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96b9cd1eee453661e3e12622ab38abe59b2477d6 | 618003631150032a5676f229d13a079ac875ff77 | /src/topology/category/Top/open_nhds.lean | f61f44bc70ec58c5f0448c6f1d48b73851cd5e13 | [
"Apache-2.0"
] | permissive | awainverse/mathlib | 939b68c8486df66cfda64d327ad3d9165248c777 | ea76bd8f3ca0a8bf0a166a06a475b10663dec44a | refs/heads/master | 1,659,592,962,036 | 1,590,987,592,000 | 1,590,987,592,000 | 268,436,019 | 1 | 0 | Apache-2.0 | 1,590,990,500,000 | 1,590,990,500,000 | null | UTF-8 | Lean | false | false | 1,767 | lean | /-
Copyright (c) 2019 Scott Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Scott Morrison
-/
import topology.category.Top.opens
open category_theory
open topological_space
open opposite
universe u
variables {X Y : Top.{u}} (f : X ⟶ Y)
namespace topological_space
def open_nhds (x : X.α) := { U : opens X // x ∈ U }
namespace open_nhds
instance open_nhds_category (x : X.α) : category.{u} (open_nhds x) := by {unfold open_nhds, apply_instance}
def inclusion (x : X.α) : open_nhds x ⥤ opens X :=
full_subcategory_inclusion _
@[simp] lemma inclusion_obj (x : X.α) (U) (p) : (inclusion x).obj ⟨U,p⟩ = U := rfl
def map (x : X) : open_nhds (f x) ⥤ open_nhds x :=
{ obj := λ U, ⟨(opens.map f).obj U.1, by tidy⟩,
map := λ U V i, (opens.map f).map i }
@[simp] lemma map_obj (x : X) (U) (q) : (map f x).obj ⟨U, q⟩ = ⟨(opens.map f).obj U, by tidy⟩ :=
rfl
@[simp] lemma map_id_obj (x : X) (U) : (map (𝟙 X) x).obj U = U :=
by tidy
@[simp] lemma map_id_obj' (x : X) (U) (p) (q) : (map (𝟙 X) x).obj ⟨⟨U, p⟩, q⟩ = ⟨⟨U, p⟩, q⟩ :=
rfl
@[simp] lemma map_id_obj_unop (x : X) (U : (open_nhds x)ᵒᵖ) : (map (𝟙 X) x).obj (unop U) = unop U :=
by simp
@[simp] lemma op_map_id_obj (x : X) (U : (open_nhds x)ᵒᵖ) : (map (𝟙 X) x).op.obj U = U :=
by simp
def inclusion_map_iso (x : X) : inclusion (f x) ⋙ opens.map f ≅ map f x ⋙ inclusion x :=
nat_iso.of_components
(λ U, begin split, exact 𝟙 _, exact 𝟙 _ end)
(by tidy)
@[simp] lemma inclusion_map_iso_hom (x : X) : (inclusion_map_iso f x).hom = 𝟙 _ := rfl
@[simp] lemma inclusion_map_iso_inv (x : X) : (inclusion_map_iso f x).inv = 𝟙 _ := rfl
end open_nhds
end topological_space
|
663e259ba0cca8366a1d485e2b60a79a36e4d78a | 80746c6dba6a866de5431094bf9f8f841b043d77 | /src/tactic/explode.lean | 3b6cdd6d495c9a677d37460ae89cc5a2a799fc83 | [
"Apache-2.0"
] | permissive | leanprover-fork/mathlib-backup | 8b5c95c535b148fca858f7e8db75a76252e32987 | 0eb9db6a1a8a605f0cf9e33873d0450f9f0ae9b0 | refs/heads/master | 1,585,156,056,139 | 1,548,864,430,000 | 1,548,864,438,000 | 143,964,213 | 0 | 0 | Apache-2.0 | 1,550,795,966,000 | 1,533,705,322,000 | Lean | UTF-8 | Lean | false | false | 5,168 | lean | /-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Mario Carneiro
Displays a proof term in a line by line format somewhat akin to a Fitch style
proof or the Metamath proof style.
-/
import tactic.basic meta.coinductive_predicates
open expr tactic
namespace tactic
namespace explode
-- TODO(Mario): move back to list.basic
@[simp] def head' {α} : list α → option α
| [] := none
| (a :: l) := some a
inductive status | reg | intro | lam | sintro
meta structure entry :=
(expr : expr)
(line : nat)
(depth : nat)
(status : status)
(thm : string)
(deps : list nat)
meta def pad_right (l : list string) : list string :=
let n := l.foldl (λ r (s:string), max r s.length) 0 in
l.map $ λ s, nat.iterate (λ s, s.push ' ') (n - s.length) s
meta structure entries := mk' ::
(s : expr_map entry)
(l : list entry)
meta def entries.find (es : entries) (e : expr) := es.s.find e
meta def entries.size (es : entries) := es.s.size
meta def entries.add : entries → entry → entries
| es@⟨s, l⟩ e := if s.contains e.expr then es else ⟨s.insert e.expr e, e :: l⟩
meta def entries.head (es : entries) : option entry := head' es.l
meta instance : inhabited entries := ⟨⟨expr_map.mk _, []⟩⟩
meta def format_aux : list string → list string → list string → list entry → tactic format
| (line :: lines) (dep :: deps) (thm :: thms) (en :: es) := do
fmt ← do {
let margin := string.join (list.repeat " │" en.depth),
let margin := match en.status with
| status.sintro := " ├" ++ margin
| status.intro := " │" ++ margin ++ " ┌"
| status.reg := " │" ++ margin ++ ""
| status.lam := " │" ++ margin ++ ""
end,
p ← infer_type en.expr >>= pp,
let lhs := line ++ "│" ++ dep ++ "│ " ++ thm ++ margin ++ " ",
return $ format.of_string lhs ++ to_string p ++ format.line },
(++ fmt) <$> format_aux lines deps thms es
| _ _ _ _ := return format.nil
meta instance : has_to_tactic_format entries :=
⟨λ es : entries,
let lines := pad_right $ es.l.map (λ en, to_string en.line),
deps := pad_right $ es.l.map (λ en, string.intercalate "," (en.deps.map to_string)),
thms := pad_right $ es.l.map entry.thm in
format_aux lines deps thms es.l⟩
meta def append_dep (filter : expr → tactic unit)
(es : entries) (e : expr) (deps : list nat) : tactic (list nat) :=
do { ei ← es.find e,
filter ei.expr,
return (ei.line :: deps) }
<|> return deps
meta def may_be_proof (e : expr) : tactic bool :=
is_proof e >>= λ b, return $
b || is_app e || is_local_constant e || is_pi e || is_lambda e
end explode
open explode
meta mutual def explode.core, explode.args (filter : expr → tactic unit)
with explode.core : expr → bool → nat → entries → tactic entries
| e@(lam n bi d b) si depth es := do
m ← mk_fresh_name,
let l := local_const m n bi d,
let b' := instantiate_var b l,
if si then
let en : entry := ⟨l, es.size, depth, status.sintro, to_string n, []⟩ in
explode.core b' si depth (es.add en)
else do
let en : entry := ⟨l, es.size, depth, status.intro, to_string n, []⟩,
es' ← explode.core b' si (depth + 1) (es.add en),
deps' ← explode.append_dep filter es' b' [],
deps' ← explode.append_dep filter es' l deps',
return $ es'.add ⟨e, es'.size, depth, status.lam, "∀I", deps'⟩
| e@(macro _ l) si depth es := explode.core l.head si depth es
| e si depth es := filter e >>
match get_app_fn_args e with
| (const n _, args) :=
explode.args e args depth es (to_string n) []
| (fn, []) := do
p ← pp fn,
let en : entry := ⟨fn, es.size, depth, status.reg, to_string p, []⟩,
return (es.add en)
| (fn, args) := do
es' ← explode.core fn ff depth es,
deps ← explode.append_dep filter es' fn [],
explode.args e args depth es' "∀E" deps
end
with explode.args : expr → list expr → nat → entries → string → list nat → tactic entries
| e (arg :: args) depth es thm deps := do
es' ← explode.core arg ff depth es <|> return es,
deps' ← explode.append_dep filter es' arg deps,
explode.args e args depth es' thm deps'
| e [] depth es thm deps :=
return (es.add ⟨e, es.size, depth, status.reg, thm, deps.reverse⟩)
meta def explode_expr (e : expr) (hide_non_prop := tt) : tactic entries :=
let filter := if hide_non_prop then λ e, may_be_proof e >>= guardb else λ _, skip in
tactic.explode.core filter e tt 0 (default _)
meta def explode (n : name) : tactic unit :=
do const n _ ← resolve_name n | fail "cannot resolve name",
d ← get_decl n,
v ← match d with
| (declaration.defn _ _ _ v _ _) := return v
| (declaration.thm _ _ _ v) := return v.get
| _ := fail "not a definition"
end,
t ← pp d.type,
explode_expr v <* trace (to_fmt n ++ " : " ++ t) >>= trace
open interactive lean lean.parser interaction_monad.result
@[user_command]
meta def explode_cmd (_ : parse $ tk "#explode") : parser unit :=
do n ← ident,
explode n
.
-- #explode iff_true_intro
-- #explode nat.strong_rec_on
end tactic
|
85c7ac076a6f0a67a7eb5f6412a70f71a0e9955e | 74addaa0e41490cbaf2abd313a764c96df57b05d | /Mathlib/testing/slim_check/gen.lean | f67325b6bce84e9bf53876b480d0b10a5594a155 | [] | no_license | AurelienSaue/Mathlib4_auto | f538cfd0980f65a6361eadea39e6fc639e9dae14 | 590df64109b08190abe22358fabc3eae000943f2 | refs/heads/master | 1,683,906,849,776 | 1,622,564,669,000 | 1,622,564,669,000 | 371,723,747 | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 5,037 | lean | /-
Copyright (c) 2020 Simon Hudon. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author(s): Simon Hudon
-/
import Mathlib.PrePort
import Mathlib.Lean3Lib.init.default
import Mathlib.control.uliftable
import Mathlib.Lean3Lib.system.random
import Mathlib.system.random.basic
import Mathlib.PostPort
universes u u_1 v
namespace Mathlib
/-!
# `gen` Monad
This monad is used to formulate randomized computations with a parameter
to specify the desired size of the result.
This is a port of the Haskell QuickCheck library.
## Main definitions
* `gen` monad
## Local notation
* `i .. j` : `Icc i j`, the set of values between `i` and `j` inclusively;
## Tags
random testing
## References
* https://hackage.haskell.org/package/QuickCheck
-/
namespace slim_check
/-- Monad to generate random examples to test properties with.
It has a `nat` parameter so that the caller can decide on the
size of the examples. -/
def gen (α : Type u) :=
reader_t (ulift ℕ) rand α
/-- Execute a `gen` inside the `io` monad using `i` as the example
size and with a fresh random number generator. -/
def io.run_gen {α : Type} (x : gen α) (i : ℕ) : io α :=
io.run_rand (reader_t.run x (ulift.up i))
namespace gen
/-- Lift `random.random` to the `gen` monad. -/
def choose_any (α : Type u) [random α] : gen α :=
reader_t.mk fun (_x : ulift ℕ) => rand.random α
/-- Lift `random.random_r` to the `gen` monad. -/
def choose {α : Type u} [preorder α] [bounded_random α] (x : α) (y : α) (p : x ≤ y) : gen ↥(set.Icc x y) :=
reader_t.mk fun (_x : ulift ℕ) => rand.random_r x y p
/-- Generate a `nat` example between `x` and `y`. -/
def choose_nat (x : ℕ) (y : ℕ) (p : x ≤ y) : gen ↥(set.Icc x y) :=
choose x y p
/-- Generate a `nat` example between `x` and `y`. -/
def choose_nat' (x : ℕ) (y : ℕ) (p : x < y) : gen ↥(set.Ico x y) :=
(fun (this : ∀ (i : ℕ), x < i → i ≤ y → Nat.pred i < y) => subtype.map Nat.pred sorry <$> choose (x + 1) y p) sorry
protected instance uliftable : uliftable gen gen :=
reader_t.uliftable' (equiv.trans equiv.ulift (equiv.symm equiv.ulift))
protected instance has_orelse : has_orelse gen :=
has_orelse.mk
fun (α : Type u) (x y : gen α) =>
do
let b ← uliftable.up (choose_any Bool)
ite (↥(ulift.down b)) x y
/-- Get access to the size parameter of the `gen` monad. For
reasons of universe polymorphism, it is specified in
continuation passing style. -/
def sized {α : Type u} (cmd : ℕ → gen α) : gen α :=
reader_t.mk fun (_x : ulift ℕ) => sorry
/-- Apply a function to the size parameter. -/
def resize {α : Type u} (f : ℕ → ℕ) (cmd : gen α) : gen α :=
reader_t.mk fun (_x : ulift ℕ) => sorry
/-- Create `n` examples using `cmd`. -/
def vector_of {α : Type u} (n : ℕ) (cmd : gen α) : gen (vector α n) :=
sorry
/-- Create a list of examples using `cmd`. The size is controlled
by the size parameter of `gen`. -/
def list_of {α : Type u} (cmd : gen α) : gen (List α) :=
sized
fun (sz : ℕ) =>
do
uliftable.up (choose_nat 0 (sz + 1) sorry)
sorry
/-- Given a list of example generators, choose one to create an example. -/
def one_of {α : Type u} (xs : List (gen α)) (pos : 0 < list.length xs) : gen α :=
do
uliftable.up (choose_nat' 0 (list.length xs) pos)
sorry
/-- Given a list of example generators, choose one to create an example. -/
def elements {α : Type u} (xs : List α) (pos : 0 < list.length xs) : gen α :=
do
uliftable.up (choose_nat' 0 (list.length xs) pos)
sorry
/--
`freq_aux xs i _` takes a weighted list of generator and a number meant to select one of the generators.
If we consider `freq_aux [(1, gena), (3, genb), (5, genc)] 4 _`, we choose a generator by splitting
the interval 1-9 into 1-1, 2-4, 5-9 so that the width of each interval corresponds to one of the
number in the list of generators. Then, we check which interval 4 falls into: it selects `genb`.
-/
def freq_aux {α : Type u} (xs : List (ℕ+ × gen α)) (i : ℕ) : i < list.sum (list.map (subtype.val ∘ prod.fst) xs) → gen α :=
sorry
/--
`freq [(1, gena), (3, genb), (5, genc)] _` will choose one of `gena`, `genb`, `genc` with
probabiities proportional to the number accompanying them. In this example, the sum of
those numbers is 9, `gena` will be chosen with probability ~1/9, `genb` with ~3/9 (i.e. 1/3)
and `genc` with probability 5/9.
-/
def freq {α : Type u} (xs : List (ℕ+ × gen α)) (pos : 0 < list.length xs) : gen α :=
let s : ℕ := list.sum (list.map (subtype.val ∘ prod.fst) xs);
(fun (ha : 1 ≤ s) =>
(fun (this : 0 ≤ s - 1) =>
uliftable.adapt_up gen gen (choose_nat 0 (s - 1) this)
fun (i : ↥(set.Icc 0 (s - 1))) => freq_aux xs (subtype.val i) sorry)
sorry)
sorry
/-- Generate a random permutation of a given list. -/
def permutation_of {α : Type u} (xs : List α) : gen (Subtype (list.perm xs)) :=
sorry
|
5fbae34e5dd6f010dabbe0d1738d57d30780ec3e | e967488e2008f07b0aa7b6b18d4398d02c7460e2 | /src/for_mathlib/ereal.lean | f9cc5a255df46ed9d64c5ae9eff8f8f8b3ca3b23 | [] | no_license | thyrgle/real-number-game | 5c53eefaa815051f3d70ca5782e41d2adb76fd6e | a420eecef62209b729c910c2170d1dd27b74bc9f | refs/heads/master | 1,606,405,407,612 | 1,574,956,743,000 | 1,574,956,743,000 | 229,126,103 | 0 | 0 | null | 1,576,784,273,000 | 1,576,784,272,000 | null | UTF-8 | Lean | false | false | 5,698 | lean | /-
Copyright (c) 2019 Kevin Buzzard. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kevin Buzzard
-/
import data.real.basic
/-!
# The extended reals [-∞, ∞].
This file defines `ereal`, the real numbers together with a top and bottom element,
referred to as ⊤ and ⊥.
Addition and multiplication are problematic in the presence of ±∞, but
negation is not, so we define negation. The main work is defining
Sup : set ereal → ereal and proving that it is a Sup in all cases.
Once we have, this, it is not hard to give a complete lattice
structure on `ereal`.
## Tags
real, ereal, complete lattice
-/
/-- ereal : The type $$[-\infty,+\infty]$$ or `[-∞, ∞]` -/
def ereal := with_bot (with_top ℝ)
instance : linear_order ereal := by unfold ereal; apply_instance
instance : lattice.order_bot ereal := by unfold ereal; apply_instance
instance : lattice.order_top ereal := by unfold ereal; apply_instance
/- neg -/
/-- negation on ereal -/
def ereal.neg : ereal → ereal
| none := ⊤
| (some none) := ⊥
| (some (some x)) := ((↑-x : with_top ℝ) : with_bot (with_top ℝ))
instance : has_neg ereal := ⟨ereal.neg⟩
/-- if -a ≤ b then -b ≤ a on ereal -/
theorem ereal.neg_le_of_neg_le : ∀ {a b : ereal} (h : -a ≤ b), -b ≤ a
| none none h := by cases (lattice.le_bot_iff.1 h)
| none (some b) h := by cases (lattice.top_le_iff.1 h); exact le_refl _
| (some none) b h := lattice.le_top
| (some (some a)) none h := by cases (lattice.le_bot_iff.1 h)
| (some (some a)) (some none) h := lattice.bot_le
| (some (some a)) (some (some b)) h :=
begin
revert h,
change (((-a : ℝ) : with_top ℝ) : with_bot (with_top ℝ)) ≤ _ →
(((-b : ℝ) : with_top ℝ) : with_bot (with_top ℝ)) ≤ _,
unfold_coes, simpa using neg_le_of_neg_le,
end
/-- -a ≤ b ↔ -b ≤ a on ereal-/
theorem ereal.neg_le {a b : ereal} : -a ≤ b ↔ -b ≤ a := ⟨ereal.neg_le_of_neg_le, ereal.neg_le_of_neg_le⟩
/-- - -a = a on ereal -/
theorem ereal.neg_neg : ∀ (a : ereal), - (- a) = a
| none := rfl
| (some none) := rfl
| (some (some a)) := show (((- -a : ℝ) : with_top ℝ) : with_bot (with_top ℝ)) = (((a : ℝ) : with_top ℝ) : with_bot (with_top ℝ)),
by simp [neg_neg a]
/-- a ≤ -b → b ≤ -a on ereal -/
theorem ereal.le_neg_of_le_neg {a b : ereal} (h : a ≤ -b) : b ≤ -a :=
by rwa [←ereal.neg_neg b, ereal.neg_le, ereal.neg_neg]
/-- The claim that a set of ereals has a supremum in ereal -/
def has_Sup (X : set ereal) : Prop := ∃ l : ereal, is_lub X l
local attribute [instance, priority 10] classical.prop_decidable
/-- A set of ereals has a Sup in ereal -/
theorem Sup_exists (X : set ereal) : has_Sup X :=
let Xoc : set (with_top ℝ) := λ x, X (↑x : with_bot _) in
dite (Xoc = ∅) (λ h, ⟨⊥, ⟨
by
{ rintro (⟨⟩|x) hx, exact le_refl none,
exfalso,
apply set.not_mem_empty x,
rw ←h,
exact hx,
},
λ u hu, lattice.bot_le⟩
⟩) (λ h, dite (⊤ ∈ Xoc) (λ h2, ⟨⊤, ⟨λ _ _, lattice.le_top, λ x hx, hx _ h2⟩⟩) $
λ htop,
let Xoo : set ℝ := λ (x : ℝ), Xoc (↑ x) in
begin
by_cases h2 : nonempty (upper_bounds Xoo),
{ rcases h2 with ⟨b, hb⟩,
use (↑(↑(real.Sup Xoo : real) : with_top ℝ) : with_bot (with_top ℝ)),
split,
{ rintros (⟨⟩|⟨⟩|x) hx,
exact lattice.bot_le,
exact false.elim (htop hx),
change (↑(↑x : with_top ℝ) : with_bot (with_top ℝ)) ≤ _,
simp [real.le_Sup _ ⟨b, hb⟩ hx],
},
{ intros c hc,
cases c with c,
cases (set.exists_mem_of_ne_empty h) with x hx,
cases (lattice.le_bot_iff.1 (hc (↑x : with_bot _) hx)),
cases c with c, {unfold_coes, simp},
suffices : real.Sup Xoo ≤ c,
unfold_coes, simp [this],
refine (real.Sup_le Xoo _ ⟨b, hb⟩).2 _,
rcases (set.exists_mem_of_ne_empty h) with ⟨⟨⟩ | ⟨x⟩, hx⟩,
contradiction,
exact ⟨x, hx⟩,
intros x hx,
replace hc := hc (↑(↑x : with_top ℝ) : with_bot (with_top ℝ)) hx,
unfold_coes at hc,
simpa using hc,
}
},
{ use ⊤,
split, intros x hx, exact lattice.le_top,
intros b hb,
rw lattice.top_le_iff,
cases b with b,
exfalso,
apply h,
ext x,
split, swap, rintro ⟨⟩,
intro hx,
cases (lattice.le_bot_iff.1 (hb (↑x : with_bot _) hx)),
cases b with b, refl,
exfalso,
apply h2,
use b,
intros x hx,
replace hb := hb (↑(↑x : with_top ℝ) : with_bot (with_top ℝ)) hx,
unfold_coes at hb,
simpa using hb,
}
end)
noncomputable def ereal.Sup := λ X, classical.some (Sup_exists X)
noncomputable instance : lattice.has_Sup ereal := ⟨ereal.Sup⟩
/-- `ereal` is a complete lattice -/
noncomputable instance : lattice.complete_lattice (ereal) :=
{ top := ⊤,
le_top := λ _, lattice.le_top,
bot := ⊥,
bot_le := @lattice.bot_le _ _,
Sup := ereal.Sup,
Inf := λ X, -classical.some (Sup_exists ({mx | ∃ x ∈ X, mx = -x})),
le_Sup := λ X x hx, (classical.some_spec (Sup_exists X)).1 _ hx,
Sup_le := λ X b hb, (classical.some_spec (Sup_exists X)).2 _ hb,
Inf_le := λ X x hx, ereal.neg_le_of_neg_le $ (classical.some_spec (Sup_exists ({mx | ∃ x ∈ X, mx = -x}))).1 _ ⟨x, hx, rfl⟩,
le_Inf := λ X b hb, ereal.le_neg_of_le_neg $ (classical.some_spec (Sup_exists ({mx | ∃ x ∈ X, mx = -x}))).2 _
(λ mx ⟨x, hx, hmx⟩, ereal.le_neg_of_le_neg $ hb _ $ by rwa [hmx, ereal.neg_neg]),
..with_bot.lattice }
|
b4e58763e070f8f68cd2c723bfc9c6794885cb68 | 8cae430f0a71442d02dbb1cbb14073b31048e4b0 | /src/data/list/zip.lean | 1528725e6a2b338acbc6b114eb8cfe7fcaa93704 | [
"Apache-2.0"
] | permissive | leanprover-community/mathlib | 56a2cadd17ac88caf4ece0a775932fa26327ba0e | 442a83d738cb208d3600056c489be16900ba701d | refs/heads/master | 1,693,584,102,358 | 1,693,471,902,000 | 1,693,471,902,000 | 97,922,418 | 1,595 | 352 | Apache-2.0 | 1,694,693,445,000 | 1,500,624,130,000 | Lean | UTF-8 | Lean | false | false | 18,268 | lean | /-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Kenny Lau
-/
import data.list.big_operators.basic
import algebra.order.monoid.min_max
/-!
# zip & unzip
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
This file provides results about `list.zip_with`, `list.zip` and `list.unzip` (definitions are in
core Lean).
`zip_with f l₁ l₂` applies `f : α → β → γ` pointwise to a list `l₁ : list α` and `l₂ : list β`. It
applies, until one of the lists is exhausted. For example,
`zip_with f [0, 1, 2] [6.28, 31] = [f 0 6.28, f 1 31]`.
`zip` is `zip_with` applied to `prod.mk`. For example,
`zip [a₁, a₂] [b₁, b₂, b₃] = [(a₁, b₁), (a₂, b₂)]`.
`unzip` undoes `zip`. For example, `unzip [(a₁, b₁), (a₂, b₂)] = ([a₁, a₂], [b₁, b₂])`.
-/
universe u
open nat
namespace list
variables {α : Type u} {β γ δ ε : Type*}
@[simp] theorem zip_with_cons_cons (f : α → β → γ) (a : α) (b : β) (l₁ : list α) (l₂ : list β) :
zip_with f (a :: l₁) (b :: l₂) = f a b :: zip_with f l₁ l₂ := rfl
@[simp] theorem zip_cons_cons (a : α) (b : β) (l₁ : list α) (l₂ : list β) :
zip (a :: l₁) (b :: l₂) = (a, b) :: zip l₁ l₂ := rfl
@[simp] theorem zip_with_nil_left (f : α → β → γ) (l) : zip_with f [] l = [] := rfl
@[simp] theorem zip_with_nil_right (f : α → β → γ) (l) : zip_with f l [] = [] :=
by cases l; refl
@[simp] lemma zip_with_eq_nil_iff {f : α → β → γ} {l l'} :
zip_with f l l' = [] ↔ l = [] ∨ l' = [] :=
by { cases l; cases l'; simp }
@[simp] theorem zip_nil_left (l : list α) : zip ([] : list β) l = [] := rfl
@[simp] theorem zip_nil_right (l : list α) : zip l ([] : list β) = [] :=
zip_with_nil_right _ l
@[simp] theorem zip_swap : ∀ (l₁ : list α) (l₂ : list β),
(zip l₁ l₂).map prod.swap = zip l₂ l₁
| [] l₂ := (zip_nil_right _).symm
| l₁ [] := by rw zip_nil_right; refl
| (a::l₁) (b::l₂) := by simp only [zip_cons_cons, map_cons, zip_swap l₁ l₂, prod.swap_prod_mk];
split; refl
@[simp] theorem length_zip_with (f : α → β → γ) : ∀ (l₁ : list α) (l₂ : list β),
length (zip_with f l₁ l₂) = min (length l₁) (length l₂)
| [] l₂ := rfl
| l₁ [] := by simp only [length, min_zero, zip_with_nil_right]
| (a::l₁) (b::l₂) := by simp [length, zip_cons_cons, length_zip_with l₁ l₂, min_add_add_right]
@[simp] theorem length_zip : ∀ (l₁ : list α) (l₂ : list β),
length (zip l₁ l₂) = min (length l₁) (length l₂) :=
length_zip_with _
theorem all₂_zip_with {f : α → β → γ} {p : γ → Prop} :
∀ {l₁ : list α} {l₂ : list β} (h : length l₁ = length l₂),
all₂ p (zip_with f l₁ l₂) ↔ forall₂ (λ x y, p (f x y)) l₁ l₂
| [] [] _ := by simp
| (a :: l₁) (b :: l₂) h :=
by { simp only [length_cons, add_left_inj] at h, simp [all₂_zip_with h] }
lemma lt_length_left_of_zip_with {f : α → β → γ} {i : ℕ} {l : list α} {l' : list β}
(h : i < (zip_with f l l').length) :
i < l.length :=
by { rw [length_zip_with, lt_min_iff] at h, exact h.left }
lemma lt_length_right_of_zip_with {f : α → β → γ} {i : ℕ} {l : list α} {l' : list β}
(h : i < (zip_with f l l').length) :
i < l'.length :=
by { rw [length_zip_with, lt_min_iff] at h, exact h.right }
lemma lt_length_left_of_zip {i : ℕ} {l : list α} {l' : list β} (h : i < (zip l l').length) :
i < l.length :=
lt_length_left_of_zip_with h
lemma lt_length_right_of_zip {i : ℕ} {l : list α} {l' : list β} (h : i < (zip l l').length) :
i < l'.length :=
lt_length_right_of_zip_with h
theorem zip_append : ∀ {l₁ r₁ : list α} {l₂ r₂ : list β} (h : length l₁ = length l₂),
zip (l₁ ++ r₁) (l₂ ++ r₂) = zip l₁ l₂ ++ zip r₁ r₂
| [] r₁ l₂ r₂ h := by simp only [eq_nil_of_length_eq_zero h.symm]; refl
| l₁ r₁ [] r₂ h := by simp only [eq_nil_of_length_eq_zero h]; refl
| (a::l₁) r₁ (b::l₂) r₂ h := by simp only [cons_append, zip_cons_cons, zip_append (succ.inj h)];
split; refl
theorem zip_map (f : α → γ) (g : β → δ) : ∀ (l₁ : list α) (l₂ : list β),
zip (l₁.map f) (l₂.map g) = (zip l₁ l₂).map (prod.map f g)
| [] l₂ := rfl
| l₁ [] := by simp only [map, zip_nil_right]
| (a::l₁) (b::l₂) := by simp only [map, zip_cons_cons, zip_map l₁ l₂, prod.map]; split; refl
theorem zip_map_left (f : α → γ) (l₁ : list α) (l₂ : list β) :
zip (l₁.map f) l₂ = (zip l₁ l₂).map (prod.map f id) :=
by rw [← zip_map, map_id]
theorem zip_map_right (f : β → γ) (l₁ : list α) (l₂ : list β) :
zip l₁ (l₂.map f) = (zip l₁ l₂).map (prod.map id f) :=
by rw [← zip_map, map_id]
@[simp] lemma zip_with_map {μ}
(f : γ → δ → μ) (g : α → γ) (h : β → δ) (as : list α) (bs : list β) :
zip_with f (as.map g) (bs.map h) =
zip_with (λ a b, f (g a) (h b)) as bs :=
begin
induction as generalizing bs,
{ simp },
{ cases bs; simp * }
end
lemma zip_with_map_left
(f : α → β → γ) (g : δ → α) (l : list δ) (l' : list β) :
zip_with f (l.map g) l' = zip_with (f ∘ g) l l' :=
by { convert (zip_with_map f g id l l'), exact eq.symm (list.map_id _) }
lemma zip_with_map_right
(f : α → β → γ) (l : list α) (g : δ → β) (l' : list δ) :
zip_with f l (l'.map g) = zip_with (λ x, f x ∘ g) l l' :=
by { convert (list.zip_with_map f id g l l'), exact eq.symm (list.map_id _) }
theorem zip_map' (f : α → β) (g : α → γ) : ∀ (l : list α),
zip (l.map f) (l.map g) = l.map (λ a, (f a, g a))
| [] := rfl
| (a::l) := by simp only [map, zip_cons_cons, zip_map' l]; split; refl
lemma map_zip_with {δ : Type*} (f : α → β) (g : γ → δ → α) (l : list γ) (l' : list δ) :
map f (zip_with g l l') = zip_with (λ x y, f (g x y)) l l' :=
begin
induction l with hd tl hl generalizing l',
{ simp },
{ cases l',
{ simp },
{ simp [hl] } }
end
theorem mem_zip {a b} : ∀ {l₁ : list α} {l₂ : list β},
(a, b) ∈ zip l₁ l₂ → a ∈ l₁ ∧ b ∈ l₂
| (_::l₁) (_::l₂) (or.inl rfl) := ⟨or.inl rfl, or.inl rfl⟩
| (a'::l₁) (b'::l₂) (or.inr h) := by split; simp only [mem_cons_iff, or_true, mem_zip h]
theorem map_fst_zip : ∀ (l₁ : list α) (l₂ : list β),
l₁.length ≤ l₂.length →
map prod.fst (zip l₁ l₂) = l₁
| [] bs _ := rfl
| (a :: as) (b :: bs) h := by { simp at h, simp! * }
| (a :: as) [] h := by { simp at h, contradiction }
theorem map_snd_zip : ∀ (l₁ : list α) (l₂ : list β),
l₂.length ≤ l₁.length →
map prod.snd (zip l₁ l₂) = l₂
| _ [] _ := by { rw zip_nil_right, refl }
| [] (b :: bs) h := by { simp at h, contradiction }
| (a :: as) (b :: bs) h := by { simp at h, simp! * }
@[simp] theorem unzip_nil : unzip (@nil (α × β)) = ([], []) := rfl
@[simp] theorem unzip_cons (a : α) (b : β) (l : list (α × β)) :
unzip ((a, b) :: l) = (a :: (unzip l).1, b :: (unzip l).2) :=
by rw unzip; cases unzip l; refl
theorem unzip_eq_map : ∀ (l : list (α × β)), unzip l = (l.map prod.fst, l.map prod.snd)
| [] := rfl
| ((a, b) :: l) := by simp only [unzip_cons, map_cons, unzip_eq_map l]
theorem unzip_left (l : list (α × β)) : (unzip l).1 = l.map prod.fst :=
by simp only [unzip_eq_map]
theorem unzip_right (l : list (α × β)) : (unzip l).2 = l.map prod.snd :=
by simp only [unzip_eq_map]
theorem unzip_swap (l : list (α × β)) : unzip (l.map prod.swap) = (unzip l).swap :=
by simp only [unzip_eq_map, map_map]; split; refl
theorem zip_unzip : ∀ (l : list (α × β)), zip (unzip l).1 (unzip l).2 = l
| [] := rfl
| ((a, b) :: l) := by simp only [unzip_cons, zip_cons_cons, zip_unzip l]; split; refl
theorem unzip_zip_left : ∀ {l₁ : list α} {l₂ : list β}, length l₁ ≤ length l₂ →
(unzip (zip l₁ l₂)).1 = l₁
| [] l₂ h := rfl
| l₁ [] h := by rw eq_nil_of_length_eq_zero (nat.eq_zero_of_le_zero h); refl
| (a::l₁) (b::l₂) h := by simp only [zip_cons_cons, unzip_cons,
unzip_zip_left (le_of_succ_le_succ h)]; split; refl
theorem unzip_zip_right {l₁ : list α} {l₂ : list β} (h : length l₂ ≤ length l₁) :
(unzip (zip l₁ l₂)).2 = l₂ :=
by rw [← zip_swap, unzip_swap]; exact unzip_zip_left h
theorem unzip_zip {l₁ : list α} {l₂ : list β} (h : length l₁ = length l₂) :
unzip (zip l₁ l₂) = (l₁, l₂) :=
by rw [← @prod.mk.eta _ _ (unzip (zip l₁ l₂)),
unzip_zip_left (le_of_eq h), unzip_zip_right (ge_of_eq h)]
lemma zip_of_prod {l : list α} {l' : list β} {lp : list (α × β)}
(hl : lp.map prod.fst = l) (hr : lp.map prod.snd = l') :
lp = l.zip l' :=
by rw [←hl, ←hr, ←zip_unzip lp, ←unzip_left, ←unzip_right, zip_unzip, zip_unzip]
lemma map_prod_left_eq_zip {l : list α} (f : α → β) : l.map (λ x, (x, f x)) = l.zip (l.map f) :=
by { rw ←zip_map', congr, exact map_id _ }
lemma map_prod_right_eq_zip {l : list α} (f : α → β) : l.map (λ x, (f x, x)) = (l.map f).zip l :=
by { rw ←zip_map', congr, exact map_id _ }
lemma zip_with_comm (f : α → β → γ) : ∀ (la : list α) (lb : list β),
zip_with f la lb = zip_with (λ b a, f a b) lb la
| [] _ := (list.zip_with_nil_right _ _).symm
| (a :: as) [] := rfl
| (a :: as) (b :: bs) := congr_arg _ (zip_with_comm as bs)
@[congr]
lemma zip_with_congr (f g : α → β → γ) (la : list α) (lb : list β)
(h : list.forall₂ (λ a b, f a b = g a b) la lb) :
zip_with f la lb = zip_with g la lb :=
begin
induction h with a b as bs hfg habs ih,
{ refl },
{ exact congr_arg2 _ hfg ih }
end
lemma zip_with_comm_of_comm (f : α → α → β) (comm : ∀ (x y : α), f x y = f y x) (l l' : list α) :
zip_with f l l' = zip_with f l' l :=
by { rw zip_with_comm, simp only [comm] }
@[simp]
lemma zip_with_same (f : α → α → δ) : ∀ (l : list α), zip_with f l l = l.map (λ a, f a a)
| [] := rfl
| (x :: xs) := congr_arg _ (zip_with_same xs)
lemma zip_with_zip_with_left (f : δ → γ → ε) (g : α → β → δ) :
∀ (la : list α) (lb : list β) (lc : list γ),
zip_with f (zip_with g la lb) lc = zip_with3 (λ a b c, f (g a b) c) la lb lc
| [] _ _ := rfl
| (a :: as) [] _ := rfl
| (a :: as) (b :: bs) [] := rfl
| (a :: as) (b :: bs) (c :: cs) := congr_arg (cons _) $ zip_with_zip_with_left as bs cs
lemma zip_with_zip_with_right (f : α → δ → ε) (g : β → γ → δ) :
∀ (la : list α) (lb : list β) (lc : list γ),
zip_with f la (zip_with g lb lc) = zip_with3 (λ a b c, f a (g b c)) la lb lc
| [] _ _ := rfl
| (a :: as) [] _ := rfl
| (a :: as) (b :: bs) [] := rfl
| (a :: as) (b :: bs) (c :: cs) := congr_arg (cons _) $ zip_with_zip_with_right as bs cs
@[simp]
lemma zip_with3_same_left (f : α → α → β → γ) : ∀ (la : list α) (lb : list β),
zip_with3 f la la lb = zip_with (λ a b, f a a b) la lb
| [] _ := rfl
| (a :: as) [] := rfl
| (a :: as) (b :: bs) := congr_arg (cons _) $ zip_with3_same_left as bs
@[simp]
lemma zip_with3_same_mid (f : α → β → α → γ) : ∀ (la : list α) (lb : list β),
zip_with3 f la lb la = zip_with (λ a b, f a b a) la lb
| [] _ := rfl
| (a :: as) [] := rfl
| (a :: as) (b :: bs) := congr_arg (cons _) $ zip_with3_same_mid as bs
@[simp]
lemma zip_with3_same_right (f : α → β → β → γ) : ∀ (la : list α) (lb : list β),
zip_with3 f la lb lb = zip_with (λ a b, f a b b) la lb
| [] _ := rfl
| (a :: as) [] := rfl
| (a :: as) (b :: bs) := congr_arg (cons _) $ zip_with3_same_right as bs
instance (f : α → α → β) [is_symm_op α β f] : is_symm_op (list α) (list β) (zip_with f) :=
⟨zip_with_comm_of_comm f is_symm_op.symm_op⟩
@[simp] theorem length_revzip (l : list α) : length (revzip l) = length l :=
by simp only [revzip, length_zip, length_reverse, min_self]
@[simp] theorem unzip_revzip (l : list α) : (revzip l).unzip = (l, l.reverse) :=
unzip_zip (length_reverse l).symm
@[simp] theorem revzip_map_fst (l : list α) : (revzip l).map prod.fst = l :=
by rw [← unzip_left, unzip_revzip]
@[simp] theorem revzip_map_snd (l : list α) : (revzip l).map prod.snd = l.reverse :=
by rw [← unzip_right, unzip_revzip]
theorem reverse_revzip (l : list α) : reverse l.revzip = revzip l.reverse :=
by rw [← zip_unzip.{u u} (revzip l).reverse, unzip_eq_map]; simp; simp [revzip]
theorem revzip_swap (l : list α) : (revzip l).map prod.swap = revzip l.reverse :=
by simp [revzip]
lemma nth_zip_with (f : α → β → γ) (l₁ : list α) (l₂ : list β) (i : ℕ) :
(zip_with f l₁ l₂).nth i = ((l₁.nth i).map f).bind (λ g, (l₂.nth i).map g) :=
begin
induction l₁ generalizing l₂ i,
{ simp [zip_with, (<*>)] },
{ cases l₂; simp only [zip_with, has_seq.seq, functor.map, nth, option.map_none'],
{ cases ((l₁_hd :: l₁_tl).nth i); refl },
{ cases i; simp only [option.map_some', nth, option.some_bind', *] } }
end
lemma nth_zip_with_eq_some {α β γ} (f : α → β → γ) (l₁ : list α) (l₂ : list β) (z : γ) (i : ℕ) :
(zip_with f l₁ l₂).nth i = some z ↔ ∃ x y, l₁.nth i = some x ∧ l₂.nth i = some y ∧ f x y = z :=
begin
induction l₁ generalizing l₂ i,
{ simp [zip_with] },
{ cases l₂; simp only [zip_with, nth, exists_false, and_false, false_and],
cases i; simp *, },
end
lemma nth_zip_eq_some (l₁ : list α) (l₂ : list β) (z : α × β) (i : ℕ) :
(zip l₁ l₂).nth i = some z ↔ l₁.nth i = some z.1 ∧ l₂.nth i = some z.2 :=
begin
cases z,
rw [zip, nth_zip_with_eq_some], split,
{ rintro ⟨x, y, h₀, h₁, h₂⟩, cc },
{ rintro ⟨h₀, h₁⟩, exact ⟨_,_,h₀,h₁,rfl⟩ }
end
@[simp] lemma nth_le_zip_with {f : α → β → γ} {l : list α} {l' : list β} {i : ℕ}
{h : i < (zip_with f l l').length} :
(zip_with f l l').nth_le i h =
f (l.nth_le i (lt_length_left_of_zip_with h)) (l'.nth_le i (lt_length_right_of_zip_with h)) :=
begin
rw [←option.some_inj, ←nth_le_nth, nth_zip_with_eq_some],
refine ⟨l.nth_le i (lt_length_left_of_zip_with h), l'.nth_le i (lt_length_right_of_zip_with h),
nth_le_nth _, _⟩,
simp only [←nth_le_nth, eq_self_iff_true, and_self]
end
@[simp] lemma nth_le_zip {l : list α} {l' : list β} {i : ℕ} {h : i < (zip l l').length} :
(zip l l').nth_le i h =
(l.nth_le i (lt_length_left_of_zip h), l'.nth_le i (lt_length_right_of_zip h)) :=
nth_le_zip_with
lemma mem_zip_inits_tails {l : list α} {init tail : list α} :
(init, tail) ∈ zip l.inits l.tails ↔ init ++ tail = l :=
begin
induction l generalizing init tail;
simp_rw [tails, inits, zip_cons_cons],
{ simp },
{ split; rw [mem_cons_iff, zip_map_left, mem_map, prod.exists],
{ rintros (⟨rfl, rfl⟩ | ⟨_, _, h, rfl, rfl⟩),
{ simp },
{ simp [l_ih.mp h], }, },
{ cases init,
{ simp },
{ intro h,
right,
use [init_tl, tail],
simp * at *, }, }, },
end
lemma map_uncurry_zip_eq_zip_with
(f : α → β → γ) (l : list α) (l' : list β) :
map (function.uncurry f) (l.zip l') = zip_with f l l' :=
begin
induction l with hd tl hl generalizing l',
{ simp },
{ cases l' with hd' tl',
{ simp },
{ simp [hl] } }
end
@[simp] lemma sum_zip_with_distrib_left {γ : Type*} [semiring γ]
(f : α → β → γ) (n : γ) (l : list α) (l' : list β) :
(l.zip_with (λ x y, n * f x y) l').sum = n * (l.zip_with f l').sum :=
begin
induction l with hd tl hl generalizing f n l',
{ simp },
{ cases l' with hd' tl',
{ simp, },
{ simp [hl, mul_add] } }
end
section distrib
/-! ### Operations that can be applied before or after a `zip_with` -/
variables (f : α → β → γ) (l : list α) (l' : list β) (n : ℕ)
lemma zip_with_distrib_take :
(zip_with f l l').take n = zip_with f (l.take n) (l'.take n) :=
begin
induction l with hd tl hl generalizing l' n,
{ simp },
{ cases l',
{ simp },
{ cases n,
{ simp },
{ simp [hl] } } }
end
lemma zip_with_distrib_drop :
(zip_with f l l').drop n = zip_with f (l.drop n) (l'.drop n) :=
begin
induction l with hd tl hl generalizing l' n,
{ simp },
{ cases l',
{ simp },
{ cases n,
{ simp },
{ simp [hl] } } }
end
lemma zip_with_distrib_tail :
(zip_with f l l').tail = zip_with f l.tail l'.tail :=
by simp_rw [←drop_one, zip_with_distrib_drop]
lemma zip_with_append (f : α → β → γ) (l la : list α) (l' lb : list β) (h : l.length = l'.length) :
zip_with f (l ++ la) (l' ++ lb) = zip_with f l l' ++ zip_with f la lb :=
begin
induction l with hd tl hl generalizing l',
{ have : l' = [] := eq_nil_of_length_eq_zero (by simpa using h.symm),
simp [this], },
{ cases l',
{ simpa using h },
{ simp only [add_left_inj, length] at h,
simp [hl _ h] } }
end
lemma zip_with_distrib_reverse (h : l.length = l'.length) :
(zip_with f l l').reverse = zip_with f l.reverse l'.reverse :=
begin
induction l with hd tl hl generalizing l',
{ simp },
{ cases l' with hd' tl',
{ simp },
{ simp only [add_left_inj, length] at h,
have : tl.reverse.length = tl'.reverse.length := by simp [h],
simp [hl _ h, zip_with_append _ _ _ _ _ this] } }
end
end distrib
section comm_monoid
variables [comm_monoid α]
@[to_additive]
lemma prod_mul_prod_eq_prod_zip_with_mul_prod_drop : ∀ (L L' : list α), L.prod * L'.prod =
(zip_with (*) L L').prod * (L.drop L'.length).prod * (L'.drop L.length).prod
| [] ys := by simp [nat.zero_le]
| xs [] := by simp [nat.zero_le]
| (x :: xs) (y :: ys) := begin
simp only [drop, length, zip_with_cons_cons, prod_cons],
rw [mul_assoc x, mul_comm xs.prod, mul_assoc y, mul_comm ys.prod,
prod_mul_prod_eq_prod_zip_with_mul_prod_drop xs ys, mul_assoc, mul_assoc, mul_assoc, mul_assoc]
end
@[to_additive]
lemma prod_mul_prod_eq_prod_zip_with_of_length_eq (L L' : list α) (h : L.length = L'.length) :
L.prod * L'.prod = (zip_with (*) L L').prod :=
(prod_mul_prod_eq_prod_zip_with_mul_prod_drop L L').trans (by simp [h])
end comm_monoid
end list
|
4735dac3e4889ad51c70344db5e919c8c0000ee8 | 74addaa0e41490cbaf2abd313a764c96df57b05d | /Mathlib/category_theory/adjunction/limits_auto.lean | 159b2dc9b3b6c0b97f292ce7a058f4fcea1105fc | [] | no_license | AurelienSaue/Mathlib4_auto | f538cfd0980f65a6361eadea39e6fc639e9dae14 | 590df64109b08190abe22358fabc3eae000943f2 | refs/heads/master | 1,683,906,849,776 | 1,622,564,669,000 | 1,622,564,669,000 | 371,723,747 | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 14,811 | lean | /-
Copyright (c) 2019 Reid Barton. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Reid Barton, Johan Commelin
-/
import Mathlib.PrePort
import Mathlib.Lean3Lib.init.default
import Mathlib.category_theory.adjunction.basic
import Mathlib.category_theory.limits.creates
import Mathlib.PostPort
universes u₁ u₂ v
namespace Mathlib
namespace category_theory.adjunction
/--
The right adjoint of `cocones.functoriality K F : cocone K ⥤ cocone (K ⋙ F)`.
Auxiliary definition for `functoriality_is_left_adjoint`.
-/
def functoriality_right_adjoint {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D}
{G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ C) :
limits.cocone (K ⋙ F) ⥤ limits.cocone K :=
limits.cocones.functoriality (K ⋙ F) G ⋙
limits.cocones.precompose
(iso.inv (functor.right_unitor K) ≫
whisker_left K (unit adj) ≫ iso.inv (functor.associator K F G))
/--
The unit for the adjunction for `cocones.functoriality K F : cocone K ⥤ cocone (K ⋙ F)`.
Auxiliary definition for `functoriality_is_left_adjoint`.
-/
def functoriality_unit {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D} {G : D ⥤ C}
(adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ C) :
𝟭 ⟶ limits.cocones.functoriality K F ⋙ functoriality_right_adjoint adj K :=
nat_trans.mk
fun (c : limits.cocone K) =>
limits.cocone_morphism.mk (nat_trans.app (unit adj) (limits.cocone.X c))
/--
The counit for the adjunction for `cocones.functoriality K F : cocone K ⥤ cocone (K ⋙ F)`.
Auxiliary definition for `functoriality_is_left_adjoint`.
-/
def functoriality_counit {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D}
{G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ C) :
functoriality_right_adjoint adj K ⋙ limits.cocones.functoriality K F ⟶ 𝟭 :=
nat_trans.mk
fun (c : limits.cocone (K ⋙ F)) =>
limits.cocone_morphism.mk (nat_trans.app (counit adj) (limits.cocone.X c))
/-- The functor `cocones.functoriality K F : cocone K ⥤ cocone (K ⋙ F)` is a left adjoint. -/
def functoriality_is_left_adjoint {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D}
{G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ C) :
is_left_adjoint (limits.cocones.functoriality K F) :=
is_left_adjoint.mk (functoriality_right_adjoint adj K)
(mk_of_unit_counit
(core_unit_counit.mk (functoriality_unit adj K) (functoriality_counit adj K)))
/--
A left adjoint preserves colimits.
See https://stacks.math.columbia.edu/tag/0038.
-/
def left_adjoint_preserves_colimits {C : Type u₁} [category C] {D : Type u₂} [category D]
{F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) : limits.preserves_colimits F :=
limits.preserves_colimits.mk
fun (J : Type v) (𝒥 : small_category J) =>
limits.preserves_colimits_of_shape.mk
fun (F_1 : J ⥤ C) =>
limits.preserves_colimit.mk
fun (c : limits.cocone F_1) (hc : limits.is_colimit c) =>
iso.inv limits.is_colimit.iso_unique_cocone_morphism
fun (s : limits.cocone (F_1 ⋙ F)) =>
equiv.unique (hom_equiv is_left_adjoint.adj c s)
protected instance is_equivalence_preserves_colimits {C : Type u₁} [category C] {D : Type u₂}
[category D] (E : C ⥤ D) [is_equivalence E] : limits.preserves_colimits E :=
left_adjoint_preserves_colimits (functor.adjunction E)
protected instance is_equivalence_reflects_colimits {C : Type u₁} [category C] {D : Type u₂}
[category D] (E : D ⥤ C) [is_equivalence E] : limits.reflects_colimits E :=
limits.reflects_colimits.mk
fun (J : Type v) (𝒥 : small_category J) =>
limits.reflects_colimits_of_shape.mk
fun (K : J ⥤ D) =>
limits.reflects_colimit.mk
fun (c : limits.cocone K) (t : limits.is_colimit (functor.map_cocone E c)) =>
limits.is_colimit.of_iso_colimit
(coe_fn
(equiv.symm
(limits.is_colimit.precompose_inv_equiv (functor.right_unitor K)
(functor.map_cocone 𝟭 c)))
(limits.is_colimit.map_cocone_equiv (functor.fun_inv_id E)
(limits.is_colimit_of_preserves (functor.inv E) t)))
(limits.cocones.ext sorry sorry)
protected instance is_equivalence_creates_colimits {C : Type u₁} [category C] {D : Type u₂}
[category D] (H : D ⥤ C) [is_equivalence H] : creates_colimits H :=
creates_colimits.mk
fun (J : Type v) (𝒥 : small_category J) =>
creates_colimits_of_shape.mk
fun (F : J ⥤ D) =>
creates_colimit.mk
fun (c : limits.cocone (F ⋙ H)) (t : limits.is_colimit c) =>
liftable_cocone.mk (functor.map_cocone_inv H c)
(functor.map_cocone_map_cocone_inv H c)
-- verify the preserve_colimits instance works as expected:
protected instance has_colimit_comp_equivalence {C : Type u₁} [category C] {D : Type u₂}
[category D] {J : Type v} [small_category J] (K : J ⥤ C) (E : C ⥤ D) [is_equivalence E]
[limits.has_colimit K] : limits.has_colimit (K ⋙ E) :=
limits.has_colimit.mk
(limits.colimit_cocone.mk (functor.map_cocone E (limits.colimit.cocone K))
(limits.preserves_colimit.preserves (limits.colimit.is_colimit K)))
theorem has_colimit_of_comp_equivalence {C : Type u₁} [category C] {D : Type u₂} [category D]
{J : Type v} [small_category J] (K : J ⥤ C) (E : C ⥤ D) [is_equivalence E]
[limits.has_colimit (K ⋙ E)] : limits.has_colimit K :=
limits.has_colimit_of_iso
(iso.symm (functor.right_unitor K) ≪≫ iso.symm (iso_whisker_left K (functor.fun_inv_id E)))
/--
The left adjoint of `cones.functoriality K G : cone K ⥤ cone (K ⋙ G)`.
Auxiliary definition for `functoriality_is_right_adjoint`.
-/
def functoriality_left_adjoint {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D}
{G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ D) :
limits.cone (K ⋙ G) ⥤ limits.cone K :=
limits.cones.functoriality (K ⋙ G) F ⋙
limits.cones.postcompose
(iso.hom (functor.associator K G F) ≫
whisker_left K (counit adj) ≫ iso.hom (functor.right_unitor K))
/--
The unit for the adjunction for`cones.functoriality K G : cone K ⥤ cone (K ⋙ G)`.
Auxiliary definition for `functoriality_is_right_adjoint`.
-/
@[simp] theorem functoriality_unit'_app_hom {C : Type u₁} [category C] {D : Type u₂} [category D]
{F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ D)
(c : limits.cone (K ⋙ G)) :
limits.cone_morphism.hom (nat_trans.app (functoriality_unit' adj K) c) =
nat_trans.app (unit adj) (limits.cone.X c) :=
Eq.refl (limits.cone_morphism.hom (nat_trans.app (functoriality_unit' adj K) c))
/--
The counit for the adjunction for`cones.functoriality K G : cone K ⥤ cone (K ⋙ G)`.
Auxiliary definition for `functoriality_is_right_adjoint`.
-/
@[simp] theorem functoriality_counit'_app_hom {C : Type u₁} [category C] {D : Type u₂} [category D]
{F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ D)
(c : limits.cone K) :
limits.cone_morphism.hom (nat_trans.app (functoriality_counit' adj K) c) =
nat_trans.app (counit adj) (limits.cone.X c) :=
Eq.refl (limits.cone_morphism.hom (nat_trans.app (functoriality_counit' adj K) c))
/-- The functor `cones.functoriality K G : cone K ⥤ cone (K ⋙ G)` is a right adjoint. -/
def functoriality_is_right_adjoint {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D}
{G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] (K : J ⥤ D) :
is_right_adjoint (limits.cones.functoriality K G) :=
is_right_adjoint.mk (functoriality_left_adjoint adj K)
(mk_of_unit_counit
(core_unit_counit.mk (functoriality_unit' adj K) (functoriality_counit' adj K)))
/--
A right adjoint preserves limits.
See https://stacks.math.columbia.edu/tag/0038.
-/
def right_adjoint_preserves_limits {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D}
{G : D ⥤ C} (adj : F ⊣ G) : limits.preserves_limits G :=
limits.preserves_limits.mk
fun (J : Type v) (𝒥 : small_category J) =>
limits.preserves_limits_of_shape.mk
fun (K : J ⥤ D) =>
limits.preserves_limit.mk
fun (c : limits.cone K) (hc : limits.is_limit c) =>
iso.inv limits.is_limit.iso_unique_cone_morphism
fun (s : limits.cone (K ⋙ G)) =>
equiv.unique (equiv.symm (hom_equiv is_right_adjoint.adj s c))
protected instance is_equivalence_preserves_limits {C : Type u₁} [category C] {D : Type u₂}
[category D] (E : D ⥤ C) [is_equivalence E] : limits.preserves_limits E :=
right_adjoint_preserves_limits (functor.adjunction (functor.inv E))
protected instance is_equivalence_reflects_limits {C : Type u₁} [category C] {D : Type u₂}
[category D] (E : D ⥤ C) [is_equivalence E] : limits.reflects_limits E :=
limits.reflects_limits.mk
fun (J : Type v) (𝒥 : small_category J) =>
limits.reflects_limits_of_shape.mk
fun (K : J ⥤ D) =>
limits.reflects_limit.mk
fun (c : limits.cone K) (t : limits.is_limit (functor.map_cone E c)) =>
limits.is_limit.of_iso_limit
(coe_fn
(equiv.symm
(limits.is_limit.postcompose_hom_equiv (functor.left_unitor K)
(functor.map_cone 𝟭 c)))
(limits.is_limit.map_cone_equiv (functor.fun_inv_id E)
(limits.is_limit_of_preserves (functor.inv E) t)))
(limits.cones.ext sorry sorry)
protected instance is_equivalence_creates_limits {C : Type u₁} [category C] {D : Type u₂}
[category D] (H : D ⥤ C) [is_equivalence H] : creates_limits H :=
creates_limits.mk
fun (J : Type v) (𝒥 : small_category J) =>
creates_limits_of_shape.mk
fun (F : J ⥤ D) =>
creates_limit.mk
fun (c : limits.cone (F ⋙ H)) (t : limits.is_limit c) =>
liftable_cone.mk (functor.map_cone_inv H c) (functor.map_cone_map_cone_inv H c)
-- verify the preserve_limits instance works as expected:
protected instance has_limit_comp_equivalence {C : Type u₁} [category C] {D : Type u₂} [category D]
{J : Type v} [small_category J] (K : J ⥤ D) (E : D ⥤ C) [is_equivalence E]
[limits.has_limit K] : limits.has_limit (K ⋙ E) :=
limits.has_limit.mk
(limits.limit_cone.mk (functor.map_cone E (limits.limit.cone K))
(limits.preserves_limit.preserves (limits.limit.is_limit K)))
theorem has_limit_of_comp_equivalence {C : Type u₁} [category C] {D : Type u₂} [category D]
{J : Type v} [small_category J] (K : J ⥤ D) (E : D ⥤ C) [is_equivalence E]
[limits.has_limit (K ⋙ E)] : limits.has_limit K :=
limits.has_limit_of_iso (iso_whisker_left K (functor.fun_inv_id E) ≪≫ functor.right_unitor K)
/-- auxiliary construction for `cocones_iso` -/
@[simp] theorem cocones_iso_component_hom_app {C : Type u₁} [category C] {D : Type u₂} [category D]
{F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] {K : J ⥤ C} (Y : D)
(t : functor.obj (functor.obj (cocones J D) (opposite.op (K ⋙ F))) Y) (j : J) :
nat_trans.app (cocones_iso_component_hom adj Y t) j =
coe_fn (hom_equiv adj (functor.obj K j) Y) (nat_trans.app t j) :=
Eq.refl (nat_trans.app (cocones_iso_component_hom adj Y t) j)
/-- auxiliary construction for `cocones_iso` -/
def cocones_iso_component_inv {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D}
{G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] {K : J ⥤ C} (Y : D)
(t : functor.obj (G ⋙ functor.obj (cocones J C) (opposite.op K)) Y) :
functor.obj (functor.obj (cocones J D) (opposite.op (K ⋙ F))) Y :=
nat_trans.mk
fun (j : J) => coe_fn (equiv.symm (hom_equiv adj (functor.obj K j) Y)) (nat_trans.app t j)
/--
When `F ⊣ G`,
the functor associating to each `Y` the cocones over `K ⋙ F` with cone point `Y`
is naturally isomorphic to
the functor associating to each `Y` the cocones over `K` with cone point `G.obj Y`.
-/
-- Note: this is natural in K, but we do not yet have the tools to formulate that.
def cocones_iso {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D} {G : D ⥤ C}
(adj : F ⊣ G) {J : Type v} [small_category J] {K : J ⥤ C} :
functor.obj (cocones J D) (opposite.op (K ⋙ F)) ≅
G ⋙ functor.obj (cocones J C) (opposite.op K) :=
nat_iso.of_components
(fun (Y : D) => iso.mk (cocones_iso_component_hom adj Y) (cocones_iso_component_inv adj Y))
sorry
/-- auxiliary construction for `cones_iso` -/
@[simp] theorem cones_iso_component_hom_app {C : Type u₁} [category C] {D : Type u₂} [category D]
{F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] {K : J ⥤ D} (X : Cᵒᵖ)
(t : functor.obj (functor.op F ⋙ functor.obj (cones J D) K) X) (j : J) :
nat_trans.app (cones_iso_component_hom adj X t) j =
coe_fn (hom_equiv adj (opposite.unop X) (functor.obj K j)) (nat_trans.app t j) :=
Eq.refl (nat_trans.app (cones_iso_component_hom adj X t) j)
/-- auxiliary construction for `cones_iso` -/
@[simp] theorem cones_iso_component_inv_app {C : Type u₁} [category C] {D : Type u₂} [category D]
{F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) {J : Type v} [small_category J] {K : J ⥤ D} (X : Cᵒᵖ)
(t : functor.obj (functor.obj (cones J C) (K ⋙ G)) X) (j : J) :
nat_trans.app (cones_iso_component_inv adj X t) j =
coe_fn (equiv.symm (hom_equiv adj (opposite.unop X) (functor.obj K j)))
(nat_trans.app t j) :=
Eq.refl (nat_trans.app (cones_iso_component_inv adj X t) j)
-- Note: this is natural in K, but we do not yet have the tools to formulate that.
/--
When `F ⊣ G`,
the functor associating to each `X` the cones over `K` with cone point `F.op.obj X`
is naturally isomorphic to
the functor associating to each `X` the cones over `K ⋙ G` with cone point `X`.
-/
def cones_iso {C : Type u₁} [category C] {D : Type u₂} [category D] {F : C ⥤ D} {G : D ⥤ C}
(adj : F ⊣ G) {J : Type v} [small_category J] {K : J ⥤ D} :
functor.op F ⋙ functor.obj (cones J D) K ≅ functor.obj (cones J C) (K ⋙ G) :=
nat_iso.of_components
(fun (X : Cᵒᵖ) => iso.mk (cones_iso_component_hom adj X) (cones_iso_component_inv adj X)) sorry
end Mathlib |
d4fe38cdc85e8770df0a69f0309b8fe1d10021f0 | fa02ed5a3c9c0adee3c26887a16855e7841c668b | /src/algebra/divisibility.lean | e8b748306481472b9fd8ced41cf982fba14f8ec8 | [
"Apache-2.0"
] | permissive | jjgarzella/mathlib | 96a345378c4e0bf26cf604aed84f90329e4896a2 | 395d8716c3ad03747059d482090e2bb97db612c8 | refs/heads/master | 1,686,480,124,379 | 1,625,163,323,000 | 1,625,163,323,000 | 281,190,421 | 2 | 0 | Apache-2.0 | 1,595,268,170,000 | 1,595,268,169,000 | null | UTF-8 | Lean | false | false | 8,140 | lean | /-
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, Amelia Livingston, Yury Kudryashov,
Neil Strickland, Aaron Anderson
-/
import algebra.group_with_zero
/-!
# Divisibility
This file defines the basics of the divisibility relation in the context of `(comm_)` `monoid`s
`(_with_zero)`.
## Main definitions
* `monoid.has_dvd`
## Implementation notes
The divisibility relation is defined for all monoids, and as such, depends on the order of
multiplication if the monoid is not commutative. There are two possible conventions for
divisibility in the noncommutative context, and this relation follows the convention for ordinals,
so `a | b` is defined as `∃ c, b = a * c`.
## Tags
divisibility, divides
-/
variables {α : Type*}
section monoid
variables [monoid α] {a b c : α}
/-- There are two possible conventions for divisibility, which coincide in a `comm_monoid`.
This matches the convention for ordinals. -/
@[priority 100]
instance monoid_has_dvd : has_dvd α :=
has_dvd.mk (λ a b, ∃ c, b = a * c)
-- TODO: this used to not have c explicit, but that seems to be important
-- for use with tactics, similar to exist.intro
theorem dvd.intro (c : α) (h : a * c = b) : a ∣ b :=
exists.intro c h^.symm
alias dvd.intro ← dvd_of_mul_right_eq
theorem exists_eq_mul_right_of_dvd (h : a ∣ b) : ∃ c, b = a * c := h
theorem dvd.elim {P : Prop} {a b : α} (H₁ : a ∣ b) (H₂ : ∀ c, b = a * c → P) : P :=
exists.elim H₁ H₂
@[refl, simp] theorem dvd_refl (a : α) : a ∣ a :=
dvd.intro 1 (by simp)
local attribute [simp] mul_assoc mul_comm mul_left_comm
@[trans] theorem dvd_trans (h₁ : a ∣ b) (h₂ : b ∣ c) : a ∣ c :=
match h₁, h₂ with
| ⟨d, (h₃ : b = a * d)⟩, ⟨e, (h₄ : c = b * e)⟩ :=
⟨d * e, show c = a * (d * e), by simp [h₃, h₄]⟩
end
alias dvd_trans ← dvd.trans
theorem one_dvd (a : α) : 1 ∣ a := dvd.intro a (by simp)
@[simp] theorem dvd_mul_right (a b : α) : a ∣ a * b := dvd.intro b rfl
theorem dvd_mul_of_dvd_left (h : a ∣ b) (c : α) : a ∣ b * c :=
dvd.elim h (λ d h', begin rw [h', mul_assoc], apply dvd_mul_right end)
theorem dvd_of_mul_right_dvd (h : a * b ∣ c) : a ∣ c :=
dvd.elim h (begin intros d h₁, rw [h₁, mul_assoc], apply dvd_mul_right end)
end monoid
section comm_monoid
variables [comm_monoid α] {a b c : α}
theorem dvd.intro_left (c : α) (h : c * a = b) : a ∣ b :=
dvd.intro _ (begin rewrite mul_comm at h, apply h end)
alias dvd.intro_left ← dvd_of_mul_left_eq
theorem exists_eq_mul_left_of_dvd (h : a ∣ b) : ∃ c, b = c * a :=
dvd.elim h (assume c, assume H1 : b = a * c, exists.intro c (eq.trans H1 (mul_comm a c)))
theorem dvd.elim_left {P : Prop} (h₁ : a ∣ b) (h₂ : ∀ c, b = c * a → P) : P :=
exists.elim (exists_eq_mul_left_of_dvd h₁) (assume c, assume h₃ : b = c * a, h₂ c h₃)
@[simp] theorem dvd_mul_left (a b : α) : a ∣ b * a := dvd.intro b (mul_comm a b)
theorem dvd_mul_of_dvd_right (h : a ∣ b) (c : α) : a ∣ c * b :=
begin rw mul_comm, exact dvd_mul_of_dvd_left h _ end
local attribute [simp] mul_assoc mul_comm mul_left_comm
theorem mul_dvd_mul : ∀ {a b c d : α}, a ∣ b → c ∣ d → a * c ∣ b * d
| a ._ c ._ ⟨e, rfl⟩ ⟨f, rfl⟩ := ⟨e * f, by simp⟩
theorem mul_dvd_mul_left (a : α) {b c : α} (h : b ∣ c) : a * b ∣ a * c :=
mul_dvd_mul (dvd_refl a) h
theorem mul_dvd_mul_right (h : a ∣ b) (c : α) : a * c ∣ b * c :=
mul_dvd_mul h (dvd_refl c)
theorem dvd_of_mul_left_dvd (h : a * b ∣ c) : b ∣ c :=
dvd.elim h (λ d ceq, dvd.intro (a * d) (by simp [ceq]))
end comm_monoid
section monoid_with_zero
variables [monoid_with_zero α] {a : α}
theorem eq_zero_of_zero_dvd (h : 0 ∣ a) : a = 0 :=
dvd.elim h (assume c, assume H' : a = 0 * c, eq.trans H' (zero_mul c))
/-- Given an element `a` of a commutative monoid with zero, there exists another element whose
product with zero equals `a` iff `a` equals zero. -/
@[simp] lemma zero_dvd_iff : 0 ∣ a ↔ a = 0 :=
⟨eq_zero_of_zero_dvd, λ h, by rw h⟩
@[simp] theorem dvd_zero (a : α) : a ∣ 0 := dvd.intro 0 (by simp)
end monoid_with_zero
/-- Given two elements `b`, `c` of a `cancel_monoid_with_zero` and a nonzero element `a`,
`a*b` divides `a*c` iff `b` divides `c`. -/
theorem mul_dvd_mul_iff_left [cancel_monoid_with_zero α] {a b c : α}
(ha : a ≠ 0) : a * b ∣ a * c ↔ b ∣ c :=
exists_congr $ λ d, by rw [mul_assoc, mul_right_inj' ha]
/-- Given two elements `a`, `b` of a commutative `cancel_monoid_with_zero` and a nonzero
element `c`, `a*c` divides `b*c` iff `a` divides `b`. -/
theorem mul_dvd_mul_iff_right [comm_cancel_monoid_with_zero α] {a b c : α} (hc : c ≠ 0) :
a * c ∣ b * c ↔ a ∣ b :=
exists_congr $ λ d, by rw [mul_right_comm, mul_left_inj' hc]
/-!
### Units in various monoids
-/
namespace units
section monoid
variables [monoid α] {a b : α} {u : units α}
/-- Elements of the unit group of a monoid represented as elements of the monoid
divide any element of the monoid. -/
lemma coe_dvd : ↑u ∣ a := ⟨↑u⁻¹ * a, by simp⟩
/-- In a monoid, an element `a` divides an element `b` iff `a` divides all
associates of `b`. -/
lemma dvd_mul_right : a ∣ b * u ↔ a ∣ b :=
iff.intro
(assume ⟨c, eq⟩, ⟨c * ↑u⁻¹, by rw [← mul_assoc, ← eq, units.mul_inv_cancel_right]⟩)
(assume ⟨c, eq⟩, eq.symm ▸ dvd_mul_of_dvd_left (dvd_mul_right _ _) _)
/-- In a monoid, an element a divides an element b iff all associates of `a` divide `b`.-/
lemma mul_right_dvd : a * u ∣ b ↔ a ∣ b :=
iff.intro
(λ ⟨c, eq⟩, ⟨↑u * c, eq.trans (mul_assoc _ _ _)⟩)
(λ h, dvd_trans (dvd.intro ↑u⁻¹ (by rw [mul_assoc, u.mul_inv, mul_one])) h)
end monoid
section comm_monoid
variables [comm_monoid α] {a b : α} {u : units α}
/-- In a commutative monoid, an element `a` divides an element `b` iff `a` divides all left
associates of `b`. -/
lemma dvd_mul_left : a ∣ u * b ↔ a ∣ b := by { rw mul_comm, apply dvd_mul_right }
/-- In a commutative monoid, an element `a` divides an element `b` iff all
left associates of `a` divide `b`.-/
lemma mul_left_dvd : ↑u * a ∣ b ↔ a ∣ b :=
by { rw mul_comm, apply mul_right_dvd }
end comm_monoid
end units
namespace is_unit
section monoid
variables [monoid α] {a b u : α} (hu : is_unit u)
include hu
/-- Units of a monoid divide any element of the monoid. -/
@[simp] lemma dvd : u ∣ a := by { rcases hu with ⟨u, rfl⟩, apply units.coe_dvd, }
@[simp] lemma dvd_mul_right : a ∣ b * u ↔ a ∣ b :=
by { rcases hu with ⟨u, rfl⟩, apply units.dvd_mul_right, }
/-- In a monoid, an element a divides an element b iff all associates of `a` divide `b`.-/
@[simp] lemma mul_right_dvd : a * u ∣ b ↔ a ∣ b :=
by { rcases hu with ⟨u, rfl⟩, apply units.mul_right_dvd, }
end monoid
section comm_monoid
variables [comm_monoid α] (a b u : α) (hu : is_unit u)
include hu
/-- In a commutative monoid, an element `a` divides an element `b` iff `a` divides all left
associates of `b`. -/
@[simp] lemma dvd_mul_left : a ∣ u * b ↔ a ∣ b :=
by { rcases hu with ⟨u, rfl⟩, apply units.dvd_mul_left, }
/-- In a commutative monoid, an element `a` divides an element `b` iff all
left associates of `a` divide `b`.-/
@[simp] lemma mul_left_dvd : u * a ∣ b ↔ a ∣ b :=
by { rcases hu with ⟨u, rfl⟩, apply units.mul_left_dvd, }
end comm_monoid
end is_unit
section comm_monoid_with_zero
variable [comm_monoid_with_zero α]
/-- `dvd_not_unit a b` expresses that `a` divides `b` "strictly", i.e. that `b` divided by `a`
is not a unit. -/
def dvd_not_unit (a b : α) : Prop := a ≠ 0 ∧ ∃ x, ¬is_unit x ∧ b = a * x
lemma dvd_not_unit_of_dvd_of_not_dvd {a b : α} (hd : a ∣ b) (hnd : ¬ b ∣ a) :
dvd_not_unit a b :=
begin
split,
{ rintro rfl, exact hnd (dvd_zero _) },
{ rcases hd with ⟨c, rfl⟩,
refine ⟨c, _, rfl⟩,
rintro ⟨u, rfl⟩,
simpa using hnd }
end
end comm_monoid_with_zero
|
cd159bd597ac8541873ed8c7a0f8196b9264cc7c | 57aec6ee746bc7e3a3dd5e767e53bd95beb82f6d | /tests/lean/run/stxKindInsideNamespace.lean | fa59c18cfb5868605452d9ffe38501677edce7f4 | [
"Apache-2.0"
] | permissive | collares/lean4 | 861a9269c4592bce49b71059e232ff0bfe4594cc | 52a4f535d853a2c7c7eea5fee8a4fa04c682c1ee | refs/heads/master | 1,691,419,031,324 | 1,618,678,138,000 | 1,618,678,138,000 | 358,989,750 | 0 | 0 | Apache-2.0 | 1,618,696,333,000 | 1,618,696,333,000 | null | UTF-8 | Lean | false | false | 267 | lean | import Lean
namespace Foo
syntax (name := foo) "bla!" term : term
macro_rules[foo]
| `(bla! $x) => pure x
#check bla! 10
macro "foo!" x:term : term => pure x
#check foo! 10
elab "boo!" x:term : term =>
Lean.Elab.Term.elabTerm x none
#check boo! 20
end Foo
|
4081c6d44eae6a3a3fbb2b10d83457c1ae7469ce | 8e6cad62ec62c6c348e5faaa3c3f2079012bdd69 | /src/field_theory/splitting_field.lean | fb8b01d52fe5a868d5d114a0a96cb31c9cf2afdc | [
"Apache-2.0"
] | permissive | benjamindavidson/mathlib | 8cc81c865aa8e7cf4462245f58d35ae9a56b150d | fad44b9f670670d87c8e25ff9cdf63af87ad731e | refs/heads/master | 1,679,545,578,362 | 1,615,343,014,000 | 1,615,343,014,000 | 312,926,983 | 0 | 0 | Apache-2.0 | 1,615,360,301,000 | 1,605,399,418,000 | Lean | UTF-8 | Lean | false | false | 35,651 | lean | /-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes
Definition of splitting fields, and definition of homomorphism into any field that splits
-/
import ring_theory.adjoin_root
import ring_theory.algebra_tower
import ring_theory.algebraic
import ring_theory.polynomial
import field_theory.minpoly
import linear_algebra.finite_dimensional
import tactic.field_simp
noncomputable theory
open_locale classical big_operators
universes u v w
variables {α : Type u} {β : Type v} {γ : Type w}
namespace polynomial
variables [field α] [field β] [field γ]
open polynomial
section splits
variables (i : α →+* β)
/-- A polynomial `splits` iff it is zero or all of its irreducible factors have `degree` 1. -/
def splits (f : polynomial α) : Prop :=
f = 0 ∨ ∀ {g : polynomial β}, irreducible g → g ∣ f.map i → degree g = 1
@[simp] lemma splits_zero : splits i (0 : polynomial α) := or.inl rfl
@[simp] lemma splits_C (a : α) : splits i (C a) :=
if ha : a = 0 then ha.symm ▸ (@C_0 α _).symm ▸ splits_zero i
else
have hia : i a ≠ 0, from mt ((is_add_group_hom.injective_iff i).1
i.injective _) ha,
or.inr $ λ g hg ⟨p, hp⟩, absurd hg.1 (not_not.2 (is_unit_iff_degree_eq_zero.2 $
by have := congr_arg degree hp;
simp [degree_C hia, @eq_comm (with_bot ℕ) 0,
nat.with_bot.add_eq_zero_iff] at this; clear _fun_match; tauto))
lemma splits_of_degree_eq_one {f : polynomial α} (hf : degree f = 1) : splits i f :=
or.inr $ λ g hg ⟨p, hp⟩,
by have := congr_arg degree hp;
simp [nat.with_bot.add_eq_one_iff, hf, @eq_comm (with_bot ℕ) 1,
mt is_unit_iff_degree_eq_zero.2 hg.1] at this;
clear _fun_match; tauto
lemma splits_of_degree_le_one {f : polynomial α} (hf : degree f ≤ 1) : splits i f :=
begin
cases h : degree f with n,
{ rw [degree_eq_bot.1 h]; exact splits_zero i },
{ cases n with n,
{ rw [eq_C_of_degree_le_zero (trans_rel_right (≤) h (le_refl _))];
exact splits_C _ _ },
{ have hn : n = 0,
{ rw h at hf,
cases n, { refl }, { exact absurd hf dec_trivial } },
exact splits_of_degree_eq_one _ (by rw [h, hn]; refl) } }
end
lemma splits_of_nat_degree_le_one {f : polynomial α} (hf : nat_degree f ≤ 1) : splits i f :=
splits_of_degree_le_one i (degree_le_of_nat_degree_le hf)
lemma splits_of_nat_degree_eq_one {f : polynomial α} (hf : nat_degree f = 1) : splits i f :=
splits_of_nat_degree_le_one i (le_of_eq hf)
lemma splits_mul {f g : polynomial α} (hf : splits i f) (hg : splits i g) : splits i (f * g) :=
if h : f * g = 0 then by simp [h]
else or.inr $ λ p hp hpf, ((principal_ideal_ring.irreducible_iff_prime.1 hp).2.2 _ _
(show p ∣ map i f * map i g, by convert hpf; rw polynomial.map_mul)).elim
(hf.resolve_left (λ hf, by simpa [hf] using h) hp)
(hg.resolve_left (λ hg, by simpa [hg] using h) hp)
lemma splits_of_splits_mul {f g : polynomial α} (hfg : f * g ≠ 0) (h : splits i (f * g)) :
splits i f ∧ splits i g :=
⟨or.inr $ λ g hgi hg, or.resolve_left h hfg hgi
(by rw map_mul; exact dvd.trans hg (dvd_mul_right _ _)),
or.inr $ λ g hgi hg, or.resolve_left h hfg hgi
(by rw map_mul; exact dvd.trans hg (dvd_mul_left _ _))⟩
lemma splits_of_splits_of_dvd {f g : polynomial α} (hf0 : f ≠ 0) (hf : splits i f) (hgf : g ∣ f) :
splits i g :=
by { obtain ⟨f, rfl⟩ := hgf, exact (splits_of_splits_mul i hf0 hf).1 }
lemma splits_of_splits_gcd_left {f g : polynomial α} (hf0 : f ≠ 0) (hf : splits i f) :
splits i (euclidean_domain.gcd f g) :=
polynomial.splits_of_splits_of_dvd i hf0 hf (euclidean_domain.gcd_dvd_left f g)
lemma splits_of_splits_gcd_right {f g : polynomial α} (hg0 : g ≠ 0) (hg : splits i g) :
splits i (euclidean_domain.gcd f g) :=
polynomial.splits_of_splits_of_dvd i hg0 hg (euclidean_domain.gcd_dvd_right f g)
lemma splits_map_iff (j : β →+* γ) {f : polynomial α} :
splits j (f.map i) ↔ splits (j.comp i) f :=
by simp [splits, polynomial.map_map]
theorem splits_one : splits i 1 :=
splits_C i 1
theorem splits_of_is_unit {u : polynomial α} (hu : is_unit u) : u.splits i :=
splits_of_splits_of_dvd i one_ne_zero (splits_one _) $ is_unit_iff_dvd_one.1 hu
theorem splits_X_sub_C {x : α} : (X - C x).splits i :=
splits_of_degree_eq_one _ $ degree_X_sub_C x
theorem splits_X : X.splits i :=
splits_of_degree_eq_one _ $ degree_X
theorem splits_id_iff_splits {f : polynomial α} :
(f.map i).splits (ring_hom.id β) ↔ f.splits i :=
by rw [splits_map_iff, ring_hom.id_comp]
theorem splits_mul_iff {f g : polynomial α} (hf : f ≠ 0) (hg : g ≠ 0) :
(f * g).splits i ↔ f.splits i ∧ g.splits i :=
⟨splits_of_splits_mul i (mul_ne_zero hf hg), λ ⟨hfs, hgs⟩, splits_mul i hfs hgs⟩
theorem splits_prod {ι : Type w} {s : ι → polynomial α} {t : finset ι} :
(∀ j ∈ t, (s j).splits i) → (∏ x in t, s x).splits i :=
begin
refine finset.induction_on t (λ _, splits_one i) (λ a t hat ih ht, _),
rw finset.forall_mem_insert at ht, rw finset.prod_insert hat,
exact splits_mul i ht.1 (ih ht.2)
end
theorem splits_prod_iff {ι : Type w} {s : ι → polynomial α} {t : finset ι} :
(∀ j ∈ t, s j ≠ 0) → ((∏ x in t, s x).splits i ↔ ∀ j ∈ t, (s j).splits i) :=
begin
refine finset.induction_on t (λ _, ⟨λ _ _ h, h.elim, λ _, splits_one i⟩) (λ a t hat ih ht, _),
rw finset.forall_mem_insert at ht ⊢,
rw [finset.prod_insert hat, splits_mul_iff i ht.1 (finset.prod_ne_zero_iff.2 ht.2), ih ht.2]
end
lemma degree_eq_one_of_irreducible_of_splits {p : polynomial β}
(h_nz : p ≠ 0) (hp : irreducible p) (hp_splits : splits (ring_hom.id β) p) :
p.degree = 1 :=
begin
rcases hp_splits,
{ contradiction },
{ apply hp_splits hp, simp }
end
lemma exists_root_of_splits {f : polynomial α} (hs : splits i f) (hf0 : degree f ≠ 0) :
∃ x, eval₂ i x f = 0 :=
if hf0 : f = 0 then ⟨37, by simp [hf0]⟩
else
let ⟨g, hg⟩ := wf_dvd_monoid.exists_irreducible_factor
(show ¬ is_unit (f.map i), from mt is_unit_iff_degree_eq_zero.1 (by rwa degree_map))
(map_ne_zero hf0) in
let ⟨x, hx⟩ := exists_root_of_degree_eq_one (hs.resolve_left hf0 hg.1 hg.2) in
let ⟨i, hi⟩ := hg.2 in
⟨x, by rw [← eval_map, hi, eval_mul, show _ = _, from hx, zero_mul]⟩
lemma exists_multiset_of_splits {f : polynomial α} : splits i f →
∃ (s : multiset β), f.map i = C (i f.leading_coeff) *
(s.map (λ a : β, (X : polynomial β) - C a)).prod :=
suffices splits (ring_hom.id _) (f.map i) → ∃ s : multiset β, f.map i =
(C (f.map i).leading_coeff) * (s.map (λ a : β, (X : polynomial β) - C a)).prod,
by rwa [splits_map_iff, leading_coeff_map i] at this,
wf_dvd_monoid.induction_on_irreducible (f.map i)
(λ _, ⟨{37}, by simp [i.map_zero]⟩)
(λ u hu _, ⟨0,
by conv_lhs { rw eq_C_of_degree_eq_zero (is_unit_iff_degree_eq_zero.1 hu) };
simp [leading_coeff, nat_degree_eq_of_degree_eq_some (is_unit_iff_degree_eq_zero.1 hu)]⟩)
(λ f p hf0 hp ih hfs,
have hpf0 : p * f ≠ 0, from mul_ne_zero hp.ne_zero hf0,
let ⟨s, hs⟩ := ih (splits_of_splits_mul _ hpf0 hfs).2 in
⟨-(p * norm_unit p).coeff 0 ::ₘ s,
have hp1 : degree p = 1, from hfs.resolve_left hpf0 hp (by simp),
begin
rw [multiset.map_cons, multiset.prod_cons, leading_coeff_mul, C_mul, mul_assoc,
mul_left_comm (C f.leading_coeff), ← hs, ← mul_assoc, mul_left_inj' hf0],
conv_lhs {rw eq_X_add_C_of_degree_eq_one hp1},
simp only [mul_add, coe_norm_unit_of_ne_zero hp.ne_zero, mul_comm p, coeff_neg,
C_neg, sub_eq_add_neg, neg_neg, coeff_C_mul, (mul_assoc _ _ _).symm, C_mul.symm,
mul_inv_cancel (show p.leading_coeff ≠ 0, from mt leading_coeff_eq_zero.1
hp.ne_zero), one_mul],
end⟩)
/-- Pick a root of a polynomial that splits. -/
def root_of_splits {f : polynomial α} (hf : f.splits i) (hfd : f.degree ≠ 0) : β :=
classical.some $ exists_root_of_splits i hf hfd
theorem map_root_of_splits {f : polynomial α} (hf : f.splits i) (hfd) :
f.eval₂ i (root_of_splits i hf hfd) = 0 :=
classical.some_spec $ exists_root_of_splits i hf hfd
theorem roots_map {f : polynomial α} (hf : f.splits $ ring_hom.id α) :
(f.map i).roots = (f.roots).map i :=
if hf0 : f = 0 then by rw [hf0, map_zero, roots_zero, roots_zero, multiset.map_zero] else
have hmf0 : f.map i ≠ 0 := map_ne_zero hf0,
let ⟨m, hm⟩ := exists_multiset_of_splits _ hf in
have h1 : (0 : polynomial α) ∉ m.map (λ r, X - C r),
from zero_nmem_multiset_map_X_sub_C _ _,
have h2 : (0 : polynomial β) ∉ m.map (λ r, X - C (i r)),
from zero_nmem_multiset_map_X_sub_C _ _,
begin
rw map_id at hm, rw hm at hf0 hmf0 ⊢, rw map_mul at hmf0 ⊢,
rw [roots_mul hf0, roots_mul hmf0, map_C, roots_C, zero_add, roots_C, zero_add,
map_multiset_prod, multiset.map_map], simp_rw [(∘), map_sub, map_X, map_C],
rw [roots_multiset_prod _ h2, multiset.bind_map,
roots_multiset_prod _ h1, multiset.bind_map],
simp_rw roots_X_sub_C,
rw [multiset.bind_cons, multiset.bind_zero, add_zero,
multiset.bind_cons, multiset.bind_zero, add_zero, multiset.map_id']
end
lemma eq_prod_roots_of_splits {p : polynomial α} {i : α →+* β}
(hsplit : splits i p) :
p.map i = C (i p.leading_coeff) * ((p.map i).roots.map (λ a, X - C a)).prod :=
begin
by_cases p_eq_zero : p = 0,
{ rw [p_eq_zero, map_zero, leading_coeff_zero, i.map_zero, C.map_zero, zero_mul] },
obtain ⟨s, hs⟩ := exists_multiset_of_splits i hsplit,
have map_ne_zero : p.map i ≠ 0 := map_ne_zero (p_eq_zero),
have prod_ne_zero : C (i p.leading_coeff) * (multiset.map (λ a, X - C a) s).prod ≠ 0 :=
by rwa hs at map_ne_zero,
have zero_nmem : (0 : polynomial β) ∉ s.map (λ a, X - C a),
from zero_nmem_multiset_map_X_sub_C _ _,
have map_bind_roots_eq : (s.map (λ a, X - C a)).bind (λ a, a.roots) = s,
{ refine multiset.induction_on s (by rw [multiset.map_zero, multiset.zero_bind]) _,
intros a s ih,
rw [multiset.map_cons, multiset.cons_bind, ih, roots_X_sub_C,
multiset.cons_add, zero_add] },
rw [hs, roots_mul prod_ne_zero, roots_C, zero_add,
roots_multiset_prod _ zero_nmem,
map_bind_roots_eq]
end
lemma eq_X_sub_C_of_splits_of_single_root {x : α} {h : polynomial α} (h_splits : splits i h)
(h_roots : (h.map i).roots = {i x}) : h = (C (leading_coeff h)) * (X - C x) :=
begin
apply polynomial.map_injective _ i.injective,
rw [eq_prod_roots_of_splits h_splits, h_roots],
simp,
end
lemma nat_degree_multiset_prod {R : Type*} [integral_domain R] {s : multiset (polynomial R)}
(h : (0 : polynomial R) ∉ s) :
nat_degree s.prod = (s.map nat_degree).sum :=
begin
revert h,
refine s.induction_on _ _,
{ simp },
intros p s ih h,
rw [multiset.mem_cons, not_or_distrib] at h,
have hprod : s.prod ≠ 0 := multiset.prod_ne_zero h.2,
rw [multiset.prod_cons, nat_degree_mul (ne.symm h.1) hprod, ih h.2,
multiset.map_cons, multiset.sum_cons],
end
lemma nat_degree_eq_card_roots {p : polynomial α} {i : α →+* β}
(hsplit : splits i p) : p.nat_degree = (p.map i).roots.card :=
begin
by_cases p_eq_zero : p = 0,
{ rw [p_eq_zero, nat_degree_zero, map_zero, roots_zero, multiset.card_zero] },
have map_ne_zero : p.map i ≠ 0 := map_ne_zero (p_eq_zero),
rw eq_prod_roots_of_splits hsplit at map_ne_zero,
conv_lhs { rw [← nat_degree_map i, eq_prod_roots_of_splits hsplit] },
have : (0 : polynomial β) ∉ (map i p).roots.map (λ a, X - C a),
from zero_nmem_multiset_map_X_sub_C _ _,
simp [nat_degree_mul (left_ne_zero_of_mul map_ne_zero) (right_ne_zero_of_mul map_ne_zero),
nat_degree_multiset_prod this]
end
lemma degree_eq_card_roots {p : polynomial α} {i : α →+* β} (p_ne_zero : p ≠ 0)
(hsplit : splits i p) : p.degree = (p.map i).roots.card :=
by rw [degree_eq_nat_degree p_ne_zero, nat_degree_eq_card_roots hsplit]
section UFD
local attribute [instance, priority 10] principal_ideal_ring.to_unique_factorization_monoid
local infix ` ~ᵤ ` : 50 := associated
open unique_factorization_monoid associates
lemma splits_of_exists_multiset {f : polynomial α} {s : multiset β}
(hs : f.map i = C (i f.leading_coeff) * (s.map (λ a : β, (X : polynomial β) - C a)).prod) :
splits i f :=
if hf0 : f = 0 then or.inl hf0
else
or.inr $ λ p hp hdp,
have ht : multiset.rel associated
(factors (f.map i)) (s.map (λ a : β, (X : polynomial β) - C a)) :=
factors_unique
(λ p hp, irreducible_of_factor _ hp)
(λ p' m, begin
obtain ⟨a,m,rfl⟩ := multiset.mem_map.1 m,
exact irreducible_of_degree_eq_one (degree_X_sub_C _),
end)
(associated.symm $ calc _ ~ᵤ f.map i :
⟨(units.map' C : units β →* units (polynomial β)) (units.mk0 (f.map i).leading_coeff
(mt leading_coeff_eq_zero.1 (map_ne_zero hf0))),
by conv_rhs {rw [hs, ← leading_coeff_map i, mul_comm]}; refl⟩
... ~ᵤ _ : associated.symm (unique_factorization_monoid.factors_prod (by simpa using hf0))),
let ⟨q, hq, hpq⟩ := exists_mem_factors_of_dvd (by simpa) hp hdp in
let ⟨q', hq', hqq'⟩ := multiset.exists_mem_of_rel_of_mem ht hq in
let ⟨a, ha⟩ := multiset.mem_map.1 hq' in
by rw [← degree_X_sub_C a, ha.2];
exact degree_eq_degree_of_associated (hpq.trans hqq')
lemma splits_of_splits_id {f : polynomial α} : splits (ring_hom.id _) f → splits i f :=
unique_factorization_monoid.induction_on_prime f (λ _, splits_zero _)
(λ _ hu _, splits_of_degree_le_one _
((is_unit_iff_degree_eq_zero.1 hu).symm ▸ dec_trivial))
(λ a p ha0 hp ih hfi, splits_mul _
(splits_of_degree_eq_one _
((splits_of_splits_mul _ (mul_ne_zero hp.1 ha0) hfi).1.resolve_left
hp.1 (irreducible_of_prime hp) (by rw map_id)))
(ih (splits_of_splits_mul _ (mul_ne_zero hp.1 ha0) hfi).2))
end UFD
lemma splits_iff_exists_multiset {f : polynomial α} : splits i f ↔
∃ (s : multiset β), f.map i = C (i f.leading_coeff) *
(s.map (λ a : β, (X : polynomial β) - C a)).prod :=
⟨exists_multiset_of_splits i, λ ⟨s, hs⟩, splits_of_exists_multiset i hs⟩
lemma splits_comp_of_splits (j : β →+* γ) {f : polynomial α}
(h : splits i f) : splits (j.comp i) f :=
begin
change i with ((ring_hom.id _).comp i) at h,
rw [← splits_map_iff],
rw [← splits_map_iff i] at h,
exact splits_of_splits_id _ h
end
/-- A monic polynomial `p` that has as much roots as its degree
can be written `p = ∏(X - a)`, for `a` in `p.roots`. -/
lemma prod_multiset_X_sub_C_of_monic_of_roots_card_eq {p : polynomial α}
(hmonic : p.monic) (hroots : p.roots.card = p.nat_degree) :
(multiset.map (λ (a : α), X - C a) p.roots).prod = p :=
begin
have hprodmonic : (multiset.map (λ (a : α), X - C a) p.roots).prod.monic,
{ simp only [prod_multiset_root_eq_finset_root (ne_zero_of_monic hmonic),
monic_prod_of_monic, monic_X_sub_C, monic_pow, forall_true_iff] },
have hdegree : (multiset.map (λ (a : α), X - C a) p.roots).prod.nat_degree = p.nat_degree,
{ rw [← hroots, nat_degree_multiset_prod (zero_nmem_multiset_map_X_sub_C _ (λ a : α, a))],
simp only [eq_self_iff_true, mul_one, nat.cast_id, nsmul_eq_mul, multiset.sum_repeat,
multiset.map_const,nat_degree_X_sub_C, function.comp, multiset.map_map] },
obtain ⟨q, hq⟩ := prod_multiset_X_sub_C_dvd p,
have qzero : q ≠ 0,
{ rintro rfl, apply hmonic.ne_zero, simpa only [mul_zero] using hq },
have degp :
p.nat_degree = (multiset.map (λ (a : α), X - C a) p.roots).prod.nat_degree + q.nat_degree,
{ nth_rewrite 0 [hq],
simp only [nat_degree_mul (ne_zero_of_monic hprodmonic) qzero] },
have degq : q.nat_degree = 0,
{ rw hdegree at degp,
exact (add_right_inj p.nat_degree).mp (tactic.ring_exp.add_pf_sum_z degp rfl).symm },
obtain ⟨u, hu⟩ := is_unit_iff_degree_eq_zero.2 ((degree_eq_iff_nat_degree_eq qzero).2 degq),
have hassoc : associated (multiset.map (λ (a : α), X - C a) p.roots).prod p,
{ rw associated, use u, rw [hu, ← hq] },
exact eq_of_monic_of_associated hprodmonic hmonic hassoc
end
/-- A polynomial `p` that has as much roots as its degree
can be written `p = p.leading_coeff * ∏(X - a)`, for `a` in `p.roots`. -/
lemma C_leading_coeff_mul_prod_multiset_X_sub_C {p : polynomial α}
(hroots : p.roots.card = p.nat_degree) :
(C p.leading_coeff) * (multiset.map (λ (a : α), X - C a) p.roots).prod = p :=
begin
by_cases hzero : p = 0,
{ rw [hzero, leading_coeff_zero, ring_hom.map_zero, zero_mul], },
{ have hcoeff : p.leading_coeff ≠ 0,
{ intro h, exact hzero (leading_coeff_eq_zero.1 h) },
have hrootsnorm : (normalize p).roots.card = (normalize p).nat_degree,
{ rw [roots_normalize, normalize_apply, nat_degree_mul hzero (units.ne_zero _), hroots,
coe_norm_unit, nat_degree_C, add_zero], },
have hprod := prod_multiset_X_sub_C_of_monic_of_roots_card_eq (monic_normalize hzero)
hrootsnorm,
rw [roots_normalize, normalize_apply, coe_norm_unit_of_ne_zero hzero] at hprod,
calc (C p.leading_coeff) * (multiset.map (λ (a : α), X - C a) p.roots).prod
= p * C ((p.leading_coeff)⁻¹ * p.leading_coeff) :
by rw [hprod, mul_comm, mul_assoc, ← C_mul]
... = p * C 1 : by field_simp
... = p : by simp only [mul_one, ring_hom.map_one], },
end
/-- A polynomial splits if and only if it has as much roots as its degree. -/
lemma splits_iff_card_roots {p : polynomial α} :
splits (ring_hom.id α) p ↔ p.roots.card = p.nat_degree :=
begin
split,
{ intro H, rw [nat_degree_eq_card_roots H, map_id] },
{ intro hroots,
apply (splits_iff_exists_multiset (ring_hom.id α)).2,
use p.roots,
simp only [ring_hom.id_apply, map_id],
exact (C_leading_coeff_mul_prod_multiset_X_sub_C hroots).symm },
end
end splits
end polynomial
section embeddings
variables (F : Type*) [field F]
/-- If `p` is the minimal polynomial of `a` over `F` then `F[a] ≃ₐ[F] F[x]/(p)` -/
def alg_equiv.adjoin_singleton_equiv_adjoin_root_minpoly
{R : Type*} [comm_ring R] [algebra F R] (x : R) :
algebra.adjoin F ({x} : set R) ≃ₐ[F] adjoin_root (minpoly F x) :=
alg_equiv.symm $ alg_equiv.of_bijective
(alg_hom.cod_restrict
(adjoin_root.lift_hom _ x $ minpoly.aeval F x) _
(λ p, adjoin_root.induction_on _ p $ λ p,
(algebra.adjoin_singleton_eq_range F x).symm ▸ (polynomial.aeval _).mem_range.mpr ⟨p, rfl⟩))
⟨(alg_hom.injective_cod_restrict _ _ _).2 $ (alg_hom.injective_iff _).2 $ λ p,
adjoin_root.induction_on _ p $ λ p hp, ideal.quotient.eq_zero_iff_mem.2 $
ideal.mem_span_singleton.2 $ minpoly.dvd F x hp,
λ y, let ⟨p, _, hp⟩ := (subalgebra.ext_iff.1 (algebra.adjoin_singleton_eq_range F x) y).1 y.2 in
⟨adjoin_root.mk _ p, subtype.eq hp⟩⟩
open finset
-- Speed up the following proof.
local attribute [irreducible] minpoly
-- TODO: Why is this so slow?
/-- If `K` and `L` are field extensions of `F` and we have `s : finset K` such that
the minimal polynomial of each `x ∈ s` splits in `L` then `algebra.adjoin F s` embeds in `L`. -/
theorem lift_of_splits {F K L : Type*} [field F] [field K] [field L]
[algebra F K] [algebra F L] (s : finset K) :
(∀ x ∈ s, is_integral F x ∧ polynomial.splits (algebra_map F L) (minpoly F x)) →
nonempty (algebra.adjoin F (↑s : set K) →ₐ[F] L) :=
begin
refine finset.induction_on s (λ H, _) (λ a s has ih H, _),
{ rw [coe_empty, algebra.adjoin_empty],
exact ⟨(algebra.of_id F L).comp (algebra.bot_equiv F K)⟩ },
rw forall_mem_insert at H, rcases H with ⟨⟨H1, H2⟩, H3⟩, cases ih H3 with f,
choose H3 H4 using H3,
rw [coe_insert, set.insert_eq, set.union_comm, algebra.adjoin_union],
letI := (f : algebra.adjoin F (↑s : set K) →+* L).to_algebra,
haveI : finite_dimensional F (algebra.adjoin F (↑s : set K)) :=
(submodule.fg_iff_finite_dimensional _).1 (fg_adjoin_of_finite (set.finite_mem_finset s) H3),
letI := field_of_finite_dimensional F (algebra.adjoin F (↑s : set K)),
have H5 : is_integral (algebra.adjoin F (↑s : set K)) a := is_integral_of_is_scalar_tower a H1,
have H6 : (minpoly (algebra.adjoin F (↑s : set K)) a).splits
(algebra_map (algebra.adjoin F (↑s : set K)) L),
{ refine polynomial.splits_of_splits_of_dvd _
(polynomial.map_ne_zero $ minpoly.ne_zero H1 :
polynomial.map (algebra_map _ _) _ ≠ 0)
((polynomial.splits_map_iff _ _).2 _)
(minpoly.dvd _ _ _),
{ rw ← is_scalar_tower.algebra_map_eq, exact H2 },
{ rw [← is_scalar_tower.aeval_apply, minpoly.aeval] } },
obtain ⟨y, hy⟩ := polynomial.exists_root_of_splits _ H6 (ne_of_lt (minpoly.degree_pos H5)).symm,
refine ⟨subalgebra.of_under _ _ _⟩,
refine (adjoin_root.lift_hom (minpoly (algebra.adjoin F (↑s : set K)) a) y hy).comp _,
exact alg_equiv.adjoin_singleton_equiv_adjoin_root_minpoly (algebra.adjoin F (↑s : set K)) a
end
end embeddings
namespace polynomial
variables [field α] [field β] [field γ]
open polynomial
section splitting_field
/-- Non-computably choose an irreducible factor from a polynomial. -/
def factor (f : polynomial α) : polynomial α :=
if H : ∃ g, irreducible g ∧ g ∣ f then classical.some H else X
instance irreducible_factor (f : polynomial α) : irreducible (factor f) :=
begin
rw factor, split_ifs with H, { exact (classical.some_spec H).1 }, { exact irreducible_X }
end
theorem factor_dvd_of_not_is_unit {f : polynomial α} (hf1 : ¬is_unit f) : factor f ∣ f :=
begin
by_cases hf2 : f = 0, { rw hf2, exact dvd_zero _ },
rw [factor, dif_pos (wf_dvd_monoid.exists_irreducible_factor hf1 hf2)],
exact (classical.some_spec $ wf_dvd_monoid.exists_irreducible_factor hf1 hf2).2
end
theorem factor_dvd_of_degree_ne_zero {f : polynomial α} (hf : f.degree ≠ 0) : factor f ∣ f :=
factor_dvd_of_not_is_unit (mt degree_eq_zero_of_is_unit hf)
theorem factor_dvd_of_nat_degree_ne_zero {f : polynomial α} (hf : f.nat_degree ≠ 0) :
factor f ∣ f :=
factor_dvd_of_degree_ne_zero (mt nat_degree_eq_of_degree_eq_some hf)
/-- Divide a polynomial f by X - C r where r is a root of f in a bigger field extension. -/
def remove_factor (f : polynomial α) : polynomial (adjoin_root $ factor f) :=
map (adjoin_root.of f.factor) f /ₘ (X - C (adjoin_root.root f.factor))
theorem X_sub_C_mul_remove_factor (f : polynomial α) (hf : f.nat_degree ≠ 0) :
(X - C (adjoin_root.root f.factor)) * f.remove_factor = map (adjoin_root.of f.factor) f :=
let ⟨g, hg⟩ := factor_dvd_of_nat_degree_ne_zero hf in
mul_div_by_monic_eq_iff_is_root.2 $ by rw [is_root.def, eval_map, hg, eval₂_mul, ← hg,
adjoin_root.eval₂_root, zero_mul]
theorem nat_degree_remove_factor (f : polynomial α) :
f.remove_factor.nat_degree = f.nat_degree - 1 :=
by rw [remove_factor, nat_degree_div_by_monic _ (monic_X_sub_C _), nat_degree_map,
nat_degree_X_sub_C]
theorem nat_degree_remove_factor' {f : polynomial α} {n : ℕ} (hfn : f.nat_degree = n+1) :
f.remove_factor.nat_degree = n :=
by rw [nat_degree_remove_factor, hfn, n.add_sub_cancel]
/-- Auxiliary construction to a splitting field of a polynomial. Uses induction on the degree. -/
def splitting_field_aux (n : ℕ) : Π {α : Type u} [field α], by exactI Π (f : polynomial α),
f.nat_degree = n → Type u :=
nat.rec_on n (λ α _ _ _, α) $ λ n ih α _ f hf, by exactI
ih f.remove_factor (nat_degree_remove_factor' hf)
namespace splitting_field_aux
theorem succ (n : ℕ) (f : polynomial α) (hfn : f.nat_degree = n + 1) :
splitting_field_aux (n+1) f hfn =
splitting_field_aux n f.remove_factor (nat_degree_remove_factor' hfn) := rfl
instance field (n : ℕ) : Π {α : Type u} [field α], by exactI
Π {f : polynomial α} (hfn : f.nat_degree = n), field (splitting_field_aux n f hfn) :=
nat.rec_on n (λ α _ _ _, ‹field α›) $ λ n ih α _ f hf, ih _
instance inhabited {n : ℕ} {f : polynomial α} (hfn : f.nat_degree = n) :
inhabited (splitting_field_aux n f hfn) := ⟨37⟩
instance algebra (n : ℕ) : Π {α : Type u} [field α], by exactI
Π {f : polynomial α} (hfn : f.nat_degree = n), algebra α (splitting_field_aux n f hfn) :=
nat.rec_on n (λ α _ _ _, by exactI algebra.id α) $ λ n ih α _ f hfn,
by exactI @@algebra.comap.algebra _ _ _ _ _ _ _ (ih _)
instance algebra' {n : ℕ} {f : polynomial α} (hfn : f.nat_degree = n + 1) :
algebra (adjoin_root f.factor) (splitting_field_aux _ _ hfn) :=
splitting_field_aux.algebra n _
instance algebra'' {n : ℕ} {f : polynomial α} (hfn : f.nat_degree = n + 1) :
algebra α (splitting_field_aux n f.remove_factor (nat_degree_remove_factor' hfn)) :=
splitting_field_aux.algebra (n+1) hfn
instance algebra''' {n : ℕ} {f : polynomial α} (hfn : f.nat_degree = n + 1) :
algebra (adjoin_root f.factor)
(splitting_field_aux n f.remove_factor (nat_degree_remove_factor' hfn)) :=
splitting_field_aux.algebra n _
instance scalar_tower {n : ℕ} {f : polynomial α} (hfn : f.nat_degree = n + 1) :
is_scalar_tower α (adjoin_root f.factor) (splitting_field_aux _ _ hfn) :=
is_scalar_tower.of_algebra_map_eq $ λ x, rfl
instance scalar_tower' {n : ℕ} {f : polynomial α} (hfn : f.nat_degree = n + 1) :
is_scalar_tower α (adjoin_root f.factor)
(splitting_field_aux n f.remove_factor (nat_degree_remove_factor' hfn)) :=
is_scalar_tower.of_algebra_map_eq $ λ x, rfl
theorem algebra_map_succ (n : ℕ) (f : polynomial α) (hfn : f.nat_degree = n + 1) :
by exact algebra_map α (splitting_field_aux _ _ hfn) =
(algebra_map (adjoin_root f.factor)
(splitting_field_aux n f.remove_factor (nat_degree_remove_factor' hfn))).comp
(adjoin_root.of f.factor) :=
rfl
protected theorem splits (n : ℕ) : ∀ {α : Type u} [field α], by exactI
∀ (f : polynomial α) (hfn : f.nat_degree = n),
splits (algebra_map α $ splitting_field_aux n f hfn) f :=
nat.rec_on n (λ α _ _ hf, by exactI splits_of_degree_le_one _
(le_trans degree_le_nat_degree $ hf.symm ▸ with_bot.coe_le_coe.2 zero_le_one)) $ λ n ih α _ f hf,
by { resetI, rw [← splits_id_iff_splits, algebra_map_succ, ← map_map, splits_id_iff_splits,
← X_sub_C_mul_remove_factor f (λ h, by { rw h at hf, cases hf })],
exact splits_mul _ (splits_X_sub_C _) (ih _ _) }
theorem exists_lift (n : ℕ) : ∀ {α : Type u} [field α], by exactI
∀ (f : polynomial α) (hfn : f.nat_degree = n) {β : Type*} [field β], by exactI
∀ (j : α →+* β) (hf : splits j f), ∃ k : splitting_field_aux n f hfn →+* β,
k.comp (algebra_map _ _) = j :=
nat.rec_on n (λ α _ _ _ β _ j _, by exactI ⟨j, j.comp_id⟩) $ λ n ih α _ f hf β _ j hj, by exactI
have hndf : f.nat_degree ≠ 0, by { intro h, rw h at hf, cases hf },
have hfn0 : f ≠ 0, by { intro h, rw h at hndf, exact hndf rfl },
let ⟨r, hr⟩ := exists_root_of_splits _ (splits_of_splits_of_dvd j hfn0 hj
(factor_dvd_of_nat_degree_ne_zero hndf))
(mt is_unit_iff_degree_eq_zero.2 f.irreducible_factor.1) in
have hmf0 : map (adjoin_root.of f.factor) f ≠ 0, from map_ne_zero hfn0,
have hsf : splits (adjoin_root.lift j r hr) f.remove_factor,
by { rw ← X_sub_C_mul_remove_factor _ hndf at hmf0, refine (splits_of_splits_mul _ hmf0 _).2,
rwa [X_sub_C_mul_remove_factor _ hndf, ← splits_id_iff_splits, map_map, adjoin_root.lift_comp_of,
splits_id_iff_splits] },
let ⟨k, hk⟩ := ih f.remove_factor (nat_degree_remove_factor' hf) (adjoin_root.lift j r hr) hsf in
⟨k, by rw [algebra_map_succ, ← ring_hom.comp_assoc, hk, adjoin_root.lift_comp_of]⟩
theorem adjoin_roots (n : ℕ) : ∀ {α : Type u} [field α], by exactI
∀ (f : polynomial α) (hfn : f.nat_degree = n),
algebra.adjoin α (↑(f.map $ algebra_map α $ splitting_field_aux n f hfn).roots.to_finset :
set (splitting_field_aux n f hfn)) = ⊤ :=
nat.rec_on n (λ α _ f hf, by exactI algebra.eq_top_iff.2 (λ x, subalgebra.range_le _ ⟨x, rfl⟩)) $
λ n ih α _ f hfn, by exactI
have hndf : f.nat_degree ≠ 0, by { intro h, rw h at hfn, cases hfn },
have hfn0 : f ≠ 0, by { intro h, rw h at hndf, exact hndf rfl },
have hmf0 : map (algebra_map α (splitting_field_aux n.succ f hfn)) f ≠ 0 := map_ne_zero hfn0,
by { rw [algebra_map_succ, ← map_map, ← X_sub_C_mul_remove_factor _ hndf, map_mul] at hmf0 ⊢,
rw [roots_mul hmf0, map_sub, map_X, map_C, roots_X_sub_C, multiset.to_finset_add, finset.coe_union,
multiset.to_finset_cons, multiset.to_finset_zero, insert_emptyc_eq, finset.coe_singleton,
algebra.adjoin_union, ← set.image_singleton, algebra.adjoin_algebra_map α (adjoin_root f.factor)
(splitting_field_aux n f.remove_factor (nat_degree_remove_factor' hfn)),
adjoin_root.adjoin_root_eq_top, algebra.map_top,
is_scalar_tower.range_under_adjoin α (adjoin_root f.factor)
(splitting_field_aux n f.remove_factor (nat_degree_remove_factor' hfn)),
ih, subalgebra.res_top] }
end splitting_field_aux
/-- A splitting field of a polynomial. -/
def splitting_field (f : polynomial α) :=
splitting_field_aux _ f rfl
namespace splitting_field
variables (f : polynomial α)
instance : field (splitting_field f) :=
splitting_field_aux.field _ _
instance inhabited : inhabited (splitting_field f) := ⟨37⟩
instance : algebra α (splitting_field f) :=
splitting_field_aux.algebra _ _
protected theorem splits : splits (algebra_map α (splitting_field f)) f :=
splitting_field_aux.splits _ _ _
variables [algebra α β] (hb : splits (algebra_map α β) f)
/-- Embeds the splitting field into any other field that splits the polynomial. -/
def lift : splitting_field f →ₐ[α] β :=
{ commutes' := λ r, by { have := classical.some_spec (splitting_field_aux.exists_lift _ _ _ _ hb),
exact ring_hom.ext_iff.1 this r },
.. classical.some (splitting_field_aux.exists_lift _ _ _ _ hb) }
theorem adjoin_roots : algebra.adjoin α
(↑(f.map (algebra_map α $ splitting_field f)).roots.to_finset : set (splitting_field f)) = ⊤ :=
splitting_field_aux.adjoin_roots _ _ _
theorem adjoin_root_set : algebra.adjoin α (f.root_set f.splitting_field) = ⊤ :=
adjoin_roots f
end splitting_field
variables (α β) [algebra α β]
/-- Typeclass characterising splitting fields. -/
class is_splitting_field (f : polynomial α) : Prop :=
(splits [] : splits (algebra_map α β) f)
(adjoin_roots [] : algebra.adjoin α (↑(f.map (algebra_map α β)).roots.to_finset : set β) = ⊤)
namespace is_splitting_field
variables {α}
instance splitting_field (f : polynomial α) : is_splitting_field α (splitting_field f) f :=
⟨splitting_field.splits f, splitting_field.adjoin_roots f⟩
section scalar_tower
variables {α β γ} [algebra β γ] [algebra α γ] [is_scalar_tower α β γ]
variables {α}
instance map (f : polynomial α) [is_splitting_field α γ f] :
is_splitting_field β γ (f.map $ algebra_map α β) :=
⟨by { rw [splits_map_iff, ← is_scalar_tower.algebra_map_eq], exact splits γ f },
subalgebra.res_inj α $ by { rw [map_map, ← is_scalar_tower.algebra_map_eq, subalgebra.res_top,
eq_top_iff, ← adjoin_roots γ f, algebra.adjoin_le_iff],
exact λ x hx, @algebra.subset_adjoin β _ _ _ _ _ _ hx }⟩
variables {α} (β)
theorem splits_iff (f : polynomial α) [is_splitting_field α β f] :
polynomial.splits (ring_hom.id α) f ↔ (⊤ : subalgebra α β) = ⊥ :=
⟨λ h, eq_bot_iff.2 $ adjoin_roots β f ▸ (roots_map (algebra_map α β) h).symm ▸
algebra.adjoin_le_iff.2 (λ y hy,
let ⟨x, hxs, hxy⟩ := finset.mem_image.1 (by rwa multiset.to_finset_map at hy) in
hxy ▸ subalgebra.algebra_map_mem _ _),
λ h, @ring_equiv.to_ring_hom_refl α _ ▸
ring_equiv.trans_symm (ring_equiv.of_bijective _ $ algebra.bijective_algebra_map_iff.2 h) ▸
by { rw ring_equiv.to_ring_hom_trans, exact splits_comp_of_splits _ _ (splits β f) }⟩
theorem mul (f g : polynomial α) (hf : f ≠ 0) (hg : g ≠ 0) [is_splitting_field α β f]
[is_splitting_field β γ (g.map $ algebra_map α β)] :
is_splitting_field α γ (f * g) :=
⟨(is_scalar_tower.algebra_map_eq α β γ).symm ▸ splits_mul _
(splits_comp_of_splits _ _ (splits β f))
((splits_map_iff _ _).1 (splits γ $ g.map $ algebra_map α β)),
by rw [map_mul, roots_mul (mul_ne_zero (map_ne_zero hf : f.map (algebra_map α γ) ≠ 0)
(map_ne_zero hg)), multiset.to_finset_add, finset.coe_union, algebra.adjoin_union,
is_scalar_tower.algebra_map_eq α β γ, ← map_map,
roots_map (algebra_map β γ) ((splits_id_iff_splits $ algebra_map α β).2 $ splits β f),
multiset.to_finset_map, finset.coe_image, algebra.adjoin_algebra_map, adjoin_roots,
algebra.map_top, is_scalar_tower.range_under_adjoin, ← map_map, adjoin_roots,
subalgebra.res_top]⟩
end scalar_tower
/-- Splitting field of `f` embeds into any field that splits `f`. -/
def lift [algebra α γ] (f : polynomial α) [is_splitting_field α β f]
(hf : polynomial.splits (algebra_map α γ) f) : β →ₐ[α] γ :=
if hf0 : f = 0 then (algebra.of_id α γ).comp $
(algebra.bot_equiv α β : (⊥ : subalgebra α β) →ₐ[α] α).comp $
by { rw ← (splits_iff β f).1 (show f.splits (ring_hom.id α), from hf0.symm ▸ splits_zero _),
exact algebra.to_top } else
alg_hom.comp (by { rw ← adjoin_roots β f, exact classical.choice (lift_of_splits _ $ λ y hy,
have aeval y f = 0, from (eval₂_eq_eval_map _).trans $
(mem_roots $ by exact map_ne_zero hf0).1 (multiset.mem_to_finset.mp hy),
⟨(is_algebraic_iff_is_integral _).1 ⟨f, hf0, this⟩,
splits_of_splits_of_dvd _ hf0 hf $ minpoly.dvd _ _ this⟩) })
algebra.to_top
theorem finite_dimensional (f : polynomial α) [is_splitting_field α β f] : finite_dimensional α β :=
finite_dimensional.iff_fg.2 $ @algebra.coe_top α β _ _ _ ▸ adjoin_roots β f ▸
fg_adjoin_of_finite (set.finite_mem_finset _) (λ y hy,
if hf : f = 0
then by { rw [hf, map_zero, roots_zero] at hy, cases hy }
else (is_algebraic_iff_is_integral _).1 ⟨f, hf, (eval₂_eq_eval_map _).trans $
(mem_roots $ by exact map_ne_zero hf).1 (multiset.mem_to_finset.mp hy)⟩)
instance (f : polynomial α) : _root_.finite_dimensional α f.splitting_field :=
finite_dimensional f.splitting_field f
/-- Any splitting field is isomorphic to `splitting_field f`. -/
def alg_equiv (f : polynomial α) [is_splitting_field α β f] : β ≃ₐ[α] splitting_field f :=
begin
refine alg_equiv.of_bijective (lift β f $ splits (splitting_field f) f)
⟨ring_hom.injective (lift β f $ splits (splitting_field f) f).to_ring_hom, _⟩,
haveI := finite_dimensional (splitting_field f) f,
haveI := finite_dimensional β f,
have : finite_dimensional.findim α β = finite_dimensional.findim α (splitting_field f) :=
le_antisymm
(linear_map.findim_le_findim_of_injective
(show function.injective (lift β f $ splits (splitting_field f) f).to_linear_map, from
ring_hom.injective (lift β f $ splits (splitting_field f) f : β →+* f.splitting_field)))
(linear_map.findim_le_findim_of_injective
(show function.injective (lift (splitting_field f) f $ splits β f).to_linear_map, from
ring_hom.injective (lift (splitting_field f) f $ splits β f : f.splitting_field →+* β))),
change function.surjective (lift β f $ splits (splitting_field f) f).to_linear_map,
refine (linear_map.injective_iff_surjective_of_findim_eq_findim this).1 _,
exact ring_hom.injective (lift β f $ splits (splitting_field f) f : β →+* f.splitting_field)
end
end is_splitting_field
end splitting_field
end polynomial
|
a3cbc43eac88f67688e34bac1cf9e5e04a71f1f2 | aa3f8992ef7806974bc1ffd468baa0c79f4d6643 | /tests/lean/run/coe3.lean | 0bb593bec3ad88147b62d68d2aae02b953398d2f | [
"Apache-2.0"
] | permissive | codyroux/lean | 7f8dff750722c5382bdd0a9a9275dc4bb2c58dd3 | 0cca265db19f7296531e339192e9b9bae4a31f8b | refs/heads/master | 1,610,909,964,159 | 1,407,084,399,000 | 1,416,857,075,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 747 | lean | import logic
namespace setoid
inductive setoid : Type :=
mk_setoid: Π (A : Type), (A → A → Prop) → setoid
definition carrier (s : setoid)
:= setoid.rec (λ a eq, a) s
definition eqv {s : setoid} : carrier s → carrier s → Prop
:= setoid.rec (λ a eqv, eqv) s
infix `≈` := eqv
coercion carrier
inductive morphism (s1 s2 : setoid) : Type :=
mk : Π (f : s1 → s2), (∀ x y, x ≈ y → f x ≈ f y) → morphism s1 s2
set_option pp.universes true
check morphism.mk
check λ (s1 s2 : setoid), s1
check λ (s1 s2 : Type), s1
inductive morphism2 (s1 : setoid) (s2 : setoid) : Type :=
mk : Π (f : s1 → s2), (∀ x y, x ≈ y → f x ≈ f y) → morphism2 s1 s2
check morphism2.mk
end setoid
|
388f253f7ba95ea4794599c17e5ad59799ad86a6 | 4d2583807a5ac6caaffd3d7a5f646d61ca85d532 | /src/geometry/manifold/partition_of_unity.lean | 8d2ce0e786ece250ad8baefe6b8615e2d31631a3 | [
"Apache-2.0"
] | permissive | AntoineChambert-Loir/mathlib | 64aabb896129885f12296a799818061bc90da1ff | 07be904260ab6e36a5769680b6012f03a4727134 | refs/heads/master | 1,693,187,631,771 | 1,636,719,886,000 | 1,636,719,886,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 18,961 | lean | /-
Copyright (c) 2021 Yury G. Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury G. Kudryashov
-/
import topology.paracompact
import topology.shrinking_lemma
import geometry.manifold.bump_function
import topology.partition_of_unity
/-!
# Smooth partition of unity
In this file we define two structures, `smooth_bump_covering` and `smooth_partition_of_unity`. Both
structures describe coverings of a set by a locally finite family of supports of smooth functions
with some additional properties. The former structure is mostly useful as an intermediate step in
the construction of a smooth partition of unity but some proofs that traditionally deal with a
partition of unity can use a `smooth_bump_covering` as well.
Given a real manifold `M` and its subset `s`, a `smooth_bump_covering ι I M s` is a collection of
`smooth_bump_function`s `f i` indexed by `i : ι` such that
* the center of each `f i` belongs to `s`;
* the family of sets `support (f i)` is locally finite;
* for each `x ∈ s`, there exists `i : ι` such that `f i =ᶠ[𝓝 x] 1`.
In the same settings, a `smooth_partition_of_unity ι I M s` is a collection of smooth nonnegative
functions `f i : C^∞⟮I, M; 𝓘(ℝ), ℝ⟯`, `i : ι`, such that
* the family of sets `support (f i)` is locally finite;
* for each `x ∈ s`, the sum `∑ᶠ i, f i x` equals one;
* for each `x`, the sum `∑ᶠ i, f i x` is less than or equal to one.
We say that `f : smooth_bump_covering ι I M s` is *subordinate* to a map `U : M → set M` if for each
index `i`, we have `closure (support (f i)) ⊆ U (f i).c`. This notion is a bit more general than
being subordinate to an open covering of `M`, because we make no assumption about the way `U x`
depends on `x`.
We prove that on a smooth finitely dimensional real manifold with `σ`-compact Hausdorff topology,
for any `U : M → set M` such that `∀ x ∈ s, U x ∈ 𝓝 x` there exists a `smooth_bump_covering ι I M s`
subordinate to `U`. Then we use this fact to prove a similar statement about smooth partitions of
unity.
## Implementation notes
## TODO
* Build a framework for to transfer local definitions to global using partition of unity and use it
to define, e.g., the integral of a differential form over a manifold.
## Tags
smooth bump function, partition of unity
-/
universes uι uE uH uM
open function filter finite_dimensional set
open_locale topological_space manifold classical filter big_operators
noncomputable theory
variables {ι : Type uι}
{E : Type uE} [normed_group E] [normed_space ℝ E] [finite_dimensional ℝ E]
{H : Type uH} [topological_space H] (I : model_with_corners ℝ E H)
{M : Type uM} [topological_space M] [charted_space H M] [smooth_manifold_with_corners I M]
/-!
### Covering by supports of smooth bump functions
In this section we define `smooth_bump_covering ι I M s` to be a collection of
`smooth_bump_function`s such that their supports is a locally finite family of sets and for each `x
∈ s` some function `f i` from the collection is equal to `1` in a neighborhood of `x`. A covering of
this type is useful to construct a smooth partition of unity and can be used instead of a partition
of unity in some proofs.
We prove that on a smooth finite dimensional real manifold with `σ`-compact Hausdorff topology, for
any `U : M → set M` such that `∀ x ∈ s, U x ∈ 𝓝 x` there exists a `smooth_bump_covering ι I M s`
subordinate to `U`. Then we use this fact to prove a version of the Whitney embedding theorem: any
compact real manifold can be embedded into `ℝ^n` for large enough `n`. -/
variables (ι M)
/-- We say that a collection of `smooth_bump_function`s is a `smooth_bump_covering` of a set `s` if
* `(f i).c ∈ s` for all `i`;
* the family `λ i, support (f i)` is locally finite;
* for each point `x ∈ s` there exists `i` such that `f i =ᶠ[𝓝 x] 1`;
in other words, `x` belongs to the interior of `{y | f i y = 1}`;
If `M` is a finite dimensional real manifold which is a sigma-compact Hausdorff topological space,
then for every covering `U : M → set M`, `∀ x, U x ∈ 𝓝 x`, there exists a `smooth_bump_covering`
subordinate to `U`, see `smooth_bump_covering.exists_is_subordinate`.
This covering can be used, e.g., to construct a partition of unity and to prove the weak
Whitney embedding theorem. -/
@[nolint has_inhabited_instance]
structure smooth_bump_covering (s : set M := univ) :=
(c : ι → M)
(to_fun : Π i, smooth_bump_function I (c i))
(c_mem' : ∀ i, c i ∈ s)
(locally_finite' : locally_finite (λ i, support (to_fun i)))
(eventually_eq_one' : ∀ x ∈ s, ∃ i, to_fun i =ᶠ[𝓝 x] 1)
/-- We say that that a collection of functions form a smooth partition of unity on a set `s` if
* all functions are infinitely smooth and nonnegative;
* the family `λ i, support (f i)` is locally finite;
* for all `x ∈ s` the sum `∑ᶠ i, f i x` equals one;
* for all `x`, the sum `∑ᶠ i, f i x` is less than or equal to one. -/
structure smooth_partition_of_unity (s : set M := univ) :=
(to_fun : ι → C^∞⟮I, M; 𝓘(ℝ), ℝ⟯)
(locally_finite' : locally_finite (λ i, support (to_fun i)))
(nonneg' : ∀ i x, 0 ≤ to_fun i x)
(sum_eq_one' : ∀ x ∈ s, ∑ᶠ i, to_fun i x = 1)
(sum_le_one' : ∀ x, ∑ᶠ i, to_fun i x ≤ 1)
variables {ι I M}
namespace smooth_partition_of_unity
variables {s : set M} (f : smooth_partition_of_unity ι I M s)
instance {s : set M} : has_coe_to_fun (smooth_partition_of_unity ι I M s)
(λ _, ι → C^∞⟮I, M; 𝓘(ℝ), ℝ⟯) :=
⟨smooth_partition_of_unity.to_fun⟩
protected lemma locally_finite : locally_finite (λ i, support (f i)) :=
f.locally_finite'
lemma nonneg (i : ι) (x : M) : 0 ≤ f i x := f.nonneg' i x
lemma sum_eq_one {x} (hx : x ∈ s) : ∑ᶠ i, f i x = 1 := f.sum_eq_one' x hx
lemma sum_le_one (x : M) : ∑ᶠ i, f i x ≤ 1 := f.sum_le_one' x
/-- Reinterpret a smooth partition of unity as a continuous partition of unity. -/
def to_partition_of_unity : partition_of_unity ι M s :=
{ to_fun := λ i, f i, .. f }
lemma smooth_sum : smooth I 𝓘(ℝ) (λ x, ∑ᶠ i, f i x) :=
smooth_finsum (λ i, (f i).smooth) f.locally_finite
lemma le_one (i : ι) (x : M) : f i x ≤ 1 := f.to_partition_of_unity.le_one i x
lemma sum_nonneg (x : M) : 0 ≤ ∑ᶠ i, f i x := f.to_partition_of_unity.sum_nonneg x
/-- A smooth 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 is_subordinate (f : smooth_partition_of_unity ι I M s) (U : ι → set M) :=
∀ i, closure (support (f i)) ⊆ U i
@[simp] lemma is_subordinate_to_partition_of_unity {f : smooth_partition_of_unity ι I M s}
{U : ι → set M} :
f.to_partition_of_unity.is_subordinate U ↔ f.is_subordinate U :=
iff.rfl
alias is_subordinate_to_partition_of_unity ↔
_ smooth_partition_of_unity.is_subordinate.to_partition_of_unity
end smooth_partition_of_unity
namespace bump_covering
-- Repeat variables to drop [finite_dimensional ℝ E] and [smooth_manifold_with_corners I M]
lemma smooth_to_partition_of_unity {E : Type uE} [normed_group E] [normed_space ℝ E]
{H : Type uH} [topological_space H] {I : model_with_corners ℝ E H}
{M : Type uM} [topological_space M] [charted_space H M] {s : set M}
(f : bump_covering ι M s) (hf : ∀ i, smooth I 𝓘(ℝ) (f i)) (i : ι) :
smooth I 𝓘(ℝ) (f.to_partition_of_unity i) :=
(hf i).mul $ smooth_finprod_cond (λ j _, smooth_const.sub (hf j)) $
by { simp only [mul_support_one_sub], exact f.locally_finite }
variables {s : set M}
/-- A `bump_covering` such that all functions in this covering are smooth generates a smooth
partition of unity.
In our formalization, not every `f : bump_covering ι M s` with smooth functions `f i` is a
`smooth_bump_covering`; instead, a `smooth_bump_covering` is a covering by supports of
`smooth_bump_function`s. So, we define `bump_covering.to_smooth_partition_of_unity`, then reuse it
in `smooth_bump_covering.to_smooth_partition_of_unity`. -/
def to_smooth_partition_of_unity (f : bump_covering ι M s) (hf : ∀ i, smooth I 𝓘(ℝ) (f i)) :
smooth_partition_of_unity ι I M s :=
{ to_fun := λ i, ⟨f.to_partition_of_unity i, f.smooth_to_partition_of_unity hf i⟩,
.. f.to_partition_of_unity }
@[simp] lemma to_smooth_partition_of_unity_to_partition_of_unity (f : bump_covering ι M s)
(hf : ∀ i, smooth I 𝓘(ℝ) (f i)) :
(f.to_smooth_partition_of_unity hf).to_partition_of_unity = f.to_partition_of_unity :=
rfl
@[simp] lemma coe_to_smooth_partition_of_unity (f : bump_covering ι M s)
(hf : ∀ i, smooth I 𝓘(ℝ) (f i)) (i : ι) :
⇑(f.to_smooth_partition_of_unity hf i) = f.to_partition_of_unity i :=
rfl
lemma is_subordinate.to_smooth_partition_of_unity {f : bump_covering ι M s}
{U : ι → set M} (h : f.is_subordinate U) (hf : ∀ i, smooth I 𝓘(ℝ) (f i)) :
(f.to_smooth_partition_of_unity hf).is_subordinate U :=
h.to_partition_of_unity
end bump_covering
namespace smooth_bump_covering
variables {s : set M} {U : M → set M} (fs : smooth_bump_covering ι I M s) {I}
instance : has_coe_to_fun (smooth_bump_covering ι I M s)
(λ x, Π (i : ι), smooth_bump_function I (x.c i)) :=
⟨to_fun⟩
@[simp] lemma coe_mk (c : ι → M) (to_fun : Π i, smooth_bump_function I (c i))
(h₁ h₂ h₃) : ⇑(mk c to_fun h₁ h₂ h₃ : smooth_bump_covering ι I M s) = to_fun :=
rfl
/--
We say that `f : smooth_bump_covering ι I M s` is *subordinate* to a map `U : M → set M` if for each
index `i`, we have `closure (support (f i)) ⊆ U (f i).c`. This notion is a bit more general than
being subordinate to an open covering of `M`, because we make no assumption about the way `U x`
depends on `x`.
-/
def is_subordinate {s : set M} (f : smooth_bump_covering ι I M s) (U : M → set M) :=
∀ i, closure (support $ f i) ⊆ U (f.c i)
lemma is_subordinate.support_subset {fs : smooth_bump_covering ι I M s} {U : M → set M}
(h : fs.is_subordinate U) (i : ι) :
support (fs i) ⊆ U (fs.c i) :=
subset.trans subset_closure (h i)
variable (I)
/-- Let `M` be a smooth manifold with corners modelled on a finite dimensional real vector space.
Suppose also that `M` is a Hausdorff `σ`-compact topological space. Let `s` be a closed set
in `M` and `U : M → set M` be a collection of sets such that `U x ∈ 𝓝 x` for every `x ∈ s`.
Then there exists a smooth bump covering of `s` that is subordinate to `U`. -/
lemma exists_is_subordinate [t2_space M] [sigma_compact_space M] (hs : is_closed s)
(hU : ∀ x ∈ s, U x ∈ 𝓝 x) :
∃ (ι : Type uM) (f : smooth_bump_covering ι I M s), f.is_subordinate U :=
begin
-- First we deduce some missing instances
haveI : locally_compact_space H := I.locally_compact,
haveI : locally_compact_space M := charted_space.locally_compact H,
haveI : normal_space M := normal_of_paracompact_t2,
-- Next we choose a covering by supports of smooth bump functions
have hB := λ x hx, smooth_bump_function.nhds_basis_support I (hU x hx),
rcases refinement_of_locally_compact_sigma_compact_of_nhds_basis_set hs hB
with ⟨ι, c, f, hf, hsub', hfin⟩, choose hcs hfU using hf,
/- Then we use the shrinking lemma to get a covering by smaller open -/
rcases exists_subset_Union_closed_subset hs (λ i, (f i).open_support)
(λ x hx, hfin.point_finite x) hsub' with ⟨V, hsV, hVc, hVf⟩,
choose r hrR hr using λ i, (f i).exists_r_pos_lt_subset_ball (hVc i) (hVf i),
refine ⟨ι, ⟨c, λ i, (f i).update_r (r i) (hrR i), hcs, _, λ x hx, _⟩, λ i, _⟩,
{ simpa only [smooth_bump_function.support_update_r] },
{ refine (mem_Union.1 $ hsV hx).imp (λ i hi, _),
exact ((f i).update_r _ _).eventually_eq_one_of_dist_lt
((f i).support_subset_source $ hVf _ hi) (hr i hi).2 },
{ simpa only [coe_mk, smooth_bump_function.support_update_r] using hfU i }
end
variables {I M}
protected lemma locally_finite : locally_finite (λ i, support (fs i)) := fs.locally_finite'
protected lemma point_finite (x : M) : {i | fs i x ≠ 0}.finite :=
fs.locally_finite.point_finite x
lemma mem_chart_at_source_of_eq_one {i : ι} {x : M} (h : fs i x = 1) :
x ∈ (chart_at H (fs.c i)).source :=
(fs i).support_subset_source $ by simp [h]
lemma mem_ext_chart_at_source_of_eq_one {i : ι} {x : M} (h : fs i x = 1) :
x ∈ (ext_chart_at I (fs.c i)).source :=
by { rw ext_chart_at_source, exact fs.mem_chart_at_source_of_eq_one h }
/-- Index of a bump function such that `fs i =ᶠ[𝓝 x] 1`. -/
def ind (x : M) (hx : x ∈ s) : ι := (fs.eventually_eq_one' x hx).some
lemma eventually_eq_one (x : M) (hx : x ∈ s) : fs (fs.ind x hx) =ᶠ[𝓝 x] 1 :=
(fs.eventually_eq_one' x hx).some_spec
lemma apply_ind (x : M) (hx : x ∈ s) : fs (fs.ind x hx) x = 1 :=
(fs.eventually_eq_one x hx).eq_of_nhds
lemma mem_support_ind (x : M) (hx : x ∈ s) : x ∈ support (fs $ fs.ind x hx) :=
by simp [fs.apply_ind x hx]
lemma mem_chart_at_ind_source (x : M) (hx : x ∈ s) :
x ∈ (chart_at H (fs.c (fs.ind x hx))).source :=
fs.mem_chart_at_source_of_eq_one (fs.apply_ind x hx)
lemma mem_ext_chart_at_ind_source (x : M) (hx : x ∈ s) :
x ∈ (ext_chart_at I (fs.c (fs.ind x hx))).source :=
fs.mem_ext_chart_at_source_of_eq_one (fs.apply_ind x hx)
/-- The index type of a `smooth_bump_covering` of a compact manifold is finite. -/
protected def fintype [compact_space M] : fintype ι :=
fs.locally_finite.fintype_of_compact $ λ i, (fs i).nonempty_support
variable [t2_space M]
/-- Reinterpret a `smooth_bump_covering` as a continuous `bump_covering`. Note that not every
`f : bump_covering ι M s` with smooth functions `f i` is a `smooth_bump_covering`. -/
def to_bump_covering : bump_covering ι M s :=
{ to_fun := λ i, ⟨fs i, (fs i).continuous⟩,
locally_finite' := fs.locally_finite,
nonneg' := λ i x, (fs i).nonneg,
le_one' := λ i x, (fs i).le_one,
eventually_eq_one' := fs.eventually_eq_one' }
@[simp] lemma is_subordinate_to_bump_covering {f : smooth_bump_covering ι I M s} {U : M → set M} :
f.to_bump_covering.is_subordinate (λ i, U (f.c i)) ↔ f.is_subordinate U :=
iff.rfl
alias is_subordinate_to_bump_covering ↔
_ smooth_bump_covering.is_subordinate.to_bump_covering
/-- Every `smooth_bump_covering` defines a smooth partition of unity. -/
def to_smooth_partition_of_unity : smooth_partition_of_unity ι I M s :=
fs.to_bump_covering.to_smooth_partition_of_unity (λ i, (fs i).smooth)
lemma to_smooth_partition_of_unity_apply (i : ι) (x : M) :
fs.to_smooth_partition_of_unity i x = fs i x * ∏ᶠ j (hj : well_ordering_rel j i), (1 - fs j x) :=
rfl
lemma to_smooth_partition_of_unity_eq_mul_prod (i : ι) (x : M) (t : finset ι)
(ht : ∀ j, well_ordering_rel j i → fs j x ≠ 0 → j ∈ t) :
fs.to_smooth_partition_of_unity i x =
fs i x * ∏ j in t.filter (λ j, well_ordering_rel j i), (1 - fs j x) :=
fs.to_bump_covering.to_partition_of_unity_eq_mul_prod i x t ht
lemma exists_finset_to_smooth_partition_of_unity_eventually_eq (i : ι) (x : M) :
∃ t : finset ι, fs.to_smooth_partition_of_unity i =ᶠ[𝓝 x]
fs i * ∏ j in t.filter (λ j, well_ordering_rel j i), (1 - fs j) :=
fs.to_bump_covering.exists_finset_to_partition_of_unity_eventually_eq i x
lemma to_smooth_partition_of_unity_zero_of_zero {i : ι} {x : M} (h : fs i x = 0) :
fs.to_smooth_partition_of_unity i x = 0 :=
fs.to_bump_covering.to_partition_of_unity_zero_of_zero h
lemma support_to_smooth_partition_of_unity_subset (i : ι) :
support (fs.to_smooth_partition_of_unity i) ⊆ support (fs i) :=
fs.to_bump_covering.support_to_partition_of_unity_subset i
lemma is_subordinate.to_smooth_partition_of_unity {f : smooth_bump_covering ι I M s} {U : M → set M}
(h : f.is_subordinate U) :
f.to_smooth_partition_of_unity.is_subordinate (λ i, U (f.c i)) :=
h.to_bump_covering.to_partition_of_unity
lemma sum_to_smooth_partition_of_unity_eq (x : M) :
∑ᶠ i, fs.to_smooth_partition_of_unity i x = 1 - ∏ᶠ i, (1 - fs i x) :=
fs.to_bump_covering.sum_to_partition_of_unity_eq x
end smooth_bump_covering
variable (I)
/-- Given two disjoint closed sets in a Hausdorff σ-compact finite dimensional manifold, there
exists an infinitely smooth function that is equal to `0` on one of them and is equal to one on the
other. -/
lemma exists_smooth_zero_one_of_closed [t2_space M] [sigma_compact_space M] {s t : set M}
(hs : is_closed s) (ht : is_closed t) (hd : disjoint s t) :
∃ f : C^∞⟮I, M; 𝓘(ℝ), ℝ⟯, eq_on f 0 s ∧ eq_on f 1 t ∧ ∀ x, f x ∈ Icc (0 : ℝ) 1 :=
begin
have : ∀ x ∈ t, sᶜ ∈ 𝓝 x, from λ x hx, hs.is_open_compl.mem_nhds (disjoint_right.1 hd hx),
rcases smooth_bump_covering.exists_is_subordinate I ht this with ⟨ι, f, hf⟩,
set g := f.to_smooth_partition_of_unity,
refine ⟨⟨_, g.smooth_sum⟩, λ x hx, _, λ x, g.sum_eq_one, λ x, ⟨g.sum_nonneg x, g.sum_le_one x⟩⟩,
suffices : ∀ i, g i x = 0,
by simp only [this, times_cont_mdiff_map.coe_fn_mk, finsum_zero, pi.zero_apply],
refine λ i, f.to_smooth_partition_of_unity_zero_of_zero _,
exact nmem_support.1 (subset_compl_comm.1 (hf.support_subset i) hx)
end
variable {I}
namespace smooth_partition_of_unity
/-- A `smooth_partition_of_unity` that consists of a single function, uniformly equal to one,
defined as an example for `inhabited` instance. -/
def single (i : ι) (s : set M) : smooth_partition_of_unity ι I M s :=
(bump_covering.single i s).to_smooth_partition_of_unity $ λ j,
begin
rcases eq_or_ne j i with rfl|h,
{ simp only [smooth_one, continuous_map.coe_one, bump_covering.coe_single, pi.single_eq_same] },
{ simp only [smooth_zero, bump_covering.coe_single, pi.single_eq_of_ne h,
continuous_map.coe_zero] }
end
instance [inhabited ι] (s : set M) : inhabited (smooth_partition_of_unity ι I M s) :=
⟨single (default ι) s⟩
variables [t2_space M] [sigma_compact_space M]
/-- If `X` is a paracompact normal topological space and `U` is an open covering of a closed set
`s`, then there exists a `bump_covering ι X s` that is subordinate to `U`. -/
lemma exists_is_subordinate {s : set M} (hs : is_closed s) (U : ι → set M) (ho : ∀ i, is_open (U i))
(hU : s ⊆ ⋃ i, U i) :
∃ f : smooth_partition_of_unity ι I M s, f.is_subordinate U :=
begin
haveI : locally_compact_space H := I.locally_compact,
haveI : locally_compact_space M := charted_space.locally_compact H,
haveI : normal_space M := normal_of_paracompact_t2,
rcases bump_covering.exists_is_subordinate_of_prop (smooth I 𝓘(ℝ)) _ hs U ho hU
with ⟨f, hf, hfU⟩,
{ exact ⟨f.to_smooth_partition_of_unity hf, hfU.to_smooth_partition_of_unity hf⟩ },
{ intros s t hs ht hd,
rcases exists_smooth_zero_one_of_closed I hs ht hd with ⟨f, hf⟩,
exact ⟨f, f.smooth, hf⟩ }
end
end smooth_partition_of_unity
|
d798dafda0f8473fb692068dad56cd4692777dbd | fa02ed5a3c9c0adee3c26887a16855e7841c668b | /src/combinatorics/simple_graph/adj_matrix.lean | 1fa7608a63dbab3a5dbd36ff832850f10fe4d6c0 | [
"Apache-2.0"
] | permissive | jjgarzella/mathlib | 96a345378c4e0bf26cf604aed84f90329e4896a2 | 395d8716c3ad03747059d482090e2bb97db612c8 | refs/heads/master | 1,686,480,124,379 | 1,625,163,323,000 | 1,625,163,323,000 | 281,190,421 | 2 | 0 | Apache-2.0 | 1,595,268,170,000 | 1,595,268,169,000 | null | UTF-8 | Lean | false | false | 3,167 | lean | /-
Copyright (c) 2020 Aaron Anderson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Aaron Anderson, Jalex Stark
-/
import combinatorics.simple_graph.basic
import data.rel
import linear_algebra.matrix.trace
/-!
# Adjacency Matrices
This module defines the adjacency matrix of a graph, and provides theorems connecting graph
properties to computational properties of the matrix.
## Main definitions
* `adj_matrix` is the adjacency matrix of a `simple_graph` with coefficients in a given semiring.
-/
open_locale big_operators matrix
open finset matrix simple_graph
universes u v
variables {α : Type u} [fintype α]
variables (R : Type v) [semiring R]
namespace simple_graph
variables (G : simple_graph α) (R) [decidable_rel G.adj]
/-- `adj_matrix G R` is the matrix `A` such that `A i j = (1 : R)` if `i` and `j` are
adjacent in the simple graph `G`, and otherwise `A i j = 0`. -/
def adj_matrix : matrix α α R
| i j := if (G.adj i j) then 1 else 0
variable {R}
@[simp]
lemma adj_matrix_apply (v w : α) : G.adj_matrix R v w = if (G.adj v w) then 1 else 0 := rfl
@[simp]
theorem transpose_adj_matrix : (G.adj_matrix R)ᵀ = G.adj_matrix R :=
by { ext, simp [edge_symm] }
@[simp]
lemma adj_matrix_dot_product (v : α) (vec : α → R) :
dot_product (G.adj_matrix R v) vec = ∑ u in G.neighbor_finset v, vec u :=
by simp [neighbor_finset_eq_filter, dot_product, sum_filter]
@[simp]
lemma dot_product_adj_matrix (v : α) (vec : α → R) :
dot_product vec (G.adj_matrix R v) = ∑ u in G.neighbor_finset v, vec u :=
by simp [neighbor_finset_eq_filter, dot_product, sum_filter, finset.sum_apply]
@[simp]
lemma adj_matrix_mul_vec_apply (v : α) (vec : α → R) :
((G.adj_matrix R).mul_vec vec) v = ∑ u in G.neighbor_finset v, vec u :=
by rw [mul_vec, adj_matrix_dot_product]
@[simp]
lemma adj_matrix_vec_mul_apply (v : α) (vec : α → R) :
((G.adj_matrix R).vec_mul vec) v = ∑ u in G.neighbor_finset v, vec u :=
begin
rw [← dot_product_adj_matrix, vec_mul],
refine congr rfl _, ext,
rw [← transpose_apply (adj_matrix R G) x v, transpose_adj_matrix],
end
@[simp]
lemma adj_matrix_mul_apply (M : matrix α α R) (v w : α) :
(G.adj_matrix R ⬝ M) v w = ∑ u in G.neighbor_finset v, M u w :=
by simp [mul_apply, neighbor_finset_eq_filter, sum_filter]
@[simp]
lemma mul_adj_matrix_apply (M : matrix α α R) (v w : α) :
(M ⬝ G.adj_matrix R) v w = ∑ u in G.neighbor_finset w, M v u :=
by simp [mul_apply, neighbor_finset_eq_filter, sum_filter, edge_symm]
variable (R)
theorem trace_adj_matrix : matrix.trace α R R (G.adj_matrix R) = 0 := by simp
variable {R}
theorem adj_matrix_mul_self_apply_self (i : α) :
((G.adj_matrix R) ⬝ (G.adj_matrix R)) i i = degree G i :=
by simp [degree]
variable {G}
@[simp]
lemma adj_matrix_mul_vec_const_apply {r : R} {v : α} :
(G.adj_matrix R).mul_vec (function.const _ r) v = G.degree v * r :=
by simp [degree]
lemma adj_matrix_mul_vec_const_apply_of_regular {d : ℕ} {r : R} (hd : G.is_regular_of_degree d)
{v : α} :
(G.adj_matrix R).mul_vec (function.const _ r) v = (d * r) :=
by simp [hd v]
end simple_graph
|
537f80663ae3f7aee0b72cb02e492ba5b1075478 | 957a80ea22c5abb4f4670b250d55534d9db99108 | /tests/lean/run/eqn_compiler_perf_issue2.lean | c20f4ecdfaab1c0224cafa51c62bf7a1705024d0 | [
"Apache-2.0"
] | permissive | GaloisInc/lean | aa1e64d604051e602fcf4610061314b9a37ab8cd | f1ec117a24459b59c6ff9e56a1d09d9e9e60a6c0 | refs/heads/master | 1,592,202,909,807 | 1,504,624,387,000 | 1,504,624,387,000 | 75,319,626 | 2 | 1 | Apache-2.0 | 1,539,290,164,000 | 1,480,616,104,000 | C++ | UTF-8 | Lean | false | false | 138 | lean | def expensive (n : ℕ) : ℕ := 100000000000000 - 100000000000000
def foo : ℕ → ℕ | n :=
expensive n
#print foo
#print foo._main
|
3fe8a658d5b4c0349c9da3bf5869f0812226e87f | 94e33a31faa76775069b071adea97e86e218a8ee | /src/linear_algebra/unitary_group.lean | c699d2b41f89c7b192955b4c3e25fa67ccd93df4 | [
"Apache-2.0"
] | permissive | urkud/mathlib | eab80095e1b9f1513bfb7f25b4fa82fa4fd02989 | 6379d39e6b5b279df9715f8011369a301b634e41 | refs/heads/master | 1,658,425,342,662 | 1,658,078,703,000 | 1,658,078,703,000 | 186,910,338 | 0 | 0 | Apache-2.0 | 1,568,512,083,000 | 1,557,958,709,000 | Lean | UTF-8 | Lean | false | false | 5,405 | lean | /-
Copyright (c) 2021 Shing Tak Lam. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Shing Tak Lam
-/
import linear_algebra.matrix.to_lin
import linear_algebra.matrix.nonsingular_inverse
import algebra.star.unitary
/-!
# The Unitary Group
This file defines elements of the unitary group `unitary_group n α`, where `α` is a `star_ring`.
This consists of all `n` by `n` matrices with entries in `α` such that the star-transpose is its
inverse. In addition, we define the group structure on `unitary_group n α`, and the embedding into
the general linear group `general_linear_group α (n → α)`.
We also define the orthogonal group `orthogonal_group n β`, where `β` is a `comm_ring`.
## Main Definitions
* `matrix.unitary_group` is the type of matrices where the star-transpose is the inverse
* `matrix.unitary_group.group` is the group structure (under multiplication)
* `matrix.unitary_group.embedding_GL` is the embedding `unitary_group n α → GLₙ(α)`
* `matrix.orthogonal_group` is the type of matrices where the transpose is the inverse
## References
* https://en.wikipedia.org/wiki/Unitary_group
## Tags
matrix group, group, unitary group, orthogonal group
-/
universes u v
namespace matrix
open linear_map
open_locale matrix
section
variables (n : Type u) [decidable_eq n] [fintype n]
variables (α : Type v) [comm_ring α] [star_ring α]
/--
`unitary_group n` is the group of `n` by `n` matrices where the star-transpose is the inverse.
-/
abbreviation unitary_group := unitary (matrix n n α)
end
variables {n : Type u} [decidable_eq n] [fintype n]
variables {α : Type v} [comm_ring α] [star_ring α]
lemma mem_unitary_group_iff {A : matrix n n α} :
A ∈ matrix.unitary_group n α ↔ A * star A = 1 :=
begin
refine ⟨and.right, λ hA, ⟨_, hA⟩⟩,
simpa only [matrix.mul_eq_mul, matrix.mul_eq_one_comm] using hA
end
namespace unitary_group
instance coe_matrix : has_coe (unitary_group n α) (matrix n n α) := ⟨subtype.val⟩
instance coe_fun : has_coe_to_fun (unitary_group n α) (λ _, n → n → α) :=
{ coe := λ A, A.val }
/--
`to_lin' A` is matrix multiplication of vectors by `A`, as a linear map.
After the group structure on `unitary_group n` is defined,
we show in `to_linear_equiv` that this gives a linear equivalence.
-/
def to_lin' (A : unitary_group n α) := matrix.to_lin' A
lemma ext_iff (A B : unitary_group n α) : A = B ↔ ∀ i j, A i j = B i j :=
subtype.ext_iff_val.trans ⟨(λ h i j, congr_fun (congr_fun h i) j), matrix.ext⟩
@[ext] lemma ext (A B : unitary_group n α) : (∀ i j, A i j = B i j) → A = B :=
(unitary_group.ext_iff A B).mpr
@[simp]
lemma star_mul_self (A : unitary_group n α) : star A ⬝ A = 1 := A.2.1
section coe_lemmas
variables (A B : unitary_group n α)
@[simp] lemma inv_val : ↑(A⁻¹) = (star A : matrix n n α) := rfl
@[simp] lemma inv_apply : ⇑(A⁻¹) = (star A : matrix n n α) := rfl
@[simp] lemma mul_val : ↑(A * B) = A ⬝ B := rfl
@[simp] lemma mul_apply : ⇑(A * B) = (A ⬝ B) := rfl
@[simp] lemma one_val : ↑(1 : unitary_group n α) = (1 : matrix n n α) := rfl
@[simp] lemma one_apply : ⇑(1 : unitary_group n α) = (1 : matrix n n α) := rfl
@[simp] lemma to_lin'_mul :
to_lin' (A * B) = (to_lin' A).comp (to_lin' B) :=
matrix.to_lin'_mul A B
@[simp] lemma to_lin'_one :
to_lin' (1 : unitary_group n α) = linear_map.id :=
matrix.to_lin'_one
end coe_lemmas
/-- `to_linear_equiv A` is matrix multiplication of vectors by `A`, as a linear equivalence. -/
def to_linear_equiv (A : unitary_group n α) : (n → α) ≃ₗ[α] (n → α) :=
{ inv_fun := to_lin' A⁻¹,
left_inv := λ x, calc
(to_lin' A⁻¹).comp (to_lin' A) x
= (to_lin' (A⁻¹ * A)) x : by rw [←to_lin'_mul]
... = x : by rw [mul_left_inv, to_lin'_one, id_apply],
right_inv := λ x, calc
(to_lin' A).comp (to_lin' A⁻¹) x
= to_lin' (A * A⁻¹) x : by rw [←to_lin'_mul]
... = x : by rw [mul_right_inv, to_lin'_one, id_apply],
..matrix.to_lin' A }
/-- `to_GL` is the map from the unitary group to the general linear group -/
def to_GL (A : unitary_group n α) : general_linear_group α (n → α) :=
general_linear_group.of_linear_equiv (to_linear_equiv A)
lemma coe_to_GL (A : unitary_group n α) :
↑(to_GL A) = to_lin' A :=
rfl
@[simp]
lemma to_GL_one : to_GL (1 : unitary_group n α) = 1 :=
by { ext1 v i, rw [coe_to_GL, to_lin'_one], refl }
@[simp]
lemma to_GL_mul (A B : unitary_group n α) :
to_GL (A * B) = to_GL A * to_GL B :=
by { ext1 v i, rw [coe_to_GL, to_lin'_mul], refl }
/-- `unitary_group.embedding_GL` is the embedding from `unitary_group n α`
to `general_linear_group n α`. -/
def embedding_GL : unitary_group n α →* general_linear_group α (n → α) :=
⟨λ A, to_GL A, by simp, by simp⟩
end unitary_group
section orthogonal_group
variables (n) (β : Type v) [comm_ring β]
local attribute [instance] star_ring_of_comm
/--
`orthogonal_group n` is the group of `n` by `n` matrices where the transpose is the inverse.
-/
abbreviation orthogonal_group := unitary_group n β
lemma mem_orthogonal_group_iff {A : matrix n n β} :
A ∈ matrix.orthogonal_group n β ↔ A * star A = 1 :=
begin
refine ⟨and.right, λ hA, ⟨_, hA⟩⟩,
simpa only [matrix.mul_eq_mul, matrix.mul_eq_one_comm] using hA
end
end orthogonal_group
end matrix
|
30fd94ff5538c8e7c5e9e3014aa45bc28e145bda | c5b07d17b3c9fb19e4b302465d237fd1d988c14f | /src/isos/zero.lean | 4815f4eee5b6d95cc09eb94f720a953dda52dce4 | [
"MIT"
] | permissive | skaslev/papers | acaec61602b28c33d6115e53913b2002136aa29b | f15b379f3c43bbd0a37ac7bb75f4278f7e901389 | refs/heads/master | 1,665,505,770,318 | 1,660,378,602,000 | 1,660,378,602,000 | 14,101,547 | 0 | 1 | MIT | 1,595,414,522,000 | 1,383,542,702,000 | Lean | UTF-8 | Lean | false | false | 435 | lean | import functors.generating
namespace zero
-- 0 = Σ n:ℕ, cₙ xⁿ
-- cₙ = {0, 0, 0, 0, 0, ...}
def ogf_iso {A} : 0 ≃ ogf (const 0) A :=
⟨λ x, pempty.rec _ x, λ x, begin
have z : fin 0 := x.2.1,
apply fin.elim0 z
end, --λ x, fin.elim0 x.2.1,
λ x, pempty.rec _ x, λ x, begin
have z : fin 0 := x.2.1,
apply fin.elim0 z
end⟩ --λ x, fin.elim0 x.2.1⟩
instance : has_ogf₁ 0 :=
⟨const 0, ogf_iso⟩
end zero
|
4504acd84c1543deb3fb01dfe3117ae5f491c235 | d7189ea2ef694124821b033e533f18905b5e87ef | /galois/calendar_time.lean | c803400dad2fee8ce7161851d2d0527aa8a48d04 | [
"Apache-2.0"
] | permissive | digama0/lean-protocol-support | eaa7e6f8b8e0d5bbfff1f7f52bfb79a3b11b0f59 | cabfa3abedbdd6fdca6e2da6fbbf91a13ed48dda | refs/heads/master | 1,625,421,450,627 | 1,506,035,462,000 | 1,506,035,462,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 3,662 | lean | /-
Copyright (c) 2017 Galois Inc. All rights reserved.
Author: Joe Hendrix
This module defines a datatype "calendar_time" for representing
Gregorian calendar times, and operations for converting from Unix
time and printing to ISO8601 time.
-/
import galois.list
-- This represents a Gregorian calendar time.
structure calendar_time :=
(year : ℕ)
(month : fin 12)
(day : ℕ)
(hour : ℕ)
(minute : ℕ)
(second : ℕ)
namespace calendar_time
def month_names : list string :=
[ "January", "February", "March", "April", "May", "June"
, "July", "August", "September", "October", "November", "December"
]
def pp_2d (x : ℕ) : string :=
if x < 10 then
"0" ++ to_string x
else
to_string x
def pp_4d (x : ℕ) : string :=
if x < 10 then
"000" ++ to_string x
else if x < 100 then
"00" ++ to_string x
else if x < 1000 then
"0" ++ to_string x
else
to_string x
-- Pretty print a calendar time as an ISO8601 time
def to_iso8601 (t:calendar_time) : string :=
let mname := month_names.fin_nth t.month in
let dname := to_string (t.day + 1) in
pp_4d t.year ++ "-" ++ pp_2d (t.month.val+1) ++ "-" ++ pp_2d (t.day+1)
++ "T" ++ pp_2d t.hour ++ ":" ++ pp_2d t.minute ++ ":" ++ pp_2d t.second
++ "Z"
instance : has_to_string calendar_time := ⟨to_iso8601⟩
-- Return Boolean indicating if this is a leap year.
def is_leap_year (year : ℕ) : bool :=
year.mod 4 = 0 ∧ (year.mod 100 ≠ 0 ∨ year.mod 400 = 0)
-- Return number of days in the given year
def number_of_days (year : ℕ) : ℕ := if is_leap_year year = tt then 366 else 365
-- Number of leap years that occured since the start of 1970.
def leap_year_count (year_offset : ℕ) : ℕ :=
-- Get number of multiples of 4 past.
let four_mul_count := (year_offset + ( 4 - 3)).div 4 in
-- Get number of multiples of 100 past.
let hundred_mul_count := (year_offset + (100 - 31)).div 100 in
-- Get number of multiples of 400 past.
let four_hundred_mul_count := (year_offset + (400 - 31)).div 400 in
-- Sum up leap years
four_mul_count - hundred_mul_count + four_hundred_mul_count
def calculate_year_and_day_offsets (days : ℕ) : ℕ × ℕ :=
let y_off := days.div 365 in
let total_days := 365 * y_off + leap_year_count y_off in
let year := 1970 + y_off in
if total_days > days then
let adj_days := total_days - number_of_days year in
(year - 1, days - adj_days)
else
(year, days - total_days)
def day_counts : list ℕ := [31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31]
def leap_day_counts : list ℕ := [31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31]
-- This maps a posix unix time to a Gregorian calendar.
--
-- One potential issue is that if the second count corresponds to a leap second, then
-- this will create a calendar time as 23:59:59 even though that time doesn't exist.
def from_posix_unix_time (sec : ℕ) : calendar_time :=
let min := sec.div 60 in
let hours := min.div 60 in
let days := hours.div 24 in
let (year, d_off) := calculate_year_and_day_offsets days in
let dc := if is_leap_year year then
leap_day_counts
else
day_counts in
let ds := dc.map_accuml (λc d, ((c,c+d), c+d)) 0 in
let pair : fin 12 × ℕ :=
match list.first_index_of (λ(c : ℕ × ℕ), c.snd > d_off) ds.fst with
| option.some (i,s) :=
if p : i < 12 then
(⟨i,p⟩,d_off - s.fst)
else
(0,0)
| option.none := (0,0)
end in
{ year := year
, month := pair.fst
, day := pair.snd
, hour := hours.mod 24
, minute := min.mod 60
, second := sec.mod 60
}
end calendar_time |
cfbff28231401fb0d4f2208f169187ba75ccd2a2 | a9d0fb7b0e4f802bd3857b803e6c5c23d87fef91 | /library/init/meta/congr_lemma.lean | a8c260d3fa2a5020dd825c2f1738ef6e0f0cec55 | [
"Apache-2.0"
] | permissive | soonhokong/lean-osx | 4a954262c780e404c1369d6c06516161d07fcb40 | 3670278342d2f4faa49d95b46d86642d7875b47c | refs/heads/master | 1,611,410,334,552 | 1,474,425,686,000 | 1,474,425,686,000 | 12,043,103 | 5 | 1 | null | null | null | null | UTF-8 | Lean | false | false | 3,606 | lean | /-
Copyright (c) 2016 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
prelude
import init.meta.tactic init.meta.format init.function
inductive congr_arg_kind
/- It is a parameter for the congruence lemma, the parameter occurs in the left and right hand sides. -/
| fixed
/- It is not a parameter for the congruence lemma, the lemma was specialized for this parameter.
This only happens if the parameter is a subsingleton/proposition, and other parameters depend on it. -/
| fixed_no_param
/- The lemma contains three parameters for this kind of argument a_i, b_i and (eq_i : a_i = b_i).
a_i and b_i represent the left and right hand sides, and eq_i is a proof for their equality. -/
| eq
/- congr-simp lemma contains only one parameter for this kind of argument, and congr-lemmas contains two.
They correspond to arguments that are subsingletons/propositions. -/
| cast
/- The lemma contains three parameters for this kind of argument a_i, b_i and (eq_i : a_i == b_i).
a_i and b_i represent the left and right hand sides, and eq_i is a proof for their heterogeneous equality. -/
| heq
structure congr_lemma :=
(type : expr) (proof : expr) (arg_kids : list congr_arg_kind)
namespace tactic
meta_constant mk_congr_simp_core : transparency → expr → tactic congr_lemma
meta_constant mk_congr_simp_n_core : transparency → expr → nat → tactic congr_lemma
/- Create a specialized theorem using (a prefix of) the arguments of the given application. -/
meta_constant mk_specialized_congr_simp_core : transparency → expr → tactic congr_lemma
meta_constant mk_congr_core : transparency → expr → tactic congr_lemma
meta_constant mk_congr_n_core : transparency → expr → nat → tactic congr_lemma
/- Create a specialized theorem using (a prefix of) the arguments of the given application. -/
meta_constant mk_specialized_congr_core : transparency → expr → tactic congr_lemma
meta_constant mk_hcongr_core : transparency → expr → tactic congr_lemma
meta_constant mk_hcongr_n_core : transparency → expr → nat → tactic congr_lemma
/- If R is an equivalence relation, construct the congruence lemma
R a1 a2 -> R b1 b2 -> (R a1 b1) <-> (R a2 b2) -/
meta_constant mk_rel_iff_congr_core : transparency → expr → tactic congr_lemma
/- Similar to mk_rel_iff_congr
It fails if propext is not available.
R a1 a2 -> R b1 b2 -> (R a1 b1) = (R a2 b2) -/
meta_constant mk_rel_eq_congr_core : transparency → expr → tactic congr_lemma
meta_definition mk_congr_simp : expr → tactic congr_lemma :=
mk_congr_simp_core semireducible
meta_definition mk_congr_simp_n : expr → nat → tactic congr_lemma :=
mk_congr_simp_n_core semireducible
meta_definition mk_specialized_congr_simp : expr → tactic congr_lemma :=
mk_specialized_congr_simp_core semireducible
meta_definition mk_congr : expr → tactic congr_lemma :=
mk_congr_core semireducible
meta_definition mk_congr_n : expr → nat → tactic congr_lemma :=
mk_congr_n_core semireducible
meta_definition mk_specialized_congr : expr → tactic congr_lemma :=
mk_specialized_congr_core semireducible
meta_definition mk_hcongr : expr → tactic congr_lemma :=
mk_hcongr_core semireducible
meta_definition mk_hcongr_n : expr → nat → tactic congr_lemma :=
mk_hcongr_n_core semireducible
meta_definition mk_rel_iff_congr : expr → tactic congr_lemma :=
mk_rel_iff_congr_core semireducible
meta_definition mk_rel_eq_congr : expr → tactic congr_lemma :=
mk_rel_eq_congr_core semireducible
end tactic
|
8c4d9b0d24e87386efdb45f1395f4fc5306d073e | 1b8f093752ba748c5ca0083afef2959aaa7dace5 | /src/category_theory/discrete_category.lean | 73e45c98da7ede4b6595b25f7e7c3c02b2e7a845 | [] | no_license | khoek/lean-category-theory | 7ec4cda9cc64a5a4ffeb84712ac7d020dbbba386 | 63dcb598e9270a3e8b56d1769eb4f825a177cd95 | refs/heads/master | 1,585,251,725,759 | 1,539,344,445,000 | 1,539,344,445,000 | 145,281,070 | 0 | 0 | null | 1,534,662,376,000 | 1,534,662,376,000 | null | UTF-8 | Lean | false | false | 1,736 | lean | -- Copyright (c) 2017 Scott Morrison. All rights reserved.
-- Released under Apache 2.0 license as described in the file LICENSE.
-- Authors: Stephen Morgan, Scott Morrison
import category_theory.functor
import category_theory.tactics.obviously
import category_theory.equivalence
namespace category_theory
universes u₁ v₁ u₂
def discrete (α : Type u₁) := α
instance discrete_category (α : Type u₁) : small_category (discrete α) :=
{ hom := λ X Y, ulift (plift (X = Y)),
id := by obviously,
comp := by obviously }
instance pempty_category : small_category pempty := (by apply_instance : small_category (discrete pempty))
instance punit_category : category.{u₁ v₁} punit :=
{ hom := λ X Y, punit,
id := by obviously,
comp := by obviously }
example : equivalence.{u₁ u₁ u₁ u₁} punit (discrete punit) := by obviously
def EmptyFunctor (C : Type (u₂+1)) [large_category C] : pempty ⥤ C := by obviously
-- TODO find a home for these in mathlib. https://leanprover.zulipchat.com/#narrow/stream/113488-general/subject/transport.20through.20trivial.20bundles/near/125769004
@[simp] lemma plift.rec.constant {α : Sort u₁} {β : Sort u₂} (b : β) : @plift.rec α (λ _, β) (λ _, b) = λ _, b :=
begin
apply funext,
intros,
cases x,
refl,
end
@[simp] lemma ulift.rec.constant {α : Type u₁} {β : Sort u₂} (b : β) : @ulift.rec α (λ _, β) (λ _, b) = λ _, b :=
begin
apply funext,
intros,
cases x,
refl,
end
namespace functor
def of_function {C : Type (u₂+1)} [large_category C] {I : Type u₁} (F : I → C) : (discrete I) ⥤ C :=
{ obj := F,
map' := λ X Y f, begin cases f, cases f, cases f, exact 𝟙 (F X) end }
end functor
end category_theory
|
ac3f3e6a0ebcd6b9dbdcb1df5354213efa9fbdf3 | a4673261e60b025e2c8c825dfa4ab9108246c32e | /stage0/src/Lean/Delaborator.lean | 9052b5fbb06fd4dd2944583e3877c1dbed0577f3 | [
"Apache-2.0"
] | permissive | jcommelin/lean4 | c02dec0cc32c4bccab009285475f265f17d73228 | 2909313475588cc20ac0436e55548a4502050d0a | refs/heads/master | 1,674,129,550,893 | 1,606,415,348,000 | 1,606,415,348,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 36,315 | lean | /-
Copyright (c) 2020 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sebastian Ullrich
-/
/-!
The delaborator is the first stage of the pretty printer, and the inverse of the
elaborator: it turns fully elaborated `Expr` core terms back into surface-level
`Syntax`, omitting some implicit information again and using higher-level syntax
abstractions like notations where possible. The exact behavior can be customized
using pretty printer options; activating `pp.all` should guarantee that the
delaborator is injective and that re-elaborating the resulting `Syntax`
round-trips.
Pretty printer options can be given not only for the whole term, but also
specific subterms. This is used both when automatically refining pp options
until round-trip and when interactively selecting pp options for a subterm (both
TBD). The association of options to subterms is done by assigning a unique,
synthetic Nat position to each subterm derived from its position in the full
term. This position is added to the corresponding Syntax object so that
elaboration errors and interactions with the pretty printer output can be traced
back to the subterm.
The delaborator is extensible via the `[delab]` attribute.
-/
import Lean.KeyedDeclsAttribute
import Lean.ProjFns
import Lean.Syntax
import Lean.Meta.Match
import Lean.Elab.Term
namespace Lean
-- TODO: move, maybe
namespace Level
protected partial def quote : Level → Syntax
| zero _ => Unhygienic.run `(level|0)
| l@(succ _ _) => match l.toNat with
| some n => Unhygienic.run `(level|$(quote n):numLit)
| none => Unhygienic.run `(level|$(Level.quote l.getLevelOffset) + $(quote l.getOffset):numLit)
| max l1 l2 _ => match_syntax Level.quote l2 with
| `(level|max $ls*) => Unhygienic.run `(level|max $(Level.quote l1) $ls*)
| l2 => Unhygienic.run `(level|max $(Level.quote l1) $l2)
| imax l1 l2 _ => match_syntax Level.quote l2 with
| `(level|imax $ls*) => Unhygienic.run `(level|imax $(Level.quote l1) $ls*)
| l2 => Unhygienic.run `(level|imax $(Level.quote l1) $l2)
| param n _ => Unhygienic.run `(level|$(mkIdent n):ident)
-- HACK: approximation
| mvar n _ => Unhygienic.run `(level|_)
instance : Quote Level := ⟨Level.quote⟩
end Level
def getPPBinderTypes (o : Options) : Bool := o.get `pp.binder_types true
def getPPCoercions (o : Options) : Bool := o.get `pp.coercions true
def getPPExplicit (o : Options) : Bool := o.get `pp.explicit false
def getPPNotation (o : Options) : Bool := o.get `pp.notation true
def getPPStructureProjections (o : Options) : Bool := o.get `pp.structure_projections true
def getPPStructureInstances (o : Options) : Bool := o.get `pp.structure_instances true
def getPPStructureInstanceType (o : Options) : Bool := o.get `pp.structure_instance_type false
def getPPUniverses (o : Options) : Bool := o.get `pp.universes false
def getPPFullNames (o : Options) : Bool := o.get `pp.full_names false
def getPPPrivateNames (o : Options) : Bool := o.get `pp.private_names false
def getPPUnicode (o : Options) : Bool := o.get `pp.unicode true
def getPPAll (o : Options) : Bool := o.get `pp.all false
builtin_initialize
registerOption `pp.explicit { defValue := false, group := "pp", descr := "(pretty printer) display implicit arguments" }
registerOption `pp.structure_instance_type { defValue := false, group := "pp", descr := "(pretty printer) display type of structure instances" }
-- TODO: register other options when old pretty printer is removed
--registerOption `pp.universes { defValue := false, group := "pp", descr := "(pretty printer) display universes" }
/-- Associate pretty printer options to a specific subterm using a synthetic position. -/
abbrev OptionsPerPos := Std.RBMap Nat Options (fun a b => a < b)
namespace Delaborator
open Lean.Meta
structure Context :=
-- In contrast to other systems like the elaborator, we do not pass the current term explicitly as a
-- parameter, but store it in the monad so that we can keep it in sync with `pos`.
(expr : Expr)
(pos : Nat := 1)
(defaultOptions : Options)
(optionsPerPos : OptionsPerPos)
(currNamespace : Name)
(openDecls : List OpenDecl)
-- Exceptions from delaborators are not expected. We use an internal exception to signal whether
-- the delaborator was able to produce a Syntax object.
builtin_initialize delabFailureId : InternalExceptionId ← registerInternalExceptionId `delabFailure
abbrev DelabM := ReaderT Context MetaM
abbrev Delab := DelabM Syntax
instance {α} : Inhabited (DelabM α) := ⟨throw arbitrary⟩
@[inline] protected def orElse {α} (d₁ d₂ : DelabM α) : DelabM α := do
catchInternalId delabFailureId d₁ (fun _ => d₂)
protected def failure {α} : DelabM α := throw $ Exception.internal delabFailureId
instance : Alternative DelabM := {
orElse := Delaborator.orElse,
failure := Delaborator.failure
}
-- HACK: necessary since it would otherwise prefer the instance from MonadExcept
instance {α} : OrElse (DelabM α) := ⟨Delaborator.orElse⟩
-- Macro scopes in the delaborator output are ultimately ignored by the pretty printer,
-- so give a trivial implementation.
instance : MonadQuotation DelabM := {
getCurrMacroScope := pure arbitrary,
getMainModule := pure arbitrary,
withFreshMacroScope := fun x => x
}
unsafe def mkDelabAttribute : IO (KeyedDeclsAttribute Delab) :=
KeyedDeclsAttribute.init {
builtinName := `builtinDelab,
name := `delab,
descr := "Register a delaborator.
[delab k] registers a declaration of type `Lean.Delaborator.Delab` for the `Lean.Expr`
constructor `k`. Multiple delaborators for a single constructor are tried in turn until
the first success. If the term to be delaborated is an application of a constant `c`,
elaborators for `app.c` are tried first; this is also done for `Expr.const`s (\"nullary applications\")
to reduce special casing. If the term is an `Expr.mdata` with a single key `k`, `mdata.k`
is tried first.",
valueTypeName := `Lean.Delaborator.Delab
} `Lean.Delaborator.delabAttribute
@[builtinInit mkDelabAttribute] constant delabAttribute : KeyedDeclsAttribute Delab
def getExpr : DelabM Expr := do
let ctx ← read
pure ctx.expr
def getExprKind : DelabM Name := do
let e ← getExpr
pure $ match e with
| Expr.bvar _ _ => `bvar
| Expr.fvar _ _ => `fvar
| Expr.mvar _ _ => `mvar
| Expr.sort _ _ => `sort
| Expr.const c _ _ =>
-- we identify constants as "nullary applications" to reduce special casing
`app ++ c
| Expr.app fn _ _ => match fn.getAppFn with
| Expr.const c _ _ => `app ++ c
| _ => `app
| Expr.lam _ _ _ _ => `lam
| Expr.forallE _ _ _ _ => `forallE
| Expr.letE _ _ _ _ _ => `letE
| Expr.lit _ _ => `lit
| Expr.mdata m _ _ => match m.entries with
| [(key, _)] => `mdata ++ key
| _ => `mdata
| Expr.proj _ _ _ _ => `proj
/-- Evaluate option accessor, using subterm-specific options if set. Default to `true` if `pp.all` is set. -/
def getPPOption (opt : Options → Bool) : DelabM Bool := do
let ctx ← read
let opt := fun opts => opt opts || getPPAll opts
let val := opt ctx.defaultOptions
match ctx.optionsPerPos.find? ctx.pos with
| some opts => pure $ opt opts
| none => pure val
def whenPPOption (opt : Options → Bool) (d : Delab) : Delab := do
let b ← getPPOption opt
if b then d else failure
def whenNotPPOption (opt : Options → Bool) (d : Delab) : Delab := do
let b ← getPPOption opt
if b then failure else d
/--
Descend into `child`, the `childIdx`-th subterm of the current term, and update position.
Because `childIdx < 3` in the case of `Expr`, we can injectively map a path
`childIdxs` to a natural number by computing the value of the 3-ary representation
`1 :: childIdxs`, since n-ary representations without leading zeros are unique.
Note that `pos` is initialized to `1` (case `childIdxs == []`).
-/
def descend {α} (child : Expr) (childIdx : Nat) (d : DelabM α) : DelabM α :=
withReader (fun cfg => { cfg with expr := child, pos := cfg.pos * 3 + childIdx }) d
def withAppFn {α} (d : DelabM α) : DelabM α := do
let Expr.app fn _ _ ← getExpr | unreachable!
descend fn 0 d
def withAppArg {α} (d : DelabM α) : DelabM α := do
let Expr.app _ arg _ ← getExpr | unreachable!
descend arg 1 d
partial def withAppFnArgs {α} : DelabM α → (α → DelabM α) → DelabM α
| fnD, argD => do
let Expr.app fn arg _ ← getExpr | fnD
let a ← withAppFn (withAppFnArgs fnD argD)
withAppArg (argD a)
def withBindingDomain {α} (d : DelabM α) : DelabM α := do
let e ← getExpr
descend e.bindingDomain! 0 d
def withBindingBody {α} (n : Name) (d : DelabM α) : DelabM α := do
let e ← getExpr
withLocalDecl n e.binderInfo e.bindingDomain! fun fvar =>
let b := e.bindingBody!.instantiate1 fvar
descend b 1 d
def withProj {α} (d : DelabM α) : DelabM α := do
let Expr.proj _ _ e _ ← getExpr | unreachable!
descend e 0 d
def withMDataExpr {α} (d : DelabM α) : DelabM α := do
let Expr.mdata _ e _ ← getExpr | unreachable!
-- do not change position so that options on an mdata are automatically forwarded to the child
withReader ({ · with expr := e }) d
partial def annotatePos (pos : Nat) : Syntax → Syntax
| stx@(Syntax.ident _ _ _ _) => stx.setInfo { pos := pos }
-- app => annotate function
| stx@(Syntax.node `Lean.Parser.Term.app args) => stx.modifyArg 0 (annotatePos pos)
-- otherwise, annotate first direct child token if any
| stx => match stx.getArgs.findIdx? Syntax.isAtom with
| some idx => stx.modifyArg idx (Syntax.setInfo { pos := pos })
| none => stx
def annotateCurPos (stx : Syntax) : Delab := do
let ctx ← read
pure $ annotatePos ctx.pos stx
def getUnusedName (suggestion : Name) : DelabM Name := do
-- Use a nicer binder name than `[anonymous]`. We probably shouldn't do this in all LocalContext use cases, so do it here.
let suggestion := if suggestion.isAnonymous then `a else suggestion;
let lctx ← getLCtx
pure $ lctx.getUnusedName suggestion
def withBindingBodyUnusedName {α} (d : Syntax → DelabM α) : DelabM α := do
let n ← getUnusedName (← getExpr).bindingName!
let stxN ← annotateCurPos (mkIdent n)
withBindingBody n $ d stxN
@[inline] def liftMetaM {α} (x : MetaM α) : DelabM α :=
liftM x
partial def delabFor : Name → Delab
| Name.anonymous => failure
| k => do
let env ← getEnv
(match (delabAttribute.ext.getState env).table.find? k with
| some delabs => delabs.firstM id >>= annotateCurPos
| none => failure) <|>
-- have `app.Option.some` fall back to `app` etc.
delabFor k.getRoot
def delab : Delab := do
let k ← getExprKind
delabFor k <|> (liftM $ show MetaM Syntax from throwError $ "don't know how to delaborate '" ++ toString k ++ "'")
@[builtinDelab fvar]
def delabFVar : Delab := do
let Expr.fvar id _ ← getExpr | unreachable!
try
let l ← getLocalDecl id
pure $ mkIdent l.userName
catch _ =>
-- loose free variable, use internal name
pure $ mkIdent id
-- loose bound variable, use pseudo syntax
@[builtinDelab bvar]
def delabBVar : Delab := do
let Expr.bvar idx _ ← getExpr | unreachable!
pure $ mkIdent $ Name.mkSimple $ "#" ++ toString idx
@[builtinDelab mvar]
def delabMVar : Delab := do
let Expr.mvar n _ ← getExpr | unreachable!
let n := n.replacePrefix `_uniq `m
`(?$(mkIdent n))
@[builtinDelab sort]
def delabSort : Delab := do
let Expr.sort l _ ← getExpr | unreachable!
match l with
| Level.zero _ => `(Prop)
| Level.succ (Level.zero _) _ => `(Type)
| _ => match l.dec with
| some l' => `(Type $(quote l'))
| none => `(Sort $(quote l))
-- find shorter names for constants, in reverse to Lean.Elab.ResolveName
private def unresolveQualifiedName (ns : Name) (c : Name) : DelabM Name := do
let c' := c.replacePrefix ns Name.anonymous;
let env ← getEnv
guard $ c' != c && !c'.isAnonymous && (!c'.isAtomic || !isProtected env c)
pure c'
private def unresolveUsingNamespace (c : Name) : Name → DelabM Name
| ns@(Name.str p _ _) => unresolveQualifiedName ns c <|> unresolveUsingNamespace c p
| _ => failure
private def unresolveOpenDecls (c : Name) : List OpenDecl → DelabM Name
| [] => failure
| OpenDecl.simple ns exs :: openDecls =>
let c' := c.replacePrefix ns Name.anonymous
if c' != c && exs.elem c' then unresolveOpenDecls c openDecls
else
unresolveQualifiedName ns c <|> unresolveOpenDecls c openDecls
| OpenDecl.explicit openedId resolvedId :: openDecls =>
guard (c == resolvedId) *> pure openedId <|> unresolveOpenDecls c openDecls
-- NOTE: not a registered delaborator, as `const` is never called (see [delab] description)
def delabConst : Delab := do
let Expr.const c ls _ ← getExpr | unreachable!
let c ← if (← getPPOption getPPFullNames) then pure c else
let ctx ← read
let env ← getEnv
let as := getRevAliases env c
-- might want to use a more clever heuristic such as selecting the shortest alias...
let c := as.headD c
unresolveUsingNamespace c ctx.currNamespace <|> unresolveOpenDecls c ctx.openDecls <|> pure c
let c ← if (← getPPOption getPPPrivateNames) then pure c else pure $ (privateToUserName? c).getD c
let ppUnivs ← getPPOption getPPUniverses
if ls.isEmpty || !ppUnivs then
pure $ mkIdent c
else
`($(mkIdent c).{$(mkSepArray (ls.toArray.map quote) (mkAtom ","))*})
inductive ParamKind :=
| explicit
-- combines implicit params, optParams, and autoParams
| implicit (defVal : Option Expr)
/-- Return array with n-th element set to kind of n-th parameter of `e`. -/
def getParamKinds (e : Expr) : MetaM (Array ParamKind) := do
let t ← inferType e
forallTelescopeReducing t fun params _ =>
params.mapM fun param => do
let l ← getLocalDecl param.fvarId!
match l.type.getOptParamDefault? with
| some val => pure $ ParamKind.implicit val
| _ =>
if l.type.isAutoParam || !l.binderInfo.isExplicit then
pure $ ParamKind.implicit none
else
pure ParamKind.explicit
@[builtinDelab app]
def delabAppExplicit : Delab := do
let (fnStx, argStxs) ← withAppFnArgs
(do
let fn ← getExpr
let stx ← if fn.isConst then delabConst else delab
let paramKinds ← liftM $ getParamKinds fn <|> pure #[]
let stx ← if paramKinds.any (fun k => match k with | ParamKind.explicit => false | _ => true) then `(@$stx) else pure stx
pure (stx, #[]))
(fun ⟨fnStx, argStxs⟩ => do
let argStx ← delab
pure (fnStx, argStxs.push argStx))
Syntax.mkApp fnStx argStxs
@[builtinDelab app]
def delabAppImplicit : Delab := whenNotPPOption getPPExplicit do
let (fnStx, _, argStxs) ← withAppFnArgs
(do
let fn ← getExpr
let stx ← if fn.isConst then delabConst else delab
let paramKinds ← liftM $ getParamKinds fn <|> pure #[]
pure (stx, paramKinds.toList, #[]))
(fun (fnStx, paramKinds, argStxs) => do
let arg ← getExpr;
let implicit : Bool := match paramKinds with -- TODO: check why we need `: Bool` here
| [ParamKind.implicit (some v)] => !v.hasLooseBVars && v == arg
| ParamKind.implicit none :: _ => true
| _ => false
if implicit then
pure (fnStx, paramKinds.tailD [], argStxs)
else do
let argStx ← delab
pure (fnStx, paramKinds.tailD [], argStxs.push argStx))
Syntax.mkApp fnStx argStxs
/-- State for `delabAppMatch` and helpers. -/
structure AppMatchState :=
(info : MatcherInfo)
(matcherTy : Expr)
(params : Array Expr := #[])
(hasMotive : Bool := false)
(discrs : Array Syntax := #[])
(rhss : Array Syntax := #[])
-- additional arguments applied to the result of the `match` expression
(moreArgs : Array Syntax := #[])
/-- Skip `numParams` binders. -/
private def skippingBinders {α} : (numParams : Nat) → (x : DelabM α) → DelabM α
| 0, x => x
| numParams+1, x =>
withBindingBodyUnusedName fun _ =>
skippingBinders numParams x
/--
Extract arguments of motive applications from the matcher type.
For the example below: `#[`([]), `(a::as)]` -/
private def delabPatterns (st : AppMatchState) : DelabM (Array Syntax) := do
let ty ← instantiateForall st.matcherTy st.params
forallTelescope ty fun params _ => do
-- skip motive and discriminators
let alts := Array.ofSubarray $ params[1 + st.discrs.size:]
alts.mapIdxM fun idx alt => do
let ty ← inferType alt
withReader ({ · with expr := ty }) $
skippingBinders st.info.altNumParams[idx] do
let pats ← withAppFnArgs (pure #[]) (fun pats => do pure $ pats.push (← delab))
Syntax.mkSep pats (mkAtom ",")
/--
Delaborate applications of "matchers" such as
```
List.map.match_1 : {α : Type _} →
(motive : List α → Sort _) →
(x : List α) → (Unit → motive List.nil) → ((a : α) → (as : List α) → motive (a :: as)) → motive x
``` -/
@[builtinDelab app]
def delabAppMatch : Delab := whenPPOption getPPNotation do
-- incrementally fill `AppMatchState` from arguments
let st ← withAppFnArgs
(do
let (Expr.const c us _) ← getExpr | failure
let (some info) ← getMatcherInfo? c | failure
{ matcherTy := (← getConstInfo c).instantiateTypeLevelParams us, info := info, : AppMatchState })
(fun st => do
if st.params.size < st.info.numParams then
pure { st with params := st.params.push (← getExpr) }
else if !st.hasMotive then
-- discard motive argument
pure { st with hasMotive := true }
else if st.discrs.size < st.info.numDiscrs then
pure { st with discrs := st.discrs.push (← delab) }
else if st.rhss.size < st.info.altNumParams.size then
pure { st with rhss := st.rhss.push (← skippingBinders st.info.altNumParams[st.rhss.size] delab) }
else
pure { st with moreArgs := st.moreArgs.push (← delab) })
if st.discrs.size < st.info.numDiscrs || st.rhss.size < st.info.altNumParams.size then
-- underapplied
failure
match st.discrs, st.rhss with
| #[discr], #[] =>
let stx ← `(nomatch $discr)
Syntax.mkApp stx st.moreArgs
| _, #[] => failure
| _, _ =>
let discrs := st.discrs.map fun discr => mkNode `Lean.Parser.Term.matchDiscr #[mkNullNode, discr]
let pats ← delabPatterns st
let alts := pats.zipWith st.rhss fun pat rhs => mkNode `Lean.Parser.Term.matchAlt #[pat, mkAtom "=>", rhs]
let stx ← `(match $(mkSepArray discrs (mkAtom ",")):matchDiscr* with | $(mkSepArray alts (mkAtom "|")):matchAlt*)
Syntax.mkApp stx st.moreArgs
@[builtinDelab mdata]
def delabMData : Delab := do
-- only interpret `pp.` values by default
let Expr.mdata m _ _ ← getExpr | unreachable!
let mut posOpts := (← read).optionsPerPos
let mut inaccessible := false
let pos := (← read).pos
for (k, v) in m do
if (`pp).isPrefixOf k then
let opts := posOpts.find? pos |>.getD {}
posOpts := posOpts.insert pos (opts.insert k v)
if k == `inaccessible then
inaccessible := true
withReader ({ · with optionsPerPos := posOpts }) do
let s ← withMDataExpr delab
if inaccessible then
`(.($s))
else
pure s
/--
Check for a `Syntax.ident` of the given name anywhere in the tree.
This is usually a bad idea since it does not check for shadowing bindings,
but in the delaborator we assume that bindings are never shadowed.
-/
partial def hasIdent (id : Name) : Syntax → Bool
| Syntax.ident _ _ id' _ => id == id'
| Syntax.node _ args => args.any (hasIdent id)
| _ => false
/--
Return `true` iff current binder should be merged with the nested
binder, if any, into a single binder group:
* both binders must have same binder info and domain
* they cannot be inst-implicit (`[a b : A]` is not valid syntax)
* `pp.binder_types` must be the same value for both terms
* prefer `fun a b` over `fun (a b)`
-/
private def shouldGroupWithNext : DelabM Bool := do
let e ← getExpr
let ppEType ← getPPOption getPPBinderTypes;
let go (e' : Expr) := do
let ppE'Type ← withBindingBody `_ $ getPPOption getPPBinderTypes
pure $ e.binderInfo == e'.binderInfo &&
e.bindingDomain! == e'.bindingDomain! &&
e'.binderInfo != BinderInfo.instImplicit &&
ppEType == ppE'Type &&
(e'.binderInfo != BinderInfo.default || ppE'Type)
match e with
| Expr.lam _ _ e'@(Expr.lam _ _ _ _) _ => go e'
| Expr.forallE _ _ e'@(Expr.forallE _ _ _ _) _ => go e'
| _ => pure false
private partial def delabBinders (delabGroup : Array Syntax → Syntax → Delab) : optParam (Array Syntax) #[] → Delab
-- Accumulate names (`Syntax.ident`s with position information) of the current, unfinished
-- binder group `(d e ...)` as determined by `shouldGroupWithNext`. We cannot do grouping
-- inside-out, on the Syntax level, because it depends on comparing the Expr binder types.
| curNames => do
if (← shouldGroupWithNext) then
-- group with nested binder => recurse immediately
withBindingBodyUnusedName fun stxN => delabBinders delabGroup (curNames.push stxN)
else
-- don't group => delab body and prepend current binder group
let (stx, stxN) ← withBindingBodyUnusedName fun stxN => do (← delab, stxN)
delabGroup (curNames.push stxN) stx
@[builtinDelab lam]
def delabLam : Delab :=
delabBinders fun curNames stxBody => do
let e ← getExpr
let stxT ← withBindingDomain delab
let ppTypes ← getPPOption getPPBinderTypes
let expl ← getPPOption getPPExplicit
-- leave lambda implicit if possible
let blockImplicitLambda := expl ||
e.binderInfo == BinderInfo.default ||
Elab.Term.blockImplicitLambda stxBody ||
curNames.any (fun n => hasIdent n.getId stxBody);
if !blockImplicitLambda then
pure stxBody
else
let group ← match e.binderInfo, ppTypes with
| BinderInfo.default, true =>
-- "default" binder group is the only one that expects binder names
-- as a term, i.e. a single `Syntax.ident` or an application thereof
let stxCurNames ←
if curNames.size > 1 then
`($(curNames.get! 0) $(curNames.eraseIdx 0)*)
else
pure $ curNames.get! 0;
`(funBinder| ($stxCurNames : $stxT))
| BinderInfo.default, false => pure curNames.back -- here `curNames.size == 1`
| BinderInfo.implicit, true => `(funBinder| {$curNames* : $stxT})
| BinderInfo.implicit, false => `(funBinder| {$curNames*})
| BinderInfo.instImplicit, _ => `(funBinder| [$curNames.back : $stxT]) -- here `curNames.size == 1`
| _ , _ => unreachable!;
match_syntax stxBody with
| `(fun $binderGroups* => $stxBody) => `(fun $group $binderGroups* => $stxBody)
| _ => `(fun $group => $stxBody)
@[builtinDelab forallE]
def delabForall : Delab :=
delabBinders fun curNames stxBody => do
let e ← getExpr
let stxT ← withBindingDomain delab
match e.binderInfo with
| BinderInfo.default =>
-- heuristic: use non-dependent arrows only if possible for whole group to avoid
-- noisy mix like `(α : Type) → Type → (γ : Type) → ...`.
let dependent := curNames.any $ fun n => hasIdent n.getId stxBody
-- NOTE: non-dependent arrows are available only for the default binder info
if dependent then do
`(($curNames* : $stxT) → $stxBody)
else
curNames.foldrM (fun _ stxBody => `($stxT → $stxBody)) stxBody
| BinderInfo.implicit => `({$curNames* : $stxT} → $stxBody)
-- here `curNames.size == 1`
| BinderInfo.instImplicit => `([$curNames.back : $stxT] → $stxBody)
| _ => unreachable!
@[builtinDelab letE]
def delabLetE : Delab := do
let Expr.letE n t v b _ ← getExpr | unreachable!
let n ← getUnusedName n
let stxT ← descend t 0 delab
let stxV ← descend v 1 delab
let stxB ← withLetDecl n t v fun fvar =>
let b := b.instantiate1 fvar
descend b 2 delab
`(let $(mkIdent n) : $stxT := $stxV; $stxB)
@[builtinDelab lit]
def delabLit : Delab := do
let Expr.lit l _ ← getExpr | unreachable!
match l with
| Literal.natVal n => pure $ quote n
| Literal.strVal s => pure $ quote s
-- `ofNat 0` ~> `0`
@[builtinDelab app.OfNat.ofNat]
def delabOfNat : Delab := whenPPOption getPPCoercions do
let e@(Expr.app _ (Expr.lit (Literal.natVal n) _) _) ← getExpr | failure
pure $ quote n
/--
Delaborate a projection primitive. These do not usually occur in
user code, but are pretty-printed when e.g. `#print`ing a projection
function.
-/
@[builtinDelab proj]
def delabProj : Delab := do
let Expr.proj _ idx _ _ ← getExpr | unreachable!
let e ← withProj delab
-- not perfectly authentic: elaborates to the `idx`-th named projection
-- function (e.g. `e.1` is `Prod.fst e`), which unfolds to the actual
-- `proj`.
let idx := Syntax.mkLit fieldIdxKind (toString (idx + 1));
`($(e).$idx:fieldIdx)
/-- Delaborate a call to a projection function such as `Prod.fst`. -/
@[builtinDelab app]
def delabProjectionApp : Delab := whenPPOption getPPStructureProjections $ do
let e@(Expr.app fn _ _) ← getExpr | failure
let Expr.const c@(Name.str _ f _) _ _ ← pure fn.getAppFn | failure
let env ← getEnv
let some info ← pure $ env.getProjectionFnInfo? c | failure
-- can't use with classes since the instance parameter is implicit
guard $ !info.fromClass
-- projection function should be fully applied (#struct params + 1 instance parameter)
-- TODO: support over-application
guard $ e.getAppNumArgs == info.nparams + 1
-- If pp.explicit is true, and the structure has parameters, we should not
-- use field notation because we will not be able to see the parameters.
let expl ← getPPOption getPPExplicit
guard $ !expl || info.nparams == 0
let appStx ← withAppArg delab
`($(appStx).$(mkIdent f):ident)
@[builtinDelab app]
def delabStructureInstance : Delab := whenPPOption getPPStructureInstances do
let env ← getEnv
let e ← getExpr
let some s ← pure $ e.isConstructorApp? env | failure
guard $ isStructure env s.induct;
/- If implicit arguments should be shown, and the structure has parameters, we should not
pretty print using { ... }, because we will not be able to see the parameters. -/
let explicit ← getPPOption getPPExplicit
guard !(explicit && s.nparams > 0)
let fieldNames := getStructureFields env s.induct
let (_, fields) ← withAppFnArgs (pure (0, #[])) fun ⟨idx, fields⟩ => do
if idx < s.nparams then
pure (idx + 1, fields)
else
let val ← delab
let field := Syntax.node `Lean.Parser.Term.structInstField #[
mkIdent $ fieldNames.get! (idx - s.nparams),
mkNullNode,
mkAtom ":=",
val
]
pure (idx + 1, fields.push field)
let fields := fields.mapIdx fun idx field =>
let comma := if idx.val < fields.size - 1 then mkNullNode #[mkAtom ","] else mkNullNode
mkNullNode #[field, comma]
if (← getPPOption getPPStructureInstanceType) then
let ty ← inferType e
-- `ty` is not actually part of `e`, but since `e` must be an application or constant, we know that
-- index 2 is unused.
let stxTy ← descend ty 2 delab
return Syntax.node `Lean.Parser.Term.structInst #[
mkAtom "{", mkNullNode, mkNullNode fields, mkNullNode,
mkNullNode #[ mkAtom ":", stxTy ],
mkAtom "}"
]
else
return Syntax.node `Lean.Parser.Term.structInst #[ mkAtom "{", mkNullNode, mkNullNode fields, mkNullNode, mkNullNode, mkAtom "}"]
@[builtinDelab app.Prod.mk]
def delabTuple : Delab := whenPPOption getPPNotation do
let e ← getExpr
guard $ e.getAppNumArgs == 4
let a ← withAppFn $ withAppArg delab
let b ← withAppArg delab
match_syntax b with
| `(($b, $bs*)) =>
let bs := #[b, mkAtom ","] ++ bs;
`(($a, $bs*))
| _ => `(($a, $b))
-- abbrev coe {α : Sort u} {β : Sort v} (a : α) [CoeT α a β] : β
@[builtinDelab app.coe]
def delabCoe : Delab := whenPPOption getPPCoercions do
let e ← getExpr
guard $ e.getAppNumArgs >= 4
-- delab as application, then discard function
let stx ← delabAppImplicit
match_syntax stx with
| `($fn $args*) =>
if args.size == 1 then
pure $ args.get! 0
else
`($(args.get! 0) $(args.eraseIdx 0)*)
| _ => failure
-- abbrev coeFun {α : Sort u} {γ : α → Sort v} (a : α) [CoeFun α γ] : γ a
@[builtinDelab app.coeFun]
def delabCoeFun : Delab := delabCoe
def delabInfixOp (op : Bool → Syntax → Syntax → Delab) : Delab := whenPPOption getPPNotation do
let stx ← delabAppImplicit <|> delabAppExplicit
guard $ stx.isOfKind `Lean.Parser.Term.app && (stx.getArg 1).getNumArgs == 2
let unicode ← getPPOption getPPUnicode
let args := stx.getArg 1
op unicode (args.getArg 0) (args.getArg 1)
def delabPrefixOp (op : Bool → Syntax → Delab) : Delab := whenPPOption getPPNotation do
let stx ← delabAppImplicit <|> delabAppExplicit
guard $ stx.isOfKind `Lean.Parser.Term.app && (stx.getArg 1).getNumArgs == 1
let unicode ← getPPOption getPPUnicode
let args := stx.getArg 1
op unicode (args.getArg 0)
@[builtinDelab app.Prod] def delabProd : Delab := delabInfixOp fun _ x y => `($x × $y)
@[builtinDelab app.Function.comp] def delabFComp : Delab := delabInfixOp fun _ x y => `($x ∘ $y)
@[builtinDelab app.Add.add] def delabAdd : Delab := delabInfixOp fun _ x y => `($x + $y)
@[builtinDelab app.Sub.sub] def delabSub : Delab := delabInfixOp fun _ x y => `($x - $y)
@[builtinDelab app.Mul.mul] def delabMul : Delab := delabInfixOp fun _ x y => `($x * $y)
@[builtinDelab app.Div.div] def delabDiv : Delab := delabInfixOp fun _ x y => `($x / $y)
@[builtinDelab app.Mod.mod] def delabMod : Delab := delabInfixOp fun _ x y => `($x % $y)
@[builtinDelab app.ModN.modn] def delabModN : Delab := delabInfixOp fun _ x y => `($x %ₙ $y)
@[builtinDelab app.Pow.pow] def delabPow : Delab := delabInfixOp fun _ x y => `($x ^ $y)
@[builtinDelab app.HasLessEq.LessEq] def delabLE : Delab := delabInfixOp fun b x y => cond b `($x ≤ $y) `($x <= $y)
@[builtinDelab app.GreaterEq] def delabGE : Delab := delabInfixOp fun b x y => cond b `($x ≥ $y) `($x >= $y)
@[builtinDelab app.HasLess.Less] def delabLT : Delab := delabInfixOp fun _ x y => `($x < $y)
@[builtinDelab app.Greater] def delabGT : Delab := delabInfixOp fun _ x y => `($x > $y)
@[builtinDelab app.Eq] def delabEq : Delab := delabInfixOp fun _ x y => `($x = $y)
@[builtinDelab app.Ne] def delabNe : Delab := delabInfixOp fun _ x y => `($x ≠ $y)
@[builtinDelab app.BEq.beq] def delabBEq : Delab := delabInfixOp fun _ x y => `($x == $y)
@[builtinDelab app.bne] def delabBNe : Delab := delabInfixOp fun _ x y => `($x != $y)
@[builtinDelab app.HEq] def delabHEq : Delab := delabInfixOp fun b x y => cond b `($x ≅ $y) `($x ~= $y)
@[builtinDelab app.HasEquiv.Equiv] def delabEquiv : Delab := delabInfixOp fun _ x y => `($x ≈ $y)
@[builtinDelab app.And] def delabAnd : Delab := delabInfixOp fun b x y => cond b `($x ∧ $y) `($x /\ $y)
@[builtinDelab app.Or] def delabOr : Delab := delabInfixOp fun b x y => cond b `($x ∨ $y) `($x || $y)
@[builtinDelab app.Iff] def delabIff : Delab := delabInfixOp fun b x y => cond b `($x ↔ $y) `($x <-> $y)
@[builtinDelab app.and] def delabBAnd : Delab := delabInfixOp fun _ x y => `($x && $y)
@[builtinDelab app.or] def delabBOr : Delab := delabInfixOp fun _ x y => `($x || $y)
@[builtinDelab app.Append.append] def delabAppend : Delab := delabInfixOp fun _ x y => `($x ++ $y)
@[builtinDelab app.List.cons] def delabCons : Delab := delabInfixOp fun _ x y => `($x :: $y)
@[builtinDelab app.AndThen.andthen] def delabAndThen : Delab := delabInfixOp fun _ x y => `($x >> $y)
@[builtinDelab app.Bind.bind] def delabBind : Delab := delabInfixOp fun _ x y => `($x >>= $y)
@[builtinDelab app.Seq.seq] def delabseq : Delab := delabInfixOp fun _ x y => `($x <*> $y)
@[builtinDelab app.SeqLeft.seqLeft] def delabseqLeft : Delab := delabInfixOp fun _ x y => `($x <* $y)
@[builtinDelab app.SeqRight.seqRight] def delabseqRight : Delab := delabInfixOp fun _ x y => `($x *> $y)
@[builtinDelab app.Functor.map] def delabMap : Delab := delabInfixOp fun _ x y => `($x <$> $y)
@[builtinDelab app.Functor.mapRev] def delabMapRev : Delab := delabInfixOp fun _ x y => `($x <&> $y)
@[builtinDelab app.OrElse.orelse] def delabOrElse : Delab := delabInfixOp fun _ x y => `($x <|> $y)
@[builtinDelab app.orM] def delabOrM : Delab := delabInfixOp fun _ x y => `($x <||> $y)
@[builtinDelab app.andM] def delabAndM : Delab := delabInfixOp fun _ x y => `($x <&&> $y)
@[builtinDelab app.Not] def delabNot : Delab := delabPrefixOp fun _ x => `(¬ $x)
@[builtinDelab app.not] def delabBNot : Delab := delabPrefixOp fun _ x => `(! $x)
@[builtinDelab app.List.nil]
def delabNil : Delab := whenPPOption getPPNotation do
guard $ (← getExpr).getAppNumArgs == 1
`([])
@[builtinDelab app.List.cons]
def delabConsList : Delab := whenPPOption getPPNotation do
guard $ (← getExpr).getAppNumArgs == 3
let x ← withAppFn (withAppArg delab)
match_syntax (← withAppArg delab) with
| `([]) => `([$x])
| `([$xs*]) => `([$x, $xs*])
| _ => failure
@[builtinDelab app.List.toArray]
def delabListToArray : Delab := whenPPOption getPPNotation do
guard $ (← getExpr).getAppNumArgs == 2
match_syntax (← withAppArg delab) with
| `([$xs*]) => `(#[$xs*])
| _ => failure
@[builtinDelab app.namedPattern]
def delabNamedPattern : Delab := do
guard $ (← getExpr).getAppNumArgs == 3
let x ← withAppFn $ withAppArg delab
let p ← withAppArg delab
guard x.isIdent
`($x:ident@$p:term)
partial def delabDoElems : DelabM (List Syntax) := do
let e ← getExpr
if e.isAppOfArity `Bind.bind 6 then
-- Bind.bind.{u, v} : {m : Type u → Type v} → [self : Bind m] → {α β : Type u} → m α → (α → m β) → m β
let ma ← withAppFn $ withAppArg delab
withAppArg do
match (← getExpr) with
| Expr.lam _ _ body _ =>
withBindingBodyUnusedName fun n => do
if body.hasLooseBVars then
prependAndRec `(doElem|let $n:term ← $ma)
else
prependAndRec `(doElem|$ma:term)
| _ => delabAndRet
else if e.isLet then
let Expr.letE n t v b _ ← getExpr | unreachable!
let n ← getUnusedName n
let stxT ← descend t 0 delab
let stxV ← descend v 1 delab
withLetDecl n t v fun fvar =>
let b := b.instantiate1 fvar
descend b 2 $
prependAndRec `(doElem|let $(mkIdent n) : $stxT := $stxV)
else
delabAndRet
where
prependAndRec x : DelabM _ := List.cons <$> x <*> delabDoElems
delabAndRet : DelabM _ := do let stx ← delab; [←`(doElem|$stx:term)]
@[builtinDelab app.Bind.bind]
def delabDo : Delab := whenPPOption getPPNotation do
unless (← getExpr).isAppOfArity `Bind.bind 6 do
failure
let elems ← delabDoElems
let items := elems.toArray.map (mkNode `Lean.Parser.Term.doSeqItem #[·, mkNullNode])
`(do $items:doSeqItem*)
end Delaborator
/-- "Delaborate" the given term into surface-level syntax using the default and given subterm-specific options. -/
def delab (currNamespace : Name) (openDecls : List OpenDecl) (e : Expr) (optionsPerPos : OptionsPerPos := {}) : MetaM Syntax := do
trace[PrettyPrinter.delab.input]! "{fmt e}"
let opts ← MonadOptions.getOptions
catchInternalId Delaborator.delabFailureId
(Delaborator.delab.run { expr := e, defaultOptions := opts, optionsPerPos := optionsPerPos, currNamespace := currNamespace, openDecls := openDecls })
(fun _ => unreachable!)
builtin_initialize registerTraceClass `PrettyPrinter.delab
end Lean
|
80eeaf24b9ce5fbdb26f886f7376719b3560110d | cf39355caa609c0f33405126beee2739aa3cb77e | /tests/lean/alias2.lean | 6cc5a0f8700f20677fb37890c490ecb371bc8cd3 | [
"Apache-2.0"
] | permissive | leanprover-community/lean | 12b87f69d92e614daea8bcc9d4de9a9ace089d0e | cce7990ea86a78bdb383e38ed7f9b5ba93c60ce0 | refs/heads/master | 1,687,508,156,644 | 1,684,951,104,000 | 1,684,951,104,000 | 169,960,991 | 457 | 107 | Apache-2.0 | 1,686,744,372,000 | 1,549,790,268,000 | C++ | UTF-8 | Lean | false | false | 174 | lean | --
namespace foo
definition t := true
end foo
open foo
namespace bla
definition t := false
#check foo.t -- <<< must print foo.t : Prop instead of t : Prop
end bla
|
6872dcb082b4c8ec1fcea622c96d0aa495354397 | cf39355caa609c0f33405126beee2739aa3cb77e | /tests/lean/quot_ind_bug.lean | 1f16f37522d4949ddc8666a4e9c45c8947cf2930 | [
"Apache-2.0"
] | permissive | leanprover-community/lean | 12b87f69d92e614daea8bcc9d4de9a9ace089d0e | cce7990ea86a78bdb383e38ed7f9b5ba93c60ce0 | refs/heads/master | 1,687,508,156,644 | 1,684,951,104,000 | 1,684,951,104,000 | 169,960,991 | 457 | 107 | Apache-2.0 | 1,686,744,372,000 | 1,549,790,268,000 | C++ | UTF-8 | Lean | false | false | 222 | lean | open quotient
variables {A : Type} [s : setoid A] {B : quotient s → Prop} (c : ∀ (a : A), B (quotient.mk a)) (a : A)
#check (quotient.ind c ⟦a⟧ : B ⟦a⟧)
#check c a
#reduce (quotient.ind c ⟦a⟧ : B ⟦a⟧)
|
9ae4e242b40208d094f02b82122a712223e4b91b | 69d4931b605e11ca61881fc4f66db50a0a875e39 | /src/data/fintype/card_embedding.lean | b7ec2669cb9072c08df3f639911020d4ee4f7139 | [
"Apache-2.0"
] | permissive | abentkamp/mathlib | d9a75d291ec09f4637b0f30cc3880ffb07549ee5 | 5360e476391508e092b5a1e5210bd0ed22dc0755 | refs/heads/master | 1,682,382,954,948 | 1,622,106,077,000 | 1,622,106,077,000 | 149,285,665 | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 3,272 | lean | /-
Copyright (c) 2021 Eric Rodriguez. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Eric Rodriguez
-/
import data.fintype.card
import data.equiv.fin
import data.equiv.embedding
/-!
# Birthday Problem
This file establishes the cardinality of `α ↪ β` in full generality.
-/
local notation `|` x `|` := finset.card x
local notation `‖` x `‖` := fintype.card x
open_locale nat
namespace fintype
-- We need the separate `fintype α` instance as it contains data,
-- and may not match definitionally with the instance coming from `unique.fintype`.
lemma card_embedding_of_unique
{α β : Type*} [unique α] [fintype α] [fintype β] [decidable_eq α] [decidable_eq β]:
‖α ↪ β‖ = ‖β‖ := card_congr equiv.unique_embedding_equiv_result
private lemma card_embedding_aux (n : ℕ) (β) [fintype β] [decidable_eq β] (h : n ≤ ‖β‖) :
‖fin n ↪ β‖ = nat.desc_fac (‖β‖ - n) n :=
begin
induction n with n hn,
{ nontriviality (fin 0 ↪ β),
rw [nat.desc_fac_zero, fintype.card_eq_one_iff],
refine ⟨nonempty.some nontrivial.to_nonempty, λ x, function.embedding.ext fin.elim0⟩ },
rw [nat.succ_eq_add_one, ←card_congr (equiv.embedding_congr fin_sum_fin_equiv (equiv.refl β))],
rw card_congr equiv.sum_embedding_equiv_sigma_embedding_restricted,
-- these `rw`s create goals for instances, which it doesn't infer for some reason
all_goals { try { apply_instance } }, -- however, this needs to be done here instead of at the end
-- else, a later `simp`, which depends on the `fintype` instance, won't work.
have : ∀ (f : fin n ↪ β), ‖fin 1 ↪ ↥((set.range f)ᶜ)‖ = ‖β‖ - n,
{ intro f,
rw card_embedding_of_unique,
rw card_of_finset' (finset.map f finset.univ)ᶜ,
{ rw [finset.card_compl, finset.card_map, finset.card_fin] },
{ simp } },
-- putting `card_sigma` in `simp` causes it not to fully simplify
rw card_sigma,
simp only [this, finset.sum_const, finset.card_univ, nsmul_eq_mul, nat.cast_id],
replace h := nat.lt_of_succ_le h,
rw [hn h.le, mul_comm, nat.desc_fac_of_sub h]
end
variables {α β : Type*} [fintype α] [fintype β] [decidable_eq α] [decidable_eq β]
/- Establishes the cardinality of the type of all injections, if any exist. -/
@[simp] theorem card_embedding (h : ‖α‖ ≤ ‖β‖) : ‖α ↪ β‖ = (nat.desc_fac (‖β‖ - ‖α‖) ‖α‖) :=
begin
trunc_cases fintype.trunc_equiv_fin α with eq,
rw fintype.card_congr (equiv.embedding_congr eq (equiv.refl β)),
exact card_embedding_aux _ _ h,
end
/-- If `‖β‖ < ‖α‖` there are no embeddings `α ↪ β`.
This is a formulation of the pigeonhole principle. -/
@[simp] theorem card_embedding_eq_zero (h : ‖β‖ < ‖α‖) : ‖α ↪ β‖ = 0 :=
card_eq_zero_iff.mpr $ function.embedding.is_empty_of_card_lt h
theorem card_embedding_eq_if : ‖α ↪ β‖ = if ‖α‖ ≤ ‖β‖ then nat.desc_fac (‖β‖ - ‖α‖) ‖α‖ else 0 :=
begin
split_ifs with h,
{ exact card_embedding h },
{ exact card_embedding_eq_zero (not_le.mp h) }
end
lemma card_embedding_eq_infinite {α β} [infinite α] [fintype β] : ‖α ↪ β‖ = 0 :=
by rw card_eq_zero_iff; apply_instance
end fintype
|
836b005c73f391a5cb9582a3cb197666a027c856 | 947fa6c38e48771ae886239b4edce6db6e18d0fb | /src/group_theory/order_of_element.lean | 03e51ce62749d20c0ee51e849a92a0fd93e66744 | [
"Apache-2.0"
] | permissive | ramonfmir/mathlib | c5dc8b33155473fab97c38bd3aa6723dc289beaa | 14c52e990c17f5a00c0cc9e09847af16fabbed25 | refs/heads/master | 1,661,979,343,526 | 1,660,830,384,000 | 1,660,830,384,000 | 182,072,989 | 0 | 0 | null | 1,555,585,876,000 | 1,555,585,876,000 | null | UTF-8 | Lean | false | false | 34,007 | lean | /-
Copyright (c) 2018 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Julian Kuelshammer
-/
import algebra.hom.iterate
import data.nat.modeq
import data.set.pointwise
import dynamics.periodic_pts
import group_theory.index
/-!
# Order of an element
This file defines the order of an element of a finite group. For a finite group `G` the order of
`x ∈ G` is the minimal `n ≥ 1` such that `x ^ n = 1`.
## Main definitions
* `is_of_fin_order` is a predicate on an element `x` of a monoid `G` saying that `x` is of finite
order.
* `is_of_fin_add_order` is the additive analogue of `is_of_fin_order`.
* `order_of x` defines the order of an element `x` of a monoid `G`, by convention its value is `0`
if `x` has infinite order.
* `add_order_of` is the additive analogue of `order_of`.
## Tags
order of an element
-/
open function nat
open_locale pointwise
universes u v
variables {G : Type u} {A : Type v}
variables {x y : G} {a b : A} {n m : ℕ}
section monoid_add_monoid
variables [monoid G] [add_monoid A]
section is_of_fin_order
@[to_additive]
lemma is_periodic_pt_mul_iff_pow_eq_one (x : G) : is_periodic_pt ((*) x) n 1 ↔ x ^ n = 1 :=
by rw [is_periodic_pt, is_fixed_pt, mul_left_iterate, mul_one]
/-- `is_of_fin_add_order` is a predicate on an element `a` of an additive monoid to be of finite
order, i.e. there exists `n ≥ 1` such that `n • a = 0`.-/
def is_of_fin_add_order (a : A) : Prop :=
(0 : A) ∈ periodic_pts ((+) a)
/-- `is_of_fin_order` is a predicate on an element `x` of a monoid to be of finite order, i.e. there
exists `n ≥ 1` such that `x ^ n = 1`.-/
@[to_additive is_of_fin_add_order]
def is_of_fin_order (x : G) : Prop :=
(1 : G) ∈ periodic_pts ((*) x)
lemma is_of_fin_add_order_of_mul_iff :
is_of_fin_add_order (additive.of_mul x) ↔ is_of_fin_order x := iff.rfl
lemma is_of_fin_order_of_add_iff :
is_of_fin_order (multiplicative.of_add a) ↔ is_of_fin_add_order a := iff.rfl
@[to_additive is_of_fin_add_order_iff_nsmul_eq_zero]
lemma is_of_fin_order_iff_pow_eq_one (x : G) :
is_of_fin_order x ↔ ∃ n, 0 < n ∧ x ^ n = 1 :=
by { convert iff.rfl, simp [is_periodic_pt_mul_iff_pow_eq_one] }
/-- Elements of finite order are of finite order in submonoids.-/
@[to_additive is_of_fin_add_order_iff_coe "Elements of finite order are of finite order in
submonoids."]
lemma is_of_fin_order_iff_coe (H : submonoid G) (x : H) :
is_of_fin_order x ↔ is_of_fin_order (x : G) :=
by { rw [is_of_fin_order_iff_pow_eq_one, is_of_fin_order_iff_pow_eq_one], norm_cast }
/-- The image of an element of finite order has finite order. -/
@[to_additive add_monoid_hom.is_of_fin_order
"The image of an element of finite additive order has finite additive order."]
lemma monoid_hom.is_of_fin_order
{H : Type v} [monoid H] (f : G →* H) {x : G} (h : is_of_fin_order x) :
is_of_fin_order $ f x :=
(is_of_fin_order_iff_pow_eq_one _).mpr $ begin
rcases (is_of_fin_order_iff_pow_eq_one _).mp h with ⟨n, npos, hn⟩,
exact ⟨n, npos, by rw [←f.map_pow, hn, f.map_one]⟩,
end
/-- If a direct product has finite order then so does each component. -/
@[to_additive "If a direct product has finite additive order then so does each component."]
lemma is_of_fin_order.apply
{η : Type*} {Gs : η → Type*} [∀ i, monoid (Gs i)] {x : Π i, Gs i} (h : is_of_fin_order x) :
∀ i, is_of_fin_order (x i) := begin
rcases (is_of_fin_order_iff_pow_eq_one _).mp h with ⟨n, npos, hn⟩,
exact λ _, (is_of_fin_order_iff_pow_eq_one _).mpr ⟨n, npos, (congr_fun hn.symm _).symm⟩,
end
/-- 1 is of finite order in any monoid. -/
@[to_additive "0 is of finite order in any additive monoid."]
lemma is_of_fin_order_one : is_of_fin_order (1 : G) :=
(is_of_fin_order_iff_pow_eq_one 1).mpr ⟨1, _root_.one_pos, one_pow 1⟩
end is_of_fin_order
/-- `order_of x` is the order of the element `x`, i.e. the `n ≥ 1`, s.t. `x ^ n = 1` if it exists.
Otherwise, i.e. if `x` is of infinite order, then `order_of x` is `0` by convention.-/
@[to_additive add_order_of
"`add_order_of a` is the order of the element `a`, i.e. the `n ≥ 1`, s.t. `n • a = 0` if it
exists. Otherwise, i.e. if `a` is of infinite order, then `add_order_of a` is `0` by convention."]
noncomputable def order_of (x : G) : ℕ :=
minimal_period ((*) x) 1
@[simp] lemma add_order_of_of_mul_eq_order_of (x : G) :
add_order_of (additive.of_mul x) = order_of x := rfl
@[simp] lemma order_of_of_add_eq_add_order_of (a : A) :
order_of (multiplicative.of_add a) = add_order_of a := rfl
@[to_additive add_order_of_pos']
lemma order_of_pos' (h : is_of_fin_order x) : 0 < order_of x :=
minimal_period_pos_of_mem_periodic_pts h
@[to_additive add_order_of_nsmul_eq_zero]
lemma pow_order_of_eq_one (x : G) : x ^ order_of x = 1 :=
begin
convert is_periodic_pt_minimal_period ((*) x) _,
rw [order_of, mul_left_iterate, mul_one],
end
@[to_additive add_order_of_eq_zero]
lemma order_of_eq_zero (h : ¬ is_of_fin_order x) : order_of x = 0 :=
by rwa [order_of, minimal_period, dif_neg]
@[to_additive add_order_of_eq_zero_iff] lemma order_of_eq_zero_iff :
order_of x = 0 ↔ ¬ is_of_fin_order x :=
⟨λ h H, (order_of_pos' H).ne' h, order_of_eq_zero⟩
@[to_additive add_order_of_eq_zero_iff'] lemma order_of_eq_zero_iff' :
order_of x = 0 ↔ ∀ n : ℕ, 0 < n → x ^ n ≠ 1 :=
by simp_rw [order_of_eq_zero_iff, is_of_fin_order_iff_pow_eq_one, not_exists, not_and]
/-- A group element has finite order iff its order is positive. -/
@[to_additive add_order_of_pos_iff
"A group element has finite additive order iff its order is positive."]
lemma order_of_pos_iff : 0 < order_of x ↔ is_of_fin_order x :=
by rwa [iff_not_comm.mp order_of_eq_zero_iff, pos_iff_ne_zero]
@[to_additive nsmul_ne_zero_of_lt_add_order_of']
lemma pow_ne_one_of_lt_order_of' (n0 : n ≠ 0) (h : n < order_of x) : x ^ n ≠ 1 :=
λ j, not_is_periodic_pt_of_pos_of_lt_minimal_period n0 h
((is_periodic_pt_mul_iff_pow_eq_one x).mpr j)
@[to_additive add_order_of_le_of_nsmul_eq_zero]
lemma order_of_le_of_pow_eq_one (hn : 0 < n) (h : x ^ n = 1) : order_of x ≤ n :=
is_periodic_pt.minimal_period_le hn (by rwa is_periodic_pt_mul_iff_pow_eq_one)
@[simp, to_additive] lemma order_of_one : order_of (1 : G) = 1 :=
by rw [order_of, one_mul_eq_id, minimal_period_id]
@[simp, to_additive add_monoid.order_of_eq_one_iff] lemma order_of_eq_one_iff :
order_of x = 1 ↔ x = 1 :=
by rw [order_of, is_fixed_point_iff_minimal_period_eq_one, is_fixed_pt, mul_one]
@[to_additive nsmul_eq_mod_add_order_of]
lemma pow_eq_mod_order_of {n : ℕ} : x ^ n = x ^ (n % order_of x) :=
calc x ^ n = x ^ (n % order_of x + order_of x * (n / order_of x)) : by rw [nat.mod_add_div]
... = x ^ (n % order_of x) : by simp [pow_add, pow_mul, pow_order_of_eq_one]
@[to_additive add_order_of_dvd_of_nsmul_eq_zero]
lemma order_of_dvd_of_pow_eq_one (h : x ^ n = 1) : order_of x ∣ n :=
is_periodic_pt.minimal_period_dvd ((is_periodic_pt_mul_iff_pow_eq_one _).mpr h)
@[to_additive add_order_of_dvd_iff_nsmul_eq_zero]
lemma order_of_dvd_iff_pow_eq_one {n : ℕ} : order_of x ∣ n ↔ x ^ n = 1 :=
⟨λ h, by rw [pow_eq_mod_order_of, nat.mod_eq_zero_of_dvd h, pow_zero], order_of_dvd_of_pow_eq_one⟩
@[to_additive add_order_of_map_dvd]
lemma order_of_map_dvd {H : Type*} [monoid H] (ψ : G →* H) (x : G) :
order_of (ψ x) ∣ order_of x :=
by { apply order_of_dvd_of_pow_eq_one, rw [←map_pow, pow_order_of_eq_one], apply map_one }
@[to_additive]
lemma exists_pow_eq_self_of_coprime (h : n.coprime (order_of x)) :
∃ m : ℕ, (x ^ n) ^ m = x :=
begin
by_cases h0 : order_of x = 0,
{ rw [h0, coprime_zero_right] at h,
exact ⟨1, by rw [h, pow_one, pow_one]⟩ },
by_cases h1 : order_of x = 1,
{ exact ⟨0, by rw [order_of_eq_one_iff.mp h1, one_pow, one_pow]⟩ },
obtain ⟨m, hm⟩ :=
exists_mul_mod_eq_one_of_coprime h (one_lt_iff_ne_zero_and_ne_one.mpr ⟨h0, h1⟩),
exact ⟨m, by rw [←pow_mul, pow_eq_mod_order_of, hm, pow_one]⟩,
end
/-- If `x^n = 1`, but `x^(n/p) ≠ 1` for all prime factors `p` of `n`, then `x` has order `n` in `G`.
-/
@[to_additive add_order_of_eq_of_nsmul_and_div_prime_nsmul "If `n * x = 0`, but `n/p * x ≠ 0` for
all prime factors `p` of `n`, then `x` has order `n` in `G`."]
theorem order_of_eq_of_pow_and_pow_div_prime (hn : 0 < n) (hx : x^n = 1)
(hd : ∀ p : ℕ, p.prime → p ∣ n → x^(n/p) ≠ 1) :
order_of x = n :=
begin
-- Let `a` be `n/(order_of x)`, and show `a = 1`
cases exists_eq_mul_right_of_dvd (order_of_dvd_of_pow_eq_one hx) with a ha,
suffices : a = 1, by simp [this, ha],
-- Assume `a` is not one...
by_contra,
have a_min_fac_dvd_p_sub_one : a.min_fac ∣ n,
{ obtain ⟨b, hb⟩ : ∃ (b : ℕ), a = b * a.min_fac := exists_eq_mul_left_of_dvd a.min_fac_dvd,
rw [hb, ←mul_assoc] at ha,
exact dvd.intro_left (order_of x * b) ha.symm, },
-- Use the minimum prime factor of `a` as `p`.
refine hd a.min_fac (nat.min_fac_prime h) a_min_fac_dvd_p_sub_one _,
rw [←order_of_dvd_iff_pow_eq_one, nat.dvd_div_iff (a_min_fac_dvd_p_sub_one),
ha, mul_comm, nat.mul_dvd_mul_iff_left (order_of_pos' _)],
{ exact nat.min_fac_dvd a, },
{ rw is_of_fin_order_iff_pow_eq_one,
exact Exists.intro n (id ⟨hn, hx⟩) },
end
@[to_additive add_order_of_eq_add_order_of_iff]
lemma order_of_eq_order_of_iff {H : Type*} [monoid H] {y : H} :
order_of x = order_of y ↔ ∀ n : ℕ, x ^ n = 1 ↔ y ^ n = 1 :=
by simp_rw [← is_periodic_pt_mul_iff_pow_eq_one, ← minimal_period_eq_minimal_period_iff, order_of]
@[to_additive add_order_of_injective]
lemma order_of_injective {H : Type*} [monoid H] (f : G →* H)
(hf : function.injective f) (x : G) : order_of (f x) = order_of x :=
by simp_rw [order_of_eq_order_of_iff, ←f.map_pow, ←f.map_one, hf.eq_iff, iff_self, forall_const]
@[simp, norm_cast, to_additive] lemma order_of_submonoid {H : submonoid G}
(y : H) : order_of (y : G) = order_of y :=
order_of_injective H.subtype subtype.coe_injective y
@[to_additive]
lemma order_of_units {y : Gˣ} : order_of (y : G) = order_of y :=
order_of_injective (units.coe_hom G) units.ext y
variables (x)
@[to_additive add_order_of_nsmul']
lemma order_of_pow' (h : n ≠ 0) :
order_of (x ^ n) = order_of x / gcd (order_of x) n :=
begin
convert minimal_period_iterate_eq_div_gcd h,
simp only [order_of, mul_left_iterate],
end
variables (a) (n)
@[to_additive add_order_of_nsmul'']
lemma order_of_pow'' (h : is_of_fin_order x) :
order_of (x ^ n) = order_of x / gcd (order_of x) n :=
begin
convert minimal_period_iterate_eq_div_gcd' h,
simp only [order_of, mul_left_iterate],
end
@[to_additive]
lemma commute.order_of_mul_dvd_lcm {x y : G} (h : commute x y) :
order_of (x * y) ∣ nat.lcm (order_of x) (order_of y) :=
begin
convert function.commute.minimal_period_of_comp_dvd_lcm h.function_commute_mul_left,
rw [order_of, comp_mul_left],
end
@[to_additive add_order_of_add_dvd_mul_add_order_of]
lemma commute.order_of_mul_dvd_mul_order_of {x y : G} (h : commute x y) :
order_of (x * y) ∣ (order_of x) * (order_of y) :=
dvd_trans h.order_of_mul_dvd_lcm (lcm_dvd_mul _ _)
@[to_additive add_order_of_add_eq_mul_add_order_of_of_coprime]
lemma commute.order_of_mul_eq_mul_order_of_of_coprime {x y : G} (h : commute x y)
(hco : nat.coprime (order_of x) (order_of y)) :
order_of (x * y) = (order_of x) * (order_of y) :=
begin
convert h.function_commute_mul_left.minimal_period_of_comp_eq_mul_of_coprime hco,
simp only [order_of, comp_mul_left],
end
/-- Commuting elements of finite order are closed under multiplication. -/
@[to_additive "Commuting elements of finite additive order are closed under addition."]
lemma commute.is_of_fin_order_mul
{x} (h : commute x y) (hx : is_of_fin_order x) (hy : is_of_fin_order y) :
is_of_fin_order (x * y) :=
order_of_pos_iff.mp $
pos_of_dvd_of_pos h.order_of_mul_dvd_mul_order_of $ mul_pos (order_of_pos' hx) (order_of_pos' hy)
section p_prime
variables {a x n} {p : ℕ} [hp : fact p.prime]
include hp
@[to_additive add_order_of_eq_prime]
lemma order_of_eq_prime (hg : x ^ p = 1) (hg1 : x ≠ 1) : order_of x = p :=
minimal_period_eq_prime ((is_periodic_pt_mul_iff_pow_eq_one _).mpr hg)
(by rwa [is_fixed_pt, mul_one])
@[to_additive add_order_of_eq_prime_pow]
lemma order_of_eq_prime_pow (hnot : ¬ x ^ p ^ n = 1) (hfin : x ^ p ^ (n + 1) = 1) :
order_of x = p ^ (n + 1) :=
begin
apply minimal_period_eq_prime_pow;
rwa is_periodic_pt_mul_iff_pow_eq_one,
end
@[to_additive exists_add_order_of_eq_prime_pow_iff]
lemma exists_order_of_eq_prime_pow_iff :
(∃ k : ℕ, order_of x = p ^ k) ↔ (∃ m : ℕ, x ^ (p : ℕ) ^ m = 1) :=
⟨λ ⟨k, hk⟩, ⟨k, by rw [←hk, pow_order_of_eq_one]⟩, λ ⟨_, hm⟩,
begin
obtain ⟨k, _, hk⟩ := (nat.dvd_prime_pow hp.elim).mp (order_of_dvd_of_pow_eq_one hm),
exact ⟨k, hk⟩,
end⟩
omit hp
-- An example on how to determine the order of an element of a finite group.
example : order_of (-1 : ℤˣ) = 2 :=
order_of_eq_prime (int.units_sq _) dec_trivial
end p_prime
end monoid_add_monoid
section cancel_monoid
variables [left_cancel_monoid G] (x y)
@[to_additive nsmul_injective_of_lt_add_order_of]
lemma pow_injective_of_lt_order_of
(hn : n < order_of x) (hm : m < order_of x) (eq : x ^ n = x ^ m) : n = m :=
eq_of_lt_minimal_period_of_iterate_eq hn hm (by simpa only [mul_left_iterate, mul_one])
@[to_additive mem_multiples_iff_mem_range_add_order_of']
lemma mem_powers_iff_mem_range_order_of' [decidable_eq G] (hx : 0 < order_of x) :
y ∈ submonoid.powers x ↔ y ∈ (finset.range (order_of x)).image ((^) x : ℕ → G) :=
finset.mem_range_iff_mem_finset_range_of_mod_eq' hx (λ i, pow_eq_mod_order_of.symm)
lemma pow_eq_one_iff_modeq : x ^ n = 1 ↔ n ≡ 0 [MOD (order_of x)] :=
by rw [modeq_zero_iff_dvd, order_of_dvd_iff_pow_eq_one]
lemma pow_eq_pow_iff_modeq : x ^ n = x ^ m ↔ n ≡ m [MOD (order_of x)] :=
begin
wlog hmn : m ≤ n,
obtain ⟨k, rfl⟩ := nat.exists_eq_add_of_le hmn,
rw [← mul_one (x ^ m), pow_add, mul_left_cancel_iff, pow_eq_one_iff_modeq],
exact ⟨λ h, nat.modeq.add_left _ h, λ h, nat.modeq.add_left_cancel' _ h⟩,
end
end cancel_monoid
section group
variables [group G] [add_group A] {x a} {i : ℤ}
/-- Inverses of elements of finite order have finite order. -/
@[to_additive "Inverses of elements of finite additive order have finite additive order."]
lemma is_of_fin_order.inv {x : G} (hx : is_of_fin_order x) : is_of_fin_order x⁻¹ :=
(is_of_fin_order_iff_pow_eq_one _).mpr $ begin
rcases (is_of_fin_order_iff_pow_eq_one x).mp hx with ⟨n, npos, hn⟩,
refine ⟨n, npos, by simp_rw [inv_pow, hn, inv_one]⟩,
end
/-- Inverses of elements of finite order have finite order. -/
@[simp, to_additive "Inverses of elements of finite additive order have finite additive order."]
lemma is_of_fin_order_inv_iff {x : G} : is_of_fin_order x⁻¹ ↔ is_of_fin_order x :=
⟨λ h, inv_inv x ▸ h.inv, is_of_fin_order.inv⟩
@[to_additive add_order_of_dvd_iff_zsmul_eq_zero]
lemma order_of_dvd_iff_zpow_eq_one : (order_of x : ℤ) ∣ i ↔ x ^ i = 1 :=
begin
rcases int.eq_coe_or_neg i with ⟨i, rfl|rfl⟩,
{ rw [int.coe_nat_dvd, order_of_dvd_iff_pow_eq_one, zpow_coe_nat] },
{ rw [dvd_neg, int.coe_nat_dvd, zpow_neg, inv_eq_one, zpow_coe_nat,
order_of_dvd_iff_pow_eq_one] }
end
@[simp, to_additive]
lemma order_of_inv (x : G) : order_of x⁻¹ = order_of x :=
by simp [order_of_eq_order_of_iff]
@[simp, norm_cast, to_additive] lemma order_of_subgroup {H : subgroup G}
(y: H) : order_of (y : G) = order_of y :=
order_of_injective H.subtype subtype.coe_injective y
@[to_additive zsmul_eq_mod_add_order_of]
lemma zpow_eq_mod_order_of : x ^ i = x ^ (i % order_of x) :=
calc x ^ i = x ^ (i % order_of x + order_of x * (i / order_of x)) :
by rw [int.mod_add_div]
... = x ^ (i % order_of x) :
by simp [zpow_add, zpow_mul, pow_order_of_eq_one]
@[to_additive nsmul_inj_iff_of_add_order_of_eq_zero]
lemma pow_inj_iff_of_order_of_eq_zero (h : order_of x = 0) {n m : ℕ} :
x ^ n = x ^ m ↔ n = m :=
begin
rw [order_of_eq_zero_iff, is_of_fin_order_iff_pow_eq_one] at h,
push_neg at h,
induction n with n IH generalizing m,
{ cases m,
{ simp },
{ simpa [eq_comm] using h m.succ m.zero_lt_succ } },
{ cases m,
{ simpa using h n.succ n.zero_lt_succ },
{ simp [pow_succ, IH] } }
end
@[to_additive]
lemma pow_inj_mod {n m : ℕ} :
x ^ n = x ^ m ↔ n % order_of x = m % order_of x :=
begin
cases (order_of x).zero_le.eq_or_lt with hx hx,
{ simp [pow_inj_iff_of_order_of_eq_zero, hx.symm] },
rw [pow_eq_mod_order_of, @pow_eq_mod_order_of _ _ _ m],
exact ⟨pow_injective_of_lt_order_of _ (nat.mod_lt _ hx) (nat.mod_lt _ hx), λ h, congr_arg _ h⟩
end
end group
section comm_monoid
variables [comm_monoid G]
/-- Elements of finite order are closed under multiplication. -/
@[to_additive "Elements of finite additive order are closed under addition."]
lemma is_of_fin_order.mul (hx : is_of_fin_order x) (hy : is_of_fin_order y) :
is_of_fin_order (x * y) :=
(commute.all x y).is_of_fin_order_mul hx hy
end comm_monoid
section finite_monoid
variables [monoid G]
open_locale big_operators
@[to_additive sum_card_add_order_of_eq_card_nsmul_eq_zero]
lemma sum_card_order_of_eq_card_pow_eq_one [fintype G] [decidable_eq G] (hn : 0 < n) :
∑ m in (finset.range n.succ).filter (∣ n), (finset.univ.filter (λ x : G, order_of x = m)).card
= (finset.univ.filter (λ x : G, x ^ n = 1)).card :=
calc ∑ m in (finset.range n.succ).filter (∣ n), (finset.univ.filter (λ x : G, order_of x = m)).card
= _ : (finset.card_bUnion (by { intros, apply finset.disjoint_filter.2, cc })).symm
... = _ : congr_arg finset.card (finset.ext (begin
assume x,
suffices : order_of x ≤ n ∧ order_of x ∣ n ↔ x ^ n = 1,
{ simpa [nat.lt_succ_iff], },
exact ⟨λ h, let ⟨m, hm⟩ := h.2 in by rw [hm, pow_mul, pow_order_of_eq_one, one_pow],
λ h, ⟨order_of_le_of_pow_eq_one hn h, order_of_dvd_of_pow_eq_one h⟩⟩
end))
end finite_monoid
section finite_cancel_monoid
-- TODO: Of course everything also works for right_cancel_monoids.
variables [left_cancel_monoid G] [add_left_cancel_monoid A]
-- TODO: Use this to show that a finite left cancellative monoid is a group.
