feat(library/standard/data/quotient): import quotient from lean 0.1

This commit is contained in:
Jeremy Avigad 2014-08-17 14:41:23 -07:00 committed by Leonardo de Moura
parent f5987b7bda
commit ad26c7c93c
7 changed files with 687 additions and 35 deletions

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-- Copyright (c) 2014 Microsoft Corporation. All rights reserved.
-- Released under Apache 2.0 license as described in the file LICENSE.
-- Author: Leonardo de Moura
-- Author: Leonardo de Moura, Jeremy Avigad
import logic.classes.inhabited logic.connectives.eq
@ -32,11 +32,11 @@ section
theorem prod_ext (p : prod A B) : pair (pr1 p) (pr2 p) = p :=
pair_destruct p (λx y, refl (x, y))
theorem pair_eq {p1 p2 : prod A B} (H1 : pr1 p1 = pr1 p2) (H2 : pr2 p1 = pr2 p2) : p1 = p2 :=
calc p1 = pair (pr1 p1) (pr2 p1) : symm (prod_ext p1)
... = pair (pr1 p2) (pr2 p1) : {H1}
... = pair (pr1 p2) (pr2 p2) : {H2}
... = p2 : prod_ext p2
theorem pair_eq {a1 a2 : A} {b1 b2 : B} (H1 : a1 = a2) (H2 : b1 = b2) : (a1, b1) = (a2, b2) :=
subst H1 (subst H2 (refl _))
theorem prod_eq {p1 p2 : prod A B} : ∀ (H1 : pr1 p1 = pr1 p2) (H2 : pr2 p1 = pr2 p2), p1 = p2 :=
pair_destruct p1 (take a1 b1, pair_destruct p2 (take a2 b2 H1 H2, pair_eq H1 H2))
theorem prod_inhabited (H1 : inhabited A) (H2 : inhabited B) : inhabited (prod A B) :=
inhabited_elim H1 (λa, inhabited_elim H2 (λb, inhabited_intro (pair a b)))

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-- 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 logic tools.tactic .subtype logic.connectives.cast struc.relation data.prod
import logic.connectives.instances
-- for now: to use substitution (iff_to_eq)
import logic.axioms.classical
-- for the last section
import logic.axioms.hilbert logic.axioms.funext
using relation prod tactic eq_proofs
-- temporary: substiution for iff
theorem substi {a b : Prop} {P : Prop → Prop} (H1 : a ↔ b) (H2 : P a) : P b :=
subst (iff_to_eq H1) H2
theorem transi {a b c : Prop} (H1 : a ↔ b) (H2 : b ↔ c) : a ↔ c :=
eq_to_iff (trans (iff_to_eq H1) (iff_to_eq H2))
theorem symmi {a b : Prop} (H : a ↔ b) : b ↔ a :=
eq_to_iff (symm (iff_to_eq H))
-- until we have the simplifier...
definition simp : tactic := apply @sorry
-- TODO: find a better name, and move to logic.connectives.basic
theorem and_inhabited_left {a : Prop} (b : Prop) (Ha : a) : a ∧ b ↔ b :=
iff_intro (take Hab, and_elim_right Hab) (take Hb, and_intro Ha Hb)
-- auxliary facts about products
-- -----------------------------
-- TODO: move to data.prod?
-- ### flip
definition flip {A B : Type} (a : A × B) : B × A := pair (pr2 a) (pr1 a)
theorem flip_def {A B : Type} (a : A × B) : flip a = pair (pr2 a) (pr1 a) := refl (flip a)
theorem flip_pair {A B : Type} (a : A) (b : B) : flip (pair a b) = pair b a := rfl
theorem flip_pr1 {A B : Type} (a : A × B) : pr1 (flip a) = pr2 a := rfl
theorem flip_pr2 {A B : Type} (a : A × B) : pr2 (flip a) = pr1 a := rfl
theorem flip_flip {A B : Type} (a : A × B) : flip (flip a) = a :=
pair_destruct a (take x y, rfl)
theorem P_flip {A B : Type} {P : A → B → Prop} {a : A × B} (H : P (pr1 a) (pr2 a))
: P (pr2 (flip a)) (pr1 (flip a)) :=
(symm (flip_pr1 a)) ▸ (symm (flip_pr2 a)) ▸ H
theorem flip_inj {A B : Type} {a b : A × B} (H : flip a = flip b) : a = b :=
have H2 : flip (flip a) = flip (flip b), from congr2 flip H,
show a = b, from (flip_flip a) ▸ (flip_flip b) ▸ H2
-- ### coordinatewise unary maps
definition map_pair {A B : Type} (f : A → B) (a : A × A) : B × B :=
pair (f (pr1 a)) (f (pr2 a))
theorem map_pair_def {A B : Type} (f : A → B) (a : A × A)
: map_pair f a = pair (f (pr1 a)) (f (pr2 a)) :=
rfl
