From Coq Require Import ZArith Lia Zquot.
Require Import SpecFloatCompat.
Notation cond_Zopp :=
cond_Zopp (
only parsing).
Notation iter_pos :=
iter_pos (
only parsing).
Section Zmissing.
About Z
Theorem Zopp_le_cancel :
forall x y :
Z,
(-
y <= -
x)%
Z ->
Z.le x y.
Proof.
intros x y Hxy.
apply Zplus_le_reg_r with (-x - y)%Z.
now ring_simplify.
Qed.
Theorem Zgt_not_eq :
forall x y :
Z,
(
y <
x)%
Z -> (
x <>
y)%
Z.
Proof.
intros x y H Hn.
apply Z.lt_irrefl with x.
now rewrite Hn at 1.
Qed.
End Zmissing.
Section Proof_Irrelevance.
Scheme eq_dep_elim :=
Induction for eq Sort Type.
Definition eqbool_dep P (
h1 :
P true)
b :=
match b return P b ->
Prop with
|
true =>
fun (
h2 :
P true) =>
h1 =
h2
|
false =>
fun (
h2 :
P false) =>
False
end.
Lemma eqbool_irrelevance :
forall (
b :
bool) (
h1 h2 :
b =
true),
h1 =
h2.
Proof.
assert (forall (h : true = true), refl_equal true = h).
apply (eq_dep_elim bool true (eqbool_dep _ _) (refl_equal _)).
intros b.
case b.
intros h1 h2.
now rewrite <- (H h1).
intros h.
discriminate h.
Qed.
End Proof_Irrelevance.
Section Even_Odd.
Theorem Zeven_ex :
forall x,
exists p,
x = (2 *
p +
if Z.even x then 0
else 1)%
Z.
Proof.
intros [|[n|n|]|[n|n|]].
now exists Z0.
now exists (Zpos n).
now exists (Zpos n).
now exists Z0.
exists (Zneg n - 1)%Z.
change (2 * Zneg n - 1 = 2 * (Zneg n - 1) + 1)%Z.
ring.
now exists (Zneg n).
now exists (-1)%Z.
Qed.
End Even_Odd.
Section Zpower.
Theorem Zpower_plus :
forall n k1 k2, (0 <=
k1)%
Z -> (0 <=
k2)%
Z ->
Zpower n (
k1 +
k2) = (
Zpower n k1 *
Zpower n k2)%
Z.
Proof.
intros n k1 k2 H1 H2.
now apply Zpower_exp ; apply Z.le_ge.
Qed.
Theorem Zpower_Zpower_nat :
forall b e, (0 <=
e)%
Z ->
Zpower b e =
Zpower_nat b (
Z.abs_nat e).
Proof.
intros b [|e|e] He.
apply refl_equal.
apply Zpower_pos_nat.
elim He.
apply refl_equal.
Qed.
Theorem Zpower_nat_S :
forall b e,
Zpower_nat b (
S e) = (
b *
Zpower_nat b e)%
Z.
Proof.
intros b e.
rewrite (Zpower_nat_is_exp 1 e).
apply (f_equal (fun x => x * _)%Z).
apply Zmult_1_r.
Qed.
Theorem Zpower_pos_gt_0 :
forall b p, (0 <
b)%
Z ->
(0 <
Zpower_pos b p)%
Z.
Proof.
intros b p Hb.
rewrite Zpower_pos_nat.
induction (nat_of_P p).
easy.
rewrite Zpower_nat_S.
now apply Zmult_lt_0_compat.
Qed.
Theorem Zeven_Zpower_odd :
forall b e, (0 <=
e)%
Z ->
Z.even b =
false ->
Z.even (
Zpower b e) =
false.
Proof.
intros b e He Hb.
destruct (Z_le_lt_eq_dec _ _ He) as [He'|He'].
rewrite <- Hb.
now apply Z.even_pow.
now rewrite <- He'.
Qed.