@[to_additive]
lemma exists_pow_eq_one [finite G] (x : G) : is_of_fin_order x :=
begin
refine (is_of_fin_order_iff_pow_eq_one _).mpr _,
obtain ⟨i, j, a_eq, ne⟩ : ∃(i j : ℕ), x ^ i = x ^ j ∧ i ≠ j :=
by simpa only [not_forall, exists_prop, injective]
using (not_injective_infinite_finite (λi:ℕ, x^i)),
wlog h'' : j ≤ i,
refine ⟨i - j, tsub_pos_of_lt (lt_of_le_of_ne h'' ne.symm), mul_right_injective (x^j) _⟩,
rw [mul_one, ← pow_add, ← a_eq, add_tsub_cancel_of_le h''],
end
@[to_additive add_order_of_le_card_univ]
lemma order_of_le_card_univ [fintype G] : order_of x ≤ fintype.card G :=
finset.le_card_of_inj_on_range ((^) x)
(assume n _, finset.mem_univ _)
(assume i hi j hj, pow_injective_of_lt_order_of x hi hj)
/-- This is the same as `order_of_pos' but with one fewer explicit assumption since this is
automatic in case of a finite cancellative monoid.-/
@[to_additive add_order_of_pos
"This is the same as `add_order_of_pos' but with one fewer explicit assumption since this is
automatic in case of a finite cancellative additive monoid."]
lemma order_of_pos [finite G] (x : G) : 0 < order_of x := order_of_pos' (exists_pow_eq_one x)
open nat
/-- This is the same as `order_of_pow'` and `order_of_pow''` but with one assumption less which is
automatic in the case of a finite cancellative monoid.-/
@[to_additive add_order_of_nsmul
"This is the same as `add_order_of_nsmul'` and `add_order_of_nsmul` but with one assumption less
which is automatic in the case of a finite cancellative additive monoid."]
lemma order_of_pow [finite G] (x : G) :
order_of (x ^ n) = order_of x / gcd (order_of x) n := order_of_pow'' _ _ (exists_pow_eq_one _)
@[to_additive mem_multiples_iff_mem_range_add_order_of]
lemma mem_powers_iff_mem_range_order_of [finite G] [decidable_eq G] :
y ∈ submonoid.powers x ↔ y ∈ (finset.range (order_of x)).image ((^) x : ℕ → G) :=
finset.mem_range_iff_mem_finset_range_of_mod_eq' (order_of_pos x)
(assume i, pow_eq_mod_order_of.symm)
@[to_additive decidable_multiples]
noncomputable instance decidable_powers : decidable_pred (∈ submonoid.powers x) :=
classical.dec_pred _
/--The equivalence between `fin (order_of x)` and `submonoid.powers x`, sending `i` to `x ^ i`."-/
@[to_additive fin_equiv_multiples "The equivalence between `fin (add_order_of a)` and
`add_submonoid.multiples a`, sending `i` to `i • a`."]
noncomputable def fin_equiv_powers [finite G] (x : G) :
fin (order_of x) ≃ (submonoid.powers x : set G) :=
equiv.of_bijective (λ n, ⟨x ^ ↑n, ⟨n, rfl⟩⟩) ⟨λ ⟨i, hi⟩ ⟨j, hj⟩ ij,
subtype.mk_eq_mk.2 (pow_injective_of_lt_order_of x hi hj (subtype.mk_eq_mk.1 ij)),
λ ⟨_, i, rfl⟩, ⟨⟨i % order_of x, mod_lt i (order_of_pos x)⟩, subtype.eq pow_eq_mod_order_of.symm⟩⟩
@[simp, to_additive fin_equiv_multiples_apply]
lemma fin_equiv_powers_apply [finite G] {x : G} {n : fin (order_of x)} :
fin_equiv_powers x n = ⟨x ^ ↑n, n, rfl⟩ := rfl
@[simp, to_additive fin_equiv_multiples_symm_apply]
lemma fin_equiv_powers_symm_apply [finite G] (x : G) (n : ℕ)
{hn : ∃ (m : ℕ), x ^ m = x ^ n} :
((fin_equiv_powers x).symm ⟨x ^ n, hn⟩) = ⟨n % order_of x, nat.mod_lt _ (order_of_pos x)⟩ :=
by rw [equiv.symm_apply_eq, fin_equiv_powers_apply, subtype.mk_eq_mk,
pow_eq_mod_order_of, fin.coe_mk]
/-- The equivalence between `submonoid.powers` of two elements `x, y` of the same order, mapping
`x ^ i` to `y ^ i`. -/
@[to_additive multiples_equiv_multiples
"The equivalence between `submonoid.multiples` of two elements `a, b` of the same additive order,
mapping `i • a` to `i • b`."]
noncomputable def powers_equiv_powers [finite G] (h : order_of x = order_of y) :
(submonoid.powers x : set G) ≃ (submonoid.powers y : set G) :=
(fin_equiv_powers x).symm.trans ((fin.cast h).to_equiv.trans (fin_equiv_powers y))
@[simp, to_additive multiples_equiv_multiples_apply]
lemma powers_equiv_powers_apply [finite G] (h : order_of x = order_of y)
(n : ℕ) : powers_equiv_powers h ⟨x ^ n, n, rfl⟩ = ⟨y ^ n, n, rfl⟩ :=
begin
rw [powers_equiv_powers, equiv.trans_apply, equiv.trans_apply,
fin_equiv_powers_symm_apply, ← equiv.eq_symm_apply, fin_equiv_powers_symm_apply],
simp [h]
end
@[to_additive add_order_of_eq_card_multiples]
lemma order_eq_card_powers [fintype G] : order_of x = fintype.card (submonoid.powers x : set G) :=
(fintype.card_fin (order_of x)).symm.trans (fintype.card_eq.2 ⟨fin_equiv_powers x⟩)
end finite_cancel_monoid
section finite_group
variables [group G] [add_group A]
@[to_additive]
lemma exists_zpow_eq_one [finite G] (x : G) : ∃ (i : ℤ) (H : i ≠ 0), x ^ (i : ℤ) = 1 :=
begin
rcases exists_pow_eq_one x with ⟨w, hw1, hw2⟩,
refine ⟨w, int.coe_nat_ne_zero.mpr (ne_of_gt hw1), _⟩,
rw zpow_coe_nat,
exact (is_periodic_pt_mul_iff_pow_eq_one _).mp hw2,
end
open subgroup
@[to_additive mem_multiples_iff_mem_zmultiples]
lemma mem_powers_iff_mem_zpowers [finite G] : y ∈ submonoid.powers x ↔ y ∈ zpowers x :=
⟨λ ⟨n, hn⟩, ⟨n, by simp * at *⟩,
λ ⟨i, hi⟩, ⟨(i % order_of x).nat_abs,
by rwa [← zpow_coe_nat, int.nat_abs_of_nonneg (int.mod_nonneg _
(int.coe_nat_ne_zero_iff_pos.2 (order_of_pos x))),
← zpow_eq_mod_order_of]⟩⟩
@[to_additive multiples_eq_zmultiples]
lemma powers_eq_zpowers [finite G] (x : G) : (submonoid.powers x : set G) = zpowers x :=
set.ext $ λ x, mem_powers_iff_mem_zpowers
@[to_additive mem_zmultiples_iff_mem_range_add_order_of]
lemma mem_zpowers_iff_mem_range_order_of [finite G] [decidable_eq G] :
y ∈ subgroup.zpowers x ↔ y ∈ (finset.range (order_of x)).image ((^) x : ℕ → G) :=
by rw [← mem_powers_iff_mem_zpowers, mem_powers_iff_mem_range_order_of]
@[to_additive decidable_zmultiples]
noncomputable instance decidable_zpowers : decidable_pred (∈ subgroup.zpowers x) :=
classical.dec_pred _
/-- The equivalence between `fin (order_of x)` and `subgroup.zpowers x`, sending `i` to `x ^ i`. -/
@[to_additive fin_equiv_zmultiples
"The equivalence between `fin (add_order_of a)` and `subgroup.zmultiples a`, sending `i`
to `i • a`."]
noncomputable def fin_equiv_zpowers [finite G] (x : G) :
fin (order_of x) ≃ (subgroup.zpowers x : set G) :=
(fin_equiv_powers x).trans (equiv.set.of_eq (powers_eq_zpowers x))
@[simp, to_additive fin_equiv_zmultiples_apply]
lemma fin_equiv_zpowers_apply [finite G] {n : fin (order_of x)} :
fin_equiv_zpowers x n = ⟨x ^ (n : ℕ), n, zpow_coe_nat x n⟩ := rfl
@[simp, to_additive fin_equiv_zmultiples_symm_apply]
lemma fin_equiv_zpowers_symm_apply [finite G] (x : G) (n : ℕ)
{hn : ∃ (m : ℤ), x ^ m = x ^ n} :
((fin_equiv_zpowers x).symm ⟨x ^ n, hn⟩) = ⟨n % order_of x, nat.mod_lt _ (order_of_pos x)⟩ :=
by { rw [fin_equiv_zpowers, equiv.symm_trans_apply, equiv.set.of_eq_symm_apply],
exact fin_equiv_powers_symm_apply x n }
/-- The equivalence between `subgroup.zpowers` of two elements `x, y` of the same order, mapping
`x ^ i` to `y ^ i`. -/
@[to_additive zmultiples_equiv_zmultiples
"The equivalence between `subgroup.zmultiples` of two elements `a, b` of the same additive order,
mapping `i • a` to `i • b`."]
noncomputable def zpowers_equiv_zpowers [finite G] (h : order_of x = order_of y) :
(subgroup.zpowers x : set G) ≃ (subgroup.zpowers y : set G) :=
(fin_equiv_zpowers x).symm.trans ((fin.cast h).to_equiv.trans (fin_equiv_zpowers y))
@[simp, to_additive zmultiples_equiv_zmultiples_apply]
lemma zpowers_equiv_zpowers_apply [finite G] (h : order_of x = order_of y)
(n : ℕ) : zpowers_equiv_zpowers h ⟨x ^ n, n, zpow_coe_nat x n⟩ = ⟨y ^ n, n, zpow_coe_nat y n⟩ :=
begin
rw [zpowers_equiv_zpowers, equiv.trans_apply, equiv.trans_apply,
fin_equiv_zpowers_symm_apply, ← equiv.eq_symm_apply, fin_equiv_zpowers_symm_apply],
simp [h]
end
variables [fintype G]
@[to_additive add_order_eq_card_zmultiples]
lemma order_eq_card_zpowers : order_of x = fintype.card (zpowers x) :=
(fintype.card_fin (order_of x)).symm.trans (fintype.card_eq.2 ⟨fin_equiv_zpowers x⟩)
open quotient_group
/- TODO: use cardinal theory, introduce `card : set G → ℕ`, or setup decidability for cosets -/
@[to_additive add_order_of_dvd_card_univ]
lemma order_of_dvd_card_univ : order_of x ∣ fintype.card G :=
begin
classical,
have ft_prod : fintype ((G ⧸ zpowers x) × zpowers x),
from fintype.of_equiv G group_equiv_quotient_times_subgroup,
have ft_s : fintype (zpowers x),
from @fintype.prod_right _ _ _ ft_prod _,
have ft_cosets : fintype (G ⧸ zpowers x),
from @fintype.prod_left _ _ _ ft_prod ⟨⟨1, (zpowers x).one_mem⟩⟩,
have eq₁ : fintype.card G = @fintype.card _ ft_cosets * @fintype.card _ ft_s,
from calc fintype.card G = @fintype.card _ ft_prod :
@fintype.card_congr _ _ _ ft_prod group_equiv_quotient_times_subgroup
... = @fintype.card _ (@prod.fintype _ _ ft_cosets ft_s) :
congr_arg (@fintype.card _) $ subsingleton.elim _ _
... = @fintype.card _ ft_cosets * @fintype.card _ ft_s :
@fintype.card_prod _ _ ft_cosets ft_s,
have eq₂ : order_of x = @fintype.card _ ft_s,
from calc order_of x = _ : order_eq_card_zpowers
... = _ : congr_arg (@fintype.card _) $ subsingleton.elim _ _,
exact dvd.intro (@fintype.card (G ⧸ subgroup.zpowers x) ft_cosets)
(by rw [eq₁, eq₂, mul_comm])
end
@[simp, to_additive card_nsmul_eq_zero]
lemma pow_card_eq_one : x ^ fintype.card G = 1 :=
let ⟨m, hm⟩ := @order_of_dvd_card_univ _ x _ _ in
by simp [hm, pow_mul, pow_order_of_eq_one]
@[to_additive] lemma subgroup.pow_index_mem {G : Type*} [group G] (H : subgroup G)
[finite (G ⧸ H)] [normal H] (g : G) : g ^ index H ∈ H :=
by { casesI nonempty_fintype (G ⧸ H),
rw [←eq_one_iff, quotient_group.coe_pow H, index_eq_card, pow_card_eq_one] }
@[to_additive] lemma pow_eq_mod_card (n : ℕ) :
x ^ n = x ^ (n % fintype.card G) :=
by rw [pow_eq_mod_order_of, ←nat.mod_mod_of_dvd n order_of_dvd_card_univ,
← pow_eq_mod_order_of]
@[to_additive] lemma zpow_eq_mod_card (n : ℤ) :
x ^ n = x ^ (n % fintype.card G) :=
by rw [zpow_eq_mod_order_of, ← int.mod_mod_of_dvd n (int.coe_nat_dvd.2 order_of_dvd_card_univ),
← zpow_eq_mod_order_of]
/-- If `gcd(|G|,n)=1` then the `n`th power map is a bijection -/
@[to_additive "If `gcd(|G|,n)=1` then the smul by `n` is a bijection", simps]
def pow_coprime (h : nat.coprime (fintype.card G) n) : G ≃ G :=
{ to_fun := λ g, g ^ n,
inv_fun := λ g, g ^ (nat.gcd_b (fintype.card G) n),
left_inv := λ g, by
{ have key : g ^ _ = g ^ _ := congr_arg (λ n : ℤ, g ^ n) (nat.gcd_eq_gcd_ab (fintype.card G) n),
rwa [zpow_add, zpow_mul, zpow_mul, zpow_coe_nat, zpow_coe_nat, zpow_coe_nat,
h.gcd_eq_one, pow_one, pow_card_eq_one, one_zpow, one_mul, eq_comm] at key },
right_inv := λ g, by
{ have key : g ^ _ = g ^ _ := congr_arg (λ n : ℤ, g ^ n) (nat.gcd_eq_gcd_ab (fintype.card G) n),
rwa [zpow_add, zpow_mul, zpow_mul', zpow_coe_nat, zpow_coe_nat, zpow_coe_nat,
h.gcd_eq_one, pow_one, pow_card_eq_one, one_zpow, one_mul, eq_comm] at key } }
@[simp, to_additive] lemma pow_coprime_one (h : nat.coprime (fintype.card G) n) :
pow_coprime h 1 = 1 := one_pow n
@[simp, to_additive] lemma pow_coprime_inv (h : nat.coprime (fintype.card G) n) {g : G} :
pow_coprime h g⁻¹ = (pow_coprime h g)⁻¹ := inv_pow g n
@[to_additive add_inf_eq_bot_of_coprime]
lemma inf_eq_bot_of_coprime {G : Type*} [group G] {H K : subgroup G} [fintype H] [fintype K]
(h : nat.coprime (fintype.card H) (fintype.card K)) : H ⊓ K = ⊥ :=
begin
refine (H ⊓ K).eq_bot_iff_forall.mpr (λ x hx, _),
rw [←order_of_eq_one_iff, ←nat.dvd_one, ←h.gcd_eq_one, nat.dvd_gcd_iff],
exact ⟨(congr_arg (∣ fintype.card H) (order_of_subgroup ⟨x, hx.1⟩)).mpr order_of_dvd_card_univ,
(congr_arg (∣ fintype.card K) (order_of_subgroup ⟨x, hx.2⟩)).mpr order_of_dvd_card_univ⟩,
end
variable (a)
/-- TODO: Generalise to `submonoid.powers`.-/
@[to_additive image_range_add_order_of, nolint to_additive_doc]
lemma image_range_order_of [decidable_eq G] :
finset.image (λ i, x ^ i) (finset.range (order_of x)) = (zpowers x : set G).to_finset :=
by { ext x, rw [set.mem_to_finset, set_like.mem_coe, mem_zpowers_iff_mem_range_order_of] }
/-- TODO: Generalise to `finite` + `cancel_monoid`. -/
@[to_additive gcd_nsmul_card_eq_zero_iff "TODO: Generalise to `finite` + `cancel_add_monoid`"]
lemma pow_gcd_card_eq_one_iff : x ^ n = 1 ↔ x ^ (gcd n (fintype.card G)) = 1 :=
⟨λ h, pow_gcd_eq_one _ h $ pow_card_eq_one,
λ h, let ⟨m, hm⟩ := gcd_dvd_left n (fintype.card G) in
by rw [hm, pow_mul, h, one_pow]⟩
end finite_group
section pow_is_subgroup
/-- A nonempty idempotent subset of a finite cancellative monoid is a submonoid -/
@[to_additive "A nonempty idempotent subset of a finite cancellative add monoid is a submonoid"]
def submonoid_of_idempotent {M : Type*} [left_cancel_monoid M] [fintype M] (S : set M)
(hS1 : S.nonempty) (hS2 : S * S = S) : submonoid M :=
have pow_mem : ∀ a : M, a ∈ S → ∀ n : ℕ, a ^ (n + 1) ∈ S :=
λ a ha, nat.rec (by rwa [zero_add, pow_one])
(λ n ih, (congr_arg2 (∈) (pow_succ a (n + 1)).symm hS2).mp (set.mul_mem_mul ha ih)),
{ carrier := S,
one_mem' := by
{ obtain ⟨a, ha⟩ := hS1,
rw [←pow_order_of_eq_one a, ← tsub_add_cancel_of_le (succ_le_of_lt (order_of_pos a))],
exact pow_mem a ha (order_of a - 1) },
mul_mem' := λ a b ha hb, (congr_arg2 (∈) rfl hS2).mp (set.mul_mem_mul ha hb) }
/-- A nonempty idempotent subset of a finite group is a subgroup -/
@[to_additive "A nonempty idempotent subset of a finite add group is a subgroup"]
def subgroup_of_idempotent {G : Type*} [group G] [fintype G] (S : set G)
(hS1 : S.nonempty) (hS2 : S * S = S) : subgroup G :=
{ carrier := S,
inv_mem' := λ a ha, show a⁻¹ ∈ submonoid_of_idempotent S hS1 hS2, by
{ rw [←one_mul a⁻¹, ←pow_one a, ←pow_order_of_eq_one a, ←pow_sub a (order_of_pos a)],
exact pow_mem ha (order_of a - 1) },
.. submonoid_of_idempotent S hS1 hS2 }
/-- If `S` is a nonempty subset of a finite group `G`, then `S ^ |G|` is a subgroup -/
@[to_additive smul_card_add_subgroup "If `S` is a nonempty subset of a finite add group `G`,
then `|G| • S` is a subgroup", simps]
def pow_card_subgroup {G : Type*} [group G] [fintype G] (S : set G) (hS : S.nonempty) :
subgroup G :=
have one_mem : (1 : G) ∈ (S ^ fintype.card G) := by
{ obtain ⟨a, ha⟩ := hS,
rw ← pow_card_eq_one,
exact set.pow_mem_pow ha (fintype.card G) },
subgroup_of_idempotent (S ^ (fintype.card G)) ⟨1, one_mem⟩ begin
classical!,
refine (set.eq_of_subset_of_card_le (set.subset_mul_left _ one_mem) (ge_of_eq _)).symm,
simp_rw [← pow_add, group.card_pow_eq_card_pow_card_univ S (fintype.card G) le_rfl,
group.card_pow_eq_card_pow_card_univ S (fintype.card G + fintype.card G) le_add_self],
end
end pow_is_subgroup
section linear_ordered_ring
variable [linear_ordered_ring G]
lemma order_of_abs_ne_one (h : |x| ≠ 1) : order_of x = 0 :=
begin
rw order_of_eq_zero_iff',
intros n hn hx,
replace hx : |x| ^ n = 1 := by simpa only [abs_one, abs_pow] using congr_arg abs hx,
cases h.lt_or_lt with h h,
{ exact ((pow_lt_one (abs_nonneg x) h hn.ne').ne hx).elim },
{ exact ((one_lt_pow h hn.ne').ne' hx).elim }
end
lemma linear_ordered_ring.order_of_le_two : order_of x ≤ 2 :=
begin
cases ne_or_eq (|x|) 1 with h h,
{ simp [order_of_abs_ne_one h] },
rcases eq_or_eq_neg_of_abs_eq h with rfl | rfl,
{ simp },
apply order_of_le_of_pow_eq_one; norm_num
end
end linear_ordered_ring
|
fb64f37f67366f5cf6e367b080ed7ea5b084d0ef | 618003631150032a5676f229d13a079ac875ff77 | /src/computability/partrec.lean | 8e3cedde34163edb0ecc4f8fb931277bed8582a2 | [
"Apache-2.0"
] | permissive | awainverse/mathlib | 939b68c8486df66cfda64d327ad3d9165248c777 | ea76bd8f3ca0a8bf0a166a06a475b10663dec44a | refs/heads/master | 1,659,592,962,036 | 1,590,987,592,000 | 1,590,987,592,000 | 268,436,019 | 1 | 0 | Apache-2.0 | 1,590,990,500,000 | 1,590,990,500,000 | null | UTF-8 | Lean | false | false | 28,382 | lean | /-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Mario Carneiro
-/
import computability.primrec
import data.pfun
/-!
# The partial recursive functions
The partial recursive functions are defined similarly to the primitive
recursive functions, but now all functions are partial, implemented
using the `roption` monad, and there is an additional operation, called
μ-recursion, which performs unbounded minimization.
## References
* [Mario Carneiro, *Formalizing computability theory via partial recursive functions*][carneiro2019]
-/
open encodable denumerable roption
namespace nat
section rfind
parameter (p : ℕ →. bool)
private def lbp (m n : ℕ) : Prop := m = n + 1 ∧ ∀ k ≤ n, ff ∈ p k
parameter (H : ∃ n, tt ∈ p n ∧ ∀ k < n, (p k).dom)
private def wf_lbp : well_founded lbp :=
⟨let ⟨n, pn⟩ := H in begin
suffices : ∀m k, n ≤ k + m → acc (lbp p) k,
{ from λa, this _ _ (nat.le_add_left _ _) },
intros m k kn,
induction m with m IH generalizing k;
refine ⟨_, λ y r, _⟩; rcases r with ⟨rfl, a⟩,
{ injection mem_unique pn.1 (a _ kn) },
{ exact IH _ (by rw nat.add_right_comm; exact kn) }
end⟩
def rfind_x : {n // tt ∈ p n ∧ ∀m < n, ff ∈ p m} :=
suffices ∀ k, (∀n < k, ff ∈ p n) → {n // tt ∈ p n ∧ ∀m < n, ff ∈ p m},
from this 0 (λ n, (nat.not_lt_zero _).elim),
@well_founded.fix _ _ lbp wf_lbp begin
intros m IH al,
have pm : (p m).dom,
{ rcases H with ⟨n, h₁, h₂⟩,
rcases decidable.lt_trichotomy m n with h₃|h₃|h₃,
{ exact h₂ _ h₃ },
{ rw h₃, exact h₁.fst },
{ injection mem_unique h₁ (al _ h₃) } },
cases e : (p m).get pm,
{ suffices,
exact IH _ ⟨rfl, this⟩ (λ n h, this _ (le_of_lt_succ h)),
intros n h, cases decidable.lt_or_eq_of_le h with h h,
{ exact al _ h },
{ rw h, exact ⟨_, e⟩ } },
{ exact ⟨m, ⟨_, e⟩, al⟩ }
end
end rfind
def rfind (p : ℕ →. bool) : roption ℕ :=
⟨_, λ h, (rfind_x p h).1⟩
theorem rfind_spec {p : ℕ →. bool} {n : ℕ} (h : n ∈ rfind p) : tt ∈ p n :=
h.snd ▸ (rfind_x p h.fst).2.1
theorem rfind_min {p : ℕ →. bool} {n : ℕ} (h : n ∈ rfind p) :
∀ {m : ℕ}, m < n → ff ∈ p m :=
h.snd ▸ (rfind_x p h.fst).2.2
@[simp] theorem rfind_dom {p : ℕ →. bool} :
(rfind p).dom ↔ ∃ n, tt ∈ p n ∧ ∀ {m : ℕ}, m < n → (p m).dom :=
iff.rfl
theorem rfind_dom' {p : ℕ →. bool} :
(rfind p).dom ↔ ∃ n, tt ∈ p n ∧ ∀ {m : ℕ}, m ≤ n → (p m).dom :=
exists_congr $ λ n, and_congr_right $ λ pn,
⟨λ H m h, (eq_or_lt_of_le h).elim (λ e, e.symm ▸ pn.fst) (H _),
λ H m h, H (le_of_lt h)⟩
@[simp] theorem mem_rfind {p : ℕ →. bool} {n : ℕ} :
n ∈ rfind p ↔ tt ∈ p n ∧ ∀ {m : ℕ}, m < n → ff ∈ p m :=
⟨λ h, ⟨rfind_spec h, @rfind_min _ _ h⟩,
λ ⟨h₁, h₂⟩, let ⟨m, hm⟩ := dom_iff_mem.1 $
(@rfind_dom p).2 ⟨_, h₁, λ m mn, (h₂ mn).fst⟩ in
begin
rcases lt_trichotomy m n with h|h|h,
{ injection mem_unique (h₂ h) (rfind_spec hm) },
{ rwa ← h },
{ injection mem_unique h₁ (rfind_min hm h) },
end⟩
theorem rfind_min' {p : ℕ → bool} {m : ℕ} (pm : p m) :
∃ n ∈ rfind p, n ≤ m :=
have tt ∈ (p : ℕ →. bool) m, from ⟨trivial, pm⟩,
let ⟨n, hn⟩ := dom_iff_mem.1 $
(@rfind_dom p).2 ⟨m, this, λ k h, ⟨⟩⟩ in
⟨n, hn, not_lt.1 $ λ h,
by injection mem_unique this (rfind_min hn h)⟩
theorem rfind_zero_none
(p : ℕ →. bool) (p0 : p 0 = none) : rfind p = none :=
eq_none_iff.2 $ λ a h,
let ⟨n, h₁, h₂⟩ := rfind_dom'.1 h.fst in
(p0 ▸ h₂ (zero_le _) : (@roption.none bool).dom)
def rfind_opt {α} (f : ℕ → option α) : roption α :=
(rfind (λ n, (f n).is_some)).bind (λ n, f n)
theorem rfind_opt_spec {α} {f : ℕ → option α} {a}
(h : a ∈ rfind_opt f) : ∃ n, a ∈ f n :=
let ⟨n, h₁, h₂⟩ := mem_bind_iff.1 h in ⟨n, mem_coe.1 h₂⟩
theorem rfind_opt_dom {α} {f : ℕ → option α} :
(rfind_opt f).dom ↔ ∃ n a, a ∈ f n :=
⟨λ h, (rfind_opt_spec ⟨h, rfl⟩).imp (λ n h, ⟨_, h⟩),
λ h, begin
have h' : ∃ n, (f n).is_some :=
h.imp (λ n, option.is_some_iff_exists.2),
have s := nat.find_spec h',
have fd : (rfind (λ n, (f n).is_some)).dom :=
⟨nat.find h', by simpa using s.symm, λ _ _, trivial⟩,
refine ⟨fd, _⟩,
have := rfind_spec (get_mem fd),
simp at this ⊢,
cases option.is_some_iff_exists.1 this.symm with a e,
rw e, trivial
end⟩
theorem rfind_opt_mono {α} {f : ℕ → option α}
(H : ∀ {a m n}, m ≤ n → a ∈ f m → a ∈ f n)
{a} : a ∈ rfind_opt f ↔ ∃ n, a ∈ f n :=
⟨rfind_opt_spec, λ ⟨n, h⟩, begin
have h' := rfind_opt_dom.2 ⟨_, _, h⟩,
cases rfind_opt_spec ⟨h', rfl⟩ with k hk,
have := (H (le_max_left _ _) h).symm.trans
(H (le_max_right _ _) hk),
simp at this, simp [this, get_mem]
end⟩
inductive partrec : (ℕ →. ℕ) → Prop
| zero : partrec (pure 0)
| succ : partrec succ
| left : partrec ↑(λ n : ℕ, n.unpair.1)
| right : partrec ↑(λ n : ℕ, n.unpair.2)
| pair {f g} : partrec f → partrec g → partrec (λ n, mkpair <$> f n <*> g n)
| comp {f g} : partrec f → partrec g → partrec (λ n, g n >>= f)
| prec {f g} : partrec f → partrec g → partrec (unpaired (λ a n,
n.elim (f a) (λ y IH, do i ← IH, g (mkpair a (mkpair y i)))))
| rfind {f} : partrec f → partrec (λ a,
rfind (λ n, (λ m, m = 0) <$> f (mkpair a n)))
namespace partrec
theorem of_eq {f g : ℕ →. ℕ} (hf : partrec f) (H : ∀ n, f n = g n) : partrec g :=
(funext H : f = g) ▸ hf
theorem of_eq_tot {f : ℕ →. ℕ} {g : ℕ → ℕ}
(hf : partrec f) (H : ∀ n, g n ∈ f n) : partrec g :=
hf.of_eq (λ n, eq_some_iff.2 (H n))
theorem of_primrec {f : ℕ → ℕ} (hf : primrec f) : partrec f :=
begin
induction hf,
case nat.primrec.zero { exact zero },
case nat.primrec.succ { exact succ },
case nat.primrec.left { exact left },
case nat.primrec.right { exact right },
case nat.primrec.pair : f g hf hg pf pg {
refine (pf.pair pg).of_eq_tot (λ n, _),
simp [has_seq.seq] },
case nat.primrec.comp : f g hf hg pf pg {
refine (pf.comp pg).of_eq_tot (λ n, _),
simp },
case nat.primrec.prec : f g hf hg pf pg {
refine (pf.prec pg).of_eq_tot (λ n, _),
simp,
induction n.unpair.2 with m IH, {simp},
simp, exact ⟨_, IH, rfl⟩ },
end
protected theorem some : partrec some := of_primrec primrec.id
theorem none : partrec (λ n, none) :=
(of_primrec (nat.primrec.const 1)).rfind.of_eq $
λ n, eq_none_iff.2 $ λ a ⟨h, e⟩, by simpa using h
theorem prec' {f g h}
(hf : partrec f) (hg : partrec g) (hh : partrec h) :
partrec (λ a, (f a).bind (λ n, n.elim (g a)
(λ y IH, do i ← IH, h (mkpair a (mkpair y i))))) :=
((prec hg hh).comp (pair partrec.some hf)).of_eq $
λ a, ext $ λ s, by simp [(<*>)]; exact
⟨λ ⟨n, h₁, h₂⟩, ⟨_, ⟨_, h₁, rfl⟩, by simpa using h₂⟩,
λ ⟨_, ⟨n, h₁, rfl⟩, h₂⟩, ⟨_, h₁, by simpa using h₂⟩⟩
theorem ppred : partrec (λ n, ppred n) :=
have primrec₂ (λ n m, if n = nat.succ m then 0 else 1),
from (primrec.ite
(@@primrec_rel.comp _ _ _ _ _ _ _ primrec.eq
primrec.fst
(_root_.primrec.succ.comp primrec.snd))
(_root_.primrec.const 0) (_root_.primrec.const 1)).to₂,
(of_primrec (primrec₂.unpaired'.2 this)).rfind.of_eq $
λ n, begin
cases n; simp,
{ exact eq_none_iff.2 (λ a ⟨⟨m, h, _⟩, _⟩,
by simpa [show 0 ≠ m.succ, by intro h; injection h] using h) },
{ refine eq_some_iff.2 _,
simp, intros m h, simp [ne_of_gt h] }
end
end partrec
end nat
def partrec {α σ} [primcodable α] [primcodable σ]
(f : α →. σ) := nat.partrec (λ n,
roption.bind (decode α n) (λ a, (f a).map encode))
def partrec₂ {α β σ} [primcodable α] [primcodable β] [primcodable σ]
(f : α → β →. σ) := partrec (λ p : α × β, f p.1 p.2)
def computable {α σ} [primcodable α] [primcodable σ] (f : α → σ) := partrec (f : α →. σ)
def computable₂ {α β σ} [primcodable α] [primcodable β] [primcodable σ]
(f : α → β → σ) := computable (λ p : α × β, f p.1 p.2)
theorem primrec.to_comp {α σ} [primcodable α] [primcodable σ]
{f : α → σ} (hf : primrec f) : computable f :=
(nat.partrec.ppred.comp (nat.partrec.of_primrec hf)).of_eq $
λ n, by simp; cases decode α n; simp
theorem primrec₂.to_comp {α β σ} [primcodable α] [primcodable β] [primcodable σ]
{f : α → β → σ} (hf : primrec₂ f) : computable₂ f := hf.to_comp
theorem computable.part {α σ} [primcodable α] [primcodable σ]
{f : α → σ} (hf : computable f) : partrec (f : α →. σ) := hf
theorem computable₂.part {α β σ} [primcodable α] [primcodable β] [primcodable σ]
{f : α → β → σ} (hf : computable₂ f) : partrec₂ (λ a, (f a : β →. σ)) := hf
namespace computable
variables {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable σ]
theorem of_eq {f g : α → σ} (hf : computable f) (H : ∀ n, f n = g n) : computable g :=
(funext H : f = g) ▸ hf
theorem const (s : σ) : computable (λ a : α, s) :=
(primrec.const _).to_comp
theorem of_option {f : α → option β}
(hf : computable f) : partrec (λ a, (f a : roption β)) :=
(nat.partrec.ppred.comp hf).of_eq $ λ n, begin
cases decode α n with a; simp,
cases f a with b; simp
end
theorem to₂ {f : α × β → σ} (hf : computable f) : computable₂ (λ a b, f (a, b)) :=
hf.of_eq $ λ ⟨a, b⟩, rfl
protected theorem id : computable (@id α) := primrec.id.to_comp
theorem fst : computable (@prod.fst α β) := primrec.fst.to_comp
theorem snd : computable (@prod.snd α β) := primrec.snd.to_comp
theorem pair {f : α → β} {g : α → γ}
(hf : computable f) (hg : computable g) : computable (λ a, (f a, g a)) :=
(hf.pair hg).of_eq $
λ n, by cases decode α n; simp [(<*>)]
theorem unpair : computable nat.unpair := primrec.unpair.to_comp
theorem succ : computable nat.succ := primrec.succ.to_comp
theorem pred : computable nat.pred := primrec.pred.to_comp
theorem nat_bodd : computable nat.bodd := primrec.nat_bodd.to_comp
theorem nat_div2 : computable nat.div2 := primrec.nat_div2.to_comp
theorem sum_inl : computable (@sum.inl α β) := primrec.sum_inl.to_comp
theorem sum_inr : computable (@sum.inr α β) := primrec.sum_inr.to_comp
theorem list_cons : computable₂ (@list.cons α) := primrec.list_cons.to_comp
theorem list_reverse : computable (@list.reverse α) := primrec.list_reverse.to_comp
theorem list_nth : computable₂ (@list.nth α) := primrec.list_nth.to_comp
theorem list_append : computable₂ ((++) : list α → list α → list α) := primrec.list_append.to_comp
theorem list_concat : computable₂ (λ l (a:α), l ++ [a]) := primrec.list_concat.to_comp
theorem list_length : computable (@list.length α) := primrec.list_length.to_comp
theorem vector_cons {n} : computable₂ (@vector.cons α n) := primrec.vector_cons.to_comp
theorem vector_to_list {n} : computable (@vector.to_list α n) := primrec.vector_to_list.to_comp
theorem vector_length {n} : computable (@vector.length α n) := primrec.vector_length.to_comp
theorem vector_head {n} : computable (@vector.head α n) := primrec.vector_head.to_comp
theorem vector_tail {n} : computable (@vector.tail α n) := primrec.vector_tail.to_comp
theorem vector_nth {n} : computable₂ (@vector.nth α n) := primrec.vector_nth.to_comp
theorem vector_nth' {n} : computable (@vector.nth α n) := primrec.vector_nth'.to_comp
theorem vector_of_fn' {n} : computable (@vector.of_fn α n) := primrec.vector_of_fn'.to_comp
theorem fin_app {n} : computable₂ (@id (fin n → σ)) := primrec.fin_app.to_comp
protected theorem encode : computable (@encode α _) :=
primrec.encode.to_comp
protected theorem decode : computable (decode α) :=
primrec.decode.to_comp
protected theorem of_nat (α) [denumerable α] : computable (of_nat α) :=
(primrec.of_nat _).to_comp
theorem encode_iff {f : α → σ} : computable (λ a, encode (f a)) ↔ computable f :=
iff.rfl
theorem option_some : computable (@option.some α) :=
primrec.option_some.to_comp
end computable
namespace partrec
variables {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable σ]
open computable
theorem of_eq {f g : α →. σ} (hf : partrec f) (H : ∀ n, f n = g n) : partrec g :=
(funext H : f = g) ▸ hf
theorem of_eq_tot {f : α →. σ} {g : α → σ}
(hf : partrec f) (H : ∀ n, g n ∈ f n) : computable g :=
hf.of_eq (λ a, eq_some_iff.2 (H a))
theorem none : partrec (λ a : α, @roption.none σ) :=
nat.partrec.none.of_eq $ λ n, by cases decode α n; simp
protected theorem some : partrec (@roption.some α) := computable.id
theorem const' (s : roption σ) : partrec (λ a : α, s) :=
by haveI := classical.dec s.dom; exact
(of_option (const (to_option s))).of_eq (λ a, of_to_option s)
protected theorem bind {f : α →. β} {g : α → β →. σ}
(hf : partrec f) (hg : partrec₂ g) : partrec (λ a, (f a).bind (g a)) :=
(hg.comp (nat.partrec.some.pair hf)).of_eq $
λ n, by simp [(<*>)]; cases e : decode α n with a;
simp [e, encodek]
theorem map {f : α →. β} {g : α → β → σ}
(hf : partrec f) (hg : computable₂ g) : partrec (λ a, (f a).map (g a)) :=
by simpa [bind_some_eq_map] using
@@partrec.bind _ _ _ (λ a b, roption.some (g a b)) hf hg
theorem to₂ {f : α × β →. σ} (hf : partrec f) : partrec₂ (λ a b, f (a, b)) :=
hf.of_eq $ λ ⟨a, b⟩, rfl
theorem nat_elim
{f : α → ℕ} {g : α →. σ} {h : α → ℕ × σ →. σ}
(hf : computable f) (hg : partrec g) (hh : partrec₂ h) :
partrec (λ a, (f a).elim (g a) (λ y IH, IH.bind (λ i, h a (y, i)))) :=
(nat.partrec.prec' hf hg hh).of_eq $ λ n, begin
cases e : decode α n with a; simp [e],
induction f a with m IH; simp,
rw [IH, bind_map],
congr, funext s,
simp [encodek]
end
theorem comp {f : β →. σ} {g : α → β}
(hf : partrec f) (hg : computable g) : partrec (λ a, f (g a)) :=
(hf.comp hg).of_eq $
λ n, by simp; cases e : decode α n with a;
simp [e, encodek]
theorem nat_iff {f : ℕ →. ℕ} : partrec f ↔ nat.partrec f :=
by simp [partrec, map_id']
theorem map_encode_iff {f : α →. σ} : partrec (λ a, (f a).map encode) ↔ partrec f :=
iff.rfl
end partrec
namespace partrec₂
variables {α : Type*} {β : Type*} {γ : Type*} {δ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable δ] [primcodable σ]
theorem unpaired {f : ℕ → ℕ →. α} : partrec (nat.unpaired f) ↔ partrec₂ f :=
⟨λ h, by simpa using h.comp primrec₂.mkpair.to_comp,
λ h, h.comp primrec.unpair.to_comp⟩
theorem unpaired' {f : ℕ → ℕ →. ℕ} : nat.partrec (nat.unpaired f) ↔ partrec₂ f :=
partrec.nat_iff.symm.trans unpaired
theorem comp
{f : β → γ →. σ} {g : α → β} {h : α → γ}
(hf : partrec₂ f) (hg : computable g) (hh : computable h) :
partrec (λ a, f (g a) (h a)) := hf.comp (hg.pair hh)
theorem comp₂
{f : γ → δ →. σ} {g : α → β → γ} {h : α → β → δ}
(hf : partrec₂ f) (hg : computable₂ g) (hh : computable₂ h) :
partrec₂ (λ a b, f (g a b) (h a b)) := hf.comp hg hh
end partrec₂
namespace computable
variables {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable σ]
theorem comp {f : β → σ} {g : α → β}
(hf : computable f) (hg : computable g) :
computable (λ a, f (g a)) := hf.comp hg
theorem comp₂ {f : γ → σ} {g : α → β → γ}
(hf : computable f) (hg : computable₂ g) :
computable₂ (λ a b, f (g a b)) := hf.comp hg
end computable
namespace computable₂
variables {α : Type*} {β : Type*} {γ : Type*} {δ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable δ] [primcodable σ]
theorem comp
{f : β → γ → σ} {g : α → β} {h : α → γ}
(hf : computable₂ f) (hg : computable g) (hh : computable h) :
computable (λ a, f (g a) (h a)) := hf.comp (hg.pair hh)
theorem comp₂
{f : γ → δ → σ} {g : α → β → γ} {h : α → β → δ}
(hf : computable₂ f) (hg : computable₂ g) (hh : computable₂ h) :
computable₂ (λ a b, f (g a b) (h a b)) := hf.comp hg hh
end computable₂
namespace partrec
variables {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable σ]
open computable
theorem rfind {p : α → ℕ →. bool} (hp : partrec₂ p) :
partrec (λ a, nat.rfind (p a)) :=
(nat.partrec.rfind $ hp.map
((primrec.dom_bool (λ b, cond b 0 1))
.comp primrec.snd).to₂.to_comp).of_eq $
λ n, begin
cases e : decode α n with a;
simp [e, nat.rfind_zero_none, map_id'],
congr, funext n,
simp [roption.map_map, (∘)],
apply map_id' (λ b, _),
cases b; refl
end
theorem rfind_opt {f : α → ℕ → option σ} (hf : computable₂ f) :
partrec (λ a, nat.rfind_opt (f a)) :=
(rfind (primrec.option_is_some.to_comp.comp hf).part.to₂).bind
(of_option hf)
theorem nat_cases_right
{f : α → ℕ} {g : α → σ} {h : α → ℕ →. σ}
(hf : computable f) (hg : computable g) (hh : partrec₂ h) :
partrec (λ a, (f a).cases (some (g a)) (h a)) :=
(nat_elim hf hg (hh.comp fst (pred.comp $ hf.comp fst)).to₂).of_eq $
λ a, begin
simp, cases f a; simp,
refine ext (λ b, ⟨λ H, _, λ H, _⟩),
{ rcases mem_bind_iff.1 H with ⟨c, h₁, h₂⟩, exact h₂ },
{ have : ∀ m, (nat.elim (roption.some (g a))
(λ y IH, IH.bind (λ _, h a n)) m).dom,
{ intro, induction m; simp [*, H.fst] },
exact ⟨⟨this n, H.fst⟩, H.snd⟩ }
end
theorem bind_decode2_iff {f : α →. σ} : partrec f ↔
nat.partrec (λ n, roption.bind (decode2 α n) (λ a, (f a).map encode)) :=
⟨λ hf, nat_iff.1 $ (of_option primrec.decode2.to_comp).bind $
(map hf (computable.encode.comp snd).to₂).comp snd,
λ h, map_encode_iff.1 $ by simpa [encodek2]
using (nat_iff.2 h).comp (@computable.encode α _)⟩
theorem vector_m_of_fn : ∀ {n} {f : fin n → α →. σ}, (∀ i, partrec (f i)) →
partrec (λ (a : α), vector.m_of_fn (λ i, f i a))
| 0 f hf := const _
| (n+1) f hf := by simp [vector.m_of_fn]; exact
(hf 0).bind (partrec.bind ((vector_m_of_fn (λ i, hf i.succ)).comp fst)
(primrec.vector_cons.to_comp.comp (snd.comp fst) snd))
end partrec
@[simp] theorem vector.m_of_fn_roption_some {α n} : ∀ (f : fin n → α),
vector.m_of_fn (λ i, roption.some (f i)) = roption.some (vector.of_fn f) :=
vector.m_of_fn_pure
namespace computable
variables {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable σ]
theorem option_some_iff {f : α → σ} : computable (λ a, some (f a)) ↔ computable f :=
⟨λ h, encode_iff.1 $ primrec.pred.to_comp.comp $ encode_iff.2 h,
option_some.comp⟩
theorem bind_decode_iff {f : α → β → option σ} : computable₂ (λ a n,
(decode β n).bind (f a)) ↔ computable₂ f :=
⟨λ hf, nat.partrec.of_eq
(((partrec.nat_iff.2 (nat.partrec.ppred.comp $
nat.partrec.of_primrec $ primcodable.prim β)).comp snd).bind
(computable.comp hf fst).to₂.part) $
λ n, by simp;
cases decode α n.unpair.1; simp;
cases decode β n.unpair.2; simp,
λ hf, begin
have : partrec (λ a : α × ℕ, (encode (decode β a.2)).cases
(some option.none) (λ n, roption.map (f a.1) (decode β n))) :=
partrec.nat_cases_right (primrec.encdec.to_comp.comp snd)
(const none) ((of_option (computable.decode.comp snd)).map
(hf.comp (fst.comp $ fst.comp fst) snd).to₂),
refine this.of_eq (λ a, _),
simp, cases decode β a.2; simp [encodek]
end⟩
theorem map_decode_iff {f : α → β → σ} : computable₂ (λ a n,
(decode β n).map (f a)) ↔ computable₂ f :=
bind_decode_iff.trans option_some_iff
theorem nat_elim
{f : α → ℕ} {g : α → σ} {h : α → ℕ × σ → σ}
(hf : computable f) (hg : computable g) (hh : computable₂ h) :
computable (λ a, (f a).elim (g a) (λ y IH, h a (y, IH))) :=
(partrec.nat_elim hf hg hh.part).of_eq $
λ a, by simp; induction f a; simp *
theorem nat_cases {f : α → ℕ} {g : α → σ} {h : α → ℕ → σ}
(hf : computable f) (hg : computable g) (hh : computable₂ h) :
computable (λ a, (f a).cases (g a) (h a)) :=
nat_elim hf hg (hh.comp fst $ fst.comp snd).to₂
theorem cond {c : α → bool} {f : α → σ} {g : α → σ}
(hc : computable c) (hf : computable f) (hg : computable g) :
computable (λ a, cond (c a) (f a) (g a)) :=
(nat_cases (encode_iff.2 hc) hg (hf.comp fst).to₂).of_eq $
λ a, by cases c a; refl
theorem option_cases {o : α → option β} {f : α → σ} {g : α → β → σ}
(ho : computable o) (hf : computable f) (hg : computable₂ g) :
@computable _ σ _ _ (λ a, option.cases_on (o a) (f a) (g a)) :=
option_some_iff.1 $
(nat_cases (encode_iff.2 ho) (option_some_iff.2 hf)
(map_decode_iff.2 hg)).of_eq $
λ a, by cases o a; simp [encodek]; refl
theorem option_bind {f : α → option β} {g : α → β → option σ}
(hf : computable f) (hg : computable₂ g) :
computable (λ a, (f a).bind (g a)) :=
(option_cases hf (const option.none) hg).of_eq $
λ a, by cases f a; refl
theorem option_map {f : α → option β} {g : α → β → σ}
(hf : computable f) (hg : computable₂ g) : computable (λ a, (f a).map (g a)) :=
option_bind hf (option_some.comp₂ hg)
theorem sum_cases
{f : α → β ⊕ γ} {g : α → β → σ} {h : α → γ → σ}
(hf : computable f) (hg : computable₂ g) (hh : computable₂ h) :
@computable _ σ _ _ (λ a, sum.cases_on (f a) (g a) (h a)) :=
option_some_iff.1 $
(cond (nat_bodd.comp $ encode_iff.2 hf)
(option_map (computable.decode.comp $ nat_div2.comp $ encode_iff.2 hf) hh)
(option_map (computable.decode.comp $ nat_div2.comp $ encode_iff.2 hf) hg)).of_eq $
λ a, by cases f a with b c;
simp [nat.div2_bit, nat.bodd_bit, encodek]; refl
theorem nat_strong_rec
(f : α → ℕ → σ) {g : α → list σ → option σ} (hg : computable₂ g)
(H : ∀ a n, g a ((list.range n).map (f a)) = some (f a n)) : computable₂ f :=
suffices computable₂ (λ a n, (list.range n).map (f a)), from
option_some_iff.1 $
(list_nth.comp (this.comp fst (succ.comp snd)) snd).to₂.of_eq $
λ a, by simp [list.nth_range (nat.lt_succ_self a.2)]; refl,
option_some_iff.1 $
(nat_elim snd (const (option.some [])) (to₂ $
option_bind (snd.comp snd) $ to₂ $
option_map
(hg.comp (fst.comp $ fst.comp fst) snd)
(to₂ $ list_concat.comp (snd.comp fst) snd))).of_eq $
λ a, begin
simp, induction a.2 with n IH, {refl},
simp [IH, H, list.range_concat]
end
theorem list_of_fn : ∀ {n} {f : fin n → α → σ},
(∀ i, computable (f i)) → computable (λ a, list.of_fn (λ i, f i a))
| 0 f hf := const []
| (n+1) f hf := by simp [list.of_fn_succ]; exact
list_cons.comp (hf 0) (list_of_fn (λ i, hf i.succ))
theorem vector_of_fn {n} {f : fin n → α → σ}
(hf : ∀ i, computable (f i)) : computable (λ a, vector.of_fn (λ i, f i a)) :=
(partrec.vector_m_of_fn hf).of_eq $ λ a, by simp
end computable
namespace partrec
variables {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variables [primcodable α] [primcodable β] [primcodable γ] [primcodable σ]
open computable
theorem option_some_iff {f : α →. σ} :
partrec (λ a, (f a).map option.some) ↔ partrec f :=
⟨λ h, (nat.partrec.ppred.comp h).of_eq $
λ n, by simp [roption.bind_assoc, bind_some_eq_map],
λ hf, hf.map (option_some.comp snd).to₂⟩
theorem option_cases_right {o : α → option β} {f : α → σ} {g : α → β →. σ}
(ho : computable o) (hf : computable f) (hg : partrec₂ g) :
@partrec _ σ _ _ (λ a, option.cases_on (o a) (some (f a)) (g a)) :=
have partrec (λ (a : α), nat.cases (roption.some (f a))
(λ n, roption.bind (decode β n) (g a)) (encode (o a))) :=
nat_cases_right (encode_iff.2 ho) hf.part $
((@computable.decode β _).comp snd).of_option.bind
(hg.comp (fst.comp fst) snd).to₂,
this.of_eq $ λ a, by cases o a with b; simp [encodek]
theorem sum_cases_right
{f : α → β ⊕ γ} {g : α → β → σ} {h : α → γ →. σ}
(hf : computable f) (hg : computable₂ g) (hh : partrec₂ h) :
@partrec _ σ _ _ (λ a, sum.cases_on (f a) (λ b, some (g a b)) (h a)) :=
have partrec (λ a, (option.cases_on
(sum.cases_on (f a) (λ b, option.none) option.some : option γ)
(some (sum.cases_on (f a) (λ b, some (g a b))
(λ c, option.none)))
(λ c, (h a c).map option.some) : roption (option σ))) :=
option_cases_right
(sum_cases hf (const option.none).to₂ (option_some.comp snd).to₂)
(sum_cases hf (option_some.comp hg) (const option.none).to₂)
(option_some_iff.2 hh),
option_some_iff.1 $ this.of_eq $ λ a, by cases f a; simp
theorem sum_cases_left
{f : α → β ⊕ γ} {g : α → β →. σ} {h : α → γ → σ}
(hf : computable f) (hg : partrec₂ g) (hh : computable₂ h) :
@partrec _ σ _ _ (λ a, sum.cases_on (f a) (g a) (λ c, some (h a c))) :=
(sum_cases_right (sum_cases hf
(sum_inr.comp snd).to₂ (sum_inl.comp snd).to₂) hh hg).of_eq $
λ a, by cases f a; simp
private lemma fix_aux
{f : α →. σ ⊕ α} (hf : partrec f)
(a : α) (b : σ) :
let F : α → ℕ →. σ ⊕ α := λ a n,
n.elim (some (sum.inr a)) $ λ y IH, IH.bind $ λ s,
sum.cases_on s (λ _, roption.some s) f in
(∃ (n : ℕ), ((∃ (b' : σ), sum.inl b' ∈ F a n) ∧
∀ {m : ℕ}, m < n → (∃ (b : α), sum.inr b ∈ F a m)) ∧
sum.inl b ∈ F a n) ↔ b ∈ pfun.fix f a :=
begin
intro, refine ⟨λ h, _, λ h, _⟩,
{ rcases h with ⟨n, ⟨_x, h₁⟩, h₂⟩,
have : ∀ m a' (_: sum.inr a' ∈ F a m)
(_: b ∈ pfun.fix f a'), b ∈ pfun.fix f a,
{ intros m a' am ba,
induction m with m IH generalizing a'; simp [F] at am,
{ rwa ← am },
rcases am with ⟨a₂, am₂, fa₂⟩,
exact IH _ am₂ (pfun.mem_fix_iff.2 (or.inr ⟨_, fa₂, ba⟩)) },
cases n; simp [F] at h₂, {cases h₂},
rcases h₂ with h₂ | ⟨a', am', fa'⟩,
{ cases h₁ (nat.lt_succ_self _) with a' h,
injection mem_unique h h₂ },
{ exact this _ _ am' (pfun.mem_fix_iff.2 (or.inl fa')) } },
{ suffices : ∀ a' (_: b ∈ pfun.fix f a') k (_: sum.inr a' ∈ F a k),
∃ n, sum.inl b ∈ F a n ∧
∀ (m < n) (_ : k ≤ m), ∃ a₂, sum.inr a₂ ∈ F a m,
{ rcases this _ h 0 (by simp [F]) with ⟨n, hn₁, hn₂⟩,
exact ⟨_, ⟨⟨_, hn₁⟩, λ m mn, hn₂ m mn (nat.zero_le _)⟩, hn₁⟩ },
intros a₁ h₁,
apply pfun.fix_induction h₁, intros a₂ h₂ IH k hk,
rcases pfun.mem_fix_iff.1 h₂ with h₂ | ⟨a₃, am₃, fa₃⟩,
{ refine ⟨k.succ, _, λ m mk km, ⟨a₂, _⟩⟩,
{ simp [F], exact or.inr ⟨_, hk, h₂⟩ },
{ rwa le_antisymm (nat.le_of_lt_succ mk) km } },
{ rcases IH _ fa₃ am₃ k.succ _ with ⟨n, hn₁, hn₂⟩,
{ refine ⟨n, hn₁, λ m mn km, _⟩,
cases lt_or_eq_of_le km with km km,
{ exact hn₂ _ mn km },
{ exact km ▸ ⟨_, hk⟩ } },
{ simp [F], exact ⟨_, hk, am₃⟩ } } }
end
theorem fix
{f : α →. σ ⊕ α} (hf : partrec f) : partrec (pfun.fix f) :=
let F : α → ℕ →. σ ⊕ α := λ a n,
n.elim (some (sum.inr a)) $ λ y IH, IH.bind $ λ s,
sum.cases_on s (λ _, roption.some s) f in
have hF : partrec₂ F :=
partrec.nat_elim snd (sum_inr.comp fst).part
(sum_cases_right (snd.comp snd)
(snd.comp $ snd.comp fst).to₂
(hf.comp snd).to₂).to₂,
let p := λ a n, @roption.map _ bool
(λ s, sum.cases_on s (λ_, tt) (λ _, ff)) (F a n) in
have hp : partrec₂ p := hF.map ((sum_cases computable.id
(const tt).to₂ (const ff).to₂).comp snd).to₂,
(hp.rfind.bind (hF.bind
(sum_cases_right snd snd.to₂ none.to₂).to₂).to₂).of_eq $
λ a, ext $ λ b, by simp; apply fix_aux hf
end partrec
|
e4fe204cc1609d3e5a84d1a1245470c450979dba | 8cae430f0a71442d02dbb1cbb14073b31048e4b0 | /src/group_theory/schur_zassenhaus.lean | fffa1ed9e956bc17ddb95353518815fdfa76ce91 | [
"Apache-2.0"
] | permissive | leanprover-community/mathlib | 56a2cadd17ac88caf4ece0a775932fa26327ba0e | 442a83d738cb208d3600056c489be16900ba701d | refs/heads/master | 1,693,584,102,358 | 1,693,471,902,000 | 1,693,471,902,000 | 97,922,418 | 1,595 | 352 | Apache-2.0 | 1,694,693,445,000 | 1,500,624,130,000 | Lean | UTF-8 | Lean | false | false | 14,879 | lean | /-
Copyright (c) 2021 Thomas Browning. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Thomas Browning
-/
import group_theory.sylow
import group_theory.transfer
/-!
# The Schur-Zassenhaus Theorem
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
In this file we prove the Schur-Zassenhaus theorem.
## Main results
- `exists_right_complement'_of_coprime` : The **Schur-Zassenhaus** theorem:
If `H : subgroup G` is normal and has order coprime to its index,
then there exists a subgroup `K` which is a (right) complement of `H`.
- `exists_left_complement'_of_coprime` The **Schur-Zassenhaus** theorem:
If `H : subgroup G` is normal and has order coprime to its index,
then there exists a subgroup `K` which is a (left) complement of `H`.
-/
open_locale big_operators
namespace subgroup
section schur_zassenhaus_abelian
open mul_opposite mul_action subgroup.left_transversals mem_left_transversals
variables {G : Type*} [group G] (H : subgroup G) [is_commutative H] [finite_index H]
(α β : left_transversals (H : set G))
/-- The quotient of the transversals of an abelian normal `N` by the `diff` relation. -/
def quotient_diff :=
quotient (setoid.mk (λ α β, diff (monoid_hom.id H) α β = 1) ⟨λ α, diff_self (monoid_hom.id H) α,
λ α β h, by rw [←diff_inv, h, inv_one], λ α β γ h h', by rw [←diff_mul_diff, h, h', one_mul]⟩)
instance : inhabited H.quotient_diff := quotient.inhabited _
lemma smul_diff_smul' [hH : normal H] (g : Gᵐᵒᵖ) :
diff (monoid_hom.id H) (g • α) (g • β) = ⟨g.unop⁻¹ * (diff (monoid_hom.id H) α β : H) * g.unop,
hH.mem_comm ((congr_arg (∈ H) (mul_inv_cancel_left _ _)).mpr (set_like.coe_mem _))⟩ :=
begin
letI := H.fintype_quotient_of_finite_index,
let ϕ : H →* H :=
{ to_fun := λ h, ⟨g.unop⁻¹ * h * g.unop,
hH.mem_comm ((congr_arg (∈ H) (mul_inv_cancel_left _ _)).mpr (set_like.coe_mem _))⟩,
map_one' := by rw [subtype.ext_iff, coe_mk, coe_one, mul_one, inv_mul_self],
map_mul' := λ h₁ h₂, by rw [subtype.ext_iff, coe_mk, coe_mul, coe_mul, coe_mk, coe_mk,
mul_assoc, mul_assoc, mul_assoc, mul_assoc, mul_assoc, mul_inv_cancel_left] },
refine eq.trans (finset.prod_bij' (λ q _, g⁻¹ • q) (λ q _, finset.mem_univ _)
(λ q _, subtype.ext _) (λ q _, g • q) (λ q _, finset.mem_univ _) (λ q _, smul_inv_smul g q)
(λ q _, inv_smul_smul g q)) (map_prod ϕ _ _).symm,
simp_rw [monoid_hom.id_apply, monoid_hom.coe_mk, coe_mk, smul_apply_eq_smul_apply_inv_smul,
smul_eq_mul_unop, mul_inv_rev, mul_assoc],
end
variables {H} [normal H]
instance : mul_action G H.quotient_diff :=
{ smul := λ g, quotient.map' (λ α, op g⁻¹ • α) (λ α β h, subtype.ext (by rwa [smul_diff_smul',
coe_mk, coe_one, mul_eq_one_iff_eq_inv, mul_right_eq_self, ←coe_one, ←subtype.ext_iff])),
mul_smul := λ g₁ g₂ q, quotient.induction_on' q (λ T, congr_arg quotient.mk'
(by rw mul_inv_rev; exact mul_smul (op g₁⁻¹) (op g₂⁻¹) T)),
one_smul := λ q, quotient.induction_on' q (λ T, congr_arg quotient.mk'
(by rw inv_one; apply one_smul Gᵐᵒᵖ T)) }
lemma smul_diff' (h : H) :
diff (monoid_hom.id H) α ((op (h : G)) • β) = diff (monoid_hom.id H) α β * h ^ H.index :=
begin
letI := H.fintype_quotient_of_finite_index,
rw [diff, diff, index_eq_card, ←finset.card_univ, ←finset.prod_const, ←finset.prod_mul_distrib],
refine finset.prod_congr rfl (λ q _, _),
simp_rw [subtype.ext_iff, monoid_hom.id_apply, coe_mul, coe_mk, mul_assoc, mul_right_inj],
rw [smul_apply_eq_smul_apply_inv_smul, smul_eq_mul_unop, unop_op,
mul_left_inj, ←subtype.ext_iff, equiv.apply_eq_iff_eq, inv_smul_eq_iff],
exact self_eq_mul_right.mpr ((quotient_group.eq_one_iff _).mpr h.2),
end
lemma eq_one_of_smul_eq_one (hH : nat.coprime (nat.card H) H.index)
(α : H.quotient_diff) (h : H) : h • α = α → h = 1 :=
quotient.induction_on' α $ λ α hα, (pow_coprime hH).injective $
calc h ^ H.index = diff (monoid_hom.id H) ((op ((h⁻¹ : H) : G)) • α) α :
by rw [←diff_inv, smul_diff', diff_self, one_mul, inv_pow, inv_inv]
... = 1 ^ H.index : (quotient.exact' hα).trans (one_pow H.index).symm
lemma exists_smul_eq (hH : nat.coprime (nat.card H) H.index)
(α β : H.quotient_diff) : ∃ h : H, h • α = β :=
quotient.induction_on' α (quotient.induction_on' β (λ β α, exists_imp_exists (λ n, quotient.sound')
⟨(pow_coprime hH).symm (diff (monoid_hom.id H) β α), (diff_inv _ _ _).symm.trans
(inv_eq_one.mpr ((smul_diff' β α ((pow_coprime hH).symm (diff (monoid_hom.id H) β α))⁻¹).trans
(by rw [inv_pow, ←pow_coprime_apply hH, equiv.apply_symm_apply, mul_inv_self])))⟩))
lemma is_complement'_stabilizer_of_coprime {α : H.quotient_diff}
(hH : nat.coprime (nat.card H) H.index) : is_complement' H (stabilizer G α) :=
is_complement'_stabilizer α (eq_one_of_smul_eq_one hH α) (λ g, exists_smul_eq hH (g • α) α)
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma exists_right_complement'_of_coprime_aux
(hH : nat.coprime (nat.card H) H.index) : ∃ K : subgroup G, is_complement' H K :=
nonempty_of_inhabited.elim (λ α, ⟨stabilizer G α, is_complement'_stabilizer_of_coprime hH⟩)
end schur_zassenhaus_abelian
open_locale classical
universe u
namespace schur_zassenhaus_induction
/-! ## Proof of the Schur-Zassenhaus theorem
In this section, we prove the Schur-Zassenhaus theorem.
The proof is by contradiction. We assume that `G` is a minimal counterexample to the theorem.
-/
variables {G : Type u} [group G] [fintype G] {N : subgroup G} [normal N]
(h1 : nat.coprime (fintype.card N) N.index)
(h2 : ∀ (G' : Type u) [group G'] [fintype G'], by exactI
∀ (hG'3 : fintype.card G' < fintype.card G)
{N' : subgroup G'} [N'.normal] (hN : nat.coprime (fintype.card N') N'.index),
∃ H' : subgroup G', is_complement' N' H')
(h3 : ∀ H : subgroup G, ¬ is_complement' N H)
include h1 h2 h3
/-! We will arrive at a contradiction via the following steps:
* step 0: `N` (the normal Hall subgroup) is nontrivial.
* step 1: If `K` is a subgroup of `G` with `K ⊔ N = ⊤`, then `K = ⊤`.
* step 2: `N` is a minimal normal subgroup, phrased in terms of subgroups of `G`.
* step 3: `N` is a minimal normal subgroup, phrased in terms of subgroups of `N`.
* step 4: `p` (`min_fact (fintype.card N)`) is prime (follows from step0).
* step 5: `P` (a Sylow `p`-subgroup of `N`) is nontrivial.
* step 6: `N` is a `p`-group (applies step 1 to the normalizer of `P` in `G`).
* step 7: `N` is abelian (applies step 3 to the center of `N`).
-/
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
@[nolint unused_arguments] private lemma step0 : N ≠ ⊥ :=
begin
unfreezingI { rintro rfl },
exact h3 ⊤ is_complement'_bot_top,
end
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma step1 (K : subgroup G) (hK : K ⊔ N = ⊤) : K = ⊤ :=
begin
contrapose! h3,
have h4 : (N.comap K.subtype).index = N.index,
{ rw [←N.relindex_top_right, ←hK],
exact (relindex_sup_right K N).symm },
have h5 : fintype.card K < fintype.card G,
{ rw ← K.index_mul_card,
exact lt_mul_of_one_lt_left fintype.card_pos (one_lt_index_of_ne_top h3) },
have h6 : nat.coprime (fintype.card (N.comap K.subtype)) (N.comap K.subtype).index,
{ rw h4,
exact h1.coprime_dvd_left (card_comap_dvd_of_injective N K.subtype subtype.coe_injective) },
obtain ⟨H, hH⟩ := h2 K h5 h6,
replace hH : fintype.card (H.map K.subtype) = N.index :=
((set.card_image_of_injective _ subtype.coe_injective).trans (mul_left_injective₀
fintype.card_ne_zero (hH.symm.card_mul.trans (N.comap K.subtype).index_mul_card.symm))).trans
h4,
have h7 : fintype.card N * fintype.card (H.map K.subtype) = fintype.card G,
{ rw [hH, ←N.index_mul_card, mul_comm] },
have h8 : (fintype.card N).coprime (fintype.card (H.map K.subtype)),
{ rwa hH },
exact ⟨H.map K.subtype, is_complement'_of_coprime h7 h8⟩,
end
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma step2 (K : subgroup G) [K.normal] (hK : K ≤ N) : K = ⊥ ∨ K = N :=
begin
have : function.surjective (quotient_group.mk' K) := quotient.surjective_quotient_mk',
have h4 := step1 h1 h2 h3,
contrapose! h4,
have h5 : fintype.card (G ⧸ K) < fintype.card G,
{ rw [←index_eq_card, ←K.index_mul_card],
refine lt_mul_of_one_lt_right (nat.pos_of_ne_zero index_ne_zero_of_finite)
(K.one_lt_card_iff_ne_bot.mpr h4.1) },
have h6 : nat.coprime (fintype.card (N.map (quotient_group.mk' K)))
(N.map (quotient_group.mk' K)).index,
{ have index_map := N.index_map_eq this (by rwa quotient_group.ker_mk),
have index_pos : 0 < N.index := nat.pos_of_ne_zero index_ne_zero_of_finite,
rw index_map,
refine h1.coprime_dvd_left _,
rw [←nat.mul_dvd_mul_iff_left index_pos, index_mul_card, ←index_map, index_mul_card],
exact K.card_quotient_dvd_card },
obtain ⟨H, hH⟩ := h2 (G ⧸ K) h5 h6,
refine ⟨H.comap (quotient_group.mk' K), _, _⟩,
{ have key : (N.map (quotient_group.mk' K)).comap (quotient_group.mk' K) = N,
{ refine comap_map_eq_self _,
rwa quotient_group.ker_mk },
rwa [←key, comap_sup_eq, hH.symm.sup_eq_top, comap_top] },
{ rw ← comap_top (quotient_group.mk' K),
intro hH',
rw [comap_injective this hH', is_complement'_top_right,
map_eq_bot_iff, quotient_group.ker_mk] at hH,
{ exact h4.2 (le_antisymm hK hH) } },
end
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma step3 (K : subgroup N) [(K.map N.subtype).normal] : K = ⊥ ∨ K = ⊤ :=
begin
have key := step2 h1 h2 h3 (K.map N.subtype) K.map_subtype_le,
rw ← map_bot N.subtype at key,
conv at key { congr, skip, to_rhs, rw [←N.subtype_range, N.subtype.range_eq_map] },
have inj := map_injective N.subtype_injective,
rwa [inj.eq_iff, inj.eq_iff] at key,
end
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma step4 : (fintype.card N).min_fac.prime :=
(nat.min_fac_prime (N.one_lt_card_iff_ne_bot.mpr (step0 h1 h2 h3)).ne')
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma step5 {P : sylow (fintype.card N).min_fac N} : P.1 ≠ ⊥ :=
begin
haveI : fact ((fintype.card N).min_fac.prime) := ⟨step4 h1 h2 h3⟩,
exact P.ne_bot_of_dvd_card (fintype.card N).min_fac_dvd,
end
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma step6 : is_p_group (fintype.card N).min_fac N :=
begin
haveI : fact ((fintype.card N).min_fac.prime) := ⟨step4 h1 h2 h3⟩,
refine sylow.nonempty.elim (λ P, P.2.of_surjective P.1.subtype _),
rw [←monoid_hom.range_top_iff_surjective, subtype_range],
haveI : (P.1.map N.subtype).normal := normalizer_eq_top.mp
(step1 h1 h2 h3 (P.1.map N.subtype).normalizer P.normalizer_sup_eq_top),
exact (step3 h1 h2 h3 P.1).resolve_left (step5 h1 h2 h3),
end
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
lemma step7 : is_commutative N :=
begin
haveI := N.bot_or_nontrivial.resolve_left (step0 h1 h2 h3),
haveI : fact ((fintype.card N).min_fac.prime) := ⟨step4 h1 h2 h3⟩,
exact ⟨⟨λ g h, eq_top_iff.mp ((step3 h1 h2 h3 N.center).resolve_left
(step6 h1 h2 h3).bot_lt_center.ne') (mem_top h) g⟩⟩,
end
end schur_zassenhaus_induction
variables {n : ℕ} {G : Type u} [group G]
/-- Do not use this lemma: It is made obsolete by `exists_right_complement'_of_coprime` -/
private lemma exists_right_complement'_of_coprime_aux' [fintype G] (hG : fintype.card G = n)
{N : subgroup G} [N.normal] (hN : nat.coprime (fintype.card N) N.index) :
∃ H : subgroup G, is_complement' N H :=
begin
unfreezingI { revert G },
apply nat.strong_induction_on n,
rintros n ih G _ _ rfl N _ hN,
refine not_forall_not.mp (λ h3, _),
haveI := by exactI
schur_zassenhaus_induction.step7 hN (λ G' _ _ hG', by { apply ih _ hG', refl }) h3,
rw ← nat.card_eq_fintype_card at hN,
exact not_exists_of_forall_not h3 (exists_right_complement'_of_coprime_aux hN),
end
/-- **Schur-Zassenhaus** for normal subgroups:
If `H : subgroup G` is normal, and has order coprime to its index, then there exists a
subgroup `K` which is a (right) complement of `H`. -/
theorem exists_right_complement'_of_coprime_of_fintype [fintype G]
{N : subgroup G} [N.normal] (hN : nat.coprime (fintype.card N) N.index) :
∃ H : subgroup G, is_complement' N H :=
exists_right_complement'_of_coprime_aux' rfl hN
/-- **Schur-Zassenhaus** for normal subgroups:
If `H : subgroup G` is normal, and has order coprime to its index, then there exists a
subgroup `K` which is a (right) complement of `H`. -/
theorem exists_right_complement'_of_coprime
{N : subgroup G} [N.normal] (hN : nat.coprime (nat.card N) N.index) :
∃ H : subgroup G, is_complement' N H :=
begin
by_cases hN1 : nat.card N = 0,
{ rw [hN1, nat.coprime_zero_left, index_eq_one] at hN,
rw hN,
exact ⟨⊥, is_complement'_top_bot⟩ },
by_cases hN2 : N.index = 0,
{ rw [hN2, nat.coprime_zero_right] at hN,
haveI := (cardinal.to_nat_eq_one_iff_unique.mp hN).1,
rw N.eq_bot_of_subsingleton,
exact ⟨⊤, is_complement'_bot_top⟩ },
have hN3 : nat.card G ≠ 0,
{ rw ← N.card_mul_index,
exact mul_ne_zero hN1 hN2 },
haveI := (cardinal.lt_aleph_0_iff_fintype.mp
(lt_of_not_ge (mt cardinal.to_nat_apply_of_aleph_0_le hN3))).some,
rw nat.card_eq_fintype_card at hN,
exact exists_right_complement'_of_coprime_of_fintype hN,
end
/-- **Schur-Zassenhaus** for normal subgroups:
If `H : subgroup G` is normal, and has order coprime to its index, then there exists a
subgroup `K` which is a (left) complement of `H`. -/
theorem exists_left_complement'_of_coprime_of_fintype
[fintype G] {N : subgroup G} [N.normal] (hN : nat.coprime (fintype.card N) N.index) :
∃ H : subgroup G, is_complement' H N :=
Exists.imp (λ _, is_complement'.symm) (exists_right_complement'_of_coprime_of_fintype hN)
/-- **Schur-Zassenhaus** for normal subgroups:
If `H : subgroup G` is normal, and has order coprime to its index, then there exists a
subgroup `K` which is a (left) complement of `H`. -/
theorem exists_left_complement'_of_coprime
{N : subgroup G} [N.normal] (hN : nat.coprime (nat.card N) N.index) :
∃ H : subgroup G, is_complement' H N :=
Exists.imp (λ _, is_complement'.symm) (exists_right_complement'_of_coprime hN)
end subgroup
|
9c8cf7d4aa6c69626a5237eca18b2e46271e1ee9 | 57aec6ee746bc7e3a3dd5e767e53bd95beb82f6d | /tests/lean/run/catchThe.lean | 695937d63684a357fe67d530872104baeae99e2c | [
"Apache-2.0"
] | permissive | collares/lean4 | 861a9269c4592bce49b71059e232ff0bfe4594cc | 52a4f535d853a2c7c7eea5fee8a4fa04c682c1ee | refs/heads/master | 1,691,419,031,324 | 1,618,678,138,000 | 1,618,678,138,000 | 358,989,750 | 0 | 0 | Apache-2.0 | 1,618,696,333,000 | 1,618,696,333,000 | null | UTF-8 | Lean | false | false | 851 | lean | import Lean.Meta
open Lean
open Lean.Meta
universes u v w
abbrev M := ExceptT String MetaM
def testM {α} [BEq α] [ToString α] (x : M α) (expected : α) : MetaM Unit := do
let r ← x
match r with
| Except.ok a => unless a == expected do throwError m!"unexpected result {a}"
| Except.error e => throwError m!"FAILED: {e}"
@[noinline] def act1 : M Nat :=
throw <| Exception.error Syntax.missing "Error at act1"
def g1 : M Nat :=
tryCatchThe Exception
(tryCatchThe String act1 (fun ex => pure 100))
(fun ex => pure 200)
#eval testM g1 200
@[noinline] def act2 : M Nat :=
throwThe String "hello world"
def g2 : M Nat :=
tryCatchThe Exception
(tryCatchThe String act2 (fun ex => pure 100))
(fun ex => pure 200)
#eval testM g2 100
def h1 : CoreM Nat :=
pure 10
#eval h1
def h2 : MetaM Nat :=
pure 20
#eval h2
|
2b32cd13de38964c63f6351ea4d3bf5057793bde | 4bcaca5dc83d49803f72b7b5920b75b6e7d9de2d | /src/Lean/Elab/Match.lean | feea07b271b50744977f0a673263e52c290647e6 | [
"Apache-2.0"
] | permissive | subfish-zhou/leanprover-zh_CN.github.io | 30b9fba9bd790720bd95764e61ae796697d2f603 | 8b2985d4a3d458ceda9361ac454c28168d920d3f | refs/heads/master | 1,689,709,967,820 | 1,632,503,056,000 | 1,632,503,056,000 | 409,962,097 | 1 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 45,261 | lean | /-
Copyright (c) 2020 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
import Lean.Util.CollectFVars
import Lean.Meta.Match.MatchPatternAttr
import Lean.Meta.Match.Match
import Lean.Meta.SortLocalDecls
import Lean.Meta.GeneralizeVars
import Lean.Elab.SyntheticMVars
import Lean.Elab.Arg
import Lean.Parser.Term
import Lean.Elab.PatternVar
namespace Lean.Elab.Term
open Meta
open Lean.Parser.Term
private def expandSimpleMatch (stx discr lhsVar rhs : Syntax) (expectedType? : Option Expr) : TermElabM Expr := do
let newStx ← `(let $lhsVar := $discr; $rhs)
withMacroExpansion stx newStx <| elabTerm newStx expectedType?
private def mkUserNameFor (e : Expr) : TermElabM Name := do
match e with
/- Remark: we use `mkFreshUserName` to make sure we don't add a variable to the local context that can be resolved to `e`. -/
| Expr.fvar fvarId _ => mkFreshUserName ((← getLocalDecl fvarId).userName)
| _ => mkFreshBinderName
/-- Return true iff `n` is an auxiliary variable created by `expandNonAtomicDiscrs?` -/
def isAuxDiscrName (n : Name) : Bool :=
n.hasMacroScopes && n.eraseMacroScopes == `_discr
/--
We treat `@x` as atomic to avoid unnecessary extra local declarations from being
inserted into the local context. Recall that `expandMatchAltsIntoMatch` uses `@` modifier.
Thus this is kind of discriminant is quite common.
Remark: if the discriminat is `Systax.missing`, we abort the elaboration of the `match`-expression.
This can happen due to error recovery. Example
```
example : (p ∨ p) → p := fun h => match
```
If we don't abort, the elaborator loops because we will keep trying to expand
```
match
```
into
```
let d := <Syntax.missing>; match
```
Recall that `Syntax.setArg stx i arg` is a no-op when `i` is out-of-bounds. -/
def isAtomicDiscr? (discr : Syntax) : TermElabM (Option Expr) := do
match discr with
| `($x:ident) => isLocalIdent? x
| `(@$x:ident) => isLocalIdent? x
| _ => if discr.isMissing then throwAbortTerm else return none
-- See expandNonAtomicDiscrs?
private def elabAtomicDiscr (discr : Syntax) : TermElabM Expr := do
let term := discr[1]
match (← isAtomicDiscr? term) with
| some e@(Expr.fvar fvarId _) =>
let localDecl ← getLocalDecl fvarId
if !isAuxDiscrName localDecl.userName then
return e -- it is not an auxiliary local created by `expandNonAtomicDiscrs?`
else
instantiateMVars localDecl.value
| _ => throwErrorAt discr "unexpected discriminant"
structure ElabMatchTypeAndDiscrsResult where
discrs : Array Expr
matchType : Expr
/- `true` when performing dependent elimination. We use this to decide whether we optimize the "match unit" case.
See `isMatchUnit?`. -/
isDep : Bool
alts : Array MatchAltView
private partial def elabMatchTypeAndDiscrs (discrStxs : Array Syntax) (matchOptType : Syntax) (matchAltViews : Array MatchAltView) (expectedType : Expr)
: TermElabM ElabMatchTypeAndDiscrsResult := do
let numDiscrs := discrStxs.size
if matchOptType.isNone then
elabDiscrs 0 #[]
else
let matchTypeStx := matchOptType[0][1]
let matchType ← elabType matchTypeStx
let (discrs, isDep) ← elabDiscrsWitMatchType matchType expectedType
return { discrs := discrs, matchType := matchType, isDep := isDep, alts := matchAltViews }
where
/- Easy case: elaborate discriminant when the match-type has been explicitly provided by the user. -/
elabDiscrsWitMatchType (matchType : Expr) (expectedType : Expr) : TermElabM (Array Expr × Bool) := do
let mut discrs := #[]
let mut i := 0
let mut matchType := matchType
let mut isDep := false
for discrStx in discrStxs do
i := i + 1
matchType ← whnf matchType
match matchType with
| Expr.forallE _ d b _ =>
let discr ← fullApproxDefEq <| elabTermEnsuringType discrStx[1] d
trace[Elab.match] "discr #{i} {discr} : {d}"
if b.hasLooseBVars then
isDep := true
matchType ← b.instantiate1 discr
discrs := discrs.push discr
| _ =>
throwError "invalid type provided to match-expression, function type with arity #{discrStxs.size} expected"
return (discrs, isDep)
markIsDep (r : ElabMatchTypeAndDiscrsResult) :=
{ r with isDep := true }
/- Elaborate discriminants inferring the match-type -/
elabDiscrs (i : Nat) (discrs : Array Expr) : TermElabM ElabMatchTypeAndDiscrsResult := do
if h : i < discrStxs.size then
let discrStx := discrStxs.get ⟨i, h⟩
let discr ← elabAtomicDiscr discrStx
let discr ← instantiateMVars discr
let discrType ← inferType discr
let discrType ← instantiateMVars discrType
let discrs := discrs.push discr
let userName ← mkUserNameFor discr
if discrStx[0].isNone then
let mut result ← elabDiscrs (i + 1) discrs
let matchTypeBody ← kabstract result.matchType discr
if matchTypeBody.hasLooseBVars then
result := markIsDep result
return { result with matchType := Lean.mkForall userName BinderInfo.default discrType matchTypeBody }
else
let discrs := discrs.push (← mkEqRefl discr)
let result ← elabDiscrs (i + 1) discrs
let result := markIsDep result
let identStx := discrStx[0][0]
withLocalDeclD userName discrType fun x => do
let eqType ← mkEq discr x
withLocalDeclD identStx.getId eqType fun h => do
let matchTypeBody ← kabstract result.matchType discr
let matchTypeBody := matchTypeBody.instantiate1 x
let matchType ← mkForallFVars #[x, h] matchTypeBody
return { result with
matchType := matchType
alts := result.alts.map fun altView => { altView with patterns := altView.patterns.insertAt (i+1) identStx }
}
else
return { discrs, alts := matchAltViews, isDep := false, matchType := expectedType }
def expandMacrosInPatterns (matchAlts : Array MatchAltView) : MacroM (Array MatchAltView) := do
matchAlts.mapM fun matchAlt => do
let patterns ← matchAlt.patterns.mapM expandMacros
pure { matchAlt with patterns := patterns }
private def getMatchGeneralizing? : Syntax → Option Bool
| `(match (generalizing := true) $discrs,* $[: $ty?]? with $alts:matchAlt*) => some true
| `(match (generalizing := false) $discrs,* $[: $ty?]? with $alts:matchAlt*) => some false
| _ => none
/- Given `stx` a match-expression, return its alternatives. -/
private def getMatchAlts : Syntax → Array MatchAltView
| `(match $[$gen]? $discrs,* $[: $ty?]? with $alts:matchAlt*) =>
alts.filterMap fun alt => match alt with
| `(matchAltExpr| | $patterns,* => $rhs) => some {
ref := alt,
patterns := patterns,
rhs := rhs
}
| _ => none
| _ => #[]
builtin_initialize Parser.registerBuiltinNodeKind `MVarWithIdKind
open Meta.Match (mkInaccessible inaccessible?)
/--
The elaboration function for `Syntax` created using `mkMVarSyntax`.
It just converts the metavariable id wrapped by the Syntax into an `Expr`. -/
@[builtinTermElab MVarWithIdKind] def elabMVarWithIdKind : TermElab := fun stx expectedType? =>
return mkInaccessible <| mkMVar (getMVarSyntaxMVarId stx)
@[builtinTermElab inaccessible] def elabInaccessible : TermElab := fun stx expectedType? => do
let e ← elabTerm stx[1] expectedType?
return mkInaccessible e
open Lean.Elab.Term.Quotation in
@[builtinQuotPrecheck Lean.Parser.Term.match] def precheckMatch : Precheck
| `(match $[$discrs:term],* with $[| $[$patss],* => $rhss]*) => do
discrs.forM precheck
for (pats, rhs) in patss.zip rhss do
let vars ←
try
getPatternsVars pats
catch
| _ => return -- can happen in case of pattern antiquotations
Quotation.withNewLocals (getPatternVarNames vars) <| precheck rhs
| _ => throwUnsupportedSyntax
/- We convert the collected `PatternVar`s intro `PatternVarDecl` -/
inductive PatternVarDecl where
/- For `anonymousVar`, we create both a metavariable and a free variable. The free variable is used as an assignment for the metavariable
when it is not assigned during pattern elaboration. -/
| anonymousVar (mvarId : MVarId) (fvarId : FVarId)
| localVar (fvarId : FVarId)
private partial def withPatternVars {α} (pVars : Array PatternVar) (k : Array PatternVarDecl → TermElabM α) : TermElabM α :=
let rec loop (i : Nat) (decls : Array PatternVarDecl) := do
if h : i < pVars.size then
match pVars.get ⟨i, h⟩ with
| PatternVar.anonymousVar mvarId =>
let type ← mkFreshTypeMVar
let userName ← mkFreshBinderName
withLocalDecl userName BinderInfo.default type fun x =>
loop (i+1) (decls.push (PatternVarDecl.anonymousVar mvarId x.fvarId!))
| PatternVar.localVar userName =>
let type ← mkFreshTypeMVar
withLocalDecl userName BinderInfo.default type fun x =>
loop (i+1) (decls.push (PatternVarDecl.localVar x.fvarId!))
else
/- We must create the metavariables for `PatternVar.anonymousVar` AFTER we create the new local decls using `withLocalDecl`.
Reason: their scope must include the new local decls since some of them are assigned by typing constraints. -/
decls.forM fun decl => match decl with
| PatternVarDecl.anonymousVar mvarId fvarId => do
let type ← inferType (mkFVar fvarId)
discard <| mkFreshExprMVarWithId mvarId type
| _ => pure ()
k decls
loop 0 #[]
/-
Remark: when performing dependent pattern matching, we often had to write code such as
```lean
def Vec.map' (f : α → β) (xs : Vec α n) : Vec β n :=
match n, xs with
| _, nil => nil
| _, cons a as => cons (f a) (map' f as)
```
We had to include `n` and the `_`s because the type of `xs` depends on `n`.
Moreover, `nil` and `cons a as` have different types.
This was quite tedious. So, we have implemented an automatic "discriminant refinement procedure".
The procedure is based on the observation that we get a type error whenenver we forget to include `_`s
and the indices a discriminant depends on. So, we catch the exception, check whether the type of the discriminant
is an indexed family, and add their indices as new discriminants.
The current implementation, adds indices as they are found, and does not
try to "sort" the new discriminants.
If the refinement process fails, we report the original error message.
-/
/- Auxiliary structure for storing an type mismatch exception when processing the
pattern #`idx` of some alternative. -/
structure PatternElabException where
ex : Exception
patternIdx : Nat -- Discriminant that sh
pathToIndex : List Nat -- Path to the problematic inductive type index that produced the type mismatch
/--
This method is part of the "discriminant refinement" procedure. It in invoked when the
type of the `pattern` does not match the expected type. The expected type is based on the
motive computed using the `match` discriminants.
It tries to compute a path to an index of the discriminant type.
For example, suppose the user has written
```
inductive Mem (a : α) : List α → Prop where
| head {as} : Mem a (a::as)
| tail {as} : Mem a as → Mem a (a'::as)
infix:50 " ∈ " => Mem
example (a b : Nat) (h : a ∈ [b]) : b = a :=
match h with
| Mem.head => rfl
```
The motive for the match is `a ∈ [b] → b = a`, and get a type mismatch between the type
of `Mem.head` and `a ∈ [b]`. This procedure return the path `[2, 1]` to the index `b`.
We use it to produce the following refinement
```
example (a b : Nat) (h : a ∈ [b]) : b = a :=
match b, h with
| _, Mem.head => rfl
```
which produces the new motive `(x : Nat) → a ∈ [x] → x = a`
After this refinement step, the `match` is elaborated successfully.
This method relies on the fact that the dependent pattern matcher compiler solves equations
between indices of indexed inductive families.
The following kinds of equations are supported by this compiler:
- `x = t`
- `t = x`
- `ctor ... = ctor ...`
where `x` is a free variable, `t` is an arbitrary term, and `ctor` is constructor.
Our procedure ensures that "information" is not lost, and will *not* succeed in an
example such as
```
example (a b : Nat) (f : Nat → Nat) (h : f a ∈ [f b]) : f b = f a :=
match h with
| Mem.head => rfl
```
and will not add `f b` as a new discriminant. We may add an option in the future to
enable this more liberal form of refinement.
-/
private partial def findDiscrRefinementPath (pattern : Expr) (expected : Expr) : OptionT MetaM (List Nat) := do
goType (← instantiateMVars (← inferType pattern)) expected
where
checkCompatibleApps (t d : Expr) : OptionT MetaM Unit := do
guard d.isApp
guard <| t.getAppNumArgs == d.getAppNumArgs
let tFn := t.getAppFn
let dFn := d.getAppFn
guard <| tFn.isConst && dFn.isConst
guard (← isDefEq tFn dFn)
-- Visitor for inductive types
goType (t d : Expr) : OptionT MetaM (List Nat) := do
trace[Meta.debug] "type {t} =?= {d}"
let t ← whnf t
let d ← whnf d
checkCompatibleApps t d
matchConstInduct t.getAppFn (fun _ => failure) fun info _ => do
let tArgs := t.getAppArgs
let dArgs := d.getAppArgs
for i in [:info.numParams] do
let tArg := tArgs[i]
let dArg := dArgs[i]
unless (← isDefEq tArg dArg) do
return i :: (← goType tArg dArg)
for i in [info.numParams : tArgs.size] do
let tArg := tArgs[i]
let dArg := dArgs[i]
unless (← isDefEq tArg dArg) do
return i :: (← goIndex tArg dArg)
failure
-- Visitor for indexed families
goIndex (t d : Expr) : OptionT MetaM (List Nat) := do
let t ← whnfD t
let d ← whnfD d
if t.isFVar || d.isFVar then
return [] -- Found refinement path
else
trace[Meta.debug] "index {t} =?= {d}"
checkCompatibleApps t d
matchConstCtor t.getAppFn (fun _ => failure) fun info _ => do
let tArgs := t.getAppArgs
let dArgs := d.getAppArgs
for i in [:info.numParams] do
let tArg := tArgs[i]
let dArg := dArgs[i]
unless (← isDefEq tArg dArg) do
failure
for i in [info.numParams : tArgs.size] do
let tArg := tArgs[i]
let dArg := dArgs[i]
unless (← isDefEq tArg dArg) do
return i :: (← goIndex tArg dArg)
failure
private partial def eraseIndices (type : Expr) : MetaM Expr := do
let type' ← whnfD type
matchConstInduct type'.getAppFn (fun _ => return type) fun info _ => do
let args := type'.getAppArgs
let params ← args[:info.numParams].toArray.mapM eraseIndices
let result := mkAppN type'.getAppFn params
let resultType ← inferType result
let (newIndices, _, _) ← forallMetaTelescopeReducing resultType (some (args.size - info.numParams))
return mkAppN result newIndices
private def elabPatterns (patternStxs : Array Syntax) (matchType : Expr) : ExceptT PatternElabException TermElabM (Array Expr × Expr) :=
withReader (fun ctx => { ctx with implicitLambda := false }) do
let mut patterns := #[]
let mut matchType := matchType
for idx in [:patternStxs.size] do
let patternStx := patternStxs[idx]
matchType ← whnf matchType
match matchType with
| Expr.forallE _ d b _ =>
let pattern ← do
let s ← saveState
try
liftM <| withSynthesize <| withoutErrToSorry <| elabTermEnsuringType patternStx d
catch ex : Exception =>
restoreState s
match (← liftM <| commitIfNoErrors? <| withoutErrToSorry do elabTermAndSynthesize patternStx (← eraseIndices d)) with
| some pattern =>
match (← findDiscrRefinementPath pattern d |>.run) with
| some path =>
trace[Meta.debug] "refinement path: {path}"
restoreState s
-- Wrap the type mismatch exception for the "discriminant refinement" feature.
throwThe PatternElabException { ex := ex, patternIdx := idx, pathToIndex := path }
| none => restoreState s; throw ex
| none => throw ex
matchType := b.instantiate1 pattern
patterns := patterns.push pattern
| _ => throwError "unexpected match type"
return (patterns, matchType)
def finalizePatternDecls (patternVarDecls : Array PatternVarDecl) : TermElabM (Array LocalDecl) := do
let mut decls := #[]
for pdecl in patternVarDecls do
match pdecl with
| PatternVarDecl.localVar fvarId =>
let decl ← getLocalDecl fvarId
let decl ← instantiateLocalDeclMVars decl
decls := decls.push decl
| PatternVarDecl.anonymousVar mvarId fvarId =>
let e ← instantiateMVars (mkMVar mvarId);
trace[Elab.match] "finalizePatternDecls: mvarId: {mvarId.name} := {e}, fvar: {mkFVar fvarId}"
match e with
| Expr.mvar newMVarId _ =>
/- Metavariable was not assigned, or assigned to another metavariable. So,
we assign to the auxiliary free variable we created at `withPatternVars` to `newMVarId`. -/
assignExprMVar newMVarId (mkFVar fvarId)
trace[Elab.match] "finalizePatternDecls: {mkMVar newMVarId} := {mkFVar fvarId}"
let decl ← getLocalDecl fvarId
let decl ← instantiateLocalDeclMVars decl
decls := decls.push decl
| _ => pure ()
/- We perform a topological sort (dependecies) on `decls` because the pattern elaboration process may produce a sequence where a declaration d₁ may occur after d₂ when d₂ depends on d₁. -/
sortLocalDecls decls
open Meta.Match (Pattern Pattern.var Pattern.inaccessible Pattern.ctor Pattern.as Pattern.val Pattern.arrayLit AltLHS MatcherResult)
namespace ToDepElimPattern
structure State where
found : FVarIdSet := {}
localDecls : Array LocalDecl
newLocals : FVarIdSet := {}
abbrev M := StateRefT State TermElabM
private def alreadyVisited (fvarId : FVarId) : M Bool := do
let s ← get
return s.found.contains fvarId
private def markAsVisited (fvarId : FVarId) : M Unit :=
modify fun s => { s with found := s.found.insert fvarId }
private def throwInvalidPattern {α} (e : Expr) : M α :=
throwError "invalid pattern {indentExpr e}"
/- Create a new LocalDecl `x` for the metavariable `mvar`, and return `Pattern.var x` -/
private def mkLocalDeclFor (mvar : Expr) : M Pattern := do
let mvarId := mvar.mvarId!
let s ← get
match (← getExprMVarAssignment? mvarId) with
| some val => return Pattern.inaccessible val
| none =>
let fvarId ← mkFreshFVarId
let type ← inferType mvar
/- HACK: `fvarId` is not in the scope of `mvarId`
If this generates problems in the future, we should update the metavariable declarations. -/
assignExprMVar mvarId (mkFVar fvarId)
let userName ← mkFreshBinderName
let newDecl := LocalDecl.cdecl arbitrary fvarId userName type BinderInfo.default;
modify fun s =>
{ s with
newLocals := s.newLocals.insert fvarId,
localDecls :=
match s.localDecls.findIdx? fun decl => mvar.occurs decl.type with
| none => s.localDecls.push newDecl -- None of the existing declarations depend on `mvar`
| some i => s.localDecls.insertAt i newDecl }
return Pattern.var fvarId
partial def main (e : Expr) : M Pattern := do
let isLocalDecl (fvarId : FVarId) : M Bool := do
return (← get).localDecls.any fun d => d.fvarId == fvarId
let mkPatternVar (fvarId : FVarId) (e : Expr) : M Pattern := do
if (← alreadyVisited fvarId) then
return Pattern.inaccessible e
else
markAsVisited fvarId
return Pattern.var e.fvarId!
let mkInaccessible (e : Expr) : M Pattern := do
match e with
| Expr.fvar fvarId _ =>
if (← isLocalDecl fvarId) then
mkPatternVar fvarId e
else
return Pattern.inaccessible e
| _ =>
return Pattern.inaccessible e
match inaccessible? e with
| some t => mkInaccessible t
| none =>
match e.arrayLit? with
| some (α, lits) =>
return Pattern.arrayLit α (← lits.mapM main)
| none =>
if e.isAppOfArity `namedPattern 3 then
let p ← main <| e.getArg! 2
match e.getArg! 1 with
| Expr.fvar fvarId _ => return Pattern.as fvarId p
| _ => throwError "unexpected occurrence of auxiliary declaration 'namedPattern'"
else if isMatchValue e then
return Pattern.val e
else if e.isFVar then
let fvarId := e.fvarId!
unless (← isLocalDecl fvarId) do
throwInvalidPattern e
mkPatternVar fvarId e
else if e.isMVar then
mkLocalDeclFor e
else
let newE ← whnf e
if newE != e then
main newE
else
matchConstCtor e.getAppFn
(fun _ => do
if (← isProof e) then
/- We mark nested proofs as inaccessible. This is fine due to proof irrelevance.
We need this feature to be able to elaborate definitions such as:
```
def f : Fin 2 → Nat
| 0 => 5
| 1 => 45
```
-/
return Pattern.inaccessible e
else
throwInvalidPattern e)
(fun v us => do
let args := e.getAppArgs
unless args.size == v.numParams + v.numFields do
throwInvalidPattern e
let params := args.extract 0 v.numParams
let fields := args.extract v.numParams args.size
let fields ← fields.mapM main
return Pattern.ctor v.name us params.toList fields.toList)
end ToDepElimPattern
def withDepElimPatterns {α} (localDecls : Array LocalDecl) (ps : Array Expr) (k : Array LocalDecl → Array Pattern → TermElabM α) : TermElabM α := do
let (patterns, s) ← (ps.mapM ToDepElimPattern.main).run { localDecls := localDecls }
let localDecls ← s.localDecls.mapM fun d => instantiateLocalDeclMVars d
/- toDepElimPatterns may have added new localDecls. Thus, we must update the local context before we execute `k` -/
let lctx ← getLCtx
let lctx := localDecls.foldl (fun (lctx : LocalContext) d => lctx.erase d.fvarId) lctx
let lctx := localDecls.foldl (fun (lctx : LocalContext) d => lctx.addDecl d) lctx
withTheReader Meta.Context (fun ctx => { ctx with lctx := lctx }) do
k localDecls patterns
private def withElaboratedLHS {α} (ref : Syntax) (patternVarDecls : Array PatternVarDecl) (patternStxs : Array Syntax) (matchType : Expr)
(k : AltLHS → Expr → TermElabM α) : ExceptT PatternElabException TermElabM α := do
let (patterns, matchType) ← withSynthesize <| elabPatterns patternStxs matchType
id (α := TermElabM α) do
let localDecls ← finalizePatternDecls patternVarDecls
let patterns ← patterns.mapM (instantiateMVars ·)
withDepElimPatterns localDecls patterns fun localDecls patterns =>
k { ref := ref, fvarDecls := localDecls.toList, patterns := patterns.toList } matchType
private def elabMatchAltView (alt : MatchAltView) (matchType : Expr) : ExceptT PatternElabException TermElabM (AltLHS × Expr) := withRef alt.ref do
let (patternVars, alt) ← collectPatternVars alt
trace[Elab.match] "patternVars: {patternVars}"
withPatternVars patternVars fun patternVarDecls => do
withElaboratedLHS alt.ref patternVarDecls alt.patterns matchType fun altLHS matchType => do
let rhs ← elabTermEnsuringType alt.rhs matchType
let xs := altLHS.fvarDecls.toArray.map LocalDecl.toExpr
let rhs ← if xs.isEmpty then pure <| mkSimpleThunk rhs else mkLambdaFVars xs rhs
trace[Elab.match] "rhs: {rhs}"
return (altLHS, rhs)
/--
Collect problematic index for the "discriminant refinement feature". This method is invoked
when we detect a type mismatch at a pattern #`idx` of some alternative. -/
private partial def getIndexToInclude? (discr : Expr) (pathToIndex : List Nat) : TermElabM (Option Expr) := do
go (← inferType discr) pathToIndex |>.run
where
go (e : Expr) (path : List Nat) : OptionT MetaM Expr := do
match path with
| [] => return e
| i::path =>
let e ← whnfD e
guard <| e.isApp && i < e.getAppNumArgs
go (e.getArg! i) path
/--
"Generalize" variables that depend on the discriminants.
Remarks and limitations:
- If `matchType` is a proposition, then we generalize even when the user did not provide `(generalizing := true)`.
Motivation: users should have control about the actual `match`-expressions in their programs.
- We currently do not generalize let-decls.
- We abort generalization if the new `matchType` is type incorrect.
- Only discriminants that are free variables are considered during specialization.
- We "generalize" by adding new discriminants and pattern variables. We do not "clear" the generalized variables,
but they become inaccessible since they are shadowed by the patterns variables. We assume this is ok since
this is the exact behavior users would get if they had written it by hand. Recall there is no `clear` in term mode.
-/
private def generalize (discrs : Array Expr) (matchType : Expr) (altViews : Array MatchAltView) (generalizing? : Option Bool) : TermElabM (Array Expr × Expr × Array MatchAltView × Bool) := do
let gen ←
match generalizing? with
| some g => pure g
| _ => isProp matchType
if !gen then
return (discrs, matchType, altViews, false)
else
let ysFVarIds ← getFVarsToGeneralize discrs
/- let-decls are currently being ignored by the generalizer. -/
let ysFVarIds ← ysFVarIds.filterM fun fvarId => return !(← getLocalDecl fvarId).isLet
if ysFVarIds.isEmpty then
return (discrs, matchType, altViews, false)
else
let ys := ysFVarIds.map mkFVar
-- trace[Meta.debug] "ys: {ys}, discrs: {discrs}"
let matchType' ← forallBoundedTelescope matchType discrs.size fun ds type => do
let type ← mkForallFVars ys type
let (discrs', ds') := Array.unzip <| Array.zip discrs ds |>.filter fun (di, d) => di.isFVar
let type := type.replaceFVars discrs' ds'
mkForallFVars ds type
-- trace[Meta.debug] "matchType': {matchType'}"
if (← isTypeCorrect matchType') then
let discrs := discrs ++ ys
let altViews ← altViews.mapM fun altView => do
let patternVars ← getPatternsVars altView.patterns
-- We traverse backwards because we want to keep the most recent names.
-- For example, if `ys` contains `#[h, h]`, we want to make sure `mkFreshUsername is applied to the first `h`,
-- since it is already shadowed by the second.
let ysUserNames ← ys.foldrM (init := #[]) fun ys ysUserNames => do
let yDecl ← getLocalDecl ys.fvarId!
let mut yUserName := yDecl.userName
if ysUserNames.contains yUserName then
yUserName ← mkFreshUserName yUserName
-- Explicitly provided pattern variables shadow `y`
else if patternVars.any fun | PatternVar.localVar x => x == yUserName | _ => false then
yUserName ← mkFreshUserName yUserName
return ysUserNames.push yUserName
let ysIds ← ysUserNames.reverse.mapM fun n => return mkIdentFrom (← getRef) n
return { altView with patterns := altView.patterns ++ ysIds }
return (discrs, matchType', altViews, true)
else
return (discrs, matchType, altViews, true)
private partial def elabMatchAltViews (generalizing? : Option Bool) (discrs : Array Expr) (matchType : Expr) (altViews : Array MatchAltView) : TermElabM (Array Expr × Expr × Array (AltLHS × Expr) × Bool) := do
loop discrs matchType altViews none
where
/-
"Discriminant refinement" main loop.
`first?` contains the first error message we found before updated the `discrs`. -/
loop (discrs : Array Expr) (matchType : Expr) (altViews : Array MatchAltView) (first? : Option (SavedState × Exception))
: TermElabM (Array Expr × Expr × Array (AltLHS × Expr) × Bool) := do
let s ← saveState
let (discrs', matchType', altViews', refined) ← generalize discrs matchType altViews generalizing?
match (← altViews'.mapM (fun altView => elabMatchAltView altView matchType') |>.run) with
| Except.ok alts => return (discrs', matchType', alts, first?.isSome || refined)
| Except.error { patternIdx := patternIdx, pathToIndex := pathToIndex, ex := ex } =>
trace[Meta.debug] "pathToIndex: {toString pathToIndex}"
let some index ← getIndexToInclude? discrs[patternIdx] pathToIndex
| throwEx (← updateFirst first? ex)
trace[Meta.debug] "index: {index}"
if (← discrs.anyM fun discr => isDefEq discr index) then
throwEx (← updateFirst first? ex)
let first ← updateFirst first? ex
s.restore
let indices ← collectDeps #[index] discrs
let matchType ←
try
updateMatchType indices matchType
catch ex =>
throwEx first
let altViews ← addWildcardPatterns indices.size altViews
let discrs := indices ++ discrs
loop discrs matchType altViews first
throwEx {α} (p : SavedState × Exception) : TermElabM α := do
p.1.restore; throw p.2
updateFirst (first? : Option (SavedState × Exception)) (ex : Exception) : TermElabM (SavedState × Exception) := do
match first? with
| none => return (← saveState, ex)
| some first => return first
containsFVar (es : Array Expr) (fvarId : FVarId) : Bool :=
es.any fun e => e.isFVar && e.fvarId! == fvarId
/- Update `indices` by including any free variable `x` s.t.
- Type of some `discr` depends on `x`.
- Type of `x` depends on some free variable in `indices`.
If we don't include these extra variables in indices, then
`updateMatchType` will generate a type incorrect term.
For example, suppose `discr` contains `h : @HEq α a α b`, and
`indices` is `#[α, b]`, and `matchType` is `@HEq α a α b → B`.
`updateMatchType indices matchType` produces the type
`(α' : Type) → (b : α') → @HEq α' a α' b → B` which is type incorrect
because we have `a : α`.
The method `collectDeps` will include `a` into `indices`.
This method does not handle dependencies among non-free variables.
We rely on the type checking method `check` at `updateMatchType`.
Remark: `indices : Array Expr` does not need to be an array anymore.
We should cleanup this code, and use `index : Expr` instead.
-/
collectDeps (indices : Array Expr) (discrs : Array Expr) : TermElabM (Array Expr) := do
let mut s : CollectFVars.State := {}
for discr in discrs do
s := collectFVars s (← instantiateMVars (← inferType discr))
let (indicesFVar, indicesNonFVar) := indices.split Expr.isFVar
let indicesFVar := indicesFVar.map Expr.fvarId!
let mut toAdd := #[]
for fvarId in s.fvarSet.toList do
unless containsFVar discrs fvarId || containsFVar indices fvarId do
let localDecl ← getLocalDecl fvarId
let mctx ← getMCtx
for indexFVarId in indicesFVar do
if mctx.localDeclDependsOn localDecl indexFVarId then
toAdd := toAdd.push fvarId
let indicesFVar ← sortFVarIds (indicesFVar ++ toAdd)
return indicesFVar.map mkFVar ++ indicesNonFVar
updateMatchType (indices : Array Expr) (matchType : Expr) : TermElabM Expr := do
let matchType ← indices.foldrM (init := matchType) fun index matchType => do
let indexType ← inferType index
let matchTypeBody ← kabstract matchType index
let userName ← mkUserNameFor index
return Lean.mkForall userName BinderInfo.default indexType matchTypeBody
check matchType
return matchType
addWildcardPatterns (num : Nat) (altViews : Array MatchAltView) : TermElabM (Array MatchAltView) := do
let hole := mkHole (← getRef)
let wildcards := mkArray num hole
return altViews.map fun altView => { altView with patterns := wildcards ++ altView.patterns }
def mkMatcher (input : Meta.Match.MkMatcherInput) : TermElabM MatcherResult :=
Meta.Match.mkMatcher input
register_builtin_option match.ignoreUnusedAlts : Bool := {
defValue := false
descr := "if true, do not generate error if an alternative is not used"
}
def reportMatcherResultErrors (altLHSS : List AltLHS) (result : MatcherResult) : TermElabM Unit := do
unless result.counterExamples.isEmpty do
withHeadRefOnly <| logError m!"missing cases:\n{Meta.Match.counterExamplesToMessageData result.counterExamples}"
unless match.ignoreUnusedAlts.get (← getOptions) || result.unusedAltIdxs.isEmpty do
let mut i := 0
for alt in altLHSS do
if result.unusedAltIdxs.contains i then
withRef alt.ref do
logError "redundant alternative"
i := i + 1
/--
If `altLHSS + rhss` is encoding `| PUnit.unit => rhs[0]`, return `rhs[0]`
Otherwise, return none.
-/
private def isMatchUnit? (altLHSS : List Match.AltLHS) (rhss : Array Expr) : MetaM (Option Expr) := do
assert! altLHSS.length == rhss.size
match altLHSS with
| [ { fvarDecls := [], patterns := [ Pattern.ctor `PUnit.unit .. ], .. } ] =>
/- Recall that for alternatives of the form `| PUnit.unit => rhs`, `rhss[0]` is of the form `fun _ : Unit => b`. -/
match rhss[0] with
| Expr.lam _ _ b _ => return if b.hasLooseBVars then none else b
| _ => return none
| _ => return none
private def elabMatchAux (generalizing? : Option Bool) (discrStxs : Array Syntax) (altViews : Array MatchAltView) (matchOptType : Syntax) (expectedType : Expr)
: TermElabM Expr := do
let mut generalizing? := generalizing?
if !matchOptType.isNone then
if generalizing? == some true then
throwError "the '(generalizing := true)' parameter is not supported when the 'match' type is explicitly provided"
generalizing? := some false
let (discrs, matchType, altLHSS, isDep, rhss) ← commitIfDidNotPostpone do
let ⟨discrs, matchType, isDep, altViews⟩ ← elabMatchTypeAndDiscrs discrStxs matchOptType altViews expectedType
let matchAlts ← liftMacroM <| expandMacrosInPatterns altViews
trace[Elab.match] "matchType: {matchType}"
let (discrs, matchType, alts, refined) ← elabMatchAltViews generalizing? discrs matchType matchAlts
let isDep := isDep || refined
/-
We should not use `synthesizeSyntheticMVarsNoPostponing` here. Otherwise, we will not be
able to elaborate examples such as:
```
def f (x : Nat) : Option Nat := none
def g (xs : List (Nat × Nat)) : IO Unit :=
xs.forM fun x =>
match f x.fst with
| _ => pure ()
```
If `synthesizeSyntheticMVarsNoPostponing`, the example above fails at `x.fst` because
the type of `x` is only available after we proces the last argument of `List.forM`.
We apply pending default types to make sure we can process examples such as
```
let (a, b) := (0, 0)
```
-/
synthesizeSyntheticMVarsUsingDefault
let rhss := alts.map Prod.snd
let matchType ← instantiateMVars matchType
let altLHSS ← alts.toList.mapM fun alt => do
let altLHS ← Match.instantiateAltLHSMVars alt.1
/- Remark: we try to postpone before throwing an error.
The combinator `commitIfDidNotPostpone` ensures we backtrack any updates that have been performed.
The quick-check `waitExpectedTypeAndDiscrs` minimizes the number of scenarios where we have to postpone here.
Here is an example that passes the `waitExpectedTypeAndDiscrs` test, but postpones here.
```
def bad (ps : Array (Nat × Nat)) : Array (Nat × Nat) :=
(ps.filter fun (p : Prod _ _) =>
match p with
| (x, y) => x == 0)
++
ps
```
When we try to elaborate `fun (p : Prod _ _) => ...` for the first time, we haven't propagated the type of `ps` yet
because `Array.filter` has type `{α : Type u_1} → (α → Bool) → (as : Array α) → optParam Nat 0 → optParam Nat (Array.size as) → Array α`
However, the partial type annotation `(p : Prod _ _)` makes sure we succeed at the quick-check `waitExpectedTypeAndDiscrs`.
-/
withRef altLHS.ref do
for d in altLHS.fvarDecls do
if d.hasExprMVar then
withExistingLocalDecls altLHS.fvarDecls do
tryPostpone
throwMVarError m!"invalid match-expression, type of pattern variable '{d.toExpr}' contains metavariables{indentExpr d.type}"
for p in altLHS.patterns do
if p.hasExprMVar then
withExistingLocalDecls altLHS.fvarDecls do
tryPostpone
throwMVarError m!"invalid match-expression, pattern contains metavariables{indentExpr (← p.toExpr)}"
pure altLHS
return (discrs, matchType, altLHSS, isDep, rhss)
if let some r ← if isDep then pure none else isMatchUnit? altLHSS rhss then
return r
else
let numDiscrs := discrs.size
let matcherName ← mkAuxName `match
let matcherResult ← mkMatcher { matcherName, matchType, numDiscrs, lhss := altLHSS }
matcherResult.addMatcher
let motive ← forallBoundedTelescope matchType numDiscrs fun xs matchType => mkLambdaFVars xs matchType
reportMatcherResultErrors altLHSS matcherResult
let r := mkApp matcherResult.matcher motive
let r := mkAppN r discrs
let r := mkAppN r rhss
trace[Elab.match] "result: {r}"
return r
private def getDiscrs (matchStx : Syntax) : Array Syntax :=
matchStx[2].getSepArgs
private def getMatchOptType (matchStx : Syntax) : Syntax :=
matchStx[3]
private def expandNonAtomicDiscrs? (matchStx : Syntax) : TermElabM (Option Syntax) :=
let matchOptType := getMatchOptType matchStx;
if matchOptType.isNone then do
let discrs := getDiscrs matchStx;
let allLocal ← discrs.allM fun discr => Option.isSome <$> isAtomicDiscr? discr[1]
if allLocal then
return none
else
-- We use `foundFVars` to make sure the discriminants are distinct variables.
-- See: code for computing "matchType" at `elabMatchTypeAndDiscrs`
let rec loop (discrs : List Syntax) (discrsNew : Array Syntax) (foundFVars : FVarIdSet) := do
match discrs with
| [] =>
let discrs := Syntax.mkSep discrsNew (mkAtomFrom matchStx ", ");
pure (matchStx.setArg 2 discrs)
| discr :: discrs =>
-- Recall that
-- matchDiscr := leading_parser optional (ident >> ":") >> termParser
let term := discr[1]
let addAux : TermElabM Syntax := withFreshMacroScope do
let d ← `(_discr);
unless isAuxDiscrName d.getId do -- Use assertion?
throwError "unexpected internal auxiliary discriminant name"
let discrNew := discr.setArg 1 d;
let r ← loop discrs (discrsNew.push discrNew) foundFVars
`(let _discr := $term; $r)
match (← isAtomicDiscr? term) with
| some x => if x.isFVar then loop discrs (discrsNew.push discr) (foundFVars.insert x.fvarId!) else addAux
| none => addAux
return some (← loop discrs.toList #[] {})
else
-- We do not pull non atomic discriminants when match type is provided explicitly by the user
return none
private def waitExpectedType (expectedType? : Option Expr) : TermElabM Expr := do
tryPostponeIfNoneOrMVar expectedType?
match expectedType? with
| some expectedType => pure expectedType
| none => mkFreshTypeMVar
private def tryPostponeIfDiscrTypeIsMVar (matchStx : Syntax) : TermElabM Unit := do
-- We don't wait for the discriminants types when match type is provided by user
if getMatchOptType matchStx |>.isNone then
let discrs := getDiscrs matchStx
for discr in discrs do
let term := discr[1]
match (← isAtomicDiscr? term) with
| none => throwErrorAt discr "unexpected discriminant" -- see `expandNonAtomicDiscrs?
| some d =>
let dType ← inferType d
trace[Elab.match] "discr {d} : {dType}"
tryPostponeIfMVar dType
/-
We (try to) elaborate a `match` only when the expected type is available.
If the `matchType` has not been provided by the user, we also try to postpone elaboration if the type
of a discriminant is not available. That is, it is of the form `(?m ...)`.
We use `expandNonAtomicDiscrs?` to make sure all discriminants are local variables.
This is a standard trick we use in the elaborator, and it is also used to elaborate structure instances.
Suppose, we are trying to elaborate
```
match g x with
| ... => ...
```
`expandNonAtomicDiscrs?` converts it intro
```
let _discr := g x
match _discr with
| ... => ...
```
Thus, at `tryPostponeIfDiscrTypeIsMVar` we only need to check whether the type of `_discr` is not of the form `(?m ...)`.
Note that, the auxiliary variable `_discr` is expanded at `elabAtomicDiscr`.
This elaboration technique is needed to elaborate terms such as:
```lean
xs.filter fun (a, b) => a > b
```
which are syntax sugar for
```lean
List.filter (fun p => match p with | (a, b) => a > b) xs
```
When we visit `match p with | (a, b) => a > b`, we don't know the type of `p` yet.
-/
private def waitExpectedTypeAndDiscrs (matchStx : Syntax) (expectedType? : Option Expr) : TermElabM Expr := do
tryPostponeIfNoneOrMVar expectedType?
tryPostponeIfDiscrTypeIsMVar matchStx
match expectedType? with
| some expectedType => return expectedType
| none => mkFreshTypeMVar
/-
```
leading_parser:leadPrec "match " >> sepBy1 matchDiscr ", " >> optType >> " with " >> matchAlts
```
Remark the `optIdent` must be `none` at `matchDiscr`. They are expanded by `expandMatchDiscr?`.
-/
private def elabMatchCore (stx : Syntax) (expectedType? : Option Expr) : TermElabM Expr := do
let expectedType ← waitExpectedTypeAndDiscrs stx expectedType?
let discrStxs := (getDiscrs stx).map fun d => d
let gen? := getMatchGeneralizing? stx
let altViews := getMatchAlts stx
let matchOptType := getMatchOptType stx
elabMatchAux gen? discrStxs altViews matchOptType expectedType
private def isPatternVar (stx : Syntax) : TermElabM Bool := do
match (← resolveId? stx "pattern") with
| none => isAtomicIdent stx
| some f => match f with
| Expr.const fName _ _ =>
match (← getEnv).find? fName with
| some (ConstantInfo.ctorInfo _) => return false
| some _ => return !hasMatchPatternAttribute (← getEnv) fName
| _ => isAtomicIdent stx
| _ => isAtomicIdent stx
where
isAtomicIdent (stx : Syntax) : Bool :=
stx.isIdent && stx.getId.eraseMacroScopes.isAtomic
-- leading_parser "match " >> sepBy1 termParser ", " >> optType >> " with " >> matchAlts
@[builtinTermElab «match»] def elabMatch : TermElab := fun stx expectedType? => do
match stx with
| `(match $discr:term with | $y:ident => $rhs:term) =>
if (← isPatternVar y) then expandSimpleMatch stx discr y rhs expectedType? else elabMatchDefault stx expectedType?
| _ => elabMatchDefault stx expectedType?
where
elabMatchDefault (stx : Syntax) (expectedType? : Option Expr) : TermElabM Expr := do
match (← expandNonAtomicDiscrs? stx) with
| some stxNew => withMacroExpansion stx stxNew <| elabTerm stxNew expectedType?
| none =>
let discrs := getDiscrs stx;
let matchOptType := getMatchOptType stx;
if !matchOptType.isNone && discrs.any fun d => !d[0].isNone then
throwErrorAt matchOptType "match expected type should not be provided when discriminants with equality proofs are used"
elabMatchCore stx expectedType?
builtin_initialize
registerTraceClass `Elab.match
-- leading_parser:leadPrec "nomatch " >> termParser
@[builtinTermElab «nomatch»] def elabNoMatch : TermElab := fun stx expectedType? => do
match stx with
| `(nomatch $discrExpr) =>
match (← isLocalIdent? discrExpr) with
| some _ =>
let expectedType ← waitExpectedType expectedType?
let discr := Syntax.node ``Lean.Parser.Term.matchDiscr #[mkNullNode, discrExpr]
elabMatchAux none #[discr] #[] mkNullNode expectedType
| _ =>
let stxNew ← `(let _discr := $discrExpr; nomatch _discr)
withMacroExpansion stx stxNew <| elabTerm stxNew expectedType?
| _ => throwUnsupportedSyntax
end Lean.Elab.Term
|
88d7eb50fa1a128eadd61f03e8b07bba118c2249 | 57aec6ee746bc7e3a3dd5e767e53bd95beb82f6d | /stage0/src/Init/Classical.lean | 9ff9ff36eab24eb1cc3d0a8f8fefcd1e4dab2da6 | [
"Apache-2.0"
] | permissive | collares/lean4 | 861a9269c4592bce49b71059e232ff0bfe4594cc | 52a4f535d853a2c7c7eea5fee8a4fa04c682c1ee | refs/heads/master | 1,691,419,031,324 | 1,618,678,138,000 | 1,618,678,138,000 | 358,989,750 | 0 | 0 | Apache-2.0 | 1,618,696,333,000 | 1,618,696,333,000 | null | UTF-8 | Lean | false | false | 5,386 | lean | /-
Copyright (c) 2020 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
prelude
import Init.Core
import Init.NotationExtra
universes u v
/- Classical reasoning support -/
namespace Classical
axiom choice {α : Sort u} : Nonempty α → α
noncomputable def indefiniteDescription {α : Sort u} (p : α → Prop) (h : ∃ x, p x) : {x // p x} :=
choice <| let ⟨x, px⟩ := h; ⟨⟨x, px⟩⟩
noncomputable def choose {α : Sort u} {p : α → Prop} (h : ∃ x, p x) : α :=
(indefiniteDescription p h).val
theorem chooseSpec {α : Sort u} {p : α → Prop} (h : ∃ x, p x) : p (choose h) :=
(indefiniteDescription p h).property
/- Diaconescu's theorem: excluded middle from choice, Function extensionality and propositional extensionality. -/
theorem em (p : Prop) : p ∨ ¬p :=
let U (x : Prop) : Prop := x = True ∨ p;
let V (x : Prop) : Prop := x = False ∨ p;
have exU : ∃ x, U x from ⟨True, Or.inl rfl⟩;
have exV : ∃ x, V x from ⟨False, Or.inl rfl⟩;
let u : Prop := choose exU;
let v : Prop := choose exV;
have uDef : U u from chooseSpec exU;
have vDef : V v from chooseSpec exV;
have notUvOrP : u ≠ v ∨ p from
match uDef, vDef with
| Or.inr h, _ => Or.inr h
| _, Or.inr h => Or.inr h
| Or.inl hut, Or.inl hvf =>
have hne : u ≠ v from hvf.symm ▸ hut.symm ▸ trueNeFalse
Or.inl hne
have pImpliesUv : p → u = v from
fun hp =>
have hpred : U = V from
funext fun x =>
have hl : (x = True ∨ p) → (x = False ∨ p) from
fun a => Or.inr hp;
have hr : (x = False ∨ p) → (x = True ∨ p) from
fun a => Or.inr hp;
show (x = True ∨ p) = (x = False ∨ p) from
propext (Iff.intro hl hr);
have h₀ : ∀ exU exV, @choose _ U exU = @choose _ V exV from
hpred ▸ fun exU exV => rfl;
show u = v from h₀ ..;
match notUvOrP with
| Or.inl hne => Or.inr (mt pImpliesUv hne)
| Or.inr h => Or.inl h
theorem existsTrueOfNonempty {α : Sort u} : Nonempty α → ∃ x : α, True
| ⟨x⟩ => ⟨x, trivial⟩
noncomputable def inhabitedOfNonempty {α : Sort u} (h : Nonempty α) : Inhabited α :=
⟨choice h⟩
noncomputable def inhabitedOfExists {α : Sort u} {p : α → Prop} (h : ∃ x, p x) : Inhabited α :=
inhabitedOfNonempty (Exists.elim h (fun w hw => ⟨w⟩))
/- all propositions are Decidable -/
noncomputable scoped instance (priority := low) propDecidable (a : Prop) : Decidable a :=
choice <| match em a with
| Or.inl h => ⟨isTrue h⟩
| Or.inr h => ⟨isFalse h⟩
noncomputable def decidableInhabited (a : Prop) : Inhabited (Decidable a) where
default := inferInstance
noncomputable def typeDecidableEq (α : Sort u) : DecidableEq α :=
fun x y => inferInstance
noncomputable def typeDecidable (α : Sort u) : PSum α (α → False) :=
match (propDecidable (Nonempty α)) with
| (isTrue hp) => PSum.inl (@arbitrary _ (inhabitedOfNonempty hp))
| (isFalse hn) => PSum.inr (fun a => absurd (Nonempty.intro a) hn)
noncomputable def strongIndefiniteDescription {α : Sort u} (p : α → Prop) (h : Nonempty α) : {x : α // (∃ y : α, p y) → p x} :=
@dite _ (∃ x : α, p x) (propDecidable _)
(fun (hp : ∃ x : α, p x) =>
show {x : α // (∃ y : α, p y) → p x} from
let xp := indefiniteDescription _ hp;
⟨xp.val, fun h' => xp.property⟩)
(fun hp => ⟨choice h, fun h => absurd h hp⟩)
/- the Hilbert epsilon Function -/
noncomputable def epsilon {α : Sort u} [h : Nonempty α] (p : α → Prop) : α :=
(strongIndefiniteDescription p h).val
theorem epsilonSpecAux {α : Sort u} (h : Nonempty α) (p : α → Prop) : (∃ y, p y) → p (@epsilon α h p) :=
(strongIndefiniteDescription p h).property
theorem epsilonSpec {α : Sort u} {p : α → Prop} (hex : ∃ y, p y) : p (@epsilon α (nonemptyOfExists hex) p) :=
epsilonSpecAux (nonemptyOfExists hex) p hex
theorem epsilonSingleton {α : Sort u} (x : α) : @epsilon α ⟨x⟩ (fun y => y = x) = x :=
@epsilonSpec α (fun y => y = x) ⟨x, rfl⟩
/- the axiom of choice -/
theorem axiomOfChoice {α : Sort u} {β : α → Sort v} {r : ∀ x, β x → Prop} (h : ∀ x, ∃ y, r x y) : ∃ (f : ∀ x, β x), ∀ x, r x (f x) :=
⟨_, fun x => chooseSpec (h x)⟩
theorem skolem {α : Sort u} {b : α → Sort v} {p : ∀ x, b x → Prop} : (∀ x, ∃ y, p x y) ↔ ∃ (f : ∀ x, b x), ∀ x, p x (f x) :=
⟨axiomOfChoice, fun ⟨f, hw⟩ (x) => ⟨f x, hw x⟩⟩
theorem propComplete (a : Prop) : a = True ∨ a = False := by
cases em a with
| inl _ => apply Or.inl; apply propext; apply Iff.intro; { intros; apply True.intro }; { intro; assumption }
| inr hn => apply Or.inr; apply propext; apply Iff.intro; { intro h; exact hn h }; { intro h; apply False.elim h }
-- this supercedes byCases in Decidable
theorem byCases {p q : Prop} (hpq : p → q) (hnpq : ¬p → q) : q :=
Decidable.byCases (dec := propDecidable _) hpq hnpq
-- this supercedes byContradiction in Decidable
theorem byContradiction {p : Prop} (h : ¬p → False) : p :=
Decidable.byContradiction (dec := propDecidable _) h
macro "byCases" h:ident ":" e:term : tactic =>
`(cases em $e:term with
| inl $h:ident => _
| inr $h:ident => _)
end Classical
|
7dd255fdbfc8ef057df188f5b3d9cbddd0e7e3c2 | 5749d8999a76f3a8fddceca1f6941981e33aaa96 | /src/algebra/module.lean | ab0ffb0678a9269d5dfef07914fe9383f1ad98f8 | [
"Apache-2.0"
] | permissive | jdsalchow/mathlib | 13ab43ef0d0515a17e550b16d09bd14b76125276 | 497e692b946d93906900bb33a51fd243e7649406 | refs/heads/master | 1,585,819,143,348 | 1,580,072,892,000 | 1,580,072,892,000 | 154,287,128 | 0 | 0 | Apache-2.0 | 1,540,281,610,000 | 1,540,281,609,000 | null | UTF-8 | Lean | false | false | 18,158 | lean | /-
Copyright (c) 2015 Nathaniel Thomas. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Nathaniel Thomas, Jeremy Avigad, Johannes Hölzl, Mario Carneiro
Modules over a ring.
## Implementation notes
Throughout the `linear_map` section implicit `{}` brackets are often used instead of type class `[]` brackets.
This is done when the instances can be inferred because they are implicit arguments to the type `linear_map`.
When they can be inferred from the type it is faster to use this method than to use type class inference
-/
import algebra.ring algebra.big_operators group_theory.subgroup group_theory.group_action
open function
universes u v w x
variables {α : Type u} {β : Type v} {γ : Type w} {δ : Type x}
-- /-- Typeclass for types with a scalar multiplication operation, denoted `•` (`\bu`) -/
-- class has_scalar (α : Type u) (γ : Type v) := (smul : α → γ → γ)
-- infixr ` • `:73 := has_scalar.smul
section prio
set_option default_priority 100 -- see Note [default priority]
/-- A semimodule is a generalization of vector spaces to a scalar semiring.
It consists of a scalar semiring `α` and an additive monoid of "vectors" `β`,
connected by a "scalar multiplication" operation `r • x : β`
(where `r : α` and `x : β`) with some natural associativity and
distributivity axioms similar to those on a ring. -/
class semimodule (α : Type u) (β : Type v) [semiring α]
[add_comm_monoid β] extends distrib_mul_action α β :=
(add_smul : ∀(r s : α) (x : β), (r + s) • x = r • x + s • x)
(zero_smul : ∀x : β, (0 : α) • x = 0)
end prio
section semimodule
variables [R:semiring α] [add_comm_monoid β] [semimodule α β] (r s : α) (x y : β)
include R
theorem add_smul : (r + s) • x = r • x + s • x := semimodule.add_smul r s x
variables (α)
@[simp] theorem zero_smul : (0 : α) • x = 0 := semimodule.zero_smul α x
variable {α}
lemma semimodule.eq_zero_of_zero_eq_one (zero_eq_one : (0 : α) = 1) : x = 0 :=
by rw [←one_smul α x, ←zero_eq_one, zero_smul]
instance smul.is_add_monoid_hom (x : β) : is_add_monoid_hom (λ r:α, r • x) :=
{ map_zero := zero_smul _ x,
map_add := λ r₁ r₂, add_smul r₁ r₂ x }
lemma list.sum_smul {l : list α} {x : β} : l.sum • x = (l.map (λ r, r • x)).sum :=
show (λ r, r • x) l.sum = (l.map (λ r, r • x)).sum,
from (list.sum_hom _ _).symm
lemma multiset.sum_smul {l : multiset α} {x : β} : l.sum • x = (l.map (λ r, r • x)).sum :=
show (λ r, r • x) l.sum = (l.map (λ r, r • x)).sum,
from (multiset.sum_hom _ _).symm
lemma finset.sum_smul {f : γ → α} {s : finset γ} {x : β} :
s.sum f • x = s.sum (λ r, (f r) • x) :=
show (λ r, r • x) (s.sum f) = s.sum (λ r, (f r) • x),
from (finset.sum_hom _ _).symm
end semimodule
section prio
set_option default_priority 100 -- see Note [default priority]
/-- A module is a generalization of vector spaces to a scalar ring.
It consists of a scalar ring `α` and an additive group of "vectors" `β`,
connected by a "scalar multiplication" operation `r • x : β`
(where `r : α` and `x : β`) with some natural associativity and
distributivity axioms similar to those on a ring. -/
class module (α : Type u) (β : Type v) [ring α] [add_comm_group β] extends semimodule α β
end prio
structure module.core (α β) [ring α] [add_comm_group β] extends has_scalar α β :=
(smul_add : ∀(r : α) (x y : β), r • (x + y) = r • x + r • y)
(add_smul : ∀(r s : α) (x : β), (r + s) • x = r • x + s • x)
(mul_smul : ∀(r s : α) (x : β), (r * s) • x = r • s • x)
(one_smul : ∀x : β, (1 : α) • x = x)
def module.of_core {α β} [ring α] [add_comm_group β] (M : module.core α β) : module α β :=
by letI := M.to_has_scalar; exact
{ zero_smul := λ x,
have (0 : α) • x + (0 : α) • x = (0 : α) • x + 0, by rw ← M.add_smul; simp,
add_left_cancel this,
smul_zero := λ r,
have r • (0:β) + r • 0 = r • 0 + 0, by rw ← M.smul_add; simp,
add_left_cancel this,
..M }
section module
variables [ring α] [add_comm_group β] [module α β] (r s : α) (x y : β)
@[simp] theorem neg_smul : -r • x = - (r • x) :=
eq_neg_of_add_eq_zero (by rw [← add_smul, add_left_neg, zero_smul])
variables (α)
theorem neg_one_smul (x : β) : (-1 : α) • x = -x := by simp
variables {α}
@[simp] theorem smul_neg : r • (-x) = -(r • x) :=
by rw [← neg_one_smul α, ← mul_smul, mul_neg_one, neg_smul]
theorem smul_sub (r : α) (x y : β) : r • (x - y) = r • x - r • y :=
by simp [smul_add]; rw smul_neg
theorem sub_smul (r s : α) (y : β) : (r - s) • y = r • y - s • y :=
by simp [add_smul]
end module
instance semiring.to_semimodule [r : semiring α] : semimodule α α :=
{ smul := (*),
smul_add := mul_add,
add_smul := add_mul,
mul_smul := mul_assoc,
one_smul := one_mul,
zero_smul := zero_mul,
smul_zero := mul_zero, ..r }
@[simp] lemma smul_eq_mul [semiring α] {a a' : α} : a • a' = a * a' := rfl
instance ring.to_module [r : ring α] : module α α :=
{ ..semiring.to_semimodule }
def is_ring_hom.to_module [ring α] [ring β] (f : α → β) [h : is_ring_hom f] : module α β :=
module.of_core
{ smul := λ r x, f r * x,
smul_add := λ r x y, by unfold has_scalar.smul; rw [mul_add],
add_smul := λ r s x, by unfold has_scalar.smul; rw [h.map_add, add_mul],
mul_smul := λ r s x, by unfold has_scalar.smul; rw [h.map_mul, mul_assoc],
one_smul := λ x, show f 1 * x = _, by rw [h.map_one, one_mul] }
class is_linear_map (α : Type u) {β : Type v} {γ : Type w}
[ring α] [add_comm_group β] [add_comm_group γ] [module α β] [module α γ]
(f : β → γ) : Prop :=
(add : ∀x y, f (x + y) = f x + f y)
(smul : ∀(c : α) x, f (c • x) = c • f x)
structure linear_map (α : Type u) (β : Type v) (γ : Type w)
[ring α] [add_comm_group β] [add_comm_group γ] [module α β] [module α γ] :=
(to_fun : β → γ)
(add : ∀x y, to_fun (x + y) = to_fun x + to_fun y)
(smul : ∀(c : α) x, to_fun (c • x) = c • to_fun x)
infixr ` →ₗ `:25 := linear_map _
notation β ` →ₗ[`:25 α:25 `] `:0 γ:0 := linear_map α β γ
namespace linear_map
variables {rα : ring α} {gβ : add_comm_group β} {gγ : add_comm_group γ} {gδ : add_comm_group δ}
variables {mβ : module α β} {mγ : module α γ} {mδ : module α δ}
variables (f g : β →ₗ[α] γ)
include α mβ mγ
instance : has_coe_to_fun (β →ₗ[α] γ) := ⟨_, to_fun⟩
@[simp] lemma coe_mk (f : β → γ) (h₁ h₂) :
((linear_map.mk f h₁ h₂ : β →ₗ[α] γ) : β → γ) = f := rfl
theorem is_linear : is_linear_map α f := {..f}
@[ext] theorem ext {f g : β →ₗ[α] γ} (H : ∀ x, f x = g x) : f = g :=
by cases f; cases g; congr'; exact funext H
theorem ext_iff {f g : β →ₗ[α] γ} : f = g ↔ ∀ x, f x = g x :=
⟨by rintro rfl; simp, ext⟩
@[simp] lemma map_add (x y : β) : f (x + y) = f x + f y := f.add x y
@[simp] lemma map_smul (c : α) (x : β) : f (c • x) = c • f x := f.smul c x
@[simp] lemma map_zero : f 0 = 0 :=
by rw [← zero_smul α, map_smul f 0 0, zero_smul]
instance : is_add_group_hom f := { map_add := map_add f }
@[simp] lemma map_neg (x : β) : f (- x) = - f x :=
by rw [← neg_one_smul α, map_smul, neg_one_smul]
@[simp] lemma map_sub (x y : β) : f (x - y) = f x - f y :=
by simp [map_neg, map_add]
@[simp] lemma map_sum {ι} {t : finset ι} {g : ι → β} :
f (t.sum g) = t.sum (λi, f (g i)) :=
(t.sum_hom f).symm
include mδ
def comp (f : γ →ₗ[α] δ) (g : β →ₗ[α] γ) : β →ₗ[α] δ := ⟨f ∘ g, by simp, by simp⟩
@[simp] lemma comp_apply (f : γ →ₗ[α] δ) (g : β →ₗ[α] γ) (x : β) : f.comp g x = f (g x) := rfl
omit mγ mδ
variables [rα] [gβ] [mβ]
def id : β →ₗ[α] β := ⟨id, by simp, by simp⟩
@[simp] lemma id_apply (x : β) : @id α β _ _ _ x = x := rfl
end linear_map
namespace is_linear_map
variables [ring α] [add_comm_group β] [add_comm_group γ]
variables [module α β] [module α γ]
include α
def mk' (f : β → γ) (H : is_linear_map α f) : β →ₗ γ := {to_fun := f, ..H}
@[simp] theorem mk'_apply {f : β → γ} (H : is_linear_map α f) (x : β) :
mk' f H x = f x := rfl
lemma is_linear_map_neg :
is_linear_map α (λ (z : β), -z) :=
is_linear_map.mk neg_add (λ x y, (smul_neg x y).symm)
lemma is_linear_map_smul {α R : Type*} [add_comm_group α] [comm_ring R] [module R α] (c : R) :
is_linear_map R (λ (z : α), c • z) :=
begin
refine is_linear_map.mk (smul_add c) _,
intros _ _,
simp [smul_smul],
ac_refl
end
--TODO: move
lemma is_linear_map_smul' {α R : Type*} [add_comm_group α] [ring R] [module R α] (a : α) :
is_linear_map R (λ (c : R), c • a) :=
begin
refine is_linear_map.mk (λ x y, add_smul x y a) _,
intros _ _,
simp [smul_smul]
end
variables {f : β → γ} (lin : is_linear_map α f)
include β γ lin
@[simp] lemma map_zero : f (0 : β) = (0 : γ) :=
by rw [← zero_smul α (0 : β), lin.smul, zero_smul]
@[simp] lemma map_add (x y : β) : f (x + y) = f x + f y :=
by rw [lin.add]
@[simp] lemma map_neg (x : β) : f (- x) = - f x :=
by rw [← neg_one_smul α, lin.smul, neg_one_smul]
@[simp] lemma map_sub (x y : β) : f (x - y) = f x - f y :=
by simp [lin.map_neg, lin.map_add]
end is_linear_map
abbreviation module.End (R : Type u) (M : Type v)
[comm_ring R] [add_comm_group M] [module R M] := M →ₗ[R] M
/-- A submodule of a module is one which is closed under vector operations.
This is a sufficient condition for the subset of vectors in the submodule
to themselves form a module. -/
structure submodule (α : Type u) (β : Type v) [ring α]
[add_comm_group β] [module α β] : Type v :=
(carrier : set β)
(zero : (0:β) ∈ carrier)
(add : ∀ {x y}, x ∈ carrier → y ∈ carrier → x + y ∈ carrier)
(smul : ∀ (c:α) {x}, x ∈ carrier → c • x ∈ carrier)
namespace submodule
variables [ring α] [add_comm_group β] [add_comm_group γ]
variables [module α β] [module α γ]
variables (p p' : submodule α β)
variables {r : α} {x y : β}
instance : has_coe (submodule α β) (set β) := ⟨submodule.carrier⟩
instance : has_mem β (submodule α β) := ⟨λ x p, x ∈ (p : set β)⟩
@[simp] theorem mem_coe : x ∈ (p : set β) ↔ x ∈ p := iff.rfl
theorem ext' {s t : submodule α β} (h : (s : set β) = t) : s = t :=
by cases s; cases t; congr'
protected theorem ext'_iff {s t : submodule α β} : (s : set β) = t ↔ s = t :=
⟨ext', λ h, h ▸ rfl⟩
@[ext] theorem ext {s t : submodule α β}
(h : ∀ x, x ∈ s ↔ x ∈ t) : s = t := ext' $ set.ext h
@[simp] lemma zero_mem : (0 : β) ∈ p := p.zero
lemma add_mem (h₁ : x ∈ p) (h₂ : y ∈ p) : x + y ∈ p := p.add h₁ h₂
lemma smul_mem (r : α) (h : x ∈ p) : r • x ∈ p := p.smul r h
lemma neg_mem (hx : x ∈ p) : -x ∈ p := by rw ← neg_one_smul α; exact p.smul_mem _ hx
lemma sub_mem (hx : x ∈ p) (hy : y ∈ p) : x - y ∈ p := p.add_mem hx (p.neg_mem hy)
lemma neg_mem_iff : -x ∈ p ↔ x ∈ p :=
⟨λ h, by simpa using neg_mem p h, neg_mem p⟩
lemma add_mem_iff_left (h₁ : y ∈ p) : x + y ∈ p ↔ x ∈ p :=
⟨λ h₂, by simpa using sub_mem _ h₂ h₁, λ h₂, add_mem _ h₂ h₁⟩
lemma add_mem_iff_right (h₁ : x ∈ p) : x + y ∈ p ↔ y ∈ p :=
⟨λ h₂, by simpa using sub_mem _ h₂ h₁, add_mem _ h₁⟩
lemma sum_mem {ι : Type w} [decidable_eq ι] {t : finset ι} {f : ι → β} :
(∀c∈t, f c ∈ p) → t.sum f ∈ p :=
finset.induction_on t (by simp [p.zero_mem]) (by simp [p.add_mem] {contextual := tt})
instance : has_add p := ⟨λx y, ⟨x.1 + y.1, add_mem _ x.2 y.2⟩⟩
instance : has_zero p := ⟨⟨0, zero_mem _⟩⟩
instance : has_neg p := ⟨λx, ⟨-x.1, neg_mem _ x.2⟩⟩
instance : has_scalar α p := ⟨λ c x, ⟨c • x.1, smul_mem _ c x.2⟩⟩
@[simp, move_cast] lemma coe_add (x y : p) : (↑(x + y) : β) = ↑x + ↑y := rfl
@[simp, elim_cast] lemma coe_zero : ((0 : p) : β) = 0 := rfl
@[simp, move_cast] lemma coe_neg (x : p) : ((-x : p) : β) = -x := rfl
@[simp, move_cast] lemma coe_smul (r : α) (x : p) : ((r • x : p) : β) = r • ↑x := rfl
instance : add_comm_group p :=
by refine {add := (+), zero := 0, neg := has_neg.neg, ..};
{ intros, apply set_coe.ext, simp }
instance submodule_is_add_subgroup : is_add_subgroup (p : set β) :=
{ zero_mem := p.zero,
add_mem := p.add,
neg_mem := λ _, p.neg_mem }
@[move_cast] lemma coe_sub (x y : p) : (↑(x - y) : β) = ↑x - ↑y := by simp
instance : module α p :=
by refine {smul := (•), ..};
{ intros, apply set_coe.ext, simp [smul_add, add_smul, mul_smul] }
protected def subtype : p →ₗ[α] β :=
by refine {to_fun := coe, ..}; simp [coe_smul]
@[simp] theorem subtype_apply (x : p) : p.subtype x = x := rfl
lemma subtype_eq_val (p : submodule α β) :
((submodule.subtype p) : p → β) = subtype.val := rfl
end submodule
@[reducible] def ideal (α : Type u) [comm_ring α] := submodule α α
namespace ideal
variables [comm_ring α] (I : ideal α) {a b : α}
protected lemma zero_mem : (0 : α) ∈ I := I.zero_mem
protected lemma add_mem : a ∈ I → b ∈ I → a + b ∈ I := I.add_mem
lemma neg_mem_iff : -a ∈ I ↔ a ∈ I := I.neg_mem_iff
lemma add_mem_iff_left : b ∈ I → (a + b ∈ I ↔ a ∈ I) := I.add_mem_iff_left
lemma add_mem_iff_right : a ∈ I → (a + b ∈ I ↔ b ∈ I) := I.add_mem_iff_right
protected lemma sub_mem : a ∈ I → b ∈ I → a - b ∈ I := I.sub_mem
lemma mul_mem_left : b ∈ I → a * b ∈ I := I.smul_mem _
lemma mul_mem_right (h : a ∈ I) : a * b ∈ I := mul_comm b a ▸ I.mul_mem_left h
end ideal
library_note "vector space definition"
"Vector spaces are defined as an `abbreviation` for modules,
if the base ring is a field.
(A previous definition made `vector_space` a structure
defined to be `module`.)
This has as advantage that vector spaces are completely transparant
for type class inference, which means that all instances for modules
are immediately picked up for vector spaces as well.
A cosmetic disadvantage is that one can not extend vector spaces an sich,
in definitions such as `normed_space`.
The solution is to extend `module` instead."
/-- A vector space is the same as a module, except the scalar ring is actually
a field. (This adds commutativity of the multiplication and existence of inverses.)
This is the traditional generalization of spaces like `ℝ^n`, which have a natural
addition operation and a way to multiply them by real numbers, but no multiplication
operation between vectors. -/
abbreviation vector_space (α : Type u) (β : Type v) [discrete_field α] [add_comm_group β] :=
module α β
instance discrete_field.to_vector_space {α : Type*} [discrete_field α] : vector_space α α :=
{ .. ring.to_module }
/-- Subspace of a vector space. Defined to equal `submodule`. -/
@[reducible] def subspace (α : Type u) (β : Type v)
[discrete_field α] [add_comm_group β] [vector_space α β] : Type v :=
submodule α β
instance subspace.vector_space {α β}
{f : discrete_field α} [add_comm_group β] [vector_space α β]
(p : subspace α β) : vector_space α p := {..submodule.module p}
namespace submodule
variables {R:discrete_field α} [add_comm_group β] [add_comm_group γ]
variables [vector_space α β] [vector_space α γ]
variables (p p' : submodule α β)
variables {r : α} {x y : β}
include R
set_option class.instance_max_depth 36
theorem smul_mem_iff (r0 : r ≠ 0) : r • x ∈ p ↔ x ∈ p :=
⟨λ h, by simpa [smul_smul, inv_mul_cancel r0] using p.smul_mem (r⁻¹) h,
p.smul_mem r⟩
end submodule
namespace add_comm_monoid
open add_monoid
variables {M : Type*} [add_comm_monoid M]
instance : semimodule ℕ M :=
{ smul := smul,
smul_add := λ _ _ _, smul_add _ _ _,
add_smul := λ _ _ _, add_smul _ _ _,
mul_smul := λ _ _ _, mul_smul _ _ _,
one_smul := one_smul,
zero_smul := zero_smul,
smul_zero := smul_zero }
end add_comm_monoid
namespace add_comm_group
variables {M : Type*} [add_comm_group M]
instance : module ℤ M :=
{ smul := gsmul,
smul_add := λ _ _ _, gsmul_add _ _ _,
add_smul := λ _ _ _, add_gsmul _ _ _,
mul_smul := λ _ _ _, gsmul_mul _ _ _,
one_smul := one_gsmul,
zero_smul := zero_gsmul,
smul_zero := gsmul_zero }
end add_comm_group
lemma gsmul_eq_smul {M : Type*} [add_comm_group M] (n : ℤ) (x : M) : gsmul n x = n • x := rfl
def is_add_group_hom.to_linear_map [add_comm_group α] [add_comm_group β]
(f : α → β) [is_add_group_hom f] : α →ₗ[ℤ] β :=
{ to_fun := f,
add := is_add_hom.map_add f,
smul := λ i x, int.induction_on i (by rw [zero_smul, zero_smul, is_add_group_hom.map_zero f])
(λ i ih, by rw [add_smul, add_smul, is_add_hom.map_add f, ih, one_smul, one_smul])
(λ i ih, by rw [sub_smul, sub_smul, is_add_group_hom.map_sub f, ih, one_smul, one_smul]) }
lemma module.smul_eq_smul {R : Type*} [ring R] {β : Type*} [add_comm_group β] [module R β]
(n : ℕ) (b : β) : n • b = (n : R) • b :=
begin
induction n with n ih,
{ rw [nat.cast_zero, zero_smul, zero_smul] },
{ change (n + 1) • b = (n + 1 : R) • b,
rw [add_smul, add_smul, one_smul, ih, one_smul] }
end
lemma nat.smul_def {M : Type*} [add_comm_monoid M] (n : ℕ) (x : M) :
n • x = add_monoid.smul n x :=
rfl
namespace finset
lemma sum_const' {α : Type*} (R : Type*) [ring R] {β : Type*}
[add_comm_group β] [module R β] {s : finset α} (b : β) :
finset.sum s (λ (a : α), b) = (finset.card s : R) • b :=
by rw [finset.sum_const, ← module.smul_eq_smul]; refl
variables {M : Type*} [decidable_linear_ordered_cancel_comm_monoid M]
{s : finset α} (f : α → M)
theorem exists_card_smul_le_sum (hs : s.nonempty) :
∃ i ∈ s, s.card • f i ≤ s.sum f :=
exists_le_of_sum_le hs $ by rw [sum_const, ← nat.smul_def, smul_sum]
theorem exists_card_smul_ge_sum (hs : s.nonempty) :
∃ i ∈ s, s.sum f ≤ s.card • f i :=
exists_le_of_sum_le hs $ by rw [sum_const, ← nat.smul_def, smul_sum]
end finset
|
61b74d6e1ce44b7dee1fd4e6759095b95b0aaf96 | 56e5b79a7ab4f2c52e6eb94f76d8100a25273cf3 | /src/evaluation/bfs/fairseq.lean | a8c0bb463954fa96a09bfae4fbc0782c5e4c8c93 | [
"Apache-2.0"
] | permissive | DyeKuu/lean-tpe-public | 3a9968f286ca182723ef7e7d97e155d8cb6b1e70 | 750ade767ab28037e80b7a80360d213a875038f8 | refs/heads/master | 1,682,842,633,115 | 1,621,330,793,000 | 1,621,330,793,000 | 368,475,816 | 0 | 0 | Apache-2.0 | 1,621,330,745,000 | 1,621,330,744,000 | null | UTF-8 | Lean | false | false | 1,735 | lean | import evaluation_step
import backends.bfs.fairseq
section main
meta def SEARCH_CORE
(req : fairseq.CompletionRequest)
(entry_pt : string)
(model_path : string)
(data_path : string)
(fuel : ℕ := 25) :
state_t BFSState tactic unit :=
fairseq.fairseq_bfs_proof_search_core req entry_pt model_path data_path fuel
meta def main : io unit := do {
args ← io.cmdline_args,
decls_file ← args.nth_except 0 "decls_file",
dest ← args.nth_except 1 "dest",
max_tokens ← string.to_nat <$> args.nth_except 2 "max_tokens",
(some temperature) ← (native.float.of_string <$> (lift_option $ args.nth 3)) | io.fail "must supply temperature",
nbest ← string.to_nat <$> args.nth_except 4 "nbest",
beam ← string.to_nat <$> args.nth_except 5 "beam",
fuel ← string.to_nat <$> args.nth_except 6 "fuel",
max_width ← string.to_nat <$> args.nth_except 7 "max_width",
max_depth ← string.to_nat <$> args.nth_except 8 "max_depth",
entry_pt ← lift_option $ args.nth 9 | io.fail "must supply entry point",
model_path ← lift_option $ args.nth 10 | io.fail "must supply model path",
data_path ← lift_option $ args.nth 11 | io.fail "must supply data path",
tac_timeout ← string.to_nat <$> args.nth_except 12 "tac_timeout",
global_timeout ← string.to_nat <$> args.nth_except 13 "global_timeout",
let req : fairseq.CompletionRequest := {
max_tokens := max_tokens,
temperature := temperature,
nbest := nbest,
beam := beam,
..fairseq.default_partial_req
},
evaluation_harness_from_decls_file
(SEARCH_CORE req entry_pt model_path data_path fuel)
decls_file dest global_timeout $
BFSState.of_current_state 0 max_width max_depth tac_timeout
}
end main
|
9ffddee365a00b00767fcf42f71f53c8942d8e3d | 55c7fc2bf55d496ace18cd6f3376e12bb14c8cc5 | /src/ring_theory/algebra_operations.lean | 9b01f6abab4265976e66f263956bd1eb323569a6 | [
"Apache-2.0"
] | permissive | dupuisf/mathlib | 62de4ec6544bf3b79086afd27b6529acfaf2c1bb | 8582b06b0a5d06c33ee07d0bdf7c646cae22cf36 | refs/heads/master | 1,669,494,854,016 | 1,595,692,409,000 | 1,595,692,409,000 | 272,046,630 | 0 | 0 | Apache-2.0 | 1,592,066,143,000 | 1,592,066,142,000 | null | UTF-8 | Lean | false | false | 9,687 | lean | /-
Copyright (c) 2019 Kenny Lau. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenny Lau
Multiplication and division of submodules of an algebra.
-/
import ring_theory.algebra
universes u v
open algebra set
namespace submodule
variables {R : Type u} [comm_semiring R]
section ring
variables {A : Type v} [semiring A] [algebra R A]
variables (S T : set A) {M N P Q : submodule R A} {m n : A}
instance : has_one (submodule R A) :=
⟨submodule.map (of_id R A).to_linear_map (⊤ : submodule R R)⟩
theorem one_eq_map_top :
(1 : submodule R A) = submodule.map (of_id R A).to_linear_map (⊤ : submodule R R) := rfl
theorem one_eq_span : (1 : submodule R A) = span R {1} :=
begin
apply submodule.ext,
intro a,
erw [mem_map, mem_span_singleton],
apply exists_congr,
intro r,
simpa [smul_def],
end
theorem one_le : (1 : submodule R A) ≤ P ↔ (1 : A) ∈ P :=
by simpa only [one_eq_span, span_le, set.singleton_subset_iff]
instance : has_mul (submodule R A) :=
⟨λ M N, ⨆ s : M, N.map $ algebra.lmul R A s.1⟩
theorem mul_mem_mul (hm : m ∈ M) (hn : n ∈ N) : m * n ∈ M * N :=
(le_supr _ ⟨m, hm⟩ : _ ≤ M * N) ⟨n, hn, rfl⟩
theorem mul_le : M * N ≤ P ↔ ∀ (m ∈ M) (n ∈ N), m * n ∈ P :=
⟨λ H m hm n hn, H $ mul_mem_mul hm hn,
λ H, supr_le $ λ ⟨m, hm⟩, map_le_iff_le_comap.2 $ λ n hn, H m hm n hn⟩
@[elab_as_eliminator] protected theorem mul_induction_on
{C : A → Prop} {r : A} (hr : r ∈ M * N)
(hm : ∀ (m ∈ M) (n ∈ N), C (m * n))
(h0 : C 0) (ha : ∀ x y, C x → C y → C (x + y))
(hs : ∀ (r : R) x, C x → C (r • x)) : C r :=
(@mul_le _ _ _ _ _ _ _ ⟨C, h0, ha, hs⟩).2 hm hr
variables R
theorem span_mul_span : span R S * span R T = span R (S * T) :=
begin
apply le_antisymm,
{ rw mul_le, intros a ha b hb,
apply span_induction ha,
work_on_goal 0 { intros, apply span_induction hb,
work_on_goal 0 { intros, exact subset_span ⟨_, _, ‹_›, ‹_›, rfl⟩ } },
all_goals { intros, simp only [mul_zero, zero_mul, zero_mem,
left_distrib, right_distrib, mul_smul_comm, smul_mul_assoc],
try {apply add_mem _ _ _}, try {apply smul_mem _ _ _} }, assumption' },
{ rw span_le, rintros _ ⟨a, b, ha, hb, rfl⟩,
exact mul_mem_mul (subset_span ha) (subset_span hb) }
end
variables {R}
variables (M N P Q)
protected theorem mul_assoc : (M * N) * P = M * (N * P) :=
le_antisymm (mul_le.2 $ λ mn hmn p hp, suffices M * N ≤ (M * (N * P)).comap ((algebra.lmul R A).flip p), from this hmn,
mul_le.2 $ λ m hm n hn, show m * n * p ∈ M * (N * P), from
(mul_assoc m n p).symm ▸ mul_mem_mul hm (mul_mem_mul hn hp))
(mul_le.2 $ λ m hm np hnp, suffices N * P ≤ (M * N * P).comap (algebra.lmul R A m), from this hnp,
mul_le.2 $ λ n hn p hp, show m * (n * p) ∈ M * N * P, from
mul_assoc m n p ▸ mul_mem_mul (mul_mem_mul hm hn) hp)
@[simp] theorem mul_bot : M * ⊥ = ⊥ :=
eq_bot_iff.2 $ mul_le.2 $ λ m hm n hn, by rw [submodule.mem_bot] at hn ⊢; rw [hn, mul_zero]
@[simp] theorem bot_mul : ⊥ * M = ⊥ :=
eq_bot_iff.2 $ mul_le.2 $ λ m hm n hn, by rw [submodule.mem_bot] at hm ⊢; rw [hm, zero_mul]
@[simp] protected theorem one_mul : (1 : submodule R A) * M = M :=
by { conv_lhs { rw [one_eq_span, ← span_eq M] }, erw [span_mul_span, one_mul, span_eq] }
@[simp] protected theorem mul_one : M * 1 = M :=
by { conv_lhs { rw [one_eq_span, ← span_eq M] }, erw [span_mul_span, mul_one, span_eq] }
variables {M N P Q}
@[mono] theorem mul_le_mul (hmp : M ≤ P) (hnq : N ≤ Q) : M * N ≤ P * Q :=
mul_le.2 $ λ m hm n hn, mul_mem_mul (hmp hm) (hnq hn)
theorem mul_le_mul_left (h : M ≤ N) : M * P ≤ N * P :=
mul_le_mul h (le_refl P)
theorem mul_le_mul_right (h : N ≤ P) : M * N ≤ M * P :=
mul_le_mul (le_refl M) h
variables (M N P)
theorem mul_sup : M * (N ⊔ P) = M * N ⊔ M * P :=
le_antisymm (mul_le.2 $ λ m hm np hnp, let ⟨n, hn, p, hp, hnp⟩ := mem_sup.1 hnp in
mem_sup.2 ⟨_, mul_mem_mul hm hn, _, mul_mem_mul hm hp, hnp ▸ (mul_add m n p).symm⟩)
(sup_le (mul_le_mul_right le_sup_left) (mul_le_mul_right le_sup_right))
theorem sup_mul : (M ⊔ N) * P = M * P ⊔ N * P :=
le_antisymm (mul_le.2 $ λ mn hmn p hp, let ⟨m, hm, n, hn, hmn⟩ := mem_sup.1 hmn in
mem_sup.2 ⟨_, mul_mem_mul hm hp, _, mul_mem_mul hn hp, hmn ▸ (add_mul m n p).symm⟩)
(sup_le (mul_le_mul_left le_sup_left) (mul_le_mul_left le_sup_right))
lemma mul_subset_mul : (↑M : set A) * (↑N : set A) ⊆ (↑(M * N) : set A) :=
by { rintros _ ⟨i, j, hi, hj, rfl⟩, exact mul_mem_mul hi hj }
lemma map_mul {A'} [semiring A'] [algebra R A'] (f : A →ₐ[R] A') :
map f.to_linear_map (M * N) = map f.to_linear_map M * map f.to_linear_map N :=
calc map f.to_linear_map (M * N)
= ⨆ (i : M), (N.map (lmul R A i)).map f.to_linear_map : map_supr _ _
... = map f.to_linear_map M * map f.to_linear_map N :
begin
apply congr_arg Sup,
ext S,
split; rintros ⟨y, hy⟩,
{ use [f y, mem_map.mpr ⟨y.1, y.2, rfl⟩],
refine trans _ hy,
ext,
simp },
{ obtain ⟨y', hy', fy_eq⟩ := mem_map.mp y.2,
use [y', hy'],
refine trans _ hy,
rw f.to_linear_map_apply at fy_eq,
ext,
simp [fy_eq] }
end
variables {M N P}
instance : semiring (submodule R A) :=
{ one_mul := submodule.one_mul,
mul_one := submodule.mul_one,
mul_assoc := submodule.mul_assoc,
zero_mul := bot_mul,
mul_zero := mul_bot,
left_distrib := mul_sup,
right_distrib := sup_mul,
..submodule.add_comm_monoid_submodule,
..submodule.has_one,
..submodule.has_mul }
variables (M)
lemma pow_subset_pow {n : ℕ} : (↑M : set A)^n ⊆ ↑(M^n : submodule R A) :=
begin
induction n with n ih,
{ erw [pow_zero, pow_zero, set.singleton_subset_iff], rw [mem_coe, ← one_le], exact le_refl _ },
{ rw [pow_succ, pow_succ],
refine set.subset.trans (set.mul_subset_mul (subset.refl _) ih) _,
apply mul_subset_mul }
end
/-- `span` is a semiring homomorphism (recall multiplication is pointwise multiplication of subsets on either side). -/
def span.ring_hom : set_semiring A →+* submodule R A :=
{ to_fun := submodule.span R,
map_zero' := span_empty,
map_one' := le_antisymm (span_le.2 $ singleton_subset_iff.2 ⟨1, ⟨⟩, (algebra_map R A).map_one⟩)
(map_le_iff_le_comap.2 $ λ r _, mem_span_singleton.2 ⟨r, (algebra_map_eq_smul_one r).symm⟩),
map_add' := span_union,
map_mul' := λ s t, by erw [span_mul_span, ← image_mul_prod] }
end ring
section comm_ring
variables {A : Type v} [comm_semiring A] [algebra R A]
variables {M N : submodule R A} {m n : A}
theorem mul_mem_mul_rev (hm : m ∈ M) (hn : n ∈ N) : n * m ∈ M * N :=
mul_comm m n ▸ mul_mem_mul hm hn
variables (M N)
protected theorem mul_comm : M * N = N * M :=
le_antisymm (mul_le.2 $ λ r hrm s hsn, mul_mem_mul_rev hsn hrm)
(mul_le.2 $ λ r hrn s hsm, mul_mem_mul_rev hsm hrn)
instance : comm_semiring (submodule R A) :=
{ mul_comm := submodule.mul_comm,
.. submodule.semiring }
variables (R A)
instance semimodule_set : semimodule (set_semiring A) (submodule R A) :=
{ smul := λ s P, span R s * P,
smul_add := λ _ _ _, mul_add _ _ _,
add_smul := λ s t P, show span R (s ⊔ t) * P = _, by { erw [span_union, right_distrib] },
mul_smul := λ s t P, show _ = _ * (_ * _),
by { rw [← mul_assoc, span_mul_span, ← image_mul_prod] },
one_smul := λ P, show span R {(1 : A)} * P = _,
by { conv_lhs {erw ← span_eq P}, erw [span_mul_span, one_mul, span_eq] },
zero_smul := λ P, show span R ∅ * P = ⊥, by erw [span_empty, bot_mul],
smul_zero := λ _, mul_bot _ }
variables {R A}
lemma smul_def {s : set_semiring A} {P : submodule R A} : s • P = span R s * P := rfl
lemma smul_le_smul {s t : set_semiring A} {M N : submodule R A} (h₁ : s.down ≤ t.down)
(h₂ : M ≤ N) : s • M ≤ t • N :=
mul_le_mul (span_mono h₁) h₂
lemma smul_singleton (a : A) (M : submodule R A) :
({a} : set A).up • M = M.map (lmul_left _ _ a) :=
begin
conv_lhs {rw ← span_eq M},
change span _ _ * span _ _ = _,
rw [span_mul_span],
apply le_antisymm,
{ rw span_le,
rintros _ ⟨b, m, hb, hm, rfl⟩,
rw [mem_coe, mem_map, set.mem_singleton_iff.mp hb],
exact ⟨m, hm, rfl⟩ },
{ rintros _ ⟨m, hm, rfl⟩, exact subset_span ⟨a, m, set.mem_singleton a, hm, rfl⟩ }
end
section quotient
/-- The elements of `I / J` are the `x` such that `x • J ⊆ I`.
In fact, we define `x ∈ I / J` to be `∀ y ∈ J, x * y ∈ I` (see `mem_div_iff_forall_mul_mem`),
which is equivalent to `x • J ⊆ I` (see `mem_div_iff_smul_subset`), but nicer to use in proofs.
This is the general form of the ideal quotient, traditionally written $I : J$.
-/
instance : has_div (submodule R A) :=
⟨ λ I J, {
carrier := { x | ∀ y ∈ J, x * y ∈ I },
zero_mem' := λ y hy, by { rw zero_mul, apply submodule.zero_mem },
add_mem' := λ a b ha hb y hy, by { rw add_mul, exact submodule.add_mem _ (ha _ hy) (hb _ hy) },
smul_mem' := λ r x hx y hy, by { rw algebra.smul_mul_assoc,
exact submodule.smul_mem _ _ (hx _ hy) } } ⟩
lemma mem_div_iff_forall_mul_mem {x : A} {I J : submodule R A} :
x ∈ I / J ↔ ∀ y ∈ J, x * y ∈ I :=
iff.refl _
lemma mem_div_iff_smul_subset {x : A} {I J : submodule R A} : x ∈ I / J ↔ x • (J : set A) ⊆ I :=
⟨ λ h y ⟨y', hy', xy'_eq_y⟩, by { rw ← xy'_eq_y, apply h, assumption },
λ h y hy, h (set.smul_mem_smul_set hy) ⟩
lemma le_div_iff {I J K : submodule R A} : I ≤ J / K ↔ ∀ (x ∈ I) (z ∈ K), x * z ∈ J := iff.refl _
end quotient
end comm_ring
end submodule
|
3ab321650e4446a0741b8263f2c8572b7c9cec14 | 8e381650eb2c1c5361be64ff97e47d956bf2ab9f | /src/spectrum_of_a_ring/structure_presheaf.lean | 23a2436ef89748472d4ea9d2ac5409b29c7f472b | [] | no_license | alreadydone/lean-scheme | 04c51ab08eca7ccf6c21344d45d202780fa667af | 52d7624f57415eea27ed4dfa916cd94189221a1c | refs/heads/master | 1,599,418,221,423 | 1,562,248,559,000 | 1,562,248,559,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 2,505 | lean | import ring_theory.localization
import to_mathlib.localization.localization_alt
import to_mathlib.localization.localization_of
import spectrum_of_a_ring.properties
import sheaves.presheaf_of_rings_on_basis
import sheaves.sheaf_of_rings_on_standard_basis
import sheaves.locally_ringed_space
import spectrum_of_a_ring.spec
import spectrum_of_a_ring.zariski_topology
import spectrum_of_a_ring.standard_basis
universe u
local attribute [instance] classical.prop_decidable
noncomputable theory
variables {R : Type u} [comm_ring R]
open topological_space
open classical
open localization
open localization_alt
-- Define S(U) so that R[1/f] ≃ R[1/S(D(f))].
def S (U : opens (Spec R)) : set R := { r : R | U ⊆ Spec.DO R (r) }
instance S.is_submonoid (U : opens (Spec R)) : is_submonoid (S U) :=
{ one_mem := λ ⟨P, PI⟩ HP, ((ideal.ne_top_iff_one P).1 PI.1),
mul_mem := λ f g Hf Hg,
begin
show U.1 ⊆ Spec.D'(f*g),
exact (Spec.D'.product_eq_inter f g).symm ▸ set.subset_inter Hf Hg,
end, }
lemma S.rev_mono {U V : opens (Spec R)} (HVU : V ⊆ U) : S U ⊆ S V :=
λ x Hx, set.subset.trans HVU Hx
lemma S.f_mem (f : R) : f ∈ S (Spec.DO R (f)) := set.subset.refl _
lemma S.inter_subset_Sinter (U V : opens (Spec R)) : (S U) ∩ (S V) ⊆ S (U ∩ V) :=
begin
rintros x ⟨HxU, HxV⟩,
change U ⊆ Spec.DO R (x) at HxU,
change V ⊆ Spec.DO R (x) at HxV,
have H := set.inter_subset_inter HxU HxV,
rw set.inter_self at H,
exact H,
end
-- Structure presheaf on Spec(R) defined on the basis by the rule ℱ(U) = R[1/S(U)].
variable (R)
def structure_presheaf_on_basis : presheaf_of_rings_on_basis (Spec R) (D_fs_basis R) :=
{ F := λ U BU, localization R (S U),
res := λ U V BU BV HVU,
begin
have H := S.rev_mono HVU,
apply quotient.lift (λ (x : R × (S U)), ⟦(x.1, (⟨x.2.1, H x.2.2⟩ : (S V)))⟧),
{ rintros ⟨a1, b1, Hb1⟩ ⟨a2, b2, Hb2⟩ ⟨t, Ht, Habt⟩,
simp,
use [t, H Ht, Habt], },
end,
Hid := λ U BU, funext $ λ x, quotient.induction_on x $ λ a, by simp,
Hcomp := λ U V W BU BV BW HWV HVU, funext $ λ x, quotient.induction_on x $ λ a, by simp,
Fring := λ U BU, by apply_instance,
res_is_ring_hom := λ U V BU BV HVU,
{ map_one := rfl,
map_add := λ x y, quotient.induction_on₂ x y $ λ ⟨r₁, s₁, hs₁⟩ ⟨r₂, s₂, hs₂⟩, rfl,
map_mul := λ x y, quotient.induction_on₂ x y $ λ ⟨r₁, s₁, hs₁⟩ ⟨r₂, s₂, hs₂⟩, rfl, }, }
|
9faa5b8f951e6d468cd1a3fc2a292dd2b7d0def8 | 626e312b5c1cb2d88fca108f5933076012633192 | /src/measure_theory/function/lp_space.lean | 023ca7c141719cbd793ca912802be0e1ff762d6e | [
"Apache-2.0"
] | permissive | Bioye97/mathlib | 9db2f9ee54418d29dd06996279ba9dc874fd6beb | 782a20a27ee83b523f801ff34efb1a9557085019 | refs/heads/master | 1,690,305,956,488 | 1,631,067,774,000 | 1,631,067,774,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 99,028 | lean | /-
Copyright (c) 2020 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne, Sébastien Gouëzel
-/
import analysis.normed_space.indicator_function
import analysis.normed_space.normed_group_hom
import measure_theory.function.ess_sup
import measure_theory.function.ae_eq_fun
import measure_theory.integral.mean_inequalities
import topology.continuous_function.compact
/-!
# ℒp space and Lp space
This file describes properties of almost everywhere measurable functions with finite seminorm,
denoted by `snorm f p μ` and defined for `p:ℝ≥0∞` as `0` if `p=0`, `(∫ ∥f a∥^p ∂μ) ^ (1/p)` for
`0 < p < ∞` and `ess_sup ∥f∥ μ` for `p=∞`.
The Prop-valued `mem_ℒp f p μ` states that a function `f : α → E` has finite seminorm.
The space `Lp E p μ` is the subtype of elements of `α →ₘ[μ] E` (see ae_eq_fun) such that
`snorm f p μ` is finite. For `1 ≤ p`, `snorm` defines a norm and `Lp` is a complete metric space.
## Main definitions
* `snorm' f p μ` : `(∫ ∥f a∥^p ∂μ) ^ (1/p)` for `f : α → F` and `p : ℝ`, where `α` is a measurable
space and `F` is a normed group.
* `snorm_ess_sup f μ` : seminorm in `ℒ∞`, equal to the essential supremum `ess_sup ∥f∥ μ`.
* `snorm f p μ` : for `p : ℝ≥0∞`, seminorm in `ℒp`, equal to `0` for `p=0`, to `snorm' f p μ`
for `0 < p < ∞` and to `snorm_ess_sup f μ` for `p = ∞`.
* `mem_ℒp f p μ` : property that the function `f` is almost everywhere measurable and has finite
p-seminorm for measure `μ` (`snorm f p μ < ∞`)
* `Lp E p μ` : elements of `α →ₘ[μ] E` (see ae_eq_fun) such that `snorm f p μ` is finite. Defined
as an `add_subgroup` of `α →ₘ[μ] E`.
Lipschitz functions vanishing at zero act by composition on `Lp`. We define this action, and prove
that it is continuous. In particular,
* `continuous_linear_map.comp_Lp` defines the action on `Lp` of a continuous linear map.
* `Lp.pos_part` is the positive part of an `Lp` function.
* `Lp.neg_part` is the negative part of an `Lp` function.
When `α` is a topological space equipped with a finite Borel measure, there is a bounded linear map
from the normed space of bounded continuous functions (`α →ᵇ E`) to `Lp E p μ`. We construct this
as `bounded_continuous_function.to_Lp`.
## Notations
* `α →₁[μ] E` : the type `Lp E 1 μ`.
* `α →₂[μ] E` : the type `Lp E 2 μ`.
## Implementation
Since `Lp` is defined as an `add_subgroup`, dot notation does not work. Use `Lp.measurable f` to
say that the coercion of `f` to a genuine function is measurable, instead of the non-working
`f.measurable`.
To prove that two `Lp` elements are equal, it suffices to show that their coercions to functions
coincide almost everywhere (this is registered as an `ext` rule). This can often be done using
`filter_upwards`. For instance, a proof from first principles that `f + (g + h) = (f + g) + h`
could read (in the `Lp` namespace)
```
example (f g h : Lp E p μ) : (f + g) + h = f + (g + h) :=
begin
ext1,
filter_upwards [coe_fn_add (f + g) h, coe_fn_add f g, coe_fn_add f (g + h), coe_fn_add g h],
assume a ha1 ha2 ha3 ha4,
simp only [ha1, ha2, ha3, ha4, add_assoc],
end
```
The lemma `coe_fn_add` states that the coercion of `f + g` coincides almost everywhere with the sum
of the coercions of `f` and `g`. All such lemmas use `coe_fn` in their name, to distinguish the
function coercion from the coercion to almost everywhere defined functions.
-/
noncomputable theory
open topological_space measure_theory filter
open_locale nnreal ennreal big_operators topological_space
lemma fact_one_le_one_ennreal : fact ((1 : ℝ≥0∞) ≤ 1) := ⟨le_refl _⟩
lemma fact_one_le_two_ennreal : fact ((1 : ℝ≥0∞) ≤ 2) :=
⟨ennreal.coe_le_coe.2 (show (1 : ℝ≥0) ≤ 2, by norm_num)⟩
lemma fact_one_le_top_ennreal : fact ((1 : ℝ≥0∞) ≤ ∞) := ⟨le_top⟩
local attribute [instance] fact_one_le_one_ennreal fact_one_le_two_ennreal fact_one_le_top_ennreal
variables {α E F G : Type*} {m m0 : measurable_space α} {p : ℝ≥0∞} {q : ℝ} {μ ν : measure α}
[measurable_space E] [normed_group E]
[normed_group F] [normed_group G]
namespace measure_theory
section ℒp
/-!
### ℒp seminorm
We define the ℒp seminorm, denoted by `snorm f p μ`. For real `p`, it is given by an integral
formula (for which we use the notation `snorm' f p μ`), and for `p = ∞` it is the essential
supremum (for which we use the notation `snorm_ess_sup f μ`).
We also define a predicate `mem_ℒp f p μ`, requesting that a function is almost everywhere
measurable and has finite `snorm f p μ`.
This paragraph is devoted to the basic properties of these definitions. It is constructed as
follows: for a given property, we prove it for `snorm'` and `snorm_ess_sup` when it makes sense,
deduce it for `snorm`, and translate it in terms of `mem_ℒp`.
-/
section ℒp_space_definition
/-- `(∫ ∥f a∥^q ∂μ) ^ (1/q)`, which is a seminorm on the space of measurable functions for which
this quantity is finite -/
def snorm' {m : measurable_space α} (f : α → F) (q : ℝ) (μ : measure α) : ℝ≥0∞ :=
(∫⁻ a, (nnnorm (f a))^q ∂μ) ^ (1/q)
/-- seminorm for `ℒ∞`, equal to the essential supremum of `∥f∥`. -/
def snorm_ess_sup {m : measurable_space α} (f : α → F) (μ : measure α) :=
ess_sup (λ x, (nnnorm (f x) : ℝ≥0∞)) μ
/-- `ℒp` seminorm, equal to `0` for `p=0`, to `(∫ ∥f a∥^p ∂μ) ^ (1/p)` for `0 < p < ∞` and to
`ess_sup ∥f∥ μ` for `p = ∞`. -/
def snorm {m : measurable_space α} (f : α → F) (p : ℝ≥0∞) (μ : measure α) : ℝ≥0∞ :=
if p = 0 then 0 else (if p = ∞ then snorm_ess_sup f μ else snorm' f (ennreal.to_real p) μ)
lemma snorm_eq_snorm' (hp_ne_zero : p ≠ 0) (hp_ne_top : p ≠ ∞) {f : α → F} :
snorm f p μ = snorm' f (ennreal.to_real p) μ :=
by simp [snorm, hp_ne_zero, hp_ne_top]
lemma snorm_eq_lintegral_rpow_nnnorm (hp_ne_zero : p ≠ 0) (hp_ne_top : p ≠ ∞) {f : α → F} :
snorm f p μ = (∫⁻ x, (nnnorm (f x)) ^ p.to_real ∂μ) ^ (1 / p.to_real) :=
by rw [snorm_eq_snorm' hp_ne_zero hp_ne_top, snorm']
lemma snorm_one_eq_lintegral_nnnorm {f : α → F} : snorm f 1 μ = ∫⁻ x, nnnorm (f x) ∂μ :=
by simp_rw [snorm_eq_lintegral_rpow_nnnorm one_ne_zero ennreal.coe_ne_top, ennreal.one_to_real,
one_div_one, ennreal.rpow_one]
@[simp] lemma snorm_exponent_top {f : α → F} : snorm f ∞ μ = snorm_ess_sup f μ := by simp [snorm]
/-- The property that `f:α→E` is ae_measurable and `(∫ ∥f a∥^p ∂μ)^(1/p)` is finite if `p < ∞`, or
`ess_sup f < ∞` if `p = ∞`. -/
def mem_ℒp {α} {m : measurable_space α} (f : α → E) (p : ℝ≥0∞) (μ : measure α) : Prop :=
ae_measurable f μ ∧ snorm f p μ < ∞
lemma mem_ℒp.ae_measurable {f : α → E} {p : ℝ≥0∞} (h : mem_ℒp f p μ) : ae_measurable f μ := h.1
lemma lintegral_rpow_nnnorm_eq_rpow_snorm' {f : α → F} (hq0_lt : 0 < q) :
∫⁻ a, (nnnorm (f a)) ^ q ∂μ = (snorm' f q μ) ^ q :=
begin
rw [snorm', ←ennreal.rpow_mul, one_div, inv_mul_cancel, ennreal.rpow_one],
exact (ne_of_lt hq0_lt).symm,
end
end ℒp_space_definition
section top
lemma mem_ℒp.snorm_lt_top {f : α → E} (hfp : mem_ℒp f p μ) : snorm f p μ < ∞ := hfp.2
lemma mem_ℒp.snorm_ne_top {f : α → E} (hfp : mem_ℒp f p μ) : snorm f p μ ≠ ∞ := ne_of_lt (hfp.2)
lemma lintegral_rpow_nnnorm_lt_top_of_snorm'_lt_top {f : α → F} (hq0_lt : 0 < q)
(hfq : snorm' f q μ < ∞) :
∫⁻ a, (nnnorm (f a)) ^ q ∂μ < ∞ :=
begin
rw lintegral_rpow_nnnorm_eq_rpow_snorm' hq0_lt,
exact ennreal.rpow_lt_top_of_nonneg (le_of_lt hq0_lt) (ne_of_lt hfq),
end
lemma lintegral_rpow_nnnorm_lt_top_of_snorm_lt_top {f : α → F} (hp_ne_zero : p ≠ 0)
(hp_ne_top : p ≠ ∞) (hfp : snorm f p μ < ∞) :
∫⁻ a, (nnnorm (f a)) ^ p.to_real ∂μ < ∞ :=
begin
apply lintegral_rpow_nnnorm_lt_top_of_snorm'_lt_top,
{ exact ennreal.to_real_pos_iff.mpr ⟨bot_lt_iff_ne_bot.mpr hp_ne_zero, hp_ne_top⟩ },
{ simpa [snorm_eq_snorm' hp_ne_zero hp_ne_top] using hfp }
end
lemma snorm_lt_top_iff_lintegral_rpow_nnnorm_lt_top {f : α → F} (hp_ne_zero : p ≠ 0)
(hp_ne_top : p ≠ ∞) :
snorm f p μ < ∞ ↔ ∫⁻ a, (nnnorm (f a)) ^ p.to_real ∂μ < ∞ :=
⟨lintegral_rpow_nnnorm_lt_top_of_snorm_lt_top hp_ne_zero hp_ne_top,
begin
intros h,
have hp' := ennreal.to_real_pos_iff.mpr ⟨bot_lt_iff_ne_bot.mpr hp_ne_zero, hp_ne_top⟩,
have : 0 < 1 / p.to_real := div_pos zero_lt_one hp',
simpa [snorm_eq_lintegral_rpow_nnnorm hp_ne_zero hp_ne_top] using
ennreal.rpow_lt_top_of_nonneg (le_of_lt this) (ne_of_lt h)
end⟩
end top
section zero
@[simp] lemma snorm'_exponent_zero {f : α → F} : snorm' f 0 μ = 1 :=
by rw [snorm', div_zero, ennreal.rpow_zero]
@[simp] lemma snorm_exponent_zero {f : α → F} : snorm f 0 μ = 0 :=
by simp [snorm]
lemma mem_ℒp_zero_iff_ae_measurable {f : α → E} : mem_ℒp f 0 μ ↔ ae_measurable f μ :=
by simp [mem_ℒp, snorm_exponent_zero]
@[simp] lemma snorm'_zero (hp0_lt : 0 < q) : snorm' (0 : α → F) q μ = 0 :=
by simp [snorm', hp0_lt]
@[simp] lemma snorm'_zero' (hq0_ne : q ≠ 0) (hμ : μ ≠ 0) : snorm' (0 : α → F) q μ = 0 :=
begin
cases le_or_lt 0 q with hq0 hq_neg,
{ exact snorm'_zero (lt_of_le_of_ne hq0 hq0_ne.symm), },
{ simp [snorm', ennreal.rpow_eq_zero_iff, hμ, hq_neg], },
end
@[simp] lemma snorm_ess_sup_zero : snorm_ess_sup (0 : α → F) μ = 0 :=
begin
simp_rw [snorm_ess_sup, pi.zero_apply, nnnorm_zero, ennreal.coe_zero, ←ennreal.bot_eq_zero],
exact ess_sup_const_bot,
end
@[simp] lemma snorm_zero : snorm (0 : α → F) p μ = 0 :=
begin
by_cases h0 : p = 0,
{ simp [h0], },
by_cases h_top : p = ∞,
{ simp only [h_top, snorm_exponent_top, snorm_ess_sup_zero], },
rw ←ne.def at h0,
simp [snorm_eq_snorm' h0 h_top,
ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) h0.symm, h_top⟩],
end
lemma zero_mem_ℒp : mem_ℒp (0 : α → E) p μ :=
⟨measurable_zero.ae_measurable, by { rw snorm_zero, exact ennreal.coe_lt_top, } ⟩
variables [measurable_space α]
lemma snorm'_measure_zero_of_pos {f : α → F} (hq_pos : 0 < q) :
snorm' f q (0 : measure α) = 0 :=
by simp [snorm', hq_pos]
lemma snorm'_measure_zero_of_exponent_zero {f : α → F} : snorm' f 0 (0 : measure α) = 1 :=
by simp [snorm']
lemma snorm'_measure_zero_of_neg {f : α → F} (hq_neg : q < 0) : snorm' f q (0 : measure α) = ∞ :=
by simp [snorm', hq_neg]
@[simp] lemma snorm_ess_sup_measure_zero {f : α → F} : snorm_ess_sup f (0 : measure α) = 0 :=
by simp [snorm_ess_sup]
@[simp] lemma snorm_measure_zero {f : α → F} : snorm f p (0 : measure α) = 0 :=
begin
by_cases h0 : p = 0,
{ simp [h0], },
by_cases h_top : p = ∞,
{ simp [h_top], },
rw ←ne.def at h0,
simp [snorm_eq_snorm' h0 h_top, snorm',
ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) h0.symm, h_top⟩],
end
end zero
section const
lemma snorm'_const (c : F) (hq_pos : 0 < q) :
snorm' (λ x : α , c) q μ = (nnnorm c : ℝ≥0∞) * (μ set.univ) ^ (1/q) :=
begin
rw [snorm', lintegral_const, ennreal.mul_rpow_of_nonneg _ _ (by simp [hq_pos.le] : 0 ≤ 1 / q)],
congr,
rw ←ennreal.rpow_mul,
suffices hq_cancel : q * (1/q) = 1, by rw [hq_cancel, ennreal.rpow_one],
rw [one_div, mul_inv_cancel (ne_of_lt hq_pos).symm],
end
lemma snorm'_const' [is_finite_measure μ] (c : F) (hc_ne_zero : c ≠ 0) (hq_ne_zero : q ≠ 0) :
snorm' (λ x : α , c) q μ = (nnnorm c : ℝ≥0∞) * (μ set.univ) ^ (1/q) :=
begin
rw [snorm', lintegral_const, ennreal.mul_rpow_of_ne_top _ (measure_ne_top μ set.univ)],
{ congr,
rw ←ennreal.rpow_mul,
suffices hp_cancel : q * (1/q) = 1, by rw [hp_cancel, ennreal.rpow_one],
rw [one_div, mul_inv_cancel hq_ne_zero], },
{ rw [ne.def, ennreal.rpow_eq_top_iff, auto.not_or_eq, auto.not_and_eq, auto.not_and_eq],
split,
{ left,
rwa [ennreal.coe_eq_zero, nnnorm_eq_zero], },
{ exact or.inl ennreal.coe_ne_top, }, },
end
lemma snorm_ess_sup_const (c : F) (hμ : μ ≠ 0) :
snorm_ess_sup (λ x : α, c) μ = (nnnorm c : ℝ≥0∞) :=
by rw [snorm_ess_sup, ess_sup_const _ hμ]
lemma snorm'_const_of_is_probability_measure (c : F) (hq_pos : 0 < q) [is_probability_measure μ] :
snorm' (λ x : α , c) q μ = (nnnorm c : ℝ≥0∞) :=
by simp [snorm'_const c hq_pos, measure_univ]
lemma snorm_const (c : F) (h0 : p ≠ 0) (hμ : μ ≠ 0) :
snorm (λ x : α , c) p μ = (nnnorm c : ℝ≥0∞) * (μ set.univ) ^ (1/(ennreal.to_real p)) :=
begin
by_cases h_top : p = ∞,
{ simp [h_top, snorm_ess_sup_const c hμ], },
simp [snorm_eq_snorm' h0 h_top, snorm'_const,
ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) h0.symm, h_top⟩],
end
lemma snorm_const' (c : F) (h0 : p ≠ 0) (h_top: p ≠ ∞) :
snorm (λ x : α , c) p μ = (nnnorm c : ℝ≥0∞) * (μ set.univ) ^ (1/(ennreal.to_real p)) :=
begin
simp [snorm_eq_snorm' h0 h_top, snorm'_const,
ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) h0.symm, h_top⟩],
end
lemma mem_ℒp_const (c : E) [is_finite_measure μ] : mem_ℒp (λ a:α, c) p μ :=
begin
refine ⟨measurable_const.ae_measurable, _⟩,
by_cases h0 : p = 0,
{ simp [h0], },
by_cases hμ : μ = 0,
{ simp [hμ], },
rw snorm_const c h0 hμ,
refine ennreal.mul_lt_top ennreal.coe_lt_top _,
refine ennreal.rpow_lt_top_of_nonneg _ (measure_ne_top μ set.univ),
simp,
end
end const
lemma snorm'_mono_ae {f : α → F} {g : α → G} (hq : 0 ≤ q) (h : ∀ᵐ x ∂μ, ∥f x∥ ≤ ∥g x∥) :
snorm' f q μ ≤ snorm' g q μ :=
begin
rw [snorm'],
refine ennreal.rpow_le_rpow _ (one_div_nonneg.2 hq),
refine lintegral_mono_ae (h.mono $ λ x hx, _),
exact ennreal.rpow_le_rpow (ennreal.coe_le_coe.2 hx) hq
end
lemma snorm'_congr_norm_ae {f g : α → F} (hfg : ∀ᵐ x ∂μ, ∥f x∥ = ∥g x∥) :
snorm' f q μ = snorm' g q μ :=
begin
have : (λ x, (nnnorm (f x) ^ q : ℝ≥0∞)) =ᵐ[μ] (λ x, nnnorm (g x) ^ q),
from hfg.mono (λ x hx, by { simp only [← coe_nnnorm, nnreal.coe_eq] at hx, simp [hx] }),
simp only [snorm', lintegral_congr_ae this]
end
lemma snorm'_congr_ae {f g : α → F} (hfg : f =ᵐ[μ] g) : snorm' f q μ = snorm' g q μ :=
snorm'_congr_norm_ae (hfg.fun_comp _)
lemma snorm_ess_sup_congr_ae {f g : α → F} (hfg : f =ᵐ[μ] g) :
snorm_ess_sup f μ = snorm_ess_sup g μ :=
ess_sup_congr_ae (hfg.fun_comp (coe ∘ nnnorm))
lemma snorm_mono_ae {f : α → F} {g : α → G} (h : ∀ᵐ x ∂μ, ∥f x∥ ≤ ∥g x∥) :
snorm f p μ ≤ snorm g p μ :=
begin
simp only [snorm],
split_ifs,
{ exact le_rfl },
{ refine ess_sup_mono_ae (h.mono $ λ x hx, _),
exact_mod_cast hx },
{ exact snorm'_mono_ae ennreal.to_real_nonneg h }
end
lemma snorm_ess_sup_le_of_ae_bound {f : α → F} {C : ℝ} (hfC : ∀ᵐ x ∂μ, ∥f x∥ ≤ C) :
snorm_ess_sup f μ ≤ ennreal.of_real C:=
begin
simp_rw [snorm_ess_sup, ← of_real_norm_eq_coe_nnnorm],
refine ess_sup_le_of_ae_le (ennreal.of_real C) (hfC.mono (λ x hx, _)),
exact ennreal.of_real_le_of_real hx,
end
lemma snorm_ess_sup_lt_top_of_ae_bound {f : α → F} {C : ℝ} (hfC : ∀ᵐ x ∂μ, ∥f x∥ ≤ C) :
snorm_ess_sup f μ < ∞ :=
(snorm_ess_sup_le_of_ae_bound hfC).trans_lt ennreal.of_real_lt_top
lemma snorm_le_of_ae_bound {f : α → F} {C : ℝ} (hfC : ∀ᵐ x ∂μ, ∥f x∥ ≤ C) :
snorm f p μ ≤ ((μ set.univ) ^ p.to_real⁻¹) * (ennreal.of_real C) :=
begin
by_cases hμ : μ = 0,
{ simp [hμ] },
haveI : μ.ae.ne_bot := ae_ne_bot.mpr hμ,
by_cases hp : p = 0,
{ simp [hp] },
have hC : 0 ≤ C, from le_trans (norm_nonneg _) hfC.exists.some_spec,
have hC' : ∥C∥ = C := by rw [real.norm_eq_abs, abs_eq_self.mpr hC],
have : ∀ᵐ x ∂μ, ∥f x∥ ≤ ∥(λ _, C) x∥, from hfC.mono (λ x hx, hx.trans (le_of_eq hC'.symm)),
convert snorm_mono_ae this,
rw [snorm_const _ hp hμ, mul_comm, ← of_real_norm_eq_coe_nnnorm, hC', one_div]
end
lemma snorm_congr_norm_ae {f : α → F} {g : α → G} (hfg : ∀ᵐ x ∂μ, ∥f x∥ = ∥g x∥) :
snorm f p μ = snorm g p μ :=
le_antisymm (snorm_mono_ae $ eventually_eq.le hfg)
(snorm_mono_ae $ (eventually_eq.symm hfg).le)
@[simp] lemma snorm'_norm {f : α → F} : snorm' (λ a, ∥f a∥) q μ = snorm' f q μ :=
by simp [snorm']
@[simp] lemma snorm_norm (f : α → F) : snorm (λ x, ∥f x∥) p μ = snorm f p μ :=
snorm_congr_norm_ae $ eventually_of_forall $ λ x, norm_norm _
lemma snorm'_norm_rpow (f : α → F) (p q : ℝ) (hq_pos : 0 < q) :
snorm' (λ x, ∥f x∥ ^ q) p μ = (snorm' f (p * q) μ) ^ q :=
begin
simp_rw snorm',
rw [← ennreal.rpow_mul, ←one_div_mul_one_div],
simp_rw one_div,
rw [mul_assoc, inv_mul_cancel hq_pos.ne.symm, mul_one],
congr,
ext1 x,
simp_rw ← of_real_norm_eq_coe_nnnorm,
rw [real.norm_eq_abs, abs_eq_self.mpr (real.rpow_nonneg_of_nonneg (norm_nonneg _) _),
mul_comm, ← ennreal.of_real_rpow_of_nonneg (norm_nonneg _) hq_pos.le, ennreal.rpow_mul],
end
lemma snorm_norm_rpow (f : α → F) (hq_pos : 0 < q) :
snorm (λ x, ∥f x∥ ^ q) p μ = (snorm f (p * ennreal.of_real q) μ) ^ q :=
begin
by_cases h0 : p = 0,
{ simp [h0, ennreal.zero_rpow_of_pos hq_pos], },
by_cases hp_top : p = ∞,
{ simp only [hp_top, snorm_exponent_top, ennreal.top_mul, hq_pos.not_le, ennreal.of_real_eq_zero,
if_false, snorm_exponent_top, snorm_ess_sup],
have h_rpow : ess_sup (λ (x : α), (nnnorm (∥f x∥ ^ q) : ℝ≥0∞)) μ
= ess_sup (λ (x : α), (↑(nnnorm (f x))) ^ q) μ,
{ congr,
ext1 x,
nth_rewrite 1 ← nnnorm_norm,
rw [ennreal.coe_rpow_of_nonneg _ hq_pos.le, ennreal.coe_eq_coe],
ext,
push_cast,
rw real.norm_rpow_of_nonneg (norm_nonneg _), },
rw h_rpow,
have h_rpow_mono := ennreal.rpow_left_strict_mono_of_pos hq_pos,
have h_rpow_surj := (ennreal.rpow_left_bijective hq_pos.ne.symm).2,
let iso := h_rpow_mono.order_iso_of_surjective _ h_rpow_surj,
exact (iso.ess_sup_apply (λ x, ((nnnorm (f x)) : ℝ≥0∞)) μ).symm, },
rw [snorm_eq_snorm' h0 hp_top, snorm_eq_snorm' _ _],
swap, { refine mul_ne_zero h0 _, rwa [ne.def, ennreal.of_real_eq_zero, not_le], },
swap, { exact ennreal.mul_ne_top hp_top ennreal.of_real_ne_top, },
rw [ennreal.to_real_mul, ennreal.to_real_of_real hq_pos.le],
exact snorm'_norm_rpow f p.to_real q hq_pos,
end
lemma snorm_congr_ae {f g : α → F} (hfg : f =ᵐ[μ] g) : snorm f p μ = snorm g p μ :=
snorm_congr_norm_ae $ hfg.mono (λ x hx, hx ▸ rfl)
lemma mem_ℒp_congr_ae {f g : α → E} (hfg : f =ᵐ[μ] g) : mem_ℒp f p μ ↔ mem_ℒp g p μ :=
by simp only [mem_ℒp, snorm_congr_ae hfg, ae_measurable_congr hfg]
lemma mem_ℒp.ae_eq {f g : α → E} (hfg : f =ᵐ[μ] g) (hf_Lp : mem_ℒp f p μ) : mem_ℒp g p μ :=
(mem_ℒp_congr_ae hfg).1 hf_Lp
lemma mem_ℒp.of_le [measurable_space F] {f : α → E} {g : α → F}
(hg : mem_ℒp g p μ) (hf : ae_measurable f μ) (hfg : ∀ᵐ x ∂μ, ∥f x∥ ≤ ∥g x∥) : mem_ℒp f p μ :=
⟨hf, (snorm_mono_ae hfg).trans_lt hg.snorm_lt_top⟩
lemma mem_ℒp_top_of_bound {f : α → E} (hf : ae_measurable f μ) (C : ℝ)
(hfC : ∀ᵐ x ∂μ, ∥f x∥ ≤ C) :
mem_ℒp f ∞ μ :=
⟨hf, by { rw snorm_exponent_top, exact snorm_ess_sup_lt_top_of_ae_bound hfC, }⟩
lemma mem_ℒp.of_bound [is_finite_measure μ] {f : α → E} (hf : ae_measurable f μ)
(C : ℝ) (hfC : ∀ᵐ x ∂μ, ∥f x∥ ≤ C) :
mem_ℒp f p μ :=
(mem_ℒp_const C).of_le hf (hfC.mono (λ x hx, le_trans hx (le_abs_self _)))
@[mono] lemma snorm'_mono_measure (f : α → F) (hμν : ν ≤ μ) (hq : 0 ≤ q) :
snorm' f q ν ≤ snorm' f q μ :=
begin
simp_rw snorm',
suffices h_integral_mono : (∫⁻ a, (nnnorm (f a) : ℝ≥0∞) ^ q ∂ν) ≤ ∫⁻ a, (nnnorm (f a)) ^ q ∂μ,
from ennreal.rpow_le_rpow h_integral_mono (by simp [hq]),
exact lintegral_mono' hμν le_rfl,
end
@[mono] lemma snorm_ess_sup_mono_measure (f : α → F) (hμν : ν ≪ μ) :
snorm_ess_sup f ν ≤ snorm_ess_sup f μ :=
by { simp_rw snorm_ess_sup, exact ess_sup_mono_measure hμν, }
@[mono] lemma snorm_mono_measure (f : α → F) (hμν : ν ≤ μ) :
snorm f p ν ≤ snorm f p μ :=
begin
by_cases hp0 : p = 0,
{ simp [hp0], },
by_cases hp_top : p = ∞,
{ simp [hp_top, snorm_ess_sup_mono_measure f (measure.absolutely_continuous_of_le hμν)], },
simp_rw snorm_eq_snorm' hp0 hp_top,
exact snorm'_mono_measure f hμν ennreal.to_real_nonneg,
end
lemma mem_ℒp.mono_measure {f : α → E} (hμν : ν ≤ μ) (hf : mem_ℒp f p μ) :
mem_ℒp f p ν :=
⟨hf.1.mono_measure hμν, (snorm_mono_measure f hμν).trans_lt hf.2⟩
lemma mem_ℒp.restrict (s : set α) {f : α → E} (hf : mem_ℒp f p μ) :
mem_ℒp f p (μ.restrict s) :=
hf.mono_measure measure.restrict_le_self
section opens_measurable_space
variable [opens_measurable_space E]
lemma mem_ℒp.norm {f : α → E} (h : mem_ℒp f p μ) : mem_ℒp (λ x, ∥f x∥) p μ :=
h.of_le h.ae_measurable.norm (eventually_of_forall (λ x, by simp))
lemma snorm'_eq_zero_of_ae_zero {f : α → F} (hq0_lt : 0 < q) (hf_zero : f =ᵐ[μ] 0) :
snorm' f q μ = 0 :=
by rw [snorm'_congr_ae hf_zero, snorm'_zero hq0_lt]
lemma snorm'_eq_zero_of_ae_zero' (hq0_ne : q ≠ 0) (hμ : μ ≠ 0) {f : α → F} (hf_zero : f =ᵐ[μ] 0) :
snorm' f q μ = 0 :=
by rw [snorm'_congr_ae hf_zero, snorm'_zero' hq0_ne hμ]
lemma ae_eq_zero_of_snorm'_eq_zero {f : α → E} (hq0 : 0 ≤ q) (hf : ae_measurable f μ)
(h : snorm' f q μ = 0) : f =ᵐ[μ] 0 :=
begin
rw [snorm', ennreal.rpow_eq_zero_iff] at h,
cases h,
{ rw lintegral_eq_zero_iff' (hf.ennnorm.pow_const q) at h,
refine h.left.mono (λ x hx, _),
rw [pi.zero_apply, ennreal.rpow_eq_zero_iff] at hx,
cases hx,
{ cases hx with hx _,
rwa [←ennreal.coe_zero, ennreal.coe_eq_coe, nnnorm_eq_zero] at hx, },
{ exact absurd hx.left ennreal.coe_ne_top, }, },
{ exfalso,
rw [one_div, inv_lt_zero] at h,
exact hq0.not_lt h.right },
end
lemma snorm'_eq_zero_iff (hq0_lt : 0 < q) {f : α → E} (hf : ae_measurable f μ) :
snorm' f q μ = 0 ↔ f =ᵐ[μ] 0 :=
⟨ae_eq_zero_of_snorm'_eq_zero (le_of_lt hq0_lt) hf, snorm'_eq_zero_of_ae_zero hq0_lt⟩
lemma coe_nnnorm_ae_le_snorm_ess_sup {m : measurable_space α} (f : α → F) (μ : measure α) :
∀ᵐ x ∂μ, (nnnorm (f x) : ℝ≥0∞) ≤ snorm_ess_sup f μ :=
ennreal.ae_le_ess_sup (λ x, (nnnorm (f x) : ℝ≥0∞))
@[simp] lemma snorm_ess_sup_eq_zero_iff {f : α → F} : snorm_ess_sup f μ = 0 ↔ f =ᵐ[μ] 0 :=
by simp [eventually_eq, snorm_ess_sup]
lemma snorm_eq_zero_iff {f : α → E} (hf : ae_measurable f μ) (h0 : p ≠ 0) :
snorm f p μ = 0 ↔ f =ᵐ[μ] 0 :=
begin
by_cases h_top : p = ∞,
{ rw [h_top, snorm_exponent_top, snorm_ess_sup_eq_zero_iff], },
rw snorm_eq_snorm' h0 h_top,
exact snorm'_eq_zero_iff
(ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) h0.symm, h_top⟩) hf,
end
section trim
lemma snorm'_trim (hm : m ≤ m0) {f : α → E} (hf : @measurable _ _ m _ f) :
snorm' f q (ν.trim hm) = snorm' f q ν :=
begin
simp_rw snorm',
congr' 1,
refine lintegral_trim hm _,
refine @measurable.pow_const _ _ _ _ _ _ _ m _ (@measurable.coe_nnreal_ennreal _ m _ _) _,
exact @measurable.nnnorm E _ _ _ _ m _ hf,
end
lemma limsup_trim (hm : m ≤ m0) {f : α → ℝ≥0∞} (hf : @measurable _ _ m _ f) :
(ν.trim hm).ae.limsup f = ν.ae.limsup f :=
begin
simp_rw limsup_eq,
suffices h_set_eq : {a : ℝ≥0∞ | ∀ᵐ n ∂(ν.trim hm), f n ≤ a} = {a : ℝ≥0∞ | ∀ᵐ n ∂ν, f n ≤ a},
by rw h_set_eq,
ext1 a,
suffices h_meas_eq : ν {x | ¬ f x ≤ a} = ν.trim hm {x | ¬ f x ≤ a},
by simp_rw [set.mem_set_of_eq, ae_iff, h_meas_eq],
refine (trim_measurable_set_eq hm _).symm,
refine @measurable_set.compl _ _ m (@measurable_set_le ℝ≥0∞ _ _ _ _ m _ _ _ _ _ hf _),
exact @measurable_const _ _ _ m _,
end
lemma ess_sup_trim (hm : m ≤ m0) {f : α → ℝ≥0∞} (hf : @measurable _ _ m _ f) :
ess_sup f (ν.trim hm) = ess_sup f ν :=
by { simp_rw ess_sup, exact limsup_trim hm hf, }
lemma snorm_ess_sup_trim (hm : m ≤ m0) {f : α → E} (hf : @measurable _ _ m _ f) :
snorm_ess_sup f (ν.trim hm) = snorm_ess_sup f ν :=
ess_sup_trim hm (@measurable.coe_nnreal_ennreal _ m _ (@measurable.nnnorm E _ _ _ _ m _ hf))
lemma snorm_trim (hm : m ≤ m0) {f : α → E} (hf : @measurable _ _ m _ f) :
snorm f p (ν.trim hm) = snorm f p ν :=
begin
by_cases h0 : p = 0,
{ simp [h0], },
by_cases h_top : p = ∞,
{ simpa only [h_top, snorm_exponent_top] using snorm_ess_sup_trim hm hf, },
simpa only [snorm_eq_snorm' h0 h_top] using snorm'_trim hm hf,
end
lemma snorm_trim_ae (hm : m ≤ m0) {f : α → E} (hf : ae_measurable f (ν.trim hm)) :
snorm f p (ν.trim hm) = snorm f p ν :=
begin
rw [snorm_congr_ae hf.ae_eq_mk, snorm_congr_ae (ae_eq_of_ae_eq_trim hf.ae_eq_mk)],
exact snorm_trim hm hf.measurable_mk,
end
lemma mem_ℒp_of_mem_ℒp_trim (hm : m ≤ m0) {f : α → E} (hf : mem_ℒp f p (ν.trim hm)) :
mem_ℒp f p ν :=
⟨ae_measurable_of_ae_measurable_trim hm hf.1, (le_of_eq (snorm_trim_ae hm hf.1).symm).trans_lt hf.2⟩
end trim
end opens_measurable_space
@[simp] lemma snorm'_neg {f : α → F} : snorm' (-f) q μ = snorm' f q μ := by simp [snorm']
@[simp] lemma snorm_neg {f : α → F} : snorm (-f) p μ = snorm f p μ :=
begin
by_cases h0 : p = 0,
{ simp [h0], },
by_cases h_top : p = ∞,
{ simp [h_top, snorm_ess_sup], },
simp [snorm_eq_snorm' h0 h_top],
end
section borel_space
variable [borel_space E]
lemma mem_ℒp.neg {f : α → E} (hf : mem_ℒp f p μ) : mem_ℒp (-f) p μ :=
⟨ae_measurable.neg hf.1, by simp [hf.right]⟩
lemma snorm'_le_snorm'_mul_rpow_measure_univ {p q : ℝ} (hp0_lt : 0 < p) (hpq : p ≤ q)
{f : α → E} (hf : ae_measurable f μ) :
snorm' f p μ ≤ snorm' f q μ * (μ set.univ) ^ (1/p - 1/q) :=
begin
have hq0_lt : 0 < q, from lt_of_lt_of_le hp0_lt hpq,
by_cases hpq_eq : p = q,
{ rw [hpq_eq, sub_self, ennreal.rpow_zero, mul_one],
exact le_refl _, },
have hpq : p < q, from lt_of_le_of_ne hpq hpq_eq,
let g := λ a : α, (1 : ℝ≥0∞),
have h_rw : ∫⁻ a, ↑(nnnorm (f a))^p ∂ μ = ∫⁻ a, (nnnorm (f a) * (g a))^p ∂ μ,
from lintegral_congr (λ a, by simp),
repeat {rw snorm'},
rw h_rw,
let r := p * q / (q - p),
have hpqr : 1/p = 1/q + 1/r,
{ field_simp [(ne_of_lt hp0_lt).symm,
(ne_of_lt hq0_lt).symm],
ring, },
calc (∫⁻ (a : α), (↑(nnnorm (f a)) * g a) ^ p ∂μ) ^ (1/p)
≤ (∫⁻ (a : α), ↑(nnnorm (f a)) ^ q ∂μ) ^ (1/q) * (∫⁻ (a : α), (g a) ^ r ∂μ) ^ (1/r) :
ennreal.lintegral_Lp_mul_le_Lq_mul_Lr hp0_lt hpq hpqr μ hf.ennnorm
ae_measurable_const
... = (∫⁻ (a : α), ↑(nnnorm (f a)) ^ q ∂μ) ^ (1/q) * μ set.univ ^ (1/p - 1/q) :
by simp [hpqr],
end
lemma snorm'_le_snorm_ess_sup_mul_rpow_measure_univ (hq_pos : 0 < q) {f : α → F} :
snorm' f q μ ≤ snorm_ess_sup f μ * (μ set.univ) ^ (1/q) :=
begin
have h_le : ∫⁻ (a : α), ↑(nnnorm (f a)) ^ q ∂μ ≤ ∫⁻ (a : α), (snorm_ess_sup f μ) ^ q ∂μ,
{ refine lintegral_mono_ae _,
have h_nnnorm_le_snorm_ess_sup := coe_nnnorm_ae_le_snorm_ess_sup f μ,
refine h_nnnorm_le_snorm_ess_sup.mono (λ x hx, ennreal.rpow_le_rpow hx (le_of_lt hq_pos)), },
rw [snorm', ←ennreal.rpow_one (snorm_ess_sup f μ)],
nth_rewrite 1 ←mul_inv_cancel (ne_of_lt hq_pos).symm,
rw [ennreal.rpow_mul, one_div,
←ennreal.mul_rpow_of_nonneg _ _ (by simp [hq_pos.le] : 0 ≤ q⁻¹)],
refine ennreal.rpow_le_rpow _ (by simp [hq_pos.le]),
rwa lintegral_const at h_le,
end
lemma snorm_le_snorm_mul_rpow_measure_univ {p q : ℝ≥0∞} (hpq : p ≤ q) {f : α → E}
(hf : ae_measurable f μ) :
snorm f p μ ≤ snorm f q μ * (μ set.univ) ^ (1/p.to_real - 1/q.to_real) :=
begin
by_cases hp0 : p = 0,
{ simp [hp0, zero_le], },
rw ← ne.def at hp0,
have hp0_lt : 0 < p, from lt_of_le_of_ne (zero_le _) hp0.symm,
have hq0_lt : 0 < q, from lt_of_lt_of_le hp0_lt hpq,
by_cases hq_top : q = ∞,
{ simp only [hq_top, div_zero, one_div, ennreal.top_to_real, sub_zero, snorm_exponent_top,
inv_zero],
by_cases hp_top : p = ∞,
{ simp only [hp_top, ennreal.rpow_zero, mul_one, ennreal.top_to_real, sub_zero, inv_zero,
snorm_exponent_top],
exact le_rfl, },
rw snorm_eq_snorm' hp0 hp_top,
have hp_pos : 0 < p.to_real, from ennreal.to_real_pos_iff.mpr ⟨hp0_lt, hp_top⟩,
refine (snorm'_le_snorm_ess_sup_mul_rpow_measure_univ hp_pos).trans (le_of_eq _),
congr,
exact one_div _, },
have hp_lt_top : p < ∞, from hpq.trans_lt (lt_top_iff_ne_top.mpr hq_top),
have hp_pos : 0 < p.to_real, from ennreal.to_real_pos_iff.mpr ⟨hp0_lt, hp_lt_top.ne⟩,
rw [snorm_eq_snorm' hp0_lt.ne.symm hp_lt_top.ne, snorm_eq_snorm' hq0_lt.ne.symm hq_top],
have hpq_real : p.to_real ≤ q.to_real, by rwa ennreal.to_real_le_to_real hp_lt_top.ne hq_top,
exact snorm'_le_snorm'_mul_rpow_measure_univ hp_pos hpq_real hf,
end
lemma snorm'_le_snorm'_of_exponent_le {m : measurable_space α} {p q : ℝ} (hp0_lt : 0 < p)
(hpq : p ≤ q) (μ : measure α) [is_probability_measure μ] {f : α → E} (hf : ae_measurable f μ) :
snorm' f p μ ≤ snorm' f q μ :=
begin
have h_le_μ := snorm'_le_snorm'_mul_rpow_measure_univ hp0_lt hpq hf,
rwa [measure_univ, ennreal.one_rpow, mul_one] at h_le_μ,
end
lemma snorm'_le_snorm_ess_sup (hq_pos : 0 < q) {f : α → F} [is_probability_measure μ] :
snorm' f q μ ≤ snorm_ess_sup f μ :=
le_trans (snorm'_le_snorm_ess_sup_mul_rpow_measure_univ hq_pos) (le_of_eq (by simp [measure_univ]))
lemma snorm_le_snorm_of_exponent_le {p q : ℝ≥0∞} (hpq : p ≤ q) [is_probability_measure μ]
{f : α → E} (hf : ae_measurable f μ) :
snorm f p μ ≤ snorm f q μ :=
(snorm_le_snorm_mul_rpow_measure_univ hpq hf).trans (le_of_eq (by simp [measure_univ]))
lemma snorm'_lt_top_of_snorm'_lt_top_of_exponent_le {p q : ℝ} [is_finite_measure μ] {f : α → E}
(hf : ae_measurable f μ) (hfq_lt_top : snorm' f q μ < ∞) (hp_nonneg : 0 ≤ p) (hpq : p ≤ q) :
snorm' f p μ < ∞ :=
begin
cases le_or_lt p 0 with hp_nonpos hp_pos,
{ rw le_antisymm hp_nonpos hp_nonneg,
simp, },
have hq_pos : 0 < q, from lt_of_lt_of_le hp_pos hpq,
calc snorm' f p μ
≤ snorm' f q μ * (μ set.univ) ^ (1/p - 1/q) :
snorm'_le_snorm'_mul_rpow_measure_univ hp_pos hpq hf
... < ∞ :
begin
rw ennreal.mul_lt_top_iff,
refine or.inl ⟨hfq_lt_top, ennreal.rpow_lt_top_of_nonneg _ (measure_ne_top μ set.univ)⟩,
rwa [le_sub, sub_zero, one_div, one_div, inv_le_inv hq_pos hp_pos],
end
end
lemma mem_ℒp.mem_ℒp_of_exponent_le {p q : ℝ≥0∞} [is_finite_measure μ] {f : α → E}
(hfq : mem_ℒp f q μ) (hpq : p ≤ q) :
mem_ℒp f p μ :=
begin
cases hfq with hfq_m hfq_lt_top,
by_cases hp0 : p = 0,
{ rwa [hp0, mem_ℒp_zero_iff_ae_measurable], },
rw ←ne.def at hp0,
refine ⟨hfq_m, _⟩,
by_cases hp_top : p = ∞,
{ have hq_top : q = ∞,
by rwa [hp_top, top_le_iff] at hpq,
rw [hp_top],
rwa hq_top at hfq_lt_top, },
have hp_pos : 0 < p.to_real,
from ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) hp0.symm, hp_top⟩,
by_cases hq_top : q = ∞,
{ rw snorm_eq_snorm' hp0 hp_top,
rw [hq_top, snorm_exponent_top] at hfq_lt_top,
refine lt_of_le_of_lt (snorm'_le_snorm_ess_sup_mul_rpow_measure_univ hp_pos) _,
refine ennreal.mul_lt_top hfq_lt_top _,
exact ennreal.rpow_lt_top_of_nonneg (by simp [le_of_lt hp_pos]) (measure_ne_top μ set.univ), },
have hq0 : q ≠ 0,
{ by_contra hq_eq_zero,
push_neg at hq_eq_zero,
have hp_eq_zero : p = 0, from le_antisymm (by rwa hq_eq_zero at hpq) (zero_le _),
rw [hp_eq_zero, ennreal.zero_to_real] at hp_pos,
exact (lt_irrefl _) hp_pos, },
have hpq_real : p.to_real ≤ q.to_real, by rwa ennreal.to_real_le_to_real hp_top hq_top,
rw snorm_eq_snorm' hp0 hp_top,
rw snorm_eq_snorm' hq0 hq_top at hfq_lt_top,
exact snorm'_lt_top_of_snorm'_lt_top_of_exponent_le hfq_m hfq_lt_top (le_of_lt hp_pos) hpq_real,
end
lemma snorm'_add_le {f g : α → E} (hf : ae_measurable f μ) (hg : ae_measurable g μ) (hq1 : 1 ≤ q) :
snorm' (f + g) q μ ≤ snorm' f q μ + snorm' g q μ :=
calc (∫⁻ a, ↑(nnnorm ((f + g) a)) ^ q ∂μ) ^ (1 / q)
≤ (∫⁻ a, (((λ a, (nnnorm (f a) : ℝ≥0∞))
+ (λ a, (nnnorm (g a) : ℝ≥0∞))) a) ^ q ∂μ) ^ (1 / q) :
begin
refine ennreal.rpow_le_rpow _ (by simp [le_trans zero_le_one hq1] : 0 ≤ 1 / q),
refine lintegral_mono (λ a, ennreal.rpow_le_rpow _ (le_trans zero_le_one hq1)),
simp [←ennreal.coe_add, nnnorm_add_le],
end
... ≤ snorm' f q μ + snorm' g q μ :
ennreal.lintegral_Lp_add_le hf.ennnorm hg.ennnorm hq1
lemma snorm_ess_sup_add_le {f g : α → F} :
snorm_ess_sup (f + g) μ ≤ snorm_ess_sup f μ + snorm_ess_sup g μ :=
begin
refine le_trans (ess_sup_mono_ae (eventually_of_forall (λ x, _)))
(ennreal.ess_sup_add_le _ _),
simp_rw [pi.add_apply, ←ennreal.coe_add, ennreal.coe_le_coe],
exact nnnorm_add_le _ _,
end
lemma snorm_add_le {f g : α → E} (hf : ae_measurable f μ) (hg : ae_measurable g μ) (hp1 : 1 ≤ p) :
snorm (f + g) p μ ≤ snorm f p μ + snorm g p μ :=
begin
by_cases hp0 : p = 0,
{ simp [hp0], },
by_cases hp_top : p = ∞,
{ simp [hp_top, snorm_ess_sup_add_le], },
have hp1_real : 1 ≤ p.to_real,
by rwa [← ennreal.one_to_real, ennreal.to_real_le_to_real ennreal.one_ne_top hp_top],
repeat { rw snorm_eq_snorm' hp0 hp_top, },
exact snorm'_add_le hf hg hp1_real,
end
lemma snorm'_sum_le [second_countable_topology E] {ι} {f : ι → α → E} {s : finset ι}
(hfs : ∀ i, i ∈ s → ae_measurable (f i) μ) (hq1 : 1 ≤ q) :
snorm' (∑ i in s, f i) q μ ≤ ∑ i in s, snorm' (f i) q μ :=
finset.le_sum_of_subadditive_on_pred (λ (f : α → E), snorm' f q μ)
(λ f, ae_measurable f μ) (snorm'_zero (zero_lt_one.trans_le hq1))
(λ f g hf hg, snorm'_add_le hf hg hq1) (λ x y, ae_measurable.add) _ hfs
lemma snorm_sum_le [second_countable_topology E] {ι} {f : ι → α → E} {s : finset ι}
(hfs : ∀ i, i ∈ s → ae_measurable (f i) μ) (hp1 : 1 ≤ p) :
snorm (∑ i in s, f i) p μ ≤ ∑ i in s, snorm (f i) p μ :=
finset.le_sum_of_subadditive_on_pred (λ (f : α → E), snorm f p μ)
(λ f, ae_measurable f μ) snorm_zero (λ f g hf hg, snorm_add_le hf hg hp1)
(λ x y, ae_measurable.add) _ hfs
lemma snorm_add_lt_top_of_one_le {f g : α → E} (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ)
(hq1 : 1 ≤ p) : snorm (f + g) p μ < ∞ :=
lt_of_le_of_lt (snorm_add_le hf.1 hg.1 hq1) (ennreal.add_lt_top.mpr ⟨hf.2, hg.2⟩)
lemma snorm'_add_lt_top_of_le_one {f g : α → E} (hf : ae_measurable f μ) (hg : ae_measurable g μ)
(hf_snorm : snorm' f q μ < ∞) (hg_snorm : snorm' g q μ < ∞) (hq_pos : 0 < q) (hq1 : q ≤ 1) :
snorm' (f + g) q μ < ∞ :=
calc (∫⁻ a, ↑(nnnorm ((f + g) a)) ^ q ∂μ) ^ (1 / q)
≤ (∫⁻ a, (((λ a, (nnnorm (f a) : ℝ≥0∞))
+ (λ a, (nnnorm (g a) : ℝ≥0∞))) a) ^ q ∂μ) ^ (1 / q) :
begin
refine ennreal.rpow_le_rpow _ (by simp [hq_pos.le] : 0 ≤ 1 / q),
refine lintegral_mono (λ a, ennreal.rpow_le_rpow _ hq_pos.le),
simp [←ennreal.coe_add, nnnorm_add_le],
end
... ≤ (∫⁻ a, (nnnorm (f a) : ℝ≥0∞) ^ q + (nnnorm (g a) : ℝ≥0∞) ^ q ∂μ) ^ (1 / q) :
begin
refine ennreal.rpow_le_rpow (lintegral_mono (λ a, _)) (by simp [hq_pos.le] : 0 ≤ 1 / q),
exact ennreal.rpow_add_le_add_rpow _ _ hq_pos hq1,
end
... < ∞ :
begin
refine ennreal.rpow_lt_top_of_nonneg (by simp [hq_pos.le] : 0 ≤ 1 / q) _,
rw [lintegral_add' (hf.ennnorm.pow_const q)
(hg.ennnorm.pow_const q), ennreal.add_ne_top, ←lt_top_iff_ne_top,
←lt_top_iff_ne_top],
exact ⟨lintegral_rpow_nnnorm_lt_top_of_snorm'_lt_top hq_pos hf_snorm,
lintegral_rpow_nnnorm_lt_top_of_snorm'_lt_top hq_pos hg_snorm⟩,
end
lemma snorm_add_lt_top {f g : α → E} (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ) :
snorm (f + g) p μ < ∞ :=
begin
by_cases h0 : p = 0,
{ simp [h0], },
rw ←ne.def at h0,
cases le_total 1 p with hp1 hp1,
{ exact snorm_add_lt_top_of_one_le hf hg hp1, },
have hp_top : p ≠ ∞, from (lt_of_le_of_lt hp1 ennreal.coe_lt_top).ne,
have hp_pos : 0 < p.to_real,
{ rw [← ennreal.zero_to_real, @ennreal.to_real_lt_to_real 0 p ennreal.coe_ne_top hp_top],
exact ((zero_le p).lt_of_ne h0.symm), },
have hp1_real : p.to_real ≤ 1,
{ rwa [← ennreal.one_to_real, @ennreal.to_real_le_to_real p 1 hp_top ennreal.coe_ne_top], },
rw snorm_eq_snorm' h0 hp_top,
rw [mem_ℒp, snorm_eq_snorm' h0 hp_top] at hf hg,
exact snorm'_add_lt_top_of_le_one hf.1 hg.1 hf.2 hg.2 hp_pos hp1_real,
end
section second_countable_topology
variable [second_countable_topology E]
lemma mem_ℒp.add {f g : α → E} (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ) : mem_ℒp (f + g) p μ :=
⟨ae_measurable.add hf.1 hg.1, snorm_add_lt_top hf hg⟩
lemma mem_ℒp.sub {f g : α → E} (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ) : mem_ℒp (f - g) p μ :=
by { rw sub_eq_add_neg, exact hf.add hg.neg }
end second_countable_topology
end borel_space
section normed_space
variables {𝕜 : Type*} [normed_field 𝕜] [normed_space 𝕜 E] [normed_space 𝕜 F]
lemma snorm'_const_smul {f : α → F} (c : 𝕜) (hq_pos : 0 < q) :
snorm' (c • f) q μ = (nnnorm c : ℝ≥0∞) * snorm' f q μ :=
begin
rw snorm',
simp_rw [pi.smul_apply, nnnorm_smul, ennreal.coe_mul,
ennreal.mul_rpow_of_nonneg _ _ hq_pos.le],
suffices h_integral : ∫⁻ a, ↑(nnnorm c) ^ q * ↑(nnnorm (f a)) ^ q ∂μ
= (nnnorm c : ℝ≥0∞)^q * ∫⁻ a, (nnnorm (f a)) ^ q ∂μ,
{ apply_fun (λ x, x ^ (1/q)) at h_integral,
rw [h_integral, ennreal.mul_rpow_of_nonneg _ _ (by simp [hq_pos.le] : 0 ≤ 1 / q)],
congr,
simp_rw [←ennreal.rpow_mul, one_div, mul_inv_cancel hq_pos.ne.symm, ennreal.rpow_one], },
rw lintegral_const_mul',
rw ennreal.coe_rpow_of_nonneg _ hq_pos.le,
exact ennreal.coe_ne_top,
end
lemma snorm_ess_sup_const_smul {f : α → F} (c : 𝕜) :
snorm_ess_sup (c • f) μ = (nnnorm c : ℝ≥0∞) * snorm_ess_sup f μ :=
by simp_rw [snorm_ess_sup, pi.smul_apply, nnnorm_smul, ennreal.coe_mul, ennreal.ess_sup_const_mul]
lemma snorm_const_smul {f : α → F} (c : 𝕜) :
snorm (c • f) p μ = (nnnorm c : ℝ≥0∞) * snorm f p μ :=
begin
by_cases h0 : p = 0,
{ simp [h0], },
by_cases h_top : p = ∞,
{ simp [h_top, snorm_ess_sup_const_smul], },
repeat { rw snorm_eq_snorm' h0 h_top, },
rw ←ne.def at h0,
exact snorm'_const_smul c
(ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) h0.symm, h_top⟩),
end
lemma mem_ℒp.const_smul [measurable_space 𝕜] [opens_measurable_space 𝕜] [borel_space E] {f : α → E}
(hf : mem_ℒp f p μ) (c : 𝕜) :
mem_ℒp (c • f) p μ :=
⟨ae_measurable.const_smul hf.1 c,
lt_of_le_of_lt (le_of_eq (snorm_const_smul c)) (ennreal.mul_lt_top ennreal.coe_lt_top hf.2)⟩
lemma mem_ℒp.const_mul [measurable_space 𝕜] [borel_space 𝕜]
{f : α → 𝕜} (hf : mem_ℒp f p μ) (c : 𝕜) : mem_ℒp (λ x, c * f x) p μ :=
hf.const_smul c
lemma snorm'_smul_le_mul_snorm' [opens_measurable_space E] [measurable_space 𝕜]
[opens_measurable_space 𝕜] {p q r : ℝ}
{f : α → E} (hf : ae_measurable f μ) {φ : α → 𝕜} (hφ : ae_measurable φ μ)
(hp0_lt : 0 < p) (hpq : p < q) (hpqr : 1/p = 1/q + 1/r) :
snorm' (φ • f) p μ ≤ snorm' φ q μ * snorm' f r μ :=
begin
simp_rw [snorm', pi.smul_apply', nnnorm_smul, ennreal.coe_mul],
exact ennreal.lintegral_Lp_mul_le_Lq_mul_Lr hp0_lt hpq hpqr μ hφ.ennnorm
hf.ennnorm,
end
end normed_space
section monotonicity
lemma snorm_le_mul_snorm_aux_of_nonneg {f : α → F} {g : α → G} {c : ℝ}
(h : ∀ᵐ x ∂μ, ∥f x∥ ≤ c * ∥g x∥) (hc : 0 ≤ c) (p : ℝ≥0∞) :
snorm f p μ ≤ (ennreal.of_real c) * snorm g p μ :=
begin
lift c to ℝ≥0 using hc,
rw [ennreal.of_real_coe_nnreal, ← c.nnnorm_eq, ← snorm_norm g, ← snorm_const_smul (c : ℝ)],
swap, apply_instance,
refine snorm_mono_ae _,
simpa
end
lemma snorm_le_mul_snorm_aux_of_neg {f : α → F} {g : α → G} {c : ℝ}
(h : ∀ᵐ x ∂μ, ∥f x∥ ≤ c * ∥g x∥) (hc : c < 0) (p : ℝ≥0∞) :
snorm f p μ = 0 ∧ snorm g p μ = 0 :=
begin
suffices : f =ᵐ[μ] 0 ∧ g =ᵐ[μ] 0,
by simp [snorm_congr_ae this.1, snorm_congr_ae this.2],
refine ⟨h.mono $ λ x hx, _, h.mono $ λ x hx, _⟩,
{ refine norm_le_zero_iff.1 (hx.trans _),
exact mul_nonpos_of_nonpos_of_nonneg hc.le (norm_nonneg _) },
{ refine norm_le_zero_iff.1 (nonpos_of_mul_nonneg_right _ hc),
exact (norm_nonneg _).trans hx }
end
lemma snorm_le_mul_snorm_of_ae_le_mul {f : α → F} {g : α → G} {c : ℝ}
(h : ∀ᵐ x ∂μ, ∥f x∥ ≤ c * ∥g x∥) (p : ℝ≥0∞) :
snorm f p μ ≤ (ennreal.of_real c) * snorm g p μ :=
begin
cases le_or_lt 0 c with hc hc,
{ exact snorm_le_mul_snorm_aux_of_nonneg h hc p },
{ simp [snorm_le_mul_snorm_aux_of_neg h hc p] }
end
lemma mem_ℒp.of_le_mul [measurable_space F] {f : α → E} {g : α → F} {c : ℝ}
(hg : mem_ℒp g p μ) (hf : ae_measurable f μ) (hfg : ∀ᵐ x ∂μ, ∥f x∥ ≤ c * ∥g x∥) :
mem_ℒp f p μ :=
begin
simp only [mem_ℒp, hf, true_and],
apply lt_of_le_of_lt (snorm_le_mul_snorm_of_ae_le_mul hfg p),
simp [lt_top_iff_ne_top, hg.snorm_ne_top],
end
end monotonicity
section is_R_or_C
variables {𝕜 : Type*} [is_R_or_C 𝕜] [measurable_space 𝕜] [opens_measurable_space 𝕜] {f : α → 𝕜}
lemma mem_ℒp.re (hf : mem_ℒp f p μ) : mem_ℒp (λ x, is_R_or_C.re (f x)) p μ :=
begin
have : ∀ x, ∥is_R_or_C.re (f x)∥ ≤ 1 * ∥f x∥,
by { intro x, rw one_mul, exact is_R_or_C.norm_re_le_norm (f x), },
exact hf.of_le_mul hf.1.re (eventually_of_forall this),
end
lemma mem_ℒp.im (hf : mem_ℒp f p μ) : mem_ℒp (λ x, is_R_or_C.im (f x)) p μ :=
begin
have : ∀ x, ∥is_R_or_C.im (f x)∥ ≤ 1 * ∥f x∥,
by { intro x, rw one_mul, exact is_R_or_C.norm_im_le_norm (f x), },
exact hf.of_le_mul hf.1.im (eventually_of_forall this),
end
end is_R_or_C
section inner_product
variables {E' 𝕜 : Type*} [is_R_or_C 𝕜] [measurable_space 𝕜] [borel_space 𝕜]
[inner_product_space 𝕜 E']
[measurable_space E'] [opens_measurable_space E'] [second_countable_topology E']
local notation `⟪`x`, `y`⟫` := @inner 𝕜 E' _ x y
lemma mem_ℒp.const_inner (c : E') {f : α → E'} (hf : mem_ℒp f p μ) :
mem_ℒp (λ a, ⟪c, f a⟫) p μ :=
hf.of_le_mul (ae_measurable.inner ae_measurable_const hf.1)
(eventually_of_forall (λ x, norm_inner_le_norm _ _))
lemma mem_ℒp.inner_const {f : α → E'} (hf : mem_ℒp f p μ) (c : E') :
mem_ℒp (λ a, ⟪f a, c⟫) p μ :=
hf.of_le_mul (ae_measurable.inner hf.1 ae_measurable_const)
(eventually_of_forall (λ x, by { rw mul_comm, exact norm_inner_le_norm _ _, }))
end inner_product
end ℒp
/-!
### Lp space
The space of equivalence classes of measurable functions for which `snorm f p μ < ∞`.
-/
@[simp] lemma snorm_ae_eq_fun {α E : Type*} [measurable_space α] {μ : measure α}
[measurable_space E] [normed_group E] {p : ℝ≥0∞} {f : α → E} (hf : ae_measurable f μ) :
snorm (ae_eq_fun.mk f hf) p μ = snorm f p μ :=
snorm_congr_ae (ae_eq_fun.coe_fn_mk _ _)
lemma mem_ℒp.snorm_mk_lt_top {α E : Type*} [measurable_space α] {μ : measure α}
[measurable_space E] [normed_group E] {p : ℝ≥0∞} {f : α → E} (hfp : mem_ℒp f p μ) :
snorm (ae_eq_fun.mk f hfp.1) p μ < ∞ :=
by simp [hfp.2]
/-- Lp space -/
def Lp {α} (E : Type*) {m : measurable_space α} [measurable_space E] [normed_group E]
[borel_space E] [second_countable_topology E]
(p : ℝ≥0∞) (μ : measure α) : add_subgroup (α →ₘ[μ] E) :=
{ carrier := {f | snorm f p μ < ∞},
zero_mem' := by simp [snorm_congr_ae ae_eq_fun.coe_fn_zero, snorm_zero],
add_mem' := λ f g hf hg, by simp [snorm_congr_ae (ae_eq_fun.coe_fn_add _ _),
snorm_add_lt_top ⟨f.ae_measurable, hf⟩ ⟨g.ae_measurable, hg⟩],
neg_mem' := λ f hf,
by rwa [set.mem_set_of_eq, snorm_congr_ae (ae_eq_fun.coe_fn_neg _), snorm_neg] }
localized "notation α ` →₁[`:25 μ `] ` E := measure_theory.Lp E 1 μ" in measure_theory
localized "notation α ` →₂[`:25 μ `] ` E := measure_theory.Lp E 2 μ" in measure_theory
namespace mem_ℒp
variables [borel_space E] [second_countable_topology E]
/-- make an element of Lp from a function verifying `mem_ℒp` -/
def to_Lp (f : α → E) (h_mem_ℒp : mem_ℒp f p μ) : Lp E p μ :=
⟨ae_eq_fun.mk f h_mem_ℒp.1, h_mem_ℒp.snorm_mk_lt_top⟩
lemma coe_fn_to_Lp {f : α → E} (hf : mem_ℒp f p μ) : hf.to_Lp f =ᵐ[μ] f :=
ae_eq_fun.coe_fn_mk _ _
@[simp] lemma to_Lp_eq_to_Lp_iff {f g : α → E} (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ) :
hf.to_Lp f = hg.to_Lp g ↔ f =ᵐ[μ] g :=
by simp [to_Lp]
@[simp] lemma to_Lp_zero (h : mem_ℒp (0 : α → E) p μ) : h.to_Lp 0 = 0 := rfl
lemma to_Lp_add {f g : α → E} (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ) :
(hf.add hg).to_Lp (f + g) = hf.to_Lp f + hg.to_Lp g := rfl
lemma to_Lp_neg {f : α → E} (hf : mem_ℒp f p μ) : hf.neg.to_Lp (-f) = - hf.to_Lp f := rfl
lemma to_Lp_sub {f g : α → E} (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ) :
(hf.sub hg).to_Lp (f - g) = hf.to_Lp f - hg.to_Lp g := rfl
end mem_ℒp
namespace Lp
variables [borel_space E] [second_countable_topology E]
instance : has_coe_to_fun (Lp E p μ) := ⟨λ _, α → E, λ f, ((f : α →ₘ[μ] E) : α → E)⟩
@[ext] lemma ext {f g : Lp E p μ} (h : f =ᵐ[μ] g) : f = g :=
begin
cases f,
cases g,
simp only [subtype.mk_eq_mk],
exact ae_eq_fun.ext h
end
lemma ext_iff {f g : Lp E p μ} : f = g ↔ f =ᵐ[μ] g :=
⟨λ h, by rw h, λ h, ext h⟩
lemma mem_Lp_iff_snorm_lt_top {f : α →ₘ[μ] E} : f ∈ Lp E p μ ↔ snorm f p μ < ∞ := iff.refl _
lemma mem_Lp_iff_mem_ℒp {f : α →ₘ[μ] E} : f ∈ Lp E p μ ↔ mem_ℒp f p μ :=
by simp [mem_Lp_iff_snorm_lt_top, mem_ℒp, f.measurable.ae_measurable]
lemma antimono [is_finite_measure μ] {p q : ℝ≥0∞} (hpq : p ≤ q) : Lp E q μ ≤ Lp E p μ :=
λ f hf, (mem_ℒp.mem_ℒp_of_exponent_le ⟨f.ae_measurable, hf⟩ hpq).2
@[simp] lemma coe_fn_mk {f : α →ₘ[μ] E} (hf : snorm f p μ < ∞) :
((⟨f, hf⟩ : Lp E p μ) : α → E) = f := rfl
@[simp] lemma coe_mk {f : α →ₘ[μ] E} (hf : snorm f p μ < ∞) :
((⟨f, hf⟩ : Lp E p μ) : α →ₘ[μ] E) = f := rfl
@[simp] lemma to_Lp_coe_fn (f : Lp E p μ) (hf : mem_ℒp f p μ) : hf.to_Lp f = f :=
by { cases f, simp [mem_ℒp.to_Lp] }
lemma snorm_lt_top (f : Lp E p μ) : snorm f p μ < ∞ := f.prop
lemma snorm_ne_top (f : Lp E p μ) : snorm f p μ ≠ ∞ := (snorm_lt_top f).ne
@[measurability]
protected lemma measurable (f : Lp E p μ) : measurable f := f.val.measurable
@[measurability]
protected lemma ae_measurable (f : Lp E p μ) : ae_measurable f μ := f.val.ae_measurable
protected lemma mem_ℒp (f : Lp E p μ) : mem_ℒp f p μ := ⟨Lp.ae_measurable f, f.prop⟩
variables (E p μ)
lemma coe_fn_zero : ⇑(0 : Lp E p μ) =ᵐ[μ] 0 := ae_eq_fun.coe_fn_zero
variables {E p μ}
lemma coe_fn_neg (f : Lp E p μ) : ⇑(-f) =ᵐ[μ] -f := ae_eq_fun.coe_fn_neg _
lemma coe_fn_add (f g : Lp E p μ) : ⇑(f + g) =ᵐ[μ] f + g := ae_eq_fun.coe_fn_add _ _
lemma coe_fn_sub (f g : Lp E p μ) : ⇑(f - g) =ᵐ[μ] f - g := ae_eq_fun.coe_fn_sub _ _
lemma mem_Lp_const (α) {m : measurable_space α} (μ : measure α) (c : E) [is_finite_measure μ] :
@ae_eq_fun.const α _ _ μ _ c ∈ Lp E p μ :=
(mem_ℒp_const c).snorm_mk_lt_top
instance : has_norm (Lp E p μ) := { norm := λ f, ennreal.to_real (snorm f p μ) }
instance : has_dist (Lp E p μ) := { dist := λ f g, ∥f - g∥}
instance : has_edist (Lp E p μ) := { edist := λ f g, ennreal.of_real (dist f g) }
lemma norm_def (f : Lp E p μ) : ∥f∥ = ennreal.to_real (snorm f p μ) := rfl
@[simp] lemma norm_to_Lp (f : α → E) (hf : mem_ℒp f p μ) :
∥hf.to_Lp f∥ = ennreal.to_real (snorm f p μ) :=
by rw [norm_def, snorm_congr_ae (mem_ℒp.coe_fn_to_Lp hf)]
lemma dist_def (f g : Lp E p μ) : dist f g = (snorm (f - g) p μ).to_real :=
begin
simp_rw [dist, norm_def],
congr' 1,
apply snorm_congr_ae (coe_fn_sub _ _),
end
lemma edist_def (f g : Lp E p μ) : edist f g = snorm (f - g) p μ :=
begin
simp_rw [edist, dist, norm_def, ennreal.of_real_to_real (snorm_ne_top _)],
exact snorm_congr_ae (coe_fn_sub _ _)
end
@[simp] lemma edist_to_Lp_to_Lp (f g : α → E) (hf : mem_ℒp f p μ) (hg : mem_ℒp g p μ) :
edist (hf.to_Lp f) (hg.to_Lp g) = snorm (f - g) p μ :=
by { rw edist_def, exact snorm_congr_ae (hf.coe_fn_to_Lp.sub hg.coe_fn_to_Lp) }
@[simp] lemma edist_to_Lp_zero (f : α → E) (hf : mem_ℒp f p μ) :
edist (hf.to_Lp f) 0 = snorm f p μ :=
by { convert edist_to_Lp_to_Lp f 0 hf zero_mem_ℒp, simp }
@[simp] lemma norm_zero : ∥(0 : Lp E p μ)∥ = 0 :=
begin
change (snorm ⇑(0 : α →ₘ[μ] E) p μ).to_real = 0,
simp [snorm_congr_ae ae_eq_fun.coe_fn_zero, snorm_zero]
end
lemma norm_eq_zero_iff {f : Lp E p μ} (hp : 0 < p) : ∥f∥ = 0 ↔ f = 0 :=
begin
refine ⟨λ hf, _, λ hf, by simp [hf]⟩,
rw [norm_def, ennreal.to_real_eq_zero_iff] at hf,
cases hf,
{ rw snorm_eq_zero_iff (Lp.ae_measurable f) hp.ne.symm at hf,
exact subtype.eq (ae_eq_fun.ext (hf.trans ae_eq_fun.coe_fn_zero.symm)), },
{ exact absurd hf (snorm_ne_top f), },
end
lemma eq_zero_iff_ae_eq_zero {f : Lp E p μ} : f = 0 ↔ f =ᵐ[μ] 0 :=
begin
split,
{ assume h,
rw h,
exact ae_eq_fun.coe_fn_const _ _ },
{ assume h,
ext1,
filter_upwards [h, ae_eq_fun.coe_fn_const α (0 : E)],
assume a ha h'a,
rw ha,
exact h'a.symm }
end
@[simp] lemma norm_neg {f : Lp E p μ} : ∥-f∥ = ∥f∥ :=
by rw [norm_def, norm_def, snorm_congr_ae (coe_fn_neg _), snorm_neg]
lemma norm_le_mul_norm_of_ae_le_mul
[second_countable_topology F] [measurable_space F] [borel_space F]
{c : ℝ} {f : Lp E p μ} {g : Lp F p μ} (h : ∀ᵐ x ∂μ, ∥f x∥ ≤ c * ∥g x∥) : ∥f∥ ≤ c * ∥g∥ :=
begin
by_cases pzero : p = 0,
{ simp [pzero, norm_def] },
cases le_or_lt 0 c with hc hc,
{ have := snorm_le_mul_snorm_aux_of_nonneg h hc p,
rw [← ennreal.to_real_le_to_real, ennreal.to_real_mul, ennreal.to_real_of_real hc] at this,
{ exact this },
{ exact (Lp.mem_ℒp _).snorm_ne_top },
{ simp [(Lp.mem_ℒp _).snorm_ne_top] } },
{ have := snorm_le_mul_snorm_aux_of_neg h hc p,
simp only [snorm_eq_zero_iff (Lp.ae_measurable _) pzero, ← eq_zero_iff_ae_eq_zero] at this,
simp [this] }
end
lemma norm_le_norm_of_ae_le [second_countable_topology F] [measurable_space F] [borel_space F]
{f : Lp E p μ} {g : Lp F p μ} (h : ∀ᵐ x ∂μ, ∥f x∥ ≤ ∥g x∥) : ∥f∥ ≤ ∥g∥ :=
begin
rw [norm_def, norm_def, ennreal.to_real_le_to_real (snorm_ne_top _) (snorm_ne_top _)],
exact snorm_mono_ae h
end
lemma mem_Lp_of_ae_le_mul [second_countable_topology F] [measurable_space F] [borel_space F]
{c : ℝ} {f : α →ₘ[μ] E} {g : Lp F p μ} (h : ∀ᵐ x ∂μ, ∥f x∥ ≤ c * ∥g x∥) : f ∈ Lp E p μ :=
mem_Lp_iff_mem_ℒp.2 $ mem_ℒp.of_le_mul (Lp.mem_ℒp g) f.ae_measurable h
lemma mem_Lp_of_ae_le [second_countable_topology F] [measurable_space F] [borel_space F]
{f : α →ₘ[μ] E} {g : Lp F p μ} (h : ∀ᵐ x ∂μ, ∥f x∥ ≤ ∥g x∥) : f ∈ Lp E p μ :=
mem_Lp_iff_mem_ℒp.2 $ mem_ℒp.of_le (Lp.mem_ℒp g) f.ae_measurable h
lemma mem_Lp_of_ae_bound [is_finite_measure μ] {f : α →ₘ[μ] E} (C : ℝ) (hfC : ∀ᵐ x ∂μ, ∥f x∥ ≤ C) :
f ∈ Lp E p μ :=
mem_Lp_iff_mem_ℒp.2 $ mem_ℒp.of_bound f.ae_measurable _ hfC
lemma norm_le_of_ae_bound [is_finite_measure μ] {f : Lp E p μ} {C : ℝ} (hC : 0 ≤ C)
(hfC : ∀ᵐ x ∂μ, ∥f x∥ ≤ C) :
∥f∥ ≤ (measure_univ_nnreal μ) ^ (p.to_real)⁻¹ * C :=
begin
by_cases hμ : μ = 0,
{ by_cases hp : p.to_real⁻¹ = 0,
{ simpa [hp, hμ, norm_def] using hC },
{ simp [hμ, norm_def, real.zero_rpow hp] } },
let A : ℝ≥0 := (measure_univ_nnreal μ) ^ (p.to_real)⁻¹ * ⟨C, hC⟩,
suffices : snorm f p μ ≤ A,
{ exact ennreal.to_real_le_coe_of_le_coe this },
convert snorm_le_of_ae_bound hfC,
rw [← coe_measure_univ_nnreal μ, ennreal.coe_rpow_of_ne_zero (measure_univ_nnreal_pos hμ).ne',
ennreal.coe_mul],
congr,
rw max_eq_left hC
end
instance [hp : fact (1 ≤ p)] : normed_group (Lp E p μ) :=
normed_group.of_core _
{ norm_eq_zero_iff := λ f, norm_eq_zero_iff (ennreal.zero_lt_one.trans_le hp.1),
triangle := begin
assume f g,
simp only [norm_def],
rw ← ennreal.to_real_add (snorm_ne_top f) (snorm_ne_top g),
suffices h_snorm : snorm ⇑(f + g) p μ ≤ snorm ⇑f p μ + snorm ⇑g p μ,
{ rwa ennreal.to_real_le_to_real (snorm_ne_top (f + g)),
exact ennreal.add_ne_top.mpr ⟨snorm_ne_top f, snorm_ne_top g⟩, },
rw [snorm_congr_ae (coe_fn_add _ _)],
exact snorm_add_le (Lp.ae_measurable f) (Lp.ae_measurable g) hp.1,
end,
norm_neg := by simp }
instance normed_group_L1 : normed_group (Lp E 1 μ) := by apply_instance
instance normed_group_L2 : normed_group (Lp E 2 μ) := by apply_instance
instance normed_group_Ltop : normed_group (Lp E ∞ μ) := by apply_instance
section normed_space
variables {𝕜 : Type*} [normed_field 𝕜] [normed_space 𝕜 E] [measurable_space 𝕜]
[opens_measurable_space 𝕜]
lemma mem_Lp_const_smul (c : 𝕜) (f : Lp E p μ) : c • ↑f ∈ Lp E p μ :=
begin
rw [mem_Lp_iff_snorm_lt_top, snorm_congr_ae (ae_eq_fun.coe_fn_smul _ _), snorm_const_smul,
ennreal.mul_lt_top_iff],
exact or.inl ⟨ennreal.coe_lt_top, f.prop⟩,
end
variables (E p μ 𝕜)
/-- The `𝕜`-submodule of elements of `α →ₘ[μ] E` whose `Lp` norm is finite. This is `Lp E p μ`,
with extra structure. -/
def Lp_submodule : submodule 𝕜 (α →ₘ[μ] E) :=
{ smul_mem' := λ c f hf, by simpa using mem_Lp_const_smul c ⟨f, hf⟩,
.. Lp E p μ }
variables {E p μ 𝕜}
lemma coe_Lp_submodule : (Lp_submodule E p μ 𝕜).to_add_subgroup = Lp E p μ := rfl
instance : module 𝕜 (Lp E p μ) :=
{ .. (Lp_submodule E p μ 𝕜).module }
lemma coe_fn_smul (c : 𝕜) (f : Lp E p μ) : ⇑(c • f) =ᵐ[μ] c • f := ae_eq_fun.coe_fn_smul _ _
lemma norm_const_smul (c : 𝕜) (f : Lp E p μ) : ∥c • f∥ = ∥c∥ * ∥f∥ :=
by rw [norm_def, snorm_congr_ae (coe_fn_smul _ _), snorm_const_smul c,
ennreal.to_real_mul, ennreal.coe_to_real, coe_nnnorm, norm_def]
instance [fact (1 ≤ p)] : normed_space 𝕜 (Lp E p μ) :=
{ norm_smul_le := λ _ _, by simp [norm_const_smul] }
instance normed_space_L1 : normed_space 𝕜 (Lp E 1 μ) := by apply_instance
instance normed_space_L2 : normed_space 𝕜 (Lp E 2 μ) := by apply_instance
instance normed_space_Ltop : normed_space 𝕜 (Lp E ∞ μ) := by apply_instance
end normed_space
end Lp
namespace mem_ℒp
variables
[borel_space E] [second_countable_topology E]
{𝕜 : Type*} [normed_field 𝕜] [normed_space 𝕜 E] [measurable_space 𝕜] [opens_measurable_space 𝕜]
lemma to_Lp_const_smul {f : α → E} (c : 𝕜) (hf : mem_ℒp f p μ) :
(hf.const_smul c).to_Lp (c • f) = c • hf.to_Lp f := rfl
end mem_ℒp
/-! ### Indicator of a set as an element of Lᵖ
For a set `s` with `(hs : measurable_set s)` and `(hμs : μ s < ∞)`, we build
`indicator_const_Lp p hs hμs c`, the element of `Lp` corresponding to `s.indicator (λ x, c)`.
-/
section indicator
variables {s : set α} {hs : measurable_set s} {c : E} {f : α → E} {hf : ae_measurable f μ}
lemma snorm_ess_sup_indicator_le (s : set α) (f : α → G) :
snorm_ess_sup (s.indicator f) μ ≤ snorm_ess_sup f μ :=
begin
refine ess_sup_mono_ae (eventually_of_forall (λ x, _)),
rw [ennreal.coe_le_coe, nnnorm_indicator_eq_indicator_nnnorm],
exact set.indicator_le_self s _ x,
end
lemma snorm_ess_sup_indicator_const_le (s : set α) (c : G) :
snorm_ess_sup (s.indicator (λ x : α , c)) μ ≤ ∥c∥₊ :=
begin
by_cases hμ0 : μ = 0,
{ rw [hμ0, snorm_ess_sup_measure_zero, ennreal.coe_nonneg],
exact zero_le', },
{ exact (snorm_ess_sup_indicator_le s (λ x, c)).trans (snorm_ess_sup_const c hμ0).le, },
end
lemma snorm_ess_sup_indicator_const_eq (s : set α) (c : G) (hμs : μ s ≠ 0) :
snorm_ess_sup (s.indicator (λ x : α , c)) μ = ∥c∥₊ :=
begin
refine le_antisymm (snorm_ess_sup_indicator_const_le s c) _,
by_contra h,
push_neg at h,
have h' := ae_iff.mp (ae_lt_of_ess_sup_lt h),
push_neg at h',
refine hμs (measure_mono_null (λ x hx_mem, _) h'),
rw [set.mem_set_of_eq, set.indicator_of_mem hx_mem],
exact le_rfl,
end
variables (hs)
lemma snorm_indicator_le {E : Type*} [normed_group E] (f : α → E) :
snorm (s.indicator f) p μ ≤ snorm f p μ :=
begin
refine snorm_mono_ae (eventually_of_forall (λ x, _)),
suffices : ∥s.indicator f x∥₊ ≤ ∥f x∥₊,
{ exact nnreal.coe_mono this },
rw nnnorm_indicator_eq_indicator_nnnorm,
exact s.indicator_le_self _ x,
end
variables {hs}
lemma snorm_indicator_const {c : G} (hs : measurable_set s) (hp : p ≠ 0) (hp_top : p ≠ ∞) :
snorm (s.indicator (λ x, c)) p μ = ∥c∥₊ * (μ s) ^ (1 / p.to_real) :=
begin
have hp_pos : 0 < p.to_real,
from ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) hp.symm, hp_top⟩,
rw snorm_eq_lintegral_rpow_nnnorm hp hp_top,
simp_rw [nnnorm_indicator_eq_indicator_nnnorm, ennreal.coe_indicator],
have h_indicator_pow : (λ a : α, s.indicator (λ (x : α), (∥c∥₊ : ℝ≥0∞)) a ^ p.to_real)
= s.indicator (λ (x : α), ↑∥c∥₊ ^ p.to_real),
{ rw set.comp_indicator_const (∥c∥₊ : ℝ≥0∞) (λ x, x ^ p.to_real) _,
simp [hp_pos], },
rw [h_indicator_pow, lintegral_indicator _ hs, set_lintegral_const, ennreal.mul_rpow_of_nonneg],
{ rw [← ennreal.rpow_mul, mul_one_div_cancel hp_pos.ne.symm, ennreal.rpow_one], },
{ simp [hp_pos.le], },
end
lemma snorm_indicator_const' {c : G} (hs : measurable_set s) (hμs : μ s ≠ 0) (hp : p ≠ 0) :
snorm (s.indicator (λ _, c)) p μ = ∥c∥₊ * (μ s) ^ (1 / p.to_real) :=
begin
by_cases hp_top : p = ∞,
{ simp [hp_top, snorm_ess_sup_indicator_const_eq s c hμs], },
{ exact snorm_indicator_const hs hp hp_top, },
end
lemma mem_ℒp.indicator (hs : measurable_set s) (hf : mem_ℒp f p μ) :
mem_ℒp (s.indicator f) p μ :=
⟨hf.ae_measurable.indicator hs, lt_of_le_of_lt (snorm_indicator_le f) hf.snorm_lt_top⟩
lemma mem_ℒp_indicator_const (p : ℝ≥0∞) (hs : measurable_set s) (c : E) (hμsc : c = 0 ∨ μ s ≠ ∞) :
mem_ℒp (s.indicator (λ _, c)) p μ :=
begin
cases hμsc with hc hμs,
{ simp only [hc, set.indicator_zero],
exact zero_mem_ℒp, },
refine ⟨(ae_measurable_indicator_iff hs).mpr ae_measurable_const, _⟩,
by_cases hp0 : p = 0,
{ simp only [hp0, snorm_exponent_zero, with_top.zero_lt_top], },
by_cases hp_top : p = ∞,
{ rw [hp_top, snorm_exponent_top],
exact (snorm_ess_sup_indicator_const_le s c).trans_lt ennreal.coe_lt_top, },
have hp_pos : 0 < p.to_real,
from ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) (ne.symm hp0), hp_top⟩,
rw snorm_lt_top_iff_lintegral_rpow_nnnorm_lt_top hp0 hp_top,
simp_rw [nnnorm_indicator_eq_indicator_nnnorm, ennreal.coe_indicator],
have h_indicator_pow : (λ a : α, s.indicator (λ _, (∥c∥₊ : ℝ≥0∞)) a ^ p.to_real)
= s.indicator (λ _, ↑∥c∥₊ ^ p.to_real),
{ rw set.comp_indicator_const (∥c∥₊ : ℝ≥0∞) (λ x, x ^ p.to_real) _, simp [hp_pos], },
rw [h_indicator_pow, lintegral_indicator _ hs, set_lintegral_const],
refine ennreal.mul_lt_top _ (lt_top_iff_ne_top.mpr hμs),
exact ennreal.rpow_lt_top_of_nonneg hp_pos.le ennreal.coe_ne_top,
end
end indicator
section indicator_const_Lp
open set function
variables {s : set α} {hs : measurable_set s} {hμs : μ s ≠ ∞} {c : E}
[borel_space E] [second_countable_topology E]
/-- Indicator of a set as an element of `Lp`. -/
def indicator_const_Lp (p : ℝ≥0∞) (hs : measurable_set s) (hμs : μ s ≠ ∞) (c : E) : Lp E p μ :=
mem_ℒp.to_Lp (s.indicator (λ _, c)) (mem_ℒp_indicator_const p hs c (or.inr hμs))
lemma indicator_const_Lp_coe_fn : ⇑(indicator_const_Lp p hs hμs c) =ᵐ[μ] s.indicator (λ _, c) :=
mem_ℒp.coe_fn_to_Lp (mem_ℒp_indicator_const p hs c (or.inr hμs))
lemma indicator_const_Lp_coe_fn_mem :
∀ᵐ (x : α) ∂μ, x ∈ s → indicator_const_Lp p hs hμs c x = c :=
indicator_const_Lp_coe_fn.mono (λ x hx hxs, hx.trans (set.indicator_of_mem hxs _))
lemma indicator_const_Lp_coe_fn_nmem :
∀ᵐ (x : α) ∂μ, x ∉ s → indicator_const_Lp p hs hμs c x = 0 :=
indicator_const_Lp_coe_fn.mono (λ x hx hxs, hx.trans (set.indicator_of_not_mem hxs _))
lemma norm_indicator_const_Lp (hp_ne_zero : p ≠ 0) (hp_ne_top : p ≠ ∞) :
∥indicator_const_Lp p hs hμs c∥ = ∥c∥ * (μ s).to_real ^ (1 / p.to_real) :=
by rw [Lp.norm_def, snorm_congr_ae indicator_const_Lp_coe_fn,
snorm_indicator_const hs hp_ne_zero hp_ne_top, ennreal.to_real_mul, ennreal.to_real_rpow,
ennreal.coe_to_real, coe_nnnorm]
lemma norm_indicator_const_Lp_top (hμs_ne_zero : μ s ≠ 0) : ∥indicator_const_Lp ∞ hs hμs c∥ = ∥c∥ :=
by rw [Lp.norm_def, snorm_congr_ae indicator_const_Lp_coe_fn,
snorm_indicator_const' hs hμs_ne_zero ennreal.top_ne_zero, ennreal.top_to_real, div_zero,
ennreal.rpow_zero, mul_one, ennreal.coe_to_real, coe_nnnorm]
lemma norm_indicator_const_Lp' (hp_pos : p ≠ 0) (hμs_pos : μ s ≠ 0) :
∥indicator_const_Lp p hs hμs c∥ = ∥c∥ * (μ s).to_real ^ (1 / p.to_real) :=
begin
by_cases hp_top : p = ∞,
{ rw [hp_top, ennreal.top_to_real, div_zero, real.rpow_zero, mul_one],
exact norm_indicator_const_Lp_top hμs_pos, },
{ exact norm_indicator_const_Lp hp_pos hp_top, },
end
@[simp] lemma indicator_const_empty :
indicator_const_Lp p measurable_set.empty (by simp : μ ∅ ≠ ∞) c = 0 :=
begin
rw Lp.eq_zero_iff_ae_eq_zero,
convert indicator_const_Lp_coe_fn,
simp [set.indicator_empty'],
end
lemma mem_ℒp_add_of_disjoint {f g : α → E}
(h : disjoint (support f) (support g)) (hf : measurable f) (hg : measurable g) :
mem_ℒp (f + g) p μ ↔ mem_ℒp f p μ ∧ mem_ℒp g p μ :=
begin
refine ⟨λ hfg, ⟨_, _⟩, λ h, h.1.add h.2⟩,
{ rw ← indicator_add_eq_left h, exact hfg.indicator (measurable_set_support hf) },
{ rw ← indicator_add_eq_right h, exact hfg.indicator (measurable_set_support hg) }
end
/-- The indicator of a disjoint union of two sets is the sum of the indicators of the sets. -/
lemma indicator_const_Lp_disjoint_union {s t : set α} (hs : measurable_set s)
(ht : measurable_set t) (hμs : μ s ≠ ∞) (hμt : μ t ≠ ∞) (hst : s ∩ t = ∅) (c : E) :
(indicator_const_Lp p (hs.union ht) ((measure_union_le s t).trans_lt
(lt_top_iff_ne_top.mpr (ennreal.add_ne_top.mpr ⟨hμs, hμt⟩))).ne c)
= indicator_const_Lp p hs hμs c + indicator_const_Lp p ht hμt c :=
begin
ext1,
refine indicator_const_Lp_coe_fn.trans (eventually_eq.trans _ (Lp.coe_fn_add _ _).symm),
refine eventually_eq.trans _
(eventually_eq.add indicator_const_Lp_coe_fn.symm indicator_const_Lp_coe_fn.symm),
rw set.indicator_union_of_disjoint (set.disjoint_iff_inter_eq_empty.mpr hst) _,
end
end indicator_const_Lp
end measure_theory
open measure_theory
/-!