theorem map_pair_pair {A B : Type} (f : A → B) (a a' : A)
: map_pair f (pair a a') = pair (f a) (f a') :=
(pr1_pair a a') ▸ (pr2_pair a a') ▸ (rfl)
theorem map_pair_pr1 {A B : Type} (f : A → B) (a : A × A) : pr1 (map_pair f a) = f (pr1 a)
:= pr1_pair _ _
theorem map_pair_pr2 {A B : Type} (f : A → B) (a : A × A) : pr2 (map_pair f a) = f (pr2 a)
:= pr2_pair _ _
-- ### coordinatewise binary maps
definition map_pair2 {A B C : Type} (f : A → B → C) (a : A × A) (b : B × B) : C × C
:= pair (f (pr1 a) (pr1 b)) (f (pr2 a) (pr2 b))
theorem map_pair2_def {A B C : Type} (f : A → B → C) (a : A × A) (b : B × B)
: map_pair2 f a b = pair (f (pr1 a) (pr1 b)) (f (pr2 a) (pr2 b)) := rfl
theorem map_pair2_pair {A B C : Type} (f : A → B → C) (a a' : A) (b b' : B)
: map_pair2 f (pair a a') (pair b b') = pair (f a b) (f a' b') :=
calc
map_pair2 f (pair a a') (pair b b')
= pair (f (pr1 (pair a a')) b) (f (pr2 (pair a a')) (pr2 (pair b b')))
: {pr1_pair b b'}
... = pair (f (pr1 (pair a a')) b) (f (pr2 (pair a a')) b') : {pr2_pair b b'}
... = pair (f (pr1 (pair a a')) b) (f a' b') : {pr2_pair a a'}
... = pair (f a b) (f a' b') : {pr1_pair a a'}
theorem map_pair2_pr1 {A B C : Type} (f : A → B → C) (a : A × A) (b : B × B)
: pr1 (map_pair2 f a b) = f (pr1 a) (pr1 b) := pr1_pair _ _
theorem map_pair2_pr2 {A B C : Type} (f : A → B → C) (a : A × A) (b : B × B)
: pr2 (map_pair2 f a b) = f (pr2 a) (pr2 b) := pr2_pair _ _
theorem map_pair2_flip {A B C : Type} (f : A → B → C) (a : A × A) (b : B × B)
: flip (map_pair2 f a b) = map_pair2 f (flip a) (flip b) :=
have Hx : pr1 (flip (map_pair2 f a b)) = pr1 (map_pair2 f (flip a) (flip b)), from
calc
pr1 (flip (map_pair2 f a b)) = pr2 (map_pair2 f a b) : flip_pr1 _
... = f (pr2 a) (pr2 b) : map_pair2_pr2 f a b
... = f (pr1 (flip a)) (pr2 b) : {symm (flip_pr1 a)}
... = f (pr1 (flip a)) (pr1 (flip b)) : {symm (flip_pr1 b)}
... = pr1 (map_pair2 f (flip a) (flip b)) : symm (map_pair2_pr1 f _ _),
have Hy : pr2 (flip (map_pair2 f a b)) = pr2 (map_pair2 f (flip a) (flip b)), from
calc
pr2 (flip (map_pair2 f a b)) = pr1 (map_pair2 f a b) : flip_pr2 _
... = f (pr1 a) (pr1 b) : map_pair2_pr1 f a b
... = f (pr2 (flip a)) (pr1 b) : {symm (flip_pr2 a)}
... = f (pr2 (flip a)) (pr2 (flip b)) : {symm (flip_pr2 b)}
... = pr2 (map_pair2 f (flip a) (flip b)) : symm (map_pair2_pr2 f _ _),
pair_eq Hx Hy
-- add_rewrite flip_pr1 flip_pr2 flip_pair
-- add_rewrite map_pair_pr1 map_pair_pr2 map_pair_pair
-- add_rewrite map_pair2_pr1 map_pair2_pr2 map_pair2_pair
theorem map_pair2_comm {A B : Type} {f : A → A → B} (Hcomm : ∀a b : A, f a b = f b a)
(v w : A × A) : map_pair2 f v w = map_pair2 f w v :=
have Hx : pr1 (map_pair2 f v w) = pr1 (map_pair2 f w v), from
calc
pr1 (map_pair2 f v w) = f (pr1 v) (pr1 w) : map_pair2_pr1 f v w
... = f (pr1 w) (pr1 v) : Hcomm _ _
... = pr1 (map_pair2 f w v) : symm (map_pair2_pr1 f w v),
have Hy : pr2 (map_pair2 f v w) = pr2 (map_pair2 f w v), from
calc
pr2 (map_pair2 f v w) = f (pr2 v) (pr2 w) : map_pair2_pr2 f v w
... = f (pr2 w) (pr2 v) : Hcomm _ _
... = pr2 (map_pair2 f w v) : symm (map_pair2_pr2 f w v),
pair_eq Hx Hy
theorem map_pair2_assoc {A : Type} {f : A → A → A}
(Hassoc : ∀a b c : A, f (f a b) c = f a (f b c)) (u v w : A × A) :
map_pair2 f (map_pair2 f u v) w = map_pair2 f u (map_pair2 f v w) :=
have Hx : pr1 (map_pair2 f (map_pair2 f u v) w) =
pr1 (map_pair2 f u (map_pair2 f v w)), from
calc
pr1 (map_pair2 f (map_pair2 f u v) w)
= f (pr1 (map_pair2 f u v)) (pr1 w) : map_pair2_pr1 f _ _
... = f (f (pr1 u) (pr1 v)) (pr1 w) : {map_pair2_pr1 f _ _}
... = f (pr1 u) (f (pr1 v) (pr1 w)) : Hassoc (pr1 u) (pr1 v) (pr1 w)
... = f (pr1 u) (pr1 (map_pair2 f v w)) : {symm (map_pair2_pr1 f _ _)}