The radix must be greater than 1
Record radix := {
radix_val :>
Z ;
radix_prop :
Zle_bool 2
radix_val =
true }.
Theorem radix_val_inj :
forall r1 r2,
radix_val r1 =
radix_val r2 ->
r1 =
r2.
Proof.
intros (r1, H1) (r2, H2) H.
simpl in H.
revert H1.
rewrite H.
intros H1.
apply f_equal.
apply eqbool_irrelevance.
Qed.
Definition radix2 :=
Build_radix 2 (
refl_equal _).
Variable r :
radix.
Theorem radix_gt_0 : (0 <
r)%
Z.
Proof.
apply Z.lt_le_trans with 2%Z.
easy.
apply Zle_bool_imp_le.
apply r.
Qed.
Theorem radix_gt_1 : (1 <
r)%
Z.
Proof.
destruct r as (v, Hr). simpl.
apply Z.lt_le_trans with 2%Z.
easy.
now apply Zle_bool_imp_le.
Qed.
Theorem Zpower_gt_1 :
forall p,
(0 <
p)%
Z ->
(1 <
Zpower r p)%
Z.
Proof.
intros [|p|p] Hp ; try easy.
simpl.
rewrite Zpower_pos_nat.
generalize (lt_O_nat_of_P p).
induction (nat_of_P p).
easy.
intros _.
rewrite Zpower_nat_S.
assert (0 < Zpower_nat r n)%Z.
clear.
induction n.
easy.
rewrite Zpower_nat_S.
apply Zmult_lt_0_compat with (2 := IHn).
apply radix_gt_0.
apply Z.le_lt_trans with (1 * Zpower_nat r n)%Z.
rewrite Zmult_1_l.
now apply (Zlt_le_succ 0).
apply Zmult_lt_compat_r with (1 := H).
apply radix_gt_1.
Qed.
Theorem Zpower_gt_0 :
forall p,
(0 <=
p)%
Z ->
(0 <
Zpower r p)%
Z.
Proof.
intros p Hp.
rewrite Zpower_Zpower_nat with (1 := Hp).
induction (Z.abs_nat p).
easy.
rewrite Zpower_nat_S.
apply Zmult_lt_0_compat with (2 := IHn).
apply radix_gt_0.
Qed.
Theorem Zpower_ge_0 :
forall e,
(0 <=
Zpower r e)%
Z.
Proof.
intros [|e|e] ; try easy.
apply Zlt_le_weak.
now apply Zpower_gt_0.
Qed.
Theorem Zpower_le :
forall e1 e2, (
e1 <=
e2)%
Z ->
(
Zpower r e1 <=
Zpower r e2)%
Z.
Proof.
intros e1 e2 He.
destruct (Zle_or_lt 0 e1)%Z as [H1|H1].
replace e2 with (e2 - e1 + e1)%Z by ring.
rewrite Zpower_plus with (2 := H1).
rewrite <- (Zmult_1_l (r ^ e1)) at 1.
apply Zmult_le_compat_r.
apply (Zlt_le_succ 0).
apply Zpower_gt_0.
now apply Zle_minus_le_0.
apply Zpower_ge_0.
now apply Zle_minus_le_0.
clear He.
destruct e1 as [|e1|e1] ; try easy.
apply Zpower_ge_0.
Qed.
Theorem Zpower_lt :
forall e1 e2, (0 <=
e2)%
Z -> (
e1 <
e2)%
Z ->
(
Zpower r e1 <
Zpower r e2)%
Z.
Proof.
intros e1 e2 He2 He.
destruct (Zle_or_lt 0 e1)%Z as [H1|H1].
replace e2 with (e2 - e1 + e1)%Z by ring.
rewrite Zpower_plus with (2 := H1).
rewrite Zmult_comm.
rewrite <- (Zmult_1_r (r ^ e1)) at 1.
apply Zmult_lt_compat2.
split.
now apply Zpower_gt_0.
apply Z.le_refl.
split.
easy.
apply Zpower_gt_1.
clear -He ; lia.
apply Zle_minus_le_0.
now apply Zlt_le_weak.
revert H1.
clear -He2.
destruct e1 ; try easy.
intros _.
now apply Zpower_gt_0.