### Composition on `L^p`
We show that Lipschitz functions vanishing at zero act by composition on `L^p`, and specialize
this to the composition with continuous linear maps, and to the definition of the positive
part of an `L^p` function.
-/
section composition
variables [second_countable_topology E] [borel_space E]
[second_countable_topology F] [measurable_space F] [borel_space F]
{g : E → F} {c : ℝ≥0}
namespace lipschitz_with
lemma mem_ℒp_comp_iff_of_antilipschitz {α E F} {K K'} [measurable_space α] {μ : measure α}
[measurable_space E] [measurable_space F] [normed_group E] [normed_group F] [borel_space E]
[borel_space F] [complete_space E]
{f : α → E} {g : E → F} (hg : lipschitz_with K g) (hg' : antilipschitz_with K' g) (g0 : g 0 = 0) :
mem_ℒp (g ∘ f) p μ ↔ mem_ℒp f p μ :=
begin
have := ae_measurable_comp_iff_of_closed_embedding g (hg'.closed_embedding hg.uniform_continuous),
split,
{ assume H,
have A : ∀ᵐ x ∂μ, ∥f x∥ ≤ K' * ∥g (f x)∥,
{ apply filter.eventually_of_forall (λ x, _),
rw [← dist_zero_right, ← dist_zero_right, ← g0],
apply hg'.le_mul_dist },
exact H.of_le_mul (this.1 H.ae_measurable) A },
{ assume H,
have A : ∀ᵐ x ∂μ, ∥g (f x)∥ ≤ K * ∥f x∥,
{ apply filter.eventually_of_forall (λ x, _),
rw [← dist_zero_right, ← dist_zero_right, ← g0],
apply hg.dist_le_mul },
exact H.of_le_mul (this.2 H.ae_measurable) A }
end
/-- When `g` is a Lipschitz function sending `0` to `0` and `f` is in `Lp`, then `g ∘ f` is well
defined as an element of `Lp`. -/
def comp_Lp (hg : lipschitz_with c g) (g0 : g 0 = 0) (f : Lp E p μ) : Lp F p μ :=
⟨ae_eq_fun.comp g hg.continuous.measurable (f : α →ₘ[μ] E),
begin
suffices : ∀ᵐ x ∂μ, ∥ae_eq_fun.comp g hg.continuous.measurable (f : α →ₘ[μ] E) x∥ ≤ c * ∥f x∥,
{ exact Lp.mem_Lp_of_ae_le_mul this },
filter_upwards [ae_eq_fun.coe_fn_comp g hg.continuous.measurable (f : α →ₘ[μ] E)],
assume a ha,
simp only [ha],
rw [← dist_zero_right, ← dist_zero_right, ← g0],
exact hg.dist_le_mul (f a) 0,
end⟩
lemma coe_fn_comp_Lp (hg : lipschitz_with c g) (g0 : g 0 = 0) (f : Lp E p μ) :
hg.comp_Lp g0 f =ᵐ[μ] g ∘ f :=
ae_eq_fun.coe_fn_comp _ _ _
@[simp] lemma comp_Lp_zero (hg : lipschitz_with c g) (g0 : g 0 = 0) :
hg.comp_Lp g0 (0 : Lp E p μ) = 0 :=
begin
rw Lp.eq_zero_iff_ae_eq_zero,
apply (coe_fn_comp_Lp _ _ _).trans,
filter_upwards [Lp.coe_fn_zero E p μ],
assume a ha,
simp [ha, g0]
end
lemma norm_comp_Lp_sub_le (hg : lipschitz_with c g) (g0 : g 0 = 0) (f f' : Lp E p μ) :
∥hg.comp_Lp g0 f - hg.comp_Lp g0 f'∥ ≤ c * ∥f - f'∥ :=
begin
apply Lp.norm_le_mul_norm_of_ae_le_mul,
filter_upwards [hg.coe_fn_comp_Lp g0 f, hg.coe_fn_comp_Lp g0 f',
Lp.coe_fn_sub (hg.comp_Lp g0 f) (hg.comp_Lp g0 f'), Lp.coe_fn_sub f f'],
assume a ha1 ha2 ha3 ha4,
simp [ha1, ha2, ha3, ha4, ← dist_eq_norm],
exact hg.dist_le_mul (f a) (f' a)
end
lemma norm_comp_Lp_le (hg : lipschitz_with c g) (g0 : g 0 = 0) (f : Lp E p μ) :
∥hg.comp_Lp g0 f∥ ≤ c * ∥f∥ :=
by simpa using hg.norm_comp_Lp_sub_le g0 f 0
lemma lipschitz_with_comp_Lp [fact (1 ≤ p)] (hg : lipschitz_with c g) (g0 : g 0 = 0) :
lipschitz_with c (hg.comp_Lp g0 : Lp E p μ → Lp F p μ) :=
lipschitz_with.of_dist_le_mul $ λ f g, by simp [dist_eq_norm, norm_comp_Lp_sub_le]
lemma continuous_comp_Lp [fact (1 ≤ p)] (hg : lipschitz_with c g) (g0 : g 0 = 0) :
continuous (hg.comp_Lp g0 : Lp E p μ → Lp F p μ) :=
(lipschitz_with_comp_Lp hg g0).continuous
end lipschitz_with
namespace continuous_linear_map
variables {𝕜 : Type*} [nondiscrete_normed_field 𝕜] [normed_space 𝕜 E] [normed_space 𝕜 F]
/-- Composing `f : Lp ` with `L : E →L[𝕜] F`. -/
def comp_Lp (L : E →L[𝕜] F) (f : Lp E p μ) : Lp F p μ :=
L.lipschitz.comp_Lp (map_zero L) f
lemma coe_fn_comp_Lp (L : E →L[𝕜] F) (f : Lp E p μ) :
∀ᵐ a ∂μ, (L.comp_Lp f) a = L (f a) :=
lipschitz_with.coe_fn_comp_Lp _ _ _
lemma norm_comp_Lp_le (L : E →L[𝕜] F) (f : Lp E p μ) : ∥L.comp_Lp f∥ ≤ ∥L∥ * ∥f∥ :=
lipschitz_with.norm_comp_Lp_le _ _ _
variables (μ p) [measurable_space 𝕜] [opens_measurable_space 𝕜]
/-- Composing `f : Lp E p μ` with `L : E →L[𝕜] F`, seen as a `𝕜`-linear map on `Lp E p μ`. -/
def comp_Lpₗ (L : E →L[𝕜] F) : (Lp E p μ) →ₗ[𝕜] (Lp F p μ) :=
{ to_fun := λ f, L.comp_Lp f,
map_add' := begin
intros f g,
ext1,
filter_upwards [Lp.coe_fn_add f g, coe_fn_comp_Lp L (f + g), coe_fn_comp_Lp L f,
coe_fn_comp_Lp L g, Lp.coe_fn_add (L.comp_Lp f) (L.comp_Lp g)],
assume a ha1 ha2 ha3 ha4 ha5,
simp only [ha1, ha2, ha3, ha4, ha5, map_add, pi.add_apply],
end,
map_smul' := begin
intros c f,
ext1,
filter_upwards [Lp.coe_fn_smul c f, coe_fn_comp_Lp L (c • f), Lp.coe_fn_smul c (L.comp_Lp f),
coe_fn_comp_Lp L f],
assume a ha1 ha2 ha3 ha4,
simp only [ha1, ha2, ha3, ha4, map_smul, pi.smul_apply],
end }
/-- Composing `f : Lp E p μ` with `L : E →L[𝕜] F`, seen as a continuous `𝕜`-linear map on
`Lp E p μ`. See also the similar
* `linear_map.comp_left` for functions,
* `continuous_linear_map.comp_left_continuous` for continuous functions,
* `continuous_linear_map.comp_left_continuous_bounded` for bounded continuous functions,
* `continuous_linear_map.comp_left_continuous_compact` for continuous functions on compact spaces.
-/
def comp_LpL [fact (1 ≤ p)] (L : E →L[𝕜] F) : (Lp E p μ) →L[𝕜] (Lp F p μ) :=
linear_map.mk_continuous (L.comp_Lpₗ p μ) ∥L∥ L.norm_comp_Lp_le
lemma norm_compLpL_le [fact (1 ≤ p)] (L : E →L[𝕜] F) :
∥L.comp_LpL p μ∥ ≤ ∥L∥ :=
linear_map.mk_continuous_norm_le _ (norm_nonneg _) _
end continuous_linear_map
namespace measure_theory
namespace Lp
section pos_part
lemma lipschitz_with_pos_part : lipschitz_with 1 (λ (x : ℝ), max x 0) :=
lipschitz_with.of_dist_le_mul $ λ x y, by simp [dist, abs_max_sub_max_le_abs]
/-- Positive part of a function in `L^p`. -/
def pos_part (f : Lp ℝ p μ) : Lp ℝ p μ :=
lipschitz_with_pos_part.comp_Lp (max_eq_right (le_refl _)) f
/-- Negative part of a function in `L^p`. -/
def neg_part (f : Lp ℝ p μ) : Lp ℝ p μ := pos_part (-f)
@[norm_cast]
lemma coe_pos_part (f : Lp ℝ p μ) : (pos_part f : α →ₘ[μ] ℝ) = (f : α →ₘ[μ] ℝ).pos_part := rfl
lemma coe_fn_pos_part (f : Lp ℝ p μ) : ⇑(pos_part f) =ᵐ[μ] λ a, max (f a) 0 :=
ae_eq_fun.coe_fn_pos_part _
lemma coe_fn_neg_part_eq_max (f : Lp ℝ p μ) : ∀ᵐ a ∂μ, neg_part f a = max (- f a) 0 :=
begin
rw neg_part,
filter_upwards [coe_fn_pos_part (-f), coe_fn_neg f],
assume a h₁ h₂,
rw [h₁, h₂, pi.neg_apply]
end
lemma coe_fn_neg_part (f : Lp ℝ p μ) : ∀ᵐ a ∂μ, neg_part f a = - min (f a) 0 :=
(coe_fn_neg_part_eq_max f).mono $ assume a h,
by rw [h, ← max_neg_neg, neg_zero]
lemma continuous_pos_part [fact (1 ≤ p)] : continuous (λf : Lp ℝ p μ, pos_part f) :=
lipschitz_with.continuous_comp_Lp _ _
lemma continuous_neg_part [fact (1 ≤ p)] : continuous (λf : Lp ℝ p μ, neg_part f) :=
have eq : (λf : Lp ℝ p μ, neg_part f) = (λf : Lp ℝ p μ, pos_part (-f)) := rfl,
by { rw eq, exact continuous_pos_part.comp continuous_neg }
end pos_part
end Lp
end measure_theory
end composition
/-!
## `L^p` is a complete space
We show that `L^p` is a complete space for `1 ≤ p`.
-/
section complete_space
variables [borel_space E] [second_countable_topology E]
namespace measure_theory
namespace Lp
lemma snorm'_lim_eq_lintegral_liminf {ι} [nonempty ι] [linear_order ι] {f : ι → α → G} {p : ℝ}
(hp_nonneg : 0 ≤ p) {f_lim : α → G}
(h_lim : ∀ᵐ (x : α) ∂μ, tendsto (λ n, f n x) at_top (𝓝 (f_lim x))) :
snorm' f_lim p μ = (∫⁻ a, at_top.liminf (λ m, (nnnorm (f m a) : ℝ≥0∞)^p) ∂μ) ^ (1/p) :=
begin
suffices h_no_pow : (∫⁻ a, (nnnorm (f_lim a)) ^ p ∂μ)
= (∫⁻ a, at_top.liminf (λ m, (nnnorm (f m a) : ℝ≥0∞)^p) ∂μ),
{ rw [snorm', h_no_pow], },
refine lintegral_congr_ae (h_lim.mono (λ a ha, _)),
rw tendsto.liminf_eq,
simp_rw [ennreal.coe_rpow_of_nonneg _ hp_nonneg, ennreal.tendsto_coe],
refine ((nnreal.continuous_rpow_const hp_nonneg).tendsto (nnnorm (f_lim a))).comp _,
exact (continuous_nnnorm.tendsto (f_lim a)).comp ha,
end
lemma snorm'_lim_le_liminf_snorm' {E} [measurable_space E]
[normed_group E] [borel_space E] {f : ℕ → α → E} {p : ℝ} (hp_pos : 0 < p)
(hf : ∀ n, ae_measurable (f n) μ) {f_lim : α → E}
(h_lim : ∀ᵐ (x : α) ∂μ, tendsto (λ n, f n x) at_top (𝓝 (f_lim x))) :
snorm' f_lim p μ ≤ at_top.liminf (λ n, snorm' (f n) p μ) :=
begin
rw snorm'_lim_eq_lintegral_liminf hp_pos.le h_lim,
rw [←ennreal.le_rpow_one_div_iff (by simp [hp_pos] : 0 < 1 / p), one_div_one_div],
refine (lintegral_liminf_le' (λ m, ((hf m).ennnorm.pow_const _))).trans_eq _,
have h_pow_liminf : at_top.liminf (λ n, snorm' (f n) p μ) ^ p
= at_top.liminf (λ n, (snorm' (f n) p μ) ^ p),
{ have h_rpow_mono := ennreal.rpow_left_strict_mono_of_pos hp_pos,
have h_rpow_surj := (ennreal.rpow_left_bijective hp_pos.ne.symm).2,
refine (h_rpow_mono.order_iso_of_surjective _ h_rpow_surj).liminf_apply _ _ _ _,
all_goals { is_bounded_default }, },
rw h_pow_liminf,
simp_rw [snorm', ← ennreal.rpow_mul, one_div, inv_mul_cancel hp_pos.ne.symm, ennreal.rpow_one],
end
lemma snorm_exponent_top_lim_eq_ess_sup_liminf {ι} [nonempty ι] [linear_order ι] {f : ι → α → G}
{f_lim : α → G}
(h_lim : ∀ᵐ (x : α) ∂μ, tendsto (λ n, f n x) at_top (𝓝 (f_lim x))) :
snorm f_lim ∞ μ = ess_sup (λ x, at_top.liminf (λ m, (nnnorm (f m x) : ℝ≥0∞))) μ :=
begin
rw [snorm_exponent_top, snorm_ess_sup],
refine ess_sup_congr_ae (h_lim.mono (λ x hx, _)),
rw tendsto.liminf_eq,
rw ennreal.tendsto_coe,
exact (continuous_nnnorm.tendsto (f_lim x)).comp hx,
end
lemma snorm_exponent_top_lim_le_liminf_snorm_exponent_top {ι} [nonempty ι] [encodable ι]
[linear_order ι] {f : ι → α → F} {f_lim : α → F}
(h_lim : ∀ᵐ (x : α) ∂μ, tendsto (λ n, f n x) at_top (𝓝 (f_lim x))) :
snorm f_lim ∞ μ ≤ at_top.liminf (λ n, snorm (f n) ∞ μ) :=
begin
rw snorm_exponent_top_lim_eq_ess_sup_liminf h_lim,
simp_rw [snorm_exponent_top, snorm_ess_sup],
exact ennreal.ess_sup_liminf_le (λ n, (λ x, (nnnorm (f n x) : ℝ≥0∞))),
end
lemma snorm_lim_le_liminf_snorm {E} [measurable_space E] [normed_group E] [borel_space E]
{f : ℕ → α → E} (hf : ∀ n, ae_measurable (f n) μ) (f_lim : α → E)
(h_lim : ∀ᵐ (x : α) ∂μ, tendsto (λ n, f n x) at_top (𝓝 (f_lim x))) :
snorm f_lim p μ ≤ at_top.liminf (λ n, snorm (f n) p μ) :=
begin
by_cases hp0 : p = 0,
{ simp [hp0], },
rw ← ne.def at hp0,
by_cases hp_top : p = ∞,
{ simp_rw [hp_top],
exact snorm_exponent_top_lim_le_liminf_snorm_exponent_top h_lim, },
simp_rw snorm_eq_snorm' hp0 hp_top,
have hp_pos : 0 < p.to_real,
from ennreal.to_real_pos_iff.mpr ⟨lt_of_le_of_ne (zero_le _) hp0.symm, hp_top⟩,
exact snorm'_lim_le_liminf_snorm' hp_pos hf h_lim,
end
/-! ### `Lp` is complete iff Cauchy sequences of `ℒp` have limits in `ℒp` -/
lemma tendsto_Lp_iff_tendsto_ℒp' {ι} {fi : filter ι} [fact (1 ≤ p)]
(f : ι → Lp E p μ) (f_lim : Lp E p μ) :
fi.tendsto f (𝓝 f_lim) ↔ fi.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0) :=
begin
rw tendsto_iff_dist_tendsto_zero,
simp_rw dist_def,
rw [← ennreal.zero_to_real, ennreal.tendsto_to_real_iff (λ n, _) ennreal.zero_ne_top],
rw snorm_congr_ae (Lp.coe_fn_sub _ _).symm,
exact Lp.snorm_ne_top _,
end
lemma tendsto_Lp_iff_tendsto_ℒp {ι} {fi : filter ι} [fact (1 ≤ p)]
(f : ι → Lp E p μ) (f_lim : α → E) (f_lim_ℒp : mem_ℒp f_lim p μ) :
fi.tendsto f (𝓝 (f_lim_ℒp.to_Lp f_lim)) ↔ fi.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0) :=
begin
rw tendsto_Lp_iff_tendsto_ℒp',
suffices h_eq : (λ n, snorm (f n - mem_ℒp.to_Lp f_lim f_lim_ℒp) p μ)
= (λ n, snorm (f n - f_lim) p μ),
by rw h_eq,
exact funext (λ n, snorm_congr_ae (eventually_eq.rfl.sub (mem_ℒp.coe_fn_to_Lp f_lim_ℒp))),
end
lemma tendsto_Lp_iff_tendsto_ℒp'' {ι} {fi : filter ι} [fact (1 ≤ p)]
(f : ι → α → E) (f_ℒp : ∀ n, mem_ℒp (f n) p μ) (f_lim : α → E) (f_lim_ℒp : mem_ℒp f_lim p μ) :
fi.tendsto (λ n, (f_ℒp n).to_Lp (f n)) (𝓝 (f_lim_ℒp.to_Lp f_lim))
↔ fi.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0) :=
begin
convert Lp.tendsto_Lp_iff_tendsto_ℒp' _ _,
ext1 n,
apply snorm_congr_ae,
filter_upwards [((f_ℒp n).sub f_lim_ℒp).coe_fn_to_Lp,
Lp.coe_fn_sub ((f_ℒp n).to_Lp (f n)) (f_lim_ℒp.to_Lp f_lim)],
intros x hx₁ hx₂,
rw ← hx₂,
exact hx₁.symm
end
lemma tendsto_Lp_of_tendsto_ℒp {ι} {fi : filter ι} [hp : fact (1 ≤ p)]
{f : ι → Lp E p μ} (f_lim : α → E) (f_lim_ℒp : mem_ℒp f_lim p μ)
(h_tendsto : fi.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0)) :
fi.tendsto f (𝓝 (f_lim_ℒp.to_Lp f_lim)) :=
(tendsto_Lp_iff_tendsto_ℒp f f_lim f_lim_ℒp).mpr h_tendsto
lemma cauchy_seq_Lp_iff_cauchy_seq_ℒp {ι} [nonempty ι] [semilattice_sup ι] [hp : fact (1 ≤ p)]
(f : ι → Lp E p μ) :
cauchy_seq f ↔ tendsto (λ (n : ι × ι), snorm (f n.fst - f n.snd) p μ) at_top (𝓝 0) :=
begin
simp_rw [cauchy_seq_iff_tendsto_dist_at_top_0, dist_def],
rw [← ennreal.zero_to_real, ennreal.tendsto_to_real_iff (λ n, _) ennreal.zero_ne_top],
rw snorm_congr_ae (Lp.coe_fn_sub _ _).symm,
exact snorm_ne_top _,
end
lemma complete_space_Lp_of_cauchy_complete_ℒp [hp : fact (1 ≤ p)]
(H : ∀ (f : ℕ → α → E) (hf : ∀ n, mem_ℒp (f n) p μ) (B : ℕ → ℝ≥0∞) (hB : ∑' i, B i < ∞)
(h_cau : ∀ (N n m : ℕ), N ≤ n → N ≤ m → snorm (f n - f m) p μ < B N),
∃ (f_lim : α → E) (hf_lim_meas : mem_ℒp f_lim p μ),
at_top.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0)) :
complete_space (Lp E p μ) :=
begin
let B := λ n : ℕ, ((1:ℝ) / 2) ^ n,
have hB_pos : ∀ n, 0 < B n, from λ n, pow_pos (div_pos zero_lt_one zero_lt_two) n,
refine metric.complete_of_convergent_controlled_sequences B hB_pos (λ f hf, _),
suffices h_limit : ∃ (f_lim : α → E) (hf_lim_meas : mem_ℒp f_lim p μ),
at_top.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0),
{ rcases h_limit with ⟨f_lim, hf_lim_meas, h_tendsto⟩,
exact ⟨hf_lim_meas.to_Lp f_lim, tendsto_Lp_of_tendsto_ℒp f_lim hf_lim_meas h_tendsto⟩, },
have hB : summable B, from summable_geometric_two,
cases hB with M hB,
let B1 := λ n, ennreal.of_real (B n),
have hB1_has : has_sum B1 (ennreal.of_real M),
{ have h_tsum_B1 : ∑' i, B1 i = (ennreal.of_real M),
{ change (∑' (n : ℕ), ennreal.of_real (B n)) = ennreal.of_real M,
rw ←hB.tsum_eq,
exact (ennreal.of_real_tsum_of_nonneg (λ n, le_of_lt (hB_pos n)) hB.summable).symm, },
have h_sum := (@ennreal.summable _ B1).has_sum,
rwa h_tsum_B1 at h_sum, },
have hB1 : ∑' i, B1 i < ∞, by {rw hB1_has.tsum_eq, exact ennreal.of_real_lt_top, },
let f1 : ℕ → α → E := λ n, f n,
refine H f1 (λ n, Lp.mem_ℒp (f n)) B1 hB1 (λ N n m hn hm, _),
specialize hf N n m hn hm,
rw dist_def at hf,
simp_rw [f1, B1],
rwa ennreal.lt_of_real_iff_to_real_lt,
rw snorm_congr_ae (Lp.coe_fn_sub _ _).symm,
exact Lp.snorm_ne_top _,
end
/-! ### Prove that controlled Cauchy sequences of `ℒp` have limits in `ℒp` -/
private lemma snorm'_sum_norm_sub_le_tsum_of_cauchy_snorm' {f : ℕ → α → E}
(hf : ∀ n, ae_measurable (f n) μ) {p : ℝ} (hp1 : 1 ≤ p)
{B : ℕ → ℝ≥0∞} (h_cau : ∀ (N n m : ℕ), N ≤ n → N ≤ m → snorm' (f n - f m) p μ < B N) (n : ℕ) :
snorm' (λ x, ∑ i in finset.range (n + 1), norm (f (i + 1) x - f i x)) p μ ≤ ∑' i, B i :=
begin
let f_norm_diff := λ i x, norm (f (i + 1) x - f i x),
have hgf_norm_diff : ∀ n, (λ x, ∑ i in finset.range (n + 1), norm (f (i + 1) x - f i x))
= ∑ i in finset.range (n + 1), f_norm_diff i,
from λ n, funext (λ x, by simp [f_norm_diff]),
rw hgf_norm_diff,
refine (snorm'_sum_le (λ i _, ((hf (i+1)).sub (hf i)).norm) hp1).trans _,
simp_rw [←pi.sub_apply, snorm'_norm],
refine (finset.sum_le_sum _).trans (sum_le_tsum _ (λ m _, zero_le _) ennreal.summable),
exact λ m _, (h_cau m (m + 1) m (nat.le_succ m) (le_refl m)).le,
end
private lemma lintegral_rpow_sum_coe_nnnorm_sub_le_rpow_tsum {f : ℕ → α → E}
(hf : ∀ n, ae_measurable (f n) μ) {p : ℝ} (hp1 : 1 ≤ p) {B : ℕ → ℝ≥0∞} (n : ℕ)
(hn : snorm' (λ x, ∑ i in finset.range (n + 1), norm (f (i + 1) x - f i x)) p μ ≤ ∑' i, B i) :
∫⁻ a, (∑ i in finset.range (n + 1), nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ
≤ (∑' i, B i) ^ p :=
begin
have hp_pos : 0 < p := zero_lt_one.trans_le hp1,
rw [←one_div_one_div p, @ennreal.le_rpow_one_div_iff _ _ (1/p) (by simp [hp_pos]),
one_div_one_div p],
simp_rw snorm' at hn,
have h_nnnorm_nonneg :
(λ a, (nnnorm (∑ i in finset.range (n + 1), ∥f (i + 1) a - f i a∥) : ℝ≥0∞) ^ p)
= λ a, (∑ i in finset.range (n + 1), (nnnorm(f (i + 1) a - f i a) : ℝ≥0∞)) ^ p,
{ ext1 a,
congr,
simp_rw ←of_real_norm_eq_coe_nnnorm,
rw ←ennreal.of_real_sum_of_nonneg,
{ rw real.norm_of_nonneg _,
exact finset.sum_nonneg (λ x hx, norm_nonneg _), },
{ exact λ x hx, norm_nonneg _, }, },
change (∫⁻ a, (λ x, ↑(nnnorm (∑ i in finset.range (n + 1), ∥f (i+1) x - f i x∥))^p) a ∂μ)^(1/p)
≤ ∑' i, B i at hn,
rwa h_nnnorm_nonneg at hn,
end
private lemma lintegral_rpow_tsum_coe_nnnorm_sub_le_tsum {f : ℕ → α → E}
(hf : ∀ n, ae_measurable (f n) μ) {p : ℝ} (hp1 : 1 ≤ p) {B : ℕ → ℝ≥0∞}
(h : ∀ n, ∫⁻ a, (∑ i in finset.range (n + 1), nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ
≤ (∑' i, B i) ^ p) :
(∫⁻ a, (∑' i, nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ) ^ (1/p) ≤ ∑' i, B i :=
begin
have hp_pos : 0 < p := zero_lt_one.trans_le hp1,
suffices h_pow : ∫⁻ a, (∑' i, nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ ≤ (∑' i, B i) ^ p,
by rwa [←ennreal.le_rpow_one_div_iff (by simp [hp_pos] : 0 < 1 / p), one_div_one_div],
have h_tsum_1 : ∀ g : ℕ → ℝ≥0∞,
∑' i, g i = at_top.liminf (λ n, ∑ i in finset.range (n + 1), g i),
by { intro g, rw [ennreal.tsum_eq_liminf_sum_nat, ← liminf_nat_add _ 1], },
simp_rw h_tsum_1 _,
rw ← h_tsum_1,
have h_liminf_pow : ∫⁻ a, at_top.liminf (λ n, ∑ i in finset.range (n + 1),
(nnnorm (f (i + 1) a - f i a)))^p ∂μ
= ∫⁻ a, at_top.liminf (λ n, (∑ i in finset.range (n + 1), (nnnorm (f (i + 1) a - f i a)))^p) ∂μ,
{ refine lintegral_congr (λ x, _),
have h_rpow_mono := ennreal.rpow_left_strict_mono_of_pos (zero_lt_one.trans_le hp1),
have h_rpow_surj := (ennreal.rpow_left_bijective hp_pos.ne.symm).2,
refine (h_rpow_mono.order_iso_of_surjective _ h_rpow_surj).liminf_apply _ _ _ _,
all_goals { is_bounded_default }, },
rw h_liminf_pow,
refine (lintegral_liminf_le' _).trans _,
{ exact λ n, (finset.ae_measurable_sum (finset.range (n+1))
(λ i _, ((hf (i+1)).sub (hf i)).ennnorm)).pow_const _, },
{ exact liminf_le_of_frequently_le' (frequently_of_forall h), },
end
private lemma tsum_nnnorm_sub_ae_lt_top
{f : ℕ → α → E} (hf : ∀ n, ae_measurable (f n) μ) {p : ℝ} (hp1 : 1 ≤ p) {B : ℕ → ℝ≥0∞}
(hB : ∑' i, B i < ∞)
(h : (∫⁻ a, (∑' i, nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ) ^ (1/p) ≤ ∑' i, B i) :
∀ᵐ x ∂μ, (∑' i, nnnorm (f (i + 1) x - f i x) : ℝ≥0∞) < ∞ :=
begin
have hp_pos : 0 < p := zero_lt_one.trans_le hp1,
have h_integral : ∫⁻ a, (∑' i, nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ < ∞,
{ have h_tsum_lt_top : (∑' i, B i) ^ p < ∞,
from ennreal.rpow_lt_top_of_nonneg hp_pos.le (lt_top_iff_ne_top.mp hB),
refine lt_of_le_of_lt _ h_tsum_lt_top,
rwa [←ennreal.le_rpow_one_div_iff (by simp [hp_pos] : 0 < 1 / p), one_div_one_div] at h, },
have rpow_ae_lt_top : ∀ᵐ x ∂μ, (∑' i, nnnorm (f (i + 1) x - f i x) : ℝ≥0∞)^p < ∞,
{ refine ae_lt_top' (ae_measurable.pow_const _ _) h_integral,
exact ae_measurable.ennreal_tsum (λ n, ((hf (n+1)).sub (hf n)).ennnorm), },
refine rpow_ae_lt_top.mono (λ x hx, _),
rwa [←ennreal.lt_rpow_one_div_iff hp_pos,
ennreal.top_rpow_of_pos (by simp [hp_pos] : 0 < 1 / p)] at hx,
end
lemma ae_tendsto_of_cauchy_snorm' [complete_space E] {f : ℕ → α → E} {p : ℝ}
(hf : ∀ n, ae_measurable (f n) μ) (hp1 : 1 ≤ p) {B : ℕ → ℝ≥0∞} (hB : ∑' i, B i < ∞)
(h_cau : ∀ (N n m : ℕ), N ≤ n → N ≤ m → snorm' (f n - f m) p μ < B N) :
∀ᵐ x ∂μ, ∃ l : E, at_top.tendsto (λ n, f n x) (𝓝 l) :=
begin
have h_summable : ∀ᵐ x ∂μ, summable (λ (i : ℕ), f (i + 1) x - f i x),
{ have h1 : ∀ n, snorm' (λ x, ∑ i in finset.range (n + 1), norm (f (i + 1) x - f i x)) p μ
≤ ∑' i, B i,
from snorm'_sum_norm_sub_le_tsum_of_cauchy_snorm' hf hp1 h_cau,
have h2 : ∀ n, ∫⁻ a, (∑ i in finset.range (n + 1), nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ
≤ (∑' i, B i) ^ p,
from λ n, lintegral_rpow_sum_coe_nnnorm_sub_le_rpow_tsum hf hp1 n (h1 n),
have h3 : (∫⁻ a, (∑' i, nnnorm (f (i + 1) a - f i a) : ℝ≥0∞)^p ∂μ) ^ (1/p) ≤ ∑' i, B i,
from lintegral_rpow_tsum_coe_nnnorm_sub_le_tsum hf hp1 h2,
have h4 : ∀ᵐ x ∂μ, (∑' i, nnnorm (f (i + 1) x - f i x) : ℝ≥0∞) < ∞,
from tsum_nnnorm_sub_ae_lt_top hf hp1 hB h3,
exact h4.mono (λ x hx, summable_of_summable_nnnorm
(ennreal.tsum_coe_ne_top_iff_summable.mp (lt_top_iff_ne_top.mp hx))), },
have h : ∀ᵐ x ∂μ, ∃ l : E,
at_top.tendsto (λ n, ∑ i in finset.range n, (f (i + 1) x - f i x)) (𝓝 l),
{ refine h_summable.mono (λ x hx, _),
let hx_sum := hx.has_sum.tendsto_sum_nat,
exact ⟨∑' i, (f (i + 1) x - f i x), hx_sum⟩, },
refine h.mono (λ x hx, _),
cases hx with l hx,
have h_rw_sum : (λ n, ∑ i in finset.range n, (f (i + 1) x - f i x)) = λ n, f n x - f 0 x,
{ ext1 n,
change ∑ (i : ℕ) in finset.range n, ((λ m, f m x) (i + 1) - (λ m, f m x) i) = f n x - f 0 x,
rw finset.sum_range_sub, },
rw h_rw_sum at hx,
have hf_rw : (λ n, f n x) = λ n, f n x - f 0 x + f 0 x, by { ext1 n, abel, },
rw hf_rw,
exact ⟨l + f 0 x, tendsto.add_const _ hx⟩,
end
lemma ae_tendsto_of_cauchy_snorm [complete_space E] {f : ℕ → α → E}
(hf : ∀ n, ae_measurable (f n) μ) (hp : 1 ≤ p) {B : ℕ → ℝ≥0∞} (hB : ∑' i, B i < ∞)
(h_cau : ∀ (N n m : ℕ), N ≤ n → N ≤ m → snorm (f n - f m) p μ < B N) :
∀ᵐ x ∂μ, ∃ l : E, at_top.tendsto (λ n, f n x) (𝓝 l) :=
begin
by_cases hp_top : p = ∞,
{ simp_rw [hp_top] at *,
have h_cau_ae : ∀ᵐ x ∂μ, ∀ N n m, N ≤ n → N ≤ m → (nnnorm ((f n - f m) x) : ℝ≥0∞) < B N,
{ simp_rw [ae_all_iff, ae_imp_iff],
exact λ N n m hnN hmN, ae_lt_of_ess_sup_lt (h_cau N n m hnN hmN), },
simp_rw [snorm_exponent_top, snorm_ess_sup] at h_cau,
refine h_cau_ae.mono (λ x hx, cauchy_seq_tendsto_of_complete _),
refine cauchy_seq_of_le_tendsto_0 (λ n, (B n).to_real) _ _,
{ intros n m N hnN hmN,
specialize hx N n m hnN hmN,
rw [dist_eq_norm, ←ennreal.to_real_of_real (norm_nonneg _),
ennreal.to_real_le_to_real ennreal.of_real_ne_top
((ennreal.ne_top_of_tsum_ne_top (lt_top_iff_ne_top.mp hB)) N)],
rw ←of_real_norm_eq_coe_nnnorm at hx,
exact hx.le, },
{ rw ← ennreal.zero_to_real,
exact tendsto.comp (ennreal.tendsto_to_real ennreal.zero_ne_top)
(ennreal.tendsto_at_top_zero_of_tsum_lt_top hB), }, },
have hp1 : 1 ≤ p.to_real,
{ rw [← ennreal.of_real_le_iff_le_to_real hp_top, ennreal.of_real_one],
exact hp, },
have h_cau' : ∀ (N n m : ℕ), N ≤ n → N ≤ m → snorm' (f n - f m) (p.to_real) μ < B N,
{ intros N n m hn hm,
specialize h_cau N n m hn hm,
rwa snorm_eq_snorm' (ennreal.zero_lt_one.trans_le hp).ne.symm hp_top at h_cau, },
exact ae_tendsto_of_cauchy_snorm' hf hp1 hB h_cau',
end
lemma cauchy_tendsto_of_tendsto {f : ℕ → α → E} (hf : ∀ n, ae_measurable (f n) μ)
(f_lim : α → E) {B : ℕ → ℝ≥0∞}
(hB : ∑' i, B i < ∞) (h_cau : ∀ (N n m : ℕ), N ≤ n → N ≤ m → snorm (f n - f m) p μ < B N)
(h_lim : ∀ᵐ (x : α) ∂μ, tendsto (λ n, f n x) at_top (𝓝 (f_lim x))) :
at_top.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0) :=
begin
rw ennreal.tendsto_at_top_zero,
intros ε hε,
have h_B : ∃ (N : ℕ), B N ≤ ε,
{ suffices h_tendsto_zero : ∃ (N : ℕ), ∀ n : ℕ, N ≤ n → B n ≤ ε,
from ⟨h_tendsto_zero.some, h_tendsto_zero.some_spec _ (le_refl _)⟩,
exact (ennreal.tendsto_at_top_zero.mp (ennreal.tendsto_at_top_zero_of_tsum_lt_top hB))
ε hε, },
cases h_B with N h_B,
refine ⟨N, λ n hn, _⟩,
have h_sub : snorm (f n - f_lim) p μ ≤ at_top.liminf (λ m, snorm (f n - f m) p μ),
{ refine snorm_lim_le_liminf_snorm (λ m, (hf n).sub (hf m)) (f n - f_lim) _,
refine h_lim.mono (λ x hx, _),
simp_rw sub_eq_add_neg,
exact tendsto.add tendsto_const_nhds (tendsto.neg hx), },
refine h_sub.trans _,
refine liminf_le_of_frequently_le' (frequently_at_top.mpr _),
refine λ N1, ⟨max N N1, le_max_right _ _, _⟩,
exact (h_cau N n (max N N1) hn (le_max_left _ _)).le.trans h_B,
end
lemma mem_ℒp_of_cauchy_tendsto (hp : 1 ≤ p) {f : ℕ → α → E} (hf : ∀ n, mem_ℒp (f n) p μ)
(f_lim : α → E) (h_lim_meas : ae_measurable f_lim μ)
(h_tendsto : at_top.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0)) :
mem_ℒp f_lim p μ :=
begin
refine ⟨h_lim_meas, _⟩,
rw ennreal.tendsto_at_top_zero at h_tendsto,
cases (h_tendsto 1 ennreal.zero_lt_one) with N h_tendsto_1,
specialize h_tendsto_1 N (le_refl N),
have h_add : f_lim = f_lim - f N + f N, by abel,
rw h_add,
refine lt_of_le_of_lt (snorm_add_le (h_lim_meas.sub (hf N).1) (hf N).1 hp) _,
rw ennreal.add_lt_top,
split,
{ refine lt_of_le_of_lt _ ennreal.one_lt_top,
have h_neg : f_lim - f N = -(f N - f_lim), by simp,
rwa [h_neg, snorm_neg], },
{ exact (hf N).2, },
end
lemma cauchy_complete_ℒp [complete_space E] (hp : 1 ≤ p)
{f : ℕ → α → E} (hf : ∀ n, mem_ℒp (f n) p μ) {B : ℕ → ℝ≥0∞} (hB : ∑' i, B i < ∞)
(h_cau : ∀ (N n m : ℕ), N ≤ n → N ≤ m → snorm (f n - f m) p μ < B N) :
∃ (f_lim : α → E) (hf_lim_meas : mem_ℒp f_lim p μ),
at_top.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0) :=
begin
obtain ⟨f_lim, h_f_lim_meas, h_lim⟩ : ∃ (f_lim : α → E) (hf_lim_meas : measurable f_lim),
∀ᵐ x ∂μ, tendsto (λ n, f n x) at_top (nhds (f_lim x)),
from measurable_limit_of_tendsto_metric_ae (λ n, (hf n).1)
(ae_tendsto_of_cauchy_snorm (λ n, (hf n).1) hp hB h_cau),
have h_tendsto' : at_top.tendsto (λ n, snorm (f n - f_lim) p μ) (𝓝 0),
from cauchy_tendsto_of_tendsto (λ m, (hf m).1) f_lim hB h_cau h_lim,
have h_ℒp_lim : mem_ℒp f_lim p μ,
from mem_ℒp_of_cauchy_tendsto hp hf f_lim h_f_lim_meas.ae_measurable h_tendsto',
exact ⟨f_lim, h_ℒp_lim, h_tendsto'⟩,
end
/-! ### `Lp` is complete for `1 ≤ p` -/
instance [complete_space E] [hp : fact (1 ≤ p)] : complete_space (Lp E p μ) :=
complete_space_Lp_of_cauchy_complete_ℒp (λ f hf B hB h_cau, cauchy_complete_ℒp hp.elim hf hB h_cau)
end Lp
end measure_theory
end complete_space
/-! ### Continuous functions in `Lp` -/
open_locale bounded_continuous_function
open bounded_continuous_function
variables [borel_space E] [second_countable_topology E] [topological_space α] [borel_space α]
variables (E p μ)
/-- An additive subgroup of `Lp E p μ`, consisting of the equivalence classes which contain a
bounded continuous representative. -/
def measure_theory.Lp.bounded_continuous_function : add_subgroup (Lp E p μ) :=
add_subgroup.add_subgroup_of
((continuous_map.to_ae_eq_fun_add_hom μ).comp (forget_boundedness_add_hom α E)).range
(Lp E p μ)
variables {E p μ}
/-- By definition, the elements of `Lp.bounded_continuous_function E p μ` are the elements of
`Lp E p μ` which contain a bounded continuous representative. -/
lemma measure_theory.Lp.mem_bounded_continuous_function_iff {f : (Lp E p μ)} :
f ∈ measure_theory.Lp.bounded_continuous_function E p μ
↔ ∃ f₀ : (α →ᵇ E), f₀.to_continuous_map.to_ae_eq_fun μ = (f : α →ₘ[μ] E) :=
add_subgroup.mem_add_subgroup_of
namespace bounded_continuous_function
variables [is_finite_measure μ]
/-- A bounded continuous function on a finite-measure space is in `Lp`. -/
lemma mem_Lp (f : α →ᵇ E) :
f.to_continuous_map.to_ae_eq_fun μ ∈ Lp E p μ :=
begin
refine Lp.mem_Lp_of_ae_bound (∥f∥) _,
filter_upwards [f.to_continuous_map.coe_fn_to_ae_eq_fun μ],
intros x hx,
convert f.norm_coe_le_norm x
end
/-- The `Lp`-norm of a bounded continuous function is at most a constant (depending on the measure
of the whole space) times its sup-norm. -/
lemma Lp_norm_le (f : α →ᵇ E) :
∥(⟨f.to_continuous_map.to_ae_eq_fun μ, mem_Lp f⟩ : Lp E p μ)∥
≤ (measure_univ_nnreal μ) ^ (p.to_real)⁻¹ * ∥f∥ :=
begin
apply Lp.norm_le_of_ae_bound (norm_nonneg f),
{ refine (f.to_continuous_map.coe_fn_to_ae_eq_fun μ).mono _,
intros x hx,
convert f.norm_coe_le_norm x },
{ apply_instance }
end
variables (p μ)
/-- The normed group homomorphism of considering a bounded continuous function on a finite-measure
space as an element of `Lp`. -/
def to_Lp_hom [fact (1 ≤ p)] : normed_group_hom (α →ᵇ E) (Lp E p μ) :=
{ bound' := ⟨_, Lp_norm_le⟩,
.. add_monoid_hom.cod_restrict
((continuous_map.to_ae_eq_fun_add_hom μ).comp (forget_boundedness_add_hom α E))
(Lp E p μ)
mem_Lp }
lemma range_to_Lp_hom [fact (1 ≤ p)] :
((to_Lp_hom p μ).range : add_subgroup (Lp E p μ))
= measure_theory.Lp.bounded_continuous_function E p μ :=
begin
symmetry,
convert add_monoid_hom.add_subgroup_of_range_eq_of_le
((continuous_map.to_ae_eq_fun_add_hom μ).comp (forget_boundedness_add_hom α E))
(by { rintros - ⟨f, rfl⟩, exact mem_Lp f } : _ ≤ Lp E p μ),
end
variables (𝕜 : Type*) [measurable_space 𝕜]
/-- The bounded linear map of considering a bounded continuous function on a finite-measure space
as an element of `Lp`. -/
def to_Lp [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E] [fact (1 ≤ p)] :
(α →ᵇ E) →L[𝕜] (Lp E p μ) :=
linear_map.mk_continuous
(linear_map.cod_restrict
(Lp.Lp_submodule E p μ 𝕜)
((continuous_map.to_ae_eq_fun_linear_map μ).comp (forget_boundedness_linear_map α E 𝕜))
mem_Lp)
_
Lp_norm_le
variables {𝕜}
lemma range_to_Lp [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E] [fact (1 ≤ p)] :
((to_Lp p μ 𝕜).range.to_add_subgroup : add_subgroup (Lp E p μ))
= measure_theory.Lp.bounded_continuous_function E p μ :=
range_to_Lp_hom p μ
variables {p}
lemma coe_fn_to_Lp [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E] [fact (1 ≤ p)]
(f : α →ᵇ E) :
to_Lp p μ 𝕜 f =ᵐ[μ] f :=
ae_eq_fun.coe_fn_mk f _
lemma to_Lp_norm_le [nondiscrete_normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E]
[fact (1 ≤ p)] :
∥(to_Lp p μ 𝕜 : (α →ᵇ E) →L[𝕜] (Lp E p μ))∥ ≤ (measure_univ_nnreal μ) ^ (p.to_real)⁻¹ :=
linear_map.mk_continuous_norm_le _ ((measure_univ_nnreal μ) ^ (p.to_real)⁻¹).coe_nonneg _
end bounded_continuous_function
namespace continuous_map
variables [compact_space α] [is_finite_measure μ]
variables (𝕜 : Type*) [measurable_space 𝕜] (p μ) [fact (1 ≤ p)]
/-- The bounded linear map of considering a continuous function on a compact finite-measure
space `α` as an element of `Lp`. By definition, the norm on `C(α, E)` is the sup-norm, transferred
from the space `α →ᵇ E` of bounded continuous functions, so this construction is just a matter of
transferring the structure from `bounded_continuous_function.to_Lp` along the isometry. -/
def to_Lp [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E] :
C(α, E) →L[𝕜] (Lp E p μ) :=
(bounded_continuous_function.to_Lp p μ 𝕜).comp
(linear_isometry_bounded_of_compact α E 𝕜).to_linear_isometry.to_continuous_linear_map
variables {𝕜}
lemma range_to_Lp [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E] :
((to_Lp p μ 𝕜).range.to_add_subgroup : add_subgroup (Lp E p μ))
= measure_theory.Lp.bounded_continuous_function E p μ :=
begin
refine set_like.ext' _,
have := (linear_isometry_bounded_of_compact α E 𝕜).surjective,
convert function.surjective.range_comp this (bounded_continuous_function.to_Lp p μ 𝕜),
rw ← bounded_continuous_function.range_to_Lp p μ,
refl,
end
variables {p}
lemma coe_fn_to_Lp [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E] (f : C(α, E)) :
to_Lp p μ 𝕜 f =ᵐ[μ] f :=
ae_eq_fun.coe_fn_mk f _
lemma to_Lp_def [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E] (f : C(α, E)) :
to_Lp p μ 𝕜 f
= bounded_continuous_function.to_Lp p μ 𝕜 (linear_isometry_bounded_of_compact α E 𝕜 f) :=
rfl
@[simp] lemma to_Lp_comp_forget_boundedness [normed_field 𝕜] [opens_measurable_space 𝕜]
[normed_space 𝕜 E] (f : α →ᵇ E) :
to_Lp p μ 𝕜 (bounded_continuous_function.forget_boundedness α E f)
= bounded_continuous_function.to_Lp p μ 𝕜 f :=
rfl
@[simp] lemma coe_to_Lp [normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E]
(f : C(α, E)) :
(to_Lp p μ 𝕜 f : α →ₘ[μ] E) = f.to_ae_eq_fun μ :=
rfl
variables [nondiscrete_normed_field 𝕜] [opens_measurable_space 𝕜] [normed_space 𝕜 E]
lemma to_Lp_norm_eq_to_Lp_norm_coe :
∥(to_Lp p μ 𝕜 : C(α, E) →L[𝕜] (Lp E p μ))∥
= ∥(bounded_continuous_function.to_Lp p μ 𝕜 : (α →ᵇ E) →L[𝕜] (Lp E p μ))∥ :=
continuous_linear_map.op_norm_comp_linear_isometry_equiv _ _
/-- Bound for the operator norm of `continuous_map.to_Lp`. -/
lemma to_Lp_norm_le :
∥(to_Lp p μ 𝕜 : C(α, E) →L[𝕜] (Lp E p μ))∥ ≤ (measure_univ_nnreal μ) ^ (p.to_real)⁻¹ :=
by { rw to_Lp_norm_eq_to_Lp_norm_coe, exact bounded_continuous_function.to_Lp_norm_le μ }
end continuous_map
--(to_Lp p μ 𝕜 : (α →ᵇ E) →L[𝕜] (Lp E p μ))
|
96c129726e1f3591402f7a172667a56eb5103b30 | 3446e92e64a5de7ed1f2109cfb024f83cd904c34 | /src/game/world4/level5.lean | 17de4a1172d0631ba9aa5ea0412d5c4fffb5bd4d | [] | no_license | kckennylau/natural_number_game | 019f4a5f419c9681e65234ecd124c564f9a0a246 | ad8c0adaa725975be8a9f978c8494a39311029be | refs/heads/master | 1,598,784,137,722 | 1,571,905,156,000 | 1,571,905,156,000 | 218,354,686 | 0 | 0 | null | 1,572,373,319,000 | 1,572,373,318,000 | null | UTF-8 | Lean | false | false | 443 | lean | import game.world4.level4 -- hide
namespace mynat -- hide
/-
# World 4 : Power World
## Level 5 of 7: `pow_add`
-/
/- Lemma
For all naturals $m$, $a$, $b$, we have $m ^{a + b} = m ^ a m ^ b$.
-/
lemma pow_add (m a b : mynat) : m ^ (a + b) = m ^ a * m ^ b :=
begin [less_leaky]
induction b with t ht,
rw [add_zero, pow_zero, mul_one],
refl,
rw [add_succ, pow_succ, pow_succ, ht, mul_assoc],
refl,
end
end mynat -- hide
|
1b3f4b31beaf83bd62e3d1bd8135a344da46df03 | 4bcaca5dc83d49803f72b7b5920b75b6e7d9de2d | /stage0/src/Lean/Elab/BuiltinCommand.lean | f97dde69921665164021665df4eb1e52fa9862aa | [
"Apache-2.0"
] | permissive | subfish-zhou/leanprover-zh_CN.github.io | 30b9fba9bd790720bd95764e61ae796697d2f603 | 8b2985d4a3d458ceda9361ac454c28168d920d3f | refs/heads/master | 1,689,709,967,820 | 1,632,503,056,000 | 1,632,503,056,000 | 409,962,097 | 1 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 13,872 | lean | /-
Copyright (c) 2021 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
import Lean.DocString
import Lean.Elab.Command
import Lean.Elab.Open
namespace Lean.Elab.Command
@[builtinCommandElab moduleDoc] def elabModuleDoc : CommandElab := fun stx =>
match stx[1] with
| Syntax.atom _ val =>
let doc := val.extract 0 (val.bsize - 2)
modifyEnv fun env => addMainModuleDoc env doc
| _ => throwErrorAt stx "unexpected module doc string{indentD stx[1]}"
private def addScope (isNewNamespace : Bool) (header : String) (newNamespace : Name) : CommandElabM Unit := do
modify fun s => { s with
env := s.env.registerNamespace newNamespace,
scopes := { s.scopes.head! with header := header, currNamespace := newNamespace } :: s.scopes
}
pushScope
if isNewNamespace then
activateScoped newNamespace
private def addScopes (isNewNamespace : Bool) : Name → CommandElabM Unit
| Name.anonymous => pure ()
| Name.str p header _ => do
addScopes isNewNamespace p
let currNamespace ← getCurrNamespace
addScope isNewNamespace header (if isNewNamespace then Name.mkStr currNamespace header else currNamespace)
| _ => throwError "invalid scope"
private def addNamespace (header : Name) : CommandElabM Unit :=
addScopes (isNewNamespace := true) header
def withNamespace {α} (ns : Name) (elabFn : CommandElabM α) : CommandElabM α := do
addNamespace ns
let a ← elabFn
modify fun s => { s with scopes := s.scopes.drop ns.getNumParts }
pure a
private def popScopes (numScopes : Nat) : CommandElabM Unit :=
for i in [0:numScopes] do
popScope
private def checkAnonymousScope : List Scope → Bool
| { header := "", .. } :: _ => true
| _ => false
private def checkEndHeader : Name → List Scope → Bool
| Name.anonymous, _ => true
| Name.str p s _, { header := h, .. } :: scopes => h == s && checkEndHeader p scopes
| _, _ => false
@[builtinCommandElab «namespace»] def elabNamespace : CommandElab := fun stx =>
match stx with
| `(namespace $n) => addNamespace n.getId
| _ => throwUnsupportedSyntax
@[builtinCommandElab «section»] def elabSection : CommandElab := fun stx =>
match stx with
| `(section $header:ident) => addScopes (isNewNamespace := false) header.getId
| `(section) => do let currNamespace ← getCurrNamespace; addScope (isNewNamespace := false) "" currNamespace
| _ => throwUnsupportedSyntax
@[builtinCommandElab «end»] def elabEnd : CommandElab := fun stx => do
let header? := (stx.getArg 1).getOptionalIdent?;
let endSize := match header? with
| none => 1
| some n => n.getNumParts
let scopes ← getScopes
if endSize < scopes.length then
modify fun s => { s with scopes := s.scopes.drop endSize }
popScopes endSize
else -- we keep "root" scope
let n := (← get).scopes.length - 1
modify fun s => { s with scopes := s.scopes.drop n }
popScopes n
throwError "invalid 'end', insufficient scopes"
match header? with
| none =>
unless checkAnonymousScope scopes do
throwError "invalid 'end', name is missing"
| some header =>
unless checkEndHeader header scopes do
addCompletionInfo <| CompletionInfo.endSection stx (scopes.map fun scope => scope.header)
throwError "invalid 'end', name mismatch"
private partial def elabChoiceAux (cmds : Array Syntax) (i : Nat) : CommandElabM Unit :=
if h : i < cmds.size then
let cmd := cmds.get ⟨i, h⟩;
catchInternalId unsupportedSyntaxExceptionId
(elabCommand cmd)
(fun ex => elabChoiceAux cmds (i+1))
else
throwUnsupportedSyntax
@[builtinCommandElab choice] def elbChoice : CommandElab := fun stx =>
elabChoiceAux stx.getArgs 0
@[builtinCommandElab «universe»] def elabUniverse : CommandElab := fun n => do
n[1].forArgsM addUnivLevel
@[builtinCommandElab «init_quot»] def elabInitQuot : CommandElab := fun stx => do
match (← getEnv).addDecl Declaration.quotDecl with
| Except.ok env => setEnv env
| Except.error ex => throwError (ex.toMessageData (← getOptions))
@[builtinCommandElab «export»] def elabExport : CommandElab := fun stx => do
-- `stx` is of the form (Command.export "export" <namespace> "(" (null <ids>*) ")")
let id := stx[1].getId
let ns ← resolveNamespace id
let currNamespace ← getCurrNamespace
if ns == currNamespace then throwError "invalid 'export', self export"
let env ← getEnv
let ids := stx[3].getArgs
let aliases ← ids.foldlM (init := []) fun (aliases : List (Name × Name)) (idStx : Syntax) => do
let id := idStx.getId
let declName ← resolveOpenDeclId ns idStx
pure <| (currNamespace ++ id, declName) :: aliases
modify fun s => { s with env := aliases.foldl (init := s.env) fun env p => addAlias env p.1 p.2 }
@[builtinCommandElab «open»] def elabOpen : CommandElab := fun n => do
let openDecls ← elabOpenDecl n[1]
modifyScope fun scope => { scope with openDecls := openDecls }
private def typelessBinder? : Syntax → Option (Array Name × Bool)
| `(bracketedBinder|($ids*)) => some <| (ids.map Syntax.getId, true)
| `(bracketedBinder|{$ids*}) => some <| (ids.map Syntax.getId, false)
| _ => none
-- This function is used to implement the `variable` command that updates binder annotations.
private def matchBinderNames (ids : Array Syntax) (binderNames : Array Name) : CommandElabM Bool :=
let ids := ids.map Syntax.getId
/-
TODO: allow users to update the annotation of some of the ids.
The current application supports the common case
```
variable (α : Type)
...
variable {α : Type}
```
-/
if ids == binderNames then
return true
else if binderNames.any ids.contains then
/- We currently do not split binder blocks. -/
throwError "failed to update variable binder annotation" -- TODO: improve error message
else
return false
/--
Auxiliary method for processing binder annotation update commands: `variable (α)` and `variable {α}`.
The argument `binder` is the binder of the `variable` command.
The method retuns `true` if the binder annotation was updated.
Remark: we currently do not suppor updates of the form
```
variable (α β : Type)
...
variable {α} -- trying to update part of the binder block defined above.
```
-/
private def replaceBinderAnnotation (binder : Syntax) : CommandElabM Bool := do
if let some (binderNames, explicit) := typelessBinder? binder then
let varDecls := (← getScope).varDecls
let mut varDeclsNew := #[]
let mut found := false
for varDecl in varDecls do
if let some (ids, ty?, annot?) :=
match varDecl with
| `(bracketedBinder|($ids* $[: $ty?]? $(annot?)?)) => some (ids, ty?, annot?)
| `(bracketedBinder|{$ids* $[: $ty?]?}) => some (ids, ty?, none)
| `(bracketedBinder|[$id : $ty]) => some (#[id], some ty, none)
| _ => none
then
if (← matchBinderNames ids binderNames) then
if annot?.isSome then
throwError "cannot update binder annotation of variables with default values/tactics"
if explicit then
varDeclsNew := varDeclsNew.push (← `(bracketedBinder| ($ids* $[: $ty?]?)))
else
varDeclsNew := varDeclsNew.push (← `(bracketedBinder| {$ids* $[: $ty?]?}))
found := true
else
varDeclsNew := varDeclsNew.push varDecl
else
varDeclsNew := varDeclsNew.push varDecl
if found then
modifyScope fun scope => { scope with varDecls := varDeclsNew }
return true
else
return false
else
return false
@[builtinCommandElab «variable»] def elabVariable : CommandElab
| `(variable $binders*) => do
-- Try to elaborate `binders` for sanity checking
runTermElabM none fun _ => Term.withAutoBoundImplicit <|
Term.elabBinders binders fun _ => pure ()
for binder in binders do
unless (← replaceBinderAnnotation binder) do
let varUIds ← getBracketedBinderIds binder |>.mapM (withFreshMacroScope ∘ MonadQuotation.addMacroScope)
modifyScope fun scope => { scope with varDecls := scope.varDecls.push binder, varUIds := scope.varUIds ++ varUIds }
| _ => throwUnsupportedSyntax
open Meta
@[builtinCommandElab Lean.Parser.Command.check] def elabCheck : CommandElab
| `(#check%$tk $term) => withoutModifyingEnv $ runTermElabM (some `_check) fun _ => do
let e ← Term.elabTerm term none
Term.synthesizeSyntheticMVarsNoPostponing
let (e, _) ← Term.levelMVarToParam (← instantiateMVars e)
let type ← inferType e
unless e.isSyntheticSorry do
logInfoAt tk m!"{e} : {type}"
| _ => throwUnsupportedSyntax
@[builtinCommandElab Lean.Parser.Command.reduce] def elabReduce : CommandElab
| `(#reduce%$tk $term) => withoutModifyingEnv <| runTermElabM (some `_check) fun _ => do
let e ← Term.elabTerm term none
Term.synthesizeSyntheticMVarsNoPostponing
let (e, _) ← Term.levelMVarToParam (← instantiateMVars e)
-- TODO: add options or notation for setting the following parameters
withTheReader Core.Context (fun ctx => { ctx with options := ctx.options.setBool `smartUnfolding false }) do
let e ← withTransparency (mode := TransparencyMode.all) <| reduce e (skipProofs := false) (skipTypes := false)
logInfoAt tk e
| _ => throwUnsupportedSyntax
def hasNoErrorMessages : CommandElabM Bool := do
return !(← get).messages.hasErrors
def failIfSucceeds (x : CommandElabM Unit) : CommandElabM Unit := do
let resetMessages : CommandElabM MessageLog := do
let s ← get
let messages := s.messages;
modify fun s => { s with messages := {} };
pure messages
let restoreMessages (prevMessages : MessageLog) : CommandElabM Unit := do
modify fun s => { s with messages := prevMessages ++ s.messages.errorsToWarnings }
let prevMessages ← resetMessages
let succeeded ←
try
x
hasNoErrorMessages
catch
| ex@(Exception.error _ _) => do logException ex; pure false
| Exception.internal id _ => do logError (← id.getName); pure false
finally
restoreMessages prevMessages
if succeeded then
throwError "unexpected success"
@[builtinCommandElab «check_failure»] def elabCheckFailure : CommandElab
| `(#check_failure $term) => do
failIfSucceeds <| elabCheck (← `(#check $term))
| _ => throwUnsupportedSyntax
unsafe def elabEvalUnsafe : CommandElab
| `(#eval%$tk $term) => do
let n := `_eval
let ctx ← read
let addAndCompile (value : Expr) : TermElabM Unit := do
let type ← inferType value
let decl := Declaration.defnDecl {
name := n
levelParams := []
type := type
value := value
hints := ReducibilityHints.opaque
safety := DefinitionSafety.unsafe
}
Term.ensureNoUnassignedMVars decl
addAndCompile decl
let elabEvalTerm : TermElabM Expr := do
let e ← Term.elabTerm term none
Term.synthesizeSyntheticMVarsNoPostponing
if (← isProp e) then
mkDecide e
else
return e
let elabMetaEval : CommandElabM Unit := runTermElabM (some n) fun _ => do
let e ← elabEvalTerm
let e ← withLocalDeclD `env (mkConst ``Lean.Environment) fun env =>
withLocalDeclD `opts (mkConst ``Lean.Options) fun opts => do
let e ← mkAppM ``Lean.runMetaEval #[env, opts, e];
mkLambdaFVars #[env, opts] e
let env ← getEnv
let opts ← getOptions
let act ← try addAndCompile e; evalConst (Environment → Options → IO (String × Except IO.Error Environment)) n finally setEnv env
let (out, res) ← act env opts -- we execute `act` using the environment
logInfoAt tk out
match res with
| Except.error e => throwError e.toString
| Except.ok env => do setEnv env; pure ()
let elabEval : CommandElabM Unit := runTermElabM (some n) fun _ => do
-- fall back to non-meta eval if MetaEval hasn't been defined yet
-- modify e to `runEval e`
let e ← elabEvalTerm
let e := mkSimpleThunk e
let e ← mkAppM ``Lean.runEval #[e]
let env ← getEnv
let act ← try addAndCompile e; evalConst (IO (String × Except IO.Error Unit)) n finally setEnv env
let (out, res) ← liftM (m := IO) act
logInfoAt tk out
match res with
| Except.error e => throwError e.toString
| Except.ok _ => pure ()
if (← getEnv).contains ``Lean.MetaEval then do
elabMetaEval
else
elabEval
| _ => throwUnsupportedSyntax
@[builtinCommandElab «eval», implementedBy elabEvalUnsafe]
constant elabEval : CommandElab
@[builtinCommandElab «synth»] def elabSynth : CommandElab := fun stx => do
let term := stx[1]
withoutModifyingEnv <| runTermElabM `_synth_cmd fun _ => do
let inst ← Term.elabTerm term none
Term.synthesizeSyntheticMVarsNoPostponing
let inst ← instantiateMVars inst
let val ← synthInstance inst
logInfo val
pure ()
@[builtinCommandElab «set_option»] def elabSetOption : CommandElab := fun stx => do
let options ← Elab.elabSetOption stx[1] stx[2]
modify fun s => { s with maxRecDepth := maxRecDepth.get options }
modifyScope fun scope => { scope with opts := options }
@[builtinMacro Lean.Parser.Command.«in»] def expandInCmd : Macro := fun stx => do
let cmd₁ := stx[0]
let cmd₂ := stx[2]
`(section $cmd₁:command $cmd₂:command end)
end Lean.Elab.Command
|
a1a23190bbcf647fc43d78fd5734d592e470c6b6 | 55c7fc2bf55d496ace18cd6f3376e12bb14c8cc5 | /src/geometry/manifold/charted_space.lean | 6ef4de254ef1df7699da0b09b530712bf0a2d0c9 | [
"Apache-2.0"
] | permissive | dupuisf/mathlib | 62de4ec6544bf3b79086afd27b6529acfaf2c1bb | 8582b06b0a5d06c33ee07d0bdf7c646cae22cf36 | refs/heads/master | 1,669,494,854,016 | 1,595,692,409,000 | 1,595,692,409,000 | 272,046,630 | 0 | 0 | Apache-2.0 | 1,592,066,143,000 | 1,592,066,142,000 | null | UTF-8 | Lean | false | false | 43,253 | lean | /-
Copyright (c) 2019 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import topology.local_homeomorph
/-!
# Charted spaces
A smooth manifold is a topological space `M` locally modelled on a euclidean space (or a euclidean
half-space for manifolds with boundaries, or an infinite dimensional vector space for more general
notions of manifolds), i.e., the manifold is covered by open subsets on which there are local
homeomorphisms (the charts) going to a model space `H`, and the changes of charts should be smooth
maps.
In this file, we introduce a general framework describing these notions, where the model space is an
arbitrary topological space. We avoid the word *manifold*, which should be reserved for the
situation where the model space is a (subset of a) vector space, and use the terminology
*charted space* instead.
If the changes of charts satisfy some additional property (for instance if they are smooth), then
`M` inherits additional structure (it makes sense to talk about smooth manifolds). There are
therefore two different ingredients in a charted space:
* the set of charts, which is data
* the fact that changes of charts belong to some group (in fact groupoid), which is additional Prop.
We separate these two parts in the definition: the charted space structure is just the set of
charts, and then the different smoothness requirements (smooth manifold, orientable manifold,
contact manifold, and so on) are additional properties of these charts. These properties are
formalized through the notion of structure groupoid, i.e., a set of local homeomorphisms stable
under composition and inverse, to which the change of coordinates should belong.
## Main definitions
* `structure_groupoid H` : a subset of local homeomorphisms of `H` stable under composition,
inverse and restriction (ex: local diffeos).
* `continuous_groupoid H` : the groupoid of all local homeomorphisms of `H`
* `charted_space H M` : charted space structure on `M` modelled on `H`, given by an atlas of
local homeomorphisms from `M` to `H` whose sources cover `M`. This is a type class.
* `has_groupoid M G` : when `G` is a structure groupoid on `H` and `M` is a charted space
modelled on `H`, require that all coordinate changes belong to `G`. This is a type class.
* `atlas H M` : when `M` is a charted space modelled on `H`, the atlas of this charted
space structure, i.e., the set of charts.
* `G.maximal_atlas M` : when `M` is a charted space modelled on `H` and admitting `G` as a
structure groupoid, one can consider all the local homeomorphisms from `M` to `H` such that
changing coordinate from any chart to them belongs to `G`. This is a larger atlas, called the
maximal atlas (for the groupoid `G`).
* `structomorph G M M'` : the type of diffeomorphisms between the charted spaces `M` and `M'` for
the groupoid `G`. We avoid the word diffeomorphism, keeping it for the smooth category.
As a basic example, we give the instance
`instance charted_space_model_space (H : Type*) [topological_space H] : charted_space H H`
saying that a topological space is a charted space over itself, with the identity as unique chart.
This charted space structure is compatible with any groupoid.
Additional useful definitions:
* `pregroupoid H` : a subset of local mas of `H` stable under composition and
restriction, but not inverse (ex: smooth maps)
* `groupoid_of_pregroupoid` : construct a groupoid from a pregroupoid, by requiring that a map and
its inverse both belong to the pregroupoid (ex: construct diffeos from smooth maps)
* `chart_at H x` is a preferred chart at `x : M` when `M` has a charted space structure modelled on
`H`.
* `G.compatible he he'` states that, for any two charts `e` and `e'` in the atlas, the composition
of `e.symm` and `e'` belongs to the groupoid `G` when `M` admits `G` as a structure groupoid.
* `G.compatible_of_mem_maximal_atlas he he'` states that, for any two charts `e` and `e'` in the
maximal atlas associated to the groupoid `G`, the composition of `e.symm` and `e'` belongs to the
`G` if `M` admits `G` as a structure groupoid.
* `charted_space_core.to_charted_space`: consider a space without a topology, but endowed with a set
of charts (which are local equivs) for which the change of coordinates are local homeos. Then
one can construct a topology on the space for which the charts become local homeos, defining
a genuine charted space structure.
## Implementation notes
The atlas in a charted space is *not* a maximal atlas in general: the notion of maximality depends
on the groupoid one considers, and changing groupoids changes the maximal atlas. With the current
formalization, it makes sense first to choose the atlas, and then to ask whether this precise atlas
defines a smooth manifold, an orientable manifold, and so on. A consequence is that structomorphisms
between `M` and `M'` do *not* induce a bijection between the atlases of `M` and `M'`: the
definition is only that, read in charts, the structomorphism locally belongs to the groupoid under
consideration. (This is equivalent to inducing a bijection between elements of the maximal atlas).
A consequence is that the invariance under structomorphisms of properties defined in terms of the
atlas is not obvious in general, and could require some work in theory (amounting to the fact
that these properties only depend on the maximal atlas, for instance). In practice, this does not
create any real difficulty.
We use the letter `H` for the model space thinking of the case of manifolds with boundary, where the
model space is a half space.
Manifolds are sometimes defined as topological spaces with an atlas of local diffeomorphisms, and
sometimes as spaces with an atlas from which a topology is deduced. We use the former approach:
otherwise, there would be an instance from manifolds to topological spaces, which means that any
instance search for topological spaces would try to find manifold structures involving a yet
unknown model space, leading to problems. However, we also introduce the latter approach,
through a structure `charted_space_core` making it possible to construct a topology out of a set of
local equivs with compatibility conditions (but we do not register it as an instance).
In the definition of a charted space, the model space is written as an explicit parameter as there
can be several model spaces for a given topological space. For instance, a complex manifold
(modelled over `ℂ^n`) will also be seen sometimes as a real manifold modelled over `ℝ^(2n)`.
## Notations
In the locale `manifold`, we denote the composition of local homeomorphisms with `≫ₕ`, and the
composition of local equivs with `≫`.
-/
noncomputable theory
open_locale classical
universes u
variables {H : Type u} {H' : Type*} {M : Type*} {M' : Type*} {M'' : Type*}
/- Notational shortcut for the composition of local homeomorphisms and local equivs, i.e.,
`local_homeomorph.trans` and `local_equiv.trans`.
Note that, as is usual for equivs, the composition is from left to right, hence the direction of
the arrow. -/
localized "infixr ` ≫ₕ `:100 := local_homeomorph.trans" in manifold
localized "infixr ` ≫ `:100 := local_equiv.trans" in manifold
open set local_homeomorph
/-! ### Structure groupoids-/
section groupoid
/-! One could add to the definition of a structure groupoid the fact that the restriction of an
element of the groupoid to any open set still belongs to the groupoid.
(This is in Kobayashi-Nomizu.)
I am not sure I want this, for instance on `H × E` where `E` is a vector space, and the groupoid is
made of functions respecting the fibers and linear in the fibers (so that a charted space over this
groupoid is naturally a vector bundle) I prefer that the members of the groupoid are always
defined on sets of the form `s × E`. There is a typeclass `closed_under_restriction` for groupoids
which have the restriction property.
The only nontrivial requirement is locality: if a local homeomorphism belongs to the groupoid
around each point in its domain of definition, then it belongs to the groupoid. Without this
requirement, the composition of structomorphisms does not have to be a structomorphism. Note that
this implies that a local homeomorphism with empty source belongs to any structure groupoid, as
it trivially satisfies this condition.
There is also a technical point, related to the fact that a local homeomorphism is by definition a
global map which is a homeomorphism when restricted to its source subset (and its values outside
of the source are not relevant). Therefore, we also require that being a member of the groupoid only
depends on the values on the source.
We use primes in the structure names as we will reformulate them below (without primes) using a
`has_mem` instance, writing `e ∈ G` instead of `e ∈ G.members`.
-/
/-- A structure groupoid is a set of local homeomorphisms of a topological space stable under
composition and inverse. They appear in the definition of the smoothness class of a manifold. -/
structure structure_groupoid (H : Type u) [topological_space H] :=
(members : set (local_homeomorph H H))
(trans' : ∀e e' : local_homeomorph H H, e ∈ members → e' ∈ members → e ≫ₕ e' ∈ members)
(symm' : ∀e : local_homeomorph H H, e ∈ members → e.symm ∈ members)
(id_mem' : local_homeomorph.refl H ∈ members)
(locality' : ∀e : local_homeomorph H H, (∀x ∈ e.source, ∃s, is_open s ∧
x ∈ s ∧ e.restr s ∈ members) → e ∈ members)
(eq_on_source' : ∀ e e' : local_homeomorph H H, e ∈ members → e' ≈ e → e' ∈ members)
variable [topological_space H]
instance : has_mem (local_homeomorph H H) (structure_groupoid H) :=
⟨λ(e : local_homeomorph H H) (G : structure_groupoid H), e ∈ G.members⟩
lemma structure_groupoid.trans (G : structure_groupoid H) {e e' : local_homeomorph H H}
(he : e ∈ G) (he' : e' ∈ G) : e ≫ₕ e' ∈ G :=
G.trans' e e' he he'
lemma structure_groupoid.symm (G : structure_groupoid H) {e : local_homeomorph H H} (he : e ∈ G) :
e.symm ∈ G :=
G.symm' e he
lemma structure_groupoid.id_mem (G : structure_groupoid H) :
local_homeomorph.refl H ∈ G :=
G.id_mem'
lemma structure_groupoid.locality (G : structure_groupoid H) {e : local_homeomorph H H}
(h : ∀x ∈ e.source, ∃s, is_open s ∧ x ∈ s ∧ e.restr s ∈ G) :
e ∈ G :=
G.locality' e h
lemma structure_groupoid.eq_on_source (G : structure_groupoid H) {e e' : local_homeomorph H H}
(he : e ∈ G) (h : e' ≈ e) : e' ∈ G :=
G.eq_on_source' e e' he h
/-- Partial order on the set of groupoids, given by inclusion of the members of the groupoid -/
instance structure_groupoid.partial_order : partial_order (structure_groupoid H) :=
partial_order.lift structure_groupoid.members
(λa b h, by { cases a, cases b, dsimp at h, induction h, refl })
lemma structure_groupoid.le_iff {G₁ G₂ : structure_groupoid H} :
G₁ ≤ G₂ ↔ ∀ e, e ∈ G₁ → e ∈ G₂ :=
iff.rfl
/-- The trivial groupoid, containing only the identity (and maps with empty source, as this is
necessary from the definition) -/
def id_groupoid (H : Type u) [topological_space H] : structure_groupoid H :=
{ members := {local_homeomorph.refl H} ∪ {e : local_homeomorph H H | e.source = ∅},
trans' := λe e' he he', begin
cases he; simp at he he',
{ simpa only [he, refl_trans]},
{ have : (e ≫ₕ e').source ⊆ e.source := sep_subset _ _,
rw he at this,
have : (e ≫ₕ e') ∈ {e : local_homeomorph H H | e.source = ∅} := disjoint_iff.1 this,
exact (mem_union _ _ _).2 (or.inr this) },
end,
symm' := λe he, begin
cases (mem_union _ _ _).1 he with E E,
{ finish },
{ right,
simpa only [e.to_local_equiv.image_source_eq_target.symm] with mfld_simps using E},
end,
id_mem' := mem_union_left _ rfl,
locality' := λe he, begin
cases e.source.eq_empty_or_nonempty with h h,
{ right, exact h },
{ left,
rcases h with ⟨x, hx⟩,
rcases he x hx with ⟨s, open_s, xs, hs⟩,
have x's : x ∈ (e.restr s).source,
{ rw [restr_source, interior_eq_of_open open_s],
exact ⟨hx, xs⟩ },
cases hs,
{ replace hs : local_homeomorph.restr e s = local_homeomorph.refl H,
by simpa only using hs,
have : (e.restr s).source = univ, by { rw hs, simp },
change (e.to_local_equiv).source ∩ interior s = univ at this,
have : univ ⊆ interior s, by { rw ← this, exact inter_subset_right _ _ },
have : s = univ, by rwa [interior_eq_of_open open_s, univ_subset_iff] at this,
simpa only [this, restr_univ] using hs },
{ exfalso,
rw mem_set_of_eq at hs,
rwa hs at x's } },
end,
eq_on_source' := λe e' he he'e, begin
cases he,
{ left,
have : e = e',
{ refine eq_of_eq_on_source_univ (setoid.symm he'e) _ _;
rw set.mem_singleton_iff.1 he ; refl },
rwa ← this },
{ right,
change (e.to_local_equiv).source = ∅ at he,
rwa [set.mem_set_of_eq, he'e.source_eq] }
end }
/-- Every structure groupoid contains the identity groupoid -/
instance : order_bot (structure_groupoid H) :=
{ bot := id_groupoid H,
bot_le := begin
assume u f hf,
change f ∈ {local_homeomorph.refl H} ∪ {e : local_homeomorph H H | e.source = ∅} at hf,
simp only [singleton_union, mem_set_of_eq, mem_insert_iff] at hf,
cases hf,
{ rw hf,
apply u.id_mem },
{ apply u.locality,
assume x hx,
rw [hf, mem_empty_eq] at hx,
exact hx.elim }
end,
..structure_groupoid.partial_order }
instance (H : Type u) [topological_space H] : inhabited (structure_groupoid H) :=
⟨id_groupoid H⟩
/-- To construct a groupoid, one may consider classes of local homeos such that both the function
and its inverse have some property. If this property is stable under composition,
one gets a groupoid. `pregroupoid` bundles the properties needed for this construction, with the
groupoid of smooth functions with smooth inverses as an application. -/
structure pregroupoid (H : Type*) [topological_space H] :=
(property : (H → H) → (set H) → Prop)
(comp : ∀{f g u v}, property f u → property g v → is_open u → is_open v → is_open (u ∩ f ⁻¹' v)
→ property (g ∘ f) (u ∩ f ⁻¹' v))
(id_mem : property id univ)
(locality : ∀{f u}, is_open u → (∀x∈u, ∃v, is_open v ∧ x ∈ v ∧ property f (u ∩ v)) → property f u)
(congr : ∀{f g : H → H} {u}, is_open u → (∀x∈u, g x = f x) → property f u → property g u)
/-- Construct a groupoid of local homeos for which the map and its inverse have some property,
from a pregroupoid asserting that this property is stable under composition. -/
def pregroupoid.groupoid (PG : pregroupoid H) : structure_groupoid H :=
{ members := {e : local_homeomorph H H | PG.property e e.source ∧ PG.property e.symm e.target},
trans' := λe e' he he', begin
split,
{ apply PG.comp he.1 he'.1 e.open_source e'.open_source,
apply e.continuous_to_fun.preimage_open_of_open e.open_source e'.open_source },
{ apply PG.comp he'.2 he.2 e'.open_target e.open_target,
apply e'.continuous_inv_fun.preimage_open_of_open e'.open_target e.open_target }
end,
symm' := λe he, ⟨he.2, he.1⟩,
id_mem' := ⟨PG.id_mem, PG.id_mem⟩,
locality' := λe he, begin
split,
{ apply PG.locality e.open_source (λx xu, _),
rcases he x xu with ⟨s, s_open, xs, hs⟩,
refine ⟨s, s_open, xs, _⟩,
convert hs.1,
exact (interior_eq_of_open s_open).symm },
{ apply PG.locality e.open_target (λx xu, _),
rcases he (e.symm x) (e.map_target xu) with ⟨s, s_open, xs, hs⟩,
refine ⟨e.target ∩ e.symm ⁻¹' s, _, ⟨xu, xs⟩, _⟩,
{ exact continuous_on.preimage_open_of_open e.continuous_inv_fun e.open_target s_open },
{ rw [← inter_assoc, inter_self],
convert hs.2,
exact (interior_eq_of_open s_open).symm } },
end,
eq_on_source' := λe e' he ee', begin
split,
{ apply PG.congr e'.open_source ee'.2,
simp only [ee'.1, he.1] },
{ have A := ee'.symm',
apply PG.congr e'.symm.open_source A.2,
convert he.2,
rw A.1,
refl }
end }
lemma mem_groupoid_of_pregroupoid {PG : pregroupoid H} {e : local_homeomorph H H} :
e ∈ PG.groupoid ↔ PG.property e e.source ∧ PG.property e.symm e.target :=
iff.rfl
lemma groupoid_of_pregroupoid_le (PG₁ PG₂ : pregroupoid H)
(h : ∀f s, PG₁.property f s → PG₂.property f s) : PG₁.groupoid ≤ PG₂.groupoid :=
begin
refine structure_groupoid.le_iff.2 (λ e he, _),
rw mem_groupoid_of_pregroupoid at he ⊢,
exact ⟨h _ _ he.1, h _ _ he.2⟩
end
lemma mem_pregroupoid_of_eq_on_source (PG : pregroupoid H) {e e' : local_homeomorph H H}
(he' : e ≈ e') (he : PG.property e e.source) : PG.property e' e'.source :=
begin
rw ← he'.1,
exact PG.congr e.open_source he'.eq_on.symm he,
end
/-- The pregroupoid of all local maps on a topological space `H` -/
@[reducible] def continuous_pregroupoid (H : Type*) [topological_space H] : pregroupoid H :=
{ property := λf s, true,
comp := λf g u v hf hg hu hv huv, trivial,
id_mem := trivial,
locality := λf u u_open h, trivial,
congr := λf g u u_open hcongr hf, trivial }
instance (H : Type*) [topological_space H] : inhabited (pregroupoid H) :=
⟨continuous_pregroupoid H⟩
/-- The groupoid of all local homeomorphisms on a topological space `H` -/
def continuous_groupoid (H : Type*) [topological_space H] : structure_groupoid H :=
pregroupoid.groupoid (continuous_pregroupoid H)
/-- Every structure groupoid is contained in the groupoid of all local homeomorphisms -/
instance : order_top (structure_groupoid H) :=
{ top := continuous_groupoid H,
le_top := λ u f hf, by { split; exact dec_trivial },
..structure_groupoid.partial_order }
/-- A groupoid is closed under restriction if it contains all restrictions of its element local
homeomorphisms to open subsets of the source. -/
class closed_under_restriction (G : structure_groupoid H) : Prop :=
(closed_under_restriction : ∀ {e : local_homeomorph H H}, e ∈ G → ∀ (s : set H), is_open s →
e.restr s ∈ G)
lemma closed_under_restriction' {G : structure_groupoid H} [closed_under_restriction G]
{e : local_homeomorph H H} (he : e ∈ G) {s : set H} (hs : is_open s) :
e.restr s ∈ G :=
closed_under_restriction.closed_under_restriction he s hs
/-- The trivial restriction-closed groupoid, containing only local homeomorphisms equivalent to the
restriction of the identity to the various open subsets. -/
def id_restr_groupoid : structure_groupoid H :=
{ members := {e | ∃ {s : set H} (h : is_open s), e ≈ local_homeomorph.of_set s h},
trans' := begin
rintros e e' ⟨s, hs, hse⟩ ⟨s', hs', hse'⟩,
refine ⟨s ∩ s', is_open_inter hs hs', _⟩,
have := local_homeomorph.eq_on_source.trans' hse hse',
rwa local_homeomorph.of_set_trans_of_set at this,
end,
symm' := begin
rintros e ⟨s, hs, hse⟩,
refine ⟨s, hs, _⟩,
rw [← of_set_symm],
exact local_homeomorph.eq_on_source.symm' hse,
end,
id_mem' := ⟨univ, is_open_univ, by simp only with mfld_simps⟩,
locality' := begin
intros e h,
refine ⟨e.source, e.open_source, by simp only with mfld_simps, _⟩,
intros x hx,
rcases h x hx with ⟨s, hs, hxs, s', hs', hes'⟩,
have hes : x ∈ (e.restr s).source,
{ rw e.restr_source, refine ⟨hx, _⟩,
rw interior_eq_of_open hs, exact hxs },
simpa only with mfld_simps using local_homeomorph.eq_on_source.eq_on hes' hes,
end,
eq_on_source' := begin
rintros e e' ⟨s, hs, hse⟩ hee',
exact ⟨s, hs, setoid.trans hee' hse⟩,
end
}
lemma id_restr_groupoid_mem {s : set H} (hs : is_open s) :
of_set s hs ∈ @id_restr_groupoid H _ := ⟨s, hs, by refl⟩
/-- The trivial restriction-closed groupoid is indeed `closed_under_restriction`. -/
instance closed_under_restriction_id_restr_groupoid :
closed_under_restriction (@id_restr_groupoid H _) :=
⟨ begin
rintros e ⟨s', hs', he⟩ s hs,
use [s' ∩ s, is_open_inter hs' hs],
refine setoid.trans (local_homeomorph.eq_on_source.restr he s) _,
exact ⟨by simp only [interior_eq_of_open hs] with mfld_simps, by simp only with mfld_simps⟩,
end ⟩
/-- A groupoid is closed under restriction if and only if it contains the trivial restriction-closed
groupoid. -/
lemma closed_under_restriction_iff_id_le (G : structure_groupoid H) :
closed_under_restriction G ↔ id_restr_groupoid ≤ G :=
begin
split,
{ introsI _i,
apply structure_groupoid.le_iff.mpr,
rintros e ⟨s, hs, hes⟩,
refine G.eq_on_source _ hes,
convert closed_under_restriction' G.id_mem hs,
rw interior_eq_of_open hs,
simp only with mfld_simps },
{ intros h,
split,
intros e he s hs,
rw ← of_set_trans (e : local_homeomorph H H) hs,
refine G.trans _ he,
apply structure_groupoid.le_iff.mp h,
exact id_restr_groupoid_mem hs },
end
/-- The groupoid of all local homeomorphisms on a topological space `H` is closed under restriction.
-/
instance : closed_under_restriction (continuous_groupoid H) :=
(closed_under_restriction_iff_id_le _).mpr (by convert le_top)
end groupoid
/-! ### Charted spaces -/
/-- A charted space is a topological space endowed with an atlas, i.e., a set of local
homeomorphisms taking value in a model space `H`, called charts, such that the domains of the charts
cover the whole space. We express the covering property by chosing for each `x` a member
`chart_at H x` of the atlas containing `x` in its source: in the smooth case, this is convenient to
construct the tangent bundle in an efficient way.
The model space is written as an explicit parameter as there can be several model spaces for a
given topological space. For instance, a complex manifold (modelled over `ℂ^n`) will also be seen
sometimes as a real manifold over `ℝ^(2n)`.
-/
class charted_space (H : Type*) [topological_space H] (M : Type*) [topological_space M] :=
(atlas [] : set (local_homeomorph M H))
(chart_at [] : M → local_homeomorph M H)
(mem_chart_source [] : ∀x, x ∈ (chart_at x).source)
(chart_mem_atlas [] : ∀x, chart_at x ∈ atlas)
export charted_space
attribute [simp, mfld_simps] mem_chart_source chart_mem_atlas
section charted_space
/-- Any space is a charted_space modelled over itself, by just using the identity chart -/
instance charted_space_self (H : Type*) [topological_space H] : charted_space H H :=
{ atlas := {local_homeomorph.refl H},
chart_at := λx, local_homeomorph.refl H,
mem_chart_source := λx, mem_univ x,
chart_mem_atlas := λx, mem_singleton _ }
/-- In the trivial charted_space structure of a space modelled over itself through the identity, the
atlas members are just the identity -/
@[simp, mfld_simps] lemma charted_space_self_atlas
{H : Type*} [topological_space H] {e : local_homeomorph H H} :
e ∈ atlas H H ↔ e = local_homeomorph.refl H :=
by simp [atlas, charted_space.atlas]
/-- In the model space, chart_at is always the identity -/
@[simp, mfld_simps] lemma chart_at_self_eq {H : Type*} [topological_space H] {x : H} :
chart_at H x = local_homeomorph.refl H :=
by simpa using chart_mem_atlas H x
/-- Same thing as `H × H'`. We introduce it for technical reasons: a charted space `M` with model `H`
is a set of local charts from `M` to `H` covering the space. Every space is registered as a charted
space over itself, using the only chart `id`, in `manifold_model_space`. You can also define a product
of charted space `M` and `M'` (with model space `H × H'`) by taking the products of the charts. Now,
on `H × H'`, there are two charted space structures with model space `H × H'` itself, the one coming
from `manifold_model_space`, and the one coming from the product of the two `manifold_model_space` on
each component. They are equal, but not defeq (because the product of `id` and `id` is not defeq to
`id`), which is bad as we know. This expedient of renaming `H × H'` solves this problem. -/
def model_prod (H : Type*) (H' : Type*) := H × H'
section
local attribute [reducible] model_prod
instance model_prod_inhabited {α β : Type*} [inhabited α] [inhabited β] :
inhabited (model_prod α β) :=
⟨(default α, default β)⟩
instance (H : Type*) [topological_space H] (H' : Type*) [topological_space H'] :
topological_space (model_prod H H') :=
by apply_instance
/- Next lemma shows up often when dealing with derivatives, register it as simp. -/
@[simp, mfld_simps] lemma model_prod_range_prod_id
{H : Type*} {H' : Type*} {α : Type*} (f : H → α) :
range (λ (p : model_prod H H'), (f p.1, p.2)) = set.prod (range f) univ :=
by rw prod_range_univ_eq
end
/-- The product of two charted spaces is naturally a charted space, with the canonical
construction of the atlas of product maps. -/
instance prod_charted_space (H : Type*) [topological_space H]
(M : Type*) [topological_space M] [charted_space H M]
(H' : Type*) [topological_space H']
(M' : Type*) [topological_space M'] [charted_space H' M'] :
charted_space (model_prod H H') (M × M') :=
{ atlas :=
{f : (local_homeomorph (M×M') (model_prod H H')) |
∃ g ∈ charted_space.atlas H M, ∃ h ∈ (charted_space.atlas H' M'),
f = local_homeomorph.prod g h},
chart_at := λ x: (M × M'),
(charted_space.chart_at H x.1).prod (charted_space.chart_at H' x.2),
mem_chart_source :=
begin
intro x,
simp only with mfld_simps,
end,
chart_mem_atlas :=
begin
intro x,
use (charted_space.chart_at H x.1),
split,
{ apply chart_mem_atlas _, },
{ use (charted_space.chart_at H' x.2), simp only [chart_mem_atlas, eq_self_iff_true, and_self], }
end }
section prod_charted_space
variables [topological_space H] [topological_space M] [charted_space H M]
[topological_space H'] [topological_space M'] [charted_space H' M'] {x : M×M'}
@[simp, mfld_simps] lemma prod_charted_space_chart_at :
(chart_at (model_prod H H') x) = (chart_at H x.fst).prod (chart_at H' x.snd) := rfl
end prod_charted_space
end charted_space
/-! ### Constructing a topology from an atlas -/
/-- Sometimes, one may want to construct a charted space structure on a space which does not yet
have a topological structure, where the topology would come from the charts. For this, one needs
charts that are only local equivs, and continuity properties for their composition.
This is formalised in `charted_space_core`. -/
@[nolint has_inhabited_instance]
structure charted_space_core (H : Type*) [topological_space H] (M : Type*) :=
(atlas : set (local_equiv M H))
(chart_at : M → local_equiv M H)
(mem_chart_source : ∀x, x ∈ (chart_at x).source)
(chart_mem_atlas : ∀x, chart_at x ∈ atlas)
(open_source : ∀e e' : local_equiv M H, e ∈ atlas → e' ∈ atlas → is_open (e.symm.trans e').source)
(continuous_to_fun : ∀e e' : local_equiv M H, e ∈ atlas → e' ∈ atlas →
continuous_on (e.symm.trans e') (e.symm.trans e').source)
namespace charted_space_core
variables [topological_space H] (c : charted_space_core H M) {e : local_equiv M H}
/-- Topology generated by a set of charts on a Type. -/
protected def to_topological_space : topological_space M :=
topological_space.generate_from $ ⋃ (e : local_equiv M H) (he : e ∈ c.atlas)
(s : set H) (s_open : is_open s), {e ⁻¹' s ∩ e.source}
lemma open_source' (he : e ∈ c.atlas) : @is_open M c.to_topological_space e.source :=
begin
apply topological_space.generate_open.basic,
simp only [exists_prop, mem_Union, mem_singleton_iff],
refine ⟨e, he, univ, is_open_univ, _⟩,
simp only [set.univ_inter, set.preimage_univ]
end
lemma open_target (he : e ∈ c.atlas) : is_open e.target :=
begin
have E : e.target ∩ e.symm ⁻¹' e.source = e.target :=
subset.antisymm (inter_subset_left _ _) (λx hx, ⟨hx,
local_equiv.target_subset_preimage_source _ hx⟩),
simpa [local_equiv.trans_source, E] using c.open_source e e he he
end
/-- An element of the atlas in a charted space without topology becomes a local homeomorphism
for the topology constructed from this atlas. The `local_homeomorph` version is given in this
definition. -/
def local_homeomorph (e : local_equiv M H) (he : e ∈ c.atlas) :
@local_homeomorph M H c.to_topological_space _ :=
{ open_source := by convert c.open_source' he,
open_target := by convert c.open_target he,
continuous_to_fun := begin
letI : topological_space M := c.to_topological_space,
rw continuous_on_open_iff (c.open_source' he),
assume s s_open,
rw inter_comm,
apply topological_space.generate_open.basic,
simp only [exists_prop, mem_Union, mem_singleton_iff],
exact ⟨e, he, ⟨s, s_open, rfl⟩⟩
end,
continuous_inv_fun := begin
letI : topological_space M := c.to_topological_space,
apply continuous_on_open_of_generate_from (c.open_target he),
assume t ht,
simp only [exists_prop, mem_Union, mem_singleton_iff] at ht,
rcases ht with ⟨e', e'_atlas, s, s_open, ts⟩,
rw ts,
let f := e.symm.trans e',
have : is_open (f ⁻¹' s ∩ f.source),
by simpa [inter_comm] using (continuous_on_open_iff (c.open_source e e' he e'_atlas)).1
(c.continuous_to_fun e e' he e'_atlas) s s_open,
have A : e' ∘ e.symm ⁻¹' s ∩ (e.target ∩ e.symm ⁻¹' e'.source) =
e.target ∩ (e' ∘ e.symm ⁻¹' s ∩ e.symm ⁻¹' e'.source),
by { rw [← inter_assoc, ← inter_assoc], congr' 1, exact inter_comm _ _ },
simpa [local_equiv.trans_source, preimage_inter, preimage_comp.symm, A] using this
end,
..e }
/-- Given a charted space without topology, endow it with a genuine charted space structure with
respect to the topology constructed from the atlas. -/
def to_charted_space : @charted_space H _ M c.to_topological_space :=
{ atlas := ⋃ (e : local_equiv M H) (he : e ∈ c.atlas), {c.local_homeomorph e he},
chart_at := λx, c.local_homeomorph (c.chart_at x) (c.chart_mem_atlas x),
mem_chart_source := λx, c.mem_chart_source x,
chart_mem_atlas := λx, begin
simp only [mem_Union, mem_singleton_iff],
exact ⟨c.chart_at x, c.chart_mem_atlas x, rfl⟩,
end }
end charted_space_core
/-! ### Charted space with a given structure groupoid -/
section has_groupoid
variables [topological_space H] [topological_space M] [charted_space H M]
/-- A charted space has an atlas in a groupoid `G` if the change of coordinates belong to the
groupoid -/
class has_groupoid {H : Type*} [topological_space H] (M : Type*) [topological_space M]
[charted_space H M] (G : structure_groupoid H) : Prop :=
(compatible [] : ∀{e e' : local_homeomorph M H}, e ∈ atlas H M → e' ∈ atlas H M → e.symm ≫ₕ e' ∈ G)
/-- Reformulate in the `structure_groupoid` namespace the compatibility condition of charts in a
charted space admitting a structure groupoid, to make it more easily accessible with dot
notation. -/
lemma structure_groupoid.compatible {H : Type*} [topological_space H] (G : structure_groupoid H)
{M : Type*} [topological_space M] [charted_space H M] [has_groupoid M G]
{e e' : local_homeomorph M H} (he : e ∈ atlas H M) (he' : e' ∈ atlas H M) :
e.symm ≫ₕ e' ∈ G :=
has_groupoid.compatible G he he'
lemma has_groupoid_of_le {G₁ G₂ : structure_groupoid H} (h : has_groupoid M G₁) (hle : G₁ ≤ G₂) :
has_groupoid M G₂ :=
⟨ λ e e' he he', hle ((h.compatible : _) he he') ⟩
lemma has_groupoid_of_pregroupoid (PG : pregroupoid H)
(h : ∀{e e' : local_homeomorph M H}, e ∈ atlas H M → e' ∈ atlas H M
→ PG.property (e.symm ≫ₕ e') (e.symm ≫ₕ e').source) :
has_groupoid M (PG.groupoid) :=
⟨assume e e' he he', mem_groupoid_of_pregroupoid.mpr ⟨h he he', h he' he⟩⟩
/-- The trivial charted space structure on the model space is compatible with any groupoid -/
instance has_groupoid_model_space (H : Type*) [topological_space H] (G : structure_groupoid H) :
has_groupoid H G :=
{ compatible := λe e' he he', begin
replace he : e ∈ atlas H H := he,
replace he' : e' ∈ atlas H H := he',
rw charted_space_self_atlas at he he',
simp [he, he', structure_groupoid.id_mem]
end }
/-- Any charted space structure is compatible with the groupoid of all local homeomorphisms -/
instance has_groupoid_continuous_groupoid : has_groupoid M (continuous_groupoid H) :=
⟨begin
assume e e' he he',
rw [continuous_groupoid, mem_groupoid_of_pregroupoid],
simp only [and_self]
end⟩
section maximal_atlas
variables (M) (G : structure_groupoid H)
/-- Given a charted space admitting a structure groupoid, the maximal atlas associated to this
structure groupoid is the set of all local charts that are compatible with the atlas, i.e., such
that changing coordinates with an atlas member gives an element of the groupoid. -/
def structure_groupoid.maximal_atlas : set (local_homeomorph M H) :=
{e | ∀ e' ∈ atlas H M, e.symm ≫ₕ e' ∈ G ∧ e'.symm ≫ₕ e ∈ G}
variable {M}
/-- The elements of the atlas belong to the maximal atlas for any structure groupoid -/
lemma structure_groupoid.mem_maximal_atlas_of_mem_atlas [has_groupoid M G]
{e : local_homeomorph M H} (he : e ∈ atlas H M) : e ∈ G.maximal_atlas M :=
λ e' he', ⟨G.compatible he he', G.compatible he' he⟩
lemma structure_groupoid.chart_mem_maximal_atlas [has_groupoid M G]
(x : M) : chart_at H x ∈ G.maximal_atlas M :=
G.mem_maximal_atlas_of_mem_atlas (chart_mem_atlas H x)
variable {G}
lemma mem_maximal_atlas_iff {e : local_homeomorph M H} :
e ∈ G.maximal_atlas M ↔ ∀ e' ∈ atlas H M, e.symm ≫ₕ e' ∈ G ∧ e'.symm ≫ₕ e ∈ G :=
iff.rfl
/-- Changing coordinates between two elements of the maximal atlas gives rise to an element
of the structure groupoid. -/
lemma structure_groupoid.compatible_of_mem_maximal_atlas {e e' : local_homeomorph M H}
(he : e ∈ G.maximal_atlas M) (he' : e' ∈ G.maximal_atlas M) : e.symm ≫ₕ e' ∈ G :=
begin
apply G.locality (λ x hx, _),
set f := chart_at H (e.symm x) with hf,
let s := e.target ∩ (e.symm ⁻¹' f.source),
have hs : is_open s,
{ apply e.symm.continuous_to_fun.preimage_open_of_open; apply open_source },
have xs : x ∈ s, by { dsimp at hx, simp [s, hx] },
refine ⟨s, hs, xs, _⟩,
have A : e.symm ≫ₕ f ∈ G := (mem_maximal_atlas_iff.1 he f (chart_mem_atlas _ _)).1,
have B : f.symm ≫ₕ e' ∈ G := (mem_maximal_atlas_iff.1 he' f (chart_mem_atlas _ _)).2,
have C : (e.symm ≫ₕ f) ≫ₕ (f.symm ≫ₕ e') ∈ G := G.trans A B,
have D : (e.symm ≫ₕ f) ≫ₕ (f.symm ≫ₕ e') ≈ (e.symm ≫ₕ e').restr s := calc
(e.symm ≫ₕ f) ≫ₕ (f.symm ≫ₕ e') = e.symm ≫ₕ (f ≫ₕ f.symm) ≫ₕ e' : by simp [trans_assoc]
... ≈ e.symm ≫ₕ (of_set f.source f.open_source) ≫ₕ e' :
by simp [eq_on_source.trans', trans_self_symm]
... ≈ (e.symm ≫ₕ (of_set f.source f.open_source)) ≫ₕ e' : by simp [trans_assoc]
... ≈ (e.symm.restr s) ≫ₕ e' : by simp [s, trans_of_set']
... ≈ (e.symm ≫ₕ e').restr s : by simp [restr_trans],
exact G.eq_on_source C (setoid.symm D),
end
variable (G)
/-- In the model space, the identity is in any maximal atlas. -/
lemma structure_groupoid.id_mem_maximal_atlas : local_homeomorph.refl H ∈ G.maximal_atlas H :=
G.mem_maximal_atlas_of_mem_atlas (by simp)
end maximal_atlas
section singleton
variables {α : Type*} [topological_space α]
variables (e : local_homeomorph α H)
/-- If a single local homeomorphism `e` from a space `α` into `H` has source covering the whole
space `α`, then that local homeomorphism induces an `H`-charted space structure on `α`.
(This condition is equivalent to `e` being an open embedding of `α` into `H`; see
`local_homeomorph.to_open_embedding` and `open_embedding.to_local_homeomorph`.) -/
def singleton_charted_space (h : e.source = set.univ) : charted_space H α :=
{ atlas := {e},
chart_at := λ _, e,
mem_chart_source := λ _, by simp only [h] with mfld_simps,
chart_mem_atlas := λ _, by tauto }
lemma singleton_charted_space_one_chart (h : e.source = set.univ) (e' : local_homeomorph α H)
(h' : e' ∈ (singleton_charted_space e h).atlas) : e' = e := h'
/-- Given a local homeomorphism `e` from a space `α` into `H`, if its source covers the whole
space `α`, then the induced charted space structure on `α` is `has_groupoid G` for any structure
groupoid `G` which is closed under restrictions. -/
lemma singleton_has_groupoid (h : e.source = set.univ) (G : structure_groupoid H)
[closed_under_restriction G] : @has_groupoid _ _ _ _ (singleton_charted_space e h) G :=
{ compatible := begin
intros e' e'' he' he'',
rw singleton_charted_space_one_chart e h e' he',
rw singleton_charted_space_one_chart e h e'' he'',
refine G.eq_on_source _ e.trans_symm_self,
have hle : id_restr_groupoid ≤ G := (closed_under_restriction_iff_id_le G).mp (by assumption),
exact structure_groupoid.le_iff.mp hle _ (id_restr_groupoid_mem _),
end }
end singleton
namespace topological_space.opens
open topological_space
variables (G : structure_groupoid H) [has_groupoid M G]
variables (s : opens M)
/-- An open subset of a charted space is naturally a charted space. -/
instance : charted_space H s :=
{ atlas := ⋃ (x : s), {@local_homeomorph.subtype_restr _ _ _ _ (chart_at H x.1) s ⟨x⟩},
chart_at := λ x, @local_homeomorph.subtype_restr _ _ _ _ (chart_at H x.1) s ⟨x⟩,
mem_chart_source := λ x, by { simp only with mfld_simps, exact (mem_chart_source H x.1) },
chart_mem_atlas := λ x, by { simp only [mem_Union, mem_singleton_iff], use x } }
/-- If a groupoid `G` is `closed_under_restriction`, then an open subset of a space which is
`has_groupoid G` is naturally `has_groupoid G`. -/
instance [closed_under_restriction G] : has_groupoid s G :=
{ compatible := begin
rintros e e' ⟨_, ⟨x, hc⟩, he⟩ ⟨_, ⟨x', hc'⟩, he'⟩,
haveI : nonempty s := ⟨x⟩,
simp only [hc.symm, mem_singleton_iff, subtype.val_eq_coe] at he,
simp only [hc'.symm, mem_singleton_iff, subtype.val_eq_coe] at he',
rw [he, he'],
convert G.eq_on_source _ (subtype_restr_symm_trans_subtype_restr s (chart_at H x) (chart_at H x')),
apply closed_under_restriction',
{ exact G.compatible (chart_mem_atlas H x) (chart_mem_atlas H x') },
{ exact preimage_open_of_open_symm (chart_at H x) s.2 },
end }
end topological_space.opens
/-! ### Structomorphisms -/
/-- A `G`-diffeomorphism between two charted spaces is a homeomorphism which, when read in the
charts, belongs to `G`. We avoid the word diffeomorph as it is too related to the smooth category,
and use structomorph instead. -/
@[nolint has_inhabited_instance]
structure structomorph (G : structure_groupoid H) (M : Type*) (M' : Type*)
[topological_space M] [topological_space M'] [charted_space H M] [charted_space H M']
extends homeomorph M M' :=
(mem_groupoid : ∀c : local_homeomorph M H, ∀c' : local_homeomorph M' H,
c ∈ atlas H M → c' ∈ atlas H M' → c.symm ≫ₕ to_homeomorph.to_local_homeomorph ≫ₕ c' ∈ G)
variables [topological_space M'] [topological_space M'']
{G : structure_groupoid H} [charted_space H M'] [charted_space H M'']
/-- The identity is a diffeomorphism of any charted space, for any groupoid. -/
def structomorph.refl (M : Type*) [topological_space M] [charted_space H M]
[has_groupoid M G] : structomorph G M M :=
{ mem_groupoid := λc c' hc hc', begin
change (local_homeomorph.symm c) ≫ₕ (local_homeomorph.refl M) ≫ₕ c' ∈ G,
rw local_homeomorph.refl_trans,
exact has_groupoid.compatible G hc hc'
end,
..homeomorph.refl M }
/-- The inverse of a structomorphism is a structomorphism -/
def structomorph.symm (e : structomorph G M M') : structomorph G M' M :=
{ mem_groupoid := begin
assume c c' hc hc',
have : (c'.symm ≫ₕ e.to_homeomorph.to_local_homeomorph ≫ₕ c).symm ∈ G :=
G.symm (e.mem_groupoid c' c hc' hc),
rwa [trans_symm_eq_symm_trans_symm, trans_symm_eq_symm_trans_symm, symm_symm, trans_assoc]
at this,
end,
..e.to_homeomorph.symm}
/-- The composition of structomorphisms is a structomorphism -/
def structomorph.trans (e : structomorph G M M') (e' : structomorph G M' M'') : structomorph G M M'' :=
{ mem_groupoid := begin
/- Let c and c' be two charts in M and M''. We want to show that e' ∘ e is smooth in these
charts, around any point x. For this, let y = e (c⁻¹ x), and consider a chart g around y.
Then g ∘ e ∘ c⁻¹ and c' ∘ e' ∘ g⁻¹ are both smooth as e and e' are structomorphisms, so
their composition is smooth, and it coincides with c' ∘ e' ∘ e ∘ c⁻¹ around x. -/
assume c c' hc hc',
refine G.locality (λx hx, _),
let f₁ := e.to_homeomorph.to_local_homeomorph,
let f₂ := e'.to_homeomorph.to_local_homeomorph,
let f := (e.to_homeomorph.trans e'.to_homeomorph).to_local_homeomorph,
have feq : f = f₁ ≫ₕ f₂ := homeomorph.trans_to_local_homeomorph _ _,
-- define the atlas g around y
let y := (c.symm ≫ₕ f₁) x,
let g := chart_at H y,
have hg₁ := chart_mem_atlas H y,
have hg₂ := mem_chart_source H y,
let s := (c.symm ≫ₕ f₁).source ∩ (c.symm ≫ₕ f₁) ⁻¹' g.source,
have open_s : is_open s,
by apply (c.symm ≫ₕ f₁).continuous_to_fun.preimage_open_of_open; apply open_source,
have : x ∈ s,
{ split,
{ simp only [trans_source, preimage_univ, inter_univ, homeomorph.to_local_homeomorph_source],
rw trans_source at hx,
exact hx.1 },
{ exact hg₂ } },
refine ⟨s, open_s, this, _⟩,
let F₁ := (c.symm ≫ₕ f₁ ≫ₕ g) ≫ₕ (g.symm ≫ₕ f₂ ≫ₕ c'),
have A : F₁ ∈ G := G.trans (e.mem_groupoid c g hc hg₁) (e'.mem_groupoid g c' hg₁ hc'),
let F₂ := (c.symm ≫ₕ f ≫ₕ c').restr s,
have : F₁ ≈ F₂ := calc
F₁ ≈ c.symm ≫ₕ f₁ ≫ₕ (g ≫ₕ g.symm) ≫ₕ f₂ ≫ₕ c' : by simp [F₁, trans_assoc]
... ≈ c.symm ≫ₕ f₁ ≫ₕ (of_set g.source g.open_source) ≫ₕ f₂ ≫ₕ c' :
by simp [eq_on_source.trans', trans_self_symm g]
... ≈ ((c.symm ≫ₕ f₁) ≫ₕ (of_set g.source g.open_source)) ≫ₕ (f₂ ≫ₕ c') :
by simp [trans_assoc]
... ≈ ((c.symm ≫ₕ f₁).restr s) ≫ₕ (f₂ ≫ₕ c') : by simp [s, trans_of_set']
... ≈ ((c.symm ≫ₕ f₁) ≫ₕ (f₂ ≫ₕ c')).restr s : by simp [restr_trans]
... ≈ (c.symm ≫ₕ (f₁ ≫ₕ f₂) ≫ₕ c').restr s : by simp [eq_on_source.restr, trans_assoc]
... ≈ F₂ : by simp [F₂, feq],
have : F₂ ∈ G := G.eq_on_source A (setoid.symm this),
exact this
end,
..homeomorph.trans e.to_homeomorph e'.to_homeomorph }
end has_groupoid
|
5f7f1fb0217f68b0d6be9ae9d4925b2728c62c2c | 05f637fa14ac28031cb1ea92086a0f4eb23ff2b1 | /tests/lean/bad4.lean | 9a26be3ed7e2651ec42a9aac7326af2de69b54d9 | [
"Apache-2.0"
] | permissive | codyroux/lean0.1 | 1ce92751d664aacff0529e139083304a7bbc8a71 | 0dc6fb974aa85ed6f305a2f4b10a53a44ee5f0ef | refs/heads/master | 1,610,830,535,062 | 1,402,150,480,000 | 1,402,150,480,000 | 19,588,851 | 2 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 110 | lean | import Int.
variable f {A : Type} (a : A) : A
variable a : Int
definition tst : Bool := (fun x, (f x) > 10) a
|
6d8cbe128e45ea9e31ca086908acf94d3b3c4257 | bb31430994044506fa42fd667e2d556327e18dfe | /src/group_theory/subsemigroup/basic.lean | daefae477541c2f44ea822ba5cd8be87bfcdfe3c | [
"Apache-2.0"
] | permissive | sgouezel/mathlib | 0cb4e5335a2ba189fa7af96d83a377f83270e503 | 00638177efd1b2534fc5269363ebf42a7871df9a | refs/heads/master | 1,674,527,483,042 | 1,673,665,568,000 | 1,673,665,568,000 | 119,598,202 | 0 | 0 | null | 1,517,348,647,000 | 1,517,348,646,000 | null | UTF-8 | Lean | false | false | 16,901 | lean | /-
Copyright (c) 2018 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Kenny Lau, Johan Commelin, Mario Carneiro, Kevin Buzzard,
Amelia Livingston, Yury Kudryashov, Yakov Pechersky
-/
import algebra.hom.group -- Only needed for notation
import data.set.lattice
import data.set_like.basic
/-!
# Subsemigroups: definition and `complete_lattice` structure
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
This file defines bundled multiplicative and additive subsemigroups. We also define
a `complete_lattice` structure on `subsemigroup`s,
and define the closure of a set as the minimal subsemigroup that includes this set.
## Main definitions
* `subsemigroup M`: the type of bundled subsemigroup of a magma `M`; the underlying set is given in
the `carrier` field of the structure, and should be accessed through coercion as in `(S : set M)`.
* `add_subsemigroup M` : the type of bundled subsemigroups of an additive magma `M`.
For each of the following definitions in the `subsemigroup` namespace, there is a corresponding
definition in the `add_subsemigroup` namespace.
* `subsemigroup.copy` : copy of a subsemigroup with `carrier` replaced by a set that is equal but
possibly not definitionally equal to the carrier of the original `subsemigroup`.
* `subsemigroup.closure` : semigroup closure of a set, i.e.,
the least subsemigroup that includes the set.
* `subsemigroup.gi` : `closure : set M → subsemigroup M` and coercion `coe : subsemigroup M → set M`
form a `galois_insertion`;
## Implementation notes
Subsemigroup inclusion is denoted `≤` rather than `⊆`, although `∈` is defined as
membership of a subsemigroup's underlying set.
Note that `subsemigroup M` does not actually require `semigroup M`,
instead requiring only the weaker `has_mul M`.
This file is designed to have very few dependencies. In particular, it should not use natural
numbers.
## Tags
subsemigroup, subsemigroups
-/
variables {M : Type*} {N : Type*}
variables {A : Type*}
section non_assoc
variables [has_mul M] {s : set M}
variables [has_add A] {t : set A}
/-- `mul_mem_class S M` says `S` is a type of subsets `s ≤ M` that are closed under `(*)` -/
class mul_mem_class (S : Type*) (M : out_param $ Type*) [has_mul M] [set_like S M] : Prop :=
(mul_mem : ∀ {s : S} {a b : M}, a ∈ s → b ∈ s → a * b ∈ s)
export mul_mem_class (mul_mem)
/-- `add_mem_class S M` says `S` is a type of subsets `s ≤ M` that are closed under `(+)` -/
class add_mem_class (S : Type*) (M : out_param $ Type*) [has_add M] [set_like S M] : Prop :=
(add_mem : ∀ {s : S} {a b : M}, a ∈ s → b ∈ s → a + b ∈ s)
export add_mem_class (add_mem)
attribute [to_additive] mul_mem_class
/-- A subsemigroup of a magma `M` is a subset closed under multiplication. -/
structure subsemigroup (M : Type*) [has_mul M] :=
(carrier : set M)
(mul_mem' {a b} : a ∈ carrier → b ∈ carrier → a * b ∈ carrier)
/-- An additive subsemigroup of an additive magma `M` is a subset closed under addition. -/
structure add_subsemigroup (M : Type*) [has_add M] :=
(carrier : set M)
(add_mem' {a b} : a ∈ carrier → b ∈ carrier → a + b ∈ carrier)
attribute [to_additive add_subsemigroup] subsemigroup
namespace subsemigroup
@[to_additive]
instance : set_like (subsemigroup M) M :=
⟨subsemigroup.carrier, λ p q h, by cases p; cases q; congr'⟩
@[to_additive]
instance : mul_mem_class (subsemigroup M) M :=
{ mul_mem := subsemigroup.mul_mem' }
/-- See Note [custom simps projection] -/
@[to_additive " See Note [custom simps projection]"]
def simps.coe (S : subsemigroup M) : set M := S
initialize_simps_projections subsemigroup (carrier → coe)
initialize_simps_projections add_subsemigroup (carrier → coe)
@[simp, to_additive]
lemma mem_carrier {s : subsemigroup M} {x : M} : x ∈ s.carrier ↔ x ∈ s := iff.rfl
@[simp, to_additive]
lemma mem_mk {s : set M} {x : M} (h_mul) : x ∈ mk s h_mul ↔ x ∈ s := iff.rfl
@[simp, to_additive]
lemma coe_set_mk {s : set M} (h_mul) : (mk s h_mul : set M) = s := rfl
@[simp, to_additive]
lemma mk_le_mk {s t : set M} (h_mul) (h_mul') :
mk s h_mul ≤ mk t h_mul' ↔ s ⊆ t := iff.rfl
/-- Two subsemigroups are equal if they have the same elements. -/
@[ext, to_additive "Two `add_subsemigroup`s are equal if they have the same elements."]
theorem ext {S T : subsemigroup M}
(h : ∀ x, x ∈ S ↔ x ∈ T) : S = T := set_like.ext h
/-- Copy a subsemigroup replacing `carrier` with a set that is equal to it. -/
@[to_additive "Copy an additive subsemigroup replacing `carrier` with a set that is equal to
it."]
protected def copy (S : subsemigroup M) (s : set M) (hs : s = S) : subsemigroup M :=
{ carrier := s,
mul_mem' := λ _ _, hs.symm ▸ S.mul_mem' }
variable {S : subsemigroup M}
@[simp, to_additive] lemma coe_copy {s : set M} (hs : s = S) :
(S.copy s hs : set M) = s := rfl
@[to_additive] lemma copy_eq {s : set M} (hs : s = S) : S.copy s hs = S :=
set_like.coe_injective hs
variable (S)
/-- A subsemigroup is closed under multiplication. -/
@[to_additive "An `add_subsemigroup` is closed under addition."]
protected theorem mul_mem {x y : M} : x ∈ S → y ∈ S → x * y ∈ S := subsemigroup.mul_mem' S
/-- The subsemigroup `M` of the magma `M`. -/
@[to_additive "The additive subsemigroup `M` of the magma `M`."]
instance : has_top (subsemigroup M) :=
⟨{ carrier := set.univ,
mul_mem' := λ _ _ _ _, set.mem_univ _ }⟩
/-- The trivial subsemigroup `∅` of a magma `M`. -/
@[to_additive "The trivial `add_subsemigroup` `∅` of an additive magma `M`."]
instance : has_bot (subsemigroup M) :=
⟨{ carrier := ∅,
mul_mem' := λ a b, by simp }⟩
@[to_additive]
instance : inhabited (subsemigroup M) := ⟨⊥⟩
@[to_additive] lemma not_mem_bot {x : M} : x ∉ (⊥ : subsemigroup M) := set.not_mem_empty x
@[simp, to_additive] lemma mem_top (x : M) : x ∈ (⊤ : subsemigroup M) := set.mem_univ x
@[simp, to_additive] lemma coe_top : ((⊤ : subsemigroup M) : set M) = set.univ := rfl
@[simp, to_additive] lemma coe_bot : ((⊥ : subsemigroup M) : set M) = ∅ := rfl
/-- The inf of two subsemigroups is their intersection. -/
@[to_additive "The inf of two `add_subsemigroup`s is their intersection."]
instance : has_inf (subsemigroup M) :=
⟨λ S₁ S₂,
{ carrier := S₁ ∩ S₂,
mul_mem' := λ _ _ ⟨hx, hx'⟩ ⟨hy, hy'⟩,
⟨S₁.mul_mem hx hy, S₂.mul_mem hx' hy'⟩ }⟩
@[simp, to_additive]
lemma coe_inf (p p' : subsemigroup M) : ((p ⊓ p' : subsemigroup M) : set M) = p ∩ p' := rfl
@[simp, to_additive]
lemma mem_inf {p p' : subsemigroup M} {x : M} : x ∈ p ⊓ p' ↔ x ∈ p ∧ x ∈ p' := iff.rfl
@[to_additive]
instance : has_Inf (subsemigroup M) :=
⟨λ s,
{ carrier := ⋂ t ∈ s, ↑t,
mul_mem' := λ x y hx hy, set.mem_bInter $ λ i h,
i.mul_mem (by apply set.mem_Inter₂.1 hx i h) (by apply set.mem_Inter₂.1 hy i h) }⟩
@[simp, norm_cast, to_additive]
lemma coe_Inf (S : set (subsemigroup M)) : ((Inf S : subsemigroup M) : set M) = ⋂ s ∈ S, ↑s := rfl
@[to_additive]
lemma mem_Inf {S : set (subsemigroup M)} {x : M} : x ∈ Inf S ↔ ∀ p ∈ S, x ∈ p := set.mem_Inter₂
@[to_additive]
lemma mem_infi {ι : Sort*} {S : ι → subsemigroup M} {x : M} : (x ∈ ⨅ i, S i) ↔ ∀ i, x ∈ S i :=
by simp only [infi, mem_Inf, set.forall_range_iff]
@[simp, norm_cast, to_additive]
lemma coe_infi {ι : Sort*} {S : ι → subsemigroup M} : (↑(⨅ i, S i) : set M) = ⋂ i, S i :=
by simp only [infi, coe_Inf, set.bInter_range]
/-- subsemigroups of a monoid form a complete lattice. -/
@[to_additive "The `add_subsemigroup`s of an `add_monoid` form a complete lattice."]
instance : complete_lattice (subsemigroup M) :=
{ le := (≤),
lt := (<),
bot := (⊥),
bot_le := λ S x hx, (not_mem_bot hx).elim,
top := (⊤),
le_top := λ S x hx, mem_top x,
inf := (⊓),
Inf := has_Inf.Inf,
le_inf := λ a b c ha hb x hx, ⟨ha hx, hb hx⟩,
inf_le_left := λ a b x, and.left,
inf_le_right := λ a b x, and.right,
.. complete_lattice_of_Inf (subsemigroup M) $ λ s,
is_glb.of_image (λ S T,
show (S : set M) ≤ T ↔ S ≤ T, from set_like.coe_subset_coe) is_glb_binfi }
@[simp, to_additive]
lemma subsingleton_of_subsingleton [subsingleton (subsemigroup M)] : subsingleton M :=
begin
constructor; intros x y,
have : ∀ a : M, a ∈ (⊥ : subsemigroup M),
{ simp [subsingleton.elim (⊥ : subsemigroup M) ⊤] },
exact absurd (this x) not_mem_bot
end
@[to_additive]
instance [hn : nonempty M] : nontrivial (subsemigroup M) :=
⟨⟨⊥, ⊤, λ h, by { obtain ⟨x⟩ := id hn, refine absurd (_ : x ∈ ⊥) not_mem_bot, simp [h] }⟩⟩
/-- The `subsemigroup` generated by a set. -/
@[to_additive "The `add_subsemigroup` generated by a set"]
def closure (s : set M) : subsemigroup M := Inf {S | s ⊆ S}
@[to_additive]
lemma mem_closure {x : M} : x ∈ closure s ↔ ∀ S : subsemigroup M, s ⊆ S → x ∈ S :=
mem_Inf
/-- The subsemigroup generated by a set includes the set. -/
@[simp, to_additive "The `add_subsemigroup` generated by a set includes the set."]
lemma subset_closure : s ⊆ closure s := λ x hx, mem_closure.2 $ λ S hS, hS hx
@[to_additive]
lemma not_mem_of_not_mem_closure {P : M} (hP : P ∉ closure s) : P ∉ s := λ h, hP (subset_closure h)
variable {S}
open set
/-- A subsemigroup `S` includes `closure s` if and only if it includes `s`. -/
@[simp, to_additive "An additive subsemigroup `S` includes `closure s`
if and only if it includes `s`"]
lemma closure_le : closure s ≤ S ↔ s ⊆ S :=
⟨subset.trans subset_closure, λ h, Inf_le h⟩
/-- subsemigroup closure of a set is monotone in its argument: if `s ⊆ t`,
then `closure s ≤ closure t`. -/
@[to_additive "Additive subsemigroup closure of a set is monotone in its argument: if `s ⊆ t`,
then `closure s ≤ closure t`"]
lemma closure_mono ⦃s t : set M⦄ (h : s ⊆ t) : closure s ≤ closure t :=
closure_le.2 $ subset.trans h subset_closure
@[to_additive]
lemma closure_eq_of_le (h₁ : s ⊆ S) (h₂ : S ≤ closure s) : closure s = S :=
le_antisymm (closure_le.2 h₁) h₂
variable (S)
/-- An induction principle for closure membership. If `p` holds for all elements of `s`, and
is preserved under multiplication, then `p` holds for all elements of the closure of `s`. -/
@[elab_as_eliminator, to_additive "An induction principle for additive closure membership. If `p`
holds for all elements of `s`, and is preserved under addition, then `p` holds for all
elements of the additive closure of `s`."]
lemma closure_induction {p : M → Prop} {x} (h : x ∈ closure s)
(Hs : ∀ x ∈ s, p x)
(Hmul : ∀ x y, p x → p y → p (x * y)) : p x :=
(@closure_le _ _ _ ⟨p, Hmul⟩).2 Hs h
/-- A dependent version of `subsemigroup.closure_induction`. -/
@[elab_as_eliminator, to_additive "A dependent version of `add_subsemigroup.closure_induction`. "]
lemma closure_induction' (s : set M) {p : Π x, x ∈ closure s → Prop}
(Hs : ∀ x (h : x ∈ s), p x (subset_closure h))
(Hmul : ∀ x hx y hy, p x hx → p y hy → p (x * y) (mul_mem hx hy))
{x} (hx : x ∈ closure s) :
p x hx :=
begin
refine exists.elim _ (λ (hx : x ∈ closure s) (hc : p x hx), hc),
exact closure_induction hx
(λ x hx, ⟨_, Hs x hx⟩) (λ x y ⟨hx', hx⟩ ⟨hy', hy⟩, ⟨_, Hmul _ _ _ _ hx hy⟩),
end
/-- An induction principle for closure membership for predicates with two arguments. -/
@[elab_as_eliminator, to_additive "An induction principle for additive closure membership for
predicates with two arguments."]
lemma closure_induction₂ {p : M → M → Prop} {x} {y : M} (hx : x ∈ closure s) (hy : y ∈ closure s)
(Hs : ∀ (x ∈ s) (y ∈ s), p x y)
(Hmul_left : ∀ x y z, p x z → p y z → p (x * y) z)
(Hmul_right : ∀ x y z, p z x → p z y → p z (x * y)) : p x y :=
closure_induction hx
(λ x xs, closure_induction hy (Hs x xs) (λ z y h₁ h₂, Hmul_right z _ _ h₁ h₂))
(λ x z h₁ h₂, Hmul_left _ _ _ h₁ h₂)
/-- If `s` is a dense set in a magma `M`, `subsemigroup.closure s = ⊤`, then in order to prove that
some predicate `p` holds for all `x : M` it suffices to verify `p x` for `x ∈ s`,
and verify that `p x` and `p y` imply `p (x * y)`. -/
@[elab_as_eliminator, to_additive "If `s` is a dense set in an additive monoid `M`,
`add_subsemigroup.closure s = ⊤`, then in order to prove that some predicate `p` holds
for all `x : M` it suffices to verify `p x` for `x ∈ s`, and verify that `p x` and `p y` imply
`p (x + y)`."]
lemma dense_induction {p : M → Prop} (x : M) {s : set M} (hs : closure s = ⊤)
(Hs : ∀ x ∈ s, p x)
(Hmul : ∀ x y, p x → p y → p (x * y)) : p x :=
have ∀ x ∈ closure s, p x, from λ x hx, closure_induction hx Hs Hmul,
by simpa [hs] using this x
variable (M)
/-- `closure` forms a Galois insertion with the coercion to set. -/
@[to_additive "`closure` forms a Galois insertion with the coercion to set."]
protected def gi : galois_insertion (@closure M _) coe :=
{ choice := λ s _, closure s,
gc := λ s t, closure_le,
le_l_u := λ s, subset_closure,
choice_eq := λ s h, rfl }
variable {M}
/-- Closure of a subsemigroup `S` equals `S`. -/
@[simp, to_additive "Additive closure of an additive subsemigroup `S` equals `S`"]
lemma closure_eq : closure (S : set M) = S := (subsemigroup.gi M).l_u_eq S
@[simp, to_additive] lemma closure_empty : closure (∅ : set M) = ⊥ :=
(subsemigroup.gi M).gc.l_bot
@[simp, to_additive] lemma closure_univ : closure (univ : set M) = ⊤ :=
@coe_top M _ ▸ closure_eq ⊤
@[to_additive]
lemma closure_union (s t : set M) : closure (s ∪ t) = closure s ⊔ closure t :=
(subsemigroup.gi M).gc.l_sup
@[to_additive]
lemma closure_Union {ι} (s : ι → set M) : closure (⋃ i, s i) = ⨆ i, closure (s i) :=
(subsemigroup.gi M).gc.l_supr
@[simp, to_additive]
lemma closure_singleton_le_iff_mem (m : M) (p : subsemigroup M) :
closure {m} ≤ p ↔ m ∈ p :=
by rw [closure_le, singleton_subset_iff, set_like.mem_coe]
@[to_additive]
lemma mem_supr {ι : Sort*} (p : ι → subsemigroup M) {m : M} :
(m ∈ ⨆ i, p i) ↔ (∀ N, (∀ i, p i ≤ N) → m ∈ N) :=
begin
rw [← closure_singleton_le_iff_mem, le_supr_iff],
simp only [closure_singleton_le_iff_mem],
end
@[to_additive]
lemma supr_eq_closure {ι : Sort*} (p : ι → subsemigroup M) :
(⨆ i, p i) = subsemigroup.closure (⋃ i, (p i : set M)) :=
by simp_rw [subsemigroup.closure_Union, subsemigroup.closure_eq]
end subsemigroup
namespace mul_hom
variables [has_mul N]
open subsemigroup
/-- The subsemigroup of elements `x : M` such that `f x = g x` -/
@[to_additive "The additive subsemigroup of elements `x : M` such that `f x = g x`"]
def eq_mlocus (f g : M →ₙ* N) : subsemigroup M :=
{ carrier := {x | f x = g x},
mul_mem' := λ x y (hx : _ = _) (hy : _ = _), by simp [*] }
/-- If two mul homomorphisms are equal on a set, then they are equal on its subsemigroup closure. -/
@[to_additive "If two add homomorphisms are equal on a set,
then they are equal on its additive subsemigroup closure."]
lemma eq_on_mclosure {f g : M →ₙ* N} {s : set M} (h : set.eq_on f g s) :
set.eq_on f g (closure s) :=
show closure s ≤ f.eq_mlocus g, from closure_le.2 h
@[to_additive]
lemma eq_of_eq_on_mtop {f g : M →ₙ* N} (h : set.eq_on f g (⊤ : subsemigroup M)) :
f = g :=
ext $ λ x, h trivial
@[to_additive]
lemma eq_of_eq_on_mdense {s : set M} (hs : closure s = ⊤) {f g : M →ₙ* N} (h : s.eq_on f g) :
f = g :=
eq_of_eq_on_mtop $ hs ▸ eq_on_mclosure h
end mul_hom
end non_assoc
section assoc
namespace mul_hom
open subsemigroup
/-- Let `s` be a subset of a semigroup `M` such that the closure of `s` is the whole semigroup.
Then `mul_hom.of_mdense` defines a mul homomorphism from `M` asking for a proof
of `f (x * y) = f x * f y` only for `y ∈ s`. -/
@[to_additive]
def of_mdense {M N} [semigroup M] [semigroup N] {s : set M} (f : M → N) (hs : closure s = ⊤)
(hmul : ∀ x (y ∈ s), f (x * y) = f x * f y) :
M →ₙ* N :=
{ to_fun := f,
map_mul' := λ x y, dense_induction y hs (λ y hy x, hmul x y hy)
(λ y₁ y₂ h₁ h₂ x, by simp only [← mul_assoc, h₁, h₂]) x }
/-- Let `s` be a subset of an additive semigroup `M` such that the closure of `s` is the whole
semigroup. Then `add_hom.of_mdense` defines an additive homomorphism from `M` asking for a proof
of `f (x + y) = f x + f y` only for `y ∈ s`. -/
add_decl_doc add_hom.of_mdense
@[simp, norm_cast, to_additive] lemma coe_of_mdense [semigroup M] [semigroup N] {s : set M}
(f : M → N) (hs : closure s = ⊤) (hmul) :
(of_mdense f hs hmul : M → N) = f := rfl
end mul_hom
end assoc
|
099dd294c18d67bdb79499333be401ce93baeecb | 4fa118f6209450d4e8d058790e2967337811b2b5 | /src/Spa/presheaf.lean | 2141a5e0b9c1a18f87672950d438ec0ae11b83dd | [
"Apache-2.0"
] | permissive | leanprover-community/lean-perfectoid-spaces | 16ab697a220ed3669bf76311daa8c466382207f7 | 95a6520ce578b30a80b4c36e36ab2d559a842690 | refs/heads/master | 1,639,557,829,139 | 1,638,797,866,000 | 1,638,797,866,000 | 135,769,296 | 96 | 10 | Apache-2.0 | 1,638,797,866,000 | 1,527,892,754,000 | Lean | UTF-8 | Lean | false | false | 9,409 | lean | import ring_theory.localization
import ring_theory.subring
import for_mathlib.nonarchimedean.basic
import for_mathlib.topological_rings
import sheaves.presheaf_of_topological_rings
import Spa.rational_open_data
/-!
# The structure presheaf on the adic spectrum of a Huber pair
The purpose of this file is to endow the adic spectrum `spa A` of a Huber pair
with a presheaf of topological rings: the structure presheaf.
Sections of this presheaf will be thought of as functions on the adic spectrum.
## Implementation details
Because the library for categorical limits was not yet very stable at the time of writing,
we implement the sections of the presheaf by manually taking a limit:
-- The underlying type of 𝒪_X(U), the structure presheaf on X = Spa(A)
def presheaf_value (U : opens (spa A)) :=
{f : Π (rd : rational_open_data_subsets U), rat_open_data_completion rd.1 //
∀ (rd1 rd2 : rational_open_data_subsets U) (h : rd1.1 ≤ rd2.1),
rat_open_data_completion.restriction h (f rd1) = (f rd2)} -- agrees on overlaps
-/
universes u₁ u₂ u₃
open_locale classical
open set function Spv valuation
local postfix `⁺` : 66 := λ A : Huber_pair, A.plus
namespace spa
variable {A : Huber_pair}
section
open topological_space
/-- The set of all rational open subsets contained in the open set U. -/
def rational_open_data_subsets (U : opens (spa A)) :=
{ r : rational_open_data A // r.open_set ⊆ U}
/-- The natural inclusion map of rational open subsets contained in the open set U
into those contained in some larger open set V (that contains U).-/
def rational_open_data_subsets.map {U V : opens (spa A)} (hUV : U ≤ V)
(rd : rational_open_data_subsets U) :
rational_open_data_subsets V :=
⟨rd.val, set.subset.trans rd.property hUV⟩
/--The intersection of two rational open subsets contained in some open set U
is a rational open subset contained in U.-/
noncomputable def rational_open_data_subsets_inter {U : opens (spa A)}
(r1 r2 : rational_open_data_subsets U) :
rational_open_data_subsets U :=
⟨rational_open_data.inter r1.1 r2.1, begin
rw rational_open_data.inter_open_set,
refine set.subset.trans (inter_subset_left r1.1.open_set r2.1.open_set) _,
exact r1.2
end⟩
lemma rational_open_data_subsets_symm {U : opens (spa A)}
(r1 r2 : rational_open_data_subsets U) :
rational_open_data_subsets_inter r1 r2 = rational_open_data_subsets_inter r2 r1 :=
begin
rw subtype.ext,
exact rational_open_data.inter_symm r1.1 r2.1
end
end -- section
open uniform_space
-- rat_open_data is short for "rational open data". KB needs to think more clearly
-- about namespaces etc.
/-- A<T/s>, the functions on D(T,s). A topological ring -/
def rat_open_data_completion (r : rational_open_data A) :=
completion (rational_open_data.localization r)
namespace rat_open_data_completion
open topological_space
/-- The ring structure on A<T/s>. -/
noncomputable instance (r : rational_open_data A) : comm_ring (rat_open_data_completion r) :=
by dunfold rat_open_data_completion; apply_instance
/-- The uniform structure on A<T/s>. -/
instance uniform_space (r : rational_open_data A) : uniform_space (rat_open_data_completion r) :=
by dunfold rat_open_data_completion; apply_instance
/-- A<T/s> is a topological ring. -/
instance (r : rational_open_data A) : topological_ring (rat_open_data_completion r) :=
by dunfold rat_open_data_completion; apply_instance
/-- The natural map A<T₁/s₁> → A<T₂/s₂> for two rational open subsets r1 and r2 with r1 ≤ r2.-/
noncomputable def restriction {r1 r2 : rational_open_data A} (h : r1 ≤ r2) :
rat_open_data_completion r1 → rat_open_data_completion r2 :=
completion.map (rational_open_data.localization_map h)
/-- The natural map A<T₁/s₁> → A<T₂/s₂> is a ring homomorphism.-/
instance restriction_is_ring_hom {r1 r2 : rational_open_data A} (h : r1 ≤ r2) :
is_ring_hom (restriction h) :=
completion.is_ring_hom_map (rational_open_data.localization_map_is_cts h)
lemma restriction_is_uniform_continuous {r1 r2 : rational_open_data A} (h : r1 ≤ r2) :
uniform_continuous (rat_open_data_completion.restriction h) :=
completion.uniform_continuous_map
end rat_open_data_completion -- namespace
open topological_space
/-- The underlying type of 𝒪_X(U), the structure presheaf on X = Spa(A) -/
def presheaf_value (U : opens (spa A)) :=
{f : Π (rd : rational_open_data_subsets U), rat_open_data_completion rd.1 //
∀ (rd1 rd2 : rational_open_data_subsets U) (h : rd1.1 ≤ rd2.1),
rat_open_data_completion.restriction h (f rd1) = (f rd2)} -- agrees on overlaps
/-- An auxilliary definition:
The underlying type of 𝒪_X(U), the structure presheaf on X = Spa(A),
but given as a subset, rather than a subtype.
This definition is used for the definition of the ring structure on 𝒪_X(U) -/
def presheaf_value_set (U : opens (spa A)) :=
{f : Π (rd : rational_open_data_subsets U), rat_open_data_completion rd.1 |
∀ (rd1 rd2 : rational_open_data_subsets U) (h : rd1.1 ≤ rd2.1),
rat_open_data_completion.restriction h (f rd1) = (f rd2)}
-- We need to check it's a ring
/-- The value of the structure presheaf on an open set U
is a subring of the big Pi-type in its definiton.-/
lemma presheaf_subring (U : opens (spa A)) : is_subring (presheaf_value_set U) :=
{ zero_mem := λ _ _ _, is_ring_hom.map_zero _,
one_mem := λ _ _ _, is_ring_hom.map_one _,
add_mem := λ a b ha hb rd₁ rd₂ h,
begin
change rat_open_data_completion.restriction h (a rd₁ + b rd₁) = a rd₂ + b rd₂,
rw is_ring_hom.map_add (rat_open_data_completion.restriction h),
rw [ha _ _ h, hb _ _ h],
end,
neg_mem := λ a ha rd₁ rd₂ h,
begin
change rat_open_data_completion.restriction h (-(a rd₁)) = -(a rd₂),
rw is_ring_hom.map_neg (rat_open_data_completion.restriction h),
rw ha _ _ h,
end,
mul_mem := λ a b ha hb rd₁ rd₂ h,
begin
change rat_open_data_completion.restriction h (a rd₁ * b rd₁) = a rd₂ * b rd₂,
rw is_ring_hom.map_mul (rat_open_data_completion.restriction h),
rw [ha _ _ h, hb _ _ h]
end }
/-- The ring structure on the value of the structure presheaf on an open set U.-/
noncomputable instance presheaf_comm_ring (U : opens (spa A)) : comm_ring (presheaf_value U) :=
@subset.comm_ring _ pi.comm_ring _ (spa.presheaf_subring U)
/-- The topology on the value of the structure presheaf on an open set U.-/
instance presheaf_top_space (U : opens (spa A)) : topological_space (presheaf_value U) :=
by unfold presheaf_value; apply_instance
/-- The value of the structure presheaf on an open set U is a topological ring.-/
instance presheaf_top_ring (U : opens (spa A)) : topological_ring (presheaf_value U) :=
begin
haveI := spa.presheaf_subring U,
letI : topological_ring (Π (rd : rational_open_data_subsets U), rat_open_data_completion (rd.1)) :=
by apply_instance,
apply topological_subring (presheaf_value_set U),
end
/-- The restriction map for the structure presheaf on the adic spectrum of a Huber pair. -/
def presheaf_map {U V : opens (spa A)} (hUV : U ≤ V) :
presheaf_value V → presheaf_value U :=
λ f, ⟨_, λ rd1 rd2 h,
(f.2 (rational_open_data_subsets.map hUV rd1)
(rational_open_data_subsets.map hUV rd2) h : _)⟩
-- Note the (X : _) trick at the end of the preceding definition,
-- which tells Lean "don't try and elaborate X assuming it has the type you know it has,
-- elaborate it independently, figure out the type, and then unify".
-- Thanks to Mario Carneiro for this trick which
-- hugely speeds up elaboration time of this definition.
@[simp] lemma presheaf_map_id (U : opens (spa A)) :
presheaf_map (le_refl U) = id :=
by { delta presheaf_map, tidy }
lemma presheaf_map_comp {U V W : opens (spa A)} (hUV : U ≤ V) (hVW : V ≤ W) :
presheaf_map hUV ∘ presheaf_map hVW = presheaf_map (le_trans hUV hVW) :=
by { delta presheaf_map, tidy }
/-- The restriction maps of the structure presheaf are ring homomorphisms. -/
instance presheaf_map_is_ring_hom {U V : opens (spa A)} (hUV : U ≤ V) :
is_ring_hom (presheaf_map hUV) :=
{ map_one := rfl,
map_mul := λ _ _, rfl,
map_add := λ _ _, rfl }
lemma presheaf_map_cts {U V : opens (spa A)} (hUV : U ≤ V) :
continuous (presheaf_map hUV) :=
continuous_subtype_mk _ (continuous_pi (λ i, ((continuous_apply _).comp continuous_subtype_val)))
variable (A)
/-- The structure presheaf on the adic spectrum of a Huber pair. -/
noncomputable def presheaf_of_topological_rings : presheaf_of_topological_rings (spa A) :=
{ F := presheaf_value,
res := λ U V, presheaf_map,
Hid := presheaf_map_id,
Hcomp := λ U V W, presheaf_map_comp,
Fring := spa.presheaf_comm_ring,
res_is_ring_hom := λ U V, spa.presheaf_map_is_ring_hom,
Ftop := spa.presheaf_top_space,
Ftop_ring := spa.presheaf_top_ring,
res_continuous := λ U V, presheaf_map_cts }
end spa -- namespace
-- notes
-- KB idle comment: I guess we never make A<T/s> a Huber pair if A is a Huber pair?
-- We would need integral closure for this and I don't think we have it in mathlib.
-- We see mid way through p75 that the definition of the presheaf
-- on V is proj lim of O_X(U) as U runs through rationals opens in V. This gets
-- the projective limit topology and then we have a presheaf (hopefully this is
-- straightforward) of complete topological rings (need proj lim of complete is complete)
|
96d241931f9495ea74971de33fa918f9974410fd | 4efff1f47634ff19e2f786deadd394270a59ecd2 | /src/topology/sheaves/local_predicate.lean | 7086918cf438222d522c6714e2c704b7d2a051e0 | [
"Apache-2.0"
] | permissive | agjftucker/mathlib | d634cd0d5256b6325e3c55bb7fb2403548371707 | 87fe50de17b00af533f72a102d0adefe4a2285e8 | refs/heads/master | 1,625,378,131,941 | 1,599,166,526,000 | 1,599,166,526,000 | 160,748,509 | 0 | 0 | Apache-2.0 | 1,544,141,789,000 | 1,544,141,789,000 | null | UTF-8 | Lean | false | false | 14,575 | lean | /-
Copyright (c) 2020 Scott Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johan Commelin, Scott Morrison, Adam Topaz
-/
import topology.sheaves.sheaf_of_functions
import topology.sheaves.stalks
/-!
# Functions satisfying a local predicate form a sheaf.
At this stage, in `topology/sheaves/sheaf_of_functions.lean`
we've proved that not-necessarily-continuous functions from a topological space
into some type (or type family) form a sheaf.
Why do the continuous functions form a sheaf?
The point is just that continuity is a local condition,
so one can use the lifting condition for functions to provide a candidate lift,
then verify that the lift is actually continuous by using the factorisation condition for the lift
(which guarantees that on each open set it agrees with the functions being lifted,
which were assumed to be continuous).
This file abstracts this argument to work for
any collection of dependent functions on a topological space
satisfying a "local predicate".
As an application, we check that continuity is a local predicate in this sense, and provide
* `Top.sheaf_condition.to_Top`: continuous functions into a topological space form a sheaf
A sheaf constructed in this way has a natural map `stalk_to_fiber` from the stalks
to the types in the ambient type family.
We give conditions sufficient to show that this map is injective and/or surjective.
-/
universe v
noncomputable theory
variables {X : Top.{v}}
variables (T : X → Type v)
open topological_space
open opposite
open category_theory
open category_theory.limits
namespace Top
/--
Given a topological space `X : Top` and a type family `T : X → Type`,
a `P : prelocal_predicate T` consists of:
* a family of predicates `P.pred`, one for each `U : opens X`, of the form `(Π x : U, T x) → Prop`
* a proof that if `f : Π x : V, T x` satisfies the predicate on `V : opens X`, then
the restriction of `f` to any open subset `U` also satisfies the predicate.
-/
structure prelocal_predicate :=
(pred : Π {U : opens X}, (Π x : U, T x) → Prop)
(res : ∀ {U V : opens X} (i : U ⟶ V) (f : Π x : V, T x) (h : pred f), pred (λ x : U, f (i x)))
variables (X)
/--
Continuity is a "prelocal" predicate on functions to a fixed topological space `T`.
-/
@[simps]
def continuous_prelocal (T : Top.{v}) : prelocal_predicate (λ x : X, T) :=
{ pred := λ U f, continuous f,
res := λ U V i f h, continuous.comp h (opens.open_embedding_of_le (le_of_hom i)).continuous, }
/-- Satisfying the inhabited linter. -/
instance inhabited_prelocal_predicate (T : Top.{v}) : inhabited (prelocal_predicate (λ x : X, T)) :=
⟨continuous_prelocal X T⟩
variables {X}
/--
Given a topological space `X : Top` and a type family `T : X → Type`,
a `P : local_predicate T` consists of:
* a family of predicates `P.pred`, one for each `U : opens X`, of the form `(Π x : U, T x) → Prop`
* a proof that if `f : Π x : V, T x` satisfies the predicate on `V : opens X`, then
the restriction of `f` to any open subset `U` also satisfies the predicate, and
* a proof that given some `f : Π x : U, T x`,
if for every `x : U` we can find an open set `x ∈ V ≤ U`
so that the restriction of `f` to `V` satisfies the predicate,
then `f` itself satisfies the predicate.
-/
structure local_predicate extends prelocal_predicate T :=
(locality : ∀ {U : opens X} (f : Π x : U, T x)
(w : ∀ x : U, ∃ (V : opens X) (m : x.1 ∈ V) (i : V ⟶ U), pred (λ x : V, f (i x : U))), pred f)
variables (X)
/--
Continuity is a "local" predicate on functions to a fixed topological space `T`.
-/
def continuous_local (T : Top.{v}) : local_predicate (λ x : X, T) :=
{ locality := λ U f w,
begin
apply continuous_iff_continuous_at.2,
intro x,
specialize w x,
rcases w with ⟨V, m, i, w⟩,
dsimp at w,
rw continuous_iff_continuous_at at w,
specialize w ⟨x, m⟩,
simpa using (opens.open_embedding_of_le (le_of_hom i)).continuous_at_iff.1 w,
end,
..continuous_prelocal X T }
/-- Satisfying the inhabited linter. -/
instance inhabited_local_predicate (T : Top.{v}) : inhabited (local_predicate _) :=
⟨continuous_local X T⟩
variables {X T}
/--
Given a `P : prelocal_predicate`, we can always construct a `local_predicate`
by asking that the condition from `P` holds locally near every point.
-/
def prelocal_predicate.sheafify {T : X → Type v} (P : prelocal_predicate T) : local_predicate T :=
{ pred := λ U f, ∀ x : U, ∃ (V : opens X) (m : x.1 ∈ V) (i : V ⟶ U), P.pred (λ x : V, f (i x : U)),
res := λ V U i f w x,
begin
specialize w (i x),
rcases w with ⟨V', m', i', p⟩,
refine ⟨V ⊓ V', ⟨x.2,m'⟩, opens.inf_le_left _ _, _⟩,
convert P.res (opens.inf_le_right V V') _ p,
end,
locality := λ U f w x,
begin
specialize w x,
rcases w with ⟨V, m, i, p⟩,
specialize p ⟨x.1, m⟩,
rcases p with ⟨V', m', i', p'⟩,
exact ⟨V', m', i' ≫ i, p'⟩,
end }
lemma prelocal_predicate.sheafify_of {T : X → Type v} {P : prelocal_predicate T}
{U : opens X} {f : Π x : U, T x} (h : P.pred f) :
P.sheafify.pred f :=
λ x, ⟨U, x.2, 𝟙 _, by { convert h, ext ⟨y, w⟩, refl, }⟩
/--
The subpresheaf of dependent functions on `X` satisfying the "pre-local" predicate `P`.
-/
@[simps]
def subpresheaf_to_Types (P : prelocal_predicate T) : presheaf (Type v) X :=
{ obj := λ U, { f : Π x : unop U, T x // P.pred f },
map := λ U V i f, ⟨λ x, f.1 (i.unop x), P.res i.unop f.1 f.2⟩ }.
namespace subpresheaf_to_Types
variables (P : prelocal_predicate T)
/--
The natural transformation including the subpresheaf of functions satisfying a local predicate
into the presheaf of all functions.
-/
def subtype : subpresheaf_to_Types P ⟶ presheaf_to_Types X T :=
{ app := λ U f, f.1 }
open Top.sheaf_condition
/--
The natural transformation
from the sheaf condition diagram for functions satisfying a local predicate
to the sheaf condition diagram for arbitrary functions,
given by forgetting that the local predicate holds.
-/
@[simps]
def diagram_subtype {ι : Type v} (U : ι → opens X) :
diagram (subpresheaf_to_Types P) U ⟶ diagram (presheaf_to_Types X T) U :=
{ app := λ j, walking_parallel_pair.rec_on j (pi.map (λ i f, f.1)) (pi.map (λ p f, f.1)),
naturality' :=
begin
rintro ⟨_|_⟩ ⟨_|_⟩ ⟨⟩,
{ refl, },
{ dsimp [left_res, subpresheaf_to_Types, presheaf_to_Types],
simp only [limit.lift_map],
ext1 ⟨i₁,i₂⟩,
simp only [limit.lift_π, cones.postcompose_obj_π, discrete.nat_trans_app, limit.map_π_assoc,
fan.mk_π_app, nat_trans.comp_app, category.assoc],
ext,
simp only [types_comp_apply, subtype.val_eq_coe], },
{ dsimp [right_res, subpresheaf_to_Types, presheaf_to_Types],
simp only [limit.lift_map],
ext1 ⟨i₁,i₂⟩,
simp only [limit.lift_π, cones.postcompose_obj_π, discrete.nat_trans_app, limit.map_π_assoc,
fan.mk_π_app, nat_trans.comp_app, category.assoc],
ext,
simp only [types_comp_apply, subtype.val_eq_coe], },
{ refl, },
end}
/--
The functions satisfying a local predicate satisfy the sheaf condition.
-/
def sheaf_condition
(P : local_predicate T) :
sheaf_condition (subpresheaf_to_Types P.to_prelocal_predicate) :=
λ ι U,
begin
refine fork.is_limit.mk _ _ _ _,
{ intros s f,
fsplit,
-- First, we use the fact that not necessarily continuous functions form a sheaf,
-- to provide the lift.
{ let s' := (cones.postcompose (diagram_subtype P.to_prelocal_predicate U)).obj s,
exact (to_Types X T U).lift s' f, },
-- Second, we need to do the actual work, proving this lift satisfies the predicate.
{ dsimp,
-- We work locally,
apply P.locality,
-- so that once we're at a particular point `x`, we can select some open set `x ∈ U i`.
rintro ⟨x, mem⟩,
change x ∈ (supr U).val at mem,
simp at mem,
choose i hi using mem,
use U i,
use hi,
use (opens.le_supr U i),
-- Now our goal is to show that the previously chosen lift,
-- when restricted to that `U i`, satisfies the predicate.
-- This follows from the factorisation condition, and
-- the fact that the underlying presheaf is a presheaf of functions satisfying the predicate.
let s' := (cones.postcompose (diagram_subtype P.to_prelocal_predicate U)).obj s,
have fac_i := ((to_Types X T U).fac s' walking_parallel_pair.zero) =≫ pi.π _ i,
simp only [sheaf_condition.res, limit.lift_π, cones.postcompose_obj_π,
sheaf_condition.fork_π_app_walking_parallel_pair_zero, fan.mk_π_app,
nat_trans.comp_app, category.assoc] at fac_i,
have fac_i_f := congr_fun fac_i f,
simp only [diagram_subtype, discrete.nat_trans_app, types_comp_apply,
presheaf_to_Types_map, limit.map_π, subtype.val_eq_coe] at fac_i_f,
erw fac_i_f,
apply subtype.property, }, },
{ -- Proving the factorisation condition is straightforward:
-- we observe that checking equality of functions satisfying a predicate reduces to
-- checking equality of the underlying functions,
-- and use the factorisation condition for the sheaf condition for functions.
intros s,
ext i f : 2,
apply subtype.coe_injective,
convert congr_fun
((to_Types X T U).fac
((cones.postcompose (diagram_subtype P.to_prelocal_predicate U)).obj s)
walking_parallel_pair.zero =≫
pi.π (λ (i : ι), (X.presheaf_to_Types T).obj (op (U i))) i) f, },
{ -- Similarly for proving the uniqueness condition, after a certain amount of bookkeeping.
intros s m w,
ext f : 1,
apply subtype.coe_injective,
let s' := (cones.postcompose (diagram_subtype P.to_prelocal_predicate U)).obj s,
refine congr_fun ((to_Types X T U).uniq s' _ _) f,
-- We "just" need to fix up our `w` to match the missing `w` argument.
-- Unfortunately, it's still gross.
intro j,
specialize w j,
dsimp [s'],
rw ←w, clear w,
simp only [category.assoc],
rcases j with ⟨_|_⟩,
{ apply limit.hom_ext,
intro i,
simp only [category.assoc, limit.map_π],
ext f' ⟨x, mem⟩,
dsimp [res, subpresheaf_to_Types, presheaf_to_Types],
simp, },
{ apply limit.hom_ext,
intro i,
simp only [category.assoc, limit.map_π],
ext f' ⟨x, mem⟩,
dsimp [res, left_res, subpresheaf_to_Types, presheaf_to_Types],
simp, }, },
end
end subpresheaf_to_Types
/--
The subsheaf of the sheaf of all dependently typed functions satisfying the local predicate `P`.
-/
@[simps]
def subsheaf_to_Types (P : local_predicate T) : sheaf (Type v) X :=
{ presheaf := subpresheaf_to_Types P.to_prelocal_predicate,
sheaf_condition := subpresheaf_to_Types.sheaf_condition P }.
/--
There is a canonical map from the stalk to the original fiber.
-/
def stalk_to_fiber (P : local_predicate T) (x : X) :
(subsheaf_to_Types P).presheaf.stalk x ⟶ T x :=
begin
refine colimit.desc _
{ X := T x, ι := { app := λ U f, _, naturality' := _ } },
{ exact f.1 ⟨x, (unop U).2⟩, },
{ tidy, }
end
@[simp] lemma stalk_to_fiber_germ (P : local_predicate T) (U : opens X) (x : U) (f) :
stalk_to_fiber P x ((subsheaf_to_Types P).presheaf.germ x f) = f.1 x :=
begin
dsimp [presheaf.germ, stalk_to_fiber],
cases x,
simp,
refl,
end
/--
The `stalk_to_fiber` map is surjective at `x` if
every point in the fiber `T x` has an allowed section passing through it.
-/
lemma stalk_to_fiber_surjective (P : local_predicate T) (x : X)
(w : ∀ (t : T x), ∃ (U : open_nhds x) (f : Π y : U.1, T y) (h : P.pred f), f ⟨x, U.2⟩ = t) :
function.surjective (stalk_to_fiber P x) :=
λ t,
begin
rcases w t with ⟨U, f, h, rfl⟩,
fsplit,
{ exact (subsheaf_to_Types P).presheaf.germ ⟨x, U.2⟩ ⟨f, h⟩, },
{ exact stalk_to_fiber_germ _ U.1 ⟨x, U.2⟩ ⟨f, h⟩, }
end
/--
The `stalk_to_fiber` map is injective at `x` if any two allowed sections which agree at `x`
agree on some neighborhood of `x`.
-/
lemma stalk_to_fiber_injective (P : local_predicate T) (x : X)
(w : ∀ (U V : open_nhds x) (fU : Π y : U.1, T y) (hU : P.pred fU)
(fV : Π y : V.1, T y) (hV : P.pred fV) (e : fU ⟨x, U.2⟩ = fV ⟨x, V.2⟩),
∃ (W : open_nhds x) (iU : W ⟶ U) (iV : W ⟶ V), ∀ (w : W.1), fU (iU w : U.1) = fV (iV w : V.1)) :
function.injective (stalk_to_fiber P x) :=
λ tU tV h,
begin
-- We promise to provide all the ingredients of the proof later:
let Q :
∃ (W : (open_nhds x)ᵒᵖ) (s : Π w : (unop W).1, T w) (hW : P.pred s),
tU = (subsheaf_to_Types P).presheaf.germ ⟨x, (unop W).2⟩ ⟨s, hW⟩ ∧
tV = (subsheaf_to_Types P).presheaf.germ ⟨x, (unop W).2⟩ ⟨s, hW⟩ := _,
{ choose W s hW e using Q,
exact e.1.trans e.2.symm, },
-- Then use induction to pick particular representatives of `tU tV : stalk x`
obtain ⟨U, ⟨fU, hU⟩, rfl⟩ := types.jointly_surjective' tU,
obtain ⟨V, ⟨fV, hV⟩, rfl⟩ := types.jointly_surjective' tV,
{ -- Decompose everything into its constituent parts:
dsimp,
simp only [stalk_to_fiber, types.ι_desc_apply] at h,
specialize w (unop U) (unop V) fU hU fV hV h,
rcases w with ⟨W, iU, iV, w⟩,
-- and put it back together again in the correct order.
refine ⟨(op W), (λ w, fU (iU w : (unop U).1)), P.res _ _ hU, _⟩,
rcases W with ⟨W, m⟩,
exact ⟨types.colimit_sound iU.op (subtype.eq rfl),
types.colimit_sound iV.op (subtype.eq (funext w).symm)⟩, },
end
/--
Some repackaging:
the presheaf of functions satisfying `continuous_prelocal` is just the same thing as
the presheaf of continuous functions.
-/
def subpresheaf_continuous_prelocal_iso_presheaf_to_Top (T : Top.{v}) :
subpresheaf_to_Types (continuous_prelocal X T) ≅ presheaf_to_Top X T :=
nat_iso.of_components
(λ X,
{ hom := by { rintro ⟨f, c⟩, exact ⟨f, c⟩, },
inv := by { rintro ⟨f, c⟩, exact ⟨f, c⟩, },
hom_inv_id' := by { ext ⟨f, p⟩ x, refl, },
inv_hom_id' := by { ext ⟨f, p⟩ x, refl, }, })
(by tidy)
/--
The sheaf of continuous functions on `X` with values in a space `T`.
-/
def sheaf_to_Top (T : Top.{v}) : sheaf (Type v) X :=
{ presheaf := presheaf_to_Top X T,
sheaf_condition :=
sheaf_condition_equiv_of_iso (subpresheaf_continuous_prelocal_iso_presheaf_to_Top T)
(subpresheaf_to_Types.sheaf_condition (continuous_local X T)), }
end Top
|
64e3c518807a1782d8679f48f03ef905ccd9ca8b | cf39355caa609c0f33405126beee2739aa3cb77e | /tests/lean/curly_notation.lean | f3588b07a5afdc10a40f729d7584796e4c1cafac | [
"Apache-2.0"
] | permissive | leanprover-community/lean | 12b87f69d92e614daea8bcc9d4de9a9ace089d0e | cce7990ea86a78bdb383e38ed7f9b5ba93c60ce0 | refs/heads/master | 1,687,508,156,644 | 1,684,951,104,000 | 1,684,951,104,000 | 169,960,991 | 457 | 107 | Apache-2.0 | 1,686,744,372,000 | 1,549,790,268,000 | C++ | UTF-8 | Lean | false | false | 477 | lean | #check ({1, 2, 3} : set nat)
#check ({1} : set nat)
#check ({} : set nat)
definition s1 : set nat := {1, 2+3, 3, 4}
#print s1
definition s2 : set char := {'a', 'b', 'c'}
#print s2
definition s3 : set string := {"hello", "world"}
#print s3
#check { a ∈ s1 | a > 1 }
#check { a in s1 | a > 1 }
set_option pp.unicode false
#check { a ∈ s1 | a > 2 }
definition a := 10
#check ({a, a} : set nat)
#check ({a, 1, a} : set nat)
#check ({a} : set nat)
#check { a // a > 0 }
|
60e7f5948b20b31f83ca189986a9787bacc0514b | 302c785c90d40ad3d6be43d33bc6a558354cc2cf | /src/number_theory/quadratic_reciprocity.lean | f5bfb25fd6506d34405cde78590b5314bb5eb3f1 | [
"Apache-2.0"
] | permissive | ilitzroth/mathlib | ea647e67f1fdfd19a0f7bdc5504e8acec6180011 | 5254ef14e3465f6504306132fe3ba9cec9ffff16 | refs/heads/master | 1,680,086,661,182 | 1,617,715,647,000 | 1,617,715,647,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 24,951 | lean | /-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes
-/
import field_theory.finite.basic
import data.zmod.basic
import data.nat.parity
/-!
# Quadratic reciprocity.
This file contains results about quadratic residues modulo a prime number.
The main results are the law of quadratic reciprocity, `quadratic_reciprocity`, as well as the
interpretations in terms of existence of square roots depending on the congruence mod 4,
`exists_pow_two_eq_prime_iff_of_mod_four_eq_one`, and
`exists_pow_two_eq_prime_iff_of_mod_four_eq_three`.
Also proven are conditions for `-1` and `2` to be a square modulo a prime,
`exists_pow_two_eq_neg_one_iff_mod_four_ne_three` and
`exists_pow_two_eq_two_iff`
## Implementation notes
The proof of quadratic reciprocity implemented uses Gauss' lemma and Eisenstein's lemma
-/
open function finset nat finite_field zmod
open_locale big_operators nat
namespace zmod
variables (p q : ℕ) [fact p.prime] [fact q.prime]
/-- Euler's Criterion: A unit `x` of `zmod p` is a square if and only if `x ^ (p / 2) = 1`. -/
lemma euler_criterion_units (x : units (zmod p)) :
(∃ y : units (zmod p), y ^ 2 = x) ↔ x ^ (p / 2) = 1 :=
begin
cases nat.prime.eq_two_or_odd (fact.out p.prime) with hp2 hp_odd,
{ substI p, refine iff_of_true ⟨1, _⟩ _; apply subsingleton.elim },
obtain ⟨g, hg⟩ := is_cyclic.exists_generator (units (zmod p)),
obtain ⟨n, hn⟩ : x ∈ submonoid.powers g, { rw mem_powers_iff_mem_gpowers, apply hg },
split,
{ rintro ⟨y, rfl⟩, rw [← pow_mul, two_mul_odd_div_two hp_odd, units_pow_card_sub_one_eq_one], },
{ subst x, assume h,
have key : 2 * (p / 2) ∣ n * (p / 2),
{ rw [← pow_mul] at h,
rw [two_mul_odd_div_two hp_odd, ← card_units, ← order_of_eq_card_of_forall_mem_gpowers hg],
apply order_of_dvd_of_pow_eq_one h },
have : 0 < p / 2 := nat.div_pos (fact.out (1 < p)) dec_trivial,
obtain ⟨m, rfl⟩ := dvd_of_mul_dvd_mul_right this key,
refine ⟨g ^ m, _⟩,
rw [mul_comm, pow_mul], },
end
/-- Euler's Criterion: a nonzero `a : zmod p` is a square if and only if `x ^ (p / 2) = 1`. -/
lemma euler_criterion {a : zmod p} (ha : a ≠ 0) :
(∃ y : zmod p, y ^ 2 = a) ↔ a ^ (p / 2) = 1 :=
begin
apply (iff_congr _ (by simp [units.ext_iff])).mp (euler_criterion_units p (units.mk0 a ha)),
simp only [units.ext_iff, pow_two, units.coe_mk0, units.coe_mul],
split, { rintro ⟨y, hy⟩, exact ⟨y, hy⟩ },
{ rintro ⟨y, rfl⟩,
have hy : y ≠ 0, { rintro rfl, simpa [zero_pow] using ha, },
refine ⟨units.mk0 y hy, _⟩, simp, }
end
lemma exists_pow_two_eq_neg_one_iff_mod_four_ne_three :
(∃ y : zmod p, y ^ 2 = -1) ↔ p % 4 ≠ 3 :=
begin
cases nat.prime.eq_two_or_odd (fact.out p.prime) with hp2 hp_odd,
{ substI p, exact dec_trivial },
haveI := fact.mk hp_odd,
have neg_one_ne_zero : (-1 : zmod p) ≠ 0, from mt neg_eq_zero.1 one_ne_zero,
rw [euler_criterion p neg_one_ne_zero, neg_one_pow_eq_pow_mod_two],
cases mod_two_eq_zero_or_one (p / 2) with p_half_even p_half_odd,
{ rw [p_half_even, pow_zero, eq_self_iff_true, true_iff],
contrapose! p_half_even with hp,
rw [← nat.mod_mul_right_div_self, show 2 * 2 = 4, from rfl, hp],
exact dec_trivial },
{ rw [p_half_odd, pow_one,
iff_false_intro (ne_neg_self p one_ne_zero).symm, false_iff, not_not],
rw [← nat.mod_mul_right_div_self, show 2 * 2 = 4, from rfl] at p_half_odd,
rw [← nat.mod_mul_left_mod _ 2, show 2 * 2 = 4, from rfl] at hp_odd,
have hp : p % 4 < 4, from nat.mod_lt _ dec_trivial,
revert hp hp_odd p_half_odd,
generalize : p % 4 = k, dec_trivial! }
end
lemma pow_div_two_eq_neg_one_or_one {a : zmod p} (ha : a ≠ 0) :
a ^ (p / 2) = 1 ∨ a ^ (p / 2) = -1 :=
begin
cases nat.prime.eq_two_or_odd (fact.out p.prime) with hp2 hp_odd,
{ substI p, revert a ha, exact dec_trivial },
rw [← mul_self_eq_one_iff, ← pow_add, ← two_mul, two_mul_odd_div_two hp_odd],
exact pow_card_sub_one_eq_one ha
end
/-- Wilson's Lemma: the product of `1`, ..., `p-1` is `-1` modulo `p`. -/
@[simp] lemma wilsons_lemma : ((p - 1)! : zmod p) = -1 :=
begin
refine
calc ((p - 1)! : zmod p) = (∏ x in Ico 1 (succ (p - 1)), x) :
by rw [← finset.prod_Ico_id_eq_factorial, prod_nat_cast]
... = (∏ x : units (zmod p), x) : _
... = -1 :
by rw [prod_hom _ (coe : units (zmod p) → zmod p),
prod_univ_units_id_eq_neg_one, units.coe_neg, units.coe_one],
have hp : 0 < p := (fact.out p.prime).pos,
symmetry,
refine prod_bij (λ a _, (a : zmod p).val) _ _ _ _,
{ intros a ha,
rw [Ico.mem, ← nat.succ_sub hp, nat.succ_sub_one],
split,
{ apply nat.pos_of_ne_zero, rw ← @val_zero p,
assume h, apply units.ne_zero a (val_injective p h) },
{ exact val_lt _ } },
{ intros a ha, simp only [cast_id, nat_cast_val], },
{ intros _ _ _ _ h, rw units.ext_iff, exact val_injective p h },
{ intros b hb,
rw [Ico.mem, nat.succ_le_iff, ← succ_sub hp, succ_sub_one, pos_iff_ne_zero] at hb,
refine ⟨units.mk0 b _, finset.mem_univ _, _⟩,
{ assume h, apply hb.1, apply_fun val at h,
simpa only [val_cast_of_lt hb.right, val_zero] using h },
{ simp only [val_cast_of_lt hb.right, units.coe_mk0], } }
end
@[simp] lemma prod_Ico_one_prime : (∏ x in Ico 1 p, (x : zmod p)) = -1 :=
begin
conv in (Ico 1 p) { rw [← succ_sub_one p, succ_sub (fact.out p.prime).pos] },
rw [← prod_nat_cast, finset.prod_Ico_id_eq_factorial, wilsons_lemma]
end
end zmod
/-- The image of the map sending a non zero natural number `x ≤ p / 2` to the absolute value
of the element of interger in the interval `(-p/2, p/2]` congruent to `a * x` mod p is the set
of non zero natural numbers `x` such that `x ≤ p / 2` -/
lemma Ico_map_val_min_abs_nat_abs_eq_Ico_map_id
(p : ℕ) [hp : fact p.prime] (a : zmod p) (hap : a ≠ 0) :
(Ico 1 (p / 2).succ).1.map (λ x, (a * x).val_min_abs.nat_abs) =
(Ico 1 (p / 2).succ).1.map (λ a, a) :=
begin
have he : ∀ {x}, x ∈ Ico 1 (p / 2).succ → x ≠ 0 ∧ x ≤ p / 2,
by simp [nat.lt_succ_iff, nat.succ_le_iff, pos_iff_ne_zero] {contextual := tt},
have hep : ∀ {x}, x ∈ Ico 1 (p / 2).succ → x < p,
from λ x hx, lt_of_le_of_lt (he hx).2 (nat.div_lt_self hp.1.pos dec_trivial),
have hpe : ∀ {x}, x ∈ Ico 1 (p / 2).succ → ¬ p ∣ x,
from λ x hx hpx, not_lt_of_ge (le_of_dvd (nat.pos_of_ne_zero (he hx).1) hpx) (hep hx),
have hmem : ∀ (x : ℕ) (hx : x ∈ Ico 1 (p / 2).succ),
(a * x : zmod p).val_min_abs.nat_abs ∈ Ico 1 (p / 2).succ,
{ assume x hx,
simp [hap, char_p.cast_eq_zero_iff (zmod p) p, hpe hx, lt_succ_iff, succ_le_iff,
pos_iff_ne_zero, nat_abs_val_min_abs_le _], },
have hsurj : ∀ (b : ℕ) (hb : b ∈ Ico 1 (p / 2).succ),
∃ x ∈ Ico 1 (p / 2).succ, b = (a * x : zmod p).val_min_abs.nat_abs,
{ assume b hb,
refine ⟨(b / a : zmod p).val_min_abs.nat_abs, Ico.mem.mpr ⟨_, _⟩, _⟩,
{ apply nat.pos_of_ne_zero,
simp only [div_eq_mul_inv, hap, char_p.cast_eq_zero_iff (zmod p) p, hpe hb, not_false_iff,
val_min_abs_eq_zero, inv_eq_zero, int.nat_abs_eq_zero, ne.def, mul_eq_zero, or_self] },
{ apply lt_succ_of_le, apply nat_abs_val_min_abs_le },
{ rw nat_cast_nat_abs_val_min_abs,
split_ifs,
{ erw [mul_div_cancel' _ hap, val_min_abs_def_pos, val_cast_of_lt (hep hb),
if_pos (le_of_lt_succ (Ico.mem.1 hb).2), int.nat_abs_of_nat], },
{ erw [mul_neg_eq_neg_mul_symm, mul_div_cancel' _ hap, nat_abs_val_min_abs_neg,
val_min_abs_def_pos, val_cast_of_lt (hep hb), if_pos (le_of_lt_succ (Ico.mem.1 hb).2),
int.nat_abs_of_nat] } } },
exact multiset.map_eq_map_of_bij_of_nodup _ _ (finset.nodup _) (finset.nodup _)
(λ x _, (a * x : zmod p).val_min_abs.nat_abs) hmem (λ _ _, rfl)
(inj_on_of_surj_on_of_card_le _ hmem hsurj (le_refl _)) hsurj
end
private lemma gauss_lemma_aux₁ (p : ℕ) [fact p.prime] [fact (p % 2 = 1)]
{a : ℕ} (hap : (a : zmod p) ≠ 0) :
(a^(p / 2) * (p / 2)! : zmod p) =
(-1)^((Ico 1 (p / 2).succ).filter
(λ x : ℕ, ¬(a * x : zmod p).val ≤ p / 2)).card * (p / 2)! :=
calc (a ^ (p / 2) * (p / 2)! : zmod p) =
(∏ x in Ico 1 (p / 2).succ, a * x) :
by rw [prod_mul_distrib, ← prod_nat_cast, ← prod_nat_cast, prod_Ico_id_eq_factorial,
prod_const, Ico.card, succ_sub_one]; simp
... = (∏ x in Ico 1 (p / 2).succ, (a * x : zmod p).val) : by simp
... = (∏ x in Ico 1 (p / 2).succ,
(if (a * x : zmod p).val ≤ p / 2 then 1 else -1) *
(a * x : zmod p).val_min_abs.nat_abs) :
prod_congr rfl $ λ _ _, begin
simp only [nat_cast_nat_abs_val_min_abs],
split_ifs; simp
end
... = (-1)^((Ico 1 (p / 2).succ).filter
(λ x : ℕ, ¬(a * x : zmod p).val ≤ p / 2)).card *
(∏ x in Ico 1 (p / 2).succ, (a * x : zmod p).val_min_abs.nat_abs) :
have (∏ x in Ico 1 (p / 2).succ,
if (a * x : zmod p).val ≤ p / 2 then (1 : zmod p) else -1) =
(∏ x in (Ico 1 (p / 2).succ).filter
(λ x : ℕ, ¬(a * x : zmod p).val ≤ p / 2), -1),
from prod_bij_ne_one (λ x _ _, x)
(λ x, by split_ifs; simp * at * {contextual := tt})
(λ _ _ _ _ _ _, id)
(λ b h _, ⟨b, by simp [-not_le, *] at *⟩)
(by intros; split_ifs at *; simp * at *),
by rw [prod_mul_distrib, this]; simp
... = (-1)^((Ico 1 (p / 2).succ).filter
(λ x : ℕ, ¬(a * x : zmod p).val ≤ p / 2)).card * (p / 2)! :
by rw [← prod_nat_cast, finset.prod_eq_multiset_prod,
Ico_map_val_min_abs_nat_abs_eq_Ico_map_id p a hap,
← finset.prod_eq_multiset_prod, prod_Ico_id_eq_factorial]
private lemma gauss_lemma_aux₂ (p : ℕ) [hp : fact p.prime] [fact (p % 2 = 1)]
{a : ℕ} (hap : (a : zmod p) ≠ 0) :
(a^(p / 2) : zmod p) = (-1)^((Ico 1 (p / 2).succ).filter
(λ x : ℕ, p / 2 < (a * x : zmod p).val)).card :=
(mul_left_inj'
(show ((p / 2)! : zmod p) ≠ 0,
by rw [ne.def, char_p.cast_eq_zero_iff (zmod p) p, hp.1.dvd_factorial, not_le];
exact nat.div_lt_self hp.1.pos dec_trivial)).1 $
by simpa using gauss_lemma_aux₁ p hap
private lemma eisenstein_lemma_aux₁ (p : ℕ) [fact p.prime] [hp2 : fact (p % 2 = 1)]
{a : ℕ} (hap : (a : zmod p) ≠ 0) :
((∑ x in Ico 1 (p / 2).succ, a * x : ℕ) : zmod 2) =
((Ico 1 (p / 2).succ).filter
((λ x : ℕ, p / 2 < (a * x : zmod p).val))).card +
∑ x in Ico 1 (p / 2).succ, x
+ (∑ x in Ico 1 (p / 2).succ, (a * x) / p : ℕ) :=
have hp2 : (p : zmod 2) = (1 : ℕ), from (eq_iff_modeq_nat _).2 hp2.1,
calc ((∑ x in Ico 1 (p / 2).succ, a * x : ℕ) : zmod 2)
= ((∑ x in Ico 1 (p / 2).succ, ((a * x) % p + p * ((a * x) / p)) : ℕ) : zmod 2) :
by simp only [mod_add_div]
... = (∑ x in Ico 1 (p / 2).succ, ((a * x : ℕ) : zmod p).val : ℕ) +
(∑ x in Ico 1 (p / 2).succ, (a * x) / p : ℕ) :
by simp only [val_nat_cast];
simp [sum_add_distrib, mul_sum.symm, nat.cast_add, nat.cast_mul, sum_nat_cast, hp2]
... = _ : congr_arg2 (+)
(calc ((∑ x in Ico 1 (p / 2).succ, ((a * x : ℕ) : zmod p).val : ℕ) : zmod 2)
= ∑ x in Ico 1 (p / 2).succ,
((((a * x : zmod p).val_min_abs +
(if (a * x : zmod p).val ≤ p / 2 then 0 else p)) : ℤ) : zmod 2) :
by simp only [(val_eq_ite_val_min_abs _).symm]; simp [sum_nat_cast]
... = ((Ico 1 (p / 2).succ).filter
(λ x : ℕ, p / 2 < (a * x : zmod p).val)).card +
((∑ x in Ico 1 (p / 2).succ, (a * x : zmod p).val_min_abs.nat_abs) : ℕ) :
by { simp [ite_cast, add_comm, sum_add_distrib, finset.sum_ite, hp2, sum_nat_cast], }
... = _ : by rw [finset.sum_eq_multiset_sum,
Ico_map_val_min_abs_nat_abs_eq_Ico_map_id p a hap,
← finset.sum_eq_multiset_sum];
simp [sum_nat_cast]) rfl
private lemma eisenstein_lemma_aux₂ (p : ℕ) [fact p.prime] [fact (p % 2 = 1)]
{a : ℕ} (ha2 : a % 2 = 1) (hap : (a : zmod p) ≠ 0) :
((Ico 1 (p / 2).succ).filter
((λ x : ℕ, p / 2 < (a * x : zmod p).val))).card
≡ ∑ x in Ico 1 (p / 2).succ, (x * a) / p [MOD 2] :=
have ha2 : (a : zmod 2) = (1 : ℕ), from (eq_iff_modeq_nat _).2 ha2,
(eq_iff_modeq_nat 2).1 $ sub_eq_zero.1 $
by simpa [add_left_comm, sub_eq_add_neg, finset.mul_sum.symm, mul_comm, ha2, sum_nat_cast,
add_neg_eq_iff_eq_add.symm, neg_eq_self_mod_two, add_assoc]
using eq.symm (eisenstein_lemma_aux₁ p hap)
lemma div_eq_filter_card {a b c : ℕ} (hb0 : 0 < b) (hc : a / b ≤ c) : a / b =
((Ico 1 c.succ).filter (λ x, x * b ≤ a)).card :=
calc a / b = (Ico 1 (a / b).succ).card : by simp
... = ((Ico 1 c.succ).filter (λ x, x * b ≤ a)).card :
congr_arg _ $ finset.ext $ λ x,
have x * b ≤ a → x ≤ c,
from λ h, le_trans (by rwa [le_div_iff_mul_le _ _ hb0]) hc,
by simp [lt_succ_iff, le_div_iff_mul_le _ _ hb0]; tauto
/-- The given sum is the number of integer points in the triangle formed by the diagonal of the
rectangle `(0, p/2) × (0, q/2)` -/
private lemma sum_Ico_eq_card_lt {p q : ℕ} :
∑ a in Ico 1 (p / 2).succ, (a * q) / p =
(((Ico 1 (p / 2).succ).product (Ico 1 (q / 2).succ)).filter
(λ x : ℕ × ℕ, x.2 * p ≤ x.1 * q)).card :=
if hp0 : p = 0 then by simp [hp0, finset.ext_iff]
else
calc ∑ a in Ico 1 (p / 2).succ, (a * q) / p =
∑ a in Ico 1 (p / 2).succ,
((Ico 1 (q / 2).succ).filter (λ x, x * p ≤ a * q)).card :
finset.sum_congr rfl $ λ x hx,
div_eq_filter_card (nat.pos_of_ne_zero hp0)
(calc x * q / p ≤ (p / 2) * q / p :
nat.div_le_div_right (mul_le_mul_of_nonneg_right
(le_of_lt_succ $ by finish)
(nat.zero_le _))
... ≤ _ : nat.div_mul_div_le_div _ _ _)
... = _ : by rw [← card_sigma];
exact card_congr (λ a _, ⟨a.1, a.2⟩)
(by simp only [mem_filter, mem_sigma, and_self, forall_true_iff, mem_product]
{contextual := tt})
(λ ⟨_, _⟩ ⟨_, _⟩, by simp only [prod.mk.inj_iff, eq_self_iff_true, and_self, heq_iff_eq,
forall_true_iff] {contextual := tt})
(λ ⟨b₁, b₂⟩ h, ⟨⟨b₁, b₂⟩,
by revert h; simp only [mem_filter, eq_self_iff_true, exists_prop_of_true, mem_sigma,
and_self, forall_true_iff, mem_product] {contextual := tt}⟩)
/-- Each of the sums in this lemma is the cardinality of the set integer points in each of the
two triangles formed by the diagonal of the rectangle `(0, p/2) × (0, q/2)`. Adding them
gives the number of points in the rectangle. -/
private lemma sum_mul_div_add_sum_mul_div_eq_mul (p q : ℕ) [hp : fact p.prime]
(hq0 : (q : zmod p) ≠ 0) :
∑ a in Ico 1 (p / 2).succ, (a * q) / p +
∑ a in Ico 1 (q / 2).succ, (a * p) / q =
(p / 2) * (q / 2) :=
begin
have hswap : (((Ico 1 (q / 2).succ).product (Ico 1 (p / 2).succ)).filter
(λ x : ℕ × ℕ, x.2 * q ≤ x.1 * p)).card =
(((Ico 1 (p / 2).succ).product (Ico 1 (q / 2).succ)).filter
(λ x : ℕ × ℕ, x.1 * q ≤ x.2 * p)).card :=
card_congr (λ x _, prod.swap x)
(λ ⟨_, _⟩, by simp only [mem_filter, and_self, prod.swap_prod_mk, forall_true_iff, mem_product]
{contextual := tt})
(λ ⟨_, _⟩ ⟨_, _⟩, by simp only [prod.mk.inj_iff, eq_self_iff_true, and_self, prod.swap_prod_mk,
forall_true_iff] {contextual := tt})
(λ ⟨x₁, x₂⟩ h, ⟨⟨x₂, x₁⟩, by revert h; simp only [mem_filter, eq_self_iff_true, and_self,
exists_prop_of_true, prod.swap_prod_mk, forall_true_iff, mem_product] {contextual := tt}⟩),
have hdisj : disjoint
(((Ico 1 (p / 2).succ).product (Ico 1 (q / 2).succ)).filter
(λ x : ℕ × ℕ, x.2 * p ≤ x.1 * q))
(((Ico 1 (p / 2).succ).product (Ico 1 (q / 2).succ)).filter
(λ x : ℕ × ℕ, x.1 * q ≤ x.2 * p)),
{ apply disjoint_filter.2 (λ x hx hpq hqp, _),
have hxp : x.1 < p, from lt_of_le_of_lt
(show x.1 ≤ p / 2, by simp only [*, lt_succ_iff, Ico.mem, mem_product] at *; tauto)
(nat.div_lt_self hp.1.pos dec_trivial),
have : (x.1 : zmod p) = 0,
{ simpa [hq0] using congr_arg (coe : ℕ → zmod p) (le_antisymm hpq hqp) },
apply_fun zmod.val at this,
rw [val_cast_of_lt hxp, val_zero] at this,
simpa only [this, nonpos_iff_eq_zero, Ico.mem, one_ne_zero, false_and, mem_product] using hx },
have hunion : ((Ico 1 (p / 2).succ).product (Ico 1 (q / 2).succ)).filter
(λ x : ℕ × ℕ, x.2 * p ≤ x.1 * q) ∪
((Ico 1 (p / 2).succ).product (Ico 1 (q / 2).succ)).filter
(λ x : ℕ × ℕ, x.1 * q ≤ x.2 * p) =
((Ico 1 (p / 2).succ).product (Ico 1 (q / 2).succ)),
from finset.ext (λ x, by have := le_total (x.2 * p) (x.1 * q);
simp only [mem_union, mem_filter, Ico.mem, mem_product]; tauto),
rw [sum_Ico_eq_card_lt, sum_Ico_eq_card_lt, hswap, ← card_disjoint_union hdisj, hunion,
card_product],
simp only [Ico.card, nat.sub_zero, succ_sub_succ_eq_sub]
end
variables (p q : ℕ) [fact p.prime] [fact q.prime]
namespace zmod
/-- The Legendre symbol of `a` and `p` is an integer defined as
* `0` if `a` is `0` modulo `p`;
* `1` if `a ^ (p / 2)` is `1` modulo `p`
(by `euler_criterion` this is equivalent to “`a` is a square modulo `p`”);
* `-1` otherwise.
-/
def legendre_sym (a p : ℕ) : ℤ :=
if (a : zmod p) = 0 then 0
else if (a : zmod p) ^ (p / 2) = 1 then 1
else -1
lemma legendre_sym_eq_pow (a p : ℕ) [hp : fact p.prime] :
(legendre_sym a p : zmod p) = (a ^ (p / 2)) :=
begin
rw legendre_sym,
by_cases ha : (a : zmod p) = 0,
{ simp only [if_pos, ha, zero_pow (nat.div_pos (hp.1.two_le) (succ_pos 1)), int.cast_zero] },
cases hp.1.eq_two_or_odd with hp2 hp_odd,
{ substI p,
generalize : (a : (zmod 2)) = b, revert b, dec_trivial, },
{ haveI := fact.mk hp_odd,
rw if_neg ha,
have : (-1 : zmod p) ≠ 1, from (ne_neg_self p one_ne_zero).symm,
cases pow_div_two_eq_neg_one_or_one p ha with h h,
{ rw [if_pos h, h, int.cast_one], },
{ rw [h, if_neg this, int.cast_neg, int.cast_one], } }
end
lemma legendre_sym_eq_one_or_neg_one (a p : ℕ) (ha : (a : zmod p) ≠ 0) :
legendre_sym a p = -1 ∨ legendre_sym a p = 1 :=
by unfold legendre_sym; split_ifs; simp only [*, eq_self_iff_true, or_true, true_or] at *
lemma legendre_sym_eq_zero_iff (a p : ℕ) :
legendre_sym a p = 0 ↔ (a : zmod p) = 0 :=
begin
split,
{ classical, contrapose,
assume ha, cases legendre_sym_eq_one_or_neg_one a p ha with h h,
all_goals { rw h, norm_num } },
{ assume ha, rw [legendre_sym, if_pos ha] }
end
/-- Gauss' lemma. The legendre symbol can be computed by considering the number of naturals less
than `p/2` such that `(a * x) % p > p / 2` -/
lemma gauss_lemma {a : ℕ} [fact (p % 2 = 1)] (ha0 : (a : zmod p) ≠ 0) :
legendre_sym a p = (-1) ^ ((Ico 1 (p / 2).succ).filter
(λ x : ℕ, p / 2 < (a * x : zmod p).val)).card :=
have (legendre_sym a p : zmod p) = (((-1)^((Ico 1 (p / 2).succ).filter
(λ x : ℕ, p / 2 < (a * x : zmod p).val)).card : ℤ) : zmod p),
by rw [legendre_sym_eq_pow, gauss_lemma_aux₂ p ha0]; simp,
begin
cases legendre_sym_eq_one_or_neg_one a p ha0;
cases neg_one_pow_eq_or ℤ ((Ico 1 (p / 2).succ).filter
(λ x : ℕ, p / 2 < (a * x : zmod p).val)).card;
simp [*, ne_neg_self p one_ne_zero, (ne_neg_self p one_ne_zero).symm] at *
end
lemma legendre_sym_eq_one_iff {a : ℕ} (ha0 : (a : zmod p) ≠ 0) :
legendre_sym a p = 1 ↔ (∃ b : zmod p, b ^ 2 = a) :=
begin
rw [euler_criterion p ha0, legendre_sym, if_neg ha0],
split_ifs,
{ simp only [h, eq_self_iff_true] },
finish -- this is quite slow. I'm actually surprised that it can close the goal at all!
end
lemma eisenstein_lemma [fact (p % 2 = 1)] {a : ℕ} (ha1 : a % 2 = 1) (ha0 : (a : zmod p) ≠ 0) :
legendre_sym a p = (-1)^∑ x in Ico 1 (p / 2).succ, (x * a) / p :=
by rw [neg_one_pow_eq_pow_mod_two, gauss_lemma p ha0, neg_one_pow_eq_pow_mod_two,
show _ = _, from eisenstein_lemma_aux₂ p ha1 ha0]
theorem quadratic_reciprocity [hp1 : fact (p % 2 = 1)] [hq1 : fact (q % 2 = 1)] (hpq : p ≠ q) :
legendre_sym p q * legendre_sym q p = (-1) ^ ((p / 2) * (q / 2)) :=
have hpq0 : (p : zmod q) ≠ 0, from prime_ne_zero q p hpq.symm,
have hqp0 : (q : zmod p) ≠ 0, from prime_ne_zero p q hpq,
by rw [eisenstein_lemma q hp1.1 hpq0, eisenstein_lemma p hq1.1 hqp0,
← pow_add, sum_mul_div_add_sum_mul_div_eq_mul q p hpq0, mul_comm]
-- move this
local attribute [instance]
lemma fact_prime_two : fact (nat.prime 2) := ⟨nat.prime_two⟩
lemma legendre_sym_two [hp1 : fact (p % 2 = 1)] : legendre_sym 2 p = (-1) ^ (p / 4 + p / 2) :=
have hp2 : p ≠ 2, from mt (congr_arg (% 2)) (by simpa using hp1.1),
have hp22 : p / 2 / 2 = _ := div_eq_filter_card (show 0 < 2, from dec_trivial)
(nat.div_le_self (p / 2) 2),
have hcard : (Ico 1 (p / 2).succ).card = p / 2, by simp,
have hx2 : ∀ x ∈ Ico 1 (p / 2).succ, (2 * x : zmod p).val = 2 * x,
from λ x hx, have h2xp : 2 * x < p,
from calc 2 * x ≤ 2 * (p / 2) : mul_le_mul_of_nonneg_left
(le_of_lt_succ $ by finish) dec_trivial
... < _ : by conv_rhs {rw [← div_add_mod p 2, hp1.1]}; exact lt_succ_self _,
by rw [← nat.cast_two, ← nat.cast_mul, val_cast_of_lt h2xp],
have hdisj : disjoint
((Ico 1 (p / 2).succ).filter (λ x, p / 2 < ((2 : ℕ) * x : zmod p).val))
((Ico 1 (p / 2).succ).filter (λ x, x * 2 ≤ p / 2)),
from disjoint_filter.2 (λ x hx, by simp [hx2 _ hx, mul_comm]),
have hunion :
((Ico 1 (p / 2).succ).filter (λ x, p / 2 < ((2 : ℕ) * x : zmod p).val)) ∪
((Ico 1 (p / 2).succ).filter (λ x, x * 2 ≤ p / 2)) =
Ico 1 (p / 2).succ,
begin
rw [filter_union_right],
conv_rhs {rw [← @filter_true _ (Ico 1 (p / 2).succ)]},
exact filter_congr (λ x hx, by simp [hx2 _ hx, lt_or_le, mul_comm])
end,
begin
rw [gauss_lemma p (prime_ne_zero p 2 hp2),
neg_one_pow_eq_pow_mod_two, @neg_one_pow_eq_pow_mod_two _ _ (p / 4 + p / 2)],
refine congr_arg2 _ rfl ((eq_iff_modeq_nat 2).1 _),
rw [show 4 = 2 * 2, from rfl, ← nat.div_div_eq_div_mul, hp22, nat.cast_add,
← sub_eq_iff_eq_add', sub_eq_add_neg, neg_eq_self_mod_two,
← nat.cast_add, ← card_disjoint_union hdisj, hunion, hcard]
end
lemma exists_pow_two_eq_two_iff [hp1 : fact (p % 2 = 1)] :
(∃ a : zmod p, a ^ 2 = 2) ↔ p % 8 = 1 ∨ p % 8 = 7 :=
have hp2 : ((2 : ℕ) : zmod p) ≠ 0,
from prime_ne_zero p 2 (λ h, by simpa [h] using hp1.1),
have hpm4 : p % 4 = p % 8 % 4, from (nat.mod_mul_left_mod p 2 4).symm,
have hpm2 : p % 2 = p % 8 % 2, from (nat.mod_mul_left_mod p 4 2).symm,
begin
rw [show (2 : zmod p) = (2 : ℕ), by simp, ← legendre_sym_eq_one_iff p hp2,
legendre_sym_two p, neg_one_pow_eq_one_iff_even (show (-1 : ℤ) ≠ 1, from dec_trivial),
even_add, even_div, even_div],
have := nat.mod_lt p (show 0 < 8, from dec_trivial),
resetI, rw fact_iff at hp1,
revert this hp1,
erw [hpm4, hpm2],
generalize hm : p % 8 = m, unfreezingI {clear_dependent p},
dec_trivial!,
end
lemma exists_pow_two_eq_prime_iff_of_mod_four_eq_one (hp1 : p % 4 = 1) [hq1 : fact (q % 2 = 1)] :
(∃ a : zmod p, a ^ 2 = q) ↔ ∃ b : zmod q, b ^ 2 = p :=
if hpq : p = q then by substI hpq else
have h1 : ((p / 2) * (q / 2)) % 2 = 0,
from (dvd_iff_mod_eq_zero _ _).1
(dvd_mul_of_dvd_left ((dvd_iff_mod_eq_zero _ _).2 $
by rw [← mod_mul_right_div_self, show 2 * 2 = 4, from rfl, hp1]; refl) _),
begin
haveI hp_odd : fact (p % 2 = 1) := ⟨odd_of_mod_four_eq_one hp1⟩,
have hpq0 : (p : zmod q) ≠ 0 := prime_ne_zero q p (ne.symm hpq),
have hqp0 : (q : zmod p) ≠ 0 := prime_ne_zero p q hpq,
have := quadratic_reciprocity p q hpq,
rw [neg_one_pow_eq_pow_mod_two, h1, legendre_sym, legendre_sym,
if_neg hqp0, if_neg hpq0] at this,
rw [euler_criterion q hpq0, euler_criterion p hqp0],
split_ifs at this; simp *; contradiction,
end
lemma exists_pow_two_eq_prime_iff_of_mod_four_eq_three (hp3 : p % 4 = 3)
(hq3 : q % 4 = 3) (hpq : p ≠ q) : (∃ a : zmod p, a ^ 2 = q) ↔ ¬∃ b : zmod q, b ^ 2 = p :=
have h1 : ((p / 2) * (q / 2)) % 2 = 1,
from nat.odd_mul_odd
(by rw [← mod_mul_right_div_self, show 2 * 2 = 4, from rfl, hp3]; refl)
(by rw [← mod_mul_right_div_self, show 2 * 2 = 4, from rfl, hq3]; refl),
begin
haveI hp_odd : fact (p % 2 = 1) := ⟨odd_of_mod_four_eq_three hp3⟩,
haveI hq_odd : fact (q % 2 = 1) := ⟨odd_of_mod_four_eq_three hq3⟩,
have hpq0 : (p : zmod q) ≠ 0 := prime_ne_zero q p (ne.symm hpq),
have hqp0 : (q : zmod p) ≠ 0 := prime_ne_zero p q hpq,
have := quadratic_reciprocity p q hpq,
rw [neg_one_pow_eq_pow_mod_two, h1, legendre_sym, legendre_sym,
if_neg hpq0, if_neg hqp0] at this,
rw [euler_criterion q hpq0, euler_criterion p hqp0],
split_ifs at this; simp *; contradiction
end
end zmod
|
63551d406fcefe0c3cb09068c4c3573a10076f15 | cbcb0199842f03e7606d4e43666573fc15dd07a5 | /src/topology/algebra/group_completion.lean | 779800cb89bf94e86027bfeccc870f73bff85dbb | [
"Apache-2.0"
] | permissive | truonghoangle/mathlib | a6a7c14b3767ec71156239d8ea97f6921fe79627 | 673bae584febcd830c2c9256eb7e7a81e27ed303 | refs/heads/master | 1,590,347,998,944 | 1,559,728,860,000 | 1,559,728,860,000 | 187,431,971 | 0 | 0 | null | 1,558,238,525,000 | 1,558,238,525,000 | null | UTF-8 | Lean | false | false | 5,555 | lean | /-
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
Completion of topological groups:
-/
import topology.uniform_space.completion topology.algebra.uniform_group
noncomputable theory
section group
open uniform_space Cauchy filter set
variables {α : Type*} [uniform_space α]
instance [has_zero α] : has_zero (completion α) := ⟨(0 : α)⟩
instance [has_neg α] : has_neg (completion α) := ⟨completion.map (λa, -a : α → α)⟩
instance [has_add α] : has_add (completion α) := ⟨completion.map₂ (+)⟩
lemma coe_zero [has_zero α] : ((0 : α) : completion α) = 0 := rfl
end group
namespace uniform_space.completion
section uniform_add_group
open uniform_space uniform_space.completion
variables {α : Type*} [uniform_space α] [add_group α] [uniform_add_group α]
lemma coe_neg (a : α) : ((- a : α) : completion α) = - a :=
(map_coe uniform_continuous_neg' a).symm
lemma coe_add (a b : α) : ((a + b : α) : completion α) = a + b :=
(map₂_coe_coe a b (+) uniform_continuous_add').symm
instance : add_group (completion α) :=
{ zero_add := assume a, completion.induction_on a
(is_closed_eq (continuous_map₂ continuous_const continuous_id) continuous_id)
(assume a, show 0 + (a : completion α) = a, by rw [← coe_zero, ← coe_add, zero_add]),
add_zero := assume a, completion.induction_on a
(is_closed_eq (continuous_map₂ continuous_id continuous_const) continuous_id)
(assume a, show (a : completion α) + 0 = a, by rw [← coe_zero, ← coe_add, add_zero]),
add_left_neg := assume a, completion.induction_on a
(is_closed_eq (continuous_map₂ completion.continuous_map continuous_id) continuous_const)
(assume a, show - (a : completion α) + a = 0, by rw [← coe_neg, ← coe_add, add_left_neg, coe_zero]),
add_assoc := assume a b c, completion.induction_on₃ a b c
(is_closed_eq
(continuous_map₂
(continuous_map₂ continuous_fst (continuous_fst.comp continuous_snd)) (continuous_snd.comp continuous_snd))
(continuous_map₂ continuous_fst
(continuous_map₂ (continuous_fst.comp continuous_snd) (continuous_snd.comp continuous_snd))))
(assume a b c, show (a : completion α) + b + c = a + (b + c),
by repeat { rw [← coe_add] }; rw [add_assoc]),
.. completion.has_zero, .. completion.has_neg, ..completion.has_add }
instance : uniform_add_group (completion α) :=
⟨ (uniform_continuous.prod_mk uniform_continuous_fst
(uniform_continuous_snd.comp uniform_continuous_map)).comp (uniform_continuous_map₂' (+)) ⟩
instance is_add_group_hom_coe : is_add_group_hom (coe : α → completion α) :=
⟨ coe_add ⟩
variables {β : Type*} [uniform_space β] [add_group β] [uniform_add_group β]
lemma is_add_group_hom_extension [complete_space β] [separated β]
{f : α → β} [is_add_group_hom f] (hf : continuous f) : is_add_group_hom (completion.extension f) :=
have hf : uniform_continuous f, from uniform_continuous_of_continuous hf,
⟨assume a b, completion.induction_on₂ a b
(is_closed_eq
(continuous_extension.comp continuous_add')
(continuous_add (continuous_extension.comp continuous_fst) (continuous_extension.comp continuous_snd)))
(assume a b, by rw [← coe_add, extension_coe hf, extension_coe hf, extension_coe hf, is_add_group_hom.map_add f])⟩
lemma is_add_group_hom_map [add_group β] [uniform_add_group β]
{f : α → β} [is_add_group_hom f] (hf : continuous f) : is_add_group_hom (completion.map f) :=
is_add_group_hom_extension ((continuous_coe _).comp hf)
section instance_max_depth
-- TODO: continuous_add requires some long proofs through
-- uniform_add_group / topological_add_group w.r.t prod / completion etc
set_option class.instance_max_depth 52
lemma is_add_group_hom_prod [add_group β] [uniform_add_group β] :
is_add_group_hom (@completion.prod α β _ _) :=
⟨assume ⟨a₁, a₂⟩ ⟨b₁, b₂⟩,
begin
refine completion.induction_on₄ a₁ a₂ b₁ b₂ (is_closed_eq _ _) _,
{ refine continuous.comp uniform_continuous_prod.continuous _ ,
refine continuous_add _ _,
exact continuous.prod_mk (continuous_fst.comp continuous_fst) (continuous_snd.comp continuous_fst),
exact continuous.prod_mk (continuous_fst.comp continuous_snd) (continuous_snd.comp continuous_snd) },
{ refine continuous_add _ _,
refine continuous.comp uniform_continuous_prod.continuous _,
exact continuous.prod_mk (continuous_fst.comp continuous_fst) (continuous_snd.comp continuous_fst),
refine continuous.comp uniform_continuous_prod.continuous _,
exact continuous.prod_mk (continuous_fst.comp continuous_snd) (continuous_snd.comp continuous_snd) },
{ assume a b c d,
show completion.prod (↑a + ↑c, ↑b + ↑d) = completion.prod (↑a, ↑b) + completion.prod (↑c, ↑d),
rw [← coe_add, ← coe_add, prod_coe_coe, prod_coe_coe, prod_coe_coe, ← coe_add],
refl }
end⟩
end instance_max_depth
instance {α : Type*} [uniform_space α] [add_comm_group α] [uniform_add_group α] : add_comm_group (completion α) :=
{ add_comm := assume a b, completion.induction_on₂ a b
(is_closed_eq (continuous_map₂ continuous_fst continuous_snd) (continuous_map₂ continuous_snd continuous_fst))
(assume x y, by { change ↑x + ↑y = ↑y + ↑x, rw [← coe_add, ← coe_add, add_comm]}),
.. completion.add_group }
end uniform_add_group
end uniform_space.completion
|
46a8186c46dd560d35af28fa29ffdbea82e04012 | 9dc8cecdf3c4634764a18254e94d43da07142918 | /src/analysis/complex/arg.lean | 34e540b1e5dd077fc4cecc9c0e8ba56869127b82 | [
"Apache-2.0"
] | permissive | jcommelin/mathlib | d8456447c36c176e14d96d9e76f39841f69d2d9b | ee8279351a2e434c2852345c51b728d22af5a156 | refs/heads/master | 1,664,782,136,488 | 1,663,638,983,000 | 1,663,638,983,000 | 132,563,656 | 0 | 0 | Apache-2.0 | 1,663,599,929,000 | 1,525,760,539,000 | Lean | UTF-8 | Lean | false | false | 1,978 | lean | /-
Copyright (c) 2022 Eric Rodriguez. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Eric Rodriguez
-/
import analysis.inner_product_space.basic
import analysis.special_functions.complex.arg
/-!
# Rays in the complex numbers
This file links the definition `same_ray ℝ x y` with the equality of arguments of complex numbers,
the usual way this is considered.
## Main statements
* `complex.same_ray_iff` : Two complex numbers are on the same ray iff one of them is zero, or they
have the same argument.
* `complex.abs_add_eq/complex.abs_sub_eq`: If two non zero complex numbers have different argument,
then the triangle inequality becomes strict.
-/
variables {x y : ℂ}
namespace complex
lemma same_ray_iff : same_ray ℝ x y ↔ x = 0 ∨ y = 0 ∨ x.arg = y.arg :=
begin
rcases eq_or_ne x 0 with rfl | hx,
{ simp },
rcases eq_or_ne y 0 with rfl | hy,
{ simp },
simp only [hx, hy, false_or, same_ray_iff_norm_smul_eq, arg_eq_arg_iff hx hy],
field_simp [hx, hy],
rw [mul_comm, eq_comm]
end
lemma same_ray_iff_arg_div_eq_zero : same_ray ℝ x y ↔ arg (x / y) = 0 :=
begin
rw [←real.angle.to_real_zero, ←arg_coe_angle_eq_iff_eq_to_real, same_ray_iff],
by_cases hx : x = 0, { simp [hx] },
by_cases hy : y = 0, { simp [hy] },
simp [hx, hy, arg_div_coe_angle, sub_eq_zero]
end
lemma abs_add_eq_iff : (x + y).abs = x.abs + y.abs ↔ x = 0 ∨ y = 0 ∨ x.arg = y.arg :=
same_ray_iff_norm_add.symm.trans same_ray_iff
lemma abs_sub_eq_iff : (x - y).abs = |x.abs - y.abs| ↔ x = 0 ∨ y = 0 ∨ x.arg = y.arg :=
same_ray_iff_norm_sub.symm.trans same_ray_iff
lemma same_ray_of_arg_eq (h : x.arg = y.arg) : same_ray ℝ x y :=
same_ray_iff.mpr $ or.inr $ or.inr h
lemma abs_add_eq (h : x.arg = y.arg) : (x + y).abs = x.abs + y.abs :=
(same_ray_of_arg_eq h).norm_add
lemma abs_sub_eq (h : x.arg = y.arg) : (x - y).abs = ∥x.abs - y.abs∥ :=
(same_ray_of_arg_eq h).norm_sub
end complex
|
95a2d9c44a13ef87ef44eb51e61b3c5e2a13970b | 6432ea7a083ff6ba21ea17af9ee47b9c371760f7 | /tests/lean/jpClosureIssue.lean | c75d6d2e6f78599ddb6477c319dfc61ccb26cf04 | [
"Apache-2.0",
"LLVM-exception",
"NCSA",
"LGPL-3.0-only",
"LicenseRef-scancode-inner-net-2.0",
"BSD-3-Clause",
"LGPL-2.0-or-later",
"Spencer-94",
"LGPL-2.1-or-later",
"HPND",
"LicenseRef-scancode-pcre",
"ISC",
"LGPL-2.1-only",
"LicenseRef-scancode-other-permissive",
"SunPro",
"CMU-Mach"... | permissive | leanprover/lean4 | 4bdf9790294964627eb9be79f5e8f6157780b4cc | f1f9dc0f2f531af3312398999d8b8303fa5f096b | refs/heads/master | 1,693,360,665,786 | 1,693,350,868,000 | 1,693,350,868,000 | 129,571,436 | 2,827 | 311 | Apache-2.0 | 1,694,716,156,000 | 1,523,760,560,000 | Lean | UTF-8 | Lean | false | false | 262 | lean | @[inline] def f (b : Bool) : IO Nat :=
match b with
| true => return 0
| false => return 1
@[noinline] def print (x : Nat) : IO Unit :=
IO.println x
set_option trace.Compiler.saveMono true
def foo (b : Bool) : IO Unit :=
bind (f b) fun x => print x
|
fd86606b23f90609b700b476270cef52ec8c0cd1 | e00ea76a720126cf9f6d732ad6216b5b824d20a7 | /src/category_theory/differential_object.lean | 124ca8e77cfe0c7f6a2414bdd0b90dc493c79941 | [
"Apache-2.0"
] | permissive | vaibhavkarve/mathlib | a574aaf68c0a431a47fa82ce0637f0f769826bfe | 17f8340912468f49bdc30acdb9a9fa02eeb0473a | refs/heads/master | 1,621,263,802,637 | 1,585,399,588,000 | 1,585,399,588,000 | 250,833,447 | 0 | 0 | Apache-2.0 | 1,585,410,341,000 | 1,585,410,341,000 | null | UTF-8 | Lean | false | false | 3,613 | lean | /-
Copyright (c) 2020 Scott Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Scott Morrison
-/
import category_theory.limits.shapes.zero
import category_theory.shift
/-!
# Differential objects in a category.
A differential object in a category with zero morphisms and a shift is
an object `X` equipped with
a morphism `d : X ⟶ X⟦1⟧`, such that `d^2 = 0`.
We build the category of differential objects, and some basic constructions
such as the forgetful functor, and zero morphisms and zero objects.
-/
open category_theory.limits
universes v u
namespace category_theory
variables (C : Type u) [𝒞 : category.{v} C]
include 𝒞
variables [has_zero_morphisms.{v} C] [has_shift.{v} C]
/--
A differential object in a category with zero morphisms and a shift is
an object `X` equipped with
a morphism `d : X ⟶ X⟦1⟧`, such that `d^2 = 0`.
-/
@[nolint has_inhabited_instance]
structure differential_object :=
(X : C)
(d : X ⟶ X⟦1⟧)
(d_squared' : d ≫ d⟦1⟧' = 0 . obviously)
restate_axiom differential_object.d_squared'
attribute [simp] differential_object.d_squared
variables {C}
namespace differential_object
/--
A morphism of differential objects is a morphism commuting with the differentials.
-/
@[ext, nolint has_inhabited_instance]
structure hom (X Y : differential_object.{v} C) :=
(f : X.X ⟶ Y.X)
(comm' : X.d ≫ f⟦1⟧' = f ≫ Y.d . obviously)
restate_axiom hom.comm'
attribute [simp, reassoc] hom.comm
namespace hom
/-- The identity morphism of a differential object. -/
@[simps]
def id (X : differential_object.{v} C) : hom X X :=
{ f := 𝟙 X.X }
/-- The composition of morphisms of differential objects. -/
@[simps]
def comp {X Y Z : differential_object.{v} C} (f : hom X Y) (g : hom Y Z) : hom X Z :=
{ f := f.f ≫ g.f, }
end hom
instance category_of_differential_objects : category.{v} (differential_object.{v} C) :=
{ hom := hom,
id := hom.id,
comp := λ X Y Z f g, hom.comp f g, }
@[simp]
lemma id_f (X : differential_object.{v} C) : ((𝟙 X) : X ⟶ X).f = 𝟙 (X.X) := rfl
@[simp]
lemma comp_f {X Y Z : differential_object.{v} C} (f : X ⟶ Y) (g : Y ⟶ Z) :
(f ≫ g).f = f.f ≫ g.f :=
rfl
variables (C)
/-- The forgetful functor taking a differential object to its underlying object. -/
def forget : (differential_object.{v} C) ⥤ C :=
{ obj := λ X, X.X,
map := λ X Y f, f.f, }
instance forget_faithful : faithful (forget C) :=
{ }
instance has_zero_morphisms : has_zero_morphisms.{v} (differential_object.{v} C) :=
{ has_zero := λ X Y,
⟨{ f := 0, }⟩}
end differential_object
end category_theory
namespace category_theory
namespace differential_object
variables (C : Type u) [𝒞 : category.{v} C]
include 𝒞
variables [has_zero_object.{v} C] [has_zero_morphisms.{v} C] [has_shift.{v} C]
local attribute [instance] has_zero_object.has_zero
instance has_zero_object : has_zero_object.{v} (differential_object.{v} C) :=
{ zero :=
{ X := (0 : C),
d := 0, },
unique_to := λ X, ⟨⟨{ f := 0 }⟩, λ f, (by ext)⟩,
unique_from := λ X, ⟨⟨{ f := 0 }⟩, λ f, (by ext)⟩, }
end differential_object
namespace differential_object
variables (C : Type (u+1))
[𝒞 : concrete_category C] [has_zero_morphisms.{u} C] [has_shift.{u} C]
include 𝒞
instance concrete_category_of_differential_objects :
concrete_category (differential_object.{u} C) :=
{ forget := forget C ⋙ category_theory.forget C }
instance : has_forget₂ (differential_object.{u} C) C :=
{ forget₂ := forget C }
end differential_object
end category_theory
|
ad85bb9670ecdcdce97ac8ebff65d9a6e6e1880e | d406927ab5617694ec9ea7001f101b7c9e3d9702 | /src/category_theory/natural_transformation.lean | 524d20db34af00370cc1b4e246465276d40b14ad | [
"Apache-2.0"
] | permissive | alreadydone/mathlib | dc0be621c6c8208c581f5170a8216c5ba6721927 | c982179ec21091d3e102d8a5d9f5fe06c8fafb73 | refs/heads/master | 1,685,523,275,196 | 1,670,184,141,000 | 1,670,184,141,000 | 287,574,545 | 0 | 0 | Apache-2.0 | 1,670,290,714,000 | 1,597,421,623,000 | Lean | UTF-8 | Lean | false | false | 3,730 | lean | /-
Copyright (c) 2017 Scott Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Tim Baumann, Stephen Morgan, Scott Morrison, Floris van Doorn
-/
import category_theory.functor.basic
/-!
# Natural transformations
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> https://github.com/leanprover-community/mathlib4/pull/749
> Any changes to this file require a corresponding PR to mathlib4.
Defines natural transformations between functors.
A natural transformation `α : nat_trans F G` consists of morphisms `α.app X : F.obj X ⟶ G.obj X`,
and the naturality squares `α.naturality f : F.map f ≫ α.app Y = α.app X ≫ G.map f`,
where `f : X ⟶ Y`.
Note that we make `nat_trans.naturality` a simp lemma, with the preferred simp normal form
pushing components of natural transformations to the left.
See also `category_theory.functor_category`, where we provide the category structure on
functors and natural transformations.
Introduces notations
* `τ.app X` for the components of natural transformations,
* `F ⟶ G` for the type of natural transformations between functors `F` and `G`
(this and the next require `category_theory.functor_category`),
* `σ ≫ τ` for vertical compositions, and
* `σ ◫ τ` for horizontal compositions.
-/
namespace category_theory
-- declare the `v`'s first; see `category_theory.category` for an explanation
universes v₁ v₂ v₃ v₄ u₁ u₂ u₃ u₄
variables {C : Type u₁} [category.{v₁} C] {D : Type u₂} [category.{v₂} D]
/--
`nat_trans F G` represents a natural transformation between functors `F` and `G`.
The field `app` provides the components of the natural transformation.
Naturality is expressed by `α.naturality_lemma`.
-/
@[ext]
structure nat_trans (F G : C ⥤ D) : Type (max u₁ v₂) :=
(app : Π X : C, F.obj X ⟶ G.obj X)
(naturality' : ∀ ⦃X Y : C⦄ (f : X ⟶ Y), F.map f ≫ app Y = app X ≫ G.map f . obviously)
restate_axiom nat_trans.naturality'
-- Rather arbitrarily, we say that the 'simpler' form is
-- components of natural transfomations moving earlier.
attribute [simp, reassoc] nat_trans.naturality
lemma congr_app {F G : C ⥤ D} {α β : nat_trans F G} (h : α = β) (X : C) : α.app X = β.app X :=
congr_fun (congr_arg nat_trans.app h) X
namespace nat_trans
/-- `nat_trans.id F` is the identity natural transformation on a functor `F`. -/
protected def id (F : C ⥤ D) : nat_trans F F :=
{ app := λ X, 𝟙 (F.obj X) }
@[simp] lemma id_app' (F : C ⥤ D) (X : C) : (nat_trans.id F).app X = 𝟙 (F.obj X) := rfl
instance (F : C ⥤ D) : inhabited (nat_trans F F) := ⟨nat_trans.id F⟩
open category
open category_theory.functor
section
variables {F G H I : C ⥤ D}
/-- `vcomp α β` is the vertical compositions of natural transformations. -/
def vcomp (α : nat_trans F G) (β : nat_trans G H) : nat_trans F H :=
{ app := λ X, (α.app X) ≫ (β.app X) }
-- functor_category will rewrite (vcomp α β) to (α ≫ β), so this is not a
-- suitable simp lemma. We will declare the variant vcomp_app' there.
lemma vcomp_app (α : nat_trans F G) (β : nat_trans G H) (X : C) :
(vcomp α β).app X = (α.app X) ≫ (β.app X) := rfl
end
/--
The diagram
F(f) F(g) F(h)
F X ----> F Y ----> F U ----> F U
| | | |
| α(X) | α(Y) | α(U) | α(V)
v v v v
G X ----> G Y ----> G U ----> G V
G(f) G(g) G(h)
commutes.
-/
example {F G : C ⥤ D} (α : nat_trans F G) {X Y U V : C} (f : X ⟶ Y) (g : Y ⟶ U) (h : U ⟶ V) :
α.app X ≫ G.map f ≫ G.map g ≫ G.map h =
F.map f ≫ F.map g ≫ F.map h ≫ α.app V :=
by simp
end nat_trans
end category_theory
|
a3d154fa1d2dd2827ca1ef5e41adaf934b5c8c0c | d1a52c3f208fa42c41df8278c3d280f075eb020c | /src/Lean/Elab/Tactic/BuiltinTactic.lean | be8c5c0cdf137dd2ede1e1e2ffcfbbfcdda7ab77 | [
"Apache-2.0",
"LLVM-exception",
"NCSA",
"LGPL-3.0-only",
"LicenseRef-scancode-inner-net-2.0",
"BSD-3-Clause",
"LGPL-2.0-or-later",
"Spencer-94",
"LGPL-2.1-or-later",
"HPND",
"LicenseRef-scancode-pcre",
"ISC",
"LGPL-2.1-only",
"LicenseRef-scancode-other-permissive",
"SunPro",
"CMU-Mach"... | permissive | cipher1024/lean4 | 6e1f98bb58e7a92b28f5364eb38a14c8d0aae393 | 69114d3b50806264ef35b57394391c3e738a9822 | refs/heads/master | 1,642,227,983,603 | 1,642,011,696,000 | 1,642,011,696,000 | 228,607,691 | 0 | 0 | Apache-2.0 | 1,576,584,269,000 | 1,576,584,268,000 | null | UTF-8 | Lean | false | false | 10,170 | lean | /-
Copyright (c) 2021 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
import Lean.Elab.Tactic.Basic
import Lean.Elab.Tactic.ElabTerm
namespace Lean.Elab.Tactic
open Meta
@[builtinTactic Lean.Parser.Tactic.«done»] def evalDone : Tactic := fun _ =>
done
@[builtinTactic seq1] def evalSeq1 : Tactic := fun stx => do
let args := stx[0].getArgs
for i in [:args.size] do
if i % 2 == 0 then
evalTactic args[i]
else
saveTacticInfoForToken args[i] -- add `TacticInfo` node for `;`
@[builtinTactic paren] def evalParen : Tactic := fun stx =>
evalTactic stx[1]
/- Evaluate `many (group (tactic >> optional ";")) -/
def evalManyTacticOptSemi (stx : Syntax) : TacticM Unit := do
stx.forArgsM fun seqElem => do
evalTactic seqElem[0]
saveTacticInfoForToken seqElem[1] -- add TacticInfo node for `;`
@[builtinTactic tacticSeq1Indented] def evalTacticSeq1Indented : Tactic := fun stx =>
evalManyTacticOptSemi stx[0]
@[builtinTactic tacticSeqBracketed] def evalTacticSeqBracketed : Tactic := fun stx => do
let initInfo ← mkInitialTacticInfo stx[0]
withRef stx[2] <| closeUsingOrAdmit do
-- save state before/after entering focus on `{`
withInfoContext (pure ()) initInfo
evalManyTacticOptSemi stx[1]
@[builtinTactic Parser.Tactic.focus] def evalFocus : Tactic := fun stx => do
let mkInfo ← mkInitialTacticInfo stx[0]
focus do
-- show focused state on `focus`
withInfoContext (pure ()) mkInfo
evalTactic stx[1]
private def getOptRotation (stx : Syntax) : Nat :=
if stx.isNone then 1 else stx[0].toNat
@[builtinTactic Parser.Tactic.rotateLeft] def evalRotateLeft : Tactic := fun stx => do
let n := getOptRotation stx[1]
setGoals <| (← getGoals).rotateLeft n
@[builtinTactic Parser.Tactic.rotateRight] def evalRotateRight : Tactic := fun stx => do
let n := getOptRotation stx[1]
setGoals <| (← getGoals).rotateRight n
@[builtinTactic Parser.Tactic.open] def evalOpen : Tactic := fun stx => do
try
pushScope
let openDecls ← elabOpenDecl stx[1]
withTheReader Core.Context (fun ctx => { ctx with openDecls := openDecls }) do
evalTactic stx[3]
finally
popScope
@[builtinTactic Parser.Tactic.set_option] def elabSetOption : Tactic := fun stx => do
let options ← Elab.elabSetOption stx[1] stx[2]
withTheReader Core.Context (fun ctx => { ctx with maxRecDepth := maxRecDepth.get options, options := options }) do
evalTactic stx[4]
@[builtinTactic Parser.Tactic.allGoals] def evalAllGoals : Tactic := fun stx => do
let mvarIds ← getGoals
let mut mvarIdsNew := #[]
for mvarId in mvarIds do
unless (← isExprMVarAssigned mvarId) do
setGoals [mvarId]
try
evalTactic stx[1]
mvarIdsNew := mvarIdsNew ++ (← getUnsolvedGoals)
catch ex =>
logException ex
mvarIdsNew := mvarIdsNew.push mvarId
setGoals mvarIdsNew.toList
@[builtinTactic Parser.Tactic.anyGoals] def evalAnyGoals : Tactic := fun stx => do
let mvarIds ← getGoals
let mut mvarIdsNew := #[]
let mut succeeded := false
for mvarId in mvarIds do
unless (← isExprMVarAssigned mvarId) do
setGoals [mvarId]
try
evalTactic stx[1]
mvarIdsNew := mvarIdsNew ++ (← getUnsolvedGoals)
succeeded := true
catch _ =>
mvarIdsNew := mvarIdsNew.push mvarId
unless succeeded do
throwError "failed on all goals"
setGoals mvarIdsNew.toList
@[builtinTactic tacticSeq] def evalTacticSeq : Tactic := fun stx =>
evalTactic stx[0]
partial def evalChoiceAux (tactics : Array Syntax) (i : Nat) : TacticM Unit :=
if h : i < tactics.size then
let tactic := tactics.get ⟨i, h⟩
catchInternalId unsupportedSyntaxExceptionId
(evalTactic tactic)
(fun _ => evalChoiceAux tactics (i+1))
else
throwUnsupportedSyntax
@[builtinTactic choice] def evalChoice : Tactic := fun stx =>
evalChoiceAux stx.getArgs 0
@[builtinTactic skip] def evalSkip : Tactic := fun stx => pure ()
@[builtinTactic unknown] def evalUnknown : Tactic := fun stx => do
addCompletionInfo <| CompletionInfo.tactic stx (← getGoals)
@[builtinTactic failIfSuccess] def evalFailIfSuccess : Tactic := fun stx => do
let tactic := stx[1]
if (← try evalTactic tactic; pure true catch _ => pure false) then
throwError "tactic succeeded"
@[builtinTactic traceState] def evalTraceState : Tactic := fun stx => do
let gs ← getUnsolvedGoals
logInfo (goalsToMessageData gs)
@[builtinTactic Lean.Parser.Tactic.assumption] def evalAssumption : Tactic := fun stx =>
liftMetaTactic fun mvarId => do Meta.assumption mvarId; pure []
@[builtinTactic Lean.Parser.Tactic.contradiction] def evalContradiction : Tactic := fun stx =>
liftMetaTactic fun mvarId => do Meta.contradiction mvarId; pure []
@[builtinTactic Lean.Parser.Tactic.intro] def evalIntro : Tactic := fun stx => do
match stx with
| `(tactic| intro) => introStep `_
| `(tactic| intro $h:ident) => introStep h.getId
| `(tactic| intro _) => introStep `_
| `(tactic| intro $pat:term) => evalTactic (← `(tactic| intro h; match h with | $pat:term => ?_; try clear h))
| `(tactic| intro $h:term $hs:term*) => evalTactic (← `(tactic| intro $h:term; intro $hs:term*))
| _ => throwUnsupportedSyntax
where
introStep (n : Name) : TacticM Unit :=
liftMetaTactic fun mvarId => do
let (_, mvarId) ← Meta.intro mvarId n
pure [mvarId]
@[builtinTactic Lean.Parser.Tactic.introMatch] def evalIntroMatch : Tactic := fun stx => do
let matchAlts := stx[1]
let stxNew ← liftMacroM <| Term.expandMatchAltsIntoMatchTactic stx matchAlts
withMacroExpansion stx stxNew <| evalTactic stxNew
@[builtinTactic «intros»] def evalIntros : Tactic := fun stx =>
match stx with
| `(tactic| intros) => liftMetaTactic fun mvarId => do
let (_, mvarId) ← Meta.intros mvarId
return [mvarId]
| `(tactic| intros $ids*) => liftMetaTactic fun mvarId => do
let (_, mvarId) ← Meta.introN mvarId ids.size (ids.map getNameOfIdent').toList
return [mvarId]
| _ => throwUnsupportedSyntax
@[builtinTactic Lean.Parser.Tactic.revert] def evalRevert : Tactic := fun stx =>
match stx with
| `(tactic| revert $hs*) => do
let (_, mvarId) ← Meta.revert (← getMainGoal) (← getFVarIds hs)
replaceMainGoal [mvarId]
| _ => throwUnsupportedSyntax
@[builtinTactic Lean.Parser.Tactic.clear] def evalClear : Tactic := fun stx =>
match stx with
| `(tactic| clear $hs*) => do
let fvarIds ← getFVarIds hs
let fvarIds ← withMainContext <| sortFVarIds fvarIds
for fvarId in fvarIds.reverse do
withMainContext do
let mvarId ← clear (← getMainGoal) fvarId
replaceMainGoal [mvarId]
| _ => throwUnsupportedSyntax
def forEachVar (hs : Array Syntax) (tac : MVarId → FVarId → MetaM MVarId) : TacticM Unit := do
for h in hs do
withMainContext do
let fvarId ← getFVarId h
let mvarId ← tac (← getMainGoal) fvarId
replaceMainGoal [mvarId]
@[builtinTactic Lean.Parser.Tactic.subst] def evalSubst : Tactic := fun stx =>
match stx with
| `(tactic| subst $hs*) => forEachVar hs Meta.subst
| _ => throwUnsupportedSyntax
/--
First method searches for a metavariable `g` s.t. `tag` is a suffix of its name.
If none is found, then it searches for a metavariable `g` s.t. `tag` is a prefix of its name. -/
private def findTag? (mvarIds : List MVarId) (tag : Name) : TacticM (Option MVarId) := do
let mvarId? ← mvarIds.findM? fun mvarId => return tag.isSuffixOf (← getMVarDecl mvarId).userName
match mvarId? with
| some mvarId => return mvarId
| none => mvarIds.findM? fun mvarId => return tag.isPrefixOf (← getMVarDecl mvarId).userName
def renameInaccessibles (mvarId : MVarId) (hs : Array Syntax) : TacticM MVarId := do
if hs.isEmpty then
return mvarId
else
let mvarDecl ← getMVarDecl mvarId
let mut lctx := mvarDecl.lctx
let mut hs := hs
let mut found : NameSet := {}
let n := lctx.numIndices
for i in [:n] do
let j := n - i - 1
match lctx.getAt? j with
| none => pure ()
| some localDecl =>
if localDecl.userName.hasMacroScopes || found.contains localDecl.userName then
let h := hs.back
if h.isIdent then
let newName := h.getId
lctx := lctx.setUserName localDecl.fvarId newName
hs := hs.pop
if hs.isEmpty then
break
found := found.insert localDecl.userName
unless hs.isEmpty do
logError m!"too many variable names provided"
let mvarNew ← mkFreshExprMVarAt lctx mvarDecl.localInstances mvarDecl.type MetavarKind.syntheticOpaque mvarDecl.userName
assignExprMVar mvarId mvarNew
return mvarNew.mvarId!
@[builtinTactic «case»] def evalCase : Tactic
| stx@`(tactic| case $tag $hs* =>%$arr $tac:tacticSeq) => do
let gs ← getUnsolvedGoals
let g ←
if tag.isIdent then
let tag := tag.getId
let some g ← findTag? gs tag | throwError "tag not found"
pure g
else
getMainGoal
let gs := gs.erase g
let g ← renameInaccessibles g hs
setGoals [g]
let savedTag ← getMVarTag g
setMVarTag g Name.anonymous
try
withCaseRef arr tac do
closeUsingOrAdmit (withTacticInfoContext stx (evalTactic tac))
finally
setMVarTag g savedTag
done
setGoals gs
| _ => throwUnsupportedSyntax
@[builtinTactic «renameI»] def evalRenameInaccessibles : Tactic
| stx@`(tactic| rename_i $hs*) => do replaceMainGoal [← renameInaccessibles (← getMainGoal) hs]
| _ => throwUnsupportedSyntax
@[builtinTactic «first»] partial def evalFirst : Tactic := fun stx => do
let tacs := stx[1].getArgs
if tacs.isEmpty then throwUnsupportedSyntax
loop tacs 0
where
loop (tacs : Array Syntax) (i : Nat) :=
if i == tacs.size - 1 then
evalTactic tacs[i][1]
else
evalTactic tacs[i][1] <|> loop tacs (i+1)
end Lean.Elab.Tactic
|
574b9d582a33d73d7f69e402a38ec69c2b1d90ff | 05b503addd423dd68145d68b8cde5cd595d74365 | /src/data/real/basic.lean | caced62408b5f372deeeddd6bf76717852c4a6a1 | [
"Apache-2.0"
] | permissive | aestriplex/mathlib | 77513ff2b176d74a3bec114f33b519069788811d | e2fa8b2b1b732d7c25119229e3cdfba8370cb00f | refs/heads/master | 1,621,969,960,692 | 1,586,279,279,000 | 1,586,279,279,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 25,981 | lean | /-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Floris van Doorn
The (classical) real numbers ℝ. This is a direct construction
from Cauchy sequences.
-/
import order.conditionally_complete_lattice data.real.cau_seq_completion
algebra.archimedean order.bounds
def real := @cau_seq.completion.Cauchy ℚ _ _ _ abs _
notation `ℝ` := real
namespace real
open cau_seq cau_seq.completion
variables {x y : ℝ}
def of_rat (x : ℚ) : ℝ := of_rat x
def mk (x : cau_seq ℚ abs) : ℝ := cau_seq.completion.mk x
def comm_ring_aux : comm_ring ℝ := cau_seq.completion.comm_ring
instance : comm_ring ℝ := { ..comm_ring_aux }
/- Extra instances to short-circuit type class resolution -/
instance : ring ℝ := by apply_instance
instance : comm_semiring ℝ := by apply_instance
instance : semiring ℝ := by apply_instance
instance : add_comm_group ℝ := by apply_instance
instance : add_group ℝ := by apply_instance
instance : add_comm_monoid ℝ := by apply_instance
instance : add_monoid ℝ := by apply_instance
instance : add_left_cancel_semigroup ℝ := by apply_instance
instance : add_right_cancel_semigroup ℝ := by apply_instance
instance : add_comm_semigroup ℝ := by apply_instance
instance : add_semigroup ℝ := by apply_instance
instance : comm_monoid ℝ := by apply_instance
instance : monoid ℝ := by apply_instance
instance : comm_semigroup ℝ := by apply_instance
instance : semigroup ℝ := by apply_instance
instance : inhabited ℝ := ⟨0⟩
theorem of_rat_sub (x y : ℚ) : of_rat (x - y) = of_rat x - of_rat y :=
congr_arg mk (const_sub _ _)
instance : has_lt ℝ :=
⟨λ x y, quotient.lift_on₂ x y (<) $
λ f₁ g₁ f₂ g₂ hf hg, propext $
⟨λ h, lt_of_eq_of_lt (setoid.symm hf) (lt_of_lt_of_eq h hg),
λ h, lt_of_eq_of_lt hf (lt_of_lt_of_eq h (setoid.symm hg))⟩⟩
@[simp] theorem mk_lt {f g : cau_seq ℚ abs} : mk f < mk g ↔ f < g := iff.rfl
theorem mk_eq {f g : cau_seq ℚ abs} : mk f = mk g ↔ f ≈ g := mk_eq
theorem quotient_mk_eq_mk (f : cau_seq ℚ abs) : ⟦f⟧ = mk f := rfl
theorem mk_eq_mk {f : cau_seq ℚ abs} : cau_seq.completion.mk f = mk f := rfl
@[simp] theorem mk_pos {f : cau_seq ℚ abs} : 0 < mk f ↔ pos f :=
iff_of_eq (congr_arg pos (sub_zero f))
protected def le (x y : ℝ) : Prop := x < y ∨ x = y
instance : has_le ℝ := ⟨real.le⟩
@[simp] theorem mk_le {f g : cau_seq ℚ abs} : mk f ≤ mk g ↔ f ≤ g :=
or_congr iff.rfl quotient.eq
theorem add_lt_add_iff_left {a b : ℝ} (c : ℝ) : c + a < c + b ↔ a < b :=
quotient.induction_on₃ a b c (λ f g h,
iff_of_eq (congr_arg pos $ by rw add_sub_add_left_eq_sub))
instance : linear_order ℝ :=
{ le := (≤), lt := (<),
le_refl := λ a, or.inr rfl,
le_trans := λ a b c, quotient.induction_on₃ a b c $
λ f g h, by simpa [quotient_mk_eq_mk] using le_trans,
lt_iff_le_not_le := λ a b, quotient.induction_on₂ a b $
λ f g, by simpa [quotient_mk_eq_mk] using lt_iff_le_not_le,
le_antisymm := λ a b, quotient.induction_on₂ a b $
λ f g, by simpa [mk_eq, quotient_mk_eq_mk] using @cau_seq.le_antisymm _ _ f g,
le_total := λ a b, quotient.induction_on₂ a b $
λ f g, by simpa [quotient_mk_eq_mk] using le_total f g }
instance : partial_order ℝ := by apply_instance
instance : preorder ℝ := by apply_instance
theorem of_rat_lt {x y : ℚ} : of_rat x < of_rat y ↔ x < y := const_lt
protected theorem zero_lt_one : (0 : ℝ) < 1 := of_rat_lt.2 zero_lt_one
protected theorem mul_pos {a b : ℝ} : 0 < a → 0 < b → 0 < a * b :=
quotient.induction_on₂ a b $ λ f g,
show pos (f - 0) → pos (g - 0) → pos (f * g - 0),
by simpa using cau_seq.mul_pos
instance : linear_ordered_comm_ring ℝ :=
{ add_le_add_left := λ a b h c,
(le_iff_le_iff_lt_iff_lt.2 $ real.add_lt_add_iff_left c).2 h,
zero_ne_one := ne_of_lt real.zero_lt_one,
mul_nonneg := λ a b a0 b0,
match a0, b0 with
| or.inl a0, or.inl b0 := le_of_lt (real.mul_pos a0 b0)
| or.inr a0, _ := by simp [a0.symm]
| _, or.inr b0 := by simp [b0.symm]
end,
mul_pos := @real.mul_pos,
zero_lt_one := real.zero_lt_one,
add_lt_add_left := λ a b h c, (real.add_lt_add_iff_left c).2 h,
..real.comm_ring, ..real.linear_order }
/- Extra instances to short-circuit type class resolution -/
instance : linear_ordered_ring ℝ := by apply_instance
instance : ordered_ring ℝ := by apply_instance
instance : linear_ordered_semiring ℝ := by apply_instance
instance : ordered_semiring ℝ := by apply_instance
instance : ordered_comm_group ℝ := by apply_instance
instance : ordered_cancel_comm_monoid ℝ := by apply_instance
instance : ordered_comm_monoid ℝ := by apply_instance
instance : domain ℝ := by apply_instance
open_locale classical
noncomputable instance : discrete_linear_ordered_field ℝ :=
{ decidable_le := by apply_instance,
..real.linear_ordered_comm_ring,
..real.domain,
..cau_seq.completion.field }
/- Extra instances to short-circuit type class resolution -/
noncomputable instance : linear_ordered_field ℝ := by apply_instance
noncomputable instance : decidable_linear_ordered_comm_ring ℝ := by apply_instance
noncomputable instance : decidable_linear_ordered_semiring ℝ := by apply_instance
noncomputable instance : decidable_linear_ordered_comm_group ℝ := by apply_instance
noncomputable instance field : field ℝ := by apply_instance
noncomputable instance : division_ring ℝ := by apply_instance
noncomputable instance : integral_domain ℝ := by apply_instance
noncomputable instance : nonzero_comm_ring ℝ := by apply_instance
noncomputable instance : decidable_linear_order ℝ := by apply_instance
noncomputable instance : distrib_lattice ℝ := by apply_instance
noncomputable instance : lattice ℝ := by apply_instance
noncomputable instance : semilattice_inf ℝ := by apply_instance
noncomputable instance : semilattice_sup ℝ := by apply_instance
noncomputable instance : has_inf ℝ := by apply_instance
noncomputable instance : has_sup ℝ := by apply_instance
lemma le_of_forall_epsilon_le {a b : real} (h : ∀ε, ε > 0 → a ≤ b + ε) : a ≤ b :=
le_of_forall_le_of_dense $ assume x hxb,
calc a ≤ b + (x - b) : h (x-b) $ sub_pos.2 hxb
... = x : by rw [add_comm]; simp
open rat
@[simp] theorem of_rat_eq_cast : ∀ x : ℚ, of_rat x = x :=
eq_cast of_rat rfl of_rat_add of_rat_mul
theorem le_mk_of_forall_le {f : cau_seq ℚ abs} :
(∃ i, ∀ j ≥ i, x ≤ f j) → x ≤ mk f :=
quotient.induction_on x $ λ g h, le_of_not_lt $
λ ⟨K, K0, hK⟩,
let ⟨i, H⟩ := exists_forall_ge_and h $
exists_forall_ge_and hK (f.cauchy₃ $ half_pos K0) in
begin
apply not_lt_of_le (H _ (le_refl _)).1,
rw ← of_rat_eq_cast,
refine ⟨_, half_pos K0, i, λ j ij, _⟩,
have := add_le_add (H _ ij).2.1
(le_of_lt (abs_lt.1 $ (H _ (le_refl _)).2.2 _ ij).1),
rwa [← sub_eq_add_neg, sub_self_div_two, sub_apply, sub_add_sub_cancel] at this
end
theorem mk_le_of_forall_le {f : cau_seq ℚ abs} {x : ℝ} :
(∃ i, ∀ j ≥ i, (f j : ℝ) ≤ x) → mk f ≤ x
| ⟨i, H⟩ := by rw [← neg_le_neg_iff, ← mk_eq_mk, mk_neg]; exact
le_mk_of_forall_le ⟨i, λ j ij, by simp [H _ ij]⟩
theorem mk_near_of_forall_near {f : cau_seq ℚ abs} {x : ℝ} {ε : ℝ}
(H : ∃ i, ∀ j ≥ i, abs ((f j : ℝ) - x) ≤ ε) : abs (mk f - x) ≤ ε :=
abs_sub_le_iff.2
⟨sub_le_iff_le_add'.2 $ mk_le_of_forall_le $
H.imp $ λ i h j ij, sub_le_iff_le_add'.1 (abs_sub_le_iff.1 $ h j ij).1,
sub_le.1 $ le_mk_of_forall_le $
H.imp $ λ i h j ij, sub_le.1 (abs_sub_le_iff.1 $ h j ij).2⟩
instance : archimedean ℝ :=
archimedean_iff_rat_le.2 $ λ x, quotient.induction_on x $ λ f,
let ⟨M, M0, H⟩ := f.bounded' 0 in
⟨M, mk_le_of_forall_le ⟨0, λ i _,
rat.cast_le.2 $ le_of_lt (abs_lt.1 (H i)).2⟩⟩
/- mark `real` irreducible in order to prevent `auto_cases` unfolding reals,
since users rarely want to consider real numbers as Cauchy sequences.
