ (o.2 h₁) (o.2 h₂))⟩ protected theorem isTotal : ∀ (_ : r ↪r s) [IsTotal β s], IsTotal α r \| ⟨_, o⟩, ⟨H⟩ => ⟨fun _ _ => (or_congr o o).1 (H _ _)⟩ protected theorem isPreorder : ∀ (_ : r ↪r s) [IsPreorder β s], IsPreorder α r \| f, _ => { f.isRefl, f.isTrans with } protected theorem isPartialOrder : ∀ (_ : r ↪r s) [IsPartialOrder β s], IsPartialOrder α r \| f, _ => { f.isPreorder, f.isAntisymm with } protected theorem isLinearOrder : ∀ (_ : r ↪r s) [IsLinearOrder β s], IsLinearOrder α r \| f, _ => { f.isPartialOrder, f.isTotal with } protected theorem isStrictOrder : ∀ (_ : r ↪r s) [IsStrictOrder β s], IsStrictOrder α r \| f, _ => { f.isIrrefl, f.isTrans with } protected theorem isTrichotomous : ∀ (_ : r ↪r s) [IsTrichotomous β s], IsTrichotomous α r \| ⟨f, o⟩, ⟨H⟩ => ⟨fun _ _ => (or_congr o (or_congr f.inj'.eq_iff o)).1 (H _ _)⟩ protected theorem isStrictTotalOrder : ∀ (_ : r ↪r s) [IsStrictTotalOrder β s], IsStrictTotalOrder α r \| f, _ => { f.isTrichotomous, f.isStrictOrder with } protected theorem acc (f : r ↪r s) (a : α) : Acc s (f a) → Acc r a := by generalize h : f a = b intro ac induction ac generalizing a with \| intro _ H IH => ?_ subst h exact ⟨_, fun a' h => IH (f a') (f.map_rel_iff.2 h) _ rfl⟩ protected theorem wellFounded : ∀ (_ : r ↪r s) (_ : WellFounded s), WellFounded r \| f, ⟨H⟩ => ⟨fun _ => f.acc _ (H _)⟩ protected theorem isWellFounded (f : r ↪r s) [IsWellFounded β s] : IsWellFounded α r := ⟨f.wellFounded IsWellFounded.wf⟩ protected theorem isWellOrder : ∀ (_ : r ↪r s) [IsWellOrder β s], IsWellOrder α r \| f, H => { f.isStrictTotalOrder with wf := f.wellFounded H.wf } end RelEmbedding instance Subtype.wellFoundedLT [LT α] [WellFoundedLT α] (p : α → Prop) : WellFoundedLT (Subtype p) := (Subtype.relEmbedding (· < ·) p).isWellFounded instance Subtype.wellFoundedGT [LT α] [WellFoundedGT α] (p : α → Prop) : WellFoundedGT (Subtype p) := (Subtype.relEmbedding (· > ·) p).isWellFounded /-- `Quotient.mk` as a relation homomorphism between the relation and the lift of a relation. -/ @[simps] def Quotient.mkRelHom {_ : Setoid α} {r : α → α → Prop} (H : ∀ (a₁ b₁ a₂ b₂ : α), a₁ ≈ a₂ → b₁ ≈ b₂ → r a₁ b₁ = r a₂ b₂) : r →r Quotient.lift₂ r H := ⟨Quotient.mk _, id⟩ /-- `Quotient.out` as a relation embedding between the lift of a relation and the relation. -/ @[simps!] noncomputable def Quotient.outRelEmbedding {_ : Setoid α} {r : α → α → Prop} (H : ∀ (a₁ b₁ a₂ b₂ : α), a₁ ≈ a₂ → b₁ ≈ b₂ → r a₁ b₁ = r a₂ b₂) : Quotient.lift₂ r H ↪r r := ⟨Embedding.quotientOut α, by refine @fun x y => Quotient.inductionOn₂ x y fun a b => ?_ apply iff_iff_eq.2 (H _ _ _ _ _ _) <;> apply Quotient.mk_out⟩ @[simp] theorem acc_lift₂_iff {_ : Setoid α} {r : α → α → Prop} {H : ∀ (a₁ b₁ a₂ b₂ : α), a₁ ≈ a₂ → b₁ ≈ b₂ → r a₁ b₁ = r a₂ b₂} {a} : Acc (Quotient.lift₂ r H) ⟦a⟧ ↔ Acc r a := by constructor · exact RelHomClass.acc (Quotient.mkRelHom H) a · intro ac induction ac with \| intro _ _ IH => ?_ refine ⟨_, fun q h => ?_⟩ obtain ⟨a', rfl⟩ := q.exists_rep exact IH a' h @[simp] theorem acc_liftOn₂'_iff {s : Setoid α} {r : α → α → Prop} {H} {a} : Acc (fun x y => Quotient.liftOn₂' x y r H) (Quotient.mk'' a : Quotient s) ↔ Acc r a := acc_lift₂_iff (H := H) /-- A relation is well founded iff its lift to a quotient is. -/ @[simp] theorem wellFounded_lift₂_iff {_ : Setoid α} {r : α → α → Prop} {H : ∀ (a₁ b₁ a₂ b₂ : α), a₁ ≈ a₂ → b₁ ≈ b₂ → r a₁ b₁ = r a₂ b₂} : WellFounded (Quotient.lift₂ r H) ↔ WellFounded r := by constructor · exact RelHomClass.wellFounded (Quotient.mkRelHom H) · refine fun wf => ⟨fun q => ?_⟩ obtain ⟨a, rfl⟩ := q.exists_rep exact acc_lift₂_iff.2 (wf.apply a) alias ⟨WellFounded.of_quotient_lift₂, WellFounded.quotient_lift₂⟩ := wellFounded_lift₂_iff @[simp] theorem wellFounded_liftOn₂'_iff {s : Setoid α} {r : α → α → Prop} {H} : (WellFounded fun x y : Quotient s => Quotient.liftOn₂' x y r H) ↔ WellFounded r := wellFounded_lift₂_iff (H := H) alias ⟨WellFounded.of_quotient_liftOn₂', WellFounded.quotient_liftOn₂'⟩ := wellFounded_liftOn₂'_iff namespace RelEmbedding /-- To define a relation embedding from an antisymmetric relation `r` to a reflexive relation `s` it suffices to give a function together with a proof that it satisfies `s (f a) (f b) ↔ r a b`. -/ def ofMapRelIff (f : α → β) [IsAntisymm α r] [IsRefl β s] (hf : ∀ a b, s (f a) (f b) ↔ r a b) : r ↪r s where toFun := f inj' _ _ h := antisymm ((hf _ _).1 (h ▸ refl _)) ((hf _ _).1 (h ▸ refl _)) map_rel_iff' := hf _ _ @[simp] theorem ofMapRelIff_coe (f : α → β) [IsAntisymm α r] [IsRefl β s] (hf : ∀ a b, s (f a) (f b) ↔ r a b) : (ofMapRelIff f hf : r ↪r s) = f := rfl /-- It suffices to prove `f` is monotone between strict relations to show it is a relation embedding. -/ def ofMonotone [IsTrichotomous α r] [IsAsymm β s] (f : α → β) (H : ∀ a b, r a b → s (f a) (f b)) : r ↪r s := by haveI := @IsAsymm.isIrrefl β s _ refine ⟨⟨f, fun a b e => ?_⟩, @fun a b => ⟨fun h => ?_, H _ _⟩⟩ · refine ((@trichotomous _ r _ a b).resolve_left ?_).resolve_right ?_ · exact fun h => irrefl (r := s) (f a) (by simpa [e] using H _ _ h) · exact fun h => irrefl (r := s) (f b) (by simpa [e] using H _ _ h) · refine (@trichotomous _ r _ a b).resolve_right (Or.rec (fun e => ?_) fun h' => ?_) · subst e exact irrefl _ h · exact asymm (H _ _ h') h @[simp] theorem ofMonotone_coe [IsTrichotomous α r] [IsAsymm β s] (f : α → β) (H) : (@ofMonotone _ _ r s _ _ f H : α → β) = f := rfl /-- A relation embedding from an empty type. -/ def ofIsEmpty (r : α → α → Prop) (s : β → β → Prop) [IsEmpty α] : r ↪r s := ⟨Embedding.ofIsEmpty, @fun a => isEmptyElim a⟩ /-- `Sum.inl` as a relation embedding into `Sum.LiftRel r s`. -/ @[simps] def sumLiftRelInl (r : α → α → Prop) (s : β → β → Prop) : r ↪r Sum.LiftRel r s where toFun := Sum.inl inj' := Sum.inl_injective map_rel_iff' := Sum.liftRel_inl_inl /-- `Sum.inr` as a relation embedding into `Sum.LiftRel r s`. -/ @[simps] def sumLiftRelInr (r : α → α → Prop) (s : β → β → Prop) : s ↪r Sum.LiftRel r s where toFun := Sum.inr inj' := Sum.inr_injective map_rel_iff' := Sum.liftRel_inr_inr /-- `Sum.map` as a relation embedding between `Sum.LiftRel` relations. -/ @[simps] def sumLiftRelMap (f : r ↪r s) (g : t ↪r u) : Sum.LiftRel r t ↪r Sum.LiftRel s u where toFun := Sum.map f g inj' := f.injective.sumMap g.injective map_rel_iff' := by rintro (a \| b) (c \| d) <;> simp [f.map_rel_iff, g.map_rel_iff] /-- `Sum.inl` as a relation embedding into `Sum.Lex r s`. -/ @[simps] def sumLexInl (r : α → α → Prop) (s : β → β → Prop) : r ↪r Sum.Lex r s where toFun := Sum.inl inj' := Sum.inl_injective map_rel_iff' := Sum.lex_inl_inl /-- `Sum.inr` as a relation embedding into `Sum.Lex r s`. -/ @[simps] def sumLexInr (r : α → α → Prop) (s : β → β → Prop) : s ↪r Sum.Lex r s where toFun := Sum.inr inj' := Sum.inr_injective map_rel_iff' := Sum.lex_inr_inr /-- `Sum.map` as a relation embedding between `Sum.Lex` relations. -/ @[simps] def sumLexMap (f : r ↪r s) (g : t ↪r u) : Sum.Lex r t ↪r Sum.Lex s u where toFun := Sum.map f g inj' := f.injective.sumMap g.injective map_rel_iff' := by rintro (a \| b) (c \| d) <;> simp [f.map_rel_iff, g.map_rel_iff] /-- `fun b ↦ Prod.mk a b` as a relation embedding. -/ @[simps] def prodLexMkLeft (s : β → β → Prop) {a : α} (h : ¬r a a) : s ↪r Prod.Lex r s where toFun := Prod.mk a inj' := Prod.mk_right_injective a map_rel_iff' := by simp [Prod.lex_def, h] /-- `fun a ↦ Prod.mk a b` as a relation embedding. -/ @[simps] def prodLexMkRight (r : α → α → Prop) {b : β} (h : ¬s b b) : r ↪r Prod.Lex r s where toFun a := (a, b) inj' := Prod.mk_left_injective b map_rel_iff' := by simp [Prod.lex_def, h] /-- `Prod.map` as a relation embedding. -/ @[simps] def prodLexMap (f : r ↪r s) (g : t ↪r u) : Prod.Lex r t ↪r Prod.Lex s u where toFun := Prod.map f g inj' := f.injective.prodMap g.injective map_rel_iff' := by simp [Prod.lex_def, f.map_rel_iff, g.map_rel_iff, f.inj] end RelEmbedding /-- A relation isomorphism is an equivalence that is also a relation embedding. -/ structure RelIso {α β : Type} (r : α → α → Prop) (s : β → β → Prop) extends α ≃ β where /-- Elements are related iff they are related after apply a `RelIso` -/ map_rel_iff' : ∀ {a b}, s (toEquiv a) (toEquiv b) ↔ r a b /-- A relation isomorphism is an equivalence that is also a relation embedding. -/ infixl:25 " ≃r " => RelIso namespace RelIso /-- Convert a `RelIso` to a `RelEmbedding`. This function is also available as a coercion but often it is easier to write `f.toRelEmbedding` than to write explicitly `r` and `s` in the target type. -/ def toRelEmbedding (f : r ≃r s) : r ↪r s := ⟨f.toEquiv.toEmbedding, f.map_rel_iff'⟩ theorem toEquiv_injective : Injective (toEquiv : r ≃r s → α ≃ β) \| ⟨e₁, o₁⟩, ⟨e₂, _⟩, h => by congr instance : CoeOut (r ≃r s) (r ↪r s) := ⟨toRelEmbedding⟩ -- TODO: define and instantiate a `RelIsoClass` when `EquivLike` is defined instance : FunLike (r ≃r s) α β where coe x := x coe_injective' := Equiv.coe_fn_injective.comp toEquiv_injective -- TODO: define and instantiate a `RelIsoClass` when `EquivLike` is defined instance : RelHomClass (r ≃r s) r s where map_rel f _ _ := Iff.mpr (map_rel_iff' f) instance : EquivLike (r ≃r s) α β where coe f := f inv f := f.toEquiv.symm left_inv f := f.left_inv right_inv f := f.right_inv coe_injective' _ _ hf _ := DFunLike.ext' hf @[simp] theorem coe_toRelEmbedding (f : r ≃r s) : (f.toRelEmbedding : α → β) = f := rfl @[simp] theorem coe_toEmbedding (f : r ≃r s) : (f.toEmbedding : α → β) = f := rfl theorem map_rel_iff (f : r ≃r s) {a b} : s (f a) (f b) ↔ r a b := f.map_rel_iff' @[simp] theorem coe_fn_mk (f : α ≃ β) (o : ∀ ⦃a b⦄, s (f a) (f b) ↔ r a b) : (RelIso.mk f @o : α → β) = f := rfl @[simp] theorem coe_fn_toEquiv (f : r ≃r s) : (f.toEquiv : α → β) = f := rfl /-- The map `DFunLike.coe : (r ≃r s) → (α → β)` is injective. -/ theorem coe_fn_injective : Injective fun f : r ≃r s => (f : α → β) := DFunLike.coe_injective @[ext] theorem ext ⦃f g : r ≃r s⦄ (h : ∀ x, f x = g x) : f = g := DFunLike.ext f g h /-- Inverse map of a relation isomorphism is a relation isomorphism. -/ protected def symm (f : r ≃r s) : s ≃r r := ⟨f.toEquiv.symm, @fun a b => by erw [← f.map_rel_iff, f.1.apply_symm_apply, f.1.apply_symm_apply]⟩ /-- See Note [custom simps projection]. We need to specify this projection explicitly in this case, because `RelIso` defines custom coercions other than the ones given by `DFunLike`. -/ def Simps.apply (h : r ≃r s) : α → β := h /-- See Note [custom simps projection]. -/ def Simps.symm_apply (h : r ≃r s) : β → α := h.symm initialize_simps_projections RelIso (toFun → apply, invFun → symm_apply) /-- Identity map is a relation isomorphism. -/ @[refl, simps! apply] protected def refl (r : α → α → Prop) : r ≃r r := ⟨Equiv.refl _, Iff.rfl⟩ /-- Composition of two relation isomorphisms is a relation isomorphism. -/ @[simps! apply] protected def trans (f₁ : r ≃r s) (f₂ : s ≃r t) : r ≃r t := ⟨f₁.toEquiv.trans f₂.toEquiv, f₂.map_rel_iff.trans f₁.map_rel_iff⟩ instance (r : α → α → Prop) : Inhabited (r ≃r r) := ⟨RelIso.refl _⟩ @[simp] theorem default_def (r : α → α → Prop) : default = RelIso.refl r := rfl @[simp] lemma apply_symm_apply (e : r ≃r s) (x : β) : e (e.symm x) = x := e.right_inv x @[simp] lemma symm_apply_apply (e : r ≃r s) (x : α) : e.symm (e x) = x := e.left_inv x @[simp] lemma symm_comp_self (e : r ≃r s) : e.symm ∘ e = id := funext e.symm_apply_apply @[simp] lemma self_comp_symm (e : r ≃r s) : e ∘ e.symm = id := funext e.apply_symm_apply @[simp] lemma symm_trans_apply (f : r ≃r s) (g : s ≃r t) (a : γ) : (f.trans g).symm a = f.symm (g.symm a) := rfl lemma symm_symm_apply (f : r ≃r s) (b : α) : f.symm.symm b = f b := rfl lemma apply_eq_iff_eq (f : r ≃r s) {x y : α} : f x = f y ↔ x = y := EquivLike.apply_eq_iff_eq f lemma apply_eq_iff_eq_symm_apply {x : α} {y : β} (f : r ≃r s) : f x = y ↔ x = f.symm y := by conv_lhs => rw [← apply_symm_apply f y] rw [apply_eq_iff_eq] lemma symm_apply_eq (e : r ≃r s) {x y} : e.symm x = y ↔ x = e y := e.toEquiv.symm_apply_eq lemma eq_symm_apply (e : r ≃r s) {x y} : y = e.symm x ↔ e y = x := e.toEquiv.eq_symm_apply @[simp] lemma symm_symm (e : r ≃r s) : e.symm.symm = e := rfl lemma symm_bijective : Bijective (.symm : (r ≃r s) → s ≃r r) := bijective_iff_has_inverse.mpr ⟨_, symm_symm, symm_symm⟩ @[simp] lemma refl_symm : (RelIso.refl r).symm = .refl _ := rfl @[simp] lemma trans_refl (e : r ≃r s) : e.trans (.refl _) = e := rfl @[simp] lemma refl_trans (e : r ≃r s) : .trans (.refl _) e = e := rfl @[simp] lemma symm_trans_self (e : r ≃r s) : e.symm.trans e = .refl _ := ext <\| by simp @[simp] lemma self_trans_symm (e : r ≃r s) : e.trans e.symm = .refl _ := ext <\| by simp lemma trans_assoc {δ : Type*} {u : δ → δ → Prop} (ab : r ≃r s) (bc : s ≃r t) (cd : t ≃r u) : (ab.trans bc).trans cd = ab.trans (bc.trans cd) := rfl /-- A relation isomorphism between equal relations on equal types. -/ @[simps! toEquiv apply] protected def cast {α β : Type u} {r : α → α → Prop} {s : β → β → Prop} (h₁ : α = β) (h₂ : HEq r s) : r ≃r s := ⟨Equiv.cast h₁, @fun a b => by subst h₁ rw [eq_of_heq h₂] rfl⟩ @[simp] protected theorem cast_symm {α β : Type u} {r : α → α → Prop} {s : β → β → Prop} (h₁ : α = β) (h₂ : HEq r s) : (RelIso.cast h₁ h₂).symm = RelIso.cast h₁.symm h₂.symm := rfl @[simp] protected theorem cast_refl {α : Type u} {r : α → α → Prop} (h₁ : α = α := rfl) (h₂ : HEq r r := HEq.rfl) : RelIso.cast h₁ h₂ = RelIso.refl r := rfl @[simp] protected theorem cast_trans {α β γ : Type u} {r : α → α → Prop} {s : β → β → Prop} {t : γ → γ → Prop} (h₁ : α = β) (h₁' : β = γ) (h₂ : HEq r s) (h₂' : HEq s t) : (RelIso.cast h₁ h₂).trans (RelIso.cast h₁' h₂') = RelIso.cast (h₁.trans h₁') (h₂.trans h₂') := ext fun x => by subst h₁; rfl /-- A relation isomorphism is also a relation isomorphism between dual relations. -/ protected def swap (f : r ≃r s) : swap r ≃r swap s := ⟨f, f.map_rel_iff⟩ /-- A relation isomorphism is also a relation isomorphism between complemented relations. -/ @[simps!] protected def compl (f : r ≃r s) : rᶜ ≃r sᶜ := ⟨f, f.map_rel_iff.not⟩ @[simp] theorem coe_fn_symm_mk (f o) : ((@RelIso.mk _ _ r s f @o).symm : β → α) = f.symm := rfl theorem rel_symm_apply (e : r ≃r s) {x y} : r x (e.symm y) ↔ s (e x) y := by rw [← e.map_rel_iff, e.apply_symm_apply] theorem symm_apply_rel (e : r ≃r s) {x y} : r (e.symm x) y ↔ s x (e y) := by rw [← e.map_rel_iff, e.apply_symm_apply] protected theorem bijective (e : r ≃r s) : Bijective e := e.toEquiv.bijective protected theorem injective (e : r ≃r s) : Injective e := e.toEquiv.injective protected theorem surjective (e : r ≃r s) : Surjective e := e.toEquiv.surjective theorem eq_iff_eq (f : r ≃r s) {a b} : f a = f b ↔ a = b := f.injective.eq_iff /-- Copy of a `RelIso` with a new `toFun` and `invFun` equal to the old ones. Useful to fix definitional equalities. -/ def copy (e : r ≃r s) (f : α → β) (g : β → α) (hf : f = e) (hg : g = e.symm) : r ≃r s where toFun := f invFun := g left_inv _ := by simp [hf, hg] right_inv _ := by simp [hf, hg] map_rel_iff' := by simp [hf, e.map_rel_iff] @[simp, norm_cast] lemma coe_copy (e : r ≃r s) (f : α → β) (g : β → α) (hf hg) : e.copy f g hf hg = f := rfl lemma copy_eq (e : r ≃r s) (f : α → β) (g : β → α) (hf hg) : e.copy f g hf hg = e := DFunLike.coe_injective hf /-- Any equivalence lifts to a relation isomorphism between `s` and its preimage. -/ protected def preimage (f : α ≃ β) (s : β → β → Prop) : f ⁻¹'o s ≃r s := ⟨f, Iff.rfl⟩ instance IsWellOrder.preimage {α : Type u} (r : α → α → Prop) [IsWellOrder α r] (f : β ≃ α) : IsWellOrder β (f ⁻¹'o r) := @RelEmbedding.isWellOrder _ _ (f ⁻¹'o r) r (RelIso.preimage f r) _ instance IsWellOrder.ulift {α : Type u} (r : α → α → Prop) [IsWellOrder α r] : IsWellOrder (ULift α) (ULift.down ⁻¹'o r) := IsWellOrder.preimage r Equiv.ulift /-- A surjective relation embedding is a relation isomorphism. -/ @[simps! apply] noncomputable def ofSurjective (f : r ↪r s) (H : Surjective f) : r ≃r s := ⟨Equiv.ofBijective f ⟨f.injective, H⟩, f.map_rel_iff⟩ /-- Given relation isomorphisms `r₁ ≃r s₁` and `r₂ ≃r s₂`, construct a relation isomorphism for the lexicographic orders on the sum. -/ def sumLexCongr {α₁ α₂ β₁ β₂ r₁ r₂ s₁ s₂} (e₁ : @RelIso α₁ β₁ r₁ s₁) (e₂ : @RelIso α₂ β₂ r₂ s₂) : Sum.Lex r₁ r₂ ≃r Sum.Lex s₁ s₂ := ⟨Equiv.sumCongr e₁.toEquiv e₂.toEquiv, @fun a b => by obtain ⟨f, hf⟩ := e₁; obtain ⟨g, hg⟩ := e₂; cases a <;> cases b <;> simp [hf, hg]⟩ /-- Given relation isomorphisms `r₁ ≃r s₁` and `r₂ ≃r s₂`, construct a relation isomorphism for the lexicographic orders on the product. -/ def prodLexCongr {α₁ α₂ β₁ β₂ r₁ r₂ s₁ s₂} (e₁ : @RelIso α₁ β₁ r₁ s₁) (e₂ : @RelIso α₂ β₂ r₂ s₂) : Prod.Lex r₁ r₂ ≃r Prod.Lex s₁ s₂ := ⟨Equiv.prodCongr e₁.toEquiv e₂.toEquiv, by simp [Prod.lex_def, e₁.map_rel_iff, e₂.map_rel_iff, e₁.injective.eq_iff]⟩ /-- Two relations on empty types are isomorphic. -/ def relIsoOfIsEmpty (r : α → α → Prop) (s : β → β → Prop) [IsEmpty α] [IsEmpty β] : r ≃r s := ⟨Equiv.equivOfIsEmpty α β, @fun a => isEmptyElim a⟩ /-- Two irreflexive relations on a unique type are isomorphic. -/ def ofUniqueOfIrrefl (r : α → α → Prop) (s : β → β → Prop) [IsIrrefl α r] [IsIrrefl β s] [Unique α] [Unique β] : r ≃r s := ⟨Equiv.ofUnique α β, iff_of_false (not_rel_of_subsingleton s _ _) (not_rel_of_subsingleton r _ _) ⟩ @[deprecated (since := "2024-12-26")] alias relIsoOfUniqueOfIrrefl := ofUniqueOfIrrefl /-- Two reflexive relations on a unique type are isomorphic. -/ def ofUniqueOfRefl (r : α → α → Prop) (s : β → β → Prop) [IsRefl α r] [IsRefl β s] [Unique α] [Unique β] : r ≃r s := ⟨Equiv.ofUnique α β, iff_of_true (rel_of_subsingleton s _ _) (rel_of_subsingleton r _ _)⟩ @[deprecated (since := "2024-12-26")] alias relIsoOfUniqueOfRefl := ofUniqueOfRefl end RelIso		Mathlib/Order/RelIso/Basic.lean	780	781
/- 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, image_mul_right_Ioo _ _ hr] ext x; simp [and_comm] -- This is also true for `ℚ`-normed spaces theorem exists_dist_eq (x z : E) {a b : ℝ} (ha : 0 ≤ a) (hb : 0 ≤ b) (hab : a + b = 1) : ∃ y, dist x y = b * dist x z ∧ dist y z = a * dist x z := by use a • x + b • z nth_rw 1 [← one_smul ℝ x] nth_rw 4 [← one_smul ℝ z] simp [dist_eq_norm, ← hab, add_smul, ← smul_sub, norm_smul_of_nonneg, ha, hb] theorem exists_dist_le_le (hδ : 0 ≤ δ) (hε : 0 ≤ ε) (h : dist x z ≤ ε + δ) : ∃ y, dist x y ≤ δ ∧ dist y z ≤ ε := by obtain rfl \| hε' := hε.eq_or_lt · exact ⟨z, by rwa [zero_add] at h, (dist_self _).le⟩ have hεδ := add_pos_of_pos_of_nonneg hε' hδ refine (exists_dist_eq x z (div_nonneg hε <\| add_nonneg hε hδ) (div_nonneg hδ <\| add_nonneg hε hδ) <\| by rw [← add_div, div_self hεδ.ne']).imp fun y hy => ?_ rw [hy.1, hy.2, div_mul_comm, div_mul_comm ε] rw [← div_le_one hεδ] at h exact ⟨mul_le_of_le_one_left hδ h, mul_le_of_le_one_left hε h⟩ -- This is also true for `ℚ`-normed spaces theorem exists_dist_le_lt (hδ : 0 ≤ δ) (hε : 0 < ε) (h : dist x z < ε + δ) : ∃ y, dist x y ≤ δ ∧ dist y z < ε := by refine (exists_dist_eq x z (div_nonneg hε.le <\| add_nonneg hε.le hδ) (div_nonneg hδ <\| add_nonneg hε.le hδ) <\| by rw [← add_div, div_self (add_pos_of_pos_of_nonneg hε hδ).ne']).imp fun y hy => ?_ rw [hy.1, hy.2, div_mul_comm, div_mul_comm ε] rw [← div_lt_one (add_pos_of_pos_of_nonneg hε hδ)] at h exact ⟨mul_le_of_le_one_left hδ h.le, mul_lt_of_lt_one_left hε h⟩ -- This is also true for `ℚ`-normed spaces theorem exists_dist_lt_le (hδ : 0 < δ) (hε : 0 ≤ ε) (h : dist x z < ε + δ) : ∃ y, dist x y < δ ∧ dist y z ≤ ε := by obtain ⟨y, yz, xy⟩ := exists_dist_le_lt hε hδ (show dist z x < δ + ε by simpa only [dist_comm, add_comm] using h) exact ⟨y, by simp [dist_comm x y, dist_comm y z, ]⟩ -- This is also true for `ℚ`-normed spaces theorem exists_dist_lt_lt (hδ : 0 < δ) (hε : 0 < ε) (h : dist x z < ε + δ) : ∃ y, dist x y < δ ∧ dist y z < ε := by refine (exists_dist_eq x z (div_nonneg hε.le <\| add_nonneg hε.le hδ.le) (div_nonneg hδ.le <\| add_nonneg hε.le hδ.le) <\| by rw [← add_div, div_self (add_pos hε hδ).ne']).imp fun y hy => ?_ rw [hy.1, hy.2, div_mul_comm, div_mul_comm ε] rw [← div_lt_one (add_pos hε hδ)] at h exact ⟨mul_lt_of_lt_one_left hδ h, mul_lt_of_lt_one_left hε h⟩ -- This is also true for `ℚ`-normed spaces theorem disjoint_ball_ball_iff (hδ : 0 < δ) (hε : 0 < ε) : Disjoint (ball x δ) (ball y ε) ↔ δ + ε ≤ dist x y := by refine ⟨fun h => le_of_not_lt fun hxy => ?_, ball_disjoint_ball⟩ rw [add_comm] at hxy obtain ⟨z, hxz, hzy⟩ := exists_dist_lt_lt hδ hε hxy rw [dist_comm] at hxz exact h.le_bot ⟨hxz, hzy⟩ -- This is also true for `ℚ`-normed spaces theorem disjoint_ball_closedBall_iff (hδ : 0 < δ) (hε : 0 ≤ ε) : Disjoint (ball x δ) (closedBall y ε) ↔ δ + ε ≤ dist x y := by refine ⟨fun h => le_of_not_lt fun hxy => ?_, ball_disjoint_closedBall⟩ rw [add_comm] at hxy obtain ⟨z, hxz, hzy⟩ := exists_dist_lt_le hδ hε hxy rw [dist_comm] at hxz exact h.le_bot ⟨hxz, hzy⟩ -- This is also true for `ℚ`-normed spaces theorem disjoint_closedBall_ball_iff (hδ : 0 ≤ δ) (hε : 0 < ε) : Disjoint (closedBall x δ) (ball y ε) ↔ δ + ε ≤ dist x y := by rw [disjoint_comm, disjoint_ball_closedBall_iff hε hδ, add_comm, dist_comm] theorem disjoint_closedBall_closedBall_iff (hδ : 0 ≤ δ) (hε : 0 ≤ ε) : Disjoint (closedBall x δ) (closedBall y ε) ↔ δ + ε < dist x y := by refine ⟨fun h => lt_of_not_ge fun hxy => ?_, closedBall_disjoint_closedBall⟩ rw [add_comm] at hxy obtain ⟨z, hxz, hzy⟩ := exists_dist_le_le hδ hε hxy rw [dist_comm] at hxz exact h.le_bot ⟨hxz, hzy⟩ open EMetric ENNReal @[simp] theorem infEdist_thickening (hδ : 0 < δ) (s : Set E) (x : E) : infEdist x (thickening δ s) = infEdist x s - ENNReal.ofReal δ := by obtain hs \| hs := lt_or_le (infEdist x s) (ENNReal.ofReal δ) · rw [infEdist_zero_of_mem, tsub_eq_zero_of_le hs.le] exact hs refine (tsub_le_iff_right.2 infEdist_le_infEdist_thickening_add).antisymm' ?_ refine le_sub_of_add_le_right ofReal_ne_top ?_ refine le_infEdist.2 fun z hz => le_of_forall_lt' fun r h => ?_ cases r with \| top => exact add_lt_top.2 ⟨lt_top_iff_ne_top.2 <\| infEdist_ne_top ⟨z, self_subset_thickening hδ _ hz⟩, ofReal_lt_top⟩ \| coe r => have hr : 0 < ↑r - δ := by refine sub_pos_of_lt ?_ have := hs.trans_lt ((infEdist_le_edist_of_mem hz).trans_lt h) rw [ofReal_eq_coe_nnreal hδ.le] at this exact mod_cast this rw [edist_lt_coe, ← dist_lt_coe, ← add_sub_cancel δ ↑r] at h obtain ⟨y, hxy, hyz⟩ := exists_dist_lt_lt hr hδ h refine (ENNReal.add_lt_add_right ofReal_ne_top <\| infEdist_lt_iff.2 ⟨_, mem_thickening_iff.2 ⟨_, hz, hyz⟩, edist_lt_ofReal.2 hxy⟩).trans_le ?_ rw [← ofReal_add hr.le hδ.le, sub_add_cancel, ofReal_coe_nnreal] @[simp] theorem thickening_thickening (hε : 0 < ε) (hδ : 0 < δ) (s : Set E) : thickening ε (thickening δ s) = thickening (ε + δ) s := (thickening_thickening_subset _ _ _).antisymm fun x => by simp_rw [mem_thickening_iff] rintro ⟨z, hz, hxz⟩ rw [add_comm] at hxz obtain ⟨y, hxy, hyz⟩ := exists_dist_lt_lt hε hδ hxz exact ⟨y, ⟨_, hz, hyz⟩, hxy⟩ @[simp] theorem cthickening_thickening (hε : 0 ≤ ε) (hδ : 0 < δ) (s : Set E) : cthickening ε (thickening δ s) = cthickening (ε + δ) s := (cthickening_thickening_subset hε _ _).antisymm fun x => by simp_rw [mem_cthickening_iff, ENNReal.ofReal_add hε hδ.le, infEdist_thickening hδ] exact tsub_le_iff_right.2 -- Note: `interior (cthickening δ s) ≠ thickening δ s` in general @[simp] theorem closure_thickening (hδ : 0 < δ) (s : Set E) : closure (thickening δ s) = cthickening δ s := by rw [← cthickening_zero, cthickening_thickening le_rfl hδ, zero_add] @[simp] theorem infEdist_cthickening (δ : ℝ) (s : Set E) (x : E) : infEdist x (cthickening δ s) = infEdist x s - ENNReal.ofReal δ := by obtain hδ \| hδ := le_or_lt δ 0 · rw [cthickening_of_nonpos hδ, infEdist_closure, ofReal_of_nonpos hδ, tsub_zero] · rw [← closure_thickening hδ, infEdist_closure, infEdist_thickening hδ] @[simp] theorem thickening_cthickening (hε : 0 < ε) (hδ : 0 ≤ δ) (s : Set E) : thickening ε (cthickening δ s) = thickening (ε + δ) s := by obtain rfl \| hδ := hδ.eq_or_lt · rw [cthickening_zero, thickening_closure, add_zero] · rw [← closure_thickening hδ, thickening_closure, thickening_thickening hε hδ] @[simp] theorem cthickening_cthickening (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (s : Set E) : cthickening ε (cthickening δ s) = cthickening (ε + δ) s := (cthickening_cthickening_subset hε hδ _).antisymm fun x => by simp_rw [mem_cthickening_iff, ENNReal.ofReal_add hε hδ, infEdist_cthickening] exact tsub_le_iff_right.2 @[simp] theorem thickening_ball (hε : 0 < ε) (hδ : 0 < δ) (x : E) : thickening ε (ball x δ) = ball x (ε + δ) := by rw [← thickening_singleton, thickening_thickening hε hδ, thickening_singleton] @[simp] theorem thickening_closedBall (hε : 0 < ε) (hδ : 0 ≤ δ) (x : E) : thickening ε (closedBall x δ) = ball x (ε + δ) := by rw [← cthickening_singleton _ hδ, thickening_cthickening hε hδ, thickening_singleton] @[simp] theorem cthickening_ball (hε : 0 ≤ ε) (hδ : 0 < δ) (x : E) : cthickening ε (ball x δ) = closedBall x (ε + δ) := by rw [← thickening_singleton, cthickening_thickening hε hδ, cthickening_singleton _ (add_nonneg hε hδ.le)] @[simp] theorem cthickening_closedBall (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (x : E) : cthickening ε (closedBall x δ) = closedBall x (ε + δ) := by rw [← cthickening_singleton _ hδ, cthickening_cthickening hε hδ, cthickening_singleton _ (add_nonneg hε hδ)] theorem ball_add_ball (hε : 0 < ε) (hδ : 0 < δ) (a b : E) : ball a ε + ball b δ = ball (a + b) (ε + δ) := by rw [ball_add, thickening_ball hε hδ b, Metric.vadd_ball, vadd_eq_add] theorem ball_sub_ball (hε : 0 < ε) (hδ : 0 < δ) (a b : E) : ball a ε - ball b δ = ball (a - b) (ε + δ) := by simp_rw [sub_eq_add_neg, neg_ball, ball_add_ball hε hδ] theorem ball_add_closedBall (hε : 0 < ε) (hδ : 0 ≤ δ) (a b : E) : ball a ε + closedBall b δ = ball (a + b) (ε + δ) := by rw [ball_add, thickening_closedBall hε hδ b, Metric.vadd_ball, vadd_eq_add] theorem ball_sub_closedBall (hε : 0 < ε) (hδ : 0 ≤ δ) (a b : E) : ball a ε - closedBall b δ = ball (a - b) (ε + δ) := by simp_rw [sub_eq_add_neg, neg_closedBall, ball_add_closedBall hε hδ] theorem closedBall_add_ball (hε : 0 ≤ ε) (hδ : 0 < δ) (a b : E) : closedBall a ε + ball b δ = ball (a + b) (ε + δ) := by rw [add_comm, ball_add_closedBall hδ hε b, add_comm, add_comm δ] theorem closedBall_sub_ball (hε : 0 ≤ ε) (hδ : 0 < δ) (a b : E) : closedBall a ε - ball b δ = ball (a - b) (ε + δ) := by simp_rw [sub_eq_add_neg, neg_ball, closedBall_add_ball hε hδ] theorem closedBall_add_closedBall [ProperSpace E] (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (a b : E) : closedBall a ε + closedBall b δ = closedBall (a + b) (ε + δ) := by rw [(isCompact_closedBall _ _).add_closedBall hδ b, cthickening_closedBall hδ hε a, Metric.vadd_closedBall, vadd_eq_add, add_comm, add_comm δ] theorem closedBall_sub_closedBall [ProperSpace E] (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (a b : E) : closedBall a ε - closedBall b δ = closedBall (a - b) (ε + δ) := by rw [sub_eq_add_neg, neg_closedBall, closedBall_add_closedBall hε hδ, sub_eq_add_neg] end SeminormedAddCommGroup section NormedAddCommGroup variable [NormedAddCommGroup E] [NormedSpace 𝕜 E] theorem smul_closedBall (c : 𝕜) (x : E) {r : ℝ} (hr : 0 ≤ r) : c • closedBall x r = closedBall (c • x) (‖c‖ r) := by rcases eq_or_ne c 0 with (rfl \| hc) · simp [hr, zero_smul_set, Set.singleton_zero, nonempty_closedBall] · exact smul_closedBall' hc x r theorem smul_unitClosedBall (c : 𝕜) : c • closedBall (0 : E) (1 : ℝ) = closedBall (0 : E) ‖c‖ := by rw [_root_.smul_closedBall _ _ zero_le_one, smul_zero, mul_one] @[deprecated (since := "2024-12-01")] alias smul_closedUnitBall := smul_unitClosedBall variable [NormedSpace ℝ E] /-- In a real normed space, the image of the unit closed ball under multiplication by a nonnegative number `r` is the closed ball of radius `r` with center at the origin. -/ theorem smul_unitClosedBall_of_nonneg {r : ℝ} (hr : 0 ≤ r) : r • closedBall (0 : E) 1 = closedBall (0 : E) r := by rw [smul_unitClosedBall, Real.norm_of_nonneg hr] @[deprecated (since := "2024-12-01")] alias smul_closedUnitBall_of_nonneg := smul_unitClosedBall_of_nonneg /-- In a nontrivial real normed space, a sphere is nonempty if and only if its radius is nonnegative. -/ @[simp] theorem NormedSpace.sphere_nonempty [Nontrivial E] {x : E} {r : ℝ} : (sphere x r).Nonempty ↔ 0 ≤ r := by obtain ⟨y, hy⟩ := exists_ne x refine ⟨fun h => nonempty_closedBall.1 (h.mono sphere_subset_closedBall), fun hr => ⟨r • ‖y - x‖⁻¹ • (y - x) + x, ?_⟩⟩ have : ‖y - x‖ ≠ 0 := by simpa [sub_eq_zero] simp only [mem_sphere_iff_norm, add_sub_cancel_right, norm_smul, Real.norm_eq_abs, norm_inv, norm_norm, ne_eq, norm_eq_zero] simp only [abs_norm, ne_eq, norm_eq_zero] rw [inv_mul_cancel₀ this, mul_one, abs_eq_self.mpr hr] theorem smul_sphere [Nontrivial E] (c : 𝕜) (x : E) {r : ℝ} (hr : 0 ≤ r) : c • sphere x r = sphere (c • x) (‖c‖ * r) := by rcases eq_or_ne c 0 with (rfl \| hc) · simp [zero_smul_set, Set.singleton_zero, hr] · exact smul_sphere' hc x r /-- Any ball `Metric.ball x r`, `0 < r` is the image of the unit ball under `fun y ↦ x + r • y`. -/ theorem affinity_unitBall {r : ℝ} (hr : 0 < r) (x : E) : x +ᵥ r • ball (0 : E) 1 = ball x r := by rw [smul_unitBall_of_pos hr, vadd_ball_zero] /-- Any closed ball `Metric.closedBall x r`, `0 ≤ r` is the image of the unit closed ball under `fun y ↦ x + r • y`. -/ theorem affinity_unitClosedBall {r : ℝ} (hr : 0 ≤ r) (x : E) : x +ᵥ r • closedBall (0 : E) 1 = closedBall x r := by rw [smul_unitClosedBall, Real.norm_of_nonneg hr, vadd_closedBall_zero] end NormedAddCommGroup		Mathlib/Analysis/NormedSpace/Pointwise.lean	415	417
/- 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, Kevin Buzzard, Yury Kudryashov, Frédéric Dupuis, Heather Macbeth -/ import Mathlib.Algebra.Group.Subgroup.Map import Mathlib.Algebra.Module.Submodule.Basic import Mathlib.Algebra.Module.Submodule.Lattice import Mathlib.Algebra.Module.Submodule.LinearMap /-! # `map` and `comap` for `Submodule`s ## Main declarations * `Submodule.map`: The pushforward of a submodule `p ⊆ M` by `f : M → M₂` * `Submodule.comap`: The pullback of a submodule `p ⊆ M₂` along `f : M → M₂` * `Submodule.giMapComap`: `map f` and `comap f` form a `GaloisInsertion` when `f` is surjective. * `Submodule.gciMapComap`: `map f` and `comap f` form a `GaloisCoinsertion` when `f` is injective. ## Tags submodule, subspace, linear map, pushforward, pullback -/ open Function Pointwise Set variable {R : Type} {R₁ : Type} {R₂ : Type} {R₃ : Type} variable {M : Type} {M₁ : Type} {M₂ : Type} {M₃ : Type} namespace Submodule section AddCommMonoid variable [Semiring R] [Semiring R₂] [Semiring R₃] variable [AddCommMonoid M] [AddCommMonoid M₂] [AddCommMonoid M₃] variable [Module R M] [Module R₂ M₂] [Module R₃ M₃] variable {σ₁₂ : R →+* R₂} {σ₂₃ : R₂ →+* R₃} {σ₁₃ : R →+* R₃} variable [RingHomCompTriple σ₁₂ σ₂₃ σ₁₃] variable (p p' : Submodule R M) (q q' : Submodule R₂ M₂) variable {x : M} section variable [RingHomSurjective σ₁₂] {F : Type} [FunLike F M M₂] [SemilinearMapClass F σ₁₂ M M₂] /-- The pushforward of a submodule `p ⊆ M` by `f : M → M₂` -/ def map (f : F) (p : Submodule R M) : Submodule R₂ M₂ := { p.toAddSubmonoid.map f with carrier := f '' p smul_mem' := by rintro c x ⟨y, hy, rfl⟩ obtain ⟨a, rfl⟩ := σ₁₂.surjective c exact ⟨_, p.smul_mem a hy, map_smulₛₗ f _ _⟩ } @[simp] theorem map_coe (f : F) (p : Submodule R M) : (map f p : Set M₂) = f '' p := rfl @[simp] theorem map_coe_toLinearMap (f : F) (p : Submodule R M) : map (f : M →ₛₗ[σ₁₂] M₂) p = map f p := rfl theorem map_toAddSubmonoid (f : M →ₛₗ[σ₁₂] M₂) (p : Submodule R M) : (p.map f).toAddSubmonoid = p.toAddSubmonoid.map (f : M →+ M₂) := SetLike.coe_injective rfl theorem map_toAddSubmonoid' (f : M →ₛₗ[σ₁₂] M₂) (p : Submodule R M) : (p.map f).toAddSubmonoid = p.toAddSubmonoid.map f := SetLike.coe_injective rfl @[simp] theorem _root_.AddMonoidHom.coe_toIntLinearMap_map {A A₂ : Type} [AddCommGroup A] [AddCommGroup A₂] (f : A →+ A₂) (s : AddSubgroup A) : (AddSubgroup.toIntSubmodule s).map f.toIntLinearMap = AddSubgroup.toIntSubmodule (s.map f) := rfl @[simp] theorem _root_.MonoidHom.coe_toAdditive_map {G G₂ : Type} [Group G] [Group G₂] (f : G → G₂) (s : Subgroup G) : s.toAddSubgroup.map (MonoidHom.toAdditive f) = Subgroup.toAddSubgroup (s.map f) := rfl @[simp] theorem _root_.AddMonoidHom.coe_toMultiplicative_map {G G₂ : Type*} [AddGroup G] [AddGroup G₂] (f : G →+ G₂) (s : AddSubgroup G) : s.toSubgroup.map (AddMonoidHom.toMultiplicative f) = AddSubgroup.toSubgroup (s.map f) := rfl @[simp] theorem mem_map {f : F} {p : Submodule R M} {x : M₂} : x ∈ map f p ↔ ∃ y, y ∈ p ∧ f y = x := Iff.rfl theorem mem_map_of_mem {f : F} {p : Submodule R M} {r} (h : r ∈ p) : f r ∈ map f p := Set.mem_image_of_mem _ h theorem apply_coe_mem_map (f : F) {p : Submodule R M} (r : p) : f r ∈ map f p := mem_map_of_mem r.prop @[simp] theorem map_id : map (LinearMap.id : M →ₗ[R] M) p = p := Submodule.ext fun a => by simp theorem map_comp [RingHomSurjective σ₂₃] [RingHomSurjective σ₁₃] (f : M →ₛₗ[σ₁₂] M₂) (g : M₂ →ₛₗ[σ₂₃] M₃) (p : Submodule R M) : map (g.comp f : M →ₛₗ[σ₁₃] M₃) p = map g (map f p) := SetLike.coe_injective <\| by simp only [← image_comp, map_coe, LinearMap.coe_comp, comp_apply] @[gcongr] theorem map_mono {f : F} {p p' : Submodule R M} : p ≤ p' → map f p ≤ map f p' := image_subset _ @[simp] protected theorem map_zero : map (0 : M →ₛₗ[σ₁₂] M₂) p = ⊥ := have : ∃ x : M, x ∈ p := ⟨0, p.zero_mem⟩ ext <\| by simp [this, eq_comm] theorem map_add_le (f g : M →ₛₗ[σ₁₂] M₂) : map (f + g) p ≤ map f p ⊔ map g p := by rintro x ⟨m, hm, rfl⟩ exact add_mem_sup (mem_map_of_mem hm) (mem_map_of_mem hm) theorem map_inf_le (f : F) {p q : Submodule R M} : (p ⊓ q).map f ≤ p.map f ⊓ q.map f :=	image_inter_subset f p q theorem map_inf (f : F) {p q : Submodule R M} (hf : Injective f) :	Mathlib/Algebra/Module/Submodule/Map.lean	121	123
/- Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Algebra.Order.Ring.Nat import Mathlib.Algebra.Ring.Int.Defs import Mathlib.Data.Nat.Bitwise import Mathlib.Data.Nat.Cast.Order.Basic import Mathlib.Data.Nat.PSub import Mathlib.Data.Nat.Size import Mathlib.Data.Num.Bitwise /-! # Properties of the binary representation of integers -/ open Int attribute [local simp] add_assoc namespace PosNum variable {α : Type} @[simp, norm_cast] theorem cast_one [One α] [Add α] : ((1 : PosNum) : α) = 1 := rfl @[simp] theorem cast_one' [One α] [Add α] : (PosNum.one : α) = 1 := rfl @[simp, norm_cast] theorem cast_bit0 [One α] [Add α] (n : PosNum) : (n.bit0 : α) = (n : α) + n := rfl @[simp, norm_cast] theorem cast_bit1 [One α] [Add α] (n : PosNum) : (n.bit1 : α) = ((n : α) + n) + 1 := rfl @[simp, norm_cast] theorem cast_to_nat [AddMonoidWithOne α] : ∀ n : PosNum, ((n : ℕ) : α) = n \| 1 => Nat.cast_one \| bit0 p => by dsimp; rw [Nat.cast_add, p.cast_to_nat] \| bit1 p => by dsimp; rw [Nat.cast_add, Nat.cast_add, Nat.cast_one, p.cast_to_nat] @[norm_cast] theorem to_nat_to_int (n : PosNum) : ((n : ℕ) : ℤ) = n := cast_to_nat _ @[simp, norm_cast] theorem cast_to_int [AddGroupWithOne α] (n : PosNum) : ((n : ℤ) : α) = n := by rw [← to_nat_to_int, Int.cast_natCast, cast_to_nat] theorem succ_to_nat : ∀ n, (succ n : ℕ) = n + 1 \| 1 => rfl \| bit0 _ => rfl \| bit1 p => (congr_arg (fun n ↦ n + n) (succ_to_nat p)).trans <\| show ↑p + 1 + ↑p + 1 = ↑p + ↑p + 1 + 1 by simp [add_left_comm] theorem one_add (n : PosNum) : 1 + n = succ n := by cases n <;> rfl theorem add_one (n : PosNum) : n + 1 = succ n := by cases n <;> rfl @[norm_cast] theorem add_to_nat : ∀ m n, ((m + n : PosNum) : ℕ) = m + n \| 1, b => by rw [one_add b, succ_to_nat, add_comm, cast_one] \| a, 1 => by rw [add_one a, succ_to_nat, cast_one] \| bit0 a, bit0 b => (congr_arg (fun n ↦ n + n) (add_to_nat a b)).trans <\| add_add_add_comm _ _ _ _ \| bit0 a, bit1 b => (congr_arg (fun n ↦ (n + n) + 1) (add_to_nat a b)).trans <\| show (a + b + (a + b) + 1 : ℕ) = a + a + (b + b + 1) by simp [add_left_comm] \| bit1 a, bit0 b => (congr_arg (fun n ↦ (n + n) + 1) (add_to_nat a b)).trans <\| show (a + b + (a + b) + 1 : ℕ) = a + a + 1 + (b + b) by simp [add_comm, add_left_comm] \| bit1 a, bit1 b => show (succ (a + b) + succ (a + b) : ℕ) = a + a + 1 + (b + b + 1) by rw [succ_to_nat, add_to_nat a b]; simp [add_left_comm] theorem add_succ : ∀ m n : PosNum, m + succ n = succ (m + n) \| 1, b => by simp [one_add] \| bit0 a, 1 => congr_arg bit0 (add_one a) \| bit1 a, 1 => congr_arg bit1 (add_one a) \| bit0 _, bit0 _ => rfl \| bit0 a, bit1 b => congr_arg bit0 (add_succ a b) \| bit1 _, bit0 _ => rfl \| bit1 a, bit1 b => congr_arg bit1 (add_succ a b) theorem bit0_of_bit0 : ∀ n, n + n = bit0 n \| 1 => rfl \| bit0 p => congr_arg bit0 (bit0_of_bit0 p) \| bit1 p => show bit0 (succ (p + p)) = _ by rw [bit0_of_bit0 p, succ] theorem bit1_of_bit1 (n : PosNum) : (n + n) + 1 = bit1 n := show (n + n) + 1 = bit1 n by rw [add_one, bit0_of_bit0, succ] @[norm_cast] theorem mul_to_nat (m) : ∀ n, ((m n : PosNum) : ℕ) = m * n \| 1 => (mul_one _).symm \| bit0 p => show (↑(m * p) + ↑(m * p) : ℕ) = ↑m * (p + p) by rw [mul_to_nat m p, left_distrib] \| bit1 p => (add_to_nat (bit0 (m * p)) m).trans <\| show (↑(m * p) + ↑(m * p) + ↑m : ℕ) = ↑m * (p + p) + m by rw [mul_to_nat m p, left_distrib] theorem to_nat_pos : ∀ n : PosNum, 0 < (n : ℕ) \| 1 => Nat.zero_lt_one \| bit0 p => let h := to_nat_pos p add_pos h h \| bit1 _p => Nat.succ_pos _ theorem cmp_to_nat_lemma {m n : PosNum} : (m : ℕ) < n → (bit1 m : ℕ) < bit0 n := show (m : ℕ) < n → (m + m + 1 + 1 : ℕ) ≤ n + n by intro h; rw [Nat.add_right_comm m m 1, add_assoc]; exact Nat.add_le_add h h theorem cmp_swap (m) : ∀ n, (cmp m n).swap = cmp n m := by induction' m with m IH m IH <;> intro n <;> obtain - \| n \| n := n <;> unfold cmp <;> try { rfl } <;> rw [← IH] <;> cases cmp m n <;> rfl theorem cmp_to_nat : ∀ m n, (Ordering.casesOn (cmp m n) ((m : ℕ) < n) (m = n) ((n : ℕ) < m) : Prop) \| 1, 1 => rfl \| bit0 a, 1 => let h : (1 : ℕ) ≤ a := to_nat_pos a Nat.add_le_add h h \| bit1 a, 1 => Nat.succ_lt_succ <\| to_nat_pos <\| bit0 a \| 1, bit0 b => let h : (1 : ℕ) ≤ b := to_nat_pos b Nat.add_le_add h h \| 1, bit1 b => Nat.succ_lt_succ <\| to_nat_pos <\| bit0 b \| bit0 a, bit0 b => by dsimp [cmp] have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this · exact Nat.add_lt_add this this · rw [this] · exact Nat.add_lt_add this this \| bit0 a, bit1 b => by dsimp [cmp] have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this · exact Nat.le_succ_of_le (Nat.add_lt_add this this) · rw [this] apply Nat.lt_succ_self · exact cmp_to_nat_lemma this \| bit1 a, bit0 b => by dsimp [cmp] have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this · exact cmp_to_nat_lemma this · rw [this] apply Nat.lt_succ_self · exact Nat.le_succ_of_le (Nat.add_lt_add this this) \| bit1 a, bit1 b => by dsimp [cmp] have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this · exact Nat.succ_lt_succ (Nat.add_lt_add this this) · rw [this] · exact Nat.succ_lt_succ (Nat.add_lt_add this this) @[norm_cast] theorem lt_to_nat {m n : PosNum} : (m : ℕ) < n ↔ m < n := show (m : ℕ) < n ↔ cmp m n = Ordering.lt from match cmp m n, cmp_to_nat m n with \| Ordering.lt, h => by simp only at h; simp [h] \| Ordering.eq, h => by simp only at h; simp [h, lt_irrefl] \| Ordering.gt, h => by simp [not_lt_of_gt h] @[norm_cast] theorem le_to_nat {m n : PosNum} : (m : ℕ) ≤ n ↔ m ≤ n := by rw [← not_lt]; exact not_congr lt_to_nat end PosNum namespace Num variable {α : Type} open PosNum theorem add_zero (n : Num) : n + 0 = n := by cases n <;> rfl theorem zero_add (n : Num) : 0 + n = n := by cases n <;> rfl theorem add_one : ∀ n : Num, n + 1 = succ n \| 0 => rfl \| pos p => by cases p <;> rfl theorem add_succ : ∀ m n : Num, m + succ n = succ (m + n) \| 0, n => by simp [zero_add] \| pos p, 0 => show pos (p + 1) = succ (pos p + 0) by rw [PosNum.add_one, add_zero, succ, succ'] \| pos _, pos _ => congr_arg pos (PosNum.add_succ _ _) theorem bit0_of_bit0 : ∀ n : Num, n + n = n.bit0 \| 0 => rfl \| pos p => congr_arg pos p.bit0_of_bit0 theorem bit1_of_bit1 : ∀ n : Num, (n + n) + 1 = n.bit1 \| 0 => rfl \| pos p => congr_arg pos p.bit1_of_bit1 @[simp] theorem ofNat'_zero : Num.ofNat' 0 = 0 := by simp [Num.ofNat'] theorem ofNat'_bit (b n) : ofNat' (Nat.bit b n) = cond b Num.bit1 Num.bit0 (ofNat' n) := Nat.binaryRec_eq _ _ (.inl rfl) @[simp] theorem ofNat'_one : Num.ofNat' 1 = 1 := by erw [ofNat'_bit true 0, cond, ofNat'_zero]; rfl theorem bit1_succ : ∀ n : Num, n.bit1.succ = n.succ.bit0 \| 0 => rfl \| pos _n => rfl theorem ofNat'_succ : ∀ {n}, ofNat' (n + 1) = ofNat' n + 1 := @(Nat.binaryRec (by simp [zero_add]) fun b n ih => by cases b · erw [ofNat'_bit true n, ofNat'_bit] simp only [← bit1_of_bit1, ← bit0_of_bit0, cond] · rw [show n.bit true + 1 = (n + 1).bit false by simp [Nat.bit, mul_add], ofNat'_bit, ofNat'_bit, ih] simp only [cond, add_one, bit1_succ]) @[simp] theorem add_ofNat' (m n) : Num.ofNat' (m + n) = Num.ofNat' m + Num.ofNat' n := by induction n · simp only [Nat.add_zero, ofNat'_zero, add_zero] · simp only [Nat.add_succ, Nat.add_zero, ofNat'_succ, add_one, add_succ, ] @[simp, norm_cast] theorem cast_zero [Zero α] [One α] [Add α] : ((0 : Num) : α) = 0 := rfl @[simp] theorem cast_zero' [Zero α] [One α] [Add α] : (Num.zero : α) = 0 := rfl @[simp, norm_cast] theorem cast_one [Zero α] [One α] [Add α] : ((1 : Num) : α) = 1 := rfl @[simp] theorem cast_pos [Zero α] [One α] [Add α] (n : PosNum) : (Num.pos n : α) = n := rfl theorem succ'_to_nat : ∀ n, (succ' n : ℕ) = n + 1 \| 0 => (Nat.zero_add _).symm \| pos _p => PosNum.succ_to_nat _ theorem succ_to_nat (n) : (succ n : ℕ) = n + 1 := succ'_to_nat n @[simp, norm_cast] theorem cast_to_nat [AddMonoidWithOne α] : ∀ n : Num, ((n : ℕ) : α) = n \| 0 => Nat.cast_zero \| pos p => p.cast_to_nat @[norm_cast] theorem add_to_nat : ∀ m n, ((m + n : Num) : ℕ) = m + n \| 0, 0 => rfl \| 0, pos _q => (Nat.zero_add _).symm \| pos _p, 0 => rfl \| pos _p, pos _q => PosNum.add_to_nat _ _ @[norm_cast] theorem mul_to_nat : ∀ m n, ((m * n : Num) : ℕ) = m * n \| 0, 0 => rfl \| 0, pos _q => (zero_mul _).symm \| pos _p, 0 => rfl \| pos _p, pos _q => PosNum.mul_to_nat _ _ theorem cmp_to_nat : ∀ m n, (Ordering.casesOn (cmp m n) ((m : ℕ) < n) (m = n) ((n : ℕ) < m) : Prop) \| 0, 0 => rfl \| 0, pos _ => to_nat_pos _ \| pos _, 0 => to_nat_pos _ \| pos a, pos b => by have := PosNum.cmp_to_nat a b; revert this; dsimp [cmp]; cases PosNum.cmp a b exacts [id, congr_arg pos, id] @[norm_cast] theorem lt_to_nat {m n : Num} : (m : ℕ) < n ↔ m < n := show (m : ℕ) < n ↔ cmp m n = Ordering.lt from match cmp m n, cmp_to_nat m n with \| Ordering.lt, h => by simp only at h; simp [h] \| Ordering.eq, h => by simp only at h; simp [h, lt_irrefl] \| Ordering.gt, h => by simp [not_lt_of_gt h] @[norm_cast] theorem le_to_nat {m n : Num} : (m : ℕ) ≤ n ↔ m ≤ n := by rw [← not_lt]; exact not_congr lt_to_nat end Num namespace PosNum @[simp] theorem of_to_nat' : ∀ n : PosNum, Num.ofNat' (n : ℕ) = Num.pos n \| 1 => by erw [@Num.ofNat'_bit true 0, Num.ofNat'_zero]; rfl \| bit0 p => by simpa only [Nat.bit_false, cond_false, two_mul, of_to_nat' p] using Num.ofNat'_bit false p \| bit1 p => by simpa only [Nat.bit_true, cond_true, two_mul, of_to_nat' p] using Num.ofNat'_bit true p end PosNum namespace Num @[simp, norm_cast] theorem of_to_nat' : ∀ n : Num, Num.ofNat' (n : ℕ) = n \| 0 => ofNat'_zero \| pos p => p.of_to_nat' lemma toNat_injective : Function.Injective (castNum : Num → ℕ) := Function.LeftInverse.injective of_to_nat' @[norm_cast] theorem to_nat_inj {m n : Num} : (m : ℕ) = n ↔ m = n := toNat_injective.eq_iff /-- This tactic tries to turn an (in)equality about `Num`s to one about `Nat`s by rewriting. ```lean example (n : Num) (m : Num) : n ≤ n + m := by transfer_rw exact Nat.le_add_right _ _ ``` -/ scoped macro (name := transfer_rw) "transfer_rw" : tactic => `(tactic\| (repeat first \| rw [← to_nat_inj] \| rw [← lt_to_nat] \| rw [← le_to_nat] repeat first \| rw [add_to_nat] \| rw [mul_to_nat] \| rw [cast_one] \| rw [cast_zero])) /-- This tactic tries to prove (in)equalities about `Num`s by transferring them to the `Nat` world and then trying to call `simp`. ```lean example (n : Num) (m : Num) : n ≤ n + m := by transfer ``` -/ scoped macro (name := transfer) "transfer" : tactic => `(tactic\| (intros; transfer_rw; try simp)) instance addMonoid : AddMonoid Num where add := (· + ·) zero := 0 zero_add := zero_add add_zero := add_zero add_assoc := by transfer nsmul := nsmulRec instance addMonoidWithOne : AddMonoidWithOne Num := { Num.addMonoid with natCast := Num.ofNat' one := 1 natCast_zero := ofNat'_zero natCast_succ := fun _ => ofNat'_succ } instance commSemiring : CommSemiring Num where __ := Num.addMonoid __ := Num.addMonoidWithOne mul := (· * ·) npow := @npowRec Num ⟨1⟩ ⟨(· * ·)⟩ mul_zero _ := by rw [← to_nat_inj, mul_to_nat, cast_zero, mul_zero] zero_mul _ := by rw [← to_nat_inj, mul_to_nat, cast_zero, zero_mul] mul_one _ := by rw [← to_nat_inj, mul_to_nat, cast_one, mul_one] one_mul _ := by rw [← to_nat_inj, mul_to_nat, cast_one, one_mul] add_comm _ _ := by simp_rw [← to_nat_inj, add_to_nat, add_comm] mul_comm _ _ := by simp_rw [← to_nat_inj, mul_to_nat, mul_comm] mul_assoc _ _ _ := by simp_rw [← to_nat_inj, mul_to_nat, mul_assoc] left_distrib _ _ _ := by simp only [← to_nat_inj, mul_to_nat, add_to_nat, mul_add] right_distrib _ _ _ := by simp only [← to_nat_inj, mul_to_nat, add_to_nat, add_mul] instance partialOrder : PartialOrder Num where lt_iff_le_not_le a b := by simp only [← lt_to_nat, ← le_to_nat, lt_iff_le_not_le] le_refl := by transfer le_trans a b c := by transfer_rw; apply le_trans le_antisymm a b := by transfer_rw; apply le_antisymm instance isOrderedCancelAddMonoid : IsOrderedCancelAddMonoid Num where add_le_add_left a b h c := by revert h; transfer_rw; exact fun h => add_le_add_left h c le_of_add_le_add_left a b c := show a + b ≤ a + c → b ≤ c by transfer_rw; apply le_of_add_le_add_left instance linearOrder : LinearOrder Num := { le_total := by intro a b transfer_rw apply le_total toDecidableLT := Num.decidableLT toDecidableLE := Num.decidableLE -- This is relying on an automatically generated instance name, -- generated in a `deriving` handler. -- See https://github.com/leanprover/lean4/issues/2343 toDecidableEq := instDecidableEqNum } instance isStrictOrderedRing : IsStrictOrderedRing Num := { zero_le_one := by decide mul_lt_mul_of_pos_left := by intro a b c transfer_rw apply mul_lt_mul_of_pos_left mul_lt_mul_of_pos_right := by intro a b c transfer_rw apply mul_lt_mul_of_pos_right exists_pair_ne := ⟨0, 1, by decide⟩ } @[norm_cast] theorem add_of_nat (m n) : ((m + n : ℕ) : Num) = m + n := add_ofNat' _ _ @[norm_cast] theorem to_nat_to_int (n : Num) : ((n : ℕ) : ℤ) = n := cast_to_nat _ @[simp, norm_cast] theorem cast_to_int {α} [AddGroupWithOne α] (n : Num) : ((n : ℤ) : α) = n := by rw [← to_nat_to_int, Int.cast_natCast, cast_to_nat] theorem to_of_nat : ∀ n : ℕ, ((n : Num) : ℕ) = n \| 0 => by rw [Nat.cast_zero, cast_zero] \| n + 1 => by rw [Nat.cast_succ, add_one, succ_to_nat, to_of_nat n] @[simp, norm_cast] theorem of_natCast {α} [AddMonoidWithOne α] (n : ℕ) : ((n : Num) : α) = n := by rw [← cast_to_nat, to_of_nat] @[norm_cast] theorem of_nat_inj {m n : ℕ} : (m : Num) = n ↔ m = n := ⟨fun h => Function.LeftInverse.injective to_of_nat h, congr_arg _⟩ -- The priority should be `high`er than `cast_to_nat`. @[simp high, norm_cast] theorem of_to_nat : ∀ n : Num, ((n : ℕ) : Num) = n := of_to_nat' @[norm_cast] theorem dvd_to_nat (m n : Num) : (m : ℕ) ∣ n ↔ m ∣ n := ⟨fun ⟨k, e⟩ => ⟨k, by rw [← of_to_nat n, e]; simp⟩, fun ⟨k, e⟩ => ⟨k, by simp [e, mul_to_nat]⟩⟩ end Num namespace PosNum variable {α : Type} open Num -- The priority should be `high`er than `cast_to_nat`. @[simp high, norm_cast] theorem