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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2010 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* Benjamin Gregoire, Laurent Thery, INRIA, 2007 *)
(************************************************************************)
(*i $Id: Nbasic.v 13734 2010-12-21 18:21:56Z letouzey $ i*)
Require Import ZArith.
Require Import BigNumPrelude.
Require Import Max.
Require Import DoubleType.
Require Import DoubleBase.
Require Import CyclicAxioms.
Require Import DoubleCyclic.
(* To compute the necessary height *)
Fixpoint plength (p: positive) : positive :=
match p with
xH => xH
| xO p1 => Psucc (plength p1)
| xI p1 => Psucc (plength p1)
end.
Theorem plength_correct: forall p, (Zpos p < 2 ^ Zpos (plength p))%Z.
assert (F: (forall p, 2 ^ (Zpos (Psucc p)) = 2 * 2 ^ Zpos p)%Z).
intros p; replace (Zpos (Psucc p)) with (1 + Zpos p)%Z.
rewrite Zpower_exp; auto with zarith.
rewrite Zpos_succ_morphism; unfold Zsucc; auto with zarith.
intros p; elim p; simpl plength; auto.
intros p1 Hp1; rewrite F; repeat rewrite Zpos_xI.
assert (tmp: (forall p, 2 * p = p + p)%Z);
try repeat rewrite tmp; auto with zarith.
intros p1 Hp1; rewrite F; rewrite (Zpos_xO p1).
assert (tmp: (forall p, 2 * p = p + p)%Z);
try repeat rewrite tmp; auto with zarith.
rewrite Zpower_1_r; auto with zarith.
Qed.
Theorem plength_pred_correct: forall p, (Zpos p <= 2 ^ Zpos (plength (Ppred p)))%Z.
intros p; case (Psucc_pred p); intros H1.
subst; simpl plength.
rewrite Zpower_1_r; auto with zarith.
pattern p at 1; rewrite <- H1.
rewrite Zpos_succ_morphism; unfold Zsucc; auto with zarith.
generalize (plength_correct (Ppred p)); auto with zarith.
Qed.
Definition Pdiv p q :=
match Zdiv (Zpos p) (Zpos q) with
Zpos q1 => match (Zpos p) - (Zpos q) * (Zpos q1) with
Z0 => q1
| _ => (Psucc q1)
end
| _ => xH
end.
Theorem Pdiv_le: forall p q,
Zpos p <= Zpos q * Zpos (Pdiv p q).
intros p q.
unfold Pdiv.
assert (H1: Zpos q > 0); auto with zarith.
assert (H1b: Zpos p >= 0); auto with zarith.
generalize (Z_div_ge0 (Zpos p) (Zpos q) H1 H1b).
generalize (Z_div_mod_eq (Zpos p) (Zpos q) H1); case Zdiv.
intros HH _; rewrite HH; rewrite Zmult_0_r; rewrite Zmult_1_r; simpl.
case (Z_mod_lt (Zpos p) (Zpos q) H1); auto with zarith.
intros q1 H2.
replace (Zpos p - Zpos q * Zpos q1) with (Zpos p mod Zpos q).
2: pattern (Zpos p) at 2; rewrite H2; auto with zarith.
generalize H2 (Z_mod_lt (Zpos p) (Zpos q) H1); clear H2;
case Zmod.
intros HH _; rewrite HH; auto with zarith.
intros r1 HH (_,HH1); rewrite HH; rewrite Zpos_succ_morphism.
unfold Zsucc; rewrite Zmult_plus_distr_r; auto with zarith.
intros r1 _ (HH,_); case HH; auto.
intros q1 HH; rewrite HH.
unfold Zge; simpl Zcompare; intros HH1; case HH1; auto.
Qed.
Definition is_one p := match p with xH => true | _ => false end.
Theorem is_one_one: forall p, is_one p = true -> p = xH.
intros p; case p; auto; intros p1 H1; discriminate H1.
Qed.
Definition get_height digits p :=
let r := Pdiv p digits in
if is_one r then xH else Psucc (plength (Ppred r)).
Theorem get_height_correct:
forall digits N,
Zpos N <= Zpos digits * (2 ^ (Zpos (get_height digits N) -1)).
intros digits N.
unfold get_height.
assert (H1 := Pdiv_le N digits).
case_eq (is_one (Pdiv N digits)); intros H2.
rewrite (is_one_one _ H2) in H1.
rewrite Zmult_1_r in H1.
change (2^(1-1))%Z with 1; rewrite Zmult_1_r; auto.
clear H2.
apply Zle_trans with (1 := H1).
apply Zmult_le_compat_l; auto with zarith.
rewrite Zpos_succ_morphism; unfold Zsucc.
rewrite Zplus_comm; rewrite Zminus_plus.
apply plength_pred_correct.