Marking `comm_ring_aux` `irreducible` is done to ensure that there are no problems
with non definitionally equal instances, caused by making `real` irreducible-/
attribute [irreducible] real comm_ring_aux
noncomputable instance : floor_ring ℝ := archimedean.floor_ring _
theorem is_cau_seq_iff_lift {f : ℕ → ℚ} : is_cau_seq abs f ↔ is_cau_seq abs (λ i, (f i : ℝ)) :=
⟨λ H ε ε0,
let ⟨δ, δ0, δε⟩ := exists_pos_rat_lt ε0 in
(H _ δ0).imp $ λ i hi j ij, lt_trans
(by simpa using (@rat.cast_lt ℝ _ _ _).2 (hi _ ij)) δε,
λ H ε ε0, (H _ (rat.cast_pos.2 ε0)).imp $
λ i hi j ij, (@rat.cast_lt ℝ _ _ _).1 $ by simpa using hi _ ij⟩
theorem of_near (f : ℕ → ℚ) (x : ℝ)
(h : ∀ ε > 0, ∃ i, ∀ j ≥ i, abs ((f j : ℝ) - x) < ε) :
∃ h', real.mk ⟨f, h'⟩ = x :=
⟨is_cau_seq_iff_lift.2 (of_near _ (const abs x) h),
sub_eq_zero.1 $ abs_eq_zero.1 $
eq_of_le_of_forall_le_of_dense (abs_nonneg _) $ λ ε ε0,
mk_near_of_forall_near $
(h _ ε0).imp (λ i h j ij, le_of_lt (h j ij))⟩
theorem exists_floor (x : ℝ) : ∃ (ub : ℤ), (ub:ℝ) ≤ x ∧
∀ (z : ℤ), (z:ℝ) ≤ x → z ≤ ub :=
int.exists_greatest_of_bdd
(let ⟨n, hn⟩ := exists_int_gt x in ⟨n, λ z h',
int.cast_le.1 $ le_trans h' $ le_of_lt hn⟩)
(let ⟨n, hn⟩ := exists_int_lt x in ⟨n, le_of_lt hn⟩)
theorem exists_sup (S : set ℝ) : (∃ x, x ∈ S) → (∃ x, ∀ y ∈ S, y ≤ x) →
∃ x, ∀ y, x ≤ y ↔ ∀ z ∈ S, z ≤ y
| ⟨L, hL⟩ ⟨U, hU⟩ := begin
choose f hf using begin
refine λ d : ℕ, @int.exists_greatest_of_bdd
(λ n, ∃ y ∈ S, (n:ℝ) ≤ y * d) _ _ _,
{ cases exists_int_gt U with k hk,
refine ⟨k * d, λ z h, _⟩,
rcases h with ⟨y, yS, hy⟩,
refine int.cast_le.1 (le_trans hy _),
simp,
exact mul_le_mul_of_nonneg_right
(le_trans (hU _ yS) (le_of_lt hk)) (nat.cast_nonneg _) },
{ exact ⟨⌊L * d⌋, L, hL, floor_le _⟩ }
end,
have hf₁ : ∀ n > 0, ∃ y ∈ S, ((f n / n:ℚ):ℝ) ≤ y := λ n n0,
let ⟨y, yS, hy⟩ := (hf n).1 in
⟨y, yS, by simpa using (div_le_iff ((nat.cast_pos.2 n0):((_:ℝ) < _))).2 hy⟩,
have hf₂ : ∀ (n > 0) (y ∈ S), (y - (n:ℕ)⁻¹ : ℝ) < (f n / n:ℚ),
{ intros n n0 y yS,
have := lt_of_lt_of_le (sub_one_lt_floor _)
(int.cast_le.2 $ (hf n).2 _ ⟨y, yS, floor_le _⟩),
simp [-sub_eq_add_neg],
rwa [lt_div_iff ((nat.cast_pos.2 n0):((_:ℝ) < _)), sub_mul, _root_.inv_mul_cancel],
exact ne_of_gt (nat.cast_pos.2 n0) },
suffices hg, let g : cau_seq ℚ abs := ⟨λ n, f n / n, hg⟩,
refine ⟨mk g, λ y, ⟨λ h x xS, le_trans _ h, λ h, _⟩⟩,
{ refine le_of_forall_ge_of_dense (λ z xz, _),
cases exists_nat_gt (x - z)⁻¹ with K hK,
refine le_mk_of_forall_le ⟨K, λ n nK, _⟩,
replace xz := sub_pos.2 xz,
replace hK := le_trans (le_of_lt hK) (nat.cast_le.2 nK),
have n0 : 0 < n := nat.cast_pos.1 (lt_of_lt_of_le (inv_pos.2 xz) hK),
refine le_trans _ (le_of_lt $ hf₂ _ n0 _ xS),
rwa [le_sub, inv_le ((nat.cast_pos.2 n0):((_:ℝ) < _)) xz] },
{ exact mk_le_of_forall_le ⟨1, λ n n1,
let ⟨x, xS, hx⟩ := hf₁ _ n1 in le_trans hx (h _ xS)⟩ },
intros ε ε0,
suffices : ∀ j k ≥ nat_ceil ε⁻¹, (f j / j - f k / k : ℚ) < ε,
{ refine ⟨_, λ j ij, abs_lt.2 ⟨_, this _ _ ij (le_refl _)⟩⟩,
rw [neg_lt, neg_sub], exact this _ _ (le_refl _) ij },
intros j k ij ik,
replace ij := le_trans (le_nat_ceil _) (nat.cast_le.2 ij),
replace ik := le_trans (le_nat_ceil _) (nat.cast_le.2 ik),
have j0 := nat.cast_pos.1 (lt_of_lt_of_le (inv_pos.2 ε0) ij),
have k0 := nat.cast_pos.1 (lt_of_lt_of_le (inv_pos.2 ε0) ik),
rcases hf₁ _ j0 with ⟨y, yS, hy⟩,
refine lt_of_lt_of_le ((@rat.cast_lt ℝ _ _ _).1 _)
((inv_le ε0 (nat.cast_pos.2 k0)).1 ik),
simpa using sub_lt_iff_lt_add'.2
(lt_of_le_of_lt hy $ sub_lt_iff_lt_add.1 $ hf₂ _ k0 _ yS)
end
noncomputable instance : has_Sup ℝ :=
⟨λ S, if h : (∃ x, x ∈ S) ∧ (∃ x, ∀ y ∈ S, y ≤ x)
then classical.some (exists_sup S h.1 h.2) else 0⟩
lemma Sup_def (S : set ℝ) :
Sup S = if h : (∃ x, x ∈ S) ∧ (∃ x, ∀ y ∈ S, y ≤ x)
then classical.some (exists_sup S h.1 h.2) else 0 := rfl
theorem Sup_le (S : set ℝ) (h₁ : ∃ x, x ∈ S) (h₂ : ∃ x, ∀ y ∈ S, y ≤ x)
{y} : Sup S ≤ y ↔ ∀ z ∈ S, z ≤ y :=
by simp [Sup_def, h₁, h₂]; exact
classical.some_spec (exists_sup S h₁ h₂) y
section
-- this proof times out without this
local attribute [instance, priority 1000] classical.prop_decidable
theorem lt_Sup (S : set ℝ) (h₁ : ∃ x, x ∈ S) (h₂ : ∃ x, ∀ y ∈ S, y ≤ x)
{y} : y < Sup S ↔ ∃ z ∈ S, y < z :=
by simpa [not_forall] using not_congr (@Sup_le S h₁ h₂ y)
end
theorem le_Sup (S : set ℝ) (h₂ : ∃ x, ∀ y ∈ S, y ≤ x) {x} (xS : x ∈ S) : x ≤ Sup S :=
(Sup_le S ⟨_, xS⟩ h₂).1 (le_refl _) _ xS
theorem Sup_le_ub (S : set ℝ) (h₁ : ∃ x, x ∈ S) {ub} (h₂ : ∀ y ∈ S, y ≤ ub) : Sup S ≤ ub :=
(Sup_le S h₁ ⟨_, h₂⟩).2 h₂
protected lemma is_lub_Sup {s : set ℝ} {a b : ℝ} (ha : a ∈ s) (hb : b ∈ upper_bounds s) :
is_lub s (Sup s) :=
⟨λ x xs, real.le_Sup s ⟨_, hb⟩ xs,
λ u h, real.Sup_le_ub _ ⟨_, ha⟩ h⟩
noncomputable instance : has_Inf ℝ := ⟨λ S, -Sup {x | -x ∈ S}⟩
lemma Inf_def (S : set ℝ) : Inf S = -Sup {x | -x ∈ S} := rfl
theorem le_Inf (S : set ℝ) (h₁ : ∃ x, x ∈ S) (h₂ : ∃ x, ∀ y ∈ S, x ≤ y)
{y} : y ≤ Inf S ↔ ∀ z ∈ S, y ≤ z :=
begin
refine le_neg.trans ((Sup_le _ _ _).trans _),
{ cases h₁ with x xS, exact ⟨-x, by simp [xS]⟩ },
{ cases h₂ with ub h, exact ⟨-ub, λ y hy, le_neg.1 $ h _ hy⟩ },
split; intros H z hz,
{ exact neg_le_neg_iff.1 (H _ $ by simp [hz]) },
{ exact le_neg.2 (H _ hz) }
end
section
-- this proof times out without this
local attribute [instance, priority 1000] classical.prop_decidable
theorem Inf_lt (S : set ℝ) (h₁ : ∃ x, x ∈ S) (h₂ : ∃ x, ∀ y ∈ S, x ≤ y)
{y} : Inf S < y ↔ ∃ z ∈ S, z < y :=
by simpa [not_forall] using not_congr (@le_Inf S h₁ h₂ y)
end
theorem Inf_le (S : set ℝ) (h₂ : ∃ x, ∀ y ∈ S, x ≤ y) {x} (xS : x ∈ S) : Inf S ≤ x :=
(le_Inf S ⟨_, xS⟩ h₂).1 (le_refl _) _ xS
theorem lb_le_Inf (S : set ℝ) (h₁ : ∃ x, x ∈ S) {lb} (h₂ : ∀ y ∈ S, lb ≤ y) : lb ≤ Inf S :=
(le_Inf S h₁ ⟨_, h₂⟩).2 h₂
noncomputable instance : conditionally_complete_linear_order ℝ :=
{ Sup := has_Sup.Sup,
Inf := has_Inf.Inf,
le_cSup :=
assume (s : set ℝ) (a : ℝ) (_ : bdd_above s) (_ : a ∈ s),
show a ≤ Sup s,
from le_Sup s ‹bdd_above s› ‹a ∈ s›,
cSup_le :=
assume (s : set ℝ) (a : ℝ) (_ : s.nonempty) (H : ∀b∈s, b ≤ a),
show Sup s ≤ a,
from Sup_le_ub s ‹s.nonempty› H,
cInf_le :=
assume (s : set ℝ) (a : ℝ) (_ : bdd_below s) (_ : a ∈ s),
show Inf s ≤ a,
from Inf_le s ‹bdd_below s› ‹a ∈ s›,
le_cInf :=
assume (s : set ℝ) (a : ℝ) (_ : s.nonempty) (H : ∀b∈s, a ≤ b),
show a ≤ Inf s,
from lb_le_Inf s ‹s.nonempty› H,
decidable_le := classical.dec_rel _,
..real.linear_order, ..real.lattice}
theorem Sup_empty : Sup (∅ : set ℝ) = 0 := dif_neg $ by simp
theorem Sup_of_not_bdd_above {s : set ℝ} (hs : ¬ bdd_above s) : Sup s = 0 :=
dif_neg $ assume h, hs h.2
theorem Sup_univ : Sup (@set.univ ℝ) = 0 :=
real.Sup_of_not_bdd_above $ λ ⟨x, h⟩, not_le_of_lt (lt_add_one _) $ h (set.mem_univ _)
theorem Inf_empty : Inf (∅ : set ℝ) = 0 :=
by simp [Inf_def, Sup_empty]
theorem Inf_of_not_bdd_below {s : set ℝ} (hs : ¬ bdd_below s) : Inf s = 0 :=
have bdd_above {x | -x ∈ s} → bdd_below s, from
assume ⟨b, hb⟩, ⟨-b, assume x hxs, neg_le.2 $ hb $ by simp [hxs]⟩,
have ¬ bdd_above {x | -x ∈ s}, from mt this hs,
neg_eq_zero.2 $ Sup_of_not_bdd_above $ this
theorem cau_seq_converges (f : cau_seq ℝ abs) : ∃ x, f ≈ const abs x :=
begin
let S := {x : ℝ | const abs x < f},
have lb : ∃ x, x ∈ S := exists_lt f,
have ub' : ∀ x, f < const abs x → ∀ y ∈ S, y ≤ x :=
λ x h y yS, le_of_lt $ const_lt.1 $ cau_seq.lt_trans yS h,
have ub : ∃ x, ∀ y ∈ S, y ≤ x := (exists_gt f).imp ub',
refine ⟨Sup S,
((lt_total _ _).resolve_left (λ h, _)).resolve_right (λ h, _)⟩,
{ rcases h with ⟨ε, ε0, i, ih⟩,
refine not_lt_of_le (Sup_le_ub S lb (ub' _ _))
((sub_lt_self_iff _).2 (half_pos ε0)),
refine ⟨_, half_pos ε0, i, λ j ij, _⟩,
rw [sub_apply, const_apply, sub_right_comm,
le_sub_iff_add_le, add_halves],
exact ih _ ij },
{ rcases h with ⟨ε, ε0, i, ih⟩,
refine not_lt_of_le (le_Sup S ub _)
((lt_add_iff_pos_left _).2 (half_pos ε0)),
refine ⟨_, half_pos ε0, i, λ j ij, _⟩,
rw [sub_apply, const_apply, add_comm, ← sub_sub,
le_sub_iff_add_le, add_halves],
exact ih _ ij }
end
noncomputable instance : cau_seq.is_complete ℝ abs := ⟨cau_seq_converges⟩
theorem sqrt_exists : ∀ {x : ℝ}, 0 ≤ x → ∃ y, 0 ≤ y ∧ y * y = x :=
suffices H : ∀ {x : ℝ}, 0 < x → x ≤ 1 → ∃ y, 0 < y ∧ y * y = x, begin
intros x x0, cases x0,
cases le_total x 1 with x1 x1,
{ rcases H x0 x1 with ⟨y, y0, hy⟩,
exact ⟨y, le_of_lt y0, hy⟩ },
{ have := (inv_le_inv x0 zero_lt_one).2 x1,
rw inv_one at this,
rcases H (inv_pos.2 x0) this with ⟨y, y0, hy⟩,
refine ⟨y⁻¹, le_of_lt (inv_pos.2 y0), _⟩, rw [← mul_inv', hy, inv_inv'] },
{ exact ⟨0, by simp [x0.symm]⟩ }
end,
λ x x0 x1, begin
let S := {y | 0 < y ∧ y * y ≤ x},
have lb : x ∈ S := ⟨x0, by simpa using (mul_le_mul_right x0).2 x1⟩,
have ub : ∀ y ∈ S, (y:ℝ) ≤ 1,
{ intros y yS, cases yS with y0 yx,
refine (mul_self_le_mul_self_iff (le_of_lt y0) zero_le_one).2 _,
simpa using le_trans yx x1 },
have S0 : 0 < Sup S := lt_of_lt_of_le x0 (le_Sup _ ⟨_, ub⟩ lb),
refine ⟨Sup S, S0, le_antisymm (not_lt.1 $ λ h, _) (not_lt.1 $ λ h, _)⟩,
{ rw [← div_lt_iff S0, lt_Sup S ⟨_, lb⟩ ⟨_, ub⟩] at h,
rcases h with ⟨y, ⟨y0, yx⟩, hy⟩,
rw [div_lt_iff S0, ← div_lt_iff' y0, lt_Sup S ⟨_, lb⟩ ⟨_, ub⟩] at hy,
rcases hy with ⟨z, ⟨z0, zx⟩, hz⟩,
rw [div_lt_iff y0] at hz,
exact not_lt_of_lt
((mul_lt_mul_right y0).1 (lt_of_le_of_lt yx hz))
((mul_lt_mul_left z0).1 (lt_of_le_of_lt zx hz)) },
{ let s := Sup S, let y := s + (x - s * s) / 3,
replace h : 0 < x - s * s := sub_pos.2 h,
have _30 := bit1_pos zero_le_one,
have : s < y := (lt_add_iff_pos_right _).2 (div_pos h _30),
refine not_le_of_lt this (le_Sup S ⟨_, ub⟩ ⟨lt_trans S0 this, _⟩),
rw [add_mul_self_eq, add_assoc, ← le_sub_iff_add_le', ← add_mul,
← le_div_iff (div_pos h _30), div_div_cancel' (ne_of_gt h)],
apply add_le_add,
{ simpa using (mul_le_mul_left (@two_pos ℝ _)).2 (Sup_le_ub _ ⟨_, lb⟩ ub) },
{ rw [div_le_one_iff_le _30],
refine le_trans (sub_le_self _ (mul_self_nonneg _)) (le_trans x1 _),
exact (le_add_iff_nonneg_left _).2 (le_of_lt two_pos) } }
end
def sqrt_aux (f : cau_seq ℚ abs) : ℕ → ℚ
| 0 := rat.mk_nat (f 0).num.to_nat.sqrt (f 0).denom.sqrt
| (n + 1) := let s := sqrt_aux n in max 0 $ (s + f (n+1) / s) / 2
theorem sqrt_aux_nonneg (f : cau_seq ℚ abs) : ∀ i : ℕ, 0 ≤ sqrt_aux f i
| 0 := by rw [sqrt_aux, mk_nat_eq, mk_eq_div];
apply div_nonneg'; exact int.cast_nonneg.2 (int.of_nat_nonneg _)
| (n + 1) := le_max_left _ _
/- TODO(Mario): finish the proof
theorem sqrt_aux_converges (f : cau_seq ℚ abs) : ∃ h x, 0 ≤ x ∧ x * x = max 0 (mk f) ∧
mk ⟨sqrt_aux f, h⟩ = x :=
begin
rcases sqrt_exists (le_max_left 0 (mk f)) with ⟨x, x0, hx⟩,
suffices : ∃ h, mk ⟨sqrt_aux f, h⟩ = x,
{ exact this.imp (λ h e, ⟨x, x0, hx, e⟩) },
apply of_near,
suffices : ∃ δ > 0, ∀ i, abs (↑(sqrt_aux f i) - x) < δ / 2 ^ i,
{ rcases this with ⟨δ, δ0, hδ⟩,
intros,
}
end -/
noncomputable def sqrt (x : ℝ) : ℝ :=
classical.some (sqrt_exists (le_max_left 0 x))
/-quotient.lift_on x
(λ f, mk ⟨sqrt_aux f, (sqrt_aux_converges f).fst⟩)
(λ f g e, begin
rcases sqrt_aux_converges f with ⟨hf, x, x0, xf, xs⟩,
rcases sqrt_aux_converges g with ⟨hg, y, y0, yg, ys⟩,
refine xs.trans (eq.trans _ ys.symm),
rw [← @mul_self_inj_of_nonneg ℝ _ x y x0 y0, xf, yg],
congr' 1, exact quotient.sound e
end)-/
theorem sqrt_prop (x : ℝ) : 0 ≤ sqrt x ∧ sqrt x * sqrt x = max 0 x :=
classical.some_spec (sqrt_exists (le_max_left 0 x))
/-quotient.induction_on x $ λ f,
by rcases sqrt_aux_converges f with ⟨hf, _, x0, xf, rfl⟩; exact ⟨x0, xf⟩-/
theorem sqrt_eq_zero_of_nonpos (h : x ≤ 0) : sqrt x = 0 :=
eq_zero_of_mul_self_eq_zero $ (sqrt_prop x).2.trans $ max_eq_left h
theorem sqrt_nonneg (x : ℝ) : 0 ≤ sqrt x := (sqrt_prop x).1
@[simp] theorem mul_self_sqrt (h : 0 ≤ x) : sqrt x * sqrt x = x :=
(sqrt_prop x).2.trans (max_eq_right h)
@[simp] theorem sqrt_mul_self (h : 0 ≤ x) : sqrt (x * x) = x :=
(mul_self_inj_of_nonneg (sqrt_nonneg _) h).1 (mul_self_sqrt (mul_self_nonneg _))
theorem sqrt_eq_iff_mul_self_eq (hx : 0 ≤ x) (hy : 0 ≤ y) :
sqrt x = y ↔ y * y = x :=
⟨λ h, by rw [← h, mul_self_sqrt hx],
λ h, by rw [← h, sqrt_mul_self hy]⟩
@[simp] theorem sqr_sqrt (h : 0 ≤ x) : sqrt x ^ 2 = x :=
by rw [pow_two, mul_self_sqrt h]
@[simp] theorem sqrt_sqr (h : 0 ≤ x) : sqrt (x ^ 2) = x :=
by rw [pow_two, sqrt_mul_self h]
theorem sqrt_eq_iff_sqr_eq (hx : 0 ≤ x) (hy : 0 ≤ y) :
sqrt x = y ↔ y ^ 2 = x :=
by rw [pow_two, sqrt_eq_iff_mul_self_eq hx hy]
theorem sqrt_mul_self_eq_abs (x : ℝ) : sqrt (x * x) = abs x :=
(le_total 0 x).elim
(λ h, (sqrt_mul_self h).trans (abs_of_nonneg h).symm)
(λ h, by rw [← neg_mul_neg,
sqrt_mul_self (neg_nonneg.2 h), abs_of_nonpos h])
theorem sqrt_sqr_eq_abs (x : ℝ) : sqrt (x ^ 2) = abs x :=
by rw [pow_two, sqrt_mul_self_eq_abs]
@[simp] theorem sqrt_zero : sqrt 0 = 0 :=
by simpa using sqrt_mul_self (le_refl _)
@[simp] theorem sqrt_one : sqrt 1 = 1 :=
by simpa using sqrt_mul_self zero_le_one
@[simp] theorem sqrt_le (hx : 0 ≤ x) (hy : 0 ≤ y) : sqrt x ≤ sqrt y ↔ x ≤ y :=
by rw [mul_self_le_mul_self_iff (sqrt_nonneg _) (sqrt_nonneg _),
mul_self_sqrt hx, mul_self_sqrt hy]
@[simp] theorem sqrt_lt (hx : 0 ≤ x) (hy : 0 ≤ y) : sqrt x < sqrt y ↔ x < y :=
lt_iff_lt_of_le_iff_le (sqrt_le hy hx)
lemma sqrt_le_sqrt (h : x ≤ y) : sqrt x ≤ sqrt y :=
begin
rw [mul_self_le_mul_self_iff (sqrt_nonneg _) (sqrt_nonneg _), (sqrt_prop _).2, (sqrt_prop _).2],
exact max_le_max (le_refl _) h
end
lemma sqrt_le_left (hy : 0 ≤ y) : sqrt x ≤ y ↔ x ≤ y ^ 2 :=
begin
rw [mul_self_le_mul_self_iff (sqrt_nonneg _) hy, pow_two],
cases le_total 0 x with hx hx,
{ rw [mul_self_sqrt hx] },
{ have h1 : 0 ≤ y * y := mul_nonneg hy hy,
have h2 : x ≤ y * y := le_trans hx h1,
simp [sqrt_eq_zero_of_nonpos, hx, h1, h2] }
end
/- note: if you want to conclude `x ≤ sqrt y`, then use `le_sqrt_of_sqr_le`.
if you have `x > 0`, consider using `le_sqrt'` -/
lemma le_sqrt (hx : 0 ≤ x) (hy : 0 ≤ y) : x ≤ sqrt y ↔ x ^ 2 ≤ y :=
by rw [mul_self_le_mul_self_iff hx (sqrt_nonneg _), pow_two, mul_self_sqrt hy]
lemma le_sqrt' (hx : 0 < x) : x ≤ sqrt y ↔ x ^ 2 ≤ y :=
begin
rw [mul_self_le_mul_self_iff (le_of_lt hx) (sqrt_nonneg _), pow_two],
cases le_total 0 y with hy hy,
{ rw [mul_self_sqrt hy] },
{ have h1 : 0 < x * x := mul_pos hx hx,
have h2 : ¬x * x ≤ y := not_le_of_lt (lt_of_le_of_lt hy h1),
simp [sqrt_eq_zero_of_nonpos, hy, h1, h2] }
end
lemma le_sqrt_of_sqr_le (h : x ^ 2 ≤ y) : x ≤ sqrt y :=
begin
cases lt_or_ge 0 x with hx hx,
{ rwa [le_sqrt' hx] },
{ exact le_trans hx (sqrt_nonneg y) }
end
@[simp] theorem sqrt_inj (hx : 0 ≤ x) (hy : 0 ≤ y) : sqrt x = sqrt y ↔ x = y :=
by simp [le_antisymm_iff, hx, hy]
@[simp] theorem sqrt_eq_zero (h : 0 ≤ x) : sqrt x = 0 ↔ x = 0 :=
by simpa using sqrt_inj h (le_refl _)
theorem sqrt_eq_zero' : sqrt x = 0 ↔ x ≤ 0 :=
(le_total x 0).elim
(λ h, by simp [h, sqrt_eq_zero_of_nonpos])
(λ h, by simp [h]; simp [le_antisymm_iff, h])
@[simp] theorem sqrt_pos : 0 < sqrt x ↔ 0 < x :=
lt_iff_lt_of_le_iff_le (iff.trans
(by simp [le_antisymm_iff, sqrt_nonneg]) sqrt_eq_zero')
@[simp] theorem sqrt_mul' (x) {y : ℝ} (hy : 0 ≤ y) : sqrt (x * y) = sqrt x * sqrt y :=
begin
cases le_total 0 x with hx hx,
{ refine (mul_self_inj_of_nonneg _ (mul_nonneg _ _)).1 _; try {apply sqrt_nonneg},
rw [mul_self_sqrt (mul_nonneg hx hy), mul_assoc,
mul_left_comm (sqrt y), mul_self_sqrt hy, ← mul_assoc, mul_self_sqrt hx] },
{ rw [sqrt_eq_zero'.2 (mul_nonpos_of_nonpos_of_nonneg hx hy),
sqrt_eq_zero'.2 hx, zero_mul] }
end
@[simp] theorem sqrt_mul (hx : 0 ≤ x) (y : ℝ) : sqrt (x * y) = sqrt x * sqrt y :=
by rw [mul_comm, sqrt_mul' _ hx, mul_comm]
@[simp] theorem sqrt_inv (x : ℝ) : sqrt x⁻¹ = (sqrt x)⁻¹ :=
(le_or_lt x 0).elim
(λ h, by simp [sqrt_eq_zero'.2, inv_nonpos, h])
(λ h, by rw [
← mul_self_inj_of_nonneg (sqrt_nonneg _) (le_of_lt $ inv_pos.2 $ sqrt_pos.2 h),
mul_self_sqrt (le_of_lt $ inv_pos.2 h), ← mul_inv', mul_self_sqrt (le_of_lt h)])
@[simp] theorem sqrt_div (hx : 0 ≤ x) (y : ℝ) : sqrt (x / y) = sqrt x / sqrt y :=
by rw [division_def, sqrt_mul hx, sqrt_inv]; refl
attribute [irreducible] real.le
end real
|
b372d444dc15b06544c112d2f510f5736eaa9f0c | 9dc8cecdf3c4634764a18254e94d43da07142918 | /src/analysis/convex/slope.lean | 4968ae9c7916e716e2a8456ad5a124912e4a5c45 | [
"Apache-2.0"
] | permissive | jcommelin/mathlib | d8456447c36c176e14d96d9e76f39841f69d2d9b | ee8279351a2e434c2852345c51b728d22af5a156 | refs/heads/master | 1,664,782,136,488 | 1,663,638,983,000 | 1,663,638,983,000 | 132,563,656 | 0 | 0 | Apache-2.0 | 1,663,599,929,000 | 1,525,760,539,000 | Lean | UTF-8 | Lean | false | false | 10,398 | lean | /-
Copyright (c) 2021 Yury Kudriashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudriashov, Malo Jaffré
-/
import analysis.convex.function
/-!
# Slopes of convex functions
This file relates convexity/concavity of functions in a linearly ordered field and the monotonicity
of their slopes.
The main use is to show convexity/concavity from monotonicity of the derivative.
-/
variables {𝕜 : Type*} [linear_ordered_field 𝕜] {s : set 𝕜} {f : 𝕜 → 𝕜}
/-- If `f : 𝕜 → 𝕜` is convex, then for any three points `x < y < z` the slope of the secant line of
`f` on `[x, y]` is less than the slope of the secant line of `f` on `[x, z]`. -/
lemma convex_on.slope_mono_adjacent (hf : convex_on 𝕜 s f)
{x y z : 𝕜} (hx : x ∈ s) (hz : z ∈ s) (hxy : x < y) (hyz : y < z) :
(f y - f x) / (y - x) ≤ (f z - f y) / (z - y) :=
begin
have hxz := hxy.trans hyz,
rw ←sub_pos at hxy hxz hyz,
suffices : f y / (y - x) + f y / (z - y) ≤ f x / (y - x) + f z / (z - y),
{ ring_nf at this ⊢, linarith },
set a := (z - y) / (z - x),
set b := (y - x) / (z - x),
have hy : a • x + b • z = y, by { field_simp, rw div_eq_iff; [ring, linarith] },
have key, from
hf.2 hx hz
(show 0 ≤ a, by apply div_nonneg; linarith)
(show 0 ≤ b, by apply div_nonneg; linarith)
(show a + b = 1, by { field_simp, rw div_eq_iff; [ring, linarith] }),
rw hy at key,
replace key := mul_le_mul_of_nonneg_left key hxz.le,
field_simp [hxy.ne', hyz.ne', hxz.ne', mul_comm (z - x) _] at key ⊢,
rw div_le_div_right,
{ linarith },
{ nlinarith }
end
/-- If `f : 𝕜 → 𝕜` is concave, then for any three points `x < y < z` the slope of the secant line of
`f` on `[x, y]` is greater than the slope of the secant line of `f` on `[x, z]`. -/
lemma concave_on.slope_anti_adjacent (hf : concave_on 𝕜 s f) {x y z : 𝕜} (hx : x ∈ s)
(hz : z ∈ s) (hxy : x < y) (hyz : y < z) :
(f z - f y) / (z - y) ≤ (f y - f x) / (y - x) :=
begin
rw [←neg_le_neg_iff, ←neg_sub_neg (f x), ←neg_sub_neg (f y)],
simp_rw [←pi.neg_apply, ←neg_div, neg_sub],
exact convex_on.slope_mono_adjacent hf.neg hx hz hxy hyz,
end
/-- If `f : 𝕜 → 𝕜` is strictly convex, then for any three points `x < y < z` the slope of the
secant line of `f` on `[x, y]` is strictly less than the slope of the secant line of `f` on
`[x, z]`. -/
lemma strict_convex_on.slope_strict_mono_adjacent (hf : strict_convex_on 𝕜 s f)
{x y z : 𝕜} (hx : x ∈ s) (hz : z ∈ s) (hxy : x < y) (hyz : y < z) :
(f y - f x) / (y - x) < (f z - f y) / (z - y) :=
begin
have hxz := hxy.trans hyz,
have hxz' := hxz.ne,
rw ←sub_pos at hxy hxz hyz,
suffices : f y / (y - x) + f y / (z - y) < f x / (y - x) + f z / (z - y),
{ ring_nf at this ⊢, linarith },
set a := (z - y) / (z - x),
set b := (y - x) / (z - x),
have hy : a • x + b • z = y, by { field_simp, rw div_eq_iff; [ring, linarith] },
have key, from
hf.2 hx hz hxz' (div_pos hyz hxz) (div_pos hxy hxz)
(show a + b = 1, by { field_simp, rw div_eq_iff; [ring, linarith] }),
rw hy at key,
replace key := mul_lt_mul_of_pos_left key hxz,
field_simp [hxy.ne', hyz.ne', hxz.ne', mul_comm (z - x) _] at key ⊢,
rw div_lt_div_right,
{ linarith },
{ nlinarith }
end
/-- If `f : 𝕜 → 𝕜` is strictly concave, then for any three points `x < y < z` the slope of the
secant line of `f` on `[x, y]` is strictly greater than the slope of the secant line of `f` on
`[x, z]`. -/
lemma strict_concave_on.slope_anti_adjacent (hf : strict_concave_on 𝕜 s f)
{x y z : 𝕜} (hx : x ∈ s) (hz : z ∈ s) (hxy : x < y) (hyz : y < z) :
(f z - f y) / (z - y) < (f y - f x) / (y - x) :=
begin
rw [←neg_lt_neg_iff, ←neg_sub_neg (f x), ←neg_sub_neg (f y)],
simp_rw [←pi.neg_apply, ←neg_div, neg_sub],
exact strict_convex_on.slope_strict_mono_adjacent hf.neg hx hz hxy hyz,
end
/-- If for any three points `x < y < z`, the slope of the secant line of `f : 𝕜 → 𝕜` on `[x, y]` is
less than the slope of the secant line of `f` on `[x, z]`, then `f` is convex. -/
lemma convex_on_of_slope_mono_adjacent (hs : convex 𝕜 s)
(hf : ∀ {x y z : 𝕜}, x ∈ s → z ∈ s → x < y → y < z →
(f y - f x) / (y - x) ≤ (f z - f y) / (z - y)) :
convex_on 𝕜 s f :=
linear_order.convex_on_of_lt hs $ λ x hx z hz hxz a b ha hb hab,
begin
let y := a * x + b * z,
have hxy : x < y,
{ rw [← one_mul x, ← hab, add_mul],
exact add_lt_add_left ((mul_lt_mul_left hb).2 hxz) _ },
have hyz : y < z,
{ rw [← one_mul z, ← hab, add_mul],
exact add_lt_add_right ((mul_lt_mul_left ha).2 hxz) _ },
have : (f y - f x) * (z - y) ≤ (f z - f y) * (y - x),
from (div_le_div_iff (sub_pos.2 hxy) (sub_pos.2 hyz)).1 (hf hx hz hxy hyz),
have hxz : 0 < z - x, from sub_pos.2 (hxy.trans hyz),
have ha : (z - y) / (z - x) = a,
{ rw [eq_comm, ← sub_eq_iff_eq_add'] at hab,
simp_rw [div_eq_iff hxz.ne', y, ←hab], ring },
have hb : (y - x) / (z - x) = b,
{ rw [eq_comm, ← sub_eq_iff_eq_add] at hab,
simp_rw [div_eq_iff hxz.ne', y, ←hab], ring },
rwa [sub_mul, sub_mul, sub_le_iff_le_add', ← add_sub_assoc, le_sub_iff_add_le, ← mul_add,
sub_add_sub_cancel, ← le_div_iff hxz, add_div, mul_div_assoc, mul_div_assoc, mul_comm (f x),
mul_comm (f z), ha, hb] at this,
end
/-- If for any three points `x < y < z`, the slope of the secant line of `f : 𝕜 → 𝕜` on `[x, y]` is
greater than the slope of the secant line of `f` on `[x, z]`, then `f` is concave. -/
lemma concave_on_of_slope_anti_adjacent (hs : convex 𝕜 s)
(hf : ∀ {x y z : 𝕜}, x ∈ s → z ∈ s → x < y → y < z →
(f z - f y) / (z - y) ≤ (f y - f x) / (y - x)) : concave_on 𝕜 s f :=
begin
rw ←neg_convex_on_iff,
refine convex_on_of_slope_mono_adjacent hs (λ x y z hx hz hxy hyz, _),
rw ←neg_le_neg_iff,
simp_rw [←neg_div, neg_sub, pi.neg_apply, neg_sub_neg],
exact hf hx hz hxy hyz,
end
/-- If for any three points `x < y < z`, the slope of the secant line of `f : 𝕜 → 𝕜` on `[x, y]` is
strictly less than the slope of the secant line of `f` on `[x, z]`, then `f` is strictly convex. -/
lemma strict_convex_on_of_slope_strict_mono_adjacent (hs : convex 𝕜 s)
(hf : ∀ {x y z : 𝕜}, x ∈ s → z ∈ s → x < y → y < z →
(f y - f x) / (y - x) < (f z - f y) / (z - y)) :
strict_convex_on 𝕜 s f :=
linear_order.strict_convex_on_of_lt hs $ λ x hx z hz hxz a b ha hb hab,
begin
let y := a * x + b * z,
have hxy : x < y,
{ rw [← one_mul x, ← hab, add_mul],
exact add_lt_add_left ((mul_lt_mul_left hb).2 hxz) _ },
have hyz : y < z,
{ rw [← one_mul z, ← hab, add_mul],
exact add_lt_add_right ((mul_lt_mul_left ha).2 hxz) _ },
have : (f y - f x) * (z - y) < (f z - f y) * (y - x),
from (div_lt_div_iff (sub_pos.2 hxy) (sub_pos.2 hyz)).1 (hf hx hz hxy hyz),
have hxz : 0 < z - x, from sub_pos.2 (hxy.trans hyz),
have ha : (z - y) / (z - x) = a,
{ rw [eq_comm, ← sub_eq_iff_eq_add'] at hab,
simp_rw [div_eq_iff hxz.ne', y, ←hab], ring },
have hb : (y - x) / (z - x) = b,
{ rw [eq_comm, ← sub_eq_iff_eq_add] at hab,
simp_rw [div_eq_iff hxz.ne', y, ←hab], ring },
rwa [sub_mul, sub_mul, sub_lt_iff_lt_add', ← add_sub_assoc, lt_sub_iff_add_lt, ← mul_add,
sub_add_sub_cancel, ← lt_div_iff hxz, add_div, mul_div_assoc, mul_div_assoc, mul_comm (f x),
mul_comm (f z), ha, hb] at this,
end
/-- If for any three points `x < y < z`, the slope of the secant line of `f : 𝕜 → 𝕜` on `[x, y]` is
strictly greater than the slope of the secant line of `f` on `[x, z]`, then `f` is strictly concave.
-/
lemma strict_concave_on_of_slope_strict_anti_adjacent (hs : convex 𝕜 s)
(hf : ∀ {x y z : 𝕜}, x ∈ s → z ∈ s → x < y → y < z →
(f z - f y) / (z - y) < (f y - f x) / (y - x)) : strict_concave_on 𝕜 s f :=
begin
rw ←neg_strict_convex_on_iff,
refine strict_convex_on_of_slope_strict_mono_adjacent hs (λ x y z hx hz hxy hyz, _),
rw ←neg_lt_neg_iff,
simp_rw [←neg_div, neg_sub, pi.neg_apply, neg_sub_neg],
exact hf hx hz hxy hyz,
end
/-- A function `f : 𝕜 → 𝕜` is convex iff for any three points `x < y < z` the slope of the secant
line of `f` on `[x, y]` is less than the slope of the secant line of `f` on `[x, z]`. -/
lemma convex_on_iff_slope_mono_adjacent :
convex_on 𝕜 s f ↔ convex 𝕜 s ∧
∀ ⦃x y z : 𝕜⦄, x ∈ s → z ∈ s → x < y → y < z →
(f y - f x) / (y - x) ≤ (f z - f y) / (z - y) :=
⟨λ h, ⟨h.1, λ x y z, h.slope_mono_adjacent⟩, λ h, convex_on_of_slope_mono_adjacent h.1 h.2⟩
/-- A function `f : 𝕜 → 𝕜` is concave iff for any three points `x < y < z` the slope of the secant
line of `f` on `[x, y]` is greater than the slope of the secant line of `f` on `[x, z]`. -/
lemma concave_on_iff_slope_anti_adjacent :
concave_on 𝕜 s f ↔ convex 𝕜 s ∧
∀ ⦃x y z : 𝕜⦄, x ∈ s → z ∈ s → x < y → y < z →
(f z - f y) / (z - y) ≤ (f y - f x) / (y - x) :=
⟨λ h, ⟨h.1, λ x y z, h.slope_anti_adjacent⟩, λ h, concave_on_of_slope_anti_adjacent h.1 h.2⟩
/-- A function `f : 𝕜 → 𝕜` is strictly convex iff for any three points `x < y < z` the slope of
the secant line of `f` on `[x, y]` is strictly less than the slope of the secant line of `f` on
`[x, z]`. -/
lemma strict_convex_on_iff_slope_strict_mono_adjacent :
strict_convex_on 𝕜 s f ↔ convex 𝕜 s ∧
∀ ⦃x y z : 𝕜⦄, x ∈ s → z ∈ s → x < y → y < z →
(f y - f x) / (y - x) < (f z - f y) / (z - y) :=
⟨λ h, ⟨h.1, λ x y z, h.slope_strict_mono_adjacent⟩,
λ h, strict_convex_on_of_slope_strict_mono_adjacent h.1 h.2⟩
/-- A function `f : 𝕜 → 𝕜` is strictly concave iff for any three points `x < y < z` the slope of
the secant line of `f` on `[x, y]` is strictly greater than the slope of the secant line of `f` on
`[x, z]`. -/
lemma strict_concave_on_iff_slope_strict_anti_adjacent :
strict_concave_on 𝕜 s f ↔ convex 𝕜 s ∧
∀ ⦃x y z : 𝕜⦄, x ∈ s → z ∈ s → x < y → y < z →
(f z - f y) / (z - y) < (f y - f x) / (y - x) :=
⟨λ h, ⟨h.1, λ x y z, h.slope_anti_adjacent⟩,
λ h, strict_concave_on_of_slope_strict_anti_adjacent h.1 h.2⟩
|
b6ee56dd5b0c89dca71b2c50b2aa228a9b5f57ad | d1a52c3f208fa42c41df8278c3d280f075eb020c | /src/Init/Control/StateRef.lean | 7c4e92f3bc3e63a3ed27787ca0426d1296620df6 | [
"Apache-2.0",
"LLVM-exception",
"NCSA",
"LGPL-3.0-only",
"LicenseRef-scancode-inner-net-2.0",
"BSD-3-Clause",
"LGPL-2.0-or-later",
"Spencer-94",
"LGPL-2.1-or-later",
"HPND",
"LicenseRef-scancode-pcre",
"ISC",
"LGPL-2.1-only",
"LicenseRef-scancode-other-permissive",
"SunPro",
"CMU-Mach"... | permissive | cipher1024/lean4 | 6e1f98bb58e7a92b28f5364eb38a14c8d0aae393 | 69114d3b50806264ef35b57394391c3e738a9822 | refs/heads/master | 1,642,227,983,603 | 1,642,011,696,000 | 1,642,011,696,000 | 228,607,691 | 0 | 0 | Apache-2.0 | 1,576,584,269,000 | 1,576,584,268,000 | null | UTF-8 | Lean | false | false | 2,527 | lean | /-
Copyright (c) 2020 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura, Sebastian Ullrich
The State monad transformer using IO references.
-/
prelude
import Init.System.IO
import Init.Control.State
def StateRefT' (ω : Type) (σ : Type) (m : Type → Type) (α : Type) : Type := ReaderT (ST.Ref ω σ) m α
/- Recall that `StateRefT` is a macro that infers `ω` from the `m`. -/
@[inline] def StateRefT'.run {ω σ : Type} {m : Type → Type} [Monad m] [MonadLiftT (ST ω) m] {α : Type} (x : StateRefT' ω σ m α) (s : σ) : m (α × σ) := do
let ref ← ST.mkRef s
let a ← x ref
let s ← ref.get
pure (a, s)
@[inline] def StateRefT'.run' {ω σ : Type} {m : Type → Type} [Monad m] [MonadLiftT (ST ω) m] {α : Type} (x : StateRefT' ω σ m α) (s : σ) : m α := do
let (a, _) ← x.run s
pure a
namespace StateRefT'
variable {ω σ : Type} {m : Type → Type} {α : Type}
@[inline] protected def lift (x : m α) : StateRefT' ω σ m α :=
fun _ => x
instance [Monad m] : Monad (StateRefT' ω σ m) := inferInstanceAs (Monad (ReaderT _ _))
instance : MonadLift m (StateRefT' ω σ m) := ⟨StateRefT'.lift⟩
instance (σ m) [Monad m] : MonadFunctor m (StateRefT' ω σ m) := inferInstanceAs (MonadFunctor m (ReaderT _ _))
instance [Alternative m] [Monad m] : Alternative (StateRefT' ω σ m) := inferInstanceAs (Alternative (ReaderT _ _))
@[inline] protected def get [Monad m] [MonadLiftT (ST ω) m] : StateRefT' ω σ m σ :=
fun ref => ref.get
@[inline] protected def set [Monad m] [MonadLiftT (ST ω) m] (s : σ) : StateRefT' ω σ m PUnit :=
fun ref => ref.set s
@[inline] protected def modifyGet [Monad m] [MonadLiftT (ST ω) m] (f : σ → α × σ) : StateRefT' ω σ m α :=
fun ref => ref.modifyGet f
instance [MonadLiftT (ST ω) m] [Monad m] : MonadStateOf σ (StateRefT' ω σ m) where
get := StateRefT'.get
set := StateRefT'.set
modifyGet := StateRefT'.modifyGet
instance (ε) [MonadExceptOf ε m] : MonadExceptOf ε (StateRefT' ω σ m) where
throw := StateRefT'.lift ∘ throwThe ε
tryCatch := fun x c s => tryCatchThe ε (x s) (fun e => c e s)
end StateRefT'
instance (ω σ : Type) (m : Type → Type) : MonadControl m (StateRefT' ω σ m) :=
inferInstanceAs (MonadControl m (ReaderT _ _))
instance {m : Type → Type} {ω σ : Type} [MonadFinally m] [Monad m] : MonadFinally (StateRefT' ω σ m) :=
inferInstanceAs (MonadFinally (ReaderT _ _))
|
3962ba42a1df7de69bca06b34cb22b2a2a15e657 | d4df7c538bbc0b06771d7b7a6f46fbadebb8c5eb | /src/comonad_transformers/traced_t.lean | d1c42b2f15459b2308b0afc6abd99c547e2a7ff8 | [] | no_license | breakerzirconia/LeanTransformers | 11bb924b59ac589d0c6b39586d27cccc8f9e939c | 3c52441b8990bab7d8cf1817df6e04f657a14e1c | refs/heads/main | 1,682,610,526,027 | 1,620,477,129,000 | 1,620,477,129,000 | 365,507,838 | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 1,254 | lean | import algebra.group
import comonad_transformers.comonad
import comonad_transformers.comonad_trans
----------------------------
-- Definition + instances --
----------------------------
structure TracedT (t : Type) (w : Type → Type) (a : Type) := (run : w (t → a))
open TracedT
instance {t : Type} {w : Type → Type} [functor w] : functor (TracedT t w) := {
map := λ α β f trcd, mk $ (λ g, f ∘ g) <$> trcd.run
}
instance {t : Type} [monoid t] {w : Type → Type} [has_extract w] : has_extract (TracedT t w) := {
extract := λ α trcd, (*trcd.run) 1
}
instance {t : Type} [monoid t] {w : Type → Type} [functor w] [has_extend w] : has_extend (TracedT t w) := {
extend := λ α β f trcd, mk $ (<<=) _ _ (λ wta tt,
f (mk $ (λ (g : t → α) tt', g (tt * tt')) <$> wta)) trcd.run
}
instance {t : Type} [monoid t] {w : Type → Type} [comonad w] : comonad (TracedT t w) := {}
protected def TracedT_lower {t : Type} [has_one t]
{w : Type → Type} [comonad w]
{a : Type} : TracedT t w a → w a := λ trcd, (λ (f : t → a), f 1) <$> trcd.run
instance {t : Type} [has_one t] : comonad_trans (TracedT t) := ⟨@TracedT_lower t _⟩ |
a1715f3ff3bafafde95e06d4335ef009e5a999c9 | d406927ab5617694ec9ea7001f101b7c9e3d9702 | /src/set_theory/game/basic.lean | 5becb01f797213764d7e5629cb1aaac5de3246ff | [
"Apache-2.0"
] | permissive | alreadydone/mathlib | dc0be621c6c8208c581f5170a8216c5ba6721927 | c982179ec21091d3e102d8a5d9f5fe06c8fafb73 | refs/heads/master | 1,685,523,275,196 | 1,670,184,141,000 | 1,670,184,141,000 | 287,574,545 | 0 | 0 | Apache-2.0 | 1,670,290,714,000 | 1,597,421,623,000 | Lean | UTF-8 | Lean | false | false | 28,049 | lean | /-
Copyright (c) 2019 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Reid Barton, Mario Carneiro, Isabel Longbottom, Scott Morrison, Apurva Nakade
-/
import set_theory.game.pgame
import tactic.abel
/-!
# Combinatorial games.
In this file we define the quotient of pre-games by the equivalence relation
`p ≈ q ↔ p ≤ q ∧ q ≤ p` (its `antisymmetrization`), and construct an instance `add_comm_group game`,
as well as an instance `partial_order game`.
## Multiplication on pre-games
We define the operations of multiplication and inverse on pre-games, and prove a few basic theorems
about them. Multiplication is not well-behaved under equivalence of pre-games i.e. `x ≈ y` does not
imply `x * z ≈ y * z`. Hence, multiplication is not a well-defined operation on games. Nevertheless,
the abelian group structure on games allows us to simplify many proofs for pre-games.
-/
open function pgame
open_locale pgame
universes u
instance pgame.setoid : setoid pgame :=
⟨(≈), equiv_refl, @pgame.equiv.symm, @pgame.equiv.trans⟩
/-- The type of combinatorial games. In ZFC, a combinatorial game is constructed from
two sets of combinatorial games that have been constructed at an earlier
stage. To do this in type theory, we say that a combinatorial pre-game is built
inductively from two families of combinatorial games indexed over any type
in Type u. The resulting type `pgame.{u}` lives in `Type (u+1)`,
reflecting that it is a proper class in ZFC.
A combinatorial game is then constructed by quotienting by the equivalence
`x ≈ y ↔ x ≤ y ∧ y ≤ x`. -/
abbreviation game := quotient pgame.setoid
namespace game
instance : add_comm_group_with_one game :=
{ zero := ⟦0⟧,
one := ⟦1⟧,
neg := quot.lift (λ x, ⟦-x⟧) (λ x y h, quot.sound ((@neg_equiv_neg_iff x y).2 h)),
add := quotient.lift₂ (λ x y : pgame, ⟦x + y⟧)
(λ x₁ y₁ x₂ y₂ hx hy, quot.sound (pgame.add_congr hx hy)),
add_zero := by { rintro ⟨x⟩, exact quot.sound (add_zero_equiv x) },
zero_add := by { rintro ⟨x⟩, exact quot.sound (zero_add_equiv x) },
add_assoc := by { rintros ⟨x⟩ ⟨y⟩ ⟨z⟩, exact quot.sound add_assoc_equiv },
add_left_neg := by { rintro ⟨x⟩, exact quot.sound (add_left_neg_equiv x) },
add_comm := by { rintros ⟨x⟩ ⟨y⟩, exact quot.sound add_comm_equiv } }
instance : inhabited game := ⟨0⟩
instance : partial_order game :=
{ le := quotient.lift₂ (≤) (λ x₁ y₁ x₂ y₂ hx hy, propext (le_congr hx hy)),
le_refl := by { rintro ⟨x⟩, exact le_refl x },
le_trans := by { rintro ⟨x⟩ ⟨y⟩ ⟨z⟩, exact @le_trans _ _ x y z },
le_antisymm := by { rintro ⟨x⟩ ⟨y⟩ h₁ h₂, apply quot.sound, exact ⟨h₁, h₂⟩ },
lt := quotient.lift₂ (<) (λ x₁ y₁ x₂ y₂ hx hy, propext (lt_congr hx hy)),
lt_iff_le_not_le := by { rintro ⟨x⟩ ⟨y⟩, exact @lt_iff_le_not_le _ _ x y }, }
/-- The less or fuzzy relation on games.
If `0 ⧏ x` (less or fuzzy with), then Left can win `x` as the first player. -/
def lf : game → game → Prop :=
quotient.lift₂ lf (λ x₁ y₁ x₂ y₂ hx hy, propext (lf_congr hx hy))
local infix ` ⧏ `:50 := lf
/-- On `game`, simp-normal inequalities should use as few negations as possible. -/
@[simp] theorem not_le : ∀ {x y : game}, ¬ x ≤ y ↔ y ⧏ x :=
by { rintro ⟨x⟩ ⟨y⟩, exact pgame.not_le }
/-- On `game`, simp-normal inequalities should use as few negations as possible. -/
@[simp] theorem not_lf : ∀ {x y : game}, ¬ x ⧏ y ↔ y ≤ x :=
by { rintro ⟨x⟩ ⟨y⟩, exact not_lf }
instance : is_trichotomous game (⧏) :=
⟨by { rintro ⟨x⟩ ⟨y⟩, change _ ∨ ⟦x⟧ = ⟦y⟧ ∨ _, rw quotient.eq, apply lf_or_equiv_or_gf }⟩
/-! It can be useful to use these lemmas to turn `pgame` inequalities into `game` inequalities, as
the `add_comm_group` structure on `game` often simplifies many proofs. -/
theorem _root_.pgame.le_iff_game_le {x y : pgame} : x ≤ y ↔ ⟦x⟧ ≤ ⟦y⟧ := iff.rfl
theorem _root_.pgame.lf_iff_game_lf {x y : pgame} : pgame.lf x y ↔ ⟦x⟧ ⧏ ⟦y⟧ := iff.rfl
theorem _root_.pgame.lt_iff_game_lt {x y : pgame} : x < y ↔ ⟦x⟧ < ⟦y⟧ := iff.rfl
theorem _root_.pgame.equiv_iff_game_eq {x y : pgame} : x ≈ y ↔ ⟦x⟧ = ⟦y⟧ :=
(@quotient.eq _ _ x y).symm
/-- The fuzzy, confused, or incomparable relation on games.
If `x ‖ 0`, then the first player can always win `x`. -/
def fuzzy : game → game → Prop :=
quotient.lift₂ fuzzy (λ x₁ y₁ x₂ y₂ hx hy, propext (fuzzy_congr hx hy))
local infix ` ‖ `:50 := fuzzy
theorem _root_.pgame.fuzzy_iff_game_fuzzy {x y : pgame} : pgame.fuzzy x y ↔ ⟦x⟧ ‖ ⟦y⟧ := iff.rfl
instance covariant_class_add_le : covariant_class game game (+) (≤) :=
⟨by { rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h, exact @add_le_add_left _ _ _ _ b c h a }⟩
instance covariant_class_swap_add_le : covariant_class game game (swap (+)) (≤) :=
⟨by { rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h, exact @add_le_add_right _ _ _ _ b c h a }⟩
instance covariant_class_add_lt : covariant_class game game (+) (<) :=
⟨by { rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h, exact @add_lt_add_left _ _ _ _ b c h a }⟩
instance covariant_class_swap_add_lt : covariant_class game game (swap (+)) (<) :=
⟨by { rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h, exact @add_lt_add_right _ _ _ _ b c h a }⟩
theorem add_lf_add_right : ∀ {b c : game} (h : b ⧏ c) (a), b + a ⧏ c + a :=
by { rintro ⟨b⟩ ⟨c⟩ h ⟨a⟩, apply add_lf_add_right h }
theorem add_lf_add_left : ∀ {b c : game} (h : b ⧏ c) (a), a + b ⧏ a + c :=
by { rintro ⟨b⟩ ⟨c⟩ h ⟨a⟩, apply add_lf_add_left h }
instance ordered_add_comm_group : ordered_add_comm_group game :=
{ add_le_add_left := @add_le_add_left _ _ _ game.covariant_class_add_le,
..game.add_comm_group_with_one,
..game.partial_order }
end game
namespace pgame
@[simp] lemma quot_neg (a : pgame) : ⟦-a⟧ = -⟦a⟧ := rfl
@[simp] lemma quot_add (a b : pgame) : ⟦a + b⟧ = ⟦a⟧ + ⟦b⟧ := rfl
@[simp] lemma quot_sub (a b : pgame) : ⟦a - b⟧ = ⟦a⟧ - ⟦b⟧ := rfl
theorem quot_eq_of_mk_quot_eq {x y : pgame}
(L : x.left_moves ≃ y.left_moves) (R : x.right_moves ≃ y.right_moves)
(hl : ∀ i, ⟦x.move_left i⟧ = ⟦y.move_left (L i)⟧)
(hr : ∀ j, ⟦x.move_right j⟧ = ⟦y.move_right (R j)⟧) : ⟦x⟧ = ⟦y⟧ :=
by { simp_rw [quotient.eq] at hl hr, exact quot.sound (equiv_of_mk_equiv L R hl hr) }
/-! Multiplicative operations can be defined at the level of pre-games,
but to prove their properties we need to use the abelian group structure of games.
Hence we define them here. -/
/-- The product of `x = {xL | xR}` and `y = {yL | yR}` is
`{xL*y + x*yL - xL*yL, xR*y + x*yR - xR*yR | xL*y + x*yR - xL*yR, x*yL + xR*y - xR*yL }`. -/
instance : has_mul pgame.{u} :=
⟨λ x y, begin
induction x with xl xr xL xR IHxl IHxr generalizing y,
induction y with yl yr yL yR IHyl IHyr,
have y := mk yl yr yL yR,
refine ⟨xl × yl ⊕ xr × yr, xl × yr ⊕ xr × yl, _, _⟩; rintro (⟨i, j⟩ | ⟨i, j⟩),
{ exact IHxl i y + IHyl j - IHxl i (yL j) },
{ exact IHxr i y + IHyr j - IHxr i (yR j) },
{ exact IHxl i y + IHyr j - IHxl i (yR j) },
{ exact IHxr i y + IHyl j - IHxr i (yL j) }
end⟩
theorem left_moves_mul : ∀ (x y : pgame.{u}), (x * y).left_moves
= (x.left_moves × y.left_moves ⊕ x.right_moves × y.right_moves)
| ⟨_, _, _, _⟩ ⟨_, _, _, _⟩ := rfl
theorem right_moves_mul : ∀ (x y : pgame.{u}), (x * y).right_moves
= (x.left_moves × y.right_moves ⊕ x.right_moves × y.left_moves)
| ⟨_, _, _, _⟩ ⟨_, _, _, _⟩ := rfl
/-- Turns two left or right moves for `x` and `y` into a left move for `x * y` and vice versa.
Even though these types are the same (not definitionally so), this is the preferred way to convert
between them. -/
def to_left_moves_mul {x y : pgame} :
x.left_moves × y.left_moves ⊕ x.right_moves × y.right_moves ≃ (x * y).left_moves :=
equiv.cast (left_moves_mul x y).symm
/-- Turns a left and a right move for `x` and `y` into a right move for `x * y` and vice versa.
Even though these types are the same (not definitionally so), this is the preferred way to convert
between them. -/
def to_right_moves_mul {x y : pgame} :
x.left_moves × y.right_moves ⊕ x.right_moves × y.left_moves ≃ (x * y).right_moves :=
equiv.cast (right_moves_mul x y).symm
@[simp] lemma mk_mul_move_left_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).move_left (sum.inl (i, j)) =
xL i * mk yl yr yL yR + mk xl xr xL xR * yL j - xL i * yL j :=
rfl
@[simp] lemma mul_move_left_inl {x y : pgame} {i j} :
(x * y).move_left (to_left_moves_mul (sum.inl (i, j))) =
x.move_left i * y + x * y.move_left j - x.move_left i * y.move_left j :=
by { cases x, cases y, refl }
@[simp] lemma mk_mul_move_left_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).move_left (sum.inr (i, j)) =
xR i * mk yl yr yL yR + mk xl xr xL xR * yR j - xR i * yR j :=
rfl
@[simp] lemma mul_move_left_inr {x y : pgame} {i j} :
(x * y).move_left (to_left_moves_mul (sum.inr (i, j))) =
x.move_right i * y + x * y.move_right j - x.move_right i * y.move_right j :=
by { cases x, cases y, refl }
@[simp] lemma mk_mul_move_right_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).move_right (sum.inl (i, j)) =
xL i * mk yl yr yL yR + mk xl xr xL xR * yR j - xL i * yR j :=
rfl
@[simp] lemma mul_move_right_inl {x y : pgame} {i j} :
(x * y).move_right (to_right_moves_mul (sum.inl (i, j))) =
x.move_left i * y + x * y.move_right j - x.move_left i * y.move_right j :=
by { cases x, cases y, refl }
@[simp] lemma mk_mul_move_right_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).move_right (sum.inr (i, j)) =
xR i * mk yl yr yL yR + mk xl xr xL xR * yL j - xR i * yL j :=
rfl
@[simp] lemma mul_move_right_inr {x y : pgame} {i j} :
(x * y).move_right (to_right_moves_mul (sum.inr (i, j))) =
x.move_right i * y + x * y.move_left j - x.move_right i * y.move_left j :=
by { cases x, cases y, refl }
@[simp] lemma neg_mk_mul_move_left_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).move_left (sum.inl (i, j)) =
-(xL i * mk yl yr yL yR + mk xl xr xL xR * yR j - xL i * yR j) :=
rfl
@[simp] lemma neg_mk_mul_move_left_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).move_left (sum.inr (i, j)) =
-(xR i * mk yl yr yL yR + mk xl xr xL xR * yL j - xR i * yL j) :=
rfl
@[simp] lemma neg_mk_mul_move_right_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).move_right (sum.inl (i, j)) =
-(xL i * mk yl yr yL yR + mk xl xr xL xR * yL j - xL i * yL j) :=
rfl
@[simp] lemma neg_mk_mul_move_right_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).move_right (sum.inr (i, j)) =
-(xR i * mk yl yr yL yR + mk xl xr xL xR * yR j - xR i * yR j) :=
rfl
lemma left_moves_mul_cases {x y : pgame} (k) {P : (x * y).left_moves → Prop}
(hl : ∀ ix iy, P $ to_left_moves_mul (sum.inl ⟨ix, iy⟩))
(hr : ∀ jx jy, P $ to_left_moves_mul (sum.inr ⟨jx, jy⟩)) : P k :=
begin
rw ←to_left_moves_mul.apply_symm_apply k,
rcases to_left_moves_mul.symm k with ⟨ix, iy⟩ | ⟨jx, jy⟩,
{ apply hl },
{ apply hr }
end
lemma right_moves_mul_cases {x y : pgame} (k) {P : (x * y).right_moves → Prop}
(hl : ∀ ix jy, P $ to_right_moves_mul (sum.inl ⟨ix, jy⟩))
(hr : ∀ jx iy, P $ to_right_moves_mul (sum.inr ⟨jx, iy⟩)) : P k :=
begin
rw ←to_right_moves_mul.apply_symm_apply k,
rcases to_right_moves_mul.symm k with ⟨ix, iy⟩ | ⟨jx, jy⟩,
{ apply hl },
{ apply hr }
end
/-- `x * y` and `y * x` have the same moves. -/
def mul_comm_relabelling : Π (x y : pgame.{u}), x * y ≡r y * x
| ⟨xl, xr, xL, xR⟩ ⟨yl, yr, yL, yR⟩ := begin
refine ⟨equiv.sum_congr (equiv.prod_comm _ _) (equiv.prod_comm _ _),
(equiv.sum_comm _ _).trans (equiv.sum_congr (equiv.prod_comm _ _) (equiv.prod_comm _ _)), _, _⟩;
rintro (⟨i, j⟩ | ⟨i, j⟩);
dsimp;
exact ((add_comm_relabelling _ _).trans $ (mul_comm_relabelling _ _).add_congr
(mul_comm_relabelling _ _)).sub_congr (mul_comm_relabelling _ _)
end
using_well_founded { dec_tac := pgame_wf_tac }
theorem quot_mul_comm (x y : pgame.{u}) : ⟦x * y⟧ = ⟦y * x⟧ :=
quot.sound (mul_comm_relabelling x y).equiv
/-- `x * y` is equivalent to `y * x`. -/
theorem mul_comm_equiv (x y : pgame) : x * y ≈ y * x :=
quotient.exact $ quot_mul_comm _ _
instance is_empty_mul_zero_left_moves (x : pgame.{u}) : is_empty (x * 0).left_moves :=
by { cases x, apply sum.is_empty }
instance is_empty_mul_zero_right_moves (x : pgame.{u}) : is_empty (x * 0).right_moves :=
by { cases x, apply sum.is_empty }
instance is_empty_zero_mul_left_moves (x : pgame.{u}) : is_empty (0 * x).left_moves :=
by { cases x, apply sum.is_empty }
instance is_empty_zero_mul_right_moves (x : pgame.{u}) : is_empty (0 * x).right_moves :=
by { cases x, apply sum.is_empty }
/-- `x * 0` has exactly the same moves as `0`. -/
def mul_zero_relabelling (x : pgame) : x * 0 ≡r 0 := relabelling.is_empty _
/-- `x * 0` is equivalent to `0`. -/
theorem mul_zero_equiv (x : pgame) : x * 0 ≈ 0 := (mul_zero_relabelling x).equiv
@[simp] theorem quot_mul_zero (x : pgame) : ⟦x * 0⟧ = ⟦0⟧ :=
@quotient.sound _ _ (x * 0) _ x.mul_zero_equiv
/-- `0 * x` has exactly the same moves as `0`. -/
def zero_mul_relabelling (x : pgame) : 0 * x ≡r 0 := relabelling.is_empty _
/-- `0 * x` is equivalent to `0`. -/
theorem zero_mul_equiv (x : pgame) : 0 * x ≈ 0 := (zero_mul_relabelling x).equiv
@[simp] theorem quot_zero_mul (x : pgame) : ⟦0 * x⟧ = ⟦0⟧ :=
@quotient.sound _ _ (0 * x) _ x.zero_mul_equiv
/-- `-x * y` and `-(x * y)` have the same moves. -/
def neg_mul_relabelling : Π (x y : pgame.{u}), -x * y ≡r -(x * y)
| ⟨xl, xr, xL, xR⟩ ⟨yl, yr, yL, yR⟩ := begin
refine ⟨equiv.sum_comm _ _, equiv.sum_comm _ _, _, _⟩;
rintro (⟨i, j⟩ | ⟨i, j⟩);
dsimp;
apply ((neg_add_relabelling _ _).trans _).symm;
apply ((neg_add_relabelling _ _).trans (relabelling.add_congr _ _)).sub_congr;
exact (neg_mul_relabelling _ _).symm
end
using_well_founded { dec_tac := pgame_wf_tac }
@[simp] theorem quot_neg_mul (x y : pgame) : ⟦-x * y⟧ = -⟦x * y⟧ :=
quot.sound (neg_mul_relabelling x y).equiv
/-- `x * -y` and `-(x * y)` have the same moves. -/
def mul_neg_relabelling (x y : pgame) : x * -y ≡r -(x * y) :=
(mul_comm_relabelling x _).trans $
(neg_mul_relabelling _ x).trans (mul_comm_relabelling y x).neg_congr
@[simp] theorem quot_mul_neg (x y : pgame) : ⟦x * -y⟧ = -⟦x * y⟧ :=
quot.sound (mul_neg_relabelling x y).equiv
@[simp] theorem quot_left_distrib : Π (x y z : pgame), ⟦x * (y + z)⟧ = ⟦x * y⟧ + ⟦x * z⟧
| (mk xl xr xL xR) (mk yl yr yL yR) (mk zl zr zL zR) :=
begin
let x := mk xl xr xL xR,
let y := mk yl yr yL yR,
let z := mk zl zr zL zR,
refine quot_eq_of_mk_quot_eq _ _ _ _,
{ fsplit,
{ rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 5 } },
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 5 } },
{ rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩); refl },
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩); refl } },
{ fsplit,
{ rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 5 } },
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 5 } },
{ rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩); refl },
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩); refl } },
{ rintro (⟨i, j | k⟩ | ⟨i, j | k⟩),
{ change ⟦xL i * (y + z) + x * (yL j + z) - xL i * (yL j + z)⟧
= ⟦xL i * y + x * yL j - xL i * yL j + x * z⟧,
simp [quot_left_distrib], abel },
{ change ⟦xL i * (y + z) + x * (y + zL k) - xL i * (y + zL k)⟧
= ⟦x * y + (xL i * z + x * zL k - xL i * zL k)⟧,
simp [quot_left_distrib], abel },
{ change ⟦xR i * (y + z) + x * (yR j + z) - xR i * (yR j + z)⟧
= ⟦xR i * y + x * yR j - xR i * yR j + x * z⟧,
simp [quot_left_distrib], abel },
{ change ⟦xR i * (y + z) + x * (y + zR k) - xR i * (y + zR k)⟧
= ⟦x * y + (xR i * z + x * zR k - xR i * zR k)⟧,
simp [quot_left_distrib], abel } },
{ rintro (⟨i, j | k⟩ | ⟨i, j | k⟩),
{ change ⟦xL i * (y + z) + x * (yR j + z) - xL i * (yR j + z)⟧
= ⟦xL i * y + x * yR j - xL i * yR j + x * z⟧,
simp [quot_left_distrib], abel },
{ change ⟦xL i * (y + z) + x * (y + zR k) - xL i * (y + zR k)⟧
= ⟦x * y + (xL i * z + x * zR k - xL i * zR k)⟧,
simp [quot_left_distrib], abel },
{ change ⟦xR i * (y + z) + x * (yL j + z) - xR i * (yL j + z)⟧
= ⟦xR i * y + x * yL j - xR i * yL j + x * z⟧,
simp [quot_left_distrib], abel },
{ change ⟦xR i * (y + z) + x * (y + zL k) - xR i * (y + zL k)⟧
= ⟦x * y + (xR i * z + x * zL k - xR i * zL k)⟧,
simp [quot_left_distrib], abel } }
end
using_well_founded { dec_tac := pgame_wf_tac }
/-- `x * (y + z)` is equivalent to `x * y + x * z.`-/
theorem left_distrib_equiv (x y z : pgame) : x * (y + z) ≈ x * y + x * z :=
quotient.exact $ quot_left_distrib _ _ _
@[simp] theorem quot_left_distrib_sub (x y z : pgame) : ⟦x * (y - z)⟧ = ⟦x * y⟧ - ⟦x * z⟧ :=
by { change ⟦x * (y + -z)⟧ = ⟦x * y⟧ + -⟦x * z⟧, rw [quot_left_distrib, quot_mul_neg] }
@[simp] theorem quot_right_distrib (x y z : pgame) : ⟦(x + y) * z⟧ = ⟦x * z⟧ + ⟦y * z⟧ :=
by simp only [quot_mul_comm, quot_left_distrib]
/-- `(x + y) * z` is equivalent to `x * z + y * z.`-/
theorem right_distrib_equiv (x y z : pgame) : (x + y) * z ≈ x * z + y * z :=
quotient.exact $ quot_right_distrib _ _ _
@[simp] theorem quot_right_distrib_sub (x y z : pgame) : ⟦(y - z) * x⟧ = ⟦y * x⟧ - ⟦z * x⟧ :=
by { change ⟦(y + -z) * x⟧ = ⟦y * x⟧ + -⟦z * x⟧, rw [quot_right_distrib, quot_neg_mul] }
/-- `x * 1` has the same moves as `x`. -/
def mul_one_relabelling : Π (x : pgame.{u}), x * 1 ≡r x
| ⟨xl, xr, xL, xR⟩ := begin
unfold has_one.one,
refine ⟨(equiv.sum_empty _ _).trans (equiv.prod_punit _),
(equiv.empty_sum _ _).trans (equiv.prod_punit _), _, _⟩;
try { rintro (⟨i, ⟨ ⟩⟩ | ⟨i, ⟨ ⟩⟩) }; try { intro i };
dsimp;
apply (relabelling.sub_congr (relabelling.refl _) (mul_zero_relabelling _)).trans;
rw sub_zero;
exact (add_zero_relabelling _).trans (((mul_one_relabelling _).add_congr
(mul_zero_relabelling _)).trans $ add_zero_relabelling _)
end
@[simp] theorem quot_mul_one (x : pgame) : ⟦x * 1⟧ = ⟦x⟧ := quot.sound $ mul_one_relabelling x
/-- `x * 1` is equivalent to `x`. -/
theorem mul_one_equiv (x : pgame) : x * 1 ≈ x := quotient.exact $ quot_mul_one x
/-- `1 * x` has the same moves as `x`. -/
def one_mul_relabelling (x : pgame) : 1 * x ≡r x :=
(mul_comm_relabelling 1 x).trans $ mul_one_relabelling x
@[simp] theorem quot_one_mul (x : pgame) : ⟦1 * x⟧ = ⟦x⟧ := quot.sound $ one_mul_relabelling x
/-- `1 * x` is equivalent to `x`. -/
theorem one_mul_equiv (x : pgame) : 1 * x ≈ x := quotient.exact $ quot_one_mul x
theorem quot_mul_assoc : Π (x y z : pgame), ⟦x * y * z⟧ = ⟦x * (y * z)⟧
| (mk xl xr xL xR) (mk yl yr yL yR) (mk zl zr zL zR) :=
begin
let x := mk xl xr xL xR,
let y := mk yl yr yL yR,
let z := mk zl zr zL zR,
refine quot_eq_of_mk_quot_eq _ _ _ _,
{ fsplit,
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_, _⟩ | ⟨_, _⟩, _⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 7 } },
{ rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_,⟨_, _⟩ | ⟨_, _⟩⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 7 } },
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_,_⟩ | ⟨_, _⟩,_⟩); refl },
{ rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_,⟨_, _⟩ | ⟨_, _⟩⟩); refl } },
{ fsplit,
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_, _⟩ | ⟨_, _⟩,_⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 7 } },
{ rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩);
solve_by_elim [sum.inl, sum.inr, prod.mk] { max_depth := 7 } },
{ rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_, _⟩ | ⟨_, _⟩,_⟩); refl },
{ rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩); refl } },
{ rintro (⟨⟨i, j⟩ | ⟨i, j⟩, k⟩ | ⟨⟨i, j⟩ | ⟨i, j⟩, k⟩),
{ change ⟦(xL i * y + x * yL j - xL i * yL j) * z + (x * y) * zL k
- (xL i * y + x * yL j - xL i * yL j) * zL k⟧
= ⟦xL i * (y * z) + x * (yL j * z + y * zL k - yL j * zL k)
- xL i * (yL j * z + y * zL k - yL j * zL k)⟧,
simp [quot_mul_assoc], abel },
{ change ⟦(xR i * y + x * yR j - xR i * yR j) * z + (x * y) * zL k
- (xR i * y + x * yR j - xR i * yR j) * zL k⟧
= ⟦xR i * (y * z) + x * (yR j * z + y * zL k - yR j * zL k)
- xR i * (yR j * z + y * zL k - yR j * zL k)⟧,
simp [quot_mul_assoc], abel },
{ change ⟦(xL i * y + x * yR j - xL i * yR j) * z + (x * y) * zR k
- (xL i * y + x * yR j - xL i * yR j) * zR k⟧
= ⟦xL i * (y * z) + x * (yR j * z + y * zR k - yR j * zR k)
- xL i * (yR j * z + y * zR k - yR j * zR k)⟧,
simp [quot_mul_assoc], abel },
{ change ⟦(xR i * y + x * yL j - xR i * yL j) * z + (x * y) * zR k
- (xR i * y + x * yL j - xR i * yL j) * zR k⟧
= ⟦xR i * (y * z) + x * (yL j * z + y * zR k - yL j * zR k)
- xR i * (yL j * z + y * zR k - yL j * zR k)⟧,
simp [quot_mul_assoc], abel } },
{ rintro (⟨⟨i, j⟩ | ⟨i, j⟩, k⟩ | ⟨⟨i, j⟩ | ⟨i, j⟩, k⟩),
{ change ⟦(xL i * y + x * yL j - xL i * yL j) * z + (x * y) * zR k
- (xL i * y + x * yL j - xL i * yL j) * zR k⟧
= ⟦xL i * (y * z) + x * (yL j * z + y * zR k - yL j * zR k)
- xL i * (yL j * z + y * zR k - yL j * zR k)⟧,
simp [quot_mul_assoc], abel },
{ change ⟦(xR i * y + x * yR j - xR i * yR j) * z + (x * y) * zR k
- (xR i * y + x * yR j - xR i * yR j) * zR k⟧
= ⟦xR i * (y * z) + x * (yR j * z + y * zR k - yR j * zR k)
- xR i * (yR j * z + y * zR k - yR j * zR k)⟧,
simp [quot_mul_assoc], abel },
{ change ⟦(xL i * y + x * yR j - xL i * yR j) * z + (x * y) * zL k
- (xL i * y + x * yR j - xL i * yR j) * zL k⟧
= ⟦xL i * (y * z) + x * (yR j * z + y * zL k - yR j * zL k)
- xL i * (yR j * z + y * zL k - yR j * zL k)⟧,
simp [quot_mul_assoc], abel },
{ change ⟦(xR i * y + x * yL j - xR i * yL j) * z + (x * y) * zL k
- (xR i * y + x * yL j - xR i * yL j) * zL k⟧
= ⟦xR i * (y * z) + x * (yL j * z + y * zL k - yL j * zL k)
- xR i * (yL j * z + y * zL k - yL j * zL k)⟧,
simp [quot_mul_assoc], abel } }
end
using_well_founded { dec_tac := pgame_wf_tac }
/-- `x * y * z` is equivalent to `x * (y * z).`-/
theorem mul_assoc_equiv (x y z : pgame) : x * y * z ≈ x * (y * z) :=
quotient.exact $ quot_mul_assoc _ _ _
/-- Because the two halves of the definition of `inv` produce more elements
on each side, we have to define the two families inductively.
This is the indexing set for the function, and `inv_val` is the function part. -/
inductive inv_ty (l r : Type u) : bool → Type u
| zero : inv_ty ff
| left₁ : r → inv_ty ff → inv_ty ff
| left₂ : l → inv_ty tt → inv_ty ff
| right₁ : l → inv_ty ff → inv_ty tt
| right₂ : r → inv_ty tt → inv_ty tt
instance (l r : Type u) [is_empty l] [is_empty r] : is_empty (inv_ty l r tt) :=
⟨by rintro (_|_|_|a|a); exact is_empty_elim a⟩
instance (l r : Type u) : inhabited (inv_ty l r ff) := ⟨inv_ty.zero⟩
instance unique_inv_ty (l r : Type u) [is_empty l] [is_empty r] : unique (inv_ty l r ff) :=
{ uniq := by { rintro (a|a|a), refl, all_goals { exact is_empty_elim a } },
..inv_ty.inhabited l r }
/-- Because the two halves of the definition of `inv` produce more elements
of each side, we have to define the two families inductively.
This is the function part, defined by recursion on `inv_ty`. -/
def inv_val {l r} (L : l → pgame) (R : r → pgame)
(IHl : l → pgame) (IHr : r → pgame) : ∀ {b}, inv_ty l r b → pgame
| _ inv_ty.zero := 0
| _ (inv_ty.left₁ i j) := (1 + (R i - mk l r L R) * inv_val j) * IHr i
| _ (inv_ty.left₂ i j) := (1 + (L i - mk l r L R) * inv_val j) * IHl i
| _ (inv_ty.right₁ i j) := (1 + (L i - mk l r L R) * inv_val j) * IHl i
| _ (inv_ty.right₂ i j) := (1 + (R i - mk l r L R) * inv_val j) * IHr i
@[simp] theorem inv_val_is_empty {l r : Type u} {b} (L R IHl IHr) (i : inv_ty l r b)
[is_empty l] [is_empty r] : inv_val L R IHl IHr i = 0 :=
begin
cases i with a _ a _ a _ a,
{ refl },
all_goals { exact is_empty_elim a }
end
/-- The inverse of a positive surreal number `x = {L | R}` is
given by `x⁻¹ = {0,
(1 + (R - x) * x⁻¹L) * R, (1 + (L - x) * x⁻¹R) * L |
(1 + (L - x) * x⁻¹L) * L, (1 + (R - x) * x⁻¹R) * R}`.
Because the two halves `x⁻¹L, x⁻¹R` of `x⁻¹` are used in their own
definition, the sets and elements are inductively generated. -/
def inv' : pgame → pgame
| ⟨l, r, L, R⟩ :=
let l' := {i // 0 < L i},
L' : l' → pgame := λ i, L i.1,
IHl' : l' → pgame := λ i, inv' (L i.1),
IHr := λ i, inv' (R i) in
⟨inv_ty l' r ff, inv_ty l' r tt,
inv_val L' R IHl' IHr, inv_val L' R IHl' IHr⟩
theorem zero_lf_inv' : ∀ (x : pgame), 0 ⧏ inv' x
| ⟨xl, xr, xL, xR⟩ := by { convert lf_mk _ _ inv_ty.zero, refl }
/-- `inv' 0` has exactly the same moves as `1`. -/
def inv'_zero : inv' 0 ≡r 1 :=
begin
change mk _ _ _ _ ≡r 1,
refine ⟨_, _, λ i, _, is_empty.elim _⟩,
{ apply equiv.equiv_punit (inv_ty _ _ _),
apply_instance },
{ apply equiv.equiv_pempty (inv_ty _ _ _),
apply_instance },
{ simp },
{ dsimp,
apply_instance }
end
theorem inv'_zero_equiv : inv' 0 ≈ 1 := inv'_zero.equiv
/-- `inv' 1` has exactly the same moves as `1`. -/
def inv'_one : inv' 1 ≡r (1 : pgame.{u}) :=
begin
change relabelling (mk _ _ _ _) 1,
haveI : is_empty {i : punit.{u+1} // (0 : pgame.{u}) < 0},
{ rw lt_self_iff_false, apply_instance },
refine ⟨_, _, λ i, _, is_empty.elim _⟩; dsimp,
{ apply equiv.equiv_punit },
{ apply equiv.equiv_of_is_empty },
{ simp },
{ apply_instance }
end
theorem inv'_one_equiv : inv' 1 ≈ 1 := inv'_one.equiv
/-- The inverse of a pre-game in terms of the inverse on positive pre-games. -/
noncomputable instance : has_inv pgame :=
⟨by { classical, exact λ x, if x ≈ 0 then 0 else if 0 < x then inv' x else -inv' (-x) }⟩
noncomputable instance : has_div pgame := ⟨λ x y, x * y⁻¹⟩
theorem inv_eq_of_equiv_zero {x : pgame} (h : x ≈ 0) : x⁻¹ = 0 := if_pos h
@[simp] theorem inv_zero : (0 : pgame)⁻¹ = 0 :=
inv_eq_of_equiv_zero (equiv_refl _)
theorem inv_eq_of_pos {x : pgame} (h : 0 < x) : x⁻¹ = inv' x :=
(if_neg h.lf.not_equiv').trans (if_pos h)
theorem inv_eq_of_lf_zero {x : pgame} (h : x ⧏ 0) : x⁻¹ = -inv' (-x) :=
(if_neg h.not_equiv).trans (if_neg h.not_gt)
/-- `1⁻¹` has exactly the same moves as `1`. -/
def inv_one : 1⁻¹ ≡r 1 :=
by { rw inv_eq_of_pos pgame.zero_lt_one, exact inv'_one }
theorem inv_one_equiv : 1⁻¹ ≈ 1 := inv_one.equiv
end pgame
|
dc034c71bfa9d39fe6a4a46fba775eac7afadfe8 | 82e44445c70db0f03e30d7be725775f122d72f3e | /src/number_theory/padics/padic_norm.lean | 6ca2f9cdb6115fd02338b4dbbab5f7ebd41f60a6 | [
"Apache-2.0"
] | permissive | stjordanis/mathlib | 51e286d19140e3788ef2c470bc7b953e4991f0c9 | 2568d41bca08f5d6bf39d915434c8447e21f42ee | refs/heads/master | 1,631,748,053,501 | 1,627,938,886,000 | 1,627,938,886,000 | 228,728,358 | 0 | 0 | Apache-2.0 | 1,576,630,588,000 | 1,576,630,587,000 | null | UTF-8 | Lean | false | false | 27,365 | lean | /-
Copyright (c) 2018 Robert Y. Lewis. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Robert Y. Lewis
-/
import ring_theory.int.basic
import algebra.field_power
import ring_theory.multiplicity
import data.real.cau_seq
import tactic.ring_exp
import tactic.basic
/-!
# p-adic norm
This file defines the p-adic valuation and the p-adic norm on ℚ.
The p-adic valuation on ℚ is the difference of the multiplicities of `p` in the numerator and
denominator of `q`. This function obeys the standard properties of a valuation, with the appropriate
assumptions on p.
The valuation induces a norm on ℚ. This norm is a nonarchimedean absolute value.
It takes values in {0} ∪ {1/p^k | k ∈ ℤ}.
## Notations
This file uses the local notation `/.` for `rat.mk`.
## Implementation notes
Much, but not all, of this file assumes that `p` is prime. This assumption is inferred automatically
by taking `[fact (prime p)]` as a type class argument.
## References
* [F. Q. Gouêva, *p-adic numbers*][gouvea1997]
* [R. Y. Lewis, *A formal proof of Hensel's lemma over the p-adic integers*][lewis2019]
* <https://en.wikipedia.org/wiki/P-adic_number>
## Tags
p-adic, p adic, padic, norm, valuation
-/
universe u
open nat
open_locale rat
open multiplicity
/--
For `p ≠ 1`, the p-adic valuation of an integer `z ≠ 0` is the largest natural number `n` such that
p^n divides z.
`padic_val_rat` defines the valuation of a rational `q` to be the valuation of `q.num` minus the
valuation of `q.denom`.
If `q = 0` or `p = 1`, then `padic_val_rat p q` defaults to 0.
-/
def padic_val_rat (p : ℕ) (q : ℚ) : ℤ :=
if h : q ≠ 0 ∧ p ≠ 1
then (multiplicity (p : ℤ) q.num).get
(multiplicity.finite_int_iff.2 ⟨h.2, rat.num_ne_zero_of_ne_zero h.1⟩) -
(multiplicity (p : ℤ) q.denom).get
(multiplicity.finite_int_iff.2 ⟨h.2, by exact_mod_cast rat.denom_ne_zero _⟩)
else 0
/--
A simplification of the definition of `padic_val_rat p q` when `q ≠ 0` and `p` is prime.
-/
lemma padic_val_rat_def (p : ℕ) [hp : fact p.prime] {q : ℚ} (hq : q ≠ 0) : padic_val_rat p q =
(multiplicity (p : ℤ) q.num).get (finite_int_iff.2 ⟨hp.1.ne_one, rat.num_ne_zero_of_ne_zero hq⟩) -
(multiplicity (p : ℤ) q.denom).get
(finite_int_iff.2 ⟨hp.1.ne_one, by exact_mod_cast rat.denom_ne_zero _⟩) :=
dif_pos ⟨hq, hp.1.ne_one⟩
namespace padic_val_rat
open multiplicity
variables {p : ℕ}
/--
`padic_val_rat p q` is symmetric in `q`.
-/
@[simp] protected lemma neg (q : ℚ) : padic_val_rat p (-q) = padic_val_rat p q :=
begin
unfold padic_val_rat,
split_ifs,
{ simp [-add_comm]; refl },
{ exfalso, simp * at * },
{ exfalso, simp * at * },
{ refl }
end
/--
`padic_val_rat p 1` is 0 for any `p`.
-/
@[simp] protected lemma one : padic_val_rat p 1 = 0 :=
by unfold padic_val_rat; split_ifs; simp *
/--
For `p ≠ 0, p ≠ 1, `padic_val_rat p p` is 1.
-/
@[simp] lemma padic_val_rat_self (hp : 1 < p) : padic_val_rat p p = 1 :=
by unfold padic_val_rat; split_ifs; simp [*, nat.one_lt_iff_ne_zero_and_ne_one] at *
/--
The p-adic value of an integer `z ≠ 0` is the multiplicity of `p` in `z`.
-/
lemma padic_val_rat_of_int (z : ℤ) (hp : p ≠ 1) (hz : z ≠ 0) :
padic_val_rat p (z : ℚ) = (multiplicity (p : ℤ) z).get
(finite_int_iff.2 ⟨hp, hz⟩) :=
by rw [padic_val_rat, dif_pos]; simp *; refl
end padic_val_rat
/--
A convenience function for the case of `padic_val_rat` when both inputs are natural numbers.
-/
def padic_val_nat (p : ℕ) (n : ℕ) : ℕ :=
int.to_nat (padic_val_rat p n)
section padic_val_nat
/--
`padic_val_nat` is defined as an `int.to_nat` cast;
this lemma ensures that the cast is well-behaved.
-/
lemma zero_le_padic_val_rat_of_nat (p n : ℕ) : 0 ≤ padic_val_rat p n :=
begin
unfold padic_val_rat,
split_ifs,
{ simp, },
{ trivial, },
end
/--
`padic_val_rat` coincides with `padic_val_nat`.
-/
@[simp, norm_cast] lemma padic_val_rat_of_nat (p n : ℕ) :
↑(padic_val_nat p n) = padic_val_rat p n :=
begin
unfold padic_val_nat,
rw int.to_nat_of_nonneg (zero_le_padic_val_rat_of_nat p n),
end
/--
A simplification of `padic_val_nat` when one input is prime, by analogy with `padic_val_rat_def`.
-/
lemma padic_val_nat_def {p : ℕ} [hp : fact p.prime] {n : ℕ} (hn : n ≠ 0) :
padic_val_nat p n =
(multiplicity p n).get
(multiplicity.finite_nat_iff.2 ⟨nat.prime.ne_one hp.1, bot_lt_iff_ne_bot.mpr hn⟩) :=
begin
have n_nonzero : (n : ℚ) ≠ 0, by simpa only [cast_eq_zero, ne.def],
-- Infinite loop with @simp padic_val_rat_of_nat unless we restrict the available lemmas here,
-- hence the very long list
simpa only
[ int.coe_nat_multiplicity p n, rat.coe_nat_denom n, (padic_val_rat_of_nat p n).symm,
int.coe_nat_zero, int.coe_nat_inj', sub_zero, get_one_right, int.coe_nat_succ, zero_add,
rat.coe_nat_num ]
using padic_val_rat_def p n_nonzero,
end
lemma one_le_padic_val_nat_of_dvd
{n p : nat} [prime : fact p.prime] (nonzero : n ≠ 0) (div : p ∣ n) :
1 ≤ padic_val_nat p n :=
begin
rw @padic_val_nat_def _ prime _ nonzero,
let one_le_mul : _ ≤ multiplicity p n :=
@multiplicity.le_multiplicity_of_pow_dvd _ _ _ p n 1 (begin norm_num, exact div end),
simp only [enat.coe_one] at one_le_mul,
rcases one_le_mul with ⟨_, q⟩,
dsimp at q,
solve_by_elim,
end
@[simp]
lemma padic_val_nat_zero (m : nat) : padic_val_nat m 0 = 0 := by simpa
@[simp]
lemma padic_val_nat_one (m : nat) : padic_val_nat m 1 = 0 := by simp [padic_val_nat]
end padic_val_nat
namespace padic_val_rat
open multiplicity
variables (p : ℕ) [p_prime : fact p.prime]
include p_prime
/--
The multiplicity of `p : ℕ` in `a : ℤ` is finite exactly when `a ≠ 0`.
-/
lemma finite_int_prime_iff {p : ℕ} [p_prime : fact p.prime] {a : ℤ} : finite (p : ℤ) a ↔ a ≠ 0 :=
by simp [finite_int_iff, ne.symm (ne_of_lt (p_prime.1.one_lt))]
/--
A rewrite lemma for `padic_val_rat p q` when `q` is expressed in terms of `rat.mk`.
-/
protected lemma defn {q : ℚ} {n d : ℤ} (hqz : q ≠ 0) (qdf : q = n /. d) :
padic_val_rat p q = (multiplicity (p : ℤ) n).get (finite_int_iff.2
⟨ne.symm $ ne_of_lt p_prime.1.one_lt, λ hn, by simp * at *⟩) -
(multiplicity (p : ℤ) d).get (finite_int_iff.2 ⟨ne.symm $ ne_of_lt p_prime.1.one_lt,
λ hd, by simp * at *⟩) :=
have hn : n ≠ 0, from rat.mk_num_ne_zero_of_ne_zero hqz qdf,
have hd : d ≠ 0, from rat.mk_denom_ne_zero_of_ne_zero hqz qdf,
let ⟨c, hc1, hc2⟩ := rat.num_denom_mk hn hd qdf in
by rw [padic_val_rat, dif_pos];
simp [hc1, hc2, multiplicity.mul' (nat.prime_iff_prime_int.1 p_prime.1),
(ne.symm (ne_of_lt p_prime.1.one_lt)), hqz]
/--
A rewrite lemma for `padic_val_rat p (q * r)` with conditions `q ≠ 0`, `r ≠ 0`.
-/
protected lemma mul {q r : ℚ} (hq : q ≠ 0) (hr : r ≠ 0) :
padic_val_rat p (q * r) = padic_val_rat p q + padic_val_rat p r :=
have q*r = (q.num * r.num) /. (↑q.denom * ↑r.denom), by rw_mod_cast rat.mul_num_denom,
have hq' : q.num /. q.denom ≠ 0, by rw rat.num_denom; exact hq,
have hr' : r.num /. r.denom ≠ 0, by rw rat.num_denom; exact hr,
have hp' : _root_.prime (p : ℤ), from nat.prime_iff_prime_int.1 p_prime.1,
begin
rw [padic_val_rat.defn p (mul_ne_zero hq hr) this],
conv_rhs { rw [←(@rat.num_denom q), padic_val_rat.defn p hq',
←(@rat.num_denom r), padic_val_rat.defn p hr'] },
rw [multiplicity.mul' hp', multiplicity.mul' hp']; simp [add_comm, add_left_comm, sub_eq_add_neg]
end
/--
A rewrite lemma for `padic_val_rat p (q^k) with condition `q ≠ 0`.
-/
protected lemma pow {q : ℚ} (hq : q ≠ 0) {k : ℕ} :
padic_val_rat p (q ^ k) = k * padic_val_rat p q :=
by induction k; simp [*, padic_val_rat.mul _ hq (pow_ne_zero _ hq),
pow_succ, add_mul, add_comm]
/--
A rewrite lemma for `padic_val_rat p (q⁻¹)` with condition `q ≠ 0`.
-/
protected lemma inv {q : ℚ} (hq : q ≠ 0) :
padic_val_rat p (q⁻¹) = -padic_val_rat p q :=
by rw [eq_neg_iff_add_eq_zero, ← padic_val_rat.mul p (inv_ne_zero hq) hq,
inv_mul_cancel hq, padic_val_rat.one]
/--
A rewrite lemma for `padic_val_rat p (q / r)` with conditions `q ≠ 0`, `r ≠ 0`.
-/
protected lemma div {q r : ℚ} (hq : q ≠ 0) (hr : r ≠ 0) :
padic_val_rat p (q / r) = padic_val_rat p q - padic_val_rat p r :=
by rw [div_eq_mul_inv, padic_val_rat.mul p hq (inv_ne_zero hr),
padic_val_rat.inv p hr, sub_eq_add_neg]
/--
A condition for `padic_val_rat p (n₁ / d₁) ≤ padic_val_rat p (n₂ / d₂),
in terms of divisibility by `p^n`.
-/
lemma padic_val_rat_le_padic_val_rat_iff {n₁ n₂ d₁ d₂ : ℤ}
(hn₁ : n₁ ≠ 0) (hn₂ : n₂ ≠ 0) (hd₁ : d₁ ≠ 0) (hd₂ : d₂ ≠ 0) :
padic_val_rat p (n₁ /. d₁) ≤ padic_val_rat p (n₂ /. d₂) ↔
∀ (n : ℕ), ↑p ^ n ∣ n₁ * d₂ → ↑p ^ n ∣ n₂ * d₁ :=
have hf1 : finite (p : ℤ) (n₁ * d₂),
from finite_int_prime_iff.2 (mul_ne_zero hn₁ hd₂),
have hf2 : finite (p : ℤ) (n₂ * d₁),
from finite_int_prime_iff.2 (mul_ne_zero hn₂ hd₁),
by conv {
to_lhs,
rw [padic_val_rat.defn p (rat.mk_ne_zero_of_ne_zero hn₁ hd₁) rfl,
padic_val_rat.defn p (rat.mk_ne_zero_of_ne_zero hn₂ hd₂) rfl,
sub_le_iff_le_add',
← add_sub_assoc,
le_sub_iff_add_le],
norm_cast,
rw [← multiplicity.mul' (nat.prime_iff_prime_int.1 p_prime.1) hf1, add_comm,
← multiplicity.mul' (nat.prime_iff_prime_int.1 p_prime.1) hf2,
enat.get_le_get, multiplicity_le_multiplicity_iff]
}
/--
Sufficient conditions to show that the p-adic valuation of `q` is less than or equal to the
p-adic vlauation of `q + r`.
-/
theorem le_padic_val_rat_add_of_le {q r : ℚ}
(hq : q ≠ 0) (hr : r ≠ 0) (hqr : q + r ≠ 0)
(h : padic_val_rat p q ≤ padic_val_rat p r) :
padic_val_rat p q ≤ padic_val_rat p (q + r) :=
have hqn : q.num ≠ 0, from rat.num_ne_zero_of_ne_zero hq,
have hqd : (q.denom : ℤ) ≠ 0, by exact_mod_cast rat.denom_ne_zero _,
have hrn : r.num ≠ 0, from rat.num_ne_zero_of_ne_zero hr,
have hrd : (r.denom : ℤ) ≠ 0, by exact_mod_cast rat.denom_ne_zero _,
have hqreq : q + r = (((q.num * r.denom + q.denom * r.num : ℤ)) /. (↑q.denom * ↑r.denom : ℤ)),
from rat.add_num_denom _ _,
have hqrd : q.num * ↑(r.denom) + ↑(q.denom) * r.num ≠ 0,
from rat.mk_num_ne_zero_of_ne_zero hqr hqreq,
begin
conv_lhs { rw ←(@rat.num_denom q) },
rw [hqreq, padic_val_rat_le_padic_val_rat_iff p hqn hqrd hqd (mul_ne_zero hqd hrd),
← multiplicity_le_multiplicity_iff, mul_left_comm,
multiplicity.mul (nat.prime_iff_prime_int.1 p_prime.1), add_mul],
rw [←(@rat.num_denom q), ←(@rat.num_denom r),
padic_val_rat_le_padic_val_rat_iff p hqn hrn hqd hrd, ← multiplicity_le_multiplicity_iff] at h,
calc _ ≤ min (multiplicity ↑p (q.num * ↑(r.denom) * ↑(q.denom)))
(multiplicity ↑p (↑(q.denom) * r.num * ↑(q.denom))) : (le_min
(by rw [@multiplicity.mul _ _ _ _ (_ * _) _ (nat.prime_iff_prime_int.1 p_prime.1), add_comm])
(by rw [mul_assoc, @multiplicity.mul _ _ _ _ (q.denom : ℤ)
(_ * _) (nat.prime_iff_prime_int.1 p_prime.1)];
exact add_le_add_left h _))
... ≤ _ : min_le_multiplicity_add
end
/--
The minimum of the valuations of `q` and `r` is less than or equal to the valuation of `q + r`.
-/
theorem min_le_padic_val_rat_add {q r : ℚ}
(hq : q ≠ 0) (hr : r ≠ 0) (hqr : q + r ≠ 0) :
min (padic_val_rat p q) (padic_val_rat p r) ≤ padic_val_rat p (q + r) :=
(le_total (padic_val_rat p q) (padic_val_rat p r)).elim
(λ h, by rw [min_eq_left h]; exact le_padic_val_rat_add_of_le _ hq hr hqr h)
(λ h, by rw [min_eq_right h, add_comm]; exact le_padic_val_rat_add_of_le _ hr hq
(by rwa add_comm) h)
open_locale big_operators
/-- A finite sum of rationals with positive p-adic valuation has positive p-adic valuation
(if the sum is non-zero). -/
theorem sum_pos_of_pos {n : ℕ} {F : ℕ → ℚ}
(hF : ∀ i, i < n → 0 < padic_val_rat p (F i)) (hn0 : ∑ i in finset.range n, F i ≠ 0) :
0 < padic_val_rat p (∑ i in finset.range n, F i) :=
begin
induction n with d hd,
{ exact false.elim (hn0 rfl) },
{ rw finset.sum_range_succ at hn0 ⊢,
by_cases h : ∑ (x : ℕ) in finset.range d, F x = 0,
{ rw [h, zero_add],
exact hF d (lt_add_one _) },
{ refine lt_of_lt_of_le _ (min_le_padic_val_rat_add p h (λ h1, _) hn0),
{ refine lt_min (hd (λ i hi, _) h) (hF d (lt_add_one _)),
exact hF _ (lt_trans hi (lt_add_one _)) },
{ have h2 := hF d (lt_add_one _),
rw h1 at h2,
exact lt_irrefl _ h2 } } }
end
end padic_val_rat
namespace padic_val_nat
/--
A rewrite lemma for `padic_val_nat p (q * r)` with conditions `q ≠ 0`, `r ≠ 0`.
-/
protected lemma mul (p : ℕ) [p_prime : fact p.prime] {q r : ℕ} (hq : q ≠ 0) (hr : r ≠ 0) :
padic_val_nat p (q * r) = padic_val_nat p q + padic_val_nat p r :=
begin
apply int.coe_nat_inj,
simp only [padic_val_rat_of_nat, nat.cast_mul],
rw padic_val_rat.mul,
norm_cast,
exact cast_ne_zero.mpr hq,
exact cast_ne_zero.mpr hr,
end
/--
Dividing out by a prime factor reduces the padic_val_nat by 1.
-/
protected lemma div {p : ℕ} [p_prime : fact p.prime] {b : ℕ} (dvd : p ∣ b) :
(padic_val_nat p (b / p)) = (padic_val_nat p b) - 1 :=
begin
by_cases b_split : (b = 0),
{ simp [b_split], },
{ have split_frac : padic_val_rat p (b / p) = padic_val_rat p b - padic_val_rat p p :=
padic_val_rat.div p (nat.cast_ne_zero.mpr b_split)
(nat.cast_ne_zero.mpr (nat.prime.ne_zero p_prime.1)),
rw padic_val_rat.padic_val_rat_self (nat.prime.one_lt p_prime.1) at split_frac,
have r : 1 ≤ padic_val_nat p b := one_le_padic_val_nat_of_dvd b_split dvd,
exact_mod_cast split_frac, }
end
end padic_val_nat
section padic_val_nat
/--
If a prime doesn't appear in `n`, `padic_val_nat p n` is `0`.
-/
lemma padic_val_nat_of_not_dvd {p : ℕ} [fact p.prime] {n : ℕ} (not_dvd : ¬(p ∣ n)) :
padic_val_nat p n = 0 :=
begin
by_cases hn : n = 0,
{ subst hn, simp at not_dvd, trivial, },
{ rw padic_val_nat_def hn,
exact (@multiplicity.unique' _ _ _ p n 0 (by simp) (by simpa using not_dvd)).symm,
assumption, },
end
lemma dvd_of_one_le_padic_val_nat {n p : nat} [prime : fact p.prime] (hp : 1 ≤ padic_val_nat p n) :
p ∣ n :=
begin
by_contra h,
rw padic_val_nat_of_not_dvd h at hp,
exact lt_irrefl 0 (lt_of_lt_of_le zero_lt_one hp),
end
lemma pow_padic_val_nat_dvd {p n : ℕ} [fact (nat.prime p)] : p ^ (padic_val_nat p n) ∣ n :=
begin
cases eq_zero_or_pos n with hn hn,
{ rw hn, exact dvd_zero (p ^ padic_val_nat p 0) },
{ rw multiplicity.pow_dvd_iff_le_multiplicity,
apply le_of_eq,
rw padic_val_nat_def (ne_of_gt hn),
{ apply enat.coe_get },
{ apply_instance } }
end
lemma pow_succ_padic_val_nat_not_dvd {p n : ℕ} [hp : fact (nat.prime p)] (hn : 0 < n) :
¬ p ^ (padic_val_nat p n + 1) ∣ n :=
begin
{ rw multiplicity.pow_dvd_iff_le_multiplicity,
rw padic_val_nat_def (ne_of_gt hn),
{ rw [enat.coe_add, enat.coe_get],
simp only [enat.coe_one, not_le],
apply enat.lt_add_one (ne_top_iff_finite.2 (finite_nat_iff.2 ⟨hp.elim.ne_one, hn⟩)) },
{ apply_instance } }
end
lemma padic_val_nat_primes {p q : ℕ} [p_prime : fact p.prime] [q_prime : fact q.prime]
(neq : p ≠ q) : padic_val_nat p q = 0 :=
@padic_val_nat_of_not_dvd p p_prime q $
(not_congr (iff.symm (prime_dvd_prime_iff_eq p_prime.1 q_prime.1))).mp neq
protected lemma padic_val_nat.div' {p : ℕ} [p_prime : fact p.prime] :
∀ {m : ℕ} (cpm : coprime p m) {b : ℕ} (dvd : m ∣ b), padic_val_nat p (b / m) = padic_val_nat p b
| 0 := λ cpm b dvd, by { rw zero_dvd_iff at dvd, rw [dvd, nat.zero_div], }
| (n + 1) :=
λ cpm b dvd,
begin
rcases dvd with ⟨c, rfl⟩,
rw [mul_div_right c (nat.succ_pos _)],by_cases hc : c = 0,
{ rw [hc, mul_zero] },
{ rw padic_val_nat.mul,
{ suffices : ¬ p ∣ (n+1),
{ rw [padic_val_nat_of_not_dvd this, zero_add] },
contrapose! cpm,
exact p_prime.1.dvd_iff_not_coprime.mp cpm },
{ exact nat.succ_ne_zero _ },
{ exact hc } },
end
lemma padic_val_nat_eq_factors_count (p : ℕ) [hp : fact p.prime] :
∀ (n : ℕ), padic_val_nat p n = (factors n).count p
| 0 := by simp
| 1 := by simp
| (m + 2) :=
let n := m + 2 in
let q := min_fac n in
have hq : fact q.prime := ⟨min_fac_prime (show m + 2 ≠ 1, by linarith)⟩,
have wf : n / q < n := nat.div_lt_self (nat.succ_pos _) hq.1.one_lt,
begin
rw factors_add_two,
show padic_val_nat p n = list.count p (q :: (factors (n / q))),
rw [list.count_cons', ← padic_val_nat_eq_factors_count],
split_ifs with h,
have p_dvd_n : p ∣ n,
{ have: q ∣ n := nat.min_fac_dvd n,
cc },
{ rw [←h, padic_val_nat.div],
{ have: 1 ≤ padic_val_nat p n := one_le_padic_val_nat_of_dvd (by linarith) p_dvd_n,
exact (nat.sub_eq_iff_eq_add this).mp rfl, },
{ exact p_dvd_n, }, },
{ suffices : p.coprime q,
{ rw [padic_val_nat.div' this (min_fac_dvd n), add_zero], },
rwa nat.coprime_primes hp.1 hq.1, },
end
open_locale big_operators
lemma prod_pow_prime_padic_val_nat (n : nat) (hn : n ≠ 0) (m : nat) (pr : n < m) :
∏ p in finset.filter nat.prime (finset.range m), p ^ (padic_val_nat p n) = n :=
begin
rw ← pos_iff_ne_zero at hn,
have H : (factors n : multiset ℕ).prod = n,
{ rw [multiset.coe_prod, prod_factors hn], },
rw finset.prod_multiset_count at H,
conv_rhs { rw ← H, },
refine finset.prod_bij_ne_one (λ p hp hp', p) _ _ _ _,
{ rintro p hp hpn,
rw [finset.mem_filter, finset.mem_range] at hp,
rw [multiset.mem_to_finset, multiset.mem_coe, mem_factors_iff_dvd hn hp.2],
contrapose! hpn,
haveI Hp : fact p.prime := ⟨hp.2⟩,
rw [padic_val_nat_of_not_dvd hpn, pow_zero], },
{ intros, assumption },
{ intros p hp hpn,
rw [multiset.mem_to_finset, multiset.mem_coe] at hp,
haveI Hp : fact p.prime := ⟨prime_of_mem_factors hp⟩,
simp only [exists_prop, ne.def, finset.mem_filter, finset.mem_range],
refine ⟨p, ⟨_, Hp.1⟩, ⟨_, rfl⟩⟩,
{ rw mem_factors_iff_dvd hn Hp.1 at hp, exact lt_of_le_of_lt (le_of_dvd hn hp) pr },
{ rw padic_val_nat_eq_factors_count,
simpa [ne.def, multiset.coe_count] using hpn } },
{ intros p hp hpn,
rw [finset.mem_filter, finset.mem_range] at hp,
haveI Hp : fact p.prime := ⟨hp.2⟩,
rw [padic_val_nat_eq_factors_count, multiset.coe_count] }
end
end padic_val_nat
/--
If `q ≠ 0`, the p-adic norm of a rational `q` is `p ^ (-(padic_val_rat p q))`.
If `q = 0`, the p-adic norm of `q` is 0.
-/
def padic_norm (p : ℕ) (q : ℚ) : ℚ :=
if q = 0 then 0 else (↑p : ℚ) ^ (-(padic_val_rat p q))
namespace padic_norm
section padic_norm
open padic_val_rat
variables (p : ℕ)
/--
Unfolds the definition of the p-adic norm of `q` when `q ≠ 0`.
-/
@[simp] protected lemma eq_fpow_of_nonzero {q : ℚ} (hq : q ≠ 0) :
padic_norm p q = p ^ (-(padic_val_rat p q)) :=
by simp [hq, padic_norm]
/--
The p-adic norm is nonnegative.
-/
protected lemma nonneg (q : ℚ) : 0 ≤ padic_norm p q :=
if hq : q = 0 then by simp [hq, padic_norm]
else
begin
unfold padic_norm; split_ifs,
apply fpow_nonneg,
exact_mod_cast nat.zero_le _
end
/--
The p-adic norm of 0 is 0.
-/
@[simp] protected lemma zero : padic_norm p 0 = 0 := by simp [padic_norm]
/--
The p-adic norm of 1 is 1.
-/
@[simp] protected lemma one : padic_norm p 1 = 1 := by simp [padic_norm]
/--
The p-adic norm of `p` is `1/p` if `p > 1`.
See also `padic_norm.padic_norm_p_of_prime` for a version that assumes `p` is prime.
-/
lemma padic_norm_p {p : ℕ} (hp : 1 < p) : padic_norm p p = 1 / p :=
by simp [padic_norm, (show p ≠ 0, by linarith), padic_val_rat.padic_val_rat_self hp]
/--
The p-adic norm of `p` is `1/p` if `p` is prime.
See also `padic_norm.padic_norm_p` for a version that assumes `1 < p`.
-/
@[simp] lemma padic_norm_p_of_prime (p : ℕ) [fact p.prime] : padic_norm p p = 1 / p :=
padic_norm_p $ nat.prime.one_lt (fact.out _)
/-- The p-adic norm of `q` is `1` if `q` is prime and not equal to `p`. -/
lemma padic_norm_of_prime_of_ne {p q : ℕ} [p_prime : fact p.prime] [q_prime : fact q.prime]
(neq : p ≠ q) : padic_norm p q = 1 :=
begin
have p : padic_val_rat p q = 0,
{ exact_mod_cast @padic_val_nat_primes p q p_prime q_prime neq },
simp [padic_norm, p, q_prime.1.1, q_prime.1.ne_zero],
end
/--
The p-adic norm of `p` is less than 1 if `1 < p`.
See also `padic_norm.padic_norm_p_lt_one_of_prime` for a version assuming `prime p`.
-/
lemma padic_norm_p_lt_one {p : ℕ} (hp : 1 < p) : padic_norm p p < 1 :=
begin
rw [padic_norm_p hp, div_lt_iff, one_mul],
{ exact_mod_cast hp },
{ exact_mod_cast zero_lt_one.trans hp },
end
/--
The p-adic norm of `p` is less than 1 if `p` is prime.
See also `padic_norm.padic_norm_p_lt_one` for a version assuming `1 < p`.
-/
lemma padic_norm_p_lt_one_of_prime (p : ℕ) [fact p.prime] : padic_norm p p < 1 :=
padic_norm_p_lt_one $ nat.prime.one_lt (fact.out _)
/--
`padic_norm p q` takes discrete values `p ^ -z` for `z : ℤ`.
-/
protected theorem values_discrete {q : ℚ} (hq : q ≠ 0) : ∃ z : ℤ, padic_norm p q = p ^ (-z) :=
⟨ (padic_val_rat p q), by simp [padic_norm, hq] ⟩
/--
`padic_norm p` is symmetric.
-/
@[simp] protected lemma neg (q : ℚ) : padic_norm p (-q) = padic_norm p q :=
if hq : q = 0 then by simp [hq]
else by simp [padic_norm, hq]
variable [hp : fact p.prime]
include hp
/--
If `q ≠ 0`, then `padic_norm p q ≠ 0`.
-/
protected lemma nonzero {q : ℚ} (hq : q ≠ 0) : padic_norm p q ≠ 0 :=
begin
rw padic_norm.eq_fpow_of_nonzero p hq,
apply fpow_ne_zero_of_ne_zero,
exact_mod_cast ne_of_gt hp.1.pos
end
/--
If the p-adic norm of `q` is 0, then `q` is 0.
-/
lemma zero_of_padic_norm_eq_zero {q : ℚ} (h : padic_norm p q = 0) : q = 0 :=
begin
apply by_contradiction, intro hq,
unfold padic_norm at h, rw if_neg hq at h,
apply absurd h,
apply fpow_ne_zero_of_ne_zero,
exact_mod_cast hp.1.ne_zero
end
/--
The p-adic norm is multiplicative.
-/
@[simp] protected theorem mul (q r : ℚ) : padic_norm p (q*r) = padic_norm p q * padic_norm p r :=
if hq : q = 0 then
by simp [hq]
else if hr : r = 0 then
by simp [hr]
else
have q*r ≠ 0, from mul_ne_zero hq hr,
have (↑p : ℚ) ≠ 0, by simp [hp.1.ne_zero],
by simp [padic_norm, *, padic_val_rat.mul, fpow_add this, mul_comm]
/--
The p-adic norm respects division.
-/
@[simp] protected theorem div (q r : ℚ) : padic_norm p (q / r) = padic_norm p q / padic_norm p r :=
if hr : r = 0 then by simp [hr] else
eq_div_of_mul_eq (padic_norm.nonzero _ hr) (by rw [←padic_norm.mul, div_mul_cancel _ hr])
/--
The p-adic norm of an integer is at most 1.
-/
protected theorem of_int (z : ℤ) : padic_norm p ↑z ≤ 1 :=
if hz : z = 0 then by simp [hz, zero_le_one] else
begin
unfold padic_norm,
rw [if_neg _],
{ refine fpow_le_one_of_nonpos _ _,
{ exact_mod_cast le_of_lt hp.1.one_lt, },
{ rw [padic_val_rat_of_int _ hp.1.ne_one hz, neg_nonpos],
norm_cast, simp }},
exact_mod_cast hz
end
private lemma nonarchimedean_aux {q r : ℚ} (h : padic_val_rat p q ≤ padic_val_rat p r) :
padic_norm p (q + r) ≤ max (padic_norm p q) (padic_norm p r) :=
have hnqp : padic_norm p q ≥ 0, from padic_norm.nonneg _ _,
have hnrp : padic_norm p r ≥ 0, from padic_norm.nonneg _ _,
if hq : q = 0 then
by simp [hq, max_eq_right hnrp, le_max_right]
else if hr : r = 0 then
by simp [hr, max_eq_left hnqp, le_max_left]
else if hqr : q + r = 0 then
le_trans (by simpa [hqr] using hnqp) (le_max_left _ _)
else
begin
unfold padic_norm, split_ifs,
apply le_max_iff.2,
left,
apply fpow_le_of_le,
{ exact_mod_cast le_of_lt hp.1.one_lt },
{ apply neg_le_neg,
have : padic_val_rat p q =
min (padic_val_rat p q) (padic_val_rat p r),
from (min_eq_left h).symm,
rw this,
apply min_le_padic_val_rat_add; assumption }
end
/--
The p-adic norm is nonarchimedean: the norm of `p + q` is at most the max of the norm of `p` and
the norm of `q`.
-/
protected theorem nonarchimedean {q r : ℚ} :
padic_norm p (q + r) ≤ max (padic_norm p q) (padic_norm p r) :=
begin
wlog hle := le_total (padic_val_rat p q) (padic_val_rat p r) using [q r],
exact nonarchimedean_aux p hle
end
/--
The p-adic norm respects the triangle inequality: the norm of `p + q` is at most the norm of `p`
plus the norm of `q`.
-/
theorem triangle_ineq (q r : ℚ) : padic_norm p (q + r) ≤ padic_norm p q + padic_norm p r :=
calc padic_norm p (q + r) ≤ max (padic_norm p q) (padic_norm p r) : padic_norm.nonarchimedean p
... ≤ padic_norm p q + padic_norm p r :
max_le_add_of_nonneg (padic_norm.nonneg p _) (padic_norm.nonneg p _)
/--
The p-adic norm of a difference is at most the max of each component. Restates the archimedean
property of the p-adic norm.
-/
protected theorem sub {q r : ℚ} : padic_norm p (q - r) ≤ max (padic_norm p q) (padic_norm p r) :=
by rw [sub_eq_add_neg, ←padic_norm.neg p r]; apply padic_norm.nonarchimedean
/--
If the p-adic norms of `q` and `r` are different, then the norm of `q + r` is equal to the max of
the norms of `q` and `r`.
-/
lemma add_eq_max_of_ne {q r : ℚ} (hne : padic_norm p q ≠ padic_norm p r) :
padic_norm p (q + r) = max (padic_norm p q) (padic_norm p r) :=
begin
wlog hle := le_total (padic_norm p r) (padic_norm p q) using [q r],
have hlt : padic_norm p r < padic_norm p q, from lt_of_le_of_ne hle hne.symm,
have : padic_norm p q ≤ max (padic_norm p (q + r)) (padic_norm p r), from calc
padic_norm p q = padic_norm p (q + r - r) : by congr; ring
... ≤ max (padic_norm p (q + r)) (padic_norm p (-r)) : padic_norm.nonarchimedean p
... = max (padic_norm p (q + r)) (padic_norm p r) : by simp,
have hnge : padic_norm p r ≤ padic_norm p (q + r),
{ apply le_of_not_gt,
intro hgt,
rw max_eq_right_of_lt hgt at this,
apply not_lt_of_ge this,
assumption },
have : padic_norm p q ≤ padic_norm p (q + r), by rwa [max_eq_left hnge] at this,
apply _root_.le_antisymm,
{ apply padic_norm.nonarchimedean p },
{ rw max_eq_left_of_lt hlt,
assumption }
end
/--
The p-adic norm is an absolute value: positive-definite and multiplicative, satisfying the triangle
inequality.
-/
instance : is_absolute_value (padic_norm p) :=
{ abv_nonneg := padic_norm.nonneg p,
abv_eq_zero :=
begin
intros,
constructor; intro,
{ apply zero_of_padic_norm_eq_zero p, assumption },
{ simp [*] }
end,
abv_add := padic_norm.triangle_ineq p,
abv_mul := padic_norm.mul p }
variable {p}
lemma dvd_iff_norm_le {n : ℕ} {z : ℤ} : ↑(p^n) ∣ z ↔ padic_norm p z ≤ ↑p ^ (-n : ℤ) :=
begin
unfold padic_norm, split_ifs with hz,
{ norm_cast at hz,
have : 0 ≤ (p^n : ℚ), {apply pow_nonneg, exact_mod_cast le_of_lt hp.1.pos },
simp [hz, this] },
{ rw [fpow_le_iff_le, neg_le_neg_iff, padic_val_rat_of_int _ hp.1.ne_one _],
{ norm_cast,
rw [← enat.coe_le_coe, enat.coe_get, ← multiplicity.pow_dvd_iff_le_multiplicity],
simp },
{ exact_mod_cast hz },
{ exact_mod_cast hp.1.one_lt } }
end
end padic_norm
end padic_norm
|
35215510dd62af444924eee71928f10d389f15a8 | 8cae430f0a71442d02dbb1cbb14073b31048e4b0 | /src/order/monotone/union.lean | f1fe9ac9d7aaebd735d096d3841ec5ce8cfed703 | [
"Apache-2.0"
] | permissive | leanprover-community/mathlib | 56a2cadd17ac88caf4ece0a775932fa26327ba0e | 442a83d738cb208d3600056c489be16900ba701d | refs/heads/master | 1,693,584,102,358 | 1,693,471,902,000 | 1,693,471,902,000 | 97,922,418 | 1,595 | 352 | Apache-2.0 | 1,694,693,445,000 | 1,500,624,130,000 | Lean | UTF-8 | Lean | false | false | 5,357 | lean | /-
Copyright (c) 2022 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov, Sébastien Gouëzel
-/
import order.bounds.basic
/-!
# Monotonicity on intervals
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
In this file we prove that a function is (strictly) monotone (or antitone) on a linear order `α`
provided that it is (strictly) monotone on `(-∞, a]` and on `[a, +∞)`. This is a special case
of a more general statement where one deduces monotonicity on a union from monotonicity on each
set.
-/
open set
variables {α β : Type*} [linear_order α] [preorder β] {a : α} {f : α → β}
/-- If `f` is strictly monotone both on `s` and `t`, with `s` to the left of `t` and the center
point belonging to both `s` and `t`, then `f` is strictly monotone on `s ∪ t` -/
protected lemma strict_mono_on.union {s t : set α} {c : α} (h₁ : strict_mono_on f s)
(h₂ : strict_mono_on f t) (hs : is_greatest s c) (ht : is_least t c) :
strict_mono_on f (s ∪ t) :=
begin
have A : ∀ x, x ∈ s ∪ t → x ≤ c → x ∈ s,
{ assume x hx hxc,
cases hx, { exact hx },
rcases eq_or_lt_of_le hxc with rfl|h'x, { exact hs.1 },
exact (lt_irrefl _ (h'x.trans_le (ht.2 hx))).elim },
have B : ∀ x, x ∈ s ∪ t → c ≤ x → x ∈ t,
{ assume x hx hxc,
cases hx, swap, { exact hx },
rcases eq_or_lt_of_le hxc with rfl|h'x, { exact ht.1 },
exact (lt_irrefl _ (h'x.trans_le (hs.2 hx))).elim },
assume x hx y hy hxy,
rcases lt_or_le x c with hxc|hcx,
{ have xs : x ∈ s, from A _ hx hxc.le,
rcases lt_or_le y c with hyc|hcy,
{ exact h₁ xs (A _ hy hyc.le) hxy },
{ exact (h₁ xs hs.1 hxc).trans_le (h₂.monotone_on ht.1 (B _ hy hcy) hcy) } },
{ have xt : x ∈ t, from B _ hx hcx,
have yt : y ∈ t, from B _ hy (hcx.trans hxy.le),
exact h₂ xt yt hxy }
end
/-- If `f` is strictly monotone both on `(-∞, a]` and `[a, ∞)`, then it is strictly monotone on the
whole line. -/
protected lemma strict_mono_on.Iic_union_Ici (h₁ : strict_mono_on f (Iic a))
(h₂ : strict_mono_on f (Ici a)) : strict_mono f :=
begin
rw [← strict_mono_on_univ, ← @Iic_union_Ici _ _ a],
exact strict_mono_on.union h₁ h₂ is_greatest_Iic is_least_Ici,
end
/-- If `f` is strictly antitone both on `s` and `t`, with `s` to the left of `t` and the center
point belonging to both `s` and `t`, then `f` is strictly antitone on `s ∪ t` -/
protected lemma strict_anti_on.union {s t : set α} {c : α} (h₁ : strict_anti_on f s)
(h₂ : strict_anti_on f t) (hs : is_greatest s c) (ht : is_least t c) :
strict_anti_on f (s ∪ t) :=
(h₁.dual_right.union h₂.dual_right hs ht).dual_right
/-- If `f` is strictly antitone both on `(-∞, a]` and `[a, ∞)`, then it is strictly antitone on the
whole line. -/
protected lemma strict_anti_on.Iic_union_Ici (h₁ : strict_anti_on f (Iic a))
(h₂ : strict_anti_on f (Ici a)) : strict_anti f :=
(h₁.dual_right.Iic_union_Ici h₂.dual_right).dual_right
/-- If `f` is monotone both on `s` and `t`, with `s` to the left of `t` and the center
point belonging to both `s` and `t`, then `f` is monotone on `s ∪ t` -/
protected lemma monotone_on.union_right {s t : set α} {c : α} (h₁ : monotone_on f s)
(h₂ : monotone_on f t) (hs : is_greatest s c) (ht : is_least t c) :
monotone_on f (s ∪ t) :=
begin
have A : ∀ x, x ∈ s ∪ t → x ≤ c → x ∈ s,
{ assume x hx hxc,
cases hx, { exact hx },
rcases eq_or_lt_of_le hxc with rfl|h'x, { exact hs.1 },
exact (lt_irrefl _ (h'x.trans_le (ht.2 hx))).elim },
have B : ∀ x, x ∈ s ∪ t → c ≤ x → x ∈ t,
{ assume x hx hxc,
cases hx, swap, { exact hx },
rcases eq_or_lt_of_le hxc with rfl|h'x, { exact ht.1 },
exact (lt_irrefl _ (h'x.trans_le (hs.2 hx))).elim },
assume x hx y hy hxy,
rcases lt_or_le x c with hxc|hcx,
{ have xs : x ∈ s, from A _ hx hxc.le,
rcases lt_or_le y c with hyc|hcy,
{ exact h₁ xs (A _ hy hyc.le) hxy },
{ exact (h₁ xs hs.1 hxc.le).trans (h₂ ht.1 (B _ hy hcy) hcy) } },
{ have xt : x ∈ t, from B _ hx hcx,
have yt : y ∈ t, from B _ hy (hcx.trans hxy),
exact h₂ xt yt hxy }
end
/-- If `f` is monotone both on `(-∞, a]` and `[a, ∞)`, then it is monotone on the whole line. -/
protected lemma monotone_on.Iic_union_Ici (h₁ : monotone_on f (Iic a))
(h₂ : monotone_on f (Ici a)) : monotone f :=
begin
rw [← monotone_on_univ, ← @Iic_union_Ici _ _ a],
exact monotone_on.union_right h₁ h₂ is_greatest_Iic is_least_Ici
end
/-- If `f` is antitone both on `s` and `t`, with `s` to the left of `t` and the center
point belonging to both `s` and `t`, then `f` is antitone on `s ∪ t` -/
protected lemma antitone_on.union_right {s t : set α} {c : α} (h₁ : antitone_on f s)
(h₂ : antitone_on f t) (hs : is_greatest s c) (ht : is_least t c) :
antitone_on f (s ∪ t) :=
(h₁.dual_right.union_right h₂.dual_right hs ht).dual_right
/-- If `f` is antitone both on `(-∞, a]` and `[a, ∞)`, then it is antitone on the whole line. -/
protected lemma antitone_on.Iic_union_Ici (h₁ : antitone_on f (Iic a))
(h₂ : antitone_on f (Ici a)) : antitone f :=
(h₁.dual_right.Iic_union_Ici h₂.dual_right).dual_right
|
7048ec2b1cc064f0f32df5576cc970fa54259d2d | 6e9cd8d58e550c481a3b45806bd34a3514c6b3e0 | /src/data/int/basic.lean | a7a7ae6b1b2a6fc8152e4dfb2eed36237154a97f | [
"Apache-2.0"
] | permissive | sflicht/mathlib | 220fd16e463928110e7b0a50bbed7b731979407f | 1b2048d7195314a7e34e06770948ee00f0ac3545 | refs/heads/master | 1,665,934,056,043 | 1,591,373,803,000 | 1,591,373,803,000 | 269,815,267 | 0 | 0 | Apache-2.0 | 1,591,402,068,000 | 1,591,402,067,000 | null | UTF-8 | Lean | false | false | 54,638 | lean | /-
Copyright (c) 2016 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad
The integers, with addition, multiplication, and subtraction.
-/
import algebra.char_zero
import init_.data.int.order
import algebra.ring
import data.list.range
open nat
namespace int
instance : inhabited ℤ := ⟨int.zero⟩
@[simp] lemma default_eq_zero : default ℤ = 0 := rfl
meta instance : has_to_format ℤ := ⟨λ z, to_string z⟩
meta instance : has_reflect ℤ := by tactic.mk_has_reflect_instance
attribute [simp] int.coe_nat_add int.coe_nat_mul int.coe_nat_zero int.coe_nat_one int.coe_nat_succ
attribute [simp] int.of_nat_eq_coe int.bodd
@[simp] theorem add_def {a b : ℤ} : int.add a b = a + b := rfl
@[simp] theorem mul_def {a b : ℤ} : int.mul a b = a * b := rfl
@[simp] theorem coe_nat_mul_neg_succ (m n : ℕ) : (m : ℤ) * -[1+ n] = -(m * succ n) := rfl
@[simp] theorem neg_succ_mul_coe_nat (m n : ℕ) : -[1+ m] * n = -(succ m * n) := rfl
@[simp] theorem neg_succ_mul_neg_succ (m n : ℕ) : -[1+ m] * -[1+ n] = succ m * succ n := rfl
@[simp, norm_cast]
theorem coe_nat_le {m n : ℕ} : (↑m : ℤ) ≤ ↑n ↔ m ≤ n := coe_nat_le_coe_nat_iff m n
@[simp, norm_cast]
theorem coe_nat_lt {m n : ℕ} : (↑m : ℤ) < ↑n ↔ m < n := coe_nat_lt_coe_nat_iff m n
@[simp, norm_cast]
theorem coe_nat_inj' {m n : ℕ} : (↑m : ℤ) = ↑n ↔ m = n := int.coe_nat_eq_coe_nat_iff m n
@[simp] theorem coe_nat_pos {n : ℕ} : (0 : ℤ) < n ↔ 0 < n :=
by rw [← int.coe_nat_zero, coe_nat_lt]
@[simp] theorem coe_nat_eq_zero {n : ℕ} : (n : ℤ) = 0 ↔ n = 0 :=
by rw [← int.coe_nat_zero, coe_nat_inj']
theorem coe_nat_ne_zero {n : ℕ} : (n : ℤ) ≠ 0 ↔ n ≠ 0 :=
not_congr coe_nat_eq_zero
lemma coe_nat_nonneg (n : ℕ) : 0 ≤ (n : ℤ) := coe_nat_le.2 (nat.zero_le _)
lemma coe_nat_ne_zero_iff_pos {n : ℕ} : (n : ℤ) ≠ 0 ↔ 0 < n :=
⟨λ h, nat.pos_of_ne_zero (coe_nat_ne_zero.1 h),
λ h, (ne_of_lt (coe_nat_lt.2 h)).symm⟩
lemma coe_nat_succ_pos (n : ℕ) : 0 < (n.succ : ℤ) := int.coe_nat_pos.2 (succ_pos n)
@[simp, norm_cast] theorem coe_nat_abs (n : ℕ) : abs (n : ℤ) = n :=
abs_of_nonneg (coe_nat_nonneg n)
/- succ and pred -/
/-- Immediate successor of an integer: `succ n = n + 1` -/
def succ (a : ℤ) := a + 1
/-- Immediate predecessor of an integer: `pred n = n - 1` -/
def pred (a : ℤ) := a - 1
theorem nat_succ_eq_int_succ (n : ℕ) : (nat.succ n : ℤ) = int.succ n := rfl
theorem pred_succ (a : ℤ) : pred (succ a) = a := add_sub_cancel _ _
theorem succ_pred (a : ℤ) : succ (pred a) = a := sub_add_cancel _ _
theorem neg_succ (a : ℤ) : -succ a = pred (-a) := neg_add _ _
theorem succ_neg_succ (a : ℤ) : succ (-succ a) = -a :=
by rw [neg_succ, succ_pred]
theorem neg_pred (a : ℤ) : -pred a = succ (-a) :=
by rw [eq_neg_of_eq_neg (neg_succ (-a)).symm, neg_neg]
theorem pred_neg_pred (a : ℤ) : pred (-pred a) = -a :=
by rw [neg_pred, pred_succ]
theorem pred_nat_succ (n : ℕ) : pred (nat.succ n) = n := pred_succ n
theorem neg_nat_succ (n : ℕ) : -(nat.succ n : ℤ) = pred (-n) := neg_succ n
theorem succ_neg_nat_succ (n : ℕ) : succ (-nat.succ n) = -n := succ_neg_succ n
theorem lt_succ_self (a : ℤ) : a < succ a :=
lt_add_of_pos_right _ zero_lt_one
theorem pred_self_lt (a : ℤ) : pred a < a :=
sub_lt_self _ zero_lt_one
theorem add_one_le_iff {a b : ℤ} : a + 1 ≤ b ↔ a < b := iff.rfl
theorem lt_add_one_iff {a b : ℤ} : a < b + 1 ↔ a ≤ b :=
@add_le_add_iff_right _ _ a b 1
theorem sub_one_lt_iff {a b : ℤ} : a - 1 < b ↔ a ≤ b :=
sub_lt_iff_lt_add.trans lt_add_one_iff
theorem le_sub_one_iff {a b : ℤ} : a ≤ b - 1 ↔ a < b :=
le_sub_iff_add_le
@[elab_as_eliminator] protected lemma induction_on {p : ℤ → Prop}
(i : ℤ) (hz : p 0) (hp : ∀i : ℕ, p i → p (i + 1)) (hn : ∀i : ℕ, p (-i) → p (-i - 1)) : p i :=
begin
induction i,
{ induction i,
{ exact hz },
{ exact hp _ i_ih } },
{ have : ∀n:ℕ, p (- n),
{ intro n, induction n,
{ simp [hz] },
{ convert hn _ n_ih using 1, simp [sub_eq_neg_add] } },
exact this (i + 1) }
end
protected def induction_on' {C : ℤ → Sort*} (z : ℤ) (b : ℤ) :
C b → (∀ k, b ≤ k → C k → C (k + 1)) → (∀ k ≤ b, C k → C (k - 1)) → C z :=
λ H0 Hs Hp,
begin
rw ←sub_add_cancel z b,
induction (z - b),
{ induction a with n ih, { rwa [of_nat_zero, zero_add] },
rw [of_nat_succ, add_assoc, add_comm 1 b, ←add_assoc],
exact Hs _ (le_add_of_nonneg_left (of_nat_nonneg _)) ih },
{ induction a with n ih,
{ rw [neg_succ_of_nat_eq, ←of_nat_eq_coe, of_nat_zero, zero_add, neg_add_eq_sub],
exact Hp _ (le_refl _) H0 },
{ rw [neg_succ_of_nat_coe', nat.succ_eq_add_one, ←neg_succ_of_nat_coe, sub_add_eq_add_sub],
exact Hp _ (le_of_lt (add_lt_of_neg_of_le (neg_succ_lt_zero _) (le_refl _))) ih } }
end
/- nat abs -/
attribute [simp] nat_abs nat_abs_of_nat nat_abs_zero nat_abs_one
theorem nat_abs_add_le (a b : ℤ) : nat_abs (a + b) ≤ nat_abs a + nat_abs b :=
begin
have : ∀ (a b : ℕ), nat_abs (sub_nat_nat a (nat.succ b)) ≤ nat.succ (a + b),
{ refine (λ a b : ℕ, sub_nat_nat_elim a b.succ
(λ m n i, n = b.succ → nat_abs i ≤ (m + b).succ) _ _ rfl);
intros i n e,
{ subst e, rw [add_comm _ i, add_assoc],
exact nat.le_add_right i (b.succ + b).succ },
{ apply succ_le_succ,
rw [← succ_inj e, ← add_assoc, add_comm],
apply nat.le_add_right } },
cases a; cases b with b b; simp [nat_abs, nat.succ_add];
try {refl}; [skip, rw add_comm a b]; apply this
end
theorem nat_abs_neg_of_nat (n : ℕ) : nat_abs (neg_of_nat n) = n :=
by cases n; refl
theorem nat_abs_mul (a b : ℤ) : nat_abs (a * b) = (nat_abs a) * (nat_abs b) :=
by cases a; cases b; simp only [(*), int.mul, nat_abs_neg_of_nat, eq_self_iff_true, int.nat_abs]
@[simp] lemma nat_abs_mul_self' (a : ℤ) : (nat_abs a * nat_abs a : ℤ) = a * a :=
by rw [← int.coe_nat_mul, nat_abs_mul_self]
theorem neg_succ_of_nat_eq' (m : ℕ) : -[1+ m] = -m - 1 :=
by simp [neg_succ_of_nat_eq, sub_eq_neg_add]
lemma nat_abs_ne_zero_of_ne_zero {z : ℤ} (hz : z ≠ 0) : z.nat_abs ≠ 0 :=
λ h, hz $ int.eq_zero_of_nat_abs_eq_zero h
@[simp] lemma nat_abs_eq_zero {a : ℤ} : a.nat_abs = 0 ↔ a = 0 :=
⟨int.eq_zero_of_nat_abs_eq_zero, λ h, h.symm ▸ rfl⟩
lemma nat_abs_lt_nat_abs_of_nonneg_of_lt {a b : ℤ} (w₁ : 0 ≤ a) (w₂ : a < b) :
a.nat_abs < b.nat_abs :=
begin
lift b to ℕ using le_trans w₁ (le_of_lt w₂),
lift a to ℕ using w₁,
simpa using w₂,
end
/- / -/
@[simp] theorem of_nat_div (m n : ℕ) : of_nat (m / n) = (of_nat m) / (of_nat n) := rfl
@[simp, norm_cast] theorem coe_nat_div (m n : ℕ) : ((m / n : ℕ) : ℤ) = m / n := rfl
theorem neg_succ_of_nat_div (m : ℕ) {b : ℤ} (H : 0 < b) :
-[1+m] / b = -(m / b + 1) :=
match b, eq_succ_of_zero_lt H with ._, ⟨n, rfl⟩ := rfl end
@[simp] protected theorem div_neg : ∀ (a b : ℤ), a / -b = -(a / b)
| (m : ℕ) 0 := show of_nat (m / 0) = -(m / 0 : ℕ), by rw nat.div_zero; refl
| (m : ℕ) (n+1:ℕ) := rfl
| 0 -[1+ n] := rfl
| (m+1:ℕ) -[1+ n] := (neg_neg _).symm
| -[1+ m] 0 := rfl
| -[1+ m] (n+1:ℕ) := rfl
| -[1+ m] -[1+ n] := rfl
theorem div_of_neg_of_pos {a b : ℤ} (Ha : a < 0) (Hb : 0 < b) : a / b = -((-a - 1) / b + 1) :=
match a, b, eq_neg_succ_of_lt_zero Ha, eq_succ_of_zero_lt Hb with
| ._, ._, ⟨m, rfl⟩, ⟨n, rfl⟩ :=
by change (- -[1+ m] : ℤ) with (m+1 : ℤ); rw add_sub_cancel; refl
end
protected theorem div_nonneg {a b : ℤ} (Ha : 0 ≤ a) (Hb : 0 ≤ b) : 0 ≤ a / b :=
match a, b, eq_coe_of_zero_le Ha, eq_coe_of_zero_le Hb with
| ._, ._, ⟨m, rfl⟩, ⟨n, rfl⟩ := coe_zero_le _
end
protected theorem div_nonpos {a b : ℤ} (Ha : 0 ≤ a) (Hb : b ≤ 0) : a / b ≤ 0 :=
nonpos_of_neg_nonneg $ by rw [← int.div_neg]; exact int.div_nonneg Ha (neg_nonneg_of_nonpos Hb)
theorem div_neg' {a b : ℤ} (Ha : a < 0) (Hb : 0 < b) : a / b < 0 :=
match a, b, eq_neg_succ_of_lt_zero Ha, eq_succ_of_zero_lt Hb with
| ._, ._, ⟨m, rfl⟩, ⟨n, rfl⟩ := neg_succ_lt_zero _
end
-- Will be generalized to Euclidean domains.
protected theorem zero_div : ∀ (b : ℤ), 0 / b = 0
| 0 := rfl
| (n+1:ℕ) := rfl
| -[1+ n] := rfl
local attribute [simp] -- Will be generalized to Euclidean domains.
protected theorem div_zero : ∀ (a : ℤ), a / 0 = 0
| 0 := rfl
| (n+1:ℕ) := rfl
| -[1+ n] := rfl
@[simp] protected theorem div_one : ∀ (a : ℤ), a / 1 = a
| 0 := rfl
| (n+1:ℕ) := congr_arg of_nat (nat.div_one _)
| -[1+ n] := congr_arg neg_succ_of_nat (nat.div_one _)
theorem div_eq_zero_of_lt {a b : ℤ} (H1 : 0 ≤ a) (H2 : a < b) : a / b = 0 :=
match a, b, eq_coe_of_zero_le H1, eq_succ_of_zero_lt (lt_of_le_of_lt H1 H2), H2 with
| ._, ._, ⟨m, rfl⟩, ⟨n, rfl⟩, H2 :=
congr_arg of_nat $ nat.div_eq_of_lt $ lt_of_coe_nat_lt_coe_nat H2
end
theorem div_eq_zero_of_lt_abs {a b : ℤ} (H1 : 0 ≤ a) (H2 : a < abs b) : a / b = 0 :=
match b, abs b, abs_eq_nat_abs b, H2 with
| (n : ℕ), ._, rfl, H2 := div_eq_zero_of_lt H1 H2
| -[1+ n], ._, rfl, H2 := neg_inj $ by rw [← int.div_neg]; exact div_eq_zero_of_lt H1 H2
end
protected theorem add_mul_div_right (a b : ℤ) {c : ℤ} (H : c ≠ 0) :
(a + b * c) / c = a / c + b :=
have ∀ {k n : ℕ} {a : ℤ}, (a + n * k.succ) / k.succ = a / k.succ + n, from
λ k n a, match a with
| (m : ℕ) := congr_arg of_nat $ nat.add_mul_div_right _ _ k.succ_pos
| -[1+ m] := show ((n * k.succ:ℕ) - m.succ : ℤ) / k.succ =
n - (m / k.succ + 1 : ℕ), begin
cases lt_or_ge m (n*k.succ) with h h,
{ rw [← int.coe_nat_sub h,
← int.coe_nat_sub ((nat.div_lt_iff_lt_mul _ _ k.succ_pos).2 h)],
apply congr_arg of_nat,
rw [mul_comm, nat.mul_sub_div], rwa mul_comm },
{ change (↑(n * nat.succ k) - (m + 1) : ℤ) / ↑(nat.succ k) =
↑n - ((m / nat.succ k : ℕ) + 1),
rw [← sub_sub, ← sub_sub, ← neg_sub (m:ℤ), ← neg_sub _ (n:ℤ),
← int.coe_nat_sub h,
← int.coe_nat_sub ((nat.le_div_iff_mul_le _ _ k.succ_pos).2 h),
← neg_succ_of_nat_coe', ← neg_succ_of_nat_coe'],
{ apply congr_arg neg_succ_of_nat,
rw [mul_comm, nat.sub_mul_div], rwa mul_comm } }
end
end,
have ∀ {a b c : ℤ}, 0 < c → (a + b * c) / c = a / c + b, from
λ a b c H, match c, eq_succ_of_zero_lt H, b with
| ._, ⟨k, rfl⟩, (n : ℕ) := this
| ._, ⟨k, rfl⟩, -[1+ n] :=
show (a - n.succ * k.succ) / k.succ = (a / k.succ) - n.succ, from
eq_sub_of_add_eq $ by rw [← this, sub_add_cancel]
end,
match lt_trichotomy c 0 with
| or.inl hlt := neg_inj $ by rw [← int.div_neg, neg_add, ← int.div_neg, ← neg_mul_neg];
apply this (neg_pos_of_neg hlt)
| or.inr (or.inl heq) := absurd heq H
| or.inr (or.inr hgt) := this hgt
end
protected theorem add_mul_div_left (a : ℤ) {b : ℤ} (c : ℤ) (H : b ≠ 0) :
(a + b * c) / b = a / b + c :=
by rw [mul_comm, int.add_mul_div_right _ _ H]
@[simp] protected theorem mul_div_cancel (a : ℤ) {b : ℤ} (H : b ≠ 0) : a * b / b = a :=
by have := int.add_mul_div_right 0 a H;
rwa [zero_add, int.zero_div, zero_add] at this
@[simp] protected theorem mul_div_cancel_left {a : ℤ} (b : ℤ) (H : a ≠ 0) : a * b / a = b :=
by rw [mul_comm, int.mul_div_cancel _ H]
@[simp] protected theorem div_self {a : ℤ} (H : a ≠ 0) : a / a = 1 :=
by have := int.mul_div_cancel 1 H; rwa one_mul at this
/- mod -/
theorem of_nat_mod (m n : nat) : (m % n : ℤ) = of_nat (m % n) := rfl
@[simp] theorem coe_nat_mod (m n : ℕ) : (↑(m % n) : ℤ) = ↑m % ↑n := rfl
theorem neg_succ_of_nat_mod (m : ℕ) {b : ℤ} (bpos : 0 < b) :
-[1+m] % b = b - 1 - m % b :=
by rw [sub_sub, add_comm]; exact
match b, eq_succ_of_zero_lt bpos with ._, ⟨n, rfl⟩ := rfl end
@[simp] theorem mod_neg : ∀ (a b : ℤ), a % -b = a % b
| (m : ℕ) n := @congr_arg ℕ ℤ _ _ (λ i, ↑(m % i)) (nat_abs_neg _)
| -[1+ m] n := @congr_arg ℕ ℤ _ _ (λ i, sub_nat_nat i (nat.succ (m % i))) (nat_abs_neg _)
@[simp] theorem mod_abs (a b : ℤ) : a % (abs b) = a % b :=
abs_by_cases (λ i, a % i = a % b) rfl (mod_neg _ _)
local attribute [simp] -- Will be generalized to Euclidean domains.
theorem zero_mod (b : ℤ) : 0 % b = 0 :=
congr_arg of_nat $ nat.zero_mod _
local attribute [simp] -- Will be generalized to Euclidean domains.
theorem mod_zero : ∀ (a : ℤ), a % 0 = a
| (m : ℕ) := congr_arg of_nat $ nat.mod_zero _
| -[1+ m] := congr_arg neg_succ_of_nat $ nat.mod_zero _
local attribute [simp] -- Will be generalized to Euclidean domains.
theorem mod_one : ∀ (a : ℤ), a % 1 = 0
| (m : ℕ) := congr_arg of_nat $ nat.mod_one _
| -[1+ m] := show (1 - (m % 1).succ : ℤ) = 0, by rw nat.mod_one; refl
theorem mod_eq_of_lt {a b : ℤ} (H1 : 0 ≤ a) (H2 : a < b) : a % b = a :=
match a, b, eq_coe_of_zero_le H1, eq_coe_of_zero_le (le_trans H1 (le_of_lt H2)), H2 with
| ._, ._, ⟨m, rfl⟩, ⟨n, rfl⟩, H2 :=
congr_arg of_nat $ nat.mod_eq_of_lt (lt_of_coe_nat_lt_coe_nat H2)
end
theorem mod_nonneg : ∀ (a : ℤ) {b : ℤ}, b ≠ 0 → 0 ≤ a % b
| (m : ℕ) n H := coe_zero_le _
| -[1+ m] n H :=
sub_nonneg_of_le $ coe_nat_le_coe_nat_of_le $ nat.mod_lt _ (nat_abs_pos_of_ne_zero H)
theorem mod_lt_of_pos (a : ℤ) {b : ℤ} (H : 0 < b) : a % b < b :=
match a, b, eq_succ_of_zero_lt H with
| (m : ℕ), ._, ⟨n, rfl⟩ := coe_nat_lt_coe_nat_of_lt (nat.mod_lt _ (nat.succ_pos _))
| -[1+ m], ._, ⟨n, rfl⟩ := sub_lt_self _ (coe_nat_lt_coe_nat_of_lt $ nat.succ_pos _)
end
theorem mod_lt (a : ℤ) {b : ℤ} (H : b ≠ 0) : a % b < abs b :=
by rw [← mod_abs]; exact mod_lt_of_pos _ (abs_pos_of_ne_zero H)
theorem mod_add_div_aux (m n : ℕ) : (n - (m % n + 1) - (n * (m / n) + n) : ℤ) = -[1+ m] :=
begin
rw [← sub_sub, neg_succ_of_nat_coe, sub_sub (n:ℤ)],
apply eq_neg_of_eq_neg,
rw [neg_sub, sub_sub_self, add_right_comm],
exact @congr_arg ℕ ℤ _ _ (λi, (i + 1 : ℤ)) (nat.mod_add_div _ _).symm
end
theorem mod_add_div : ∀ (a b : ℤ), a % b + b * (a / b) = a
| (m : ℕ) 0 := congr_arg of_nat (nat.mod_add_div _ _)
| (m : ℕ) (n+1:ℕ) := congr_arg of_nat (nat.mod_add_div _ _)
| 0 -[1+ n] := rfl
| (m+1:ℕ) -[1+ n] := show (_ + -(n+1) * -((m + 1) / (n + 1) : ℕ) : ℤ) = _,
by rw [neg_mul_neg]; exact congr_arg of_nat (nat.mod_add_div _ _)
| -[1+ m] 0 := by rw [mod_zero, int.div_zero]; refl
| -[1+ m] (n+1:ℕ) := mod_add_div_aux m n.succ
| -[1+ m] -[1+ n] := mod_add_div_aux m n.succ
theorem mod_def (a b : ℤ) : a % b = a - b * (a / b) :=
eq_sub_of_add_eq (mod_add_div _ _)
@[simp] theorem add_mul_mod_self {a b c : ℤ} : (a + b * c) % c = a % c :=
if cz : c = 0 then by rw [cz, mul_zero, add_zero] else
by rw [mod_def, mod_def, int.add_mul_div_right _ _ cz,
mul_add, mul_comm, add_sub_add_right_eq_sub]
@[simp] theorem add_mul_mod_self_left (a b c : ℤ) : (a + b * c) % b = a % b :=
by rw [mul_comm, add_mul_mod_self]
@[simp] theorem add_mod_self {a b : ℤ} : (a + b) % b = a % b :=
by have := add_mul_mod_self_left a b 1; rwa mul_one at this
@[simp] theorem add_mod_self_left {a b : ℤ} : (a + b) % a = b % a :=
by rw [add_comm, add_mod_self]
@[simp] theorem mod_add_mod (m n k : ℤ) : (m % n + k) % n = (m + k) % n :=
by have := (add_mul_mod_self_left (m % n + k) n (m / n)).symm;
rwa [add_right_comm, mod_add_div] at this
@[simp] theorem add_mod_mod (m n k : ℤ) : (m + n % k) % k = (m + n) % k :=
by rw [add_comm, mod_add_mod, add_comm]
lemma add_mod (a b n : ℤ) : (a + b) % n = ((a % n) + (b % n)) % n :=
by rw [add_mod_mod, mod_add_mod]
theorem add_mod_eq_add_mod_right {m n k : ℤ} (i : ℤ) (H : m % n = k % n) :
(m + i) % n = (k + i) % n :=
by rw [← mod_add_mod, ← mod_add_mod k, H]
theorem add_mod_eq_add_mod_left {m n k : ℤ} (i : ℤ) (H : m % n = k % n) :
(i + m) % n = (i + k) % n :=
by rw [add_comm, add_mod_eq_add_mod_right _ H, add_comm]
theorem mod_add_cancel_right {m n k : ℤ} (i) : (m + i) % n = (k + i) % n ↔
m % n = k % n :=
⟨λ H, by have := add_mod_eq_add_mod_right (-i) H;
rwa [add_neg_cancel_right, add_neg_cancel_right] at this,
add_mod_eq_add_mod_right _⟩
theorem mod_add_cancel_left {m n k i : ℤ} :
(i + m) % n = (i + k) % n ↔ m % n = k % n :=
by rw [add_comm, add_comm i, mod_add_cancel_right]
theorem mod_sub_cancel_right {m n k : ℤ} (i) : (m - i) % n = (k - i) % n ↔
m % n = k % n :=
mod_add_cancel_right _
theorem mod_eq_mod_iff_mod_sub_eq_zero {m n k : ℤ} : m % n = k % n ↔ (m - k) % n = 0 :=
(mod_sub_cancel_right k).symm.trans $ by simp
@[simp] theorem mul_mod_left (a b : ℤ) : (a * b) % b = 0 :=
by rw [← zero_add (a * b), add_mul_mod_self, zero_mod]
@[simp] theorem mul_mod_right (a b : ℤ) : (a * b) % a = 0 :=
by rw [mul_comm, mul_mod_left]
lemma mul_mod (a b n : ℤ) : (a * b) % n = ((a % n) * (b % n)) % n :=
begin
conv_lhs {
rw [←mod_add_div a n, ←mod_add_div b n, right_distrib, left_distrib, left_distrib,
mul_assoc, mul_assoc, ←left_distrib n _ _, add_mul_mod_self_left,
mul_comm _ (n * (b / n)), mul_assoc, add_mul_mod_self_left] }
end
local attribute [simp] -- Will be generalized to Euclidean domains.
theorem mod_self {a : ℤ} : a % a = 0 :=
by have := mul_mod_left 1 a; rwa one_mul at this
@[simp] theorem mod_mod_of_dvd (n : int) {m k : int} (h : m ∣ k) : n % k % m = n % m :=
begin
conv { to_rhs, rw ←mod_add_div n k },
rcases h with ⟨t, rfl⟩, rw [mul_assoc, add_mul_mod_self_left]
end
@[simp] theorem mod_mod (a b : ℤ) : a % b % b = a % b :=
by conv {to_rhs, rw [← mod_add_div a b, add_mul_mod_self_left]}
/- properties of / and % -/
@[simp] theorem mul_div_mul_of_pos {a : ℤ} (b c : ℤ) (H : 0 < a) : a * b / (a * c) = b / c :=
suffices ∀ (m k : ℕ) (b : ℤ), (m.succ * b / (m.succ * k) : ℤ) = b / k, from
match a, eq_succ_of_zero_lt H, c, eq_coe_or_neg c with
| ._, ⟨m, rfl⟩, ._, ⟨k, or.inl rfl⟩ := this _ _ _
| ._, ⟨m, rfl⟩, ._, ⟨k, or.inr rfl⟩ :=
by rw [← neg_mul_eq_mul_neg, int.div_neg, int.div_neg];
apply congr_arg has_neg.neg; apply this
end,
λ m k b, match b, k with
| (n : ℕ), k := congr_arg of_nat (nat.mul_div_mul _ _ m.succ_pos)
| -[1+ n], 0 := by rw [int.coe_nat_zero, mul_zero, int.div_zero, int.div_zero]
| -[1+ n], k+1 := congr_arg neg_succ_of_nat $
show (m.succ * n + m) / (m.succ * k.succ) = n / k.succ, begin
apply nat.div_eq_of_lt_le,
{ refine le_trans _ (nat.le_add_right _ _),
rw [← nat.mul_div_mul _ _ m.succ_pos],
apply nat.div_mul_le_self },
{ change m.succ * n.succ ≤ _,
rw [mul_left_comm],
apply nat.mul_le_mul_left,
apply (nat.div_lt_iff_lt_mul _ _ k.succ_pos).1,
apply nat.lt_succ_self }
end
end
@[simp] theorem mul_div_mul_of_pos_left (a : ℤ) {b : ℤ} (c : ℤ) (H : 0 < b) :
a * b / (c * b) = a / c :=
by rw [mul_comm, mul_comm c, mul_div_mul_of_pos _ _ H]
@[simp] theorem mul_mod_mul_of_pos {a : ℤ} (b c : ℤ) (H : 0 < a) : a * b % (a * c) = a * (b % c) :=
by rw [mod_def, mod_def, mul_div_mul_of_pos _ _ H, mul_sub_left_distrib, mul_assoc]
theorem lt_div_add_one_mul_self (a : ℤ) {b : ℤ} (H : 0 < b) : a < (a / b + 1) * b :=
by rw [add_mul, one_mul, mul_comm]; apply lt_add_of_sub_left_lt;
rw [← mod_def]; apply mod_lt_of_pos _ H
theorem abs_div_le_abs : ∀ (a b : ℤ), abs (a / b) ≤ abs a :=
suffices ∀ (a : ℤ) (n : ℕ), abs (a / n) ≤ abs a, from
λ a b, match b, eq_coe_or_neg b with
| ._, ⟨n, or.inl rfl⟩ := this _ _
| ._, ⟨n, or.inr rfl⟩ := by rw [int.div_neg, abs_neg]; apply this
end,
λ a n, by rw [abs_eq_nat_abs, abs_eq_nat_abs]; exact
coe_nat_le_coe_nat_of_le (match a, n with
| (m : ℕ), n := nat.div_le_self _ _
| -[1+ m], 0 := nat.zero_le _
| -[1+ m], n+1 := nat.succ_le_succ (nat.div_le_self _ _)
end)
theorem div_le_self {a : ℤ} (b : ℤ) (Ha : 0 ≤ a) : a / b ≤ a :=
by have := le_trans (le_abs_self _) (abs_div_le_abs a b);
rwa [abs_of_nonneg Ha] at this
theorem mul_div_cancel_of_mod_eq_zero {a b : ℤ} (H : a % b = 0) : b * (a / b) = a :=
by have := mod_add_div a b; rwa [H, zero_add] at this
theorem div_mul_cancel_of_mod_eq_zero {a b : ℤ} (H : a % b = 0) : a / b * b = a :=
by rw [mul_comm, mul_div_cancel_of_mod_eq_zero H]
lemma mod_two_eq_zero_or_one (n : ℤ) : n % 2 = 0 ∨ n % 2 = 1 :=
have h : n % 2 < 2 := abs_of_nonneg (show 0 ≤ (2 : ℤ), from dec_trivial) ▸ int.mod_lt _ dec_trivial,
have h₁ : 0 ≤ n % 2 := int.mod_nonneg _ dec_trivial,
match (n % 2), h, h₁ with
| (0 : ℕ) := λ _ _, or.inl rfl
| (1 : ℕ) := λ _ _, or.inr rfl
| (k + 2 : ℕ) := λ h _, absurd h dec_trivial
| -[1+ a] := λ _ h₁, absurd h₁ dec_trivial
end
/- dvd -/
@[norm_cast] theorem coe_nat_dvd {m n : ℕ} : (↑m : ℤ) ∣ ↑n ↔ m ∣ n :=
⟨λ ⟨a, ae⟩, m.eq_zero_or_pos.elim
(λm0, by simp [m0] at ae; simp [ae, m0])
(λm0l, by {
cases eq_coe_of_zero_le (@nonneg_of_mul_nonneg_left ℤ _ m a
(by simp [ae.symm]) (by simpa using m0l)) with k e,
subst a, exact ⟨k, int.coe_nat_inj ae⟩ }),
λ ⟨k, e⟩, dvd.intro k $ by rw [e, int.coe_nat_mul]⟩
theorem coe_nat_dvd_left {n : ℕ} {z : ℤ} : (↑n : ℤ) ∣ z ↔ n ∣ z.nat_abs :=
by rcases nat_abs_eq z with eq | eq; rw eq; simp [coe_nat_dvd]
theorem coe_nat_dvd_right {n : ℕ} {z : ℤ} : z ∣ (↑n : ℤ) ↔ z.nat_abs ∣ n :=
by rcases nat_abs_eq z with eq | eq; rw eq; simp [coe_nat_dvd]
theorem dvd_antisymm {a b : ℤ} (H1 : 0 ≤ a) (H2 : 0 ≤ b) : a ∣ b → b ∣ a → a = b :=
begin
rw [← abs_of_nonneg H1, ← abs_of_nonneg H2, abs_eq_nat_abs, abs_eq_nat_abs],
rw [coe_nat_dvd, coe_nat_dvd, coe_nat_inj'],
apply nat.dvd_antisymm
end
theorem dvd_of_mod_eq_zero {a b : ℤ} (H : b % a = 0) : a ∣ b :=
⟨b / a, (mul_div_cancel_of_mod_eq_zero H).symm⟩
theorem mod_eq_zero_of_dvd : ∀ {a b : ℤ}, a ∣ b → b % a = 0
| a ._ ⟨c, rfl⟩ := mul_mod_right _ _
theorem dvd_iff_mod_eq_zero (a b : ℤ) : a ∣ b ↔ b % a = 0 :=
⟨mod_eq_zero_of_dvd, dvd_of_mod_eq_zero⟩
/-- If `a % b = c` then `b` divides `a - c`. -/
lemma dvd_sub_of_mod_eq {a b c : ℤ} (h : a % b = c) : b ∣ a - c :=
begin
have hx : a % b % b = c % b, { rw h },
rw [mod_mod, ←mod_sub_cancel_right c, sub_self, zero_mod] at hx,
exact dvd_of_mod_eq_zero hx
end
theorem nat_abs_dvd {a b : ℤ} : (a.nat_abs : ℤ) ∣ b ↔ a ∣ b :=
(nat_abs_eq a).elim (λ e, by rw ← e) (λ e, by rw [← neg_dvd_iff_dvd, ← e])
theorem dvd_nat_abs {a b : ℤ} : a ∣ b.nat_abs ↔ a ∣ b :=
(nat_abs_eq b).elim (λ e, by rw ← e) (λ e, by rw [← dvd_neg_iff_dvd, ← e])
instance decidable_dvd : @decidable_rel ℤ (∣) :=
assume a n, decidable_of_decidable_of_iff (by apply_instance) (dvd_iff_mod_eq_zero _ _).symm
protected theorem div_mul_cancel {a b : ℤ} (H : b ∣ a) : a / b * b = a :=
div_mul_cancel_of_mod_eq_zero (mod_eq_zero_of_dvd H)
protected theorem mul_div_cancel' {a b : ℤ} (H : a ∣ b) : a * (b / a) = b :=
by rw [mul_comm, int.div_mul_cancel H]
protected theorem mul_div_assoc (a : ℤ) : ∀ {b c : ℤ}, c ∣ b → (a * b) / c = a * (b / c)
| ._ c ⟨d, rfl⟩ := if cz : c = 0 then by simp [cz] else
by rw [mul_left_comm, int.mul_div_cancel_left _ cz, int.mul_div_cancel_left _ cz]
theorem div_dvd_div : ∀ {a b c : ℤ} (H1 : a ∣ b) (H2 : b ∣ c), b / a ∣ c / a
| a ._ ._ ⟨b, rfl⟩ ⟨c, rfl⟩ := if az : a = 0 then by simp [az] else
by rw [int.mul_div_cancel_left _ az, mul_assoc, int.mul_div_cancel_left _ az];
apply dvd_mul_right
protected theorem eq_mul_of_div_eq_right {a b c : ℤ} (H1 : b ∣ a) (H2 : a / b = c) :
a = b * c :=
by rw [← H2, int.mul_div_cancel' H1]
protected theorem div_eq_of_eq_mul_right {a b c : ℤ} (H1 : b ≠ 0) (H2 : a = b * c) :
a / b = c :=
by rw [H2, int.mul_div_cancel_left _ H1]
protected theorem div_eq_iff_eq_mul_right {a b c : ℤ} (H : b ≠ 0) (H' : b ∣ a) :
a / b = c ↔ a = b * c :=
⟨int.eq_mul_of_div_eq_right H', int.div_eq_of_eq_mul_right H⟩
protected theorem div_eq_iff_eq_mul_left {a b c : ℤ} (H : b ≠ 0) (H' : b ∣ a) :
a / b = c ↔ a = c * b :=
by rw mul_comm; exact int.div_eq_iff_eq_mul_right H H'
protected theorem eq_mul_of_div_eq_left {a b c : ℤ} (H1 : b ∣ a) (H2 : a / b = c) :
a = c * b :=
by rw [mul_comm, int.eq_mul_of_div_eq_right H1 H2]
protected theorem div_eq_of_eq_mul_left {a b c : ℤ} (H1 : b ≠ 0) (H2 : a = c * b) :
a / b = c :=
int.div_eq_of_eq_mul_right H1 (by rw [mul_comm, H2])
theorem neg_div_of_dvd : ∀ {a b : ℤ} (H : b ∣ a), -a / b = -(a / b)
| ._ b ⟨c, rfl⟩ := if bz : b = 0 then by simp [bz] else
by rw [neg_mul_eq_mul_neg, int.mul_div_cancel_left _ bz, int.mul_div_cancel_left _ bz]
lemma add_div_of_dvd {a b c : ℤ} :
c ∣ a → c ∣ b → (a + b) / c = a / c + b / c :=
begin
intros h1 h2,
by_cases h3 : c = 0,
{ rw [h3, zero_dvd_iff] at *,
rw [h1, h2, h3], refl },
{ apply eq_of_mul_eq_mul_right h3,
rw add_mul, repeat {rw [int.div_mul_cancel]};
try {apply dvd_add}; assumption }
end
theorem div_sign : ∀ a b, a / sign b = a * sign b
| a (n+1:ℕ) := by unfold sign; simp
| a 0 := by simp [sign]
| a -[1+ n] := by simp [sign]
@[simp] theorem sign_mul : ∀ a b, sign (a * b) = sign a * sign b
| a 0 := by simp
| 0 b := by simp
| (m+1:ℕ) (n+1:ℕ) := rfl
| (m+1:ℕ) -[1+ n] := rfl
| -[1+ m] (n+1:ℕ) := rfl
| -[1+ m] -[1+ n] := rfl
protected theorem sign_eq_div_abs (a : ℤ) : sign a = a / (abs a) :=
if az : a = 0 then by simp [az] else
(int.div_eq_of_eq_mul_left (mt eq_zero_of_abs_eq_zero az)
(sign_mul_abs _).symm).symm
theorem mul_sign : ∀ (i : ℤ), i * sign i = nat_abs i
| (n+1:ℕ) := mul_one _
| 0 := mul_zero _
| -[1+ n] := mul_neg_one _
theorem le_of_dvd {a b : ℤ} (bpos : 0 < b) (H : a ∣ b) : a ≤ b :=
match a, b, eq_succ_of_zero_lt bpos, H with
| (m : ℕ), ._, ⟨n, rfl⟩, H := coe_nat_le_coe_nat_of_le $
nat.le_of_dvd n.succ_pos $ coe_nat_dvd.1 H
| -[1+ m], ._, ⟨n, rfl⟩, _ :=
le_trans (le_of_lt $ neg_succ_lt_zero _) (coe_zero_le _)
end
theorem eq_one_of_dvd_one {a : ℤ} (H : 0 ≤ a) (H' : a ∣ 1) : a = 1 :=
match a, eq_coe_of_zero_le H, H' with
| ._, ⟨n, rfl⟩, H' := congr_arg coe $
nat.eq_one_of_dvd_one $ coe_nat_dvd.1 H'
end
theorem eq_one_of_mul_eq_one_right {a b : ℤ} (H : 0 ≤ a) (H' : a * b = 1) : a = 1 :=
eq_one_of_dvd_one H ⟨b, H'.symm⟩
theorem eq_one_of_mul_eq_one_left {a b : ℤ} (H : 0 ≤ b) (H' : a * b = 1) : b = 1 :=
eq_one_of_mul_eq_one_right H (by rw [mul_comm, H'])
lemma of_nat_dvd_of_dvd_nat_abs {a : ℕ} : ∀ {z : ℤ} (haz : a ∣ z.nat_abs), ↑a ∣ z
| (int.of_nat _) haz := int.coe_nat_dvd.2 haz
| -[1+k] haz :=
begin
change ↑a ∣ -(k+1 : ℤ),
apply dvd_neg_of_dvd,
apply int.coe_nat_dvd.2,
exact haz
end
lemma dvd_nat_abs_of_of_nat_dvd {a : ℕ} : ∀ {z : ℤ} (haz : ↑a ∣ z), a ∣ z.nat_abs
| (int.of_nat _) haz := int.coe_nat_dvd.1 (int.dvd_nat_abs.2 haz)
| -[1+k] haz :=
have haz' : (↑a:ℤ) ∣ (↑(k+1):ℤ), from dvd_of_dvd_neg haz,
int.coe_nat_dvd.1 haz'
lemma pow_dvd_of_le_of_pow_dvd {p m n : ℕ} {k : ℤ} (hmn : m ≤ n) (hdiv : ↑(p ^ n) ∣ k) :
↑(p ^ m) ∣ k :=
begin
induction k,
{ apply int.coe_nat_dvd.2,
apply pow_dvd_of_le_of_pow_dvd hmn,
apply int.coe_nat_dvd.1 hdiv },
{ change -[1+k] with -(↑(k+1) : ℤ),
apply dvd_neg_of_dvd,
apply int.coe_nat_dvd.2,
apply pow_dvd_of_le_of_pow_dvd hmn,
apply int.coe_nat_dvd.1,
apply dvd_of_dvd_neg,
exact hdiv }
end
lemma dvd_of_pow_dvd {p k : ℕ} {m : ℤ} (hk : 1 ≤ k) (hpk : ↑(p^k) ∣ m) : ↑p ∣ m :=
by rw ←nat.pow_one p; exact pow_dvd_of_le_of_pow_dvd hk hpk
/- / and ordering -/
protected theorem div_mul_le (a : ℤ) {b : ℤ} (H : b ≠ 0) : a / b * b ≤ a :=
le_of_sub_nonneg $ by rw [mul_comm, ← mod_def]; apply mod_nonneg _ H
protected theorem div_le_of_le_mul {a b c : ℤ} (H : 0 < c) (H' : a ≤ b * c) : a / c ≤ b :=
le_of_mul_le_mul_right (le_trans (int.div_mul_le _ (ne_of_gt H)) H') H
protected theorem mul_lt_of_lt_div {a b c : ℤ} (H : 0 < c) (H3 : a < b / c) : a * c < b :=
lt_of_not_ge $ mt (int.div_le_of_le_mul H) (not_le_of_gt H3)
protected theorem mul_le_of_le_div {a b c : ℤ} (H1 : 0 < c) (H2 : a ≤ b / c) : a * c ≤ b :=
le_trans (mul_le_mul_of_nonneg_right H2 (le_of_lt H1)) (int.div_mul_le _ (ne_of_gt H1))
protected theorem le_div_of_mul_le {a b c : ℤ} (H1 : 0 < c) (H2 : a * c ≤ b) : a ≤ b / c :=
le_of_lt_add_one $ lt_of_mul_lt_mul_right
(lt_of_le_of_lt H2 (lt_div_add_one_mul_self _ H1)) (le_of_lt H1)
protected theorem le_div_iff_mul_le {a b c : ℤ} (H : 0 < c) : a ≤ b / c ↔ a * c ≤ b :=
⟨int.mul_le_of_le_div H, int.le_div_of_mul_le H⟩
protected theorem div_le_div {a b c : ℤ} (H : 0 < c) (H' : a ≤ b) : a / c ≤ b / c :=
int.le_div_of_mul_le H (le_trans (int.div_mul_le _ (ne_of_gt H)) H')
protected theorem div_lt_of_lt_mul {a b c : ℤ} (H : 0 < c) (H' : a < b * c) : a / c < b :=
lt_of_not_ge $ mt (int.mul_le_of_le_div H) (not_le_of_gt H')
protected theorem lt_mul_of_div_lt {a b c : ℤ} (H1 : 0 < c) (H2 : a / c < b) : a < b * c :=
lt_of_not_ge $ mt (int.le_div_of_mul_le H1) (not_le_of_gt H2)
protected theorem div_lt_iff_lt_mul {a b c : ℤ} (H : 0 < c) : a / c < b ↔ a < b * c :=
⟨int.lt_mul_of_div_lt H, int.div_lt_of_lt_mul H⟩
protected theorem le_mul_of_div_le {a b c : ℤ} (H1 : 0 ≤ b) (H2 : b ∣ a) (H3 : a / b ≤ c) :
a ≤ c * b :=
by rw [← int.div_mul_cancel H2]; exact mul_le_mul_of_nonneg_right H3 H1
protected theorem lt_div_of_mul_lt {a b c : ℤ} (H1 : 0 ≤ b) (H2 : b ∣ c) (H3 : a * b < c) :
a < c / b :=
lt_of_not_ge $ mt (int.le_mul_of_div_le H1 H2) (not_le_of_gt H3)
protected theorem lt_div_iff_mul_lt {a b : ℤ} (c : ℤ) (H : 0 < c) (H' : c ∣ b) :
a < b / c ↔ a * c < b :=
⟨int.mul_lt_of_lt_div H, int.lt_div_of_mul_lt (le_of_lt H) H'⟩
theorem div_pos_of_pos_of_dvd {a b : ℤ} (H1 : 0 < a) (H2 : 0 ≤ b) (H3 : b ∣ a) : 0 < a / b :=
int.lt_div_of_mul_lt H2 H3 (by rwa zero_mul)
theorem div_eq_div_of_mul_eq_mul {a b c d : ℤ} (H2 : d ∣ c) (H3 : b ≠ 0)
(H4 : d ≠ 0) (H5 : a * d = b * c) :
a / b = c / d :=
int.div_eq_of_eq_mul_right H3 $
by rw [← int.mul_div_assoc _ H2]; exact
(int.div_eq_of_eq_mul_left H4 H5.symm).symm
theorem eq_mul_div_of_mul_eq_mul_of_dvd_left {a b c d : ℤ} (hb : b ≠ 0) (hbc : b ∣ c)
(h : b * a = c * d) : a = c / b * d :=
begin
cases hbc with k hk,
subst hk,
rw int.mul_div_cancel_left, rw mul_assoc at h,
apply _root_.eq_of_mul_eq_mul_left _ h,
repeat {assumption}
end
/-- If an integer with larger absolute value divides an integer, it is
zero. -/
lemma eq_zero_of_dvd_of_nat_abs_lt_nat_abs {a b : ℤ} (w : a ∣ b) (h : nat_abs b < nat_abs a) :
b = 0 :=
begin
rw [←nat_abs_dvd, ←dvd_nat_abs, coe_nat_dvd] at w,
rw ←nat_abs_eq_zero,
exact eq_zero_of_dvd_of_lt w h
end
lemma eq_zero_of_dvd_of_nonneg_of_lt {a b : ℤ} (w₁ : 0 ≤ a) (w₂ : a < b) (h : b ∣ a) : a = 0 :=
eq_zero_of_dvd_of_nat_abs_lt_nat_abs h (nat_abs_lt_nat_abs_of_nonneg_of_lt w₁ w₂)
/-- If two integers are congruent to a sufficiently large modulus,
they are equal. -/
lemma eq_of_mod_eq_of_nat_abs_sub_lt_nat_abs {a b c : ℤ} (h1 : a % b = c)
(h2 : nat_abs (a - c) < nat_abs b) :
a = c :=
eq_of_sub_eq_zero (eq_zero_of_dvd_of_nat_abs_lt_nat_abs (dvd_sub_of_mod_eq h1) h2)
theorem of_nat_add_neg_succ_of_nat_of_lt {m n : ℕ}
(h : m < n.succ) : of_nat m + -[1+n] = -[1+ n - m] :=
begin
change sub_nat_nat _ _ = _,
have h' : n.succ - m = (n - m).succ,
apply succ_sub,
apply le_of_lt_succ h,
simp [*, sub_nat_nat]
end
theorem of_nat_add_neg_succ_of_nat_of_ge {m n : ℕ}
(h : n.succ ≤ m) : of_nat m + -[1+n] = of_nat (m - n.succ) :=
begin
change sub_nat_nat _ _ = _,
have h' : n.succ - m = 0,
apply sub_eq_zero_of_le h,
simp [*, sub_nat_nat]
end
@[simp] theorem neg_add_neg (m n : ℕ) : -[1+m] + -[1+n] = -[1+nat.succ(m+n)] := rfl
/- to_nat -/
theorem to_nat_eq_max : ∀ (a : ℤ), (to_nat a : ℤ) = max a 0
| (n : ℕ) := (max_eq_left (coe_zero_le n)).symm
| -[1+ n] := (max_eq_right (le_of_lt (neg_succ_lt_zero n))).symm
@[simp] theorem to_nat_of_nonneg {a : ℤ} (h : 0 ≤ a) : (to_nat a : ℤ) = a :=
by rw [to_nat_eq_max, max_eq_left h]
@[simp] lemma to_nat_sub_of_le (a b : ℤ) (h : b ≤ a) : (to_nat (a + -b) : ℤ) = a + - b :=
int.to_nat_of_nonneg (sub_nonneg_of_le h)
@[simp] theorem to_nat_coe_nat (n : ℕ) : to_nat ↑n = n := rfl
theorem le_to_nat (a : ℤ) : a ≤ to_nat a :=
by rw [to_nat_eq_max]; apply le_max_left
@[simp] theorem to_nat_le {a : ℤ} {n : ℕ} : to_nat a ≤ n ↔ a ≤ n :=
by rw [(coe_nat_le_coe_nat_iff _ _).symm, to_nat_eq_max, max_le_iff];
exact and_iff_left (coe_zero_le _)
@[simp] theorem lt_to_nat {n : ℕ} {a : ℤ} : n < to_nat a ↔ (n : ℤ) < a :=
le_iff_le_iff_lt_iff_lt.1 to_nat_le
theorem to_nat_le_to_nat {a b : ℤ} (h : a ≤ b) : to_nat a ≤ to_nat b :=
by rw to_nat_le; exact le_trans h (le_to_nat b)
theorem to_nat_lt_to_nat {a b : ℤ} (hb : 0 < b) : to_nat a < to_nat b ↔ a < b :=
⟨λ h, begin cases a, exact lt_to_nat.1 h, exact lt_trans (neg_succ_of_nat_lt_zero a) hb, end,
λ h, begin rw lt_to_nat, cases a, exact h, exact hb end⟩
theorem lt_of_to_nat_lt {a b : ℤ} (h : to_nat a < to_nat b) : a < b :=
(to_nat_lt_to_nat $ lt_to_nat.1 $ lt_of_le_of_lt (nat.zero_le _) h).1 h
def to_nat' : ℤ → option ℕ
| (n : ℕ) := some n
| -[1+ n] := none
theorem mem_to_nat' : ∀ (a : ℤ) (n : ℕ), n ∈ to_nat' a ↔ a = n
| (m : ℕ) n := option.some_inj.trans coe_nat_inj'.symm
| -[1+ m] n := by split; intro h; cases h
/- units -/
@[simp] theorem units_nat_abs (u : units ℤ) : nat_abs u = 1 :=
units.ext_iff.1 $ nat.units_eq_one ⟨nat_abs u, nat_abs ↑u⁻¹,
by rw [← nat_abs_mul, units.mul_inv]; refl,
by rw [← nat_abs_mul, units.inv_mul]; refl⟩
theorem units_eq_one_or (u : units ℤ) : u = 1 ∨ u = -1 :=
by simpa [units.ext_iff, units_nat_abs] using nat_abs_eq u
lemma units_inv_eq_self (u : units ℤ) : u⁻¹ = u :=
(units_eq_one_or u).elim (λ h, h.symm ▸ rfl) (λ h, h.symm ▸ rfl)
/- bitwise ops -/
@[simp] lemma bodd_zero : bodd 0 = ff := rfl
@[simp] lemma bodd_one : bodd 1 = tt := rfl
@[simp] lemma bodd_two : bodd 2 = ff := rfl
@[simp, norm_cast] lemma bodd_coe (n : ℕ) : int.bodd n = nat.bodd n := rfl
@[simp] lemma bodd_sub_nat_nat (m n : ℕ) : bodd (sub_nat_nat m n) = bxor m.bodd n.bodd :=
by apply sub_nat_nat_elim m n (λ m n i, bodd i = bxor m.bodd n.bodd); intros;
simp; cases i.bodd; simp
@[simp] lemma bodd_neg_of_nat (n : ℕ) : bodd (neg_of_nat n) = n.bodd :=
by cases n; simp; refl
@[simp] lemma bodd_neg (n : ℤ) : bodd (-n) = bodd n :=
by cases n; simp [has_neg.neg, int.coe_nat_eq, int.neg, bodd, -of_nat_eq_coe]
@[simp] lemma bodd_add (m n : ℤ) : bodd (m + n) = bxor (bodd m) (bodd n) :=
by cases m with m m; cases n with n n; unfold has_add.add;
simp [int.add, -of_nat_eq_coe, bool.bxor_comm]
@[simp] lemma bodd_mul (m n : ℤ) : bodd (m * n) = bodd m && bodd n :=
by cases m with m m; cases n with n n; unfold has_mul.mul;
simp [int.mul, -of_nat_eq_coe, bool.bxor_comm]
theorem bodd_add_div2 : ∀ n, cond (bodd n) 1 0 + 2 * div2 n = n
| (n : ℕ) :=
by rw [show (cond (bodd n) 1 0 : ℤ) = (cond (bodd n) 1 0 : ℕ),
by cases bodd n; refl]; exact congr_arg of_nat n.bodd_add_div2
| -[1+ n] := begin
refine eq.trans _ (congr_arg neg_succ_of_nat n.bodd_add_div2),
dsimp [bodd], cases nat.bodd n; dsimp [cond, bnot, div2, int.mul],
{ change -[1+ 2 * nat.div2 n] = _, rw zero_add },
{ rw [zero_add, add_comm], refl }
end
theorem div2_val : ∀ n, div2 n = n / 2
| (n : ℕ) := congr_arg of_nat n.div2_val
| -[1+ n] := congr_arg neg_succ_of_nat n.div2_val
lemma bit0_val (n : ℤ) : bit0 n = 2 * n := (two_mul _).symm
lemma bit1_val (n : ℤ) : bit1 n = 2 * n + 1 := congr_arg (+(1:ℤ)) (bit0_val _)
lemma bit_val (b n) : bit b n = 2 * n + cond b 1 0 :=
by { cases b, apply (bit0_val n).trans (add_zero _).symm, apply bit1_val }
lemma bit_decomp (n : ℤ) : bit (bodd n) (div2 n) = n :=
(bit_val _ _).trans $ (add_comm _ _).trans $ bodd_add_div2 _
def {u} bit_cases_on {C : ℤ → Sort u} (n) (h : ∀ b n, C (bit b n)) : C n :=
by rw [← bit_decomp n]; apply h
@[simp] lemma bit_zero : bit ff 0 = 0 := rfl
@[simp] lemma bit_coe_nat (b) (n : ℕ) : bit b n = nat.bit b n :=
by rw [bit_val, nat.bit_val]; cases b; refl
@[simp] lemma bit_neg_succ (b) (n : ℕ) : bit b -[1+ n] = -[1+ nat.bit (bnot b) n] :=
by rw [bit_val, nat.bit_val]; cases b; refl
@[simp] lemma bodd_bit (b n) : bodd (bit b n) = b :=
by rw bit_val; simp; cases b; cases bodd n; refl
@[simp] lemma div2_bit (b n) : div2 (bit b n) = n :=
begin
rw [bit_val, div2_val, add_comm, int.add_mul_div_left, (_ : (_/2:ℤ) = 0), zero_add],
cases b, all_goals {exact dec_trivial}
end
@[simp] lemma test_bit_zero (b) : ∀ n, test_bit (bit b n) 0 = b
| (n : ℕ) := by rw [bit_coe_nat]; apply nat.test_bit_zero
| -[1+ n] := by rw [bit_neg_succ]; dsimp [test_bit]; rw [nat.test_bit_zero];
clear test_bit_zero; cases b; refl
@[simp] lemma test_bit_succ (m b) : ∀ n, test_bit (bit b n) (nat.succ m) = test_bit n m
| (n : ℕ) := by rw [bit_coe_nat]; apply nat.test_bit_succ
| -[1+ n] := by rw [bit_neg_succ]; dsimp [test_bit]; rw [nat.test_bit_succ]
private meta def bitwise_tac : tactic unit := `[
funext m,
funext n,
cases m with m m; cases n with n n; try {refl},
all_goals {
apply congr_arg of_nat <|> apply congr_arg neg_succ_of_nat,
try {dsimp [nat.land, nat.ldiff, nat.lor]},
try {rw [
show nat.bitwise (λ a b, a && bnot b) n m =
nat.bitwise (λ a b, b && bnot a) m n, from
congr_fun (congr_fun (@nat.bitwise_swap (λ a b, b && bnot a) rfl) n) m]},
apply congr_arg (λ f, nat.bitwise f m n),
funext a,
funext b,
cases a; cases b; refl
},
all_goals {unfold nat.land nat.ldiff nat.lor}
]
theorem bitwise_or : bitwise bor = lor := by bitwise_tac
theorem bitwise_and : bitwise band = land := by bitwise_tac
theorem bitwise_diff : bitwise (λ a b, a && bnot b) = ldiff := by bitwise_tac
theorem bitwise_xor : bitwise bxor = lxor := by bitwise_tac
@[simp] lemma bitwise_bit (f : bool → bool → bool) (a m b n) :
bitwise f (bit a m) (bit b n) = bit (f a b) (bitwise f m n) :=
begin
cases m with m m; cases n with n n;
repeat { rw [← int.coe_nat_eq] <|> rw bit_coe_nat <|> rw bit_neg_succ };
unfold bitwise nat_bitwise bnot;
[ induction h : f ff ff,
induction h : f ff tt,
induction h : f tt ff,
induction h : f tt tt ],
all_goals {
unfold cond, rw nat.bitwise_bit,
repeat { rw bit_coe_nat <|> rw bit_neg_succ <|> rw bnot_bnot } },
all_goals { unfold bnot {fail_if_unchanged := ff}; rw h; refl }
end
@[simp] lemma lor_bit (a m b n) : lor (bit a m) (bit b n) = bit (a || b) (lor m n) :=
by rw [← bitwise_or, bitwise_bit]
@[simp] lemma land_bit (a m b n) : land (bit a m) (bit b n) = bit (a && b) (land m n) :=
by rw [← bitwise_and, bitwise_bit]
@[simp] lemma ldiff_bit (a m b n) : ldiff (bit a m) (bit b n) = bit (a && bnot b) (ldiff m n) :=
by rw [← bitwise_diff, bitwise_bit]
@[simp] lemma lxor_bit (a m b n) : lxor (bit a m) (bit b n) = bit (bxor a b) (lxor m n) :=
by rw [← bitwise_xor, bitwise_bit]
@[simp] lemma lnot_bit (b) : ∀ n, lnot (bit b n) = bit (bnot b) (lnot n)
| (n : ℕ) := by simp [lnot]
| -[1+ n] := by simp [lnot]
@[simp] lemma test_bit_bitwise (f : bool → bool → bool) (m n k) :
test_bit (bitwise f m n) k = f (test_bit m k) (test_bit n k) :=
begin
induction k with k IH generalizing m n;
apply bit_cases_on m; intros a m';
apply bit_cases_on n; intros b n';
rw bitwise_bit,
{ simp [test_bit_zero] },
{ simp [test_bit_succ, IH] }
end
@[simp] lemma test_bit_lor (m n k) : test_bit (lor m n) k = test_bit m k || test_bit n k :=
by rw [← bitwise_or, test_bit_bitwise]
@[simp] lemma test_bit_land (m n k) : test_bit (land m n) k = test_bit m k && test_bit n k :=
by rw [← bitwise_and, test_bit_bitwise]
@[simp]
lemma test_bit_ldiff (m n k) : test_bit (ldiff m n) k = test_bit m k && bnot (test_bit n k) :=
by rw [← bitwise_diff, test_bit_bitwise]
@[simp] lemma test_bit_lxor (m n k) : test_bit (lxor m n) k = bxor (test_bit m k) (test_bit n k) :=
by rw [← bitwise_xor, test_bit_bitwise]
@[simp] lemma test_bit_lnot : ∀ n k, test_bit (lnot n) k = bnot (test_bit n k)
| (n : ℕ) k := by simp [lnot, test_bit]
| -[1+ n] k := by simp [lnot, test_bit]
lemma shiftl_add : ∀ (m : ℤ) (n : ℕ) (k : ℤ), shiftl m (n + k) = shiftl (shiftl m n) k
| (m : ℕ) n (k:ℕ) := congr_arg of_nat (nat.shiftl_add _ _ _)
| -[1+ m] n (k:ℕ) := congr_arg neg_succ_of_nat (nat.shiftl'_add _ _ _ _)
| (m : ℕ) n -[1+k] := sub_nat_nat_elim n k.succ
(λ n k i, shiftl ↑m i = nat.shiftr (nat.shiftl m n) k)
(λ i n, congr_arg coe $
by rw [← nat.shiftl_sub, nat.add_sub_cancel_left]; apply nat.le_add_right)
(λ i n, congr_arg coe $
by rw [add_assoc, nat.shiftr_add, ← nat.shiftl_sub, nat.sub_self]; refl)
| -[1+ m] n -[1+k] := sub_nat_nat_elim n k.succ
(λ n k i, shiftl -[1+ m] i = -[1+ nat.shiftr (nat.shiftl' tt m n) k])
(λ i n, congr_arg neg_succ_of_nat $
by rw [← nat.shiftl'_sub, nat.add_sub_cancel_left]; apply nat.le_add_right)
(λ i n, congr_arg neg_succ_of_nat $
by rw [add_assoc, nat.shiftr_add, ← nat.shiftl'_sub, nat.sub_self]; refl)
lemma shiftl_sub (m : ℤ) (n : ℕ) (k : ℤ) : shiftl m (n - k) = shiftr (shiftl m n) k :=
shiftl_add _ _ _
@[simp] lemma shiftl_neg (m n : ℤ) : shiftl m (-n) = shiftr m n := rfl
@[simp] lemma shiftr_neg (m n : ℤ) : shiftr m (-n) = shiftl m n := by rw [← shiftl_neg, neg_neg]
@[simp] lemma shiftl_coe_nat (m n : ℕ) : shiftl m n = nat.shiftl m n := rfl
@[simp] lemma shiftr_coe_nat (m n : ℕ) : shiftr m n = nat.shiftr m n := by cases n; refl
@[simp] lemma shiftl_neg_succ (m n : ℕ) : shiftl -[1+ m] n = -[1+ nat.shiftl' tt m n] := rfl
@[simp]
lemma shiftr_neg_succ (m n : ℕ) : shiftr -[1+ m] n = -[1+ nat.shiftr m n] := by cases n; refl
lemma shiftr_add : ∀ (m : ℤ) (n k : ℕ), shiftr m (n + k) = shiftr (shiftr m n) k
| (m : ℕ) n k := by rw [shiftr_coe_nat, shiftr_coe_nat,
← int.coe_nat_add, shiftr_coe_nat, nat.shiftr_add]
| -[1+ m] n k := by rw [shiftr_neg_succ, shiftr_neg_succ,
← int.coe_nat_add, shiftr_neg_succ, nat.shiftr_add]
lemma shiftl_eq_mul_pow : ∀ (m : ℤ) (n : ℕ), shiftl m n = m * ↑(2 ^ n)
| (m : ℕ) n := congr_arg coe (nat.shiftl_eq_mul_pow _ _)
| -[1+ m] n := @congr_arg ℕ ℤ _ _ (λi, -i) (nat.shiftl'_tt_eq_mul_pow _ _)
lemma shiftr_eq_div_pow : ∀ (m : ℤ) (n : ℕ), shiftr m n = m / ↑(2 ^ n)
| (m : ℕ) n := by rw shiftr_coe_nat; exact congr_arg coe (nat.shiftr_eq_div_pow _ _)
| -[1+ m] n := begin
rw [shiftr_neg_succ, neg_succ_of_nat_div, nat.shiftr_eq_div_pow], refl,
exact coe_nat_lt_coe_nat_of_lt (nat.pos_pow_of_pos _ dec_trivial)
end
lemma one_shiftl (n : ℕ) : shiftl 1 n = (2 ^ n : ℕ) :=
congr_arg coe (nat.one_shiftl _)
@[simp] lemma zero_shiftl : ∀ n : ℤ, shiftl 0 n = 0
| (n : ℕ) := congr_arg coe (nat.zero_shiftl _)
| -[1+ n] := congr_arg coe (nat.zero_shiftr _)
@[simp] lemma zero_shiftr (n) : shiftr 0 n = 0 := zero_shiftl _
/- Least upper bound property for integers -/
section classical
open_locale classical
theorem exists_least_of_bdd {P : ℤ → Prop}
(Hbdd : ∃ b : ℤ, ∀ z : ℤ, P z → b ≤ z)
(Hinh : ∃ z : ℤ, P z) : ∃ lb : ℤ, P lb ∧ (∀ z : ℤ, P z → lb ≤ z) :=
let ⟨b, Hb⟩ := Hbdd in
have EX : ∃ n : ℕ, P (b + n), from
let ⟨elt, Helt⟩ := Hinh in
match elt, le.dest (Hb _ Helt), Helt with
| ._, ⟨n, rfl⟩, Hn := ⟨n, Hn⟩
end,
⟨b + (nat.find EX : ℤ), nat.find_spec EX, λ z h,
match z, le.dest (Hb _ h), h with
| ._, ⟨n, rfl⟩, h := add_le_add_left
(int.coe_nat_le.2 $ nat.find_min' _ h) _
end⟩
theorem exists_greatest_of_bdd {P : ℤ → Prop}
(Hbdd : ∃ b : ℤ, ∀ z : ℤ, P z → z ≤ b)
(Hinh : ∃ z : ℤ, P z) : ∃ ub : ℤ, P ub ∧ (∀ z : ℤ, P z → z ≤ ub) :=
have Hbdd' : ∃ (b : ℤ), ∀ (z : ℤ), P (-z) → b ≤ z, from
let ⟨b, Hb⟩ := Hbdd in ⟨-b, λ z h, neg_le.1 (Hb _ h)⟩,
have Hinh' : ∃ z : ℤ, P (-z), from
let ⟨elt, Helt⟩ := Hinh in ⟨-elt, by rw [neg_neg]; exact Helt⟩,
let ⟨lb, Plb, al⟩ := exists_least_of_bdd Hbdd' Hinh' in
⟨-lb, Plb, λ z h, le_neg.1 $ al _ $ by rwa neg_neg⟩
end classical
/- cast (injection into groups with one) -/
@[simp] theorem nat_cast_eq_coe_nat : ∀ n,
@coe ℕ ℤ (@coe_to_lift _ _ nat.cast_coe) n =
@coe ℕ ℤ (@coe_to_lift _ _ (@coe_base _ _ int.has_coe)) n
| 0 := rfl
| (n+1) := congr_arg (+(1:ℤ)) (nat_cast_eq_coe_nat n)
/-- Coercion `ℕ → ℤ` as a `ring_hom`. -/
def of_nat_hom : ℕ →+* ℤ := ⟨coe, rfl, int.of_nat_mul, rfl, int.of_nat_add⟩
section cast
variables {α : Type*}
section
variables [has_zero α] [has_one α] [has_add α] [has_neg α]
/-- Canonical homomorphism from the integers to any ring(-like) structure `α` -/
protected def cast : ℤ → α
| (n : ℕ) := n
| -[1+ n] := -(n+1)
-- see Note [coercion into rings]
@[priority 900] instance cast_coe : has_coe_t ℤ α := ⟨int.cast⟩
@[simp, norm_cast] theorem cast_zero : ((0 : ℤ) : α) = 0 := rfl
theorem cast_of_nat (n : ℕ) : (of_nat n : α) = n := rfl
@[simp, norm_cast] theorem cast_coe_nat (n : ℕ) : ((n : ℤ) : α) = n := rfl
theorem cast_coe_nat' (n : ℕ) :
(@coe ℕ ℤ (@coe_to_lift _ _ nat.cast_coe) n : α) = n :=
by simp
@[simp, norm_cast] theorem cast_neg_succ_of_nat (n : ℕ) : (-[1+ n] : α) = -(n + 1) := rfl
end
@[simp, norm_cast] theorem cast_one [add_monoid α] [has_one α] [has_neg α] :
((1 : ℤ) : α) = 1 := nat.cast_one
@[simp, norm_cast] theorem cast_sub_nat_nat [add_group α] [has_one α] (m n) :
((int.sub_nat_nat m n : ℤ) : α) = m - n :=
begin
unfold sub_nat_nat, cases e : n - m,
{ simp [sub_nat_nat, e, nat.le_of_sub_eq_zero e] },
{ rw [sub_nat_nat, cast_neg_succ_of_nat, ← nat.cast_succ, ← e,
nat.cast_sub $ _root_.le_of_lt $ nat.lt_of_sub_eq_succ e, neg_sub] },
end
@[simp, norm_cast] theorem cast_neg_of_nat [add_group α] [has_one α] :
∀ n, ((neg_of_nat n : ℤ) : α) = -n
| 0 := neg_zero.symm
| (n+1) := rfl
@[simp, norm_cast] theorem cast_add [add_group α] [has_one α] : ∀ m n, ((m + n : ℤ) : α) = m + n
| (m : ℕ) (n : ℕ) := nat.cast_add _ _
| (m : ℕ) -[1+ n] := cast_sub_nat_nat _ _
| -[1+ m] (n : ℕ) := (cast_sub_nat_nat _ _).trans $ sub_eq_of_eq_add $
show (n:α) = -(m+1) + n + (m+1),
by rw [add_assoc, ← cast_succ, ← nat.cast_add, add_comm,
nat.cast_add, cast_succ, neg_add_cancel_left]
| -[1+ m] -[1+ n] := show -((m + n + 1 + 1 : ℕ) : α) = -(m + 1) + -(n + 1),
begin
rw [← neg_add_rev, ← nat.cast_add_one, ← nat.cast_add_one, ← nat.cast_add],
apply congr_arg (λ x:ℕ, -(x:α)),
ac_refl
end
@[simp, norm_cast] theorem cast_neg [add_group α] [has_one α] : ∀ n, ((-n : ℤ) : α) = -n
| (n : ℕ) := cast_neg_of_nat _
| -[1+ n] := (neg_neg _).symm
@[simp, norm_cast] theorem cast_sub [add_group α] [has_one α] (m n) : ((m - n : ℤ) : α) = m - n :=
by simp [sub_eq_add_neg]
@[simp]
theorem cast_eq_zero [add_group α] [has_one α] [char_zero α] {n : ℤ} : (n : α) = 0 ↔ n = 0 :=
⟨λ h, begin cases n,
{ exact congr_arg coe (nat.cast_eq_zero.1 h) },
{ rw [cast_neg_succ_of_nat, neg_eq_zero, ← cast_succ, nat.cast_eq_zero] at h,
contradiction }
end, λ h, by rw [h, cast_zero]⟩
@[simp, norm_cast] theorem cast_inj [add_group α] [has_one α] [char_zero α] {m n : ℤ} :
(m : α) = n ↔ m = n :=
by rw [← sub_eq_zero, ← cast_sub, cast_eq_zero, sub_eq_zero]
theorem cast_injective [add_group α] [has_one α] [char_zero α] : function.injective (coe : ℤ → α)
| m n := cast_inj.1
theorem cast_ne_zero [add_group α] [has_one α] [char_zero α] {n : ℤ} : (n : α) ≠ 0 ↔ n ≠ 0 :=
not_congr cast_eq_zero
@[simp, norm_cast] theorem cast_mul [ring α] : ∀ m n, ((m * n : ℤ) : α) = m * n
| (m : ℕ) (n : ℕ) := nat.cast_mul _ _
| (m : ℕ) -[1+ n] := (cast_neg_of_nat _).trans $
show (-(m * (n + 1) : ℕ) : α) = m * -(n + 1),
by rw [nat.cast_mul, nat.cast_add_one, neg_mul_eq_mul_neg]
| -[1+ m] (n : ℕ) := (cast_neg_of_nat _).trans $
show (-((m + 1) * n : ℕ) : α) = -(m + 1) * n,
by rw [nat.cast_mul, nat.cast_add_one, neg_mul_eq_neg_mul]
| -[1+ m] -[1+ n] := show (((m + 1) * (n + 1) : ℕ) : α) = -(m + 1) * -(n + 1),
by rw [nat.cast_mul, nat.cast_add_one, nat.cast_add_one, neg_mul_neg]
/-- `coe : ℤ → α` as an `add_monoid_hom`. -/
def cast_add_hom (α : Type*) [add_group α] [has_one α] : ℤ →+ α := ⟨coe, cast_zero, cast_add⟩
@[simp] lemma coe_cast_add_hom [add_group α] [has_one α] : ⇑(cast_add_hom α) = coe := rfl
/-- `coe : ℤ → α` as a `ring_hom`. -/
def cast_ring_hom (α : Type*) [ring α] : ℤ →+* α := ⟨coe, cast_one, cast_mul, cast_zero, cast_add⟩
@[simp] lemma coe_cast_ring_hom [ring α] : ⇑(cast_ring_hom α) = coe := rfl
theorem mul_cast_comm [ring α] (a : α) (n : ℤ) : a * n = n * a :=
by cases n; simp [nat.mul_cast_comm, left_distrib, right_distrib, *]
@[simp, norm_cast]
theorem coe_nat_bit0 (n : ℕ) : (↑(bit0 n) : ℤ) = bit0 ↑n := by {unfold bit0, simp}
@[simp, norm_cast]
theorem coe_nat_bit1 (n : ℕ) : (↑(bit1 n) : ℤ) = bit1 ↑n := by {unfold bit1, unfold bit0, simp}
@[simp, norm_cast] theorem cast_bit0 [ring α] (n : ℤ) : ((bit0 n : ℤ) : α) = bit0 n := cast_add _ _
@[simp, norm_cast] theorem cast_bit1 [ring α] (n : ℤ) : ((bit1 n : ℤ) : α) = bit1 n :=
by rw [bit1, cast_add, cast_one, cast_bit0]; refl
lemma cast_two [ring α] : ((2 : ℤ) : α) = 2 := by simp
theorem cast_nonneg [linear_ordered_ring α] : ∀ {n : ℤ}, (0 : α) ≤ n ↔ 0 ≤ n
| (n : ℕ) := by simp
| -[1+ n] := by simpa [not_le_of_gt (neg_succ_lt_zero n)] using
show -(n:α) < 1, from lt_of_le_of_lt (by simp) zero_lt_one
@[simp, norm_cast] theorem cast_le [linear_ordered_ring α] {m n : ℤ} : (m : α) ≤ n ↔ m ≤ n :=
by rw [← sub_nonneg, ← cast_sub, cast_nonneg, sub_nonneg]
@[simp, norm_cast] theorem cast_lt [linear_ordered_ring α] {m n : ℤ} : (m : α) < n ↔ m < n :=
by simpa [-cast_le] using not_congr (@cast_le α _ n m)
@[simp] theorem cast_nonpos [linear_ordered_ring α] {n : ℤ} : (n : α) ≤ 0 ↔ n ≤ 0 :=
by rw [← cast_zero, cast_le]
@[simp] theorem cast_pos [linear_ordered_ring α] {n : ℤ} : (0 : α) < n ↔ 0 < n :=
by rw [← cast_zero, cast_lt]
@[simp] theorem cast_lt_zero [linear_ordered_ring α] {n : ℤ} : (n : α) < 0 ↔ n < 0 :=
by rw [← cast_zero, cast_lt]
@[simp, norm_cast] theorem cast_min [decidable_linear_ordered_comm_ring α] {a b : ℤ} :
(↑(min a b) : α) = min a b :=
by by_cases a ≤ b; simp [h, min]
@[simp, norm_cast] theorem cast_max [decidable_linear_ordered_comm_ring α] {a b : ℤ} :
(↑(max a b) : α) = max a b :=
by by_cases a ≤ b; simp [h, max]
@[simp, norm_cast] theorem cast_abs [decidable_linear_ordered_comm_ring α] {q : ℤ} :
((abs q : ℤ) : α) = abs q :=
by simp [abs]
end cast
section decidable
/-- List enumerating `[m, n)`. -/
def range (m n : ℤ) : list ℤ :=
(list.range (to_nat (n-m))).map $ λ r, m+r
theorem mem_range_iff {m n r : ℤ} : r ∈ range m n ↔ m ≤ r ∧ r < n :=
⟨λ H, let ⟨s, h1, h2⟩ := list.mem_map.1 H in h2 ▸
⟨le_add_of_nonneg_right trivial,
add_lt_of_lt_sub_left $ match n-m, h1 with
| (k:ℕ), h1 := by rwa [list.mem_range, to_nat_coe_nat, ← coe_nat_lt] at h1
end⟩,
λ ⟨h1, h2⟩, list.mem_map.2 ⟨to_nat (r-m),
list.mem_range.2 $ by rw [← coe_nat_lt, to_nat_of_nonneg (sub_nonneg_of_le h1),
to_nat_of_nonneg (sub_nonneg_of_le (le_of_lt (lt_of_le_of_lt h1 h2)))];
exact sub_lt_sub_right h2 _,
show m + _ = _, by rw [to_nat_of_nonneg (sub_nonneg_of_le h1), add_sub_cancel'_right]⟩⟩
instance decidable_le_lt (P : int → Prop) [decidable_pred P] (m n : ℤ) :
decidable (∀ r, m ≤ r → r < n → P r) :=
decidable_of_iff (∀ r ∈ range m n, P r) $ by simp only [mem_range_iff, and_imp]
instance decidable_le_le (P : int → Prop) [decidable_pred P] (m n : ℤ) :
decidable (∀ r, m ≤ r → r ≤ n → P r) :=
decidable_of_iff (∀ r ∈ range m (n+1), P r) $ by simp only [mem_range_iff, and_imp, lt_add_one_iff]
instance decidable_lt_lt (P : int → Prop) [decidable_pred P] (m n : ℤ) :
decidable (∀ r, m < r → r < n → P r) :=
int.decidable_le_lt P _ _
instance decidable_lt_le (P : int → Prop) [decidable_pred P] (m n : ℤ) :
decidable (∀ r, m < r → r ≤ n → P r) :=
int.decidable_le_le P _ _
end decidable
end int
open int
namespace add_monoid_hom
variables {A : Type*}
/-- Two additive monoid homomorphisms `f`, `g` from `ℤ` to an additive monoid are equal
if `f 1 = g 1`. -/
@[ext] theorem ext_int [add_monoid A] {f g : ℤ →+ A} (h1 : f 1 = g 1) : f = g :=
have f.comp (int.of_nat_hom : ℕ →+ ℤ) = g.comp (int.of_nat_hom : ℕ →+ ℤ) := ext_nat h1,
have ∀ n : ℕ, f n = g n := ext_iff.1 this,
ext $ λ n, int.cases_on n this $ λ n, eq_on_neg (this $ n + 1)
variables [add_group A] [has_one A]
theorem eq_int_cast_hom (f : ℤ →+ A) (h1 : f 1 = 1) : f = int.cast_add_hom A :=
ext_int $ by simp [h1]
theorem eq_int_cast (f : ℤ →+ A) (h1 : f 1 = 1) : ∀ n : ℤ, f n = n :=
ext_iff.1 (f.eq_int_cast_hom h1)
end add_monoid_hom
namespace ring_hom
variables {α : Type*} {β : Type*} [ring α] [ring β]
@[simp] lemma eq_int_cast (f : ℤ →+* α) (n : ℤ) : f n = n :=
f.to_add_monoid_hom.eq_int_cast f.map_one n
lemma eq_int_cast' (f : ℤ →+* α) : f = int.cast_ring_hom α :=
ring_hom.ext f.eq_int_cast
@[simp] lemma map_int_cast (f : α →+* β) (n : ℤ) : f n = n :=
(f.comp (int.cast_ring_hom α)).eq_int_cast n
lemma ext_int {R : Type*} [semiring R] (f g : ℤ →+* R) : f = g :=
coe_add_monoid_hom_inj $ add_monoid_hom.ext_int $ f.map_one.trans g.map_one.symm
instance int.subsingleton_ring_hom {R : Type*} [semiring R] : subsingleton (ℤ →+* R) :=
⟨ring_hom.ext_int⟩
end ring_hom
@[simp, norm_cast] theorem int.cast_id (n : ℤ) : ↑n = n :=
((ring_hom.id ℤ).eq_int_cast n).symm
|
c93c0b94cfbced34bd5f56ca03278c3c4a93ac1d | 4950bf76e5ae40ba9f8491647d0b6f228ddce173 | /src/topology/algebra/polynomial.lean | cac056fc14a92acc50a4933fcf5216a8191d4eed | [
"Apache-2.0"
] | permissive | ntzwq/mathlib | ca50b21079b0a7c6781c34b62199a396dd00cee2 | 36eec1a98f22df82eaccd354a758ef8576af2a7f | refs/heads/master | 1,675,193,391,478 | 1,607,822,996,000 | 1,607,822,996,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 5,254 | lean | /-
Copyright (c) 2018 Robert Y. Lewis. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Robert Y. Lewis
-/
import data.polynomial.algebra_map
import data.polynomial.div
import topology.metric_space.cau_seq_filter
/-!
# Polynomials and limits
In this file we prove the following lemmas.
* `polynomial.continuous_eval₂: `polynomial.eval₂` defines a continuous function.
* `polynomial.continuous_aeval: `polynomial.aeval` defines a continuous function;
we also prove convenience lemmas `polynomial.continuous_at_aeval`,
`polynomial.continuous_within_at_aeval`, `polynomial.continuous_on_aeval`.
* `polynomial.continuous`: `polynomial.eval` defines a continuous functions;
we also prove convenience lemmas `polynomial.continuous_at`, `polynomial.continuous_within_at`,
`polynomial.continuous_on`.
* `polynomial.tendsto_norm_at_top`: `λ x, ∥polynomial.eval (z x) p∥` tends to infinity provided that
`λ x, ∥z x∥` tends to infinity and `0 < degree p`;
* `polynomial.tendsto_abv_eval₂_at_top`, `polynomial.tendsto_abv_at_top`,
`polynomial.tendsto_abv_aeval_at_top`: a few versions of the previous statement for
`is_absolute_value abv` instead of norm.
## Tags
polynomial, continuity
-/
open is_absolute_value filter
namespace polynomial
section topological_semiring
variables {R S : Type*} [semiring R] [topological_space R] [topological_semiring R]
(p : polynomial R)
@[continuity]
protected lemma continuous_eval₂ [semiring S] (p : polynomial S) (f : S →+* R) :
continuous (λ x, p.eval₂ f x) :=
begin
dsimp only [eval₂_eq_sum, finsupp.sum],
exact continuous_finset_sum _ (λ c hc, continuous_const.mul (continuous_pow _))
end
@[continuity]
protected lemma continuous : continuous (λ x, p.eval x) :=
p.continuous_eval₂ _
protected lemma continuous_at {a : R} : continuous_at (λ x, p.eval x) a :=
p.continuous.continuous_at
protected lemma continuous_within_at {s a} : continuous_within_at (λ x, p.eval x) s a :=
p.continuous.continuous_within_at
protected lemma continuous_on {s} : continuous_on (λ x, p.eval x) s :=
p.continuous.continuous_on
end topological_semiring
section topological_algebra
variables {R A : Type*} [comm_semiring R] [semiring A] [algebra R A]
[topological_space A] [topological_semiring A]
(p : polynomial R)
@[continuity]
protected lemma continuous_aeval : continuous (λ x : A, aeval x p) :=
p.continuous_eval₂ _
protected lemma continuous_at_aeval {a : A} : continuous_at (λ x : A, aeval x p) a :=
p.continuous_aeval.continuous_at
protected lemma continuous_within_at_aeval {s a} : continuous_within_at (λ x : A, aeval x p) s a :=
p.continuous_aeval.continuous_within_at
protected lemma continuous_on_aeval {s} : continuous_on (λ x : A, aeval x p) s :=
p.continuous_aeval.continuous_on
end topological_algebra
lemma tendsto_abv_eval₂_at_top {R S k α : Type*} [semiring R] [ring S] [linear_ordered_field k]
(f : R →+* S) (abv : S → k) [is_absolute_value abv] (p : polynomial R) (hd : 0 < degree p)
(hf : f p.leading_coeff ≠ 0) {l : filter α} {z : α → S} (hz : tendsto (abv ∘ z) l at_top) :
tendsto (λ x, abv (p.eval₂ f (z x))) l at_top :=
begin
revert hf, refine degree_pos_induction_on p hd _ _ _; clear hd p,
{ rintros c - hc,
rw [leading_coeff_mul_X, leading_coeff_C] at hc,
simpa [abv_mul abv] using tendsto_at_top_mul_left' ((abv_pos abv).2 hc) hz },
{ intros p hpd ihp hf,
rw [leading_coeff_mul_X] at hf,
simpa [abv_mul abv] using tendsto_at_top_mul_at_top (ihp hf) hz },
{ intros p a hd ihp hf,
rw [add_comm, leading_coeff_add_of_degree_lt (degree_C_le.trans_lt hd)] at hf,
refine tendsto_at_top_of_add_const_right (abv (-f a)) _,
refine tendsto_at_top_mono (λ _, abv_add abv _ _) _,
simpa using ihp hf }
end
lemma tendsto_abv_at_top {R k α : Type*} [ring R] [linear_ordered_field k]
(abv : R → k) [is_absolute_value abv] (p : polynomial R) (h : 0 < degree p)
{l : filter α} {z : α → R} (hz : tendsto (abv ∘ z) l at_top) :
tendsto (λ x, abv (p.eval (z x))) l at_top :=
tendsto_abv_eval₂_at_top _ _ _ h (mt leading_coeff_eq_zero.1 $ ne_zero_of_degree_gt h) hz
lemma tendsto_abv_aeval_at_top {R A k α : Type*} [comm_semiring R] [ring A] [algebra R A]
[linear_ordered_field k] (abv : A → k) [is_absolute_value abv] (p : polynomial R)
(hd : 0 < degree p) (h₀ : algebra_map R A p.leading_coeff ≠ 0)
{l : filter α} {z : α → A} (hz : tendsto (abv ∘ z) l at_top) :
tendsto (λ x, abv (aeval (z x) p)) l at_top :=
tendsto_abv_eval₂_at_top _ abv p hd h₀ hz
variables {α R : Type*} [normed_ring R] [is_absolute_value (norm : R → ℝ)]
lemma tendsto_norm_at_top (p : polynomial R) (h : 0 < degree p) {l : filter α} {z : α → R}
(hz : tendsto (λ x, ∥z x∥) l at_top) :
tendsto (λ x, ∥p.eval (z x)∥) l at_top :=
p.tendsto_abv_at_top norm h hz
lemma exists_forall_norm_le [proper_space R] (p : polynomial R) :
∃ x, ∀ y, ∥p.eval x∥ ≤ ∥p.eval y∥ :=
if hp0 : 0 < degree p
then p.continuous.norm.exists_forall_le $ p.tendsto_norm_at_top hp0 tendsto_norm_cocompact_at_top
else ⟨p.coeff 0, by rw [eq_C_of_degree_le_zero (le_of_not_gt hp0)]; simp⟩
end polynomial
|
eee110bfe5f6d45001a82fe3ade36f3c46ee7d00 | bb31430994044506fa42fd667e2d556327e18dfe | /src/data/set/image.lean | be5dcf78c6a9188f49a2089b49a5aa8cce3338b7 | [
"Apache-2.0"
] | permissive | sgouezel/mathlib | 0cb4e5335a2ba189fa7af96d83a377f83270e503 | 00638177efd1b2534fc5269363ebf42a7871df9a | refs/heads/master | 1,674,527,483,042 | 1,673,665,568,000 | 1,673,665,568,000 | 119,598,202 | 0 | 0 | null | 1,517,348,647,000 | 1,517,348,646,000 | null | UTF-8 | Lean | false | false | 49,188 | lean | /-
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
-/
import data.set.basic
/-!
# Images and preimages of sets
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
## Main definitions
* `preimage f t : set α` : the preimage f⁻¹(t) (written `f ⁻¹' t` in Lean) of a subset of β.
* `range f : set β` : the image of `univ` under `f`.
Also works for `{p : Prop} (f : p → α)` (unlike `image`)
## Notation
* `f ⁻¹' t` for `set.preimage f t`
* `f '' s` for `set.image f s`
## Tags
set, sets, image, preimage, pre-image, range
-/
universes u v
open function
namespace set
variables {α β γ : Type*} {ι : Sort*}
/-! ### Inverse image -/
/-- The preimage of `s : set β` by `f : α → β`, written `f ⁻¹' s`,
is the set of `x : α` such that `f x ∈ s`. -/
def preimage {α : Type u} {β : Type v} (f : α → β) (s : set β) : set α := {x | f x ∈ s}
infix ` ⁻¹' `:80 := preimage
section preimage
variables {f : α → β} {g : β → γ}
@[simp] theorem preimage_empty : f ⁻¹' ∅ = ∅ := rfl
@[simp] theorem mem_preimage {s : set β} {a : α} : (a ∈ f ⁻¹' s) ↔ (f a ∈ s) := iff.rfl
lemma preimage_congr {f g : α → β} {s : set β} (h : ∀ (x : α), f x = g x) : f ⁻¹' s = g ⁻¹' s :=
by { congr' with x, apply_assumption }
theorem preimage_mono {s t : set β} (h : s ⊆ t) : f ⁻¹' s ⊆ f ⁻¹' t :=
assume x hx, h hx
@[simp] theorem preimage_univ : f ⁻¹' univ = univ := rfl
theorem subset_preimage_univ {s : set α} : s ⊆ f ⁻¹' univ := subset_univ _
@[simp] theorem preimage_inter {s t : set β} : f ⁻¹' (s ∩ t) = f ⁻¹' s ∩ f ⁻¹' t := rfl
@[simp] theorem preimage_union {s t : set β} : f ⁻¹' (s ∪ t) = f ⁻¹' s ∪ f ⁻¹' t := rfl
@[simp] theorem preimage_compl {s : set β} : f ⁻¹' sᶜ = (f ⁻¹' s)ᶜ := rfl
@[simp] theorem preimage_diff (f : α → β) (s t : set β) :
f ⁻¹' (s \ t) = f ⁻¹' s \ f ⁻¹' t := rfl
@[simp] theorem preimage_ite (f : α → β) (s t₁ t₂ : set β) :
f ⁻¹' (s.ite t₁ t₂) = (f ⁻¹' s).ite (f ⁻¹' t₁) (f ⁻¹' t₂) :=
rfl
@[simp] theorem preimage_set_of_eq {p : α → Prop} {f : β → α} : f ⁻¹' {a | p a} = {a | p (f a)} :=
rfl
@[simp] lemma preimage_id_eq : preimage (id : α → α) = id := rfl
theorem preimage_id {s : set α} : id ⁻¹' s = s := rfl
@[simp] theorem preimage_id' {s : set α} : (λ x, x) ⁻¹' s = s := rfl
@[simp] theorem preimage_const_of_mem {b : β} {s : set β} (h : b ∈ s) :
(λ (x : α), b) ⁻¹' s = univ :=
eq_univ_of_forall $ λ x, h
@[simp] theorem preimage_const_of_not_mem {b : β} {s : set β} (h : b ∉ s) :
(λ (x : α), b) ⁻¹' s = ∅ :=
eq_empty_of_subset_empty $ λ x hx, h hx
theorem preimage_const (b : β) (s : set β) [decidable (b ∈ s)] :
(λ (x : α), b) ⁻¹' s = if b ∈ s then univ else ∅ :=
by { split_ifs with hb hb, exacts [preimage_const_of_mem hb, preimage_const_of_not_mem hb] }
theorem preimage_comp {s : set γ} : (g ∘ f) ⁻¹' s = f ⁻¹' (g ⁻¹' s) := rfl
lemma preimage_comp_eq : preimage (g ∘ f) = preimage f ∘ preimage g := rfl
@[simp] lemma preimage_iterate_eq {f : α → α} {n : ℕ} :
set.preimage (f^[n]) = ((set.preimage f)^[n]) :=
begin
induction n with n ih, { simp, },
rw [iterate_succ, iterate_succ', set.preimage_comp_eq, ih],
end
lemma preimage_preimage {g : β → γ} {f : α → β} {s : set γ} :
f ⁻¹' (g ⁻¹' s) = (λ x, g (f x)) ⁻¹' s :=
preimage_comp.symm
theorem eq_preimage_subtype_val_iff {p : α → Prop} {s : set (subtype p)} {t : set α} :
s = subtype.val ⁻¹' t ↔ (∀x (h : p x), (⟨x, h⟩ : subtype p) ∈ s ↔ x ∈ t) :=
⟨assume s_eq x h, by { rw [s_eq], simp },
assume h, ext $ λ ⟨x, hx⟩, by simp [h]⟩
lemma nonempty_of_nonempty_preimage {s : set β} {f : α → β} (hf : (f ⁻¹' s).nonempty) :
s.nonempty :=
let ⟨x, hx⟩ := hf in ⟨f x, hx⟩
lemma preimage_subtype_coe_eq_compl {α : Type*} {s u v : set α} (hsuv : s ⊆ u ∪ v)
(H : s ∩ (u ∩ v) = ∅) : (coe : s → α) ⁻¹' u = (coe ⁻¹' v)ᶜ :=
begin
ext ⟨x, x_in_s⟩,
split,
{ intros x_in_u x_in_v,
exact eq_empty_iff_forall_not_mem.mp H x ⟨x_in_s, ⟨x_in_u, x_in_v⟩⟩ },
{ intro hx,
exact or.elim (hsuv x_in_s) id (λ hx', hx.elim hx') }
end
end preimage
/-! ### Image of a set under a function -/
section image
variables {f : α → β} {s t : set α}
/-- The image of `s : set α` by `f : α → β`, written `f '' s`,
is the set of `y : β` such that `f x = y` for some `x ∈ s`. -/
def image (f : α → β) (s : set α) : set β := {y | ∃ x, x ∈ s ∧ f x = y}
infix ` '' `:80 := image
theorem mem_image_iff_bex {f : α → β} {s : set α} {y : β} :
y ∈ f '' s ↔ ∃ x (_ : x ∈ s), f x = y := bex_def.symm
@[simp] theorem mem_image (f : α → β) (s : set α) (y : β) :
y ∈ f '' s ↔ ∃ x, x ∈ s ∧ f x = y := iff.rfl
lemma image_eta (f : α → β) : f '' s = (λ x, f x) '' s := rfl
theorem mem_image_of_mem (f : α → β) {x : α} {a : set α} (h : x ∈ a) : f x ∈ f '' a :=
⟨_, h, rfl⟩
theorem _root_.function.injective.mem_set_image {f : α → β} (hf : injective f) {s : set α} {a : α} :
f a ∈ f '' s ↔ a ∈ s :=
⟨λ ⟨b, hb, eq⟩, (hf eq) ▸ hb, mem_image_of_mem f⟩
theorem ball_image_iff {f : α → β} {s : set α} {p : β → Prop} :
(∀ y ∈ f '' s, p y) ↔ (∀ x ∈ s, p (f x)) :=
by simp
theorem ball_image_of_ball {f : α → β} {s : set α} {p : β → Prop}
(h : ∀ x ∈ s, p (f x)) : ∀ y ∈ f '' s, p y :=
ball_image_iff.2 h
theorem bex_image_iff {f : α → β} {s : set α} {p : β → Prop} :
(∃ y ∈ f '' s, p y) ↔ (∃ x ∈ s, p (f x)) :=
by simp
theorem mem_image_elim {f : α → β} {s : set α} {C : β → Prop} (h : ∀ (x : α), x ∈ s → C (f x)) :
∀{y : β}, y ∈ f '' s → C y
| ._ ⟨a, a_in, rfl⟩ := h a a_in
theorem mem_image_elim_on {f : α → β} {s : set α} {C : β → Prop} {y : β} (h_y : y ∈ f '' s)
(h : ∀ (x : α), x ∈ s → C (f x)) : C y :=
mem_image_elim h h_y
@[congr] lemma image_congr {f g : α → β} {s : set α}
(h : ∀a∈s, f a = g a) : f '' s = g '' s :=
by safe [ext_iff, iff_def]
/-- A common special case of `image_congr` -/
lemma image_congr' {f g : α → β} {s : set α} (h : ∀ (x : α), f x = g x) : f '' s = g '' s :=
image_congr (λx _, h x)
theorem image_comp (f : β → γ) (g : α → β) (a : set α) : (f ∘ g) '' a = f '' (g '' a) :=
subset.antisymm
(ball_image_of_ball $ assume a ha, mem_image_of_mem _ $ mem_image_of_mem _ ha)
(ball_image_of_ball $ ball_image_of_ball $ assume a ha, mem_image_of_mem _ ha)
/-- A variant of `image_comp`, useful for rewriting -/
lemma image_image (g : β → γ) (f : α → β) (s : set α) : g '' (f '' s) = (λ x, g (f x)) '' s :=
(image_comp g f s).symm
lemma image_comm {β'} {f : β → γ} {g : α → β} {f' : α → β'} {g' : β' → γ}
(h_comm : ∀ a, f (g a) = g' (f' a)) :
(s.image g).image f = (s.image f').image g' :=
by simp_rw [image_image, h_comm]
lemma _root_.function.semiconj.set_image {f : α → β} {ga : α → α} {gb : β → β}
(h : function.semiconj f ga gb) :
function.semiconj (image f) (image ga) (image gb) :=
λ s, image_comm h
lemma _root_.function.commute.set_image {f g : α → α} (h : function.commute f g) :
function.commute (image f) (image g) :=
h.set_image
/-- Image is monotone with respect to `⊆`. See `set.monotone_image` for the statement in
terms of `≤`. -/
theorem image_subset {a b : set α} (f : α → β) (h : a ⊆ b) : f '' a ⊆ f '' b :=
by { simp only [subset_def, mem_image], exact λ x, λ ⟨w, h1, h2⟩, ⟨w, h h1, h2⟩ }
/-- `set.image` is monotone. See `set.image_subset` for the statement in terms of `⊆`. -/
lemma monotone_image {f : α → β} : monotone (image f) :=
λ s t, image_subset _
theorem image_union (f : α → β) (s t : set α) :
f '' (s ∪ t) = f '' s ∪ f '' t :=
ext $ λ x, ⟨by rintro ⟨a, h|h, rfl⟩; [left, right]; exact ⟨_, h, rfl⟩,
by rintro (⟨a, h, rfl⟩ | ⟨a, h, rfl⟩); refine ⟨_, _, rfl⟩; [left, right]; exact h⟩
@[simp] theorem image_empty (f : α → β) : f '' ∅ = ∅ := by { ext, simp }
lemma image_inter_subset (f : α → β) (s t : set α) :
f '' (s ∩ t) ⊆ f '' s ∩ f '' t :=
subset_inter (image_subset _ $ inter_subset_left _ _) (image_subset _ $ inter_subset_right _ _)
theorem image_inter_on {f : α → β} {s t : set α} (h : ∀x∈t, ∀y∈s, f x = f y → x = y) :
f '' (s ∩ t) = f '' s ∩ f '' t :=
(image_inter_subset _ _ _).antisymm
(assume b ⟨⟨a₁, ha₁, h₁⟩, ⟨a₂, ha₂, h₂⟩⟩,
have a₂ = a₁, from h _ ha₂ _ ha₁ (by simp *),
⟨a₁, ⟨ha₁, this ▸ ha₂⟩, h₁⟩)
theorem image_inter {f : α → β} {s t : set α} (H : injective f) :
f '' (s ∩ t) = f '' s ∩ f '' t :=
image_inter_on (assume x _ y _ h, H h)
theorem image_univ_of_surjective {ι : Type*} {f : ι → β} (H : surjective f) : f '' univ = univ :=
eq_univ_of_forall $ by { simpa [image] }
@[simp] theorem image_singleton {f : α → β} {a : α} : f '' {a} = {f a} :=
by { ext, simp [image, eq_comm] }
@[simp] theorem nonempty.image_const {s : set α} (hs : s.nonempty) (a : β) : (λ _, a) '' s = {a} :=
ext $ λ x, ⟨λ ⟨y, _, h⟩, h ▸ mem_singleton _,
λ h, (eq_of_mem_singleton h).symm ▸ hs.imp (λ y hy, ⟨hy, rfl⟩)⟩
@[simp] lemma image_eq_empty {α β} {f : α → β} {s : set α} : f '' s = ∅ ↔ s = ∅ :=
by { simp only [eq_empty_iff_forall_not_mem],
exact ⟨λ H a ha, H _ ⟨_, ha, rfl⟩, λ H b ⟨_, ha, _⟩, H _ ha⟩ }
lemma preimage_compl_eq_image_compl [boolean_algebra α] (S : set α) :
compl ⁻¹' S = compl '' S :=
set.ext (λ x, ⟨λ h, ⟨xᶜ,h, compl_compl x⟩,
λ h, exists.elim h (λ y hy, (compl_eq_comm.mp hy.2).symm.subst hy.1)⟩)
theorem mem_compl_image [boolean_algebra α] (t : α) (S : set α) :
t ∈ compl '' S ↔ tᶜ ∈ S :=
by simp [←preimage_compl_eq_image_compl]
/-- A variant of `image_id` -/
@[simp] lemma image_id' (s : set α) : (λx, x) '' s = s := by { ext, simp }
theorem image_id (s : set α) : id '' s = s := by simp
theorem compl_compl_image [boolean_algebra α] (S : set α) :
compl '' (compl '' S) = S :=
by rw [←image_comp, compl_comp_compl, image_id]
theorem image_insert_eq {f : α → β} {a : α} {s : set α} :
f '' (insert a s) = insert (f a) (f '' s) :=
by { ext, simp [and_or_distrib_left, exists_or_distrib, eq_comm, or_comm, and_comm] }
theorem image_pair (f : α → β) (a b : α) : f '' {a, b} = {f a, f b} :=
by simp only [image_insert_eq, image_singleton]
theorem image_subset_preimage_of_inverse {f : α → β} {g : β → α}
(I : left_inverse g f) (s : set α) : f '' s ⊆ g ⁻¹' s :=
λ b ⟨a, h, e⟩, e ▸ ((I a).symm ▸ h : g (f a) ∈ s)
theorem preimage_subset_image_of_inverse {f : α → β} {g : β → α}
(I : left_inverse g f) (s : set β) : f ⁻¹' s ⊆ g '' s :=
λ b h, ⟨f b, h, I b⟩
theorem image_eq_preimage_of_inverse {f : α → β} {g : β → α}
(h₁ : left_inverse g f) (h₂ : right_inverse g f) :
image f = preimage g :=
funext $ λ s, subset.antisymm
(image_subset_preimage_of_inverse h₁ s)
(preimage_subset_image_of_inverse h₂ s)
theorem mem_image_iff_of_inverse {f : α → β} {g : β → α} {b : β} {s : set α}
(h₁ : left_inverse g f) (h₂ : right_inverse g f) :
b ∈ f '' s ↔ g b ∈ s :=
by rw image_eq_preimage_of_inverse h₁ h₂; refl
theorem image_compl_subset {f : α → β} {s : set α} (H : injective f) : f '' sᶜ ⊆ (f '' s)ᶜ :=
disjoint.subset_compl_left $ by simp [disjoint_iff_inf_le, ←image_inter H]
theorem subset_image_compl {f : α → β} {s : set α} (H : surjective f) : (f '' s)ᶜ ⊆ f '' sᶜ :=
compl_subset_iff_union.2 $
by { rw ← image_union, simp [image_univ_of_surjective H] }
theorem image_compl_eq {f : α → β} {s : set α} (H : bijective f) : f '' sᶜ = (f '' s)ᶜ :=
subset.antisymm (image_compl_subset H.1) (subset_image_compl H.2)
theorem subset_image_diff (f : α → β) (s t : set α) :
f '' s \ f '' t ⊆ f '' (s \ t) :=
begin
rw [diff_subset_iff, ← image_union, union_diff_self],
exact image_subset f (subset_union_right t s)
end
lemma subset_image_symm_diff : (f '' s) ∆ (f '' t) ⊆ f '' s ∆ t :=
(union_subset_union (subset_image_diff _ _ _) $ subset_image_diff _ _ _).trans
(image_union _ _ _).superset
theorem image_diff {f : α → β} (hf : injective f) (s t : set α) :
f '' (s \ t) = f '' s \ f '' t :=
subset.antisymm
(subset.trans (image_inter_subset _ _ _) $ inter_subset_inter_right _ $ image_compl_subset hf)
(subset_image_diff f s t)
lemma image_symm_diff (hf : injective f) (s t : set α) : f '' (s ∆ t) = (f '' s) ∆ (f '' t) :=
by simp_rw [set.symm_diff_def, image_union, image_diff hf]
lemma nonempty.image (f : α → β) {s : set α} : s.nonempty → (f '' s).nonempty
| ⟨x, hx⟩ := ⟨f x, mem_image_of_mem f hx⟩
lemma nonempty.of_image {f : α → β} {s : set α} : (f '' s).nonempty → s.nonempty
| ⟨y, x, hx, _⟩ := ⟨x, hx⟩
@[simp] lemma nonempty_image_iff {f : α → β} {s : set α} :
(f '' s).nonempty ↔ s.nonempty :=
⟨nonempty.of_image, λ h, h.image f⟩
lemma nonempty.preimage {s : set β} (hs : s.nonempty) {f : α → β} (hf : surjective f) :
(f ⁻¹' s).nonempty :=
let ⟨y, hy⟩ := hs, ⟨x, hx⟩ := hf y in ⟨x, mem_preimage.2 $ hx.symm ▸ hy⟩
instance (f : α → β) (s : set α) [nonempty s] : nonempty (f '' s) :=
(set.nonempty.image f nonempty_of_nonempty_subtype).to_subtype
/-- image and preimage are a Galois connection -/
@[simp] theorem image_subset_iff {s : set α} {t : set β} {f : α → β} :
f '' s ⊆ t ↔ s ⊆ f ⁻¹' t :=
ball_image_iff
theorem image_preimage_subset (f : α → β) (s : set β) : f '' (f ⁻¹' s) ⊆ s :=
image_subset_iff.2 subset.rfl
theorem subset_preimage_image (f : α → β) (s : set α) :
s ⊆ f ⁻¹' (f '' s) :=
λ x, mem_image_of_mem f
theorem preimage_image_eq {f : α → β} (s : set α) (h : injective f) : f ⁻¹' (f '' s) = s :=
subset.antisymm
(λ x ⟨y, hy, e⟩, h e ▸ hy)
(subset_preimage_image f s)
theorem image_preimage_eq {f : α → β} (s : set β) (h : surjective f) : f '' (f ⁻¹' s) = s :=
subset.antisymm
(image_preimage_subset f s)
(λ x hx, let ⟨y, e⟩ := h x in ⟨y, (e.symm ▸ hx : f y ∈ s), e⟩)
lemma preimage_eq_preimage {f : β → α} (hf : surjective f) : f ⁻¹' s = f ⁻¹' t ↔ s = t :=
iff.intro
(assume eq, by rw [← image_preimage_eq s hf, ← image_preimage_eq t hf, eq])
(assume eq, eq ▸ rfl)
lemma image_inter_preimage (f : α → β) (s : set α) (t : set β) :
f '' (s ∩ f ⁻¹' t) = f '' s ∩ t :=
begin
apply subset.antisymm,
{ calc f '' (s ∩ f ⁻¹' t) ⊆ f '' s ∩ (f '' (f⁻¹' t)) : image_inter_subset _ _ _
... ⊆ f '' s ∩ t : inter_subset_inter_right _ (image_preimage_subset f t) },
{ rintros _ ⟨⟨x, h', rfl⟩, h⟩,
exact ⟨x, ⟨h', h⟩, rfl⟩ }
end
lemma image_preimage_inter (f : α → β) (s : set α) (t : set β) :
f '' (f ⁻¹' t ∩ s) = t ∩ f '' s :=
by simp only [inter_comm, image_inter_preimage]
@[simp] lemma image_inter_nonempty_iff {f : α → β} {s : set α} {t : set β} :
(f '' s ∩ t).nonempty ↔ (s ∩ f ⁻¹' t).nonempty :=
by rw [←image_inter_preimage, nonempty_image_iff]
lemma image_diff_preimage {f : α → β} {s : set α} {t : set β} : f '' (s \ f ⁻¹' t) = f '' s \ t :=
by simp_rw [diff_eq, ← preimage_compl, image_inter_preimage]
theorem compl_image : image (compl : set α → set α) = preimage compl :=
image_eq_preimage_of_inverse compl_compl compl_compl
theorem compl_image_set_of {p : set α → Prop} :
compl '' {s | p s} = {s | p sᶜ} :=
congr_fun compl_image p
theorem inter_preimage_subset (s : set α) (t : set β) (f : α → β) :
s ∩ f ⁻¹' t ⊆ f ⁻¹' (f '' s ∩ t) :=
λ x h, ⟨mem_image_of_mem _ h.left, h.right⟩
theorem union_preimage_subset (s : set α) (t : set β) (f : α → β) :
s ∪ f ⁻¹' t ⊆ f ⁻¹' (f '' s ∪ t) :=
λ x h, or.elim h (λ l, or.inl $ mem_image_of_mem _ l) (λ r, or.inr r)
theorem subset_image_union (f : α → β) (s : set α) (t : set β) :
f '' (s ∪ f ⁻¹' t) ⊆ f '' s ∪ t :=
image_subset_iff.2 (union_preimage_subset _ _ _)
lemma preimage_subset_iff {A : set α} {B : set β} {f : α → β} :
f⁻¹' B ⊆ A ↔ (∀ a : α, f a ∈ B → a ∈ A) := iff.rfl
lemma image_eq_image {f : α → β} (hf : injective f) : f '' s = f '' t ↔ s = t :=
iff.symm $ iff.intro (assume eq, eq ▸ rfl) $ assume eq,
by rw [← preimage_image_eq s hf, ← preimage_image_eq t hf, eq]
lemma image_subset_image_iff {f : α → β} (hf : injective f) : f '' s ⊆ f '' t ↔ s ⊆ t :=
begin
refine (iff.symm $ iff.intro (image_subset f) $ assume h, _),
rw [← preimage_image_eq s hf, ← preimage_image_eq t hf],
exact preimage_mono h
end
lemma prod_quotient_preimage_eq_image [s : setoid α] (g : quotient s → β) {h : α → β}
(Hh : h = g ∘ quotient.mk) (r : set (β × β)) :
{x : quotient s × quotient s | (g x.1, g x.2) ∈ r} =
(λ a : α × α, (⟦a.1⟧, ⟦a.2⟧)) '' ((λ a : α × α, (h a.1, h a.2)) ⁻¹' r) :=
Hh.symm ▸ set.ext (λ ⟨a₁, a₂⟩, ⟨quotient.induction_on₂ a₁ a₂
(λ a₁ a₂ h, ⟨(a₁, a₂), h, rfl⟩),
λ ⟨⟨b₁, b₂⟩, h₁, h₂⟩, show (g a₁, g a₂) ∈ r, from
have h₃ : ⟦b₁⟧ = a₁ ∧ ⟦b₂⟧ = a₂ := prod.ext_iff.1 h₂,
h₃.1 ▸ h₃.2 ▸ h₁⟩)
lemma exists_image_iff (f : α → β) (x : set α) (P : β → Prop) :
(∃ (a : f '' x), P a) ↔ ∃ (a : x), P (f a) :=
⟨λ ⟨a, h⟩, ⟨⟨_, a.prop.some_spec.1⟩, a.prop.some_spec.2.symm ▸ h⟩,
λ ⟨a, h⟩, ⟨⟨_, _, a.prop, rfl⟩, h⟩⟩
/-- Restriction of `f` to `s` factors through `s.image_factorization f : s → f '' s`. -/
def image_factorization (f : α → β) (s : set α) : s → f '' s :=
λ p, ⟨f p.1, mem_image_of_mem f p.2⟩
lemma image_factorization_eq {f : α → β} {s : set α} :
subtype.val ∘ image_factorization f s = f ∘ subtype.val :=
funext $ λ p, rfl
lemma surjective_onto_image {f : α → β} {s : set α} :
surjective (image_factorization f s) :=
λ ⟨_, ⟨a, ha, rfl⟩⟩, ⟨⟨a, ha⟩, rfl⟩
/-- If the only elements outside `s` are those left fixed by `σ`, then mapping by `σ` has no effect.
-/
lemma image_perm {s : set α} {σ : equiv.perm α} (hs : {a : α | σ a ≠ a} ⊆ s) : σ '' s = s :=
begin
ext i,
obtain hi | hi := eq_or_ne (σ i) i,
{ refine ⟨_, λ h, ⟨i, h, hi⟩⟩,
rintro ⟨j, hj, h⟩,
rwa σ.injective (hi.trans h.symm) },
{ refine iff_of_true ⟨σ.symm i, hs $ λ h, hi _, σ.apply_symm_apply _⟩ (hs hi),
convert congr_arg σ h; exact (σ.apply_symm_apply _).symm }
end
end image
/-! ### Lemmas about range of a function. -/
section range
variables {f : ι → α} {s t : set α}
/-- Range of a function.
This function is more flexible than `f '' univ`, as the image requires that the domain is in Type
and not an arbitrary Sort. -/
def range (f : ι → α) : set α := {x | ∃y, f y = x}
@[simp] theorem mem_range {x : α} : x ∈ range f ↔ ∃ y, f y = x := iff.rfl
@[simp] theorem mem_range_self (i : ι) : f i ∈ range f := ⟨i, rfl⟩
theorem forall_range_iff {p : α → Prop} : (∀ a ∈ range f, p a) ↔ (∀ i, p (f i)) :=
by simp
theorem forall_subtype_range_iff {p : range f → Prop} :
(∀ a : range f, p a) ↔ ∀ i, p ⟨f i, mem_range_self _⟩ :=
⟨λ H i, H _, λ H ⟨y, i, hi⟩, by { subst hi, apply H }⟩
theorem exists_range_iff {p : α → Prop} : (∃ a ∈ range f, p a) ↔ (∃ i, p (f i)) :=
by simp
lemma exists_range_iff' {p : α → Prop} :
(∃ a, a ∈ range f ∧ p a) ↔ ∃ i, p (f i) :=
by simpa only [exists_prop] using exists_range_iff
lemma exists_subtype_range_iff {p : range f → Prop} :
(∃ a : range f, p a) ↔ ∃ i, p ⟨f i, mem_range_self _⟩ :=
⟨λ ⟨⟨a, i, hi⟩, ha⟩, by { subst a, exact ⟨i, ha⟩}, λ ⟨i, hi⟩, ⟨_, hi⟩⟩
theorem range_iff_surjective : range f = univ ↔ surjective f :=
eq_univ_iff_forall
alias range_iff_surjective ↔ _ _root_.function.surjective.range_eq
@[simp] theorem image_univ {f : α → β} : f '' univ = range f :=
by { ext, simp [image, range] }
theorem image_subset_range (f : α → β) (s) : f '' s ⊆ range f :=
by rw ← image_univ; exact image_subset _ (subset_univ _)
theorem mem_range_of_mem_image (f : α → β) (s) {x : β} (h : x ∈ f '' s) : x ∈ range f :=
image_subset_range f s h
lemma _root_.nat.mem_range_succ (i : ℕ) : i ∈ range nat.succ ↔ 0 < i :=
⟨by { rintros ⟨n, rfl⟩, exact nat.succ_pos n, }, λ h, ⟨_, nat.succ_pred_eq_of_pos h⟩⟩
lemma nonempty.preimage' {s : set β} (hs : s.nonempty) {f : α → β} (hf : s ⊆ set.range f) :
(f ⁻¹' s).nonempty :=
let ⟨y, hy⟩ := hs, ⟨x, hx⟩ := hf hy in ⟨x, set.mem_preimage.2 $ hx.symm ▸ hy⟩
theorem range_comp (g : α → β) (f : ι → α) : range (g ∘ f) = g '' range f :=
subset.antisymm
(forall_range_iff.mpr $ assume i, mem_image_of_mem g (mem_range_self _))
(ball_image_iff.mpr $ forall_range_iff.mpr mem_range_self)
theorem range_subset_iff : range f ⊆ s ↔ ∀ y, f y ∈ s :=
forall_range_iff
theorem range_eq_iff (f : α → β) (s : set β) :
range f = s ↔ (∀ a, f a ∈ s) ∧ ∀ b ∈ s, ∃ a, f a = b :=
by { rw ←range_subset_iff, exact le_antisymm_iff }
lemma range_comp_subset_range (f : α → β) (g : β → γ) : range (g ∘ f) ⊆ range g :=
by rw range_comp; apply image_subset_range
lemma range_nonempty_iff_nonempty : (range f).nonempty ↔ nonempty ι :=
⟨λ ⟨y, x, hxy⟩, ⟨x⟩, λ ⟨x⟩, ⟨f x, mem_range_self x⟩⟩
lemma range_nonempty [h : nonempty ι] (f : ι → α) : (range f).nonempty :=
range_nonempty_iff_nonempty.2 h
@[simp] lemma range_eq_empty_iff {f : ι → α} : range f = ∅ ↔ is_empty ι :=
by rw [← not_nonempty_iff, ← range_nonempty_iff_nonempty, not_nonempty_iff_eq_empty]
lemma range_eq_empty [is_empty ι] (f : ι → α) : range f = ∅ := range_eq_empty_iff.2 ‹_›
instance [nonempty ι] (f : ι → α) : nonempty (range f) := (range_nonempty f).to_subtype
@[simp] lemma image_union_image_compl_eq_range (f : α → β) :
(f '' s) ∪ (f '' sᶜ) = range f :=
by rw [← image_union, ← image_univ, ← union_compl_self]
lemma insert_image_compl_eq_range (f : α → β) (x : α) :
insert (f x) (f '' {x}ᶜ) = range f :=
begin
ext y, rw [mem_range, mem_insert_iff, mem_image],
split,
{ rintro (h | ⟨x', hx', h⟩),
{ exact ⟨x, h.symm⟩ },
{ exact ⟨x', h⟩ } },
{ rintro ⟨x', h⟩,
by_cases hx : x' = x,
{ left, rw [← h, hx] },
{ right, refine ⟨_, _, h⟩, rw mem_compl_singleton_iff, exact hx } }
end
theorem image_preimage_eq_inter_range {f : α → β} {t : set β} :
f '' (f ⁻¹' t) = t ∩ range f :=
ext $ assume x, ⟨assume ⟨x, hx, heq⟩, heq ▸ ⟨hx, mem_range_self _⟩,
assume ⟨hx, ⟨y, h_eq⟩⟩, h_eq ▸ mem_image_of_mem f $
show y ∈ f ⁻¹' t, by simp [preimage, h_eq, hx]⟩
lemma image_preimage_eq_of_subset {f : α → β} {s : set β} (hs : s ⊆ range f) :
f '' (f ⁻¹' s) = s :=
by rw [image_preimage_eq_inter_range, inter_eq_self_of_subset_left hs]
lemma image_preimage_eq_iff {f : α → β} {s : set β} : f '' (f ⁻¹' s) = s ↔ s ⊆ range f :=
⟨by { intro h, rw [← h], apply image_subset_range }, image_preimage_eq_of_subset⟩
lemma subset_range_iff_exists_image_eq {f : α → β} {s : set β} :
s ⊆ range f ↔ ∃ t, f '' t = s :=
⟨λ h, ⟨_, image_preimage_eq_iff.2 h⟩, λ ⟨t, ht⟩, ht ▸ image_subset_range _ _⟩
@[simp] lemma exists_subset_range_and_iff {f : α → β} {p : set β → Prop} :
(∃ s, s ⊆ range f ∧ p s) ↔ ∃ s, p (f '' s) :=
⟨λ ⟨s, hsf, hps⟩, ⟨f ⁻¹' s, (image_preimage_eq_of_subset hsf).symm ▸ hps⟩,
λ ⟨s, hs⟩, ⟨f '' s, image_subset_range _ _, hs⟩⟩
lemma exists_subset_range_iff {f : α → β} {p : set β → Prop} :
(∃ s ⊆ range f, p s) ↔ ∃ s, p (f '' s) :=
by simp only [exists_prop, exists_subset_range_and_iff]
lemma range_image (f : α → β) : range (image f) = 𝒫 (range f) :=
ext $ λ s, subset_range_iff_exists_image_eq.symm
lemma preimage_subset_preimage_iff {s t : set α} {f : β → α} (hs : s ⊆ range f) :
f ⁻¹' s ⊆ f ⁻¹' t ↔ s ⊆ t :=
begin
split,
{ intros h x hx, rcases hs hx with ⟨y, rfl⟩, exact h hx },
intros h x, apply h
end
lemma preimage_eq_preimage' {s t : set α} {f : β → α} (hs : s ⊆ range f) (ht : t ⊆ range f) :
f ⁻¹' s = f ⁻¹' t ↔ s = t :=
begin
split,
{ intro h, apply subset.antisymm, rw [←preimage_subset_preimage_iff hs, h],
rw [←preimage_subset_preimage_iff ht, h] },
rintro rfl, refl
end
@[simp] theorem preimage_inter_range {f : α → β} {s : set β} : f ⁻¹' (s ∩ range f) = f ⁻¹' s :=
set.ext $ λ x, and_iff_left ⟨x, rfl⟩
@[simp] theorem preimage_range_inter {f : α → β} {s : set β} : f ⁻¹' (range f ∩ s) = f ⁻¹' s :=
by rw [inter_comm, preimage_inter_range]
theorem preimage_image_preimage {f : α → β} {s : set β} :
f ⁻¹' (f '' (f ⁻¹' s)) = f ⁻¹' s :=
by rw [image_preimage_eq_inter_range, preimage_inter_range]
@[simp] theorem range_id : range (@id α) = univ := range_iff_surjective.2 surjective_id
@[simp] theorem range_id' : range (λ (x : α), x) = univ := range_id
@[simp] theorem _root_.prod.range_fst [nonempty β] : range (prod.fst : α × β → α) = univ :=
prod.fst_surjective.range_eq
@[simp] theorem _root_.prod.range_snd [nonempty α] : range (prod.snd : α × β → β) = univ :=
prod.snd_surjective.range_eq
@[simp] theorem range_eval {ι : Type*} {α : ι → Sort*} [Π i, nonempty (α i)] (i : ι) :
range (eval i : (Π i, α i) → α i) = univ :=
(surjective_eval i).range_eq
theorem is_compl_range_inl_range_inr : is_compl (range $ @sum.inl α β) (range sum.inr) :=
is_compl.of_le
(by { rintro y ⟨⟨x₁, rfl⟩, ⟨x₂, _⟩⟩, cc })
(by { rintro (x|y) -; [left, right]; exact mem_range_self _ })
@[simp] theorem range_inl_union_range_inr : range (sum.inl : α → α ⊕ β) ∪ range sum.inr = univ :=
is_compl_range_inl_range_inr.sup_eq_top
@[simp] theorem range_inl_inter_range_inr : range (sum.inl : α → α ⊕ β) ∩ range sum.inr = ∅ :=
is_compl_range_inl_range_inr.inf_eq_bot
@[simp] theorem range_inr_union_range_inl : range (sum.inr : β → α ⊕ β) ∪ range sum.inl = univ :=
is_compl_range_inl_range_inr.symm.sup_eq_top
@[simp] theorem range_inr_inter_range_inl : range (sum.inr : β → α ⊕ β) ∩ range sum.inl = ∅ :=
is_compl_range_inl_range_inr.symm.inf_eq_bot
@[simp] theorem preimage_inl_image_inr (s : set β) : sum.inl ⁻¹' (@sum.inr α β '' s) = ∅ :=
by { ext, simp }
@[simp] theorem preimage_inr_image_inl (s : set α) : sum.inr ⁻¹' (@sum.inl α β '' s) = ∅ :=
by { ext, simp }
@[simp] theorem preimage_inl_range_inr : sum.inl ⁻¹' range (sum.inr : β → α ⊕ β) = ∅ :=
by rw [← image_univ, preimage_inl_image_inr]
@[simp] theorem preimage_inr_range_inl : sum.inr ⁻¹' range (sum.inl : α → α ⊕ β) = ∅ :=
by rw [← image_univ, preimage_inr_image_inl]
@[simp] lemma compl_range_inl : (range (sum.inl : α → α ⊕ β))ᶜ = range (sum.inr : β → α ⊕ β) :=
is_compl.compl_eq is_compl_range_inl_range_inr
@[simp] lemma compl_range_inr : (range (sum.inr : β → α ⊕ β))ᶜ = range (sum.inl : α → α ⊕ β) :=
is_compl.compl_eq is_compl_range_inl_range_inr.symm
theorem image_preimage_inl_union_image_preimage_inr (s : set (α ⊕ β)) :
sum.inl '' (sum.inl ⁻¹' s) ∪ sum.inr '' (sum.inr ⁻¹' s) = s :=
by rw [image_preimage_eq_inter_range, image_preimage_eq_inter_range, ← inter_distrib_left,
range_inl_union_range_inr, inter_univ]
@[simp] theorem range_quot_mk (r : α → α → Prop) : range (quot.mk r) = univ :=
(surjective_quot_mk r).range_eq
@[simp] theorem range_quot_lift {r : ι → ι → Prop} (hf : ∀ x y, r x y → f x = f y) :
range (quot.lift f hf) = range f :=
ext $ λ y, (surjective_quot_mk _).exists
@[simp] theorem range_quotient_mk [setoid α] : range (λx : α, ⟦x⟧) = univ :=
range_quot_mk _
@[simp] theorem range_quotient_lift [s : setoid ι] (hf) :
range (quotient.lift f hf : quotient s → α) = range f :=
range_quot_lift _
@[simp] theorem range_quotient_mk' {s : setoid α} : range (quotient.mk' : α → quotient s) = univ :=
range_quot_mk _
@[simp] theorem range_quotient_lift_on' {s : setoid ι} (hf) :
range (λ x : quotient s, quotient.lift_on' x f hf) = range f :=
range_quot_lift _
instance can_lift (c) (p) [can_lift α β c p] :
can_lift (set α) (set β) (('') c) (λ s, ∀ x ∈ s, p x) :=
{ prf := λ s hs, subset_range_iff_exists_image_eq.mp (λ x hx, can_lift.prf _ (hs x hx)) }
lemma range_const_subset {c : α} : range (λ x : ι, c) ⊆ {c} :=
range_subset_iff.2 $ λ x, rfl
@[simp] lemma range_const : ∀ [nonempty ι] {c : α}, range (λx:ι, c) = {c}
| ⟨x⟩ c := subset.antisymm range_const_subset $
assume y hy, (mem_singleton_iff.1 hy).symm ▸ mem_range_self x
lemma range_subtype_map {p : α → Prop} {q : β → Prop} (f : α → β) (h : ∀ x, p x → q (f x)) :
range (subtype.map f h) = coe ⁻¹' (f '' {x | p x}) :=
begin
ext ⟨x, hx⟩,
simp_rw [mem_preimage, mem_range, mem_image, subtype.exists, subtype.map, subtype.coe_mk,
mem_set_of, exists_prop]
end
lemma image_swap_eq_preimage_swap : image (@prod.swap α β) = preimage prod.swap :=
image_eq_preimage_of_inverse prod.swap_left_inverse prod.swap_right_inverse
theorem preimage_singleton_nonempty {f : α → β} {y : β} :
(f ⁻¹' {y}).nonempty ↔ y ∈ range f :=
iff.rfl
theorem preimage_singleton_eq_empty {f : α → β} {y : β} :
f ⁻¹' {y} = ∅ ↔ y ∉ range f :=
not_nonempty_iff_eq_empty.symm.trans preimage_singleton_nonempty.not
lemma range_subset_singleton {f : ι → α} {x : α} : range f ⊆ {x} ↔ f = const ι x :=
by simp [range_subset_iff, funext_iff, mem_singleton]
lemma image_compl_preimage {f : α → β} {s : set β} : f '' ((f ⁻¹' s)ᶜ) = range f \ s :=
by rw [compl_eq_univ_diff, image_diff_preimage, image_univ]
/-- Any map `f : ι → β` factors through a map `range_factorization f : ι → range f`. -/
def range_factorization (f : ι → β) : ι → range f :=
λ i, ⟨f i, mem_range_self i⟩
lemma range_factorization_eq {f : ι → β} :
subtype.val ∘ range_factorization f = f :=
funext $ λ i, rfl
@[simp] lemma range_factorization_coe (f : ι → β) (a : ι) :
(range_factorization f a : β) = f a := rfl
@[simp] lemma coe_comp_range_factorization (f : ι → β) : coe ∘ range_factorization f = f := rfl
lemma surjective_onto_range : surjective (range_factorization f) :=
λ ⟨_, ⟨i, rfl⟩⟩, ⟨i, rfl⟩
lemma image_eq_range (f : α → β) (s : set α) : f '' s = range (λ(x : s), f x) :=
by { ext, split, rintro ⟨x, h1, h2⟩, exact ⟨⟨x, h1⟩, h2⟩, rintro ⟨⟨x, h1⟩, h2⟩, exact ⟨x, h1, h2⟩ }
lemma _root_.sum.range_eq (f : α ⊕ β → γ) : range f = range (f ∘ sum.inl) ∪ range (f ∘ sum.inr) :=
ext $ λ x, sum.exists
@[simp] lemma sum.elim_range (f : α → γ) (g : β → γ) : range (sum.elim f g) = range f ∪ range g :=
sum.range_eq _
lemma range_ite_subset' {p : Prop} [decidable p] {f g : α → β} :
range (if p then f else g) ⊆ range f ∪ range g :=
begin
by_cases h : p, {rw if_pos h, exact subset_union_left _ _},
{rw if_neg h, exact subset_union_right _ _}
end
lemma range_ite_subset {p : α → Prop} [decidable_pred p] {f g : α → β} :
range (λ x, if p x then f x else g x) ⊆ range f ∪ range g :=
begin
rw range_subset_iff, intro x, by_cases h : p x,
simp [if_pos h, mem_union, mem_range_self],
simp [if_neg h, mem_union, mem_range_self]
end
@[simp] lemma preimage_range (f : α → β) : f ⁻¹' (range f) = univ :=
eq_univ_of_forall mem_range_self
/-- The range of a function from a `unique` type contains just the
function applied to its single value. -/
lemma range_unique [h : unique ι] : range f = {f default} :=
begin
ext x,
rw mem_range,
split,
{ rintros ⟨i, hi⟩,
rw h.uniq i at hi,
exact hi ▸ mem_singleton _ },
{ exact λ h, ⟨default, h.symm⟩ }
end
lemma range_diff_image_subset (f : α → β) (s : set α) :
range f \ f '' s ⊆ f '' sᶜ :=
λ y ⟨⟨x, h₁⟩, h₂⟩, ⟨x, λ h, h₂ ⟨x, h, h₁⟩, h₁⟩
lemma range_diff_image {f : α → β} (H : injective f) (s : set α) :
range f \ f '' s = f '' sᶜ :=
subset.antisymm (range_diff_image_subset f s) $ λ y ⟨x, hx, hy⟩, hy ▸
⟨mem_range_self _, λ ⟨x', hx', eq⟩, hx $ H eq ▸ hx'⟩
@[simp] lemma range_inclusion (h : s ⊆ t) : range (inclusion h) = {x : t | (x:α) ∈ s} :=
by { ext ⟨x, hx⟩, simp [inclusion] }
/-- We can use the axiom of choice to pick a preimage for every element of `range f`. -/
noncomputable def range_splitting (f : α → β) : range f → α := λ x, x.2.some
-- This can not be a `@[simp]` lemma because the head of the left hand side is a variable.
lemma apply_range_splitting (f : α → β) (x : range f) : f (range_splitting f x) = x :=
x.2.some_spec
attribute [irreducible] range_splitting
@[simp] lemma comp_range_splitting (f : α → β) : f ∘ range_splitting f = coe :=
by { ext, simp only [function.comp_app], apply apply_range_splitting, }
-- When `f` is injective, see also `equiv.of_injective`.
lemma left_inverse_range_splitting (f : α → β) :
left_inverse (range_factorization f) (range_splitting f) :=
λ x, by { ext, simp only [range_factorization_coe], apply apply_range_splitting, }
lemma range_splitting_injective (f : α → β) : injective (range_splitting f) :=
(left_inverse_range_splitting f).injective
lemma right_inverse_range_splitting {f : α → β} (h : injective f) :
right_inverse (range_factorization f) (range_splitting f) :=
(left_inverse_range_splitting f).right_inverse_of_injective $
λ x y hxy, h $ subtype.ext_iff.1 hxy
lemma preimage_range_splitting {f : α → β} (hf : injective f) :
preimage (range_splitting f) = image (range_factorization f) :=
(image_eq_preimage_of_inverse (right_inverse_range_splitting hf)
(left_inverse_range_splitting f)).symm
lemma is_compl_range_some_none (α : Type*) :
is_compl (range (some : α → option α)) {none} :=
is_compl.of_le
(λ x ⟨⟨a, ha⟩, (hn : x = none)⟩, option.some_ne_none _ (ha.trans hn))
(λ x hx, option.cases_on x (or.inr rfl) (λ x, or.inl $ mem_range_self _))
@[simp] lemma compl_range_some (α : Type*) :
(range (some : α → option α))ᶜ = {none} :=
(is_compl_range_some_none α).compl_eq
@[simp] lemma range_some_inter_none (α : Type*) : range (some : α → option α) ∩ {none} = ∅ :=
(is_compl_range_some_none α).inf_eq_bot
@[simp] lemma range_some_union_none (α : Type*) : range (some : α → option α) ∪ {none} = univ :=
(is_compl_range_some_none α).sup_eq_top
@[simp] lemma insert_none_range_some (α : Type*) :
insert none (range (some : α → option α)) = univ :=
(is_compl_range_some_none α).symm.sup_eq_top
end range
section subsingleton
variables {s : set α}
/-- The image of a subsingleton is a subsingleton. -/
lemma subsingleton.image (hs : s.subsingleton) (f : α → β) : (f '' s).subsingleton :=
λ _ ⟨x, hx, Hx⟩ _ ⟨y, hy, Hy⟩, Hx ▸ Hy ▸ congr_arg f (hs hx hy)
/-- The preimage of a subsingleton under an injective map is a subsingleton. -/
theorem subsingleton.preimage {s : set β} (hs : s.subsingleton) {f : α → β}
(hf : function.injective f) : (f ⁻¹' s).subsingleton := λ a ha b hb, hf $ hs ha hb
/-- If the image of a set under an injective map is a subsingleton, the set is a subsingleton. -/
theorem subsingleton_of_image {α β : Type*} {f : α → β} (hf : function.injective f)
(s : set α) (hs : (f '' s).subsingleton) : s.subsingleton :=
(hs.preimage hf).anti $ subset_preimage_image _ _
/-- If the preimage of a set under an surjective map is a subsingleton,
the set is a subsingleton. -/
theorem subsingleton_of_preimage {α β : Type*} {f : α → β} (hf : function.surjective f)
(s : set β) (hs : (f ⁻¹' s).subsingleton) : s.subsingleton :=
λ fx hx fy hy, by { rcases ⟨hf fx, hf fy⟩ with ⟨⟨x, rfl⟩, ⟨y, rfl⟩⟩, exact congr_arg f (hs hx hy) }
lemma subsingleton_range {α : Sort*} [subsingleton α] (f : α → β) : (range f).subsingleton :=
forall_range_iff.2 $ λ x, forall_range_iff.2 $ λ y, congr_arg f (subsingleton.elim x y)
/-- The preimage of a nontrivial set under a surjective map is nontrivial. -/
theorem nontrivial.preimage {s : set β} (hs : s.nontrivial) {f : α → β}
(hf : function.surjective f) : (f ⁻¹' s).nontrivial :=
begin
rcases hs with ⟨fx, hx, fy, hy, hxy⟩,
rcases ⟨hf fx, hf fy⟩ with ⟨⟨x, rfl⟩, ⟨y, rfl⟩⟩,
exact ⟨x, hx, y, hy, mt (congr_arg f) hxy⟩
end
/-- The image of a nontrivial set under an injective map is nontrivial. -/
theorem nontrivial.image (hs : s.nontrivial)
{f : α → β} (hf : function.injective f) : (f '' s).nontrivial :=
let ⟨x, hx, y, hy, hxy⟩ := hs in ⟨f x, mem_image_of_mem f hx, f y, mem_image_of_mem f hy, hf.ne hxy⟩
/-- If the image of a set is nontrivial, the set is nontrivial. -/
lemma nontrivial_of_image (f : α → β) (s : set α) (hs : (f '' s).nontrivial) : s.nontrivial :=
let ⟨_, ⟨x, hx, rfl⟩, _, ⟨y, hy, rfl⟩, hxy⟩ := hs in ⟨x, hx, y, hy, mt (congr_arg f) hxy⟩
/-- If the preimage of a set under an injective map is nontrivial, the set is nontrivial. -/
lemma nontrivial_of_preimage {f : α → β} (hf : function.injective f) (s : set β)
(hs : (f ⁻¹' s).nontrivial) : s.nontrivial :=
(hs.image hf).mono $ image_preimage_subset _ _
end subsingleton
end set
namespace function
variables {ι : Sort*} {α : Type*} {β : Type*} {f : α → β}
open set
lemma surjective.preimage_injective (hf : surjective f) : injective (preimage f) :=
assume s t, (preimage_eq_preimage hf).1
lemma injective.preimage_image (hf : injective f) (s : set α) : f ⁻¹' (f '' s) = s :=
preimage_image_eq s hf
lemma injective.preimage_surjective (hf : injective f) : surjective (preimage f) :=
by { intro s, use f '' s, rw hf.preimage_image }
lemma injective.subsingleton_image_iff (hf : injective f) {s : set α} :
(f '' s).subsingleton ↔ s.subsingleton :=
⟨subsingleton_of_image hf s, λ h, h.image f⟩
lemma surjective.image_preimage (hf : surjective f) (s : set β) : f '' (f ⁻¹' s) = s :=
image_preimage_eq s hf
lemma surjective.image_surjective (hf : surjective f) : surjective (image f) :=
by { intro s, use f ⁻¹' s, rw hf.image_preimage }
lemma surjective.nonempty_preimage (hf : surjective f) {s : set β} :
(f ⁻¹' s).nonempty ↔ s.nonempty :=
by rw [← nonempty_image_iff, hf.image_preimage]
lemma injective.image_injective (hf : injective f) : injective (image f) :=
by { intros s t h, rw [←preimage_image_eq s hf, ←preimage_image_eq t hf, h] }
lemma surjective.preimage_subset_preimage_iff {s t : set β} (hf : surjective f) :
f ⁻¹' s ⊆ f ⁻¹' t ↔ s ⊆ t :=
by { apply preimage_subset_preimage_iff, rw [hf.range_eq], apply subset_univ }
lemma surjective.range_comp {ι' : Sort*} {f : ι → ι'} (hf : surjective f) (g : ι' → α) :
range (g ∘ f) = range g :=
ext $ λ y, (@surjective.exists _ _ _ hf (λ x, g x = y)).symm
lemma injective.mem_range_iff_exists_unique (hf : injective f) {b : β} :
b ∈ range f ↔ ∃! a, f a = b :=
⟨λ ⟨a, h⟩, ⟨a, h, λ a' ha, hf (ha.trans h.symm)⟩, exists_unique.exists⟩
lemma injective.exists_unique_of_mem_range (hf : injective f) {b : β} (hb : b ∈ range f) :
∃! a, f a = b :=
hf.mem_range_iff_exists_unique.mp hb
theorem injective.compl_image_eq (hf : injective f) (s : set α) :
(f '' s)ᶜ = f '' sᶜ ∪ (range f)ᶜ :=
begin
ext y,
rcases em (y ∈ range f) with ⟨x, rfl⟩|hx,
{ simp [hf.eq_iff] },
{ rw [mem_range, not_exists] at hx,
simp [hx] }
end
lemma left_inverse.image_image {g : β → α} (h : left_inverse g f) (s : set α) :
g '' (f '' s) = s :=
by rw [← image_comp, h.comp_eq_id, image_id]
lemma left_inverse.preimage_preimage {g : β → α} (h : left_inverse g f) (s : set α) :
f ⁻¹' (g ⁻¹' s) = s :=
by rw [← preimage_comp, h.comp_eq_id, preimage_id]
end function
/-! ### Image and preimage on subtypes -/
namespace subtype
open set
variable {α : Type*}
lemma coe_image {p : α → Prop} {s : set (subtype p)} :
coe '' s = {x | ∃h : p x, (⟨x, h⟩ : subtype p) ∈ s} :=
set.ext $ assume a,
⟨assume ⟨⟨a', ha'⟩, in_s, h_eq⟩, h_eq ▸ ⟨ha', in_s⟩,
assume ⟨ha, in_s⟩, ⟨⟨a, ha⟩, in_s, rfl⟩⟩
@[simp] lemma coe_image_of_subset {s t : set α} (h : t ⊆ s) : coe '' {x : ↥s | ↑x ∈ t} = t :=
begin
ext x,
rw set.mem_image,
exact ⟨λ ⟨x', hx', hx⟩, hx ▸ hx', λ hx, ⟨⟨x, h hx⟩, hx, rfl⟩⟩,
end
lemma range_coe {s : set α} :
range (coe : s → α) = s :=
by { rw ← set.image_univ, simp [-set.image_univ, coe_image] }
/-- A variant of `range_coe`. Try to use `range_coe` if possible.