Qed.
Theorem Zpower_lt_Zpower :
forall e1 e2,
(
Zpower r (
e1 - 1) <
Zpower r e2)%
Z ->
(
e1 <=
e2)%
Z.
Proof.
intros e1 e2 He.
apply Znot_gt_le.
intros H.
apply Zlt_not_le with (1 := He).
apply Zpower_le.
clear -H ; lia.
Qed.
Theorem Zpower_gt_id :
forall n, (
n <
Zpower r n)%
Z.
Proof.
intros [|n|n] ; try easy.
simpl.
rewrite Zpower_pos_nat.
rewrite Zpos_eq_Z_of_nat_o_nat_of_P.
induction (nat_of_P n).
easy.
rewrite inj_S.
change (Zpower_nat r (S n0)) with (r * Zpower_nat r n0)%Z.
unfold Z.succ.
apply Z.lt_le_trans with (r * (Z_of_nat n0 + 1))%Z.
clear.
apply Zlt_0_minus_lt.
replace (r * (Z_of_nat n0 + 1) - (Z_of_nat n0 + 1))%Z with ((r - 1) * (Z_of_nat n0 + 1))%Z by ring.
apply Zmult_lt_0_compat.
cut (2 <= r)%Z. lia.
apply Zle_bool_imp_le.
apply r.
apply (Zle_lt_succ 0).
apply Zle_0_nat.
apply Zmult_le_compat_l.
now apply Zlt_le_succ.
apply Z.le_trans with 2%Z.
easy.
apply Zle_bool_imp_le.
apply r.
Qed.
End Zpower.
Section Div_Mod.
Theorem Zmod_mod_mult :
forall n a b, (0 <
a)%
Z -> (0 <=
b)%
Z ->
Zmod (
Zmod n (
a *
b))
b =
Zmod n b.
Proof.
intros n a [|b|b] Ha Hb.
now rewrite 2!Zmod_0_r.
rewrite (Zmod_eq n (a * Zpos b)).
rewrite Zmult_assoc.
unfold Zminus.
rewrite Zopp_mult_distr_l.
apply Z_mod_plus.
easy.
apply Zmult_gt_0_compat.
now apply Z.lt_gt.
easy.
now elim Hb.
Qed.
Theorem ZOmod_eq :
forall a b,
Z.rem a b = (
a -
Z.quot a b *
b)%
Z.
Proof.
intros a b.
rewrite (Z.quot_rem' a b) at 2.
ring.
Qed.
Theorem ZOmod_mod_mult :
forall n a b,
Z.rem (
Z.rem n (
a *
b))
b =
Z.rem n b.
Proof.
intros n a b.
assert (Z.rem n (a * b) = n + - (Z.quot n (a * b) * a) * b)%Z.
rewrite <- Zopp_mult_distr_l.
rewrite <- Zmult_assoc.
apply ZOmod_eq.
rewrite H.
apply Z_rem_plus.
rewrite <- H.
apply Zrem_sgn2.
Qed.
Theorem Zdiv_mod_mult :
forall n a b, (0 <=
a)%
Z -> (0 <=
b)%
Z ->
(
Z.div (
Zmod n (
a *
b))
a) =
Zmod (
Z.div n a)
b.
Proof.
intros n a b Ha Hb.
destruct (Zle_lt_or_eq _ _ Ha) as [Ha'|Ha'].
destruct (Zle_lt_or_eq _ _ Hb) as [Hb'|Hb'].
rewrite (Zmod_eq n (a * b)).
rewrite (Zmult_comm a b) at 2.
rewrite Zmult_assoc.
unfold Zminus.
rewrite Zopp_mult_distr_l.
rewrite Z_div_plus by now apply Z.lt_gt.
rewrite <- Zdiv_Zdiv by easy.
apply sym_eq.
apply Zmod_eq.
now apply Z.lt_gt.
now apply Zmult_gt_0_compat ; apply Z.lt_gt.
rewrite <- Hb'.
rewrite Zmult_0_r, 2!Zmod_0_r.
apply Zdiv_0_l.
rewrite <- Ha'.
now rewrite 2!Zdiv_0_r, Zmod_0_l.