of_to_nat : ∀ n : PosNum, ((n : ℕ) : Num) = Num.pos n := of_to_nat' @[norm_cast] theorem to_nat_inj {m n : PosNum} : (m : ℕ) = n ↔ m = n := ⟨fun h => Num.pos.inj <\| by rw [← PosNum.of_to_nat, ← PosNum.of_to_nat, h], congr_arg _⟩ theorem pred'_to_nat : ∀ n, (pred' n : ℕ) = Nat.pred n \| 1 => rfl \| bit0 n => have : Nat.succ ↑(pred' n) = ↑n := by rw [pred'_to_nat n, Nat.succ_pred_eq_of_pos (to_nat_pos n)] match (motive := ∀ k : Num, Nat.succ ↑k = ↑n → ↑(Num.casesOn k 1 bit1 : PosNum) = Nat.pred (n + n)) pred' n, this with \| 0, (h : ((1 : Num) : ℕ) = n) => by rw [← to_nat_inj.1 h]; rfl \| Num.pos p, (h : Nat.succ ↑p = n) => by rw [← h]; exact (Nat.succ_add p p).symm \| bit1 _ => rfl @[simp] theorem pred'_succ' (n) : pred' (succ' n) = n := Num.to_nat_inj.1 <\| by rw [pred'_to_nat, succ'_to_nat, Nat.add_one, Nat.pred_succ] @[simp] theorem succ'_pred' (n) : succ' (pred' n) = n := to_nat_inj.1 <\| by rw [succ'_to_nat, pred'_to_nat, Nat.add_one, Nat.succ_pred_eq_of_pos (to_nat_pos _)] instance dvd : Dvd PosNum := ⟨fun m n => pos m ∣ pos n⟩ @[norm_cast] theorem dvd_to_nat {m n : PosNum} : (m : ℕ) ∣ n ↔ m ∣ n := Num.dvd_to_nat (pos m) (pos n) theorem size_to_nat : ∀ n, (size n : ℕ) = Nat.size n \| 1 => Nat.size_one.symm \| bit0 n => by rw [size, succ_to_nat, size_to_nat n, cast_bit0, ← two_mul] erw [@Nat.size_bit false n] have := to_nat_pos n dsimp [Nat.bit]; omega \| bit1 n => by rw [size, succ_to_nat, size_to_nat n, cast_bit1, ← two_mul] erw [@Nat.size_bit true n] dsimp [Nat.bit]; omega theorem size_eq_natSize : ∀ n, (size n : ℕ) = natSize n \| 1 => rfl \| bit0 n => by rw [size, succ_to_nat, natSize, size_eq_natSize n] \| bit1 n => by rw [size, succ_to_nat, natSize, size_eq_natSize n] theorem natSize_to_nat (n) : natSize n = Nat.size n := by rw [← size_eq_natSize, size_to_nat] theorem natSize_pos (n) : 0 < natSize n := by cases n <;> apply Nat.succ_pos /-- This tactic tries to turn an (in)equality about `PosNum`s to one about `Nat`s by rewriting. ```lean example (n : PosNum) (m : PosNum) : n ≤ n + m := by transfer_rw exact Nat.le_add_right _ _ ``` -/ scoped macro (name := transfer_rw) "transfer_rw" : tactic => `(tactic\| (repeat first \| rw [← to_nat_inj] \| rw [← lt_to_nat] \| rw [← le_to_nat] repeat first \| rw [add_to_nat] \| rw [mul_to_nat] \| rw [cast_one] \| rw [cast_zero])) /-- This tactic tries to prove (in)equalities about `PosNum`s by transferring them to the `Nat` world and then trying to call `simp`. ```lean example (n : PosNum) (m : PosNum) : n ≤ n + m := by transfer ``` -/ scoped macro (name := transfer) "transfer" : tactic => `(tactic\| (intros; transfer_rw; try simp [add_comm, add_left_comm, mul_comm, mul_left_comm])) instance addCommSemigroup : AddCommSemigroup PosNum where add := (· + ·) add_assoc := by transfer add_comm := by transfer instance commMonoid : CommMonoid PosNum where mul := (· ·) one := (1 : PosNum) npow := @npowRec PosNum ⟨1⟩ ⟨(· * ·)⟩ mul_assoc := by transfer one_mul := by transfer mul_one := by transfer mul_comm := by transfer instance distrib : Distrib PosNum where add := (· + ·) mul := (· * ·) left_distrib := by transfer; simp [mul_add] right_distrib := by transfer; simp [mul_add, mul_comm] instance linearOrder : LinearOrder PosNum where lt := (· < ·) lt_iff_le_not_le := by intro a b transfer_rw apply lt_iff_le_not_le le := (· ≤ ·) le_refl := by transfer le_trans := by intro a b c transfer_rw apply le_trans le_antisymm := by intro a b transfer_rw apply le_antisymm le_total := by intro a b transfer_rw apply le_total toDecidableLT := by infer_instance toDecidableLE := by infer_instance toDecidableEq := by infer_instance @[simp] theorem cast_to_num (n : PosNum) : ↑n = Num.pos n := by rw [← cast_to_nat, ← of_to_nat n] @[simp, norm_cast] theorem bit_to_nat (b n) : (bit b n : ℕ) = Nat.bit b n := by cases b <;> simp [bit, two_mul] @[simp, norm_cast] theorem cast_add [AddMonoidWithOne α] (m n) : ((m + n : PosNum) : α) = m + n := by rw [← cast_to_nat, add_to_nat, Nat.cast_add, cast_to_nat, cast_to_nat] @[simp 500, norm_cast] theorem cast_succ [AddMonoidWithOne α] (n : PosNum) : (succ n : α) = n + 1 := by rw [← add_one, cast_add, cast_one] @[simp, norm_cast] theorem cast_inj [AddMonoidWithOne α] [CharZero α] {m n : PosNum} : (m : α) = n ↔ m = n := by rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_inj, to_nat_inj] @[simp] theorem one_le_cast [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] (n : PosNum) : (1 : α) ≤ n := by rw [← cast_to_nat, ← Nat.cast_one, Nat.cast_le (α := α)]; apply to_nat_pos @[simp] theorem cast_pos [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] (n : PosNum) : 0 < (n : α) := lt_of_lt_of_le zero_lt_one (one_le_cast n) @[simp, norm_cast] theorem cast_mul [NonAssocSemiring α] (m n) : ((m * n : PosNum) : α) = m * n := by rw [← cast_to_nat, mul_to_nat, Nat.cast_mul, cast_to_nat, cast_to_nat] @[simp] theorem cmp_eq (m n) : cmp m n = Ordering.eq ↔ m = n := by have := cmp_to_nat m n -- Porting note: `cases` didn't rewrite at `this`, so `revert` & `intro` are required. revert this; cases cmp m n <;> intro this <;> simp at this ⊢ <;> try { exact this } <;> simp [show m ≠ n from fun e => by rw [e] at this;exact lt_irrefl _ this] @[simp, norm_cast] theorem cast_lt [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] {m n : PosNum} : (m : α) < n ↔ m < n := by rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_lt (α := α), lt_to_nat] @[simp, norm_cast] theorem cast_le [Semiring α] [LinearOrder α] [IsStrictOrderedRing α] {m n : PosNum} : (m : α) ≤ n ↔ m ≤ n := by rw [← not_lt]; exact not_congr cast_lt end PosNum namespace Num variable {α : Type} open PosNum theorem bit_to_nat (b n) : (bit b n : ℕ) = Nat.bit b n := by cases b <;> cases n <;> simp [bit, two_mul] <;> rfl theorem cast_succ' [AddMonoidWithOne α] (n) : (succ' n : α) = n + 1 := by rw [← PosNum.cast_to_nat, succ'_to_nat, Nat.cast_add_one, cast_to_nat] theorem cast_succ [AddMonoidWithOne α] (n) : (succ n : α) = n + 1 := cast_succ' n @[simp, norm_cast] theorem cast_add [AddMonoidWithOne α] (m n) : ((m + n : Num) : α) = m + n := by rw [← cast_to_nat, add_to_nat, Nat.cast_add, cast_to_nat, cast_to_nat] @[simp, norm_cast] theorem cast_bit0 [NonAssocSemiring α] (n : Num) : (n.bit0 : α) = 2 (n : α) := by rw [← bit0_of_bit0, two_mul, cast_add] @[simp, norm_cast] theorem cast_bit1 [NonAssocSemiring α] (n : Num) : (n.bit1 : α) = 2 * (n : α) + 1 := by rw [← bit1_of_bit1, bit0_of_bit0, cast_add, cast_bit0]; rfl @[simp, norm_cast] theorem cast_mul [NonAssocSemiring α] : ∀ m n, ((m * n : Num) : α) = m * n \| 0, 0 => (zero_mul _).symm \| 0, pos _q => (zero_mul _).symm \| pos _p, 0 => (mul_zero _).symm \| pos _p, pos _q => PosNum.cast_mul _ _ theorem size_to_nat : ∀ n, (size n : ℕ) = Nat.size n \| 0 => Nat.size_zero.symm \| pos p => p.size_to_nat theorem size_eq_natSize : ∀ n, (size n : ℕ) = natSize n \| 0 => rfl \| pos p => p.size_eq_natSize theorem natSize_to_nat (n) : natSize n = Nat.size n := by rw [← size_eq_natSize, size_to_nat] @[simp 999] theorem ofNat'_eq : ∀ n, Num.ofNat' n = n := Nat.binaryRec (by simp) fun b n IH => by tauto theorem zneg_toZNum (n : Num) : -n.toZNum = n.toZNumNeg := by cases n <;> rfl theorem zneg_toZNumNeg (n : Num) : -n.toZNumNeg = n.toZNum := by cases n <;> rfl theorem toZNum_inj {m n : Num} : m.toZNum = n.toZNum ↔ m = n := ⟨fun h => by cases m <;> cases n <;> cases h <;> rfl, congr_arg _⟩ @[simp] theorem cast_toZNum [Zero α] [One α] [Add α] [Neg α] : ∀ n : Num, (n.toZNum : α) = n \| 0 => rfl \| Num.pos _p => rfl @[simp] theorem cast_toZNumNeg [SubtractionMonoid α] [One α] : ∀ n : Num, (n.toZNumNeg : α) = -n \| 0 => neg_zero.symm \| Num.pos _p => rfl @[simp] theorem add_toZNum (m n : Num) : Num.toZNum (m + n) = m.toZNum + n.toZNum := by cases m <;> cases n <;> rfl end Num namespace PosNum open Num theorem pred_to_nat {n : PosNum} (h : 1 < n) : (pred n : ℕ) = Nat.pred n := by unfold pred cases e : pred' n · have : (1 : ℕ) ≤ Nat.pred n := Nat.pred_le_pred ((@cast_lt ℕ _ _ _).2 h) rw [← pred'_to_nat, e] at this exact absurd this (by decide) · rw [← pred'_to_nat, e] rfl theorem sub'_one (a : PosNum) : sub' a 1 = (pred' a).toZNum := by cases a <;> rfl theorem one_sub' (a : PosNum) : sub' 1 a = (pred' a).toZNumNeg := by cases a <;> rfl theorem lt_iff_cmp {m n} : m < n ↔ cmp m n = Ordering.lt := Iff.rfl theorem le_iff_cmp {m n} : m ≤ n ↔ cmp m n ≠ Ordering.gt := not_congr <\| lt_iff_cmp.trans <\| by rw [← cmp_swap]; cases cmp m n <;> decide end PosNum namespace Num variable {α : Type} open PosNum theorem pred_to_nat : ∀ n : Num, (pred n : ℕ) = Nat.pred n \| 0 => rfl \| pos p => by rw [pred, PosNum.pred'_to_nat]; rfl theorem ppred_to_nat : ∀ n : Num, (↑) <$> ppred n = Nat.ppred n \| 0 => rfl \| pos p => by rw [ppred, Option.map_some, Nat.ppred_eq_some.2] rw [PosNum.pred'_to_nat, Nat.succ_pred_eq_of_pos (PosNum.to_nat_pos _)] rfl theorem cmp_swap (m n) : (cmp m n).swap = cmp n m := by cases m <;> cases n <;> try { rfl }; apply PosNum.cmp_swap theorem cmp_eq (m n) : cmp m n = Ordering.eq ↔ m = n := by have := cmp_to_nat m n -- Porting note: `cases` didn't rewrite at `this`, so `revert` & `intro` are required. revert this; cases cmp m n <;> intro this <;> simp at this ⊢ <;> try { exact this } <;> simp [show m ≠ n from fun e => by rw [e] at this; exact lt_irrefl _ this] @[simp, norm_cast] theorem cast_lt [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] {m n : Num} : (m : α) < n ↔ m < n := by rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_lt (α := α), lt_to_nat] @[simp, norm_cast] theorem cast_le [Semiring α] [LinearOrder α] [IsStrictOrderedRing α] {m n : Num} : (m : α) ≤ n ↔ m ≤ n := by rw [← not_lt]; exact not_congr cast_lt @[simp, norm_cast] theorem cast_inj [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] {m n : Num} : (m : α) = n ↔ m = n := by rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_inj, to_nat_inj] theorem lt_iff_cmp {m n} : m < n ↔ cmp m n = Ordering.lt := Iff.rfl theorem le_iff_cmp {m n} : m ≤ n ↔ cmp m n ≠ Ordering.gt := not_congr <\| lt_iff_cmp.trans <\| by rw [← cmp_swap]; cases cmp m n <;> decide theorem castNum_eq_bitwise {f : Num → Num → Num} {g : Bool → Bool → Bool} (p : PosNum → PosNum → Num) (gff : g false false = false) (f00 : f 0 0 = 0) (f0n : ∀ n, f 0 (pos n) = cond (g false true) (pos n) 0) (fn0 : ∀ n, f (pos n) 0 = cond (g true false) (pos n) 0) (fnn : ∀ m n, f (pos m) (pos n) = p m n) (p11 : p 1 1 = cond (g true true) 1 0) (p1b : ∀ b n, p 1 (PosNum.bit b n) = bit (g true b) (cond (g false true) (pos n) 0)) (pb1 : ∀ a m, p (PosNum.bit a m) 1 = bit (g a true) (cond (g true false) (pos m) 0)) (pbb : ∀ a b m n, p (PosNum.bit a m) (PosNum.bit b n) = bit (g a b) (p m n)) : ∀ m n : Num, (f m n : ℕ) = Nat.bitwise g m n := by intros m n obtain - \| m := m <;> obtain - \| n := n <;> try simp only [show zero = 0 from rfl, show ((0 : Num) : ℕ) = 0 from rfl] · rw [f00, Nat.bitwise_zero]; rfl · rw [f0n, Nat.bitwise_zero_left] cases g false true <;> rfl · rw [fn0, Nat.bitwise_zero_right] cases g true false <;> rfl · rw [fnn] have this b (n : PosNum) : (cond b (↑n) 0 : ℕ) = ↑(cond b (pos n) 0 : Num) := by cases b <;> rfl have this' b (n : PosNum) : ↑ (pos (PosNum.bit b n)) = Nat.bit b ↑n := by cases b <;> simp induction' m with m IH m IH generalizing n <;> obtain - \| n \| n := n any_goals simp only [show one = 1 from rfl, show pos 1 = 1 from rfl, show PosNum.bit0 = PosNum.bit false from rfl, show PosNum.bit1 = PosNum.bit true from rfl, show ((1 : Num) : ℕ) = Nat.bit true 0 from rfl] all_goals repeat rw [this'] rw [Nat.bitwise_bit gff] any_goals rw [Nat.bitwise_zero, p11]; cases g true true <;> rfl any_goals rw [Nat.bitwise_zero_left, ← Bool.cond_eq_ite, this, ← bit_to_nat, p1b] any_goals rw [Nat.bitwise_zero_right, ← Bool.cond_eq_ite, this, ← bit_to_nat, pb1] all_goals rw [← show ∀ n : PosNum, ↑(p m n) = Nat.bitwise g ↑m ↑n from IH] rw [← bit_to_nat, pbb] @[simp, norm_cast] theorem castNum_or : ∀ m n : Num, ↑(m \|\|\| n) = (↑m \|\|\| ↑n : ℕ) := by apply castNum_eq_bitwise fun x y => pos (PosNum.lor x y) <;> (try rintro (_ \| _)) <;> (try rintro (_ \| _)) <;> intros <;> rfl @[simp, norm_cast] theorem castNum_and : ∀ m n : Num, ↑(m &&& n) = (↑m &&& ↑n : ℕ) := by apply castNum_eq_bitwise PosNum.land <;> intros <;> (try cases_type Bool) <;> rfl @[simp, norm_cast] theorem castNum_ldiff : ∀ m n : Num, (ldiff m n : ℕ) = Nat.ldiff m n := by apply castNum_eq_bitwise PosNum.ldiff <;> intros <;> (try cases_type* Bool) <;> rfl @[simp, norm_cast] theorem castNum_xor : ∀ m n : Num, ↑(m ^^^ n) = (↑m ^^^ ↑n : ℕ) := by apply castNum_eq_bitwise PosNum.lxor <;> intros <;> (try cases_type* Bool) <;> rfl @[simp, norm_cast] theorem castNum_shiftLeft (m : Num) (n : Nat) : ↑(m <<< n) = (m : ℕ) <<< (n : ℕ) := by cases m <;> dsimp only [← shiftl_eq_shiftLeft, shiftl] · symm apply Nat.zero_shiftLeft simp only [cast_pos] induction' n with n IH · rfl simp [PosNum.shiftl_succ_eq_bit0_shiftl, Nat.shiftLeft_succ, IH, pow_succ, ← mul_assoc, mul_comm, -shiftl_eq_shiftLeft, -PosNum.shiftl_eq_shiftLeft, shiftl, mul_two] @[simp, norm_cast] theorem castNum_shiftRight (m : Num) (n : Nat) : ↑(m >>> n) = (m : ℕ) >>> (n : ℕ) := by obtain - \| m := m <;> dsimp only [← shiftr_eq_shiftRight, shiftr] · symm apply Nat.zero_shiftRight induction' n with n IH generalizing m · cases m <;> rfl have hdiv2 : ∀ m, Nat.div2 (m + m) = m := by intro; rw [Nat.div2_val]; omega obtain - \| m \| m := m <;> dsimp only [PosNum.shiftr, ← PosNum.shiftr_eq_shiftRight] · rw [Nat.shiftRight_eq_div_pow] symm apply Nat.div_eq_of_lt simp · trans · apply IH change Nat.shiftRight m n = Nat.shiftRight (m + m + 1) (n + 1) rw [add_comm n 1, @Nat.shiftRight_eq _ (1 + n), Nat.shiftRight_add] apply congr_arg fun x => Nat.shiftRight x n simp [-add_assoc, Nat.shiftRight_succ, Nat.shiftRight_zero, ← Nat.div2_val, hdiv2] · trans · apply IH change Nat.shiftRight m n = Nat.shiftRight (m + m) (n + 1) rw [add_comm n 1, @Nat.shiftRight_eq _ (1 + n), Nat.shiftRight_add] apply congr_arg fun x => Nat.shiftRight x n simp [-add_assoc, Nat.shiftRight_succ, Nat.shiftRight_zero, ← Nat.div2_val, hdiv2] @[simp] theorem castNum_testBit (m n) : testBit m n = Nat.testBit m n := by cases m with dsimp only [testBit] \| zero => rw [show (Num.zero : Nat) = 0 from rfl, Nat.zero_testBit] \| pos m => rw [cast_pos] induction' n with n IH generalizing m <;> obtain - \| m \| m := m <;> simp only [PosNum.testBit] · rfl · rw [PosNum.cast_bit1, ← two_mul, ← congr_fun Nat.bit_true, Nat.testBit_bit_zero] · rw [PosNum.cast_bit0, ← two_mul, ← congr_fun Nat.bit_false, Nat.testBit_bit_zero] · simp [Nat.testBit_add_one] · rw [PosNum.cast_bit1, ← two_mul, ← congr_fun Nat.bit_true, Nat.testBit_bit_succ, IH] · rw [PosNum.cast_bit0, ← two_mul, ← congr_fun Nat.bit_false, Nat.testBit_bit_succ, IH] end Num namespace Int /-- Cast a `SNum` to the corresponding integer. -/ def ofSnum : SNum → ℤ := SNum.rec' (fun a => cond a (-1) 0) fun a _p IH => cond a (2 * IH + 1) (2 * IH) instance snumCoe : Coe SNum ℤ := ⟨ofSnum⟩ end Int instance SNum.lt : LT SNum := ⟨fun a b => (a : ℤ) < b⟩ instance SNum.le : LE SNum := ⟨fun a b => (a : ℤ) ≤ b⟩		Mathlib/Data/Num/Lemmas.lean	1,587	1,610
/- 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.Analysis.Analytic.IsolatedZeros import Mathlib.Analysis.SpecialFunctions.Complex.CircleMap import Mathlib.Analysis.SpecialFunctions.NonIntegrable /-! # Integral over a circle in `ℂ` In this file we define `∮ z in C(c, R), f z` to be the integral $\oint_{\|z-c\|=\|R\|} f(z)\,dz$ and prove some properties of this integral. We give definition and prove most lemmas for a function `f : ℂ → E`, where `E` is a complex Banach space. For this reason, some lemmas use, e.g., `(z - c)⁻¹ • f z` instead of `f z / (z - c)`. ## Main definitions * `CircleIntegrable f c R`: a function `f : ℂ → E` is integrable on the circle with center `c` and radius `R` if `f ∘ circleMap c R` is integrable on `[0, 2π]`; * `circleIntegral f c R`: the integral $\oint_{\|z-c\|=\|R\|} f(z)\,dz$, defined as $\int_{0}^{2π}(c + Re^{θ i})' f(c+Re^{θ i})\,dθ$; * `cauchyPowerSeries f c R`: the power series that is equal to $\sum_{n=0}^{\infty} \oint_{\|z-c\|=R} \left(\frac{w-c}{z - c}\right)^n \frac{1}{z-c}f(z)\,dz$ at `w - c`. The coefficients of this power series depend only on `f ∘ circleMap c R`, and the power series converges to `f w` if `f` is differentiable on the closed ball `Metric.closedBall c R` and `w` belongs to the corresponding open ball. ## Main statements * `hasFPowerSeriesOn_cauchy_integral`: for any circle integrable function `f`, the power series `cauchyPowerSeries f c R`, `R > 0`, converges to the Cauchy integral `(2 * π * I : ℂ)⁻¹ • ∮ z in C(c, R), (z - w)⁻¹ • f z` on the open disc `Metric.ball c R`; * `circleIntegral.integral_sub_zpow_of_undef`, `circleIntegral.integral_sub_zpow_of_ne`, and `circleIntegral.integral_sub_inv_of_mem_ball`: formulas for `∮ z in C(c, R), (z - w) ^ n`, `n : ℤ`. These lemmas cover the following cases: - `circleIntegral.integral_sub_zpow_of_undef`, `n < 0` and `\|w - c\| = \|R\|`: in this case the function is not integrable, so the integral is equal to its default value (zero); - `circleIntegral.integral_sub_zpow_of_ne`, `n ≠ -1`: in the cases not covered by the previous lemma, we have `(z - w) ^ n = ((z - w) ^ (n + 1) / (n + 1))'`, thus the integral equals zero; - `circleIntegral.integral_sub_inv_of_mem_ball`, `n = -1`, `\|w - c\| < R`: in this case the integral is equal to `2πi`. The case `n = -1`, `\|w -c\| > R` is not covered by these lemmas. While it is possible to construct an explicit primitive, it is easier to apply Cauchy theorem, so we postpone the proof till we have this theorem (see https://github.com/leanprover-community/mathlib4/pull/10000). ## Notation - `∮ z in C(c, R), f z`: notation for the integral $\oint_{\|z-c\|=\|R\|} f(z)\,dz$, defined as $\int_{0}^{2π}(c + Re^{θ i})' f(c+Re^{θ i})\,dθ$. ## Tags integral, circle, Cauchy integral -/ variable {E : Type} [NormedAddCommGroup E] noncomputable section open scoped Real NNReal Interval Pointwise Topology open Complex MeasureTheory TopologicalSpace Metric Function Set Filter Asymptotics /-! ### Facts about `circleMap` -/ /-- The range of `circleMap c R` is the circle with center `c` and radius `\|R\|`. -/ @[simp] theorem range_circleMap (c : ℂ) (R : ℝ) : range (circleMap c R) = sphere c \|R\| := calc range (circleMap c R) = c +ᵥ R • range fun θ : ℝ => exp (θ I) := by simp +unfoldPartialApp only [← image_vadd, ← image_smul, ← range_comp, vadd_eq_add, circleMap, comp_def, real_smul] _ = sphere c \|R\| := by rw [range_exp_mul_I, smul_sphere R 0 zero_le_one] simp /-- The image of `(0, 2π]` under `circleMap c R` is the circle with center `c` and radius `\|R\|`. -/ @[simp] theorem image_circleMap_Ioc (c : ℂ) (R : ℝ) : circleMap c R '' Ioc 0 (2 * π) = sphere c \|R\| := by rw [← range_circleMap, ← (periodic_circleMap c R).image_Ioc Real.two_pi_pos 0, zero_add] theorem hasDerivAt_circleMap (c : ℂ) (R : ℝ) (θ : ℝ) : HasDerivAt (circleMap c R) (circleMap 0 R θ * I) θ := by simpa only [mul_assoc, one_mul, ofRealCLM_apply, circleMap, ofReal_one, zero_add] using (((ofRealCLM.hasDerivAt (x := θ)).mul_const I).cexp.const_mul (R : ℂ)).const_add c theorem differentiable_circleMap (c : ℂ) (R : ℝ) : Differentiable ℝ (circleMap c R) := fun θ => (hasDerivAt_circleMap c R θ).differentiableAt /-- The circleMap is real analytic. -/ theorem analyticOnNhd_circleMap (c : ℂ) (R : ℝ) : AnalyticOnNhd ℝ (circleMap c R) Set.univ := by intro z hz apply analyticAt_const.add apply analyticAt_const.mul rw [← Function.comp_def] apply analyticAt_cexp.restrictScalars.comp ((ofRealCLM.analyticAt z).mul (by fun_prop)) /-- The circleMap is continuously differentiable. -/ theorem contDiff_circleMap (c : ℂ) (R : ℝ) {n : WithTop ℕ∞} : ContDiff ℝ n (circleMap c R) := (analyticOnNhd_circleMap c R).contDiff @[continuity, fun_prop] theorem continuous_circleMap (c : ℂ) (R : ℝ) : Continuous (circleMap c R) := (differentiable_circleMap c R).continuous @[fun_prop, measurability] theorem measurable_circleMap (c : ℂ) (R : ℝ) : Measurable (circleMap c R) := (continuous_circleMap c R).measurable @[simp] theorem deriv_circleMap (c : ℂ) (R : ℝ) (θ : ℝ) : deriv (circleMap c R) θ = circleMap 0 R θ * I := (hasDerivAt_circleMap _ _ _).deriv theorem deriv_circleMap_eq_zero_iff {c : ℂ} {R : ℝ} {θ : ℝ} : deriv (circleMap c R) θ = 0 ↔ R = 0 := by simp [I_ne_zero] theorem deriv_circleMap_ne_zero {c : ℂ} {R : ℝ} {θ : ℝ} (hR : R ≠ 0) : deriv (circleMap c R) θ ≠ 0 := mt deriv_circleMap_eq_zero_iff.1 hR theorem lipschitzWith_circleMap (c : ℂ) (R : ℝ) : LipschitzWith (Real.nnabs R) (circleMap c R) := lipschitzWith_of_nnnorm_deriv_le (differentiable_circleMap _ _) fun θ => NNReal.coe_le_coe.1 <\| by simp theorem continuous_circleMap_inv {R : ℝ} {z w : ℂ} (hw : w ∈ ball z R) : Continuous fun θ => (circleMap z R θ - w)⁻¹ := by have : ∀ θ, circleMap z R θ - w ≠ 0 := by simp_rw [sub_ne_zero] exact fun θ => circleMap_ne_mem_ball hw θ -- Porting note: was `continuity` exact Continuous.inv₀ (by fun_prop) this theorem circleMap_preimage_codiscrete {c : ℂ} {R : ℝ} (hR : R ≠ 0) : map (circleMap c R) (codiscrete ℝ) ≤ codiscreteWithin (Metric.sphere c \|R\|) := by intro s hs apply (analyticOnNhd_circleMap c R).preimage_mem_codiscreteWithin · intro x hx by_contra hCon obtain ⟨a, ha⟩ := eventuallyConst_iff_exists_eventuallyEq.1 hCon have := ha.deriv.eq_of_nhds simp [hR] at this · rwa [Set.image_univ, range_circleMap] /-! ### Integrability of a function on a circle -/ /-- We say that a function `f : ℂ → E` is integrable on the circle with center `c` and radius `R` if the function `f ∘ circleMap c R` is integrable on `[0, 2π]`. Note that the actual function used in the definition of `circleIntegral` is `(deriv (circleMap c R) θ) • f (circleMap c R θ)`. Integrability of this function is equivalent to integrability of `f ∘ circleMap c R` whenever `R ≠ 0`. -/ def CircleIntegrable (f : ℂ → E) (c : ℂ) (R : ℝ) : Prop := IntervalIntegrable (fun θ : ℝ => f (circleMap c R θ)) volume 0 (2 * π) @[simp] theorem circleIntegrable_const (a : E) (c : ℂ) (R : ℝ) : CircleIntegrable (fun _ => a) c R := intervalIntegrable_const namespace CircleIntegrable variable {f g : ℂ → E} {c : ℂ} {R : ℝ} nonrec theorem add (hf : CircleIntegrable f c R) (hg : CircleIntegrable g c R) : CircleIntegrable (f + g) c R := hf.add hg nonrec theorem neg (hf : CircleIntegrable f c R) : CircleIntegrable (-f) c R := hf.neg /-- The function we actually integrate over `[0, 2π]` in the definition of `circleIntegral` is integrable. -/ theorem out [NormedSpace ℂ E] (hf : CircleIntegrable f c R) : IntervalIntegrable (fun θ : ℝ => deriv (circleMap c R) θ • f (circleMap c R θ)) volume 0 (2 * π) := by simp only [CircleIntegrable, deriv_circleMap, intervalIntegrable_iff] at * refine (hf.norm.const_mul \|R\|).mono' ?_ ?_ · exact ((continuous_circleMap _ _).aestronglyMeasurable.mul_const I).smul hf.aestronglyMeasurable · simp [norm_smul] end CircleIntegrable @[simp] theorem circleIntegrable_zero_radius {f : ℂ → E} {c : ℂ} : CircleIntegrable f c 0 := by simp [CircleIntegrable] /-- Circle integrability is invariant when functions change along discrete sets. -/ theorem CircleIntegrable.congr_codiscreteWithin {c : ℂ} {R : ℝ} {f₁ f₂ : ℂ → ℂ} (hf : f₁ =ᶠ[codiscreteWithin (Metric.sphere c \|R\|)] f₂) (hf₁ : CircleIntegrable f₁ c R) : CircleIntegrable f₂ c R := by by_cases hR : R = 0 · simp [hR] apply (intervalIntegrable_congr_codiscreteWithin _).1 hf₁ rw [eventuallyEq_iff_exists_mem] exact ⟨(circleMap c R)⁻¹' {z \| f₁ z = f₂ z}, codiscreteWithin.mono (by simp only [Set.subset_univ]) (circleMap_preimage_codiscrete hR hf), by tauto⟩ /-- Circle integrability is invariant when functions change along discrete sets. -/ theorem circleIntegrable_congr_codiscreteWithin {c : ℂ} {R : ℝ} {f₁ f₂ : ℂ → ℂ} (hf : f₁ =ᶠ[codiscreteWithin (Metric.sphere c \|R\|)] f₂) : CircleIntegrable f₁ c R ↔ CircleIntegrable f₂ c R := ⟨(CircleIntegrable.congr_codiscreteWithin hf ·), (CircleIntegrable.congr_codiscreteWithin hf.symm ·)⟩ theorem circleIntegrable_iff [NormedSpace ℂ E] {f : ℂ → E} {c : ℂ} (R : ℝ) : CircleIntegrable f c R ↔ IntervalIntegrable (fun θ : ℝ => deriv (circleMap c R) θ • f (circleMap c R θ)) volume 0 (2 * π) := by by_cases h₀ : R = 0 · simp +unfoldPartialApp [h₀, const] refine ⟨fun h => h.out, fun h => ?_⟩ simp only [CircleIntegrable, intervalIntegrable_iff, deriv_circleMap] at h ⊢ refine (h.norm.const_mul \|R\|⁻¹).mono' ?_ ?_ · have H : ∀ {θ}, circleMap 0 R θ * I ≠ 0 := fun {θ} => by simp [h₀, I_ne_zero] simpa only [inv_smul_smul₀ H] using ((continuous_circleMap 0 R).aestronglyMeasurable.mul_const I).aemeasurable.inv.aestronglyMeasurable.smul h.aestronglyMeasurable · simp [norm_smul, h₀] theorem ContinuousOn.circleIntegrable' {f : ℂ → E} {c : ℂ} {R : ℝ} (hf : ContinuousOn f (sphere c \|R\|)) : CircleIntegrable f c R := (hf.comp_continuous (continuous_circleMap _ _) (circleMap_mem_sphere' _ _)).intervalIntegrable _ _ theorem ContinuousOn.circleIntegrable {f : ℂ → E} {c : ℂ} {R : ℝ} (hR : 0 ≤ R) (hf : ContinuousOn f (sphere c R)) : CircleIntegrable f c R := ContinuousOn.circleIntegrable' <\| (abs_of_nonneg hR).symm ▸ hf /-- The function `fun z ↦ (z - w) ^ n`, `n : ℤ`, is circle integrable on the circle with center `c` and radius `\|R\|` if and only if `R = 0` or `0 ≤ n`, or `w` does not belong to this circle. -/ @[simp] theorem circleIntegrable_sub_zpow_iff {c w : ℂ} {R : ℝ} {n : ℤ} : CircleIntegrable (fun z => (z - w) ^ n) c R ↔ R = 0 ∨ 0 ≤ n ∨ w ∉ sphere c \|R\| := by constructor · intro h; contrapose! h; rcases h with ⟨hR, hn, hw⟩ simp only [circleIntegrable_iff R, deriv_circleMap] rw [← image_circleMap_Ioc] at hw; rcases hw with ⟨θ, hθ, rfl⟩ replace hθ : θ ∈ [[0, 2 * π]] := Icc_subset_uIcc (Ioc_subset_Icc_self hθ) refine not_intervalIntegrable_of_sub_inv_isBigO_punctured ?_ Real.two_pi_pos.ne hθ set f : ℝ → ℂ := fun θ' => circleMap c R θ' - circleMap c R θ have : ∀ᶠ θ' in 𝓝[≠] θ, f θ' ∈ ball (0 : ℂ) 1 \ {0} := by suffices ∀ᶠ z in 𝓝[≠] circleMap c R θ, z - circleMap c R θ ∈ ball (0 : ℂ) 1 \ {0} from ((differentiable_circleMap c R θ).hasDerivAt.tendsto_nhdsNE (deriv_circleMap_ne_zero hR)).eventually this filter_upwards [self_mem_nhdsWithin, mem_nhdsWithin_of_mem_nhds (ball_mem_nhds _ zero_lt_one)] simp_all [dist_eq, sub_eq_zero] refine (((hasDerivAt_circleMap c R θ).isBigO_sub.mono inf_le_left).inv_rev (this.mono fun θ' h₁ h₂ => absurd h₂ h₁.2)).trans ?_ refine IsBigO.of_bound \|R\|⁻¹ (this.mono fun θ' hθ' => ?_) set x := ‖f θ'‖ suffices x⁻¹ ≤ x ^ n by simp only [inv_mul_cancel_left₀, abs_eq_zero.not.2 hR, Algebra.id.smul_eq_mul, norm_mul, norm_inv, norm_I, mul_one] simpa only [norm_circleMap_zero, norm_zpow, Ne, abs_eq_zero.not.2 hR, not_false_iff, inv_mul_cancel_left₀] using this have : x ∈ Ioo (0 : ℝ) 1 := by simpa [x, and_comm] using hθ' rw [← zpow_neg_one] refine (zpow_right_strictAnti₀ this.1 this.2).le_iff_le.2 (Int.lt_add_one_iff.1 ?_); exact hn · rintro (rfl \| H) exacts [circleIntegrable_zero_radius, ((continuousOn_id.sub continuousOn_const).zpow₀ _ fun z hz => H.symm.imp_left fun (hw : w ∉ sphere c \|R\|) => sub_ne_zero.2 <\| ne_of_mem_of_not_mem hz hw).circleIntegrable'] @[simp] theorem circleIntegrable_sub_inv_iff {c w : ℂ} {R : ℝ} : CircleIntegrable (fun z => (z - w)⁻¹) c R ↔ R = 0 ∨ w ∉ sphere c \|R\| := by simp only [← zpow_neg_one, circleIntegrable_sub_zpow_iff]; norm_num variable [NormedSpace ℂ E] /-- Definition for $\oint_{\|z-c\|=R} f(z)\,dz$ -/ def circleIntegral (f : ℂ → E) (c : ℂ) (R : ℝ) : E := ∫ θ : ℝ in (0)..2 * π, deriv (circleMap c R) θ • f (circleMap c R θ) /-- `∮ z in C(c, R), f z` is the circle integral $\oint_{\|z-c\|=R} f(z)\,dz$. -/ notation3 "∮ "(...)" in ""C("c", "R")"", "r:(scoped f => circleIntegral f c R) => r theorem circleIntegral_def_Icc (f : ℂ → E) (c : ℂ) (R : ℝ) : (∮ z in C(c, R), f z) = ∫ θ in Icc 0 (2 * π), deriv (circleMap c R) θ • f (circleMap c R θ) := by rw [circleIntegral, intervalIntegral.integral_of_le Real.two_pi_pos.le, Measure.restrict_congr_set Ioc_ae_eq_Icc] namespace circleIntegral @[simp] theorem integral_radius_zero (f : ℂ → E) (c : ℂ) : (∮ z in C(c, 0), f z) = 0 := by simp +unfoldPartialApp [circleIntegral, const] theorem integral_congr {f g : ℂ → E} {c : ℂ} {R : ℝ} (hR : 0 ≤ R) (h : EqOn f g (sphere c R)) : (∮ z in C(c, R), f z) = ∮ z in C(c, R), g z := intervalIntegral.integral_congr fun θ _ => by simp only [h (circleMap_mem_sphere _ hR _)] /-- Circle integrals are invariant when functions change along discrete sets. -/ theorem circleIntegral_congr_codiscreteWithin {c : ℂ} {R : ℝ} {f₁ f₂ : ℂ → ℂ} (hf : f₁ =ᶠ[codiscreteWithin (Metric.sphere c \|R\|)] f₂) (hR : R ≠ 0) : (∮ z in C(c, R), f₁ z) = (∮ z in C(c, R), f₂ z) := by apply intervalIntegral.integral_congr_ae_restrict apply ae_restrict_le_codiscreteWithin measurableSet_uIoc simp only [deriv_circleMap, smul_eq_mul, mul_eq_mul_left_iff, mul_eq_zero, circleMap_eq_center_iff, hR, Complex.I_ne_zero, or_self, or_false] exact codiscreteWithin.mono (by tauto) (circleMap_preimage_codiscrete hR hf) theorem integral_sub_inv_smul_sub_smul (f : ℂ → E) (c w : ℂ) (R : ℝ) : (∮ z in C(c, R), (z - w)⁻¹ • (z - w) • f z) = ∮ z in C(c, R), f z := by rcases eq_or_ne R 0 with (rfl \| hR); · simp only [integral_radius_zero] have : (circleMap c R ⁻¹' {w}).Countable := (countable_singleton _).preimage_circleMap c hR refine intervalIntegral.integral_congr_ae ((this.ae_not_mem _).mono fun θ hθ _' => ?_) change circleMap c R θ ≠ w at hθ simp only [inv_smul_smul₀ (sub_ne_zero.2 <\| hθ)] theorem integral_undef {f : ℂ → E} {c : ℂ} {R : ℝ} (hf : ¬CircleIntegrable f c R) : (∮ z in C(c, R), f z) = 0 := intervalIntegral.integral_undef (mt (circleIntegrable_iff R).mpr hf) theorem integral_add {f g : ℂ → E} {c : ℂ} {R : ℝ} (hf : CircleIntegrable f c R) (hg : CircleIntegrable g c R) : (∮ z in C(c, R), f z + g z) = (∮ z in C(c, R), f z) + (∮ z in C(c, R), g z) := by simp only [circleIntegral, smul_add, intervalIntegral.integral_add hf.out hg.out] theorem integral_sub {f g : ℂ → E} {c : ℂ} {R : ℝ} (hf : CircleIntegrable f c R) (hg : CircleIntegrable g c R) : (∮ z in C(c, R), f z - g z) = (∮ z in C(c, R), f z) - ∮ z in C(c, R), g z := by simp only [circleIntegral, smul_sub, intervalIntegral.integral_sub hf.out hg.out] theorem norm_integral_le_of_norm_le_const' {f : ℂ → E} {c : ℂ} {R C : ℝ} (hf : ∀ z ∈ sphere c \|R\|, ‖f z‖ ≤ C) : ‖∮ z in C(c, R), f z‖ ≤ 2 * π * \|R\| * C := calc ‖∮ z in C(c, R), f z‖ ≤ \|R\| * C * \|2 * π - 0\| := intervalIntegral.norm_integral_le_of_norm_le_const fun θ _ => calc ‖deriv (circleMap c R) θ • f (circleMap c R θ)‖ = \|R\| * ‖f (circleMap c R θ)‖ := by simp [norm_smul] _ ≤ \|R\| * C := mul_le_mul_of_nonneg_left (hf _ <\| circleMap_mem_sphere' _ _ _) (abs_nonneg _) _ = 2 * π * \|R\| * C := by rw [sub_zero, _root_.abs_of_pos Real.two_pi_pos]; ac_rfl theorem norm_integral_le_of_norm_le_const {f : ℂ → E} {c : ℂ} {R C : ℝ} (hR : 0 ≤ R) (hf : ∀ z ∈ sphere c R, ‖f z‖ ≤ C) : ‖∮ z in C(c, R), f z‖ ≤ 2 * π * R * C := have : \|R\| = R := abs_of_nonneg hR calc ‖∮ z in C(c, R), f z‖ ≤ 2 * π * \|R\| * C := norm_integral_le_of_norm_le_const' <\| by rwa [this] _ = 2 * π * R * C := by rw [this] theorem norm_two_pi_i_inv_smul_integral_le_of_norm_le_const {f : ℂ → E} {c : ℂ} {R C : ℝ} (hR : 0 ≤ R) (hf : ∀ z ∈ sphere c R, ‖f z‖ ≤ C) : ‖(2 * π * I : ℂ)⁻¹ • ∮ z in C(c, R), f z‖ ≤ R * C := by have : ‖(2 * π * I : ℂ)⁻¹‖ = (2 * π)⁻¹ := by simp [Real.pi_pos.le] rw [norm_smul, this, ← div_eq_inv_mul, div_le_iff₀ Real.two_pi_pos, mul_comm (R * C), ← mul_assoc] exact norm_integral_le_of_norm_le_const hR hf /-- If `f` is continuous on the circle `\|z - c\| = R`, `R > 0`, the `‖f z‖` is less than or equal to `C : ℝ` on this circle, and this norm is strictly less than `C` at some point `z` of the circle, then `‖∮ z in C(c, R), f z‖ < 2 * π * R * C`. -/ theorem norm_integral_lt_of_norm_le_const_of_lt {f : ℂ → E} {c : ℂ} {R C : ℝ} (hR : 0 < R) (hc : ContinuousOn f (sphere c R)) (hf : ∀ z ∈ sphere c R, ‖f z‖ ≤ C) (hlt : ∃ z ∈ sphere c R, ‖f z‖ < C) : ‖∮ z in C(c, R), f z‖ < 2 * π * R * C := by rw [← _root_.abs_of_pos hR, ← image_circleMap_Ioc] at hlt rcases hlt with ⟨_, ⟨θ₀, hmem, rfl⟩, hlt⟩ calc ‖∮ z in C(c, R), f z‖ ≤ ∫ θ in (0)..2 * π, ‖deriv (circleMap c R) θ • f (circleMap c R θ)‖ := intervalIntegral.norm_integral_le_integral_norm Real.two_pi_pos.le _ < ∫ _ in (0)..2 * π, R * C := by simp only [deriv_circleMap, norm_smul, norm_mul, norm_circleMap_zero, abs_of_pos hR, norm_I, mul_one] refine intervalIntegral.integral_lt_integral_of_continuousOn_of_le_of_exists_lt Real.two_pi_pos ?_ continuousOn_const (fun θ _ => ?_) ⟨θ₀, Ioc_subset_Icc_self hmem, ?_⟩ · exact continuousOn_const.mul (hc.comp (continuous_circleMap _ _).continuousOn fun θ _ => circleMap_mem_sphere _ hR.le _).norm · exact mul_le_mul_of_nonneg_left (hf _ <\| circleMap_mem_sphere _ hR.le _) hR.le · exact (mul_lt_mul_left hR).2 hlt _ = 2 * π * R * C := by simp [mul_assoc]; ring @[simp] theorem integral_smul {𝕜 : Type} [RCLike 𝕜] [NormedSpace 𝕜 E] [SMulCommClass 𝕜 ℂ E] (a : 𝕜) (f : ℂ → E) (c : ℂ) (R : ℝ) : (∮ z in C(c, R), a • f z) = a • ∮ z in C(c, R), f z := by simp only [circleIntegral, ← smul_comm a (_ : ℂ) (_ : E), intervalIntegral.integral_smul] @[simp] theorem integral_smul_const [CompleteSpace E] (f : ℂ → ℂ) (a : E) (c : ℂ) (R : ℝ) : (∮ z in C(c, R), f z • a) = (∮ z in C(c, R), f z) • a := by simp only [circleIntegral, intervalIntegral.integral_smul_const, ← smul_assoc] @[simp] theorem integral_const_mul (a : ℂ) (f : ℂ → ℂ) (c : ℂ) (R : ℝ) : (∮ z in C(c, R), a f z) = a * ∮ z in C(c, R), f z := integral_smul a f c R @[simp] theorem integral_sub_center_inv (c : ℂ) {R : ℝ} (hR : R ≠ 0) : (∮ z in C(c, R), (z - c)⁻¹) = 2 * π * I := by simp [circleIntegral, ← div_eq_mul_inv, mul_div_cancel_left₀ _ (circleMap_ne_center hR)] /-- If `f' : ℂ → E` is a derivative of a complex differentiable function on the circle `Metric.sphere c \|R\|`, then `∮ z in C(c, R), f' z = 0`. -/ theorem integral_eq_zero_of_hasDerivWithinAt' [CompleteSpace E] {f f' : ℂ → E} {c : ℂ} {R : ℝ} (h : ∀ z ∈ sphere c \|R\|, HasDerivWithinAt f (f' z) (sphere c \|R\|) z) : (∮ z in C(c, R), f' z) = 0 := by by_cases hi : CircleIntegrable f' c R · rw [← sub_eq_zero.2 ((periodic_circleMap c R).comp f).eq] refine intervalIntegral.integral_eq_sub_of_hasDerivAt (fun θ _ => ?_) hi.out exact (h _ (circleMap_mem_sphere' _ _ _)).scomp_hasDerivAt θ (differentiable_circleMap _ _ _).hasDerivAt (circleMap_mem_sphere' _ _) · exact integral_undef hi /-- If `f' : ℂ → E` is a derivative of a complex differentiable function on the circle `Metric.sphere c R`, then `∮ z in C(c, R), f' z = 0`. -/ theorem integral_eq_zero_of_hasDerivWithinAt [CompleteSpace E] {f f' : ℂ → E} {c : ℂ} {R : ℝ} (hR : 0 ≤ R) (h : ∀ z ∈ sphere c R, HasDerivWithinAt f (f' z) (sphere c R) z) : (∮ z in C(c, R), f' z) = 0 := integral_eq_zero_of_hasDerivWithinAt' <\| (abs_of_nonneg hR).symm ▸ h /-- If `n < 0` and `\|w - c\| = \|R\|`, then `(z - w) ^ n` is not circle integrable on the circle with center `c` and radius `\|R\|`, so the integral `∮ z in C(c, R), (z - w) ^ n` is equal to zero. -/ theorem integral_sub_zpow_of_undef {n : ℤ} {c w : ℂ} {R : ℝ} (hn : n < 0) (hw : w ∈ sphere c \|R\|) : (∮ z in C(c, R), (z - w) ^ n) = 0 := by rcases eq_or_ne R 0 with (rfl \| h0) · apply integral_radius_zero · apply integral_undef simpa [circleIntegrable_sub_zpow_iff, , not_or] /-- If `n ≠ -1` is an integer number, then the integral of `(z - w) ^ n` over the circle equals zero. -/ theorem integral_sub_zpow_of_ne {n : ℤ} (hn : n ≠ -1) (c w : ℂ) (R : ℝ) : (∮ z in C(c, R), (z - w) ^ n) = 0 := by rcases em (w ∈ sphere c \|R\| ∧ n < -1) with (⟨hw, hn⟩ \| H) · exact integral_sub_zpow_of_undef (hn.trans (by decide)) hw push_neg at H have hd : ∀ z, z ≠ w ∨ -1 ≤ n → HasDerivAt (fun z => (z - w) ^ (n + 1) / (n + 1)) ((z - w) ^ n) z := by intro z hne convert ((hasDerivAt_zpow (n + 1) _ (hne.imp _ _)).comp z ((hasDerivAt_id z).sub_const w)).div_const _ using 1 · have hn' : (n + 1 : ℂ) ≠ 0 := by rwa [Ne, ← eq_neg_iff_add_eq_zero, ← Int.cast_one, ← Int.cast_neg, Int.cast_inj] simp [mul_assoc, mul_div_cancel_left₀ _ hn'] exacts [sub_ne_zero.2, neg_le_iff_add_nonneg.1] refine integral_eq_zero_of_hasDerivWithinAt' fun z hz => (hd z ?_).hasDerivWithinAt exact (ne_or_eq z w).imp_right fun (h : z = w) => H <\| h ▸ hz end circleIntegral /-- The power series that is equal to $\frac{1}{2πi}\sum_{n=0}^{\infty} \oint_{\|z-c\|=R} \left(\frac{w-c}{z - c}\right)^n \frac{1}{z-c}f(z)\,dz$ at `w - c`. The coefficients of this power series depend only on `f ∘ circleMap c R`, and the power series converges to `f w` if `f` is differentiable on the closed ball `Metric.closedBall c R` and `w` belongs to the corresponding open ball. For any circle integrable function `f`, this power series converges to the Cauchy integral for `f`. -/ def cauchyPowerSeries (f : ℂ → E) (c : ℂ) (R : ℝ) : FormalMultilinearSeries ℂ ℂ E := fun n => ContinuousMultilinearMap.mkPiRing ℂ _ <\| (2 π * I : ℂ)⁻¹ • ∮ z in C(c, R), (z - c)⁻¹ ^ n • (z - c)⁻¹ • f z theorem cauchyPowerSeries_apply (f : ℂ → E) (c : ℂ) (R : ℝ) (n : ℕ) (w : ℂ) : (cauchyPowerSeries f c R n fun _ => w) = (2 * π * I : ℂ)⁻¹ • ∮ z in C(c, R), (w / (z - c)) ^ n • (z - c)⁻¹ • f z := by simp only [cauchyPowerSeries, ContinuousMultilinearMap.mkPiRing_apply, Fin.prod_const, div_eq_mul_inv, mul_pow, mul_smul, circleIntegral.integral_smul] rw [← smul_comm (w ^ n)] theorem norm_cauchyPowerSeries_le (f : ℂ → E) (c : ℂ) (R : ℝ) (n : ℕ) : ‖cauchyPowerSeries f c R n‖ ≤ ((2 * π)⁻¹ * ∫ θ : ℝ in (0)..2 * π, ‖f (circleMap c R θ)‖) * \|R\|⁻¹ ^ n := calc ‖cauchyPowerSeries f c R n‖ _ = (2 * π)⁻¹ * ‖∮ z in C(c, R), (z - c)⁻¹ ^ n • (z - c)⁻¹ • f z‖ := by simp [cauchyPowerSeries, norm_smul, Real.pi_pos.le] _ ≤ (2 * π)⁻¹ * ∫ θ in (0)..2 * π, ‖deriv (circleMap c R) θ • (circleMap c R θ - c)⁻¹ ^ n • (circleMap c R θ - c)⁻¹ • f (circleMap c R θ)‖ := (mul_le_mul_of_nonneg_left (intervalIntegral.norm_integral_le_integral_norm Real.two_pi_pos.le) (by simp [Real.pi_pos.le])) _ = (2 * π)⁻¹ * (\|R\|⁻¹ ^ n * (\|R\| * (\|R\|⁻¹ * ∫ x : ℝ in (0)..2 * π, ‖f (circleMap c R x)‖))) := by simp [norm_smul, mul_left_comm \|R\|] _ ≤ ((2 * π)⁻¹ * ∫ θ : ℝ in (0)..2 * π, ‖f (circleMap c R θ)‖) * \|R\|⁻¹ ^ n := by rcases eq_or_ne R 0 with (rfl \| hR)	· cases n <;> simp [-mul_inv_rev] rw [← mul_assoc, inv_mul_cancel₀ (Real.two_pi_pos.ne.symm), one_mul] apply norm_nonneg · rw [mul_inv_cancel_left₀, mul_assoc, mul_comm (\|R\|⁻¹ ^ n)] rwa [Ne, _root_.abs_eq_zero]	Mathlib/MeasureTheory/Integral/CircleIntegral.lean	491	496
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Bryan Gin-ge Chen -/ import Mathlib.Order.Heyting.Basic /-! # (Generalized) Boolean algebras A Boolean algebra is a bounded distributive lattice with a complement operator. Boolean algebras generalize the (classical) logic of propositions and the lattice of subsets of a set. Generalized Boolean algebras may be less familiar, but they are essentially Boolean algebras which do not necessarily have a top element (`⊤`) (and hence not all elements may have complements). One example in mathlib is `Finset α`, the type of all finite subsets of an arbitrary (not-necessarily-finite) type `α`. `GeneralizedBooleanAlgebra α` is defined to be a distributive lattice with bottom (`⊥`) admitting a relative complement operator, written using "set difference" notation as `x \ y` (`sdiff x y`). For convenience, the `BooleanAlgebra` type class is defined to extend `GeneralizedBooleanAlgebra` so that it is also bundled with a `\` operator. (A terminological point: `x \ y` is the complement of `y` relative to the interval `[⊥, x]`. We do not yet have relative complements for arbitrary intervals, as we do not even have lattice intervals.) ## Main declarations * `GeneralizedBooleanAlgebra`: a type class for generalized Boolean algebras * `BooleanAlgebra`: a type class for Boolean algebras. * `Prop.booleanAlgebra`: the Boolean algebra instance on `Prop` ## Implementation notes The `sup_inf_sdiff` and `inf_inf_sdiff` axioms for the relative complement operator in `GeneralizedBooleanAlgebra` are taken from [Wikipedia](https://en.wikipedia.org/wiki/Boolean_algebra_(structure)#Generalizations). [Stone's paper introducing generalized Boolean algebras][Stone1935] does not define a relative complement operator `a \ b` for all `a`, `b`. Instead, the postulates there amount to an assumption that for all `a, b : α` where `a ≤ b`, the equations `x ⊔ a = b` and `x ⊓ a = ⊥` have a solution `x`. `Disjoint.sdiff_unique` proves that this `x` is in fact `b \ a`. ## References * <https://en.wikipedia.org/wiki/Boolean_algebra_(structure)#Generalizations> * [Postulates for Boolean Algebras and Generalized Boolean Algebras, M.H. Stone][Stone1935] * [Lattice Theory: Foundation, George Grätzer][Gratzer2011] ## Tags generalized Boolean algebras, Boolean algebras, lattices, sdiff, compl -/ assert_not_exists RelIso open Function OrderDual universe u v variable {α : Type u} {β : Type} {x y z : α} /-! ### Generalized Boolean algebras Some of the lemmas in this section are from: [Lattice Theory: Foundation, George Grätzer][Gratzer2011] * <https://ncatlab.org/nlab/show/relative+complement> * <https://people.math.gatech.edu/~mccuan/courses/4317/symmetricdifference.pdf> -/ /-- A generalized Boolean algebra is a distributive lattice with `⊥` and a relative complement operation `\` (called `sdiff`, after "set difference") satisfying `(a ⊓ b) ⊔ (a \ b) = a` and `(a ⊓ b) ⊓ (a \ b) = ⊥`, i.e. `a \ b` is the complement of `b` in `a`. This is a generalization of Boolean algebras which applies to `Finset α` for arbitrary (not-necessarily-`Fintype`) `α`. -/ class GeneralizedBooleanAlgebra (α : Type u) extends DistribLattice α, SDiff α, Bot α where /-- For any `a`, `b`, `(a ⊓ b) ⊔ (a / b) = a` -/ sup_inf_sdiff : ∀ a b : α, a ⊓ b ⊔ a \ b = a /-- For any `a`, `b`, `(a ⊓ b) ⊓ (a / b) = ⊥` -/ inf_inf_sdiff : ∀ a b : α, a ⊓ b ⊓ a \ b = ⊥ -- We might want an `IsCompl_of` predicate (for relative complements) generalizing `IsCompl`, -- however we'd need another type class for lattices with bot, and all the API for that. section GeneralizedBooleanAlgebra variable [GeneralizedBooleanAlgebra α] @[simp] theorem sup_inf_sdiff (x y : α) : x ⊓ y ⊔ x \ y = x := GeneralizedBooleanAlgebra.sup_inf_sdiff _ _ @[simp] theorem inf_inf_sdiff (x y : α) : x ⊓ y ⊓ x \ y = ⊥ := GeneralizedBooleanAlgebra.inf_inf_sdiff _ _ @[simp] theorem sup_sdiff_inf (x y : α) : x \ y ⊔ x ⊓ y = x := by rw [sup_comm, sup_inf_sdiff] @[simp] theorem inf_sdiff_inf (x y : α) : x \ y ⊓ (x ⊓ y) = ⊥ := by rw [inf_comm, inf_inf_sdiff] -- see Note [lower instance priority] instance (priority := 100) GeneralizedBooleanAlgebra.toOrderBot : OrderBot α where __ := GeneralizedBooleanAlgebra.toBot bot_le a := by rw [← inf_inf_sdiff a a, inf_assoc] exact inf_le_left theorem disjoint_inf_sdiff : Disjoint (x ⊓ y) (x \ y) := disjoint_iff_inf_le.mpr (inf_inf_sdiff x y).le -- TODO: in distributive lattices, relative complements are unique when they exist theorem sdiff_unique (s : x ⊓ y ⊔ z = x) (i : x ⊓ y ⊓ z = ⊥) : x \ y = z := by conv_rhs at s => rw [← sup_inf_sdiff x y, sup_comm] rw [sup_comm] at s conv_rhs at i => rw [← inf_inf_sdiff x y, inf_comm] rw [inf_comm] at i exact (eq_of_inf_eq_sup_eq i s).symm -- Use `sdiff_le` private theorem sdiff_le' : x \ y ≤ x := calc x \ y ≤ x ⊓ y ⊔ x \ y := le_sup_right _ = x := sup_inf_sdiff x y -- Use `sdiff_sup_self` private theorem sdiff_sup_self' : y \ x ⊔ x = y ⊔ x := calc y \ x ⊔ x = y \ x ⊔ (x ⊔ x ⊓ y) := by rw [sup_inf_self] _ = y ⊓ x ⊔ y \ x ⊔ x := by ac_rfl _ = y ⊔ x := by rw [sup_inf_sdiff] @[simp] theorem sdiff_inf_sdiff : x \ y ⊓ y \ x = ⊥ := Eq.symm <\| calc ⊥ = x ⊓ y ⊓ x \ y := by rw [inf_inf_sdiff] _ = x ⊓ (y ⊓ x ⊔ y \ x) ⊓ x \ y := by rw [sup_inf_sdiff] _ = (x ⊓ (y ⊓ x) ⊔ x ⊓ y \ x) ⊓ x \ y := by rw [inf_sup_left] _ = (y ⊓ (x ⊓ x) ⊔ x ⊓ y \ x) ⊓ x \ y := by ac_rfl _ = (y ⊓ x ⊔ x ⊓ y \ x) ⊓ x \ y := by rw [inf_idem] _ = x ⊓ y ⊓ x \ y ⊔ x ⊓ y \ x ⊓ x \ y := by rw [inf_sup_right, inf_comm x y] _ = x ⊓ y \ x ⊓ x \ y := by rw [inf_inf_sdiff, bot_sup_eq] _ = x ⊓ x \ y ⊓ y \ x := by ac_rfl _ = x \ y ⊓ y \ x := by rw [inf_of_le_right sdiff_le'] theorem disjoint_sdiff_sdiff : Disjoint (x \ y) (y \ x) := disjoint_iff_inf_le.mpr sdiff_inf_sdiff.le @[simp] theorem inf_sdiff_self_right : x ⊓ y \ x = ⊥ := calc x ⊓ y \ x = (x ⊓ y ⊔ x \ y) ⊓ y \ x := by rw [sup_inf_sdiff] _ = x ⊓ y ⊓ y \ x ⊔ x \ y ⊓ y \ x := by rw [inf_sup_right] _ = ⊥ := by rw [inf_comm x y, inf_inf_sdiff, sdiff_inf_sdiff, bot_sup_eq] @[simp] theorem inf_sdiff_self_left : y \ x ⊓ x = ⊥ := by rw [inf_comm, inf_sdiff_self_right] -- see Note [lower instance priority] instance (priority := 100) GeneralizedBooleanAlgebra.toGeneralizedCoheytingAlgebra : GeneralizedCoheytingAlgebra α where __ := ‹GeneralizedBooleanAlgebra α› __ := GeneralizedBooleanAlgebra.toOrderBot sdiff := (· \ ·) sdiff_le_iff y x z := ⟨fun h => le_of_inf_le_sup_le (le_of_eq (calc y ⊓ y \ x = y \ x := inf_of_le_right sdiff_le' _ = x ⊓ y \ x ⊔ z ⊓ y \ x := by rw [inf_eq_right.2 h, inf_sdiff_self_right, bot_sup_eq] _ = (x ⊔ z) ⊓ y \ x := by rw [← inf_sup_right])) (calc y ⊔ y \ x = y := sup_of_le_left sdiff_le' _ ≤ y ⊔ (x ⊔ z) := le_sup_left _ = y \ x ⊔ x ⊔ z := by rw [← sup_assoc, ← @sdiff_sup_self' _ x y] _ = x ⊔ z ⊔ y \ x := by ac_rfl), fun h => le_of_inf_le_sup_le (calc y \ x ⊓ x = ⊥ := inf_sdiff_self_left _ ≤ z ⊓ x := bot_le) (calc y \ x ⊔ x = y ⊔ x := sdiff_sup_self' _ ≤ x ⊔ z ⊔ x := sup_le_sup_right h x _ ≤ z ⊔ x := by rw [sup_assoc, sup_comm, sup_assoc, sup_idem])⟩ theorem disjoint_sdiff_self_left : Disjoint (y \ x) x := disjoint_iff_inf_le.mpr inf_sdiff_self_left.le theorem disjoint_sdiff_self_right : Disjoint x (y \ x) := disjoint_iff_inf_le.mpr inf_sdiff_self_right.le lemma le_sdiff : x ≤ y \ z ↔ x ≤ y ∧ Disjoint x z := ⟨fun h ↦ ⟨h.trans sdiff_le, disjoint_sdiff_self_left.mono_left h⟩, fun h ↦ by rw [← h.2.sdiff_eq_left]; exact sdiff_le_sdiff_right h.1⟩ @[simp] lemma sdiff_eq_left : x \ y = x ↔ Disjoint x y := ⟨fun h ↦ disjoint_sdiff_self_left.mono_left h.ge, Disjoint.sdiff_eq_left⟩ /- TODO: we could make an alternative constructor for `GeneralizedBooleanAlgebra` using `Disjoint x (y \ x)` and `x ⊔ (y \ x) = y` as axioms. -/ theorem Disjoint.sdiff_eq_of_sup_eq (hi : Disjoint x z) (hs : x ⊔ z = y) : y \ x = z := have h : y ⊓ x = x := inf_eq_right.2 <\| le_sup_left.trans hs.le sdiff_unique (by rw [h, hs]) (by rw [h, hi.eq_bot]) protected theorem Disjoint.sdiff_unique (hd : Disjoint x z) (hz : z ≤ y) (hs : y ≤ x ⊔ z) : y \ x = z := sdiff_unique (by rw [← inf_eq_right] at hs rwa [sup_inf_right, inf_sup_right, sup_comm x, inf_sup_self, inf_comm, sup_comm z, hs, sup_eq_left]) (by rw [inf_assoc, hd.eq_bot, inf_bot_eq]) -- cf. `IsCompl.disjoint_left_iff` and `IsCompl.disjoint_right_iff` theorem disjoint_sdiff_iff_le (hz : z ≤ y) (hx : x ≤ y) : Disjoint z (y \ x) ↔ z ≤ x := ⟨fun H => le_of_inf_le_sup_le (le_trans H.le_bot bot_le) (by rw [sup_sdiff_cancel_right hx] refine le_trans (sup_le_sup_left sdiff_le z) ?_ rw [sup_eq_right.2 hz]), fun H => disjoint_sdiff_self_right.mono_left H⟩ -- cf. `IsCompl.le_left_iff` and `IsCompl.le_right_iff` theorem le_iff_disjoint_sdiff (hz : z ≤ y) (hx : x ≤ y) : z ≤ x ↔ Disjoint z (y \ x) := (disjoint_sdiff_iff_le hz hx).symm -- cf. `IsCompl.inf_left_eq_bot_iff` and `IsCompl.inf_right_eq_bot_iff` theorem inf_sdiff_eq_bot_iff (hz : z ≤ y) (hx : x ≤ y) : z ⊓ y \ x = ⊥ ↔ z ≤ x := by rw [← disjoint_iff] exact disjoint_sdiff_iff_le hz hx -- cf. `IsCompl.left_le_iff` and `IsCompl.right_le_iff` theorem le_iff_eq_sup_sdiff (hz : z ≤ y) (hx : x ≤ y) : x ≤ z ↔ y = z ⊔ y \ x := ⟨fun H => by apply le_antisymm · conv_lhs => rw [← sup_inf_sdiff y x] apply sup_le_sup_right rwa [inf_eq_right.2 hx] · apply le_trans · apply sup_le_sup_right hz · rw [sup_sdiff_left], fun H => by conv_lhs at H => rw [← sup_sdiff_cancel_right hx] refine le_of_inf_le_sup_le ?_ H.le rw [inf_sdiff_self_right] exact bot_le⟩ -- cf. `IsCompl.sup_inf` theorem sdiff_sup : y \ (x ⊔ z) = y \ x ⊓ y \ z := sdiff_unique (calc y ⊓ (x ⊔ z) ⊔ y \ x ⊓ y \ z = (y ⊓ (x ⊔ z) ⊔ y \ x) ⊓ (y ⊓ (x ⊔ z) ⊔ y \ z) := by rw [sup_inf_left] _ = (y ⊓ x ⊔ y ⊓ z ⊔ y \ x) ⊓ (y ⊓ x ⊔ y ⊓ z ⊔ y \ z) := by rw [@inf_sup_left _ _ y] _ = (y ⊓ z ⊔ (y ⊓ x ⊔ y \ x)) ⊓ (y ⊓ x ⊔ (y ⊓ z ⊔ y \ z)) := by ac_rfl _ = (y ⊓ z ⊔ y) ⊓ (y ⊓ x ⊔ y) := by rw [sup_inf_sdiff, sup_inf_sdiff] _ = (y ⊔ y ⊓ z) ⊓ (y ⊔ y ⊓ x) := by ac_rfl _ = y := by rw [sup_inf_self, sup_inf_self, inf_idem]) (calc y ⊓ (x ⊔ z) ⊓ (y \ x ⊓ y \ z) = (y ⊓ x ⊔ y ⊓ z) ⊓ (y \ x ⊓ y \ z) := by rw [inf_sup_left] _ = y ⊓ x ⊓ (y \ x ⊓ y \ z) ⊔ y ⊓ z ⊓ (y \ x ⊓ y \ z) := by rw [inf_sup_right] _ = y ⊓ x ⊓ y \ x ⊓ y \ z ⊔ y \ x ⊓ (y \ z ⊓ (y ⊓ z)) := by ac_rfl _ = ⊥ := by rw [inf_inf_sdiff, bot_inf_eq, bot_sup_eq, inf_comm (y \ z), inf_inf_sdiff, inf_bot_eq]) theorem sdiff_eq_sdiff_iff_inf_eq_inf : y \ x = y \ z ↔ y ⊓ x = y ⊓ z := ⟨fun h => eq_of_inf_eq_sup_eq (a := y \ x) (by rw [inf_inf_sdiff, h, inf_inf_sdiff]) (by rw [sup_inf_sdiff, h, sup_inf_sdiff]), fun h => by rw [← sdiff_inf_self_right, ← sdiff_inf_self_right z y, inf_comm, h, inf_comm]⟩ theorem sdiff_eq_self_iff_disjoint : x \ y = x ↔ Disjoint y x := calc x \ y = x ↔ x \ y = x \ ⊥ := by rw [sdiff_bot] _ ↔ x ⊓ y = x ⊓ ⊥ := sdiff_eq_sdiff_iff_inf_eq_inf _ ↔ Disjoint y x := by rw [inf_bot_eq, inf_comm, disjoint_iff] theorem sdiff_eq_self_iff_disjoint' : x \ y = x ↔ Disjoint x y := by rw [sdiff_eq_self_iff_disjoint, disjoint_comm] theorem sdiff_lt (hx : y ≤ x) (hy : y ≠ ⊥) : x \ y < x := by refine sdiff_le.lt_of_ne fun h => hy ?_ rw [sdiff_eq_self_iff_disjoint', disjoint_iff] at h rw [← h, inf_eq_right.mpr hx] theorem sdiff_lt_left : x \ y < x ↔ ¬ Disjoint y x := by rw [lt_iff_le_and_ne, Ne, sdiff_eq_self_iff_disjoint, and_iff_right sdiff_le] @[simp] theorem le_sdiff_right : x ≤ y \ x ↔ x = ⊥ := ⟨fun h => disjoint_self.1 (disjoint_sdiff_self_right.mono_right h), fun h => h.le.trans bot_le⟩ @[simp] lemma sdiff_eq_right : x \ y = y ↔ x = ⊥ ∧ y = ⊥ := by rw [disjoint_sdiff_self_left.eq_iff]; aesop lemma sdiff_ne_right : x \ y ≠ y ↔ x ≠ ⊥ ∨ y ≠ ⊥ := sdiff_eq_right.not.trans not_and_or theorem sdiff_lt_sdiff_right (h : x < y) (hz : z ≤ x) : x \ z < y \ z := (sdiff_le_sdiff_right h.le).lt_of_not_le fun h' => h.not_le <\| le_sdiff_sup.trans <\| sup_le_of_le_sdiff_right h' hz theorem sup_inf_inf_sdiff : x ⊓ y ⊓ z ⊔ y \ z = x ⊓ y ⊔ y \ z := calc x ⊓ y ⊓ z ⊔ y \ z = x ⊓ (y ⊓ z) ⊔ y \ z := by rw [inf_assoc] _ = (x ⊔ y \ z) ⊓ y := by rw [sup_inf_right, sup_inf_sdiff] _ = x ⊓ y ⊔ y \ z := by rw [inf_sup_right, inf_sdiff_left] theorem sdiff_sdiff_right : x \ (y \ z) = x \ y ⊔ x ⊓ y ⊓ z := by rw [sup_comm, inf_comm, ← inf_assoc, sup_inf_inf_sdiff] apply sdiff_unique · calc x ⊓ y \ z ⊔ (z ⊓ x ⊔ x \ y) = (x ⊔ (z ⊓ x ⊔ x \ y)) ⊓ (y \ z ⊔ (z ⊓ x ⊔ x \ y)) := by rw [sup_inf_right] _ = (x ⊔ x ⊓ z ⊔ x \ y) ⊓ (y \ z ⊔ (x ⊓ z ⊔ x \ y)) := by ac_rfl _ = x ⊓ (y \ z ⊔ x ⊓ z ⊔ x \ y) := by rw [sup_inf_self, sup_sdiff_left, ← sup_assoc] _ = x ⊓ (y \ z ⊓ (z ⊔ y) ⊔ x ⊓ (z ⊔ y) ⊔ x \ y) := by rw [sup_inf_left, sdiff_sup_self', inf_sup_right, sup_comm y] _ = x ⊓ (y \ z ⊔ (x ⊓ z ⊔ x ⊓ y) ⊔ x \ y) := by rw [inf_sdiff_sup_right, @inf_sup_left _ _ x z y] _ = x ⊓ (y \ z ⊔ (x ⊓ z ⊔ (x ⊓ y ⊔ x \ y))) := by ac_rfl _ = x ⊓ (y \ z ⊔ (x ⊔ x ⊓ z)) := by rw [sup_inf_sdiff, sup_comm (x ⊓ z)] _ = x := by rw [sup_inf_self, sup_comm, inf_sup_self] · calc x ⊓ y \ z ⊓ (z ⊓ x ⊔ x \ y) = x ⊓ y \ z ⊓ (z ⊓ x) ⊔ x ⊓ y \ z ⊓ x \ y := by rw [inf_sup_left] _ = x ⊓ (y \ z ⊓ z ⊓ x) ⊔ x ⊓ y \ z ⊓ x \ y := by ac_rfl _ = x ⊓ y \ z ⊓ x \ y := by rw [inf_sdiff_self_left, bot_inf_eq, inf_bot_eq, bot_sup_eq] _ = x ⊓ (y \ z ⊓ y) ⊓ x \ y := by conv_lhs => rw [← inf_sdiff_left] _ = x ⊓ (y \ z ⊓ (y ⊓ x \ y)) := by ac_rfl _ = ⊥ := by rw [inf_sdiff_self_right, inf_bot_eq, inf_bot_eq] theorem sdiff_sdiff_right' : x \ (y \ z) = x \ y ⊔ x ⊓ z := calc x \ (y \ z) = x \ y ⊔ x ⊓ y ⊓ z := sdiff_sdiff_right _ = z ⊓ x ⊓ y ⊔ x \ y := by ac_rfl _ = x \ y ⊔ x ⊓ z := by rw [sup_inf_inf_sdiff, sup_comm, inf_comm] theorem sdiff_sdiff_eq_sdiff_sup (h : z ≤ x) : x \ (y \ z) = x \ y ⊔ z := by rw [sdiff_sdiff_right', inf_eq_right.2 h] @[simp] theorem sdiff_sdiff_right_self : x \ (x \ y) = x ⊓ y := by rw [sdiff_sdiff_right, inf_idem, sdiff_self, bot_sup_eq] theorem sdiff_sdiff_eq_self (h : y ≤ x) : x \ (x \ y) = y := by rw [sdiff_sdiff_right_self, inf_of_le_right h] theorem sdiff_eq_symm (hy : y ≤ x) (h : x \ y = z) : x \ z = y := by rw [← h, sdiff_sdiff_eq_self hy] theorem sdiff_eq_comm (hy : y ≤ x) (hz : z ≤ x) : x \ y = z ↔ x \ z = y := ⟨sdiff_eq_symm hy, sdiff_eq_symm hz⟩ theorem eq_of_sdiff_eq_sdiff (hxz : x ≤ z) (hyz : y ≤ z) (h : z \ x = z \ y) : x = y := by rw [← sdiff_sdiff_eq_self hxz, h, sdiff_sdiff_eq_self hyz] theorem sdiff_le_sdiff_iff_le (hx : x ≤ z) (hy : y ≤ z) : z \ x ≤ z \ y ↔ y ≤ x := by refine ⟨fun h ↦ ?_, sdiff_le_sdiff_left⟩ rw [← sdiff_sdiff_eq_self hx, ← sdiff_sdiff_eq_self hy] exact sdiff_le_sdiff_left h theorem sdiff_sdiff_left' : (x \ y) \ z = x \ y ⊓ x \ z := by rw [sdiff_sdiff_left, sdiff_sup] theorem sdiff_sdiff_sup_sdiff : z \ (x \ y ⊔ y \ x) = z ⊓ (z \ x ⊔ y) ⊓ (z \ y ⊔ x) := calc z \ (x \ y ⊔ y \ x) = (z \ x ⊔ z ⊓ x ⊓ y) ⊓ (z \ y ⊔ z ⊓ y ⊓ x) := by rw [sdiff_sup, sdiff_sdiff_right, sdiff_sdiff_right] _ = z ⊓ (z \ x ⊔ y) ⊓ (z \ y ⊔ z ⊓ y ⊓ x) := by rw [sup_inf_left, sup_comm, sup_inf_sdiff] _ = z ⊓ (z \ x ⊔ y) ⊓ (z ⊓ (z \ y ⊔ x)) := by rw [sup_inf_left, sup_comm (z \ y), sup_inf_sdiff] _ = z ⊓ z ⊓ (z \ x ⊔ y) ⊓ (z \ y ⊔ x) := by ac_rfl _ = z ⊓ (z \ x ⊔ y) ⊓ (z \ y ⊔ x) := by rw [inf_idem] theorem sdiff_sdiff_sup_sdiff' : z \ (x \ y ⊔ y \ x) = z ⊓ x ⊓ y ⊔ z \ x ⊓ z \ y := calc z \ (x \ y ⊔ y \ x) = z \ (x \ y) ⊓ z \ (y \ x) := sdiff_sup _ = (z \ x ⊔ z ⊓ x ⊓ y) ⊓ (z \ y ⊔ z ⊓ y ⊓ x) := by rw [sdiff_sdiff_right, sdiff_sdiff_right] _ = (z \ x ⊔ z ⊓ y ⊓ x) ⊓ (z \ y ⊔ z ⊓ y ⊓ x) := by ac_rfl _ = z \ x ⊓ z \ y ⊔ z ⊓ y ⊓ x := by rw [← sup_inf_right] _ = z ⊓ x ⊓ y ⊔ z \ x ⊓ z \ y := by ac_rfl lemma sdiff_sdiff_sdiff_cancel_left (hca : z ≤ x) : (x \ y) \ (x \ z) = z \ y := sdiff_sdiff_sdiff_le_sdiff.antisymm <\| (disjoint_sdiff_self_right.mono_left sdiff_le).le_sdiff_of_le_left <\| sdiff_le_sdiff_right hca lemma sdiff_sdiff_sdiff_cancel_right (hcb : z ≤ y) : (x \ z) \ (y \ z) = x \ y := by rw [le_antisymm_iff, sdiff_le_comm] exact ⟨sdiff_sdiff_sdiff_le_sdiff, (disjoint_sdiff_self_left.mono_right sdiff_le).le_sdiff_of_le_left <\| sdiff_le_sdiff_left hcb⟩	theorem inf_sdiff : (x ⊓ y) \ z = x \ z ⊓ y \ z :=	Mathlib/Order/BooleanAlgebra.lean	399	400