This version is useful when defining a new type that is defined as the subtype of something.
In that case, the coercion doesn't fire anymore. -/
lemma range_val {s : set α} :
range (subtype.val : s → α) = s :=
range_coe
/-- We make this the simp lemma instead of `range_coe`. The reason is that if we write
for `s : set α` the function `coe : s → α`, then the inferred implicit arguments of `coe` are
`coe α (λ x, x ∈ s)`. -/
@[simp] lemma range_coe_subtype {p : α → Prop} :
range (coe : subtype p → α) = {x | p x} :=
range_coe
@[simp] lemma coe_preimage_self (s : set α) : (coe : s → α) ⁻¹' s = univ :=
by rw [← preimage_range (coe : s → α), range_coe]
lemma range_val_subtype {p : α → Prop} :
range (subtype.val : subtype p → α) = {x | p x} :=
range_coe
theorem coe_image_subset (s : set α) (t : set s) : coe '' t ⊆ s :=
λ x ⟨y, yt, yvaleq⟩, by rw ←yvaleq; exact y.property
theorem coe_image_univ (s : set α) : (coe : s → α) '' set.univ = s :=
image_univ.trans range_coe
@[simp] theorem image_preimage_coe (s t : set α) :
(coe : s → α) '' (coe ⁻¹' t) = t ∩ s :=
image_preimage_eq_inter_range.trans $ congr_arg _ range_coe
theorem image_preimage_val (s t : set α) :
(subtype.val : s → α) '' (subtype.val ⁻¹' t) = t ∩ s :=
image_preimage_coe s t
theorem preimage_coe_eq_preimage_coe_iff {s t u : set α} :
((coe : s → α) ⁻¹' t = coe ⁻¹' u) ↔ t ∩ s = u ∩ s :=
by rw [← image_preimage_coe, ← image_preimage_coe, coe_injective.image_injective.eq_iff]
@[simp] theorem preimage_coe_inter_self (s t : set α) :
(coe : s → α) ⁻¹' (t ∩ s) = coe ⁻¹' t :=
by rw [preimage_coe_eq_preimage_coe_iff, inter_assoc, inter_self]
theorem preimage_val_eq_preimage_val_iff (s t u : set α) :
((subtype.val : s → α) ⁻¹' t = subtype.val ⁻¹' u) ↔ (t ∩ s = u ∩ s) :=
preimage_coe_eq_preimage_coe_iff
lemma exists_set_subtype {t : set α} (p : set α → Prop) :
(∃(s : set t), p (coe '' s)) ↔ ∃(s : set α), s ⊆ t ∧ p s :=
begin
split,
{ rintro ⟨s, hs⟩, refine ⟨coe '' s, _, hs⟩,
convert image_subset_range _ _, rw [range_coe] },
rintro ⟨s, hs₁, hs₂⟩, refine ⟨coe ⁻¹' s, _⟩,
rw [image_preimage_eq_of_subset], exact hs₂, rw [range_coe], exact hs₁
end
lemma preimage_coe_nonempty {s t : set α} : ((coe : s → α) ⁻¹' t).nonempty ↔ (s ∩ t).nonempty :=
by rw [inter_comm, ← image_preimage_coe, nonempty_image_iff]
lemma preimage_coe_eq_empty {s t : set α} : (coe : s → α) ⁻¹' t = ∅ ↔ s ∩ t = ∅ :=
by simp only [← not_nonempty_iff_eq_empty, preimage_coe_nonempty]
@[simp] lemma preimage_coe_compl (s : set α) : (coe : s → α) ⁻¹' sᶜ = ∅ :=
preimage_coe_eq_empty.2 (inter_compl_self s)
@[simp] lemma preimage_coe_compl' (s : set α) : (coe : sᶜ → α) ⁻¹' s = ∅ :=
preimage_coe_eq_empty.2 (compl_inter_self s)
end subtype
/-! ### Images and preimages on `option` -/
open set
namespace option
lemma injective_iff {α β} {f : option α → β} :
injective f ↔ injective (f ∘ some) ∧ f none ∉ range (f ∘ some) :=
begin
simp only [mem_range, not_exists, (∘)],
refine ⟨λ hf, ⟨hf.comp (option.some_injective _), λ x, hf.ne $ option.some_ne_none _⟩, _⟩,
rintro ⟨h_some, h_none⟩ (_|a) (_|b) hab,
exacts [rfl, (h_none _ hab.symm).elim, (h_none _ hab).elim, congr_arg some (h_some hab)]
end
lemma range_eq {α β} (f : option α → β) : range f = insert (f none) (range (f ∘ some)) :=
set.ext $ λ y, option.exists.trans $ eq_comm.or iff.rfl
end option
lemma with_bot.range_eq {α β} (f : with_bot α → β) :
range f = insert (f ⊥) (range (f ∘ coe : α → β)) :=
option.range_eq f
lemma with_top.range_eq {α β} (f : with_top α → β) :
range f = insert (f ⊤) (range (f ∘ coe : α → β)) :=
option.range_eq f
namespace set
open function
/-! ### Injectivity and surjectivity lemmas for image and preimage -/
section image_preimage
variables {α : Type u} {β : Type v} {f : α → β}
@[simp]
lemma preimage_injective : injective (preimage f) ↔ surjective f :=
begin
refine ⟨λ h y, _, surjective.preimage_injective⟩,
obtain ⟨x, hx⟩ : (f ⁻¹' {y}).nonempty,
{ rw [h.nonempty_apply_iff preimage_empty], apply singleton_nonempty },
exact ⟨x, hx⟩
end
@[simp]
lemma preimage_surjective : surjective (preimage f) ↔ injective f :=
begin
refine ⟨λ h x x' hx, _, injective.preimage_surjective⟩,
cases h {x} with s hs, have := mem_singleton x,
rwa [← hs, mem_preimage, hx, ← mem_preimage, hs, mem_singleton_iff, eq_comm] at this
end
@[simp] lemma image_surjective : surjective (image f) ↔ surjective f :=
begin
refine ⟨λ h y, _, surjective.image_surjective⟩,
cases h {y} with s hs,
have := mem_singleton y, rw [← hs] at this, rcases this with ⟨x, h1x, h2x⟩,
exact ⟨x, h2x⟩
end
@[simp] lemma image_injective : injective (image f) ↔ injective f :=
begin
refine ⟨λ h x x' hx, _, injective.image_injective⟩,
rw [← singleton_eq_singleton_iff], apply h,
rw [image_singleton, image_singleton, hx]
end
lemma preimage_eq_iff_eq_image {f : α → β} (hf : bijective f) {s t} :
f ⁻¹' s = t ↔ s = f '' t :=
by rw [← image_eq_image hf.1, hf.2.image_preimage]
lemma eq_preimage_iff_image_eq {f : α → β} (hf : bijective f) {s t} :
s = f ⁻¹' t ↔ f '' s = t :=
by rw [← image_eq_image hf.1, hf.2.image_preimage]
end image_preimage
end set
/-! ### Disjoint lemmas for image and preimage -/
section disjoint
variables {α β γ : Type*} {f : α → β} {s t : set α}
lemma disjoint.preimage (f : α → β) {s t : set β} (h : disjoint s t) :
disjoint (f ⁻¹' s) (f ⁻¹' t) :=
disjoint_iff_inf_le.mpr $ λ x hx, h.le_bot hx
namespace set
theorem disjoint_image_image {f : β → α} {g : γ → α} {s : set β} {t : set γ}
(h : ∀ b ∈ s, ∀ c ∈ t, f b ≠ g c) : disjoint (f '' s) (g '' t) :=
disjoint_iff_inf_le.mpr $ by rintro a ⟨⟨b, hb, eq⟩, c, hc, rfl⟩; exact h b hb c hc eq
lemma disjoint_image_of_injective {f : α → β} (hf : injective f) {s t : set α}
(hd : disjoint s t) : disjoint (f '' s) (f '' t) :=
disjoint_image_image $ λ x hx y hy, hf.ne $ λ H, set.disjoint_iff.1 hd ⟨hx, H.symm ▸ hy⟩
lemma _root_.disjoint.of_image (h : disjoint (f '' s) (f '' t)) : disjoint s t :=
disjoint_iff_inf_le.mpr $
λ x hx, disjoint_left.1 h (mem_image_of_mem _ hx.1) (mem_image_of_mem _ hx.2)
lemma disjoint_image_iff (hf : injective f) : disjoint (f '' s) (f '' t) ↔ disjoint s t :=
⟨disjoint.of_image, disjoint_image_of_injective hf⟩
lemma _root_.disjoint.of_preimage (hf : surjective f) {s t : set β}
(h : disjoint (f ⁻¹' s) (f ⁻¹' t)) :
disjoint s t :=
by rw [disjoint_iff_inter_eq_empty, ←image_preimage_eq (_ ∩ _) hf, preimage_inter, h.inter_eq,
image_empty]
lemma disjoint_preimage_iff (hf : surjective f) {s t : set β} :
disjoint (f ⁻¹' s) (f ⁻¹' t) ↔ disjoint s t :=
⟨disjoint.of_preimage hf, disjoint.preimage _⟩
lemma preimage_eq_empty {f : α → β} {s : set β} (h : disjoint s (range f)) :
f ⁻¹' s = ∅ :=
by simpa using h.preimage f
lemma preimage_eq_empty_iff {s : set β} : f ⁻¹' s = ∅ ↔ disjoint s (range f) :=
⟨λ h, begin
simp only [eq_empty_iff_forall_not_mem, disjoint_iff_inter_eq_empty, not_exists,
mem_inter_iff, not_and, mem_range, mem_preimage] at h ⊢,
assume y hy x hx,
rw ← hx at hy,
exact h x hy,
end, preimage_eq_empty⟩
end set
end disjoint
|
17b1dc566802d0cfb814384d556ef317a21616ff | 6e9cd8d58e550c481a3b45806bd34a3514c6b3e0 | /src/data/equiv/ring.lean | 43d7bb3a14f0f8c4348dfd0c0fea18b439aca246 | [
"Apache-2.0"
] | permissive | sflicht/mathlib | 220fd16e463928110e7b0a50bbed7b731979407f | 1b2048d7195314a7e34e06770948ee00f0ac3545 | refs/heads/master | 1,665,934,056,043 | 1,591,373,803,000 | 1,591,373,803,000 | 269,815,267 | 0 | 0 | Apache-2.0 | 1,591,402,068,000 | 1,591,402,067,000 | null | UTF-8 | Lean | false | false | 10,341 | lean | /-
Copyright (c) 2018 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Callum Sutton, Yury Kudryashov
-/
import data.equiv.mul_add
import algebra.field
import algebra.opposites
import deprecated.ring
/-!
# (Semi)ring equivs
In this file we define extension of `equiv` called `ring_equiv`, which is a datatype representing an
isomorphism of `semiring`s, `ring`s, `division_ring`s, or `field`s. We also introduce the
corresponding group of automorphisms `ring_aut`.
## Notations
The extended equiv have coercions to functions, and the coercion is the canonical notation when
treating the isomorphism as maps.
## Implementation notes
The fields for `ring_equiv` now avoid the unbundled `is_mul_hom` and `is_add_hom`, as these are
deprecated.
Definition of multiplication in the groups of automorphisms agrees with function composition,
multiplication in `equiv.perm`, and multiplication in `category_theory.End`, not with
`category_theory.comp`.
## Tags
equiv, mul_equiv, add_equiv, ring_equiv, mul_aut, add_aut, ring_aut
-/
variables {R : Type*} {S : Type*} {S' : Type*}
set_option old_structure_cmd true
/- (semi)ring equivalence. -/
structure ring_equiv (R S : Type*) [has_mul R] [has_add R] [has_mul S] [has_add S]
extends R ≃ S, R ≃* S, R ≃+ S
infix ` ≃+* `:25 := ring_equiv
namespace ring_equiv
section basic
variables [has_mul R] [has_add R] [has_mul S] [has_add S] [has_mul S'] [has_add S']
instance : has_coe_to_fun (R ≃+* S) := ⟨_, ring_equiv.to_fun⟩
@[simp]
lemma to_fun_eq_coe (f : R ≃+* S) : f.to_fun = f := rfl
instance has_coe_to_mul_equiv : has_coe (R ≃+* S) (R ≃* S) := ⟨ring_equiv.to_mul_equiv⟩
instance has_coe_to_add_equiv : has_coe (R ≃+* S) (R ≃+ S) := ⟨ring_equiv.to_add_equiv⟩
@[norm_cast] lemma coe_mul_equiv (f : R ≃+* S) (a : R) :
(f : R ≃* S) a = f a := rfl
@[norm_cast] lemma coe_add_equiv (f : R ≃+* S) (a : R) :
(f : R ≃+ S) a = f a := rfl
variable (R)
/-- The identity map is a ring isomorphism. -/
@[refl] protected def refl : R ≃+* R := { .. mul_equiv.refl R, .. add_equiv.refl R }
variables {R}
/-- The inverse of a ring isomorphism is a ring isomorphism. -/
@[symm] protected def symm (e : R ≃+* S) : S ≃+* R :=
{ .. e.to_mul_equiv.symm, .. e.to_add_equiv.symm }
/-- Transitivity of `ring_equiv`. -/
@[trans] protected def trans (e₁ : R ≃+* S) (e₂ : S ≃+* S') : R ≃+* S' :=
{ .. (e₁.to_mul_equiv.trans e₂.to_mul_equiv), .. (e₁.to_add_equiv.trans e₂.to_add_equiv) }
protected lemma bijective (e : R ≃+* S) : function.bijective e := e.to_equiv.bijective
protected lemma injective (e : R ≃+* S) : function.injective e := e.to_equiv.injective
protected lemma surjective (e : R ≃+* S) : function.surjective e := e.to_equiv.surjective
@[simp] lemma apply_symm_apply (e : R ≃+* S) : ∀ x, e (e.symm x) = x := e.to_equiv.apply_symm_apply
@[simp] lemma symm_apply_apply (e : R ≃+* S) : ∀ x, e.symm (e x) = x := e.to_equiv.symm_apply_apply
lemma image_eq_preimage (e : R ≃+* S) (s : set R) : e '' s = e.symm ⁻¹' s :=
e.to_equiv.image_eq_preimage s
end basic
section comm_semiring
open opposite
variables (R) [comm_semiring R]
/-- A commutative ring is isomorphic to its opposite. -/
def to_opposite : R ≃+* Rᵒᵖ :=
{ map_add' := λ x y, rfl,
map_mul' := λ x y, mul_comm (op y) (op x),
..equiv_to_opposite }
@[simp]
lemma to_opposite_apply (r : R) : to_opposite R r = op r := rfl
@[simp]
lemma to_opposite_symm_apply (r : Rᵒᵖ) : (to_opposite R).symm r = unop r := rfl
end comm_semiring
section
variables [semiring R] [semiring S] (f : R ≃+* S) (x y : R)
/-- A ring isomorphism preserves multiplication. -/
@[simp] lemma map_mul : f (x * y) = f x * f y := f.map_mul' x y
/-- A ring isomorphism sends one to one. -/
@[simp] lemma map_one : f 1 = 1 := (f : R ≃* S).map_one
/-- A ring isomorphism preserves addition. -/
@[simp] lemma map_add : f (x + y) = f x + f y := f.map_add' x y
/-- A ring isomorphism sends zero to zero. -/
@[simp] lemma map_zero : f 0 = 0 := (f : R ≃+ S).map_zero
variable {x}
@[simp] lemma map_eq_one_iff : f x = 1 ↔ x = 1 := (f : R ≃* S).map_eq_one_iff
@[simp] lemma map_eq_zero_iff : f x = 0 ↔ x = 0 := (f : R ≃+ S).map_eq_zero_iff
lemma map_ne_one_iff : f x ≠ 1 ↔ x ≠ 1 := (f : R ≃* S).map_ne_one_iff
lemma map_ne_zero_iff : f x ≠ 0 ↔ x ≠ 0 := (f : R ≃+ S).map_ne_zero_iff
end
section
variables [ring R] [ring S] (f : R ≃+* S) (x y : R)
@[simp] lemma map_neg : f (-x) = -f x := (f : R ≃+ S).map_neg x
@[simp] lemma map_sub : f (x - y) = f x - f y := (f : R ≃+ S).map_sub x y
@[simp] lemma map_neg_one : f (-1) = -1 := f.map_one ▸ f.map_neg 1
end
section semiring_hom
variables [semiring R] [semiring S]
/-- Reinterpret a ring equivalence as a ring homomorphism. -/
def to_ring_hom (e : R ≃+* S) : R →+* S :=
{ .. e.to_mul_equiv.to_monoid_hom, .. e.to_add_equiv.to_add_monoid_hom }
/-- Reinterpret a ring equivalence as a monoid homomorphism. -/
abbreviation to_monoid_hom (e : R ≃+* S) : R →* S := e.to_ring_hom.to_monoid_hom
/-- Reinterpret a ring equivalence as an `add_monoid` homomorphism. -/
abbreviation to_add_monoid_hom (e : R ≃+* S) : R →+ S := e.to_ring_hom.to_add_monoid_hom
/-- Interpret an equivalence `f : R ≃ S` as a ring equivalence `R ≃+* S`. -/
def of (e : R ≃ S) [is_semiring_hom e] : R ≃+* S :=
{ .. e, .. monoid_hom.of e, .. add_monoid_hom.of e }
instance (e : R ≃+* S) : is_semiring_hom e := e.to_ring_hom.is_semiring_hom
@[simp]
lemma to_ring_hom_apply_symm_to_ring_hom_apply {R S} [semiring R] [semiring S] (e : R ≃+* S) :
∀ (y : S), e.to_ring_hom (e.symm.to_ring_hom y) = y :=
e.to_equiv.apply_symm_apply
@[simp]
lemma symm_to_ring_hom_apply_to_ring_hom_apply {R S} [semiring R] [semiring S] (e : R ≃+* S) :
∀ (x : R), e.symm.to_ring_hom (e.to_ring_hom x) = x :=
equiv.symm_apply_apply (e.to_equiv)
end semiring_hom
end ring_equiv
namespace mul_equiv
/-- Gives an `is_semiring_hom` instance from a `mul_equiv` of semirings that preserves addition. -/
protected lemma to_semiring_hom {R : Type*} {S : Type*} [semiring R] [semiring S]
(h : R ≃* S) (H : ∀ x y : R, h (x + y) = h x + h y) : is_semiring_hom h :=
⟨add_equiv.map_zero $ add_equiv.mk' h.to_equiv H, h.map_one, H, h.5⟩
/-- Gives a `ring_equiv` from a `mul_equiv` preserving addition.-/
def to_ring_equiv {R : Type*} {S : Type*} [has_add R] [has_add S] [has_mul R] [has_mul S]
(h : R ≃* S) (H : ∀ x y : R, h (x + y) = h x + h y) : R ≃+* S :=
{..h.to_equiv, ..h, ..add_equiv.mk' h.to_equiv H }
end mul_equiv
namespace add_equiv
/-- Gives an `is_semiring_hom` instance from a `mul_equiv` of semirings that preserves addition. -/
protected lemma to_semiring_hom {R : Type*} {S : Type*} [semiring R] [semiring S]
(h : R ≃+ S) (H : ∀ x y : R, h (x * y) = h x * h y) : is_semiring_hom h :=
⟨h.map_zero, mul_equiv.map_one $ mul_equiv.mk' h.to_equiv H, h.5, H⟩
end add_equiv
namespace ring_equiv
section ring_hom
variables [ring R] [ring S]
/-- Interpret an equivalence `f : R ≃ S` as a ring equivalence `R ≃+* S`. -/
def of' (e : R ≃ S) [is_ring_hom e] : R ≃+* S :=
{ .. e, .. monoid_hom.of e, .. add_monoid_hom.of e }
instance (e : R ≃+* S) : is_ring_hom e := e.to_ring_hom.is_ring_hom
end ring_hom
/-- Two ring isomorphisms agree if they are defined by the
same underlying function. -/
@[ext] lemma ext {R S : Type*} [has_mul R] [has_add R] [has_mul S] [has_add S]
{f g : R ≃+* S} (h : ∀ x, f x = g x) : f = g :=
begin
have h₁ : f.to_equiv = g.to_equiv := equiv.ext h,
cases f, cases g, congr,
{ exact (funext h) },
{ exact congr_arg equiv.inv_fun h₁ }
end
/-- If two rings are isomorphic, and the second is an integral domain, then so is the first. -/
protected lemma is_integral_domain {A : Type*} (B : Type*) [ring A] [ring B]
(hB : is_integral_domain B) (e : A ≃+* B) : is_integral_domain A :=
{ mul_comm := λ x y, have e.symm (e x * e y) = e.symm (e y * e x), by rw hB.mul_comm, by simpa,
eq_zero_or_eq_zero_of_mul_eq_zero := λ x y hxy,
have e x * e y = 0, by rw [← e.map_mul, hxy, e.map_zero],
(hB.eq_zero_or_eq_zero_of_mul_eq_zero _ _ this).imp (λ hx, by simpa using congr_arg e.symm hx)
(λ hy, by simpa using congr_arg e.symm hy),
zero_ne_one := λ H, hB.zero_ne_one $ by rw [← e.map_zero, ← e.map_one, H] }
/-- If two rings are isomorphic, and the second is an integral domain, then so is the first. -/
protected def integral_domain {A : Type*} (B : Type*) [ring A] [integral_domain B]
(e : A ≃+* B) : integral_domain A :=
{ .. (‹_› : ring A), .. e.is_integral_domain B (integral_domain.to_is_integral_domain B) }
end ring_equiv
/-- The group of ring automorphisms. -/
@[reducible] def ring_aut (R : Type*) [has_mul R] [has_add R] := ring_equiv R R
namespace ring_aut
variables (R) [has_mul R] [has_add R]
/--
The group operation on automorphisms of a ring is defined by
λ g h, ring_equiv.trans h g.
This means that multiplication agrees with composition, (g*h)(x) = g (h x) .
-/
instance : group (ring_aut R) :=
by refine_struct
{ mul := λ g h, ring_equiv.trans h g,
one := ring_equiv.refl R,
inv := ring_equiv.symm };
intros; ext; try { refl }; apply equiv.left_inv
instance : inhabited (ring_aut R) := ⟨1⟩
/-- Monoid homomorphism from ring automorphisms to additive automorphisms. -/
def to_add_aut : ring_aut R →* add_aut R :=
by refine_struct { to_fun := ring_equiv.to_add_equiv }; intros; refl
/-- Monoid homomorphism from ring automorphisms to multiplicative automorphisms. -/
def to_mul_aut : ring_aut R →* mul_aut R :=
by refine_struct { to_fun := ring_equiv.to_mul_equiv }; intros; refl
/-- Monoid homomorphism from ring automorphisms to permutations. -/
def to_perm : ring_aut R →* equiv.perm R :=
by refine_struct { to_fun := ring_equiv.to_equiv }; intros; refl
end ring_aut
namespace equiv
variables (K : Type*) [division_ring K]
def units_equiv_ne_zero : units K ≃ {a : K | a ≠ 0} :=
⟨λ a, ⟨a.1, a.coe_ne_zero⟩, λ a, units.mk0 _ a.2, λ ⟨_, _, _, _⟩, units.ext rfl, λ ⟨_, _⟩, rfl⟩
variable {K}
@[simp]
lemma coe_units_equiv_ne_zero (a : units K) :
((units_equiv_ne_zero K a) : K) = a := rfl
end equiv
|
2f69ad8ccf2f44533a287c638d9436d6c86d7a63 | 432d948a4d3d242fdfb44b81c9e1b1baacd58617 | /src/data/multiset/basic.lean | 4e735e8de150e420944a13d94a01eebb2f85015f | [
"Apache-2.0"
] | permissive | JLimperg/aesop3 | 306cc6570c556568897ed2e508c8869667252e8a | a4a116f650cc7403428e72bd2e2c4cda300fe03f | refs/heads/master | 1,682,884,916,368 | 1,620,320,033,000 | 1,620,320,033,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 96,107 | lean | /-
Copyright (c) 2015 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro
-/
import data.list.perm
import algebra.group_power
/-!
# Multisets
These are implemented as the quotient of a list by permutations.
## Notation
We define the global infix notation `::ₘ` for `multiset.cons`.
-/
open list subtype nat
variables {α : Type*} {β : Type*} {γ : Type*}
/-- `multiset α` is the quotient of `list α` by list permutation. The result
is a type of finite sets with duplicates allowed. -/
def {u} multiset (α : Type u) : Type u :=
quotient (list.is_setoid α)
namespace multiset
instance : has_coe (list α) (multiset α) := ⟨quot.mk _⟩
@[simp] theorem quot_mk_to_coe (l : list α) : @eq (multiset α) ⟦l⟧ l := rfl
@[simp] theorem quot_mk_to_coe' (l : list α) : @eq (multiset α) (quot.mk (≈) l) l := rfl
@[simp] theorem quot_mk_to_coe'' (l : list α) : @eq (multiset α) (quot.mk setoid.r l) l := rfl
@[simp] theorem coe_eq_coe {l₁ l₂ : list α} : (l₁ : multiset α) = l₂ ↔ l₁ ~ l₂ := quotient.eq
instance has_decidable_eq [decidable_eq α] : decidable_eq (multiset α)
| s₁ s₂ := quotient.rec_on_subsingleton₂ s₁ s₂ $ λ l₁ l₂,
decidable_of_iff' _ quotient.eq
/-- defines a size for a multiset by referring to the size of the underlying list -/
protected def sizeof [has_sizeof α] (s : multiset α) : ℕ :=
quot.lift_on s sizeof $ λ l₁ l₂, perm.sizeof_eq_sizeof
instance has_sizeof [has_sizeof α] : has_sizeof (multiset α) := ⟨multiset.sizeof⟩
/-! ### Empty multiset -/
/-- `0 : multiset α` is the empty set -/
protected def zero : multiset α := @nil α
instance : has_zero (multiset α) := ⟨multiset.zero⟩
instance : has_emptyc (multiset α) := ⟨0⟩
instance inhabited_multiset : inhabited (multiset α) := ⟨0⟩
@[simp] theorem coe_nil_eq_zero : (@nil α : multiset α) = 0 := rfl
@[simp] theorem empty_eq_zero : (∅ : multiset α) = 0 := rfl
theorem coe_eq_zero (l : list α) : (l : multiset α) = 0 ↔ l = [] :=
iff.trans coe_eq_coe perm_nil
/-! ### `multiset.cons` -/
/-- `cons a s` is the multiset which contains `s` plus one more
instance of `a`. -/
def cons (a : α) (s : multiset α) : multiset α :=
quot.lift_on s (λ l, (a :: l : multiset α))
(λ l₁ l₂ p, quot.sound (p.cons a))
infixr ` ::ₘ `:67 := multiset.cons
instance : has_insert α (multiset α) := ⟨cons⟩
@[simp] theorem insert_eq_cons (a : α) (s : multiset α) :
insert a s = a ::ₘ s := rfl
@[simp] theorem cons_coe (a : α) (l : list α) :
(a ::ₘ l : multiset α) = (a::l : list α) := rfl
theorem singleton_coe (a : α) : (a ::ₘ 0 : multiset α) = ([a] : list α) := rfl
@[simp] theorem cons_inj_left {a b : α} (s : multiset α) :
a ::ₘ s = b ::ₘ s ↔ a = b :=
⟨quot.induction_on s $ λ l e,
have [a] ++ l ~ [b] ++ l, from quotient.exact e,
singleton_perm_singleton.1 $ (perm_append_right_iff _).1 this, congr_arg _⟩
@[simp] theorem cons_inj_right (a : α) : ∀{s t : multiset α}, a ::ₘ s = a ::ₘ t ↔ s = t :=
by rintros ⟨l₁⟩ ⟨l₂⟩; simp
@[recursor 5] protected theorem induction {p : multiset α → Prop}
(h₁ : p 0) (h₂ : ∀ ⦃a : α⦄ {s : multiset α}, p s → p (a ::ₘ s)) : ∀s, p s :=
by rintros ⟨l⟩; induction l with _ _ ih; [exact h₁, exact h₂ ih]
@[elab_as_eliminator] protected theorem induction_on {p : multiset α → Prop}
(s : multiset α) (h₁ : p 0) (h₂ : ∀ ⦃a : α⦄ {s : multiset α}, p s → p (a ::ₘ s)) : p s :=
multiset.induction h₁ h₂ s
theorem cons_swap (a b : α) (s : multiset α) : a ::ₘ b ::ₘ s = b ::ₘ a ::ₘ s :=
quot.induction_on s $ λ l, quotient.sound $ perm.swap _ _ _
section rec
variables {C : multiset α → Sort*}
/-- Dependent recursor on multisets.
TODO: should be @[recursor 6], but then the definition of `multiset.pi` fails with a stack
overflow in `whnf`.
-/
protected def rec
(C_0 : C 0)
(C_cons : Πa m, C m → C (a ::ₘ m))
(C_cons_heq : ∀ a a' m b, C_cons a (a' ::ₘ m) (C_cons a' m b) ==
C_cons a' (a ::ₘ m) (C_cons a m b))
(m : multiset α) : C m :=
quotient.hrec_on m (@list.rec α (λl, C ⟦l⟧) C_0 (λa l b, C_cons a ⟦l⟧ b)) $
assume l l' h,
h.rec_heq
(assume a l l' b b' hl, have ⟦l⟧ = ⟦l'⟧, from quot.sound hl, by cc)
(assume a a' l, C_cons_heq a a' ⟦l⟧)
@[elab_as_eliminator]
protected def rec_on (m : multiset α)
(C_0 : C 0)
(C_cons : Πa m, C m → C (a ::ₘ m))
(C_cons_heq : ∀a a' m b, C_cons a (a' ::ₘ m) (C_cons a' m b) ==
C_cons a' (a ::ₘ m) (C_cons a m b)) :
C m :=
multiset.rec C_0 C_cons C_cons_heq m
variables {C_0 : C 0} {C_cons : Πa m, C m → C (a ::ₘ m)}
{C_cons_heq : ∀a a' m b, C_cons a (a' ::ₘ m) (C_cons a' m b) ==
C_cons a' (a ::ₘ m) (C_cons a m b)}
@[simp] lemma rec_on_0 : @multiset.rec_on α C (0:multiset α) C_0 C_cons C_cons_heq = C_0 :=
rfl
@[simp] lemma rec_on_cons (a : α) (m : multiset α) :
(a ::ₘ m).rec_on C_0 C_cons C_cons_heq = C_cons a m (m.rec_on C_0 C_cons C_cons_heq) :=
quotient.induction_on m $ assume l, rfl
end rec
section mem
/-- `a ∈ s` means that `a` has nonzero multiplicity in `s`. -/
def mem (a : α) (s : multiset α) : Prop :=
quot.lift_on s (λ l, a ∈ l) (λ l₁ l₂ (e : l₁ ~ l₂), propext $ e.mem_iff)
instance : has_mem α (multiset α) := ⟨mem⟩
@[simp] lemma mem_coe {a : α} {l : list α} : a ∈ (l : multiset α) ↔ a ∈ l := iff.rfl
instance decidable_mem [decidable_eq α] (a : α) (s : multiset α) : decidable (a ∈ s) :=
quot.rec_on_subsingleton s $ list.decidable_mem a
@[simp] theorem mem_cons {a b : α} {s : multiset α} : a ∈ b ::ₘ s ↔ a = b ∨ a ∈ s :=
quot.induction_on s $ λ l, iff.rfl
lemma mem_cons_of_mem {a b : α} {s : multiset α} (h : a ∈ s) : a ∈ b ::ₘ s :=
mem_cons.2 $ or.inr h
@[simp] theorem mem_cons_self (a : α) (s : multiset α) : a ∈ a ::ₘ s :=
mem_cons.2 (or.inl rfl)
theorem forall_mem_cons {p : α → Prop} {a : α} {s : multiset α} :
(∀ x ∈ (a ::ₘ s), p x) ↔ p a ∧ ∀ x ∈ s, p x :=
quotient.induction_on' s $ λ L, list.forall_mem_cons
theorem exists_cons_of_mem {s : multiset α} {a : α} : a ∈ s → ∃ t, s = a ::ₘ t :=
quot.induction_on s $ λ l (h : a ∈ l),
let ⟨l₁, l₂, e⟩ := mem_split h in
e.symm ▸ ⟨(l₁++l₂ : list α), quot.sound perm_middle⟩
@[simp] theorem not_mem_zero (a : α) : a ∉ (0 : multiset α) := id
theorem eq_zero_of_forall_not_mem {s : multiset α} : (∀x, x ∉ s) → s = 0 :=
quot.induction_on s $ λ l H, by rw eq_nil_iff_forall_not_mem.mpr H; refl
theorem eq_zero_iff_forall_not_mem {s : multiset α} : s = 0 ↔ ∀ a, a ∉ s :=
⟨λ h, h.symm ▸ λ _, not_false, eq_zero_of_forall_not_mem⟩
theorem exists_mem_of_ne_zero {s : multiset α} : s ≠ 0 → ∃ a : α, a ∈ s :=
quot.induction_on s $ assume l hl,
match l, hl with
| [] := assume h, false.elim $ h rfl
| (a :: l) := assume _, ⟨a, by simp⟩
end
@[simp] lemma zero_ne_cons {a : α} {m : multiset α} : 0 ≠ a ::ₘ m :=
assume h, have a ∈ (0:multiset α), from h.symm ▸ mem_cons_self _ _, not_mem_zero _ this
@[simp] lemma cons_ne_zero {a : α} {m : multiset α} : a ::ₘ m ≠ 0 := zero_ne_cons.symm
lemma cons_eq_cons {a b : α} {as bs : multiset α} :
a ::ₘ as = b ::ₘ bs ↔ ((a = b ∧ as = bs) ∨ (a ≠ b ∧ ∃cs, as = b ::ₘ cs ∧ bs = a ::ₘ cs)) :=
begin
haveI : decidable_eq α := classical.dec_eq α,
split,
{ assume eq,
by_cases a = b,
{ subst h, simp * at * },
{ have : a ∈ b ::ₘ bs, from eq ▸ mem_cons_self _ _,
have : a ∈ bs, by simpa [h],
rcases exists_cons_of_mem this with ⟨cs, hcs⟩,
simp [h, hcs],
have : a ::ₘ as = b ::ₘ a ::ₘ cs, by simp [eq, hcs],
have : a ::ₘ as = a ::ₘ b ::ₘ cs, by rwa [cons_swap],
simpa using this } },
{ assume h,
rcases h with ⟨eq₁, eq₂⟩ | ⟨h, cs, eq₁, eq₂⟩,
{ simp * },
{ simp [*, cons_swap a b] } }
end
end mem
/-! ### `multiset.subset` -/
section subset
/-- `s ⊆ t` is the lift of the list subset relation. It means that any
element with nonzero multiplicity in `s` has nonzero multiplicity in `t`,
but it does not imply that the multiplicity of `a` in `s` is less or equal than in `t`;
see `s ≤ t` for this relation. -/
protected def subset (s t : multiset α) : Prop := ∀ ⦃a : α⦄, a ∈ s → a ∈ t
instance : has_subset (multiset α) := ⟨multiset.subset⟩
@[simp] theorem coe_subset {l₁ l₂ : list α} : (l₁ : multiset α) ⊆ l₂ ↔ l₁ ⊆ l₂ := iff.rfl
@[simp] theorem subset.refl (s : multiset α) : s ⊆ s := λ a h, h
theorem subset.trans {s t u : multiset α} : s ⊆ t → t ⊆ u → s ⊆ u :=
λ h₁ h₂ a m, h₂ (h₁ m)
theorem subset_iff {s t : multiset α} : s ⊆ t ↔ (∀⦃x⦄, x ∈ s → x ∈ t) := iff.rfl
theorem mem_of_subset {s t : multiset α} {a : α} (h : s ⊆ t) : a ∈ s → a ∈ t := @h _
@[simp] theorem zero_subset (s : multiset α) : 0 ⊆ s :=
λ a, (not_mem_nil a).elim
@[simp] theorem cons_subset {a : α} {s t : multiset α} : (a ::ₘ s) ⊆ t ↔ a ∈ t ∧ s ⊆ t :=
by simp [subset_iff, or_imp_distrib, forall_and_distrib]
theorem eq_zero_of_subset_zero {s : multiset α} (h : s ⊆ 0) : s = 0 :=
eq_zero_of_forall_not_mem h
theorem subset_zero {s : multiset α} : s ⊆ 0 ↔ s = 0 :=
⟨eq_zero_of_subset_zero, λ xeq, xeq.symm ▸ subset.refl 0⟩
lemma induction_on' {p : multiset α → Prop} (S : multiset α)
(h₁ : p ∅) (h₂ : ∀ {a s}, a ∈ S → s ⊆ S → p s → p (insert a s)) : p S :=
@multiset.induction_on α (λ T, T ⊆ S → p T) S (λ _, h₁) (λ a s hps hs,
let ⟨hS, sS⟩ := cons_subset.1 hs in h₂ hS sS (hps sS)) (subset.refl S)
end subset
section to_list
/-- Produces a list of the elements in the multiset using choice. -/
@[reducible] noncomputable def to_list {α : Type*} (s : multiset α) :=
classical.some (quotient.exists_rep s)
@[simp] lemma to_list_zero {α : Type*} : (multiset.to_list 0 : list α) = [] :=
(multiset.coe_eq_zero _).1 (classical.some_spec (quotient.exists_rep multiset.zero))
@[simp, norm_cast]
lemma coe_to_list {α : Type*} (s : multiset α) : (s.to_list : multiset α) = s :=
classical.some_spec (quotient.exists_rep _)
@[simp]
lemma mem_to_list {α : Type*} (a : α) (s : multiset α) : a ∈ s.to_list ↔ a ∈ s :=
by rw [←multiset.mem_coe, multiset.coe_to_list]
end to_list
/-! ### Partial order on `multiset`s -/
/-- `s ≤ t` means that `s` is a sublist of `t` (up to permutation).
Equivalently, `s ≤ t` means that `count a s ≤ count a t` for all `a`. -/
protected def le (s t : multiset α) : Prop :=
quotient.lift_on₂ s t (<+~) $ λ v₁ v₂ w₁ w₂ p₁ p₂,
propext (p₂.subperm_left.trans p₁.subperm_right)
instance : partial_order (multiset α) :=
{ le := multiset.le,
le_refl := by rintros ⟨l⟩; exact subperm.refl _,
le_trans := by rintros ⟨l₁⟩ ⟨l₂⟩ ⟨l₃⟩; exact @subperm.trans _ _ _ _,
le_antisymm := by rintros ⟨l₁⟩ ⟨l₂⟩ h₁ h₂; exact quot.sound (subperm.antisymm h₁ h₂) }
theorem subset_of_le {s t : multiset α} : s ≤ t → s ⊆ t :=
quotient.induction_on₂ s t $ λ l₁ l₂, subperm.subset
theorem mem_of_le {s t : multiset α} {a : α} (h : s ≤ t) : a ∈ s → a ∈ t :=
mem_of_subset (subset_of_le h)
@[simp] theorem coe_le {l₁ l₂ : list α} : (l₁ : multiset α) ≤ l₂ ↔ l₁ <+~ l₂ := iff.rfl
@[elab_as_eliminator] theorem le_induction_on {C : multiset α → multiset α → Prop}
{s t : multiset α} (h : s ≤ t)
(H : ∀ {l₁ l₂ : list α}, l₁ <+ l₂ → C l₁ l₂) : C s t :=
quotient.induction_on₂ s t (λ l₁ l₂ ⟨l, p, s⟩,
(show ⟦l⟧ = ⟦l₁⟧, from quot.sound p) ▸ H s) h
theorem zero_le (s : multiset α) : 0 ≤ s :=
quot.induction_on s $ λ l, (nil_sublist l).subperm
theorem le_zero {s : multiset α} : s ≤ 0 ↔ s = 0 :=
⟨λ h, le_antisymm h (zero_le _), le_of_eq⟩
theorem lt_cons_self (s : multiset α) (a : α) : s < a ::ₘ s :=
quot.induction_on s $ λ l,
suffices l <+~ a :: l ∧ (¬l ~ a :: l),
by simpa [lt_iff_le_and_ne],
⟨(sublist_cons _ _).subperm,
λ p, ne_of_lt (lt_succ_self (length l)) p.length_eq⟩
theorem le_cons_self (s : multiset α) (a : α) : s ≤ a ::ₘ s :=
le_of_lt $ lt_cons_self _ _
theorem cons_le_cons_iff (a : α) {s t : multiset α} : a ::ₘ s ≤ a ::ₘ t ↔ s ≤ t :=
quotient.induction_on₂ s t $ λ l₁ l₂, subperm_cons a
theorem cons_le_cons (a : α) {s t : multiset α} : s ≤ t → a ::ₘ s ≤ a ::ₘ t :=
(cons_le_cons_iff a).2
theorem le_cons_of_not_mem {a : α} {s t : multiset α} (m : a ∉ s) : s ≤ a ::ₘ t ↔ s ≤ t :=
begin
refine ⟨_, λ h, le_trans h $ le_cons_self _ _⟩,
suffices : ∀ {t'} (_ : s ≤ t') (_ : a ∈ t'), a ::ₘ s ≤ t',
{ exact λ h, (cons_le_cons_iff a).1 (this h (mem_cons_self _ _)) },
introv h, revert m, refine le_induction_on h _,
introv s m₁ m₂,
rcases mem_split m₂ with ⟨r₁, r₂, rfl⟩,
exact perm_middle.subperm_left.2 ((subperm_cons _).2 $
((sublist_or_mem_of_sublist s).resolve_right m₁).subperm)
end
/-! ### Additive monoid -/
/-- The sum of two multisets is the lift of the list append operation.
This adds the multiplicities of each element,
i.e. `count a (s + t) = count a s + count a t`. -/
protected def add (s₁ s₂ : multiset α) : multiset α :=
quotient.lift_on₂ s₁ s₂ (λ l₁ l₂, ((l₁ ++ l₂ : list α) : multiset α)) $
λ v₁ v₂ w₁ w₂ p₁ p₂, quot.sound $ p₁.append p₂
instance : has_add (multiset α) := ⟨multiset.add⟩
@[simp] theorem coe_add (s t : list α) : (s + t : multiset α) = (s ++ t : list α) := rfl
protected theorem add_comm (s t : multiset α) : s + t = t + s :=
quotient.induction_on₂ s t $ λ l₁ l₂, quot.sound perm_append_comm
protected theorem zero_add (s : multiset α) : 0 + s = s :=
quot.induction_on s $ λ l, rfl
theorem singleton_add (a : α) (s : multiset α) : ↑[a] + s = a ::ₘ s := rfl
protected theorem add_le_add_left (s) {t u : multiset α} : s + t ≤ s + u ↔ t ≤ u :=
quotient.induction_on₃ s t u $ λ l₁ l₂ l₃, subperm_append_left _
protected theorem add_left_cancel (s) {t u : multiset α} (h : s + t = s + u) : t = u :=
le_antisymm ((multiset.add_le_add_left _).1 (le_of_eq h))
((multiset.add_le_add_left _).1 (le_of_eq h.symm))
instance : ordered_cancel_add_comm_monoid (multiset α) :=
{ zero := 0,
add := (+),
add_comm := multiset.add_comm,
add_assoc := λ s₁ s₂ s₃, quotient.induction_on₃ s₁ s₂ s₃ $ λ l₁ l₂ l₃,
congr_arg coe $ append_assoc l₁ l₂ l₃,
zero_add := multiset.zero_add,
add_zero := λ s, by rw [multiset.add_comm, multiset.zero_add],
add_left_cancel := multiset.add_left_cancel,
add_le_add_left := λ s₁ s₂ h s₃, (multiset.add_le_add_left _).2 h,
le_of_add_le_add_left := λ s₁ s₂ s₃, (multiset.add_le_add_left _).1,
..@multiset.partial_order α }
theorem le_add_right (s t : multiset α) : s ≤ s + t :=
by simpa using add_le_add_left (zero_le t) s
theorem le_add_left (s t : multiset α) : s ≤ t + s :=
by simpa using add_le_add_right (zero_le t) s
theorem le_iff_exists_add {s t : multiset α} : s ≤ t ↔ ∃ u, t = s + u :=
⟨λ h, le_induction_on h $ λ l₁ l₂ s,
let ⟨l, p⟩ := s.exists_perm_append in ⟨l, quot.sound p⟩,
λ ⟨u, e⟩, e.symm ▸ le_add_right _ _⟩
instance : canonically_ordered_add_monoid (multiset α) :=
{ lt_of_add_lt_add_left := @lt_of_add_lt_add_left _ _,
le_iff_exists_add := @le_iff_exists_add _,
bot := 0,
bot_le := multiset.zero_le,
..multiset.ordered_cancel_add_comm_monoid }
@[simp] theorem cons_add (a : α) (s t : multiset α) : a ::ₘ s + t = a ::ₘ (s + t) :=
by rw [← singleton_add, ← singleton_add, add_assoc]
@[simp] theorem add_cons (a : α) (s t : multiset α) : s + a ::ₘ t = a ::ₘ (s + t) :=
by rw [add_comm, cons_add, add_comm]
@[simp] theorem mem_add {a : α} {s t : multiset α} : a ∈ s + t ↔ a ∈ s ∨ a ∈ t :=
quotient.induction_on₂ s t $ λ l₁ l₂, mem_append
/-! ### Cardinality -/
/-- The cardinality of a multiset is the sum of the multiplicities
of all its elements, or simply the length of the underlying list. -/
def card : multiset α →+ ℕ :=
{ to_fun := λ s, quot.lift_on s length $ λ l₁ l₂, perm.length_eq,
map_zero' := rfl,
map_add' := λ s t, quotient.induction_on₂ s t length_append }
@[simp] theorem coe_card (l : list α) : card (l : multiset α) = length l := rfl
@[simp] theorem card_zero : @card α 0 = 0 := rfl
theorem card_add (s t : multiset α) : card (s + t) = card s + card t :=
card.map_add s t
lemma card_nsmul (s : multiset α) (n : ℕ) :
(n • s).card = n * s.card :=
by rw [card.map_nsmul s n, nat.nsmul_eq_mul]
@[simp] theorem card_cons (a : α) (s : multiset α) : card (a ::ₘ s) = card s + 1 :=
quot.induction_on s $ λ l, rfl
@[simp] theorem card_singleton (a : α) : card (a ::ₘ 0) = 1 := by simp
theorem card_le_of_le {s t : multiset α} (h : s ≤ t) : card s ≤ card t :=
le_induction_on h $ λ l₁ l₂, length_le_of_sublist
theorem eq_of_le_of_card_le {s t : multiset α} (h : s ≤ t) : card t ≤ card s → s = t :=
le_induction_on h $ λ l₁ l₂ s h₂, congr_arg coe $ eq_of_sublist_of_length_le s h₂
theorem card_lt_of_lt {s t : multiset α} (h : s < t) : card s < card t :=
lt_of_not_ge $ λ h₂, ne_of_lt h $ eq_of_le_of_card_le (le_of_lt h) h₂
theorem lt_iff_cons_le {s t : multiset α} : s < t ↔ ∃ a, a ::ₘ s ≤ t :=
⟨quotient.induction_on₂ s t $ λ l₁ l₂ h,
subperm.exists_of_length_lt (le_of_lt h) (card_lt_of_lt h),
λ ⟨a, h⟩, lt_of_lt_of_le (lt_cons_self _ _) h⟩
@[simp] theorem card_eq_zero {s : multiset α} : card s = 0 ↔ s = 0 :=
⟨λ h, (eq_of_le_of_card_le (zero_le _) (le_of_eq h)).symm, λ e, by simp [e]⟩
theorem card_pos {s : multiset α} : 0 < card s ↔ s ≠ 0 :=
pos_iff_ne_zero.trans $ not_congr card_eq_zero
theorem card_pos_iff_exists_mem {s : multiset α} : 0 < card s ↔ ∃ a, a ∈ s :=
quot.induction_on s $ λ l, length_pos_iff_exists_mem
@[elab_as_eliminator] def strong_induction_on {p : multiset α → Sort*} :
∀ (s : multiset α), (∀ s, (∀t < s, p t) → p s) → p s
| s := λ ih, ih s $ λ t h,
have card t < card s, from card_lt_of_lt h,
strong_induction_on t ih
using_well_founded {rel_tac := λ _ _, `[exact ⟨_, measure_wf card⟩]}
theorem strong_induction_eq {p : multiset α → Sort*}
(s : multiset α) (H) : @strong_induction_on _ p s H =
H s (λ t h, @strong_induction_on _ p t H) :=
by rw [strong_induction_on]
@[elab_as_eliminator] lemma case_strong_induction_on {p : multiset α → Prop}
(s : multiset α) (h₀ : p 0) (h₁ : ∀ a s, (∀t ≤ s, p t) → p (a ::ₘ s)) : p s :=
multiset.strong_induction_on s $ assume s,
multiset.induction_on s (λ _, h₀) $ λ a s _ ih, h₁ _ _ $
λ t h, ih _ $ lt_of_le_of_lt h $ lt_cons_self _ _
/-! ### Singleton -/
instance : has_singleton α (multiset α) := ⟨λ a, a ::ₘ 0⟩
instance : is_lawful_singleton α (multiset α) := ⟨λ a, rfl⟩
@[simp] theorem singleton_eq_singleton (a : α) : singleton a = a ::ₘ 0 := rfl
@[simp] theorem mem_singleton {a b : α} : b ∈ a ::ₘ 0 ↔ b = a := by simp
theorem mem_singleton_self (a : α) : a ∈ (a ::ₘ 0 : multiset α) := mem_cons_self _ _
theorem singleton_inj {a b : α} : a ::ₘ 0 = b ::ₘ 0 ↔ a = b := cons_inj_left _
@[simp] theorem singleton_ne_zero (a : α) : a ::ₘ 0 ≠ 0 :=
ne_of_gt (lt_cons_self _ _)
@[simp] theorem singleton_le {a : α} {s : multiset α} : a ::ₘ 0 ≤ s ↔ a ∈ s :=
⟨λ h, mem_of_le h (mem_singleton_self _),
λ h, let ⟨t, e⟩ := exists_cons_of_mem h in e.symm ▸ cons_le_cons _ (zero_le _)⟩
theorem card_eq_one {s : multiset α} : card s = 1 ↔ ∃ a, s = a ::ₘ 0 :=
⟨quot.induction_on s $ λ l h,
(list.length_eq_one.1 h).imp $ λ a, congr_arg coe,
λ ⟨a, e⟩, e.symm ▸ rfl⟩
/-! ### `multiset.repeat` -/
/-- `repeat a n` is the multiset containing only `a` with multiplicity `n`. -/
def repeat (a : α) (n : ℕ) : multiset α := repeat a n
@[simp] lemma repeat_zero (a : α) : repeat a 0 = 0 := rfl
@[simp] lemma repeat_succ (a : α) (n) : repeat a (n+1) = a ::ₘ repeat a n := by simp [repeat]
@[simp] lemma repeat_one (a : α) : repeat a 1 = a ::ₘ 0 := by simp
@[simp] lemma card_repeat : ∀ (a : α) n, card (repeat a n) = n := length_repeat
theorem eq_of_mem_repeat {a b : α} {n} : b ∈ repeat a n → b = a := eq_of_mem_repeat
theorem eq_repeat' {a : α} {s : multiset α} : s = repeat a s.card ↔ ∀ b ∈ s, b = a :=
quot.induction_on s $ λ l, iff.trans ⟨λ h,
(perm_repeat.1 $ (quotient.exact h)), congr_arg coe⟩ eq_repeat'
theorem eq_repeat_of_mem {a : α} {s : multiset α} : (∀ b ∈ s, b = a) → s = repeat a s.card :=
eq_repeat'.2
theorem eq_repeat {a : α} {n} {s : multiset α} : s = repeat a n ↔ card s = n ∧ ∀ b ∈ s, b = a :=
⟨λ h, h.symm ▸ ⟨card_repeat _ _, λ b, eq_of_mem_repeat⟩,
λ ⟨e, al⟩, e ▸ eq_repeat_of_mem al⟩
theorem repeat_subset_singleton : ∀ (a : α) n, repeat a n ⊆ a ::ₘ 0 := repeat_subset_singleton
theorem repeat_le_coe {a : α} {n} {l : list α} : repeat a n ≤ l ↔ list.repeat a n <+ l :=
⟨λ ⟨l', p, s⟩, (perm_repeat.1 p) ▸ s, sublist.subperm⟩
/-! ### Erasing one copy of an element -/
section erase
variables [decidable_eq α] {s t : multiset α} {a b : α}
/-- `erase s a` is the multiset that subtracts 1 from the
multiplicity of `a`. -/
def erase (s : multiset α) (a : α) : multiset α :=
quot.lift_on s (λ l, (l.erase a : multiset α))
(λ l₁ l₂ p, quot.sound (p.erase a))
@[simp] theorem coe_erase (l : list α) (a : α) :
erase (l : multiset α) a = l.erase a := rfl
@[simp] theorem erase_zero (a : α) : (0 : multiset α).erase a = 0 := rfl
@[simp] theorem erase_cons_head (a : α) (s : multiset α) : (a ::ₘ s).erase a = s :=
quot.induction_on s $ λ l, congr_arg coe $ erase_cons_head a l
@[simp, priority 990]
theorem erase_cons_tail {a b : α} (s : multiset α) (h : b ≠ a) :
(b ::ₘ s).erase a = b ::ₘ s.erase a :=
quot.induction_on s $ λ l, congr_arg coe $ erase_cons_tail l h
@[simp, priority 980]
theorem erase_of_not_mem {a : α} {s : multiset α} : a ∉ s → s.erase a = s :=
quot.induction_on s $ λ l h, congr_arg coe $ erase_of_not_mem h
@[simp, priority 980]
theorem cons_erase {s : multiset α} {a : α} : a ∈ s → a ::ₘ s.erase a = s :=
quot.induction_on s $ λ l h, quot.sound (perm_cons_erase h).symm
theorem le_cons_erase (s : multiset α) (a : α) : s ≤ a ::ₘ s.erase a :=
if h : a ∈ s then le_of_eq (cons_erase h).symm
else by rw erase_of_not_mem h; apply le_cons_self
theorem erase_add_left_pos {a : α} {s : multiset α} (t) : a ∈ s → (s + t).erase a = s.erase a + t :=
quotient.induction_on₂ s t $ λ l₁ l₂ h, congr_arg coe $ erase_append_left l₂ h
theorem erase_add_right_pos {a : α} (s) {t : multiset α} (h : a ∈ t) :
(s + t).erase a = s + t.erase a :=
by rw [add_comm, erase_add_left_pos s h, add_comm]
theorem erase_add_right_neg {a : α} {s : multiset α} (t) :
a ∉ s → (s + t).erase a = s + t.erase a :=
quotient.induction_on₂ s t $ λ l₁ l₂ h, congr_arg coe $ erase_append_right l₂ h
theorem erase_add_left_neg {a : α} (s) {t : multiset α} (h : a ∉ t) :
(s + t).erase a = s.erase a + t :=
by rw [add_comm, erase_add_right_neg s h, add_comm]
theorem erase_le (a : α) (s : multiset α) : s.erase a ≤ s :=
quot.induction_on s $ λ l, (erase_sublist a l).subperm
@[simp] theorem erase_lt {a : α} {s : multiset α} : s.erase a < s ↔ a ∈ s :=
⟨λ h, not_imp_comm.1 erase_of_not_mem (ne_of_lt h),
λ h, by simpa [h] using lt_cons_self (s.erase a) a⟩
theorem erase_subset (a : α) (s : multiset α) : s.erase a ⊆ s :=
subset_of_le (erase_le a s)
theorem mem_erase_of_ne {a b : α} {s : multiset α} (ab : a ≠ b) : a ∈ s.erase b ↔ a ∈ s :=
quot.induction_on s $ λ l, list.mem_erase_of_ne ab
theorem mem_of_mem_erase {a b : α} {s : multiset α} : a ∈ s.erase b → a ∈ s :=
mem_of_subset (erase_subset _ _)
theorem erase_comm (s : multiset α) (a b : α) : (s.erase a).erase b = (s.erase b).erase a :=
quot.induction_on s $ λ l, congr_arg coe $ l.erase_comm a b
theorem erase_le_erase {s t : multiset α} (a : α) (h : s ≤ t) : s.erase a ≤ t.erase a :=
le_induction_on h $ λ l₁ l₂ h, (h.erase _).subperm
theorem erase_le_iff_le_cons {s t : multiset α} {a : α} : s.erase a ≤ t ↔ s ≤ a ::ₘ t :=
⟨λ h, le_trans (le_cons_erase _ _) (cons_le_cons _ h),
λ h, if m : a ∈ s
then by rw ← cons_erase m at h; exact (cons_le_cons_iff _).1 h
else le_trans (erase_le _ _) ((le_cons_of_not_mem m).1 h)⟩
@[simp] theorem card_erase_of_mem {a : α} {s : multiset α} :
a ∈ s → card (s.erase a) = pred (card s) :=
quot.induction_on s $ λ l, length_erase_of_mem
theorem card_erase_lt_of_mem {a : α} {s : multiset α} : a ∈ s → card (s.erase a) < card s :=
λ h, card_lt_of_lt (erase_lt.mpr h)
theorem card_erase_le {a : α} {s : multiset α} : card (s.erase a) ≤ card s :=
card_le_of_le (erase_le a s)
end erase
@[simp] theorem coe_reverse (l : list α) : (reverse l : multiset α) = l :=
quot.sound $ reverse_perm _
/-! ### `multiset.map` -/
/-- `map f s` is the lift of the list `map` operation. The multiplicity
of `b` in `map f s` is the number of `a ∈ s` (counting multiplicity)
such that `f a = b`. -/
def map (f : α → β) (s : multiset α) : multiset β :=
quot.lift_on s (λ l : list α, (l.map f : multiset β))
(λ l₁ l₂ p, quot.sound (p.map f))
theorem forall_mem_map_iff {f : α → β} {p : β → Prop} {s : multiset α} :
(∀ y ∈ s.map f, p y) ↔ (∀ x ∈ s, p (f x)) :=
quotient.induction_on' s $ λ L, list.forall_mem_map_iff
@[simp] theorem coe_map (f : α → β) (l : list α) : map f ↑l = l.map f := rfl
@[simp] theorem map_zero (f : α → β) : map f 0 = 0 := rfl
@[simp] theorem map_cons (f : α → β) (a s) : map f (a ::ₘ s) = f a ::ₘ map f s :=
quot.induction_on s $ λ l, rfl
lemma map_singleton (f : α → β) (a : α) : ({a} : multiset α).map f = {f a} := rfl
theorem map_repeat (f : α → β) (a : α) (k : ℕ) : (repeat a k).map f = repeat (f a) k := by
{ induction k, simp, simpa }
@[simp] theorem map_add (f : α → β) (s t) : map f (s + t) = map f s + map f t :=
quotient.induction_on₂ s t $ λ l₁ l₂, congr_arg coe $ map_append _ _ _
instance (f : α → β) : is_add_monoid_hom (map f) :=
{ map_add := map_add _, map_zero := map_zero _ }
theorem map_nsmul (f : α → β) (n : ℕ) (s) : map f (n • s) = n • (map f s) :=
(add_monoid_hom.of (map f)).map_nsmul _ _
@[simp] theorem mem_map {f : α → β} {b : β} {s : multiset α} :
b ∈ map f s ↔ ∃ a, a ∈ s ∧ f a = b :=
quot.induction_on s $ λ l, mem_map
@[simp] theorem card_map (f : α → β) (s) : card (map f s) = card s :=
quot.induction_on s $ λ l, length_map _ _
@[simp] theorem map_eq_zero {s : multiset α} {f : α → β} : s.map f = 0 ↔ s = 0 :=
by rw [← multiset.card_eq_zero, multiset.card_map, multiset.card_eq_zero]
theorem mem_map_of_mem (f : α → β) {a : α} {s : multiset α} (h : a ∈ s) : f a ∈ map f s :=
mem_map.2 ⟨_, h, rfl⟩
theorem mem_map_of_injective {f : α → β} (H : function.injective f) {a : α} {s : multiset α} :
f a ∈ map f s ↔ a ∈ s :=
quot.induction_on s $ λ l, mem_map_of_injective H
@[simp] theorem map_map (g : β → γ) (f : α → β) (s : multiset α) :
map g (map f s) = map (g ∘ f) s :=
quot.induction_on s $ λ l, congr_arg coe $ list.map_map _ _ _
theorem map_id (s : multiset α) : map id s = s :=
quot.induction_on s $ λ l, congr_arg coe $ map_id _
@[simp] lemma map_id' (s : multiset α) : map (λx, x) s = s := map_id s
@[simp] theorem map_const (s : multiset α) (b : β) : map (function.const α b) s = repeat b s.card :=
quot.induction_on s $ λ l, congr_arg coe $ map_const _ _
@[congr] theorem map_congr {f g : α → β} {s : multiset α} :
(∀ x ∈ s, f x = g x) → map f s = map g s :=
quot.induction_on s $ λ l H, congr_arg coe $ map_congr H
lemma map_hcongr {β' : Type*} {m : multiset α} {f : α → β} {f' : α → β'}
(h : β = β') (hf : ∀a∈m, f a == f' a) : map f m == map f' m :=
begin subst h, simp at hf, simp [map_congr hf] end
theorem eq_of_mem_map_const {b₁ b₂ : β} {l : list α} (h : b₁ ∈ map (function.const α b₂) l) :
b₁ = b₂ :=
eq_of_mem_repeat $ by rwa map_const at h
@[simp] theorem map_le_map {f : α → β} {s t : multiset α} (h : s ≤ t) : map f s ≤ map f t :=
le_induction_on h $ λ l₁ l₂ h, (h.map f).subperm
@[simp] theorem map_subset_map {f : α → β} {s t : multiset α} (H : s ⊆ t) : map f s ⊆ map f t :=
λ b m, let ⟨a, h, e⟩ := mem_map.1 m in mem_map.2 ⟨a, H h, e⟩
/-! ### `multiset.fold` -/
/-- `foldl f H b s` is the lift of the list operation `foldl f b l`,
which folds `f` over the multiset. It is well defined when `f` is right-commutative,
that is, `f (f b a₁) a₂ = f (f b a₂) a₁`. -/
def foldl (f : β → α → β) (H : right_commutative f) (b : β) (s : multiset α) : β :=
quot.lift_on s (λ l, foldl f b l)
(λ l₁ l₂ p, p.foldl_eq H b)
@[simp] theorem foldl_zero (f : β → α → β) (H b) : foldl f H b 0 = b := rfl
@[simp] theorem foldl_cons (f : β → α → β) (H b a s) :
foldl f H b (a ::ₘ s) = foldl f H (f b a) s :=
quot.induction_on s $ λ l, rfl
@[simp] theorem foldl_add (f : β → α → β) (H b s t) :
foldl f H b (s + t) = foldl f H (foldl f H b s) t :=
quotient.induction_on₂ s t $ λ l₁ l₂, foldl_append _ _ _ _
/-- `foldr f H b s` is the lift of the list operation `foldr f b l`,
which folds `f` over the multiset. It is well defined when `f` is left-commutative,
that is, `f a₁ (f a₂ b) = f a₂ (f a₁ b)`. -/
def foldr (f : α → β → β) (H : left_commutative f) (b : β) (s : multiset α) : β :=
quot.lift_on s (λ l, foldr f b l)
(λ l₁ l₂ p, p.foldr_eq H b)
@[simp] theorem foldr_zero (f : α → β → β) (H b) : foldr f H b 0 = b := rfl
@[simp] theorem foldr_cons (f : α → β → β) (H b a s) :
foldr f H b (a ::ₘ s) = f a (foldr f H b s) :=
quot.induction_on s $ λ l, rfl
@[simp] theorem foldr_add (f : α → β → β) (H b s t) :
foldr f H b (s + t) = foldr f H (foldr f H b t) s :=
quotient.induction_on₂ s t $ λ l₁ l₂, foldr_append _ _ _ _
@[simp] theorem coe_foldr (f : α → β → β) (H : left_commutative f) (b : β) (l : list α) :
foldr f H b l = l.foldr f b := rfl
@[simp] theorem coe_foldl (f : β → α → β) (H : right_commutative f) (b : β) (l : list α) :
foldl f H b l = l.foldl f b := rfl
theorem coe_foldr_swap (f : α → β → β) (H : left_commutative f) (b : β) (l : list α) :
foldr f H b l = l.foldl (λ x y, f y x) b :=
(congr_arg (foldr f H b) (coe_reverse l)).symm.trans $ foldr_reverse _ _ _
theorem foldr_swap (f : α → β → β) (H : left_commutative f) (b : β) (s : multiset α) :
foldr f H b s = foldl (λ x y, f y x) (λ x y z, (H _ _ _).symm) b s :=
quot.induction_on s $ λ l, coe_foldr_swap _ _ _ _
theorem foldl_swap (f : β → α → β) (H : right_commutative f) (b : β) (s : multiset α) :
foldl f H b s = foldr (λ x y, f y x) (λ x y z, (H _ _ _).symm) b s :=
(foldr_swap _ _ _ _).symm
lemma foldr_induction' (f : α → β → β) (H : left_commutative f) (x : β) (q : α → Prop)
(p : β → Prop) (s : multiset α) (hpqf : ∀ a b, q a → p b → p (f a b)) (px : p x)
(q_s : ∀ a ∈ s, q a) :
p (foldr f H x s) :=
begin
revert s,
refine multiset.induction (by simp [px]) _,
intros a s hs hsa,
rw foldr_cons,
have hps : ∀ (x : α), x ∈ s → q x, from λ x hxs, hsa x (mem_cons_of_mem hxs),
exact hpqf a (foldr f H x s) (hsa a (mem_cons_self a s)) (hs hps),
end
lemma foldr_induction (f : α → α → α) (H : left_commutative f) (x : α) (p : α → Prop)
(s : multiset α) (p_f : ∀ a b, p a → p b → p (f a b)) (px : p x) (p_s : ∀ a ∈ s, p a) :
p (foldr f H x s) :=
foldr_induction' f H x p p s p_f px p_s
lemma foldl_induction' (f : β → α → β) (H : right_commutative f) (x : β) (q : α → Prop)
(p : β → Prop) (s : multiset α) (hpqf : ∀ a b, q a → p b → p (f b a)) (px : p x)
(q_s : ∀ a ∈ s, q a) :
p (foldl f H x s) :=
begin
rw foldl_swap,
exact foldr_induction' (λ x y, f y x) (λ x y z, (H _ _ _).symm) x q p s hpqf px q_s,
end
lemma foldl_induction (f : α → α → α) (H : right_commutative f) (x : α) (p : α → Prop)
(s : multiset α) (p_f : ∀ a b, p a → p b → p (f b a)) (px : p x) (p_s : ∀ a ∈ s, p a) :
p (foldl f H x s) :=
foldl_induction' f H x p p s p_f px p_s
/-- Product of a multiset given a commutative monoid structure on `α`.
`prod {a, b, c} = a * b * c` -/
@[to_additive]
def prod [comm_monoid α] : multiset α → α :=
foldr (*) (λ x y z, by simp [mul_left_comm]) 1
@[to_additive]
theorem prod_eq_foldr [comm_monoid α] (s : multiset α) :
prod s = foldr (*) (λ x y z, by simp [mul_left_comm]) 1 s := rfl
@[to_additive]
theorem prod_eq_foldl [comm_monoid α] (s : multiset α) :
prod s = foldl (*) (λ x y z, by simp [mul_right_comm]) 1 s :=
(foldr_swap _ _ _ _).trans (by simp [mul_comm])
@[simp, to_additive]
theorem coe_prod [comm_monoid α] (l : list α) : prod ↑l = l.prod :=
prod_eq_foldl _
attribute [norm_cast] coe_prod coe_sum
@[simp, to_additive]
theorem prod_zero [comm_monoid α] : @prod α _ 0 = 1 := rfl
@[simp, to_additive]
theorem prod_cons [comm_monoid α] (a : α) (s) : prod (a ::ₘ s) = a * prod s :=
foldr_cons _ _ _ _ _
@[to_additive]
theorem prod_singleton [comm_monoid α] (a : α) : prod (a ::ₘ 0) = a := by simp
@[simp, to_additive]
theorem prod_add [comm_monoid α] (s t : multiset α) : prod (s + t) = prod s * prod t :=
quotient.induction_on₂ s t $ λ l₁ l₂, by simp
instance sum.is_add_monoid_hom [add_comm_monoid α] : is_add_monoid_hom (sum : multiset α → α) :=
{ map_add := sum_add, map_zero := sum_zero }
lemma prod_nsmul {α : Type*} [comm_monoid α] (m : multiset α) :
∀ (n : ℕ), (n • m).prod = m.prod ^ n
| 0 := by { rw [zero_nsmul, pow_zero], refl }
| (n + 1) :=
by rw [add_nsmul, one_nsmul, pow_add, pow_one, prod_add, prod_nsmul n]
@[simp] theorem prod_repeat [comm_monoid α] (a : α) (n : ℕ) : prod (multiset.repeat a n) = a ^ n :=
by simp [repeat, list.prod_repeat]
@[simp] theorem sum_repeat [add_comm_monoid α] :
∀ (a : α) (n : ℕ), sum (multiset.repeat a n) = n • a :=
@prod_repeat (multiplicative α) _
attribute [to_additive] prod_repeat
lemma prod_map_one [comm_monoid γ] {m : multiset α} :
prod (m.map (λa, (1 : γ))) = (1 : γ) :=
by simp
lemma sum_map_zero [add_comm_monoid γ] {m : multiset α} :
sum (m.map (λa, (0 : γ))) = (0 : γ) :=
by simp [nsmul_zero]
attribute [to_additive] prod_map_one
@[simp, to_additive]
lemma prod_map_mul [comm_monoid γ] {m : multiset α} {f g : α → γ} :
prod (m.map $ λa, f a * g a) = prod (m.map f) * prod (m.map g) :=
multiset.induction_on m (by simp) (assume a m ih, by simp [ih]; cc)
lemma prod_map_prod_map [comm_monoid γ] (m : multiset α) (n : multiset β) {f : α → β → γ} :
prod (m.map $ λa, prod $ n.map $ λb, f a b) = prod (n.map $ λb, prod $ m.map $ λa, f a b) :=
multiset.induction_on m (by simp) (assume a m ih, by simp [ih])
lemma sum_map_sum_map [add_comm_monoid γ] : ∀ (m : multiset α) (n : multiset β) {f : α → β → γ},
sum (m.map $ λa, sum $ n.map $ λb, f a b) = sum (n.map $ λb, sum $ m.map $ λa, f a b) :=
@prod_map_prod_map _ _ (multiplicative γ) _
attribute [to_additive] prod_map_prod_map
lemma sum_map_mul_left [semiring β] {b : β} {s : multiset α} {f : α → β} :
sum (s.map (λa, b * f a)) = b * sum (s.map f) :=
multiset.induction_on s (by simp) (assume a s ih, by simp [ih, mul_add])
lemma sum_map_mul_right [semiring β] {b : β} {s : multiset α} {f : α → β} :
sum (s.map (λa, f a * b)) = sum (s.map f) * b :=
multiset.induction_on s (by simp) (assume a s ih, by simp [ih, add_mul])
lemma prod_eq_zero {M₀ : Type*} [comm_monoid_with_zero M₀] {s : multiset M₀} (h : (0 : M₀) ∈ s) :
multiset.prod s = 0 :=
begin
rcases multiset.exists_cons_of_mem h with ⟨s', hs'⟩,
simp [hs', multiset.prod_cons]
end
lemma prod_eq_zero_iff {M₀ : Type*} [comm_monoid_with_zero M₀] [no_zero_divisors M₀] [nontrivial M₀]
{s : multiset M₀} :
multiset.prod s = 0 ↔ (0 : M₀) ∈ s :=
by { rcases s with ⟨l⟩, simp }
theorem prod_ne_zero {M₀ : Type*} [comm_monoid_with_zero M₀] [no_zero_divisors M₀] [nontrivial M₀]
{m : multiset M₀} (h : (0 : M₀) ∉ m) : m.prod ≠ 0 :=
mt prod_eq_zero_iff.1 h
@[to_additive]
lemma prod_hom [comm_monoid α] [comm_monoid β] (s : multiset α) (f : α →* β) :
(s.map f).prod = f s.prod :=
quotient.induction_on s $ λ l, by simp only [l.prod_hom f, quot_mk_to_coe, coe_map, coe_prod]
@[to_additive]
theorem prod_hom_rel [comm_monoid β] [comm_monoid γ] (s : multiset α) {r : β → γ → Prop}
{f : α → β} {g : α → γ} (h₁ : r 1 1) (h₂ : ∀⦃a b c⦄, r b c → r (f a * b) (g a * c)) :
r (s.map f).prod (s.map g).prod :=
quotient.induction_on s $ λ l,
by simp only [l.prod_hom_rel h₁ h₂, quot_mk_to_coe, coe_map, coe_prod]
lemma dvd_prod [comm_monoid α] {a : α} {s : multiset α} : a ∈ s → a ∣ s.prod :=
quotient.induction_on s (λ l a h, by simpa using list.dvd_prod h) a
lemma prod_dvd_prod [comm_monoid α] {s t : multiset α} (h : s ≤ t) :
s.prod ∣ t.prod :=
begin
rcases multiset.le_iff_exists_add.1 h with ⟨z, rfl⟩,
simp,
end
@[to_additive sum_nonneg]
lemma one_le_prod_of_one_le [ordered_comm_monoid α] {m : multiset α} :
(∀ x ∈ m, (1 : α) ≤ x) → 1 ≤ m.prod :=
quotient.induction_on m $ λ l hl, by simpa using list.one_le_prod_of_one_le hl
@[to_additive]
lemma single_le_prod [ordered_comm_monoid α] {m : multiset α} :
(∀ x ∈ m, (1 : α) ≤ x) → ∀ x ∈ m, x ≤ m.prod :=
quotient.induction_on m $ λ l hl x hx, by simpa using list.single_le_prod hl x hx
@[to_additive all_zero_of_le_zero_le_of_sum_eq_zero]
lemma all_one_of_le_one_le_of_prod_eq_one [ordered_comm_monoid α] {m : multiset α} :
(∀ x ∈ m, (1 : α) ≤ x) → m.prod = 1 → (∀ x ∈ m, x = (1 : α)) :=
begin
apply quotient.induction_on m,
simp only [quot_mk_to_coe, coe_prod, mem_coe],
intros l hl₁ hl₂ x hx,
apply all_one_of_le_one_le_of_prod_eq_one hl₁ hl₂ _ hx,
end
lemma sum_eq_zero_iff [canonically_ordered_add_monoid α] {m : multiset α} :
m.sum = 0 ↔ ∀ x ∈ m, x = (0 : α) :=
quotient.induction_on m $ λ l, by simpa using list.sum_eq_zero_iff l
@[to_additive]
lemma prod_induction {M : Type*} [comm_monoid M] (p : M → Prop) (s : multiset M)
(p_mul : ∀ a b, p a → p b → p (a * b)) (p_one : p 1) (p_s : ∀ a ∈ s, p a) :
p s.prod :=
begin
rw prod_eq_foldr,
exact foldr_induction (*) (λ x y z, by simp [mul_left_comm]) 1 p s p_mul p_one p_s,
end
@[to_additive le_sum_of_subadditive_on_pred]
lemma le_prod_of_submultiplicative_on_pred [comm_monoid α] [ordered_comm_monoid β]
(f : α → β) (p : α → Prop) (h_one : f 1 = 1) (hp_one : p 1)
(h_mul : ∀ a b, p a → p b → f (a * b) ≤ f a * f b)
(hp_mul : ∀ a b, p a → p b → p (a * b)) (s : multiset α) (hps : ∀ a, a ∈ s → p a) :
f s.prod ≤ (s.map f).prod :=
begin
revert s,
refine multiset.induction _ _,
{ simp [le_of_eq h_one], },
intros a s hs hpsa,
have hps : ∀ x, x ∈ s → p x, from λ x hx, hpsa x (mem_cons_of_mem hx),
have hp_prod : p s.prod, from prod_induction p s hp_mul hp_one hps,
rw [prod_cons, map_cons, prod_cons],
exact (h_mul a s.prod (hpsa a (mem_cons_self a s)) hp_prod).trans (mul_le_mul_left' (hs hps) _),
end
@[to_additive le_sum_of_subadditive]
lemma le_prod_of_submultiplicative [comm_monoid α] [ordered_comm_monoid β]
(f : α → β) (h_one : f 1 = 1) (h_mul : ∀ a b, f (a * b) ≤ f a * f b) (s : multiset α) :
f s.prod ≤ (s.map f).prod :=
le_prod_of_submultiplicative_on_pred f (λ i, true) h_one trivial (λ x y _ _ , h_mul x y) (by simp)
s (by simp)
@[to_additive]
lemma prod_induction_nonempty {M : Type*} [comm_monoid M] (p : M → Prop)
(p_mul : ∀ a b, p a → p b → p (a * b)) {s : multiset M} (hs_nonempty : s ≠ ∅)
(p_s : ∀ a ∈ s, p a) :
p s.prod :=
begin
revert s,
refine multiset.induction _ _,
{ intro h,
exfalso,
simpa using h, },
intros a s hs hsa hpsa,
rw prod_cons,
by_cases hs_empty : s = ∅,
{ simp [hs_empty, hpsa a], },
have hps : ∀ (x : M), x ∈ s → p x, from λ x hxs, hpsa x (mem_cons_of_mem hxs),
exact p_mul a s.prod (hpsa a (mem_cons_self a s)) (hs hs_empty hps),
end
@[to_additive le_sum_nonempty_of_subadditive_on_pred]
lemma le_prod_nonempty_of_submultiplicative_on_pred [comm_monoid α] [ordered_comm_monoid β]
(f : α → β) (p : α → Prop) (h_mul : ∀ a b, p a → p b → f (a * b) ≤ f a * f b)
(hp_mul : ∀ a b, p a → p b → p (a * b)) (s : multiset α) (hs_nonempty : s ≠ ∅)
(hs : ∀ a, a ∈ s → p a) :
f s.prod ≤ (s.map f).prod :=
begin
revert s,
refine multiset.induction _ _,
{ intro h,
exfalso,
exact h rfl, },
rintros a s hs hsa_nonempty hsa_prop,
rw [prod_cons, map_cons, prod_cons],
by_cases hs_empty : s = ∅,
{ simp [hs_empty], },
have hsa_restrict : (∀ x, x ∈ s → p x), from λ x hx, hsa_prop x (mem_cons_of_mem hx),
have hp_sup : p s.prod,
from prod_induction_nonempty p hp_mul hs_empty hsa_restrict,
have hp_a : p a, from hsa_prop a (mem_cons_self a s),
exact (h_mul a _ hp_a hp_sup).trans (mul_le_mul_left' (hs hs_empty hsa_restrict) _),
end
@[to_additive le_sum_nonempty_of_subadditive]
lemma le_prod_nonempty_of_submultiplicative [comm_monoid α] [ordered_comm_monoid β]
(f : α → β) (h_mul : ∀ a b, f (a * b) ≤ f a * f b) (s : multiset α) (hs_nonempty : s ≠ ∅) :
f s.prod ≤ (s.map f).prod :=
le_prod_nonempty_of_submultiplicative_on_pred f (λ i, true) (by simp [h_mul]) (by simp) s
hs_nonempty (by simp)
lemma abs_sum_le_sum_abs [linear_ordered_field α] {s : multiset α} :
abs s.sum ≤ (s.map abs).sum :=
le_sum_of_subadditive _ abs_zero abs_add s
theorem dvd_sum [comm_semiring α] {a : α} {s : multiset α} : (∀ x ∈ s, a ∣ x) → a ∣ s.sum :=
multiset.induction_on s (λ _, dvd_zero _)
(λ x s ih h, by rw sum_cons; exact dvd_add
(h _ (mem_cons_self _ _)) (ih (λ y hy, h _ (mem_cons.2 (or.inr hy)))))
@[simp] theorem sum_map_singleton (s : multiset α) : (s.map (λ a, a ::ₘ 0)).sum = s :=
multiset.induction_on s (by simp) (by simp)
@[simp, to_additive] theorem prod_to_list [comm_monoid α] (s : multiset α) :
s.to_list.prod = s.prod :=
begin
conv_rhs { rw ←coe_to_list s, },
rw coe_prod,
end
/-! ### Join -/
/-- `join S`, where `S` is a multiset of multisets, is the lift of the list join
operation, that is, the union of all the sets.
join {{1, 2}, {1, 2}, {0, 1}} = {0, 1, 1, 1, 2, 2} -/
def join : multiset (multiset α) → multiset α := sum
theorem coe_join : ∀ L : list (list α),
join (L.map (@coe _ (multiset α) _) : multiset (multiset α)) = L.join
| [] := rfl
| (l :: L) := congr_arg (λ s : multiset α, ↑l + s) (coe_join L)
@[simp] theorem join_zero : @join α 0 = 0 := rfl
@[simp] theorem join_cons (s S) : @join α (s ::ₘ S) = s + join S :=
sum_cons _ _
@[simp] theorem join_add (S T) : @join α (S + T) = join S + join T :=
sum_add _ _
@[simp] theorem mem_join {a S} : a ∈ @join α S ↔ ∃ s ∈ S, a ∈ s :=
multiset.induction_on S (by simp) $
by simp [or_and_distrib_right, exists_or_distrib] {contextual := tt}
@[simp] theorem card_join (S) : card (@join α S) = sum (map card S) :=
multiset.induction_on S (by simp) (by simp)
/-! ### `multiset.bind` -/
/-- `bind s f` is the monad bind operation, defined as `join (map f s)`.
It is the union of `f a` as `a` ranges over `s`. -/
def bind (s : multiset α) (f : α → multiset β) : multiset β :=
join (map f s)
@[simp] theorem coe_bind (l : list α) (f : α → list β) :
@bind α β l (λ a, f a) = l.bind f :=
by rw [list.bind, ← coe_join, list.map_map]; refl
@[simp] theorem zero_bind (f : α → multiset β) : bind 0 f = 0 := rfl
@[simp] theorem cons_bind (a s) (f : α → multiset β) : bind (a ::ₘ s) f = f a + bind s f :=
by simp [bind]
@[simp] theorem add_bind (s t) (f : α → multiset β) : bind (s + t) f = bind s f + bind t f :=
by simp [bind]
@[simp] theorem bind_zero (s : multiset α) : bind s (λa, 0 : α → multiset β) = 0 :=
by simp [bind, join, nsmul_zero]
@[simp] theorem bind_add (s : multiset α) (f g : α → multiset β) :
bind s (λa, f a + g a) = bind s f + bind s g :=
by simp [bind, join]
@[simp] theorem bind_cons (s : multiset α) (f : α → β) (g : α → multiset β) :
bind s (λa, f a ::ₘ g a) = map f s + bind s g :=
multiset.induction_on s (by simp) (by simp [add_comm, add_left_comm] {contextual := tt})
@[simp] theorem mem_bind {b s} {f : α → multiset β} : b ∈ bind s f ↔ ∃ a ∈ s, b ∈ f a :=
by simp [bind]; simp [-exists_and_distrib_right, exists_and_distrib_right.symm];
rw exists_swap; simp [and_assoc]
@[simp] theorem card_bind (s) (f : α → multiset β) : card (bind s f) = sum (map (card ∘ f) s) :=
by simp [bind]
lemma bind_congr {f g : α → multiset β} {m : multiset α} :
(∀a∈m, f a = g a) → bind m f = bind m g :=
by simp [bind] {contextual := tt}
lemma bind_hcongr {β' : Type*} {m : multiset α} {f : α → multiset β} {f' : α → multiset β'}
(h : β = β') (hf : ∀a∈m, f a == f' a) : bind m f == bind m f' :=
begin subst h, simp at hf, simp [bind_congr hf] end
lemma map_bind (m : multiset α) (n : α → multiset β) (f : β → γ) :
map f (bind m n) = bind m (λa, map f (n a)) :=
multiset.induction_on m (by simp) (by simp {contextual := tt})
lemma bind_map (m : multiset α) (n : β → multiset γ) (f : α → β) :
bind (map f m) n = bind m (λa, n (f a)) :=
multiset.induction_on m (by simp) (by simp {contextual := tt})
lemma bind_assoc {s : multiset α} {f : α → multiset β} {g : β → multiset γ} :
(s.bind f).bind g = s.bind (λa, (f a).bind g) :=
multiset.induction_on s (by simp) (by simp {contextual := tt})
lemma bind_bind (m : multiset α) (n : multiset β) {f : α → β → multiset γ} :
(bind m $ λa, bind n $ λb, f a b) = (bind n $ λb, bind m $ λa, f a b) :=
multiset.induction_on m (by simp) (by simp {contextual := tt})
lemma bind_map_comm (m : multiset α) (n : multiset β) {f : α → β → γ} :
(bind m $ λa, n.map $ λb, f a b) = (bind n $ λb, m.map $ λa, f a b) :=
multiset.induction_on m (by simp) (by simp {contextual := tt})
@[simp, to_additive]
lemma prod_bind [comm_monoid β] (s : multiset α) (t : α → multiset β) :
prod (bind s t) = prod (s.map $ λa, prod (t a)) :=
multiset.induction_on s (by simp) (assume a s ih, by simp [ih, cons_bind])
/-! ### Product of two `multiset`s -/
/-- The multiplicity of `(a, b)` in `product s t` is
the product of the multiplicity of `a` in `s` and `b` in `t`. -/
def product (s : multiset α) (t : multiset β) : multiset (α × β) :=
s.bind $ λ a, t.map $ prod.mk a
@[simp] theorem coe_product (l₁ : list α) (l₂ : list β) :
@product α β l₁ l₂ = l₁.product l₂ :=
by rw [product, list.product, ← coe_bind]; simp
@[simp] theorem zero_product (t) : @product α β 0 t = 0 := rfl
@[simp] theorem cons_product (a : α) (s : multiset α) (t : multiset β) :
product (a ::ₘ s) t = map (prod.mk a) t + product s t :=
by simp [product]
@[simp] theorem product_singleton (a : α) (b : β) : product (a ::ₘ 0) (b ::ₘ 0) = (a,b) ::ₘ 0 := rfl
@[simp] theorem add_product (s t : multiset α) (u : multiset β) :
product (s + t) u = product s u + product t u :=
by simp [product]
@[simp] theorem product_add (s : multiset α) : ∀ t u : multiset β,
product s (t + u) = product s t + product s u :=
multiset.induction_on s (λ t u, rfl) $ λ a s IH t u,
by rw [cons_product, IH]; simp; cc
@[simp] theorem mem_product {s t} : ∀ {p : α × β}, p ∈ @product α β s t ↔ p.1 ∈ s ∧ p.2 ∈ t
| (a, b) := by simp [product, and.left_comm]
@[simp] theorem card_product (s : multiset α) (t : multiset β) :
card (product s t) = card s * card t :=
by simp [product, repeat, (∘), mul_comm]
/-! ### Sigma multiset -/
section
variable {σ : α → Type*}
/-- `sigma s t` is the dependent version of `product`. It is the sum of
`(a, b)` as `a` ranges over `s` and `b` ranges over `t a`. -/
protected def sigma (s : multiset α) (t : Π a, multiset (σ a)) : multiset (Σ a, σ a) :=
s.bind $ λ a, (t a).map $ sigma.mk a
@[simp] theorem coe_sigma (l₁ : list α) (l₂ : Π a, list (σ a)) :
@multiset.sigma α σ l₁ (λ a, l₂ a) = l₁.sigma l₂ :=
by rw [multiset.sigma, list.sigma, ← coe_bind]; simp
@[simp] theorem zero_sigma (t) : @multiset.sigma α σ 0 t = 0 := rfl
@[simp] theorem cons_sigma (a : α) (s : multiset α) (t : Π a, multiset (σ a)) :
(a ::ₘ s).sigma t = map (sigma.mk a) (t a) + s.sigma t :=
by simp [multiset.sigma]
@[simp] theorem sigma_singleton (a : α) (b : α → β) :
(a ::ₘ 0).sigma (λ a, b a ::ₘ 0) = ⟨a, b a⟩ ::ₘ 0 := rfl
@[simp] theorem add_sigma (s t : multiset α) (u : Π a, multiset (σ a)) :
(s + t).sigma u = s.sigma u + t.sigma u :=
by simp [multiset.sigma]
@[simp] theorem sigma_add (s : multiset α) : ∀ t u : Π a, multiset (σ a),
s.sigma (λ a, t a + u a) = s.sigma t + s.sigma u :=
multiset.induction_on s (λ t u, rfl) $ λ a s IH t u,
by rw [cons_sigma, IH]; simp; cc
@[simp] theorem mem_sigma {s t} : ∀ {p : Σ a, σ a},
p ∈ @multiset.sigma α σ s t ↔ p.1 ∈ s ∧ p.2 ∈ t p.1
| ⟨a, b⟩ := by simp [multiset.sigma, and_assoc, and.left_comm]
@[simp] theorem card_sigma (s : multiset α) (t : Π a, multiset (σ a)) :
card (s.sigma t) = sum (map (λ a, card (t a)) s) :=
by simp [multiset.sigma, (∘)]
end
/-! ### Map for partial functions -/
/-- Lift of the list `pmap` operation. Map a partial function `f` over a multiset
`s` whose elements are all in the domain of `f`. -/
def pmap {p : α → Prop} (f : Π a, p a → β) (s : multiset α) : (∀ a ∈ s, p a) → multiset β :=
quot.rec_on s (λ l H, ↑(pmap f l H)) $ λ l₁ l₂ (pp : l₁ ~ l₂),
funext $ λ (H₂ : ∀ a ∈ l₂, p a),
have H₁ : ∀ a ∈ l₁, p a, from λ a h, H₂ a (pp.subset h),
have ∀ {s₂ e H}, @eq.rec (multiset α) l₁
(λ s, (∀ a ∈ s, p a) → multiset β) (λ _, ↑(pmap f l₁ H₁))
s₂ e H = ↑(pmap f l₁ H₁), by intros s₂ e _; subst e,
this.trans $ quot.sound $ pp.pmap f
@[simp] theorem coe_pmap {p : α → Prop} (f : Π a, p a → β)
(l : list α) (H : ∀ a ∈ l, p a) : pmap f l H = l.pmap f H := rfl
@[simp] lemma pmap_zero {p : α → Prop} (f : Π a, p a → β) (h : ∀a∈(0:multiset α), p a) :
pmap f 0 h = 0 := rfl
@[simp] lemma pmap_cons {p : α → Prop} (f : Π a, p a → β) (a : α) (m : multiset α) :
∀(h : ∀b∈a ::ₘ m, p b), pmap f (a ::ₘ m) h =
f a (h a (mem_cons_self a m)) ::ₘ pmap f m (λa ha, h a $ mem_cons_of_mem ha) :=
quotient.induction_on m $ assume l h, rfl
/-- "Attach" a proof that `a ∈ s` to each element `a` in `s` to produce
a multiset on `{x // x ∈ s}`. -/
def attach (s : multiset α) : multiset {x // x ∈ s} := pmap subtype.mk s (λ a, id)
@[simp] theorem coe_attach (l : list α) :
@eq (multiset {x // x ∈ l}) (@attach α l) l.attach := rfl
theorem sizeof_lt_sizeof_of_mem [has_sizeof α] {x : α} {s : multiset α} (hx : x ∈ s) :
sizeof x < sizeof s := by
{ induction s with l a b, exact list.sizeof_lt_sizeof_of_mem hx, refl }
theorem pmap_eq_map (p : α → Prop) (f : α → β) (s : multiset α) :
∀ H, @pmap _ _ p (λ a _, f a) s H = map f s :=
quot.induction_on s $ λ l H, congr_arg coe $ pmap_eq_map p f l H
theorem pmap_congr {p q : α → Prop} {f : Π a, p a → β} {g : Π a, q a → β}
(s : multiset α) {H₁ H₂} (h : ∀ a h₁ h₂, f a h₁ = g a h₂) :
pmap f s H₁ = pmap g s H₂ :=
quot.induction_on s (λ l H₁ H₂, congr_arg coe $ pmap_congr l h) H₁ H₂
theorem map_pmap {p : α → Prop} (g : β → γ) (f : Π a, p a → β)
(s) : ∀ H, map g (pmap f s H) = pmap (λ a h, g (f a h)) s H :=
quot.induction_on s $ λ l H, congr_arg coe $ map_pmap g f l H
theorem pmap_eq_map_attach {p : α → Prop} (f : Π a, p a → β)
(s) : ∀ H, pmap f s H = s.attach.map (λ x, f x.1 (H _ x.2)) :=
quot.induction_on s $ λ l H, congr_arg coe $ pmap_eq_map_attach f l H
theorem attach_map_val (s : multiset α) : s.attach.map subtype.val = s :=
quot.induction_on s $ λ l, congr_arg coe $ attach_map_val l
@[simp] theorem mem_attach (s : multiset α) : ∀ x, x ∈ s.attach :=
quot.induction_on s $ λ l, mem_attach _
@[simp] theorem mem_pmap {p : α → Prop} {f : Π a, p a → β}
{s H b} : b ∈ pmap f s H ↔ ∃ a (h : a ∈ s), f a (H a h) = b :=
quot.induction_on s (λ l H, mem_pmap) H
@[simp] theorem card_pmap {p : α → Prop} (f : Π a, p a → β)
(s H) : card (pmap f s H) = card s :=
quot.induction_on s (λ l H, length_pmap) H
@[simp] theorem card_attach {m : multiset α} : card (attach m) = card m := card_pmap _ _ _
@[simp] lemma attach_zero : (0 : multiset α).attach = 0 := rfl
lemma attach_cons (a : α) (m : multiset α) :
(a ::ₘ m).attach = ⟨a, mem_cons_self a m⟩ ::ₘ (m.attach.map $ λp, ⟨p.1, mem_cons_of_mem p.2⟩) :=
quotient.induction_on m $ assume l, congr_arg coe $ congr_arg (list.cons _) $
by rw [list.map_pmap]; exact list.pmap_congr _ (assume a' h₁ h₂, subtype.eq rfl)
section decidable_pi_exists
variables {m : multiset α}
protected def decidable_forall_multiset {p : α → Prop} [hp : ∀a, decidable (p a)] :
decidable (∀a∈m, p a) :=
quotient.rec_on_subsingleton m (λl, decidable_of_iff (∀a∈l, p a) $ by simp)
instance decidable_dforall_multiset {p : Πa∈m, Prop} [hp : ∀a (h : a ∈ m), decidable (p a h)] :
decidable (∀a (h : a ∈ m), p a h) :=
decidable_of_decidable_of_iff
(@multiset.decidable_forall_multiset {a // a ∈ m} m.attach (λa, p a.1 a.2) _)
(iff.intro (assume h a ha, h ⟨a, ha⟩ (mem_attach _ _)) (assume h ⟨a, ha⟩ _, h _ _))
/-- decidable equality for functions whose domain is bounded by multisets -/
instance decidable_eq_pi_multiset {β : α → Type*} [h : ∀a, decidable_eq (β a)] :
decidable_eq (Πa∈m, β a) :=
assume f g, decidable_of_iff (∀a (h : a ∈ m), f a h = g a h) (by simp [function.funext_iff])
def decidable_exists_multiset {p : α → Prop} [decidable_pred p] :
decidable (∃ x ∈ m, p x) :=
quotient.rec_on_subsingleton m list.decidable_exists_mem
instance decidable_dexists_multiset {p : Πa∈m, Prop} [hp : ∀a (h : a ∈ m), decidable (p a h)] :
decidable (∃a (h : a ∈ m), p a h) :=
decidable_of_decidable_of_iff
(@multiset.decidable_exists_multiset {a // a ∈ m} m.attach (λa, p a.1 a.2) _)
(iff.intro (λ ⟨⟨a, ha₁⟩, _, ha₂⟩, ⟨a, ha₁, ha₂⟩)
(λ ⟨a, ha₁, ha₂⟩, ⟨⟨a, ha₁⟩, mem_attach _ _, ha₂⟩))
end decidable_pi_exists
/-! ### Subtraction -/
section
variables [decidable_eq α] {s t u : multiset α} {a b : α}
/-- `s - t` is the multiset such that
`count a (s - t) = count a s - count a t` for all `a`. -/
protected def sub (s t : multiset α) : multiset α :=
quotient.lift_on₂ s t (λ l₁ l₂, (l₁.diff l₂ : multiset α)) $ λ v₁ v₂ w₁ w₂ p₁ p₂,
quot.sound $ p₁.diff p₂
instance : has_sub (multiset α) := ⟨multiset.sub⟩
@[simp] theorem coe_sub (s t : list α) : (s - t : multiset α) = (s.diff t : list α) := rfl
theorem sub_eq_fold_erase (s t : multiset α) : s - t = foldl erase erase_comm s t :=
quotient.induction_on₂ s t $ λ l₁ l₂,
show ↑(l₁.diff l₂) = foldl erase erase_comm ↑l₁ ↑l₂,
by { rw diff_eq_foldl l₁ l₂, symmetry, exact foldl_hom _ _ _ _ _ (λ x y, rfl) }
@[simp] theorem sub_zero (s : multiset α) : s - 0 = s :=
quot.induction_on s $ λ l, rfl
@[simp] theorem sub_cons (a : α) (s t : multiset α) : s - a ::ₘ t = s.erase a - t :=
quotient.induction_on₂ s t $ λ l₁ l₂, congr_arg coe $ diff_cons _ _ _
theorem add_sub_of_le (h : s ≤ t) : s + (t - s) = t :=
begin
revert t,
refine multiset.induction_on s (by simp) (λ a s IH t h, _),
have := cons_erase (mem_of_le h (mem_cons_self _ _)),
rw [cons_add, sub_cons, IH, this],
exact (cons_le_cons_iff a).1 (this.symm ▸ h)
end
theorem sub_add' : s - (t + u) = s - t - u :=
quotient.induction_on₃ s t u $
λ l₁ l₂ l₃, congr_arg coe $ diff_append _ _ _
theorem sub_add_cancel (h : t ≤ s) : s - t + t = s :=
by rw [add_comm, add_sub_of_le h]
@[simp] theorem add_sub_cancel_left (s : multiset α) : ∀ t, s + t - s = t :=
multiset.induction_on s (by simp)
(λ a s IH t, by rw [cons_add, sub_cons, erase_cons_head, IH])
@[simp] theorem add_sub_cancel (s t : multiset α) : s + t - t = s :=
by rw [add_comm, add_sub_cancel_left]
theorem sub_le_sub_right (h : s ≤ t) (u) : s - u ≤ t - u :=
by revert s t h; exact
multiset.induction_on u (by simp {contextual := tt})
(λ a u IH s t h, by simp [IH, erase_le_erase a h])
theorem sub_le_sub_left (h : s ≤ t) : ∀ u, u - t ≤ u - s :=
le_induction_on h $ λ l₁ l₂ h, begin
induction h with l₁ l₂ a s IH l₁ l₂ a s IH; intro u,
{ refl },
{ rw [← cons_coe, sub_cons],
exact le_trans (sub_le_sub_right (erase_le _ _) _) (IH u) },
{ rw [← cons_coe, sub_cons, ← cons_coe, sub_cons],
exact IH _ }
end
theorem sub_le_iff_le_add : s - t ≤ u ↔ s ≤ u + t :=
by revert s; exact
multiset.induction_on t (by simp)
(λ a t IH s, by simp [IH, erase_le_iff_le_cons])
theorem le_sub_add (s t : multiset α) : s ≤ s - t + t :=
sub_le_iff_le_add.1 (le_refl _)
theorem sub_le_self (s t : multiset α) : s - t ≤ s :=
sub_le_iff_le_add.2 (le_add_right _ _)
@[simp] theorem card_sub {s t : multiset α} (h : t ≤ s) : card (s - t) = card s - card t :=
(nat.sub_eq_of_eq_add $ by rw [add_comm, ← card_add, sub_add_cancel h]).symm
/-! ### Union -/
/-- `s ∪ t` is the lattice join operation with respect to the
multiset `≤`. The multiplicity of `a` in `s ∪ t` is the maximum
of the multiplicities in `s` and `t`. -/
def union (s t : multiset α) : multiset α := s - t + t
instance : has_union (multiset α) := ⟨union⟩
theorem union_def (s t : multiset α) : s ∪ t = s - t + t := rfl
theorem le_union_left (s t : multiset α) : s ≤ s ∪ t := le_sub_add _ _
theorem le_union_right (s t : multiset α) : t ≤ s ∪ t := le_add_left _ _
theorem eq_union_left : t ≤ s → s ∪ t = s := sub_add_cancel
theorem union_le_union_right (h : s ≤ t) (u) : s ∪ u ≤ t ∪ u :=
add_le_add_right (sub_le_sub_right h _) u
theorem union_le (h₁ : s ≤ u) (h₂ : t ≤ u) : s ∪ t ≤ u :=
by rw ← eq_union_left h₂; exact union_le_union_right h₁ t
@[simp] theorem mem_union : a ∈ s ∪ t ↔ a ∈ s ∨ a ∈ t :=
⟨λ h, (mem_add.1 h).imp_left (mem_of_le $ sub_le_self _ _),
or.rec (mem_of_le $ le_union_left _ _) (mem_of_le $ le_union_right _ _)⟩
@[simp] theorem map_union [decidable_eq β] {f : α → β} (finj : function.injective f)
{s t : multiset α} :
map f (s ∪ t) = map f s ∪ map f t :=
quotient.induction_on₂ s t $ λ l₁ l₂,
congr_arg coe (by rw [list.map_append f, list.map_diff finj])
/-! ### Intersection -/
/-- `s ∩ t` is the lattice meet operation with respect to the
multiset `≤`. The multiplicity of `a` in `s ∩ t` is the minimum
of the multiplicities in `s` and `t`. -/
def inter (s t : multiset α) : multiset α :=
quotient.lift_on₂ s t (λ l₁ l₂, (l₁.bag_inter l₂ : multiset α)) $ λ v₁ v₂ w₁ w₂ p₁ p₂,
quot.sound $ p₁.bag_inter p₂
instance : has_inter (multiset α) := ⟨inter⟩
@[simp] theorem inter_zero (s : multiset α) : s ∩ 0 = 0 :=
quot.induction_on s $ λ l, congr_arg coe l.bag_inter_nil
@[simp] theorem zero_inter (s : multiset α) : 0 ∩ s = 0 :=
quot.induction_on s $ λ l, congr_arg coe l.nil_bag_inter
@[simp] theorem cons_inter_of_pos {a} (s : multiset α) {t} :
a ∈ t → (a ::ₘ s) ∩ t = a ::ₘ s ∩ t.erase a :=
quotient.induction_on₂ s t $ λ l₁ l₂ h,
congr_arg coe $ cons_bag_inter_of_pos _ h
@[simp] theorem cons_inter_of_neg {a} (s : multiset α) {t} :
a ∉ t → (a ::ₘ s) ∩ t = s ∩ t :=
quotient.induction_on₂ s t $ λ l₁ l₂ h,
congr_arg coe $ cons_bag_inter_of_neg _ h
theorem inter_le_left (s t : multiset α) : s ∩ t ≤ s :=
quotient.induction_on₂ s t $ λ l₁ l₂,
(bag_inter_sublist_left _ _).subperm
theorem inter_le_right (s : multiset α) : ∀ t, s ∩ t ≤ t :=
multiset.induction_on s (λ t, (zero_inter t).symm ▸ zero_le _) $
λ a s IH t, if h : a ∈ t
then by simpa [h] using cons_le_cons a (IH (t.erase a))
else by simp [h, IH]
theorem le_inter (h₁ : s ≤ t) (h₂ : s ≤ u) : s ≤ t ∩ u :=
begin
revert s u, refine multiset.induction_on t _ (λ a t IH, _); intros,
{ simp [h₁] },
by_cases a ∈ u,
{ rw [cons_inter_of_pos _ h, ← erase_le_iff_le_cons],
exact IH (erase_le_iff_le_cons.2 h₁) (erase_le_erase _ h₂) },
{ rw cons_inter_of_neg _ h,
exact IH ((le_cons_of_not_mem $ mt (mem_of_le h₂) h).1 h₁) h₂ }
end
@[simp] theorem mem_inter : a ∈ s ∩ t ↔ a ∈ s ∧ a ∈ t :=
⟨λ h, ⟨mem_of_le (inter_le_left _ _) h, mem_of_le (inter_le_right _ _) h⟩,
λ ⟨h₁, h₂⟩, by rw [← cons_erase h₁, cons_inter_of_pos _ h₂]; apply mem_cons_self⟩
instance : lattice (multiset α) :=
{ sup := (∪),
sup_le := @union_le _ _,
le_sup_left := le_union_left,
le_sup_right := le_union_right,
inf := (∩),
le_inf := @le_inter _ _,
inf_le_left := inter_le_left,
inf_le_right := inter_le_right,
..@multiset.partial_order α }
@[simp] theorem sup_eq_union (s t : multiset α) : s ⊔ t = s ∪ t := rfl
@[simp] theorem inf_eq_inter (s t : multiset α) : s ⊓ t = s ∩ t := rfl
@[simp] theorem le_inter_iff : s ≤ t ∩ u ↔ s ≤ t ∧ s ≤ u := le_inf_iff
@[simp] theorem union_le_iff : s ∪ t ≤ u ↔ s ≤ u ∧ t ≤ u := sup_le_iff
instance : semilattice_inf_bot (multiset α) :=
{ bot := 0, bot_le := zero_le, ..multiset.lattice }
theorem union_comm (s t : multiset α) : s ∪ t = t ∪ s := sup_comm
theorem inter_comm (s t : multiset α) : s ∩ t = t ∩ s := inf_comm
theorem eq_union_right (h : s ≤ t) : s ∪ t = t :=
by rw [union_comm, eq_union_left h]
theorem union_le_union_left (h : s ≤ t) (u) : u ∪ s ≤ u ∪ t :=
sup_le_sup_left h _
theorem union_le_add (s t : multiset α) : s ∪ t ≤ s + t :=
union_le (le_add_right _ _) (le_add_left _ _)
theorem union_add_distrib (s t u : multiset α) : (s ∪ t) + u = (s + u) ∪ (t + u) :=
by simpa [(∪), union, eq_comm, add_assoc] using show s + u - (t + u) = s - t,
by rw [add_comm t, sub_add', add_sub_cancel]
theorem add_union_distrib (s t u : multiset α) : s + (t ∪ u) = (s + t) ∪ (s + u) :=
by rw [add_comm, union_add_distrib, add_comm s, add_comm s]
theorem cons_union_distrib (a : α) (s t : multiset α) : a ::ₘ (s ∪ t) = (a ::ₘ s) ∪ (a ::ₘ t) :=
by simpa using add_union_distrib (a ::ₘ 0) s t
theorem inter_add_distrib (s t u : multiset α) : (s ∩ t) + u = (s + u) ∩ (t + u) :=
begin
by_contra h,
cases lt_iff_cons_le.1 (lt_of_le_of_ne (le_inter
(add_le_add_right (inter_le_left s t) u)
(add_le_add_right (inter_le_right s t) u)) h) with a hl,
rw ← cons_add at hl,
exact not_le_of_lt (lt_cons_self (s ∩ t) a) (le_inter
(le_of_add_le_add_right (le_trans hl (inter_le_left _ _)))
(le_of_add_le_add_right (le_trans hl (inter_le_right _ _))))
end
theorem add_inter_distrib (s t u : multiset α) : s + (t ∩ u) = (s + t) ∩ (s + u) :=
by rw [add_comm, inter_add_distrib, add_comm s, add_comm s]
theorem cons_inter_distrib (a : α) (s t : multiset α) : a ::ₘ (s ∩ t) = (a ::ₘ s) ∩ (a ::ₘ t) :=
by simp
theorem union_add_inter (s t : multiset α) : s ∪ t + s ∩ t = s + t :=
begin
apply le_antisymm,
{ rw union_add_distrib,
refine union_le (add_le_add_left (inter_le_right _ _) _) _,
rw add_comm, exact add_le_add_right (inter_le_left _ _) _ },
{ rw [add_comm, add_inter_distrib],
refine le_inter (add_le_add_right (le_union_right _ _) _) _,
rw add_comm, exact add_le_add_right (le_union_left _ _) _ }
end
theorem sub_add_inter (s t : multiset α) : s - t + s ∩ t = s :=
begin
rw [inter_comm],
revert s, refine multiset.induction_on t (by simp) (λ a t IH s, _),
by_cases a ∈ s,
{ rw [cons_inter_of_pos _ h, sub_cons, add_cons, IH, cons_erase h] },
{ rw [cons_inter_of_neg _ h, sub_cons, erase_of_not_mem h, IH] }
end
theorem sub_inter (s t : multiset α) : s - (s ∩ t) = s - t :=
add_right_cancel $
by rw [sub_add_inter s t, sub_add_cancel (inter_le_left _ _)]
end
/-! ### `multiset.filter` -/
section
variables (p : α → Prop) [decidable_pred p]
/-- `filter p s` returns the elements in `s` (with the same multiplicities)
which satisfy `p`, and removes the rest. -/
def filter (s : multiset α) : multiset α :=
quot.lift_on s (λ l, (filter p l : multiset α))
(λ l₁ l₂ h, quot.sound $ h.filter p)
@[simp] theorem coe_filter (l : list α) : filter p (↑l) = l.filter p := rfl
@[simp] theorem filter_zero : filter p 0 = 0 := rfl
lemma filter_congr {p q : α → Prop} [decidable_pred p] [decidable_pred q]
{s : multiset α} : (∀ x ∈ s, p x ↔ q x) → filter p s = filter q s :=
quot.induction_on s $ λ l h, congr_arg coe $ filter_congr h
@[simp] theorem filter_add (s t : multiset α) : filter p (s + t) = filter p s + filter p t :=
quotient.induction_on₂ s t $ λ l₁ l₂, congr_arg coe $ filter_append _ _
@[simp] theorem filter_le (s : multiset α) : filter p s ≤ s :=
quot.induction_on s $ λ l, (filter_sublist _).subperm
@[simp] theorem filter_subset (s : multiset α) : filter p s ⊆ s :=
subset_of_le $ filter_le _ _
theorem filter_le_filter {s t} (h : s ≤ t) : filter p s ≤ filter p t :=
le_induction_on h $ λ l₁ l₂ h, (filter_sublist_filter p h).subperm
variable {p}
@[simp] theorem filter_cons_of_pos {a : α} (s) : p a → filter p (a ::ₘ s) = a ::ₘ filter p s :=
quot.induction_on s $ λ l h, congr_arg coe $ filter_cons_of_pos l h
@[simp] theorem filter_cons_of_neg {a : α} (s) : ¬ p a → filter p (a ::ₘ s) = filter p s :=
quot.induction_on s $ λ l h, @congr_arg _ _ _ _ coe $ filter_cons_of_neg l h
@[simp] theorem mem_filter {a : α} {s} : a ∈ filter p s ↔ a ∈ s ∧ p a :=
quot.induction_on s $ λ l, mem_filter
theorem of_mem_filter {a : α} {s} (h : a ∈ filter p s) : p a :=
(mem_filter.1 h).2
theorem mem_of_mem_filter {a : α} {s} (h : a ∈ filter p s) : a ∈ s :=
(mem_filter.1 h).1
theorem mem_filter_of_mem {a : α} {l} (m : a ∈ l) (h : p a) : a ∈ filter p l :=
mem_filter.2 ⟨m, h⟩
theorem filter_eq_self {s} : filter p s = s ↔ ∀ a ∈ s, p a :=
quot.induction_on s $ λ l, iff.trans ⟨λ h,
eq_of_sublist_of_length_eq (filter_sublist _) (@congr_arg _ _ _ _ card h),
congr_arg coe⟩ filter_eq_self
theorem filter_eq_nil {s} : filter p s = 0 ↔ ∀ a ∈ s, ¬p a :=
quot.induction_on s $ λ l, iff.trans ⟨λ h,
eq_nil_of_length_eq_zero (@congr_arg _ _ _ _ card h),
congr_arg coe⟩ filter_eq_nil
theorem le_filter {s t} : s ≤ filter p t ↔ s ≤ t ∧ ∀ a ∈ s, p a :=
⟨λ h, ⟨le_trans h (filter_le _ _), λ a m, of_mem_filter (mem_of_le h m)⟩,
λ ⟨h, al⟩, filter_eq_self.2 al ▸ filter_le_filter p h⟩
variable (p)
@[simp] theorem filter_sub [decidable_eq α] (s t : multiset α) :
filter p (s - t) = filter p s - filter p t :=
begin
revert s, refine multiset.induction_on t (by simp) (λ a t IH s, _),
rw [sub_cons, IH],
by_cases p a,
{ rw [filter_cons_of_pos _ h, sub_cons], congr,
by_cases m : a ∈ s,
{ rw [← cons_inj_right a, ← filter_cons_of_pos _ h,
cons_erase (mem_filter_of_mem m h), cons_erase m] },
{ rw [erase_of_not_mem m, erase_of_not_mem (mt mem_of_mem_filter m)] } },
{ rw [filter_cons_of_neg _ h],
by_cases m : a ∈ s,
{ rw [(by rw filter_cons_of_neg _ h : filter p (erase s a) = filter p (a ::ₘ erase s a)),
cons_erase m] },
{ rw [erase_of_not_mem m] } }
end
@[simp] theorem filter_union [decidable_eq α] (s t : multiset α) :
filter p (s ∪ t) = filter p s ∪ filter p t :=
by simp [(∪), union]
@[simp] theorem filter_inter [decidable_eq α] (s t : multiset α) :
filter p (s ∩ t) = filter p s ∩ filter p t :=
le_antisymm (le_inter
(filter_le_filter _ $ inter_le_left _ _)
(filter_le_filter _ $ inter_le_right _ _)) $ le_filter.2
⟨inf_le_inf (filter_le _ _) (filter_le _ _),
λ a h, of_mem_filter (mem_of_le (inter_le_left _ _) h)⟩
@[simp] theorem filter_filter (q) [decidable_pred q] (s : multiset α) :
filter p (filter q s) = filter (λ a, p a ∧ q a) s :=
quot.induction_on s $ λ l, congr_arg coe $ filter_filter p q l
theorem filter_add_filter (q) [decidable_pred q] (s : multiset α) :
filter p s + filter q s = filter (λ a, p a ∨ q a) s + filter (λ a, p a ∧ q a) s :=
multiset.induction_on s rfl $ λ a s IH,
by by_cases p a; by_cases q a; simp *
theorem filter_add_not (s : multiset α) :
filter p s + filter (λ a, ¬ p a) s = s :=
by rw [filter_add_filter, filter_eq_self.2, filter_eq_nil.2]; simp [decidable.em]
theorem map_filter (f : β → α) (s : multiset β) :
filter p (map f s) = map f (filter (p ∘ f) s) :=
quot.induction_on s (λ l, by simp [map_filter])
/-! ### Simultaneously filter and map elements of a multiset -/
/-- `filter_map f s` is a combination filter/map operation on `s`.
The function `f : α → option β` is applied to each element of `s`;
if `f a` is `some b` then `b` is added to the result, otherwise
`a` is removed from the resulting multiset. -/
def filter_map (f : α → option β) (s : multiset α) : multiset β :=
quot.lift_on s (λ l, (filter_map f l : multiset β))
(λ l₁ l₂ h, quot.sound $ h.filter_map f)
@[simp] theorem coe_filter_map (f : α → option β) (l : list α) :
filter_map f l = l.filter_map f := rfl
@[simp] theorem filter_map_zero (f : α → option β) : filter_map f 0 = 0 := rfl
@[simp] theorem filter_map_cons_none {f : α → option β} (a : α) (s : multiset α) (h : f a = none) :
filter_map f (a ::ₘ s) = filter_map f s :=
quot.induction_on s $ λ l, @congr_arg _ _ _ _ coe $ filter_map_cons_none a l h
@[simp] theorem filter_map_cons_some (f : α → option β)
(a : α) (s : multiset α) {b : β} (h : f a = some b) :
filter_map f (a ::ₘ s) = b ::ₘ filter_map f s :=
quot.induction_on s $ λ l, @congr_arg _ _ _ _ coe $ filter_map_cons_some f a l h
theorem filter_map_eq_map (f : α → β) : filter_map (some ∘ f) = map f :=
funext $ λ s, quot.induction_on s $ λ l,
@congr_arg _ _ _ _ coe $ congr_fun (filter_map_eq_map f) l
theorem filter_map_eq_filter : filter_map (option.guard p) = filter p :=
funext $ λ s, quot.induction_on s $ λ l,
@congr_arg _ _ _ _ coe $ congr_fun (filter_map_eq_filter p) l
theorem filter_map_filter_map (f : α → option β) (g : β → option γ) (s : multiset α) :
filter_map g (filter_map f s) = filter_map (λ x, (f x).bind g) s :=
quot.induction_on s $ λ l, congr_arg coe $ filter_map_filter_map f g l
theorem map_filter_map (f : α → option β) (g : β → γ) (s : multiset α) :
map g (filter_map f s) = filter_map (λ x, (f x).map g) s :=
quot.induction_on s $ λ l, congr_arg coe $ map_filter_map f g l
theorem filter_map_map (f : α → β) (g : β → option γ) (s : multiset α) :
filter_map g (map f s) = filter_map (g ∘ f) s :=
quot.induction_on s $ λ l, congr_arg coe $ filter_map_map f g l
theorem filter_filter_map (f : α → option β) (p : β → Prop) [decidable_pred p] (s : multiset α) :
filter p (filter_map f s) = filter_map (λ x, (f x).filter p) s :=
quot.induction_on s $ λ l, congr_arg coe $ filter_filter_map f p l
theorem filter_map_filter (f : α → option β) (s : multiset α) :
filter_map f (filter p s) = filter_map (λ x, if p x then f x else none) s :=
quot.induction_on s $ λ l, congr_arg coe $ filter_map_filter p f l
@[simp] theorem filter_map_some (s : multiset α) : filter_map some s = s :=
quot.induction_on s $ λ l, congr_arg coe $ filter_map_some l
@[simp] theorem mem_filter_map (f : α → option β) (s : multiset α) {b : β} :
b ∈ filter_map f s ↔ ∃ a, a ∈ s ∧ f a = some b :=
quot.induction_on s $ λ l, mem_filter_map f l
theorem map_filter_map_of_inv (f : α → option β) (g : β → α)
(H : ∀ x : α, (f x).map g = some x) (s : multiset α) :
map g (filter_map f s) = s :=
quot.induction_on s $ λ l, congr_arg coe $ map_filter_map_of_inv f g H l
theorem filter_map_le_filter_map (f : α → option β) {s t : multiset α}
(h : s ≤ t) : filter_map f s ≤ filter_map f t :=
le_induction_on h $ λ l₁ l₂ h, (h.filter_map _).subperm
/-! ### countp -/
/-- `countp p s` counts the number of elements of `s` (with multiplicity) that
satisfy `p`. -/
def countp (s : multiset α) : ℕ :=
quot.lift_on s (countp p) (λ l₁ l₂, perm.countp_eq p)
@[simp] theorem coe_countp (l : list α) : countp p l = l.countp p := rfl
@[simp] theorem countp_zero : countp p 0 = 0 := rfl
variable {p}
@[simp] theorem countp_cons_of_pos {a : α} (s) : p a → countp p (a ::ₘ s) = countp p s + 1 :=
quot.induction_on s $ countp_cons_of_pos p
@[simp] theorem countp_cons_of_neg {a : α} (s) : ¬ p a → countp p (a ::ₘ s) = countp p s :=
quot.induction_on s $ countp_cons_of_neg p
variable (p)
theorem countp_eq_card_filter (s) : countp p s = card (filter p s) :=
quot.induction_on s $ λ l, countp_eq_length_filter _ _
@[simp] theorem countp_add (s t) : countp p (s + t) = countp p s + countp p t :=
by simp [countp_eq_card_filter]
instance countp.is_add_monoid_hom : is_add_monoid_hom (countp p : multiset α → ℕ) :=
{ map_add := countp_add _, map_zero := countp_zero _ }
@[simp] theorem countp_sub [decidable_eq α] {s t : multiset α} (h : t ≤ s) :
countp p (s - t) = countp p s - countp p t :=
by simp [countp_eq_card_filter, h, filter_le_filter]
theorem countp_le_of_le {s t} (h : s ≤ t) : countp p s ≤ countp p t :=
by simpa [countp_eq_card_filter] using card_le_of_le (filter_le_filter p h)
@[simp] theorem countp_filter (q) [decidable_pred q] (s : multiset α) :
countp p (filter q s) = countp (λ a, p a ∧ q a) s :=
by simp [countp_eq_card_filter]
variable {p}
theorem countp_pos {s} : 0 < countp p s ↔ ∃ a ∈ s, p a :=
by simp [countp_eq_card_filter, card_pos_iff_exists_mem]
theorem countp_pos_of_mem {s a} (h : a ∈ s) (pa : p a) : 0 < countp p s :=
countp_pos.2 ⟨_, h, pa⟩
end
/-! ### Multiplicity of an element -/
section
variable [decidable_eq α]
/-- `count a s` is the multiplicity of `a` in `s`. -/
def count (a : α) : multiset α → ℕ := countp (eq a)
@[simp] theorem coe_count (a : α) (l : list α) : count a (↑l) = l.count a := coe_countp _ _
@[simp] theorem count_zero (a : α) : count a 0 = 0 := rfl
@[simp] theorem count_cons_self (a : α) (s : multiset α) : count a (a ::ₘ s) = succ (count a s) :=
countp_cons_of_pos _ rfl
@[simp, priority 990]
theorem count_cons_of_ne {a b : α} (h : a ≠ b) (s : multiset α) : count a (b ::ₘ s) = count a s :=
countp_cons_of_neg _ h
theorem count_le_of_le (a : α) {s t} : s ≤ t → count a s ≤ count a t :=
countp_le_of_le _
theorem count_le_count_cons (a b : α) (s : multiset α) : count a s ≤ count a (b ::ₘ s) :=
count_le_of_le _ (le_cons_self _ _)
theorem count_cons (a b : α) (s : multiset α) :
count a (b ::ₘ s) = count a s + (if a = b then 1 else 0) :=
by by_cases h : a = b; simp [h]
theorem count_singleton (a : α) : count a (a ::ₘ 0) = 1 :=
by simp
@[simp] theorem count_add (a : α) : ∀ s t, count a (s + t) = count a s + count a t :=
countp_add _
instance count.is_add_monoid_hom (a : α) : is_add_monoid_hom (count a : multiset α → ℕ) :=
countp.is_add_monoid_hom _
@[simp] theorem count_nsmul (a : α) (n s) : count a (n • s) = n * count a s :=
by induction n; simp [*, succ_nsmul', succ_mul, zero_nsmul]
theorem count_pos {a : α} {s : multiset α} : 0 < count a s ↔ a ∈ s :=
by simp [count, countp_pos]
@[simp, priority 980]
theorem count_eq_zero_of_not_mem {a : α} {s : multiset α} (h : a ∉ s) : count a s = 0 :=
by_contradiction $ λ h', h $ count_pos.1 (nat.pos_of_ne_zero h')
@[simp] theorem count_eq_zero {a : α} {s : multiset α} : count a s = 0 ↔ a ∉ s :=
iff_not_comm.1 $ count_pos.symm.trans pos_iff_ne_zero
theorem count_ne_zero {a : α} {s : multiset α} : count a s ≠ 0 ↔ a ∈ s :=
by simp [ne.def, count_eq_zero]
@[simp] theorem count_repeat_self (a : α) (n : ℕ) : count a (repeat a n) = n :=
by simp [repeat]
theorem count_repeat (a b : α) (n : ℕ) :
count a (repeat b n) = if (a = b) then n else 0 :=
begin
split_ifs with h₁,
{ rw [h₁, count_repeat_self] },
{ rw [count_eq_zero],
apply mt eq_of_mem_repeat h₁ },
end
@[simp] theorem count_erase_self (a : α) (s : multiset α) :
count a (erase s a) = pred (count a s) :=
begin
by_cases a ∈ s,
{ rw [(by rw cons_erase h : count a s = count a (a ::ₘ erase s a)),
count_cons_self]; refl },
{ rw [erase_of_not_mem h, count_eq_zero.2 h]; refl }
end
@[simp, priority 980] theorem count_erase_of_ne {a b : α} (ab : a ≠ b) (s : multiset α) :
count a (erase s b) = count a s :=
begin
by_cases b ∈ s,
{ rw [← count_cons_of_ne ab, cons_erase h] },
{ rw [erase_of_not_mem h] }
end
@[simp] theorem count_sub (a : α) (s t : multiset α) : count a (s - t) = count a s - count a t :=
begin
revert s, refine multiset.induction_on t (by simp) (λ b t IH s, _),
rw [sub_cons, IH],
by_cases ab : a = b,
{ subst b, rw [count_erase_self, count_cons_self, sub_succ, pred_sub] },
{ rw [count_erase_of_ne ab, count_cons_of_ne ab] }
end
@[simp] theorem count_union (a : α) (s t : multiset α) :
count a (s ∪ t) = max (count a s) (count a t) :=
by simp [(∪), union, sub_add_eq_max, -add_comm]
@[simp] theorem count_inter (a : α) (s t : multiset α) :
count a (s ∩ t) = min (count a s) (count a t) :=
begin
apply @nat.add_left_cancel (count a (s - t)),
rw [← count_add, sub_add_inter, count_sub, sub_add_min],
end
lemma count_sum {m : multiset β} {f : β → multiset α} {a : α} :
count a (map f m).sum = sum (m.map $ λb, count a $ f b) :=
multiset.induction_on m (by simp) ( by simp)
lemma count_bind {m : multiset β} {f : β → multiset α} {a : α} :
count a (bind m f) = sum (m.map $ λb, count a $ f b) := count_sum
theorem le_count_iff_repeat_le {a : α} {s : multiset α} {n : ℕ} : n ≤ count a s ↔ repeat a n ≤ s :=
quot.induction_on s $ λ l, le_count_iff_repeat_sublist.trans repeat_le_coe.symm
@[simp] theorem count_filter_of_pos {p} [decidable_pred p]
{a} {s : multiset α} (h : p a) : count a (filter p s) = count a s :=
quot.induction_on s $ λ l, count_filter h
@[simp] theorem count_filter_of_neg {p} [decidable_pred p]
{a} {s : multiset α} (h : ¬ p a) : count a (filter p s) = 0 :=
multiset.count_eq_zero_of_not_mem (λ t, h (of_mem_filter t))
theorem ext {s t : multiset α} : s = t ↔ ∀ a, count a s = count a t :=
quotient.induction_on₂ s t $ λ l₁ l₂, quotient.eq.trans perm_iff_count
@[ext]
theorem ext' {s t : multiset α} : (∀ a, count a s = count a t) → s = t :=
ext.2
@[simp] theorem coe_inter (s t : list α) : (s ∩ t : multiset α) = (s.bag_inter t : list α) :=
by ext; simp
theorem le_iff_count {s t : multiset α} : s ≤ t ↔ ∀ a, count a s ≤ count a t :=
⟨λ h a, count_le_of_le a h, λ al,
by rw ← (ext.2 (λ a, by simp [max_eq_right (al a)]) : s ∪ t = t);
apply le_union_left⟩
instance : distrib_lattice (multiset α) :=
{ le_sup_inf := λ s t u, le_of_eq $ eq.symm $
ext.2 $ λ a, by simp only [max_min_distrib_left,
multiset.count_inter, multiset.sup_eq_union, multiset.count_union, multiset.inf_eq_inter],
..multiset.lattice }
instance : semilattice_sup_bot (multiset α) :=
{ bot := 0,
bot_le := zero_le,
..multiset.lattice }
end
@[simp]
lemma mem_nsmul {a : α} {s : multiset α} {n : ℕ} (h0 : n ≠ 0) :
a ∈ n • s ↔ a ∈ s :=
begin
classical,
cases n,
{ exfalso, apply h0 rfl },
rw [← not_iff_not, ← count_eq_zero, ← count_eq_zero],
simp [h0],
end
/-! ### Lift a relation to `multiset`s -/
section rel
/-- `rel r s t` -- lift the relation `r` between two elements to a relation between `s` and `t`,
s.t. there is a one-to-one mapping betweem elements in `s` and `t` following `r`. -/
@[mk_iff] inductive rel (r : α → β → Prop) : multiset α → multiset β → Prop
| zero : rel 0 0
| cons {a b as bs} : r a b → rel as bs → rel (a ::ₘ as) (b ::ₘ bs)
variables {δ : Type*} {r : α → β → Prop} {p : γ → δ → Prop}
private lemma rel_flip_aux {s t} (h : rel r s t) : rel (flip r) t s :=
rel.rec_on h rel.zero (assume _ _ _ _ h₀ h₁ ih, rel.cons h₀ ih)
lemma rel_flip {s t} : rel (flip r) s t ↔ rel r t s :=
⟨rel_flip_aux, rel_flip_aux⟩
lemma rel_refl_of_refl_on {m : multiset α} {r : α → α → Prop} :
(∀ x ∈ m, r x x) → rel r m m :=
begin
apply m.induction_on,
{ intros, apply rel.zero },
{ intros a m ih h,
exact rel.cons (h _ (mem_cons_self _ _)) (ih (λ _ ha, h _ (mem_cons_of_mem ha))) }
end
lemma rel_eq_refl {s : multiset α} : rel (=) s s :=
rel_refl_of_refl_on (λ x hx, rfl)
lemma rel_eq {s t : multiset α} : rel (=) s t ↔ s = t :=
begin
split,
{ assume h, induction h; simp * },
{ assume h, subst h, exact rel_eq_refl }
end
lemma rel.mono {r p : α → β → Prop} {s t} (hst : rel r s t) (h : ∀(a ∈ s) (b ∈ t), r a b → p a b) :
rel p s t :=
begin
induction hst,
case rel.zero { exact rel.zero },
case rel.cons : a b s t hab hst ih {
apply rel.cons (h a (mem_cons_self _ _) b (mem_cons_self _ _) hab),
exact ih (λ a' ha' b' hb' h', h a' (mem_cons_of_mem ha') b' (mem_cons_of_mem hb') h') }
end
lemma rel.add {s t u v} (hst : rel r s t) (huv : rel r u v) : rel r (s + u) (t + v) :=
begin
induction hst,
case rel.zero { simpa using huv },
case rel.cons : a b s t hab hst ih { simpa using ih.cons hab }
end
lemma rel_flip_eq {s t : multiset α} : rel (λa b, b = a) s t ↔ s = t :=
show rel (flip (=)) s t ↔ s = t, by rw [rel_flip, rel_eq, eq_comm]
@[simp] lemma rel_zero_left {b : multiset β} : rel r 0 b ↔ b = 0 :=
by rw [rel_iff]; simp
@[simp] lemma rel_zero_right {a : multiset α} : rel r a 0 ↔ a = 0 :=
by rw [rel_iff]; simp
lemma rel_cons_left {a as bs} :
rel r (a ::ₘ as) bs ↔ (∃b bs', r a b ∧ rel r as bs' ∧ bs = b ::ₘ bs') :=
begin
split,
{ generalize hm : a ::ₘ as = m,
assume h,
induction h generalizing as,
case rel.zero { simp at hm, contradiction },
case rel.cons : a' b as' bs ha'b h ih {
rcases cons_eq_cons.1 hm with ⟨eq₁, eq₂⟩ | ⟨h, cs, eq₁, eq₂⟩,
{ subst eq₁, subst eq₂, exact ⟨b, bs, ha'b, h, rfl⟩ },
{ rcases ih eq₂.symm with ⟨b', bs', h₁, h₂, eq⟩,
exact ⟨b', b ::ₘ bs', h₁, eq₁.symm ▸ rel.cons ha'b h₂, eq.symm ▸ cons_swap _ _ _⟩ }
} },
{ exact assume ⟨b, bs', hab, h, eq⟩, eq.symm ▸ rel.cons hab h }
end
lemma rel_cons_right {as b bs} :
rel r as (b ::ₘ bs) ↔ (∃a as', r a b ∧ rel r as' bs ∧ as = a ::ₘ as') :=
begin
rw [← rel_flip, rel_cons_left],
apply exists_congr, assume a,
apply exists_congr, assume as',
rw [rel_flip, flip]
end
lemma rel_add_left {as₀ as₁} :
∀{bs}, rel r (as₀ + as₁) bs ↔ (∃bs₀ bs₁, rel r as₀ bs₀ ∧ rel r as₁ bs₁ ∧ bs = bs₀ + bs₁) :=
multiset.induction_on as₀ (by simp)
begin
assume a s ih bs,
simp only [ih, cons_add, rel_cons_left],
split,
{ assume h,
rcases h with ⟨b, bs', hab, h, rfl⟩,
rcases h with ⟨bs₀, bs₁, h₀, h₁, rfl⟩,
exact ⟨b ::ₘ bs₀, bs₁, ⟨b, bs₀, hab, h₀, rfl⟩, h₁, by simp⟩ },
{ assume h,
rcases h with ⟨bs₀, bs₁, h, h₁, rfl⟩,
rcases h with ⟨b, bs, hab, h₀, rfl⟩,
exact ⟨b, bs + bs₁, hab, ⟨bs, bs₁, h₀, h₁, rfl⟩, by simp⟩ }
end
lemma rel_add_right {as bs₀ bs₁} :
rel r as (bs₀ + bs₁) ↔ (∃as₀ as₁, rel r as₀ bs₀ ∧ rel r as₁ bs₁ ∧ as = as₀ + as₁) :=
by rw [← rel_flip, rel_add_left]; simp [rel_flip]
lemma rel_map_left {s : multiset γ} {f : γ → α} :
∀{t}, rel r (s.map f) t ↔ rel (λa b, r (f a) b) s t :=
multiset.induction_on s (by simp) (by simp [rel_cons_left] {contextual := tt})
lemma rel_map_right {s : multiset α} {t : multiset γ} {f : γ → β} :
rel r s (t.map f) ↔ rel (λa b, r a (f b)) s t :=
by rw [← rel_flip, rel_map_left, ← rel_flip]; refl
lemma rel_join {s t} (h : rel (rel r) s t) : rel r s.join t.join :=
begin
induction h,
case rel.zero { simp },
case rel.cons : a b s t hab hst ih { simpa using hab.add ih }
end
lemma rel_map {s : multiset α} {t : multiset β} {f : α → γ} {g : β → δ} :
rel p (s.map f) (t.map g) ↔ rel (λa b, p (f a) (g b)) s t :=
rel_map_left.trans rel_map_right
lemma rel_bind {p : γ → δ → Prop} {s t} {f : α → multiset γ} {g : β → multiset δ}
(h : (r ⇒ rel p) f g) (hst : rel r s t) :
rel p (s.bind f) (t.bind g) :=
by { apply rel_join, rw rel_map, exact hst.mono (λ a ha b hb hr, h hr) }
lemma card_eq_card_of_rel {r : α → β → Prop} {s : multiset α} {t : multiset β} (h : rel r s t) :
card s = card t :=
by induction h; simp [*]
lemma exists_mem_of_rel_of_mem {r : α → β → Prop} {s : multiset α} {t : multiset β}
(h : rel r s t) :
∀ {a : α} (ha : a ∈ s), ∃ b ∈ t, r a b :=
begin
induction h with x y s t hxy hst ih,
{ simp },
{ assume a ha,
cases mem_cons.1 ha with ha ha,
{ exact ⟨y, mem_cons_self _ _, ha.symm ▸ hxy⟩ },
{ rcases ih ha with ⟨b, hbt, hab⟩,
exact ⟨b, mem_cons.2 (or.inr hbt), hab⟩ } }
end
lemma rel_of_forall {m1 m2 : multiset α} {r : α → α → Prop} (h : ∀ a b, a ∈ m1 → b ∈ m2 → r a b)
(hc : card m1 = card m2) :
m1.rel r m2 :=
begin
revert m1,
apply m2.induction_on,
{ intros m h hc,
rw [rel_zero_right, ← card_eq_zero, hc, card_zero] },
{ intros a t ih m h hc,
rw card_cons at hc,
obtain ⟨b, hb⟩ := card_pos_iff_exists_mem.1 (show 0 < card m, from hc.symm ▸ (nat.succ_pos _)),
obtain ⟨m', rfl⟩ := exists_cons_of_mem hb,
refine rel_cons_right.mpr ⟨b, m', h _ _ hb (mem_cons_self _ _), ih _ _, rfl⟩,
{ exact λ _ _ ha hb, h _ _ (mem_cons_of_mem ha) (mem_cons_of_mem hb) },
{ simpa using hc } }
end
lemma rel_repeat_left {m : multiset α} {a : α} {r : α → α → Prop} {n : ℕ} :
(repeat a n).rel r m ↔ m.card = n ∧ ∀ x, x ∈ m → r a x :=
⟨λ h, ⟨(card_eq_card_of_rel h).symm.trans (card_repeat _ _), λ x hx, begin
obtain ⟨b, hb1, hb2⟩ := exists_mem_of_rel_of_mem (rel_flip.2 h) hx,
rwa eq_of_mem_repeat hb1 at hb2,
end⟩,
λ h, rel_of_forall (λ x y hx hy, (eq_of_mem_repeat hx).symm ▸ (h.2 _ hy))
(eq.trans (card_repeat _ _) h.1.symm)⟩
lemma rel_repeat_right {m : multiset α} {a : α} {r : α → α → Prop} {n : ℕ} :
m.rel r (repeat a n) ↔ m.card = n ∧ ∀ x, x ∈ m → r x a :=
by { rw [← rel_flip], exact rel_repeat_left }
lemma sum_le_sum_of_rel_le [ordered_add_comm_monoid α]
{m1 m2 : multiset α} (h : m1.rel (≤) m2) : m1.sum ≤ m2.sum :=
begin
induction h with _ _ _ _ rh _ rt,
{ refl },
{ rw [sum_cons, sum_cons],
exact add_le_add rh rt }
end
end rel
section sum_inequalities
variables [ordered_add_comm_monoid α]
lemma sum_map_le_sum
{m : multiset α} (f : α → α) (h : ∀ x, x ∈ m → f x ≤ x) : (m.map f).sum ≤ m.sum :=
sum_le_sum_of_rel_le (rel_map_left.2 (rel_refl_of_refl_on h))
lemma sum_le_sum_map
{m : multiset α} (f : α → α) (h : ∀ x, x ∈ m → x ≤ f x) : m.sum ≤ (m.map f).sum :=
@sum_map_le_sum (order_dual α) _ _ f h
lemma card_nsmul_le_sum {b : α}
{m : multiset α} (h : ∀ x, x ∈ m → b ≤ x) : (card m) • b ≤ m.sum :=
begin
rw [←multiset.sum_repeat, ←multiset.map_const],
exact sum_map_le_sum _ h,
end
lemma sum_le_card_nsmul {b : α}
{m : multiset α} (h : ∀ x, x ∈ m → x ≤ b) : m.sum ≤ (card m) • b :=
begin
rw [←multiset.sum_repeat, ←multiset.map_const],
exact sum_le_sum_map _ h,
end
end sum_inequalities
section map
theorem map_eq_map {f : α → β} (hf : function.injective f) {s t : multiset α} :
s.map f = t.map f ↔ s = t :=
by { rw [← rel_eq, ← rel_eq, rel_map], simp only [hf.eq_iff] }
theorem map_injective {f : α → β} (hf : function.injective f) :
function.injective (multiset.map f) :=
assume x y, (map_eq_map hf).1
end map
section quot
theorem map_mk_eq_map_mk_of_rel {r : α → α → Prop} {s t : multiset α} (hst : s.rel r t) :
s.map (quot.mk r) = t.map (quot.mk r) :=
rel.rec_on hst rfl $ assume a b s t hab hst ih, by simp [ih, quot.sound hab]
theorem exists_multiset_eq_map_quot_mk {r : α → α → Prop} (s : multiset (quot r)) :
∃t:multiset α, s = t.map (quot.mk r) :=
multiset.induction_on s ⟨0, rfl⟩ $
assume a s ⟨t, ht⟩, quot.induction_on a $ assume a, ht.symm ▸ ⟨a ::ₘ t, (map_cons _ _ _).symm⟩
theorem induction_on_multiset_quot
{r : α → α → Prop} {p : multiset (quot r) → Prop} (s : multiset (quot r)) :
(∀s:multiset α, p (s.map (quot.mk r))) → p s :=
match s, exists_multiset_eq_map_quot_mk s with _, ⟨t, rfl⟩ := assume h, h _ end
end quot
/-! ### Disjoint multisets -/
/-- `disjoint s t` means that `s` and `t` have no elements in common. -/
def disjoint (s t : multiset α) : Prop := ∀ ⦃a⦄, a ∈ s → a ∈ t → false
@[simp] theorem coe_disjoint (l₁ l₂ : list α) : @disjoint α l₁ l₂ ↔ l₁.disjoint l₂ := iff.rfl
theorem disjoint.symm {s t : multiset α} (d : disjoint s t) : disjoint t s
| a i₂ i₁ := d i₁ i₂
theorem disjoint_comm {s t : multiset α} : disjoint s t ↔ disjoint t s :=
⟨disjoint.symm, disjoint.symm⟩
theorem disjoint_left {s t : multiset α} : disjoint s t ↔ ∀ {a}, a ∈ s → a ∉ t := iff.rfl
theorem disjoint_right {s t : multiset α} : disjoint s t ↔ ∀ {a}, a ∈ t → a ∉ s :=
disjoint_comm
theorem disjoint_iff_ne {s t : multiset α} : disjoint s t ↔ ∀ a ∈ s, ∀ b ∈ t, a ≠ b :=
by simp [disjoint_left, imp_not_comm]
theorem disjoint_of_subset_left {s t u : multiset α} (h : s ⊆ u) (d : disjoint u t) : disjoint s t
| x m₁ := d (h m₁)
theorem disjoint_of_subset_right {s t u : multiset α} (h : t ⊆ u) (d : disjoint s u) : disjoint s t
| x m m₁ := d m (h m₁)
theorem disjoint_of_le_left {s t u : multiset α} (h : s ≤ u) : disjoint u t → disjoint s t :=
disjoint_of_subset_left (subset_of_le h)
theorem disjoint_of_le_right {s t u : multiset α} (h : t ≤ u) : disjoint s u → disjoint s t :=
disjoint_of_subset_right (subset_of_le h)
@[simp] theorem zero_disjoint (l : multiset α) : disjoint 0 l
| a := (not_mem_nil a).elim
@[simp, priority 1100]
theorem singleton_disjoint {l : multiset α} {a : α} : disjoint (a ::ₘ 0) l ↔ a ∉ l :=
by simp [disjoint]; refl
@[simp, priority 1100]
theorem disjoint_singleton {l : multiset α} {a : α} : disjoint l (a ::ₘ 0) ↔ a ∉ l :=
by rw disjoint_comm; simp
@[simp] theorem disjoint_add_left {s t u : multiset α} :
disjoint (s + t) u ↔ disjoint s u ∧ disjoint t u :=
by simp [disjoint, or_imp_distrib, forall_and_distrib]
@[simp] theorem disjoint_add_right {s t u : multiset α} :
disjoint s (t + u) ↔ disjoint s t ∧ disjoint s u :=
by rw [disjoint_comm, disjoint_add_left]; tauto
@[simp] theorem disjoint_cons_left {a : α} {s t : multiset α} :
disjoint (a ::ₘ s) t ↔ a ∉ t ∧ disjoint s t :=
(@disjoint_add_left _ (a ::ₘ 0) s t).trans $ by simp
@[simp] theorem disjoint_cons_right {a : α} {s t : multiset α} :
disjoint s (a ::ₘ t) ↔ a ∉ s ∧ disjoint s t :=
by rw [disjoint_comm, disjoint_cons_left]; tauto
theorem inter_eq_zero_iff_disjoint [decidable_eq α] {s t : multiset α} : s ∩ t = 0 ↔ disjoint s t :=
by rw ← subset_zero; simp [subset_iff, disjoint]
@[simp] theorem disjoint_union_left [decidable_eq α] {s t u : multiset α} :
disjoint (s ∪ t) u ↔ disjoint s u ∧ disjoint t u :=
by simp [disjoint, or_imp_distrib, forall_and_distrib]
@[simp] theorem disjoint_union_right [decidable_eq α] {s t u : multiset α} :
disjoint s (t ∪ u) ↔ disjoint s t ∧ disjoint s u :=
by simp [disjoint, or_imp_distrib, forall_and_distrib]
lemma disjoint_map_map {f : α → γ} {g : β → γ} {s : multiset α} {t : multiset β} :
disjoint (s.map f) (t.map g) ↔ (∀a∈s, ∀b∈t, f a ≠ g b) :=
by { simp [disjoint, @eq_comm _ (f _) (g _)], refl }
/-- `pairwise r m` states that there exists a list of the elements s.t. `r` holds pairwise on this
list. -/
def pairwise (r : α → α → Prop) (m : multiset α) : Prop :=
∃l:list α, m = l ∧ l.pairwise r
lemma pairwise_coe_iff_pairwise {r : α → α → Prop} (hr : symmetric r) {l : list α} :
multiset.pairwise r l ↔ l.pairwise r :=
iff.intro
(assume ⟨l', eq, h⟩, ((quotient.exact eq).pairwise_iff hr).2 h)
(assume h, ⟨l, rfl, h⟩)
end multiset
namespace multiset
section choose
variables (p : α → Prop) [decidable_pred p] (l : multiset α)
/-- Given a proof `hp` that there exists a unique `a ∈ l` such that `p a`, `choose_x p l hp` returns
that `a` together with proofs of `a ∈ l` and `p a`. -/
def choose_x : Π hp : (∃! a, a ∈ l ∧ p a), { a // a ∈ l ∧ p a } :=
quotient.rec_on l (λ l' ex_unique, list.choose_x p l' (exists_of_exists_unique ex_unique)) begin
intros,
funext hp,
suffices all_equal : ∀ x y : { t // t ∈ b ∧ p t }, x = y,
{ apply all_equal },
{ rintros ⟨x, px⟩ ⟨y, py⟩,
rcases hp with ⟨z, ⟨z_mem_l, pz⟩, z_unique⟩,
congr,
calc x = z : z_unique x px
... = y : (z_unique y py).symm }
end
/-- Given a proof `hp` that there exists a unique `a ∈ l` such that `p a`, `choose p l hp` returns
that `a`. -/
def choose (hp : ∃! a, a ∈ l ∧ p a) : α := choose_x p l hp
lemma choose_spec (hp : ∃! a, a ∈ l ∧ p a) : choose p l hp ∈ l ∧ p (choose p l hp) :=
(choose_x p l hp).property
lemma choose_mem (hp : ∃! a, a ∈ l ∧ p a) : choose p l hp ∈ l := (choose_spec _ _ _).1
lemma choose_property (hp : ∃! a, a ∈ l ∧ p a) : p (choose p l hp) := (choose_spec _ _ _).2
end choose
variable (α)
/-- The equivalence between lists and multisets of a subsingleton type. -/
def subsingleton_equiv [subsingleton α] : list α ≃ multiset α :=
{ to_fun := coe,
inv_fun := quot.lift id $ λ (a b : list α) (h : a ~ b),
list.ext_le h.length_eq $ λ n h₁ h₂, subsingleton.elim _ _,
left_inv := λ l, rfl,
right_inv := λ m, quot.induction_on m $ λ l, rfl }
variable {α}
@[simp]
lemma coe_subsingleton_equiv [subsingleton α] :
(subsingleton_equiv α : list α → multiset α) = coe :=
rfl
end multiset
@[to_additive]
theorem monoid_hom.map_multiset_prod [comm_monoid α] [comm_monoid β] (f : α →* β) (s : multiset α) :
f s.prod = (s.map f).prod :=
(s.prod_hom f).symm
|
bce4ebda7d62abe7a543bfc05c77f8d468aec085 | 7617a8700fc3eebd9200f1e620ee65b3565d2eff | /src/c0/ast.lean | e4edc2334f50a6bbe8fa8c965e32ddb13975261c | [] | no_license | digama0/vc0 | 9747eee791c5c2f58eb53264ca6263ee53de0f87 | b8b192c8c139e0b5a25a7284b93ed53cdf7fd7a5 | refs/heads/master | 1,626,186,940,436 | 1,592,385,972,000 | 1,592,385,972,000 | 158,556,766 | 5 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 2,576 | lean | import c0.common util.basic util.int32
namespace c0
namespace ast
inductive type
| int | bool
| var : ident → type
| ref : type → type
| arr : type → type
| struct : ident → type
-- | the expressions
inductive exp
| int : int32 → exp -- An integer literal e.g. @42@
| bool : bool → exp -- A boolean literal @true@ or @false@
| null -- The null literal for pointers
| var : ident → exp -- an identifier
| binop : binop → exp → exp → exp -- a binary operation @e1 op e2@
| unop : unop → exp → exp -- a unary operation @op e@
| cond : exp → exp → exp → exp -- a ternary conditional @cond ? e1 : e2@
| nil -- an empty expression list
| cons : exp → exp → exp -- a comma (e1, ...) in an expression list
| call : ident → exp → exp -- a function call $f(e1, ..., en)@
| deref : exp → exp -- a pointer dereference @*e@
| index : exp → exp → exp -- an array dereference @e1[e2]@
| field : exp → ident → exp -- a field access @e.f@
| alloc_ref : type → exp -- a pointer allocation @alloc(ty)@
| alloc_arr : type → exp → exp -- an array allocation @alloc_array(ty, len)@
inductive lval
| var : ident → lval
| deref : lval → lval
| index : lval → exp → lval
| field : lval → ident → lval
inductive stmt
| decl : ident → type → stmt → stmt
| decl_asgn : ident → type → exp → stmt → stmt
| If : exp → stmt → stmt → stmt
| while : exp → stmt → stmt
| asgn : lval → exp → stmt -- ^ @x = e;@
| asnop : lval → binop → exp → stmt -- ^ @x op= e;@
| eval : exp → stmt -- ^ @e;@ (a bare expression statement)
| assert : exp → stmt -- ^ @assert(e);@ (an assertion)
| ret : option exp → stmt -- ^ @return e;@
| nop : stmt -- ^ an empty statement
| seq : stmt → stmt → stmt -- ^ @stmt; stmt@
inductive gdecl
| fdecl : bool → ident → list (ident × type) → option type → option stmt → gdecl
| typedef : ident → type → gdecl
| sdecl : ident → option (list (ident × type)) → gdecl
def lval.to_exp : lval → exp
| (lval.var v) := exp.var v
| (lval.deref e) := e.to_exp.deref
| (lval.index e₁ e₂) := e₁.to_exp.index e₂
| (lval.field e f) := e.to_exp.field f
instance : has_andthen stmt stmt stmt := ⟨stmt.seq⟩
def exp.of_list : list exp → exp
| [] := exp.nil
| (e::es) := exp.cons e (exp.of_list es)
end ast
@[reducible] def ast := list ast.gdecl
end c0
|
e647af325a9a1b3f62f157554b85200e7ca42d22 | cbb817439c51008d66b37ce6b1964fea61434d35 | /theorem-proving-in-lean/src/chap_3_take_2.lean | 7a02eb26ca4f8dab7718b361eed613ba28af3703 | [] | no_license | tomhoule/theorem-proving-in-lean-exercises | a07f99d4f6b41ce003e8a0274c7bc46359fa62b2 | 60ccc71b8a6df6924e7cc90aab713b804f78da9f | refs/heads/master | 1,663,582,321,828 | 1,590,352,467,000 | 1,590,352,476,000 | 257,107,936 | 3 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 8,755 | lean |
namespace ex1
variables p q r : Prop
-- >>> Proofs <<< --
theorem and_commutes : p ∧ q ↔ q ∧ p :=
iff.intro
(λ pq, ⟨pq.right, pq.left⟩)
(λ qp, ⟨qp.right, qp.left⟩)
theorem or_commutes : p ∨ q ↔ q ∨ p :=
iff.intro
(λ pq, pq.elim (λ hp, or.inr hp) (λ hq, or.inl hq) )
(λ qp, qp.elim (λ hq, or.inr hq) (λ hp, or.inl hp))
theorem and_associates : (p ∧ q) ∧ r ↔ p ∧ (q ∧ r) :=
have ltr : (p ∧ q) ∧ r → p ∧ (q ∧ r), from λ hpqr, ⟨hpqr.left.left, ⟨hpqr.left.right, hpqr.right⟩⟩,
have rtl : p ∧ (q ∧ r) → (p ∧ q) ∧ r, from λ hpqr, ⟨⟨hpqr.left, hpqr.right.left⟩, hpqr.right.right⟩ ,
⟨ltr, rtl⟩
theorem or_associates : (p ∨ q) ∨ r ↔ p ∨ (q ∨ r) :=
let ltr := λ (h : (p ∨ q) ∨ r),
h.elim
(λ hpq, hpq.elim (λ hp, or.inl hp) (λ hq, or.inr (or.inl hq)))
(λ hr, or.inr (or.inr hr)) in
let rtl := λ (h : p ∨ (q ∨ r)),
h.elim
(λ hp, or.inl (or.inl hp))
(λ hqr, hqr.elim (λ hq, or.inl (or.inr hq)) (λ hr, or.inr hr)) in
⟨ltr, rtl⟩
theorem and_distributes : p ∧ (q ∨ r) ↔ (p ∧ q) ∨ (p ∧ r) :=
have left_to_right : p ∧ (q ∨ r) → (p ∧ q) ∨ (p ∧ r), from
λ h, and.elim h (λ hp hqr, hqr.elim (λ hq, or.inl ⟨hp, hq⟩) (λ hr, or.inr ⟨hp, hr⟩)),
have right_to_left : (p ∧ q) ∨ (p ∧ r) → p ∧ (q ∨ r), from
λ h, or.elim h
(λ hpq, ⟨hpq.left, or.inl hpq.right⟩)
(λ hpr, ⟨hpr.left, or.inr hpr.right⟩),
⟨left_to_right, right_to_left⟩
theorem or_distributes : p ∨ (q ∧ r) ↔ (p ∨ q) ∧ (p ∨ r) :=
have left_to_right : p ∨ (q ∧ r) → (p ∨ q) ∧ (p ∨ r), from
λ h, or.elim h
(λ hp, ⟨or.inl hp, or.inl hp⟩)
(λ hqr, ⟨or.inr hqr.left, or.inr hqr.right⟩),
have right_to_left : (p ∨ q) ∧ (p ∨ r) → p ∨ (q ∧ r), from
λ h, and.elim h
(λ h₁ h₂, h₁.elim (λ hp, or.inl hp) (λ hq, h₂.elim (λ hp, or.inl hp) (λ hr, or.inr ⟨hq, hr⟩))),
⟨left_to_right, right_to_left⟩
theorem implication_flips (h : p → q) (hnq : ¬q): ¬p :=
assume hp : p,
absurd (h hp) hnq
theorem p_and_not_p_is_absurd : ¬(p ∧ ¬p) :=
assume h₁ : p ∧ ¬p,
absurd h₁.left h₁.right
-- negation is a powerful drug
theorem p_is_equivalent_to_not_p_is_absurd : ¬(p ↔ ¬p) :=
assume h,
have p_implies_not_p : p → ¬p, from iff.elim_left h,
have not_p_implies_p : ¬p → p, from iff.elim_right h,
have hnp : ¬p, from λ hp : p, absurd hp (p_implies_not_p hp),
absurd (not_p_implies_p hnp) hnp
theorem implication_composition : (p → (q → r)) ↔ (p ∧ q → r) :=
have left_to_right : (p → (q → r)) → (p ∧ q → r), from λ f₁, λ hpq, (f₁ hpq.left) hpq.right,
have right_to_left : (p ∧ q → r) → (p → (q → r)), from λ f₁ hp hq, f₁ (and.intro hp hq),
⟨left_to_right, right_to_left⟩
theorem disjunct_implications_decomposition : ((p ∨ q) → r) ↔ (p → r) ∧ (q → r) :=
have left_to_right : ((p ∨ q) → r) → (p → r) ∧ (q → r), from λ f, and.intro (λ hp, f $ or.inl hp) (λ hq, f $ or.inr hq),
have right_to_left : (p → r) ∧ (q → r) → ((p ∨ q) → r), from λ fs, λ hor, or.elim hor (λ hp, fs.left hp) (λ hq, fs.right hq),
⟨left_to_right, right_to_left⟩
theorem de_morgan_disjunction : ¬(p ∨ q) ↔ ¬p ∧ ¬q :=
have left_to_right : ¬(p ∨ q) → ¬p ∧ ¬q, from λ hnpq, and.intro (λ hp, hnpq (or.inl hp)) (λ hq, hnpq (or.inr hq)),
have right_to_left : ¬p ∧ ¬q → ¬(p ∨ q), from λ hnpq, assume p_or_q, or.elim p_or_q (λ hp, hnpq.left hp) (λ hq, hnpq.right hq),
⟨left_to_right, right_to_left⟩
theorem disjunction_of_negations_implies_negation_of_conjunction : ¬p ∨ ¬q → ¬(p ∧ q) :=
λ h, assume p_and_q, or.elim h (λ hnp, hnp p_and_q.left) (λ hnq, hnq p_and_q.right)
theorem p_and_not_q_means_p_does_not_imply_q : p ∧ ¬q → ¬(p → q) := λ h, assume ptoq, absurd (ptoq h.left) h.right
theorem p_or_false_equivalent_to_p : p ∨ false ↔ p :=
have left_to_right : p ∨ false → p, from λ h, or.elim h (λ hp, hp) (λ ff, false.elim ff),
have right_to_left : p → p ∨ false, from λ hp, or.inl hp,
⟨left_to_right, right_to_left⟩
theorem p_and_false_equivalent_to_false : p ∧ false ↔ false :=
have left_to_right : p ∧ false → false, from λ pair, pair.right,
have right_to_left : false → p ∧ false, from λ f, false.elim f,
⟨left_to_right, right_to_left⟩
theorem not_p_or_q_implies_p_implies_q : (¬p ∨ q) → (p → q) := λ h, λ hp, or.elim h (λ hnp, absurd hp hnp) (λ hq, hq)
-- >>> Goals <<< --
-- commutativity of ∧ and ∨
example : p ∧ q ↔ q ∧ p := @and_commutes p q
example : p ∨ q ↔ q ∨ p := @or_commutes p q
-- associativity of ∧ and ∨
example : (p ∧ q) ∧ r ↔ p ∧ (q ∧ r) := @and_associates p q r
example : (p ∨ q) ∨ r ↔ p ∨ (q ∨ r) := @or_associates p q r
-- distributivity
example : p ∧ (q ∨ r) ↔ (p ∧ q) ∨ (p ∧ r) := @and_distributes p q r
example : p ∨ (q ∧ r) ↔ (p ∨ q) ∧ (p ∨ r) := @or_distributes p q r
-- other properties
example : (p → (q → r)) ↔ (p ∧ q → r) := @implication_composition p q r
example : ((p ∨ q) → r) ↔ (p → r) ∧ (q → r) := @disjunct_implications_decomposition p q r
example : ¬(p ∨ q) ↔ ¬p ∧ ¬q := @de_morgan_disjunction p q
example : ¬p ∨ ¬q → ¬(p ∧ q) := @disjunction_of_negations_implies_negation_of_conjunction p q
example : ¬(p ∧ ¬p) := @p_and_not_p_is_absurd p
example : p ∧ ¬q → ¬(p → q) := @p_and_not_q_means_p_does_not_imply_q p q
example : ¬p → (p → q) := assume hnp hp, absurd hp hnp
example : (¬p ∨ q) → (p → q) := @not_p_or_q_implies_p_implies_q p q
example : p ∨ false ↔ p := @p_or_false_equivalent_to_p p
example : p ∧ false ↔ false := @p_and_false_equivalent_to_false p
example : ¬(p ↔ ¬p) := @p_is_equivalent_to_not_p_is_absurd p
example : (p → q) → (¬q → ¬p) := @implication_flips p q
end ex1
section ex2
open classical
variables p q r s : Prop
theorem long (h : p → r ∨ s) : (p → r) ∨ (p → s) :=
by_cases
(λ hp : p,
have r_or_s : r ∨ s, from h hp,
or.elim r_or_s (λ hr : r, or.inl (λ hp, hr)) (λ hs : s, or.inr (λ hp, hs))
)
(λ hnp : ¬p, or.inl (λ hp : p, absurd hp hnp))
theorem not_conjunction_implies_disjunction_of_nots (h : ¬(p ∧ q)) : ¬p ∨ ¬q :=
by_cases
(λ hp : p, by_cases (λ hq : q, false.elim $ h (and.intro hp hq)) (λ hnq : ¬q, or.inr hnq))
(λ hnp : ¬p, or.inl hnp)
theorem nptoq_to_p_and_nq (h : ¬(p → q)) : p ∧ ¬q :=
by_cases
(λ hq : q,
have p_to_q : p → q, from λ hp : p, hq,
false.elim $ absurd p_to_q h
)
(λ hnq : ¬q,
by_cases
(λ hp : p, and.intro hp hnq)
(λ hnp : ¬p,
have p_to_q : p → q, from λ hp, absurd hp hnp,
false.elim $ absurd p_to_q h
)
)
theorem p_implies_q_implies_not_p_or_q (h : p → q) : (¬p ∨ q) :=
or.elim (em p)
(λ hp, or.inr (h hp))
(λ hnp, or.inl hnp)
theorem give_this_one_a_name (h : ¬q → ¬p) (hp : p) : q :=
by_contradiction (
λ hnq,
have hnp : ¬p, from h hnq,
absurd hp hnp
)
theorem last_one (h : (p → q) → p) : p :=
or.elim (em p)
(@id p)
(λ hnp,
have p_to_q : p → q, from λ hp, absurd hp hnp,
show p, from h p_to_q
)
example : (p → r ∨ s) → ((p → r) ∨ (p → s)) := @long p r s
example : ¬(p ∧ q) → ¬p ∨ ¬q := @not_conjunction_implies_disjunction_of_nots p q
example : ¬(p → q) → p ∧ ¬q := @nptoq_to_p_and_nq p q
example : (p → q) → (¬p ∨ q) := @p_implies_q_implies_not_p_or_q p q
example : (¬q → ¬p) → (p → q) := @give_this_one_a_name p q
example : p ∨ ¬p := @em p
example : (((p → q) → p) → p) := @last_one p q
end ex2
section ex3
variable p : Prop
example : ¬(p ↔ ¬p) := @ex1.p_is_equivalent_to_not_p_is_absurd p
end ex3
|
8d83306e99724a6663f62794a9a9554b625556dc | 8be24982c807641260370bd09243eac768750811 | /src/Z_Q.lean | 4785ce21ba172ea3d07be339921ff5c5d2855819 | [] | no_license | jjaassoonn/transcendental | 8008813253af3aa80b5a5c56551317e7ab4246ab | 99bc6ea6089f04ed90a0f55f0533ebb7f47b22ff | refs/heads/master | 1,607,869,957,944 | 1,599,659,687,000 | 1,599,659,687,000 | 234,444,826 | 9 | 1 | null | 1,598,218,307,000 | 1,579,224,232,000 | HTML | UTF-8 | Lean | false | false | 8,249 | lean | import ring_theory.algebraic
import small_things
noncomputable theory
open_locale classical
open_locale big_operators
notation `transcendental` x := ¬(is_algebraic ℤ x)
notation `transcendental_over_ℚ` x := ¬(is_algebraic ℚ x)
notation α`[X]` := polynomial α
theorem aeval_sum' (s : finset ℕ) (f : ℕ -> (polynomial ℤ)) (t : ℝ) : @polynomial.aeval ℤ ℝ _ _ _ t (∑ i in s, f i) = ∑ i in s, @polynomial.aeval ℤ ℝ _ _ _ t (f i) :=
begin
apply finset.induction_on s, simp only [finset.sum_empty, alg_hom.map_zero],
intros a s ha ih, rw finset.sum_insert, simp only [alg_hom.map_add], rw ih,
rw finset.sum_insert, exact ha, exact ha,
end
theorem eval₂_sum' (s : finset ℕ) (g : ℤ →+* ℝ) (f : ℕ -> (polynomial ℤ)) (t : ℝ) :
polynomial.eval₂ g t (∑ i in s, f i) = ∑ i in s, polynomial.eval₂ g t (f i) :=
begin
apply finset.induction_on s, simp only [finset.sum_empty, alg_hom.map_zero],
exact is_ring_hom.map_zero (polynomial.eval₂ g t),
intros a s ha ih, rw finset.sum_insert, simp only [polynomial.eval₂_add], rw ih,
rw finset.sum_insert, exact ha, exact ha,
end
theorem algebraic_over_Z_then_algebraic_over_Q (x : ℝ) : is_algebraic ℤ x -> is_algebraic ℚ x :=
begin
rintro ⟨p, p_nonzero, root⟩,
use (p.map (algebra_map ℤ ℚ)),
split,
intro rid,
apply p_nonzero,
apply polynomial.map_injective (algebra_map ℤ ℚ) _,
simp only [polynomial.map_zero], exact rid,
intros x y h, simp only [ring_hom.eq_int_cast, int.cast_inj] at h ⊢, exact h,
rw polynomial.aeval_def,
rw polynomial.eval₂_map,
rw polynomial.as_sum p at root ⊢,
rw aeval_sum' at root,
rw eval₂_sum',
rw <-root,
apply finset.sum_congr, refl, intros m h,
simp only [polynomial.aeval_X, alg_hom.map_pow, polynomial.eval₂_mul, polynomial.eval₂_X_pow, alg_hom.map_mul],
apply congr_arg2,
rw polynomial.eval₂_C,
rw polynomial.aeval_C,
apply congr_fun, ext y,
simp only [ring_hom.eq_int_cast],
refl,
end
example : ℕ[X] :=
begin
exact 0,
end
def rat_to_int_by_mul (r : ℚ) (m : ℕ) : ℤ := (r.num * m) / r.denom
theorem rat_to_int_by_mul_eq (r : ℚ) (m : ℕ) (h : r.denom ∣ m) : ↑(rat_to_int_by_mul r m) = r * m :=
begin
unfold rat_to_int_by_mul,
replace h : ∃ n, m = r.denom * n, exact exists_eq_mul_right_of_dvd h,
rcases h with ⟨n, h⟩, conv_lhs {rw h},
rw int.mul_div_assoc,
push_cast,
rw int.mul_div_cancel_left,
rw h,
norm_cast, push_cast, rw <-mul_assoc,
simp only [rat.mul_denom_eq_num],
norm_cast, intro rid,
have H := r.pos,
rw rid at H, linarith,
norm_cast, exact dvd.intro n rfl,
end
theorem rat_to_int_by_mul_ne_zero (r : ℚ) (m : ℕ) (r_nonzero : r ≠ 0) (hr : r.denom ∣ m) (hm : m ≠ 0) : rat_to_int_by_mul r m ≠ 0 :=
begin
unfold rat_to_int_by_mul,
intro rid,
suffices : r.num * ↑m / ↑(r.denom) < 0 ∨ 0 < r.num * ↑m / ↑(r.denom),
{
cases this; linarith,
},
by_cases (r.num > 0),
{
have key := (@int.lt_div_iff_mul_lt 0 (r.num * m) r.denom _ _).2 _,
linarith,
norm_cast, exact r.pos,
apply dvd_mul_of_dvd_right, norm_cast, exact hr,
simp only [zero_mul], apply mul_pos, exact h,
norm_cast, exact nat.pos_of_ne_zero hm,
},
simp only [not_lt] at h,
replace h : r.num < 0,
{
apply lt_of_le_of_ne, exact h, exact rat.num_ne_zero_of_ne_zero r_nonzero,
},
have key := ((@int.div_lt_iff_lt_mul (r.num * ↑m) 0 r.denom) _).2 _, left, exact key,
norm_cast, exact r.pos, simp only [zero_mul],
apply mul_neg_of_neg_of_pos h, norm_cast, exact nat.pos_of_ne_zero hm,
end
theorem rat_to_int_by_mul_ne_zero' (r : ℚ) (m : ℕ) (hr : r.denom ∣ m) (hm : m ≠ 0) (h : rat_to_int_by_mul r m ≠ 0) :
r ≠ 0 :=
begin
intro rid, rw rid at h,
unfold rat_to_int_by_mul at h,
simp only [zero_mul, euclidean_domain.zero_div, eq_self_iff_true, not_true, ne.def, rat.num_zero] at h,
exact h,
end
def coeffs_denom_prod (p : ℚ[X]) : ℕ :=
(finset.image (λ n, (p.coeff n).denom) p.support).prod id
lemma coeffs_denom_prod_ne_zero (p : ℚ[X]) : coeffs_denom_prod p ≠ 0 :=
begin
unfold coeffs_denom_prod,
rw finset.prod_ne_zero_iff, intros an han,
simp only [exists_prop, finsupp.mem_support_iff, finset.mem_image, ne.def] at han,
rcases han with ⟨n, nonzero, hn⟩, simp only [id.def, ne.def],
intro rid, rw <-hn at rid,
linarith [(p.coeff n).pos],
end
lemma denom_dvd_coeffs_denom_prod (p : ℚ[X]) (n : ℕ) : (p.coeff n).denom ∣ coeffs_denom_prod p :=
begin
by_cases hn : n ∈ p.support,
unfold coeffs_denom_prod,
apply multiset.dvd_prod,
simp only [multiset.mem_erase_dup, id.def, multiset.map_id', multiset.mem_map, finset.image_val],
use (p.coeff n).denom, use n, split, exact hn, refl,
have H := (p.mem_support_to_fun n).2,
replace H := mt H hn,
simp only [not_not] at H,
replace H : p.coeff n = 0, rw <-H, refl,
rw H,
replace H : (0:ℚ).denom = 1, refl, rw H, exact one_dvd (coeffs_denom_prod p),
end
-- #check finset.prod
def rat_poly_to_int_poly (p : ℚ[X]) : ℤ[X] :=
{
support := p.support,
to_fun := λ i, rat_to_int_by_mul (p.coeff i) (coeffs_denom_prod p),
mem_support_to_fun :=
begin
intros n,
split,
{
intros hn,
apply rat_to_int_by_mul_ne_zero,
exact (p.mem_support_to_fun n).1 hn,
apply denom_dvd_coeffs_denom_prod,
apply coeffs_denom_prod_ne_zero,
},
{
intro h,
have H := rat_to_int_by_mul_ne_zero' _ _ _ _ h,
exact (p.mem_support_to_fun n).2 H,
-- apply denom_dvd_coeffs_denom_prod,
by_cases (n ∈ p.support),
apply denom_dvd_coeffs_denom_prod,
apply denom_dvd_coeffs_denom_prod,
apply coeffs_denom_prod_ne_zero,
}
end,
}
lemma rat_poly_to_int_poly_coeff (p : ℚ[X]) (n : ℕ) :
(rat_poly_to_int_poly p).coeff n = rat_to_int_by_mul (p.coeff n) (coeffs_denom_prod p) :=
begin
simp only [rat_poly_to_int_poly, polynomial.coeff_mk],
end
lemma rat_poly_to_int_coeff' (p : ℚ[X]) (n : ℕ) :
↑((rat_poly_to_int_poly p).coeff n) = (p.coeff n) * (coeffs_denom_prod p) :=
begin
rw rat_poly_to_int_poly_coeff,
rw rat_to_int_by_mul_eq,
apply denom_dvd_coeffs_denom_prod,
end
lemma rat_poly_to_int_poly_eq (p : ℚ[X]) :
(rat_poly_to_int_poly p).map (algebra_map ℤ ℚ) = ((polynomial.C (coeffs_denom_prod p : ℚ)) * p) :=
begin
ext,
simp only [rat_poly_to_int_coeff', ring_hom.eq_int_cast, polynomial.coeff_map],
rw polynomial.coeff_C_mul, rw mul_comm,
end
theorem rat_poly_to_int_poly_p_ne_zero (p : ℚ[X]) (hp : p ≠ 0) : rat_poly_to_int_poly p ≠ 0 :=
begin
intro rid,
rw polynomial.ext_iff at rid,
simp only [polynomial.coeff_zero] at rid,
replace hp : ∃ n : ℕ, p.coeff n ≠ 0,
{
by_contra absurd,
simp only [not_exists_not] at absurd,
apply hp, ext, simp only [polynomial.coeff_zero], exact absurd n,
},
rcases hp with ⟨n, hn⟩,
replace rid := rid n,
simp only [rat_poly_to_int_poly_coeff] at rid,
apply rat_to_int_by_mul_ne_zero (p.coeff n) (coeffs_denom_prod p) hn _ _,
exact rid,
apply denom_dvd_coeffs_denom_prod,
apply coeffs_denom_prod_ne_zero,
end
theorem algebraic_over_Q_then_algebraic_over_Z (x : ℝ) : is_algebraic ℚ x -> is_algebraic ℤ x :=
begin
rintro ⟨p, p_nonzero, root⟩,
use rat_poly_to_int_poly p,
split,
apply rat_poly_to_int_poly_p_ne_zero, exact p_nonzero,
have p_eq := rat_poly_to_int_poly_eq p,
suffices : polynomial.aeval x (polynomial.map (algebra_map ℤ ℚ) (rat_poly_to_int_poly p)) = 0,
{
simp only [polynomial.aeval_def] at this ⊢,
rw polynomial.eval₂_map at this,
have eq : (algebra_map ℚ ℝ).comp (algebra_map ℤ ℚ) = algebra_map ℤ ℝ,
{
ext y, simp only [ring_hom.eq_int_cast],
}, rw eq at this, exact this,
},
rw p_eq,
simp only [alg_hom.map_nat_cast, polynomial.C_eq_nat_cast, nat.cast_eq_zero, alg_hom.map_mul, mul_eq_zero],
right, exact root,
end
theorem transcendental_iff_transcendental_over_ℚ (x : ℝ) : (transcendental x) <-> (transcendental_over_ℚ x) :=
begin
split;
intro h;
contrapose h;
rw not_not at h ⊢,
apply algebraic_over_Q_then_algebraic_over_Z _ h,
apply algebraic_over_Z_then_algebraic_over_Q _ h,
end
|
38169b6eeab2316312fe1d323122a105736bc46b | bbecf0f1968d1fba4124103e4f6b55251d08e9c4 | /src/topology/uniform_space/cauchy.lean | 348bb0269f33462910240db8df2cfce8b83d6596 | [
"Apache-2.0"
] | permissive | waynemunro/mathlib | e3fd4ff49f4cb43d4a8ded59d17be407bc5ee552 | 065a70810b5480d584033f7bbf8e0409480c2118 | refs/heads/master | 1,693,417,182,397 | 1,634,644,781,000 | 1,634,644,781,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 30,333 | lean | /-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Mario Carneiro
-/
import topology.uniform_space.basic
import topology.bases
import data.set.intervals
/-!
# Theory of Cauchy filters in uniform spaces. Complete uniform spaces. Totally bounded subsets.
-/
universes u v
open filter topological_space set classical uniform_space
open_locale classical uniformity topological_space filter
variables {α : Type u} {β : Type v} [uniform_space α]
/-- A filter `f` is Cauchy if for every entourage `r`, there exists an
`s ∈ f` such that `s × s ⊆ r`. This is a generalization of Cauchy
sequences, because if `a : ℕ → α` then the filter of sets containing
cofinitely many of the `a n` is Cauchy iff `a` is a Cauchy sequence. -/
def cauchy (f : filter α) := ne_bot f ∧ f ×ᶠ f ≤ (𝓤 α)
/-- A set `s` is called *complete*, if any Cauchy filter `f` such that `s ∈ f`
has a limit in `s` (formally, it satisfies `f ≤ 𝓝 x` for some `x ∈ s`). -/
def is_complete (s : set α) := ∀f, cauchy f → f ≤ 𝓟 s → ∃x∈s, f ≤ 𝓝 x
lemma filter.has_basis.cauchy_iff {p : β → Prop} {s : β → set (α × α)} (h : (𝓤 α).has_basis p s)
{f : filter α} :
cauchy f ↔ (ne_bot f ∧ (∀ i, p i → ∃ t ∈ f, ∀ x y ∈ t, (x, y) ∈ s i)) :=
and_congr iff.rfl $ (f.basis_sets.prod_self.le_basis_iff h).trans $
by simp only [subset_def, prod.forall, mem_prod_eq, and_imp, id]
lemma cauchy_iff' {f : filter α} :
cauchy f ↔ (ne_bot f ∧ (∀ s ∈ 𝓤 α, ∃t∈f, ∀ x y ∈ t, (x, y) ∈ s)) :=
(𝓤 α).basis_sets.cauchy_iff
lemma cauchy_iff {f : filter α} :
cauchy f ↔ (ne_bot f ∧ (∀ s ∈ 𝓤 α, ∃t∈f, (set.prod t t) ⊆ s)) :=
(𝓤 α).basis_sets.cauchy_iff.trans $
by simp only [subset_def, prod.forall, mem_prod_eq, and_imp, id]
lemma cauchy_map_iff {l : filter β} {f : β → α} :
cauchy (l.map f) ↔ (ne_bot l ∧ tendsto (λp:β×β, (f p.1, f p.2)) (l ×ᶠ l) (𝓤 α)) :=
by rw [cauchy, map_ne_bot_iff, prod_map_map_eq, tendsto]
lemma cauchy_map_iff' {l : filter β} [hl : ne_bot l] {f : β → α} :
cauchy (l.map f) ↔ tendsto (λp:β×β, (f p.1, f p.2)) (l ×ᶠ l) (𝓤 α) :=
cauchy_map_iff.trans $ and_iff_right hl
lemma cauchy.mono {f g : filter α} [hg : ne_bot g] (h_c : cauchy f) (h_le : g ≤ f) : cauchy g :=
⟨hg, le_trans (filter.prod_mono h_le h_le) h_c.right⟩
lemma cauchy.mono' {f g : filter α} (h_c : cauchy f) (hg : ne_bot g) (h_le : g ≤ f) : cauchy g :=
h_c.mono h_le
lemma cauchy_nhds {a : α} : cauchy (𝓝 a) :=
⟨nhds_ne_bot,
calc 𝓝 a ×ᶠ 𝓝 a =
(𝓤 α).lift (λs:set (α×α), (𝓤 α).lift' (λt:set(α×α),
set.prod {y : α | (y, a) ∈ s} {y : α | (a, y) ∈ t})) : nhds_nhds_eq_uniformity_uniformity_prod
... ≤ (𝓤 α).lift' (λs:set (α×α), comp_rel s s) :
le_infi $ assume s, le_infi $ assume hs,
infi_le_of_le s $ infi_le_of_le hs $ infi_le_of_le s $ infi_le_of_le hs $
principal_mono.mpr $
assume ⟨x, y⟩ ⟨(hx : (x, a) ∈ s), (hy : (a, y) ∈ s)⟩, ⟨a, hx, hy⟩
... ≤ 𝓤 α : comp_le_uniformity⟩
lemma cauchy_pure {a : α} : cauchy (pure a) :=
cauchy_nhds.mono (pure_le_nhds a)
lemma filter.tendsto.cauchy_map {l : filter β} [ne_bot l] {f : β → α} {a : α}
(h : tendsto f l (𝓝 a)) :
cauchy (map f l) :=
cauchy_nhds.mono h
lemma cauchy.prod [uniform_space β] {f : filter α} {g : filter β} (hf : cauchy f) (hg : cauchy g) :
cauchy (f ×ᶠ g) :=
begin
refine ⟨hf.1.prod hg.1, _⟩,
simp only [uniformity_prod, le_inf_iff, ← map_le_iff_le_comap, ← prod_map_map_eq],
exact ⟨le_trans (prod_mono tendsto_fst tendsto_fst) hf.2,
le_trans (prod_mono tendsto_snd tendsto_snd) hg.2⟩
end
/-- The common part of the proofs of `le_nhds_of_cauchy_adhp` and
`sequentially_complete.le_nhds_of_seq_tendsto_nhds`: if for any entourage `s`
one can choose a set `t ∈ f` of diameter `s` such that it contains a point `y`
with `(x, y) ∈ s`, then `f` converges to `x`. -/
lemma le_nhds_of_cauchy_adhp_aux {f : filter α} {x : α}
(adhs : ∀ s ∈ 𝓤 α, ∃ t ∈ f, (set.prod t t ⊆ s) ∧ ∃ y, (x, y) ∈ s ∧ y ∈ t) :
f ≤ 𝓝 x :=
begin
-- Consider a neighborhood `s` of `x`
assume s hs,
-- Take an entourage twice smaller than `s`
rcases comp_mem_uniformity_sets (mem_nhds_uniformity_iff_right.1 hs) with ⟨U, U_mem, hU⟩,
-- Take a set `t ∈ f`, `t × t ⊆ U`, and a point `y ∈ t` such that `(x, y) ∈ U`
rcases adhs U U_mem with ⟨t, t_mem, ht, y, hxy, hy⟩,
apply mem_of_superset t_mem,
-- Given a point `z ∈ t`, we have `(x, y) ∈ U` and `(y, z) ∈ t × t ⊆ U`, hence `z ∈ s`
exact (λ z hz, hU (prod_mk_mem_comp_rel hxy (ht $ mk_mem_prod hy hz)) rfl)
end
/-- If `x` is an adherent (cluster) point for a Cauchy filter `f`, then it is a limit point
for `f`. -/
lemma le_nhds_of_cauchy_adhp {f : filter α} {x : α} (hf : cauchy f)
(adhs : cluster_pt x f) : f ≤ 𝓝 x :=
le_nhds_of_cauchy_adhp_aux
begin
assume s hs,
obtain ⟨t, t_mem, ht⟩ : ∃ t ∈ f, set.prod t t ⊆ s,
from (cauchy_iff.1 hf).2 s hs,
use [t, t_mem, ht],
exact (forall_mem_nonempty_iff_ne_bot.2 adhs _
(inter_mem_inf (mem_nhds_left x hs) t_mem ))
end
lemma le_nhds_iff_adhp_of_cauchy {f : filter α} {x : α} (hf : cauchy f) :
f ≤ 𝓝 x ↔ cluster_pt x f :=
⟨assume h, cluster_pt.of_le_nhds' h hf.1, le_nhds_of_cauchy_adhp hf⟩
lemma cauchy.map [uniform_space β] {f : filter α} {m : α → β}
(hf : cauchy f) (hm : uniform_continuous m) : cauchy (map m f) :=
⟨hf.1.map _,
calc map m f ×ᶠ map m f = map (λp:α×α, (m p.1, m p.2)) (f ×ᶠ f) : filter.prod_map_map_eq
... ≤ map (λp:α×α, (m p.1, m p.2)) (𝓤 α) : map_mono hf.right
... ≤ 𝓤 β : hm⟩
lemma cauchy.comap [uniform_space β] {f : filter β} {m : α → β}
(hf : cauchy f) (hm : comap (λp:α×α, (m p.1, m p.2)) (𝓤 β) ≤ 𝓤 α)
[ne_bot (comap m f)] : cauchy (comap m f) :=
⟨‹_›,
calc comap m f ×ᶠ comap m f = comap (λp:α×α, (m p.1, m p.2)) (f ×ᶠ f) : filter.prod_comap_comap_eq
... ≤ comap (λp:α×α, (m p.1, m p.2)) (𝓤 β) : comap_mono hf.right
... ≤ 𝓤 α : hm⟩
lemma cauchy.comap' [uniform_space β] {f : filter β} {m : α → β}
(hf : cauchy f) (hm : comap (λp:α×α, (m p.1, m p.2)) (𝓤 β) ≤ 𝓤 α)
(hb : ne_bot (comap m f)) : cauchy (comap m f) :=
hf.comap hm
/-- Cauchy sequences. Usually defined on ℕ, but often it is also useful to say that a function
defined on ℝ is Cauchy at +∞ to deduce convergence. Therefore, we define it in a type class that
is general enough to cover both ℕ and ℝ, which are the main motivating examples. -/
def cauchy_seq [semilattice_sup β] (u : β → α) := cauchy (at_top.map u)
lemma cauchy_seq.tendsto_uniformity [semilattice_sup β] {u : β → α} (h : cauchy_seq u) :
tendsto (prod.map u u) at_top (𝓤 α) :=
by simpa only [tendsto, prod_map_map_eq', prod_at_top_at_top_eq] using h.right
lemma cauchy_seq.nonempty [semilattice_sup β] {u : β → α} (hu : cauchy_seq u) : nonempty β :=
@nonempty_of_ne_bot _ _ $ (map_ne_bot_iff _).1 hu.1
lemma cauchy_seq.mem_entourage {β : Type*} [semilattice_sup β] {u : β → α}
(h : cauchy_seq u) {V : set (α × α)} (hV : V ∈ 𝓤 α) :
∃ k₀, ∀ i j, k₀ ≤ i → k₀ ≤ j → (u i, u j) ∈ V :=
begin
haveI := h.nonempty,
have := h.tendsto_uniformity, rw ← prod_at_top_at_top_eq at this,
simpa [maps_to] using at_top_basis.prod_self.tendsto_left_iff.1 this V hV
end
lemma filter.tendsto.cauchy_seq [semilattice_sup β] [nonempty β] {f : β → α} {x}
(hx : tendsto f at_top (𝓝 x)) :
cauchy_seq f :=
hx.cauchy_map
lemma cauchy_seq_const (x : α) : cauchy_seq (λ n : ℕ, x) :=
tendsto_const_nhds.cauchy_seq
lemma cauchy_seq_iff_tendsto [nonempty β] [semilattice_sup β] {u : β → α} :
cauchy_seq u ↔ tendsto (prod.map u u) at_top (𝓤 α) :=
cauchy_map_iff'.trans $ by simp only [prod_at_top_at_top_eq, prod.map_def]
lemma cauchy_seq.comp_tendsto {γ} [semilattice_sup β] [semilattice_sup γ] [nonempty γ]
{f : β → α} (hf : cauchy_seq f) {g : γ → β} (hg : tendsto g at_top at_top) :
cauchy_seq (f ∘ g) :=
cauchy_seq_iff_tendsto.2 $ hf.tendsto_uniformity.comp (hg.prod_at_top hg)
lemma cauchy_seq.subseq_subseq_mem {V : ℕ → set (α × α)} (hV : ∀ n, V n ∈ 𝓤 α)
{u : ℕ → α} (hu : cauchy_seq u)
{f g : ℕ → ℕ} (hf : tendsto f at_top at_top) (hg : tendsto g at_top at_top) :
∃ φ : ℕ → ℕ, strict_mono φ ∧ ∀ n, ((u ∘ f ∘ φ) n, (u ∘ g ∘ φ) n) ∈ V n :=
begin
rw cauchy_seq_iff_tendsto at hu,
exact ((hu.comp $ hf.prod_at_top hg).comp tendsto_at_top_diagonal).subseq_mem hV,
end
lemma cauchy_seq_iff' {u : ℕ → α} :
cauchy_seq u ↔ ∀ V ∈ 𝓤 α, ∀ᶠ k in at_top, k ∈ (prod.map u u) ⁻¹' V :=
by simpa only [cauchy_seq_iff_tendsto]
lemma cauchy_seq_iff {u : ℕ → α} :
cauchy_seq u ↔ ∀ V ∈ 𝓤 α, ∃ N, ∀ k ≥ N, ∀ l ≥ N, (u k, u l) ∈ V :=
by simp [cauchy_seq_iff', filter.eventually_at_top_prod_self', prod_map]
lemma cauchy_seq.prod_map {γ δ} [uniform_space β] [semilattice_sup γ] [semilattice_sup δ]
{u : γ → α} {v : δ → β}
(hu : cauchy_seq u) (hv : cauchy_seq v) : cauchy_seq (prod.map u v) :=
by simpa only [cauchy_seq, prod_map_map_eq', prod_at_top_at_top_eq] using hu.prod hv
lemma cauchy_seq.prod {γ} [uniform_space β] [semilattice_sup γ] {u : γ → α} {v : γ → β}
(hu : cauchy_seq u) (hv : cauchy_seq v) : cauchy_seq (λ x, (u x, v x)) :=
begin
haveI := hu.nonempty,
exact (hu.prod hv).mono (tendsto.prod_mk le_rfl le_rfl)
end
lemma uniform_continuous.comp_cauchy_seq {γ} [uniform_space β] [semilattice_sup γ]
{f : α → β} (hf : uniform_continuous f) {u : γ → α} (hu : cauchy_seq u) :
cauchy_seq (f ∘ u) :=
hu.map hf
lemma cauchy_seq.subseq_mem {V : ℕ → set (α × α)} (hV : ∀ n, V n ∈ 𝓤 α)
{u : ℕ → α} (hu : cauchy_seq u) :
∃ φ : ℕ → ℕ, strict_mono φ ∧ ∀ n, (u $ φ (n + 1), u $ φ n) ∈ V n :=
begin
have : ∀ n, ∃ N, ∀ k ≥ N, ∀ l ≥ k, (u l, u k) ∈ V n,
{ intro n,
rw [cauchy_seq_iff] at hu,
rcases hu _ (hV n) with ⟨N, H⟩,
exact ⟨N, λ k hk l hl, H _ (le_trans hk hl) _ hk ⟩ },
obtain ⟨φ : ℕ → ℕ, φ_extr : strict_mono φ, hφ : ∀ n, ∀ l ≥ φ n, (u l, u $ φ n) ∈ V n⟩ :=
extraction_forall_of_eventually' this,
exact ⟨φ, φ_extr, λ n, hφ _ _ (φ_extr $ lt_add_one n).le⟩,
end
lemma filter.tendsto.subseq_mem_entourage {V : ℕ → set (α × α)} (hV : ∀ n, V n ∈ 𝓤 α)
{u : ℕ → α} {a : α} (hu : tendsto u at_top (𝓝 a)) :
∃ φ : ℕ → ℕ, strict_mono φ ∧ (u (φ 0), a) ∈ V 0 ∧ ∀ n, (u $ φ (n + 1), u $ φ n) ∈ V (n + 1) :=
begin
rcases mem_at_top_sets.1 (hu (ball_mem_nhds a (symm_le_uniformity $ hV 0))) with ⟨n, hn⟩,
rcases (hu.comp (tendsto_add_at_top_nat n)).cauchy_seq.subseq_mem (λ n, hV (n + 1))
with ⟨φ, φ_mono, hφV⟩,
exact ⟨λ k, φ k + n, φ_mono.add_const _, hn _ le_add_self, hφV⟩
end
/-- If a Cauchy sequence has a convergent subsequence, then it converges. -/
lemma tendsto_nhds_of_cauchy_seq_of_subseq
[semilattice_sup β] {u : β → α} (hu : cauchy_seq u)
{ι : Type*} {f : ι → β} {p : filter ι} [ne_bot p]
(hf : tendsto f p at_top) {a : α} (ha : tendsto (u ∘ f) p (𝓝 a)) :
tendsto u at_top (𝓝 a) :=
le_nhds_of_cauchy_adhp hu (map_cluster_pt_of_comp hf ha)
@[nolint ge_or_gt] -- see Note [nolint_ge]
lemma filter.has_basis.cauchy_seq_iff {γ} [nonempty β] [semilattice_sup β] {u : β → α}
{p : γ → Prop} {s : γ → set (α × α)} (h : (𝓤 α).has_basis p s) :
cauchy_seq u ↔ ∀ i, p i → ∃N, ∀m n≥N, (u m, u n) ∈ s i :=
begin
rw [cauchy_seq_iff_tendsto, ← prod_at_top_at_top_eq],
refine (at_top_basis.prod_self.tendsto_iff h).trans _,
simp only [exists_prop, true_and, maps_to, preimage, subset_def, prod.forall,
mem_prod_eq, mem_set_of_eq, mem_Ici, and_imp, prod.map]
end
lemma filter.has_basis.cauchy_seq_iff' {γ} [nonempty β] [semilattice_sup β] {u : β → α}
{p : γ → Prop} {s : γ → set (α × α)} (H : (𝓤 α).has_basis p s) :
cauchy_seq u ↔ ∀ i, p i → ∃N, ∀n≥N, (u n, u N) ∈ s i :=
begin
refine H.cauchy_seq_iff.trans ⟨λ h i hi, _, λ h i hi, _⟩,
{ exact (h i hi).imp (λ N hN n hn, hN n N hn (le_refl N)) },
{ rcases comp_symm_of_uniformity (H.mem_of_mem hi) with ⟨t, ht, ht', hts⟩,
rcases H.mem_iff.1 ht with ⟨j, hj, hjt⟩,
refine (h j hj).imp (λ N hN m n hm hn, hts ⟨u N, hjt _, ht' $ hjt _⟩),
{ exact hN m hm },
{ exact hN n hn } }
end
lemma cauchy_seq_of_controlled [semilattice_sup β] [nonempty β]
(U : β → set (α × α)) (hU : ∀ s ∈ 𝓤 α, ∃ n, U n ⊆ s)
{f : β → α} (hf : ∀ {N m n : β}, N ≤ m → N ≤ n → (f m, f n) ∈ U N) :
cauchy_seq f :=
cauchy_seq_iff_tendsto.2
begin
assume s hs,
rw [mem_map, mem_at_top_sets],
cases hU s hs with N hN,
refine ⟨(N, N), λ mn hmn, _⟩,
cases mn with m n,
exact hN (hf hmn.1 hmn.2)
end
/-- A complete space is defined here using uniformities. A uniform space
is complete if every Cauchy filter converges. -/
class complete_space (α : Type u) [uniform_space α] : Prop :=
(complete : ∀{f:filter α}, cauchy f → ∃x, f ≤ 𝓝 x)
lemma complete_univ {α : Type u} [uniform_space α] [complete_space α] :
is_complete (univ : set α) :=
begin
assume f hf _,
rcases complete_space.complete hf with ⟨x, hx⟩,
exact ⟨x, mem_univ x, hx⟩
end
instance complete_space.prod [uniform_space β] [complete_space α] [complete_space β] :
complete_space (α × β) :=
{ complete := λ f hf,
let ⟨x1, hx1⟩ := complete_space.complete $ hf.map uniform_continuous_fst in
let ⟨x2, hx2⟩ := complete_space.complete $ hf.map uniform_continuous_snd in
⟨(x1, x2), by rw [nhds_prod_eq, filter.prod_def];
from filter.le_lift (λ s hs, filter.le_lift' $ λ t ht,
have H1 : prod.fst ⁻¹' s ∈ f.sets := hx1 hs,
have H2 : prod.snd ⁻¹' t ∈ f.sets := hx2 ht,
filter.inter_mem H1 H2)⟩ }
/--If `univ` is complete, the space is a complete space -/
lemma complete_space_of_is_complete_univ (h : is_complete (univ : set α)) : complete_space α :=
⟨λ f hf, let ⟨x, _, hx⟩ := h f hf ((@principal_univ α).symm ▸ le_top) in ⟨x, hx⟩⟩
lemma complete_space_iff_is_complete_univ :
complete_space α ↔ is_complete (univ : set α) :=
⟨@complete_univ α _, complete_space_of_is_complete_univ⟩
lemma cauchy_iff_exists_le_nhds [complete_space α] {l : filter α} [ne_bot l] :
cauchy l ↔ (∃x, l ≤ 𝓝 x) :=
⟨complete_space.complete, assume ⟨x, hx⟩, cauchy_nhds.mono hx⟩
lemma cauchy_map_iff_exists_tendsto [complete_space α] {l : filter β} {f : β → α} [ne_bot l] :
cauchy (l.map f) ↔ (∃x, tendsto f l (𝓝 x)) :=
cauchy_iff_exists_le_nhds
/-- A Cauchy sequence in a complete space converges -/
theorem cauchy_seq_tendsto_of_complete [semilattice_sup β] [complete_space α]
{u : β → α} (H : cauchy_seq u) : ∃x, tendsto u at_top (𝓝 x) :=
complete_space.complete H
/-- If `K` is a complete subset, then any cauchy sequence in `K` converges to a point in `K` -/
lemma cauchy_seq_tendsto_of_is_complete [semilattice_sup β] {K : set α} (h₁ : is_complete K)
{u : β → α} (h₂ : ∀ n, u n ∈ K) (h₃ : cauchy_seq u) : ∃ v ∈ K, tendsto u at_top (𝓝 v) :=
h₁ _ h₃ $ le_principal_iff.2 $ mem_map_iff_exists_image.2 ⟨univ, univ_mem,
by { simp only [image_univ], rintros _ ⟨n, rfl⟩, exact h₂ n }⟩
theorem cauchy.le_nhds_Lim [complete_space α] [nonempty α] {f : filter α} (hf : cauchy f) :
f ≤ 𝓝 (Lim f) :=
le_nhds_Lim (complete_space.complete hf)
theorem cauchy_seq.tendsto_lim [semilattice_sup β] [complete_space α] [nonempty α] {u : β → α}
(h : cauchy_seq u) :
tendsto u at_top (𝓝 $ lim at_top u) :=
h.le_nhds_Lim
lemma is_closed.is_complete [complete_space α] {s : set α}
(h : is_closed s) : is_complete s :=
λ f cf fs, let ⟨x, hx⟩ := complete_space.complete cf in
⟨x, is_closed_iff_cluster_pt.mp h x (cf.left.mono (le_inf hx fs)), hx⟩
/-- A set `s` is totally bounded if for every entourage `d` there is a finite
set of points `t` such that every element of `s` is `d`-near to some element of `t`. -/
def totally_bounded (s : set α) : Prop :=
∀d ∈ 𝓤 α, ∃t : set α, finite t ∧ s ⊆ (⋃y∈t, {x | (x,y) ∈ d})
theorem totally_bounded_iff_subset {s : set α} : totally_bounded s ↔
∀d ∈ 𝓤 α, ∃t ⊆ s, finite t ∧ s ⊆ (⋃y∈t, {x | (x,y) ∈ d}) :=
⟨λ H d hd, begin
rcases comp_symm_of_uniformity hd with ⟨r, hr, rs, rd⟩,
rcases H r hr with ⟨k, fk, ks⟩,
let u := k ∩ {y | ∃ x ∈ s, (x, y) ∈ r},
choose hk f hfs hfr using λ x : u, x.coe_prop,
refine ⟨range f, _, _, _⟩,
{ exact range_subset_iff.2 hfs },
{ haveI : fintype u := (fk.inter_of_left _).fintype,
exact finite_range f },
{ intros x xs,
obtain ⟨y, hy, xy⟩ : ∃ y ∈ k, (x, y) ∈ r, from mem_bUnion_iff.1 (ks xs),
rw [bUnion_range, mem_Union],
set z : ↥u := ⟨y, hy, ⟨x, xs, xy⟩⟩,
exact ⟨z, rd $ mem_comp_rel.2 ⟨y, xy, rs (hfr z)⟩⟩ }
end,
λ H d hd, let ⟨t, _, ht⟩ := H d hd in ⟨t, ht⟩⟩
lemma totally_bounded_of_forall_symm {s : set α}
(h : ∀ V ∈ 𝓤 α, symmetric_rel V → ∃ t : set α, finite t ∧ s ⊆ ⋃ y ∈ t, ball y V) :
totally_bounded s :=
begin
intros V V_in,
rcases h _ (symmetrize_mem_uniformity V_in) (symmetric_symmetrize_rel V) with ⟨t, tfin, h⟩,
refine ⟨t, tfin, subset.trans h _⟩,
mono,
intros x x_in z z_in,
exact z_in.right
end
lemma totally_bounded_subset {s₁ s₂ : set α} (hs : s₁ ⊆ s₂)
(h : totally_bounded s₂) : totally_bounded s₁ :=
assume d hd, let ⟨t, ht₁, ht₂⟩ := h d hd in ⟨t, ht₁, subset.trans hs ht₂⟩
lemma totally_bounded_empty : totally_bounded (∅ : set α) :=
λ d hd, ⟨∅, finite_empty, empty_subset _⟩
/-- The closure of a totally bounded set is totally bounded. -/
lemma totally_bounded.closure {s : set α} (h : totally_bounded s) :
totally_bounded (closure s) :=
assume t ht,
let ⟨t', ht', hct', htt'⟩ := mem_uniformity_is_closed ht, ⟨c, hcf, hc⟩ := h t' ht' in
⟨c, hcf,
calc closure s ⊆ closure (⋃ (y : α) (H : y ∈ c), {x : α | (x, y) ∈ t'}) : closure_mono hc
... = _ : is_closed.closure_eq $ is_closed_bUnion hcf $ assume i hi,
continuous_iff_is_closed.mp (continuous_id.prod_mk continuous_const) _ hct'
... ⊆ _ : bUnion_subset $ assume i hi, subset.trans (assume x, @htt' (x, i))
(subset_bUnion_of_mem hi)⟩
/-- The image of a totally bounded set under a unifromly continuous map is totally bounded. -/
lemma totally_bounded.image [uniform_space β] {f : α → β} {s : set α}
(hs : totally_bounded s) (hf : uniform_continuous f) : totally_bounded (f '' s) :=
assume t ht,
have {p:α×α | (f p.1, f p.2) ∈ t} ∈ 𝓤 α,
from hf ht,
let ⟨c, hfc, hct⟩ := hs _ this in
⟨f '' c, hfc.image f,
begin
simp [image_subset_iff],
simp [subset_def] at hct,
intros x hx, simp,
exact hct x hx
end⟩
lemma ultrafilter.cauchy_of_totally_bounded {s : set α} (f : ultrafilter α)
(hs : totally_bounded s) (h : ↑f ≤ 𝓟 s) : cauchy (f : filter α) :=
⟨f.ne_bot', assume t ht,
let ⟨t', ht'₁, ht'_symm, ht'_t⟩ := comp_symm_of_uniformity ht in
let ⟨i, hi, hs_union⟩ := hs t' ht'₁ in
have (⋃y∈i, {x | (x,y) ∈ t'}) ∈ f,
from mem_of_superset (le_principal_iff.mp h) hs_union,
have ∃y∈i, {x | (x,y) ∈ t'} ∈ f,
from (ultrafilter.finite_bUnion_mem_iff hi).1 this,
let ⟨y, hy, hif⟩ := this in
have set.prod {x | (x,y) ∈ t'} {x | (x,y) ∈ t'} ⊆ comp_rel t' t',
from assume ⟨x₁, x₂⟩ ⟨(h₁ : (x₁, y) ∈ t'), (h₂ : (x₂, y) ∈ t')⟩,
⟨y, h₁, ht'_symm h₂⟩,
mem_of_superset (prod_mem_prod hif hif) (subset.trans this ht'_t)⟩
lemma totally_bounded_iff_filter {s : set α} :
totally_bounded s ↔ (∀f, ne_bot f → f ≤ 𝓟 s → ∃c ≤ f, cauchy c) :=
begin
split,
{ introsI H f hf hfs,
exact ⟨ultrafilter.of f, ultrafilter.of_le f,
(ultrafilter.of f).cauchy_of_totally_bounded H ((ultrafilter.of_le f).trans hfs)⟩ },
{ intros H d hd,
contrapose! H with hd_cover,
set f := ⨅ t : finset α, 𝓟 (s \ ⋃ y ∈ t, {x | (x, y) ∈ d}),
have : ne_bot f,
{ refine infi_ne_bot_of_directed' (directed_of_sup _) _,
{ intros t₁ t₂ h,
exact principal_mono.2 (diff_subset_diff_right $ bUnion_subset_bUnion_left h) },
{ intro t,
simpa [nonempty_diff] using hd_cover t t.finite_to_set } },
have : f ≤ 𝓟 s, from infi_le_of_le ∅ (by simp),
refine ⟨f, ‹_›, ‹_›, λ c hcf hc, _⟩,
rcases mem_prod_same_iff.1 (hc.2 hd) with ⟨m, hm, hmd⟩,
have : m ∩ s ∈ c, from inter_mem hm (le_principal_iff.mp (hcf.trans ‹_›)),
rcases hc.1.nonempty_of_mem this with ⟨y, hym, hys⟩,
set ys := ⋃ y' ∈ ({y} : finset α), {x | (x, y') ∈ d},
have : m ⊆ ys, by simpa [ys] using λ x hx, hmd (mk_mem_prod hx hym),
have : c ≤ 𝓟 (s \ ys) := hcf.trans (infi_le_of_le {y} le_rfl),
refine hc.1.ne (empty_mem_iff_bot.mp _),
filter_upwards [le_principal_iff.1 this, hm],
refine λ x hx hxm, hx.2 _,
simpa [ys] using hmd (mk_mem_prod hxm hym) }
end
lemma totally_bounded_iff_ultrafilter {s : set α} :
totally_bounded s ↔ (∀f : ultrafilter α, ↑f ≤ 𝓟 s → cauchy (f : filter α)) :=
begin
refine ⟨λ hs f, f.cauchy_of_totally_bounded hs, λ H, totally_bounded_iff_filter.2 _⟩,
introsI f hf hfs,
exact ⟨ultrafilter.of f, ultrafilter.of_le f, H _ ((ultrafilter.of_le f).trans hfs)⟩
end
lemma compact_iff_totally_bounded_complete {s : set α} :
is_compact s ↔ totally_bounded s ∧ is_complete s :=
⟨λ hs, ⟨totally_bounded_iff_ultrafilter.2 (λ f hf,
let ⟨x, xs, fx⟩ := is_compact_iff_ultrafilter_le_nhds.1 hs f hf in cauchy_nhds.mono fx),
λ f fc fs,
let ⟨a, as, fa⟩ := @hs f fc.1 fs in
⟨a, as, le_nhds_of_cauchy_adhp fc fa⟩⟩,
λ ⟨ht, hc⟩, is_compact_iff_ultrafilter_le_nhds.2
(λf hf, hc _ (totally_bounded_iff_ultrafilter.1 ht f hf) hf)⟩
lemma is_compact.totally_bounded {s : set α} (h : is_compact s) : totally_bounded s :=
(compact_iff_totally_bounded_complete.1 h).1
lemma is_compact.is_complete {s : set α} (h : is_compact s) : is_complete s :=
(compact_iff_totally_bounded_complete.1 h).2
@[priority 100] -- see Note [lower instance priority]
instance complete_of_compact {α : Type u} [uniform_space α] [compact_space α] : complete_space α :=
⟨λf hf, by simpa using (compact_iff_totally_bounded_complete.1 compact_univ).2 f hf⟩
lemma compact_of_totally_bounded_is_closed [complete_space α] {s : set α}
(ht : totally_bounded s) (hc : is_closed s) : is_compact s :=
(@compact_iff_totally_bounded_complete α _ s).2 ⟨ht, hc.is_complete⟩
/-!
### Sequentially complete space
In this section we prove that a uniform space is complete provided that it is sequentially complete
(i.e., any Cauchy sequence converges) and its uniformity filter admits a countable generating set.
In particular, this applies to (e)metric spaces, see the files `topology/metric_space/emetric_space`
and `topology/metric_space/basic`.
More precisely, we assume that there is a sequence of entourages `U_n` such that any other
entourage includes one of `U_n`. Then any Cauchy filter `f` generates a decreasing sequence of
sets `s_n ∈ f` such that `s_n × s_n ⊆ U_n`. Choose a sequence `x_n∈s_n`. It is easy to show
that this is a Cauchy sequence. If this sequence converges to some `a`, then `f ≤ 𝓝 a`. -/
namespace sequentially_complete
variables {f : filter α} (hf : cauchy f) {U : ℕ → set (α × α)}
(U_mem : ∀ n, U n ∈ 𝓤 α) (U_le : ∀ s ∈ 𝓤 α, ∃ n, U n ⊆ s)
open set finset
noncomputable theory
/-- An auxiliary sequence of sets approximating a Cauchy filter. -/
def set_seq_aux (n : ℕ) : {s : set α // ∃ (_ : s ∈ f), s.prod s ⊆ U n } :=
indefinite_description _ $ (cauchy_iff.1 hf).2 (U n) (U_mem n)
/-- Given a Cauchy filter `f` and a sequence `U` of entourages, `set_seq` provides
an antitone sequence of sets `s n ∈ f` such that `(s n).prod (s n) ⊆ U`. -/
def set_seq (n : ℕ) : set α := ⋂ m ∈ Iic n, (set_seq_aux hf U_mem m).val
lemma set_seq_mem (n : ℕ) : set_seq hf U_mem n ∈ f :=
(bInter_mem (finite_le_nat n)).2 (λ m _, (set_seq_aux hf U_mem m).2.fst)
lemma set_seq_mono ⦃m n : ℕ⦄ (h : m ≤ n) : set_seq hf U_mem n ⊆ set_seq hf U_mem m :=
bInter_subset_bInter_left (λ k hk, le_trans hk h)
lemma set_seq_sub_aux (n : ℕ) : set_seq hf U_mem n ⊆ set_seq_aux hf U_mem n :=
bInter_subset_of_mem right_mem_Iic
lemma set_seq_prod_subset {N m n} (hm : N ≤ m) (hn : N ≤ n) :
(set_seq hf U_mem m).prod (set_seq hf U_mem n) ⊆ U N :=
begin
assume p hp,
refine (set_seq_aux hf U_mem N).2.snd ⟨_, _⟩;
apply set_seq_sub_aux,
exact set_seq_mono hf U_mem hm hp.1,
exact set_seq_mono hf U_mem hn hp.2
end
/-- A sequence of points such that `seq n ∈ set_seq n`. Here `set_seq` is an antitone
sequence of sets `set_seq n ∈ f` with diameters controlled by a given sequence
of entourages. -/
def seq (n : ℕ) : α := some $ hf.1.nonempty_of_mem (set_seq_mem hf U_mem n)
lemma seq_mem (n : ℕ) : seq hf U_mem n ∈ set_seq hf U_mem n :=
some_spec $ hf.1.nonempty_of_mem (set_seq_mem hf U_mem n)
lemma seq_pair_mem ⦃N m n : ℕ⦄ (hm : N ≤ m) (hn : N ≤ n) :
(seq hf U_mem m, seq hf U_mem n) ∈ U N :=
set_seq_prod_subset hf U_mem hm hn ⟨seq_mem hf U_mem m, seq_mem hf U_mem n⟩
include U_le
theorem seq_is_cauchy_seq : cauchy_seq $ seq hf U_mem :=
cauchy_seq_of_controlled U U_le $ seq_pair_mem hf U_mem
/-- If the sequence `sequentially_complete.seq` converges to `a`, then `f ≤ 𝓝 a`. -/
theorem le_nhds_of_seq_tendsto_nhds ⦃a : α⦄ (ha : tendsto (seq hf U_mem) at_top (𝓝 a)) :
f ≤ 𝓝 a :=
le_nhds_of_cauchy_adhp_aux
begin
assume s hs,
rcases U_le s hs with ⟨m, hm⟩,
rcases tendsto_at_top'.1 ha _ (mem_nhds_left a (U_mem m)) with ⟨n, hn⟩,
refine ⟨set_seq hf U_mem (max m n), set_seq_mem hf U_mem _, _,
seq hf U_mem (max m n), _, seq_mem hf U_mem _⟩,
{ have := le_max_left m n,
exact set.subset.trans (set_seq_prod_subset hf U_mem this this) hm },
{ exact hm (hn _ $ le_max_right m n) }
end
end sequentially_complete
namespace uniform_space
open sequentially_complete
variables (H : is_countably_generated (𝓤 α))
include H
/-- A uniform space is complete provided that (a) its uniformity filter has a countable basis;
(b) any sequence satisfying a "controlled" version of the Cauchy condition converges. -/
theorem complete_of_convergent_controlled_sequences (U : ℕ → set (α × α)) (U_mem : ∀ n, U n ∈ 𝓤 α)
(HU : ∀ u : ℕ → α, (∀ N m n, N ≤ m → N ≤ n → (u m, u n) ∈ U N) → ∃ a, tendsto u at_top (𝓝 a)) :
complete_space α :=
begin
obtain ⟨U', U'_mono, hU'⟩ := H.exists_antitone_seq',
have Hmem : ∀ n, U n ∩ U' n ∈ 𝓤 α,
from λ n, inter_mem (U_mem n) (hU'.2 ⟨n, subset.refl _⟩),
refine ⟨λ f hf, (HU (seq hf Hmem) (λ N m n hm hn, _)).imp $
le_nhds_of_seq_tendsto_nhds _ _ (λ s hs, _)⟩,
{ rcases (hU'.1 hs) with ⟨N, hN⟩,
exact ⟨N, subset.trans (inter_subset_right _ _) hN⟩ },
{ exact inter_subset_left _ _ (seq_pair_mem hf Hmem hm hn) }
end
/-- A sequentially complete uniform space with a countable basis of the uniformity filter is
complete. -/
theorem complete_of_cauchy_seq_tendsto
(H' : ∀ u : ℕ → α, cauchy_seq u → ∃a, tendsto u at_top (𝓝 a)) :
complete_space α :=
let ⟨U', U'_mono, hU'⟩ := H.exists_antitone_seq' in
complete_of_convergent_controlled_sequences H U' (λ n, hU'.2 ⟨n, subset.refl _⟩)
(λ u hu, H' u $ cauchy_seq_of_controlled U' (λ s hs, hU'.1 hs) hu)
protected lemma first_countable_topology : first_countable_topology α :=
⟨λ a, by { rw nhds_eq_comap_uniformity, exact H.comap (prod.mk a) }⟩
/-- A separable uniform space with countably generated uniformity filter is second countable:
one obtains a countable basis by taking the balls centered at points in a dense subset,
and with rational "radii" from a countable open symmetric antitone basis of `𝓤 α`. We do not
register this as an instance, as there is already an instance going in the other direction
from second countable spaces to separable spaces, and we want to avoid loops. -/
lemma second_countable_of_separable [separable_space α] : second_countable_topology α :=
begin
rcases exists_countable_dense α with ⟨s, hsc, hsd⟩,
obtain ⟨t : ℕ → set (α × α),
hto : ∀ (i : ℕ), t i ∈ (𝓤 α).sets ∧ is_open (t i) ∧ symmetric_rel (t i),
h_basis : (𝓤 α).has_antitone_basis (λ _, true) t⟩ :=
H.exists_antitone_subbasis uniformity_has_basis_open_symmetric,
refine ⟨⟨⋃ (x ∈ s), range (λ k, ball x (t k)), hsc.bUnion (λ x hx, countable_range _), _⟩⟩,
refine (is_topological_basis_of_open_of_nhds _ _).eq_generate_from,
{ simp only [mem_bUnion_iff, mem_range],
rintros _ ⟨x, hxs, k, rfl⟩,
exact is_open_ball x (hto k).2.1 },
{ intros x V hxV hVo,
simp only [mem_bUnion_iff, mem_range, exists_prop],
rcases uniform_space.mem_nhds_iff.1 (is_open.mem_nhds hVo hxV) with ⟨U, hU, hUV⟩,
rcases comp_symm_of_uniformity hU with ⟨U', hU', hsymm, hUU'⟩,
rcases h_basis.to_has_basis.mem_iff.1 hU' with ⟨k, -, hk⟩,
rcases hsd.inter_open_nonempty (ball x $ t k) (uniform_space.is_open_ball x (hto k).2.1)
⟨x, uniform_space.mem_ball_self _ (hto k).1⟩ with ⟨y, hxy, hys⟩,
refine ⟨_, ⟨y, hys, k, rfl⟩, (hto k).2.2.subset hxy, λ z hz, _⟩,
exact hUV (ball_subset_of_comp_subset (hk hxy) hUU' (hk hz)) }
end
end uniform_space
|
a90047ef154c79db2506887092ad793623732db3 | 947b78d97130d56365ae2ec264df196ce769371a | /src/Lean/Meta/Basic.lean | d22dfc30bed5e560ac79e6d1ee2fdfd81a704282 | [
"Apache-2.0"
] | permissive | shyamalschandra/lean4 | 27044812be8698f0c79147615b1d5090b9f4b037 | 6e7a883b21eaf62831e8111b251dc9b18f40e604 | refs/heads/master | 1,671,417,126,371 | 1,601,859,995,000 | 1,601,860,020,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 43,346 | lean | /-
Copyright (c) 2019 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
import Lean.Data.LOption
import Lean.Environment
import Lean.Class
import Lean.ReducibilityAttrs
import Lean.Util.Trace
import Lean.Util.RecDepth
import Lean.Util.PPExt
import Lean.Compiler.InlineAttrs
import Lean.Meta.Exception
import Lean.Meta.TransparencyMode
import Lean.Meta.DiscrTreeTypes
import Lean.Eval
import Lean.CoreM
/-
This module provides four (mutually dependent) goodies that are needed for building the elaborator and tactic frameworks.
1- Weak head normal form computation with support for metavariables and transparency modes.
2- Definitionally equality checking with support for metavariables (aka unification modulo definitional equality).
3- Type inference.
4- Type class resolution.
They are packed into the MetaM monad.
-/
namespace Lean
namespace Meta
structure Config :=
(foApprox : Bool := false)
(ctxApprox : Bool := false)
(quasiPatternApprox : Bool := false)
/- When `constApprox` is set to true,
we solve `?m t =?= c` using
`?m := fun _ => c`
when `?m t` is not a higher-order pattern and `c` is not an application as -/
(constApprox : Bool := false)
/-
When the following flag is set,
`isDefEq` throws the exeption `Exeption.isDefEqStuck`
whenever it encounters a constraint `?m ... =?= t` where
`?m` is read only.
This feature is useful for type class resolution where
we may want to notify the caller that the TC problem may be solveable
later after it assigns `?m`. -/
(isDefEqStuckEx : Bool := false)
(transparency : TransparencyMode := TransparencyMode.default)
/- If zetaNonDep == false, then non dependent let-decls are not zeta expanded. -/
(zetaNonDep : Bool := true)
/- When `trackZeta == true`, we store zetaFVarIds all free variables that have been zeta-expanded. -/
(trackZeta : Bool := false)
structure ParamInfo :=
(implicit : Bool := false)
(instImplicit : Bool := false)
(hasFwdDeps : Bool := false)
(backDeps : Array Nat := #[])
instance ParamInfo.inhabited : Inhabited ParamInfo := ⟨{}⟩
structure FunInfo :=
(paramInfo : Array ParamInfo := #[])
(resultDeps : Array Nat := #[])
structure InfoCacheKey :=
(transparency : TransparencyMode)
(expr : Expr)
(nargs? : Option Nat)
namespace InfoCacheKey
instance : Inhabited InfoCacheKey := ⟨⟨arbitrary _, arbitrary _, arbitrary _⟩⟩
instance : Hashable InfoCacheKey :=
⟨fun ⟨transparency, expr, nargs⟩ => mixHash (hash transparency) $ mixHash (hash expr) (hash nargs)⟩
instance : HasBeq InfoCacheKey :=
⟨fun ⟨t₁, e₁, n₁⟩ ⟨t₂, e₂, n₂⟩ => t₁ == t₂ && n₁ == n₂ && e₁ == e₂⟩
end InfoCacheKey
open Std (PersistentArray PersistentHashMap)
abbrev SynthInstanceCache := PersistentHashMap Expr (Option Expr)
structure Cache :=
(inferType : PersistentExprStructMap Expr := {})
(funInfo : PersistentHashMap InfoCacheKey FunInfo := {})
(synthInstance : SynthInstanceCache := {})
(whnfDefault : PersistentExprStructMap Expr := {}) -- cache for closed terms and `TransparencyMode.default`
(whnfAll : PersistentExprStructMap Expr := {}) -- cache for closed terms and `TransparencyMode.all`
structure State :=
(mctx : MetavarContext := {})
(cache : Cache := {})
/- When `trackZeta == true`, then any let-decl free variable that is zeta expansion performed by `MetaM` is stored in `zetaFVarIds`. -/
(zetaFVarIds : NameSet := {})
instance State.inhabited : Inhabited State := ⟨{}⟩
structure Context :=
(config : Config := {})
(lctx : LocalContext := {})
(localInstances : LocalInstances := #[])
abbrev MetaM := ReaderT Context $ StateRefT State $ CoreM
structure PostponedEntry :=
(lhs : Level)
(rhs : Level)
abbrev DefEqM := StateRefT (PersistentArray PostponedEntry) MetaM
instance : MonadIO MetaM :=
{ liftIO := fun α x => liftM (liftIO x : CoreM α) }
instance MetaM.inhabited {α} : Inhabited (MetaM α) :=
⟨fun _ _ => arbitrary _⟩
instance : MonadLCtx MetaM :=
{ getLCtx := do ctx ← read; pure ctx.lctx }
instance : MonadMCtx MetaM :=
{ getMCtx := do s ← get; pure s.mctx }
instance : AddMessageContext MetaM :=
{ addMessageContext := addMessageContextFull }
instance : Ref MetaM :=
{ getRef := getRef,
withRef := fun α => withRef }
@[inline] def MetaM.run {α} (x : MetaM α) (ctx : Context := {}) (s : State := {}) : CoreM (α × State) :=
(x.run ctx).run s
@[inline] def MetaM.run' {α} (x : MetaM α) (ctx : Context := {}) (s : State := {}) : CoreM α :=
Prod.fst <$> x.run ctx s
@[inline] def MetaM.toIO {α} (x : MetaM α) (ctxCore : Core.Context) (sCore : Core.State) (ctx : Context := {}) (s : State := {}) : IO (α × Core.State × State) := do
((a, s), sCore) ← (x.run ctx s).toIO ctxCore sCore;
pure (a, sCore, s)
instance hasEval {α} [MetaHasEval α] : MetaHasEval (MetaM α) :=
⟨fun env opts x _ => MetaHasEval.eval env opts $ x.run'⟩
protected def throwIsDefEqStuck {α} : DefEqM α :=
throw $ Exception.internal isDefEqStuckExceptionId
@[init] private def regTraceClasses : IO Unit := do
registerTraceClass `Meta;
registerTraceClass `Meta.debug
@[inline] def liftMetaM {α m} [MonadLiftT MetaM m] (x : MetaM α) : m α :=
liftM x
@[inline] def mapMetaM {m} [MonadControlT MetaM m] [Monad m] (f : forall {α}, MetaM α → MetaM α) {α} (x : m α) : m α :=
controlAt MetaM fun runInBase => f $ runInBase x
@[inline] def map1MetaM {β m} [MonadControlT MetaM m] [Monad m] (f : forall {α}, (β → MetaM α) → MetaM α) {α} (k : β → m α) : m α :=
controlAt MetaM fun runInBase => f fun b => runInBase $ k b
@[inline] def map2MetaM {β γ m} [MonadControlT MetaM m] [Monad m] (f : forall {α}, (β → γ → MetaM α) → MetaM α) {α} (k : β → γ → m α) : m α :=
controlAt MetaM fun runInBase => f fun b c => runInBase $ k b c
section Methods
variables {m : Type → Type} [MonadLiftT MetaM m]
variables {n : Type → Type} [MonadControlT MetaM n] [Monad n]
def getLocalInstances : m LocalInstances := liftMetaM do ctx ← read; pure ctx.localInstances
def getConfig : m Config := liftMetaM do ctx ← read; pure ctx.config
def setMCtx (mctx : MetavarContext) : m Unit := liftMetaM $ modify fun s => { s with mctx := mctx }
@[inline] def modifyMCtx (f : MetavarContext → MetavarContext) : m Unit :=
liftMetaM $ modify fun s => { s with mctx := f s.mctx }
def resetZetaFVarIds : m Unit := liftMetaM $ modify fun s => { s with zetaFVarIds := {} }
def getZetaFVarIds : m NameSet := liftMetaM do s ← get; pure s.zetaFVarIds
def mkWHNFRef : IO (IO.Ref (Expr → MetaM Expr)) :=
IO.mkRef $ fun _ => throwError "whnf implementation was not set"
@[init mkWHNFRef] def whnfRef : IO.Ref (Expr → MetaM Expr) := arbitrary _
def mkInferTypeRef : IO (IO.Ref (Expr → MetaM Expr)) :=
IO.mkRef $ fun _ => throwError "inferType implementation was not set"
@[init mkInferTypeRef] def inferTypeRef : IO.Ref (Expr → MetaM Expr) := arbitrary _
def mkIsExprDefEqAuxRef : IO (IO.Ref (Expr → Expr → DefEqM Bool)) :=
IO.mkRef $ fun _ _ => throwError "isDefEq implementation was not set"
@[init mkIsExprDefEqAuxRef] def isExprDefEqAuxRef : IO.Ref (Expr → Expr → DefEqM Bool) := arbitrary _
def mkSynthPendingRef : IO (IO.Ref (MVarId → MetaM Bool)) :=
IO.mkRef $ fun _ => pure false
@[init mkSynthPendingRef] def synthPendingRef : IO.Ref (MVarId → MetaM Bool) := arbitrary _
def whnf (e : Expr) : m Expr :=
liftMetaM $ withIncRecDepth do
fn ← liftIO whnfRef.get;
fn e
def whnfForall [Monad m] (e : Expr) : m Expr := do
e' ← whnf e;
if e'.isForall then pure e' else pure e
def inferType (e : Expr) : m Expr :=
liftMetaM $ withIncRecDepth do
fn ← liftIO inferTypeRef.get;
fn e
protected def isExprDefEqAux (t s : Expr) : DefEqM Bool :=
withIncRecDepth do
fn ← liftIO isExprDefEqAuxRef.get;
fn t s
protected def synthPending (mvarId : MVarId) : MetaM Bool :=
withIncRecDepth do
fn ← liftIO synthPendingRef.get;
fn mvarId
private def mkFreshExprMVarAtCore
(mvarId : MVarId) (lctx : LocalContext) (localInsts : LocalInstances) (type : Expr) (kind : MetavarKind) (userName : Name) (numScopeArgs : Nat) : MetaM Expr := do
modifyMCtx fun mctx => mctx.addExprMVarDecl mvarId userName lctx localInsts type kind numScopeArgs;
pure $ mkMVar mvarId
def mkFreshExprMVarAt
(lctx : LocalContext) (localInsts : LocalInstances) (type : Expr)
(kind : MetavarKind := MetavarKind.natural) (userName : Name := Name.anonymous) (numScopeArgs : Nat := 0)
: m Expr := liftMetaM do
mvarId ← mkFreshId;
mkFreshExprMVarAtCore mvarId lctx localInsts type kind userName numScopeArgs
def mkFreshLevelMVar : m Level := liftMetaM do
mvarId ← mkFreshId;
modifyMCtx fun mctx => mctx.addLevelMVarDecl mvarId;
pure $ mkLevelMVar mvarId
private def mkFreshExprMVarCore (type : Expr) (kind : MetavarKind) (userName : Name) : MetaM Expr := do
lctx ← getLCtx;
localInsts ← getLocalInstances;
mkFreshExprMVarAt lctx localInsts type kind userName
private def mkFreshExprMVarImpl (type? : Option Expr) (kind : MetavarKind) (userName : Name) : MetaM Expr :=
match type? with
| some type => mkFreshExprMVarCore type kind userName
| none => do
u ← mkFreshLevelMVar;
type ← mkFreshExprMVarCore (mkSort u) MetavarKind.natural Name.anonymous;
mkFreshExprMVarCore type kind userName
def mkFreshExprMVar (type? : Option Expr) (kind := MetavarKind.natural) (userName := Name.anonymous) : m Expr :=
liftMetaM $ mkFreshExprMVarImpl type? kind userName
def mkFreshTypeMVar (kind := MetavarKind.natural) (userName := Name.anonymous) : m Expr := liftMetaM do
u ← mkFreshLevelMVar; mkFreshExprMVar (mkSort u) kind userName
/- Low-level version of `MkFreshExprMVar` which allows users to create/reserve a `mvarId` using `mkFreshId`, and then later create
the metavar using this method. -/
private def mkFreshExprMVarWithIdCore (mvarId : MVarId) (type : Expr)
(kind : MetavarKind := MetavarKind.natural) (userName : Name := Name.anonymous) (numScopeArgs : Nat := 0)
: m Expr := liftMetaM do
lctx ← getLCtx;
localInsts ← getLocalInstances;
mkFreshExprMVarAtCore mvarId lctx localInsts type kind userName numScopeArgs
def mkFreshExprMVarWithIdImpl (mvarId : MVarId) (type? : Option Expr) (kind : MetavarKind) (userName : Name) : MetaM Expr :=
match type? with
| some type => mkFreshExprMVarWithIdCore mvarId type kind userName
| none => do
u ← mkFreshLevelMVar;
type ← mkFreshExprMVar (mkSort u);
mkFreshExprMVarWithIdCore mvarId type kind userName
def mkFreshExprMVarWithId (mvarId : MVarId) (type? : Option Expr := none) (kind : MetavarKind := MetavarKind.natural) (userName := Name.anonymous) : m Expr :=
liftMetaM $ mkFreshExprMVarWithIdImpl mvarId type? kind userName
def shouldReduceAll : MetaM Bool := liftMetaM do
ctx ← read; pure $ ctx.config.transparency == TransparencyMode.all
def shouldReduceReducibleOnly : m Bool := liftMetaM do
ctx ← read; pure $ ctx.config.transparency == TransparencyMode.reducible
def getTransparency : m TransparencyMode := liftMetaM do
ctx ← read; pure $ ctx.config.transparency
-- Remark: wanted to use `private`, but in the C++ parser, `private` declarations do not shadow outer public ones.
-- TODO: fix this bug
def isReducible (constName : Name) : MetaM Bool := do
env ← getEnv; pure $ isReducible env constName
def getMVarDecl (mvarId : MVarId) : m MetavarDecl := liftMetaM do
mctx ← getMCtx;
match mctx.findDecl? mvarId with
| some d => pure d
| none => throwError ("unknown metavariable '" ++ mkMVar mvarId ++ "'")
def setMVarKind (mvarId : MVarId) (kind : MetavarKind) : m Unit :=
modifyMCtx fun mctx => mctx.setMVarKind mvarId kind
def isReadOnlyExprMVar (mvarId : MVarId) : m Bool := liftMetaM do
mvarDecl ← getMVarDecl mvarId;
mctx ← getMCtx;
pure $ mvarDecl.depth != mctx.depth
def isReadOnlyOrSyntheticOpaqueExprMVar (mvarId : MVarId) : m Bool := liftMetaM do
mvarDecl ← getMVarDecl mvarId;
match mvarDecl.kind with
| MetavarKind.syntheticOpaque => pure true
| _ => do
mctx ← getMCtx;
pure $ mvarDecl.depth != mctx.depth
def isReadOnlyLevelMVar (mvarId : MVarId) : m Bool := liftMetaM do
mctx ← getMCtx;
match mctx.findLevelDepth? mvarId with
| some depth => pure $ depth != mctx.depth
| _ => throwError ("unknown universe metavariable '" ++ mkLevelMVar mvarId ++ "'")
def renameMVar (mvarId : MVarId) (newUserName : Name) : m Unit :=
modifyMCtx fun mctx => mctx.renameMVar mvarId newUserName
def isExprMVarAssigned (mvarId : MVarId) : m Bool := liftMetaM do
mctx ← getMCtx;
pure $ mctx.isExprAssigned mvarId
def getExprMVarAssignment? (mvarId : MVarId) : m (Option Expr) := liftMetaM do
mctx ← getMCtx; pure (mctx.getExprAssignment? mvarId)
def assignExprMVar (mvarId : MVarId) (val : Expr) : m Unit := liftMetaM do
modifyMCtx fun mctx => mctx.assignExpr mvarId val
def isDelayedAssigned (mvarId : MVarId) : m Bool := liftMetaM do
mctx ← getMCtx;
pure $ mctx.isDelayedAssigned mvarId
def getDelayedAssignment? (mvarId : MVarId) : m (Option DelayedMetavarAssignment) := liftMetaM do
mctx ← getMCtx;
pure $ mctx.getDelayedAssignment? mvarId
def hasAssignableMVar (e : Expr) : m Bool := liftMetaM do
mctx ← getMCtx;
pure $ mctx.hasAssignableMVar e
def throwUnknownFVar {α} (fvarId : FVarId) : MetaM α :=
throwError ("unknown free variable '" ++ mkFVar fvarId ++ "'")
def findLocalDecl? (fvarId : FVarId) : m (Option LocalDecl) := liftMetaM do
lctx ← getLCtx;
pure $ lctx.find? fvarId
def getLocalDecl (fvarId : FVarId) : m LocalDecl := liftMetaM do
lctx ← getLCtx;
match lctx.find? fvarId with
| some d => pure d
| none => throwUnknownFVar fvarId
def getFVarLocalDecl (fvar : Expr) : m LocalDecl := liftMetaM do
getLocalDecl fvar.fvarId!
def getLocalDeclFromUserName (userName : Name) : m LocalDecl := liftMetaM do
lctx ← getLCtx;
match lctx.findFromUserName? userName with
| some d => pure d
| none => throwError ("unknown local declaration '" ++ userName ++ "'")
def instantiateMVars (e : Expr) : m Expr := liftMetaM do
if e.hasMVar then
modifyGet $ fun s =>
let (e, mctx) := s.mctx.instantiateMVars e;
(e, { s with mctx := mctx })
else
pure e
def instantiateLocalDeclMVars (localDecl : LocalDecl) : m LocalDecl := liftMetaM do
match localDecl with
| LocalDecl.cdecl idx id n type bi => do
type ← instantiateMVars type;
pure $ LocalDecl.cdecl idx id n type bi
| LocalDecl.ldecl idx id n type val nonDep => do
type ← instantiateMVars type;
val ← instantiateMVars val;
pure $ LocalDecl.ldecl idx id n type val nonDep
@[inline] private def liftMkBindingM {α} (x : MetavarContext.MkBindingM α) : MetaM α := do
mctx ← getMCtx;
ngen ← getNGen;
lctx ← getLCtx;
match x lctx { mctx := mctx, ngen := ngen } with
| EStateM.Result.ok e newS => do
setNGen newS.ngen;
setMCtx newS.mctx;
pure e
| EStateM.Result.error (MetavarContext.MkBinding.Exception.revertFailure mctx lctx toRevert decl) newS => do
setMCtx newS.mctx;
setNGen newS.ngen;
throwError "failed to create binder due to failure when reverting variable dependencies"
def mkForallFVars (xs : Array Expr) (e : Expr) : m Expr := liftMetaM do
if xs.isEmpty then pure e else liftMkBindingM $ MetavarContext.mkForall xs e
def mkLambdaFVars (xs : Array Expr) (e : Expr) : m Expr := liftMetaM do
if xs.isEmpty then pure e else liftMkBindingM $ MetavarContext.mkLambda xs e
def mkLetFVars (xs : Array Expr) (e : Expr) : m Expr :=
mkLambdaFVars xs e
def mkArrow (d b : Expr) : m Expr := liftMetaM do
n ← mkFreshUserName `x;
pure $ Lean.mkForall n BinderInfo.default d b
def mkForallUsedOnly (xs : Array Expr) (e : Expr) : m (Expr × Nat) := liftMetaM do
if xs.isEmpty then pure (e, 0) else liftMkBindingM $ MetavarContext.mkForallUsedOnly xs e
def elimMVarDeps (xs : Array Expr) (e : Expr) (preserveOrder : Bool := false) : m Expr := liftMetaM do
if xs.isEmpty then pure e else liftMkBindingM $ MetavarContext.elimMVarDeps xs e preserveOrder
@[inline] def withConfig {α} (f : Config → Config) : n α → n α :=
mapMetaM fun _ => adaptReader (fun (ctx : Context) => { ctx with config := f ctx.config })
@[inline] def withTrackingZeta {α} (x : n α) : n α :=
withConfig (fun cfg => { cfg with trackZeta := true }) x
@[inline] def withTransparency {α} (mode : TransparencyMode) : n α → n α :=
mapMetaM fun _ => withConfig (fun config => { config with transparency := mode })
@[inline] def withReducible {α} (x : n α) : n α :=
withTransparency TransparencyMode.reducible x
@[inline] def withAtLeastTransparency {α} (mode : TransparencyMode) (x : n α) : n α :=
withConfig
(fun config =>
let oldMode := config.transparency;
let mode := if oldMode.lt mode then mode else oldMode;
{ config with transparency := mode })
x
def throwUnknownConstant {α} (constName : Name) : MetaM α :=
throwError ("unknown constant '" ++ constName ++ "'")
def getConst? (constName : Name) : MetaM (Option ConstantInfo) := do
env ← getEnv;
match env.find? constName with
| some (info@(ConstantInfo.thmInfo _)) =>
condM shouldReduceAll (pure (some info)) (pure none)
| some (info@(ConstantInfo.defnInfo _)) =>
condM shouldReduceReducibleOnly
(condM (isReducible constName) (pure (some info)) (pure none))
(pure (some info))
| some info => pure (some info)
| none => throwUnknownConstant constName
def getConstNoEx? (constName : Name) : MetaM (Option ConstantInfo) := do
env ← getEnv;
match env.find? constName with
| some (info@(ConstantInfo.thmInfo _)) =>
condM shouldReduceAll (pure (some info)) (pure none)
| some (info@(ConstantInfo.defnInfo _)) =>
condM shouldReduceReducibleOnly
(condM (isReducible constName) (pure (some info)) (pure none))
(pure (some info))
| some info => pure (some info)
| none => pure none
/-- Save cache, execute `x`, restore cache -/
@[inline] private def savingCacheImpl {α} (x : MetaM α) : MetaM α := do
s ← get;
let savedCache := s.cache;
finally x (modify fun s => { s with cache := savedCache })
@[inline] def savingCache {α} : n α → n α :=
mapMetaM fun _ => savingCacheImpl
private def isClassQuickConst? (constName : Name) : MetaM (LOption Name) := do
env ← getEnv;
if isClass env constName then
pure (LOption.some constName)
else do
cinfo? ← getConst? constName;
match cinfo? with
| some _ => pure LOption.undef
| none => pure LOption.none
private partial def isClassQuick? : Expr → MetaM (LOption Name)
| Expr.bvar _ _ => pure LOption.none
| Expr.lit _ _ => pure LOption.none
| Expr.fvar _ _ => pure LOption.none
| Expr.sort _ _ => pure LOption.none
| Expr.lam _ _ _ _ => pure LOption.none
| Expr.letE _ _ _ _ _ => pure LOption.undef
| Expr.proj _ _ _ _ => pure LOption.undef
| Expr.forallE _ _ b _ => isClassQuick? b
| Expr.mdata _ e _ => isClassQuick? e
| Expr.const n _ _ => isClassQuickConst? n
| Expr.mvar mvarId _ => do
val? ← getExprMVarAssignment? mvarId;
match val? with
| some val => isClassQuick? val
| none => pure LOption.none
| Expr.app f _ _ =>
match f.getAppFn with
| Expr.const n _ _ => isClassQuickConst? n
| Expr.lam _ _ _ _ => pure LOption.undef
| _ => pure LOption.none
| Expr.localE _ _ _ _ => unreachable!
def saveAndResetSynthInstanceCache : MetaM SynthInstanceCache := do
s ← get;
let savedSythInstance := s.cache.synthInstance;
modify $ fun s => { s with cache := { s.cache with synthInstance := {} } };
pure savedSythInstance
def restoreSynthInstanceCache (cache : SynthInstanceCache) : MetaM Unit :=
modify $ fun s => { s with cache := { s.cache with synthInstance := cache } }
@[inline] private def resettingSynthInstanceCacheImpl {α} (x : MetaM α) : MetaM α := do
savedSythInstance ← saveAndResetSynthInstanceCache;
finally x (restoreSynthInstanceCache savedSythInstance)
/-- Reset `synthInstance` cache, execute `x`, and restore cache -/
@[inline] def resettingSynthInstanceCache {α} : n α → n α :=
mapMetaM fun _ => resettingSynthInstanceCacheImpl
@[inline] def resettingSynthInstanceCacheWhen {α} (b : Bool) (x : n α) : n α :=
if b then resettingSynthInstanceCache x else x
private def withNewLocalInstanceImp {α} (className : Name) (fvar : Expr) (k : MetaM α) : MetaM α := do
localDecl ← getFVarLocalDecl fvar;
/- Recall that we use `auxDecl` binderInfo when compiling recursive declarations. -/
match localDecl.binderInfo with
| BinderInfo.auxDecl => k
| _ =>
resettingSynthInstanceCache $
adaptReader
(fun (ctx : Context) => { ctx with localInstances := ctx.localInstances.push { className := className, fvar := fvar } })
k
/-- Add entry `{ className := className, fvar := fvar }` to localInstances,
and then execute continuation `k`.