Qed.
Theorem ZOdiv_mod_mult :
forall n a b,
(
Z.quot (
Z.rem n (
a *
b))
a) =
Z.rem (
Z.quot n a)
b.
Proof.
intros n a b.
destruct (Z.eq_dec a 0) as [Za|Za].
rewrite Za.
now rewrite 2!Zquot_0_r, Zrem_0_l.
assert (Z.rem n (a * b) = n + - (Z.quot (Z.quot n a) b * b) * a)%Z.
rewrite (ZOmod_eq n (a * b)) at 1.
rewrite Zquot_Zquot.
ring.
rewrite H.
rewrite Z_quot_plus with (2 := Za).
apply sym_eq.
apply ZOmod_eq.
rewrite <- H.
apply Zrem_sgn2.
Qed.
Theorem ZOdiv_small_abs :
forall a b,
(
Z.abs a <
b)%
Z ->
Z.quot a b =
Z0.
Proof.
intros a b Ha.
destruct (Zle_or_lt 0 a) as [H|H].
apply Z.quot_small.
split.
exact H.
now rewrite Z.abs_eq in Ha.
apply Z.opp_inj.
rewrite <- Zquot_opp_l, Z.opp_0.
apply Z.quot_small.
generalize (Zabs_non_eq a).
lia.
Qed.
Theorem ZOmod_small_abs :
forall a b,
(
Z.abs a <
b)%
Z ->
Z.rem a b =
a.
Proof.
intros a b Ha.
destruct (Zle_or_lt 0 a) as [H|H].
apply Z.rem_small.
split.
exact H.
now rewrite Z.abs_eq in Ha.
apply Z.opp_inj.
rewrite <- Zrem_opp_l.
apply Z.rem_small.
generalize (Zabs_non_eq a).
lia.
Qed.
Theorem ZOdiv_plus :
forall a b c, (0 <=
a *
b)%
Z ->
(
Z.quot (
a +
b)
c =
Z.quot a c +
Z.quot b c +
Z.quot (
Z.rem a c +
Z.rem b c)
c)%
Z.
Proof.
intros a b c Hab.
destruct (Z.eq_dec c 0) as [Zc|Zc].
now rewrite Zc, 4!Zquot_0_r.
apply Zmult_reg_r with (1 := Zc).
rewrite 2!Zmult_plus_distr_l.
assert (forall d, Z.quot d c * c = d - Z.rem d c)%Z.
intros d.
rewrite ZOmod_eq.
ring.
rewrite 4!H.
rewrite <- Zplus_rem with (1 := Hab).
ring.
Qed.
End Div_Mod.
Section Same_sign.
Theorem Zsame_sign_trans :
forall v u w,
v <>
Z0 ->
(0 <=
u *
v)%
Z -> (0 <=
v *
w)%
Z -> (0 <=
u *
w)%
Z.
Proof.
intros [|v|v] [|u|u] [|w|w] Zv Huv Hvw ; try easy ; now elim Zv.
Qed.
Theorem Zsame_sign_trans_weak :
forall v u w, (
v =
Z0 ->
w =
Z0) ->
(0 <=
u *
v)%
Z -> (0 <=
v *
w)%
Z -> (0 <=
u *
w)%
Z.
Proof.
intros [|v|v] [|u|u] [|w|w] Zv Huv Hvw ; try easy ; now discriminate Zv.
Qed.
Theorem Zsame_sign_imp :
forall u v,
(0 <
u -> 0 <=
v)%
Z ->
(0 < -
u -> 0 <= -
v)%
Z ->
(0 <=
u *
v)%
Z.