/- 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.Fintype.Card import Mathlib.Algebra.Order.BigOperators.Group.Multiset import Mathlib.Algebra.Order.Group.Nat import Mathlib.Data.Multiset.OrderedMonoid import Mathlib.Tactic.Bound.Attribute import Mathlib.Algebra.BigOperators.Group.Finset.Sigma import Mathlib.Data.Multiset.Powerset /-! # Big operators on a finset in ordered groups This file contains the results concerning the interaction of multiset big operators with ordered groups/monoids. -/ assert_not_exists Ring open Function variable {ι α β M N G k R : Type} namespace Finset section OrderedCommMonoid variable [CommMonoid M] [CommMonoid N] [PartialOrder N] [IsOrderedMonoid N] /-- Let `{x \| p x}` be a subsemigroup of a commutative monoid `M`. Let `f : M → N` be a map submultiplicative on `{x \| p x}`, i.e., `p x → p y → f (x y) ≤ f x * f y`. Let `g i`, `i ∈ s`, be a nonempty finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∏ x ∈ s, g x) ≤ ∏ x ∈ s, f (g x)`. -/ @[to_additive le_sum_nonempty_of_subadditive_on_pred] theorem le_prod_nonempty_of_submultiplicative_on_pred (f : M → N) (p : M → Prop) (h_mul : ∀ x y, p x → p y → f (x * y) ≤ f x * f y) (hp_mul : ∀ x y, p x → p y → p (x * y)) (g : ι → M) (s : Finset ι) (hs_nonempty : s.Nonempty) (hs : ∀ i ∈ s, p (g i)) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := by refine le_trans (Multiset.le_prod_nonempty_of_submultiplicative_on_pred f p h_mul hp_mul _ ?_ ?_) ?_ · simp [hs_nonempty.ne_empty] · exact Multiset.forall_mem_map_iff.mpr hs rw [Multiset.map_map] rfl /-- Let `{x \| p x}` be an additive subsemigroup of an additive commutative monoid `M`. Let `f : M → N` be a map subadditive on `{x \| p x}`, i.e., `p x → p y → f (x + y) ≤ f x + f y`. Let `g i`, `i ∈ s`, be a nonempty finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∑ i ∈ s, g i) ≤ ∑ i ∈ s, f (g i)`. -/ add_decl_doc le_sum_nonempty_of_subadditive_on_pred /-- If `f : M → N` is a submultiplicative function, `f (x * y) ≤ f x * f y` and `g i`, `i ∈ s`, is a nonempty finite family of elements of `M`, then `f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i)`. -/ @[to_additive le_sum_nonempty_of_subadditive] theorem le_prod_nonempty_of_submultiplicative (f : M → N) (h_mul : ∀ x y, f (x * y) ≤ f x * f y) {s : Finset ι} (hs : s.Nonempty) (g : ι → M) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := le_prod_nonempty_of_submultiplicative_on_pred f (fun _ ↦ True) (fun x y _ _ ↦ h_mul x y) (fun _ _ _ _ ↦ trivial) g s hs fun _ _ ↦ trivial /-- If `f : M → N` is a subadditive function, `f (x + y) ≤ f x + f y` and `g i`, `i ∈ s`, is a nonempty finite family of elements of `M`, then `f (∑ i ∈ s, g i) ≤ ∑ i ∈ s, f (g i)`. -/ add_decl_doc le_sum_nonempty_of_subadditive /-- Let `{x \| p x}` be a subsemigroup of a commutative monoid `M`. Let `f : M → N` be a map such that `f 1 = 1` and `f` is submultiplicative on `{x \| p x}`, i.e., `p x → p y → f (x * y) ≤ f x * f y`. Let `g i`, `i ∈ s`, be a finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i)`. -/ @[to_additive le_sum_of_subadditive_on_pred] theorem le_prod_of_submultiplicative_on_pred (f : M → N) (p : M → Prop) (h_one : f 1 = 1) (h_mul : ∀ x y, p x → p y → f (x * y) ≤ f x * f y) (hp_mul : ∀ x y, p x → p y → p (x * y)) (g : ι → M) {s : Finset ι} (hs : ∀ i ∈ s, p (g i)) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := by rcases eq_empty_or_nonempty s with (rfl \| hs_nonempty) · simp [h_one] · exact le_prod_nonempty_of_submultiplicative_on_pred f p h_mul hp_mul g s hs_nonempty hs /-- Let `{x \| p x}` be a subsemigroup of a commutative additive monoid `M`. Let `f : M → N` be a map such that `f 0 = 0` and `f` is subadditive on `{x \| p x}`, i.e. `p x → p y → f (x + y) ≤ f x + f y`. Let `g i`, `i ∈ s`, be a finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∑ x ∈ s, g x) ≤ ∑ x ∈ s, f (g x)`. -/ add_decl_doc le_sum_of_subadditive_on_pred /-- If `f : M → N` is a submultiplicative function, `f (x * y) ≤ f x * f y`, `f 1 = 1`, and `g i`, `i ∈ s`, is a finite family of elements of `M`, then `f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i)`. -/ @[to_additive le_sum_of_subadditive] theorem le_prod_of_submultiplicative (f : M → N) (h_one : f 1 = 1) (h_mul : ∀ x y, f (x * y) ≤ f x * f y) (s : Finset ι) (g : ι → M) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := by refine le_trans (Multiset.le_prod_of_submultiplicative f h_one h_mul _) ?_ rw [Multiset.map_map] rfl /-- If `f : M → N` is a subadditive function, `f (x + y) ≤ f x + f y`, `f 0 = 0`, and `g i`, `i ∈ s`, is a finite family of elements of `M`, then `f (∑ i ∈ s, g i) ≤ ∑ i ∈ s, f (g i)`. -/ add_decl_doc le_sum_of_subadditive variable {f g : ι → N} {s t : Finset ι} /-- In an ordered commutative monoid, if each factor `f i` of one finite product is less than or equal to the corresponding factor `g i` of another finite product, then `∏ i ∈ s, f i ≤ ∏ i ∈ s, g i`. -/ @[to_additive (attr := gcongr) sum_le_sum] theorem prod_le_prod' (h : ∀ i ∈ s, f i ≤ g i) : ∏ i ∈ s, f i ≤ ∏ i ∈ s, g i := Multiset.prod_map_le_prod_map f g h attribute [bound] sum_le_sum /-- In an ordered additive commutative monoid, if each summand `f i` of one finite sum is less than or equal to the corresponding summand `g i` of another finite sum, then `∑ i ∈ s, f i ≤ ∑ i ∈ s, g i`. -/ add_decl_doc sum_le_sum @[to_additive sum_nonneg] theorem one_le_prod' (h : ∀ i ∈ s, 1 ≤ f i) : 1 ≤ ∏ i ∈ s, f i := le_trans (by rw [prod_const_one]) (prod_le_prod' h) @[to_additive Finset.sum_nonneg'] theorem one_le_prod'' (h : ∀ i : ι, 1 ≤ f i) : 1 ≤ ∏ i ∈ s, f i := Finset.one_le_prod' fun i _ ↦ h i @[to_additive sum_nonpos] theorem prod_le_one' (h : ∀ i ∈ s, f i ≤ 1) : ∏ i ∈ s, f i ≤ 1 := (prod_le_prod' h).trans_eq (by rw [prod_const_one]) @[to_additive (attr := gcongr) sum_le_sum_of_subset_of_nonneg] theorem prod_le_prod_of_subset_of_one_le' (h : s ⊆ t) (hf : ∀ i ∈ t, i ∉ s → 1 ≤ f i) : ∏ i ∈ s, f i ≤ ∏ i ∈ t, f i := by classical calc ∏ i ∈ s, f i ≤ (∏ i ∈ t \ s, f i) * ∏ i ∈ s, f i := le_mul_of_one_le_left' <\| one_le_prod' <\| by simpa only [mem_sdiff, and_imp] _ = ∏ i ∈ t \ s ∪ s, f i := (prod_union sdiff_disjoint).symm _ = ∏ i ∈ t, f i := by rw [sdiff_union_of_subset h] @[to_additive sum_mono_set_of_nonneg] theorem prod_mono_set_of_one_le' (hf : ∀ x, 1 ≤ f x) : Monotone fun s ↦ ∏ x ∈ s, f x := fun _ _ hst ↦ prod_le_prod_of_subset_of_one_le' hst fun x _ _ ↦ hf x @[to_additive sum_le_univ_sum_of_nonneg] theorem prod_le_univ_prod_of_one_le' [Fintype ι] {s : Finset ι} (w : ∀ x, 1 ≤ f x) : ∏ x ∈ s, f x ≤ ∏ x, f x := prod_le_prod_of_subset_of_one_le' (subset_univ s) fun a _ _ ↦ w a @[to_additive sum_eq_zero_iff_of_nonneg] theorem prod_eq_one_iff_of_one_le' : (∀ i ∈ s, 1 ≤ f i) → ((∏ i ∈ s, f i) = 1 ↔ ∀ i ∈ s, f i = 1) := by classical refine Finset.induction_on s (fun _ ↦ ⟨fun _ _ h ↦ False.elim (Finset.not_mem_empty _ h), fun _ ↦ rfl⟩) ?_ intro a s ha ih H have : ∀ i ∈ s, 1 ≤ f i := fun _ ↦ H _ ∘ mem_insert_of_mem rw [prod_insert ha, mul_eq_one_iff_of_one_le (H _ <\| mem_insert_self _ _) (one_le_prod' this), forall_mem_insert, ih this] @[to_additive sum_eq_zero_iff_of_nonpos] theorem prod_eq_one_iff_of_le_one' : (∀ i ∈ s, f i ≤ 1) → ((∏ i ∈ s, f i) = 1 ↔ ∀ i ∈ s, f i = 1) := prod_eq_one_iff_of_one_le' (N := Nᵒᵈ) @[to_additive single_le_sum] theorem single_le_prod' (hf : ∀ i ∈ s, 1 ≤ f i) {a} (h : a ∈ s) : f a ≤ ∏ x ∈ s, f x := calc f a = ∏ i ∈ {a}, f i := (prod_singleton _ _).symm _ ≤ ∏ i ∈ s, f i := prod_le_prod_of_subset_of_one_le' (singleton_subset_iff.2 h) fun i hi _ ↦ hf i hi @[to_additive] lemma mul_le_prod {i j : ι} (hf : ∀ i ∈ s, 1 ≤ f i) (hi : i ∈ s) (hj : j ∈ s) (hne : i ≠ j) : f i * f j ≤ ∏ k ∈ s, f k := calc f i * f j = ∏ k ∈ .cons i {j} (by simpa), f k := by rw [prod_cons, prod_singleton] _ ≤ ∏ k ∈ s, f k := by refine prod_le_prod_of_subset_of_one_le' ?_ fun k hk _ ↦ hf k hk simp [cons_subset, ] @[to_additive sum_le_card_nsmul] theorem prod_le_pow_card (s : Finset ι) (f : ι → N) (n : N) (h : ∀ x ∈ s, f x ≤ n) : s.prod f ≤ n ^ #s := by refine (Multiset.prod_le_pow_card (s.val.map f) n ?_).trans ?_ · simpa using h · simp @[to_additive card_nsmul_le_sum] theorem pow_card_le_prod (s : Finset ι) (f : ι → N) (n : N) (h : ∀ x ∈ s, n ≤ f x) : n ^ #s ≤ s.prod f := Finset.prod_le_pow_card (N := Nᵒᵈ) _ _ _ h theorem card_biUnion_le_card_mul [DecidableEq β] (s : Finset ι) (f : ι → Finset β) (n : ℕ) (h : ∀ a ∈ s, #(f a) ≤ n) : #(s.biUnion f) ≤ #s n := card_biUnion_le.trans <\| sum_le_card_nsmul _ _ _ h variable {ι' : Type} [DecidableEq ι'] @[to_additive sum_fiberwise_le_sum_of_sum_fiber_nonneg] theorem prod_fiberwise_le_prod_of_one_le_prod_fiber' {t : Finset ι'} {g : ι → ι'} {f : ι → N} (h : ∀ y ∉ t, (1 : N) ≤ ∏ x ∈ s with g x = y, f x) : (∏ y ∈ t, ∏ x ∈ s with g x = y, f x) ≤ ∏ x ∈ s, f x := calc (∏ y ∈ t, ∏ x ∈ s with g x = y, f x) ≤ ∏ y ∈ t ∪ s.image g, ∏ x ∈ s with g x = y, f x := prod_le_prod_of_subset_of_one_le' subset_union_left fun y _ ↦ h y _ = ∏ x ∈ s, f x := prod_fiberwise_of_maps_to (fun _ hx ↦ mem_union.2 <\| Or.inr <\| mem_image_of_mem _ hx) _ @[to_additive sum_le_sum_fiberwise_of_sum_fiber_nonpos] theorem prod_le_prod_fiberwise_of_prod_fiber_le_one' {t : Finset ι'} {g : ι → ι'} {f : ι → N} (h : ∀ y ∉ t, ∏ x ∈ s with g x = y, f x ≤ 1) : ∏ x ∈ s, f x ≤ ∏ y ∈ t, ∏ x ∈ s with g x = y, f x := prod_fiberwise_le_prod_of_one_le_prod_fiber' (N := Nᵒᵈ) h @[to_additive] lemma prod_image_le_of_one_le {g : ι → ι'} {f : ι' → N} (hf : ∀ u ∈ s.image g, 1 ≤ f u) : ∏ u ∈ s.image g, f u ≤ ∏ u ∈ s, f (g u) := by rw [prod_comp f g] refine prod_le_prod' fun a hag ↦ ?_ obtain ⟨i, hi, hig⟩ := Finset.mem_image.mp hag apply le_self_pow (hf a hag) rw [← Nat.pos_iff_ne_zero, card_pos] exact ⟨i, mem_filter.mpr ⟨hi, hig⟩⟩ end OrderedCommMonoid @[to_additive] lemma max_prod_le [CommMonoid M] [LinearOrder M] [IsOrderedMonoid M] {f g : ι → M} {s : Finset ι} : max (s.prod f) (s.prod g) ≤ s.prod (fun i ↦ max (f i) (g i)) := Multiset.max_prod_le @[to_additive] lemma prod_min_le [CommMonoid M] [LinearOrder M] [IsOrderedMonoid M] {f g : ι → M} {s : Finset ι} : s.prod (fun i ↦ min (f i) (g i)) ≤ min (s.prod f) (s.prod g) := Multiset.prod_min_le theorem abs_sum_le_sum_abs {G : Type} [AddCommGroup G] [LinearOrder G] [IsOrderedAddMonoid G] (f : ι → G) (s : Finset ι) : \|∑ i ∈ s, f i\| ≤ ∑ i ∈ s, \|f i\| := le_sum_of_subadditive _ abs_zero abs_add s f theorem abs_sum_of_nonneg {G : Type} [AddCommGroup G] [LinearOrder G] [IsOrderedAddMonoid G] {f : ι → G} {s : Finset ι} (hf : ∀ i ∈ s, 0 ≤ f i) : \|∑ i ∈ s, f i\| = ∑ i ∈ s, f i := by rw [abs_of_nonneg (Finset.sum_nonneg hf)] theorem abs_sum_of_nonneg' {G : Type} [AddCommGroup G] [LinearOrder G] [IsOrderedAddMonoid G] {f : ι → G} {s : Finset ι} (hf : ∀ i, 0 ≤ f i) : \|∑ i ∈ s, f i\| = ∑ i ∈ s, f i := by rw [abs_of_nonneg (Finset.sum_nonneg' hf)] section CommMonoid variable [CommMonoid α] [LE α] [MulLeftMono α] {s : Finset ι} {f : ι → α} @[to_additive (attr := simp)] lemma mulLECancellable_prod : MulLECancellable (∏ i ∈ s, f i) ↔ ∀ ⦃i⦄, i ∈ s → MulLECancellable (f i) := by induction' s using Finset.cons_induction with i s hi ih <;> simp [] end CommMonoid section Pigeonhole variable [DecidableEq β] theorem card_le_mul_card_image_of_maps_to {f : α → β} {s : Finset α} {t : Finset β} (Hf : ∀ a ∈ s, f a ∈ t) (n : ℕ) (hn : ∀ b ∈ t, #{a ∈ s \| f a = b} ≤ n) : #s ≤ n #t := calc #s = ∑ b ∈ t, #{a ∈ s \| f a = b} := card_eq_sum_card_fiberwise Hf _ ≤ ∑ _b ∈ t, n := sum_le_sum hn _ = _ := by simp [mul_comm] theorem card_le_mul_card_image {f : α → β} (s : Finset α) (n : ℕ) (hn : ∀ b ∈ s.image f, #{a ∈ s \| f a = b} ≤ n) : #s ≤ n * #(s.image f) := card_le_mul_card_image_of_maps_to (fun _ ↦ mem_image_of_mem _) n hn theorem mul_card_image_le_card_of_maps_to {f : α → β} {s : Finset α} {t : Finset β} (Hf : ∀ a ∈ s, f a ∈ t) (n : ℕ) (hn : ∀ b ∈ t, n ≤ #{a ∈ s \| f a = b}) : n * #t ≤ #s := calc n * #t = ∑ _a ∈ t, n := by simp [mul_comm] _ ≤ ∑ b ∈ t, #{a ∈ s \| f a = b} := sum_le_sum hn _ = #s := by rw [← card_eq_sum_card_fiberwise Hf] theorem mul_card_image_le_card {f : α → β} (s : Finset α) (n : ℕ) (hn : ∀ b ∈ s.image f, n ≤ #{a ∈ s \| f a = b}) : n * #(s.image f) ≤ #s := mul_card_image_le_card_of_maps_to (fun _ ↦ mem_image_of_mem _) n hn end Pigeonhole section DoubleCounting variable [DecidableEq α] {s : Finset α} {B : Finset (Finset α)} {n : ℕ} /-- If every element belongs to at most `n` Finsets, then the sum of their sizes is at most `n` times how many they are. -/ theorem sum_card_inter_le (h : ∀ a ∈ s, #{b ∈ B \| a ∈ b} ≤ n) : (∑ t ∈ B, #(s ∩ t)) ≤ #s * n := by refine le_trans ?_ (s.sum_le_card_nsmul _ _ h) simp_rw [← filter_mem_eq_inter, card_eq_sum_ones, sum_filter] exact sum_comm.le /-- If every element belongs to at most `n` Finsets, then the sum of their sizes is at most `n` times how many they are. -/ lemma sum_card_le [Fintype α] (h : ∀ a, #{b ∈ B \| a ∈ b} ≤ n) : ∑ s ∈ B, #s ≤ Fintype.card α * n := calc ∑ s ∈ B, #s = ∑ s ∈ B, #(univ ∩ s) := by simp_rw [univ_inter] _ ≤ Fintype.card α * n := sum_card_inter_le fun a _ ↦ h a /-- If every element belongs to at least `n` Finsets, then the sum of their sizes is at least `n` times how many they are. -/ theorem le_sum_card_inter (h : ∀ a ∈ s, n ≤ #{b ∈ B \| a ∈ b}) : #s * n ≤ ∑ t ∈ B, #(s ∩ t) := by apply (s.card_nsmul_le_sum _ _ h).trans simp_rw [← filter_mem_eq_inter, card_eq_sum_ones, sum_filter] exact sum_comm.le /-- If every element belongs to at least `n` Finsets, then the sum of their sizes is at least `n` times how many they are. -/ theorem le_sum_card [Fintype α] (h : ∀ a, n ≤ #{b ∈ B \| a ∈ b}) : Fintype.card α * n ≤ ∑ s ∈ B, #s := calc Fintype.card α * n ≤ ∑ s ∈ B, #(univ ∩ s) := le_sum_card_inter fun a _ ↦ h a _ = ∑ s ∈ B, #s := by simp_rw [univ_inter] /-- If every element belongs to exactly `n` Finsets, then the sum of their sizes is `n` times how many they are. -/ theorem sum_card_inter (h : ∀ a ∈ s, #{b ∈ B \| a ∈ b} = n) : (∑ t ∈ B, #(s ∩ t)) = #s * n := (sum_card_inter_le fun a ha ↦ (h a ha).le).antisymm (le_sum_card_inter fun a ha ↦ (h a ha).ge) /-- If every element belongs to exactly `n` Finsets, then the sum of their sizes is `n` times how many they are. -/ theorem sum_card [Fintype α] (h : ∀ a, #{b ∈ B \| a ∈ b} = n) : ∑ s ∈ B, #s = Fintype.card α * n := by simp_rw [Fintype.card, ← sum_card_inter fun a _ ↦ h a, univ_inter] theorem card_le_card_biUnion {s : Finset ι} {f : ι → Finset α} (hs : (s : Set ι).PairwiseDisjoint f) (hf : ∀ i ∈ s, (f i).Nonempty) : #s ≤ #(s.biUnion f) := by rw [card_biUnion hs, card_eq_sum_ones] exact sum_le_sum fun i hi ↦ (hf i hi).card_pos theorem card_le_card_biUnion_add_card_fiber {s : Finset ι} {f : ι → Finset α} (hs : (s : Set ι).PairwiseDisjoint f) : #s ≤ #(s.biUnion f) + #{i ∈ s \| f i = ∅} := by rw [← Finset.filter_card_add_filter_neg_card_eq_card fun i ↦ f i = ∅, add_comm] exact add_le_add_right ((card_le_card_biUnion (hs.subset <\| filter_subset _ _) fun i hi ↦ nonempty_of_ne_empty <\| (mem_filter.1 hi).2).trans <\| card_le_card <\| biUnion_subset_biUnion_of_subset_left _ <\| filter_subset _ _) _ theorem card_le_card_biUnion_add_one {s : Finset ι} {f : ι → Finset α} (hf : Injective f) (hs : (s : Set ι).PairwiseDisjoint f) : #s ≤ #(s.biUnion f) + 1 := (card_le_card_biUnion_add_card_fiber hs).trans <\| add_le_add_left (card_le_one.2 fun _ hi _ hj ↦ hf <\| (mem_filter.1 hi).2.trans (mem_filter.1 hj).2.symm) _ end DoubleCounting section CanonicallyOrderedMul variable [CommMonoid M] [PartialOrder M] [IsOrderedMonoid M] [CanonicallyOrderedMul M] {f : ι → M} {s t : Finset ι} /-- In a canonically-ordered monoid, a product bounds each of its terms. See also `Finset.single_le_prod'`. -/ @[to_additive "In a canonically-ordered additive monoid, a sum bounds each of its terms. See also `Finset.single_le_sum`."] lemma _root_.CanonicallyOrderedCommMonoid.single_le_prod {i : ι} (hi : i ∈ s) : f i ≤ ∏ j ∈ s, f j := single_le_prod' (fun _ _ ↦ one_le _) hi @[to_additive sum_le_sum_of_subset] theorem prod_le_prod_of_subset' (h : s ⊆ t) : ∏ x ∈ s, f x ≤ ∏ x ∈ t, f x := prod_le_prod_of_subset_of_one_le' h fun _ _ _ ↦ one_le _ @[to_additive sum_mono_set] theorem prod_mono_set' (f : ι → M) : Monotone fun s ↦ ∏ x ∈ s, f x := fun _ _ hs ↦ prod_le_prod_of_subset' hs @[to_additive sum_le_sum_of_ne_zero] theorem prod_le_prod_of_ne_one' (h : ∀ x ∈ s, f x ≠ 1 → x ∈ t) : ∏ x ∈ s, f x ≤ ∏ x ∈ t, f x := by classical calc ∏ x ∈ s, f x = (∏ x ∈ s with f x = 1, f x) * ∏ x ∈ s with f x ≠ 1, f x := by rw [← prod_union, filter_union_filter_neg_eq] exact disjoint_filter.2 fun _ _ h n_h ↦ n_h h _ ≤ ∏ x ∈ t, f x := mul_le_of_le_one_of_le (prod_le_one' <\| by simp only [mem_filter, and_imp]; exact fun _ _ ↦ le_of_eq) (prod_le_prod_of_subset' <\| by simpa only [subset_iff, mem_filter, and_imp] ) end CanonicallyOrderedMul section OrderedCancelCommMonoid variable [CommMonoid M] [PartialOrder M] [IsOrderedCancelMonoid M] {f g : ι → M} {s t : Finset ι} @[to_additive sum_lt_sum] theorem prod_lt_prod' (hle : ∀ i ∈ s, f i ≤ g i) (hlt : ∃ i ∈ s, f i < g i) : ∏ i ∈ s, f i < ∏ i ∈ s, g i := Multiset.prod_lt_prod' hle hlt /-- In an ordered commutative monoid, if each factor `f i` of one nontrivial finite product is strictly less than the corresponding factor `g i` of another nontrivial finite product, then `s.prod f < s.prod g`. -/ @[to_additive (attr := gcongr) sum_lt_sum_of_nonempty] theorem prod_lt_prod_of_nonempty' (hs : s.Nonempty) (hlt : ∀ i ∈ s, f i < g i) : ∏ i ∈ s, f i < ∏ i ∈ s, g i := Multiset.prod_lt_prod_of_nonempty' (by aesop) hlt /-- In an ordered additive commutative monoid, if each summand `f i` of one nontrivial finite sum is strictly less than the corresponding summand `g i` of another nontrivial finite sum, then `s.sum f < s.sum g`. -/ add_decl_doc sum_lt_sum_of_nonempty @[to_additive sum_lt_sum_of_subset] theorem prod_lt_prod_of_subset' (h : s ⊆ t) {i : ι} (ht : i ∈ t) (hs : i ∉ s) (hlt : 1 < f i) (hle : ∀ j ∈ t, j ∉ s → 1 ≤ f j) : ∏ j ∈ s, f j < ∏ j ∈ t, f j := by classical calc ∏ j ∈ s, f j < ∏ j ∈ insert i s, f j := by rw [prod_insert hs] exact lt_mul_of_one_lt_left' (∏ j ∈ s, f j) hlt _ ≤ ∏ j ∈ t, f j := by apply prod_le_prod_of_subset_of_one_le' · simp [Finset.insert_subset_iff, h, ht] · intro x hx h'x simp only [mem_insert, not_or] at h'x exact hle x hx h'x.2 @[to_additive single_lt_sum] theorem single_lt_prod' {i j : ι} (hij : j ≠ i) (hi : i ∈ s) (hj : j ∈ s) (hlt : 1 < f j) (hle : ∀ k ∈ s, k ≠ i → 1 ≤ f k) : f i < ∏ k ∈ s, f k := calc f i = ∏ k ∈ {i}, f k := by rw [prod_singleton] _ < ∏ k ∈ s, f k := prod_lt_prod_of_subset' (singleton_subset_iff.2 hi) hj (mt mem_singleton.1 hij) hlt fun k hks hki ↦ hle k hks (mt mem_singleton.2 hki) @[to_additive sum_pos] theorem one_lt_prod (h : ∀ i ∈ s, 1 < f i) (hs : s.Nonempty) : 1 < ∏ i ∈ s, f i := lt_of_le_of_lt (by rw [prod_const_one]) <\| prod_lt_prod_of_nonempty' hs h @[to_additive] theorem prod_lt_one (h : ∀ i ∈ s, f i < 1) (hs : s.Nonempty) : ∏ i ∈ s, f i < 1 := (prod_lt_prod_of_nonempty' hs h).trans_le (by rw [prod_const_one]) @[to_additive sum_pos'] theorem one_lt_prod' (h : ∀ i ∈ s, 1 ≤ f i) (hs : ∃ i ∈ s, 1 < f i) : 1 < ∏ i ∈ s, f i := prod_const_one.symm.trans_lt <\| prod_lt_prod' h hs @[to_additive] theorem prod_lt_one' (h : ∀ i ∈ s, f i ≤ 1) (hs : ∃ i ∈ s, f i < 1) : ∏ i ∈ s, f i < 1 := prod_const_one.le.trans_lt' <\| prod_lt_prod' h hs @[to_additive] theorem prod_eq_prod_iff_of_le {f g : ι → M} (h : ∀ i ∈ s, f i ≤ g i) : ((∏ i ∈ s, f i) = ∏ i ∈ s, g i) ↔ ∀ i ∈ s, f i = g i := by classical revert h refine Finset.induction_on s (fun _ ↦ ⟨fun _ _ h ↦ False.elim (Finset.not_mem_empty _ h), fun _ ↦ rfl⟩) fun a s ha ih H ↦ ?_ specialize ih fun i ↦ H i ∘ Finset.mem_insert_of_mem rw [Finset.prod_insert ha, Finset.prod_insert ha, Finset.forall_mem_insert, ← ih] exact mul_eq_mul_iff_eq_and_eq (H a (s.mem_insert_self a)) (Finset.prod_le_prod' fun i ↦ H i ∘ Finset.mem_insert_of_mem) variable [DecidableEq ι] @[to_additive] lemma prod_sdiff_le_prod_sdiff : ∏ i ∈ s \ t, f i ≤ ∏ i ∈ t \ s, f i ↔ ∏ i ∈ s, f i ≤ ∏ i ∈ t, f i := by rw [← mul_le_mul_iff_right, ← prod_union (disjoint_sdiff_inter _ _), sdiff_union_inter, ← prod_union, inter_comm, sdiff_union_inter] simpa only [inter_comm] using disjoint_sdiff_inter t s @[to_additive] lemma prod_sdiff_lt_prod_sdiff : ∏ i ∈ s \ t, f i < ∏ i ∈ t \ s, f i ↔ ∏ i ∈ s, f i < ∏ i ∈ t, f i := by rw [← mul_lt_mul_iff_right, ← prod_union (disjoint_sdiff_inter _ _), sdiff_union_inter, ← prod_union, inter_comm, sdiff_union_inter] simpa only [inter_comm] using disjoint_sdiff_inter t s end OrderedCancelCommMonoid section LinearOrderedCancelCommMonoid variable [CommMonoid M] [LinearOrder M] [IsOrderedCancelMonoid M] {f g : ι → M} {s t : Finset ι} @[to_additive exists_lt_of_sum_lt] theorem exists_lt_of_prod_lt' (Hlt : ∏ i ∈ s, f i < ∏ i ∈ s, g i) : ∃ i ∈ s, f i < g i := by contrapose! Hlt with Hle exact prod_le_prod' Hle @[to_additive exists_le_of_sum_le] theorem exists_le_of_prod_le' (hs : s.Nonempty) (Hle : ∏ i ∈ s, f i ≤ ∏ i ∈ s, g i) : ∃ i ∈ s, f i ≤ g i := by contrapose! Hle with Hlt exact prod_lt_prod_of_nonempty' hs Hlt @[to_additive exists_pos_of_sum_zero_of_exists_nonzero] theorem exists_one_lt_of_prod_one_of_exists_ne_one' (f : ι → M) (h₁ : ∏ i ∈ s, f i = 1) (h₂ : ∃ i ∈ s, f i ≠ 1) : ∃ i ∈ s, 1 < f i := by contrapose! h₁ obtain ⟨i, m, i_ne⟩ : ∃ i ∈ s, f i ≠ 1 := h₂ apply ne_of_lt calc ∏ j ∈ s, f j < ∏ j ∈ s, 1 := prod_lt_prod' h₁ ⟨i, m, (h₁ i m).lt_of_ne i_ne⟩ _ = 1 := prod_const_one end LinearOrderedCancelCommMonoid end Finset namespace Fintype section OrderedCommMonoid variable [Fintype ι] [CommMonoid M] [PartialOrder M] [IsOrderedMonoid M] {f : ι → M} @[to_additive (attr := mono) sum_mono] theorem prod_mono' : Monotone fun f : ι → M ↦ ∏ i, f i := fun _ _ hfg ↦ Finset.prod_le_prod' fun x _ ↦ hfg x @[to_additive sum_nonneg] lemma one_le_prod (hf : 1 ≤ f) : 1 ≤ ∏ i, f i := Finset.one_le_prod' fun _ _ ↦ hf _ @[to_additive] lemma prod_le_one (hf : f ≤ 1) : ∏ i, f i ≤ 1 := Finset.prod_le_one' fun _ _ ↦ hf _ @[to_additive] lemma prod_eq_one_iff_of_one_le (hf : 1 ≤ f) : ∏ i, f i = 1 ↔ f = 1 := (Finset.prod_eq_one_iff_of_one_le' fun i _ ↦ hf i).trans <\| by simp [funext_iff] @[to_additive] lemma prod_eq_one_iff_of_le_one (hf : f ≤ 1) : ∏ i, f i = 1 ↔ f = 1 := (Finset.prod_eq_one_iff_of_le_one' fun i _ ↦ hf i).trans <\| by simp [funext_iff] end OrderedCommMonoid section OrderedCancelCommMonoid variable [Fintype ι] [CommMonoid M] [PartialOrder M] [IsOrderedCancelMonoid M] {f : ι → M} @[to_additive sum_strictMono] theorem prod_strictMono' : StrictMono fun f : ι → M ↦ ∏ x, f x := fun _ _ hfg ↦ let ⟨hle, i, hlt⟩ := Pi.lt_def.mp hfg Finset.prod_lt_prod' (fun i _ ↦ hle i) ⟨i, Finset.mem_univ i, hlt⟩ @[to_additive sum_pos] lemma one_lt_prod (hf : 1 < f) : 1 < ∏ i, f i := Finset.one_lt_prod' (fun _ _ ↦ hf.le _) <\| by simpa using (Pi.lt_def.1 hf).2 @[to_additive] lemma prod_lt_one (hf : f < 1) : ∏ i, f i < 1 := Finset.prod_lt_one' (fun _ _ ↦ hf.le _) <\| by simpa using (Pi.lt_def.1 hf).2 @[to_additive sum_pos_iff_of_nonneg] lemma one_lt_prod_iff_of_one_le (hf : 1 ≤ f) : 1 < ∏ i, f i ↔ 1 < f := by obtain rfl \| hf := hf.eq_or_lt <;> simp [, one_lt_prod] @[to_additive] lemma prod_lt_one_iff_of_le_one (hf : f ≤ 1) : ∏ i, f i < 1 ↔ f < 1 := by obtain rfl \| hf := hf.eq_or_lt <;> simp [, prod_lt_one] end OrderedCancelCommMonoid end Fintype namespace Multiset theorem finset_sum_eq_sup_iff_disjoint [DecidableEq α] {i : Finset β} {f : β → Multiset α} : i.sum f = i.sup f ↔ ∀ x ∈ i, ∀ y ∈ i, x ≠ y → Disjoint (f x) (f y) := by	induction' i using Finset.cons_induction_on with z i hz hr · simp only [Finset.not_mem_empty, IsEmpty.forall_iff, imp_true_iff, Finset.sum_empty, Finset.sup_empty, bot_eq_zero, eq_self_iff_true]	Mathlib/Algebra/Order/BigOperators/Group/Finset.lean	566	568
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Johannes Hölzl -/ import Mathlib.Algebra.Order.Pi import Mathlib.MeasureTheory.Constructions.BorelSpace.Order /-! # Simple functions A function `f` from a measurable space to any type is called simple, if every preimage `f ⁻¹' {x}` is measurable, and the range is finite. In this file, we define simple functions and establish their basic properties; and we construct a sequence of simple functions approximating an arbitrary Borel measurable function `f : α → ℝ≥0∞`. The theorem `Measurable.ennreal_induction` shows that in order to prove something for an arbitrary measurable function into `ℝ≥0∞`, it is sufficient to show that the property holds for (multiples of) characteristic functions and is closed under addition and supremum of increasing sequences of functions. -/ noncomputable section open Set hiding restrict restrict_apply open Filter ENNReal open Function (support) open Topology NNReal ENNReal MeasureTheory namespace MeasureTheory variable {α β γ δ : Type} /-- A function `f` from a measurable space to any type is called simple, if every preimage `f ⁻¹' {x}` is measurable, and the range is finite. This structure bundles a function with these properties. -/ structure SimpleFunc.{u, v} (α : Type u) [MeasurableSpace α] (β : Type v) where /-- The underlying function -/ toFun : α → β measurableSet_fiber' : ∀ x, MeasurableSet (toFun ⁻¹' {x}) finite_range' : (Set.range toFun).Finite local infixr:25 " →ₛ " => SimpleFunc namespace SimpleFunc section Measurable variable [MeasurableSpace α] instance instFunLike : FunLike (α →ₛ β) α β where coe := toFun coe_injective' \| ⟨_, _, _⟩, ⟨_, _, _⟩, rfl => rfl theorem coe_injective ⦃f g : α →ₛ β⦄ (H : (f : α → β) = g) : f = g := DFunLike.ext' H @[ext] theorem ext {f g : α →ₛ β} (H : ∀ a, f a = g a) : f = g := DFunLike.ext _ _ H theorem finite_range (f : α →ₛ β) : (Set.range f).Finite := f.finite_range' theorem measurableSet_fiber (f : α →ₛ β) (x : β) : MeasurableSet (f ⁻¹' {x}) := f.measurableSet_fiber' x @[simp] theorem coe_mk (f : α → β) (h h') : ⇑(mk f h h') = f := rfl theorem apply_mk (f : α → β) (h h') (x : α) : SimpleFunc.mk f h h' x = f x := rfl /-- Simple function defined on a finite type. -/ def ofFinite [Finite α] [MeasurableSingletonClass α] (f : α → β) : α →ₛ β where toFun := f measurableSet_fiber' x := (toFinite (f ⁻¹' {x})).measurableSet finite_range' := Set.finite_range f /-- Simple function defined on the empty type. -/ def ofIsEmpty [IsEmpty α] : α →ₛ β := ofFinite isEmptyElim /-- Range of a simple function `α →ₛ β` as a `Finset β`. -/ protected def range (f : α →ₛ β) : Finset β := f.finite_range.toFinset @[simp] theorem mem_range {f : α →ₛ β} {b} : b ∈ f.range ↔ b ∈ range f := Finite.mem_toFinset _ theorem mem_range_self (f : α →ₛ β) (x : α) : f x ∈ f.range := mem_range.2 ⟨x, rfl⟩ @[simp] theorem coe_range (f : α →ₛ β) : (↑f.range : Set β) = Set.range f := f.finite_range.coe_toFinset theorem mem_range_of_measure_ne_zero {f : α →ₛ β} {x : β} {μ : Measure α} (H : μ (f ⁻¹' {x}) ≠ 0) : x ∈ f.range := let ⟨a, ha⟩ := nonempty_of_measure_ne_zero H mem_range.2 ⟨a, ha⟩ theorem forall_mem_range {f : α →ₛ β} {p : β → Prop} : (∀ y ∈ f.range, p y) ↔ ∀ x, p (f x) := by simp only [mem_range, Set.forall_mem_range] theorem exists_range_iff {f : α →ₛ β} {p : β → Prop} : (∃ y ∈ f.range, p y) ↔ ∃ x, p (f x) := by simpa only [mem_range, exists_prop] using Set.exists_range_iff theorem preimage_eq_empty_iff (f : α →ₛ β) (b : β) : f ⁻¹' {b} = ∅ ↔ b ∉ f.range := preimage_singleton_eq_empty.trans <\| not_congr mem_range.symm theorem exists_forall_le [Nonempty β] [Preorder β] [IsDirected β (· ≤ ·)] (f : α →ₛ β) : ∃ C, ∀ x, f x ≤ C := f.range.exists_le.imp fun _ => forall_mem_range.1 /-- Constant function as a `SimpleFunc`. -/ def const (α) {β} [MeasurableSpace α] (b : β) : α →ₛ β := ⟨fun _ => b, fun _ => MeasurableSet.const _, finite_range_const⟩ instance instInhabited [Inhabited β] : Inhabited (α →ₛ β) := ⟨const _ default⟩ theorem const_apply (a : α) (b : β) : (const α b) a = b := rfl @[simp] theorem coe_const (b : β) : ⇑(const α b) = Function.const α b := rfl @[simp] theorem range_const (α) [MeasurableSpace α] [Nonempty α] (b : β) : (const α b).range = {b} := Finset.coe_injective <\| by simp +unfoldPartialApp [Function.const] theorem range_const_subset (α) [MeasurableSpace α] (b : β) : (const α b).range ⊆ {b} := Finset.coe_subset.1 <\| by simp theorem simpleFunc_bot {α} (f : @SimpleFunc α ⊥ β) [Nonempty β] : ∃ c, ∀ x, f x = c := by have hf_meas := @SimpleFunc.measurableSet_fiber α _ ⊥ f simp_rw [MeasurableSpace.measurableSet_bot_iff] at hf_meas exact (exists_eq_const_of_preimage_singleton hf_meas).imp fun c hc ↦ congr_fun hc theorem simpleFunc_bot' {α} [Nonempty β] (f : @SimpleFunc α ⊥ β) : ∃ c, f = @SimpleFunc.const α _ ⊥ c := letI : MeasurableSpace α := ⊥; (simpleFunc_bot f).imp fun _ ↦ ext theorem measurableSet_cut (r : α → β → Prop) (f : α →ₛ β) (h : ∀ b, MeasurableSet { a \| r a b }) : MeasurableSet { a \| r a (f a) } := by have : { a \| r a (f a) } = ⋃ b ∈ range f, { a \| r a b } ∩ f ⁻¹' {b} := by ext a suffices r a (f a) ↔ ∃ i, r a (f i) ∧ f a = f i by simpa exact ⟨fun h => ⟨a, ⟨h, rfl⟩⟩, fun ⟨a', ⟨h', e⟩⟩ => e.symm ▸ h'⟩ rw [this] exact MeasurableSet.biUnion f.finite_range.countable fun b _ => MeasurableSet.inter (h b) (f.measurableSet_fiber _) @[measurability] theorem measurableSet_preimage (f : α →ₛ β) (s) : MeasurableSet (f ⁻¹' s) := measurableSet_cut (fun _ b => b ∈ s) f fun b => MeasurableSet.const (b ∈ s) /-- A simple function is measurable -/ @[measurability, fun_prop] protected theorem measurable [MeasurableSpace β] (f : α →ₛ β) : Measurable f := fun s _ => measurableSet_preimage f s @[measurability] protected theorem aemeasurable [MeasurableSpace β] {μ : Measure α} (f : α →ₛ β) : AEMeasurable f μ := f.measurable.aemeasurable protected theorem sum_measure_preimage_singleton (f : α →ₛ β) {μ : Measure α} (s : Finset β) : (∑ y ∈ s, μ (f ⁻¹' {y})) = μ (f ⁻¹' ↑s) := sum_measure_preimage_singleton _ fun _ _ => f.measurableSet_fiber _ theorem sum_range_measure_preimage_singleton (f : α →ₛ β) (μ : Measure α) : (∑ y ∈ f.range, μ (f ⁻¹' {y})) = μ univ := by rw [f.sum_measure_preimage_singleton, coe_range, preimage_range] open scoped Classical in /-- If-then-else as a `SimpleFunc`. -/ def piecewise (s : Set α) (hs : MeasurableSet s) (f g : α →ₛ β) : α →ₛ β := ⟨s.piecewise f g, fun _ => letI : MeasurableSpace β := ⊤ f.measurable.piecewise hs g.measurable trivial, (f.finite_range.union g.finite_range).subset range_ite_subset⟩ open scoped Classical in @[simp] theorem coe_piecewise {s : Set α} (hs : MeasurableSet s) (f g : α →ₛ β) : ⇑(piecewise s hs f g) = s.piecewise f g := rfl open scoped Classical in theorem piecewise_apply {s : Set α} (hs : MeasurableSet s) (f g : α →ₛ β) (a) : piecewise s hs f g a = if a ∈ s then f a else g a := rfl open scoped Classical in @[simp] theorem piecewise_compl {s : Set α} (hs : MeasurableSet sᶜ) (f g : α →ₛ β) : piecewise sᶜ hs f g = piecewise s hs.of_compl g f := coe_injective <\| by simp [hs] @[simp] theorem piecewise_univ (f g : α →ₛ β) : piecewise univ MeasurableSet.univ f g = f := coe_injective <\| by simp @[simp] theorem piecewise_empty (f g : α →ₛ β) : piecewise ∅ MeasurableSet.empty f g = g := coe_injective <\| by simp open scoped Classical in @[simp] theorem piecewise_same (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) : piecewise s hs f f = f := coe_injective <\| Set.piecewise_same _ _ theorem support_indicator [Zero β] {s : Set α} (hs : MeasurableSet s) (f : α →ₛ β) : Function.support (f.piecewise s hs (SimpleFunc.const α 0)) = s ∩ Function.support f := Set.support_indicator open scoped Classical in theorem range_indicator {s : Set α} (hs : MeasurableSet s) (hs_nonempty : s.Nonempty) (hs_ne_univ : s ≠ univ) (x y : β) : (piecewise s hs (const α x) (const α y)).range = {x, y} := by simp only [← Finset.coe_inj, coe_range, coe_piecewise, range_piecewise, coe_const, Finset.coe_insert, Finset.coe_singleton, hs_nonempty.image_const, (nonempty_compl.2 hs_ne_univ).image_const, singleton_union, Function.const] theorem measurable_bind [MeasurableSpace γ] (f : α →ₛ β) (g : β → α → γ) (hg : ∀ b, Measurable (g b)) : Measurable fun a => g (f a) a := fun s hs => f.measurableSet_cut (fun a b => g b a ∈ s) fun b => hg b hs /-- If `f : α →ₛ β` is a simple function and `g : β → α →ₛ γ` is a family of simple functions, then `f.bind g` binds the first argument of `g` to `f`. In other words, `f.bind g a = g (f a) a`. -/ def bind (f : α →ₛ β) (g : β → α →ₛ γ) : α →ₛ γ := ⟨fun a => g (f a) a, fun c => f.measurableSet_cut (fun a b => g b a = c) fun b => (g b).measurableSet_preimage {c}, (f.finite_range.biUnion fun b _ => (g b).finite_range).subset <\| by rintro _ ⟨a, rfl⟩; simp⟩ @[simp] theorem bind_apply (f : α →ₛ β) (g : β → α →ₛ γ) (a) : f.bind g a = g (f a) a := rfl /-- Given a function `g : β → γ` and a simple function `f : α →ₛ β`, `f.map g` return the simple function `g ∘ f : α →ₛ γ` -/ def map (g : β → γ) (f : α →ₛ β) : α →ₛ γ := bind f (const α ∘ g) theorem map_apply (g : β → γ) (f : α →ₛ β) (a) : f.map g a = g (f a) := rfl theorem map_map (g : β → γ) (h : γ → δ) (f : α →ₛ β) : (f.map g).map h = f.map (h ∘ g) := rfl @[simp] theorem coe_map (g : β → γ) (f : α →ₛ β) : (f.map g : α → γ) = g ∘ f := rfl @[simp] theorem range_map [DecidableEq γ] (g : β → γ) (f : α →ₛ β) : (f.map g).range = f.range.image g := Finset.coe_injective <\| by simp only [coe_range, coe_map, Finset.coe_image, range_comp] @[simp] theorem map_const (g : β → γ) (b : β) : (const α b).map g = const α (g b) := rfl open scoped Classical in theorem map_preimage (f : α →ₛ β) (g : β → γ) (s : Set γ) : f.map g ⁻¹' s = f ⁻¹' ↑{b ∈ f.range \| g b ∈ s} := by simp only [coe_range, sep_mem_eq, coe_map, Finset.coe_filter, ← mem_preimage, inter_comm, preimage_inter_range, ← Finset.mem_coe] exact preimage_comp open scoped Classical in theorem map_preimage_singleton (f : α →ₛ β) (g : β → γ) (c : γ) : f.map g ⁻¹' {c} = f ⁻¹' ↑{b ∈ f.range \| g b = c} := map_preimage _ _ _ /-- Composition of a `SimpleFun` and a measurable function is a `SimpleFunc`. -/ def comp [MeasurableSpace β] (f : β →ₛ γ) (g : α → β) (hgm : Measurable g) : α →ₛ γ where toFun := f ∘ g finite_range' := f.finite_range.subset <\| Set.range_comp_subset_range _ _ measurableSet_fiber' z := hgm (f.measurableSet_fiber z) @[simp] theorem coe_comp [MeasurableSpace β] (f : β →ₛ γ) {g : α → β} (hgm : Measurable g) : ⇑(f.comp g hgm) = f ∘ g := rfl theorem range_comp_subset_range [MeasurableSpace β] (f : β →ₛ γ) {g : α → β} (hgm : Measurable g) : (f.comp g hgm).range ⊆ f.range := Finset.coe_subset.1 <\| by simp only [coe_range, coe_comp, Set.range_comp_subset_range] /-- Extend a `SimpleFunc` along a measurable embedding: `f₁.extend g hg f₂` is the function `F : β →ₛ γ` such that `F ∘ g = f₁` and `F y = f₂ y` whenever `y ∉ range g`. -/ def extend [MeasurableSpace β] (f₁ : α →ₛ γ) (g : α → β) (hg : MeasurableEmbedding g) (f₂ : β →ₛ γ) : β →ₛ γ where toFun := Function.extend g f₁ f₂ finite_range' := (f₁.finite_range.union <\| f₂.finite_range.subset (image_subset_range _ _)).subset (range_extend_subset _ _ _) measurableSet_fiber' := by letI : MeasurableSpace γ := ⊤; haveI : MeasurableSingletonClass γ := ⟨fun _ => trivial⟩ exact fun x => hg.measurable_extend f₁.measurable f₂.measurable (measurableSet_singleton _) @[simp] theorem extend_apply [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g) (f₂ : β →ₛ γ) (x : α) : (f₁.extend g hg f₂) (g x) = f₁ x := hg.injective.extend_apply _ _ _ @[simp] theorem extend_apply' [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g) (f₂ : β →ₛ γ) {y : β} (h : ¬∃ x, g x = y) : (f₁.extend g hg f₂) y = f₂ y := Function.extend_apply' _ _ _ h @[simp] theorem extend_comp_eq' [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g) (f₂ : β →ₛ γ) : f₁.extend g hg f₂ ∘ g = f₁ := funext fun _ => extend_apply _ _ _ _ @[simp] theorem extend_comp_eq [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g) (f₂ : β →ₛ γ) : (f₁.extend g hg f₂).comp g hg.measurable = f₁ := coe_injective <\| extend_comp_eq' _ hg _ /-- If `f` is a simple function taking values in `β → γ` and `g` is another simple function with the same domain and codomain `β`, then `f.seq g = f a (g a)`. -/ def seq (f : α →ₛ β → γ) (g : α →ₛ β) : α →ₛ γ := f.bind fun f => g.map f @[simp] theorem seq_apply (f : α →ₛ β → γ) (g : α →ₛ β) (a : α) : f.seq g a = f a (g a) := rfl /-- Combine two simple functions `f : α →ₛ β` and `g : α →ₛ β` into `fun a => (f a, g a)`. -/ def pair (f : α →ₛ β) (g : α →ₛ γ) : α →ₛ β × γ := (f.map Prod.mk).seq g @[simp] theorem pair_apply (f : α →ₛ β) (g : α →ₛ γ) (a) : pair f g a = (f a, g a) := rfl theorem pair_preimage (f : α →ₛ β) (g : α →ₛ γ) (s : Set β) (t : Set γ) : pair f g ⁻¹' s ×ˢ t = f ⁻¹' s ∩ g ⁻¹' t := rfl -- A special form of `pair_preimage` theorem pair_preimage_singleton (f : α →ₛ β) (g : α →ₛ γ) (b : β) (c : γ) : pair f g ⁻¹' {(b, c)} = f ⁻¹' {b} ∩ g ⁻¹' {c} := by rw [← singleton_prod_singleton] exact pair_preimage _ _ _ _ @[simp] theorem map_fst_pair (f : α →ₛ β) (g : α →ₛ γ) : (f.pair g).map Prod.fst = f := rfl @[simp] theorem map_snd_pair (f : α →ₛ β) (g : α →ₛ γ) : (f.pair g).map Prod.snd = g := rfl @[simp] theorem bind_const (f : α →ₛ β) : f.bind (const α) = f := by ext; simp @[to_additive] instance instOne [One β] : One (α →ₛ β) := ⟨const α 1⟩ @[to_additive] instance instMul [Mul β] : Mul (α →ₛ β) := ⟨fun f g => (f.map (· ·)).seq g⟩ @[to_additive] instance instDiv [Div β] : Div (α →ₛ β) := ⟨fun f g => (f.map (· / ·)).seq g⟩ @[to_additive] instance instInv [Inv β] : Inv (α →ₛ β) := ⟨fun f => f.map Inv.inv⟩ instance instSup [Max β] : Max (α →ₛ β) := ⟨fun f g => (f.map (· ⊔ ·)).seq g⟩ instance instInf [Min β] : Min (α →ₛ β) := ⟨fun f g => (f.map (· ⊓ ·)).seq g⟩ instance instLE [LE β] : LE (α →ₛ β) := ⟨fun f g => ∀ a, f a ≤ g a⟩ @[to_additive (attr := simp)] theorem const_one [One β] : const α (1 : β) = 1 := rfl @[to_additive (attr := simp, norm_cast)] theorem coe_one [One β] : ⇑(1 : α →ₛ β) = 1 := rfl @[to_additive (attr := simp, norm_cast)] theorem coe_mul [Mul β] (f g : α →ₛ β) : ⇑(f * g) = ⇑f * ⇑g := rfl @[to_additive (attr := simp, norm_cast)] theorem coe_inv [Inv β] (f : α →ₛ β) : ⇑(f⁻¹) = (⇑f)⁻¹ := rfl @[to_additive (attr := simp, norm_cast)] theorem coe_div [Div β] (f g : α →ₛ β) : ⇑(f / g) = ⇑f / ⇑g := rfl @[simp, norm_cast] theorem coe_le [LE β] {f g : α →ₛ β} : (f : α → β) ≤ g ↔ f ≤ g := Iff.rfl @[simp, norm_cast] theorem coe_sup [Max β] (f g : α →ₛ β) : ⇑(f ⊔ g) = ⇑f ⊔ ⇑g := rfl @[simp, norm_cast] theorem coe_inf [Min β] (f g : α →ₛ β) : ⇑(f ⊓ g) = ⇑f ⊓ ⇑g := rfl @[to_additive] theorem mul_apply [Mul β] (f g : α →ₛ β) (a : α) : (f * g) a = f a * g a := rfl @[to_additive] theorem div_apply [Div β] (f g : α →ₛ β) (x : α) : (f / g) x = f x / g x := rfl @[to_additive] theorem inv_apply [Inv β] (f : α →ₛ β) (x : α) : f⁻¹ x = (f x)⁻¹ := rfl theorem sup_apply [Max β] (f g : α →ₛ β) (a : α) : (f ⊔ g) a = f a ⊔ g a := rfl theorem inf_apply [Min β] (f g : α →ₛ β) (a : α) : (f ⊓ g) a = f a ⊓ g a := rfl @[to_additive (attr := simp)] theorem range_one [Nonempty α] [One β] : (1 : α →ₛ β).range = {1} := Finset.ext fun x => by simp [eq_comm] @[simp] theorem range_eq_empty_of_isEmpty {β} [hα : IsEmpty α] (f : α →ₛ β) : f.range = ∅ := by rw [← Finset.not_nonempty_iff_eq_empty] by_contra h obtain ⟨y, hy_mem⟩ := h rw [SimpleFunc.mem_range, Set.mem_range] at hy_mem obtain ⟨x, hxy⟩ := hy_mem rw [isEmpty_iff] at hα exact hα x theorem eq_zero_of_mem_range_zero [Zero β] : ∀ {y : β}, y ∈ (0 : α →ₛ β).range → y = 0 := @(forall_mem_range.2 fun _ => rfl) @[to_additive] theorem mul_eq_map₂ [Mul β] (f g : α →ₛ β) : f * g = (pair f g).map fun p : β × β => p.1 * p.2 := rfl theorem sup_eq_map₂ [Max β] (f g : α →ₛ β) : f ⊔ g = (pair f g).map fun p : β × β => p.1 ⊔ p.2 := rfl @[to_additive] theorem const_mul_eq_map [Mul β] (f : α →ₛ β) (b : β) : const α b * f = f.map fun a => b * a := rfl @[to_additive] theorem map_mul [Mul β] [Mul γ] {g : β → γ} (hg : ∀ x y, g (x * y) = g x * g y) (f₁ f₂ : α →ₛ β) : (f₁ * f₂).map g = f₁.map g * f₂.map g := ext fun _ => hg _ _ variable {K : Type} @[to_additive] instance instSMul [SMul K β] : SMul K (α →ₛ β) := ⟨fun k f => f.map (k • ·)⟩ @[to_additive (attr := simp)] theorem coe_smul [SMul K β] (c : K) (f : α →ₛ β) : ⇑(c • f) = c • ⇑f := rfl @[to_additive (attr := simp)] theorem smul_apply [SMul K β] (k : K) (f : α →ₛ β) (a : α) : (k • f) a = k • f a := rfl instance hasNatSMul [AddMonoid β] : SMul ℕ (α →ₛ β) := inferInstance @[to_additive existing hasNatSMul] instance hasNatPow [Monoid β] : Pow (α →ₛ β) ℕ := ⟨fun f n => f.map (· ^ n)⟩ @[simp] theorem coe_pow [Monoid β] (f : α →ₛ β) (n : ℕ) : ⇑(f ^ n) = (⇑f) ^ n := rfl theorem pow_apply [Monoid β] (n : ℕ) (f : α →ₛ β) (a : α) : (f ^ n) a = f a ^ n := rfl instance hasIntPow [DivInvMonoid β] : Pow (α →ₛ β) ℤ := ⟨fun f n => f.map (· ^ n)⟩ @[simp] theorem coe_zpow [DivInvMonoid β] (f : α →ₛ β) (z : ℤ) : ⇑(f ^ z) = (⇑f) ^ z := rfl theorem zpow_apply [DivInvMonoid β] (z : ℤ) (f : α →ₛ β) (a : α) : (f ^ z) a = f a ^ z := rfl -- TODO: work out how to generate these instances with `to_additive`, which gets confused by the -- argument order swap between `coe_smul` and `coe_pow`. section Additive instance instAddMonoid [AddMonoid β] : AddMonoid (α →ₛ β) := Function.Injective.addMonoid (fun f => show α → β from f) coe_injective coe_zero coe_add fun _ _ => coe_smul _ _ instance instAddCommMonoid [AddCommMonoid β] : AddCommMonoid (α →ₛ β) := Function.Injective.addCommMonoid (fun f => show α → β from f) coe_injective coe_zero coe_add fun _ _ => coe_smul _ _ instance instAddGroup [AddGroup β] : AddGroup (α →ₛ β) := Function.Injective.addGroup (fun f => show α → β from f) coe_injective coe_zero coe_add coe_neg coe_sub (fun _ _ => coe_smul _ _) fun _ _ => coe_smul _ _ instance instAddCommGroup [AddCommGroup β] : AddCommGroup (α →ₛ β) := Function.Injective.addCommGroup (fun f => show α → β from f) coe_injective coe_zero coe_add coe_neg coe_sub (fun _ _ => coe_smul _ _) fun _ _ => coe_smul _ _ end Additive @[to_additive existing] instance instMonoid [Monoid β] : Monoid (α →ₛ β) := Function.Injective.monoid (fun f => show α → β from f) coe_injective coe_one coe_mul coe_pow @[to_additive existing] instance instCommMonoid [CommMonoid β] : CommMonoid (α →ₛ β) := Function.Injective.commMonoid (fun f => show α → β from f) coe_injective coe_one coe_mul coe_pow @[to_additive existing] instance instGroup [Group β] : Group (α →ₛ β) := Function.Injective.group (fun f => show α → β from f) coe_injective coe_one coe_mul coe_inv coe_div coe_pow coe_zpow @[to_additive existing] instance instCommGroup [CommGroup β] : CommGroup (α →ₛ β) := Function.Injective.commGroup (fun f => show α → β from f) coe_injective coe_one coe_mul coe_inv coe_div coe_pow coe_zpow instance instModule [Semiring K] [AddCommMonoid β] [Module K β] : Module K (α →ₛ β) := Function.Injective.module K ⟨⟨fun f => show α → β from f, coe_zero⟩, coe_add⟩ coe_injective coe_smul theorem smul_eq_map [SMul K β] (k : K) (f : α →ₛ β) : k • f = f.map (k • ·) := rfl section Preorder variable [Preorder β] {s : Set α} {f f₁ f₂ g g₁ g₂ : α →ₛ β} {hs : MeasurableSet s} instance instPreorder : Preorder (α →ₛ β) := Preorder.lift (⇑) @[norm_cast] lemma coe_le_coe : ⇑f ≤ g ↔ f ≤ g := .rfl @[simp, norm_cast] lemma coe_lt_coe : ⇑f < g ↔ f < g := .rfl @[simp] lemma mk_le_mk {f g : α → β} {hf hg hf' hg'} : mk f hf hf' ≤ mk g hg hg' ↔ f ≤ g := Iff.rfl @[simp] lemma mk_lt_mk {f g : α → β} {hf hg hf' hg'} : mk f hf hf' < mk g hg hg' ↔ f < g := Iff.rfl @[gcongr] protected alias ⟨_, GCongr.mk_le_mk⟩ := mk_le_mk @[gcongr] protected alias ⟨_, GCongr.mk_lt_mk⟩ := mk_lt_mk @[gcongr] protected alias ⟨_, GCongr.coe_le_coe⟩ := coe_le_coe @[gcongr] protected alias ⟨_, GCongr.coe_lt_coe⟩ := coe_lt_coe open scoped Classical in @[gcongr] lemma piecewise_mono (hf : ∀ a ∈ s, f₁ a ≤ f₂ a) (hg : ∀ a ∉ s, g₁ a ≤ g₂ a) : piecewise s hs f₁ g₁ ≤ piecewise s hs f₂ g₂ := Set.piecewise_mono hf hg end Preorder instance instPartialOrder [PartialOrder β] : PartialOrder (α →ₛ β) := { SimpleFunc.instPreorder with le_antisymm := fun _f _g hfg hgf => ext fun a => le_antisymm (hfg a) (hgf a) } instance instOrderBot [LE β] [OrderBot β] : OrderBot (α →ₛ β) where bot := const α ⊥ bot_le _ _ := bot_le instance instOrderTop [LE β] [OrderTop β] : OrderTop (α →ₛ β) where top := const α ⊤ le_top _ _ := le_top @[to_additive] instance [CommMonoid β] [PartialOrder β] [IsOrderedMonoid β] : IsOrderedMonoid (α →ₛ β) where mul_le_mul_left _ _ h _ _ := mul_le_mul_left' (h _) _ instance instSemilatticeInf [SemilatticeInf β] : SemilatticeInf (α →ₛ β) := { SimpleFunc.instPartialOrder with inf := (· ⊓ ·) inf_le_left := fun _ _ _ => inf_le_left inf_le_right := fun _ _ _ => inf_le_right le_inf := fun _f _g _h hfh hgh a => le_inf (hfh a) (hgh a) } instance instSemilatticeSup [SemilatticeSup β] : SemilatticeSup (α →ₛ β) := { SimpleFunc.instPartialOrder with sup := (· ⊔ ·) le_sup_left := fun _ _ _ => le_sup_left le_sup_right := fun _ _ _ => le_sup_right sup_le := fun _f _g _h hfh hgh a => sup_le (hfh a) (hgh a) } instance instLattice [Lattice β] : Lattice (α →ₛ β) := { SimpleFunc.instSemilatticeSup, SimpleFunc.instSemilatticeInf with } instance instBoundedOrder [LE β] [BoundedOrder β] : BoundedOrder (α →ₛ β) := { SimpleFunc.instOrderBot, SimpleFunc.instOrderTop with } theorem finset_sup_apply [SemilatticeSup β] [OrderBot β] {f : γ → α →ₛ β} (s : Finset γ) (a : α) : s.sup f a = s.sup fun c => f c a := by classical refine Finset.induction_on s rfl ?