Qed.
Definition zn2z_word_comm : forall w n, zn2z (word w n) = word (zn2z w) n.
fix zn2z_word_comm 2.
intros w n; case n.
reflexivity.
intros n0;simpl.
case (zn2z_word_comm w n0).
reflexivity.
Defined.
Fixpoint extend (n:nat) {struct n} : forall w:Type, zn2z w -> word w (S n) :=
match n return forall w:Type, zn2z w -> word w (S n) with
| O => fun w x => x
| S m =>
let aux := extend m in
fun w x => WW W0 (aux w x)
end.
Section ExtendMax.
Open Scope nat_scope.
Fixpoint plusnS (n m: nat) {struct n} : (n + S m = S (n + m))%nat :=
match n return (n + S m = S (n + m))%nat with
| 0 => refl_equal (S m)
| S n1 =>
let v := S (S n1 + m) in
eq_ind_r (fun n => S n = v) (refl_equal v) (plusnS n1 m)
end.
Fixpoint plusn0 n : n + 0 = n :=
match n return (n + 0 = n) with
| 0 => refl_equal 0
| S n1 =>
let v := S n1 in
eq_ind_r (fun n : nat => S n = v) (refl_equal v) (plusn0 n1)
end.
Fixpoint diff (m n: nat) {struct m}: nat * nat :=
match m, n with
O, n => (O, n)
| m, O => (m, O)
| S m1, S n1 => diff m1 n1
end.
Fixpoint diff_l (m n : nat) {struct m} : fst (diff m n) + n = max m n :=
match m return fst (diff m n) + n = max m n with
| 0 =>
match n return (n = max 0 n) with
| 0 => refl_equal _
| S n0 => refl_equal _
end
| S m1 =>
match n return (fst (diff (S m1) n) + n = max (S m1) n)
with
| 0 => plusn0 _
| S n1 =>
let v := fst (diff m1 n1) + n1 in
let v1 := fst (diff m1 n1) + S n1 in
eq_ind v (fun n => v1 = S n)
(eq_ind v1 (fun n => v1 = n) (refl_equal v1) (S v) (plusnS _ _))
_ (diff_l _ _)
end
end.
Fixpoint diff_r (m n: nat) {struct m}: snd (diff m n) + m = max m n :=
match m return (snd (diff m n) + m = max m n) with
| 0 =>
match n return (snd (diff 0 n) + 0 = max 0 n) with
| 0 => refl_equal _
| S _ => plusn0 _
end
| S m =>
match n return (snd (diff (S m) n) + S m = max (S m) n) with
| 0 => refl_equal (snd (diff (S m) 0) + S m)
| S n1 =>
let v := S (max m n1) in
eq_ind_r (fun n => n = v)
(eq_ind_r (fun n => S n = v)
(refl_equal v) (diff_r _ _)) (plusnS _ _)
end
end.
Variable w: Type.
Definition castm (m n: nat) (H: m = n) (x: word w (S m)):
(word w (S n)) :=
match H in (_ = y) return (word w (S y)) with
| refl_equal => x
end.
Variable m: nat.
Variable v: (word w (S m)).
Fixpoint extend_tr (n : nat) {struct n}: (word w (S (n + m))) :=
match n return (word w (S (n + m))) with
| O => v
| S n1 => WW W0 (extend_tr n1)
end.
End ExtendMax.
Implicit Arguments extend_tr[w m].
Implicit Arguments castm[w m n].
Section Reduce.
Variable w : Type.
Variable nT : Type.
Variable N0 : nT.
Variable eq0 : w -> bool.
Variable reduce_n : w -> nT.
Variable zn2z_to_Nt : zn2z w -> nT.
Definition reduce_n1 (x:zn2z w) :=
match x with
| W0 => N0
| WW xh xl =>
if eq0 xh then reduce_n xl
else zn2z_to_Nt x
end.
End Reduce.
Section ReduceRec.
Variable w : Type.
Variable nT : Type.
Variable N0 : nT.
Variable reduce_1n : zn2z w -> nT.
Variable c : forall n, word w (S n) -> nT.