Proof.
intros [|u|u] v Hp Hn.
easy.
apply Zmult_le_0_compat.
easy.
now apply Hp.
replace (Zneg u * v)%Z with (Zpos u * (-v))%Z.
apply Zmult_le_0_compat.
easy.
now apply Hn.
rewrite <- Zopp_mult_distr_r.
apply Zopp_mult_distr_l.
Qed.
Theorem Zsame_sign_odiv :
forall u v, (0 <=
v)%
Z ->
(0 <=
u *
Z.quot u v)%
Z.
Proof.
intros u v Hv.
apply Zsame_sign_imp ; intros Hu.
apply Z_quot_pos with (2 := Hv).
now apply Zlt_le_weak.
rewrite <- Zquot_opp_l.
apply Z_quot_pos with (2 := Hv).
now apply Zlt_le_weak.
Qed.
End Same_sign.
Boolean comparisons
Section Zeq_bool.
Inductive Zeq_bool_prop (
x y :
Z) :
bool ->
Prop :=
|
Zeq_bool_true_ :
x =
y ->
Zeq_bool_prop x y true
|
Zeq_bool_false_ :
x <>
y ->
Zeq_bool_prop x y false.
Theorem Zeq_bool_spec :
forall x y,
Zeq_bool_prop x y (
Zeq_bool x y).
Proof.
intros x y.
generalize (Zeq_is_eq_bool x y).
case (Zeq_bool x y) ; intros (H1, H2) ; constructor.
now apply H2.
intros H.
specialize (H1 H).
discriminate H1.
Qed.
Theorem Zeq_bool_true :
forall x y,
x =
y ->
Zeq_bool x y =
true.
Proof.
intros x y.
apply -> Zeq_is_eq_bool.
Qed.
Theorem Zeq_bool_false :
forall x y,
x <>
y ->
Zeq_bool x y =
false.
Proof.
intros x y.
generalize (proj2 (Zeq_is_eq_bool x y)).
case Zeq_bool.
intros He Hn.
elim Hn.
now apply He.
now intros _ _.
Qed.
End Zeq_bool.
Section Zle_bool.
Inductive Zle_bool_prop (
x y :
Z) :
bool ->
Prop :=
|
Zle_bool_true_ : (
x <=
y)%
Z ->
Zle_bool_prop x y true
|
Zle_bool_false_ : (
y <
x)%
Z ->
Zle_bool_prop x y false.
Theorem Zle_bool_spec :
forall x y,
Zle_bool_prop x y (
Zle_bool x y).
Proof.
intros x y.
generalize (Zle_is_le_bool x y).
case Zle_bool ; intros (H1, H2) ; constructor.
now apply H2.
destruct (Zle_or_lt x y) as [H|H].
now specialize (H1 H).
exact H.
Qed.
Theorem Zle_bool_true :
forall x y :
Z,
(
x <=
y)%
Z ->
Zle_bool x y =
true.
Proof.
intros x y.
apply (proj1 (Zle_is_le_bool x y)).
Qed.
Theorem Zle_bool_false :
forall x y :
Z,
(
y <
x)%
Z ->
Zle_bool x y =
false.
Proof.
intros x y Hxy.
generalize (Zle_cases x y).
case Zle_bool ; intros H.
elim (Z.lt_irrefl x).
now apply Z.le_lt_trans with y.
apply refl_equal.
Qed.
End Zle_bool.
Section Zlt_bool.
Inductive Zlt_bool_prop (
x y :
Z) :
bool ->
Prop :=
|
Zlt_bool_true_ : (
x <
y)%
Z ->
Zlt_bool_prop x y true
|
Zlt_bool_false_ : (
y <=
x)%
Z ->
Zlt_bool_prop x y false.
Theorem Zlt_bool_spec :
forall x y,
Zlt_bool_prop x y (
Zlt_bool x y).