_ intro a s _ ih rw [Finset.sup_insert, Finset.sup_insert, sup_apply, ih] section Restrict variable [Zero β] open scoped Classical in /-- Restrict a simple function `f : α →ₛ β` to a set `s`. If `s` is measurable, then `f.restrict s a = if a ∈ s then f a else 0`, otherwise `f.restrict s = const α 0`. -/ def restrict (f : α →ₛ β) (s : Set α) : α →ₛ β := if hs : MeasurableSet s then piecewise s hs f 0 else 0 theorem restrict_of_not_measurable {f : α →ₛ β} {s : Set α} (hs : ¬MeasurableSet s) : restrict f s = 0 := dif_neg hs @[simp] theorem coe_restrict (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) : ⇑(restrict f s) = indicator s f := by classical rw [restrict, dif_pos hs, coe_piecewise, coe_zero, piecewise_eq_indicator] @[simp] theorem restrict_univ (f : α →ₛ β) : restrict f univ = f := by simp [restrict] @[simp] theorem restrict_empty (f : α →ₛ β) : restrict f ∅ = 0 := by simp [restrict] open scoped Classical in theorem map_restrict_of_zero [Zero γ] {g : β → γ} (hg : g 0 = 0) (f : α →ₛ β) (s : Set α) : (f.restrict s).map g = (f.map g).restrict s := ext fun x => if hs : MeasurableSet s then by simp [hs, Set.indicator_comp_of_zero hg] else by simp [restrict_of_not_measurable hs, hg] theorem map_coe_ennreal_restrict (f : α →ₛ ℝ≥0) (s : Set α) : (f.restrict s).map ((↑) : ℝ≥0 → ℝ≥0∞) = (f.map (↑)).restrict s := map_restrict_of_zero ENNReal.coe_zero _ _ theorem map_coe_nnreal_restrict (f : α →ₛ ℝ≥0) (s : Set α) : (f.restrict s).map ((↑) : ℝ≥0 → ℝ) = (f.map (↑)).restrict s := map_restrict_of_zero NNReal.coe_zero _ _ theorem restrict_apply (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) (a) : restrict f s a = indicator s f a := by simp only [f.coe_restrict hs] theorem restrict_preimage (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) {t : Set β} (ht : (0 : β) ∉ t) : restrict f s ⁻¹' t = s ∩ f ⁻¹' t := by simp [hs, indicator_preimage_of_not_mem _ _ ht, inter_comm] theorem restrict_preimage_singleton (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) {r : β} (hr : r ≠ 0) : restrict f s ⁻¹' {r} = s ∩ f ⁻¹' {r} := f.restrict_preimage hs hr.symm theorem mem_restrict_range {r : β} {s : Set α} {f : α →ₛ β} (hs : MeasurableSet s) : r ∈ (restrict f s).range ↔ r = 0 ∧ s ≠ univ ∨ r ∈ f '' s := by rw [← Finset.mem_coe, coe_range, coe_restrict _ hs, mem_range_indicator] open scoped Classical in theorem mem_image_of_mem_range_restrict {r : β} {s : Set α} {f : α →ₛ β} (hr : r ∈ (restrict f s).range) (h0 : r ≠ 0) : r ∈ f '' s := if hs : MeasurableSet s then by simpa [mem_restrict_range hs, h0, -mem_range] using hr else by rw [restrict_of_not_measurable hs] at hr exact (h0 <\| eq_zero_of_mem_range_zero hr).elim open scoped Classical in @[gcongr, mono] theorem restrict_mono [Preorder β] (s : Set α) {f g : α →ₛ β} (H : f ≤ g) : f.restrict s ≤ g.restrict s := if hs : MeasurableSet s then fun x => by simp only [coe_restrict _ hs, indicator_le_indicator (H x)] else by simp only [restrict_of_not_measurable hs, le_refl] end Restrict section Approx section variable [SemilatticeSup β] [OrderBot β] [Zero β] /-- Fix a sequence `i : ℕ → β`. Given a function `α → β`, its `n`-th approximation by simple functions is defined so that in case `β = ℝ≥0∞` it sends each `a` to the supremum of the set `{i k \| k ≤ n ∧ i k ≤ f a}`, see `approx_apply` and `iSup_approx_apply` for details. -/ def approx (i : ℕ → β) (f : α → β) (n : ℕ) : α →ₛ β := (Finset.range n).sup fun k => restrict (const α (i k)) { a : α \| i k ≤ f a } open scoped Classical in theorem approx_apply [TopologicalSpace β] [OrderClosedTopology β] [MeasurableSpace β] [OpensMeasurableSpace β] {i : ℕ → β} {f : α → β} {n : ℕ} (a : α) (hf : Measurable f) : (approx i f n : α →ₛ β) a = (Finset.range n).sup fun k => if i k ≤ f a then i k else 0 := by dsimp only [approx] rw [finset_sup_apply] congr funext k rw [restrict_apply] · simp only [coe_const, mem_setOf_eq, indicator_apply, Function.const_apply] · exact hf measurableSet_Ici theorem monotone_approx (i : ℕ → β) (f : α → β) : Monotone (approx i f) := fun _ _ h => Finset.sup_mono <\| Finset.range_subset.2 h theorem approx_comp [TopologicalSpace β] [OrderClosedTopology β] [MeasurableSpace β] [OpensMeasurableSpace β] [MeasurableSpace γ] {i : ℕ → β} {f : γ → β} {g : α → γ} {n : ℕ} (a : α) (hf : Measurable f) (hg : Measurable g) : (approx i (f ∘ g) n : α →ₛ β) a = (approx i f n : γ →ₛ β) (g a) := by rw [approx_apply _ hf, approx_apply _ (hf.comp hg), Function.comp_apply] end theorem iSup_approx_apply [TopologicalSpace β] [CompleteLattice β] [OrderClosedTopology β] [Zero β] [MeasurableSpace β] [OpensMeasurableSpace β] (i : ℕ → β) (f : α → β) (a : α) (hf : Measurable f) (h_zero : (0 : β) = ⊥) : ⨆ n, (approx i f n : α →ₛ β) a = ⨆ (k) (_ : i k ≤ f a), i k := by refine le_antisymm (iSup_le fun n => ?_) (iSup_le fun k => iSup_le fun hk => ?_) · rw [approx_apply a hf, h_zero] refine Finset.sup_le fun k _ => ?_ split_ifs with h · exact le_iSup_of_le k (le_iSup (fun _ : i k ≤ f a => i k) h) · exact bot_le · refine le_iSup_of_le (k + 1) ?_ rw [approx_apply a hf] have : k ∈ Finset.range (k + 1) := Finset.mem_range.2 (Nat.lt_succ_self _) refine le_trans (le_of_eq ?_) (Finset.le_sup this) rw [if_pos hk] end Approx section EApprox variable {f : α → ℝ≥0∞} /-- A sequence of `ℝ≥0∞`s such that its range is the set of non-negative rational numbers. -/ def ennrealRatEmbed (n : ℕ) : ℝ≥0∞ := ENNReal.ofReal ((Encodable.decode (α := ℚ) n).getD (0 : ℚ)) theorem ennrealRatEmbed_encode (q : ℚ) : ennrealRatEmbed (Encodable.encode q) = Real.toNNReal q := by rw [ennrealRatEmbed, Encodable.encodek]; rfl /-- Approximate a function `α → ℝ≥0∞` by a sequence of simple functions. -/ def eapprox : (α → ℝ≥0∞) → ℕ → α →ₛ ℝ≥0∞ := approx ennrealRatEmbed theorem eapprox_lt_top (f : α → ℝ≥0∞) (n : ℕ) (a : α) : eapprox f n a < ∞ := by simp only [eapprox, approx, finset_sup_apply, Finset.mem_range, ENNReal.bot_eq_zero, restrict] rw [Finset.sup_lt_iff (α := ℝ≥0∞) WithTop.top_pos] intro b _ split_ifs · simp only [coe_zero, coe_piecewise, piecewise_eq_indicator, coe_const] calc { a : α \| ennrealRatEmbed b ≤ f a }.indicator (fun _ => ennrealRatEmbed b) a ≤ ennrealRatEmbed b := indicator_le_self _ _ a _ < ⊤ := ENNReal.coe_lt_top · exact WithTop.top_pos @[mono] theorem monotone_eapprox (f : α → ℝ≥0∞) : Monotone (eapprox f) := monotone_approx _ f @[gcongr] lemma eapprox_mono {m n : ℕ} (hmn : m ≤ n) : eapprox f m ≤ eapprox f n := monotone_eapprox _ hmn lemma iSup_eapprox_apply (hf : Measurable f) (a : α) : ⨆ n, (eapprox f n : α →ₛ ℝ≥0∞) a = f a := by rw [eapprox, iSup_approx_apply ennrealRatEmbed f a hf rfl] refine le_antisymm (iSup_le fun i => iSup_le fun hi => hi) (le_of_not_gt ?_) intro h rcases ENNReal.lt_iff_exists_rat_btwn.1 h with ⟨q, _, lt_q, q_lt⟩ have : (Real.toNNReal q : ℝ≥0∞) ≤ ⨆ (k : ℕ) (_ : ennrealRatEmbed k ≤ f a), ennrealRatEmbed k := by refine le_iSup_of_le (Encodable.encode q) ?_ rw [ennrealRatEmbed_encode q] exact le_iSup_of_le (le_of_lt q_lt) le_rfl exact lt_irrefl _ (lt_of_le_of_lt this lt_q) lemma iSup_coe_eapprox (hf : Measurable f) : ⨆ n, ⇑(eapprox f n) = f := by simpa [funext_iff] using iSup_eapprox_apply hf theorem eapprox_comp [MeasurableSpace γ] {f : γ → ℝ≥0∞} {g : α → γ} {n : ℕ} (hf : Measurable f) (hg : Measurable g) : (eapprox (f ∘ g) n : α → ℝ≥0∞) = (eapprox f n : γ →ₛ ℝ≥0∞) ∘ g := funext fun a => approx_comp a hf hg lemma tendsto_eapprox {f : α → ℝ≥0∞} (hf_meas : Measurable f) (a : α) : Tendsto (fun n ↦ eapprox f n a) atTop (𝓝 (f a)) := by nth_rw 2 [← iSup_coe_eapprox hf_meas] rw [iSup_apply] exact tendsto_atTop_iSup fun _ _ hnm ↦ monotone_eapprox f hnm a /-- Approximate a function `α → ℝ≥0∞` by a series of simple functions taking their values in `ℝ≥0`. -/ def eapproxDiff (f : α → ℝ≥0∞) : ℕ → α →ₛ ℝ≥0 \| 0 => (eapprox f 0).map ENNReal.toNNReal \| n + 1 => (eapprox f (n + 1) - eapprox f n).map ENNReal.toNNReal theorem sum_eapproxDiff (f : α → ℝ≥0∞) (n : ℕ) (a : α) : (∑ k ∈ Finset.range (n + 1), (eapproxDiff f k a : ℝ≥0∞)) = eapprox f n a := by induction' n with n IH · simp only [Nat.zero_add, Finset.sum_singleton, Finset.range_one] rfl · rw [Finset.sum_range_succ, IH, eapproxDiff, coe_map, Function.comp_apply, coe_sub, Pi.sub_apply, ENNReal.coe_toNNReal, add_tsub_cancel_of_le (monotone_eapprox f (Nat.le_succ _) _)] apply (lt_of_le_of_lt _ (eapprox_lt_top f (n + 1) a)).ne rw [tsub_le_iff_right] exact le_self_add theorem tsum_eapproxDiff (f : α → ℝ≥0∞) (hf : Measurable f) (a : α) : (∑' n, (eapproxDiff f n a : ℝ≥0∞)) = f a := by simp_rw [ENNReal.tsum_eq_iSup_nat' (tendsto_add_atTop_nat 1), sum_eapproxDiff, iSup_eapprox_apply hf a] end EApprox end Measurable section Measure variable {m : MeasurableSpace α} {μ ν : Measure α} /-- Integral of a simple function whose codomain is `ℝ≥0∞`. -/ def lintegral {_m : MeasurableSpace α} (f : α →ₛ ℝ≥0∞) (μ : Measure α) : ℝ≥0∞ := ∑ x ∈ f.range, x μ (f ⁻¹' {x}) theorem lintegral_eq_of_subset (f : α →ₛ ℝ≥0∞) {s : Finset ℝ≥0∞} (hs : ∀ x, f x ≠ 0 → μ (f ⁻¹' {f x}) ≠ 0 → f x ∈ s) : f.lintegral μ = ∑ x ∈ s, x * μ (f ⁻¹' {x}) := by refine Finset.sum_bij_ne_zero (fun r _ _ => r) ?_ ?_ ?_ ?_ · simpa only [forall_mem_range, mul_ne_zero_iff, and_imp] · intros assumption · intro b _ hb refine ⟨b, ?_, hb, rfl⟩ rw [mem_range, ← preimage_singleton_nonempty] exact nonempty_of_measure_ne_zero (mul_ne_zero_iff.1 hb).2 · intros rfl theorem lintegral_eq_of_subset' (f : α →ₛ ℝ≥0∞) {s : Finset ℝ≥0∞} (hs : f.range \ {0} ⊆ s) : f.lintegral μ = ∑ x ∈ s, x * μ (f ⁻¹' {x}) := f.lintegral_eq_of_subset fun x hfx _ => hs <\| Finset.mem_sdiff.2 ⟨f.mem_range_self x, mt Finset.mem_singleton.1 hfx⟩ /-- Calculate the integral of `(g ∘ f)`, where `g : β → ℝ≥0∞` and `f : α →ₛ β`. -/ theorem map_lintegral (g : β → ℝ≥0∞) (f : α →ₛ β) : (f.map g).lintegral μ = ∑ x ∈ f.range, g x * μ (f ⁻¹' {x}) := by simp only [lintegral, range_map] refine Finset.sum_image' _ fun b hb => ?_ rcases mem_range.1 hb with ⟨a, rfl⟩ rw [map_preimage_singleton, ← f.sum_measure_preimage_singleton, Finset.mul_sum] refine Finset.sum_congr ?_ ?_ · congr · intro x simp only [Finset.mem_filter] rintro ⟨_, h⟩ rw [h] theorem add_lintegral (f g : α →ₛ ℝ≥0∞) : (f + g).lintegral μ = f.lintegral μ + g.lintegral μ := calc (f + g).lintegral μ = ∑ x ∈ (pair f g).range, (x.1 * μ (pair f g ⁻¹' {x}) + x.2 * μ (pair f g ⁻¹' {x})) := by rw [add_eq_map₂, map_lintegral]; exact Finset.sum_congr rfl fun a _ => add_mul _ _ _ _ = (∑ x ∈ (pair f g).range, x.1 * μ (pair f g ⁻¹' {x})) + ∑ x ∈ (pair f g).range, x.2 * μ (pair f g ⁻¹' {x}) := by rw [Finset.sum_add_distrib] _ = ((pair f g).map Prod.fst).lintegral μ + ((pair f g).map Prod.snd).lintegral μ := by rw [map_lintegral, map_lintegral] _ = lintegral f μ + lintegral g μ := rfl theorem const_mul_lintegral (f : α →ₛ ℝ≥0∞) (x : ℝ≥0∞) : (const α x * f).lintegral μ = x * f.lintegral μ := calc (f.map fun a => x * a).lintegral μ = ∑ r ∈ f.range, x * r * μ (f ⁻¹' {r}) := map_lintegral _ _ _ = x * ∑ r ∈ f.range, r * μ (f ⁻¹' {r}) := by simp_rw [Finset.mul_sum, mul_assoc] /-- Integral of a simple function `α →ₛ ℝ≥0∞` as a bilinear map. -/ def lintegralₗ {m : MeasurableSpace α} : (α →ₛ ℝ≥0∞) →ₗ[ℝ≥0∞] Measure α →ₗ[ℝ≥0∞] ℝ≥0∞ where toFun f := { toFun := lintegral f map_add' := by simp [lintegral, mul_add, Finset.sum_add_distrib] map_smul' := fun c μ => by simp [lintegral, mul_left_comm _ c, Finset.mul_sum, Measure.smul_apply c] } map_add' f g := LinearMap.ext fun _ => add_lintegral f g map_smul' c f := LinearMap.ext fun _ => const_mul_lintegral f c @[simp] theorem zero_lintegral : (0 : α →ₛ ℝ≥0∞).lintegral μ = 0 := LinearMap.ext_iff.1 lintegralₗ.map_zero μ theorem lintegral_add {ν} (f : α →ₛ ℝ≥0∞) : f.lintegral (μ + ν) = f.lintegral μ + f.lintegral ν := (lintegralₗ f).map_add μ ν theorem lintegral_smul {R : Type} [SMul R ℝ≥0∞] [IsScalarTower R ℝ≥0∞ ℝ≥0∞] (f : α →ₛ ℝ≥0∞) (c : R) : f.lintegral (c • μ) = c • f.lintegral μ := by simpa only [smul_one_smul] using (lintegralₗ f).map_smul (c • 1) μ @[simp] theorem lintegral_zero [MeasurableSpace α] (f : α →ₛ ℝ≥0∞) : f.lintegral 0 = 0 := (lintegralₗ f).map_zero theorem lintegral_finset_sum {ι} (f : α →ₛ ℝ≥0∞) (μ : ι → Measure α) (s : Finset ι) : f.lintegral (∑ i ∈ s, μ i) = ∑ i ∈ s, f.lintegral (μ i) := map_sum (lintegralₗ f) .. theorem lintegral_sum {m : MeasurableSpace α} {ι} (f : α →ₛ ℝ≥0∞) (μ : ι → Measure α) : f.lintegral (Measure.sum μ) = ∑' i, f.lintegral (μ i) := by simp only [lintegral, Measure.sum_apply, f.measurableSet_preimage, ← Finset.tsum_subtype, ← ENNReal.tsum_mul_left] apply ENNReal.tsum_comm open scoped Classical in theorem restrict_lintegral (f : α →ₛ ℝ≥0∞) {s : Set α} (hs : MeasurableSet s) : (restrict f s).lintegral μ = ∑ r ∈ f.range, r μ (f ⁻¹' {r} ∩ s) := calc (restrict f s).lintegral μ = ∑ r ∈ f.range, r * μ (restrict f s ⁻¹' {r}) := lintegral_eq_of_subset _ fun x hx => if hxs : x ∈ s then fun _ => by simp only [f.restrict_apply hs, indicator_of_mem hxs, mem_range_self] else False.elim <\| hx <\| by simp [] _ = ∑ r ∈ f.range, r μ (f ⁻¹' {r} ∩ s) := Finset.sum_congr rfl <\| forall_mem_range.2 fun b => if hb : f b = 0 then by simp only [hb, zero_mul] else by rw [restrict_preimage_singleton _ hs hb, inter_comm] theorem lintegral_restrict {m : MeasurableSpace α} (f : α →ₛ ℝ≥0∞) (s : Set α) (μ : Measure α) : f.lintegral (μ.restrict s) = ∑ y ∈ f.range, y * μ (f ⁻¹' {y} ∩ s) := by simp only [lintegral, Measure.restrict_apply, f.measurableSet_preimage] theorem restrict_lintegral_eq_lintegral_restrict (f : α →ₛ ℝ≥0∞) {s : Set α} (hs : MeasurableSet s) : (restrict f s).lintegral μ = f.lintegral (μ.restrict s) := by rw [f.restrict_lintegral hs, lintegral_restrict] theorem lintegral_restrict_iUnion_of_directed {ι : Type} [Countable ι] (f : α →ₛ ℝ≥0∞) {s : ι → Set α} (hd : Directed (· ⊆ ·) s) (μ : Measure α) : f.lintegral (μ.restrict (⋃ i, s i)) = ⨆ i, f.lintegral (μ.restrict (s i)) := by simp only [lintegral, Measure.restrict_iUnion_apply_eq_iSup hd (measurableSet_preimage ..), ENNReal.mul_iSup] refine finsetSum_iSup fun i j ↦ (hd i j).imp fun k ⟨hik, hjk⟩ ↦ fun a ↦ ?_ -- TODO https://github.com/leanprover-community/mathlib4/pull/14739 make `gcongr` close this goal constructor <;> · gcongr; refine Measure.restrict_mono ?_ le_rfl _; assumption theorem const_lintegral (c : ℝ≥0∞) : (const α c).lintegral μ = c μ univ := by rw [lintegral] cases isEmpty_or_nonempty α · simp [μ.eq_zero_of_isEmpty] · simp only [range_const, coe_const, Finset.sum_singleton] unfold Function.const; rw [preimage_const_of_mem (mem_singleton c)] theorem const_lintegral_restrict (c : ℝ≥0∞) (s : Set α) : (const α c).lintegral (μ.restrict s) = c * μ s := by rw [const_lintegral, Measure.restrict_apply MeasurableSet.univ, univ_inter] theorem restrict_const_lintegral (c : ℝ≥0∞) {s : Set α} (hs : MeasurableSet s) : ((const α c).restrict s).lintegral μ = c * μ s := by rw [restrict_lintegral_eq_lintegral_restrict _ hs, const_lintegral_restrict] @[gcongr] theorem lintegral_mono_fun {f g : α →ₛ ℝ≥0∞} (h : f ≤ g) : f.lintegral μ ≤ g.lintegral μ := by refine Monotone.of_left_le_map_sup (f := (lintegral · μ)) (fun f g ↦ ?_) h calc f.lintegral μ = ((pair f g).map Prod.fst).lintegral μ := by rw [map_fst_pair] _ ≤ ((pair f g).map fun p ↦ p.1 ⊔ p.2).lintegral μ := by simp only [map_lintegral] gcongr exact le_sup_left theorem le_sup_lintegral (f g : α →ₛ ℝ≥0∞) : f.lintegral μ ⊔ g.lintegral μ ≤ (f ⊔ g).lintegral μ := Monotone.le_map_sup (fun _ _ ↦ lintegral_mono_fun) f g @[gcongr] theorem lintegral_mono_measure {f : α →ₛ ℝ≥0∞} (h : μ ≤ ν) : f.lintegral μ ≤ f.lintegral ν := by simp only [lintegral] gcongr apply h /-- `SimpleFunc.lintegral` is monotone both in function and in measure. -/ @[mono, gcongr] theorem lintegral_mono {f g : α →ₛ ℝ≥0∞} (hfg : f ≤ g) (hμν : μ ≤ ν) : f.lintegral μ ≤ g.lintegral ν := (lintegral_mono_fun hfg).trans (lintegral_mono_measure hμν) /-- `SimpleFunc.lintegral` depends only on the measures of `f ⁻¹' {y}`. -/ theorem lintegral_eq_of_measure_preimage [MeasurableSpace β] {f : α →ₛ ℝ≥0∞} {g : β →ₛ ℝ≥0∞} {ν : Measure β} (H : ∀ y, μ (f ⁻¹' {y}) = ν (g ⁻¹' {y})) : f.lintegral μ = g.lintegral ν := by simp only [lintegral, ← H] apply lintegral_eq_of_subset simp only [H] intros exact mem_range_of_measure_ne_zero ‹_› /-- If two simple functions are equal a.e., then their `lintegral`s are equal. -/ theorem lintegral_congr {f g : α →ₛ ℝ≥0∞} (h : f =ᵐ[μ] g) : f.lintegral μ = g.lintegral μ := lintegral_eq_of_measure_preimage fun y => measure_congr <\| Eventually.set_eq <\| h.mono fun x hx => by simp [hx] theorem lintegral_map' {β} [MeasurableSpace β] {μ' : Measure β} (f : α →ₛ ℝ≥0∞) (g : β →ₛ ℝ≥0∞) (m' : α → β) (eq : ∀ a, f a = g (m' a)) (h : ∀ s, MeasurableSet s → μ' s = μ (m' ⁻¹' s)) : f.lintegral μ = g.lintegral μ' := lintegral_eq_of_measure_preimage fun y => by simp only [preimage, eq] exact (h (g ⁻¹' {y}) (g.measurableSet_preimage _)).symm theorem lintegral_map {β} [MeasurableSpace β] (g : β →ₛ ℝ≥0∞) {f : α → β} (hf : Measurable f) : g.lintegral (Measure.map f μ) = (g.comp f hf).lintegral μ := Eq.symm <\| lintegral_map' _ _ f (fun _ => rfl) fun _s hs => Measure.map_apply hf hs end Measure section FinMeasSupp open Finset Function open scoped Classical in theorem support_eq [MeasurableSpace α] [Zero β] (f : α →ₛ β) : support f = ⋃ y ∈ {y ∈ f.range \| y ≠ 0}, f ⁻¹' {y} := Set.ext fun x => by simp only [mem_support, Set.mem_preimage, mem_filter, mem_range_self, true_and, exists_prop, mem_iUnion, Set.mem_range, mem_singleton_iff, exists_eq_right'] variable {m : MeasurableSpace α} [Zero β] [Zero γ] {μ : Measure α} {f : α →ₛ β} theorem measurableSet_support [MeasurableSpace α] (f : α →ₛ β) : MeasurableSet (support f) := by rw [f.support_eq] exact Finset.measurableSet_biUnion _ fun y _ => measurableSet_fiber _ _ lemma measure_support_lt_top (f : α →ₛ β) (hf : ∀ y, y ≠ 0 → μ (f ⁻¹' {y}) < ∞) : μ (support f) < ∞ := by classical rw [support_eq] refine (measure_biUnion_finset_le _ _).trans_lt (ENNReal.sum_lt_top.mpr fun y hy => ?_) rw [Finset.mem_filter] at hy exact hf y hy.2 /-- A `SimpleFunc` has finite measure support if it is equal to `0` outside of a set of finite measure. -/ protected def FinMeasSupp {_m : MeasurableSpace α} (f : α →ₛ β) (μ : Measure α) : Prop := f =ᶠ[μ.cofinite] 0 theorem finMeasSupp_iff_support : f.FinMeasSupp μ ↔ μ (support f) < ∞ := Iff.rfl theorem finMeasSupp_iff : f.FinMeasSupp μ ↔ ∀ y, y ≠ 0 → μ (f ⁻¹' {y}) < ∞ := by classical constructor · refine fun h y hy => lt_of_le_of_lt (measure_mono ?_) h exact fun x hx (H : f x = 0) => hy <\| H ▸ Eq.symm hx · intro H rw [finMeasSupp_iff_support, support_eq] exact measure_biUnion_lt_top (finite_toSet _) fun y hy ↦ H y (mem_filter.1 hy).2 namespace FinMeasSupp theorem meas_preimage_singleton_ne_zero (h : f.FinMeasSupp μ) {y : β} (hy : y ≠ 0) : μ (f ⁻¹' {y}) < ∞ := finMeasSupp_iff.1 h y hy protected theorem map {g : β → γ} (hf : f.FinMeasSupp μ) (hg : g 0 = 0) : (f.map g).FinMeasSupp μ := flip lt_of_le_of_lt hf (measure_mono <\| support_comp_subset hg f) theorem of_map {g : β → γ} (h : (f.map g).FinMeasSupp μ) (hg : ∀ b, g b = 0 → b = 0) : f.FinMeasSupp μ := flip lt_of_le_of_lt h <\| measure_mono <\| support_subset_comp @(hg) _ theorem map_iff {g : β → γ} (hg : ∀ {b}, g b = 0 ↔ b = 0) : (f.map g).FinMeasSupp μ ↔ f.FinMeasSupp μ := ⟨fun h => h.of_map fun _ => hg.1, fun h => h.map <\| hg.2 rfl⟩ protected theorem pair {g : α →ₛ γ} (hf : f.FinMeasSupp μ) (hg : g.FinMeasSupp μ) : (pair f g).FinMeasSupp μ := calc μ (support <\| pair f g) = μ (support f ∪ support g) := congr_arg μ <\| support_prod_mk f g _ ≤ μ (support f) + μ (support g) := measure_union_le _ _ _ < _ := add_lt_top.2 ⟨hf, hg⟩ protected theorem map₂ [Zero δ] (hf : f.FinMeasSupp μ) {g : α →ₛ γ} (hg : g.FinMeasSupp μ) {op : β → γ → δ} (H : op 0 0 = 0) : ((pair f g).map (Function.uncurry op)).FinMeasSupp μ := (hf.pair hg).map H protected theorem add {β} [AddZeroClass β] {f g : α →ₛ β} (hf : f.FinMeasSupp μ) (hg : g.FinMeasSupp μ) : (f + g).FinMeasSupp μ := by rw [add_eq_map₂] exact hf.map₂ hg (zero_add 0) protected theorem mul {β} [MulZeroClass β] {f g : α →ₛ β} (hf : f.FinMeasSupp μ) (hg : g.FinMeasSupp μ) : (f * g).FinMeasSupp μ := by rw [mul_eq_map₂] exact hf.map₂ hg (zero_mul 0) theorem lintegral_lt_top {f : α →ₛ ℝ≥0∞} (hm : f.FinMeasSupp μ) (hf : ∀ᵐ a ∂μ, f a ≠ ∞) : f.lintegral μ < ∞ := by refine sum_lt_top.2 fun a ha => ?_ rcases eq_or_ne a ∞ with (rfl \| ha) · simp only [ae_iff, Ne, Classical.not_not] at hf simp [Set.preimage, hf] · by_cases ha0 : a = 0 · subst a simp · exact mul_lt_top ha.lt_top (finMeasSupp_iff.1 hm _ ha0) theorem of_lintegral_ne_top {f : α →ₛ ℝ≥0∞} (h : f.lintegral μ ≠ ∞) : f.FinMeasSupp μ := by refine finMeasSupp_iff.2 fun b hb => ?_ rw [f.lintegral_eq_of_subset' (Finset.subset_insert b _)] at h refine ENNReal.lt_top_of_mul_ne_top_right ?_ hb exact (lt_top_of_sum_ne_top h (Finset.mem_insert_self _ _)).ne theorem iff_lintegral_lt_top {f : α →ₛ ℝ≥0∞} (hf : ∀ᵐ a ∂μ, f a ≠ ∞) : f.FinMeasSupp μ ↔ f.lintegral μ < ∞ :=	⟨fun h => h.lintegral_lt_top hf, fun h => of_lintegral_ne_top h.ne⟩ end FinMeasSupp lemma measure_support_lt_top_of_lintegral_ne_top {f : α →ₛ ℝ≥0∞} (hf : f.lintegral μ ≠ ∞) : μ (support f) < ∞ := by refine measure_support_lt_top f ?_	Mathlib/MeasureTheory/Function/SimpleFunc.lean	1,128	1,134
/- Copyright (c) 2019 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin, Kenny Lau -/ import Mathlib.Algebra.Order.Antidiag.Finsupp import Mathlib.Data.Finsupp.Weight import Mathlib.Tactic.Linarith import Mathlib.LinearAlgebra.Pi import Mathlib.Algebra.MvPolynomial.Eval /-! # Formal (multivariate) power series This file defines multivariate formal power series and develops the basic properties of these objects. A formal power series is to a polynomial like an infinite sum is to a finite sum. We provide the natural inclusion from multivariate polynomials to multivariate formal power series. ## Main definitions - `MvPowerSeries.C`: constant power series - `MvPowerSeries.X`: the indeterminates - `MvPowerSeries.coeff`, `MvPowerSeries.constantCoeff`: the coefficients of a `MvPowerSeries`, its constant coefficient - `MvPowerSeries.monomial`: the monomials - `MvPowerSeries.coeff_mul`: computes the coefficients of the product of two `MvPowerSeries` - `MvPowerSeries.coeff_prod` : computes the coefficients of products of `MvPowerSeries` - `MvPowerSeries.coeff_pow` : computes the coefficients of powers of a `MvPowerSeries` - `MvPowerSeries.coeff_eq_zero_of_constantCoeff_nilpotent`: if the constant coefficient of a `MvPowerSeries` is nilpotent, then some coefficients of its powers are automatically zero - `MvPowerSeries.map`: apply a `RingHom` to the coefficients of a `MvPowerSeries` (as a `RingHom) - `MvPowerSeries.X_pow_dvd_iff`, `MvPowerSeries.X_dvd_iff`: equivalent conditions for (a power of) an indeterminate to divide a `MvPowerSeries` - `MvPolynomial.toMvPowerSeries`: the canonical coercion from `MvPolynomial` to `MvPowerSeries` ## Note This file sets up the (semi)ring structure on multivariate power series: additional results are in: * `Mathlib.RingTheory.MvPowerSeries.Inverse` : invertibility, formal power series over a local ring form a local ring; * `Mathlib.RingTheory.MvPowerSeries.Trunc`: truncation of power series. In `Mathlib.RingTheory.PowerSeries.Basic`, formal power series in one variable will be obtained as a particular case, defined by `PowerSeries R := MvPowerSeries Unit R`. See that file for a specific description. ## Implementation notes In this file we define multivariate formal power series with variables indexed by `σ` and coefficients in `R` as `MvPowerSeries σ R := (σ →₀ ℕ) → R`. Unfortunately there is not yet enough API to show that they are the completion of the ring of multivariate polynomials. However, we provide most of the infrastructure that is needed to do this. Once I-adic completion (topological or algebraic) is available it should not be hard to fill in the details. -/ noncomputable section open Finset (antidiagonal mem_antidiagonal) /-- Multivariate formal power series, where `σ` is the index set of the variables and `R` is the coefficient ring. -/ def MvPowerSeries (σ : Type) (R : Type) := (σ →₀ ℕ) → R namespace MvPowerSeries open Finsupp variable {σ R : Type} instance [Inhabited R] : Inhabited (MvPowerSeries σ R) := ⟨fun _ => default⟩ instance [Zero R] : Zero (MvPowerSeries σ R) := Pi.instZero instance [AddMonoid R] : AddMonoid (MvPowerSeries σ R) := Pi.addMonoid instance [AddGroup R] : AddGroup (MvPowerSeries σ R) := Pi.addGroup instance [AddCommMonoid R] : AddCommMonoid (MvPowerSeries σ R) := Pi.addCommMonoid instance [AddCommGroup R] : AddCommGroup (MvPowerSeries σ R) := Pi.addCommGroup instance [Nontrivial R] : Nontrivial (MvPowerSeries σ R) := Function.nontrivial instance {A} [Semiring R] [AddCommMonoid A] [Module R A] : Module R (MvPowerSeries σ A) := Pi.module _ _ _ instance {A S} [Semiring R] [Semiring S] [AddCommMonoid A] [Module R A] [Module S A] [SMul R S] [IsScalarTower R S A] : IsScalarTower R S (MvPowerSeries σ A) := Pi.isScalarTower section Semiring variable (R) [Semiring R] /-- The `n`th monomial as multivariate formal power series: it is defined as the `R`-linear map from `R` to the semi-ring of multivariate formal power series associating to each `a` the map sending `n : σ →₀ ℕ` to the value `a` and sending all other `x : σ →₀ ℕ` different from `n` to `0`. -/ def monomial (n : σ →₀ ℕ) : R →ₗ[R] MvPowerSeries σ R := letI := Classical.decEq σ LinearMap.single R (fun _ ↦ R) n /-- The `n`th coefficient of a multivariate formal power series. -/ def coeff (n : σ →₀ ℕ) : MvPowerSeries σ R →ₗ[R] R := LinearMap.proj n theorem coeff_apply (f : MvPowerSeries σ R) (d : σ →₀ ℕ) : coeff R d f = f d := rfl variable {R} /-- Two multivariate formal power series are equal if all their coefficients are equal. -/ @[ext] theorem ext {φ ψ} (h : ∀ n : σ →₀ ℕ, coeff R n φ = coeff R n ψ) : φ = ψ := funext h /-- Two multivariate formal power series are equal if and only if all their coefficients are equal. -/ add_decl_doc MvPowerSeries.ext_iff theorem monomial_def [DecidableEq σ] (n : σ →₀ ℕ) : (monomial R n) = LinearMap.single R (fun _ ↦ R) n := by rw [monomial] -- unify the `Decidable` arguments convert rfl theorem coeff_monomial [DecidableEq σ] (m n : σ →₀ ℕ) (a : R) : coeff R m (monomial R n a) = if m = n then a else 0 := by dsimp only [coeff, MvPowerSeries] rw [monomial_def, LinearMap.proj_apply (i := m), LinearMap.single_apply, Pi.single_apply] @[simp] theorem coeff_monomial_same (n : σ →₀ ℕ) (a : R) : coeff R n (monomial R n a) = a := by classical rw [monomial_def] exact Pi.single_eq_same _ _ theorem coeff_monomial_ne {m n : σ →₀ ℕ} (h : m ≠ n) (a : R) : coeff R m (monomial R n a) = 0 := by classical rw [monomial_def] exact Pi.single_eq_of_ne h _ theorem eq_of_coeff_monomial_ne_zero {m n : σ →₀ ℕ} {a : R} (h : coeff R m (monomial R n a) ≠ 0) : m = n := by_contra fun h' => h <\| coeff_monomial_ne h' a @[simp] theorem coeff_comp_monomial (n : σ →₀ ℕ) : (coeff R n).comp (monomial R n) = LinearMap.id := LinearMap.ext <\| coeff_monomial_same n @[simp] theorem coeff_zero (n : σ →₀ ℕ) : coeff R n (0 : MvPowerSeries σ R) = 0 := rfl theorem eq_zero_iff_forall_coeff_zero {f : MvPowerSeries σ R} : f = 0 ↔ (∀ d : σ →₀ ℕ, coeff R d f = 0) := MvPowerSeries.ext_iff theorem ne_zero_iff_exists_coeff_ne_zero (f : MvPowerSeries σ R) : f ≠ 0 ↔ (∃ d : σ →₀ ℕ, coeff R d f ≠ 0) := by simp only [MvPowerSeries.ext_iff, ne_eq, coeff_zero, not_forall] variable (m n : σ →₀ ℕ) (φ ψ : MvPowerSeries σ R) instance : One (MvPowerSeries σ R) := ⟨monomial R (0 : σ →₀ ℕ) 1⟩ theorem coeff_one [DecidableEq σ] : coeff R n (1 : MvPowerSeries σ R) = if n = 0 then 1 else 0 := coeff_monomial _ _ _ theorem coeff_zero_one : coeff R (0 : σ →₀ ℕ) 1 = 1 := coeff_monomial_same 0 1 theorem monomial_zero_one : monomial R (0 : σ →₀ ℕ) 1 = 1 := rfl instance : AddMonoidWithOne (MvPowerSeries σ R) := { show AddMonoid (MvPowerSeries σ R) by infer_instance with natCast := fun n => monomial R 0 n natCast_zero := by simp [Nat.cast] natCast_succ := by simp [Nat.cast, monomial_zero_one] one := 1 } instance : Mul (MvPowerSeries σ R) := letI := Classical.decEq σ ⟨fun φ ψ n => ∑ p ∈ antidiagonal n, coeff R p.1 φ coeff R p.2 ψ⟩ theorem coeff_mul [DecidableEq σ] : coeff R n (φ * ψ) = ∑ p ∈ antidiagonal n, coeff R p.1 φ * coeff R p.2 ψ := by refine Finset.sum_congr ?_ fun _ _ => rfl rw [Subsingleton.elim (Classical.decEq σ) ‹DecidableEq σ›] protected theorem zero_mul : (0 : MvPowerSeries σ R) * φ = 0 := ext fun n => by classical simp [coeff_mul] protected theorem mul_zero : φ * 0 = 0 := ext fun n => by classical simp [coeff_mul] theorem coeff_monomial_mul (a : R) : coeff R m (monomial R n a * φ) = if n ≤ m then a * coeff R (m - n) φ else 0 := by classical have : ∀ p ∈ antidiagonal m, coeff R (p : (σ →₀ ℕ) × (σ →₀ ℕ)).1 (monomial R n a) * coeff R p.2 φ ≠ 0 → p.1 = n := fun p _ hp => eq_of_coeff_monomial_ne_zero (left_ne_zero_of_mul hp) rw [coeff_mul, ← Finset.sum_filter_of_ne this, Finset.filter_fst_eq_antidiagonal _ n, Finset.sum_ite_index] simp only [Finset.sum_singleton, coeff_monomial_same, Finset.sum_empty] theorem coeff_mul_monomial (a : R) : coeff R m (φ * monomial R n a) = if n ≤ m then coeff R (m - n) φ * a else 0 := by classical have : ∀ p ∈ antidiagonal m, coeff R (p : (σ →₀ ℕ) × (σ →₀ ℕ)).1 φ * coeff R p.2 (monomial R n a) ≠ 0 → p.2 = n := fun p _ hp => eq_of_coeff_monomial_ne_zero (right_ne_zero_of_mul hp) rw [coeff_mul, ← Finset.sum_filter_of_ne this, Finset.filter_snd_eq_antidiagonal _ n, Finset.sum_ite_index] simp only [Finset.sum_singleton, coeff_monomial_same, Finset.sum_empty] theorem coeff_add_monomial_mul (a : R) : coeff R (m + n) (monomial R m a * φ) = a * coeff R n φ := by rw [coeff_monomial_mul, if_pos, add_tsub_cancel_left] exact le_add_right le_rfl theorem coeff_add_mul_monomial (a : R) : coeff R (m + n) (φ * monomial R n a) = coeff R m φ * a := by rw [coeff_mul_monomial, if_pos, add_tsub_cancel_right] exact le_add_left le_rfl @[simp] theorem commute_monomial {a : R} {n} : Commute φ (monomial R n a) ↔ ∀ m, Commute (coeff R m φ) a := by rw [commute_iff_eq, MvPowerSeries.ext_iff] refine ⟨fun h m => ?_, fun h m => ?_⟩ · have := h (m + n) rwa [coeff_add_mul_monomial, add_comm, coeff_add_monomial_mul] at this · rw [coeff_mul_monomial, coeff_monomial_mul] split_ifs <;> [apply h; rfl] protected theorem one_mul : (1 : MvPowerSeries σ R) * φ = φ := ext fun n => by simpa using coeff_add_monomial_mul 0 n φ 1 protected theorem mul_one : φ * 1 = φ := ext fun n => by simpa using coeff_add_mul_monomial n 0 φ 1 protected theorem mul_add (φ₁ φ₂ φ₃ : MvPowerSeries σ R) : φ₁ * (φ₂ + φ₃) = φ₁ * φ₂ + φ₁ * φ₃ := ext fun n => by classical simp only [coeff_mul, mul_add, Finset.sum_add_distrib, LinearMap.map_add] protected theorem add_mul (φ₁ φ₂ φ₃ : MvPowerSeries σ R) : (φ₁ + φ₂) * φ₃ = φ₁ * φ₃ + φ₂ * φ₃ := ext fun n => by classical simp only [coeff_mul, add_mul, Finset.sum_add_distrib, LinearMap.map_add] protected theorem mul_assoc (φ₁ φ₂ φ₃ : MvPowerSeries σ R) : φ₁ * φ₂ * φ₃ = φ₁ * (φ₂ * φ₃) := by ext1 n classical simp only [coeff_mul, Finset.sum_mul, Finset.mul_sum, Finset.sum_sigma'] apply Finset.sum_nbij' (fun ⟨⟨_i, j⟩, ⟨k, l⟩⟩ ↦ ⟨(k, l + j), (l, j)⟩) (fun ⟨⟨i, _j⟩, ⟨k, l⟩⟩ ↦ ⟨(i + k, l), (i, k)⟩) <;> aesop (add simp [add_assoc, mul_assoc]) instance : Semiring (MvPowerSeries σ R) := { inferInstanceAs (AddMonoidWithOne (MvPowerSeries σ R)), inferInstanceAs (Mul (MvPowerSeries σ R)), inferInstanceAs (AddCommMonoid (MvPowerSeries σ R)) with mul_one := MvPowerSeries.mul_one one_mul := MvPowerSeries.one_mul mul_assoc := MvPowerSeries.mul_assoc mul_zero := MvPowerSeries.mul_zero zero_mul := MvPowerSeries.zero_mul left_distrib := MvPowerSeries.mul_add right_distrib := MvPowerSeries.add_mul } end Semiring instance [CommSemiring R] : CommSemiring (MvPowerSeries σ R) := { show Semiring (MvPowerSeries σ R) by infer_instance with mul_comm := fun φ ψ => ext fun n => by classical simpa only [coeff_mul, mul_comm] using sum_antidiagonal_swap n fun a b => coeff R a φ * coeff R b ψ } instance [Ring R] : Ring (MvPowerSeries σ R) := { inferInstanceAs (Semiring (MvPowerSeries σ R)), inferInstanceAs (AddCommGroup (MvPowerSeries σ R)) with } instance [CommRing R] : CommRing (MvPowerSeries σ R) := { inferInstanceAs (CommSemiring (MvPowerSeries σ R)), inferInstanceAs (AddCommGroup (MvPowerSeries σ R)) with } section Semiring variable [Semiring R] theorem monomial_mul_monomial (m n : σ →₀ ℕ) (a b : R) : monomial R m a * monomial R n b = monomial R (m + n) (a * b) := by classical ext k simp only [coeff_mul_monomial, coeff_monomial] split_ifs with h₁ h₂ h₃ h₃ h₂ <;> try rfl · rw [← h₂, tsub_add_cancel_of_le h₁] at h₃ exact (h₃ rfl).elim · rw [h₃, add_tsub_cancel_right] at h₂ exact (h₂ rfl).elim · exact zero_mul b · rw [h₂] at h₁ exact (h₁ <\| le_add_left le_rfl).elim variable (σ) (R) /-- The constant multivariate formal power series. -/ def C : R →+* MvPowerSeries σ R := { monomial R (0 : σ →₀ ℕ) with map_one' := rfl map_mul' := fun a b => (monomial_mul_monomial 0 0 a b).symm map_zero' := (monomial R 0).map_zero } variable {σ} {R} @[simp] theorem monomial_zero_eq_C : ⇑(monomial R (0 : σ →₀ ℕ)) = C σ R := rfl theorem monomial_zero_eq_C_apply (a : R) : monomial R (0 : σ →₀ ℕ) a = C σ R a := rfl theorem coeff_C [DecidableEq σ] (n : σ →₀ ℕ) (a : R) : coeff R n (C σ R a) = if n = 0 then a else 0 := coeff_monomial _ _ _ theorem coeff_zero_C (a : R) : coeff R (0 : σ →₀ ℕ) (C σ R a) = a := coeff_monomial_same 0 a /-- The variables of the multivariate formal power series ring. -/ def X (s : σ) : MvPowerSeries σ R := monomial R (single s 1) 1 theorem coeff_X [DecidableEq σ] (n : σ →₀ ℕ) (s : σ) : coeff R n (X s : MvPowerSeries σ R) = if n = single s 1 then 1 else 0 := coeff_monomial _ _ _ theorem coeff_index_single_X [DecidableEq σ] (s t : σ) : coeff R (single t 1) (X s : MvPowerSeries σ R) = if t = s then 1 else 0 := by simp only [coeff_X, single_left_inj (one_ne_zero : (1 : ℕ) ≠ 0)] @[simp] theorem coeff_index_single_self_X (s : σ) : coeff R (single s 1) (X s : MvPowerSeries σ R) = 1 := coeff_monomial_same _ _ theorem coeff_zero_X (s : σ) : coeff R (0 : σ →₀ ℕ) (X s : MvPowerSeries σ R) = 0 := by classical rw [coeff_X, if_neg] intro h exact one_ne_zero (single_eq_zero.mp h.symm) theorem commute_X (φ : MvPowerSeries σ R) (s : σ) : Commute φ (X s) := φ.commute_monomial.mpr fun _m => Commute.one_right _ theorem X_mul {φ : MvPowerSeries σ R} {s : σ} : X s * φ = φ * X s := φ.commute_X s \|>.symm.eq theorem commute_X_pow (φ : MvPowerSeries σ R) (s : σ) (n : ℕ) : Commute φ (X s ^ n) := φ.commute_X s \|>.pow_right _ theorem X_pow_mul {φ : MvPowerSeries σ R} {s : σ} {n : ℕ} : X s ^ n * φ = φ * X s ^ n := φ.commute_X_pow s n \|>.symm.eq theorem X_def (s : σ) : X s = monomial R (single s 1) 1 := rfl theorem X_pow_eq (s : σ) (n : ℕ) : (X s : MvPowerSeries σ R) ^ n = monomial R (single s n) 1 := by induction n with \| zero => simp \| succ n ih => rw [pow_succ, ih, Finsupp.single_add, X, monomial_mul_monomial, one_mul] theorem coeff_X_pow [DecidableEq σ] (m : σ →₀ ℕ) (s : σ) (n : ℕ) : coeff R m ((X s : MvPowerSeries σ R) ^ n) = if m = single s n then 1 else 0 := by rw [X_pow_eq s n, coeff_monomial] @[simp] theorem coeff_mul_C (n : σ →₀ ℕ) (φ : MvPowerSeries σ R) (a : R) : coeff R n (φ * C σ R a) = coeff R n φ * a := by simpa using coeff_add_mul_monomial n 0 φ a @[simp] theorem coeff_C_mul (n : σ →₀ ℕ) (φ : MvPowerSeries σ R) (a : R) : coeff R n (C σ R a * φ) = a * coeff R n φ := by simpa using coeff_add_monomial_mul 0 n φ a theorem coeff_zero_mul_X (φ : MvPowerSeries σ R) (s : σ) : coeff R (0 : σ →₀ ℕ) (φ * X s) = 0 := by have : ¬single s 1 ≤ 0 := fun h => by simpa using h s simp only [X, coeff_mul_monomial, if_neg this] theorem coeff_zero_X_mul (φ : MvPowerSeries σ R) (s : σ) : coeff R (0 : σ →₀ ℕ) (X s * φ) = 0 := by rw [← (φ.commute_X s).eq, coeff_zero_mul_X] variable (σ) (R) /-- The constant coefficient of a formal power series. -/ def constantCoeff : MvPowerSeries σ R →+* R := { coeff R (0 : σ →₀ ℕ) with toFun := coeff R (0 : σ →₀ ℕ) map_one' := coeff_zero_one map_mul' := fun φ ψ => by classical simp [coeff_mul, support_single_ne_zero] map_zero' := LinearMap.map_zero _ } variable {σ} {R} @[simp] theorem coeff_zero_eq_constantCoeff : ⇑(coeff R (0 : σ →₀ ℕ)) = constantCoeff σ R := rfl theorem coeff_zero_eq_constantCoeff_apply (φ : MvPowerSeries σ R) : coeff R (0 : σ →₀ ℕ) φ = constantCoeff σ R φ := rfl @[simp] theorem constantCoeff_C (a : R) : constantCoeff σ R (C σ R a) = a := rfl @[simp] theorem constantCoeff_comp_C : (constantCoeff σ R).comp (C σ R) = RingHom.id R := rfl @[simp] theorem constantCoeff_zero : constantCoeff σ R 0 = 0 := rfl @[simp] theorem constantCoeff_one : constantCoeff σ R 1 = 1 := rfl @[simp] theorem constantCoeff_X (s : σ) : constantCoeff σ R (X s) = 0 := coeff_zero_X s @[simp] theorem constantCoeff_smul {S : Type} [Semiring S] [Module R S] (φ : MvPowerSeries σ S) (a : R) : constantCoeff σ S (a • φ) = a • constantCoeff σ S φ := rfl /-- If a multivariate formal power series is invertible, then so is its constant coefficient. -/ theorem isUnit_constantCoeff (φ : MvPowerSeries σ R) (h : IsUnit φ) : IsUnit (constantCoeff σ R φ) := h.map _ @[simp] theorem coeff_smul (f : MvPowerSeries σ R) (n) (a : R) : coeff _ n (a • f) = a coeff _ n f := rfl theorem smul_eq_C_mul (f : MvPowerSeries σ R) (a : R) : a • f = C σ R a * f := by ext simp theorem X_inj [Nontrivial R] {s t : σ} : (X s : MvPowerSeries σ R) = X t ↔ s = t := ⟨by classical intro h replace h := congr_arg (coeff R (single s 1)) h rw [coeff_X, if_pos rfl, coeff_X] at h split_ifs at h with H · rw [Finsupp.single_eq_single_iff] at H rcases H with H \| H · exact H.1 · exfalso exact one_ne_zero H.1 · exfalso exact one_ne_zero h, congr_arg X⟩ end Semiring section Map variable {S T : Type} [Semiring R] [Semiring S] [Semiring T] variable (f : R →+ S) (g : S →+* T) variable (σ) in /-- The map between multivariate formal power series induced by a map on the coefficients. -/ def map : MvPowerSeries σ R →+* MvPowerSeries σ S where toFun φ n := f <\| coeff R n φ map_zero' := ext fun _n => f.map_zero map_one' := ext fun n => show f ((coeff R n) 1) = (coeff S n) 1 by classical rw [coeff_one, coeff_one] split_ifs with h · simp only [ite_true, map_one, h]	· simp only [ite_false, map_zero, h] map_add' φ ψ := ext fun n => show f ((coeff R n) (φ + ψ)) = f ((coeff R n) φ) + f ((coeff R n) ψ) by simp map_mul' φ ψ := ext fun n => show f _ = _ by classical rw [coeff_mul, map_sum, coeff_mul] apply Finset.sum_congr rfl rintro ⟨i, j⟩ _; rw [f.map_mul]; rfl @[simp] theorem map_id : map σ (RingHom.id R) = RingHom.id _ := rfl	Mathlib/RingTheory/MvPowerSeries/Basic.lean	519	532
/- Copyright (c) 2019 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn, Yury Kudryashov -/ import Mathlib.Data.Set.Lattice.Image import Mathlib.Order.Interval.Set.LinearOrder /-! # Extra lemmas about intervals This file contains lemmas about intervals that cannot be included into `Order.Interval.Set.Basic` because this would create an `import` cycle. Namely, lemmas in this file can use definitions from `Data.Set.Lattice`, including `Disjoint`. We consider various intersections and unions of half infinite intervals. -/ universe u v w variable {ι : Sort u} {α : Type v} {β : Type w} open Set open OrderDual (toDual) namespace Set section Preorder variable [Preorder α] {a b c : α} @[simp] theorem Iic_disjoint_Ioi (h : a ≤ b) : Disjoint (Iic a) (Ioi b) := disjoint_left.mpr fun _ ha hb => (h.trans_lt hb).not_le ha @[simp] theorem Iio_disjoint_Ici (h : a ≤ b) : Disjoint (Iio a) (Ici b) := disjoint_left.mpr fun _ ha hb => (h.trans_lt' ha).not_le hb @[simp] theorem Iic_disjoint_Ioc (h : a ≤ b) : Disjoint (Iic a) (Ioc b c) := (Iic_disjoint_Ioi h).mono le_rfl Ioc_subset_Ioi_self @[simp] theorem Ioc_disjoint_Ioc_of_le {d : α} (h : b ≤ c) : Disjoint (Ioc a b) (Ioc c d) := (Iic_disjoint_Ioc h).mono Ioc_subset_Iic_self le_rfl @[deprecated Ioc_disjoint_Ioc_of_le (since := "2025-03-04")] theorem Ioc_disjoint_Ioc_same : Disjoint (Ioc a b) (Ioc b c) := (Iic_disjoint_Ioc le_rfl).mono Ioc_subset_Iic_self le_rfl @[simp] theorem Ico_disjoint_Ico_same : Disjoint (Ico a b) (Ico b c) := disjoint_left.mpr fun _ hab hbc => hab.2.not_le hbc.1 @[simp] theorem Ici_disjoint_Iic : Disjoint (Ici a) (Iic b) ↔ ¬a ≤ b := by rw [Set.disjoint_iff_inter_eq_empty, Ici_inter_Iic, Icc_eq_empty_iff] @[simp] theorem Iic_disjoint_Ici : Disjoint (Iic a) (Ici b) ↔ ¬b ≤ a := disjoint_comm.trans Ici_disjoint_Iic @[simp] theorem Ioc_disjoint_Ioi (h : b ≤ c) : Disjoint (Ioc a b) (Ioi c) := disjoint_left.mpr (fun _ hx hy ↦ (hx.2.trans h).not_lt hy) theorem Ioc_disjoint_Ioi_same : Disjoint (Ioc a b) (Ioi b) := Ioc_disjoint_Ioi le_rfl @[simp] theorem iUnion_Iic : ⋃ a : α, Iic a = univ := iUnion_eq_univ_iff.2 fun x => ⟨x, right_mem_Iic⟩ @[simp] theorem iUnion_Ici : ⋃ a : α, Ici a = univ := iUnion_eq_univ_iff.2 fun x => ⟨x, left_mem_Ici⟩ @[simp] theorem iUnion_Icc_right (a : α) : ⋃ b, Icc a b = Ici a := by simp only [← Ici_inter_Iic, ← inter_iUnion, iUnion_Iic, inter_univ] @[simp] theorem iUnion_Ioc_right (a : α) : ⋃ b, Ioc a b = Ioi a := by simp only [← Ioi_inter_Iic, ← inter_iUnion, iUnion_Iic, inter_univ] @[simp] theorem iUnion_Icc_left (b : α) : ⋃ a, Icc a b = Iic b := by simp only [← Ici_inter_Iic, ← iUnion_inter, iUnion_Ici, univ_inter] @[simp] theorem iUnion_Ico_left (b : α) : ⋃ a, Ico a b = Iio b := by simp only [← Ici_inter_Iio, ← iUnion_inter, iUnion_Ici, univ_inter] @[simp] theorem iUnion_Iio [NoMaxOrder α] : ⋃ a : α, Iio a = univ := iUnion_eq_univ_iff.2 exists_gt @[simp] theorem iUnion_Ioi [NoMinOrder α] : ⋃ a : α, Ioi a = univ := iUnion_eq_univ_iff.2 exists_lt @[simp] theorem iUnion_Ico_right [NoMaxOrder α] (a : α) : ⋃ b, Ico a b = Ici a := by simp only [← Ici_inter_Iio, ← inter_iUnion, iUnion_Iio, inter_univ] @[simp] theorem iUnion_Ioo_right [NoMaxOrder α] (a : α) : ⋃ b, Ioo a b = Ioi a := by simp only [← Ioi_inter_Iio, ← inter_iUnion, iUnion_Iio, inter_univ] @[simp] theorem iUnion_Ioc_left [NoMinOrder α] (b : α) : ⋃ a, Ioc a b = Iic b := by simp only [← Ioi_inter_Iic, ← iUnion_inter, iUnion_Ioi, univ_inter] @[simp] theorem iUnion_Ioo_left [NoMinOrder α] (b : α) : ⋃ a, Ioo a b = Iio b := by simp only [← Ioi_inter_Iio, ← iUnion_inter, iUnion_Ioi, univ_inter] end Preorder	section LinearOrder	Mathlib/Order/Interval/Set/Disjoint.lean	122	123