... = pr1 (map_pair2 f u (map_pair2 f v w)) : symm (map_pair2_pr1 f _ _),
have Hy : pr2 (map_pair2 f (map_pair2 f u v) w) =
pr2 (map_pair2 f u (map_pair2 f v w)), from
calc
pr2 (map_pair2 f (map_pair2 f u v) w)
= f (pr2 (map_pair2 f u v)) (pr2 w) : map_pair2_pr2 f _ _
... = f (f (pr2 u) (pr2 v)) (pr2 w) : {map_pair2_pr2 f _ _}
... = f (pr2 u) (f (pr2 v) (pr2 w)) : Hassoc (pr2 u) (pr2 v) (pr2 w)
... = f (pr2 u) (pr2 (map_pair2 f v w)) : {symm (map_pair2_pr2 f _ _)}
... = pr2 (map_pair2 f u (map_pair2 f v w)) : symm (map_pair2_pr2 f _ _),
pair_eq Hx Hy
theorem map_pair2_id_right {A B : Type} {f : A → B → A} {e : B} (Hid : ∀a : A, f a e = a)
(v : A × A) : map_pair2 f v (pair e e) = v :=
have Hx : pr1 (map_pair2 f v (pair e e)) = pr1 v, from
(calc
pr1 (map_pair2 f v (pair e e)) = f (pr1 v) (pr1 (pair e e)) : by simp
... = f (pr1 v) e : by simp
... = pr1 v : Hid (pr1 v)),
have Hy : pr2 (map_pair2 f v (pair e e)) = pr2 v, from
(calc
pr2 (map_pair2 f v (pair e e)) = f (pr2 v) (pr2 (pair e e)) : by simp
... = f (pr2 v) e : by simp
... = pr2 v : Hid (pr2 v)),
prod_eq Hx Hy
theorem map_pair2_id_left {A B : Type} {f : B → A → A} {e : B} (Hid : ∀a : A, f e a = a)
(v : A × A) : map_pair2 f (pair e e) v = v :=
have Hx : pr1 (map_pair2 f (pair e e) v) = pr1 v, from
calc
pr1 (map_pair2 f (pair e e) v) = f (pr1 (pair e e)) (pr1 v) : by simp
... = f e (pr1 v) : by simp
... = pr1 v : Hid (pr1 v),
have Hy : pr2 (map_pair2 f (pair e e) v) = pr2 v, from
calc
pr2 (map_pair2 f (pair e e) v) = f (pr2 (pair e e)) (pr2 v) : by simp
... = f e (pr2 v) : by simp
... = pr2 v : Hid (pr2 v),
prod_eq Hx Hy
opaque_hint (hiding flip map_pair map_pair2)
-- Theory data.quotient
-- ====================
namespace quotient
using subtype
-- definition and basics
-- ---------------------
-- TODO: make this a structure
definition is_quotient {A B : Type} (R : A → A → Prop) (abs : A → B) (rep : B → A) : Prop :=
(∀b, abs (rep b) = b) ∧
(∀b, R (rep b) (rep b)) ∧
(∀r s, R r s ↔ (R r r ∧ R s s ∧ abs r = abs s))
theorem intro {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(H1 : ∀b, abs (rep b) = b) (H2 : ∀b, R (rep b) (rep b))
(H3 : ∀r s, R r s ↔ (R r r ∧ R s s ∧ abs r = abs s)) : is_quotient R abs rep :=
and_intro H1 (and_intro H2 H3)
-- theorem intro_refl {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
-- (H1 : reflexive R) (H2 : ∀b, abs (rep b) = b)
-- (H3 : ∀r s, R r s ↔ abs r = abs s) : is_quotient R abs rep :=
-- intro
-- H2
-- (take b, H1 (rep b))
-- (take r s,
-- have H4 : R r s ↔ R s s ∧ abs r = abs s,
-- from
-- gensubst.subst (relation.operations.symm (and_inhabited_left _ (H1 s))) (H3 r s),
-- gensubst.subst (relation.operations.symm (and_inhabited_left _ (H1 r))) H4)
-- these work now, but the above still does not
-- theorem test (a b c : Prop) (P : Prop → Prop) (H1 : a ↔ b) (H2 : c ∧ a) : c ∧ b :=
-- gensubst.subst H1 H2
-- theorem test2 {A : Type} {R : A → A → Prop} (Q : Prop) (r s : A)
-- (H3 : R r s ↔ Q) (H1 : R s s) : Q ↔ (R s s ∧ Q) :=
-- relation.operations.symm (and_inhabited_left Q H1)
-- theorem test3 {A : Type} {R : A → A → Prop} (Q : Prop) (r s : A)
-- (H3 : R r s ↔ Q) (H1 : R s s) : R r s ↔ (R s s ∧ Q) :=
-- gensubst.subst (test2 Q r s H3 H1) H3
-- theorem test4 {A : Type} {R : A → A → Prop} (Q : Prop) (r s : A)
-- (H3 : R r s ↔ Q) (H1 : R s s) : R r s ↔ (R s s ∧ Q) :=
-- gensubst.subst (relation.operations.symm (and_inhabited_left Q H1)) H3
theorem intro_refl {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(H1 : reflexive R) (H2 : ∀b, abs (rep b) = b)
(H3 : ∀r s, R r s ↔ abs r = abs s) : is_quotient R abs rep :=
intro
H2