Proof.
intros x y.
generalize (Zlt_is_lt_bool x y).
case Zlt_bool ; intros (H1, H2) ; constructor.
now apply H2.
destruct (Zle_or_lt y x) as [H|H].
exact H.
now specialize (H1 H).
Qed.
Theorem Zlt_bool_true :
forall x y :
Z,
(
x <
y)%
Z ->
Zlt_bool x y =
true.
Proof.
intros x y.
apply (proj1 (Zlt_is_lt_bool x y)).
Qed.
Theorem Zlt_bool_false :
forall x y :
Z,
(
y <=
x)%
Z ->
Zlt_bool x y =
false.
Proof.
intros x y Hxy.
generalize (Zlt_cases x y).
case Zlt_bool ; intros H.
elim (Z.lt_irrefl x).
now apply Z.lt_le_trans with y.
apply refl_equal.
Qed.
Theorem negb_Zle_bool :
forall x y :
Z,
negb (
Zle_bool x y) =
Zlt_bool y x.
Proof.
intros x y.
case Zle_bool_spec ; intros H.
now rewrite Zlt_bool_false.
now rewrite Zlt_bool_true.
Qed.
Theorem negb_Zlt_bool :
forall x y :
Z,
negb (
Zlt_bool x y) =
Zle_bool y x.
Proof.
intros x y.
case Zlt_bool_spec ; intros H.
now rewrite Zle_bool_false.
now rewrite Zle_bool_true.
Qed.
End Zlt_bool.
Section Zcompare.
Inductive Zcompare_prop (
x y :
Z) :
comparison ->
Prop :=
|
Zcompare_Lt_ : (
x <
y)%
Z ->
Zcompare_prop x y Lt
|
Zcompare_Eq_ :
x =
y ->
Zcompare_prop x y Eq
|
Zcompare_Gt_ : (
y <
x)%
Z ->
Zcompare_prop x y Gt.
Theorem Zcompare_spec :
forall x y,
Zcompare_prop x y (
Z.compare x y).
Proof.
intros x y.
destruct (Z_dec x y) as [[H|H]|H].
generalize (Zlt_compare _ _ H).
case (Z.compare x y) ; try easy.
now constructor.
generalize (Zgt_compare _ _ H).
case (Z.compare x y) ; try easy.
constructor.
now apply Z.gt_lt.
generalize (proj2 (Zcompare_Eq_iff_eq _ _) H).
case (Z.compare x y) ; try easy.
now constructor.
Qed.
Theorem Zcompare_Lt :
forall x y,
(
x <
y)%
Z ->
Z.compare x y =
Lt.
Proof.
easy.
Qed.
Theorem Zcompare_Eq :
forall x y,
(
x =
y)%
Z ->
Z.compare x y =
Eq.
Proof.
intros x y.
apply <- Zcompare_Eq_iff_eq.
Qed.
Theorem Zcompare_Gt :
forall x y,
(
y <
x)%
Z ->
Z.compare x y =
Gt.
Proof.
intros x y.
apply Z.lt_gt.
Qed.
End Zcompare.
Section cond_Zopp.
Theorem cond_Zopp_negb :
forall x y,
cond_Zopp (
negb x)
y =
Z.opp (
cond_Zopp x y).
Proof.
intros [|] y.
apply sym_eq, Z.opp_involutive.
easy.
Qed.
Theorem abs_cond_Zopp :
forall b m,
Z.abs (
cond_Zopp b m) =
Z.abs m.
Proof.
intros [|] m.
apply Zabs_Zopp.
apply refl_equal.
Qed.
Theorem cond_Zopp_Zlt_bool :
forall m,
cond_Zopp (
Zlt_bool m 0)
m =
Z.abs m.
Proof.
intros m.
apply sym_eq.
case Zlt_bool_spec ; intros Hm.
apply Zabs_non_eq.
now apply Zlt_le_weak.
now apply Z.abs_eq.
Qed.
End cond_Zopp.
Section fast_pow_pos.