/- Copyright (c) 2019 Patrick Massot. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Patrick Massot -/ import Mathlib.RingTheory.SimpleRing.Basic import Mathlib.Topology.Algebra.Field import Mathlib.Topology.Algebra.UniformRing /-! # Completion of topological fields The goal of this file is to prove the main part of Proposition 7 of Bourbaki GT III 6.8 : The completion `hat K` of a Hausdorff topological field is a field if the image under the mapping `x ↦ x⁻¹` of every Cauchy filter (with respect to the additive uniform structure) which does not have a cluster point at `0` is a Cauchy filter (with respect to the additive uniform structure). Bourbaki does not give any detail here, he refers to the general discussion of extending functions defined on a dense subset with values in a complete Hausdorff space. In particular the subtlety about clustering at zero is totally left to readers. Note that the separated completion of a non-separated topological field is the zero ring, hence the separation assumption is needed. Indeed the kernel of the completion map is the closure of zero which is an ideal. Hence it's either zero (and the field is separated) or the full field, which implies one is sent to zero and the completion ring is trivial. The main definition is `CompletableTopField` which packages the assumptions as a Prop-valued type class and the main results are the instances `UniformSpace.Completion.Field` and `UniformSpace.Completion.IsTopologicalDivisionRing`. -/ noncomputable section open uniformity Topology open Set UniformSpace UniformSpace.Completion Filter variable (K : Type*) [Field K] [UniformSpace K] local notation "hat" => Completion /-- A topological field is completable if it is separated and the image under the mapping x ↦ x⁻¹ of every Cauchy filter (with respect to the additive uniform structure) which does not have a cluster point at 0 is a Cauchy filter (with respect to the additive uniform structure). This ensures the completion is a field. -/ class CompletableTopField : Prop extends T0Space K where nice : ∀ F : Filter K, Cauchy F → 𝓝 0 ⊓ F = ⊥ → Cauchy (map (fun x => x⁻¹) F) namespace UniformSpace namespace Completion instance (priority := 100) [T0Space K] : Nontrivial (hat K) := ⟨⟨0, 1, fun h => zero_ne_one <\| (isUniformEmbedding_coe K).injective h⟩⟩ variable {K} /-- extension of inversion to the completion of a field. -/ def hatInv : hat K → hat K := isDenseInducing_coe.extend fun x : K => (↑x⁻¹ : hat K) @[fun_prop] theorem continuous_hatInv [CompletableTopField K] {x : hat K} (h : x ≠ 0) : ContinuousAt hatInv x := by refine isDenseInducing_coe.continuousAt_extend ?_ apply mem_of_superset (compl_singleton_mem_nhds h) intro y y_ne rw [mem_compl_singleton_iff] at y_ne apply CompleteSpace.complete have : (fun (x : K) => (↑x⁻¹ : hat K)) = ((fun (y : K) => (↑y : hat K))∘(fun (x : K) => (x⁻¹ : K))) := by unfold Function.comp simp rw [this, ← Filter.map_map] apply Cauchy.map _ (Completion.uniformContinuous_coe K) apply CompletableTopField.nice · haveI := isDenseInducing_coe.comap_nhds_neBot y apply cauchy_nhds.comap rw [Completion.comap_coe_eq_uniformity] · have eq_bot : 𝓝 (0 : hat K) ⊓ 𝓝 y = ⊥ := by by_contra h exact y_ne (eq_of_nhds_neBot <\| neBot_iff.mpr h).symm rw [isDenseInducing_coe.nhds_eq_comap (0 : K), ← Filter.comap_inf] norm_cast rw [eq_bot] exact comap_bot open Classical in /-- The value of `hat_inv` at zero is not really specified, although it's probably zero. Here we explicitly enforce the `inv_zero` axiom. -/ instance instInvCompletion : Inv (hat K) := ⟨fun x => if x = 0 then 0 else hatInv x⟩ variable [IsTopologicalDivisionRing K] theorem hatInv_extends {x : K} (h : x ≠ 0) : hatInv (x : hat K) = ↑(x⁻¹ : K) := isDenseInducing_coe.extend_eq_at ((continuous_coe K).continuousAt.comp (continuousAt_inv₀ h)) variable [CompletableTopField K] @[norm_cast] theorem coe_inv (x : K) : (x : hat K)⁻¹ = ((x⁻¹ : K) : hat K) := by by_cases h : x = 0 · rw [h, inv_zero] dsimp [Inv.inv]	norm_cast simp · conv_lhs => dsimp [Inv.inv] rw [if_neg] · exact hatInv_extends h · exact fun H => h (isDenseEmbedding_coe.injective H) variable [IsUniformAddGroup K] theorem mul_hatInv_cancel {x : hat K} (x_ne : x ≠ 0) : x * hatInv x = 1 := by	Mathlib/Topology/Algebra/UniformField.lean	112	121
/- 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)] theorem Finite.encard_eq_coe_toFinset_card (h : s.Finite) : s.encard = h.toFinset.card := by have := h.fintype rw [encard, ENat.card_eq_coe_fintype_card, toFinite_toFinset, toFinset_card] theorem encard_eq_coe_toFinset_card (s : Set α) [Fintype s] : encard s = s.toFinset.card := by have h := toFinite s rw [h.encard_eq_coe_toFinset_card, toFinite_toFinset] @[simp] theorem toENat_cardinalMk (s : Set α) : (Cardinal.mk s).toENat = s.encard := rfl theorem toENat_cardinalMk_subtype (P : α → Prop) : (Cardinal.mk {x // P x}).toENat = {x \| P x}.encard := rfl @[simp] theorem coe_fintypeCard (s : Set α) [Fintype s] : Fintype.card s = s.encard := by simp [encard_eq_coe_toFinset_card] @[simp, norm_cast] theorem encard_coe_eq_coe_finsetCard (s : Finset α) : encard (s : Set α) = s.card := by rw [Finite.encard_eq_coe_toFinset_card (Finset.finite_toSet s)]; simp @[simp] theorem Infinite.encard_eq {s : Set α} (h : s.Infinite) : s.encard = ⊤ := by have := h.to_subtype rw [encard, ENat.card_eq_top_of_infinite] @[simp] theorem encard_eq_zero : s.encard = 0 ↔ s = ∅ := by rw [encard, ENat.card_eq_zero_iff_empty, isEmpty_subtype, eq_empty_iff_forall_not_mem] @[simp] theorem encard_empty : (∅ : Set α).encard = 0 := by rw [encard_eq_zero] theorem nonempty_of_encard_ne_zero (h : s.encard ≠ 0) : s.Nonempty := by rwa [nonempty_iff_ne_empty, Ne, ← encard_eq_zero] theorem encard_ne_zero : s.encard ≠ 0 ↔ s.Nonempty := by rw [ne_eq, encard_eq_zero, nonempty_iff_ne_empty] @[simp] theorem encard_pos : 0 < s.encard ↔ s.Nonempty := by rw [pos_iff_ne_zero, encard_ne_zero] protected alias ⟨_, Nonempty.encard_pos⟩ := encard_pos @[simp] theorem encard_singleton (e : α) : ({e} : Set α).encard = 1 := by rw [encard, ENat.card_eq_coe_fintype_card, Fintype.card_ofSubsingleton, Nat.cast_one] theorem encard_union_eq (h : Disjoint s t) : (s ∪ t).encard = s.encard + t.encard := by classical simp [encard, ENat.card_congr (Equiv.Set.union h)] theorem encard_insert_of_not_mem {a : α} (has : a ∉ s) : (insert a s).encard = s.encard + 1 := by rw [← union_singleton, encard_union_eq (by simpa), encard_singleton] theorem Finite.encard_lt_top (h : s.Finite) : s.encard < ⊤ := by induction s, h using Set.Finite.induction_on with \| empty => simp \| insert hat _ ht' => rw [encard_insert_of_not_mem hat] exact lt_tsub_iff_right.1 ht' theorem Finite.encard_eq_coe (h : s.Finite) : s.encard = ENat.toNat s.encard := (ENat.coe_toNat h.encard_lt_top.ne).symm theorem Finite.exists_encard_eq_coe (h : s.Finite) : ∃ (n : ℕ), s.encard = n := ⟨_, h.encard_eq_coe⟩ @[simp] theorem encard_lt_top_iff : s.encard < ⊤ ↔ s.Finite := ⟨fun h ↦ by_contra fun h' ↦ h.ne (Infinite.encard_eq h'), Finite.encard_lt_top⟩ @[simp] theorem encard_eq_top_iff : s.encard = ⊤ ↔ s.Infinite := by rw [← not_iff_not, ← Ne, ← lt_top_iff_ne_top, encard_lt_top_iff, not_infinite] alias ⟨_, encard_eq_top⟩ := encard_eq_top_iff theorem encard_ne_top_iff : s.encard ≠ ⊤ ↔ s.Finite := by simp theorem finite_of_encard_le_coe {k : ℕ} (h : s.encard ≤ k) : s.Finite := by rw [← encard_lt_top_iff]; exact h.trans_lt (WithTop.coe_lt_top _) theorem finite_of_encard_eq_coe {k : ℕ} (h : s.encard = k) : s.Finite := finite_of_encard_le_coe h.le theorem encard_le_coe_iff {k : ℕ} : s.encard ≤ k ↔ s.Finite ∧ ∃ (n₀ : ℕ), s.encard = n₀ ∧ n₀ ≤ k := ⟨fun h ↦ ⟨finite_of_encard_le_coe h, by rwa [ENat.le_coe_iff] at h⟩, fun ⟨_,⟨n₀,hs, hle⟩⟩ ↦ by rwa [hs, Nat.cast_le]⟩ @[simp] theorem encard_prod : (s ×ˢ t).encard = s.encard * t.encard := by simp [Set.encard, ENat.card_congr (Equiv.Set.prod ..)] section Lattice theorem encard_le_encard (h : s ⊆ t) : s.encard ≤ t.encard := by rw [← union_diff_cancel h, encard_union_eq disjoint_sdiff_right]; exact le_self_add @[deprecated (since := "2025-01-05")] alias encard_le_card := encard_le_encard theorem encard_mono {α : Type} : Monotone (encard : Set α → ℕ∞) := fun _ _ ↦ encard_le_encard theorem encard_diff_add_encard_of_subset (h : s ⊆ t) : (t \ s).encard + s.encard = t.encard := by rw [← encard_union_eq disjoint_sdiff_left, diff_union_self, union_eq_self_of_subset_right h] @[simp] theorem one_le_encard_iff_nonempty : 1 ≤ s.encard ↔ s.Nonempty := by rw [nonempty_iff_ne_empty, Ne, ← encard_eq_zero, ENat.one_le_iff_ne_zero] theorem encard_diff_add_encard_inter (s t : Set α) : (s \ t).encard + (s ∩ t).encard = s.encard := by rw [← encard_union_eq (disjoint_of_subset_right inter_subset_right disjoint_sdiff_left), diff_union_inter] theorem encard_union_add_encard_inter (s t : Set α) : (s ∪ t).encard + (s ∩ t).encard = s.encard + t.encard := by rw [← diff_union_self, encard_union_eq disjoint_sdiff_left, add_right_comm, encard_diff_add_encard_inter] theorem encard_eq_encard_iff_encard_diff_eq_encard_diff (h : (s ∩ t).Finite) : s.encard = t.encard ↔ (s \ t).encard = (t \ s).encard := by rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_right_inj h.encard_lt_top.ne] theorem encard_le_encard_iff_encard_diff_le_encard_diff (h : (s ∩ t).Finite) : s.encard ≤ t.encard ↔ (s \ t).encard ≤ (t \ s).encard := by rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_le_add_iff_right h.encard_lt_top.ne] theorem encard_lt_encard_iff_encard_diff_lt_encard_diff (h : (s ∩ t).Finite) : s.encard < t.encard ↔ (s \ t).encard < (t \ s).encard := by rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_lt_add_iff_right h.encard_lt_top.ne] theorem encard_union_le (s t : Set α) : (s ∪ t).encard ≤ s.encard + t.encard := by rw [← encard_union_add_encard_inter]; exact le_self_add theorem finite_iff_finite_of_encard_eq_encard (h : s.encard = t.encard) : s.Finite ↔ t.Finite := by rw [← encard_lt_top_iff, ← encard_lt_top_iff, h] theorem infinite_iff_infinite_of_encard_eq_encard (h : s.encard = t.encard) : s.Infinite ↔ t.Infinite := by rw [← encard_eq_top_iff, h, encard_eq_top_iff] theorem Finite.finite_of_encard_le {s : Set α} {t : Set β} (hs : s.Finite) (h : t.encard ≤ s.encard) : t.Finite := encard_lt_top_iff.1 (h.trans_lt hs.encard_lt_top) lemma Finite.eq_of_subset_of_encard_le' (ht : t.Finite) (hst : s ⊆ t) (hts : t.encard ≤ s.encard) : s = t := by rw [← zero_add (a := encard s), ← encard_diff_add_encard_of_subset hst] at hts have hdiff := WithTop.le_of_add_le_add_right (ht.subset hst).encard_lt_top.ne hts rw [nonpos_iff_eq_zero, encard_eq_zero, diff_eq_empty] at hdiff exact hst.antisymm hdiff theorem Finite.eq_of_subset_of_encard_le (hs : s.Finite) (hst : s ⊆ t) (hts : t.encard ≤ s.encard) : s = t := (hs.finite_of_encard_le hts).eq_of_subset_of_encard_le' hst hts theorem Finite.encard_lt_encard (hs : s.Finite) (h : s ⊂ t) : s.encard < t.encard := (encard_mono h.subset).lt_of_ne fun he ↦ h.ne (hs.eq_of_subset_of_encard_le h.subset he.symm.le) theorem encard_strictMono [Finite α] : StrictMono (encard : Set α → ℕ∞) := fun _ _ h ↦ (toFinite _).encard_lt_encard h theorem encard_diff_add_encard (s t : Set α) : (s \ t).encard + t.encard = (s ∪ t).encard := by rw [← encard_union_eq disjoint_sdiff_left, diff_union_self] theorem encard_le_encard_diff_add_encard (s t : Set α) : s.encard ≤ (s \ t).encard + t.encard := (encard_mono subset_union_left).trans_eq (encard_diff_add_encard _ _).symm theorem tsub_encard_le_encard_diff (s t : Set α) : s.encard - t.encard ≤ (s \ t).encard := by rw [tsub_le_iff_left, add_comm]; apply encard_le_encard_diff_add_encard theorem encard_add_encard_compl (s : Set α) : s.encard + sᶜ.encard = (univ : Set α).encard := by rw [← encard_union_eq disjoint_compl_right, union_compl_self] end Lattice section InsertErase variable {a b : α} theorem encard_insert_le (s : Set α) (x : α) : (insert x s).encard ≤ s.encard + 1 := by rw [← union_singleton, ← encard_singleton x]; apply encard_union_le theorem encard_singleton_inter (s : Set α) (x : α) : ({x} ∩ s).encard ≤ 1 := by rw [← encard_singleton x]; exact encard_le_encard inter_subset_left theorem encard_diff_singleton_add_one (h : a ∈ s) : (s \ {a}).encard + 1 = s.encard := by rw [← encard_insert_of_not_mem (fun h ↦ h.2 rfl), insert_diff_singleton, insert_eq_of_mem h] theorem encard_diff_singleton_of_mem (h : a ∈ s) : (s \ {a}).encard = s.encard - 1 := by rw [← encard_diff_singleton_add_one h, ← WithTop.add_right_inj WithTop.one_ne_top, tsub_add_cancel_of_le (self_le_add_left _ _)] theorem encard_tsub_one_le_encard_diff_singleton (s : Set α) (x : α) : s.encard - 1 ≤ (s \ {x}).encard := by rw [← encard_singleton x]; apply tsub_encard_le_encard_diff theorem encard_exchange (ha : a ∉ s) (hb : b ∈ s) : (insert a (s \ {b})).encard = s.encard := by rw [encard_insert_of_not_mem, encard_diff_singleton_add_one hb] simp_all only [not_true, mem_diff, mem_singleton_iff, false_and, not_false_eq_true] theorem encard_exchange' (ha : a ∉ s) (hb : b ∈ s) : (insert a s \ {b}).encard = s.encard := by rw [← insert_diff_singleton_comm (by rintro rfl; exact ha hb), encard_exchange ha hb] theorem encard_eq_add_one_iff {k : ℕ∞} : s.encard = k + 1 ↔ (∃ a t, ¬a ∈ t ∧ insert a t = s ∧ t.encard = k) := by refine ⟨fun h ↦ ?_, ?_⟩ · obtain ⟨a, ha⟩ := nonempty_of_encard_ne_zero (s := s) (by simp [h]) refine ⟨a, s \ {a}, fun h ↦ h.2 rfl, by rwa [insert_diff_singleton, insert_eq_of_mem], ?_⟩ rw [← WithTop.add_right_inj WithTop.one_ne_top, ← h, encard_diff_singleton_add_one ha] rintro ⟨a, t, h, rfl, rfl⟩ rw [encard_insert_of_not_mem h] /-- Every set is either empty, infinite, or can have its `encard` reduced by a removal. Intended for well-founded induction on the value of `encard`. -/ theorem eq_empty_or_encard_eq_top_or_encard_diff_singleton_lt (s : Set α) : s = ∅ ∨ s.encard = ⊤ ∨ ∃ a ∈ s, (s \ {a}).encard < s.encard := by refine s.eq_empty_or_nonempty.elim Or.inl (Or.inr ∘ fun ⟨a,ha⟩ ↦ (s.finite_or_infinite.elim (fun hfin ↦ Or.inr ⟨a, ha, ?_⟩) (Or.inl ∘ Infinite.encard_eq))) rw [← encard_diff_singleton_add_one ha]; nth_rw 1 [← add_zero (encard _)] exact WithTop.add_lt_add_left hfin.diff.encard_lt_top.ne zero_lt_one end InsertErase section SmallSets theorem encard_pair {x y : α} (hne : x ≠ y) : ({x, y} : Set α).encard = 2 := by rw [encard_insert_of_not_mem (by simpa), ← one_add_one_eq_two, WithTop.add_right_inj WithTop.one_ne_top, encard_singleton] theorem encard_eq_one : s.encard = 1 ↔ ∃ x, s = {x} := by refine ⟨fun h ↦ ?_, fun ⟨x, hx⟩ ↦ by rw [hx, encard_singleton]⟩ obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp) exact ⟨x, ((finite_singleton x).eq_of_subset_of_encard_le (by simpa) (by simp [h])).symm⟩ theorem encard_le_one_iff_eq : s.encard ≤ 1 ↔ s = ∅ ∨ ∃ x, s = {x} := by rw [le_iff_lt_or_eq, lt_iff_not_le, ENat.one_le_iff_ne_zero, not_not, encard_eq_zero, encard_eq_one] theorem encard_le_one_iff : s.encard ≤ 1 ↔ ∀ a b, a ∈ s → b ∈ s → a = b := by rw [encard_le_one_iff_eq, or_iff_not_imp_left, ← Ne, ← nonempty_iff_ne_empty] refine ⟨fun h a b has hbs ↦ ?_, fun h ⟨x, hx⟩ ↦ ⟨x, ((singleton_subset_iff.2 hx).antisymm' (fun y hy ↦ h _ _ hy hx))⟩⟩ obtain ⟨x, rfl⟩ := h ⟨_, has⟩ rw [(has : a = x), (hbs : b = x)] theorem encard_le_one_iff_subsingleton : s.encard ≤ 1 ↔ s.Subsingleton := by rw [encard_le_one_iff, Set.Subsingleton] tauto theorem one_lt_encard_iff_nontrivial : 1 < s.encard ↔ s.Nontrivial := by rw [← not_iff_not, not_lt, Set.not_nontrivial_iff, ← encard_le_one_iff_subsingleton] theorem one_lt_encard_iff : 1 < s.encard ↔ ∃ a b, a ∈ s ∧ b ∈ s ∧ a ≠ b := by rw [← not_iff_not, not_exists, not_lt, encard_le_one_iff]; aesop theorem exists_ne_of_one_lt_encard (h : 1 < s.encard) (a : α) : ∃ b ∈ s, b ≠ a := by by_contra! h' obtain ⟨b, b', hb, hb', hne⟩ := one_lt_encard_iff.1 h apply hne rw [h' b hb, h' b' hb'] theorem encard_eq_two : s.encard = 2 ↔ ∃ x y, x ≠ y ∧ s = {x, y} := by refine ⟨fun h ↦ ?_, fun ⟨x, y, hne, hs⟩ ↦ by rw [hs, encard_pair hne]⟩ obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp) rw [← insert_eq_of_mem hx, ← insert_diff_singleton, encard_insert_of_not_mem (fun h ↦ h.2 rfl), ← one_add_one_eq_two, WithTop.add_right_inj (WithTop.one_ne_top), encard_eq_one] at h obtain ⟨y, h⟩ := h refine ⟨x, y, by rintro rfl; exact (h.symm.subset rfl).2 rfl, ?_⟩ rw [← h, insert_diff_singleton, insert_eq_of_mem hx] theorem encard_eq_three {α : Type u_1} {s : Set α} : encard s = 3 ↔ ∃ x y z, x ≠ y ∧ x ≠ z ∧ y ≠ z ∧ s = {x, y, z} := by refine ⟨fun h ↦ ?_, fun ⟨x, y, z, hxy, hyz, hxz, hs⟩ ↦ ?_⟩ · obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp) rw [← insert_eq_of_mem hx, ← insert_diff_singleton, encard_insert_of_not_mem (fun h ↦ h.2 rfl), (by exact rfl : (3 : ℕ∞) = 2 + 1), WithTop.add_right_inj WithTop.one_ne_top, encard_eq_two] at h obtain ⟨y, z, hne, hs⟩ := h refine ⟨x, y, z, ?_, ?_, hne, ?_⟩ · rintro rfl; exact (hs.symm.subset (Or.inl rfl)).2 rfl · rintro rfl; exact (hs.symm.subset (Or.inr rfl)).2 rfl rw [← hs, insert_diff_singleton, insert_eq_of_mem hx] rw [hs, encard_insert_of_not_mem, encard_insert_of_not_mem, encard_singleton] <;> aesop theorem Nat.encard_range (k : ℕ) : {i \| i < k}.encard = k := by convert encard_coe_eq_coe_finsetCard (Finset.range k) using 1 · rw [Finset.coe_range, Iio_def] rw [Finset.card_range] end SmallSets theorem Finite.eq_insert_of_subset_of_encard_eq_succ (hs : s.Finite) (h : s ⊆ t) (hst : t.encard = s.encard + 1) : ∃ a, t = insert a s := by rw [← encard_diff_add_encard_of_subset h, add_comm, WithTop.add_left_inj hs.encard_lt_top.ne, encard_eq_one] at hst obtain ⟨x, hx⟩ := hst; use x; rw [← diff_union_of_subset h, hx, singleton_union] theorem exists_subset_encard_eq {k : ℕ∞} (hk : k ≤ s.encard) : ∃ t, t ⊆ s ∧ t.encard = k := by revert hk refine ENat.nat_induction k (fun _ ↦ ⟨∅, empty_subset _, by simp⟩) (fun n IH hle ↦ ?_) ?_ · obtain ⟨t₀, ht₀s, ht₀⟩ := IH (le_trans (by simp) hle) simp only [Nat.cast_succ] at have hne : t₀ ≠ s := by rintro rfl; rw [ht₀, ← Nat.cast_one, ← Nat.cast_add, Nat.cast_le] at hle; simp at hle obtain ⟨x, hx⟩ := exists_of_ssubset (ht₀s.ssubset_of_ne hne) exact ⟨insert x t₀, insert_subset hx.1 ht₀s, by rw [encard_insert_of_not_mem hx.2, ht₀]⟩ simp only [top_le_iff, encard_eq_top_iff] exact fun _ hi ↦ ⟨s, Subset.rfl, hi⟩ theorem exists_superset_subset_encard_eq {k : ℕ∞} (hst : s ⊆ t) (hsk : s.encard ≤ k) (hkt : k ≤ t.encard) : ∃ r, s ⊆ r ∧ r ⊆ t ∧ r.encard = k := by obtain (hs \| hs) := eq_or_ne s.encard ⊤ · rw [hs, top_le_iff] at hsk; subst hsk; exact ⟨s, Subset.rfl, hst, hs⟩ obtain ⟨k, rfl⟩ := exists_add_of_le hsk obtain ⟨k', hk'⟩ := exists_add_of_le hkt have hk : k ≤ encard (t \ s) := by rw [← encard_diff_add_encard_of_subset hst, add_comm] at hkt exact WithTop.le_of_add_le_add_right hs hkt obtain ⟨r', hr', rfl⟩ := exists_subset_encard_eq hk refine ⟨s ∪ r', subset_union_left, union_subset hst (hr'.trans diff_subset), ?_⟩ rw [encard_union_eq (disjoint_of_subset_right hr' disjoint_sdiff_right)] section Function variable {s : Set α} {t : Set β} {f : α → β} theorem InjOn.encard_image (h : InjOn f s) : (f '' s).encard = s.encard := by rw [encard, ENat.card_image_of_injOn h, encard] theorem encard_congr (e : s ≃ t) : s.encard = t.encard := by rw [← encard_univ_coe, ← encard_univ_coe t, encard_univ, encard_univ, ENat.card_congr e] theorem _root_.Function.Injective.encard_image (hf : f.Injective) (s : Set α) : (f '' s).encard = s.encard := hf.injOn.encard_image theorem _root_.Function.Embedding.encard_le (e : s ↪ t) : s.encard ≤ t.encard := by rw [← encard_univ_coe, ← e.injective.encard_image, ← Subtype.coe_injective.encard_image] exact encard_mono (by simp) theorem encard_image_le (f : α → β) (s : Set α) : (f '' s).encard ≤ s.encard := by obtain (h \| h) := isEmpty_or_nonempty α · rw [s.eq_empty_of_isEmpty]; simp rw [← (f.invFunOn_injOn_image s).encard_image] apply encard_le_encard exact f.invFunOn_image_image_subset s theorem Finite.injOn_of_encard_image_eq (hs : s.Finite) (h : (f '' s).encard = s.encard) : InjOn f s := by obtain (h' \| hne) := isEmpty_or_nonempty α · rw [s.eq_empty_of_isEmpty]; simp rw [← (f.invFunOn_injOn_image s).encard_image] at h rw [injOn_iff_invFunOn_image_image_eq_self] exact hs.eq_of_subset_of_encard_le' (f.invFunOn_image_image_subset s) h.symm.le theorem encard_preimage_of_injective_subset_range (hf : f.Injective) (ht : t ⊆ range f) : (f ⁻¹' t).encard = t.encard := by rw [← hf.encard_image, image_preimage_eq_inter_range, inter_eq_self_of_subset_left ht] lemma encard_preimage_of_bijective (hf : f.Bijective) (t : Set β) : (f ⁻¹' t).encard = t.encard := encard_preimage_of_injective_subset_range hf.injective (by simp [hf.surjective.range_eq]) theorem encard_le_encard_of_injOn (hf : MapsTo f s t) (f_inj : InjOn f s) : s.encard ≤ t.encard := by rw [← f_inj.encard_image]; apply encard_le_encard; rintro _ ⟨x, hx, rfl⟩; exact hf hx theorem Finite.exists_injOn_of_encard_le [Nonempty β] {s : Set α} {t : Set β} (hs : s.Finite) (hle : s.encard ≤ t.encard) : ∃ (f : α → β), s ⊆ f ⁻¹' t ∧ InjOn f s := by classical obtain (rfl \| h \| ⟨a, has, -⟩) := s.eq_empty_or_encard_eq_top_or_encard_diff_singleton_lt · simp · exact (encard_ne_top_iff.mpr hs h).elim obtain ⟨b, hbt⟩ := encard_pos.1 ((encard_pos.2 ⟨_, has⟩).trans_le hle) have hle' : (s \ {a}).encard ≤ (t \ {b}).encard := by rwa [← WithTop.add_le_add_iff_right WithTop.one_ne_top, encard_diff_singleton_add_one has, encard_diff_singleton_add_one hbt] obtain ⟨f₀, hf₀s, hinj⟩ := exists_injOn_of_encard_le hs.diff hle' simp only [preimage_diff, subset_def, mem_diff, mem_singleton_iff, mem_preimage, and_imp] at hf₀s use Function.update f₀ a b rw [← insert_eq_of_mem has, ← insert_diff_singleton, injOn_insert (fun h ↦ h.2 rfl)] simp only [mem_diff, mem_singleton_iff, not_true, and_false, insert_diff_singleton, subset_def, mem_insert_iff, mem_preimage, ne_eq, Function.update_apply, forall_eq_or_imp, ite_true, and_imp, mem_image, ite_eq_left_iff, not_exists, not_and, not_forall, exists_prop, and_iff_right hbt] refine ⟨?_, ?_, fun x hxs hxa ↦ ⟨hxa, (hf₀s x hxs hxa).2⟩⟩ · rintro x hx; split_ifs with h · assumption · exact (hf₀s x hx h).1 exact InjOn.congr hinj (fun x ⟨_, hxa⟩ ↦ by rwa [Function.update_of_ne]) termination_by encard s theorem Finite.exists_bijOn_of_encard_eq [Nonempty β] (hs : s.Finite) (h : s.encard = t.encard) : ∃ (f : α → β), BijOn f s t := by obtain ⟨f, hf, hinj⟩ := hs.exists_injOn_of_encard_le h.le; use f convert hinj.bijOn_image rw [(hs.image f).eq_of_subset_of_encard_le (image_subset_iff.mpr hf) (h.symm.trans hinj.encard_image.symm).le] end Function section ncard open Nat /-- A tactic (for use in default params) that applies `Set.toFinite` to synthesize a `Set.Finite` term. -/ syntax "toFinite_tac" : tactic macro_rules \| `(tactic\| toFinite_tac) => `(tactic\| apply Set.toFinite) /-- A tactic useful for transferring proofs for `encard` to their corresponding `card` statements -/ syntax "to_encard_tac" : tactic macro_rules \| `(tactic\| to_encard_tac) => `(tactic\| simp only [← Nat.cast_le (α := ℕ∞), ← Nat.cast_inj (R := ℕ∞), Nat.cast_add, Nat.cast_one]) /-- The cardinality of `s : Set α` . Has the junk value `0` if `s` is infinite -/ noncomputable def ncard (s : Set α) : ℕ := ENat.toNat s.encard theorem ncard_def (s : Set α) : s.ncard = ENat.toNat s.encard := rfl theorem Finite.cast_ncard_eq (hs : s.Finite) : s.ncard = s.encard := by rwa [ncard, ENat.coe_toNat_eq_self, ne_eq, encard_eq_top_iff, Set.Infinite, not_not] lemma ncard_le_encard (s : Set α) : s.ncard ≤ s.encard := ENat.coe_toNat_le_self _ theorem Nat.card_coe_set_eq (s : Set α) : Nat.card s = s.ncard := by obtain (h \| h) := s.finite_or_infinite · have := h.fintype rw [ncard, h.encard_eq_coe_toFinset_card, Nat.card_eq_fintype_card, toFinite_toFinset, toFinset_card, ENat.toNat_coe] have := infinite_coe_iff.2 h rw [ncard, h.encard_eq, Nat.card_eq_zero_of_infinite, ENat.toNat_top] theorem ncard_eq_toFinset_card (s : Set α) (hs : s.Finite := by toFinite_tac) : s.ncard = hs.toFinset.card := by rw [← Nat.card_coe_set_eq, @Nat.card_eq_fintype_card _ hs.fintype, @Finite.card_toFinset _ _ hs.fintype hs] theorem ncard_eq_toFinset_card' (s : Set α) [Fintype s] : s.ncard = s.toFinset.card := by simp [← Nat.card_coe_set_eq, Nat.card_eq_fintype_card] lemma cast_ncard {s : Set α} (hs : s.Finite) : (s.ncard : Cardinal) = Cardinal.mk s := @Nat.cast_card _ hs theorem encard_le_coe_iff_finite_ncard_le {k : ℕ} : s.encard ≤ k ↔ s.Finite ∧ s.ncard ≤ k := by rw [encard_le_coe_iff, and_congr_right_iff] exact fun hfin ↦ ⟨fun ⟨n₀, hn₀, hle⟩ ↦ by rwa [ncard_def, hn₀, ENat.toNat_coe], fun h ↦ ⟨s.ncard, by rw [hfin.cast_ncard_eq], h⟩⟩ theorem Infinite.ncard (hs : s.Infinite) : s.ncard = 0 := by rw [← Nat.card_coe_set_eq, @Nat.card_eq_zero_of_infinite _ hs.to_subtype] @[gcongr] theorem ncard_le_ncard (hst : s ⊆ t) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ t.ncard := by rw [← Nat.cast_le (α := ℕ∞), ht.cast_ncard_eq, (ht.subset hst).cast_ncard_eq] exact encard_mono hst theorem ncard_mono [Finite α] : @Monotone (Set α) _ _ _ ncard := fun _ _ ↦ ncard_le_ncard @[simp] theorem ncard_eq_zero (hs : s.Finite := by toFinite_tac) : s.ncard = 0 ↔ s = ∅ := by rw [← Nat.cast_inj (R := ℕ∞), hs.cast_ncard_eq, Nat.cast_zero, encard_eq_zero] @[simp, norm_cast] theorem ncard_coe_Finset (s : Finset α) : (s : Set α).ncard = s.card := by rw [ncard_eq_toFinset_card _, Finset.finite_toSet_toFinset] theorem ncard_univ (α : Type) : (univ : Set α).ncard = Nat.card α := by rcases finite_or_infinite α with h \| h · have hft := Fintype.ofFinite α rw [ncard_eq_toFinset_card, Finite.toFinset_univ, Finset.card_univ, Nat.card_eq_fintype_card] rw [Nat.card_eq_zero_of_infinite, Infinite.ncard] exact infinite_univ @[simp] theorem ncard_empty (α : Type) : (∅ : Set α).ncard = 0 := by rw [ncard_eq_zero] theorem ncard_pos (hs : s.Finite := by toFinite_tac) : 0 < s.ncard ↔ s.Nonempty := by rw [pos_iff_ne_zero, Ne, ncard_eq_zero hs, nonempty_iff_ne_empty] protected alias ⟨_, Nonempty.ncard_pos⟩ := ncard_pos theorem ncard_ne_zero_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : s.ncard ≠ 0 := ((ncard_pos hs).mpr ⟨a, h⟩).ne.symm theorem finite_of_ncard_ne_zero (hs : s.ncard ≠ 0) : s.Finite := s.finite_or_infinite.elim id fun h ↦ (hs h.ncard).elim theorem finite_of_ncard_pos (hs : 0 < s.ncard) : s.Finite := finite_of_ncard_ne_zero hs.ne.symm theorem nonempty_of_ncard_ne_zero (hs : s.ncard ≠ 0) : s.Nonempty := by rw [nonempty_iff_ne_empty]; rintro rfl; simp at hs @[simp] theorem ncard_singleton (a : α) : ({a} : Set α).ncard = 1 := by simp [ncard] theorem ncard_singleton_inter (a : α) (s : Set α) : ({a} ∩ s).ncard ≤ 1 := by rw [← Nat.cast_le (α := ℕ∞), (toFinite _).cast_ncard_eq, Nat.cast_one] apply encard_singleton_inter @[simp] theorem ncard_prod : (s ×ˢ t).ncard = s.ncard * t.ncard := by simp [ncard, ENat.toNat_mul] @[simp] theorem ncard_powerset (s : Set α) (hs : s.Finite := by toFinite_tac) : (𝒫 s).ncard = 2 ^ s.ncard := by have h := Cardinal.mk_powerset s rw [← cast_ncard hs.powerset, ← cast_ncard hs] at h norm_cast at h section InsertErase @[simp] theorem ncard_insert_of_not_mem {a : α} (h : a ∉ s) (hs : s.Finite := by toFinite_tac) : (insert a s).ncard = s.ncard + 1 := by rw [← Nat.cast_inj (R := ℕ∞), (hs.insert a).cast_ncard_eq, Nat.cast_add, Nat.cast_one, hs.cast_ncard_eq, encard_insert_of_not_mem h] theorem ncard_insert_of_mem {a : α} (h : a ∈ s) : ncard (insert a s) = s.ncard := by rw [insert_eq_of_mem h] theorem ncard_insert_le (a : α) (s : Set α) : (insert a s).ncard ≤ s.ncard + 1 := by obtain hs \| hs := s.finite_or_infinite · to_encard_tac; rw [hs.cast_ncard_eq, (hs.insert _).cast_ncard_eq]; apply encard_insert_le rw [(hs.mono (subset_insert a s)).ncard] exact Nat.zero_le _ theorem ncard_insert_eq_ite {a : α} [Decidable (a ∈ s)] (hs : s.Finite := by toFinite_tac) : ncard (insert a s) = if a ∈ s then s.ncard else s.ncard + 1 := by by_cases h : a ∈ s · rw [ncard_insert_of_mem h, if_pos h] · rw [ncard_insert_of_not_mem h hs, if_neg h] theorem ncard_le_ncard_insert (a : α) (s : Set α) : s.ncard ≤ (insert a s).ncard := by classical refine s.finite_or_infinite.elim (fun h ↦ ?_) (fun h ↦ by (rw [h.ncard]; exact Nat.zero_le _)) rw [ncard_insert_eq_ite h]; split_ifs <;> simp @[simp] theorem ncard_pair {a b : α} (h : a ≠ b) : ({a, b} : Set α).ncard = 2 := by rw [ncard_insert_of_not_mem, ncard_singleton]; simpa @[simp] theorem ncard_diff_singleton_add_one {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : (s \ {a}).ncard + 1 = s.ncard := by to_encard_tac; rw [hs.cast_ncard_eq, hs.diff.cast_ncard_eq, encard_diff_singleton_add_one h] @[simp] theorem ncard_diff_singleton_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : (s \ {a}).ncard = s.ncard - 1 := eq_tsub_of_add_eq (ncard_diff_singleton_add_one h hs) theorem ncard_diff_singleton_lt_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : (s \ {a}).ncard < s.ncard := by rw [← ncard_diff_singleton_add_one h hs]; apply lt_add_one theorem ncard_diff_singleton_le (s : Set α) (a : α) : (s \ {a}).ncard ≤ s.ncard := by obtain hs \| hs := s.finite_or_infinite · apply ncard_le_ncard diff_subset hs convert zero_le (α := ℕ) _ exact (hs.diff (by simp : Set.Finite {a})).ncard theorem pred_ncard_le_ncard_diff_singleton (s : Set α) (a : α) : s.ncard - 1 ≤ (s \ {a}).ncard := by rcases s.finite_or_infinite with hs \| hs · by_cases h : a ∈ s · rw [ncard_diff_singleton_of_mem h hs] rw [diff_singleton_eq_self h] apply Nat.pred_le convert Nat.zero_le _ rw [hs.ncard] theorem ncard_exchange {a b : α} (ha : a ∉ s) (hb : b ∈ s) : (insert a (s \ {b})).ncard = s.ncard := congr_arg ENat.toNat <\| encard_exchange ha hb theorem ncard_exchange' {a b : α} (ha : a ∉ s) (hb : b ∈ s) : (insert a s \ {b}).ncard = s.ncard := by rw [← ncard_exchange ha hb, ← singleton_union, ← singleton_union, union_diff_distrib, @diff_singleton_eq_self _ b {a} fun h ↦ ha (by rwa [← mem_singleton_iff.mp h])] lemma odd_card_insert_iff {a : α} (ha : a ∉ s) (hs : s.Finite := by toFinite_tac) : Odd (insert a s).ncard ↔ Even s.ncard := by rw [ncard_insert_of_not_mem ha hs, Nat.odd_add] simp only [Nat.odd_add, ← Nat.not_even_iff_odd, Nat.not_even_one, iff_false, Decidable.not_not] lemma even_card_insert_iff {a : α} (ha : a ∉ s) (hs : s.Finite := by toFinite_tac) : Even (insert a s).ncard ↔ Odd s.ncard := by rw [ncard_insert_of_not_mem ha hs, Nat.even_add_one, Nat.not_even_iff_odd] end InsertErase variable {f : α → β} theorem ncard_image_le (hs : s.Finite := by toFinite_tac) : (f '' s).ncard ≤ s.ncard := by to_encard_tac; rw [hs.cast_ncard_eq, (hs.image _).cast_ncard_eq]; apply encard_image_le theorem ncard_image_of_injOn (H : Set.InjOn f s) : (f '' s).ncard = s.ncard := congr_arg ENat.toNat <\| H.encard_image theorem injOn_of_ncard_image_eq (h : (f '' s).ncard = s.ncard) (hs : s.Finite := by toFinite_tac) : Set.InjOn f s := by rw [← Nat.cast_inj (R := ℕ∞), hs.cast_ncard_eq, (hs.image _).cast_ncard_eq] at h exact hs.injOn_of_encard_image_eq h theorem ncard_image_iff (hs : s.Finite := by toFinite_tac) : (f '' s).ncard = s.ncard ↔ Set.InjOn f s := ⟨fun h ↦ injOn_of_ncard_image_eq h hs, ncard_image_of_injOn⟩ theorem ncard_image_of_injective (s : Set α) (H : f.Injective) : (f '' s).ncard = s.ncard := ncard_image_of_injOn fun _ _ _ _ h ↦ H h theorem ncard_preimage_of_injective_subset_range {s : Set β} (H : f.Injective) (hs : s ⊆ Set.range f) : (f ⁻¹' s).ncard = s.ncard := by rw [← ncard_image_of_injective _ H, image_preimage_eq_iff.mpr hs] theorem fiber_ncard_ne_zero_iff_mem_image {y : β} (hs : s.Finite := by toFinite_tac) : { x ∈ s \| f x = y }.ncard ≠ 0 ↔ y ∈ f '' s := by refine ⟨nonempty_of_ncard_ne_zero, ?_⟩ rintro ⟨z, hz, rfl⟩ exact @ncard_ne_zero_of_mem _ ({ x ∈ s \| f x = f z }) z (mem_sep hz rfl) (hs.subset (sep_subset _ _)) @[simp] theorem ncard_map (f : α ↪ β) : (f '' s).ncard = s.ncard := ncard_image_of_injective _ f.inj' @[simp] theorem ncard_subtype (P : α → Prop) (s : Set α) : { x : Subtype P \| (x : α) ∈ s }.ncard = (s ∩ setOf P).ncard := by convert (ncard_image_of_injective _ (@Subtype.coe_injective _ P)).symm ext x simp [← and_assoc, exists_eq_right] theorem ncard_inter_le_ncard_left (s t : Set α) (hs : s.Finite := by toFinite_tac) : (s ∩ t).ncard ≤ s.ncard := ncard_le_ncard inter_subset_left hs theorem ncard_inter_le_ncard_right (s t : Set α) (ht : t.Finite := by toFinite_tac) : (s ∩ t).ncard ≤ t.ncard := ncard_le_ncard inter_subset_right ht theorem eq_of_subset_of_ncard_le (h : s ⊆ t) (h' : t.ncard ≤ s.ncard) (ht : t.Finite := by toFinite_tac) : s = t := ht.eq_of_subset_of_encard_le' h (by rwa [← Nat.cast_le (α := ℕ∞), ht.cast_ncard_eq, (ht.subset h).cast_ncard_eq] at h') theorem subset_iff_eq_of_ncard_le (h : t.ncard ≤ s.ncard) (ht : t.Finite := by toFinite_tac) : s ⊆ t ↔ s = t := ⟨fun hst ↦ eq_of_subset_of_ncard_le hst h ht, Eq.subset'⟩ theorem map_eq_of_subset {f : α ↪ α} (h : f '' s ⊆ s) (hs : s.Finite := by toFinite_tac) : f '' s = s := eq_of_subset_of_ncard_le h (ncard_map _).ge hs theorem sep_of_ncard_eq {a : α} {P : α → Prop} (h : { x ∈ s \| P x }.ncard = s.ncard) (ha : a ∈ s) (hs : s.Finite := by toFinite_tac) : P a := sep_eq_self_iff_mem_true.mp (eq_of_subset_of_ncard_le (by simp) h.symm.le hs) _ ha theorem ncard_lt_ncard (h : s ⊂ t) (ht : t.Finite := by toFinite_tac) : s.ncard < t.ncard := by rw [← Nat.cast_lt (α := ℕ∞), ht.cast_ncard_eq, (ht.subset h.subset).cast_ncard_eq] exact (ht.subset h.subset).encard_lt_encard h theorem ncard_strictMono [Finite α] : @StrictMono (Set α) _ _ _ ncard := fun _ _ h ↦ ncard_lt_ncard h theorem ncard_eq_of_bijective {n : ℕ} (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.ncard = n := by let f' : Fin n → α := fun i ↦ f i.val i.is_lt suffices himage : s = f' '' Set.univ by rw [← Fintype.card_fin n, ← Nat.card_eq_fintype_card, ← Set.ncard_univ, himage] exact ncard_image_of_injOn <\| fun i _hi j _hj h ↦ Fin.ext <\| f_inj i.val j.val i.is_lt j.is_lt h ext x simp only [image_univ, mem_range] refine ⟨fun hx ↦ ?_, fun ⟨⟨i, hi⟩, hx⟩ ↦ hx ▸ hf' i hi⟩ obtain ⟨i, hi, rfl⟩ := hf x hx use ⟨i, hi⟩ theorem ncard_congr {t : Set β} (f : ∀ a ∈ s, β) (h₁ : ∀ a ha, f a ha ∈ t) (h₂ : ∀ a b ha hb, f a ha = f b hb → a = b) (h₃ : ∀ b ∈ t, ∃ a ha, f a ha = b) : s.ncard = t.ncard := by set f' : s → t := fun x ↦ ⟨f x.1 x.2, h₁ _ _⟩ have hbij : f'.Bijective := by constructor · rintro ⟨x, hx⟩ ⟨y, hy⟩ hxy simp only [f', Subtype.mk.injEq] at hxy ⊢ exact h₂ _ _ hx hy hxy rintro ⟨y, hy⟩ obtain ⟨a, ha, rfl⟩ := h₃ y hy simp only [Subtype.mk.injEq, Subtype.exists] exact ⟨_, ha, rfl⟩ simp_rw [← Nat.card_coe_set_eq] exact Nat.card_congr (Equiv.ofBijective f' hbij) theorem ncard_le_ncard_of_injOn {t : Set β} (f : α → β) (hf : ∀ a ∈ s, f a ∈ t) (f_inj : InjOn f s) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ t.ncard := by have hle := encard_le_encard_of_injOn hf f_inj to_encard_tac; rwa [ht.cast_ncard_eq, (ht.finite_of_encard_le hle).cast_ncard_eq] theorem exists_ne_map_eq_of_ncard_lt_of_maps_to {t : Set β} (hc : t.ncard < s.ncard) {f : α → β} (hf : ∀ a ∈ s, f a ∈ t) (ht : t.Finite := by toFinite_tac) : ∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ f x = f y := by by_contra h' simp only [Ne, exists_prop, not_exists, not_and, not_imp_not] at h' exact (ncard_le_ncard_of_injOn f hf h' ht).not_lt hc theorem le_ncard_of_inj_on_range {n : ℕ} (f : ℕ → α) (hf : ∀ i < n, f i ∈ s) (f_inj : ∀ i < n, ∀ j < n, f i = f j → i = j) (hs : s.Finite := by toFinite_tac) : n ≤ s.ncard := by rw [ncard_eq_toFinset_card _ hs] apply Finset.le_card_of_inj_on_range <;> simpa theorem surj_on_of_inj_on_of_ncard_le {t : Set β} (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.ncard ≤ s.ncard) (ht : t.Finite := by toFinite_tac) : ∀ b ∈ t, ∃ a ha, b = f a ha := by intro b hb set f' : s → t := fun x ↦ ⟨f x.1 x.2, hf _ _⟩ have finj : f'.Injective := by rintro ⟨x, hx⟩ ⟨y, hy⟩ hxy simp only [f', Subtype.mk.injEq] at hxy ⊢ apply hinj _ _ hx hy hxy have hft := ht.fintype have hft' := Fintype.ofInjective f' finj set f'' : ∀ a, a ∈ s.toFinset → β := fun a h ↦ f a (by simpa using h) convert @Finset.surj_on_of_inj_on_of_card_le _ _ _ t.toFinset f'' _ _ _ _ (by simpa) using 1 · simp [f''] · simp [f'', hf] · intros a₁ a₂ ha₁ ha₂ h rw [mem_toFinset] at ha₁ ha₂ exact hinj _ _ ha₁ ha₂ h rwa [← ncard_eq_toFinset_card', ← ncard_eq_toFinset_card'] theorem inj_on_of_surj_on_of_ncard_le {t : Set β} (f : ∀ a ∈ s, β) (hf : ∀ a ha, f a ha ∈ t) (hsurj : ∀ b ∈ t, ∃ a ha, f a ha = b) (hst : s.ncard ≤ t.ncard) ⦃a₁⦄ (ha₁ : a₁ ∈ s) ⦃a₂⦄ (ha₂ : a₂ ∈ s) (ha₁a₂ : f a₁ ha₁ = f a₂ ha₂) (hs : s.Finite := by toFinite_tac) : a₁ = a₂ := by classical set f' : s → t := fun x ↦ ⟨f x.1 x.2, hf _ _⟩ have hsurj : f'.Surjective := by rintro ⟨y, hy⟩ obtain ⟨a, ha, rfl⟩ := hsurj y hy simp only [Subtype.mk.injEq, Subtype.exists] exact ⟨_, ha, rfl⟩ haveI := hs.fintype haveI := Fintype.ofSurjective _ hsurj set f'' : ∀ a, a ∈ s.toFinset → β := fun a h ↦ f a (by simpa using h) exact @Finset.inj_on_of_surj_on_of_card_le _ _ _ t.toFinset f'' (fun a ha ↦ by { rw [mem_toFinset] at ha ⊢; exact hf a ha }) (by simpa) (by { rwa [← ncard_eq_toFinset_card', ← ncard_eq_toFinset_card'] }) a₁ (by simpa) a₂ (by simpa) (by simpa) @[simp] theorem ncard_coe {α : Type} (s : Set α) : Set.ncard (Set.univ : Set (Set.Elem s)) = s.ncard := Set.ncard_congr (fun a ha ↦ ↑a) (fun a ha ↦ a.prop) (by simp) (by simp) @[simp] lemma ncard_graphOn (s : Set α) (f : α → β) : (s.graphOn f).ncard = s.ncard := by rw [← ncard_image_of_injOn fst_injOn_graph, image_fst_graphOn] section Lattice theorem ncard_union_add_ncard_inter (s t : Set α) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s ∪ t).ncard + (s ∩ t).ncard = s.ncard + t.ncard := by to_encard_tac; rw [hs.cast_ncard_eq, ht.cast_ncard_eq, (hs.union ht).cast_ncard_eq, (hs.subset inter_subset_left).cast_ncard_eq, encard_union_add_encard_inter] theorem ncard_inter_add_ncard_union (s t : Set α) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s ∩ t).ncard + (s ∪ t).ncard = s.ncard + t.ncard := by rw [add_comm, ncard_union_add_ncard_inter _ _ hs ht] theorem ncard_union_le (s t : Set α) : (s ∪ t).ncard ≤ s.ncard + t.ncard := by obtain (h \| h) := (s ∪ t).finite_or_infinite · to_encard_tac rw [h.cast_ncard_eq, (h.subset subset_union_left).cast_ncard_eq, (h.subset subset_union_right).cast_ncard_eq] apply encard_union_le rw [h.ncard] apply zero_le theorem ncard_union_eq (h : Disjoint s t) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s ∪ t).ncard = s.ncard + t.ncard := by to_encard_tac rw [hs.cast_ncard_eq, ht.cast_ncard_eq, (hs.union ht).cast_ncard_eq, encard_union_eq h] theorem ncard_diff_add_ncard_of_subset (h : s ⊆ t) (ht : t.Finite := by toFinite_tac) : (t \ s).ncard + s.ncard = t.ncard := by to_encard_tac rw [ht.cast_ncard_eq, (ht.subset h).cast_ncard_eq, ht.diff.cast_ncard_eq, encard_diff_add_encard_of_subset h] theorem ncard_diff (hst : s ⊆ t) (hs : s.Finite := by toFinite_tac) : (t \ s).ncard = t.ncard - s.ncard := by obtain ht \| ht := t.finite_or_infinite · rw [← ncard_diff_add_ncard_of_subset hst ht, add_tsub_cancel_right] · rw [ht.ncard, Nat.zero_sub, (ht.diff hs).ncard] lemma cast_ncard_sdiff {R : Type} [AddGroupWithOne R] (hst : s ⊆ t) (ht : t.Finite) : ((t \ s).ncard : R) = t.ncard - s.ncard := by rw [ncard_diff hst (ht.subset hst), Nat.cast_sub (ncard_le_ncard hst ht)] theorem ncard_le_ncard_diff_add_ncard (s t : Set α) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ (s \ t).ncard + t.ncard := by rcases s.finite_or_infinite with hs \| hs · to_encard_tac rw [ht.cast_ncard_eq, hs.cast_ncard_eq, hs.diff.cast_ncard_eq] apply encard_le_encard_diff_add_encard convert Nat.zero_le _ rw [hs.ncard] theorem le_ncard_diff (s t : Set α) (hs : s.Finite := by toFinite_tac) : t.ncard - s.ncard ≤ (t \ s).ncard := tsub_le_iff_left.mpr (by rw [add_comm]; apply ncard_le_ncard_diff_add_ncard _ _ hs) theorem ncard_diff_add_ncard (s t : Set α) (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : (s \ t).ncard + t.ncard = (s ∪ t).ncard := by rw [← ncard_union_eq disjoint_sdiff_left hs.diff ht, diff_union_self] theorem diff_nonempty_of_ncard_lt_ncard (h : s.ncard < t.ncard) (hs : s.Finite := by toFinite_tac) : (t \ s).Nonempty := by rw [Set.nonempty_iff_ne_empty, Ne, diff_eq_empty] exact fun h' ↦ h.not_le (ncard_le_ncard h' hs) theorem exists_mem_not_mem_of_ncard_lt_ncard (h : s.ncard < t.ncard) (hs : s.Finite := by toFinite_tac) : ∃ e, e ∈ t ∧ e ∉ s := diff_nonempty_of_ncard_lt_ncard h hs @[simp] theorem ncard_inter_add_ncard_diff_eq_ncard (s t : Set α) (hs : s.Finite := by toFinite_tac) : (s ∩ t).ncard + (s \ t).ncard = s.ncard := by rw [← ncard_union_eq (disjoint_of_subset_left inter_subset_right disjoint_sdiff_right) (hs.inter_of_left _) hs.diff, union_comm, diff_union_inter] theorem ncard_eq_ncard_iff_ncard_diff_eq_ncard_diff (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : s.ncard = t.ncard ↔ (s \ t).ncard = (t \ s).ncard := by rw [← ncard_inter_add_ncard_diff_eq_ncard s t hs, ← ncard_inter_add_ncard_diff_eq_ncard t s ht, inter_comm, add_right_inj] theorem ncard_le_ncard_iff_ncard_diff_le_ncard_diff (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : s.ncard ≤ t.ncard ↔ (s \ t).ncard ≤ (t \ s).ncard := by rw [← ncard_inter_add_ncard_diff_eq_ncard s t hs, ← ncard_inter_add_ncard_diff_eq_ncard t s ht, inter_comm, add_le_add_iff_left] theorem ncard_lt_ncard_iff_ncard_diff_lt_ncard_diff (hs : s.Finite := by toFinite_tac) (ht : t.Finite := by toFinite_tac) : s.ncard < t.ncard ↔ (s \ t).ncard < (t \ s).ncard := by rw [← ncard_inter_add_ncard_diff_eq_ncard s t hs, ← ncard_inter_add_ncard_diff_eq_ncard t s ht, inter_comm, add_lt_add_iff_left] theorem ncard_add_ncard_compl (s : Set α) (hs : s.Finite := by toFinite_tac) (hsc : sᶜ.Finite := by toFinite_tac) : s.ncard + sᶜ.ncard = Nat.card α := by rw [← ncard_univ, ← ncard_union_eq (@disjoint_compl_right _ _ s) hs hsc, union_compl_self] theorem eq_univ_iff_ncard [Finite α] (s : Set α) : s = univ ↔ ncard s = Nat.card α := by rw [← compl_empty_iff, ← ncard_eq_zero, ← ncard_add_ncard_compl s, left_eq_add] lemma even_ncard_compl_iff [Finite α] (heven : Even (Nat.card α)) (s : Set α) : Even sᶜ.ncard ↔ Even s.ncard := by simp [compl_eq_univ_diff, ncard_diff (subset_univ _ : s ⊆ Set.univ), Nat.even_sub (ncard_le_ncard (subset_univ _ : s ⊆ Set.univ)), (ncard_univ _).symm ▸ heven] lemma odd_ncard_compl_iff [Finite α] (heven : Even (Nat.card α)) (s : Set α) : Odd sᶜ.ncard ↔ Odd s.ncard := by rw [← Nat.not_even_iff_odd, even_ncard_compl_iff heven, Nat.not_even_iff_odd] end Lattice /-- Given a subset `s` of a set `t`, of sizes at most and at least `n` respectively, there exists a set `u` of size `n` which is both a superset of `s` and a subset of `t`. -/ lemma exists_subsuperset_card_eq {n : ℕ} (hst : s ⊆ t) (hsn : s.ncard ≤ n) (hnt : n ≤ t.ncard) : ∃ u, s ⊆ u ∧ u ⊆ t ∧ u.ncard = n := by obtain ht \| ht := t.infinite_or_finite · rw [ht.ncard, Nat.le_zero, ← ht.ncard] at hnt exact ⟨t, hst, Subset.rfl, hnt.symm⟩ lift s to Finset α using ht.subset hst lift t to Finset α using ht obtain ⟨u, hsu, hut, hu⟩ := Finset.exists_subsuperset_card_eq (mod_cast hst) (by simpa using hsn) (mod_cast hnt) exact ⟨u, mod_cast hsu, mod_cast hut, mod_cast hu⟩ /-- We can shrink a set to any smaller size. -/ lemma exists_subset_card_eq {n : ℕ} (hns : n ≤ s.ncard) : ∃ t ⊆ s, t.ncard = n := by simpa using exists_subsuperset_card_eq s.empty_subset (by simp) hns theorem Infinite.exists_subset_ncard_eq {s : Set α} (hs : s.Infinite) (k : ℕ) : ∃ t, t ⊆ s ∧ t.Finite ∧ t.ncard = k := by have := hs.to_subtype obtain ⟨t', -, rfl⟩ := @Infinite.exists_subset_card_eq s univ infinite_univ k refine ⟨Subtype.val '' (t' : Set s), by simp, Finite.image _ (by simp), ?_⟩ rw [ncard_image_of_injective _ Subtype.coe_injective] simp theorem Infinite.exists_superset_ncard_eq {s t : Set α} (ht : t.Infinite) (hst : s ⊆ t) (hs : s.Finite) {k : ℕ} (hsk : s.ncard ≤ k) : ∃ s', s ⊆ s' ∧ s' ⊆ t ∧ s'.ncard = k := by obtain ⟨s₁, hs₁, hs₁fin, hs₁card⟩ := (ht.diff hs).exists_subset_ncard_eq (k - s.ncard) refine ⟨s ∪ s₁, subset_union_left, union_subset hst (hs₁.trans diff_subset), ?_⟩ rwa [ncard_union_eq (disjoint_of_subset_right hs₁ disjoint_sdiff_right) hs hs₁fin, hs₁card, add_tsub_cancel_of_le] theorem exists_subset_or_subset_of_two_mul_lt_ncard {n : ℕ} (hst : 2 * n < (s ∪ t).ncard) : ∃ r : Set α, n < r.ncard ∧ (r ⊆ s ∨ r ⊆ t) := by classical have hu := finite_of_ncard_ne_zero ((Nat.zero_le _).trans_lt hst).ne.symm rw [ncard_eq_toFinset_card _ hu, Finite.toFinset_union (hu.subset subset_union_left) (hu.subset subset_union_right)] at hst obtain ⟨r', hnr', hr'⟩ := Finset.exists_subset_or_subset_of_two_mul_lt_card hst exact ⟨r', by simpa, by simpa using hr'⟩ /-! ### Explicit description of a set from its cardinality -/ @[simp] theorem ncard_eq_one : s.ncard = 1 ↔ ∃ a, s = {a} := by refine ⟨fun h ↦ ?_, by rintro ⟨a, rfl⟩; rw [ncard_singleton]⟩ have hft := (finite_of_ncard_ne_zero (ne_zero_of_eq_one h)).fintype simp_rw [ncard_eq_toFinset_card', @Finset.card_eq_one _ (toFinset s)] at h refine h.imp fun a ha ↦ ?_ simp_rw [Set.ext_iff, mem_singleton_iff] simp only [Finset.ext_iff, mem_toFinset, Finset.mem_singleton] at ha exact ha theorem exists_eq_insert_iff_ncard (hs : s.Finite := by toFinite_tac) : (∃ a ∉ s, insert a s = t) ↔ s ⊆ t ∧ s.ncard + 1 = t.ncard := by classical	rcases t.finite_or_infinite with ht \| ht · rw [ncard_eq_toFinset_card _ hs, ncard_eq_toFinset_card _ ht, ← @Finite.toFinset_subset_toFinset _ _ _ hs ht, ← Finset.exists_eq_insert_iff] convert Iff.rfl using 2; simp only [Finite.mem_toFinset] ext x simp [Finset.ext_iff, Set.ext_iff] simp only [ht.ncard, exists_prop, add_eq_zero, and_false, iff_false, not_exists, not_and, reduceCtorEq]	Mathlib/Data/Set/Card.lean	1,007	1,014