(take b, H1 (rep b))
(take r s,
have H4 : R r s ↔ R s s ∧ abs r = abs s,
from
substi (symmi (and_inhabited_left _ (H1 s))) (H3 r s),
substi (symmi (and_inhabited_left _ (H1 r))) H4)
theorem abs_rep {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) (b : B) : abs (rep b) = b :=
and_elim_left Q b
theorem refl_rep {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) (b : B) : R (rep b) (rep b) :=
and_elim_left (and_elim_right Q) b
theorem R_iff {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) (r s : A) : R r s ↔ (R r r ∧ R s s ∧ abs r = abs s) :=
and_elim_right (and_elim_right Q) r s
theorem refl_left {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {r s : A} (H : R r s) : R r r :=
and_elim_left (iff_elim_left (R_iff Q r s) H)
theorem refl_right {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {r s : A} (H : R r s) : R s s :=
and_elim_left (and_elim_right (iff_elim_left (R_iff Q r s) H))
theorem eq_abs {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {r s : A} (H : R r s) : abs r = abs s :=
and_elim_right (and_elim_right (iff_elim_left (R_iff Q r s) H))
theorem R_intro {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {r s : A} (H1 : R r r) (H2 : R s s) (H3 : abs r = abs s) : R r s :=
iff_elim_right (R_iff Q r s) (and_intro H1 (and_intro H2 H3))
theorem R_intro_refl {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) (H1 : reflexive R) {r s : A} (H2 : abs r = abs s) : R r s :=
iff_elim_right (R_iff Q r s) (and_intro (H1 r) (and_intro (H1 s) H2))
theorem rep_eq {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {a b : B} (H : R (rep a) (rep b)) : a = b :=
calc
a = abs (rep a) : symm (abs_rep Q a)
... = abs (rep b) : {eq_abs Q H}
... = b : abs_rep Q b
theorem R_rep_abs {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {a : A} (H : R a a) : R a (rep (abs a)) :=
have H3 : abs a = abs (rep (abs a)), from symm (abs_rep Q (abs a)),
R_intro Q H (refl_rep Q (abs a)) H3
theorem quotient_imp_symm {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) : symmetric R :=
take a b : A,
assume H : R a b,
have Ha : R a a, from refl_left Q H,
have Hb : R b b, from refl_right Q H,
have Hab : abs b = abs a, from symm (eq_abs Q H),
R_intro Q Hb Ha Hab
theorem quotient_imp_trans {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) : transitive R :=
take a b c : A,
assume Hab : R a b,
assume Hbc : R b c,
have Ha : R a a, from refl_left Q Hab,
have Hc : R c c, from refl_right Q Hbc,
have Hac : abs a = abs c, from trans (eq_abs Q Hab) (eq_abs Q Hbc),
R_intro Q Ha Hc Hac
-- recursion
-- ---------
-- (maybe some are superfluous)
definition rec {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {C : B → Type} (f : forall (a : A), C (abs a)) (b : B) : C b :=
eq_rec_on (abs_rep Q b) (f (rep b))
theorem comp {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {C : B → Type} {f : forall (a : A), C (abs a)}
(H : forall (r s : A) (H' : R r s), eq_rec_on (eq_abs Q H') (f r) = f s)
{a : A} (Ha : R a a) : rec Q f (abs a) = f a :=
have H2 [fact] : R a (rep (abs a)), from R_rep_abs Q Ha,
calc
rec Q f (abs a) = eq_rec_on _ (f (rep (abs a))) : rfl
... = eq_rec_on _ (eq_rec_on _ (f a)) : {symm (H _ _ H2)}
... = eq_rec_on _ (f a) : eq_rec_on_compose _ _ _
... = f a : eq_rec_on_id _ _
definition rec_constant {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {C : Type} (f : A → C) (b : B) : C :=
f (rep b)
theorem comp_constant {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {C : Type} {f : A → C}
(H : forall (r s : A) (H' : R r s), f r = f s)
{a : A} (Ha : R a a) : rec_constant Q f (abs a) = f a :=
have H2 : R a (rep (abs a)), from R_rep_abs Q Ha,
calc