Fixpoint Zfast_pow_pos (
v :
Z) (
e :
positive) :
Z :=
match e with
|
xH =>
v
|
xO e' =>
Z.square (
Zfast_pow_pos v e')
|
xI e' =>
Zmult v (
Z.square (
Zfast_pow_pos v e'))
end.
Theorem Zfast_pow_pos_correct :
forall v e,
Zfast_pow_pos v e =
Zpower_pos v e.
Proof.
intros v e.
rewrite <- (Zmult_1_r (Zfast_pow_pos v e)).
unfold Z.pow_pos.
generalize 1%Z.
revert v.
induction e ; intros v f ; simpl.
- rewrite <- 2!IHe.
rewrite Z.square_spec.
ring.
- rewrite <- 2!IHe.
rewrite Z.square_spec.
apply eq_sym, Zmult_assoc.
- apply eq_refl.
Qed.
End fast_pow_pos.
Section faster_div.
Lemma Zdiv_eucl_unique :
forall a b,
Z.div_eucl a b = (
Z.div a b,
Zmod a b).
Proof.
intros a b.
unfold Z.div, Zmod.
now case Z.div_eucl.
Qed.
Fixpoint Zpos_div_eucl_aux1 (
a b :
positive) {
struct b} :=
match b with
|
xO b' =>
match a with
|
xO a' =>
let (
q,
r) :=
Zpos_div_eucl_aux1 a'
b'
in (
q, 2 *
r)%
Z
|
xI a' =>
let (
q,
r) :=
Zpos_div_eucl_aux1 a'
b'
in (
q, 2 *
r + 1)%
Z
|
xH => (
Z0,
Zpos a)
end
|
xH => (
Zpos a,
Z0)
|
xI _ =>
Z.pos_div_eucl a (
Zpos b)
end.
Lemma Zpos_div_eucl_aux1_correct :
forall a b,
Zpos_div_eucl_aux1 a b =
Z.pos_div_eucl a (
Zpos b).
Proof.
intros a b.
revert a.
induction b ; intros a.
- easy.
- change (Z.pos_div_eucl a (Zpos b~0)) with (Z.div_eucl (Zpos a) (Zpos b~0)).
rewrite Zdiv_eucl_unique.
change (Zpos b~0) with (2 * Zpos b)%Z.
rewrite Z.rem_mul_r by easy.
rewrite <- Zdiv_Zdiv by easy.
destruct a as [a|a|].
+ change (Zpos_div_eucl_aux1 a~1 b~0) with (let (q, r) := Zpos_div_eucl_aux1 a b in (q, 2 * r + 1)%Z).
rewrite IHb. clear IHb.
change (Z.pos_div_eucl a (Zpos b)) with (Z.div_eucl (Zpos a) (Zpos b)).
rewrite Zdiv_eucl_unique.
change (Zpos a~1) with (1 + 2 * Zpos a)%Z.
rewrite (Zmult_comm 2 (Zpos a)).
rewrite Z_div_plus_full by easy.
apply f_equal.
rewrite Z_mod_plus_full.
apply Zplus_comm.
+ change (Zpos_div_eucl_aux1 a~0 b~0) with (let (q, r) := Zpos_div_eucl_aux1 a b in (q, 2 * r)%Z).
rewrite IHb. clear IHb.
change (Z.pos_div_eucl a (Zpos b)) with (Z.div_eucl (Zpos a) (Zpos b)).
rewrite Zdiv_eucl_unique.
change (Zpos a~0) with (2 * Zpos a)%Z.
rewrite (Zmult_comm 2 (Zpos a)).
rewrite Z_div_mult_full by easy.
apply f_equal.
now rewrite Z_mod_mult.
+ easy.
- change (Z.pos_div_eucl a 1) with (Z.div_eucl (Zpos a) 1).
rewrite Zdiv_eucl_unique.
now rewrite Zdiv_1_r, Zmod_1_r.
Qed.