Fixpoint reduce_n (n:nat) : word w (S n) -> nT :=
match n return word w (S n) -> nT with
| O => reduce_1n
| S m => fun x =>
match x with
| W0 => N0
| WW xh xl =>
match xh with
| W0 => @reduce_n m xl
| _ => @c (S m) x
end
end
end.
End ReduceRec.
Section CompareRec.
Variable wm w : Type.
Variable w_0 : w.
Variable compare : w -> w -> comparison.
Variable compare0_m : wm -> comparison.
Variable compare_m : wm -> w -> comparison.
Fixpoint compare0_mn (n:nat) : word wm n -> comparison :=
match n return word wm n -> comparison with
| O => compare0_m
| S m => fun x =>
match x with
| W0 => Eq
| WW xh xl =>
match compare0_mn m xh with
| Eq => compare0_mn m xl
| r => Lt
end
end
end.
Variable wm_base: positive.
Variable wm_to_Z: wm -> Z.
Variable w_to_Z: w -> Z.
Variable w_to_Z_0: w_to_Z w_0 = 0.
Variable spec_compare0_m: forall x,
match compare0_m x with
Eq => w_to_Z w_0 = wm_to_Z x
| Lt => w_to_Z w_0 < wm_to_Z x
| Gt => w_to_Z w_0 > wm_to_Z x
end.
Variable wm_to_Z_pos: forall x, 0 <= wm_to_Z x < base wm_base.
Let double_to_Z := double_to_Z wm_base wm_to_Z.
Let double_wB := double_wB wm_base.
Lemma base_xO: forall n, base (xO n) = (base n)^2.
Proof.
intros n1; unfold base.
rewrite (Zpos_xO n1); rewrite Zmult_comm; rewrite Zpower_mult; auto with zarith.
Qed.
Let double_to_Z_pos: forall n x, 0 <= double_to_Z n x < double_wB n :=
(spec_double_to_Z wm_base wm_to_Z wm_to_Z_pos).
Lemma spec_compare0_mn: forall n x,
match compare0_mn n x with
Eq => 0 = double_to_Z n x
| Lt => 0 < double_to_Z n x
| Gt => 0 > double_to_Z n x
end.
Proof.
intros n; elim n; clear n; auto.
intros x; generalize (spec_compare0_m x); rewrite w_to_Z_0; auto.
intros n Hrec x; case x; unfold compare0_mn; fold compare0_mn; auto.
intros xh xl.
generalize (Hrec xh); case compare0_mn; auto.
generalize (Hrec xl); case compare0_mn; auto.
simpl double_to_Z; intros H1 H2; rewrite H1; rewrite <- H2; auto.
simpl double_to_Z; intros H1 H2; rewrite <- H2; auto.
case (double_to_Z_pos n xl); auto with zarith.
intros H1; simpl double_to_Z.
set (u := DoubleBase.double_wB wm_base n).
case (double_to_Z_pos n xl); intros H2 H3.
assert (0 < u); auto with zarith.
unfold u, DoubleBase.double_wB, base; auto with zarith.
change 0 with (0 + 0); apply Zplus_lt_le_compat; auto with zarith.
apply Zmult_lt_0_compat; auto with zarith.
case (double_to_Z_pos n xh); auto with zarith.
Qed.
Fixpoint compare_mn_1 (n:nat) : word wm n -> w -> comparison :=
match n return word wm n -> w -> comparison with
| O => compare_m
| S m => fun x y =>
match x with
| W0 => compare w_0 y
| WW xh xl =>
match compare0_mn m xh with
| Eq => compare_mn_1 m xl y
| r => Gt
end
end
end.
Variable spec_compare: forall x y,
match compare x y with
Eq => w_to_Z x = w_to_Z y
| Lt => w_to_Z x < w_to_Z y
| Gt => w_to_Z x > w_to_Z y
end.
Variable spec_compare_m: forall x y,
match compare_m x y with
Eq => wm_to_Z x = w_to_Z y
| Lt => wm_to_Z x < w_to_Z y
| Gt => wm_to_Z x > w_to_Z y
end.
Variable wm_base_lt: forall x,
0 <= w_to_Z x < base (wm_base).
Let double_wB_lt: forall n x,
0 <= w_to_Z x < (double_wB n).
Proof.
intros n x; elim n; simpl; auto; clear n.
intros n (H0, H); split; auto.
apply Zlt_le_trans with (1:= H).
unfold double_wB, DoubleBase.double_wB; simpl.
rewrite base_xO.
set (u := base (double_digits wm_base n)).
assert (0 < u).
unfold u, base; auto with zarith.
replace (u^2) with (u * u); simpl; auto with zarith.
apply Zle_trans with (1 * u); auto with zarith.
unfold Zpower_pos; simpl; ring.