It resets the type class cache using `resettingSynthInstanceCache`. -/
def withNewLocalInstance {α} (className : Name) (fvar : Expr) : n α → n α :=
mapMetaM fun _ => withNewLocalInstanceImp className fvar
/--
`withNewLocalInstances isClassExpensive fvars j k` updates the vector or local instances
using free variables `fvars[j] ... fvars.back`, and execute `k`.
- `isClassExpensive` is defined later.
- The type class chache is reset whenever a new local instance is found.
- `isClassExpensive` uses `whnf` which depends (indirectly) on the set of local instances.
Thus, each new local instance requires a new `resettingSynthInstanceCache`. -/
@[specialize] private partial def withNewLocalInstancesImp {α}
(isClassExpensive? : Expr → MetaM (Option Name))
(fvars : Array Expr) : Nat → MetaM α → MetaM α
| i, k =>
if h : i < fvars.size then do
let fvar := fvars.get ⟨i, h⟩;
decl ← getFVarLocalDecl fvar;
c? ← isClassQuick? decl.type;
match c? with
| LOption.none => withNewLocalInstancesImp (i+1) k
| LOption.undef => do
c? ← isClassExpensive? decl.type;
match c? with
| none => withNewLocalInstancesImp (i+1) k
| some c => withNewLocalInstance c fvar $ withNewLocalInstancesImp (i+1) k
| LOption.some c => withNewLocalInstance c fvar $ withNewLocalInstancesImp (i+1) k
else
k
private def fvarsSizeLtMaxFVars (fvars : Array Expr) (maxFVars? : Option Nat) : Bool :=
match maxFVars? with
| some maxFVars => fvars.size < maxFVars
| none => true
/--
`forallTelescopeAux whnf k lctx fvars j type`
Remarks:
- `lctx` is the `MetaM` local context exteded with the declaration for `fvars`.
- `type` is the type we are computing the telescope for. It contains only
dangling bound variables in the range `[j, fvars.size)`
- if `reducing? == true` and `type` is not `forallE`, we use `whnf`.
- when `type` is not a `forallE` nor it can't be reduced to one, we
excute the continuation `k`.
Here is an example that demonstrates the `reducing?`.
Suppose we have
```
abbrev StateM s a := s -> Prod a s
```
Now, assume we are trying to build the telescope for
```
forall (x : Nat), StateM Int Bool
```
if `reducing? == true`, the function executes `k #[(x : Nat) (s : Int)] Bool`.
if `reducing? == false`, the function executes `k #[(x : Nat)] (StateM Int Bool)`
if `maxFVars?` is `some max`, then we interrupt the telescope construction
when `fvars.size == max`
-/
@[specialize] private partial def forallTelescopeReducingAuxAux {α}
(isClassExpensive? : Expr → MetaM (Option Name))
(reducing? : Bool) (maxFVars? : Option Nat)
(k : Array Expr → Expr → MetaM α)
: LocalContext → Array Expr → Nat → Expr → MetaM α
| lctx, fvars, j, type@(Expr.forallE n d b c) => do
let process : Unit → MetaM α := fun _ => do {
let d := d.instantiateRevRange j fvars.size fvars;
fvarId ← mkFreshId;
let lctx := lctx.mkLocalDecl fvarId n d c.binderInfo;
let fvar := mkFVar fvarId;
let fvars := fvars.push fvar;
forallTelescopeReducingAuxAux lctx fvars j b
};
if fvarsSizeLtMaxFVars fvars maxFVars? then
process ()
else
let type := type.instantiateRevRange j fvars.size fvars;
adaptReader (fun (ctx : Context) => { ctx with lctx := lctx }) $
withNewLocalInstancesImp isClassExpensive? fvars j $
k fvars type
| lctx, fvars, j, type =>
let type := type.instantiateRevRange j fvars.size fvars;
adaptReader (fun (ctx : Context) => { ctx with lctx := lctx }) $
withNewLocalInstancesImp isClassExpensive? fvars j $
if reducing? && fvarsSizeLtMaxFVars fvars maxFVars? then do
newType ← whnf type;
if newType.isForall then
forallTelescopeReducingAuxAux lctx fvars fvars.size newType
else
k fvars type
else
k fvars type
/- We need this auxiliary definition because it depends on `isClassExpensive`,
and `isClassExpensive` depends on it. -/
@[specialize] private def forallTelescopeReducingAux {α}
(isClassExpensive? : Expr → MetaM (Option Name))
(type : Expr) (maxFVars? : Option Nat) (k : Array Expr → Expr → MetaM α) : MetaM α := do
match maxFVars? with
| some 0 => k #[] type
| _ => do
newType ← whnf type;
if newType.isForall then do
lctx ← getLCtx;
forallTelescopeReducingAuxAux isClassExpensive? true maxFVars? k lctx #[] 0 newType
else
k #[] type
private partial def isClassExpensive? : Expr → MetaM (Option Name)
| type => withReducible $ -- when testing whether a type is a type class, we only unfold reducible constants.
forallTelescopeReducingAux isClassExpensive? type none $ fun xs type => do
match type.getAppFn with
| Expr.const c _ _ => do
env ← getEnv;
pure $ if isClass env c then some c else none
| _ => pure none
private def isClassImp? (type : Expr) : MetaM (Option Name) := do
c? ← isClassQuick? type;
match c? with
| LOption.none => pure none
| LOption.some c => pure (some c)
| LOption.undef => isClassExpensive? type
def isClass? (type : Expr) : m (Option Name) :=
liftMetaM $ catch (isClassImp? type) (fun _ => pure none)
private def withNewLocalInstancesImpAux {α} (fvars : Array Expr) (j : Nat) : n α → n α :=
mapMetaM fun _ => withNewLocalInstancesImp isClassExpensive? fvars j
def withNewLocalInstances {α} (fvars : Array Expr) (j : Nat) : n α → n α :=
mapMetaM fun _ => withNewLocalInstancesImpAux fvars j
private def forallTelescopeImp {α} (type : Expr) (k : Array Expr → Expr → MetaM α) : MetaM α := do
lctx ← getLCtx;
forallTelescopeReducingAuxAux isClassExpensive? false none k lctx #[] 0 type
/--
Given `type` of the form `forall xs, A`, execute `k xs A`.
This combinator will declare local declarations, create free variables for them,
execute `k` with updated local context, and make sure the cache is restored after executing `k`. -/
def forallTelescope {α} (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun _ k => forallTelescopeImp type k) k
@[noinline] private def forallTelescopeReducingImp {α} (type : Expr) (k : Array Expr → Expr → MetaM α) : MetaM α :=
forallTelescopeReducingAux isClassExpensive? type none k
/--
Similar to `forallTelescope`, but given `type` of the form `forall xs, A`,
it reduces `A` and continues bulding the telescope if it is a `forall`. -/
def forallTelescopeReducing {α} (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun _ k => forallTelescopeReducingImp type k) k
@[noinline] private def forallBoundedTelescopeImp {α} (type : Expr) (maxFVars? : Option Nat) (k : Array Expr → Expr → MetaM α) : MetaM α :=
forallTelescopeReducingAux isClassExpensive? type maxFVars? k
/--
Similar to `forallTelescopeReducing`, stops constructing the telescope when
it reaches size `maxFVars`. -/
def forallBoundedTelescope {α} (type : Expr) (maxFVars? : Option Nat) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun _ k => forallBoundedTelescopeImp type maxFVars? k) k
/-- Similar to `forallTelescopeAuxAux` but for lambda and let expressions. -/
private partial def lambdaTelescopeAux {α}
(k : Array Expr → Expr → MetaM α)
: Bool → LocalContext → Array Expr → Nat → Expr → MetaM α
| consumeLet, lctx, fvars, j, Expr.lam n d b c => do
let d := d.instantiateRevRange j fvars.size fvars;
fvarId ← mkFreshId;
let lctx := lctx.mkLocalDecl fvarId n d c.binderInfo;
let fvar := mkFVar fvarId;
lambdaTelescopeAux consumeLet lctx (fvars.push fvar) j b
| true, lctx, fvars, j, Expr.letE n t v b _ => do
let t := t.instantiateRevRange j fvars.size fvars;
let v := v.instantiateRevRange j fvars.size fvars;
fvarId ← mkFreshId;
let lctx := lctx.mkLetDecl fvarId n t v;
let fvar := mkFVar fvarId;
lambdaTelescopeAux true lctx (fvars.push fvar) j b
| _, lctx, fvars, j, e =>
let e := e.instantiateRevRange j fvars.size fvars;
adaptReader (fun (ctx : Context) => { ctx with lctx := lctx }) $
withNewLocalInstancesImp isClassExpensive? fvars j $ do
k fvars e
private def lambdaTelescopeImp {α} (e : Expr) (consumeLet : Bool) (k : Array Expr → Expr → MetaM α) : MetaM α := do
lctx ← getLCtx;
lambdaTelescopeAux k consumeLet lctx #[] 0 e
/-- Similar to `forallTelescope` but for lambda and let expressions. -/
def lambdaLetTelescope {α} (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun _ k => lambdaTelescopeImp type true k) k
/-- Similar to `forallTelescope` but for lambda expressions. -/
def lambdaTelescope {α} (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun _ k => lambdaTelescopeImp type false k) k
def getParamNamesImp (declName : Name) : MetaM (Array Name) := do
cinfo ← getConstInfo declName;
forallTelescopeReducing cinfo.type $ fun xs _ => do
xs.mapM $ fun x => do
localDecl ← getLocalDecl x.fvarId!;
pure localDecl.userName
/-- Return the parameter names for the givel global declaration. -/
def getParamNames (declName : Name) : m (Array Name) :=
liftMetaM $ getParamNamesImp declName
-- `kind` specifies the metavariable kind for metavariables not corresponding to instance implicit `[ ... ]` arguments.
private partial def forallMetaTelescopeReducingAux
(reducing? : Bool) (maxMVars? : Option Nat) (kind : MetavarKind)
: Array Expr → Array BinderInfo → Nat → Expr → MetaM (Array Expr × Array BinderInfo × Expr)
| mvars, bis, j, type@(Expr.forallE n d b c) => do
let process : Unit → MetaM (Array Expr × Array BinderInfo × Expr) := fun _ => do {
let d := d.instantiateRevRange j mvars.size mvars;
let k := if c.binderInfo.isInstImplicit then MetavarKind.synthetic else kind;
mvar ← mkFreshExprMVar d k n;
let mvars := mvars.push mvar;
let bis := bis.push c.binderInfo;
forallMetaTelescopeReducingAux mvars bis j b
};
match maxMVars? with
| none => process ()
| some maxMVars =>
if mvars.size < maxMVars then
process ()
else
let type := type.instantiateRevRange j mvars.size mvars;
pure (mvars, bis, type)
| mvars, bis, j, type =>
let type := type.instantiateRevRange j mvars.size mvars;
if reducing? then do
newType ← whnf type;
if newType.isForall then
forallMetaTelescopeReducingAux mvars bis mvars.size newType
else
pure (mvars, bis, type)
else
pure (mvars, bis, type)
/-- Similar to `forallTelescope`, but creates metavariables instead of free variables. -/
def forallMetaTelescope (e : Expr) (kind := MetavarKind.natural) : m (Array Expr × Array BinderInfo × Expr) :=
liftMetaM $ forallMetaTelescopeReducingAux false none kind #[] #[] 0 e
/-- Similar to `forallTelescopeReducing`, but creates metavariables instead of free variables. -/
def forallMetaTelescopeReducing (e : Expr) (maxMVars? : Option Nat := none) (kind := MetavarKind.natural) : m (Array Expr × Array BinderInfo × Expr) :=
liftMetaM $ forallMetaTelescopeReducingAux true maxMVars? kind #[] #[] 0 e
/-- Similar to `forallMetaTelescopeReducingAux` but for lambda expressions. -/
private partial def lambdaMetaTelescopeAux (maxMVars? : Option Nat)
: Array Expr → Array BinderInfo → Nat → Expr → MetaM (Array Expr × Array BinderInfo × Expr)
| mvars, bis, j, type => do
let finalize : Unit → MetaM (Array Expr × Array BinderInfo × Expr) := fun _ => do {
let type := type.instantiateRevRange j mvars.size mvars;
pure (mvars, bis, type)
};
let process : Unit → MetaM (Array Expr × Array BinderInfo × Expr) := fun _ => do {
match type with
| Expr.lam n d b c => do
let d := d.instantiateRevRange j mvars.size mvars;
mvar ← mkFreshExprMVar d;
let mvars := mvars.push mvar;
let bis := bis.push c.binderInfo;
lambdaMetaTelescopeAux mvars bis j b
| _ => finalize ()
};
match maxMVars? with
| none => process ()
| some maxMVars =>
if mvars.size < maxMVars then
process ()
else
finalize ()
/-- Similar to `forallMetaTelescope` but for lambda expressions. -/
def lambdaMetaTelescope (e : Expr) (maxMVars? : Option Nat := none) : m (Array Expr × Array BinderInfo × Expr) :=
liftMetaM $ lambdaMetaTelescopeAux maxMVars? #[] #[] 0 e
private def withNewFVar {α} (fvar fvarType : Expr) (k : Expr → MetaM α) : MetaM α := do
c? ← isClass? fvarType;
match c? with
| none => k fvar
| some c => withNewLocalInstance c fvar $ k fvar
private def withLocalDeclImp {α} (n : Name) (bi : BinderInfo) (type : Expr) (k : Expr → MetaM α) : MetaM α := do
fvarId ← mkFreshId;
ctx ← read;
let lctx := ctx.lctx.mkLocalDecl fvarId n type bi;
let fvar := mkFVar fvarId;
adaptReader (fun (ctx : Context) => { ctx with lctx := lctx }) $
withNewFVar fvar type k
def withLocalDecl {α} (name : Name) (bi : BinderInfo) (type : Expr) (k : Expr → n α) : n α :=
map1MetaM (fun _ k => withLocalDeclImp name bi type k) k
def withLocalDeclD {α} (name : Name) (type : Expr) (k : Expr → n α) : n α :=
withLocalDecl name BinderInfo.default type k
private def withLetDeclImp {α} (n : Name) (type : Expr) (val : Expr) (k : Expr → MetaM α) : MetaM α := do
fvarId ← mkFreshId;
ctx ← read;
let lctx := ctx.lctx.mkLetDecl fvarId n type val;
let fvar := mkFVar fvarId;
adaptReader (fun (ctx : Context) => { ctx with lctx := lctx }) $
withNewFVar fvar type k
def withLetDecl {α} (name : Name) (type : Expr) (val : Expr) (k : Expr → n α) : n α :=
map1MetaM (fun _ k => withLetDeclImp name type val k) k
private def withExistingLocalDeclsImp {α} (decls : List LocalDecl) (k : MetaM α) : MetaM α := do
ctx ← read;
let numLocalInstances := ctx.localInstances.size;
let lctx := decls.foldl (fun (lctx : LocalContext) decl => lctx.addDecl decl) ctx.lctx;
adaptReader (fun (ctx : Context) => { ctx with lctx := lctx }) do
newLocalInsts ← decls.foldlM
(fun (newlocalInsts : Array LocalInstance) (decl : LocalDecl) => (do {
c? ← isClass? decl.type;
match c? with
| none => pure newlocalInsts
| some c => pure $ newlocalInsts.push { className := c, fvar := decl.toExpr } } : MetaM _))
ctx.localInstances;
if newLocalInsts.size == numLocalInstances then
k
else
resettingSynthInstanceCache $ adaptReader (fun (ctx : Context) => { ctx with localInstances := newLocalInsts }) k
def withExistingLocalDecls {α} (decls : List LocalDecl) : n α → n α :=
mapMetaM fun _ => withExistingLocalDeclsImp decls
private def withNewMCtxDepthImp {α} (x : MetaM α) : MetaM α := do
s ← get;
let savedMCtx := s.mctx;
modifyMCtx fun mctx => mctx.incDepth;
finally x (setMCtx savedMCtx)
/--
Save cache and `MetavarContext`, bump the `MetavarContext` depth, execute `x`,
and restore saved data. -/
def withNewMCtxDepth {α} : n α → n α :=
mapMetaM fun _ => withNewMCtxDepthImp
private def withLocalContextImp {α} (lctx : LocalContext) (localInsts : LocalInstances) (x : MetaM α) : MetaM α := do
localInstsCurr ← getLocalInstances;
adaptReader (fun (ctx : Context) => { ctx with lctx := lctx, localInstances := localInsts }) $
if localInsts == localInstsCurr then
x
else
resettingSynthInstanceCache x
def withLCtx {α} (lctx : LocalContext) (localInsts : LocalInstances) : n α → n α :=
mapMetaM fun _ => withLocalContextImp lctx localInsts
private def withMVarContextImp {α} (mvarId : MVarId) (x : MetaM α) : MetaM α := do
mvarDecl ← getMVarDecl mvarId;
withLocalContextImp mvarDecl.lctx mvarDecl.localInstances x
/--
Execute `x` using the given metavariable `LocalContext` and `LocalInstances`.
The type class resolution cache is flushed when executing `x` if its `LocalInstances` are
different from the current ones. -/
def withMVarContext {α} (mvarId : MVarId) : n α → n α :=
mapMetaM fun _ => withMVarContextImp mvarId
private def withMCtxImp {α} (mctx : MetavarContext) (x : MetaM α) : MetaM α := do
mctx' ← getMCtx;
setMCtx mctx;
finally x (setMCtx mctx')
def withMCtx {α} (mctx : MetavarContext) : n α → n α :=
mapMetaM fun _ => withMCtxImp mctx
@[inline] private def approxDefEqImp {α} (x : MetaM α) : MetaM α :=
withConfig (fun config => { config with foApprox := true, ctxApprox := true, quasiPatternApprox := true}) x
/-- Execute `x` using approximate unification: `foApprox`, `ctxApprox` and `quasiPatternApprox`. -/
@[inline] def approxDefEq {α} : n α → n α :=
mapMetaM fun _ => approxDefEqImp
@[inline] private def fullApproxDefEqImp {α} (x : MetaM α) : MetaM α :=
withConfig (fun config => { config with foApprox := true, ctxApprox := true, quasiPatternApprox := true, constApprox := true }) x
/--
Similar to `approxDefEq`, but uses all available approximations.
We don't use `constApprox` by default at `approxDefEq` because it often produces undesirable solution for monadic code.
For example, suppose we have `pure (x > 0)` which has type `?m Prop`. We also have the goal `[HasPure ?m]`.
Now, assume the expected type is `IO Bool`. Then, the unification constraint `?m Prop =?= IO Bool` could be solved
as `?m := fun _ => IO Bool` using `constApprox`, but this spurious solution would generate a failure when we try to
solve `[HasPure (fun _ => IO Bool)]` -/
@[inline] def fullApproxDefEq {α} : n α → n α :=
mapMetaM fun _ => fullApproxDefEqImp
@[inline] private def liftStateMCtx {α} (x : StateM MetavarContext α) : MetaM α := do
mctx ← getMCtx;
let (a, mctx) := x.run mctx;
setMCtx mctx;
pure a
def instantiateLevelMVars (u : Level) : m Level :=
liftMetaM $ liftStateMCtx $ MetavarContext.instantiateLevelMVars u
def normalizeLevel (u : Level) : m Level :=
liftMetaM do u ← instantiateLevelMVars u; pure u.normalize
def assignLevelMVar (mvarId : MVarId) (u : Level) : m Unit :=
modifyMCtx fun mctx => mctx.assignLevel mvarId u
def whnfD [MonadLiftT MetaM n] (e : Expr) : n Expr :=
withTransparency TransparencyMode.default $ whnf e
def setInlineAttribute (declName : Name) (kind := Compiler.InlineAttributeKind.inline): m Unit := liftMetaM do
env ← getEnv;
match Compiler.setInlineAttribute env declName kind with
| Except.ok env => setEnv env
| Except.error msg => throwError msg
private partial def instantiateForallAux (ps : Array Expr) : Nat → Expr → MetaM Expr
| i, e =>
if h : i < ps.size then do
let p := ps.get ⟨i, h⟩;
e ← whnf e;
match e with
| Expr.forallE _ _ b _ => instantiateForallAux (i+1) (b.instantiate1 p)
| _ => throwError "invalid instantiateForall, too many parameters"
else
pure e
/- Given `e` of the form `forall (a_1 : A_1) ... (a_n : A_n), B[a_1, ..., a_n]` and `p_1 : A_1, ... p_n : A_n`, return `B[p_1, ..., p_n]`. -/
def instantiateForall (e : Expr) (ps : Array Expr) : m Expr :=
liftMetaM $ instantiateForallAux ps 0 e
private partial def instantiateLambdaAux (ps : Array Expr) : Nat → Expr → MetaM Expr
| i, e =>
if h : i < ps.size then do
let p := ps.get ⟨i, h⟩;
e ← whnf e;
match e with
| Expr.lam _ _ b _ => instantiateLambdaAux (i+1) (b.instantiate1 p)
| _ => throwError "invalid instantiateLambda, too many parameters"
else
pure e
/- Given `e` of the form `fun (a_1 : A_1) ... (a_n : A_n) => t[a_1, ..., a_n]` and `p_1 : A_1, ... p_n : A_n`, return `t[p_1, ..., p_n]`.
It uses `whnf` to reduce `e` if it is not a lambda -/
def instantiateLambda (e : Expr) (ps : Array Expr) : m Expr :=
liftMetaM $ instantiateLambdaAux ps 0 e
/-- Return true iff `e` depends on the free variable `fvarId` -/
def dependsOn (e : Expr) (fvarId : FVarId) : m Bool := liftMetaM do
mctx ← getMCtx;
pure $ mctx.exprDependsOn e fvarId
def ppExprImp (e : Expr) : MetaM Format := do
env ← getEnv;
mctx ← getMCtx;
lctx ← getLCtx;
opts ← getOptions;
liftIO $ Lean.ppExpr { env := env, mctx := mctx, lctx := lctx, opts := opts } e
def ppExpr (e : Expr) : m Format :=
liftMetaM $ ppExprImp e
@[inline] protected def orelse {α} (x y : MetaM α) : MetaM α := do
env ← getEnv;
mctx ← getMCtx;
catch x (fun _ => do setEnv env; setMCtx mctx; y)
instance Meta.hasOrelse {α} : HasOrelse (MetaM α) := ⟨Meta.orelse⟩
@[inline] private def orelseMergeErrorsImp {α} (x y : MetaM α)
(mergeRef : Syntax → Syntax → Syntax := fun r₁ r₂ => r₁)
(mergeMsg : MessageData → MessageData → MessageData := fun m₁ m₂ => m₁ ++ Format.line ++ m₂)
: MetaM α := do
env ← getEnv;
mctx ← getMCtx;
catch x fun ex => do
setEnv env; setMCtx mctx;
match ex with
| Exception.error ref₁ m₁ =>
catch y fun ex => match ex with
| Exception.error ref₂ m₂ => throw $ Exception.error (mergeRef ref₁ ref₂) (mergeMsg m₁ m₂)
| _ => throw ex
| _ => throw ex
/--
Similar to `orelse`, but merge errors. Note that internal errors are not caught.
The default `mergeRef` uses the `ref` (position information) for the first message.
The default `mergeMsg` combines error messages using `Format.line ++ Format.line` as a separator. -/
@[inline] def orelseMergeErrors {α m} [MonadControlT MetaM m] [Monad m] (x y : m α)
(mergeRef : Syntax → Syntax → Syntax := fun r₁ r₂ => r₁)
(mergeMsg : MessageData → MessageData → MessageData := fun m₁ m₂ => m₁ ++ Format.line ++ Format.line ++ m₂)
: m α := do
controlAt MetaM fun runInBase => orelseMergeErrorsImp (runInBase x) (runInBase y) mergeRef mergeMsg
/-- Execute `x`, and apply `f` to the produced error message -/
def mapErrorImp {α} (x : MetaM α) (f : MessageData → MessageData) : MetaM α :=
catch x fun ex => match ex with
| Exception.error ref msg => throw $ Exception.error ref $ f msg
| _ => throw ex
@[inline] def mapError {α m} [MonadControlT MetaM m] [Monad m] (x : m α) (f : MessageData → MessageData) : m α :=
controlAt MetaM fun runInBase => mapErrorImp (runInBase x) f
/-- `commitWhenSome? x` executes `x` and keep modifications when it returns `some a`. -/
@[specialize] def commitWhenSome? {α} (x? : MetaM (Option α)) : MetaM (Option α) := do
env ← getEnv;
mctx ← getMCtx;
catch
(do
a? ← x?;
match a? with
| some a => pure a?
| none => do setEnv env; setMCtx mctx; pure none)
(fun ex => do setEnv env; setMCtx mctx; throw ex)
end Methods
end Meta
export Meta (MetaM)
end Lean
|
979e1aa03f8bb440b13e7797434689fc44a12dee | 76c77df8a58af24dbf1d75c7012076a42244d728 | /src/ch2.lean | 9a543bd013ed3d23814be4269a110b965a72ec28 | [] | no_license | kris-brown/theorem_proving_in_lean | 7a7a584ba2c657a35335dc895d49d991c997a0c9 | 774460c21bf857daff158210741bd88d1c8323cd | refs/heads/master | 1,668,278,123,743 | 1,593,445,161,000 | 1,593,445,161,000 | 265,748,924 | 0 | 1 | null | null | null | null | UTF-8 | Lean | false | false | 14,795 | lean |
-- Section 2.1: Simple type theory
namespace s21
/- declare some constants -/
constant m : nat -- m is a natural number
constant n : nat
constants b1 b2 : bool -- declare two constants at once
/- check their types -/
#check m -- output: nat
#check n
#check n + 0 -- nat
#check m * (n + 0) -- nat
#check b1 -- bool
#check b1 && b2 -- "&&" is boolean and
#check b1 || b2 -- boolean or
#check tt -- boolean "true"
constant f : nat → nat -- type the arrow as "\to" or "\r"
constant f' : nat -> nat -- alternative ASCII notation
constant f'' : ℕ → ℕ -- alternative notation for nat
constant p : nat × nat -- type the product as "\times"
constant q : prod nat nat -- alternative notation
constant g : nat → nat → nat
constant g' : nat → (nat → nat) -- has the same type as g!
constant h : nat × nat → nat
constant F : (nat → nat) → nat -- a "functional"
#check f -- ℕ → ℕ
#check f n -- ℕ
#check g m n -- ℕ
#check g m -- ℕ → ℕ
#check (m, n) -- ℕ × ℕ
#check p.1 -- ℕ
#check p.2 -- ℕ
#check (m, n).1 -- ℕ
#check (p.1, n) -- ℕ × ℕ
#check F f -- ℕ
end s21
-- Section 2.2: Types as Objects
namespace s22
-- Going beyond simple types
#check nat -- Type
#check bool -- Type
#check nat → bool -- Type
#check nat × bool -- Type
#check nat → nat -- ...
#check nat × nat → nat
#check nat → nat → nat
#check nat → (nat → nat)
#check nat → nat → bool
#check (nat → nat) → nat
-- Declare constants/constructors for types
constants α β : Type
constant F : Type → Type
constant G : Type → Type → Type
#check α -- Type
#check F α -- Type
#check F nat -- Type
#check G α -- Type → Type
#check G α β -- Type
#check G α nat -- Type
#check prod α β -- Type
#check prod nat nat -- Type
#check list α -- Type
#check list nat -- Type
-- Infinite hierarchy of types
#check Type -- Type 1
#check Type 0 -- Type 1
#check Type 1 -- Type 2
#check Type 2 -- Type 3
#check Type 3 -- Type 4
#check Type 4 -- Type 5
-- Has special properties
#check Prop -- Type
-- Polymorphic types
#check list -- Type u_1 → Type u_1
#check prod -- Type u_1 → Type u_2 → Type (max u_1 u_2)
universe u
constant αα : Type u
#check αα
end s22
-- Section 2.3: Function abstraction and evaluation
namespace s23
#check fun x : nat, x + 5
#check λ x : nat, x + 5
-- more abstract examples
constants α β : Type
constants a1 a2 : α
constants b1 b2 : β
constant f : α → α
constant g : α → β
constant h : α → β → α
constant p : α → α → bool
#check fun x : α, f x -- α → α
#check λ x : α, f x -- α → α
#check λ x : α, f (f x) -- α → α
#check λ x : α, h x b1 -- α → α
#check λ y : β, h a1 y -- β → α
#check λ x : α, p (f (f x)) (h (f a1) b2) -- α → bool
-- Due to type inference, these next three things are all the same
#check λ x : α, λ y : β, h (f x) y -- α → β → α
#check λ (x : α) (y : β), h (f x) y -- α → β → α
#check λ x y, h (f x) y -- α → β → α
constant b : β
-- Identity function
#check λ x : α, x -- α → α
-- Constant function
#check λ x : α, b -- α → β
-- Composition
#check λ x : α, g (f x) -- α → γ
#check λ x, g (f x)
-- Multiple arguments
constants γ : Type
#check λ b : β, λ x : α, x -- β → α → α
#check λ (b : β) (x : α), x -- β → α → α
#check λ (g : β → γ) (f : α → β) (x : α), g (f x)
-- (β → γ) → (α → β) → α → γ
-- Abstract over type
#check λ (α β : Type) (b : β) (x : α), x
#check λ (α β γ : Type) (g : β → γ) (f : α → β) (x : α), g (f x)
constants (a : α)
constant e : α → β
constant y : β → γ
constant w : α → α
#check (λ x : α, x) a -- α
#check (λ x : α, b) a -- β
#check (λ x : α, b) (w a) -- β
#check (λ x : α, y (e x)) (w (w a)) -- γ
#check (λ (v : β → γ) (u : α → β) x, v (u x)) y e a -- γ
#check (λ (Q R S : Type) (v : R → S) (u : Q → R) (x : Q),
v (u x)) α β γ y e a -- γ
-- Evaluate the function (beta reduction)
#reduce (λ x : α, x) a -- a
#reduce (λ x : α, b) a -- b
#reduce (λ x : α, b) (w a) -- b
#reduce (λ x : α, y (e x)) a -- g (f a)
#reduce (λ (v : β → γ) (u : α → β) x, v (u x)) y e a -- g (f a)
#reduce (λ (Q R S : Type) (v : R → S) (u : Q → R) (x : Q),
v (u x)) α β γ y e a -- g (f a)
-- "reducing pairs"
constants m n : nat
constant A : bool
#reduce (m, n).1 -- m
#reduce (m, n).2 -- n
-- "reducing boolean expressions"
#reduce tt && ff -- ff
#reduce ff && A -- ff
#reduce A && ff -- bool.rec ff ff b
-- WARNING This last one doesn't seem to work...
-- "reducing arithmetic expressions"
#reduce n + 0 -- n
#reduce n + 2 -- nat.succ (nat.succ n)
#reduce 2 + 3 -- 5
-- evaluating (less trustworthy, more efficient)
#eval 12345 * 54321
end s23
-- Section 2.4: Introducing Definitions
namespace s24
-- one way to define new objects
def foo : (ℕ → ℕ) → ℕ := λ f, f 0
#check foo -- (ℕ → ℕ) → ℕ
#print foo -- λ (f : ℕ → ℕ), f 0
-- type inferred (though it's preferable to provide it)
def foo' := λ f:(ℕ → ℕ), f 0
#check foo'
-- Alternative syntax for declaring function type
def double (x : ℕ) : ℕ := x + x
#print double
#check double 3
#reduce double 3 -- 6
def do_twice (f : ℕ → ℕ) (x : ℕ) : ℕ := f (f x)
#reduce do_twice double 2 -- 8
def compose (α β γ : Type) (g : β → γ) (f : α → β) (x : α) :
γ :=
g (f x)
#check compose
end s24
-- Section 2.5: Local definitions
namespace s25
#check let y := 2 + 2 in y * y -- ℕ
#reduce let y := 2 + 2 in y * y -- 16
def t (x : ℕ) : ℕ :=
let y := x + x in y * y
#reduce t 2 -- 16
-- Let a:= t1 in t2 is DIFFERENT from (λa, t2) t1
def foo := let a := nat in λ x : a, x + 2
#check foo
/-
def bar := (λ a, λ x : a, x + 2) nat
This doesn't typecheck because "a" can be any type, whereas x+2 does not make sense for
all types. The 'let' construct is a STRONGER means of abbreviation;
-/
end s25
-- Section 2.6 Variables and Sections
namespace s26
-- In general, not good practice to declare constants, we want to be constructive
-- Tedious to specify type variables as proper variables with every declaration, so this syntax makes it easier:
section variable_demo
variables (β α γ : Type)
def compose (g : β → γ) (f : α → β) (x : α) : γ := g (f x)
def do_twice (h : α → α) (x : α) : α := h (h x)
def do_thrice (h : α → α) (x : α) : α := h (h (h x))
-- Lean automatically can add whichever variables were actually used as additional parameters
def isnonzero(n:nat) : bool := n > 0
def nott(b:bool) : bool := ¬b
def iszero := compose bool ℕ bool nott isnonzero -- order of hidden parameters seems to be determined by their original declaration order
end variable_demo -- These declarations can be limited to sections
-- Sections do not have to have a name
end s26
-- Section 2.7 Namespaces
namespace s27
-- Refer to things in another namespace
#reduce s26.iszero 0
-- Open up a namespace (stays open until end of current namespace)
open s26
#check do_twice
end s27
-- Section 8: Dependent types
namespace s28
namespace hidden -- avoid conflicting with the standard library
universe u
constant list : Type u → Type u
constant cons : Π α : Type u, α → list α → list α
constant nil : Π α : Type u, list α
constant head : Π α : Type u, list α → α
constant tail : Π α : Type u, list α → list α
constant append : Π α : Type u, list α → list α → list α
variable α : Type
variable a : α
variables l1 l2 : list α
#check cons α a (nil α)
#check append α (cons α a (nil α)) l1
#check append α (append α (cons α a (nil α)) l1) l2
end hidden
open list
#check list -- Type u_1 → Type u_1
#check @cons -- Π {α : Type u_1}, α → list α → list α
#check @nil -- Π {α : Type u_1}, list α
#check @head -- Π {α : Type u_1} [_inst_1 : inhabited α], list α → α
#check @tail -- Π {α : Type u_1}, list α → list α
#check @append -- Π {α : Type u_1}, list α → list α → list α
universe u
constant vec : Type u → ℕ → Type u
namespace vec
constant empty : Π α : Type u, vec α 0
constant cons :
Π (α : Type u) (n : ℕ), α → vec α n → vec α (n + 1)
constant append :
Π (α : Type u) (n m : ℕ), vec α m → vec α n → vec α (n + m)
end vec
variable α : Type
variable β : α → Type
variable a : α
variable b : β a
#check sigma.mk a b -- Σ (a : α), β a
#check (sigma.mk a b).1 -- α
#check (sigma.mk a b).2 -- β (sigma.snd (sigma.mk a b))
#reduce (sigma.mk a b).1 -- a
#reduce (sigma.mk a b).2 -- b
end s28
-- Section 9: Implicit Variables
namespace s29
namespace hidden
universe u
constant list : Type u → Type u
namespace list
constant cons : Π α : Type u, α → list α → list α
constant nil : Π α : Type u, list α
constant append : Π α : Type u, list α → list α → list α
variable α : Type
variable a : α
variables l1 l2 : list α
-- This is "tedious"
#check cons α a (nil α)
#check append α (cons α a (nil α)) l1
#check append α (append α (cons α a (nil α)) l1) l2
-- We can use "implicit argument" to tell Lean to infer
#check cons _ a (nil _)
#check append _ (cons _ a (nil _)) l1
#check append _ (append _ (cons _ a (nil _)) l1) l2
end list
-- Even implicit arguments are tedious, so make some variables implicit by default with curly braces
namespace list2
constant cons : Π {α : Type u}, α → list α → list α
constant nil : Π {α : Type u}, list α
constant append : Π {α : Type u}, list α → list α → list α
variable α : Type
variable a : α
variables l1 l2 : list α
#check cons a nil
#check append (cons a nil) l1
#check append (append (cons a nil) l1) l2
end list2
def ident {α : Type u} (x : α) : α := x
variables α β : Type u
variables (a : α) (b : β)
#check ident -- ?M_1 → ?M_1
#check ident a -- α
#check ident b -- β
end hidden
-- Same way of defining ident above using variables instead of curly braces
universe u
section
variable {α : Type u}
variable x : α
def identi := x
end
variables α β : Type u
variables (a : α) (b : β)
#check identi
#check identi a
#check identi b
-- Numbers are overloaded, default to Nats
#check 2 -- ℕ
#check (2 : ℕ) -- ℕ
#check (2 : ℤ) -- ℤ
-- When we want to override implicit-as-default, preface with @
#check @id -- Π {α : Type u_1}, α → α
#check id α -- Type u
#check @id α -- α → α
#check @id β -- β → β
#check @id α a -- α
#check @id β b -- β
--#check id α a -- ERROR
end s29
-- Section 10: Exercises
namespace s2x
-- Ex 1. applies its argument twice, so that Do_Twice do_twice is a function that applies its input four times
def Do_Twice : ((ℕ → ℕ) → (ℕ → ℕ)) → (ℕ → ℕ) → (ℕ → ℕ) :=
λ (g :(ℕ → ℕ) → (ℕ → ℕ)) (f : (ℕ → ℕ)) x:ℕ,
g(g(f)) x
#reduce Do_Twice s24.do_twice s24.double 2
-- Ex 2.
def curry (α β γ : Type) (f : α × β → γ) : α → β → γ := λ (a:α) (b:β), f (a, b)
#check curry
def uncurry (α β γ : Type) (f : α → β → γ) : α × β → γ := λ (ab:α×β), f ab.1 ab.2
#check uncurry
def add(p:ℕ) (q:ℕ) : ℕ := p+q
#reduce uncurry ℕ ℕ ℕ add (4,2)
-- Ex 3.
-- could represent a function that adds two vectors of natural numbers of the same length
universe u
constant vec : Π {α : Type u}, ℕ → α
constant empty : vec 0
constant cons :
Π (β : Type u) (n : ℕ), β → vec n → vec (n + 1)
#check cons
constant append :
Π (α : Type u) (n m : ℕ), vec m → vec n → vec (n + m)
constant vec_add : Π {n:ℕ}, s28.vec ℕ n → s28.vec ℕ n → s28.vec ℕ n
-- can represent a function that reverses its argument
constant vec_reverse : Π {n:ℕ}, s28.vec ℕ n → s28.vec ℕ n
variable α : Type
variable a : α
variables l1 l2 : list α
#check vec_add (s28.vec.empty _) (s28.vec.empty _) -- add < > < >
#check vec_add (s28.vec.cons _ _ 1 (s28.vec.empty _)) (s28.vec.cons _ _ 3 (s28.vec.empty _)) -- add <1> <3>
#check vec_reverse (s28.vec.cons _ _ 3 (s28.vec.empty _))
-- Ex 4. Declare m x n matrices
constant mat : Π {α : Type u}, ℕ → ℕ → α
constant emptyM : mat 0 0
constant vcat : Π {n m o:ℕ}, vec o → mat n m → mat (n+o) m
constant hcat : Π {n m o:ℕ}, vec o → mat n m → mat n (m+o)
constant matmul: Π {n m o:ℕ}, mat n m → mat m o → mat n o
constant matadd: Π {n m:ℕ}, mat n m → mat n m → mat n m
constant matvecmul: Π {n m:ℕ}, mat n m → vec m → vec n
variables x y z : ℕ
constant vx : vec x
constant vy : vec y
end s2x
|
3a09c2a4d2225985c96722b4e016ec4c210901e2 | 2eab05920d6eeb06665e1a6df77b3157354316ad | /src/algebra/group_power/lemmas.lean | 3d179cab974d0ffa9bbaa18db683d6bcb3aba14c | [
"Apache-2.0"
] | permissive | ayush1801/mathlib | 78949b9f789f488148142221606bf15c02b960d2 | ce164e28f262acbb3de6281b3b03660a9f744e3c | refs/heads/master | 1,692,886,907,941 | 1,635,270,866,000 | 1,635,270,866,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 36,367 | lean | /-
Copyright (c) 2015 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Robert Y. Lewis
-/
import algebra.group_power.basic
import algebra.invertible
import algebra.opposites
import data.list.basic
import data.int.cast
import data.equiv.basic
import data.equiv.mul_add
/-!
# Lemmas about power operations on monoids and groups
This file contains lemmas about `monoid.pow`, `group.pow`, `nsmul`, `gsmul`
which require additional imports besides those available in `.basic`.
-/
universes u v w x y z u₁ u₂
variables {M : Type u} {N : Type v} {G : Type w} {H : Type x} {A : Type y} {B : Type z}
{R : Type u₁} {S : Type u₂}
/-!
### (Additive) monoid
-/
section monoid
variables [monoid M] [monoid N] [add_monoid A] [add_monoid B]
@[simp] theorem nsmul_one [has_one A] : ∀ n : ℕ, n • (1 : A) = n :=
add_monoid_hom.eq_nat_cast
⟨λ n, n • (1 : A), zero_nsmul _, λ _ _, add_nsmul _ _ _⟩
(one_nsmul _)
@[simp, norm_cast] lemma units.coe_pow (u : units M) (n : ℕ) : ((u ^ n : units M) : M) = u ^ n :=
(units.coe_hom M).map_pow u n
instance invertible_pow (m : M) [invertible m] (n : ℕ) : invertible (m ^ n) :=
{ inv_of := ⅟ m ^ n,
inv_of_mul_self := by rw [← (commute_inv_of m).symm.mul_pow, inv_of_mul_self, one_pow],
mul_inv_of_self := by rw [← (commute_inv_of m).mul_pow, mul_inv_of_self, one_pow] }
lemma inv_of_pow (m : M) [invertible m] (n : ℕ) [invertible (m ^ n)] :
⅟(m ^ n) = ⅟m ^ n :=
@invertible_unique M _ (m ^ n) (m ^ n) rfl ‹_› (invertible_pow m n)
lemma is_unit.pow {m : M} (n : ℕ) : is_unit m → is_unit (m ^ n) :=
λ ⟨u, hu⟩, ⟨u ^ n, by simp *⟩
lemma is_unit_pos_pow_iff {M : Type*} [comm_monoid M] {m : M} {n : ℕ} (h : 0 < n) :
is_unit (m ^ n) ↔ is_unit m :=
begin
obtain ⟨p, rfl⟩ := nat.exists_eq_succ_of_ne_zero h.ne',
refine ⟨λ h, _, is_unit.pow _⟩,
obtain ⟨⟨k, k', hk, hk'⟩, h⟩ := h,
rw [units.coe_mk] at h,
refine ⟨⟨m, m ^ p * k', _, _⟩, _⟩,
{ rw [←mul_assoc, ←pow_succ, ←h, hk] },
{ rw [mul_right_comm, ←pow_succ', ←h, hk] },
{ exact units.coe_mk _ _ _ _ }
end
/-- If `x ^ n.succ = 1` then `x` has an inverse, `x^n`. -/
def invertible_of_pow_succ_eq_one (x : M) (n : ℕ) (hx : x ^ n.succ = 1) :
invertible x :=
⟨x ^ n, (pow_succ' x n).symm.trans hx, (pow_succ x n).symm.trans hx⟩
/-- If `x ^ n = 1` then `x` has an inverse, `x^(n - 1)`. -/
def invertible_of_pow_eq_one (x : M) (n : ℕ) (hx : x ^ n = 1) (hn : 0 < n) :
invertible x :=
begin
apply invertible_of_pow_succ_eq_one x (n - 1),
convert hx,
exact tsub_add_cancel_of_le (nat.succ_le_of_lt hn),
end
lemma is_unit_of_pow_eq_one (x : M) (n : ℕ) (hx : x ^ n = 1) (hn : 0 < n) :
is_unit x :=
begin
haveI := invertible_of_pow_eq_one x n hx hn,
exact is_unit_of_invertible x
end
lemma smul_pow [mul_action M N] [is_scalar_tower M N N] [smul_comm_class M N N]
(k : M) (x : N) (p : ℕ) :
(k • x) ^ p = k ^ p • x ^ p :=
begin
induction p with p IH,
{ simp },
{ rw [pow_succ', IH, smul_mul_smul, ←pow_succ', ←pow_succ'] }
end
@[simp] lemma smul_pow' [mul_distrib_mul_action M N] (x : M) (m : N) (n : ℕ) :
x • m ^ n = (x • m) ^ n :=
begin
induction n with n ih,
{ rw [pow_zero, pow_zero], exact smul_one x },
{ rw [pow_succ, pow_succ], exact (smul_mul' x m (m ^ n)).trans (congr_arg _ ih) }
end
end monoid
section group
variables [group G] [group H] [add_group A] [add_group B]
open int
local attribute [ematch] le_of_lt
open nat
theorem gsmul_one [has_one A] (n : ℤ) : n • (1 : A) = n :=
by cases n; simp
lemma gpow_add_one (a : G) : ∀ n : ℤ, a ^ (n + 1) = a ^ n * a
| (of_nat n) := by simp [← int.coe_nat_succ, pow_succ']
| -[1+0] := by simp [int.neg_succ_of_nat_eq]
| -[1+(n+1)] := by rw [int.neg_succ_of_nat_eq, gpow_neg, neg_add, neg_add_cancel_right, gpow_neg,
← int.coe_nat_succ, gpow_coe_nat, gpow_coe_nat, pow_succ _ (n + 1), mul_inv_rev,
inv_mul_cancel_right]
theorem add_one_gsmul : ∀ (a : A) (i : ℤ), (i + 1) • a = i • a + a :=
@gpow_add_one (multiplicative A) _
lemma gpow_sub_one (a : G) (n : ℤ) : a ^ (n - 1) = a ^ n * a⁻¹ :=
calc a ^ (n - 1) = a ^ (n - 1) * a * a⁻¹ : (mul_inv_cancel_right _ _).symm
... = a^n * a⁻¹ : by rw [← gpow_add_one, sub_add_cancel]
lemma gpow_add (a : G) (m n : ℤ) : a ^ (m + n) = a ^ m * a ^ n :=
begin
induction n using int.induction_on with n ihn n ihn,
case hz : { simp },
{ simp only [← add_assoc, gpow_add_one, ihn, mul_assoc] },
{ rw [gpow_sub_one, ← mul_assoc, ← ihn, ← gpow_sub_one, add_sub_assoc] }
end
lemma mul_self_gpow (b : G) (m : ℤ) : b*b^m = b^(m+1) :=
by { conv_lhs {congr, rw ← gpow_one b }, rw [← gpow_add, add_comm] }
lemma mul_gpow_self (b : G) (m : ℤ) : b^m*b = b^(m+1) :=
by { conv_lhs {congr, skip, rw ← gpow_one b }, rw [← gpow_add, add_comm] }
theorem add_gsmul : ∀ (a : A) (i j : ℤ), (i + j) • a = i • a + j • a :=
@gpow_add (multiplicative A) _
lemma gpow_sub (a : G) (m n : ℤ) : a ^ (m - n) = a ^ m * (a ^ n)⁻¹ :=
by rw [sub_eq_add_neg, gpow_add, gpow_neg]
lemma sub_gsmul (m n : ℤ) (a : A) : (m - n) • a = m • a - n • a :=
by simpa only [sub_eq_add_neg] using @gpow_sub (multiplicative A) _ _ _ _
theorem gpow_one_add (a : G) (i : ℤ) : a ^ (1 + i) = a * a ^ i :=
by rw [gpow_add, gpow_one]
theorem one_add_gsmul : ∀ (a : A) (i : ℤ), (1 + i) • a = a + i • a :=
@gpow_one_add (multiplicative A) _
theorem gpow_mul_comm (a : G) (i j : ℤ) : a ^ i * a ^ j = a ^ j * a ^ i :=
by rw [← gpow_add, ← gpow_add, add_comm]
theorem gsmul_add_comm : ∀ (a : A) (i j : ℤ), i • a + j • a = j • a + i • a :=
@gpow_mul_comm (multiplicative A) _
theorem gpow_mul (a : G) (m n : ℤ) : a ^ (m * n) = (a ^ m) ^ n :=
int.induction_on n (by simp) (λ n ihn, by simp [mul_add, gpow_add, ihn])
(λ n ihn, by simp only [mul_sub, gpow_sub, ihn, mul_one, gpow_one])
theorem gsmul_mul' : ∀ (a : A) (m n : ℤ), (m * n) • a = n • (m • a) :=
@gpow_mul (multiplicative A) _
theorem gpow_mul' (a : G) (m n : ℤ) : a ^ (m * n) = (a ^ n) ^ m :=
by rw [mul_comm, gpow_mul]
theorem mul_gsmul (a : A) (m n : ℤ) : (m * n) • a = m • (n • a) :=
by rw [mul_comm, gsmul_mul']
theorem gpow_bit0 (a : G) (n : ℤ) : a ^ bit0 n = a ^ n * a ^ n := gpow_add _ _ _
theorem bit0_gsmul (a : A) (n : ℤ) : bit0 n • a = n • a + n • a :=
@gpow_bit0 (multiplicative A) _ _ _
theorem gpow_bit1 (a : G) (n : ℤ) : a ^ bit1 n = a ^ n * a ^ n * a :=
by rw [bit1, gpow_add, gpow_bit0, gpow_one]
theorem bit1_gsmul : ∀ (a : A) (n : ℤ), bit1 n • a = n • a + n • a + a :=
@gpow_bit1 (multiplicative A) _
@[simp] theorem monoid_hom.map_gpow (f : G →* H) (a : G) (n : ℤ) : f (a ^ n) = f a ^ n :=
by cases n; simp
@[simp] theorem add_monoid_hom.map_gsmul (f : A →+ B) (a : A) (n : ℤ) : f (n • a) = n • f a :=
f.to_multiplicative.map_gpow a n
@[simp, norm_cast] lemma units.coe_gpow (u : units G) (n : ℤ) : ((u ^ n : units G) : G) = u ^ n :=
(units.coe_hom G).map_gpow u n
end group
section ordered_add_comm_group
variables [ordered_add_comm_group A]
/-! Lemmas about `gsmul` under ordering, placed here (rather than in `algebra.group_power.order`
with their friends) because they require facts from `data.int.basic`-/
open int
lemma gsmul_pos {a : A} (ha : 0 < a) {k : ℤ} (hk : (0:ℤ) < k) : 0 < k • a :=
begin
lift k to ℕ using int.le_of_lt hk,
rw gsmul_coe_nat,
apply nsmul_pos ha,
exact (coe_nat_pos.mp hk).ne',
end
theorem gsmul_strict_mono_left {a : A} (ha : 0 < a) : strict_mono (λ n : ℤ, n • a) :=
λ n m h,
calc n • a = n • a + 0 : (add_zero _).symm
... < n • a + (m - n) • a : add_lt_add_left (gsmul_pos ha (sub_pos.mpr h)) _
... = m • a : by { rw [← add_gsmul], simp }
theorem gsmul_mono_left {a : A} (ha : 0 ≤ a) : monotone (λ n : ℤ, n • a) :=
λ n m h,
calc n • a = n • a + 0 : (add_zero _).symm
... ≤ n • a + (m - n) • a : add_le_add_left (gsmul_nonneg ha (sub_nonneg.mpr h)) _
... = m • a : by { rw [← add_gsmul], simp }
theorem gsmul_le_gsmul {a : A} {n m : ℤ} (ha : 0 ≤ a) (h : n ≤ m) : n • a ≤ m • a :=
gsmul_mono_left ha h
theorem gsmul_lt_gsmul {a : A} {n m : ℤ} (ha : 0 < a) (h : n < m) : n • a < m • a :=
gsmul_strict_mono_left ha h
theorem gsmul_le_gsmul_iff {a : A} {n m : ℤ} (ha : 0 < a) : n • a ≤ m • a ↔ n ≤ m :=
(gsmul_strict_mono_left ha).le_iff_le
theorem gsmul_lt_gsmul_iff {a : A} {n m : ℤ} (ha : 0 < a) : n • a < m • a ↔ n < m :=
(gsmul_strict_mono_left ha).lt_iff_lt
variables (A)
lemma gsmul_strict_mono_right {n : ℤ} (hn : 0 < n) :
strict_mono ((•) n : A → A) :=
λ a b hab, begin
rw ← sub_pos at hab,
rw [← sub_pos, ← gsmul_sub],
exact gsmul_pos hab hn,
end
lemma gsmul_mono_right {n : ℤ} (hn : 0 ≤ n) :
monotone ((•) n : A → A) :=
λ a b hab, begin
rw ← sub_nonneg at hab,
rw [← sub_nonneg, ← gsmul_sub],
exact gsmul_nonneg hab hn,
end
variables {A}
theorem gsmul_le_gsmul' {n : ℤ} (hn : 0 ≤ n) {a₁ a₂ : A} (h : a₁ ≤ a₂) : n • a₁ ≤ n • a₂ :=
gsmul_mono_right A hn h
theorem gsmul_lt_gsmul' {n : ℤ} (hn : 0 < n) {a₁ a₂ : A} (h : a₁ < a₂) : n • a₁ < n • a₂ :=
gsmul_strict_mono_right A hn h
lemma abs_nsmul {α : Type*} [linear_ordered_add_comm_group α] (n : ℕ) (a : α) :
|n • a| = n • |a| :=
begin
cases le_total a 0 with hneg hpos,
{ rw [abs_of_nonpos hneg, ← abs_neg, ← neg_nsmul, abs_of_nonneg],
exact nsmul_nonneg (neg_nonneg.mpr hneg) n },
{ rw [abs_of_nonneg hpos, abs_of_nonneg],
exact nsmul_nonneg hpos n }
end
lemma abs_gsmul {α : Type*} [linear_ordered_add_comm_group α] (n : ℤ) (a : α) :
|n • a| = |n| • |a| :=
begin
by_cases n0 : 0 ≤ n,
{ lift n to ℕ using n0,
simp only [abs_nsmul, coe_nat_abs, gsmul_coe_nat] },
{ lift (- n) to ℕ using int.le_of_lt (neg_pos.mpr (not_le.mp n0)) with m h,
rw [← abs_neg (n • a), ← neg_gsmul, ← abs_neg n, ← h, gsmul_coe_nat, coe_nat_abs,
gsmul_coe_nat],
exact abs_nsmul m _ },
end
lemma abs_add_eq_add_abs_le {α : Type*} [linear_ordered_add_comm_group α] {a b : α} (hle : a ≤ b) :
|a + b| = |a| + |b| ↔ (0 ≤ a ∧ 0 ≤ b ∨ a ≤ 0 ∧ b ≤ 0) :=
begin
by_cases a0 : 0 ≤ a; by_cases b0 : 0 ≤ b,
{ simp [a0, b0, abs_of_nonneg, add_nonneg a0 b0] },
{ exact (lt_irrefl (0 : α) (a0.trans_lt (hle.trans_lt (not_le.mp b0)))).elim },
any_goals { simp [(not_le.mp a0).le, (not_le.mp b0).le, abs_of_nonpos, add_nonpos, add_comm] },
obtain F := (not_le.mp a0),
have : (|a + b| = -a + b ↔ b ≤ 0) ↔ (|a + b| =
|a| + |b| ↔ 0 ≤ a ∧ 0 ≤ b ∨ a ≤ 0 ∧ b ≤ 0),
{ simp [a0, b0, abs_of_neg, abs_of_nonneg, F, F.le] },
refine this.mp ⟨λ h, _, λ h, by simp only [le_antisymm h b0, abs_of_neg F, add_zero]⟩,
by_cases ba : a + b ≤ 0,
{ refine le_of_eq (eq_zero_of_neg_eq _),
rwa [abs_of_nonpos ba, neg_add_rev, add_comm, add_right_inj] at h },
{ refine (lt_irrefl (0 : α) _).elim,
rw [abs_of_pos (not_le.mp ba), add_left_inj] at h,
rwa eq_zero_of_neg_eq h.symm at F }
end
lemma abs_add_eq_add_abs_iff {α : Type*} [linear_ordered_add_comm_group α] (a b : α) :
|a + b| = |a| + |b| ↔ (0 ≤ a ∧ 0 ≤ b ∨ a ≤ 0 ∧ b ≤ 0) :=
begin
by_cases ab : a ≤ b,
{ exact abs_add_eq_add_abs_le ab },
{ rw [add_comm a, add_comm (abs _), abs_add_eq_add_abs_le ((not_le.mp ab).le), and.comm,
@and.comm (b ≤ 0 ) _] }
end
end ordered_add_comm_group
section linear_ordered_add_comm_group
variable [linear_ordered_add_comm_group A]
theorem gsmul_le_gsmul_iff' {n : ℤ} (hn : 0 < n) {a₁ a₂ : A} : n • a₁ ≤ n • a₂ ↔ a₁ ≤ a₂ :=
(gsmul_strict_mono_right A hn).le_iff_le
theorem gsmul_lt_gsmul_iff' {n : ℤ} (hn : 0 < n) {a₁ a₂ : A} : n • a₁ < n • a₂ ↔ a₁ < a₂ :=
(gsmul_strict_mono_right A hn).lt_iff_lt
theorem nsmul_le_nsmul_iff {a : A} {n m : ℕ} (ha : 0 < a) : n • a ≤ m • a ↔ n ≤ m :=
begin
refine ⟨λ h, _, nsmul_le_nsmul $ le_of_lt ha⟩,
by_contra H,
exact lt_irrefl _ (lt_of_lt_of_le (nsmul_lt_nsmul ha (not_le.mp H)) h)
end
theorem nsmul_lt_nsmul_iff {a : A} {n m : ℕ} (ha : 0 < a) : n • a < m • a ↔ n < m :=
begin
refine ⟨λ h, _, nsmul_lt_nsmul ha⟩,
by_contra H,
exact lt_irrefl _ (lt_of_le_of_lt (nsmul_le_nsmul (le_of_lt ha) $ not_lt.mp H) h)
end
/-- See also `smul_right_injective`. TODO: provide a `no_zero_smul_divisors` instance. We can't
do that here because importing that definition would create import cycles. -/
lemma gsmul_right_injective {m : ℤ} (hm : m ≠ 0) : function.injective ((•) m : A → A) :=
begin
cases hm.symm.lt_or_lt,
{ exact (gsmul_strict_mono_right A h).injective, },
{ intros a b hab,
refine (gsmul_strict_mono_right A (neg_pos.mpr h)).injective _,
rw [neg_gsmul, neg_gsmul, hab], },
end
lemma gsmul_right_inj {a b : A} {m : ℤ} (hm : m ≠ 0) : m • a = m • b ↔ a = b :=
(gsmul_right_injective hm).eq_iff
/-- Alias of `gsmul_right_inj`, for ease of discovery alongside `gsmul_le_gsmul_iff'` and
`gsmul_lt_gsmul_iff'`. -/
lemma gsmul_eq_gsmul_iff' {a b : A} {m : ℤ} (hm : m ≠ 0) : m • a = m • b ↔ a = b :=
gsmul_right_inj hm
end linear_ordered_add_comm_group
@[simp] lemma with_bot.coe_nsmul [add_monoid A] (a : A) (n : ℕ) :
((n • a : A) : with_bot A) = n • a :=
add_monoid_hom.map_nsmul ⟨(coe : A → with_bot A), with_bot.coe_zero, with_bot.coe_add⟩ a n
theorem nsmul_eq_mul' [semiring R] (a : R) (n : ℕ) : n • a = a * n :=
by induction n with n ih; [rw [zero_nsmul, nat.cast_zero, mul_zero],
rw [succ_nsmul', ih, nat.cast_succ, mul_add, mul_one]]
@[simp] theorem nsmul_eq_mul [semiring R] (n : ℕ) (a : R) : n • a = n * a :=
by rw [nsmul_eq_mul', (n.cast_commute a).eq]
theorem mul_nsmul_left [semiring R] (a b : R) (n : ℕ) : n • (a * b) = a * (n • b) :=
by rw [nsmul_eq_mul', nsmul_eq_mul', mul_assoc]
theorem mul_nsmul_assoc [semiring R] (a b : R) (n : ℕ) : n • (a * b) = n • a * b :=
by rw [nsmul_eq_mul, nsmul_eq_mul, mul_assoc]
@[simp, norm_cast] theorem nat.cast_pow [semiring R] (n m : ℕ) : (↑(n ^ m) : R) = ↑n ^ m :=
begin
induction m with m ih,
{ rw [pow_zero, pow_zero], exact nat.cast_one },
{ rw [pow_succ', pow_succ', nat.cast_mul, ih] }
end
@[simp, norm_cast] theorem int.coe_nat_pow (n m : ℕ) : ((n ^ m : ℕ) : ℤ) = n ^ m :=
by induction m with m ih; [exact int.coe_nat_one, rw [pow_succ', pow_succ', int.coe_nat_mul, ih]]
theorem int.nat_abs_pow (n : ℤ) (k : ℕ) : int.nat_abs (n ^ k) = (int.nat_abs n) ^ k :=
by induction k with k ih; [refl, rw [pow_succ', int.nat_abs_mul, pow_succ', ih]]
-- The next four lemmas allow us to replace multiplication by a numeral with a `gsmul` expression.
-- They are used by the `noncomm_ring` tactic, to normalise expressions before passing to `abel`.
lemma bit0_mul [ring R] {n r : R} : bit0 n * r = (2 : ℤ) • (n * r) :=
by { dsimp [bit0], rw [add_mul, add_gsmul, one_gsmul], }
lemma mul_bit0 [ring R] {n r : R} : r * bit0 n = (2 : ℤ) • (r * n) :=
by { dsimp [bit0], rw [mul_add, add_gsmul, one_gsmul], }
lemma bit1_mul [ring R] {n r : R} : bit1 n * r = (2 : ℤ) • (n * r) + r :=
by { dsimp [bit1], rw [add_mul, bit0_mul, one_mul], }
lemma mul_bit1 [ring R] {n r : R} : r * bit1 n = (2 : ℤ) • (r * n) + r :=
by { dsimp [bit1], rw [mul_add, mul_bit0, mul_one], }
@[simp] theorem gsmul_eq_mul [ring R] (a : R) : ∀ (n : ℤ), n • a = n * a
| (n : ℕ) := by { rw [gsmul_coe_nat, nsmul_eq_mul], refl }
| -[1+ n] := by simp [nat.cast_succ, neg_add_rev, int.cast_neg_succ_of_nat, add_mul]
theorem gsmul_eq_mul' [ring R] (a : R) (n : ℤ) : n • a = a * n :=
by rw [gsmul_eq_mul, (n.cast_commute a).eq]
theorem mul_gsmul_left [ring R] (a b : R) (n : ℤ) : n • (a * b) = a * (n • b) :=
by rw [gsmul_eq_mul', gsmul_eq_mul', mul_assoc]
theorem mul_gsmul_assoc [ring R] (a b : R) (n : ℤ) : n • (a * b) = n • a * b :=
by rw [gsmul_eq_mul, gsmul_eq_mul, mul_assoc]
lemma gsmul_int_int (a b : ℤ) : a • b = a * b := by simp
lemma gsmul_int_one (n : ℤ) : n • 1 = n := by simp
@[simp, norm_cast] theorem int.cast_pow [ring R] (n : ℤ) (m : ℕ) : (↑(n ^ m) : R) = ↑n ^ m :=
begin
induction m with m ih,
{ rw [pow_zero, pow_zero, int.cast_one] },
{ rw [pow_succ, pow_succ, int.cast_mul, ih] }
end
lemma neg_one_pow_eq_pow_mod_two [ring R] {n : ℕ} : (-1 : R) ^ n = (-1) ^ (n % 2) :=
by rw [← nat.mod_add_div n 2, pow_add, pow_mul]; simp [sq]
section ordered_semiring
variable [ordered_semiring R]
/-- Bernoulli's inequality. This version works for semirings but requires
additional hypotheses `0 ≤ a * a` and `0 ≤ (1 + a) * (1 + a)`. -/
theorem one_add_mul_le_pow' {a : R} (Hsq : 0 ≤ a * a) (Hsq' : 0 ≤ (1 + a) * (1 + a))
(H : 0 ≤ 2 + a) :
∀ (n : ℕ), 1 + (n : R) * a ≤ (1 + a) ^ n
| 0 := by simp
| 1 := by simp
| (n+2) :=
have 0 ≤ (n : R) * (a * a * (2 + a)) + a * a,
from add_nonneg (mul_nonneg n.cast_nonneg (mul_nonneg Hsq H)) Hsq,
calc 1 + (↑(n + 2) : R) * a ≤ 1 + ↑(n + 2) * a + (n * (a * a * (2 + a)) + a * a) :
(le_add_iff_nonneg_right _).2 this
... = (1 + a) * (1 + a) * (1 + n * a) :
by { simp [add_mul, mul_add, bit0, mul_assoc, (n.cast_commute (_ : R)).left_comm],
ac_refl }
... ≤ (1 + a) * (1 + a) * (1 + a)^n :
mul_le_mul_of_nonneg_left (one_add_mul_le_pow' n) Hsq'
... = (1 + a)^(n + 2) : by simp only [pow_succ, mul_assoc]
private lemma pow_lt_pow_of_lt_one_aux {a : R} (h : 0 < a) (ha : a < 1) (i : ℕ) :
∀ k : ℕ, a ^ (i + k + 1) < a ^ i
| 0 :=
begin
rw [←one_mul (a^i), add_zero, pow_succ],
exact mul_lt_mul ha (le_refl _) (pow_pos h _) zero_le_one
end
| (k+1) :=
begin
rw [←one_mul (a^i), pow_succ],
apply mul_lt_mul ha _ _ zero_le_one,
{ apply le_of_lt, apply pow_lt_pow_of_lt_one_aux },
{ show 0 < a ^ (i + (k + 1) + 0), apply pow_pos h }
end
private lemma pow_le_pow_of_le_one_aux {a : R} (h : 0 ≤ a) (ha : a ≤ 1) (i : ℕ) :
∀ k : ℕ, a ^ (i + k) ≤ a ^ i
| 0 := by simp
| (k+1) := by { rw [←add_assoc, ←one_mul (a^i), pow_succ],
exact mul_le_mul ha (pow_le_pow_of_le_one_aux _) (pow_nonneg h _) zero_le_one }
lemma pow_lt_pow_of_lt_one {a : R} (h : 0 < a) (ha : a < 1)
{i j : ℕ} (hij : i < j) : a ^ j < a ^ i :=
let ⟨k, hk⟩ := nat.exists_eq_add_of_lt hij in
by rw hk; exact pow_lt_pow_of_lt_one_aux h ha _ _
lemma pow_lt_pow_iff_of_lt_one {a : R} {n m : ℕ} (hpos : 0 < a) (h : a < 1) :
a ^ m < a ^ n ↔ n < m :=
begin
have : strict_mono (λ (n : order_dual ℕ), a ^ (id n : ℕ)) := λ m n, pow_lt_pow_of_lt_one hpos h,
exact this.lt_iff_lt
end
lemma pow_le_pow_of_le_one {a : R} (h : 0 ≤ a) (ha : a ≤ 1) {i j : ℕ} (hij : i ≤ j) :
a ^ j ≤ a ^ i :=
let ⟨k, hk⟩ := nat.exists_eq_add_of_le hij in
by rw hk; exact pow_le_pow_of_le_one_aux h ha _ _
lemma pow_le_of_le_one {a : R} (h₀ : 0 ≤ a) (h₁ : a ≤ 1) {n : ℕ} (hn : n ≠ 0) : a ^ n ≤ a :=
(pow_one a).subst (pow_le_pow_of_le_one h₀ h₁ (nat.pos_of_ne_zero hn))
lemma sq_le {a : R} (h₀ : 0 ≤ a) (h₁ : a ≤ 1) : a ^ 2 ≤ a := pow_le_of_le_one h₀ h₁ two_ne_zero
end ordered_semiring
section linear_ordered_semiring
variables [linear_ordered_semiring R]
lemma sign_cases_of_C_mul_pow_nonneg {C r : R} (h : ∀ n : ℕ, 0 ≤ C * r ^ n) :
C = 0 ∨ (0 < C ∧ 0 ≤ r) :=
begin
have : 0 ≤ C, by simpa only [pow_zero, mul_one] using h 0,
refine this.eq_or_lt.elim (λ h, or.inl h.symm) (λ hC, or.inr ⟨hC, _⟩),
refine nonneg_of_mul_nonneg_left _ hC,
simpa only [pow_one] using h 1
end
end linear_ordered_semiring
section linear_ordered_ring
variables [linear_ordered_ring R] {a : R} {n : ℕ}
@[simp] lemma abs_pow (a : R) (n : ℕ) : |a ^ n| = |a| ^ n :=
(pow_abs a n).symm
@[simp] theorem pow_bit1_neg_iff : a ^ bit1 n < 0 ↔ a < 0 :=
⟨λ h, not_le.1 $ λ h', not_le.2 h $ pow_nonneg h' _,
λ h, by { rw [bit1, pow_succ], exact mul_neg_of_neg_of_pos h (pow_bit0_pos h.ne _)}⟩
@[simp] theorem pow_bit1_nonneg_iff : 0 ≤ a ^ bit1 n ↔ 0 ≤ a :=
le_iff_le_iff_lt_iff_lt.2 pow_bit1_neg_iff
@[simp] theorem pow_bit1_nonpos_iff : a ^ bit1 n ≤ 0 ↔ a ≤ 0 :=
by simp only [le_iff_lt_or_eq, pow_bit1_neg_iff, pow_eq_zero_iff (bit1_pos (zero_le n))]
@[simp] theorem pow_bit1_pos_iff : 0 < a ^ bit1 n ↔ 0 < a :=
lt_iff_lt_of_le_iff_le pow_bit1_nonpos_iff
lemma even.pow_nonneg (hn : even n) (a : R) : 0 ≤ a ^ n :=
by cases hn with k hk; simpa only [hk, two_mul] using pow_bit0_nonneg a k
lemma even.pow_pos (hn : even n) (ha : a ≠ 0) : 0 < a ^ n :=
by cases hn with k hk; simpa only [hk, two_mul] using pow_bit0_pos ha k
lemma odd.pow_nonpos (hn : odd n) (ha : a ≤ 0) : a ^ n ≤ 0:=
by cases hn with k hk; simpa only [hk, two_mul] using pow_bit1_nonpos_iff.mpr ha
lemma odd.pow_neg (hn : odd n) (ha : a < 0) : a ^ n < 0:=
by cases hn with k hk; simpa only [hk, two_mul] using pow_bit1_neg_iff.mpr ha
lemma odd.pow_nonneg_iff (hn : odd n) : 0 ≤ a ^ n ↔ 0 ≤ a :=
⟨λ h, le_of_not_lt (λ ha, h.not_lt $ hn.pow_neg ha), λ ha, pow_nonneg ha n⟩
lemma odd.pow_nonpos_iff (hn : odd n) : a ^ n ≤ 0 ↔ a ≤ 0 :=
⟨λ h, le_of_not_lt (λ ha, h.not_lt $ pow_pos ha _), hn.pow_nonpos⟩
lemma odd.pow_pos_iff (hn : odd n) : 0 < a ^ n ↔ 0 < a :=
⟨λ h, lt_of_not_ge' (λ ha, h.not_le $ hn.pow_nonpos ha), λ ha, pow_pos ha n⟩
lemma odd.pow_neg_iff (hn : odd n) : a ^ n < 0 ↔ a < 0 :=
⟨λ h, lt_of_not_ge' (λ ha, h.not_le $ pow_nonneg ha _), hn.pow_neg⟩
lemma even.pow_pos_iff (hn : even n) (h₀ : 0 < n) : 0 < a ^ n ↔ a ≠ 0 :=
⟨λ h ha, by { rw [ha, zero_pow h₀] at h, exact lt_irrefl 0 h }, hn.pow_pos⟩
lemma even.pow_abs {p : ℕ} (hp : even p) (a : R) : |a| ^ p = a ^ p :=
begin
rw [←abs_pow, abs_eq_self],
exact hp.pow_nonneg _
end
@[simp] lemma pow_bit0_abs (a : R) (p : ℕ) : |a| ^ bit0 p = a ^ bit0 p := (even_bit0 _).pow_abs _
lemma strict_mono_pow_bit1 (n : ℕ) : strict_mono (λ a : R, a ^ bit1 n) :=
begin
intros a b hab,
cases le_total a 0 with ha ha,
{ cases le_or_lt b 0 with hb hb,
{ rw [← neg_lt_neg_iff, ← neg_pow_bit1, ← neg_pow_bit1],
exact pow_lt_pow_of_lt_left (neg_lt_neg hab) (neg_nonneg.2 hb) (bit1_pos (zero_le n)) },
{ exact (pow_bit1_nonpos_iff.2 ha).trans_lt (pow_bit1_pos_iff.2 hb) } },
{ exact pow_lt_pow_of_lt_left hab ha (bit1_pos (zero_le n)) }
end
/-- Bernoulli's inequality for `n : ℕ`, `-2 ≤ a`. -/
theorem one_add_mul_le_pow (H : -2 ≤ a) (n : ℕ) : 1 + (n : R) * a ≤ (1 + a) ^ n :=
one_add_mul_le_pow' (mul_self_nonneg _) (mul_self_nonneg _) (neg_le_iff_add_nonneg'.1 H) _
/-- Bernoulli's inequality reformulated to estimate `a^n`. -/
theorem one_add_mul_sub_le_pow (H : -1 ≤ a) (n : ℕ) : 1 + (n : R) * (a - 1) ≤ a ^ n :=
have -2 ≤ a - 1, by rwa [bit0, neg_add, ← sub_eq_add_neg, sub_le_sub_iff_right],
by simpa only [add_sub_cancel'_right] using one_add_mul_le_pow this n
end linear_ordered_ring
/-- Bernoulli's inequality reformulated to estimate `(n : K)`. -/
theorem nat.cast_le_pow_sub_div_sub {K : Type*} [linear_ordered_field K] {a : K} (H : 1 < a)
(n : ℕ) :
(n : K) ≤ (a ^ n - 1) / (a - 1) :=
(le_div_iff (sub_pos.2 H)).2 $ le_sub_left_of_add_le $
one_add_mul_sub_le_pow ((neg_le_self $ @zero_le_one K _).trans H.le) _
/-- For any `a > 1` and a natural `n` we have `n ≤ a ^ n / (a - 1)`. See also
`nat.cast_le_pow_sub_div_sub` for a stronger inequality with `a ^ n - 1` in the numerator. -/
theorem nat.cast_le_pow_div_sub {K : Type*} [linear_ordered_field K] {a : K} (H : 1 < a) (n : ℕ) :
(n : K) ≤ a ^ n / (a - 1) :=
(n.cast_le_pow_sub_div_sub H).trans $ div_le_div_of_le (sub_nonneg.2 H.le)
(sub_le_self _ zero_le_one)
namespace int
lemma units_sq (u : units ℤ) : u ^ 2 = 1 :=
(sq u).symm ▸ units_mul_self u
alias int.units_sq ← int.units_pow_two
lemma units_pow_eq_pow_mod_two (u : units ℤ) (n : ℕ) : u ^ n = u ^ (n % 2) :=
by conv {to_lhs, rw ← nat.mod_add_div n 2}; rw [pow_add, pow_mul, units_sq, one_pow, mul_one]
@[simp] lemma nat_abs_sq (x : ℤ) : (x.nat_abs ^ 2 : ℤ) = x ^ 2 :=
by rw [sq, int.nat_abs_mul_self', sq]
alias int.nat_abs_sq ← int.nat_abs_pow_two
lemma abs_le_self_sq (a : ℤ) : (int.nat_abs a : ℤ) ≤ a ^ 2 :=
by { rw [← int.nat_abs_sq a, sq], norm_cast, apply nat.le_mul_self }
alias int.abs_le_self_sq ← int.abs_le_self_pow_two
lemma le_self_sq (b : ℤ) : b ≤ b ^ 2 := le_trans (le_nat_abs) (abs_le_self_sq _)
alias int.le_self_sq ← int.le_self_pow_two
lemma pow_right_injective {x : ℤ} (h : 1 < x.nat_abs) : function.injective ((^) x : ℕ → ℤ) :=
begin
suffices : function.injective (nat_abs ∘ ((^) x : ℕ → ℤ)),
{ exact function.injective.of_comp this },
convert nat.pow_right_injective h,
ext n,
rw [function.comp_app, nat_abs_pow]
end
end int
variables (M G A)
/-- Monoid homomorphisms from `multiplicative ℕ` are defined by the image
of `multiplicative.of_add 1`. -/
def powers_hom [monoid M] : M ≃ (multiplicative ℕ →* M) :=
{ to_fun := λ x, ⟨λ n, x ^ n.to_add, by { convert pow_zero x, exact to_add_one },
λ m n, pow_add x m n⟩,
inv_fun := λ f, f (multiplicative.of_add 1),
left_inv := pow_one,
right_inv := λ f, monoid_hom.ext $ λ n, by { simp [← f.map_pow, ← of_add_nsmul] } }
/-- Monoid homomorphisms from `multiplicative ℤ` are defined by the image
of `multiplicative.of_add 1`. -/
def gpowers_hom [group G] : G ≃ (multiplicative ℤ →* G) :=
{ to_fun := λ x, ⟨λ n, x ^ n.to_add, gpow_zero x, λ m n, gpow_add x m n⟩,
inv_fun := λ f, f (multiplicative.of_add 1),
left_inv := gpow_one,
right_inv := λ f, monoid_hom.ext $ λ n, by { simp [← f.map_gpow, ← of_add_gsmul ] } }
/-- Additive homomorphisms from `ℕ` are defined by the image of `1`. -/
def multiples_hom [add_monoid A] : A ≃ (ℕ →+ A) :=
{ to_fun := λ x, ⟨λ n, n • x, zero_nsmul x, λ m n, add_nsmul _ _ _⟩,
inv_fun := λ f, f 1,
left_inv := one_nsmul,
right_inv := λ f, add_monoid_hom.ext_nat $ one_nsmul (f 1) }
/-- Additive homomorphisms from `ℤ` are defined by the image of `1`. -/
def gmultiples_hom [add_group A] : A ≃ (ℤ →+ A) :=
{ to_fun := λ x, ⟨λ n, n • x, zero_gsmul x, λ m n, add_gsmul _ _ _⟩,
inv_fun := λ f, f 1,
left_inv := one_gsmul,
right_inv := λ f, add_monoid_hom.ext_int $ one_gsmul (f 1) }
variables {M G A}
@[simp] lemma powers_hom_apply [monoid M] (x : M) (n : multiplicative ℕ) :
powers_hom M x n = x ^ n.to_add := rfl
@[simp] lemma powers_hom_symm_apply [monoid M] (f : multiplicative ℕ →* M) :
(powers_hom M).symm f = f (multiplicative.of_add 1) := rfl
@[simp] lemma gpowers_hom_apply [group G] (x : G) (n : multiplicative ℤ) :
gpowers_hom G x n = x ^ n.to_add := rfl
@[simp] lemma gpowers_hom_symm_apply [group G] (f : multiplicative ℤ →* G) :
(gpowers_hom G).symm f = f (multiplicative.of_add 1) := rfl
@[simp] lemma multiples_hom_apply [add_monoid A] (x : A) (n : ℕ) :
multiples_hom A x n = n • x := rfl
@[simp] lemma multiples_hom_symm_apply [add_monoid A] (f : ℕ →+ A) :
(multiples_hom A).symm f = f 1 := rfl
@[simp] lemma gmultiples_hom_apply [add_group A] (x : A) (n : ℤ) :
gmultiples_hom A x n = n • x := rfl
@[simp] lemma gmultiples_hom_symm_apply [add_group A] (f : ℤ →+ A) :
(gmultiples_hom A).symm f = f 1 := rfl
lemma monoid_hom.apply_mnat [monoid M] (f : multiplicative ℕ →* M) (n : multiplicative ℕ) :
f n = (f (multiplicative.of_add 1)) ^ n.to_add :=
by rw [← powers_hom_symm_apply, ← powers_hom_apply, equiv.apply_symm_apply]
@[ext] lemma monoid_hom.ext_mnat [monoid M] ⦃f g : multiplicative ℕ →* M⦄
(h : f (multiplicative.of_add 1) = g (multiplicative.of_add 1)) : f = g :=
monoid_hom.ext $ λ n, by rw [f.apply_mnat, g.apply_mnat, h]
lemma monoid_hom.apply_mint [group M] (f : multiplicative ℤ →* M) (n : multiplicative ℤ) :
f n = (f (multiplicative.of_add 1)) ^ n.to_add :=
by rw [← gpowers_hom_symm_apply, ← gpowers_hom_apply, equiv.apply_symm_apply]
/-! `monoid_hom.ext_mint` is defined in `data.int.cast` -/
lemma add_monoid_hom.apply_nat [add_monoid M] (f : ℕ →+ M) (n : ℕ) :
f n = n • (f 1) :=
by rw [← multiples_hom_symm_apply, ← multiples_hom_apply, equiv.apply_symm_apply]
/-! `add_monoid_hom.ext_nat` is defined in `data.nat.cast` -/
lemma add_monoid_hom.apply_int [add_group M] (f : ℤ →+ M) (n : ℤ) :
f n = n • (f 1) :=
by rw [← gmultiples_hom_symm_apply, ← gmultiples_hom_apply, equiv.apply_symm_apply]
/-! `add_monoid_hom.ext_int` is defined in `data.int.cast` -/
variables (M G A)
/-- If `M` is commutative, `powers_hom` is a multiplicative equivalence. -/
def powers_mul_hom [comm_monoid M] : M ≃* (multiplicative ℕ →* M) :=
{ map_mul' := λ a b, monoid_hom.ext $ by simp [mul_pow],
..powers_hom M}
/-- If `M` is commutative, `gpowers_hom` is a multiplicative equivalence. -/
def gpowers_mul_hom [comm_group G] : G ≃* (multiplicative ℤ →* G) :=
{ map_mul' := λ a b, monoid_hom.ext $ by simp [mul_gpow],
..gpowers_hom G}
/-- If `M` is commutative, `multiples_hom` is an additive equivalence. -/
def multiples_add_hom [add_comm_monoid A] : A ≃+ (ℕ →+ A) :=
{ map_add' := λ a b, add_monoid_hom.ext $ by simp [nsmul_add],
..multiples_hom A}
/-- If `M` is commutative, `gmultiples_hom` is an additive equivalence. -/
def gmultiples_add_hom [add_comm_group A] : A ≃+ (ℤ →+ A) :=
{ map_add' := λ a b, add_monoid_hom.ext $ by simp [gsmul_add],
..gmultiples_hom A}
variables {M G A}
@[simp] lemma powers_mul_hom_apply [comm_monoid M] (x : M) (n : multiplicative ℕ) :
powers_mul_hom M x n = x ^ n.to_add := rfl
@[simp] lemma powers_mul_hom_symm_apply [comm_monoid M] (f : multiplicative ℕ →* M) :
(powers_mul_hom M).symm f = f (multiplicative.of_add 1) := rfl
@[simp] lemma gpowers_mul_hom_apply [comm_group G] (x : G) (n : multiplicative ℤ) :
gpowers_mul_hom G x n = x ^ n.to_add := rfl
@[simp] lemma gpowers_mul_hom_symm_apply [comm_group G] (f : multiplicative ℤ →* G) :
(gpowers_mul_hom G).symm f = f (multiplicative.of_add 1) := rfl
@[simp] lemma multiples_add_hom_apply [add_comm_monoid A] (x : A) (n : ℕ) :
multiples_add_hom A x n = n • x := rfl
@[simp] lemma multiples_add_hom_symm_apply [add_comm_monoid A] (f : ℕ →+ A) :
(multiples_add_hom A).symm f = f 1 := rfl
@[simp] lemma gmultiples_add_hom_apply [add_comm_group A] (x : A) (n : ℤ) :
gmultiples_add_hom A x n = n • x := rfl
@[simp] lemma gmultiples_add_hom_symm_apply [add_comm_group A] (f : ℤ →+ A) :
(gmultiples_add_hom A).symm f = f 1 := rfl
/-!
### Commutativity (again)
Facts about `semiconj_by` and `commute` that require `gpow` or `gsmul`, or the fact that integer
multiplication equals semiring multiplication.
-/
namespace semiconj_by
section
variables [semiring R] {a x y : R}
@[simp] lemma cast_nat_mul_right (h : semiconj_by a x y) (n : ℕ) :
semiconj_by a ((n : R) * x) (n * y) :=
semiconj_by.mul_right (nat.commute_cast _ _) h
@[simp] lemma cast_nat_mul_left (h : semiconj_by a x y) (n : ℕ) : semiconj_by ((n : R) * a) x y :=
semiconj_by.mul_left (nat.cast_commute _ _) h
@[simp] lemma cast_nat_mul_cast_nat_mul (h : semiconj_by a x y) (m n : ℕ) :
semiconj_by ((m : R) * a) (n * x) (n * y) :=
(h.cast_nat_mul_left m).cast_nat_mul_right n
end
variables [monoid M] [group G] [ring R]
@[simp] lemma units_gpow_right {a : M} {x y : units M} (h : semiconj_by a x y) :
∀ m : ℤ, semiconj_by a (↑(x^m)) (↑(y^m))
| (n : ℕ) := by simp only [gpow_coe_nat, units.coe_pow, h, pow_right]
| -[1+n] := by simp only [gpow_neg_succ_of_nat, units.coe_pow, units_inv_right, h, pow_right]
variables {a b x y x' y' : R}
@[simp] lemma cast_int_mul_right (h : semiconj_by a x y) (m : ℤ) :
semiconj_by a ((m : ℤ) * x) (m * y) :=
semiconj_by.mul_right (int.commute_cast _ _) h
@[simp] lemma cast_int_mul_left (h : semiconj_by a x y) (m : ℤ) : semiconj_by ((m : R) * a) x y :=
semiconj_by.mul_left (int.cast_commute _ _) h
@[simp] lemma cast_int_mul_cast_int_mul (h : semiconj_by a x y) (m n : ℤ) :
semiconj_by ((m : R) * a) (n * x) (n * y) :=
(h.cast_int_mul_left m).cast_int_mul_right n
end semiconj_by
namespace commute
section
variables [semiring R] {a b : R}
@[simp] theorem cast_nat_mul_right (h : commute a b) (n : ℕ) : commute a ((n : R) * b) :=
h.cast_nat_mul_right n
@[simp] theorem cast_nat_mul_left (h : commute a b) (n : ℕ) : commute ((n : R) * a) b :=
h.cast_nat_mul_left n
@[simp] theorem cast_nat_mul_cast_nat_mul (h : commute a b) (m n : ℕ) :
commute ((m : R) * a) (n * b) :=
h.cast_nat_mul_cast_nat_mul m n
@[simp] theorem self_cast_nat_mul (n : ℕ) : commute a (n * a) :=
(commute.refl a).cast_nat_mul_right n
@[simp] theorem cast_nat_mul_self (n : ℕ) : commute ((n : R) * a) a :=
(commute.refl a).cast_nat_mul_left n
@[simp] theorem self_cast_nat_mul_cast_nat_mul (m n : ℕ) : commute ((m : R) * a) (n * a) :=
(commute.refl a).cast_nat_mul_cast_nat_mul m n
end
variables [monoid M] [group G] [ring R]
@[simp] lemma units_gpow_right {a : M} {u : units M} (h : commute a u) (m : ℤ) :
commute a (↑(u^m)) :=
h.units_gpow_right m
@[simp] lemma units_gpow_left {u : units M} {a : M} (h : commute ↑u a) (m : ℤ) :
commute (↑(u^m)) a :=
(h.symm.units_gpow_right m).symm
variables {a b : R}
@[simp] lemma cast_int_mul_right (h : commute a b) (m : ℤ) : commute a (m * b) :=
h.cast_int_mul_right m
@[simp] lemma cast_int_mul_left (h : commute a b) (m : ℤ) : commute ((m : R) * a) b :=
h.cast_int_mul_left m
lemma cast_int_mul_cast_int_mul (h : commute a b) (m n : ℤ) : commute ((m : R) * a) (n * b) :=
h.cast_int_mul_cast_int_mul m n
variables (a) (m n : ℤ)
@[simp] lemma cast_int_left : commute (m : R) a :=
by { rw [← mul_one (m : R)], exact (one_left a).cast_int_mul_left m }
@[simp] lemma cast_int_right : commute a m :=
by { rw [← mul_one (m : R)], exact (one_right a).cast_int_mul_right m }
@[simp] theorem self_cast_int_mul : commute a (n * a) := (commute.refl a).cast_int_mul_right n
@[simp] theorem cast_int_mul_self : commute ((n : R) * a) a := (commute.refl a).cast_int_mul_left n
theorem self_cast_int_mul_cast_int_mul : commute ((m : R) * a) (n * a) :=
(commute.refl a).cast_int_mul_cast_int_mul m n
end commute
section multiplicative
open multiplicative
@[simp] lemma nat.to_add_pow (a : multiplicative ℕ) (b : ℕ) : to_add (a ^ b) = to_add a * b :=
begin
induction b with b ih,
{ erw [pow_zero, to_add_one, mul_zero] },
{ simp [*, pow_succ, add_comm, nat.mul_succ] }
end
@[simp] lemma nat.of_add_mul (a b : ℕ) : of_add (a * b) = of_add a ^ b :=
(nat.to_add_pow _ _).symm
@[simp] lemma int.to_add_pow (a : multiplicative ℤ) (b : ℕ) : to_add (a ^ b) = to_add a * b :=
by induction b; simp [*, mul_add, pow_succ, add_comm]
@[simp] lemma int.to_add_gpow (a : multiplicative ℤ) (b : ℤ) : to_add (a ^ b) = to_add a * b :=
int.induction_on b (by simp)
(by simp [gpow_add, mul_add] {contextual := tt})
(by simp [gpow_add, mul_add, sub_eq_add_neg, -int.add_neg_one] {contextual := tt})
@[simp] lemma int.of_add_mul (a b : ℤ) : of_add (a * b) = of_add a ^ b :=
(int.to_add_gpow _ _).symm
end multiplicative
namespace units
variables [monoid M]
lemma conj_pow (u : units M) (x : M) (n : ℕ) : (↑u * x * ↑(u⁻¹))^n = u * x^n * ↑(u⁻¹) :=
(divp_eq_iff_mul_eq.2 ((u.mk_semiconj_by x).pow_right n).eq.symm).symm
lemma conj_pow' (u : units M) (x : M) (n : ℕ) : (↑(u⁻¹) * x * u)^n = ↑(u⁻¹) * x^n * u:=
(u⁻¹).conj_pow x n
end units
namespace opposite
/-- Moving to the opposite monoid commutes with taking powers. -/
@[simp] lemma op_pow [monoid M] (x : M) (n : ℕ) : op (x ^ n) = (op x) ^ n := rfl
@[simp] lemma unop_pow [monoid M] (x : Mᵒᵖ) (n : ℕ) : unop (x ^ n) = (unop x) ^ n := rfl
/-- Moving to the opposite group or group_with_zero commutes with taking powers. -/
@[simp] lemma op_gpow [div_inv_monoid M] (x : M) (z : ℤ) : op (x ^ z) = (op x) ^ z := rfl
@[simp] lemma unop_gpow [div_inv_monoid M] (x : Mᵒᵖ) (z : ℤ) : unop (x ^ z) = (unop x) ^ z := rfl
end opposite
|
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"Apache-2.0"
] | permissive | ColaDrill/certigrad | fefb1be3670adccd3bed2f3faf57507f156fd501 | fe288251f623ac7152e5ce555f1cd9d3a20203c2 | refs/heads/master | 1,593,297,324,250 | 1,499,903,753,000 | 1,499,903,753,000 | 97,075,797 | 1 | 0 | null | 1,499,916,210,000 | 1,499,916,210,000 | null | UTF-8 | Lean | false | false | 1,547 | lean | /-
Copyright (c) 2017 Daniel Selsam. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Daniel Selsam
Utilities for the AEVB model.
-/
import ..tensor ..graph ..env
namespace certigrad
namespace aevb
structure arch : Type := (bs n_x n_in nz ne nd : ℕ)
structure weights (a : arch) : Type :=
(batch_num : ℕ)
(W_encode₁ : T [a^.ne, a^.n_in])
(W_encode₂ : T [a^.ne, a^.ne])
(W_encode_μ W_encode_logσ₂ : T [a^.nz, a^.ne])
(W_decode₁ : T [a^.nd, a^.nz])
(W_decode₂ : T [a^.nd, a^.nd])
(W_decode_p : T [a^.n_in, a^.nd])
section label
open certigrad.label
@[cgsimp] def mk_input_dict : Π {a : arch} (ws : weights a) (x_data : T [a^.n_in, a^.n_x]) (g : graph), env
| a ws x_data g := env.insert_all [(ID.str x, [a^.n_in, a^.bs]),
(ID.str W_encode₁, [a^.ne, a^.n_in]),
(ID.str W_encode₂, [a^.ne, a^.ne]),
(ID.str W_encode_μ, [a^.nz, a^.ne]),
(ID.str W_encode_logσ₂, [a^.nz, a^.ne]),
(ID.str W_decode₁, [a^.nd, a^.nz]),
(ID.str W_decode₂, [a^.nd, a^.nd]),
(ID.str W_decode_p, [a^.n_in, a^.nd])]
⟦T.get_col_range a^.bs x_data (a^.bs * ws^.batch_num), ws^.W_encode₁, ws^.W_encode₂, ws^.W_encode_μ, ws^.W_encode_logσ₂,
ws^.W_decode₁, ws^.W_decode₂, ws^.W_decode_p⟧
end label
end aevb
end certigrad
|
6ca2e9dfee1d37700080e644fd95c2d993add751 | 302c785c90d40ad3d6be43d33bc6a558354cc2cf | /src/algebra/geom_sum.lean | 055f64b2a756fd6a0b73ac9973db104d3ae5fa07 | [
"Apache-2.0"
] | permissive | ilitzroth/mathlib | ea647e67f1fdfd19a0f7bdc5504e8acec6180011 | 5254ef14e3465f6504306132fe3ba9cec9ffff16 | refs/heads/master | 1,680,086,661,182 | 1,617,715,647,000 | 1,617,715,647,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 13,406 | lean | /-
Copyright (c) 2019 Neil Strickland. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Neil Strickland
-/
import algebra.group_with_zero.power
import algebra.big_operators.order
import algebra.big_operators.ring
import algebra.big_operators.intervals
/-!
# Partial sums of geometric series
This file determines the values of the geometric series $\sum_{i=0}^{n-1} x^i$ and
$\sum_{i=0}^{n-1} x^i y^{n-1-i}$ and variants thereof.
## Main definitions
* `geom_sum` defines for each $x$ in a semiring and each natural number $n$ the partial sum
$\sum_{i=0}^{n-1} x^i$ of the geometric series.
* `geom_sum₂` defines for each $x,y$ in a semiring and each natural number $n$ the partial sum
$\sum_{i=0}^{n-1} x^i y^{n-1-i}$ of the geometric series.
## Main statements
* `geom_sum_Ico` proves that $\sum_{i=m}^{n-1} x^i=\frac{x^n-x^m}{x-1}$ in a division ring.
* `geom_sum₂_Ico` proves that $\sum_{i=m}^{n-1} x^i=\frac{x^n-y^{n-m}x^m}{x-y}$ in a field.
Several variants are recorded, generalising in particular to the case of a noncommutative ring in
which `x` and `y` commute. Even versions not using division or subtraction, valid in each semiring,
are recorded.
-/
universe u
variable {α : Type u}
open finset opposite
open_locale big_operators
/-- Sum of the finite geometric series $\sum_{i=0}^{n-1} x^i$. -/
def geom_sum [semiring α] (x : α) (n : ℕ) :=
∑ i in range n, x ^ i
theorem geom_sum_def [semiring α] (x : α) (n : ℕ) :
geom_sum x n = ∑ i in range n, x ^ i := rfl
@[simp] theorem geom_sum_zero [semiring α] (x : α) :
geom_sum x 0 = 0 := rfl
@[simp] theorem geom_sum_one [semiring α] (x : α) :
geom_sum x 1 = 1 :=
by { rw [geom_sum_def, sum_range_one, pow_zero] }
@[simp] lemma op_geom_sum [ring α] (x : α) (n : ℕ) :
op (geom_sum x n) = geom_sum (op x) n :=
by simp [geom_sum_def]
/-- Sum of the finite geometric series $\sum_{i=0}^{n-1} x^i y^{n-1-i}$. -/
def geom_sum₂ [semiring α] (x y : α) (n : ℕ) :=
∑ i in range n, x ^ i * (y ^ (n - 1 - i))
theorem geom_sum₂_def [semiring α] (x y : α) (n : ℕ) :
geom_sum₂ x y n = ∑ i in range n, x ^ i * y ^ (n - 1 - i) := rfl
@[simp] theorem geom_sum₂_zero [semiring α] (x y : α) :
geom_sum₂ x y 0 = 0 := rfl
@[simp] theorem geom_sum₂_one [semiring α] (x y : α) :
geom_sum₂ x y 1 = 1 :=
by { have : 1 - 1 - 0 = 0 := rfl,
rw [geom_sum₂_def, sum_range_one, this, pow_zero, pow_zero, mul_one] }
@[simp] lemma op_geom_sum₂ [ring α] (x y : α) (n : ℕ) :
op (geom_sum₂ x y n) = geom_sum₂ (op y) (op x) n :=
begin
simp only [geom_sum₂_def, op_sum, op_mul, units.op_pow],
rw ← sum_range_reflect,
refine sum_congr rfl (λ j j_in, _),
rw [mem_range, nat.lt_iff_add_one_le] at j_in,
congr,
apply nat.sub_sub_self,
exact nat.le_sub_right_of_add_le j_in
end
@[simp] theorem geom_sum₂_with_one [semiring α] (x : α) (n : ℕ) :
geom_sum₂ x 1 n = geom_sum x n :=
sum_congr rfl (λ i _, by { rw [one_pow, mul_one] })
/-- $x^n-y^n = (x-y) \sum x^ky^{n-1-k}$ reformulated without `-` signs. -/
protected theorem commute.geom_sum₂_mul_add [semiring α] {x y : α} (h : commute x y) (n : ℕ) :
(geom_sum₂ (x + y) y n) * x + y ^ n = (x + y) ^ n :=
begin
let f := λ (m i : ℕ), (x + y) ^ i * y ^ (m - 1 - i),
change (∑ i in range n, (f n) i) * x + y ^ n = (x + y) ^ n,
induction n with n ih,
{ rw [range_zero, sum_empty, zero_mul, zero_add, pow_zero, pow_zero] },
{ have f_last : f (n + 1) n = (x + y) ^ n :=
by { dsimp [f],
rw [nat.sub_sub, nat.add_comm, nat.sub_self, pow_zero, mul_one] },
have f_succ : ∀ i, i ∈ range n → f (n + 1) i = y * f n i :=
λ i hi, by {
dsimp [f],
have : commute y ((x + y) ^ i) :=
(h.symm.add_right (commute.refl y)).pow_right i,
rw [← mul_assoc, this.eq, mul_assoc, ← pow_succ y (n - 1 - i)],
congr' 2,
rw [nat.add_sub_cancel, nat.sub_sub, add_comm 1 i],
have : i + 1 + (n - (i + 1)) = n := nat.add_sub_of_le (mem_range.mp hi),
rw [add_comm (i + 1)] at this,
rw [← this, nat.add_sub_cancel, add_comm i 1, ← add_assoc,
nat.add_sub_cancel] },
rw [pow_succ (x + y), add_mul, sum_range_succ, f_last, add_mul, add_assoc],
rw [(((commute.refl x).add_right h).pow_right n).eq],
congr' 1,
rw[sum_congr rfl f_succ, ← mul_sum, pow_succ y],
rw[mul_assoc, ← mul_add y, ih] }
end
theorem geom_sum₂_self {α : Type*} [comm_ring α] (x : α) (n : ℕ) :
geom_sum₂ x x n = n * x ^ (n-1) :=
calc ∑ i in finset.range n, x ^ i * x ^ (n - 1 - i)
= ∑ i in finset.range n, x ^ (i + (n - 1 - i)) : by simp_rw [← pow_add]
... = ∑ i in finset.range n, x ^ (n - 1) : finset.sum_congr rfl
(λ i hi, congr_arg _ $ nat.add_sub_cancel' $ nat.le_pred_of_lt $ finset.mem_range.1 hi)
... = (finset.range n).card •ℕ (x ^ (n - 1)) : finset.sum_const _
... = n * x ^ (n - 1) : by rw [finset.card_range, nsmul_eq_mul]
/-- $x^n-y^n = (x-y) \sum x^ky^{n-1-k}$ reformulated without `-` signs. -/
theorem geom_sum₂_mul_add [comm_semiring α] (x y : α) (n : ℕ) :
(geom_sum₂ (x + y) y n) * x + y ^ n = (x + y) ^ n :=
(commute.all x y).geom_sum₂_mul_add n
theorem geom_sum_mul_add [semiring α] (x : α) (n : ℕ) :
(geom_sum (x + 1) n) * x + 1 = (x + 1) ^ n :=
begin
have := (commute.one_right x).geom_sum₂_mul_add n,
rw [one_pow, geom_sum₂_with_one] at this,
exact this
end
protected theorem commute.geom_sum₂_mul [ring α] {x y : α} (h : commute x y) (n : ℕ) :
(geom_sum₂ x y n) * (x - y) = x ^ n - y ^ n :=
begin
have := (h.sub_left (commute.refl y)).geom_sum₂_mul_add n,
rw [sub_add_cancel] at this,
rw [← this, add_sub_cancel]
end
lemma commute.mul_neg_geom_sum₂ [ring α] {x y : α} (h : commute x y) (n : ℕ) :
(y - x) * (geom_sum₂ x y n) = y ^ n - x ^ n :=
begin
rw ← op_inj_iff,
simp only [op_mul, op_sub, op_geom_sum₂, units.op_pow],
exact (commute.op h.symm).geom_sum₂_mul n
end
lemma commute.mul_geom_sum₂ [ring α] {x y : α} (h : commute x y) (n : ℕ) :
(x - y) * (geom_sum₂ x y n) = x ^ n - y ^ n :=
by rw [← neg_sub (y ^ n), ← h.mul_neg_geom_sum₂, ← neg_mul_eq_neg_mul_symm, neg_sub]
theorem geom_sum₂_mul [comm_ring α] (x y : α) (n : ℕ) :
(geom_sum₂ x y n) * (x - y) = x ^ n - y ^ n :=
(commute.all x y).geom_sum₂_mul n
theorem geom_sum_mul [ring α] (x : α) (n : ℕ) :
(geom_sum x n) * (x - 1) = x ^ n - 1 :=
begin
have := (commute.one_right x).geom_sum₂_mul n,
rw [one_pow, geom_sum₂_with_one] at this,
exact this
end
lemma mul_geom_sum [ring α] (x : α) (n : ℕ) :
(x - 1) * (geom_sum x n) = x ^ n - 1 :=
begin
rw ← op_inj_iff,
simpa using geom_sum_mul (op x) n,
end
theorem geom_sum_mul_neg [ring α] (x : α) (n : ℕ) :
(geom_sum x n) * (1 - x) = 1 - x ^ n :=
begin
have := congr_arg has_neg.neg (geom_sum_mul x n),
rw [neg_sub, ← mul_neg_eq_neg_mul_symm, neg_sub] at this,
exact this
end
lemma mul_neg_geom_sum [ring α] (x : α) (n : ℕ) :
(1 - x) * (geom_sum x n) = 1 - x ^ n :=
begin
rw ← op_inj_iff,
simpa using geom_sum_mul_neg (op x) n,
end
protected theorem commute.geom_sum₂ [division_ring α] {x y : α} (h' : commute x y) (h : x ≠ y)
(n : ℕ) : (geom_sum₂ x y n) = (x ^ n - y ^ n) / (x - y) :=
have x - y ≠ 0, by simp [*, -sub_eq_add_neg, sub_eq_iff_eq_add] at *,
by rw [← h'.geom_sum₂_mul, mul_div_cancel _ this]
theorem geom₂_sum [field α] {x y : α} (h : x ≠ y) (n : ℕ) :
(geom_sum₂ x y n) = (x ^ n - y ^ n) / (x - y) :=
(commute.all x y).geom_sum₂ h n
theorem geom_sum_eq [division_ring α] {x : α} (h : x ≠ 1) (n : ℕ) :
(geom_sum x n) = (x ^ n - 1) / (x - 1) :=
have x - 1 ≠ 0, by simp [*, -sub_eq_add_neg, sub_eq_iff_eq_add] at *,
by rw [← geom_sum_mul, mul_div_cancel _ this]
protected theorem commute.mul_geom_sum₂_Ico [ring α] {x y : α} (h : commute x y) {m n : ℕ}
(hmn : m ≤ n) :
(x - y) * (∑ i in finset.Ico m n, x ^ i * y ^ (n - 1 - i)) = x ^ n - x ^ m * y ^ (n - m) :=
begin
rw [sum_Ico_eq_sub _ hmn, ← geom_sum₂_def],
have : ∑ k in range m, x ^ k * y ^ (n - 1 - k)
= ∑ k in range m, x ^ k * (y ^ (n - m) * y ^ (m - 1 - k)),
{ refine sum_congr rfl (λ j j_in, _),
rw ← pow_add,
congr,
rw [mem_range, nat.lt_iff_add_one_le, add_comm] at j_in,
have h' : n - m + (m - (1 + j)) = n - (1 + j) := nat.sub_add_sub_cancel hmn j_in,
rw [nat.sub_sub m, h', nat.sub_sub] },
rw this,
simp_rw pow_mul_comm y (n-m) _,
simp_rw ← mul_assoc,
rw [← sum_mul, ← geom_sum₂_def, mul_sub, h.mul_geom_sum₂, ← mul_assoc,
h.mul_geom_sum₂, sub_mul, ← pow_add, nat.add_sub_of_le hmn,
sub_sub_sub_cancel_right (x ^ n) (x ^ m * y ^ (n - m)) (y ^ n)],
end
protected theorem commute.geom_sum₂_succ_eq {α : Type u} [ring α] {x y : α}
(h : commute x y) {n : ℕ} :
geom_sum₂ x y (n + 1) = x ^ n + y * (geom_sum₂ x y n) :=
begin
dunfold geom_sum₂,
rw [mul_sum, sum_range_succ _ n, nat.add_succ_sub_one, add_zero, nat.sub_self, pow_zero, mul_one],
apply congr_arg (has_add.add (x ^ n)),
apply finset.sum_congr rfl,
intros i hi,
rw [←mul_assoc, (h.symm.pow_right i).eq, mul_assoc, ←pow_succ],
suffices : n - 1 - i + 1 = n - i , { rw this },
cases n,
{ exact absurd (list.mem_range.mp hi) i.not_lt_zero },
{ rw [nat.sub_add_eq_add_sub (nat.le_pred_of_lt (list.mem_range.mp hi)),
nat.sub_add_cancel (nat.succ_le_iff.mpr n.succ_pos)] },
end
theorem geom_sum₂_succ_eq {α : Type u} [comm_ring α] (x y : α) {n : ℕ} :
geom_sum₂ x y (n + 1) = x ^ n + y * (geom_sum₂ x y n) :=
(commute.all x y).geom_sum₂_succ_eq
theorem mul_geom_sum₂_Ico [comm_ring α] (x y : α) {m n : ℕ} (hmn : m ≤ n) :
(x - y) * (∑ i in finset.Ico m n, x ^ i * y ^ (n - 1 - i)) = x ^ n - x ^ m * y ^ (n - m) :=
(commute.all x y).mul_geom_sum₂_Ico hmn
protected theorem commute.geom_sum₂_Ico_mul [ring α] {x y : α} (h : commute x y) {m n : ℕ}
(hmn : m ≤ n) :
(∑ i in finset.Ico m n, x ^ i * y ^ (n - 1 - i)) * (x - y) = x ^ n - y ^ (n - m) * x ^ m :=
begin
rw ← op_inj_iff,
simp only [op_sub, op_mul, units.op_pow, op_sum],
have : ∑ k in Ico m n, op y ^ (n - 1 - k) * op x ^ k
= ∑ k in Ico m n, op x ^ k * op y ^ (n - 1 - k),
{ refine sum_congr rfl (λ k k_in, _),
apply commute.pow_pow (commute.op h.symm) },
rw this,
exact (commute.op h).mul_geom_sum₂_Ico hmn
end
theorem geom_sum_Ico_mul [ring α] (x : α) {m n : ℕ} (hmn : m ≤ n) :
(∑ i in finset.Ico m n, x ^ i) * (x - 1) = x^n - x^m :=
by rw [sum_Ico_eq_sub _ hmn, ← geom_sum_def, ← geom_sum_def, sub_mul,
geom_sum_mul, geom_sum_mul, sub_sub_sub_cancel_right]
theorem geom_sum_Ico_mul_neg [ring α] (x : α) {m n : ℕ} (hmn : m ≤ n) :
(∑ i in finset.Ico m n, x ^ i) * (1 - x) = x^m - x^n :=
by rw [sum_Ico_eq_sub _ hmn, ← geom_sum_def, ← geom_sum_def, sub_mul,
geom_sum_mul_neg, geom_sum_mul_neg, sub_sub_sub_cancel_left]
protected theorem commute.geom_sum₂_Ico [division_ring α] {x y : α} (h : commute x y) (hxy : x ≠ y)
{m n : ℕ} (hmn : m ≤ n) :
∑ i in finset.Ico m n, x ^ i * y ^ (n - 1 - i) = (x ^ n - y ^ (n - m) * x ^ m ) / (x - y) :=
have x - y ≠ 0, by simp [*, -sub_eq_add_neg, sub_eq_iff_eq_add] at *,
by rw [← h.geom_sum₂_Ico_mul hmn, mul_div_cancel _ this]
theorem geom_sum₂_Ico [field α] {x y : α} (hxy : x ≠ y) {m n : ℕ} (hmn : m ≤ n) :
∑ i in finset.Ico m n, x ^ i * y ^ (n - 1 - i) = (x ^ n - y ^ (n - m) * x ^ m ) / (x - y) :=
(commute.all x y).geom_sum₂_Ico hxy hmn
theorem geom_sum_Ico [division_ring α] {x : α} (hx : x ≠ 1) {m n : ℕ} (hmn : m ≤ n) :
∑ i in finset.Ico m n, x ^ i = (x ^ n - x ^ m) / (x - 1) :=
by simp only [sum_Ico_eq_sub _ hmn, (geom_sum_def _ _).symm, geom_sum_eq hx, div_sub_div_same,
sub_sub_sub_cancel_right]
theorem geom_sum_Ico' [division_ring α] {x : α} (hx : x ≠ 1) {m n : ℕ} (hmn : m ≤ n) :
∑ i in finset.Ico m n, x ^ i = (x ^ m - x ^ n) / (1 - x) :=
by { simp only [geom_sum_Ico hx hmn], convert neg_div_neg_eq (x^m - x^n) (1-x); abel }
lemma geom_sum_inv [division_ring α] {x : α} (hx1 : x ≠ 1) (hx0 : x ≠ 0) (n : ℕ) :
(geom_sum x⁻¹ n) = (x - 1)⁻¹ * (x - x⁻¹ ^ n * x) :=
have h₁ : x⁻¹ ≠ 1, by rwa [inv_eq_one_div, ne.def, div_eq_iff_mul_eq hx0, one_mul],
have h₂ : x⁻¹ - 1 ≠ 0, from mt sub_eq_zero.1 h₁,
have h₃ : x - 1 ≠ 0, from mt sub_eq_zero.1 hx1,
have h₄ : x * (x ^ n)⁻¹ = (x ^ n)⁻¹ * x :=
nat.rec_on n (by simp)
(λ n h, by rw [pow_succ, mul_inv_rev', ←mul_assoc, h, mul_assoc, mul_inv_cancel hx0, mul_assoc,
inv_mul_cancel hx0]),
begin
rw [geom_sum_eq h₁, div_eq_iff_mul_eq h₂, ← mul_right_inj' h₃,
← mul_assoc, ← mul_assoc, mul_inv_cancel h₃],
simp [mul_add, add_mul, mul_inv_cancel hx0, mul_assoc, h₄, sub_eq_add_neg, add_comm,
add_left_comm],
end
variables {β : Type*}
theorem ring_hom.map_geom_sum [semiring α] [semiring β] (x : α) (n : ℕ) (f : α →+* β) :
f (geom_sum x n) = geom_sum (f x) n :=
by simp [geom_sum_def, f.map_sum]
theorem ring_hom.map_geom_sum₂ [semiring α] [semiring β] (x y : α) (n : ℕ) (f : α →+* β) :
f (geom_sum₂ x y n) = geom_sum₂ (f x) (f y) n :=
by simp [geom_sum₂_def, f.map_sum]
|
7aac6e8f2beb952541c9e905b0442956360da737 | 4bcaca5dc83d49803f72b7b5920b75b6e7d9de2d | /stage0/src/Lean/Data/Lsp/LanguageFeatures.lean | b95851d1f1bcb192746ecc41b96335054e2420f3 | [
"Apache-2.0"
] | permissive | subfish-zhou/leanprover-zh_CN.github.io | 30b9fba9bd790720bd95764e61ae796697d2f603 | 8b2985d4a3d458ceda9361ac454c28168d920d3f | refs/heads/master | 1,689,709,967,820 | 1,632,503,056,000 | 1,632,503,056,000 | 409,962,097 | 1 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 5,705 | lean | /-
Copyright (c) 2020 Wojciech Nawrocki. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Wojciech Nawrocki
-/
import Lean.Data.Json
import Lean.Data.Lsp.Basic
namespace Lean
namespace Lsp
open Json
structure CompletionOptions where
triggerCharacters? : Option (Array String) := none
allCommitCharacters? : Option (Array String) := none
resolveProvider : Bool := false
deriving FromJson, ToJson
structure CompletionItem where
label : String
detail? : Option String
documentation? : Option MarkupContent
/-
kind? : CompletionItemKind
tags? : CompletionItemTag[]
deprecated? : boolean
preselect? : boolean
sortText? : string
filterText? : string
insertText? : string
insertTextFormat? : InsertTextFormat
insertTextMode? : InsertTextMode
textEdit? : TextEdit | InsertReplaceEdit
additionalTextEdits? : TextEdit[]
commitCharacters? : string[]
command? : Command
data? : any -/
deriving FromJson, ToJson, Inhabited
structure CompletionList where
isIncomplete : Bool
items : Array CompletionItem
deriving FromJson, ToJson
structure CompletionParams extends TextDocumentPositionParams where
-- context? : CompletionContext
deriving FromJson, ToJson
structure Hover where
/- NOTE we should also accept MarkedString/MarkedString[] here
but they are deprecated, so maybe can get away without. -/
contents : MarkupContent
range? : Option Range := none
deriving ToJson, FromJson
structure HoverParams extends TextDocumentPositionParams
deriving FromJson, ToJson
structure DeclarationParams extends TextDocumentPositionParams
deriving FromJson, ToJson
structure DefinitionParams extends TextDocumentPositionParams
deriving FromJson, ToJson
structure TypeDefinitionParams extends TextDocumentPositionParams
deriving FromJson, ToJson
structure DocumentHighlightParams extends TextDocumentPositionParams
deriving FromJson, ToJson
inductive DocumentHighlightKind where
| text
| read
| write
instance : ToJson DocumentHighlightKind where
toJson
| DocumentHighlightKind.text => 1
| DocumentHighlightKind.read => 2
| DocumentHighlightKind.write => 3
structure DocumentHighlight where
range : Range
kind? : Option DocumentHighlightKind := none
deriving ToJson
abbrev DocumentHighlightResult := Array DocumentHighlight
structure DocumentSymbolParams where
textDocument : TextDocumentIdentifier
deriving FromJson, ToJson
inductive SymbolKind where
| file
| module
| «namespace»
| package
| «class»
| method
| property
| field
| constructor
| «enum»
| interface
| function
| «variable»
| «constant»
| string
| number
| boolean
| array
| object
| key
| null
| enumMember
| struct
| event
| operator
| typeParameter
instance : ToJson SymbolKind where
toJson
| SymbolKind.file => 1
| SymbolKind.module => 2
| SymbolKind.namespace => 3
| SymbolKind.package => 4
| SymbolKind.class => 5
| SymbolKind.method => 6
| SymbolKind.property => 7
| SymbolKind.field => 8
| SymbolKind.constructor => 9
| SymbolKind.enum => 10
| SymbolKind.interface => 11
| SymbolKind.function => 12
| SymbolKind.variable => 13
| SymbolKind.constant => 14
| SymbolKind.string => 15
| SymbolKind.number => 16
| SymbolKind.boolean => 17
| SymbolKind.array => 18
| SymbolKind.object => 19
| SymbolKind.key => 20
| SymbolKind.null => 21
| SymbolKind.enumMember => 22
| SymbolKind.struct => 23
| SymbolKind.event => 24
| SymbolKind.operator => 25
| SymbolKind.typeParameter => 26
structure DocumentSymbolAux (Self : Type) where
name : String
detail? : Option String := none
kind : SymbolKind
-- tags? : Array SymbolTag
range : Range
selectionRange : Range
children? : Option (Array Self) := none
deriving ToJson
inductive DocumentSymbol where
| mk (sym : DocumentSymbolAux DocumentSymbol)
partial instance : ToJson DocumentSymbol where
toJson :=
let rec go
| DocumentSymbol.mk sym =>
have : ToJson DocumentSymbol := ⟨go⟩
toJson sym
go
structure DocumentSymbolResult where
syms : Array DocumentSymbol
instance : ToJson DocumentSymbolResult where
toJson dsr := toJson dsr.syms
inductive SemanticTokenType where
| keyword
| «variable»
| property
/-
| «namespace»
| type
| «class»
| enum
| interface
| struct
| typeParameter
| parameter
| enumMember
| event
| function
| method
| «macro»
| modifier
| comment
| string
| number
| regexp
| operator
-/
def SemanticTokenType.names : Array String :=
#["keyword", "variable", "property"]
-- must be the correct index in `names`
def SemanticTokenType.toNat : SemanticTokenType → Nat
| keyword => 0
| «variable» => 1
| property => 2
/-
inductive SemanticTokenModifier where
| declaration
| definition
| readonly
| static
| deprecated
| abstract
| async
| modification
| documentation
| defaultLibrary
-/
structure SemanticTokensLegend where
tokenTypes : Array String
tokenModifiers : Array String
deriving FromJson, ToJson
structure SemanticTokensOptions where
legend : SemanticTokensLegend
range : Bool
full : Bool /- | {
delta?: boolean;
} -/
deriving FromJson, ToJson
structure SemanticTokensParams where
textDocument : TextDocumentIdentifier
deriving FromJson, ToJson
structure SemanticTokensRangeParams where
textDocument : TextDocumentIdentifier
range : Range
deriving FromJson, ToJson
structure SemanticTokens where
-- resultId?: string;
data : Array Nat
deriving FromJson, ToJson
end Lsp
end Lean
|
dd615009726ae0a38aefe8cf9785063b6333a101 | 6432ea7a083ff6ba21ea17af9ee47b9c371760f7 | /tests/lean/run/2182.lean | fb79544aaabc9433bff4fa0e7e35250bad5ded4a | [
"Apache-2.0",
"LLVM-exception",
"NCSA",
"LGPL-3.0-only",
"LicenseRef-scancode-inner-net-2.0",
"BSD-3-Clause",
"LGPL-2.0-or-later",
"Spencer-94",
"LGPL-2.1-or-later",
"HPND",
"LicenseRef-scancode-pcre",
"ISC",
"LGPL-2.1-only",
"LicenseRef-scancode-other-permissive",
"SunPro",
"CMU-Mach"... | permissive | leanprover/lean4 | 4bdf9790294964627eb9be79f5e8f6157780b4cc | f1f9dc0f2f531af3312398999d8b8303fa5f096b | refs/heads/master | 1,693,360,665,786 | 1,693,350,868,000 | 1,693,350,868,000 | 129,571,436 | 2,827 | 311 | Apache-2.0 | 1,694,716,156,000 | 1,523,760,560,000 | Lean | UTF-8 | Lean | false | false | 74 | lean | example : (¬ False) = True :=
by simp (config := { decide := false } )
|
ebe19ea5b2617c867e4948988c2d5d682a0afa00 | 35677d2df3f081738fa6b08138e03ee36bc33cad | /src/tactic/hint.lean | f8dc52ac1067084c446af7d5d4d0945b39ffec2e | [
"Apache-2.0"
] | permissive | gebner/mathlib | eab0150cc4f79ec45d2016a8c21750244a2e7ff0 | cc6a6edc397c55118df62831e23bfbd6e6c6b4ab | refs/heads/master | 1,625,574,853,976 | 1,586,712,827,000 | 1,586,712,827,000 | 99,101,412 | 1 | 0 | Apache-2.0 | 1,586,716,389,000 | 1,501,667,958,000 | Lean | UTF-8 | Lean | false | false | 3,655 | lean | /-
Copyright (c) 2020 Scott Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Scott Morrison
-/
import tactic.solve_by_elim
import tactic.interactive
namespace tactic
namespace hint
/-- An attribute marking a `tactic unit` or `tactic string` which should be used by the `hint`
tactic. -/
@[user_attribute] meta def hint_tactic_attribute : user_attribute := {
name := `hint_tactic,
descr := "A tactic that should be tried by `hint`."
}
add_tactic_doc
{ name := "hint_tactic",
category := doc_category.attr,
decl_names := [`tactic.hint.hint_tactic_attribute],
tags := ["rewrite", "search"] }
open lean lean.parser interactive
private meta def add_tactic_hint (n : name) (t : expr) : tactic unit :=
do
add_decl $ declaration.defn n [] `(tactic string) t reducibility_hints.opaque ff,
hint_tactic_attribute.set n () tt
/--
`add_hint_tactic t` runs the tactic `t` whenever `hint` is invoked.
The typical use case is `add_hint_tactic "foo"` for some interactive tactic `foo`.
-/
@[user_command] meta def add_hint_tactic (_ : parse (tk "add_hint_tactic")) : parser unit :=
do n ← parser.pexpr,
e ← to_expr n,
s ← eval_expr string e,
let t := "`[" ++ s ++ "]",
(t, _) ← with_input parser.pexpr t,
of_tactic $ do
let h := s <.> "_hint",
t ← to_expr ``(do %%t, pure %%n),
add_tactic_hint h t.
add_tactic_doc
{ name := "add_hint_tactic",
category := doc_category.cmd,
decl_names := [`tactic.hint.add_hint_tactic],
tags := ["search"] }
add_hint_tactic "refl"
add_hint_tactic "exact dec_trivial"
add_hint_tactic "assumption"
add_hint_tactic "intro" -- tidy does something better here: it suggests the actual "intros X Y f" string; perhaps add a wrapper?
add_hint_tactic "apply_auto_param"
add_hint_tactic "dsimp at *"
add_hint_tactic "simp at *" -- TODO hook up to squeeze_simp?
add_hint_tactic "fconstructor"
add_hint_tactic "injections_and_clear"
add_hint_tactic "solve_by_elim"
add_hint_tactic "unfold_coes"
add_hint_tactic "unfold_aux"
end hint
/-- report a list of tactics that can make progress against the current goal -/
meta def hint : tactic (list string) :=
do names ← attribute.get_instances `hint_tactic,
try_all_sorted (names.reverse.map name_to_tactic)
namespace interactive
/--
report a list of tactics that can make progress against the current goal
-/
meta def hint : tactic unit :=
do hints ← tactic.hint,
if hints.length = 0 then
fail "no hints available"
else
do trace "the following tactics make progress:\n----",
hints.mmap' (λ s, tactic.trace format!"Try this: {s}")
/--
`hint` lists possible tactics which will make progress (that is, not fail) against the current goal.
```lean
example {P Q : Prop} (p : P) (h : P → Q) : Q :=
begin
hint,
/- the following tactics make progress:
----
Try this: solve_by_elim
Try this: finish
Try this: tauto
-/
solve_by_elim,
end
```
You can add a tactic to the list that `hint` tries by either using
1. `attribute [hint_tactic] my_tactic`, if `my_tactic` is already of type `tactic string`
(`tactic unit` is allowed too, in which case the printed string will be the name of the
tactic), or
2. `add_hint_tactic "my_tactic"`, specifying a string which works as an interactive tactic.
-/
add_tactic_doc
{ name := "hint",
category := doc_category.tactic,
decl_names := [`tactic.interactive.hint],
tags := ["search", "Try this"] }
end interactive
end tactic
|
e679df88a3d64b4c4f209939c931e836908945d6 | 86f6f4f8d827a196a32bfc646234b73328aeb306 | /examples/basics/unnamed_1721.lean | 8f5284ba10ce14531ea95710037f520462483f85 | [] | no_license | jamescheuk91/mathematics_in_lean | 09f1f87d2b0dce53464ff0cbe592c568ff59cf5e | 4452499264e2975bca2f42565c0925506ba5dda3 | refs/heads/master | 1,679,716,410,967 | 1,613,957,947,000 | 1,613,957,947,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 209 | lean | import data.nat.gcd
open nat
variables n : ℕ
#check (gcd_zero_right n : gcd n 0 = n)
#check (gcd_zero_left n : gcd 0 n = n)
#check (lcm_zero_right n : lcm n 0 = 0)
#check (lcm_zero_left n : lcm 0 n = 0) |
c39058a61b3662a153d7d5b7dff4d767b082419a | aa3f8992ef7806974bc1ffd468baa0c79f4d6643 | /library/standard/logic/default.lean | 302573209d9deb923a01c94cb34cfeb5dde69d9f | [
"Apache-2.0"
] | permissive | codyroux/lean | 7f8dff750722c5382bdd0a9a9275dc4bb2c58dd3 | 0cca265db19f7296531e339192e9b9bae4a31f8b | refs/heads/master | 1,610,909,964,159 | 1,407,084,399,000 | 1,416,857,075,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 552 | lean | ----------------------------------------------------------------------------------------------------
--- Copyright (c) 2014 Microsoft Corporation. All rights reserved.
--- Released under Apache 2.0 license as described in the file LICENSE.
--- Author: Jeremy Avigad
----------------------------------------------------------------------------------------------------
import logic.connectives.basic logic.connectives.eq logic.connectives.quantifiers
import logic.classes.decidable logic.classes.inhabited logic.classes.congr
import logic.connectives.if |
0491d4126a344e4afab8b3897a78d572c1512628 | bdb33f8b7ea65f7705fc342a178508e2722eb851 | /data/set/finite.lean | 5dc4bf391f775eff80f343a944a69f79bcbb3564 | [
"Apache-2.0"
] | permissive | rwbarton/mathlib | 939ae09bf8d6eb1331fc2f7e067d39567e10e33d | c13c5ea701bb1eec057e0a242d9f480a079105e9 | refs/heads/master | 1,584,015,335,862 | 1,524,142,167,000 | 1,524,142,167,000 | 130,614,171 | 0 | 0 | Apache-2.0 | 1,548,902,667,000 | 1,524,437,371,000 | Lean | UTF-8 | Lean | false | false | 11,677 | lean | /-
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
Finite sets.
-/
import data.set.lattice data.nat.basic logic.function
data.fintype
open set lattice function
universes u v w
variables {α : Type u} {β : Type v} {ι : Sort w}
namespace set
/-- A set is finite if the subtype is a fintype, i.e. there is a
list that enumerates its members. -/
def finite (s : set α) : Prop := nonempty (fintype s)
/-- A set is infinite if it is not finite. -/
def infinite (s : set α) : Prop := ¬ finite s
/-- Construct a fintype from a finset with the same elements. -/
def fintype_of_finset {p : set α} (s : finset α) (H : ∀ x, x ∈ s ↔ x ∈ p) : fintype p :=
fintype.subtype s H
@[simp] theorem card_fintype_of_finset {p : set α} (s : finset α) (H : ∀ x, x ∈ s ↔ x ∈ p) :
@fintype.card p (fintype_of_finset s H) = s.card :=
fintype.subtype_card s H
theorem card_fintype_of_finset' {p : set α} (s : finset α)
(H : ∀ x, x ∈ s ↔ x ∈ p) [fintype p] : fintype.card p = s.card :=
by rw ← card_fintype_of_finset s H; congr
/-- Construct a finset enumerating a set `s`, given a `fintype` instance. -/
def to_finset (s : set α) [fintype s] : finset α :=
⟨(@finset.univ s _).1.map subtype.val,
multiset.nodup_map (λ a b, subtype.eq) finset.univ.2⟩
@[simp] theorem mem_to_finset {s : set α} [fintype s] {a : α} : a ∈ s.to_finset ↔ a ∈ s :=
by simp [to_finset]
@[simp] theorem mem_to_finset_val {s : set α} [fintype s] {a : α} : a ∈ s.to_finset.1 ↔ a ∈ s :=
mem_to_finset
noncomputable instance finite.fintype {s : set α} (h : finite s) : fintype s :=
classical.choice h
/-- Get a finset from a finite set -/
noncomputable def finite.to_finset {s : set α} (h : finite s) : finset α :=
@set.to_finset _ _ (finite.fintype h)
@[simp] theorem finite.mem_to_finset {s : set α} {h : finite s} {a : α} : a ∈ h.to_finset ↔ a ∈ s :=
@mem_to_finset _ _ (finite.fintype h) _
theorem finite_mem_finset (s : finset α) : finite {a | a ∈ s} :=
⟨fintype_of_finset s (λ _, iff.rfl)⟩
instance decidable_mem_of_fintype [decidable_eq α] (s : set α) [fintype s] (a) : decidable (a ∈ s) :=
decidable_of_iff _ mem_to_finset
instance fintype_empty : fintype (∅ : set α) :=
fintype_of_finset ∅ $ by simp
@[simp] theorem empty_card : fintype.card (∅ : set α) = 0 := rfl
@[simp] theorem finite_empty : @finite α ∅ := ⟨set.fintype_empty⟩
def fintype_insert' {a : α} (s : set α) [fintype s] (h : a ∉ s) : fintype (insert a s : set α) :=
fintype_of_finset ⟨a :: s.to_finset.1,
multiset.nodup_cons_of_nodup (by simp [h]) s.to_finset.2⟩ $ by simp
theorem card_fintype_insert' {a : α} (s : set α) [fintype s] (h : a ∉ s) :
@fintype.card _ (fintype_insert' s h) = fintype.card s + 1 :=
by rw [fintype_insert', card_fintype_of_finset];
simp [finset.card, to_finset]; refl
instance fintype_insert [decidable_eq α] (a : α) (s : set α) [fintype s] : fintype (insert a s : set α) :=
if h : a ∈ s then by rwa [insert_eq, union_eq_self_of_subset_left (singleton_subset_iff.2 h)]
else fintype_insert' _ h
@[simp] theorem card_insert [decidable_eq α] {a : α} (s : set α) [fintype s] (h : a ∉ s) :
fintype.card (insert a s : set α) = fintype.card s + 1 :=
by rw ← card_fintype_insert' s h; congr
@[simp] theorem finite_insert (a : α) {s : set α} : finite s → finite (insert a s)
| ⟨h⟩ := ⟨@set.fintype_insert _ (classical.dec_eq α) _ _ h⟩
lemma to_finset_insert [decidable_eq α] {a : α} {s : set α} (hs : finite s) :
(finite_insert a hs).to_finset = insert a hs.to_finset :=
finset.ext.mpr $ by simp
@[elab_as_eliminator]
theorem finite.induction_on {C : set α → Prop} {s : set α} (h : finite s)
(H0 : C ∅) (H1 : ∀ {a s}, a ∉ s → finite s → C s → C (insert a s)) : C s :=
let ⟨t⟩ := h in by exactI
match s.to_finset, @mem_to_finset _ s _ with
| ⟨l, nd⟩, al := begin
change ∀ a, a ∈ l ↔ a ∈ s at al,
clear _let_match _match t h, revert s nd al,
refine multiset.induction_on l _ (λ a l IH, _); intros s nd al,
{ rw show s = ∅, from eq_empty_iff_forall_not_mem.2 (by simpa using al),
exact H0 },
{ rw ← show insert a {x | x ∈ l} = s, from set.ext (by simpa using al),
cases multiset.nodup_cons.1 nd with m nd',
refine H1 _ ⟨finset.subtype.fintype ⟨l, nd'⟩⟩ (IH nd' (λ _, iff.rfl)),
exact m }
end
end
@[elab_as_eliminator]
theorem finite.dinduction_on {C : ∀s:set α, finite s → Prop} {s : set α} (h : finite s)
(H0 : C ∅ finite_empty)
(H1 : ∀ {a s}, a ∉ s → ∀h:finite s, C s h → C (insert a s) (finite_insert a h)) :
C s h :=
have ∀h:finite s, C s h,
from finite.induction_on h (assume h, H0) (assume a s has hs ih h, H1 has hs (ih _)),
this h
instance fintype_singleton (a : α) : fintype ({a} : set α) :=
fintype_insert' _ (not_mem_empty _)
@[simp] theorem card_singleton (a : α) :
fintype.card ({a} : set α) = 1 :=
by rw [show fintype.card ({a} : set α) = _, from
card_fintype_insert' ∅ (not_mem_empty a)]; refl
@[simp] theorem finite_singleton (a : α) : finite ({a} : set α) :=
⟨set.fintype_singleton _⟩
instance fintype_union [decidable_eq α] (s t : set α) [fintype s] [fintype t] : fintype (s ∪ t : set α) :=
fintype_of_finset (s.to_finset ∪ t.to_finset) $ by simp
theorem finite_union {s t : set α} : finite s → finite t → finite (s ∪ t)
| ⟨hs⟩ ⟨ht⟩ := ⟨@set.fintype_union _ (classical.dec_eq α) _ _ hs ht⟩
instance fintype_sep (s : set α) (p : α → Prop) [fintype s] [decidable_pred p] : fintype ({a ∈ s | p a} : set α) :=
fintype_of_finset (s.to_finset.filter p) $ by simp
instance fintype_inter (s t : set α) [fintype s] [decidable_pred t] : fintype (s ∩ t : set α) :=
set.fintype_sep s t
def fintype_subset (s : set α) {t : set α} [fintype s] [decidable_pred t] (h : t ⊆ s) : fintype t :=
by rw ← inter_eq_self_of_subset_right h; apply_instance
theorem finite_subset {s : set α} : finite s → ∀ {t : set α}, t ⊆ s → finite t
| ⟨hs⟩ t h := ⟨@set.fintype_subset _ _ _ hs (classical.dec_pred t) h⟩
instance fintype_image [decidable_eq β] (s : set α) (f : α → β) [fintype s] : fintype (f '' s) :=
fintype_of_finset (s.to_finset.image f) $ by simp
instance fintype_range [decidable_eq β] (f : α → β) [fintype α] : fintype (range f) :=
fintype_of_finset (finset.univ.image f) $ by simp [range]
theorem finite_image {s : set α} (f : α → β) : finite s → finite (f '' s)
| ⟨h⟩ := ⟨@set.fintype_image _ _ (classical.dec_eq β) _ _ h⟩
def fintype_of_fintype_image [decidable_eq β] (s : set α)
{f : α → β} {g} (I : is_partial_inv f g) [fintype (f '' s)] : fintype s :=
fintype_of_finset ⟨_, @multiset.nodup_filter_map β α g _
(@injective_of_partial_inv_right _ _ f g I) (f '' s).to_finset.2⟩ $ λ a,
begin
suffices : (∃ b x, f x = b ∧ g b = some a ∧ x ∈ s) ↔ a ∈ s,
by simpa [exists_and_distrib_left.symm, and.comm, and.left_comm, and.assoc],
rw exists_swap,
suffices : (∃ x, x ∈ s ∧ g (f x) = some a) ↔ a ∈ s, {simpa [and.comm, and.left_comm, and.assoc]},
simp [I _, (injective_of_partial_inv I).eq_iff]
end
theorem finite_of_finite_image {s : set α} {f : α → β}
(I : injective f) : finite (f '' s) → finite s | ⟨hs⟩ :=
by haveI := classical.dec_eq β; exact
⟨fintype_of_fintype_image _ (partial_inv_of_injective I)⟩
theorem finite_preimage {s : set β} {f : α → β}
(I : injective f) (h : finite s) : finite (f ⁻¹' s) :=
finite_of_finite_image I (finite_subset h (image_preimage_subset f s))
instance fintype_Union [decidable_eq α] {ι : Type*} [fintype ι]
(f : ι → set α) [∀ i, fintype (f i)] : fintype (⋃ i, f i) :=
fintype_of_finset (finset.univ.bind (λ i, (f i).to_finset)) $ by simp
theorem finite_Union {ι : Type*} [fintype ι] {f : ι → set α} (H : ∀i, finite (f i)) : finite (⋃ i, f i) :=
⟨@set.fintype_Union _ (classical.dec_eq α) _ _ _ (λ i, finite.fintype (H i))⟩
theorem finite_sUnion {s : set (set α)} (h : finite s) (H : ∀t∈s, finite t) : finite (⋃₀ s) :=
by rw sUnion_eq_Union'; haveI := finite.fintype h;
apply finite_Union; simpa using H
instance fintype_lt_nat (n : ℕ) : fintype {i | i < n} :=
fintype_of_finset (finset.range n) $ by simp
instance fintype_le_nat (n : ℕ) : fintype {i | i ≤ n} :=
by simpa [nat.lt_succ_iff] using set.fintype_lt_nat (n+1)
lemma finite_le_nat (n : ℕ) : finite {i | i ≤ n} := ⟨set.fintype_le_nat _⟩
instance fintype_prod (s : set α) (t : set β) [fintype s] [fintype t] : fintype (set.prod s t) :=
fintype_of_finset (s.to_finset.product t.to_finset) $ by simp
lemma finite_prod {s : set α} {t : set β} : finite s → finite t → finite (set.prod s t)
| ⟨hs⟩ ⟨ht⟩ := by exactI ⟨set.fintype_prod s t⟩
end set
namespace finset
variables [decidable_eq α] [decidable_eq β]
variables {s t u : finset α} {f : α → β} {a : α}
/-- Convert a finset to a set in the natural way. -/
def to_set (s : finset α) : set α := {x | x ∈ s}
instance : has_lift (finset α) (set α) := ⟨to_set⟩
@[simp] lemma mem_coe : a ∈ (↑s : set α) = (a ∈ s) :=
rfl
lemma finite_to_set (s : finset α) : set.finite (↑s : set α) :=
set.finite_mem_finset s
@[simp] lemma coe_eq_coe : ((↑s : set α) = ↑t) ↔ s = t :=
by simp [finset.ext, set.set_eq_def]
@[simp] lemma coe_subseteq_coe : ((↑s : set α) ⊆ ↑t) ↔ s ⊆ t :=
by simp [finset.subset_iff, set.subset_def]
@[simp] lemma coe_empty : ↑(∅ : finset α) = (∅ : set α) :=
by simp [set.set_eq_def]
@[simp] lemma coe_insert : ↑(insert a s) = (insert a ↑s : set α) :=
by simp [set.set_eq_def]
@[simp] lemma coe_erase : ↑(erase s a) = (↑s \ {a} : set α) :=
by simp [set.set_eq_def, and_comm]
@[simp] lemma coe_sdiff : ↑(s \ t) = (↑s \ ↑t : set α) :=
by simp [set.set_eq_def]
@[simp] lemma coe_singleton : ↑({a} : finset α) = ({a} : set α) :=
by simp [set.set_eq_def]
@[simp] lemma coe_union : ↑(s ∪ t) = (↑s ∪ ↑t : set α) :=
by simp [set.set_eq_def]
@[simp] lemma coe_inter : ↑(s ∩ t) = (↑s ∩ ↑t : set α) :=
by simp [set.set_eq_def]
@[simp] lemma coe_image {f : α → β} : ↑(s.image f) = f '' ↑s :=
by simp [set.set_eq_def]
@[simp] lemma coe_bind {f : α → finset β} : ↑(s.bind f) = (⋃x ∈ (↑s : set α), ↑(f x) : set β) :=
by simp [set.set_eq_def]
@[simp] lemma coe_filter {p : α → Prop} [decidable_pred p] :
↑(s.filter p) = ({x ∈ ↑s | p x} : set α) :=
by simp [set.set_eq_def]
@[simp] lemma coe_to_finset {s : set α} {hs : set.finite s} : ↑(hs.to_finset) = s :=
by simp [set.set_eq_def]
end finset
namespace set
lemma infinite_univ_nat : infinite (univ : set ℕ) :=
assume (h : finite (univ : set ℕ)),
let ⟨n, hn⟩ := finset.exists_nat_subset_range h.to_finset in
have n ∈ finset.range n, from finset.subset_iff.mpr hn $ by simp,
by simp * at *
lemma not_injective_nat_fintype [fintype α] [decidable_eq α] {f : ℕ → α} : ¬ injective f :=
assume (h : injective f),
have finite (f '' univ),
from finite_subset (finset.finite_to_set $ fintype.elems α) (assume a h, fintype.complete a),
have finite (univ : set ℕ), from finite_of_finite_image h this,
infinite_univ_nat this
lemma not_injective_int_fintype [fintype α] [decidable_eq α] {f : ℤ → α} : ¬ injective f :=
assume hf,
have injective (f ∘ (coe : ℕ → ℤ)), from injective_comp hf $ assume i j, int.of_nat_inj,
not_injective_nat_fintype this
end set
|
f64e87e55e1b4297ff447f0f481c6d4b0e9db49c | a7eef317ddec01b9fc6cfbb876fe7ac00f205ac7 | /src/number_theory/sum_four_squares.lean | 26aacc5e96c4bc881e990678d3e0b2dbb1cbcd6b | [
"Apache-2.0"
] | permissive | kmill/mathlib | ea5a007b67ae4e9e18dd50d31d8aa60f650425ee | 1a419a9fea7b959317eddd556e1bb9639f4dcc05 | refs/heads/master | 1,668,578,197,719 | 1,593,629,163,000 | 1,593,629,163,000 | 276,482,939 | 0 | 0 | null | 1,593,637,960,000 | 1,593,637,959,000 | null | UTF-8 | Lean | false | false | 11,897 | lean | /-
Copyright (c) 2019 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes
## Lagrange's four square theorem
The main result in this file is `sum_four_squares`,
a proof that every natural number is the sum of four square numbers.
# Implementation Notes
The proof used is close to Lagrange's original proof.
-/
import data.zmod.basic
import field_theory.finite
import data.int.parity
import data.fintype.card
open finset polynomial finite_field equiv
open_locale big_operators
namespace int
lemma sum_two_squares_of_two_mul_sum_two_squares {m x y : ℤ} (h : 2 * m = x^2 + y^2) :
m = ((x - y) / 2) ^ 2 + ((x + y) / 2) ^ 2 :=
have (x^2 + y^2).even, by simp [h.symm, even_mul],
have hxaddy : (x + y).even, by simpa [pow_two] with parity_simps,
have hxsuby : (x - y).even, by simpa [pow_two] with parity_simps,
have (x^2 + y^2) % 2 = 0, by simp [h.symm],
(domain.mul_right_inj (show (2*2 : ℤ) ≠ 0, from dec_trivial)).1 $
calc 2 * 2 * m = (x - y)^2 + (x + y)^2 : by rw [mul_assoc, h]; ring
... = (2 * ((x - y) / 2))^2 + (2 * ((x + y) / 2))^2 :
by rw [int.mul_div_cancel' hxsuby, int.mul_div_cancel' hxaddy]
... = 2 * 2 * (((x - y) / 2) ^ 2 + ((x + y) / 2) ^ 2) :
by simp [mul_add, pow_succ, mul_comm, mul_assoc, mul_left_comm]
lemma exists_sum_two_squares_add_one_eq_k (p : ℕ) [hp : fact p.prime] :
∃ (a b : ℤ) (k : ℕ), a^2 + b^2 + 1 = k * p ∧ k < p :=
hp.eq_two_or_odd.elim (λ hp2, hp2.symm ▸ ⟨1, 0, 1, rfl, dec_trivial⟩) $ λ hp1,
let ⟨a, b, hab⟩ := zmod.sum_two_squares p (-1) in
have hab' : (p : ℤ) ∣ a.val_min_abs ^ 2 + b.val_min_abs ^ 2 + 1,
from (char_p.int_cast_eq_zero_iff (zmod p) p _).1 $ by simpa [eq_neg_iff_add_eq_zero] using hab,
let ⟨k, hk⟩ := hab' in
have hk0 : 0 ≤ k, from nonneg_of_mul_nonneg_left
(by rw ← hk; exact (add_nonneg (add_nonneg (pow_two_nonneg _) (pow_two_nonneg _)) zero_le_one))
(int.coe_nat_pos.2 hp.pos),
⟨a.val_min_abs, b.val_min_abs, k.nat_abs,
by rw [hk, int.nat_abs_of_nonneg hk0, mul_comm],
lt_of_mul_lt_mul_left
(calc p * k.nat_abs = a.val_min_abs.nat_abs ^ 2 + b.val_min_abs.nat_abs ^ 2 + 1 :
by rw [← int.coe_nat_inj', int.coe_nat_add, int.coe_nat_add, int.coe_nat_pow,
int.coe_nat_pow, int.nat_abs_pow_two, int.nat_abs_pow_two,
int.coe_nat_one, hk, int.coe_nat_mul, int.nat_abs_of_nonneg hk0]
... ≤ (p / 2) ^ 2 + (p / 2)^2 + 1 :
add_le_add
(add_le_add
(nat.pow_le_pow_of_le_left (zmod.nat_abs_val_min_abs_le _) _)
(nat.pow_le_pow_of_le_left (zmod.nat_abs_val_min_abs_le _) _))
(le_refl _)
... < (p / 2) ^ 2 + (p / 2)^ 2 + (p % 2)^2 + ((2 * (p / 2)^2 + (4 * (p / 2) * (p % 2)))) :
by rw [hp1, nat.one_pow, mul_one];
exact (lt_add_iff_pos_right _).2
(add_pos_of_nonneg_of_pos (nat.zero_le _) (mul_pos dec_trivial
(nat.div_pos hp.two_le dec_trivial)))
... = p * p : by { conv_rhs { rw [← nat.mod_add_div p 2] }, ring })
(show 0 ≤ p, from nat.zero_le _)⟩
end int
namespace nat
open int
open_locale classical
private lemma sum_four_squares_of_two_mul_sum_four_squares {m a b c d : ℤ}
(h : a^2 + b^2 + c^2 + d^2 = 2 * m) : ∃ w x y z : ℤ, w^2 + x^2 + y^2 + z^2 = m :=
have ∀ f : fin 4 → zmod 2, (f 0)^2 + (f 1)^2 + (f 2)^2 + (f 3)^2 = 0 →
∃ i : (fin 4), (f i)^2 + f (swap i 0 1)^2 = 0 ∧ f (swap i 0 2)^2 + f (swap i 0 3)^2 = 0,
from dec_trivial,
let f : fin 4 → ℤ := vector.nth (a::b::c::d::vector.nil) in
let ⟨i, hσ⟩ := this (coe ∘ f) (by rw [← @zero_mul (zmod 2) _ m, ← show ((2 : ℤ) : zmod 2) = 0, from rfl,
← int.cast_mul, ← h]; simp only [int.cast_add, int.cast_pow]; refl) in
let σ := swap i 0 in
have h01 : 2 ∣ f (σ 0) ^ 2 + f (σ 1) ^ 2,
from (char_p.int_cast_eq_zero_iff (zmod 2) 2 _).1 $ by simpa [σ] using hσ.1,
have h23 : 2 ∣ f (σ 2) ^ 2 + f (σ 3) ^ 2,
from (char_p.int_cast_eq_zero_iff (zmod 2) 2 _).1 $ by simpa using hσ.2,
let ⟨x, hx⟩ := h01 in let ⟨y, hy⟩ := h23 in
⟨(f (σ 0) - f (σ 1)) / 2, (f (σ 0) + f (σ 1)) / 2, (f (σ 2) - f (σ 3)) / 2, (f (σ 2) + f (σ 3)) / 2,
begin
rw [← int.sum_two_squares_of_two_mul_sum_two_squares hx.symm, add_assoc,
← int.sum_two_squares_of_two_mul_sum_two_squares hy.symm,
← domain.mul_right_inj (show (2 : ℤ) ≠ 0, from dec_trivial), ← h, mul_add, ← hx, ← hy],
have : ∑ x, f (σ x)^2 = ∑ x, f x^2,
{ conv_rhs { rw ← finset.sum_equiv σ } },
have fin4univ : (univ : finset (fin 4)).1 = 0::1::2::3::0, from dec_trivial,
simpa [finset.sum_eq_multiset_sum, fin4univ, multiset.sum_cons, f, add_assoc]
end⟩
private lemma prime_sum_four_squares (p : ℕ) [hp : _root_.fact p.prime] :
∃ a b c d : ℤ, a^2 + b^2 + c^2 + d^2 = p :=
have hm : ∃ m < p, 0 < m ∧ ∃ a b c d : ℤ, a^2 + b^2 + c^2 + d^2 = m * p,
from let ⟨a, b, k, hk⟩ := exists_sum_two_squares_add_one_eq_k p in
⟨k, hk.2, nat.pos_of_ne_zero $
(λ hk0, by { rw [hk0, int.coe_nat_zero, zero_mul] at hk,
exact ne_of_gt (show a^2 + b^2 + 1 > 0, from add_pos_of_nonneg_of_pos
(add_nonneg (pow_two_nonneg _) (pow_two_nonneg _)) zero_lt_one) hk.1 }),
a, b, 1, 0, by simpa [_root_.pow_two] using hk.1⟩,
let m := nat.find hm in
let ⟨a, b, c, d, (habcd : a^2 + b^2 + c^2 + d^2 = m * p)⟩ := (nat.find_spec hm).snd.2 in
by haveI hm0 : _root_.fact (0 < m) := (nat.find_spec hm).snd.1; exact
have hmp : m < p, from (nat.find_spec hm).fst,
m.mod_two_eq_zero_or_one.elim
(λ hm2 : m % 2 = 0,
let ⟨k, hk⟩ := (nat.dvd_iff_mod_eq_zero _ _).2 hm2 in
have hk0 : 0 < k, from nat.pos_of_ne_zero $ λ _, by { simp [*, lt_irrefl] at * },
have hkm : k < m, { rw [hk, two_mul], exact (lt_add_iff_pos_left _).2 hk0 },
false.elim $ nat.find_min hm hkm ⟨lt_trans hkm hmp, hk0,
sum_four_squares_of_two_mul_sum_four_squares
(show a^2 + b^2 + c^2 + d^2 = 2 * (k * p),
by { rw [habcd, hk, int.coe_nat_mul, mul_assoc], simp })⟩)
(λ hm2 : m % 2 = 1,
if hm1 : m = 1 then ⟨a, b, c, d, by simp only [hm1, habcd, int.coe_nat_one, one_mul]⟩
else
let w := (a : zmod m).val_min_abs, x := (b : zmod m).val_min_abs,
y := (c : zmod m).val_min_abs, z := (d : zmod m).val_min_abs in
have hnat_abs : w^2 + x^2 + y^2 + z^2 =
(w.nat_abs^2 + x.nat_abs^2 + y.nat_abs ^2 + z.nat_abs ^ 2 : ℕ),
by simp [_root_.pow_two],
have hwxyzlt : w^2 + x^2 + y^2 + z^2 < m^2,
from calc w^2 + x^2 + y^2 + z^2
= (w.nat_abs^2 + x.nat_abs^2 + y.nat_abs ^2 + z.nat_abs ^ 2 : ℕ) : hnat_abs
... ≤ ((m / 2) ^ 2 + (m / 2) ^ 2 + (m / 2) ^ 2 + (m / 2) ^ 2 : ℕ) :
int.coe_nat_le.2 $ add_le_add (add_le_add (add_le_add
(nat.pow_le_pow_of_le_left (zmod.nat_abs_val_min_abs_le _) _)
(nat.pow_le_pow_of_le_left (zmod.nat_abs_val_min_abs_le _) _))
(nat.pow_le_pow_of_le_left (zmod.nat_abs_val_min_abs_le _) _))
(nat.pow_le_pow_of_le_left (zmod.nat_abs_val_min_abs_le _) _)
... = 4 * (m / 2 : ℕ) ^ 2 : by simp [_root_.pow_two, bit0, bit1, mul_add, add_mul, add_assoc]
... < 4 * (m / 2 : ℕ) ^ 2 + ((4 * (m / 2) : ℕ) * (m % 2 : ℕ) + (m % 2 : ℕ)^2) :
(lt_add_iff_pos_right _).2 (by { rw [hm2, int.coe_nat_one, _root_.one_pow, mul_one],
exact add_pos_of_nonneg_of_pos (int.coe_nat_nonneg _) zero_lt_one })
... = m ^ 2 : by { conv_rhs {rw [← nat.mod_add_div m 2]},
simp [-nat.mod_add_div, mul_add, add_mul, bit0, bit1, mul_comm, mul_assoc, mul_left_comm,
_root_.pow_add, add_comm, add_left_comm] },
have hwxyzabcd : ((w^2 + x^2 + y^2 + z^2 : ℤ) : zmod m) =
((a^2 + b^2 + c^2 + d^2 : ℤ) : zmod m),
by simp [w, x, y, z, pow_two],
have hwxyz0 : ((w^2 + x^2 + y^2 + z^2 : ℤ) : zmod m) = 0,
by rw [hwxyzabcd, habcd, int.cast_mul, cast_coe_nat, zmod.cast_self, zero_mul],
let ⟨n, hn⟩ := ((char_p.int_cast_eq_zero_iff _ m _).1 hwxyz0) in
have hn0 : 0 < n.nat_abs, from int.nat_abs_pos_of_ne_zero (λ hn0,
have hwxyz0 : (w.nat_abs^2 + x.nat_abs^2 + y.nat_abs^2 + z.nat_abs^2 : ℕ) = 0,
by { rw [← int.coe_nat_eq_zero, ← hnat_abs], rwa [hn0, mul_zero] at hn },
have habcd0 : (m : ℤ) ∣ a ∧ (m : ℤ) ∣ b ∧ (m : ℤ) ∣ c ∧ (m : ℤ) ∣ d,
by simpa [@add_eq_zero_iff_eq_zero_of_nonneg ℤ _ _ _ (pow_two_nonneg _) (pow_two_nonneg _),
nat.pow_two, w, x, y, z, (char_p.int_cast_eq_zero_iff _ m _), and.assoc] using hwxyz0,
let ⟨ma, hma⟩ := habcd0.1, ⟨mb, hmb⟩ := habcd0.2.1,
⟨mc, hmc⟩ := habcd0.2.2.1, ⟨md, hmd⟩ := habcd0.2.2.2 in
have hmdvdp : m ∣ p,
from int.coe_nat_dvd.1 ⟨ma^2 + mb^2 + mc^2 + md^2,
(domain.mul_right_inj (show (m : ℤ) ≠ 0, from int.coe_nat_ne_zero_iff_pos.2 hm0)).1 $
by { rw [← habcd, hma, hmb, hmc, hmd], ring }⟩,
(hp.2 _ hmdvdp).elim hm1 (λ hmeqp, by simpa [lt_irrefl, hmeqp] using hmp)),
have hawbxcydz : ((m : ℕ) : ℤ) ∣ a * w + b * x + c * y + d * z,
from (char_p.int_cast_eq_zero_iff (zmod m) m _).1 $ by { rw [← hwxyz0], simp, ring },
have haxbwczdy : ((m : ℕ) : ℤ) ∣ a * x - b * w - c * z + d * y,
from (char_p.int_cast_eq_zero_iff (zmod m) m _).1 $ by { simp [sub_eq_add_neg], ring },
have haybzcwdx : ((m : ℕ) : ℤ) ∣ a * y + b * z - c * w - d * x,
from (char_p.int_cast_eq_zero_iff (zmod m) m _).1 $ by { simp [sub_eq_add_neg], ring },
have hazbycxdw : ((m : ℕ) : ℤ) ∣ a * z - b * y + c * x - d * w,
from (char_p.int_cast_eq_zero_iff (zmod m) m _).1 $ by { simp [sub_eq_add_neg], ring },
let ⟨s, hs⟩ := hawbxcydz, ⟨t, ht⟩ := haxbwczdy, ⟨u, hu⟩ := haybzcwdx, ⟨v, hv⟩ := hazbycxdw in
have hn_nonneg : 0 ≤ n,
from nonneg_of_mul_nonneg_left
(by { erw [← hn], repeat {try {refine add_nonneg _ _}, try {exact pow_two_nonneg _}} })
(int.coe_nat_pos.2 hm0),
have hnm : n.nat_abs < m,
from int.coe_nat_lt.1 (lt_of_mul_lt_mul_left
(by { rw [int.nat_abs_of_nonneg hn_nonneg, ← hn, ← _root_.pow_two], exact hwxyzlt })
(int.coe_nat_nonneg m)),
have hstuv : s^2 + t^2 + u^2 + v^2 = n.nat_abs * p,
from (domain.mul_right_inj (show (m^2 : ℤ) ≠ 0, from pow_ne_zero 2
(int.coe_nat_ne_zero_iff_pos.2 hm0))).1 $
calc (m : ℤ)^2 * (s^2 + t^2 + u^2 + v^2) = ((m : ℕ) * s)^2 + ((m : ℕ) * t)^2 +
((m : ℕ) * u)^2 + ((m : ℕ) * v)^2 :
by { simp [_root_.mul_pow], ring }
... = (w^2 + x^2 + y^2 + z^2) * (a^2 + b^2 + c^2 + d^2) :
by { simp only [hs.symm, ht.symm, hu.symm, hv.symm], ring }
... = _ : by { rw [hn, habcd, int.nat_abs_of_nonneg hn_nonneg], dsimp [m], ring },
false.elim $ nat.find_min hm hnm ⟨lt_trans hnm hmp, hn0, s, t, u, v, hstuv⟩)
lemma sum_four_squares : ∀ n : ℕ, ∃ a b c d : ℕ, a^2 + b^2 + c^2 + d^2 = n
| 0 := ⟨0, 0, 0, 0, rfl⟩
| 1 := ⟨1, 0, 0, 0, rfl⟩
| n@(k+2) :=
have hm : _root_.fact (min_fac (k+2)).prime := min_fac_prime dec_trivial,
have n / min_fac n < n := factors_lemma,
let ⟨a, b, c, d, h₁⟩ := show ∃ a b c d : ℤ, a^2 + b^2 + c^2 + d^2 = min_fac n,
by exactI prime_sum_four_squares (min_fac (k+2)) in
let ⟨w, x, y, z, h₂⟩ := sum_four_squares (n / min_fac n) in
⟨(a * x - b * w - c * z + d * y).nat_abs,
(a * y + b * z - c * w - d * x).nat_abs,
(a * z - b * y + c * x - d * w).nat_abs,
(a * w + b * x + c * y + d * z).nat_abs,
begin
rw [← int.coe_nat_inj', ← nat.mul_div_cancel' (min_fac_dvd (k+2)), int.coe_nat_mul, ← h₁, ← h₂],
simp,
ring
end⟩
end nat
|
e99b51bb32e22f798a902b7604bbf2a4d0f2754d | 5d166a16ae129621cb54ca9dde86c275d7d2b483 | /library/init/meta/level.lean | c67c5e9c8ea083325f63a022376eec88cd62e44c | [
"Apache-2.0"
] | permissive | jcarlson23/lean | b00098763291397e0ac76b37a2dd96bc013bd247 | 8de88701247f54d325edd46c0eed57aeacb64baf | refs/heads/master | 1,611,571,813,719 | 1,497,020,963,000 | 1,497,021,515,000 | 93,882,536 | 1 | 0 | null | 1,497,029,896,000 | 1,497,029,896,000 | null | UTF-8 | Lean | false | false | 2,287 | lean | /-
Copyright (c) 2016 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
prelude
import init.meta.name init.meta.format
/- Reflect a C++ level object. The VM replaces it with the C++ implementation. -/
meta inductive level
| zero : level
| succ : level → level
| max : level → level → level
| imax : level → level → level
| param : name → level
| mvar : name → level
meta instance : inhabited level :=
⟨level.zero⟩
/- TODO(Leo): provide a definition in Lean. -/
meta constant level.has_decidable_eq : decidable_eq level
attribute [instance] level.has_decidable_eq
meta constant level.lt : level → level → bool
meta constant level.lex_lt : level → level → bool
meta constant level.fold {α :Type} : level → α → (level → α → α) → α
/- Return the given level expression normal form -/
meta constant level.normalize : level → level
/- Return tt iff lhs and rhs denote the same level.
The check is done by normalization. -/
meta constant level.eqv : level → level → bool
/- Return tt iff the first level occurs in the second -/
meta constant level.occurs : level → level → bool
/- Replace a parameter named n with l in the first level if the list contains the pair (n, l) -/
meta constant level.instantiate : level → list (name × level) → list level
meta constant level.to_format : level → options → format
meta constant level.to_string : level → string
meta def level.cmp (a b : level) : ordering :=
if level.lt a b then ordering.lt
else if a = b then ordering.eq
else ordering.gt
meta instance : has_to_string level :=
⟨level.to_string⟩
meta instance : has_to_format level :=
⟨λ l, level.to_format l options.mk⟩
meta instance : has_ordering level :=
⟨level.cmp⟩
meta def level.of_nat : nat → level
| 0 := level.zero
| (nat.succ n) := level.succ (level.of_nat n)
meta def level.has_param : level → name → bool
| (level.succ l) n := level.has_param l n
| (level.max l₁ l₂) n := level.has_param l₁ n || level.has_param l₂ n
| (level.imax l₁ l₂) n := level.has_param l₁ n || level.has_param l₂ n
| (level.param n₁) n := n₁ = n
| l n := ff
|
ac2dc12bd13fbf3e0834a686c0e3461630fa6425 | 7cef822f3b952965621309e88eadf618da0c8ae9 | /src/data/equiv/basic.lean | 733e2ab1d2d8636310b5a9f72c772384f70b7161 | [
"Apache-2.0"
] | permissive | rmitta/mathlib | 8d90aee30b4db2b013e01f62c33f297d7e64a43d | 883d974b608845bad30ae19e27e33c285200bf84 | refs/heads/master | 1,585,776,832,544 | 1,576,874,096,000 | 1,576,874,096,000 | 153,663,165 | 0 | 2 | Apache-2.0 | 1,544,806,490,000 | 1,539,884,365,000 | Lean | UTF-8 | Lean | false | false | 42,981 | lean | /-
Copyright (c) 2015 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura, Mario Carneiro
In the standard library we cannot assume the univalence axiom.
We say two types are equivalent if they are isomorphic.
Two equivalent types have the same cardinality.
-/
import tactic.split_ifs logic.function logic.unique data.set.function data.bool data.quot
open function
universes u v w
variables {α : Sort u} {β : Sort v} {γ : Sort w}
/-- `α ≃ β` is the type of functions from `α → β` with a two-sided inverse. -/
structure equiv (α : Sort*) (β : Sort*) :=
(to_fun : α → β)
(inv_fun : β → α)
(left_inv : left_inverse inv_fun to_fun)
(right_inv : right_inverse inv_fun to_fun)
infix ` ≃ `:25 := equiv
def function.involutive.to_equiv {f : α → α} (h : involutive f) : α ≃ α :=
⟨f, f, h.left_inverse, h.right_inverse⟩
namespace equiv
/-- `perm α` is the type of bijections from `α` to itself. -/
@[reducible] def perm (α : Sort*) := equiv α α
instance : has_coe_to_fun (α ≃ β) :=
⟨_, to_fun⟩
@[simp] theorem coe_fn_mk (f : α → β) (g l r) : (equiv.mk f g l r : α → β) = f :=
rfl
theorem eq_of_to_fun_eq : ∀ {e₁ e₂ : equiv α β}, (e₁ : α → β) = e₂ → e₁ = e₂
| ⟨f₁, g₁, l₁, r₁⟩ ⟨f₂, g₂, l₂, r₂⟩ h :=
have f₁ = f₂, from h,
have g₁ = g₂, from funext $ assume x,
have f₁ (g₁ x) = f₂ (g₂ x), from (r₁ x).trans (r₂ x).symm,
have f₁ (g₁ x) = f₁ (g₂ x), by { subst f₂, exact this },
show g₁ x = g₂ x, from injective_of_left_inverse l₁ this,
by simp *
@[ext] lemma ext (f g : equiv α β) (H : ∀ x, f x = g x) : f = g :=
eq_of_to_fun_eq (funext H)
@[ext] lemma perm.ext (σ τ : equiv.perm α) (H : ∀ x, σ x = τ x) : σ = τ :=
equiv.ext _ _ H
@[refl] protected def refl (α : Sort*) : α ≃ α := ⟨id, id, λ x, rfl, λ x, rfl⟩
@[symm] protected def symm (e : α ≃ β) : β ≃ α := ⟨e.inv_fun, e.to_fun, e.right_inv, e.left_inv⟩
@[trans] protected def trans (e₁ : α ≃ β) (e₂ : β ≃ γ) : α ≃ γ :=
⟨e₂.to_fun ∘ e₁.to_fun, e₁.inv_fun ∘ e₂.inv_fun,
e₂.left_inv.comp e₁.left_inv, e₂.right_inv.comp e₁.right_inv⟩
protected theorem injective : ∀ f : α ≃ β, injective f
| ⟨f, g, h₁, h₂⟩ := injective_of_left_inverse h₁
protected theorem surjective : ∀ f : α ≃ β, surjective f
| ⟨f, g, h₁, h₂⟩ := surjective_of_has_right_inverse ⟨_, h₂⟩
protected theorem bijective (f : α ≃ β) : bijective f :=
⟨f.injective, f.surjective⟩
@[simp] lemma range_eq_univ {α : Type*} {β : Type*} (e : α ≃ β) : set.range e = set.univ :=
set.eq_univ_of_forall e.surjective
protected theorem subsingleton (e : α ≃ β) : ∀ [subsingleton β], subsingleton α
| ⟨H⟩ := ⟨λ a b, e.injective (H _ _)⟩
protected def decidable_eq (e : α ≃ β) [H : decidable_eq β] : decidable_eq α
| a b := decidable_of_iff _ e.injective.eq_iff
lemma nonempty_iff_nonempty : α ≃ β → (nonempty α ↔ nonempty β)
| ⟨f, g, _, _⟩ := nonempty.congr f g
protected def cast {α β : Sort*} (h : α = β) : α ≃ β :=
⟨cast h, cast h.symm, λ x, by { cases h, refl }, λ x, by { cases h, refl }⟩
@[simp] theorem coe_fn_symm_mk (f : α → β) (g l r) : ((equiv.mk f g l r).symm : β → α) = g :=
rfl
@[simp] theorem refl_apply (x : α) : equiv.refl α x = x := rfl
@[simp] theorem trans_apply (f : α ≃ β) (g : β ≃ γ) (a : α) : (f.trans g) a = g (f a) := rfl
@[simp] theorem apply_symm_apply : ∀ (e : α ≃ β) (x : β), e (e.symm x) = x
| ⟨f₁, g₁, l₁, r₁⟩ x := by { simp [equiv.symm], rw r₁ }
@[simp] theorem symm_apply_apply : ∀ (e : α ≃ β) (x : α), e.symm (e x) = x
| ⟨f₁, g₁, l₁, r₁⟩ x := by { simp [equiv.symm], rw l₁ }
@[simp] lemma symm_trans_apply (f : α ≃ β) (g : β ≃ γ) (a : γ) :
(f.trans g).symm a = f.symm (g.symm a) := rfl
@[simp] theorem apply_eq_iff_eq : ∀ (f : α ≃ β) (x y : α), f x = f y ↔ x = y
| ⟨f₁, g₁, l₁, r₁⟩ x y := (injective_of_left_inverse l₁).eq_iff
@[simp] theorem cast_apply {α β} (h : α = β) (x : α) : equiv.cast h x = cast h x := rfl
lemma symm_apply_eq {α β} (e : α ≃ β) {x y} : e.symm x = y ↔ x = e y :=
⟨λ H, by simp [H.symm], λ H, by simp [H]⟩
lemma eq_symm_apply {α β} (e : α ≃ β) {x y} : y = e.symm x ↔ e y = x :=
(eq_comm.trans e.symm_apply_eq).trans eq_comm
@[simp] theorem symm_symm (e : α ≃ β) : e.symm.symm = e := by { cases e, refl }
@[simp] theorem symm_symm_apply (e : α ≃ β) (a : α) : e.symm.symm a = e a := by { cases e, refl }
@[simp] theorem trans_refl (e : α ≃ β) : e.trans (equiv.refl β) = e := by { cases e, refl }
@[simp] theorem refl_symm : (equiv.refl α).symm = equiv.refl α := rfl
@[simp] theorem refl_trans (e : α ≃ β) : (equiv.refl α).trans e = e := by { cases e, refl }
@[simp] theorem symm_trans (e : α ≃ β) : e.symm.trans e = equiv.refl β := ext _ _ (by simp)
@[simp] theorem trans_symm (e : α ≃ β) : e.trans e.symm = equiv.refl α := ext _ _ (by simp)
lemma trans_assoc {δ} (ab : α ≃ β) (bc : β ≃ γ) (cd : γ ≃ δ) :
(ab.trans bc).trans cd = ab.trans (bc.trans cd) :=
equiv.ext _ _ $ assume a, rfl
theorem left_inverse_symm (f : equiv α β) : left_inverse f.symm f := f.left_inv
theorem right_inverse_symm (f : equiv α β) : function.right_inverse f.symm f := f.right_inv
def equiv_congr {δ} (ab : α ≃ β) (cd : γ ≃ δ) : (α ≃ γ) ≃ (β ≃ δ) :=
⟨ λac, (ab.symm.trans ac).trans cd, λbd, ab.trans $ bd.trans $ cd.symm,
assume ac, begin simp [trans_assoc], rw [← trans_assoc], simp end,
assume ac, begin simp [trans_assoc], rw [← trans_assoc], simp end, ⟩
def perm_congr {α : Type*} {β : Type*} (e : α ≃ β) : perm α ≃ perm β :=
equiv_congr e e
protected lemma image_eq_preimage {α β} (e : α ≃ β) (s : set α) : e '' s = e.symm ⁻¹' s :=
set.ext $ assume x, set.mem_image_iff_of_inverse e.left_inv e.right_inv
protected lemma subset_image {α β} (e : α ≃ β) (s : set α) (t : set β) : t ⊆ e '' s ↔ e.symm '' t ⊆ s :=
by rw [set.image_subset_iff, e.image_eq_preimage]
lemma symm_image_image {α β} (f : equiv α β) (s : set α) : f.symm '' (f '' s) = s :=
by { rw [← set.image_comp], simp }
protected lemma image_compl {α β} (f : equiv α β) (s : set α) :
f '' -s = -(f '' s) :=
set.image_compl_eq f.bijective
/- The group of permutations (self-equivalences) of a type `α` -/
namespace perm
instance perm_group {α : Type u} : group (perm α) :=
begin
refine { mul := λ f g, equiv.trans g f, one := equiv.refl α, inv:= equiv.symm, ..};
intros; apply equiv.ext; try { apply trans_apply },
apply symm_apply_apply
end
@[simp] theorem mul_apply {α : Type u} (f g : perm α) (x) : (f * g) x = f (g x) :=
equiv.trans_apply _ _ _
@[simp] theorem one_apply {α : Type u} (x) : (1 : perm α) x = x := rfl
@[simp] lemma inv_apply_self {α : Type u} (f : perm α) (x) :
f⁻¹ (f x) = x := equiv.symm_apply_apply _ _
@[simp] lemma apply_inv_self {α : Type u} (f : perm α) (x) :
f (f⁻¹ x) = x := equiv.apply_symm_apply _ _
lemma one_def {α : Type u} : (1 : perm α) = equiv.refl α := rfl
lemma mul_def {α : Type u} (f g : perm α) : f * g = g.trans f := rfl
lemma inv_def {α : Type u} (f : perm α) : f⁻¹ = f.symm := rfl
end perm
def equiv_empty (h : α → false) : α ≃ empty :=
⟨λ x, (h x).elim, λ e, e.rec _, λ x, (h x).elim, λ e, e.rec _⟩
def false_equiv_empty : false ≃ empty :=
equiv_empty _root_.id
def equiv_pempty (h : α → false) : α ≃ pempty :=
⟨λ x, (h x).elim, λ e, e.rec _, λ x, (h x).elim, λ e, e.rec _⟩
def false_equiv_pempty : false ≃ pempty :=
equiv_pempty _root_.id
def empty_equiv_pempty : empty ≃ pempty :=
equiv_pempty $ empty.rec _
def pempty_equiv_pempty : pempty.{v} ≃ pempty.{w} :=
equiv_pempty pempty.elim
def empty_of_not_nonempty {α : Sort*} (h : ¬ nonempty α) : α ≃ empty :=
equiv_empty $ assume a, h ⟨a⟩
def pempty_of_not_nonempty {α : Sort*} (h : ¬ nonempty α) : α ≃ pempty :=
equiv_pempty $ assume a, h ⟨a⟩
def prop_equiv_punit {p : Prop} (h : p) : p ≃ punit :=
⟨λ x, (), λ x, h, λ _, rfl, λ ⟨⟩, rfl⟩
def true_equiv_punit : true ≃ punit := prop_equiv_punit trivial
protected def ulift {α : Type u} : ulift α ≃ α :=
⟨ulift.down, ulift.up, ulift.up_down, λ a, rfl⟩
protected def plift : plift α ≃ α :=
⟨plift.down, plift.up, plift.up_down, plift.down_up⟩
@[congr] def arrow_congr {α₁ β₁ α₂ β₂ : Sort*} (e₁ : α₁ ≃ α₂) (e₂ : β₁ ≃ β₂) :
(α₁ → β₁) ≃ (α₂ → β₂) :=
{ to_fun := λ f, e₂.to_fun ∘ f ∘ e₁.inv_fun,
inv_fun := λ f, e₂.inv_fun ∘ f ∘ e₁.to_fun,
left_inv := λ f, funext $ λ x, by { dsimp, rw [e₂.left_inv, e₁.left_inv] },
right_inv := λ f, funext $ λ x, by { dsimp, rw [e₂.right_inv, e₁.right_inv] } }
@[simp] lemma arrow_congr_apply {α₁ β₁ α₂ β₂ : Sort*} (e₁ : α₁ ≃ α₂) (e₂ : β₁ ≃ β₂)
(f : α₁ → β₁) (x : α₂) :
arrow_congr e₁ e₂ f x = (e₂ $ f $ e₁.symm x) :=
rfl
lemma arrow_congr_comp {α₁ β₁ γ₁ α₂ β₂ γ₂ : Sort*}
(ea : α₁ ≃ α₂) (eb : β₁ ≃ β₂) (ec : γ₁ ≃ γ₂) (f : α₁ → β₁) (g : β₁ → γ₁) :
arrow_congr ea ec (g ∘ f) = (arrow_congr eb ec g) ∘ (arrow_congr ea eb f) :=
by { ext, simp only [comp, arrow_congr_apply, eb.symm_apply_apply] }
@[simp] lemma arrow_congr_refl {α β : Sort*} :
arrow_congr (equiv.refl α) (equiv.refl β) = equiv.refl (α → β) := rfl
@[simp] lemma arrow_congr_trans {α₁ β₁ α₂ β₂ α₃ β₃ : Sort*}
(e₁ : α₁ ≃ α₂) (e₁' : β₁ ≃ β₂) (e₂ : α₂ ≃ α₃) (e₂' : β₂ ≃ β₃) :
arrow_congr (e₁.trans e₂) (e₁'.trans e₂') = (arrow_congr e₁ e₁').trans (arrow_congr e₂ e₂') :=
rfl
@[simp] lemma arrow_congr_symm {α₁ β₁ α₂ β₂ : Sort*} (e₁ : α₁ ≃ α₂) (e₂ : β₁ ≃ β₂) :
(arrow_congr e₁ e₂).symm = arrow_congr e₁.symm e₂.symm :=
rfl
def conj (e : α ≃ β) : (α → α) ≃ (β → β) := arrow_congr e e
@[simp] lemma conj_apply (e : α ≃ β) (f : α → α) (x : β) :
e.conj f x = (e $ f $ e.symm x) :=
rfl
@[simp] lemma conj_refl : conj (equiv.refl α) = equiv.refl (α → α) := rfl
@[simp] lemma conj_symm (e : α ≃ β) : e.conj.symm = e.symm.conj := rfl
@[simp] lemma conj_trans (e₁ : α ≃ β) (e₂ : β ≃ γ) :
(e₁.trans e₂).conj = e₁.conj.trans e₂.conj :=
rfl
@[simp] lemma conj_comp (e : α ≃ β) (f₁ f₂ : α → α) :
e.conj (f₁ ∘ f₂) = (e.conj f₁) ∘ (e.conj f₂) :=
by apply arrow_congr_comp
def punit_equiv_punit : punit.{v} ≃ punit.{w} :=
⟨λ _, punit.star, λ _, punit.star, λ u, by { cases u, refl }, λ u, by { cases u, reflexivity }⟩
section
@[simp] def arrow_punit_equiv_punit (α : Sort*) : (α → punit.{v}) ≃ punit.{w} :=
⟨λ f, punit.star, λ u f, punit.star,
λ f, by { funext x, cases f x, refl }, λ u, by { cases u, reflexivity }⟩
@[simp] def punit_arrow_equiv (α : Sort*) : (punit.{u} → α) ≃ α :=
⟨λ f, f punit.star, λ a u, a, λ f, by { funext x, cases x, refl }, λ u, rfl⟩
@[simp] def empty_arrow_equiv_punit (α : Sort*) : (empty → α) ≃ punit.{u} :=
⟨λ f, punit.star, λ u e, e.rec _, λ f, funext $ λ x, x.rec _, λ u, by { cases u, refl }⟩
@[simp] def pempty_arrow_equiv_punit (α : Sort*) : (pempty → α) ≃ punit.{u} :=
⟨λ f, punit.star, λ u e, e.rec _, λ f, funext $ λ x, x.rec _, λ u, by { cases u, refl }⟩
@[simp] def false_arrow_equiv_punit (α : Sort*) : (false → α) ≃ punit.{u} :=
calc (false → α) ≃ (empty → α) : arrow_congr false_equiv_empty (equiv.refl _)
... ≃ punit : empty_arrow_equiv_punit _
end
@[congr] def prod_congr {α₁ β₁ α₂ β₂ : Sort*} (e₁ : α₁ ≃ α₂) (e₂ :β₁ ≃ β₂) : α₁ × β₁ ≃ α₂ × β₂ :=
⟨λp, (e₁ p.1, e₂ p.2), λp, (e₁.symm p.1, e₂.symm p.2),
λ ⟨a, b⟩, show (e₁.symm (e₁ a), e₂.symm (e₂ b)) = (a, b), by rw [symm_apply_apply, symm_apply_apply],
λ ⟨a, b⟩, show (e₁ (e₁.symm a), e₂ (e₂.symm b)) = (a, b), by rw [apply_symm_apply, apply_symm_apply]⟩
@[simp] theorem prod_congr_apply {α₁ β₁ α₂ β₂ : Sort*} (e₁ : α₁ ≃ α₂) (e₂ : β₁ ≃ β₂) (a : α₁) (b : β₁) :
prod_congr e₁ e₂ (a, b) = (e₁ a, e₂ b) :=
rfl
@[simp] def prod_comm (α β : Sort*) : α × β ≃ β × α :=
⟨λ p, (p.2, p.1), λ p, (p.2, p.1), λ⟨a, b⟩, rfl, λ⟨a, b⟩, rfl⟩
@[simp] def prod_assoc (α β γ : Sort*) : (α × β) × γ ≃ α × (β × γ) :=
⟨λ p, ⟨p.1.1, ⟨p.1.2, p.2⟩⟩, λp, ⟨⟨p.1, p.2.1⟩, p.2.2⟩, λ ⟨⟨a, b⟩, c⟩, rfl, λ ⟨a, ⟨b, c⟩⟩, rfl⟩
@[simp] theorem prod_assoc_apply {α β γ : Sort*} (p : (α × β) × γ) :
prod_assoc α β γ p = ⟨p.1.1, ⟨p.1.2, p.2⟩⟩ := rfl
section
@[simp] def prod_punit (α : Sort*) : α × punit.{u+1} ≃ α :=
⟨λ p, p.1, λ a, (a, punit.star), λ ⟨_, punit.star⟩, rfl, λ a, rfl⟩
@[simp] theorem prod_punit_apply {α : Sort*} (a : α × punit.{u+1}) : prod_punit α a = a.1 := rfl
@[simp] def punit_prod (α : Sort*) : punit.{u+1} × α ≃ α :=
calc punit × α ≃ α × punit : prod_comm _ _
... ≃ α : prod_punit _
@[simp] theorem punit_prod_apply {α : Sort*} (a : punit.{u+1} × α) : punit_prod α a = a.2 := rfl
@[simp] def prod_empty (α : Sort*) : α × empty ≃ empty :=
equiv_empty (λ ⟨_, e⟩, e.rec _)
@[simp] def empty_prod (α : Sort*) : empty × α ≃ empty :=
equiv_empty (λ ⟨e, _⟩, e.rec _)
@[simp] def prod_pempty (α : Sort*) : α × pempty ≃ pempty :=
equiv_pempty (λ ⟨_, e⟩, e.rec _)
@[simp] def pempty_prod (α : Sort*) : pempty × α ≃ pempty :=
equiv_pempty (λ ⟨e, _⟩, e.rec _)
end
section
open sum
def psum_equiv_sum (α β : Sort*) : psum α β ≃ α ⊕ β :=
⟨λ s, psum.cases_on s inl inr,
λ s, sum.cases_on s psum.inl psum.inr,
λ s, by cases s; refl,
λ s, by cases s; refl⟩
def sum_congr {α₁ β₁ α₂ β₂ : Sort*} : α₁ ≃ α₂ → β₁ ≃ β₂ → α₁ ⊕ β₁ ≃ α₂ ⊕ β₂
| ⟨f₁, g₁, l₁, r₁⟩ ⟨f₂, g₂, l₂, r₂⟩ :=
⟨λ s, match s with inl a₁ := inl (f₁ a₁) | inr b₁ := inr (f₂ b₁) end,
λ s, match s with inl a₂ := inl (g₁ a₂) | inr b₂ := inr (g₂ b₂) end,
λ s, match s with inl a := congr_arg inl (l₁ a) | inr a := congr_arg inr (l₂ a) end,
λ s, match s with inl a := congr_arg inl (r₁ a) | inr a := congr_arg inr (r₂ a) end⟩
@[simp] theorem sum_congr_apply_inl {α₁ β₁ α₂ β₂ : Sort*} (e₁ : α₁ ≃ α₂) (e₂ : β₁ ≃ β₂) (a : α₁) :
sum_congr e₁ e₂ (inl a) = inl (e₁ a) :=
by { cases e₁, cases e₂, refl }
@[simp] theorem sum_congr_apply_inr {α₁ β₁ α₂ β₂ : Sort*} (e₁ : α₁ ≃ α₂) (e₂ : β₁ ≃ β₂) (b : β₁) :
sum_congr e₁ e₂ (inr b) = inr (e₂ b) :=
by { cases e₁, cases e₂, refl }
@[simp] lemma sum_congr_symm {α β γ δ : Type u} (e : α ≃ β) (f : γ ≃ δ) (x) :
(equiv.sum_congr e f).symm x = (equiv.sum_congr (e.symm) (f.symm)) x :=
by { cases e, cases f, cases x; refl }
def bool_equiv_punit_sum_punit : bool ≃ punit.{u+1} ⊕ punit.{v+1} :=
⟨λ b, cond b (inr punit.star) (inl punit.star),
λ s, sum.rec_on s (λ_, ff) (λ_, tt),
λ b, by cases b; refl,
λ s, by rcases s with ⟨⟨⟩⟩ | ⟨⟨⟩⟩; refl⟩
noncomputable def Prop_equiv_bool : Prop ≃ bool :=
⟨λ p, @to_bool p (classical.prop_decidable _),
λ b, b, λ p, by simp, λ b, by simp⟩
@[simp] def sum_comm (α β : Sort*) : α ⊕ β ≃ β ⊕ α :=
⟨λ s, match s with inl a := inr a | inr b := inl b end,
λ s, match s with inl b := inr b | inr a := inl a end,
λ s, by cases s; refl,
λ s, by cases s; refl⟩
@[simp] def sum_assoc (α β γ : Sort*) : (α ⊕ β) ⊕ γ ≃ α ⊕ (β ⊕ γ) :=
⟨λ s, match s with inl (inl a) := inl a | inl (inr b) := inr (inl b) | inr c := inr (inr c) end,
λ s, match s with inl a := inl (inl a) | inr (inl b) := inl (inr b) | inr (inr c) := inr c end,
λ s, by rcases s with ⟨_ | _⟩ | _; refl,
λ s, by rcases s with _ | _ | _; refl⟩
@[simp] theorem sum_assoc_apply_in1 {α β γ} (a) : sum_assoc α β γ (inl (inl a)) = inl a := rfl
@[simp] theorem sum_assoc_apply_in2 {α β γ} (b) : sum_assoc α β γ (inl (inr b)) = inr (inl b) := rfl
@[simp] theorem sum_assoc_apply_in3 {α β γ} (c) : sum_assoc α β γ (inr c) = inr (inr c) := rfl
@[simp] def sum_empty (α : Sort*) : α ⊕ empty ≃ α :=
⟨λ s, match s with inl a := a | inr e := empty.rec _ e end,
inl,
λ s, by { rcases s with _ | ⟨⟨⟩⟩, refl },
λ a, rfl⟩
@[simp] def empty_sum (α : Sort*) : empty ⊕ α ≃ α :=
(sum_comm _ _).trans $ sum_empty _
@[simp] def sum_pempty (α : Sort*) : α ⊕ pempty ≃ α :=
⟨λ s, match s with inl a := a | inr e := pempty.rec _ e end,
inl,
λ s, by { rcases s with _ | ⟨⟨⟩⟩, refl },
λ a, rfl⟩
@[simp] def pempty_sum (α : Sort*) : pempty ⊕ α ≃ α :=
(sum_comm _ _).trans $ sum_pempty _
@[simp] def option_equiv_sum_punit (α : Sort*) : option α ≃ α ⊕ punit.{u+1} :=
⟨λ o, match o with none := inr punit.star | some a := inl a end,
λ s, match s with inr _ := none | inl a := some a end,
λ o, by cases o; refl,
λ s, by rcases s with _ | ⟨⟨⟩⟩; refl⟩
def sum_equiv_sigma_bool (α β : Sort*) : α ⊕ β ≃ (Σ b: bool, cond b α β) :=
⟨λ s, match s with inl a := ⟨tt, a⟩ | inr b := ⟨ff, b⟩ end,
λ s, match s with ⟨tt, a⟩ := inl a | ⟨ff, b⟩ := inr b end,
λ s, by cases s; refl,
λ s, by rcases s with ⟨_|_, _⟩; refl⟩
def sigma_preimage_equiv {α β : Type*} (f : α → β) :
(Σ y : β, {x // f x = y}) ≃ α :=
⟨λ x, x.2.1, λ x, ⟨f x, x, rfl⟩, λ ⟨y, x, rfl⟩, rfl, λ x, rfl⟩
end
section
def Pi_congr_right {α} {β₁ β₂ : α → Sort*} (F : ∀ a, β₁ a ≃ β₂ a) : (Π a, β₁ a) ≃ (Π a, β₂ a) :=
⟨λ H a, F a (H a), λ H a, (F a).symm (H a),
λ H, funext $ by simp, λ H, funext $ by simp⟩
def Pi_curry {α} {β : α → Sort*} (γ : Π a, β a → Sort*) : (Π x : sigma β, γ x.1 x.2) ≃ (Π a b, γ a b) :=
{ to_fun := λ f x y, f ⟨x,y⟩,
inv_fun := λ f x, f x.1 x.2,
left_inv := λ f, funext $ λ ⟨x,y⟩, rfl,
right_inv := λ f, funext $ λ x, funext $ λ y, rfl }
end
section
def psigma_equiv_sigma {α} (β : α → Sort*) : psigma β ≃ sigma β :=
⟨λ ⟨a, b⟩, ⟨a, b⟩, λ ⟨a, b⟩, ⟨a, b⟩, λ ⟨a, b⟩, rfl, λ ⟨a, b⟩, rfl⟩
def sigma_congr_right {α} {β₁ β₂ : α → Sort*} (F : ∀ a, β₁ a ≃ β₂ a) : sigma β₁ ≃ sigma β₂ :=
⟨λ ⟨a, b⟩, ⟨a, F a b⟩, λ ⟨a, b⟩, ⟨a, (F a).symm b⟩,
λ ⟨a, b⟩, congr_arg (sigma.mk a) $ symm_apply_apply (F a) b,
λ ⟨a, b⟩, congr_arg (sigma.mk a) $ apply_symm_apply (F a) b⟩
def sigma_congr_left {α₁ α₂} {β : α₂ → Sort*} : ∀ f : α₁ ≃ α₂, (Σ a:α₁, β (f a)) ≃ (Σ a:α₂, β a)
| ⟨f, g, l, r⟩ :=
⟨λ ⟨a, b⟩, ⟨f a, b⟩, λ ⟨a, b⟩, ⟨g a, @@eq.rec β b (r a).symm⟩,
λ ⟨a, b⟩, match g (f a), l a : ∀ a' (h : a' = a),
@sigma.mk _ (β ∘ f) _ (@@eq.rec β b (congr_arg f h.symm)) = ⟨a, b⟩ with
| _, rfl := rfl end,
λ ⟨a, b⟩, match f (g a), _ : ∀ a' (h : a' = a), sigma.mk a' (@@eq.rec β b h.symm) = ⟨a, b⟩ with
| _, rfl := rfl end⟩
def sigma_equiv_prod (α β : Sort*) : (Σ_:α, β) ≃ α × β :=
⟨λ ⟨a, b⟩, ⟨a, b⟩, λ ⟨a, b⟩, ⟨a, b⟩, λ ⟨a, b⟩, rfl, λ ⟨a, b⟩, rfl⟩
def sigma_equiv_prod_of_equiv {α β} {β₁ : α → Sort*} (F : ∀ a, β₁ a ≃ β) : sigma β₁ ≃ α × β :=
(sigma_congr_right F).trans (sigma_equiv_prod α β)
end
section
def arrow_prod_equiv_prod_arrow (α β γ : Type*) : (γ → α × β) ≃ (γ → α) × (γ → β) :=
⟨λ f, (λ c, (f c).1, λ c, (f c).2),
λ p c, (p.1 c, p.2 c),
λ f, funext $ λ c, prod.mk.eta,
λ p, by { cases p, refl }⟩
def arrow_arrow_equiv_prod_arrow (α β γ : Sort*) : (α → β → γ) ≃ (α × β → γ) :=
⟨λ f, λ p, f p.1 p.2,
λ f, λ a b, f (a, b),
λ f, rfl,
λ f, by { funext p, cases p, refl }⟩
open sum
def sum_arrow_equiv_prod_arrow (α β γ : Type*) : ((α ⊕ β) → γ) ≃ (α → γ) × (β → γ) :=
⟨λ f, (f ∘ inl, f ∘ inr),
λ p s, sum.rec_on s p.1 p.2,
λ f, by { funext s, cases s; refl },
λ p, by { cases p, refl }⟩
def sum_prod_distrib (α β γ : Sort*) : (α ⊕ β) × γ ≃ (α × γ) ⊕ (β × γ) :=
⟨λ p, match p with (inl a, c) := inl (a, c) | (inr b, c) := inr (b, c) end,
λ s, match s with inl (a, c) := (inl a, c) | inr (b, c) := (inr b, c) end,
λ p, by rcases p with ⟨_ | _, _⟩; refl,
λ s, by rcases s with ⟨_, _⟩ | ⟨_, _⟩; refl⟩
@[simp] theorem sum_prod_distrib_apply_left {α β γ} (a : α) (c : γ) :
sum_prod_distrib α β γ (sum.inl a, c) = sum.inl (a, c) := rfl
@[simp] theorem sum_prod_distrib_apply_right {α β γ} (b : β) (c : γ) :
sum_prod_distrib α β γ (sum.inr b, c) = sum.inr (b, c) := rfl
def prod_sum_distrib (α β γ : Sort*) : α × (β ⊕ γ) ≃ (α × β) ⊕ (α × γ) :=
calc α × (β ⊕ γ) ≃ (β ⊕ γ) × α : prod_comm _ _
... ≃ (β × α) ⊕ (γ × α) : sum_prod_distrib _ _ _
... ≃ (α × β) ⊕ (α × γ) : sum_congr (prod_comm _ _) (prod_comm _ _)
@[simp] theorem prod_sum_distrib_apply_left {α β γ} (a : α) (b : β) :
prod_sum_distrib α β γ (a, sum.inl b) = sum.inl (a, b) := rfl
@[simp] theorem prod_sum_distrib_apply_right {α β γ} (a : α) (c : γ) :
prod_sum_distrib α β γ (a, sum.inr c) = sum.inr (a, c) := rfl
def sigma_prod_distrib {ι : Type*} (α : ι → Type*) (β : Type*) :
((Σ i, α i) × β) ≃ (Σ i, (α i × β)) :=
⟨λ p, ⟨p.1.1, (p.1.2, p.2)⟩,
λ p, (⟨p.1, p.2.1⟩, p.2.2),
λ p, by { rcases p with ⟨⟨_, _⟩, _⟩, refl },
λ p, by { rcases p with ⟨_, ⟨_, _⟩⟩, refl }⟩
def bool_prod_equiv_sum (α : Type u) : bool × α ≃ α ⊕ α :=
calc bool × α ≃ (unit ⊕ unit) × α : prod_congr bool_equiv_punit_sum_punit (equiv.refl _)
... ≃ α × (unit ⊕ unit) : prod_comm _ _
... ≃ (α × unit) ⊕ (α × unit) : prod_sum_distrib _ _ _
... ≃ α ⊕ α : sum_congr (prod_punit _) (prod_punit _)
end
section
open sum nat
def nat_equiv_nat_sum_punit : ℕ ≃ ℕ ⊕ punit.{u+1} :=
⟨λ n, match n with zero := inr punit.star | succ a := inl a end,
λ s, match s with inl n := succ n | inr punit.star := zero end,
λ n, begin cases n, repeat { refl } end,
λ s, begin cases s with a u, { refl }, {cases u, { refl }} end⟩
@[simp] def nat_sum_punit_equiv_nat : ℕ ⊕ punit.{u+1} ≃ ℕ :=
nat_equiv_nat_sum_punit.symm
def int_equiv_nat_sum_nat : ℤ ≃ ℕ ⊕ ℕ :=
by refine ⟨_, _, _, _⟩; intro z; {cases z; [left, right]; assumption} <|> {cases z; refl}
end
def list_equiv_of_equiv {α β : Type*} : α ≃ β → list α ≃ list β
| ⟨f, g, l, r⟩ :=
by refine ⟨list.map f, list.map g, λ x, _, λ x, _⟩;
simp [id_of_left_inverse l, id_of_right_inverse r]
def fin_equiv_subtype (n : ℕ) : fin n ≃ {m // m < n} :=
⟨λ x, ⟨x.1, x.2⟩, λ x, ⟨x.1, x.2⟩, λ ⟨a, b⟩, rfl,λ ⟨a, b⟩, rfl⟩
def decidable_eq_of_equiv [decidable_eq β] (e : α ≃ β) : decidable_eq α
| a₁ a₂ := decidable_of_iff (e a₁ = e a₂) e.injective.eq_iff
def inhabited_of_equiv [inhabited β] (e : α ≃ β) : inhabited α :=
⟨e.symm (default _)⟩
def unique_of_equiv (e : α ≃ β) (h : unique β) : unique α :=
unique.of_surjective e.symm.surjective
def unique_congr (e : α ≃ β) : unique α ≃ unique β :=
{ to_fun := e.symm.unique_of_equiv,
inv_fun := e.unique_of_equiv,
left_inv := λ _, subsingleton.elim _ _,
right_inv := λ _, subsingleton.elim _ _ }
section
open subtype
def subtype_congr {p : α → Prop} {q : β → Prop}
(e : α ≃ β) (h : ∀ a, p a ↔ q (e a)) : {a : α // p a} ≃ {b : β // q b} :=
⟨λ x, ⟨e x.1, (h _).1 x.2⟩,
λ y, ⟨e.symm y.1, (h _).2 (by { simp, exact y.2 })⟩,
λ ⟨x, h⟩, subtype.eq' $ by simp,
λ ⟨y, h⟩, subtype.eq' $ by simp⟩
def subtype_congr_right {p q : α → Prop} (e : ∀x, p x ↔ q x) : subtype p ≃ subtype q :=
subtype_congr (equiv.refl _) e
@[simp] lemma subtype_congr_right_mk {p q : α → Prop} (e : ∀x, p x ↔ q x)
{x : α} (h : p x) : subtype_congr_right e ⟨x, h⟩ = ⟨x, (e x).1 h⟩ := rfl
def subtype_equiv_of_subtype' {p : α → Prop} (e : α ≃ β) :
{a : α // p a} ≃ {b : β // p (e.symm b)} :=
subtype_congr e $ by simp
def subtype_congr_prop {α : Type*} {p q : α → Prop} (h : p = q) : subtype p ≃ subtype q :=
subtype_congr (equiv.refl α) (assume a, h ▸ iff.rfl)
def set_congr {α : Type*} {s t : set α} (h : s = t) : s ≃ t :=
subtype_congr_prop h
def subtype_subtype_equiv_subtype_exists {α : Type u} (p : α → Prop) (q : subtype p → Prop) :
subtype q ≃ {a : α // ∃h:p a, q ⟨a, h⟩ } :=
⟨λ⟨⟨a, ha⟩, ha'⟩, ⟨a, ha, ha'⟩,
λ⟨a, ha⟩, ⟨⟨a, ha.cases_on $ assume h _, h⟩, by { cases ha, exact ha_h }⟩,
assume ⟨⟨a, ha⟩, h⟩, rfl, assume ⟨a, h₁, h₂⟩, rfl⟩
def subtype_subtype_equiv_subtype_inter {α : Type u} (p q : α → Prop) :
{x : subtype p // q x.1} ≃ subtype (λ x, p x ∧ q x) :=
(subtype_subtype_equiv_subtype_exists p _).trans $
subtype_congr_right $ λ x, exists_prop
/-- If the outer subtype has more restrictive predicate than the inner one,
then we can drop the latter. -/
def subtype_subtype_equiv_subtype {α : Type u} {p q : α → Prop} (h : ∀ {x}, q x → p x) :
{x : subtype p // q x.1} ≃ subtype q :=
(subtype_subtype_equiv_subtype_inter p _).trans $
subtype_congr_right $
assume x,
⟨and.right, λ h₁, ⟨h h₁, h₁⟩⟩
/-- If a proposition holds for all elements, then the subtype is
equivalent to the original type. -/
def subtype_univ_equiv {α : Type u} {p : α → Prop} (h : ∀ x, p x) :
subtype p ≃ α :=
⟨λ x, x, λ x, ⟨x, h x⟩, λ x, subtype.eq rfl, λ x, rfl⟩
/-- A subtype of a sigma-type is a sigma-type over a subtype. -/
def subtype_sigma_equiv {α : Type u} (p : α → Type v) (q : α → Prop) :
{ y : sigma p // q y.1 } ≃ Σ(x : subtype q), p x.1 :=
⟨λ x, ⟨⟨x.1.1, x.2⟩, x.1.2⟩,
λ x, ⟨⟨x.1.1, x.2⟩, x.1.2⟩,
λ ⟨⟨x, h⟩, y⟩, rfl,
λ ⟨⟨x, y⟩, h⟩, rfl⟩
/-- A sigma type over a subtype is equivalent to the sigma set over the original type,
if the fiber is empty outside of the subset -/
def sigma_subtype_equiv_of_subset {α : Type u} (p : α → Type v) (q : α → Prop)
(h : ∀ x, p x → q x) :
(Σ x : subtype q, p x) ≃ Σ x : α, p x :=
(subtype_sigma_equiv p q).symm.trans $ subtype_univ_equiv $ λ x, h x.1 x.2
def sigma_subtype_preimage_equiv {α : Type u} {β : Type v} (f : α → β) (p : β → Prop)
(h : ∀ x, p (f x)) :
(Σ y : subtype p, {x : α // f x = y}) ≃ α :=
calc _ ≃ Σ y : β, {x : α // f x = y} : sigma_subtype_equiv_of_subset _ p (λ y ⟨x, h'⟩, h' ▸ h x)
... ≃ α : sigma_preimage_equiv f
def sigma_subtype_preimage_equiv_subtype {α : Type u} {β : Type v} (f : α → β)
{p : α → Prop} {q : β → Prop} (h : ∀ x, p x ↔ q (f x)) :
(Σ y : subtype q, {x : α // f x = y}) ≃ subtype p :=
calc (Σ y : subtype q, {x : α // f x = y}) ≃
Σ y : subtype q, {x : subtype p // subtype.mk (f x) ((h x).1 x.2) = y} :
begin
apply sigma_congr_right,
assume y,
symmetry,
refine (subtype_subtype_equiv_subtype_exists _ _).trans (subtype_congr_right _),
assume x,
exact ⟨λ ⟨hp, h'⟩, congr_arg subtype.val h', λ h', ⟨(h x).2 (h'.symm ▸ y.2), subtype.eq h'⟩⟩
end
... ≃ subtype p : sigma_preimage_equiv (λ x : subtype p, (⟨f x, (h x).1 x.property⟩ : subtype q))
def pi_equiv_subtype_sigma (ι : Type*) (π : ι → Type*) :
(Πi, π i) ≃ {f : ι → Σi, π i | ∀i, (f i).1 = i } :=
⟨ λf, ⟨λi, ⟨i, f i⟩, assume i, rfl⟩, λf i, begin rw ← f.2 i, exact (f.1 i).2 end,
assume f, funext $ assume i, rfl,
assume ⟨f, hf⟩, subtype.eq $ funext $ assume i, sigma.eq (hf i).symm $
eq_of_heq $ rec_heq_of_heq _ $ rec_heq_of_heq _ $ heq.refl _⟩
def subtype_pi_equiv_pi {α : Sort u} {β : α → Sort v} {p : Πa, β a → Prop} :
{f : Πa, β a // ∀a, p a (f a) } ≃ Πa, { b : β a // p a b } :=
⟨λf a, ⟨f.1 a, f.2 a⟩, λf, ⟨λa, (f a).1, λa, (f a).2⟩,
by { rintro ⟨f, h⟩, refl },
by { rintro f, funext a, exact subtype.eq' rfl }⟩
end
namespace set
open set
protected def univ (α) : @univ α ≃ α :=
⟨subtype.val, λ a, ⟨a, trivial⟩, λ ⟨a, _⟩, rfl, λ a, rfl⟩
@[simp] lemma univ_apply {α : Type u} (x : @univ α) :
equiv.set.univ α x = x := rfl
@[simp] lemma univ_symm_apply {α : Type u} (x : α) :
(equiv.set.univ α).symm x = ⟨x, trivial⟩ := rfl
protected def empty (α) : (∅ : set α) ≃ empty :=
equiv_empty $ λ ⟨x, h⟩, not_mem_empty x h
protected def pempty (α) : (∅ : set α) ≃ pempty :=
equiv_pempty $ λ ⟨x, h⟩, not_mem_empty x h
protected def union' {α} {s t : set α}
(p : α → Prop) [decidable_pred p]
(hs : ∀ x ∈ s, p x)
(ht : ∀ x ∈ t, ¬ p x) : (s ∪ t : set α) ≃ s ⊕ t :=
{ to_fun := λ x, if hp : p x.1
then sum.inl ⟨_, x.2.resolve_right (λ xt, ht _ xt hp)⟩
else sum.inr ⟨_, x.2.resolve_left (λ xs, hp (hs _ xs))⟩,
inv_fun := λ o, match o with
| (sum.inl x) := ⟨x.1, or.inl x.2⟩
| (sum.inr x) := ⟨x.1, or.inr x.2⟩
end,
left_inv := λ ⟨x, h'⟩, by by_cases p x; simp [union'._match_1, h]; congr,
right_inv := λ o, begin
rcases o with ⟨x, h⟩ | ⟨x, h⟩;
dsimp [union'._match_1];
[simp [hs _ h], simp [ht _ h]]
end }
protected def union {α} {s t : set α} [decidable_pred s] (H : s ∩ t = ∅) :
(s ∪ t : set α) ≃ s ⊕ t :=
set.union' s (λ _, id) (λ x xt xs, subset_empty_iff.2 H ⟨xs, xt⟩)
lemma union_apply_left {α} {s t : set α} [decidable_pred s] (H : s ∩ t = ∅)
{a : (s ∪ t : set α)} (ha : ↑a ∈ s) : equiv.set.union H a = sum.inl ⟨a, ha⟩ :=
dif_pos ha
lemma union_apply_right {α} {s t : set α} [decidable_pred s] (H : s ∩ t = ∅)
{a : (s ∪ t : set α)} (ha : ↑a ∈ t) : equiv.set.union H a = sum.inr ⟨a, ha⟩ :=
dif_neg (show ↑a ∉ s, by finish [set.ext_iff])
protected def singleton {α} (a : α) : ({a} : set α) ≃ punit.{u} :=
⟨λ _, punit.star, λ _, ⟨a, mem_singleton _⟩,
λ ⟨x, h⟩, by { simp at h, subst x },
λ ⟨⟩, rfl⟩
protected def of_eq {α : Type u} {s t : set α} (h : s = t) : s ≃ t :=
{ to_fun := λ x, ⟨x.1, h ▸ x.2⟩,
inv_fun := λ x, ⟨x.1, h.symm ▸ x.2⟩,
left_inv := λ _, subtype.eq rfl,
right_inv := λ _, subtype.eq rfl }
@[simp] lemma of_eq_apply {α : Type u} {s t : set α} (h : s = t) (a : s) :
equiv.set.of_eq h a = ⟨a, h ▸ a.2⟩ := rfl
@[simp] lemma of_eq_symm_apply {α : Type u} {s t : set α} (h : s = t) (a : t) :
(equiv.set.of_eq h).symm a = ⟨a, h.symm ▸ a.2⟩ := rfl
protected def insert {α} {s : set.{u} α} [decidable_pred s] {a : α} (H : a ∉ s) :
(insert a s : set α) ≃ s ⊕ punit.{u+1} :=
calc (insert a s : set α) ≃ ↥(s ∪ {a}) : equiv.set.of_eq (by simp)
... ≃ s ⊕ ({a} : set α) : equiv.set.union (by finish [set.ext_iff])
... ≃ s ⊕ punit.{u+1} : sum_congr (equiv.refl _) (equiv.set.singleton _)
protected def sum_compl {α} (s : set α) [decidable_pred s] : s ⊕ (-s : set α) ≃ α :=
calc s ⊕ (-s : set α) ≃ ↥(s ∪ -s) : (equiv.set.union (by simp [set.ext_iff])).symm
... ≃ @univ α : equiv.set.of_eq (by simp)
... ≃ α : equiv.set.univ _
@[simp] lemma sum_compl_apply_inl {α : Type u} (s : set α) [decidable_pred s] (x : s) :
equiv.set.sum_compl s (sum.inl x) = x := rfl
@[simp] lemma sum_compl_apply_inr {α : Type u} (s : set α) [decidable_pred s] (x : -s) :
equiv.set.sum_compl s (sum.inr x) = x := rfl
lemma sum_compl_symm_apply_of_mem {α : Type u} {s : set α} [decidable_pred s] {x : α}
(hx : x ∈ s) : (equiv.set.sum_compl s).symm x = sum.inl ⟨x, hx⟩ :=
have ↑(⟨x, or.inl hx⟩ : (s ∪ -s : set α)) ∈ s, from hx,
by { rw [equiv.set.sum_compl], simpa using set.union_apply_left _ this }
lemma sum_compl_symm_apply_of_not_mem {α : Type u} {s : set α} [decidable_pred s] {x : α}
(hx : x ∉ s) : (equiv.set.sum_compl s).symm x = sum.inr ⟨x, hx⟩ :=
have ↑(⟨x, or.inr hx⟩ : (s ∪ -s : set α)) ∈ -s, from hx,
by { rw [equiv.set.sum_compl], simpa using set.union_apply_right _ this }
protected def union_sum_inter {α : Type u} (s t : set α) [decidable_pred s] :
(s ∪ t : set α) ⊕ (s ∩ t : set α) ≃ s ⊕ t :=
calc (s ∪ t : set α) ⊕ (s ∩ t : set α)
≃ (s ∪ t \ s : set α) ⊕ (s ∩ t : set α) : by rw [union_diff_self]
... ≃ (s ⊕ (t \ s : set α)) ⊕ (s ∩ t : set α) :
sum_congr (set.union (inter_diff_self _ _)) (equiv.refl _)
... ≃ s ⊕ (t \ s : set α) ⊕ (s ∩ t : set α) : sum_assoc _ _ _
... ≃ s ⊕ (t \ s ∪ s ∩ t : set α) : sum_congr (equiv.refl _) begin
refine (set.union' (∉ s) _ _).symm,
exacts [λ x hx, hx.2, λ x hx, not_not_intro hx.1]
end
... ≃ s ⊕ t : by { rw (_ : t \ s ∪ s ∩ t = t), rw [union_comm, inter_comm, inter_union_diff] }
protected def prod {α β} (s : set α) (t : set β) :
s.prod t ≃ s × t :=
⟨λp, ⟨⟨p.1.1, p.2.1⟩, ⟨p.1.2, p.2.2⟩⟩,
λp, ⟨⟨p.1.1, p.2.1⟩, ⟨p.1.2, p.2.2⟩⟩,
λ ⟨⟨x, y⟩, ⟨h₁, h₂⟩⟩, rfl,
λ ⟨⟨x, h₁⟩, ⟨y, h₂⟩⟩, rfl⟩
protected noncomputable def image_of_inj_on {α β} (f : α → β) (s : set α) (H : inj_on f s) :
s ≃ (f '' s) :=
⟨λ ⟨x, h⟩, ⟨f x, mem_image_of_mem f h⟩,
λ ⟨y, h⟩, ⟨classical.some h, (classical.some_spec h).1⟩,
λ ⟨x, h⟩, subtype.eq (H (classical.some_spec (mem_image_of_mem f h)).1 h
(classical.some_spec (mem_image_of_mem f h)).2),
λ ⟨y, h⟩, subtype.eq (classical.some_spec h).2⟩
protected noncomputable def image {α β} (f : α → β) (s : set α) (H : injective f) : s ≃ (f '' s) :=
equiv.set.image_of_inj_on f s (λ x y hx hy hxy, H hxy)
@[simp] theorem image_apply {α β} (f : α → β) (s : set α) (H : injective f) (a h) :
set.image f s H ⟨a, h⟩ = ⟨f a, mem_image_of_mem _ h⟩ := rfl
protected noncomputable def range {α β} (f : α → β) (H : injective f) :
α ≃ range f :=
{ to_fun := λ x, ⟨f x, mem_range_self _⟩,
inv_fun := λ x, classical.some x.2,
left_inv := λ x, H (classical.some_spec (show f x ∈ range f, from mem_range_self _)),
right_inv := λ x, subtype.eq $ classical.some_spec x.2 }
@[simp] theorem range_apply {α β} (f : α → β) (H : injective f) (a) :
set.range f H a = ⟨f a, set.mem_range_self _⟩ := rfl
protected def congr {α β : Type*} (e : α ≃ β) : set α ≃ set β :=
⟨λ s, e '' s, λ t, e.symm '' t, symm_image_image e, symm_image_image e.symm⟩
protected def sep {α : Type u} (s : set α) (t : α → Prop) :
({ x ∈ s | t x } : set α) ≃ { x : s | t x.1 } :=
(equiv.subtype_subtype_equiv_subtype_inter s t).symm
end set
noncomputable def of_bijective {α β} {f : α → β} (hf : bijective f) : α ≃ β :=
⟨f, λ x, classical.some (hf.2 x), λ x, hf.1 (classical.some_spec (hf.2 (f x))),
λ x, classical.some_spec (hf.2 x)⟩
@[simp] theorem of_bijective_to_fun {α β} {f : α → β} (hf : bijective f) : (of_bijective hf : α → β) = f := rfl
def subtype_quotient_equiv_quotient_subtype (p₁ : α → Prop) [s₁ : setoid α]
[s₂ : setoid (subtype p₁)] (p₂ : quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧)
(h : ∀ x y : subtype p₁, @setoid.r _ s₂ x y ↔ (x : α) ≈ y) :
{x // p₂ x} ≃ quotient s₂ :=
{ to_fun := λ a, quotient.hrec_on a.1 (λ a h, ⟦⟨a, (hp₂ _).2 h⟩⟧)
(λ a b hab, hfunext (by rw quotient.sound hab)
(λ h₁ h₂ _, heq_of_eq (quotient.sound ((h _ _).2 hab)))) a.2,
inv_fun := λ a, quotient.lift_on a (λ a, (⟨⟦a.1⟧, (hp₂ _).1 a.2⟩ : {x // p₂ x}))
(λ a b hab, subtype.eq' (quotient.sound ((h _ _).1 hab))),
left_inv := λ ⟨a, ha⟩, quotient.induction_on a (λ a ha, rfl) ha,
right_inv := λ a, quotient.induction_on a (λ ⟨a, ha⟩, rfl) }
section swap
variable [decidable_eq α]
open decidable
def swap_core (a b r : α) : α :=
if r = a then b
else if r = b then a
else r
theorem swap_core_self (r a : α) : swap_core a a r = r :=
by { unfold swap_core, split_ifs; cc }
theorem swap_core_swap_core (r a b : α) : swap_core a b (swap_core a b r) = r :=
by { unfold swap_core, split_ifs; cc }
theorem swap_core_comm (r a b : α) : swap_core a b r = swap_core b a r :=
by { unfold swap_core, split_ifs; cc }
/-- `swap a b` is the permutation that swaps `a` and `b` and
leaves other values as is. -/
def swap (a b : α) : perm α :=
⟨swap_core a b, swap_core a b, λr, swap_core_swap_core r a b, λr, swap_core_swap_core r a b⟩
theorem swap_self (a : α) : swap a a = equiv.refl _ :=
eq_of_to_fun_eq $ funext $ λ r, swap_core_self r a
theorem swap_comm (a b : α) : swap a b = swap b a :=
eq_of_to_fun_eq $ funext $ λ r, swap_core_comm r _ _
theorem swap_apply_def (a b x : α) : swap a b x = if x = a then b else if x = b then a else x :=
rfl
@[simp] theorem swap_apply_left (a b : α) : swap a b a = b :=
if_pos rfl
@[simp] theorem swap_apply_right (a b : α) : swap a b b = a :=
by { by_cases b = a; simp [swap_apply_def, *] }
theorem swap_apply_of_ne_of_ne {a b x : α} : x ≠ a → x ≠ b → swap a b x = x :=
by simp [swap_apply_def] {contextual := tt}
@[simp] theorem swap_swap (a b : α) : (swap a b).trans (swap a b) = equiv.refl _ :=
eq_of_to_fun_eq $ funext $ λ x, swap_core_swap_core _ _ _
theorem swap_comp_apply {a b x : α} (π : perm α) :
π.trans (swap a b) x = if π x = a then b else if π x = b then a else π x :=
by { cases π, refl }
@[simp] lemma swap_inv {α : Type*} [decidable_eq α] (x y : α) :
(swap x y)⁻¹ = swap x y := rfl
@[simp] lemma symm_trans_swap_trans [decidable_eq β] (a b : α)
(e : α ≃ β) : (e.symm.trans (swap a b)).trans e = swap (e a) (e b) :=
equiv.ext _ _ (λ x, begin
have : ∀ a, e.symm x = a ↔ x = e a :=
λ a, by { rw @eq_comm _ (e.symm x), split; intros; simp * at * },
simp [swap_apply_def, this],
split_ifs; simp
end)
@[simp] lemma swap_mul_self {α : Type*} [decidable_eq α] (i j : α) : swap i j * swap i j = 1 :=
equiv.swap_swap i j
@[simp] lemma swap_apply_self {α : Type*} [decidable_eq α] (i j a : α) : swap i j (swap i j a) = a :=
by rw [← perm.mul_apply, swap_mul_self, perm.one_apply]
/-- Augment an equivalence with a prescribed mapping `f a = b` -/
def set_value (f : α ≃ β) (a : α) (b : β) : α ≃ β :=
(swap a (f.symm b)).trans f
@[simp] theorem set_value_eq (f : α ≃ β) (a : α) (b : β) : set_value f a b a = b :=
by { dsimp [set_value], simp [swap_apply_left] }
end swap
protected lemma forall_congr {p : α → Prop} {q : β → Prop} (f : α ≃ β)
(h : ∀{x}, p x ↔ q (f x)) : (∀x, p x) ↔ (∀y, q y) :=
begin
split; intros h₂ x,
{ rw [←f.right_inv x], apply h.mp, apply h₂ },
apply h.mpr, apply h₂
end
end equiv
instance {α} [subsingleton α] : subsingleton (ulift α) := equiv.ulift.subsingleton
instance {α} [subsingleton α] : subsingleton (plift α) := equiv.plift.subsingleton
instance {α} [decidable_eq α] : decidable_eq (ulift α) := equiv.ulift.decidable_eq
instance {α} [decidable_eq α] : decidable_eq (plift α) := equiv.plift.decidable_eq
def unique_unique_equiv : unique (unique α) ≃ unique α :=
{ to_fun := λ h, h.default,
inv_fun := λ h, { default := h, uniq := λ _, subsingleton.elim _ _ },
left_inv := λ _, subsingleton.elim _ _,
right_inv := λ _, subsingleton.elim _ _ }
def equiv_of_unique_of_unique [unique α] [unique β] : α ≃ β :=
{ to_fun := λ _, default β,
inv_fun := λ _, default α,
left_inv := λ _, subsingleton.elim _ _,
right_inv := λ _, subsingleton.elim _ _ }
def equiv_punit_of_unique [unique α] : α ≃ punit.{v} :=
equiv_of_unique_of_unique
namespace quot
/-- An equivalence `e : α ≃ β` generates an equivalence between quotient spaces,
if `ra a₁ a₂ ↔ rb (e a₁) (e a₂). -/
protected def congr {ra : α → α → Prop} {rb : β → β → Prop} (e : α ≃ β)
(eq : ∀a₁ a₂, ra a₁ a₂ ↔ rb (e a₁) (e a₂)) :
quot ra ≃ quot rb :=
{ to_fun := quot.map e (assume a₁ a₂, (eq a₁ a₂).1),
inv_fun := quot.map e.symm
(assume b₁ b₂ h,
(eq (e.symm b₁) (e.symm b₂)).2
((e.apply_symm_apply b₁).symm ▸ (e.apply_symm_apply b₂).symm ▸ h)),
left_inv := by { rintros ⟨a⟩, dunfold quot.map, simp only [equiv.symm_apply_apply] },
right_inv := by { rintros ⟨a⟩, dunfold quot.map, simp only [equiv.apply_symm_apply] } }
/-- Quotients are congruent on equivalences under equality of their relation.
An alternative is just to use rewriting with `eq`, but then computational proofs get stuck. -/
protected def congr_right {r r' : α → α → Prop} (eq : ∀a₁ a₂, r a₁ a₂ ↔ r' a₁ a₂) :
quot r ≃ quot r' :=
quot.congr (equiv.refl α) eq
/-- An equivalence `e : α ≃ β` generates an equivalence between the quotient space of `α`
by a relation `ra` and the quotient space of `β` by the image of this relation under `e`. -/
protected def congr_left {r : α → α → Prop} (e : α ≃ β) :
quot r ≃ quot (λ b b', r (e.symm b) (e.symm b')) :=
@quot.congr α β r (λ b b', r (e.symm b) (e.symm b')) e (λ a₁ a₂, by simp only [e.symm_apply_apply])
end quot
namespace quotient
/-- An equivalence `e : α ≃ β` generates an equivalence between quotient spaces,
if `ra a₁ a₂ ↔ rb (e a₁) (e a₂). -/
protected def congr {ra : setoid α} {rb : setoid β} (e : α ≃ β)
(eq : ∀a₁ a₂, @setoid.r α ra a₁ a₂ ↔ @setoid.r β rb (e a₁) (e a₂)) :
quotient ra ≃ quotient rb :=
quot.congr e eq
/-- Quotients are congruent on equivalences under equality of their relation.
An alternative is just to use rewriting with `eq`, but then computational proofs get stuck. -/
protected def congr_right {r r' : setoid α}
(eq : ∀a₁ a₂, @setoid.r α r a₁ a₂ ↔ @setoid.r α r' a₁ a₂) : quotient r ≃ quotient r' :=
quot.congr_right eq
end quotient
|
01e29d7f5ef5a178088d8cef8c11e57283b917f6 | 367134ba5a65885e863bdc4507601606690974c1 | /src/ring_theory/polynomial/gauss_lemma.lean | 9c0f1c39966b50c402c8b0e23496339d2045e508 | [
"Apache-2.0"
] | permissive | kodyvajjha/mathlib | 9bead00e90f68269a313f45f5561766cfd8d5cad | b98af5dd79e13a38d84438b850a2e8858ec21284 | refs/heads/master | 1,624,350,366,310 | 1,615,563,062,000 | 1,615,563,062,000 | 162,666,963 | 0 | 0 | Apache-2.0 | 1,545,367,651,000 | 1,545,367,651,000 | null | UTF-8 | Lean | false | false | 7,633 | lean | /-
Copyright (c) 2020 Aaron Anderson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Aaron Anderson
-/
import ring_theory.int.basic
import ring_theory.localization
/-!
# Gauss's Lemma
Gauss's Lemma is one of a few results pertaining to irreducibility of primitive polynomials.
## Main Results
- `polynomial.is_primitive.irreducible_iff_irreducible_map_fraction_map`:
A primitive polynomial is irreducible iff it is irreducible in a fraction field.
- `polynomial.is_primitive.int.irreducible_iff_irreducible_map_cast`:
A primitive polynomial over `ℤ` is irreducible iff it is irreducible over `ℚ`.
- `polynomial.is_primitive.dvd_iff_fraction_map_dvd_fraction_map`:
Two primitive polynomials divide each other iff they do in a fraction field.
- `polynomial.is_primitive.int.dvd_iff_map_cast_dvd_map_cast`:
Two primitive polynomials over `ℤ` divide each other if they do in `ℚ`.
-/
variables {R : Type*} [integral_domain R]
namespace polynomial
section gcd_monoid
variable [gcd_monoid R]
section
variables {S : Type*} [integral_domain S] {φ : R →+* S} (hinj : function.injective φ)
variables {f : polynomial R} (hf : f.is_primitive)
include hinj hf
lemma is_primitive.is_unit_iff_is_unit_map_of_injective :
is_unit f ↔ is_unit (map φ f) :=
begin
refine ⟨(ring_hom.of (map φ)).is_unit_map, λ h, _⟩,
rcases is_unit_iff.1 h with ⟨_, ⟨u, rfl⟩, hu⟩,
have hdeg := degree_C u.ne_zero,
rw [hu, degree_map' hinj] at hdeg,
rw [eq_C_of_degree_eq_zero hdeg, is_primitive, content_C, normalize_eq_one] at hf,
rwa [eq_C_of_degree_eq_zero hdeg, is_unit_C],
end
lemma is_primitive.irreducible_of_irreducible_map_of_injective (h_irr : irreducible (map φ f)) :
irreducible f :=
begin
refine ⟨λ h, h_irr.not_unit (is_unit.map (monoid_hom.of (map φ)) h), _⟩,
intros a b h,
rcases h_irr.is_unit_or_is_unit (by rw [h, map_mul]) with hu | hu,
{ left,
rwa (hf.is_primitive_of_dvd (dvd.intro _ h.symm)).is_unit_iff_is_unit_map_of_injective hinj },
right,
rwa (hf.is_primitive_of_dvd (dvd.intro_left _ h.symm)).is_unit_iff_is_unit_map_of_injective hinj
end
end
section fraction_map
variables {K : Type*} [field K] (f : fraction_map R K)
lemma is_primitive.is_unit_iff_is_unit_map {p : polynomial R} (hp : p.is_primitive) :
is_unit p ↔ is_unit (p.map f.to_map) :=
hp.is_unit_iff_is_unit_map_of_injective f.injective
open localization_map
lemma is_unit_or_eq_zero_of_is_unit_integer_normalization_prim_part
{p : polynomial K} (h0 : p ≠ 0) (h : is_unit (f.integer_normalization p).prim_part) :
is_unit p :=
begin
rcases is_unit_iff.1 h with ⟨_, ⟨u, rfl⟩, hu⟩,
obtain ⟨⟨c, c0⟩, hc⟩ := @integer_normalization_map_to_map _ _ _ _ _ f p,
rw [algebra.smul_def, ← C_eq_algebra_map, subtype.coe_mk] at hc,
apply is_unit_of_mul_is_unit_right,
rw [← hc, (f.integer_normalization p).eq_C_content_mul_prim_part, ← hu,
← ring_hom.map_mul, is_unit_iff],
refine ⟨f.to_map ((f.integer_normalization p).content * ↑u),
is_unit_iff_ne_zero.2 (λ con, _), by simp⟩,
replace con := (ring_hom.injective_iff f.to_map).1 f.injective _ con,
rw [mul_eq_zero, content_eq_zero_iff, fraction_map.integer_normalization_eq_zero_iff] at con,
rcases con with con | con,
{ apply h0 con },
{ apply units.ne_zero _ con },
end
/-- Gauss's Lemma states that a primitive polynomial is irreducible iff it is irreducible in the
fraction field. -/
theorem is_primitive.irreducible_iff_irreducible_map_fraction_map
{p : polynomial R} (hp : p.is_primitive) :
irreducible p ↔ irreducible (p.map f.to_map) :=
begin
refine ⟨λ hi, ⟨λ h, hi.not_unit ((hp.is_unit_iff_is_unit_map f).2 h), λ a b hab, _⟩,
hp.irreducible_of_irreducible_map_of_injective f.injective⟩,
obtain ⟨⟨c, c0⟩, hc⟩ := @integer_normalization_map_to_map _ _ _ _ _ f a,
obtain ⟨⟨d, d0⟩, hd⟩ := @integer_normalization_map_to_map _ _ _ _ _ f b,
rw [algebra.smul_def, ← C_eq_algebra_map, subtype.coe_mk] at hc hd,
rw mem_non_zero_divisors_iff_ne_zero at c0 d0,
have hcd0 : c * d ≠ 0 := mul_ne_zero c0 d0,
rw [ne.def, ← C_eq_zero] at hcd0,
have h1 : C c * C d * p = f.integer_normalization a * f.integer_normalization b,
{ apply (map_injective _ f.injective _),
rw [map_mul, map_mul, map_mul, hc, hd, map_C, map_C, hab],
ring },
obtain ⟨u, hu⟩ : associated (c * d) (content (f.integer_normalization a) *
content (f.integer_normalization b)),
{ rw [← dvd_dvd_iff_associated, ← normalize_eq_normalize_iff, normalize.map_mul,
normalize.map_mul, normalize_content, normalize_content,
← mul_one (normalize c * normalize d), ← hp.content_eq_one, ← content_C, ← content_C,
← content_mul, ← content_mul, ← content_mul, h1] },
rw [← ring_hom.map_mul, eq_comm,
(f.integer_normalization a).eq_C_content_mul_prim_part,
(f.integer_normalization b).eq_C_content_mul_prim_part, mul_assoc,
mul_comm _ (C _ * _), ← mul_assoc, ← mul_assoc, ← ring_hom.map_mul, ← hu, ring_hom.map_mul,
mul_assoc, mul_assoc, ← mul_assoc (C ↑u)] at h1,
have h0 : (a ≠ 0) ∧ (b ≠ 0),
{ classical,
rw [ne.def, ne.def, ← decidable.not_or_iff_and_not, ← mul_eq_zero, ← hab],
intro con,
apply hp.ne_zero (map_injective _ f.injective _),
simp [con] },
rcases hi.is_unit_or_is_unit (mul_left_cancel' hcd0 h1).symm with h | h,
{ right,
apply is_unit_or_eq_zero_of_is_unit_integer_normalization_prim_part f h0.2
(is_unit_of_mul_is_unit_right h) },
{ left,
apply is_unit_or_eq_zero_of_is_unit_integer_normalization_prim_part f h0.1 h },
end
lemma is_primitive.dvd_of_fraction_map_dvd_fraction_map {p q : polynomial R}
(hp : p.is_primitive) (hq : q.is_primitive) (h_dvd : p.map f.to_map ∣ q.map f.to_map) :
(p ∣ q) :=
begin
rcases h_dvd with ⟨r, hr⟩,
obtain ⟨⟨s, s0⟩, hs⟩ := @integer_normalization_map_to_map _ _ _ _ _ f r,
rw [algebra.smul_def, ← C_eq_algebra_map, subtype.coe_mk] at hs,
have h : p ∣ q * C s,
{ use (f.integer_normalization r),
apply map_injective _ f.injective,
rw [map_mul, map_mul, hs, hr, mul_assoc, mul_comm r],
simp },
rw [← hp.dvd_prim_part_iff_dvd, prim_part_mul, hq.prim_part_eq, dvd_iff_dvd_of_rel_right] at h,
{ exact h },
{ symmetry,
rcases is_unit_prim_part_C s with ⟨u, hu⟩,
use u,
simp [hu], },
iterate 2 { apply mul_ne_zero hq.ne_zero,
rw [ne.def, C_eq_zero],
contrapose! s0,
simp [s0, mem_non_zero_divisors_iff_ne_zero] }
end
lemma is_primitive.dvd_iff_fraction_map_dvd_fraction_map {p q : polynomial R}
(hp : p.is_primitive) (hq : q.is_primitive) :
(p ∣ q) ↔ (p.map f.to_map ∣ q.map f.to_map) :=
⟨λ ⟨a,b⟩, ⟨a.map f.to_map, b.symm ▸ (map_mul f.to_map)⟩,
λ h, hp.dvd_of_fraction_map_dvd_fraction_map f hq h⟩
end fraction_map
/-- Gauss's Lemma for `ℤ` states that a primitive integer polynomial is irreducible iff it is
irreducible over `ℚ`. -/
theorem is_primitive.int.irreducible_iff_irreducible_map_cast
{p : polynomial ℤ} (hp : p.is_primitive) :
irreducible p ↔ irreducible (p.map (int.cast_ring_hom ℚ)) :=
hp.irreducible_iff_irreducible_map_fraction_map fraction_map.int.fraction_map
lemma is_primitive.int.dvd_iff_map_cast_dvd_map_cast (p q : polynomial ℤ)
(hp : p.is_primitive) (hq : q.is_primitive) :
(p ∣ q) ↔ (p.map (int.cast_ring_hom ℚ) ∣ q.map (int.cast_ring_hom ℚ)) :=
hp.dvd_iff_fraction_map_dvd_fraction_map fraction_map.int.fraction_map hq
end gcd_monoid
end polynomial
|
c3632309ecf4bd9120a23e0918b1b56748cb9e54 | 737dc4b96c97368cb66b925eeea3ab633ec3d702 | /stage0/src/Lean/Meta/Basic.lean | e0328612df4a9aa072e4b081979215b10171376d | [
"Apache-2.0"
] | permissive | Bioye97/lean4 | 1ace34638efd9913dc5991443777b01a08983289 | bc3900cbb9adda83eed7e6affeaade7cfd07716d | refs/heads/master | 1,690,589,820,211 | 1,631,051,000,000 | 1,631,067,598,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 49,147 | lean | /-
Copyright (c) 2019 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
import Lean.Data.LOption
import Lean.Environment
import Lean.Class
import Lean.ReducibilityAttrs
import Lean.Util.Trace
import Lean.Util.RecDepth
import Lean.Util.PPExt
import Lean.Util.OccursCheck
import Lean.Util.MonadBacktrack
import Lean.Compiler.InlineAttrs
import Lean.Meta.TransparencyMode
import Lean.Meta.DiscrTreeTypes
import Lean.Eval
import Lean.CoreM
/-
This module provides four (mutually dependent) goodies that are needed for building the elaborator and tactic frameworks.
1- Weak head normal form computation with support for metavariables and transparency modes.
2- Definitionally equality checking with support for metavariables (aka unification modulo definitional equality).
3- Type inference.
4- Type class resolution.
They are packed into the MetaM monad.
-/
namespace Lean.Meta
builtin_initialize isDefEqStuckExceptionId : InternalExceptionId ← registerInternalExceptionId `isDefEqStuck
structure Config where
foApprox : Bool := false
ctxApprox : Bool := false
quasiPatternApprox : Bool := false
/- When `constApprox` is set to true,
we solve `?m t =?= c` using
`?m := fun _ => c`
when `?m t` is not a higher-order pattern and `c` is not an application as -/
constApprox : Bool := false
/-
When the following flag is set,
`isDefEq` throws the exeption `Exeption.isDefEqStuck`
whenever it encounters a constraint `?m ... =?= t` where
`?m` is read only.
This feature is useful for type class resolution where
we may want to notify the caller that the TC problem may be solveable
later after it assigns `?m`. -/
isDefEqStuckEx : Bool := false
transparency : TransparencyMode := TransparencyMode.default
/- If zetaNonDep == false, then non dependent let-decls are not zeta expanded. -/
zetaNonDep : Bool := true
/- When `trackZeta == true`, we store zetaFVarIds all free variables that have been zeta-expanded. -/
trackZeta : Bool := false
unificationHints : Bool := true
/- Enables proof irrelevance at `isDefEq` -/
proofIrrelevance : Bool := true
/- By default synthetic opaque metavariables are not assigned by `isDefEq`. Motivation: we want to make
sure typing constraints resolved during elaboration should not "fill" holes that are supposed to be filled using tactics.
However, this restriction is too restrictive for tactics such as `exact t`. When elaborating `t`, we dot not fill
named holes when solving typing constraints or TC resolution. But, we ignore the restriction when we try to unify
the type of `t` with the goal target type. We claim this is not a hack and is defensible behavior because
this last unification step is not really part of the term elaboration. -/
assignSyntheticOpaque : Bool := false
/- When `ignoreLevelDepth` is `false`, only universe level metavariables with depth == metavariable context depth
can be assigned.
We used to have `ignoreLevelDepth == false` always, but this setting produced counterintuitive behavior in a few
cases. Recall that universe levels are often ignored by users, they may not even be aware they exist.
We still use this restriction for regular metavariables. See discussion at the beginning of `MetavarContext.lean`.
We claim it is reasonable to ignore this restriction for universe metavariables because their values are often
contrained by the terms is instances and simp theorems.
TODO: we should delete this configuration option and the method `isReadOnlyLevelMVar` after we have more tests.
-/
ignoreLevelMVarDepth : Bool := true
structure ParamInfo where
binderInfo : BinderInfo := BinderInfo.default
hasFwdDeps : Bool := false
backDeps : Array Nat := #[]
deriving Inhabited
def ParamInfo.isImplicit (p : ParamInfo) : Bool :=
p.binderInfo == BinderInfo.implicit
def ParamInfo.isInstImplicit (p : ParamInfo) : Bool :=
p.binderInfo == BinderInfo.instImplicit
def ParamInfo.isStrictImplicit (p : ParamInfo) : Bool :=
p.binderInfo == BinderInfo.strictImplicit
def ParamInfo.isExplicit (p : ParamInfo) : Bool :=
p.binderInfo == BinderInfo.default || p.binderInfo == BinderInfo.auxDecl
structure FunInfo where
paramInfo : Array ParamInfo := #[]
resultDeps : Array Nat := #[]
structure InfoCacheKey where
transparency : TransparencyMode
expr : Expr
nargs? : Option Nat
deriving Inhabited, BEq
namespace InfoCacheKey
instance : Hashable InfoCacheKey :=
⟨fun ⟨transparency, expr, nargs⟩ => mixHash (hash transparency) <| mixHash (hash expr) (hash nargs)⟩
end InfoCacheKey
open Std (PersistentArray PersistentHashMap)
abbrev SynthInstanceCache := PersistentHashMap Expr (Option Expr)
abbrev InferTypeCache := PersistentExprStructMap Expr
abbrev FunInfoCache := PersistentHashMap InfoCacheKey FunInfo
abbrev WhnfCache := PersistentExprStructMap Expr
/- A set of pairs. TODO: consider more efficient representations (e.g., a proper set) and caching policies (e.g., imperfect cache).
We should also investigate the impact on memory consumption. -/
abbrev DefEqCache := PersistentHashMap (Expr × Expr) Unit
structure Cache where
inferType : InferTypeCache := {}
funInfo : FunInfoCache := {}
synthInstance : SynthInstanceCache := {}
whnfDefault : WhnfCache := {} -- cache for closed terms and `TransparencyMode.default`
whnfAll : WhnfCache := {} -- cache for closed terms and `TransparencyMode.all`
defEqDefault : DefEqCache := {}
defEqAll : DefEqCache := {}
deriving Inhabited
/--
"Context" for a postponed universe constraint.
`lhs` and `rhs` are the surrounding `isDefEq` call when the postponed constraint was created.
-/
structure DefEqContext where
lhs : Expr
rhs : Expr
lctx : LocalContext
localInstances : LocalInstances
/--
Auxiliary structure for representing postponed universe constraints.
Remark: the fields `ref` and `rootDefEq?` are used for error message generation only.
Remark: we may consider improving the error message generation in the future.
-/
structure PostponedEntry where
ref : Syntax -- We save the `ref` at entry creation time
lhs : Level
rhs : Level
ctx? : Option DefEqContext -- Context for the surrounding `isDefEq` call when entry was created
deriving Inhabited
structure State where
mctx : MetavarContext := {}
cache : Cache := {}
/- When `trackZeta == true`, then any let-decl free variable that is zeta expansion performed by `MetaM` is stored in `zetaFVarIds`. -/
zetaFVarIds : NameSet := {}
postponed : PersistentArray PostponedEntry := {}
deriving Inhabited
structure SavedState where
core : Core.State
meta : State
deriving Inhabited
structure Context where
config : Config := {}
lctx : LocalContext := {}
localInstances : LocalInstances := #[]
/-- Not `none` when inside of an `isDefEq` test. See `PostponedEntry`. -/
defEqCtx? : Option DefEqContext := none
/--
Track the number of nested `synthPending` invocations. Nested invocations can happen
when the type class resolution invokes `synthPending`.
Remark: in the current implementation, `synthPending` fails if `synthPendingDepth > 0`.
We will add a configuration option if necessary. -/
synthPendingDepth : Nat := 0
abbrev MetaM := ReaderT Context $ StateRefT State CoreM
-- Make the compiler generate specialized `pure`/`bind` so we do not have to optimize through the
-- whole monad stack at every use site. May eventually be covered by `deriving`.
instance : Monad MetaM := let i := inferInstanceAs (Monad MetaM); { pure := i.pure, bind := i.bind }
instance : Inhabited (MetaM α) where
default := fun _ _ => arbitrary
instance : MonadLCtx MetaM where
getLCtx := return (← read).lctx
instance : MonadMCtx MetaM where
getMCtx := return (← get).mctx
modifyMCtx f := modify fun s => { s with mctx := f s.mctx }
instance : AddMessageContext MetaM where
addMessageContext := addMessageContextFull
protected def saveState : MetaM SavedState :=
return { core := (← getThe Core.State), meta := (← get) }
/-- Restore backtrackable parts of the state. -/
def SavedState.restore (b : SavedState) : MetaM Unit := do
Core.restore b.core
modify fun s => { s with mctx := b.meta.mctx, zetaFVarIds := b.meta.zetaFVarIds, postponed := b.meta.postponed }
instance : MonadBacktrack SavedState MetaM where
saveState := Meta.saveState
restoreState s := s.restore
@[inline] def MetaM.run (x : MetaM α) (ctx : Context := {}) (s : State := {}) : CoreM (α × State) :=
x ctx |>.run s
@[inline] def MetaM.run' (x : MetaM α) (ctx : Context := {}) (s : State := {}) : CoreM α :=
Prod.fst <$> x.run ctx s
@[inline] def MetaM.toIO (x : MetaM α) (ctxCore : Core.Context) (sCore : Core.State) (ctx : Context := {}) (s : State := {}) : IO (α × Core.State × State) := do
let ((a, s), sCore) ← (x.run ctx s).toIO ctxCore sCore
pure (a, sCore, s)
instance [MetaEval α] : MetaEval (MetaM α) :=
⟨fun env opts x _ => MetaEval.eval env opts x.run' true⟩
protected def throwIsDefEqStuck : MetaM α :=
throw <| Exception.internal isDefEqStuckExceptionId
builtin_initialize
registerTraceClass `Meta
registerTraceClass `Meta.debug
@[inline] def liftMetaM [MonadLiftT MetaM m] (x : MetaM α) : m α :=
liftM x
@[inline] def mapMetaM [MonadControlT MetaM m] [Monad m] (f : forall {α}, MetaM α → MetaM α) {α} (x : m α) : m α :=
controlAt MetaM fun runInBase => f <| runInBase x
@[inline] def map1MetaM [MonadControlT MetaM m] [Monad m] (f : forall {α}, (β → MetaM α) → MetaM α) {α} (k : β → m α) : m α :=
controlAt MetaM fun runInBase => f fun b => runInBase <| k b
@[inline] def map2MetaM [MonadControlT MetaM m] [Monad m] (f : forall {α}, (β → γ → MetaM α) → MetaM α) {α} (k : β → γ → m α) : m α :=
controlAt MetaM fun runInBase => f fun b c => runInBase <| k b c
section Methods
variable [MonadControlT MetaM n] [Monad n]
@[inline] def modifyCache (f : Cache → Cache) : MetaM Unit :=
modify fun ⟨mctx, cache, zetaFVarIds, postponed⟩ => ⟨mctx, f cache, zetaFVarIds, postponed⟩
@[inline] def modifyInferTypeCache (f : InferTypeCache → InferTypeCache) : MetaM Unit :=
modifyCache fun ⟨ic, c1, c2, c3, c4, c5, c6⟩ => ⟨f ic, c1, c2, c3, c4, c5, c6⟩
def getLocalInstances : MetaM LocalInstances :=
return (← read).localInstances
def getConfig : MetaM Config :=
return (← read).config
def setMCtx (mctx : MetavarContext) : MetaM Unit :=
modify fun s => { s with mctx := mctx }
def resetZetaFVarIds : MetaM Unit :=
modify fun s => { s with zetaFVarIds := {} }
def getZetaFVarIds : MetaM NameSet :=
return (← get).zetaFVarIds
def getPostponed : MetaM (PersistentArray PostponedEntry) :=
return (← get).postponed
def setPostponed (postponed : PersistentArray PostponedEntry) : MetaM Unit :=
modify fun s => { s with postponed := postponed }
@[inline] def modifyPostponed (f : PersistentArray PostponedEntry → PersistentArray PostponedEntry) : MetaM Unit :=
modify fun s => { s with postponed := f s.postponed }
/- WARNING: The following 4 constants are a hack for simulating forward declarations.
They are defined later using the `export` attribute. This is hackish because we
have to hard-code the true arity of these definitions here, and make sure the C names match.