rec_constant Q f (abs a) = f (rep (abs a)) : rfl
... = f a : {symm (H _ _ H2)}
definition rec_binary {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {C : Type} (f : A → A → C) (b c : B) : C :=
f (rep b) (rep c)
theorem comp_binary {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {C : Type} {f : A → A → C}
(H : forall (a a' b b' : A) (Ha : R a a') (Hb : R b b'), f a b = f a' b')
{a b : A} (Ha : R a a) (Hb : R b b) : rec_binary Q f (abs a) (abs b) = f a b :=
have H2 : R a (rep (abs a)), from R_rep_abs Q Ha,
have H3 : R b (rep (abs b)), from R_rep_abs Q Hb,
calc
rec_binary Q f (abs a) (abs b) = f (rep (abs a)) (rep (abs b)) : rfl
... = f a b : {symm (H _ _ _ _ H2 H3)}
theorem comp_binary_refl {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) (Hrefl : reflexive R) {C : Type} {f : A → A → C}
(H : forall (a a' b b' : A) (Ha : R a a') (Hb : R b b'), f a b = f a' b')
(a b : A) : rec_binary Q f (abs a) (abs b) = f a b :=
comp_binary Q H (Hrefl a) (Hrefl b)
definition quotient_map {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) (f : A → A) (b : B) : B :=
abs (f (rep b))
theorem comp_quotient_map {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {f : A → A}
(H : forall (a a' : A) (Ha : R a a'), R (f a) (f a'))
{a : A} (Ha : R a a) : quotient_map Q f (abs a) = abs (f a) :=
have H2 : R a (rep (abs a)), from R_rep_abs Q Ha,
have H3 : R (f a) (f (rep (abs a))), from H _ _ H2,
have H4 : abs (f a) = abs (f (rep (abs a))), from eq_abs Q H3,
symm H4
definition quotient_map_binary {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) (f : A → A → A) (b c : B) : B :=
abs (f (rep b) (rep c))
theorem comp_quotient_map_binary {A B : Type} {R : A → A → Prop} {abs : A → B} {rep : B → A}
(Q : is_quotient R abs rep) {f : A → A → A}
(H : forall (a a' b b' : A) (Ha : R a a') (Hb : R b b'), R (f a b) (f a' b'))
{a b : A} (Ha : R a a) (Hb : R b b) : quotient_map_binary Q f (abs a) (abs b) = abs (f a b) :=
have Ha2 : R a (rep (abs a)), from R_rep_abs Q Ha,
have Hb2 : R b (rep (abs b)), from R_rep_abs Q Hb,
have H2 : R (f a b) (f (rep (abs a)) (rep (abs b))), from H _ _ _ _ Ha2 Hb2,
symm (eq_abs Q H2)
theorem comp_quotient_map_binary_refl {A B : Type} {R : A → A → Prop} (Hrefl : reflexive R)
{abs : A → B} {rep : B → A} (Q : is_quotient R abs rep) {f : A → A → A}
(H : forall (a a' b b' : A) (Ha : R a a') (Hb : R b b'), R (f a b) (f a' b'))
(a b : A) : quotient_map_binary Q f (abs a) (abs b) = abs (f a b) :=
comp_quotient_map_binary Q H (Hrefl a) (Hrefl b)
opaque_hint (hiding rec rec_constant rec_binary quotient_map quotient_map_binary)
-- image
-- -----
-- has to be an abbreviation, so that fun_image_definition below will typecheck outside
-- the file
abbreviation image {A B : Type} (f : A → B) := subtype (fun b, ∃a, f a = b)
theorem image_inhabited {A B : Type} (f : A → B) (H : inhabited A) : inhabited (image f) :=
inhabited_intro (tag (f (default A)) (exists_intro (default A) rfl))
theorem image_inhabited2 {A B : Type} (f : A → B) (a : A) : inhabited (image f) :=
image_inhabited f (inhabited_intro a)
definition fun_image {A B : Type} (f : A → B) (a : A) : image f :=
tag (f a) (exists_intro a rfl)
theorem fun_image_def {A B : Type} (f : A → B) (a : A) :
fun_image f a = tag (f a) (exists_intro a rfl) := rfl
theorem elt_of_fun_image {A B : Type} (f : A → B) (a : A) : elt_of (fun_image f a) = f a :=
elt_of_tag _ _
theorem image_elt_of {A B : Type} {f : A → B} (u : image f) : ∃a, f a = elt_of u :=
has_property u
theorem fun_image_surj {A B : Type} {f : A → B} (u : image f) : ∃a, fun_image f a = u :=
subtype_destruct u
(take (b : B) (H : ∃a, f a = b),
obtain a (H': f a = b), from H,