Qed.
Lemma spec_compare_mn_1: forall n x y,
match compare_mn_1 n x y with
Eq => double_to_Z n x = w_to_Z y
| Lt => double_to_Z n x < w_to_Z y
| Gt => double_to_Z n x > w_to_Z y
end.
Proof.
intros n; elim n; simpl; auto; clear n.
intros n Hrec x; case x; clear x; auto.
intros y; generalize (spec_compare w_0 y); rewrite w_to_Z_0; case compare; auto.
intros xh xl y; simpl; generalize (spec_compare0_mn n xh); case compare0_mn; intros H1b.
rewrite <- H1b; rewrite Zmult_0_l; rewrite Zplus_0_l; auto.
apply Hrec.
apply Zlt_gt.
case (double_wB_lt n y); intros _ H0.
apply Zlt_le_trans with (1:= H0).
fold double_wB.
case (double_to_Z_pos n xl); intros H1 H2.
apply Zle_trans with (double_to_Z n xh * double_wB n); auto with zarith.
apply Zle_trans with (1 * double_wB n); auto with zarith.
case (double_to_Z_pos n xh); auto with zarith.
Qed.
End CompareRec.
Section AddS.
Variable w wm : Type.
Variable incr : wm -> carry wm.
Variable addr : w -> wm -> carry wm.
Variable injr : w -> zn2z wm.
Variable w_0 u: w.
Fixpoint injs (n:nat): word w (S n) :=
match n return (word w (S n)) with
O => WW w_0 u
| S n1 => (WW W0 (injs n1))
end.
Definition adds x y :=
match y with
W0 => C0 (injr x)
| WW hy ly => match addr x ly with
C0 z => C0 (WW hy z)
| C1 z => match incr hy with
C0 z1 => C0 (WW z1 z)
| C1 z1 => C1 (WW z1 z)
end
end
end.
End AddS.
Lemma spec_opp: forall u x y,
match u with
| Eq => y = x
| Lt => y < x
| Gt => y > x
end ->
match CompOpp u with
| Eq => x = y
| Lt => x < y
| Gt => x > y
end.
Proof.
intros u x y; case u; simpl; auto with zarith.
Qed.
Fixpoint length_pos x :=
match x with xH => O | xO x1 => S (length_pos x1) | xI x1 => S (length_pos x1) end.
Theorem length_pos_lt: forall x y,
(length_pos x < length_pos y)%nat -> Zpos x < Zpos y.
Proof.
intros x; elim x; clear x; [intros x1 Hrec | intros x1 Hrec | idtac];
intros y; case y; clear y; intros y1 H || intros H; simpl length_pos;
try (rewrite (Zpos_xI x1) || rewrite (Zpos_xO x1));
try (rewrite (Zpos_xI y1) || rewrite (Zpos_xO y1));
try (inversion H; fail);
try (assert (Zpos x1 < Zpos y1); [apply Hrec; apply lt_S_n | idtac]; auto with zarith);
assert (0 < Zpos y1); auto with zarith; red; auto.
Qed.
Theorem cancel_app: forall A B (f g: A -> B) x, f = g -> f x = g x.
Proof.
intros A B f g x H; rewrite H; auto.
Qed.
Section SimplOp.
Variable w: Type.
Theorem digits_zop: forall w (x: znz_op w),
znz_digits (mk_zn2z_op x) = xO (znz_digits x).
intros ww x; auto.
Qed.
Theorem digits_kzop: forall w (x: znz_op w),
znz_digits (mk_zn2z_op_karatsuba x) = xO (znz_digits x).
intros ww x; auto.
Qed.
Theorem make_zop: forall w (x: znz_op w),
znz_to_Z (mk_zn2z_op x) =
fun z => match z with
W0 => 0
| WW xh xl => znz_to_Z x xh * base (znz_digits x)
+ znz_to_Z x xl
end.
intros ww x; auto.
Qed.
Theorem make_kzop: forall w (x: znz_op w),
znz_to_Z (mk_zn2z_op_karatsuba x) =
fun z => match z with
W0 => 0
| WW xh xl => znz_to_Z x xh * base (znz_digits x)
+ znz_to_Z x xl
end.
intros ww x; auto.
Qed.
End SimplOp.
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