/- Copyright (c) 2021 Anatole Dedecker. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anatole Dedecker, Bhavik Mehta -/ import Mathlib.Analysis.Calculus.Deriv.Support import Mathlib.Analysis.SpecialFunctions.Pow.Deriv import Mathlib.MeasureTheory.Function.Jacobian import Mathlib.MeasureTheory.Integral.IntervalIntegral.IntegrationByParts import Mathlib.MeasureTheory.Measure.Haar.NormedSpace import Mathlib.MeasureTheory.Measure.Haar.Unique /-! # Links between an integral and its "improper" version In its current state, mathlib only knows how to talk about definite ("proper") integrals, in the sense that it treats integrals over `[x, +∞)` the same as it treats integrals over `[y, z]`. For example, the integral over `[1, +∞)` is not defined to be the limit of the integral over `[1, x]` as `x` tends to `+∞`, which is known as an improper integral. Indeed, the "proper" definition is stronger than the "improper" one. The usual counterexample is `x ↦ sin(x)/x`, which has an improper integral over `[1, +∞)` but no definite integral. Although definite integrals have better properties, they are hardly usable when it comes to computing integrals on unbounded sets, which is much easier using limits. Thus, in this file, we prove various ways of studying the proper integral by studying the improper one. ## Definitions The main definition of this file is `MeasureTheory.AECover`. It is a rather technical definition whose sole purpose is generalizing and factoring proofs. Given an index type `ι`, a countably generated filter `l` over `ι`, and an `ι`-indexed family `φ` of subsets of a measurable space `α` equipped with a measure `μ`, one should think of a hypothesis `hφ : MeasureTheory.AECover μ l φ` as a sufficient condition for being able to interpret `∫ x, f x ∂μ` (if it exists) as the limit of `∫ x in φ i, f x ∂μ` as `i` tends to `l`. When using this definition with a measure restricted to a set `s`, which happens fairly often, one should not try too hard to use a `MeasureTheory.AECover` of subsets of `s`, as it often makes proofs more complicated than necessary. See for example the proof of `MeasureTheory.integrableOn_Iic_of_intervalIntegral_norm_tendsto` where we use `(fun x ↦ oi x)` as a `MeasureTheory.AECover` w.r.t. `μ.restrict (Iic b)`, instead of using `(fun x ↦ Ioc x b)`. ## Main statements - `MeasureTheory.AECover.lintegral_tendsto_of_countably_generated` : if `φ` is a `MeasureTheory.AECover μ l`, where `l` is a countably generated filter, and if `f` is a measurable `ENNReal`-valued function, then `∫⁻ x in φ n, f x ∂μ` tends to `∫⁻ x, f x ∂μ` as `n` tends to `l` - `MeasureTheory.AECover.integrable_of_integral_norm_tendsto` : if `φ` is a `MeasureTheory.AECover μ l`, where `l` is a countably generated filter, if `f` is measurable and integrable on each `φ n`, and if `∫ x in φ n, ‖f x‖ ∂μ` tends to some `I : ℝ` as n tends to `l`, then `f` is integrable - `MeasureTheory.AECover.integral_tendsto_of_countably_generated` : if `φ` is a `MeasureTheory.AECover μ l`, where `l` is a countably generated filter, and if `f` is measurable and integrable (globally), then `∫ x in φ n, f x ∂μ` tends to `∫ x, f x ∂μ` as `n` tends to `+∞`. We then specialize these lemmas to various use cases involving intervals, which are frequent in analysis. In particular, - `MeasureTheory.integral_Ioi_of_hasDerivAt_of_tendsto` is a version of FTC-2 on the interval `(a, +∞)`, giving the formula `∫ x in (a, +∞), g' x = l - g a` if `g'` is integrable and `g` tends to `l` at `+∞`. - `MeasureTheory.integral_Ioi_of_hasDerivAt_of_nonneg` gives the same result assuming that `g'` is nonnegative instead of integrable. Its automatic integrability in this context is proved in `MeasureTheory.integrableOn_Ioi_deriv_of_nonneg`. - `MeasureTheory.integral_comp_smul_deriv_Ioi` is a version of the change of variables formula on semi-infinite intervals. - `MeasureTheory.tendsto_limUnder_of_hasDerivAt_of_integrableOn_Ioi` shows that a function whose derivative is integrable on `(a, +∞)` has a limit at `+∞`. - `MeasureTheory.tendsto_zero_of_hasDerivAt_of_integrableOn_Ioi` shows that an integrable function whose derivative is integrable on `(a, +∞)` tends to `0` at `+∞`. Versions of these results are also given on the intervals `(-∞, a]` and `(-∞, +∞)`, as well as the corresponding versions of integration by parts. -/ open MeasureTheory Filter Set TopologicalSpace Topology open scoped ENNReal NNReal namespace MeasureTheory section AECover variable {α ι : Type} [MeasurableSpace α] (μ : Measure α) (l : Filter ι) /-- A sequence `φ` of subsets of `α` is a `MeasureTheory.AECover` w.r.t. a measure `μ` and a filter `l` if almost every point (w.r.t. `μ`) of `α` eventually belongs to `φ n` (w.r.t. `l`), and if each `φ n` is measurable. This definition is a technical way to avoid duplicating a lot of proofs. It should be thought of as a sufficient condition for being able to interpret `∫ x, f x ∂μ` (if it exists) as the limit of `∫ x in φ n, f x ∂μ` as `n` tends to `l`. See for example `MeasureTheory.AECover.lintegral_tendsto_of_countably_generated`, `MeasureTheory.AECover.integrable_of_integral_norm_tendsto` and `MeasureTheory.AECover.integral_tendsto_of_countably_generated`. -/ structure AECover (φ : ι → Set α) : Prop where ae_eventually_mem : ∀ᵐ x ∂μ, ∀ᶠ i in l, x ∈ φ i protected measurableSet : ∀ i, MeasurableSet <\| φ i variable {μ} {l} namespace AECover /-! ## Operations on `AECover`s -/ /-- Elementwise intersection of two `AECover`s is an `AECover`. -/ theorem inter {φ ψ : ι → Set α} (hφ : AECover μ l φ) (hψ : AECover μ l ψ) : AECover μ l (fun i ↦ φ i ∩ ψ i) where ae_eventually_mem := hψ.1.mp <\| hφ.1.mono fun _ ↦ Eventually.and measurableSet _ := (hφ.2 _).inter (hψ.2 _) theorem superset {φ ψ : ι → Set α} (hφ : AECover μ l φ) (hsub : ∀ i, φ i ⊆ ψ i) (hmeas : ∀ i, MeasurableSet (ψ i)) : AECover μ l ψ := ⟨hφ.1.mono fun _x hx ↦ hx.mono fun i hi ↦ hsub i hi, hmeas⟩ theorem mono_ac {ν : Measure α} {φ : ι → Set α} (hφ : AECover μ l φ) (hle : ν ≪ μ) : AECover ν l φ := ⟨hle hφ.1, hφ.2⟩ theorem mono {ν : Measure α} {φ : ι → Set α} (hφ : AECover μ l φ) (hle : ν ≤ μ) : AECover ν l φ := hφ.mono_ac hle.absolutelyContinuous end AECover section MetricSpace variable [PseudoMetricSpace α] [OpensMeasurableSpace α] theorem aecover_ball {x : α} {r : ι → ℝ} (hr : Tendsto r l atTop) : AECover μ l (fun i ↦ Metric.ball x (r i)) where measurableSet _ := Metric.isOpen_ball.measurableSet ae_eventually_mem := by filter_upwards with y filter_upwards [hr (Ioi_mem_atTop (dist x y))] with a ha using by simpa [dist_comm] using ha theorem aecover_closedBall {x : α} {r : ι → ℝ} (hr : Tendsto r l atTop) : AECover μ l (fun i ↦ Metric.closedBall x (r i)) where measurableSet _ := Metric.isClosed_closedBall.measurableSet ae_eventually_mem := by filter_upwards with y filter_upwards [hr (Ici_mem_atTop (dist x y))] with a ha using by simpa [dist_comm] using ha end MetricSpace section Preorderα variable [Preorder α] [TopologicalSpace α] [OrderClosedTopology α] [OpensMeasurableSpace α] {a b : ι → α} theorem aecover_Ici (ha : Tendsto a l atBot) : AECover μ l fun i => Ici (a i) where ae_eventually_mem := ae_of_all μ ha.eventually_le_atBot measurableSet _ := measurableSet_Ici theorem aecover_Iic (hb : Tendsto b l atTop) : AECover μ l fun i => Iic <\| b i := aecover_Ici (α := αᵒᵈ) hb theorem aecover_Icc (ha : Tendsto a l atBot) (hb : Tendsto b l atTop) : AECover μ l fun i => Icc (a i) (b i) := (aecover_Ici ha).inter (aecover_Iic hb) end Preorderα section LinearOrderα variable [LinearOrder α] [TopologicalSpace α] [OrderClosedTopology α] [OpensMeasurableSpace α] {a b : ι → α} (ha : Tendsto a l atBot) (hb : Tendsto b l atTop) include ha in theorem aecover_Ioi [NoMinOrder α] : AECover μ l fun i => Ioi (a i) where ae_eventually_mem := ae_of_all μ ha.eventually_lt_atBot measurableSet _ := measurableSet_Ioi include hb in theorem aecover_Iio [NoMaxOrder α] : AECover μ l fun i => Iio (b i) := aecover_Ioi (α := αᵒᵈ) hb include ha hb theorem aecover_Ioo [NoMinOrder α] [NoMaxOrder α] : AECover μ l fun i => Ioo (a i) (b i) := (aecover_Ioi ha).inter (aecover_Iio hb) theorem aecover_Ioc [NoMinOrder α] : AECover μ l fun i => Ioc (a i) (b i) := (aecover_Ioi ha).inter (aecover_Iic hb) theorem aecover_Ico [NoMaxOrder α] : AECover μ l fun i => Ico (a i) (b i) := (aecover_Ici ha).inter (aecover_Iio hb) end LinearOrderα section FiniteIntervals variable [LinearOrder α] [TopologicalSpace α] [OrderClosedTopology α] [OpensMeasurableSpace α] {a b : ι → α} {A B : α} (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) include ha in theorem aecover_Ioi_of_Ioi : AECover (μ.restrict (Ioi A)) l fun i ↦ Ioi (a i) where ae_eventually_mem := (ae_restrict_mem measurableSet_Ioi).mono fun _x hx ↦ ha.eventually <\| eventually_lt_nhds hx measurableSet _ := measurableSet_Ioi include hb in theorem aecover_Iio_of_Iio : AECover (μ.restrict (Iio B)) l fun i ↦ Iio (b i) := aecover_Ioi_of_Ioi (α := αᵒᵈ) hb include ha in theorem aecover_Ioi_of_Ici : AECover (μ.restrict (Ioi A)) l fun i ↦ Ici (a i) := (aecover_Ioi_of_Ioi ha).superset (fun _ ↦ Ioi_subset_Ici_self) fun _ ↦ measurableSet_Ici include hb in theorem aecover_Iio_of_Iic : AECover (μ.restrict (Iio B)) l fun i ↦ Iic (b i) := aecover_Ioi_of_Ici (α := αᵒᵈ) hb include ha hb in theorem aecover_Ioo_of_Ioo : AECover (μ.restrict <\| Ioo A B) l fun i => Ioo (a i) (b i) := ((aecover_Ioi_of_Ioi ha).mono <\| Measure.restrict_mono Ioo_subset_Ioi_self le_rfl).inter ((aecover_Iio_of_Iio hb).mono <\| Measure.restrict_mono Ioo_subset_Iio_self le_rfl) include ha hb in theorem aecover_Ioo_of_Icc : AECover (μ.restrict <\| Ioo A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).superset (fun _ ↦ Ioo_subset_Icc_self) fun _ ↦ measurableSet_Icc include ha hb in theorem aecover_Ioo_of_Ico : AECover (μ.restrict <\| Ioo A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).superset (fun _ ↦ Ioo_subset_Ico_self) fun _ ↦ measurableSet_Ico include ha hb in theorem aecover_Ioo_of_Ioc : AECover (μ.restrict <\| Ioo A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).superset (fun _ ↦ Ioo_subset_Ioc_self) fun _ ↦ measurableSet_Ioc variable [NoAtoms μ] theorem aecover_Ioc_of_Icc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Icc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ioc_of_Ico (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ico ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ioc_of_Ioc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ioc_of_Ioo (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Ioo (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ico_of_Icc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Icc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Ico_of_Ico (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ico ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Ico_of_Ioc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Ico_of_Ioo (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Ioo (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Icc_of_Icc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Icc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge theorem aecover_Icc_of_Ico (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ico ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge theorem aecover_Icc_of_Ioc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge theorem aecover_Icc_of_Ioo (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Ioo (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge end FiniteIntervals protected theorem AECover.restrict {φ : ι → Set α} (hφ : AECover μ l φ) {s : Set α} : AECover (μ.restrict s) l φ := hφ.mono Measure.restrict_le_self theorem aecover_restrict_of_ae_imp {s : Set α} {φ : ι → Set α} (hs : MeasurableSet s) (ae_eventually_mem : ∀ᵐ x ∂μ, x ∈ s → ∀ᶠ n in l, x ∈ φ n) (measurable : ∀ n, MeasurableSet <\| φ n) : AECover (μ.restrict s) l φ where ae_eventually_mem := by rwa [ae_restrict_iff' hs] measurableSet := measurable theorem AECover.inter_restrict {φ : ι → Set α} (hφ : AECover μ l φ) {s : Set α} (hs : MeasurableSet s) : AECover (μ.restrict s) l fun i => φ i ∩ s := aecover_restrict_of_ae_imp hs (hφ.ae_eventually_mem.mono fun _x hx hxs => hx.mono fun _i hi => ⟨hi, hxs⟩) fun i => (hφ.measurableSet i).inter hs theorem AECover.ae_tendsto_indicator {β : Type} [Zero β] [TopologicalSpace β] (f : α → β) {φ : ι → Set α} (hφ : AECover μ l φ) : ∀ᵐ x ∂μ, Tendsto (fun i => (φ i).indicator f x) l (𝓝 <\| f x) := hφ.ae_eventually_mem.mono fun _x hx => tendsto_const_nhds.congr' <\| hx.mono fun _n hn => (indicator_of_mem hn _).symm theorem AECover.aemeasurable {β : Type} [MeasurableSpace β] [l.IsCountablyGenerated] [l.NeBot] {f : α → β} {φ : ι → Set α} (hφ : AECover μ l φ) (hfm : ∀ i, AEMeasurable f (μ.restrict <\| φ i)) : AEMeasurable f μ := by obtain ⟨u, hu⟩ := l.exists_seq_tendsto have := aemeasurable_iUnion_iff.mpr fun n : ℕ => hfm (u n) rwa [Measure.restrict_eq_self_of_ae_mem] at this filter_upwards [hφ.ae_eventually_mem] with x hx using mem_iUnion.mpr (hu.eventually hx).exists theorem AECover.aestronglyMeasurable {β : Type} [TopologicalSpace β] [PseudoMetrizableSpace β] [l.IsCountablyGenerated] [l.NeBot] {f : α → β} {φ : ι → Set α} (hφ : AECover μ l φ) (hfm : ∀ i, AEStronglyMeasurable f (μ.restrict <\| φ i)) : AEStronglyMeasurable f μ := by obtain ⟨u, hu⟩ := l.exists_seq_tendsto have := aestronglyMeasurable_iUnion_iff.mpr fun n : ℕ => hfm (u n) rwa [Measure.restrict_eq_self_of_ae_mem] at this filter_upwards [hφ.ae_eventually_mem] with x hx using mem_iUnion.mpr (hu.eventually hx).exists end AECover theorem AECover.comp_tendsto {α ι ι' : Type} [MeasurableSpace α] {μ : Measure α} {l : Filter ι} {l' : Filter ι'} {φ : ι → Set α} (hφ : AECover μ l φ) {u : ι' → ι} (hu : Tendsto u l' l) : AECover μ l' (φ ∘ u) where ae_eventually_mem := hφ.ae_eventually_mem.mono fun _x hx => hu.eventually hx measurableSet i := hφ.measurableSet (u i) section AECoverUnionInterCountable variable {α ι : Type} [Countable ι] [MeasurableSpace α] {μ : Measure α} theorem AECover.biUnion_Iic_aecover [Preorder ι] {φ : ι → Set α} (hφ : AECover μ atTop φ) : AECover μ atTop fun n : ι => ⋃ (k) (_h : k ∈ Iic n), φ k := hφ.superset (fun _ ↦ subset_biUnion_of_mem right_mem_Iic) fun _ ↦ .biUnion (to_countable _) fun _ _ ↦ (hφ.2 _) theorem AECover.biInter_Ici_aecover [Preorder ι] {φ : ι → Set α} (hφ : AECover μ atTop φ) : AECover μ atTop fun n : ι => ⋂ (k) (_h : k ∈ Ici n), φ k where ae_eventually_mem := hφ.ae_eventually_mem.mono fun x h ↦ by simpa only [mem_iInter, mem_Ici, eventually_forall_ge_atTop] measurableSet _ := .biInter (to_countable _) fun n _ => hφ.measurableSet n end AECoverUnionInterCountable section Lintegral variable {α ι : Type} [MeasurableSpace α] {μ : Measure α} {l : Filter ι} private theorem lintegral_tendsto_of_monotone_of_nat {φ : ℕ → Set α} (hφ : AECover μ atTop φ) (hmono : Monotone φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : Tendsto (fun i => ∫⁻ x in φ i, f x ∂μ) atTop (𝓝 <\| ∫⁻ x, f x ∂μ) := let F n := (φ n).indicator f have key₁ : ∀ n, AEMeasurable (F n) μ := fun n => hfm.indicator (hφ.measurableSet n) have key₂ : ∀ᵐ x : α ∂μ, Monotone fun n => F n x := ae_of_all _ fun x _i _j hij => indicator_le_indicator_of_subset (hmono hij) (fun x => zero_le <\| f x) x have key₃ : ∀ᵐ x : α ∂μ, Tendsto (fun n => F n x) atTop (𝓝 (f x)) := hφ.ae_tendsto_indicator f (lintegral_tendsto_of_tendsto_of_monotone key₁ key₂ key₃).congr fun n => lintegral_indicator (hφ.measurableSet n) _ theorem AECover.lintegral_tendsto_of_nat {φ : ℕ → Set α} (hφ : AECover μ atTop φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : Tendsto (∫⁻ x in φ ·, f x ∂μ) atTop (𝓝 <\| ∫⁻ x, f x ∂μ) := by have lim₁ := lintegral_tendsto_of_monotone_of_nat hφ.biInter_Ici_aecover (fun i j hij => biInter_subset_biInter_left (Ici_subset_Ici.mpr hij)) hfm have lim₂ := lintegral_tendsto_of_monotone_of_nat hφ.biUnion_Iic_aecover (fun i j hij => biUnion_subset_biUnion_left (Iic_subset_Iic.mpr hij)) hfm refine tendsto_of_tendsto_of_tendsto_of_le_of_le lim₁ lim₂ (fun n ↦ ?_) fun n ↦ ?_ exacts [lintegral_mono_set (biInter_subset_of_mem left_mem_Ici), lintegral_mono_set (subset_biUnion_of_mem right_mem_Iic)] theorem AECover.lintegral_tendsto_of_countably_generated [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : Tendsto (fun i => ∫⁻ x in φ i, f x ∂μ) l (𝓝 <\| ∫⁻ x, f x ∂μ) := tendsto_of_seq_tendsto fun _u hu => (hφ.comp_tendsto hu).lintegral_tendsto_of_nat hfm theorem AECover.lintegral_eq_of_tendsto [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → ℝ≥0∞} (I : ℝ≥0∞) (hfm : AEMeasurable f μ) (htendsto : Tendsto (fun i => ∫⁻ x in φ i, f x ∂μ) l (𝓝 I)) : ∫⁻ x, f x ∂μ = I := tendsto_nhds_unique (hφ.lintegral_tendsto_of_countably_generated hfm) htendsto theorem AECover.iSup_lintegral_eq_of_countably_generated [Nonempty ι] [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : ⨆ i : ι, ∫⁻ x in φ i, f x ∂μ = ∫⁻ x, f x ∂μ := by have := hφ.lintegral_tendsto_of_countably_generated hfm refine ciSup_eq_of_forall_le_of_forall_lt_exists_gt (fun i => lintegral_mono' Measure.restrict_le_self le_rfl) fun w hw => ?_ exact (this.eventually_const_lt hw).exists end Lintegral section Integrable variable {α ι E : Type} [MeasurableSpace α] {μ : Measure α} {l : Filter ι} [NormedAddCommGroup E] theorem AECover.integrable_of_lintegral_enorm_bounded [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ) (hfm : AEStronglyMeasurable f μ) (hbounded : ∀ᶠ i in l, ∫⁻ x in φ i, ‖f x‖ₑ ∂μ ≤ ENNReal.ofReal I) : Integrable f μ := by refine ⟨hfm, (le_of_tendsto ?_ hbounded).trans_lt ENNReal.ofReal_lt_top⟩ exact hφ.lintegral_tendsto_of_countably_generated hfm.enorm @[deprecated (since := "2025-01-22")] alias AECover.integrable_of_lintegral_nnnorm_bounded := AECover.integrable_of_lintegral_enorm_bounded theorem AECover.integrable_of_lintegral_enorm_tendsto [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ) (hfm : AEStronglyMeasurable f μ) (htendsto : Tendsto (fun i => ∫⁻ x in φ i, ‖f x‖ₑ ∂μ) l (𝓝 <\| .ofReal I)) : Integrable f μ := by refine hφ.integrable_of_lintegral_enorm_bounded (max 1 (I + 1)) hfm ?_ refine htendsto.eventually (ge_mem_nhds ?_) refine (ENNReal.ofReal_lt_ofReal_iff (lt_max_of_lt_left zero_lt_one)).2 ?_ exact lt_max_of_lt_right (lt_add_one I) @[deprecated (since := "2025-01-22")] alias AECover.integrable_of_lintegral_nnnorm_tendsto := AECover.integrable_of_lintegral_enorm_tendsto theorem AECover.integrable_of_lintegral_enorm_bounded' [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ≥0) (hfm : AEStronglyMeasurable f μ) (hbounded : ∀ᶠ i in l, ∫⁻ x in φ i, ‖f x‖ₑ ∂μ ≤ I) : Integrable f μ := hφ.integrable_of_lintegral_enorm_bounded I hfm (by simpa only [ENNReal.ofReal_coe_nnreal] using hbounded) @[deprecated (since := "2025-01-22")] alias AECover.integrable_of_lintegral_nnnorm_bounded' := AECover.integrable_of_lintegral_enorm_bounded' theorem AECover.integrable_of_lintegral_enorm_tendsto' [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ≥0) (hfm : AEStronglyMeasurable f μ) (htendsto : Tendsto (fun i => ∫⁻ x in φ i, ‖f x‖ₑ ∂μ) l (𝓝 I)) : Integrable f μ := hφ.integrable_of_lintegral_enorm_tendsto I hfm (by simpa only [ENNReal.ofReal_coe_nnreal] using htendsto) @[deprecated (since := "2025-01-22")] alias AECover.integrable_of_lintegral_nnnorm_tendsto' := AECover.integrable_of_lintegral_enorm_tendsto'	theorem AECover.integrable_of_integral_norm_bounded [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ) (hfi : ∀ i, IntegrableOn f (φ i) μ) (hbounded : ∀ᶠ i in l, (∫ x in φ i, ‖f x‖ ∂μ) ≤ I) : Integrable f μ := by have hfm : AEStronglyMeasurable f μ := hφ.aestronglyMeasurable fun i => (hfi i).aestronglyMeasurable refine hφ.integrable_of_lintegral_enorm_bounded I hfm ?_ conv at hbounded in integral _ _ =>	Mathlib/MeasureTheory/Integral/IntegralEqImproper.lean	437	444
/- 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.AlgebraicGeometry.Morphisms.UnderlyingMap /-! # Open immersions A morphism is an open immersion if the underlying map of spaces is an open embedding `f : X ⟶ U ⊆ Y`, and the sheaf map `Y(V) ⟶ f _* X(V)` is an iso for each `V ⊆ U`. Most of the theories are developed in `AlgebraicGeometry/OpenImmersion`, and we provide the remaining theorems analogous to other lemmas in `AlgebraicGeometry/Morphisms/*`. -/ noncomputable section open CategoryTheory CategoryTheory.Limits Opposite TopologicalSpace Topology universe u namespace AlgebraicGeometry /-- `Spec (R ⧸ I) ⟶ Spec R` is an open immersion iff `I` is generated by an idempotent. -/ lemma isOpenImmersion_SpecMap_iff_of_surjective {R S : CommRingCat} (f : R ⟶ S) (hf : Function.Surjective f.hom) : IsOpenImmersion (Spec.map f) ↔ ∃ e, IsIdempotentElem e ∧ RingHom.ker f.hom = Ideal.span {e} := by constructor · intro H obtain ⟨e, he, he'⟩ := PrimeSpectrum.isClopen_iff_zeroLocus.mp ⟨PrimeSpectrum.isClosed_range_comap_of_surjective _ _ hf, (Spec.map f).isOpenEmbedding.isOpen_range⟩ refine ⟨e, he, ?_⟩ let φ : R ⟶ _ := (CommRingCat.ofHom (Ideal.Quotient.mk (.span {e}))) have : IsOpenImmersion (Spec.map φ) := have : IsLocalization.Away (1 - e) (↑R ⧸ Ideal.span {e}) := IsLocalization.away_of_isIdempotentElem he.one_sub (by simp) Ideal.Quotient.mk_surjective IsOpenImmersion.of_isLocalization (1 - e) have H : Set.range (Spec.map φ).base = Set.range (Spec.map f).base := ((PrimeSpectrum.range_comap_of_surjective _ _ Ideal.Quotient.mk_surjective).trans (by simp [φ])).trans he'.symm let i : S ≅ .of _ := (Scheme.Spec.preimageIso (IsOpenImmersion.isoOfRangeEq (Spec.map φ) (Spec.map f) H)).unop have hi : Function.Injective i.inv.hom := (ConcreteCategory.bijective_of_isIso i.inv).1 have : f = φ ≫ i.inv := by apply Spec.map_injective; simp [i, ← Scheme.Spec_map] rw [this, CommRingCat.hom_comp, RingHom.ker_eq_comap_bot, ← Ideal.comap_comap,	← RingHom.ker_eq_comap_bot, (RingHom.injective_iff_ker_eq_bot i.inv.hom).mp hi, ← RingHom.ker_eq_comap_bot] simp [φ] · rintro ⟨e, he, he'⟩ letI := f.hom.toAlgebra have : IsLocalization.Away (1 - e) S := IsLocalization.away_of_isIdempotentElem he.one_sub (by simpa using he') hf exact IsOpenImmersion.of_isLocalization (1 - e) variable {X Y : Scheme.{u}} theorem isOpenImmersion_iff_stalk {f : X ⟶ Y} : IsOpenImmersion f ↔ IsOpenEmbedding f.base ∧ ∀ x, IsIso (f.stalkMap x) := by constructor · intro h; exact ⟨h.1, inferInstance⟩ · rintro ⟨h₁, h₂⟩; exact IsOpenImmersion.of_stalk_iso f h₁ theorem isOpenImmersion_eq_inf : @IsOpenImmersion = (topologically IsOpenEmbedding) ⊓ stalkwise (fun f ↦ Function.Bijective f) := by ext exact isOpenImmersion_iff_stalk.trans	Mathlib/AlgebraicGeometry/Morphisms/OpenImmersion.lean	53	74
/- 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.Partrec import Mathlib.Data.Option.Basic /-! # Gödel Numbering for Partial Recursive Functions. This file defines `Nat.Partrec.Code`, an inductive datatype describing code for partial recursive functions on ℕ. It defines an encoding for these codes, and proves that the constructors are primitive recursive with respect to the encoding. It also defines the evaluation of these codes as partial functions using `PFun`, and proves that a function is partially recursive (as defined by `Nat.Partrec`) if and only if it is the evaluation of some code. ## Main Definitions * `Nat.Partrec.Code`: Inductive datatype for partial recursive codes. * `Nat.Partrec.Code.encodeCode`: A (computable) encoding of codes as natural numbers. * `Nat.Partrec.Code.ofNatCode`: The inverse of this encoding. * `Nat.Partrec.Code.eval`: The interpretation of a `Nat.Partrec.Code` as a partial function. ## Main Results * `Nat.Partrec.Code.rec_prim`: Recursion on `Nat.Partrec.Code` is primitive recursive. * `Nat.Partrec.Code.rec_computable`: Recursion on `Nat.Partrec.Code` is computable. * `Nat.Partrec.Code.smn`: The $S_n^m$ theorem. * `Nat.Partrec.Code.exists_code`: Partial recursiveness is equivalent to being the eval of a code. * `Nat.Partrec.Code.evaln_prim`: `evaln` is primitive recursive. * `Nat.Partrec.Code.fixed_point`: Roger's fixed point theorem. * `Nat.Partrec.Code.fixed_point₂`: Kleene's second recursion theorem. ## References * [Mario Carneiro, Formalizing computability theory via partial recursive functions][carneiro2019] -/ open Encodable Denumerable namespace Nat.Partrec theorem rfind' {f} (hf : Nat.Partrec f) :	Nat.Partrec (Nat.unpaired fun a m => (Nat.rfind fun n => (fun m => m = 0) <$> f (Nat.pair a (n + m))).map (· + m)) := Partrec₂.unpaired'.2 <\| by refine Partrec.map ((@Partrec₂.unpaired' fun a b : ℕ => Nat.rfind fun n => (fun m => m = 0) <$> f (Nat.pair a (n + b))).1 ?_) (Primrec.nat_add.comp Primrec.snd <\| Primrec.snd.comp Primrec.fst).to_comp.to₂ have : Nat.Partrec (fun a => Nat.rfind (fun n => (fun m => decide (m = 0)) <$> Nat.unpaired (fun a b => f (Nat.pair (Nat.unpair a).1 (b + (Nat.unpair a).2))) (Nat.pair a n))) := rfind (Partrec₂.unpaired'.2 ((Partrec.nat_iff.2 hf).comp (Primrec₂.pair.comp (Primrec.fst.comp <\| Primrec.unpair.comp Primrec.fst) (Primrec.nat_add.comp Primrec.snd (Primrec.snd.comp <\| Primrec.unpair.comp Primrec.fst))).to_comp)) simpa	Mathlib/Computability/PartrecCode.lean	49	69
/- 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.CharP.Defs import Mathlib.Algebra.GeomSum import Mathlib.Algebra.MvPolynomial.CommRing import Mathlib.Algebra.MvPolynomial.Equiv import Mathlib.Algebra.Polynomial.BigOperators import Mathlib.RingTheory.Noetherian.Basic /-! # Ring-theoretic supplement of Algebra.Polynomial. ## Main results * `MvPolynomial.isDomain`: If a ring is an integral domain, then so is its polynomial ring over finitely many variables. * `Polynomial.isNoetherianRing`: Hilbert basis theorem, that if a ring is noetherian then so is its polynomial ring. -/ noncomputable section open Polynomial open Finset universe u v w variable {R : Type u} {S : Type} namespace Polynomial section Semiring variable [Semiring R] instance instCharP (p : ℕ) [h : CharP R p] : CharP R[X] p := let ⟨h⟩ := h ⟨fun n => by rw [← map_natCast C, ← C_0, C_inj, h]⟩ instance instExpChar (p : ℕ) [h : ExpChar R p] : ExpChar R[X] p := by cases h; exacts [ExpChar.zero, ExpChar.prime ‹_›] variable (R) /-- The `R`-submodule of `R[X]` consisting of polynomials of degree ≤ `n`. -/ def degreeLE (n : WithBot ℕ) : Submodule R R[X] := ⨅ k : ℕ, ⨅ _ : ↑k > n, LinearMap.ker (lcoeff R k) /-- The `R`-submodule of `R[X]` consisting of polynomials of degree < `n`. -/ def degreeLT (n : ℕ) : Submodule R R[X] := ⨅ k : ℕ, ⨅ (_ : k ≥ n), LinearMap.ker (lcoeff R k) variable {R} theorem mem_degreeLE {n : WithBot ℕ} {f : R[X]} : f ∈ degreeLE R n ↔ degree f ≤ n := by simp only [degreeLE, Submodule.mem_iInf, degree_le_iff_coeff_zero, LinearMap.mem_ker]; rfl @[mono] theorem degreeLE_mono {m n : WithBot ℕ} (H : m ≤ n) : degreeLE R m ≤ degreeLE R n := fun _ hf => mem_degreeLE.2 (le_trans (mem_degreeLE.1 hf) H) theorem degreeLE_eq_span_X_pow [DecidableEq R] {n : ℕ} : degreeLE R n = Submodule.span R ↑((Finset.range (n + 1)).image fun n => (X : R[X]) ^ n) := by apply le_antisymm · intro p hp replace hp := mem_degreeLE.1 hp rw [← Polynomial.sum_monomial_eq p, Polynomial.sum] refine Submodule.sum_mem _ fun k hk => ?_ have := WithBot.coe_le_coe.1 (Finset.sup_le_iff.1 hp k hk) rw [← C_mul_X_pow_eq_monomial, C_mul'] refine Submodule.smul_mem _ _ (Submodule.subset_span <\| Finset.mem_coe.2 <\| Finset.mem_image.2 ⟨_, Finset.mem_range.2 (Nat.lt_succ_of_le this), rfl⟩) rw [Submodule.span_le, Finset.coe_image, Set.image_subset_iff] intro k hk apply mem_degreeLE.2 exact (degree_X_pow_le _).trans (WithBot.coe_le_coe.2 <\| Nat.le_of_lt_succ <\| Finset.mem_range.1 hk) theorem mem_degreeLT {n : ℕ} {f : R[X]} : f ∈ degreeLT R n ↔ degree f < n := by rw [degreeLT, Submodule.mem_iInf] conv_lhs => intro i; rw [Submodule.mem_iInf] rw [degree, Finset.max_eq_sup_coe] rw [Finset.sup_lt_iff ?_] rotate_left · apply WithBot.bot_lt_coe conv_rhs => simp only [mem_support_iff] intro b rw [Nat.cast_withBot, WithBot.coe_lt_coe, lt_iff_not_le, Ne, not_imp_not] rfl @[mono] theorem degreeLT_mono {m n : ℕ} (H : m ≤ n) : degreeLT R m ≤ degreeLT R n := fun _ hf => mem_degreeLT.2 (lt_of_lt_of_le (mem_degreeLT.1 hf) <\| WithBot.coe_le_coe.2 H) theorem degreeLT_eq_span_X_pow [DecidableEq R] {n : ℕ} : degreeLT R n = Submodule.span R ↑((Finset.range n).image fun n => X ^ n : Finset R[X]) := by apply le_antisymm · intro p hp replace hp := mem_degreeLT.1 hp rw [← Polynomial.sum_monomial_eq p, Polynomial.sum] refine Submodule.sum_mem _ fun k hk => ?_ have := WithBot.coe_lt_coe.1 ((Finset.sup_lt_iff <\| WithBot.bot_lt_coe n).1 hp k hk) rw [← C_mul_X_pow_eq_monomial, C_mul'] refine Submodule.smul_mem _ _ (Submodule.subset_span <\| Finset.mem_coe.2 <\| Finset.mem_image.2 ⟨_, Finset.mem_range.2 this, rfl⟩) rw [Submodule.span_le, Finset.coe_image, Set.image_subset_iff] intro k hk apply mem_degreeLT.2 exact lt_of_le_of_lt (degree_X_pow_le _) (WithBot.coe_lt_coe.2 <\| Finset.mem_range.1 hk) /-- The first `n` coefficients on `degreeLT n` form a linear equivalence with `Fin n → R`. -/ def degreeLTEquiv (R) [Semiring R] (n : ℕ) : degreeLT R n ≃ₗ[R] Fin n → R where toFun p n := (↑p : R[X]).coeff n invFun f := ⟨∑ i : Fin n, monomial i (f i), (degreeLT R n).sum_mem fun i _ => mem_degreeLT.mpr (lt_of_le_of_lt (degree_monomial_le i (f i)) (WithBot.coe_lt_coe.mpr i.is_lt))⟩ map_add' p q := by ext dsimp rw [coeff_add] map_smul' x p := by ext dsimp rw [coeff_smul] rfl left_inv := by rintro ⟨p, hp⟩ ext1 simp only [Submodule.coe_mk] by_cases hp0 : p = 0 · subst hp0 simp only [coeff_zero, LinearMap.map_zero, Finset.sum_const_zero] rw [mem_degreeLT, degree_eq_natDegree hp0, Nat.cast_lt] at hp conv_rhs => rw [p.as_sum_range' n hp, ← Fin.sum_univ_eq_sum_range] right_inv f := by ext i simp only [finset_sum_coeff, Submodule.coe_mk] rw [Finset.sum_eq_single i, coeff_monomial, if_pos rfl] · rintro j - hji rw [coeff_monomial, if_neg] rwa [← Fin.ext_iff] · intro h exact (h (Finset.mem_univ _)).elim theorem degreeLTEquiv_eq_zero_iff_eq_zero {n : ℕ} {p : R[X]} (hp : p ∈ degreeLT R n) : degreeLTEquiv _ _ ⟨p, hp⟩ = 0 ↔ p = 0 := by simp theorem eval_eq_sum_degreeLTEquiv {n : ℕ} {p : R[X]} (hp : p ∈ degreeLT R n) (x : R) : p.eval x = ∑ i, degreeLTEquiv _ _ ⟨p, hp⟩ i x ^ (i : ℕ) := by simp_rw [eval_eq_sum] exact (sum_fin _ (by simp_rw [zero_mul, forall_const]) (mem_degreeLT.mp hp)).symm theorem degreeLT_succ_eq_degreeLE {n : ℕ} : degreeLT R (n + 1) = degreeLE R n := by ext x by_cases x_zero : x = 0 · simp_rw [x_zero, Submodule.zero_mem] · rw [mem_degreeLT, mem_degreeLE, ← natDegree_lt_iff_degree_lt (by rwa [ne_eq]), ← natDegree_le_iff_degree_le, Nat.lt_succ] /-- The equivalence between monic polynomials of degree `n` and polynomials of degree less than `n`, formed by adding a term `X ^ n`. -/ def monicEquivDegreeLT [Nontrivial R] (n : ℕ) : { p : R[X] // p.Monic ∧ p.natDegree = n } ≃ degreeLT R n where toFun p := ⟨p.1.eraseLead, by rcases p with ⟨p, hp, rfl⟩ simp only [mem_degreeLT] refine lt_of_lt_of_le ?_ degree_le_natDegree exact degree_eraseLead_lt (ne_zero_of_ne_zero_of_monic one_ne_zero hp)⟩ invFun := fun p => ⟨X^n + p.1, monic_X_pow_add (mem_degreeLT.1 p.2), by rw [natDegree_add_eq_left_of_degree_lt] · simp · simp [mem_degreeLT.1 p.2]⟩ left_inv := by rintro ⟨p, hp, rfl⟩ ext1 simp only conv_rhs => rw [← eraseLead_add_C_mul_X_pow p] simp [Monic.def.1 hp, add_comm] right_inv := by rintro ⟨p, hp⟩ ext1 simp only rw [eraseLead_add_of_degree_lt_left] · simp · simp [mem_degreeLT.1 hp] /-- For every polynomial `p` in the span of a set `s : Set R[X]`, there exists a polynomial of `p' ∈ s` with higher degree. See also `Polynomial.exists_degree_le_of_mem_span_of_finite`. -/ theorem exists_degree_le_of_mem_span {s : Set R[X]} {p : R[X]} (hs : s.Nonempty) (hp : p ∈ Submodule.span R s) : ∃ p' ∈ s, degree p ≤ degree p' := by by_contra! h by_cases hp_zero : p = 0 · rw [hp_zero, degree_zero] at h rcases hs with ⟨x, hx⟩ exact not_lt_bot (h x hx) · have : p ∈ degreeLT R (natDegree p) := by refine (Submodule.span_le.mpr fun p' p'_mem => ?_) hp rw [SetLike.mem_coe, mem_degreeLT, Nat.cast_withBot] exact lt_of_lt_of_le (h p' p'_mem) degree_le_natDegree rwa [mem_degreeLT, Nat.cast_withBot, degree_eq_natDegree hp_zero, Nat.cast_withBot, lt_self_iff_false] at this /-- A stronger version of `Polynomial.exists_degree_le_of_mem_span` under the assumption that the set `s : R[X]` is finite. There exists a polynomial `p' ∈ s` whose degree dominates the degree of every element of `p ∈ span R s`. -/ theorem exists_degree_le_of_mem_span_of_finite {s : Set R[X]} (s_fin : s.Finite) (hs : s.Nonempty) : ∃ p' ∈ s, ∀ (p : R[X]), p ∈ Submodule.span R s → degree p ≤ degree p' := by rcases Set.Finite.exists_maximal_wrt degree s s_fin hs with ⟨a, has, hmax⟩ refine ⟨a, has, fun p hp => ?_⟩ rcases exists_degree_le_of_mem_span hs hp with ⟨p', hp'⟩ by_cases h : degree a ≤ degree p' · rw [← hmax p' hp'.left h] at hp'; exact hp'.right · exact le_trans hp'.right (not_le.mp h).le /-- The span of every finite set of polynomials is contained in a `degreeLE n` for some `n`. -/ theorem span_le_degreeLE_of_finite {s : Set R[X]} (s_fin : s.Finite) : ∃ n : ℕ, Submodule.span R s ≤ degreeLE R n := by by_cases s_emp : s.Nonempty · rcases exists_degree_le_of_mem_span_of_finite s_fin s_emp with ⟨p', _, hp'max⟩ exact ⟨natDegree p', fun p hp => mem_degreeLE.mpr ((hp'max _ hp).trans degree_le_natDegree)⟩ · rw [Set.not_nonempty_iff_eq_empty] at s_emp rw [s_emp, Submodule.span_empty] exact ⟨0, bot_le⟩ /-- The span of every finite set of polynomials is contained in a `degreeLT n` for some `n`. -/ theorem span_of_finite_le_degreeLT {s : Set R[X]} (s_fin : s.Finite) : ∃ n : ℕ, Submodule.span R s ≤ degreeLT R n := by rcases span_le_degreeLE_of_finite s_fin with ⟨n, _⟩ exact ⟨n + 1, by rwa [degreeLT_succ_eq_degreeLE]⟩ /-- If `R` is a nontrivial ring, the polynomials `R[X]` are not finite as an `R`-module. When `R` is a field, this is equivalent to `R[X]` being an infinite-dimensional vector space over `R`. -/ theorem not_finite [Nontrivial R] : ¬ Module.Finite R R[X] := by rw [Module.finite_def, Submodule.fg_def] push_neg intro s hs contra rcases span_le_degreeLE_of_finite hs with ⟨n,hn⟩ have : ((X : R[X]) ^ (n + 1)) ∈ Polynomial.degreeLE R ↑n := by rw [contra] at hn exact hn Submodule.mem_top rw [mem_degreeLE, degree_X_pow, Nat.cast_le, add_le_iff_nonpos_right, nonpos_iff_eq_zero] at this exact one_ne_zero this theorem geom_sum_X_comp_X_add_one_eq_sum (n : ℕ) : (∑ i ∈ range n, (X : R[X]) ^ i).comp (X + 1) = (Finset.range n).sum fun i : ℕ => (n.choose (i + 1) : R[X]) * X ^ i := by ext i trans (n.choose (i + 1) : R); swap · simp only [finset_sum_coeff, ← C_eq_natCast, coeff_C_mul_X_pow] rw [Finset.sum_eq_single i, if_pos rfl] · simp +contextual only [@eq_comm _ i, if_false, eq_self_iff_true, imp_true_iff] · simp +contextual only [Nat.lt_add_one_iff, Nat.choose_eq_zero_of_lt, Nat.cast_zero, Finset.mem_range, not_lt, eq_self_iff_true, if_true, imp_true_iff] induction' n with n ih generalizing i · dsimp; simp only [zero_comp, coeff_zero, Nat.cast_zero] · simp only [geom_sum_succ', ih, add_comp, X_pow_comp, coeff_add, Nat.choose_succ_succ, Nat.cast_add, coeff_X_add_one_pow] theorem Monic.geom_sum {P : R[X]} (hP : P.Monic) (hdeg : 0 < P.natDegree) {n : ℕ} (hn : n ≠ 0) : (∑ i ∈ range n, P ^ i).Monic := by nontriviality R obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero hn rw [geom_sum_succ'] refine (hP.pow _).add_of_left ?_ refine lt_of_le_of_lt (degree_sum_le _ _) ?_ rw [Finset.sup_lt_iff] · simp only [Finset.mem_range, degree_eq_natDegree (hP.pow _).ne_zero] simp only [Nat.cast_lt, hP.natDegree_pow] intro k exact nsmul_lt_nsmul_left hdeg · rw [bot_lt_iff_ne_bot, Ne, degree_eq_bot] exact (hP.pow _).ne_zero theorem Monic.geom_sum' {P : R[X]} (hP : P.Monic) (hdeg : 0 < P.degree) {n : ℕ} (hn : n ≠ 0) : (∑ i ∈ range n, P ^ i).Monic := hP.geom_sum (natDegree_pos_iff_degree_pos.2 hdeg) hn theorem monic_geom_sum_X {n : ℕ} (hn : n ≠ 0) : (∑ i ∈ range n, (X : R[X]) ^ i).Monic := by nontriviality R apply monic_X.geom_sum _ hn simp only [natDegree_X, zero_lt_one] end Semiring section Ring variable [Ring R] /-- Given a polynomial, return the polynomial whose coefficients are in the ring closure of the original coefficients. -/ def restriction (p : R[X]) : Polynomial (Subring.closure (↑p.coeffs : Set R)) := ∑ i ∈ p.support, monomial i (⟨p.coeff i, letI := Classical.decEq R if H : p.coeff i = 0 then H.symm ▸ (Subring.closure _).zero_mem else Subring.subset_closure (p.coeff_mem_coeffs _ H)⟩ : Subring.closure (↑p.coeffs : Set R)) @[simp] theorem coeff_restriction {p : R[X]} {n : ℕ} : ↑(coeff (restriction p) n) = coeff p n := by classical simp only [restriction, coeff_monomial, finset_sum_coeff, mem_support_iff, Finset.sum_ite_eq', Ne, ite_not] split_ifs with h · rw [h] rfl · rfl theorem coeff_restriction' {p : R[X]} {n : ℕ} : (coeff (restriction p) n).1 = coeff p n := by simp @[simp] theorem support_restriction (p : R[X]) : support (restriction p) = support p := by ext i simp only [mem_support_iff, not_iff_not, Ne] conv_rhs => rw [← coeff_restriction] exact ⟨fun H => by rw [H, ZeroMemClass.coe_zero], fun H => Subtype.coe_injective H⟩ @[simp] theorem map_restriction {R : Type u} [CommRing R] (p : R[X]) : p.restriction.map (algebraMap _ _) = p := ext fun n => by rw [coeff_map, Algebra.algebraMap_ofSubring_apply, coeff_restriction] @[simp] theorem degree_restriction {p : R[X]} : (restriction p).degree = p.degree := by simp [degree] @[simp] theorem natDegree_restriction {p : R[X]} : (restriction p).natDegree = p.natDegree := by simp [natDegree] @[simp] theorem monic_restriction {p : R[X]} : Monic (restriction p) ↔ Monic p := by simp only [Monic, leadingCoeff, natDegree_restriction] rw [← @coeff_restriction _ _ p] exact ⟨fun H => by rw [H, OneMemClass.coe_one], fun H => Subtype.coe_injective H⟩ @[simp] theorem restriction_zero : restriction (0 : R[X]) = 0 := by simp only [restriction, Finset.sum_empty, support_zero] @[simp] theorem restriction_one : restriction (1 : R[X]) = 1 := ext fun i => Subtype.eq <\| by rw [coeff_restriction', coeff_one, coeff_one]; split_ifs <;> rfl variable [Semiring S] {f : R →+* S} {x : S} theorem eval₂_restriction {p : R[X]} : eval₂ f x p = eval₂ (f.comp (Subring.subtype (Subring.closure (p.coeffs : Set R)))) x p.restriction := by simp only [eval₂_eq_sum, sum, support_restriction, ← @coeff_restriction _ _ p, RingHom.comp_apply, Subring.coe_subtype] section ToSubring variable (p : R[X]) (T : Subring R) /-- Given a polynomial `p` and a subring `T` that contains the coefficients of `p`, return the corresponding polynomial whose coefficients are in `T`. -/ def toSubring (hp : (↑p.coeffs : Set R) ⊆ T) : T[X] := ∑ i ∈ p.support, monomial i (⟨p.coeff i, letI := Classical.decEq R if H : p.coeff i = 0 then H.symm ▸ T.zero_mem else hp (p.coeff_mem_coeffs _ H)⟩ : T) variable (hp : (↑p.coeffs : Set R) ⊆ T) @[simp] theorem coeff_toSubring {n : ℕ} : ↑(coeff (toSubring p T hp) n) = coeff p n := by classical simp only [toSubring, coeff_monomial, finset_sum_coeff, mem_support_iff, Finset.sum_ite_eq', Ne, ite_not] split_ifs with h · rw [h] rfl · rfl theorem coeff_toSubring' {n : ℕ} : (coeff (toSubring p T hp) n).1 = coeff p n := by simp @[simp] theorem support_toSubring : support (toSubring p T hp) = support p := by ext i simp only [mem_support_iff, not_iff_not, Ne] conv_rhs => rw [← coeff_toSubring p T hp] exact ⟨fun H => by rw [H, ZeroMemClass.coe_zero], fun H => Subtype.coe_injective H⟩ @[simp] theorem degree_toSubring : (toSubring p T hp).degree = p.degree := by simp [degree] @[simp] theorem natDegree_toSubring : (toSubring p T hp).natDegree = p.natDegree := by simp [natDegree] @[simp] theorem monic_toSubring : Monic (toSubring p T hp) ↔ Monic p := by simp_rw [Monic, leadingCoeff, natDegree_toSubring, ← coeff_toSubring p T hp] exact ⟨fun H => by rw [H, OneMemClass.coe_one], fun H => Subtype.coe_injective H⟩ @[simp] theorem toSubring_zero : toSubring (0 : R[X]) T (by simp [coeffs]) = 0 := by ext i simp @[simp] theorem toSubring_one : toSubring (1 : R[X]) T (Set.Subset.trans coeffs_one <\| Finset.singleton_subset_set_iff.2 T.one_mem) = 1 := ext fun i => Subtype.eq <\| by rw [coeff_toSubring', coeff_one, coeff_one, apply_ite Subtype.val, ZeroMemClass.coe_zero, OneMemClass.coe_one] @[simp] theorem map_toSubring : (p.toSubring T hp).map (Subring.subtype T) = p := by ext n simp [coeff_map] end ToSubring variable (T : Subring R) /-- Given a polynomial whose coefficients are in some subring, return the corresponding polynomial whose coefficients are in the ambient ring. -/ def ofSubring (p : T[X]) : R[X] := ∑ i ∈ p.support, monomial i (p.coeff i : R) theorem coeff_ofSubring (p : T[X]) (n : ℕ) : coeff (ofSubring T p) n = (coeff p n : T) := by simp only [ofSubring, coeff_monomial, finset_sum_coeff, mem_support_iff, Finset.sum_ite_eq', ite_eq_right_iff, Ne, ite_not, Classical.not_not, ite_eq_left_iff] intro h rw [h, ZeroMemClass.coe_zero] @[simp] theorem coeffs_ofSubring {p : T[X]} : (↑(p.ofSubring T).coeffs : Set R) ⊆ T := by classical intro i hi simp only [coeffs, Set.mem_image, mem_support_iff, Ne, Finset.mem_coe, (Finset.coe_image)] at hi rcases hi with ⟨n, _, h'n⟩ rw [← h'n, coeff_ofSubring] exact Subtype.mem (coeff p n : T) end Ring end Polynomial namespace Ideal open Polynomial section Semiring variable [Semiring R] /-- Transport an ideal of `R[X]` to an `R`-submodule of `R[X]`. -/ def ofPolynomial (I : Ideal R[X]) : Submodule R R[X] where carrier := I.carrier zero_mem' := I.zero_mem add_mem' := I.add_mem smul_mem' c x H := by rw [← C_mul'] exact I.mul_mem_left _ H variable {I : Ideal R[X]} theorem mem_ofPolynomial (x) : x ∈ I.ofPolynomial ↔ x ∈ I := Iff.rfl variable (I) /-- Given an ideal `I` of `R[X]`, make the `R`-submodule of `I` consisting of polynomials of degree ≤ `n`. -/ def degreeLE (n : WithBot ℕ) : Submodule R R[X] := Polynomial.degreeLE R n ⊓ I.ofPolynomial /-- Given an ideal `I` of `R[X]`, make the ideal in `R` of leading coefficients of polynomials in `I` with degree ≤ `n`. -/ def leadingCoeffNth (n : ℕ) : Ideal R := (I.degreeLE n).map <\| lcoeff R n /-- Given an ideal `I` in `R[X]`, make the ideal in `R` of the leading coefficients in `I`. -/ def leadingCoeff : Ideal R := ⨆ n : ℕ, I.leadingCoeffNth n end Semiring section CommSemiring variable [CommSemiring R] [Semiring S] /-- If every coefficient of a polynomial is in an ideal `I`, then so is the polynomial itself -/ theorem polynomial_mem_ideal_of_coeff_mem_ideal (I : Ideal R[X]) (p : R[X]) (hp : ∀ n : ℕ, p.coeff n ∈ I.comap (C : R →+* R[X])) : p ∈ I := sum_C_mul_X_pow_eq p ▸ Submodule.sum_mem I fun n _ => I.mul_mem_right _ (hp n) /-- The push-forward of an ideal `I` of `R` to `R[X]` via inclusion is exactly the set of polynomials whose coefficients are in `I` -/ theorem mem_map_C_iff {I : Ideal R} {f : R[X]} : f ∈ (Ideal.map (C : R →+* R[X]) I : Ideal R[X]) ↔ ∀ n : ℕ, f.coeff n ∈ I := by constructor · intro hf refine Submodule.span_induction ?_ ?_ ?_ ?_ hf · intro f hf n obtain ⟨x, hx⟩ := (Set.mem_image _ _ _).mp hf rw [← hx.right, coeff_C] by_cases h : n = 0 · simpa [h] using hx.left · simp [h] · simp · exact fun f g _ _ hf hg n => by simp [I.add_mem (hf n) (hg n)] · refine fun f g _ hg n => ?_ rw [smul_eq_mul, coeff_mul] exact I.sum_mem fun c _ => I.mul_mem_left (f.coeff c.fst) (hg c.snd) · intro hf rw [← sum_monomial_eq f] refine (I.map C : Ideal R[X]).sum_mem fun n _ => ?_ simp only [← C_mul_X_pow_eq_monomial, ne_eq] rw [mul_comm] exact (I.map C : Ideal R[X]).mul_mem_left _ (mem_map_of_mem _ (hf n)) theorem _root_.Polynomial.ker_mapRingHom (f : R →+* S) : RingHom.ker (Polynomial.mapRingHom f) = (RingHom.ker f).map (C : R →+* R[X]) := by ext simp only [RingHom.mem_ker, coe_mapRingHom] rw [mem_map_C_iff, Polynomial.ext_iff] simp [RingHom.mem_ker] variable (I : Ideal R[X]) theorem mem_leadingCoeffNth (n : ℕ) (x) : x ∈ I.leadingCoeffNth n ↔ ∃ p ∈ I, degree p ≤ n ∧ p.leadingCoeff = x := by simp only [leadingCoeffNth, degreeLE, Submodule.mem_map, lcoeff_apply, Submodule.mem_inf, mem_degreeLE] constructor · rintro ⟨p, ⟨hpdeg, hpI⟩, rfl⟩ rcases lt_or_eq_of_le hpdeg with hpdeg \| hpdeg · refine ⟨0, I.zero_mem, bot_le, ?_⟩ rw [leadingCoeff_zero, eq_comm] exact coeff_eq_zero_of_degree_lt hpdeg · refine ⟨p, hpI, le_of_eq hpdeg, ?_⟩ rw [Polynomial.leadingCoeff, natDegree, hpdeg, Nat.cast_withBot, WithBot.unbotD_coe] · rintro ⟨p, hpI, hpdeg, rfl⟩ have : natDegree p + (n - natDegree p) = n := add_tsub_cancel_of_le (natDegree_le_of_degree_le hpdeg) refine ⟨p * X ^ (n - natDegree p), ⟨?_, I.mul_mem_right _ hpI⟩, ?_⟩ · apply le_trans (degree_mul_le _ _) _ apply le_trans (add_le_add degree_le_natDegree (degree_X_pow_le _)) _ rw [← Nat.cast_add, this] · rw [Polynomial.leadingCoeff, ← coeff_mul_X_pow p (n - natDegree p), this] theorem mem_leadingCoeffNth_zero (x) : x ∈ I.leadingCoeffNth 0 ↔ C x ∈ I := (mem_leadingCoeffNth _ _ _).trans ⟨fun ⟨p, hpI, hpdeg, hpx⟩ => by rwa [← hpx, Polynomial.leadingCoeff, Nat.eq_zero_of_le_zero (natDegree_le_of_degree_le hpdeg), ← eq_C_of_degree_le_zero hpdeg], fun hx => ⟨C x, hx, degree_C_le, leadingCoeff_C x⟩⟩ theorem leadingCoeffNth_mono {m n : ℕ} (H : m ≤ n) : I.leadingCoeffNth m ≤ I.leadingCoeffNth n := by intro r hr simp only [SetLike.mem_coe, mem_leadingCoeffNth] at hr ⊢ rcases hr with ⟨p, hpI, hpdeg, rfl⟩ refine ⟨p * X ^ (n - m), I.mul_mem_right _ hpI, ?_, leadingCoeff_mul_X_pow⟩ refine le_trans (degree_mul_le _ _) ?_ refine le_trans (add_le_add hpdeg (degree_X_pow_le _)) ?_ rw [← Nat.cast_add, add_tsub_cancel_of_le H] theorem mem_leadingCoeff (x) : x ∈ I.leadingCoeff ↔ ∃ p ∈ I, Polynomial.leadingCoeff p = x := by rw [leadingCoeff, Submodule.mem_iSup_of_directed] · simp only [mem_leadingCoeffNth] constructor · rintro ⟨i, p, hpI, _, rfl⟩ exact ⟨p, hpI, rfl⟩ rintro ⟨p, hpI, rfl⟩ exact ⟨natDegree p, p, hpI, degree_le_natDegree, rfl⟩ intro i j exact ⟨i + j, I.leadingCoeffNth_mono (Nat.le_add_right _ _), I.leadingCoeffNth_mono (Nat.le_add_left _ _)⟩ /-- If `I` is an ideal, and `pᵢ` is a finite family of polynomials each satisfying `∀ k, (pᵢ)ₖ ∈ Iⁿⁱ⁻ᵏ` for some `nᵢ`, then `p = ∏ pᵢ` also satisfies `∀ k, pₖ ∈ Iⁿ⁻ᵏ` with `n = ∑ nᵢ`. -/ theorem _root_.Polynomial.coeff_prod_mem_ideal_pow_tsub {ι : Type} (s : Finset ι) (f : ι → R[X]) (I : Ideal R) (n : ι → ℕ) (h : ∀ i ∈ s, ∀ (k), (f i).coeff k ∈ I ^ (n i - k)) (k : ℕ) : (s.prod f).coeff k ∈ I ^ (s.sum n - k) := by classical induction' s using Finset.induction with a s ha hs generalizing k · rw [sum_empty, prod_empty, coeff_one, zero_tsub, pow_zero, Ideal.one_eq_top] exact Submodule.mem_top · rw [sum_insert ha, prod_insert ha, coeff_mul] apply sum_mem rintro ⟨i, j⟩ e obtain rfl : i + j = k := mem_antidiagonal.mp e apply Ideal.pow_le_pow_right add_tsub_add_le_tsub_add_tsub rw [pow_add] exact Ideal.mul_mem_mul (h _ (Finset.mem_insert.mpr <\| Or.inl rfl) _) (hs (fun i hi k => h _ (Finset.mem_insert.mpr <\| Or.inr hi) _) j) end CommSemiring section Ring variable [Ring R] /-- `R[X]` is never a field for any ring `R`. -/ theorem polynomial_not_isField : ¬IsField R[X] := by nontriviality R intro hR obtain ⟨p, hp⟩ := hR.mul_inv_cancel X_ne_zero have hp0 : p ≠ 0 := right_ne_zero_of_mul_eq_one hp have := degree_lt_degree_mul_X hp0 rw [← X_mul, congr_arg degree hp, degree_one, Nat.WithBot.lt_zero_iff, degree_eq_bot] at this exact hp0 this /-- The only constant in a maximal ideal over a field is `0`. -/ theorem eq_zero_of_constant_mem_of_maximal (hR : IsField R) (I : Ideal R[X]) [hI : I.IsMaximal] (x : R) (hx : C x ∈ I) : x = 0 := by refine Classical.by_contradiction fun hx0 => hI.ne_top ((eq_top_iff_one I).2 ?_) obtain ⟨y, hy⟩ := hR.mul_inv_cancel hx0 convert I.mul_mem_left (C y) hx rw [← C.map_mul, hR.mul_comm y x, hy, RingHom.map_one] end Ring section CommRing variable [CommRing R] /-- If `P` is a prime ideal of `R`, then `P.R[x]` is a prime ideal of `R[x]`. -/ theorem isPrime_map_C_iff_isPrime (P : Ideal R) : IsPrime (map (C : R →+ R[X]) P : Ideal R[X]) ↔ IsPrime P := by -- Note: the following proof avoids quotient rings -- It can be golfed substantially by using something like -- `(Quotient.isDomain_iff_prime (map C P : Ideal R[X]))` constructor · intro H have := comap_isPrime C (map C P) convert this using 1 ext x simp only [mem_comap, mem_map_C_iff] constructor · rintro h (- \| n) · rwa [coeff_C_zero] · simp only [coeff_C_ne_zero (Nat.succ_ne_zero _), Submodule.zero_mem] · intro h simpa only [coeff_C_zero] using h 0 · intro h constructor · rw [Ne, eq_top_iff_one, mem_map_C_iff, not_forall] use 0 rw [coeff_one_zero, ← eq_top_iff_one] exact h.1 · intro f g simp only [mem_map_C_iff] contrapose! rintro ⟨hf, hg⟩ classical let m := Nat.find hf let n := Nat.find hg refine ⟨m + n, ?_⟩ rw [coeff_mul, ← Finset.insert_erase ((Finset.mem_antidiagonal (a := (m,n))).mpr rfl), Finset.sum_insert (Finset.not_mem_erase _ _), (P.add_mem_iff_left _).not] · apply mt h.2 rw [not_or] exact ⟨Nat.find_spec hf, Nat.find_spec hg⟩ apply P.sum_mem rintro ⟨i, j⟩ hij rw [Finset.mem_erase, Finset.mem_antidiagonal] at hij simp only [Ne, Prod.mk_inj, not_and_or] at hij obtain hi \| hj : i < m ∨ j < n := by omega · rw [mul_comm] apply P.mul_mem_left exact Classical.not_not.1 (Nat.find_min hf hi) · apply P.mul_mem_left exact Classical.not_not.1 (Nat.find_min hg hj) /-- If `P` is a prime ideal of `R`, then `P.R[x]` is a prime ideal of `R[x]`. -/ theorem isPrime_map_C_of_isPrime {P : Ideal R} (H : IsPrime P) : IsPrime (map (C : R →+* R[X]) P : Ideal R[X]) := (isPrime_map_C_iff_isPrime P).mpr H theorem is_fg_degreeLE [IsNoetherianRing R] (I : Ideal R[X]) (n : ℕ) : Submodule.FG (I.degreeLE n) := letI := Classical.decEq R isNoetherian_submodule_left.1 (isNoetherian_of_fg_of_noetherian _ ⟨_, degreeLE_eq_span_X_pow.symm⟩) _ end CommRing end Ideal section Ideal open Submodule Set variable [Semiring R] {f : R[X]} {I : Ideal R[X]} /-- If the coefficients of a polynomial belong to an ideal, then that ideal contains the ideal spanned by the coefficients of the polynomial. -/ theorem span_le_of_C_coeff_mem (cf : ∀ i : ℕ, C (f.coeff i) ∈ I) : Ideal.span { g \| ∃ i, g = C (f.coeff i) } ≤ I := by simp only [@eq_comm _ _ (C _)] exact (Ideal.span_le.trans range_subset_iff).mpr cf theorem mem_span_C_coeff : f ∈ Ideal.span { g : R[X] \| ∃ i : ℕ, g = C (coeff f i) } := by let p := Ideal.span { g : R[X] \| ∃ i : ℕ, g = C (coeff f i) } nth_rw 2 [(sum_C_mul_X_pow_eq f).symm] refine Submodule.sum_mem _ fun n _hn => ?_ dsimp have : C (coeff f n) ∈ p := by apply subset_span rw [mem_setOf_eq] use n have : monomial n (1 : R) • C (coeff f n) ∈ p := p.smul_mem _ this convert this using 1 simp only [monomial_mul_C, one_mul, smul_eq_mul] rw [← C_mul_X_pow_eq_monomial] theorem exists_C_coeff_not_mem : f ∉ I → ∃ i : ℕ, C (coeff f i) ∉ I := Not.imp_symm fun cf => span_le_of_C_coeff_mem (not_exists_not.mp cf) mem_span_C_coeff end Ideal variable {σ : Type v} {M : Type w} variable [CommRing R] [CommRing S] [AddCommGroup M] [Module R M] section Prime variable (σ) {r : R} namespace Polynomial theorem prime_C_iff : Prime (C r) ↔ Prime r := ⟨comap_prime C (evalRingHom (0 : R)) fun _ => eval_C, fun hr => by have := hr.1 rw [← Ideal.span_singleton_prime] at hr ⊢ · rw [← Set.image_singleton, ← Ideal.map_span] apply Ideal.isPrime_map_C_of_isPrime hr · intro h; apply (this (C_eq_zero.mp h)) · assumption⟩ end Polynomial namespace MvPolynomial private theorem prime_C_iff_of_fintype {R : Type u} (σ : Type v) {r : R} [CommRing R] [Fintype σ] : Prime (C r : MvPolynomial σ R) ↔ Prime r := by rw [← MulEquiv.prime_iff (renameEquiv R (Fintype.equivFin σ))] convert_to Prime (C r) ↔ _ · congr! simp only [renameEquiv_apply, algHom_C, algebraMap_eq] · induction' Fintype.card σ with d hd · exact MulEquiv.prime_iff (isEmptyAlgEquiv R (Fin 0)).symm (p := r) · convert MulEquiv.prime_iff (finSuccEquiv R d).symm (p := Polynomial.C (C r)) · simp [← finSuccEquiv_comp_C_eq_C] · simp [← hd, Polynomial.prime_C_iff] theorem prime_C_iff : Prime (C r : MvPolynomial σ R) ↔ Prime r := ⟨comap_prime C constantCoeff (constantCoeff_C _), fun hr => ⟨fun h => hr.1 <\| by rw [← C_inj, h] simp, fun h => hr.2.1 <\| by rw [← constantCoeff_C _ r] exact h.map _, fun a b hd => by obtain ⟨s, a', b', rfl, rfl⟩ := exists_finset_rename₂ a b rw [← algebraMap_eq] at hd have : algebraMap R _ r ∣ a' * b' := by convert killCompl Subtype.coe_injective \|>.toRingHom.map_dvd hd <;> simp rw [← rename_C ((↑) : s → σ)] let f := (rename (R := R) ((↑) : s → σ)).toRingHom exact (((prime_C_iff_of_fintype s).2 hr).2.2 a' b' this).imp f.map_dvd f.map_dvd⟩⟩ variable {σ} theorem prime_rename_iff (s : Set σ) {p : MvPolynomial s R} : Prime (rename ((↑) : s → σ) p) ↔ Prime (p : MvPolynomial s R) := by classical symm let eqv := (sumAlgEquiv R (↥sᶜ) s).symm.trans (renameEquiv R <\| (Equiv.sumComm (↥sᶜ) s).trans <\| Equiv.Set.sumCompl s) have : (rename (↑)).toRingHom = eqv.toAlgHom.toRingHom.comp C := by apply ringHom_ext · intro simp only [eqv, AlgHom.toRingHom_eq_coe, RingHom.coe_coe, rename_C, AlgEquiv.toAlgHom_eq_coe, AlgEquiv.toAlgHom_toRingHom, RingHom.coe_comp, AlgEquiv.coe_trans, Function.comp_apply, MvPolynomial.sumAlgEquiv_symm_apply, iterToSum_C_C, renameEquiv_apply, Equiv.coe_trans, Equiv.sumComm_apply] · intro simp only [eqv, AlgHom.toRingHom_eq_coe, RingHom.coe_coe, rename_X, AlgEquiv.toAlgHom_eq_coe, AlgEquiv.toAlgHom_toRingHom, RingHom.coe_comp, AlgEquiv.coe_trans, Function.comp_apply, MvPolynomial.sumAlgEquiv_symm_apply, iterToSum_C_X, renameEquiv_apply, Equiv.coe_trans, Equiv.sumComm_apply, Sum.swap_inr, Equiv.Set.sumCompl_apply_inl] apply_fun (· p) at this simp only [AlgHom.toRingHom_eq_coe, RingHom.coe_coe, AlgEquiv.toAlgHom_eq_coe, AlgEquiv.toAlgHom_toRingHom, RingHom.coe_comp, Function.comp_apply] at this rw [this, MulEquiv.prime_iff, prime_C_iff] end MvPolynomial end Prime /-- Hilbert basis theorem: a polynomial ring over a Noetherian ring is a Noetherian ring. -/ protected theorem Polynomial.isNoetherianRing [inst : IsNoetherianRing R] : IsNoetherianRing R[X] := isNoetherianRing_iff.2 ⟨fun I : Ideal R[X] => let M := inst.wf.min (Set.range I.leadingCoeffNth) ⟨_, ⟨0, rfl⟩⟩ have hm : M ∈ Set.range I.leadingCoeffNth := WellFounded.min_mem _ _ _ let ⟨N, HN⟩ := hm let ⟨s, hs⟩ := I.is_fg_degreeLE N have hm2 : ∀ k, I.leadingCoeffNth k ≤ M := fun k =>	Or.casesOn (le_or_lt k N) (fun h => HN ▸ I.leadingCoeffNth_mono h) fun h _ hx => Classical.by_contradiction fun hxm => haveI : IsNoetherian R R := inst have : ¬M < I.leadingCoeffNth k := by refine WellFounded.not_lt_min inst.wf _ _ ?_; exact ⟨k, rfl⟩ this ⟨HN ▸ I.leadingCoeffNth_mono (le_of_lt h), fun H => hxm (H hx)⟩ have hs2 : ∀ {x}, x ∈ I.degreeLE N → x ∈ Ideal.span (↑s : Set R[X]) := hs ▸ fun hx =>	Mathlib/RingTheory/Polynomial/Basic.lean	834	841