(exists_intro a (tag_eq H')))
theorem image_tag {A B : Type} {f : A → B} (u : image f) : ∃a H, tag (f a) H = u :=
obtain a (H : fun_image f a = u), from fun_image_surj u,
exists_intro a (exists_intro (exists_intro a rfl) H)
theorem fun_image_eq {A B : Type} (f : A → B) (a a' : A)
: (f a = f a') ↔ (fun_image f a = fun_image f a') :=
iff_intro
(assume H : f a = f a', tag_eq H)
(assume H : fun_image f a = fun_image f a',
subst (subst (congr2 elt_of H) (elt_of_fun_image f a)) (elt_of_fun_image f a'))
theorem idempotent_image_elt_of {A : Type} {f : A → A} (H : ∀a, f (f a) = f a) (u : image f)
: fun_image f (elt_of u) = u :=
obtain (a : A) (Ha : fun_image f a = u), from fun_image_surj u,
calc
fun_image f (elt_of u) = fun_image f (elt_of (fun_image f a)) : {symm Ha}
... = fun_image f (f a) : {elt_of_fun_image f a}
... = fun_image f a : {iff_elim_left (fun_image_eq f (f a) a) (H a)}
... = u : Ha
theorem idempotent_image_fix {A : Type} {f : A → A} (H : ∀a, f (f a) = f a) (u : image f)
: f (elt_of u) = elt_of u :=
obtain (a : A) (Ha : f a = elt_of u), from image_elt_of u,
calc
f (elt_of u) = f (f a) : {symm Ha}
... = f a : H a
... = elt_of u : Ha
-- construct quotient from representative map
-- ------------------------------------------
theorem representative_map_idempotent {A : Type} {R : A → A → Prop} {f : A → A}
(H1 : ∀a, R a (f a)) (H2 : ∀a b, R a b ↔ R a a ∧ R b b ∧ f a = f b) (a : A)
: f (f a) = f a :=
symm (and_elim_right (and_elim_right (iff_elim_left (H2 a (f a)) (H1 a))))
theorem representative_map_idempotent_equiv {A : Type} {R : A → A → Prop} {f : A → A}
(H1 : ∀a, R a (f a)) (H2 : ∀a b, R a b → f a = f b) (a : A)
: f (f a) = f a :=
symm (H2 a (f a) (H1 a))
theorem representative_map_refl_rep {A : Type} {R : A → A → Prop} {f : A → A}
(H1 : ∀a, R a (f a)) (H2 : ∀a b, R a b ↔ R a a ∧ R b b ∧ f a = f b) (a : A)
: R (f a) (f a) :=
subst (representative_map_idempotent H1 H2 a) (H1 (f a))
theorem representative_map_image_fix {A : Type} {R : A → A → Prop} {f : A → A}
(H1 : ∀a, R a (f a)) (H2 : ∀a a', R a a' ↔ R a a ∧ R a' a' ∧ f a = f a') (b : image f)
: f (elt_of b) = elt_of b :=
idempotent_image_fix (representative_map_idempotent H1 H2) b
theorem representative_map_to_quotient {A : Type} {R : A → A → Prop} {f : A → A}
(H1 : ∀a, R a (f a)) (H2 : ∀a a', R a a' ↔ R a a ∧ R a' a' ∧ f a = f a')
: is_quotient _ (fun_image f) elt_of :=
let abs [inline] := fun_image f in
intro
(take u : image f,
obtain (a : A) (Ha : f a = elt_of u), from image_elt_of u,
have H : elt_of (abs (elt_of u)) = elt_of u, from
calc
elt_of (abs (elt_of u)) = f (elt_of u) : elt_of_fun_image _ _
... = f (f a) : {symm Ha}
... = f a : representative_map_idempotent H1 H2 a
... = elt_of u : Ha,
show abs (elt_of u) = u, from subtype_eq H)
(take u : image f,
show R (elt_of u) (elt_of u), from
obtain (a : A) (Ha : f a = elt_of u), from image_elt_of u,
subst Ha (@representative_map_refl_rep A R f H1 H2 a))
(take a a',
substi (fun_image_eq f a a') (H2 a a'))
-- TODO: fix these
-- e.g. in the next three lemmas, we should not need to specify the equivalence relation
-- but the class inference finds reflexive.class eq
theorem equiv_is_refl {A : Type} {R : A → A → Prop} (equiv : is_equivalence.class R) :=
@operations.refl _ R (@is_equivalence.is_reflexive _ _ equiv)
-- we should be able to write
-- @operations.refl _ R _
theorem equiv_is_symm {A : Type} {R : A → A → Prop} (equiv : is_equivalence.class R) :=
@operations.symm _ R (@is_equivalence.is_symmetric _ _ equiv)
theorem equiv_is_trans {A : Type} {R : A → A → Prop} (equiv : is_equivalence.class R) :=
@operations.trans _ R (@is_equivalence.is_transitive _ _ equiv)