We have used another hack based on `IO.Ref`s in the past, it was safer but less efficient. -/
@[extern 6 "lean_whnf"] constant whnf : Expr → MetaM Expr
@[extern 6 "lean_infer_type"] constant inferType : Expr → MetaM Expr
@[extern 7 "lean_is_expr_def_eq"] constant isExprDefEqAux : Expr → Expr → MetaM Bool
@[extern 6 "lean_synth_pending"] protected constant synthPending : MVarId → MetaM Bool
def whnfForall (e : Expr) : MetaM Expr := do
let e' ← whnf e
if e'.isForall then pure e' else pure e
-- withIncRecDepth for a monad `n` such that `[MonadControlT MetaM n]`
protected def withIncRecDepth (x : n α) : n α :=
mapMetaM (withIncRecDepth (m := MetaM)) x
private def mkFreshExprMVarAtCore
(mvarId : MVarId) (lctx : LocalContext) (localInsts : LocalInstances) (type : Expr) (kind : MetavarKind) (userName : Name) (numScopeArgs : Nat) : MetaM Expr := do
modifyMCtx fun mctx => mctx.addExprMVarDecl mvarId userName lctx localInsts type kind numScopeArgs;
return mkMVar mvarId
def mkFreshExprMVarAt
(lctx : LocalContext) (localInsts : LocalInstances) (type : Expr)
(kind : MetavarKind := MetavarKind.natural) (userName : Name := Name.anonymous) (numScopeArgs : Nat := 0)
: MetaM Expr := do
mkFreshExprMVarAtCore (← mkFreshId) lctx localInsts type kind userName numScopeArgs
def mkFreshLevelMVar : MetaM Level := do
let mvarId ← mkFreshId
modifyMCtx fun mctx => mctx.addLevelMVarDecl mvarId;
return mkLevelMVar mvarId
private def mkFreshExprMVarCore (type : Expr) (kind : MetavarKind) (userName : Name) : MetaM Expr := do
mkFreshExprMVarAt (← getLCtx) (← getLocalInstances) type kind userName
private def mkFreshExprMVarImpl (type? : Option Expr) (kind : MetavarKind) (userName : Name) : MetaM Expr :=
match type? with
| some type => mkFreshExprMVarCore type kind userName
| none => do
let u ← mkFreshLevelMVar
let type ← mkFreshExprMVarCore (mkSort u) MetavarKind.natural Name.anonymous
mkFreshExprMVarCore type kind userName
def mkFreshExprMVar (type? : Option Expr) (kind := MetavarKind.natural) (userName := Name.anonymous) : MetaM Expr :=
mkFreshExprMVarImpl type? kind userName
def mkFreshTypeMVar (kind := MetavarKind.natural) (userName := Name.anonymous) : MetaM Expr := do
let u ← mkFreshLevelMVar
mkFreshExprMVar (mkSort u) kind userName
/- Low-level version of `MkFreshExprMVar` which allows users to create/reserve a `mvarId` using `mkFreshId`, and then later create
the metavar using this method. -/
private def mkFreshExprMVarWithIdCore (mvarId : MVarId) (type : Expr)
(kind : MetavarKind := MetavarKind.natural) (userName : Name := Name.anonymous) (numScopeArgs : Nat := 0)
: MetaM Expr := do
mkFreshExprMVarAtCore mvarId (← getLCtx) (← getLocalInstances) type kind userName numScopeArgs
def mkFreshExprMVarWithId (mvarId : MVarId) (type? : Option Expr := none) (kind : MetavarKind := MetavarKind.natural) (userName := Name.anonymous) : MetaM Expr :=
match type? with
| some type => mkFreshExprMVarWithIdCore mvarId type kind userName
| none => do
let u ← mkFreshLevelMVar
let type ← mkFreshExprMVar (mkSort u)
mkFreshExprMVarWithIdCore mvarId type kind userName
def mkFreshLevelMVars (num : Nat) : MetaM (List Level) :=
num.foldM (init := []) fun _ us =>
return (← mkFreshLevelMVar)::us
def mkFreshLevelMVarsFor (info : ConstantInfo) : MetaM (List Level) :=
mkFreshLevelMVars info.numLevelParams
def mkConstWithFreshMVarLevels (declName : Name) : MetaM Expr := do
let info ← getConstInfo declName
return mkConst declName (← mkFreshLevelMVarsFor info)
def getTransparency : MetaM TransparencyMode :=
return (← getConfig).transparency
def shouldReduceAll : MetaM Bool :=
return (← getTransparency) == TransparencyMode.all
def shouldReduceReducibleOnly : MetaM Bool :=
return (← getTransparency) == TransparencyMode.reducible
def getMVarDecl (mvarId : MVarId) : MetaM MetavarDecl := do
match (← getMCtx).findDecl? mvarId with
| some d => pure d
| none => throwError "unknown metavariable '?{mvarId}'"
def setMVarKind (mvarId : MVarId) (kind : MetavarKind) : MetaM Unit :=
modifyMCtx fun mctx => mctx.setMVarKind mvarId kind
/- Update the type of the given metavariable. This function assumes the new type is
definitionally equal to the current one -/
def setMVarType (mvarId : MVarId) (type : Expr) : MetaM Unit := do
modifyMCtx fun mctx => mctx.setMVarType mvarId type
def isReadOnlyExprMVar (mvarId : MVarId) : MetaM Bool := do
return (← getMVarDecl mvarId).depth != (← getMCtx).depth
def isReadOnlyOrSyntheticOpaqueExprMVar (mvarId : MVarId) : MetaM Bool := do
let mvarDecl ← getMVarDecl mvarId
match mvarDecl.kind with
| MetavarKind.syntheticOpaque => return !(← getConfig).assignSyntheticOpaque
| _ => return mvarDecl.depth != (← getMCtx).depth
def getLevelMVarDepth (mvarId : MVarId) : MetaM Nat := do
match (← getMCtx).findLevelDepth? mvarId with
| some depth => return depth
| _ => throwError "unknown universe metavariable '?{mvarId}'"
def isReadOnlyLevelMVar (mvarId : MVarId) : MetaM Bool := do
if (← getConfig).ignoreLevelMVarDepth then
return false
else
return (← getLevelMVarDepth mvarId) != (← getMCtx).depth
def renameMVar (mvarId : MVarId) (newUserName : Name) : MetaM Unit :=
modifyMCtx fun mctx => mctx.renameMVar mvarId newUserName
def isExprMVarAssigned (mvarId : MVarId) : MetaM Bool :=
return (← getMCtx).isExprAssigned mvarId
def getExprMVarAssignment? (mvarId : MVarId) : MetaM (Option Expr) :=
return (← getMCtx).getExprAssignment? mvarId
/-- Return true if `e` contains `mvarId` directly or indirectly -/
def occursCheck (mvarId : MVarId) (e : Expr) : MetaM Bool :=
return (← getMCtx).occursCheck mvarId e
def assignExprMVar (mvarId : MVarId) (val : Expr) : MetaM Unit :=
modifyMCtx fun mctx => mctx.assignExpr mvarId val
def isDelayedAssigned (mvarId : MVarId) : MetaM Bool :=
return (← getMCtx).isDelayedAssigned mvarId
def getDelayedAssignment? (mvarId : MVarId) : MetaM (Option DelayedMetavarAssignment) :=
return (← getMCtx).getDelayedAssignment? mvarId
def hasAssignableMVar (e : Expr) : MetaM Bool :=
return (← getMCtx).hasAssignableMVar e
def throwUnknownFVar (fvarId : FVarId) : MetaM α :=
throwError "unknown free variable '{mkFVar fvarId}'"
def findLocalDecl? (fvarId : FVarId) : MetaM (Option LocalDecl) :=
return (← getLCtx).find? fvarId
def getLocalDecl (fvarId : FVarId) : MetaM LocalDecl := do
match (← getLCtx).find? fvarId with
| some d => pure d
| none => throwUnknownFVar fvarId
def getFVarLocalDecl (fvar : Expr) : MetaM LocalDecl :=
getLocalDecl fvar.fvarId!
def getLocalDeclFromUserName (userName : Name) : MetaM LocalDecl := do
match (← getLCtx).findFromUserName? userName with
| some d => pure d
| none => throwError "unknown local declaration '{userName}'"
def instantiateLevelMVars (u : Level) : MetaM Level :=
MetavarContext.instantiateLevelMVars u
def instantiateMVars (e : Expr) : MetaM Expr :=
(MetavarContext.instantiateExprMVars e).run
def instantiateLocalDeclMVars (localDecl : LocalDecl) : MetaM LocalDecl :=
match localDecl with
| LocalDecl.cdecl idx id n type bi =>
return LocalDecl.cdecl idx id n (← instantiateMVars type) bi
| LocalDecl.ldecl idx id n type val nonDep =>
return LocalDecl.ldecl idx id n (← instantiateMVars type) (← instantiateMVars val) nonDep
@[inline] def liftMkBindingM (x : MetavarContext.MkBindingM α) : MetaM α := do
match x (← getLCtx) { mctx := (← getMCtx), ngen := (← getNGen) } with
| EStateM.Result.ok e newS => do
setNGen newS.ngen;
setMCtx newS.mctx;
pure e
| EStateM.Result.error (MetavarContext.MkBinding.Exception.revertFailure mctx lctx toRevert decl) newS => do
setMCtx newS.mctx;
setNGen newS.ngen;
throwError "failed to create binder due to failure when reverting variable dependencies"
def abstractRange (e : Expr) (n : Nat) (xs : Array Expr) : MetaM Expr :=
liftMkBindingM <| MetavarContext.abstractRange e n xs
def abstract (e : Expr) (xs : Array Expr) : MetaM Expr :=
abstractRange e xs.size xs
def mkForallFVars (xs : Array Expr) (e : Expr) (usedOnly : Bool := false) (usedLetOnly : Bool := true) : MetaM Expr :=
if xs.isEmpty then pure e else liftMkBindingM <| MetavarContext.mkForall xs e usedOnly usedLetOnly
def mkLambdaFVars (xs : Array Expr) (e : Expr) (usedOnly : Bool := false) (usedLetOnly : Bool := true) : MetaM Expr :=
if xs.isEmpty then pure e else liftMkBindingM <| MetavarContext.mkLambda xs e usedOnly usedLetOnly
def mkLetFVars (xs : Array Expr) (e : Expr) (usedLetOnly := true) : MetaM Expr :=
mkLambdaFVars xs e (usedLetOnly := usedLetOnly)
def mkArrow (d b : Expr) : MetaM Expr :=
return Lean.mkForall (← mkFreshUserName `x) BinderInfo.default d b
/-- `fun _ : Unit => a` -/
def mkFunUnit (a : Expr) : MetaM Expr :=
return Lean.mkLambda (← mkFreshUserName `x) BinderInfo.default (mkConst ``Unit) a
def elimMVarDeps (xs : Array Expr) (e : Expr) (preserveOrder : Bool := false) : MetaM Expr :=
if xs.isEmpty then pure e else liftMkBindingM <| MetavarContext.elimMVarDeps xs e preserveOrder
@[inline] def withConfig (f : Config → Config) : n α → n α :=
mapMetaM <| withReader (fun ctx => { ctx with config := f ctx.config })
@[inline] def withTrackingZeta (x : n α) : n α :=
withConfig (fun cfg => { cfg with trackZeta := true }) x
@[inline] def withoutProofIrrelevance (x : n α) : n α :=
withConfig (fun cfg => { cfg with proofIrrelevance := false }) x
@[inline] def withTransparency (mode : TransparencyMode) : n α → n α :=
mapMetaM <| withConfig (fun config => { config with transparency := mode })
@[inline] def withDefault (x : n α) : n α :=
withTransparency TransparencyMode.default x
@[inline] def withReducible (x : n α) : n α :=
withTransparency TransparencyMode.reducible x
@[inline] def withReducibleAndInstances (x : n α) : n α :=
withTransparency TransparencyMode.instances x
@[inline] def withAtLeastTransparency (mode : TransparencyMode) (x : n α) : n α :=
withConfig
(fun config =>
let oldMode := config.transparency
let mode := if oldMode.lt mode then mode else oldMode
{ config with transparency := mode })
x
/-- Execute `x` allowing `isDefEq` to assign synthetic opaque metavariables. -/
@[inline] def withAssignableSyntheticOpaque (x : n α) : n α :=
withConfig (fun config => { config with assignSyntheticOpaque := true }) x
/-- Save cache, execute `x`, restore cache -/
@[inline] private def savingCacheImpl (x : MetaM α) : MetaM α := do
let savedCache := (← get).cache
try x finally modify fun s => { s with cache := savedCache }
@[inline] def savingCache : n α → n α :=
mapMetaM savingCacheImpl
def getTheoremInfo (info : ConstantInfo) : MetaM (Option ConstantInfo) := do
if (← shouldReduceAll) then
return some info
else
return none
private def getDefInfoTemp (info : ConstantInfo) : MetaM (Option ConstantInfo) := do
match (← getTransparency) with
| TransparencyMode.all => return some info
| TransparencyMode.default => return some info
| _ =>
if (← isReducible info.name) then
return some info
else
return none
/- Remark: we later define `getConst?` at `GetConst.lean` after we define `Instances.lean`.
This method is only used to implement `isClassQuickConst?`.
It is very similar to `getConst?`, but it returns none when `TransparencyMode.instances` and
`constName` is an instance. This difference should be irrelevant for `isClassQuickConst?`. -/
private def getConstTemp? (constName : Name) : MetaM (Option ConstantInfo) := do
match (← getEnv).find? constName with
| some (info@(ConstantInfo.thmInfo _)) => getTheoremInfo info
| some (info@(ConstantInfo.defnInfo _)) => getDefInfoTemp info
| some info => pure (some info)
| none => throwUnknownConstant constName
private def isClassQuickConst? (constName : Name) : MetaM (LOption Name) := do
if isClass (← getEnv) constName then
pure (LOption.some constName)
else
match (← getConstTemp? constName) with
| some _ => pure LOption.undef
| none => pure LOption.none
private partial def isClassQuick? : Expr → MetaM (LOption Name)
| Expr.bvar .. => pure LOption.none
| Expr.lit .. => pure LOption.none
| Expr.fvar .. => pure LOption.none
| Expr.sort .. => pure LOption.none
| Expr.lam .. => pure LOption.none
| Expr.letE .. => pure LOption.undef
| Expr.proj .. => pure LOption.undef
| Expr.forallE _ _ b _ => isClassQuick? b
| Expr.mdata _ e _ => isClassQuick? e
| Expr.const n _ _ => isClassQuickConst? n
| Expr.mvar mvarId _ => do
match (← getExprMVarAssignment? mvarId) with
| some val => isClassQuick? val
| none => pure LOption.none
| Expr.app f _ _ =>
match f.getAppFn with
| Expr.const n .. => isClassQuickConst? n
| Expr.lam .. => pure LOption.undef
| _ => pure LOption.none
def saveAndResetSynthInstanceCache : MetaM SynthInstanceCache := do
let savedSythInstance := (← get).cache.synthInstance
modifyCache fun c => { c with synthInstance := {} }
pure savedSythInstance
def restoreSynthInstanceCache (cache : SynthInstanceCache) : MetaM Unit :=
modifyCache fun c => { c with synthInstance := cache }
@[inline] private def resettingSynthInstanceCacheImpl (x : MetaM α) : MetaM α := do
let savedSythInstance ← saveAndResetSynthInstanceCache
try x finally restoreSynthInstanceCache savedSythInstance
/-- Reset `synthInstance` cache, execute `x`, and restore cache -/
@[inline] def resettingSynthInstanceCache : n α → n α :=
mapMetaM resettingSynthInstanceCacheImpl
@[inline] def resettingSynthInstanceCacheWhen (b : Bool) (x : n α) : n α :=
if b then resettingSynthInstanceCache x else x
private def withNewLocalInstanceImp (className : Name) (fvar : Expr) (k : MetaM α) : MetaM α := do
let localDecl ← getFVarLocalDecl fvar
/- Recall that we use `auxDecl` binderInfo when compiling recursive declarations. -/
match localDecl.binderInfo with
| BinderInfo.auxDecl => k
| _ =>
resettingSynthInstanceCache <|
withReader
(fun ctx => { ctx with localInstances := ctx.localInstances.push { className := className, fvar := fvar } })
k
/-- Add entry `{ className := className, fvar := fvar }` to localInstances,
and then execute continuation `k`.
It resets the type class cache using `resettingSynthInstanceCache`. -/
def withNewLocalInstance (className : Name) (fvar : Expr) : n α → n α :=
mapMetaM <| withNewLocalInstanceImp className fvar
private def fvarsSizeLtMaxFVars (fvars : Array Expr) (maxFVars? : Option Nat) : Bool :=
match maxFVars? with
| some maxFVars => fvars.size < maxFVars
| none => true
mutual
/--
`withNewLocalInstances isClassExpensive fvars j k` updates the vector or local instances
using free variables `fvars[j] ... fvars.back`, and execute `k`.
- `isClassExpensive` is defined later.
- The type class chache is reset whenever a new local instance is found.
- `isClassExpensive` uses `whnf` which depends (indirectly) on the set of local instances.
Thus, each new local instance requires a new `resettingSynthInstanceCache`. -/
private partial def withNewLocalInstancesImp
(fvars : Array Expr) (i : Nat) (k : MetaM α) : MetaM α := do
if h : i < fvars.size then
let fvar := fvars.get ⟨i, h⟩
let decl ← getFVarLocalDecl fvar
match (← isClassQuick? decl.type) with
| LOption.none => withNewLocalInstancesImp fvars (i+1) k
| LOption.undef =>
match (← isClassExpensive? decl.type) with
| none => withNewLocalInstancesImp fvars (i+1) k
| some c => withNewLocalInstance c fvar <| withNewLocalInstancesImp fvars (i+1) k
| LOption.some c => withNewLocalInstance c fvar <| withNewLocalInstancesImp fvars (i+1) k
else
k
/--
`forallTelescopeAuxAux lctx fvars j type`
Remarks:
- `lctx` is the `MetaM` local context extended with declarations for `fvars`.
- `type` is the type we are computing the telescope for. It contains only
dangling bound variables in the range `[j, fvars.size)`
- if `reducing? == true` and `type` is not `forallE`, we use `whnf`.
- when `type` is not a `forallE` nor it can't be reduced to one, we
excute the continuation `k`.
Here is an example that demonstrates the `reducing?`.
Suppose we have
```
abbrev StateM s a := s -> Prod a s
```
Now, assume we are trying to build the telescope for
```
forall (x : Nat), StateM Int Bool
```
if `reducing == true`, the function executes `k #[(x : Nat) (s : Int)] Bool`.
if `reducing == false`, the function executes `k #[(x : Nat)] (StateM Int Bool)`
if `maxFVars?` is `some max`, then we interrupt the telescope construction
when `fvars.size == max`
-/
private partial def forallTelescopeReducingAuxAux
(reducing : Bool) (maxFVars? : Option Nat)
(type : Expr)
(k : Array Expr → Expr → MetaM α) : MetaM α := do
let rec process (lctx : LocalContext) (fvars : Array Expr) (j : Nat) (type : Expr) : MetaM α := do
match type with
| Expr.forallE n d b c =>
if fvarsSizeLtMaxFVars fvars maxFVars? then
let d := d.instantiateRevRange j fvars.size fvars
let fvarId ← mkFreshId
let lctx := lctx.mkLocalDecl fvarId n d c.binderInfo
let fvar := mkFVar fvarId
let fvars := fvars.push fvar
process lctx fvars j b
else
let type := type.instantiateRevRange j fvars.size fvars;
withReader (fun ctx => { ctx with lctx := lctx }) do
withNewLocalInstancesImp fvars j do
k fvars type
| _ =>
let type := type.instantiateRevRange j fvars.size fvars;
withReader (fun ctx => { ctx with lctx := lctx }) do
withNewLocalInstancesImp fvars j do
if reducing && fvarsSizeLtMaxFVars fvars maxFVars? then
let newType ← whnf type
if newType.isForall then
process lctx fvars fvars.size newType
else
k fvars type
else
k fvars type
process (← getLCtx) #[] 0 type
private partial def forallTelescopeReducingAux (type : Expr) (maxFVars? : Option Nat) (k : Array Expr → Expr → MetaM α) : MetaM α := do
match maxFVars? with
| some 0 => k #[] type
| _ => do
let newType ← whnf type
if newType.isForall then
forallTelescopeReducingAuxAux true maxFVars? newType k
else
k #[] type
private partial def isClassExpensive? : Expr → MetaM (Option Name)
| type => withReducible <| -- when testing whether a type is a type class, we only unfold reducible constants.
forallTelescopeReducingAux type none fun xs type => do
let env ← getEnv
match type.getAppFn with
| Expr.const c _ _ => do
if isClass env c then
return some c
else
-- make sure abbreviations are unfolded
match (← whnf type).getAppFn with
| Expr.const c _ _ => return if isClass env c then some c else none
| _ => return none
| _ => return none
private partial def isClassImp? (type : Expr) : MetaM (Option Name) := do
match (← isClassQuick? type) with
| LOption.none => pure none
| LOption.some c => pure (some c)
| LOption.undef => isClassExpensive? type
end
def isClass? (type : Expr) : MetaM (Option Name) :=
try isClassImp? type catch _ => pure none
private def withNewLocalInstancesImpAux (fvars : Array Expr) (j : Nat) : n α → n α :=
mapMetaM <| withNewLocalInstancesImp fvars j
partial def withNewLocalInstances (fvars : Array Expr) (j : Nat) : n α → n α :=
mapMetaM <| withNewLocalInstancesImpAux fvars j
@[inline] private def forallTelescopeImp (type : Expr) (k : Array Expr → Expr → MetaM α) : MetaM α := do
forallTelescopeReducingAuxAux (reducing := false) (maxFVars? := none) type k
/--
Given `type` of the form `forall xs, A`, execute `k xs A`.
This combinator will declare local declarations, create free variables for them,
execute `k` with updated local context, and make sure the cache is restored after executing `k`. -/
def forallTelescope (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun k => forallTelescopeImp type k) k
private def forallTelescopeReducingImp (type : Expr) (k : Array Expr → Expr → MetaM α) : MetaM α :=
forallTelescopeReducingAux type (maxFVars? := none) k
/--
Similar to `forallTelescope`, but given `type` of the form `forall xs, A`,
it reduces `A` and continues bulding the telescope if it is a `forall`. -/
def forallTelescopeReducing (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun k => forallTelescopeReducingImp type k) k
private def forallBoundedTelescopeImp (type : Expr) (maxFVars? : Option Nat) (k : Array Expr → Expr → MetaM α) : MetaM α :=
forallTelescopeReducingAux type maxFVars? k
/--
Similar to `forallTelescopeReducing`, stops constructing the telescope when
it reaches size `maxFVars`. -/
def forallBoundedTelescope (type : Expr) (maxFVars? : Option Nat) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun k => forallBoundedTelescopeImp type maxFVars? k) k
private partial def lambdaTelescopeImp (e : Expr) (consumeLet : Bool) (k : Array Expr → Expr → MetaM α) : MetaM α := do
process consumeLet (← getLCtx) #[] 0 e
where
process (consumeLet : Bool) (lctx : LocalContext) (fvars : Array Expr) (j : Nat) (e : Expr) : MetaM α := do
match consumeLet, e with
| _, Expr.lam n d b c =>
let d := d.instantiateRevRange j fvars.size fvars
let fvarId ← mkFreshId
let lctx := lctx.mkLocalDecl fvarId n d c.binderInfo
let fvar := mkFVar fvarId
process consumeLet lctx (fvars.push fvar) j b
| true, Expr.letE n t v b _ => do
let t := t.instantiateRevRange j fvars.size fvars
let v := v.instantiateRevRange j fvars.size fvars
let fvarId ← mkFreshId
let lctx := lctx.mkLetDecl fvarId n t v
let fvar := mkFVar fvarId
process true lctx (fvars.push fvar) j b
| _, e =>
let e := e.instantiateRevRange j fvars.size fvars
withReader (fun ctx => { ctx with lctx := lctx }) do
withNewLocalInstancesImp fvars j do
k fvars e
/-- Similar to `forallTelescope` but for lambda and let expressions. -/
def lambdaLetTelescope (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun k => lambdaTelescopeImp type true k) k
/-- Similar to `forallTelescope` but for lambda expressions. -/
def lambdaTelescope (type : Expr) (k : Array Expr → Expr → n α) : n α :=
map2MetaM (fun k => lambdaTelescopeImp type false k) k
/-- Return the parameter names for the givel global declaration. -/
def getParamNames (declName : Name) : MetaM (Array Name) := do
forallTelescopeReducing (← getConstInfo declName).type fun xs _ => do
xs.mapM fun x => do
let localDecl ← getLocalDecl x.fvarId!
pure localDecl.userName
-- `kind` specifies the metavariable kind for metavariables not corresponding to instance implicit `[ ... ]` arguments.
private partial def forallMetaTelescopeReducingAux
(e : Expr) (reducing : Bool) (maxMVars? : Option Nat) (kind : MetavarKind) : MetaM (Array Expr × Array BinderInfo × Expr) :=
process #[] #[] 0 e
where
process (mvars : Array Expr) (bis : Array BinderInfo) (j : Nat) (type : Expr) : MetaM (Array Expr × Array BinderInfo × Expr) := do
if maxMVars?.isEqSome mvars.size then
let type := type.instantiateRevRange j mvars.size mvars;
return (mvars, bis, type)
else
match type with
| Expr.forallE n d b c =>
let d := d.instantiateRevRange j mvars.size mvars
let k := if c.binderInfo.isInstImplicit then MetavarKind.synthetic else kind
let mvar ← mkFreshExprMVar d k n
let mvars := mvars.push mvar
let bis := bis.push c.binderInfo
process mvars bis j b
| _ =>
let type := type.instantiateRevRange j mvars.size mvars;
if reducing then do
let newType ← whnf type;
if newType.isForall then
process mvars bis mvars.size newType
else
return (mvars, bis, type)
else
return (mvars, bis, type)
/-- Similar to `forallTelescope`, but creates metavariables instead of free variables. -/
def forallMetaTelescope (e : Expr) (kind := MetavarKind.natural) : MetaM (Array Expr × Array BinderInfo × Expr) :=
forallMetaTelescopeReducingAux e (reducing := false) (maxMVars? := none) kind
/-- Similar to `forallTelescopeReducing`, but creates metavariables instead of free variables. -/
def forallMetaTelescopeReducing (e : Expr) (maxMVars? : Option Nat := none) (kind := MetavarKind.natural) : MetaM (Array Expr × Array BinderInfo × Expr) :=
forallMetaTelescopeReducingAux e (reducing := true) maxMVars? kind
/-- Similar to `forallMetaTelescopeReducing`, stops constructing the telescope when it reaches size `maxMVars`. -/
def forallMetaBoundedTelescope (e : Expr) (maxMVars : Nat) (kind : MetavarKind := MetavarKind.natural) : MetaM (Array Expr × Array BinderInfo × Expr) :=
forallMetaTelescopeReducingAux e (reducing := true) (maxMVars? := some maxMVars) (kind := kind)
/-- Similar to `forallMetaTelescopeReducingAux` but for lambda expressions. -/
partial def lambdaMetaTelescope (e : Expr) (maxMVars? : Option Nat := none) : MetaM (Array Expr × Array BinderInfo × Expr) :=
process #[] #[] 0 e
where
process (mvars : Array Expr) (bis : Array BinderInfo) (j : Nat) (type : Expr) : MetaM (Array Expr × Array BinderInfo × Expr) := do
let finalize : Unit → MetaM (Array Expr × Array BinderInfo × Expr) := fun _ => do
let type := type.instantiateRevRange j mvars.size mvars
pure (mvars, bis, type)
if maxMVars?.isEqSome mvars.size then
finalize ()
else
match type with
| Expr.lam n d b c =>
let d := d.instantiateRevRange j mvars.size mvars
let mvar ← mkFreshExprMVar d
let mvars := mvars.push mvar
let bis := bis.push c.binderInfo
process mvars bis j b
| _ => finalize ()
private def withNewFVar (fvar fvarType : Expr) (k : Expr → MetaM α) : MetaM α := do
match (← isClass? fvarType) with
| none => k fvar
| some c => withNewLocalInstance c fvar <| k fvar
private def withLocalDeclImp (n : Name) (bi : BinderInfo) (type : Expr) (k : Expr → MetaM α) : MetaM α := do
let fvarId ← mkFreshId
let ctx ← read
let lctx := ctx.lctx.mkLocalDecl fvarId n type bi
let fvar := mkFVar fvarId
withReader (fun ctx => { ctx with lctx := lctx }) do
withNewFVar fvar type k
def withLocalDecl (name : Name) (bi : BinderInfo) (type : Expr) (k : Expr → n α) : n α :=
map1MetaM (fun k => withLocalDeclImp name bi type k) k
def withLocalDeclD (name : Name) (type : Expr) (k : Expr → n α) : n α :=
withLocalDecl name BinderInfo.default type k
partial def withLocalDecls
[Inhabited α]
(declInfos : Array (Name × BinderInfo × (Array Expr → n Expr)))
(k : (xs : Array Expr) → n α)
: n α :=
loop #[]
where
loop [Inhabited α] (acc : Array Expr) : n α := do
if acc.size < declInfos.size then
let (name, bi, typeCtor) := declInfos[acc.size]
withLocalDecl name bi (←typeCtor acc) fun x => loop (acc.push x)
else
k acc
def withLocalDeclsD [Inhabited α] (declInfos : Array (Name × (Array Expr → n Expr))) (k : (xs : Array Expr) → n α) : n α :=
withLocalDecls
(declInfos.map (fun (name, typeCtor) => (name, BinderInfo.default, typeCtor))) k
private def withNewBinderInfosImp (bs : Array (FVarId × BinderInfo)) (k : MetaM α) : MetaM α := do
let lctx := bs.foldl (init := (← getLCtx)) fun lctx (fvarId, bi) =>
lctx.setBinderInfo fvarId bi
withReader (fun ctx => { ctx with lctx := lctx }) k
def withNewBinderInfos (bs : Array (FVarId × BinderInfo)) (k : n α) : n α :=
mapMetaM (fun k => withNewBinderInfosImp bs k) k
private def withLetDeclImp (n : Name) (type : Expr) (val : Expr) (k : Expr → MetaM α) : MetaM α := do
let fvarId ← mkFreshId
let ctx ← read
let lctx := ctx.lctx.mkLetDecl fvarId n type val
let fvar := mkFVar fvarId
withReader (fun ctx => { ctx with lctx := lctx }) do
withNewFVar fvar type k
def withLetDecl (name : Name) (type : Expr) (val : Expr) (k : Expr → n α) : n α :=
map1MetaM (fun k => withLetDeclImp name type val k) k
private def withExistingLocalDeclsImp (decls : List LocalDecl) (k : MetaM α) : MetaM α := do
let ctx ← read
let numLocalInstances := ctx.localInstances.size
let lctx := decls.foldl (fun (lctx : LocalContext) decl => lctx.addDecl decl) ctx.lctx
withReader (fun ctx => { ctx with lctx := lctx }) do
let newLocalInsts ← decls.foldlM
(fun (newlocalInsts : Array LocalInstance) (decl : LocalDecl) => (do {
match (← isClass? decl.type) with
| none => pure newlocalInsts
| some c => pure <| newlocalInsts.push { className := c, fvar := decl.toExpr } } : MetaM _))
ctx.localInstances;
if newLocalInsts.size == numLocalInstances then
k
else
resettingSynthInstanceCache <| withReader (fun ctx => { ctx with localInstances := newLocalInsts }) k
def withExistingLocalDecls (decls : List LocalDecl) : n α → n α :=
mapMetaM <| withExistingLocalDeclsImp decls
private def withNewMCtxDepthImp (x : MetaM α) : MetaM α := do
let saved ← get
modify fun s => { s with mctx := s.mctx.incDepth, postponed := {} }
try
x
finally
modify fun s => { s with mctx := saved.mctx, postponed := saved.postponed }
/--
Save cache and `MetavarContext`, bump the `MetavarContext` depth, execute `x`,
and restore saved data. -/
def withNewMCtxDepth : n α → n α :=
mapMetaM withNewMCtxDepthImp
private def withLocalContextImp (lctx : LocalContext) (localInsts : LocalInstances) (x : MetaM α) : MetaM α := do
let localInstsCurr ← getLocalInstances
withReader (fun ctx => { ctx with lctx := lctx, localInstances := localInsts }) do
if localInsts == localInstsCurr then
x
else
resettingSynthInstanceCache x
def withLCtx (lctx : LocalContext) (localInsts : LocalInstances) : n α → n α :=
mapMetaM <| withLocalContextImp lctx localInsts
private def withMVarContextImp (mvarId : MVarId) (x : MetaM α) : MetaM α := do
let mvarDecl ← getMVarDecl mvarId
withLocalContextImp mvarDecl.lctx mvarDecl.localInstances x
/--
Execute `x` using the given metavariable `LocalContext` and `LocalInstances`.
The type class resolution cache is flushed when executing `x` if its `LocalInstances` are
different from the current ones. -/
def withMVarContext (mvarId : MVarId) : n α → n α :=
mapMetaM <| withMVarContextImp mvarId
private def withMCtxImp (mctx : MetavarContext) (x : MetaM α) : MetaM α := do
let mctx' ← getMCtx
setMCtx mctx
try x finally setMCtx mctx'
def withMCtx (mctx : MetavarContext) : n α → n α :=
mapMetaM <| withMCtxImp mctx
@[inline] private def approxDefEqImp (x : MetaM α) : MetaM α :=
withConfig (fun config => { config with foApprox := true, ctxApprox := true, quasiPatternApprox := true}) x
/-- Execute `x` using approximate unification: `foApprox`, `ctxApprox` and `quasiPatternApprox`. -/
@[inline] def approxDefEq : n α → n α :=
mapMetaM approxDefEqImp
@[inline] private def fullApproxDefEqImp (x : MetaM α) : MetaM α :=
withConfig (fun config => { config with foApprox := true, ctxApprox := true, quasiPatternApprox := true, constApprox := true }) x
/--
Similar to `approxDefEq`, but uses all available approximations.
We don't use `constApprox` by default at `approxDefEq` because it often produces undesirable solution for monadic code.
For example, suppose we have `pure (x > 0)` which has type `?m Prop`. We also have the goal `[Pure ?m]`.
Now, assume the expected type is `IO Bool`. Then, the unification constraint `?m Prop =?= IO Bool` could be solved
as `?m := fun _ => IO Bool` using `constApprox`, but this spurious solution would generate a failure when we try to
solve `[Pure (fun _ => IO Bool)]` -/
@[inline] def fullApproxDefEq : n α → n α :=
mapMetaM fullApproxDefEqImp
def normalizeLevel (u : Level) : MetaM Level := do
let u ← instantiateLevelMVars u
pure u.normalize
def assignLevelMVar (mvarId : MVarId) (u : Level) : MetaM Unit := do
modifyMCtx fun mctx => mctx.assignLevel mvarId u
def whnfR (e : Expr) : MetaM Expr :=
withTransparency TransparencyMode.reducible <| whnf e
def whnfD (e : Expr) : MetaM Expr :=
withTransparency TransparencyMode.default <| whnf e
def whnfI (e : Expr) : MetaM Expr :=
withTransparency TransparencyMode.instances <| whnf e
def setInlineAttribute (declName : Name) (kind := Compiler.InlineAttributeKind.inline): MetaM Unit := do
let env ← getEnv
match Compiler.setInlineAttribute env declName kind with
| Except.ok env => setEnv env
| Except.error msg => throwError msg
private partial def instantiateForallAux (ps : Array Expr) (i : Nat) (e : Expr) : MetaM Expr := do
if h : i < ps.size then
let p := ps.get ⟨i, h⟩
match (← whnf e) with
| Expr.forallE _ _ b _ => instantiateForallAux ps (i+1) (b.instantiate1 p)
| _ => throwError "invalid instantiateForall, too many parameters"
else
pure e
/- Given `e` of the form `forall (a_1 : A_1) ... (a_n : A_n), B[a_1, ..., a_n]` and `p_1 : A_1, ... p_n : A_n`, return `B[p_1, ..., p_n]`. -/
def instantiateForall (e : Expr) (ps : Array Expr) : MetaM Expr :=
instantiateForallAux ps 0 e
private partial def instantiateLambdaAux (ps : Array Expr) (i : Nat) (e : Expr) : MetaM Expr := do
if h : i < ps.size then
let p := ps.get ⟨i, h⟩
match (← whnf e) with
| Expr.lam _ _ b _ => instantiateLambdaAux ps (i+1) (b.instantiate1 p)
| _ => throwError "invalid instantiateLambda, too many parameters"
else
pure e
/- Given `e` of the form `fun (a_1 : A_1) ... (a_n : A_n) => t[a_1, ..., a_n]` and `p_1 : A_1, ... p_n : A_n`, return `t[p_1, ..., p_n]`.
It uses `whnf` to reduce `e` if it is not a lambda -/
def instantiateLambda (e : Expr) (ps : Array Expr) : MetaM Expr :=
instantiateLambdaAux ps 0 e
/-- Return true iff `e` depends on the free variable `fvarId` -/
def dependsOn (e : Expr) (fvarId : FVarId) : MetaM Bool :=
return (← getMCtx).exprDependsOn e fvarId
def ppExpr (e : Expr) : MetaM Format := do
let ctxCore ← readThe Core.Context
Lean.ppExpr { env := (← getEnv), mctx := (← getMCtx), lctx := (← getLCtx), opts := (← getOptions), currNamespace := ctxCore.currNamespace, openDecls := ctxCore.openDecls } e
@[inline] protected def orElse (x : MetaM α) (y : Unit → MetaM α) : MetaM α := do
let s ← saveState
try x catch _ => s.restore; y ()
instance : OrElse (MetaM α) := ⟨Meta.orElse⟩
instance : Alternative MetaM where
failure := fun {α} => throwError "failed"
orElse := Meta.orElse
@[inline] private def orelseMergeErrorsImp (x y : MetaM α)
(mergeRef : Syntax → Syntax → Syntax := fun r₁ r₂ => r₁)
(mergeMsg : MessageData → MessageData → MessageData := fun m₁ m₂ => m₁ ++ Format.line ++ m₂) : MetaM α := do
let env ← getEnv
let mctx ← getMCtx
try
x
catch ex =>
setEnv env
setMCtx mctx
match ex with
| Exception.error ref₁ m₁ =>
try
y
catch
| Exception.error ref₂ m₂ => throw <| Exception.error (mergeRef ref₁ ref₂) (mergeMsg m₁ m₂)
| ex => throw ex
| ex => throw ex
/--
Similar to `orelse`, but merge errors. Note that internal errors are not caught.
The default `mergeRef` uses the `ref` (position information) for the first message.
The default `mergeMsg` combines error messages using `Format.line ++ Format.line` as a separator. -/
@[inline] def orelseMergeErrors [MonadControlT MetaM m] [Monad m] (x y : m α)
(mergeRef : Syntax → Syntax → Syntax := fun r₁ r₂ => r₁)
(mergeMsg : MessageData → MessageData → MessageData := fun m₁ m₂ => m₁ ++ Format.line ++ Format.line ++ m₂) : m α := do
controlAt MetaM fun runInBase => orelseMergeErrorsImp (runInBase x) (runInBase y) mergeRef mergeMsg
/-- Execute `x`, and apply `f` to the produced error message -/
def mapErrorImp (x : MetaM α) (f : MessageData → MessageData) : MetaM α := do
try
x
catch
| Exception.error ref msg => throw <| Exception.error ref <| f msg
| ex => throw ex
@[inline] def mapError [MonadControlT MetaM m] [Monad m] (x : m α) (f : MessageData → MessageData) : m α :=
controlAt MetaM fun runInBase => mapErrorImp (runInBase x) f
end Methods
end Meta
export Meta (MetaM)
end Lean
|
9014860ecdcfbc06ea9bb4d2b9c6404b5a807323 | df561f413cfe0a88b1056655515399c546ff32a5 | /8-inequality-world/l11.lean | 3933ca04cd425fa7f5a845f193db957a3c93e9d3 | [] | no_license | nicholaspun/natural-number-game-solutions | 31d5158415c6f582694680044c5c6469032c2a06 | 1e2aed86d2e76a3f4a275c6d99e795ad30cf6df0 | refs/heads/main | 1,675,123,625,012 | 1,607,633,548,000 | 1,607,633,548,000 | 318,933,860 | 3 | 1 | null | null | null | null | UTF-8 | Lean | false | false | 162 | lean | theorem add_le_add_right {a b : mynat} : a ≤ b → ∀ t, (a + t) ≤ (b + t) :=
begin
intros h t,
cases h with c hc,
rw hc,
use c,
rw add_right_comm,
refl,
end |
cf262ba4b6facbfe767b74dd1cbb0ef48ab8ce62 | de91c42b87530c3bdcc2b138ef1a3c3d9bee0d41 | /old/expressions/classical_geometry.lean | fd9c4d635cf4b7cd4c3dca1fde183581c2876b31 | [] | no_license | kevinsullivan/lang | d3e526ba363dc1ddf5ff1c2f36607d7f891806a7 | e9d869bff94fb13ad9262222a6f3c4aafba82d5e | refs/heads/master | 1,687,840,064,795 | 1,628,047,969,000 | 1,628,047,969,000 | 282,210,749 | 0 | 1 | null | 1,608,153,830,000 | 1,595,592,637,000 | Lean | UTF-8 | Lean | false | false | 5,182 | lean | import ...phys.src.classical_geometry
namespace lang.euclideanGeometry3
structure var : Type :=
mk :: (num : ℕ)
structure spaceVar extends var
def myvar : spaceVar := ⟨⟨2⟩⟩
def p : spaceVar := ⟨⟨1⟩⟩
inductive spaceExpr
| lit (v : euclideanGeometry3)
| var (v : spaceVar)
abbreviation spaceEnv := spaceVar → euclideanGeometry3
abbreviation spaceEval := spaceExpr → spaceEnv → euclideanGeometry3
structure frameVar extends var
inductive frameExpr
| lit (f : euclideanGeometry3Frame)
| var (v : frameVar)
abbreviation frameEnv := frameVar → euclideanGeometry3Frame
abbreviation frameEval := frameExpr → frameEnv → euclideanGeometry3Frame
structure TransformVar extends var
inductive TransformExpr
| lit (t : euclideanGeometry3Transform)
| var (v : TransformVar)
abbreviation transformEnv := TransformVar → euclideanGeometry3Transform
abbreviation transformEval := TransformExpr → transformEnv → euclideanGeometry3Transform
structure ScalarVar extends var
inductive ScalarExpr
| lit (f : euclideanGeometry3Scalar)
| var (v : ScalarVar)
abbreviation scalarEnv := ScalarVar → euclideanGeometry3Scalar
abbreviation scalarEval := ScalarExpr → scalarEnv → euclideanGeometry3Scalar
structure AngleVar extends var
inductive AngleExpr
| lit (f : euclideanGeometry3Angle)
| var (v : AngleVar)
abbreviation angleEnv := AngleVar → euclideanGeometry3Angle
abbreviation angleEval := AngleExpr → angleEnv → euclideanGeometry3Angle
--abbreviation
structure CoordinateVectorVar extends var
inductive CoordinateVectorExpr
| lit (f : euclideanGeometry3CoordinateVector)
| var (v : CoordinateVectorVar)
abbreviation CoordinateVectorEnv := CoordinateVectorVar → euclideanGeometry3CoordinateVector
abbreviation CoordinateVectorEval := CoordinateVectorExpr → CoordinateVectorEnv → euclideanGeometry3CoordinateVector
structure CoordinatePointVar extends var
inductive CoordinatePointExpr
| lit (f : euclideanGeometry3CoordinatePoint)
| var(v : CoordinatePointVar )
abbreviation pointEnv := CoordinatePointVar → euclideanGeometry3CoordinatePoint
abbreviation pointEval := CoordinatePointExpr → pointEnv → euclideanGeometry3CoordinatePoint
structure OrientationVar extends var
inductive OrientationExpr
| lit (f : euclideanGeometry3Orientation)
| var(v : OrientationVar )
abbreviation orientationEnv := OrientationVar → euclideanGeometry3Orientation
abbreviation orientationEval := OrientationExpr → orientationEnv → euclideanGeometry3Orientation
structure RotationVar extends var
inductive RotationExpr
| lit (f : euclideanGeometry3Rotation)
| var(v : RotationVar )
abbreviation rotationEnv := RotationVar → euclideanGeometry3Rotation
abbreviation rotationEval := RotationExpr → rotationEnv → euclideanGeometry3Rotation
def spaceVarEq : spaceVar → spaceVar → bool
| v1 v2 := v1.num=v2.num
def vectorVarEq : CoordinateVectorVar → CoordinateVectorVar → bool
| v1 v2 := v1.num=v2.num
def pointVarEq : CoordinatePointVar → CoordinatePointVar → bool
| v1 v2 := v1.num=v2.num
def frameVarEq : frameVar → frameVar → bool
| v1 v2 := v1.num=v2.num
def transformVarEq : TransformVar → TransformVar → bool
| v1 v2 := v1.num=v2.num
def scalarVarEq : ScalarVar → ScalarVar → bool
| v1 v2 := v1.num=v2.num
def angleVarEq : AngleVar → AngleVar → bool
| v1 v2 := v1.num=v2.num
def orientationVarEq : OrientationVar → OrientationVar → bool
| v1 v2 := v1.num=v2.num
def rotationVarEq : RotationVar → RotationVar → bool
| v1 v2 := v1.num=v2.num
structure env : Type :=
(sp : spaceEnv)
(fr : frameEnv )
(tr : transformEnv)
(vec : CoordinateVectorEnv)
(pt : pointEnv)
(s : scalarEnv)
(a : angleEnv)
(or : orientationEnv)
(r : rotationEnv)
noncomputable def initSp := λ v : spaceVar, euclideanGeometry3.build 9999
noncomputable def initFr :=
λ v : frameVar,
euclideanGeometry3.stdFrame (initSp ⟨⟨9999⟩⟩)
noncomputable def initTransform :=
λ v : TransformVar,
euclideanGeometry3Transform.mk (initSp ⟨⟨9999⟩⟩) (initFr ⟨⟨9999⟩⟩) (initFr ⟨⟨9999⟩⟩)
noncomputable def initVec :=
λ v : CoordinateVectorVar,
euclideanGeometry3CoordinateVector.build (initSp ⟨⟨9999⟩⟩) (initFr ⟨⟨9999⟩⟩) ⟨[1,1,1], by refl⟩
noncomputable def initPt :=
λ v : CoordinatePointVar,
euclideanGeometry3CoordinatePoint.build (initSp ⟨⟨9999⟩⟩) (initFr ⟨⟨9999⟩⟩) ⟨[1,1,1], by refl⟩
noncomputable def initScalar :=
λ v : ScalarVar,
euclideanGeometry3Scalar.build (initSp ⟨⟨9999⟩⟩) ⟨[1],rfl⟩
noncomputable def initAngle :=
λ v : AngleVar,
euclideanGeometry3Angle.build (initSp ⟨⟨9999⟩⟩) ⟨[1],rfl⟩
noncomputable def initOrientation :=
λ v : OrientationVar,
euclideanGeometry3Orientation.build (initSp ⟨⟨9999⟩⟩)
noncomputable def initRotation :=
λ v : RotationVar,
euclideanGeometry3Rotation.build (initSp ⟨⟨9999⟩⟩)
noncomputable def
initEnv : env :=
⟨initSp, initFr, initTransform, initVec, initPt, initScalar, initAngle, initOrientation, initRotation⟩
end lang.euclideanGeometry3 |
b98bd6994864ed62725a162aab0a8e32b01f0329 | 4950bf76e5ae40ba9f8491647d0b6f228ddce173 | /src/topology/metric_space/basic.lean | 54366ce43656e1075abb6e7aa8a7e2d042b58a12 | [
"Apache-2.0"
] | permissive | ntzwq/mathlib | ca50b21079b0a7c6781c34b62199a396dd00cee2 | 36eec1a98f22df82eaccd354a758ef8576af2a7f | refs/heads/master | 1,675,193,391,478 | 1,607,822,996,000 | 1,607,822,996,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 76,435 | lean | /-
Copyright (c) 2015, 2017 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Metric spaces.
Authors: Jeremy Avigad, Robert Y. Lewis, Johannes Hölzl, Mario Carneiro, Sébastien Gouëzel
Many definitions and theorems expected on metric spaces are already introduced on uniform spaces and
topological spaces. For example:
open and closed sets, compactness, completeness, continuity and uniform continuity
-/
import topology.metric_space.emetric_space
import topology.algebra.ordered
open set filter classical topological_space
noncomputable theory
open_locale uniformity topological_space big_operators filter
universes u v w
variables {α : Type u} {β : Type v} {γ : Type w}
/-- Construct a uniform structure from a distance function and metric space axioms -/
def uniform_space_of_dist
(dist : α → α → ℝ)
(dist_self : ∀ x : α, dist x x = 0)
(dist_comm : ∀ x y : α, dist x y = dist y x)
(dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z) : uniform_space α :=
uniform_space.of_core {
uniformity := (⨅ ε>0, 𝓟 {p:α×α | dist p.1 p.2 < ε}),
refl := le_infi $ assume ε, le_infi $
by simp [set.subset_def, id_rel, dist_self, (>)] {contextual := tt},
comp := le_infi $ assume ε, le_infi $ assume h, lift'_le
(mem_infi_sets (ε / 2) $ mem_infi_sets (div_pos h zero_lt_two) (subset.refl _)) $
have ∀ (a b c : α), dist a c < ε / 2 → dist c b < ε / 2 → dist a b < ε,
from assume a b c hac hcb,
calc dist a b ≤ dist a c + dist c b : dist_triangle _ _ _
... < ε / 2 + ε / 2 : add_lt_add hac hcb
... = ε : by rw [div_add_div_same, add_self_div_two],
by simpa [comp_rel],
symm := tendsto_infi.2 $ assume ε, tendsto_infi.2 $ assume h,
tendsto_infi' ε $ tendsto_infi' h $ tendsto_principal_principal.2 $ by simp [dist_comm] }
/-- The distance function (given an ambient metric space on `α`), which returns
a nonnegative real number `dist x y` given `x y : α`. -/
class has_dist (α : Type*) := (dist : α → α → ℝ)
export has_dist (dist)
-- the uniform structure and the emetric space structure are embedded in the metric space structure
-- to avoid instance diamond issues. See Note [forgetful inheritance].
/-- Metric space
Each metric space induces a canonical `uniform_space` and hence a canonical `topological_space`.
This is enforced in the type class definition, by extending the `uniform_space` structure. When
instantiating a `metric_space` structure, the uniformity fields are not necessary, they will be
filled in by default. In the same way, each metric space induces an emetric space structure.
It is included in the structure, but filled in by default.
-/
class metric_space (α : Type u) extends has_dist α : Type u :=
(dist_self : ∀ x : α, dist x x = 0)
(eq_of_dist_eq_zero : ∀ {x y : α}, dist x y = 0 → x = y)
(dist_comm : ∀ x y : α, dist x y = dist y x)
(dist_triangle : ∀ x y z : α, dist x z ≤ dist x y + dist y z)
(edist : α → α → ennreal := λx y, ennreal.of_real (dist x y))
(edist_dist : ∀ x y : α, edist x y = ennreal.of_real (dist x y) . control_laws_tac)
(to_uniform_space : uniform_space α := uniform_space_of_dist dist dist_self dist_comm dist_triangle)
(uniformity_dist : 𝓤 α = ⨅ ε>0, 𝓟 {p:α×α | dist p.1 p.2 < ε} . control_laws_tac)
variables [metric_space α]
@[priority 100] -- see Note [lower instance priority]
instance metric_space.to_uniform_space' : uniform_space α :=
metric_space.to_uniform_space
@[priority 200] -- see Note [lower instance priority]
instance metric_space.to_has_edist : has_edist α := ⟨metric_space.edist⟩
@[simp] theorem dist_self (x : α) : dist x x = 0 := metric_space.dist_self x
theorem eq_of_dist_eq_zero {x y : α} : dist x y = 0 → x = y :=
metric_space.eq_of_dist_eq_zero
theorem dist_comm (x y : α) : dist x y = dist y x := metric_space.dist_comm x y
theorem edist_dist (x y : α) : edist x y = ennreal.of_real (dist x y) :=
metric_space.edist_dist x y
@[simp] theorem dist_eq_zero {x y : α} : dist x y = 0 ↔ x = y :=
iff.intro eq_of_dist_eq_zero (assume : x = y, this ▸ dist_self _)
@[simp] theorem zero_eq_dist {x y : α} : 0 = dist x y ↔ x = y :=
by rw [eq_comm, dist_eq_zero]
theorem dist_triangle (x y z : α) : dist x z ≤ dist x y + dist y z :=
metric_space.dist_triangle x y z
theorem dist_triangle_left (x y z : α) : dist x y ≤ dist z x + dist z y :=
by rw dist_comm z; apply dist_triangle
theorem dist_triangle_right (x y z : α) : dist x y ≤ dist x z + dist y z :=
by rw dist_comm y; apply dist_triangle
lemma dist_triangle4 (x y z w : α) :
dist x w ≤ dist x y + dist y z + dist z w :=
calc
dist x w ≤ dist x z + dist z w : dist_triangle x z w
... ≤ (dist x y + dist y z) + dist z w : add_le_add_right (metric_space.dist_triangle x y z) _
lemma dist_triangle4_left (x₁ y₁ x₂ y₂ : α) :
dist x₂ y₂ ≤ dist x₁ y₁ + (dist x₁ x₂ + dist y₁ y₂) :=
by rw [add_left_comm, dist_comm x₁, ← add_assoc]; apply dist_triangle4
lemma dist_triangle4_right (x₁ y₁ x₂ y₂ : α) :
dist x₁ y₁ ≤ dist x₁ x₂ + dist y₁ y₂ + dist x₂ y₂ :=
by rw [add_right_comm, dist_comm y₁]; apply dist_triangle4
/-- The triangle (polygon) inequality for sequences of points; `finset.Ico` version. -/
lemma dist_le_Ico_sum_dist (f : ℕ → α) {m n} (h : m ≤ n) :
dist (f m) (f n) ≤ ∑ i in finset.Ico m n, dist (f i) (f (i + 1)) :=
begin
revert n,
apply nat.le_induction,
{ simp only [finset.sum_empty, finset.Ico.self_eq_empty, dist_self] },
{ assume n hn hrec,
calc dist (f m) (f (n+1)) ≤ dist (f m) (f n) + dist _ _ : dist_triangle _ _ _
... ≤ ∑ i in finset.Ico m n, _ + _ : add_le_add hrec (le_refl _)
... = ∑ i in finset.Ico m (n+1), _ :
by rw [finset.Ico.succ_top hn, finset.sum_insert, add_comm]; simp }
end
/-- The triangle (polygon) inequality for sequences of points; `finset.range` version. -/
lemma dist_le_range_sum_dist (f : ℕ → α) (n : ℕ) :
dist (f 0) (f n) ≤ ∑ i in finset.range n, dist (f i) (f (i + 1)) :=
finset.Ico.zero_bot n ▸ dist_le_Ico_sum_dist f (nat.zero_le n)
/-- A version of `dist_le_Ico_sum_dist` with each intermediate distance replaced
with an upper estimate. -/
lemma dist_le_Ico_sum_of_dist_le {f : ℕ → α} {m n} (hmn : m ≤ n)
{d : ℕ → ℝ} (hd : ∀ {k}, m ≤ k → k < n → dist (f k) (f (k + 1)) ≤ d k) :
dist (f m) (f n) ≤ ∑ i in finset.Ico m n, d i :=
le_trans (dist_le_Ico_sum_dist f hmn) $
finset.sum_le_sum $ λ k hk, hd (finset.Ico.mem.1 hk).1 (finset.Ico.mem.1 hk).2
/-- A version of `dist_le_range_sum_dist` with each intermediate distance replaced
with an upper estimate. -/
lemma dist_le_range_sum_of_dist_le {f : ℕ → α} (n : ℕ)
{d : ℕ → ℝ} (hd : ∀ {k}, k < n → dist (f k) (f (k + 1)) ≤ d k) :
dist (f 0) (f n) ≤ ∑ i in finset.range n, d i :=
finset.Ico.zero_bot n ▸ dist_le_Ico_sum_of_dist_le (zero_le n) (λ _ _, hd)
theorem swap_dist : function.swap (@dist α _) = dist :=
by funext x y; exact dist_comm _ _
theorem abs_dist_sub_le (x y z : α) : abs (dist x z - dist y z) ≤ dist x y :=
abs_sub_le_iff.2
⟨sub_le_iff_le_add.2 (dist_triangle _ _ _),
sub_le_iff_le_add.2 (dist_triangle_left _ _ _)⟩
theorem dist_nonneg {x y : α} : 0 ≤ dist x y :=
have 2 * dist x y ≥ 0,
from calc 2 * dist x y = dist x y + dist y x : by rw [dist_comm x y, two_mul]
... ≥ 0 : by rw ← dist_self x; apply dist_triangle,
nonneg_of_mul_nonneg_left this zero_lt_two
@[simp] theorem dist_le_zero {x y : α} : dist x y ≤ 0 ↔ x = y :=
by simpa [le_antisymm_iff, dist_nonneg] using @dist_eq_zero _ _ x y
@[simp] theorem dist_pos {x y : α} : 0 < dist x y ↔ x ≠ y :=
by simpa only [not_le] using not_congr dist_le_zero
@[simp] theorem abs_dist {a b : α} : abs (dist a b) = dist a b :=
abs_of_nonneg dist_nonneg
theorem eq_of_forall_dist_le {x y : α} (h : ∀ ε > 0, dist x y ≤ ε) : x = y :=
eq_of_dist_eq_zero (eq_of_le_of_forall_le_of_dense dist_nonneg h)
/-- Distance as a nonnegative real number. -/
def nndist (a b : α) : nnreal := ⟨dist a b, dist_nonneg⟩
/--Express `nndist` in terms of `edist`-/
lemma nndist_edist (x y : α) : nndist x y = (edist x y).to_nnreal :=
by simp [nndist, edist_dist, nnreal.of_real, max_eq_left dist_nonneg, ennreal.of_real]
/--Express `edist` in terms of `nndist`-/
lemma edist_nndist (x y : α) : edist x y = ↑(nndist x y) :=
by { rw [edist_dist, nndist, ennreal.of_real_eq_coe_nnreal] }
@[simp, norm_cast] lemma ennreal_coe_nndist (x y : α) : ↑(nndist x y) = edist x y :=
(edist_nndist x y).symm
@[simp, norm_cast] lemma edist_lt_coe {x y : α} {c : nnreal} :
edist x y < c ↔ nndist x y < c :=
by rw [edist_nndist, ennreal.coe_lt_coe]
@[simp, norm_cast] lemma edist_le_coe {x y : α} {c : nnreal} :
edist x y ≤ c ↔ nndist x y ≤ c :=
by rw [edist_nndist, ennreal.coe_le_coe]
/--In a metric space, the extended distance is always finite-/
lemma edist_ne_top (x y : α) : edist x y ≠ ⊤ :=
by rw [edist_dist x y]; apply ennreal.coe_ne_top
/--In a metric space, the extended distance is always finite-/
lemma edist_lt_top {α : Type*} [metric_space α] (x y : α) : edist x y < ⊤ :=
ennreal.lt_top_iff_ne_top.2 (edist_ne_top x y)
/--`nndist x x` vanishes-/
@[simp] lemma nndist_self (a : α) : nndist a a = 0 := (nnreal.coe_eq_zero _).1 (dist_self a)
/--Express `dist` in terms of `nndist`-/
lemma dist_nndist (x y : α) : dist x y = ↑(nndist x y) := rfl
@[simp, norm_cast] lemma coe_nndist (x y : α) : ↑(nndist x y) = dist x y :=
(dist_nndist x y).symm
@[simp, norm_cast] lemma dist_lt_coe {x y : α} {c : nnreal} :
dist x y < c ↔ nndist x y < c :=
iff.rfl
@[simp, norm_cast] lemma dist_le_coe {x y : α} {c : nnreal} :
dist x y ≤ c ↔ nndist x y ≤ c :=
iff.rfl
/--Express `nndist` in terms of `dist`-/
lemma nndist_dist (x y : α) : nndist x y = nnreal.of_real (dist x y) :=
by rw [dist_nndist, nnreal.of_real_coe]
/--Deduce the equality of points with the vanishing of the nonnegative distance-/
theorem eq_of_nndist_eq_zero {x y : α} : nndist x y = 0 → x = y :=
by simp only [← nnreal.eq_iff, ← dist_nndist, imp_self, nnreal.coe_zero, dist_eq_zero]
theorem nndist_comm (x y : α) : nndist x y = nndist y x :=
by simpa only [dist_nndist, nnreal.coe_eq] using dist_comm x y
/--Characterize the equality of points with the vanishing of the nonnegative distance-/
@[simp] theorem nndist_eq_zero {x y : α} : nndist x y = 0 ↔ x = y :=
by simp only [← nnreal.eq_iff, ← dist_nndist, imp_self, nnreal.coe_zero, dist_eq_zero]
@[simp] theorem zero_eq_nndist {x y : α} : 0 = nndist x y ↔ x = y :=
by simp only [← nnreal.eq_iff, ← dist_nndist, imp_self, nnreal.coe_zero, zero_eq_dist]
/--Triangle inequality for the nonnegative distance-/
theorem nndist_triangle (x y z : α) : nndist x z ≤ nndist x y + nndist y z :=
by simpa [nnreal.coe_le_coe] using dist_triangle x y z
theorem nndist_triangle_left (x y z : α) : nndist x y ≤ nndist z x + nndist z y :=
by simpa [nnreal.coe_le_coe] using dist_triangle_left x y z
theorem nndist_triangle_right (x y z : α) : nndist x y ≤ nndist x z + nndist y z :=
by simpa [nnreal.coe_le_coe] using dist_triangle_right x y z
/--Express `dist` in terms of `edist`-/
lemma dist_edist (x y : α) : dist x y = (edist x y).to_real :=
by rw [edist_dist, ennreal.to_real_of_real (dist_nonneg)]
namespace metric
/- instantiate metric space as a topology -/
variables {x y z : α} {ε ε₁ ε₂ : ℝ} {s : set α}
/-- `ball x ε` is the set of all points `y` with `dist y x < ε` -/
def ball (x : α) (ε : ℝ) : set α := {y | dist y x < ε}
@[simp] theorem mem_ball : y ∈ ball x ε ↔ dist y x < ε := iff.rfl
theorem mem_ball' : y ∈ ball x ε ↔ dist x y < ε := by rw dist_comm; refl
@[simp] lemma nonempty_ball (h : 0 < ε) : (ball x ε).nonempty :=
⟨x, by simp [h]⟩
lemma ball_eq_ball (ε : ℝ) (x : α) :
uniform_space.ball x {p | dist p.2 p.1 < ε} = metric.ball x ε := rfl
lemma ball_eq_ball' (ε : ℝ) (x : α) :
uniform_space.ball x {p | dist p.1 p.2 < ε} = metric.ball x ε :=
by { ext, simp [dist_comm, uniform_space.ball] }
/-- `closed_ball x ε` is the set of all points `y` with `dist y x ≤ ε` -/
def closed_ball (x : α) (ε : ℝ) := {y | dist y x ≤ ε}
/-- `sphere x ε` is the set of all points `y` with `dist y x = ε` -/
def sphere (x : α) (ε : ℝ) := {y | dist y x = ε}
@[simp] theorem mem_closed_ball : y ∈ closed_ball x ε ↔ dist y x ≤ ε := iff.rfl
theorem mem_closed_ball' : y ∈ closed_ball x ε ↔ dist x y ≤ ε :=
by { rw dist_comm, refl }
lemma nonempty_closed_ball (h : 0 ≤ ε) : (closed_ball x ε).nonempty :=
⟨x, by simp [h]⟩
theorem ball_subset_closed_ball : ball x ε ⊆ closed_ball x ε :=
assume y (hy : _ < _), le_of_lt hy
theorem sphere_subset_closed_ball : sphere x ε ⊆ closed_ball x ε :=
λ y, le_of_eq
theorem sphere_disjoint_ball : disjoint (sphere x ε) (ball x ε) :=
λ y ⟨hy₁, hy₂⟩, absurd hy₁ $ ne_of_lt hy₂
@[simp] theorem ball_union_sphere : ball x ε ∪ sphere x ε = closed_ball x ε :=
set.ext $ λ y, (@le_iff_lt_or_eq ℝ _ _ _).symm
@[simp] theorem sphere_union_ball : sphere x ε ∪ ball x ε = closed_ball x ε :=
by rw [union_comm, ball_union_sphere]
@[simp] theorem closed_ball_diff_sphere : closed_ball x ε \ sphere x ε = ball x ε :=
by rw [← ball_union_sphere, set.union_diff_cancel_right sphere_disjoint_ball.symm]
@[simp] theorem closed_ball_diff_ball : closed_ball x ε \ ball x ε = sphere x ε :=
by rw [← ball_union_sphere, set.union_diff_cancel_left sphere_disjoint_ball.symm]
theorem pos_of_mem_ball (hy : y ∈ ball x ε) : 0 < ε :=
lt_of_le_of_lt dist_nonneg hy
theorem mem_ball_self (h : 0 < ε) : x ∈ ball x ε :=
show dist x x < ε, by rw dist_self; assumption
theorem mem_closed_ball_self (h : 0 ≤ ε) : x ∈ closed_ball x ε :=
show dist x x ≤ ε, by rw dist_self; assumption
theorem mem_ball_comm : x ∈ ball y ε ↔ y ∈ ball x ε :=
by simp [dist_comm]
theorem ball_subset_ball (h : ε₁ ≤ ε₂) : ball x ε₁ ⊆ ball x ε₂ :=
λ y (yx : _ < ε₁), lt_of_lt_of_le yx h
theorem closed_ball_subset_closed_ball {α : Type u} [metric_space α] {ε₁ ε₂ : ℝ} {x : α} (h : ε₁ ≤ ε₂) :
closed_ball x ε₁ ⊆ closed_ball x ε₂ :=
λ y (yx : _ ≤ ε₁), le_trans yx h
theorem ball_disjoint (h : ε₁ + ε₂ ≤ dist x y) : ball x ε₁ ∩ ball y ε₂ = ∅ :=
eq_empty_iff_forall_not_mem.2 $ λ z ⟨h₁, h₂⟩,
not_lt_of_le (dist_triangle_left x y z)
(lt_of_lt_of_le (add_lt_add h₁ h₂) h)
theorem ball_disjoint_same (h : ε ≤ dist x y / 2) : ball x ε ∩ ball y ε = ∅ :=
ball_disjoint $ by rwa [← two_mul, ← le_div_iff' (@zero_lt_two ℝ _ _)]
theorem ball_subset (h : dist x y ≤ ε₂ - ε₁) : ball x ε₁ ⊆ ball y ε₂ :=
λ z zx, by rw ← add_sub_cancel'_right ε₁ ε₂; exact
lt_of_le_of_lt (dist_triangle z x y) (add_lt_add_of_lt_of_le zx h)
theorem ball_half_subset (y) (h : y ∈ ball x (ε / 2)) : ball y (ε / 2) ⊆ ball x ε :=
ball_subset $ by rw sub_self_div_two; exact le_of_lt h
theorem exists_ball_subset_ball (h : y ∈ ball x ε) : ∃ ε' > 0, ball y ε' ⊆ ball x ε :=
⟨_, sub_pos.2 h, ball_subset $ by rw sub_sub_self⟩
@[simp] theorem ball_eq_empty_iff_nonpos : ball x ε = ∅ ↔ ε ≤ 0 :=
eq_empty_iff_forall_not_mem.trans
⟨λ h, le_of_not_gt $ λ ε0, h _ $ mem_ball_self ε0,
λ ε0 y h, not_lt_of_le ε0 $ pos_of_mem_ball h⟩
@[simp] theorem closed_ball_eq_empty_iff_neg : closed_ball x ε = ∅ ↔ ε < 0 :=
eq_empty_iff_forall_not_mem.trans
⟨λ h, not_le.1 $ λ ε0, h x $ mem_closed_ball_self ε0,
λ ε0 y h, not_lt_of_le (mem_closed_ball.1 h) (lt_of_lt_of_le ε0 dist_nonneg)⟩
@[simp] lemma ball_zero : ball x 0 = ∅ :=
by rw [ball_eq_empty_iff_nonpos]
@[simp] lemma closed_ball_zero : closed_ball x 0 = {x} :=
set.ext $ λ y, dist_le_zero
theorem uniformity_basis_dist :
(𝓤 α).has_basis (λ ε : ℝ, 0 < ε) (λ ε, {p:α×α | dist p.1 p.2 < ε}) :=
begin
rw ← metric_space.uniformity_dist.symm,
refine has_basis_binfi_principal _ nonempty_Ioi,
exact λ r (hr : 0 < r) p (hp : 0 < p), ⟨min r p, lt_min hr hp,
λ x (hx : dist _ _ < _), lt_of_lt_of_le hx (min_le_left r p),
λ x (hx : dist _ _ < _), lt_of_lt_of_le hx (min_le_right r p)⟩
end
/-- Given `f : β → ℝ`, if `f` sends `{i | p i}` to a set of positive numbers
accumulating to zero, then `f i`-neighborhoods of the diagonal form a basis of `𝓤 α`.
For specific bases see `uniformity_basis_dist`, `uniformity_basis_dist_inv_nat_succ`,
and `uniformity_basis_dist_inv_nat_pos`. -/
protected theorem mk_uniformity_basis {β : Type*} {p : β → Prop} {f : β → ℝ}
(hf₀ : ∀ i, p i → 0 < f i) (hf : ∀ ⦃ε⦄, 0 < ε → ∃ i (hi : p i), f i ≤ ε) :
(𝓤 α).has_basis p (λ i, {p:α×α | dist p.1 p.2 < f i}) :=
begin
refine ⟨λ s, uniformity_basis_dist.mem_iff.trans _⟩,
split,
{ rintros ⟨ε, ε₀, hε⟩,
obtain ⟨i, hi, H⟩ : ∃ i (hi : p i), f i ≤ ε, from hf ε₀,
exact ⟨i, hi, λ x (hx : _ < _), hε $ lt_of_lt_of_le hx H⟩ },
{ exact λ ⟨i, hi, H⟩, ⟨f i, hf₀ i hi, H⟩ }
end
theorem uniformity_basis_dist_inv_nat_succ :
(𝓤 α).has_basis (λ _, true) (λ n:ℕ, {p:α×α | dist p.1 p.2 < 1 / (↑n+1) }) :=
metric.mk_uniformity_basis (λ n _, div_pos zero_lt_one $ nat.cast_add_one_pos n)
(λ ε ε0, (exists_nat_one_div_lt ε0).imp $ λ n hn, ⟨trivial, le_of_lt hn⟩)
theorem uniformity_basis_dist_inv_nat_pos :
(𝓤 α).has_basis (λ n:ℕ, 0<n) (λ n:ℕ, {p:α×α | dist p.1 p.2 < 1 / ↑n }) :=
metric.mk_uniformity_basis (λ n hn, div_pos zero_lt_one $ nat.cast_pos.2 hn)
(λ ε ε0, let ⟨n, hn⟩ := exists_nat_one_div_lt ε0 in ⟨n+1, nat.succ_pos n, le_of_lt hn⟩)
/-- Given `f : β → ℝ`, if `f` sends `{i | p i}` to a set of positive numbers
accumulating to zero, then closed neighborhoods of the diagonal of sizes `{f i | p i}`
form a basis of `𝓤 α`.
Currently we have only one specific basis `uniformity_basis_dist_le` based on this constructor.
More can be easily added if needed in the future. -/
protected theorem mk_uniformity_basis_le {β : Type*} {p : β → Prop} {f : β → ℝ}
(hf₀ : ∀ x, p x → 0 < f x) (hf : ∀ ε, 0 < ε → ∃ x (hx : p x), f x ≤ ε) :
(𝓤 α).has_basis p (λ x, {p:α×α | dist p.1 p.2 ≤ f x}) :=
begin
refine ⟨λ s, uniformity_basis_dist.mem_iff.trans _⟩,
split,
{ rintros ⟨ε, ε₀, hε⟩,
rcases exists_between ε₀ with ⟨ε', hε'⟩,
rcases hf ε' hε'.1 with ⟨i, hi, H⟩,
exact ⟨i, hi, λ x (hx : _ ≤ _), hε $ lt_of_le_of_lt (le_trans hx H) hε'.2⟩ },
{ exact λ ⟨i, hi, H⟩, ⟨f i, hf₀ i hi, λ x (hx : _ < _), H (le_of_lt hx)⟩ }
end
/-- Contant size closed neighborhoods of the diagonal form a basis
of the uniformity filter. -/
theorem uniformity_basis_dist_le :
(𝓤 α).has_basis (λ ε : ℝ, 0 < ε) (λ ε, {p:α×α | dist p.1 p.2 ≤ ε}) :=
metric.mk_uniformity_basis_le (λ _, id) (λ ε ε₀, ⟨ε, ε₀, le_refl ε⟩)
theorem mem_uniformity_dist {s : set (α×α)} :
s ∈ 𝓤 α ↔ (∃ε>0, ∀{a b:α}, dist a b < ε → (a, b) ∈ s) :=
uniformity_basis_dist.mem_uniformity_iff
/-- A constant size neighborhood of the diagonal is an entourage. -/
theorem dist_mem_uniformity {ε:ℝ} (ε0 : 0 < ε) :
{p:α×α | dist p.1 p.2 < ε} ∈ 𝓤 α :=
mem_uniformity_dist.2 ⟨ε, ε0, λ a b, id⟩
theorem uniform_continuous_iff [metric_space β] {f : α → β} :
uniform_continuous f ↔ ∀ ε > 0, ∃ δ > 0,
∀{a b:α}, dist a b < δ → dist (f a) (f b) < ε :=
uniformity_basis_dist.uniform_continuous_iff uniformity_basis_dist
lemma uniform_continuous_on_iff [metric_space β] {f : α → β} {s : set α} :
uniform_continuous_on f s ↔ ∀ ε > 0, ∃ δ > 0, ∀ x y ∈ s, dist x y < δ → dist (f x) (f y) < ε :=
begin
dsimp [uniform_continuous_on],
rw (metric.uniformity_basis_dist.inf_principal (s.prod s)).tendsto_iff metric.uniformity_basis_dist,
simp only [and_imp, exists_prop, prod.forall, mem_inter_eq, gt_iff_lt, mem_set_of_eq, mem_prod],
finish,
end
theorem uniform_embedding_iff [metric_space β] {f : α → β} :
uniform_embedding f ↔ function.injective f ∧ uniform_continuous f ∧
∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, dist (f a) (f b) < ε → dist a b < δ :=
uniform_embedding_def'.trans $ and_congr iff.rfl $ and_congr iff.rfl
⟨λ H δ δ0, let ⟨t, tu, ht⟩ := H _ (dist_mem_uniformity δ0),
⟨ε, ε0, hε⟩ := mem_uniformity_dist.1 tu in
⟨ε, ε0, λ a b h, ht _ _ (hε h)⟩,
λ H s su, let ⟨δ, δ0, hδ⟩ := mem_uniformity_dist.1 su, ⟨ε, ε0, hε⟩ := H _ δ0 in
⟨_, dist_mem_uniformity ε0, λ a b h, hδ (hε h)⟩⟩
/-- A map between metric spaces is a uniform embedding if and only if the distance between `f x`
and `f y` is controlled in terms of the distance between `x` and `y` and conversely. -/
theorem uniform_embedding_iff' [metric_space β] {f : α → β} :
uniform_embedding f ↔
(∀ ε > 0, ∃ δ > 0, ∀ {a b : α}, dist a b < δ → dist (f a) (f b) < ε) ∧
(∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, dist (f a) (f b) < ε → dist a b < δ) :=
begin
split,
{ assume h,
exact ⟨uniform_continuous_iff.1 (uniform_embedding_iff.1 h).2.1,
(uniform_embedding_iff.1 h).2.2⟩ },
{ rintros ⟨h₁, h₂⟩,
refine uniform_embedding_iff.2 ⟨_, uniform_continuous_iff.2 h₁, h₂⟩,
assume x y hxy,
have : dist x y ≤ 0,
{ refine le_of_forall_lt' (λδ δpos, _),
rcases h₂ δ δpos with ⟨ε, εpos, hε⟩,
have : dist (f x) (f y) < ε, by simpa [hxy],
exact hε this },
simpa using this }
end
theorem totally_bounded_iff {s : set α} :
totally_bounded s ↔ ∀ ε > 0, ∃t : set α, finite t ∧ s ⊆ ⋃y∈t, ball y ε :=
⟨λ H ε ε0, H _ (dist_mem_uniformity ε0),
λ H r ru, let ⟨ε, ε0, hε⟩ := mem_uniformity_dist.1 ru,
⟨t, ft, h⟩ := H ε ε0 in
⟨t, ft, subset.trans h $ Union_subset_Union $ λ y, Union_subset_Union $ λ yt z, hε⟩⟩
/-- A metric space space is totally bounded if one can reconstruct up to any ε>0 any element of the
space from finitely many data. -/
lemma totally_bounded_of_finite_discretization {s : set α}
(H : ∀ε > (0 : ℝ), ∃ (β : Type u) [fintype β] (F : s → β),
∀x y, F x = F y → dist (x:α) y < ε) :
totally_bounded s :=
begin
cases s.eq_empty_or_nonempty with hs hs,
{ rw hs, exact totally_bounded_empty },
rcases hs with ⟨x0, hx0⟩,
haveI : inhabited s := ⟨⟨x0, hx0⟩⟩,
refine totally_bounded_iff.2 (λ ε ε0, _),
rcases H ε ε0 with ⟨β, fβ, F, hF⟩,
resetI,
let Finv := function.inv_fun F,
refine ⟨range (subtype.val ∘ Finv), finite_range _, λ x xs, _⟩,
let x' := Finv (F ⟨x, xs⟩),
have : F x' = F ⟨x, xs⟩ := function.inv_fun_eq ⟨⟨x, xs⟩, rfl⟩,
simp only [set.mem_Union, set.mem_range],
exact ⟨_, ⟨F ⟨x, xs⟩, rfl⟩, hF _ _ this.symm⟩
end
theorem finite_approx_of_totally_bounded {s : set α} (hs : totally_bounded s) :
∀ ε > 0, ∃ t ⊆ s, finite t ∧ s ⊆ ⋃y∈t, ball y ε :=
begin
intros ε ε_pos,
rw totally_bounded_iff_subset at hs,
exact hs _ (dist_mem_uniformity ε_pos),
end
/-- Expressing locally uniform convergence on a set using `dist`. -/
lemma tendsto_locally_uniformly_on_iff {ι : Type*} [topological_space β]
{F : ι → β → α} {f : β → α} {p : filter ι} {s : set β} :
tendsto_locally_uniformly_on F f p s ↔
∀ ε > 0, ∀ x ∈ s, ∃ t ∈ 𝓝[s] x, ∀ᶠ n in p, ∀ y ∈ t, dist (f y) (F n y) < ε :=
begin
refine ⟨λ H ε hε, H _ (dist_mem_uniformity hε), λ H u hu x hx, _⟩,
rcases mem_uniformity_dist.1 hu with ⟨ε, εpos, hε⟩,
rcases H ε εpos x hx with ⟨t, ht, Ht⟩,
exact ⟨t, ht, Ht.mono (λ n hs x hx, hε (hs x hx))⟩
end
/-- Expressing uniform convergence on a set using `dist`. -/
lemma tendsto_uniformly_on_iff {ι : Type*}
{F : ι → β → α} {f : β → α} {p : filter ι} {s : set β} :
tendsto_uniformly_on F f p s ↔ ∀ ε > 0, ∀ᶠ n in p, ∀ x ∈ s, dist (f x) (F n x) < ε :=
begin
refine ⟨λ H ε hε, H _ (dist_mem_uniformity hε), λ H u hu, _⟩,
rcases mem_uniformity_dist.1 hu with ⟨ε, εpos, hε⟩,
exact (H ε εpos).mono (λ n hs x hx, hε (hs x hx))
end
/-- Expressing locally uniform convergence using `dist`. -/
lemma tendsto_locally_uniformly_iff {ι : Type*} [topological_space β]
{F : ι → β → α} {f : β → α} {p : filter ι} :
tendsto_locally_uniformly F f p ↔
∀ ε > 0, ∀ (x : β), ∃ t ∈ 𝓝 x, ∀ᶠ n in p, ∀ y ∈ t, dist (f y) (F n y) < ε :=
by simp only [← tendsto_locally_uniformly_on_univ, tendsto_locally_uniformly_on_iff,
nhds_within_univ, mem_univ, forall_const, exists_prop]
/-- Expressing uniform convergence using `dist`. -/
lemma tendsto_uniformly_iff {ι : Type*}
{F : ι → β → α} {f : β → α} {p : filter ι} :
tendsto_uniformly F f p ↔ ∀ ε > 0, ∀ᶠ n in p, ∀ x, dist (f x) (F n x) < ε :=
by { rw [← tendsto_uniformly_on_univ, tendsto_uniformly_on_iff], simp }
protected lemma cauchy_iff {f : filter α} :
cauchy f ↔ ne_bot f ∧ ∀ ε > 0, ∃ t ∈ f, ∀ x y ∈ t, dist x y < ε :=
uniformity_basis_dist.cauchy_iff
theorem nhds_basis_ball : (𝓝 x).has_basis (λ ε:ℝ, 0 < ε) (ball x) :=
nhds_basis_uniformity uniformity_basis_dist
theorem mem_nhds_iff : s ∈ 𝓝 x ↔ ∃ε>0, ball x ε ⊆ s :=
nhds_basis_ball.mem_iff
theorem eventually_nhds_iff {p : α → Prop} :
(∀ᶠ y in 𝓝 x, p y) ↔ ∃ε>0, ∀ ⦃y⦄, dist y x < ε → p y :=
mem_nhds_iff
lemma eventually_nhds_iff_ball {p : α → Prop} :
(∀ᶠ y in 𝓝 x, p y) ↔ ∃ ε>0, ∀ y ∈ ball x ε, p y :=
mem_nhds_iff
theorem nhds_basis_closed_ball : (𝓝 x).has_basis (λ ε:ℝ, 0 < ε) (closed_ball x) :=
nhds_basis_uniformity uniformity_basis_dist_le
theorem nhds_basis_ball_inv_nat_succ :
(𝓝 x).has_basis (λ _, true) (λ n:ℕ, ball x (1 / (↑n+1))) :=
nhds_basis_uniformity uniformity_basis_dist_inv_nat_succ
theorem nhds_basis_ball_inv_nat_pos :
(𝓝 x).has_basis (λ n, 0<n) (λ n:ℕ, ball x (1 / ↑n)) :=
nhds_basis_uniformity uniformity_basis_dist_inv_nat_pos
theorem is_open_iff : is_open s ↔ ∀x∈s, ∃ε>0, ball x ε ⊆ s :=
by simp only [is_open_iff_mem_nhds, mem_nhds_iff]
theorem is_open_ball : is_open (ball x ε) :=
is_open_iff.2 $ λ y, exists_ball_subset_ball
theorem ball_mem_nhds (x : α) {ε : ℝ} (ε0 : 0 < ε) : ball x ε ∈ 𝓝 x :=
mem_nhds_sets is_open_ball (mem_ball_self ε0)
theorem closed_ball_mem_nhds (x : α) {ε : ℝ} (ε0 : 0 < ε) : closed_ball x ε ∈ 𝓝 x :=
mem_sets_of_superset (ball_mem_nhds x ε0) ball_subset_closed_ball
theorem nhds_within_basis_ball {s : set α} :
(𝓝[s] x).has_basis (λ ε:ℝ, 0 < ε) (λ ε, ball x ε ∩ s) :=
nhds_within_has_basis nhds_basis_ball s
theorem mem_nhds_within_iff {t : set α} : s ∈ 𝓝[t] x ↔ ∃ε>0, ball x ε ∩ t ⊆ s :=
nhds_within_basis_ball.mem_iff
theorem tendsto_nhds_within_nhds_within [metric_space β] {t : set β} {f : α → β} {a b} :
tendsto f (𝓝[s] a) (𝓝[t] b) ↔
∀ ε > 0, ∃ δ > 0, ∀{x:α}, x ∈ s → dist x a < δ → f x ∈ t ∧ dist (f x) b < ε :=
(nhds_within_basis_ball.tendsto_iff nhds_within_basis_ball).trans $
by simp only [inter_comm, mem_inter_iff, and_imp, mem_ball]
theorem tendsto_nhds_within_nhds [metric_space β] {f : α → β} {a b} :
tendsto f (𝓝[s] a) (𝓝 b) ↔
∀ ε > 0, ∃ δ > 0, ∀{x:α}, x ∈ s → dist x a < δ → dist (f x) b < ε :=
by { rw [← nhds_within_univ b, tendsto_nhds_within_nhds_within],
simp only [mem_univ, true_and] }
theorem tendsto_nhds_nhds [metric_space β] {f : α → β} {a b} :
tendsto f (𝓝 a) (𝓝 b) ↔
∀ ε > 0, ∃ δ > 0, ∀{x:α}, dist x a < δ → dist (f x) b < ε :=
nhds_basis_ball.tendsto_iff nhds_basis_ball
theorem continuous_at_iff [metric_space β] {f : α → β} {a : α} :
continuous_at f a ↔
∀ ε > 0, ∃ δ > 0, ∀{x:α}, dist x a < δ → dist (f x) (f a) < ε :=
by rw [continuous_at, tendsto_nhds_nhds]
theorem continuous_within_at_iff [metric_space β] {f : α → β} {a : α} {s : set α} :
continuous_within_at f s a ↔
∀ ε > 0, ∃ δ > 0, ∀{x:α}, x ∈ s → dist x a < δ → dist (f x) (f a) < ε :=
by rw [continuous_within_at, tendsto_nhds_within_nhds]
theorem continuous_on_iff [metric_space β] {f : α → β} {s : set α} :
continuous_on f s ↔
∀ (b ∈ s) (ε > 0), ∃ δ > 0, ∀a ∈ s, dist a b < δ → dist (f a) (f b) < ε :=
by simp [continuous_on, continuous_within_at_iff]
theorem continuous_iff [metric_space β] {f : α → β} :
continuous f ↔
∀b (ε > 0), ∃ δ > 0, ∀a, dist a b < δ → dist (f a) (f b) < ε :=
continuous_iff_continuous_at.trans $ forall_congr $ λ b, tendsto_nhds_nhds
theorem tendsto_nhds {f : filter β} {u : β → α} {a : α} :
tendsto u f (𝓝 a) ↔ ∀ ε > 0, ∀ᶠ x in f, dist (u x) a < ε :=
nhds_basis_ball.tendsto_right_iff
theorem continuous_at_iff' [topological_space β] {f : β → α} {b : β} :
continuous_at f b ↔
∀ ε > 0, ∀ᶠ x in 𝓝 b, dist (f x) (f b) < ε :=
by rw [continuous_at, tendsto_nhds]
theorem continuous_within_at_iff' [topological_space β] {f : β → α} {b : β} {s : set β} :
continuous_within_at f s b ↔
∀ ε > 0, ∀ᶠ x in 𝓝[s] b, dist (f x) (f b) < ε :=
by rw [continuous_within_at, tendsto_nhds]
theorem continuous_on_iff' [topological_space β] {f : β → α} {s : set β} :
continuous_on f s ↔
∀ (b ∈ s) (ε > 0), ∀ᶠ x in 𝓝[s] b, dist (f x) (f b) < ε :=
by simp [continuous_on, continuous_within_at_iff']
theorem continuous_iff' [topological_space β] {f : β → α} :
continuous f ↔ ∀a (ε > 0), ∀ᶠ x in 𝓝 a, dist (f x) (f a) < ε :=
continuous_iff_continuous_at.trans $ forall_congr $ λ b, tendsto_nhds
theorem tendsto_at_top [nonempty β] [semilattice_sup β] {u : β → α} {a : α} :
tendsto u at_top (𝓝 a) ↔ ∀ε>0, ∃N, ∀n≥N, dist (u n) a < ε :=
(at_top_basis.tendsto_iff nhds_basis_ball).trans $
by { simp only [exists_prop, true_and], refl }
lemma is_open_singleton_iff {X : Type*} [metric_space X] {x : X} :
is_open ({x} : set X) ↔ ∃ ε > 0, ∀ y, dist y x < ε → y = x :=
by simp [is_open_iff, subset_singleton_iff, mem_ball]
end metric
open metric
@[priority 100] -- see Note [lower instance priority]
instance metric_space.to_separated : separated_space α :=
separated_def.2 $ λ x y h, eq_of_forall_dist_le $
λ ε ε0, le_of_lt (h _ (dist_mem_uniformity ε0))
/-Instantiate a metric space as an emetric space. Before we can state the instance,
we need to show that the uniform structure coming from the edistance and the
distance coincide. -/
/-- Expressing the uniformity in terms of `edist` -/
protected lemma metric.uniformity_basis_edist :
(𝓤 α).has_basis (λ ε:ennreal, 0 < ε) (λ ε, {p | edist p.1 p.2 < ε}) :=
⟨begin
intro t,
refine mem_uniformity_dist.trans ⟨_, _⟩; rintro ⟨ε, ε0, Hε⟩,
{ use [ennreal.of_real ε, ennreal.of_real_pos.2 ε0],
rintros ⟨a, b⟩,
simp only [edist_dist, ennreal.of_real_lt_of_real_iff ε0],
exact Hε },
{ rcases ennreal.lt_iff_exists_real_btwn.1 ε0 with ⟨ε', _, ε0', hε⟩,
rw [ennreal.of_real_pos] at ε0',
refine ⟨ε', ε0', λ a b h, Hε (lt_trans _ hε)⟩,
rwa [edist_dist, ennreal.of_real_lt_of_real_iff ε0'] }
end⟩
theorem metric.uniformity_edist : 𝓤 α = (⨅ ε>0, 𝓟 {p:α×α | edist p.1 p.2 < ε}) :=
metric.uniformity_basis_edist.eq_binfi
/-- A metric space induces an emetric space -/
@[priority 100] -- see Note [lower instance priority]
instance metric_space.to_emetric_space : emetric_space α :=
{ edist := edist,
edist_self := by simp [edist_dist],
eq_of_edist_eq_zero := assume x y h, by simpa [edist_dist] using h,
edist_comm := by simp only [edist_dist, dist_comm]; simp,
edist_triangle := assume x y z, begin
simp only [edist_dist, ← ennreal.of_real_add, dist_nonneg],
rw ennreal.of_real_le_of_real_iff _,
{ exact dist_triangle _ _ _ },
{ simpa using add_le_add (dist_nonneg : 0 ≤ dist x y) dist_nonneg }
end,
uniformity_edist := metric.uniformity_edist,
..‹metric_space α› }
/-- Balls defined using the distance or the edistance coincide -/
lemma metric.emetric_ball {x : α} {ε : ℝ} : emetric.ball x (ennreal.of_real ε) = ball x ε :=
begin
ext y,
simp only [emetric.mem_ball, mem_ball, edist_dist],
exact ennreal.of_real_lt_of_real_iff_of_nonneg dist_nonneg
end
/-- Balls defined using the distance or the edistance coincide -/
lemma metric.emetric_ball_nnreal {x : α} {ε : nnreal} : emetric.ball x ε = ball x ε :=
by { convert metric.emetric_ball, simp }
/-- Closed balls defined using the distance or the edistance coincide -/
lemma metric.emetric_closed_ball {x : α} {ε : ℝ} (h : 0 ≤ ε) :
emetric.closed_ball x (ennreal.of_real ε) = closed_ball x ε :=
by ext y; simp [edist_dist]; rw ennreal.of_real_le_of_real_iff h
/-- Closed balls defined using the distance or the edistance coincide -/
lemma metric.emetric_closed_ball_nnreal {x : α} {ε : nnreal} :
emetric.closed_ball x ε = closed_ball x ε :=
by { convert metric.emetric_closed_ball ε.2, simp }
/-- Build a new metric space from an old one where the bundled uniform structure is provably
(but typically non-definitionaly) equal to some given uniform structure.
See Note [forgetful inheritance].
-/
def metric_space.replace_uniformity {α} [U : uniform_space α] (m : metric_space α)
(H : @uniformity _ U = @uniformity _ emetric_space.to_uniform_space') :
metric_space α :=
{ dist := @dist _ m.to_has_dist,
dist_self := dist_self,
eq_of_dist_eq_zero := @eq_of_dist_eq_zero _ _,
dist_comm := dist_comm,
dist_triangle := dist_triangle,
edist := edist,
edist_dist := edist_dist,
to_uniform_space := U,
uniformity_dist := H.trans metric_space.uniformity_dist }
/-- One gets a metric space from an emetric space if the edistance
is everywhere finite, by pushing the edistance to reals. We set it up so that the edist and the
uniformity are defeq in the metric space and the emetric space. In this definition, the distance
is given separately, to be able to prescribe some expression which is not defeq to the push-forward
of the edistance to reals. -/
def emetric_space.to_metric_space_of_dist {α : Type u} [e : emetric_space α]
(dist : α → α → ℝ)
(edist_ne_top : ∀x y: α, edist x y ≠ ⊤)
(h : ∀x y, dist x y = ennreal.to_real (edist x y)) :
metric_space α :=
let m : metric_space α :=
{ dist := dist,
eq_of_dist_eq_zero := λx y hxy, by simpa [h, ennreal.to_real_eq_zero_iff, edist_ne_top x y] using hxy,
dist_self := λx, by simp [h],
dist_comm := λx y, by simp [h, emetric_space.edist_comm],
dist_triangle := λx y z, begin
simp only [h],
rw [← ennreal.to_real_add (edist_ne_top _ _) (edist_ne_top _ _),
ennreal.to_real_le_to_real (edist_ne_top _ _)],
{ exact edist_triangle _ _ _ },
{ simp [ennreal.add_eq_top, edist_ne_top] }
end,
edist := λx y, edist x y,
edist_dist := λx y, by simp [h, ennreal.of_real_to_real, edist_ne_top] } in
m.replace_uniformity $ by { rw [uniformity_edist, metric.uniformity_edist], refl }
/-- One gets a metric space from an emetric space if the edistance
is everywhere finite, by pushing the edistance to reals. We set it up so that the edist and the
uniformity are defeq in the metric space and the emetric space. -/
def emetric_space.to_metric_space {α : Type u} [e : emetric_space α] (h : ∀x y: α, edist x y ≠ ⊤) :
metric_space α :=
emetric_space.to_metric_space_of_dist (λx y, ennreal.to_real (edist x y)) h (λx y, rfl)
/-- A very useful criterion to show that a space is complete is to show that all sequences
which satisfy a bound of the form `dist (u n) (u m) < B N` for all `n m ≥ N` are
converging. This is often applied for `B N = 2^{-N}`, i.e., with a very fast convergence to
`0`, which makes it possible to use arguments of converging series, while this is impossible
to do in general for arbitrary Cauchy sequences. -/
theorem metric.complete_of_convergent_controlled_sequences (B : ℕ → real) (hB : ∀n, 0 < B n)
(H : ∀u : ℕ → α, (∀N n m : ℕ, N ≤ n → N ≤ m → dist (u n) (u m) < B N) → ∃x, tendsto u at_top (𝓝 x)) :
complete_space α :=
begin
-- this follows from the same criterion in emetric spaces. We just need to translate
-- the convergence assumption from `dist` to `edist`
apply emetric.complete_of_convergent_controlled_sequences (λn, ennreal.of_real (B n)),
{ simp [hB] },
{ assume u Hu,
apply H,
assume N n m hn hm,
rw [← ennreal.of_real_lt_of_real_iff (hB N), ← edist_dist],
exact Hu N n m hn hm }
end
theorem metric.complete_of_cauchy_seq_tendsto :
(∀ u : ℕ → α, cauchy_seq u → ∃a, tendsto u at_top (𝓝 a)) → complete_space α :=
emetric.complete_of_cauchy_seq_tendsto
section real
/-- Instantiate the reals as a metric space. -/
instance real.metric_space : metric_space ℝ :=
{ dist := λx y, abs (x - y),
dist_self := by simp [abs_zero],
eq_of_dist_eq_zero := by simp [sub_eq_zero],
dist_comm := assume x y, abs_sub _ _,
dist_triangle := assume x y z, abs_sub_le _ _ _ }
theorem real.dist_eq (x y : ℝ) : dist x y = abs (x - y) := rfl
theorem real.dist_0_eq_abs (x : ℝ) : dist x 0 = abs x :=
by simp [real.dist_eq]
instance : order_topology ℝ :=
order_topology_of_nhds_abs $ λ x, begin
simp only [show ∀ r, {b : ℝ | abs (x - b) < r} = ball x r,
by simp [abs_sub, ball, real.dist_eq]],
apply le_antisymm,
{ simp [le_infi_iff],
exact λ ε ε0, mem_nhds_sets (is_open_ball) (mem_ball_self ε0) },
{ intros s h,
rcases mem_nhds_iff.1 h with ⟨ε, ε0, ss⟩,
exact mem_infi_sets _ (mem_infi_sets ε0 (mem_principal_sets.2 ss)) },
end
lemma closed_ball_Icc {x r : ℝ} : closed_ball x r = Icc (x-r) (x+r) :=
by ext y; rw [mem_closed_ball, dist_comm, real.dist_eq,
abs_sub_le_iff, mem_Icc, ← sub_le_iff_le_add', sub_le]
/-- Special case of the sandwich theorem; see `tendsto_of_tendsto_of_tendsto_of_le_of_le'` for the
general case. -/
lemma squeeze_zero' {α} {f g : α → ℝ} {t₀ : filter α} (hf : ∀ᶠ t in t₀, 0 ≤ f t)
(hft : ∀ᶠ t in t₀, f t ≤ g t) (g0 : tendsto g t₀ (nhds 0)) : tendsto f t₀ (𝓝 0) :=
tendsto_of_tendsto_of_tendsto_of_le_of_le' tendsto_const_nhds g0 hf hft
/-- Special case of the sandwich theorem; see `tendsto_of_tendsto_of_tendsto_of_le_of_le`
and `tendsto_of_tendsto_of_tendsto_of_le_of_le'` for the general case. -/
lemma squeeze_zero {α} {f g : α → ℝ} {t₀ : filter α} (hf : ∀t, 0 ≤ f t) (hft : ∀t, f t ≤ g t)
(g0 : tendsto g t₀ (𝓝 0)) : tendsto f t₀ (𝓝 0) :=
squeeze_zero' (eventually_of_forall hf) (eventually_of_forall hft) g0
theorem metric.uniformity_eq_comap_nhds_zero :
𝓤 α = comap (λp:α×α, dist p.1 p.2) (𝓝 (0 : ℝ)) :=
by { ext s,
simp [mem_uniformity_dist, (nhds_basis_ball.comap _).mem_iff, subset_def, real.dist_0_eq_abs] }
lemma cauchy_seq_iff_tendsto_dist_at_top_0 [nonempty β] [semilattice_sup β] {u : β → α} :
cauchy_seq u ↔ tendsto (λ (n : β × β), dist (u n.1) (u n.2)) at_top (𝓝 0) :=
by rw [cauchy_seq_iff_tendsto, metric.uniformity_eq_comap_nhds_zero, tendsto_comap_iff,
prod.map_def]
lemma tendsto_uniformity_iff_dist_tendsto_zero {ι : Type*} {f : ι → α × α} {p : filter ι} :
tendsto f p (𝓤 α) ↔ tendsto (λ x, dist (f x).1 (f x).2) p (𝓝 0) :=
by rw [metric.uniformity_eq_comap_nhds_zero, tendsto_comap_iff]
lemma filter.tendsto.congr_dist {ι : Type*} {f₁ f₂ : ι → α} {p : filter ι} {a : α}
(h₁ : tendsto f₁ p (𝓝 a)) (h : tendsto (λ x, dist (f₁ x) (f₂ x)) p (𝓝 0)) :
tendsto f₂ p (𝓝 a) :=
h₁.congr_uniformity $ tendsto_uniformity_iff_dist_tendsto_zero.2 h
alias filter.tendsto.congr_dist ← tendsto_of_tendsto_of_dist
lemma tendsto_iff_of_dist {ι : Type*} {f₁ f₂ : ι → α} {p : filter ι} {a : α}
(h : tendsto (λ x, dist (f₁ x) (f₂ x)) p (𝓝 0)) :
tendsto f₁ p (𝓝 a) ↔ tendsto f₂ p (𝓝 a) :=
uniform.tendsto_congr $ tendsto_uniformity_iff_dist_tendsto_zero.2 h
end real
section cauchy_seq
variables [nonempty β] [semilattice_sup β]
/-- In a metric space, Cauchy sequences are characterized by the fact that, eventually,
the distance between its elements is arbitrarily small -/
@[nolint ge_or_gt] -- see Note [nolint_ge]
theorem metric.cauchy_seq_iff {u : β → α} :
cauchy_seq u ↔ ∀ε>0, ∃N, ∀m n≥N, dist (u m) (u n) < ε :=
uniformity_basis_dist.cauchy_seq_iff
/-- A variation around the metric characterization of Cauchy sequences -/
theorem metric.cauchy_seq_iff' {u : β → α} :
cauchy_seq u ↔ ∀ε>0, ∃N, ∀n≥N, dist (u n) (u N) < ε :=
uniformity_basis_dist.cauchy_seq_iff'
/-- If the distance between `s n` and `s m`, `n, m ≥ N` is bounded above by `b N`
and `b` converges to zero, then `s` is a Cauchy sequence. -/
lemma cauchy_seq_of_le_tendsto_0 {s : β → α} (b : β → ℝ)
(h : ∀ n m N : β, N ≤ n → N ≤ m → dist (s n) (s m) ≤ b N) (h₀ : tendsto b at_top (nhds 0)) :
cauchy_seq s :=
metric.cauchy_seq_iff.2 $ λ ε ε0,
(metric.tendsto_at_top.1 h₀ ε ε0).imp $ λ N hN m n hm hn,
calc dist (s m) (s n) ≤ b N : h m n N hm hn
... ≤ abs (b N) : le_abs_self _
... = dist (b N) 0 : by rw real.dist_0_eq_abs; refl
... < ε : (hN _ (le_refl N))
/-- A Cauchy sequence on the natural numbers is bounded. -/
theorem cauchy_seq_bdd {u : ℕ → α} (hu : cauchy_seq u) :
∃ R > 0, ∀ m n, dist (u m) (u n) < R :=
begin
rcases metric.cauchy_seq_iff'.1 hu 1 zero_lt_one with ⟨N, hN⟩,
suffices : ∃ R > 0, ∀ n, dist (u n) (u N) < R,
{ rcases this with ⟨R, R0, H⟩,
exact ⟨_, add_pos R0 R0, λ m n,
lt_of_le_of_lt (dist_triangle_right _ _ _) (add_lt_add (H m) (H n))⟩ },
let R := finset.sup (finset.range N) (λ n, nndist (u n) (u N)),
refine ⟨↑R + 1, add_pos_of_nonneg_of_pos R.2 zero_lt_one, λ n, _⟩,
cases le_or_lt N n,
{ exact lt_of_lt_of_le (hN _ h) (le_add_of_nonneg_left R.2) },
{ have : _ ≤ R := finset.le_sup (finset.mem_range.2 h),
exact lt_of_le_of_lt this (lt_add_of_pos_right _ zero_lt_one) }
end
/-- Yet another metric characterization of Cauchy sequences on integers. This one is often the
most efficient. -/
lemma cauchy_seq_iff_le_tendsto_0 {s : ℕ → α} : cauchy_seq s ↔ ∃ b : ℕ → ℝ,
(∀ n, 0 ≤ b n) ∧
(∀ n m N : ℕ, N ≤ n → N ≤ m → dist (s n) (s m) ≤ b N) ∧
tendsto b at_top (𝓝 0) :=
⟨λ hs, begin
/- `s` is a Cauchy sequence. The sequence `b` will be constructed by taking
the supremum of the distances between `s n` and `s m` for `n m ≥ N`.
First, we prove that all these distances are bounded, as otherwise the Sup
would not make sense. -/
let S := λ N, (λ(p : ℕ × ℕ), dist (s p.1) (s p.2)) '' {p | p.1 ≥ N ∧ p.2 ≥ N},
have hS : ∀ N, ∃ x, ∀ y ∈ S N, y ≤ x,
{ rcases cauchy_seq_bdd hs with ⟨R, R0, hR⟩,
refine λ N, ⟨R, _⟩, rintro _ ⟨⟨m, n⟩, _, rfl⟩,
exact le_of_lt (hR m n) },
have bdd : bdd_above (range (λ(p : ℕ × ℕ), dist (s p.1) (s p.2))),
{ rcases cauchy_seq_bdd hs with ⟨R, R0, hR⟩,
use R, rintro _ ⟨⟨m, n⟩, rfl⟩, exact le_of_lt (hR m n) },
-- Prove that it bounds the distances of points in the Cauchy sequence
have ub : ∀ m n N, N ≤ m → N ≤ n → dist (s m) (s n) ≤ Sup (S N) :=
λ m n N hm hn, real.le_Sup _ (hS N) ⟨⟨_, _⟩, ⟨hm, hn⟩, rfl⟩,
have S0m : ∀ n, (0:ℝ) ∈ S n := λ n, ⟨⟨n, n⟩, ⟨le_refl _, le_refl _⟩, dist_self _⟩,
have S0 := λ n, real.le_Sup _ (hS n) (S0m n),
-- Prove that it tends to `0`, by using the Cauchy property of `s`
refine ⟨λ N, Sup (S N), S0, ub, metric.tendsto_at_top.2 (λ ε ε0, _)⟩,
refine (metric.cauchy_seq_iff.1 hs (ε/2) (half_pos ε0)).imp (λ N hN n hn, _),
rw [real.dist_0_eq_abs, abs_of_nonneg (S0 n)],
refine lt_of_le_of_lt (real.Sup_le_ub _ ⟨_, S0m _⟩ _) (half_lt_self ε0),
rintro _ ⟨⟨m', n'⟩, ⟨hm', hn'⟩, rfl⟩,
exact le_of_lt (hN _ _ (le_trans hn hm') (le_trans hn hn'))
end,
λ ⟨b, _, b_bound, b_lim⟩, cauchy_seq_of_le_tendsto_0 b b_bound b_lim⟩
end cauchy_seq
/-- Metric space structure pulled back by an injective function. Injectivity is necessary to
ensure that `dist x y = 0` only if `x = y`. -/
def metric_space.induced {α β} (f : α → β) (hf : function.injective f)
(m : metric_space β) : metric_space α :=
{ dist := λ x y, dist (f x) (f y),
dist_self := λ x, dist_self _,
eq_of_dist_eq_zero := λ x y h, hf (dist_eq_zero.1 h),
dist_comm := λ x y, dist_comm _ _,
dist_triangle := λ x y z, dist_triangle _ _ _,
edist := λ x y, edist (f x) (f y),
edist_dist := λ x y, edist_dist _ _,
to_uniform_space := uniform_space.comap f m.to_uniform_space,
uniformity_dist := begin
apply @uniformity_dist_of_mem_uniformity _ _ _ _ _ (λ x y, dist (f x) (f y)),
refine λ s, mem_comap_sets.trans _,
split; intro H,
{ rcases H with ⟨r, ru, rs⟩,
rcases mem_uniformity_dist.1 ru with ⟨ε, ε0, hε⟩,
refine ⟨ε, ε0, λ a b h, rs (hε _)⟩, exact h },
{ rcases H with ⟨ε, ε0, hε⟩,
exact ⟨_, dist_mem_uniformity ε0, λ ⟨a, b⟩, hε⟩ }
end }
instance subtype.metric_space {α : Type*} {p : α → Prop} [t : metric_space α] :
metric_space (subtype p) :=
metric_space.induced coe (λ x y, subtype.ext) t
theorem subtype.dist_eq {p : α → Prop} (x y : subtype p) : dist x y = dist (x : α) y := rfl
section nnreal
instance : metric_space nnreal := by unfold nnreal; apply_instance
lemma nnreal.dist_eq (a b : nnreal) : dist a b = abs ((a:ℝ) - b) := rfl
lemma nnreal.nndist_eq (a b : nnreal) :
nndist a b = max (a - b) (b - a) :=
begin
wlog h : a ≤ b,
{ apply nnreal.coe_eq.1,
rw [nnreal.sub_eq_zero h, max_eq_right (zero_le $ b - a), ← dist_nndist, nnreal.dist_eq,
nnreal.coe_sub h, abs, neg_sub],
apply max_eq_right,
linarith [nnreal.coe_le_coe.2 h] },
rwa [nndist_comm, max_comm]
end
end nnreal
section prod
instance prod.metric_space_max [metric_space β] : metric_space (α × β) :=
{ dist := λ x y, max (dist x.1 y.1) (dist x.2 y.2),
dist_self := λ x, by simp,
eq_of_dist_eq_zero := λ x y h, begin
cases max_le_iff.1 (le_of_eq h) with h₁ h₂,
exact prod.ext_iff.2 ⟨dist_le_zero.1 h₁, dist_le_zero.1 h₂⟩
end,
dist_comm := λ x y, by simp [dist_comm],
dist_triangle := λ x y z, max_le
(le_trans (dist_triangle _ _ _) (add_le_add (le_max_left _ _) (le_max_left _ _)))
(le_trans (dist_triangle _ _ _) (add_le_add (le_max_right _ _) (le_max_right _ _))),
edist := λ x y, max (edist x.1 y.1) (edist x.2 y.2),
edist_dist := assume x y, begin
have : monotone ennreal.of_real := assume x y h, ennreal.of_real_le_of_real h,
rw [edist_dist, edist_dist, ← this.map_max]
end,
uniformity_dist := begin
refine uniformity_prod.trans _,
simp only [uniformity_basis_dist.eq_binfi, comap_infi],
rw ← infi_inf_eq, congr, funext,
rw ← infi_inf_eq, congr, funext,
simp [inf_principal, ext_iff, max_lt_iff]
end,
to_uniform_space := prod.uniform_space }
lemma prod.dist_eq [metric_space β] {x y : α × β} :
dist x y = max (dist x.1 y.1) (dist x.2 y.2) := rfl
end prod
theorem uniform_continuous_dist : uniform_continuous (λp:α×α, dist p.1 p.2) :=
metric.uniform_continuous_iff.2 (λ ε ε0, ⟨ε/2, half_pos ε0,
begin
suffices,
{ intros p q h, cases p with p₁ p₂, cases q with q₁ q₂,
cases max_lt_iff.1 h with h₁ h₂, clear h,
dsimp at h₁ h₂ ⊢,
rw real.dist_eq,
refine abs_sub_lt_iff.2 ⟨_, _⟩,
{ revert p₁ p₂ q₁ q₂ h₁ h₂, exact this },
{ apply this; rwa dist_comm } },
intros p₁ p₂ q₁ q₂ h₁ h₂,
have := add_lt_add
(abs_sub_lt_iff.1 (lt_of_le_of_lt (abs_dist_sub_le p₁ q₁ p₂) h₁)).1
(abs_sub_lt_iff.1 (lt_of_le_of_lt (abs_dist_sub_le p₂ q₂ q₁) h₂)).1,
rwa [add_halves, dist_comm p₂, sub_add_sub_cancel, dist_comm q₂] at this
end⟩)
theorem uniform_continuous.dist [uniform_space β] {f g : β → α}
(hf : uniform_continuous f) (hg : uniform_continuous g) :
uniform_continuous (λb, dist (f b) (g b)) :=
uniform_continuous_dist.comp (hf.prod_mk hg)
theorem continuous_dist : continuous (λp:α×α, dist p.1 p.2) :=
uniform_continuous_dist.continuous
theorem continuous.dist [topological_space β] {f g : β → α}
(hf : continuous f) (hg : continuous g) : continuous (λb, dist (f b) (g b)) :=
continuous_dist.comp (hf.prod_mk hg : _)
theorem filter.tendsto.dist {f g : β → α} {x : filter β} {a b : α}
(hf : tendsto f x (𝓝 a)) (hg : tendsto g x (𝓝 b)) :
tendsto (λx, dist (f x) (g x)) x (𝓝 (dist a b)) :=
(continuous_dist.tendsto (a, b)).comp (hf.prod_mk_nhds hg)
lemma nhds_comap_dist (a : α) : (𝓝 (0 : ℝ)).comap (λa', dist a' a) = 𝓝 a :=
by simp only [@nhds_eq_comap_uniformity α, metric.uniformity_eq_comap_nhds_zero,
comap_comap, (∘), dist_comm]
lemma tendsto_iff_dist_tendsto_zero {f : β → α} {x : filter β} {a : α} :
(tendsto f x (𝓝 a)) ↔ (tendsto (λb, dist (f b) a) x (𝓝 0)) :=
by rw [← nhds_comap_dist a, tendsto_comap_iff]
lemma uniform_continuous_nndist : uniform_continuous (λp:α×α, nndist p.1 p.2) :=
uniform_continuous_subtype_mk uniform_continuous_dist _
lemma uniform_continuous.nndist [uniform_space β] {f g : β → α} (hf : uniform_continuous f)
(hg : uniform_continuous g) :
uniform_continuous (λ b, nndist (f b) (g b)) :=
uniform_continuous_nndist.comp (hf.prod_mk hg)
lemma continuous_nndist : continuous (λp:α×α, nndist p.1 p.2) :=
uniform_continuous_nndist.continuous
lemma continuous.nndist [topological_space β] {f g : β → α}
(hf : continuous f) (hg : continuous g) : continuous (λb, nndist (f b) (g b)) :=
continuous_nndist.comp (hf.prod_mk hg : _)
theorem filter.tendsto.nndist {f g : β → α} {x : filter β} {a b : α}
(hf : tendsto f x (𝓝 a)) (hg : tendsto g x (𝓝 b)) :
tendsto (λx, nndist (f x) (g x)) x (𝓝 (nndist a b)) :=
(continuous_nndist.tendsto (a, b)).comp (hf.prod_mk_nhds hg)
namespace metric
variables {x y z : α} {ε ε₁ ε₂ : ℝ} {s : set α}
theorem is_closed_ball : is_closed (closed_ball x ε) :=
is_closed_le (continuous_id.dist continuous_const) continuous_const
lemma is_closed_sphere : is_closed (sphere x ε) :=
is_closed_eq (continuous_id.dist continuous_const) continuous_const
@[simp] theorem closure_closed_ball : closure (closed_ball x ε) = closed_ball x ε :=
is_closed_ball.closure_eq
theorem closure_ball_subset_closed_ball : closure (ball x ε) ⊆ closed_ball x ε :=
closure_minimal ball_subset_closed_ball is_closed_ball
theorem frontier_ball_subset_sphere : frontier (ball x ε) ⊆ sphere x ε :=
frontier_lt_subset_eq (continuous_id.dist continuous_const) continuous_const
theorem frontier_closed_ball_subset_sphere : frontier (closed_ball x ε) ⊆ sphere x ε :=
frontier_le_subset_eq (continuous_id.dist continuous_const) continuous_const
theorem ball_subset_interior_closed_ball : ball x ε ⊆ interior (closed_ball x ε) :=
interior_maximal ball_subset_closed_ball is_open_ball
/-- ε-characterization of the closure in metric spaces-/
theorem mem_closure_iff {α : Type u} [metric_space α] {s : set α} {a : α} :
a ∈ closure s ↔ ∀ε>0, ∃b ∈ s, dist a b < ε :=
(mem_closure_iff_nhds_basis nhds_basis_ball).trans $
by simp only [mem_ball, dist_comm]
lemma mem_closure_range_iff {α : Type u} [metric_space α] {e : β → α} {a : α} :
a ∈ closure (range e) ↔ ∀ε>0, ∃ k : β, dist a (e k) < ε :=
by simp only [mem_closure_iff, exists_range_iff]
lemma mem_closure_range_iff_nat {α : Type u} [metric_space α] {e : β → α} {a : α} :
a ∈ closure (range e) ↔ ∀n : ℕ, ∃ k : β, dist a (e k) < 1 / ((n : ℝ) + 1) :=
(mem_closure_iff_nhds_basis nhds_basis_ball_inv_nat_succ).trans $
by simp only [mem_ball, dist_comm, exists_range_iff, forall_const]
theorem mem_of_closed' {α : Type u} [metric_space α] {s : set α} (hs : is_closed s)
{a : α} : a ∈ s ↔ ∀ε>0, ∃b ∈ s, dist a b < ε :=
by simpa only [hs.closure_eq] using @mem_closure_iff _ _ s a
end metric
section pi
open finset
variables {π : β → Type*} [fintype β] [∀b, metric_space (π b)]
/-- A finite product of metric spaces is a metric space, with the sup distance. -/
instance metric_space_pi : metric_space (Πb, π b) :=
begin
/- we construct the instance from the emetric space instance to avoid checking again that the
uniformity is the same as the product uniformity, but we register nevertheless a nice formula
for the distance -/
refine emetric_space.to_metric_space_of_dist
(λf g, ((sup univ (λb, nndist (f b) (g b)) : nnreal) : ℝ)) _ _,
show ∀ (x y : Π (b : β), π b), edist x y ≠ ⊤,
{ assume x y,
rw ← lt_top_iff_ne_top,
have : (⊥ : ennreal) < ⊤ := ennreal.coe_lt_top,
simp [edist_pi_def, finset.sup_lt_iff this, edist_lt_top] },
show ∀ (x y : Π (b : β), π b), ↑(sup univ (λ (b : β), nndist (x b) (y b))) =
ennreal.to_real (sup univ (λ (b : β), edist (x b) (y b))),
{ assume x y,
simp only [edist_nndist],
norm_cast }
end
lemma nndist_pi_def (f g : Πb, π b) : nndist f g = sup univ (λb, nndist (f b) (g b)) :=
subtype.eta _ _
lemma dist_pi_def (f g : Πb, π b) :
dist f g = (sup univ (λb, nndist (f b) (g b)) : nnreal) := rfl
lemma dist_pi_lt_iff {f g : Πb, π b} {r : ℝ} (hr : 0 < r) :
dist f g < r ↔ ∀b, dist (f b) (g b) < r :=
begin
lift r to nnreal using hr.le,
simp [dist_pi_def, finset.sup_lt_iff (show ⊥ < r, from hr)],
end
lemma dist_pi_le_iff {f g : Πb, π b} {r : ℝ} (hr : 0 ≤ r) :
dist f g ≤ r ↔ ∀b, dist (f b) (g b) ≤ r :=
begin
lift r to nnreal using hr,
simp [nndist_pi_def]
end
lemma nndist_le_pi_nndist (f g : Πb, π b) (b : β) : nndist (f b) (g b) ≤ nndist f g :=
by { rw [nndist_pi_def], exact finset.le_sup (finset.mem_univ b) }
lemma dist_le_pi_dist (f g : Πb, π b) (b : β) : dist (f b) (g b) ≤ dist f g :=
by simp only [dist_nndist, nnreal.coe_le_coe, nndist_le_pi_nndist f g b]
/-- An open ball in a product space is a product of open balls. The assumption `0 < r`
is necessary for the case of the empty product. -/
lemma ball_pi (x : Πb, π b) {r : ℝ} (hr : 0 < r) :
ball x r = { y | ∀b, y b ∈ ball (x b) r } :=
by { ext p, simp [dist_pi_lt_iff hr] }
/-- A closed ball in a product space is a product of closed balls. The assumption `0 ≤ r`
is necessary for the case of the empty product. -/
lemma closed_ball_pi (x : Πb, π b) {r : ℝ} (hr : 0 ≤ r) :
closed_ball x r = { y | ∀b, y b ∈ closed_ball (x b) r } :=
by { ext p, simp [dist_pi_le_iff hr] }
end pi
section compact
/-- Any compact set in a metric space can be covered by finitely many balls of a given positive
radius -/
lemma finite_cover_balls_of_compact {α : Type u} [metric_space α] {s : set α}
(hs : is_compact s) {e : ℝ} (he : 0 < e) :
∃t ⊆ s, finite t ∧ s ⊆ ⋃x∈t, ball x e :=
begin
apply hs.elim_finite_subcover_image,
{ simp [is_open_ball] },
{ intros x xs,
simp,
exact ⟨x, ⟨xs, by simpa⟩⟩ }
end
alias finite_cover_balls_of_compact ← is_compact.finite_cover_balls
end compact
section proper_space
open metric
/-- A metric space is proper if all closed balls are compact. -/
class proper_space (α : Type u) [metric_space α] : Prop :=
(compact_ball : ∀x:α, ∀r, is_compact (closed_ball x r))
lemma tendsto_dist_right_cocompact_at_top [proper_space α] (x : α) :
tendsto (λ y, dist y x) (cocompact α) at_top :=
(has_basis_cocompact.tendsto_iff at_top_basis).2 $ λ r hr,
⟨closed_ball x r, proper_space.compact_ball x r, λ y hy, (not_le.1 $ mt mem_closed_ball.2 hy).le⟩
lemma tendsto_dist_left_cocompact_at_top [proper_space α] (x : α) :
tendsto (dist x) (cocompact α) at_top :=
by simpa only [dist_comm] using tendsto_dist_right_cocompact_at_top x
/-- If all closed balls of large enough radius are compact, then the space is proper. Especially
useful when the lower bound for the radius is 0. -/
lemma proper_space_of_compact_closed_ball_of_le
(R : ℝ) (h : ∀x:α, ∀r, R ≤ r → is_compact (closed_ball x r)) :
proper_space α :=
⟨begin
assume x r,
by_cases hr : R ≤ r,
{ exact h x r hr },
{ have : closed_ball x r = closed_ball x R ∩ closed_ball x r,
{ symmetry,
apply inter_eq_self_of_subset_right,
exact closed_ball_subset_closed_ball (le_of_lt (not_le.1 hr)) },
rw this,
exact (h x R (le_refl _)).inter_right is_closed_ball }
end⟩
/- A compact metric space is proper -/
@[priority 100] -- see Note [lower instance priority]
instance proper_of_compact [compact_space α] : proper_space α :=
⟨assume x r, is_closed_ball.compact⟩
/-- A proper space is locally compact -/
@[priority 100] -- see Note [lower instance priority]
instance locally_compact_of_proper [proper_space α] :
locally_compact_space α :=
begin
apply locally_compact_of_compact_nhds,
intros x,
existsi closed_ball x 1,
split,
{ apply mem_nhds_iff.2,
existsi (1 : ℝ),
simp,
exact ⟨zero_lt_one, ball_subset_closed_ball⟩ },
{ apply proper_space.compact_ball }
end
/-- A proper space is complete -/
@[priority 100] -- see Note [lower instance priority]
instance complete_of_proper [proper_space α] : complete_space α :=
⟨begin
intros f hf,
/- We want to show that the Cauchy filter `f` is converging. It suffices to find a closed
ball (therefore compact by properness) where it is nontrivial. -/
have A : ∃ t ∈ f, ∀ x y ∈ t, dist x y < 1 := (metric.cauchy_iff.1 hf).2 1 zero_lt_one,
rcases A with ⟨t, ⟨t_fset, ht⟩⟩,
rcases hf.1.nonempty_of_mem t_fset with ⟨x, xt⟩,
have : t ⊆ closed_ball x 1 := by intros y yt; simp [dist_comm]; apply le_of_lt (ht x y xt yt),
have : closed_ball x 1 ∈ f := f.sets_of_superset t_fset this,
rcases (compact_iff_totally_bounded_complete.1 (proper_space.compact_ball x 1)).2 f hf (le_principal_iff.2 this)
with ⟨y, _, hy⟩,
exact ⟨y, hy⟩
end⟩
/-- A proper metric space is separable, and therefore second countable. Indeed, any ball is
compact, and therefore admits a countable dense subset. Taking a countable union over the balls
centered at a fixed point and with integer radius, one obtains a countable set which is
dense in the whole space. -/
@[priority 100] -- see Note [lower instance priority]
instance second_countable_of_proper [proper_space α] :
second_countable_topology α :=
begin
/- It suffices to show that `α` admits a countable dense subset. -/
suffices : separable_space α,
{ resetI, apply emetric.second_countable_of_separable },
constructor,
/- We show that the space admits a countable dense subset. The case where the space is empty
is special, and trivial. -/
rcases _root_.em (nonempty α) with (⟨⟨x⟩⟩|hα), swap,
{ exact ⟨∅, countable_empty, λ x, (hα ⟨x⟩).elim⟩ },
/- When the space is not empty, we take a point `x` in the space, and then a countable set
`T r` which is dense in the closed ball `closed_ball x r` for each `r`. Then the set
`t = ⋃ T n` (where the union is over all integers `n`) is countable, as a countable union
of countable sets, and dense in the space by construction. -/
choose T T_sub T_count T_closure using
show ∀ (r:ℝ), ∃ t ⊆ closed_ball x r, (countable (t : set α) ∧ closed_ball x r = closure t),
from assume r, emetric.countable_closure_of_compact (proper_space.compact_ball _ _),
use [⋃n:ℕ, T (n : ℝ), countable_Union (λ n, T_count n)],
intro y,
rcases exists_nat_gt (dist y x) with ⟨n, n_large⟩,
have h : y ∈ closed_ball x (n : ℝ) := n_large.le,
rw [T_closure] at h,
exact closure_mono (subset_Union _ _) h
end
/-- A finite product of proper spaces is proper. -/
instance pi_proper_space {π : β → Type*} [fintype β] [∀b, metric_space (π b)]
[h : ∀b, proper_space (π b)] : proper_space (Πb, π b) :=
begin
refine proper_space_of_compact_closed_ball_of_le 0 (λx r hr, _),
rw closed_ball_pi _ hr,
apply compact_pi_infinite (λb, _),
apply (h b).compact_ball
end
end proper_space
namespace metric
section second_countable
open topological_space
/-- A metric space is second countable if, for every `ε > 0`, there is a countable set which is
`ε`-dense. -/
lemma second_countable_of_almost_dense_set
(H : ∀ε > (0 : ℝ), ∃ s : set α, countable s ∧ (∀x, ∃y ∈ s, dist x y ≤ ε)) :
second_countable_topology α :=
begin
choose T T_dense using H,
have I1 : ∀n:ℕ, (n:ℝ) + 1 > 0 :=
λn, lt_of_lt_of_le zero_lt_one (le_add_of_nonneg_left (nat.cast_nonneg _)),
have I : ∀n:ℕ, (n+1 : ℝ)⁻¹ > 0 := λn, inv_pos.2 (I1 n),
let t := ⋃n:ℕ, T (n+1)⁻¹ (I n),
have count_t : countable t := by finish [countable_Union],
have dense_t : dense t,
{ refine (λx, mem_closure_iff.2 (λε εpos, _)),
rcases exists_nat_gt ε⁻¹ with ⟨n, hn⟩,
have : ε⁻¹ < n + 1 := lt_of_lt_of_le hn (le_add_of_nonneg_right zero_le_one),
have nε : ((n:ℝ)+1)⁻¹ < ε := (inv_lt (I1 n) εpos).2 this,
rcases (T_dense (n+1)⁻¹ (I n)).2 x with ⟨y, yT, Dxy⟩,
have : y ∈ t := mem_of_mem_of_subset yT (by apply subset_Union (λ (n:ℕ), T (n+1)⁻¹ (I n))),
exact ⟨y, this, lt_of_le_of_lt Dxy nε⟩ },
haveI : separable_space α := ⟨⟨t, ⟨count_t, dense_t⟩⟩⟩,
exact emetric.second_countable_of_separable α
end
/-- A metric space space is second countable if one can reconstruct up to any `ε>0` any element of
the space from countably many data. -/
lemma second_countable_of_countable_discretization {α : Type u} [metric_space α]
(H : ∀ε > (0 : ℝ), ∃ (β : Type*) [encodable β] (F : α → β), ∀x y, F x = F y → dist x y ≤ ε) :
second_countable_topology α :=
begin
cases (univ : set α).eq_empty_or_nonempty with hs hs,
{ haveI : compact_space α := ⟨by rw hs; exact compact_empty⟩, by apply_instance },
rcases hs with ⟨x0, hx0⟩,
letI : inhabited α := ⟨x0⟩,
refine second_countable_of_almost_dense_set (λε ε0, _),
rcases H ε ε0 with ⟨β, fβ, F, hF⟩,
resetI,
let Finv := function.inv_fun F,
refine ⟨range Finv, ⟨countable_range _, λx, _⟩⟩,
let x' := Finv (F x),
have : F x' = F x := function.inv_fun_eq ⟨x, rfl⟩,
exact ⟨x', mem_range_self _, hF _ _ this.symm⟩
end
end second_countable
end metric
lemma lebesgue_number_lemma_of_metric
{s : set α} {ι} {c : ι → set α} (hs : is_compact s)
(hc₁ : ∀ i, is_open (c i)) (hc₂ : s ⊆ ⋃ i, c i) :
∃ δ > 0, ∀ x ∈ s, ∃ i, ball x δ ⊆ c i :=
let ⟨n, en, hn⟩ := lebesgue_number_lemma hs hc₁ hc₂,
⟨δ, δ0, hδ⟩ := mem_uniformity_dist.1 en in
⟨δ, δ0, assume x hx, let ⟨i, hi⟩ := hn x hx in
⟨i, assume y hy, hi (hδ (mem_ball'.mp hy))⟩⟩
lemma lebesgue_number_lemma_of_metric_sUnion
{s : set α} {c : set (set α)} (hs : is_compact s)
(hc₁ : ∀ t ∈ c, is_open t) (hc₂ : s ⊆ ⋃₀ c) :
∃ δ > 0, ∀ x ∈ s, ∃ t ∈ c, ball x δ ⊆ t :=
by rw sUnion_eq_Union at hc₂;
simpa using lebesgue_number_lemma_of_metric hs (by simpa) hc₂
namespace metric
/-- Boundedness of a subset of a metric space. We formulate the definition to work
even in the empty space. -/
def bounded (s : set α) : Prop :=
∃C, ∀x y ∈ s, dist x y ≤ C
section bounded
variables {x : α} {s t : set α} {r : ℝ}
@[simp] lemma bounded_empty : bounded (∅ : set α) :=
⟨0, by simp⟩
lemma bounded_iff_mem_bounded : bounded s ↔ ∀ x ∈ s, bounded s :=
⟨λ h _ _, h, λ H,
s.eq_empty_or_nonempty.elim
(λ hs, hs.symm ▸ bounded_empty)
(λ ⟨x, hx⟩, H x hx)⟩
/-- Subsets of a bounded set are also bounded -/
lemma bounded.subset (incl : s ⊆ t) : bounded t → bounded s :=
Exists.imp $ λ C hC x y hx hy, hC x y (incl hx) (incl hy)
/-- Closed balls are bounded -/
lemma bounded_closed_ball : bounded (closed_ball x r) :=
⟨r + r, λ y z hy hz, begin
simp only [mem_closed_ball] at *,
calc dist y z ≤ dist y x + dist z x : dist_triangle_right _ _ _
... ≤ r + r : add_le_add hy hz
end⟩
/-- Open balls are bounded -/
lemma bounded_ball : bounded (ball x r) :=
bounded_closed_ball.subset ball_subset_closed_ball
/-- Given a point, a bounded subset is included in some ball around this point -/
lemma bounded_iff_subset_ball (c : α) : bounded s ↔ ∃r, s ⊆ closed_ball c r :=
begin
split; rintro ⟨C, hC⟩,
{ cases s.eq_empty_or_nonempty with h h,
{ subst s, exact ⟨0, by simp⟩ },
{ rcases h with ⟨x, hx⟩,
exact ⟨C + dist x c, λ y hy, calc
dist y c ≤ dist y x + dist x c : dist_triangle _ _ _
... ≤ C + dist x c : add_le_add_right (hC y x hy hx) _⟩ } },
{ exact bounded_closed_ball.subset hC }
end
lemma bounded_closure_of_bounded (h : bounded s) : bounded (closure s) :=
begin
cases h with C h,
replace h : ∀ p : α × α, p ∈ set.prod s s → dist p.1 p.2 ∈ { d | d ≤ C },
{ rintros ⟨x, y⟩ ⟨x_in, y_in⟩,
exact h x y x_in y_in },
use C,
suffices : ∀ p : α × α, p ∈ closure (set.prod s s) → dist p.1 p.2 ∈ { d | d ≤ C },
{ rw closure_prod_eq at this,
intros x y x_in y_in,
exact this (x, y) (mk_mem_prod x_in y_in) },
intros p p_in,
have := map_mem_closure continuous_dist p_in h,
rwa (is_closed_le' C).closure_eq at this
end
alias bounded_closure_of_bounded ← bounded.closure
/-- The union of two bounded sets is bounded iff each of the sets is bounded -/
@[simp] lemma bounded_union :
bounded (s ∪ t) ↔ bounded s ∧ bounded t :=
⟨λh, ⟨h.subset (by simp), h.subset (by simp)⟩,
begin
rintro ⟨hs, ht⟩,
refine bounded_iff_mem_bounded.2 (λ x _, _),
rw bounded_iff_subset_ball x at hs ht ⊢,
rcases hs with ⟨Cs, hCs⟩, rcases ht with ⟨Ct, hCt⟩,
exact ⟨max Cs Ct, union_subset
(subset.trans hCs $ closed_ball_subset_closed_ball $ le_max_left _ _)
(subset.trans hCt $ closed_ball_subset_closed_ball $ le_max_right _ _)⟩,
end⟩
/-- A finite union of bounded sets is bounded -/
lemma bounded_bUnion {I : set β} {s : β → set α} (H : finite I) :
bounded (⋃i∈I, s i) ↔ ∀i ∈ I, bounded (s i) :=
finite.induction_on H (by simp) $ λ x I _ _ IH,
by simp [or_imp_distrib, forall_and_distrib, IH]
/-- A compact set is bounded -/
lemma bounded_of_compact {s : set α} (h : is_compact s) : bounded s :=
-- We cover the compact set by finitely many balls of radius 1,
-- and then argue that a finite union of bounded sets is bounded
let ⟨t, ht, fint, subs⟩ := finite_cover_balls_of_compact h zero_lt_one in
bounded.subset subs $ (bounded_bUnion fint).2 $ λ i hi, bounded_ball
alias bounded_of_compact ← is_compact.bounded
/-- A finite set is bounded -/
lemma bounded_of_finite {s : set α} (h : finite s) : bounded s :=
h.is_compact.bounded
/-- A singleton is bounded -/
lemma bounded_singleton {x : α} : bounded ({x} : set α) :=
bounded_of_finite $ finite_singleton _
/-- Characterization of the boundedness of the range of a function -/
lemma bounded_range_iff {f : β → α} : bounded (range f) ↔ ∃C, ∀x y, dist (f x) (f y) ≤ C :=
exists_congr $ λ C, ⟨
λ H x y, H _ _ ⟨x, rfl⟩ ⟨y, rfl⟩,
by rintro H _ _ ⟨x, rfl⟩ ⟨y, rfl⟩; exact H x y⟩
/-- In a compact space, all sets are bounded -/
lemma bounded_of_compact_space [compact_space α] : bounded s :=
compact_univ.bounded.subset (subset_univ _)
/-- The Heine–Borel theorem:
In a proper space, a set is compact if and only if it is closed and bounded -/
lemma compact_iff_closed_bounded [proper_space α] :
is_compact s ↔ is_closed s ∧ bounded s :=
⟨λ h, ⟨h.is_closed, h.bounded⟩, begin
rintro ⟨hc, hb⟩,
cases s.eq_empty_or_nonempty with h h, {simp [h, compact_empty]},
rcases h with ⟨x, hx⟩,
rcases (bounded_iff_subset_ball x).1 hb with ⟨r, hr⟩,
exact compact_of_is_closed_subset (proper_space.compact_ball x r) hc hr
end⟩
/-- The image of a proper space under an expanding onto map is proper. -/
lemma proper_image_of_proper [proper_space α] [metric_space β] (f : α → β)
(f_cont : continuous f) (hf : range f = univ) (C : ℝ)
(hC : ∀x y, dist x y ≤ C * dist (f x) (f y)) : proper_space β :=
begin
apply proper_space_of_compact_closed_ball_of_le 0 (λx₀ r hr, _),
let K := f ⁻¹' (closed_ball x₀ r),
have A : is_closed K :=
continuous_iff_is_closed.1 f_cont (closed_ball x₀ r) is_closed_ball,
have B : bounded K := ⟨max C 0 * (r + r), λx y hx hy, calc
dist x y ≤ C * dist (f x) (f y) : hC x y
... ≤ max C 0 * dist (f x) (f y) : mul_le_mul_of_nonneg_right (le_max_left _ _) (dist_nonneg)
... ≤ max C 0 * (dist (f x) x₀ + dist (f y) x₀) :
mul_le_mul_of_nonneg_left (dist_triangle_right (f x) (f y) x₀) (le_max_right _ _)
... ≤ max C 0 * (r + r) : begin
simp only [mem_closed_ball, mem_preimage] at hx hy,
exact mul_le_mul_of_nonneg_left (add_le_add hx hy) (le_max_right _ _)
end⟩,
have : is_compact K := compact_iff_closed_bounded.2 ⟨A, B⟩,
have C : is_compact (f '' K) := this.image f_cont,
have : f '' K = closed_ball x₀ r,
by { rw image_preimage_eq_of_subset, rw hf, exact subset_univ _ },
rwa this at C
end
end bounded
section diam
variables {s : set α} {x y z : α}
/-- The diameter of a set in a metric space. To get controllable behavior even when the diameter
should be infinite, we express it in terms of the emetric.diameter -/
def diam (s : set α) : ℝ := ennreal.to_real (emetric.diam s)
/-- The diameter of a set is always nonnegative -/
lemma diam_nonneg : 0 ≤ diam s := ennreal.to_real_nonneg
lemma diam_subsingleton (hs : s.subsingleton) : diam s = 0 :=
by simp only [diam, emetric.diam_subsingleton hs, ennreal.zero_to_real]
/-- The empty set has zero diameter -/
@[simp] lemma diam_empty : diam (∅ : set α) = 0 :=
diam_subsingleton subsingleton_empty
/-- A singleton has zero diameter -/
@[simp] lemma diam_singleton : diam ({x} : set α) = 0 :=
diam_subsingleton subsingleton_singleton
-- Does not work as a simp-lemma, since {x, y} reduces to (insert y {x})
lemma diam_pair : diam ({x, y} : set α) = dist x y :=
by simp only [diam, emetric.diam_pair, dist_edist]
-- Does not work as a simp-lemma, since {x, y, z} reduces to (insert z (insert y {x}))
lemma diam_triple :
metric.diam ({x, y, z} : set α) = max (max (dist x y) (dist x z)) (dist y z) :=
begin
simp only [metric.diam, emetric.diam_triple, dist_edist],
rw [ennreal.to_real_max, ennreal.to_real_max];
apply_rules [ne_of_lt, edist_lt_top, max_lt]
end
/-- If the distance between any two points in a set is bounded by some constant `C`,
then `ennreal.of_real C` bounds the emetric diameter of this set. -/
lemma ediam_le_of_forall_dist_le {C : ℝ} (h : ∀ (x ∈ s) (y ∈ s), dist x y ≤ C) :
emetric.diam s ≤ ennreal.of_real C :=
emetric.diam_le_of_forall_edist_le $
λ x hx y hy, (edist_dist x y).symm ▸ ennreal.of_real_le_of_real (h x hx y hy)
/-- If the distance between any two points in a set is bounded by some non-negative constant,
this constant bounds the diameter. -/
lemma diam_le_of_forall_dist_le {C : ℝ} (h₀ : 0 ≤ C) (h : ∀ (x ∈ s) (y ∈ s), dist x y ≤ C) :
diam s ≤ C :=
ennreal.to_real_le_of_le_of_real h₀ (ediam_le_of_forall_dist_le h)
/-- If the distance between any two points in a nonempty set is bounded by some constant,
this constant bounds the diameter. -/
lemma diam_le_of_forall_dist_le_of_nonempty (hs : s.nonempty) {C : ℝ}
(h : ∀ (x ∈ s) (y ∈ s), dist x y ≤ C) : diam s ≤ C :=
have h₀ : 0 ≤ C, from let ⟨x, hx⟩ := hs in le_trans dist_nonneg (h x hx x hx),
diam_le_of_forall_dist_le h₀ h
/-- The distance between two points in a set is controlled by the diameter of the set. -/
lemma dist_le_diam_of_mem' (h : emetric.diam s ≠ ⊤) (hx : x ∈ s) (hy : y ∈ s) :
dist x y ≤ diam s :=
begin
rw [diam, dist_edist],
rw ennreal.to_real_le_to_real (edist_ne_top _ _) h,
exact emetric.edist_le_diam_of_mem hx hy
end
/-- Characterize the boundedness of a set in terms of the finiteness of its emetric.diameter. -/
lemma bounded_iff_ediam_ne_top : bounded s ↔ emetric.diam s ≠ ⊤ :=
iff.intro
(λ ⟨C, hC⟩, ne_top_of_le_ne_top ennreal.of_real_ne_top
(ediam_le_of_forall_dist_le $ λ x hx y hy, hC x y hx hy))
(λ h, ⟨diam s, λ x y hx hy, dist_le_diam_of_mem' h hx hy⟩)
lemma bounded.ediam_ne_top (h : bounded s) : emetric.diam s ≠ ⊤ :=
bounded_iff_ediam_ne_top.1 h
/-- The distance between two points in a set is controlled by the diameter of the set. -/
lemma dist_le_diam_of_mem (h : bounded s) (hx : x ∈ s) (hy : y ∈ s) : dist x y ≤ diam s :=
dist_le_diam_of_mem' h.ediam_ne_top hx hy
/-- An unbounded set has zero diameter. If you would prefer to get the value ∞, use `emetric.diam`.
This lemma makes it possible to avoid side conditions in some situations -/
lemma diam_eq_zero_of_unbounded (h : ¬(bounded s)) : diam s = 0 :=
begin
simp only [bounded_iff_ediam_ne_top, not_not, ne.def] at h,
simp [diam, h]
end
/-- If `s ⊆ t`, then the diameter of `s` is bounded by that of `t`, provided `t` is bounded. -/
lemma diam_mono {s t : set α} (h : s ⊆ t) (ht : bounded t) : diam s ≤ diam t :=
begin
unfold diam,
rw ennreal.to_real_le_to_real (bounded.subset h ht).ediam_ne_top ht.ediam_ne_top,
exact emetric.diam_mono h
end
/-- The diameter of a union is controlled by the sum of the diameters, and the distance between
any two points in each of the sets. This lemma is true without any side condition, since it is
obviously true if `s ∪ t` is unbounded. -/
lemma diam_union {t : set α} (xs : x ∈ s) (yt : y ∈ t) : diam (s ∪ t) ≤ diam s + dist x y + diam t :=
begin
classical, by_cases H : bounded (s ∪ t),
{ have hs : bounded s, from H.subset (subset_union_left _ _),
have ht : bounded t, from H.subset (subset_union_right _ _),
rw [bounded_iff_ediam_ne_top] at H hs ht,
rw [dist_edist, diam, diam, diam, ← ennreal.to_real_add, ← ennreal.to_real_add,
ennreal.to_real_le_to_real];
repeat { apply ennreal.add_ne_top.2; split }; try { assumption };
try { apply edist_ne_top },
exact emetric.diam_union xs yt },
{ rw [diam_eq_zero_of_unbounded H],
apply_rules [add_nonneg, diam_nonneg, dist_nonneg] }
end
/-- If two sets intersect, the diameter of the union is bounded by the sum of the diameters. -/
lemma diam_union' {t : set α} (h : (s ∩ t).nonempty) : diam (s ∪ t) ≤ diam s + diam t :=
begin
rcases h with ⟨x, ⟨xs, xt⟩⟩,
simpa using diam_union xs xt
end
/-- The diameter of a closed ball of radius `r` is at most `2 r`. -/
lemma diam_closed_ball {r : ℝ} (h : 0 ≤ r) : diam (closed_ball x r) ≤ 2 * r :=
diam_le_of_forall_dist_le (mul_nonneg (le_of_lt zero_lt_two) h) $ λa ha b hb, calc
dist a b ≤ dist a x + dist b x : dist_triangle_right _ _ _
... ≤ r + r : add_le_add ha hb
... = 2 * r : by simp [mul_two, mul_comm]
/-- The diameter of a ball of radius `r` is at most `2 r`. -/
lemma diam_ball {r : ℝ} (h : 0 ≤ r) : diam (ball x r) ≤ 2 * r :=
le_trans (diam_mono ball_subset_closed_ball bounded_closed_ball) (diam_closed_ball h)
end diam
end metric
|
ac0d78f5d67e5d3a7f9554e720c581bf7d6a8605 | fa02ed5a3c9c0adee3c26887a16855e7841c668b | /src/tactic/trunc_cases.lean | efd28a824345c88f4590eab9789389e32e76ecc0 | [
"Apache-2.0"
] | permissive | jjgarzella/mathlib | 96a345378c4e0bf26cf604aed84f90329e4896a2 | 395d8716c3ad03747059d482090e2bb97db612c8 | refs/heads/master | 1,686,480,124,379 | 1,625,163,323,000 | 1,625,163,323,000 | 281,190,421 | 2 | 0 | Apache-2.0 | 1,595,268,170,000 | 1,595,268,169,000 | null | UTF-8 | Lean | false | false | 4,419 | lean | /-
Copyright (c) 2020 Scott Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Scott Morrison
-/
import tactic.chain
import data.quot
namespace tactic
/-- Auxiliary tactic for `trunc_cases`. -/
private meta def trunc_cases_subsingleton (e : expr) (ids : list name) : tactic expr :=
do
-- When the target is a subsingleton,
-- we can just use induction along `trunc.rec_on_subsingleton`,
-- generating just a single goal.
[(_, [e], _)] ← tactic.induction e ids `trunc.rec_on_subsingleton,
return e
/-- Auxiliary tactic for `trunc_cases`. -/
private meta def trunc_cases_nondependent (e : expr) (ids : list name) : tactic expr :=
do
-- We may as well just use `trunc.lift_on`.
-- (It would be nice if we could use the `induction` tactic with non-dependent recursors, too?)
-- (In fact, the general strategy works just as well here,
-- except that it leaves a beta redex in the invariance goal.)
to_expr ``(trunc.lift_on %%e) >>= tactic.fapply,
-- Replace the hypothesis `e` with the unboxed version.
tactic.clear e,
e ← tactic.intro e.local_pp_name,
-- In the invariance goal, introduce the two arguments using the specified identifiers
tactic.swap,
match ids.nth 1 with
| some n := tactic.intro n
| none := tactic.intro1
end,
match ids.nth 2 with
| some n := tactic.intro n
| none := tactic.intro1
end,
tactic.swap,
return e
/-- Auxiliary tactic for `trunc_cases`. -/
private meta def trunc_cases_dependent (e : expr) (ids : list name) : tactic expr :=
do
-- If all else fails, just use the general induction principle.
[(_, [e], _), (_, [e_a, e_b, e_p], _)] ← tactic.induction e ids,
-- However even now we can do something useful:
-- the invariance goal has a useless `e_p : true` hypothesis,
-- and after casing on that we may be able to simplify away
-- the `eq.rec`.
swap, (tactic.cases e_p >> `[try { simp only [eq_rec_constant] }]), swap,
return e
namespace interactive
open interactive
open interactive.types
open tactic
/--
`trunc_cases e` performs case analysis on a `trunc` expression `e`,
attempting the following strategies:
1. when the goal is a subsingleton, calling `induction e using trunc.rec_on_subsingleton`,
2. when the goal does not depend on `e`, calling `fapply trunc.lift_on e`,
and using `intro` and `clear` afterwards to make the goals look like we used `induction`,
3. otherwise, falling through to `trunc.rec_on`, and in the new invariance goal
calling `cases h_p` on the useless `h_p : true` hypothesis,
and then attempting to simplify the `eq.rec`.
`trunc_cases e with h` names the new hypothesis `h`.
If `e` is a local hypothesis already,
`trunc_cases` defaults to reusing the same name.
`trunc_cases e with h h_a h_b` will use the names `h_a` and `h_b` for the new hypothesis
in the invariance goal if `trunc_cases` uses `trunc.lift_on` or `trunc.rec_on`.
Finally, if the new hypothesis from inside the `trunc` is a type class,
`trunc_cases` resets the instance cache so that it is immediately available.
-/
meta def trunc_cases (e : parse texpr) (ids : parse with_ident_list) : tactic unit :=
do
e ← to_expr e,
-- If `ids = []` and `e` is a local constant, we'll want to give
-- the new unboxed hypothesis the same name.
let ids := if ids = [] ∧ e.is_local_constant then [e.local_pp_name] else ids,
-- Make a note of the expr `e`, or reuse `e` if it is already a local constant.
e ← if e.is_local_constant then
return e
else
(do n ← match ids.nth 0 with | some n := pure n | none := mk_fresh_name end, note n none e),
-- Now check if the target is a subsingleton.
tgt ← target,
ss ← succeeds (mk_app `subsingleton [tgt] >>= mk_instance),
-- In each branch here, we're going to capture the name of the new unboxed hypothesis
-- so that we can later check if it's a typeclass and if so unfreeze local instances.
e ← if ss then trunc_cases_subsingleton e ids
else if e.occurs tgt then trunc_cases_dependent e ids
else trunc_cases_nondependent e ids,
c ← infer_type e >>= is_class,
when c reset_instance_cache
end interactive
end tactic
add_tactic_doc
{ name := "trunc_cases",
category := doc_category.tactic,
decl_names := [`tactic.interactive.trunc_cases],
tags := ["case bashing"] }
|
ccda9199b6e9adfca977a71827687403bc94eb97 | 82e44445c70db0f03e30d7be725775f122d72f3e | /src/ring_theory/fractional_ideal.lean | cbb7963d894f1af62014ef4fdc9c0c7e418a1c9e | [
"Apache-2.0"
] | permissive | stjordanis/mathlib | 51e286d19140e3788ef2c470bc7b953e4991f0c9 | 2568d41bca08f5d6bf39d915434c8447e21f42ee | refs/heads/master | 1,631,748,053,501 | 1,627,938,886,000 | 1,627,938,886,000 | 228,728,358 | 0 | 0 | Apache-2.0 | 1,576,630,588,000 | 1,576,630,587,000 | null | UTF-8 | Lean | false | false | 45,789 | lean | /-
Copyright (c) 2020 Anne Baanen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Anne Baanen, Filippo A. E. Nuccio
-/
import ring_theory.localization
import ring_theory.noetherian
import ring_theory.principal_ideal_domain
import tactic.field_simp
/-!
# Fractional ideals
This file defines fractional ideals of an integral domain and proves basic facts about them.
## Main definitions
Let `S` be a submonoid of an integral domain `R`, `P` the localization of `R` at `S`, and `f` the
natural ring hom from `R` to `P`.
* `is_fractional` defines which `R`-submodules of `P` are fractional ideals
* `fractional_ideal S P` is the type of fractional ideals in `P`
* `has_coe (ideal R) (fractional_ideal S P)` instance
* `comm_semiring (fractional_ideal S P)` instance:
the typical ideal operations generalized to fractional ideals
* `lattice (fractional_ideal S P)` instance
* `map` is the pushforward of a fractional ideal along an algebra morphism
Let `K` be the localization of `R` at `R⁰ = R \ {0}` (i.e. the field of fractions).
* `fractional_ideal R⁰ K` is the type of fractional ideals in the field of fractions
* `has_div (fractional_ideal R⁰ K)` instance:
the ideal quotient `I / J` (typically written $I : J$, but a `:` operator cannot be defined)
## Main statements
* `mul_left_mono` and `mul_right_mono` state that ideal multiplication is monotone
* `prod_one_self_div_eq` states that `1 / I` is the inverse of `I` if one exists
* `is_noetherian` states that very fractional ideal of a noetherian integral domain is noetherian
## Implementation notes
Fractional ideals are considered equal when they contain the same elements,
independent of the denominator `a : R` such that `a I ⊆ R`.
Thus, we define `fractional_ideal` to be the subtype of the predicate `is_fractional`,
instead of having `fractional_ideal` be a structure of which `a` is a field.
Most definitions in this file specialize operations from submodules to fractional ideals,
proving that the result of this operation is fractional if the input is fractional.
Exceptions to this rule are defining `(+) := (⊔)` and `⊥ := 0`,
in order to re-use their respective proof terms.
We can still use `simp` to show `↑I + ↑J = ↑(I + J)` and `↑⊥ = ↑0`.
Many results in fact do not need that `P` is a localization, only that `P` is an
`R`-algebra. We omit the `is_localization` parameter whenever this is practical.
Similarly, we don't assume that the localization is a field until we need it to
define ideal quotients. When this assumption is needed, we replace `S` with `R⁰`,
making the localization a field.
## References
* https://en.wikipedia.org/wiki/Fractional_ideal
## Tags
fractional ideal, fractional ideals, invertible ideal
-/
open is_localization
local notation R`⁰`:9000 := non_zero_divisors R
section defs
variables {R : Type*} [comm_ring R] {S : submonoid R} {P : Type*} [comm_ring P]
variables [algebra R P]
variables (S)
/-- A submodule `I` is a fractional ideal if `a I ⊆ R` for some `a ≠ 0`. -/
def is_fractional (I : submodule R P) :=
∃ a ∈ S, ∀ b ∈ I, is_integer R (a • b)
variables (S P)
/-- The fractional ideals of a domain `R` are ideals of `R` divided by some `a ∈ R`.
More precisely, let `P` be a localization of `R` at some submonoid `S`,
then a fractional ideal `I ⊆ P` is an `R`-submodule of `P`,
such that there is a nonzero `a : R` with `a I ⊆ R`.
-/
def fractional_ideal :=
{I : submodule R P // is_fractional S I}
end defs
namespace fractional_ideal
open set
open submodule
variables {R : Type*} [comm_ring R] {S : submonoid R} {P : Type*} [comm_ring P]
variables [algebra R P] [loc : is_localization S P]
/-- Map a fractional ideal `I` to a submodule by forgetting that `∃ a, a I ⊆ R`.
This coercion is typically called `coe_to_submodule` in lemma names
(or `coe` when the coercion is clear from the context),
not to be confused with `is_localization.coe_submodule : ideal R → submodule R P`
(which we use to define `coe : ideal R → fractional_ideal S P`,
referred to as `coe_ideal` in theorem names).
-/
instance : has_coe (fractional_ideal S P) (submodule R P) := ⟨λ I, I.val⟩
protected lemma is_fractional (I : fractional_ideal S P) :
is_fractional S (I : submodule R P) :=
I.prop
section set_like
instance : set_like (fractional_ideal S P) P :=
{ coe := λ I, ↑(I : submodule R P),
coe_injective' := set_like.coe_injective.comp subtype.coe_injective }
@[simp] lemma mem_coe {I : fractional_ideal S P} {x : P} :
x ∈ (I : submodule R P) ↔ x ∈ I :=
iff.rfl
@[ext] lemma ext {I J : fractional_ideal S P} : (∀ x, x ∈ I ↔ x ∈ J) → I = J := set_like.ext
/-- Copy of a `fractional_ideal` with a new underlying set equal to the old one.
Useful to fix definitional equalities. -/
protected def copy (p : fractional_ideal S P) (s : set P) (hs : s = ↑p) : fractional_ideal S P :=
⟨submodule.copy p s hs, by { convert p.is_fractional, ext, simp only [hs], refl }⟩
end set_like
@[simp] lemma val_eq_coe (I : fractional_ideal S P) : I.val = I := rfl
@[simp, norm_cast] lemma coe_mk (I : submodule R P) (hI : is_fractional S I) :
(subtype.mk I hI : submodule R P) = I := rfl
lemma coe_to_submodule_injective :
function.injective (coe : fractional_ideal S P → submodule R P) :=
subtype.coe_injective
lemma is_fractional_of_le_one (I : submodule R P) (h : I ≤ 1) :
is_fractional S I :=
begin
use [1, S.one_mem],
intros b hb,
rw one_smul,
obtain ⟨b', b'_mem, rfl⟩ := h hb,
exact set.mem_range_self b',
end
lemma is_fractional_of_le {I : submodule R P} {J : fractional_ideal S P}
(hIJ : I ≤ J) : is_fractional S I :=
begin
obtain ⟨a, a_mem, ha⟩ := J.is_fractional,
use [a, a_mem],
intros b b_mem,
exact ha b (hIJ b_mem)
end
/-- Map an ideal `I` to a fractional ideal by forgetting `I` is integral.
This is a bundled version of `is_localization.coe_submodule : ideal R → submodule R P`,
which is not to be confused with the `coe : fractional_ideal S P → submodule R P`,
also called `coe_to_submodule` in theorem names.
-/
instance coe_to_fractional_ideal : has_coe (ideal R) (fractional_ideal S P) :=
⟨λ I, ⟨coe_submodule P I, is_fractional_of_le_one _
(by simpa using coe_submodule_mono P (le_top : I ≤ ⊤))⟩⟩
@[simp, norm_cast] lemma coe_coe_ideal (I : ideal R) :
((I : fractional_ideal S P) : submodule R P) = coe_submodule P I := rfl
variables (S)
@[simp] lemma mem_coe_ideal {x : P} {I : ideal R} :
x ∈ (I : fractional_ideal S P) ↔ ∃ x', x' ∈ I ∧ algebra_map R P x' = x :=
mem_coe_submodule _ _
lemma mem_coe_ideal_of_mem {x : R} {I : ideal R} (hx : x ∈ I) :
algebra_map R P x ∈ (I : fractional_ideal S P) :=
(mem_coe_ideal S).mpr ⟨x, hx, rfl⟩
lemma coe_ideal_le_coe_ideal' [is_localization S P] (h : S ≤ non_zero_divisors R)
{I J : ideal R} : (I : fractional_ideal S P) ≤ J ↔ I ≤ J :=
coe_submodule_le_coe_submodule h
@[simp] lemma coe_ideal_le_coe_ideal (K : Type*) [comm_ring K] [algebra R K] [is_fraction_ring R K]
{I J : ideal R} : (I : fractional_ideal R⁰ K) ≤ J ↔ I ≤ J :=
is_fraction_ring.coe_submodule_le_coe_submodule
instance : has_zero (fractional_ideal S P) := ⟨(0 : ideal R)⟩
@[simp] lemma mem_zero_iff {x : P} : x ∈ (0 : fractional_ideal S P) ↔ x = 0 :=
⟨(λ ⟨x', x'_mem_zero, x'_eq_x⟩,
have x'_eq_zero : x' = 0 := x'_mem_zero,
by simp [x'_eq_x.symm, x'_eq_zero]),
(λ hx, ⟨0, rfl, by simp [hx]⟩)⟩
variables {S}
@[simp, norm_cast] lemma coe_zero : ↑(0 : fractional_ideal S P) = (⊥ : submodule R P) :=
submodule.ext $ λ _, mem_zero_iff S
@[simp, norm_cast] lemma coe_to_fractional_ideal_bot : ((⊥ : ideal R) : fractional_ideal S P) = 0 :=
rfl
variables (P)
include loc
@[simp] lemma exists_mem_to_map_eq {x : R} {I : ideal R} (h : S ≤ non_zero_divisors R) :
(∃ x', x' ∈ I ∧ algebra_map R P x' = algebra_map R P x) ↔ x ∈ I :=
⟨λ ⟨x', hx', eq⟩, is_localization.injective _ h eq ▸ hx', λ h, ⟨x, h, rfl⟩⟩
variables {P}
lemma coe_to_fractional_ideal_injective (h : S ≤ non_zero_divisors R) :
function.injective (coe : ideal R → fractional_ideal S P) :=
λ I J heq, have
∀ (x : R), algebra_map R P x ∈ (I : fractional_ideal S P) ↔
algebra_map R P x ∈ (J : fractional_ideal S P) :=
λ x, heq ▸ iff.rfl,
ideal.ext (by simpa only [mem_coe_ideal, exists_prop, exists_mem_to_map_eq P h] using this)
lemma coe_to_fractional_ideal_eq_zero {I : ideal R} (hS : S ≤ non_zero_divisors R) :
(I : fractional_ideal S P) = 0 ↔ I = (⊥ : ideal R) :=
⟨λ h, coe_to_fractional_ideal_injective hS h,
λ h, by rw [h, coe_to_fractional_ideal_bot]⟩
lemma coe_to_fractional_ideal_ne_zero {I : ideal R} (hS : S ≤ non_zero_divisors R) :
(I : fractional_ideal S P) ≠ 0 ↔ I ≠ (⊥ : ideal R) :=
not_iff_not.mpr (coe_to_fractional_ideal_eq_zero hS)
omit loc
lemma coe_to_submodule_eq_bot {I : fractional_ideal S P} :
(I : submodule R P) = ⊥ ↔ I = 0 :=
⟨λ h, coe_to_submodule_injective (by simp [h]),
λ h, by simp [h]⟩
lemma coe_to_submodule_ne_bot {I : fractional_ideal S P} :
↑I ≠ (⊥ : submodule R P) ↔ I ≠ 0 :=
not_iff_not.mpr coe_to_submodule_eq_bot
instance : inhabited (fractional_ideal S P) := ⟨0⟩
instance : has_one (fractional_ideal S P) :=
⟨(⊤ : ideal R)⟩
variables (S)
@[simp, norm_cast] lemma coe_ideal_top : ((⊤ : ideal R) : fractional_ideal S P) = 1 :=
rfl
lemma mem_one_iff {x : P} : x ∈ (1 : fractional_ideal S P) ↔ ∃ x' : R, algebra_map R P x' = x :=
iff.intro (λ ⟨x', _, h⟩, ⟨x', h⟩) (λ ⟨x', h⟩, ⟨x', ⟨⟩, h⟩)
lemma coe_mem_one (x : R) : algebra_map R P x ∈ (1 : fractional_ideal S P) :=
(mem_one_iff S).mpr ⟨x, rfl⟩
lemma one_mem_one : (1 : P) ∈ (1 : fractional_ideal S P) :=
(mem_one_iff S).mpr ⟨1, ring_hom.map_one _⟩
variables {S}
/-- `(1 : fractional_ideal S P)` is defined as the R-submodule `f(R) ≤ P`.
However, this is not definitionally equal to `1 : submodule R P`,
which is proved in the actual `simp` lemma `coe_one`. -/
lemma coe_one_eq_coe_submodule_top :
↑(1 : fractional_ideal S P) = coe_submodule P (⊤ : ideal R) :=
rfl
@[simp, norm_cast] lemma coe_one :
(↑(1 : fractional_ideal S P) : submodule R P) = 1 :=
by rw [coe_one_eq_coe_submodule_top, coe_submodule_top]
section lattice
/-!
### `lattice` section
Defines the order on fractional ideals as inclusion of their underlying sets,
and ports the lattice structure on submodules to fractional ideals.
-/
@[simp] lemma coe_le_coe {I J : fractional_ideal S P} :
(I : submodule R P) ≤ (J : submodule R P) ↔ I ≤ J :=
iff.rfl
lemma zero_le (I : fractional_ideal S P) : 0 ≤ I :=
begin
intros x hx,
convert submodule.zero_mem _,
simpa using hx
end
instance order_bot : order_bot (fractional_ideal S P) :=
{ bot := 0,
bot_le := zero_le,
..set_like.partial_order }
@[simp] lemma bot_eq_zero : (⊥ : fractional_ideal S P) = 0 :=
rfl
@[simp] lemma le_zero_iff {I : fractional_ideal S P} : I ≤ 0 ↔ I = 0 :=
le_bot_iff
lemma eq_zero_iff {I : fractional_ideal S P} : I = 0 ↔ (∀ x ∈ I, x = (0 : P)) :=
⟨ (λ h x hx, by simpa [h, mem_zero_iff] using hx),
(λ h, le_bot_iff.mp (λ x hx, (mem_zero_iff S).mpr (h x hx))) ⟩
lemma fractional_sup (I J : fractional_ideal S P) : is_fractional S (I ⊔ J : submodule R P) :=
begin
rcases I.is_fractional with ⟨aI, haI, hI⟩,
rcases J.is_fractional with ⟨aJ, haJ, hJ⟩,
use aI * aJ,
use S.mul_mem haI haJ,
intros b hb,
rcases mem_sup.mp hb with ⟨bI, hbI, bJ, hbJ, rfl⟩,
rw smul_add,
apply is_integer_add,
{ rw [mul_smul, smul_comm],
exact is_integer_smul (hI bI hbI), },
{ rw mul_smul,
exact is_integer_smul (hJ bJ hbJ) }
end
lemma fractional_inf (I J : fractional_ideal S P) : is_fractional S (I ⊓ J : submodule R P) :=
begin
rcases I.is_fractional with ⟨aI, haI, hI⟩,
use aI,
use haI,
intros b hb,
rcases mem_inf.mp hb with ⟨hbI, hbJ⟩,
exact hI b hbI
end
instance lattice : lattice (fractional_ideal S P) :=
{ inf := λ I J, ⟨I ⊓ J, fractional_inf I J⟩,
sup := λ I J, ⟨I ⊔ J, fractional_sup I J⟩,
inf_le_left := λ I J, show (I ⊓ J : submodule R P) ≤ I, from inf_le_left,
inf_le_right := λ I J, show (I ⊓ J : submodule R P) ≤ J, from inf_le_right,
le_inf := λ I J K hIJ hIK, show (I : submodule R P) ≤ J ⊓ K, from le_inf hIJ hIK,
le_sup_left := λ I J, show (I : submodule R P) ≤ I ⊔ J, from le_sup_left,
le_sup_right := λ I J, show (J : submodule R P) ≤ I ⊔ J, from le_sup_right,
sup_le := λ I J K hIK hJK, show (I ⊔ J : submodule R P) ≤ K, from sup_le hIK hJK,
..set_like.partial_order }
instance : semilattice_sup_bot (fractional_ideal S P) :=
{ ..fractional_ideal.order_bot, ..fractional_ideal.lattice }
end lattice
section semiring
instance : has_add (fractional_ideal S P) := ⟨(⊔)⟩
@[simp]
lemma sup_eq_add (I J : fractional_ideal S P) : I ⊔ J = I + J := rfl
@[simp, norm_cast]
lemma coe_add (I J : fractional_ideal S P) : (↑(I + J) : submodule R P) = I + J := rfl
lemma fractional_mul (I J : fractional_ideal S P) : is_fractional S (I * J : submodule R P) :=
begin
rcases I with ⟨I, aI, haI, hI⟩,
rcases J with ⟨J, aJ, haJ, hJ⟩,
use aI * aJ,
use S.mul_mem haI haJ,
intros b hb,
apply submodule.mul_induction_on hb,
{ intros m hm n hn,
obtain ⟨n', hn'⟩ := hJ n hn,
rw [mul_smul, mul_comm m, ← smul_mul_assoc, ← hn', ← algebra.smul_def],
apply hI,
exact submodule.smul_mem _ _ hm },
{ rw smul_zero,
exact ⟨0, ring_hom.map_zero _⟩ },
{ intros x y hx hy,
rw smul_add,
apply is_integer_add hx hy },
{ intros r x hx,
rw smul_comm,
exact is_integer_smul hx },
end
/-- `fractional_ideal.mul` is the product of two fractional ideals,
used to define the `has_mul` instance.
This is only an auxiliary definition: the preferred way of writing `I.mul J` is `I * J`.
Elaborated terms involving `fractional_ideal` tend to grow quite large,
so by making definitions irreducible, we hope to avoid deep unfolds.
-/
@[irreducible]
def mul (I J : fractional_ideal S P) : fractional_ideal S P :=
⟨I * J, fractional_mul I J⟩
local attribute [semireducible] mul
instance : has_mul (fractional_ideal S P) := ⟨λ I J, mul I J⟩
@[simp] lemma mul_eq_mul (I J : fractional_ideal S P) : mul I J = I * J := rfl
@[simp, norm_cast]
lemma coe_mul (I J : fractional_ideal S P) : (↑(I * J) : submodule R P) = I * J := rfl
lemma mul_left_mono (I : fractional_ideal S P) : monotone ((*) I) :=
λ J J' h, mul_le.mpr (λ x hx y hy, mul_mem_mul hx (h hy))
lemma mul_right_mono (I : fractional_ideal S P) : monotone (λ J, J * I) :=
λ J J' h, mul_le.mpr (λ x hx y hy, mul_mem_mul (h hx) hy)
lemma mul_mem_mul {I J : fractional_ideal S P} {i j : P} (hi : i ∈ I) (hj : j ∈ J) :
i * j ∈ I * J := submodule.mul_mem_mul hi hj
lemma mul_le {I J K : fractional_ideal S P} :
I * J ≤ K ↔ (∀ (i ∈ I) (j ∈ J), i * j ∈ K) :=
submodule.mul_le
@[elab_as_eliminator] protected theorem mul_induction_on
{I J : fractional_ideal S P}
{C : P → Prop} {r : P} (hr : r ∈ I * J)
(hm : ∀ (i ∈ I) (j ∈ J), C (i * j))
(h0 : C 0) (ha : ∀ x y, C x → C y → C (x + y))
(hs : ∀ (r : R) x, C x → C (r • x)) : C r :=
submodule.mul_induction_on hr hm h0 ha hs
instance comm_semiring : comm_semiring (fractional_ideal S P) :=
{ add_assoc := λ I J K, sup_assoc,
add_comm := λ I J, sup_comm,
add_zero := λ I, sup_bot_eq,
zero_add := λ I, bot_sup_eq,
mul_assoc := λ I J K, coe_to_submodule_injective (submodule.mul_assoc _ _ _),
mul_comm := λ I J, coe_to_submodule_injective (submodule.mul_comm _ _),
mul_one := λ I, begin
ext,
split; intro h,
{ apply mul_le.mpr _ h,
rintros x hx y ⟨y', y'_mem_R, rfl⟩,
convert submodule.smul_mem _ y' hx,
rw [mul_comm, eq_comm],
exact algebra.smul_def y' x },
{ have : x * 1 ∈ (I * 1) := mul_mem_mul h (one_mem_one _),
rwa [mul_one] at this }
end,
one_mul := λ I, begin
ext,
split; intro h,
{ apply mul_le.mpr _ h,
rintros x ⟨x', x'_mem_R, rfl⟩ y hy,
convert submodule.smul_mem _ x' hy,
rw eq_comm,
exact algebra.smul_def x' y },
{ have : 1 * x ∈ (1 * I) := mul_mem_mul (one_mem_one _) h,
rwa one_mul at this }
end,
mul_zero := λ I, eq_zero_iff.mpr (λ x hx, submodule.mul_induction_on hx
(λ x hx y hy, by simp [(mem_zero_iff S).mp hy])
rfl
(λ x y hx hy, by simp [hx, hy])
(λ r x hx, by simp [hx])),
zero_mul := λ I, eq_zero_iff.mpr (λ x hx, submodule.mul_induction_on hx
(λ x hx y hy, by simp [(mem_zero_iff S).mp hx])
rfl
(λ x y hx hy, by simp [hx, hy])
(λ r x hx, by simp [hx])),
left_distrib := λ I J K, coe_to_submodule_injective (mul_add _ _ _),
right_distrib := λ I J K, coe_to_submodule_injective (add_mul _ _ _),
..fractional_ideal.has_zero S,
..fractional_ideal.has_add,
..fractional_ideal.has_one,
..fractional_ideal.has_mul }
section order
lemma add_le_add_left {I J : fractional_ideal S P} (hIJ : I ≤ J) (J' : fractional_ideal S P) :
J' + I ≤ J' + J :=
sup_le_sup_left hIJ J'
lemma mul_le_mul_left {I J : fractional_ideal S P} (hIJ : I ≤ J) (J' : fractional_ideal S P) :
J' * I ≤ J' * J :=
mul_le.mpr (λ k hk j hj, mul_mem_mul hk (hIJ hj))
lemma le_self_mul_self {I : fractional_ideal S P} (hI: 1 ≤ I) : I ≤ I * I :=
begin
convert mul_left_mono I hI,
exact (mul_one I).symm
end
lemma mul_self_le_self {I : fractional_ideal S P} (hI: I ≤ 1) : I * I ≤ I :=
begin
convert mul_left_mono I hI,
exact (mul_one I).symm
end
lemma coe_ideal_le_one {I : ideal R} : (I : fractional_ideal S P) ≤ 1 :=
λ x hx, let ⟨y, _, hy⟩ := (fractional_ideal.mem_coe_ideal S).mp hx
in (fractional_ideal.mem_one_iff S).mpr ⟨y, hy⟩
lemma le_one_iff_exists_coe_ideal {J : fractional_ideal S P} :
J ≤ (1 : fractional_ideal S P) ↔ ∃ (I : ideal R), ↑I = J :=
begin
split,
{ intro hJ,
refine ⟨⟨{x : R | algebra_map R P x ∈ J}, _, _, _⟩, _⟩,
{ rw [mem_set_of_eq, ring_hom.map_zero],
exact J.val.zero_mem },
{ intros a b ha hb,
rw [mem_set_of_eq, ring_hom.map_add],
exact J.val.add_mem ha hb },
{ intros c x hx,
rw [smul_eq_mul, mem_set_of_eq, ring_hom.map_mul, ← algebra.smul_def],
exact J.val.smul_mem c hx },
{ ext x,
split,
{ rintros ⟨y, hy, eq_y⟩,
rwa ← eq_y },
{ intro hx,
obtain ⟨y, eq_x⟩ := (fractional_ideal.mem_one_iff S).mp (hJ hx),
rw ← eq_x at *,
exact ⟨y, hx, rfl⟩ } } },
{ rintro ⟨I, hI⟩,
rw ← hI,
apply coe_ideal_le_one },
end
end order
variables {P' : Type*} [comm_ring P'] [algebra R P'] [loc' : is_localization S P']
variables {P'' : Type*} [comm_ring P''] [algebra R P''] [loc'' : is_localization S P'']
lemma fractional_map (g : P →ₐ[R] P') (I : fractional_ideal S P) :
is_fractional S (submodule.map g.to_linear_map I) :=
begin
rcases I with ⟨I, a, a_nonzero, hI⟩,
use [a, a_nonzero],
intros b hb,
obtain ⟨b', b'_mem, hb'⟩ := submodule.mem_map.mp hb,
obtain ⟨x, hx⟩ := hI b' b'_mem,
use x,
erw [←g.commutes, hx, g.map_smul, hb']
end
/-- `I.map g` is the pushforward of the fractional ideal `I` along the algebra morphism `g` -/
def map (g : P →ₐ[R] P') :
fractional_ideal S P → fractional_ideal S P' :=
λ I, ⟨submodule.map g.to_linear_map I, fractional_map g I⟩
@[simp, norm_cast] lemma coe_map (g : P →ₐ[R] P') (I : fractional_ideal S P) :
↑(map g I) = submodule.map g.to_linear_map I := rfl
@[simp] lemma mem_map {I : fractional_ideal S P} {g : P →ₐ[R] P'}
{y : P'} : y ∈ I.map g ↔ ∃ x, x ∈ I ∧ g x = y :=
submodule.mem_map
variables (I J : fractional_ideal S P) (g : P →ₐ[R] P')
@[simp] lemma map_id : I.map (alg_hom.id _ _) = I :=
coe_to_submodule_injective (submodule.map_id I)
@[simp] lemma map_comp (g' : P' →ₐ[R] P'') :
I.map (g'.comp g) = (I.map g).map g' :=
coe_to_submodule_injective (submodule.map_comp g.to_linear_map g'.to_linear_map I)
@[simp, norm_cast] lemma map_coe_ideal (I : ideal R) :
(I : fractional_ideal S P).map g = I :=
begin
ext x,
simp only [mem_coe_ideal],
split,
{ rintro ⟨_, ⟨y, hy, rfl⟩, rfl⟩,
exact ⟨y, hy, (g.commutes y).symm⟩ },
{ rintro ⟨y, hy, rfl⟩,
exact ⟨_, ⟨y, hy, rfl⟩, g.commutes y⟩ },
end
@[simp] lemma map_one :
(1 : fractional_ideal S P).map g = 1 :=
map_coe_ideal g ⊤
@[simp] lemma map_zero :
(0 : fractional_ideal S P).map g = 0 :=
map_coe_ideal g 0
@[simp] lemma map_add : (I + J).map g = I.map g + J.map g :=
coe_to_submodule_injective (submodule.map_sup _ _ _)
@[simp] lemma map_mul : (I * J).map g = I.map g * J.map g :=
coe_to_submodule_injective (submodule.map_mul _ _ _)
@[simp] lemma map_map_symm (g : P ≃ₐ[R] P') :
(I.map (g : P →ₐ[R] P')).map (g.symm : P' →ₐ[R] P) = I :=
by rw [←map_comp, g.symm_comp, map_id]
@[simp] lemma map_symm_map (I : fractional_ideal S P') (g : P ≃ₐ[R] P') :
(I.map (g.symm : P' →ₐ[R] P)).map (g : P →ₐ[R] P') = I :=
by rw [←map_comp, g.comp_symm, map_id]
/-- If `g` is an equivalence, `map g` is an isomorphism -/
def map_equiv (g : P ≃ₐ[R] P') :
fractional_ideal S P ≃+* fractional_ideal S P' :=
{ to_fun := map g,
inv_fun := map g.symm,
map_add' := λ I J, map_add I J _,
map_mul' := λ I J, map_mul I J _,
left_inv := λ I, by { rw [←map_comp, alg_equiv.symm_comp, map_id] },
right_inv := λ I, by { rw [←map_comp, alg_equiv.comp_symm, map_id] } }
@[simp] lemma coe_fun_map_equiv (g : P ≃ₐ[R] P') :
(map_equiv g : fractional_ideal S P → fractional_ideal S P') = map g :=
rfl
@[simp] lemma map_equiv_apply (g : P ≃ₐ[R] P') (I : fractional_ideal S P) :
map_equiv g I = map ↑g I := rfl
@[simp] lemma map_equiv_symm (g : P ≃ₐ[R] P') :
((map_equiv g).symm : fractional_ideal S P' ≃+* _) = map_equiv g.symm := rfl
@[simp] lemma map_equiv_refl :
map_equiv alg_equiv.refl = ring_equiv.refl (fractional_ideal S P) :=
ring_equiv.ext (λ x, by simp)
lemma is_fractional_span_iff {s : set P} :
is_fractional S (span R s) ↔ ∃ a ∈ S, ∀ (b : P), b ∈ s → is_integer R (a • b) :=
⟨λ ⟨a, a_mem, h⟩, ⟨a, a_mem, λ b hb, h b (subset_span hb)⟩,
λ ⟨a, a_mem, h⟩, ⟨a, a_mem, λ b hb, span_induction hb
h
(by { rw smul_zero, exact is_integer_zero })
(λ x y hx hy, by { rw smul_add, exact is_integer_add hx hy })
(λ s x hx, by { rw smul_comm, exact is_integer_smul hx })⟩⟩
include loc
lemma is_fractional_of_fg {I : submodule R P} (hI : I.fg) :
is_fractional S I :=
begin
rcases hI with ⟨I, rfl⟩,
rcases exist_integer_multiples_of_finset S I with ⟨⟨s, hs1⟩, hs⟩,
rw is_fractional_span_iff,
exact ⟨s, hs1, hs⟩,
end
omit loc
lemma mem_span_mul_finite_of_mem_mul {I J : fractional_ideal S P} {x : P} (hx : x ∈ I * J) :
∃ (T T' : finset P), (T : set P) ⊆ I ∧ (T' : set P) ⊆ J ∧ x ∈ span R (T * T' : set P) :=
submodule.mem_span_mul_finite_of_mem_mul (by simpa using mem_coe.mpr hx)
variables (S)
lemma coe_ideal_fg (inj : function.injective (algebra_map R P)) (I : ideal R) :
fg ((I : fractional_ideal S P) : submodule R P) ↔ fg I :=
coe_submodule_fg _ inj _
variables {S}
lemma fg_unit (I : units (fractional_ideal S P)) :
fg (I : submodule R P) :=
begin
have : (1 : P) ∈ (I * ↑I⁻¹ : fractional_ideal S P),
{ rw units.mul_inv, exact one_mem_one _ },
obtain ⟨T, T', hT, hT', one_mem⟩ := mem_span_mul_finite_of_mem_mul this,
refine ⟨T, submodule.span_eq_of_le _ hT _⟩,
rw [← one_mul ↑I, ← mul_one (span R ↑T)],
conv_rhs { rw [← fractional_ideal.coe_one, ← units.mul_inv I, fractional_ideal.coe_mul,
mul_comm ↑↑I, ← mul_assoc] },
refine submodule.mul_le_mul_left
(le_trans _ (submodule.mul_le_mul_right (submodule.span_le.mpr hT'))),
rwa [submodule.one_le, submodule.span_mul_span]
end
lemma fg_of_is_unit (I : fractional_ideal S P) (h : is_unit I) :
fg (I : submodule R P) :=
by { rcases h with ⟨I, rfl⟩, exact fg_unit I }
lemma _root_.ideal.fg_of_is_unit (inj : function.injective (algebra_map R P))
(I : ideal R) (h : is_unit (I : fractional_ideal S P)) :
I.fg :=
by { rw ← coe_ideal_fg S inj I, exact fg_of_is_unit I h }
variables (S P P')
include loc loc'
/-- `canonical_equiv f f'` is the canonical equivalence between the fractional
ideals in `P` and in `P'` -/
@[irreducible]
noncomputable def canonical_equiv :
fractional_ideal S P ≃+* fractional_ideal S P' :=
map_equiv
{ commutes' := λ r, ring_equiv_of_ring_equiv_eq _ _,
..ring_equiv_of_ring_equiv P P' (ring_equiv.refl R)
(show S.map _ = S, by rw [ring_equiv.to_monoid_hom_refl, submonoid.map_id]) }
@[simp] lemma mem_canonical_equiv_apply {I : fractional_ideal S P} {x : P'} :
x ∈ canonical_equiv S P P' I ↔
∃ y ∈ I, is_localization.map P' (ring_hom.id R)
(λ y (hy : y ∈ S), show ring_hom.id R y ∈ S, from hy) (y : P) = x :=
begin
rw [canonical_equiv, map_equiv_apply, mem_map],
exact ⟨λ ⟨y, mem, eq⟩, ⟨y, mem, eq⟩, λ ⟨y, mem, eq⟩, ⟨y, mem, eq⟩⟩
end
@[simp] lemma canonical_equiv_symm :
(canonical_equiv S P P').symm = canonical_equiv S P' P :=
ring_equiv.ext $ λ I, set_like.ext_iff.mpr $ λ x,
by { rw [mem_canonical_equiv_apply, canonical_equiv, map_equiv_symm, map_equiv,
ring_equiv.coe_mk, mem_map],
exact ⟨λ ⟨y, mem, eq⟩, ⟨y, mem, eq⟩, λ ⟨y, mem, eq⟩, ⟨y, mem, eq⟩⟩ }
@[simp] lemma canonical_equiv_flip (I) :
canonical_equiv S P P' (canonical_equiv S P' P I) = I :=
by rw [←canonical_equiv_symm, ring_equiv.symm_apply_apply]
end semiring
section is_fraction_ring
/-!
### `is_fraction_ring` section
This section concerns fractional ideals in the field of fractions,
i.e. the type `fractional_ideal R⁰ K` where `is_fraction_ring R K`.
-/
variables {K K' : Type*} [field K] [field K']
variables [algebra R K] [is_fraction_ring R K] [algebra R K'] [is_fraction_ring R K']
variables {I J : fractional_ideal R⁰ K} (h : K →ₐ[R] K')
/-- Nonzero fractional ideals contain a nonzero integer. -/
lemma exists_ne_zero_mem_is_integer [nontrivial R] (hI : I ≠ 0) :
∃ x ≠ (0 : R), algebra_map R K x ∈ I :=
begin
obtain ⟨y, y_mem, y_not_mem⟩ := set_like.exists_of_lt (bot_lt_iff_ne_bot.mpr hI),
have y_ne_zero : y ≠ 0 := by simpa using y_not_mem,
obtain ⟨z, ⟨x, hx⟩⟩ := exists_integer_multiple R⁰ y,
refine ⟨x, _, _⟩,
{ rw [ne.def, ← @is_fraction_ring.to_map_eq_zero_iff R _ K, hx, algebra.smul_def],
exact mul_ne_zero (is_fraction_ring.to_map_ne_zero_of_mem_non_zero_divisors z.2) y_ne_zero },
{ rw hx,
exact smul_mem _ _ y_mem }
end
lemma map_ne_zero [nontrivial R] (hI : I ≠ 0) : I.map h ≠ 0 :=
begin
obtain ⟨x, x_ne_zero, hx⟩ := exists_ne_zero_mem_is_integer hI,
contrapose! x_ne_zero with map_eq_zero,
refine is_fraction_ring.to_map_eq_zero_iff.mp (eq_zero_iff.mp map_eq_zero _ (mem_map.mpr _)),
exact ⟨algebra_map R K x, hx, h.commutes x⟩,
end
@[simp] lemma map_eq_zero_iff [nontrivial R] : I.map h = 0 ↔ I = 0 :=
⟨imp_of_not_imp_not _ _ (map_ne_zero _),
λ hI, hI.symm ▸ map_zero h⟩
lemma coe_ideal_injective :
function.injective (coe : ideal R → fractional_ideal R⁰ K) :=
injective_of_le_imp_le _ (λ _ _, (coe_ideal_le_coe_ideal _).mp)
@[simp]
lemma coe_ideal_eq_zero_iff
{I : ideal R} : (I : fractional_ideal R⁰ K) = 0 ↔ I = ⊥ :=
by { rw ← coe_to_fractional_ideal_bot, exact coe_ideal_injective.eq_iff }
lemma coe_ideal_ne_zero_iff
{I : ideal R} : (I : fractional_ideal R⁰ K) ≠ 0 ↔ I ≠ ⊥ :=
not_iff_not.mpr coe_ideal_eq_zero_iff
lemma coe_ideal_ne_zero
{I : ideal R} (hI : I ≠ ⊥) : (I : fractional_ideal R⁰ K) ≠ 0 :=
coe_ideal_ne_zero_iff.mpr hI
end is_fraction_ring
section quotient
/-!
### `quotient` section
This section defines the ideal quotient of fractional ideals.
In this section we need that each non-zero `y : R` has an inverse in
the localization, i.e. that the localization is a field. We satisfy this
assumption by taking `S = non_zero_divisors R`, `R`'s localization at which
is a field because `R` is a domain.
-/
open_locale classical
variables {R₁ : Type*} [integral_domain R₁] {K : Type*} [field K]
variables [algebra R₁ K] [frac : is_fraction_ring R₁ K]
instance : nontrivial (fractional_ideal R₁⁰ K) :=
⟨⟨0, 1, λ h,
have this : (1 : K) ∈ (0 : fractional_ideal R₁⁰ K) :=
by { rw ← (algebra_map R₁ K).map_one, simpa only [h] using coe_mem_one R₁⁰ 1 },
one_ne_zero ((mem_zero_iff _).mp this)⟩⟩
include frac
lemma fractional_div_of_nonzero {I J : fractional_ideal R₁⁰ K} (h : J ≠ 0) :
is_fractional R₁⁰ (I / J : submodule R₁ K) :=
begin
rcases I with ⟨I, aI, haI, hI⟩,
rcases J with ⟨J, aJ, haJ, hJ⟩,
obtain ⟨y, mem_J, not_mem_zero⟩ := set_like.exists_of_lt (bot_lt_iff_ne_bot.mpr h),
obtain ⟨y', hy'⟩ := hJ y mem_J,
use (aI * y'),
split,
{ apply (non_zero_divisors R₁).mul_mem haI (mem_non_zero_divisors_iff_ne_zero.mpr _),
intro y'_eq_zero,
have : algebra_map R₁ K aJ * y = 0,
{ rw [← algebra.smul_def, ←hy', y'_eq_zero, ring_hom.map_zero] },
have y_zero := (mul_eq_zero.mp this).resolve_left
(mt ((algebra_map R₁ K).injective_iff.1 (is_fraction_ring.injective _ _) _)
(mem_non_zero_divisors_iff_ne_zero.mp haJ)),
exact not_mem_zero ((mem_zero_iff R₁⁰).mpr y_zero) },
intros b hb,
convert hI _ (hb _ (submodule.smul_mem _ aJ mem_J)) using 1,
rw [← hy', mul_comm b, ← algebra.smul_def, mul_smul]
end
noncomputable instance fractional_ideal_has_div :
has_div (fractional_ideal R₁⁰ K) :=
⟨ λ I J, if h : J = 0 then 0 else ⟨I / J, fractional_div_of_nonzero h⟩ ⟩
variables {I J : fractional_ideal R₁⁰ K} [ J ≠ 0 ]
@[simp] lemma div_zero {I : fractional_ideal R₁⁰ K} :
I / 0 = 0 :=
dif_pos rfl
lemma div_nonzero {I J : fractional_ideal R₁⁰ K} (h : J ≠ 0) :
(I / J) = ⟨I / J, fractional_div_of_nonzero h⟩ :=
dif_neg h
@[simp] lemma coe_div {I J : fractional_ideal R₁⁰ K} (hJ : J ≠ 0) :
(↑(I / J) : submodule R₁ K) = ↑I / (↑J : submodule R₁ K) :=
begin
unfold has_div.div,
simp only [dif_neg hJ, coe_mk, val_eq_coe],
end
lemma mem_div_iff_of_nonzero {I J : fractional_ideal R₁⁰ K} (h : J ≠ 0) {x} :
x ∈ I / J ↔ ∀ y ∈ J, x * y ∈ I :=
by { rw div_nonzero h, exact submodule.mem_div_iff_forall_mul_mem }
lemma mul_one_div_le_one {I : fractional_ideal R₁⁰ K} : I * (1 / I) ≤ 1 :=
begin
by_cases hI : I = 0,
{ rw [hI, div_zero, mul_zero],
exact zero_le 1 },
{ rw [← coe_le_coe, coe_mul, coe_div hI, coe_one],
apply submodule.mul_one_div_le_one },
end
lemma le_self_mul_one_div {I : fractional_ideal R₁⁰ K} (hI : I ≤ (1 : fractional_ideal R₁⁰ K)) :
I ≤ I * (1 / I) :=
begin
by_cases hI_nz : I = 0,
{ rw [hI_nz, div_zero, mul_zero], exact zero_le 0 },
{ rw [← coe_le_coe, coe_mul, coe_div hI_nz, coe_one],
rw [← coe_le_coe, coe_one] at hI,
exact submodule.le_self_mul_one_div hI },
end
lemma le_div_iff_of_nonzero {I J J' : fractional_ideal R₁⁰ K} (hJ' : J' ≠ 0) :
I ≤ J / J' ↔ ∀ (x ∈ I) (y ∈ J'), x * y ∈ J :=
⟨ λ h x hx, (mem_div_iff_of_nonzero hJ').mp (h hx),
λ h x hx, (mem_div_iff_of_nonzero hJ').mpr (h x hx) ⟩
lemma le_div_iff_mul_le {I J J' : fractional_ideal R₁⁰ K} (hJ' : J' ≠ 0) :
I ≤ J / J' ↔ I * J' ≤ J :=
begin
rw div_nonzero hJ',
convert submodule.le_div_iff_mul_le using 1,
rw [← coe_mul, coe_le_coe]
end
@[simp] lemma div_one {I : fractional_ideal R₁⁰ K} : I / 1 = I :=
begin
rw [div_nonzero (@one_ne_zero (fractional_ideal R₁⁰ K) _ _)],
ext,
split; intro h,
{ simpa using mem_div_iff_forall_mul_mem.mp h 1
((algebra_map R₁ K).map_one ▸ coe_mem_one R₁⁰ 1) },
{ apply mem_div_iff_forall_mul_mem.mpr,
rintros y ⟨y', _, rfl⟩,
rw mul_comm,
convert submodule.smul_mem _ y' h,
exact (algebra.smul_def _ _).symm }
end
omit frac
lemma ne_zero_of_mul_eq_one (I J : fractional_ideal R₁⁰ K) (h : I * J = 1) : I ≠ 0 :=
λ hI, @zero_ne_one (fractional_ideal R₁⁰ K) _ _ (by { convert h, simp [hI], })
include frac
theorem eq_one_div_of_mul_eq_one (I J : fractional_ideal R₁⁰ K) (h : I * J = 1) :
J = 1 / I :=
begin
have hI : I ≠ 0 := ne_zero_of_mul_eq_one I J h,
suffices h' : I * (1 / I) = 1,
{ exact (congr_arg units.inv $
@units.ext _ _ (units.mk_of_mul_eq_one _ _ h) (units.mk_of_mul_eq_one _ _ h') rfl) },
apply le_antisymm,
{ apply mul_le.mpr _,
intros x hx y hy,
rw mul_comm,
exact (mem_div_iff_of_nonzero hI).mp hy x hx },
rw ← h,
apply mul_left_mono I,
apply (le_div_iff_of_nonzero hI).mpr _,
intros y hy x hx,
rw mul_comm,
exact mul_mem_mul hx hy,
end
theorem mul_div_self_cancel_iff {I : fractional_ideal R₁⁰ K} :
I * (1 / I) = 1 ↔ ∃ J, I * J = 1 :=
⟨λ h, ⟨(1 / I), h⟩, λ ⟨J, hJ⟩, by rwa [← eq_one_div_of_mul_eq_one I J hJ]⟩
variables {K' : Type*} [field K'] [algebra R₁ K'] [is_fraction_ring R₁ K']
@[simp] lemma map_div (I J : fractional_ideal R₁⁰ K) (h : K ≃ₐ[R₁] K') :
(I / J).map (h : K →ₐ[R₁] K') = I.map h / J.map h :=
begin
by_cases H : J = 0,
{ rw [H, div_zero, map_zero, div_zero] },
{ apply coe_to_submodule_injective,
simp [div_nonzero H, div_nonzero (map_ne_zero _ H), submodule.map_div] }
end
@[simp] lemma map_one_div (I : fractional_ideal R₁⁰ K) (h : K ≃ₐ[R₁] K') :
(1 / I).map (h : K →ₐ[R₁] K') = 1 / I.map h :=
by rw [map_div, map_one]
end quotient
section field
variables {R₁ K L : Type*} [integral_domain R₁] [field K] [field L]
variables [algebra R₁ K] [is_fraction_ring R₁ K] [algebra K L] [is_fraction_ring K L]
lemma eq_zero_or_one (I : fractional_ideal K⁰ L) : I = 0 ∨ I = 1 :=
begin
rw or_iff_not_imp_left,
intro hI,
simp_rw [@set_like.ext_iff _ _ _ I 1, fractional_ideal.mem_one_iff],
intro x,
split,
{ intro x_mem,
obtain ⟨n, d, rfl⟩ := is_localization.mk'_surjective K⁰ x,
refine ⟨n / d, _⟩,
rw [ring_hom.map_div, is_fraction_ring.mk'_eq_div] },
{ rintro ⟨x, rfl⟩,
obtain ⟨y, y_ne, y_mem⟩ := fractional_ideal.exists_ne_zero_mem_is_integer hI,
rw [← div_mul_cancel x y_ne, ring_hom.map_mul, ← algebra.smul_def],
exact submodule.smul_mem I _ y_mem }
end
lemma eq_zero_or_one_of_is_field (hF : is_field R₁) (I : fractional_ideal R₁⁰ K) : I = 0 ∨ I = 1 :=
by { letI : field R₁ := hF.to_field R₁, exact eq_zero_or_one I }
end field
section principal_ideal_ring
variables {R₁ : Type*} [integral_domain R₁] {K : Type*} [field K]
variables [algebra R₁ K] [is_fraction_ring R₁ K]
open_locale classical
open submodule submodule.is_principal
include loc
lemma is_fractional_span_singleton (x : P) : is_fractional S (span R {x} : submodule R P) :=
let ⟨a, ha⟩ := exists_integer_multiple S x in
is_fractional_span_iff.mpr ⟨a, a.2, λ x' hx', (set.mem_singleton_iff.mp hx').symm ▸ ha⟩
variables (S)
/-- `span_singleton x` is the fractional ideal generated by `x` if `0 ∉ S` -/
@[irreducible]
def span_singleton (x : P) : fractional_ideal S P :=
⟨span R {x}, is_fractional_span_singleton x⟩
local attribute [semireducible] span_singleton
@[simp] lemma coe_span_singleton (x : P) :
(span_singleton S x : submodule R P) = span R {x} := rfl
@[simp] lemma mem_span_singleton {x y : P} :
x ∈ span_singleton S y ↔ ∃ (z : R), z • y = x :=
submodule.mem_span_singleton
lemma mem_span_singleton_self (x : P) :
x ∈ span_singleton S x :=
(mem_span_singleton S).mpr ⟨1, one_smul _ _⟩
variables {S}
lemma eq_span_singleton_of_principal (I : fractional_ideal S P)
[is_principal (I : submodule R P)] :
I = span_singleton S (generator (I : submodule R P)) :=
coe_to_submodule_injective (span_singleton_generator ↑I).symm
lemma is_principal_iff (I : fractional_ideal S P) :
is_principal (I : submodule R P) ↔ ∃ x, I = span_singleton S x :=
⟨λ h, ⟨@generator _ _ _ _ _ ↑I h, @eq_span_singleton_of_principal _ _ _ _ _ _ _ I h⟩,
λ ⟨x, hx⟩, { principal := ⟨x, trans (congr_arg _ hx) (coe_span_singleton _ x)⟩ } ⟩
@[simp] lemma span_singleton_zero : span_singleton S (0 : P) = 0 :=
by { ext, simp [submodule.mem_span_singleton, eq_comm] }
lemma span_singleton_eq_zero_iff {y : P} : span_singleton S y = 0 ↔ y = 0 :=
⟨λ h, span_eq_bot.mp (by simpa using congr_arg subtype.val h : span R {y} = ⊥) y (mem_singleton y),
λ h, by simp [h] ⟩
lemma span_singleton_ne_zero_iff {y : P} : span_singleton S y ≠ 0 ↔ y ≠ 0 :=
not_congr span_singleton_eq_zero_iff
@[simp] lemma span_singleton_one : span_singleton S (1 : P) = 1 :=
begin
ext,
refine (mem_span_singleton S).trans ((exists_congr _).trans (mem_one_iff S).symm),
intro x',
rw [algebra.smul_def, mul_one]
end
@[simp]
lemma span_singleton_mul_span_singleton (x y : P) :
span_singleton S x * span_singleton S y = span_singleton S (x * y) :=
begin
apply coe_to_submodule_injective,
simp only [coe_mul, coe_span_singleton, span_mul_span, singleton_mul_singleton],
end
@[simp]
lemma coe_ideal_span_singleton (x : R) :
(↑(span R {x} : ideal R) : fractional_ideal S P) = span_singleton S (algebra_map R P x) :=
begin
ext y,
refine (mem_coe_ideal S).trans (iff.trans _ (mem_span_singleton S).symm),
split,
{ rintros ⟨y', hy', rfl⟩,
obtain ⟨x', rfl⟩ := submodule.mem_span_singleton.mp hy',
use x',
rw [smul_eq_mul, ring_hom.map_mul, algebra.smul_def] },
{ rintros ⟨y', rfl⟩,
refine ⟨y' * x, submodule.mem_span_singleton.mpr ⟨y', rfl⟩, _⟩,
rw [ring_hom.map_mul, algebra.smul_def] }
end
@[simp]
lemma canonical_equiv_span_singleton {P'} [comm_ring P'] [algebra R P'] [is_localization S P']
(x : P) :
canonical_equiv S P P' (span_singleton S x) =
span_singleton S (is_localization.map P' (ring_hom.id R)
(λ y (hy : y ∈ S), show ring_hom.id R y ∈ S, from hy) x) :=
begin
apply set_like.ext_iff.mpr,
intro y,
split; intro h,
{ rw mem_span_singleton,
obtain ⟨x', hx', rfl⟩ := (mem_canonical_equiv_apply _ _ _).mp h,
obtain ⟨z, rfl⟩ := (mem_span_singleton _).mp hx',
use z,
rw is_localization.map_smul,
refl },
{ rw mem_canonical_equiv_apply,
obtain ⟨z, rfl⟩ := (mem_span_singleton _).mp h,
use z • x,
use (mem_span_singleton _).mpr ⟨z, rfl⟩,
simp [is_localization.map_smul] }
end
lemma mem_singleton_mul {x y : P} {I : fractional_ideal S P} :
y ∈ span_singleton S x * I ↔ ∃ y' ∈ I, y = x * y' :=
begin
split,
{ intro h,
apply fractional_ideal.mul_induction_on h,
{ intros x' hx' y' hy',
obtain ⟨a, ha⟩ := (mem_span_singleton S).mp hx',
use [a • y', submodule.smul_mem I a hy'],
rw [←ha, algebra.mul_smul_comm, algebra.smul_mul_assoc] },
{ exact ⟨0, submodule.zero_mem I, (mul_zero x).symm⟩ },
{ rintros _ _ ⟨y, hy, rfl⟩ ⟨y', hy', rfl⟩,
exact ⟨y + y', submodule.add_mem I hy hy', (mul_add _ _ _).symm⟩ },
{ rintros r _ ⟨y', hy', rfl⟩,
exact ⟨r • y', submodule.smul_mem I r hy', (algebra.mul_smul_comm _ _ _).symm ⟩ } },
{ rintros ⟨y', hy', rfl⟩,
exact mul_mem_mul ((mem_span_singleton S).mpr ⟨1, one_smul _ _⟩) hy' }
end
omit loc
lemma one_div_span_singleton (x : K) :
1 / span_singleton R₁⁰ x = span_singleton R₁⁰ (x⁻¹) :=
if h : x = 0 then by simp [h] else (eq_one_div_of_mul_eq_one _ _ (by simp [h])).symm
@[simp] lemma div_span_singleton (J : fractional_ideal R₁⁰ K) (d : K) :
J / span_singleton R₁⁰ d = span_singleton R₁⁰ (d⁻¹) * J :=
begin
rw ← one_div_span_singleton,
by_cases hd : d = 0,
{ simp only [hd, span_singleton_zero, div_zero, zero_mul] },
have h_spand : span_singleton R₁⁰ d ≠ 0 := mt span_singleton_eq_zero_iff.mp hd,
apply le_antisymm,
{ intros x hx,
rw [← mem_coe, coe_div h_spand, submodule.mem_div_iff_forall_mul_mem] at hx,
specialize hx d (mem_span_singleton_self R₁⁰ d),
have h_xd : x = d⁻¹ * (x * d), { field_simp },
rw [← mem_coe, coe_mul, one_div_span_singleton, h_xd],
exact submodule.mul_mem_mul (mem_span_singleton_self R₁⁰ _) hx },
{ rw [le_div_iff_mul_le h_spand, mul_assoc, mul_left_comm, one_div_span_singleton,
span_singleton_mul_span_singleton, inv_mul_cancel hd, span_singleton_one, mul_one],
exact le_refl J },
end
lemma exists_eq_span_singleton_mul (I : fractional_ideal R₁⁰ K) :
∃ (a : R₁) (aI : ideal R₁), a ≠ 0 ∧ I = span_singleton R₁⁰ (algebra_map R₁ K a)⁻¹ * aI :=
begin
obtain ⟨a_inv, nonzero, ha⟩ := I.is_fractional,
have nonzero := mem_non_zero_divisors_iff_ne_zero.mp nonzero,
have map_a_nonzero : algebra_map R₁ K a_inv ≠ 0 :=
mt is_fraction_ring.to_map_eq_zero_iff.mp nonzero,
refine ⟨a_inv,
submodule.comap (algebra.linear_map R₁ K)
↑(span_singleton R₁⁰ (algebra_map R₁ K a_inv) * I),
nonzero,
ext (λ x, iff.trans ⟨_, _⟩ mem_singleton_mul.symm)⟩,
{ intro hx,
obtain ⟨x', hx'⟩ := ha x hx,
rw algebra.smul_def at hx',
refine ⟨algebra_map R₁ K x', (mem_coe_ideal _).mpr ⟨x', mem_singleton_mul.mpr _, rfl⟩, _⟩,
{ exact ⟨x, hx, hx'⟩ },
{ rw [hx', ← mul_assoc, inv_mul_cancel map_a_nonzero, one_mul] } },
{ rintros ⟨y, hy, rfl⟩,
obtain ⟨x', hx', rfl⟩ := (mem_coe_ideal _).mp hy,
obtain ⟨y', hy', hx'⟩ := mem_singleton_mul.mp hx',
rw algebra.linear_map_apply at hx',
rwa [hx', ←mul_assoc, inv_mul_cancel map_a_nonzero, one_mul] }
end
instance is_principal {R} [integral_domain R] [is_principal_ideal_ring R]
[algebra R K] [is_fraction_ring R K]
(I : fractional_ideal R⁰ K) : (I : submodule R K).is_principal :=
begin
obtain ⟨a, aI, -, ha⟩ := exists_eq_span_singleton_mul I,
use (algebra_map R K a)⁻¹ * algebra_map R K (generator aI),
suffices : I = span_singleton R⁰ ((algebra_map R K a)⁻¹ * algebra_map R K (generator aI)),
{ exact congr_arg subtype.val this },
conv_lhs { rw [ha, ←span_singleton_generator aI] },
rw [coe_ideal_span_singleton (generator aI), span_singleton_mul_span_singleton]
end
end principal_ideal_ring
variables {R₁ : Type*} [integral_domain R₁]
variables {K : Type*} [field K] [algebra R₁ K] [frac : is_fraction_ring R₁ K]
local attribute [instance] classical.prop_decidable
lemma is_noetherian_zero : is_noetherian R₁ (0 : fractional_ideal R₁⁰ K) :=
is_noetherian_submodule.mpr (λ I (hI : I ≤ (0 : fractional_ideal R₁⁰ K)),
by { rw coe_zero at hI, rw le_bot_iff.mp hI, exact fg_bot })
lemma is_noetherian_iff {I : fractional_ideal R₁⁰ K} :
is_noetherian R₁ I ↔ ∀ J ≤ I, (J : submodule R₁ K).fg :=
is_noetherian_submodule.trans ⟨λ h J hJ, h _ hJ, λ h J hJ, h ⟨J, is_fractional_of_le hJ⟩ hJ⟩
lemma is_noetherian_coe_to_fractional_ideal [_root_.is_noetherian_ring R₁] (I : ideal R₁) :
is_noetherian R₁ (I : fractional_ideal R₁⁰ K) :=
begin
rw is_noetherian_iff,
intros J hJ,
obtain ⟨J, rfl⟩ := le_one_iff_exists_coe_ideal.mp (le_trans hJ coe_ideal_le_one),
exact fg_map (is_noetherian.noetherian J),
end
include frac
lemma is_noetherian_span_singleton_inv_to_map_mul (x : R₁) {I : fractional_ideal R₁⁰ K}
(hI : is_noetherian R₁ I) :
is_noetherian R₁ (span_singleton R₁⁰ (algebra_map R₁ K x)⁻¹ * I : fractional_ideal R₁⁰ K) :=
begin
by_cases hx : x = 0,
{ rw [hx, ring_hom.map_zero, _root_.inv_zero, span_singleton_zero, zero_mul],
exact is_noetherian_zero },
have h_gx : algebra_map R₁ K x ≠ 0,
from mt ((algebra_map R₁ K).injective_iff.mp (is_fraction_ring.injective _ _) x) hx,
have h_spanx : span_singleton R₁⁰ (algebra_map R₁ K x) ≠ 0,
from span_singleton_ne_zero_iff.mpr h_gx,
rw is_noetherian_iff at ⊢ hI,
intros J hJ,
rw [← div_span_singleton, le_div_iff_mul_le h_spanx] at hJ,
obtain ⟨s, hs⟩ := hI _ hJ,
use s * {(algebra_map R₁ K x)⁻¹},
rw [finset.coe_mul, finset.coe_singleton, ← span_mul_span, hs, ← coe_span_singleton R₁⁰,
← coe_mul, mul_assoc, span_singleton_mul_span_singleton, mul_inv_cancel h_gx,
span_singleton_one, mul_one],
end
/-- Every fractional ideal of a noetherian integral domain is noetherian. -/
theorem is_noetherian [_root_.is_noetherian_ring R₁] (I : fractional_ideal R₁⁰ K) :
is_noetherian R₁ I :=
begin
obtain ⟨d, J, h_nzd, rfl⟩ := exists_eq_span_singleton_mul I,
apply is_noetherian_span_singleton_inv_to_map_mul,
apply is_noetherian_coe_to_fractional_ideal,
end
section adjoin
include loc
omit frac
variables {R P} (S) (x : P) (hx : is_integral R x)
/-- `A[x]` is a fractional ideal for every integral `x`. -/
lemma is_fractional_adjoin_integral :
is_fractional S (algebra.adjoin R ({x} : set P)).to_submodule :=
is_fractional_of_fg (fg_adjoin_singleton_of_integral x hx)
/-- `fractional_ideal.adjoin_integral (S : submonoid R) x hx` is `R[x]` as a fractional ideal,
where `hx` is a proof that `x : P` is integral over `R`. -/
@[simps]
def adjoin_integral : fractional_ideal S P :=
⟨_, is_fractional_adjoin_integral S x hx⟩
lemma mem_adjoin_integral_self :
x ∈ adjoin_integral S x hx :=
algebra.subset_adjoin (set.mem_singleton x)
end adjoin
end fractional_ideal
|
7573e85b03486d42595e95cbe75ba255eb8d1e2e | e0f9ba56b7fedc16ef8697f6caeef5898b435143 | /src/field_theory/perfect_closure.lean | f434167151da9f1c12b3b34f1fe6cb82b900c392 | [
"Apache-2.0"
] | permissive | anrddh/mathlib | 6a374da53c7e3a35cb0298b0cd67824efef362b4 | a4266a01d2dcb10de19369307c986d038c7bb6a6 | refs/heads/master | 1,656,710,827,909 | 1,589,560,456,000 | 1,589,560,456,000 | 264,271,800 | 0 | 0 | Apache-2.0 | 1,589,568,062,000 | 1,589,568,061,000 | null | UTF-8 | Lean | false | false | 16,726 | lean | /-
Copyright (c) 2018 Kenny Lau. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenny Lau, Yury Kudryashov
-/
import algebra.char_p
import data.equiv.ring
import algebra.group_with_zero_power
/-!
# The perfect closure of a field
-/
universes u v
section defs
variables (K : Type u) [field K] (p : ℕ) [fact p.prime] [char_p K p]
/-- A perfect field is a field of characteristic p that has p-th root. -/
class perfect_field (K : Type u) [field K] (p : ℕ) [fact p.prime] [char_p K p] : Type u :=
(pth_root' : K → K)
(frobenius_pth_root' : ∀ x, frobenius K p (pth_root' x) = x)
/-- Frobenius automorphism of a perfect field. -/
def frobenius_equiv [perfect_field K p] : K ≃+* K :=
{ inv_fun := perfect_field.pth_root' p,
left_inv := λ x, frobenius_inj K p $ perfect_field.frobenius_pth_root' _,
right_inv := perfect_field.frobenius_pth_root',
.. frobenius K p }
/-- `p`-th root of a number in a `perfect_field` as a `ring_hom`. -/
def pth_root [perfect_field K p] : K →+* K :=
(frobenius_equiv K p).symm.to_ring_hom
end defs
section
variables {K : Type u} [field K] {L : Type v} [field L] (f : K →* L) (g : K →+* L)
{p : ℕ} [fact p.prime] [char_p K p] [perfect_field K p] [char_p L p] [perfect_field L p]
@[simp] lemma coe_frobenius_equiv : ⇑(frobenius_equiv K p) = frobenius K p := rfl
@[simp] lemma coe_frobenius_equiv_symm : ⇑(frobenius_equiv K p).symm = pth_root K p := rfl
@[simp] theorem frobenius_pth_root (x : K) : frobenius K p (pth_root K p x) = x :=
(frobenius_equiv K p).apply_symm_apply x
@[simp] theorem pth_root_frobenius (x : K) : pth_root K p (frobenius K p x) = x :=
(frobenius_equiv K p).symm_apply_apply x
theorem eq_pth_root_iff {x y : K} : x = pth_root K p y ↔ frobenius K p x = y :=
(frobenius_equiv K p).to_equiv.eq_symm_apply
theorem pth_root_eq_iff {x y : K} : pth_root K p x = y ↔ x = frobenius K p y :=
(frobenius_equiv K p).to_equiv.symm_apply_eq
theorem monoid_hom.map_pth_root (x : K) : f (pth_root K p x) = pth_root L p (f x) :=
eq_pth_root_iff.2 $ by rw [← f.map_frobenius, frobenius_pth_root]
theorem monoid_hom.map_iterate_pth_root (x : K) (n : ℕ) :
f (pth_root K p^[n] x) = (pth_root L p^[n] (f x)) :=
(nat.iterate₁ $ λ x, (f.map_pth_root x).symm).symm
theorem ring_hom.map_pth_root (x : K) :
g (pth_root K p x) = pth_root L p (g x) :=
g.to_monoid_hom.map_pth_root x
theorem ring_hom.map_iterate_pth_root (x : K) (n : ℕ) :
g (pth_root K p^[n] x) = (pth_root L p^[n] (g x)) :=
g.to_monoid_hom.map_iterate_pth_root x n
end
section
variables (K : Type u) [comm_ring K] (p : ℕ) [fact p.prime] [char_p K p]
/-- `perfect_closure K p` is the quotient by this relation. -/
inductive perfect_closure.r : (ℕ × K) → (ℕ × K) → Prop
| intro : ∀ n x, perfect_closure.r (n, x) (n+1, frobenius K p x)
mk_iff_of_inductive_prop perfect_closure.r perfect_closure.r_iff
/-- The perfect closure is the smallest extension that makes frobenius surjective. -/
def perfect_closure : Type u := quot (perfect_closure.r K p)
end
namespace perfect_closure
variables (K : Type u)
section ring
variables [comm_ring K] (p : ℕ) [fact p.prime] [char_p K p]
/-- Constructor for `perfect_closure`. -/
def mk (x : ℕ × K) : perfect_closure K p := quot.mk (r K p) x
@[simp] lemma quot_mk_eq_mk (x : ℕ × K) :
(quot.mk (r K p) x : perfect_closure K p) = mk K p x := rfl
variables {K p}
/-- Lift a function `ℕ × K → L` to a function on `perfect_closure K p`. -/
@[elab_as_eliminator]
def lift_on {L : Type*} (x : perfect_closure K p) (f : ℕ × K → L)
(hf : ∀ x y, r K p x y → f x = f y) : L :=
quot.lift_on x f hf
@[simp] lemma lift_on_mk {L : Sort*} (f : ℕ × K → L)
(hf : ∀ x y, r K p x y → f x = f y) (x : ℕ × K) :
(mk K p x).lift_on f hf = f x :=
rfl
@[elab_as_eliminator]
lemma induction_on (x : perfect_closure K p) {q : perfect_closure K p → Prop}
(h : ∀ x, q (mk K p x)) : q x :=
quot.induction_on x h
variables (K p)
private lemma mul_aux_left (x1 x2 y : ℕ × K) (H : r K p x1 x2) :
mk K p (x1.1 + y.1, ((frobenius K p)^[y.1] x1.2) * ((frobenius K p)^[x1.1] y.2)) =
mk K p (x2.1 + y.1, ((frobenius K p)^[y.1] x2.2) * ((frobenius K p)^[x2.1] y.2)) :=
match x1, x2, H with
| _, _, r.intro n x := quot.sound $ by rw [← nat.iterate_succ, nat.iterate_succ',
nat.iterate_succ', ← frobenius_mul, nat.succ_add]; apply r.intro
end
private lemma mul_aux_right (x y1 y2 : ℕ × K) (H : r K p y1 y2) :
mk K p (x.1 + y1.1, ((frobenius K p)^[y1.1] x.2) * ((frobenius K p)^[x.1] y1.2)) =
mk K p (x.1 + y2.1, ((frobenius K p)^[y2.1] x.2) * ((frobenius K p)^[x.1] y2.2)) :=
match y1, y2, H with
| _, _, r.intro n y := quot.sound $ by rw [← nat.iterate_succ, nat.iterate_succ',
nat.iterate_succ', ← frobenius_mul]; apply r.intro
end
instance : has_mul (perfect_closure K p) :=
⟨quot.lift (λ x:ℕ×K, quot.lift (λ y:ℕ×K, mk K p
(x.1 + y.1, ((frobenius K p)^[y.1] x.2) * ((frobenius K p)^[x.1] y.2))) (mul_aux_right K p x))
(λ x1 x2 (H : r K p x1 x2), funext $ λ e, quot.induction_on e $ λ y,
mul_aux_left K p x1 x2 y H)⟩
@[simp] lemma mk_mul_mk (x y : ℕ × K) :
mk K p x * mk K p y = mk K p
(x.1 + y.1, ((frobenius K p)^[y.1] x.2) * ((frobenius K p)^[x.1] y.2)) :=
rfl
instance : comm_monoid (perfect_closure K p) :=
{ mul_assoc := λ e f g, quot.induction_on e $ λ ⟨m, x⟩, quot.induction_on f $ λ ⟨n, y⟩,
quot.induction_on g $ λ ⟨s, z⟩, congr_arg (quot.mk _) $
by simp only [add_assoc, mul_assoc, nat.iterate₂ (frobenius_mul _),
← nat.iterate_add, add_comm, add_left_comm],
one := mk K p (0, 1),
one_mul := λ e, quot.induction_on e (λ ⟨n, x⟩, congr_arg (quot.mk _) $
by simp only [nat.iterate₀ (frobenius_one _), nat.iterate_zero, one_mul, zero_add]),
mul_one := λ e, quot.induction_on e (λ ⟨n, x⟩, congr_arg (quot.mk _) $
by simp only [nat.iterate₀ (frobenius_one _), nat.iterate_zero, mul_one, add_zero]),
mul_comm := λ e f, quot.induction_on e (λ ⟨m, x⟩, quot.induction_on f (λ ⟨n, y⟩,
congr_arg (quot.mk _) $ by simp only [add_comm, mul_comm])),
.. (infer_instance : has_mul (perfect_closure K p)) }
lemma one_def : (1 : perfect_closure K p) = mk K p (0, 1) := rfl
instance : inhabited (perfect_closure K p) := ⟨1⟩
private lemma add_aux_left (x1 x2 y : ℕ × K) (H : r K p x1 x2) :
mk K p (x1.1 + y.1, ((frobenius K p)^[y.1] x1.2) + ((frobenius K p)^[x1.1] y.2)) =
mk K p (x2.1 + y.1, ((frobenius K p)^[y.1] x2.2) + ((frobenius K p)^[x2.1] y.2)) :=
match x1, x2, H with
| _, _, r.intro n x := quot.sound $ by rw [← nat.iterate_succ, nat.iterate_succ',
nat.iterate_succ', ← frobenius_add, nat.succ_add]; apply r.intro
end
private lemma add_aux_right (x y1 y2 : ℕ × K) (H : r K p y1 y2) :
mk K p (x.1 + y1.1, ((frobenius K p)^[y1.1] x.2) + ((frobenius K p)^[x.1] y1.2)) =
mk K p (x.1 + y2.1, ((frobenius K p)^[y2.1] x.2) + ((frobenius K p)^[x.1] y2.2)) :=
match y1, y2, H with
| _, _, r.intro n y := quot.sound $ by rw [← nat.iterate_succ, nat.iterate_succ',
nat.iterate_succ', ← frobenius_add]; apply r.intro
end
instance : has_add (perfect_closure K p) :=
⟨quot.lift (λ x:ℕ×K, quot.lift (λ y:ℕ×K, mk K p
(x.1 + y.1, ((frobenius K p)^[y.1] x.2) + ((frobenius K p)^[x.1] y.2))) (add_aux_right K p x))
(λ x1 x2 (H : r K p x1 x2), funext $ λ e, quot.induction_on e $ λ y,
add_aux_left K p x1 x2 y H)⟩
@[simp] lemma mk_add_mk (x y : ℕ × K) :
mk K p x + mk K p y =
mk K p (x.1 + y.1, ((frobenius K p)^[y.1] x.2) + ((frobenius K p)^[x.1] y.2)) := rfl
instance : has_neg (perfect_closure K p) :=
⟨quot.lift (λ x:ℕ×K, mk K p (x.1, -x.2)) (λ x y (H : r K p x y), match x, y, H with
| _, _, r.intro n x := quot.sound $ by rw ← frobenius_neg; apply r.intro
end)⟩
@[simp] lemma neg_mk (x : ℕ × K) : - mk K p x = mk K p (x.1, -x.2) := rfl
instance : has_zero (perfect_closure K p) := ⟨mk K p (0, 0)⟩
lemma zero_def : (0 : perfect_closure K p) = mk K p (0, 0) := rfl
theorem mk_zero (n : ℕ) : mk K p (n, 0) = 0 :=
by induction n with n ih; [refl, rw ← ih]; symmetry; apply quot.sound;
have := r.intro n (0:K); rwa [frobenius_zero K p] at this
theorem r.sound (m n : ℕ) (x y : K) (H : frobenius K p^[m] x = y) :
mk K p (n, x) = mk K p (m + n, y) :=
by subst H; induction m with m ih; [simp only [zero_add, nat.iterate_zero],
rw [ih, nat.succ_add, nat.iterate_succ']]; apply quot.sound; apply r.intro
instance : comm_ring (perfect_closure K p) :=
{ add_assoc := λ e f g, quot.induction_on e $ λ ⟨m, x⟩, quot.induction_on f $ λ ⟨n, y⟩,
quot.induction_on g $ λ ⟨s, z⟩, congr_arg (quot.mk _) $
by simp only [add_assoc, nat.iterate₂ (frobenius_add K p),
(nat.iterate_add _ _ _ _).symm, add_comm, add_left_comm],
zero := 0,
zero_add := λ e, quot.induction_on e (λ ⟨n, x⟩, congr_arg (quot.mk _) $
by simp only [nat.iterate₀ (frobenius_zero K p), nat.iterate_zero, zero_add]),
add_zero := λ e, quot.induction_on e (λ ⟨n, x⟩, congr_arg (quot.mk _) $
by simp only [nat.iterate₀ (frobenius_zero K p), nat.iterate_zero, add_zero]),
add_left_neg := λ e, quot.induction_on e (λ ⟨n, x⟩,
by simp only [quot_mk_eq_mk, neg_mk, mk_add_mk,
nat.iterate₁ (frobenius_neg K p), add_left_neg, mk_zero]),
add_comm := λ e f, quot.induction_on e (λ ⟨m, x⟩, quot.induction_on f (λ ⟨n, y⟩,
congr_arg (quot.mk _) $ by simp only [add_comm])),
left_distrib := λ e f g, quot.induction_on e $ λ ⟨m, x⟩, quot.induction_on f $ λ ⟨n, y⟩,
quot.induction_on g $ λ ⟨s, z⟩, show quot.mk _ _ = quot.mk _ _,
by simp only [add_assoc, add_comm, add_left_comm]; apply r.sound;
simp only [nat.iterate₂ (frobenius_mul p), nat.iterate₂ (frobenius_add K p),
(nat.iterate_add _ _ _ _).symm, mul_add, add_comm, add_left_comm],
right_distrib := λ e f g, quot.induction_on e $ λ ⟨m, x⟩, quot.induction_on f $ λ ⟨n, y⟩,
quot.induction_on g $ λ ⟨s, z⟩, show quot.mk _ _ = quot.mk _ _,
by simp only [add_assoc, add_comm _ s, add_left_comm _ s]; apply r.sound;
simp only [nat.iterate₂ (frobenius_mul p), nat.iterate₂ (frobenius_add K p),
(nat.iterate_add _ _ _ _).symm, add_mul, add_comm, add_left_comm],
.. (infer_instance : has_add (perfect_closure K p)),
.. (infer_instance : has_neg (perfect_closure K p)),
.. (infer_instance : comm_monoid (perfect_closure K p)) }
theorem eq_iff' (x y : ℕ × K) : mk K p x = mk K p y ↔
∃ z, (frobenius K p^[y.1 + z] x.2) = (frobenius K p^[x.1 + z] y.2) :=
begin
split,
{ intro H,
replace H := quot.exact _ H,
induction H,
case eqv_gen.rel : x y H
{ cases H with n x, exact ⟨0, rfl⟩ },
case eqv_gen.refl : H
{ exact ⟨0, rfl⟩ },
case eqv_gen.symm : x y H ih
{ cases ih with w ih, exact ⟨w, ih.symm⟩ },
case eqv_gen.trans : x y z H1 H2 ih1 ih2
{ cases ih1 with z1 ih1,
cases ih2 with z2 ih2,
existsi z2+(y.1+z1),
rw [← add_assoc, nat.iterate_add, ih1],
rw [← nat.iterate_add, add_comm, nat.iterate_add, ih2],
rw [← nat.iterate_add],
simp only [add_comm, add_left_comm] } },
intro H,
cases x with m x,
cases y with n y,
cases H with z H, dsimp only at H,
rw [r.sound K p (n+z) m x _ rfl, r.sound K p (m+z) n y _ rfl, H],
rw [add_assoc, add_comm, add_comm z]
end
theorem nat_cast (n x : ℕ) : (x : perfect_closure K p) = mk K p (n, x) :=
begin
induction n with n ih,
{ induction x with x ih, {refl},
rw [nat.cast_succ, nat.cast_succ, ih], refl },
rw ih, apply quot.sound,
conv {congr, skip, skip, rw ← frobenius_nat_cast K p x},
apply r.intro
end
theorem int_cast (x : ℤ) : (x : perfect_closure K p) = mk K p (0, x) :=
by induction x; simp only [int.cast_of_nat, int.cast_neg_succ_of_nat, nat_cast K p 0]; refl
theorem nat_cast_eq_iff (x y : ℕ) : (x : perfect_closure K p) = y ↔ (x : K) = y :=
begin
split; intro H,
{ rw [nat_cast K p 0, nat_cast K p 0, eq_iff'] at H,
cases H with z H,
simpa only [zero_add, nat.iterate₀ (frobenius_nat_cast K p _)] using H },
rw [nat_cast K p 0, nat_cast K p 0, H]
end
instance : char_p (perfect_closure K p) p :=
begin
constructor, intro x, rw ← char_p.cast_eq_zero_iff K,
rw [← nat.cast_zero, nat_cast_eq_iff, nat.cast_zero]
end
theorem frobenius_mk (x : ℕ × K) :
(frobenius (perfect_closure K p) p : perfect_closure K p → perfect_closure K p)
(mk K p x) = mk _ _ (x.1, x.2^p) :=
begin
simp only [frobenius_def], cases x with n x, dsimp only,
suffices : ∀ p':ℕ, mk K p (n, x) ^ p' = mk K p (n, x ^ p'),
{ apply this },
intro p, induction p with p ih,
case nat.zero { apply r.sound, rw [(frobenius _ _).iterate_map_one, pow_zero] },
case nat.succ {
rw [pow_succ, ih],
symmetry,
apply r.sound,
simp only [pow_succ, (frobenius _ _).iterate_map_mul]
}
end
/-- Embedding of `K` into `perfect_closure K p` -/
def of : K →+* perfect_closure K p :=
{ to_fun := λ x, mk _ _ (0, x),
map_one' := rfl,
map_mul' := λ x y, rfl,
map_zero' := rfl,
map_add' := λ x y, rfl }
lemma of_apply (x : K) : of K p x = mk _ _ (0, x) := rfl
end ring
theorem eq_iff [integral_domain K] (p : ℕ) [fact p.prime] [char_p K p]
(x y : ℕ × K) : quot.mk (r K p) x = quot.mk (r K p) y ↔
(frobenius K p^[y.1] x.2) = (frobenius K p^[x.1] y.2) :=
(eq_iff' K p x y).trans ⟨λ ⟨z, H⟩, (frobenius_inj K p).iterate z $
by simpa only [add_comm, nat.iterate_add] using H,
λ H, ⟨0, H⟩⟩
section field
variables [field K] (p : ℕ) [fact p.prime] [char_p K p]
instance : has_inv (perfect_closure K p) :=
⟨quot.lift (λ x:ℕ×K, quot.mk (r K p) (x.1, x.2⁻¹)) (λ x y (H : r K p x y), match x, y, H with
| _, _, r.intro n x := quot.sound $ by { simp only [frobenius_def], rw ← inv_pow', apply r.intro }
end)⟩
instance : field (perfect_closure K p) :=
{ zero_ne_one := λ H, zero_ne_one ((eq_iff _ _ _ _).1 H),
mul_inv_cancel := λ e, induction_on e $ λ ⟨m, x⟩ H,
have _ := mt (eq_iff _ _ _ _).2 H, (eq_iff _ _ _ _).2
(by simp only [(frobenius _ _).iterate_map_one, (frobenius K p).iterate_map_zero,
nat.iterate_zero, ← (frobenius _ p).iterate_map_mul] at this ⊢;
rw [mul_inv_cancel this, (frobenius _ _).iterate_map_one]),
inv_zero := congr_arg (quot.mk (r K p)) (by rw [inv_zero]),
.. (infer_instance : has_inv (perfect_closure K p)),
.. (infer_instance : comm_ring (perfect_closure K p)) }
instance : perfect_field (perfect_closure K p) p :=
{ pth_root' := λ e, lift_on e (λ x, mk K p (x.1 + 1, x.2)) (λ x y H,
match x, y, H with
| _, _, r.intro n x := quot.sound (r.intro _ _)
end),
frobenius_pth_root' := λ e, induction_on e (λ ⟨n, x⟩,
by { simp only [lift_on_mk, frobenius_mk], exact (quot.sound $ r.intro _ _).symm }) }
theorem eq_pth_root (x : ℕ × K) :
mk K p x = (pth_root (perfect_closure K p) p^[x.1] (of K p x.2)) :=
begin
rcases x with ⟨m, x⟩,
induction m with m ih, {refl},
rw [nat.iterate_succ', ← ih]; refl
end
/-- Given a field `K` of characteristic `p` and a perfect field `L` of the same characteristic,
any homomorphism `K →+* L` can be lifted to `perfect_closure K p`. -/
def lift (L : Type v) [field L] [char_p L p] [perfect_field L p] :
(K →+* L) ≃ (perfect_closure K p →+* L) :=
begin
refine_struct { .. },
field to_fun { intro f,
refine_struct { .. },
field to_fun { refine λ e, lift_on e (λ x, pth_root L p^[x.1] (f x.2)) _,
rintro a b ⟨n⟩,
simp only [f.map_frobenius, nat.iterate_succ, pth_root_frobenius] },
field map_one' { exact f.map_one },
field map_zero' { exact f.map_zero },
field map_mul' { rintro ⟨x⟩ ⟨y⟩,
simp only [quot_mk_eq_mk, lift_on_mk, mk_mul_mk, ring_hom.map_iterate_frobenius,
ring_hom.iterate_map_mul, ring_hom.map_mul],
rw [nat.iterate_add, nat.iterate_cancel, add_comm, nat.iterate_add, nat.iterate_cancel];
exact pth_root_frobenius },
field map_add' { rintro ⟨x⟩ ⟨y⟩,
simp only [quot_mk_eq_mk, lift_on_mk, mk_add_mk, ring_hom.map_iterate_frobenius,
ring_hom.iterate_map_add, ring_hom.map_add],
rw [nat.iterate_add, nat.iterate_cancel, add_comm x.1, nat.iterate_add, nat.iterate_cancel];
exact pth_root_frobenius } },
field inv_fun { exact λ f, f.comp (of K p) },
field left_inv { intro f, ext x, refl },
field right_inv { intro f, ext ⟨x⟩,
simp only [ring_hom.coe_mk, quot_mk_eq_mk, ring_hom.comp_apply, lift_on_mk],
rw [eq_pth_root, ring_hom.map_iterate_pth_root] }
end
end field
end perfect_closure
|
6df2f0b1ef7dc4783ae05c6ab1f47835dbb885e2 | dbd2d342e674b01c9097c761d49e297e3ce18292 | /src/leanpkg/main.lean | 2c0771edf853be5ba1c139776e97e91f3f2793fa | [] | no_license | cipher1024/lean-depot | b4c3b096fb2d9b669d171fe9b2395f0822821dbe | 4b2b879f429eac70dc4e9fa210a3d92f1db2b7f5 | refs/heads/master | 1,599,422,553,618 | 1,574,715,661,000 | 1,574,715,661,000 | 220,534,909 | 1 | 0 | null | 1,574,715,992,000 | 1,573,241,547,000 | Lean | UTF-8 | Lean | false | false | 12,214 | lean | /-
Copyright (c) 2017 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Gabriel Ebner
-/
import leanpkg.resolve leanpkg.git
namespace leanpkg
def write_file (fn : string) (cnts : string) (mode := io.mode.write) : io unit := do
h ← io.mk_file_handle fn io.mode.write,
io.fs.write h cnts.to_char_buffer,
io.fs.close h
def read_manifest : io manifest := do
m ← manifest.from_file leanpkg_toml_fn,
when (m.lean_version ≠ lean_version_string) $
io.print_ln $ "\nWARNING: Lean version mismatch: installed version is " ++ lean_version_string
++ ", but package requires " ++ m.lean_version ++ "\n",
return m
def write_manifest (d : manifest) (fn := leanpkg_toml_fn) : io unit :=
write_file fn (repr d)
-- TODO(gabriel): implement a cross-platform api
def get_dot_lean_dir : io string := do
some home ← io.env.get "HOME" | io.fail "environment variable HOME is not set",
return $ home ++ "/.lean"
def mk_path_file : ∀ (paths : list string), string
| [] := "builtin_path\n"
| (x :: xs) := mk_path_file xs ++ "path " ++ x ++ "\n"
def configure : io unit := do
d ← read_manifest,
io.put_str_ln $ "configuring " ++ d.name ++ " " ++ d.version,
when (d.path ≠ some "src") $ io.put_str_ln "WARNING: leanpkg configurations not specifying `path = \"src\"` are deprecated.",
assg ← solve_deps d,
path_file_cnts ← mk_path_file <$> construct_path assg,
write_file "leanpkg.path" path_file_cnts
def call_lean (manifest : leanpkg.manifest) (args : list string) : io unit := do
exec_cmd {
cmd := "elan",
args := "run" :: manifest.lean_version :: "lean" :: args,
env := [("LEAN_PATH", none)]
}
def make (lean_args : list string) : io unit := do
manifest ← read_manifest,
let t_out := match manifest.timeout with some t := ["-T", repr t] | none := [] end,
call_lean manifest $ t_out ++ ["--make"] ++ manifest.effective_path ++ lean_args
def build (lean_args : list string) := configure >> make lean_args
def make_test (lean_args : list string) : io unit := do
manifest ← read_manifest,
call_lean manifest $ ["--make", "test"] ++ lean_args
def test (lean_args : list string) := build lean_args >> make_test lean_args
def init_gitignore_contents :=
"*.olean
/_target
/leanpkg.path
"
def init_pkg (n : string) (from_new : bool) : io unit := do
write_manifest { name := n, path := "src", version := "0.1" } leanpkg_toml_fn,
src_ex ← io.fs.dir_exists "src",
when (¬src_ex) (do
when ¬from_new $ io.put_str_ln "Move existing .lean files into the 'src' folder.",
io.fs.mkdir "src" >> return ()),
write_file ".gitignore" init_gitignore_contents io.mode.append,
git_ex ← io.fs.dir_exists ".git",
when (¬git_ex) (do {
exec_cmd {cmd := "git", args := ["init", "-q"]},
when (upstream_git_branch ≠ "master") $
exec_cmd {cmd := "git", args := ["checkout", "-b", upstream_git_branch]}
} <|> io.print_ln "WARNING: failed to initialize git repository"),
configure
def init (n : string) := init_pkg n false
-- TODO(gabriel): windows
def basename (s : string) : string :=
s.fold "" $ λ s c, if c = '/' then "" else s.str c
def add_dep_to_manifest (dep : dependency) : io unit := do
d ← read_manifest,
let d' := { d with dependencies := d.dependencies.filter (λ old_dep, old_dep.name ≠ dep.name) ++ [dep] },
write_manifest d'
def strip_dot_git (url : string) : string :=
if url.backn 4 = ".git" then url.popn_back 4 else url
def looks_like_git_url (dep : string) : bool :=
':' ∈ dep.to_list
def parse_add_dep (dep : string) (branch : option string) : io dependency :=
if looks_like_git_url dep then
pure { name := basename (strip_dot_git dep), src := source.git dep (git_default_revision branch) branch }
else do
ex ← io.fs.dir_exists dep,
if ex then match branch with
| some branch := io.fail sformat!"extraneous trailing path argument '{branch}'"
| none := pure { name := basename dep, src := source.path dep }
end
else do
[user, repo] ← pure $ dep.split (= '/')
| io.fail sformat!"path '{dep}' does not exist",
pure { name := repo, src := source.git sformat!"https://github.com/{user}/{repo}" (git_default_revision branch) branch }
def absolutize_dep (dep : dependency) : io dependency :=
match dep.src with
| source.path p := do
cwd ← io.env.get_cwd,
pure {src := source.path (resolve_dir p cwd), ..dep}
| _ := pure dep
end
def parse_install_dep (dep : string) (branch : option string) : io dependency := do
dep ← parse_add_dep dep none,
dep ← absolutize_dep dep,
dot_lean_dir ← get_dot_lean_dir,
io.fs.mkdir dot_lean_dir tt,
let user_toml_fn := dot_lean_dir ++ "/" ++ leanpkg_toml_fn,
ex ← io.fs.file_exists user_toml_fn,
when (¬ ex) $ write_manifest {
name := "_user_local_packages",
version := "1"
} user_toml_fn,
change_dir dot_lean_dir,
return dep
def fixup_git_version (dir : string) : ∀ (src : source), io source
| (source.git url _ _) := do
rev ← git_head_revision dir,
return $ source.git url rev none
| src := return src
def add (dep : dependency) : io unit := do
(_, assg) ← (materialize "." dep).run assignment.empty,
some downloaded_path ← return (assg.find dep.name),
manif ← manifest.from_file (downloaded_path ++ "/" ++ leanpkg_toml_fn),
src ← fixup_git_version downloaded_path dep.src,
let dep := { dep with name := manif.name, src := src },
add_dep_to_manifest dep,
configure
def new (dir : string) := do
ex ← io.fs.dir_exists dir,
when ex $ io.fail $ "directory already exists: " ++ dir,
io.fs.mkdir dir tt,
change_dir dir,
init_pkg (basename dir) true
def upgrade_dep (assg : assignment) (d : dependency) : io dependency :=
match d.src with
| (source.git url rev branch) := (do
some path ← return (assg.find d.name) | io.fail "unresolved dependency",
new_rev ← git_latest_origin_revision path branch,
return {d with src := source.git url new_rev branch})
<|> return d
| _ := return d
end
def upgrade := do
m ← read_manifest,
assg ← solve_deps m,
ds' ← m.dependencies.mmap (upgrade_dep assg),
write_manifest {m with dependencies := ds'},
configure
def usage :=
"Lean package manager, version " ++ ui_lean_version_string ++ "
Usage: leanpkg <command>
configure download dependencies
build [-- <lean-args>] download dependencies and build *.olean files
test [-- <lean-args>] download dependencies, build *.olean files, and run test files
new <dir> create a Lean package in a new directory
init <name> create a Lean package in the current directory
add <url> [branch] add a dependency from a git repository (uses latest upstream revision)
add <dir> add a local dependency
upgrade upgrade all git dependencies to the latest upstream version
install <url> [branch] install a user-wide package from git
install <dir> install a user-wide package from a local directory
dump print the parsed leanpkg.toml file (for debugging)
See `leanpkg help <command>` for more information on a specific command."
def main : ∀ (cmd : string) (leanpkg_args lean_args : list string), io unit
| "configure" [] [] := configure
| "build" _ lean_args := build lean_args
| "test" _ lean_args := test lean_args
| "new" [dir] [] := new dir
| "init" [name] [] := init name
| "add" [dep] [] := parse_add_dep dep none >>= add
| "add" [dep] [branch] := parse_add_dep dep branch >>= add
| "upgrade" [] [] := upgrade
| "install" [dep] [] := parse_install_dep dep none >>= add >> build []
| "install" [dep] [branch] := parse_install_dep dep branch >>= add >> build []
| "dump" [] [] := read_manifest >>= io.print_ln ∘ repr
| "help" ["configure"] [] := io.print_ln "Download dependencies
Usage:
leanpkg configure
This command sets up the `_target/deps` directory and the `leanpkg.path` file.
For each (transitive) git dependency, the specified commit is checked out
into a sub-directory of `_target/deps`. If there are dependencies on multiple
versions of the same package, the version materialized is undefined.
The `leanpkg.path` file used to resolve Lean imports is populated with paths
to the `src` directories of all (transitive) dependencies. No copy is made
of local dependencies."
| "help" ["build"] [] := io.print_ln "Download dependencies and build *.olean files
Usage:
leanpkg build [-- <lean-args>]
This command invokes `leanpkg configure` followed by
`lean --make src <lean-args>`, building the package's Lean files as well as
(transitively) imported files of dependencies. If defined, the `package.timeout`
configuration value is passed to Lean via its `-T` parameter."
| "help" ["test"] [] := io.print_ln "Download dependencies, build *.olean files, and run test files
Usage:
leanpkg test [-- <lean-args>]
This command invokes `leanpkg build <lean-args>` followed by
`lean --make test <lean-args>`, executing the package's test files. A failed
test should generate a Lean error message, which makes this command return a
non-zero exit code."
| "help" ["add"] [] := io.print_ln sformat!"Add a dependency
Usage:
leanpkg add <local-path>
leanpkg add <git-url>
leanpkg add <github-user>/<github-repo>
Examples:
leanpkg add ../mathlib
leanpkg add https://github.com/leanprover/mathlib
leanpkg add leanprover/mathlib
This command adds the specified local or git dependency, then calls
`leanpkg configure`. For git dependencies, the pinned commit is
the head of the branch `lean-<version>` (e.g. `lean-3.3.0`) on stable
releases of Lean, or else `master` (current branch: {upstream_git_branch})."
| "help" ["new"] [] := io.print_ln "Create a new Lean package in a new directory
Usage:
leanpkg new <path>/.../<name>
This command creates a new Lean package named '<name>' in a new directory
`<path>/.../<name>`. A new git repository is initialized to the branch name
expected by `leanpkg add` (see `leanpkg help add`).
For converting an existing directory into a Lean package, use `leanpkg init`."
| "help" ["init"] [] := io.print_ln "Create a new Lean package in the current directory
Usage:
leanpkg init <name>
This command creates a new Lean package with the given name in the current
directory. Existing Lean source files should be moved into the new `src`
directory."
| "help" ["upgrade"] [] := io.print_ln "Upgrade all git dependencies to the latest upstream version
Usage:
leanpkg upgrade
This command fetches the remote repositories of all git dependencies and updates
the pinned commits to the head of the respective branch (see
`leanpkg help add`)."
| "help" ["install"] [] := io.print_ln "Install a user-wide package
Usage:
leanpkg install <local-path>
leanpkg install <git-url>
leanpkg install <github-user>/<github-repo>
This command adds a dependency to a user-wide \"meta\" package in `~/.lean`.
For files not part of a Lean package, Lean falls back to the core library
and this meta package for import resolution.
For removing or upgrading user-wide dependencies, you currently have to change
into `~/.lean` yourself and edit the leanpkg.toml file or execute
`leanpkg upgrade`, respectively."
| "help" _ [] := io.print_ln usage
| _ _ _ := io.fail usage
private def split_cmdline_args_core : list string → list string × list string
| [] := ([], [])
| (arg::args) := if arg = "--"
then ([], args)
else match split_cmdline_args_core args with
| (outer_args, inner_args) := (arg::outer_args, inner_args)
end
def split_cmdline_args : list string → io (string × list string × list string)
| [] := io.fail usage
| [cmd] := return (cmd, [], [])
| (cmd::rest) := match split_cmdline_args_core rest with
| (outer_args, inner_args) := return (cmd, outer_args, inner_args)
end
end leanpkg
-- def main : io unit :=
-- do (cmd, outer_args, inner_args) ← io.cmdline_args >>= leanpkg.split_cmdline_args,
-- leanpkg.main cmd outer_args inner_args
|
48118cf9883968e0f0ec3046d30906dca5874736 | 618003631150032a5676f229d13a079ac875ff77 | /src/linear_algebra/linear_action.lean | a216426d49323aaae82f79dc742714c859b98f2e | [
"Apache-2.0"
] | permissive | awainverse/mathlib | 939b68c8486df66cfda64d327ad3d9165248c777 | ea76bd8f3ca0a8bf0a166a06a475b10663dec44a | refs/heads/master | 1,659,592,962,036 | 1,590,987,592,000 | 1,590,987,592,000 | 268,436,019 | 1 | 0 | Apache-2.0 | 1,590,990,500,000 | 1,590,990,500,000 | null | UTF-8 | Lean | false | false | 3,406 | lean | /-
Copyright (c) 2020 Oliver Nash. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Oliver Nash
-/
import linear_algebra.basic
/-!
# Linear actions
For modules M and N, we can regard a linear map M →ₗ End N as a "linear action" of M on N.
In this file we introduce the class `linear_action` to make it easier to work with such actions.
## Tags
linear action
-/
universes u v
section linear_action
variables (R : Type u) (M N : Type v)
variables [comm_ring R] [add_comm_group M] [add_comm_group N] [module R M] [module R N]
section prio
set_option default_priority 100 -- see Note [default priority]
/--
A binary operation representing one module acting linearly on another.
-/
class linear_action :=
(act : M → N → N)
(add_act : ∀ (m m' : M) (n : N), act (m + m') n = act m n + act m' n)
(act_add : ∀ (m : M) (n n' : N), act m (n + n') = act m n + act m n')
(act_smul : ∀ (r : R) (m : M) (n : N), act (r • m) n = r • (act m n))
(smul_act : ∀ (r : R) (m : M) (n : N), act m (r • n) = act (r • m) n)
end prio
@[simp] lemma zero_linear_action [linear_action R M N] (n : N) :
linear_action.act R (0 : M) n = 0 :=
begin
let z := linear_action.act R (0 : M) n,
have H : z + z = z + 0 := by { rw ←linear_action.add_act, simp, },
exact add_left_cancel H,
end
@[simp] lemma linear_action_zero [linear_action R M N] (m : M) :
linear_action.act R m (0 : N) = 0 :=
begin
let z := linear_action.act R m (0 : N),
have H : z + z = z + 0 := by { rw ←linear_action.act_add, simp, },
exact add_left_cancel H,
end
@[simp] lemma linear_action_add_act [linear_action R M N] (m m' : M) (n : N) :
linear_action.act R (m + m') n = linear_action.act R m n +
linear_action.act R m' n :=
linear_action.add_act m m' n
@[simp] lemma linear_action_act_add [linear_action R M N] (m : M) (n n' : N) :
linear_action.act R m (n + n') = linear_action.act R m n +
linear_action.act R m n' :=
linear_action.act_add m n n'
@[simp] lemma linear_action_act_smul [linear_action R M N] (r : R) (m : M) (n : N) :
linear_action.act R (r • m) n = r • (linear_action.act R m n) :=
linear_action.act_smul r m n
@[simp] lemma linear_action_smul_act [linear_action R M N] (r : R) (m : M) (n : N) :
linear_action.act R m (r • n) = linear_action.act R (r • m) n :=
linear_action.smul_act r m n
end linear_action
namespace linear_action
variables (R : Type u) (M N : Type v)
variables [comm_ring R] [add_comm_group M] [add_comm_group N] [module R M] [module R N]
/--
A linear map to the endomorphism algebra yields a linear action.
-/
def of_endo_map (α : M →ₗ[R] module.End R N) : linear_action R M N :=
{ act := λ m n, α m n,
add_act := by { intros, rw linear_map.map_add, simp, },
act_add := by { intros, simp, },
act_smul := by { intros, rw linear_map.map_smul, simp, },
smul_act := by { intros, repeat { rw linear_map.map_smul }, simp, } }
/--
A linear action yields a linear map to the endomorphism algebra.
-/
def to_endo_map (α : linear_action R M N) : M →ₗ[R] module.End R N :=
{ to_fun := λ m,
{ to_fun := λ n, linear_action.act R m n,
add := by { intros, simp, },
smul := by { intros, simp, }, },
add := by { intros, ext, simp, },
smul := by { intros, ext, simp, } }
end linear_action
|
8b5e70d0ec99f29f6ad714bfb42aefc17ca4114f | 8cae430f0a71442d02dbb1cbb14073b31048e4b0 | /src/data/real/cardinality.lean | 189427b8ebc41b53bd94046c98a23d3703d03e19 | [
"Apache-2.0"
] | permissive | leanprover-community/mathlib | 56a2cadd17ac88caf4ece0a775932fa26327ba0e | 442a83d738cb208d3600056c489be16900ba701d | refs/heads/master | 1,693,584,102,358 | 1,693,471,902,000 | 1,693,471,902,000 | 97,922,418 | 1,595 | 352 | Apache-2.0 | 1,694,693,445,000 | 1,500,624,130,000 | Lean | UTF-8 | Lean | false | false | 9,874 | lean | /-
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
-/
import analysis.specific_limits.basic
import data.rat.denumerable
import data.set.pointwise.interval
import set_theory.cardinal.continuum
/-!
# The cardinality of the reals
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
This file shows that the real numbers have cardinality continuum, i.e. `#ℝ = 𝔠`.
We show that `#ℝ ≤ 𝔠` by noting that every real number is determined by a Cauchy-sequence of the
form `ℕ → ℚ`, which has cardinality `𝔠`. To show that `#ℝ ≥ 𝔠` we define an injection from
`{0, 1} ^ ℕ` to `ℝ` with `f ↦ Σ n, f n * (1 / 3) ^ n`.
We conclude that all intervals with distinct endpoints have cardinality continuum.
## Main definitions
* `cardinal.cantor_function` is the function that sends `f` in `{0, 1} ^ ℕ` to `ℝ` by
`f ↦ Σ' n, f n * (1 / 3) ^ n`
## Main statements
* `cardinal.mk_real : #ℝ = 𝔠`: the reals have cardinality continuum.
* `cardinal.not_countable_real`: the universal set of real numbers is not countable.
We can use this same proof to show that all the other sets in this file are not countable.
* 8 lemmas of the form `mk_Ixy_real` for `x,y ∈ {i,o,c}` state that intervals on the reals
have cardinality continuum.
## Notation
* `𝔠` : notation for `cardinal.continuum` in locale `cardinal`, defined in `set_theory.continuum`.
## Tags
continuum, cardinality, reals, cardinality of the reals
-/
open nat set
open_locale cardinal
noncomputable theory
namespace cardinal
variables {c : ℝ} {f g : ℕ → bool} {n : ℕ}
/-- The body of the sum in `cantor_function`.
