Powers of large locales

module order-theory.powers-of-large-locales where
Imports
open import foundation.identity-types
open import foundation.propositions
open import foundation.sets
open import foundation.universe-levels

open import order-theory.dependent-products-large-locales
open import order-theory.greatest-lower-bounds-large-posets
open import order-theory.large-locales
open import order-theory.large-meet-semilattices
open import order-theory.large-posets
open import order-theory.large-suplattices
open import order-theory.least-upper-bounds-large-posets
open import order-theory.top-elements-large-posets

Idea

Given a large locale L and a type X : UU l, the large power locale is the locale X → L of functions from X to L.

Definitions

module _
  {α : Level  Level} {β : Level  Level  Level} {l1 : Level}
  (X : UU l1) (L : Large-Locale α β)
  where

  power-Large-Locale :
    Large-Locale  l2  α l2  l1)  l2 l3  β l2 l3  l1)
  power-Large-Locale = Π-Large-Locale  (x : X)  L)

  large-poset-power-Large-Locale :
    Large-Poset  l2  α l2  l1)  l2 l3  β l2 l3  l1)
  large-poset-power-Large-Locale =
    large-poset-Large-Locale power-Large-Locale

  set-power-Large-Locale : (l : Level)  Set (α l  l1)
  set-power-Large-Locale =
    set-Large-Locale power-Large-Locale

  type-power-Large-Locale : (l : Level)  UU (α l  l1)
  type-power-Large-Locale =
    type-Large-Locale power-Large-Locale

  is-set-type-power-Large-Locale :
    {l : Level}  is-set (type-power-Large-Locale l)
  is-set-type-power-Large-Locale =
    is-set-type-Large-Locale power-Large-Locale

  leq-power-Large-Locale-Prop :
    {l2 l3 : Level}  type-power-Large-Locale l2  type-power-Large-Locale l3 
    Prop (β l2 l3  l1)
  leq-power-Large-Locale-Prop =
    leq-Large-Locale-Prop power-Large-Locale

  leq-power-Large-Locale :
    {l2 l3 : Level} 
    type-power-Large-Locale l2  type-power-Large-Locale l3  UU (β l2 l3  l1)
  leq-power-Large-Locale =
    leq-Large-Locale power-Large-Locale

  is-prop-leq-power-Large-Locale :
    {l2 l3 : Level}
    (x : type-power-Large-Locale l2) (y : type-power-Large-Locale l3) 
    is-prop (leq-power-Large-Locale x y)
  is-prop-leq-power-Large-Locale =
    is-prop-leq-Large-Locale power-Large-Locale

  refl-leq-power-Large-Locale :
    {l2 : Level} (x : type-power-Large-Locale l2)  leq-power-Large-Locale x x
  refl-leq-power-Large-Locale =
    refl-leq-Large-Locale power-Large-Locale

  antisymmetric-leq-power-Large-Locale :
    {l2 : Level} (x y : type-power-Large-Locale l2) 
    leq-power-Large-Locale x y  leq-power-Large-Locale y x  x  y
  antisymmetric-leq-power-Large-Locale =
    antisymmetric-leq-Large-Locale power-Large-Locale

  transitive-leq-power-Large-Locale :
    {l2 l3 l4 : Level}
    (x : type-power-Large-Locale l2)
    (y : type-power-Large-Locale l3)
    (z : type-power-Large-Locale l4) 
    leq-power-Large-Locale y z  leq-power-Large-Locale x y 
    leq-power-Large-Locale x z
  transitive-leq-power-Large-Locale =
    transitive-leq-Large-Locale power-Large-Locale

  large-meet-semilattice-power-Large-Locale :
    Large-Meet-Semilattice  l2  α l2  l1)  l2 l3  β l2 l3  l1)
  large-meet-semilattice-power-Large-Locale =
    large-meet-semilattice-Large-Locale power-Large-Locale

  has-meets-power-Large-Locale :
    has-meets-Large-Poset large-poset-power-Large-Locale
  has-meets-power-Large-Locale =
    has-meets-Large-Locale power-Large-Locale

  meet-power-Large-Locale :
    {l2 l3 : Level} 
    type-power-Large-Locale l2  type-power-Large-Locale l3 
    type-power-Large-Locale (l2  l3)
  meet-power-Large-Locale =
    meet-Large-Locale power-Large-Locale

  is-greatest-binary-lower-bound-meet-power-Large-Locale :
    {l2 l3 : Level}
    (x : type-power-Large-Locale l2)
    (y : type-power-Large-Locale l3) 
    is-greatest-binary-lower-bound-Large-Poset
      ( large-poset-power-Large-Locale)
      ( x)
      ( y)
      ( meet-power-Large-Locale x y)
  is-greatest-binary-lower-bound-meet-power-Large-Locale =
    is-greatest-binary-lower-bound-meet-Large-Locale power-Large-Locale

  has-top-element-power-Large-Locale :
    has-top-element-Large-Poset large-poset-power-Large-Locale
  has-top-element-power-Large-Locale =
    has-top-element-Large-Locale power-Large-Locale

  top-power-Large-Locale : type-power-Large-Locale lzero
  top-power-Large-Locale = top-Large-Locale power-Large-Locale

  is-top-element-top-power-Large-Locale :
    {l1 : Level} (x : type-power-Large-Locale l1) 
    leq-power-Large-Locale x top-power-Large-Locale
  is-top-element-top-power-Large-Locale =
    is-top-element-top-Large-Locale power-Large-Locale

  large-suplattice-power-Large-Locale :
    Large-Suplattice  l2  α l2  l1)  l2 l3  β l2 l3  l1)
  large-suplattice-power-Large-Locale =
    large-suplattice-Large-Locale power-Large-Locale

  is-large-suplattice-power-Large-Locale :
    is-large-suplattice-Large-Poset large-poset-power-Large-Locale
  is-large-suplattice-power-Large-Locale =
    is-large-suplattice-Large-Locale power-Large-Locale

  sup-power-Large-Locale :
    {l2 l3 : Level} {J : UU l2} (x : J  type-power-Large-Locale l3) 
    type-power-Large-Locale (l2  l3)
  sup-power-Large-Locale =
    sup-Large-Locale power-Large-Locale

  is-least-upper-bound-sup-power-Large-Locale :
    {l2 l3 : Level} {J : UU l2} (x : J  type-power-Large-Locale l3) 
    is-least-upper-bound-family-of-elements-Large-Poset
      ( large-poset-power-Large-Locale)
      ( x)
      ( sup-power-Large-Locale x)
  is-least-upper-bound-sup-power-Large-Locale =
    is-least-upper-bound-sup-Large-Locale power-Large-Locale

  distributive-meet-sup-power-Large-Locale :
    {l2 l3 l4 : Level}
    (x : type-power-Large-Locale l2)
    {J : UU l3} (y : J  type-power-Large-Locale l4) 
    meet-power-Large-Locale x (sup-power-Large-Locale y) 
    sup-power-Large-Locale  j  meet-power-Large-Locale x (y j))
  distributive-meet-sup-power-Large-Locale =
    distributive-meet-sup-Large-Locale power-Large-Locale