theorem representative_map_equiv_inj {A : Type} {R : A → A → Prop}
(equiv : is_equivalence.class R) {f : A → A} (H1 : ∀a, R a (f a)) (H2 : ∀a b, R a b → f a = f b)
{a b : A} (H3 : f a = f b) : R a b :=
-- have symmR : symmetric R, from @relation.operations.symm _ R _,
have symmR : symmetric R, from equiv_is_symm equiv,
have transR : transitive R, from equiv_is_trans equiv,
show R a b, from
have H2 : R a (f b), from subst H3 (H1 a),
have H3 : R (f b) b, from symmR _ _ (H1 b),
transR _ _ _ H2 H3
theorem representative_map_to_quotient_equiv {A : Type} {R : A → A → Prop}
(equiv : is_equivalence.class R) {f : A → A} (H1 : ∀a, R a (f a)) (H2 : ∀a b, R a b → f a = f b)
: @is_quotient A (image f) R (fun_image f) elt_of :=
representative_map_to_quotient
H1
(take a b,
have reflR : reflexive R, from equiv_is_refl equiv,
have H3 : f a = f b → R a b, from representative_map_equiv_inj equiv H1 H2,
have H4 : R a b ↔ f a = f b, from iff_intro (H2 a b) H3,
have H5 : R a b ↔ R b b ∧ f a = f b,
from substi (symmi (and_inhabited_left _ (reflR b))) H4,
substi (symmi (and_inhabited_left _ (reflR a))) H5)
-- TODO: split this into another file -- it depends on hilbert
-- 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.class R) (a : A)
: R a (prelim_map R a) :=
have reflR : reflexive R, from equiv_is_refl H,
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.class R) {a b : A}
(H2 : R a b) : prelim_map R a = prelim_map R b :=
have symmR : symmetric R, from equiv_is_symm H1,
have transR : transitive R, from equiv_is_trans H1,
have H3 : ∀c, R a c ↔ R b c, from
take c,
iff_intro
(assume H4 : R a c, transR b a c (symmR a b H2) H4)
(assume H4 : R b c, transR a b c 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 congr2 _ 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
theorem quotient_is_quotient {A : Type} (R : A → A → Prop) (H : is_equivalence.class 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)
-- previously:
-- opaque_hint (hiding fun_image rec is_quotient prelim_map)
-- transparent: image, image_incl, quotient, quotient_abs, quotient_rep
end quotient

View file

@ -38,7 +38,7 @@ section
assume (H2' : eq_rec_on H1' b1 = b2'),
show dpair a1 b1 = dpair a1 b2', from
calc
dpair a1 b1 = dpair a1 (eq_rec_on H1' b1) : {symm (eq_rec_on_irrel H1' b1)}
dpair a1 b1 = dpair a1 (eq_rec_on H1' b1) : {symm (eq_rec_on_id H1' b1)}
... = dpair a1 b2' : {H2'}) H1)
b2 H1 H2

View file

@ -27,7 +27,7 @@ section
theorem tag_irrelevant {a : A} (H1 H2 : P a) : tag a H1 = tag a H2 := refl (tag a H1)
theorem tag_ext (a : subtype P) : Π(H : P (elt_of a)), tag (elt_of a) H = a :=
theorem tag_elt_of (a : subtype P) : Π(H : P (elt_of a)), tag (elt_of a) H = a :=
subtype_destruct a (take (x : A) (H1 : P x) (H2 : P x), refl _)
theorem tag_eq {a1 a2 : A} {H1 : P a1} {H2 : P a2} (H3 : a1 = a2) : tag a1 H1 = tag a2 H2 :=

View file

@ -4,5 +4,13 @@ logic.classes
Useful classes for general logical manipulations.
* [inhabited](inhabited.lean) : inhabited types
* [nonempty](nonempty.lean) : nonempty type
* [decidable](decidable.lean) : decidable types
* [congr](congr.lean) : congruences with respect to suitable relations
* [congr](congr.lean) : congruences with respect to suitable relations
Constructively, inhabited types have a witness, while nonempty types
are "proof irrelevant". Classically (assuming the axiom in
`logic.axioms.hilbert`) the two are equivalent. Type class inferences
are set up to use "inhabited" however, so users should use that to
declare that types have an element. Use "nonempty" in the hypothesis
of a theorem when the theorem does not depend on the witness chosen.