Definition Zpos_div_eucl_aux (
a b :
positive) :=
match Pos.compare a b with
|
Lt => (
Z0,
Zpos a)
|
Eq => (1%
Z,
Z0)
|
Gt =>
Zpos_div_eucl_aux1 a b
end.
Lemma Zpos_div_eucl_aux_correct :
forall a b,
Zpos_div_eucl_aux a b =
Z.pos_div_eucl a (
Zpos b).
Proof.
intros a b.
unfold Zpos_div_eucl_aux.
change (Z.pos_div_eucl a (Zpos b)) with (Z.div_eucl (Zpos a) (Zpos b)).
rewrite Zdiv_eucl_unique.
case Pos.compare_spec ; intros H.
now rewrite H, Z_div_same, Z_mod_same.
now rewrite Zdiv_small, Zmod_small by (split ; easy).
rewrite Zpos_div_eucl_aux1_correct.
change (Z.pos_div_eucl a (Zpos b)) with (Z.div_eucl (Zpos a) (Zpos b)).
apply Zdiv_eucl_unique.
Qed.
Definition Zfast_div_eucl (
a b :
Z) :=
match a with
|
Z0 => (0, 0)%
Z
|
Zpos a' =>
match b with
|
Z0 => (0, 0)%
Z
|
Zpos b' =>
Zpos_div_eucl_aux a'
b'
|
Zneg b' =>
let (
q,
r) :=
Zpos_div_eucl_aux a'
b'
in
match r with
|
Z0 => (-
q, 0)%
Z
|
Zpos _ => (-(
q + 1), (
b +
r))%
Z
|
Zneg _ => (-(
q + 1), (
b +
r))%
Z
end
end
|
Zneg a' =>
match b with
|
Z0 => (0, 0)%
Z
|
Zpos b' =>
let (
q,
r) :=
Zpos_div_eucl_aux a'
b'
in
match r with
|
Z0 => (-
q, 0)%
Z
|
Zpos _ => (-(
q + 1), (
b -
r))%
Z
|
Zneg _ => (-(
q + 1), (
b -
r))%
Z
end
|
Zneg b' =>
let (
q,
r) :=
Zpos_div_eucl_aux a'
b'
in (
q, (-
r)%
Z)
end
end.
Theorem Zfast_div_eucl_correct :
forall a b :
Z,
Zfast_div_eucl a b =
Z.div_eucl a b.
Proof.
unfold Zfast_div_eucl.
intros [|a|a] [|b|b] ; try rewrite Zpos_div_eucl_aux_correct ; easy.
Qed.
End faster_div.
Section Iter.
Context {
A :
Type}.
Variable (
f :
A ->
A).
Fixpoint iter_nat (
n :
nat) (
x :
A) {
struct n} :
A :=
match n with
|
S n' =>
iter_nat n' (
f x)
|
O =>
x
end.
Lemma iter_nat_plus :
forall (
p q :
nat) (
x :
A),
iter_nat (
p +
q)
x =
iter_nat p (
iter_nat q x).
Proof.
induction q.
now rewrite plus_0_r.
intros x.
rewrite <- plus_n_Sm.
apply IHq.
Qed.
Lemma iter_nat_S :
forall (
p :
nat) (
x :
A),
iter_nat (
S p)
x =
f (
iter_nat p x).
Proof.
induction p.
easy.
simpl.
intros x.
apply IHp.
Qed.
Lemma iter_pos_nat :
forall (
p :
positive) (
x :
A),
iter_pos f p x =
iter_nat (
Pos.to_nat p)
x.
Proof.
induction p ; intros x.
rewrite Pos2Nat.inj_xI.
simpl.
rewrite plus_0_r.
rewrite iter_nat_plus.
rewrite (IHp (f x)).
apply IHp.
rewrite Pos2Nat.inj_xO.
simpl.
rewrite plus_0_r.
rewrite iter_nat_plus.
rewrite (IHp x).
apply IHp.
easy.
Qed.
End Iter.