`cantor_function_aux c f n = c ^ n` if `f n = tt`;
`cantor_function_aux c f n = 0` if `f n = ff`. -/
def cantor_function_aux (c : ℝ) (f : ℕ → bool) (n : ℕ) : ℝ := cond (f n) (c ^ n) 0
@[simp] lemma cantor_function_aux_tt (h : f n = tt) : cantor_function_aux c f n = c ^ n :=
by simp [cantor_function_aux, h]
@[simp] lemma cantor_function_aux_ff (h : f n = ff) : cantor_function_aux c f n = 0 :=
by simp [cantor_function_aux, h]
lemma cantor_function_aux_nonneg (h : 0 ≤ c) : 0 ≤ cantor_function_aux c f n :=
by { cases h' : f n; simp [h'], apply pow_nonneg h }
lemma cantor_function_aux_eq (h : f n = g n) :
cantor_function_aux c f n = cantor_function_aux c g n :=
by simp [cantor_function_aux, h]
lemma cantor_function_aux_zero (f : ℕ → bool) :
cantor_function_aux c f 0 = cond (f 0) 1 0 :=
by { cases h : f 0; simp [h] }
lemma cantor_function_aux_succ (f : ℕ → bool) :
(λ n, cantor_function_aux c f (n + 1)) = λ n, c * cantor_function_aux c (λ n, f (n + 1)) n :=
by { ext n, cases h : f (n + 1); simp [h, pow_succ] }
lemma summable_cantor_function (f : ℕ → bool) (h1 : 0 ≤ c) (h2 : c < 1) :
summable (cantor_function_aux c f) :=
begin
apply (summable_geometric_of_lt_1 h1 h2).summable_of_eq_zero_or_self,
intro n, cases h : f n; simp [h]
end
/-- `cantor_function c (f : ℕ → bool)` is `Σ n, f n * c ^ n`, where `tt` is interpreted as `1` and
`ff` is interpreted as `0`. It is implemented using `cantor_function_aux`. -/
def cantor_function (c : ℝ) (f : ℕ → bool) : ℝ := ∑' n, cantor_function_aux c f n
lemma cantor_function_le (h1 : 0 ≤ c) (h2 : c < 1) (h3 : ∀ n, f n → g n) :
cantor_function c f ≤ cantor_function c g :=
begin
apply tsum_le_tsum _ (summable_cantor_function f h1 h2) (summable_cantor_function g h1 h2),
intro n, cases h : f n, simp [h, cantor_function_aux_nonneg h1],
replace h3 : g n = tt := h3 n h, simp [h, h3]
end
lemma cantor_function_succ (f : ℕ → bool) (h1 : 0 ≤ c) (h2 : c < 1) :
cantor_function c f = cond (f 0) 1 0 + c * cantor_function c (λ n, f (n+1)) :=
begin
rw [cantor_function, tsum_eq_zero_add (summable_cantor_function f h1 h2)],
rw [cantor_function_aux_succ, tsum_mul_left, cantor_function_aux, pow_zero],
refl
end
/-- `cantor_function c` is strictly increasing with if `0 < c < 1/2`, if we endow `ℕ → bool` with a
lexicographic order. The lexicographic order doesn't exist for these infinitary products, so we
explicitly write out what it means. -/
lemma increasing_cantor_function (h1 : 0 < c) (h2 : c < 1 / 2) {n : ℕ} {f g : ℕ → bool}
(hn : ∀(k < n), f k = g k) (fn : f n = ff) (gn : g n = tt) :
cantor_function c f < cantor_function c g :=
begin
have h3 : c < 1, { apply h2.trans, norm_num },
induction n with n ih generalizing f g,
{ let f_max : ℕ → bool := λ n, nat.rec ff (λ _ _, tt) n,
have hf_max : ∀n, f n → f_max n,
{ intros n hn, cases n, rw [fn] at hn, contradiction, apply rfl },
let g_min : ℕ → bool := λ n, nat.rec tt (λ _ _, ff) n,
have hg_min : ∀n, g_min n → g n,
{ intros n hn, cases n, rw [gn], apply rfl, contradiction },
apply (cantor_function_le (le_of_lt h1) h3 hf_max).trans_lt,
refine lt_of_lt_of_le _ (cantor_function_le (le_of_lt h1) h3 hg_min),
have : c / (1 - c) < 1,
{ rw [div_lt_one, lt_sub_iff_add_lt],
{ convert add_lt_add h2 h2, norm_num },
rwa sub_pos },
convert this,
{ rw [cantor_function_succ _ (le_of_lt h1) h3, div_eq_mul_inv,
←tsum_geometric_of_lt_1 (le_of_lt h1) h3],
apply zero_add },
{ refine (tsum_eq_single 0 _).trans _,
{ intros n hn, cases n, contradiction, refl },
{ exact cantor_function_aux_zero _ }, } },
rw [cantor_function_succ f (le_of_lt h1) h3, cantor_function_succ g (le_of_lt h1) h3],
rw [hn 0 $ zero_lt_succ n],
apply add_lt_add_left, rw mul_lt_mul_left h1, exact ih (λ k hk, hn _ $ nat.succ_lt_succ hk) fn gn
end
/-- `cantor_function c` is injective if `0 < c < 1/2`. -/
lemma cantor_function_injective (h1 : 0 < c) (h2 : c < 1 / 2) :
function.injective (cantor_function c) :=
begin
intros f g hfg, classical, by_contra h, revert hfg,
have : ∃n, f n ≠ g n,
{ rw [←not_forall], intro h', apply h, ext, apply h' },
let n := nat.find this,
have hn : ∀ (k : ℕ), k < n → f k = g k,
{ intros k hk, apply of_not_not, exact nat.find_min this hk },
cases fn : f n,
{ apply ne_of_lt, refine increasing_cantor_function h1 h2 hn fn _,
apply eq_tt_of_not_eq_ff, rw [←fn], apply ne.symm, exact nat.find_spec this },
{ apply ne_of_gt, refine increasing_cantor_function h1 h2 (λ k hk, (hn k hk).symm) _ fn,
apply eq_ff_of_not_eq_tt, rw [←fn], apply ne.symm, exact nat.find_spec this }
end
/-- The cardinality of the reals, as a type. -/
lemma mk_real : #ℝ = 𝔠 :=
begin
apply le_antisymm,
{ rw real.equiv_Cauchy.cardinal_eq,
apply mk_quotient_le.trans, apply (mk_subtype_le _).trans_eq,
rw [← power_def, mk_nat, mk_rat, aleph_0_power_aleph_0] },
{ convert mk_le_of_injective (cantor_function_injective _ _),
rw [←power_def, mk_bool, mk_nat, two_power_aleph_0], exact 1 / 3, norm_num, norm_num }
end
/-- The cardinality of the reals, as a set. -/
lemma mk_univ_real : #(set.univ : set ℝ) = 𝔠 :=
by rw [mk_univ, mk_real]
/-- **Non-Denumerability of the Continuum**: The reals are not countable. -/
lemma not_countable_real : ¬ (set.univ : set ℝ).countable :=
by { rw [← le_aleph_0_iff_set_countable, not_le, mk_univ_real], apply cantor }
/-- The cardinality of the interval (a, ∞). -/
lemma mk_Ioi_real (a : ℝ) : #(Ioi a) = 𝔠 :=
begin
refine le_antisymm (mk_real ▸ mk_set_le _) _,
rw [← not_lt], intro h,
refine ne_of_lt _ mk_univ_real,
have hu : Iio a ∪ {a} ∪ Ioi a = set.univ,
{ convert Iic_union_Ioi, exact Iio_union_right },
rw ← hu,
refine lt_of_le_of_lt (mk_union_le _ _) _,
refine lt_of_le_of_lt (add_le_add_right (mk_union_le _ _) _) _,
have h2 : (λ x, a + a - x) '' Ioi a = Iio a,
{ convert image_const_sub_Ioi _ _, simp },
rw ← h2,
refine add_lt_of_lt (cantor _).le _ h,
refine add_lt_of_lt (cantor _).le (mk_image_le.trans_lt h) _,
rw mk_singleton,
exact one_lt_aleph_0.trans (cantor _)
end
/-- The cardinality of the interval [a, ∞). -/
lemma mk_Ici_real (a : ℝ) : #(Ici a) = 𝔠 :=
le_antisymm (mk_real ▸ mk_set_le _) (mk_Ioi_real a ▸ mk_le_mk_of_subset Ioi_subset_Ici_self)
/-- The cardinality of the interval (-∞, a). -/
lemma mk_Iio_real (a : ℝ) : #(Iio a) = 𝔠 :=
begin
refine le_antisymm (mk_real ▸ mk_set_le _) _,
have h2 : (λ x, a + a - x) '' Iio a = Ioi a,
{ convert image_const_sub_Iio _ _, simp },
exact mk_Ioi_real a ▸ h2 ▸ mk_image_le
end
/-- The cardinality of the interval (-∞, a]. -/
lemma mk_Iic_real (a : ℝ) : #(Iic a) = 𝔠 :=
le_antisymm (mk_real ▸ mk_set_le _) (mk_Iio_real a ▸ mk_le_mk_of_subset Iio_subset_Iic_self)
/-- The cardinality of the interval (a, b). -/
lemma mk_Ioo_real {a b : ℝ} (h : a < b) : #(Ioo a b) = 𝔠 :=
begin
refine le_antisymm (mk_real ▸ mk_set_le _) _,
have h1 : #((λ x, x - a) '' Ioo a b) ≤ #(Ioo a b) := mk_image_le,
refine le_trans _ h1,
rw [image_sub_const_Ioo, sub_self],
replace h := sub_pos_of_lt h,
have h2 : #(has_inv.inv '' Ioo 0 (b - a)) ≤ #(Ioo 0 (b - a)) := mk_image_le,
refine le_trans _ h2,
rw [image_inv, inv_Ioo_0_left h, mk_Ioi_real]
end
/-- The cardinality of the interval [a, b). -/
lemma mk_Ico_real {a b : ℝ} (h : a < b) : #(Ico a b) = 𝔠 :=
le_antisymm (mk_real ▸ mk_set_le _) (mk_Ioo_real h ▸ mk_le_mk_of_subset Ioo_subset_Ico_self)
/-- The cardinality of the interval [a, b]. -/
lemma mk_Icc_real {a b : ℝ} (h : a < b) : #(Icc a b) = 𝔠 :=
le_antisymm (mk_real ▸ mk_set_le _) (mk_Ioo_real h ▸ mk_le_mk_of_subset Ioo_subset_Icc_self)
/-- The cardinality of the interval (a, b]. -/
lemma mk_Ioc_real {a b : ℝ} (h : a < b) : #(Ioc a b) = 𝔠 :=
le_antisymm (mk_real ▸ mk_set_le _) (mk_Ioo_real h ▸ mk_le_mk_of_subset Ioo_subset_Ioc_self)
end cardinal
|
9618ec451d489ed20fc7094e9c3f66282f9deb05 | 9b9a16fa2cb737daee6b2785474678b6fa91d6d4 | /src/data/list/sigma.lean | a2ea1952c29d66b1bf78f7db62b5deeb5e6938aa | [
"Apache-2.0"
] | permissive | johoelzl/mathlib | 253f46daa30b644d011e8e119025b01ad69735c4 | 592e3c7a2dfbd5826919b4605559d35d4d75938f | refs/heads/master | 1,625,657,216,488 | 1,551,374,946,000 | 1,551,374,946,000 | 98,915,829 | 0 | 0 | Apache-2.0 | 1,522,917,267,000 | 1,501,524,499,000 | Lean | UTF-8 | Lean | false | false | 15,395 | lean | /-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Sean Leather
Functions on lists of sigma types.
-/
import data.list.perm
universes u v
namespace list
variables {α : Type u} {β : α → Type v}
/- keys -/
/-- List of keys from a list of key-value pairs -/
def keys : list (sigma β) → list α :=
map sigma.fst
@[simp] theorem keys_nil : @keys α β [] = [] :=
rfl
@[simp] theorem keys_cons {s} {l : list (sigma β)} : (s :: l).keys = s.1 :: l.keys :=
rfl
theorem mem_keys_of_mem {s : sigma β} {l : list (sigma β)} : s ∈ l → s.1 ∈ l.keys :=
mem_map_of_mem sigma.fst
theorem exists_of_mem_keys {a} {l : list (sigma β)} (h : a ∈ l.keys) :
∃ (b : β a), sigma.mk a b ∈ l :=
let ⟨⟨a', b'⟩, m, e⟩ := exists_of_mem_map h in
eq.rec_on e (exists.intro b' m)
theorem mem_keys {a} {l : list (sigma β)} : a ∈ l.keys ↔ ∃ (b : β a), sigma.mk a b ∈ l :=
⟨exists_of_mem_keys, λ ⟨b, h⟩, mem_keys_of_mem h⟩
theorem not_mem_keys {a} {l : list (sigma β)} : a ∉ l.keys ↔ ∀ b : β a, sigma.mk a b ∉ l :=
(not_iff_not_of_iff mem_keys).trans not_exists
theorem not_eq_key {a} {l : list (sigma β)} : a ∉ l.keys ↔ ∀ s : sigma β, s ∈ l → a ≠ s.1 :=
iff.intro
(λ h₁ s h₂ e, absurd (mem_keys_of_mem h₂) (by rwa e at h₁))
(λ f h₁, let ⟨b, h₂⟩ := exists_of_mem_keys h₁ in f _ h₂ rfl)
/- nodupkeys -/
def nodupkeys (l : list (sigma β)) : Prop :=
l.keys.nodup
theorem nodupkeys_iff_pairwise {l} : nodupkeys l ↔
pairwise (λ s s' : sigma β, s.1 ≠ s'.1) l := pairwise_map _
@[simp] theorem nodupkeys_nil : @nodupkeys α β [] := pairwise.nil
@[simp] theorem nodupkeys_cons {s : sigma β} {l : list (sigma β)} :
nodupkeys (s::l) ↔ s.1 ∉ l.keys ∧ nodupkeys l :=
by simp [keys, nodupkeys]
theorem nodupkeys.eq_of_fst_eq {l : list (sigma β)}
(nd : nodupkeys l) {s s' : sigma β} (h : s ∈ l) (h' : s' ∈ l) :
s.1 = s'.1 → s = s' :=
@forall_of_forall_of_pairwise _
(λ s s' : sigma β, s.1 = s'.1 → s = s')
(λ s s' H h, (H h.symm).symm) _ (λ x h _, rfl)
((nodupkeys_iff_pairwise.1 nd).imp (λ s s' h h', (h h').elim)) _ h _ h'
theorem nodupkeys.eq_of_mk_mem {a : α} {b b' : β a} {l : list (sigma β)}
(nd : nodupkeys l) (h : sigma.mk a b ∈ l) (h' : sigma.mk a b' ∈ l) : b = b' :=
by cases nd.eq_of_fst_eq h h' rfl; refl
theorem nodupkeys_singleton (s : sigma β) : nodupkeys [s] := nodup_singleton _
theorem nodupkeys_of_sublist {l₁ l₂ : list (sigma β)} (h : l₁ <+ l₂) : nodupkeys l₂ → nodupkeys l₁ :=
nodup_of_sublist (map_sublist_map _ h)
theorem nodup_of_nodupkeys {l : list (sigma β)} : nodupkeys l → nodup l :=
nodup_of_nodup_map _
theorem perm_nodupkeys {l₁ l₂ : list (sigma β)} (h : l₁ ~ l₂) : nodupkeys l₁ ↔ nodupkeys l₂ :=
perm_nodup $ perm_map _ h
theorem nodupkeys_join {L : list (list (sigma β))} :
nodupkeys (join L) ↔ (∀ l ∈ L, nodupkeys l) ∧ pairwise disjoint (L.map keys) :=
begin
rw [nodupkeys_iff_pairwise, pairwise_join, pairwise_map],
refine and_congr (ball_congr $ λ l h, by simp [nodupkeys_iff_pairwise]) _,
apply iff_of_eq, congr', ext l₁ l₂,
simp [keys, disjoint_iff_ne]
end
theorem nodup_enum_map_fst (l : list α) : (l.enum.map prod.fst).nodup :=
by simp [list.nodup_range]
variables [decidable_eq α]
/- lookup -/
/-- `lookup a l` is the first value in `l` corresponding to the key `a`,
or `none` if no such element exists. -/
def lookup (a : α) : list (sigma β) → option (β a)
| [] := none
| (⟨a', b⟩ :: l) := if h : a' = a then some (eq.rec_on h b) else lookup l
@[simp] theorem lookup_nil (a : α) : lookup a [] = @none (β a) := rfl
@[simp] theorem lookup_cons_eq (l) (a : α) (b : β a) : lookup a (⟨a, b⟩::l) = some b :=
dif_pos rfl
@[simp] theorem lookup_cons_ne (l) {a} :
∀ s : sigma β, a ≠ s.1 → lookup a (s::l) = lookup a l
| ⟨a', b⟩ h := dif_neg h.symm
theorem lookup_is_some {a : α} : ∀ {l : list (sigma β)},
(lookup a l).is_some ↔ a ∈ l.keys
| [] := by simp
| (⟨a', b⟩ :: l) := begin
by_cases h : a = a',
{ subst a', simp },
{ simp [h, lookup_is_some] },
end
theorem lookup_eq_none {a : α} {l : list (sigma β)} :
lookup a l = none ↔ a ∉ l.keys :=
begin
have := not_congr (@lookup_is_some _ _ _ a l),
simp at this, refine iff.trans _ this,
cases lookup a l; exact dec_trivial
end
theorem of_mem_lookup
{a : α} {b : β a} : ∀ {l : list (sigma β)}, b ∈ lookup a l → sigma.mk a b ∈ l
| (⟨a', b'⟩ :: l) H := begin
by_cases h : a = a',
{ subst a', simp at H, simp [H] },
{ simp [h] at H, exact or.inr (of_mem_lookup H) }
end
theorem mem_lookup {a} {b : β a} {l : list (sigma β)} (nd : l.nodupkeys)
(h : sigma.mk a b ∈ l) : b ∈ lookup a l :=
begin
cases option.is_some_iff_exists.mp (lookup_is_some.mpr (mem_keys_of_mem h)) with b' h',
cases nd.eq_of_mk_mem h (of_mem_lookup h'),
exact h'
end
theorem map_lookup_eq_find (a : α) : ∀ l : list (sigma β),
(lookup a l).map (sigma.mk a) = find (λ s, a = s.1) l
| [] := rfl
| (⟨a', b'⟩ :: l) := begin
by_cases h : a = a',
{ subst a', simp },
{ simp [h, map_lookup_eq_find] }
end
theorem mem_lookup_iff {a : α} {b : β a} {l : list (sigma β)} (nd : l.nodupkeys) :
b ∈ lookup a l ↔ sigma.mk a b ∈ l :=
⟨of_mem_lookup, mem_lookup nd⟩
theorem perm_lookup (a : α) {l₁ l₂ : list (sigma β)}
(nd₁ : l₁.nodupkeys) (nd₂ : l₂.nodupkeys) (p : l₁ ~ l₂) : lookup a l₁ = lookup a l₂ :=
by ext b; simp [mem_lookup_iff, nd₁, nd₂]; exact mem_of_perm p
/- lookup_all -/
/-- `lookup_all a l` is the list of all values in `l` corresponding to the key `a`. -/
def lookup_all (a : α) : list (sigma β) → list (β a)
| [] := []
| (⟨a', b⟩ :: l) := if h : a' = a then eq.rec_on h b :: lookup_all l else lookup_all l
@[simp] theorem lookup_all_nil (a : α) : lookup_all a [] = @nil (β a) := rfl
@[simp] theorem lookup_all_cons_eq (l) (a : α) (b : β a) :
lookup_all a (⟨a, b⟩::l) = b :: lookup_all a l :=
dif_pos rfl
@[simp] theorem lookup_all_cons_ne (l) {a} :
∀ s : sigma β, a ≠ s.1 → lookup_all a (s::l) = lookup_all a l
| ⟨a', b⟩ h := dif_neg h.symm
theorem lookup_all_eq_nil {a : α} : ∀ {l : list (sigma β)},
lookup_all a l = [] ↔ ∀ b : β a, sigma.mk a b ∉ l
| [] := by simp
| (⟨a', b⟩ :: l) := begin
by_cases h : a = a',
{ subst a', simp, exact λ H, H b (or.inl rfl) },
{ simp [h, lookup_all_eq_nil] },
end
theorem head_lookup_all (a : α) : ∀ l : list (sigma β),
head' (lookup_all a l) = lookup a l
| [] := by simp
| (⟨a', b⟩ :: l) := by by_cases h : a = a'; [{subst h, simp}, simp *]
theorem mem_lookup_all {a : α} {b : β a} :
∀ {l : list (sigma β)}, b ∈ lookup_all a l ↔ sigma.mk a b ∈ l
| [] := by simp
| (⟨a', b'⟩ :: l) := by by_cases h : a = a'; [{subst h, simp *}, simp *]
theorem lookup_all_sublist (a : α) :
∀ l : list (sigma β), (lookup_all a l).map (sigma.mk a) <+ l
| [] := by simp
| (⟨a', b'⟩ :: l) := begin
by_cases h : a = a',
{ subst h, simp, exact (lookup_all_sublist l).cons2 _ _ _ },
{ simp [h], exact (lookup_all_sublist l).cons _ _ _ }
end
theorem lookup_all_length_le_one (a : α) {l : list (sigma β)} (h : l.nodupkeys) :
length (lookup_all a l) ≤ 1 :=
by have := nodup_of_sublist (map_sublist_map _ $ lookup_all_sublist a l) h;
rw map_map at this; rwa [← nodup_repeat, ← map_const _ a]
theorem lookup_all_eq_lookup (a : α) {l : list (sigma β)} (h : l.nodupkeys) :
lookup_all a l = (lookup a l).to_list :=
begin
rw ← head_lookup_all,
have := lookup_all_length_le_one a h, revert this,
rcases lookup_all a l with _|⟨b, _|⟨c, l⟩⟩; intro; try {refl},
exact absurd this dec_trivial
end
theorem lookup_all_nodup (a : α) {l : list (sigma β)} (h : l.nodupkeys) :
(lookup_all a l).nodup :=
by rw lookup_all_eq_lookup a h; apply option.to_list_nodup
theorem perm_lookup_all (a : α) {l₁ l₂ : list (sigma β)}
(nd₁ : l₁.nodupkeys) (nd₂ : l₂.nodupkeys) (p : l₁ ~ l₂) : lookup_all a l₁ = lookup_all a l₂ :=
by simp [lookup_all_eq_lookup, nd₁, nd₂, perm_lookup a nd₁ nd₂ p]
/- kreplace -/
def kreplace (a : α) (b : β a) : list (sigma β) → list (sigma β) :=
lookmap $ λ s, if h : a = s.1 then some ⟨a, b⟩ else none
theorem kreplace_of_forall_not (a : α) (b : β a) {l : list (sigma β)}
(H : ∀ b : β a, sigma.mk a b ∉ l) : kreplace a b l = l :=
lookmap_of_forall_not _ $ begin
rintro ⟨a', b'⟩ h, dsimp, split_ifs,
{ subst a', exact H _ h }, {refl}
end
theorem kreplace_self {a : α} {b : β a} {l : list (sigma β)}
(nd : nodupkeys l) (h : sigma.mk a b ∈ l) : kreplace a b l = l :=
begin
refine (lookmap_congr _).trans
(lookmap_id' (option.guard (λ s, a = s.1)) _ _),
{ rintro ⟨a', b'⟩ h', dsimp [option.guard], split_ifs,
{ subst a', exact ⟨rfl, heq_of_eq $ nd.eq_of_mk_mem h h'⟩ },
{ refl } },
{ rintro ⟨a₁, b₁⟩ ⟨a₂, b₂⟩, dsimp [option.guard], split_ifs,
{ subst a₁, rintro ⟨⟩, simp }, { rintro ⟨⟩ } },
end
theorem keys_kreplace (a : α) (b : β a) : ∀ l : list (sigma β),
(kreplace a b l).keys = l.keys :=
lookmap_map_eq _ _ $ by rintro ⟨a₁, b₂⟩ ⟨a₂, b₂⟩;
dsimp; split_ifs; simp [h] {contextual := tt}
theorem kreplace_nodupkeys (a : α) (b : β a) {l : list (sigma β)} :
(kreplace a b l).nodupkeys ↔ l.nodupkeys :=
by simp [nodupkeys, keys_kreplace]
theorem perm_kreplace {a : α} {b : β a} {l₁ l₂ : list (sigma β)}
(nd : l₁.nodupkeys) : l₁ ~ l₂ →
kreplace a b l₁ ~ kreplace a b l₂ :=
perm_lookmap _ $ begin
refine (nodupkeys_iff_pairwise.1 nd).imp _,
intros x y h z h₁ w h₂,
split_ifs at h₁ h₂; cases h₁; cases h₂,
exact (h (h_2.symm.trans h_1)).elim
end
/- kerase -/
/-- Remove the first pair with the key `a`. -/
def kerase (a : α) : list (sigma β) → list (sigma β) :=
erasep $ λ s, a = s.1
@[simp] theorem kerase_nil {a} : @kerase _ β _ a [] = [] :=
rfl
@[simp] theorem kerase_cons_eq {a} {s : sigma β} {l : list (sigma β)} (h : a = s.1) :
kerase a (s :: l) = l :=
by simp [kerase, h]
@[simp] theorem kerase_cons_ne {a} {s : sigma β} {l : list (sigma β)} (h : a ≠ s.1) :
kerase a (s :: l) = s :: kerase a l :=
by simp [kerase, h]
@[simp] theorem kerase_of_not_mem_keys {a} {l : list (sigma β)} (h : a ∉ l.keys) :
kerase a l = l :=
by induction l with _ _ ih;
[refl, { simp [not_or_distrib] at h, simp [h.1, ih h.2] }]
theorem kerase_sublist (a : α) (l : list (sigma β)) : kerase a l <+ l :=
erasep_sublist _
theorem kerase_keys_subset (a) (l : list (sigma β)) :
(kerase a l).keys ⊆ l.keys :=
subset_of_sublist (map_sublist_map _ (kerase_sublist a l))
theorem mem_keys_of_mem_keys_kerase {a₁ a₂} {l : list (sigma β)} :
a₁ ∈ (kerase a₂ l).keys → a₁ ∈ l.keys :=
@kerase_keys_subset _ _ _ _ _ _
theorem exists_of_kerase {a : α} {l : list (sigma β)} (h : a ∈ l.keys) :
∃ (b : β a) (l₁ l₂ : list (sigma β)),
a ∉ l₁.keys ∧
l = l₁ ++ ⟨a, b⟩ :: l₂ ∧
kerase a l = l₁ ++ l₂ :=
begin
induction l,
case list.nil { cases h },
case list.cons : hd tl ih {
by_cases e : a = hd.1,
{ subst e,
exact ⟨hd.2, [], tl, by simp, by cases hd; refl, by simp⟩ },
{ simp at h,
cases h,
case or.inl : h { exact absurd h e },
case or.inr : h {
rcases ih h with ⟨b, tl₁, tl₂, h₁, h₂, h₃⟩,
exact ⟨b, hd :: tl₁, tl₂, not_mem_cons_of_ne_of_not_mem e h₁,
by rw h₂; refl, by simp [e, h₃]⟩ } } }
end
@[simp] theorem mem_keys_kerase_of_ne {a₁ a₂} {l : list (sigma β)} (h : a₁ ≠ a₂) :
a₁ ∈ (kerase a₂ l).keys ↔ a₁ ∈ l.keys :=
iff.intro mem_keys_of_mem_keys_kerase $ λ p,
if q : a₂ ∈ l.keys then
match l, kerase a₂ l, exists_of_kerase q, p with
| _, _, ⟨_, _, _, _, rfl, rfl⟩, p := by simpa [keys, h] using p
end
else
by simp [q, p]
theorem keys_kerase {a} {l : list (sigma β)} : (kerase a l).keys = l.keys.erase a :=
by rw [keys, kerase, ←erasep_map sigma.fst l, erase_eq_erasep]
theorem kerase_nodupkeys (a : α) {l : list (sigma β)} : nodupkeys l → (kerase a l).nodupkeys :=
nodupkeys_of_sublist $ kerase_sublist _ _
theorem perm_kerase {a : α} {l₁ l₂ : list (sigma β)}
(nd : l₁.nodupkeys) : l₁ ~ l₂ → kerase a l₁ ~ kerase a l₂ :=
perm_erasep _ $ (nodupkeys_iff_pairwise.1 nd).imp $
by rintro x y h rfl; exact h
@[simp] theorem not_mem_keys_kerase (a) {l : list (sigma β)} (nd : l.nodupkeys) :
a ∉ (kerase a l).keys :=
begin
induction l,
case list.nil { simp },
case list.cons : hd tl ih {
simp at nd,
by_cases h : a = hd.1,
{ subst h, simp [nd.1] },
{ simp [h, ih nd.2] } }
end
@[simp] theorem lookup_kerase (a) {l : list (sigma β)} (nd : l.nodupkeys) :
lookup a (kerase a l) = none :=
lookup_eq_none.mpr (not_mem_keys_kerase a nd)
@[simp] theorem lookup_kerase_ne {a a'} {l : list (sigma β)} (h : a ≠ a') :
lookup a' (kerase a l) = lookup a' l :=
begin
induction l,
case list.nil { refl },
case list.cons : hd tl ih {
cases hd with ah bh,
by_cases h₁ : a = ah; by_cases h₂ : a' = ah,
{ substs h₁ h₂, cases ne.irrefl h },
{ subst h₁, simp [h₂] },
{ subst h₂, simp [h] },
{ simp [h₁, h₂, ih] }
}
end
/- kinsert -/
/-- Insert the pair `⟨a, b⟩` and erase the first pair with the key `a`. -/
def kinsert (a : α) (b : β a) (l : list (sigma β)) : list (sigma β) :=
⟨a, b⟩ :: kerase a l
@[simp] theorem kinsert_def {a} {b : β a} {l : list (sigma β)} :
kinsert a b l = ⟨a, b⟩ :: kerase a l := rfl
@[simp] theorem mem_keys_kinsert {a a'} {b : β a} {l : list (sigma β)} :
a' ∈ (kinsert a b l).keys ↔ a = a' ∨ a' ∈ l.keys :=
by by_cases h : a = a'; [simp [h], simp [h, ne.symm h]]
theorem kinsert_nodupkeys (a) (b : β a) {l : list (sigma β)} (nd : l.nodupkeys) :
(kinsert a b l).nodupkeys :=
nodupkeys_cons.mpr ⟨not_mem_keys_kerase a nd, kerase_nodupkeys a nd⟩
theorem perm_kinsert {a} {b : β a} {l₁ l₂ : list (sigma β)} (nd₁ : l₁.nodupkeys)
(p : l₁ ~ l₂) : kinsert a b l₁ ~ kinsert a b l₂ :=
perm.skip ⟨a, b⟩ $ perm_kerase nd₁ p
@[simp] theorem lookup_kinsert {a} {b : β a} (l : list (sigma β)) :
lookup a (kinsert a b l) = some b :=
by simp only [kinsert, lookup_cons_eq]
@[simp] theorem lookup_kinsert_ne {a a'} {b : β a} {l : list (sigma β)} (h : a ≠ a') :
lookup a' (kinsert a b l) = lookup a' l :=
by simp [h, lookup_cons_ne _ ⟨a, b⟩ (ne.symm h)]
/- kextract -/
def kextract (a : α) : list (sigma β) → option (β a) × list (sigma β)
| [] := (none, [])
| (s::l) := if h : s.1 = a then (some (eq.rec_on h s.2), l) else
let (b', l') := kextract l in (b', s :: l')
@[simp] theorem kextract_eq_lookup_kerase (a : α) :
∀ l : list (sigma β), kextract a l = (lookup a l, kerase a l)
| [] := rfl
| (⟨a', b⟩::l) := begin
simp [kextract], dsimp, split_ifs,
{ subst a', simp [kerase] },
{ simp [kextract, ne.symm h, kextract_eq_lookup_kerase l, kerase] }
end
end list
|
af307be083ff9bc880badd4154c9b1e7475d5548 | 77c5b91fae1b966ddd1db969ba37b6f0e4901e88 | /src/analysis/normed_space/riesz_lemma.lean | 5af87af2e2412cab4c05fd7dbd6815928505abf1 | [
"Apache-2.0"
] | permissive | dexmagic/mathlib | ff48eefc56e2412429b31d4fddd41a976eb287ce | 7a5d15a955a92a90e1d398b2281916b9c41270b2 | refs/heads/master | 1,693,481,322,046 | 1,633,360,193,000 | 1,633,360,193,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 4,612 | lean | /-
Copyright (c) 2019 Jean Lo. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jean Lo
-/
import topology.metric_space.hausdorff_distance
/-!
# Riesz's lemma
Riesz's lemma, stated for a normed space over a normed field: for any
closed proper subspace `F` of `E`, there is a nonzero `x` such that `∥x - F∥`
is at least `r * ∥x∥` for any `r < 1`. This is `riesz_lemma`.
In a nondiscrete normed field (with an element `c` of norm `> 1`) and any `R > ∥c∥`, one can
guarantee `∥x∥ ≤ R` and `∥x - y∥ ≥ 1` for any `y` in `F`. This is `riesz_lemma_of_norm_lt`.
-/
variables {𝕜 : Type*} [normed_field 𝕜]
variables {E : Type*} [normed_group E] [normed_space 𝕜 E]
/-- Riesz's lemma, which usually states that it is possible to find a
vector with norm 1 whose distance to a closed proper subspace is
arbitrarily close to 1. The statement here is in terms of multiples of
norms, since in general the existence of an element of norm exactly 1
is not guaranteed. For a variant giving an element with norm in `[1, R]`, see
`riesz_lemma_of_norm_lt`. -/
lemma riesz_lemma {F : subspace 𝕜 E} (hFc : is_closed (F : set E))
(hF : ∃ x : E, x ∉ F) {r : ℝ} (hr : r < 1) :
∃ x₀ : E, x₀ ∉ F ∧ ∀ y ∈ F, r * ∥x₀∥ ≤ ∥x₀ - y∥ :=
begin
classical,
obtain ⟨x, hx⟩ : ∃ x : E, x ∉ F := hF,
let d := metric.inf_dist x F,
have hFn : (F : set E).nonempty, from ⟨_, F.zero_mem⟩,
have hdp : 0 < d,
from lt_of_le_of_ne metric.inf_dist_nonneg (λ heq, hx
((metric.mem_iff_inf_dist_zero_of_closed hFc hFn).2 heq.symm)),
let r' := max r 2⁻¹,
have hr' : r' < 1, by { simp [r', hr], norm_num },
have hlt : 0 < r' := lt_of_lt_of_le (by norm_num) (le_max_right r 2⁻¹),
have hdlt : d < d / r', from (lt_div_iff hlt).mpr ((mul_lt_iff_lt_one_right hdp).2 hr'),
obtain ⟨y₀, hy₀F, hxy₀⟩ : ∃ y ∈ F, dist x y < d / r' :=
metric.exists_dist_lt_of_inf_dist_lt hdlt hFn,
have x_ne_y₀ : x - y₀ ∉ F,
{ by_contradiction h,
have : (x - y₀) + y₀ ∈ F, from F.add_mem h hy₀F,
simp only [neg_add_cancel_right, sub_eq_add_neg] at this,
exact hx this },
refine ⟨x - y₀, x_ne_y₀, λy hy, le_of_lt _⟩,
have hy₀y : y₀ + y ∈ F, from F.add_mem hy₀F hy,
calc
r * ∥x - y₀∥ ≤ r' * ∥x - y₀∥ : mul_le_mul_of_nonneg_right (le_max_left _ _) (norm_nonneg _)
... < d : by { rw ←dist_eq_norm, exact (lt_div_iff' hlt).1 hxy₀ }
... ≤ dist x (y₀ + y) : metric.inf_dist_le_dist_of_mem hy₀y
... = ∥x - y₀ - y∥ : by { rw [sub_sub, dist_eq_norm] }
end
/--
A version of Riesz lemma: given a strict closed subspace `F`, one may find an element of norm `≤ R`
which is at distance at least `1` of every element of `F`. Here, `R` is any given constant
strictly larger than the norm of an element of norm `> 1`. For a version without an `R`, see
`riesz_lemma`.
Since we are considering a general nondiscrete normed field, there may be a gap in possible norms
(for instance no element of norm in `(1,2)`). Hence, we can not allow `R` arbitrarily close to `1`,
and require `R > ∥c∥` for some `c : 𝕜` with norm `> 1`.
-/
lemma riesz_lemma_of_norm_lt
{c : 𝕜} (hc : 1 < ∥c∥) {R : ℝ} (hR : ∥c∥ < R)
{F : subspace 𝕜 E} (hFc : is_closed (F : set E)) (hF : ∃ x : E, x ∉ F) :
∃ x₀ : E, ∥x₀∥ ≤ R ∧ ∀ y ∈ F, 1 ≤ ∥x₀ - y∥ :=
begin
have Rpos : 0 < R := (norm_nonneg _).trans_lt hR,
have : ∥c∥ / R < 1, by { rw div_lt_iff Rpos, simpa using hR },
rcases riesz_lemma hFc hF this with ⟨x, xF, hx⟩,
have x0 : x ≠ 0 := λ H, by simpa [H] using xF,
obtain ⟨d, d0, dxlt, ledx, -⟩ :
∃ (d : 𝕜), d ≠ 0 ∧ ∥d • x∥ < R ∧ R / ∥c∥ ≤ ∥d • x∥ ∧ ∥d∥⁻¹ ≤ R⁻¹ * ∥c∥ * ∥x∥ :=
rescale_to_shell hc Rpos x0,
refine ⟨d • x, dxlt.le, λ y hy, _⟩,
set y' := d⁻¹ • y with hy',
have y'F : y' ∈ F, by simp [hy', submodule.smul_mem _ _ hy],
have yy' : y = d • y', by simp [hy', smul_smul, mul_inv_cancel d0],
calc 1 = (∥c∥/R) * (R/∥c∥) : by field_simp [Rpos.ne', (zero_lt_one.trans hc).ne']
... ≤ (∥c∥/R) * (∥d • x∥) :
mul_le_mul_of_nonneg_left ledx (div_nonneg (norm_nonneg _) Rpos.le)
... = ∥d∥ * (∥c∥/R * ∥x∥) : by { simp [norm_smul], ring }
... ≤ ∥d∥ * ∥x - y'∥ :
mul_le_mul_of_nonneg_left (hx y' (by simp [hy', submodule.smul_mem _ _ hy])) (norm_nonneg _)
... = ∥d • x - y∥ : by simp [yy', ← smul_sub, norm_smul],
end
|
5153fbf26a0ea9b2063dfceff60e2c8bff547b8b | 947b78d97130d56365ae2ec264df196ce769371a | /tests/lean/run/reduce1.lean | 99215eabf1737c07b023eb33ac1cb34a9102ab12 | [
"Apache-2.0"
] | permissive | shyamalschandra/lean4 | 27044812be8698f0c79147615b1d5090b9f4b037 | 6e7a883b21eaf62831e8111b251dc9b18f40e604 | refs/heads/master | 1,671,417,126,371 | 1,601,859,995,000 | 1,601,860,020,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 1,479 | lean | new_frontend
partial def fact : Nat → Nat
| 0 => 1
| (n+1) => (n+1)*fact n
#eval fact 10
#eval fact 100
theorem tst1 : fact 10 = 3628800 :=
nativeRefl! (fact 10)
theorem tst2 : fact 100 = 93326215443944152681699238856266700490715968264381621468592963895217599993229915608941463976156518286253697920827223758251185210916864000000000000000000000000 :=
nativeRefl! (fact 100)
theorem tst3 : decide (10000000000000000 < 200000000000000000000) = true :=
nativeRefl! (decide (10000000000000000 < 200000000000000000000))
theorem tst4 : 10000000000000000 < 200000000000000000000 :=
ofDecideEqTrue (nativeRefl! (decide (10000000000000000 < 200000000000000000000)))
theorem tst5 : 10000000000000000 < 200000000000000000000 :=
nativeDecide! (10000000000000000 < 200000000000000000000)
theorem tst6 : 10000000000000000 < 200000000000000000000 :=
let h₁ := nativeDecide! (10000000000000000 < 10000000000000010);
let h₂ := nativeDecide! (10000000000000010 < 200000000000000000000);
Nat.ltTrans h₁ h₂
theorem tst7 : 10000000000000000 < 200000000000000000000 :=
decide! (10000000000000000 < 200000000000000000000)
theorem tst8 : 10000000000000000 < 200000000000000000000 :=
let h₁ := decide! (10000000000000000 < 10000000000000010);
let h₂ := decide! (10000000000000010 < 200000000000000000000);
Nat.ltTrans h₁ h₂
theorem tst9 : 10000000000000000 < 200000000000000000000 :=
decide! _
theorem tst10 : 10000000000000000 < 200000000000000000000 :=
nativeDecide! _
|
c4b07f1f427f522ae093d8c6f049b07965cd294c | 1dd482be3f611941db7801003235dc84147ec60a | /src/category_theory/instances/rings.lean | 65531aa87e628fd7129120ab17a379dc796a9c93 | [
"Apache-2.0"
] | permissive | sanderdahmen/mathlib | 479039302bd66434bb5672c2a4cecf8d69981458 | 8f0eae75cd2d8b7a083cf935666fcce4565df076 | refs/heads/master | 1,587,491,322,775 | 1,549,672,060,000 | 1,549,672,060,000 | 169,748,224 | 0 | 0 | Apache-2.0 | 1,549,636,694,000 | 1,549,636,694,000 | null | UTF-8 | Lean | false | false | 5,218 | lean | /- Copyright (c) 2018 Scott Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Scott Morrison, Johannes Hölzl
Introduce CommRing -- the category of commutative rings.
Currently only the basic setup.
-/
import category_theory.instances.monoids
import category_theory.fully_faithful
import category_theory.adjunction
import linear_algebra.multivariate_polynomial
import algebra.ring
universes u v
open category_theory
namespace category_theory.instances
/-- The category of rings. -/
@[reducible] def Ring : Type (u+1) := bundled ring
instance (x : Ring) : ring x := x.str
instance concrete_is_ring_hom : concrete_category @is_ring_hom :=
⟨by introsI α ia; apply_instance,
by introsI α β γ ia ib ic f g hf hg; apply_instance⟩
instance Ring_hom_is_ring_hom {R S : Ring} (f : R ⟶ S) : is_ring_hom (f : R → S) := f.2
/-- The category of commutative rings. -/
@[reducible] def CommRing : Type (u+1) := bundled comm_ring
instance (x : CommRing) : comm_ring x := x.str
-- Here we don't use the `concrete` machinery,
-- because it would require introducing a useless synonym for `is_ring_hom`.
instance : category CommRing :=
{ hom := λ R S, { f : R → S // is_ring_hom f },
id := λ R, ⟨ id, by resetI; apply_instance ⟩,
comp := λ R S T g h, ⟨ h.1 ∘ g.1, begin haveI := g.2, haveI := h.2, apply_instance end ⟩ }
namespace CommRing
variables {R S T : CommRing.{u}}
@[simp] lemma id_val : subtype.val (𝟙 R) = id := rfl
@[simp] lemma comp_val (f : R ⟶ S) (g : S ⟶ T) :
(f ≫ g).val = g.val ∘ f.val := rfl
instance hom_coe : has_coe_to_fun (R ⟶ S) :=
{ F := λ f, R → S,
coe := λ f, f.1 }
@[simp] lemma hom_coe_app (f : R ⟶ S) (r : R) : f r = f.val r := rfl
instance hom_is_ring_hom (f : R ⟶ S) : is_ring_hom (f : R → S) := f.2
def Int : CommRing := ⟨ℤ, infer_instance⟩
def Int.cast {R : CommRing} : Int ⟶ R := { val := int.cast, property := by apply_instance }
def int.eq_cast' {R : Type u} [ring R] (f : int → R) [is_ring_hom f] : f = int.cast :=
funext $ int.eq_cast f (is_ring_hom.map_one f) (λ _ _, is_ring_hom.map_add f)
def Int.hom_unique {R : CommRing} : unique (Int ⟶ R) :=
{ default := Int.cast,
uniq := λ f, subtype.ext.mpr $ funext $ int.eq_cast f f.2.map_one f.2.map_add }
/-- The forgetful functor commutative rings to Type. -/
def forget : CommRing.{u} ⥤ Type u :=
{ obj := λ R, R,
map := λ _ _ f, f }
instance forget.faithful : faithful (forget) := {}
/-- The functor from commutative rings to rings. -/
def to_Ring : CommRing.{u} ⥤ Ring.{u} :=
{ obj := λ X, { α := X.1, str := by apply_instance },
map := λ X Y f, ⟨ f, by apply_instance ⟩ }
instance to_Ring.faithful : faithful (to_Ring) := {}
/-- The forgetful functor from commutative rings to (multiplicative) commutative monoids. -/
def forget_to_CommMon : CommRing.{u} ⥤ CommMon.{u} :=
{ obj := λ X, { α := X.1, str := by apply_instance },
map := λ X Y f, ⟨ f, by apply_instance ⟩ }
instance forget_to_CommMon.faithful : faithful (forget_to_CommMon) := {}
example : faithful (forget_to_CommMon ⋙ CommMon.forget_to_Mon) := by apply_instance
section
open mv_polynomial
local attribute [instance, priority 0] subtype.fintype set_fintype classical.prop_decidable
noncomputable def polynomial : Type u ⥤ CommRing.{u} :=
{ obj := λ α, ⟨mv_polynomial α ℤ, by apply_instance⟩,
map := λ α β f, ⟨eval₂ C (X ∘ f), by apply_instance⟩,
map_id' := λ α, subtype.ext.mpr $ funext $ eval₂_eta,
map_comp' := λ α β γ f g, subtype.ext.mpr $ funext $ λ p,
by apply mv_polynomial.induction_on p; intros;
simp only [*, eval₂_add, eval₂_mul, eval₂_C, eval₂_X, comp_val,
eq_self_iff_true, function.comp_app, types_comp] at * }
@[simp] lemma polynomial_obj_α {α : Type u} :
(polynomial.obj α).α = mv_polynomial α ℤ := rfl
@[simp] lemma polynomial_map_val {α β : Type u} {f : α → β} :
(polynomial.map f).val = eval₂ C (X ∘ f) := rfl
noncomputable def adj : adjunction polynomial (forget : CommRing ⥤ Type u) :=
adjunction.mk_of_hom_equiv _ _
{ hom_equiv := λ α R,
{ to_fun := λ f, f ∘ X,
inv_fun := λ f, ⟨eval₂ int.cast f, by apply_instance⟩,
left_inv := λ f, subtype.ext.mpr $ funext $ λ p,
begin
have H0 := λ n, (congr (int.eq_cast' (f.val ∘ C)) (rfl : n = n)).symm,
have H1 := λ p₁ p₂, (@is_ring_hom.map_add _ _ _ _ f.val f.2 p₁ p₂).symm,
have H2 := λ p₁ p₂, (@is_ring_hom.map_mul _ _ _ _ f.val f.2 p₁ p₂).symm,
apply mv_polynomial.induction_on p; intros;
simp only [*, eval₂_add, eval₂_mul, eval₂_C, eval₂_X,
eq_self_iff_true, function.comp_app, hom_coe_app] at *
end,
right_inv := by tidy },
hom_equiv_naturality_left_symm' := λ X' X Y f g, subtype.ext.mpr $ funext $ λ p,
begin
apply mv_polynomial.induction_on p; intros;
simp only [*, eval₂_mul, eval₂_add, eval₂_C, eval₂_X,
comp_val, equiv.coe_fn_symm_mk, hom_coe_app, polynomial_map_val,
eq_self_iff_true, function.comp_app, add_right_inj, types_comp] at *
end }
end
end CommRing
end category_theory.instances
|
82568286ab7fdfd38b8e1e25d24918ad9ce6e332 | 6dc0c8ce7a76229dd81e73ed4474f15f88a9e294 | /tests/lean/run/panicAtCheckAssignment.lean | 0c1587ef0b0e5269af8517a0bc247c261a4e49d0 | [
"Apache-2.0"
] | permissive | williamdemeo/lean4 | 72161c58fe65c3ad955d6a3050bb7d37c04c0d54 | 6d00fcf1d6d873e195f9220c668ef9c58e9c4a35 | refs/heads/master | 1,678,305,356,877 | 1,614,708,995,000 | 1,614,708,995,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 212 | lean | import Lean
open Lean
open Lean.Meta
def bug : MetaM Unit := do
let i := 0
forallTelescopeReducing arbitrary fun ys _ => do
let mut j := 0
for y in ys do
throwError! "#{i+1}"
j := j + 1
|
a0047547e71ff96040c898ddab10a061bf954f0b | 82e44445c70db0f03e30d7be725775f122d72f3e | /src/ring_theory/power_series/basic.lean | 00c176f28f8b98e08ded5ad7ab7e7dd3bb58e432 | [
"Apache-2.0"
] | permissive | stjordanis/mathlib | 51e286d19140e3788ef2c470bc7b953e4991f0c9 | 2568d41bca08f5d6bf39d915434c8447e21f42ee | refs/heads/master | 1,631,748,053,501 | 1,627,938,886,000 | 1,627,938,886,000 | 228,728,358 | 0 | 0 | Apache-2.0 | 1,576,630,588,000 | 1,576,630,587,000 | null | UTF-8 | Lean | false | false | 64,455 | lean | /-
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 data.mv_polynomial
import linear_algebra.std_basis
import ring_theory.ideal.operations
import ring_theory.multiplicity
import ring_theory.algebra_tower
import tactic.linarith
import algebra.big_operators.nat_antidiagonal
/-!
# Formal 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 polynomials to formal power series.
## Generalities
The file starts with setting up the (semi)ring structure on multivariate power series.
`trunc n φ` truncates a formal power series to the polynomial
that has the same coefficients as `φ`, for all `m ≤ n`, and `0` otherwise.
If the constant coefficient of a formal power series is invertible,
then this formal power series is invertible.
Formal power series over a local ring form a local ring.
## Formal power series in one variable
We prove that if the ring of coefficients is an integral domain,
then formal power series in one variable form an integral domain.
The `order` of a formal power series `φ` is the multiplicity of the variable `X` in `φ`.
If the coefficients form an integral domain, then `order` is a valuation
(`order_mul`, `le_order_add`).
## Implementation notes
In this file we define multivariate formal power series with
variables indexed by `σ` and coefficients in `R` as
`mv_power_series 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.
Formal power series in one variable are defined as
`power_series R := mv_power_series unit R`.
This allows us to port a lot of proofs and properties
from the multivariate case to the single variable case.
However, it means that formal power series are indexed by `unit →₀ ℕ`,
which is of course canonically isomorphic to `ℕ`.
We then build some glue to treat formal power series as if they are indexed by `ℕ`.
Occasionally this leads to proofs that are uglier than expected.
-/
noncomputable theory
open_locale classical big_operators
/-- Multivariate formal power series, where `σ` is the index set of the variables
and `R` is the coefficient ring.-/
def mv_power_series (σ : Type*) (R : Type*) := (σ →₀ ℕ) → R
namespace mv_power_series
open finsupp
variables {σ R : Type*}
instance [inhabited R] : inhabited (mv_power_series σ R) := ⟨λ _, default _⟩
instance [has_zero R] : has_zero (mv_power_series σ R) := pi.has_zero
instance [add_monoid R] : add_monoid (mv_power_series σ R) := pi.add_monoid
instance [add_group R] : add_group (mv_power_series σ R) := pi.add_group
instance [add_comm_monoid R] : add_comm_monoid (mv_power_series σ R) := pi.add_comm_monoid
instance [add_comm_group R] : add_comm_group (mv_power_series σ R) := pi.add_comm_group
instance [nontrivial R] : nontrivial (mv_power_series σ R) := function.nontrivial
instance {A} [semiring R] [add_comm_monoid A] [module R A] :
module R (mv_power_series σ A) := pi.module _ _ _
instance {A S} [semiring R] [semiring S] [add_comm_monoid A] [module R A] [module S A]
[has_scalar R S] [is_scalar_tower R S A] :
is_scalar_tower R S (mv_power_series σ A) :=
pi.is_scalar_tower
section semiring
variables (R) [semiring R]
/-- The `n`th monomial with coefficient `a` as multivariate formal power series.-/
def monomial (n : σ →₀ ℕ) : R →ₗ[R] mv_power_series σ R :=
linear_map.std_basis R _ n
/-- The `n`th coefficient of a multivariate formal power series.-/
def coeff (n : σ →₀ ℕ) : (mv_power_series σ R) →ₗ[R] R := linear_map.proj n
variables {R}
/-- Two multivariate formal power series are equal if all their coefficients are equal.-/
@[ext] lemma 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.-/
lemma ext_iff {φ ψ : mv_power_series σ R} :
φ = ψ ↔ (∀ (n : σ →₀ ℕ), coeff R n φ = coeff R n ψ) :=
function.funext_iff
lemma monomial_def [decidable_eq σ] (n : σ →₀ ℕ) :
monomial R n = linear_map.std_basis R _ n :=
by convert rfl -- unify the `decidable` arguments
lemma coeff_monomial [decidable_eq σ] (m n : σ →₀ ℕ) (a : R) :
coeff R m (monomial R n a) = if m = n then a else 0 :=
by rw [coeff, monomial_def, linear_map.proj_apply, linear_map.std_basis_apply,
function.update_apply, pi.zero_apply]
@[simp] lemma coeff_monomial_same (n : σ →₀ ℕ) (a : R) :
coeff R n (monomial R n a) = a :=
linear_map.std_basis_same R _ n a
lemma coeff_monomial_ne {m n : σ →₀ ℕ} (h : m ≠ n) (a : R) :
coeff R m (monomial R n a) = 0 :=
linear_map.std_basis_ne R _ _ _ h a
lemma 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 $ λ h', h $ coeff_monomial_ne h' a
@[simp] lemma coeff_comp_monomial (n : σ →₀ ℕ) :
(coeff R n).comp (monomial R n) = linear_map.id :=
linear_map.ext $ coeff_monomial_same n
@[simp] lemma coeff_zero (n : σ →₀ ℕ) : coeff R n (0 : mv_power_series σ R) = 0 := rfl
variables (m n : σ →₀ ℕ) (φ ψ : mv_power_series σ R)
instance : has_one (mv_power_series σ R) := ⟨monomial R (0 : σ →₀ ℕ) 1⟩
lemma coeff_one [decidable_eq σ] :
coeff R n (1 : mv_power_series σ R) = if n = 0 then 1 else 0 :=
coeff_monomial _ _ _
lemma coeff_zero_one : coeff R (0 : σ →₀ ℕ) 1 = 1 :=
coeff_monomial_same 0 1
lemma monomial_zero_one : monomial R (0 : σ →₀ ℕ) 1 = 1 := rfl
instance : has_mul (mv_power_series σ R) :=
⟨λ φ ψ n, ∑ p in finsupp.antidiagonal n, coeff R p.1 φ * coeff R p.2 ψ⟩
lemma coeff_mul : coeff R n (φ * ψ) =
∑ p in finsupp.antidiagonal n, coeff R p.1 φ * coeff R p.2 ψ := rfl
protected lemma zero_mul : (0 : mv_power_series σ R) * φ = 0 :=
ext $ λ n, by simp [coeff_mul]
protected lemma mul_zero : φ * 0 = 0 :=
ext $ λ n, by simp [coeff_mul]
lemma 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 :=
begin
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 :=
λ p _ hp, eq_of_coeff_monomial_ne_zero (left_ne_zero_of_mul hp),
rw [coeff_mul, ← finset.sum_filter_of_ne this, antidiagonal_filter_fst_eq,
finset.sum_ite_index],
simp only [finset.sum_singleton, coeff_monomial_same, finset.sum_empty]
end
lemma 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 :=
begin
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 :=
λ p _ hp, eq_of_coeff_monomial_ne_zero (right_ne_zero_of_mul hp),
rw [coeff_mul, ← finset.sum_filter_of_ne this, antidiagonal_filter_snd_eq,
finset.sum_ite_index],
simp only [finset.sum_singleton, coeff_monomial_same, finset.sum_empty]
end
lemma coeff_add_monomial_mul (a : R) :
coeff R (m + n) (monomial R m a * φ) = a * coeff R n φ :=
begin
rw [coeff_monomial_mul, if_pos, nat_add_sub_cancel_left],
exact le_add_right le_rfl
end
lemma coeff_add_mul_monomial (a : R) :
coeff R (m + n) (φ * monomial R n a) = coeff R m φ * a :=
begin
rw [coeff_mul_monomial, if_pos, nat_add_sub_cancel],
exact le_add_left le_rfl
end
protected lemma one_mul : (1 : mv_power_series σ R) * φ = φ :=
ext $ λ n, by simpa using coeff_add_monomial_mul 0 n φ 1
protected lemma mul_one : φ * 1 = φ :=
ext $ λ n, by simpa using coeff_add_mul_monomial n 0 φ 1
protected lemma mul_add (φ₁ φ₂ φ₃ : mv_power_series σ R) :
φ₁ * (φ₂ + φ₃) = φ₁ * φ₂ + φ₁ * φ₃ :=
ext $ λ n, by simp only [coeff_mul, mul_add, finset.sum_add_distrib, linear_map.map_add]
protected lemma add_mul (φ₁ φ₂ φ₃ : mv_power_series σ R) :
(φ₁ + φ₂) * φ₃ = φ₁ * φ₃ + φ₂ * φ₃ :=
ext $ λ n, by simp only [coeff_mul, add_mul, finset.sum_add_distrib, linear_map.map_add]
protected lemma mul_assoc (φ₁ φ₂ φ₃ : mv_power_series σ R) :
(φ₁ * φ₂) * φ₃ = φ₁ * (φ₂ * φ₃) :=
begin
ext1 n,
simp only [coeff_mul, finset.sum_mul, finset.mul_sum, finset.sum_sigma'],
refine finset.sum_bij (λ p _, ⟨(p.2.1, p.2.2 + p.1.2), (p.2.2, p.1.2)⟩) _ _ _ _;
simp only [mem_antidiagonal, finset.mem_sigma, heq_iff_eq, prod.mk.inj_iff, and_imp,
exists_prop],
{ rintros ⟨⟨i,j⟩, ⟨k,l⟩⟩, dsimp only, rintro rfl rfl,
simp [add_assoc] },
{ rintros ⟨⟨a, b⟩, ⟨c, d⟩⟩, dsimp only, rintro rfl rfl,
apply mul_assoc },
{ rintros ⟨⟨a, b⟩, ⟨c, d⟩⟩ ⟨⟨i, j⟩, ⟨k, l⟩⟩, dsimp only, rintro rfl rfl - rfl rfl - rfl rfl,
refl },
{ rintro ⟨⟨i, j⟩, ⟨k, l⟩⟩, dsimp only, rintro rfl rfl,
refine ⟨⟨(i + k, l), (i, k)⟩, _, _⟩; simp [add_assoc] }
end
instance : semiring (mv_power_series σ R) :=
{ mul_one := mv_power_series.mul_one,
one_mul := mv_power_series.one_mul,
mul_assoc := mv_power_series.mul_assoc,
mul_zero := mv_power_series.mul_zero,
zero_mul := mv_power_series.zero_mul,
left_distrib := mv_power_series.mul_add,
right_distrib := mv_power_series.add_mul,
.. mv_power_series.has_one,
.. mv_power_series.has_mul,
.. mv_power_series.add_comm_monoid }
end semiring
instance [comm_semiring R] : comm_semiring (mv_power_series σ R) :=
{ mul_comm := λ φ ψ, ext $ λ n, by simpa only [coeff_mul, mul_comm]
using sum_antidiagonal_swap n (λ a b, coeff R a φ * coeff R b ψ),
.. mv_power_series.semiring }
instance [ring R] : ring (mv_power_series σ R) :=
{ .. mv_power_series.semiring,
.. mv_power_series.add_comm_group }
instance [comm_ring R] : comm_ring (mv_power_series σ R) :=
{ .. mv_power_series.comm_semiring,
.. mv_power_series.add_comm_group }
section semiring
variables [semiring R]
lemma 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) :=
begin
ext k,
simp only [coeff_mul_monomial, coeff_monomial],
split_ifs with h₁ h₂ h₃ h₃ h₂; try { refl },
{ rw [← h₂, nat_sub_add_cancel h₁] at h₃, exact (h₃ rfl).elim },
{ rw [h₃, nat_add_sub_cancel] at h₂, exact (h₂ rfl).elim },
{ exact zero_mul b },
{ rw h₂ at h₁, exact (h₁ $ le_add_left le_rfl).elim }
end
variables (σ) (R)
/-- The constant multivariate formal power series.-/
def C : R →+* mv_power_series σ R :=
{ map_one' := rfl,
map_mul' := λ a b, (monomial_mul_monomial 0 0 a b).symm,
map_zero' := (monomial R (0 : _)).map_zero,
.. monomial R (0 : σ →₀ ℕ) }
variables {σ} {R}
@[simp] lemma monomial_zero_eq_C : ⇑(monomial R (0 : σ →₀ ℕ)) = C σ R := rfl
lemma monomial_zero_eq_C_apply (a : R) : monomial R (0 : σ →₀ ℕ) a = C σ R a := rfl
lemma coeff_C [decidable_eq σ] (n : σ →₀ ℕ) (a : R) :
coeff R n (C σ R a) = if n = 0 then a else 0 :=
coeff_monomial _ _ _
lemma coeff_zero_C (a : R) : coeff R (0 : σ →₀ℕ) (C σ R a) = a :=
coeff_monomial_same 0 a
/-- The variables of the multivariate formal power series ring.-/
def X (s : σ) : mv_power_series σ R := monomial R (single s 1) 1
lemma coeff_X [decidable_eq σ] (n : σ →₀ ℕ) (s : σ) :
coeff R n (X s : mv_power_series σ R) = if n = (single s 1) then 1 else 0 :=
coeff_monomial _ _ _
lemma coeff_index_single_X [decidable_eq σ] (s t : σ) :
coeff R (single t 1) (X s : mv_power_series σ R) = if t = s then 1 else 0 :=
by { simp only [coeff_X, single_left_inj one_ne_zero], split_ifs; refl }
@[simp] lemma coeff_index_single_self_X (s : σ) :
coeff R (single s 1) (X s : mv_power_series σ R) = 1 :=
coeff_monomial_same _ _
lemma coeff_zero_X (s : σ) : coeff R (0 : σ →₀ ℕ) (X s : mv_power_series σ R) = 0 :=
by { rw [coeff_X, if_neg], intro h, exact one_ne_zero (single_eq_zero.mp h.symm) }
lemma X_def (s : σ) : X s = monomial R (single s 1) 1 := rfl
lemma X_pow_eq (s : σ) (n : ℕ) :
(X s : mv_power_series σ R)^n = monomial R (single s n) 1 :=
begin
induction n with n ih,
{ rw [pow_zero, finsupp.single_zero, monomial_zero_one] },
{ rw [pow_succ', ih, nat.succ_eq_add_one, finsupp.single_add, X, monomial_mul_monomial, one_mul] }
end
lemma coeff_X_pow [decidable_eq σ] (m : σ →₀ ℕ) (s : σ) (n : ℕ) :
coeff R m ((X s : mv_power_series σ R)^n) = if m = single s n then 1 else 0 :=
by rw [X_pow_eq s n, coeff_monomial]
@[simp] lemma coeff_mul_C (n : σ →₀ ℕ) (φ : mv_power_series 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] lemma coeff_C_mul (n : σ →₀ ℕ) (φ : mv_power_series 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
lemma coeff_zero_mul_X (φ : mv_power_series σ R) (s : σ) :
coeff R (0 : σ →₀ ℕ) (φ * X s) = 0 :=
begin
have : ¬single s 1 ≤ 0, from λ h, by simpa using h s,
simp only [X, coeff_mul_monomial, if_neg this]
end
lemma coeff_zero_X_mul (φ : mv_power_series σ R) (s : σ) :
coeff R (0 : σ →₀ ℕ) (X s * φ) = 0 :=
begin
have : ¬single s 1 ≤ 0, from λ h, by simpa using h s,
simp only [X, coeff_monomial_mul, if_neg this]
end
variables (σ) (R)
/-- The constant coefficient of a formal power series.-/
def constant_coeff : (mv_power_series σ R) →+* R :=
{ to_fun := coeff R (0 : σ →₀ ℕ),
map_one' := coeff_zero_one,
map_mul' := λ φ ψ, by simp [coeff_mul, support_single_ne_zero],
map_zero' := linear_map.map_zero _,
.. coeff R (0 : σ →₀ ℕ) }
variables {σ} {R}
@[simp] lemma coeff_zero_eq_constant_coeff :
⇑(coeff R (0 : σ →₀ ℕ)) = constant_coeff σ R := rfl
lemma coeff_zero_eq_constant_coeff_apply (φ : mv_power_series σ R) :
coeff R (0 : σ →₀ ℕ) φ = constant_coeff σ R φ := rfl
@[simp] lemma constant_coeff_C (a : R) : constant_coeff σ R (C σ R a) = a := rfl
@[simp] lemma constant_coeff_comp_C :
(constant_coeff σ R).comp (C σ R) = ring_hom.id R := rfl
@[simp] lemma constant_coeff_zero : constant_coeff σ R 0 = 0 := rfl
@[simp] lemma constant_coeff_one : constant_coeff σ R 1 = 1 := rfl
@[simp] lemma constant_coeff_X (s : σ) : constant_coeff σ R (X s) = 0 := coeff_zero_X s
/-- If a multivariate formal power series is invertible,
then so is its constant coefficient.-/
lemma is_unit_constant_coeff (φ : mv_power_series σ R) (h : is_unit φ) :
is_unit (constant_coeff σ R φ) :=
h.map (constant_coeff σ R).to_monoid_hom
@[simp]
lemma coeff_smul (f : mv_power_series σ R) (n) (a : R) :
coeff _ n (a • f) = a * coeff _ n f :=
rfl
lemma X_inj [nontrivial R] {s t : σ} : (X s : mv_power_series σ R) = X t ↔ s = t :=
⟨begin
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,
cases H, { exact H.1 }, { exfalso, exact one_ne_zero H.1 } },
{ exfalso, exact one_ne_zero h }
end, congr_arg X⟩
end semiring
section map
variables {S T : Type*} [semiring R] [semiring S] [semiring T]
variables (f : R →+* S) (g : S →+* T)
variable (σ)
/-- The map between multivariate formal power series induced by a map on the coefficients.-/
def map : mv_power_series σ R →+* mv_power_series σ S :=
{ to_fun := λ φ n, f $ coeff R n φ,
map_zero' := ext $ λ n, f.map_zero,
map_one' := ext $ λ n, show f ((coeff R n) 1) = (coeff S n) 1,
by { rw [coeff_one, coeff_one], split_ifs; simp [f.map_one, f.map_zero] },
map_add' := λ φ ψ, ext $ λ n,
show f ((coeff R n) (φ + ψ)) = f ((coeff R n) φ) + f ((coeff R n) ψ), by simp,
map_mul' := λ φ ψ, ext $ λ n, show f _ = _,
begin
rw [coeff_mul, f.map_sum, coeff_mul, finset.sum_congr rfl],
rintros ⟨i,j⟩ hij, rw [f.map_mul], refl,
end }
variable {σ}
@[simp] lemma map_id : map σ (ring_hom.id R) = ring_hom.id _ := rfl
lemma map_comp : map σ (g.comp f) = (map σ g).comp (map σ f) := rfl
@[simp] lemma coeff_map (n : σ →₀ ℕ) (φ : mv_power_series σ R) :
coeff S n (map σ f φ) = f (coeff R n φ) := rfl
@[simp] lemma constant_coeff_map (φ : mv_power_series σ R) :
constant_coeff σ S (map σ f φ) = f (constant_coeff σ R φ) := rfl
@[simp] lemma map_monomial (n : σ →₀ ℕ) (a : R) :
map σ f (monomial R n a) = monomial S n (f a) :=
by { ext m, simp [coeff_monomial, apply_ite f] }
@[simp] lemma map_C (a : R) : map σ f (C σ R a) = C σ S (f a) :=
map_monomial _ _ _
@[simp] lemma map_X (s : σ) : map σ f (X s) = X s := by simp [X]
end map
section algebra
variables {A : Type*} [comm_semiring R] [semiring A] [algebra R A]
instance : algebra R (mv_power_series σ A) :=
{ commutes' := λ a φ, by { ext n, simp [algebra.commutes] },
smul_def' := λ a σ, by { ext n, simp [(coeff A n).map_smul_of_tower a, algebra.smul_def] },
to_ring_hom := (mv_power_series.map σ (algebra_map R A)).comp (C σ R),
.. mv_power_series.module }
theorem C_eq_algebra_map : C σ R = (algebra_map R (mv_power_series σ R)) := rfl
theorem algebra_map_apply {r : R} :
algebra_map R (mv_power_series σ A) r = C σ A (algebra_map R A r) :=
begin
change (mv_power_series.map σ (algebra_map R A)).comp (C σ R) r = _,
simp,
end
instance [nonempty σ] [nontrivial R] : nontrivial (subalgebra R (mv_power_series σ R)) :=
⟨⟨⊥, ⊤, begin
rw [ne.def, set_like.ext_iff, not_forall],
inhabit σ,
refine ⟨X (default σ), _⟩,
simp only [algebra.mem_bot, not_exists, set.mem_range, iff_true, algebra.mem_top],
intros x,
rw [ext_iff, not_forall],
refine ⟨finsupp.single (default σ) 1, _⟩,
simp [algebra_map_apply, coeff_C],
end⟩⟩
end algebra
section trunc
variables [comm_semiring R] (n : σ →₀ ℕ)
/-- Auxiliary definition for the truncation function. -/
def trunc_fun (φ : mv_power_series σ R) : mv_polynomial σ R :=
∑ m in Iic_finset n, mv_polynomial.monomial m (coeff R m φ)
lemma coeff_trunc_fun (m : σ →₀ ℕ) (φ : mv_power_series σ R) :
(trunc_fun n φ).coeff m = if m ≤ n then coeff R m φ else 0 :=
by simp [trunc_fun, mv_polynomial.coeff_sum]
variable (R)
/-- The `n`th truncation of a multivariate formal power series to a multivariate polynomial -/
def trunc : mv_power_series σ R →+ mv_polynomial σ R :=
{ to_fun := trunc_fun n,
map_zero' := by { ext, simp [coeff_trunc_fun] },
map_add' := by { intros, ext, simp [coeff_trunc_fun, ite_add], split_ifs; refl } }
variable {R}
lemma coeff_trunc (m : σ →₀ ℕ) (φ : mv_power_series σ R) :
(trunc R n φ).coeff m = if m ≤ n then coeff R m φ else 0 :=
by simp [trunc, coeff_trunc_fun]
@[simp] lemma trunc_one : trunc R n 1 = 1 :=
mv_polynomial.ext _ _ $ λ m,
begin
rw [coeff_trunc, coeff_one],
split_ifs with H H' H',
{ subst m, simp },
{ symmetry, rw mv_polynomial.coeff_one, exact if_neg (ne.symm H'), },
{ symmetry, rw mv_polynomial.coeff_one, refine if_neg _,
intro H', apply H, subst m, intro s, exact nat.zero_le _ }
end
@[simp] lemma trunc_C (a : R) : trunc R n (C σ R a) = mv_polynomial.C a :=
mv_polynomial.ext _ _ $ λ m,
begin
rw [coeff_trunc, coeff_C, mv_polynomial.coeff_C],
split_ifs with H; refl <|> try {simp * at *},
exfalso, apply H, subst m, intro s, exact nat.zero_le _
end
end trunc
section comm_semiring
variable [comm_semiring R]
lemma X_pow_dvd_iff {s : σ} {n : ℕ} {φ : mv_power_series σ R} :
(X s : mv_power_series σ R)^n ∣ φ ↔ ∀ m : σ →₀ ℕ, m s < n → coeff R m φ = 0 :=
begin
split,
{ rintros ⟨φ, rfl⟩ m h,
rw [coeff_mul, finset.sum_eq_zero],
rintros ⟨i,j⟩ hij, rw [coeff_X_pow, if_neg, zero_mul],
contrapose! h, subst i, rw finsupp.mem_antidiagonal at hij,
rw [← hij, finsupp.add_apply, finsupp.single_eq_same], exact nat.le_add_right n _ },
{ intro h, refine ⟨λ m, coeff R (m + (single s n)) φ, _⟩,
ext m, by_cases H : m - single s n + single s n = m,
{ rw [coeff_mul, finset.sum_eq_single (single s n, m - single s n)],
{ rw [coeff_X_pow, if_pos rfl, one_mul],
simpa using congr_arg (λ (m : σ →₀ ℕ), coeff R m φ) H.symm },
{ rintros ⟨i,j⟩ hij hne, rw finsupp.mem_antidiagonal at hij,
rw coeff_X_pow, split_ifs with hi,
{ exfalso, apply hne, rw [← hij, ← hi, prod.mk.inj_iff], refine ⟨rfl, _⟩,
ext t, simp only [nat.add_sub_cancel_left, finsupp.add_apply, finsupp.nat_sub_apply] },
{ exact zero_mul _ } },
{ intro hni, exfalso, apply hni, rwa [finsupp.mem_antidiagonal, add_comm] } },
{ rw [h, coeff_mul, finset.sum_eq_zero],
{ rintros ⟨i,j⟩ hij, rw finsupp.mem_antidiagonal at hij,
rw coeff_X_pow, split_ifs with hi,
{ exfalso, apply H, rw [← hij, hi], ext,
rw [coe_add, coe_add, pi.add_apply, pi.add_apply, nat_add_sub_cancel_left, add_comm], },
{ exact zero_mul _ } },
{ classical, contrapose! H, ext t,
by_cases hst : s = t,
{ subst t, simpa using nat.sub_add_cancel H },
{ simp [finsupp.single_apply, hst] } } } }
end
lemma X_dvd_iff {s : σ} {φ : mv_power_series σ R} :
(X s : mv_power_series σ R) ∣ φ ↔ ∀ m : σ →₀ ℕ, m s = 0 → coeff R m φ = 0 :=
begin
rw [← pow_one (X s : mv_power_series σ R), X_pow_dvd_iff],
split; intros h m hm,
{ exact h m (hm.symm ▸ zero_lt_one) },
{ exact h m (nat.eq_zero_of_le_zero $ nat.le_of_succ_le_succ hm) }
end
end comm_semiring
section ring
variables [ring R]
/-
The inverse of a multivariate formal power series is defined by
well-founded recursion on the coeffients of the inverse.
-/
/-- Auxiliary definition that unifies
the totalised inverse formal power series `(_)⁻¹` and
the inverse formal power series that depends on
an inverse of the constant coefficient `inv_of_unit`.-/
protected noncomputable def inv.aux (a : R) (φ : mv_power_series σ R) : mv_power_series σ R
| n := if n = 0 then a else
- a * ∑ x in n.antidiagonal,
if h : x.2 < n then coeff R x.1 φ * inv.aux x.2 else 0
using_well_founded
{ rel_tac := λ _ _, `[exact ⟨_, finsupp.lt_wf σ⟩],
dec_tac := tactic.assumption }
lemma coeff_inv_aux [decidable_eq σ] (n : σ →₀ ℕ) (a : R) (φ : mv_power_series σ R) :
coeff R n (inv.aux a φ) = if n = 0 then a else
- a * ∑ x in n.antidiagonal,
if x.2 < n then coeff R x.1 φ * coeff R x.2 (inv.aux a φ) else 0 :=
show inv.aux a φ n = _,
begin
rw inv.aux,
convert rfl -- unify `decidable` instances
end
/-- A multivariate formal power series is invertible if the constant coefficient is invertible.-/
def inv_of_unit (φ : mv_power_series σ R) (u : units R) : mv_power_series σ R :=
inv.aux (↑u⁻¹) φ
lemma coeff_inv_of_unit [decidable_eq σ] (n : σ →₀ ℕ) (φ : mv_power_series σ R) (u : units R) :
coeff R n (inv_of_unit φ u) = if n = 0 then ↑u⁻¹ else
- ↑u⁻¹ * ∑ x in n.antidiagonal,
if x.2 < n then coeff R x.1 φ * coeff R x.2 (inv_of_unit φ u) else 0 :=
coeff_inv_aux n (↑u⁻¹) φ
@[simp] lemma constant_coeff_inv_of_unit (φ : mv_power_series σ R) (u : units R) :
constant_coeff σ R (inv_of_unit φ u) = ↑u⁻¹ :=
by rw [← coeff_zero_eq_constant_coeff_apply, coeff_inv_of_unit, if_pos rfl]
lemma mul_inv_of_unit (φ : mv_power_series σ R) (u : units R) (h : constant_coeff σ R φ = u) :
φ * inv_of_unit φ u = 1 :=
ext $ λ n, if H : n = 0 then by { rw H, simp [coeff_mul, support_single_ne_zero, h], }
else
begin
have : ((0 : σ →₀ ℕ), n) ∈ n.antidiagonal,
{ rw [finsupp.mem_antidiagonal, zero_add] },
rw [coeff_one, if_neg H, coeff_mul,
← finset.insert_erase this, finset.sum_insert (finset.not_mem_erase _ _),
coeff_zero_eq_constant_coeff_apply, h, coeff_inv_of_unit, if_neg H,
neg_mul_eq_neg_mul_symm, mul_neg_eq_neg_mul_symm, units.mul_inv_cancel_left,
← finset.insert_erase this, finset.sum_insert (finset.not_mem_erase _ _),
finset.insert_erase this, if_neg (not_lt_of_ge $ le_refl _), zero_add, add_comm,
← sub_eq_add_neg, sub_eq_zero, finset.sum_congr rfl],
rintros ⟨i,j⟩ hij, rw [finset.mem_erase, finsupp.mem_antidiagonal] at hij,
cases hij with h₁ h₂,
subst n, rw if_pos,
suffices : (0 : _) + j < i + j, {simpa},
apply add_lt_add_right,
split,
{ intro s, exact nat.zero_le _ },
{ intro H, apply h₁,
suffices : i = 0, {simp [this]},
ext1 s, exact nat.eq_zero_of_le_zero (H s) }
end
end ring
section comm_ring
variable [comm_ring R]
/-- Multivariate formal power series over a local ring form a local ring. -/
instance is_local_ring [local_ring R] : local_ring (mv_power_series σ R) :=
{ is_local := by { intro φ, rcases local_ring.is_local (constant_coeff σ R φ) with ⟨u,h⟩|⟨u,h⟩;
[left, right];
{ refine is_unit_of_mul_eq_one _ _ (mul_inv_of_unit _ u _),
simpa using h.symm } } }
-- TODO(jmc): once adic topology lands, show that this is complete
end comm_ring
section local_ring
variables {S : Type*} [comm_ring R] [comm_ring S] (f : R →+* S)
[is_local_ring_hom f]
-- Thanks to the linter for informing us that this instance does
-- not actually need R and S to be local rings!
/-- The map `A[[X]] → B[[X]]` induced by a local ring hom `A → B` is local -/
instance map.is_local_ring_hom : is_local_ring_hom (map σ f) :=
⟨begin
rintros φ ⟨ψ, h⟩,
replace h := congr_arg (constant_coeff σ S) h,
rw constant_coeff_map at h,
have : is_unit (constant_coeff σ S ↑ψ) := @is_unit_constant_coeff σ S _ (↑ψ) ψ.is_unit,
rw h at this,
rcases is_unit_of_map_unit f _ this with ⟨c, hc⟩,
exact is_unit_of_mul_eq_one φ (inv_of_unit φ c) (mul_inv_of_unit φ c hc.symm)
end⟩
variables [local_ring R] [local_ring S]
instance : local_ring (mv_power_series σ R) :=
{ is_local := local_ring.is_local }
end local_ring
section field
variables {k : Type*} [field k]
/-- The inverse `1/f` of a multivariable power series `f` over a field -/
protected def inv (φ : mv_power_series σ k) : mv_power_series σ k :=
inv.aux (constant_coeff σ k φ)⁻¹ φ
instance : has_inv (mv_power_series σ k) := ⟨mv_power_series.inv⟩
lemma coeff_inv [decidable_eq σ] (n : σ →₀ ℕ) (φ : mv_power_series σ k) :
coeff k n (φ⁻¹) = if n = 0 then (constant_coeff σ k φ)⁻¹ else
- (constant_coeff σ k φ)⁻¹ * ∑ x in n.antidiagonal,
if x.2 < n then coeff k x.1 φ * coeff k x.2 (φ⁻¹) else 0 :=
coeff_inv_aux n _ φ
@[simp] lemma constant_coeff_inv (φ : mv_power_series σ k) :
constant_coeff σ k (φ⁻¹) = (constant_coeff σ k φ)⁻¹ :=
by rw [← coeff_zero_eq_constant_coeff_apply, coeff_inv, if_pos rfl]
lemma inv_eq_zero {φ : mv_power_series σ k} :
φ⁻¹ = 0 ↔ constant_coeff σ k φ = 0 :=
⟨λ h, by simpa using congr_arg (constant_coeff σ k) h,
λ h, ext $ λ n, by { rw coeff_inv, split_ifs;
simp only [h, mv_power_series.coeff_zero, zero_mul, inv_zero, neg_zero] }⟩
@[simp, priority 1100]
lemma inv_of_unit_eq (φ : mv_power_series σ k) (h : constant_coeff σ k φ ≠ 0) :
inv_of_unit φ (units.mk0 _ h) = φ⁻¹ := rfl
@[simp]
lemma inv_of_unit_eq' (φ : mv_power_series σ k) (u : units k) (h : constant_coeff σ k φ = u) :
inv_of_unit φ u = φ⁻¹ :=
begin
rw ← inv_of_unit_eq φ (h.symm ▸ u.ne_zero),
congr' 1, rw [units.ext_iff], exact h.symm,
end
@[simp] protected lemma mul_inv (φ : mv_power_series σ k) (h : constant_coeff σ k φ ≠ 0) :
φ * φ⁻¹ = 1 :=
by rw [← inv_of_unit_eq φ h, mul_inv_of_unit φ (units.mk0 _ h) rfl]
@[simp] protected lemma inv_mul (φ : mv_power_series σ k) (h : constant_coeff σ k φ ≠ 0) :
φ⁻¹ * φ = 1 :=
by rw [mul_comm, φ.mul_inv h]
protected lemma eq_mul_inv_iff_mul_eq {φ₁ φ₂ φ₃ : mv_power_series σ k}
(h : constant_coeff σ k φ₃ ≠ 0) :
φ₁ = φ₂ * φ₃⁻¹ ↔ φ₁ * φ₃ = φ₂ :=
⟨λ k, by simp [k, mul_assoc, mv_power_series.inv_mul _ h],
λ k, by simp [← k, mul_assoc, mv_power_series.mul_inv _ h]⟩
protected lemma eq_inv_iff_mul_eq_one {φ ψ : mv_power_series σ k} (h : constant_coeff σ k ψ ≠ 0) :
φ = ψ⁻¹ ↔ φ * ψ = 1 :=
by rw [← mv_power_series.eq_mul_inv_iff_mul_eq h, one_mul]
protected lemma inv_eq_iff_mul_eq_one {φ ψ : mv_power_series σ k} (h : constant_coeff σ k ψ ≠ 0) :
ψ⁻¹ = φ ↔ φ * ψ = 1 :=
by rw [eq_comm, mv_power_series.eq_inv_iff_mul_eq_one h]
end field
end mv_power_series
namespace mv_polynomial
open finsupp
variables {σ : Type*} {R : Type*} [comm_semiring R]
/-- The natural inclusion from multivariate polynomials into multivariate formal power series.-/
instance coe_to_mv_power_series : has_coe (mv_polynomial σ R) (mv_power_series σ R) :=
⟨λ φ n, coeff n φ⟩
@[simp, norm_cast] lemma coeff_coe (φ : mv_polynomial σ R) (n : σ →₀ ℕ) :
mv_power_series.coeff R n ↑φ = coeff n φ := rfl
@[simp, norm_cast] lemma coe_monomial (n : σ →₀ ℕ) (a : R) :
(monomial n a : mv_power_series σ R) = mv_power_series.monomial R n a :=
mv_power_series.ext $ λ m,
begin
rw [coeff_coe, coeff_monomial, mv_power_series.coeff_monomial],
split_ifs with h₁ h₂; refl <|> subst m; contradiction
end
@[simp, norm_cast] lemma coe_zero : ((0 : mv_polynomial σ R) : mv_power_series σ R) = 0 := rfl
@[simp, norm_cast] lemma coe_one : ((1 : mv_polynomial σ R) : mv_power_series σ R) = 1 :=
coe_monomial _ _
@[simp, norm_cast] lemma coe_add (φ ψ : mv_polynomial σ R) :
((φ + ψ : mv_polynomial σ R) : mv_power_series σ R) = φ + ψ := rfl
@[simp, norm_cast] lemma coe_mul (φ ψ : mv_polynomial σ R) :
((φ * ψ : mv_polynomial σ R) : mv_power_series σ R) = φ * ψ :=
mv_power_series.ext $ λ n,
by simp only [coeff_coe, mv_power_series.coeff_mul, coeff_mul]
@[simp, norm_cast] lemma coe_C (a : R) :
((C a : mv_polynomial σ R) : mv_power_series σ R) = mv_power_series.C σ R a :=
coe_monomial _ _
@[simp, norm_cast] lemma coe_X (s : σ) :
((X s : mv_polynomial σ R) : mv_power_series σ R) = mv_power_series.X s :=
coe_monomial _ _
/--
The coercion from multivariable polynomials to multivariable power series
as a ring homomorphism.
-/
-- TODO as an algebra homomorphism?
def coe_to_mv_power_series.ring_hom : mv_polynomial σ R →+* mv_power_series σ R :=
{ to_fun := (coe : mv_polynomial σ R → mv_power_series σ R),
map_zero' := coe_zero,
map_one' := coe_one,
map_add' := coe_add,
map_mul' := coe_mul }
end mv_polynomial
/-- Formal power series over the coefficient ring `R`.-/
def power_series (R : Type*) := mv_power_series unit R
namespace power_series
open finsupp (single)
variable {R : Type*}
section
local attribute [reducible] power_series
instance [inhabited R] : inhabited (power_series R) := by apply_instance
instance [add_monoid R] : add_monoid (power_series R) := by apply_instance
instance [add_group R] : add_group (power_series R) := by apply_instance
instance [add_comm_monoid R] : add_comm_monoid (power_series R) := by apply_instance
instance [add_comm_group R] : add_comm_group (power_series R) := by apply_instance
instance [semiring R] : semiring (power_series R) := by apply_instance
instance [comm_semiring R] : comm_semiring (power_series R) := by apply_instance
instance [ring R] : ring (power_series R) := by apply_instance
instance [comm_ring R] : comm_ring (power_series R) := by apply_instance
instance [nontrivial R] : nontrivial (power_series R) := by apply_instance
instance {A} [semiring R] [add_comm_monoid A] [module R A] :
module R (power_series A) := by apply_instance
instance {A S} [semiring R] [semiring S] [add_comm_monoid A] [module R A] [module S A]
[has_scalar R S] [is_scalar_tower R S A] :
is_scalar_tower R S (power_series A) :=
pi.is_scalar_tower
instance {A} [semiring A] [comm_semiring R] [algebra R A] :
algebra R (power_series A) := by apply_instance
end
section semiring
variables (R) [semiring R]
/-- The `n`th coefficient of a formal power series.-/
def coeff (n : ℕ) : power_series R →ₗ[R] R := mv_power_series.coeff R (single () n)
/-- The `n`th monomial with coefficient `a` as formal power series.-/
def monomial (n : ℕ) : R →ₗ[R] power_series R := mv_power_series.monomial R (single () n)
variables {R}
lemma coeff_def {s : unit →₀ ℕ} {n : ℕ} (h : s () = n) :
coeff R n = mv_power_series.coeff R s :=
by erw [coeff, ← h, ← finsupp.unique_single s]
/-- Two formal power series are equal if all their coefficients are equal.-/
@[ext] lemma ext {φ ψ : power_series R} (h : ∀ n, coeff R n φ = coeff R n ψ) :
φ = ψ :=
mv_power_series.ext $ λ n,
by { rw ← coeff_def, { apply h }, refl }
/-- Two formal power series are equal if all their coefficients are equal.-/
lemma ext_iff {φ ψ : power_series R} : φ = ψ ↔ (∀ n, coeff R n φ = coeff R n ψ) :=
⟨λ h n, congr_arg (coeff R n) h, ext⟩
/-- Constructor for formal power series.-/
def mk {R} (f : ℕ → R) : power_series R := λ s, f (s ())
@[simp] lemma coeff_mk (n : ℕ) (f : ℕ → R) : coeff R n (mk f) = f n :=
congr_arg f finsupp.single_eq_same
lemma coeff_monomial (m n : ℕ) (a : R) :
coeff R m (monomial R n a) = if m = n then a else 0 :=
calc coeff R m (monomial R n a) = _ : mv_power_series.coeff_monomial _ _ _
... = if m = n then a else 0 :
by { simp only [finsupp.unique_single_eq_iff], split_ifs; refl }
lemma monomial_eq_mk (n : ℕ) (a : R) :
monomial R n a = mk (λ m, if m = n then a else 0) :=
ext $ λ m, by { rw [coeff_monomial, coeff_mk] }
@[simp] lemma coeff_monomial_same (n : ℕ) (a : R) :
coeff R n (monomial R n a) = a :=
mv_power_series.coeff_monomial_same _ _
@[simp] lemma coeff_comp_monomial (n : ℕ) :
(coeff R n).comp (monomial R n) = linear_map.id :=
linear_map.ext $ coeff_monomial_same n
variable (R)
/--The constant coefficient of a formal power series. -/
def constant_coeff : power_series R →+* R := mv_power_series.constant_coeff unit R
/-- The constant formal power series.-/
def C : R →+* power_series R := mv_power_series.C unit R
variable {R}
/-- The variable of the formal power series ring.-/
def X : power_series R := mv_power_series.X ()
@[simp] lemma coeff_zero_eq_constant_coeff :
⇑(coeff R 0) = constant_coeff R :=
by { rw [coeff, finsupp.single_zero], refl }
lemma coeff_zero_eq_constant_coeff_apply (φ : power_series R) :
coeff R 0 φ = constant_coeff R φ :=
by rw [coeff_zero_eq_constant_coeff]; refl
@[simp] lemma monomial_zero_eq_C : ⇑(monomial R 0) = C R :=
by rw [monomial, finsupp.single_zero, mv_power_series.monomial_zero_eq_C, C]
lemma monomial_zero_eq_C_apply (a : R) : monomial R 0 a = C R a :=
by simp
lemma coeff_C (n : ℕ) (a : R) :
coeff R n (C R a : power_series R) = if n = 0 then a else 0 :=
by rw [← monomial_zero_eq_C_apply, coeff_monomial]
@[simp] lemma coeff_zero_C (a : R) : coeff R 0 (C R a) = a :=
by rw [← monomial_zero_eq_C_apply, coeff_monomial_same 0 a]
lemma X_eq : (X : power_series R) = monomial R 1 1 := rfl
lemma coeff_X (n : ℕ) :
coeff R n (X : power_series R) = if n = 1 then 1 else 0 :=
by rw [X_eq, coeff_monomial]
@[simp] lemma coeff_zero_X : coeff R 0 (X : power_series R) = 0 :=
by rw [coeff, finsupp.single_zero, X, mv_power_series.coeff_zero_X]
@[simp] lemma coeff_one_X : coeff R 1 (X : power_series R) = 1 :=
by rw [coeff_X, if_pos rfl]
lemma X_pow_eq (n : ℕ) : (X : power_series R)^n = monomial R n 1 :=
mv_power_series.X_pow_eq _ n
lemma coeff_X_pow (m n : ℕ) :
coeff R m ((X : power_series R)^n) = if m = n then 1 else 0 :=
by rw [X_pow_eq, coeff_monomial]
@[simp] lemma coeff_X_pow_self (n : ℕ) :
coeff R n ((X : power_series R)^n) = 1 :=
by rw [coeff_X_pow, if_pos rfl]
@[simp] lemma coeff_one (n : ℕ) :
coeff R n (1 : power_series R) = if n = 0 then 1 else 0 :=
coeff_C n 1
lemma coeff_zero_one : coeff R 0 (1 : power_series R) = 1 :=
coeff_zero_C 1
lemma coeff_mul (n : ℕ) (φ ψ : power_series R) :
coeff R n (φ * ψ) = ∑ p in finset.nat.antidiagonal n, coeff R p.1 φ * coeff R p.2 ψ :=
begin
symmetry,
apply finset.sum_bij (λ (p : ℕ × ℕ) h, (single () p.1, single () p.2)),
{ rintros ⟨i,j⟩ hij, rw finset.nat.mem_antidiagonal at hij,
rw [finsupp.mem_antidiagonal, ← finsupp.single_add, hij], },
{ rintros ⟨i,j⟩ hij, refl },
{ rintros ⟨i,j⟩ ⟨k,l⟩ hij hkl,
simpa only [prod.mk.inj_iff, finsupp.unique_single_eq_iff] using id },
{ rintros ⟨f,g⟩ hfg,
refine ⟨(f (), g ()), _, _⟩,
{ rw finsupp.mem_antidiagonal at hfg,
rw [finset.nat.mem_antidiagonal, ← finsupp.add_apply, hfg, finsupp.single_eq_same] },
{ rw prod.mk.inj_iff, dsimp,
exact ⟨finsupp.unique_single f, finsupp.unique_single g⟩ } }
end
@[simp] lemma coeff_mul_C (n : ℕ) (φ : power_series R) (a : R) :
coeff R n (φ * C R a) = coeff R n φ * a :=
mv_power_series.coeff_mul_C _ φ a
@[simp] lemma coeff_C_mul (n : ℕ) (φ : power_series R) (a : R) :
coeff R n (C R a * φ) = a * coeff R n φ :=
mv_power_series.coeff_C_mul _ φ a
@[simp] lemma coeff_smul (n : ℕ) (φ : power_series R) (a : R) :
coeff R n (a • φ) = a * coeff R n φ :=
rfl
@[simp] lemma coeff_succ_mul_X (n : ℕ) (φ : power_series R) :
coeff R (n+1) (φ * X) = coeff R n φ :=
begin
simp only [coeff, finsupp.single_add],
convert φ.coeff_add_mul_monomial (single () n) (single () 1) _,
rw mul_one
end
@[simp] lemma coeff_succ_X_mul (n : ℕ) (φ : power_series R) :
coeff R (n + 1) (X * φ) = coeff R n φ :=
begin
simp only [coeff, finsupp.single_add, add_comm n 1],
convert φ.coeff_add_monomial_mul (single () 1) (single () n) _,
rw one_mul,
end
@[simp] lemma constant_coeff_C (a : R) : constant_coeff R (C R a) = a := rfl
@[simp] lemma constant_coeff_comp_C :
(constant_coeff R).comp (C R) = ring_hom.id R := rfl
@[simp] lemma constant_coeff_zero : constant_coeff R 0 = 0 := rfl
@[simp] lemma constant_coeff_one : constant_coeff R 1 = 1 := rfl
@[simp] lemma constant_coeff_X : constant_coeff R X = 0 := mv_power_series.coeff_zero_X _
lemma coeff_zero_mul_X (φ : power_series R) : coeff R 0 (φ * X) = 0 := by simp
lemma coeff_zero_X_mul (φ : power_series R) : coeff R 0 (X * φ) = 0 := by simp
/-- If a formal power series is invertible, then so is its constant coefficient.-/
lemma is_unit_constant_coeff (φ : power_series R) (h : is_unit φ) :
is_unit (constant_coeff R φ) :=
mv_power_series.is_unit_constant_coeff φ h
/-- Split off the constant coefficient. -/
lemma eq_shift_mul_X_add_const (φ : power_series R) :
φ = mk (λ p, coeff R (p + 1) φ) * X + C R (constant_coeff R φ) :=
begin
ext (_ | n),
{ simp only [ring_hom.map_add, constant_coeff_C, constant_coeff_X, coeff_zero_eq_constant_coeff,
zero_add, mul_zero, ring_hom.map_mul], },
{ simp only [coeff_succ_mul_X, coeff_mk, linear_map.map_add, coeff_C, n.succ_ne_zero, sub_zero,
if_false, add_zero], }
end
/-- Split off the constant coefficient. -/
lemma eq_X_mul_shift_add_const (φ : power_series R) :
φ = X * mk (λ p, coeff R (p + 1) φ) + C R (constant_coeff R φ) :=
begin
ext (_ | n),
{ simp only [ring_hom.map_add, constant_coeff_C, constant_coeff_X, coeff_zero_eq_constant_coeff,
zero_add, zero_mul, ring_hom.map_mul], },
{ simp only [coeff_succ_X_mul, coeff_mk, linear_map.map_add, coeff_C, n.succ_ne_zero, sub_zero,
if_false, add_zero], }
end
section map
variables {S : Type*} {T : Type*} [semiring S] [semiring T]
variables (f : R →+* S) (g : S →+* T)
/-- The map between formal power series induced by a map on the coefficients.-/
def map : power_series R →+* power_series S :=
mv_power_series.map _ f
@[simp] lemma map_id : (map (ring_hom.id R) :
power_series R → power_series R) = id := rfl
lemma map_comp : map (g.comp f) = (map g).comp (map f) := rfl
@[simp] lemma coeff_map (n : ℕ) (φ : power_series R) :
coeff S n (map f φ) = f (coeff R n φ) := rfl
end map
end semiring
section comm_semiring
variables [comm_semiring R]
lemma X_pow_dvd_iff {n : ℕ} {φ : power_series R} :
(X : power_series R)^n ∣ φ ↔ ∀ m, m < n → coeff R m φ = 0 :=
begin
convert @mv_power_series.X_pow_dvd_iff unit R _ () n φ, apply propext,
classical, split; intros h m hm,
{ rw finsupp.unique_single m, convert h _ hm },
{ apply h, simpa only [finsupp.single_eq_same] using hm }
end
lemma X_dvd_iff {φ : power_series R} :
(X : power_series R) ∣ φ ↔ constant_coeff R φ = 0 :=
begin
rw [← pow_one (X : power_series R), X_pow_dvd_iff, ← coeff_zero_eq_constant_coeff_apply],
split; intro h,
{ exact h 0 zero_lt_one },
{ intros m hm, rwa nat.eq_zero_of_le_zero (nat.le_of_succ_le_succ hm) }
end
open finset nat
/-- The ring homomorphism taking a power series `f(X)` to `f(aX)`. -/
noncomputable def rescale (a : R) : power_series R →+* power_series R :=
{ to_fun := λ f, power_series.mk $ λ n, a^n * (power_series.coeff R n f),
map_zero' := by { ext, simp only [linear_map.map_zero, power_series.coeff_mk, mul_zero], },
map_one' := by { ext1, simp only [mul_boole, power_series.coeff_mk, power_series.coeff_one],
split_ifs, { rw [h, pow_zero], }, refl, },
map_add' := by { intros, ext, exact mul_add _ _ _, },
map_mul' := λ f g, by {
ext,
rw [power_series.coeff_mul, power_series.coeff_mk, power_series.coeff_mul, finset.mul_sum],
apply sum_congr rfl,
simp only [coeff_mk, prod.forall, nat.mem_antidiagonal],
intros b c H,
rw [←H, pow_add, mul_mul_mul_comm] }, }
@[simp] lemma coeff_rescale (f : power_series R) (a : R) (n : ℕ) :
coeff R n (rescale a f) = a^n * coeff R n f := coeff_mk n _
@[simp] lemma rescale_zero : rescale 0 = (C R).comp (constant_coeff R) :=
begin
ext,
simp only [function.comp_app, ring_hom.coe_comp, rescale, ring_hom.coe_mk,
power_series.coeff_mk _ _, coeff_C],
split_ifs,
{ simp only [h, one_mul, coeff_zero_eq_constant_coeff, pow_zero], },
{ rw [zero_pow' n h, zero_mul], },
end
lemma rescale_zero_apply : rescale 0 X = C R (constant_coeff R X) :=
by simp
@[simp] lemma rescale_one : rescale 1 = ring_hom.id (power_series R) :=
by { ext, simp only [ring_hom.id_apply, rescale, one_pow, coeff_mk, one_mul,
ring_hom.coe_mk], }
section trunc
/-- The `n`th truncation of a formal power series to a polynomial -/
def trunc (n : ℕ) (φ : power_series R) : polynomial R :=
∑ m in Ico 0 (n + 1), polynomial.monomial m (coeff R m φ)
lemma coeff_trunc (m) (n) (φ : power_series R) :
(trunc n φ).coeff m = if m ≤ n then coeff R m φ else 0 :=
by simp [trunc, polynomial.coeff_sum, polynomial.coeff_monomial, nat.lt_succ_iff]
@[simp] lemma trunc_zero (n) : trunc n (0 : power_series R) = 0 :=
polynomial.ext $ λ m,
begin
rw [coeff_trunc, linear_map.map_zero, polynomial.coeff_zero],
split_ifs; refl
end
@[simp] lemma trunc_one (n) : trunc n (1 : power_series R) = 1 :=
polynomial.ext $ λ m,
begin
rw [coeff_trunc, coeff_one],
split_ifs with H H' H'; rw [polynomial.coeff_one],
{ subst m, rw [if_pos rfl] },
{ symmetry, exact if_neg (ne.elim (ne.symm H')) },
{ symmetry, refine if_neg _,
intro H', apply H, subst m, exact nat.zero_le _ }
end
@[simp] lemma trunc_C (n) (a : R) : trunc n (C R a) = polynomial.C a :=
polynomial.ext $ λ m,
begin
rw [coeff_trunc, coeff_C, polynomial.coeff_C],
split_ifs with H; refl <|> try {simp * at *}
end
@[simp] lemma trunc_add (n) (φ ψ : power_series R) :
trunc n (φ + ψ) = trunc n φ + trunc n ψ :=
polynomial.ext $ λ m,
begin
simp only [coeff_trunc, add_monoid_hom.map_add, polynomial.coeff_add],
split_ifs with H, {refl}, {rw [zero_add]}
end
end trunc
end comm_semiring
section ring
variables [ring R]
/-- Auxiliary function used for computing inverse of a power series -/
protected def inv.aux : R → power_series R → power_series R :=
mv_power_series.inv.aux
lemma coeff_inv_aux (n : ℕ) (a : R) (φ : power_series R) :
coeff R n (inv.aux a φ) = if n = 0 then a else
- a * ∑ x in finset.nat.antidiagonal n,
if x.2 < n then coeff R x.1 φ * coeff R x.2 (inv.aux a φ) else 0 :=
begin
rw [coeff, inv.aux, mv_power_series.coeff_inv_aux],
simp only [finsupp.single_eq_zero],
split_ifs, {refl},
congr' 1,
symmetry,
apply finset.sum_bij (λ (p : ℕ × ℕ) h, (single () p.1, single () p.2)),
{ rintros ⟨i,j⟩ hij, rw finset.nat.mem_antidiagonal at hij,
rw [finsupp.mem_antidiagonal, ← finsupp.single_add, hij], },
{ rintros ⟨i,j⟩ hij,
by_cases H : j < n,
{ rw [if_pos H, if_pos], {refl},
split,
{ rintro ⟨⟩, simpa [finsupp.single_eq_same] using le_of_lt H },
{ intro hh, rw lt_iff_not_ge at H, apply H,
simpa [finsupp.single_eq_same] using hh () } },
{ rw [if_neg H, if_neg], rintro ⟨h₁, h₂⟩, apply h₂, rintro ⟨⟩,
simpa [finsupp.single_eq_same] using not_lt.1 H } },
{ rintros ⟨i,j⟩ ⟨k,l⟩ hij hkl,
simpa only [prod.mk.inj_iff, finsupp.unique_single_eq_iff] using id },
{ rintros ⟨f,g⟩ hfg,
refine ⟨(f (), g ()), _, _⟩,
{ rw finsupp.mem_antidiagonal at hfg,
rw [finset.nat.mem_antidiagonal, ← finsupp.add_apply, hfg, finsupp.single_eq_same] },
{ rw prod.mk.inj_iff, dsimp,
exact ⟨finsupp.unique_single f, finsupp.unique_single g⟩ } }
end
/-- A formal power series is invertible if the constant coefficient is invertible.-/
def inv_of_unit (φ : power_series R) (u : units R) : power_series R :=
mv_power_series.inv_of_unit φ u
lemma coeff_inv_of_unit (n : ℕ) (φ : power_series R) (u : units R) :
coeff R n (inv_of_unit φ u) = if n = 0 then ↑u⁻¹ else
- ↑u⁻¹ * ∑ x in finset.nat.antidiagonal n,
if x.2 < n then coeff R x.1 φ * coeff R x.2 (inv_of_unit φ u) else 0 :=
coeff_inv_aux n ↑u⁻¹ φ
@[simp] lemma constant_coeff_inv_of_unit (φ : power_series R) (u : units R) :
constant_coeff R (inv_of_unit φ u) = ↑u⁻¹ :=
by rw [← coeff_zero_eq_constant_coeff_apply, coeff_inv_of_unit, if_pos rfl]
lemma mul_inv_of_unit (φ : power_series R) (u : units R) (h : constant_coeff R φ = u) :
φ * inv_of_unit φ u = 1 :=
mv_power_series.mul_inv_of_unit φ u $ h
/-- Two ways of removing the constant coefficient of a power series are the same. -/
lemma sub_const_eq_shift_mul_X (φ : power_series R) :
φ - C R (constant_coeff R φ) = power_series.mk (λ p, coeff R (p + 1) φ) * X :=
sub_eq_iff_eq_add.mpr (eq_shift_mul_X_add_const φ)
lemma sub_const_eq_X_mul_shift (φ : power_series R) :
φ - C R (constant_coeff R φ) = X * power_series.mk (λ p, coeff R (p + 1) φ) :=
sub_eq_iff_eq_add.mpr (eq_X_mul_shift_add_const φ)
end ring
section comm_ring
variables {A : Type*} [comm_ring A]
@[simp] lemma rescale_neg_one_X : rescale (-1 : A) X = -X :=
begin
ext, simp only [linear_map.map_neg, coeff_rescale, coeff_X],
split_ifs with h; simp [h]
end
/-- The ring homomorphism taking a power series `f(X)` to `f(-X)`. -/
noncomputable def eval_neg_hom : power_series A →+* power_series A :=
rescale (-1 : A)
@[simp] lemma eval_neg_hom_X : eval_neg_hom (X : power_series A) = -X :=
rescale_neg_one_X
end comm_ring
section integral_domain
variable [integral_domain R]
lemma eq_zero_or_eq_zero_of_mul_eq_zero (φ ψ : power_series R) (h : φ * ψ = 0) :
φ = 0 ∨ ψ = 0 :=
begin
rw or_iff_not_imp_left, intro H,
have ex : ∃ m, coeff R m φ ≠ 0, { contrapose! H, exact ext H },
let m := nat.find ex,
have hm₁ : coeff R m φ ≠ 0 := nat.find_spec ex,
have hm₂ : ∀ k < m, ¬coeff R k φ ≠ 0 := λ k, nat.find_min ex,
ext n, rw (coeff R n).map_zero, apply nat.strong_induction_on n,
clear n, intros n ih,
replace h := congr_arg (coeff R (m + n)) h,
rw [linear_map.map_zero, coeff_mul, finset.sum_eq_single (m,n)] at h,
{ replace h := eq_zero_or_eq_zero_of_mul_eq_zero h,
rw or_iff_not_imp_left at h, exact h hm₁ },
{ rintro ⟨i,j⟩ hij hne,
by_cases hj : j < n, { rw [ih j hj, mul_zero] },
by_cases hi : i < m,
{ specialize hm₂ _ hi, push_neg at hm₂, rw [hm₂, zero_mul] },
rw finset.nat.mem_antidiagonal at hij,
push_neg at hi hj,
suffices : m < i,
{ have : m + n < i + j := add_lt_add_of_lt_of_le this hj,
exfalso, exact ne_of_lt this hij.symm },
contrapose! hne, have : i = m := le_antisymm hne hi, subst i, clear hi hne,
simpa [ne.def, prod.mk.inj_iff] using (add_right_inj m).mp hij },
{ contrapose!, intro h, rw finset.nat.mem_antidiagonal }
end
instance : integral_domain (power_series R) :=
{ eq_zero_or_eq_zero_of_mul_eq_zero := eq_zero_or_eq_zero_of_mul_eq_zero,
.. power_series.nontrivial,
.. power_series.comm_ring }
/-- The ideal spanned by the variable in the power series ring
over an integral domain is a prime ideal.-/
lemma span_X_is_prime : (ideal.span ({X} : set (power_series R))).is_prime :=
begin
suffices : ideal.span ({X} : set (power_series R)) = (constant_coeff R).ker,
{ rw this, exact ring_hom.ker_is_prime _ },
apply ideal.ext, intro φ,
rw [ring_hom.mem_ker, ideal.mem_span_singleton, X_dvd_iff]
end
/-- The variable of the power series ring over an integral domain is prime.-/
lemma X_prime : prime (X : power_series R) :=
begin
rw ← ideal.span_singleton_prime,
{ exact span_X_is_prime },
{ intro h, simpa using congr_arg (coeff R 1) h }
end
lemma rescale_injective {a : R} (ha : a ≠ 0) : function.injective (rescale a) :=
begin
intros p q h,
rw power_series.ext_iff at *,
intros n,
specialize h n,
rw [coeff_rescale, coeff_rescale, mul_eq_mul_left_iff] at h,
apply h.resolve_right,
intro h',
exact ha (pow_eq_zero h'),
end
end integral_domain
section local_ring
variables {S : Type*} [comm_ring R] [comm_ring S]
(f : R →+* S) [is_local_ring_hom f]
instance map.is_local_ring_hom : is_local_ring_hom (map f) :=
mv_power_series.map.is_local_ring_hom f
variables [local_ring R] [local_ring S]
instance : local_ring (power_series R) :=
mv_power_series.local_ring
end local_ring
section algebra
variables {A : Type*} [comm_semiring R] [semiring A] [algebra R A]
theorem C_eq_algebra_map {r : R} : C R r = (algebra_map R (power_series R)) r := rfl
theorem algebra_map_apply {r : R} :
algebra_map R (power_series A) r = C A (algebra_map R A r) :=
mv_power_series.algebra_map_apply
instance [nontrivial R] : nontrivial (subalgebra R (power_series R)) :=
mv_power_series.subalgebra.nontrivial
end algebra
section field
variables {k : Type*} [field k]
/-- The inverse 1/f of a power series f defined over a field -/
protected def inv : power_series k → power_series k :=
mv_power_series.inv
instance : has_inv (power_series k) := ⟨power_series.inv⟩
lemma inv_eq_inv_aux (φ : power_series k) :
φ⁻¹ = inv.aux (constant_coeff k φ)⁻¹ φ := rfl
lemma coeff_inv (n) (φ : power_series k) :
coeff k n (φ⁻¹) = if n = 0 then (constant_coeff k φ)⁻¹ else
- (constant_coeff k φ)⁻¹ * ∑ x in finset.nat.antidiagonal n,
if x.2 < n then coeff k x.1 φ * coeff k x.2 (φ⁻¹) else 0 :=
by rw [inv_eq_inv_aux, coeff_inv_aux n (constant_coeff k φ)⁻¹ φ]
@[simp] lemma constant_coeff_inv (φ : power_series k) :
constant_coeff k (φ⁻¹) = (constant_coeff k φ)⁻¹ :=
mv_power_series.constant_coeff_inv φ
lemma inv_eq_zero {φ : power_series k} :
φ⁻¹ = 0 ↔ constant_coeff k φ = 0 :=
mv_power_series.inv_eq_zero
@[simp, priority 1100] lemma inv_of_unit_eq (φ : power_series k) (h : constant_coeff k φ ≠ 0) :
inv_of_unit φ (units.mk0 _ h) = φ⁻¹ :=
mv_power_series.inv_of_unit_eq _ _
@[simp] lemma inv_of_unit_eq' (φ : power_series k) (u : units k) (h : constant_coeff k φ = u) :
inv_of_unit φ u = φ⁻¹ :=
mv_power_series.inv_of_unit_eq' φ _ h
@[simp] protected lemma mul_inv (φ : power_series k) (h : constant_coeff k φ ≠ 0) :
φ * φ⁻¹ = 1 :=
mv_power_series.mul_inv φ h
@[simp] protected lemma inv_mul (φ : power_series k) (h : constant_coeff k φ ≠ 0) :
φ⁻¹ * φ = 1 :=
mv_power_series.inv_mul φ h
lemma eq_mul_inv_iff_mul_eq {φ₁ φ₂ φ₃ : power_series k} (h : constant_coeff k φ₃ ≠ 0) :
φ₁ = φ₂ * φ₃⁻¹ ↔ φ₁ * φ₃ = φ₂ :=
mv_power_series.eq_mul_inv_iff_mul_eq h
lemma eq_inv_iff_mul_eq_one {φ ψ : power_series k} (h : constant_coeff k ψ ≠ 0) :
φ = ψ⁻¹ ↔ φ * ψ = 1 :=
mv_power_series.eq_inv_iff_mul_eq_one h
lemma inv_eq_iff_mul_eq_one {φ ψ : power_series k} (h : constant_coeff k ψ ≠ 0) :
ψ⁻¹ = φ ↔ φ * ψ = 1 :=
mv_power_series.inv_eq_iff_mul_eq_one h
end field
end power_series
namespace power_series
variable {R : Type*}
local attribute [instance, priority 1] classical.prop_decidable
noncomputable theory
section order_basic
open multiplicity
variables [comm_semiring R]
/-- The order of a formal power series `φ` is the greatest `n : enat`
such that `X^n` divides `φ`. The order is `⊤` if and only if `φ = 0`. -/
@[reducible] def order (φ : power_series R) : enat :=
multiplicity X φ
lemma order_finite_of_coeff_ne_zero (φ : power_series R) (h : ∃ n, coeff R n φ ≠ 0) :
(order φ).dom :=
begin
cases h with n h, refine ⟨n, _⟩, dsimp only,
rw X_pow_dvd_iff, push_neg, exact ⟨n, lt_add_one n, h⟩
end
/-- If the order of a formal power series is finite,
then the coefficient indexed by the order is nonzero.-/
lemma coeff_order (φ : power_series R) (h : (order φ).dom) :
coeff R (φ.order.get h) φ ≠ 0 :=
begin
have H := nat.find_spec h, contrapose! H, rw X_pow_dvd_iff,
intros m hm, by_cases Hm : m < nat.find h,
{ have := nat.find_min h Hm, push_neg at this,
rw X_pow_dvd_iff at this, exact this m (lt_add_one m) },
have : m = nat.find h, {linarith}, {rwa this}
end
/-- If the `n`th coefficient of a formal power series is nonzero,
then the order of the power series is less than or equal to `n`.-/
lemma order_le (φ : power_series R) (n : ℕ) (h : coeff R n φ ≠ 0) :
order φ ≤ n :=
begin
have h : ¬ X^(n+1) ∣ φ,
{ rw X_pow_dvd_iff, push_neg, exact ⟨n, lt_add_one n, h⟩ },
have : (order φ).dom := ⟨n, h⟩,
rw [← enat.coe_get this, enat.coe_le_coe],
refine nat.find_min' this h
end
/-- The `n`th coefficient of a formal power series is `0` if `n` is strictly
smaller than the order of the power series.-/
lemma coeff_of_lt_order (φ : power_series R) (n : ℕ) (h: ↑n < order φ) :
coeff R n φ = 0 :=
by { contrapose! h, exact order_le _ _ h }
/-- The order of the `0` power series is infinite.-/
@[simp] lemma order_zero : order (0 : power_series R) = ⊤ :=
multiplicity.zero _
/-- The `0` power series is the unique power series with infinite order.-/
@[simp] lemma order_eq_top {φ : power_series R} :
φ.order = ⊤ ↔ φ = 0 :=
begin
split,
{ intro h, ext n, rw [(coeff R n).map_zero, coeff_of_lt_order], simp [h] },
{ rintros rfl, exact order_zero }
end
/-- The order of a formal power series is at least `n` if
the `i`th coefficient is `0` for all `i < n`.-/
lemma nat_le_order (φ : power_series R) (n : ℕ) (h : ∀ i < n, coeff R i φ = 0) :
↑n ≤ order φ :=
begin
by_contra H, rw not_le at H,
have : (order φ).dom := enat.dom_of_le_some (le_of_lt H),
rw [← enat.coe_get this, enat.coe_lt_coe] at H,
exact coeff_order _ this (h _ H)
end
/-- The order of a formal power series is at least `n` if
the `i`th coefficient is `0` for all `i < n`.-/
lemma le_order (φ : power_series R) (n : enat) (h : ∀ i : ℕ, ↑i < n → coeff R i φ = 0) :
n ≤ order φ :=
begin
induction n using enat.cases_on,
{ show _ ≤ _, rw [top_le_iff, order_eq_top],
ext i, exact h _ (enat.coe_lt_top i) },
{ apply nat_le_order, simpa only [enat.coe_lt_coe] using h }
end
/-- The order of a formal power series is exactly `n` if the `n`th coefficient is nonzero,
and the `i`th coefficient is `0` for all `i < n`.-/
lemma order_eq_nat {φ : power_series R} {n : ℕ} :
order φ = n ↔ (coeff R n φ ≠ 0) ∧ (∀ i, i < n → coeff R i φ = 0) :=
begin
simp only [eq_some_iff, X_pow_dvd_iff], push_neg,
split,
{ rintros ⟨h₁, m, hm₁, hm₂⟩, refine ⟨_, h₁⟩,
suffices : n = m, { rwa this },
suffices : m ≥ n, { linarith },
contrapose! hm₂, exact h₁ _ hm₂ },
{ rintros ⟨h₁, h₂⟩, exact ⟨h₂, n, lt_add_one n, h₁⟩ }
end
/-- The order of a formal power series is exactly `n` if the `n`th coefficient is nonzero,
and the `i`th coefficient is `0` for all `i < n`.-/
lemma order_eq {φ : power_series R} {n : enat} :
order φ = n ↔ (∀ i:ℕ, ↑i = n → coeff R i φ ≠ 0) ∧ (∀ i:ℕ, ↑i < n → coeff R i φ = 0) :=
begin
induction n using enat.cases_on,
{ rw order_eq_top, split,
{ rintro rfl, split; intros,
{ exfalso, exact enat.coe_ne_top ‹_› ‹_› },
{ exact (coeff _ _).map_zero } },
{ rintro ⟨h₁, h₂⟩, ext i, exact h₂ i (enat.coe_lt_top i) } },
{ simpa [enat.coe_inj] using order_eq_nat }
end
/-- The order of the sum of two formal power series
is at least the minimum of their orders.-/
lemma le_order_add (φ ψ : power_series R) :
min (order φ) (order ψ) ≤ order (φ + ψ) :=
multiplicity.min_le_multiplicity_add
private lemma order_add_of_order_eq.aux (φ ψ : power_series R)
(h : order φ ≠ order ψ) (H : order φ < order ψ) :
order (φ + ψ) ≤ order φ ⊓ order ψ :=
begin
suffices : order (φ + ψ) = order φ,
{ rw [le_inf_iff, this], exact ⟨le_refl _, le_of_lt H⟩ },
{ rw order_eq, split,
{ intros i hi, rw [(coeff _ _).map_add, coeff_of_lt_order ψ i (hi.symm ▸ H), add_zero],
exact (order_eq_nat.1 hi.symm).1 },
{ intros i hi,
rw [(coeff _ _).map_add, coeff_of_lt_order φ i hi,
coeff_of_lt_order ψ i (lt_trans hi H), zero_add] } }
end
/-- The order of the sum of two formal power series
is the minimum of their orders if their orders differ.-/
lemma order_add_of_order_eq (φ ψ : power_series R) (h : order φ ≠ order ψ) :
order (φ + ψ) = order φ ⊓ order ψ :=
begin
refine le_antisymm _ (le_order_add _ _),
by_cases H₁ : order φ < order ψ,
{ apply order_add_of_order_eq.aux _ _ h H₁ },
by_cases H₂ : order ψ < order φ,
{ simpa only [add_comm, inf_comm] using order_add_of_order_eq.aux _ _ h.symm H₂ },
exfalso, exact h (le_antisymm (not_lt.1 H₂) (not_lt.1 H₁))
end
/-- The order of the product of two formal power series
is at least the sum of their orders.-/
lemma order_mul_ge (φ ψ : power_series R) :
order φ + order ψ ≤ order (φ * ψ) :=
begin
apply le_order,
intros n hn, rw [coeff_mul, finset.sum_eq_zero],
rintros ⟨i,j⟩ hij,
by_cases hi : ↑i < order φ,
{ rw [coeff_of_lt_order φ i hi, zero_mul] },
by_cases hj : ↑j < order ψ,
{ rw [coeff_of_lt_order ψ j hj, mul_zero] },
rw not_lt at hi hj, rw finset.nat.mem_antidiagonal at hij,
exfalso,
apply ne_of_lt (lt_of_lt_of_le hn $ add_le_add hi hj),
rw [← enat.coe_add, hij]
end
/-- The order of the monomial `a*X^n` is infinite if `a = 0` and `n` otherwise.-/
lemma order_monomial (n : ℕ) (a : R) [decidable (a = 0)] :
order (monomial R n a) = if a = 0 then ⊤ else n :=
begin
split_ifs with h,
{ rw [h, order_eq_top, linear_map.map_zero] },
{ rw [order_eq], split; intros i hi,
{ rw [enat.coe_inj] at hi, rwa [hi, coeff_monomial_same] },
{ rw [enat.coe_lt_coe] at hi, rw [coeff_monomial, if_neg], exact ne_of_lt hi } }
end
/-- The order of the monomial `a*X^n` is `n` if `a ≠ 0`.-/
lemma order_monomial_of_ne_zero (n : ℕ) (a : R) (h : a ≠ 0) :
order (monomial R n a) = n :=
by rw [order_monomial, if_neg h]
/-- If `n` is strictly smaller than the order of `ψ`, then the `n`th coefficient of its product
with any other power series is `0`. -/
lemma coeff_mul_of_lt_order {φ ψ : power_series R} {n : ℕ} (h : ↑n < ψ.order) :
coeff R n (φ * ψ) = 0 :=
begin
suffices : coeff R n (φ * ψ) = ∑ p in finset.nat.antidiagonal n, 0,
rw [this, finset.sum_const_zero],
rw [coeff_mul],
apply finset.sum_congr rfl (λ x hx, _),
refine mul_eq_zero_of_right (coeff R x.fst φ) (ψ.coeff_of_lt_order x.snd (lt_of_le_of_lt _ h)),
rw finset.nat.mem_antidiagonal at hx,
norm_cast,
linarith,
end
lemma coeff_mul_one_sub_of_lt_order {R : Type*} [comm_ring R] {φ ψ : power_series R}
(n : ℕ) (h : ↑n < ψ.order) :
coeff R n (φ * (1 - ψ)) = coeff R n φ :=
by simp [coeff_mul_of_lt_order h, mul_sub]
lemma coeff_mul_prod_one_sub_of_lt_order {R ι : Type*} [comm_ring R] (k : ℕ) (s : finset ι)
(φ : power_series R) (f : ι → power_series R) :
(∀ i ∈ s, ↑k < (f i).order) → coeff R k (φ * ∏ i in s, (1 - f i)) = coeff R k φ :=
begin
apply finset.induction_on s,
{ simp },
{ intros a s ha ih t,
simp only [finset.mem_insert, forall_eq_or_imp] at t,
rw [finset.prod_insert ha, ← mul_assoc, mul_right_comm, coeff_mul_one_sub_of_lt_order _ t.1],
exact ih t.2 },
end
end order_basic
section order_zero_ne_one
variables [comm_semiring R] [nontrivial R]
/-- The order of the formal power series `1` is `0`.-/
@[simp] lemma order_one : order (1 : power_series R) = 0 :=
by simpa using order_monomial_of_ne_zero 0 (1:R) one_ne_zero
/-- The order of the formal power series `X` is `1`.-/
@[simp] lemma order_X : order (X : power_series R) = 1 :=
order_monomial_of_ne_zero 1 (1:R) one_ne_zero
/-- The order of the formal power series `X^n` is `n`.-/
@[simp] lemma order_X_pow (n : ℕ) : order ((X : power_series R)^n) = n :=
by { rw [X_pow_eq, order_monomial_of_ne_zero], exact one_ne_zero }
end order_zero_ne_one
section order_integral_domain
variables [integral_domain R]
/-- The order of the product of two formal power series over an integral domain
is the sum of their orders.-/
lemma order_mul (φ ψ : power_series R) :
order (φ * ψ) = order φ + order ψ :=
multiplicity.mul (X_prime)
end order_integral_domain
end power_series
namespace polynomial
open finsupp
variables {σ : Type*} {R : Type*} [comm_semiring R]
/-- The natural inclusion from polynomials into formal power series.-/
instance coe_to_power_series : has_coe (polynomial R) (power_series R) :=
⟨λ φ, power_series.mk $ λ n, coeff φ n⟩
@[simp, norm_cast] lemma coeff_coe (φ : polynomial R) (n) :
power_series.coeff R n φ = coeff φ n :=
congr_arg (coeff φ) (finsupp.single_eq_same)
@[simp, norm_cast] lemma coe_monomial (n : ℕ) (a : R) :
(monomial n a : power_series R) = power_series.monomial R n a :=
by { ext, simp [coeff_coe, power_series.coeff_monomial, polynomial.coeff_monomial, eq_comm] }
@[simp, norm_cast] lemma coe_zero : ((0 : polynomial R) : power_series R) = 0 := rfl
@[simp, norm_cast] lemma coe_one : ((1 : polynomial R) : power_series R) = 1 :=
begin
have := coe_monomial 0 (1:R),
rwa power_series.monomial_zero_eq_C_apply at this,
end
@[simp, norm_cast] lemma coe_add (φ ψ : polynomial R) :
((φ + ψ : polynomial R) : power_series R) = φ + ψ :=
by { ext, simp }
@[simp, norm_cast] lemma coe_mul (φ ψ : polynomial R) :
((φ * ψ : polynomial R) : power_series R) = φ * ψ :=
power_series.ext $ λ n,
by simp only [coeff_coe, power_series.coeff_mul, coeff_mul]
@[simp, norm_cast] lemma coe_C (a : R) :
((C a : polynomial R) : power_series R) = power_series.C R a :=
begin
have := coe_monomial 0 a,
rwa power_series.monomial_zero_eq_C_apply at this,
end
@[simp, norm_cast] lemma coe_X :
((X : polynomial R) : power_series R) = power_series.X :=
coe_monomial _ _
/--
The coercion from polynomials to power series
as a ring homomorphism.
-/
-- TODO as an algebra homomorphism?
def coe_to_power_series.ring_hom : polynomial R →+* power_series R :=
{ to_fun := (coe : polynomial R → power_series R),
map_zero' := coe_zero,
map_one' := coe_one,
map_add' := coe_add,
map_mul' := coe_mul }
end polynomial
|
94d36d894d852bbbe37810b2364890a6119cde2a | 1e3a43e8ba59c6fe1c66775b6e833e721eaf1675 | /src/analysis/normed_space/operator_norm.lean | 8f17ff2c074d12a81fe01998e4fad4af043fa98a | [
"Apache-2.0"
] | permissive | Sterrs/mathlib | ea6910847b8dfd18500486de9ab0ee35704a3f52 | d9327e433804004aa1dc65091bbe0de1e5a08c5e | refs/heads/master | 1,650,769,884,257 | 1,587,808,694,000 | 1,587,808,694,000 | null | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 27,869 | lean | /-
Copyright (c) 2019 Jan-David Salchow. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jan-David Salchow, Sébastien Gouëzel, Jean Lo
Operator norm on the space of continuous linear maps
Define the operator norm on the space of continuous linear maps between normed spaces, and prove
its basic properties. In particular, show that this space is itself a normed space.
-/
import analysis.normed_space.riesz_lemma
import analysis.asymptotics
noncomputable theory
open_locale classical
set_option class.instance_max_depth 70
variables {𝕜 : Type*} {E : Type*} {F : Type*} {G : Type*}
[normed_group E] [normed_group F] [normed_group G]
open metric continuous_linear_map
lemma exists_pos_bound_of_bound {f : E → F} (M : ℝ) (h : ∀x, ∥f x∥ ≤ M * ∥x∥) :
∃ N, 0 < N ∧ ∀x, ∥f x∥ ≤ N * ∥x∥ :=
⟨max M 1, lt_of_lt_of_le zero_lt_one (le_max_right _ _), λx, calc
∥f x∥ ≤ M * ∥x∥ : h x
... ≤ max M 1 * ∥x∥ : mul_le_mul_of_nonneg_right (le_max_left _ _) (norm_nonneg _) ⟩
section normed_field
/- Most statements in this file require the field to be non-discrete, as this is necessary
to deduce an inequality `∥f x∥ ≤ C ∥x∥` from the continuity of f. However, the other direction always
holds. In this section, we just assume that `𝕜` is a normed field. In the remainder of the file,
it will be non-discrete. -/
variables [normed_field 𝕜] [normed_space 𝕜 E] [normed_space 𝕜 F] (f : E →ₗ[𝕜] F)
lemma linear_map.lipschitz_of_bound (C : ℝ) (h : ∀x, ∥f x∥ ≤ C * ∥x∥) :
lipschitz_with (nnreal.of_real C) f :=
lipschitz_with.of_dist_le' $ λ x y, by simpa only [dist_eq_norm, f.map_sub] using h (x - y)
theorem linear_map.antilipschitz_of_bound {K : nnreal} (h : ∀ x, ∥x∥ ≤ K * ∥f x∥) :
antilipschitz_with K f :=
antilipschitz_with.of_le_mul_dist $
λ x y, by simpa only [dist_eq_norm, f.map_sub] using h (x - y)
lemma linear_map.uniform_continuous_of_bound (C : ℝ) (h : ∀x, ∥f x∥ ≤ C * ∥x∥) :
uniform_continuous f :=
(f.lipschitz_of_bound C h).uniform_continuous
lemma linear_map.continuous_of_bound (C : ℝ) (h : ∀x, ∥f x∥ ≤ C * ∥x∥) :
continuous f :=
(f.lipschitz_of_bound C h).continuous
/-- Construct a continuous linear map from a linear map and a bound on this linear map.
The fact that the norm of the continuous linear map is then controlled is given in
`linear_map.mk_continuous_norm_le`. -/
def linear_map.mk_continuous (C : ℝ) (h : ∀x, ∥f x∥ ≤ C * ∥x∥) : E →L[𝕜] F :=
⟨f, linear_map.continuous_of_bound f C h⟩
/-- Construct a continuous linear map from a linear map and the existence of a bound on this linear
map. If you have an explicit bound, use `linear_map.mk_continuous` instead, as a norm estimate will
follow automatically in `linear_map.mk_continuous_norm_le`. -/
def linear_map.mk_continuous_of_exists_bound (h : ∃C, ∀x, ∥f x∥ ≤ C * ∥x∥) : E →L[𝕜] F :=
⟨f, let ⟨C, hC⟩ := h in linear_map.continuous_of_bound f C hC⟩
@[simp, norm_cast] lemma linear_map.mk_continuous_coe (C : ℝ) (h : ∀x, ∥f x∥ ≤ C * ∥x∥) :
((f.mk_continuous C h) : E →ₗ[𝕜] F) = f := rfl
@[simp] lemma linear_map.mk_continuous_apply (C : ℝ) (h : ∀x, ∥f x∥ ≤ C * ∥x∥) (x : E) :
f.mk_continuous C h x = f x := rfl
@[simp, norm_cast] lemma linear_map.mk_continuous_of_exists_bound_coe (h : ∃C, ∀x, ∥f x∥ ≤ C * ∥x∥) :
((f.mk_continuous_of_exists_bound h) : E →ₗ[𝕜] F) = f := rfl
@[simp] lemma linear_map.mk_continuous_of_exists_bound_apply (h : ∃C, ∀x, ∥f x∥ ≤ C * ∥x∥) (x : E) :
f.mk_continuous_of_exists_bound h x = f x := rfl
lemma linear_map.continuous_iff_is_closed_ker {f : E →ₗ[𝕜] 𝕜} :
continuous f ↔ is_closed (f.ker : set E) :=
begin
-- the continuity of f obviously implies that its kernel is closed
refine ⟨λh, (continuous_iff_is_closed.1 h) {0} (t1_space.t1 0), λh, _⟩,
-- for the other direction, we assume that the kernel is closed
by_cases hf : ∀x, x ∈ f.ker,
{ -- if `f = 0`, its continuity is obvious
have : (f : E → 𝕜) = (λx, 0), by { ext x, simpa using hf x },
rw this,
exact continuous_const },
{ /- if `f` is not zero, we use an element `x₀ ∉ ker f` such that `∥x₀∥ ≤ 2 ∥x₀ - y∥` for all
`y ∈ ker f`, given by Riesz's lemma, and prove that `2 ∥f x₀∥ / ∥x₀∥` gives a bound on the
operator norm of `f`. For this, start from an arbitrary `x` and note that
`y = x₀ - (f x₀ / f x) x` belongs to the kernel of `f`. Applying the above inequality to `x₀`
and `y` readily gives the conclusion. -/
push_neg at hf,
let r : ℝ := (2 : ℝ)⁻¹,
have : 0 ≤ r, by norm_num [r],
have : r < 1, by norm_num [r],
obtain ⟨x₀, x₀ker, h₀⟩ : ∃ (x₀ : E), x₀ ∉ f.ker ∧ ∀ y ∈ linear_map.ker f, r * ∥x₀∥ ≤ ∥x₀ - y∥,
from riesz_lemma h hf this,
have : x₀ ≠ 0,
{ assume h,
have : x₀ ∈ f.ker, by { rw h, exact (linear_map.ker f).zero },
exact x₀ker this },
have rx₀_ne_zero : r * ∥x₀∥ ≠ 0, by { simp [norm_eq_zero, this], norm_num },
have : ∀x, ∥f x∥ ≤ (((r * ∥x₀∥)⁻¹) * ∥f x₀∥) * ∥x∥,
{ assume x,
by_cases hx : f x = 0,
{ rw [hx, norm_zero],
apply_rules [mul_nonneg', norm_nonneg, inv_nonneg.2, norm_nonneg] },
{ let y := x₀ - (f x₀ * (f x)⁻¹ ) • x,
have fy_zero : f y = 0, by calc
f y = f x₀ - (f x₀ * (f x)⁻¹ ) * f x : by simp [y]
... = 0 :
by { rw [mul_assoc, inv_mul_cancel hx, mul_one, sub_eq_zero_of_eq], refl },
have A : r * ∥x₀∥ ≤ ∥f x₀∥ * ∥f x∥⁻¹ * ∥x∥, from calc
r * ∥x₀∥ ≤ ∥x₀ - y∥ : h₀ _ (linear_map.mem_ker.2 fy_zero)
... = ∥(f x₀ * (f x)⁻¹ ) • x∥ : by { dsimp [y], congr, abel }
... = ∥f x₀∥ * ∥f x∥⁻¹ * ∥x∥ :
by rw [norm_smul, normed_field.norm_mul, normed_field.norm_inv],
calc
∥f x∥ = (r * ∥x₀∥)⁻¹ * (r * ∥x₀∥) * ∥f x∥ : by rwa [inv_mul_cancel, one_mul]
... ≤ (r * ∥x₀∥)⁻¹ * (∥f x₀∥ * ∥f x∥⁻¹ * ∥x∥) * ∥f x∥ : begin
apply mul_le_mul_of_nonneg_right (mul_le_mul_of_nonneg_left A _) (norm_nonneg _),
exact inv_nonneg.2 (mul_nonneg' (by norm_num) (norm_nonneg _))
end
... = (∥f x∥ ⁻¹ * ∥f x∥) * (((r * ∥x₀∥)⁻¹) * ∥f x₀∥) * ∥x∥ : by ring
... = (((r * ∥x₀∥)⁻¹) * ∥f x₀∥) * ∥x∥ :
by { rw [inv_mul_cancel, one_mul], simp [norm_eq_zero, hx] } } },
exact linear_map.continuous_of_bound f _ this }
end
end normed_field
variables [nondiscrete_normed_field 𝕜] [normed_space 𝕜 E] [normed_space 𝕜 F] [normed_space 𝕜 G]
(c : 𝕜) (f g : E →L[𝕜] F) (h : F →L[𝕜] G) (x y z : E)
include 𝕜
/-- A continuous linear map between normed spaces is bounded when the field is nondiscrete.
The continuity ensures boundedness on a ball of some radius `δ`. The nondiscreteness is then
used to rescale any element into an element of norm in `[δ/C, δ]`, whose image has a controlled norm.
The norm control for the original element follows by rescaling. -/
lemma linear_map.bound_of_continuous (f : E →ₗ[𝕜] F) (hf : continuous f) :
∃ C, 0 < C ∧ (∀ x : E, ∥f x∥ ≤ C * ∥x∥) :=
begin
have : continuous_at f 0 := continuous_iff_continuous_at.1 hf _,
rcases metric.tendsto_nhds_nhds.1 this 1 zero_lt_one with ⟨ε, ε_pos, hε⟩,
let δ := ε/2,
have δ_pos : δ > 0 := half_pos ε_pos,
have H : ∀{a}, ∥a∥ ≤ δ → ∥f a∥ ≤ 1,
{ assume a ha,
have : dist (f a) (f 0) ≤ 1,
{ apply le_of_lt (hε _),
rw [dist_eq_norm, sub_zero],
exact lt_of_le_of_lt ha (half_lt_self ε_pos) },
simpa using this },
rcases normed_field.exists_one_lt_norm 𝕜 with ⟨c, hc⟩,
refine ⟨δ⁻¹ * ∥c∥, mul_pos (inv_pos.2 δ_pos) (lt_trans zero_lt_one hc), (λx, _)⟩,
by_cases h : x = 0,
{ simp only [h, norm_zero, mul_zero, linear_map.map_zero] },
{ rcases rescale_to_shell hc δ_pos h with ⟨d, hd, dxle, ledx, dinv⟩,
calc ∥f x∥
= ∥f ((d⁻¹ * d) • x)∥ : by rwa [inv_mul_cancel, one_smul]
... = ∥d∥⁻¹ * ∥f (d • x)∥ :
by rw [mul_smul, linear_map.map_smul, norm_smul, normed_field.norm_inv]
... ≤ ∥d∥⁻¹ * 1 :
mul_le_mul_of_nonneg_left (H dxle) (by { rw ← normed_field.norm_inv, exact norm_nonneg _ })
... ≤ δ⁻¹ * ∥c∥ * ∥x∥ : by { rw mul_one, exact dinv } }
end
namespace continuous_linear_map
theorem bound : ∃ C, 0 < C ∧ (∀ x : E, ∥f x∥ ≤ C * ∥x∥) :=
f.to_linear_map.bound_of_continuous f.2
section
open asymptotics filter
theorem is_O_id (l : filter E) : is_O f (λ x, x) l :=
let ⟨M, hMp, hM⟩ := f.bound in is_O_of_le' l hM
theorem is_O_comp {E : Type*} (g : F →L[𝕜] G) (f : E → F) (l : filter E) :
is_O (λ x', g (f x')) f l :=
(g.is_O_id ⊤).comp_tendsto le_top
theorem is_O_sub (f : E →L[𝕜] F) (l : filter E) (x : E) :
is_O (λ x', f (x' - x)) (λ x', x' - x) l :=
f.is_O_comp _ l
end
section op_norm
open set real
set_option class.instance_max_depth 100
/-- The operator norm of a continuous linear map is the inf of all its bounds. -/
def op_norm := Inf { c | c ≥ 0 ∧ ∀ x, ∥f x∥ ≤ c * ∥x∥ }
instance has_op_norm : has_norm (E →L[𝕜] F) := ⟨op_norm⟩
-- So that invocations of `real.Inf_le` make sense: we show that the set of
-- bounds is nonempty and bounded below.
lemma bounds_nonempty {f : E →L[𝕜] F} :
∃ c, c ∈ { c | 0 ≤ c ∧ ∀ x, ∥f x∥ ≤ c * ∥x∥ } :=
let ⟨M, hMp, hMb⟩ := f.bound in ⟨M, le_of_lt hMp, hMb⟩
lemma bounds_bdd_below {f : E →L[𝕜] F} :
bdd_below { c | 0 ≤ c ∧ ∀ x, ∥f x∥ ≤ c * ∥x∥ } :=
⟨0, λ _ ⟨hn, _⟩, hn⟩
lemma op_norm_nonneg : 0 ≤ ∥f∥ :=
lb_le_Inf _ bounds_nonempty (λ _ ⟨hx, _⟩, hx)
/-- The fundamental property of the operator norm: `∥f x∥ ≤ ∥f∥ * ∥x∥`. -/
theorem le_op_norm : ∥f x∥ ≤ ∥f∥ * ∥x∥ :=
classical.by_cases
(λ heq : x = 0, by { rw heq, simp })
(λ hne, have hlt : 0 < ∥x∥, from norm_pos_iff.2 hne,
le_mul_of_div_le hlt ((le_Inf _ bounds_nonempty bounds_bdd_below).2
(λ c ⟨_, hc⟩, div_le_of_le_mul hlt (by { rw mul_comm, apply hc }))))
theorem le_op_norm_of_le {c : ℝ} {x} (h : ∥x∥ ≤ c) : ∥f x∥ ≤ ∥f∥ * c :=
le_trans (f.le_op_norm x) (mul_le_mul_of_nonneg_left h f.op_norm_nonneg)
/-- continuous linear maps are Lipschitz continuous. -/
theorem lipschitz : lipschitz_with ⟨∥f∥, op_norm_nonneg f⟩ f :=
lipschitz_with.of_dist_le_mul $ λ x y,
by { rw [dist_eq_norm, dist_eq_norm, ←map_sub], apply le_op_norm }
lemma ratio_le_op_norm : ∥f x∥ / ∥x∥ ≤ ∥f∥ :=
(or.elim (lt_or_eq_of_le (norm_nonneg _))
(λ hlt, div_le_of_le_mul hlt (by { rw mul_comm, apply le_op_norm }))
(λ heq, by { rw [←heq, div_zero], apply op_norm_nonneg }))
/-- The image of the unit ball under a continuous linear map is bounded. -/
lemma unit_le_op_norm : ∥x∥ ≤ 1 → ∥f x∥ ≤ ∥f∥ :=
mul_one ∥f∥ ▸ f.le_op_norm_of_le
/-- If one controls the norm of every `A x`, then one controls the norm of `A`. -/
lemma op_norm_le_bound {M : ℝ} (hMp: 0 ≤ M) (hM : ∀ x, ∥f x∥ ≤ M * ∥x∥) :
∥f∥ ≤ M :=
Inf_le _ bounds_bdd_below ⟨hMp, hM⟩
theorem op_norm_le_of_lipschitz {f : E →L[𝕜] F} {K : nnreal} (hf : lipschitz_with K f) :
∥f∥ ≤ K :=
f.op_norm_le_bound K.2 $ λ x, by simpa only [dist_zero_right, f.map_zero] using hf.dist_le_mul x 0
/-- The operator norm satisfies the triangle inequality. -/
theorem op_norm_add_le : ∥f + g∥ ≤ ∥f∥ + ∥g∥ :=
show ∥f + g∥ ≤ (coe : nnreal → ℝ) (⟨_, f.op_norm_nonneg⟩ + ⟨_, g.op_norm_nonneg⟩),
from op_norm_le_of_lipschitz (f.lipschitz.add g.lipschitz)
/-- An operator is zero iff its norm vanishes. -/
theorem op_norm_zero_iff : ∥f∥ = 0 ↔ f = 0 :=
iff.intro
(λ hn, continuous_linear_map.ext (λ x, norm_le_zero_iff.1
(calc _ ≤ ∥f∥ * ∥x∥ : le_op_norm _ _
... = _ : by rw [hn, zero_mul])))
(λ hf, le_antisymm (Inf_le _ bounds_bdd_below
⟨ge_of_eq rfl, λ _, le_of_eq (by { rw [zero_mul, hf], exact norm_zero })⟩)
(op_norm_nonneg _))
@[simp] lemma norm_zero : ∥(0 : E →L[𝕜] F)∥ = 0 :=
by rw op_norm_zero_iff
/-- The norm of the identity is at most `1`. It is in fact `1`, except when the space is trivial
where it is `0`. It means that one can not do better than an inequality in general. -/
lemma norm_id_le : ∥id 𝕜 E∥ ≤ 1 :=
op_norm_le_bound _ zero_le_one (λx, by simp)
/-- If a space is non-trivial, then the norm of the identity equals `1`. -/
lemma norm_id (h : ∃ x : E, x ≠ 0) : ∥id 𝕜 E∥ = 1 :=
le_antisymm norm_id_le $ let ⟨x, hx⟩ := h in
have _ := (id 𝕜 E).ratio_le_op_norm x,
by rwa [id_apply, div_self (ne_of_gt $ norm_pos_iff.2 hx)] at this
/-- The operator norm is homogeneous. -/
lemma op_norm_smul : ∥c • f∥ = ∥c∥ * ∥f∥ :=
le_antisymm
((c • f).op_norm_le_bound
(mul_nonneg (norm_nonneg _) (op_norm_nonneg _)) (λ _,
begin
erw [norm_smul, mul_assoc],
exact mul_le_mul_of_nonneg_left (le_op_norm _ _) (norm_nonneg _)
end))
(lb_le_Inf _ bounds_nonempty (λ _ ⟨hn, hc⟩,
(or.elim (lt_or_eq_of_le (norm_nonneg c))
(λ hlt,
begin
rw mul_comm,
exact mul_le_of_le_div hlt (Inf_le _ bounds_bdd_below
⟨div_nonneg hn hlt, λ _,
(by { rw div_mul_eq_mul_div, exact le_div_of_mul_le hlt
(by { rw [ mul_comm, ←norm_smul ], exact hc _ }) })⟩)
end)
(λ heq, by { rw [←heq, zero_mul], exact hn }))))
lemma op_norm_neg : ∥-f∥ = ∥f∥ := calc
∥-f∥ = ∥(-1:𝕜) • f∥ : by rw neg_one_smul
... = ∥(-1:𝕜)∥ * ∥f∥ : by rw op_norm_smul
... = ∥f∥ : by simp
/-- Continuous linear maps themselves form a normed space with respect to
the operator norm. -/
instance to_normed_group : normed_group (E →L[𝕜] F) :=
normed_group.of_core _ ⟨op_norm_zero_iff, op_norm_add_le, op_norm_neg⟩
instance to_normed_space : normed_space 𝕜 (E →L[𝕜] F) :=
⟨op_norm_smul⟩
/-- The operator norm is submultiplicative. -/
lemma op_norm_comp_le (f : E →L[𝕜] F) : ∥h.comp f∥ ≤ ∥h∥ * ∥f∥ :=
(Inf_le _ bounds_bdd_below
⟨mul_nonneg (op_norm_nonneg _) (op_norm_nonneg _), λ x,
by { rw mul_assoc, exact h.le_op_norm_of_le (f.le_op_norm x) } ⟩)
/-- A continuous linear map is automatically uniformly continuous. -/
protected theorem uniform_continuous : uniform_continuous f :=
f.lipschitz.uniform_continuous
variable {f}
/-- A continuous linear map is an isometry if and only if it preserves the norm. -/
lemma isometry_iff_norm_image_eq_norm :
isometry f ↔ ∀x, ∥f x∥ = ∥x∥ :=
begin
rw isometry_emetric_iff_metric,
split,
{ assume H x,
have := H x 0,
rwa [dist_eq_norm, dist_eq_norm, f.map_zero, sub_zero, sub_zero] at this },
{ assume H x y,
rw [dist_eq_norm, dist_eq_norm, ← f.map_sub, H] }
end
variable (f)
theorem uniform_embedding_of_bound {K : nnreal} (hf : ∀ x, ∥x∥ ≤ K * ∥f x∥) :
uniform_embedding f :=
(f.to_linear_map.antilipschitz_of_bound hf).uniform_embedding f.uniform_continuous
/-- If a continuous linear map is a uniform embedding, then it is expands the distances
by a positive factor.-/
theorem antilipschitz_of_uniform_embedding (hf : uniform_embedding f) :
∃ K, antilipschitz_with K f :=
begin
obtain ⟨ε, εpos, hε⟩ : ∃ (ε : ℝ) (H : ε > 0), ∀ {x y : E}, dist (f x) (f y) < ε → dist x y < 1, from
(uniform_embedding_iff.1 hf).2.2 1 zero_lt_one,
let δ := ε/2,
have δ_pos : δ > 0 := half_pos εpos,
have H : ∀{x}, ∥f x∥ ≤ δ → ∥x∥ ≤ 1,
{ assume x hx,
have : dist x 0 ≤ 1,
{ apply le_of_lt,
apply hε,
simp [dist_eq_norm],
exact lt_of_le_of_lt hx (half_lt_self εpos) },
simpa using this },
rcases normed_field.exists_one_lt_norm 𝕜 with ⟨c, hc⟩,
refine ⟨⟨δ⁻¹, _⟩ * nnnorm c, f.to_linear_map.antilipschitz_of_bound $ λx, _⟩,
exact inv_nonneg.2 (le_of_lt δ_pos),
by_cases hx : f x = 0,
{ have : f x = f 0, by { simp [hx] },
have : x = 0 := (uniform_embedding_iff.1 hf).1 this,
simp [this] },
{ rcases rescale_to_shell hc δ_pos hx with ⟨d, hd, dxle, ledx, dinv⟩,
have : ∥f (d • x)∥ ≤ δ, by simpa,
have : ∥d • x∥ ≤ 1 := H this,
calc ∥x∥ = ∥d∥⁻¹ * ∥d • x∥ :
by rwa [← normed_field.norm_inv, ← norm_smul, ← mul_smul, inv_mul_cancel, one_smul]
... ≤ ∥d∥⁻¹ * 1 :
mul_le_mul_of_nonneg_left this (inv_nonneg.2 (norm_nonneg _))
... ≤ δ⁻¹ * ∥c∥ * ∥f x∥ :
by rwa [mul_one] }
end
section completeness
open_locale topological_space
open filter
/-- If the target space is complete, the space of continuous linear maps with its norm is also
complete. -/
instance [complete_space F] : complete_space (E →L[𝕜] F) :=
begin
-- We show that every Cauchy sequence converges.
refine metric.complete_of_cauchy_seq_tendsto (λ f hf, _),
-- We now expand out the definition of a Cauchy sequence,
rcases cauchy_seq_iff_le_tendsto_0.1 hf with ⟨b, b0, b_bound, b_lim⟩, clear hf,
-- and establish that the evaluation at any point `v : E` is Cauchy.
have cau : ∀ v, cauchy_seq (λ n, f n v),
{ assume v,
apply cauchy_seq_iff_le_tendsto_0.2 ⟨λ n, b n * ∥v∥, λ n, _, _, _⟩,
{ exact mul_nonneg (b0 n) (norm_nonneg _) },
{ assume n m N hn hm,
rw dist_eq_norm,
apply le_trans ((f n - f m).le_op_norm v) _,
exact mul_le_mul_of_nonneg_right (b_bound n m N hn hm) (norm_nonneg v) },
{ simpa using b_lim.mul tendsto_const_nhds } },
-- We assemble the limits points of those Cauchy sequences
-- (which exist as `F` is complete)
-- into a function which we call `G`.
choose G hG using λv, cauchy_seq_tendsto_of_complete (cau v),
-- Next, we show that this `G` is linear,
let Glin : E →ₗ[𝕜] F :=
{ to_fun := G,
add := λ v w, begin
have A := hG (v + w),
have B := (hG v).add (hG w),
simp only [map_add] at A B,
exact tendsto_nhds_unique filter.at_top_ne_bot A B,
end,
smul := λ c v, begin
have A := hG (c • v),
have B := filter.tendsto.smul (@tendsto_const_nhds _ ℕ _ c _) (hG v),
simp only [map_smul] at A B,
exact tendsto_nhds_unique filter.at_top_ne_bot A B
end },
-- and that `G` has norm at most `(b 0 + ∥f 0∥)`.
have Gnorm : ∀ v, ∥G v∥ ≤ (b 0 + ∥f 0∥) * ∥v∥,
{ assume v,
have A : ∀ n, ∥f n v∥ ≤ (b 0 + ∥f 0∥) * ∥v∥,
{ assume n,
apply le_trans ((f n).le_op_norm _) _,
apply mul_le_mul_of_nonneg_right _ (norm_nonneg v),
calc ∥f n∥ = ∥(f n - f 0) + f 0∥ : by { congr' 1, abel }
... ≤ ∥f n - f 0∥ + ∥f 0∥ : norm_add_le _ _
... ≤ b 0 + ∥f 0∥ : begin
apply add_le_add_right,
simpa [dist_eq_norm] using b_bound n 0 0 (zero_le _) (zero_le _)
end },
exact le_of_tendsto at_top_ne_bot (hG v).norm (eventually_of_forall _ A) },
-- Thus `G` is continuous, and we propose that as the limit point of our original Cauchy sequence.
let Gcont := Glin.mk_continuous _ Gnorm,
use Gcont,
-- Our last task is to establish convergence to `G` in norm.
have : ∀ n, ∥f n - Gcont∥ ≤ b n,
{ assume n,
apply op_norm_le_bound _ (b0 n) (λ v, _),
have A : ∀ᶠ m in at_top, ∥(f n - f m) v∥ ≤ b n * ∥v∥,
{ refine eventually_at_top.2 ⟨n, λ m hm, _⟩,
apply le_trans ((f n - f m).le_op_norm _) _,
exact mul_le_mul_of_nonneg_right (b_bound n m n (le_refl _) hm) (norm_nonneg v) },
have B : tendsto (λ m, ∥(f n - f m) v∥) at_top (𝓝 (∥(f n - Gcont) v∥)) :=
tendsto.norm (tendsto_const_nhds.sub (hG v)),
exact le_of_tendsto at_top_ne_bot B A },
erw tendsto_iff_norm_tendsto_zero,
exact squeeze_zero (λ n, norm_nonneg _) this b_lim,
end
end completeness
section uniformly_extend
variables [complete_space F] (e : E →L[𝕜] G) (h_dense : dense_range e)
section
variables (h_e : uniform_inducing e)
/-- Extension of a continuous linear map `f : E →L[𝕜] F`, with `E` a normed space and `F` a complete
normed space, along a uniform and dense embedding `e : E →L[𝕜] G`. -/
def extend : G →L[𝕜] F :=
/- extension of `f` is continuous -/
have cont : _ := (uniform_continuous_uniformly_extend h_e h_dense f.uniform_continuous).continuous,
/- extension of `f` agrees with `f` on the domain of the embedding `e` -/
have eq : _ := uniformly_extend_of_ind h_e h_dense f.uniform_continuous,
{ to_fun := (h_e.dense_inducing h_dense).extend f,
add :=
begin
refine is_closed_property2 h_dense (is_closed_eq _ _) _,
{ exact cont.comp (continuous_fst.add continuous_snd) },
{ exact (cont.comp continuous_fst).add (cont.comp continuous_snd) },
{ assume x y, rw ← e.map_add, simp only [eq], exact f.map_add _ _ },
end,
smul := λk,
begin
refine is_closed_property h_dense (is_closed_eq _ _) _,
{ exact cont.comp (continuous_const.smul continuous_id) },
{ exact (continuous_const.smul continuous_id).comp cont },
{ assume x, rw ← map_smul, simp only [eq], exact map_smul _ _ _ },
end,
cont := cont
}
@[simp] lemma extend_zero : extend (0 : E →L[𝕜] F) e h_dense h_e = 0 :=
begin
apply ext,
refine is_closed_property h_dense (is_closed_eq _ _) _,
{ exact (uniform_continuous_uniformly_extend h_e h_dense uniform_continuous_const).continuous },
{ simp only [zero_apply], exact continuous_const },
{ assume x, exact uniformly_extend_of_ind h_e h_dense uniform_continuous_const x }
end
end
section
variables {N : nnreal} (h_e : ∀x, ∥x∥ ≤ N * ∥e x∥)
local notation `ψ` := f.extend e h_dense (uniform_embedding_of_bound _ h_e).to_uniform_inducing
/-- If a dense embedding `e : E →L[𝕜] G` expands the norm by a constant factor `N⁻¹`, then the norm
of the extension of `f` along `e` is bounded by `N * ∥f∥`. -/
lemma op_norm_extend_le : ∥ψ∥ ≤ N * ∥f∥ :=
begin
have uni : uniform_inducing e := (uniform_embedding_of_bound _ h_e).to_uniform_inducing,
have eq : ∀x, ψ (e x) = f x := uniformly_extend_of_ind uni h_dense f.uniform_continuous,
by_cases N0 : 0 ≤ N,
{ refine op_norm_le_bound ψ _ (is_closed_property h_dense (is_closed_le _ _) _),
{ exact mul_nonneg N0 (norm_nonneg _) },
{ exact continuous_norm.comp (cont ψ) },
{ exact continuous_const.mul continuous_norm },
{ assume x,
rw eq,
calc ∥f x∥ ≤ ∥f∥ * ∥x∥ : le_op_norm _ _
... ≤ ∥f∥ * (N * ∥e x∥) : mul_le_mul_of_nonneg_left (h_e x) (norm_nonneg _)
... ≤ N * ∥f∥ * ∥e x∥ : by rw [mul_comm ↑N ∥f∥, mul_assoc] } },
{ have he : ∀ x : E, x = 0,
{ assume x,
have N0 : N ≤ 0 := le_of_lt (lt_of_not_ge N0),
rw ← norm_le_zero_iff,
exact le_trans (h_e x) (mul_nonpos_of_nonpos_of_nonneg N0 (norm_nonneg _)) },
have hf : f = 0, { ext, simp only [he x, zero_apply, map_zero] },
have hψ : ψ = 0, { rw hf, apply extend_zero },
rw [hψ, hf, norm_zero, norm_zero, mul_zero] }
end
end
end uniformly_extend
end op_norm
/-- The norm of the tensor product of a scalar linear map and of an element of a normed space
is the product of the norms. -/
@[simp] lemma smul_right_norm {c : E →L[𝕜] 𝕜} {f : F} :
∥smul_right c f∥ = ∥c∥ * ∥f∥ :=
begin
refine le_antisymm _ _,
{ apply op_norm_le_bound _ (mul_nonneg (norm_nonneg _) (norm_nonneg _)) (λx, _),
calc
∥(c x) • f∥ = ∥c x∥ * ∥f∥ : norm_smul _ _
... ≤ (∥c∥ * ∥x∥) * ∥f∥ :
mul_le_mul_of_nonneg_right (le_op_norm _ _) (norm_nonneg _)
... = ∥c∥ * ∥f∥ * ∥x∥ : by ring },
{ by_cases h : ∥f∥ = 0,
{ rw h, simp [norm_nonneg] },
{ have : 0 < ∥f∥ := lt_of_le_of_ne (norm_nonneg _) (ne.symm h),
rw ← le_div_iff this,
apply op_norm_le_bound _ (div_nonneg (norm_nonneg _) this) (λx, _),
rw [div_mul_eq_mul_div, le_div_iff this],
calc ∥c x∥ * ∥f∥ = ∥c x • f∥ : (norm_smul _ _).symm
... = ∥((smul_right c f) : E → F) x∥ : rfl
... ≤ ∥smul_right c f∥ * ∥x∥ : le_op_norm _ _ } },
end
section restrict_scalars
variable (𝕜)
variables {𝕜' : Type*} [normed_field 𝕜'] [normed_algebra 𝕜 𝕜']
{E' : Type*} [normed_group E'] [normed_space 𝕜' E']
{F' : Type*} [normed_group F'] [normed_space 𝕜' F']
local attribute [instance, priority 500] normed_space.restrict_scalars
/-- `𝕜`-linear continuous function induced by a `𝕜'`-linear continuous function when `𝕜'` is a
normed algebra over `𝕜`. -/
def restrict_scalars (f : E' →L[𝕜'] F') : E' →L[𝕜] F' :=
{ cont := f.cont,
..linear_map.restrict_scalars 𝕜 (f.to_linear_map) }
@[simp, norm_cast] lemma restrict_scalars_coe_eq_coe (f : E' →L[𝕜'] F') :
(f.restrict_scalars 𝕜 : E' →ₗ[𝕜] F') = (f : E' →ₗ[𝕜'] F').restrict_scalars 𝕜 := rfl
@[simp, norm_cast squash] lemma restrict_scalars_coe_eq_coe' (f : E' →L[𝕜'] F') :
(f.restrict_scalars 𝕜 : E' → F') = f := rfl
end restrict_scalars
end continuous_linear_map
namespace continuous_linear_equiv
variable (e : E ≃L[𝕜] F)
protected lemma lipschitz : lipschitz_with (nnnorm (e : E →L[𝕜] F)) e :=
(e : E →L[𝕜] F).lipschitz
protected lemma antilipschitz : antilipschitz_with (nnnorm (e.symm : F →L[𝕜] E)) e :=
e.symm.lipschitz.to_right_inverse e.left_inv
/-- A continuous linear equiv is a uniform embedding. -/
lemma uniform_embedding : uniform_embedding e :=
e.antilipschitz.uniform_embedding e.lipschitz.uniform_continuous
lemma one_le_norm_mul_norm_symm (h : ∃ x : E, x ≠ 0) :
1 ≤ ∥(e : E →L[𝕜] F)∥ * ∥(e.symm : F →L[𝕜] E)∥ :=
begin
rw [mul_comm],
convert (e.symm : F →L[𝕜] E).op_norm_comp_le (e : E →L[𝕜] F),
rw [e.coe_symm_comp_coe, continuous_linear_map.norm_id h]
end
lemma norm_pos (h : ∃ x : E, x ≠ 0) : 0 < ∥(e : E →L[𝕜] F)∥ :=
pos_of_mul_pos_right (lt_of_lt_of_le zero_lt_one (e.one_le_norm_mul_norm_symm h)) (norm_nonneg _)
lemma norm_symm_pos (h : ∃ x : E, x ≠ 0) : 0 < ∥(e.symm : F →L[𝕜] E)∥ :=
pos_of_mul_pos_left (lt_of_lt_of_le zero_lt_one (e.one_le_norm_mul_norm_symm h)) (norm_nonneg _)
lemma subsingleton_or_norm_symm_pos : subsingleton E ∨ 0 < ∥(e.symm : F →L[𝕜] E)∥ :=
(subsingleton_or_exists_ne (0 : E)).imp id (λ hE, e.norm_symm_pos hE)
lemma subsingleton_or_nnnorm_symm_pos : subsingleton E ∨ 0 < (nnnorm $ (e.symm : F →L[𝕜] E)) :=
subsingleton_or_norm_symm_pos e
end continuous_linear_equiv
lemma linear_equiv.uniform_embedding (e : E ≃ₗ[𝕜] F) (h₁ : continuous e) (h₂ : continuous e.symm) :
uniform_embedding e :=
continuous_linear_equiv.uniform_embedding
{ continuous_to_fun := h₁,
continuous_inv_fun := h₂,
.. e }
/-- If a continuous linear map is constructed from a linear map via the constructor `mk_continuous`,
then its norm is bounded by the bound given to the constructor if it is nonnegative. -/
lemma linear_map.mk_continuous_norm_le (f : E →ₗ[𝕜] F) {C : ℝ} (hC : 0 ≤ C) (h : ∀x, ∥f x∥ ≤ C * ∥x∥) :
∥f.mk_continuous C h∥ ≤ C :=
continuous_linear_map.op_norm_le_bound _ hC h
|
07e6dfb231f8d75614d7870cddf0e5a3f29045b9 | 2fbe653e4bc441efde5e5d250566e65538709888 | /src/tactic/lint.lean | 9f9d2e05b06ed57b2687d9c45960d48f30e9f50f | [
"Apache-2.0"
] | permissive | aceg00/mathlib | 5e15e79a8af87ff7eb8c17e2629c442ef24e746b | 8786ea6d6d46d6969ac9a869eb818bf100802882 | refs/heads/master | 1,649,202,698,930 | 1,580,924,783,000 | 1,580,924,783,000 | 149,197,272 | 0 | 0 | Apache-2.0 | 1,537,224,208,000 | 1,537,224,207,000 | null | UTF-8 | Lean | false | false | 31,850 | lean | /-
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, Robert Y. Lewis
-/
import tactic.core
/-!
# lint command
This file defines the following user commands to spot common mistakes in the code.
* `#lint`: check all declarations in the current file
* `#lint_mathlib`: check all declarations in mathlib (so excluding core or other projects,
and also excluding the current file)
* `#lint_all`: check all declarations in the environment (the current file and all
imported files)
The following linters are run by default:
1. `unused_arguments` checks for unused arguments in declarations.
2. `def_lemma` checks whether a declaration is incorrectly marked as a def/lemma.
3. `dup_namespce` checks whether a namespace is duplicated in the name of a declaration.
4. `ge_or_gt` checks whether ≥/> is used in the declaration.
5. `instance_priority` checks that instances that always apply have priority below default.
6. `doc_blame` checks for missing doc strings on definitions and constants.
7. `has_inhabited_instance` checks whether every type has an associated `inhabited` instance.
8. `impossible_instance` checks for instances that can never fire.
9. `incorrect_type_class_argument` checks for arguments in [square brackets] that are not classes.
10. `dangerous_instance` checks for instances that generate type-class problems with metavariables.
Another linter, `doc_blame_thm`, checks for missing doc strings on lemmas and theorems.
This is not run by default.
The command `#list_linters` prints a list of the names of all available linters.
You can append a `*` to any command (e.g. `#lint_mathlib*`) to omit the slow tests (4).
You can append a `-` to any command (e.g. `#lint_mathlib-`) to run a silent lint
that suppresses the output of passing checks.
A silent lint will fail if any test fails.
You can append a sequence of linter names to any command to run extra tests, in addition to the
default ones. e.g. `#lint doc_blame_thm` will run all default tests and `doc_blame_thm`.
You can append `only name1 name2 ...` to any command to run a subset of linters, e.g.
`#lint only unused_arguments`
You can add custom linters by defining a term of type `linter` in the `linter` namespace.
A linter defined with the name `linter.my_new_check` can be run with `#lint my_new_check`
or `lint only my_new_check`.
If you add the attribute `@[linter]` to `linter.my_new_check` it will run by default.
Adding the attribute `@[nolint]` to a declaration omits it from all linter checks.
## Tags
sanity check, lint, cleanup, command, tactic
-/
universe variable u
open expr tactic native
reserve notation `#lint`
reserve notation `#lint_mathlib`
reserve notation `#lint_all`
reserve notation `#list_linters`
run_cmd tactic.skip -- apparently doc strings can't come directly after `reserve notation`
/-- Defines the user attribute `nolint` for skipping `#lint` -/
@[user_attribute]
meta def nolint_attr : user_attribute :=
{ name := "nolint",
descr := "Do not report this declaration in any of the tests of `#lint`" }
attribute [nolint] imp_intro
classical.dec classical.dec_pred classical.dec_rel classical.dec_eq
pempty -- has no inhabited instance
/--
A linting test for the `#lint` command.
`test` defines a test to perform on every declaration. It should never fail. Returning `none`
signifies a passing test. Returning `some msg` reports a failing test with error `msg`.
`no_errors_found` is the message printed when all tests are negative, and `errors_found` is printed
when at least one test is positive.
If `is_fast` is false, this test will be omitted from `#lint-`.
-/
meta structure linter :=
(test : declaration → tactic (option string))
(no_errors_found : string)
(errors_found : string)
(is_fast : bool := tt)
/-- Takes a list of names that resolve to declarations of type `linter`,
and produces a list of linters. -/
meta def get_linters (l : list name) : tactic (list linter) :=
l.mmap (λ n, mk_const n >>= eval_expr linter <|> fail format!"invalid linter: {n}")
/-- Defines the user attribute `linter` for adding a linter to the default set.
Linters should be defined in the `linter` namespace.
A linter `linter.my_new_linter` is referred to as `my_new_linter` (without the `linter` namespace)
when used in `#lint`.
-/
@[user_attribute]
meta def linter_attr : user_attribute unit unit :=
{ name := "linter",
descr := "Use this declaration as a linting test in #lint",
after_set := some $ λ nm _ _,
mk_const nm >>= infer_type >>= unify `(linter) }
setup_tactic_parser
universe variable v
/-- Find all declarations in `l` where tac returns `some x` and list them. -/
meta def fold_over_with_cond {α} (l : list declaration) (tac : declaration → tactic (option α)) :
tactic (list (declaration × α)) :=
l.mmap_filter $ λ d, option.map (λ x, (d, x)) <$> tac d
/-- Find all declarations in `l` where tac returns `some x` and sort the resulting list by file name. -/
meta def fold_over_with_cond_sorted {α} (l : list declaration)
(tac : declaration → tactic (option α)) : tactic (list (string × list (declaration × α))) := do
e ← get_env,
ds ← fold_over_with_cond l tac,
let ds₂ := rb_lmap.of_list (ds.map (λ x, ((e.decl_olean x.1.to_name).iget, x))),
return $ ds₂.to_list
/-- Make the output of `fold_over_with_cond` printable, in the following form:
`#print <name> <open multiline comment> <elt of α> <close multiline comment>` -/
meta def print_decls {α} [has_to_format α] (ds : list (declaration × α)) : format :=
ds.foldl
(λ f x, f ++ "\n" ++ to_fmt "#print " ++ to_fmt x.1.to_name ++ " /- " ++ to_fmt x.2 ++ " -/")
format.nil
/-- Make the output of `fold_over_with_cond_sorted` printable, with the file path + name inserted.-/
meta def print_decls_sorted {α} [has_to_format α] (ds : list (string × list (declaration × α))) :
format :=
ds.foldl
(λ f x, f ++ "\n\n" ++ to_fmt "-- " ++ to_fmt x.1 ++ print_decls x.2)
format.nil
/-- Same as `print_decls_sorted`, but removing the first `n` characters from the string.
Useful for omitting the mathlib directory from the output. -/
meta def print_decls_sorted_mathlib {α} [has_to_format α] (n : ℕ)
(ds : list (string × list (declaration × α))) : format :=
ds.foldl
(λ f x, f ++ "\n\n" ++ to_fmt "-- " ++ to_fmt (x.1.popn n) ++ print_decls x.2)
format.nil
/-- Pretty prints a list of arguments of a declaration. Assumes `l` is a list of argument positions
and binders (or any other element that can be pretty printed).
`l` can be obtained e.g. by applying `list.indexes_values` to a list obtained by
`get_pi_binders`. -/
meta def print_arguments {α} [has_to_tactic_format α] (l : list (ℕ × α)) : tactic string := do
fs ← l.mmap (λ ⟨n, b⟩, (λ s, to_fmt "argument " ++ to_fmt (n+1) ++ ": " ++ s) <$> pp b),
return $ fs.to_string_aux tt
/- Implementation of the linters -/
/-- Auxilliary definition for `check_unused_arguments` -/
meta def check_unused_arguments_aux : list ℕ → ℕ → ℕ → expr → list ℕ | l n n_max e :=
if n > n_max then l else
if ¬ is_lambda e ∧ ¬ is_pi e then l else
let b := e.binding_body in
let l' := if b.has_var_idx 0 then l else n :: l in check_unused_arguments_aux l' (n+1) n_max b
/-- Check which arguments of a declaration are not used.
Prints a list of natural numbers corresponding to which arguments are not used (e.g.
this outputs [1, 4] if the first and fourth arguments are unused).
Checks both the type and the value of `d` for whether the argument is used
(in rare cases an argument is used in the type but not in the value).
We return [] if the declaration was automatically generated.
We print arguments that are larger than the arity of the type of the declaration
(without unfolding definitions). -/
meta def check_unused_arguments (d : declaration) : option (list ℕ) :=
let l := check_unused_arguments_aux [] 1 d.type.pi_arity d.value in
if l = [] then none else
let l2 := check_unused_arguments_aux [] 1 d.type.pi_arity d.type in
(l.filter $ λ n, n ∈ l2).reverse
/-- Check for unused arguments, and print them with their position, variable name, type and whether
the argument is a duplicate.
See also `check_unused_arguments`.
This tactic additionally filters out all unused arguments of type `parse _` -/
meta def unused_arguments (d : declaration) : tactic (option string) := do
let ns := check_unused_arguments d,
if ¬ ns.is_some then return none else do
let ns := ns.iget,
(ds, _) ← get_pi_binders d.type,
let ns := ns.map (λ n, (n, (ds.nth $ n - 1).iget)),
let ns := ns.filter (λ x, x.2.type.get_app_fn ≠ const `interactive.parse []),
if ns = [] then return none else do
ds' ← ds.mmap pp,
ns ← ns.mmap (λ ⟨n, b⟩, (λ s, to_fmt "argument " ++ to_fmt n ++ ": " ++ s ++
(if ds.countp (λ b', b.type = b'.type) ≥ 2 then " (duplicate)" else "")) <$> pp b),
return $ some $ ns.to_string_aux tt
/-- A linter object for checking for unused arguments. This is in the default linter set. -/
@[linter, priority 1500] meta def linter.unused_arguments : linter :=
{ test := unused_arguments,
no_errors_found := "No unused arguments",
errors_found := "UNUSED ARGUMENTS" }
/-- Checks whether the correct declaration constructor (definition or theorem) by comparing it
to its sort. Instances will not be printed. -/
/- This test is not very quick: maybe we can speed-up testing that something is a proposition?
This takes almost all of the execution time. -/
meta def incorrect_def_lemma (d : declaration) : tactic (option string) :=
if d.is_constant ∨ d.is_axiom
then return none else do
is_instance_d ← is_instance d.to_name,
if is_instance_d then return none else do
-- the following seems to be a little quicker than `is_prop d.type`.
expr.sort n ← infer_type d.type, return $
if d.is_theorem ↔ n = level.zero then none
else if (d.is_definition : bool) then "is a def, should be a lemma/theorem"
else "is a lemma/theorem, should be a def"
/-- A linter for checking whether the correct declaration constructor (definition or theorem)
has been used. -/
@[linter, priority 1490] meta def linter.def_lemma : linter :=
{ test := incorrect_def_lemma,
no_errors_found := "All declarations correctly marked as def/lemma",
errors_found := "INCORRECT DEF/LEMMA" }
/-- Checks whether a declaration has a namespace twice consecutively in its name -/
meta def dup_namespace (d : declaration) : tactic (option string) :=
is_instance d.to_name >>= λ is_inst,
return $ let nm := d.to_name.components in if nm.chain' (≠) ∨ is_inst then none
else let s := (nm.find $ λ n, nm.count n ≥ 2).iget.to_string in
some $ "The namespace `" ++ s ++ "` is duplicated in the name"
/-- A linter for checking whether a declaration has a namespace twice consecutively in its name. -/
@[linter, priority 1480] meta def linter.dup_namespace : linter :=
{ test := dup_namespace,
no_errors_found := "No declarations have a duplicate namespace",
errors_found := "DUPLICATED NAMESPACES IN NAME" }
/-- Checks whether a `>`/`≥` is used in the statement of `d`.
Currently it checks only the conclusion of the declaration, to eliminate false positive from
binders such as `∀ ε > 0, ...` -/
meta def ge_or_gt_in_statement (d : declaration) : tactic (option string) :=
return $ let illegal := [`gt, `ge] in if d.type.pi_codomain.contains_constant (λ n, n ∈ illegal)
then some "the type contains ≥/>. Use ≤/< instead."
else none
-- TODO: the commented out code also checks for classicality in statements, but needs fixing
-- TODO: this probably needs to also check whether the argument is a variable or @eq <var> _ _
-- meta def illegal_constants_in_statement (d : declaration) : tactic (option string) :=
-- return $ if d.type.contains_constant (λ n, (n.get_prefix = `classical ∧
-- n.last ∈ ["prop_decidable", "dec", "dec_rel", "dec_eq"]) ∨ n ∈ [`gt, `ge])
-- then
-- let illegal1 := [`classical.prop_decidable, `classical.dec, `classical.dec_rel, `classical.dec_eq],
-- illegal2 := [`gt, `ge],
-- occur1 := illegal1.filter (λ n, d.type.contains_constant (eq n)),
-- occur2 := illegal2.filter (λ n, d.type.contains_constant (eq n)) in
-- some $ sformat!"the type contains the following declarations: {occur1 ++ occur2}." ++
-- (if occur1 = [] then "" else " Add decidability type-class arguments instead.") ++
-- (if occur2 = [] then "" else " Use ≤/< instead.")
-- else none
/-- A linter for checking whether illegal constants (≥, >) appear in a declaration's type. -/
@[linter, priority 1470] meta def linter.ge_or_gt : linter :=
{ test := ge_or_gt_in_statement,
no_errors_found := "Not using ≥/> in declarations",
errors_found := "USING ≥/> IN DECLARATIONS",
is_fast := ff }
library_note "nolint_ge" "Currently, the linter forbids the use of `>` and `≥` in definitions and
statements, as they cause problems in rewrites. However, we still allow them in some contexts,
for instance when expressing properties of the operator (as in `cobounded (≥)`), or in quantifiers
such as `∀ ε > 0`. Such statements should be marked with the attribute `nolint` to avoid linter
failures."
/-- checks whether an instance that always applies has priority ≥ 1000. -/
-- TODO: instance_priority should also be tested on automatically-generated declarations
meta def instance_priority (d : declaration) : tactic (option string) := do
let nm := d.to_name,
b ← is_instance nm,
/- return `none` if `d` is not an instance -/
if ¬ b then return none else do
prio ← has_attribute `instance nm,
/- return `none` if `d` is has low priority -/
if prio < 1000 then return none else do
let (fn, args) := d.type.pi_codomain.get_app_fn_args,
cls ← get_decl fn.const_name,
let (pi_args, _) := cls.type.pi_binders,
guard (args.length = pi_args.length),
/- List all the arguments of the class that block type-class inference from firing
(if they are metavariables). These are all the arguments except instance-arguments and
out-params. -/
let relevant_args := (args.zip pi_args).filter_map $ λ⟨e, ⟨_, info, tp⟩⟩,
if info = binder_info.inst_implicit ∨ tp.get_app_fn.is_constant_of `out_param
then none else some e,
let always_applies := relevant_args.all expr.is_var ∧ relevant_args.nodup,
if always_applies then return $ some "set priority below 1000" else return none
library_note "lower instance priority"
"Certain instances always apply during type-class resolution. For example, the instance
`add_comm_group.to_add_group {α} [add_comm_group α] : add_group α` applies to all type-class
resolution problems of the form `add_group _`, and type-class inference will then do an
exhaustive search to find a commutative group. These instances take a long time to fail.
Other instances will only apply if the goal has a certain shape. For example
`int.add_group : add_group ℤ` or
`add_group.prod {α β} [add_group α] [add_group β] : add_group (α × β)`. Usually these instances
will fail quickly, and when they apply, they are almost the desired instance.
For this reason, we want the instances of the second type (that only apply in specific cases) to
always have higher priority than the instances of the first type (that always apply).
See also #1561.
Therefore, if we create an instance that always applies, we set the priority of these instances to
100 (or something similar, which is below the default value of 1000)."
library_note "default priority"
"Instances that always apply should be applied after instances that only apply in specific cases,
see note [lower instance priority] above.
Classes that use the `extends` keyword automatically generate instances that always apply.
Therefore, we set the priority of these instances to 100 (or something similar, which is below the
default value of 1000) using `set_option default_priority 100`.
We have to put this option inside a section, so that the default priority is the default
1000 outside the section."
/-- A linter object for checking instance priorities of instances that always apply.
This is in the default linter set. -/
@[linter, priority 1460] meta def linter.instance_priority : linter :=
{ test := instance_priority,
no_errors_found := "All instance priorities are good",
errors_found := "DANGEROUS INSTANCE PRIORITIES.\nThe following instances always apply, and therefore should have a priority < 1000.\nIf you don't know what priority to choose, use priority 100." }
/-- Reports definitions and constants that are missing doc strings -/
meta def doc_blame_report_defn : declaration → tactic (option string)
| (declaration.defn n _ _ _ _ _) := doc_string n >> return none <|> return "def missing doc string"
| (declaration.cnst n _ _ _) := doc_string n >> return none <|> return "constant missing doc string"
| _ := return none
/-- Reports definitions and constants that are missing doc strings -/
meta def doc_blame_report_thm : declaration → tactic (option string)
| (declaration.thm n _ _ _) := doc_string n >> return none <|> return "theorem missing doc string"
| _ := return none
/-- A linter for checking definition doc strings -/
@[linter, priority 1450] meta def linter.doc_blame : linter :=
{ test := λ d, mcond (bnot <$> has_attribute' `instance d.to_name) (doc_blame_report_defn d) (return none),
no_errors_found := "No definitions are missing documentation.",
errors_found := "DEFINITIONS ARE MISSING DOCUMENTATION STRINGS" }
/-- A linter for checking theorem doc strings. This is not in the default linter set. -/
meta def linter.doc_blame_thm : linter :=
{ test := doc_blame_report_thm,
no_errors_found := "No theorems are missing documentation.",
errors_found := "THEOREMS ARE MISSING DOCUMENTATION STRINGS",
is_fast := ff }
/-- Reports declarations of types that do not have an associated `inhabited` instance. -/
meta def has_inhabited_instance (d : declaration) : tactic (option string) := do
tt ← pure d.is_trusted | pure none,
ff ← has_attribute' `reducible d.to_name | pure none,
ff ← has_attribute' `class d.to_name | pure none,
(_, ty) ← mk_local_pis d.type,
ty ← whnf ty,
if ty = `(Prop) then pure none else do
`(Sort _) ← whnf ty | pure none,
insts ← attribute.get_instances `instance,
insts_tys ← insts.mmap $ λ i, expr.pi_codomain <$> declaration.type <$> get_decl i,
let inhabited_insts := insts_tys.filter (λ i,
i.app_fn.const_name = ``inhabited ∨ i.app_fn.const_name = `unique),
let inhabited_tys := inhabited_insts.map (λ i, i.app_arg.get_app_fn.const_name),
if d.to_name ∈ inhabited_tys then
pure none
else
pure "inhabited instance missing"
/-- A linter for missing `inhabited` instances. -/
@[linter, priority 1440]
meta def linter.has_inhabited_instance : linter :=
{ test := has_inhabited_instance,
no_errors_found := "No types have missing inhabited instances.",
errors_found := "TYPES ARE MISSING INHABITED INSTANCES",
is_fast := ff }
/-- Checks whether an instance can never be applied. -/
meta def impossible_instance (d : declaration) : tactic (option string) := do
tt ← is_instance d.to_name | return none,
(binders, _) ← get_pi_binders_dep d.type,
let bad_arguments := binders.filter $ λ nb, nb.2.info ≠ binder_info.inst_implicit,
_ :: _ ← return bad_arguments | return none,
(λ s, some $ "Impossible to infer " ++ s) <$> print_arguments bad_arguments
/-- A linter object for `impossible_instance`. -/
@[linter, priority 1430] meta def linter.impossible_instance : linter :=
{ test := impossible_instance,
no_errors_found := "All instances are applicable",
errors_found := "IMPOSSIBLE INSTANCES FOUND.\nThese instances have an argument that cannot be found during type-class resolution, and therefore can never succeed. Either mark the arguments with square brackets (if it is a class), or don't make it an instance" }
/-- Checks whether the definition `nm` unfolds to a class. -/
/- Note: Caching the result of `unfolds_to_class` by giving it an attribute
(so that e.g. `vector_space` or `decidable_eq` would not be repeatedly unfold to check whether it is
a class), did not speed up this tactic when executed on all of mathlib (and instead significantly
slowed it down) -/
meta def unfolds_to_class : name → tactic bool | nm :=
if nm = `has_reflect then return tt else
succeeds $ has_attribute `class nm <|> do
d ← get_decl nm,
tt ← unfolds_to_class d.value.lambda_body.pi_codomain.get_app_fn.const_name,
return 0 -- We do anything that succeeds here. We return a `ℕ` because of `has_attribute`.
/-- Checks whether an instance can never be applied. -/
meta def incorrect_type_class_argument (d : declaration) : tactic (option string) := do
(binders, _) ← get_pi_binders d.type,
let instance_arguments := binders.indexes_values $
λ b : binder, b.info = binder_info.inst_implicit,
/- the head of the type should either unfold to a class, or be a local constant.
A local constant is allowed, because that could be a class when applied to the proper arguments. -/
bad_arguments ← instance_arguments.mfilter $
λ⟨_, b⟩, let head := b.type.erase_annotations.pi_codomain.get_app_fn in
if head.is_local_constant then return ff else bnot <$> unfolds_to_class head.const_name,
_ :: _ ← return bad_arguments | return none,
(λ s, some $ "These are not classes. " ++ s) <$> print_arguments bad_arguments
/-- A linter object for `impossible_instance`. -/
@[linter, priority 1420] meta def linter.incorrect_type_class_argument : linter :=
{ test := incorrect_type_class_argument,
no_errors_found := "All declarations have correct type-class arguments",
errors_found := "INCORRECT TYPE-CLASS ARGUMENTS.\nSome declarations have non-classes between [square brackets]" }
/-- Checks whether an instance is dangerous: it creates a new type-class problem with metavariable arguments. -/
meta def dangerous_instance (d : declaration) : tactic (option string) := do
tt ← is_instance d.to_name | return none,
(local_constants, target) ← mk_local_pis d.type,
let instance_arguments := local_constants.indexes_values $
λ e : expr, e.local_binding_info = binder_info.inst_implicit,
let bad_arguments := local_constants.indexes_values $ λ x,
!target.has_local_constant x &&
(x.local_binding_info ≠ binder_info.inst_implicit) &&
instance_arguments.any (λ nb, nb.2.local_type.has_local_constant x),
let bad_arguments : list (ℕ × binder) := bad_arguments.map $ λ ⟨n, e⟩, ⟨n, e.to_binder⟩,
_ :: _ ← return bad_arguments | return none,
(λ s, some $ "The following arguments become metavariables. " ++ s) <$> print_arguments bad_arguments
/-- A linter object for `dangerous_instance`. -/
@[linter, priority 1410] meta def linter.dangerous_instance : linter :=
{ test := dangerous_instance,
no_errors_found := "No dangerous instances",
errors_found := "DANGEROUS INSTANCES FOUND.\nThese instances are recursive, and create a new type-class problem which will have metavariables. Currently this linter does not check whether the metavariables only occur in arguments marked with `out_param`, in which case this linter gives a false positive." }
/- Implementation of the frontend. -/
/-- `get_checks slow extra use_only` produces a list of linters.
`extras` is a list of names that should resolve to declarations with type `linter`.
If `use_only` is true, it only uses the linters in `extra`.
Otherwise, it uses all linters in the environment tagged with `@[linter]`.
If `slow` is false, it only uses the fast default tests. -/
meta def get_checks (slow : bool) (extra : list name) (use_only : bool) :
tactic (list linter) := do
default ← if use_only then return [] else attribute.get_instances `linter >>= get_linters,
let default := if slow then default else default.filter (λ l, l.is_fast),
list.append default <$> get_linters extra
/-- If `verbose` is true, return `old ++ new`, else return `old`. -/
private meta def append_when (verbose : bool) (old new : format) : format :=
cond verbose (old ++ new) old
private meta def check_fold (printer : (declaration → tactic (option string)) → tactic (name_set × format))
(verbose : bool) : name_set × format → linter → tactic (name_set × format)
| (ns, s) ⟨tac, ok_string, warning_string, _⟩ :=
do (new_ns, f) ← printer tac,
if f.is_nil then return $ (ns, append_when verbose s format!"/- OK: {ok_string}. -/\n")
else return $ (ns.union new_ns, s ++ format!"/- {warning_string}: -/" ++ f ++ "\n\n")
/-- The common denominator of `#lint[|mathlib|all]`.
The different commands have different configurations for `l`, `printer` and `where_desc`.
If `slow` is false, doesn't do the checks that take a lot of time.
If `verbose` is false, it will suppress messages from passing checks.
By setting `checks` you can customize which checks are performed.
Returns a `name_set` containing the names of all declarations that fail any check in `check`,
and a `format` object describing the failures. -/
meta def lint_aux (l : list declaration)
(printer : (declaration → tactic (option string)) → tactic (name_set × format))
(where_desc : string) (slow verbose : bool) (checks : list linter) : tactic (name_set × format) := do
let s : format := append_when verbose format.nil "/- Note: This command is still in development. -/\n",
let s := append_when verbose s format!"/- Checking {l.length} declarations {where_desc} -/\n\n",
(ns, s) ← checks.mfoldl (check_fold printer verbose) (mk_name_set, s),
return $ (ns, if slow then s else append_when verbose s "/- (slow tests skipped) -/\n")
/-- Return the message printed by `#lint` and a `name_set` containing all declarations that fail. -/
meta def lint (slow : bool := tt) (verbose : bool := tt) (extra : list name := [])
(use_only : bool := ff) : tactic (name_set × format) := do
checks ← get_checks slow extra use_only,
e ← get_env,
l ← e.mfilter (λ d,
if e.in_current_file' d.to_name ∧ ¬ d.to_name.is_internal ∧ ¬ d.is_auto_generated e
then bnot <$> has_attribute' `nolint d.to_name else return ff),
lint_aux l (λ t, do lst ← fold_over_with_cond l t, return
(name_set.of_list (lst.map (declaration.to_name ∘ prod.fst)), print_decls lst))
"in the current file" slow verbose checks
private meta def name_list_of_decl_lists (l : list (string × list (declaration × string))) :
name_set :=
name_set.of_list $ list.join $ l.map $ λ ⟨_, l'⟩, l'.map $ declaration.to_name ∘ prod.fst
/-- Return the message printed by `#lint_mathlib` and a `name_set` containing all declarations that fail. -/
meta def lint_mathlib (slow : bool := tt) (verbose : bool := tt) (extra : list name := [])
(use_only : bool := ff) : tactic (name_set × format) := do
checks ← get_checks slow extra use_only,
e ← get_env,
ml ← get_mathlib_dir,
/- note: we don't separate out some of these tests in `lint_aux` because that causes a
performance hit. That is also the reason for the current formulation using if then else. -/
l ← e.mfilter (λ d,
if e.is_prefix_of_file ml d.to_name ∧ ¬ d.to_name.is_internal ∧ ¬ d.is_auto_generated e
then bnot <$> has_attribute' `nolint d.to_name else return ff),
let ml' := ml.length,
lint_aux l (λ t, do lst ← fold_over_with_cond_sorted l t,
return (name_list_of_decl_lists lst, print_decls_sorted_mathlib ml' lst))
"in mathlib (only in imported files)" slow verbose checks
/-- Return the message printed by `#lint_all` and a `name_set` containing all declarations that fail. -/
meta def lint_all (slow : bool := tt) (verbose : bool := tt) (extra : list name := [])
(use_only : bool := ff) : tactic (name_set × format) := do
checks ← get_checks slow extra use_only,
e ← get_env,
l ← e.mfilter (λ d, if ¬ d.to_name.is_internal ∧ ¬ d.is_auto_generated e
then bnot <$> has_attribute' `nolint d.to_name else return ff),
lint_aux l (λ t, do lst ← fold_over_with_cond_sorted l t,
return (name_list_of_decl_lists lst, print_decls_sorted lst))
"in all imported files (including this one)" slow verbose checks
/-- Parses an optional `only`, followed by a sequence of zero or more identifiers.
Prepends `linter.` to each of these identifiers. -/
private meta def parse_lint_additions : parser (bool × list name) :=
prod.mk <$> only_flag <*> (list.map (name.append `linter) <$> ident_*)
/-- The common denominator of `lint_cmd`, `lint_mathlib_cmd`, `lint_all_cmd` -/
private meta def lint_cmd_aux (scope : bool → bool → list name → bool → tactic (name_set × format)) :
parser unit :=
do silent ← optional (tk "-"),
fast_only ← optional (tk "*"),
silent ← if silent.is_some then return silent else optional (tk "-"), -- allow either order of *-
(use_only, extra) ← parse_lint_additions,
(_, s) ← scope fast_only.is_none silent.is_none extra use_only,
when (¬ s.is_nil) $ do
trace s,
when silent.is_some $ fail "Linting did not succeed"
/-- The command `#lint` at the bottom of a file will warn you about some common mistakes
in that file. Usage: `#lint`, `#lint linter_1 linter_2`, `#lint only linter_1 linter_2`.
`#lint-` will suppress the output of passing checks.
Use the command `#list_linters` to see all available linters. -/
@[user_command] meta def lint_cmd (_ : parse $ tk "#lint") : parser unit :=
lint_cmd_aux @lint
/-- The command `#lint_mathlib` checks all of mathlib for certain mistakes.
Usage: `#lint_mathlib`, `#lint_mathlib linter_1 linter_2`, `#lint_mathlib only linter_1 linter_2`.
`#lint_mathlib-` will suppress the output of passing checks.
Use the command `#list_linters` to see all available linters. -/
@[user_command] meta def lint_mathlib_cmd (_ : parse $ tk "#lint_mathlib") : parser unit :=
lint_cmd_aux @lint_mathlib
/-- The command `#lint_all` checks all imported files for certain mistakes.
Usage: `#lint_all`, `#lint_all linter_1 linter_2`, `#lint_all only linter_1 linter_2`.
`#lint_all-` will suppress the output of passing checks.
Use the command `#list_linters` to see all available linters. -/
@[user_command] meta def lint_all_cmd (_ : parse $ tk "#lint_all") : parser unit :=
lint_cmd_aux @lint_all
/-- The command `#list_linters` prints a list of all available linters. -/
@[user_command] meta def list_linters (_ : parse $ tk "#list_linters") : parser unit :=
do env ← get_env,
let ns := env.decl_filter_map $ λ dcl,
if (dcl.to_name.get_prefix = `linter) && (dcl.type = `(linter)) then some dcl.to_name else none,
trace "Available linters:\n linters marked with (*) are in the default lint set\n",
ns.mmap' $ λ n, do
b ← has_attribute' `linter n,
trace $ n.pop_prefix.to_string ++ if b then " (*)" else ""
/-- Use `lint` as a hole command. Note: In a large file, there might be some delay between
choosing the option and the information appearing -/
@[hole_command] meta def lint_hole_cmd : hole_command :=
{ name := "Lint",
descr := "Lint: Find common mistakes in current file.",
action := λ es, do (_, s) ← lint, return [(s.to_string,"")] }
/-- Tries to apply the `nolint` attribute to a list of declarations. Always succeeds, even if some
of the declarations don't exist. -/
meta def apply_nolint_tac (decls : list name) : tactic unit :=
decls.mmap' (λ d, try (nolint_attr.set d () tt))
/-- `apply_nolint id1 id2 ...` tries to apply the `nolint` attribute to `id1`, `id2`, ...
It will always succeed, even if some of the declarations do not exist. -/
@[user_command] meta def apply_nolint_cmd (_ : parse $ tk "apply_nolint") : parser unit :=
ident_* >>= ↑apply_nolint_tac
|
313efaa02f2e33b3f78cfe3ed32fc09183b20673 | 8cae430f0a71442d02dbb1cbb14073b31048e4b0 | /src/algebraic_geometry/open_immersion/basic.lean | 0592e7c1bed519243bd6fa772ccf9b03f47826f9 | [
"Apache-2.0"
] | permissive | leanprover-community/mathlib | 56a2cadd17ac88caf4ece0a775932fa26327ba0e | 442a83d738cb208d3600056c489be16900ba701d | refs/heads/master | 1,693,584,102,358 | 1,693,471,902,000 | 1,693,471,902,000 | 97,922,418 | 1,595 | 352 | Apache-2.0 | 1,694,693,445,000 | 1,500,624,130,000 | Lean | UTF-8 | Lean | false | false | 43,349 | lean | /-
Copyright (c) 2021 Andrew Yang. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Andrew Yang
-/
import topology.category.Top.limits.pullbacks
import algebraic_geometry.locally_ringed_space
/-!
# Open immersions of structured spaces
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
We say that a morphism of presheafed spaces `f : X ⟶ Y` 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`.
Abbreviations are also provided for `SheafedSpace`, `LocallyRingedSpace` and `Scheme`.
## Main definitions
* `algebraic_geometry.PresheafedSpace.is_open_immersion`: the `Prop`-valued typeclass asserting
that a PresheafedSpace hom `f` is an open_immersion.
* `algebraic_geometry.is_open_immersion`: the `Prop`-valued typeclass asserting
that a Scheme morphism `f` is an open_immersion.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.iso_restrict`: The source of an
open immersion is isomorphic to the restriction of the target onto the image.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.lift`: Any morphism whose range is
contained in an open immersion factors though the open immersion.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.to_SheafedSpace`: If `f : X ⟶ Y` is an
open immersion of presheafed spaces, and `Y` is a sheafed space, then `X` is also a sheafed
space. The morphism as morphisms of sheafed spaces is given by `to_SheafedSpace_hom`.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.to_LocallyRingedSpace`: If `f : X ⟶ Y` is
an open immersion of presheafed spaces, and `Y` is a locally ringed space, then `X` is also a
locally ringed space. The morphism as morphisms of locally ringed spaces is given by
`to_LocallyRingedSpace_hom`.
## Main results
* `algebraic_geometry.PresheafedSpace.is_open_immersion.comp`: The composition of two open
immersions is an open immersion.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.of_iso`: An iso is an open immersion.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.to_iso`:
A surjective open immersion is an isomorphism.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.stalk_iso`: An open immersion induces
an isomorphism on stalks.
* `algebraic_geometry.PresheafedSpace.is_open_immersion.has_pullback_of_left`: If `f` is an open
immersion, then the pullback `(f, g)` exists (and the forgetful functor to `Top` preserves it).
* `algebraic_geometry.PresheafedSpace.is_open_immersion.pullback_snd_of_left`: Open immersions
are stable under pullbacks.
* `algebraic_geometry.SheafedSpace.is_open_immersion.of_stalk_iso` An (topological) open embedding
between two sheafed spaces is an open immersion if all the stalk maps are isomorphisms.
-/
open topological_space category_theory opposite
open category_theory.limits
namespace algebraic_geometry
universes v v₁ v₂ u
variables {C : Type u} [category.{v} C]
/--
An open immersion of PresheafedSpaces is an open embedding `f : X ⟶ U ⊆ Y` of the underlying
spaces, such that the sheaf map `Y(V) ⟶ f _* X(V)` is an iso for each `V ⊆ U`.
-/
class PresheafedSpace.is_open_immersion {X Y : PresheafedSpace.{v} C} (f : X ⟶ Y) : Prop :=
(base_open : open_embedding f.base)
(c_iso : ∀ U : opens X, is_iso (f.c.app (op (base_open.is_open_map.functor.obj U))))
/--
A morphism of SheafedSpaces is an open immersion if it is an open immersion as a morphism
of PresheafedSpaces
-/
abbreviation SheafedSpace.is_open_immersion {X Y : SheafedSpace.{v} C} (f : X ⟶ Y) : Prop :=
PresheafedSpace.is_open_immersion f
/--
A morphism of LocallyRingedSpaces is an open immersion if it is an open immersion as a morphism
of SheafedSpaces
-/
abbreviation LocallyRingedSpace.is_open_immersion {X Y : LocallyRingedSpace} (f : X ⟶ Y) : Prop :=
SheafedSpace.is_open_immersion f.1
namespace PresheafedSpace.is_open_immersion
open PresheafedSpace
local notation `is_open_immersion` := PresheafedSpace.is_open_immersion
attribute [instance] is_open_immersion.c_iso
section
variables {X Y : PresheafedSpace.{v} C} {f : X ⟶ Y} (H : is_open_immersion f)
/-- The functor `opens X ⥤ opens Y` associated with an open immersion `f : X ⟶ Y`. -/
abbreviation open_functor := H.base_open.is_open_map.functor
/-- An open immersion `f : X ⟶ Y` induces an isomorphism `X ≅ Y|_{f(X)}`. -/
@[simps hom_c_app] noncomputable
def iso_restrict : X ≅ Y.restrict H.base_open :=
PresheafedSpace.iso_of_components (iso.refl _)
begin
symmetry,
fapply nat_iso.of_components,
intro U,
refine as_iso (f.c.app (op (H.open_functor.obj (unop U)))) ≪≫ X.presheaf.map_iso (eq_to_iso _),
{ induction U using opposite.rec,
cases U,
dsimp only [is_open_map.functor, functor.op, opens.map],
congr' 2,
erw set.preimage_image_eq _ H.base_open.inj,
refl },
{ intros U V i,
simp only [category_theory.eq_to_iso.hom, Top.presheaf.pushforward_obj_map, category.assoc,
functor.op_map, iso.trans_hom, as_iso_hom, functor.map_iso_hom, ←X.presheaf.map_comp],
erw [f.c.naturality_assoc, ←X.presheaf.map_comp],
congr }
end
@[simp] lemma iso_restrict_hom_of_restrict : H.iso_restrict.hom ≫ Y.of_restrict _ = f :=
begin
ext,
{ simp only [comp_c_app, iso_restrict_hom_c_app, nat_trans.comp_app,
eq_to_hom_refl, of_restrict_c_app, category.assoc, whisker_right_id'],
erw [category.comp_id, f.c.naturality_assoc, ←X.presheaf.map_comp],
transitivity f.c.app x ≫ X.presheaf.map (𝟙 _),
{ congr },
{ erw [X.presheaf.map_id, category.comp_id] } },
{ refl, }
end
@[simp] lemma iso_restrict_inv_of_restrict : H.iso_restrict.inv ≫ f = Y.of_restrict _ :=
by { rw [iso.inv_comp_eq, iso_restrict_hom_of_restrict] }
instance mono [H : is_open_immersion f] : mono f :=
by { rw ← H.iso_restrict_hom_of_restrict, apply mono_comp }
/-- The composition of two open immersions is an open immersion. -/
instance comp {Z : PresheafedSpace C} (f : X ⟶ Y) [hf : is_open_immersion f] (g : Y ⟶ Z)
[hg : is_open_immersion g] :
is_open_immersion (f ≫ g) :=
{ base_open := hg.base_open.comp hf.base_open,
c_iso := λ U,
begin
generalize_proofs h,
dsimp only [algebraic_geometry.PresheafedSpace.comp_c_app, unop_op, functor.op, comp_base,
Top.presheaf.pushforward_obj_obj, opens.map_comp_obj],
apply_with is_iso.comp_is_iso { instances := ff },
swap,
{ have : (opens.map g.base).obj (h.functor.obj U) = hf.open_functor.obj U,
{ ext1,
dsimp only [opens.map_coe, is_open_map.functor_obj_coe, comp_base],
rw [coe_comp, ← set.image_image, set.preimage_image_eq _ hg.base_open.inj] },
rw this,
apply_instance },
{ have : h.functor.obj U = hg.open_functor.obj (hf.open_functor.obj U),
{ ext1,
dsimp only [is_open_map.functor_obj_coe],
rw [comp_base, coe_comp, ←set.image_image] },
rw this,
apply_instance }
end }
/-- For an open immersion `f : X ⟶ Y` and an open set `U ⊆ X`, we have the map `X(U) ⟶ Y(U)`. -/
noncomputable
def inv_app (U : opens X) : X.presheaf.obj (op U) ⟶ Y.presheaf.obj (op (H.open_functor.obj U)) :=
X.presheaf.map (eq_to_hom (by simp [opens.map, set.preimage_image_eq _ H.base_open.inj])) ≫
inv (f.c.app (op (H.open_functor.obj U)))
@[simp, reassoc] lemma inv_naturality {U V : (opens X)ᵒᵖ} (i : U ⟶ V) :
X.presheaf.map i ≫ H.inv_app (unop V) = H.inv_app (unop U) ≫
Y.presheaf.map (H.open_functor.op.map i) :=
begin
simp only [inv_app, ←category.assoc],
rw [is_iso.comp_inv_eq],
simp only [category.assoc, f.c.naturality, is_iso.inv_hom_id_assoc, ← X.presheaf.map_comp],
erw ← X.presheaf.map_comp,
congr
end
instance (U : opens X) : is_iso (H.inv_app U) := by { delta inv_app, apply_instance }
lemma inv_inv_app (U : opens X) :
inv (H.inv_app U) = f.c.app (op (H.open_functor.obj U)) ≫
X.presheaf.map (eq_to_hom (by simp [opens.map, set.preimage_image_eq _ H.base_open.inj])) :=
begin
rw ← cancel_epi (H.inv_app U),
rw is_iso.hom_inv_id,
delta inv_app,
simp [← functor.map_comp]
end
@[simp, reassoc, elementwise] lemma inv_app_app (U : opens X) :
H.inv_app U ≫ f.c.app (op (H.open_functor.obj U)) =
X.presheaf.map (eq_to_hom (by simp [opens.map, set.preimage_image_eq _ H.base_open.inj])) :=
by rw [inv_app, category.assoc, is_iso.inv_hom_id, category.comp_id]
@[simp, reassoc] lemma app_inv_app (U : opens Y) :
f.c.app (op U) ≫ H.inv_app ((opens.map f.base).obj U) =
Y.presheaf.map ((hom_of_le (by exact set.image_preimage_subset f.base U)).op :
op U ⟶ op (H.open_functor.obj ((opens.map f.base).obj U))) :=
by { erw ← category.assoc, rw [is_iso.comp_inv_eq, f.c.naturality], congr }
/-- A variant of `app_inv_app` that gives an `eq_to_hom` instead of `hom_of_le`. -/
@[reassoc] lemma app_inv_app' (U : opens Y) (hU : (U : set Y) ⊆ set.range f.base) :
f.c.app (op U) ≫ H.inv_app ((opens.map f.base).obj U) =
Y.presheaf.map (eq_to_hom (by
{ apply le_antisymm,
{ exact set.image_preimage_subset f.base U.1 },
{ rw [← set_like.coe_subset_coe],
refine has_le.le.trans_eq _ (@set.image_preimage_eq_inter_range _ _ f.base U.1).symm,
exact set.subset_inter_iff.mpr ⟨λ _ h, h, hU⟩ } })).op :=
by { erw ← category.assoc, rw [is_iso.comp_inv_eq, f.c.naturality], congr }
/-- An isomorphism is an open immersion. -/
instance of_iso {X Y : PresheafedSpace.{v} C} (H : X ≅ Y) : is_open_immersion H.hom :=
{ base_open := (Top.homeo_of_iso ((forget C).map_iso H)).open_embedding,
c_iso := λ _, infer_instance }
@[priority 100]
instance of_is_iso {X Y : PresheafedSpace.{v} C} (f : X ⟶ Y) [is_iso f] : is_open_immersion f :=
algebraic_geometry.PresheafedSpace.is_open_immersion.of_iso (as_iso f)
instance of_restrict {X : Top} (Y : PresheafedSpace C) {f : X ⟶ Y.carrier}
(hf : open_embedding f) : is_open_immersion (Y.of_restrict hf) :=
{ base_open := hf,
c_iso := λ U,
begin
dsimp,
have : (opens.map f).obj (hf.is_open_map.functor.obj U) = U,
{ ext1,
exact set.preimage_image_eq _ hf.inj },
convert (show is_iso (Y.presheaf.map (𝟙 _)), from infer_instance),
{ apply subsingleton.helim,
rw this },
{ rw Y.presheaf.map_id,
apply_instance }
end }
@[elementwise, simp]
lemma of_restrict_inv_app {C : Type*} [category C] (X : PresheafedSpace C) {Y : Top}
{f : Y ⟶ Top.of X.carrier}
(h : open_embedding f) (U : opens (X.restrict h).carrier) :
(PresheafedSpace.is_open_immersion.of_restrict X h).inv_app U = 𝟙 _ :=
begin
delta PresheafedSpace.is_open_immersion.inv_app,
rw [is_iso.comp_inv_eq, category.id_comp],
change X.presheaf.map _ = X.presheaf.map _,
congr
end
/-- An open immersion is an iso if the underlying continuous map is epi. -/
lemma to_iso (f : X ⟶ Y) [h : is_open_immersion f] [h' : epi f.base] : is_iso f :=
begin
apply_with is_iso_of_components { instances := ff },
{ let : X ≃ₜ Y := (homeomorph.of_embedding _ h.base_open.to_embedding).trans
{ to_fun := subtype.val, inv_fun := λ x, ⟨x,
by { rw set.range_iff_surjective.mpr ((Top.epi_iff_surjective _).mp h'), trivial }⟩,
left_inv := λ ⟨_,_⟩, rfl, right_inv := λ _, rfl },
convert is_iso.of_iso (Top.iso_of_homeo this),
{ ext, refl } },
{ apply_with nat_iso.is_iso_of_is_iso_app { instances := ff },
intro U,
have : U = op (h.open_functor.obj ((opens.map f.base).obj (unop U))),
{ induction U using opposite.rec,
cases U,
dsimp only [functor.op, opens.map],
congr,
exact (set.image_preimage_eq _ ((Top.epi_iff_surjective _).mp h')).symm },
convert @@is_open_immersion.c_iso _ h ((opens.map f.base).obj (unop U)) }
end
instance stalk_iso [has_colimits C] [H : is_open_immersion f] (x : X) : is_iso (stalk_map f x) :=
begin
rw ← H.iso_restrict_hom_of_restrict,
rw PresheafedSpace.stalk_map.comp,
apply_instance
end
end
section pullback
noncomputable theory
variables {X Y Z : PresheafedSpace.{v} C} (f : X ⟶ Z) [hf : is_open_immersion f] (g : Y ⟶ Z)
include hf
/--
(Implementation.) The projection map when constructing the pullback along an open immersion.
-/
def pullback_cone_of_left_fst :
Y.restrict (Top.snd_open_embedding_of_left_open_embedding hf.base_open g.base) ⟶ X :=
{ base := pullback.fst,
c :=
{ app := λ U, hf.inv_app (unop U) ≫
g.c.app (op (hf.base_open.is_open_map.functor.obj (unop U))) ≫
Y.presheaf.map (eq_to_hom
(begin
simp only [is_open_map.functor, subtype.mk_eq_mk, unop_op, op_inj_iff, opens.map,
subtype.coe_mk, functor.op_obj, subtype.val_eq_coe],
apply has_le.le.antisymm,
{ rintros _ ⟨_, h₁, h₂⟩,
use (Top.pullback_iso_prod_subtype _ _).inv ⟨⟨_, _⟩, h₂⟩,
simpa using h₁ },
{ rintros _ ⟨x, h₁, rfl⟩,
exact ⟨_, h₁, concrete_category.congr_hom pullback.condition x⟩ }
end)),
naturality' :=
begin
intros U V i,
induction U using opposite.rec,
induction V using opposite.rec,
simp only [quiver.hom.unop_op, Top.presheaf.pushforward_obj_map, category.assoc,
nat_trans.naturality_assoc, functor.op_map, inv_naturality_assoc, ← Y.presheaf.map_comp],
erw ← Y.presheaf.map_comp,
congr
end } }
lemma pullback_cone_of_left_condition :
pullback_cone_of_left_fst f g ≫ f = Y.of_restrict _ ≫ g :=
begin
ext U,
{ induction U using opposite.rec,
dsimp only [comp_c_app, nat_trans.comp_app, unop_op,
whisker_right_app, pullback_cone_of_left_fst],
simp only [quiver.hom.unop_op, Top.presheaf.pushforward_obj_map, app_inv_app_assoc,
eq_to_hom_app, eq_to_hom_unop, category.assoc, nat_trans.naturality_assoc, functor.op_map],
erw [← Y.presheaf.map_comp, ← Y.presheaf.map_comp],
congr },
{ simpa using pullback.condition }
end
/--
We construct the pullback along an open immersion via restricting along the pullback of the
maps of underlying spaces (which is also an open embedding).
-/
def pullback_cone_of_left : pullback_cone f g :=
pullback_cone.mk (pullback_cone_of_left_fst f g) (Y.of_restrict _)
(pullback_cone_of_left_condition f g)
variable (s : pullback_cone f g)
/--
(Implementation.) Any cone over `cospan f g` indeed factors through the constructed cone.
-/
def pullback_cone_of_left_lift : s.X ⟶ (pullback_cone_of_left f g).X :=
{ base := pullback.lift s.fst.base s.snd.base
(congr_arg (λ x, PresheafedSpace.hom.base x) s.condition),
c :=
{ app := λ U, s.snd.c.app _ ≫ s.X.presheaf.map (eq_to_hom (begin
dsimp only [opens.map, is_open_map.functor, functor.op],
congr' 2,
let s' : pullback_cone f.base g.base := pullback_cone.mk s.fst.base s.snd.base _,
have : _ = s.snd.base := limit.lift_π s' walking_cospan.right,
conv_lhs { erw ← this, rw coe_comp, erw ← set.preimage_preimage },
erw set.preimage_image_eq _
(Top.snd_open_embedding_of_left_open_embedding hf.base_open g.base).inj,
end)),
naturality' := λ U V i,
begin
erw s.snd.c.naturality_assoc,
rw category.assoc,
erw [← s.X.presheaf.map_comp, ← s.X.presheaf.map_comp],
congr
end } }
-- this lemma is not a `simp` lemma, because it is an implementation detail
lemma pullback_cone_of_left_lift_fst :
pullback_cone_of_left_lift f g s ≫ (pullback_cone_of_left f g).fst = s.fst :=
begin
ext x,
{ induction x using opposite.rec,
change ((_ ≫ _) ≫ _ ≫ _) ≫ _ = _,
simp_rw [category.assoc],
erw ← s.X.presheaf.map_comp,
erw s.snd.c.naturality_assoc,
have := congr_app s.condition (op (hf.open_functor.obj x)),
dsimp only [comp_c_app, unop_op] at this,
rw ← is_iso.comp_inv_eq at this,
reassoc! this,
erw [← this, hf.inv_app_app_assoc, s.fst.c.naturality_assoc],
simpa [eq_to_hom_map], },
{ change pullback.lift _ _ _ ≫ pullback.fst = _,
simp }
end
-- this lemma is not a `simp` lemma, because it is an implementation detail
lemma pullback_cone_of_left_lift_snd :
pullback_cone_of_left_lift f g s ≫ (pullback_cone_of_left f g).snd = s.snd :=
begin
ext x,
{ change (_ ≫ _ ≫ _) ≫ _ = _,
simp_rw category.assoc,
erw s.snd.c.naturality_assoc,
erw [← s.X.presheaf.map_comp, ← s.X.presheaf.map_comp],
transitivity s.snd.c.app x ≫ s.X.presheaf.map (𝟙 _),
{ congr },
{ rw s.X.presheaf.map_id, erw category.comp_id } },
{ change pullback.lift _ _ _ ≫ pullback.snd = _,
simp }
end
instance pullback_cone_snd_is_open_immersion :
is_open_immersion (pullback_cone_of_left f g).snd :=
begin
erw category_theory.limits.pullback_cone.mk_snd,
apply_instance
end
/-- The constructed pullback cone is indeed the pullback. -/
def pullback_cone_of_left_is_limit :
is_limit (pullback_cone_of_left f g) :=
begin
apply pullback_cone.is_limit_aux',
intro s,
use pullback_cone_of_left_lift f g s,
use pullback_cone_of_left_lift_fst f g s,
use pullback_cone_of_left_lift_snd f g s,
intros m h₁ h₂,
rw ← cancel_mono (pullback_cone_of_left f g).snd,
exact (h₂.trans (pullback_cone_of_left_lift_snd f g s).symm)
end
instance has_pullback_of_left :
has_pullback f g :=
⟨⟨⟨_, pullback_cone_of_left_is_limit f g⟩⟩⟩
instance has_pullback_of_right :
has_pullback g f := has_pullback_symmetry f g
/-- Open immersions are stable under base-change. -/
instance pullback_snd_of_left :
is_open_immersion (pullback.snd : pullback f g ⟶ _) :=
begin
delta pullback.snd,
rw ← limit.iso_limit_cone_hom_π ⟨_, pullback_cone_of_left_is_limit f g⟩ walking_cospan.right,
apply_instance
end
/-- Open immersions are stable under base-change. -/
instance pullback_fst_of_right :
is_open_immersion (pullback.fst : pullback g f ⟶ _) :=
begin
rw ← pullback_symmetry_hom_comp_snd,
apply_instance
end
instance pullback_to_base_is_open_immersion [is_open_immersion g] :
is_open_immersion (limit.π (cospan f g) walking_cospan.one) :=
begin
rw [←limit.w (cospan f g) walking_cospan.hom.inl, cospan_map_inl],
apply_instance
end
instance forget_preserves_limits_of_left : preserves_limit (cospan f g) (forget C) :=
preserves_limit_of_preserves_limit_cone (pullback_cone_of_left_is_limit f g)
begin
apply (is_limit.postcompose_hom_equiv (diagram_iso_cospan.{v} _) _).to_fun,
refine (is_limit.equiv_iso_limit _).to_fun (limit.is_limit (cospan f.base g.base)),
fapply cones.ext,
exact (iso.refl _),
change ∀ j, _ = 𝟙 _ ≫ _ ≫ _,
simp_rw category.id_comp,
rintros (_|_|_); symmetry,
{ erw category.comp_id,
exact limit.w (cospan f.base g.base) walking_cospan.hom.inl },
{ exact category.comp_id _ },
{ exact category.comp_id _ },
end
instance forget_preserves_limits_of_right : preserves_limit (cospan g f) (forget C) :=
preserves_pullback_symmetry (forget C) f g
lemma pullback_snd_is_iso_of_range_subset (H : set.range g.base ⊆ set.range f.base) :
is_iso (pullback.snd : pullback f g ⟶ _) :=
begin
haveI := Top.snd_iso_of_left_embedding_range_subset hf.base_open.to_embedding g.base H,
haveI : is_iso (pullback.snd : pullback f g ⟶ _).base,
{ delta pullback.snd,
rw ← limit.iso_limit_cone_hom_π ⟨_, pullback_cone_of_left_is_limit f g⟩ walking_cospan.right,
change is_iso (_ ≫ pullback.snd),
apply_instance },
apply to_iso
end
/--
The universal property of open immersions:
For an open immersion `f : X ⟶ Z`, given any morphism of schemes `g : Y ⟶ Z` whose topological
image is contained in the image of `f`, we can lift this morphism to a unique `Y ⟶ X` that
commutes with these maps.
-/
def lift (H : set.range g.base ⊆ set.range f.base) : Y ⟶ X :=
begin
haveI := pullback_snd_is_iso_of_range_subset f g H,
exact inv (pullback.snd : pullback f g ⟶ _) ≫ pullback.fst,
end
@[simp, reassoc] lemma lift_fac (H : set.range g.base ⊆ set.range f.base) :
lift f g H ≫ f = g :=
by { erw category.assoc, rw is_iso.inv_comp_eq, exact pullback.condition }
lemma lift_uniq (H : set.range g.base ⊆ set.range f.base) (l : Y ⟶ X)
(hl : l ≫ f = g) : l = lift f g H :=
by rw [← cancel_mono f, hl, lift_fac]
/-- Two open immersions with equal range is isomorphic. -/
@[simps] def iso_of_range_eq [is_open_immersion g] (e : set.range f.base = set.range g.base) :
X ≅ Y :=
{ hom := lift g f (le_of_eq e),
inv := lift f g (le_of_eq e.symm),
hom_inv_id' := by { rw ← cancel_mono f, simp },
inv_hom_id' := by { rw ← cancel_mono g, simp } }
end pullback
open category_theory.limits.walking_cospan
section to_SheafedSpace
variables {X : PresheafedSpace.{v} C} (Y : SheafedSpace C)
variables (f : X ⟶ Y.to_PresheafedSpace) [H : is_open_immersion f]
include H
/-- If `X ⟶ Y` is an open immersion, and `Y` is a SheafedSpace, then so is `X`. -/
def to_SheafedSpace : SheafedSpace C :=
{ is_sheaf :=
begin
apply Top.presheaf.is_sheaf_of_iso (sheaf_iso_of_iso H.iso_restrict.symm).symm,
apply Top.sheaf.pushforward_sheaf_of_sheaf,
exact (Y.restrict H.base_open).is_sheaf
end,
to_PresheafedSpace := X }
@[simp] lemma to_SheafedSpace_to_PresheafedSpace : (to_SheafedSpace Y f).to_PresheafedSpace = X :=
rfl
/--
If `X ⟶ Y` is an open immersion of PresheafedSpaces, and `Y` is a SheafedSpace, we can
upgrade it into a morphism of SheafedSpaces.
-/
def to_SheafedSpace_hom : to_SheafedSpace Y f ⟶ Y := f
@[simp] lemma to_SheafedSpace_hom_base : (to_SheafedSpace_hom Y f).base = f.base := rfl
@[simp] lemma to_SheafedSpace_hom_c : (to_SheafedSpace_hom Y f).c = f.c := rfl
instance to_SheafedSpace_is_open_immersion :
SheafedSpace.is_open_immersion (to_SheafedSpace_hom Y f) := H
omit H
@[simp] lemma SheafedSpace_to_SheafedSpace {X Y : SheafedSpace.{v} C} (f : X ⟶ Y)
[is_open_immersion f] : to_SheafedSpace Y f = X := by unfreezingI { cases X, refl }
end to_SheafedSpace
section to_LocallyRingedSpace
variables {X : PresheafedSpace.{u} CommRing.{u}} (Y : LocallyRingedSpace.{u})
variables (f : X ⟶ Y.to_PresheafedSpace) [H : is_open_immersion f]
include H
/-- If `X ⟶ Y` is an open immersion, and `Y` is a LocallyRingedSpace, then so is `X`. -/
def to_LocallyRingedSpace : LocallyRingedSpace :=
{ to_SheafedSpace := to_SheafedSpace Y.to_SheafedSpace f,
local_ring := λ x, begin
haveI : local_ring (Y.to_SheafedSpace.to_PresheafedSpace.stalk (f.base x)) := Y.local_ring _,
exact (as_iso (stalk_map f x)).CommRing_iso_to_ring_equiv.local_ring
end }
@[simp] lemma to_LocallyRingedSpace_to_SheafedSpace :
(to_LocallyRingedSpace Y f).to_SheafedSpace = (to_SheafedSpace Y.1 f) := rfl
/--
If `X ⟶ Y` is an open immersion of PresheafedSpaces, and `Y` is a LocallyRingedSpace, we can
upgrade it into a morphism of LocallyRingedSpace.
-/
def to_LocallyRingedSpace_hom : to_LocallyRingedSpace Y f ⟶ Y := ⟨f, λ x, infer_instance⟩
@[simp] lemma to_LocallyRingedSpace_hom_val :
(to_LocallyRingedSpace_hom Y f).val = f := rfl
instance to_LocallyRingedSpace_is_open_immersion :
LocallyRingedSpace.is_open_immersion (to_LocallyRingedSpace_hom Y f) := H
omit H
@[simp] lemma LocallyRingedSpace_to_LocallyRingedSpace {X Y : LocallyRingedSpace} (f : X ⟶ Y)
[LocallyRingedSpace.is_open_immersion f] :
to_LocallyRingedSpace Y f.1 = X :=
by unfreezingI { cases X, delta to_LocallyRingedSpace, simp }
end to_LocallyRingedSpace
lemma is_iso_of_subset {X Y : PresheafedSpace.{v} C} (f : X ⟶ Y)
[H : PresheafedSpace.is_open_immersion f] (U : opens Y.carrier)
(hU : (U : set Y.carrier) ⊆ set.range f.base) : is_iso (f.c.app $ op U) :=
begin
have : U = H.base_open.is_open_map.functor.obj ((opens.map f.base).obj U),
{ ext1,
exact (set.inter_eq_left_iff_subset.mpr hU).symm.trans set.image_preimage_eq_inter_range.symm },
convert PresheafedSpace.is_open_immersion.c_iso ((opens.map f.base).obj U),
end
end PresheafedSpace.is_open_immersion
namespace SheafedSpace.is_open_immersion
@[priority 100]
instance of_is_iso {X Y : SheafedSpace.{v} C} (f : X ⟶ Y) [is_iso f] :
SheafedSpace.is_open_immersion f :=
@@PresheafedSpace.is_open_immersion.of_is_iso _ f
(SheafedSpace.forget_to_PresheafedSpace.map_is_iso _)
instance comp {X Y Z : SheafedSpace C} (f : X ⟶ Y) (g : Y ⟶ Z)
[SheafedSpace.is_open_immersion f] [SheafedSpace.is_open_immersion g] :
SheafedSpace.is_open_immersion (f ≫ g) := PresheafedSpace.is_open_immersion.comp f g
section pullback
variables {X Y Z : SheafedSpace C} (f : X ⟶ Z) (g : Y ⟶ Z)
variable [H : SheafedSpace.is_open_immersion f]
include H
local notation `forget` := SheafedSpace.forget_to_PresheafedSpace
open category_theory.limits.walking_cospan
instance : mono f :=
forget .mono_of_mono_map (show @mono (PresheafedSpace C) _ _ _ f, by apply_instance)
instance forget_map_is_open_immersion :
PresheafedSpace.is_open_immersion (forget .map f) := ⟨H.base_open, H.c_iso⟩
instance has_limit_cospan_forget_of_left : has_limit (cospan f g ⋙ forget) :=
begin
apply has_limit_of_iso (diagram_iso_cospan.{v} _).symm,
change has_limit (cospan (forget .map f) (forget .map g)),
apply_instance
end
instance has_limit_cospan_forget_of_left' : has_limit (cospan ((cospan f g ⋙ forget).map hom.inl)
((cospan f g ⋙ forget).map hom.inr)) :=
show has_limit (cospan (forget .map f) (forget .map g)), from infer_instance
instance has_limit_cospan_forget_of_right : has_limit (cospan g f ⋙ forget) :=
begin
apply has_limit_of_iso (diagram_iso_cospan.{v} _).symm,
change has_limit (cospan (forget .map g) (forget .map f)),
apply_instance
end
instance has_limit_cospan_forget_of_right' : has_limit (cospan ((cospan g f ⋙ forget).map hom.inl)
((cospan g f ⋙ forget).map hom.inr)) :=
show has_limit (cospan (forget .map g) (forget .map f)), from infer_instance
instance forget_creates_pullback_of_left : creates_limit (cospan f g) forget :=
creates_limit_of_fully_faithful_of_iso
(PresheafedSpace.is_open_immersion.to_SheafedSpace Y
(@pullback.snd (PresheafedSpace C) _ _ _ _ f g _))
(eq_to_iso (show pullback _ _ = pullback _ _, by congr)
≪≫ has_limit.iso_of_nat_iso (diagram_iso_cospan _).symm)
instance forget_creates_pullback_of_right : creates_limit (cospan g f) forget :=
creates_limit_of_fully_faithful_of_iso
(PresheafedSpace.is_open_immersion.to_SheafedSpace Y
(@pullback.fst (PresheafedSpace C) _ _ _ _ g f _))
(eq_to_iso (show pullback _ _ = pullback _ _, by congr)
≪≫ has_limit.iso_of_nat_iso (diagram_iso_cospan _).symm)
instance SheafedSpace_forget_preserves_of_left :
preserves_limit (cospan f g) (SheafedSpace.forget C) :=
@@limits.comp_preserves_limit _ _ _ _ forget (PresheafedSpace.forget C) _
begin
apply_with (preserves_limit_of_iso_diagram _ (diagram_iso_cospan.{v} _).symm) { instances := tt },
dsimp,
apply_instance
end
instance SheafedSpace_forget_preserves_of_right :
preserves_limit (cospan g f) (SheafedSpace.forget C) :=
preserves_pullback_symmetry _ _ _
instance SheafedSpace_has_pullback_of_left : has_pullback f g :=
has_limit_of_created (cospan f g) forget
instance SheafedSpace_has_pullback_of_right : has_pullback g f :=
has_limit_of_created (cospan g f) forget
/-- Open immersions are stable under base-change. -/
instance SheafedSpace_pullback_snd_of_left :
SheafedSpace.is_open_immersion (pullback.snd : pullback f g ⟶ _) :=
begin
delta pullback.snd,
have : _ = limit.π (cospan f g) right := preserves_limits_iso_hom_π
forget (cospan f g) right,
rw ← this,
have := has_limit.iso_of_nat_iso_hom_π
(diagram_iso_cospan.{v} (cospan f g ⋙ forget))
right,
erw category.comp_id at this,
rw ← this,
dsimp,
apply_instance
end
instance SheafedSpace_pullback_fst_of_right :
SheafedSpace.is_open_immersion (pullback.fst : pullback g f ⟶ _) :=
begin
delta pullback.fst,
have : _ = limit.π (cospan g f) left := preserves_limits_iso_hom_π
forget (cospan g f) left,
rw ← this,
have := has_limit.iso_of_nat_iso_hom_π
(diagram_iso_cospan.{v} (cospan g f ⋙ forget)) left,
erw category.comp_id at this,
rw ← this,
dsimp,
apply_instance
end
instance SheafedSpace_pullback_to_base_is_open_immersion [SheafedSpace.is_open_immersion g] :
SheafedSpace.is_open_immersion (limit.π (cospan f g) one : pullback f g ⟶ Z) :=
begin
rw [←limit.w (cospan f g) hom.inl, cospan_map_inl],
apply_instance
end
end pullback
section of_stalk_iso
variables [has_limits C] [has_colimits C] [concrete_category.{v} C]
variables [reflects_isomorphisms (forget C)] [preserves_limits (forget C)]
variables [preserves_filtered_colimits (forget C)]
/--
Suppose `X Y : SheafedSpace C`, where `C` is a concrete category,
whose forgetful functor reflects isomorphisms, preserves limits and filtered colimits.
Then a morphism `X ⟶ Y` that is a topological open embedding
is an open immersion iff every stalk map is an iso.
-/
lemma of_stalk_iso {X Y : SheafedSpace C} (f : X ⟶ Y)
(hf : open_embedding f.base) [H : ∀ x : X, is_iso (PresheafedSpace.stalk_map f x)] :
SheafedSpace.is_open_immersion f :=
{ base_open := hf,
c_iso := λ U, begin
apply_with (Top.presheaf.app_is_iso_of_stalk_functor_map_iso
(show Y.sheaf ⟶ (Top.sheaf.pushforward f.base).obj X.sheaf, from ⟨f.c⟩)) { instances := ff },
rintros ⟨_, y, hy, rfl⟩,
specialize H y,
delta PresheafedSpace.stalk_map at H,
haveI H' := Top.presheaf.stalk_pushforward.stalk_pushforward_iso_of_open_embedding
C hf X.presheaf y,
have := @@is_iso.comp_is_iso _ H (@@is_iso.inv_is_iso _ H'),
rw [category.assoc, is_iso.hom_inv_id, category.comp_id] at this,
exact this
end }
end of_stalk_iso
section prod
variables [has_limits C] {ι : Type v} (F : discrete ι ⥤ SheafedSpace C) [has_colimit F]
(i : discrete ι)
lemma sigma_ι_open_embedding : open_embedding (colimit.ι F i).base :=
begin
rw ← (show _ = (colimit.ι F i).base,
from ι_preserves_colimits_iso_inv (SheafedSpace.forget C) F i),
have : _ = _ ≫ colimit.ι (discrete.functor ((F ⋙ SheafedSpace.forget C).obj ∘ discrete.mk)) i :=
has_colimit.iso_of_nat_iso_ι_hom discrete.nat_iso_functor i,
rw ← iso.eq_comp_inv at this,
rw this,
have : colimit.ι _ _ ≫ _ = _ :=
Top.sigma_iso_sigma_hom_ι.{v v} ((F ⋙ SheafedSpace.forget C).obj ∘ discrete.mk) i.as,
rw ← iso.eq_comp_inv at this,
cases i,
rw this,
simp_rw [← category.assoc, Top.open_embedding_iff_comp_is_iso,
Top.open_embedding_iff_is_iso_comp],
dsimp,
exact open_embedding_sigma_mk
end
lemma image_preimage_is_empty (j : discrete ι) (h : i ≠ j) (U : opens (F.obj i)) :
(opens.map (colimit.ι (F ⋙ SheafedSpace.forget_to_PresheafedSpace) j).base).obj
((opens.map (preserves_colimit_iso SheafedSpace.forget_to_PresheafedSpace F).inv.base).obj
((sigma_ι_open_embedding F i).is_open_map.functor.obj U)) = ⊥ :=
begin
ext,
apply iff_false_intro,
rintro ⟨y, hy, eq⟩,
replace eq := concrete_category.congr_arg
(preserves_colimit_iso (SheafedSpace.forget C) F ≪≫
has_colimit.iso_of_nat_iso discrete.nat_iso_functor ≪≫ Top.sigma_iso_sigma.{v} _).hom eq,
simp_rw [category_theory.iso.trans_hom, ← Top.comp_app, ← PresheafedSpace.comp_base] at eq,
rw ι_preserves_colimits_iso_inv at eq,
change ((SheafedSpace.forget C).map (colimit.ι F i) ≫ _) y =
((SheafedSpace.forget C).map (colimit.ι F j) ≫ _) x at eq,
cases i, cases j,
rw [ι_preserves_colimits_iso_hom_assoc, ι_preserves_colimits_iso_hom_assoc,
has_colimit.iso_of_nat_iso_ι_hom_assoc, has_colimit.iso_of_nat_iso_ι_hom_assoc,
Top.sigma_iso_sigma_hom_ι.{v}, Top.sigma_iso_sigma_hom_ι.{v}] at eq,
exact h (congr_arg discrete.mk (congr_arg sigma.fst eq)),
end
instance sigma_ι_is_open_immersion [has_strict_terminal_objects C] :
SheafedSpace.is_open_immersion (colimit.ι F i) :=
{ base_open := sigma_ι_open_embedding F i,
c_iso := λ U, begin
have e : colimit.ι F i = _ :=
(ι_preserves_colimits_iso_inv SheafedSpace.forget_to_PresheafedSpace F i).symm,
have H : open_embedding (colimit.ι (F ⋙ SheafedSpace.forget_to_PresheafedSpace) i ≫
(preserves_colimit_iso SheafedSpace.forget_to_PresheafedSpace F).inv).base :=
e ▸ sigma_ι_open_embedding F i,
suffices : is_iso ((colimit.ι (F ⋙ SheafedSpace.forget_to_PresheafedSpace) i ≫
(preserves_colimit_iso SheafedSpace.forget_to_PresheafedSpace F).inv).c.app
(op (H.is_open_map.functor.obj U))),
{ convert this },
rw [PresheafedSpace.comp_c_app,
← PresheafedSpace.colimit_presheaf_obj_iso_componentwise_limit_hom_π],
rsufficesI : is_iso (limit.π (PresheafedSpace.componentwise_diagram
(F ⋙ SheafedSpace.forget_to_PresheafedSpace)
((opens.map (preserves_colimit_iso SheafedSpace.forget_to_PresheafedSpace F).inv.base).obj
(unop $ op $ H.is_open_map.functor.obj U))) (op i)),
{ apply_instance },
apply limit_π_is_iso_of_is_strict_terminal,
intros j hj,
induction j using opposite.rec,
dsimp,
convert (F.obj j).sheaf.is_terminal_of_empty,
convert image_preimage_is_empty F i j (λ h, hj (congr_arg op h.symm)) U,
exact (congr_arg PresheafedSpace.hom.base e).symm
end }
end prod
end SheafedSpace.is_open_immersion
namespace LocallyRingedSpace.is_open_immersion
section pullback
variables {X Y Z : LocallyRingedSpace.{u}} (f : X ⟶ Z) (g : Y ⟶ Z)
variable [H : LocallyRingedSpace.is_open_immersion f]
@[priority 100]
instance of_is_iso [is_iso g] :
LocallyRingedSpace.is_open_immersion g :=
@@PresheafedSpace.is_open_immersion.of_is_iso _ g.1 ⟨⟨(inv g).1,
by { erw ← LocallyRingedSpace.comp_val, rw is_iso.hom_inv_id,
erw ← LocallyRingedSpace.comp_val, rw is_iso.inv_hom_id, split; simpa }⟩⟩
include H
instance comp (g : Z ⟶ Y) [LocallyRingedSpace.is_open_immersion g] :
LocallyRingedSpace.is_open_immersion (f ≫ g) := PresheafedSpace.is_open_immersion.comp f.1 g.1
instance mono : mono f :=
LocallyRingedSpace.forget_to_SheafedSpace.mono_of_mono_map (show mono f.1, by apply_instance)
instance : SheafedSpace.is_open_immersion (LocallyRingedSpace.forget_to_SheafedSpace.map f) := H
/-- An explicit pullback cone over `cospan f g` if `f` is an open immersion. -/
def pullback_cone_of_left : pullback_cone f g :=
begin
refine pullback_cone.mk _
(Y.of_restrict (Top.snd_open_embedding_of_left_open_embedding H.base_open g.1.base)) _,
{ use PresheafedSpace.is_open_immersion.pullback_cone_of_left_fst f.1 g.1,
intro x,
have := PresheafedSpace.stalk_map.congr_hom _ _
(PresheafedSpace.is_open_immersion.pullback_cone_of_left_condition f.1 g.1) x,
rw [PresheafedSpace.stalk_map.comp, PresheafedSpace.stalk_map.comp] at this,
rw ← is_iso.eq_inv_comp at this,
rw this,
apply_instance },
{ exact LocallyRingedSpace.hom.ext _ _
(PresheafedSpace.is_open_immersion.pullback_cone_of_left_condition _ _) },
end
instance : LocallyRingedSpace.is_open_immersion (pullback_cone_of_left f g).snd :=
show PresheafedSpace.is_open_immersion (Y.to_PresheafedSpace.of_restrict _), by apply_instance
/-- The constructed `pullback_cone_of_left` is indeed limiting. -/
def pullback_cone_of_left_is_limit : is_limit (pullback_cone_of_left f g) :=
pullback_cone.is_limit_aux' _ $ λ s,
begin
use PresheafedSpace.is_open_immersion.pullback_cone_of_left_lift f.1 g.1
(pullback_cone.mk s.fst.1 s.snd.1 (congr_arg LocallyRingedSpace.hom.val s.condition)),
{ intro x,
have := PresheafedSpace.stalk_map.congr_hom _ _
(PresheafedSpace.is_open_immersion.pullback_cone_of_left_lift_snd f.1 g.1
(pullback_cone.mk s.fst.1 s.snd.1 (congr_arg LocallyRingedSpace.hom.val s.condition))) x,
change _ = _ ≫ PresheafedSpace.stalk_map s.snd.1 x at this,
rw [PresheafedSpace.stalk_map.comp, ← is_iso.eq_inv_comp] at this,
rw this,
apply_instance },
split,
{ exact LocallyRingedSpace.hom.ext _ _
(PresheafedSpace.is_open_immersion.pullback_cone_of_left_lift_fst f.1 g.1 _) },
split,
{ exact LocallyRingedSpace.hom.ext _ _
(PresheafedSpace.is_open_immersion.pullback_cone_of_left_lift_snd f.1 g.1 _) },
intros m h₁ h₂,
rw ← cancel_mono (pullback_cone_of_left f g).snd,
exact (h₂.trans (LocallyRingedSpace.hom.ext _ _
(PresheafedSpace.is_open_immersion.pullback_cone_of_left_lift_snd f.1 g.1
(pullback_cone.mk s.fst.1 s.snd.1 (congr_arg LocallyRingedSpace.hom.val s.condition))).symm))
end
instance has_pullback_of_left :
has_pullback f g :=
⟨⟨⟨_, pullback_cone_of_left_is_limit f g⟩⟩⟩
instance has_pullback_of_right :
has_pullback g f := has_pullback_symmetry f g
/-- Open immersions are stable under base-change. -/
instance pullback_snd_of_left :
LocallyRingedSpace.is_open_immersion (pullback.snd : pullback f g ⟶ _) :=
begin
delta pullback.snd,
rw ← limit.iso_limit_cone_hom_π ⟨_, pullback_cone_of_left_is_limit f g⟩ walking_cospan.right,
apply_instance
end
/-- Open immersions are stable under base-change. -/
instance pullback_fst_of_right :
LocallyRingedSpace.is_open_immersion (pullback.fst : pullback g f ⟶ _) :=
begin
rw ← pullback_symmetry_hom_comp_snd,
apply_instance
end
instance pullback_to_base_is_open_immersion [LocallyRingedSpace.is_open_immersion g] :
LocallyRingedSpace.is_open_immersion (limit.π (cospan f g) walking_cospan.one) :=
begin
rw [←limit.w (cospan f g) walking_cospan.hom.inl, cospan_map_inl],
apply_instance
end
instance forget_preserves_pullback_of_left :
preserves_limit (cospan f g) LocallyRingedSpace.forget_to_SheafedSpace :=
preserves_limit_of_preserves_limit_cone (pullback_cone_of_left_is_limit f g)
begin
apply (is_limit_map_cone_pullback_cone_equiv _ _).symm.to_fun,
apply is_limit_of_is_limit_pullback_cone_map SheafedSpace.forget_to_PresheafedSpace,
exact PresheafedSpace.is_open_immersion.pullback_cone_of_left_is_limit f.1 g.1
end
instance forget_to_PresheafedSpace_preserves_pullback_of_left :
preserves_limit (cospan f g)
(LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget_to_PresheafedSpace) :=
preserves_limit_of_preserves_limit_cone (pullback_cone_of_left_is_limit f g)
begin
apply (is_limit_map_cone_pullback_cone_equiv _ _).symm.to_fun,
exact PresheafedSpace.is_open_immersion.pullback_cone_of_left_is_limit f.1 g.1
end
instance forget_to_PresheafedSpace_preserves_open_immersion :
PresheafedSpace.is_open_immersion ((LocallyRingedSpace.forget_to_SheafedSpace ⋙
SheafedSpace.forget_to_PresheafedSpace).map f) := H
instance forget_to_Top_preserves_pullback_of_left :
preserves_limit (cospan f g)
(LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget _) :=
begin
change preserves_limit _
((LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget_to_PresheafedSpace)
⋙ PresheafedSpace.forget _),
apply_with limits.comp_preserves_limit { instances := ff },
apply_instance,
apply preserves_limit_of_iso_diagram _ (diagram_iso_cospan.{u} _).symm,
dsimp [SheafedSpace.forget_to_PresheafedSpace],
apply_instance,
end
instance forget_reflects_pullback_of_left :
reflects_limit (cospan f g) LocallyRingedSpace.forget_to_SheafedSpace :=
reflects_limit_of_reflects_isomorphisms _ _
instance forget_preserves_pullback_of_right :
preserves_limit (cospan g f) LocallyRingedSpace.forget_to_SheafedSpace :=
preserves_pullback_symmetry _ _ _
instance forget_to_PresheafedSpace_preserves_pullback_of_right :
preserves_limit (cospan g f) (LocallyRingedSpace.forget_to_SheafedSpace ⋙
SheafedSpace.forget_to_PresheafedSpace) :=
preserves_pullback_symmetry _ _ _
instance forget_reflects_pullback_of_right :
reflects_limit (cospan g f) LocallyRingedSpace.forget_to_SheafedSpace :=
reflects_limit_of_reflects_isomorphisms _ _
instance forget_to_PresheafedSpace_reflects_pullback_of_left :
reflects_limit (cospan f g)
(LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget_to_PresheafedSpace) :=
reflects_limit_of_reflects_isomorphisms _ _
instance forget_to_PresheafedSpace_reflects_pullback_of_right :
reflects_limit (cospan g f)
(LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget_to_PresheafedSpace) :=
reflects_limit_of_reflects_isomorphisms _ _
lemma pullback_snd_is_iso_of_range_subset (H' : set.range g.1.base ⊆ set.range f.1.base) :
is_iso (pullback.snd : pullback f g ⟶ _) :=
begin
apply_with (reflects_isomorphisms.reflects LocallyRingedSpace.forget_to_SheafedSpace)
{ instances := ff },
apply_with (reflects_isomorphisms.reflects SheafedSpace.forget_to_PresheafedSpace)
{ instances := ff },
erw ← preserves_pullback.iso_hom_snd
(LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget_to_PresheafedSpace) f g,
haveI := PresheafedSpace.is_open_immersion.pullback_snd_is_iso_of_range_subset _ _ H',
apply_instance,
apply_instance
end
/--
The universal property of open immersions:
For an open immersion `f : X ⟶ Z`, given any morphism of schemes `g : Y ⟶ Z` whose topological
image is contained in the image of `f`, we can lift this morphism to a unique `Y ⟶ X` that
commutes with these maps.
-/
def lift (H' : set.range g.1.base ⊆ set.range f.1.base) : Y ⟶ X :=
begin
haveI := pullback_snd_is_iso_of_range_subset f g H',
exact inv (pullback.snd : pullback f g ⟶ _) ≫ pullback.fst,
end
@[simp, reassoc] lemma lift_fac (H' : set.range g.1.base ⊆ set.range f.1.base) :
lift f g H' ≫ f = g :=
by { erw category.assoc, rw is_iso.inv_comp_eq, exact pullback.condition }
lemma lift_uniq (H' : set.range g.1.base ⊆ set.range f.1.base) (l : Y ⟶ X)
(hl : l ≫ f = g) : l = lift f g H' :=
by rw [← cancel_mono f, hl, lift_fac]
lemma lift_range (H' : set.range g.1.base ⊆ set.range f.1.base) :
set.range (lift f g H').1.base = f.1.base ⁻¹' (set.range g.1.base) :=
begin
haveI := pullback_snd_is_iso_of_range_subset f g H',
dsimp only [lift],
have : _ = (pullback.fst : pullback f g ⟶ _).val.base := preserves_pullback.iso_hom_fst
(LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget _) f g,
rw [LocallyRingedSpace.comp_val, SheafedSpace.comp_base, ← this, ← category.assoc, coe_comp],
rw [set.range_comp, set.range_iff_surjective.mpr, set.image_univ, Top.pullback_fst_range],
ext,
split,
{ rintros ⟨y, eq⟩, exact ⟨y, eq.symm⟩ },
{ rintros ⟨y, eq⟩, exact ⟨y, eq.symm⟩ },
{ rw ← Top.epi_iff_surjective,
rw (show (inv (pullback.snd : pullback f g ⟶ _)).val.base = _, from
(LocallyRingedSpace.forget_to_SheafedSpace ⋙ SheafedSpace.forget _).map_inv _),
apply_instance }
end
end pullback
/-- An open immersion is isomorphic to the induced open subscheme on its image. -/
def iso_restrict {X Y : LocallyRingedSpace} {f : X ⟶ Y}
(H : LocallyRingedSpace.is_open_immersion f) : X ≅ Y.restrict H.base_open :=
begin
apply LocallyRingedSpace.iso_of_SheafedSpace_iso,
refine SheafedSpace.forget_to_PresheafedSpace.preimage_iso _,
exact H.iso_restrict
end
end LocallyRingedSpace.is_open_immersion
section open_cover
end open_cover
end algebraic_geometry
|
35beac106ff7354e41b5a12e33397766b029fafc | 74addaa0e41490cbaf2abd313a764c96df57b05d | /Mathlib/tactic/simpa_auto.lean | a420f89a88a4a520ffce58e98b6fbab7cd8cf0e3 | [] | no_license | AurelienSaue/Mathlib4_auto | f538cfd0980f65a6361eadea39e6fc639e9dae14 | 590df64109b08190abe22358fabc3eae000943f2 | refs/heads/master | 1,683,906,849,776 | 1,622,564,669,000 | 1,622,564,669,000 | 371,723,747 | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 919 | lean | /-
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.PrePort
import Mathlib.Lean3Lib.init.default
import Mathlib.tactic.doc_commands
import Mathlib.PostPort
namespace Mathlib
namespace tactic
namespace interactive
/--
This is a "finishing" tactic modification of `simp`. It has two forms.
* `simpa [rules, ...] using e` will simplify the goal and the type of
`e` using `rules`, then try to close the goal using `e`.
Simplifying the type of `e` makes it more likely to match the goal
(which has also been simplified). This construction also tends to be
more robust under changes to the simp lemma set.
* `simpa [rules, ...]` will simplify the goal and the type of a
hypothesis `this` if present in the context, then try to close the goal using
the `assumption` tactic. -/
end Mathlib |
a531e69ef6cd46ad6efafb3c71c6db627e36ae4a | 74addaa0e41490cbaf2abd313a764c96df57b05d | /Mathlib/Lean3Lib/init/meta/converter/default_auto.lean | 1ef94b15d09ccecf8c28ab755afcdb732e0bf38c | [] | no_license | AurelienSaue/Mathlib4_auto | f538cfd0980f65a6361eadea39e6fc639e9dae14 | 590df64109b08190abe22358fabc3eae000943f2 | refs/heads/master | 1,683,906,849,776 | 1,622,564,669,000 | 1,622,564,669,000 | 371,723,747 | 0 | 0 | null | null | null | null | UTF-8 | Lean | false | false | 366 | lean | /-
Copyright (c) 2017 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
Converter monad for building simplifiers.
-/
import Mathlib.PrePort
import Mathlib.Lean3Lib.init.meta.converter.conv
import Mathlib.Lean3Lib.init.meta.converter.interactive
namespace Mathlib
end Mathlib |
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