View file

@ -14,7 +14,12 @@ inductive eq {A : Type} (a : A) : A → Prop :=
infix `=`:50 := eq
theorem eq_irrel {A : Type} {a : A} (H1 : a = a) : H1 = (refl a) := refl _
-- TODO: try this out -- shorthand for "refl _"
notation `rfl`:max := refl _
theorem eq_id_refl {A : Type} {a : A} (H1 : a = a) : H1 = (refl a) := rfl
theorem eq_irrel {A : Type} {a b : A} (H1 H2 : a = b) : H1 = H2 := rfl
theorem subst {A : Type} {a b : A} {P : A → Prop} (H1 : a = b) (H2 : P a) : P b :=
eq_rec H2 H1
@ -37,11 +42,17 @@ assume H : true = false,
definition eq_rec_on {A : Type} {a1 a2 : A} {B : A → Type} (H1 : a1 = a2) (H2 : B a1) : B a2 :=
eq_rec H2 H1
theorem eq_rec_on_irrel {A : Type} {a : A} {B : A → Type} (H : a = a) (b : B a) : eq_rec_on H b = b :=
theorem eq_rec_on_id {A : Type} {a : A} {B : A → Type} (H : a = a) (b : B a) : eq_rec_on H b = b :=
@trans _ _ (eq_rec_on (refl a) b) _ (refl _) (refl _)
theorem eq_rec_irrel {A : Type} {a : A} {B : A → Type} (H : a = a) (b : B a) : eq_rec b H = b :=
eq_rec_on_irrel H b
theorem eq_rec_id {A : Type} {a : A} {B : A → Type} (H : a = a) (b : B a) : eq_rec b H = b :=
eq_rec_on_id H b
theorem eq_rec_on_compose {A : Type} {a b c : A} {P : A → Type} (H1 : a = b) (H2 : b = c) (u : P a) :
eq_rec_on H2 (eq_rec_on H1 u) = eq_rec_on (trans H1 H2) u :=
(show ∀(H2 : b = c), eq_rec_on H2 (eq_rec_on H1 u) = eq_rec_on (trans H1 H2) u,
from eq_rec_on H2 (take (H2 : b = b), eq_rec_on_id H2 _))
H2
namespace eq_proofs
postfix `⁻¹`:100 := symm

View file

@ -1,8 +1,6 @@
----------------------------------------------------------------------------------------------------
-- 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.prop
@ -17,45 +15,81 @@ abbreviation transitive {T : Type} (R : T → T → Type) : Type := ∀x y z, R
namespace is_reflexive
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : reflexive R → class R
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : reflexive R → class R
abbreviation app ⦃T : Type⦄ {R : T → T → Type} (C : class R) : reflexive R
:= class_rec (λu, u) C
abbreviation app ⦃T : Type⦄ {R : T → T → Type} (C : class R) : reflexive R :=
class_rec (λu, u) C
abbreviation infer ⦃T : Type⦄ {R : T → T → Type} {C : class R} : reflexive R
:= class_rec (λu, u) C
abbreviation infer ⦃T : Type⦄ {R : T → T → Type} {C : class R} : reflexive R :=
class_rec (λu, u) C
end is_reflexive
namespace is_symmetric
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : symmetric R → class R
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : symmetric R → class R
abbreviation app ⦃T : Type⦄ {R : T → T → Type} (C : class R) ⦃x y : T⦄ (H : R x y) : R y x
:= class_rec (λu, u) C x y H
abbreviation app ⦃T : Type⦄ {R : T → T → Type} (C : class R) ⦃x y : T⦄ (H : R x y) : R y x :=
class_rec (λu, u) C x y H
abbreviation infer ⦃T : Type⦄ {R : T → T → Type} {C : class R} ⦃x y : T⦄ (H : R x y) : R y x
:= class_rec (λu, u) C x y H
abbreviation infer ⦃T : Type⦄ {R : T → T → Type} {C : class R} ⦃x y : T⦄ (H : R x y) : R y x :=
class_rec (λu, u) C x y H
end is_symmetric
namespace is_transitive
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : transitive R → class R
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : transitive R → class R
abbreviation app ⦃T : Type⦄ {R : T → T → Type} (C : class R) ⦃x y z : T⦄ (H1 : R x y)
(H2 : R y z) : R x z
:= class_rec (λu, u) C x y z H1 H2
abbreviation app ⦃T : Type⦄ {R : T → T → Type} (C : class R) ⦃x y z : T⦄ (H1 : R x y)
(H2 : R y z) : R x z :=
class_rec (λu, u) C x y z H1 H2
abbreviation infer ⦃T : Type⦄ {R : T → T → Type} {C : class R} ⦃x y z : T⦄ (H1 : R x y)
(H2 : R y z) : R x z
:= class_rec (λu, u) C x y z H1 H2
abbreviation infer ⦃T : Type⦄ {R : T → T → Type} {C : class R} ⦃x y z : T⦄ (H1 : R x y)
(H2 : R y z) : R x z :=
class_rec (λu, u) C x y z H1 H2
end is_transitive
namespace is_equivalence
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : is_reflexive.class R → is_symmetric.class R → is_transitive.class R → class R
theorem is_reflexive {T : Type} {R : T → T → Type} {C : class R} : is_reflexive.class R :=
class_rec (λx y z, x) C
theorem is_symmetric {T : Type} {R : T → T → Type} {C : class R} : is_symmetric.class R :=
class_rec (λx y z, y) C
theorem is_transitive {T : Type} {R : T → T → Type} {C : class R} : is_transitive.class R :=
class_rec (λx y z, z) C
end is_equivalence
instance is_equivalence.is_reflexive
instance is_equivalence.is_symmetric
instance is_equivalence.is_transitive
namespace is_PER
inductive class {T : Type} (R : T → T → Type) : Prop :=
| mk : is_symmetric.class R → is_transitive.class R → class R
theorem is_symmetric {T : Type} {R : T → T → Type} {C : class R} : is_symmetric.class R :=
class_rec (λx y, x) C
theorem is_transitive {T : Type} {R : T → T → Type} {C : class R} : is_transitive.class R :=
class_rec (λx y, y) C
end is_PER
-- instance is_PER.is_symmetric
instance is_PER.is_transitive
-- Congruence for unary and binary functions
-- -----------------------------------------