/- Copyright (c) 2022 Oliver Nash. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Oliver Nash -/ import Mathlib.Algebra.Order.ToIntervalMod import Mathlib.Algebra.Ring.AddAut import Mathlib.Data.Nat.Totient import Mathlib.GroupTheory.Divisible import Mathlib.Topology.Connected.PathConnected import Mathlib.Topology.IsLocalHomeomorph import Mathlib.Topology.Instances.ZMultiples /-! # The additive circle We define the additive circle `AddCircle p` as the quotient `𝕜 ⧸ (ℤ ∙ p)` for some period `p : 𝕜`. See also `Circle` and `Real.angle`. For the normed group structure on `AddCircle`, see `AddCircle.NormedAddCommGroup` in a later file. ## Main definitions and results: * `AddCircle`: the additive circle `𝕜 ⧸ (ℤ ∙ p)` for some period `p : 𝕜` * `UnitAddCircle`: the special case `ℝ ⧸ ℤ` * `AddCircle.equivAddCircle`: the rescaling equivalence `AddCircle p ≃+ AddCircle q` * `AddCircle.equivIco`: the natural equivalence `AddCircle p ≃ Ico a (a + p)` * `AddCircle.addOrderOf_div_of_gcd_eq_one`: rational points have finite order * `AddCircle.exists_gcd_eq_one_of_isOfFinAddOrder`: finite-order points are rational * `AddCircle.homeoIccQuot`: the natural topological equivalence between `AddCircle p` and `Icc a (a + p)` with its endpoints identified. * `AddCircle.liftIco_continuous`: if `f : ℝ → B` is continuous, and `f a = f (a + p)` for some `a`, then there is a continuous function `AddCircle p → B` which agrees with `f` on `Icc a (a + p)`. ## Implementation notes: Although the most important case is `𝕜 = ℝ` we wish to support other types of scalars, such as the rational circle `AddCircle (1 : ℚ)`, and so we set things up more generally. ## TODO * Link with periodicity * Lie group structure * Exponential equivalence to `Circle` -/ noncomputable section open AddCommGroup Set Function AddSubgroup TopologicalSpace open Topology variable {𝕜 B : Type} section Continuity variable [AddCommGroup 𝕜] [LinearOrder 𝕜] [IsOrderedAddMonoid 𝕜] [Archimedean 𝕜] [TopologicalSpace 𝕜] [OrderTopology 𝕜] {p : 𝕜} (hp : 0 < p) (a x : 𝕜) theorem continuous_right_toIcoMod : ContinuousWithinAt (toIcoMod hp a) (Ici x) x := by intro s h rw [Filter.mem_map, mem_nhdsWithin_iff_exists_mem_nhds_inter] haveI : Nontrivial 𝕜 := ⟨⟨0, p, hp.ne⟩⟩ simp_rw [mem_nhds_iff_exists_Ioo_subset] at h ⊢ obtain ⟨l, u, hxI, hIs⟩ := h let d := toIcoDiv hp a x • p have hd := toIcoMod_mem_Ico hp a x simp_rw [subset_def, mem_inter_iff] refine ⟨_, ⟨l + d, min (a + p) u + d, ?_, fun x => id⟩, fun y => ?_⟩ <;> simp_rw [← sub_mem_Ioo_iff_left, mem_Ioo, lt_min_iff] · exact ⟨hxI.1, hd.2, hxI.2⟩ · rintro ⟨h, h'⟩ apply hIs rw [← toIcoMod_sub_zsmul, (toIcoMod_eq_self _).2] exacts [⟨h.1, h.2.2⟩, ⟨hd.1.trans (sub_le_sub_right h' _), h.2.1⟩] theorem continuous_left_toIocMod : ContinuousWithinAt (toIocMod hp a) (Iic x) x := by rw [(funext fun y => Eq.trans (by rw [neg_neg]) <\| toIocMod_neg _ _ _ : toIocMod hp a = (fun x => p - x) ∘ toIcoMod hp (-a) ∘ Neg.neg)] exact (continuous_sub_left _).continuousAt.comp_continuousWithinAt <\| (continuous_right_toIcoMod _ _ _).comp continuous_neg.continuousWithinAt fun y => neg_le_neg variable {x} theorem toIcoMod_eventuallyEq_toIocMod (hx : (x : 𝕜 ⧸ zmultiples p) ≠ a) : toIcoMod hp a =ᶠ[𝓝 x] toIocMod hp a := IsOpen.mem_nhds (by rw [Ico_eq_locus_Ioc_eq_iUnion_Ioo] exact isOpen_iUnion fun i => isOpen_Ioo) <\| (not_modEq_iff_toIcoMod_eq_toIocMod hp).1 <\| not_modEq_iff_ne_mod_zmultiples.2 hx theorem continuousAt_toIcoMod (hx : (x : 𝕜 ⧸ zmultiples p) ≠ a) : ContinuousAt (toIcoMod hp a) x := let h := toIcoMod_eventuallyEq_toIocMod hp a hx continuousAt_iff_continuous_left_right.2 <\| ⟨(continuous_left_toIocMod hp a x).congr_of_eventuallyEq (h.filter_mono nhdsWithin_le_nhds) h.eq_of_nhds, continuous_right_toIcoMod hp a x⟩ theorem continuousAt_toIocMod (hx : (x : 𝕜 ⧸ zmultiples p) ≠ a) : ContinuousAt (toIocMod hp a) x := let h := toIcoMod_eventuallyEq_toIocMod hp a hx continuousAt_iff_continuous_left_right.2 <\| ⟨continuous_left_toIocMod hp a x, (continuous_right_toIcoMod hp a x).congr_of_eventuallyEq (h.symm.filter_mono nhdsWithin_le_nhds) h.symm.eq_of_nhds⟩ end Continuity /-- The "additive circle": `𝕜 ⧸ (ℤ ∙ p)`. See also `Circle` and `Real.angle`. -/ abbrev AddCircle [AddCommGroup 𝕜] (p : 𝕜) := 𝕜 ⧸ zmultiples p namespace AddCircle section LinearOrderedAddCommGroup variable [AddCommGroup 𝕜] (p : 𝕜) theorem coe_nsmul {n : ℕ} {x : 𝕜} : (↑(n • x) : AddCircle p) = n • (x : AddCircle p) := rfl theorem coe_zsmul {n : ℤ} {x : 𝕜} : (↑(n • x) : AddCircle p) = n • (x : AddCircle p) := rfl theorem coe_add (x y : 𝕜) : (↑(x + y) : AddCircle p) = (x : AddCircle p) + (y : AddCircle p) := rfl theorem coe_sub (x y : 𝕜) : (↑(x - y) : AddCircle p) = (x : AddCircle p) - (y : AddCircle p) := rfl theorem coe_neg {x : 𝕜} : (↑(-x) : AddCircle p) = -(x : AddCircle p) := rfl @[norm_cast] theorem coe_zero : ↑(0 : 𝕜) = (0 : AddCircle p) := rfl theorem coe_eq_zero_iff {x : 𝕜} : (x : AddCircle p) = 0 ↔ ∃ n : ℤ, n • p = x := by simp [AddSubgroup.mem_zmultiples_iff] theorem coe_period : (p : AddCircle p) = 0 := (QuotientAddGroup.eq_zero_iff p).2 <\| mem_zmultiples p theorem coe_add_period (x : 𝕜) : ((x + p : 𝕜) : AddCircle p) = x := by rw [coe_add, ← eq_sub_iff_add_eq', sub_self, coe_period] @[continuity, nolint unusedArguments] protected theorem continuous_mk' [TopologicalSpace 𝕜] : Continuous (QuotientAddGroup.mk' (zmultiples p) : 𝕜 → AddCircle p) := continuous_coinduced_rng variable [LinearOrder 𝕜] [IsOrderedAddMonoid 𝕜] theorem coe_eq_zero_of_pos_iff (hp : 0 < p) {x : 𝕜} (hx : 0 < x) : (x : AddCircle p) = 0 ↔ ∃ n : ℕ, n • p = x := by rw [coe_eq_zero_iff] constructor <;> rintro ⟨n, rfl⟩ · replace hx : 0 < n := by contrapose! hx simpa only [← neg_nonneg, ← zsmul_neg, zsmul_neg'] using zsmul_nonneg hp.le (neg_nonneg.2 hx) exact ⟨n.toNat, by rw [← natCast_zsmul, Int.toNat_of_nonneg hx.le]⟩ · exact ⟨(n : ℤ), by simp⟩ variable [hp : Fact (0 < p)] (a : 𝕜) [Archimedean 𝕜] /-- The equivalence between `AddCircle p` and the half-open interval `[a, a + p)`, whose inverse is the natural quotient map. -/ def equivIco : AddCircle p ≃ Ico a (a + p) := QuotientAddGroup.equivIcoMod hp.out a /-- The equivalence between `AddCircle p` and the half-open interval `(a, a + p]`, whose inverse is the natural quotient map. -/ def equivIoc : AddCircle p ≃ Ioc a (a + p) := QuotientAddGroup.equivIocMod hp.out a /-- Given a function on `𝕜`, return the unique function on `AddCircle p` agreeing with `f` on `[a, a + p)`. -/ def liftIco (f : 𝕜 → B) : AddCircle p → B := restrict _ f ∘ AddCircle.equivIco p a /-- Given a function on `𝕜`, return the unique function on `AddCircle p` agreeing with `f` on `(a, a + p]`. -/ def liftIoc (f : 𝕜 → B) : AddCircle p → B := restrict _ f ∘ AddCircle.equivIoc p a variable {p a} theorem coe_eq_coe_iff_of_mem_Ico {x y : 𝕜} (hx : x ∈ Ico a (a + p)) (hy : y ∈ Ico a (a + p)) : (x : AddCircle p) = y ↔ x = y := by refine ⟨fun h => ?_, by tauto⟩ suffices (⟨x, hx⟩ : Ico a (a + p)) = ⟨y, hy⟩ by exact Subtype.mk.inj this apply_fun equivIco p a at h rw [← (equivIco p a).right_inv ⟨x, hx⟩, ← (equivIco p a).right_inv ⟨y, hy⟩] exact h theorem liftIco_coe_apply {f : 𝕜 → B} {x : 𝕜} (hx : x ∈ Ico a (a + p)) : liftIco p a f ↑x = f x := by have : (equivIco p a) x = ⟨x, hx⟩ := by rw [Equiv.apply_eq_iff_eq_symm_apply] rfl rw [liftIco, comp_apply, this] rfl theorem liftIoc_coe_apply {f : 𝕜 → B} {x : 𝕜} (hx : x ∈ Ioc a (a + p)) : liftIoc p a f ↑x = f x := by have : (equivIoc p a) x = ⟨x, hx⟩ := by rw [Equiv.apply_eq_iff_eq_symm_apply] rfl rw [liftIoc, comp_apply, this] rfl lemma eq_coe_Ico (a : AddCircle p) : ∃ b, b ∈ Ico 0 p ∧ ↑b = a := by let b := QuotientAddGroup.equivIcoMod hp.out 0 a exact ⟨b.1, by simpa only [zero_add] using b.2, (QuotientAddGroup.equivIcoMod hp.out 0).symm_apply_apply a⟩ lemma coe_eq_zero_iff_of_mem_Ico (ha : a ∈ Ico 0 p) : (a : AddCircle p) = 0 ↔ a = 0 := by have h0 : 0 ∈ Ico 0 (0 + p) := by simpa [zero_add, left_mem_Ico] using hp.out have ha' : a ∈ Ico 0 (0 + p) := by rwa [zero_add] rw [← AddCircle.coe_eq_coe_iff_of_mem_Ico ha' h0, QuotientAddGroup.mk_zero] variable (p a) section Continuity variable [TopologicalSpace 𝕜] @[continuity] theorem continuous_equivIco_symm : Continuous (equivIco p a).symm := continuous_quotient_mk'.comp continuous_subtype_val @[continuity] theorem continuous_equivIoc_symm : Continuous (equivIoc p a).symm := continuous_quotient_mk'.comp continuous_subtype_val variable [OrderTopology 𝕜] {x : AddCircle p} theorem continuousAt_equivIco (hx : x ≠ a) : ContinuousAt (equivIco p a) x := by induction x using QuotientAddGroup.induction_on rw [ContinuousAt, Filter.Tendsto, QuotientAddGroup.nhds_eq, Filter.map_map] exact (continuousAt_toIcoMod hp.out a hx).codRestrict _ theorem continuousAt_equivIoc (hx : x ≠ a) : ContinuousAt (equivIoc p a) x := by induction x using QuotientAddGroup.induction_on rw [ContinuousAt, Filter.Tendsto, QuotientAddGroup.nhds_eq, Filter.map_map] exact (continuousAt_toIocMod hp.out a hx).codRestrict _ /-- The quotient map `𝕜 → AddCircle p` as a partial homeomorphism. -/ @[simps] def partialHomeomorphCoe [DiscreteTopology (zmultiples p)] : PartialHomeomorph 𝕜 (AddCircle p) where toFun := (↑) invFun := fun x ↦ equivIco p a x source := Ioo a (a + p) target := {↑a}ᶜ map_source' := by intro x hx hx' exact hx.1.ne' ((coe_eq_coe_iff_of_mem_Ico (Ioo_subset_Ico_self hx) (left_mem_Ico.mpr (lt_add_of_pos_right a hp.out))).mp hx') map_target' := by intro x hx exact (eq_left_or_mem_Ioo_of_mem_Ico (equivIco p a x).2).resolve_left (hx ∘ ((equivIco p a).symm_apply_apply x).symm.trans ∘ congrArg _) left_inv' := fun x hx ↦ congrArg _ ((equivIco p a).apply_symm_apply ⟨x, Ioo_subset_Ico_self hx⟩) right_inv' := fun x _ ↦ (equivIco p a).symm_apply_apply x open_source := isOpen_Ioo open_target := isOpen_compl_singleton continuousOn_toFun := (AddCircle.continuous_mk' p).continuousOn continuousOn_invFun := by exact continuousOn_of_forall_continuousAt (fun _ ↦ continuousAt_subtype_val.comp ∘ continuousAt_equivIco p a) lemma isLocalHomeomorph_coe [DiscreteTopology (zmultiples p)] [DenselyOrdered 𝕜] : IsLocalHomeomorph ((↑) : 𝕜 → AddCircle p) := by intro a obtain ⟨b, hb1, hb2⟩ := exists_between (sub_lt_self a hp.out) exact ⟨partialHomeomorphCoe p b, ⟨hb2, lt_add_of_sub_right_lt hb1⟩, rfl⟩ end Continuity /-- The image of the closed-open interval `[a, a + p)` under the quotient map `𝕜 → AddCircle p` is the entire space. -/ @[simp] theorem coe_image_Ico_eq : ((↑) : 𝕜 → AddCircle p) '' Ico a (a + p) = univ := by rw [image_eq_range] exact (equivIco p a).symm.range_eq_univ /-- The image of the closed-open interval `[a, a + p)` under the quotient map `𝕜 → AddCircle p` is the entire space. -/ @[simp] theorem coe_image_Ioc_eq : ((↑) : 𝕜 → AddCircle p) '' Ioc a (a + p) = univ := by rw [image_eq_range] exact (equivIoc p a).symm.range_eq_univ /-- The image of the closed interval `[0, p]` under the quotient map `𝕜 → AddCircle p` is the entire space. -/ @[simp] theorem coe_image_Icc_eq : ((↑) : 𝕜 → AddCircle p) '' Icc a (a + p) = univ := eq_top_mono (image_subset _ Ico_subset_Icc_self) <\| coe_image_Ico_eq _ _ end LinearOrderedAddCommGroup section LinearOrderedField variable [Field 𝕜] (p q : 𝕜) /-- The rescaling equivalence between additive circles with different periods. -/ def equivAddCircle (hp : p ≠ 0) (hq : q ≠ 0) : AddCircle p ≃+ AddCircle q := QuotientAddGroup.congr _ _ (AddAut.mulRight <\| (Units.mk0 p hp)⁻¹ Units.mk0 q hq) <\| by rw [AddMonoidHom.map_zmultiples, AddMonoidHom.coe_coe, AddAut.mulRight_apply, Units.val_mul, Units.val_mk0, Units.val_inv_eq_inv_val, Units.val_mk0, mul_inv_cancel_left₀ hp] @[simp] theorem equivAddCircle_apply_mk (hp : p ≠ 0) (hq : q ≠ 0) (x : 𝕜) : equivAddCircle p q hp hq (x : 𝕜) = (x * (p⁻¹ * q) : 𝕜) := rfl @[simp] theorem equivAddCircle_symm_apply_mk (hp : p ≠ 0) (hq : q ≠ 0) (x : 𝕜) : (equivAddCircle p q hp hq).symm (x : 𝕜) = (x * (q⁻¹ * p) : 𝕜) := rfl section variable [LinearOrder 𝕜] [IsStrictOrderedRing 𝕜] [TopologicalSpace 𝕜] [OrderTopology 𝕜] /-- The rescaling homeomorphism between additive circles with different periods. -/ def homeomorphAddCircle (hp : p ≠ 0) (hq : q ≠ 0) : AddCircle p ≃ₜ AddCircle q := ⟨equivAddCircle p q hp hq, (continuous_quotient_mk'.comp (continuous_mul_right (p⁻¹ * q))).quotient_lift _, (continuous_quotient_mk'.comp (continuous_mul_right (q⁻¹ * p))).quotient_lift _⟩ @[simp] theorem homeomorphAddCircle_apply_mk (hp : p ≠ 0) (hq : q ≠ 0) (x : 𝕜) : homeomorphAddCircle p q hp hq (x : 𝕜) = (x * (p⁻¹ * q) : 𝕜) := rfl @[simp] theorem homeomorphAddCircle_symm_apply_mk (hp : p ≠ 0) (hq : q ≠ 0) (x : 𝕜) : (homeomorphAddCircle p q hp hq).symm (x : 𝕜) = (x * (q⁻¹ * p) : 𝕜) := rfl end variable [LinearOrder 𝕜] [IsStrictOrderedRing 𝕜] [hp : Fact (0 < p)] section FloorRing variable [FloorRing 𝕜] @[simp] theorem coe_equivIco_mk_apply (x : 𝕜) : (equivIco p 0 <\| QuotientAddGroup.mk x : 𝕜) = Int.fract (x / p) * p := toIcoMod_eq_fract_mul _ x instance : DivisibleBy (AddCircle p) ℤ where div x n := (↑((n : 𝕜)⁻¹ * (equivIco p 0 x : 𝕜)) : AddCircle p) div_zero x := by simp only [algebraMap.coe_zero, Int.cast_zero, inv_zero, zero_mul, QuotientAddGroup.mk_zero] div_cancel {n} x hn := by replace hn : (n : 𝕜) ≠ 0 := by norm_cast change n • QuotientAddGroup.mk' _ ((n : 𝕜)⁻¹ * ↑(equivIco p 0 x)) = x rw [← map_zsmul, ← smul_mul_assoc, zsmul_eq_mul, mul_inv_cancel₀ hn, one_mul] exact (equivIco p 0).symm_apply_apply x end FloorRing section FiniteOrderPoints variable {p} theorem addOrderOf_period_div {n : ℕ} (h : 0 < n) : addOrderOf ((p / n : 𝕜) : AddCircle p) = n := by rw [addOrderOf_eq_iff h] replace h : 0 < (n : 𝕜) := Nat.cast_pos.2 h refine ⟨?_, fun m hn h0 => ?_⟩ <;> simp only [Ne, ← coe_nsmul, nsmul_eq_mul] · rw [mul_div_cancel₀ _ h.ne', coe_period] rw [coe_eq_zero_of_pos_iff p hp.out (mul_pos (Nat.cast_pos.2 h0) <\| div_pos hp.out h)] rintro ⟨k, hk⟩ rw [mul_div, eq_div_iff h.ne', nsmul_eq_mul, mul_right_comm, ← Nat.cast_mul, (mul_left_injective₀ hp.out.ne').eq_iff, Nat.cast_inj, mul_comm] at hk exact (Nat.le_of_dvd h0 ⟨_, hk.symm⟩).not_lt hn variable (p) in theorem gcd_mul_addOrderOf_div_eq {n : ℕ} (m : ℕ) (hn : 0 < n) : m.gcd n * addOrderOf (↑(↑m / ↑n * p) : AddCircle p) = n := by rw [mul_comm_div, ← nsmul_eq_mul, coe_nsmul, IsOfFinAddOrder.addOrderOf_nsmul] · rw [addOrderOf_period_div hn, Nat.gcd_comm, Nat.mul_div_cancel'] exact n.gcd_dvd_left m · rwa [← addOrderOf_pos_iff, addOrderOf_period_div hn] theorem addOrderOf_div_of_gcd_eq_one {m n : ℕ} (hn : 0 < n) (h : m.gcd n = 1) : addOrderOf (↑(↑m / ↑n * p) : AddCircle p) = n := by convert gcd_mul_addOrderOf_div_eq p m hn rw [h, one_mul] theorem addOrderOf_div_of_gcd_eq_one' {m : ℤ} {n : ℕ} (hn : 0 < n) (h : m.natAbs.gcd n = 1) : addOrderOf (↑(↑m / ↑n * p) : AddCircle p) = n := by cases m · simp only [Int.ofNat_eq_coe, Int.cast_natCast, Int.natAbs_natCast] at h ⊢ exact addOrderOf_div_of_gcd_eq_one hn h · simp only [Int.cast_negSucc, neg_div, neg_mul, coe_neg, addOrderOf_neg] exact addOrderOf_div_of_gcd_eq_one hn h theorem addOrderOf_coe_rat {q : ℚ} : addOrderOf (↑(↑q * p) : AddCircle p) = q.den := by have : (↑(q.den : ℤ) : 𝕜) ≠ 0 := by norm_cast exact q.pos.ne.symm rw [← q.num_divInt_den, Rat.cast_divInt_of_ne_zero _ this, Int.cast_natCast, Rat.num_divInt_den, addOrderOf_div_of_gcd_eq_one' q.pos q.reduced] theorem addOrderOf_eq_pos_iff {u : AddCircle p} {n : ℕ} (h : 0 < n) : addOrderOf u = n ↔ ∃ m < n, m.gcd n = 1 ∧ ↑(↑m / ↑n * p) = u := by refine ⟨QuotientAddGroup.induction_on u fun k hk => ?_, ?_⟩ · rintro ⟨m, _, h₁, rfl⟩ exact addOrderOf_div_of_gcd_eq_one h h₁ have h0 := addOrderOf_nsmul_eq_zero (k : AddCircle p) rw [hk, ← coe_nsmul, coe_eq_zero_iff] at h0 obtain ⟨a, ha⟩ := h0 have h0 : (_ : 𝕜) ≠ 0 := Nat.cast_ne_zero.2 h.ne' rw [nsmul_eq_mul, mul_comm, ← div_eq_iff h0, ← a.ediv_add_emod' n, add_smul, add_div, zsmul_eq_mul, Int.cast_mul, Int.cast_natCast, mul_assoc, ← mul_div, mul_comm _ p, mul_div_cancel_right₀ p h0] at ha have han : _ = a % n := Int.toNat_of_nonneg (Int.emod_nonneg _ <\| mod_cast h.ne') have he : (↑(↑((a % n).toNat) / ↑n * p) : AddCircle p) = k := by convert congr_arg (QuotientAddGroup.mk : 𝕜 → (AddCircle p)) ha using 1 rw [coe_add, ← Int.cast_natCast, han, zsmul_eq_mul, mul_div_right_comm, eq_comm, add_eq_right, ← zsmul_eq_mul, coe_zsmul, coe_period, smul_zero] refine ⟨(a % n).toNat, ?_, ?_, he⟩ · rw [← Int.ofNat_lt, han] exact Int.emod_lt_of_pos _ (Int.ofNat_lt.2 h) · have := (gcd_mul_addOrderOf_div_eq p (Int.toNat (a % ↑n)) h).trans ((congr_arg addOrderOf he).trans hk).symm rw [he, Nat.mul_left_eq_self_iff] at this · exact this · rwa [hk] theorem exists_gcd_eq_one_of_isOfFinAddOrder {u : AddCircle p} (h : IsOfFinAddOrder u) : ∃ m : ℕ, m.gcd (addOrderOf u) = 1 ∧ m < addOrderOf u ∧ ↑((m : 𝕜) / addOrderOf u * p) = u := let ⟨m, hl, hg, he⟩ := (addOrderOf_eq_pos_iff h.addOrderOf_pos).1 rfl ⟨m, hg, hl, he⟩ theorem addOrderOf_coe_eq_zero_iff_forall_rat_ne_div {a : 𝕜} : addOrderOf (a : AddCircle p) = 0 ↔ ∀ q : ℚ, (q : 𝕜) ≠ a / p := by simp only [ne_eq, eq_div_iff (Fact.out : 0 < p).ne'] constructor · rintro h q rfl rw [addOrderOf_coe_rat] at h exact q.den_ne_zero h · rw [addOrderOf_eq_zero_iff'] intro h n hn han simp only [← coe_nsmul, coe_eq_zero_iff, nsmul_eq_mul, zsmul_eq_mul] at han rcases han with ⟨m, hm⟩ apply h (m / n) field_simp [hm] variable (p) /-- The natural bijection between points of order `n` and natural numbers less than and coprime to `n`. The inverse of the map sends `m ↦ (m/n * p : AddCircle p)` where `m` is coprime to `n` and satisfies `0 ≤ m < n`. -/ def setAddOrderOfEquiv {n : ℕ} (hn : 0 < n) : { u : AddCircle p \| addOrderOf u = n } ≃ { m \| m < n ∧ m.gcd n = 1 } := Equiv.symm <\| Equiv.ofBijective (fun m => ⟨↑((m : 𝕜) / n * p), addOrderOf_div_of_gcd_eq_one hn m.prop.2⟩) (by refine ⟨fun m₁ m₂ h => Subtype.ext ?_, fun u => ?_⟩ · simp_rw [Subtype.ext_iff] at h rw [← sub_eq_zero, ← coe_sub, ← sub_mul, ← sub_div, ← Int.cast_natCast m₁, ← Int.cast_natCast m₂, ← Int.cast_sub, coe_eq_zero_iff] at h obtain ⟨m, hm⟩ := h rw [← mul_div_right_comm, eq_div_iff, mul_comm, ← zsmul_eq_mul, mul_smul_comm, ← nsmul_eq_mul, ← natCast_zsmul, smul_smul, zsmul_left_inj hp.out, mul_comm] at hm swap · exact Nat.cast_ne_zero.2 hn.ne' rw [← @Nat.cast_inj ℤ, ← sub_eq_zero] refine Int.eq_zero_of_abs_lt_dvd ⟨_, hm.symm⟩ (abs_sub_lt_iff.2 ⟨?_, ?_⟩) <;> apply (Int.sub_le_self _ <\| Nat.cast_nonneg _).trans_lt (Nat.cast_lt.2 _) exacts [m₁.2.1, m₂.2.1] obtain ⟨m, hmn, hg, he⟩ := (addOrderOf_eq_pos_iff hn).mp u.2 exact ⟨⟨m, hmn, hg⟩, Subtype.ext he⟩) @[simp] theorem card_addOrderOf_eq_totient {n : ℕ} : Nat.card { u : AddCircle p // addOrderOf u = n } = n.totient := by rcases n.eq_zero_or_pos with (rfl \| hn) · simp only [Nat.totient_zero, addOrderOf_eq_zero_iff] rcases em (∃ u : AddCircle p, ¬IsOfFinAddOrder u) with (⟨u, hu⟩ \| h) · have : Infinite { u : AddCircle p // ¬IsOfFinAddOrder u } := by rw [← coe_setOf, infinite_coe_iff] exact infinite_not_isOfFinAddOrder hu exact Nat.card_eq_zero_of_infinite · have : IsEmpty { u : AddCircle p // ¬IsOfFinAddOrder u } := by simpa [isEmpty_subtype] using h exact Nat.card_of_isEmpty · rw [← coe_setOf, Nat.card_congr (setAddOrderOfEquiv p hn), n.totient_eq_card_lt_and_coprime] simp only [Nat.gcd_comm] theorem finite_setOf_addOrderOf_eq {n : ℕ} (hn : 0 < n) : {u : AddCircle p \| addOrderOf u = n}.Finite := finite_coe_iff.mp <\| Nat.finite_of_card_ne_zero <\| by simp [hn.ne'] @[deprecated (since := "2025-03-26")] alias finite_setOf_add_order_eq := finite_setOf_addOrderOf_eq end FiniteOrderPoints end LinearOrderedField	variable (p : ℝ) instance pathConnectedSpace : PathConnectedSpace <\| AddCircle p := (inferInstance : PathConnectedSpace (Quotient _)) /-- The "additive circle" `ℝ ⧸ (ℤ ∙ p)` is compact. -/ instance compactSpace [Fact (0 < p)] : CompactSpace <\| AddCircle p := by rw [← isCompact_univ_iff, ← coe_image_Icc_eq p 0] exact isCompact_Icc.image (AddCircle.continuous_mk' p) /-- The action on `ℝ` by right multiplication of its the subgroup `zmultiples p` (the multiples of `p:ℝ`) is properly discontinuous. -/ instance : ProperlyDiscontinuousVAdd (zmultiples p).op ℝ :=	Mathlib/Topology/Instances/AddCircle.lean	513	526
/- Copyright (c) 2020 Simon Hudon. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Simon Hudon, Ira Fesefeldt -/ import Mathlib.Control.Monad.Basic import Mathlib.Dynamics.FixedPoints.Basic import Mathlib.Order.CompleteLattice.Basic import Mathlib.Order.Iterate import Mathlib.Order.Part import Mathlib.Order.Preorder.Chain import Mathlib.Order.ScottContinuity /-! # Omega Complete Partial Orders An omega-complete partial order is a partial order with a supremum operation on increasing sequences indexed by natural numbers (which we call `ωSup`). In this sense, it is strictly weaker than join complete semi-lattices as only ω-sized totally ordered sets have a supremum. The concept of an omega-complete partial order (ωCPO) is useful for the formalization of the semantics of programming languages. Its notion of supremum helps define the meaning of recursive procedures. ## Main definitions * class `OmegaCompletePartialOrder` * `ite`, `map`, `bind`, `seq` as continuous morphisms ## Instances of `OmegaCompletePartialOrder` * `Part` * every `CompleteLattice` * pi-types * product types * `OrderHom` * `ContinuousHom` (with notation →𝒄) * an instance of `OmegaCompletePartialOrder (α →𝒄 β)` * `ContinuousHom.ofFun` * `ContinuousHom.ofMono` * continuous functions: * `id` * `ite` * `const` * `Part.bind` * `Part.map` * `Part.seq` ## References * [Chain-complete posets and directed sets with applications][markowsky1976] * [Recursive definitions of partial functions and their computations][cadiou1972] * [Semantics of Programming Languages: Structures and Techniques][gunter1992] -/ assert_not_exists OrderedCommMonoid universe u v variable {ι : Sort} {α β γ δ : Type} namespace OmegaCompletePartialOrder /-- A chain is a monotone sequence. See the definition on page 114 of [gunter1992]. -/ def Chain (α : Type u) [Preorder α] := ℕ →o α namespace Chain variable [Preorder α] [Preorder β] [Preorder γ] instance : FunLike (Chain α) ℕ α := inferInstanceAs <\| FunLike (ℕ →o α) ℕ α instance : OrderHomClass (Chain α) ℕ α := inferInstanceAs <\| OrderHomClass (ℕ →o α) ℕ α instance [Inhabited α] : Inhabited (Chain α) := ⟨⟨default, fun _ _ _ => le_rfl⟩⟩ instance : Membership α (Chain α) := ⟨fun (c : ℕ →o α) a => ∃ i, a = c i⟩ variable (c c' : Chain α) variable (f : α →o β) variable (g : β →o γ) instance : LE (Chain α) where le x y := ∀ i, ∃ j, x i ≤ y j lemma isChain_range : IsChain (· ≤ ·) (Set.range c) := Monotone.isChain_range (OrderHomClass.mono c) lemma directed : Directed (· ≤ ·) c := directedOn_range.2 c.isChain_range.directedOn /-- `map` function for `Chain` -/ -- Porting note: `simps` doesn't work with type synonyms -- @[simps! -fullyApplied] def map : Chain β := f.comp c @[simp] theorem map_coe : ⇑(map c f) = f ∘ c := rfl variable {f} theorem mem_map (x : α) : x ∈ c → f x ∈ Chain.map c f := fun ⟨i, h⟩ => ⟨i, h.symm ▸ rfl⟩ theorem exists_of_mem_map {b : β} : b ∈ c.map f → ∃ a, a ∈ c ∧ f a = b := fun ⟨i, h⟩ => ⟨c i, ⟨i, rfl⟩, h.symm⟩ @[simp] theorem mem_map_iff {b : β} : b ∈ c.map f ↔ ∃ a, a ∈ c ∧ f a = b := ⟨exists_of_mem_map _, fun h => by rcases h with ⟨w, h, h'⟩ subst b apply mem_map c _ h⟩ @[simp] theorem map_id : c.map OrderHom.id = c := OrderHom.comp_id _ theorem map_comp : (c.map f).map g = c.map (g.comp f) := rfl @[mono] theorem map_le_map {g : α →o β} (h : f ≤ g) : c.map f ≤ c.map g := fun i => by simp only [map_coe, Function.comp_apply]; exists i; apply h /-- `OmegaCompletePartialOrder.Chain.zip` pairs up the elements of two chains that have the same index. -/ -- Porting note: `simps` doesn't work with type synonyms -- @[simps!] def zip (c₀ : Chain α) (c₁ : Chain β) : Chain (α × β) := OrderHom.prod c₀ c₁ @[simp] theorem zip_coe (c₀ : Chain α) (c₁ : Chain β) (n : ℕ) : c₀.zip c₁ n = (c₀ n, c₁ n) := rfl /-- An example of a `Chain` constructed from an ordered pair. -/ def pair (a b : α) (hab : a ≤ b) : Chain α where toFun \| 0 => a \| _ => b monotone' _ _ _ := by aesop @[simp] lemma pair_zero (a b : α) (hab) : pair a b hab 0 = a := rfl @[simp] lemma pair_succ (a b : α) (hab) (n : ℕ) : pair a b hab (n + 1) = b := rfl @[simp] lemma range_pair (a b : α) (hab) : Set.range (pair a b hab) = {a, b} := by ext; exact Nat.or_exists_add_one.symm.trans (by aesop) @[simp] lemma pair_zip_pair (a₁ a₂ : α) (b₁ b₂ : β) (ha hb) : (pair a₁ a₂ ha).zip (pair b₁ b₂ hb) = pair (a₁, b₁) (a₂, b₂) (Prod.le_def.2 ⟨ha, hb⟩) := by unfold Chain; ext n : 2; cases n <;> rfl end Chain end OmegaCompletePartialOrder open OmegaCompletePartialOrder /-- An omega-complete partial order is a partial order with a supremum operation on increasing sequences indexed by natural numbers (which we call `ωSup`). In this sense, it is strictly weaker than join complete semi-lattices as only ω-sized totally ordered sets have a supremum. See the definition on page 114 of [gunter1992]. -/ class OmegaCompletePartialOrder (α : Type) extends PartialOrder α where /-- The supremum of an increasing sequence -/ ωSup : Chain α → α /-- `ωSup` is an upper bound of the increasing sequence -/ le_ωSup : ∀ c : Chain α, ∀ i, c i ≤ ωSup c /-- `ωSup` is a lower bound of the set of upper bounds of the increasing sequence -/ ωSup_le : ∀ (c : Chain α) (x), (∀ i, c i ≤ x) → ωSup c ≤ x namespace OmegaCompletePartialOrder variable [OmegaCompletePartialOrder α] /-- Transfer an `OmegaCompletePartialOrder` on `β` to an `OmegaCompletePartialOrder` on `α` using a strictly monotone function `f : β →o α`, a definition of ωSup and a proof that `f` is continuous with regard to the provided `ωSup` and the ωCPO on `α`. -/ protected abbrev lift [PartialOrder β] (f : β →o α) (ωSup₀ : Chain β → β) (h : ∀ x y, f x ≤ f y → x ≤ y) (h' : ∀ c, f (ωSup₀ c) = ωSup (c.map f)) : OmegaCompletePartialOrder β where ωSup := ωSup₀ ωSup_le c x hx := h _ _ (by rw [h']; apply ωSup_le; intro i; apply f.monotone (hx i)) le_ωSup c i := h _ _ (by rw [h']; apply le_ωSup (c.map f)) theorem le_ωSup_of_le {c : Chain α} {x : α} (i : ℕ) (h : x ≤ c i) : x ≤ ωSup c := le_trans h (le_ωSup c _) theorem ωSup_total {c : Chain α} {x : α} (h : ∀ i, c i ≤ x ∨ x ≤ c i) : ωSup c ≤ x ∨ x ≤ ωSup c := by_cases (fun (this : ∀ i, c i ≤ x) => Or.inl (ωSup_le _ _ this)) (fun (this : ¬∀ i, c i ≤ x) => have : ∃ i, ¬c i ≤ x := by simp only [not_forall] at this ⊢; assumption let ⟨i, hx⟩ := this have : x ≤ c i := (h i).resolve_left hx Or.inr <\| le_ωSup_of_le _ this) @[mono] theorem ωSup_le_ωSup_of_le {c₀ c₁ : Chain α} (h : c₀ ≤ c₁) : ωSup c₀ ≤ ωSup c₁ := (ωSup_le _ _) fun i => by obtain ⟨_, h⟩ := h i exact le_trans h (le_ωSup _ _) @[simp] theorem ωSup_le_iff {c : Chain α} {x : α} : ωSup c ≤ x ↔ ∀ i, c i ≤ x := by constructor <;> intros · trans ωSup c · exact le_ωSup _ _ · assumption exact ωSup_le _ _ ‹_› lemma isLUB_range_ωSup (c : Chain α) : IsLUB (Set.range c) (ωSup c) := by constructor · simp only [upperBounds, Set.mem_range, forall_exists_index, forall_apply_eq_imp_iff, Set.mem_setOf_eq] exact fun a ↦ le_ωSup c a · simp only [lowerBounds, upperBounds, Set.mem_range, forall_exists_index, forall_apply_eq_imp_iff, Set.mem_setOf_eq] exact fun ⦃a⦄ a_1 ↦ ωSup_le c a a_1 lemma ωSup_eq_of_isLUB {c : Chain α} {a : α} (h : IsLUB (Set.range c) a) : a = ωSup c := by rw [le_antisymm_iff] simp only [IsLUB, IsLeast, upperBounds, lowerBounds, Set.mem_range, forall_exists_index, forall_apply_eq_imp_iff, Set.mem_setOf_eq] at h constructor · apply h.2 exact fun a ↦ le_ωSup c a · rw [ωSup_le_iff] apply h.1 /-- A subset `p : α → Prop` of the type closed under `ωSup` induces an `OmegaCompletePartialOrder` on the subtype `{a : α // p a}`. -/ def subtype {α : Type} [OmegaCompletePartialOrder α] (p : α → Prop) (hp : ∀ c : Chain α, (∀ i ∈ c, p i) → p (ωSup c)) : OmegaCompletePartialOrder (Subtype p) := OmegaCompletePartialOrder.lift (OrderHom.Subtype.val p) (fun c => ⟨ωSup _, hp (c.map (OrderHom.Subtype.val p)) fun _ ⟨n, q⟩ => q.symm ▸ (c n).2⟩) (fun _ _ h => h) (fun _ => rfl) section Continuity open Chain variable [OmegaCompletePartialOrder β] variable [OmegaCompletePartialOrder γ] variable {f : α → β} {g : β → γ} /-- A function `f` between `ω`-complete partial orders is `ωScottContinuous` if it is Scott continuous over chains. -/	def ωScottContinuous (f : α → β) : Prop := ScottContinuousOn (Set.range fun c : Chain α => Set.range c) f lemma _root_.ScottContinuous.ωScottContinuous (hf : ScottContinuous f) : ωScottContinuous f := hf.scottContinuousOn lemma ωScottContinuous.monotone (h : ωScottContinuous f) : Monotone f := ScottContinuousOn.monotone _ (fun a b hab => by use pair a b hab; exact range_pair a b hab) h	Mathlib/Order/OmegaCompletePartialOrder.lean	247	255
/- Copyright (c) 2019 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl -/ import Mathlib.Order.Filter.Prod import Mathlib.Order.ConditionallyCompleteLattice.Basic import Mathlib.Order.Filter.Finite import Mathlib.Order.Filter.Bases.Basic /-! # Lift filters along filter and set functions -/ open Set Filter Function namespace Filter variable {α β γ : Type} {ι : Sort} section lift variable {f f₁ f₂ : Filter α} {g g₁ g₂ : Set α → Filter β} @[simp] theorem lift_top (g : Set α → Filter β) : (⊤ : Filter α).lift g = g univ := by simp [Filter.lift] /-- If `(p : ι → Prop, s : ι → Set α)` is a basis of a filter `f`, `g` is a monotone function `Set α → Filter γ`, and for each `i`, `(pg : β i → Prop, sg : β i → Set α)` is a basis of the filter `g (s i)`, then `(fun (i : ι) (x : β i) ↦ p i ∧ pg i x, fun (i : ι) (x : β i) ↦ sg i x)` is a basis of the filter `f.lift g`. This basis is parametrized by `i : ι` and `x : β i`, so in order to formulate this fact using `Filter.HasBasis` one has to use `Σ i, β i` as the index type, see `Filter.HasBasis.lift`. This lemma states the corresponding `mem_iff` statement without using a sigma type. -/ theorem HasBasis.mem_lift_iff {ι} {p : ι → Prop} {s : ι → Set α} {f : Filter α} (hf : f.HasBasis p s) {β : ι → Type} {pg : ∀ i, β i → Prop} {sg : ∀ i, β i → Set γ} {g : Set α → Filter γ} (hg : ∀ i, (g <\| s i).HasBasis (pg i) (sg i)) (gm : Monotone g) {s : Set γ} : s ∈ f.lift g ↔ ∃ i, p i ∧ ∃ x, pg i x ∧ sg i x ⊆ s := by refine (mem_biInf_of_directed ?_ ⟨univ, univ_sets _⟩).trans ?_ · intro t₁ ht₁ t₂ ht₂ exact ⟨t₁ ∩ t₂, inter_mem ht₁ ht₂, gm inter_subset_left, gm inter_subset_right⟩ · simp only [← (hg _).mem_iff] exact hf.exists_iff fun t₁ t₂ ht H => gm ht H /-- If `(p : ι → Prop, s : ι → Set α)` is a basis of a filter `f`, `g` is a monotone function `Set α → Filter γ`, and for each `i`, `(pg : β i → Prop, sg : β i → Set α)` is a basis of the filter `g (s i)`, then `(fun (i : ι) (x : β i) ↦ p i ∧ pg i x, fun (i : ι) (x : β i) ↦ sg i x)` is a basis of the filter `f.lift g`. This basis is parametrized by `i : ι` and `x : β i`, so in order to formulate this fact using `has_basis` one has to use `Σ i, β i` as the index type. See also `Filter.HasBasis.mem_lift_iff` for the corresponding `mem_iff` statement formulated without using a sigma type. -/ theorem HasBasis.lift {ι} {p : ι → Prop} {s : ι → Set α} {f : Filter α} (hf : f.HasBasis p s) {β : ι → Type} {pg : ∀ i, β i → Prop} {sg : ∀ i, β i → Set γ} {g : Set α → Filter γ} (hg : ∀ i, (g (s i)).HasBasis (pg i) (sg i)) (gm : Monotone g) : (f.lift g).HasBasis (fun i : Σi, β i => p i.1 ∧ pg i.1 i.2) fun i : Σi, β i => sg i.1 i.2 := by refine ⟨fun t => (hf.mem_lift_iff hg gm).trans ?_⟩ simp [Sigma.exists, and_assoc, exists_and_left] theorem mem_lift_sets (hg : Monotone g) {s : Set β} : s ∈ f.lift g ↔ ∃ t ∈ f, s ∈ g t := (f.basis_sets.mem_lift_iff (fun s => (g s).basis_sets) hg).trans <\| by simp only [id, exists_mem_subset_iff] theorem sInter_lift_sets (hg : Monotone g) : ⋂₀ { s \| s ∈ f.lift g } = ⋂ s ∈ f, ⋂₀ { t \| t ∈ g s } := by simp only [sInter_eq_biInter, mem_setOf_eq, Filter.mem_sets, mem_lift_sets hg, iInter_exists, iInter_and, @iInter_comm _ (Set β)] theorem mem_lift {s : Set β} {t : Set α} (ht : t ∈ f) (hs : s ∈ g t) : s ∈ f.lift g := le_principal_iff.mp <\| show f.lift g ≤ 𝓟 s from iInf_le_of_le t <\| iInf_le_of_le ht <\| le_principal_iff.mpr hs theorem lift_le {f : Filter α} {g : Set α → Filter β} {h : Filter β} {s : Set α} (hs : s ∈ f) (hg : g s ≤ h) : f.lift g ≤ h := iInf₂_le_of_le s hs hg theorem le_lift {f : Filter α} {g : Set α → Filter β} {h : Filter β} : h ≤ f.lift g ↔ ∀ s ∈ f, h ≤ g s := le_iInf₂_iff theorem lift_mono (hf : f₁ ≤ f₂) (hg : g₁ ≤ g₂) : f₁.lift g₁ ≤ f₂.lift g₂ := iInf_mono fun s => iInf_mono' fun hs => ⟨hf hs, hg s⟩ theorem lift_mono' (hg : ∀ s ∈ f, g₁ s ≤ g₂ s) : f.lift g₁ ≤ f.lift g₂ := iInf₂_mono hg theorem tendsto_lift {m : γ → β} {l : Filter γ} : Tendsto m l (f.lift g) ↔ ∀ s ∈ f, Tendsto m l (g s) := by simp only [Filter.lift, tendsto_iInf] theorem map_lift_eq {m : β → γ} (hg : Monotone g) : map m (f.lift g) = f.lift (map m ∘ g) := have : Monotone (map m ∘ g) := map_mono.comp hg Filter.ext fun s => by simp only [mem_lift_sets hg, mem_lift_sets this, exists_prop, mem_map, Function.comp_apply] theorem comap_lift_eq {m : γ → β} : comap m (f.lift g) = f.lift (comap m ∘ g) := by simp only [Filter.lift, comap_iInf]; rfl theorem comap_lift_eq2 {m : β → α} {g : Set β → Filter γ} (hg : Monotone g) : (comap m f).lift g = f.lift (g ∘ preimage m) := le_antisymm (le_iInf₂ fun s hs => iInf₂_le (m ⁻¹' s) ⟨s, hs, Subset.rfl⟩) (le_iInf₂ fun _s ⟨s', hs', h_sub⟩ => iInf₂_le_of_le s' hs' <\| hg h_sub) theorem lift_map_le {g : Set β → Filter γ} {m : α → β} : (map m f).lift g ≤ f.lift (g ∘ image m) := le_lift.2 fun _s hs => lift_le (image_mem_map hs) le_rfl theorem map_lift_eq2 {g : Set β → Filter γ} {m : α → β} (hg : Monotone g) : (map m f).lift g = f.lift (g ∘ image m) := lift_map_le.antisymm <\| le_lift.2 fun _s hs => lift_le hs <\| hg <\| image_preimage_subset _ _ theorem lift_comm {g : Filter β} {h : Set α → Set β → Filter γ} : (f.lift fun s => g.lift (h s)) = g.lift fun t => f.lift fun s => h s t := le_antisymm (le_iInf fun i => le_iInf fun hi => le_iInf fun j => le_iInf fun hj => iInf_le_of_le j <\| iInf_le_of_le hj <\| iInf_le_of_le i <\| iInf_le _ hi) (le_iInf fun i => le_iInf fun hi => le_iInf fun j => le_iInf fun hj => iInf_le_of_le j <\| iInf_le_of_le hj <\| iInf_le_of_le i <\| iInf_le _ hi) theorem lift_assoc {h : Set β → Filter γ} (hg : Monotone g) : (f.lift g).lift h = f.lift fun s => (g s).lift h := le_antisymm (le_iInf₂ fun _s hs => le_iInf₂ fun t ht => iInf_le_of_le t <\| iInf_le _ <\| (mem_lift_sets hg).mpr ⟨_, hs, ht⟩) (le_iInf₂ fun t ht => let ⟨s, hs, h'⟩ := (mem_lift_sets hg).mp ht iInf_le_of_le s <\| iInf_le_of_le hs <\| iInf_le_of_le t <\| iInf_le _ h') theorem lift_lift_same_le_lift {g : Set α → Set α → Filter β} : (f.lift fun s => f.lift (g s)) ≤ f.lift fun s => g s s := le_lift.2 fun _s hs => lift_le hs <\| lift_le hs le_rfl theorem lift_lift_same_eq_lift {g : Set α → Set α → Filter β} (hg₁ : ∀ s, Monotone fun t => g s t) (hg₂ : ∀ t, Monotone fun s => g s t) : (f.lift fun s => f.lift (g s)) = f.lift fun s => g s s := lift_lift_same_le_lift.antisymm <\| le_lift.2 fun s hs => le_lift.2 fun t ht => lift_le (inter_mem hs ht) <\| calc g (s ∩ t) (s ∩ t) ≤ g s (s ∩ t) := hg₂ (s ∩ t) inter_subset_left _ ≤ g s t := hg₁ s inter_subset_right theorem lift_principal {s : Set α} (hg : Monotone g) : (𝓟 s).lift g = g s := (lift_le (mem_principal_self _) le_rfl).antisymm (le_lift.2 fun _t ht => hg ht) theorem monotone_lift [Preorder γ] {f : γ → Filter α} {g : γ → Set α → Filter β} (hf : Monotone f) (hg : Monotone g) : Monotone fun c => (f c).lift (g c) := fun _ _ h => lift_mono (hf h) (hg h) theorem lift_neBot_iff (hm : Monotone g) : (NeBot (f.lift g)) ↔ ∀ s ∈ f, NeBot (g s) := by simp only [neBot_iff, Ne, ← empty_mem_iff_bot, mem_lift_sets hm, not_exists, not_and] @[simp] theorem lift_const {f : Filter α} {g : Filter β} : (f.lift fun _ => g) = g := iInf_subtype'.trans iInf_const @[simp] theorem lift_inf {f : Filter α} {g h : Set α → Filter β} : (f.lift fun x => g x ⊓ h x) = f.lift g ⊓ f.lift h := by simp only [Filter.lift, iInf_inf_eq] @[simp] theorem lift_principal2 {f : Filter α} : f.lift 𝓟 = f := le_antisymm (fun s hs => mem_lift hs (mem_principal_self s)) (le_iInf fun s => le_iInf fun hs => by simp only [hs, le_principal_iff]) theorem lift_iInf_le {f : ι → Filter α} {g : Set α → Filter β} : (iInf f).lift g ≤ ⨅ i, (f i).lift g := le_iInf fun _ => lift_mono (iInf_le _ _) le_rfl theorem lift_iInf [Nonempty ι] {f : ι → Filter α} {g : Set α → Filter β} (hg : ∀ s t, g (s ∩ t) = g s ⊓ g t) : (iInf f).lift g = ⨅ i, (f i).lift g := by refine lift_iInf_le.antisymm fun s => ?_ have H : ∀ t ∈ iInf f, ⨅ i, (f i).lift g ≤ g t := by intro t ht refine iInf_sets_induct ht ?_ fun hs ht => ?_ · inhabit ι exact iInf₂_le_of_le default univ (iInf_le _ univ_mem) · rw [hg]	exact le_inf (iInf₂_le_of_le _ _ <\| iInf_le _ hs) ht simp only [mem_lift_sets (Monotone.of_map_inf hg), exists_imp, and_imp]	Mathlib/Order/Filter/Lift.lean	177	178
