lean2/library/data/quotient/classical.lean

-- Copyright (c) 2014 Floris van Doorn. All rights reserved.
-- Released under Apache 2.0 license as described in the file LICENSE.
-- Author: Floris van Doorn

import algebra.relation logic.core.nonempty data.subtype
import .basic
import logic.axioms.classical logic.axioms.hilbert logic.axioms.funext

namespace quotient

open relation nonempty subtype

-- abstract quotient
-- -----------------

definition prelim_map {A : Type} (R : A → A → Prop) (a : A) :=
-- TODO: it is interesting how the elaborator fails here
-- epsilon (fun b, R a b)
@epsilon _ (nonempty.intro a) (fun b, R a b)

-- TODO: only needed R reflexive (or weaker: R a a)
theorem prelim_map_rel {A : Type} {R : A → A → Prop} (H : is_equivalence R) (a : A)
  : R a (prelim_map R a) :=
have reflR : reflexive R, from is_reflexive.infer R,
epsilon_spec (exists_intro a (reflR a))

-- TODO: only needed: R PER
theorem prelim_map_congr {A : Type} {R : A → A → Prop} (H1 : is_equivalence R) {a b : A}
  (H2 : R a b) : prelim_map R a = prelim_map R b :=
have symmR : symmetric R, from is_symmetric.infer R,
have transR : transitive R, from is_transitive.infer R,
have H3 : ∀c, R a c ↔ R b c, from
  take c,
    iff.intro
      (assume H4 : R a c, transR (symmR H2) H4)
      (assume H4 : R b c, transR H2 H4),
have H4 : (fun c, R a c) = (fun c, R b c), from funext (take c, iff_to_eq (H3 c)),
show @epsilon _ (nonempty.intro a) (λc, R a c) = @epsilon _ (nonempty.intro b) (λc, R b c),
  from congr_arg _ H4

definition quotient {A : Type} (R : A → A → Prop) : Type := image (prelim_map R)

definition quotient_abs {A : Type} (R : A → A → Prop) : A → quotient R :=
fun_image (prelim_map R)

definition quotient_elt_of {A : Type} (R : A → A → Prop) : quotient R → A := elt_of

-- TODO: I had to make is_quotient transparent -- change this?
theorem quotient_is_quotient  {A : Type} (R : A → A → Prop) (H : is_equivalence R)
  : is_quotient R (quotient_abs R) (quotient_elt_of R) :=
representative_map_to_quotient_equiv
  H
  (prelim_map_rel H)
  (@prelim_map_congr _ _ H)

end quotient
feat(library/standard): port int, and reorganize a lot 2014-08-20 02:32:44 +00:00			`-- Copyright (c) 2014 Floris van Doorn. All rights reserved.`
			`-- Released under Apache 2.0 license as described in the file LICENSE.`
			`-- Author: Floris van Doorn`

refactor(library): rename algebra directory to struc, move categories.lean to algebra 2014-09-16 18:58:54 +00:00			`import algebra.relation logic.core.nonempty data.subtype`
feat(library/standard): port int, and reorganize a lot 2014-08-20 02:32:44 +00:00			`import .basic`
			`import logic.axioms.classical logic.axioms.hilbert logic.axioms.funext`

			`namespace quotient`

feat(frontends/lean): rename 'using' command to 'open' Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-09-03 23:00:38 +00:00			`open relation nonempty subtype`
feat(library/standard): port int, and reorganize a lot 2014-08-20 02:32:44 +00:00
			`-- abstract quotient`
			`-- -----------------`

			`definition prelim_map {A : Type} (R : A → A → Prop) (a : A) :=`
			`-- TODO: it is interesting how the elaborator fails here`
			`-- epsilon (fun b, R a b)`
feat(frontends/lean/inductive_cmd): prefix introduction rules with the name of the inductive datatype Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-09-04 23:36:06 +00:00			`@epsilon _ (nonempty.intro a) (fun b, R a b)`
feat(library/standard): port int, and reorganize a lot 2014-08-20 02:32:44 +00:00
			`-- TODO: only needed R reflexive (or weaker: R a a)`
			`theorem prelim_map_rel {A : Type} {R : A → A → Prop} (H : is_equivalence R) (a : A)`
			`: R a (prelim_map R a) :=`
			`have reflR : reflexive R, from is_reflexive.infer R,`
			`epsilon_spec (exists_intro a (reflR a))`

			`-- TODO: only needed: R PER`
			`theorem prelim_map_congr {A : Type} {R : A → A → Prop} (H1 : is_equivalence R) {a b : A}`
			`(H2 : R a b) : prelim_map R a = prelim_map R b :=`
			`have symmR : symmetric R, from is_symmetric.infer R,`
			`have transR : transitive R, from is_transitive.infer R,`
			`have H3 : ∀c, R a c ↔ R b c, from`
			`take c,`
refactor(library): add namespaces 'or', 'and' and 'iff' Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-09-05 04:25:21 +00:00			`iff.intro`
feat(library/standard): port int, and reorganize a lot 2014-08-20 02:32:44 +00:00			`(assume H4 : R a c, transR (symmR H2) H4)`
			`(assume H4 : R b c, transR H2 H4),`
			`have H4 : (fun c, R a c) = (fun c, R b c), from funext (take c, iff_to_eq (H3 c)),`
feat(frontends/lean/inductive_cmd): prefix introduction rules with the name of the inductive datatype Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-09-04 23:36:06 +00:00			`show @epsilon _ (nonempty.intro a) (λc, R a c) = @epsilon _ (nonempty.intro b) (λc, R b c),`
feat(library/standard): port int, and reorganize a lot 2014-08-20 02:32:44 +00:00			`from congr_arg _ H4`

			`definition quotient {A : Type} (R : A → A → Prop) : Type := image (prelim_map R)`

			`definition quotient_abs {A : Type} (R : A → A → Prop) : A → quotient R :=`
			`fun_image (prelim_map R)`

			`definition quotient_elt_of {A : Type} (R : A → A → Prop) : quotient R → A := elt_of`

			`-- TODO: I had to make is_quotient transparent -- change this?`
			`theorem quotient_is_quotient {A : Type} (R : A → A → Prop) (H : is_equivalence R)`
			`: is_quotient R (quotient_abs R) (quotient_elt_of R) :=`
			`representative_map_to_quotient_equiv`
			`H`
			`(prelim_map_rel H)`
			`(@prelim_map_congr _ _ H)`

			`end quotient`