/- Copyright (c) 2018 Ellen Arlt. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Ellen Arlt, Blair Shi, Sean Leather, Mario Carneiro, Johan Commelin, Lu-Ming Zhang -/ import Mathlib.Algebra.Algebra.Opposite import Mathlib.Algebra.Algebra.Pi import Mathlib.Algebra.BigOperators.RingEquiv import Mathlib.Data.Finite.Prod import Mathlib.Data.Matrix.Mul import Mathlib.LinearAlgebra.Pi /-! # Matrices This file contains basic results on matrices including bundled versions of matrix operators. ## Implementation notes For convenience, `Matrix m n α` is defined as `m → n → α`, as this allows elements of the matrix to be accessed with `A i j`. However, it is not advisable to _construct_ matrices using terms of the form `fun i j ↦ _` or even `(fun i j ↦ _ : Matrix m n α)`, as these are not recognized by Lean as having the right type. Instead, `Matrix.of` should be used. ## TODO Under various conditions, multiplication of infinite matrices makes sense. These have not yet been implemented. -/ assert_not_exists Star universe u u' v w variable {l m n o : Type} {m' : o → Type} {n' : o → Type} variable {R : Type} {S : Type} {α : Type v} {β : Type w} {γ : Type} namespace Matrix instance decidableEq [DecidableEq α] [Fintype m] [Fintype n] : DecidableEq (Matrix m n α) := Fintype.decidablePiFintype instance {n m} [Fintype m] [DecidableEq m] [Fintype n] [DecidableEq n] (α) [Fintype α] : Fintype (Matrix m n α) := inferInstanceAs (Fintype (m → n → α)) instance {n m} [Finite m] [Finite n] (α) [Finite α] : Finite (Matrix m n α) := inferInstanceAs (Finite (m → n → α)) section variable (R) /-- This is `Matrix.of` bundled as a linear equivalence. -/ def ofLinearEquiv [Semiring R] [AddCommMonoid α] [Module R α] : (m → n → α) ≃ₗ[R] Matrix m n α where __ := ofAddEquiv map_smul' _ _ := rfl @[simp] lemma coe_ofLinearEquiv [Semiring R] [AddCommMonoid α] [Module R α] : ⇑(ofLinearEquiv _ : (m → n → α) ≃ₗ[R] Matrix m n α) = of := rfl @[simp] lemma coe_ofLinearEquiv_symm [Semiring R] [AddCommMonoid α] [Module R α] : ⇑((ofLinearEquiv _).symm : Matrix m n α ≃ₗ[R] (m → n → α)) = of.symm := rfl end theorem sum_apply [AddCommMonoid α] (i : m) (j : n) (s : Finset β) (g : β → Matrix m n α) : (∑ c ∈ s, g c) i j = ∑ c ∈ s, g c i j := (congr_fun (s.sum_apply i g) j).trans (s.sum_apply j _) end Matrix open Matrix namespace Matrix section Diagonal variable [DecidableEq n] variable (n α) /-- `Matrix.diagonal` as an `AddMonoidHom`. -/ @[simps] def diagonalAddMonoidHom [AddZeroClass α] : (n → α) →+ Matrix n n α where toFun := diagonal map_zero' := diagonal_zero map_add' x y := (diagonal_add x y).symm variable (R) /-- `Matrix.diagonal` as a `LinearMap`. -/ @[simps] def diagonalLinearMap [Semiring R] [AddCommMonoid α] [Module R α] : (n → α) →ₗ[R] Matrix n n α := { diagonalAddMonoidHom n α with map_smul' := diagonal_smul } variable {n α R} section One variable [Zero α] [One α] lemma zero_le_one_elem [Preorder α] [ZeroLEOneClass α] (i j : n) : 0 ≤ (1 : Matrix n n α) i j := by by_cases hi : i = j · subst hi simp · simp [hi] lemma zero_le_one_row [Preorder α] [ZeroLEOneClass α] (i : n) : 0 ≤ (1 : Matrix n n α) i := zero_le_one_elem i end One end Diagonal section Diag variable (n α) /-- `Matrix.diag` as an `AddMonoidHom`. -/ @[simps] def diagAddMonoidHom [AddZeroClass α] : Matrix n n α →+ n → α where toFun := diag map_zero' := diag_zero map_add' := diag_add variable (R) /-- `Matrix.diag` as a `LinearMap`. -/ @[simps] def diagLinearMap [Semiring R] [AddCommMonoid α] [Module R α] : Matrix n n α →ₗ[R] n → α := { diagAddMonoidHom n α with map_smul' := diag_smul } variable {n α R} @[simp] theorem diag_list_sum [AddMonoid α] (l : List (Matrix n n α)) : diag l.sum = (l.map diag).sum := map_list_sum (diagAddMonoidHom n α) l @[simp] theorem diag_multiset_sum [AddCommMonoid α] (s : Multiset (Matrix n n α)) : diag s.sum = (s.map diag).sum := map_multiset_sum (diagAddMonoidHom n α) s @[simp] theorem diag_sum {ι} [AddCommMonoid α] (s : Finset ι) (f : ι → Matrix n n α) : diag (∑ i ∈ s, f i) = ∑ i ∈ s, diag (f i) := map_sum (diagAddMonoidHom n α) f s end Diag open Matrix section AddCommMonoid variable [AddCommMonoid α] [Mul α] end AddCommMonoid section NonAssocSemiring variable [NonAssocSemiring α] variable (α n) /-- `Matrix.diagonal` as a `RingHom`. -/ @[simps] def diagonalRingHom [Fintype n] [DecidableEq n] : (n → α) →+* Matrix n n α := { diagonalAddMonoidHom n α with toFun := diagonal map_one' := diagonal_one map_mul' := fun _ _ => (diagonal_mul_diagonal' _ _).symm } end NonAssocSemiring section Semiring variable [Semiring α] theorem diagonal_pow [Fintype n] [DecidableEq n] (v : n → α) (k : ℕ) : diagonal v ^ k = diagonal (v ^ k) := (map_pow (diagonalRingHom n α) v k).symm /-- The ring homomorphism `α →+* Matrix n n α` sending `a` to the diagonal matrix with `a` on the diagonal. -/ def scalar (n : Type u) [DecidableEq n] [Fintype n] : α →+* Matrix n n α := (diagonalRingHom n α).comp <\| Pi.constRingHom n α section Scalar variable [DecidableEq n] [Fintype n] @[simp] theorem scalar_apply (a : α) : scalar n a = diagonal fun _ => a := rfl theorem scalar_inj [Nonempty n] {r s : α} : scalar n r = scalar n s ↔ r = s := (diagonal_injective.comp Function.const_injective).eq_iff theorem scalar_commute_iff {r : α} {M : Matrix n n α} : Commute (scalar n r) M ↔ r • M = MulOpposite.op r • M := by simp_rw [Commute, SemiconjBy, scalar_apply, ← smul_eq_diagonal_mul, ← op_smul_eq_mul_diagonal] theorem scalar_commute (r : α) (hr : ∀ r', Commute r r') (M : Matrix n n α) : Commute (scalar n r) M := scalar_commute_iff.2 <\| ext fun _ _ => hr _ end Scalar end Semiring section Algebra variable [Fintype n] [DecidableEq n] variable [CommSemiring R] [Semiring α] [Semiring β] [Algebra R α] [Algebra R β] instance instAlgebra : Algebra R (Matrix n n α) where algebraMap := (Matrix.scalar n).comp (algebraMap R α) commutes' _ _ := scalar_commute _ (fun _ => Algebra.commutes _ _) _ smul_def' r x := by ext; simp [Matrix.scalar, Algebra.smul_def r] theorem algebraMap_matrix_apply {r : R} {i j : n} : algebraMap R (Matrix n n α) r i j = if i = j then algebraMap R α r else 0 := by dsimp [algebraMap, Algebra.algebraMap, Matrix.scalar] split_ifs with h <;> simp [h, Matrix.one_apply_ne] theorem algebraMap_eq_diagonal (r : R) : algebraMap R (Matrix n n α) r = diagonal (algebraMap R (n → α) r) := rfl theorem algebraMap_eq_diagonalRingHom : algebraMap R (Matrix n n α) = (diagonalRingHom n α).comp (algebraMap R _) := rfl @[simp] theorem map_algebraMap (r : R) (f : α → β) (hf : f 0 = 0) (hf₂ : f (algebraMap R α r) = algebraMap R β r) : (algebraMap R (Matrix n n α) r).map f = algebraMap R (Matrix n n β) r := by rw [algebraMap_eq_diagonal, algebraMap_eq_diagonal, diagonal_map hf] simp [hf₂] variable (R) /-- `Matrix.diagonal` as an `AlgHom`. -/ @[simps] def diagonalAlgHom : (n → α) →ₐ[R] Matrix n n α := { diagonalRingHom n α with toFun := diagonal commutes' := fun r => (algebraMap_eq_diagonal r).symm } end Algebra section AddHom variable [Add α] variable (R α) in /-- Extracting entries from a matrix as an additive homomorphism. -/ @[simps] def entryAddHom (i : m) (j : n) : AddHom (Matrix m n α) α where toFun M := M i j map_add' _ _ := rfl -- It is necessary to spell out the name of the coercion explicitly on the RHS -- for unification to succeed lemma entryAddHom_eq_comp {i : m} {j : n} : entryAddHom α i j = ((Pi.evalAddHom (fun _ => α) j).comp (Pi.evalAddHom _ i)).comp (AddHomClass.toAddHom ofAddEquiv.symm) := rfl end AddHom section AddMonoidHom variable [AddZeroClass α] variable (R α) in /-- Extracting entries from a matrix as an additive monoid homomorphism. Note this cannot be upgraded to a ring homomorphism, as it does not respect multiplication. -/ @[simps] def entryAddMonoidHom (i : m) (j : n) : Matrix m n α →+ α where toFun M := M i j map_add' _ _ := rfl map_zero' := rfl -- It is necessary to spell out the name of the coercion explicitly on the RHS -- for unification to succeed lemma entryAddMonoidHom_eq_comp {i : m} {j : n} : entryAddMonoidHom α i j = ((Pi.evalAddMonoidHom (fun _ => α) j).comp (Pi.evalAddMonoidHom _ i)).comp (AddMonoidHomClass.toAddMonoidHom ofAddEquiv.symm) := by rfl @[simp] lemma evalAddMonoidHom_comp_diagAddMonoidHom (i : m) : (Pi.evalAddMonoidHom _ i).comp (diagAddMonoidHom m α) = entryAddMonoidHom α i i := by simp [AddMonoidHom.ext_iff] @[simp] lemma entryAddMonoidHom_toAddHom {i : m} {j : n} : (entryAddMonoidHom α i j : AddHom _ _) = entryAddHom α i j := rfl end AddMonoidHom section LinearMap variable [Semiring R] [AddCommMonoid α] [Module R α] variable (R α) in /-- Extracting entries from a matrix as a linear map. Note this cannot be upgraded to an algebra homomorphism, as it does not respect multiplication. -/ @[simps] def entryLinearMap (i : m) (j : n) : Matrix m n α →ₗ[R] α where toFun M := M i j map_add' _ _ := rfl map_smul' _ _ := rfl -- It is necessary to spell out the name of the coercion explicitly on the RHS -- for unification to succeed lemma entryLinearMap_eq_comp {i : m} {j : n} : entryLinearMap R α i j = LinearMap.proj j ∘ₗ LinearMap.proj i ∘ₗ (ofLinearEquiv R).symm.toLinearMap := by rfl @[simp] lemma proj_comp_diagLinearMap (i : m) : LinearMap.proj i ∘ₗ diagLinearMap m R α = entryLinearMap R α i i := by simp [LinearMap.ext_iff] @[simp] lemma entryLinearMap_toAddMonoidHom {i : m} {j : n} : (entryLinearMap R α i j : _ →+ _) = entryAddMonoidHom α i j := rfl @[simp] lemma entryLinearMap_toAddHom {i : m} {j : n} : (entryLinearMap R α i j : AddHom _ _) = entryAddHom α i j := rfl end LinearMap end Matrix /-! ### Bundled versions of `Matrix.map` -/ namespace Equiv /-- The `Equiv` between spaces of matrices induced by an `Equiv` between their coefficients. This is `Matrix.map` as an `Equiv`. -/ @[simps apply] def mapMatrix (f : α ≃ β) : Matrix m n α ≃ Matrix m n β where toFun M := M.map f invFun M := M.map f.symm left_inv _ := Matrix.ext fun _ _ => f.symm_apply_apply _ right_inv _ := Matrix.ext fun _ _ => f.apply_symm_apply _ @[simp] theorem mapMatrix_refl : (Equiv.refl α).mapMatrix = Equiv.refl (Matrix m n α) := rfl @[simp] theorem mapMatrix_symm (f : α ≃ β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m n β ≃ _) := rfl @[simp] theorem mapMatrix_trans (f : α ≃ β) (g : β ≃ γ) : f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m n α ≃ _) := rfl end Equiv namespace AddMonoidHom variable [AddZeroClass α] [AddZeroClass β] [AddZeroClass γ] /-- The `AddMonoidHom` between spaces of matrices induced by an `AddMonoidHom` between their coefficients. This is `Matrix.map` as an `AddMonoidHom`. -/ @[simps] def mapMatrix (f : α →+ β) : Matrix m n α →+ Matrix m n β where toFun M := M.map f map_zero' := Matrix.map_zero f f.map_zero map_add' := Matrix.map_add f f.map_add @[simp] theorem mapMatrix_id : (AddMonoidHom.id α).mapMatrix = AddMonoidHom.id (Matrix m n α) := rfl @[simp] theorem mapMatrix_comp (f : β →+ γ) (g : α →+ β) : f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m n α →+ _) := rfl @[simp] lemma entryAddMonoidHom_comp_mapMatrix (f : α →+ β) (i : m) (j : n) : (entryAddMonoidHom β i j).comp f.mapMatrix = f.comp (entryAddMonoidHom α i j) := rfl end AddMonoidHom namespace AddEquiv variable [Add α] [Add β] [Add γ] /-- The `AddEquiv` between spaces of matrices induced by an `AddEquiv` between their coefficients. This is `Matrix.map` as an `AddEquiv`. -/ @[simps apply] def mapMatrix (f : α ≃+ β) : Matrix m n α ≃+ Matrix m n β := { f.toEquiv.mapMatrix with toFun := fun M => M.map f invFun := fun M => M.map f.symm map_add' := Matrix.map_add f (map_add f) } @[simp] theorem mapMatrix_refl : (AddEquiv.refl α).mapMatrix = AddEquiv.refl (Matrix m n α) := rfl @[simp] theorem mapMatrix_symm (f : α ≃+ β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m n β ≃+ _) := rfl @[simp] theorem mapMatrix_trans (f : α ≃+ β) (g : β ≃+ γ) : f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m n α ≃+ _) := rfl @[simp] lemma entryAddHom_comp_mapMatrix (f : α ≃+ β) (i : m) (j : n) : (entryAddHom β i j).comp (AddHomClass.toAddHom f.mapMatrix) = (f : AddHom α β).comp (entryAddHom _ i j) := rfl end AddEquiv namespace LinearMap variable [Semiring R] [AddCommMonoid α] [AddCommMonoid β] [AddCommMonoid γ] variable [Module R α] [Module R β] [Module R γ] /-- The `LinearMap` between spaces of matrices induced by a `LinearMap` between their coefficients. This is `Matrix.map` as a `LinearMap`. -/ @[simps] def mapMatrix (f : α →ₗ[R] β) : Matrix m n α →ₗ[R] Matrix m n β where toFun M := M.map f map_add' := Matrix.map_add f f.map_add map_smul' r := Matrix.map_smul f r (f.map_smul r) @[simp] theorem mapMatrix_id : LinearMap.id.mapMatrix = (LinearMap.id : Matrix m n α →ₗ[R] _) := rfl @[simp] theorem mapMatrix_comp (f : β →ₗ[R] γ) (g : α →ₗ[R] β) : f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m n α →ₗ[R] _) := rfl @[simp] lemma entryLinearMap_comp_mapMatrix (f : α →ₗ[R] β) (i : m) (j : n) : entryLinearMap R _ i j ∘ₗ f.mapMatrix = f ∘ₗ entryLinearMap R _ i j := rfl end LinearMap namespace LinearEquiv variable [Semiring R] [AddCommMonoid α] [AddCommMonoid β] [AddCommMonoid γ] variable [Module R α] [Module R β] [Module R γ] /-- The `LinearEquiv` between spaces of matrices induced by a `LinearEquiv` between their coefficients. This is `Matrix.map` as a `LinearEquiv`. -/ @[simps apply] def mapMatrix (f : α ≃ₗ[R] β) : Matrix m n α ≃ₗ[R] Matrix m n β := { f.toEquiv.mapMatrix, f.toLinearMap.mapMatrix with toFun := fun M => M.map f invFun := fun M => M.map f.symm } @[simp] theorem mapMatrix_refl : (LinearEquiv.refl R α).mapMatrix = LinearEquiv.refl R (Matrix m n α) := rfl @[simp] theorem mapMatrix_symm (f : α ≃ₗ[R] β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m n β ≃ₗ[R] _) := rfl @[simp] theorem mapMatrix_trans (f : α ≃ₗ[R] β) (g : β ≃ₗ[R] γ) : f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m n α ≃ₗ[R] _) := rfl @[simp] lemma mapMatrix_toLinearMap (f : α ≃ₗ[R] β) : (f.mapMatrix : _ ≃ₗ[R] Matrix m n β).toLinearMap = f.toLinearMap.mapMatrix := by rfl @[simp] lemma entryLinearMap_comp_mapMatrix (f : α ≃ₗ[R] β) (i : m) (j : n) : entryLinearMap R _ i j ∘ₗ f.mapMatrix.toLinearMap = f.toLinearMap ∘ₗ entryLinearMap R _ i j := by simp only [mapMatrix_toLinearMap, LinearMap.entryLinearMap_comp_mapMatrix] end LinearEquiv namespace RingHom variable [Fintype m] [DecidableEq m] variable [NonAssocSemiring α] [NonAssocSemiring β] [NonAssocSemiring γ] /-- The `RingHom` between spaces of square matrices induced by a `RingHom` between their coefficients. This is `Matrix.map` as a `RingHom`. -/ @[simps] def mapMatrix (f : α →+* β) : Matrix m m α →+* Matrix m m β := { f.toAddMonoidHom.mapMatrix with toFun := fun M => M.map f map_one' := by simp map_mul' := fun _ _ => Matrix.map_mul } @[simp] theorem mapMatrix_id : (RingHom.id α).mapMatrix = RingHom.id (Matrix m m α) := rfl @[simp] theorem mapMatrix_comp (f : β →+* γ) (g : α →+* β) : f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m m α →+* _) := rfl end RingHom namespace RingEquiv variable [Fintype m] [DecidableEq m] variable [NonAssocSemiring α] [NonAssocSemiring β] [NonAssocSemiring γ] /-- The `RingEquiv` between spaces of square matrices induced by a `RingEquiv` between their coefficients. This is `Matrix.map` as a `RingEquiv`. -/ @[simps apply] def mapMatrix (f : α ≃+* β) : Matrix m m α ≃+* Matrix m m β := { f.toRingHom.mapMatrix, f.toAddEquiv.mapMatrix with toFun := fun M => M.map f invFun := fun M => M.map f.symm } @[simp] theorem mapMatrix_refl : (RingEquiv.refl α).mapMatrix = RingEquiv.refl (Matrix m m α) := rfl @[simp] theorem mapMatrix_symm (f : α ≃+* β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m m β ≃+* _) := rfl @[simp] theorem mapMatrix_trans (f : α ≃+* β) (g : β ≃+* γ) : f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m m α ≃+* _) := rfl open MulOpposite in /-- For any ring `R`, we have ring isomorphism `Matₙₓₙ(Rᵒᵖ) ≅ (Matₙₓₙ(R))ᵒᵖ` given by transpose. -/ @[simps apply symm_apply] def mopMatrix : Matrix m m αᵐᵒᵖ ≃+* (Matrix m m α)ᵐᵒᵖ where toFun M := op (M.transpose.map unop) invFun M := M.unop.transpose.map op left_inv _ := by aesop right_inv _ := by aesop map_mul' _ _ := unop_injective <\| by ext; simp [transpose, mul_apply] map_add' _ _ := by aesop end RingEquiv namespace AlgHom variable [Fintype m] [DecidableEq m] variable [CommSemiring R] [Semiring α] [Semiring β] [Semiring γ] variable [Algebra R α] [Algebra R β] [Algebra R γ] /-- The `AlgHom` between spaces of square matrices induced by an `AlgHom` between their coefficients. This is `Matrix.map` as an `AlgHom`. -/ @[simps] def mapMatrix (f : α →ₐ[R] β) : Matrix m m α →ₐ[R] Matrix m m β := { f.toRingHom.mapMatrix with toFun := fun M => M.map f commutes' := fun r => Matrix.map_algebraMap r f (map_zero _) (f.commutes r) } @[simp] theorem mapMatrix_id : (AlgHom.id R α).mapMatrix = AlgHom.id R (Matrix m m α) := rfl @[simp] theorem mapMatrix_comp (f : β →ₐ[R] γ) (g : α →ₐ[R] β) : f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m m α →ₐ[R] _) := rfl end AlgHom namespace AlgEquiv variable [Fintype m] [DecidableEq m] variable [CommSemiring R] [Semiring α] [Semiring β] [Semiring γ] variable [Algebra R α] [Algebra R β] [Algebra R γ] /-- The `AlgEquiv` between spaces of square matrices induced by an `AlgEquiv` between their coefficients. This is `Matrix.map` as an `AlgEquiv`. -/ @[simps apply] def mapMatrix (f : α ≃ₐ[R] β) : Matrix m m α ≃ₐ[R] Matrix m m β := { f.toAlgHom.mapMatrix, f.toRingEquiv.mapMatrix with toFun := fun M => M.map f invFun := fun M => M.map f.symm } @[simp] theorem mapMatrix_refl : AlgEquiv.refl.mapMatrix = (AlgEquiv.refl : Matrix m m α ≃ₐ[R] _) := rfl @[simp] theorem mapMatrix_symm (f : α ≃ₐ[R] β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m m β ≃ₐ[R] _) := rfl @[simp] theorem mapMatrix_trans (f : α ≃ₐ[R] β) (g : β ≃ₐ[R] γ) : f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m m α ≃ₐ[R] _) := rfl /-- For any algebra `α` over a ring `R`, we have an `R`-algebra isomorphism `Matₙₓₙ(αᵒᵖ) ≅ (Matₙₓₙ(R))ᵒᵖ` given by transpose. If `α` is commutative, we can get rid of the `ᵒᵖ` in the left-hand side, see `Matrix.transposeAlgEquiv`. -/ @[simps!] def mopMatrix : Matrix m m αᵐᵒᵖ ≃ₐ[R] (Matrix m m α)ᵐᵒᵖ where __ := RingEquiv.mopMatrix commutes' _ := MulOpposite.unop_injective <\| by ext; simp [algebraMap_matrix_apply, eq_comm, apply_ite MulOpposite.unop] end AlgEquiv open Matrix namespace Matrix section Transpose open Matrix variable (m n α) /-- `Matrix.transpose` as an `AddEquiv` -/ @[simps apply] def transposeAddEquiv [Add α] : Matrix m n α ≃+ Matrix n m α where toFun := transpose invFun := transpose left_inv := transpose_transpose right_inv := transpose_transpose map_add' := transpose_add @[simp] theorem transposeAddEquiv_symm [Add α] : (transposeAddEquiv m n α).symm = transposeAddEquiv n m α := rfl variable {m n α} theorem transpose_list_sum [AddMonoid α] (l : List (Matrix m n α)) : l.sumᵀ = (l.map transpose).sum := map_list_sum (transposeAddEquiv m n α) l theorem transpose_multiset_sum [AddCommMonoid α] (s : Multiset (Matrix m n α)) : s.sumᵀ = (s.map transpose).sum := (transposeAddEquiv m n α).toAddMonoidHom.map_multiset_sum s theorem transpose_sum [AddCommMonoid α] {ι : Type} (s : Finset ι) (M : ι → Matrix m n α) : (∑ i ∈ s, M i)ᵀ = ∑ i ∈ s, (M i)ᵀ := map_sum (transposeAddEquiv m n α) _ s variable (m n R α) /-- `Matrix.transpose` as a `LinearMap` -/ @[simps apply] def transposeLinearEquiv [Semiring R] [AddCommMonoid α] [Module R α] : Matrix m n α ≃ₗ[R] Matrix n m α := { transposeAddEquiv m n α with map_smul' := transpose_smul } @[simp] theorem transposeLinearEquiv_symm [Semiring R] [AddCommMonoid α] [Module R α] : (transposeLinearEquiv m n R α).symm = transposeLinearEquiv n m R α := rfl variable {m n R α} variable (m α) /-- `Matrix.transpose` as a `RingEquiv` to the opposite ring -/ @[simps] def transposeRingEquiv [AddCommMonoid α] [CommSemigroup α] [Fintype m] : Matrix m m α ≃+ (Matrix m m α)ᵐᵒᵖ := { (transposeAddEquiv m m α).trans MulOpposite.opAddEquiv with toFun := fun M => MulOpposite.op Mᵀ invFun := fun M => M.unopᵀ map_mul' := fun M N => (congr_arg MulOpposite.op (transpose_mul M N)).trans (MulOpposite.op_mul _ _) left_inv := fun M => transpose_transpose M right_inv := fun M => MulOpposite.unop_injective <\| transpose_transpose M.unop } variable {m α} @[simp] theorem transpose_pow [CommSemiring α] [Fintype m] [DecidableEq m] (M : Matrix m m α) (k : ℕ) : (M ^ k)ᵀ = Mᵀ ^ k := MulOpposite.op_injective <\| map_pow (transposeRingEquiv m α) M k theorem transpose_list_prod [CommSemiring α] [Fintype m] [DecidableEq m] (l : List (Matrix m m α)) : l.prodᵀ = (l.map transpose).reverse.prod := (transposeRingEquiv m α).unop_map_list_prod l variable (R m α) /-- `Matrix.transpose` as an `AlgEquiv` to the opposite ring -/ @[simps] def transposeAlgEquiv [CommSemiring R] [CommSemiring α] [Fintype m] [DecidableEq m] [Algebra R α] : Matrix m m α ≃ₐ[R] (Matrix m m α)ᵐᵒᵖ := { (transposeAddEquiv m m α).trans MulOpposite.opAddEquiv, transposeRingEquiv m α with toFun := fun M => MulOpposite.op Mᵀ commutes' := fun r => by simp only [algebraMap_eq_diagonal, diagonal_transpose, MulOpposite.algebraMap_apply] } variable {R m α} end Transpose end Matrix		Mathlib/Data/Matrix/Basic.lean	1,025	1,028
/- Copyright (c) 2021 Henry Swanson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Henry Swanson -/ import Mathlib.Algebra.BigOperators.Ring.Finset import Mathlib.Combinatorics.Derangements.Basic import Mathlib.Data.Fintype.BigOperators import Mathlib.Tactic.Ring /-! # Derangements on fintypes This file contains lemmas that describe the cardinality of `derangements α` when `α` is a fintype. # Main definitions * `card_derangements_invariant`: A lemma stating that the number of derangements on a type `α` depends only on the cardinality of `α`. * `numDerangements n`: The number of derangements on an n-element set, defined in a computation- friendly way. * `card_derangements_eq_numDerangements`: Proof that `numDerangements` really does compute the number of derangements. * `numDerangements_sum`: A lemma giving an expression for `numDerangements n` in terms of factorials. -/ open derangements Equiv Fintype variable {α : Type} [DecidableEq α] [Fintype α] instance : DecidablePred (derangements α) := fun _ => Fintype.decidableForallFintype -- Porting note: used to use the tactic delta_instance instance : Fintype (derangements α) := Subtype.fintype (fun (_ : Perm α) => ∀ (x_1 : α), ¬_ = x_1) theorem card_derangements_invariant {α β : Type} [Fintype α] [DecidableEq α] [Fintype β] [DecidableEq β] (h : card α = card β) : card (derangements α) = card (derangements β) := Fintype.card_congr (Equiv.derangementsCongr <\| equivOfCardEq h) theorem card_derangements_fin_add_two (n : ℕ) : card (derangements (Fin (n + 2))) = (n + 1) * card (derangements (Fin n)) + (n + 1) * card (derangements (Fin (n + 1))) := by -- get some basic results about the size of Fin (n+1) plus or minus an element have h1 : ∀ a : Fin (n + 1), card ({a}ᶜ : Set (Fin (n + 1))) = card (Fin n) := by intro a simp only [card_ofFinset (s := Finset.filter (fun x => x ∈ ({a}ᶜ : Set (Fin (n + 1)))) Finset.univ), Set.mem_compl_singleton_iff, Finset.filter_ne' _ a, Finset.card_erase_of_mem (Finset.mem_univ a), Finset.card_fin, add_tsub_cancel_right, card_fin] have h2 : card (Fin (n + 2)) = card (Option (Fin (n + 1))) := by simp only [card_fin, card_option] -- rewrite the LHS and substitute in our fintype-level equivalence simp only [card_derangements_invariant h2, card_congr (@derangementsRecursionEquiv (Fin (n + 1)) _),-- push the cardinality through the Σ and ⊕ so that we can use `card_n` card_sigma, card_sum, card_derangements_invariant (h1 _), Finset.sum_const, nsmul_eq_mul, Finset.card_fin, mul_add, Nat.cast_id] /-- The number of derangements of an `n`-element set. -/ def numDerangements : ℕ → ℕ \| 0 => 1 \| 1 => 0 \| n + 2 => (n + 1) * (numDerangements n + numDerangements (n + 1)) @[simp] theorem numDerangements_zero : numDerangements 0 = 1 := rfl @[simp] theorem numDerangements_one : numDerangements 1 = 0 := rfl theorem numDerangements_add_two (n : ℕ) : numDerangements (n + 2) = (n + 1) * (numDerangements n + numDerangements (n + 1)) := rfl theorem numDerangements_succ (n : ℕ) : (numDerangements (n + 1) : ℤ) = (n + 1) * (numDerangements n : ℤ) - (-1) ^ n := by induction n with \| zero => rfl \| succ n hn => simp only [numDerangements_add_two, hn, pow_succ, Int.natCast_mul, Int.natCast_add] ring theorem card_derangements_fin_eq_numDerangements {n : ℕ} : card (derangements (Fin n)) = numDerangements n := by induction n using Nat.strongRecOn with \| ind n hyp => _ rcases n with _ \| _ \| n -- knock out cases 0 and 1 · rfl	· rfl -- now we have n ≥ 2. rewrite everything in terms of card_derangements, so that we can use -- `card_derangements_fin_add_two` rw [numDerangements_add_two, card_derangements_fin_add_two, mul_add, hyp, hyp] <;> omega theorem card_derangements_eq_numDerangements (α : Type*) [Fintype α] [DecidableEq α] : card (derangements α) = numDerangements (card α) := by rw [← card_derangements_invariant (card_fin _)] exact card_derangements_fin_eq_numDerangements	Mathlib/Combinatorics/Derangements/Finite.lean	95	104
/- 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.Data.Ordmap.Invariants /-! # Verification of `Ordnode` This file uses the invariants defined in `Mathlib.Data.Ordmap.Invariants` to construct `Ordset α`, a wrapper around `Ordnode α` which includes the correctness invariant of the type. It exposes parallel operations like `insert` as functions on `Ordset` that do the same thing but bundle the correctness proofs. The advantage is that it is possible to, for example, prove that the result of `find` on `insert` will actually find the element, while `Ordnode` cannot guarantee this if the input tree did not satisfy the type invariants. ## Main definitions * `Ordnode.Valid`: The validity predicate for an `Ordnode` subtree. * `Ordset α`: A well formed set of values of type `α`. ## Implementation notes Because the `Ordnode` file was ported from Haskell, the correctness invariants of some of the functions have not been spelled out, and some theorems like `Ordnode.Valid'.balanceL_aux` show very intricate assumptions on the sizes, which may need to be revised if it turns out some operations violate these assumptions, because there is a decent amount of slop in the actual data structure invariants, so the theorem will go through with multiple choices of assumption. -/ variable {α : Type} namespace Ordnode section Valid variable [Preorder α] /-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are correct, the tree is balanced, and the elements of the tree are organized according to the ordering. This version of `Valid` also puts all elements in the tree in the interval `(lo, hi)`. -/ structure Valid' (lo : WithBot α) (t : Ordnode α) (hi : WithTop α) : Prop where ord : t.Bounded lo hi sz : t.Sized bal : t.Balanced /-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are correct, the tree is balanced, and the elements of the tree are organized according to the ordering. -/ def Valid (t : Ordnode α) : Prop := Valid' ⊥ t ⊤ theorem Valid'.mono_left {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' y t o) : Valid' x t o := ⟨h.1.mono_left xy, h.2, h.3⟩ theorem Valid'.mono_right {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' o t x) : Valid' o t y := ⟨h.1.mono_right xy, h.2, h.3⟩ theorem Valid'.trans_left {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (h : Bounded t₁ o₁ x) (H : Valid' x t₂ o₂) : Valid' o₁ t₂ o₂ := ⟨h.trans_left H.1, H.2, H.3⟩ theorem Valid'.trans_right {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t₁ x) (h : Bounded t₂ x o₂) : Valid' o₁ t₁ o₂ := ⟨H.1.trans_right h, H.2, H.3⟩ theorem Valid'.of_lt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil o₁ x) (h₂ : All (· < x) t) : Valid' o₁ t x := ⟨H.1.of_lt h₁ h₂, H.2, H.3⟩ theorem Valid'.of_gt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil x o₂) (h₂ : All (· > x) t) : Valid' x t o₂ := ⟨H.1.of_gt h₁ h₂, H.2, H.3⟩ theorem Valid'.valid {t o₁ o₂} (h : @Valid' α _ o₁ t o₂) : Valid t := ⟨h.1.weak, h.2, h.3⟩ theorem valid'_nil {o₁ o₂} (h : Bounded nil o₁ o₂) : Valid' o₁ (@nil α) o₂ := ⟨h, ⟨⟩, ⟨⟩⟩ theorem valid_nil : Valid (@nil α) := valid'_nil ⟨⟩ theorem Valid'.node {s l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : BalancedSz (size l) (size r)) (hs : s = size l + size r + 1) : Valid' o₁ (@node α s l x r) o₂ := ⟨⟨hl.1, hr.1⟩, ⟨hs, hl.2, hr.2⟩, ⟨H, hl.3, hr.3⟩⟩ theorem Valid'.dual : ∀ {t : Ordnode α} {o₁ o₂}, Valid' o₁ t o₂ → @Valid' αᵒᵈ _ o₂ (dual t) o₁ \| .nil, _, _, h => valid'_nil h.1.dual \| .node _ l _ r, _, _, ⟨⟨ol, Or⟩, ⟨rfl, sl, sr⟩, ⟨b, bl, br⟩⟩ => let ⟨ol', sl', bl'⟩ := Valid'.dual ⟨ol, sl, bl⟩ let ⟨or', sr', br'⟩ := Valid'.dual ⟨Or, sr, br⟩ ⟨⟨or', ol'⟩, ⟨by simp [size_dual, add_comm], sr', sl'⟩, ⟨by rw [size_dual, size_dual]; exact b.symm, br', bl'⟩⟩ theorem Valid'.dual_iff {t : Ordnode α} {o₁ o₂} : Valid' o₁ t o₂ ↔ @Valid' αᵒᵈ _ o₂ (.dual t) o₁ := ⟨Valid'.dual, fun h => by have := Valid'.dual h; rwa [dual_dual, OrderDual.Preorder.dual_dual] at this⟩ theorem Valid.dual {t : Ordnode α} : Valid t → @Valid αᵒᵈ _ (.dual t) := Valid'.dual theorem Valid.dual_iff {t : Ordnode α} : Valid t ↔ @Valid αᵒᵈ _ (.dual t) := Valid'.dual_iff theorem Valid'.left {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' o₁ l x := ⟨H.1.1, H.2.2.1, H.3.2.1⟩ theorem Valid'.right {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' x r o₂ := ⟨H.1.2, H.2.2.2, H.3.2.2⟩ nonrec theorem Valid.left {s l x r} (H : Valid (@node α s l x r)) : Valid l := H.left.valid nonrec theorem Valid.right {s l x r} (H : Valid (@node α s l x r)) : Valid r := H.right.valid theorem Valid.size_eq {s l x r} (H : Valid (@node α s l x r)) : size (@node α s l x r) = size l + size r + 1 := H.2.1 theorem Valid'.node' {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : BalancedSz (size l) (size r)) : Valid' o₁ (@node' α l x r) o₂ := hl.node hr H rfl theorem valid'_singleton {x : α} {o₁ o₂} (h₁ : Bounded nil o₁ x) (h₂ : Bounded nil x o₂) : Valid' o₁ (singleton x : Ordnode α) o₂ := (valid'_nil h₁).node (valid'_nil h₂) (Or.inl zero_le_one) rfl theorem valid_singleton {x : α} : Valid (singleton x : Ordnode α) := valid'_singleton ⟨⟩ ⟨⟩ theorem Valid'.node3L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m)) (H2 : BalancedSz (size l + size m + 1) (size r)) : Valid' o₁ (@node3L α l x m y r) o₂ := (hl.node' hm H1).node' hr H2 theorem Valid'.node3R {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m + size r + 1)) (H2 : BalancedSz (size m) (size r)) : Valid' o₁ (@node3R α l x m y r) o₂ := hl.node' (hm.node' hr H2) H1 theorem Valid'.node4L_lemma₁ {a b c d : ℕ} (lr₂ : 3 (b + c + 1 + d) ≤ 16 * a + 9) (mr₂ : b + c + 1 ≤ 3 * d) (mm₁ : b ≤ 3 * c) : b < 3 * a + 1 := by omega theorem Valid'.node4L_lemma₂ {b c d : ℕ} (mr₂ : b + c + 1 ≤ 3 * d) : c ≤ 3 * d := by omega theorem Valid'.node4L_lemma₃ {b c d : ℕ} (mr₁ : 2 * d ≤ b + c + 1) (mm₁ : b ≤ 3 * c) : d ≤ 3 * c := by omega theorem Valid'.node4L_lemma₄ {a b c d : ℕ} (lr₁ : 3 * a ≤ b + c + 1 + d) (mr₂ : b + c + 1 ≤ 3 * d) (mm₁ : b ≤ 3 * c) : a + b + 1 ≤ 3 * (c + d + 1) := by omega theorem Valid'.node4L_lemma₅ {a b c d : ℕ} (lr₂ : 3 * (b + c + 1 + d) ≤ 16 * a + 9) (mr₁ : 2 * d ≤ b + c + 1) (mm₂ : c ≤ 3 * b) : c + d + 1 ≤ 3 * (a + b + 1) := by omega theorem Valid'.node4L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' (↑y) r o₂) (Hm : 0 < size m) (H : size l = 0 ∧ size m = 1 ∧ size r ≤ 1 ∨ 0 < size l ∧ ratio * size r ≤ size m ∧ delta * size l ≤ size m + size r ∧ 3 * (size m + size r) ≤ 16 * size l + 9 ∧ size m ≤ delta * size r) : Valid' o₁ (@node4L α l x m y r) o₂ := by obtain - \| ⟨s, ml, z, mr⟩ := m; · cases Hm suffices BalancedSz (size l) (size ml) ∧ BalancedSz (size mr) (size r) ∧ BalancedSz (size l + size ml + 1) (size mr + size r + 1) from Valid'.node' (hl.node' hm.left this.1) (hm.right.node' hr this.2.1) this.2.2 rcases H with (⟨l0, m1, r0⟩ \| ⟨l0, mr₁, lr₁, lr₂, mr₂⟩) · rw [hm.2.size_eq, Nat.succ_inj, add_eq_zero] at m1 rw [l0, m1.1, m1.2]; revert r0; rcases size r with (_ \| _ \| _) <;> [decide; decide; (intro r0; unfold BalancedSz delta; omega)] · rcases Nat.eq_zero_or_pos (size r) with r0 \| r0 · rw [r0] at mr₂; cases not_le_of_lt Hm mr₂ rw [hm.2.size_eq] at lr₁ lr₂ mr₁ mr₂ by_cases mm : size ml + size mr ≤ 1 · have r1 := le_antisymm ((mul_le_mul_left (by decide)).1 (le_trans mr₁ (Nat.succ_le_succ mm) : _ ≤ ratio * 1)) r0 rw [r1, add_assoc] at lr₁ have l1 := le_antisymm ((mul_le_mul_left (by decide)).1 (le_trans lr₁ (add_le_add_right mm 2) : _ ≤ delta * 1)) l0 rw [l1, r1] revert mm; cases size ml <;> cases size mr <;> intro mm · decide · rw [zero_add] at mm; rcases mm with (_ \| ⟨⟨⟩⟩) decide · rcases mm with (_ \| ⟨⟨⟩⟩); decide · rw [Nat.succ_add] at mm; rcases mm with (_ \| ⟨⟨⟩⟩) rcases hm.3.1.resolve_left mm with ⟨mm₁, mm₂⟩ rcases Nat.eq_zero_or_pos (size ml) with ml0 \| ml0 · rw [ml0, mul_zero, Nat.le_zero] at mm₂ rw [ml0, mm₂] at mm; cases mm (by decide) have : 2 * size l ≤ size ml + size mr + 1 := by have := Nat.mul_le_mul_left ratio lr₁ rw [mul_left_comm, mul_add] at this have := le_trans this (add_le_add_left mr₁ _) rw [← Nat.succ_mul] at this exact (mul_le_mul_left (by decide)).1 this refine ⟨Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩⟩ · refine (mul_le_mul_left (by decide)).1 (le_trans this ?_) rw [two_mul, Nat.succ_le_iff] refine add_lt_add_of_lt_of_le ?_ mm₂ simpa using (mul_lt_mul_right ml0).2 (by decide : 1 < 3) · exact Nat.le_of_lt_succ (Valid'.node4L_lemma₁ lr₂ mr₂ mm₁) · exact Valid'.node4L_lemma₂ mr₂ · exact Valid'.node4L_lemma₃ mr₁ mm₁ · exact Valid'.node4L_lemma₄ lr₁ mr₂ mm₁ · exact Valid'.node4L_lemma₅ lr₂ mr₁ mm₂ theorem Valid'.rotateL_lemma₁ {a b c : ℕ} (H2 : 3 * a ≤ b + c) (hb₂ : c ≤ 3 * b) : a ≤ 3 * b := by omega theorem Valid'.rotateL_lemma₂ {a b c : ℕ} (H3 : 2 * (b + c) ≤ 9 * a + 3) (h : b < 2 * c) : b < 3 * a + 1 := by omega theorem Valid'.rotateL_lemma₃ {a b c : ℕ} (H2 : 3 * a ≤ b + c) (h : b < 2 * c) : a + b < 3 * c := by omega theorem Valid'.rotateL_lemma₄ {a b : ℕ} (H3 : 2 * b ≤ 9 * a + 3) : 3 * b ≤ 16 * a + 9 := by omega theorem Valid'.rotateL {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H1 : ¬size l + size r ≤ 1) (H2 : delta * size l < size r) (H3 : 2 * size r ≤ 9 * size l + 5 ∨ size r ≤ 3) : Valid' o₁ (@rotateL α l x r) o₂ := by obtain - \| ⟨rs, rl, rx, rr⟩ := r; · cases H2 rw [hr.2.size_eq, Nat.lt_succ_iff] at H2 rw [hr.2.size_eq] at H3 replace H3 : 2 * (size rl + size rr) ≤ 9 * size l + 3 ∨ size rl + size rr ≤ 2 := H3.imp (@Nat.le_of_add_le_add_right _ 2 _) Nat.le_of_succ_le_succ have H3_0 : size l = 0 → size rl + size rr ≤ 2 := by intro l0; rw [l0] at H3 exact (or_iff_right_of_imp fun h => (mul_le_mul_left (by decide)).1 (le_trans h (by decide))).1 H3 have H3p : size l > 0 → 2 * (size rl + size rr) ≤ 9 * size l + 3 := fun l0 : 1 ≤ size l => (or_iff_left_of_imp <\| by omega).1 H3 have ablem : ∀ {a b : ℕ}, 1 ≤ a → a + b ≤ 2 → b ≤ 1 := by omega have hlp : size l > 0 → ¬size rl + size rr ≤ 1 := fun l0 hb => absurd (le_trans (le_trans (Nat.mul_le_mul_left _ l0) H2) hb) (by decide) rw [Ordnode.rotateL_node]; split_ifs with h · have rr0 : size rr > 0 := (mul_lt_mul_left (by decide)).1 (lt_of_le_of_lt (Nat.zero_le _) h : ratio * 0 < _) suffices BalancedSz (size l) (size rl) ∧ BalancedSz (size l + size rl + 1) (size rr) by exact hl.node3L hr.left hr.right this.1 this.2 rcases Nat.eq_zero_or_pos (size l) with l0 \| l0 · rw [l0]; replace H3 := H3_0 l0 have := hr.3.1 rcases Nat.eq_zero_or_pos (size rl) with rl0 \| rl0 · rw [rl0] at this ⊢ rw [le_antisymm (balancedSz_zero.1 this.symm) rr0] decide have rr1 : size rr = 1 := le_antisymm (ablem rl0 H3) rr0 rw [add_comm] at H3 rw [rr1, show size rl = 1 from le_antisymm (ablem rr0 H3) rl0] decide replace H3 := H3p l0 rcases hr.3.1.resolve_left (hlp l0) with ⟨_, hb₂⟩ refine ⟨Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩⟩ · exact Valid'.rotateL_lemma₁ H2 hb₂ · exact Nat.le_of_lt_succ (Valid'.rotateL_lemma₂ H3 h) · exact Valid'.rotateL_lemma₃ H2 h · exact le_trans hb₂ (Nat.mul_le_mul_left _ <\| le_trans (Nat.le_add_left _ _) (Nat.le_add_right _ _)) · rcases Nat.eq_zero_or_pos (size rl) with rl0 \| rl0 · rw [rl0, not_lt, Nat.le_zero, Nat.mul_eq_zero] at h replace h := h.resolve_left (by decide) rw [rl0, h, Nat.le_zero, Nat.mul_eq_zero] at H2 rw [hr.2.size_eq, rl0, h, H2.resolve_left (by decide)] at H1 cases H1 (by decide) refine hl.node4L hr.left hr.right rl0 ?_ rcases Nat.eq_zero_or_pos (size l) with l0 \| l0 · replace H3 := H3_0 l0 rcases Nat.eq_zero_or_pos (size rr) with rr0 \| rr0 · have := hr.3.1 rw [rr0] at this exact Or.inl ⟨l0, le_antisymm (balancedSz_zero.1 this) rl0, rr0.symm ▸ zero_le_one⟩ exact Or.inl ⟨l0, le_antisymm (ablem rr0 <\| by rwa [add_comm]) rl0, ablem rl0 H3⟩ exact Or.inr ⟨l0, not_lt.1 h, H2, Valid'.rotateL_lemma₄ (H3p l0), (hr.3.1.resolve_left (hlp l0)).1⟩ theorem Valid'.rotateR {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H1 : ¬size l + size r ≤ 1) (H2 : delta * size r < size l) (H3 : 2 * size l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@rotateR α l x r) o₂ := by refine Valid'.dual_iff.2 ?_ rw [dual_rotateR] refine hr.dual.rotateL hl.dual ?_ ?_ ?_ · rwa [size_dual, size_dual, add_comm] · rwa [size_dual, size_dual] · rwa [size_dual, size_dual] theorem Valid'.balance'_aux {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H₁ : 2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3) (H₂ : 2 * @size α l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@balance' α l x r) o₂ := by rw [balance']; split_ifs with h h_1 h_2 · exact hl.node' hr (Or.inl h) · exact hl.rotateL hr h h_1 H₁ · exact hl.rotateR hr h h_2 H₂ · exact hl.node' hr (Or.inr ⟨not_lt.1 h_2, not_lt.1 h_1⟩) theorem Valid'.balance'_lemma {α l l' r r'} (H1 : BalancedSz l' r') (H2 : Nat.dist (@size α l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l') : 2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3 := by suffices @size α r ≤ 3 * (size l + 1) by omega rcases H2 with (⟨hl, rfl⟩ \| ⟨hr, rfl⟩) <;> rcases H1 with (h \| ⟨_, h₂⟩) · exact le_trans (Nat.le_add_left _ _) (le_trans h (Nat.le_add_left _ _)) · exact le_trans h₂ (Nat.mul_le_mul_left _ <\| le_trans (Nat.dist_tri_right _ _) (Nat.add_le_add_left hl _)) · exact le_trans (Nat.dist_tri_left' _ _) (le_trans (add_le_add hr (le_trans (Nat.le_add_left _ _) h)) (by omega)) · rw [Nat.mul_succ] exact le_trans (Nat.dist_tri_right' _ _) (add_le_add h₂ (le_trans hr (by decide))) theorem Valid'.balance' {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : ∃ l' r', BalancedSz l' r' ∧ (Nat.dist (size l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l')) : Valid' o₁ (@balance' α l x r) o₂ :=	let ⟨_, _, H1, H2⟩ := H Valid'.balance'_aux hl hr (Valid'.balance'_lemma H1 H2) (Valid'.balance'_lemma H1.symm H2.symm)	Mathlib/Data/Ordmap/Ordset.lean	331	333
/- Copyright (c) 2022 Markus Himmel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Markus Himmel -/ import Mathlib.CategoryTheory.Limits.Shapes.BinaryBiproducts import Mathlib.CategoryTheory.Limits.Preserves.Shapes.Zero /-! # Preservation of biproducts We define the image of a (binary) bicone under a functor that preserves zero morphisms and define classes `PreservesBiproduct` and `PreservesBinaryBiproduct`. We then * show that a functor that preserves biproducts of a two-element type preserves binary biproducts, * construct the comparison morphisms between the image of a biproduct and the biproduct of the images and show that the biproduct is preserved if one of them is an isomorphism, * give the canonical isomorphism between the image of a biproduct and the biproduct of the images in case that the biproduct is preserved. -/ universe w₁ w₂ v₁ v₂ u₁ u₂ noncomputable section open CategoryTheory open CategoryTheory.Limits namespace CategoryTheory variable {C : Type u₁} [Category.{v₁} C] {D : Type u₂} [Category.{v₂} D] section HasZeroMorphisms variable [HasZeroMorphisms C] [HasZeroMorphisms D] namespace Functor section Map variable (F : C ⥤ D) [PreservesZeroMorphisms F] section Bicone variable {J : Type w₁} /-- The image of a bicone under a functor. -/ @[simps] def mapBicone {f : J → C} (b : Bicone f) : Bicone (F.obj ∘ f) where pt := F.obj b.pt π j := F.map (b.π j) ι j := F.map (b.ι j) ι_π j j' := by rw [← F.map_comp] split_ifs with h · subst h simp only [bicone_ι_π_self, CategoryTheory.Functor.map_id, eqToHom_refl]; dsimp · rw [bicone_ι_π_ne _ h, F.map_zero] theorem mapBicone_whisker {K : Type w₂} {g : K ≃ J} {f : J → C} (c : Bicone f) : F.mapBicone (c.whisker g) = (F.mapBicone c).whisker g := rfl end Bicone /-- The image of a binary bicone under a functor. -/ @[simps!] def mapBinaryBicone {X Y : C} (b : BinaryBicone X Y) : BinaryBicone (F.obj X) (F.obj Y) := (BinaryBicones.functoriality _ _ F).obj b end Map end Functor open CategoryTheory.Functor namespace Limits section Bicone variable {J : Type w₁} {K : Type w₂} /-- A functor `F` preserves biproducts of `f` if `F` maps every bilimit bicone over `f` to a bilimit bicone over `F.obj ∘ f`. -/ class PreservesBiproduct (f : J → C) (F : C ⥤ D) [PreservesZeroMorphisms F] : Prop where preserves : ∀ {b : Bicone f}, b.IsBilimit → Nonempty (F.mapBicone b).IsBilimit attribute [inherit_doc PreservesBiproduct] PreservesBiproduct.preserves /-- A functor `F` preserves biproducts of `f` if `F` maps every bilimit bicone over `f` to a bilimit bicone over `F.obj ∘ f`. -/ def isBilimitOfPreserves {f : J → C} (F : C ⥤ D) [PreservesZeroMorphisms F] [PreservesBiproduct f F] {b : Bicone f} (hb : b.IsBilimit) : (F.mapBicone b).IsBilimit := (PreservesBiproduct.preserves hb).some variable (J) /-- A functor `F` preserves biproducts of shape `J` if it preserves biproducts of `f` for every `f : J → C`. -/ class PreservesBiproductsOfShape (F : C ⥤ D) [PreservesZeroMorphisms F] : Prop where preserves : ∀ {f : J → C}, PreservesBiproduct f F attribute [inherit_doc PreservesBiproductsOfShape] PreservesBiproductsOfShape.preserves attribute [instance 100] PreservesBiproductsOfShape.preserves end Bicone /-- A functor `F` preserves finite biproducts if it preserves biproducts of shape `J` whenever `J` is a finite type. -/ class PreservesFiniteBiproducts (F : C ⥤ D) [PreservesZeroMorphisms F] : Prop where preserves : ∀ {J : Type} [Finite J], PreservesBiproductsOfShape J F attribute [inherit_doc PreservesFiniteBiproducts] PreservesFiniteBiproducts.preserves attribute [instance 100] PreservesFiniteBiproducts.preserves /-- A functor `F` preserves biproducts if it preserves biproducts of any shape `J` of size `w`. The usual notion of preservation of biproducts is recovered by choosing `w` to be the universe of the morphisms of `C`. -/ class PreservesBiproducts (F : C ⥤ D) [PreservesZeroMorphisms F] : Prop where preserves : ∀ {J : Type w₁}, PreservesBiproductsOfShape J F attribute [inherit_doc PreservesBiproducts] PreservesBiproducts.preserves attribute [instance 100] PreservesBiproducts.preserves /-- Preserving biproducts at a bigger universe level implies preserving biproducts at a smaller universe level. -/ lemma preservesBiproducts_shrink (F : C ⥤ D) [PreservesZeroMorphisms F] [PreservesBiproducts.{max w₁ w₂} F] : PreservesBiproducts.{w₁} F := ⟨fun {_} => ⟨fun {_} => ⟨fun {b} ib => ⟨((F.mapBicone b).whiskerIsBilimitIff _).toFun (isBilimitOfPreserves F ((b.whiskerIsBilimitIff Equiv.ulift.{w₂}).invFun ib))⟩⟩⟩⟩ instance (priority := 100) preservesFiniteBiproductsOfPreservesBiproducts (F : C ⥤ D) [PreservesZeroMorphisms F] [PreservesBiproducts.{w₁} F] : PreservesFiniteBiproducts F where preserves {J} _ := by letI := preservesBiproducts_shrink.{0} F; infer_instance /-- A functor `F` preserves binary biproducts of `X` and `Y` if `F` maps every bilimit bicone over `X` and `Y` to a bilimit bicone over `F.obj X` and `F.obj Y`. -/ class PreservesBinaryBiproduct (X Y : C) (F : C ⥤ D) [PreservesZeroMorphisms F] : Prop where preserves : ∀ {b : BinaryBicone X Y}, b.IsBilimit → Nonempty ((F.mapBinaryBicone b).IsBilimit) attribute [inherit_doc PreservesBinaryBiproduct] PreservesBinaryBiproduct.preserves /-- A functor `F` preserves binary biproducts of `X` and `Y` if `F` maps every bilimit bicone over `X` and `Y` to a bilimit bicone over `F.obj X` and `F.obj Y`. -/ def isBinaryBilimitOfPreserves {X Y : C} (F : C ⥤ D) [PreservesZeroMorphisms F] [PreservesBinaryBiproduct X Y F] {b : BinaryBicone X Y} (hb : b.IsBilimit) : (F.mapBinaryBicone b).IsBilimit := (PreservesBinaryBiproduct.preserves hb).some /-- A functor `F` preserves binary biproducts if it preserves the binary biproduct of `X` and `Y` for all `X` and `Y`. -/ class PreservesBinaryBiproducts (F : C ⥤ D) [PreservesZeroMorphisms F] : Prop where preserves : ∀ {X Y : C}, PreservesBinaryBiproduct X Y F := by infer_instance attribute [inherit_doc PreservesBinaryBiproducts] PreservesBinaryBiproducts.preserves /-- A functor that preserves biproducts of a pair preserves binary biproducts. -/ lemma preservesBinaryBiproduct_of_preservesBiproduct (F : C ⥤ D) [PreservesZeroMorphisms F] (X Y : C) [PreservesBiproduct (pairFunction X Y) F] : PreservesBinaryBiproduct X Y F where preserves {b} hb := ⟨{ isLimit := IsLimit.ofIsoLimit ((IsLimit.postcomposeHomEquiv (diagramIsoPair _) _).symm (isBilimitOfPreserves F (b.toBiconeIsBilimit.symm hb)).isLimit) <\| Cones.ext (Iso.refl _) fun j => by rcases j with ⟨⟨⟩⟩ <;> simp isColimit := IsColimit.ofIsoColimit ((IsColimit.precomposeInvEquiv (diagramIsoPair _) _).symm (isBilimitOfPreserves F (b.toBiconeIsBilimit.symm hb)).isColimit) <\| Cocones.ext (Iso.refl _) fun j => by rcases j with ⟨⟨⟩⟩ <;> simp }⟩ /-- A functor that preserves biproducts of a pair preserves binary biproducts. -/ lemma preservesBinaryBiproducts_of_preservesBiproducts (F : C ⥤ D) [PreservesZeroMorphisms F] [PreservesBiproductsOfShape WalkingPair F] : PreservesBinaryBiproducts F where preserves {X} Y := preservesBinaryBiproduct_of_preservesBiproduct F X Y attribute [instance 100] PreservesBinaryBiproducts.preserves end Limits open CategoryTheory.Limits namespace Functor section Bicone variable {J : Type w₁} (F : C ⥤ D) (f : J → C) [HasBiproduct f] section variable [HasBiproduct (F.obj ∘ f)] /-- As for products, any functor between categories with biproducts gives rise to a morphism `F.obj (⨁ f) ⟶ ⨁ (F.obj ∘ f)`. -/ def biproductComparison : F.obj (⨁ f) ⟶ ⨁ F.obj ∘ f := biproduct.lift fun j => F.map (biproduct.π f j) @[reassoc (attr := simp)] theorem biproductComparison_π (j : J) : biproductComparison F f ≫ biproduct.π _ j = F.map (biproduct.π f j) := biproduct.lift_π _ _ /-- As for coproducts, any functor between categories with biproducts gives rise to a morphism `⨁ (F.obj ∘ f) ⟶ F.obj (⨁ f)` -/ def biproductComparison' : ⨁ F.obj ∘ f ⟶ F.obj (⨁ f) := biproduct.desc fun j => F.map (biproduct.ι f j) @[reassoc (attr := simp)] theorem ι_biproductComparison' (j : J) : biproduct.ι _ j ≫ biproductComparison' F f = F.map (biproduct.ι f j) := biproduct.ι_desc _ _ variable [PreservesZeroMorphisms F] /-- The composition in the opposite direction is equal to the identity if and only if `F` preserves the biproduct, see `preservesBiproduct_of_monoBiproductComparison`. -/ @[reassoc (attr := simp)] theorem biproductComparison'_comp_biproductComparison : biproductComparison' F f ≫ biproductComparison F f = 𝟙 (⨁ F.obj ∘ f) := by classical ext simp [biproduct.ι_π, ← Functor.map_comp, eqToHom_map] /-- `biproduct_comparison F f` is a split epimorphism. -/ @[simps] def splitEpiBiproductComparison : SplitEpi (biproductComparison F f) where section_ := biproductComparison' F f id := by simp instance : IsSplitEpi (biproductComparison F f) := IsSplitEpi.mk' (splitEpiBiproductComparison F f) /-- `biproduct_comparison' F f` is a split monomorphism. -/ @[simps] def splitMonoBiproductComparison' : SplitMono (biproductComparison' F f) where retraction := biproductComparison F f id := by simp instance : IsSplitMono (biproductComparison' F f) := IsSplitMono.mk' (splitMonoBiproductComparison' F f) end variable [PreservesZeroMorphisms F] [PreservesBiproduct f F] instance hasBiproduct_of_preserves : HasBiproduct (F.obj ∘ f) := HasBiproduct.mk { bicone := F.mapBicone (biproduct.bicone f) isBilimit := isBilimitOfPreserves _ (biproduct.isBilimit _) } /-- If `F` preserves a biproduct, we get a definitionally nice isomorphism `F.obj (⨁ f) ≅ ⨁ (F.obj ∘ f)`. -/ abbrev mapBiproduct : F.obj (⨁ f) ≅ ⨁ F.obj ∘ f := biproduct.uniqueUpToIso _ (isBilimitOfPreserves _ (biproduct.isBilimit _)) theorem mapBiproduct_hom : haveI : HasBiproduct fun j => F.obj (f j) := hasBiproduct_of_preserves F f (mapBiproduct F f).hom = biproduct.lift fun j => F.map (biproduct.π f j) := rfl theorem mapBiproduct_inv : haveI : HasBiproduct fun j => F.obj (f j) := hasBiproduct_of_preserves F f (mapBiproduct F f).inv = biproduct.desc fun j => F.map (biproduct.ι f j) := rfl end Bicone variable (F : C ⥤ D) (X Y : C) [HasBinaryBiproduct X Y] section variable [HasBinaryBiproduct (F.obj X) (F.obj Y)] /-- As for products, any functor between categories with binary biproducts gives rise to a morphism `F.obj (X ⊞ Y) ⟶ F.obj X ⊞ F.obj Y`. -/ def biprodComparison : F.obj (X ⊞ Y) ⟶ F.obj X ⊞ F.obj Y := biprod.lift (F.map biprod.fst) (F.map biprod.snd) @[reassoc (attr := simp)] theorem biprodComparison_fst : biprodComparison F X Y ≫ biprod.fst = F.map biprod.fst := biprod.lift_fst _ _ @[reassoc (attr := simp)] theorem biprodComparison_snd : biprodComparison F X Y ≫ biprod.snd = F.map biprod.snd := biprod.lift_snd _ _ /-- As for coproducts, any functor between categories with binary biproducts gives rise to a morphism `F.obj X ⊞ F.obj Y ⟶ F.obj (X ⊞ Y)`. -/ def biprodComparison' : F.obj X ⊞ F.obj Y ⟶ F.obj (X ⊞ Y) := biprod.desc (F.map biprod.inl) (F.map biprod.inr) @[reassoc (attr := simp)] theorem inl_biprodComparison' : biprod.inl ≫ biprodComparison' F X Y = F.map biprod.inl := biprod.inl_desc _ _ @[reassoc (attr := simp)] theorem inr_biprodComparison' : biprod.inr ≫ biprodComparison' F X Y = F.map biprod.inr := biprod.inr_desc _ _ variable [PreservesZeroMorphisms F] /-- The composition in the opposite direction is equal to the identity if and only if `F` preserves the biproduct, see `preservesBinaryBiproduct_of_monoBiprodComparison`. -/ @[reassoc (attr := simp)] theorem biprodComparison'_comp_biprodComparison : biprodComparison' F X Y ≫ biprodComparison F X Y = 𝟙 (F.obj X ⊞ F.obj Y) := by ext <;> simp [← Functor.map_comp] /-- `biprodComparison F X Y` is a split epi. -/ @[simps] def splitEpiBiprodComparison : SplitEpi (biprodComparison F X Y) where section_ := biprodComparison' F X Y id := by simp instance : IsSplitEpi (biprodComparison F X Y) := IsSplitEpi.mk' (splitEpiBiprodComparison F X Y) /-- `biprodComparison' F X Y` is a split mono. -/ @[simps] def splitMonoBiprodComparison' : SplitMono (biprodComparison' F X Y) where retraction := biprodComparison F X Y id := by simp instance : IsSplitMono (biprodComparison' F X Y) := IsSplitMono.mk' (splitMonoBiprodComparison' F X Y) end variable [PreservesZeroMorphisms F] [PreservesBinaryBiproduct X Y F] instance hasBinaryBiproduct_of_preserves : HasBinaryBiproduct (F.obj X) (F.obj Y) := HasBinaryBiproduct.mk { bicone := F.mapBinaryBicone (BinaryBiproduct.bicone X Y) isBilimit := isBinaryBilimitOfPreserves F (BinaryBiproduct.isBilimit _ _) } /-- If `F` preserves a binary biproduct, we get a definitionally nice isomorphism `F.obj (X ⊞ Y) ≅ F.obj X ⊞ F.obj Y`. -/ abbrev mapBiprod : F.obj (X ⊞ Y) ≅ F.obj X ⊞ F.obj Y := biprod.uniqueUpToIso _ _ (isBinaryBilimitOfPreserves F (BinaryBiproduct.isBilimit _ _)) theorem mapBiprod_hom : (mapBiprod F X Y).hom = biprod.lift (F.map biprod.fst) (F.map biprod.snd) := rfl theorem mapBiprod_inv : (mapBiprod F X Y).inv = biprod.desc (F.map biprod.inl) (F.map biprod.inr) := rfl end Functor namespace Limits variable (F : C ⥤ D) [PreservesZeroMorphisms F] section Bicone variable {J : Type w₁} (f : J → C) [HasBiproduct f] [PreservesBiproduct f F] {W : C} theorem biproduct.map_lift_mapBiprod (g : ∀ j, W ⟶ f j) : -- Porting note: we need haveI to tell Lean about hasBiproduct_of_preserves F f haveI : HasBiproduct fun j => F.obj (f j) := hasBiproduct_of_preserves F f F.map (biproduct.lift g) ≫ (F.mapBiproduct f).hom = biproduct.lift fun j => F.map (g j) := by ext j dsimp only [Function.comp_def] simp only [mapBiproduct_hom, Category.assoc, biproduct.lift_π, ← F.map_comp] theorem biproduct.mapBiproduct_inv_map_desc (g : ∀ j, f j ⟶ W) : -- Porting note: we need haveI to tell Lean about hasBiproduct_of_preserves F f haveI : HasBiproduct fun j => F.obj (f j) := hasBiproduct_of_preserves F f (F.mapBiproduct f).inv ≫ F.map (biproduct.desc g) = biproduct.desc fun j => F.map (g j) := by ext j dsimp only [Function.comp_def] simp only [mapBiproduct_inv, ← Category.assoc, biproduct.ι_desc ,← F.map_comp] theorem biproduct.mapBiproduct_hom_desc (g : ∀ j, f j ⟶ W) : ((F.mapBiproduct f).hom ≫ biproduct.desc fun j => F.map (g j)) = F.map (biproduct.desc g) := by rw [← biproduct.mapBiproduct_inv_map_desc, Iso.hom_inv_id_assoc] end Bicone section BinaryBicone variable (X Y : C) [HasBinaryBiproduct X Y] [PreservesBinaryBiproduct X Y F] {W : C} theorem biprod.map_lift_mapBiprod (f : W ⟶ X) (g : W ⟶ Y) : F.map (biprod.lift f g) ≫ (F.mapBiprod X Y).hom = biprod.lift (F.map f) (F.map g) := by ext <;> simp [mapBiprod, ← F.map_comp] theorem biprod.lift_mapBiprod (f : W ⟶ X) (g : W ⟶ Y) : biprod.lift (F.map f) (F.map g) ≫ (F.mapBiprod X Y).inv = F.map (biprod.lift f g) := by rw [← biprod.map_lift_mapBiprod, Category.assoc, Iso.hom_inv_id, Category.comp_id] theorem biprod.mapBiprod_inv_map_desc (f : X ⟶ W) (g : Y ⟶ W) : (F.mapBiprod X Y).inv ≫ F.map (biprod.desc f g) = biprod.desc (F.map f) (F.map g) := by ext <;> simp [mapBiprod, ← F.map_comp] theorem biprod.mapBiprod_hom_desc (f : X ⟶ W) (g : Y ⟶ W) : (F.mapBiprod X Y).hom ≫ biprod.desc (F.map f) (F.map g) = F.map (biprod.desc f g) := by rw [← biprod.mapBiprod_inv_map_desc, Iso.hom_inv_id_assoc] end BinaryBicone end Limits end HasZeroMorphisms end CategoryTheory		Mathlib/CategoryTheory/Limits/Preserves/Shapes/Biproducts.lean	450	452

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